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authorBrian Picciano <mediocregopher@gmail.com>2018-11-12 16:18:45 -0500
committerBrian Picciano <mediocregopher@gmail.com>2018-11-12 16:18:45 -0500
commit5ed62d23b4bbbf7717de4adfa0eaf2af19365408 (patch)
treeaa3285b40f9905e45b33f61b77afa06a0d33a790 /assets/viz/2/processing.js
parent886684ec4c0a3d032a974ae8b8e29fb0e0632125 (diff)
add viz 2 post
Diffstat (limited to 'assets/viz/2/processing.js')
-rw-r--r--assets/viz/2/processing.js21796
1 files changed, 21796 insertions, 0 deletions
diff --git a/assets/viz/2/processing.js b/assets/viz/2/processing.js
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+++ b/assets/viz/2/processing.js
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+(function e(t,n,r){function s(o,u){if(!n[o]){if(!t[o]){var a=typeof require=="function"&&require;if(!u&&a)return a(o,!0);if(i)return i(o,!0);var f=new Error("Cannot find module '"+o+"'");throw f.code="MODULE_NOT_FOUND",f}var l=n[o]={exports:{}};t[o][0].call(l.exports,function(e){var n=t[o][1][e];return s(n?n:e)},l,l.exports,e,t,n,r)}return n[o].exports}var i=typeof require=="function"&&require;for(var o=0;o<r.length;o++)s(r[o]);return s})({1:[function(require,module,exports){
+// build script for generating processing.js
+
+var Browser = {
+ isDomPresent: true,
+ navigator: navigator,
+ window: window,
+ document: document,
+ ajax: function(url) {
+ var xhr = new XMLHttpRequest();
+ xhr.open("GET", url, false);
+ if (xhr.overrideMimeType) {
+ xhr.overrideMimeType("text/plain");
+ }
+ xhr.setRequestHeader("If-Modified-Since", "Fri, 01 Jan 1960 00:00:00 GMT");
+ xhr.send(null);
+ // failed request?
+ if (xhr.status !== 200 && xhr.status !== 0) { throw ("XMLHttpRequest failed, status code " + xhr.status); }
+ return xhr.responseText;
+ }
+};
+
+window.Processing = require('./src/')(Browser);
+
+},{"./src/":28}],2:[function(require,module,exports){
+module.exports={
+ "name": "processing-js",
+ "version": "1.6.4",
+ "author": "Processing.js",
+ "repository": {
+ "type": "git",
+ "url": "git@github.com/processing-js/processing-js.git"
+ },
+ "main": "processing.min.js",
+ "bugs": "https://github.com/processing-js/processing-js/issues",
+ "devDependencies": {
+ "argv": "~0.0.2",
+ "browserify": "^11.0.1",
+ "express": "~3.3.3",
+ "grunt": "~0.4.1",
+ "grunt-cli": "~0.1.8",
+ "grunt-contrib-jshint": "~0.4.3",
+ "http-server": "^0.9.0",
+ "minifier": "^0.7.1",
+ "node-minify": "~0.7.3",
+ "nunjucks": "~0.1.9",
+ "open": "0.0.3"
+ },
+ "scripts": {
+ "test": "node test",
+ "test:manual": "http-server -o test/manual",
+ "start": "browserify build.js -o processing.js && minify --output processing.min.js processing.js"
+ },
+ "license": "MIT",
+ "dependencies": {
+ "minifier": "^0.7.1"
+ }
+}
+
+},{}],3:[function(require,module,exports){
+/**
+* A ObjectIterator is an iterator wrapper for objects. If passed object contains
+* the iterator method, the object instance will be replaced by the result returned by
+* this method call. If passed object is an array, the ObjectIterator instance iterates
+* through its items.
+*
+* @param {Object} obj The object to be iterated.
+*/
+module.exports = function ObjectIterator(obj) {
+ if (obj instanceof Array) {
+ // iterate through array items
+ var index = -1;
+ this.hasNext = function() {
+ return ++index < obj.length;
+ };
+ this.next = function() {
+ return obj[index];
+ };
+ } else if (obj.iterator instanceof Function) {
+ return obj.iterator();
+ } else {
+ throw "Unable to iterate: " + obj;
+ }
+};
+
+},{}],4:[function(require,module,exports){
+/**
+ * Processing.js environment constants
+ */
+module.exports = {
+ X: 0,
+ Y: 1,
+ Z: 2,
+
+ R: 3,
+ G: 4,
+ B: 5,
+ A: 6,
+
+ U: 7,
+ V: 8,
+
+ NX: 9,
+ NY: 10,
+ NZ: 11,
+
+ EDGE: 12,
+
+ // Stroke
+ SR: 13,
+ SG: 14,
+ SB: 15,
+ SA: 16,
+
+ SW: 17,
+
+ // Transformations (2D and 3D)
+ TX: 18,
+ TY: 19,
+ TZ: 20,
+
+ VX: 21,
+ VY: 22,
+ VZ: 23,
+ VW: 24,
+
+ // Material properties
+ AR: 25,
+ AG: 26,
+ AB: 27,
+
+ DR: 3,
+ DG: 4,
+ DB: 5,
+ DA: 6,
+
+ SPR: 28,
+ SPG: 29,
+ SPB: 30,
+
+ SHINE: 31,
+
+ ER: 32,
+ EG: 33,
+ EB: 34,
+
+ BEEN_LIT: 35,
+
+ VERTEX_FIELD_COUNT: 36,
+
+ // Renderers
+ P2D: 1,
+ JAVA2D: 1,
+ WEBGL: 2,
+ P3D: 2,
+ OPENGL: 2,
+ PDF: 0,
+ DXF: 0,
+
+ // Platform IDs
+ OTHER: 0,
+ WINDOWS: 1,
+ MAXOSX: 2,
+ LINUX: 3,
+
+ EPSILON: 0.0001,
+
+ MAX_FLOAT: 3.4028235e+38,
+ MIN_FLOAT: -3.4028235e+38,
+ MAX_INT: 2147483647,
+ MIN_INT: -2147483648,
+
+ PI: Math.PI,
+ TWO_PI: 2 * Math.PI,
+ TAU: 2 * Math.PI,
+ HALF_PI: Math.PI / 2,
+ THIRD_PI: Math.PI / 3,
+ QUARTER_PI: Math.PI / 4,
+
+ DEG_TO_RAD: Math.PI / 180,
+ RAD_TO_DEG: 180 / Math.PI,
+
+ WHITESPACE: " \t\n\r\f\u00A0",
+
+ // Color modes
+ RGB: 1,
+ ARGB: 2,
+ HSB: 3,
+ ALPHA: 4,
+ CMYK: 5,
+
+ // Image file types
+ TIFF: 0,
+ TARGA: 1,
+ JPEG: 2,
+ GIF: 3,
+
+ // Filter/convert types
+ BLUR: 11,
+ GRAY: 12,
+ INVERT: 13,
+ OPAQUE: 14,
+ POSTERIZE: 15,
+ THRESHOLD: 16,
+ ERODE: 17,
+ DILATE: 18,
+
+ // Blend modes
+ REPLACE: 0,
+ BLEND: 1 << 0,
+ ADD: 1 << 1,
+ SUBTRACT: 1 << 2,
+ LIGHTEST: 1 << 3,
+ DARKEST: 1 << 4,
+ DIFFERENCE: 1 << 5,
+ EXCLUSION: 1 << 6,
+ MULTIPLY: 1 << 7,
+ SCREEN: 1 << 8,
+ OVERLAY: 1 << 9,
+ HARD_LIGHT: 1 << 10,
+ SOFT_LIGHT: 1 << 11,
+ DODGE: 1 << 12,
+ BURN: 1 << 13,
+
+ // Color component bit masks
+ ALPHA_MASK: 0xff000000,
+ RED_MASK: 0x00ff0000,
+ GREEN_MASK: 0x0000ff00,
+ BLUE_MASK: 0x000000ff,
+
+ // Projection matrices
+ CUSTOM: 0,
+ ORTHOGRAPHIC: 2,
+ PERSPECTIVE: 3,
+
+ // Shapes
+ POINT: 2,
+ POINTS: 2,
+ LINE: 4,
+ LINES: 4,
+ TRIANGLE: 8,
+ TRIANGLES: 9,
+ TRIANGLE_STRIP: 10,
+ TRIANGLE_FAN: 11,
+ QUAD: 16,
+ QUADS: 16,
+ QUAD_STRIP: 17,
+ POLYGON: 20,
+ PATH: 21,
+ RECT: 30,
+ ELLIPSE: 31,
+ ARC: 32,
+ SPHERE: 40,
+ BOX: 41,
+
+ // Arc drawing modes
+ //OPEN: 1, // shared with Shape closing modes
+ CHORD: 2,
+ PIE: 3,
+
+
+ GROUP: 0,
+ PRIMITIVE: 1,
+ //PATH: 21, // shared with Shape PATH
+ GEOMETRY: 3,
+
+ // Shape Vertex
+ VERTEX: 0,
+ BEZIER_VERTEX: 1,
+ CURVE_VERTEX: 2,
+ BREAK: 3,
+ CLOSESHAPE: 4,
+
+ // Shape closing modes
+ OPEN: 1,
+ CLOSE: 2,
+
+ // Shape drawing modes
+ CORNER: 0, // Draw mode convention to use (x, y) to (width, height)
+ CORNERS: 1, // Draw mode convention to use (x1, y1) to (x2, y2) coordinates
+ RADIUS: 2, // Draw mode from the center, and using the radius
+ CENTER_RADIUS: 2, // Deprecated! Use RADIUS instead
+ CENTER: 3, // Draw from the center, using second pair of values as the diameter
+ DIAMETER: 3, // Synonym for the CENTER constant. Draw from the center
+ CENTER_DIAMETER: 3, // Deprecated! Use DIAMETER instead
+
+ // Text vertical alignment modes
+ BASELINE: 0, // Default vertical alignment for text placement
+ TOP: 101, // Align text to the top
+ BOTTOM: 102, // Align text from the bottom, using the baseline
+
+ // UV Texture coordinate modes
+ NORMAL: 1,
+ NORMALIZED: 1,
+ IMAGE: 2,
+
+ // Text placement modes
+ MODEL: 4,
+ SHAPE: 5,
+
+ // Stroke modes
+ SQUARE: 'butt',
+ ROUND: 'round',
+ PROJECT: 'square',
+ MITER: 'miter',
+ BEVEL: 'bevel',
+
+ // Lighting modes
+ AMBIENT: 0,
+ DIRECTIONAL: 1,
+ //POINT: 2, Shared with Shape constant
+ SPOT: 3,
+
+ // Key constants
+
+ // Both key and keyCode will be equal to these values
+ BACKSPACE: 8,
+ TAB: 9,
+ ENTER: 10,
+ RETURN: 13,
+ ESC: 27,
+ DELETE: 127,
+ CODED: 0xffff,
+
+ // p.key will be CODED and p.keyCode will be this value
+ SHIFT: 16,
+ CONTROL: 17,
+ ALT: 18,
+ CAPSLK: 20,
+ PGUP: 33,
+ PGDN: 34,
+ END: 35,
+ HOME: 36,
+ LEFT: 37,
+ UP: 38,
+ RIGHT: 39,
+ DOWN: 40,
+ F1: 112,
+ F2: 113,
+ F3: 114,
+ F4: 115,
+ F5: 116,
+ F6: 117,
+ F7: 118,
+ F8: 119,
+ F9: 120,
+ F10: 121,
+ F11: 122,
+ F12: 123,
+ NUMLK: 144,
+ META: 157,
+ INSERT: 155,
+
+ // Cursor types
+ ARROW: 'default',
+ CROSS: 'crosshair',
+ HAND: 'pointer',
+ MOVE: 'move',
+ TEXT: 'text',
+ WAIT: 'wait',
+ NOCURSOR: "url('data:image/gif;base64,R0lGODlhAQABAIAAAP///wAAACH5BAEAAAAALAAAAAABAAEAAAICRAEAOw=='), auto",
+
+ // Hints
+ DISABLE_OPENGL_2X_SMOOTH: 1,
+ ENABLE_OPENGL_2X_SMOOTH: -1,
+ ENABLE_OPENGL_4X_SMOOTH: 2,
+ ENABLE_NATIVE_FONTS: 3,
+ DISABLE_DEPTH_TEST: 4,
+ ENABLE_DEPTH_TEST: -4,
+ ENABLE_DEPTH_SORT: 5,
+ DISABLE_DEPTH_SORT: -5,
+ DISABLE_OPENGL_ERROR_REPORT: 6,
+ ENABLE_OPENGL_ERROR_REPORT: -6,
+ ENABLE_ACCURATE_TEXTURES: 7,
+ DISABLE_ACCURATE_TEXTURES: -7,
+ HINT_COUNT: 10,
+
+ // PJS defined constants
+ SINCOS_LENGTH: 720, // every half degree
+ PRECISIONB: 15, // fixed point precision is limited to 15 bits!!
+ PRECISIONF: 1 << 15,
+ PREC_MAXVAL: (1 << 15) - 1,
+ PREC_ALPHA_SHIFT: 24 - 15,
+ PREC_RED_SHIFT: 16 - 15,
+ NORMAL_MODE_AUTO: 0,
+ NORMAL_MODE_SHAPE: 1,
+ NORMAL_MODE_VERTEX: 2,
+ MAX_LIGHTS: 8
+};
+
+},{}],5:[function(require,module,exports){
+// the logger for print() and println()
+module.exports = function PjsConsole(document) {
+ var e = { BufferMax: 200 },
+ style = document.createElement("style"),
+ added = false;
+
+ style.textContent = [
+ ".pjsconsole.hidden {",
+ " display: none!important;",
+ "}"
+ ].join('\n');
+
+ e.wrapper = document.createElement("div");
+ style.textContent += [
+ "",
+ ".pjsconsole {",
+ " opacity: .75;",
+ " display: block;",
+ " position: fixed;",
+ " bottom: 0px;",
+ " left: 0px;",
+ " right: 0px;",
+ " height: 50px;",
+ " background-color: #aaa;",
+ "}"
+ ].join('\n');
+ e.wrapper.classList.add("pjsconsole");
+
+ e.dragger = document.createElement("div");
+ style.textContent += [
+ "",
+ ".pjsconsole .dragger {",
+ " display: block;",
+ " border: 3px black raised;",
+ " cursor: n-resize;",
+ " position: absolute;",
+ " top: 0px;",
+ " left: 0px;",
+ " right: 0px;",
+ " height: 5px;",
+ " background-color: #333;",
+ "}"
+ ].join('\n');
+ e.dragger.classList.add("dragger");
+
+ e.closer = document.createElement("div");
+ style.textContent += [
+ "",
+ ".pjsconsole .closer {",
+ " opacity: .5;",
+ " display: block;",
+ " border: 3px black raised;",
+ " position: absolute;",
+ " top: 10px;",
+ " right: 30px;",
+ " height: 20px;",
+ " width: 20px;",
+ " background-color: #ddd;",
+ " color: #000;",
+ " line-height: 20px;",
+ " text-align: center;",
+ " cursor: pointer",
+ "}"
+ ].join('\n');
+ e.closer.classList.add("closer");
+ e.closer.innerHTML = "&#10006;";
+
+ e.javaconsole = document.createElement("div");
+ style.textContent += [
+ "",
+ ".pjsconsole .console {",
+ " overflow-x: auto;",
+ " display: block;",
+ " position: absolute;",
+ " left: 10px;",
+ " right: 0px;",
+ " bottom: 5px;",
+ " top: 10px;",
+ " overflow-y: scroll;",
+ " height: 40px;",
+ "}"
+ ].join('\n');
+ e.javaconsole.setAttribute("class", "console");
+
+ e.wrapper.appendChild(e.dragger);
+ e.wrapper.appendChild(e.javaconsole);
+ e.wrapper.appendChild(e.closer);
+
+ e.dragger.onmousedown = function (t) {
+ e.divheight = e.wrapper.style.height;
+ if (document.selection) document.selection.empty();
+ else window.getSelection().removeAllRanges();
+ var n = t.screenY;
+ window.onmousemove = function (t) {
+ e.wrapper.style.height = parseFloat(e.divheight) + (n - t.screenY) + "px";
+ e.javaconsole.style.height = parseFloat(e.divheight) + (n - t.screenY) - 10 + "px";
+ };
+ window.onmouseup = function (t) {
+ if (document.selection) document.selection.empty();
+ else window.getSelection().removeAllRanges();
+ e.wrapper.style.height = parseFloat(e.divheight) + (n - t.screenY) + "px";
+ e.javaconsole.style.height = parseFloat(e.divheight) + (n - t.screenY) - 10 + "px";
+ window.onmousemove = null;
+ window.onmouseup = null;
+ };
+ };
+
+ e.BufferArray = [];
+
+ e.print = e.log = function () {
+ if(!added) {
+ document.body.appendChild(style);
+ document.body.appendChild(e.wrapper);
+ added = true;
+ }
+ var args = Array.prototype.slice.call(arguments);
+ t = args.map(function(t, idx) { return t + (idx+1 === args.length ? "" : " "); }).join('');
+ if (e.BufferArray[e.BufferArray.length - 1]) e.BufferArray[e.BufferArray.length - 1] += (t) + "";
+ else e.BufferArray.push(t);
+ e.javaconsole.innerHTML = e.BufferArray.join('');
+ e.showconsole();
+ };
+
+ e.println = function () {
+ var args = Array.prototype.slice.call(arguments);
+ args.push('<br>');
+ e.print.apply(e, args);
+ if (e.BufferArray.length > e.BufferMax) {
+ e.BufferArray.splice(0, 1);
+ } else {
+ e.javaconsole.scrollTop = e.javaconsole.scrollHeight;
+ }
+ };
+
+ e.showconsole = function () { e.wrapper.classList.remove("hidden"); };
+ e.hideconsole = function () { e.wrapper.classList.add("hidden"); };
+
+ e.closer.onclick = function () { e.hideconsole(); };
+
+ e.hideconsole();
+
+ return e;
+};
+
+},{}],6:[function(require,module,exports){
+/**
+ * Processing.js default scope
+ */
+module.exports = function(options) {
+
+ // Building defaultScope. Changing of the prototype protects
+ // internal Processing code from the changes in defaultScope
+ function DefaultScope() {}
+ DefaultScope.prototype = options.PConstants;
+
+ var defaultScope = new DefaultScope();
+
+ // copy over all known Object types and helper objects
+ Object.keys(options).forEach(function(prop) {
+ defaultScope[prop] = options[prop];
+ });
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Class inheritance helper methods
+ ////////////////////////////////////////////////////////////////////////////
+
+ defaultScope.defineProperty = function(obj, name, desc) {
+ if("defineProperty" in Object) {
+ Object.defineProperty(obj, name, desc);
+ } else {
+ if (desc.hasOwnProperty("get")) {
+ obj.__defineGetter__(name, desc.get);
+ }
+ if (desc.hasOwnProperty("set")) {
+ obj.__defineSetter__(name, desc.set);
+ }
+ }
+ };
+
+ /**
+ * class overloading, part 1
+ */
+ function overloadBaseClassFunction(object, name, basefn) {
+ if (!object.hasOwnProperty(name) || typeof object[name] !== 'function') {
+ // object method is not a function or just inherited from Object.prototype
+ object[name] = basefn;
+ return;
+ }
+ var fn = object[name];
+ if ("$overloads" in fn) {
+ // the object method already overloaded (see defaultScope.addMethod)
+ // let's just change a fallback method
+ fn.$defaultOverload = basefn;
+ return;
+ }
+ if (!("$overloads" in basefn) && fn.length === basefn.length) {
+ // special case when we just overriding the method
+ return;
+ }
+ var overloads, defaultOverload;
+ if ("$overloads" in basefn) {
+ // let's inherit base class overloads to speed up things
+ overloads = basefn.$overloads.slice(0);
+ overloads[fn.length] = fn;
+ defaultOverload = basefn.$defaultOverload;
+ } else {
+ overloads = [];
+ overloads[basefn.length] = basefn;
+ overloads[fn.length] = fn;
+ defaultOverload = fn;
+ }
+ var hubfn = function() {
+ var fn = hubfn.$overloads[arguments.length] ||
+ ("$methodArgsIndex" in hubfn && arguments.length > hubfn.$methodArgsIndex ?
+ hubfn.$overloads[hubfn.$methodArgsIndex] : null) ||
+ hubfn.$defaultOverload;
+ return fn.apply(this, arguments);
+ };
+ hubfn.$overloads = overloads;
+ if ("$methodArgsIndex" in basefn) {
+ hubfn.$methodArgsIndex = basefn.$methodArgsIndex;
+ }
+ hubfn.$defaultOverload = defaultOverload;
+ hubfn.name = name;
+ object[name] = hubfn;
+ }
+
+ /**
+ * class overloading, part 2
+ */
+
+ function extendClass(subClass, baseClass) {
+ function extendGetterSetter(propertyName) {
+ defaultScope.defineProperty(subClass, propertyName, {
+ get: function() {
+ return baseClass[propertyName];
+ },
+ set: function(v) {
+ baseClass[propertyName]=v;
+ },
+ enumerable: true
+ });
+ }
+
+ var properties = [];
+ for (var propertyName in baseClass) {
+ if (typeof baseClass[propertyName] === 'function') {
+ overloadBaseClassFunction(subClass, propertyName, baseClass[propertyName]);
+ } else if(propertyName.charAt(0) !== "$" && !(propertyName in subClass)) {
+ // Delaying the properties extension due to the IE9 bug (see #918).
+ properties.push(propertyName);
+ }
+ }
+ while (properties.length > 0) {
+ extendGetterSetter(properties.shift());
+ }
+
+ subClass.$super = baseClass;
+ }
+
+ /**
+ * class overloading, part 3
+ */
+ defaultScope.extendClassChain = function(base) {
+ var path = [base];
+ for (var self = base.$upcast; self; self = self.$upcast) {
+ extendClass(self, base);
+ path.push(self);
+ base = self;
+ }
+ while (path.length > 0) {
+ path.pop().$self=base;
+ }
+ };
+
+ // static
+ defaultScope.extendStaticMembers = function(derived, base) {
+ extendClass(derived, base);
+ };
+
+ // interface
+ defaultScope.extendInterfaceMembers = function(derived, base) {
+ extendClass(derived, base);
+ };
+
+ /**
+ * Java methods and JavaScript functions differ enough that
+ * we need a special function to make sure it all links up
+ * as classical hierarchical class chains.
+ */
+ defaultScope.addMethod = function(object, name, fn, hasMethodArgs) {
+ var existingfn = object[name];
+ if (existingfn || hasMethodArgs) {
+ var args = fn.length;
+ // builds the overload methods table
+ if ("$overloads" in existingfn) {
+ existingfn.$overloads[args] = fn;
+ } else {
+ var hubfn = function() {
+ var fn = hubfn.$overloads[arguments.length] ||
+ ("$methodArgsIndex" in hubfn && arguments.length > hubfn.$methodArgsIndex ?
+ hubfn.$overloads[hubfn.$methodArgsIndex] : null) ||
+ hubfn.$defaultOverload;
+ return fn.apply(this, arguments);
+ };
+ var overloads = [];
+ if (existingfn) {
+ overloads[existingfn.length] = existingfn;
+ }
+ overloads[args] = fn;
+ hubfn.$overloads = overloads;
+ hubfn.$defaultOverload = existingfn || fn;
+ if (hasMethodArgs) {
+ hubfn.$methodArgsIndex = args;
+ }
+ hubfn.name = name;
+ object[name] = hubfn;
+ }
+ } else {
+ object[name] = fn;
+ }
+ };
+
+ // internal helper function
+ function isNumericalJavaType(type) {
+ if (typeof type !== "string") {
+ return false;
+ }
+ return ["byte", "int", "char", "color", "float", "long", "double"].indexOf(type) !== -1;
+ }
+
+ /**
+ * Java's arrays are pre-filled when declared with
+ * an initial size, but no content. JS arrays are not.
+ */
+ defaultScope.createJavaArray = function(type, bounds) {
+ var result = null,
+ defaultValue = null;
+ if (typeof type === "string") {
+ if (type === "boolean") {
+ defaultValue = false;
+ } else if (isNumericalJavaType(type)) {
+ defaultValue = 0;
+ }
+ }
+ if (typeof bounds[0] === 'number') {
+ var itemsCount = 0 | bounds[0];
+ if (bounds.length <= 1) {
+ result = [];
+ result.length = itemsCount;
+ for (var i = 0; i < itemsCount; ++i) {
+ result[i] = defaultValue;
+ }
+ } else {
+ result = [];
+ var newBounds = bounds.slice(1);
+ for (var j = 0; j < itemsCount; ++j) {
+ result.push(defaultScope.createJavaArray(type, newBounds));
+ }
+ }
+ }
+ return result;
+ };
+
+ // screenWidth and screenHeight are shared by all instances.
+ // and return the width/height of the browser's viewport.
+ defaultScope.defineProperty(defaultScope, 'screenWidth',
+ { get: function() { return window.innerWidth; } });
+
+ defaultScope.defineProperty(defaultScope, 'screenHeight',
+ { get: function() { return window.innerHeight; } });
+
+ return defaultScope;
+};
+
+},{}],7:[function(require,module,exports){
+/**
+ * Finalise the Processing.js object.
+ */
+module.exports = function finalizeProcessing(Processing, options) {
+
+ // unpack options
+ var window = options.window,
+ document = options.document,
+ XMLHttpRequest = window.XMLHttpRequest,
+ noop = options.noop,
+ isDOMPresent = options.isDOMPresent,
+ version = options.version,
+ undef;
+
+ // versioning
+ Processing.version = (version ? version : "@DEV-VERSION@");
+
+ // Share lib space
+ Processing.lib = {};
+
+ /**
+ * External libraries can be added to the global Processing
+ * objects with the `registerLibrary` function.
+ */
+ Processing.registerLibrary = function(name, library) {
+ Processing.lib[name] = library;
+ if(library.hasOwnProperty("init")) {
+ library.init(defaultScope);
+ }
+ };
+
+ /**
+ * This is the object that acts as our version of PApplet.
+ * This can be called as Processing.Sketch() or as
+ * Processing.Sketch(function) in which case the function
+ * must be an already-compiled-to-JS sketch function.
+ */
+ Processing.Sketch = function(attachFunction) {
+ this.attachFunction = attachFunction;
+ this.options = {
+ pauseOnBlur: false,
+ globalKeyEvents: false
+ };
+
+ /* Optional Sketch event hooks:
+ * onLoad - parsing/preloading is done, before sketch starts
+ * onSetup - setup() has been called, before first draw()
+ * onPause - noLoop() has been called, pausing draw loop
+ * onLoop - loop() has been called, resuming draw loop
+ * onFrameStart - draw() loop about to begin
+ * onFrameEnd - draw() loop finished
+ * onExit - exit() done being called
+ */
+ this.onLoad = noop;
+ this.onSetup = noop;
+ this.onPause = noop;
+ this.onLoop = noop;
+ this.onFrameStart = noop;
+ this.onFrameEnd = noop;
+ this.onExit = noop;
+
+ this.params = {};
+ this.imageCache = {
+ pending: 0,
+ images: {},
+ // Opera requires special administration for preloading
+ operaCache: {},
+ // Specify an optional img arg if the image is already loaded in the DOM,
+ // otherwise href will get loaded.
+ add: function(href, img) {
+ // Prevent muliple loads for an image, in case it gets
+ // preloaded more than once, or is added via JS and then preloaded.
+ if (this.images[href]) {
+ return;
+ }
+
+ if (!isDOMPresent) {
+ this.images[href] = null;
+ }
+
+ // No image in the DOM, kick-off a background load
+ if (!img) {
+ img = new Image();
+ img.onload = (function(owner) {
+ return function() {
+ owner.pending--;
+ };
+ }(this));
+ this.pending++;
+ img.src = href;
+ }
+
+ this.images[href] = img;
+
+ // Opera will not load images until they are inserted into the DOM.
+ if (window.opera) {
+ var div = document.createElement("div");
+ div.appendChild(img);
+ // we can't use "display: none", since that makes it invisible, and thus not load
+ div.style.position = "absolute";
+ div.style.opacity = 0;
+ div.style.width = "1px";
+ div.style.height= "1px";
+ if (!this.operaCache[href]) {
+ document.body.appendChild(div);
+ this.operaCache[href] = div;
+ }
+ }
+ }
+ };
+
+ this.sourceCode = undefined;
+ this.attach = function(processing) {
+ // either attachFunction or sourceCode must be present on attach
+ if(typeof this.attachFunction === "function") {
+ this.attachFunction(processing);
+ } else if(this.sourceCode) {
+ var func = ((new Function("return (" + this.sourceCode + ");"))());
+ func(processing);
+ this.attachFunction = func;
+ } else {
+ throw "Unable to attach sketch to the processing instance";
+ }
+ };
+
+ this.toString = function() {
+ var i;
+ var code = "((function(Sketch) {\n";
+ code += "var sketch = new Sketch(\n" + this.sourceCode + ");\n";
+ for(i in this.options) {
+ if(this.options.hasOwnProperty(i)) {
+ var value = this.options[i];
+ code += "sketch.options." + i + " = " +
+ (typeof value === 'string' ? '\"' + value + '\"' : "" + value) + ";\n";
+ }
+ }
+ for(i in this.imageCache) {
+ if(this.options.hasOwnProperty(i)) {
+ code += "sketch.imageCache.add(\"" + i + "\");\n";
+ }
+ }
+ // TODO serialize fonts
+ code += "return sketch;\n})(Processing.Sketch))";
+ return code;
+ };
+ };
+
+ /**
+ * aggregate all source code into a single file, then rewrite that
+ * source and bind to canvas via new Processing(canvas, sourcestring).
+ * @param {CANVAS} canvas The html canvas element to bind to
+ * @param {String[]} source The array of files that must be loaded
+ * @param {Function} onComplete A callback, called with the sketch as the argument.
+ */
+ var loadSketchFromSources = Processing.loadSketchFromSources = function(canvas, sources, onComplete) {
+ var code = [], errors = [], sourcesCount = sources.length, loaded = 0;
+
+ function ajaxAsync(url, callback) {
+ var xhr = new XMLHttpRequest();
+ xhr.onreadystatechange = function() {
+ if (xhr.readyState === 4) {
+ var error;
+ if (xhr.status !== 200 && xhr.status !== 0) {
+ error = "Invalid XHR status " + xhr.status;
+ } else if (xhr.responseText === "") {
+ // Give a hint when loading fails due to same-origin issues on file:/// urls
+ if ( ("withCredentials" in new XMLHttpRequest()) &&
+ (new XMLHttpRequest()).withCredentials === false &&
+ window.location.protocol === "file:" ) {
+ error = "XMLHttpRequest failure, possibly due to a same-origin policy violation. You can try loading this page in another browser, or load it from http://localhost using a local webserver. See the Processing.js README for a more detailed explanation of this problem and solutions.";
+ } else {
+ error = "File is empty.";
+ }
+ }
+
+ callback(xhr.responseText, error);
+ }
+ };
+ xhr.open("GET", url, true);
+ if (xhr.overrideMimeType) {
+ xhr.overrideMimeType("application/json");
+ }
+ xhr.setRequestHeader("If-Modified-Since", "Fri, 01 Jan 1960 00:00:00 GMT"); // no cache
+ xhr.send(null);
+ }
+
+ function loadBlock(index, filename) {
+ function callback(block, error) {
+ code[index] = block;
+ ++loaded;
+ if (error) {
+ errors.push(filename + " ==> " + error);
+ }
+ if (loaded === sourcesCount) {
+ if (errors.length === 0) {
+ // This used to throw, but it was constantly getting in the way of debugging where things go wrong!
+ var sketch = new Processing(canvas, code.join("\n"));
+ if (onComplete) {
+ onComplete(sketch);
+ }
+ } else {
+ throw "Processing.js: Unable to load pjs sketch files: " + errors.join("\n");
+ }
+ }
+ }
+ if (filename.charAt(0) === '#') {
+ // trying to get script from the element
+ var scriptElement = document.getElementById(filename.substring(1));
+ if (scriptElement) {
+ callback(scriptElement.text || scriptElement.textContent);
+ } else {
+ callback("", "Unable to load pjs sketch: element with id \'" + filename.substring(1) + "\' was not found");
+ }
+ return;
+ }
+
+ ajaxAsync(filename, callback);
+ }
+
+ for (var i = 0; i < sourcesCount; ++i) {
+ loadBlock(i, sources[i]);
+ }
+ };
+
+ /**
+ * Automatic initialization function.
+ */
+ var init = function() {
+ document.removeEventListener('DOMContentLoaded', init, false);
+ var i;
+
+ // before running through init, clear the instances list, to prevent
+ // sketch duplication when page content is dynamically swapped without
+ // swapping out processing.js
+ while (Processing.instances.length > 0) {
+ for (i = Processing.instances.length - 1; i >= 0; i--) {
+ if (Processing.instances[i]) {
+ Processing.instances[i].exit();
+ }
+ }
+ }
+
+ var canvas = document.getElementsByTagName('canvas'),
+ filenames;
+
+ for (i = 0, l = canvas.length; i < l; i++) {
+ // datasrc and data-src are deprecated.
+ var processingSources = canvas[i].getAttribute('data-processing-sources');
+ if (processingSources === null) {
+ // Temporary fallback for datasrc and data-src
+ processingSources = canvas[i].getAttribute('data-src');
+ if (processingSources === null) {
+ processingSources = canvas[i].getAttribute('datasrc');
+ }
+ }
+ if (processingSources) {
+ filenames = processingSources.split(/\s+/g);
+ for (var j = 0; j < filenames.length;) {
+ if (filenames[j]) {
+ j++;
+ } else {
+ filenames.splice(j, 1);
+ }
+ }
+ loadSketchFromSources(canvas[i], filenames);
+ }
+ }
+
+ // also process all <script>-indicated sketches, if there are any
+ var s, last, source, instance,
+ nodelist = document.getElementsByTagName('script'),
+ scripts=[];
+
+ // snapshot the DOM, as the nodelist is only a DOM view, and is
+ // updated instantly when a script element is added or removed.
+ for (s = nodelist.length - 1; s >= 0; s--) {
+ scripts.push(nodelist[s]);
+ }
+
+ // iterate over all script elements to see if they contain Processing code
+ for (s = 0, last = scripts.length; s < last; s++) {
+ var script = scripts[s];
+ if (!script.getAttribute) {
+ continue;
+ }
+
+ var type = script.getAttribute("type");
+ if (type && (type.toLowerCase() === "text/processing" || type.toLowerCase() === "application/processing")) {
+ var target = script.getAttribute("data-processing-target");
+ canvas = undef;
+ if (target) {
+ canvas = document.getElementById(target);
+ } else {
+ var nextSibling = script.nextSibling;
+ while (nextSibling && nextSibling.nodeType !== 1) {
+ nextSibling = nextSibling.nextSibling;
+ }
+ if (nextSibling && nextSibling.nodeName.toLowerCase() === "canvas") {
+ canvas = nextSibling;
+ }
+ }
+
+ if (canvas) {
+ if (script.getAttribute("src")) {
+ filenames = script.getAttribute("src").split(/\s+/);
+ loadSketchFromSources(canvas, filenames);
+ continue;
+ }
+ source = script.textContent || script.text;
+ instance = new Processing(canvas, source);
+ }
+ }
+ }
+ };
+
+ /**
+ * automatic loading of all sketches on the page
+ */
+ document.addEventListener('DOMContentLoaded', init, false);
+
+ /**
+ * Make Processing run through init after already having
+ * been set up for a page. This function exists mostly for pages
+ * that swap content in/out without reloading a page.
+ */
+ Processing.reload = init;
+
+ /**
+ * Disable the automatic loading of all sketches on the page.
+ * This will work as long as it's issued before DOMContentLoaded.
+ */
+ Processing.disableInit = function() {
+ document.removeEventListener('DOMContentLoaded', init, false);
+ };
+
+ // done.
+ return Processing;
+};
+
+},{}],8:[function(require,module,exports){
+/**
+ * Returns Java equals() result for two objects. If the first object
+ * has the "equals" function, it preforms the call of this function.
+ * Otherwise the method uses the JavaScript === operator.
+ *
+ * @param {Object} obj The first object.
+ * @param {Object} other The second object.
+ *
+ * @returns {boolean} true if the objects are equal.
+ */
+module.exports = function virtEquals(obj, other) {
+ if (obj === null || other === null) {
+ return (obj === null) && (other === null);
+ }
+ if (typeof (obj) === "string") {
+ return obj === other;
+ }
+ if (typeof(obj) !== "object") {
+ return obj === other;
+ }
+ if (obj.equals instanceof Function) {
+ return obj.equals(other);
+ }
+ return obj === other;
+};
+
+},{}],9:[function(require,module,exports){
+/**
+ * Returns Java hashCode() result for the object. If the object has the "hashCode" function,
+ * it preforms the call of this function. Otherwise it uses/creates the "$id" property,
+ * which is used as the hashCode.
+ *
+ * @param {Object} obj The object.
+ * @returns {int} The object's hash code.
+ */
+module.exports = function virtHashCode(obj, undef) {
+ if (typeof(obj) === "string") {
+ var hash = 0;
+ for (var i = 0; i < obj.length; ++i) {
+ hash = (hash * 31 + obj.charCodeAt(i)) & 0xFFFFFFFF;
+ }
+ return hash;
+ }
+ if (typeof(obj) !== "object") {
+ return obj & 0xFFFFFFFF;
+ }
+ if (obj.hashCode instanceof Function) {
+ return obj.hashCode();
+ }
+ if (obj.$id === undef) {
+ obj.$id = ((Math.floor(Math.random() * 0x10000) - 0x8000) << 16) | Math.floor(Math.random() * 0x10000);
+ }
+ return obj.$id;
+};
+
+},{}],10:[function(require,module,exports){
+/**
+ * An ArrayList stores a variable number of objects.
+ *
+ * @param {int} initialCapacity optional defines the initial capacity of the list, it's empty by default
+ *
+ * @returns {ArrayList} new ArrayList object
+ */
+module.exports = function(options) {
+ var virtHashCode = options.virtHashCode,
+ virtEquals = options.virtEquals;
+
+ function Iterator(array) {
+ var index = -1;
+ this.hasNext = function() {
+ return (index + 1) < array.length;
+ };
+
+ this.next = function() {
+ return array[++index];
+ };
+
+ this.remove = function() {
+ array.splice(index--, 1);
+ };
+ }
+
+ function ArrayList(a) {
+ var array = [];
+
+ if (a && a.toArray) {
+ array = a.toArray();
+ }
+
+ /**
+ * @member ArrayList
+ * ArrayList.get() Returns the element at the specified position in this list.
+ *
+ * @param {int} i index of element to return
+ *
+ * @returns {Object} the element at the specified position in this list.
+ */
+ this.get = function(i) {
+ return array[i];
+ };
+ /**
+ * @member ArrayList
+ * ArrayList.contains() Returns true if this list contains the specified element.
+ *
+ * @param {Object} item element whose presence in this List is to be tested.
+ *
+ * @returns {boolean} true if the specified element is present; false otherwise.
+ */
+ this.contains = function(item) {
+ return this.indexOf(item)>-1;
+ };
+ /**
+ * @member ArrayList
+ * ArrayList.indexOf() Returns the position this element takes in the list, or -1 if the element is not found.
+ *
+ * @param {Object} item element whose position in this List is to be tested.
+ *
+ * @returns {int} the list position that the first match for this element holds in the list, or -1 if it is not in the list.
+ */
+ this.indexOf = function(item) {
+ for (var i = 0, len = array.length; i < len; ++i) {
+ if (virtEquals(item, array[i])) {
+ return i;
+ }
+ }
+ return -1;
+ };
+ /**
+ * @member ArrayList
+ * ArrayList.lastIndexOf() Returns the index of the last occurrence of the specified element in this list,
+ * or -1 if this list does not contain the element. More formally, returns the highest index i such that
+ * (o==null ? get(i)==null : o.equals(get(i))), or -1 if there is no such index.
+ *
+ * @param {Object} item element to search for.
+ *
+ * @returns {int} the index of the last occurrence of the specified element in this list, or -1 if this list does not contain the element.
+ */
+ this.lastIndexOf = function(item) {
+ for (var i = array.length-1; i >= 0; --i) {
+ if (virtEquals(item, array[i])) {
+ return i;
+ }
+ }
+ return -1;
+ };
+ /**
+ * @member ArrayList
+ * ArrayList.add() Adds the specified element to this list.
+ *
+ * @param {int} index optional index at which the specified element is to be inserted
+ * @param {Object} object element to be added to the list
+ */
+ this.add = function() {
+ if (arguments.length === 1) {
+ array.push(arguments[0]); // for add(Object)
+ } else if (arguments.length === 2) {
+ var arg0 = arguments[0];
+ if (typeof arg0 === 'number') {
+ if (arg0 >= 0 && arg0 <= array.length) {
+ array.splice(arg0, 0, arguments[1]); // for add(i, Object)
+ } else {
+ throw(arg0 + " is not a valid index");
+ }
+ } else {
+ throw(typeof arg0 + " is not a number");
+ }
+ } else {
+ throw("Please use the proper number of parameters.");
+ }
+ };
+ /**
+ * @member ArrayList
+ * ArrayList.addAll(collection) appends all of the elements in the specified
+ * Collection to the end of this list, in the order that they are returned by
+ * the specified Collection's Iterator.
+ *
+ * When called as addAll(index, collection) the elements are inserted into
+ * this list at the position indicated by index.
+ *
+ * @param {index} Optional; specifies the position the colletion should be inserted at
+ * @param {collection} Any iterable object (ArrayList, HashMap.keySet(), etc.)
+ * @throws out of bounds error for negative index, or index greater than list size.
+ */
+ this.addAll = function(arg1, arg2) {
+ // addAll(int, Collection)
+ var it;
+ if (typeof arg1 === "number") {
+ if (arg1 < 0 || arg1 > array.length) {
+ throw("Index out of bounds for addAll: " + arg1 + " greater or equal than " + array.length);
+ }
+ it = new ObjectIterator(arg2);
+ while (it.hasNext()) {
+ array.splice(arg1++, 0, it.next());
+ }
+ }
+ // addAll(Collection)
+ else {
+ it = new ObjectIterator(arg1);
+ while (it.hasNext()) {
+ array.push(it.next());
+ }
+ }
+ };
+ /**
+ * @member ArrayList
+ * ArrayList.set() Replaces the element at the specified position in this list with the specified element.
+ *
+ * @param {int} index index of element to replace
+ * @param {Object} object element to be stored at the specified position
+ */
+ this.set = function() {
+ if (arguments.length === 2) {
+ var arg0 = arguments[0];
+ if (typeof arg0 === 'number') {
+ if (arg0 >= 0 && arg0 < array.length) {
+ array.splice(arg0, 1, arguments[1]);
+ } else {
+ throw(arg0 + " is not a valid index.");
+ }
+ } else {
+ throw(typeof arg0 + " is not a number");
+ }
+ } else {
+ throw("Please use the proper number of parameters.");
+ }
+ };
+
+ /**
+ * @member ArrayList
+ * ArrayList.size() Returns the number of elements in this list.
+ *
+ * @returns {int} the number of elements in this list
+ */
+ this.size = function() {
+ return array.length;
+ };
+
+ /**
+ * @member ArrayList
+ * ArrayList.clear() Removes all of the elements from this list. The list will be empty after this call returns.
+ */
+ this.clear = function() {
+ array.length = 0;
+ };
+
+ /**
+ * @member ArrayList
+ * ArrayList.remove() Removes an element either based on index, if the argument is a number, or
+ * by equality check, if the argument is an object.
+ *
+ * @param {int|Object} item either the index of the element to be removed, or the element itself.
+ *
+ * @returns {Object|boolean} If removal is by index, the element that was removed, or null if nothing was removed. If removal is by object, true if removal occurred, otherwise false.
+ */
+ this.remove = function(item) {
+ if (typeof item === 'number') {
+ return array.splice(item, 1)[0];
+ }
+ item = this.indexOf(item);
+ if (item > -1) {
+ array.splice(item, 1);
+ return true;
+ }
+ return false;
+ };
+
+ /**
+ * @member ArrayList
+ * ArrayList.removeAll Removes from this List all of the elements from
+ * the current ArrayList which are present in the passed in paramater ArrayList 'c'.
+ * Shifts any succeeding elements to the left (reduces their index).
+ *
+ * @param {ArrayList} the ArrayList to compare to the current ArrayList
+ *
+ * @returns {boolean} true if the ArrayList had an element removed; false otherwise
+ */
+ this.removeAll = function(c) {
+ var i, x, item,
+ newList = new ArrayList();
+ newList.addAll(this);
+ this.clear();
+ // For every item that exists in the original ArrayList and not in the c ArrayList
+ // copy it into the empty 'this' ArrayList to create the new 'this' Array.
+ for (i = 0, x = 0; i < newList.size(); i++) {
+ item = newList.get(i);
+ if (!c.contains(item)) {
+ this.add(x++, item);
+ }
+ }
+ if (this.size() < newList.size()) {
+ return true;
+ }
+ return false;
+ };
+
+ /**
+ * @member ArrayList
+ * ArrayList.isEmpty() Tests if this list has no elements.
+ *
+ * @returns {boolean} true if this list has no elements; false otherwise
+ */
+ this.isEmpty = function() {
+ return !array.length;
+ };
+
+ /**
+ * @member ArrayList
+ * ArrayList.clone() Returns a shallow copy of this ArrayList instance. (The elements themselves are not copied.)
+ *
+ * @returns {ArrayList} a clone of this ArrayList instance
+ */
+ this.clone = function() {
+ return new ArrayList(this);
+ };
+
+ /**
+ * @member ArrayList
+ * ArrayList.toArray() Returns an array containing all of the elements in this list in the correct order.
+ *
+ * @returns {Object[]} Returns an array containing all of the elements in this list in the correct order
+ */
+ this.toArray = function() {
+ return array.slice(0);
+ };
+
+ this.iterator = function() {
+ return new Iterator(array);
+ };
+ }
+
+ return ArrayList;
+};
+
+},{}],11:[function(require,module,exports){
+module.exports = (function(charMap, undef) {
+
+ var Char = function(chr) {
+ if (typeof chr === 'string' && chr.length === 1) {
+ this.code = chr.charCodeAt(0);
+ } else if (typeof chr === 'number') {
+ this.code = chr;
+ } else if (chr instanceof Char) {
+ this.code = chr;
+ } else {
+ this.code = NaN;
+ }
+ return (charMap[this.code] === undef) ? charMap[this.code] = this : charMap[this.code];
+ };
+
+ Char.prototype.toString = function() {
+ return String.fromCharCode(this.code);
+ };
+
+ Char.prototype.valueOf = function() {
+ return this.code;
+ };
+
+ return Char;
+}({}));
+
+},{}],12:[function(require,module,exports){
+/**
+* A HashMap stores a collection of objects, each referenced by a key. This is similar to an Array, only
+* instead of accessing elements with a numeric index, a String is used. (If you are familiar with
+* associative arrays from other languages, this is the same idea.)
+*
+* @param {int} initialCapacity defines the initial capacity of the map, it's 16 by default
+* @param {float} loadFactor the load factor for the map, the default is 0.75
+* @param {Map} m gives the new HashMap the same mappings as this Map
+*/
+module.exports = function(options) {
+ var virtHashCode = options.virtHashCode,
+ virtEquals = options.virtEquals;
+
+ /**
+ * @member HashMap
+ * A HashMap stores a collection of objects, each referenced by a key. This is similar to an Array, only
+ * instead of accessing elements with a numeric index, a String is used. (If you are familiar with
+ * associative arrays from other languages, this is the same idea.)
+ *
+ * @param {int} initialCapacity defines the initial capacity of the map, it's 16 by default
+ * @param {float} loadFactor the load factor for the map, the default is 0.75
+ * @param {Map} m gives the new HashMap the same mappings as this Map
+ */
+ function HashMap() {
+ if (arguments.length === 1 && arguments[0] instanceof HashMap) {
+ return arguments[0].clone();
+ }
+
+ var initialCapacity = arguments.length > 0 ? arguments[0] : 16;
+ var loadFactor = arguments.length > 1 ? arguments[1] : 0.75;
+ var buckets = [];
+ buckets.length = initialCapacity;
+ var count = 0;
+ var hashMap = this;
+
+ function getBucketIndex(key) {
+ var index = virtHashCode(key) % buckets.length;
+ return index < 0 ? buckets.length + index : index;
+ }
+ function ensureLoad() {
+ if (count <= loadFactor * buckets.length) {
+ return;
+ }
+ var allEntries = [];
+ for (var i = 0; i < buckets.length; ++i) {
+ if (buckets[i] !== undefined) {
+ allEntries = allEntries.concat(buckets[i]);
+ }
+ }
+ var newBucketsLength = buckets.length * 2;
+ buckets = [];
+ buckets.length = newBucketsLength;
+ for (var j = 0; j < allEntries.length; ++j) {
+ var index = getBucketIndex(allEntries[j].key);
+ var bucket = buckets[index];
+ if (bucket === undefined) {
+ buckets[index] = bucket = [];
+ }
+ bucket.push(allEntries[j]);
+ }
+ }
+
+ function Iterator(conversion, removeItem) {
+ var bucketIndex = 0;
+ var itemIndex = -1;
+ var endOfBuckets = false;
+ var currentItem;
+
+ function findNext() {
+ while (!endOfBuckets) {
+ ++itemIndex;
+ if (bucketIndex >= buckets.length) {
+ endOfBuckets = true;
+ } else if (buckets[bucketIndex] === undefined || itemIndex >= buckets[bucketIndex].length) {
+ itemIndex = -1;
+ ++bucketIndex;
+ } else {
+ return;
+ }
+ }
+ }
+
+ /*
+ * @member Iterator
+ * Checks if the Iterator has more items
+ */
+ this.hasNext = function() {
+ return !endOfBuckets;
+ };
+
+ /*
+ * @member Iterator
+ * Return the next Item
+ */
+ this.next = function() {
+ currentItem = conversion(buckets[bucketIndex][itemIndex]);
+ findNext();
+ return currentItem;
+ };
+
+ /*
+ * @member Iterator
+ * Remove the current item
+ */
+ this.remove = function() {
+ if (currentItem !== undefined) {
+ removeItem(currentItem);
+ --itemIndex;
+ findNext();
+ }
+ };
+
+ findNext();
+ }
+
+ function Set(conversion, isIn, removeItem) {
+ this.clear = function() {
+ hashMap.clear();
+ };
+
+ this.contains = function(o) {
+ return isIn(o);
+ };
+
+ this.containsAll = function(o) {
+ var it = o.iterator();
+ while (it.hasNext()) {
+ if (!this.contains(it.next())) {
+ return false;
+ }
+ }
+ return true;
+ };
+
+ this.isEmpty = function() {
+ return hashMap.isEmpty();
+ };
+
+ this.iterator = function() {
+ return new Iterator(conversion, removeItem);
+ };
+
+ this.remove = function(o) {
+ if (this.contains(o)) {
+ removeItem(o);
+ return true;
+ }
+ return false;
+ };
+
+ this.removeAll = function(c) {
+ var it = c.iterator();
+ var changed = false;
+ while (it.hasNext()) {
+ var item = it.next();
+ if (this.contains(item)) {
+ removeItem(item);
+ changed = true;
+ }
+ }
+ return true;
+ };
+
+ this.retainAll = function(c) {
+ var it = this.iterator();
+ var toRemove = [];
+ while (it.hasNext()) {
+ var entry = it.next();
+ if (!c.contains(entry)) {
+ toRemove.push(entry);
+ }
+ }
+ for (var i = 0; i < toRemove.length; ++i) {
+ removeItem(toRemove[i]);
+ }
+ return toRemove.length > 0;
+ };
+
+ this.size = function() {
+ return hashMap.size();
+ };
+
+ this.toArray = function() {
+ var result = [];
+ var it = this.iterator();
+ while (it.hasNext()) {
+ result.push(it.next());
+ }
+ return result;
+ };
+ }
+
+ function Entry(pair) {
+ this._isIn = function(map) {
+ return map === hashMap && (pair.removed === undefined);
+ };
+
+ this.equals = function(o) {
+ return virtEquals(pair.key, o.getKey());
+ };
+
+ this.getKey = function() {
+ return pair.key;
+ };
+
+ this.getValue = function() {
+ return pair.value;
+ };
+
+ this.hashCode = function(o) {
+ return virtHashCode(pair.key);
+ };
+
+ this.setValue = function(value) {
+ var old = pair.value;
+ pair.value = value;
+ return old;
+ };
+ }
+
+ this.clear = function() {
+ count = 0;
+ buckets = [];
+ buckets.length = initialCapacity;
+ };
+
+ this.clone = function() {
+ var map = new HashMap();
+ map.putAll(this);
+ return map;
+ };
+
+ this.containsKey = function(key) {
+ var index = getBucketIndex(key);
+ var bucket = buckets[index];
+ if (bucket === undefined) {
+ return false;
+ }
+ for (var i = 0; i < bucket.length; ++i) {
+ if (virtEquals(bucket[i].key, key)) {
+ return true;
+ }
+ }
+ return false;
+ };
+
+ this.containsValue = function(value) {
+ for (var i = 0; i < buckets.length; ++i) {
+ var bucket = buckets[i];
+ if (bucket === undefined) {
+ continue;
+ }
+ for (var j = 0; j < bucket.length; ++j) {
+ if (virtEquals(bucket[j].value, value)) {
+ return true;
+ }
+ }
+ }
+ return false;
+ };
+
+ this.entrySet = function() {
+ return new Set(
+
+ function(pair) {
+ return new Entry(pair);
+ },
+
+ function(pair) {
+ return (pair instanceof Entry) && pair._isIn(hashMap);
+ },
+
+ function(pair) {
+ return hashMap.remove(pair.getKey());
+ });
+ };
+
+ this.get = function(key) {
+ var index = getBucketIndex(key);
+ var bucket = buckets[index];
+ if (bucket === undefined) {
+ return null;
+ }
+ for (var i = 0; i < bucket.length; ++i) {
+ if (virtEquals(bucket[i].key, key)) {
+ return bucket[i].value;
+ }
+ }
+ return null;
+ };
+
+ this.isEmpty = function() {
+ return count === 0;
+ };
+
+ this.keySet = function() {
+ return new Set(
+ // get key from pair
+ function(pair) {
+ return pair.key;
+ },
+ // is-in test
+ function(key) {
+ return hashMap.containsKey(key);
+ },
+ // remove from hashmap by key
+ function(key) {
+ return hashMap.remove(key);
+ }
+ );
+ };
+
+ this.values = function() {
+ return new Set(
+ // get value from pair
+ function(pair) {
+ return pair.value;
+ },
+ // is-in test
+ function(value) {
+ return hashMap.containsValue(value);
+ },
+ // remove from hashmap by value
+ function(value) {
+ return hashMap.removeByValue(value);
+ }
+ );
+ };
+
+ this.put = function(key, value) {
+ var index = getBucketIndex(key);
+ var bucket = buckets[index];
+ if (bucket === undefined) {
+ ++count;
+ buckets[index] = [{
+ key: key,
+ value: value
+ }];
+ ensureLoad();
+ return null;
+ }
+ for (var i = 0; i < bucket.length; ++i) {
+ if (virtEquals(bucket[i].key, key)) {
+ var previous = bucket[i].value;
+ bucket[i].value = value;
+ return previous;
+ }
+ }
+ ++count;
+ bucket.push({
+ key: key,
+ value: value
+ });
+ ensureLoad();
+ return null;
+ };
+
+ this.putAll = function(m) {
+ var it = m.entrySet().iterator();
+ while (it.hasNext()) {
+ var entry = it.next();
+ this.put(entry.getKey(), entry.getValue());
+ }
+ };
+
+ this.remove = function(key) {
+ var index = getBucketIndex(key);
+ var bucket = buckets[index];
+ if (bucket === undefined) {
+ return null;
+ }
+ for (var i = 0; i < bucket.length; ++i) {
+ if (virtEquals(bucket[i].key, key)) {
+ --count;
+ var previous = bucket[i].value;
+ bucket[i].removed = true;
+ if (bucket.length > 1) {
+ bucket.splice(i, 1);
+ } else {
+ buckets[index] = undefined;
+ }
+ return previous;
+ }
+ }
+ return null;
+ };
+
+ this.removeByValue = function(value) {
+ var bucket, i, ilen, pair;
+ for (bucket in buckets) {
+ if (buckets.hasOwnProperty(bucket)) {
+ for (i = 0, ilen = buckets[bucket].length; i < ilen; i++) {
+ pair = buckets[bucket][i];
+ // removal on values is based on identity, not equality
+ if (pair.value === value) {
+ buckets[bucket].splice(i, 1);
+ return true;
+ }
+ }
+ }
+ }
+ return false;
+ };
+
+ this.size = function() {
+ return count;
+ };
+ }
+
+ return HashMap;
+};
+
+},{}],13:[function(require,module,exports){
+// module export
+module.exports = function(options,undef) {
+ var window = options.Browser.window,
+ document = options.Browser.document,
+ noop = options.noop;
+
+ /**
+ * [internal function] computeFontMetrics() calculates various metrics for text
+ * placement. Currently this function computes the ascent, descent and leading
+ * (from "lead", used for vertical space) values for the currently active font.
+ */
+ function computeFontMetrics(pfont) {
+ var emQuad = 250,
+ correctionFactor = pfont.size / emQuad,
+ canvas = document.createElement("canvas");
+ canvas.width = 2*emQuad;
+ canvas.height = 2*emQuad;
+ canvas.style.opacity = 0;
+ var cfmFont = pfont.getCSSDefinition(emQuad+"px", "normal"),
+ ctx = canvas.getContext("2d");
+ ctx.font = cfmFont;
+
+ // Size the canvas using a string with common max-ascent and max-descent letters.
+ // Changing the canvas dimensions resets the context, so we must reset the font.
+ var protrusions = "dbflkhyjqpg";
+ canvas.width = ctx.measureText(protrusions).width;
+ ctx.font = cfmFont;
+
+ // for text lead values, we meaure a multiline text container.
+ var leadDiv = document.createElement("div");
+ leadDiv.style.position = "absolute";
+ leadDiv.style.opacity = 0;
+ leadDiv.style.fontFamily = '"' + pfont.name + '"';
+ leadDiv.style.fontSize = emQuad + "px";
+ leadDiv.innerHTML = protrusions + "<br/>" + protrusions;
+ document.body.appendChild(leadDiv);
+
+ var w = canvas.width,
+ h = canvas.height,
+ baseline = h/2;
+
+ // Set all canvas pixeldata values to 255, with all the content
+ // data being 0. This lets us scan for data[i] != 255.
+ ctx.fillStyle = "white";
+ ctx.fillRect(0, 0, w, h);
+ ctx.fillStyle = "black";
+ ctx.fillText(protrusions, 0, baseline);
+ var pixelData = ctx.getImageData(0, 0, w, h).data;
+
+ // canvas pixel data is w*4 by h*4, because R, G, B and A are separate,
+ // consecutive values in the array, rather than stored as 32 bit ints.
+ var i = 0,
+ w4 = w * 4,
+ len = pixelData.length;
+
+ // Finding the ascent uses a normal, forward scanline
+ while (++i < len && pixelData[i] === 255) {
+ noop();
+ }
+ var ascent = Math.round(i / w4);
+
+ // Finding the descent uses a reverse scanline
+ i = len - 1;
+ while (--i > 0 && pixelData[i] === 255) {
+ noop();
+ }
+ var descent = Math.round(i / w4);
+
+ // set font metrics
+ pfont.ascent = correctionFactor * (baseline - ascent);
+ pfont.descent = correctionFactor * (descent - baseline);
+
+ // Then we try to get the real value from the browser
+ if (document.defaultView.getComputedStyle) {
+ var leadDivHeight = document.defaultView.getComputedStyle(leadDiv,null).getPropertyValue("height");
+ leadDivHeight = correctionFactor * leadDivHeight.replace("px","");
+ if (leadDivHeight >= pfont.size * 2) {
+ pfont.leading = Math.round(leadDivHeight/2);
+ }
+ }
+ document.body.removeChild(leadDiv);
+
+ // if we're caching, cache the context used for this pfont
+ if (pfont.caching) {
+ return ctx;
+ }
+ }
+
+ /**
+ * Constructor for a system or from-file (non-SVG) font.
+ */
+ function PFont(name, size) {
+ // according to the P5 API, new PFont() is legal (albeit completely useless)
+ if (name === undef) {
+ name = "";
+ }
+ this.name = name;
+ if (size === undef) {
+ size = 0;
+ }
+ this.size = size;
+ this.glyph = false;
+ this.ascent = 0;
+ this.descent = 0;
+ // For leading, the "safe" value uses the standard TEX ratio
+ this.leading = 1.2 * size;
+
+ // Note that an italic, bold font must used "... Bold Italic"
+ // in P5. "... Italic Bold" is treated as normal/normal.
+ var illegalIndicator = name.indexOf(" Italic Bold");
+ if (illegalIndicator !== -1) {
+ name = name.substring(0, illegalIndicator);
+ }
+
+ // determine font style
+ this.style = "normal";
+ var italicsIndicator = name.indexOf(" Italic");
+ if (italicsIndicator !== -1) {
+ name = name.substring(0, italicsIndicator);
+ this.style = "italic";
+ }
+
+ // determine font weight
+ this.weight = "normal";
+ var boldIndicator = name.indexOf(" Bold");
+ if (boldIndicator !== -1) {
+ name = name.substring(0, boldIndicator);
+ this.weight = "bold";
+ }
+
+ // determine font-family name
+ this.family = "sans-serif";
+ if (name !== undef) {
+ switch(name) {
+ case "sans-serif":
+ case "serif":
+ case "monospace":
+ case "fantasy":
+ case "cursive":
+ this.family = name;
+ break;
+ default:
+ this.family = '"' + name + '", sans-serif';
+ break;
+ }
+ }
+ // Calculate the ascent/descent/leading value based on
+ // how the browser renders this font.
+ this.context2d = computeFontMetrics(this);
+ this.css = this.getCSSDefinition();
+ if (this.context2d) {
+ this.context2d.font = this.css;
+ }
+ }
+
+ /**
+ * regulates whether or not we're caching the canvas
+ * 2d context for quick text width computation.
+ */
+ PFont.prototype.caching = true;
+
+ /**
+ * This function generates the CSS "font" string for this PFont
+ */
+ PFont.prototype.getCSSDefinition = function(fontSize, lineHeight) {
+ if(fontSize===undef) {
+ fontSize = this.size + "px";
+ }
+ if(lineHeight===undef) {
+ lineHeight = this.leading + "px";
+ }
+ // CSS "font" definition: font-style font-variant font-weight font-size/line-height font-family
+ var components = [this.style, "normal", this.weight, fontSize + "/" + lineHeight, this.family];
+ return components.join(" ");
+ };
+
+ /**
+ * Rely on the cached context2d measureText function.
+ */
+ PFont.prototype.measureTextWidth = function(string) {
+ return this.context2d.measureText(string).width;
+ };
+
+ /**
+ * FALLBACK FUNCTION -- replaces Pfont.prototype.measureTextWidth
+ * when the font cache becomes too large. This contructs a new
+ * canvas 2d context object for calling measureText on.
+ */
+ PFont.prototype.measureTextWidthFallback = function(string) {
+ var canvas = document.createElement("canvas"),
+ ctx = canvas.getContext("2d");
+ ctx.font = this.css;
+ return ctx.measureText(string).width;
+ };
+
+ /**
+ * Global "loaded fonts" list, internal to PFont
+ */
+ PFont.PFontCache = { length: 0 };
+
+ /**
+ * This function acts as single access point for getting and caching
+ * fonts across all sketches handled by an instance of Processing.js
+ */
+ PFont.get = function(fontName, fontSize) {
+ // round fontSize to one decimal point
+ fontSize = ((fontSize*10)+0.5|0)/10;
+ var cache = PFont.PFontCache,
+ idx = fontName+"/"+fontSize;
+ if (!cache[idx]) {
+ cache[idx] = new PFont(fontName, fontSize);
+ cache.length++;
+
+ // FALLBACK FUNCTIONALITY 1:
+ // If the cache has become large, switch over from full caching
+ // to caching only the static metrics for each new font request.
+ if (cache.length === 50) {
+ PFont.prototype.measureTextWidth = PFont.prototype.measureTextWidthFallback;
+ PFont.prototype.caching = false;
+ // clear contexts stored for each cached font
+ var entry;
+ for (entry in cache) {
+ if (entry !== "length") {
+ cache[entry].context2d = null;
+ }
+ }
+ return new PFont(fontName, fontSize);
+ }
+
+ // FALLBACK FUNCTIONALITY 2:
+ // If the cache has become too large, switch off font caching entirely.
+ if (cache.length === 400) {
+ PFont.PFontCache = {};
+ PFont.get = PFont.getFallback;
+ return new PFont(fontName, fontSize);
+ }
+ }
+ return cache[idx];
+ };
+
+ /**
+ * FALLBACK FUNCTION -- replaces PFont.get when the font cache
+ * becomes too large. This function bypasses font caching entirely.
+ */
+ PFont.getFallback = function(fontName, fontSize) {
+ return new PFont(fontName, fontSize);
+ };
+
+ /**
+ * Lists all standard fonts. Due to browser limitations, this list is
+ * not the system font list, like in P5, but the CSS "genre" list.
+ */
+ PFont.list = function() {
+ return ["sans-serif", "serif", "monospace", "fantasy", "cursive"];
+ };
+
+ /**
+ * Loading external fonts through @font-face rules is handled by PFont,
+ * to ensure fonts loaded in this way are globally available.
+ */
+ PFont.preloading = {
+ // template element used to compare font sizes
+ template: {},
+ // indicates whether or not the reference tiny font has been loaded
+ initialized: false,
+ // load the reference tiny font via a css @font-face rule
+ initialize: function() {
+ var generateTinyFont = function() {
+ var encoded = "#E3KAI2wAgT1MvMg7Eo3VmNtYX7ABi3CxnbHlm" +
+ "7Abw3kaGVhZ7ACs3OGhoZWE7A53CRobXR47AY3" +
+ "AGbG9jYQ7G03Bm1heH7ABC3CBuYW1l7Ae3AgcG" +
+ "9zd7AI3AE#B3AQ2kgTY18PPPUACwAg3ALSRoo3" +
+ "#yld0xg32QAB77#E777773B#E3C#I#Q77773E#" +
+ "Q7777777772CMAIw7AB77732B#M#Q3wAB#g3B#" +
+ "E#E2BB//82BB////w#B7#gAEg3E77x2B32B#E#" +
+ "Q#MTcBAQ32gAe#M#QQJ#E32M#QQJ#I#g32Q77#";
+ var expand = function(input) {
+ return "AAAAAAAA".substr(~~input ? 7-input : 6);
+ };
+ return encoded.replace(/[#237]/g, expand);
+ };
+ var fontface = document.createElement("style");
+ fontface.setAttribute("type","text/css");
+ fontface.innerHTML = "@font-face {\n" +
+ ' font-family: "PjsEmptyFont";' + "\n" +
+ " src: url('data:application/x-font-ttf;base64,"+generateTinyFont()+"')\n" +
+ " format('truetype');\n" +
+ "}";
+ document.head.appendChild(fontface);
+
+ // set up the template element
+ var element = document.createElement("span");
+ element.style.cssText = 'position: absolute; top: -1000; left: 0; opacity: 0; font-family: "PjsEmptyFont", fantasy;';
+ element.innerHTML = "AAAAAAAA";
+ document.body.appendChild(element);
+ this.template = element;
+
+ this.initialized = true;
+ },
+ // Shorthand function to get the computed width for an element.
+ getElementWidth: function(element) {
+ return document.defaultView.getComputedStyle(element,"").getPropertyValue("width");
+ },
+ // time taken so far in attempting to load a font
+ timeAttempted: 0,
+ // returns false if no fonts are pending load, or true otherwise.
+ pending: function(intervallength) {
+ if (!this.initialized) {
+ this.initialize();
+ }
+ var element,
+ computedWidthFont,
+ computedWidthRef = this.getElementWidth(this.template);
+ for (var i = 0; i < this.fontList.length; i++) {
+ // compares size of text in pixels. if equal, custom font is not yet loaded
+ element = this.fontList[i];
+ computedWidthFont = this.getElementWidth(element);
+ if (this.timeAttempted < 4000 && computedWidthFont === computedWidthRef) {
+ this.timeAttempted += intervallength;
+ return true;
+ } else {
+ document.body.removeChild(element);
+ this.fontList.splice(i--, 1);
+ this.timeAttempted = 0;
+ }
+ }
+ // if there are no more fonts to load, pending is false
+ if (this.fontList.length === 0) {
+ return false;
+ }
+ // We should have already returned before getting here.
+ // But, if we do get here, length!=0 so fonts are pending.
+ return true;
+ },
+ // fontList contains elements to compare font sizes against a template
+ fontList: [],
+ // addedList contains the fontnames of all the fonts loaded via @font-face
+ addedList: {},
+ // adds a font to the font cache
+ // creates an element using the font, to start loading the font,
+ // and compare against a default font to see if the custom font is loaded
+ add: function(fontSrc) {
+ if (!this.initialized) {
+ this.initialize();
+ }
+ // fontSrc can be a string or a javascript object
+ // acceptable fonts are .ttf, .otf, and data uri
+ var fontName = (typeof fontSrc === 'object' ? fontSrc.fontFace : fontSrc),
+ fontUrl = (typeof fontSrc === 'object' ? fontSrc.url : fontSrc);
+
+ // check whether we already created the @font-face rule for this font
+ if (this.addedList[fontName]) {
+ return;
+ }
+
+ // if we didn't, create the @font-face rule
+ var style = document.createElement("style");
+ style.setAttribute("type","text/css");
+ style.innerHTML = "@font-face{\n font-family: '" + fontName + "';\n src: url('" + fontUrl + "');\n}\n";
+ document.head.appendChild(style);
+ this.addedList[fontName] = true;
+
+ // also create the element to load and compare the new font
+ var element = document.createElement("span");
+ element.style.cssText = "position: absolute; top: 0; left: 0; opacity: 0;";
+ element.style.fontFamily = '"' + fontName + '", "PjsEmptyFont", fantasy';
+ element.innerHTML = "AAAAAAAA";
+ document.body.appendChild(element);
+ this.fontList.push(element);
+ }
+ };
+
+ return PFont;
+};
+},{}],14:[function(require,module,exports){
+module.exports = function(options, undef) {
+
+ // FIXME: hack
+ var p = options.p;
+
+ /**
+ * PMatrix2D is a 3x2 affine matrix implementation. The constructor accepts another PMatrix2D or a list of six float elements.
+ * If no parameters are provided the matrix is set to the identity matrix.
+ *
+ * @param {PMatrix2D} matrix the initial matrix to set to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m10 the fourth element of the matrix
+ * @param {float} m11 the fifth element of the matrix
+ * @param {float} m12 the sixth element of the matrix
+ */
+ var PMatrix2D = function() {
+ if (arguments.length === 0) {
+ this.reset();
+ } else if (arguments.length === 1 && arguments[0] instanceof PMatrix2D) {
+ this.set(arguments[0].array());
+ } else if (arguments.length === 6) {
+ this.set(arguments[0], arguments[1], arguments[2], arguments[3], arguments[4], arguments[5]);
+ }
+ };
+
+ /**
+ * PMatrix2D methods
+ */
+ PMatrix2D.prototype = {
+ /**
+ * @member PMatrix2D
+ * The set() function sets the matrix elements. The function accepts either another PMatrix2D, an array of elements, or a list of six floats.
+ *
+ * @param {PMatrix2D} matrix the matrix to set this matrix to
+ * @param {float[]} elements an array of elements to set this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the third element of the matrix
+ * @param {float} m10 the fourth element of the matrix
+ * @param {float} m11 the fith element of the matrix
+ * @param {float} m12 the sixth element of the matrix
+ */
+ set: function() {
+ if (arguments.length === 6) {
+ var a = arguments;
+ this.set([a[0], a[1], a[2],
+ a[3], a[4], a[5]]);
+ } else if (arguments.length === 1 && arguments[0] instanceof PMatrix2D) {
+ this.elements = arguments[0].array();
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ this.elements = arguments[0].slice();
+ }
+ },
+ /**
+ * @member PMatrix2D
+ * The get() function returns a copy of this PMatrix2D.
+ *
+ * @return {PMatrix2D} a copy of this PMatrix2D
+ */
+ get: function() {
+ var outgoing = new PMatrix2D();
+ outgoing.set(this.elements);
+ return outgoing;
+ },
+ /**
+ * @member PMatrix2D
+ * The reset() function sets this PMatrix2D to the identity matrix.
+ */
+ reset: function() {
+ this.set([1, 0, 0, 0, 1, 0]);
+ },
+ /**
+ * @member PMatrix2D
+ * The array() function returns a copy of the element values.
+ * @addon
+ *
+ * @return {float[]} returns a copy of the element values
+ */
+ array: function array() {
+ return this.elements.slice();
+ },
+ /**
+ * @member PMatrix2D
+ * The translate() function translates this matrix by moving the current coordinates to the location specified by tx and ty.
+ *
+ * @param {float} tx the x-axis coordinate to move to
+ * @param {float} ty the y-axis coordinate to move to
+ */
+ translate: function(tx, ty) {
+ this.elements[2] = tx * this.elements[0] + ty * this.elements[1] + this.elements[2];
+ this.elements[5] = tx * this.elements[3] + ty * this.elements[4] + this.elements[5];
+ },
+ /**
+ * @member PMatrix2D
+ * The invTranslate() function translates this matrix by moving the current coordinates to the negative location specified by tx and ty.
+ *
+ * @param {float} tx the x-axis coordinate to move to
+ * @param {float} ty the y-axis coordinate to move to
+ */
+ invTranslate: function(tx, ty) {
+ this.translate(-tx, -ty);
+ },
+ /**
+ * @member PMatrix2D
+ * The transpose() function is not used in processingjs.
+ */
+ transpose: function() {
+ // Does nothing in Processing.
+ },
+ /**
+ * @member PMatrix2D
+ * The mult() function multiplied this matrix.
+ * If two array elements are passed in the function will multiply a two element vector against this matrix.
+ * If target is null or not length four, a new float array will be returned.
+ * The values for vec and target can be the same (though that's less efficient).
+ * If two PVectors are passed in the function multiply the x and y coordinates of a PVector against this matrix.
+ *
+ * @param {PVector} source, target the PVectors used to multiply this matrix
+ * @param {float[]} source, target the arrays used to multiply this matrix
+ *
+ * @return {PVector|float[]} returns a PVector or an array representing the new matrix
+ */
+ mult: function(source, target) {
+ var x, y;
+ if (source instanceof PVector) {
+ x = source.x;
+ y = source.y;
+ if (!target) {
+ target = new PVector();
+ }
+ } else if (source instanceof Array) {
+ x = source[0];
+ y = source[1];
+ if (!target) {
+ target = [];
+ }
+ }
+ if (target instanceof Array) {
+ target[0] = this.elements[0] * x + this.elements[1] * y + this.elements[2];
+ target[1] = this.elements[3] * x + this.elements[4] * y + this.elements[5];
+ } else if (target instanceof PVector) {
+ target.x = this.elements[0] * x + this.elements[1] * y + this.elements[2];
+ target.y = this.elements[3] * x + this.elements[4] * y + this.elements[5];
+ target.z = 0;
+ }
+ return target;
+ },
+ /**
+ * @member PMatrix2D
+ * The multX() function calculates the x component of a vector from a transformation.
+ *
+ * @param {float} x the x component of the vector being transformed
+ * @param {float} y the y component of the vector being transformed
+ *
+ * @return {float} returnes the result of the calculation
+ */
+ multX: function(x, y) {
+ return (x * this.elements[0] + y * this.elements[1] + this.elements[2]);
+ },
+ /**
+ * @member PMatrix2D
+ * The multY() function calculates the y component of a vector from a transformation.
+ *
+ * @param {float} x the x component of the vector being transformed
+ * @param {float} y the y component of the vector being transformed
+ *
+ * @return {float} returnes the result of the calculation
+ */
+ multY: function(x, y) {
+ return (x * this.elements[3] + y * this.elements[4] + this.elements[5]);
+ },
+ /**
+ * @member PMatrix2D
+ * The skewX() function skews the matrix along the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ skewX: function(angle) {
+ this.apply(1, 0, 1, angle, 0, 0);
+ },
+ /**
+ * @member PMatrix2D
+ * The skewY() function skews the matrix along the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ skewY: function(angle) {
+ this.apply(1, 0, 1, 0, angle, 0);
+ },
+ /**
+ * @member PMatrix2D
+ * The shearX() function shears the matrix along the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ shearX: function(angle) {
+ this.apply(1, 0, 1, Math.tan(angle) , 0, 0);
+ },
+ /**
+ * @member PMatrix2D
+ * The shearY() function shears the matrix along the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ shearY: function(angle) {
+ this.apply(1, 0, 1, 0, Math.tan(angle), 0);
+ },
+ /**
+ * @member PMatrix2D
+ * The determinant() function calvculates the determinant of this matrix.
+ *
+ * @return {float} the determinant of the matrix
+ */
+ determinant: function() {
+ return (this.elements[0] * this.elements[4] - this.elements[1] * this.elements[3]);
+ },
+ /**
+ * @member PMatrix2D
+ * The invert() function inverts this matrix
+ *
+ * @return {boolean} true if successful
+ */
+ invert: function() {
+ var d = this.determinant();
+ if (Math.abs( d ) > PConstants.MIN_INT) {
+ var old00 = this.elements[0];
+ var old01 = this.elements[1];
+ var old02 = this.elements[2];
+ var old10 = this.elements[3];
+ var old11 = this.elements[4];
+ var old12 = this.elements[5];
+ this.elements[0] = old11 / d;
+ this.elements[3] = -old10 / d;
+ this.elements[1] = -old01 / d;
+ this.elements[4] = old00 / d;
+ this.elements[2] = (old01 * old12 - old11 * old02) / d;
+ this.elements[5] = (old10 * old02 - old00 * old12) / d;
+ return true;
+ }
+ return false;
+ },
+ /**
+ * @member PMatrix2D
+ * The scale() function increases or decreases the size of a shape by expanding and contracting vertices. When only one parameter is specified scale will occur in all dimensions.
+ * This is equivalent to a two parameter call.
+ *
+ * @param {float} sx the amount to scale on the x-axis
+ * @param {float} sy the amount to scale on the y-axis
+ */
+ scale: function(sx, sy) {
+ if (sx && sy === undef) {
+ sy = sx;
+ }
+ if (sx && sy) {
+ this.elements[0] *= sx;
+ this.elements[1] *= sy;
+ this.elements[3] *= sx;
+ this.elements[4] *= sy;
+ }
+ },
+ /**
+ * @member PMatrix2D
+ * The invScale() function decreases or increases the size of a shape by contracting and expanding vertices. When only one parameter is specified scale will occur in all dimensions.
+ * This is equivalent to a two parameter call.
+ *
+ * @param {float} sx the amount to scale on the x-axis
+ * @param {float} sy the amount to scale on the y-axis
+ */
+ invScale: function(sx, sy) {
+ if (sx && !sy) {
+ sy = sx;
+ }
+ this.scale(1 / sx, 1 / sy);
+ },
+ /**
+ * @member PMatrix2D
+ * The apply() function multiplies the current matrix by the one specified through the parameters. Note that either a PMatrix2D or a list of floats can be passed in.
+ *
+ * @param {PMatrix2D} matrix the matrix to apply this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the third element of the matrix
+ * @param {float} m10 the fourth element of the matrix
+ * @param {float} m11 the fith element of the matrix
+ * @param {float} m12 the sixth element of the matrix
+ */
+ apply: function() {
+ var source;
+ if (arguments.length === 1 && arguments[0] instanceof PMatrix2D) {
+ source = arguments[0].array();
+ } else if (arguments.length === 6) {
+ source = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ source = arguments[0];
+ }
+
+ var result = [0, 0, this.elements[2],
+ 0, 0, this.elements[5]];
+ var e = 0;
+ for (var row = 0; row < 2; row++) {
+ for (var col = 0; col < 3; col++, e++) {
+ result[e] += this.elements[row * 3 + 0] * source[col + 0] +
+ this.elements[row * 3 + 1] * source[col + 3];
+ }
+ }
+ this.elements = result.slice();
+ },
+ /**
+ * @member PMatrix2D
+ * The preApply() function applies another matrix to the left of this one. Note that either a PMatrix2D or elements of a matrix can be passed in.
+ *
+ * @param {PMatrix2D} matrix the matrix to apply this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the third element of the matrix
+ * @param {float} m10 the fourth element of the matrix
+ * @param {float} m11 the fith element of the matrix
+ * @param {float} m12 the sixth element of the matrix
+ */
+ preApply: function() {
+ var source;
+ if (arguments.length === 1 && arguments[0] instanceof PMatrix2D) {
+ source = arguments[0].array();
+ } else if (arguments.length === 6) {
+ source = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ source = arguments[0];
+ }
+ var result = [0, 0, source[2],
+ 0, 0, source[5]];
+ result[2] = source[2] + this.elements[2] * source[0] + this.elements[5] * source[1];
+ result[5] = source[5] + this.elements[2] * source[3] + this.elements[5] * source[4];
+ result[0] = this.elements[0] * source[0] + this.elements[3] * source[1];
+ result[3] = this.elements[0] * source[3] + this.elements[3] * source[4];
+ result[1] = this.elements[1] * source[0] + this.elements[4] * source[1];
+ result[4] = this.elements[1] * source[3] + this.elements[4] * source[4];
+ this.elements = result.slice();
+ },
+ /**
+ * @member PMatrix2D
+ * The rotate() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotate: function(angle) {
+ var c = Math.cos(angle);
+ var s = Math.sin(angle);
+ var temp1 = this.elements[0];
+ var temp2 = this.elements[1];
+ this.elements[0] = c * temp1 + s * temp2;
+ this.elements[1] = -s * temp1 + c * temp2;
+ temp1 = this.elements[3];
+ temp2 = this.elements[4];
+ this.elements[3] = c * temp1 + s * temp2;
+ this.elements[4] = -s * temp1 + c * temp2;
+ },
+ /**
+ * @member PMatrix2D
+ * The rotateZ() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotateZ: function(angle) {
+ this.rotate(angle);
+ },
+ /**
+ * @member PMatrix2D
+ * The invRotateZ() function rotates the matrix in opposite direction.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ invRotateZ: function(angle) {
+ this.rotateZ(angle - Math.PI);
+ },
+ /**
+ * @member PMatrix2D
+ * The print() function prints out the elements of this matrix
+ */
+ print: function() {
+ var digits = printMatrixHelper(this.elements);
+ var output = "" + p.nfs(this.elements[0], digits, 4) + " " +
+ p.nfs(this.elements[1], digits, 4) + " " +
+ p.nfs(this.elements[2], digits, 4) + "\n" +
+ p.nfs(this.elements[3], digits, 4) + " " +
+ p.nfs(this.elements[4], digits, 4) + " " +
+ p.nfs(this.elements[5], digits, 4) + "\n\n";
+ p.println(output);
+ }
+ };
+
+ return PMatrix2D;
+};
+
+},{}],15:[function(require,module,exports){
+module.exports = function(options, undef) {
+
+ // FIXME: hack
+ var p = options.p;
+
+ /**
+ * PMatrix3D is a 4x4 matrix implementation. The constructor accepts another PMatrix3D or a list of six or sixteen float elements.
+ * If no parameters are provided the matrix is set to the identity matrix.
+ */
+ var PMatrix3D = function() {
+ // When a matrix is created, it is set to an identity matrix
+ this.reset();
+ };
+
+ /**
+ * PMatrix3D methods
+ */
+ PMatrix3D.prototype = {
+ /**
+ * @member PMatrix2D
+ * The set() function sets the matrix elements. The function accepts either another PMatrix3D, an array of elements, or a list of six or sixteen floats.
+ *
+ * @param {PMatrix3D} matrix the initial matrix to set to
+ * @param {float[]} elements an array of elements to set this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m03 the fourth element of the matrix
+ * @param {float} m10 the fifth element of the matrix
+ * @param {float} m11 the sixth element of the matrix
+ * @param {float} m12 the seventh element of the matrix
+ * @param {float} m13 the eight element of the matrix
+ * @param {float} m20 the nineth element of the matrix
+ * @param {float} m21 the tenth element of the matrix
+ * @param {float} m22 the eleventh element of the matrix
+ * @param {float} m23 the twelveth element of the matrix
+ * @param {float} m30 the thirteenth element of the matrix
+ * @param {float} m31 the fourtheenth element of the matrix
+ * @param {float} m32 the fivetheenth element of the matrix
+ * @param {float} m33 the sixteenth element of the matrix
+ */
+ set: function() {
+ if (arguments.length === 16) {
+ this.elements = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof PMatrix3D) {
+ this.elements = arguments[0].array();
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ this.elements = arguments[0].slice();
+ }
+ },
+ /**
+ * @member PMatrix3D
+ * The get() function returns a copy of this PMatrix3D.
+ *
+ * @return {PMatrix3D} a copy of this PMatrix3D
+ */
+ get: function() {
+ var outgoing = new PMatrix3D();
+ outgoing.set(this.elements);
+ return outgoing;
+ },
+ /**
+ * @member PMatrix3D
+ * The reset() function sets this PMatrix3D to the identity matrix.
+ */
+ reset: function() {
+ this.elements = [1,0,0,0,
+ 0,1,0,0,
+ 0,0,1,0,
+ 0,0,0,1];
+ },
+ /**
+ * @member PMatrix3D
+ * The array() function returns a copy of the element values.
+ * @addon
+ *
+ * @return {float[]} returns a copy of the element values
+ */
+ array: function array() {
+ return this.elements.slice();
+ },
+ /**
+ * @member PMatrix3D
+ * The translate() function translates this matrix by moving the current coordinates to the location specified by tx, ty, and tz.
+ *
+ * @param {float} tx the x-axis coordinate to move to
+ * @param {float} ty the y-axis coordinate to move to
+ * @param {float} tz the z-axis coordinate to move to
+ */
+ translate: function(tx, ty, tz) {
+ if (tz === undef) {
+ tz = 0;
+ }
+
+ this.elements[3] += tx * this.elements[0] + ty * this.elements[1] + tz * this.elements[2];
+ this.elements[7] += tx * this.elements[4] + ty * this.elements[5] + tz * this.elements[6];
+ this.elements[11] += tx * this.elements[8] + ty * this.elements[9] + tz * this.elements[10];
+ this.elements[15] += tx * this.elements[12] + ty * this.elements[13] + tz * this.elements[14];
+ },
+ /**
+ * @member PMatrix3D
+ * The transpose() function transpose this matrix.
+ */
+ transpose: function() {
+ var temp = this.elements[4];
+ this.elements[4] = this.elements[1];
+ this.elements[1] = temp;
+
+ temp = this.elements[8];
+ this.elements[8] = this.elements[2];
+ this.elements[2] = temp;
+
+ temp = this.elements[6];
+ this.elements[6] = this.elements[9];
+ this.elements[9] = temp;
+
+ temp = this.elements[3];
+ this.elements[3] = this.elements[12];
+ this.elements[12] = temp;
+
+ temp = this.elements[7];
+ this.elements[7] = this.elements[13];
+ this.elements[13] = temp;
+
+ temp = this.elements[11];
+ this.elements[11] = this.elements[14];
+ this.elements[14] = temp;
+ },
+ /**
+ * @member PMatrix3D
+ * The mult() function multiplied this matrix.
+ * If two array elements are passed in the function will multiply a two element vector against this matrix.
+ * If target is null or not length four, a new float array will be returned.
+ * The values for vec and target can be the same (though that's less efficient).
+ * If two PVectors are passed in the function multiply the x and y coordinates of a PVector against this matrix.
+ *
+ * @param {PVector} source, target the PVectors used to multiply this matrix
+ * @param {float[]} source, target the arrays used to multiply this matrix
+ *
+ * @return {PVector|float[]} returns a PVector or an array representing the new matrix
+ */
+ mult: function(source, target) {
+ var x, y, z, w;
+ if (source instanceof PVector) {
+ x = source.x;
+ y = source.y;
+ z = source.z;
+ w = 1;
+ if (!target) {
+ target = new PVector();
+ }
+ } else if (source instanceof Array) {
+ x = source[0];
+ y = source[1];
+ z = source[2];
+ w = source[3] || 1;
+
+ if ( !target || (target.length !== 3 && target.length !== 4) ) {
+ target = [0, 0, 0];
+ }
+ }
+
+ if (target instanceof Array) {
+ if (target.length === 3) {
+ target[0] = this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3];
+ target[1] = this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7];
+ target[2] = this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11];
+ } else if (target.length === 4) {
+ target[0] = this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3] * w;
+ target[1] = this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7] * w;
+ target[2] = this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11] * w;
+ target[3] = this.elements[12] * x + this.elements[13] * y + this.elements[14] * z + this.elements[15] * w;
+ }
+ }
+ if (target instanceof PVector) {
+ target.x = this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3];
+ target.y = this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7];
+ target.z = this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11];
+ }
+ return target;
+ },
+ /**
+ * @member PMatrix3D
+ * The preApply() function applies another matrix to the left of this one. Note that either a PMatrix3D or elements of a matrix can be passed in.
+ *
+ * @param {PMatrix3D} matrix the matrix to apply this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m03 the fourth element of the matrix
+ * @param {float} m10 the fifth element of the matrix
+ * @param {float} m11 the sixth element of the matrix
+ * @param {float} m12 the seventh element of the matrix
+ * @param {float} m13 the eight element of the matrix
+ * @param {float} m20 the nineth element of the matrix
+ * @param {float} m21 the tenth element of the matrix
+ * @param {float} m22 the eleventh element of the matrix
+ * @param {float} m23 the twelveth element of the matrix
+ * @param {float} m30 the thirteenth element of the matrix
+ * @param {float} m31 the fourtheenth element of the matrix
+ * @param {float} m32 the fivetheenth element of the matrix
+ * @param {float} m33 the sixteenth element of the matrix
+ */
+ preApply: function() {
+ var source;
+ if (arguments.length === 1 && arguments[0] instanceof PMatrix3D) {
+ source = arguments[0].array();
+ } else if (arguments.length === 16) {
+ source = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ source = arguments[0];
+ }
+
+ var result = [0, 0, 0, 0,
+ 0, 0, 0, 0,
+ 0, 0, 0, 0,
+ 0, 0, 0, 0];
+ var e = 0;
+ for (var row = 0; row < 4; row++) {
+ for (var col = 0; col < 4; col++, e++) {
+ result[e] += this.elements[col + 0] * source[row * 4 + 0] + this.elements[col + 4] *
+ source[row * 4 + 1] + this.elements[col + 8] * source[row * 4 + 2] +
+ this.elements[col + 12] * source[row * 4 + 3];
+ }
+ }
+ this.elements = result.slice();
+ },
+ /**
+ * @member PMatrix3D
+ * The apply() function multiplies the current matrix by the one specified through the parameters. Note that either a PMatrix3D or a list of floats can be passed in.
+ *
+ * @param {PMatrix3D} matrix the matrix to apply this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m03 the fourth element of the matrix
+ * @param {float} m10 the fifth element of the matrix
+ * @param {float} m11 the sixth element of the matrix
+ * @param {float} m12 the seventh element of the matrix
+ * @param {float} m13 the eight element of the matrix
+ * @param {float} m20 the nineth element of the matrix
+ * @param {float} m21 the tenth element of the matrix
+ * @param {float} m22 the eleventh element of the matrix
+ * @param {float} m23 the twelveth element of the matrix
+ * @param {float} m30 the thirteenth element of the matrix
+ * @param {float} m31 the fourtheenth element of the matrix
+ * @param {float} m32 the fivetheenth element of the matrix
+ * @param {float} m33 the sixteenth element of the matrix
+ */
+ apply: function() {
+ var source;
+ if (arguments.length === 1 && arguments[0] instanceof PMatrix3D) {
+ source = arguments[0].array();
+ } else if (arguments.length === 16) {
+ source = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ source = arguments[0];
+ }
+
+ var result = [0, 0, 0, 0,
+ 0, 0, 0, 0,
+ 0, 0, 0, 0,
+ 0, 0, 0, 0];
+ var e = 0;
+ for (var row = 0; row < 4; row++) {
+ for (var col = 0; col < 4; col++, e++) {
+ result[e] += this.elements[row * 4 + 0] * source[col + 0] + this.elements[row * 4 + 1] *
+ source[col + 4] + this.elements[row * 4 + 2] * source[col + 8] +
+ this.elements[row * 4 + 3] * source[col + 12];
+ }
+ }
+ this.elements = result.slice();
+ },
+ /**
+ * @member PMatrix3D
+ * The rotate() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotate: function(angle, v0, v1, v2) {
+ if (!v1) {
+ this.rotateZ(angle);
+ } else {
+ // TODO should make sure this vector is normalized
+ var c = Math.cos(angle);
+ var s = Math.sin(angle);
+ var t = 1.0 - c;
+
+ this.apply((t * v0 * v0) + c,
+ (t * v0 * v1) - (s * v2),
+ (t * v0 * v2) + (s * v1),
+ 0,
+ (t * v0 * v1) + (s * v2),
+ (t * v1 * v1) + c,
+ (t * v1 * v2) - (s * v0),
+ 0,
+ (t * v0 * v2) - (s * v1),
+ (t * v1 * v2) + (s * v0),
+ (t * v2 * v2) + c,
+ 0,
+ 0, 0, 0, 1);
+ }
+ },
+ /**
+ * @member PMatrix3D
+ * The invApply() function applies the inverted matrix to this matrix.
+ *
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m03 the fourth element of the matrix
+ * @param {float} m10 the fifth element of the matrix
+ * @param {float} m11 the sixth element of the matrix
+ * @param {float} m12 the seventh element of the matrix
+ * @param {float} m13 the eight element of the matrix
+ * @param {float} m20 the nineth element of the matrix
+ * @param {float} m21 the tenth element of the matrix
+ * @param {float} m22 the eleventh element of the matrix
+ * @param {float} m23 the twelveth element of the matrix
+ * @param {float} m30 the thirteenth element of the matrix
+ * @param {float} m31 the fourtheenth element of the matrix
+ * @param {float} m32 the fivetheenth element of the matrix
+ * @param {float} m33 the sixteenth element of the matrix
+ *
+ * @return {boolean} returns true if the operation was successful.
+ */
+ invApply: function() {
+ if (inverseCopy === undef) {
+ inverseCopy = new PMatrix3D();
+ }
+ var a = arguments;
+ inverseCopy.set(a[0], a[1], a[2], a[3], a[4], a[5], a[6], a[7], a[8],
+ a[9], a[10], a[11], a[12], a[13], a[14], a[15]);
+
+ if (!inverseCopy.invert()) {
+ return false;
+ }
+ this.preApply(inverseCopy);
+ return true;
+ },
+ /**
+ * @member PMatrix3D
+ * The rotateZ() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotateX: function(angle) {
+ var c = Math.cos(angle);
+ var s = Math.sin(angle);
+ this.apply([1, 0, 0, 0, 0, c, -s, 0, 0, s, c, 0, 0, 0, 0, 1]);
+ },
+ /**
+ * @member PMatrix3D
+ * The rotateY() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotateY: function(angle) {
+ var c = Math.cos(angle);
+ var s = Math.sin(angle);
+ this.apply([c, 0, s, 0, 0, 1, 0, 0, -s, 0, c, 0, 0, 0, 0, 1]);
+ },
+ /**
+ * @member PMatrix3D
+ * The rotateZ() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotateZ: function(angle) {
+ var c = Math.cos(angle);
+ var s = Math.sin(angle);
+ this.apply([c, -s, 0, 0, s, c, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1]);
+ },
+ /**
+ * @member PMatrix3D
+ * The scale() function increases or decreases the size of a matrix by expanding and contracting vertices. When only one parameter is specified scale will occur in all dimensions.
+ * This is equivalent to a three parameter call.
+ *
+ * @param {float} sx the amount to scale on the x-axis
+ * @param {float} sy the amount to scale on the y-axis
+ * @param {float} sz the amount to scale on the z-axis
+ */
+ scale: function(sx, sy, sz) {
+ if (sx && sy === undef && sz === undef) {
+ sy = sz = sx;
+ } else if (sx && sy && sz === undef) {
+ sz = 1;
+ }
+
+ if (sx && sy && sz) {
+ this.elements[0] *= sx;
+ this.elements[1] *= sy;
+ this.elements[2] *= sz;
+ this.elements[4] *= sx;
+ this.elements[5] *= sy;
+ this.elements[6] *= sz;
+ this.elements[8] *= sx;
+ this.elements[9] *= sy;
+ this.elements[10] *= sz;
+ this.elements[12] *= sx;
+ this.elements[13] *= sy;
+ this.elements[14] *= sz;
+ }
+ },
+ /**
+ * @member PMatrix3D
+ * The skewX() function skews the matrix along the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ skewX: function(angle) {
+ var t = Math.tan(angle);
+ this.apply(1, t, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1);
+ },
+ /**
+ * @member PMatrix3D
+ * The skewY() function skews the matrix along the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ skewY: function(angle) {
+ var t = Math.tan(angle);
+ this.apply(1, 0, 0, 0, t, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1);
+ },
+ /**
+ * @member PMatrix3D
+ * The shearX() function shears the matrix along the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of shear specified in radians
+ */
+ shearX: function(angle) {
+ var t = Math.tan(angle);
+ this.apply(1, t, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1);
+ },
+ /**
+ * @member PMatrix3D
+ * The shearY() function shears the matrix along the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of shear specified in radians
+ */
+ shearY: function(angle) {
+ var t = Math.tan(angle);
+ this.apply(1, 0, 0, 0, t, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1);
+ },
+ multX: function(x, y, z, w) {
+ if (!z) {
+ return this.elements[0] * x + this.elements[1] * y + this.elements[3];
+ }
+ if (!w) {
+ return this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3];
+ }
+ return this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3] * w;
+ },
+ multY: function(x, y, z, w) {
+ if (!z) {
+ return this.elements[4] * x + this.elements[5] * y + this.elements[7];
+ }
+ if (!w) {
+ return this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7];
+ }
+ return this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7] * w;
+ },
+ multZ: function(x, y, z, w) {
+ if (!w) {
+ return this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11];
+ }
+ return this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11] * w;
+ },
+ multW: function(x, y, z, w) {
+ if (!w) {
+ return this.elements[12] * x + this.elements[13] * y + this.elements[14] * z + this.elements[15];
+ }
+ return this.elements[12] * x + this.elements[13] * y + this.elements[14] * z + this.elements[15] * w;
+ },
+ /**
+ * @member PMatrix3D
+ * The invert() function inverts this matrix
+ *
+ * @return {boolean} true if successful
+ */
+ invert: function() {
+ var fA0 = this.elements[0] * this.elements[5] - this.elements[1] * this.elements[4];
+ var fA1 = this.elements[0] * this.elements[6] - this.elements[2] * this.elements[4];
+ var fA2 = this.elements[0] * this.elements[7] - this.elements[3] * this.elements[4];
+ var fA3 = this.elements[1] * this.elements[6] - this.elements[2] * this.elements[5];
+ var fA4 = this.elements[1] * this.elements[7] - this.elements[3] * this.elements[5];
+ var fA5 = this.elements[2] * this.elements[7] - this.elements[3] * this.elements[6];
+ var fB0 = this.elements[8] * this.elements[13] - this.elements[9] * this.elements[12];
+ var fB1 = this.elements[8] * this.elements[14] - this.elements[10] * this.elements[12];
+ var fB2 = this.elements[8] * this.elements[15] - this.elements[11] * this.elements[12];
+ var fB3 = this.elements[9] * this.elements[14] - this.elements[10] * this.elements[13];
+ var fB4 = this.elements[9] * this.elements[15] - this.elements[11] * this.elements[13];
+ var fB5 = this.elements[10] * this.elements[15] - this.elements[11] * this.elements[14];
+
+ // Determinant
+ var fDet = fA0 * fB5 - fA1 * fB4 + fA2 * fB3 + fA3 * fB2 - fA4 * fB1 + fA5 * fB0;
+
+ // Account for a very small value
+ // return false if not successful.
+ if (Math.abs(fDet) <= 1e-9) {
+ return false;
+ }
+
+ var kInv = [];
+ kInv[0] = +this.elements[5] * fB5 - this.elements[6] * fB4 + this.elements[7] * fB3;
+ kInv[4] = -this.elements[4] * fB5 + this.elements[6] * fB2 - this.elements[7] * fB1;
+ kInv[8] = +this.elements[4] * fB4 - this.elements[5] * fB2 + this.elements[7] * fB0;
+ kInv[12] = -this.elements[4] * fB3 + this.elements[5] * fB1 - this.elements[6] * fB0;
+ kInv[1] = -this.elements[1] * fB5 + this.elements[2] * fB4 - this.elements[3] * fB3;
+ kInv[5] = +this.elements[0] * fB5 - this.elements[2] * fB2 + this.elements[3] * fB1;
+ kInv[9] = -this.elements[0] * fB4 + this.elements[1] * fB2 - this.elements[3] * fB0;
+ kInv[13] = +this.elements[0] * fB3 - this.elements[1] * fB1 + this.elements[2] * fB0;
+ kInv[2] = +this.elements[13] * fA5 - this.elements[14] * fA4 + this.elements[15] * fA3;
+ kInv[6] = -this.elements[12] * fA5 + this.elements[14] * fA2 - this.elements[15] * fA1;
+ kInv[10] = +this.elements[12] * fA4 - this.elements[13] * fA2 + this.elements[15] * fA0;
+ kInv[14] = -this.elements[12] * fA3 + this.elements[13] * fA1 - this.elements[14] * fA0;
+ kInv[3] = -this.elements[9] * fA5 + this.elements[10] * fA4 - this.elements[11] * fA3;
+ kInv[7] = +this.elements[8] * fA5 - this.elements[10] * fA2 + this.elements[11] * fA1;
+ kInv[11] = -this.elements[8] * fA4 + this.elements[9] * fA2 - this.elements[11] * fA0;
+ kInv[15] = +this.elements[8] * fA3 - this.elements[9] * fA1 + this.elements[10] * fA0;
+
+ // Inverse using Determinant
+ var fInvDet = 1.0 / fDet;
+ kInv[0] *= fInvDet;
+ kInv[1] *= fInvDet;
+ kInv[2] *= fInvDet;
+ kInv[3] *= fInvDet;
+ kInv[4] *= fInvDet;
+ kInv[5] *= fInvDet;
+ kInv[6] *= fInvDet;
+ kInv[7] *= fInvDet;
+ kInv[8] *= fInvDet;
+ kInv[9] *= fInvDet;
+ kInv[10] *= fInvDet;
+ kInv[11] *= fInvDet;
+ kInv[12] *= fInvDet;
+ kInv[13] *= fInvDet;
+ kInv[14] *= fInvDet;
+ kInv[15] *= fInvDet;
+
+ this.elements = kInv.slice();
+ return true;
+ },
+ toString: function() {
+ var str = "";
+ for (var i = 0; i < 15; i++) {
+ str += this.elements[i] + ", ";
+ }
+ str += this.elements[15];
+ return str;
+ },
+ /**
+ * @member PMatrix3D
+ * The print() function prints out the elements of this matrix
+ */
+ print: function() {
+ var digits = printMatrixHelper(this.elements);
+
+ var output = "" + p.nfs(this.elements[0], digits, 4) + " " + p.nfs(this.elements[1], digits, 4) +
+ " " + p.nfs(this.elements[2], digits, 4) + " " + p.nfs(this.elements[3], digits, 4) +
+ "\n" + p.nfs(this.elements[4], digits, 4) + " " + p.nfs(this.elements[5], digits, 4) +
+ " " + p.nfs(this.elements[6], digits, 4) + " " + p.nfs(this.elements[7], digits, 4) +
+ "\n" + p.nfs(this.elements[8], digits, 4) + " " + p.nfs(this.elements[9], digits, 4) +
+ " " + p.nfs(this.elements[10], digits, 4) + " " + p.nfs(this.elements[11], digits, 4) +
+ "\n" + p.nfs(this.elements[12], digits, 4) + " " + p.nfs(this.elements[13], digits, 4) +
+ " " + p.nfs(this.elements[14], digits, 4) + " " + p.nfs(this.elements[15], digits, 4) + "\n\n";
+ p.println(output);
+ },
+ invTranslate: function(tx, ty, tz) {
+ this.preApply(1, 0, 0, -tx, 0, 1, 0, -ty, 0, 0, 1, -tz, 0, 0, 0, 1);
+ },
+ invRotateX: function(angle) {
+ var c = Math.cos(-angle);
+ var s = Math.sin(-angle);
+ this.preApply([1, 0, 0, 0, 0, c, -s, 0, 0, s, c, 0, 0, 0, 0, 1]);
+ },
+ invRotateY: function(angle) {
+ var c = Math.cos(-angle);
+ var s = Math.sin(-angle);
+ this.preApply([c, 0, s, 0, 0, 1, 0, 0, -s, 0, c, 0, 0, 0, 0, 1]);
+ },
+ invRotateZ: function(angle) {
+ var c = Math.cos(-angle);
+ var s = Math.sin(-angle);
+ this.preApply([c, -s, 0, 0, s, c, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1]);
+ },
+ invScale: function(x, y, z) {
+ this.preApply([1 / x, 0, 0, 0, 0, 1 / y, 0, 0, 0, 0, 1 / z, 0, 0, 0, 0, 1]);
+ }
+ };
+
+ return PMatrix3D;
+};
+},{}],16:[function(require,module,exports){
+module.exports = function(options) {
+ var PConstants = options.PConstants,
+ PMatrix2D = options.PMatrix2D,
+ PMatrix3D = options.PMatrix3D;
+
+ /**
+ * Datatype for storing shapes. Processing can currently load and display SVG (Scalable Vector Graphics) shapes.
+ * Before a shape is used, it must be loaded with the <b>loadShape()</b> function. The <b>shape()</b> function is used to draw the shape to the display window.
+ * The <b>PShape</b> object contain a group of methods, linked below, that can operate on the shape data.
+ * <br><br>The <b>loadShape()</b> method supports SVG files created with Inkscape and Adobe Illustrator.
+ * It is not a full SVG implementation, but offers some straightforward support for handling vector data.
+ *
+ * @param {int} family the shape type, one of GROUP, PRIMITIVE, PATH, or GEOMETRY
+ *
+ * @see #shape()
+ * @see #loadShape()
+ * @see #shapeMode()
+ */
+ var PShape = function(family) {
+ this.family = family || PConstants.GROUP;
+ this.visible = true;
+ this.style = true;
+ this.children = [];
+ this.nameTable = [];
+ this.params = [];
+ this.name = "";
+ this.image = null; //type PImage
+ this.matrix = null;
+ this.kind = null;
+ this.close = null;
+ this.width = null;
+ this.height = null;
+ this.parent = null;
+ };
+ /**
+ * PShape methods
+ * missing: findChild(), apply(), contains(), findChild(), getPrimitive(), getParams(), getVertex() , getVertexCount(),
+ * getVertexCode() , getVertexCodes() , getVertexCodeCount(), getVertexX(), getVertexY(), getVertexZ()
+ */
+ PShape.prototype = {
+ /**
+ * @member PShape
+ * The isVisible() function returns a boolean value "true" if the image is set to be visible, "false" if not. This is modified with the <b>setVisible()</b> parameter.
+ * <br><br>The visibility of a shape is usually controlled by whatever program created the SVG file.
+ * For instance, this parameter is controlled by showing or hiding the shape in the layers palette in Adobe Illustrator.
+ *
+ * @return {boolean} returns "true" if the image is set to be visible, "false" if not
+ */
+ isVisible: function(){
+ return this.visible;
+ },
+ /**
+ * @member PShape
+ * The setVisible() function sets the shape to be visible or invisible. This is determined by the value of the <b>visible</b> parameter.
+ * <br><br>The visibility of a shape is usually controlled by whatever program created the SVG file.
+ * For instance, this parameter is controlled by showing or hiding the shape in the layers palette in Adobe Illustrator.
+ *
+ * @param {boolean} visible "false" makes the shape invisible and "true" makes it visible
+ */
+ setVisible: function (visible){
+ this.visible = visible;
+ },
+ /**
+ * @member PShape
+ * The disableStyle() function disables the shape's style data and uses Processing's current styles. Styles include attributes such as colors, stroke weight, and stroke joints.
+ * Overrides this shape's style information and uses PGraphics styles and colors. Identical to ignoreStyles(true). Also disables styles for all child shapes.
+ */
+ disableStyle: function(){
+ this.style = false;
+ for(var i = 0, j=this.children.length; i<j; i++) {
+ this.children[i].disableStyle();
+ }
+ },
+ /**
+ * @member PShape
+ * The enableStyle() function enables the shape's style data and ignores Processing's current styles. Styles include attributes such as colors, stroke weight, and stroke joints.
+ */
+ enableStyle: function(){
+ this.style = true;
+ for(var i = 0, j=this.children.length; i<j; i++) {
+ this.children[i].enableStyle();
+ }
+ },
+ /**
+ * @member PShape
+ * The getFamily function returns the shape type
+ *
+ * @return {int} the shape type, one of GROUP, PRIMITIVE, PATH, or GEOMETRY
+ */
+ getFamily: function(){
+ return this.family;
+ },
+ /**
+ * @member PShape
+ * The getWidth() function gets the width of the drawing area (not necessarily the shape boundary).
+ */
+ getWidth: function(){
+ return this.width;
+ },
+ /**
+ * @member PShape
+ * The getHeight() function gets the height of the drawing area (not necessarily the shape boundary).
+ */
+ getHeight: function(){
+ return this.height;
+ },
+ /**
+ * @member PShape
+ * The setName() function sets the name of the shape
+ *
+ * @param {String} name the name of the shape
+ */
+ setName: function(name){
+ this.name = name;
+ },
+ /**
+ * @member PShape
+ * The getName() function returns the name of the shape
+ *
+ * @return {String} the name of the shape
+ */
+ getName: function(){
+ return this.name;
+ },
+ /**
+ * @member PShape
+ * Called by the following (the shape() command adds the g)
+ * PShape s = loadShapes("blah.svg");
+ * shape(s);
+ */
+ draw: function(renderContext) {
+ if(!renderContext) {
+ throw "render context missing for draw() in PShape";
+ }
+ if (this.visible) {
+ this.pre(renderContext);
+ this.drawImpl(renderContext);
+ this.post(renderContext);
+ }
+ },
+ /**
+ * @member PShape
+ * the drawImpl() function draws the SVG document.
+ */
+ drawImpl: function(renderContext) {
+ if (this.family === PConstants.GROUP) {
+ this.drawGroup(renderContext);
+ } else if (this.family === PConstants.PRIMITIVE) {
+ this.drawPrimitive(renderContext);
+ } else if (this.family === PConstants.GEOMETRY) {
+ this.drawGeometry(renderContext);
+ } else if (this.family === PConstants.PATH) {
+ this.drawPath(renderContext);
+ }
+ },
+ /**
+ * @member PShape
+ * The drawPath() function draws the <path> part of the SVG document.
+ */
+ drawPath: function(renderContext) {
+ var i, j;
+ if (this.vertices.length === 0) { return; }
+ renderContext.beginShape();
+ if (this.vertexCodes.length === 0) { // each point is a simple vertex
+ if (this.vertices[0].length === 2) { // drawing 2D vertices
+ for (i = 0, j = this.vertices.length; i < j; i++) {
+ renderContext.vertex(this.vertices[i][0], this.vertices[i][1]);
+ }
+ } else { // drawing 3D vertices
+ for (i = 0, j = this.vertices.length; i < j; i++) {
+ renderContext.vertex(this.vertices[i][0],
+ this.vertices[i][1],
+ this.vertices[i][2]);
+ }
+ }
+ } else { // coded set of vertices
+ var index = 0;
+ if (this.vertices[0].length === 2) { // drawing a 2D path
+ for (i = 0, j = this.vertexCodes.length; i < j; i++) {
+ if (this.vertexCodes[i] === PConstants.VERTEX) {
+ renderContext.vertex(this.vertices[index][0], this.vertices[index][1], this.vertices[index].moveTo);
+ renderContext.breakShape = false;
+ index++;
+ } else if (this.vertexCodes[i] === PConstants.BEZIER_VERTEX) {
+ renderContext.bezierVertex(this.vertices[index+0][0],
+ this.vertices[index+0][1],
+ this.vertices[index+1][0],
+ this.vertices[index+1][1],
+ this.vertices[index+2][0],
+ this.vertices[index+2][1]);
+ index += 3;
+ } else if (this.vertexCodes[i] === PConstants.CURVE_VERTEX) {
+ renderContext.curveVertex(this.vertices[index][0],
+ this.vertices[index][1]);
+ index++;
+ } else if (this.vertexCodes[i] === PConstants.BREAK) {
+ renderContext.breakShape = true;
+ }
+ }
+ } else { // drawing a 3D path
+ for (i = 0, j = this.vertexCodes.length; i < j; i++) {
+ if (this.vertexCodes[i] === PConstants.VERTEX) {
+ renderContext.vertex(this.vertices[index][0],
+ this.vertices[index][1],
+ this.vertices[index][2]);
+ if (this.vertices[index].moveTo === true) {
+ vertArray[vertArray.length-1].moveTo = true;
+ } else if (this.vertices[index].moveTo === false) {
+ vertArray[vertArray.length-1].moveTo = false;
+ }
+ renderContext.breakShape = false;
+ } else if (this.vertexCodes[i] === PConstants.BEZIER_VERTEX) {
+ renderContext.bezierVertex(this.vertices[index+0][0],
+ this.vertices[index+0][1],
+ this.vertices[index+0][2],
+ this.vertices[index+1][0],
+ this.vertices[index+1][1],
+ this.vertices[index+1][2],
+ this.vertices[index+2][0],
+ this.vertices[index+2][1],
+ this.vertices[index+2][2]);
+ index += 3;
+ } else if (this.vertexCodes[i] === PConstants.CURVE_VERTEX) {
+ renderContext.curveVertex(this.vertices[index][0],
+ this.vertices[index][1],
+ this.vertices[index][2]);
+ index++;
+ } else if (this.vertexCodes[i] === PConstants.BREAK) {
+ renderContext.breakShape = true;
+ }
+ }
+ }
+ }
+ renderContext.endShape(this.close ? PConstants.CLOSE : PConstants.OPEN);
+ },
+ /**
+ * @member PShape
+ * The drawGeometry() function draws the geometry part of the SVG document.
+ */
+ drawGeometry: function(renderContext) {
+ var i, j;
+ renderContext.beginShape(this.kind);
+ if (this.style) {
+ for (i = 0, j = this.vertices.length; i < j; i++) {
+ renderContext.vertex(this.vertices[i]);
+ }
+ } else {
+ for (i = 0, j = this.vertices.length; i < j; i++) {
+ var vert = this.vertices[i];
+ if (vert[2] === 0) {
+ renderContext.vertex(vert[0], vert[1]);
+ } else {
+ renderContext.vertex(vert[0], vert[1], vert[2]);
+ }
+ }
+ }
+ renderContext.endShape();
+ },
+ /**
+ * @member PShape
+ * The drawGroup() function draws the <g> part of the SVG document.
+ */
+ drawGroup: function(renderContext) {
+ for (var i = 0, j = this.children.length; i < j; i++) {
+ this.children[i].draw(renderContext);
+ }
+ },
+ /**
+ * @member PShape
+ * The drawPrimitive() function draws SVG document shape elements. These can be point, line, triangle, quad, rect, ellipse, arc, box, or sphere.
+ */
+ drawPrimitive: function(renderContext) {
+ if (this.kind === PConstants.POINT) {
+ renderContext.point(this.params[0], this.params[1]);
+ } else if (this.kind === PConstants.LINE) {
+ if (this.params.length === 4) { // 2D
+ renderContext.line(this.params[0], this.params[1],
+ this.params[2], this.params[3]);
+ } else { // 3D
+ renderContext.line(this.params[0], this.params[1], this.params[2],
+ this.params[3], this.params[4], this.params[5]);
+ }
+ } else if (this.kind === PConstants.TRIANGLE) {
+ renderContext.triangle(this.params[0], this.params[1],
+ this.params[2], this.params[3],
+ this.params[4], this.params[5]);
+ } else if (this.kind === PConstants.QUAD) {
+ renderContext.quad(this.params[0], this.params[1],
+ this.params[2], this.params[3],
+ this.params[4], this.params[5],
+ this.params[6], this.params[7]);
+ } else if (this.kind === PConstants.RECT) {
+ if (this.image !== null) {
+ var imMode = imageModeConvert;
+ renderContext.imageMode(PConstants.CORNER);
+ renderContext.image(this.image,
+ this.params[0],
+ this.params[1],
+ this.params[2],
+ this.params[3]);
+ imageModeConvert = imMode;
+ } else {
+ var rcMode = renderContext.curRectMode;
+ renderContext.rectMode(PConstants.CORNER);
+ renderContext.rect(this.params[0],
+ this.params[1],
+ this.params[2],
+ this.params[3]);
+ renderContext.curRectMode = rcMode;
+ }
+ } else if (this.kind === PConstants.ELLIPSE) {
+ var elMode = renderContext.curEllipseMode;
+ renderContext.ellipseMode(PConstants.CORNER);
+ renderContext.ellipse(this.params[0],
+ this.params[1],
+ this.params[2],
+ this.params[3]);
+ renderContext.curEllipseMode = elMode;
+ } else if (this.kind === PConstants.ARC) {
+ var eMode = curEllipseMode;
+ renderContext.ellipseMode(PConstants.CORNER);
+ renderContext.arc(this.params[0],
+ this.params[1],
+ this.params[2],
+ this.params[3],
+ this.params[4],
+ this.params[5]);
+ curEllipseMode = eMode;
+ } else if (this.kind === PConstants.BOX) {
+ if (this.params.length === 1) {
+ renderContext.box(this.params[0]);
+ } else {
+ renderContext.box(this.params[0], this.params[1], this.params[2]);
+ }
+ } else if (this.kind === PConstants.SPHERE) {
+ renderContext.sphere(this.params[0]);
+ }
+ },
+ /**
+ * @member PShape
+ * The pre() function performs the preparations before the SVG is drawn. This includes doing transformations and storing previous styles.
+ */
+ pre: function(renderContext) {
+ if (this.matrix) {
+ renderContext.pushMatrix();
+ renderContext.transform(this.matrix);
+ }
+ if (this.style) {
+ renderContext.pushStyle();
+ this.styles(renderContext);
+ }
+ },
+ /**
+ * @member PShape
+ * The post() function performs the necessary actions after the SVG is drawn. This includes removing transformations and removing added styles.
+ */
+ post: function(renderContext) {
+ if (this.matrix) {
+ renderContext.popMatrix();
+ }
+ if (this.style) {
+ renderContext.popStyle();
+ }
+ },
+ /**
+ * @member PShape
+ * The styles() function changes the Processing's current styles
+ */
+ styles: function(renderContext) {
+ if (this.stroke) {
+ renderContext.stroke(this.strokeColor);
+ renderContext.strokeWeight(this.strokeWeight);
+ renderContext.strokeCap(this.strokeCap);
+ renderContext.strokeJoin(this.strokeJoin);
+ } else {
+ renderContext.noStroke();
+ }
+
+ if (this.fill) {
+ renderContext.fill(this.fillColor);
+
+ } else {
+ renderContext.noFill();
+ }
+ },
+ /**
+ * @member PShape
+ * The getChild() function extracts a child shape from a parent shape. Specify the name of the shape with the <b>target</b> parameter or the
+ * layer position of the shape to get with the <b>index</b> parameter.
+ * The shape is returned as a <b>PShape</b> object, or <b>null</b> is returned if there is an error.
+ *
+ * @param {String} target the name of the shape to get
+ * @param {int} index the layer position of the shape to get
+ *
+ * @return {PShape} returns a child element of a shape as a PShape object or null if there is an error
+ */
+ getChild: function(child) {
+ var i, j;
+ if (typeof child === 'number') {
+ return this.children[child];
+ }
+ var found;
+ if(child === "" || this.name === child){
+ return this;
+ }
+ if(this.nameTable.length > 0) {
+ for(i = 0, j = this.nameTable.length; i < j || found; i++) {
+ if(this.nameTable[i].getName === child) {
+ found = this.nameTable[i];
+ break;
+ }
+ }
+ if (found) { return found; }
+ }
+ for(i = 0, j = this.children.length; i < j; i++) {
+ found = this.children[i].getChild(child);
+ if(found) { return found; }
+ }
+ return null;
+ },
+ /**
+ * @member PShape
+ * The getChildCount() returns the number of children
+ *
+ * @return {int} returns a count of children
+ */
+ getChildCount: function () {
+ return this.children.length;
+ },
+ /**
+ * @member PShape
+ * The addChild() adds a child to the PShape.
+ *
+ * @param {PShape} child the child to add
+ */
+ addChild: function( child ) {
+ this.children.push(child);
+ child.parent = this;
+ if (child.getName() !== null) {
+ this.addName(child.getName(), child);
+ }
+ },
+ /**
+ * @member PShape
+ * The addName() functions adds a shape to the name lookup table.
+ *
+ * @param {String} name the name to be added
+ * @param {PShape} shape the shape
+ */
+ addName: function(name, shape) {
+ if (this.parent !== null) {
+ this.parent.addName( name, shape );
+ } else {
+ this.nameTable.push( [name, shape] );
+ }
+ },
+ /**
+ * @member PShape
+ * The translate() function specifies an amount to displace the shape. The <b>x</b> parameter specifies left/right translation, the <b>y</b> parameter specifies up/down translation, and the <b>z</b> parameter specifies translations toward/away from the screen.
+ * Subsequent calls to the method accumulates the effect. For example, calling <b>translate(50, 0)</b> and then <b>translate(20, 0)</b> is the same as <b>translate(70, 0)</b>.
+ * This transformation is applied directly to the shape, it's not refreshed each time <b>draw()</b> is run.
+ * <br><br>Using this method with the <b>z</b> parameter requires using the P3D or OPENGL parameter in combination with size.
+ *
+ * @param {int|float} x left/right translation
+ * @param {int|float} y up/down translation
+ * @param {int|float} z forward/back translation
+ *
+ * @see PMatrix2D#translate
+ * @see PMatrix3D#translate
+ */
+ translate: function() {
+ if(arguments.length === 2)
+ {
+ this.checkMatrix(2);
+ this.matrix.translate(arguments[0], arguments[1]);
+ } else {
+ this.checkMatrix(3);
+ this.matrix.translate(arguments[0], arguments[1], 0);
+ }
+ },
+ /**
+ * @member PShape
+ * The checkMatrix() function makes sure that the shape's matrix is 1) not null, and 2) has a matrix
+ * that can handle <em>at least</em> the specified number of dimensions.
+ *
+ * @param {int} dimensions the specified number of dimensions
+ */
+ checkMatrix: function(dimensions) {
+ if(this.matrix === null) {
+ if(dimensions === 2) {
+ this.matrix = new PMatrix2D();
+ } else {
+ this.matrix = new PMatrix3D();
+ }
+ }else if(dimensions === 3 && this.matrix instanceof PMatrix2D) {
+ this.matrix = new PMatrix3D();
+ }
+ },
+ /**
+ * @member PShape
+ * The rotateX() function rotates a shape around the x-axis the amount specified by the <b>angle</b> parameter. Angles should be specified in radians (values from 0 to TWO_PI) or converted to radians with the <b>radians()</b> method.
+ * <br><br>Shapes are always rotated around the upper-left corner of their bounding box. Positive numbers rotate objects in a clockwise direction.
+ * Subsequent calls to the method accumulates the effect. For example, calling <b>rotateX(HALF_PI)</b> and then <b>rotateX(HALF_PI)</b> is the same as <b>rotateX(PI)</b>.
+ * This transformation is applied directly to the shape, it's not refreshed each time <b>draw()</b> is run.
+ * <br><br>This method requires a 3D renderer. You need to pass P3D or OPENGL as a third parameter into the <b>size()</b> method as shown in the example above.
+ *
+ * @param {float}angle angle of rotation specified in radians
+ *
+ * @see PMatrix3D#rotateX
+ */
+ rotateX: function(angle) {
+ this.rotate(angle, 1, 0, 0);
+ },
+ /**
+ * @member PShape
+ * The rotateY() function rotates a shape around the y-axis the amount specified by the <b>angle</b> parameter. Angles should be specified in radians (values from 0 to TWO_PI) or converted to radians with the <b>radians()</b> method.
+ * <br><br>Shapes are always rotated around the upper-left corner of their bounding box. Positive numbers rotate objects in a clockwise direction.
+ * Subsequent calls to the method accumulates the effect. For example, calling <b>rotateY(HALF_PI)</b> and then <b>rotateY(HALF_PI)</b> is the same as <b>rotateY(PI)</b>.
+ * This transformation is applied directly to the shape, it's not refreshed each time <b>draw()</b> is run.
+ * <br><br>This method requires a 3D renderer. You need to pass P3D or OPENGL as a third parameter into the <b>size()</b> method as shown in the example above.
+ *
+ * @param {float}angle angle of rotation specified in radians
+ *
+ * @see PMatrix3D#rotateY
+ */
+ rotateY: function(angle) {
+ this.rotate(angle, 0, 1, 0);
+ },
+ /**
+ * @member PShape
+ * The rotateZ() function rotates a shape around the z-axis the amount specified by the <b>angle</b> parameter. Angles should be specified in radians (values from 0 to TWO_PI) or converted to radians with the <b>radians()</b> method.
+ * <br><br>Shapes are always rotated around the upper-left corner of their bounding box. Positive numbers rotate objects in a clockwise direction.
+ * Subsequent calls to the method accumulates the effect. For example, calling <b>rotateZ(HALF_PI)</b> and then <b>rotateZ(HALF_PI)</b> is the same as <b>rotateZ(PI)</b>.
+ * This transformation is applied directly to the shape, it's not refreshed each time <b>draw()</b> is run.
+ * <br><br>This method requires a 3D renderer. You need to pass P3D or OPENGL as a third parameter into the <b>size()</b> method as shown in the example above.
+ *
+ * @param {float}angle angle of rotation specified in radians
+ *
+ * @see PMatrix3D#rotateZ
+ */
+ rotateZ: function(angle) {
+ this.rotate(angle, 0, 0, 1);
+ },
+ /**
+ * @member PShape
+ * The rotate() function rotates a shape the amount specified by the <b>angle</b> parameter. Angles should be specified in radians (values from 0 to TWO_PI) or converted to radians with the <b>radians()</b> method.
+ * <br><br>Shapes are always rotated around the upper-left corner of their bounding box. Positive numbers rotate objects in a clockwise direction.
+ * Transformations apply to everything that happens after and subsequent calls to the method accumulates the effect.
+ * For example, calling <b>rotate(HALF_PI)</b> and then <b>rotate(HALF_PI)</b> is the same as <b>rotate(PI)</b>.
+ * This transformation is applied directly to the shape, it's not refreshed each time <b>draw()</b> is run.
+ * If optional parameters x,y,z are supplied, the rotate is about the point (x, y, z).
+ *
+ * @param {float}angle angle of rotation specified in radians
+ * @param {float}x x-coordinate of the point
+ * @param {float}y y-coordinate of the point
+ * @param {float}z z-coordinate of the point
+ * @see PMatrix2D#rotate
+ * @see PMatrix3D#rotate
+ */
+ rotate: function() {
+ if(arguments.length === 1){
+ this.checkMatrix(2);
+ this.matrix.rotate(arguments[0]);
+ } else {
+ this.checkMatrix(3);
+ this.matrix.rotate(arguments[0],
+ arguments[1],
+ arguments[2],
+ arguments[3]);
+ }
+ },
+ /**
+ * @member PShape
+ * The scale() function increases or decreases the size of a shape by expanding and contracting vertices. Shapes always scale from the relative origin of their bounding box.
+ * Scale values are specified as decimal percentages. For example, the method call <b>scale(2.0)</b> increases the dimension of a shape by 200%.
+ * Subsequent calls to the method multiply the effect. For example, calling <b>scale(2.0)</b> and then <b>scale(1.5)</b> is the same as <b>scale(3.0)</b>.
+ * This transformation is applied directly to the shape, it's not refreshed each time <b>draw()</b> is run.
+ * <br><br>Using this fuction with the <b>z</b> parameter requires passing P3D or OPENGL into the size() parameter.
+ *
+ * @param {float}s percentage to scale the object
+ * @param {float}x percentage to scale the object in the x-axis
+ * @param {float}y percentage to scale the object in the y-axis
+ * @param {float}z percentage to scale the object in the z-axis
+ *
+ * @see PMatrix2D#scale
+ * @see PMatrix3D#scale
+ */
+ scale: function() {
+ if(arguments.length === 2) {
+ this.checkMatrix(2);
+ this.matrix.scale(arguments[0], arguments[1]);
+ } else if (arguments.length === 3) {
+ this.checkMatrix(2);
+ this.matrix.scale(arguments[0], arguments[1], arguments[2]);
+ } else {
+ this.checkMatrix(2);
+ this.matrix.scale(arguments[0]);
+ }
+ },
+ /**
+ * @member PShape
+ * The resetMatrix() function resets the matrix
+ *
+ * @see PMatrix2D#reset
+ * @see PMatrix3D#reset
+ */
+ resetMatrix: function() {
+ this.checkMatrix(2);
+ this.matrix.reset();
+ },
+ /**
+ * @member PShape
+ * The applyMatrix() function multiplies this matrix by another matrix of type PMatrix3D or PMatrix2D.
+ * Individual elements can also be provided
+ *
+ * @param {PMatrix3D|PMatrix2D} matrix the matrix to multiply by
+ *
+ * @see PMatrix2D#apply
+ * @see PMatrix3D#apply
+ */
+ applyMatrix: function(matrix) {
+ if (arguments.length === 1) {
+ this.applyMatrix(matrix.elements[0],
+ matrix.elements[1], 0,
+ matrix.elements[2],
+ matrix.elements[3],
+ matrix.elements[4], 0,
+ matrix.elements[5],
+ 0, 0, 1, 0,
+ 0, 0, 0, 1);
+ } else if (arguments.length === 6) {
+ this.checkMatrix(2);
+ this.matrix.apply(arguments[0], arguments[1], arguments[2], 0,
+ arguments[3], arguments[4], arguments[5], 0,
+ 0, 0, 1, 0,
+ 0, 0, 0, 1);
+
+ } else if (arguments.length === 16) {
+ this.checkMatrix(3);
+ this.matrix.apply(arguments[0],
+ arguments[1],
+ arguments[2],
+ arguments[3],
+ arguments[4],
+ arguments[5],
+ arguments[6],
+ arguments[7],
+ arguments[8],
+ arguments[9],
+ arguments[10],
+ arguments[11],
+ arguments[12],
+ arguments[13],
+ arguments[14],
+ arguments[15]);
+ }
+ }
+ };
+
+ return PShape;
+};
+},{}],17:[function(require,module,exports){
+/**
+ * SVG stands for Scalable Vector Graphics, a portable graphics format. It is
+ * a vector format so it allows for infinite resolution and relatively small
+ * file sizes. Most modern media software can view SVG files, including Adobe
+ * products, Firefox, etc. Illustrator and Inkscape can edit SVG files.
+ *
+ * @param {PApplet} parent typically use "this"
+ * @param {String} filename name of the SVG file to load
+ * @param {XMLElement} xml an XMLElement element
+ * @param {PShapeSVG} parent the parent PShapeSVG
+ *
+ * @see PShape
+ */
+module.exports = function(options) {
+ var CommonFunctions = options.CommonFunctions,
+ PConstants = options.PConstants,
+ PShape = options.PShape,
+ XMLElement = options.XMLElement,
+ colors = options.colors;
+
+ var PShapeSVG = function() {
+ PShape.call(this); // PShape is the base class.
+ if (arguments.length === 1) { // xml element coming in
+ this.element = arguments[0];
+
+ // set values to their defaults according to the SVG spec
+ this.vertexCodes = [];
+ this.vertices = [];
+ this.opacity = 1;
+
+ this.stroke = false;
+ this.strokeColor = PConstants.ALPHA_MASK;
+ this.strokeWeight = 1;
+ this.strokeCap = PConstants.SQUARE; // BUTT in svg spec
+ this.strokeJoin = PConstants.MITER;
+ this.strokeGradient = null;
+ this.strokeGradientPaint = null;
+ this.strokeName = null;
+ this.strokeOpacity = 1;
+
+ this.fill = true;
+ this.fillColor = PConstants.ALPHA_MASK;
+ this.fillGradient = null;
+ this.fillGradientPaint = null;
+ this.fillName = null;
+ this.fillOpacity = 1;
+
+ if (this.element.getName() !== "svg") {
+ throw("root is not <svg>, it's <" + this.element.getName() + ">");
+ }
+ }
+ else if (arguments.length === 2) {
+ if (typeof arguments[1] === 'string') {
+ if (arguments[1].indexOf(".svg") > -1) { //its a filename
+ this.element = new XMLElement(true, arguments[1]);
+ // set values to their defaults according to the SVG spec
+ this.vertexCodes = [];
+ this.vertices = [];
+ this.opacity = 1;
+
+ this.stroke = false;
+ this.strokeColor = PConstants.ALPHA_MASK;
+ this.strokeWeight = 1;
+ this.strokeCap = PConstants.SQUARE; // BUTT in svg spec
+ this.strokeJoin = PConstants.MITER;
+ this.strokeGradient = "";
+ this.strokeGradientPaint = "";
+ this.strokeName = "";
+ this.strokeOpacity = 1;
+
+ this.fill = true;
+ this.fillColor = PConstants.ALPHA_MASK;
+ this.fillGradient = null;
+ this.fillGradientPaint = null;
+ this.fillOpacity = 1;
+
+ }
+ } else { // XMLElement
+ if (arguments[0]) { // PShapeSVG
+ this.element = arguments[1];
+ this.vertexCodes = arguments[0].vertexCodes.slice();
+ this.vertices = arguments[0].vertices.slice();
+
+ this.stroke = arguments[0].stroke;
+ this.strokeColor = arguments[0].strokeColor;
+ this.strokeWeight = arguments[0].strokeWeight;
+ this.strokeCap = arguments[0].strokeCap;
+ this.strokeJoin = arguments[0].strokeJoin;
+ this.strokeGradient = arguments[0].strokeGradient;
+ this.strokeGradientPaint = arguments[0].strokeGradientPaint;
+ this.strokeName = arguments[0].strokeName;
+
+ this.fill = arguments[0].fill;
+ this.fillColor = arguments[0].fillColor;
+ this.fillGradient = arguments[0].fillGradient;
+ this.fillGradientPaint = arguments[0].fillGradientPaint;
+ this.fillName = arguments[0].fillName;
+ this.strokeOpacity = arguments[0].strokeOpacity;
+ this.fillOpacity = arguments[0].fillOpacity;
+ this.opacity = arguments[0].opacity;
+ }
+ }
+ }
+
+ this.name = this.element.getStringAttribute("id");
+ var displayStr = this.element.getStringAttribute("display", "inline");
+ this.visible = displayStr !== "none";
+ var str = this.element.getAttribute("transform");
+ if (str) {
+ this.matrix = this.parseMatrix(str);
+ }
+ // not proper parsing of the viewBox, but will cover us for cases where
+ // the width and height of the object is not specified
+ var viewBoxStr = this.element.getStringAttribute("viewBox");
+ if ( viewBoxStr !== null ) {
+ var viewBox = viewBoxStr.split(" ");
+ this.width = viewBox[2];
+ this.height = viewBox[3];
+ }
+
+ // TODO if viewbox is not same as width/height, then use it to scale
+ // the original objects. for now, viewbox only used when width/height
+ // are empty values (which by the spec means w/h of "100%"
+ var unitWidth = this.element.getStringAttribute("width");
+ var unitHeight = this.element.getStringAttribute("height");
+ if (unitWidth !== null) {
+ this.width = this.parseUnitSize(unitWidth);
+ this.height = this.parseUnitSize(unitHeight);
+ } else {
+ if ((this.width === 0) || (this.height === 0)) {
+ // For the spec, the default is 100% and 100%. For purposes
+ // here, insert a dummy value because this is prolly just a
+ // font or something for which the w/h doesn't matter.
+ this.width = 1;
+ this.height = 1;
+
+ //show warning
+ throw("The width and/or height is not " +
+ "readable in the <svg> tag of this file.");
+ }
+ }
+ this.parseColors(this.element);
+ this.parseChildren(this.element);
+
+ };
+ /**
+ * PShapeSVG methods are inherited from the PShape prototype
+ */
+ PShapeSVG.prototype = new PShape();
+ /**
+ * @member PShapeSVG
+ * The parseMatrix() function parses the specified SVG matrix into a PMatrix2D. Note that PMatrix2D
+ * is rotated relative to the SVG definition, so parameters are rearranged
+ * here. More about the transformation matrices in
+ * <a href="http://www.w3.org/TR/SVG/coords.html#TransformAttribute">this section</a>
+ * of the SVG documentation.
+ *
+ * @param {String} str text of the matrix param.
+ *
+ * @return {PMatrix2D} a PMatrix2D
+ */
+ PShapeSVG.prototype.parseMatrix = (function() {
+ function getCoords(s) {
+ var m = [];
+ s.replace(/\((.*?)\)/, (function() {
+ return function(all, params) {
+ // get the coordinates that can be separated by spaces or a comma
+ m = params.replace(/,+/g, " ").split(/\s+/);
+ };
+ }()));
+ return m;
+ }
+
+ return function(str) {
+ this.checkMatrix(2);
+ var pieces = [];
+ str.replace(/\s*(\w+)\((.*?)\)/g, function(all) {
+ // get a list of transform definitions
+ pieces.push(CommonFunctions.trim(all));
+ });
+ if (pieces.length === 0) {
+ return null;
+ }
+
+ for (var i = 0, j = pieces.length; i < j; i++) {
+ var m = getCoords(pieces[i]);
+
+ if (pieces[i].indexOf("matrix") !== -1) {
+ this.matrix.set(m[0], m[2], m[4], m[1], m[3], m[5]);
+ } else if (pieces[i].indexOf("translate") !== -1) {
+ var tx = m[0];
+ var ty = (m.length === 2) ? m[1] : 0;
+ this.matrix.translate(tx,ty);
+ } else if (pieces[i].indexOf("scale") !== -1) {
+ var sx = m[0];
+ var sy = (m.length === 2) ? m[1] : m[0];
+ this.matrix.scale(sx,sy);
+ } else if (pieces[i].indexOf("rotate") !== -1) {
+ var angle = m[0];
+ if (m.length === 1) {
+ this.matrix.rotate(CommonFunctions.radians(angle));
+ } else if (m.length === 3) {
+ this.matrix.translate(m[1], m[2]);
+ this.matrix.rotate(CommonFunctions.radians(m[0]));
+ this.matrix.translate(-m[1], -m[2]);
+ }
+ } else if (pieces[i].indexOf("skewX") !== -1) {
+ this.matrix.skewX(parseFloat(m[0]));
+ } else if (pieces[i].indexOf("skewY") !== -1) {
+ this.matrix.skewY(m[0]);
+ } else if (pieces[i].indexOf("shearX") !== -1) {
+ this.matrix.shearX(m[0]);
+ } else if (pieces[i].indexOf("shearY") !== -1) {
+ this.matrix.shearY(m[0]);
+ }
+ }
+ return this.matrix;
+ };
+ }());
+
+ /**
+ * @member PShapeSVG
+ * The parseChildren() function parses the specified XMLElement
+ *
+ * @param {XMLElement}element the XMLElement to parse
+ */
+ PShapeSVG.prototype.parseChildren = function(element) {
+ var newelement = element.getChildren();
+ var base = new PShape();
+ var i, j;
+ for (i = 0, j = newelement.length; i < j; i++) {
+ var kid = this.parseChild(newelement[i]);
+ if (kid) {
+ base.addChild(kid);
+ }
+ }
+ for (i = 0, j = base.children.length; i < j; i++) {
+ this.children.push(base.children[i]);
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * The getName() function returns the name
+ *
+ * @return {String} the name
+ */
+ PShapeSVG.prototype.getName = function() {
+ return this.name;
+ };
+ /**
+ * @member PShapeSVG
+ * The parseChild() function parses a child XML element.
+ *
+ * @param {XMLElement} elem the element to parse
+ *
+ * @return {PShape} the newly created PShape
+ */
+ PShapeSVG.prototype.parseChild = function( elem ) {
+ var name = elem.getName();
+ var shape;
+ if (name === "g") {
+ shape = new PShapeSVG(this, elem);
+ } else if (name === "defs") {
+ // generally this will contain gradient info, so may
+ // as well just throw it into a group element for parsing
+ shape = new PShapeSVG(this, elem);
+ } else if (name === "line") {
+ shape = new PShapeSVG(this, elem);
+ shape.parseLine();
+ } else if (name === "circle") {
+ shape = new PShapeSVG(this, elem);
+ shape.parseEllipse(true);
+ } else if (name === "ellipse") {
+ shape = new PShapeSVG(this, elem);
+ shape.parseEllipse(false);
+ } else if (name === "rect") {
+ shape = new PShapeSVG(this, elem);
+ shape.parseRect();
+ } else if (name === "polygon") {
+ shape = new PShapeSVG(this, elem);
+ shape.parsePoly(true);
+ } else if (name === "polyline") {
+ shape = new PShapeSVG(this, elem);
+ shape.parsePoly(false);
+ } else if (name === "path") {
+ shape = new PShapeSVG(this, elem);
+ shape.parsePath();
+ } else if (name === "radialGradient") {
+ //return new RadialGradient(this, elem);
+ unimplemented('PShapeSVG.prototype.parseChild, name = radialGradient');
+ } else if (name === "linearGradient") {
+ //return new LinearGradient(this, elem);
+ unimplemented('PShapeSVG.prototype.parseChild, name = linearGradient');
+ } else if (name === "text") {
+ unimplemented('PShapeSVG.prototype.parseChild, name = text');
+ } else if (name === "filter") {
+ unimplemented('PShapeSVG.prototype.parseChild, name = filter');
+ } else if (name === "mask") {
+ unimplemented('PShapeSVG.prototype.parseChild, name = mask');
+ } else {
+ // ignoring
+ }
+ return shape;
+ };
+ /**
+ * @member PShapeSVG
+ * The parsePath() function parses the <path> element of the svg file
+ * A path is defined by including a path element which contains a d="(path data)" attribute, where the d attribute contains
+ * the moveto, line, curve (both cubic and quadratic Beziers), arc and closepath instructions.
+ **/
+ PShapeSVG.prototype.parsePath = function() {
+ this.family = PConstants.PATH;
+ this.kind = 0;
+ var pathDataChars = [];
+ var c;
+ //change multiple spaces and commas to single space
+ var pathData = CommonFunctions.trim(this.element.getStringAttribute("d").replace(/[\s,]+/g,' '));
+ if (pathData === null) {
+ return;
+ }
+ pathData = pathData.split('');
+ var cx = 0,
+ cy = 0,
+ ctrlX = 0,
+ ctrlY = 0,
+ ctrlX1 = 0,
+ ctrlX2 = 0,
+ ctrlY1 = 0,
+ ctrlY2 = 0,
+ endX = 0,
+ endY = 0,
+ ppx = 0,
+ ppy = 0,
+ px = 0,
+ py = 0,
+ i = 0,
+ valOf = 0;
+ var str = "";
+ var tmpArray = [];
+ var flag = false;
+ var lastInstruction;
+ var command;
+ var j, k;
+ while (i< pathData.length) {
+ valOf = pathData[i].charCodeAt(0);
+ if ((valOf >= 65 && valOf <= 90) || (valOf >= 97 && valOf <= 122)) {
+ // if it's a letter
+ // populate the tmpArray with coordinates
+ j = i;
+ i++;
+ if (i < pathData.length) { // don't go over boundary of array
+ tmpArray = [];
+ valOf = pathData[i].charCodeAt(0);
+ while (!((valOf >= 65 && valOf <= 90) ||
+ (valOf >= 97 && valOf <= 100) ||
+ (valOf >= 102 && valOf <= 122)) && flag === false) { // if its NOT a letter
+ if (valOf === 32) { //if its a space and the str isn't empty
+ // sometimes you get a space after the letter
+ if (str !== "") {
+ tmpArray.push(parseFloat(str));
+ str = "";
+ }
+ i++;
+ } else if (valOf === 45) { //if it's a -
+ // allow for 'e' notation in numbers, e.g. 2.10e-9
+ if (pathData[i-1].charCodeAt(0) === 101) {
+ str += pathData[i].toString();
+ i++;
+ } else {
+ // sometimes no space separator after (ex: 104.535-16.322)
+ if (str !== "") {
+ tmpArray.push(parseFloat(str));
+ }
+ str = pathData[i].toString();
+ i++;
+ }
+ } else {
+ str += pathData[i].toString();
+ i++;
+ }
+ if (i === pathData.length) { // don't go over boundary of array
+ flag = true;
+ } else {
+ valOf = pathData[i].charCodeAt(0);
+ }
+ }
+ }
+ if (str !== "") {
+ tmpArray.push(parseFloat(str));
+ str = "";
+ }
+ command = pathData[j];
+ valOf = command.charCodeAt(0);
+ if (valOf === 77) { // M - move to (absolute)
+ if (tmpArray.length >= 2 && tmpArray.length % 2 === 0) {
+ // need one+ pairs of co-ordinates
+ cx = tmpArray[0];
+ cy = tmpArray[1];
+ this.parsePathMoveto(cx, cy);
+ if (tmpArray.length > 2) {
+ for (j = 2, k = tmpArray.length; j < k; j+=2) {
+ // absolute line to
+ cx = tmpArray[j];
+ cy = tmpArray[j+1];
+ this.parsePathLineto(cx,cy);
+ }
+ }
+ }
+ } else if (valOf === 109) { // m - move to (relative)
+ if (tmpArray.length >= 2 && tmpArray.length % 2 === 0) {
+ // need one+ pairs of co-ordinates
+ cx += tmpArray[0];
+ cy += tmpArray[1];
+ this.parsePathMoveto(cx,cy);
+ if (tmpArray.length > 2) {
+ for (j = 2, k = tmpArray.length; j < k; j+=2) {
+ // relative line to
+ cx += tmpArray[j];
+ cy += tmpArray[j + 1];
+ this.parsePathLineto(cx,cy);
+ }
+ }
+ }
+ } else if (valOf === 76) { // L - lineto (absolute)
+ if (tmpArray.length >= 2 && tmpArray.length % 2 === 0) {
+ // need one+ pairs of co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=2) {
+ cx = tmpArray[j];
+ cy = tmpArray[j + 1];
+ this.parsePathLineto(cx,cy);
+ }
+ }
+ } else if (valOf === 108) { // l - lineto (relative)
+ if (tmpArray.length >= 2 && tmpArray.length % 2 === 0) {
+ // need one+ pairs of co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=2) {
+ cx += tmpArray[j];
+ cy += tmpArray[j+1];
+ this.parsePathLineto(cx,cy);
+ }
+ }
+ } else if (valOf === 72) { // H - horizontal lineto (absolute)
+ for (j = 0, k = tmpArray.length; j < k; j++) {
+ // multiple x co-ordinates can be provided
+ cx = tmpArray[j];
+ this.parsePathLineto(cx, cy);
+ }
+ } else if (valOf === 104) { // h - horizontal lineto (relative)
+ for (j = 0, k = tmpArray.length; j < k; j++) {
+ // multiple x co-ordinates can be provided
+ cx += tmpArray[j];
+ this.parsePathLineto(cx, cy);
+ }
+ } else if (valOf === 86) { // V - vertical lineto (absolute)
+ for (j = 0, k = tmpArray.length; j < k; j++) {
+ // multiple y co-ordinates can be provided
+ cy = tmpArray[j];
+ this.parsePathLineto(cx, cy);
+ }
+ } else if (valOf === 118) { // v - vertical lineto (relative)
+ for (j = 0, k = tmpArray.length; j < k; j++) {
+ // multiple y co-ordinates can be provided
+ cy += tmpArray[j];
+ this.parsePathLineto(cx, cy);
+ }
+ } else if (valOf === 67) { // C - curve to (absolute)
+ if (tmpArray.length >= 6 && tmpArray.length % 6 === 0) {
+ // need one+ multiples of 6 co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=6) {
+ ctrlX1 = tmpArray[j];
+ ctrlY1 = tmpArray[j + 1];
+ ctrlX2 = tmpArray[j + 2];
+ ctrlY2 = tmpArray[j + 3];
+ endX = tmpArray[j + 4];
+ endY = tmpArray[j + 5];
+ this.parsePathCurveto(ctrlX1,
+ ctrlY1,
+ ctrlX2,
+ ctrlY2,
+ endX,
+ endY);
+ cx = endX;
+ cy = endY;
+ }
+ }
+ } else if (valOf === 99) { // c - curve to (relative)
+ if (tmpArray.length >= 6 && tmpArray.length % 6 === 0) {
+ // need one+ multiples of 6 co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=6) {
+ ctrlX1 = cx + tmpArray[j];
+ ctrlY1 = cy + tmpArray[j + 1];
+ ctrlX2 = cx + tmpArray[j + 2];
+ ctrlY2 = cy + tmpArray[j + 3];
+ endX = cx + tmpArray[j + 4];
+ endY = cy + tmpArray[j + 5];
+ this.parsePathCurveto(ctrlX1,
+ ctrlY1,
+ ctrlX2,
+ ctrlY2,
+ endX,
+ endY);
+ cx = endX;
+ cy = endY;
+ }
+ }
+ } else if (valOf === 83) { // S - curve to shorthand (absolute)
+ if (tmpArray.length >= 4 && tmpArray.length % 4 === 0) {
+ // need one+ multiples of 4 co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=4) {
+ if (lastInstruction.toLowerCase() === "c" ||
+ lastInstruction.toLowerCase() === "s") {
+ ppx = this.vertices[ this.vertices.length-2 ][0];
+ ppy = this.vertices[ this.vertices.length-2 ][1];
+ px = this.vertices[ this.vertices.length-1 ][0];
+ py = this.vertices[ this.vertices.length-1 ][1];
+ ctrlX1 = px + (px - ppx);
+ ctrlY1 = py + (py - ppy);
+ } else {
+ //If there is no previous curve,
+ //the current point will be used as the first control point.
+ ctrlX1 = this.vertices[this.vertices.length-1][0];
+ ctrlY1 = this.vertices[this.vertices.length-1][1];
+ }
+ ctrlX2 = tmpArray[j];
+ ctrlY2 = tmpArray[j + 1];
+ endX = tmpArray[j + 2];
+ endY = tmpArray[j + 3];
+ this.parsePathCurveto(ctrlX1,
+ ctrlY1,
+ ctrlX2,
+ ctrlY2,
+ endX,
+ endY);
+ cx = endX;
+ cy = endY;
+ }
+ }
+ } else if (valOf === 115) { // s - curve to shorthand (relative)
+ if (tmpArray.length >= 4 && tmpArray.length % 4 === 0) {
+ // need one+ multiples of 4 co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=4) {
+ if (lastInstruction.toLowerCase() === "c" ||
+ lastInstruction.toLowerCase() === "s") {
+ ppx = this.vertices[this.vertices.length-2][0];
+ ppy = this.vertices[this.vertices.length-2][1];
+ px = this.vertices[this.vertices.length-1][0];
+ py = this.vertices[this.vertices.length-1][1];
+ ctrlX1 = px + (px - ppx);
+ ctrlY1 = py + (py - ppy);
+ } else {
+ //If there is no previous curve,
+ //the current point will be used as the first control point.
+ ctrlX1 = this.vertices[this.vertices.length-1][0];
+ ctrlY1 = this.vertices[this.vertices.length-1][1];
+ }
+ ctrlX2 = cx + tmpArray[j];
+ ctrlY2 = cy + tmpArray[j + 1];
+ endX = cx + tmpArray[j + 2];
+ endY = cy + tmpArray[j + 3];
+ this.parsePathCurveto(ctrlX1,
+ ctrlY1,
+ ctrlX2,
+ ctrlY2,
+ endX,
+ endY);
+ cx = endX;
+ cy = endY;
+ }
+ }
+ } else if (valOf === 81) { // Q - quadratic curve to (absolute)
+ if (tmpArray.length >= 4 && tmpArray.length % 4 === 0) {
+ // need one+ multiples of 4 co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=4) {
+ ctrlX = tmpArray[j];
+ ctrlY = tmpArray[j + 1];
+ endX = tmpArray[j + 2];
+ endY = tmpArray[j + 3];
+ this.parsePathQuadto(cx, cy, ctrlX, ctrlY, endX, endY);
+ cx = endX;
+ cy = endY;
+ }
+ }
+ } else if (valOf === 113) { // q - quadratic curve to (relative)
+ if (tmpArray.length >= 4 && tmpArray.length % 4 === 0) {
+ // need one+ multiples of 4 co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=4) {
+ ctrlX = cx + tmpArray[j];
+ ctrlY = cy + tmpArray[j + 1];
+ endX = cx + tmpArray[j + 2];
+ endY = cy + tmpArray[j + 3];
+ this.parsePathQuadto(cx, cy, ctrlX, ctrlY, endX, endY);
+ cx = endX;
+ cy = endY;
+ }
+ }
+ } else if (valOf === 84) {
+ // T - quadratic curve to shorthand (absolute)
+ if (tmpArray.length >= 2 && tmpArray.length % 2 === 0) {
+ // need one+ pairs of co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=2) {
+ if (lastInstruction.toLowerCase() === "q" ||
+ lastInstruction.toLowerCase() === "t") {
+ ppx = this.vertices[this.vertices.length-2][0];
+ ppy = this.vertices[this.vertices.length-2][1];
+ px = this.vertices[this.vertices.length-1][0];
+ py = this.vertices[this.vertices.length-1][1];
+ ctrlX = px + (px - ppx);
+ ctrlY = py + (py - ppy);
+ } else {
+ // If there is no previous command or if the previous command
+ // was not a Q, q, T or t, assume the control point is
+ // coincident with the current point.
+ ctrlX = cx;
+ ctrlY = cy;
+ }
+ endX = tmpArray[j];
+ endY = tmpArray[j + 1];
+ this.parsePathQuadto(cx, cy, ctrlX, ctrlY, endX, endY);
+ cx = endX;
+ cy = endY;
+ }
+ }
+ } else if (valOf === 116) {
+ // t - quadratic curve to shorthand (relative)
+ if (tmpArray.length >= 2 && tmpArray.length % 2 === 0) {
+ // need one+ pairs of co-ordinates
+ for (j = 0, k = tmpArray.length; j < k; j+=2) {
+ if (lastInstruction.toLowerCase() === "q" ||
+ lastInstruction.toLowerCase() === "t") {
+ ppx = this.vertices[this.vertices.length-2][0];
+ ppy = this.vertices[this.vertices.length-2][1];
+ px = this.vertices[this.vertices.length-1][0];
+ py = this.vertices[this.vertices.length-1][1];
+ ctrlX = px + (px - ppx);
+ ctrlY = py + (py - ppy);
+ } else {
+ // If there is no previous command or if the previous command
+ // was not a Q, q, T or t, assume the control point is
+ // coincident with the current point.
+ ctrlX = cx;
+ ctrlY = cy;
+ }
+ endX = cx + tmpArray[j];
+ endY = cy + tmpArray[j + 1];
+ this.parsePathQuadto(cx, cy, ctrlX, ctrlY, endX, endY);
+ cx = endX;
+ cy = endY;
+ }
+ }
+ } else if (valOf === 90 || valOf === 122) { // Z or z (these do the same thing)
+ this.close = true;
+ }
+ lastInstruction = command.toString();
+ } else { i++;}
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parsePath() helper function
+ *
+ * @see PShapeSVG#parsePath
+ */
+ PShapeSVG.prototype.parsePathQuadto = function(x1, y1, cx, cy, x2, y2) {
+ if (this.vertices.length > 0) {
+ this.parsePathCode(PConstants.BEZIER_VERTEX);
+ // x1/y1 already covered by last moveto, lineto, or curveto
+ this.parsePathVertex(x1 + ((cx-x1)*2/3), y1 + ((cy-y1)*2/3));
+ this.parsePathVertex(x2 + ((cx-x2)*2/3), y2 + ((cy-y2)*2/3));
+ this.parsePathVertex(x2, y2);
+ } else {
+ throw ("Path must start with M/m");
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parsePath() helper function
+ *
+ * @see PShapeSVG#parsePath
+ */
+ PShapeSVG.prototype.parsePathCurveto = function(x1, y1, x2, y2, x3, y3) {
+ if (this.vertices.length > 0) {
+ this.parsePathCode(PConstants.BEZIER_VERTEX );
+ this.parsePathVertex(x1, y1);
+ this.parsePathVertex(x2, y2);
+ this.parsePathVertex(x3, y3);
+ } else {
+ throw ("Path must start with M/m");
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parsePath() helper function
+ *
+ * @see PShapeSVG#parsePath
+ */
+ PShapeSVG.prototype.parsePathLineto = function(px, py) {
+ if (this.vertices.length > 0) {
+ this.parsePathCode(PConstants.VERTEX);
+ this.parsePathVertex(px, py);
+ // add property to distinguish between curContext.moveTo
+ // or curContext.lineTo
+ this.vertices[this.vertices.length-1].moveTo = false;
+ } else {
+ throw ("Path must start with M/m");
+ }
+ };
+
+ PShapeSVG.prototype.parsePathMoveto = function(px, py) {
+ if (this.vertices.length > 0) {
+ this.parsePathCode(PConstants.BREAK);
+ }
+ this.parsePathCode(PConstants.VERTEX);
+ this.parsePathVertex(px, py);
+ // add property to distinguish between curContext.moveTo
+ // or curContext.lineTo
+ this.vertices[this.vertices.length-1].moveTo = true;
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parsePath() helper function
+ *
+ * @see PShapeSVG#parsePath
+ */
+ PShapeSVG.prototype.parsePathVertex = function(x, y) {
+ var verts = [];
+ verts[0] = x;
+ verts[1] = y;
+ this.vertices.push(verts);
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parsePath() helper function
+ *
+ * @see PShapeSVG#parsePath
+ */
+ PShapeSVG.prototype.parsePathCode = function(what) {
+ this.vertexCodes.push(what);
+ };
+ /**
+ * @member PShapeSVG
+ * The parsePoly() function parses a polyline or polygon from an SVG file.
+ *
+ * @param {boolean}val true if shape is closed (polygon), false if not (polyline)
+ */
+ PShapeSVG.prototype.parsePoly = function(val) {
+ this.family = PConstants.PATH;
+ this.close = val;
+ var pointsAttr = CommonFunctions.trim(this.element.getStringAttribute("points").replace(/[,\s]+/g,' '));
+ if (pointsAttr !== null) {
+ //split into array
+ var pointsBuffer = pointsAttr.split(" ");
+ if (pointsBuffer.length % 2 === 0) {
+ for (var i = 0, j = pointsBuffer.length; i < j; i++) {
+ var verts = [];
+ verts[0] = pointsBuffer[i];
+ verts[1] = pointsBuffer[++i];
+ this.vertices.push(verts);
+ }
+ } else {
+ throw("Error parsing polygon points: odd number of coordinates provided");
+ }
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * The parseRect() function parses a rect from an SVG file.
+ */
+ PShapeSVG.prototype.parseRect = function() {
+ this.kind = PConstants.RECT;
+ this.family = PConstants.PRIMITIVE;
+ this.params = [];
+ this.params[0] = this.element.getFloatAttribute("x");
+ this.params[1] = this.element.getFloatAttribute("y");
+ this.params[2] = this.element.getFloatAttribute("width");
+ this.params[3] = this.element.getFloatAttribute("height");
+ if (this.params[2] < 0 || this.params[3] < 0) {
+ throw("svg error: negative width or height found while parsing <rect>");
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * The parseEllipse() function handles parsing ellipse and circle tags.
+ *
+ * @param {boolean}val true if this is a circle and not an ellipse
+ */
+ PShapeSVG.prototype.parseEllipse = function(val) {
+ this.kind = PConstants.ELLIPSE;
+ this.family = PConstants.PRIMITIVE;
+ this.params = [];
+
+ this.params[0] = this.element.getFloatAttribute("cx") | 0 ;
+ this.params[1] = this.element.getFloatAttribute("cy") | 0;
+
+ var rx, ry;
+ if (val) {
+ rx = ry = this.element.getFloatAttribute("r");
+ if (rx < 0) {
+ throw("svg error: negative radius found while parsing <circle>");
+ }
+ } else {
+ rx = this.element.getFloatAttribute("rx");
+ ry = this.element.getFloatAttribute("ry");
+ if (rx < 0 || ry < 0) {
+ throw("svg error: negative x-axis radius or y-axis radius found while parsing <ellipse>");
+ }
+ }
+ this.params[0] -= rx;
+ this.params[1] -= ry;
+
+ this.params[2] = rx*2;
+ this.params[3] = ry*2;
+ };
+ /**
+ * @member PShapeSVG
+ * The parseLine() function handles parsing line tags.
+ *
+ * @param {boolean}val true if this is a circle and not an ellipse
+ */
+ PShapeSVG.prototype.parseLine = function() {
+ this.kind = PConstants.LINE;
+ this.family = PConstants.PRIMITIVE;
+ this.params = [];
+ this.params[0] = this.element.getFloatAttribute("x1");
+ this.params[1] = this.element.getFloatAttribute("y1");
+ this.params[2] = this.element.getFloatAttribute("x2");
+ this.params[3] = this.element.getFloatAttribute("y2");
+ };
+ /**
+ * @member PShapeSVG
+ * The parseColors() function handles parsing the opacity, strijem stroke-width, stroke-linejoin,stroke-linecap, fill, and style attributes
+ *
+ * @param {XMLElement}element the element of which attributes to parse
+ */
+ PShapeSVG.prototype.parseColors = function(element) {
+ if (element.hasAttribute("opacity")) {
+ this.setOpacity(element.getAttribute("opacity"));
+ }
+ if (element.hasAttribute("stroke")) {
+ this.setStroke(element.getAttribute("stroke"));
+ }
+ if (element.hasAttribute("stroke-width")) {
+ // if NaN (i.e. if it's 'inherit') then default
+ // back to the inherit setting
+ this.setStrokeWeight(element.getAttribute("stroke-width"));
+ }
+ if (element.hasAttribute("stroke-linejoin") ) {
+ this.setStrokeJoin(element.getAttribute("stroke-linejoin"));
+ }
+ if (element.hasAttribute("stroke-linecap")) {
+ this.setStrokeCap(element.getStringAttribute("stroke-linecap"));
+ }
+ // fill defaults to black (though stroke defaults to "none")
+ // http://www.w3.org/TR/SVG/painting.html#FillProperties
+ if (element.hasAttribute("fill")) {
+ this.setFill(element.getStringAttribute("fill"));
+ }
+ if (element.hasAttribute("style")) {
+ var styleText = element.getStringAttribute("style");
+ var styleTokens = styleText.toString().split( ";" );
+
+ for (var i = 0, j = styleTokens.length; i < j; i++) {
+ var tokens = CommonFunctions.trim(styleTokens[i].split( ":" ));
+ if (tokens[0] === "fill") {
+ this.setFill(tokens[1]);
+ } else if (tokens[0] === "fill-opacity") {
+ this.setFillOpacity(tokens[1]);
+ } else if (tokens[0] === "stroke") {
+ this.setStroke(tokens[1]);
+ } else if (tokens[0] === "stroke-width") {
+ this.setStrokeWeight(tokens[1]);
+ } else if (tokens[0] === "stroke-linecap") {
+ this.setStrokeCap(tokens[1]);
+ } else if (tokens[0] === "stroke-linejoin") {
+ this.setStrokeJoin(tokens[1]);
+ } else if (tokens[0] === "stroke-opacity") {
+ this.setStrokeOpacity(tokens[1]);
+ } else if (tokens[0] === "opacity") {
+ this.setOpacity(tokens[1]);
+ } // Other attributes are not yet implemented
+ }
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parseColors() helper function
+ *
+ * @param {String} opacityText the value of fillOpacity
+ *
+ * @see PShapeSVG#parseColors
+ */
+ PShapeSVG.prototype.setFillOpacity = function(opacityText) {
+ this.fillOpacity = parseFloat(opacityText);
+ this.fillColor = this.fillOpacity * 255 << 24 |
+ this.fillColor & 0xFFFFFF;
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parseColors() helper function
+ *
+ * @param {String} fillText the value of fill
+ *
+ * @see PShapeSVG#parseColors
+ */
+ PShapeSVG.prototype.setFill = function (fillText) {
+ var opacityMask = this.fillColor & 0xFF000000;
+ if (fillText === "none") {
+ this.fill = false;
+ } else if (fillText.indexOf("#") === 0) {
+ this.fill = true;
+ if (fillText.length === 4) {
+ // convert #00F to #0000FF
+ fillText = fillText.replace(/#(.)(.)(.)/,"#$1$1$2$2$3$3");
+ }
+ this.fillColor = opacityMask |
+ (parseInt(fillText.substring(1), 16 )) &
+ 0xFFFFFF;
+ } else if (fillText.indexOf("rgb") === 0) {
+ this.fill = true;
+ this.fillColor = opacityMask | this.parseRGB(fillText);
+ } else if (fillText.indexOf("url(#") === 0) {
+ this.fillName = fillText.substring(5, fillText.length - 1 );
+ } else if (colors[fillText]) {
+ this.fill = true;
+ this.fillColor = opacityMask |
+ (parseInt(colors[fillText].substring(1), 16)) &
+ 0xFFFFFF;
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parseColors() helper function
+ *
+ * @param {String} opacity the value of opacity
+ *
+ * @see PShapeSVG#parseColors
+ */
+ PShapeSVG.prototype.setOpacity = function(opacity) {
+ this.strokeColor = parseFloat(opacity) * 255 << 24 |
+ this.strokeColor & 0xFFFFFF;
+ this.fillColor = parseFloat(opacity) * 255 << 24 |
+ this.fillColor & 0xFFFFFF;
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parseColors() helper function
+ *
+ * @param {String} strokeText the value to set stroke to
+ *
+ * @see PShapeSVG#parseColors
+ */
+ PShapeSVG.prototype.setStroke = function(strokeText) {
+ var opacityMask = this.strokeColor & 0xFF000000;
+ if (strokeText === "none") {
+ this.stroke = false;
+ } else if (strokeText.charAt( 0 ) === "#") {
+ this.stroke = true;
+ if (strokeText.length === 4) {
+ // convert #00F to #0000FF
+ strokeText = strokeText.replace(/#(.)(.)(.)/,"#$1$1$2$2$3$3");
+ }
+ this.strokeColor = opacityMask |
+ (parseInt( strokeText.substring( 1 ), 16 )) &
+ 0xFFFFFF;
+ } else if (strokeText.indexOf( "rgb" ) === 0 ) {
+ this.stroke = true;
+ this.strokeColor = opacityMask | this.parseRGB(strokeText);
+ } else if (strokeText.indexOf( "url(#" ) === 0) {
+ this.strokeName = strokeText.substring(5, strokeText.length - 1);
+ } else if (colors[strokeText]) {
+ this.stroke = true;
+ this.strokeColor = opacityMask |
+ (parseInt(colors[strokeText].substring(1), 16)) &
+ 0xFFFFFF;
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parseColors() helper function
+ *
+ * @param {String} weight the value to set strokeWeight to
+ *
+ * @see PShapeSVG#parseColors
+ */
+ PShapeSVG.prototype.setStrokeWeight = function(weight) {
+ this.strokeWeight = this.parseUnitSize(weight);
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parseColors() helper function
+ *
+ * @param {String} linejoin the value to set strokeJoin to
+ *
+ * @see PShapeSVG#parseColors
+ */
+ PShapeSVG.prototype.setStrokeJoin = function(linejoin) {
+ if (linejoin === "miter") {
+ this.strokeJoin = PConstants.MITER;
+
+ } else if (linejoin === "round") {
+ this.strokeJoin = PConstants.ROUND;
+
+ } else if (linejoin === "bevel") {
+ this.strokeJoin = PConstants.BEVEL;
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parseColors() helper function
+ *
+ * @param {String} linecap the value to set strokeCap to
+ *
+ * @see PShapeSVG#parseColors
+ */
+ PShapeSVG.prototype.setStrokeCap = function (linecap) {
+ if (linecap === "butt") {
+ this.strokeCap = PConstants.SQUARE;
+
+ } else if (linecap === "round") {
+ this.strokeCap = PConstants.ROUND;
+
+ } else if (linecap === "square") {
+ this.strokeCap = PConstants.PROJECT;
+ }
+ };
+ /**
+ * @member PShapeSVG
+ * PShapeSVG.parseColors() helper function
+ *
+ * @param {String} opacityText the value to set stroke opacity to
+ *
+ * @see PShapeSVG#parseColors
+ */
+ PShapeSVG.prototype.setStrokeOpacity = function (opacityText) {
+ this.strokeOpacity = parseFloat(opacityText);
+ this.strokeColor = this.strokeOpacity * 255 << 24 |
+ this.strokeColor &
+ 0xFFFFFF;
+ };
+ /**
+ * @member PShapeSVG
+ * The parseRGB() function parses an rbg() color string and returns a color int
+ *
+ * @param {String} color the color to parse in rbg() format
+ *
+ * @return {int} the equivalent color int
+ */
+ PShapeSVG.prototype.parseRGB = function(color) {
+ var sub = color.substring(color.indexOf('(') + 1, color.indexOf(')'));
+ var values = sub.split(", ");
+ return (values[0] << 16) | (values[1] << 8) | (values[2]);
+ };
+ /**
+ * @member PShapeSVG
+ * The parseUnitSize() function parse a size that may have a suffix for its units.
+ * Ignoring cases where this could also be a percentage.
+ * The <A HREF="http://www.w3.org/TR/SVG/coords.html#Units">units</A> spec:
+ * <UL>
+ * <LI>"1pt" equals "1.25px" (and therefore 1.25 user units)
+ * <LI>"1pc" equals "15px" (and therefore 15 user units)
+ * <LI>"1mm" would be "3.543307px" (3.543307 user units)
+ * <LI>"1cm" equals "35.43307px" (and therefore 35.43307 user units)
+ * <LI>"1in" equals "90px" (and therefore 90 user units)
+ * </UL>
+ */
+ PShapeSVG.prototype.parseUnitSize = function (text) {
+ var len = text.length - 2;
+ if (len < 0) { return text; }
+ if (text.indexOf("pt") === len) {
+ return parseFloat(text.substring(0, len)) * 1.25;
+ }
+ if (text.indexOf("pc") === len) {
+ return parseFloat( text.substring( 0, len)) * 15;
+ }
+ if (text.indexOf("mm") === len) {
+ return parseFloat( text.substring(0, len)) * 3.543307;
+ }
+ if (text.indexOf("cm") === len) {
+ return parseFloat(text.substring(0, len)) * 35.43307;
+ }
+ if (text.indexOf("in") === len) {
+ return parseFloat(text.substring(0, len)) * 90;
+ }
+ if (text.indexOf("px") === len) {
+ return parseFloat(text.substring(0, len));
+ }
+ return parseFloat(text);
+ };
+
+ return PShapeSVG;
+};
+
+},{}],18:[function(require,module,exports){
+module.exports = function(options, undef) {
+ var PConstants = options.PConstants;
+
+ function PVector(x, y, z) {
+ this.x = x || 0;
+ this.y = y || 0;
+ this.z = z || 0;
+ }
+
+ PVector.fromAngle = function(angle, v) {
+ if (v === undef || v === null) {
+ v = new PVector();
+ }
+ v.x = Math.cos(angle);
+ v.y = Math.sin(angle);
+ return v;
+ };
+
+ PVector.random2D = function(v) {
+ return PVector.fromAngle(Math.random() * PConstants.TWO_PI, v);
+ };
+
+ PVector.random3D = function(v) {
+ var angle = Math.random() * PConstants.TWO_PI;
+ var vz = Math.random() * 2 - 1;
+ var mult = Math.sqrt(1 - vz * vz);
+ var vx = mult * Math.cos(angle);
+ var vy = mult * Math.sin(angle);
+ if (v === undef || v === null) {
+ v = new PVector(vx, vy, vz);
+ } else {
+ v.set(vx, vy, vz);
+ }
+ return v;
+ };
+
+ PVector.dist = function(v1, v2) {
+ return v1.dist(v2);
+ };
+
+ PVector.dot = function(v1, v2) {
+ return v1.dot(v2);
+ };
+
+ PVector.cross = function(v1, v2) {
+ return v1.cross(v2);
+ };
+
+ PVector.sub = function(v1, v2) {
+ return new PVector(v1.x - v2.x, v1.y - v2.y, v1.z - v2.z);
+ };
+
+ PVector.angleBetween = function(v1, v2) {
+ return Math.acos(v1.dot(v2) / Math.sqrt(v1.magSq() * v2.magSq()));
+ };
+
+ PVector.lerp = function(v1, v2, amt) {
+ // non-static lerp mutates object, but this version returns a new vector
+ var retval = new PVector(v1.x, v1.y, v1.z);
+ retval.lerp(v2, amt);
+ return retval;
+ };
+
+ // Common vector operations for PVector
+ PVector.prototype = {
+ set: function(v, y, z) {
+ if (arguments.length === 1) {
+ this.set(v.x || v[0] || 0,
+ v.y || v[1] || 0,
+ v.z || v[2] || 0);
+ } else {
+ this.x = v;
+ this.y = y;
+ this.z = z;
+ }
+ },
+ get: function() {
+ return new PVector(this.x, this.y, this.z);
+ },
+ mag: function() {
+ var x = this.x,
+ y = this.y,
+ z = this.z;
+ return Math.sqrt(x * x + y * y + z * z);
+ },
+ magSq: function() {
+ var x = this.x,
+ y = this.y,
+ z = this.z;
+ return (x * x + y * y + z * z);
+ },
+ setMag: function(v_or_len, len) {
+ if (len === undef) {
+ len = v_or_len;
+ this.normalize();
+ this.mult(len);
+ } else {
+ var v = v_or_len;
+ v.normalize();
+ v.mult(len);
+ return v;
+ }
+ },
+ add: function(v, y, z) {
+ if (arguments.length === 1) {
+ this.x += v.x;
+ this.y += v.y;
+ this.z += v.z;
+ } else if (arguments.length === 2) {
+ // 2D Vector
+ this.x += v;
+ this.y += y;
+ } else {
+ this.x += v;
+ this.y += y;
+ this.z += z;
+ }
+ },
+ sub: function(v, y, z) {
+ if (arguments.length === 1) {
+ this.x -= v.x;
+ this.y -= v.y;
+ this.z -= v.z;
+ } else if (arguments.length === 2) {
+ // 2D Vector
+ this.x -= v;
+ this.y -= y;
+ } else {
+ this.x -= v;
+ this.y -= y;
+ this.z -= z;
+ }
+ },
+ mult: function(v) {
+ if (typeof v === 'number') {
+ this.x *= v;
+ this.y *= v;
+ this.z *= v;
+ } else {
+ this.x *= v.x;
+ this.y *= v.y;
+ this.z *= v.z;
+ }
+ },
+ div: function(v) {
+ if (typeof v === 'number') {
+ this.x /= v;
+ this.y /= v;
+ this.z /= v;
+ } else {
+ this.x /= v.x;
+ this.y /= v.y;
+ this.z /= v.z;
+ }
+ },
+ rotate: function(angle) {
+ var prev_x = this.x;
+ var c = Math.cos(angle);
+ var s = Math.sin(angle);
+ this.x = c * this.x - s * this.y;
+ this.y = s * prev_x + c * this.y;
+ },
+ dist: function(v) {
+ var dx = this.x - v.x,
+ dy = this.y - v.y,
+ dz = this.z - v.z;
+ return Math.sqrt(dx * dx + dy * dy + dz * dz);
+ },
+ dot: function(v, y, z) {
+ if (arguments.length === 1) {
+ return (this.x * v.x + this.y * v.y + this.z * v.z);
+ }
+ return (this.x * v + this.y * y + this.z * z);
+ },
+ cross: function(v) {
+ var x = this.x,
+ y = this.y,
+ z = this.z;
+ return new PVector(y * v.z - v.y * z,
+ z * v.x - v.z * x,
+ x * v.y - v.x * y);
+ },
+ lerp: function(v_or_x, amt_or_y, z, amt) {
+ var lerp_val = function(start, stop, amt) {
+ return start + (stop - start) * amt;
+ };
+ var x, y;
+ if (arguments.length === 2) {
+ // given vector and amt
+ amt = amt_or_y;
+ x = v_or_x.x;
+ y = v_or_x.y;
+ z = v_or_x.z;
+ } else {
+ // given x, y, z and amt
+ x = v_or_x;
+ y = amt_or_y;
+ }
+ this.x = lerp_val(this.x, x, amt);
+ this.y = lerp_val(this.y, y, amt);
+ this.z = lerp_val(this.z, z, amt);
+ },
+ normalize: function() {
+ var m = this.mag();
+ if (m > 0) {
+ this.div(m);
+ }
+ },
+ limit: function(high) {
+ if (this.mag() > high) {
+ this.normalize();
+ this.mult(high);
+ }
+ },
+ heading: function() {
+ return (-Math.atan2(-this.y, this.x));
+ },
+ heading2D: function() {
+ return this.heading();
+ },
+ toString: function() {
+ return "[" + this.x + ", " + this.y + ", " + this.z + "]";
+ },
+ array: function() {
+ return [this.x, this.y, this.z];
+ }
+ };
+
+ function createPVectorMethod(method) {
+ return function(v1, v2) {
+ var v = v1.get();
+ v[method](v2);
+ return v;
+ };
+ }
+
+ for (var method in PVector.prototype) {
+ if (PVector.prototype.hasOwnProperty(method) && !PVector.hasOwnProperty(method)) {
+ PVector[method] = createPVectorMethod(method);
+ }
+ }
+
+ return PVector;
+};
+
+},{}],19:[function(require,module,exports){
+/**
+ * XMLAttribute is an attribute of a XML element.
+ *
+ * @param {String} fname the full name of the attribute
+ * @param {String} n the short name of the attribute
+ * @param {String} namespace the namespace URI of the attribute
+ * @param {String} v the value of the attribute
+ * @param {String }t the type of the attribute
+ *
+ * @see XMLElement
+ */
+module.exports = function() {
+
+ var XMLAttribute = function (fname, n, nameSpace, v, t){
+ this.fullName = fname || "";
+ this.name = n || "";
+ this.namespace = nameSpace || "";
+ this.value = v;
+ this.type = t;
+ };
+
+ XMLAttribute.prototype = {
+ /**
+ * @member XMLAttribute
+ * The getName() function returns the short name of the attribute
+ *
+ * @return {String} the short name of the attribute
+ */
+ getName: function() {
+ return this.name;
+ },
+ /**
+ * @member XMLAttribute
+ * The getFullName() function returns the full name of the attribute
+ *
+ * @return {String} the full name of the attribute
+ */
+ getFullName: function() {
+ return this.fullName;
+ },
+ /**
+ * @member XMLAttribute
+ * The getNamespace() function returns the namespace of the attribute
+ *
+ * @return {String} the namespace of the attribute
+ */
+ getNamespace: function() {
+ return this.namespace;
+ },
+ /**
+ * @member XMLAttribute
+ * The getValue() function returns the value of the attribute
+ *
+ * @return {String} the value of the attribute
+ */
+ getValue: function() {
+ return this.value;
+ },
+ /**
+ * @member XMLAttribute
+ * The getValue() function returns the type of the attribute
+ *
+ * @return {String} the type of the attribute
+ */
+ getType: function() {
+ return this.type;
+ },
+ /**
+ * @member XMLAttribute
+ * The setValue() function sets the value of the attribute
+ *
+ * @param {String} newval the new value
+ */
+ setValue: function(newval) {
+ this.value = newval;
+ }
+ };
+
+ return XMLAttribute;
+};
+
+},{}],20:[function(require,module,exports){
+/**
+ * XMLElement is a representation of an XML object. The object is able to parse XML code
+ *
+ * @param {PApplet} parent typically use "this"
+ * @param {String} filename name of the XML/SVG file to load
+ * @param {String} xml the xml/svg string
+ * @param {String} fullname the full name of the element
+ * @param {String} namespace the namespace of the URI
+ * @param {String} systemID the system ID of the XML data where the element starts
+ * @param {Integer }lineNr the line in the XML data where the element starts
+ */
+module.exports = function(options, undef) {
+
+ var Browser = options.Browser,
+ ajax = Browser.ajax,
+ window = Browser.window,
+ XMLHttpRequest = window.XMLHttpRequest,
+ DOMParser = window.DOMParser,
+ XMLAttribute = options. XMLAttribute;
+
+ var XMLElement = function(selector, uri, sysid, line) {
+ this.attributes = [];
+ this.children = [];
+ this.fullName = null;
+ this.name = null;
+ this.namespace = "";
+ this.content = null;
+ this.parent = null;
+ this.lineNr = "";
+ this.systemID = "";
+ this.type = "ELEMENT";
+
+ if (selector) {
+ if (typeof selector === "string") {
+ if (uri === undef && selector.indexOf("<") > -1) {
+ // load XML from text string
+ this.parse(selector);
+ } else {
+ // XMLElement(fullname, namespace, sysid, line) format
+ this.fullName = selector;
+ this.namespace = uri;
+ this.systemId = sysid;
+ this.lineNr = line;
+ }
+ } else {
+ // XMLElement(this, file uri) format
+ this.parse(uri, true);
+ }
+ }
+ };
+ /**
+ * XMLElement methods
+ * missing: enumerateAttributeNames(), enumerateChildren(),
+ * NOTE: parse does not work when a url is passed in
+ */
+ XMLElement.prototype = {
+ /**
+ * @member XMLElement
+ * The parse() function retrieves the file via ajax() and uses DOMParser()
+ * parseFromString method to make an XML document
+ * @addon
+ *
+ * @param {String} filename name of the XML/SVG file to load
+ *
+ * @throws ExceptionType Error loading document
+ *
+ * @see XMLElement#parseChildrenRecursive
+ */
+ parse: function(textstring, stringIsURI) {
+ var xmlDoc;
+ try {
+ if (stringIsURI) {
+ textstring = ajax(textstring);
+ }
+ xmlDoc = new DOMParser().parseFromString(textstring, "text/xml");
+ var elements = xmlDoc.documentElement;
+ if (elements) {
+ this.parseChildrenRecursive(null, elements);
+ } else {
+ throw ("Error loading document");
+ }
+ return this;
+ } catch(e) {
+ throw(e);
+ }
+ },
+ /**
+ * @member XMLElement
+ * Internal helper function for parse().
+ * Loops through the
+ * @addon
+ *
+ * @param {XMLElement} parent the parent node
+ * @param {XML document childNodes} elementpath the remaining nodes that need parsing
+ *
+ * @return {XMLElement} the new element and its children elements
+ */
+ parseChildrenRecursive: function (parent, elementpath){
+ var xmlelement,
+ xmlattribute,
+ tmpattrib,
+ l, m,
+ child;
+ if (!parent) { // this element is the root element
+ this.fullName = elementpath.localName;
+ this.name = elementpath.nodeName;
+ xmlelement = this;
+ } else { // this element has a parent
+ xmlelement = new XMLElement(elementpath.nodeName);
+ xmlelement.parent = parent;
+ }
+
+ // if this is a text node, return a PCData element (parsed character data)
+ if (elementpath.nodeType === 3 && elementpath.textContent !== "") {
+ return this.createPCDataElement(elementpath.textContent);
+ }
+
+ // if this is a CDATA node, return a CData element (unparsed character data)
+ if (elementpath.nodeType === 4) {
+ return this.createCDataElement(elementpath.textContent);
+ }
+
+ // bind all attributes, if there are any
+ if (elementpath.attributes) {
+ for (l = 0, m = elementpath.attributes.length; l < m; l++) {
+ tmpattrib = elementpath.attributes[l];
+ xmlattribute = new XMLAttribute(tmpattrib.getname,
+ tmpattrib.nodeName,
+ tmpattrib.namespaceURI,
+ tmpattrib.nodeValue,
+ tmpattrib.nodeType);
+ xmlelement.attributes.push(xmlattribute);
+ }
+ }
+
+ // bind all children, if there are any
+ if (elementpath.childNodes) {
+ for (l = 0, m = elementpath.childNodes.length; l < m; l++) {
+ var node = elementpath.childNodes[l];
+ child = xmlelement.parseChildrenRecursive(xmlelement, node);
+ if (child !== null) {
+ xmlelement.children.push(child);
+ }
+ }
+ }
+
+ return xmlelement;
+ },
+ /**
+ * @member XMLElement
+ * The createElement() function Creates an empty element
+ *
+ * @param {String} fullName the full name of the element
+ * @param {String} namespace the namespace URI
+ * @param {String} systemID the system ID of the XML data where the element starts
+ * @param {int} lineNr the line in the XML data where the element starts
+ */
+ createElement: function (fullname, namespaceuri, sysid, line) {
+ if (sysid === undef) {
+ return new XMLElement(fullname, namespaceuri);
+ }
+ return new XMLElement(fullname, namespaceuri, sysid, line);
+ },
+ /**
+ * @member XMLElement
+ * The createPCDataElement() function creates an element to be used for #PCDATA content.
+ * Because Processing discards whitespace TEXT nodes, this method will not build an element
+ * if the passed content is empty after trimming for whitespace.
+ *
+ * @return {XMLElement} new "pcdata" XMLElement, or null if content consists only of whitespace
+ */
+ createPCDataElement: function (content, isCDATA) {
+ if (content.replace(/^\s+$/g,"") === "") {
+ return null;
+ }
+ var pcdata = new XMLElement();
+ pcdata.type = "TEXT";
+ pcdata.content = content;
+ return pcdata;
+ },
+ /**
+ * @member XMLElement
+ * The createCDataElement() function creates an element to be used for CDATA content.
+ *
+ * @return {XMLElement} new "cdata" XMLElement, or null if content consists only of whitespace
+ */
+ createCDataElement: function (content) {
+ var cdata = this.createPCDataElement(content);
+ if (cdata === null) {
+ return null;
+ }
+
+ cdata.type = "CDATA";
+ var htmlentities = {"<": "&lt;", ">": "&gt;", "'": "&apos;", '"': "&quot;"},
+ entity;
+ for (entity in htmlentities) {
+ if (!Object.hasOwnProperty(htmlentities,entity)) {
+ content = content.replace(new RegExp(entity, "g"), htmlentities[entity]);
+ }
+ }
+ cdata.cdata = content;
+ return cdata;
+ },
+ /**
+ * @member XMLElement
+ * The hasAttribute() function returns whether an attribute exists
+ *
+ * @param {String} name name of the attribute
+ * @param {String} namespace the namespace URI of the attribute
+ *
+ * @return {boolean} true if the attribute exists
+ */
+ hasAttribute: function () {
+ if (arguments.length === 1) {
+ return this.getAttribute(arguments[0]) !== null;
+ }
+ if (arguments.length === 2) {
+ return this.getAttribute(arguments[0],arguments[1]) !== null;
+ }
+ },
+ /**
+ * @member XMLElement
+ * The equals() function checks to see if the XMLElement being passed in equals another XMLElement
+ *
+ * @param {XMLElement} rawElement the element to compare to
+ *
+ * @return {boolean} true if the element equals another element
+ */
+ equals: function(other) {
+ if (!(other instanceof XMLElement)) {
+ return false;
+ }
+ var i, j;
+ if (this.fullName !== other.fullName) { return false; }
+ if (this.attributes.length !== other.getAttributeCount()) { return false; }
+ // attributes may be ordered differently
+ if (this.attributes.length !== other.attributes.length) { return false; }
+ var attr_name, attr_ns, attr_value, attr_type, attr_other;
+ for (i = 0, j = this.attributes.length; i < j; i++) {
+ attr_name = this.attributes[i].getName();
+ attr_ns = this.attributes[i].getNamespace();
+ attr_other = other.findAttribute(attr_name, attr_ns);
+ if (attr_other === null) { return false; }
+ if (this.attributes[i].getValue() !== attr_other.getValue()) { return false; }
+ if (this.attributes[i].getType() !== attr_other.getType()) { return false; }
+ }
+ // children must be ordered identically
+ if (this.children.length !== other.getChildCount()) { return false; }
+ if (this.children.length>0) {
+ var child1, child2;
+ for (i = 0, j = this.children.length; i < j; i++) {
+ child1 = this.getChild(i);
+ child2 = other.getChild(i);
+ if (!child1.equals(child2)) { return false; }
+ }
+ return true;
+ }
+ return (this.content === other.content);
+ },
+ /**
+ * @member XMLElement
+ * The getContent() function returns the content of an element. If there is no such content, null is returned
+ *
+ * @return {String} the (possibly null) content
+ */
+ getContent: function(){
+ if (this.type === "TEXT" || this.type === "CDATA") {
+ return this.content;
+ }
+ var children = this.children;
+ if (children.length === 1 && (children[0].type === "TEXT" || children[0].type === "CDATA")) {
+ return children[0].content;
+ }
+ return null;
+ },
+ /**
+ * @member XMLElement
+ * The getAttribute() function returns the value of an attribute
+ *
+ * @param {String} name the non-null full name of the attribute
+ * @param {String} namespace the namespace URI, which may be null
+ * @param {String} defaultValue the default value of the attribute
+ *
+ * @return {String} the value, or defaultValue if the attribute does not exist
+ */
+ getAttribute: function (){
+ var attribute;
+ if (arguments.length === 2) {
+ attribute = this.findAttribute(arguments[0]);
+ if (attribute) {
+ return attribute.getValue();
+ }
+ return arguments[1];
+ } else if (arguments.length === 1) {
+ attribute = this.findAttribute(arguments[0]);
+ if (attribute) {
+ return attribute.getValue();
+ }
+ return null;
+ } else if (arguments.length === 3) {
+ attribute = this.findAttribute(arguments[0],arguments[1]);
+ if (attribute) {
+ return attribute.getValue();
+ }
+ return arguments[2];
+ }
+ },
+ /**
+ * @member XMLElement
+ * The getStringAttribute() function returns the string attribute of the element
+ * If the <b>defaultValue</b> parameter is used and the attribute doesn't exist, the <b>defaultValue</b> value is returned.
+ * When calling the function without the <b>defaultValue</b> parameter, if the attribute doesn't exist, the value 0 is returned.
+ *
+ * @param name the name of the attribute
+ * @param defaultValue value returned if the attribute is not found
+ *
+ * @return {String} the value, or defaultValue if the attribute does not exist
+ */
+ getStringAttribute: function() {
+ if (arguments.length === 1) {
+ return this.getAttribute(arguments[0]);
+ }
+ if (arguments.length === 2) {
+ return this.getAttribute(arguments[0], arguments[1]);
+ }
+ return this.getAttribute(arguments[0], arguments[1],arguments[2]);
+ },
+ /**
+ * Processing 1.5 XML API wrapper for the generic String
+ * attribute getter. This may only take one argument.
+ */
+ getString: function(attributeName) {
+ return this.getStringAttribute(attributeName);
+ },
+ /**
+ * @member XMLElement
+ * The getFloatAttribute() function returns the float attribute of the element.
+ * If the <b>defaultValue</b> parameter is used and the attribute doesn't exist, the <b>defaultValue</b> value is returned.
+ * When calling the function without the <b>defaultValue</b> parameter, if the attribute doesn't exist, the value 0 is returned.
+ *
+ * @param name the name of the attribute
+ * @param defaultValue value returned if the attribute is not found
+ *
+ * @return {float} the value, or defaultValue if the attribute does not exist
+ */
+ getFloatAttribute: function() {
+ if (arguments.length === 1 ) {
+ return parseFloat(this.getAttribute(arguments[0], 0));
+ }
+ if (arguments.length === 2 ) {
+ return this.getAttribute(arguments[0], arguments[1]);
+ }
+ return this.getAttribute(arguments[0], arguments[1],arguments[2]);
+ },
+ /**
+ * Processing 1.5 XML API wrapper for the generic float
+ * attribute getter. This may only take one argument.
+ */
+ getFloat: function(attributeName) {
+ return this.getFloatAttribute(attributeName);
+ },
+ /**
+ * @member XMLElement
+ * The getIntAttribute() function returns the integer attribute of the element.
+ * If the <b>defaultValue</b> parameter is used and the attribute doesn't exist, the <b>defaultValue</b> value is returned.
+ * When calling the function without the <b>defaultValue</b> parameter, if the attribute doesn't exist, the value 0 is returned.
+ *
+ * @param name the name of the attribute
+ * @param defaultValue value returned if the attribute is not found
+ *
+ * @return {int} the value, or defaultValue if the attribute does not exist
+ */
+ getIntAttribute: function () {
+ if (arguments.length === 1) {
+ return this.getAttribute( arguments[0], 0 );
+ }
+ if (arguments.length === 2) {
+ return this.getAttribute(arguments[0], arguments[1]);
+ }
+ return this.getAttribute(arguments[0], arguments[1],arguments[2]);
+ },
+ /**
+ * Processing 1.5 XML API wrapper for the generic int
+ * attribute getter. This may only take one argument.
+ */
+ getInt: function(attributeName) {
+ return this.getIntAttribute(attributeName);
+ },
+ /**
+ * @member XMLElement
+ * The hasChildren() function returns whether the element has children.
+ *
+ * @return {boolean} true if the element has children.
+ */
+ hasChildren: function () {
+ return this.children.length > 0 ;
+ },
+ /**
+ * @member XMLElement
+ * The addChild() function adds a child element
+ *
+ * @param {XMLElement} child the non-null child to add.
+ */
+ addChild: function (child) {
+ if (child !== null) {
+ child.parent = this;
+ this.children.push(child);
+ }
+ },
+ /**
+ * @member XMLElement
+ * The insertChild() function inserts a child element at the index provided
+ *
+ * @param {XMLElement} child the non-null child to add.
+ * @param {int} index where to put the child.
+ */
+ insertChild: function (child, index) {
+ if (child) {
+ if ((child.getLocalName() === null) && (! this.hasChildren())) {
+ var lastChild = this.children[this.children.length -1];
+ if (lastChild.getLocalName() === null) {
+ lastChild.setContent(lastChild.getContent() + child.getContent());
+ return;
+ }
+ }
+ child.parent = this;
+ this.children.splice(index,0,child);
+ }
+ },
+ /**
+ * @member XMLElement
+ * The getChild() returns the child XMLElement as specified by the <b>index</b> parameter.
+ * The value of the <b>index</b> parameter must be less than the total number of children to avoid going out of the array storing the child elements.
+ * When the <b>path</b> parameter is specified, then it will return all children that match that path. The path is a series of elements and sub-elements, separated by slashes.
+ *
+ * @param {int} index where to put the child.
+ * @param {String} path path to a particular element
+ *
+ * @return {XMLElement} the element
+ */
+ getChild: function (selector) {
+ if (typeof selector === "number") {
+ return this.children[selector];
+ }
+ if (selector.indexOf('/') !== -1) {
+ // path traversal is required
+ return this.getChildRecursive(selector.split("/"), 0);
+ }
+ var kid, kidName;
+ for (var i = 0, j = this.getChildCount(); i < j; i++) {
+ kid = this.getChild(i);
+ kidName = kid.getName();
+ if (kidName !== null && kidName === selector) {
+ return kid;
+ }
+ }
+ return null;
+ },
+ /**
+ * @member XMLElement
+ * The getChildren() returns all of the children as an XMLElement array.
+ * When the <b>path</b> parameter is specified, then it will return all children that match that path.
+ * The path is a series of elements and sub-elements, separated by slashes.
+ *
+ * @param {String} path element name or path/to/element
+ *
+ * @return {XMLElement} array of child elements that match
+ *
+ * @see XMLElement#getChildCount()
+ * @see XMLElement#getChild()
+ */
+ getChildren: function(){
+ if (arguments.length === 1) {
+ if (typeof arguments[0] === "number") {
+ return this.getChild( arguments[0]);
+ }
+ if (arguments[0].indexOf('/') !== -1) { // path was given
+ return this.getChildrenRecursive( arguments[0].split("/"), 0);
+ }
+ var matches = [];
+ var kid, kidName;
+ for (var i = 0, j = this.getChildCount(); i < j; i++) {
+ kid = this.getChild(i);
+ kidName = kid.getName();
+ if (kidName !== null && kidName === arguments[0]) {
+ matches.push(kid);
+ }
+ }
+ return matches;
+ }
+ return this.children;
+ },
+ /**
+ * @member XMLElement
+ * The getChildCount() returns the number of children for the element.
+ *
+ * @return {int} the count
+ *
+ * @see XMLElement#getChild()
+ * @see XMLElement#getChildren()
+ */
+ getChildCount: function() {
+ return this.children.length;
+ },
+ /**
+ * @member XMLElement
+ * Internal helper function for getChild().
+ *
+ * @param {String[]} items result of splitting the query on slashes
+ * @param {int} offset where in the items[] array we're currently looking
+ *
+ * @return {XMLElement} matching element or null if no match
+ */
+ getChildRecursive: function (items, offset) {
+ // terminating clause: we are the requested candidate
+ if (offset === items.length) {
+ return this;
+ }
+ // continuation clause
+ var kid, kidName, matchName = items[offset];
+ for(var i = 0, j = this.getChildCount(); i < j; i++) {
+ kid = this.getChild(i);
+ kidName = kid.getName();
+ if (kidName !== null && kidName === matchName) {
+ return kid.getChildRecursive(items, offset+1);
+ }
+ }
+ return null;
+ },
+ /**
+ * @member XMLElement
+ * Internal helper function for getChildren().
+ *
+ * @param {String[]} items result of splitting the query on slashes
+ * @param {int} offset where in the items[] array we're currently looking
+ *
+ * @return {XMLElement[]} matching elements or empty array if no match
+ */
+ getChildrenRecursive: function (items, offset) {
+ if (offset === items.length-1) {
+ return this.getChildren(items[offset]);
+ }
+ var matches = this.getChildren(items[offset]);
+ var kidMatches = [];
+ for (var i = 0; i < matches.length; i++) {
+ kidMatches = kidMatches.concat(matches[i].getChildrenRecursive(items, offset+1));
+ }
+ return kidMatches;
+ },
+ /**
+ * @member XMLElement
+ * The isLeaf() function returns whether the element is a leaf element.
+ *
+ * @return {boolean} true if the element has no children.
+ */
+ isLeaf: function() {
+ return !this.hasChildren();
+ },
+ /**
+ * @member XMLElement
+ * The listChildren() function put the names of all children into an array. Same as looping through
+ * each child and calling getName() on each XMLElement.
+ *
+ * @return {String[]} a list of element names.
+ */
+ listChildren: function() {
+ var arr = [];
+ for (var i = 0, j = this.children.length; i < j; i++) {
+ arr.push( this.getChild(i).getName());
+ }
+ return arr;
+ },
+ /**
+ * @member XMLElement
+ * The removeAttribute() function removes an attribute
+ *
+ * @param {String} name the non-null name of the attribute.
+ * @param {String} namespace the namespace URI of the attribute, which may be null.
+ */
+ removeAttribute: function (name , namespace) {
+ this.namespace = namespace || "";
+ for (var i = 0, j = this.attributes.length; i < j; i++) {
+ if (this.attributes[i].getName() === name && this.attributes[i].getNamespace() === this.namespace) {
+ this.attributes.splice(i, 1);
+ break;
+ }
+ }
+ },
+ /**
+ * @member XMLElement
+ * The removeChild() removes a child element.
+ *
+ * @param {XMLElement} child the the non-null child to be renoved
+ */
+ removeChild: function(child) {
+ if (child) {
+ for (var i = 0, j = this.children.length; i < j; i++) {
+ if (this.children[i].equals(child)) {
+ this.children.splice(i, 1);
+ break;
+ }
+ }
+ }
+ },
+ /**
+ * @member XMLElement
+ * The removeChildAtIndex() removes the child located at a certain index
+ *
+ * @param {int} index the index of the child, where the first child has index 0
+ */
+ removeChildAtIndex: function(index) {
+ if (this.children.length > index) { //make sure its not outofbounds
+ this.children.splice(index, 1);
+ }
+ },
+ /**
+ * @member XMLElement
+ * The findAttribute() function searches an attribute
+ *
+ * @param {String} name fullName the non-null full name of the attribute
+ * @param {String} namespace the name space, which may be null
+ *
+ * @return {XMLAttribute} the attribute, or null if the attribute does not exist.
+ */
+ findAttribute: function (name, namespace) {
+ this.namespace = namespace || "";
+ for (var i = 0, j = this.attributes.length; i < j; i++) {
+ if (this.attributes[i].getName() === name && this.attributes[i].getNamespace() === this.namespace) {
+ return this.attributes[i];
+ }
+ }
+ return null;
+ },
+ /**
+ * @member XMLElement
+ * The setAttribute() function sets an attribute.
+ *
+ * @param {String} name the non-null full name of the attribute
+ * @param {String} namespace the non-null value of the attribute
+ */
+ setAttribute: function() {
+ var attr;
+ if (arguments.length === 3) {
+ var index = arguments[0].indexOf(':');
+ var name = arguments[0].substring(index + 1);
+ attr = this.findAttribute(name, arguments[1]);
+ if (attr) {
+ attr.setValue(arguments[2]);
+ } else {
+ attr = new XMLAttribute(arguments[0], name, arguments[1], arguments[2], "CDATA");
+ this.attributes.push(attr);
+ }
+ } else {
+ attr = this.findAttribute(arguments[0]);
+ if (attr) {
+ attr.setValue(arguments[1]);
+ } else {
+ attr = new XMLAttribute(arguments[0], arguments[0], null, arguments[1], "CDATA");
+ this.attributes.push(attr);
+ }
+ }
+ },
+ /**
+ * Processing 1.5 XML API wrapper for the generic String
+ * attribute setter. This must take two arguments.
+ */
+ setString: function(attribute, value) {
+ this.setAttribute(attribute, value);
+ },
+ /**
+ * Processing 1.5 XML API wrapper for the generic int
+ * attribute setter. This must take two arguments.
+ */
+ setInt: function(attribute, value) {
+ this.setAttribute(attribute, value);
+ },
+ /**
+ * Processing 1.5 XML API wrapper for the generic float
+ * attribute setter. This must take two arguments.
+ */
+ setFloat: function(attribute, value) {
+ this.setAttribute(attribute, value);
+ },
+ /**
+ * @member XMLElement
+ * The setContent() function sets the #PCDATA content. It is an error to call this method with a
+ * non-null value if there are child objects.
+ *
+ * @param {String} content the (possibly null) content
+ */
+ setContent: function(content) {
+ if (this.children.length > 0) {
+ Processing.debug("Tried to set content for XMLElement with children"); }
+ this.content = content;
+ },
+ /**
+ * @member XMLElement
+ * The setName() function sets the full name. This method also sets the short name and clears the
+ * namespace URI.
+ *
+ * @param {String} name the non-null name
+ * @param {String} namespace the namespace URI, which may be null.
+ */
+ setName: function() {
+ if (arguments.length === 1) {
+ this.name = arguments[0];
+ this.fullName = arguments[0];
+ this.namespace = null;
+ } else {
+ var index = arguments[0].indexOf(':');
+ if ((arguments[1] === null) || (index < 0)) {
+ this.name = arguments[0];
+ } else {
+ this.name = arguments[0].substring(index + 1);
+ }
+ this.fullName = arguments[0];
+ this.namespace = arguments[1];
+ }
+ },
+ /**
+ * @member XMLElement
+ * The getName() function returns the full name (i.e. the name including an eventual namespace
+ * prefix) of the element.
+ *
+ * @return {String} the name, or null if the element only contains #PCDATA.
+ */
+ getName: function() {
+ return this.fullName;
+ },
+ /**
+ * @member XMLElement
+ * The getLocalName() function returns the local name (i.e. the name excluding an eventual namespace
+ * prefix) of the element.
+ *
+ * @return {String} the name, or null if the element only contains #PCDATA.
+ */
+ getLocalName: function() {
+ return this.name;
+ },
+ /**
+ * @member XMLElement
+ * The getAttributeCount() function returns the number of attributes for the node
+ * that this XMLElement represents.
+ *
+ * @return {int} the number of attributes in this XMLElement
+ */
+ getAttributeCount: function() {
+ return this.attributes.length;
+ },
+ /**
+ * @member XMLElement
+ * The toString() function returns the XML definition of an XMLElement.
+ *
+ * @return {String} the XML definition of this XMLElement
+ */
+ toString: function() {
+ // shortcut for text and cdata nodes
+ if (this.type === "TEXT") {
+ return this.content || "";
+ }
+
+ if (this.type === "CDATA") {
+ return this.cdata || "";
+ }
+
+ // real XMLElements
+ var tagstring = this.fullName;
+ var xmlstring = "<" + tagstring;
+ var a,c;
+
+ // serialize the attributes to XML string
+ for (a = 0; a<this.attributes.length; a++) {
+ var attr = this.attributes[a];
+ xmlstring += " " + attr.getName() + "=" + '"' + attr.getValue() + '"';
+ }
+
+ // serialize all children to XML string
+ if (this.children.length === 0) {
+ if (this.content === "" || this.content === null || this.content === undefined) {
+ xmlstring += "/>";
+ } else {
+ xmlstring += ">" + this.content + "</"+tagstring+">";
+ }
+ } else {
+ xmlstring += ">";
+ for (c = 0; c<this.children.length; c++) {
+ xmlstring += this.children[c].toString();
+ }
+ xmlstring += "</" + tagstring + ">";
+ }
+ return xmlstring;
+ }
+ };
+
+ /**
+ * static Processing 1.5 XML API wrapper for the
+ * parse method. This may only take one argument.
+ */
+ XMLElement.parse = function(xmlstring) {
+ var element = new XMLElement();
+ element.parse(xmlstring);
+ return element;
+ };
+
+ return XMLElement;
+};
+
+},{}],21:[function(require,module,exports){
+/**
+ * web colors, by name
+ */
+module.exports = {
+ aliceblue: "#f0f8ff",
+ antiquewhite: "#faebd7",
+ aqua: "#00ffff",
+ aquamarine: "#7fffd4",
+ azure: "#f0ffff",
+ beige: "#f5f5dc",
+ bisque: "#ffe4c4",
+ black: "#000000",
+ blanchedalmond: "#ffebcd",
+ blue: "#0000ff",
+ blueviolet: "#8a2be2",
+ brown: "#a52a2a",
+ burlywood: "#deb887",
+ cadetblue: "#5f9ea0",
+ chartreuse: "#7fff00",
+ chocolate: "#d2691e",
+ coral: "#ff7f50",
+ cornflowerblue: "#6495ed",
+ cornsilk: "#fff8dc",
+ crimson: "#dc143c",
+ cyan: "#00ffff",
+ darkblue: "#00008b",
+ darkcyan: "#008b8b",
+ darkgoldenrod: "#b8860b",
+ darkgray: "#a9a9a9",
+ darkgreen: "#006400",
+ darkkhaki: "#bdb76b",
+ darkmagenta: "#8b008b",
+ darkolivegreen: "#556b2f",
+ darkorange: "#ff8c00",
+ darkorchid: "#9932cc",
+ darkred: "#8b0000",
+ darksalmon: "#e9967a",
+ darkseagreen: "#8fbc8f",
+ darkslateblue: "#483d8b",
+ darkslategray: "#2f4f4f",
+ darkturquoise: "#00ced1",
+ darkviolet: "#9400d3",
+ deeppink: "#ff1493",
+ deepskyblue: "#00bfff",
+ dimgray: "#696969",
+ dodgerblue: "#1e90ff",
+ firebrick: "#b22222",
+ floralwhite: "#fffaf0",
+ forestgreen: "#228b22",
+ fuchsia: "#ff00ff",
+ gainsboro: "#dcdcdc",
+ ghostwhite: "#f8f8ff",
+ gold: "#ffd700",
+ goldenrod: "#daa520",
+ gray: "#808080",
+ green: "#008000",
+ greenyellow: "#adff2f",
+ honeydew: "#f0fff0",
+ hotpink: "#ff69b4",
+ indianred: "#cd5c5c",
+ indigo: "#4b0082",
+ ivory: "#fffff0",
+ khaki: "#f0e68c",
+ lavender: "#e6e6fa",
+ lavenderblush: "#fff0f5",
+ lawngreen: "#7cfc00",
+ lemonchiffon: "#fffacd",
+ lightblue: "#add8e6",
+ lightcoral: "#f08080",
+ lightcyan: "#e0ffff",
+ lightgoldenrodyellow: "#fafad2",
+ lightgrey: "#d3d3d3",
+ lightgreen: "#90ee90",
+ lightpink: "#ffb6c1",
+ lightsalmon: "#ffa07a",
+ lightseagreen: "#20b2aa",
+ lightskyblue: "#87cefa",
+ lightslategray: "#778899",
+ lightsteelblue: "#b0c4de",
+ lightyellow: "#ffffe0",
+ lime: "#00ff00",
+ limegreen: "#32cd32",
+ linen: "#faf0e6",
+ magenta: "#ff00ff",
+ maroon: "#800000",
+ mediumaquamarine: "#66cdaa",
+ mediumblue: "#0000cd",
+ mediumorchid: "#ba55d3",
+ mediumpurple: "#9370d8",
+ mediumseagreen: "#3cb371",
+ mediumslateblue: "#7b68ee",
+ mediumspringgreen: "#00fa9a",
+ mediumturquoise: "#48d1cc",
+ mediumvioletred: "#c71585",
+ midnightblue: "#191970",
+ mintcream: "#f5fffa",
+ mistyrose: "#ffe4e1",
+ moccasin: "#ffe4b5",
+ navajowhite: "#ffdead",
+ navy: "#000080",
+ oldlace: "#fdf5e6",
+ olive: "#808000",
+ olivedrab: "#6b8e23",
+ orange: "#ffa500",
+ orangered: "#ff4500",
+ orchid: "#da70d6",
+ palegoldenrod: "#eee8aa",
+ palegreen: "#98fb98",
+ paleturquoise: "#afeeee",
+ palevioletred: "#d87093",
+ papayawhip: "#ffefd5",
+ peachpuff: "#ffdab9",
+ peru: "#cd853f",
+ pink: "#ffc0cb",
+ plum: "#dda0dd",
+ powderblue: "#b0e0e6",
+ purple: "#800080",
+ red: "#ff0000",
+ rosybrown: "#bc8f8f",
+ royalblue: "#4169e1",
+ saddlebrown: "#8b4513",
+ salmon: "#fa8072",
+ sandybrown: "#f4a460",
+ seagreen: "#2e8b57",
+ seashell: "#fff5ee",
+ sienna: "#a0522d",
+ silver: "#c0c0c0",
+ skyblue: "#87ceeb",
+ slateblue: "#6a5acd",
+ slategray: "#708090",
+ snow: "#fffafa",
+ springgreen: "#00ff7f",
+ steelblue: "#4682b4",
+ tan: "#d2b48c",
+ teal: "#008080",
+ thistle: "#d8bfd8",
+ tomato: "#ff6347",
+ turquoise: "#40e0d0",
+ violet: "#ee82ee",
+ wheat: "#f5deb3",
+ white: "#ffffff",
+ whitesmoke: "#f5f5f5",
+ yellow: "#ffff00",
+ yellowgreen: "#9acd32"
+ };
+
+},{}],22:[function(require,module,exports){
+module.exports = function(virtHashCode, virtEquals, undef) {
+
+ return function withProxyFunctions(p, removeFirstArgument) {
+ /**
+ * The contains(string) function returns true if the string passed in the parameter
+ * is a substring of this string. It returns false if the string passed
+ * in the parameter is not a substring of this string.
+ *
+ * @param {String} The string to look for in the current string
+ *
+ * @return {boolean} returns true if this string contains
+ * the string passed as parameter. returns false, otherwise.
+ *
+ */
+ p.__contains = function (subject, subStr) {
+ if (typeof subject !== "string") {
+ return subject.contains.apply(subject, removeFirstArgument(arguments));
+ }
+ //Parameter is not null AND
+ //The type of the parameter is the same as this object (string)
+ //The javascript function that finds a substring returns 0 or higher
+ return (
+ (subject !== null) &&
+ (subStr !== null) &&
+ (typeof subStr === "string") &&
+ (subject.indexOf(subStr) > -1)
+ );
+ };
+
+ /**
+ * The __replaceAll() function searches all matches between a substring (or regular expression) and a string,
+ * and replaces the matched substring with a new substring
+ *
+ * @param {String} subject a substring
+ * @param {String} regex a substring or a regular expression
+ * @param {String} replace the string to replace the found value
+ *
+ * @return {String} returns result
+ *
+ * @see #match
+ */
+ p.__replaceAll = function(subject, regex, replacement) {
+ if (typeof subject !== "string") {
+ return subject.replaceAll.apply(subject, removeFirstArgument(arguments));
+ }
+
+ return subject.replace(new RegExp(regex, "g"), replacement);
+ };
+
+ /**
+ * The __replaceFirst() function searches first matche between a substring (or regular expression) and a string,
+ * and replaces the matched substring with a new substring
+ *
+ * @param {String} subject a substring
+ * @param {String} regex a substring or a regular expression
+ * @param {String} replace the string to replace the found value
+ *
+ * @return {String} returns result
+ *
+ * @see #match
+ */
+ p.__replaceFirst = function(subject, regex, replacement) {
+ if (typeof subject !== "string") {
+ return subject.replaceFirst.apply(subject, removeFirstArgument(arguments));
+ }
+
+ return subject.replace(new RegExp(regex, ""), replacement);
+ };
+
+ /**
+ * The __replace() function searches all matches between a substring and a string,
+ * and replaces the matched substring with a new substring
+ *
+ * @param {String} subject a substring
+ * @param {String} what a substring to find
+ * @param {String} replacement the string to replace the found value
+ *
+ * @return {String} returns result
+ */
+ p.__replace = function(subject, what, replacement) {
+ if (typeof subject !== "string") {
+ return subject.replace.apply(subject, removeFirstArgument(arguments));
+ }
+ if (what instanceof RegExp) {
+ return subject.replace(what, replacement);
+ }
+
+ if (typeof what !== "string") {
+ what = what.toString();
+ }
+ if (what === "") {
+ return subject;
+ }
+
+ var i = subject.indexOf(what);
+ if (i < 0) {
+ return subject;
+ }
+
+ var j = 0, result = "";
+ do {
+ result += subject.substring(j, i) + replacement;
+ j = i + what.length;
+ } while ( (i = subject.indexOf(what, j)) >= 0);
+ return result + subject.substring(j);
+ };
+
+ /**
+ * The __equals() function compares two strings (or objects) to see if they are the same.
+ * This method is necessary because it's not possible to compare strings using the equality operator (==).
+ * Returns true if the strings are the same and false if they are not.
+ *
+ * @param {String} subject a string used for comparison
+ * @param {String} other a string used for comparison with
+ *
+ * @return {boolean} true is the strings are the same false otherwise
+ */
+ p.__equals = function(subject, other) {
+ if (subject.equals instanceof Function) {
+ return subject.equals.apply(subject, removeFirstArgument(arguments));
+ }
+
+ return virtEquals(subject, other);
+ };
+
+ /**
+ * The __equalsIgnoreCase() function compares two strings to see if they are the same.
+ * Returns true if the strings are the same, either when forced to all lower case or
+ * all upper case.
+ *
+ * @param {String} subject a string used for comparison
+ * @param {String} other a string used for comparison with
+ *
+ * @return {boolean} true is the strings are the same, ignoring case. false otherwise
+ */
+ p.__equalsIgnoreCase = function(subject, other) {
+ if (typeof subject !== "string") {
+ return subject.equalsIgnoreCase.apply(subject, removeFirstArgument(arguments));
+ }
+
+ return subject.toLowerCase() === other.toLowerCase();
+ };
+
+ /**
+ * The __toCharArray() function splits the string into a char array.
+ *
+ * @param {String} subject The string
+ *
+ * @return {Char[]} a char array
+ */
+ p.__toCharArray = function(subject) {
+ if (typeof subject !== "string") {
+ return subject.toCharArray.apply(subject, removeFirstArgument(arguments));
+ }
+
+ var chars = [];
+ for (var i = 0, len = subject.length; i < len; ++i) {
+ chars[i] = new Char(subject.charAt(i));
+ }
+ return chars;
+ };
+
+ /**
+ * The __split() function splits a string using the regex delimiter
+ * specified. If limit is specified, the resultant array will have number
+ * of elements equal to or less than the limit.
+ *
+ * @param {String} subject string to be split
+ * @param {String} regexp regex string used to split the subject
+ * @param {int} limit max number of tokens to be returned
+ *
+ * @return {String[]} an array of tokens from the split string
+ */
+ p.__split = function(subject, regex, limit) {
+ if (typeof subject !== "string") {
+ return subject.split.apply(subject, removeFirstArgument(arguments));
+ }
+
+ var pattern = new RegExp(regex);
+
+ // If limit is not specified, use JavaScript's built-in String.split.
+ if ((limit === undef) || (limit < 1)) {
+ return subject.split(pattern);
+ }
+
+ // If limit is specified, JavaScript's built-in String.split has a
+ // different behaviour than Java's. A Java-compatible implementation is
+ // provided here.
+ var result = [], currSubject = subject, pos;
+ while (((pos = currSubject.search(pattern)) !== -1) && (result.length < (limit - 1))) {
+ var match = pattern.exec(currSubject).toString();
+ result.push(currSubject.substring(0, pos));
+ currSubject = currSubject.substring(pos + match.length);
+ }
+ if ((pos !== -1) || (currSubject !== "")) {
+ result.push(currSubject);
+ }
+ return result;
+ };
+
+ /**
+ * The codePointAt() function returns the unicode value of the character at a given index of a string.
+ *
+ * @param {int} idx the index of the character
+ *
+ * @return {String} code the String containing the unicode value of the character
+ */
+ p.__codePointAt = function(subject, idx) {
+ var code = subject.charCodeAt(idx),
+ hi,
+ low;
+ if (0xD800 <= code && code <= 0xDBFF) {
+ hi = code;
+ low = subject.charCodeAt(idx + 1);
+ return ((hi - 0xD800) * 0x400) + (low - 0xDC00) + 0x10000;
+ }
+ return code;
+ };
+
+ /**
+ * The matches() function checks whether or not a string matches a given regular expression.
+ *
+ * @param {String} str the String on which the match is tested
+ * @param {String} regexp the regexp for which a match is tested
+ *
+ * @return {boolean} true if the string fits the regexp, false otherwise
+ */
+ p.__matches = function(str, regexp) {
+ return (new RegExp(regexp)).test(str);
+ };
+
+ /**
+ * The startsWith() function tests if a string starts with the specified prefix. If the prefix
+ * is the empty String or equal to the subject String, startsWith() will also return true.
+ *
+ * @param {String} prefix the String used to compare against the start of the subject String.
+ * @param {int} toffset (optional) an offset into the subject String where searching should begin.
+ *
+ * @return {boolean} true if the subject String starts with the prefix.
+ */
+ p.__startsWith = function(subject, prefix, toffset) {
+ if (typeof subject !== "string") {
+ return subject.startsWith.apply(subject, removeFirstArgument(arguments));
+ }
+
+ toffset = toffset || 0;
+ if (toffset < 0 || toffset > subject.length) {
+ return false;
+ }
+ return (prefix === '' || prefix === subject) ? true : (subject.indexOf(prefix) === toffset);
+ };
+
+ /**
+ * The endsWith() function tests if a string ends with the specified suffix. If the suffix
+ * is the empty String, endsWith() will also return true.
+ *
+ * @param {String} suffix the String used to compare against the end of the subject String.
+ *
+ * @return {boolean} true if the subject String starts with the prefix.
+ */
+ p.__endsWith = function(subject, suffix) {
+ if (typeof subject !== "string") {
+ return subject.endsWith.apply(subject, removeFirstArgument(arguments));
+ }
+
+ var suffixLen = suffix ? suffix.length : 0;
+ return (suffix === '' || suffix === subject) ? true :
+ (subject.indexOf(suffix) === subject.length - suffixLen);
+ };
+
+ /**
+ * The returns hash code of the.
+ *
+ * @param {Object} subject The string
+ *
+ * @return {int} a hash code
+ */
+ p.__hashCode = function(subject) {
+ if (subject.hashCode instanceof Function) {
+ return subject.hashCode.apply(subject, removeFirstArgument(arguments));
+ }
+ return virtHashCode(subject);
+ };
+
+ /**
+ * The __printStackTrace() prints stack trace to the console.
+ *
+ * @param {Exception} subject The error
+ */
+ p.__printStackTrace = function(subject) {
+ p.println("Exception: " + subject.toString() );
+ };
+ };
+
+};
+
+},{}],23:[function(require,module,exports){
+/**
+ * For many "math" functions, we can delegate
+ * to the Math object. For others, we can't.
+ */
+module.exports = function withMath(p, undef) {
+ var internalRandomGenerator = function() { return Math.random(); };
+
+ /**
+ * Calculates the absolute value (magnitude) of a number. The absolute value of a number is always positive.
+ *
+ * @param {int|float} value int or float
+ *
+ * @returns {int|float}
+ */
+ p.abs = Math.abs;
+
+ /**
+ * Calculates the closest int value that is greater than or equal to the value of the parameter.
+ * For example, ceil(9.03) returns the value 10.
+ *
+ * @param {float} value float
+ *
+ * @returns {int}
+ *
+ * @see floor
+ * @see round
+ */
+ p.ceil = Math.ceil;
+
+ /**
+ * Returns Euler's number e (2.71828...) raised to the power of the value parameter.
+ *
+ * @param {int|float} value int or float: the exponent to raise e to
+ *
+ * @returns {float}
+ */
+ p.exp = Math.exp;
+
+ /**
+ * Calculates the closest int value that is less than or equal to the value of the parameter.
+ *
+ * @param {int|float} value the value to floor
+ *
+ * @returns {int|float}
+ *
+ * @see ceil
+ * @see round
+ */
+ p.floor = Math.floor;
+
+ /**
+ * Calculates the natural logarithm (the base-e logarithm) of a number. This function
+ * expects the values greater than 0.0.
+ *
+ * @param {int|float} value int or float: number must be greater then 0.0
+ *
+ * @returns {float}
+ */
+ p.log = Math.log;
+
+ /**
+ * Facilitates exponential expressions. The pow() function is an efficient way of
+ * multiplying numbers by themselves (or their reciprocal) in large quantities.
+ * For example, pow(3, 5) is equivalent to the expression 3*3*3*3*3 and pow(3, -5)
+ * is equivalent to 1 / 3*3*3*3*3.
+ *
+ * @param {int|float} num base of the exponential expression
+ * @param {int|float} exponent power of which to raise the base
+ *
+ * @returns {float}
+ *
+ * @see sqrt
+ */
+ p.pow = Math.pow;
+
+ /**
+ * Calculates the integer closest to the value parameter. For example, round(9.2) returns the value 9.
+ *
+ * @param {float} value number to round
+ *
+ * @returns {int}
+ *
+ * @see floor
+ * @see ceil
+ */
+ p.round = Math.round;
+ /**
+ * Calculates the square root of a number. The square root of a number is always positive,
+ * even though there may be a valid negative root. The square root s of number a is such
+ * that s*s = a. It is the opposite of squaring.
+ *
+ * @param {float} value int or float, non negative
+ *
+ * @returns {float}
+ *
+ * @see pow
+ * @see sq
+ */
+
+ p.sqrt = Math.sqrt;
+
+ // Trigonometry
+ /**
+ * The inverse of cos(), returns the arc cosine of a value. This function expects the
+ * values in the range of -1 to 1 and values are returned in the range 0 to PI (3.1415927).
+ *
+ * @param {float} value the value whose arc cosine is to be returned
+ *
+ * @returns {float}
+ *
+ * @see cos
+ * @see asin
+ * @see atan
+ */
+ p.acos = Math.acos;
+
+ /**
+ * The inverse of sin(), returns the arc sine of a value. This function expects the values
+ * in the range of -1 to 1 and values are returned in the range -PI/2 to PI/2.
+ *
+ * @param {float} value the value whose arc sine is to be returned
+ *
+ * @returns {float}
+ *
+ * @see sin
+ * @see acos
+ * @see atan
+ */
+ p.asin = Math.asin;
+
+ /**
+ * The inverse of tan(), returns the arc tangent of a value. This function expects the values
+ * in the range of -Infinity to Infinity (exclusive) and values are returned in the range -PI/2 to PI/2 .
+ *
+ * @param {float} value -Infinity to Infinity (exclusive)
+ *
+ * @returns {float}
+ *
+ * @see tan
+ * @see asin
+ * @see acos
+ */
+ p.atan = Math.atan;
+
+ /**
+ * Calculates the angle (in radians) from a specified point to the coordinate origin as measured from
+ * the positive x-axis. Values are returned as a float in the range from PI to -PI. The atan2() function
+ * is most often used for orienting geometry to the position of the cursor. Note: The y-coordinate of the
+ * point is the first parameter and the x-coordinate is the second due the the structure of calculating the tangent.
+ *
+ * @param {float} y y-coordinate of the point
+ * @param {float} x x-coordinate of the point
+ *
+ * @returns {float}
+ *
+ * @see tan
+ */
+ p.atan2 = Math.atan2;
+
+ /**
+ * Calculates the cosine of an angle. This function expects the values of the angle parameter to be provided
+ * in radians (values from 0 to PI*2). Values are returned in the range -1 to 1.
+ *
+ * @param {float} value an angle in radians
+ *
+ * @returns {float}
+ *
+ * @see tan
+ * @see sin
+ */
+ p.cos = Math.cos;
+
+ /**
+ * Calculates the sine of an angle. This function expects the values of the angle parameter to be provided in
+ * radians (values from 0 to 6.28). Values are returned in the range -1 to 1.
+ *
+ * @param {float} value an angle in radians
+ *
+ * @returns {float}
+ *
+ * @see cos
+ * @see radians
+ */
+ p.sin = Math.sin;
+
+ /**
+ * Calculates the ratio of the sine and cosine of an angle. This function expects the values of the angle
+ * parameter to be provided in radians (values from 0 to PI*2). Values are returned in the range infinity to -infinity.
+ *
+ * @param {float} value an angle in radians
+ *
+ * @returns {float}
+ *
+ * @see cos
+ * @see sin
+ * @see radians
+ */
+ p.tan = Math.tan;
+
+ /**
+ * Constrains a value to not exceed a maximum and minimum value.
+ *
+ * @param {int|float} value the value to constrain
+ * @param {int|float} value minimum limit
+ * @param {int|float} value maximum limit
+ *
+ * @returns {int|float}
+ *
+ * @see max
+ * @see min
+ */
+ p.constrain = function(aNumber, aMin, aMax) {
+ return aNumber > aMax ? aMax : aNumber < aMin ? aMin : aNumber;
+ };
+
+ /**
+ * Calculates the distance between two points.
+ *
+ * @param {int|float} x1 int or float: x-coordinate of the first point
+ * @param {int|float} y1 int or float: y-coordinate of the first point
+ * @param {int|float} z1 int or float: z-coordinate of the first point
+ * @param {int|float} x2 int or float: x-coordinate of the second point
+ * @param {int|float} y2 int or float: y-coordinate of the second point
+ * @param {int|float} z2 int or float: z-coordinate of the second point
+ *
+ * @returns {float}
+ */
+ p.dist = function() {
+ var dx, dy, dz;
+ if (arguments.length === 4) {
+ dx = arguments[0] - arguments[2];
+ dy = arguments[1] - arguments[3];
+ return Math.sqrt(dx * dx + dy * dy);
+ }
+ if (arguments.length === 6) {
+ dx = arguments[0] - arguments[3];
+ dy = arguments[1] - arguments[4];
+ dz = arguments[2] - arguments[5];
+ return Math.sqrt(dx * dx + dy * dy + dz * dz);
+ }
+ };
+
+ /**
+ * Calculates a number between two numbers at a specific increment. The amt parameter is the
+ * amount to interpolate between the two values where 0.0 equal to the first point, 0.1 is very
+ * near the first point, 0.5 is half-way in between, etc. The lerp function is convenient for
+ * creating motion along a straight path and for drawing dotted lines.
+ *
+ * @param {int|float} value1 float or int: first value
+ * @param {int|float} value2 float or int: second value
+ * @param {int|float} amt float: between 0.0 and 1.0
+ *
+ * @returns {float}
+ *
+ * @see curvePoint
+ * @see bezierPoint
+ */
+ p.lerp = function(value1, value2, amt) {
+ return ((value2 - value1) * amt) + value1;
+ };
+
+ /**
+ * Calculates the magnitude (or length) of a vector. A vector is a direction in space commonly
+ * used in computer graphics and linear algebra. Because it has no "start" position, the magnitude
+ * of a vector can be thought of as the distance from coordinate (0,0) to its (x,y) value.
+ * Therefore, mag() is a shortcut for writing "dist(0, 0, x, y)".
+ *
+ * @param {int|float} a float or int: first value
+ * @param {int|float} b float or int: second value
+ * @param {int|float} c float or int: third value
+ *
+ * @returns {float}
+ *
+ * @see dist
+ */
+ p.mag = function(a, b, c) {
+ if (c) {
+ return Math.sqrt(a * a + b * b + c * c);
+ }
+
+ return Math.sqrt(a * a + b * b);
+ };
+
+ /**
+ * Re-maps a number from one range to another. In the example above, the number '25' is converted from
+ * a value in the range 0..100 into a value that ranges from the left edge (0) to the right edge (width) of the screen.
+ * Numbers outside the range are not clamped to 0 and 1, because out-of-range values are often intentional and useful.
+ *
+ * @param {float} value The incoming value to be converted
+ * @param {float} istart Lower bound of the value's current range
+ * @param {float} istop Upper bound of the value's current range
+ * @param {float} ostart Lower bound of the value's target range
+ * @param {float} ostop Upper bound of the value's target range
+ *
+ * @returns {float}
+ *
+ * @see norm
+ * @see lerp
+ */
+ p.map = function(value, istart, istop, ostart, ostop) {
+ return ostart + (ostop - ostart) * ((value - istart) / (istop - istart));
+ };
+
+ /**
+ * Determines the largest value in a sequence of numbers.
+ *
+ * @param {int|float} value1 int or float
+ * @param {int|float} value2 int or float
+ * @param {int|float} value3 int or float
+ * @param {int|float} array int or float array
+ *
+ * @returns {int|float}
+ *
+ * @see min
+ */
+ p.max = function() {
+ if (arguments.length === 2) {
+ return arguments[0] < arguments[1] ? arguments[1] : arguments[0];
+ }
+ var numbers = arguments.length === 1 ? arguments[0] : arguments; // if single argument, array is used
+ if (! ("length" in numbers && numbers.length > 0)) {
+ throw "Non-empty array is expected";
+ }
+ var max = numbers[0],
+ count = numbers.length;
+ for (var i = 1; i < count; ++i) {
+ if (max < numbers[i]) {
+ max = numbers[i];
+ }
+ }
+ return max;
+ };
+
+ /**
+ * Determines the smallest value in a sequence of numbers.
+ *
+ * @param {int|float} value1 int or float
+ * @param {int|float} value2 int or float
+ * @param {int|float} value3 int or float
+ * @param {int|float} array int or float array
+ *
+ * @returns {int|float}
+ *
+ * @see max
+ */
+ p.min = function() {
+ if (arguments.length === 2) {
+ return arguments[0] < arguments[1] ? arguments[0] : arguments[1];
+ }
+ var numbers = arguments.length === 1 ? arguments[0] : arguments; // if single argument, array is used
+ if (! ("length" in numbers && numbers.length > 0)) {
+ throw "Non-empty array is expected";
+ }
+ var min = numbers[0],
+ count = numbers.length;
+ for (var i = 1; i < count; ++i) {
+ if (min > numbers[i]) {
+ min = numbers[i];
+ }
+ }
+ return min;
+ };
+
+ /**
+ * Normalizes a number from another range into a value between 0 and 1.
+ * Identical to map(value, low, high, 0, 1);
+ * Numbers outside the range are not clamped to 0 and 1, because out-of-range
+ * values are often intentional and useful.
+ *
+ * @param {float} aNumber The incoming value to be converted
+ * @param {float} low Lower bound of the value's current range
+ * @param {float} high Upper bound of the value's current range
+ *
+ * @returns {float}
+ *
+ * @see map
+ * @see lerp
+ */
+ p.norm = function(aNumber, low, high) {
+ return (aNumber - low) / (high - low);
+ };
+
+ /**
+ * Squares a number (multiplies a number by itself). The result is always a positive number,
+ * as multiplying two negative numbers always yields a positive result. For example, -1 * -1 = 1.
+ *
+ * @param {float} value int or float
+ *
+ * @returns {float}
+ *
+ * @see sqrt
+ */
+ p.sq = function(aNumber) {
+ return aNumber * aNumber;
+ };
+
+ /**
+ * Converts a radian measurement to its corresponding value in degrees. Radians and degrees are two ways of
+ * measuring the same thing. There are 360 degrees in a circle and 2*PI radians in a circle. For example,
+ * 90 degrees = PI/2 = 1.5707964. All trigonometric methods in Processing require their parameters to be specified in radians.
+ *
+ * @param {int|float} value an angle in radians
+ *
+ * @returns {float}
+ *
+ * @see radians
+ */
+ p.degrees = function(aAngle) {
+ return (aAngle * 180) / Math.PI;
+ };
+
+ /**
+ * Generates random numbers. Each time the random() function is called, it returns an unexpected value within
+ * the specified range. If one parameter is passed to the function it will return a float between zero and the
+ * value of the high parameter. The function call random(5) returns values between 0 and 5 (starting at zero,
+ * up to but not including 5). If two parameters are passed, it will return a float with a value between the
+ * parameters. The function call random(-5, 10.2) returns values starting at -5 up to (but not including) 10.2.
+ * To convert a floating-point random number to an integer, use the int() function.
+ *
+ * @param {int|float} value1 if one parameter is used, the top end to random from, if two params the low end
+ * @param {int|float} value2 the top end of the random range
+ *
+ * @returns {float}
+ *
+ * @see randomSeed
+ * @see noise
+ */
+ p.random = function(aMin, aMax) {
+ if (arguments.length === 0) {
+ aMax = 1;
+ aMin = 0;
+ } else if (arguments.length === 1) {
+ aMax = aMin;
+ aMin = 0;
+ }
+ if (aMin === aMax) {
+ return aMin;
+ }
+ for (var i = 0; i < 100; i++) {
+ var ir = internalRandomGenerator();
+ var result = ir * (aMax - aMin) + aMin;
+ if (result !== aMax) {
+ return result;
+ }
+ // assertion: ir is never less than 0.5
+ }
+ return aMin;
+ };
+
+ // Pseudo-random generator
+ function Marsaglia(i1, i2) {
+ // from http://www.math.uni-bielefeld.de/~sillke/ALGORITHMS/random/marsaglia-c
+ var z=i1 || 362436069, w= i2 || 521288629;
+ var intGenerator = function() {
+ z=(36969*(z&65535)+(z>>>16)) & 0xFFFFFFFF;
+ w=(18000*(w&65535)+(w>>>16)) & 0xFFFFFFFF;
+ return (((z&0xFFFF)<<16) | (w&0xFFFF)) & 0xFFFFFFFF;
+ };
+
+ this.doubleGenerator = function() {
+ var i = intGenerator() / 4294967296;
+ return i < 0 ? 1 + i : i;
+ };
+ this.intGenerator = intGenerator;
+ }
+
+ Marsaglia.createRandomized = function() {
+ var now = new Date();
+ return new Marsaglia((now / 60000) & 0xFFFFFFFF, now & 0xFFFFFFFF);
+ };
+
+ /**
+ * Sets the seed value for random(). By default, random() produces different results each time the
+ * program is run. Set the value parameter to a constant to return the same pseudo-random numbers
+ * each time the software is run.
+ *
+ * @param {int|float} seed int
+ *
+ * @see random
+ * @see noise
+ * @see noiseSeed
+ */
+ p.randomSeed = function(seed) {
+ internalRandomGenerator = (new Marsaglia(seed, (seed<<16)+(seed>>16))).doubleGenerator;
+ this.haveNextNextGaussian = false;
+ };
+
+ /**
+ * Returns a float from a random series of numbers having a mean of 0 and standard deviation of 1. Each time
+ * the randomGaussian() function is called, it returns a number fitting a Gaussian, or normal, distribution.
+ * There is theoretically no minimum or maximum value that randomGaussian() might return. Rather, there is just a
+ * very low probability that values far from the mean will be returned; and a higher probability that numbers
+ * near the mean will be returned.
+ *
+ * @returns {float}
+ *
+ * @see random
+ * @see noise
+ */
+ p.randomGaussian = function() {
+ if (this.haveNextNextGaussian) {
+ this.haveNextNextGaussian = false;
+ return this.nextNextGaussian;
+ }
+ var v1, v2, s;
+ do {
+ v1 = 2 * internalRandomGenerator() - 1; // between -1.0 and 1.0
+ v2 = 2 * internalRandomGenerator() - 1; // between -1.0 and 1.0
+ s = v1 * v1 + v2 * v2;
+ }
+ while (s >= 1 || s === 0);
+
+ var multiplier = Math.sqrt(-2 * Math.log(s) / s);
+ this.nextNextGaussian = v2 * multiplier;
+ this.haveNextNextGaussian = true;
+
+ return v1 * multiplier;
+ };
+
+ // Noise functions and helpers
+ function PerlinNoise(seed) {
+ var rnd = seed !== undef ? new Marsaglia(seed, (seed<<16)+(seed>>16)) : Marsaglia.createRandomized();
+ var i, j;
+ // http://www.noisemachine.com/talk1/17b.html
+ // http://mrl.nyu.edu/~perlin/noise/
+ // generate permutation
+ var perm = new Uint8Array(512);
+ for(i=0;i<256;++i) { perm[i] = i; }
+ for(i=0;i<256;++i) {
+ // NOTE: we can only do this because we've made sure the Marsaglia generator
+ // gives us numbers where the last byte in a pseudo-random number is
+ // still pseudo-random. If no 2nd argument is passed in the constructor,
+ // that is no longer the case and this pair swap will always run identically.
+ var t = perm[j = rnd.intGenerator() & 0xFF];
+ perm[j] = perm[i];
+ perm[i] = t;
+ }
+ // copy to avoid taking mod in perm[0];
+ for(i=0;i<256;++i) { perm[i + 256] = perm[i]; }
+
+ function grad3d(i,x,y,z) {
+ var h = i & 15; // convert into 12 gradient directions
+ var u = h<8 ? x : y,
+ v = h<4 ? y : h===12||h===14 ? x : z;
+ return ((h&1) === 0 ? u : -u) + ((h&2) === 0 ? v : -v);
+ }
+
+ function grad2d(i,x,y) {
+ var v = (i & 1) === 0 ? x : y;
+ return (i&2) === 0 ? -v : v;
+ }
+
+ function grad1d(i,x) {
+ return (i&1) === 0 ? -x : x;
+ }
+
+ function lerp(t,a,b) { return a + t * (b - a); }
+
+ this.noise3d = function(x, y, z) {
+ var X = Math.floor(x)&255, Y = Math.floor(y)&255, Z = Math.floor(z)&255;
+ x -= Math.floor(x); y -= Math.floor(y); z -= Math.floor(z);
+ var fx = (3-2*x)*x*x, fy = (3-2*y)*y*y, fz = (3-2*z)*z*z;
+ var p0 = perm[X]+Y, p00 = perm[p0] + Z, p01 = perm[p0 + 1] + Z,
+ p1 = perm[X + 1] + Y, p10 = perm[p1] + Z, p11 = perm[p1 + 1] + Z;
+ return lerp(fz,
+ lerp(fy, lerp(fx, grad3d(perm[p00], x, y, z), grad3d(perm[p10], x-1, y, z)),
+ lerp(fx, grad3d(perm[p01], x, y-1, z), grad3d(perm[p11], x-1, y-1,z))),
+ lerp(fy, lerp(fx, grad3d(perm[p00 + 1], x, y, z-1), grad3d(perm[p10 + 1], x-1, y, z-1)),
+ lerp(fx, grad3d(perm[p01 + 1], x, y-1, z-1), grad3d(perm[p11 + 1], x-1, y-1,z-1))));
+ };
+
+ this.noise2d = function(x, y) {
+ var X = Math.floor(x)&255, Y = Math.floor(y)&255;
+ x -= Math.floor(x); y -= Math.floor(y);
+ var fx = (3-2*x)*x*x, fy = (3-2*y)*y*y;
+ var p0 = perm[X]+Y, p1 = perm[X + 1] + Y;
+ return lerp(fy,
+ lerp(fx, grad2d(perm[p0], x, y), grad2d(perm[p1], x-1, y)),
+ lerp(fx, grad2d(perm[p0 + 1], x, y-1), grad2d(perm[p1 + 1], x-1, y-1)));
+ };
+
+ this.noise1d = function(x) {
+ var X = Math.floor(x)&255;
+ x -= Math.floor(x);
+ var fx = (3-2*x)*x*x;
+ return lerp(fx, grad1d(perm[X], x), grad1d(perm[X+1], x-1));
+ };
+ }
+
+ // processing defaults
+ var noiseProfile = { generator: undef, octaves: 4, fallout: 0.5, seed: undef};
+
+ /**
+ * Returns the Perlin noise value at specified coordinates. Perlin noise is a random sequence
+ * generator producing a more natural ordered, harmonic succession of numbers compared to the
+ * standard random() function. It was invented by Ken Perlin in the 1980s and been used since
+ * in graphical applications to produce procedural textures, natural motion, shapes, terrains etc.
+ * The main difference to the random() function is that Perlin noise is defined in an infinite
+ * n-dimensional space where each pair of coordinates corresponds to a fixed semi-random value
+ * (fixed only for the lifespan of the program). The resulting value will always be between 0.0
+ * and 1.0. Processing can compute 1D, 2D and 3D noise, depending on the number of coordinates
+ * given. The noise value can be animated by moving through the noise space as demonstrated in
+ * the example above. The 2nd and 3rd dimension can also be interpreted as time.
+ * The actual noise is structured similar to an audio signal, in respect to the function's use
+ * of frequencies. Similar to the concept of harmonics in physics, perlin noise is computed over
+ * several octaves which are added together for the final result.
+ * Another way to adjust the character of the resulting sequence is the scale of the input
+ * coordinates. As the function works within an infinite space the value of the coordinates
+ * doesn't matter as such, only the distance between successive coordinates does (eg. when using
+ * noise() within a loop). As a general rule the smaller the difference between coordinates, the
+ * smoother the resulting noise sequence will be. Steps of 0.005-0.03 work best for most applications,
+ * but this will differ depending on use.
+ *
+ * @param {float} x x coordinate in noise space
+ * @param {float} y y coordinate in noise space
+ * @param {float} z z coordinate in noise space
+ *
+ * @returns {float}
+ *
+ * @see random
+ * @see noiseDetail
+ */
+ p.noise = function(x, y, z) {
+ if(noiseProfile.generator === undef) {
+ // caching
+ noiseProfile.generator = new PerlinNoise(noiseProfile.seed);
+ }
+ var generator = noiseProfile.generator;
+ var effect = 1, k = 1, sum = 0;
+ for(var i=0; i<noiseProfile.octaves; ++i) {
+ effect *= noiseProfile.fallout;
+ switch (arguments.length) {
+ case 1:
+ sum += effect * (1 + generator.noise1d(k*x))/2; break;
+ case 2:
+ sum += effect * (1 + generator.noise2d(k*x, k*y))/2; break;
+ case 3:
+ sum += effect * (1 + generator.noise3d(k*x, k*y, k*z))/2; break;
+ }
+ k *= 2;
+ }
+ return sum;
+ };
+
+ /**
+ * Adjusts the character and level of detail produced by the Perlin noise function.
+ * Similar to harmonics in physics, noise is computed over several octaves. Lower octaves
+ * contribute more to the output signal and as such define the overal intensity of the noise,
+ * whereas higher octaves create finer grained details in the noise sequence. By default,
+ * noise is computed over 4 octaves with each octave contributing exactly half than its
+ * predecessor, starting at 50% strength for the 1st octave. This falloff amount can be
+ * changed by adding an additional function parameter. Eg. a falloff factor of 0.75 means
+ * each octave will now have 75% impact (25% less) of the previous lower octave. Any value
+ * between 0.0 and 1.0 is valid, however note that values greater than 0.5 might result in
+ * greater than 1.0 values returned by noise(). By changing these parameters, the signal
+ * created by the noise() function can be adapted to fit very specific needs and characteristics.
+ *
+ * @param {int} octaves number of octaves to be used by the noise() function
+ * @param {float} falloff falloff factor for each octave
+ *
+ * @see noise
+ */
+ p.noiseDetail = function(octaves, fallout) {
+ noiseProfile.octaves = octaves;
+ if(fallout !== undef) {
+ noiseProfile.fallout = fallout;
+ }
+ };
+
+ /**
+ * Sets the seed value for noise(). By default, noise() produces different results each
+ * time the program is run. Set the value parameter to a constant to return the same
+ * pseudo-random numbers each time the software is run.
+ *
+ * @param {int} seed int
+ *
+ * @returns {float}
+ *
+ * @see random
+ * @see radomSeed
+ * @see noise
+ * @see noiseDetail
+ */
+ p.noiseSeed = function(seed) {
+ noiseProfile.seed = seed;
+ noiseProfile.generator = undef;
+ };
+};
+
+},{}],24:[function(require,module,exports){
+/**
+ * Common functions traditionally on "p" that should be class functions
+ * that get bound to "p" when an instance is actually built, instead.
+ */
+module.exports = (function commonFunctions(undef) {
+
+ var CommonFunctions = {
+ /**
+ * Remove whitespace characters from the beginning and ending
+ * of a String or a String array. Works like String.trim() but includes the
+ * unicode nbsp character as well. If an array is passed in the function will return a new array not effecting the array passed in.
+ *
+ * @param {String} str the string to trim
+ * @param {String[]} str the string array to trim
+ *
+ * @return {String|String[]} retrurns a string or an array will removed whitespaces
+ */
+ trim: function(str) {
+ if (str instanceof Array) {
+ var arr = [];
+ for (var i = 0; i < str.length; i++) {
+ arr.push(str[i].replace(/^\s*/, '').replace(/\s*$/, '').replace(/\r*$/, ''));
+ }
+ return arr;
+ }
+ return str.replace(/^\s*/, '').replace(/\s*$/, '').replace(/\r*$/, '');
+ },
+
+ /**
+ * Converts a degree measurement to its corresponding value in radians. Radians and degrees are two ways of
+ * measuring the same thing. There are 360 degrees in a circle and 2*PI radians in a circle. For example,
+ * 90 degrees = PI/2 = 1.5707964. All trigonometric methods in Processing require their parameters to be specified in radians.
+ *
+ * @param {int|float} value an angle in radians
+ *
+ * @returns {float}
+ *
+ * @see degrees
+ */
+ radians: function(aAngle) {
+ return (aAngle / 180) * Math.PI;
+ },
+
+ /**
+ * Number-to-String formatting function. Prepends "plus" or "minus" depending
+ * on whether the value is positive or negative, respectively, after padding
+ * the value with zeroes on the left and right, the number of zeroes used dictated
+ * by the values 'leftDigits' and 'rightDigits'. 'value' cannot be an array.
+ *
+ * @param {int|float} value the number to format
+ * @param {String} plus the prefix for positive numbers
+ * @param {String} minus the prefix for negative numbers
+ * @param {int} left number of digits to the left of the decimal point
+ * @param {int} right number of digits to the right of the decimal point
+ * @param {String} group string delimited for groups, such as the comma in "1,000"
+ *
+ * @returns {String or String[]}
+ *
+ * @see nfCore
+ */
+ nfCoreScalar: function (value, plus, minus, leftDigits, rightDigits, group) {
+ var sign = (value < 0) ? minus : plus;
+ var autoDetectDecimals = rightDigits === 0;
+ var rightDigitsOfDefault = (rightDigits === undef || rightDigits < 0) ? 0 : rightDigits;
+
+ var absValue = Math.abs(value);
+ if (autoDetectDecimals) {
+ rightDigitsOfDefault = 1;
+ absValue *= 10;
+ while (Math.abs(Math.round(absValue) - absValue) > 1e-6 && rightDigitsOfDefault < 7) {
+ ++rightDigitsOfDefault;
+ absValue *= 10;
+ }
+ } else if (rightDigitsOfDefault !== 0) {
+ absValue *= Math.pow(10, rightDigitsOfDefault);
+ }
+
+ // Using Java's default rounding policy HALF_EVEN. This policy is based
+ // on the idea that 0.5 values round to the nearest even number, and
+ // everything else is rounded normally.
+ var number, doubled = absValue * 2;
+ if (Math.floor(absValue) === absValue) {
+ number = absValue;
+ } else if (Math.floor(doubled) === doubled) {
+ var floored = Math.floor(absValue);
+ number = floored + (floored % 2);
+ } else {
+ number = Math.round(absValue);
+ }
+
+ var buffer = "";
+ var totalDigits = leftDigits + rightDigitsOfDefault;
+ while (totalDigits > 0 || number > 0) {
+ totalDigits--;
+ buffer = "" + (number % 10) + buffer;
+ number = Math.floor(number / 10);
+ }
+ if (group !== undef) {
+ var i = buffer.length - 3 - rightDigitsOfDefault;
+ while(i > 0) {
+ buffer = buffer.substring(0,i) + group + buffer.substring(i);
+ i-=3;
+ }
+ }
+ if (rightDigitsOfDefault > 0) {
+ return sign + buffer.substring(0, buffer.length - rightDigitsOfDefault) +
+ "." + buffer.substring(buffer.length - rightDigitsOfDefault, buffer.length);
+ }
+ return sign + buffer;
+ },
+
+ /**
+ * Number-to-String formatting function. Prepends "plus" or "minus" depending
+ * on whether the value is positive or negative, respectively, after padding
+ * the value with zeroes on the left and right, the number of zeroes used dictated
+ * by the values 'leftDigits' and 'rightDigits'. 'value' can be an array;
+ * if the input is an array, each value in it is formatted separately, and
+ * an array with formatted values is returned.
+ *
+ * @param {int|int[]|float|float[]} value the number(s) to format
+ * @param {String} plus the prefix for positive numbers
+ * @param {String} minus the prefix for negative numbers
+ * @param {int} left number of digits to the left of the decimal point
+ * @param {int} right number of digits to the right of the decimal point
+ * @param {String} group string delimited for groups, such as the comma in "1,000"
+ *
+ * @returns {String or String[]}
+ *
+ * @see nfCoreScalar
+ */
+ nfCore: function(value, plus, minus, leftDigits, rightDigits, group) {
+ if (value instanceof Array) {
+ var arr = [];
+ for (var i = 0, len = value.length; i < len; i++) {
+ arr.push(CommonFunctions.nfCoreScalar(value[i], plus, minus, leftDigits, rightDigits, group));
+ }
+ return arr;
+ }
+ return CommonFunctions.nfCoreScalar(value, plus, minus, leftDigits, rightDigits, group);
+ },
+
+ /**
+ * Utility function for formatting numbers into strings. There are two versions, one for
+ * formatting floats and one for formatting ints. The values for the digits, left, and
+ * right parameters should always be positive integers.
+ * As shown in the above example, nf() is used to add zeros to the left and/or right
+ * of a number. This is typically for aligning a list of numbers. To remove digits from
+ * a floating-point number, use the int(), ceil(), floor(), or round() functions.
+ *
+ * @param {int|int[]|float|float[]} value the number(s) to format
+ * @param {int} left number of digits to the left of the decimal point
+ * @param {int} right number of digits to the right of the decimal point
+ *
+ * @returns {String or String[]}
+ *
+ * @see nfs
+ * @see nfp
+ * @see nfc
+ */
+ nf: function(value, leftDigits, rightDigits) {
+ return CommonFunctions.nfCore(value, "", "-", leftDigits, rightDigits);
+ },
+
+ /**
+ * Utility function for formatting numbers into strings. Similar to nf() but leaves a blank space in front
+ * of positive numbers so they align with negative numbers in spite of the minus symbol. There are two
+ * versions, one for formatting floats and one for formatting ints. The values for the digits, left,
+ * and right parameters should always be positive integers.
+ *
+ * @param {int|int[]|float|float[]} value the number(s) to format
+ * @param {int} left number of digits to the left of the decimal point
+ * @param {int} right number of digits to the right of the decimal point
+ *
+ * @returns {String or String[]}
+ *
+ * @see nf
+ * @see nfp
+ * @see nfc
+ */
+ nfs: function(value, leftDigits, rightDigits) {
+ return CommonFunctions.nfCore(value, " ", "-", leftDigits, rightDigits);
+ },
+
+ /**
+ * Utility function for formatting numbers into strings. Similar to nf() but puts a "+" in front of
+ * positive numbers and a "-" in front of negative numbers. There are two versions, one for formatting
+ * floats and one for formatting ints. The values for the digits, left, and right parameters should
+ * always be positive integers.
+ *
+ * @param {int|int[]|float|float[]} value the number(s) to format
+ * @param {int} left number of digits to the left of the decimal point
+ * @param {int} right number of digits to the right of the decimal point
+ *
+ * @returns {String or String[]}
+ *
+ * @see nfs
+ * @see nf
+ * @see nfc
+ */
+ nfp: function(value, leftDigits, rightDigits) {
+ return CommonFunctions.nfCore(value, "+", "-", leftDigits, rightDigits);
+ },
+
+ /**
+ * Utility function for formatting numbers into strings and placing appropriate commas to mark
+ * units of 1000. There are two versions, one for formatting ints and one for formatting an array
+ * of ints. The value for the digits parameter should always be a positive integer.
+ *
+ * @param {int|int[]|float|float[]} value the number(s) to format
+ * @param {int} left number of digits to the left of the decimal point
+ * @param {int} right number of digits to the right of the decimal point
+ *
+ * @returns {String or String[]}
+ *
+ * @see nf
+ * @see nfs
+ * @see nfp
+ */
+ nfc: function(value, rightDigits) {
+ return CommonFunctions.nfCore(value, "", "-", 0, rightDigits, ",");
+ },
+
+ // used to bind all common functions to "p"
+ withCommonFunctions: function withCommonFunctions(p) {
+ ["trim", "radians", "nf", "nfs", "nfp", "nfc"].forEach(function(f){
+ p[f] = CommonFunctions[f];
+ });
+ }
+ };
+
+ return CommonFunctions;
+}());
+
+},{}],25:[function(require,module,exports){
+/**
+ * Touch and Mouse event handling
+ */
+module.exports = function withTouch(p, curElement, attachEventHandler, document, PConstants, undef) {
+
+ /**
+ * Determine the location of the (mouse) pointer.
+ */
+ function calculateOffset(curElement, event) {
+ var element = curElement,
+ offsetX = 0,
+ offsetY = 0;
+
+ p.pmouseX = p.mouseX;
+ p.pmouseY = p.mouseY;
+
+ // Find element offset
+ if (element.offsetParent) {
+ do {
+ offsetX += element.offsetLeft;
+ offsetY += element.offsetTop;
+ } while (!!(element = element.offsetParent));
+ }
+
+ // Find Scroll offset
+ element = curElement;
+ do {
+ offsetX -= element.scrollLeft || 0;
+ offsetY -= element.scrollTop || 0;
+ } while (!!(element = element.parentNode));
+
+ // Get padding and border style widths for mouse offsets
+ var stylePaddingLeft, stylePaddingTop, styleBorderLeft, styleBorderTop;
+ if (document.defaultView && document.defaultView.getComputedStyle) {
+ stylePaddingLeft = parseInt(document.defaultView.getComputedStyle(curElement, null).paddingLeft, 10) || 0;
+ stylePaddingTop = parseInt(document.defaultView.getComputedStyle(curElement, null).paddingTop, 10) || 0;
+ styleBorderLeft = parseInt(document.defaultView.getComputedStyle(curElement, null).borderLeftWidth, 10) || 0;
+ styleBorderTop = parseInt(document.defaultView.getComputedStyle(curElement, null).borderTopWidth, 10) || 0;
+ }
+
+ // Add padding and border style widths to offset
+ offsetX += stylePaddingLeft;
+ offsetY += stylePaddingTop;
+
+ offsetX += styleBorderLeft;
+ offsetY += styleBorderTop;
+
+ // Take into account any scrolling done
+ offsetX += window.pageXOffset;
+ offsetY += window.pageYOffset;
+
+ return {'X':offsetX,'Y':offsetY};
+ }
+
+ // simple relative position
+ function updateMousePosition(curElement, event) {
+ var offset = calculateOffset(curElement, event);
+ // Dropping support for IE clientX and clientY, switching to pageX and pageY
+ // so we don't have to calculate scroll offset.
+ // Removed in ticket #184. See rev: 2f106d1c7017fed92d045ba918db47d28e5c16f4
+ p.mouseX = event.pageX - offset.X;
+ p.mouseY = event.pageY - offset.Y;
+ }
+
+ /**
+ * Return a TouchEvent with canvas-specific x/y co-ordinates
+ */
+ function addTouchEventOffset(t) {
+ var offset = calculateOffset(t.changedTouches[0].target, t.changedTouches[0]),
+ i;
+
+ for (i = 0; i < t.touches.length; i++) {
+ var touch = t.touches[i];
+ touch.offsetX = touch.pageX - offset.X;
+ touch.offsetY = touch.pageY - offset.Y;
+ }
+ for (i = 0; i < t.targetTouches.length; i++) {
+ var targetTouch = t.targetTouches[i];
+ targetTouch.offsetX = targetTouch.pageX - offset.X;
+ targetTouch.offsetY = targetTouch.pageY - offset.Y;
+ }
+ for (i = 0; i < t.changedTouches.length; i++) {
+ var changedTouch = t.changedTouches[i];
+ changedTouch.offsetX = changedTouch.pageX - offset.X;
+ changedTouch.offsetY = changedTouch.pageY - offset.Y;
+ }
+
+ return t;
+ }
+
+ /**
+ * Touch event support.
+ */
+ attachEventHandler(curElement, "touchstart", function (t) {
+ // Removes unwanted behaviour of the canvas when touching canvas
+ curElement.setAttribute("style","-webkit-user-select: none");
+ curElement.setAttribute("onclick","void(0)");
+ curElement.setAttribute("style","-webkit-tap-highlight-color:rgba(0,0,0,0)");
+ // Loop though eventHandlers and remove mouse listeners
+ for (var i=0, ehl=eventHandlers.length; i<ehl; i++) {
+ var type = eventHandlers[i].type;
+ // Have this function remove itself from the eventHandlers list too
+ if (type === "mouseout" || type === "mousemove" ||
+ type === "mousedown" || type === "mouseup" ||
+ type === "DOMMouseScroll" || type === "mousewheel" || type === "touchstart") {
+ detachEventHandler(eventHandlers[i]);
+ }
+ }
+
+ // If there are any native touch events defined in the sketch, connect all of them
+ // Otherwise, connect all of the emulated mouse events
+ if (p.touchStart !== undef || p.touchMove !== undef ||
+ p.touchEnd !== undef || p.touchCancel !== undef) {
+ attachEventHandler(curElement, "touchstart", function(t) {
+ if (p.touchStart !== undef) {
+ t = addTouchEventOffset(t);
+ p.touchStart(t);
+ }
+ });
+
+ attachEventHandler(curElement, "touchmove", function(t) {
+ if (p.touchMove !== undef) {
+ t.preventDefault(); // Stop the viewport from scrolling
+ t = addTouchEventOffset(t);
+ p.touchMove(t);
+ }
+ });
+
+ attachEventHandler(curElement, "touchend", function(t) {
+ if (p.touchEnd !== undef) {
+ t = addTouchEventOffset(t);
+ p.touchEnd(t);
+ }
+ });
+
+ attachEventHandler(curElement, "touchcancel", function(t) {
+ if (p.touchCancel !== undef) {
+ t = addTouchEventOffset(t);
+ p.touchCancel(t);
+ }
+ });
+
+ } else {
+ // Emulated touch start/mouse down event
+ attachEventHandler(curElement, "touchstart", function(e) {
+ updateMousePosition(curElement, e.touches[0]);
+
+ p.__mousePressed = true;
+ p.mouseDragging = false;
+ p.mouseButton = PConstants.LEFT;
+
+ if (typeof p.mousePressed === "function") {
+ p.mousePressed();
+ }
+ });
+
+ // Emulated touch move/mouse move event
+ attachEventHandler(curElement, "touchmove", function(e) {
+ e.preventDefault();
+ updateMousePosition(curElement, e.touches[0]);
+
+ if (typeof p.mouseMoved === "function" && !p.__mousePressed) {
+ p.mouseMoved();
+ }
+ if (typeof p.mouseDragged === "function" && p.__mousePressed) {
+ p.mouseDragged();
+ p.mouseDragging = true;
+ }
+ });
+
+ // Emulated touch up/mouse up event
+ attachEventHandler(curElement, "touchend", function(e) {
+ p.__mousePressed = false;
+
+ if (typeof p.mouseClicked === "function" && !p.mouseDragging) {
+ p.mouseClicked();
+ }
+
+ if (typeof p.mouseReleased === "function") {
+ p.mouseReleased();
+ }
+ });
+ }
+
+ // Refire the touch start event we consumed in this function
+ curElement.dispatchEvent(t);
+ });
+
+ /**
+ * Context menu toggles. Most often you will not want the
+ * browser's context menu to show on a right click, but
+ * sometimes, you do, so we add two unofficial functions
+ * that can be used to trigger context menu behaviour.
+ */
+ (function() {
+ var enabled = true,
+ contextMenu = function(e) {
+ e.preventDefault();
+ e.stopPropagation();
+ };
+
+ p.disableContextMenu = function() {
+ if (!enabled) {
+ return;
+ }
+ attachEventHandler(curElement, 'contextmenu', contextMenu);
+ enabled = false;
+ };
+
+ p.enableContextMenu = function() {
+ if (enabled) {
+ return;
+ }
+ detachEventHandler({elem: curElement, type: 'contextmenu', fn: contextMenu});
+ enabled = true;
+ };
+ }());
+
+ /**
+ * Mouse moved or dragged
+ */
+ attachEventHandler(curElement, "mousemove", function(e) {
+ updateMousePosition(curElement, e);
+ if (typeof p.mouseMoved === "function" && !p.__mousePressed) {
+ p.mouseMoved();
+ }
+ if (typeof p.mouseDragged === "function" && p.__mousePressed) {
+ p.mouseDragged();
+ p.mouseDragging = true;
+ }
+ });
+
+ /**
+ * Unofficial mouse-out handling
+ */
+ attachEventHandler(curElement, "mouseout", function(e) {
+ if (typeof p.mouseOut === "function") {
+ p.mouseOut();
+ }
+ });
+
+ /**
+ * Mouse over
+ */
+ attachEventHandler(curElement, "mouseover", function(e) {
+ updateMousePosition(curElement, e);
+ if (typeof p.mouseOver === "function") {
+ p.mouseOver();
+ }
+ });
+
+ /**
+ * Disable browser's default handling for click-drag of a canvas.
+ */
+ curElement.onmousedown = function () {
+ // make sure focus happens, but nothing else
+ curElement.focus();
+ return false;
+ };
+
+ /**
+ * Mouse pressed or drag
+ */
+ attachEventHandler(curElement, "mousedown", function(e) {
+ p.__mousePressed = true;
+ p.mouseDragging = false;
+ switch (e.which) {
+ case 1:
+ p.mouseButton = PConstants.LEFT;
+ break;
+ case 2:
+ p.mouseButton = PConstants.CENTER;
+ break;
+ case 3:
+ p.mouseButton = PConstants.RIGHT;
+ break;
+ }
+
+ if (typeof p.mousePressed === "function") {
+ p.mousePressed();
+ }
+ });
+
+ /**
+ * Mouse clicked or released
+ */
+ attachEventHandler(curElement, "mouseup", function(e) {
+ p.__mousePressed = false;
+
+ if (typeof p.mouseClicked === "function" && !p.mouseDragging) {
+ p.mouseClicked();
+ }
+
+ if (typeof p.mouseReleased === "function") {
+ p.mouseReleased();
+ }
+ });
+
+ /**
+ * Unofficial scroll wheel handling.
+ */
+ var mouseWheelHandler = function(e) {
+ // do not handle scroll wheel if initiated outside of the sketch
+ if (e.target !== curElement) return;
+
+ var delta = 0;
+
+ if (e.wheelDelta) {
+ delta = e.wheelDelta / 120;
+ if (window.opera) {
+ delta = -delta;
+ }
+ } else if (e.detail) {
+ delta = -e.detail / 3;
+ }
+
+ p.mouseScroll = delta;
+
+ if (delta && typeof p.mouseScrolled === 'function') {
+ // If this sketch has explicit scroll handling,
+ // prevent scroll from kicking in globally before
+ // calling the scroll handler.
+ e.stopPropagation();
+ e.preventDefault();
+ p.mouseScrolled();
+ }
+ };
+
+ // Support Gecko and non-Gecko scroll events
+ attachEventHandler(document, 'DOMMouseScroll', mouseWheelHandler);
+ attachEventHandler(document, 'mousewheel', mouseWheelHandler);
+
+};
+
+
+},{}],26:[function(require,module,exports){
+/**
+ * The parser for turning Processing syntax into Pjs JavaScript.
+ * This code is not trivial; unless you know what you're doing,
+ * you shouldn't be changing things in here =)
+ */
+module.exports = function setupParser(Processing, options) {
+
+ var defaultScope = options.defaultScope,
+ PConstants = defaultScope.PConstants,
+ aFunctions = options.aFunctions,
+ Browser = options.Browser,
+ document = Browser.document,
+ undef;
+
+ // Processing global methods and constants for the parser
+ function getGlobalMembers() {
+ // The names array contains the names of everything that is inside "p."
+ // When something new is added to "p." it must also be added to this list.
+ var names = [ /* this code is generated by jsglobals.js */
+ "abs", "acos", "alpha", "ambient", "ambientLight", "append", "applyMatrix",
+ "arc", "arrayCopy", "asin", "atan", "atan2", "background", "beginCamera",
+ "beginDraw", "beginShape", "bezier", "bezierDetail", "bezierPoint",
+ "bezierTangent", "bezierVertex", "binary", "blend", "blendColor",
+ "blit_resize", "blue", "box", "breakShape", "brightness",
+ "camera", "ceil", "Character", "color", "colorMode",
+ "concat", "constrain", "copy", "cos", "createFont",
+ "createGraphics", "createImage", "cursor", "curve", "curveDetail",
+ "curvePoint", "curveTangent", "curveTightness", "curveVertex", "day",
+ "degrees", "directionalLight", "disableContextMenu",
+ "dist", "draw", "ellipse", "ellipseMode", "emissive", "enableContextMenu",
+ "endCamera", "endDraw", "endShape", "exit", "exp", "expand", "externals",
+ "fill", "filter", "floor", "focused", "frameCount", "frameRate", "frustum",
+ "get", "glyphLook", "glyphTable", "green", "height", "hex", "hint", "hour",
+ "hue", "image", "imageMode", "intersect", "join", "key",
+ "keyCode", "keyPressed", "keyReleased", "keyTyped", "lerp", "lerpColor",
+ "lightFalloff", "lights", "lightSpecular", "line", "link", "loadBytes",
+ "loadFont", "loadGlyphs", "loadImage", "loadPixels", "loadShape", "loadXML",
+ "loadStrings", "log", "loop", "mag", "map", "match", "matchAll", "max",
+ "millis", "min", "minute", "mix", "modelX", "modelY", "modelZ", "modes",
+ "month", "mouseButton", "mouseClicked", "mouseDragged", "mouseMoved",
+ "mouseOut", "mouseOver", "mousePressed", "mouseReleased", "mouseScroll",
+ "mouseScrolled", "mouseX", "mouseY", "name", "nf", "nfc", "nfp", "nfs",
+ "noCursor", "noFill", "noise", "noiseDetail", "noiseSeed", "noLights",
+ "noLoop", "norm", "normal", "noSmooth", "noStroke", "noTint", "ortho",
+ "param", "parseBoolean", "parseByte", "parseChar", "parseFloat",
+ "parseInt", "parseXML", "peg", "perspective", "PImage", "pixels",
+ "PMatrix2D", "PMatrix3D", "PMatrixStack", "pmouseX", "pmouseY", "point",
+ "pointLight", "popMatrix", "popStyle", "pow", "print", "printCamera",
+ "println", "printMatrix", "printProjection", "PShape", "PShapeSVG",
+ "pushMatrix", "pushStyle", "quad", "radians", "random", "randomGaussian",
+ "randomSeed", "rect", "rectMode", "red", "redraw", "requestImage",
+ "resetMatrix", "reverse", "rotate", "rotateX", "rotateY", "rotateZ",
+ "round", "saturation", "save", "saveFrame", "saveStrings", "scale",
+ "screenX", "screenY", "screenZ", "second", "set", "setup", "shape",
+ "shapeMode", "shared", "shearX", "shearY", "shininess", "shorten", "sin", "size", "smooth",
+ "sort", "specular", "sphere", "sphereDetail", "splice", "split",
+ "splitTokens", "spotLight", "sq", "sqrt", "status", "str", "stroke",
+ "strokeCap", "strokeJoin", "strokeWeight", "subset", "tan", "text",
+ "textAlign", "textAscent", "textDescent", "textFont", "textLeading",
+ "textMode", "textSize", "texture", "textureMode", "textWidth", "tint", "toImageData",
+ "touchCancel", "touchEnd", "touchMove", "touchStart", "translate", "transform",
+ "triangle", "trim", "unbinary", "unhex", "updatePixels", "use3DContext",
+ "vertex", "width", "XMLElement", "XML", "year", "__contains", "__equals",
+ "__equalsIgnoreCase", "__frameRate", "__hashCode", "__int_cast",
+ "__instanceof", "__keyPressed", "__mousePressed", "__printStackTrace",
+ "__replace", "__replaceAll", "__replaceFirst", "__toCharArray", "__split",
+ "__codePointAt", "__startsWith", "__endsWith", "__matches"];
+
+ // custom functions and properties are added here
+ if(aFunctions) {
+ Object.keys(aFunctions).forEach(function(name) {
+ names.push(name);
+ });
+ }
+
+ // custom libraries that were attached to Processing
+ var members = {};
+ var i, l;
+ for (i = 0, l = names.length; i < l ; ++i) {
+ members[names[i]] = null;
+ }
+ for (var lib in Processing.lib) {
+ if (Processing.lib.hasOwnProperty(lib)) {
+ if (Processing.lib[lib].exports) {
+ var exportedNames = Processing.lib[lib].exports;
+ for (i = 0, l = exportedNames.length; i < l; ++i) {
+ members[exportedNames[i]] = null;
+ }
+ }
+ }
+ }
+ return members;
+ }
+
+ /*
+
+ Parser converts Java-like syntax into JavaScript.
+ Creates an Abstract Syntax Tree -- "Light AST" from the Java-like code.
+
+ It is an object tree. The root object is created from the AstRoot class, which contains statements.
+
+ A statement object can be of type: AstForStatement, AstCatchStatement, AstPrefixStatement, AstMethod, AstClass,
+ AstInterface, AstFunction, AstStatementBlock and AstLabel.
+
+ AstPrefixStatement can be a statement of type: if, switch, while, with, do, else, finally, return, throw, try, break, and continue.
+
+ These object's toString function returns the JavaScript code for the statement.
+
+ Any processing calls need "processing." prepended to them.
+
+ Similarly, calls from inside classes need "$this_1.", prepended to them,
+ with 1 being the depth level for inner classes.
+ This includes members passed down from inheritance.
+
+ The resulting code is then eval'd and run.
+
+ */
+
+ function parseProcessing(code) {
+ var globalMembers = getGlobalMembers();
+
+ // masks parentheses, brackets and braces with '"A5"'
+ // where A is the bracket type, and 5 is the index in an array containing all brackets split into atoms
+ // 'while(true){}' -> 'while"B1""A2"'
+ // parentheses() = B, brackets[] = C and braces{} = A
+ function splitToAtoms(code) {
+ var atoms = [];
+ var items = code.split(/([\{\[\(\)\]\}])/);
+ var result = items[0];
+
+ var stack = [];
+ for(var i=1; i < items.length; i += 2) {
+ var item = items[i];
+ if(item === '[' || item === '{' || item === '(') {
+ stack.push(result); result = item;
+ } else if(item === ']' || item === '}' || item === ')') {
+ var kind = item === '}' ? 'A' : item === ')' ? 'B' : 'C';
+ var index = atoms.length; atoms.push(result + item);
+ result = stack.pop() + '"' + kind + (index + 1) + '"';
+ }
+ result += items[i + 1];
+ }
+ atoms.unshift(result);
+ return atoms;
+ }
+
+ // replaces strings and regexs keyed by index with an array of strings
+ function injectStrings(code, strings) {
+ return code.replace(/'(\d+)'/g, function(all, index) {
+ var val = strings[index];
+ if(val.charAt(0) === "/") {
+ return val;
+ }
+ return (/^'((?:[^'\\\n])|(?:\\.[0-9A-Fa-f]*))'$/).test(val) ? "(new $p.Character(" + val + "))" : val;
+ });
+ }
+
+ // trims off leading and trailing spaces
+ // returns an object. object.left, object.middle, object.right, object.untrim
+ function trimSpaces(string) {
+ var m1 = /^\s*/.exec(string), result;
+ if(m1[0].length === string.length) {
+ result = {left: m1[0], middle: "", right: ""};
+ } else {
+ var m2 = /\s*$/.exec(string);
+ result = {left: m1[0], middle: string.substring(m1[0].length, m2.index), right: m2[0]};
+ }
+ result.untrim = function(t) { return this.left + t + this.right; };
+ return result;
+ }
+
+ // simple trim of leading and trailing spaces
+ function trim(string) {
+ return string.replace(/^\s+/,'').replace(/\s+$/,'');
+ }
+
+ function appendToLookupTable(table, array) {
+ for(var i=0,l=array.length;i<l;++i) {
+ table[array[i]] = null;
+ }
+ return table;
+ }
+
+ function isLookupTableEmpty(table) {
+ for(var i in table) {
+ if(table.hasOwnProperty(i)) {
+ return false;
+ }
+ }
+ return true;
+ }
+
+ function getAtomIndex(templ) { return templ.substring(2, templ.length - 1); }
+
+ // remove carriage returns "\r"
+ var codeWoExtraCr = code.replace(/\r\n?|\n\r/g, "\n");
+
+ // masks strings and regexs with "'5'", where 5 is the index in an array containing all strings and regexs
+ // also removes all comments
+ var strings = [];
+ var codeWoStrings = codeWoExtraCr.replace(/("(?:[^"\\\n]|\\.)*")|('(?:[^'\\\n]|\\.)*')|(([\[\(=|&!\^:?]\s*)(\/(?![*\/])(?:[^\/\\\n]|\\.)*\/[gim]*)\b)|(\/\/[^\n]*\n)|(\/\*(?:(?!\*\/)(?:.|\n))*\*\/)/g,
+ function(all, quoted, aposed, regexCtx, prefix, regex, singleComment, comment) {
+ var index;
+ if(quoted || aposed) { // replace strings
+ index = strings.length; strings.push(all);
+ return "'" + index + "'";
+ }
+ if(regexCtx) { // replace RegExps
+ index = strings.length; strings.push(regex);
+ return prefix + "'" + index + "'";
+ }
+ // kill comments
+ return comment !== "" ? " " : "\n";
+ });
+
+ // protect character codes from namespace collision
+ codeWoStrings = codeWoStrings.replace(/__x([0-9A-F]{4})/g, function(all, hexCode) {
+ // $ = __x0024
+ // _ = __x005F
+ // this protects existing character codes from conversion
+ // __x0024 = __x005F_x0024
+ return "__x005F_x" + hexCode;
+ });
+
+ // convert dollar sign to character code
+ codeWoStrings = codeWoStrings.replace(/\$/g, "__x0024");
+
+ // Remove newlines after return statements
+ codeWoStrings = codeWoStrings.replace(/return\s*[\n\r]+/g, "return ");
+
+ // removes generics
+ var genericsWereRemoved;
+ var codeWoGenerics = codeWoStrings;
+ var replaceFunc = function(all, before, types, after) {
+ if(!!before || !!after) {
+ return all;
+ }
+ genericsWereRemoved = true;
+ return "";
+ };
+
+ do {
+ genericsWereRemoved = false;
+ codeWoGenerics = codeWoGenerics.replace(/([<]?)<\s*((?:\?|[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)(?:\[\])*(?:\s+(?:extends|super)\s+[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)?(?:\s*,\s*(?:\?|[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)(?:\[\])*(?:\s+(?:extends|super)\s+[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)?)*)\s*>([=]?)/g, replaceFunc);
+ } while (genericsWereRemoved);
+
+ var atoms = splitToAtoms(codeWoGenerics);
+ var replaceContext;
+ var declaredClasses = {}, currentClassId, classIdSeed = 0;
+
+ function addAtom(text, type) {
+ var lastIndex = atoms.length;
+ atoms.push(text);
+ return '"' + type + lastIndex + '"';
+ }
+
+ function generateClassId() {
+ return "class" + (++classIdSeed);
+ }
+
+ function appendClass(class_, classId, scopeId) {
+ class_.classId = classId;
+ class_.scopeId = scopeId;
+ declaredClasses[classId] = class_;
+ }
+
+ // functions defined below
+ var transformClassBody, transformInterfaceBody, transformStatementsBlock, transformStatements, transformMain, transformExpression;
+
+ var classesRegex = /\b((?:(?:public|private|final|protected|static|abstract)\s+)*)(class|interface)\s+([A-Za-z_$][\w$]*\b)(\s+extends\s+[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*(?:\s*,\s*[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*\b)*)?(\s+implements\s+[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*(?:\s*,\s*[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*\b)*)?\s*("A\d+")/g;
+ var methodsRegex = /\b((?:(?:public|private|final|protected|static|abstract|synchronized)\s+)*)((?!(?:else|new|return|throw|function|public|private|protected)\b)[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*(?:\s*"C\d+")*)\s*([A-Za-z_$][\w$]*\b)\s*("B\d+")(\s*throws\s+[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*(?:\s*,\s*[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)*)?\s*("A\d+"|;)/g;
+ var fieldTest = /^((?:(?:public|private|final|protected|static)\s+)*)((?!(?:else|new|return|throw)\b)[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*(?:\s*"C\d+")*)\s*([A-Za-z_$][\w$]*\b)\s*(?:"C\d+"\s*)*([=,]|$)/;
+ var cstrsRegex = /\b((?:(?:public|private|final|protected|static|abstract)\s+)*)((?!(?:new|return|throw)\b)[A-Za-z_$][\w$]*\b)\s*("B\d+")(\s*throws\s+[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*(?:\s*,\s*[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)*)?\s*("A\d+")/g;
+ var attrAndTypeRegex = /^((?:(?:public|private|final|protected|static)\s+)*)((?!(?:new|return|throw)\b)[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*(?:\s*"C\d+")*)\s*/;
+ var functionsRegex = /\bfunction(?:\s+([A-Za-z_$][\w$]*))?\s*("B\d+")\s*("A\d+")/g;
+
+ // This converts classes, methods and functions into atoms, and adds them to the atoms array.
+ // classes = E, methods = D and functions = H
+ function extractClassesAndMethods(code) {
+ var s = code;
+ s = s.replace(classesRegex, function(all) {
+ return addAtom(all, 'E');
+ });
+ s = s.replace(methodsRegex, function(all) {
+ return addAtom(all, 'D');
+ });
+ s = s.replace(functionsRegex, function(all) {
+ return addAtom(all, 'H');
+ });
+ return s;
+ }
+
+ // This converts constructors into atoms, and adds them to the atoms array.
+ // constructors = G
+ function extractConstructors(code, className) {
+ var result = code.replace(cstrsRegex, function(all, attr, name, params, throws_, body) {
+ if(name !== className) {
+ return all;
+ }
+ return addAtom(all, 'G');
+ });
+ return result;
+ }
+
+ // AstParam contains the name of a parameter inside a function declaration
+ function AstParam(name) {
+ this.name = name;
+ }
+ AstParam.prototype.toString = function() {
+ return this.name;
+ };
+ // AstParams contains an array of AstParam objects
+ function AstParams(params, methodArgsParam) {
+ this.params = params;
+ this.methodArgsParam = methodArgsParam;
+ }
+ AstParams.prototype.getNames = function() {
+ var names = [];
+ for(var i=0,l=this.params.length;i<l;++i) {
+ names.push(this.params[i].name);
+ }
+ return names;
+ };
+ AstParams.prototype.prependMethodArgs = function(body) {
+ if (!this.methodArgsParam) {
+ return body;
+ }
+ return "{\nvar " + this.methodArgsParam.name +
+ " = Array.prototype.slice.call(arguments, " +
+ this.params.length + ");\n" + body.substring(1);
+ };
+ AstParams.prototype.toString = function() {
+ if(this.params.length === 0) {
+ return "()";
+ }
+ var result = "(";
+ for(var i=0,l=this.params.length;i<l;++i) {
+ result += this.params[i] + ", ";
+ }
+ return result.substring(0, result.length - 2) + ")";
+ };
+
+ function transformParams(params) {
+ var paramsWoPars = trim(params.substring(1, params.length - 1));
+ var result = [], methodArgsParam = null;
+ if(paramsWoPars !== "") {
+ var paramList = paramsWoPars.split(",");
+ for(var i=0; i < paramList.length; ++i) {
+ var param = /\b([A-Za-z_$][\w$]*\b)(\s*"[ABC][\d]*")*\s*$/.exec(paramList[i]);
+ if (i === paramList.length - 1 && paramList[i].indexOf('...') >= 0) {
+ methodArgsParam = new AstParam(param[1]);
+ break;
+ }
+ result.push(new AstParam(param[1]));
+ }
+ }
+ return new AstParams(result, methodArgsParam);
+ }
+
+ function preExpressionTransform(expr) {
+ var s = expr;
+ // new type[] {...} --> {...}
+ s = s.replace(/\bnew\s+([A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)(?:\s*"C\d+")+\s*("A\d+")/g, function(all, type, init) {
+ return init;
+ });
+ // new Runnable() {...} --> "F???"
+ s = s.replace(/\bnew\s+([A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)(?:\s*"B\d+")\s*("A\d+")/g, function(all, type, init) {
+ return addAtom(all, 'F');
+ });
+ // function(...) { } --> "H???"
+ s = s.replace(functionsRegex, function(all) {
+ return addAtom(all, 'H');
+ });
+ // new type[?] --> createJavaArray('type', [?])
+ s = s.replace(/\bnew\s+([A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)\s*("C\d+"(?:\s*"C\d+")*)/g, function(all, type, index) {
+ var args = index.replace(/"C(\d+)"/g, function(all, j) { return atoms[j]; })
+ .replace(/\[\s*\]/g, "[null]").replace(/\s*\]\s*\[\s*/g, ", ");
+ var arrayInitializer = "{" + args.substring(1, args.length - 1) + "}";
+ var createArrayArgs = "('" + type + "', " + addAtom(arrayInitializer, 'A') + ")";
+ return '$p.createJavaArray' + addAtom(createArrayArgs, 'B');
+ });
+ // .length() --> .length
+ s = s.replace(/(\.\s*length)\s*"B\d+"/g, "$1");
+ // #000000 --> 0x000000
+ s = s.replace(/#([0-9A-Fa-f]{6})\b/g, function(all, digits) {
+ return "0xFF" + digits;
+ });
+ // delete (type)???, except (int)???
+ s = s.replace(/"B(\d+)"(\s*(?:[\w$']|"B))/g, function(all, index, next) {
+ var atom = atoms[index];
+ if(!/^\(\s*[A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*\s*(?:"C\d+"\s*)*\)$/.test(atom)) {
+ return all;
+ }
+ if(/^\(\s*int\s*\)$/.test(atom)) {
+ return "(int)" + next;
+ }
+ var indexParts = atom.split(/"C(\d+)"/g);
+ if(indexParts.length > 1) {
+ // even items contains atom numbers, can check only first
+ if(! /^\[\s*\]$/.test(atoms[indexParts[1]])) {
+ return all; // fallback - not a cast
+ }
+ }
+ return "" + next;
+ });
+ // (int)??? -> __int_cast(???)
+ s = s.replace(/\(int\)([^,\]\)\}\?\:\*\+\-\/\^\|\%\&\~<\>\=]+)/g, function(all, arg) {
+ var trimmed = trimSpaces(arg);
+ return trimmed.untrim("__int_cast(" + trimmed.middle + ")");
+ });
+ // super() -> $superCstr(), super. -> $super.;
+ s = s.replace(/\bsuper(\s*"B\d+")/g, "$$superCstr$1").replace(/\bsuper(\s*\.)/g, "$$super$1");
+ // 000.43->0.43 and 0010f->10, but not 0010
+ s = s.replace(/\b0+((\d*)(?:\.[\d*])?(?:[eE][\-\+]?\d+)?[fF]?)\b/, function(all, numberWo0, intPart) {
+ if( numberWo0 === intPart) {
+ return all;
+ }
+ return intPart === "" ? "0" + numberWo0 : numberWo0;
+ });
+ // 3.0f -> 3.0
+ s = s.replace(/\b(\.?\d+\.?)[fF]\b/g, "$1");
+ // Weird (?) parsing errors with %
+ s = s.replace(/([^\s])%([^=\s])/g, "$1 % $2");
+ // Since frameRate() and frameRate are different things,
+ // we need to differentiate them somehow. So when we parse
+ // the Processing.js source, replace frameRate so it isn't
+ // confused with frameRate(), as well as keyPressed and mousePressed
+ s = s.replace(/\b(frameRate|keyPressed|mousePressed)\b(?!\s*"B)/g, "__$1");
+ // "boolean", "byte", "int", etc. => "parseBoolean", "parseByte", "parseInt", etc.
+ s = s.replace(/\b(boolean|byte|char|float|int)\s*"B/g, function(all, name) {
+ return "parse" + name.substring(0, 1).toUpperCase() + name.substring(1) + "\"B";
+ });
+ // "pixels" replacements:
+ // pixels[i] = c => pixels.setPixel(i,c) | pixels[i] => pixels.getPixel(i)
+ // pixels.length => pixels.getLength()
+ // pixels = ar => pixels.set(ar) | pixels => pixels.toArray()
+ s = s.replace(/\bpixels\b\s*(("C(\d+)")|\.length)?(\s*=(?!=)([^,\]\)\}]+))?/g,
+ function(all, indexOrLength, index, atomIndex, equalsPart, rightSide) {
+ if(index) {
+ var atom = atoms[atomIndex];
+ if(equalsPart) {
+ return "pixels.setPixel" + addAtom("(" +atom.substring(1, atom.length - 1) +
+ "," + rightSide + ")", 'B');
+ }
+ return "pixels.getPixel" + addAtom("(" + atom.substring(1, atom.length - 1) +
+ ")", 'B');
+ }
+ if(indexOrLength) {
+ // length
+ return "pixels.getLength" + addAtom("()", 'B');
+ }
+ if(equalsPart) {
+ return "pixels.set" + addAtom("(" + rightSide + ")", 'B');
+ }
+ return "pixels.toArray" + addAtom("()", 'B');
+ });
+ // Java method replacements for: replace, replaceAll, replaceFirst, equals, hashCode, etc.
+ // xxx.replace(yyy) -> __replace(xxx, yyy)
+ // "xx".replace(yyy) -> __replace("xx", yyy)
+ var repeatJavaReplacement;
+ function replacePrototypeMethods(all, subject, method, atomIndex) {
+ var atom = atoms[atomIndex];
+ repeatJavaReplacement = true;
+ var trimmed = trimSpaces(atom.substring(1, atom.length - 1));
+ return "__" + method + ( trimmed.middle === "" ? addAtom("(" + subject.replace(/\.\s*$/, "") + ")", 'B') :
+ addAtom("(" + subject.replace(/\.\s*$/, "") + "," + trimmed.middle + ")", 'B') );
+ }
+ do {
+ repeatJavaReplacement = false;
+ s = s.replace(/((?:'\d+'|\b[A-Za-z_$][\w$]*\s*(?:"[BC]\d+")*)\s*\.\s*(?:[A-Za-z_$][\w$]*\s*(?:"[BC]\d+"\s*)*\.\s*)*)(replace|replaceAll|replaceFirst|contains|equals|equalsIgnoreCase|hashCode|toCharArray|printStackTrace|split|startsWith|endsWith|codePointAt|matches)\s*"B(\d+)"/g,
+ replacePrototypeMethods);
+ } while (repeatJavaReplacement);
+ // xxx instanceof yyy -> __instanceof(xxx, yyy)
+ function replaceInstanceof(all, subject, type) {
+ repeatJavaReplacement = true;
+ return "__instanceof" + addAtom("(" + subject + ", " + type + ")", 'B');
+ }
+ do {
+ repeatJavaReplacement = false;
+ s = s.replace(/((?:'\d+'|\b[A-Za-z_$][\w$]*\s*(?:"[BC]\d+")*)\s*(?:\.\s*[A-Za-z_$][\w$]*\s*(?:"[BC]\d+"\s*)*)*)instanceof\s+([A-Za-z_$][\w$]*\s*(?:\.\s*[A-Za-z_$][\w$]*)*)/g,
+ replaceInstanceof);
+ } while (repeatJavaReplacement);
+ // this() -> $constr()
+ s = s.replace(/\bthis(\s*"B\d+")/g, "$$constr$1");
+
+ return s;
+ }
+
+ function AstInlineClass(baseInterfaceName, body) {
+ this.baseInterfaceName = baseInterfaceName;
+ this.body = body;
+ body.owner = this;
+ }
+ AstInlineClass.prototype.toString = function() {
+ return "new (" + this.body + ")";
+ };
+
+ function transformInlineClass(class_) {
+ var m = new RegExp(/\bnew\s*([A-Za-z_$][\w$]*\s*(?:\.\s*[A-Za-z_$][\w$]*)*)\s*"B\d+"\s*"A(\d+)"/).exec(class_);
+ var oldClassId = currentClassId, newClassId = generateClassId();
+ currentClassId = newClassId;
+ var uniqueClassName = m[1] + "$" + newClassId;
+ var inlineClass = new AstInlineClass(uniqueClassName,
+ transformClassBody(atoms[m[2]], uniqueClassName, "", "implements " + m[1]));
+ appendClass(inlineClass, newClassId, oldClassId);
+ currentClassId = oldClassId;
+ return inlineClass;
+ }
+
+ function AstFunction(name, params, body) {
+ this.name = name;
+ this.params = params;
+ this.body = body;
+ }
+ AstFunction.prototype.toString = function() {
+ var oldContext = replaceContext;
+ // saving "this." and parameters
+ var names = appendToLookupTable({"this":null}, this.params.getNames());
+ replaceContext = function (subject) {
+ return names.hasOwnProperty(subject.name) ? subject.name : oldContext(subject);
+ };
+ var result = "function";
+ if(this.name) {
+ result += " " + this.name;
+ }
+ var body = this.params.prependMethodArgs(this.body.toString());
+ result += this.params + " " + body;
+ replaceContext = oldContext;
+ return result;
+ };
+
+ function transformFunction(class_) {
+ var m = new RegExp(/\b([A-Za-z_$][\w$]*)\s*"B(\d+)"\s*"A(\d+)"/).exec(class_);
+ return new AstFunction( m[1] !== "function" ? m[1] : null,
+ transformParams(atoms[m[2]]), transformStatementsBlock(atoms[m[3]]));
+ }
+
+ function AstInlineObject(members) {
+ this.members = members;
+ }
+ AstInlineObject.prototype.toString = function() {
+ var oldContext = replaceContext;
+ replaceContext = function (subject) {
+ return subject.name === "this" ? "this" : oldContext(subject); // saving "this."
+ };
+ var result = "";
+ for(var i=0,l=this.members.length;i<l;++i) {
+ if(this.members[i].label) {
+ result += this.members[i].label + ": ";
+ }
+ result += this.members[i].value.toString() + ", ";
+ }
+ replaceContext = oldContext;
+ return result.substring(0, result.length - 2);
+ };
+
+ function transformInlineObject(obj) {
+ var members = obj.split(',');
+ for(var i=0; i < members.length; ++i) {
+ var label = members[i].indexOf(':');
+ if(label < 0) {
+ members[i] = { value: transformExpression(members[i]) };
+ } else {
+ members[i] = { label: trim(members[i].substring(0, label)),
+ value: transformExpression( trim(members[i].substring(label + 1)) ) };
+ }
+ }
+ return new AstInlineObject(members);
+ }
+
+ function expandExpression(expr) {
+ if(expr.charAt(0) === '(' || expr.charAt(0) === '[') {
+ return expr.charAt(0) + expandExpression(expr.substring(1, expr.length - 1)) + expr.charAt(expr.length - 1);
+ }
+ if(expr.charAt(0) === '{') {
+ if(/^\{\s*(?:[A-Za-z_$][\w$]*|'\d+')\s*:/.test(expr)) {
+ return "{" + addAtom(expr.substring(1, expr.length - 1), 'I') + "}";
+ }
+ return "[" + expandExpression(expr.substring(1, expr.length - 1)) + "]";
+ }
+ var trimmed = trimSpaces(expr);
+ var result = preExpressionTransform(trimmed.middle);
+ result = result.replace(/"[ABC](\d+)"/g, function(all, index) {
+ return expandExpression(atoms[index]);
+ });
+ return trimmed.untrim(result);
+ }
+
+ function replaceContextInVars(expr) {
+ return expr.replace(/(\.\s*)?((?:\b[A-Za-z_]|\$)[\w$]*)(\s*\.\s*([A-Za-z_$][\w$]*)(\s*\()?)?/g,
+ function(all, memberAccessSign, identifier, suffix, subMember, callSign) {
+ if(memberAccessSign) {
+ return all;
+ }
+ var subject = { name: identifier, member: subMember, callSign: !!callSign };
+ return replaceContext(subject) + (suffix === undef ? "" : suffix);
+ });
+ }
+
+ function AstExpression(expr, transforms) {
+ this.expr = expr;
+ this.transforms = transforms;
+ }
+ AstExpression.prototype.toString = function() {
+ var transforms = this.transforms;
+ var expr = replaceContextInVars(this.expr);
+ return expr.replace(/"!(\d+)"/g, function(all, index) {
+ return transforms[index].toString();
+ });
+ };
+
+ transformExpression = function(expr) {
+ var transforms = [];
+ var s = expandExpression(expr);
+ s = s.replace(/"H(\d+)"/g, function(all, index) {
+ transforms.push(transformFunction(atoms[index]));
+ return '"!' + (transforms.length - 1) + '"';
+ });
+ s = s.replace(/"F(\d+)"/g, function(all, index) {
+ transforms.push(transformInlineClass(atoms[index]));
+ return '"!' + (transforms.length - 1) + '"';
+ });
+ s = s.replace(/"I(\d+)"/g, function(all, index) {
+ transforms.push(transformInlineObject(atoms[index]));
+ return '"!' + (transforms.length - 1) + '"';
+ });
+
+ return new AstExpression(s, transforms);
+ };
+
+ function AstVarDefinition(name, value, isDefault) {
+ this.name = name;
+ this.value = value;
+ this.isDefault = isDefault;
+ }
+ AstVarDefinition.prototype.toString = function() {
+ return this.name + ' = ' + this.value;
+ };
+
+ function transformVarDefinition(def, defaultTypeValue) {
+ var eqIndex = def.indexOf("=");
+ var name, value, isDefault;
+ if(eqIndex < 0) {
+ name = def;
+ value = defaultTypeValue;
+ isDefault = true;
+ } else {
+ name = def.substring(0, eqIndex);
+ value = transformExpression(def.substring(eqIndex + 1));
+ isDefault = false;
+ }
+ return new AstVarDefinition( trim(name.replace(/(\s*"C\d+")+/g, "")),
+ value, isDefault);
+ }
+
+ function getDefaultValueForType(type) {
+ if(type === "int" || type === "float") {
+ return "0";
+ }
+ if(type === "boolean") {
+ return "false";
+ }
+ if(type === "color") {
+ return "0x00000000";
+ }
+ return "null";
+ }
+
+ function AstVar(definitions, varType) {
+ this.definitions = definitions;
+ this.varType = varType;
+ }
+ AstVar.prototype.getNames = function() {
+ var names = [];
+ for(var i=0,l=this.definitions.length;i<l;++i) {
+ names.push(this.definitions[i].name);
+ }
+ return names;
+ };
+ AstVar.prototype.toString = function() {
+ return "var " + this.definitions.join(",");
+ };
+ function AstStatement(expression) {
+ this.expression = expression;
+ }
+ AstStatement.prototype.toString = function() {
+ return this.expression.toString();
+ };
+
+ function transformStatement(statement) {
+ if(fieldTest.test(statement)) {
+ var attrAndType = attrAndTypeRegex.exec(statement);
+ var definitions = statement.substring(attrAndType[0].length).split(",");
+ var defaultTypeValue = getDefaultValueForType(attrAndType[2]);
+ for(var i=0; i < definitions.length; ++i) {
+ definitions[i] = transformVarDefinition(definitions[i], defaultTypeValue);
+ }
+ return new AstVar(definitions, attrAndType[2]);
+ }
+ return new AstStatement(transformExpression(statement));
+ }
+
+ function AstForExpression(initStatement, condition, step) {
+ this.initStatement = initStatement;
+ this.condition = condition;
+ this.step = step;
+ }
+ AstForExpression.prototype.toString = function() {
+ return "(" + this.initStatement + "; " + this.condition + "; " + this.step + ")";
+ };
+
+ function AstForInExpression(initStatement, container) {
+ this.initStatement = initStatement;
+ this.container = container;
+ }
+ AstForInExpression.prototype.toString = function() {
+ var init = this.initStatement.toString();
+ if(init.indexOf("=") >= 0) { // can be without var declaration
+ init = init.substring(0, init.indexOf("="));
+ }
+ return "(" + init + " in " + this.container + ")";
+ };
+
+ function AstForEachExpression(initStatement, container) {
+ this.initStatement = initStatement;
+ this.container = container;
+ }
+ AstForEachExpression.iteratorId = 0;
+ AstForEachExpression.prototype.toString = function() {
+ var init = this.initStatement.toString();
+ var iterator = "$it" + (AstForEachExpression.iteratorId++);
+ var variableName = init.replace(/^\s*var\s*/, "").split("=")[0];
+ var initIteratorAndVariable = "var " + iterator + " = new $p.ObjectIterator(" + this.container + "), " +
+ variableName + " = void(0)";
+ var nextIterationCondition = iterator + ".hasNext() && ((" +
+ variableName + " = " + iterator + ".next()) || true)";
+ return "(" + initIteratorAndVariable + "; " + nextIterationCondition + ";)";
+ };
+
+ function transformForExpression(expr) {
+ var content;
+ if (/\bin\b/.test(expr)) {
+ content = expr.substring(1, expr.length - 1).split(/\bin\b/g);
+ return new AstForInExpression( transformStatement(trim(content[0])),
+ transformExpression(content[1]));
+ }
+ if (expr.indexOf(":") >= 0 && expr.indexOf(";") < 0) {
+ content = expr.substring(1, expr.length - 1).split(":");
+ return new AstForEachExpression( transformStatement(trim(content[0])),
+ transformExpression(content[1]));
+ }
+ content = expr.substring(1, expr.length - 1).split(";");
+ return new AstForExpression( transformStatement(trim(content[0])),
+ transformExpression(content[1]), transformExpression(content[2]));
+ }
+
+ function sortByWeight(array) {
+ array.sort(function (a,b) {
+ return b.weight - a.weight;
+ });
+ }
+
+ function AstInnerInterface(name, body, isStatic) {
+ this.name = name;
+ this.body = body;
+ this.isStatic = isStatic;
+ body.owner = this;
+ }
+ AstInnerInterface.prototype.toString = function() {
+ return "" + this.body;
+ };
+ function AstInnerClass(name, body, isStatic) {
+ this.name = name;
+ this.body = body;
+ this.isStatic = isStatic;
+ body.owner = this;
+ }
+ AstInnerClass.prototype.toString = function() {
+ return "" + this.body;
+ };
+
+ function transformInnerClass(class_) {
+ var m = classesRegex.exec(class_); // 1 - attr, 2 - class|int, 3 - name, 4 - extends, 5 - implements, 6 - body
+ classesRegex.lastIndex = 0;
+ var isStatic = m[1].indexOf("static") >= 0;
+ var body = atoms[getAtomIndex(m[6])], innerClass;
+ var oldClassId = currentClassId, newClassId = generateClassId();
+ currentClassId = newClassId;
+ if(m[2] === "interface") {
+ innerClass = new AstInnerInterface(m[3], transformInterfaceBody(body, m[3], m[4]), isStatic);
+ } else {
+ innerClass = new AstInnerClass(m[3], transformClassBody(body, m[3], m[4], m[5]), isStatic);
+ }
+ appendClass(innerClass, newClassId, oldClassId);
+ currentClassId = oldClassId;
+ return innerClass;
+ }
+
+ function AstClassMethod(name, params, body, isStatic) {
+ this.name = name;
+ this.params = params;
+ this.body = body;
+ this.isStatic = isStatic;
+ }
+ AstClassMethod.prototype.toString = function(){
+ var paramNames = appendToLookupTable({}, this.params.getNames());
+ var oldContext = replaceContext;
+ replaceContext = function (subject) {
+ return paramNames.hasOwnProperty(subject.name) ? subject.name : oldContext(subject);
+ };
+ var body = this.params.prependMethodArgs(this.body.toString());
+ var result = "function " + this.methodId + this.params + " " + body +"\n";
+ replaceContext = oldContext;
+ return result;
+ };
+
+ function transformClassMethod(method) {
+ var m = methodsRegex.exec(method);
+ methodsRegex.lastIndex = 0;
+ var isStatic = m[1].indexOf("static") >= 0;
+ var body = m[6] !== ';' ? atoms[getAtomIndex(m[6])] : "{}";
+ return new AstClassMethod(m[3], transformParams(atoms[getAtomIndex(m[4])]),
+ transformStatementsBlock(body), isStatic );
+ }
+
+ function AstClassField(definitions, fieldType, isStatic) {
+ this.definitions = definitions;
+ this.fieldType = fieldType;
+ this.isStatic = isStatic;
+ }
+ AstClassField.prototype.getNames = function() {
+ var names = [];
+ for(var i=0,l=this.definitions.length;i<l;++i) {
+ names.push(this.definitions[i].name);
+ }
+ return names;
+ };
+ AstClassField.prototype.toString = function() {
+ var thisPrefix = replaceContext({ name: "[this]" });
+ if(this.isStatic) {
+ var className = this.owner.name;
+ var staticDeclarations = [];
+ for(var i=0,l=this.definitions.length;i<l;++i) {
+ var definition = this.definitions[i];
+ var name = definition.name, staticName = className + "." + name;
+ var declaration = "if(" + staticName + " === void(0)) {\n" +
+ " " + staticName + " = " + definition.value + "; }\n" +
+ "$p.defineProperty(" + thisPrefix + ", " +
+ "'" + name + "', { get: function(){return " + staticName + ";}, " +
+ "set: function(val){" + staticName + " = val;} });\n";
+ staticDeclarations.push(declaration);
+ }
+ return staticDeclarations.join("");
+ }
+ return thisPrefix + "." + this.definitions.join("; " + thisPrefix + ".");
+ };
+
+ function transformClassField(statement) {
+ var attrAndType = attrAndTypeRegex.exec(statement);
+ var isStatic = attrAndType[1].indexOf("static") >= 0;
+ var definitions = statement.substring(attrAndType[0].length).split(/,\s*/g);
+ var defaultTypeValue = getDefaultValueForType(attrAndType[2]);
+ for(var i=0; i < definitions.length; ++i) {
+ definitions[i] = transformVarDefinition(definitions[i], defaultTypeValue);
+ }
+ return new AstClassField(definitions, attrAndType[2], isStatic);
+ }
+
+ function AstConstructor(params, body) {
+ this.params = params;
+ this.body = body;
+ }
+ AstConstructor.prototype.toString = function() {
+ var paramNames = appendToLookupTable({}, this.params.getNames());
+ var oldContext = replaceContext;
+ replaceContext = function (subject) {
+ return paramNames.hasOwnProperty(subject.name) ? subject.name : oldContext(subject);
+ };
+ var prefix = "function $constr_" + this.params.params.length + this.params.toString();
+ var body = this.params.prependMethodArgs(this.body.toString());
+ if(!/\$(superCstr|constr)\b/.test(body)) {
+ body = "{\n$superCstr();\n" + body.substring(1);
+ }
+ replaceContext = oldContext;
+ return prefix + body + "\n";
+ };
+
+ function transformConstructor(cstr) {
+ var m = new RegExp(/"B(\d+)"\s*"A(\d+)"/).exec(cstr);
+ var params = transformParams(atoms[m[1]]);
+
+ return new AstConstructor(params, transformStatementsBlock(atoms[m[2]]));
+ }
+
+ function AstInterfaceBody(name, interfacesNames, methodsNames, fields, innerClasses, misc) {
+ var i,l;
+ this.name = name;
+ this.interfacesNames = interfacesNames;
+ this.methodsNames = methodsNames;
+ this.fields = fields;
+ this.innerClasses = innerClasses;
+ this.misc = misc;
+ for(i=0,l=fields.length; i<l; ++i) {
+ fields[i].owner = this;
+ }
+ }
+ AstInterfaceBody.prototype.getMembers = function(classFields, classMethods, classInners) {
+ if(this.owner.base) {
+ this.owner.base.body.getMembers(classFields, classMethods, classInners);
+ }
+ var i, j, l, m;
+ for(i=0,l=this.fields.length;i<l;++i) {
+ var fieldNames = this.fields[i].getNames();
+ for(j=0,m=fieldNames.length;j<m;++j) {
+ classFields[fieldNames[j]] = this.fields[i];
+ }
+ }
+ for(i=0,l=this.methodsNames.length;i<l;++i) {
+ var methodName = this.methodsNames[i];
+ classMethods[methodName] = true;
+ }
+ for(i=0,l=this.innerClasses.length;i<l;++i) {
+ var innerClass = this.innerClasses[i];
+ classInners[innerClass.name] = innerClass;
+ }
+ };
+ AstInterfaceBody.prototype.toString = function() {
+ function getScopeLevel(p) {
+ var i = 0;
+ while(p) {
+ ++i;
+ p=p.scope;
+ }
+ return i;
+ }
+
+ var scopeLevel = getScopeLevel(this.owner);
+
+ var className = this.name;
+ var staticDefinitions = "";
+ var metadata = "";
+
+ var thisClassFields = {}, thisClassMethods = {}, thisClassInners = {};
+ this.getMembers(thisClassFields, thisClassMethods, thisClassInners);
+
+ var i, l, j, m;
+
+ if (this.owner.interfaces) {
+ // interface name can be present, but interface is not
+ var resolvedInterfaces = [], resolvedInterface;
+ for (i = 0, l = this.interfacesNames.length; i < l; ++i) {
+ if (!this.owner.interfaces[i]) {
+ continue;
+ }
+ resolvedInterface = replaceContext({name: this.interfacesNames[i]});
+ resolvedInterfaces.push(resolvedInterface);
+ staticDefinitions += "$p.extendInterfaceMembers(" + className + ", " + resolvedInterface + ");\n";
+ }
+ metadata += className + ".$interfaces = [" + resolvedInterfaces.join(", ") + "];\n";
+ }
+ metadata += className + ".$isInterface = true;\n";
+ metadata += className + ".$methods = [\'" + this.methodsNames.join("\', \'") + "\'];\n";
+
+ sortByWeight(this.innerClasses);
+ for (i = 0, l = this.innerClasses.length; i < l; ++i) {
+ var innerClass = this.innerClasses[i];
+ if (innerClass.isStatic) {
+ staticDefinitions += className + "." + innerClass.name + " = " + innerClass + ";\n";
+ }
+ }
+
+ for (i = 0, l = this.fields.length; i < l; ++i) {
+ var field = this.fields[i];
+ if (field.isStatic) {
+ staticDefinitions += className + "." + field.definitions.join(";\n" + className + ".") + ";\n";
+ }
+ }
+
+ return "(function() {\n" +
+ "function " + className + "() { throw \'Unable to create the interface\'; }\n" +
+ staticDefinitions +
+ metadata +
+ "return " + className + ";\n" +
+ "})()";
+ };
+
+ transformInterfaceBody = function(body, name, baseInterfaces) {
+ var declarations = body.substring(1, body.length - 1);
+ declarations = extractClassesAndMethods(declarations);
+ declarations = extractConstructors(declarations, name);
+ var methodsNames = [], classes = [];
+ declarations = declarations.replace(/"([DE])(\d+)"/g, function(all, type, index) {
+ if(type === 'D') { methodsNames.push(index); }
+ else if(type === 'E') { classes.push(index); }
+ return "";
+ });
+ var fields = declarations.split(/;(?:\s*;)*/g);
+ var baseInterfaceNames;
+ var i, l;
+
+ if(baseInterfaces !== undef) {
+ baseInterfaceNames = baseInterfaces.replace(/^\s*extends\s+(.+?)\s*$/g, "$1").split(/\s*,\s*/g);
+ }
+
+ for(i = 0, l = methodsNames.length; i < l; ++i) {
+ var method = transformClassMethod(atoms[methodsNames[i]]);
+ methodsNames[i] = method.name;
+ }
+ for(i = 0, l = fields.length - 1; i < l; ++i) {
+ var field = trimSpaces(fields[i]);
+ fields[i] = transformClassField(field.middle);
+ }
+ var tail = fields.pop();
+ for(i = 0, l = classes.length; i < l; ++i) {
+ classes[i] = transformInnerClass(atoms[classes[i]]);
+ }
+
+ return new AstInterfaceBody(name, baseInterfaceNames, methodsNames, fields, classes, { tail: tail });
+ };
+
+ function AstClassBody(name, baseClassName, interfacesNames, functions, methods, fields, cstrs, innerClasses, misc) {
+ var i,l;
+ this.name = name;
+ this.baseClassName = baseClassName;
+ this.interfacesNames = interfacesNames;
+ this.functions = functions;
+ this.methods = methods;
+ this.fields = fields;
+ this.cstrs = cstrs;
+ this.innerClasses = innerClasses;
+ this.misc = misc;
+ for(i=0,l=fields.length; i<l; ++i) {
+ fields[i].owner = this;
+ }
+ }
+ AstClassBody.prototype.getMembers = function(classFields, classMethods, classInners) {
+ if(this.owner.base) {
+ this.owner.base.body.getMembers(classFields, classMethods, classInners);
+ }
+ var i, j, l, m;
+ for(i=0,l=this.fields.length;i<l;++i) {
+ var fieldNames = this.fields[i].getNames();
+ for(j=0,m=fieldNames.length;j<m;++j) {
+ classFields[fieldNames[j]] = this.fields[i];
+ }
+ }
+ for(i=0,l=this.methods.length;i<l;++i) {
+ var method = this.methods[i];
+ classMethods[method.name] = method;
+ }
+ for(i=0,l=this.innerClasses.length;i<l;++i) {
+ var innerClass = this.innerClasses[i];
+ classInners[innerClass.name] = innerClass;
+ }
+ };
+ AstClassBody.prototype.toString = function() {
+ function getScopeLevel(p) {
+ var i = 0;
+ while(p) {
+ ++i;
+ p=p.scope;
+ }
+ return i;
+ }
+
+ var scopeLevel = getScopeLevel(this.owner);
+
+ var selfId = "$this_" + scopeLevel;
+ var className = this.name;
+ var result = "var " + selfId + " = this;\n";
+ var staticDefinitions = "";
+ var metadata = "";
+
+ var thisClassFields = {}, thisClassMethods = {}, thisClassInners = {};
+ this.getMembers(thisClassFields, thisClassMethods, thisClassInners);
+
+ var oldContext = replaceContext;
+ replaceContext = function (subject) {
+ var name = subject.name;
+ if(name === "this") {
+ // returns "$this_N.$self" pointer instead of "this" in cases:
+ // "this()", "this.XXX()", "this", but not for "this.XXX"
+ return subject.callSign || !subject.member ? selfId + ".$self" : selfId;
+ }
+ if(thisClassFields.hasOwnProperty(name)) {
+ return thisClassFields[name].isStatic ? className + "." + name : selfId + "." + name;
+ }
+ if(thisClassInners.hasOwnProperty(name)) {
+ return selfId + "." + name;
+ }
+ if(thisClassMethods.hasOwnProperty(name)) {
+ return thisClassMethods[name].isStatic ? className + "." + name : selfId + ".$self." + name;
+ }
+ return oldContext(subject);
+ };
+
+ var resolvedBaseClassName;
+ if (this.baseClassName) {
+ resolvedBaseClassName = oldContext({name: this.baseClassName});
+ result += "var $super = { $upcast: " + selfId + " };\n";
+ result += "function $superCstr(){" + resolvedBaseClassName +
+ ".apply($super,arguments);if(!('$self' in $super)) $p.extendClassChain($super)}\n";
+ metadata += className + ".$base = " + resolvedBaseClassName + ";\n";
+ } else {
+ result += "function $superCstr(){$p.extendClassChain("+ selfId +")}\n";
+ }
+
+ if (this.owner.base) {
+ // base class name can be present, but class is not
+ staticDefinitions += "$p.extendStaticMembers(" + className + ", " + resolvedBaseClassName + ");\n";
+ }
+
+ var i, l, j, m;
+
+ if (this.owner.interfaces) {
+ // interface name can be present, but interface is not
+ var resolvedInterfaces = [], resolvedInterface;
+ for (i = 0, l = this.interfacesNames.length; i < l; ++i) {
+ if (!this.owner.interfaces[i]) {
+ continue;
+ }
+ resolvedInterface = oldContext({name: this.interfacesNames[i]});
+ resolvedInterfaces.push(resolvedInterface);
+ staticDefinitions += "$p.extendInterfaceMembers(" + className + ", " + resolvedInterface + ");\n";
+ }
+ metadata += className + ".$interfaces = [" + resolvedInterfaces.join(", ") + "];\n";
+ }
+
+ if (this.functions.length > 0) {
+ result += this.functions.join('\n') + '\n';
+ }
+
+ sortByWeight(this.innerClasses);
+ for (i = 0, l = this.innerClasses.length; i < l; ++i) {
+ var innerClass = this.innerClasses[i];
+ if (innerClass.isStatic) {
+ staticDefinitions += className + "." + innerClass.name + " = " + innerClass + ";\n";
+ result += selfId + "." + innerClass.name + " = " + className + "." + innerClass.name + ";\n";
+ } else {
+ result += selfId + "." + innerClass.name + " = " + innerClass + ";\n";
+ }
+ }
+
+ for (i = 0, l = this.fields.length; i < l; ++i) {
+ var field = this.fields[i];
+ if (field.isStatic) {
+ staticDefinitions += className + "." + field.definitions.join(";\n" + className + ".") + ";\n";
+ for (j = 0, m = field.definitions.length; j < m; ++j) {
+ var fieldName = field.definitions[j].name, staticName = className + "." + fieldName;
+ result += "$p.defineProperty(" + selfId + ", '" + fieldName + "', {" +
+ "get: function(){return " + staticName + "}, " +
+ "set: function(val){" + staticName + " = val}});\n";
+ }
+ } else {
+ result += selfId + "." + field.definitions.join(";\n" + selfId + ".") + ";\n";
+ }
+ }
+ var methodOverloads = {};
+ for (i = 0, l = this.methods.length; i < l; ++i) {
+ var method = this.methods[i];
+ var overload = methodOverloads[method.name];
+ var methodId = method.name + "$" + method.params.params.length;
+ var hasMethodArgs = !!method.params.methodArgsParam;
+ if (overload) {
+ ++overload;
+ methodId += "_" + overload;
+ } else {
+ overload = 1;
+ }
+ method.methodId = methodId;
+ methodOverloads[method.name] = overload;
+ if (method.isStatic) {
+ staticDefinitions += method;
+ staticDefinitions += "$p.addMethod(" + className + ", '" + method.name + "', " + methodId + ", " + hasMethodArgs + ");\n";
+ result += "$p.addMethod(" + selfId + ", '" + method.name + "', " + methodId + ", " + hasMethodArgs + ");\n";
+ } else {
+ result += method;
+ result += "$p.addMethod(" + selfId + ", '" + method.name + "', " + methodId + ", " + hasMethodArgs + ");\n";
+ }
+ }
+ result += trim(this.misc.tail);
+
+ if (this.cstrs.length > 0) {
+ result += this.cstrs.join('\n') + '\n';
+ }
+
+ result += "function $constr() {\n";
+ var cstrsIfs = [];
+ for (i = 0, l = this.cstrs.length; i < l; ++i) {
+ var paramsLength = this.cstrs[i].params.params.length;
+ var methodArgsPresent = !!this.cstrs[i].params.methodArgsParam;
+ cstrsIfs.push("if(arguments.length " + (methodArgsPresent ? ">=" : "===") +
+ " " + paramsLength + ") { " +
+ "$constr_" + paramsLength + ".apply(" + selfId + ", arguments); }");
+ }
+ if(cstrsIfs.length > 0) {
+ result += cstrsIfs.join(" else ") + " else ";
+ }
+ // ??? add check if length is 0, otherwise fail
+ result += "$superCstr();\n}\n";
+ result += "$constr.apply(null, arguments);\n";
+
+ replaceContext = oldContext;
+ return "(function() {\n" +
+ "function " + className + "() {\n" + result + "}\n" +
+ staticDefinitions +
+ metadata +
+ "return " + className + ";\n" +
+ "})()";
+ };
+
+ transformClassBody = function(body, name, baseName, interfaces) {
+ var declarations = body.substring(1, body.length - 1);
+ declarations = extractClassesAndMethods(declarations);
+ declarations = extractConstructors(declarations, name);
+ var methods = [], classes = [], cstrs = [], functions = [];
+ declarations = declarations.replace(/"([DEGH])(\d+)"/g, function(all, type, index) {
+ if(type === 'D') { methods.push(index); }
+ else if(type === 'E') { classes.push(index); }
+ else if(type === 'H') { functions.push(index); }
+ else { cstrs.push(index); }
+ return "";
+ });
+ var fields = declarations.replace(/^(?:\s*;)+/, "").split(/;(?:\s*;)*/g);
+ var baseClassName, interfacesNames;
+ var i;
+
+ if(baseName !== undef) {
+ baseClassName = baseName.replace(/^\s*extends\s+([A-Za-z_$][\w$]*\b(?:\s*\.\s*[A-Za-z_$][\w$]*\b)*)\s*$/g, "$1");
+ }
+
+ if(interfaces !== undef) {
+ interfacesNames = interfaces.replace(/^\s*implements\s+(.+?)\s*$/g, "$1").split(/\s*,\s*/g);
+ }
+
+ for(i = 0; i < functions.length; ++i) {
+ functions[i] = transformFunction(atoms[functions[i]]);
+ }
+ for(i = 0; i < methods.length; ++i) {
+ methods[i] = transformClassMethod(atoms[methods[i]]);
+ }
+ for(i = 0; i < fields.length - 1; ++i) {
+ var field = trimSpaces(fields[i]);
+ fields[i] = transformClassField(field.middle);
+ }
+ var tail = fields.pop();
+ for(i = 0; i < cstrs.length; ++i) {
+ cstrs[i] = transformConstructor(atoms[cstrs[i]]);
+ }
+ for(i = 0; i < classes.length; ++i) {
+ classes[i] = transformInnerClass(atoms[classes[i]]);
+ }
+
+ return new AstClassBody(name, baseClassName, interfacesNames, functions, methods, fields, cstrs,
+ classes, { tail: tail });
+ };
+
+ function AstInterface(name, body) {
+ this.name = name;
+ this.body = body;
+ body.owner = this;
+ }
+ AstInterface.prototype.toString = function() {
+ return "var " + this.name + " = " + this.body + ";\n" +
+ "$p." + this.name + " = " + this.name + ";\n";
+ };
+ function AstClass(name, body) {
+ this.name = name;
+ this.body = body;
+ body.owner = this;
+ }
+ AstClass.prototype.toString = function() {
+ return "var " + this.name + " = " + this.body + ";\n" +
+ "$p." + this.name + " = " + this.name + ";\n";
+ };
+
+ function transformGlobalClass(class_) {
+ var m = classesRegex.exec(class_); // 1 - attr, 2 - class|int, 3 - name, 4 - extends, 5 - implements, 6 - body
+ classesRegex.lastIndex = 0;
+ var body = atoms[getAtomIndex(m[6])];
+ var oldClassId = currentClassId, newClassId = generateClassId();
+ currentClassId = newClassId;
+ var globalClass;
+ if(m[2] === "interface") {
+ globalClass = new AstInterface(m[3], transformInterfaceBody(body, m[3], m[4]) );
+ } else {
+ globalClass = new AstClass(m[3], transformClassBody(body, m[3], m[4], m[5]) );
+ }
+ appendClass(globalClass, newClassId, oldClassId);
+ currentClassId = oldClassId;
+ return globalClass;
+ }
+
+ function AstMethod(name, params, body) {
+ this.name = name;
+ this.params = params;
+ this.body = body;
+ }
+ AstMethod.prototype.toString = function(){
+ var paramNames = appendToLookupTable({}, this.params.getNames());
+ var oldContext = replaceContext;
+ replaceContext = function (subject) {
+ return paramNames.hasOwnProperty(subject.name) ? subject.name : oldContext(subject);
+ };
+ var body = this.params.prependMethodArgs(this.body.toString());
+ var result = "function " + this.name + this.params + " " + body + "\n" +
+ "$p." + this.name + " = " + this.name + ";\n" +
+ this.name + " = " + this.name + ".bind($p);";
+// "$p." + this.name + " = " + this.name + ";";
+ replaceContext = oldContext;
+ return result;
+ };
+
+ function transformGlobalMethod(method) {
+ var m = methodsRegex.exec(method);
+ var result =
+ methodsRegex.lastIndex = 0;
+ return new AstMethod(m[3], transformParams(atoms[getAtomIndex(m[4])]),
+ transformStatementsBlock(atoms[getAtomIndex(m[6])]));
+ }
+
+ function preStatementsTransform(statements) {
+ var s = statements;
+ // turns multiple catch blocks into one, because we have no way to properly get into them anyway.
+ s = s.replace(/\b(catch\s*"B\d+"\s*"A\d+")(\s*catch\s*"B\d+"\s*"A\d+")+/g, "$1");
+ return s;
+ }
+
+ function AstForStatement(argument, misc) {
+ this.argument = argument;
+ this.misc = misc;
+ }
+ AstForStatement.prototype.toString = function() {
+ return this.misc.prefix + this.argument.toString();
+ };
+ function AstCatchStatement(argument, misc) {
+ this.argument = argument;
+ this.misc = misc;
+ }
+ AstCatchStatement.prototype.toString = function() {
+ return this.misc.prefix + this.argument.toString();
+ };
+ function AstPrefixStatement(name, argument, misc) {
+ this.name = name;
+ this.argument = argument;
+ this.misc = misc;
+ }
+ AstPrefixStatement.prototype.toString = function() {
+ var result = this.misc.prefix;
+ if(this.argument !== undef) {
+ result += this.argument.toString();
+ }
+ return result;
+ };
+ function AstSwitchCase(expr) {
+ this.expr = expr;
+ }
+ AstSwitchCase.prototype.toString = function() {
+ return "case " + this.expr + ":";
+ };
+ function AstLabel(label) {
+ this.label = label;
+ }
+ AstLabel.prototype.toString = function() {
+ return this.label;
+ };
+
+ transformStatements = function(statements, transformMethod, transformClass) {
+ var nextStatement = new RegExp(/\b(catch|for|if|switch|while|with)\s*"B(\d+)"|\b(do|else|finally|return|throw|try|break|continue)\b|("[ADEH](\d+)")|\b(case)\s+([^:]+):|\b([A-Za-z_$][\w$]*\s*:)|(;)/g);
+ var res = [];
+ statements = preStatementsTransform(statements);
+ var lastIndex = 0, m, space;
+ // m contains the matches from the nextStatement regexp, null if there are no matches.
+ // nextStatement.exec starts searching at nextStatement.lastIndex.
+ while((m = nextStatement.exec(statements)) !== null) {
+ if(m[1] !== undef) { // catch, for ...
+ var i = statements.lastIndexOf('"B', nextStatement.lastIndex);
+ var statementsPrefix = statements.substring(lastIndex, i);
+ if(m[1] === "for") {
+ res.push(new AstForStatement(transformForExpression(atoms[m[2]]),
+ { prefix: statementsPrefix }) );
+ } else if(m[1] === "catch") {
+ res.push(new AstCatchStatement(transformParams(atoms[m[2]]),
+ { prefix: statementsPrefix }) );
+ } else {
+ res.push(new AstPrefixStatement(m[1], transformExpression(atoms[m[2]]),
+ { prefix: statementsPrefix }) );
+ }
+ } else if(m[3] !== undef) { // do, else, ...
+ res.push(new AstPrefixStatement(m[3], undef,
+ { prefix: statements.substring(lastIndex, nextStatement.lastIndex) }) );
+ } else if(m[4] !== undef) { // block, class and methods
+ space = statements.substring(lastIndex, nextStatement.lastIndex - m[4].length);
+ if(trim(space).length !== 0) { continue; } // avoiding new type[] {} construct
+ res.push(space);
+ var kind = m[4].charAt(1), atomIndex = m[5];
+ if(kind === 'D') {
+ res.push(transformMethod(atoms[atomIndex]));
+ } else if(kind === 'E') {
+ res.push(transformClass(atoms[atomIndex]));
+ } else if(kind === 'H') {
+ res.push(transformFunction(atoms[atomIndex]));
+ } else {
+ res.push(transformStatementsBlock(atoms[atomIndex]));
+ }
+ } else if(m[6] !== undef) { // switch case
+ res.push(new AstSwitchCase(transformExpression(trim(m[7]))));
+ } else if(m[8] !== undef) { // label
+ space = statements.substring(lastIndex, nextStatement.lastIndex - m[8].length);
+ if(trim(space).length !== 0) { continue; } // avoiding ?: construct
+ res.push(new AstLabel(statements.substring(lastIndex, nextStatement.lastIndex)) );
+ } else { // semicolon
+ var statement = trimSpaces(statements.substring(lastIndex, nextStatement.lastIndex - 1));
+ res.push(statement.left);
+ res.push(transformStatement(statement.middle));
+ res.push(statement.right + ";");
+ }
+ lastIndex = nextStatement.lastIndex;
+ }
+ var statementsTail = trimSpaces(statements.substring(lastIndex));
+ res.push(statementsTail.left);
+ if(statementsTail.middle !== "") {
+ res.push(transformStatement(statementsTail.middle));
+ res.push(";" + statementsTail.right);
+ }
+ return res;
+ };
+
+ function getLocalNames(statements) {
+ var localNames = [];
+ for(var i=0,l=statements.length;i<l;++i) {
+ var statement = statements[i];
+ if(statement instanceof AstVar) {
+ localNames = localNames.concat(statement.getNames());
+ } else if(statement instanceof AstForStatement &&
+ statement.argument.initStatement instanceof AstVar) {
+ localNames = localNames.concat(statement.argument.initStatement.getNames());
+ } else if(statement instanceof AstInnerInterface || statement instanceof AstInnerClass ||
+ statement instanceof AstInterface || statement instanceof AstClass ||
+ statement instanceof AstMethod || statement instanceof AstFunction) {
+ localNames.push(statement.name);
+ }
+ }
+ return appendToLookupTable({}, localNames);
+ }
+
+ function AstStatementsBlock(statements) {
+ this.statements = statements;
+ }
+ AstStatementsBlock.prototype.toString = function() {
+ var localNames = getLocalNames(this.statements);
+ var oldContext = replaceContext;
+
+ // replacing context only when necessary
+ if(!isLookupTableEmpty(localNames)) {
+ replaceContext = function (subject) {
+ return localNames.hasOwnProperty(subject.name) ? subject.name : oldContext(subject);
+ };
+ }
+
+ var result = "{\n" + this.statements.join('') + "\n}";
+ replaceContext = oldContext;
+ return result;
+ };
+
+ transformStatementsBlock = function(block) {
+ var content = trimSpaces(block.substring(1, block.length - 1));
+ return new AstStatementsBlock(transformStatements(content.middle));
+ };
+
+ function AstRoot(statements) {
+ this.statements = statements;
+ }
+ AstRoot.prototype.toString = function() {
+ var classes = [], otherStatements = [], statement;
+ for (var i = 0, len = this.statements.length; i < len; ++i) {
+ statement = this.statements[i];
+ if (statement instanceof AstClass || statement instanceof AstInterface) {
+ classes.push(statement);
+ } else {
+ otherStatements.push(statement);
+ }
+ }
+ sortByWeight(classes);
+
+ var localNames = getLocalNames(this.statements);
+ replaceContext = function (subject) {
+ var name = subject.name;
+ if(localNames.hasOwnProperty(name)) {
+ return name;
+ }
+ if(globalMembers.hasOwnProperty(name) ||
+ PConstants.hasOwnProperty(name) ||
+ defaultScope.hasOwnProperty(name)) {
+ return "$p." + name;
+ }
+ return name;
+ };
+ var result = "// this code was autogenerated from PJS\n" +
+ "(function($p) {\n" +
+ classes.join('') + "\n" +
+ otherStatements.join('') + "\n})";
+ replaceContext = null;
+ return result;
+ };
+
+ transformMain = function() {
+ var statements = extractClassesAndMethods(atoms[0]);
+ statements = statements.replace(/\bimport\s+[^;]+;/g, "");
+ return new AstRoot( transformStatements(statements,
+ transformGlobalMethod, transformGlobalClass) );
+ };
+
+ function generateMetadata(ast) {
+ var globalScope = {};
+ var id, class_;
+ for(id in declaredClasses) {
+ if(declaredClasses.hasOwnProperty(id)) {
+ class_ = declaredClasses[id];
+ var scopeId = class_.scopeId, name = class_.name;
+ if(scopeId) {
+ var scope = declaredClasses[scopeId];
+ class_.scope = scope;
+ if(scope.inScope === undef) {
+ scope.inScope = {};
+ }
+ scope.inScope[name] = class_;
+ } else {
+ globalScope[name] = class_;
+ }
+ }
+ }
+
+ function findInScopes(class_, name) {
+ var parts = name.split('.');
+ var currentScope = class_.scope, found;
+ while(currentScope) {
+ if(currentScope.hasOwnProperty(parts[0])) {
+ found = currentScope[parts[0]]; break;
+ }
+ currentScope = currentScope.scope;
+ }
+ if(found === undef) {
+ found = globalScope[parts[0]];
+ }
+ for(var i=1,l=parts.length;i<l && found;++i) {
+ found = found.inScope[parts[i]];
+ }
+ return found;
+ }
+
+ for(id in declaredClasses) {
+ if(declaredClasses.hasOwnProperty(id)) {
+ class_ = declaredClasses[id];
+ var baseClassName = class_.body.baseClassName;
+ if(baseClassName) {
+ var parent = findInScopes(class_, baseClassName);
+ if (parent) {
+ class_.base = parent;
+ if (!parent.derived) {
+ parent.derived = [];
+ }
+ parent.derived.push(class_);
+ }
+ }
+ var interfacesNames = class_.body.interfacesNames,
+ interfaces = [], i, l;
+ if (interfacesNames && interfacesNames.length > 0) {
+ for (i = 0, l = interfacesNames.length; i < l; ++i) {
+ var interface_ = findInScopes(class_, interfacesNames[i]);
+ interfaces.push(interface_);
+ if (!interface_) {
+ continue;
+ }
+ if (!interface_.derived) {
+ interface_.derived = [];
+ }
+ interface_.derived.push(class_);
+ }
+ if (interfaces.length > 0) {
+ class_.interfaces = interfaces;
+ }
+ }
+ }
+ }
+ }
+
+ function setWeight(ast) {
+ var queue = [], tocheck = {};
+ var id, scopeId, class_;
+ // queue most inner and non-inherited
+ for (id in declaredClasses) {
+ if (declaredClasses.hasOwnProperty(id)) {
+ class_ = declaredClasses[id];
+ if (!class_.inScope && !class_.derived) {
+ queue.push(id);
+ class_.weight = 0;
+ } else {
+ var dependsOn = [];
+ if (class_.inScope) {
+ for (scopeId in class_.inScope) {
+ if (class_.inScope.hasOwnProperty(scopeId)) {
+ dependsOn.push(class_.inScope[scopeId]);
+ }
+ }
+ }
+ if (class_.derived) {
+ dependsOn = dependsOn.concat(class_.derived);
+ }
+ tocheck[id] = dependsOn;
+ }
+ }
+ }
+ function removeDependentAndCheck(targetId, from) {
+ var dependsOn = tocheck[targetId];
+ if (!dependsOn) {
+ return false; // no need to process
+ }
+ var i = dependsOn.indexOf(from);
+ if (i < 0) {
+ return false;
+ }
+ dependsOn.splice(i, 1);
+ if (dependsOn.length > 0) {
+ return false;
+ }
+ delete tocheck[targetId];
+ return true;
+ }
+ while (queue.length > 0) {
+ id = queue.shift();
+ class_ = declaredClasses[id];
+ if (class_.scopeId && removeDependentAndCheck(class_.scopeId, class_)) {
+ queue.push(class_.scopeId);
+ declaredClasses[class_.scopeId].weight = class_.weight + 1;
+ }
+ if (class_.base && removeDependentAndCheck(class_.base.classId, class_)) {
+ queue.push(class_.base.classId);
+ class_.base.weight = class_.weight + 1;
+ }
+ if (class_.interfaces) {
+ var i, l;
+ for (i = 0, l = class_.interfaces.length; i < l; ++i) {
+ if (!class_.interfaces[i] ||
+ !removeDependentAndCheck(class_.interfaces[i].classId, class_)) {
+ continue;
+ }
+ queue.push(class_.interfaces[i].classId);
+ class_.interfaces[i].weight = class_.weight + 1;
+ }
+ }
+ }
+ }
+
+ var transformed = transformMain();
+ generateMetadata(transformed);
+ setWeight(transformed);
+
+ var redendered = transformed.toString();
+
+ // remove empty extra lines with space
+ redendered = redendered.replace(/\s*\n(?:[\t ]*\n)+/g, "\n\n");
+
+ // convert character codes to characters
+ redendered = redendered.replace(/__x([0-9A-F]{4})/g, function(all, hexCode) {
+ return String.fromCharCode(parseInt(hexCode,16));
+ });
+
+ return injectStrings(redendered, strings);
+ }// Parser ends
+
+ function preprocessCode(aCode, sketch) {
+ // Parse out @pjs directive, if any.
+ var dm = new RegExp(/\/\*\s*@pjs\s+((?:[^\*]|\*+[^\*\/])*)\*\//g).exec(aCode);
+ if (dm && dm.length === 2) {
+ // masks contents of a JSON to be replaced later
+ // to protect the contents from further parsing
+ var jsonItems = [],
+ directives = dm.splice(1, 2)[0].replace(/\{([\s\S]*?)\}/g, (function() {
+ return function(all, item) {
+ jsonItems.push(item);
+ return "{" + (jsonItems.length-1) + "}";
+ };
+ }())).replace('\n', '').replace('\r', '').split(";");
+
+ // We'll L/RTrim, and also remove any surrounding double quotes (e.g., just take string contents)
+ var clean = function(s) {
+ return s.replace(/^\s*["']?/, '').replace(/["']?\s*$/, '');
+ };
+
+ for (var i = 0, dl = directives.length; i < dl; i++) {
+ var pair = directives[i].split('=');
+ if (pair && pair.length === 2) {
+ var key = clean(pair[0]),
+ value = clean(pair[1]),
+ list = [];
+ // A few directives require work beyond storying key/value pairings
+ if (key === "preload") {
+ list = value.split(',');
+ // All pre-loaded images will get put in imageCache, keyed on filename
+ for (var j = 0, jl = list.length; j < jl; j++) {
+ var imageName = clean(list[j]);
+ sketch.imageCache.add(imageName);
+ }
+ // fonts can be declared as a string containing a url,
+ // or a JSON object, containing a font name, and a url
+ } else if (key === "font") {
+ list = value.split(",");
+ for (var x = 0, xl = list.length; x < xl; x++) {
+ var fontName = clean(list[x]),
+ index = /^\{(\d*?)\}$/.exec(fontName);
+ // if index is not null, send JSON, otherwise, send string
+ PFont.preloading.add(index ? JSON.parse("{" + jsonItems[index[1]] + "}") : fontName);
+ }
+ } else if (key === "pauseOnBlur") {
+ sketch.options.pauseOnBlur = value === "true";
+ } else if (key === "globalKeyEvents") {
+ sketch.options.globalKeyEvents = value === "true";
+ } else if (key.substring(0, 6) === "param-") {
+ sketch.params[key.substring(6)] = value;
+ } else {
+ sketch.options[key] = value;
+ }
+ }
+ }
+ }
+ return aCode;
+ }
+
+ // Parse/compiles Processing (Java-like) syntax to JavaScript syntax
+ Processing.compile = function(pdeCode) {
+ var sketch = new Processing.Sketch();
+ var code = preprocessCode(pdeCode, sketch);
+ var compiledPde = parseProcessing(code);
+ sketch.sourceCode = compiledPde;
+ return sketch;
+ };
+
+ var PjsConsole = require("../Helpers/PjsConsole");
+ Processing.logger = new PjsConsole(document);
+
+ // done
+ return Processing;
+};
+
+},{"../Helpers/PjsConsole":5}],27:[function(require,module,exports){
+/**
+ * Processing.js object
+ */
+ module.exports = function(options, undef) {
+ var defaultScope = options.defaultScope,
+ extend = options.extend,
+ Browser = options.Browser,
+ ajax = Browser.ajax,
+ navigator = Browser.navigator,
+ window = Browser.window,
+ XMLHttpRequest = window.XMLHttpRequest,
+ document = Browser.document,
+ noop = options.noop,
+
+ PConstants = defaultScope.PConstants;
+ PFont = defaultScope.PFont,
+ PShapeSVG = defaultScope.PShapeSVG,
+ PVector = defaultScope.PVector,
+ Char = Character = defaultScope.Char,
+ ObjectIterator = defaultScope.ObjectIterator,
+ XMLElement = defaultScope.XMLElement,
+ XML = defaultScope.XML;
+
+ // fascinating "read only" jshint error if we don't start a new var block here.
+ var HTMLCanvasElement = window.HTMLCanvasElement,
+ HTMLImageElement = window.HTMLImageElement;
+
+ // window.localStorage cannot be accessed if a user is blocking cookies.
+ // In that case, we make it a temporary source cache object.
+ var localStorage;
+ try { localStorage = window.localStorage; } catch (e) { localStorage = {}; }
+
+ var isDOMPresent = ("document" in this) && !("fake" in this.document);
+
+ // document.head polyfill for the benefit of Firefox 3.6
+ if (!document.head) {
+ document.head = document.getElementsByTagName('head')[0];
+ }
+
+ var Float32Array = setupTypedArray("Float32Array", "WebGLFloatArray"),
+ Int32Array = setupTypedArray("Int32Array", "WebGLIntArray"),
+ Uint16Array = setupTypedArray("Uint16Array", "WebGLUnsignedShortArray"),
+ Uint8Array = setupTypedArray("Uint8Array", "WebGLUnsignedByteArray");
+
+ // Typed Arrays: fallback to WebGL arrays or Native JS arrays if unavailable
+ function setupTypedArray(name, fallback) {
+ // Check if TypedArray exists, and use if so.
+ if (name in window) {
+ return window[name];
+ }
+
+ // Check if WebGLArray exists
+ if (typeof window[fallback] === "function") {
+ return window[fallback];
+ }
+
+ // Use Native JS array
+ return function(obj) {
+ if (obj instanceof Array) {
+ return obj;
+ }
+ if (typeof obj === "number") {
+ var arr = [];
+ arr.length = obj;
+ return arr;
+ }
+ };
+ }
+
+ /* IE9+ quirks mode check - ticket #1606 */
+ if (document.documentMode >= 9 && !document.doctype) {
+ throw("The doctype directive is missing. The recommended doctype in Internet Explorer is the HTML5 doctype: <!DOCTYPE html>");
+ }
+
+ // Manage multiple Processing instances
+ var processingInstances = [];
+ var processingInstanceIds = {};
+
+ /**
+ * instance tracking - adding new instances
+ */
+ var addInstance = function(processing) {
+ if (processing.externals.canvas.id === undef || !processing.externals.canvas.id.length) {
+ processing.externals.canvas.id = "__processing" + processingInstances.length;
+ }
+ processingInstanceIds[processing.externals.canvas.id] = processingInstances.length;
+ processingInstances.push(processing);
+ };
+
+ /**
+ * instance tracking - removal
+ */
+ var removeInstance = function(id) {
+ processingInstances.splice(processingInstanceIds[id], 1);
+ delete processingInstanceIds[id];
+ };
+
+
+ /**
+ * The Processing object
+ */
+ var Processing = this.Processing = function(aCanvas, aCode, aFunctions) {
+
+ if (!(this instanceof Processing)) {
+ throw("called Processing constructor as if it were a function: missing 'new'.");
+ }
+
+ var curElement = {},
+ pgraphicsMode = (aCanvas === undef && aCode === undef);
+
+ if (pgraphicsMode) {
+ curElement = document.createElement("canvas");
+ } else {
+ // We'll take a canvas element or a string for a canvas element's id
+ curElement = typeof aCanvas === "string" ? document.getElementById(aCanvas) : aCanvas;
+ }
+
+ if (!('getContext' in curElement)) {
+ throw("called Processing constructor without passing canvas element reference or id.");
+ }
+
+ function unimplemented(s) {
+ Processing.debug('Unimplemented - ' + s);
+ }
+
+ ////////////////////////////////////////////////////////////////////////////
+ // JavaScript event binding and releasing
+ ////////////////////////////////////////////////////////////////////////////
+
+ var eventHandlers = [];
+
+ function attachEventHandler(elem, type, fn) {
+ if (elem.addEventListener) {
+ elem.addEventListener(type, fn, false);
+ } else {
+ elem.attachEvent("on" + type, fn);
+ }
+ eventHandlers.push({elem: elem, type: type, fn: fn});
+ }
+
+ function detachEventHandler(eventHandler) {
+ var elem = eventHandler.elem,
+ type = eventHandler.type,
+ fn = eventHandler.fn;
+ if (elem.removeEventListener) {
+ elem.removeEventListener(type, fn, false);
+ } else if (elem.detachEvent) {
+ elem.detachEvent("on" + type, fn);
+ }
+ }
+
+ function removeFirstArgument(args) {
+ return Array.prototype.slice.call(args, 1);
+ }
+
+ // When something new is added to "p." it must also be added to the "names" array.
+ // The names array contains the names of everything that is inside "p."
+ var p = this;
+
+ p.Char = p.Character = Char;
+
+ // add in the Processing API functions
+ extend.withCommonFunctions(p);
+ extend.withMath(p);
+ extend.withProxyFunctions(p, removeFirstArgument);
+ extend.withTouch(p, curElement, attachEventHandler, document, PConstants);
+
+ // custom functions and properties are added here
+ if(aFunctions) {
+ Object.keys(aFunctions).forEach(function(name) {
+ p[name] = aFunctions[name];
+ });
+ }
+
+ // PJS specific (non-p5) methods and properties to externalize
+ p.externals = {
+ canvas: curElement,
+ context: undef,
+ sketch: undef,
+ window: window
+ };
+
+ p.name = 'Processing.js Instance'; // Set Processing defaults / environment variables
+ p.use3DContext = false; // default '2d' canvas context
+
+ /**
+ * Confirms if a Processing program is "focused", meaning that it is
+ * active and will accept input from mouse or keyboard. This variable
+ * is "true" if it is focused and "false" if not. This variable is
+ * often used when you want to warn people they need to click on the
+ * browser before it will work.
+ */
+ p.focused = false;
+ p.breakShape = false;
+
+ // Glyph path storage for textFonts
+ p.glyphTable = {};
+
+ // Global vars for tracking mouse position
+ p.pmouseX = 0;
+ p.pmouseY = 0;
+ p.mouseX = 0;
+ p.mouseY = 0;
+ p.mouseButton = 0;
+ p.mouseScroll = 0;
+
+ // Undefined event handlers to be replaced by user when needed
+ p.mouseClicked = undef;
+ p.mouseDragged = undef;
+ p.mouseMoved = undef;
+ p.mousePressed = undef;
+ p.mouseReleased = undef;
+ p.mouseScrolled = undef;
+ p.mouseOver = undef;
+ p.mouseOut = undef;
+ p.touchStart = undef;
+ p.touchEnd = undef;
+ p.touchMove = undef;
+ p.touchCancel = undef;
+ p.key = undef;
+ p.keyCode = undef;
+ p.keyPressed = noop; // needed to remove function checks
+ p.keyReleased = noop;
+ p.keyTyped = noop;
+ p.draw = undef;
+ p.setup = undef;
+
+ // Remapped vars
+ p.__mousePressed = false;
+ p.__keyPressed = false;
+ p.__frameRate = 60;
+
+ // The current animation frame
+ p.frameCount = 0;
+
+ // The height/width of the canvas
+ p.width = 100;
+ p.height = 100;
+
+ // "Private" variables used to maintain state
+ var curContext,
+ curSketch,
+ drawing, // hold a Drawing2D or Drawing3D object
+ doFill = true,
+ fillStyle = [1.0, 1.0, 1.0, 1.0],
+ currentFillColor = 0xFFFFFFFF,
+ isFillDirty = true,
+ doStroke = true,
+ strokeStyle = [0.0, 0.0, 0.0, 1.0],
+ currentStrokeColor = 0xFF000000,
+ isStrokeDirty = true,
+ lineWidth = 1,
+ loopStarted = false,
+ renderSmooth = false,
+ doLoop = true,
+ looping = 0,
+ curRectMode = PConstants.CORNER,
+ curEllipseMode = PConstants.CENTER,
+ normalX = 0,
+ normalY = 0,
+ normalZ = 0,
+ normalMode = PConstants.NORMAL_MODE_AUTO,
+ curFrameRate = 60,
+ curMsPerFrame = 1000/curFrameRate,
+ curCursor = PConstants.ARROW,
+ oldCursor = curElement.style.cursor,
+ curShape = PConstants.POLYGON,
+ curShapeCount = 0,
+ curvePoints = [],
+ curTightness = 0,
+ curveDet = 20,
+ curveInited = false,
+ backgroundObj = -3355444, // rgb(204, 204, 204) is the default gray background colour
+ bezDetail = 20,
+ colorModeA = 255,
+ colorModeX = 255,
+ colorModeY = 255,
+ colorModeZ = 255,
+ pathOpen = false,
+ mouseDragging = false,
+ pmouseXLastFrame = 0,
+ pmouseYLastFrame = 0,
+ curColorMode = PConstants.RGB,
+ curTint = null,
+ curTint3d = null,
+ getLoaded = false,
+ start = Date.now(),
+ timeSinceLastFPS = start,
+ framesSinceLastFPS = 0,
+ textcanvas,
+ curveBasisMatrix,
+ curveToBezierMatrix,
+ curveDrawMatrix,
+ bezierDrawMatrix,
+ bezierBasisInverse,
+ bezierBasisMatrix,
+ curContextCache = { attributes: {}, locations: {} },
+ // Shaders
+ programObject3D,
+ programObject2D,
+ programObjectUnlitShape,
+ boxBuffer,
+ boxNormBuffer,
+ boxOutlineBuffer,
+ rectBuffer,
+ rectNormBuffer,
+ sphereBuffer,
+ lineBuffer,
+ fillBuffer,
+ fillColorBuffer,
+ strokeColorBuffer,
+ pointBuffer,
+ shapeTexVBO,
+ canTex, // texture for createGraphics
+ textTex, // texture for 3d tex
+ curTexture = {width:0,height:0},
+ curTextureMode = PConstants.IMAGE,
+ usingTexture = false,
+ textBuffer,
+ textureBuffer,
+ indexBuffer,
+ // Text alignment
+ horizontalTextAlignment = PConstants.LEFT,
+ verticalTextAlignment = PConstants.BASELINE,
+ textMode = PConstants.MODEL,
+ // Font state
+ curFontName = "Arial",
+ curTextSize = 12,
+ curTextAscent = 9,
+ curTextDescent = 2,
+ curTextLeading = 14,
+ curTextFont = PFont.get(curFontName, curTextSize),
+ // Pixels cache
+ originalContext,
+ proxyContext = null,
+ isContextReplaced = false,
+ setPixelsCached,
+ maxPixelsCached = 1000,
+ pressedKeysMap = [],
+ lastPressedKeyCode = null,
+ codedKeys = [ PConstants.SHIFT, PConstants.CONTROL, PConstants.ALT, PConstants.CAPSLK, PConstants.PGUP, PConstants.PGDN,
+ PConstants.END, PConstants.HOME, PConstants.LEFT, PConstants.UP, PConstants.RIGHT, PConstants.DOWN, PConstants.NUMLK,
+ PConstants.INSERT, PConstants.F1, PConstants.F2, PConstants.F3, PConstants.F4, PConstants.F5, PConstants.F6, PConstants.F7,
+ PConstants.F8, PConstants.F9, PConstants.F10, PConstants.F11, PConstants.F12, PConstants.META ];
+
+ // User can only have MAX_LIGHTS lights
+ var lightCount = 0;
+
+ //sphere stuff
+ var sphereDetailV = 0,
+ sphereDetailU = 0,
+ sphereX = [],
+ sphereY = [],
+ sphereZ = [],
+ sinLUT = new Float32Array(PConstants.SINCOS_LENGTH),
+ cosLUT = new Float32Array(PConstants.SINCOS_LENGTH),
+ sphereVerts,
+ sphereNorms;
+
+ // Camera defaults and settings
+ var cam,
+ cameraInv,
+ modelView,
+ modelViewInv,
+ userMatrixStack,
+ userReverseMatrixStack,
+ inverseCopy,
+ projection,
+ manipulatingCamera = false,
+ frustumMode = false,
+ cameraFOV = 60 * (Math.PI / 180),
+ cameraX = p.width / 2,
+ cameraY = p.height / 2,
+ cameraZ = cameraY / Math.tan(cameraFOV / 2),
+ cameraNear = cameraZ / 10,
+ cameraFar = cameraZ * 10,
+ cameraAspect = p.width / p.height;
+
+ var vertArray = [],
+ curveVertArray = [],
+ curveVertCount = 0,
+ isCurve = false,
+ isBezier = false,
+ firstVert = true;
+
+ //PShape stuff
+ var curShapeMode = PConstants.CORNER;
+
+ // Stores states for pushStyle() and popStyle().
+ var styleArray = [];
+
+ // The vertices for the box cannot be specified using a triangle strip since each
+ // side of the cube must have its own set of normals.
+ // Vertices are specified in a counter-clockwise order.
+ // Triangles are in this order: back, front, right, bottom, left, top.
+ var boxVerts = new Float32Array([
+ 0.5, 0.5, -0.5, 0.5, -0.5, -0.5, -0.5, -0.5, -0.5, -0.5, -0.5, -0.5, -0.5, 0.5, -0.5, 0.5, 0.5, -0.5,
+ 0.5, 0.5, 0.5, -0.5, 0.5, 0.5, -0.5, -0.5, 0.5, -0.5, -0.5, 0.5, 0.5, -0.5, 0.5, 0.5, 0.5, 0.5,
+ 0.5, 0.5, -0.5, 0.5, 0.5, 0.5, 0.5, -0.5, 0.5, 0.5, -0.5, 0.5, 0.5, -0.5, -0.5, 0.5, 0.5, -0.5,
+ 0.5, -0.5, -0.5, 0.5, -0.5, 0.5, -0.5, -0.5, 0.5, -0.5, -0.5, 0.5, -0.5, -0.5, -0.5, 0.5, -0.5, -0.5,
+ -0.5, -0.5, -0.5, -0.5, -0.5, 0.5, -0.5, 0.5, 0.5, -0.5, 0.5, 0.5, -0.5, 0.5, -0.5, -0.5, -0.5, -0.5,
+ 0.5, 0.5, 0.5, 0.5, 0.5, -0.5, -0.5, 0.5, -0.5, -0.5, 0.5, -0.5, -0.5, 0.5, 0.5, 0.5, 0.5, 0.5]);
+
+ var boxOutlineVerts = new Float32Array([
+ 0.5, 0.5, 0.5, 0.5, -0.5, 0.5, 0.5, 0.5, -0.5, 0.5, -0.5, -0.5,
+ -0.5, 0.5, -0.5, -0.5, -0.5, -0.5, -0.5, 0.5, 0.5, -0.5, -0.5, 0.5,
+ 0.5, 0.5, 0.5, 0.5, 0.5, -0.5, 0.5, 0.5, -0.5, -0.5, 0.5, -0.5,
+ -0.5, 0.5, -0.5, -0.5, 0.5, 0.5, -0.5, 0.5, 0.5, 0.5, 0.5, 0.5,
+ 0.5, -0.5, 0.5, 0.5, -0.5, -0.5, 0.5, -0.5, -0.5, -0.5, -0.5, -0.5,
+ -0.5, -0.5, -0.5, -0.5, -0.5, 0.5, -0.5, -0.5, 0.5, 0.5, -0.5, 0.5]);
+
+ var boxNorms = new Float32Array([
+ 0, 0, -1, 0, 0, -1, 0, 0, -1, 0, 0, -1, 0, 0, -1, 0, 0, -1,
+ 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1,
+ 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0,
+ 0, -1, 0, 0, -1, 0, 0, -1, 0, 0, -1, 0, 0, -1, 0, 0, -1, 0,
+ -1, 0, 0, -1, 0, 0, -1, 0, 0, -1, 0, 0, -1, 0, 0, -1, 0, 0,
+ 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0]);
+
+ // These verts are used for the fill and stroke using TRIANGLE_FAN and LINE_LOOP.
+ var rectVerts = new Float32Array([0,0,0, 0,1,0, 1,1,0, 1,0,0]);
+
+ var rectNorms = new Float32Array([0,0,1, 0,0,1, 0,0,1, 0,0,1]);
+
+ // Shader for points and lines in begin/endShape.
+ var vertexShaderSrcUnlitShape =
+ "varying vec4 vFrontColor;" +
+
+ "attribute vec3 aVertex;" +
+ "attribute vec4 aColor;" +
+
+ "uniform mat4 uView;" +
+ "uniform mat4 uProjection;" +
+ "uniform float uPointSize;" +
+
+ "void main(void) {" +
+ " vFrontColor = aColor;" +
+ " gl_PointSize = uPointSize;" +
+ " gl_Position = uProjection * uView * vec4(aVertex, 1.0);" +
+ "}";
+
+ var fragmentShaderSrcUnlitShape =
+ "#ifdef GL_ES\n" +
+ "precision highp float;\n" +
+ "#endif\n" +
+
+ "varying vec4 vFrontColor;" +
+ "uniform bool uSmooth;" +
+
+ "void main(void){" +
+ " if(uSmooth == true){" +
+ " float dist = distance(gl_PointCoord, vec2(0.5));" +
+ " if(dist > 0.5){" +
+ " discard;" +
+ " }" +
+ " }" +
+ " gl_FragColor = vFrontColor;" +
+ "}";
+
+ // Shader for rect, text, box outlines, sphere outlines, point() and line().
+ var vertexShaderSrc2D =
+ "varying vec4 vFrontColor;" +
+
+ "attribute vec3 aVertex;" +
+ "attribute vec2 aTextureCoord;" +
+ "uniform vec4 uColor;" +
+
+ "uniform mat4 uModel;" +
+ "uniform mat4 uView;" +
+ "uniform mat4 uProjection;" +
+ "uniform float uPointSize;" +
+ "varying vec2 vTextureCoord;"+
+
+ "void main(void) {" +
+ " gl_PointSize = uPointSize;" +
+ " vFrontColor = uColor;" +
+ " gl_Position = uProjection * uView * uModel * vec4(aVertex, 1.0);" +
+ " vTextureCoord = aTextureCoord;" +
+ "}";
+
+ var fragmentShaderSrc2D =
+ "#ifdef GL_ES\n" +
+ "precision highp float;\n" +
+ "#endif\n" +
+
+ "varying vec4 vFrontColor;" +
+ "varying vec2 vTextureCoord;"+
+
+ "uniform sampler2D uSampler;"+
+ "uniform int uIsDrawingText;"+
+ "uniform bool uSmooth;" +
+
+ "void main(void){" +
+ // WebGL does not support POINT_SMOOTH, so we do it ourselves
+ " if(uSmooth == true){" +
+ " float dist = distance(gl_PointCoord, vec2(0.5));" +
+ " if(dist > 0.5){" +
+ " discard;" +
+ " }" +
+ " }" +
+
+ " if(uIsDrawingText == 1){" +
+ " float alpha = texture2D(uSampler, vTextureCoord).a;"+
+ " gl_FragColor = vec4(vFrontColor.rgb * alpha, alpha);"+
+ " }" +
+ " else{" +
+ " gl_FragColor = vFrontColor;" +
+ " }" +
+ "}";
+
+ var webglMaxTempsWorkaround = /Windows/.test(navigator.userAgent);
+
+ // Vertex shader for boxes and spheres.
+ var vertexShaderSrc3D =
+ "varying vec4 vFrontColor;" +
+
+ "attribute vec3 aVertex;" +
+ "attribute vec3 aNormal;" +
+ "attribute vec4 aColor;" +
+ "attribute vec2 aTexture;" +
+ "varying vec2 vTexture;" +
+
+ "uniform vec4 uColor;" +
+
+ "uniform bool uUsingMat;" +
+ "uniform vec3 uSpecular;" +
+ "uniform vec3 uMaterialEmissive;" +
+ "uniform vec3 uMaterialAmbient;" +
+ "uniform vec3 uMaterialSpecular;" +
+ "uniform float uShininess;" +
+
+ "uniform mat4 uModel;" +
+ "uniform mat4 uView;" +
+ "uniform mat4 uProjection;" +
+ "uniform mat4 uNormalTransform;" +
+
+ "uniform int uLightCount;" +
+ "uniform vec3 uFalloff;" +
+
+ // Careful changing the order of these fields. Some cards
+ // have issues with memory alignment.
+ "struct Light {" +
+ " int type;" +
+ " vec3 color;" +
+ " vec3 position;" +
+ " vec3 direction;" +
+ " float angle;" +
+ " vec3 halfVector;" +
+ " float concentration;" +
+ "};" +
+
+ // nVidia cards have issues with arrays of structures
+ // so instead we create 8 instances of Light.
+ "uniform Light uLights0;" +
+ "uniform Light uLights1;" +
+ "uniform Light uLights2;" +
+ "uniform Light uLights3;" +
+ "uniform Light uLights4;" +
+ "uniform Light uLights5;" +
+ "uniform Light uLights6;" +
+ "uniform Light uLights7;" +
+
+ // GLSL does not support switch.
+ "Light getLight(int index){" +
+ " if(index == 0) return uLights0;" +
+ " if(index == 1) return uLights1;" +
+ " if(index == 2) return uLights2;" +
+ " if(index == 3) return uLights3;" +
+ " if(index == 4) return uLights4;" +
+ " if(index == 5) return uLights5;" +
+ " if(index == 6) return uLights6;" +
+ // Do not use a conditional for the last return statement
+ // because some video cards will fail and complain that
+ // "not all paths return".
+ " return uLights7;" +
+ "}" +
+
+ "void AmbientLight( inout vec3 totalAmbient, in vec3 ecPos, in Light light ) {" +
+ // Get the vector from the light to the vertex and
+ // get the distance from the current vector to the light position.
+ " float d = length( light.position - ecPos );" +
+ " float attenuation = 1.0 / ( uFalloff[0] + ( uFalloff[1] * d ) + ( uFalloff[2] * d * d ));" +
+ " totalAmbient += light.color * attenuation;" +
+ "}" +
+
+ /*
+ col - accumulated color
+ spec - accumulated specular highlight
+ vertNormal - Normal of the vertex
+ ecPos - eye coordinate position
+ light - light structure
+ */
+ "void DirectionalLight( inout vec3 col, inout vec3 spec, in vec3 vertNormal, in vec3 ecPos, in Light light ) {" +
+ " float powerFactor = 0.0;" +
+ " float nDotVP = max(0.0, dot( vertNormal, normalize(-light.position) ));" +
+ " float nDotVH = max(0.0, dot( vertNormal, normalize(-light.position-normalize(ecPos) )));" +
+
+ " if( nDotVP != 0.0 ){" +
+ " powerFactor = pow( nDotVH, uShininess );" +
+ " }" +
+
+ " col += light.color * nDotVP;" +
+ " spec += uSpecular * powerFactor;" +
+ "}" +
+
+ /*
+ col - accumulated color
+ spec - accumulated specular highlight
+ vertNormal - Normal of the vertex
+ ecPos - eye coordinate position
+ light - light structure
+ */
+ "void PointLight( inout vec3 col, inout vec3 spec, in vec3 vertNormal, in vec3 ecPos, in Light light ) {" +
+ " float powerFactor;" +
+
+ // Get the vector from the light to the vertex.
+ " vec3 VP = light.position - ecPos;" +
+
+ // Get the distance from the current vector to the light position.
+ " float d = length( VP ); " +
+
+ // Normalize the light ray so it can be used in the dot product operation.
+ " VP = normalize( VP );" +
+
+ " float attenuation = 1.0 / ( uFalloff[0] + ( uFalloff[1] * d ) + ( uFalloff[2] * d * d ));" +
+
+ " float nDotVP = max( 0.0, dot( vertNormal, VP ));" +
+ " vec3 halfVector = normalize( VP - normalize(ecPos) );" +
+ " float nDotHV = max( 0.0, dot( vertNormal, halfVector ));" +
+
+ " if( nDotVP == 0.0 ) {" +
+ " powerFactor = 0.0;" +
+ " }" +
+ " else {" +
+ " powerFactor = pow( nDotHV, uShininess );" +
+ " }" +
+
+ " spec += uSpecular * powerFactor * attenuation;" +
+ " col += light.color * nDotVP * attenuation;" +
+ "}" +
+
+ /*
+ col - accumulated color
+ spec - accumulated specular highlight
+ vertNormal - Normal of the vertex
+ ecPos - eye coordinate position
+ light - light structure
+ */
+ "void SpotLight( inout vec3 col, inout vec3 spec, in vec3 vertNormal, in vec3 ecPos, in Light light ) {" +
+ " float spotAttenuation;" +
+ " float powerFactor = 0.0;" +
+
+ // Calculate the vector from the current vertex to the light.
+ " vec3 VP = light.position - ecPos;" +
+ " vec3 ldir = normalize( -light.direction );" +
+
+ // Get the distance from the spotlight and the vertex
+ " float d = length( VP );" +
+ " VP = normalize( VP );" +
+
+ " float attenuation = 1.0 / ( uFalloff[0] + ( uFalloff[1] * d ) + ( uFalloff[2] * d * d ) );" +
+
+ // Dot product of the vector from vertex to light and light direction.
+ " float spotDot = dot( VP, ldir );" +
+
+ // If the vertex falls inside the cone
+ (webglMaxTempsWorkaround ? // Windows reports max temps error if light.angle is used
+ " spotAttenuation = 1.0; " :
+ " if( spotDot > cos( light.angle ) ) {" +
+ " spotAttenuation = pow( spotDot, light.concentration );" +
+ " }" +
+ " else{" +
+ " spotAttenuation = 0.0;" +
+ " }" +
+ " attenuation *= spotAttenuation;" +
+ "") +
+
+ " float nDotVP = max( 0.0, dot( vertNormal, VP ) );" +
+ " vec3 halfVector = normalize( VP - normalize(ecPos) );" +
+ " float nDotHV = max( 0.0, dot( vertNormal, halfVector ) );" +
+
+ " if( nDotVP != 0.0 ) {" +
+ " powerFactor = pow( nDotHV, uShininess );" +
+ " }" +
+
+ " spec += uSpecular * powerFactor * attenuation;" +
+ " col += light.color * nDotVP * attenuation;" +
+ "}" +
+
+ "void main(void) {" +
+ " vec3 finalAmbient = vec3( 0.0 );" +
+ " vec3 finalDiffuse = vec3( 0.0 );" +
+ " vec3 finalSpecular = vec3( 0.0 );" +
+
+ " vec4 col = uColor;" +
+
+ " if ( uColor[0] == -1.0 ){" +
+ " col = aColor;" +
+ " }" +
+
+ // We use the sphere vertices as the normals when we create the sphere buffer.
+ // But this only works if the sphere vertices are unit length, so we
+ // have to normalize the normals here. Since this is only required for spheres
+ // we could consider placing this in a conditional later on.
+ " vec3 norm = normalize(vec3( uNormalTransform * vec4( aNormal, 0.0 ) ));" +
+
+ " vec4 ecPos4 = uView * uModel * vec4(aVertex, 1.0);" +
+ " vec3 ecPos = (vec3(ecPos4))/ecPos4.w;" +
+
+ // If there were no lights this draw call, just use the
+ // assigned fill color of the shape and the specular value.
+ " if( uLightCount == 0 ) {" +
+ " vFrontColor = col + vec4(uMaterialSpecular, 1.0);" +
+ " }" +
+ " else {" +
+ // WebGL forces us to iterate over a constant value
+ // so we can't iterate using lightCount.
+ " for( int i = 0; i < 8; i++ ) {" +
+ " Light l = getLight(i);" +
+
+ // We can stop iterating if we know we have gone past
+ // the number of lights which are actually on. This gives us a
+ // significant performance increase with high vertex counts.
+ " if( i >= uLightCount ){" +
+ " break;" +
+ " }" +
+
+ " if( l.type == 0 ) {" +
+ " AmbientLight( finalAmbient, ecPos, l );" +
+ " }" +
+ " else if( l.type == 1 ) {" +
+ " DirectionalLight( finalDiffuse, finalSpecular, norm, ecPos, l );" +
+ " }" +
+ " else if( l.type == 2 ) {" +
+ " PointLight( finalDiffuse, finalSpecular, norm, ecPos, l );" +
+ " }" +
+ " else {" +
+ " SpotLight( finalDiffuse, finalSpecular, norm, ecPos, l );" +
+ " }" +
+ " }" +
+
+ " if( uUsingMat == false ) {" +
+ " vFrontColor = vec4(" +
+ " vec3( col ) * finalAmbient +" +
+ " vec3( col ) * finalDiffuse +" +
+ " vec3( col ) * finalSpecular," +
+ " col[3] );" +
+ " }" +
+ " else{" +
+ " vFrontColor = vec4( " +
+ " uMaterialEmissive + " +
+ " (vec3(col) * uMaterialAmbient * finalAmbient ) + " +
+ " (vec3(col) * finalDiffuse) + " +
+ " (uMaterialSpecular * finalSpecular), " +
+ " col[3] );" +
+ " }" +
+ " }" +
+
+ " vTexture.xy = aTexture.xy;" +
+ " gl_Position = uProjection * uView * uModel * vec4( aVertex, 1.0 );" +
+ "}";
+
+ var fragmentShaderSrc3D =
+ "#ifdef GL_ES\n" +
+ "precision highp float;\n" +
+ "#endif\n" +
+
+ "varying vec4 vFrontColor;" +
+
+ "uniform sampler2D uSampler;" +
+ "uniform bool uUsingTexture;" +
+ "varying vec2 vTexture;" +
+
+ // In Processing, when a texture is used, the fill color is ignored
+ // vec4(1.0,1.0,1.0,0.5)
+ "void main(void){" +
+ " if( uUsingTexture ){" +
+ " gl_FragColor = vec4(texture2D(uSampler, vTexture.xy)) * vFrontColor;" +
+ " }"+
+ " else{" +
+ " gl_FragColor = vFrontColor;" +
+ " }" +
+ "}";
+
+ ////////////////////////////////////////////////////////////////////////////
+ // 3D Functions
+ ////////////////////////////////////////////////////////////////////////////
+
+ /*
+ * Sets a uniform variable in a program object to a particular
+ * value. Before calling this function, ensure the correct
+ * program object has been installed as part of the current
+ * rendering state by calling useProgram.
+ *
+ * On some systems, if the variable exists in the shader but isn't used,
+ * the compiler will optimize it out and this function will fail.
+ *
+ * @param {String} cacheId
+ * @param {WebGLProgram} programObj program object returned from
+ * createProgramObject
+ * @param {String} varName the name of the variable in the shader
+ * @param {float | Array} varValue either a scalar value or an Array
+ *
+ * @returns none
+ *
+ * @see uniformi
+ * @see uniformMatrix
+ */
+ function uniformf(cacheId, programObj, varName, varValue) {
+ var varLocation = curContextCache.locations[cacheId];
+ if(varLocation === undef) {
+ varLocation = curContext.getUniformLocation(programObj, varName);
+ curContextCache.locations[cacheId] = varLocation;
+ }
+ // the variable won't be found if it was optimized out.
+ if (varLocation !== null) {
+ if (varValue.length === 4) {
+ curContext.uniform4fv(varLocation, varValue);
+ } else if (varValue.length === 3) {
+ curContext.uniform3fv(varLocation, varValue);
+ } else if (varValue.length === 2) {
+ curContext.uniform2fv(varLocation, varValue);
+ } else {
+ curContext.uniform1f(varLocation, varValue);
+ }
+ }
+ }
+
+ /**
+ * Sets a uniform int or int array in a program object to a particular
+ * value. Before calling this function, ensure the correct
+ * program object has been installed as part of the current
+ * rendering state.
+ *
+ * On some systems, if the variable exists in the shader but isn't used,
+ * the compiler will optimize it out and this function will fail.
+ *
+ * @param {String} cacheId
+ * @param {WebGLProgram} programObj program object returned from
+ * createProgramObject
+ * @param {String} varName the name of the variable in the shader
+ * @param {int | Array} varValue either a scalar value or an Array
+ *
+ * @returns none
+ *
+ * @see uniformf
+ * @see uniformMatrix
+ */
+ function uniformi(cacheId, programObj, varName, varValue) {
+ var varLocation = curContextCache.locations[cacheId];
+ if(varLocation === undef) {
+ varLocation = curContext.getUniformLocation(programObj, varName);
+ curContextCache.locations[cacheId] = varLocation;
+ }
+ // the variable won't be found if it was optimized out.
+ if (varLocation !== null) {
+ if (varValue.length === 4) {
+ curContext.uniform4iv(varLocation, varValue);
+ } else if (varValue.length === 3) {
+ curContext.uniform3iv(varLocation, varValue);
+ } else if (varValue.length === 2) {
+ curContext.uniform2iv(varLocation, varValue);
+ } else {
+ curContext.uniform1i(varLocation, varValue);
+ }
+ }
+ }
+
+ /**
+ * Sets the value of a uniform matrix variable in a program
+ * object. Before calling this function, ensure the correct
+ * program object has been installed as part of the current
+ * rendering state.
+ *
+ * On some systems, if the variable exists in the shader but
+ * isn't used, the compiler will optimize it out and this
+ * function will fail.
+ *
+ * @param {String} cacheId
+ * @param {WebGLProgram} programObj program object returned from
+ * createProgramObject
+ * @param {String} varName the name of the variable in the shader
+ * @param {boolean} transpose must be false
+ * @param {Array} matrix an array of 4, 9 or 16 values
+ *
+ * @returns none
+ *
+ * @see uniformi
+ * @see uniformf
+ */
+ function uniformMatrix(cacheId, programObj, varName, transpose, matrix) {
+ var varLocation = curContextCache.locations[cacheId];
+ if(varLocation === undef) {
+ varLocation = curContext.getUniformLocation(programObj, varName);
+ curContextCache.locations[cacheId] = varLocation;
+ }
+ // The variable won't be found if it was optimized out.
+ if (varLocation !== -1) {
+ if (matrix.length === 16) {
+ curContext.uniformMatrix4fv(varLocation, transpose, matrix);
+ } else if (matrix.length === 9) {
+ curContext.uniformMatrix3fv(varLocation, transpose, matrix);
+ } else {
+ curContext.uniformMatrix2fv(varLocation, transpose, matrix);
+ }
+ }
+ }
+
+ /**
+ * Binds the VBO, sets the vertex attribute data for the program
+ * object and enables the attribute.
+ *
+ * On some systems, if the attribute exists in the shader but
+ * isn't used, the compiler will optimize it out and this
+ * function will fail.
+ *
+ * @param {String} cacheId
+ * @param {WebGLProgram} programObj program object returned from
+ * createProgramObject
+ * @param {String} varName the name of the variable in the shader
+ * @param {int} size the number of components per vertex attribute
+ * @param {WebGLBuffer} VBO Vertex Buffer Object
+ *
+ * @returns none
+ *
+ * @see disableVertexAttribPointer
+ */
+ function vertexAttribPointer(cacheId, programObj, varName, size, VBO) {
+ var varLocation = curContextCache.attributes[cacheId];
+ if(varLocation === undef) {
+ varLocation = curContext.getAttribLocation(programObj, varName);
+ curContextCache.attributes[cacheId] = varLocation;
+ }
+ if (varLocation !== -1) {
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, VBO);
+ curContext.vertexAttribPointer(varLocation, size, curContext.FLOAT, false, 0, 0);
+ curContext.enableVertexAttribArray(varLocation);
+ }
+ }
+
+ /**
+ * Disables a program object attribute from being sent to WebGL.
+ *
+ * @param {String} cacheId
+ * @param {WebGLProgram} programObj program object returned from
+ * createProgramObject
+ * @param {String} varName name of the attribute
+ *
+ * @returns none
+ *
+ * @see vertexAttribPointer
+ */
+ function disableVertexAttribPointer(cacheId, programObj, varName){
+ var varLocation = curContextCache.attributes[cacheId];
+ if(varLocation === undef) {
+ varLocation = curContext.getAttribLocation(programObj, varName);
+ curContextCache.attributes[cacheId] = varLocation;
+ }
+ if (varLocation !== -1) {
+ curContext.disableVertexAttribArray(varLocation);
+ }
+ }
+
+ /**
+ * Creates a WebGL program object.
+ *
+ * @param {String} vetexShaderSource
+ * @param {String} fragmentShaderSource
+ *
+ * @returns {WebGLProgram} A program object
+ */
+ var createProgramObject = function(curContext, vetexShaderSource, fragmentShaderSource) {
+ var vertexShaderObject = curContext.createShader(curContext.VERTEX_SHADER);
+ curContext.shaderSource(vertexShaderObject, vetexShaderSource);
+ curContext.compileShader(vertexShaderObject);
+ if (!curContext.getShaderParameter(vertexShaderObject, curContext.COMPILE_STATUS)) {
+ throw curContext.getShaderInfoLog(vertexShaderObject);
+ }
+
+ var fragmentShaderObject = curContext.createShader(curContext.FRAGMENT_SHADER);
+ curContext.shaderSource(fragmentShaderObject, fragmentShaderSource);
+ curContext.compileShader(fragmentShaderObject);
+ if (!curContext.getShaderParameter(fragmentShaderObject, curContext.COMPILE_STATUS)) {
+ throw curContext.getShaderInfoLog(fragmentShaderObject);
+ }
+
+ var programObject = curContext.createProgram();
+ curContext.attachShader(programObject, vertexShaderObject);
+ curContext.attachShader(programObject, fragmentShaderObject);
+ curContext.linkProgram(programObject);
+ if (!curContext.getProgramParameter(programObject, curContext.LINK_STATUS)) {
+ throw "Error linking shaders.";
+ }
+
+ return programObject;
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // 2D/3D drawing handling
+ ////////////////////////////////////////////////////////////////////////////
+ var imageModeCorner = function(x, y, w, h, whAreSizes) {
+ return {
+ x: x,
+ y: y,
+ w: w,
+ h: h
+ };
+ };
+ var imageModeConvert = imageModeCorner;
+
+ var imageModeCorners = function(x, y, w, h, whAreSizes) {
+ return {
+ x: x,
+ y: y,
+ w: whAreSizes ? w : w - x,
+ h: whAreSizes ? h : h - y
+ };
+ };
+
+ var imageModeCenter = function(x, y, w, h, whAreSizes) {
+ return {
+ x: x - w / 2,
+ y: y - h / 2,
+ w: w,
+ h: h
+ };
+ };
+
+ // Objects for shared, 2D and 3D contexts
+ var DrawingShared = function(){};
+ var Drawing2D = function(){};
+ var Drawing3D = function(){};
+ var DrawingPre = function(){};
+
+ // Setup the prototype chain
+ Drawing2D.prototype = new DrawingShared();
+ Drawing2D.prototype.constructor = Drawing2D;
+ Drawing3D.prototype = new DrawingShared();
+ Drawing3D.prototype.constructor = Drawing3D;
+ DrawingPre.prototype = new DrawingShared();
+ DrawingPre.prototype.constructor = DrawingPre;
+
+ // A no-op function for when the user calls 3D functions from a 2D sketch
+ // We can change this to a throw or console.error() later if we want
+ DrawingShared.prototype.a3DOnlyFunction = noop;
+
+ /**
+ * The shape() function displays shapes to the screen.
+ * Processing currently works with SVG shapes only.
+ * The <b>shape</b> parameter specifies the shape to display and the <b>x</b>
+ * and <b>y</b> parameters define the location of the shape from its
+ * upper-left corner.
+ * The shape is displayed at its original size unless the <b>width</b>
+ * and <b>height</b> parameters specify a different size.
+ * The <b>shapeMode()</b> function changes the way the parameters work.
+ * A call to <b>shapeMode(CORNERS)</b>, for example, will change the width
+ * and height parameters to define the x and y values of the opposite corner
+ * of the shape.
+ * <br><br>
+ * Note complex shapes may draw awkwardly with P2D, P3D, and OPENGL. Those
+ * renderers do not yet support shapes that have holes or complicated breaks.
+ *
+ * @param {PShape} shape the shape to display
+ * @param {int|float} x x-coordinate of the shape
+ * @param {int|float} y y-coordinate of the shape
+ * @param {int|float} width width to display the shape
+ * @param {int|float} height height to display the shape
+ *
+ * @see PShape
+ * @see loadShape()
+ * @see shapeMode()
+ */
+ p.shape = function(shape, x, y, width, height) {
+ if (arguments.length >= 1 && arguments[0] !== null) {
+ if (shape.isVisible()) {
+ p.pushMatrix();
+ if (curShapeMode === PConstants.CENTER) {
+ if (arguments.length === 5) {
+ p.translate(x - width/2, y - height/2);
+ p.scale(width / shape.getWidth(), height / shape.getHeight());
+ } else if (arguments.length === 3) {
+ p.translate(x - shape.getWidth()/2, - shape.getHeight()/2);
+ } else {
+ p.translate(-shape.getWidth()/2, -shape.getHeight()/2);
+ }
+ } else if (curShapeMode === PConstants.CORNER) {
+ if (arguments.length === 5) {
+ p.translate(x, y);
+ p.scale(width / shape.getWidth(), height / shape.getHeight());
+ } else if (arguments.length === 3) {
+ p.translate(x, y);
+ }
+ } else if (curShapeMode === PConstants.CORNERS) {
+ if (arguments.length === 5) {
+ width -= x;
+ height -= y;
+ p.translate(x, y);
+ p.scale(width / shape.getWidth(), height / shape.getHeight());
+ } else if (arguments.length === 3) {
+ p.translate(x, y);
+ }
+ }
+ shape.draw(p);
+ if ((arguments.length === 1 && curShapeMode === PConstants.CENTER ) || arguments.length > 1) {
+ p.popMatrix();
+ }
+ }
+ }
+ };
+
+ /**
+ * The shapeMode() function modifies the location from which shapes draw.
+ * The default mode is <b>shapeMode(CORNER)</b>, which specifies the
+ * location to be the upper left corner of the shape and uses the third
+ * and fourth parameters of <b>shape()</b> to specify the width and height.
+ * The syntax <b>shapeMode(CORNERS)</b> uses the first and second parameters
+ * of <b>shape()</b> to set the location of one corner and uses the third
+ * and fourth parameters to set the opposite corner.
+ * The syntax <b>shapeMode(CENTER)</b> draws the shape from its center point
+ * and uses the third and forth parameters of <b>shape()</b> to specify the
+ * width and height.
+ * The parameter must be written in "ALL CAPS" because Processing syntax
+ * is case sensitive.
+ *
+ * @param {int} mode One of CORNER, CORNERS, CENTER
+ *
+ * @see shape()
+ * @see rectMode()
+ */
+ p.shapeMode = function (mode) {
+ curShapeMode = mode;
+ };
+
+ /**
+ * The loadShape() function loads vector shapes into a variable of type PShape. Currently, only SVG files may be loaded.
+ * In most cases, <b>loadShape()</b> should be used inside <b>setup()</b> because loading shapes inside <b>draw()</b> will reduce the speed of a sketch.
+ *
+ * @param {String} filename an SVG file
+ *
+ * @return {PShape} a object of type PShape or null
+ * @see PShape
+ * @see PApplet#shape()
+ * @see PApplet#shapeMode()
+ */
+ p.loadShape = function (filename) {
+ if (arguments.length === 1) {
+ if (filename.indexOf(".svg") > -1) {
+ return new PShapeSVG(null, filename);
+ }
+ }
+ return null;
+ };
+
+ /**
+ * Processing 2.0 function for loading XML files.
+ *
+ * @param {String} uri The uri for the xml file to load.
+ *
+ * @return {XML} An XML object representing the xml data.
+ */
+ p.loadXML = function(uri) {
+ return new XML(p, uri);
+ };
+
+ /**
+ * Processing 2.0 function for creating XML elements from string
+ *
+ * @param {String} xml the XML source code
+ *
+ * @return {XML} An XML object representation of the input XML markup.
+ */
+ p.parseXML = function(xmlstring) {
+ var element = new XML();
+ element.parse(xmlstring);
+ return element;
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // 2D Matrix
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Helper function for printMatrix(). Finds the largest scalar
+ * in the matrix, then number of digits left of the decimal.
+ * Call from PMatrix2D and PMatrix3D's print() function.
+ */
+ var printMatrixHelper = function(elements) {
+ var big = 0;
+ for (var i = 0; i < elements.length; i++) {
+ if (i !== 0) {
+ big = Math.max(big, Math.abs(elements[i]));
+ } else {
+ big = Math.abs(elements[i]);
+ }
+ }
+
+ var digits = (big + "").indexOf(".");
+ if (digits === 0) {
+ digits = 1;
+ } else if (digits === -1) {
+ digits = (big + "").length;
+ }
+
+ return digits;
+ };
+ /**
+ * PMatrix2D is a 3x2 affine matrix implementation. The constructor accepts another PMatrix2D or a list of six float elements.
+ * If no parameters are provided the matrix is set to the identity matrix.
+ *
+ * @param {PMatrix2D} matrix the initial matrix to set to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m10 the fourth element of the matrix
+ * @param {float} m11 the fifth element of the matrix
+ * @param {float} m12 the sixth element of the matrix
+ */
+ var PMatrix2D = p.PMatrix2D = function() {
+ if (arguments.length === 0) {
+ this.reset();
+ } else if (arguments.length === 1 && arguments[0] instanceof PMatrix2D) {
+ this.set(arguments[0].array());
+ } else if (arguments.length === 6) {
+ this.set(arguments[0], arguments[1], arguments[2], arguments[3], arguments[4], arguments[5]);
+ }
+ };
+ /**
+ * PMatrix2D methods
+ */
+ PMatrix2D.prototype = {
+ /**
+ * @member PMatrix2D
+ * The set() function sets the matrix elements. The function accepts either another PMatrix2D, an array of elements, or a list of six floats.
+ *
+ * @param {PMatrix2D} matrix the matrix to set this matrix to
+ * @param {float[]} elements an array of elements to set this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the third element of the matrix
+ * @param {float} m10 the fourth element of the matrix
+ * @param {float} m11 the fith element of the matrix
+ * @param {float} m12 the sixth element of the matrix
+ */
+ set: function() {
+ if (arguments.length === 6) {
+ var a = arguments;
+ this.set([a[0], a[1], a[2],
+ a[3], a[4], a[5]]);
+ } else if (arguments.length === 1 && arguments[0] instanceof PMatrix2D) {
+ this.elements = arguments[0].array();
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ this.elements = arguments[0].slice();
+ }
+ },
+ /**
+ * @member PMatrix2D
+ * The get() function returns a copy of this PMatrix2D.
+ *
+ * @return {PMatrix2D} a copy of this PMatrix2D
+ */
+ get: function() {
+ var outgoing = new PMatrix2D();
+ outgoing.set(this.elements);
+ return outgoing;
+ },
+ /**
+ * @member PMatrix2D
+ * The reset() function sets this PMatrix2D to the identity matrix.
+ */
+ reset: function() {
+ this.set([1, 0, 0, 0, 1, 0]);
+ },
+ /**
+ * @member PMatrix2D
+ * The array() function returns a copy of the element values.
+ * @addon
+ *
+ * @return {float[]} returns a copy of the element values
+ */
+ array: function array() {
+ return this.elements.slice();
+ },
+ /**
+ * @member PMatrix2D
+ * The translate() function translates this matrix by moving the current coordinates to the location specified by tx and ty.
+ *
+ * @param {float} tx the x-axis coordinate to move to
+ * @param {float} ty the y-axis coordinate to move to
+ */
+ translate: function(tx, ty) {
+ this.elements[2] = tx * this.elements[0] + ty * this.elements[1] + this.elements[2];
+ this.elements[5] = tx * this.elements[3] + ty * this.elements[4] + this.elements[5];
+ },
+ /**
+ * @member PMatrix2D
+ * The invTranslate() function translates this matrix by moving the current coordinates to the negative location specified by tx and ty.
+ *
+ * @param {float} tx the x-axis coordinate to move to
+ * @param {float} ty the y-axis coordinate to move to
+ */
+ invTranslate: function(tx, ty) {
+ this.translate(-tx, -ty);
+ },
+ /**
+ * @member PMatrix2D
+ * The transpose() function is not used in processingjs.
+ */
+ transpose: function() {
+ // Does nothing in Processing.
+ },
+ /**
+ * @member PMatrix2D
+ * The mult() function multiplied this matrix.
+ * If two array elements are passed in the function will multiply a two element vector against this matrix.
+ * If target is null or not length four, a new float array will be returned.
+ * The values for vec and target can be the same (though that's less efficient).
+ * If two PVectors are passed in the function multiply the x and y coordinates of a PVector against this matrix.
+ *
+ * @param {PVector} source, target the PVectors used to multiply this matrix
+ * @param {float[]} source, target the arrays used to multiply this matrix
+ *
+ * @return {PVector|float[]} returns a PVector or an array representing the new matrix
+ */
+ mult: function(source, target) {
+ var x, y;
+ if (source instanceof PVector) {
+ x = source.x;
+ y = source.y;
+ if (!target) {
+ target = new PVector();
+ }
+ } else if (source instanceof Array) {
+ x = source[0];
+ y = source[1];
+ if (!target) {
+ target = [];
+ }
+ }
+ if (target instanceof Array) {
+ target[0] = this.elements[0] * x + this.elements[1] * y + this.elements[2];
+ target[1] = this.elements[3] * x + this.elements[4] * y + this.elements[5];
+ } else if (target instanceof PVector) {
+ target.x = this.elements[0] * x + this.elements[1] * y + this.elements[2];
+ target.y = this.elements[3] * x + this.elements[4] * y + this.elements[5];
+ target.z = 0;
+ }
+ return target;
+ },
+ /**
+ * @member PMatrix2D
+ * The multX() function calculates the x component of a vector from a transformation.
+ *
+ * @param {float} x the x component of the vector being transformed
+ * @param {float} y the y component of the vector being transformed
+ *
+ * @return {float} returnes the result of the calculation
+ */
+ multX: function(x, y) {
+ return (x * this.elements[0] + y * this.elements[1] + this.elements[2]);
+ },
+ /**
+ * @member PMatrix2D
+ * The multY() function calculates the y component of a vector from a transformation.
+ *
+ * @param {float} x the x component of the vector being transformed
+ * @param {float} y the y component of the vector being transformed
+ *
+ * @return {float} returnes the result of the calculation
+ */
+ multY: function(x, y) {
+ return (x * this.elements[3] + y * this.elements[4] + this.elements[5]);
+ },
+ /**
+ * @member PMatrix2D
+ * The skewX() function skews the matrix along the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ skewX: function(angle) {
+ this.apply(1, 0, 1, angle, 0, 0);
+ },
+ /**
+ * @member PMatrix2D
+ * The skewY() function skews the matrix along the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ skewY: function(angle) {
+ this.apply(1, 0, 1, 0, angle, 0);
+ },
+ /**
+ * @member PMatrix2D
+ * The shearX() function shears the matrix along the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ shearX: function(angle) {
+ this.apply(1, 0, 1, Math.tan(angle) , 0, 0);
+ },
+ /**
+ * @member PMatrix2D
+ * The shearY() function shears the matrix along the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ shearY: function(angle) {
+ this.apply(1, 0, 1, 0, Math.tan(angle), 0);
+ },
+ /**
+ * @member PMatrix2D
+ * The determinant() function calvculates the determinant of this matrix.
+ *
+ * @return {float} the determinant of the matrix
+ */
+ determinant: function() {
+ return (this.elements[0] * this.elements[4] - this.elements[1] * this.elements[3]);
+ },
+ /**
+ * @member PMatrix2D
+ * The invert() function inverts this matrix
+ *
+ * @return {boolean} true if successful
+ */
+ invert: function() {
+ var d = this.determinant();
+ if (Math.abs( d ) > PConstants.MIN_INT) {
+ var old00 = this.elements[0];
+ var old01 = this.elements[1];
+ var old02 = this.elements[2];
+ var old10 = this.elements[3];
+ var old11 = this.elements[4];
+ var old12 = this.elements[5];
+ this.elements[0] = old11 / d;
+ this.elements[3] = -old10 / d;
+ this.elements[1] = -old01 / d;
+ this.elements[4] = old00 / d;
+ this.elements[2] = (old01 * old12 - old11 * old02) / d;
+ this.elements[5] = (old10 * old02 - old00 * old12) / d;
+ return true;
+ }
+ return false;
+ },
+ /**
+ * @member PMatrix2D
+ * The scale() function increases or decreases the size of a shape by expanding and contracting vertices. When only one parameter is specified scale will occur in all dimensions.
+ * This is equivalent to a two parameter call.
+ *
+ * @param {float} sx the amount to scale on the x-axis
+ * @param {float} sy the amount to scale on the y-axis
+ */
+ scale: function(sx, sy) {
+ if (sx && !sy) {
+ sy = sx;
+ }
+ if (sx && sy) {
+ this.elements[0] *= sx;
+ this.elements[1] *= sy;
+ this.elements[3] *= sx;
+ this.elements[4] *= sy;
+ }
+ },
+ /**
+ * @member PMatrix2D
+ * The invScale() function decreases or increases the size of a shape by contracting and expanding vertices. When only one parameter is specified scale will occur in all dimensions.
+ * This is equivalent to a two parameter call.
+ *
+ * @param {float} sx the amount to scale on the x-axis
+ * @param {float} sy the amount to scale on the y-axis
+ */
+ invScale: function(sx, sy) {
+ if (sx && !sy) {
+ sy = sx;
+ }
+ this.scale(1 / sx, 1 / sy);
+ },
+ /**
+ * @member PMatrix2D
+ * The apply() function multiplies the current matrix by the one specified through the parameters. Note that either a PMatrix2D or a list of floats can be passed in.
+ *
+ * @param {PMatrix2D} matrix the matrix to apply this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the third element of the matrix
+ * @param {float} m10 the fourth element of the matrix
+ * @param {float} m11 the fith element of the matrix
+ * @param {float} m12 the sixth element of the matrix
+ */
+ apply: function() {
+ var source;
+ if (arguments.length === 1 && arguments[0] instanceof PMatrix2D) {
+ source = arguments[0].array();
+ } else if (arguments.length === 6) {
+ source = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ source = arguments[0];
+ }
+
+ var result = [0, 0, this.elements[2],
+ 0, 0, this.elements[5]];
+ var e = 0;
+ for (var row = 0; row < 2; row++) {
+ for (var col = 0; col < 3; col++, e++) {
+ result[e] += this.elements[row * 3 + 0] * source[col + 0] +
+ this.elements[row * 3 + 1] * source[col + 3];
+ }
+ }
+ this.elements = result.slice();
+ },
+ /**
+ * @member PMatrix2D
+ * The preApply() function applies another matrix to the left of this one. Note that either a PMatrix2D or elements of a matrix can be passed in.
+ *
+ * @param {PMatrix2D} matrix the matrix to apply this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the third element of the matrix
+ * @param {float} m10 the fourth element of the matrix
+ * @param {float} m11 the fith element of the matrix
+ * @param {float} m12 the sixth element of the matrix
+ */
+ preApply: function() {
+ var source;
+ if (arguments.length === 1 && arguments[0] instanceof PMatrix2D) {
+ source = arguments[0].array();
+ } else if (arguments.length === 6) {
+ source = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ source = arguments[0];
+ }
+ var result = [0, 0, source[2],
+ 0, 0, source[5]];
+ result[2] = source[2] + this.elements[2] * source[0] + this.elements[5] * source[1];
+ result[5] = source[5] + this.elements[2] * source[3] + this.elements[5] * source[4];
+ result[0] = this.elements[0] * source[0] + this.elements[3] * source[1];
+ result[3] = this.elements[0] * source[3] + this.elements[3] * source[4];
+ result[1] = this.elements[1] * source[0] + this.elements[4] * source[1];
+ result[4] = this.elements[1] * source[3] + this.elements[4] * source[4];
+ this.elements = result.slice();
+ },
+ /**
+ * @member PMatrix2D
+ * The rotate() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotate: function(angle) {
+ var c = Math.cos(angle);
+ var s = Math.sin(angle);
+ var temp1 = this.elements[0];
+ var temp2 = this.elements[1];
+ this.elements[0] = c * temp1 + s * temp2;
+ this.elements[1] = -s * temp1 + c * temp2;
+ temp1 = this.elements[3];
+ temp2 = this.elements[4];
+ this.elements[3] = c * temp1 + s * temp2;
+ this.elements[4] = -s * temp1 + c * temp2;
+ },
+ /**
+ * @member PMatrix2D
+ * The rotateZ() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotateZ: function(angle) {
+ this.rotate(angle);
+ },
+ /**
+ * @member PMatrix2D
+ * The invRotateZ() function rotates the matrix in opposite direction.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ invRotateZ: function(angle) {
+ this.rotateZ(angle - Math.PI);
+ },
+ /**
+ * @member PMatrix2D
+ * The print() function prints out the elements of this matrix
+ */
+ print: function() {
+ var digits = printMatrixHelper(this.elements);
+ var output = "" + p.nfs(this.elements[0], digits, 4) + " " +
+ p.nfs(this.elements[1], digits, 4) + " " +
+ p.nfs(this.elements[2], digits, 4) + "\n" +
+ p.nfs(this.elements[3], digits, 4) + " " +
+ p.nfs(this.elements[4], digits, 4) + " " +
+ p.nfs(this.elements[5], digits, 4) + "\n\n";
+ p.println(output);
+ }
+ };
+
+ /**
+ * PMatrix3D is a 4x4 matrix implementation. The constructor accepts another PMatrix3D or a list of six or sixteen float elements.
+ * If no parameters are provided the matrix is set to the identity matrix.
+ */
+ var PMatrix3D = p.PMatrix3D = function() {
+ // When a matrix is created, it is set to an identity matrix
+ this.reset();
+ };
+ /**
+ * PMatrix3D methods
+ */
+ PMatrix3D.prototype = {
+ /**
+ * @member PMatrix2D
+ * The set() function sets the matrix elements. The function accepts either another PMatrix3D, an array of elements, or a list of six or sixteen floats.
+ *
+ * @param {PMatrix3D} matrix the initial matrix to set to
+ * @param {float[]} elements an array of elements to set this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m03 the fourth element of the matrix
+ * @param {float} m10 the fifth element of the matrix
+ * @param {float} m11 the sixth element of the matrix
+ * @param {float} m12 the seventh element of the matrix
+ * @param {float} m13 the eight element of the matrix
+ * @param {float} m20 the nineth element of the matrix
+ * @param {float} m21 the tenth element of the matrix
+ * @param {float} m22 the eleventh element of the matrix
+ * @param {float} m23 the twelveth element of the matrix
+ * @param {float} m30 the thirteenth element of the matrix
+ * @param {float} m31 the fourtheenth element of the matrix
+ * @param {float} m32 the fivetheenth element of the matrix
+ * @param {float} m33 the sixteenth element of the matrix
+ */
+ set: function() {
+ if (arguments.length === 16) {
+ this.elements = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof PMatrix3D) {
+ this.elements = arguments[0].array();
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ this.elements = arguments[0].slice();
+ }
+ },
+ /**
+ * @member PMatrix3D
+ * The get() function returns a copy of this PMatrix3D.
+ *
+ * @return {PMatrix3D} a copy of this PMatrix3D
+ */
+ get: function() {
+ var outgoing = new PMatrix3D();
+ outgoing.set(this.elements);
+ return outgoing;
+ },
+ /**
+ * @member PMatrix3D
+ * The reset() function sets this PMatrix3D to the identity matrix.
+ */
+ reset: function() {
+ this.elements = [1,0,0,0,
+ 0,1,0,0,
+ 0,0,1,0,
+ 0,0,0,1];
+ },
+ /**
+ * @member PMatrix3D
+ * The array() function returns a copy of the element values.
+ * @addon
+ *
+ * @return {float[]} returns a copy of the element values
+ */
+ array: function array() {
+ return this.elements.slice();
+ },
+ /**
+ * @member PMatrix3D
+ * The translate() function translates this matrix by moving the current coordinates to the location specified by tx, ty, and tz.
+ *
+ * @param {float} tx the x-axis coordinate to move to
+ * @param {float} ty the y-axis coordinate to move to
+ * @param {float} tz the z-axis coordinate to move to
+ */
+ translate: function(tx, ty, tz) {
+ if (tz === undef) {
+ tz = 0;
+ }
+
+ this.elements[3] += tx * this.elements[0] + ty * this.elements[1] + tz * this.elements[2];
+ this.elements[7] += tx * this.elements[4] + ty * this.elements[5] + tz * this.elements[6];
+ this.elements[11] += tx * this.elements[8] + ty * this.elements[9] + tz * this.elements[10];
+ this.elements[15] += tx * this.elements[12] + ty * this.elements[13] + tz * this.elements[14];
+ },
+ /**
+ * @member PMatrix3D
+ * The transpose() function transpose this matrix.
+ */
+ transpose: function() {
+ var temp = this.elements[4];
+ this.elements[4] = this.elements[1];
+ this.elements[1] = temp;
+
+ temp = this.elements[8];
+ this.elements[8] = this.elements[2];
+ this.elements[2] = temp;
+
+ temp = this.elements[6];
+ this.elements[6] = this.elements[9];
+ this.elements[9] = temp;
+
+ temp = this.elements[3];
+ this.elements[3] = this.elements[12];
+ this.elements[12] = temp;
+
+ temp = this.elements[7];
+ this.elements[7] = this.elements[13];
+ this.elements[13] = temp;
+
+ temp = this.elements[11];
+ this.elements[11] = this.elements[14];
+ this.elements[14] = temp;
+ },
+ /**
+ * @member PMatrix3D
+ * The mult() function multiplied this matrix.
+ * If two array elements are passed in the function will multiply a two element vector against this matrix.
+ * If target is null or not length four, a new float array will be returned.
+ * The values for vec and target can be the same (though that's less efficient).
+ * If two PVectors are passed in the function multiply the x and y coordinates of a PVector against this matrix.
+ *
+ * @param {PVector} source, target the PVectors used to multiply this matrix
+ * @param {float[]} source, target the arrays used to multiply this matrix
+ *
+ * @return {PVector|float[]} returns a PVector or an array representing the new matrix
+ */
+ mult: function(source, target) {
+ var x, y, z, w;
+ if (source instanceof PVector) {
+ x = source.x;
+ y = source.y;
+ z = source.z;
+ w = 1;
+ if (!target) {
+ target = new PVector();
+ }
+ } else if (source instanceof Array) {
+ x = source[0];
+ y = source[1];
+ z = source[2];
+ w = source[3] || 1;
+
+ if ( !target || (target.length !== 3 && target.length !== 4) ) {
+ target = [0, 0, 0];
+ }
+ }
+
+ if (target instanceof Array) {
+ if (target.length === 3) {
+ target[0] = this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3];
+ target[1] = this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7];
+ target[2] = this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11];
+ } else if (target.length === 4) {
+ target[0] = this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3] * w;
+ target[1] = this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7] * w;
+ target[2] = this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11] * w;
+ target[3] = this.elements[12] * x + this.elements[13] * y + this.elements[14] * z + this.elements[15] * w;
+ }
+ }
+ if (target instanceof PVector) {
+ target.x = this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3];
+ target.y = this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7];
+ target.z = this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11];
+ }
+ return target;
+ },
+ /**
+ * @member PMatrix3D
+ * The preApply() function applies another matrix to the left of this one. Note that either a PMatrix3D or elements of a matrix can be passed in.
+ *
+ * @param {PMatrix3D} matrix the matrix to apply this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m03 the fourth element of the matrix
+ * @param {float} m10 the fifth element of the matrix
+ * @param {float} m11 the sixth element of the matrix
+ * @param {float} m12 the seventh element of the matrix
+ * @param {float} m13 the eight element of the matrix
+ * @param {float} m20 the nineth element of the matrix
+ * @param {float} m21 the tenth element of the matrix
+ * @param {float} m22 the eleventh element of the matrix
+ * @param {float} m23 the twelveth element of the matrix
+ * @param {float} m30 the thirteenth element of the matrix
+ * @param {float} m31 the fourtheenth element of the matrix
+ * @param {float} m32 the fivetheenth element of the matrix
+ * @param {float} m33 the sixteenth element of the matrix
+ */
+ preApply: function() {
+ var source;
+ if (arguments.length === 1 && arguments[0] instanceof PMatrix3D) {
+ source = arguments[0].array();
+ } else if (arguments.length === 16) {
+ source = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ source = arguments[0];
+ }
+
+ var result = [0, 0, 0, 0,
+ 0, 0, 0, 0,
+ 0, 0, 0, 0,
+ 0, 0, 0, 0];
+ var e = 0;
+ for (var row = 0; row < 4; row++) {
+ for (var col = 0; col < 4; col++, e++) {
+ result[e] += this.elements[col + 0] * source[row * 4 + 0] + this.elements[col + 4] *
+ source[row * 4 + 1] + this.elements[col + 8] * source[row * 4 + 2] +
+ this.elements[col + 12] * source[row * 4 + 3];
+ }
+ }
+ this.elements = result.slice();
+ },
+ /**
+ * @member PMatrix3D
+ * The apply() function multiplies the current matrix by the one specified through the parameters. Note that either a PMatrix3D or a list of floats can be passed in.
+ *
+ * @param {PMatrix3D} matrix the matrix to apply this matrix to
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m03 the fourth element of the matrix
+ * @param {float} m10 the fifth element of the matrix
+ * @param {float} m11 the sixth element of the matrix
+ * @param {float} m12 the seventh element of the matrix
+ * @param {float} m13 the eight element of the matrix
+ * @param {float} m20 the nineth element of the matrix
+ * @param {float} m21 the tenth element of the matrix
+ * @param {float} m22 the eleventh element of the matrix
+ * @param {float} m23 the twelveth element of the matrix
+ * @param {float} m30 the thirteenth element of the matrix
+ * @param {float} m31 the fourtheenth element of the matrix
+ * @param {float} m32 the fivetheenth element of the matrix
+ * @param {float} m33 the sixteenth element of the matrix
+ */
+ apply: function() {
+ var source;
+ if (arguments.length === 1 && arguments[0] instanceof PMatrix3D) {
+ source = arguments[0].array();
+ } else if (arguments.length === 16) {
+ source = Array.prototype.slice.call(arguments);
+ } else if (arguments.length === 1 && arguments[0] instanceof Array) {
+ source = arguments[0];
+ }
+
+ var result = [0, 0, 0, 0,
+ 0, 0, 0, 0,
+ 0, 0, 0, 0,
+ 0, 0, 0, 0];
+ var e = 0;
+ for (var row = 0; row < 4; row++) {
+ for (var col = 0; col < 4; col++, e++) {
+ result[e] += this.elements[row * 4 + 0] * source[col + 0] + this.elements[row * 4 + 1] *
+ source[col + 4] + this.elements[row * 4 + 2] * source[col + 8] +
+ this.elements[row * 4 + 3] * source[col + 12];
+ }
+ }
+ this.elements = result.slice();
+ },
+ /**
+ * @member PMatrix3D
+ * The rotate() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotate: function(angle, v0, v1, v2) {
+ if (arguments.length < 4) {
+ this.rotateZ(angle);
+ } else {
+ var v = new PVector(v0, v1, v2);
+ var m = v.mag();
+ if (m === 0) {
+ return;
+ } else if (m != 1) {
+ v.normalize();
+ v0 = v.x;
+ v1 = v.y;
+ v2 = v.z;
+ }
+ var c = p.cos(angle);
+ var s = p.sin(angle);
+ var t = 1.0 - c;
+
+ this.apply((t * v0 * v0) + c,
+ (t * v0 * v1) - (s * v2),
+ (t * v0 * v2) + (s * v1),
+ 0,
+ (t * v0 * v1) + (s * v2),
+ (t * v1 * v1) + c,
+ (t * v1 * v2) - (s * v0),
+ 0,
+ (t * v0 * v2) - (s * v1),
+ (t * v1 * v2) + (s * v0),
+ (t * v2 * v2) + c,
+ 0,
+ 0, 0, 0, 1);
+ }
+ },
+ /**
+ * @member PMatrix3D
+ * The invApply() function applies the inverted matrix to this matrix.
+ *
+ * @param {float} m00 the first element of the matrix
+ * @param {float} m01 the second element of the matrix
+ * @param {float} m02 the third element of the matrix
+ * @param {float} m03 the fourth element of the matrix
+ * @param {float} m10 the fifth element of the matrix
+ * @param {float} m11 the sixth element of the matrix
+ * @param {float} m12 the seventh element of the matrix
+ * @param {float} m13 the eight element of the matrix
+ * @param {float} m20 the nineth element of the matrix
+ * @param {float} m21 the tenth element of the matrix
+ * @param {float} m22 the eleventh element of the matrix
+ * @param {float} m23 the twelveth element of the matrix
+ * @param {float} m30 the thirteenth element of the matrix
+ * @param {float} m31 the fourtheenth element of the matrix
+ * @param {float} m32 the fivetheenth element of the matrix
+ * @param {float} m33 the sixteenth element of the matrix
+ *
+ * @return {boolean} returns true if the operation was successful.
+ */
+ invApply: function() {
+ if (inverseCopy === undef) {
+ inverseCopy = new PMatrix3D();
+ }
+ var a = arguments;
+ inverseCopy.set(a[0], a[1], a[2], a[3], a[4], a[5], a[6], a[7], a[8],
+ a[9], a[10], a[11], a[12], a[13], a[14], a[15]);
+
+ if (!inverseCopy.invert()) {
+ return false;
+ }
+ this.preApply(inverseCopy);
+ return true;
+ },
+ /**
+ * @member PMatrix3D
+ * The rotateZ() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotateX: function(angle) {
+ var c = p.cos(angle);
+ var s = p.sin(angle);
+ this.apply([1, 0, 0, 0, 0, c, -s, 0, 0, s, c, 0, 0, 0, 0, 1]);
+ },
+ /**
+ * @member PMatrix3D
+ * The rotateY() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotateY: function(angle) {
+ var c = p.cos(angle);
+ var s = p.sin(angle);
+ this.apply([c, 0, s, 0, 0, 1, 0, 0, -s, 0, c, 0, 0, 0, 0, 1]);
+ },
+ /**
+ * @member PMatrix3D
+ * The rotateZ() function rotates the matrix.
+ *
+ * @param {float} angle the angle of rotation in radiants
+ */
+ rotateZ: function(angle) {
+ var c = Math.cos(angle);
+ var s = Math.sin(angle);
+ this.apply([c, -s, 0, 0, s, c, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1]);
+ },
+ /**
+ * @member PMatrix3D
+ * The scale() function increases or decreases the size of a matrix by expanding and contracting vertices. When only one parameter is specified scale will occur in all dimensions.
+ * This is equivalent to a three parameter call.
+ *
+ * @param {float} sx the amount to scale on the x-axis
+ * @param {float} sy the amount to scale on the y-axis
+ * @param {float} sz the amount to scale on the z-axis
+ */
+ scale: function(sx, sy, sz) {
+ if (sx && !sy && !sz) {
+ sy = sz = sx;
+ } else if (sx && sy && !sz) {
+ sz = 1;
+ }
+
+ if (sx && sy && sz) {
+ this.elements[0] *= sx;
+ this.elements[1] *= sy;
+ this.elements[2] *= sz;
+ this.elements[4] *= sx;
+ this.elements[5] *= sy;
+ this.elements[6] *= sz;
+ this.elements[8] *= sx;
+ this.elements[9] *= sy;
+ this.elements[10] *= sz;
+ this.elements[12] *= sx;
+ this.elements[13] *= sy;
+ this.elements[14] *= sz;
+ }
+ },
+ /**
+ * @member PMatrix3D
+ * The skewX() function skews the matrix along the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ skewX: function(angle) {
+ var t = Math.tan(angle);
+ this.apply(1, t, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1);
+ },
+ /**
+ * @member PMatrix3D
+ * The skewY() function skews the matrix along the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of skew specified in radians
+ */
+ skewY: function(angle) {
+ var t = Math.tan(angle);
+ this.apply(1, 0, 0, 0, t, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1);
+ },
+ /**
+ * @member PMatrix3D
+ * The shearX() function shears the matrix along the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of shear specified in radians
+ */
+ shearX: function(angle) {
+ var t = Math.tan(angle);
+ this.apply(1, t, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1);
+ },
+ /**
+ * @member PMatrix3D
+ * The shearY() function shears the matrix along the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians with the <b>radians()</b> function.
+ *
+ * @param {float} angle angle of shear specified in radians
+ */
+ shearY: function(angle) {
+ var t = Math.tan(angle);
+ this.apply(1, 0, 0, 0, t, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1);
+ },
+ multX: function(x, y, z, w) {
+ if (!z) {
+ return this.elements[0] * x + this.elements[1] * y + this.elements[3];
+ }
+ if (!w) {
+ return this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3];
+ }
+ return this.elements[0] * x + this.elements[1] * y + this.elements[2] * z + this.elements[3] * w;
+ },
+ multY: function(x, y, z, w) {
+ if (!z) {
+ return this.elements[4] * x + this.elements[5] * y + this.elements[7];
+ }
+ if (!w) {
+ return this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7];
+ }
+ return this.elements[4] * x + this.elements[5] * y + this.elements[6] * z + this.elements[7] * w;
+ },
+ multZ: function(x, y, z, w) {
+ if (!w) {
+ return this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11];
+ }
+ return this.elements[8] * x + this.elements[9] * y + this.elements[10] * z + this.elements[11] * w;
+ },
+ multW: function(x, y, z, w) {
+ if (!w) {
+ return this.elements[12] * x + this.elements[13] * y + this.elements[14] * z + this.elements[15];
+ }
+ return this.elements[12] * x + this.elements[13] * y + this.elements[14] * z + this.elements[15] * w;
+ },
+ /**
+ * @member PMatrix3D
+ * The invert() function inverts this matrix
+ *
+ * @return {boolean} true if successful
+ */
+ invert: function() {
+ var fA0 = this.elements[0] * this.elements[5] - this.elements[1] * this.elements[4];
+ var fA1 = this.elements[0] * this.elements[6] - this.elements[2] * this.elements[4];
+ var fA2 = this.elements[0] * this.elements[7] - this.elements[3] * this.elements[4];
+ var fA3 = this.elements[1] * this.elements[6] - this.elements[2] * this.elements[5];
+ var fA4 = this.elements[1] * this.elements[7] - this.elements[3] * this.elements[5];
+ var fA5 = this.elements[2] * this.elements[7] - this.elements[3] * this.elements[6];
+ var fB0 = this.elements[8] * this.elements[13] - this.elements[9] * this.elements[12];
+ var fB1 = this.elements[8] * this.elements[14] - this.elements[10] * this.elements[12];
+ var fB2 = this.elements[8] * this.elements[15] - this.elements[11] * this.elements[12];
+ var fB3 = this.elements[9] * this.elements[14] - this.elements[10] * this.elements[13];
+ var fB4 = this.elements[9] * this.elements[15] - this.elements[11] * this.elements[13];
+ var fB5 = this.elements[10] * this.elements[15] - this.elements[11] * this.elements[14];
+
+ // Determinant
+ var fDet = fA0 * fB5 - fA1 * fB4 + fA2 * fB3 + fA3 * fB2 - fA4 * fB1 + fA5 * fB0;
+
+ // Account for a very small value
+ // return false if not successful.
+ if (Math.abs(fDet) <= 1e-9) {
+ return false;
+ }
+
+ var kInv = [];
+ kInv[0] = +this.elements[5] * fB5 - this.elements[6] * fB4 + this.elements[7] * fB3;
+ kInv[4] = -this.elements[4] * fB5 + this.elements[6] * fB2 - this.elements[7] * fB1;
+ kInv[8] = +this.elements[4] * fB4 - this.elements[5] * fB2 + this.elements[7] * fB0;
+ kInv[12] = -this.elements[4] * fB3 + this.elements[5] * fB1 - this.elements[6] * fB0;
+ kInv[1] = -this.elements[1] * fB5 + this.elements[2] * fB4 - this.elements[3] * fB3;
+ kInv[5] = +this.elements[0] * fB5 - this.elements[2] * fB2 + this.elements[3] * fB1;
+ kInv[9] = -this.elements[0] * fB4 + this.elements[1] * fB2 - this.elements[3] * fB0;
+ kInv[13] = +this.elements[0] * fB3 - this.elements[1] * fB1 + this.elements[2] * fB0;
+ kInv[2] = +this.elements[13] * fA5 - this.elements[14] * fA4 + this.elements[15] * fA3;
+ kInv[6] = -this.elements[12] * fA5 + this.elements[14] * fA2 - this.elements[15] * fA1;
+ kInv[10] = +this.elements[12] * fA4 - this.elements[13] * fA2 + this.elements[15] * fA0;
+ kInv[14] = -this.elements[12] * fA3 + this.elements[13] * fA1 - this.elements[14] * fA0;
+ kInv[3] = -this.elements[9] * fA5 + this.elements[10] * fA4 - this.elements[11] * fA3;
+ kInv[7] = +this.elements[8] * fA5 - this.elements[10] * fA2 + this.elements[11] * fA1;
+ kInv[11] = -this.elements[8] * fA4 + this.elements[9] * fA2 - this.elements[11] * fA0;
+ kInv[15] = +this.elements[8] * fA3 - this.elements[9] * fA1 + this.elements[10] * fA0;
+
+ // Inverse using Determinant
+ var fInvDet = 1.0 / fDet;
+ kInv[0] *= fInvDet;
+ kInv[1] *= fInvDet;
+ kInv[2] *= fInvDet;
+ kInv[3] *= fInvDet;
+ kInv[4] *= fInvDet;
+ kInv[5] *= fInvDet;
+ kInv[6] *= fInvDet;
+ kInv[7] *= fInvDet;
+ kInv[8] *= fInvDet;
+ kInv[9] *= fInvDet;
+ kInv[10] *= fInvDet;
+ kInv[11] *= fInvDet;
+ kInv[12] *= fInvDet;
+ kInv[13] *= fInvDet;
+ kInv[14] *= fInvDet;
+ kInv[15] *= fInvDet;
+
+ this.elements = kInv.slice();
+ return true;
+ },
+ toString: function() {
+ var str = "";
+ for (var i = 0; i < 15; i++) {
+ str += this.elements[i] + ", ";
+ }
+ str += this.elements[15];
+ return str;
+ },
+ /**
+ * @member PMatrix3D
+ * The print() function prints out the elements of this matrix
+ */
+ print: function() {
+ var digits = printMatrixHelper(this.elements);
+
+ var output = "" + p.nfs(this.elements[0], digits, 4) + " " + p.nfs(this.elements[1], digits, 4) +
+ " " + p.nfs(this.elements[2], digits, 4) + " " + p.nfs(this.elements[3], digits, 4) +
+ "\n" + p.nfs(this.elements[4], digits, 4) + " " + p.nfs(this.elements[5], digits, 4) +
+ " " + p.nfs(this.elements[6], digits, 4) + " " + p.nfs(this.elements[7], digits, 4) +
+ "\n" + p.nfs(this.elements[8], digits, 4) + " " + p.nfs(this.elements[9], digits, 4) +
+ " " + p.nfs(this.elements[10], digits, 4) + " " + p.nfs(this.elements[11], digits, 4) +
+ "\n" + p.nfs(this.elements[12], digits, 4) + " " + p.nfs(this.elements[13], digits, 4) +
+ " " + p.nfs(this.elements[14], digits, 4) + " " + p.nfs(this.elements[15], digits, 4) + "\n\n";
+ p.println(output);
+ },
+ invTranslate: function(tx, ty, tz) {
+ this.preApply(1, 0, 0, -tx, 0, 1, 0, -ty, 0, 0, 1, -tz, 0, 0, 0, 1);
+ },
+ invRotateX: function(angle) {
+ var c = Math.cos(-angle);
+ var s = Math.sin(-angle);
+ this.preApply([1, 0, 0, 0, 0, c, -s, 0, 0, s, c, 0, 0, 0, 0, 1]);
+ },
+ invRotateY: function(angle) {
+ var c = Math.cos(-angle);
+ var s = Math.sin(-angle);
+ this.preApply([c, 0, s, 0, 0, 1, 0, 0, -s, 0, c, 0, 0, 0, 0, 1]);
+ },
+ invRotateZ: function(angle) {
+ var c = Math.cos(-angle);
+ var s = Math.sin(-angle);
+ this.preApply([c, -s, 0, 0, s, c, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1]);
+ },
+ invScale: function(x, y, z) {
+ this.preApply([1 / x, 0, 0, 0, 0, 1 / y, 0, 0, 0, 0, 1 / z, 0, 0, 0, 0, 1]);
+ }
+ };
+
+ /**
+ * @private
+ * The matrix stack stores the transformations and translations that occur within the space.
+ */
+ var PMatrixStack = p.PMatrixStack = function() {
+ this.matrixStack = [];
+ };
+
+ /**
+ * @member PMatrixStack
+ * load pushes the matrix given in the function into the stack
+ *
+ * @param {Object | Array} matrix the matrix to be pushed into the stack
+ */
+ PMatrixStack.prototype.load = function() {
+ var tmpMatrix = drawing.$newPMatrix();
+
+ if (arguments.length === 1) {
+ tmpMatrix.set(arguments[0]);
+ } else {
+ tmpMatrix.set(arguments);
+ }
+ this.matrixStack.push(tmpMatrix);
+ };
+
+ Drawing2D.prototype.$newPMatrix = function() {
+ return new PMatrix2D();
+ };
+
+ Drawing3D.prototype.$newPMatrix = function() {
+ return new PMatrix3D();
+ };
+
+ /**
+ * @member PMatrixStack
+ * push adds a duplicate of the top of the stack onto the stack - uses the peek function
+ */
+ PMatrixStack.prototype.push = function() {
+ this.matrixStack.push(this.peek());
+ };
+
+ /**
+ * @member PMatrixStack
+ * pop removes returns the matrix at the top of the stack
+ *
+ * @returns {Object} the matrix at the top of the stack
+ */
+ PMatrixStack.prototype.pop = function() {
+ return this.matrixStack.pop();
+ };
+
+ /**
+ * @member PMatrixStack
+ * peek returns but doesn't remove the matrix at the top of the stack
+ *
+ * @returns {Object} the matrix at the top of the stack
+ */
+ PMatrixStack.prototype.peek = function() {
+ var tmpMatrix = drawing.$newPMatrix();
+
+ tmpMatrix.set(this.matrixStack[this.matrixStack.length - 1]);
+ return tmpMatrix;
+ };
+
+ /**
+ * @member PMatrixStack
+ * this function multiplies the matrix at the top of the stack with the matrix given as a parameter
+ *
+ * @param {Object | Array} matrix the matrix to be multiplied into the stack
+ */
+ PMatrixStack.prototype.mult = function(matrix) {
+ this.matrixStack[this.matrixStack.length - 1].apply(matrix);
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Array handling
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * The split() function breaks a string into pieces using a character or string
+ * as the divider. The delim parameter specifies the character or characters that
+ * mark the boundaries between each piece. A String[] array is returned that contains
+ * each of the pieces.
+ * If the result is a set of numbers, you can convert the String[] array to to a float[]
+ * or int[] array using the datatype conversion functions int() and float() (see example above).
+ * The splitTokens() function works in a similar fashion, except that it splits using a range
+ * of characters instead of a specific character or sequence.
+ *
+ * @param {String} str the String to be split
+ * @param {String} delim the character or String used to separate the data
+ *
+ * @returns {string[]} The new string array
+ *
+ * @see splitTokens
+ * @see join
+ * @see trim
+ */
+ p.split = function(str, delim) {
+ return str.split(delim);
+ };
+
+ /**
+ * The splitTokens() function splits a String at one or many character "tokens." The tokens
+ * parameter specifies the character or characters to be used as a boundary.
+ * If no tokens character is specified, any whitespace character is used to split.
+ * Whitespace characters include tab (\t), line feed (\n), carriage return (\r), form
+ * feed (\f), and space. To convert a String to an array of integers or floats, use the
+ * datatype conversion functions int() and float() to convert the array of Strings.
+ *
+ * @param {String} str the String to be split
+ * @param {Char[]} tokens list of individual characters that will be used as separators
+ *
+ * @returns {string[]} The new string array
+ *
+ * @see split
+ * @see join
+ * @see trim
+ */
+ p.splitTokens = function(str, tokens) {
+ if (tokens === undef) {
+ return str.split(/\s+/g);
+ }
+
+ var chars = tokens.split(/()/g),
+ buffer = "",
+ len = str.length,
+ i, c,
+ tokenized = [];
+
+ for (i = 0; i < len; i++) {
+ c = str[i];
+ if (chars.indexOf(c) > -1) {
+ if (buffer !== "") {
+ tokenized.push(buffer);
+ }
+ buffer = "";
+ } else {
+ buffer += c;
+ }
+ }
+
+ if (buffer !== "") {
+ tokenized.push(buffer);
+ }
+
+ return tokenized;
+ };
+
+ /**
+ * Expands an array by one element and adds data to the new position. The datatype of
+ * the element parameter must be the same as the datatype of the array.
+ * When using an array of objects, the data returned from the function must be cast to
+ * the object array's data type. For example: SomeClass[] items = (SomeClass[])
+ * append(originalArray, element).
+ *
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects} array boolean[],
+ * byte[], char[], int[], float[], or String[], or an array of objects
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects} element new data for the array
+ *
+ * @returns Array (the same datatype as the input)
+ *
+ * @see shorten
+ * @see expand
+ */
+ p.append = function(array, element) {
+ array[array.length] = element;
+ return array;
+ };
+
+ /**
+ * Concatenates two arrays. For example, concatenating the array { 1, 2, 3 } and the
+ * array { 4, 5, 6 } yields { 1, 2, 3, 4, 5, 6 }. Both parameters must be arrays of the
+ * same datatype.
+ * When using an array of objects, the data returned from the function must be cast to the
+ * object array's data type. For example: SomeClass[] items = (SomeClass[]) concat(array1, array2).
+ *
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects} array1 boolean[],
+ * byte[], char[], int[], float[], String[], or an array of objects
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects} array2 boolean[],
+ * byte[], char[], int[], float[], String[], or an array of objects
+ *
+ * @returns Array (the same datatype as the input)
+ *
+ * @see splice
+ */
+ p.concat = function(array1, array2) {
+ return array1.concat(array2);
+ };
+
+ /**
+ * Sorts an array of numbers from smallest to largest and puts an array of
+ * words in alphabetical order. The original array is not modified, a
+ * re-ordered array is returned. The count parameter states the number of
+ * elements to sort. For example if there are 12 elements in an array and
+ * if count is the value 5, only the first five elements on the array will
+ * be sorted. Alphabetical ordering is case insensitive.
+ *
+ * @param {String[] | int[] | float[]} array Array of elements to sort
+ * @param {int} numElem Number of elements to sort
+ *
+ * @returns {String[] | int[] | float[]} Array (same datatype as the input)
+ *
+ * @see reverse
+ */
+ p.sort = function(array, numElem) {
+ var ret = [];
+
+ // depending on the type used (int, float) or string
+ // we'll need to use a different compare function
+ if (array.length > 0) {
+ // copy since we need to return another array
+ var elemsToCopy = numElem > 0 ? numElem : array.length;
+ for (var i = 0; i < elemsToCopy; i++) {
+ ret.push(array[i]);
+ }
+ if (typeof array[0] === "string") {
+ ret.sort();
+ }
+ // int or float
+ else {
+ ret.sort(function(a, b) {
+ return a - b;
+ });
+ }
+
+ // copy on the rest of the elements that were not sorted in case the user
+ // only wanted a subset of an array to be sorted.
+ if (numElem > 0) {
+ for (var j = ret.length; j < array.length; j++) {
+ ret.push(array[j]);
+ }
+ }
+ }
+ return ret;
+ };
+
+ /**
+ * Inserts a value or array of values into an existing array. The first two parameters must
+ * be of the same datatype. The array parameter defines the array which will be modified
+ * and the second parameter defines the data which will be inserted. When using an array
+ * of objects, the data returned from the function must be cast to the object array's data
+ * type. For example: SomeClass[] items = (SomeClass[]) splice(array1, array2, index).
+ *
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects} array boolean[],
+ * byte[], char[], int[], float[], String[], or an array of objects
+ * @param {boolean|byte|char|int|float|String|boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects}
+ * value boolean, byte, char, int, float, String, boolean[], byte[], char[], int[],
+ * float[], String[], or other Object: value or an array of objects to be spliced in
+ * @param {int} index position in the array from which to insert data
+ *
+ * @returns Array (the same datatype as the input)
+ *
+ * @see contract
+ * @see subset
+ */
+ p.splice = function(array, value, index) {
+
+ // Trying to splice an empty array into "array" in P5 won't do
+ // anything, just return the original.
+ if(value.length === 0)
+ {
+ return array;
+ }
+
+ // If the second argument was an array, we'll need to iterate over all
+ // the "value" elements and add one by one because
+ // array.splice(index, 0, value);
+ // would create a multi-dimensional array which isn't what we want.
+ if(value instanceof Array) {
+ for(var i = 0, j = index; i < value.length; j++,i++) {
+ array.splice(j, 0, value[i]);
+ }
+ } else {
+ array.splice(index, 0, value);
+ }
+
+ return array;
+ };
+
+ /**
+ * Extracts an array of elements from an existing array. The array parameter defines the
+ * array from which the elements will be copied and the offset and length parameters determine
+ * which elements to extract. If no length is given, elements will be extracted from the offset
+ * to the end of the array. When specifying the offset remember the first array element is 0.
+ * This function does not change the source array.
+ * When using an array of objects, the data returned from the function must be cast to the
+ * object array's data type.
+ *
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects} array boolean[],
+ * byte[], char[], int[], float[], String[], or an array of objects
+ * @param {int} offset position to begin
+ * @param {int} length number of values to extract
+ *
+ * @returns Array (the same datatype as the input)
+ *
+ * @see splice
+ */
+ p.subset = function(array, offset, length) {
+ var end = (length !== undef) ? offset + length : array.length;
+ return array.slice(offset, end);
+ };
+
+ /**
+ * Combines an array of Strings into one String, each separated by the character(s) used for
+ * the separator parameter. To join arrays of ints or floats, it's necessary to first convert
+ * them to strings using nf() or nfs().
+ *
+ * @param {Array} array array of Strings
+ * @param {char|String} separator char or String to be placed between each item
+ *
+ * @returns {String} The combined string
+ *
+ * @see split
+ * @see trim
+ * @see nf
+ * @see nfs
+ */
+ p.join = function(array, seperator) {
+ return array.join(seperator);
+ };
+
+ /**
+ * Decreases an array by one element and returns the shortened array. When using an
+ * array of objects, the data returned from the function must be cast to the object array's
+ * data type. For example: SomeClass[] items = (SomeClass[]) shorten(originalArray).
+ *
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects} array
+ * boolean[], byte[], char[], int[], float[], or String[], or an array of objects
+ *
+ * @returns Array (the same datatype as the input)
+ *
+ * @see append
+ * @see expand
+ */
+ p.shorten = function(ary) {
+ var newary = [];
+
+ // copy array into new array
+ var len = ary.length;
+ for (var i = 0; i < len; i++) {
+ newary[i] = ary[i];
+ }
+ newary.pop();
+
+ return newary;
+ };
+
+ /**
+ * Increases the size of an array. By default, this function doubles the size of the array,
+ * but the optional newSize parameter provides precise control over the increase in size.
+ * When using an array of objects, the data returned from the function must be cast to the
+ * object array's data type. For example: SomeClass[] items = (SomeClass[]) expand(originalArray).
+ *
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]|array of objects} ary
+ * boolean[], byte[], char[], int[], float[], String[], or an array of objects
+ * @param {int} newSize positive int: new size for the array
+ *
+ * @returns Array (the same datatype as the input)
+ *
+ * @see contract
+ */
+ p.expand = function(ary, targetSize) {
+ var temp = ary.slice(0),
+ newSize = targetSize || ary.length * 2;
+ temp.length = newSize;
+ return temp;
+ };
+
+ /**
+ * Copies an array (or part of an array) to another array. The src array is copied to the
+ * dst array, beginning at the position specified by srcPos and into the position specified
+ * by dstPos. The number of elements to copy is determined by length. The simplified version
+ * with two arguments copies an entire array to another of the same size. It is equivalent
+ * to "arrayCopy(src, 0, dst, 0, src.length)". This function is far more efficient for copying
+ * array data than iterating through a for and copying each element.
+ *
+ * @param {Array} src an array of any data type: the source array
+ * @param {Array} dest an array of any data type (as long as it's the same as src): the destination array
+ * @param {int} srcPos starting position in the source array
+ * @param {int} destPos starting position in the destination array
+ * @param {int} length number of array elements to be copied
+ *
+ * @returns none
+ */
+ p.arrayCopy = function() { // src, srcPos, dest, destPos, length) {
+ var src, srcPos = 0, dest, destPos = 0, length;
+
+ if (arguments.length === 2) {
+ // recall itself and copy src to dest from start index 0 to 0 of src.length
+ src = arguments[0];
+ dest = arguments[1];
+ length = src.length;
+ } else if (arguments.length === 3) {
+ // recall itself and copy src to dest from start index 0 to 0 of length
+ src = arguments[0];
+ dest = arguments[1];
+ length = arguments[2];
+ } else if (arguments.length === 5) {
+ src = arguments[0];
+ srcPos = arguments[1];
+ dest = arguments[2];
+ destPos = arguments[3];
+ length = arguments[4];
+ }
+
+ // copy src to dest from index srcPos to index destPos of length recursivly on objects
+ for (var i = srcPos, j = destPos; i < length + srcPos; i++, j++) {
+ if (dest[j] !== undef) {
+ dest[j] = src[i];
+ } else {
+ throw "array index out of bounds exception";
+ }
+ }
+ };
+
+ /**
+ * Reverses the order of an array.
+ *
+ * @param {boolean[]|byte[]|char[]|int[]|float[]|String[]} array
+ * boolean[], byte[], char[], int[], float[], or String[]
+ *
+ * @returns Array (the same datatype as the input)
+ *
+ * @see sort
+ */
+ p.reverse = function(array) {
+ return array.reverse();
+ };
+
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Color functions
+ ////////////////////////////////////////////////////////////////////////////
+
+ // helper functions for internal blending modes
+ p.mix = function(a, b, f) {
+ return a + (((b - a) * f) >> 8);
+ };
+
+ p.peg = function(n) {
+ return (n < 0) ? 0 : ((n > 255) ? 255 : n);
+ };
+
+ // blending modes
+ /**
+ * These are internal blending modes used for BlendColor()
+ *
+ * @param {Color} c1 First Color to blend
+ * @param {Color} c2 Second Color to blend
+ *
+ * @returns {Color} The blended Color
+ *
+ * @see BlendColor
+ * @see Blend
+ */
+ p.modes = (function() {
+ var ALPHA_MASK = PConstants.ALPHA_MASK,
+ RED_MASK = PConstants.RED_MASK,
+ GREEN_MASK = PConstants.GREEN_MASK,
+ BLUE_MASK = PConstants.BLUE_MASK,
+ min = Math.min,
+ max = Math.max;
+
+ function applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb) {
+ var a = min(((c1 & 0xff000000) >>> 24) + f, 0xff) << 24;
+
+ var r = (ar + (((cr - ar) * f) >> 8));
+ r = ((r < 0) ? 0 : ((r > 255) ? 255 : r)) << 16;
+
+ var g = (ag + (((cg - ag) * f) >> 8));
+ g = ((g < 0) ? 0 : ((g > 255) ? 255 : g)) << 8;
+
+ var b = ab + (((cb - ab) * f) >> 8);
+ b = (b < 0) ? 0 : ((b > 255) ? 255 : b);
+
+ return (a | r | g | b);
+ }
+
+ return {
+ replace: function(c1, c2) {
+ return c2;
+ },
+ blend: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK),
+ ag = (c1 & GREEN_MASK),
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK),
+ bg = (c2 & GREEN_MASK),
+ bb = (c2 & BLUE_MASK);
+
+ return (min(((c1 & ALPHA_MASK) >>> 24) + f, 0xff) << 24 |
+ (ar + (((br - ar) * f) >> 8)) & RED_MASK |
+ (ag + (((bg - ag) * f) >> 8)) & GREEN_MASK |
+ (ab + (((bb - ab) * f) >> 8)) & BLUE_MASK);
+ },
+ add: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24;
+ return (min(((c1 & ALPHA_MASK) >>> 24) + f, 0xff) << 24 |
+ min(((c1 & RED_MASK) + ((c2 & RED_MASK) >> 8) * f), RED_MASK) & RED_MASK |
+ min(((c1 & GREEN_MASK) + ((c2 & GREEN_MASK) >> 8) * f), GREEN_MASK) & GREEN_MASK |
+ min((c1 & BLUE_MASK) + (((c2 & BLUE_MASK) * f) >> 8), BLUE_MASK));
+ },
+ subtract: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24;
+ return (min(((c1 & ALPHA_MASK) >>> 24) + f, 0xff) << 24 |
+ max(((c1 & RED_MASK) - ((c2 & RED_MASK) >> 8) * f), GREEN_MASK) & RED_MASK |
+ max(((c1 & GREEN_MASK) - ((c2 & GREEN_MASK) >> 8) * f), BLUE_MASK) & GREEN_MASK |
+ max((c1 & BLUE_MASK) - (((c2 & BLUE_MASK) * f) >> 8), 0));
+ },
+ lightest: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24;
+ return (min(((c1 & ALPHA_MASK) >>> 24) + f, 0xff) << 24 |
+ max(c1 & RED_MASK, ((c2 & RED_MASK) >> 8) * f) & RED_MASK |
+ max(c1 & GREEN_MASK, ((c2 & GREEN_MASK) >> 8) * f) & GREEN_MASK |
+ max(c1 & BLUE_MASK, ((c2 & BLUE_MASK) * f) >> 8));
+ },
+ darkest: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK),
+ ag = (c1 & GREEN_MASK),
+ ab = (c1 & BLUE_MASK),
+ br = min(c1 & RED_MASK, ((c2 & RED_MASK) >> 8) * f),
+ bg = min(c1 & GREEN_MASK, ((c2 & GREEN_MASK) >> 8) * f),
+ bb = min(c1 & BLUE_MASK, ((c2 & BLUE_MASK) * f) >> 8);
+
+ return (min(((c1 & ALPHA_MASK) >>> 24) + f, 0xff) << 24 |
+ (ar + (((br - ar) * f) >> 8)) & RED_MASK |
+ (ag + (((bg - ag) * f) >> 8)) & GREEN_MASK |
+ (ab + (((bb - ab) * f) >> 8)) & BLUE_MASK);
+ },
+ difference: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK),
+ cr = (ar > br) ? (ar - br) : (br - ar),
+ cg = (ag > bg) ? (ag - bg) : (bg - ag),
+ cb = (ab > bb) ? (ab - bb) : (bb - ab);
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ },
+ exclusion: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK),
+ cr = ar + br - ((ar * br) >> 7),
+ cg = ag + bg - ((ag * bg) >> 7),
+ cb = ab + bb - ((ab * bb) >> 7);
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ },
+ multiply: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK),
+ cr = (ar * br) >> 8,
+ cg = (ag * bg) >> 8,
+ cb = (ab * bb) >> 8;
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ },
+ screen: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK),
+ cr = 255 - (((255 - ar) * (255 - br)) >> 8),
+ cg = 255 - (((255 - ag) * (255 - bg)) >> 8),
+ cb = 255 - (((255 - ab) * (255 - bb)) >> 8);
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ },
+ hard_light: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK),
+ cr = (br < 128) ? ((ar * br) >> 7) : (255 - (((255 - ar) * (255 - br)) >> 7)),
+ cg = (bg < 128) ? ((ag * bg) >> 7) : (255 - (((255 - ag) * (255 - bg)) >> 7)),
+ cb = (bb < 128) ? ((ab * bb) >> 7) : (255 - (((255 - ab) * (255 - bb)) >> 7));
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ },
+ soft_light: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK),
+ cr = ((ar * br) >> 7) + ((ar * ar) >> 8) - ((ar * ar * br) >> 15),
+ cg = ((ag * bg) >> 7) + ((ag * ag) >> 8) - ((ag * ag * bg) >> 15),
+ cb = ((ab * bb) >> 7) + ((ab * ab) >> 8) - ((ab * ab * bb) >> 15);
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ },
+ overlay: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK),
+ cr = (ar < 128) ? ((ar * br) >> 7) : (255 - (((255 - ar) * (255 - br)) >> 7)),
+ cg = (ag < 128) ? ((ag * bg) >> 7) : (255 - (((255 - ag) * (255 - bg)) >> 7)),
+ cb = (ab < 128) ? ((ab * bb) >> 7) : (255 - (((255 - ab) * (255 - bb)) >> 7));
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ },
+ dodge: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK);
+
+ var cr = 255;
+ if (br !== 255) {
+ cr = (ar << 8) / (255 - br);
+ cr = (cr < 0) ? 0 : ((cr > 255) ? 255 : cr);
+ }
+
+ var cg = 255;
+ if (bg !== 255) {
+ cg = (ag << 8) / (255 - bg);
+ cg = (cg < 0) ? 0 : ((cg > 255) ? 255 : cg);
+ }
+
+ var cb = 255;
+ if (bb !== 255) {
+ cb = (ab << 8) / (255 - bb);
+ cb = (cb < 0) ? 0 : ((cb > 255) ? 255 : cb);
+ }
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ },
+ burn: function(c1, c2) {
+ var f = (c2 & ALPHA_MASK) >>> 24,
+ ar = (c1 & RED_MASK) >> 16,
+ ag = (c1 & GREEN_MASK) >> 8,
+ ab = (c1 & BLUE_MASK),
+ br = (c2 & RED_MASK) >> 16,
+ bg = (c2 & GREEN_MASK) >> 8,
+ bb = (c2 & BLUE_MASK);
+
+ var cr = 0;
+ if (br !== 0) {
+ cr = ((255 - ar) << 8) / br;
+ cr = 255 - ((cr < 0) ? 0 : ((cr > 255) ? 255 : cr));
+ }
+
+ var cg = 0;
+ if (bg !== 0) {
+ cg = ((255 - ag) << 8) / bg;
+ cg = 255 - ((cg < 0) ? 0 : ((cg > 255) ? 255 : cg));
+ }
+
+ var cb = 0;
+ if (bb !== 0) {
+ cb = ((255 - ab) << 8) / bb;
+ cb = 255 - ((cb < 0) ? 0 : ((cb > 255) ? 255 : cb));
+ }
+
+ return applyMode(c1, f, ar, ag, ab, br, bg, bb, cr, cg, cb);
+ }
+ };
+ }());
+
+ function color$4(aValue1, aValue2, aValue3, aValue4) {
+ var r, g, b, a;
+
+ if (curColorMode === PConstants.HSB) {
+ var rgb = p.color.toRGB(aValue1, aValue2, aValue3);
+ r = rgb[0];
+ g = rgb[1];
+ b = rgb[2];
+ } else {
+ r = Math.round(255 * (aValue1 / colorModeX));
+ g = Math.round(255 * (aValue2 / colorModeY));
+ b = Math.round(255 * (aValue3 / colorModeZ));
+ }
+
+ a = Math.round(255 * (aValue4 / colorModeA));
+
+ // Limit values less than 0 and greater than 255
+ r = (r < 0) ? 0 : r;
+ g = (g < 0) ? 0 : g;
+ b = (b < 0) ? 0 : b;
+ a = (a < 0) ? 0 : a;
+ r = (r > 255) ? 255 : r;
+ g = (g > 255) ? 255 : g;
+ b = (b > 255) ? 255 : b;
+ a = (a > 255) ? 255 : a;
+
+ // Create color int
+ return (a << 24) & PConstants.ALPHA_MASK | (r << 16) & PConstants.RED_MASK | (g << 8) & PConstants.GREEN_MASK | b & PConstants.BLUE_MASK;
+ }
+
+ function color$2(aValue1, aValue2) {
+ var a;
+
+ // Color int and alpha
+ if (aValue1 & PConstants.ALPHA_MASK) {
+ a = Math.round(255 * (aValue2 / colorModeA));
+ // Limit values less than 0 and greater than 255
+ a = (a > 255) ? 255 : a;
+ a = (a < 0) ? 0 : a;
+
+ return aValue1 - (aValue1 & PConstants.ALPHA_MASK) + ((a << 24) & PConstants.ALPHA_MASK);
+ }
+ // Grayscale and alpha
+ if (curColorMode === PConstants.RGB) {
+ return color$4(aValue1, aValue1, aValue1, aValue2);
+ }
+ if (curColorMode === PConstants.HSB) {
+ return color$4(0, 0, (aValue1 / colorModeX) * colorModeZ, aValue2);
+ }
+ }
+
+ function color$1(aValue1) {
+ // Grayscale
+ if (aValue1 <= colorModeX && aValue1 >= 0) {
+ if (curColorMode === PConstants.RGB) {
+ return color$4(aValue1, aValue1, aValue1, colorModeA);
+ }
+ if (curColorMode === PConstants.HSB) {
+ return color$4(0, 0, (aValue1 / colorModeX) * colorModeZ, colorModeA);
+ }
+ }
+ // Color int
+ if (aValue1) {
+ if (aValue1 > 2147483647) {
+ // Java Overflow
+ aValue1 -= 4294967296;
+ }
+ return aValue1;
+ }
+ }
+
+ /**
+ * Creates colors for storing in variables of the color datatype. The parameters are
+ * interpreted as RGB or HSB values depending on the current colorMode(). The default
+ * mode is RGB values from 0 to 255 and therefore, the function call color(255, 204, 0)
+ * will return a bright yellow color. More about how colors are stored can be found in
+ * the reference for the color datatype.
+ *
+ * @param {int|float} aValue1 red or hue or grey values relative to the current color range.
+ * Also can be color value in hexadecimal notation (i.e. #FFCC00 or 0xFFFFCC00)
+ * @param {int|float} aValue2 green or saturation values relative to the current color range
+ * @param {int|float} aValue3 blue or brightness values relative to the current color range
+ * @param {int|float} aValue4 relative to current color range. Represents alpha
+ *
+ * @returns {color} the color
+ *
+ * @see colorMode
+ */
+ p.color = function(aValue1, aValue2, aValue3, aValue4) {
+
+ // 4 arguments: (R, G, B, A) or (H, S, B, A)
+ if (aValue1 !== undef && aValue2 !== undef && aValue3 !== undef && aValue4 !== undef) {
+ return color$4(aValue1, aValue2, aValue3, aValue4);
+ }
+
+ // 3 arguments: (R, G, B) or (H, S, B)
+ if (aValue1 !== undef && aValue2 !== undef && aValue3 !== undef) {
+ return color$4(aValue1, aValue2, aValue3, colorModeA);
+ }
+
+ // 2 arguments: (Color, A) or (Grayscale, A)
+ if (aValue1 !== undef && aValue2 !== undef) {
+ return color$2(aValue1, aValue2);
+ }
+
+ // 1 argument: (Grayscale) or (Color)
+ if (typeof aValue1 === "number") {
+ return color$1(aValue1);
+ }
+
+ // Default
+ return color$4(colorModeX, colorModeY, colorModeZ, colorModeA);
+ };
+
+ // Ease of use function to extract the colour bits into a string
+ p.color.toString = function(colorInt) {
+ return "rgba(" + ((colorInt & PConstants.RED_MASK) >>> 16) + "," + ((colorInt & PConstants.GREEN_MASK) >>> 8) +
+ "," + ((colorInt & PConstants.BLUE_MASK)) + "," + ((colorInt & PConstants.ALPHA_MASK) >>> 24) / 255 + ")";
+ };
+
+ // Easy of use function to pack rgba values into a single bit-shifted color int.
+ p.color.toInt = function(r, g, b, a) {
+ return (a << 24) & PConstants.ALPHA_MASK | (r << 16) & PConstants.RED_MASK | (g << 8) & PConstants.GREEN_MASK | b & PConstants.BLUE_MASK;
+ };
+
+ // Creates a simple array in [R, G, B, A] format, [255, 255, 255, 255]
+ p.color.toArray = function(colorInt) {
+ return [(colorInt & PConstants.RED_MASK) >>> 16, (colorInt & PConstants.GREEN_MASK) >>> 8,
+ colorInt & PConstants.BLUE_MASK, (colorInt & PConstants.ALPHA_MASK) >>> 24];
+ };
+
+ // Creates a WebGL color array in [R, G, B, A] format. WebGL wants the color ranges between 0 and 1, [1, 1, 1, 1]
+ p.color.toGLArray = function(colorInt) {
+ return [((colorInt & PConstants.RED_MASK) >>> 16) / 255, ((colorInt & PConstants.GREEN_MASK) >>> 8) / 255,
+ (colorInt & PConstants.BLUE_MASK) / 255, ((colorInt & PConstants.ALPHA_MASK) >>> 24) / 255];
+ };
+
+ // HSB conversion function from Mootools, MIT Licensed
+ p.color.toRGB = function(h, s, b) {
+ // Limit values greater than range
+ h = (h > colorModeX) ? colorModeX : h;
+ s = (s > colorModeY) ? colorModeY : s;
+ b = (b > colorModeZ) ? colorModeZ : b;
+
+ h = (h / colorModeX) * 360;
+ s = (s / colorModeY) * 100;
+ b = (b / colorModeZ) * 100;
+
+ var br = Math.round(b / 100 * 255);
+
+ if (s === 0) { // Grayscale
+ return [br, br, br];
+ }
+ var hue = h % 360;
+ var f = hue % 60;
+ var p = Math.round((b * (100 - s)) / 10000 * 255);
+ var q = Math.round((b * (6000 - s * f)) / 600000 * 255);
+ var t = Math.round((b * (6000 - s * (60 - f))) / 600000 * 255);
+ switch (Math.floor(hue / 60)) {
+ case 0:
+ return [br, t, p];
+ case 1:
+ return [q, br, p];
+ case 2:
+ return [p, br, t];
+ case 3:
+ return [p, q, br];
+ case 4:
+ return [t, p, br];
+ case 5:
+ return [br, p, q];
+ }
+ };
+
+ function colorToHSB(colorInt) {
+ var red, green, blue;
+
+ red = ((colorInt & PConstants.RED_MASK) >>> 16) / 255;
+ green = ((colorInt & PConstants.GREEN_MASK) >>> 8) / 255;
+ blue = (colorInt & PConstants.BLUE_MASK) / 255;
+
+ var max = p.max(p.max(red,green), blue),
+ min = p.min(p.min(red,green), blue),
+ hue, saturation;
+
+ if (min === max) {
+ return [0, 0, max*colorModeZ];
+ }
+ saturation = (max - min) / max;
+
+ if (red === max) {
+ hue = (green - blue) / (max - min);
+ } else if (green === max) {
+ hue = 2 + ((blue - red) / (max - min));
+ } else {
+ hue = 4 + ((red - green) / (max - min));
+ }
+
+ hue /= 6;
+
+ if (hue < 0) {
+ hue += 1;
+ } else if (hue > 1) {
+ hue -= 1;
+ }
+ return [hue*colorModeX, saturation*colorModeY, max*colorModeZ];
+ }
+
+ /**
+ * Extracts the brightness value from a color.
+ *
+ * @param {color} colInt any value of the color datatype
+ *
+ * @returns {float} The brightness color value.
+ *
+ * @see red
+ * @see green
+ * @see blue
+ * @see hue
+ * @see saturation
+ */
+ p.brightness = function(colInt){
+ return colorToHSB(colInt)[2];
+ };
+
+ /**
+ * Extracts the saturation value from a color.
+ *
+ * @param {color} colInt any value of the color datatype
+ *
+ * @returns {float} The saturation color value.
+ *
+ * @see red
+ * @see green
+ * @see blue
+ * @see hue
+ * @see brightness
+ */
+ p.saturation = function(colInt){
+ return colorToHSB(colInt)[1];
+ };
+
+ /**
+ * Extracts the hue value from a color.
+ *
+ * @param {color} colInt any value of the color datatype
+ *
+ * @returns {float} The hue color value.
+ *
+ * @see red
+ * @see green
+ * @see blue
+ * @see saturation
+ * @see brightness
+ */
+ p.hue = function(colInt){
+ return colorToHSB(colInt)[0];
+ };
+
+ /**
+ * Extracts the red value from a color, scaled to match current colorMode().
+ * This value is always returned as a float so be careful not to assign it to an int value.
+ *
+ * @param {color} aColor any value of the color datatype
+ *
+ * @returns {float} The red color value.
+ *
+ * @see green
+ * @see blue
+ * @see alpha
+ * @see >> right shift
+ * @see hue
+ * @see saturation
+ * @see brightness
+ */
+ p.red = function(aColor) {
+ return ((aColor & PConstants.RED_MASK) >>> 16) / 255 * colorModeX;
+ };
+
+ /**
+ * Extracts the green value from a color, scaled to match current colorMode().
+ * This value is always returned as a float so be careful not to assign it to an int value.
+ *
+ * @param {color} aColor any value of the color datatype
+ *
+ * @returns {float} The green color value.
+ *
+ * @see red
+ * @see blue
+ * @see alpha
+ * @see >> right shift
+ * @see hue
+ * @see saturation
+ * @see brightness
+ */
+ p.green = function(aColor) {
+ return ((aColor & PConstants.GREEN_MASK) >>> 8) / 255 * colorModeY;
+ };
+
+ /**
+ * Extracts the blue value from a color, scaled to match current colorMode().
+ * This value is always returned as a float so be careful not to assign it to an int value.
+ *
+ * @param {color} aColor any value of the color datatype
+ *
+ * @returns {float} The blue color value.
+ *
+ * @see red
+ * @see green
+ * @see alpha
+ * @see >> right shift
+ * @see hue
+ * @see saturation
+ * @see brightness
+ */
+ p.blue = function(aColor) {
+ return (aColor & PConstants.BLUE_MASK) / 255 * colorModeZ;
+ };
+
+ /**
+ * Extracts the alpha value from a color, scaled to match current colorMode().
+ * This value is always returned as a float so be careful not to assign it to an int value.
+ *
+ * @param {color} aColor any value of the color datatype
+ *
+ * @returns {float} The alpha color value.
+ *
+ * @see red
+ * @see green
+ * @see blue
+ * @see >> right shift
+ * @see hue
+ * @see saturation
+ * @see brightness
+ */
+ p.alpha = function(aColor) {
+ return ((aColor & PConstants.ALPHA_MASK) >>> 24) / 255 * colorModeA;
+ };
+
+ /**
+ * Calculates a color or colors between two colors at a specific increment.
+ * The amt parameter is the amount to interpolate between the two values where 0.0
+ * equal to the first point, 0.1 is very near the first point, 0.5 is half-way in between, etc.
+ *
+ * @param {color} c1 interpolate from this color
+ * @param {color} c2 interpolate to this color
+ * @param {float} amt between 0.0 and 1.0
+ *
+ * @returns {float} The blended color.
+ *
+ * @see blendColor
+ * @see color
+ */
+ p.lerpColor = function(c1, c2, amt) {
+ var r, g, b, a, r1, g1, b1, a1, r2, g2, b2, a2;
+ var hsb1, hsb2, rgb, h, s;
+ var colorBits1 = p.color(c1);
+ var colorBits2 = p.color(c2);
+
+ if (curColorMode === PConstants.HSB) {
+ // Special processing for HSB mode.
+ // Get HSB and Alpha values for Color 1 and 2
+ hsb1 = colorToHSB(colorBits1);
+ a1 = ((colorBits1 & PConstants.ALPHA_MASK) >>> 24) / colorModeA;
+ hsb2 = colorToHSB(colorBits2);
+ a2 = ((colorBits2 & PConstants.ALPHA_MASK) >>> 24) / colorModeA;
+
+ // Return lerp value for each channel, for HSB components
+ h = p.lerp(hsb1[0], hsb2[0], amt);
+ s = p.lerp(hsb1[1], hsb2[1], amt);
+ b = p.lerp(hsb1[2], hsb2[2], amt);
+ rgb = p.color.toRGB(h, s, b);
+ // ... and for Alpha-range
+ a = (p.lerp(a1, a2, amt) * colorModeA + 0.5) | 0;
+
+ return (a << 24) & PConstants.ALPHA_MASK |
+ (rgb[0] << 16) & PConstants.RED_MASK |
+ (rgb[1] << 8) & PConstants.GREEN_MASK |
+ rgb[2] & PConstants.BLUE_MASK;
+ }
+
+ // Get RGBA values for Color 1 to floats
+ r1 = (colorBits1 & PConstants.RED_MASK) >>> 16;
+ g1 = (colorBits1 & PConstants.GREEN_MASK) >>> 8;
+ b1 = (colorBits1 & PConstants.BLUE_MASK);
+ a1 = ((colorBits1 & PConstants.ALPHA_MASK) >>> 24) / colorModeA;
+
+ // Get RGBA values for Color 2 to floats
+ r2 = (colorBits2 & PConstants.RED_MASK) >>> 16;
+ g2 = (colorBits2 & PConstants.GREEN_MASK) >>> 8;
+ b2 = (colorBits2 & PConstants.BLUE_MASK);
+ a2 = ((colorBits2 & PConstants.ALPHA_MASK) >>> 24) / colorModeA;
+
+ // Return lerp value for each channel, INT for color, Float for Alpha-range
+ r = (p.lerp(r1, r2, amt) + 0.5) | 0;
+ g = (p.lerp(g1, g2, amt) + 0.5) | 0;
+ b = (p.lerp(b1, b2, amt) + 0.5) | 0;
+ a = (p.lerp(a1, a2, amt) * colorModeA + 0.5) | 0;
+
+ return (a << 24) & PConstants.ALPHA_MASK |
+ (r << 16) & PConstants.RED_MASK |
+ (g << 8) & PConstants.GREEN_MASK |
+ b & PConstants.BLUE_MASK;
+ };
+
+ /**
+ * Changes the way Processing interprets color data. By default, fill(), stroke(), and background()
+ * colors are set by values between 0 and 255 using the RGB color model. It is possible to change the
+ * numerical range used for specifying colors and to switch color systems. For example, calling colorMode(RGB, 1.0)
+ * will specify that values are specified between 0 and 1. The limits for defining colors are altered by setting the
+ * parameters range1, range2, range3, and range 4.
+ *
+ * @param {MODE} mode Either RGB or HSB, corresponding to Red/Green/Blue and Hue/Saturation/Brightness
+ * @param {int|float} range range for all color elements
+ * @param {int|float} range1 range for the red or hue depending on the current color mode
+ * @param {int|float} range2 range for the green or saturation depending on the current color mode
+ * @param {int|float} range3 range for the blue or brightness depending on the current color mode
+ * @param {int|float} range4 range for the alpha
+ *
+ * @returns none
+ *
+ * @see background
+ * @see fill
+ * @see stroke
+ */
+ p.colorMode = function() { // mode, range1, range2, range3, range4
+ curColorMode = arguments[0];
+ if (arguments.length > 1) {
+ colorModeX = arguments[1];
+ colorModeY = arguments[2] || arguments[1];
+ colorModeZ = arguments[3] || arguments[1];
+ colorModeA = arguments[4] || arguments[1];
+ }
+ };
+
+ /**
+ * Blends two color values together based on the blending mode given as the MODE parameter.
+ * The possible modes are described in the reference for the blend() function.
+ *
+ * @param {color} c1 color: the first color to blend
+ * @param {color} c2 color: the second color to blend
+ * @param {MODE} MODE Either BLEND, ADD, SUBTRACT, DARKEST, LIGHTEST, DIFFERENCE, EXCLUSION, MULTIPLY,
+ * SCREEN, OVERLAY, HARD_LIGHT, SOFT_LIGHT, DODGE, or BURN
+ *
+ * @returns {float} The blended color.
+ *
+ * @see blend
+ * @see color
+ */
+ p.blendColor = function(c1, c2, mode) {
+ if (mode === PConstants.REPLACE) {
+ return p.modes.replace(c1, c2);
+ } else if (mode === PConstants.BLEND) {
+ return p.modes.blend(c1, c2);
+ } else if (mode === PConstants.ADD) {
+ return p.modes.add(c1, c2);
+ } else if (mode === PConstants.SUBTRACT) {
+ return p.modes.subtract(c1, c2);
+ } else if (mode === PConstants.LIGHTEST) {
+ return p.modes.lightest(c1, c2);
+ } else if (mode === PConstants.DARKEST) {
+ return p.modes.darkest(c1, c2);
+ } else if (mode === PConstants.DIFFERENCE) {
+ return p.modes.difference(c1, c2);
+ } else if (mode === PConstants.EXCLUSION) {
+ return p.modes.exclusion(c1, c2);
+ } else if (mode === PConstants.MULTIPLY) {
+ return p.modes.multiply(c1, c2);
+ } else if (mode === PConstants.SCREEN) {
+ return p.modes.screen(c1, c2);
+ } else if (mode === PConstants.HARD_LIGHT) {
+ return p.modes.hard_light(c1, c2);
+ } else if (mode === PConstants.SOFT_LIGHT) {
+ return p.modes.soft_light(c1, c2);
+ } else if (mode === PConstants.OVERLAY) {
+ return p.modes.overlay(c1, c2);
+ } else if (mode === PConstants.DODGE) {
+ return p.modes.dodge(c1, c2);
+ } else if (mode === PConstants.BURN) {
+ return p.modes.burn(c1, c2);
+ }
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Canvas-Matrix manipulation
+ ////////////////////////////////////////////////////////////////////////////
+
+ function saveContext() {
+ curContext.save();
+ }
+
+ function restoreContext() {
+ curContext.restore();
+ isStrokeDirty = true;
+ isFillDirty = true;
+ }
+
+ /**
+ * Prints the current matrix to the text window.
+ *
+ * @returns none
+ *
+ * @see pushMatrix
+ * @see popMatrix
+ * @see resetMatrix
+ * @see applyMatrix
+ */
+ p.printMatrix = function() {
+ modelView.print();
+ };
+
+ /**
+ * Specifies an amount to displace objects within the display window. The x parameter specifies left/right translation,
+ * the y parameter specifies up/down translation, and the z parameter specifies translations toward/away from the screen.
+ * Using this function with the z parameter requires using the P3D or OPENGL parameter in combination with size as shown
+ * in the above example. Transformations apply to everything that happens after and subsequent calls to the function
+ * accumulates the effect. For example, calling translate(50, 0) and then translate(20, 0) is the same as translate(70, 0).
+ * If translate() is called within draw(), the transformation is reset when the loop begins again.
+ * This function can be further controlled by the pushMatrix() and popMatrix().
+ *
+ * @param {int|float} x left/right translation
+ * @param {int|float} y up/down translation
+ * @param {int|float} z forward/back translation
+ *
+ * @returns none
+ *
+ * @see pushMatrix
+ * @see popMatrix
+ * @see scale
+ * @see rotate
+ * @see rotateX
+ * @see rotateY
+ * @see rotateZ
+ */
+ Drawing2D.prototype.translate = function(x, y) {
+ modelView.translate(x, y);
+ modelViewInv.invTranslate(x, y);
+ curContext.translate(x, y);
+ };
+
+ Drawing3D.prototype.translate = function(x, y, z) {
+ modelView.translate(x, y, z);
+ modelViewInv.invTranslate(x, y, z);
+ };
+
+ /**
+ * Increases or decreases the size of a shape by expanding and contracting vertices. Objects always scale from their
+ * relative origin to the coordinate system. Scale values are specified as decimal percentages. For example, the
+ * function call scale(2.0) increases the dimension of a shape by 200%. Transformations apply to everything that
+ * happens after and subsequent calls to the function multiply the effect. For example, calling scale(2.0) and
+ * then scale(1.5) is the same as scale(3.0). If scale() is called within draw(), the transformation is reset when
+ * the loop begins again. Using this fuction with the z parameter requires passing P3D or OPENGL into the size()
+ * parameter as shown in the example above. This function can be further controlled by pushMatrix() and popMatrix().
+ *
+ * @param {int|float} size percentage to scale the object
+ * @param {int|float} x percentage to scale the object in the x-axis
+ * @param {int|float} y percentage to scale the object in the y-axis
+ * @param {int|float} z percentage to scale the object in the z-axis
+ *
+ * @returns none
+ *
+ * @see pushMatrix
+ * @see popMatrix
+ * @see translate
+ * @see rotate
+ * @see rotateX
+ * @see rotateY
+ * @see rotateZ
+ */
+ Drawing2D.prototype.scale = function(x, y) {
+ modelView.scale(x, y);
+ modelViewInv.invScale(x, y);
+ curContext.scale(x, y || x);
+ };
+
+ Drawing3D.prototype.scale = function(x, y, z) {
+ modelView.scale(x, y, z);
+ modelViewInv.invScale(x, y, z);
+ };
+
+
+ /**
+ * helper function for applying a transfrom matrix to a 2D context.
+ */
+ Drawing2D.prototype.transform = function(pmatrix) {
+ var e = pmatrix.array();
+ curContext.transform(e[0],e[3],e[1],e[4],e[2],e[5]);
+ };
+
+ /**
+ * helper function for applying a transfrom matrix to a 3D context.
+ * not currently implemented.
+ */
+ Drawing3D.prototype.transformm = function(pmatrix3d) {
+ throw("p.transform is currently not supported in 3D mode");
+ };
+
+
+ /**
+ * Pushes the current transformation matrix onto the matrix stack. Understanding pushMatrix() and popMatrix()
+ * requires understanding the concept of a matrix stack. The pushMatrix() function saves the current coordinate
+ * system to the stack and popMatrix() restores the prior coordinate system. pushMatrix() and popMatrix() are
+ * used in conjuction with the other transformation methods and may be embedded to control the scope of
+ * the transformations.
+ *
+ * @returns none
+ *
+ * @see popMatrix
+ * @see translate
+ * @see rotate
+ * @see rotateX
+ * @see rotateY
+ * @see rotateZ
+ */
+ Drawing2D.prototype.pushMatrix = function() {
+ userMatrixStack.load(modelView);
+ userReverseMatrixStack.load(modelViewInv);
+ saveContext();
+ };
+
+ Drawing3D.prototype.pushMatrix = function() {
+ userMatrixStack.load(modelView);
+ userReverseMatrixStack.load(modelViewInv);
+ };
+
+ /**
+ * Pops the current transformation matrix off the matrix stack. Understanding pushing and popping requires
+ * understanding the concept of a matrix stack. The pushMatrix() function saves the current coordinate system to
+ * the stack and popMatrix() restores the prior coordinate system. pushMatrix() and popMatrix() are used in
+ * conjuction with the other transformation methods and may be embedded to control the scope of the transformations.
+ *
+ * @returns none
+ *
+ * @see popMatrix
+ * @see pushMatrix
+ */
+ Drawing2D.prototype.popMatrix = function() {
+ modelView.set(userMatrixStack.pop());
+ modelViewInv.set(userReverseMatrixStack.pop());
+ restoreContext();
+ };
+
+ Drawing3D.prototype.popMatrix = function() {
+ modelView.set(userMatrixStack.pop());
+ modelViewInv.set(userReverseMatrixStack.pop());
+ };
+
+ /**
+ * Replaces the current matrix with the identity matrix. The equivalent function in OpenGL is glLoadIdentity().
+ *
+ * @returns none
+ *
+ * @see popMatrix
+ * @see pushMatrix
+ * @see applyMatrix
+ * @see printMatrix
+ */
+ Drawing2D.prototype.resetMatrix = function() {
+ modelView.reset();
+ modelViewInv.reset();
+ curContext.setTransform(1,0,0,1,0,0);
+ };
+
+ Drawing3D.prototype.resetMatrix = function() {
+ modelView.reset();
+ modelViewInv.reset();
+ };
+
+ /**
+ * Multiplies the current matrix by the one specified through the parameters. This is very slow because it will
+ * try to calculate the inverse of the transform, so avoid it whenever possible. The equivalent function
+ * in OpenGL is glMultMatrix().
+ *
+ * @param {int|float} n00-n15 numbers which define the 4x4 matrix to be multiplied
+ *
+ * @returns none
+ *
+ * @see popMatrix
+ * @see pushMatrix
+ * @see resetMatrix
+ * @see printMatrix
+ */
+ DrawingShared.prototype.applyMatrix = function() {
+ var a = arguments;
+ modelView.apply(a[0], a[1], a[2], a[3], a[4], a[5], a[6], a[7], a[8], a[9], a[10], a[11], a[12], a[13], a[14], a[15]);
+ modelViewInv.invApply(a[0], a[1], a[2], a[3], a[4], a[5], a[6], a[7], a[8], a[9], a[10], a[11], a[12], a[13], a[14], a[15]);
+ };
+
+ Drawing2D.prototype.applyMatrix = function() {
+ var a = arguments;
+ for (var cnt = a.length; cnt < 16; cnt++) {
+ a[cnt] = 0;
+ }
+ a[10] = a[15] = 1;
+ DrawingShared.prototype.applyMatrix.apply(this, a);
+ };
+
+ /**
+ * Rotates a shape around the x-axis the amount specified by the angle parameter. Angles should be
+ * specified in radians (values from 0 to PI*2) or converted to radians with the radians() function.
+ * Objects are always rotated around their relative position to the origin and positive numbers
+ * rotate objects in a counterclockwise direction. Transformations apply to everything that happens
+ * after and subsequent calls to the function accumulates the effect. For example, calling rotateX(PI/2)
+ * and then rotateX(PI/2) is the same as rotateX(PI). If rotateX() is called within the draw(), the
+ * transformation is reset when the loop begins again. This function requires passing P3D or OPENGL
+ * into the size() parameter as shown in the example above.
+ *
+ * @param {int|float} angleInRadians angle of rotation specified in radians
+ *
+ * @returns none
+ *
+ * @see rotateY
+ * @see rotateZ
+ * @see rotate
+ * @see translate
+ * @see scale
+ * @see popMatrix
+ * @see pushMatrix
+ */
+ p.rotateX = function(angleInRadians) {
+ modelView.rotateX(angleInRadians);
+ modelViewInv.invRotateX(angleInRadians);
+ };
+
+ /**
+ * Rotates a shape around the z-axis the amount specified by the angle parameter. Angles should be
+ * specified in radians (values from 0 to PI*2) or converted to radians with the radians() function.
+ * Objects are always rotated around their relative position to the origin and positive numbers
+ * rotate objects in a counterclockwise direction. Transformations apply to everything that happens
+ * after and subsequent calls to the function accumulates the effect. For example, calling rotateZ(PI/2)
+ * and then rotateZ(PI/2) is the same as rotateZ(PI). If rotateZ() is called within the draw(), the
+ * transformation is reset when the loop begins again. This function requires passing P3D or OPENGL
+ * into the size() parameter as shown in the example above.
+ *
+ * @param {int|float} angleInRadians angle of rotation specified in radians
+ *
+ * @returns none
+ *
+ * @see rotateX
+ * @see rotateY
+ * @see rotate
+ * @see translate
+ * @see scale
+ * @see popMatrix
+ * @see pushMatrix
+ */
+ Drawing2D.prototype.rotateZ = function() {
+ throw "rotateZ() is not supported in 2D mode. Use rotate(float) instead.";
+ };
+
+ Drawing3D.prototype.rotateZ = function(angleInRadians) {
+ modelView.rotateZ(angleInRadians);
+ modelViewInv.invRotateZ(angleInRadians);
+ };
+
+ /**
+ * Rotates a shape around the y-axis the amount specified by the angle parameter. Angles should be
+ * specified in radians (values from 0 to PI*2) or converted to radians with the radians() function.
+ * Objects are always rotated around their relative position to the origin and positive numbers
+ * rotate objects in a counterclockwise direction. Transformations apply to everything that happens
+ * after and subsequent calls to the function accumulates the effect. For example, calling rotateY(PI/2)
+ * and then rotateY(PI/2) is the same as rotateY(PI). If rotateY() is called within the draw(), the
+ * transformation is reset when the loop begins again. This function requires passing P3D or OPENGL
+ * into the size() parameter as shown in the example above.
+ *
+ * @param {int|float} angleInRadians angle of rotation specified in radians
+ *
+ * @returns none
+ *
+ * @see rotateX
+ * @see rotateZ
+ * @see rotate
+ * @see translate
+ * @see scale
+ * @see popMatrix
+ * @see pushMatrix
+ */
+ p.rotateY = function(angleInRadians) {
+ modelView.rotateY(angleInRadians);
+ modelViewInv.invRotateY(angleInRadians);
+ };
+
+ /**
+ * Rotates a shape the amount specified by the angle parameter. Angles should be specified in radians
+ * (values from 0 to TWO_PI) or converted to radians with the radians() function. Objects are always
+ * rotated around their relative position to the origin and positive numbers rotate objects in a
+ * clockwise direction. Transformations apply to everything that happens after and subsequent calls
+ * to the function accumulates the effect. For example, calling rotate(HALF_PI) and then rotate(HALF_PI)
+ * is the same as rotate(PI). All tranformations are reset when draw() begins again. Technically,
+ * rotate() multiplies the current transformation matrix by a rotation matrix. This function can be
+ * further controlled by the pushMatrix() and popMatrix().
+ *
+ * @param {int|float} angleInRadians angle of rotation specified in radians
+ *
+ * @returns none
+ *
+ * @see rotateX
+ * @see rotateY
+ * @see rotateZ
+ * @see rotate
+ * @see translate
+ * @see scale
+ * @see popMatrix
+ * @see pushMatrix
+ */
+ Drawing2D.prototype.rotate = function(angleInRadians) {
+ modelView.rotateZ(angleInRadians);
+ modelViewInv.invRotateZ(angleInRadians);
+ curContext.rotate(angleInRadians);
+ };
+
+ Drawing3D.prototype.rotate = function(angleInRadians) {
+ if (arguments.length < 4) {
+ p.rotateZ(angleInRadians);
+ } else {
+ modelView.rotate(angleInRadians, arguments[1], arguments[2], arguments[3]);
+ modelViewInv.rotate((-angleInRadians), arguments[1], arguments[2], arguments[3]);
+ }
+ };
+
+ /**
+ * Shears a shape around the x-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to radians
+ * with the radians() function. Objects are always sheared around their relative position
+ * to the origin and positive numbers shear objects in a clockwise direction. Transformations
+ * apply to everything that happens after and subsequent calls to the function accumulates the
+ * effect. For example, calling shearX(PI/2) and then shearX(PI/2) is the same as shearX(PI)
+ *
+ * @param {int|float} angleInRadians angle of rotation specified in radians
+ *
+ * @returns none
+ *
+ * @see rotateX
+ * @see rotateY
+ * @see rotateZ
+ * @see rotate
+ * @see translate
+ * @see scale
+ * @see popMatrix
+ * @see pushMatrix
+ */
+
+ Drawing2D.prototype.shearX = function(angleInRadians) {
+ modelView.shearX(angleInRadians);
+ curContext.transform(1,0,angleInRadians,1,0,0);
+ };
+
+ Drawing3D.prototype.shearX = function(angleInRadians) {
+ modelView.shearX(angleInRadians);
+ };
+
+ /**
+ * Shears a shape around the y-axis the amount specified by the angle parameter.
+ * Angles should be specified in radians (values from 0 to PI*2) or converted to
+ * radians with the radians() function. Objects are always sheared around their
+ * relative position to the origin and positive numbers shear objects in a
+ * clockwise direction. Transformations apply to everything that happens after
+ * and subsequent calls to the function accumulates the effect. For example,
+ * calling shearY(PI/2) and then shearY(PI/2) is the same as shearY(PI).
+ *
+ * @param {int|float} angleInRadians angle of rotation specified in radians
+ *
+ * @returns none
+ *
+ * @see rotateX
+ * @see rotateY
+ * @see rotateZ
+ * @see rotate
+ * @see translate
+ * @see scale
+ * @see popMatrix
+ * @see pushMatrix
+ * @see shearX
+ */
+
+ Drawing2D.prototype.shearY = function(angleInRadians) {
+ modelView.shearY(angleInRadians);
+ curContext.transform(1,angleInRadians,0,1,0,0);
+ };
+
+ Drawing3D.prototype.shearY = function(angleInRadians) {
+ modelView.shearY(angleInRadians);
+ };
+
+ /**
+ * The pushStyle() function saves the current style settings and popStyle() restores the prior settings.
+ * Note that these functions are always used together. They allow you to change the style settings and later
+ * return to what you had. When a new style is started with pushStyle(), it builds on the current style information.
+ * The pushStyle() and popStyle() functions can be embedded to provide more control (see the second example
+ * above for a demonstration.)
+ * The style information controlled by the following functions are included in the style: fill(), stroke(), tint(),
+ * strokeWeight(), strokeCap(), strokeJoin(), imageMode(), rectMode(), ellipseMode(), shapeMode(), colorMode(),
+ * textAlign(), textFont(), textMode(), textSize(), textLeading(), emissive(), specular(), shininess(), ambient()
+ *
+ * @returns none
+ *
+ * @see popStyle
+ */
+ p.pushStyle = function() {
+ // Save the canvas state.
+ saveContext();
+
+ p.pushMatrix();
+
+ var newState = {
+ 'doFill': doFill,
+ 'currentFillColor': currentFillColor,
+ 'doStroke': doStroke,
+ 'currentStrokeColor': currentStrokeColor,
+ 'curTint': curTint,
+ 'curRectMode': curRectMode,
+ 'curColorMode': curColorMode,
+ 'colorModeX': colorModeX,
+ 'colorModeZ': colorModeZ,
+ 'colorModeY': colorModeY,
+ 'colorModeA': colorModeA,
+ 'curTextFont': curTextFont,
+ 'horizontalTextAlignment': horizontalTextAlignment,
+ 'verticalTextAlignment': verticalTextAlignment,
+ 'textMode': textMode,
+ 'curFontName': curFontName,
+ 'curTextSize': curTextSize,
+ 'curTextAscent': curTextAscent,
+ 'curTextDescent': curTextDescent,
+ 'curTextLeading': curTextLeading
+ };
+
+ styleArray.push(newState);
+ };
+
+ /**
+ * The pushStyle() function saves the current style settings and popStyle() restores the prior settings; these
+ * functions are always used together. They allow you to change the style settings and later return to what you had.
+ * When a new style is started with pushStyle(), it builds on the current style information. The pushStyle() and
+ * popStyle() functions can be embedded to provide more control (see the second example above for a demonstration.)
+ *
+ * @returns none
+ *
+ * @see pushStyle
+ */
+ p.popStyle = function() {
+ var oldState = styleArray.pop();
+
+ if (oldState) {
+ restoreContext();
+
+ p.popMatrix();
+
+ doFill = oldState.doFill;
+ currentFillColor = oldState.currentFillColor;
+ doStroke = oldState.doStroke;
+ currentStrokeColor = oldState.currentStrokeColor;
+ curTint = oldState.curTint;
+ curRectMode = oldState.curRectMode;
+ curColorMode = oldState.curColorMode;
+ colorModeX = oldState.colorModeX;
+ colorModeZ = oldState.colorModeZ;
+ colorModeY = oldState.colorModeY;
+ colorModeA = oldState.colorModeA;
+ curTextFont = oldState.curTextFont;
+ curFontName = oldState.curFontName;
+ curTextSize = oldState.curTextSize;
+ horizontalTextAlignment = oldState.horizontalTextAlignment;
+ verticalTextAlignment = oldState.verticalTextAlignment;
+ textMode = oldState.textMode;
+ curTextAscent = oldState.curTextAscent;
+ curTextDescent = oldState.curTextDescent;
+ curTextLeading = oldState.curTextLeading;
+ } else {
+ throw "Too many popStyle() without enough pushStyle()";
+ }
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Time based functions
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Processing communicates with the clock on your computer.
+ * The year() function returns the current year as an integer (2003, 2004, 2005, etc).
+ *
+ * @returns {float} The current year.
+ *
+ * @see millis
+ * @see second
+ * @see minute
+ * @see hour
+ * @see day
+ * @see month
+ */
+ p.year = function() {
+ return new Date().getFullYear();
+ };
+ /**
+ * Processing communicates with the clock on your computer.
+ * The month() function returns the current month as a value from 1 - 12.
+ *
+ * @returns {float} The current month.
+ *
+ * @see millis
+ * @see second
+ * @see minute
+ * @see hour
+ * @see day
+ * @see year
+ */
+ p.month = function() {
+ return new Date().getMonth() + 1;
+ };
+ /**
+ * Processing communicates with the clock on your computer.
+ * The day() function returns the current day as a value from 1 - 31.
+ *
+ * @returns {float} The current day.
+ *
+ * @see millis
+ * @see second
+ * @see minute
+ * @see hour
+ * @see month
+ * @see year
+ */
+ p.day = function() {
+ return new Date().getDate();
+ };
+ /**
+ * Processing communicates with the clock on your computer.
+ * The hour() function returns the current hour as a value from 0 - 23.
+ *
+ * @returns {float} The current hour.
+ *
+ * @see millis
+ * @see second
+ * @see minute
+ * @see month
+ * @see day
+ * @see year
+ */
+ p.hour = function() {
+ return new Date().getHours();
+ };
+ /**
+ * Processing communicates with the clock on your computer.
+ * The minute() function returns the current minute as a value from 0 - 59.
+ *
+ * @returns {float} The current minute.
+ *
+ * @see millis
+ * @see second
+ * @see month
+ * @see hour
+ * @see day
+ * @see year
+ */
+ p.minute = function() {
+ return new Date().getMinutes();
+ };
+ /**
+ * Processing communicates with the clock on your computer.
+ * The second() function returns the current second as a value from 0 - 59.
+ *
+ * @returns {float} The current minute.
+ *
+ * @see millis
+ * @see month
+ * @see minute
+ * @see hour
+ * @see day
+ * @see year
+ */
+ p.second = function() {
+ return new Date().getSeconds();
+ };
+ /**
+ * Returns the number of milliseconds (thousandths of a second) since starting a sketch.
+ * This information is often used for timing animation sequences.
+ *
+ * @returns {long} The number of milliseconds since starting the sketch.
+ *
+ * @see month
+ * @see second
+ * @see minute
+ * @see hour
+ * @see day
+ * @see year
+ */
+ p.millis = function() {
+ return Date.now() - start;
+ };
+
+ /**
+ * Executes the code within draw() one time. This functions allows the program to update
+ * the display window only when necessary, for example when an event registered by
+ * mousePressed() or keyPressed() occurs.
+ * In structuring a program, it only makes sense to call redraw() within events such as
+ * mousePressed(). This is because redraw() does not run draw() immediately (it only sets
+ * a flag that indicates an update is needed).
+ * Calling redraw() within draw() has no effect because draw() is continuously called anyway.
+ *
+ * @returns none
+ *
+ * @see noLoop
+ * @see loop
+ */
+ function redrawHelper() {
+ var sec = (Date.now() - timeSinceLastFPS) / 1000;
+ framesSinceLastFPS++;
+ var fps = framesSinceLastFPS / sec;
+
+ // recalculate FPS every half second for better accuracy.
+ if (sec > 0.5) {
+ timeSinceLastFPS = Date.now();
+ framesSinceLastFPS = 0;
+ p.__frameRate = fps;
+ }
+
+ p.frameCount++;
+ }
+
+ Drawing2D.prototype.redraw = function() {
+ redrawHelper();
+
+ curContext.lineWidth = lineWidth;
+ var pmouseXLastEvent = p.pmouseX,
+ pmouseYLastEvent = p.pmouseY;
+ p.pmouseX = pmouseXLastFrame;
+ p.pmouseY = pmouseYLastFrame;
+
+ saveContext();
+ p.draw();
+ restoreContext();
+
+ pmouseXLastFrame = p.mouseX;
+ pmouseYLastFrame = p.mouseY;
+ p.pmouseX = pmouseXLastEvent;
+ p.pmouseY = pmouseYLastEvent;
+ };
+
+ Drawing3D.prototype.redraw = function() {
+ redrawHelper();
+
+ var pmouseXLastEvent = p.pmouseX,
+ pmouseYLastEvent = p.pmouseY;
+ p.pmouseX = pmouseXLastFrame;
+ p.pmouseY = pmouseYLastFrame;
+ // even if the color buffer isn't cleared with background(),
+ // the depth buffer needs to be cleared regardless.
+ curContext.clear(curContext.DEPTH_BUFFER_BIT);
+ curContextCache = { attributes: {}, locations: {} };
+ // Delete all the lighting states and the materials the
+ // user set in the last draw() call.
+ p.noLights();
+ p.lightFalloff(1, 0, 0);
+ p.shininess(1);
+ p.ambient(255, 255, 255);
+ p.specular(0, 0, 0);
+ p.emissive(0, 0, 0);
+ p.camera();
+ p.draw();
+
+ pmouseXLastFrame = p.mouseX;
+ pmouseYLastFrame = p.mouseY;
+ p.pmouseX = pmouseXLastEvent;
+ p.pmouseY = pmouseYLastEvent;
+ };
+
+ /**
+ * Stops Processing from continuously executing the code within draw(). If loop() is
+ * called, the code in draw() begin to run continuously again. If using noLoop() in
+ * setup(), it should be the last line inside the block.
+ * When noLoop() is used, it's not possible to manipulate or access the screen inside event
+ * handling functions such as mousePressed() or keyPressed(). Instead, use those functions
+ * to call redraw() or loop(), which will run draw(), which can update the screen properly.
+ * This means that when noLoop() has been called, no drawing can happen, and functions like
+ * saveFrame() or loadPixels() may not be used.
+ * Note that if the sketch is resized, redraw() will be called to update the sketch, even
+ * after noLoop() has been specified. Otherwise, the sketch would enter an odd state until
+ * loop() was called.
+ *
+ * @returns none
+ *
+ * @see redraw
+ * @see draw
+ * @see loop
+ */
+ p.noLoop = function() {
+ doLoop = false;
+ loopStarted = false;
+ clearInterval(looping);
+ curSketch.onPause();
+ };
+
+ /**
+ * Causes Processing to continuously execute the code within draw(). If noLoop() is called,
+ * the code in draw() stops executing.
+ *
+ * @returns none
+ *
+ * @see noLoop
+ */
+ p.loop = function() {
+ if (loopStarted) {
+ return;
+ }
+
+ timeSinceLastFPS = Date.now();
+ framesSinceLastFPS = 0;
+
+ looping = window.setInterval(function() {
+ try {
+ curSketch.onFrameStart();
+ p.redraw();
+ curSketch.onFrameEnd();
+ } catch(e_loop) {
+ window.clearInterval(looping);
+ throw e_loop;
+ }
+ }, curMsPerFrame);
+ doLoop = true;
+ loopStarted = true;
+ curSketch.onLoop();
+ };
+
+ /**
+ * Specifies the number of frames to be displayed every second. If the processor is not
+ * fast enough to maintain the specified rate, it will not be achieved. For example, the
+ * function call frameRate(30) will attempt to refresh 30 times a second. It is recommended
+ * to set the frame rate within setup(). The default rate is 60 frames per second.
+ *
+ * @param {int} aRate number of frames per second.
+ *
+ * @returns none
+ *
+ * @see delay
+ */
+ p.frameRate = function(aRate) {
+ curFrameRate = aRate;
+ curMsPerFrame = 1000 / curFrameRate;
+
+ // clear and reset interval
+ if (doLoop) {
+ p.noLoop();
+ p.loop();
+ }
+ };
+
+ /**
+ * Quits/stops/exits the program.
+ * Rather than terminating immediately, exit() will cause the sketch to exit after draw()
+ * has completed (or after setup() completes if called during the setup() method).
+ *
+ * @returns none
+ */
+ p.exit = function() {
+ // cleanup
+ window.clearInterval(looping);
+ removeInstance(p.externals.canvas.id);
+ delete(curElement.onmousedown);
+
+ // Step through the libraries to detach them
+ for (var lib in Processing.lib) {
+ if (Processing.lib.hasOwnProperty(lib)) {
+ if (Processing.lib[lib].hasOwnProperty("detach")) {
+ Processing.lib[lib].detach(p);
+ }
+ }
+ }
+
+ // clean up all event handling
+ var i = eventHandlers.length;
+ while (i--) {
+ detachEventHandler(eventHandlers[i]);
+ }
+ curSketch.onExit();
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // MISC functions
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Sets the cursor to a predefined symbol, an image, or turns it on if already hidden.
+ * If you are trying to set an image as the cursor, it is recommended to make the size
+ * 16x16 or 32x32 pixels. It is not possible to load an image as the cursor if you are
+ * exporting your program for the Web. The values for parameters x and y must be less
+ * than the dimensions of the image.
+ *
+ * @param {MODE} MODE either ARROW, CROSS, HAND, MOVE, TEXT, WAIT
+ * @param {PImage} image any variable of type PImage
+ * @param {int} x the horizonal active spot of the cursor
+ * @param {int} y the vertical active spot of the cursor
+ *
+ * @returns none
+ *
+ * @see noCursor
+ */
+ p.cursor = function() {
+ if (arguments.length > 1 || (arguments.length === 1 && arguments[0] instanceof p.PImage)) {
+ var image = arguments[0],
+ x, y;
+ if (arguments.length >= 3) {
+ x = arguments[1];
+ y = arguments[2];
+ if (x < 0 || y < 0 || y >= image.height || x >= image.width) {
+ throw "x and y must be non-negative and less than the dimensions of the image";
+ }
+ } else {
+ x = image.width >>> 1;
+ y = image.height >>> 1;
+ }
+
+ // see https://developer.mozilla.org/en/Using_URL_values_for_the_cursor_property
+ var imageDataURL = image.toDataURL();
+ var style = "url(\"" + imageDataURL + "\") " + x + " " + y + ", default";
+ curCursor = curElement.style.cursor = style;
+ } else if (arguments.length === 1) {
+ var mode = arguments[0];
+ curCursor = curElement.style.cursor = mode;
+ } else {
+ curCursor = curElement.style.cursor = oldCursor;
+ }
+ };
+
+ /**
+ * Hides the cursor from view.
+ *
+ * @returns none
+ *
+ * @see cursor
+ */
+ p.noCursor = function() {
+ curCursor = curElement.style.cursor = PConstants.NOCURSOR;
+ };
+
+ /**
+ * Links to a webpage either in the same window or in a new window. The complete URL
+ * must be specified.
+ *
+ * @param {String} href complete url as a String in quotes
+ * @param {String} target name of the window to load the URL as a string in quotes
+ *
+ * @returns none
+ */
+ p.link = function(href, target) {
+ if (target !== undef) {
+ window.open(href, target);
+ } else {
+ window.location = href;
+ }
+ };
+
+ // PGraphics methods
+ // These functions exist only for compatibility with P5
+ p.beginDraw = noop;
+ p.endDraw = noop;
+
+ /**
+ * This function takes content from a canvas and turns it into an ImageData object to be used with a PImage
+ *
+ * @returns {ImageData} ImageData object to attach to a PImage (1D array of pixel data)
+ *
+ * @see PImage
+ */
+ Drawing2D.prototype.toImageData = function(x, y, w, h) {
+ x = x !== undef ? x : 0;
+ y = y !== undef ? y : 0;
+ w = w !== undef ? w : p.width;
+ h = h !== undef ? h : p.height;
+ return curContext.getImageData(x, y, w, h);
+ };
+
+ Drawing3D.prototype.toImageData = function(x, y, w, h) {
+ x = x !== undef ? x : 0;
+ y = y !== undef ? y : 0;
+ w = w !== undef ? w : p.width;
+ h = h !== undef ? h : p.height;
+ var c = document.createElement("canvas"),
+ ctx = c.getContext("2d"),
+ obj = ctx.createImageData(w, h),
+ uBuff = new Uint8Array(w * h * 4);
+ curContext.readPixels(x, y, w, h, curContext.RGBA, curContext.UNSIGNED_BYTE, uBuff);
+ for (var i=0, ul=uBuff.length, obj_data=obj.data; i < ul; i++) {
+ obj_data[i] = uBuff[(h - 1 - Math.floor(i / 4 / w)) * w * 4 + (i % (w * 4))];
+ }
+ return obj;
+ };
+
+ /**
+ * Displays message in the browser's status area. This is the text area in the lower
+ * left corner of the browser. The status() function will only work when the
+ * Processing program is running in a web browser.
+ *
+ * @param {String} text any valid String
+ *
+ * @returns none
+ */
+ p.status = function(text) {
+ window.status = text;
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Binary Functions
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Converts a byte, char, int, or color to a String containing the equivalent binary
+ * notation. For example color(0, 102, 153, 255) will convert to the String
+ * "11111111000000000110011010011001". This function can help make your geeky debugging
+ * sessions much happier.
+ *
+ * @param {byte|char|int|color} num byte, char, int, color: value to convert
+ * @param {int} numBits number of digits to return
+ *
+ * @returns {String}
+ *
+ * @see unhex
+ * @see hex
+ * @see unbinary
+ */
+ p.binary = function(num, numBits) {
+ var bit;
+ if (numBits > 0) {
+ bit = numBits;
+ } else if(num instanceof Char) {
+ bit = 16;
+ num |= 0; // making it int
+ } else {
+ // autodetect, skipping zeros
+ bit = 32;
+ while (bit > 1 && !((num >>> (bit - 1)) & 1)) {
+ bit--;
+ }
+ }
+ var result = "";
+ while (bit > 0) {
+ result += ((num >>> (--bit)) & 1) ? "1" : "0";
+ }
+ return result;
+ };
+
+ /**
+ * Converts a String representation of a binary number to its equivalent integer value.
+ * For example, unbinary("00001000") will return 8.
+ *
+ * @param {String} binaryString String
+ *
+ * @returns {Int}
+ *
+ * @see hex
+ * @see binary
+ * @see unbinary
+ */
+ p.unbinary = function(binaryString) {
+ var i = binaryString.length - 1, mask = 1, result = 0;
+ while (i >= 0) {
+ var ch = binaryString[i--];
+ if (ch !== '0' && ch !== '1') {
+ throw "the value passed into unbinary was not an 8 bit binary number";
+ }
+ if (ch === '1') {
+ result += mask;
+ }
+ mask <<= 1;
+ }
+ return result;
+ };
+
+ var decimalToHex = function(d, padding) {
+ //if there is no padding value added, default padding to 8 else go into while statement.
+ padding = (padding === undef || padding === null) ? padding = 8 : padding;
+ if (d < 0) {
+ d = 0xFFFFFFFF + d + 1;
+ }
+ var hex = Number(d).toString(16).toUpperCase();
+ while (hex.length < padding) {
+ hex = "0" + hex;
+ }
+ if (hex.length >= padding) {
+ hex = hex.substring(hex.length - padding, hex.length);
+ }
+ return hex;
+ };
+
+ // note: since we cannot keep track of byte, int types by default the returned string is 8 chars long
+ // if no 2nd argument is passed. closest compromise we can use to match java implementation Feb 5 2010
+ // also the char parser has issues with chars that are not digits or letters IE: !@#$%^&*
+ /**
+ * Converts a byte, char, int, or color to a String containing the equivalent hexadecimal notation.
+ * For example color(0, 102, 153, 255) will convert to the String "FF006699". This function can help
+ * make your geeky debugging sessions much happier.
+ *
+ * @param {byte|char|int|Color} value the value to turn into a hex string
+ * @param {int} digits the number of digits to return
+ *
+ * @returns {String}
+ *
+ * @see unhex
+ * @see binary
+ * @see unbinary
+ */
+ p.hex = function(value, len) {
+ if (arguments.length === 1) {
+ if (value instanceof Char) {
+ len = 4;
+ } else { // int or byte, indistinguishable at the moment, default to 8
+ len = 8;
+ }
+ }
+ return decimalToHex(value, len);
+ };
+
+ function unhexScalar(hex) {
+ var value = parseInt("0x" + hex, 16);
+
+ // correct for int overflow java expectation
+ if (value > 2147483647) {
+ value -= 4294967296;
+ }
+ return value;
+ }
+
+ /**
+ * Converts a String representation of a hexadecimal number to its equivalent integer value.
+ *
+ * @param {String} hex the hex string to convert to an int
+ *
+ * @returns {int}
+ *
+ * @see hex
+ * @see binary
+ * @see unbinary
+ */
+ p.unhex = function(hex) {
+ if (hex instanceof Array) {
+ var arr = [];
+ for (var i = 0; i < hex.length; i++) {
+ arr.push(unhexScalar(hex[i]));
+ }
+ return arr;
+ }
+ return unhexScalar(hex);
+ };
+
+ // Load a file or URL into strings
+ /**
+ * Reads the contents of a file or url and creates a String array of its individual lines.
+ * The filename parameter can also be a URL to a file found online. If the file is not available or an error occurs,
+ * null will be returned and an error message will be printed to the console. The error message does not halt
+ * the program.
+ *
+ * @param {String} filename name of the file or url to load
+ *
+ * @returns {String[]}
+ *
+ * @see loadBytes
+ * @see saveStrings
+ * @see saveBytes
+ */
+ p.loadStrings = function(filename) {
+ if (localStorage[filename]) {
+ return localStorage[filename].split("\n");
+ }
+
+ var filecontent = ajax(filename);
+ if(typeof filecontent !== "string" || filecontent === "") {
+ return [];
+ }
+
+ // deal with the fact that Windows uses \r\n, Unix uses \n,
+ // Mac uses \r, and we actually expect \n
+ filecontent = filecontent.replace(/(\r\n?)/g,"\n").replace(/\n$/,"");
+
+ return filecontent.split("\n");
+ };
+
+ // Writes an array of strings to a file, one line per string
+ /**
+ * Writes an array of strings to a file, one line per string. This file is saved to the localStorage.
+ *
+ * @param {String} filename name of the file to save to localStorage
+ * @param {String[]} strings string array to be written
+ *
+ * @see loadBytes
+ * @see loadStrings
+ * @see saveBytes
+ */
+ p.saveStrings = function(filename, strings) {
+ localStorage[filename] = strings.join('\n');
+ };
+
+ /**
+ * Reads the contents of a file or url and places it in a byte array. If a file is specified, it must be located in the localStorage.
+ * The filename parameter can also be a URL to a file found online.
+ *
+ * @param {String} filename name of a file in the localStorage or a URL.
+ *
+ * @returns {byte[]}
+ *
+ * @see loadStrings
+ * @see saveStrings
+ * @see saveBytes
+ */
+ p.loadBytes = function(url) {
+ var string = ajax(url);
+ var ret = [];
+
+ for (var i = 0; i < string.length; i++) {
+ ret.push(string.charCodeAt(i));
+ }
+
+ return ret;
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // String Functions
+ ////////////////////////////////////////////////////////////////////////////
+ /**
+ * The matchAll() function is identical to match(), except that it returns an array of all matches in
+ * the specified String, rather than just the first.
+ *
+ * @param {String} aString the String to search inside
+ * @param {String} aRegExp the regexp to be used for matching
+ *
+ * @return {String[]} returns an array of matches
+ *
+ * @see #match
+ */
+ p.matchAll = function(aString, aRegExp) {
+ var results = [],
+ latest;
+ var regexp = new RegExp(aRegExp, "g");
+ while ((latest = regexp.exec(aString)) !== null) {
+ results.push(latest);
+ if (latest[0].length === 0) {
+ ++regexp.lastIndex;
+ }
+ }
+ return results.length > 0 ? results : null;
+ };
+ /**
+ * The match() function matches a string with a regular expression, and returns the match as an
+ * array. The first index is the matching expression, and array elements
+ * [1] and higher represent each of the groups (sequences found in parens).
+ *
+ * @param {String} str the String to be searched
+ * @param {String} regexp the regexp to be used for matching
+ *
+ * @return {String[]} an array of matching strings
+ */
+ p.match = function(str, regexp) {
+ return str.match(regexp);
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Other java specific functions
+ ////////////////////////////////////////////////////////////////////////////
+
+
+ var logBuffer = [];
+
+ /**
+ * The println() function writes to the console area of the Processing environment.
+ * Each call to this function creates a new line of output. Individual elements can be separated with quotes ("") and joined with the string concatenation operator (+).
+ *
+ * @param {String} message the string to write to the console
+ *
+ * @see #join
+ * @see #print
+ */
+ p.println = function() {
+ Processing.logger.println.apply(Processing.logger, arguments);
+ };
+ /**
+ * The print() function writes to the console area of the Processing environment.
+ *
+ * @param {String} message the string to write to the console
+ *
+ * @see #join
+ */
+ p.print = function() {
+ Processing.logger.print.apply(Processing.logger, arguments);
+ };
+
+ // Alphanumeric chars arguments automatically converted to numbers when
+ // passed in, and will come out as numbers.
+ p.str = function(val) {
+ if (val instanceof Array) {
+ var arr = [];
+ for (var i = 0; i < val.length; i++) {
+ arr.push(val[i].toString() + "");
+ }
+ return arr;
+ }
+ return (val.toString() + "");
+ };
+
+
+ // Conversion
+ function booleanScalar(val) {
+ if (typeof val === 'number') {
+ return val !== 0;
+ }
+ if (typeof val === 'boolean') {
+ return val;
+ }
+ if (typeof val === 'string') {
+ return val.toLowerCase() === 'true';
+ }
+ if (val instanceof Char) {
+ // 1, T or t
+ return val.code === 49 || val.code === 84 || val.code === 116;
+ }
+ }
+
+ /**
+ * Converts the passed parameter to the function to its boolean value.
+ * It will return an array of booleans if an array is passed in.
+ *
+ * @param {int, byte, string} val the parameter to be converted to boolean
+ * @param {int[], byte[], string[]} val the array to be converted to boolean[]
+ *
+ * @return {boolean|boolean[]} returns a boolean or an array of booleans
+ */
+ p.parseBoolean = function (val) {
+ if (val instanceof Array) {
+ var ret = [];
+ for (var i = 0; i < val.length; i++) {
+ ret.push(booleanScalar(val[i]));
+ }
+ return ret;
+ }
+ return booleanScalar(val);
+ };
+
+ /**
+ * Converts the passed parameter to the function to its byte value.
+ * A byte is a number between -128 and 127.
+ * It will return an array of bytes if an array is passed in.
+ *
+ * @param {int, char} what the parameter to be conveted to byte
+ * @param {int[], char[]} what the array to be converted to byte[]
+ *
+ * @return {byte|byte[]} returns a byte or an array of bytes
+ */
+ p.parseByte = function(what) {
+ if (what instanceof Array) {
+ var bytes = [];
+ for (var i = 0; i < what.length; i++) {
+ bytes.push((0 - (what[i] & 0x80)) | (what[i] & 0x7F));
+ }
+ return bytes;
+ }
+ return (0 - (what & 0x80)) | (what & 0x7F);
+ };
+
+ /**
+ * Converts the passed parameter to the function to its char value.
+ * It will return an array of chars if an array is passed in.
+ *
+ * @param {int, byte} key the parameter to be conveted to char
+ * @param {int[], byte[]} key the array to be converted to char[]
+ *
+ * @return {char|char[]} returns a char or an array of chars
+ */
+ p.parseChar = function(key) {
+ if (typeof key === "number") {
+ return new Char(String.fromCharCode(key & 0xFFFF));
+ }
+ if (key instanceof Array) {
+ var ret = [];
+ for (var i = 0; i < key.length; i++) {
+ ret.push(new Char(String.fromCharCode(key[i] & 0xFFFF)));
+ }
+ return ret;
+ }
+ throw "char() may receive only one argument of type int, byte, int[], or byte[].";
+ };
+
+ // Processing doc claims good argument types are: int, char, byte, boolean,
+ // String, int[], char[], byte[], boolean[], String[].
+ // floats should not work. However, floats with only zeroes right of the
+ // decimal will work because JS converts those to int.
+ function floatScalar(val) {
+ if (typeof val === 'number') {
+ return val;
+ }
+ if (typeof val === 'boolean') {
+ return val ? 1 : 0;
+ }
+ if (typeof val === 'string') {
+ return parseFloat(val);
+ }
+ if (val instanceof Char) {
+ return val.code;
+ }
+ }
+
+ /**
+ * Converts the passed parameter to the function to its float value.
+ * It will return an array of floats if an array is passed in.
+ *
+ * @param {int, char, boolean, string} val the parameter to be conveted to float
+ * @param {int[], char[], boolean[], string[]} val the array to be converted to float[]
+ *
+ * @return {float|float[]} returns a float or an array of floats
+ */
+ p.parseFloat = function(val) {
+ if (val instanceof Array) {
+ var ret = [];
+ for (var i = 0; i < val.length; i++) {
+ ret.push(floatScalar(val[i]));
+ }
+ return ret;
+ }
+ return floatScalar(val);
+ };
+
+ function intScalar(val, radix) {
+ if (typeof val === 'number') {
+ return val & 0xFFFFFFFF;
+ }
+ if (typeof val === 'boolean') {
+ return val ? 1 : 0;
+ }
+ if (typeof val === 'string') {
+ var number = parseInt(val, radix || 10); // Default to decimal radix.
+ return number & 0xFFFFFFFF;
+ }
+ if (val instanceof Char) {
+ return val.code;
+ }
+ }
+
+ /**
+ * Converts the passed parameter to the function to its int value.
+ * It will return an array of ints if an array is passed in.
+ *
+ * @param {string, char, boolean, float} val the parameter to be conveted to int
+ * @param {string[], char[], boolean[], float[]} val the array to be converted to int[]
+ * @param {int} radix optional the radix of the number (for js compatibility)
+ *
+ * @return {int|int[]} returns a int or an array of ints
+ */
+ p.parseInt = function(val, radix) {
+ if (val instanceof Array) {
+ var ret = [];
+ for (var i = 0; i < val.length; i++) {
+ if (typeof val[i] === 'string' && !/^\s*[+\-]?\d+\s*$/.test(val[i])) {
+ ret.push(0);
+ } else {
+ ret.push(intScalar(val[i], radix));
+ }
+ }
+ return ret;
+ }
+ return intScalar(val, radix);
+ };
+
+ p.__int_cast = function(val) {
+ return 0|val;
+ };
+
+ p.__instanceof = function(obj, type) {
+ if (typeof type !== "function") {
+ throw "Function is expected as type argument for instanceof operator";
+ }
+
+ if (typeof obj === "string") {
+ // special case for strings
+ return type === Object || type === String;
+ }
+
+ if (obj instanceof type) {
+ // fast check if obj is already of type instance
+ return true;
+ }
+
+ if (typeof obj !== "object" || obj === null) {
+ return false; // not an object or null
+ }
+
+ var objType = obj.constructor;
+ if (type.$isInterface) {
+ // expecting the interface
+ // queueing interfaces from type and its base classes
+ var interfaces = [];
+ while (objType) {
+ if (objType.$interfaces) {
+ interfaces = interfaces.concat(objType.$interfaces);
+ }
+ objType = objType.$base;
+ }
+ while (interfaces.length > 0) {
+ var i = interfaces.shift();
+ if (i === type) {
+ return true;
+ }
+ // wide search in base interfaces
+ if (i.$interfaces) {
+ interfaces = interfaces.concat(i.$interfaces);
+ }
+ }
+ return false;
+ }
+
+ while (objType.hasOwnProperty("$base")) {
+ objType = objType.$base;
+ if (objType === type) {
+ return true; // object was found
+ }
+ }
+
+ return false;
+ };
+
+ /**
+ * Defines the dimension of the display window in units of pixels. The size() function must
+ * be the first line in setup(). If size() is not called, the default size of the window is
+ * 100x100 pixels. The system variables width and height are set by the parameters passed to
+ * the size() function.
+ *
+ * @param {int} aWidth width of the display window in units of pixels
+ * @param {int} aHeight height of the display window in units of pixels
+ * @param {MODE} aMode Either P2D, P3D, JAVA2D, or OPENGL
+ *
+ * @see createGraphics
+ * @see screen
+ */
+ DrawingShared.prototype.size = function(aWidth, aHeight, aMode) {
+ if (doStroke) {
+ p.stroke(0);
+ }
+
+ if (doFill) {
+ p.fill(255);
+ }
+
+ // The default 2d context has already been created in the p.init() stage if
+ // a 3d context was not specified. This is so that a 2d context will be
+ // available if size() was not called.
+ var savedProperties = {
+ fillStyle: curContext.fillStyle,
+ strokeStyle: curContext.strokeStyle,
+ lineCap: curContext.lineCap,
+ lineJoin: curContext.lineJoin
+ };
+ // remove the style width and height properties to ensure that the canvas gets set to
+ // aWidth and aHeight coming in
+ if (curElement.style.length > 0 ) {
+ curElement.style.removeProperty("width");
+ curElement.style.removeProperty("height");
+ }
+
+ curElement.width = p.width = aWidth || 100;
+ curElement.height = p.height = aHeight || 100;
+
+ for (var prop in savedProperties) {
+ if (savedProperties.hasOwnProperty(prop)) {
+ curContext[prop] = savedProperties[prop];
+ }
+ }
+
+ // make sure to set the default font the first time round.
+ p.textFont(curTextFont);
+
+ // Set the background to whatever it was called last as if background() was called before size()
+ // If background() hasn't been called before, set background() to a light gray
+ p.background();
+
+ // set 5% for pixels to cache (or 1000)
+ maxPixelsCached = Math.max(1000, aWidth * aHeight * 0.05);
+
+ // Externalize the context
+ p.externals.context = curContext;
+
+ for (var i = 0; i < PConstants.SINCOS_LENGTH; i++) {
+ sinLUT[i] = p.sin(i * (PConstants.PI / 180) * 0.5);
+ cosLUT[i] = p.cos(i * (PConstants.PI / 180) * 0.5);
+ }
+ };
+
+ Drawing2D.prototype.size = function(aWidth, aHeight, aMode) {
+ if (curContext === undef) {
+ // size() was called without p.init() default context, i.e. p.createGraphics()
+ curContext = curElement.getContext("2d");
+ userMatrixStack = new PMatrixStack();
+ userReverseMatrixStack = new PMatrixStack();
+ modelView = new PMatrix2D();
+ modelViewInv = new PMatrix2D();
+ }
+
+ DrawingShared.prototype.size.apply(this, arguments);
+ };
+
+ Drawing3D.prototype.size = (function() {
+ var size3DCalled = false;
+
+ return function size(aWidth, aHeight, aMode) {
+ if (size3DCalled) {
+ throw "Multiple calls to size() for 3D renders are not allowed.";
+ }
+ size3DCalled = true;
+
+ function getGLContext(canvas) {
+ var ctxNames = ['experimental-webgl', 'webgl', 'webkit-3d'],
+ gl;
+
+ for (var i=0, l=ctxNames.length; i<l; i++) {
+ gl = canvas.getContext(ctxNames[i], {antialias: false, preserveDrawingBuffer: true});
+ if (gl) {
+ break;
+ }
+ }
+
+ return gl;
+ }
+
+ // Get the 3D rendering context.
+ try {
+ // If the HTML <canvas> dimensions differ from the
+ // dimensions specified in the size() call in the sketch, for
+ // 3D sketches, browsers will either not render or render the
+ // scene incorrectly. To fix this, we need to adjust the
+ // width and height attributes of the canvas.
+ curElement.width = p.width = aWidth || 100;
+ curElement.height = p.height = aHeight || 100;
+ curContext = getGLContext(curElement);
+ canTex = curContext.createTexture();
+ textTex = curContext.createTexture();
+ } catch(e_size) {
+ Processing.debug(e_size);
+ }
+
+ if (!curContext) {
+ throw "WebGL context is not supported on this browser.";
+ }
+
+ // Set defaults
+ curContext.viewport(0, 0, curElement.width, curElement.height);
+ curContext.enable(curContext.DEPTH_TEST);
+ curContext.enable(curContext.BLEND);
+ curContext.blendFunc(curContext.SRC_ALPHA, curContext.ONE_MINUS_SRC_ALPHA);
+
+ // Create the program objects to render 2D (points, lines) and
+ // 3D (spheres, boxes) shapes. Because 2D shapes are not lit,
+ // lighting calculations are ommitted from this program object.
+ programObject2D = createProgramObject(curContext, vertexShaderSrc2D, fragmentShaderSrc2D);
+
+ programObjectUnlitShape = createProgramObject(curContext, vertexShaderSrcUnlitShape, fragmentShaderSrcUnlitShape);
+
+ // Set the default point and line width for the 2D and unlit shapes.
+ p.strokeWeight(1);
+
+ // Now that the programs have been compiled, we can set the default
+ // states for the lights.
+ programObject3D = createProgramObject(curContext, vertexShaderSrc3D, fragmentShaderSrc3D);
+ curContext.useProgram(programObject3D);
+
+ // Assume we aren't using textures by default.
+ uniformi("usingTexture3d", programObject3D, "usingTexture", usingTexture);
+
+ // Set some defaults.
+ p.lightFalloff(1, 0, 0);
+ p.shininess(1);
+ p.ambient(255, 255, 255);
+ p.specular(0, 0, 0);
+ p.emissive(0, 0, 0);
+
+ // Create buffers for 3D primitives
+ boxBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, boxBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, boxVerts, curContext.STATIC_DRAW);
+
+ boxNormBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, boxNormBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, boxNorms, curContext.STATIC_DRAW);
+
+ boxOutlineBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, boxOutlineBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, boxOutlineVerts, curContext.STATIC_DRAW);
+
+ // used to draw the rectangle and the outline
+ rectBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, rectBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, rectVerts, curContext.STATIC_DRAW);
+
+ rectNormBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, rectNormBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, rectNorms, curContext.STATIC_DRAW);
+
+ // The sphere vertices are specified dynamically since the user
+ // can change the level of detail. Everytime the user does that
+ // using sphereDetail(), the new vertices are calculated.
+ sphereBuffer = curContext.createBuffer();
+
+ lineBuffer = curContext.createBuffer();
+
+ // Shape buffers
+ fillBuffer = curContext.createBuffer();
+ fillColorBuffer = curContext.createBuffer();
+ strokeColorBuffer = curContext.createBuffer();
+ shapeTexVBO = curContext.createBuffer();
+
+ pointBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, pointBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array([0, 0, 0]), curContext.STATIC_DRAW);
+
+ textBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, textBuffer );
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array([1,1,0,-1,1,0,-1,-1,0,1,-1,0]), curContext.STATIC_DRAW);
+
+ textureBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, textureBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array([0,0,1,0,1,1,0,1]), curContext.STATIC_DRAW);
+
+ indexBuffer = curContext.createBuffer();
+ curContext.bindBuffer(curContext.ELEMENT_ARRAY_BUFFER, indexBuffer);
+ curContext.bufferData(curContext.ELEMENT_ARRAY_BUFFER, new Uint16Array([0,1,2,2,3,0]), curContext.STATIC_DRAW);
+
+ cam = new PMatrix3D();
+ cameraInv = new PMatrix3D();
+ modelView = new PMatrix3D();
+ modelViewInv = new PMatrix3D();
+ projection = new PMatrix3D();
+ p.camera();
+ p.perspective();
+
+ userMatrixStack = new PMatrixStack();
+ userReverseMatrixStack = new PMatrixStack();
+ // used by both curve and bezier, so just init here
+ curveBasisMatrix = new PMatrix3D();
+ curveToBezierMatrix = new PMatrix3D();
+ curveDrawMatrix = new PMatrix3D();
+ bezierDrawMatrix = new PMatrix3D();
+ bezierBasisInverse = new PMatrix3D();
+ bezierBasisMatrix = new PMatrix3D();
+ bezierBasisMatrix.set(-1, 3, -3, 1, 3, -6, 3, 0, -3, 3, 0, 0, 1, 0, 0, 0);
+
+ DrawingShared.prototype.size.apply(this, arguments);
+ };
+ }());
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Lights
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Adds an ambient light. Ambient light doesn't come from a specific direction,
+ * the rays have light have bounced around so much that objects are evenly lit
+ * from all sides. Ambient lights are almost always used in combination with
+ * other types of lights. Lights need to be included in the <b>draw()</b> to
+ * remain persistent in a looping program. Placing them in the <b>setup()</b>
+ * of a looping program will cause them to only have an effect the first time
+ * through the loop. The effect of the parameters is determined by the current
+ * color mode.
+ *
+ * @param {int | float} r red or hue value
+ * @param {int | float} g green or hue value
+ * @param {int | float} b blue or hue value
+ *
+ * @param {int | float} x x position of light (used for falloff)
+ * @param {int | float} y y position of light (used for falloff)
+ * @param {int | float} z z position of light (used for falloff)
+ *
+ * @returns none
+ *
+ * @see lights
+ * @see directionalLight
+ * @see pointLight
+ * @see spotLight
+ */
+ Drawing2D.prototype.ambientLight = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.ambientLight = function(r, g, b, x, y, z) {
+ if (lightCount === PConstants.MAX_LIGHTS) {
+ throw "can only create " + PConstants.MAX_LIGHTS + " lights";
+ }
+
+ var pos = new PVector(x, y, z);
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.mult(pos, pos);
+
+ // Instead of calling p.color, we do the calculations ourselves to
+ // reduce property lookups.
+ var col = color$4(r, g, b, 0);
+ var normalizedCol = [ ((col & PConstants.RED_MASK) >>> 16) / 255,
+ ((col & PConstants.GREEN_MASK) >>> 8) / 255,
+ (col & PConstants.BLUE_MASK) / 255 ];
+
+ curContext.useProgram(programObject3D);
+ uniformf("uLights.color.3d." + lightCount, programObject3D, "uLights" + lightCount + ".color", normalizedCol);
+ uniformf("uLights.position.3d." + lightCount, programObject3D, "uLights" + lightCount + ".position", pos.array());
+ uniformi("uLights.type.3d." + lightCount, programObject3D, "uLights" + lightCount + ".type", 0);
+ uniformi("uLightCount3d", programObject3D, "uLightCount", ++lightCount);
+ };
+
+ /**
+ * Adds a directional light. Directional light comes from one direction and
+ * is stronger when hitting a surface squarely and weaker if it hits at a
+ * gentle angle. After hitting a surface, a directional lights scatters in
+ * all directions. Lights need to be included in the <b>draw()</b> to remain
+ * persistent in a looping program. Placing them in the <b>setup()</b> of a
+ * looping program will cause them to only have an effect the first time
+ * through the loop. The affect of the <br>r</b>, <br>g</b>, and <br>b</b>
+ * parameters is determined by the current color mode. The <b>nx</b>,
+ * <b>ny</b>, and <b>nz</b> parameters specify the direction the light is
+ * facing. For example, setting <b>ny</b> to -1 will cause the geometry to be
+ * lit from below (the light is facing directly upward).
+ *
+ * @param {int | float} r red or hue value
+ * @param {int | float} g green or hue value
+ * @param {int | float} b blue or hue value
+ *
+ * @param {int | float} nx direction along the x axis
+ * @param {int | float} ny direction along the y axis
+ * @param {int | float} nz direction along the z axis
+ *
+ * @returns none
+ *
+ * @see lights
+ * @see ambientLight
+ * @see pointLight
+ * @see spotLight
+ */
+ Drawing2D.prototype.directionalLight = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.directionalLight = function(r, g, b, nx, ny, nz) {
+ if (lightCount === PConstants.MAX_LIGHTS) {
+ throw "can only create " + PConstants.MAX_LIGHTS + " lights";
+ }
+
+ curContext.useProgram(programObject3D);
+
+ var mvm = new PMatrix3D();
+ mvm.scale(1, -1, 1);
+ mvm.apply(modelView.array());
+ mvm = mvm.array();
+
+ // We need to multiply the direction by the model view matrix, but
+ // the mult function checks the w component of the vector, if it isn't
+ // present, it uses 1, so we manually multiply.
+ var dir = [
+ mvm[0] * nx + mvm[4] * ny + mvm[8] * nz,
+ mvm[1] * nx + mvm[5] * ny + mvm[9] * nz,
+ mvm[2] * nx + mvm[6] * ny + mvm[10] * nz
+ ];
+
+ // Instead of calling p.color, we do the calculations ourselves to
+ // reduce property lookups.
+ var col = color$4(r, g, b, 0);
+ var normalizedCol = [ ((col & PConstants.RED_MASK) >>> 16) / 255,
+ ((col & PConstants.GREEN_MASK) >>> 8) / 255,
+ (col & PConstants.BLUE_MASK) / 255 ];
+
+ uniformf("uLights.color.3d." + lightCount, programObject3D, "uLights" + lightCount + ".color", normalizedCol);
+ uniformf("uLights.position.3d." + lightCount, programObject3D, "uLights" + lightCount + ".position", dir);
+ uniformi("uLights.type.3d." + lightCount, programObject3D, "uLights" + lightCount + ".type", 1);
+ uniformi("uLightCount3d", programObject3D, "uLightCount", ++lightCount);
+ };
+
+ /**
+ * Sets the falloff rates for point lights, spot lights, and ambient lights.
+ * The parameters are used to determine the falloff with the following equation:
+ *
+ * d = distance from light position to vertex position
+ * falloff = 1 / (CONSTANT + d * LINEAR + (d*d) * QUADRATIC)
+ *
+ * Like <b>fill()</b>, it affects only the elements which are created after it in the
+ * code. The default value if <b>LightFalloff(1.0, 0.0, 0.0)</b>. Thinking about an
+ * ambient light with a falloff can be tricky. It is used, for example, if you
+ * wanted a region of your scene to be lit ambiently one color and another region
+ * to be lit ambiently by another color, you would use an ambient light with location
+ * and falloff. You can think of it as a point light that doesn't care which direction
+ * a surface is facing.
+ *
+ * @param {int | float} constant constant value for determining falloff
+ * @param {int | float} linear linear value for determining falloff
+ * @param {int | float} quadratic quadratic value for determining falloff
+ *
+ * @returns none
+ *
+ * @see lights
+ * @see ambientLight
+ * @see pointLight
+ * @see spotLight
+ * @see lightSpecular
+ */
+ Drawing2D.prototype.lightFalloff = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.lightFalloff = function(constant, linear, quadratic) {
+ curContext.useProgram(programObject3D);
+ uniformf("uFalloff3d", programObject3D, "uFalloff", [constant, linear, quadratic]);
+ };
+
+ /**
+ * Sets the specular color for lights. Like <b>fill()</b>, it affects only the
+ * elements which are created after it in the code. Specular refers to light
+ * which bounces off a surface in a perferred direction (rather than bouncing
+ * in all directions like a diffuse light) and is used for creating highlights.
+ * The specular quality of a light interacts with the specular material qualities
+ * set through the <b>specular()</b> and <b>shininess()</b> functions.
+ *
+ * @param {int | float} r red or hue value
+ * @param {int | float} g green or hue value
+ * @param {int | float} b blue or hue value
+ *
+ * @returns none
+ *
+ * @see lights
+ * @see ambientLight
+ * @see pointLight
+ * @see spotLight
+ */
+ Drawing2D.prototype.lightSpecular = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.lightSpecular = function(r, g, b) {
+
+ // Instead of calling p.color, we do the calculations ourselves to
+ // reduce property lookups.
+ var col = color$4(r, g, b, 0);
+ var normalizedCol = [ ((col & PConstants.RED_MASK) >>> 16) / 255,
+ ((col & PConstants.GREEN_MASK) >>> 8) / 255,
+ (col & PConstants.BLUE_MASK) / 255 ];
+
+ curContext.useProgram(programObject3D);
+ uniformf("uSpecular3d", programObject3D, "uSpecular", normalizedCol);
+ };
+
+ /**
+ * Sets the default ambient light, directional light, falloff, and specular
+ * values. The defaults are ambientLight(128, 128, 128) and
+ * directionalLight(128, 128, 128, 0, 0, -1), lightFalloff(1, 0, 0), and
+ * lightSpecular(0, 0, 0). Lights need to be included in the draw() to remain
+ * persistent in a looping program. Placing them in the setup() of a looping
+ * program will cause them to only have an effect the first time through the
+ * loop.
+ *
+ * @returns none
+ *
+ * @see ambientLight
+ * @see directionalLight
+ * @see pointLight
+ * @see spotLight
+ * @see noLights
+ *
+ */
+ p.lights = function() {
+ p.ambientLight(128, 128, 128);
+ p.directionalLight(128, 128, 128, 0, 0, -1);
+ p.lightFalloff(1, 0, 0);
+ p.lightSpecular(0, 0, 0);
+ };
+
+ /**
+ * Adds a point light. Lights need to be included in the <b>draw()</b> to remain
+ * persistent in a looping program. Placing them in the <b>setup()</b> of a
+ * looping program will cause them to only have an effect the first time through
+ * the loop. The affect of the <b>r</b>, <b>g</b>, and <b>b</b> parameters
+ * is determined by the current color mode. The <b>x</b>, <b>y</b>, and <b>z</b>
+ * parameters set the position of the light.
+ *
+ * @param {int | float} r red or hue value
+ * @param {int | float} g green or hue value
+ * @param {int | float} b blue or hue value
+ * @param {int | float} x x coordinate of the light
+ * @param {int | float} y y coordinate of the light
+ * @param {int | float} z z coordinate of the light
+ *
+ * @returns none
+ *
+ * @see lights
+ * @see directionalLight
+ * @see ambientLight
+ * @see spotLight
+ */
+ Drawing2D.prototype.pointLight = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.pointLight = function(r, g, b, x, y, z) {
+ if (lightCount === PConstants.MAX_LIGHTS) {
+ throw "can only create " + PConstants.MAX_LIGHTS + " lights";
+ }
+
+ // Place the point in view space once instead of once per vertex
+ // in the shader.
+ var pos = new PVector(x, y, z);
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.mult(pos, pos);
+
+ // Instead of calling p.color, we do the calculations ourselves to
+ // reduce property lookups.
+ var col = color$4(r, g, b, 0);
+ var normalizedCol = [ ((col & PConstants.RED_MASK) >>> 16) / 255,
+ ((col & PConstants.GREEN_MASK) >>> 8) / 255,
+ (col & PConstants.BLUE_MASK) / 255 ];
+
+ curContext.useProgram(programObject3D);
+ uniformf("uLights.color.3d." + lightCount, programObject3D, "uLights" + lightCount + ".color", normalizedCol);
+ uniformf("uLights.position.3d." + lightCount, programObject3D, "uLights" + lightCount + ".position", pos.array());
+ uniformi("uLights.type.3d." + lightCount, programObject3D, "uLights" + lightCount + ".type", 2);
+ uniformi("uLightCount3d", programObject3D, "uLightCount", ++lightCount);
+ };
+
+ /**
+ * Disable all lighting. Lighting is turned off by default and enabled with
+ * the lights() method. This function can be used to disable lighting so
+ * that 2D geometry (which does not require lighting) can be drawn after a
+ * set of lighted 3D geometry.
+ *
+ * @returns none
+ *
+ * @see lights
+ */
+ Drawing2D.prototype.noLights = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.noLights = function() {
+ lightCount = 0;
+ curContext.useProgram(programObject3D);
+ uniformi("uLightCount3d", programObject3D, "uLightCount", lightCount);
+ };
+
+ /**
+ * Adds a spot light. Lights need to be included in the <b>draw()</b> to
+ * remain persistent in a looping program. Placing them in the <b>setup()</b>
+ * of a looping program will cause them to only have an effect the first time
+ * through the loop. The affect of the <b>r</b>, <b>g</b>, and <b>b</b> parameters
+ * is determined by the current color mode. The <b>x</b>, <b>y</b>, and <b>z</b>
+ * parameters specify the position of the light and <b>nx</b>, <b>ny</b>, <b>nz</b>
+ * specify the direction or light. The angle parameter affects <b>angle</b> of the
+ * spotlight cone.
+ *
+ * @param {int | float} r red or hue value
+ * @param {int | float} g green or hue value
+ * @param {int | float} b blue or hue value
+ * @param {int | float} x coordinate of the light
+ * @param {int | float} y coordinate of the light
+ * @param {int | float} z coordinate of the light
+ * @param {int | float} nx direction along the x axis
+ * @param {int | float} ny direction along the y axis
+ * @param {int | float} nz direction along the z axis
+ * @param {float} angle angle of the spotlight cone
+ * @param {float} concentration exponent determining the center bias of the cone
+ *
+ * @returns none
+ *
+ * @see lights
+ * @see directionalLight
+ * @see ambientLight
+ * @see pointLight
+ */
+ Drawing2D.prototype.spotLight = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.spotLight = function(r, g, b, x, y, z, nx, ny, nz, angle, concentration) {
+ if (lightCount === PConstants.MAX_LIGHTS) {
+ throw "can only create " + PConstants.MAX_LIGHTS + " lights";
+ }
+
+ curContext.useProgram(programObject3D);
+
+ // multiply the position and direction by the model view matrix
+ // once per object rather than once per vertex.
+ var pos = new PVector(x, y, z);
+ var mvm = new PMatrix3D();
+ mvm.scale(1, -1, 1);
+ mvm.apply(modelView.array());
+ mvm.mult(pos, pos);
+
+ // Convert to array since we need to directly access the elements.
+ mvm = mvm.array();
+
+ // We need to multiply the direction by the model view matrix, but
+ // the mult function checks the w component of the vector, if it isn't
+ // present, it uses 1, so we use a very small value as a work around.
+ var dir = [
+ mvm[0] * nx + mvm[4] * ny + mvm[8] * nz,
+ mvm[1] * nx + mvm[5] * ny + mvm[9] * nz,
+ mvm[2] * nx + mvm[6] * ny + mvm[10] * nz
+ ];
+
+ // Instead of calling p.color, we do the calculations ourselves to
+ // reduce property lookups.
+ var col = color$4(r, g, b, 0);
+ var normalizedCol = [ ((col & PConstants.RED_MASK) >>> 16) / 255,
+ ((col & PConstants.GREEN_MASK) >>> 8) / 255,
+ (col & PConstants.BLUE_MASK) / 255 ];
+
+ uniformf("uLights.color.3d." + lightCount, programObject3D, "uLights" + lightCount + ".color", normalizedCol);
+ uniformf("uLights.position.3d." + lightCount, programObject3D, "uLights" + lightCount + ".position", pos.array());
+ uniformf("uLights.direction.3d." + lightCount, programObject3D, "uLights" + lightCount + ".direction", dir);
+ uniformf("uLights.concentration.3d." + lightCount, programObject3D, "uLights" + lightCount + ".concentration", concentration);
+ uniformf("uLights.angle.3d." + lightCount, programObject3D, "uLights" + lightCount + ".angle", angle);
+ uniformi("uLights.type.3d." + lightCount, programObject3D, "uLights" + lightCount + ".type", 3);
+ uniformi("uLightCount3d", programObject3D, "uLightCount", ++lightCount);
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Camera functions
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * The <b>beginCamera()</b> and <b>endCamera()</b> functions enable advanced customization of the camera space.
+ * The functions are useful if you want to more control over camera movement, however for most users, the <b>camera()</b>
+ * function will be sufficient.<br /><br />The camera functions will replace any transformations (such as <b>rotate()</b>
+ * or <b>translate()</b>) that occur before them in <b>draw()</b>, but they will not automatically replace the camera
+ * transform itself. For this reason, camera functions should be placed at the beginning of <b>draw()</b> (so that
+ * transformations happen afterwards), and the <b>camera()</b> function can be used after <b>beginCamera()</b> if
+ * you want to reset the camera before applying transformations.<br /><br />This function sets the matrix mode to the
+ * camera matrix so calls such as <b>translate()</b>, <b>rotate()</b>, applyMatrix() and resetMatrix() affect the camera.
+ * <b>beginCamera()</b> should always be used with a following <b>endCamera()</b> and pairs of <b>beginCamera()</b> and
+ * <b>endCamera()</b> cannot be nested.
+ *
+ * @see camera
+ * @see endCamera
+ * @see applyMatrix
+ * @see resetMatrix
+ * @see translate
+ * @see rotate
+ * @see scale
+ */
+ Drawing2D.prototype.beginCamera = function() {
+ throw ("beginCamera() is not available in 2D mode");
+ };
+
+ Drawing3D.prototype.beginCamera = function() {
+ if (manipulatingCamera) {
+ throw ("You cannot call beginCamera() again before calling endCamera()");
+ }
+ manipulatingCamera = true;
+ modelView = cameraInv;
+ modelViewInv = cam;
+ };
+
+ /**
+ * The <b>beginCamera()</b> and <b>endCamera()</b> functions enable advanced customization of the camera space.
+ * Please see the reference for <b>beginCamera()</b> for a description of how the functions are used.
+ *
+ * @see beginCamera
+ */
+ Drawing2D.prototype.endCamera = function() {
+ throw ("endCamera() is not available in 2D mode");
+ };
+
+ Drawing3D.prototype.endCamera = function() {
+ if (!manipulatingCamera) {
+ throw ("You cannot call endCamera() before calling beginCamera()");
+ }
+ modelView.set(cam);
+ modelViewInv.set(cameraInv);
+ manipulatingCamera = false;
+ };
+
+ /**
+ * Sets the position of the camera through setting the eye position, the center of the scene, and which axis is facing
+ * upward. Moving the eye position and the direction it is pointing (the center of the scene) allows the images to be
+ * seen from different angles. The version without any parameters sets the camera to the default position, pointing to
+ * the center of the display window with the Y axis as up. The default values are camera(width/2.0, height/2.0,
+ * (height/2.0) / tan(PI*60.0 / 360.0), width/2.0, height/2.0, 0, 0, 1, 0). This function is similar to gluLookAt()
+ * in OpenGL, but it first clears the current camera settings.
+ *
+ * @param {float} eyeX x-coordinate for the eye
+ * @param {float} eyeY y-coordinate for the eye
+ * @param {float} eyeZ z-coordinate for the eye
+ * @param {float} centerX x-coordinate for the center of the scene
+ * @param {float} centerY y-coordinate for the center of the scene
+ * @param {float} centerZ z-coordinate for the center of the scene
+ * @param {float} upX usually 0.0, 1.0, -1.0
+ * @param {float} upY usually 0.0, 1.0, -1.0
+ * @param {float} upZ usually 0.0, 1.0, -1.0
+ *
+ * @see beginCamera
+ * @see endCamera
+ * @see frustum
+ */
+ p.camera = function(eyeX, eyeY, eyeZ, centerX, centerY, centerZ, upX, upY, upZ) {
+ if (eyeX === undef) {
+ // Workaround if createGraphics is used.
+ cameraX = p.width / 2;
+ cameraY = p.height / 2;
+ cameraZ = cameraY / Math.tan(cameraFOV / 2);
+ eyeX = cameraX;
+ eyeY = cameraY;
+ eyeZ = cameraZ;
+ centerX = cameraX;
+ centerY = cameraY;
+ centerZ = 0;
+ upX = 0;
+ upY = 1;
+ upZ = 0;
+ }
+
+ var z = new PVector(eyeX - centerX, eyeY - centerY, eyeZ - centerZ);
+ var y = new PVector(upX, upY, upZ);
+ z.normalize();
+ var x = PVector.cross(y, z);
+ y = PVector.cross(z, x);
+ x.normalize();
+ y.normalize();
+
+ var xX = x.x,
+ xY = x.y,
+ xZ = x.z;
+
+ var yX = y.x,
+ yY = y.y,
+ yZ = y.z;
+
+ var zX = z.x,
+ zY = z.y,
+ zZ = z.z;
+
+ cam.set(xX, xY, xZ, 0, yX, yY, yZ, 0, zX, zY, zZ, 0, 0, 0, 0, 1);
+
+ cam.translate(-eyeX, -eyeY, -eyeZ);
+
+ cameraInv.reset();
+ cameraInv.invApply(xX, xY, xZ, 0, yX, yY, yZ, 0, zX, zY, zZ, 0, 0, 0, 0, 1);
+
+ cameraInv.translate(eyeX, eyeY, eyeZ);
+
+ modelView.set(cam);
+ modelViewInv.set(cameraInv);
+ };
+
+ /**
+ * Sets a perspective projection applying foreshortening, making distant objects appear smaller than closer ones. The
+ * parameters define a viewing volume with the shape of truncated pyramid. Objects near to the front of the volume appear
+ * their actual size, while farther objects appear smaller. This projection simulates the perspective of the world more
+ * accurately than orthographic projection. The version of perspective without parameters sets the default perspective and
+ * the version with four parameters allows the programmer to set the area precisely. The default values are:
+ * perspective(PI/3.0, width/height, cameraZ/10.0, cameraZ*10.0) where cameraZ is ((height/2.0) / tan(PI*60.0/360.0));
+ *
+ * @param {float} fov field-of-view angle (in radians) for vertical direction
+ * @param {float} aspect ratio of width to height
+ * @param {float} zNear z-position of nearest clipping plane
+ * @param {float} zFar z-positions of farthest clipping plane
+ */
+ p.perspective = function(fov, aspect, near, far) {
+ if (arguments.length === 0) {
+ //in case canvas is resized
+ cameraY = curElement.height / 2;
+ cameraZ = cameraY / Math.tan(cameraFOV / 2);
+ cameraNear = cameraZ / 10;
+ cameraFar = cameraZ * 10;
+ cameraAspect = p.width / p.height;
+ fov = cameraFOV;
+ aspect = cameraAspect;
+ near = cameraNear;
+ far = cameraFar;
+ }
+
+ var yMax, yMin, xMax, xMin;
+ yMax = near * Math.tan(fov / 2);
+ yMin = -yMax;
+ xMax = yMax * aspect;
+ xMin = yMin * aspect;
+ p.frustum(xMin, xMax, yMin, yMax, near, far);
+ };
+
+ /**
+ * Sets a perspective matrix defined through the parameters. Works like glFrustum, except it wipes out the current
+ * perspective matrix rather than muliplying itself with it.
+ *
+ * @param {float} left left coordinate of the clipping plane
+ * @param {float} right right coordinate of the clipping plane
+ * @param {float} bottom bottom coordinate of the clipping plane
+ * @param {float} top top coordinate of the clipping plane
+ * @param {float} near near coordinate of the clipping plane
+ * @param {float} far far coordinate of the clipping plane
+ *
+ * @see beginCamera
+ * @see camera
+ * @see endCamera
+ * @see perspective
+ */
+ Drawing2D.prototype.frustum = function() {
+ throw("Processing.js: frustum() is not supported in 2D mode");
+ };
+
+ Drawing3D.prototype.frustum = function(left, right, bottom, top, near, far) {
+ frustumMode = true;
+ projection = new PMatrix3D();
+ projection.set((2 * near) / (right - left), 0, (right + left) / (right - left),
+ 0, 0, (2 * near) / (top - bottom), (top + bottom) / (top - bottom),
+ 0, 0, 0, -(far + near) / (far - near), -(2 * far * near) / (far - near),
+ 0, 0, -1, 0);
+ var proj = new PMatrix3D();
+ proj.set(projection);
+ proj.transpose();
+ curContext.useProgram(programObject2D);
+ uniformMatrix("projection2d", programObject2D, "uProjection", false, proj.array());
+ curContext.useProgram(programObject3D);
+ uniformMatrix("projection3d", programObject3D, "uProjection", false, proj.array());
+ curContext.useProgram(programObjectUnlitShape);
+ uniformMatrix("uProjectionUS", programObjectUnlitShape, "uProjection", false, proj.array());
+ };
+
+ /**
+ * Sets an orthographic projection and defines a parallel clipping volume. All objects with the same dimension appear
+ * the same size, regardless of whether they are near or far from the camera. The parameters to this function specify
+ * the clipping volume where left and right are the minimum and maximum x values, top and bottom are the minimum and
+ * maximum y values, and near and far are the minimum and maximum z values. If no parameters are given, the default
+ * is used: ortho(0, width, 0, height, -10, 10).
+ *
+ * @param {float} left left plane of the clipping volume
+ * @param {float} right right plane of the clipping volume
+ * @param {float} bottom bottom plane of the clipping volume
+ * @param {float} top top plane of the clipping volume
+ * @param {float} near maximum distance from the origin to the viewer
+ * @param {float} far maximum distance from the origin away from the viewer
+ */
+ p.ortho = function(left, right, bottom, top, near, far) {
+ if (arguments.length === 0) {
+ left = 0;
+ right = p.width;
+ bottom = 0;
+ top = p.height;
+ near = -10;
+ far = 10;
+ }
+
+ var x = 2 / (right - left);
+ var y = 2 / (top - bottom);
+ var z = -2 / (far - near);
+
+ var tx = -(right + left) / (right - left);
+ var ty = -(top + bottom) / (top - bottom);
+ var tz = -(far + near) / (far - near);
+
+ projection = new PMatrix3D();
+ projection.set(x, 0, 0, tx, 0, y, 0, ty, 0, 0, z, tz, 0, 0, 0, 1);
+
+ var proj = new PMatrix3D();
+ proj.set(projection);
+ proj.transpose();
+ curContext.useProgram(programObject2D);
+ uniformMatrix("projection2d", programObject2D, "uProjection", false, proj.array());
+ curContext.useProgram(programObject3D);
+ uniformMatrix("projection3d", programObject3D, "uProjection", false, proj.array());
+ curContext.useProgram(programObjectUnlitShape);
+ uniformMatrix("uProjectionUS", programObjectUnlitShape, "uProjection", false, proj.array());
+ frustumMode = false;
+ };
+ /**
+ * The printProjection() prints the current projection matrix to the text window.
+ */
+ p.printProjection = function() {
+ projection.print();
+ };
+ /**
+ * The printCamera() function prints the current camera matrix.
+ */
+ p.printCamera = function() {
+ cam.print();
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Shapes
+ ////////////////////////////////////////////////////////////////////////////
+ /**
+ * The box() function renders a box. A box is an extruded rectangle. A box with equal dimension on all sides is a cube.
+ * Calling this function with only one parameter will create a cube.
+ *
+ * @param {int|float} w dimension of the box in the x-dimension
+ * @param {int|float} h dimension of the box in the y-dimension
+ * @param {int|float} d dimension of the box in the z-dimension
+ */
+ Drawing2D.prototype.box = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.box = function(w, h, d) {
+ // user can uniformly scale the box by
+ // passing in only one argument.
+ if (!h || !d) {
+ h = d = w;
+ }
+
+ // Modeling transformation
+ var model = new PMatrix3D();
+ model.scale(w, h, d);
+
+ // Viewing transformation needs to have Y flipped
+ // becuase that's what Processing does.
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.transpose();
+
+ if (doFill) {
+ curContext.useProgram(programObject3D);
+ uniformMatrix("model3d", programObject3D, "uModel", false, model.array());
+ uniformMatrix("view3d", programObject3D, "uView", false, view.array());
+ // Fix stitching problems. (lines get occluded by triangles
+ // since they share the same depth values). This is not entirely
+ // working, but it's a start for drawing the outline. So
+ // developers can start playing around with styles.
+ curContext.enable(curContext.POLYGON_OFFSET_FILL);
+ curContext.polygonOffset(1, 1);
+ uniformf("color3d", programObject3D, "uColor", fillStyle);
+
+ // Calculating the normal matrix can be expensive, so only
+ // do it if it's necessary.
+ if(lightCount > 0){
+ // Create the normal transformation matrix.
+ var v = new PMatrix3D();
+ v.set(view);
+
+ var m = new PMatrix3D();
+ m.set(model);
+
+ v.mult(m);
+
+ var normalMatrix = new PMatrix3D();
+ normalMatrix.set(v);
+ normalMatrix.invert();
+ normalMatrix.transpose();
+
+ uniformMatrix("uNormalTransform3d", programObject3D, "uNormalTransform", false, normalMatrix.array());
+ vertexAttribPointer("aNormal3d", programObject3D, "aNormal", 3, boxNormBuffer);
+ }
+ else{
+ disableVertexAttribPointer("aNormal3d", programObject3D, "aNormal");
+ }
+
+ vertexAttribPointer("aVertex3d", programObject3D, "aVertex", 3, boxBuffer);
+
+ // Turn off per vertex colors.
+ disableVertexAttribPointer("aColor3d", programObject3D, "aColor");
+ disableVertexAttribPointer("aTexture3d", programObject3D, "aTexture");
+
+ curContext.drawArrays(curContext.TRIANGLES, 0, boxVerts.length / 3);
+ curContext.disable(curContext.POLYGON_OFFSET_FILL);
+ }
+
+ // Draw the box outline.
+ if (lineWidth > 0 && doStroke) {
+ curContext.useProgram(programObject2D);
+ uniformMatrix("uModel2d", programObject2D, "uModel", false, model.array());
+ uniformMatrix("uView2d", programObject2D, "uView", false, view.array());
+ uniformf("uColor2d", programObject2D, "uColor", strokeStyle);
+ uniformi("uIsDrawingText2d", programObject2D, "uIsDrawingText", false);
+ vertexAttribPointer("vertex2d", programObject2D, "aVertex", 3, boxOutlineBuffer);
+ disableVertexAttribPointer("aTextureCoord2d", programObject2D, "aTextureCoord");
+ curContext.drawArrays(curContext.LINES, 0, boxOutlineVerts.length / 3);
+ }
+ };
+
+ /**
+ * The initSphere() function is a helper function used by <b>sphereDetail()</b>
+ * This function creates and stores sphere vertices every time the user changes sphere detail.
+ *
+ * @see #sphereDetail
+ */
+ var initSphere = function() {
+ var i;
+ sphereVerts = [];
+
+ for (i = 0; i < sphereDetailU; i++) {
+ sphereVerts.push(0);
+ sphereVerts.push(-1);
+ sphereVerts.push(0);
+ sphereVerts.push(sphereX[i]);
+ sphereVerts.push(sphereY[i]);
+ sphereVerts.push(sphereZ[i]);
+ }
+ sphereVerts.push(0);
+ sphereVerts.push(-1);
+ sphereVerts.push(0);
+ sphereVerts.push(sphereX[0]);
+ sphereVerts.push(sphereY[0]);
+ sphereVerts.push(sphereZ[0]);
+
+ var v1, v11, v2;
+
+ // middle rings
+ var voff = 0;
+ for (i = 2; i < sphereDetailV; i++) {
+ v1 = v11 = voff;
+ voff += sphereDetailU;
+ v2 = voff;
+ for (var j = 0; j < sphereDetailU; j++) {
+ sphereVerts.push(sphereX[v1]);
+ sphereVerts.push(sphereY[v1]);
+ sphereVerts.push(sphereZ[v1++]);
+ sphereVerts.push(sphereX[v2]);
+ sphereVerts.push(sphereY[v2]);
+ sphereVerts.push(sphereZ[v2++]);
+ }
+
+ // close each ring
+ v1 = v11;
+ v2 = voff;
+
+ sphereVerts.push(sphereX[v1]);
+ sphereVerts.push(sphereY[v1]);
+ sphereVerts.push(sphereZ[v1]);
+ sphereVerts.push(sphereX[v2]);
+ sphereVerts.push(sphereY[v2]);
+ sphereVerts.push(sphereZ[v2]);
+ }
+
+ // add the northern cap
+ for (i = 0; i < sphereDetailU; i++) {
+ v2 = voff + i;
+
+ sphereVerts.push(sphereX[v2]);
+ sphereVerts.push(sphereY[v2]);
+ sphereVerts.push(sphereZ[v2]);
+ sphereVerts.push(0);
+ sphereVerts.push(1);
+ sphereVerts.push(0);
+ }
+
+ sphereVerts.push(sphereX[voff]);
+ sphereVerts.push(sphereY[voff]);
+ sphereVerts.push(sphereZ[voff]);
+ sphereVerts.push(0);
+ sphereVerts.push(1);
+ sphereVerts.push(0);
+
+ //set the buffer data
+ curContext.bindBuffer(curContext.ARRAY_BUFFER, sphereBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array(sphereVerts), curContext.STATIC_DRAW);
+ };
+
+ /**
+ * The sphereDetail() function controls the detail used to render a sphere by adjusting the number of
+ * vertices of the sphere mesh. The default resolution is 30, which creates
+ * a fairly detailed sphere definition with vertices every 360/30 = 12
+ * degrees. If you're going to render a great number of spheres per frame,
+ * it is advised to reduce the level of detail using this function.
+ * The setting stays active until <b>sphereDetail()</b> is called again with
+ * a new parameter and so should <i>not</i> be called prior to every
+ * <b>sphere()</b> statement, unless you wish to render spheres with
+ * different settings, e.g. using less detail for smaller spheres or ones
+ * further away from the camera. To control the detail of the horizontal
+ * and vertical resolution independently, use the version of the functions
+ * with two parameters. Calling this function with one parameter sets the number of segments
+ *(minimum of 3) used per full circle revolution. This is equivalent to calling the function with
+ * two identical values.
+ *
+ * @param {int} ures number of segments used horizontally (longitudinally) per full circle revolution
+ * @param {int} vres number of segments used vertically (latitudinally) from top to bottom
+ *
+ * @see #sphere()
+ */
+ p.sphereDetail = function(ures, vres) {
+ var i;
+
+ if (arguments.length === 1) {
+ ures = vres = arguments[0];
+ }
+
+ if (ures < 3) {
+ ures = 3;
+ } // force a minimum res
+ if (vres < 2) {
+ vres = 2;
+ } // force a minimum res
+ // if it hasn't changed do nothing
+ if ((ures === sphereDetailU) && (vres === sphereDetailV)) {
+ return;
+ }
+
+ var delta = PConstants.SINCOS_LENGTH / ures;
+ var cx = new Float32Array(ures);
+ var cz = new Float32Array(ures);
+ // calc unit circle in XZ plane
+ for (i = 0; i < ures; i++) {
+ cx[i] = cosLUT[((i * delta) % PConstants.SINCOS_LENGTH) | 0];
+ cz[i] = sinLUT[((i * delta) % PConstants.SINCOS_LENGTH) | 0];
+ }
+
+ // computing vertexlist
+ // vertexlist starts at south pole
+ var vertCount = ures * (vres - 1) + 2;
+ var currVert = 0;
+
+ // re-init arrays to store vertices
+ sphereX = new Float32Array(vertCount);
+ sphereY = new Float32Array(vertCount);
+ sphereZ = new Float32Array(vertCount);
+
+ var angle_step = (PConstants.SINCOS_LENGTH * 0.5) / vres;
+ var angle = angle_step;
+
+ // step along Y axis
+ for (i = 1; i < vres; i++) {
+ var curradius = sinLUT[(angle % PConstants.SINCOS_LENGTH) | 0];
+ var currY = -cosLUT[(angle % PConstants.SINCOS_LENGTH) | 0];
+ for (var j = 0; j < ures; j++) {
+ sphereX[currVert] = cx[j] * curradius;
+ sphereY[currVert] = currY;
+ sphereZ[currVert++] = cz[j] * curradius;
+ }
+ angle += angle_step;
+ }
+ sphereDetailU = ures;
+ sphereDetailV = vres;
+
+ // make the sphere verts and norms
+ initSphere();
+ };
+
+ /**
+ * The sphere() function draws a sphere with radius r centered at coordinate 0, 0, 0.
+ * A sphere is a hollow ball made from tessellated triangles.
+ *
+ * @param {int|float} r the radius of the sphere
+ */
+ Drawing2D.prototype.sphere = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.sphere = function() {
+ var sRad = arguments[0];
+
+ if ((sphereDetailU < 3) || (sphereDetailV < 2)) {
+ p.sphereDetail(30);
+ }
+
+ // Modeling transformation.
+ var model = new PMatrix3D();
+ model.scale(sRad, sRad, sRad);
+
+ // viewing transformation needs to have Y flipped
+ // becuase that's what Processing does.
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.transpose();
+
+ if (doFill) {
+ // Calculating the normal matrix can be expensive, so only
+ // do it if it's necessary.
+ if(lightCount > 0){
+ // Create a normal transformation matrix.
+ var v = new PMatrix3D();
+ v.set(view);
+
+ var m = new PMatrix3D();
+ m.set(model);
+
+ v.mult(m);
+
+ var normalMatrix = new PMatrix3D();
+ normalMatrix.set(v);
+ normalMatrix.invert();
+ normalMatrix.transpose();
+
+ uniformMatrix("uNormalTransform3d", programObject3D, "uNormalTransform", false, normalMatrix.array());
+ vertexAttribPointer("aNormal3d", programObject3D, "aNormal", 3, sphereBuffer);
+ }
+ else{
+ disableVertexAttribPointer("aNormal3d", programObject3D, "aNormal");
+ }
+
+ curContext.useProgram(programObject3D);
+ disableVertexAttribPointer("aTexture3d", programObject3D, "aTexture");
+
+ uniformMatrix("uModel3d", programObject3D, "uModel", false, model.array());
+ uniformMatrix("uView3d", programObject3D, "uView", false, view.array());
+ vertexAttribPointer("aVertex3d", programObject3D, "aVertex", 3, sphereBuffer);
+
+ // Turn off per vertex colors.
+ disableVertexAttribPointer("aColor3d", programObject3D, "aColor");
+
+ // fix stitching problems. (lines get occluded by triangles
+ // since they share the same depth values). This is not entirely
+ // working, but it's a start for drawing the outline. So
+ // developers can start playing around with styles.
+ curContext.enable(curContext.POLYGON_OFFSET_FILL);
+ curContext.polygonOffset(1, 1);
+ uniformf("uColor3d", programObject3D, "uColor", fillStyle);
+ curContext.drawArrays(curContext.TRIANGLE_STRIP, 0, sphereVerts.length / 3);
+ curContext.disable(curContext.POLYGON_OFFSET_FILL);
+ }
+
+ // Draw the sphere outline.
+ if (lineWidth > 0 && doStroke) {
+ curContext.useProgram(programObject2D);
+ uniformMatrix("uModel2d", programObject2D, "uModel", false, model.array());
+ uniformMatrix("uView2d", programObject2D, "uView", false, view.array());
+ vertexAttribPointer("aVertex2d", programObject2D, "aVertex", 3, sphereBuffer);
+ disableVertexAttribPointer("aTextureCoord2d", programObject2D, "aTextureCoord");
+ uniformf("uColor2d", programObject2D, "uColor", strokeStyle);
+ uniformi("uIsDrawingText", programObject2D, "uIsDrawingText", false);
+ curContext.drawArrays(curContext.LINE_STRIP, 0, sphereVerts.length / 3);
+ }
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Coordinates
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Returns the three-dimensional X, Y, Z position in model space. This returns
+ * the X value for a given coordinate based on the current set of transformations
+ * (scale, rotate, translate, etc.) The X value can be used to place an object
+ * in space relative to the location of the original point once the transformations
+ * are no longer in use.<br />
+ * <br />
+ *
+ * @param {int | float} x 3D x coordinate to be mapped
+ * @param {int | float} y 3D y coordinate to be mapped
+ * @param {int | float} z 3D z coordinate to be mapped
+ *
+ * @returns {float}
+ *
+ * @see modelY
+ * @see modelZ
+ */
+ p.modelX = function(x, y, z) {
+ var mv = modelView.array();
+ var ci = cameraInv.array();
+
+ var ax = mv[0] * x + mv[1] * y + mv[2] * z + mv[3];
+ var ay = mv[4] * x + mv[5] * y + mv[6] * z + mv[7];
+ var az = mv[8] * x + mv[9] * y + mv[10] * z + mv[11];
+ var aw = mv[12] * x + mv[13] * y + mv[14] * z + mv[15];
+
+ var ox = ci[0] * ax + ci[1] * ay + ci[2] * az + ci[3] * aw;
+ var ow = ci[12] * ax + ci[13] * ay + ci[14] * az + ci[15] * aw;
+
+ return (ow !== 0) ? ox / ow : ox;
+ };
+
+ /**
+ * Returns the three-dimensional X, Y, Z position in model space. This returns
+ * the Y value for a given coordinate based on the current set of transformations
+ * (scale, rotate, translate, etc.) The Y value can be used to place an object in
+ * space relative to the location of the original point once the transformations
+ * are no longer in use.<br />
+ * <br />
+ *
+ * @param {int | float} x 3D x coordinate to be mapped
+ * @param {int | float} y 3D y coordinate to be mapped
+ * @param {int | float} z 3D z coordinate to be mapped
+ *
+ * @returns {float}
+ *
+ * @see modelX
+ * @see modelZ
+ */
+ p.modelY = function(x, y, z) {
+ var mv = modelView.array();
+ var ci = cameraInv.array();
+
+ var ax = mv[0] * x + mv[1] * y + mv[2] * z + mv[3];
+ var ay = mv[4] * x + mv[5] * y + mv[6] * z + mv[7];
+ var az = mv[8] * x + mv[9] * y + mv[10] * z + mv[11];
+ var aw = mv[12] * x + mv[13] * y + mv[14] * z + mv[15];
+
+ var oy = ci[4] * ax + ci[5] * ay + ci[6] * az + ci[7] * aw;
+ var ow = ci[12] * ax + ci[13] * ay + ci[14] * az + ci[15] * aw;
+
+ return (ow !== 0) ? oy / ow : oy;
+ };
+
+ /**
+ * Returns the three-dimensional X, Y, Z position in model space. This returns
+ * the Z value for a given coordinate based on the current set of transformations
+ * (scale, rotate, translate, etc.) The Z value can be used to place an object in
+ * space relative to the location of the original point once the transformations
+ * are no longer in use.
+ *
+ * @param {int | float} x 3D x coordinate to be mapped
+ * @param {int | float} y 3D y coordinate to be mapped
+ * @param {int | float} z 3D z coordinate to be mapped
+ *
+ * @returns {float}
+ *
+ * @see modelX
+ * @see modelY
+ */
+ p.modelZ = function(x, y, z) {
+ var mv = modelView.array();
+ var ci = cameraInv.array();
+
+ var ax = mv[0] * x + mv[1] * y + mv[2] * z + mv[3];
+ var ay = mv[4] * x + mv[5] * y + mv[6] * z + mv[7];
+ var az = mv[8] * x + mv[9] * y + mv[10] * z + mv[11];
+ var aw = mv[12] * x + mv[13] * y + mv[14] * z + mv[15];
+
+ var oz = ci[8] * ax + ci[9] * ay + ci[10] * az + ci[11] * aw;
+ var ow = ci[12] * ax + ci[13] * ay + ci[14] * az + ci[15] * aw;
+
+ return (ow !== 0) ? oz / ow : oz;
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Material Properties
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Sets the ambient reflectance for shapes drawn to the screen. This is
+ * combined with the ambient light component of environment. The color
+ * components set through the parameters define the reflectance. For example in
+ * the default color mode, setting v1=255, v2=126, v3=0, would cause all the
+ * red light to reflect and half of the green light to reflect. Used in combination
+ * with <b>emissive()</b>, <b>specular()</b>, and <b>shininess()</b> in setting
+ * the materal properties of shapes.
+ *
+ * @param {int | float} gray
+ *
+ * @returns none
+ *
+ * @see emissive
+ * @see specular
+ * @see shininess
+ */
+ Drawing2D.prototype.ambient = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.ambient = function(v1, v2, v3) {
+ curContext.useProgram(programObject3D);
+ uniformi("uUsingMat3d", programObject3D, "uUsingMat", true);
+ var col = p.color(v1, v2, v3);
+ uniformf("uMaterialAmbient3d", programObject3D, "uMaterialAmbient", p.color.toGLArray(col).slice(0, 3));
+ };
+
+ /**
+ * Sets the emissive color of the material used for drawing shapes
+ * drawn to the screen. Used in combination with ambient(), specular(),
+ * and shininess() in setting the material properties of shapes.
+ *
+ * Can be called in the following ways:
+ *
+ * emissive(gray)
+ * @param {int | float} gray number specifying value between white and black
+ *
+ * emissive(color)
+ * @param {color} color any value of the color datatype
+ *
+ * emissive(v1, v2, v3)
+ * @param {int | float} v1 red or hue value
+ * @param {int | float} v2 green or saturation value
+ * @param {int | float} v3 blue or brightness value
+ *
+ * @returns none
+ *
+ * @see ambient
+ * @see specular
+ * @see shininess
+ */
+ Drawing2D.prototype.emissive = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.emissive = function(v1, v2, v3) {
+ curContext.useProgram(programObject3D);
+ uniformi("uUsingMat3d", programObject3D, "uUsingMat", true);
+ var col = p.color(v1, v2, v3);
+ uniformf("uMaterialEmissive3d", programObject3D, "uMaterialEmissive", p.color.toGLArray(col).slice(0, 3));
+ };
+
+ /**
+ * Sets the amount of gloss in the surface of shapes. Used in combination with
+ * <b>ambient()</b>, <b>specular()</b>, and <b>emissive()</b> in setting the
+ * material properties of shapes.
+ *
+ * @param {float} shine degree of shininess
+ *
+ * @returns none
+ */
+ Drawing2D.prototype.shininess = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.shininess = function(shine) {
+ curContext.useProgram(programObject3D);
+ uniformi("uUsingMat3d", programObject3D, "uUsingMat", true);
+ uniformf("uShininess3d", programObject3D, "uShininess", shine);
+ };
+
+ /**
+ * Sets the specular color of the materials used for shapes drawn to the screen,
+ * which sets the color of hightlights. Specular refers to light which bounces
+ * off a surface in a perferred direction (rather than bouncing in all directions
+ * like a diffuse light). Used in combination with emissive(), ambient(), and
+ * shininess() in setting the material properties of shapes.
+ *
+ * Can be called in the following ways:
+ *
+ * specular(gray)
+ * @param {int | float} gray number specifying value between white and black
+ *
+ * specular(gray, alpha)
+ * @param {int | float} gray number specifying value between white and black
+ * @param {int | float} alpha opacity
+ *
+ * specular(color)
+ * @param {color} color any value of the color datatype
+ *
+ * specular(v1, v2, v3)
+ * @param {int | float} v1 red or hue value
+ * @param {int | float} v2 green or saturation value
+ * @param {int | float} v3 blue or brightness value
+ *
+ * specular(v1, v2, v3, alpha)
+ * @param {int | float} v1 red or hue value
+ * @param {int | float} v2 green or saturation value
+ * @param {int | float} v3 blue or brightness value
+ * @param {int | float} alpha opacity
+ *
+ * @returns none
+ *
+ * @see ambient
+ * @see emissive
+ * @see shininess
+ */
+ Drawing2D.prototype.specular = DrawingShared.prototype.a3DOnlyFunction;
+
+ Drawing3D.prototype.specular = function(v1, v2, v3) {
+ curContext.useProgram(programObject3D);
+ uniformi("uUsingMat3d", programObject3D, "uUsingMat", true);
+ var col = p.color(v1, v2, v3);
+ uniformf("uMaterialSpecular3d", programObject3D, "uMaterialSpecular", p.color.toGLArray(col).slice(0, 3));
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Coordinates
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Takes a three-dimensional X, Y, Z position and returns the X value for
+ * where it will appear on a (two-dimensional) screen.
+ *
+ * @param {int | float} x 3D x coordinate to be mapped
+ * @param {int | float} y 3D y coordinate to be mapped
+ * @param {int | float} z 3D z optional coordinate to be mapped
+ *
+ * @returns {float}
+ *
+ * @see screenY
+ * @see screenZ
+ */
+ p.screenX = function( x, y, z ) {
+ var mv = modelView.array();
+ if( mv.length === 16 )
+ {
+ var ax = mv[ 0]*x + mv[ 1]*y + mv[ 2]*z + mv[ 3];
+ var ay = mv[ 4]*x + mv[ 5]*y + mv[ 6]*z + mv[ 7];
+ var az = mv[ 8]*x + mv[ 9]*y + mv[10]*z + mv[11];
+ var aw = mv[12]*x + mv[13]*y + mv[14]*z + mv[15];
+
+ var pj = projection.array();
+
+ var ox = pj[ 0]*ax + pj[ 1]*ay + pj[ 2]*az + pj[ 3]*aw;
+ var ow = pj[12]*ax + pj[13]*ay + pj[14]*az + pj[15]*aw;
+
+ if ( ow !== 0 ){
+ ox /= ow;
+ }
+ return p.width * ( 1 + ox ) / 2.0;
+ }
+ // We assume that we're in 2D
+ return modelView.multX(x, y);
+ };
+
+ /**
+ * Takes a three-dimensional X, Y, Z position and returns the Y value for
+ * where it will appear on a (two-dimensional) screen.
+ *
+ * @param {int | float} x 3D x coordinate to be mapped
+ * @param {int | float} y 3D y coordinate to be mapped
+ * @param {int | float} z 3D z optional coordinate to be mapped
+ *
+ * @returns {float}
+ *
+ * @see screenX
+ * @see screenZ
+ */
+ p.screenY = function screenY( x, y, z ) {
+ var mv = modelView.array();
+ if( mv.length === 16 ) {
+ var ax = mv[ 0]*x + mv[ 1]*y + mv[ 2]*z + mv[ 3];
+ var ay = mv[ 4]*x + mv[ 5]*y + mv[ 6]*z + mv[ 7];
+ var az = mv[ 8]*x + mv[ 9]*y + mv[10]*z + mv[11];
+ var aw = mv[12]*x + mv[13]*y + mv[14]*z + mv[15];
+
+ var pj = projection.array();
+
+ var oy = pj[ 4]*ax + pj[ 5]*ay + pj[ 6]*az + pj[ 7]*aw;
+ var ow = pj[12]*ax + pj[13]*ay + pj[14]*az + pj[15]*aw;
+
+ if ( ow !== 0 ){
+ oy /= ow;
+ }
+ return p.height * ( 1 + oy ) / 2.0;
+ }
+ // We assume that we're in 2D
+ return modelView.multY(x, y);
+ };
+
+ /**
+ * Takes a three-dimensional X, Y, Z position and returns the Z value for
+ * where it will appear on a (two-dimensional) screen.
+ *
+ * @param {int | float} x 3D x coordinate to be mapped
+ * @param {int | float} y 3D y coordinate to be mapped
+ * @param {int | float} z 3D z coordinate to be mapped
+ *
+ * @returns {float}
+ *
+ * @see screenX
+ * @see screenY
+ */
+ p.screenZ = function screenZ( x, y, z ) {
+ var mv = modelView.array();
+ if( mv.length !== 16 ) {
+ return 0;
+ }
+
+ var pj = projection.array();
+
+ var ax = mv[ 0]*x + mv[ 1]*y + mv[ 2]*z + mv[ 3];
+ var ay = mv[ 4]*x + mv[ 5]*y + mv[ 6]*z + mv[ 7];
+ var az = mv[ 8]*x + mv[ 9]*y + mv[10]*z + mv[11];
+ var aw = mv[12]*x + mv[13]*y + mv[14]*z + mv[15];
+
+ var oz = pj[ 8]*ax + pj[ 9]*ay + pj[10]*az + pj[11]*aw;
+ var ow = pj[12]*ax + pj[13]*ay + pj[14]*az + pj[15]*aw;
+
+ if ( ow !== 0 ) {
+ oz /= ow;
+ }
+ return ( oz + 1 ) / 2.0;
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Style functions
+ ////////////////////////////////////////////////////////////////////////////
+ /**
+ * The fill() function sets the color used to fill shapes. For example, if you run <b>fill(204, 102, 0)</b>, all subsequent shapes will be filled with orange.
+ * This color is either specified in terms of the RGB or HSB color depending on the current <b>colorMode()</b>
+ *(the default color space is RGB, with each value in the range from 0 to 255).
+ * <br><br>When using hexadecimal notation to specify a color, use "#" or "0x" before the values (e.g. #CCFFAA, 0xFFCCFFAA).
+ * The # syntax uses six digits to specify a color (the way colors are specified in HTML and CSS). When using the hexadecimal notation starting with "0x",
+ * the hexadecimal value must be specified with eight characters; the first two characters define the alpha component and the remainder the red, green, and blue components.
+ * <br><br>The value for the parameter "gray" must be less than or equal to the current maximum value as specified by <b>colorMode()</b>. The default maximum value is 255.
+ * <br><br>To change the color of an image (or a texture), use tint().
+ *
+ * @param {int|float} gray number specifying value between white and black
+ * @param {int|float} value1 red or hue value
+ * @param {int|float} value2 green or saturation value
+ * @param {int|float} value3 blue or brightness value
+ * @param {int|float} alpha opacity of the fill
+ * @param {Color} color any value of the color datatype
+ * @param {int} hex color value in hexadecimal notation (i.e. #FFCC00 or 0xFFFFCC00)
+ *
+ * @see #noFill()
+ * @see #stroke()
+ * @see #tint()
+ * @see #background()
+ * @see #colorMode()
+ */
+ DrawingShared.prototype.fill = function() {
+ var color = p.color.apply(this, arguments);
+ if(color === currentFillColor && doFill) {
+ return;
+ }
+ doFill = true;
+ currentFillColor = color;
+ };
+
+ Drawing2D.prototype.fill = function() {
+ DrawingShared.prototype.fill.apply(this, arguments);
+ isFillDirty = true;
+ };
+
+ Drawing3D.prototype.fill = function() {
+ DrawingShared.prototype.fill.apply(this, arguments);
+ fillStyle = p.color.toGLArray(currentFillColor);
+ };
+
+ function executeContextFill() {
+ if(doFill) {
+ if(isFillDirty) {
+ curContext.fillStyle = p.color.toString(currentFillColor);
+ isFillDirty = false;
+ }
+ curContext.fill();
+ }
+ }
+
+ /**
+ * The noFill() function disables filling geometry. If both <b>noStroke()</b> and <b>noFill()</b>
+ * are called, no shapes will be drawn to the screen.
+ *
+ * @see #fill()
+ *
+ */
+ p.noFill = function() {
+ doFill = false;
+ };
+
+ /**
+ * The stroke() function sets the color used to draw lines and borders around shapes. This color
+ * is either specified in terms of the RGB or HSB color depending on the
+ * current <b>colorMode()</b> (the default color space is RGB, with each
+ * value in the range from 0 to 255).
+ * <br><br>When using hexadecimal notation to specify a color, use "#" or
+ * "0x" before the values (e.g. #CCFFAA, 0xFFCCFFAA). The # syntax uses six
+ * digits to specify a color (the way colors are specified in HTML and CSS).
+ * When using the hexadecimal notation starting with "0x", the hexadecimal
+ * value must be specified with eight characters; the first two characters
+ * define the alpha component and the remainder the red, green, and blue
+ * components.
+ * <br><br>The value for the parameter "gray" must be less than or equal
+ * to the current maximum value as specified by <b>colorMode()</b>.
+ * The default maximum value is 255.
+ *
+ * @param {int|float} gray number specifying value between white and black
+ * @param {int|float} value1 red or hue value
+ * @param {int|float} value2 green or saturation value
+ * @param {int|float} value3 blue or brightness value
+ * @param {int|float} alpha opacity of the stroke
+ * @param {Color} color any value of the color datatype
+ * @param {int} hex color value in hexadecimal notation (i.e. #FFCC00 or 0xFFFFCC00)
+ *
+ * @see #fill()
+ * @see #noStroke()
+ * @see #tint()
+ * @see #background()
+ * @see #colorMode()
+ */
+ DrawingShared.prototype.stroke = function() {
+ var color = p.color.apply(this, arguments);
+ if(color === currentStrokeColor && doStroke) {
+ return;
+ }
+ doStroke = true;
+ currentStrokeColor = color;
+ };
+
+ Drawing2D.prototype.stroke = function() {
+ DrawingShared.prototype.stroke.apply(this, arguments);
+ isStrokeDirty = true;
+ };
+
+ Drawing3D.prototype.stroke = function() {
+ DrawingShared.prototype.stroke.apply(this, arguments);
+ strokeStyle = p.color.toGLArray(currentStrokeColor);
+ };
+
+ function executeContextStroke() {
+ if(doStroke) {
+ if(isStrokeDirty) {
+ curContext.strokeStyle = p.color.toString(currentStrokeColor);
+ isStrokeDirty = false;
+ }
+ curContext.stroke();
+ }
+ }
+
+ /**
+ * The noStroke() function disables drawing the stroke (outline). If both <b>noStroke()</b> and
+ * <b>noFill()</b> are called, no shapes will be drawn to the screen.
+ *
+ * @see #stroke()
+ */
+ p.noStroke = function() {
+ doStroke = false;
+ };
+
+ /**
+ * The strokeWeight() function sets the width of the stroke used for lines, points, and the border around shapes.
+ * All widths are set in units of pixels.
+ *
+ * @param {int|float} w the weight (in pixels) of the stroke
+ */
+ DrawingShared.prototype.strokeWeight = function(w) {
+ lineWidth = w;
+ };
+
+ Drawing2D.prototype.strokeWeight = function(w) {
+ DrawingShared.prototype.strokeWeight.apply(this, arguments);
+ curContext.lineWidth = w;
+ };
+
+ Drawing3D.prototype.strokeWeight = function(w) {
+ DrawingShared.prototype.strokeWeight.apply(this, arguments);
+
+ // Processing groups the weight of points and lines under this one function,
+ // but for WebGL, we need to set a uniform for points and call a function for line.
+
+ curContext.useProgram(programObject2D);
+ uniformf("pointSize2d", programObject2D, "uPointSize", w);
+
+ curContext.useProgram(programObjectUnlitShape);
+ uniformf("pointSizeUnlitShape", programObjectUnlitShape, "uPointSize", w);
+
+ curContext.lineWidth(w);
+ };
+
+ /**
+ * The strokeCap() function sets the style for rendering line endings. These ends are either squared, extended, or rounded and
+ * specified with the corresponding parameters SQUARE, PROJECT, and ROUND. The default cap is ROUND.
+ * This function is not available with the P2D, P3D, or OPENGL renderers
+ *
+ * @param {int} value Either SQUARE, PROJECT, or ROUND
+ */
+ p.strokeCap = function(value) {
+ drawing.$ensureContext().lineCap = value;
+ };
+
+ /**
+ * The strokeJoin() function sets the style of the joints which connect line segments.
+ * These joints are either mitered, beveled, or rounded and specified with the corresponding parameters MITER, BEVEL, and ROUND. The default joint is MITER.
+ * This function is not available with the P2D, P3D, or OPENGL renderers
+ *
+ * @param {int} value Either SQUARE, PROJECT, or ROUND
+ */
+ p.strokeJoin = function(value) {
+ drawing.$ensureContext().lineJoin = value;
+ };
+
+ /**
+ * The smooth() function draws all geometry with smooth (anti-aliased) edges. This will slow down the frame rate of the application,
+ * but will enhance the visual refinement. <br/><br/>
+ * Note that smooth() will also improve image quality of resized images, and noSmooth() will disable image (and font) smoothing altogether.
+ * When working with a 3D sketch, smooth will draw points as circles rather than squares.
+ *
+ * @see #noSmooth()
+ * @see #hint()
+ * @see #size()
+ */
+
+ Drawing2D.prototype.smooth = function() {
+ renderSmooth = true;
+ var style = curElement.style;
+ style.setProperty("image-rendering", "optimizeQuality", "important");
+ style.setProperty("-ms-interpolation-mode", "bicubic", "important");
+ if (curContext.hasOwnProperty("mozImageSmoothingEnabled")) {
+ curContext.mozImageSmoothingEnabled = true;
+ }
+ };
+
+ Drawing3D.prototype.smooth = function(){
+ renderSmooth = true;
+ };
+
+ /**
+ * The noSmooth() function draws all geometry with jagged (aliased) edges.
+ *
+ * @see #smooth()
+ */
+
+ Drawing2D.prototype.noSmooth = function() {
+ renderSmooth = false;
+ var style = curElement.style;
+ style.setProperty("image-rendering", "optimizeSpeed", "important");
+ style.setProperty("image-rendering", "-moz-crisp-edges", "important");
+ style.setProperty("image-rendering", "-webkit-optimize-contrast", "important");
+ style.setProperty("image-rendering", "optimize-contrast", "important");
+ style.setProperty("-ms-interpolation-mode", "nearest-neighbor", "important");
+ if (curContext.hasOwnProperty("mozImageSmoothingEnabled")) {
+ curContext.mozImageSmoothingEnabled = false;
+ }
+ };
+
+ Drawing3D.prototype.noSmooth = function(){
+ renderSmooth = false;
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Vector drawing functions
+ ////////////////////////////////////////////////////////////////////////////
+ /**
+ * The point() function draws a point, a coordinate in space at the dimension of one pixel.
+ * The first parameter is the horizontal value for the point, the second
+ * value is the vertical value for the point, and the optional third value
+ * is the depth value. Drawing this shape in 3D using the <b>z</b>
+ * parameter requires the P3D or OPENGL parameter in combination with
+ * size as shown in the above example.
+ *
+ * @param {int|float} x x-coordinate of the point
+ * @param {int|float} y y-coordinate of the point
+ * @param {int|float} z z-coordinate of the point
+ *
+ * @see #beginShape()
+ */
+ Drawing2D.prototype.point = function(x, y) {
+ if (!doStroke) {
+ return;
+ }
+ if (!renderSmooth) {
+ x = Math.round(x);
+ y = Math.round(y);
+ }
+ curContext.fillStyle = p.color.toString(currentStrokeColor);
+ isFillDirty = true;
+ // Draw a circle for any point larger than 1px
+ if (lineWidth > 1) {
+ curContext.beginPath();
+ curContext.arc(x, y, lineWidth / 2, 0, PConstants.TWO_PI, false);
+ curContext.fill();
+ } else {
+ curContext.fillRect(x, y, 1, 1);
+ }
+ };
+
+ Drawing3D.prototype.point = function(x, y, z) {
+ var model = new PMatrix3D();
+
+ // move point to position
+ model.translate(x, y, z || 0);
+ model.transpose();
+
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.transpose();
+
+ curContext.useProgram(programObject2D);
+ uniformMatrix("uModel2d", programObject2D, "uModel", false, model.array());
+ uniformMatrix("uView2d", programObject2D, "uView", false, view.array());
+
+ if (lineWidth > 0 && doStroke) {
+ // this will be replaced with the new bit shifting color code
+ uniformf("uColor2d", programObject2D, "uColor", strokeStyle);
+ uniformi("uIsDrawingText2d", programObject2D, "uIsDrawingText", false);
+ uniformi("uSmooth2d", programObject2D, "uSmooth", renderSmooth);
+ vertexAttribPointer("aVertex2d", programObject2D, "aVertex", 3, pointBuffer);
+ disableVertexAttribPointer("aTextureCoord2d", programObject2D, "aTextureCoord");
+ curContext.drawArrays(curContext.POINTS, 0, 1);
+ }
+ };
+
+ /**
+ * Using the <b>beginShape()</b> and <b>endShape()</b> functions allow creating more complex forms.
+ * <b>beginShape()</b> begins recording vertices for a shape and <b>endShape()</b> stops recording.
+ * The value of the <b>MODE</b> parameter tells it which types of shapes to create from the provided vertices.
+ * With no mode specified, the shape can be any irregular polygon. After calling the <b>beginShape()</b> function,
+ * a series of <b>vertex()</b> commands must follow. To stop drawing the shape, call <b>endShape()</b>.
+ * The <b>vertex()</b> function with two parameters specifies a position in 2D and the <b>vertex()</b>
+ * function with three parameters specifies a position in 3D. Each shape will be outlined with the current
+ * stroke color and filled with the fill color.
+ *
+ * @param {int} MODE either POINTS, LINES, TRIANGLES, TRIANGLE_FAN, TRIANGLE_STRIP, QUADS, and QUAD_STRIP.
+ *
+ * @see endShape
+ * @see vertex
+ * @see curveVertex
+ * @see bezierVertex
+ */
+ p.beginShape = function(type) {
+ curShape = type;
+ curvePoints = [];
+ vertArray = [];
+ };
+
+ /**
+ * All shapes are constructed by connecting a series of vertices. <b>vertex()</b> is used to specify the vertex
+ * coordinates for points, lines, triangles, quads, and polygons and is used exclusively within the <b>beginShape()</b>
+ * and <b>endShape()</b> function. <br /><br />Drawing a vertex in 3D using the <b>z</b> parameter requires the P3D or
+ * OPENGL parameter in combination with size as shown in the above example.<br /><br />This function is also used to map a
+ * texture onto the geometry. The <b>texture()</b> function declares the texture to apply to the geometry and the <b>u</b>
+ * and <b>v</b> coordinates set define the mapping of this texture to the form. By default, the coordinates used for
+ * <b>u</b> and <b>v</b> are specified in relation to the image's size in pixels, but this relation can be changed with
+ * <b>textureMode()</b>.
+ *
+ * @param {int | float} x x-coordinate of the vertex
+ * @param {int | float} y y-coordinate of the vertex
+ * @param {boolean} moveto flag to indicate whether this is a new subpath
+ *
+ * @see beginShape
+ * @see endShape
+ * @see bezierVertex
+ * @see curveVertex
+ * @see texture
+ */
+
+ Drawing2D.prototype.vertex = function(x, y, moveTo) {
+ var vert = [];
+
+ if (firstVert) { firstVert = false; }
+ vert.isVert = true;
+
+ vert[0] = x;
+ vert[1] = y;
+ vert[2] = 0;
+ vert[3] = 0;
+ vert[4] = 0;
+
+ // fill and stroke color
+ vert[5] = currentFillColor;
+ vert[6] = currentStrokeColor;
+
+ vertArray.push(vert);
+ if (moveTo) {
+ vertArray[vertArray.length-1].moveTo = moveTo;
+ }
+ };
+
+ Drawing3D.prototype.vertex = function(x, y, z, u, v) {
+ var vert = [];
+
+ if (firstVert) { firstVert = false; }
+ vert.isVert = true;
+
+ if (v === undef && usingTexture) {
+ v = u;
+ u = z;
+ z = 0;
+ }
+
+ // Convert u and v to normalized coordinates
+ if (u !== undef && v !== undef) {
+ if (curTextureMode === PConstants.IMAGE) {
+ u /= curTexture.width;
+ v /= curTexture.height;
+ }
+ u = u > 1 ? 1 : u;
+ u = u < 0 ? 0 : u;
+ v = v > 1 ? 1 : v;
+ v = v < 0 ? 0 : v;
+ }
+
+ vert[0] = x;
+ vert[1] = y;
+ vert[2] = z || 0;
+ vert[3] = u || 0;
+ vert[4] = v || 0;
+
+ // fill rgba
+ vert[5] = fillStyle[0];
+ vert[6] = fillStyle[1];
+ vert[7] = fillStyle[2];
+ vert[8] = fillStyle[3];
+ // stroke rgba
+ vert[9] = strokeStyle[0];
+ vert[10] = strokeStyle[1];
+ vert[11] = strokeStyle[2];
+ vert[12] = strokeStyle[3];
+ //normals
+ vert[13] = normalX;
+ vert[14] = normalY;
+ vert[15] = normalZ;
+
+ vertArray.push(vert);
+ };
+
+ /**
+ * @private
+ * Renders 3D points created from calls to vertex and beginShape/endShape
+ *
+ * @param {Array} vArray an array of vertex coordinate
+ * @param {Array} cArray an array of colours used for the vertices
+ *
+ * @see beginShape
+ * @see endShape
+ * @see vertex
+ */
+ var point3D = function(vArray, cArray){
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.transpose();
+
+ curContext.useProgram(programObjectUnlitShape);
+
+ uniformMatrix("uViewUS", programObjectUnlitShape, "uView", false, view.array());
+ uniformi("uSmoothUS", programObjectUnlitShape, "uSmooth", renderSmooth);
+
+ vertexAttribPointer("aVertexUS", programObjectUnlitShape, "aVertex", 3, pointBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array(vArray), curContext.STREAM_DRAW);
+
+ vertexAttribPointer("aColorUS", programObjectUnlitShape, "aColor", 4, fillColorBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array(cArray), curContext.STREAM_DRAW);
+
+ curContext.drawArrays(curContext.POINTS, 0, vArray.length/3);
+ };
+
+ /**
+ * @private
+ * Renders 3D lines created from calls to beginShape/vertex/endShape - based on the mode specified LINES, LINE_LOOP, etc.
+ *
+ * @param {Array} vArray an array of vertex coordinate
+ * @param {String} mode either LINES, LINE_LOOP, or LINE_STRIP
+ * @param {Array} cArray an array of colours used for the vertices
+ *
+ * @see beginShape
+ * @see endShape
+ * @see vertex
+ */
+ var line3D = function(vArray, mode, cArray){
+ var ctxMode;
+ if (mode === "LINES"){
+ ctxMode = curContext.LINES;
+ }
+ else if(mode === "LINE_LOOP"){
+ ctxMode = curContext.LINE_LOOP;
+ }
+ else{
+ ctxMode = curContext.LINE_STRIP;
+ }
+
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.transpose();
+
+ curContext.useProgram(programObjectUnlitShape);
+ uniformMatrix("uViewUS", programObjectUnlitShape, "uView", false, view.array());
+ vertexAttribPointer("aVertexUS", programObjectUnlitShape, "aVertex", 3, lineBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array(vArray), curContext.STREAM_DRAW);
+ vertexAttribPointer("aColorUS", programObjectUnlitShape, "aColor", 4, strokeColorBuffer);
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array(cArray), curContext.STREAM_DRAW);
+ curContext.drawArrays(ctxMode, 0, vArray.length/3);
+ };
+
+ /**
+ * @private
+ * Render filled shapes created from calls to beginShape/vertex/endShape - based on the mode specified TRIANGLES, etc.
+ *
+ * @param {Array} vArray an array of vertex coordinate
+ * @param {String} mode either LINES, LINE_LOOP, or LINE_STRIP
+ * @param {Array} cArray an array of colours used for the vertices
+ * @param {Array} tArray an array of u,v coordinates for textures
+ *
+ * @see beginShape
+ * @see endShape
+ * @see vertex
+ */
+ var fill3D = function(vArray, mode, cArray, tArray){
+ var ctxMode;
+ if (mode === "TRIANGLES") {
+ ctxMode = curContext.TRIANGLES;
+ } else if(mode === "TRIANGLE_FAN") {
+ ctxMode = curContext.TRIANGLE_FAN;
+ } else {
+ ctxMode = curContext.TRIANGLE_STRIP;
+ }
+
+ var view = new PMatrix3D();
+ view.scale( 1, -1, 1 );
+ view.apply( modelView.array() );
+ view.transpose();
+
+ curContext.useProgram( programObject3D );
+ uniformMatrix( "model3d", programObject3D, "uModel", false, [1,0,0,0, 0,1,0,0, 0,0,1,0, 0,0,0,1] );
+ uniformMatrix( "view3d", programObject3D, "uView", false, view.array() );
+ curContext.enable( curContext.POLYGON_OFFSET_FILL );
+ curContext.polygonOffset( 1, 1 );
+ uniformf( "color3d", programObject3D, "uColor", [-1,0,0,0] );
+ vertexAttribPointer( "vertex3d", programObject3D, "aVertex", 3, fillBuffer );
+ curContext.bufferData( curContext.ARRAY_BUFFER, new Float32Array(vArray), curContext.STREAM_DRAW );
+
+ // if we are using a texture and a tint, then overwrite the
+ // contents of the color buffer with the current tint
+ if ( usingTexture && curTint !== null ){
+ curTint3d( cArray );
+ }
+
+ vertexAttribPointer( "aColor3d", programObject3D, "aColor", 4, fillColorBuffer );
+ curContext.bufferData( curContext.ARRAY_BUFFER, new Float32Array(cArray), curContext.STREAM_DRAW );
+
+ // No support for lights....yet
+ disableVertexAttribPointer( "aNormal3d", programObject3D, "aNormal" );
+
+ if ( usingTexture ) {
+ uniformi( "uUsingTexture3d", programObject3D, "uUsingTexture", usingTexture );
+ vertexAttribPointer( "aTexture3d", programObject3D, "aTexture", 2, shapeTexVBO );
+ curContext.bufferData( curContext.ARRAY_BUFFER, new Float32Array(tArray), curContext.STREAM_DRAW );
+ }
+
+ curContext.drawArrays( ctxMode, 0, vArray.length/3 );
+ curContext.disable( curContext.POLYGON_OFFSET_FILL );
+ };
+
+ /**
+ * this series of three operations is used a lot in Drawing2D.prototype.endShape
+ * and has been split off as its own function, to tighten the code and allow for
+ * fewer bugs.
+ */
+ function fillStrokeClose() {
+ executeContextFill();
+ executeContextStroke();
+ curContext.closePath();
+ }
+
+ /**
+ * The endShape() function is the companion to beginShape() and may only be called after beginShape().
+ * When endshape() is called, all of image data defined since the previous call to beginShape() is written
+ * into the image buffer.
+ *
+ * @param {int} MODE Use CLOSE to close the shape
+ *
+ * @see beginShape
+ */
+ Drawing2D.prototype.endShape = function(mode) {
+ // Duplicated in Drawing3D; too many variables used
+ if (vertArray.length === 0) { return; }
+
+ var closeShape = mode === PConstants.CLOSE;
+
+ // if the shape is closed, the first element is also the last element
+ if (closeShape) {
+ vertArray.push(vertArray[0]);
+ }
+
+ var lineVertArray = [];
+ var fillVertArray = [];
+ var colorVertArray = [];
+ var strokeVertArray = [];
+ var texVertArray = [];
+ var cachedVertArray;
+
+ firstVert = true;
+ var i, j, k;
+ var vertArrayLength = vertArray.length;
+
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 0; j < 3; j++) {
+ fillVertArray.push(cachedVertArray[j]);
+ }
+ }
+
+ // 5,6,7,8
+ // R,G,B,A - fill colour
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 5; j < 9; j++) {
+ colorVertArray.push(cachedVertArray[j]);
+ }
+ }
+
+ // 9,10,11,12
+ // R, G, B, A - stroke colour
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(cachedVertArray[j]);
+ }
+ }
+
+ // texture u,v
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ texVertArray.push(cachedVertArray[3]);
+ texVertArray.push(cachedVertArray[4]);
+ }
+
+ // curveVertex
+ if ( isCurve && (curShape === PConstants.POLYGON || curShape === undef) ) {
+ if (vertArrayLength > 3) {
+ var b = [],
+ s = 1 - curTightness;
+ curContext.beginPath();
+ curContext.moveTo(vertArray[1][0], vertArray[1][1]);
+ /*
+ * Matrix to convert from Catmull-Rom to cubic Bezier
+ * where t = curTightness
+ * |0 1 0 0 |
+ * |(t-1)/6 1 (1-t)/6 0 |
+ * |0 (1-t)/6 1 (t-1)/6 |
+ * |0 0 0 0 |
+ */
+ for (i = 1; (i+2) < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ b[0] = [cachedVertArray[0], cachedVertArray[1]];
+ b[1] = [cachedVertArray[0] + (s * vertArray[i+1][0] - s * vertArray[i-1][0]) / 6,
+ cachedVertArray[1] + (s * vertArray[i+1][1] - s * vertArray[i-1][1]) / 6];
+ b[2] = [vertArray[i+1][0] + (s * vertArray[i][0] - s * vertArray[i+2][0]) / 6,
+ vertArray[i+1][1] + (s * vertArray[i][1] - s * vertArray[i+2][1]) / 6];
+ b[3] = [vertArray[i+1][0], vertArray[i+1][1]];
+ curContext.bezierCurveTo(b[1][0], b[1][1], b[2][0], b[2][1], b[3][0], b[3][1]);
+ }
+ fillStrokeClose();
+ }
+ }
+
+ // bezierVertex
+ else if ( isBezier && (curShape === PConstants.POLYGON || curShape === undef) ) {
+ curContext.beginPath();
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ if (vertArray[i].isVert) { //if it is a vertex move to the position
+ if (vertArray[i].moveTo) {
+ curContext.moveTo(cachedVertArray[0], cachedVertArray[1]);
+ } else {
+ curContext.lineTo(cachedVertArray[0], cachedVertArray[1]);
+ }
+ } else { //otherwise continue drawing bezier
+ curContext.bezierCurveTo(vertArray[i][0], vertArray[i][1], vertArray[i][2], vertArray[i][3], vertArray[i][4], vertArray[i][5]);
+ }
+ }
+ fillStrokeClose();
+ }
+
+ // render the vertices provided
+ else {
+ if (curShape === PConstants.POINTS) {
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ if (doStroke) {
+ p.stroke(cachedVertArray[6]);
+ }
+ p.point(cachedVertArray[0], cachedVertArray[1]);
+ }
+ } else if (curShape === PConstants.LINES) {
+ for (i = 0; (i + 1) < vertArrayLength; i+=2) {
+ cachedVertArray = vertArray[i];
+ if (doStroke) {
+ p.stroke(vertArray[i+1][6]);
+ }
+ p.line(cachedVertArray[0], cachedVertArray[1], vertArray[i+1][0], vertArray[i+1][1]);
+ }
+ } else if (curShape === PConstants.TRIANGLES) {
+ for (i = 0; (i + 2) < vertArrayLength; i+=3) {
+ cachedVertArray = vertArray[i];
+ curContext.beginPath();
+ curContext.moveTo(cachedVertArray[0], cachedVertArray[1]);
+ curContext.lineTo(vertArray[i+1][0], vertArray[i+1][1]);
+ curContext.lineTo(vertArray[i+2][0], vertArray[i+2][1]);
+ curContext.lineTo(cachedVertArray[0], cachedVertArray[1]);
+
+ if (doFill) {
+ p.fill(vertArray[i+2][5]);
+ executeContextFill();
+ }
+ if (doStroke) {
+ p.stroke(vertArray[i+2][6]);
+ executeContextStroke();
+ }
+
+ curContext.closePath();
+ }
+ } else if (curShape === PConstants.TRIANGLE_STRIP) {
+ for (i = 0; (i+1) < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ curContext.beginPath();
+ curContext.moveTo(vertArray[i+1][0], vertArray[i+1][1]);
+ curContext.lineTo(cachedVertArray[0], cachedVertArray[1]);
+
+ if (doStroke) {
+ p.stroke(vertArray[i+1][6]);
+ }
+ if (doFill) {
+ p.fill(vertArray[i+1][5]);
+ }
+
+ if (i + 2 < vertArrayLength) {
+ curContext.lineTo(vertArray[i+2][0], vertArray[i+2][1]);
+ if (doStroke) {
+ p.stroke(vertArray[i+2][6]);
+ }
+ if (doFill) {
+ p.fill(vertArray[i+2][5]);
+ }
+ }
+ fillStrokeClose();
+ }
+ } else if (curShape === PConstants.TRIANGLE_FAN) {
+ if (vertArrayLength > 2) {
+ curContext.beginPath();
+ curContext.moveTo(vertArray[0][0], vertArray[0][1]);
+ curContext.lineTo(vertArray[1][0], vertArray[1][1]);
+ curContext.lineTo(vertArray[2][0], vertArray[2][1]);
+
+ if (doFill) {
+ p.fill(vertArray[2][5]);
+ executeContextFill();
+ }
+ if (doStroke) {
+ p.stroke(vertArray[2][6]);
+ executeContextStroke();
+ }
+
+ curContext.closePath();
+ for (i = 3; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ curContext.beginPath();
+ curContext.moveTo(vertArray[0][0], vertArray[0][1]);
+ curContext.lineTo(vertArray[i-1][0], vertArray[i-1][1]);
+ curContext.lineTo(cachedVertArray[0], cachedVertArray[1]);
+
+ if (doFill) {
+ p.fill(cachedVertArray[5]);
+ executeContextFill();
+ }
+ if (doStroke) {
+ p.stroke(cachedVertArray[6]);
+ executeContextStroke();
+ }
+
+ curContext.closePath();
+ }
+ }
+ } else if (curShape === PConstants.QUADS) {
+ for (i = 0; (i + 3) < vertArrayLength; i+=4) {
+ cachedVertArray = vertArray[i];
+ curContext.beginPath();
+ curContext.moveTo(cachedVertArray[0], cachedVertArray[1]);
+ for (j = 1; j < 4; j++) {
+ curContext.lineTo(vertArray[i+j][0], vertArray[i+j][1]);
+ }
+ curContext.lineTo(cachedVertArray[0], cachedVertArray[1]);
+
+ if (doFill) {
+ p.fill(vertArray[i+3][5]);
+ executeContextFill();
+ }
+ if (doStroke) {
+ p.stroke(vertArray[i+3][6]);
+ executeContextStroke();
+ }
+
+ curContext.closePath();
+ }
+ } else if (curShape === PConstants.QUAD_STRIP) {
+ if (vertArrayLength > 3) {
+ for (i = 0; (i+1) < vertArrayLength; i+=2) {
+ cachedVertArray = vertArray[i];
+ curContext.beginPath();
+ if (i+3 < vertArrayLength) {
+ curContext.moveTo(vertArray[i+2][0], vertArray[i+2][1]);
+ curContext.lineTo(cachedVertArray[0], cachedVertArray[1]);
+ curContext.lineTo(vertArray[i+1][0], vertArray[i+1][1]);
+ curContext.lineTo(vertArray[i+3][0], vertArray[i+3][1]);
+
+ if (doFill) {
+ p.fill(vertArray[i+3][5]);
+ }
+ if (doStroke) {
+ p.stroke(vertArray[i+3][6]);
+ }
+ } else {
+ curContext.moveTo(cachedVertArray[0], cachedVertArray[1]);
+ curContext.lineTo(vertArray[i+1][0], vertArray[i+1][1]);
+ }
+ fillStrokeClose();
+ }
+ }
+ } else {
+ curContext.beginPath();
+ curContext.moveTo(vertArray[0][0], vertArray[0][1]);
+ for (i = 1; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ if (cachedVertArray.isVert) { //if it is a vertex move to the position
+ if (cachedVertArray.moveTo) {
+ curContext.moveTo(cachedVertArray[0], cachedVertArray[1]);
+ } else {
+ curContext.lineTo(cachedVertArray[0], cachedVertArray[1]);
+ }
+ }
+ }
+ fillStrokeClose();
+ }
+ }
+
+ // Reset some settings
+ isCurve = false;
+ isBezier = false;
+ curveVertArray = [];
+ curveVertCount = 0;
+
+ // If the shape is closed, the first element was added as last element.
+ // We must remove it again to prevent the list of vertices from growing
+ // over successive calls to endShape(CLOSE)
+ if (closeShape) {
+ vertArray.pop();
+ }
+ };
+
+ Drawing3D.prototype.endShape = function(mode) {
+ // Duplicated in Drawing3D; too many variables used
+ if (vertArray.length === 0) { return; }
+
+ var closeShape = mode === PConstants.CLOSE;
+ var lineVertArray = [];
+ var fillVertArray = [];
+ var colorVertArray = [];
+ var strokeVertArray = [];
+ var texVertArray = [];
+ var cachedVertArray;
+
+ firstVert = true;
+ var i, j, k;
+ var vertArrayLength = vertArray.length;
+
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 0; j < 3; j++) {
+ fillVertArray.push(cachedVertArray[j]);
+ }
+ }
+
+ // 5,6,7,8
+ // R,G,B,A - fill colour
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 5; j < 9; j++) {
+ colorVertArray.push(cachedVertArray[j]);
+ }
+ }
+
+ // 9,10,11,12
+ // R, G, B, A - stroke colour
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(cachedVertArray[j]);
+ }
+ }
+
+ // texture u,v
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ texVertArray.push(cachedVertArray[3]);
+ texVertArray.push(cachedVertArray[4]);
+ }
+
+ // if shape is closed, push the first point into the last point (including colours)
+ if (closeShape) {
+ fillVertArray.push(vertArray[0][0]);
+ fillVertArray.push(vertArray[0][1]);
+ fillVertArray.push(vertArray[0][2]);
+
+ for (i = 5; i < 9; i++) {
+ colorVertArray.push(vertArray[0][i]);
+ }
+
+ for (i = 9; i < 13; i++) {
+ strokeVertArray.push(vertArray[0][i]);
+ }
+
+ texVertArray.push(vertArray[0][3]);
+ texVertArray.push(vertArray[0][4]);
+ }
+ // End duplication
+
+ // curveVertex
+ if ( isCurve && (curShape === PConstants.POLYGON || curShape === undef) ) {
+ lineVertArray = fillVertArray;
+ if (doStroke) {
+ line3D(lineVertArray, null, strokeVertArray);
+ }
+ if (doFill) {
+ fill3D(fillVertArray, null, colorVertArray);
+ }
+ }
+ // bezierVertex
+ else if ( isBezier && (curShape === PConstants.POLYGON || curShape === undef) ) {
+ lineVertArray = fillVertArray;
+ lineVertArray.splice(lineVertArray.length - 3);
+ strokeVertArray.splice(strokeVertArray.length - 4);
+ if (doStroke) {
+ line3D(lineVertArray, null, strokeVertArray);
+ }
+ if (doFill) {
+ fill3D(fillVertArray, "TRIANGLES", colorVertArray);
+ }
+ }
+
+ // render the vertices provided
+ else {
+ if (curShape === PConstants.POINTS) { // if POINTS was the specified parameter in beginShape
+ for (i = 0; i < vertArrayLength; i++) { // loop through and push the point location information to the array
+ cachedVertArray = vertArray[i];
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(cachedVertArray[j]);
+ }
+ }
+ point3D(lineVertArray, strokeVertArray); // render function for points
+ } else if (curShape === PConstants.LINES) { // if LINES was the specified parameter in beginShape
+ for (i = 0; i < vertArrayLength; i++) { // loop through and push the point location information to the array
+ cachedVertArray = vertArray[i];
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(cachedVertArray[j]);
+ }
+ }
+ for (i = 0; i < vertArrayLength; i++) { // loop through and push the color information to the array
+ cachedVertArray = vertArray[i];
+ for (j = 5; j < 9; j++) {
+ colorVertArray.push(cachedVertArray[j]);
+ }
+ }
+ line3D(lineVertArray, "LINES", strokeVertArray); // render function for lines
+ } else if (curShape === PConstants.TRIANGLES) { // if TRIANGLES was the specified parameter in beginShape
+ if (vertArrayLength > 2) {
+ for (i = 0; (i+2) < vertArrayLength; i+=3) { // loop through the array per triangle
+ fillVertArray = [];
+ texVertArray = [];
+ lineVertArray = [];
+ colorVertArray = [];
+ strokeVertArray = [];
+ for (j = 0; j < 3; j++) {
+ for (k = 0; k < 3; k++) { // loop through and push
+ lineVertArray.push(vertArray[i+j][k]); // the line point location information
+ fillVertArray.push(vertArray[i+j][k]); // and fill point location information
+ }
+ }
+ for (j = 0; j < 3; j++) { // loop through and push the texture information
+ for (k = 3; k < 5; k++) {
+ texVertArray.push(vertArray[i+j][k]);
+ }
+ }
+ for (j = 0; j < 3; j++) {
+ for (k = 5; k < 9; k++) { // loop through and push
+ colorVertArray.push(vertArray[i+j][k]); // the colour information
+ strokeVertArray.push(vertArray[i+j][k+4]);// and the stroke information
+ }
+ }
+ if (doStroke) {
+ line3D(lineVertArray, "LINE_LOOP", strokeVertArray ); // line render function
+ }
+ if (doFill || usingTexture) {
+ fill3D(fillVertArray, "TRIANGLES", colorVertArray, texVertArray); // fill shape render function
+ }
+ }
+ }
+ } else if (curShape === PConstants.TRIANGLE_STRIP) { // if TRIANGLE_STRIP was the specified parameter in beginShape
+ if (vertArrayLength > 2) {
+ for (i = 0; (i+2) < vertArrayLength; i++) {
+ lineVertArray = [];
+ fillVertArray = [];
+ strokeVertArray = [];
+ colorVertArray = [];
+ texVertArray = [];
+ for (j = 0; j < 3; j++) {
+ for (k = 0; k < 3; k++) {
+ lineVertArray.push(vertArray[i+j][k]);
+ fillVertArray.push(vertArray[i+j][k]);
+ }
+ }
+ for (j = 0; j < 3; j++) {
+ for (k = 3; k < 5; k++) {
+ texVertArray.push(vertArray[i+j][k]);
+ }
+ }
+ for (j = 0; j < 3; j++) {
+ for (k = 5; k < 9; k++) {
+ strokeVertArray.push(vertArray[i+j][k+4]);
+ colorVertArray.push(vertArray[i+j][k]);
+ }
+ }
+
+ if (doFill || usingTexture) {
+ fill3D(fillVertArray, "TRIANGLE_STRIP", colorVertArray, texVertArray);
+ }
+ if (doStroke) {
+ line3D(lineVertArray, "LINE_LOOP", strokeVertArray);
+ }
+ }
+ }
+ } else if (curShape === PConstants.TRIANGLE_FAN) {
+ if (vertArrayLength > 2) {
+ for (i = 0; i < 3; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(cachedVertArray[j]);
+ }
+ }
+ for (i = 0; i < 3; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(cachedVertArray[j]);
+ }
+ }
+ if (doStroke) {
+ line3D(lineVertArray, "LINE_LOOP", strokeVertArray);
+ }
+
+ for (i = 2; (i+1) < vertArrayLength; i++) {
+ lineVertArray = [];
+ strokeVertArray = [];
+ lineVertArray.push(vertArray[0][0]);
+ lineVertArray.push(vertArray[0][1]);
+ lineVertArray.push(vertArray[0][2]);
+
+ strokeVertArray.push(vertArray[0][9]);
+ strokeVertArray.push(vertArray[0][10]);
+ strokeVertArray.push(vertArray[0][11]);
+ strokeVertArray.push(vertArray[0][12]);
+
+ for (j = 0; j < 2; j++) {
+ for (k = 0; k < 3; k++) {
+ lineVertArray.push(vertArray[i+j][k]);
+ }
+ }
+ for (j = 0; j < 2; j++) {
+ for (k = 9; k < 13; k++) {
+ strokeVertArray.push(vertArray[i+j][k]);
+ }
+ }
+ if (doStroke) {
+ line3D(lineVertArray, "LINE_STRIP",strokeVertArray);
+ }
+ }
+ if (doFill || usingTexture) {
+ fill3D(fillVertArray, "TRIANGLE_FAN", colorVertArray, texVertArray);
+ }
+ }
+ } else if (curShape === PConstants.QUADS) {
+ for (i = 0; (i + 3) < vertArrayLength; i+=4) {
+ lineVertArray = [];
+ for (j = 0; j < 4; j++) {
+ cachedVertArray = vertArray[i+j];
+ for (k = 0; k < 3; k++) {
+ lineVertArray.push(cachedVertArray[k]);
+ }
+ }
+ if (doStroke) {
+ line3D(lineVertArray, "LINE_LOOP",strokeVertArray);
+ }
+
+ if (doFill) {
+ fillVertArray = [];
+ colorVertArray = [];
+ texVertArray = [];
+ for (j = 0; j < 3; j++) {
+ fillVertArray.push(vertArray[i][j]);
+ }
+ for (j = 5; j < 9; j++) {
+ colorVertArray.push(vertArray[i][j]);
+ }
+
+ for (j = 0; j < 3; j++) {
+ fillVertArray.push(vertArray[i+1][j]);
+ }
+ for (j = 5; j < 9; j++) {
+ colorVertArray.push(vertArray[i+1][j]);
+ }
+
+ for (j = 0; j < 3; j++) {
+ fillVertArray.push(vertArray[i+3][j]);
+ }
+ for (j = 5; j < 9; j++) {
+ colorVertArray.push(vertArray[i+3][j]);
+ }
+
+ for (j = 0; j < 3; j++) {
+ fillVertArray.push(vertArray[i+2][j]);
+ }
+ for (j = 5; j < 9; j++) {
+ colorVertArray.push(vertArray[i+2][j]);
+ }
+
+ if (usingTexture) {
+ texVertArray.push(vertArray[i+0][3]);
+ texVertArray.push(vertArray[i+0][4]);
+ texVertArray.push(vertArray[i+1][3]);
+ texVertArray.push(vertArray[i+1][4]);
+ texVertArray.push(vertArray[i+3][3]);
+ texVertArray.push(vertArray[i+3][4]);
+ texVertArray.push(vertArray[i+2][3]);
+ texVertArray.push(vertArray[i+2][4]);
+ }
+
+ fill3D(fillVertArray, "TRIANGLE_STRIP", colorVertArray, texVertArray);
+ }
+ }
+ } else if (curShape === PConstants.QUAD_STRIP) {
+ var tempArray = [];
+ if (vertArrayLength > 3) {
+ for (i = 0; i < 2; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(cachedVertArray[j]);
+ }
+ }
+
+ for (i = 0; i < 2; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(cachedVertArray[j]);
+ }
+ }
+
+ line3D(lineVertArray, "LINE_STRIP", strokeVertArray);
+ if (vertArrayLength > 4 && vertArrayLength % 2 > 0) {
+ tempArray = fillVertArray.splice(fillVertArray.length - 3);
+ vertArray.pop();
+ }
+ for (i = 0; (i+3) < vertArrayLength; i+=2) {
+ lineVertArray = [];
+ strokeVertArray = [];
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(vertArray[i+1][j]);
+ }
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(vertArray[i+3][j]);
+ }
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(vertArray[i+2][j]);
+ }
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(vertArray[i+0][j]);
+ }
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(vertArray[i+1][j]);
+ }
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(vertArray[i+3][j]);
+ }
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(vertArray[i+2][j]);
+ }
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(vertArray[i+0][j]);
+ }
+ if (doStroke) {
+ line3D(lineVertArray, "LINE_STRIP", strokeVertArray);
+ }
+ }
+
+ if (doFill || usingTexture) {
+ fill3D(fillVertArray, "TRIANGLE_LIST", colorVertArray, texVertArray);
+ }
+ }
+ }
+ // If the user didn't specify a type (LINES, TRIANGLES, etc)
+ else {
+ // If only one vertex was specified, it must be a point
+ if (vertArrayLength === 1) {
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(vertArray[0][j]);
+ }
+ for (j = 9; j < 13; j++) {
+ strokeVertArray.push(vertArray[0][j]);
+ }
+ point3D(lineVertArray,strokeVertArray);
+ } else {
+ for (i = 0; i < vertArrayLength; i++) {
+ cachedVertArray = vertArray[i];
+ for (j = 0; j < 3; j++) {
+ lineVertArray.push(cachedVertArray[j]);
+ }
+ for (j = 5; j < 9; j++) {
+ strokeVertArray.push(cachedVertArray[j]);
+ }
+ }
+ if (doStroke && closeShape) {
+ line3D(lineVertArray, "LINE_LOOP", strokeVertArray);
+ } else if (doStroke && !closeShape) {
+ line3D(lineVertArray, "LINE_STRIP", strokeVertArray);
+ }
+
+ // fill is ignored if textures are used
+ if (doFill || usingTexture) {
+ fill3D(fillVertArray, "TRIANGLE_FAN", colorVertArray, texVertArray);
+ }
+ }
+ }
+ // everytime beginShape is followed by a call to
+ // texture(), texturing it turned back on. We do this to
+ // figure out if the shape should be textured or filled
+ // with a color.
+ usingTexture = false;
+ curContext.useProgram(programObject3D);
+ uniformi("usingTexture3d", programObject3D, "uUsingTexture", usingTexture);
+ }
+
+ // Reset some settings
+ isCurve = false;
+ isBezier = false;
+ curveVertArray = [];
+ curveVertCount = 0;
+ };
+
+ /**
+ * The function splineForward() setup forward-differencing matrix to be used for speedy
+ * curve rendering. It's based on using a specific number
+ * of curve segments and just doing incremental adds for each
+ * vertex of the segment, rather than running the mathematically
+ * expensive cubic equation. This function is used by both curveDetail and bezierDetail.
+ *
+ * @param {int} segments number of curve segments to use when drawing
+ * @param {PMatrix3D} matrix target object for the new matrix
+ */
+ var splineForward = function(segments, matrix) {
+ var f = 1.0 / segments;
+ var ff = f * f;
+ var fff = ff * f;
+
+ matrix.set(0, 0, 0, 1, fff, ff, f, 0, 6 * fff, 2 * ff, 0, 0, 6 * fff, 0, 0, 0);
+ };
+
+ /**
+ * The curveInit() function set the number of segments to use when drawing a Catmull-Rom
+ * curve, and setting the s parameter, which defines how tightly
+ * the curve fits to each vertex. Catmull-Rom curves are actually
+ * a subset of this curve type where the s is set to zero.
+ * This in an internal function used by curveDetail() and curveTightness().
+ */
+ var curveInit = function() {
+ // allocate only if/when used to save startup time
+ if (!curveDrawMatrix) {
+ curveBasisMatrix = new PMatrix3D();
+ curveDrawMatrix = new PMatrix3D();
+ curveInited = true;
+ }
+
+ var s = curTightness;
+ curveBasisMatrix.set((s - 1) / 2, (s + 3) / 2, (-3 - s) / 2, (1 - s) / 2,
+ (1 - s), (-5 - s) / 2, (s + 2), (s - 1) / 2,
+ (s - 1) / 2, 0, (1 - s) / 2, 0, 0, 1, 0, 0);
+
+ splineForward(curveDet, curveDrawMatrix);
+
+ if (!bezierBasisInverse) {
+ //bezierBasisInverse = bezierBasisMatrix.get();
+ //bezierBasisInverse.invert();
+ curveToBezierMatrix = new PMatrix3D();
+ }
+
+ // TODO only needed for PGraphicsJava2D? if so, move it there
+ // actually, it's generally useful for other renderers, so keep it
+ // or hide the implementation elsewhere.
+ curveToBezierMatrix.set(curveBasisMatrix);
+ curveToBezierMatrix.preApply(bezierBasisInverse);
+
+ // multiply the basis and forward diff matrices together
+ // saves much time since this needn't be done for each curve
+ curveDrawMatrix.apply(curveBasisMatrix);
+ };
+
+ /**
+ * Specifies vertex coordinates for Bezier curves. Each call to <b>bezierVertex()</b> defines the position of two control
+ * points and one anchor point of a Bezier curve, adding a new segment to a line or shape. The first time
+ * <b>bezierVertex()</b> is used within a <b>beginShape()</b> call, it must be prefaced with a call to <b>vertex()</b>
+ * to set the first anchor point. This function must be used between <b>beginShape()</b> and <b>endShape()</b> and only
+ * when there is no MODE parameter specified to <b>beginShape()</b>. Using the 3D version of requires rendering with P3D
+ * or OPENGL (see the Environment reference for more information). <br /> <br /> <b>NOTE: </b> Fill does not work properly yet.
+ *
+ * @param {float | int} cx1 The x-coordinate of 1st control point
+ * @param {float | int} cy1 The y-coordinate of 1st control point
+ * @param {float | int} cz1 The z-coordinate of 1st control point
+ * @param {float | int} cx2 The x-coordinate of 2nd control point
+ * @param {float | int} cy2 The y-coordinate of 2nd control point
+ * @param {float | int} cz2 The z-coordinate of 2nd control point
+ * @param {float | int} x The x-coordinate of the anchor point
+ * @param {float | int} y The y-coordinate of the anchor point
+ * @param {float | int} z The z-coordinate of the anchor point
+ *
+ * @see curveVertex
+ * @see vertex
+ * @see bezier
+ */
+ Drawing2D.prototype.bezierVertex = function() {
+ isBezier = true;
+ var vert = [];
+ if (firstVert) {
+ throw ("vertex() must be used at least once before calling bezierVertex()");
+ }
+
+ for (var i = 0; i < arguments.length; i++) {
+ vert[i] = arguments[i];
+ }
+ vertArray.push(vert);
+ vertArray[vertArray.length -1].isVert = false;
+ };
+
+ Drawing3D.prototype.bezierVertex = function() {
+ isBezier = true;
+ var vert = [];
+ if (firstVert) {
+ throw ("vertex() must be used at least once before calling bezierVertex()");
+ }
+
+ if (arguments.length === 9) {
+ if (bezierDrawMatrix === undef) {
+ bezierDrawMatrix = new PMatrix3D();
+ }
+ // setup matrix for forward differencing to speed up drawing
+ var lastPoint = vertArray.length - 1;
+ splineForward( bezDetail, bezierDrawMatrix );
+ bezierDrawMatrix.apply( bezierBasisMatrix );
+ var draw = bezierDrawMatrix.array();
+ var x1 = vertArray[lastPoint][0],
+ y1 = vertArray[lastPoint][1],
+ z1 = vertArray[lastPoint][2];
+ var xplot1 = draw[4] * x1 + draw[5] * arguments[0] + draw[6] * arguments[3] + draw[7] * arguments[6];
+ var xplot2 = draw[8] * x1 + draw[9] * arguments[0] + draw[10]* arguments[3] + draw[11]* arguments[6];
+ var xplot3 = draw[12]* x1 + draw[13]* arguments[0] + draw[14]* arguments[3] + draw[15]* arguments[6];
+
+ var yplot1 = draw[4] * y1 + draw[5] * arguments[1] + draw[6] * arguments[4] + draw[7] * arguments[7];
+ var yplot2 = draw[8] * y1 + draw[9] * arguments[1] + draw[10]* arguments[4] + draw[11]* arguments[7];
+ var yplot3 = draw[12]* y1 + draw[13]* arguments[1] + draw[14]* arguments[4] + draw[15]* arguments[7];
+
+ var zplot1 = draw[4] * z1 + draw[5] * arguments[2] + draw[6] * arguments[5] + draw[7] * arguments[8];
+ var zplot2 = draw[8] * z1 + draw[9] * arguments[2] + draw[10]* arguments[5] + draw[11]* arguments[8];
+ var zplot3 = draw[12]* z1 + draw[13]* arguments[2] + draw[14]* arguments[5] + draw[15]* arguments[8];
+ for (var j = 0; j < bezDetail; j++) {
+ x1 += xplot1; xplot1 += xplot2; xplot2 += xplot3;
+ y1 += yplot1; yplot1 += yplot2; yplot2 += yplot3;
+ z1 += zplot1; zplot1 += zplot2; zplot2 += zplot3;
+ p.vertex(x1, y1, z1);
+ }
+ p.vertex(arguments[6], arguments[7], arguments[8]);
+ }
+ };
+
+ /**
+ * Sets a texture to be applied to vertex points. The <b>texture()</b> function
+ * must be called between <b>beginShape()</b> and <b>endShape()</b> and before
+ * any calls to vertex().
+ *
+ * When textures are in use, the fill color is ignored. Instead, use tint() to
+ * specify the color of the texture as it is applied to the shape.
+ *
+ * @param {PImage} pimage the texture to apply
+ *
+ * @returns none
+ *
+ * @see textureMode
+ * @see beginShape
+ * @see endShape
+ * @see vertex
+ */
+ p.texture = function(pimage) {
+ var curContext = drawing.$ensureContext();
+
+ if (pimage.__texture) {
+ curContext.bindTexture(curContext.TEXTURE_2D, pimage.__texture);
+ } else if (pimage.localName === "canvas") {
+ curContext.bindTexture(curContext.TEXTURE_2D, canTex);
+ curContext.texImage2D(curContext.TEXTURE_2D, 0, curContext.RGBA, curContext.RGBA, curContext.UNSIGNED_BYTE, pimage);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_MAG_FILTER, curContext.LINEAR);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_MIN_FILTER, curContext.LINEAR);
+ curContext.generateMipmap(curContext.TEXTURE_2D);
+ curTexture.width = pimage.width;
+ curTexture.height = pimage.height;
+ } else {
+ var texture = curContext.createTexture(),
+ cvs = document.createElement('canvas'),
+ cvsTextureCtx = cvs.getContext('2d'),
+ pot;
+
+ // WebGL requires power of two textures
+ if (pimage.width & (pimage.width-1) === 0) {
+ cvs.width = pimage.width;
+ } else {
+ pot = 1;
+ while (pot < pimage.width) {
+ pot *= 2;
+ }
+ cvs.width = pot;
+ }
+
+ if (pimage.height & (pimage.height-1) === 0) {
+ cvs.height = pimage.height;
+ } else {
+ pot = 1;
+ while (pot < pimage.height) {
+ pot *= 2;
+ }
+ cvs.height = pot;
+ }
+
+ cvsTextureCtx.drawImage(pimage.sourceImg, 0, 0, pimage.width, pimage.height, 0, 0, cvs.width, cvs.height);
+
+ curContext.bindTexture(curContext.TEXTURE_2D, texture);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_MIN_FILTER, curContext.LINEAR_MIPMAP_LINEAR);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_MAG_FILTER, curContext.LINEAR);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_WRAP_T, curContext.CLAMP_TO_EDGE);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_WRAP_S, curContext.CLAMP_TO_EDGE);
+ curContext.texImage2D(curContext.TEXTURE_2D, 0, curContext.RGBA, curContext.RGBA, curContext.UNSIGNED_BYTE, cvs);
+ curContext.generateMipmap(curContext.TEXTURE_2D);
+
+ pimage.__texture = texture;
+ curTexture.width = pimage.width;
+ curTexture.height = pimage.height;
+ }
+
+ usingTexture = true;
+ curContext.useProgram(programObject3D);
+ uniformi("usingTexture3d", programObject3D, "uUsingTexture", usingTexture);
+ };
+
+ /**
+ * Sets the coordinate space for texture mapping. There are two options, IMAGE,
+ * which refers to the actual coordinates of the image, and NORMALIZED, which
+ * refers to a normalized space of values ranging from 0 to 1. The default mode
+ * is IMAGE. In IMAGE, if an image is 100 x 200 pixels, mapping the image onto
+ * the entire size of a quad would require the points (0,0) (0,100) (100,200) (0,200).
+ * The same mapping in NORMAL_SPACE is (0,0) (0,1) (1,1) (0,1).
+ *
+ * @param MODE either IMAGE or NORMALIZED
+ *
+ * @returns none
+ *
+ * @see texture
+ */
+ p.textureMode = function(mode){
+ curTextureMode = mode;
+ };
+ /**
+ * The curveVertexSegment() function handle emitting a specific segment of Catmull-Rom curve. Internal helper function used by <b>curveVertex()</b>.
+ */
+ var curveVertexSegment = function(x1, y1, z1, x2, y2, z2, x3, y3, z3, x4, y4, z4) {
+ var x0 = x2;
+ var y0 = y2;
+ var z0 = z2;
+
+ var draw = curveDrawMatrix.array();
+
+ var xplot1 = draw[4] * x1 + draw[5] * x2 + draw[6] * x3 + draw[7] * x4;
+ var xplot2 = draw[8] * x1 + draw[9] * x2 + draw[10] * x3 + draw[11] * x4;
+ var xplot3 = draw[12] * x1 + draw[13] * x2 + draw[14] * x3 + draw[15] * x4;
+
+ var yplot1 = draw[4] * y1 + draw[5] * y2 + draw[6] * y3 + draw[7] * y4;
+ var yplot2 = draw[8] * y1 + draw[9] * y2 + draw[10] * y3 + draw[11] * y4;
+ var yplot3 = draw[12] * y1 + draw[13] * y2 + draw[14] * y3 + draw[15] * y4;
+
+ var zplot1 = draw[4] * z1 + draw[5] * z2 + draw[6] * z3 + draw[7] * z4;
+ var zplot2 = draw[8] * z1 + draw[9] * z2 + draw[10] * z3 + draw[11] * z4;
+ var zplot3 = draw[12] * z1 + draw[13] * z2 + draw[14] * z3 + draw[15] * z4;
+
+ p.vertex(x0, y0, z0);
+ for (var j = 0; j < curveDet; j++) {
+ x0 += xplot1; xplot1 += xplot2; xplot2 += xplot3;
+ y0 += yplot1; yplot1 += yplot2; yplot2 += yplot3;
+ z0 += zplot1; zplot1 += zplot2; zplot2 += zplot3;
+ p.vertex(x0, y0, z0);
+ }
+ };
+
+ /**
+ * Specifies vertex coordinates for curves. This function may only be used between <b>beginShape()</b> and
+ * <b>endShape()</b> and only when there is no MODE parameter specified to <b>beginShape()</b>. The first and last points
+ * in a series of <b>curveVertex()</b> lines will be used to guide the beginning and end of a the curve. A minimum of four
+ * points is required to draw a tiny curve between the second and third points. Adding a fifth point with
+ * <b>curveVertex()</b> will draw the curve between the second, third, and fourth points. The <b>curveVertex()</b> function
+ * is an implementation of Catmull-Rom splines. Using the 3D version of requires rendering with P3D or OPENGL (see the
+ * Environment reference for more information). <br /> <br /><b>NOTE: </b> Fill does not work properly yet.
+ *
+ * @param {float | int} x The x-coordinate of the vertex
+ * @param {float | int} y The y-coordinate of the vertex
+ * @param {float | int} z The z-coordinate of the vertex
+ *
+ * @see curve
+ * @see beginShape
+ * @see endShape
+ * @see vertex
+ * @see bezierVertex
+ */
+ Drawing2D.prototype.curveVertex = function(x, y) {
+ isCurve = true;
+
+ p.vertex(x, y);
+ };
+
+ Drawing3D.prototype.curveVertex = function(x, y, z) {
+ isCurve = true;
+
+ if (!curveInited) {
+ curveInit();
+ }
+ var vert = [];
+ vert[0] = x;
+ vert[1] = y;
+ vert[2] = z;
+ curveVertArray.push(vert);
+ curveVertCount++;
+
+ if (curveVertCount > 3) {
+ curveVertexSegment( curveVertArray[curveVertCount-4][0],
+ curveVertArray[curveVertCount-4][1],
+ curveVertArray[curveVertCount-4][2],
+ curveVertArray[curveVertCount-3][0],
+ curveVertArray[curveVertCount-3][1],
+ curveVertArray[curveVertCount-3][2],
+ curveVertArray[curveVertCount-2][0],
+ curveVertArray[curveVertCount-2][1],
+ curveVertArray[curveVertCount-2][2],
+ curveVertArray[curveVertCount-1][0],
+ curveVertArray[curveVertCount-1][1],
+ curveVertArray[curveVertCount-1][2] );
+ }
+ };
+
+ /**
+ * The curve() function draws a curved line on the screen. The first and second parameters
+ * specify the beginning control point and the last two parameters specify
+ * the ending control point. The middle parameters specify the start and
+ * stop of the curve. Longer curves can be created by putting a series of
+ * <b>curve()</b> functions together or using <b>curveVertex()</b>.
+ * An additional function called <b>curveTightness()</b> provides control
+ * for the visual quality of the curve. The <b>curve()</b> function is an
+ * implementation of Catmull-Rom splines. Using the 3D version of requires
+ * rendering with P3D or OPENGL (see the Environment reference for more
+ * information).
+ *
+ * @param {int|float} x1 coordinates for the beginning control point
+ * @param {int|float} y1 coordinates for the beginning control point
+ * @param {int|float} z1 coordinates for the beginning control point
+ * @param {int|float} x2 coordinates for the first point
+ * @param {int|float} y2 coordinates for the first point
+ * @param {int|float} z2 coordinates for the first point
+ * @param {int|float} x3 coordinates for the second point
+ * @param {int|float} y3 coordinates for the second point
+ * @param {int|float} z3 coordinates for the second point
+ * @param {int|float} x4 coordinates for the ending control point
+ * @param {int|float} y4 coordinates for the ending control point
+ * @param {int|float} z4 coordinates for the ending control point
+ *
+ * @see #curveVertex()
+ * @see #curveTightness()
+ * @see #bezier()
+ */
+ Drawing2D.prototype.curve = function(x1, y1, x2, y2, x3, y3, x4, y4) {
+ p.beginShape();
+ p.curveVertex(x1, y1);
+ p.curveVertex(x2, y2);
+ p.curveVertex(x3, y3);
+ p.curveVertex(x4, y4);
+ p.endShape();
+ };
+
+ Drawing3D.prototype.curve = function(x1, y1, z1, x2, y2, z2, x3, y3, z3, x4, y4, z4) {
+ if (z4 !== undef) {
+ p.beginShape();
+ p.curveVertex(x1, y1, z1);
+ p.curveVertex(x2, y2, z2);
+ p.curveVertex(x3, y3, z3);
+ p.curveVertex(x4, y4, z4);
+ p.endShape();
+ return;
+ }
+ p.beginShape();
+ p.curveVertex(x1, y1);
+ p.curveVertex(z1, x2);
+ p.curveVertex(y2, z2);
+ p.curveVertex(x3, y3);
+ p.endShape();
+ };
+
+ /**
+ * The curveTightness() function modifies the quality of forms created with <b>curve()</b> and
+ * <b>curveVertex()</b>. The parameter <b>squishy</b> determines how the
+ * curve fits to the vertex points. The value 0.0 is the default value for
+ * <b>squishy</b> (this value defines the curves to be Catmull-Rom splines)
+ * and the value 1.0 connects all the points with straight lines.
+ * Values within the range -5.0 and 5.0 will deform the curves but
+ * will leave them recognizable and as values increase in magnitude,
+ * they will continue to deform.
+ *
+ * @param {float} tightness amount of deformation from the original vertices
+ *
+ * @see #curve()
+ * @see #curveVertex()
+ *
+ */
+ p.curveTightness = function(tightness) {
+ curTightness = tightness;
+ };
+
+ /**
+ * The curveDetail() function sets the resolution at which curves display. The default value is 20.
+ * This function is only useful when using the P3D or OPENGL renderer.
+ *
+ * @param {int} detail resolution of the curves
+ *
+ * @see curve()
+ * @see curveVertex()
+ * @see curveTightness()
+ */
+ p.curveDetail = function(detail) {
+ curveDet = detail;
+ curveInit();
+ };
+
+ /**
+ * Modifies the location from which rectangles draw. The default mode is rectMode(CORNER), which
+ * specifies the location to be the upper left corner of the shape and uses the third and fourth
+ * parameters of rect() to specify the width and height. The syntax rectMode(CORNERS) uses the
+ * first and second parameters of rect() to set the location of one corner and uses the third and
+ * fourth parameters to set the opposite corner. The syntax rectMode(CENTER) draws the image from
+ * its center point and uses the third and forth parameters of rect() to specify the image's width
+ * and height. The syntax rectMode(RADIUS) draws the image from its center point and uses the third
+ * and forth parameters of rect() to specify half of the image's width and height. The parameter must
+ * be written in ALL CAPS because Processing is a case sensitive language. Note: In version 125, the
+ * mode named CENTER_RADIUS was shortened to RADIUS.
+ *
+ * @param {MODE} MODE Either CORNER, CORNERS, CENTER, or RADIUS
+ *
+ * @see rect
+ */
+ p.rectMode = function(aRectMode) {
+ curRectMode = aRectMode;
+ };
+
+ /**
+ * Modifies the location from which images draw. The default mode is imageMode(CORNER), which specifies
+ * the location to be the upper left corner and uses the fourth and fifth parameters of image() to set
+ * the image's width and height. The syntax imageMode(CORNERS) uses the second and third parameters of
+ * image() to set the location of one corner of the image and uses the fourth and fifth parameters to
+ * set the opposite corner. Use imageMode(CENTER) to draw images centered at the given x and y position.
+ * The parameter to imageMode() must be written in ALL CAPS because Processing is a case sensitive language.
+ *
+ * @param {MODE} MODE Either CORNER, CORNERS, or CENTER
+ *
+ * @see loadImage
+ * @see PImage
+ * @see image
+ * @see background
+ */
+ p.imageMode = function(mode) {
+ switch (mode) {
+ case PConstants.CORNER:
+ imageModeConvert = imageModeCorner;
+ break;
+ case PConstants.CORNERS:
+ imageModeConvert = imageModeCorners;
+ break;
+ case PConstants.CENTER:
+ imageModeConvert = imageModeCenter;
+ break;
+ default:
+ throw "Invalid imageMode";
+ }
+ };
+
+ /**
+ * The origin of the ellipse is modified by the ellipseMode() function. The default configuration is
+ * ellipseMode(CENTER), which specifies the location of the ellipse as the center of the shape. The RADIUS
+ * mode is the same, but the width and height parameters to ellipse() specify the radius of the ellipse,
+ * rather than the diameter. The CORNER mode draws the shape from the upper-left corner of its bounding box.
+ * The CORNERS mode uses the four parameters to ellipse() to set two opposing corners of the ellipse's bounding
+ * box. The parameter must be written in "ALL CAPS" because Processing is a case sensitive language.
+ *
+ * @param {MODE} MODE Either CENTER, RADIUS, CORNER, or CORNERS.
+ *
+ * @see ellipse
+ */
+ p.ellipseMode = function(aEllipseMode) {
+ curEllipseMode = aEllipseMode;
+ };
+
+ /**
+ * The arc() function draws an arc in the display window.
+ * Arcs are drawn along the outer edge of an ellipse defined by the
+ * <b>x</b>, <b>y</b>, <b>width</b> and <b>height</b> parameters.
+ * The origin or the arc's ellipse may be changed with the
+ * <b>ellipseMode()</b> function.
+ * The <b>start</b> and <b>stop</b> parameters specify the angles
+ * at which to draw the arc.
+ *
+ * @param {float} a x-coordinate of the arc's ellipse
+ * @param {float} b y-coordinate of the arc's ellipse
+ * @param {float} c width of the arc's ellipse
+ * @param {float} d height of the arc's ellipse
+ * @param {float} start angle to start the arc, specified in radians
+ * @param {float} stop angle to stop the arc, specified in radians
+ * @param {enum} mode drawing mode (OPEN, CHORD, PIE)
+ *
+ * @see #ellipseMode()
+ * @see #ellipse()
+ */
+ p.arc = function(x, y, width, height, start, stop, mode) {
+ if (width <= 0 || stop < start) { return; }
+
+ if (curEllipseMode === PConstants.CORNERS) {
+ width = width - x;
+ height = height - y;
+ } else if (curEllipseMode === PConstants.RADIUS) {
+ x = x - width;
+ y = y - height;
+ width = width * 2;
+ height = height * 2;
+ } else if (curEllipseMode === PConstants.CENTER) {
+ x = x - width/2;
+ y = y - height/2;
+ }
+ // make sure that we're starting at a useful point
+ while (start < 0) {
+ start += PConstants.TWO_PI;
+ stop += PConstants.TWO_PI;
+ }
+ if (stop - start > PConstants.TWO_PI) {
+ // don't change start, it is visible in PIE mode
+ stop = start + PConstants.TWO_PI;
+ }
+ var hr = width / 2,
+ vr = height / 2,
+ centerX = x + hr,
+ centerY = y + vr,
+ step = 1/(hr+vr);
+
+ var drawSlice = (function(x, y, start, step, stop) {
+ return function(p, closed, i, a, e) {
+ i = 0;
+ a = start;
+ e = stop + step;
+ p.beginShape();
+ if(closed) { p.vertex(x-0.5, y-0.5); }
+ for (; a < e; i++, a = i*step + start) {
+ p.vertex(
+ (x + Math.cos(a) * hr)|0,
+ (y + Math.sin(a) * vr)|0
+ );
+ }
+
+ if (mode === PConstants.OPEN && doFill) {
+ p.vertex(centerX + Math.cos(start) * hr, centerY + Math.sin(start) * vr);
+ } else if (mode === PConstants.CHORD) {
+ p.vertex(centerX + Math.cos(start) * hr, centerY + Math.sin(start) * vr);
+ } else if (mode === PConstants.PIE) {
+ p.line(centerX + Math.cos(start) * hr, centerY + Math.sin(start) * vr, centerX, centerY);
+ p.line(centerX, centerY, centerX + Math.cos(stop) * hr, centerY + Math.sin(stop) * vr);
+ }
+
+ p.endShape(closed ? PConstants.CLOSE : undefined);
+ };
+ }(centerX+0.5, centerY+0.5, start, step, stop));
+
+ if (doFill) {
+ var savedStroke = doStroke;
+ doStroke = false;
+ drawSlice(p, true);
+ doStroke = savedStroke;
+ }
+
+ if (doStroke) {
+ var savedFill = doFill;
+ doFill = false;
+ drawSlice(p);
+ doFill = savedFill;
+ }
+ };
+
+ /**
+ * Draws a line (a direct path between two points) to the screen. The version of line() with four parameters
+ * draws the line in 2D. To color a line, use the stroke() function. A line cannot be filled, therefore the
+ * fill() method will not affect the color of a line. 2D lines are drawn with a width of one pixel by default,
+ * but this can be changed with the strokeWeight() function. The version with six parameters allows the line
+ * to be placed anywhere within XYZ space. Drawing this shape in 3D using the z parameter requires the P3D or
+ * OPENGL parameter in combination with size.
+ *
+ * @param {int|float} x1 x-coordinate of the first point
+ * @param {int|float} y1 y-coordinate of the first point
+ * @param {int|float} z1 z-coordinate of the first point
+ * @param {int|float} x2 x-coordinate of the second point
+ * @param {int|float} y2 y-coordinate of the second point
+ * @param {int|float} z2 z-coordinate of the second point
+ *
+ * @see strokeWeight
+ * @see strokeJoin
+ * @see strokeCap
+ * @see beginShape
+ */
+ Drawing2D.prototype.line = function(x1, y1, x2, y2) {
+ if (!doStroke) {
+ return;
+ }
+ if (!renderSmooth) {
+ x1 = Math.round(x1);
+ x2 = Math.round(x2);
+ y1 = Math.round(y1);
+ y2 = Math.round(y2);
+ }
+
+ // A line is only defined if it has different start and end coordinates.
+ // If they are the same, we call point instead.
+ if (x1 === x2 && y1 === y2) {
+ p.point(x1, y1);
+ return;
+ }
+
+ var swap = undef,
+ lineCap = undef,
+ drawCrisp = true,
+ currentModelView = modelView.array(),
+ identityMatrix = [1, 0, 0, 0, 1, 0];
+ // Test if any transformations have been applied to the sketch
+ for (var i = 0; i < 6 && drawCrisp; i++) {
+ drawCrisp = currentModelView[i] === identityMatrix[i];
+ }
+ /* Draw crisp lines if the line is vertical or horizontal with the following method
+ * If any transformations have been applied to the sketch, don't make the line crisp
+ * If the line is directed up or to the left, reverse it by swapping x1/x2 or y1/y2
+ * Make the line 1 pixel longer to work around cross-platform canvas implementations
+ * If the lineWidth is odd, translate the line by 0.5 in the perpendicular direction
+ * Even lineWidths do not need to be translated because the canvas will draw them on pixel boundaries
+ * Change the cap to butt-end to work around cross-platform canvas implementations
+ * Reverse the translate and lineCap canvas state changes after drawing the line
+ */
+ if (drawCrisp) {
+ if (x1 === x2) {
+ if (y1 > y2) {
+ swap = y1;
+ y1 = y2;
+ y2 = swap;
+ }
+ y2++;
+ if (lineWidth % 2 === 1) {
+ curContext.translate(0.5, 0.0);
+ }
+ } else if (y1 === y2) {
+ if (x1 > x2) {
+ swap = x1;
+ x1 = x2;
+ x2 = swap;
+ }
+ x2++;
+ if (lineWidth % 2 === 1) {
+ curContext.translate(0.0, 0.5);
+ }
+ }
+ if (lineWidth === 1) {
+ lineCap = curContext.lineCap;
+ curContext.lineCap = 'butt';
+ }
+ }
+ curContext.beginPath();
+ curContext.moveTo(x1 || 0, y1 || 0);
+ curContext.lineTo(x2 || 0, y2 || 0);
+ executeContextStroke();
+ if (drawCrisp) {
+ if (x1 === x2 && lineWidth % 2 === 1) {
+ curContext.translate(-0.5, 0.0);
+ } else if (y1 === y2 && lineWidth % 2 === 1) {
+ curContext.translate(0.0, -0.5);
+ }
+ if (lineWidth === 1) {
+ curContext.lineCap = lineCap;
+ }
+ }
+ };
+
+ Drawing3D.prototype.line = function(x1, y1, z1, x2, y2, z2) {
+ if (y2 === undef || z2 === undef) { // 2D line called in 3D context
+ z2 = 0;
+ y2 = x2;
+ x2 = z1;
+ z1 = 0;
+ }
+
+ // a line is only defined if it has different start and end coordinates.
+ // If they are the same, we call point instead.
+ if (x1===x2 && y1===y2 && z1===z2) {
+ p.point(x1,y1,z1);
+ return;
+ }
+
+ var lineVerts = [x1, y1, z1, x2, y2, z2];
+
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.transpose();
+
+ if (lineWidth > 0 && doStroke) {
+ curContext.useProgram(programObject2D);
+
+ uniformMatrix("uModel2d", programObject2D, "uModel", false, [1,0,0,0, 0,1,0,0, 0,0,1,0, 0,0,0,1]);
+ uniformMatrix("uView2d", programObject2D, "uView", false, view.array());
+
+ uniformf("uColor2d", programObject2D, "uColor", strokeStyle);
+ uniformi("uIsDrawingText", programObject2D, "uIsDrawingText", false);
+
+ vertexAttribPointer("aVertex2d", programObject2D, "aVertex", 3, lineBuffer);
+ disableVertexAttribPointer("aTextureCoord2d", programObject2D, "aTextureCoord");
+
+ curContext.bufferData(curContext.ARRAY_BUFFER, new Float32Array(lineVerts), curContext.STREAM_DRAW);
+ curContext.drawArrays(curContext.LINES, 0, 2);
+ }
+ };
+
+ /**
+ * Draws a Bezier curve on the screen. These curves are defined by a series of anchor and control points. The first
+ * two parameters specify the first anchor point and the last two parameters specify the other anchor point. The
+ * middle parameters specify the control points which define the shape of the curve. Bezier curves were developed
+ * by French engineer Pierre Bezier. Using the 3D version of requires rendering with P3D or OPENGL (see the
+ * Environment reference for more information).
+ *
+ * @param {int | float} x1,y1,z1 coordinates for the first anchor point
+ * @param {int | float} cx1,cy1,cz1 coordinates for the first control point
+ * @param {int | float} cx2,cy2,cz2 coordinates for the second control point
+ * @param {int | float} x2,y2,z2 coordinates for the second anchor point
+ *
+ * @see bezierVertex
+ * @see curve
+ */
+ Drawing2D.prototype.bezier = function() {
+ if (arguments.length !== 8) {
+ throw("You must use 8 parameters for bezier() in 2D mode");
+ }
+
+ p.beginShape();
+ p.vertex( arguments[0], arguments[1] );
+ p.bezierVertex( arguments[2], arguments[3],
+ arguments[4], arguments[5],
+ arguments[6], arguments[7] );
+ p.endShape();
+ };
+
+ Drawing3D.prototype.bezier = function() {
+ if (arguments.length !== 12) {
+ throw("You must use 12 parameters for bezier() in 3D mode");
+ }
+
+ p.beginShape();
+ p.vertex( arguments[0], arguments[1], arguments[2] );
+ p.bezierVertex( arguments[3], arguments[4], arguments[5],
+ arguments[6], arguments[7], arguments[8],
+ arguments[9], arguments[10], arguments[11] );
+ p.endShape();
+ };
+
+ /**
+ * Sets the resolution at which Beziers display. The default value is 20. This function is only useful when using the P3D
+ * or OPENGL renderer as the default (JAVA2D) renderer does not use this information.
+ *
+ * @param {int} detail resolution of the curves
+ *
+ * @see curve
+ * @see curveVertex
+ * @see curveTightness
+ */
+ p.bezierDetail = function( detail ){
+ bezDetail = detail;
+ };
+
+ /**
+ * The bezierPoint() function evalutes quadratic bezier at point t for points a, b, c, d.
+ * The parameter t varies between 0 and 1. The a and d parameters are the
+ * on-curve points, b and c are the control points. To make a two-dimensional
+ * curve, call this function once with the x coordinates and a second time
+ * with the y coordinates to get the location of a bezier curve at t.
+ *
+ * @param {float} a coordinate of first point on the curve
+ * @param {float} b coordinate of first control point
+ * @param {float} c coordinate of second control point
+ * @param {float} d coordinate of second point on the curve
+ * @param {float} t value between 0 and 1
+ *
+ * @see #bezier()
+ * @see #bezierVertex()
+ * @see #curvePoint()
+ */
+ p.bezierPoint = function(a, b, c, d, t) {
+ return (1 - t) * (1 - t) * (1 - t) * a + 3 * (1 - t) * (1 - t) * t * b + 3 * (1 - t) * t * t * c + t * t * t * d;
+ };
+
+ /**
+ * The bezierTangent() function calculates the tangent of a point on a Bezier curve. There is a good
+ * definition of "tangent" at Wikipedia: <a href="http://en.wikipedia.org/wiki/Tangent" target="new">http://en.wikipedia.org/wiki/Tangent</a>
+ *
+ * @param {float} a coordinate of first point on the curve
+ * @param {float} b coordinate of first control point
+ * @param {float} c coordinate of second control point
+ * @param {float} d coordinate of second point on the curve
+ * @param {float} t value between 0 and 1
+ *
+ * @see #bezier()
+ * @see #bezierVertex()
+ * @see #curvePoint()
+ */
+ p.bezierTangent = function(a, b, c, d, t) {
+ return (3 * t * t * (-a + 3 * b - 3 * c + d) + 6 * t * (a - 2 * b + c) + 3 * (-a + b));
+ };
+
+ /**
+ * The curvePoint() function evalutes the Catmull-Rom curve at point t for points a, b, c, d. The
+ * parameter t varies between 0 and 1, a and d are points on the curve,
+ * and b and c are the control points. This can be done once with the x
+ * coordinates and a second time with the y coordinates to get the
+ * location of a curve at t.
+ *
+ * @param {int|float} a coordinate of first point on the curve
+ * @param {int|float} b coordinate of second point on the curve
+ * @param {int|float} c coordinate of third point on the curve
+ * @param {int|float} d coordinate of fourth point on the curve
+ * @param {float} t value between 0 and 1
+ *
+ * @see #curve()
+ * @see #curveVertex()
+ * @see #bezierPoint()
+ */
+ p.curvePoint = function(a, b, c, d, t) {
+ return 0.5 * ((2 * b) + (-a + c) * t + (2 * a - 5 * b + 4 * c - d) * t * t + (-a + 3 * b - 3 * c + d) * t * t * t);
+ };
+
+ /**
+ * The curveTangent() function calculates the tangent of a point on a Catmull-Rom curve.
+ * There is a good definition of "tangent" at Wikipedia: <a href="http://en.wikipedia.org/wiki/Tangent" target="new">http://en.wikipedia.org/wiki/Tangent</a>.
+ *
+ * @param {int|float} a coordinate of first point on the curve
+ * @param {int|float} b coordinate of first control point
+ * @param {int|float} c coordinate of second control point
+ * @param {int|float} d coordinate of second point on the curve
+ * @param {float} t value between 0 and 1
+ *
+ * @see #curve()
+ * @see #curveVertex()
+ * @see #curvePoint()
+ * @see #bezierTangent()
+ */
+ p.curveTangent = function(a, b, c, d, t) {
+ return 0.5 * ((-a + c) + 2 * (2 * a - 5 * b + 4 * c - d) * t + 3 * (-a + 3 * b - 3 * c + d) * t * t);
+ };
+
+ /**
+ * A triangle is a plane created by connecting three points. The first two arguments specify the first point,
+ * the middle two arguments specify the second point, and the last two arguments specify the third point.
+ *
+ * @param {int | float} x1 x-coordinate of the first point
+ * @param {int | float} y1 y-coordinate of the first point
+ * @param {int | float} x2 x-coordinate of the second point
+ * @param {int | float} y2 y-coordinate of the second point
+ * @param {int | float} x3 x-coordinate of the third point
+ * @param {int | float} y3 y-coordinate of the third point
+ */
+ p.triangle = function(x1, y1, x2, y2, x3, y3) {
+ p.beginShape(PConstants.TRIANGLES);
+ p.vertex(x1, y1, 0);
+ p.vertex(x2, y2, 0);
+ p.vertex(x3, y3, 0);
+ p.endShape();
+ };
+
+ /**
+ * A quad is a quadrilateral, a four sided polygon. It is similar to a rectangle, but the angles between its
+ * edges are not constrained to ninety degrees. The first pair of parameters (x1,y1) sets the first vertex
+ * and the subsequent pairs should proceed clockwise or counter-clockwise around the defined shape.
+ *
+ * @param {float | int} x1 x-coordinate of the first corner
+ * @param {float | int} y1 y-coordinate of the first corner
+ * @param {float | int} x2 x-coordinate of the second corner
+ * @param {float | int} y2 y-coordinate of the second corner
+ * @param {float | int} x3 x-coordinate of the third corner
+ * @param {float | int} y3 y-coordinate of the third corner
+ * @param {float | int} x4 x-coordinate of the fourth corner
+ * @param {float | int} y4 y-coordinate of the fourth corner
+ */
+ p.quad = function(x1, y1, x2, y2, x3, y3, x4, y4) {
+ p.beginShape(PConstants.QUADS);
+ p.vertex(x1, y1, 0);
+ p.vertex(x2, y2, 0);
+ p.vertex(x3, y3, 0);
+ p.vertex(x4, y4, 0);
+ p.endShape();
+ };
+
+ var roundedRect$2d = function(x, y, width, height, tl, tr, br, bl) {
+ if (bl === undef) {
+ tr = tl;
+ br = tl;
+ bl = tl;
+ }
+ var halfWidth = width / 2,
+ halfHeight = height / 2;
+ if (tl > halfWidth || tl > halfHeight) {
+ tl = Math.min(halfWidth, halfHeight);
+ }
+ if (tr > halfWidth || tr > halfHeight) {
+ tr = Math.min(halfWidth, halfHeight);
+ }
+ if (br > halfWidth || br > halfHeight) {
+ br = Math.min(halfWidth, halfHeight);
+ }
+ if (bl > halfWidth || bl > halfHeight) {
+ bl = Math.min(halfWidth, halfHeight);
+ }
+ // Translate the stroke by (0.5, 0.5) to draw a crisp border
+ if (!doFill || doStroke) {
+ curContext.translate(0.5, 0.5);
+ }
+ curContext.beginPath();
+ curContext.moveTo(x + tl, y);
+ curContext.lineTo(x + width - tr, y);
+ curContext.quadraticCurveTo(x + width, y, x + width, y + tr);
+ curContext.lineTo(x + width, y + height - br);
+ curContext.quadraticCurveTo(x + width, y + height, x + width - br, y + height);
+ curContext.lineTo(x + bl, y + height);
+ curContext.quadraticCurveTo(x, y + height, x, y + height - bl);
+ curContext.lineTo(x, y + tl);
+ curContext.quadraticCurveTo(x, y, x + tl, y);
+ if (!doFill || doStroke) {
+ curContext.translate(-0.5, -0.5);
+ }
+ executeContextFill();
+ executeContextStroke();
+ };
+
+ /**
+ * Draws a rectangle to the screen. A rectangle is a four-sided shape with every angle at ninety
+ * degrees. The first two parameters set the location, the third sets the width, and the fourth
+ * sets the height. The origin is changed with the rectMode() function.
+ *
+ * @param {int|float} x x-coordinate of the rectangle
+ * @param {int|float} y y-coordinate of the rectangle
+ * @param {int|float} width width of the rectangle
+ * @param {int|float} height height of the rectangle
+ *
+ * @see rectMode
+ * @see quad
+ */
+ Drawing2D.prototype.rect = function(x, y, width, height, tl, tr, br, bl) {
+ // width and height need to be defined, numerical values
+ if (width!=''+width && height!=''+height) {
+ return;
+ }
+
+ if (curRectMode === PConstants.CORNERS) {
+ width -= x;
+ height -= y;
+ } else if (curRectMode === PConstants.RADIUS) {
+ width *= 2;
+ height *= 2;
+ x -= width / 2;
+ y -= height / 2;
+ } else if (curRectMode === PConstants.CENTER) {
+ x -= width / 2;
+ y -= height / 2;
+ }
+
+ if (!renderSmooth) {
+ x = Math.round(x);
+ y = Math.round(y);
+ width = Math.round(width);
+ height = Math.round(height);
+ }
+ if (tl !== undef) {
+ roundedRect$2d(x, y, width, height, tl, tr, br, bl);
+ return;
+ }
+
+ // Translate the line by (0.5, 0.5) to draw a crisp rectangle border
+ if (doStroke && lineWidth % 2 === 1) {
+ curContext.translate(0.5, 0.5);
+ }
+ curContext.beginPath();
+ curContext.rect(x, y, width, height);
+ executeContextFill();
+ executeContextStroke();
+ if (doStroke && lineWidth % 2 === 1) {
+ curContext.translate(-0.5, -0.5);
+ }
+ };
+
+ Drawing3D.prototype.rect = function(x, y, width, height, tl, tr, br, bl) {
+ if (tl !== undef) {
+ throw "rect() with rounded corners is not supported in 3D mode";
+ }
+
+ if (curRectMode === PConstants.CORNERS) {
+ width -= x;
+ height -= y;
+ } else if (curRectMode === PConstants.RADIUS) {
+ width *= 2;
+ height *= 2;
+ x -= width / 2;
+ y -= height / 2;
+ } else if (curRectMode === PConstants.CENTER) {
+ x -= width / 2;
+ y -= height / 2;
+ }
+
+ // Modeling transformation
+ var model = new PMatrix3D();
+ model.translate(x, y, 0);
+ model.scale(width, height, 1);
+ model.transpose();
+
+ // viewing transformation needs to have Y flipped
+ // becuase that's what Processing does.
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.transpose();
+
+ if (lineWidth > 0 && doStroke) {
+ curContext.useProgram(programObject2D);
+ uniformMatrix("uModel2d", programObject2D, "uModel", false, model.array());
+ uniformMatrix("uView2d", programObject2D, "uView", false, view.array());
+ uniformf("uColor2d", programObject2D, "uColor", strokeStyle);
+ uniformi("uIsDrawingText2d", programObject2D, "uIsDrawingText", false);
+ vertexAttribPointer("aVertex2d", programObject2D, "aVertex", 3, rectBuffer);
+ disableVertexAttribPointer("aTextureCoord2d", programObject2D, "aTextureCoord");
+ curContext.drawArrays(curContext.LINE_LOOP, 0, rectVerts.length / 3);
+ }
+
+ if (doFill) {
+ curContext.useProgram(programObject3D);
+ uniformMatrix("uModel3d", programObject3D, "uModel", false, model.array());
+ uniformMatrix("uView3d", programObject3D, "uView", false, view.array());
+
+ // fix stitching problems. (lines get occluded by triangles
+ // since they share the same depth values). This is not entirely
+ // working, but it's a start for drawing the outline. So
+ // developers can start playing around with styles.
+ curContext.enable(curContext.POLYGON_OFFSET_FILL);
+ curContext.polygonOffset(1, 1);
+
+ uniformf("color3d", programObject3D, "uColor", fillStyle);
+
+ if(lightCount > 0){
+ var v = new PMatrix3D();
+ v.set(view);
+
+ var m = new PMatrix3D();
+ m.set(model);
+
+ v.mult(m);
+
+ var normalMatrix = new PMatrix3D();
+ normalMatrix.set(v);
+ normalMatrix.invert();
+ normalMatrix.transpose();
+
+ uniformMatrix("uNormalTransform3d", programObject3D, "uNormalTransform", false, normalMatrix.array());
+ vertexAttribPointer("aNormal3d", programObject3D, "aNormal", 3, rectNormBuffer);
+ }
+ else{
+ disableVertexAttribPointer("normal3d", programObject3D, "aNormal");
+ }
+
+ vertexAttribPointer("vertex3d", programObject3D, "aVertex", 3, rectBuffer);
+
+ curContext.drawArrays(curContext.TRIANGLE_FAN, 0, rectVerts.length / 3);
+ curContext.disable(curContext.POLYGON_OFFSET_FILL);
+ }
+ };
+
+ /**
+ * Draws an ellipse (oval) in the display window. An ellipse with an equal <b>width</b> and <b>height</b> is a circle.
+ * The first two parameters set the location, the third sets the width, and the fourth sets the height. The origin may be
+ * changed with the <b>ellipseMode()</b> function.
+ *
+ * @param {float|int} x x-coordinate of the ellipse
+ * @param {float|int} y y-coordinate of the ellipse
+ * @param {float|int} width width of the ellipse
+ * @param {float|int} height height of the ellipse
+ *
+ * @see ellipseMode
+ */
+ Drawing2D.prototype.ellipse = function(x, y, width, height) {
+ x = x || 0;
+ y = y || 0;
+
+ if (width <= 0 && height <= 0) {
+ return;
+ }
+
+ if (curEllipseMode === PConstants.RADIUS) {
+ width *= 2;
+ height *= 2;
+ } else if (curEllipseMode === PConstants.CORNERS) {
+ width = width - x;
+ height = height - y;
+ x += width / 2;
+ y += height / 2;
+ } else if (curEllipseMode === PConstants.CORNER) {
+ x += width / 2;
+ y += height / 2;
+ }
+
+ // Shortcut for drawing a 2D circle
+ if (width === height) {
+ curContext.beginPath();
+ curContext.arc(x, y, width / 2, 0, PConstants.TWO_PI, false);
+ executeContextFill();
+ executeContextStroke();
+ } else {
+ var w = width / 2,
+ h = height / 2,
+ C = 0.5522847498307933,
+ c_x = C * w,
+ c_y = C * h;
+
+ p.beginShape();
+ p.vertex(x + w, y);
+ p.bezierVertex(x + w, y - c_y, x + c_x, y - h, x, y - h);
+ p.bezierVertex(x - c_x, y - h, x - w, y - c_y, x - w, y);
+ p.bezierVertex(x - w, y + c_y, x - c_x, y + h, x, y + h);
+ p.bezierVertex(x + c_x, y + h, x + w, y + c_y, x + w, y);
+ p.endShape();
+ }
+ };
+
+ Drawing3D.prototype.ellipse = function(x, y, width, height) {
+ x = x || 0;
+ y = y || 0;
+
+ if (width <= 0 && height <= 0) {
+ return;
+ }
+
+ if (curEllipseMode === PConstants.RADIUS) {
+ width *= 2;
+ height *= 2;
+ } else if (curEllipseMode === PConstants.CORNERS) {
+ width = width - x;
+ height = height - y;
+ x += width / 2;
+ y += height / 2;
+ } else if (curEllipseMode === PConstants.CORNER) {
+ x += width / 2;
+ y += height / 2;
+ }
+
+ var w = width / 2,
+ h = height / 2,
+ C = 0.5522847498307933,
+ c_x = C * w,
+ c_y = C * h;
+
+ p.beginShape();
+ p.vertex(x + w, y);
+ p.bezierVertex(x + w, y - c_y, 0, x + c_x, y - h, 0, x, y - h, 0);
+ p.bezierVertex(x - c_x, y - h, 0, x - w, y - c_y, 0, x - w, y, 0);
+ p.bezierVertex(x - w, y + c_y, 0, x - c_x, y + h, 0, x, y + h, 0);
+ p.bezierVertex(x + c_x, y + h, 0, x + w, y + c_y, 0, x + w, y, 0);
+ p.endShape();
+
+ if (doFill) {
+ //temporary workaround to not working fills for bezier -- will fix later
+ var xAv = 0, yAv = 0, i, j;
+ for (i = 0; i < vertArray.length; i++) {
+ xAv += vertArray[i][0];
+ yAv += vertArray[i][1];
+ }
+ xAv /= vertArray.length;
+ yAv /= vertArray.length;
+ var vert = [],
+ fillVertArray = [],
+ colorVertArray = [];
+ vert[0] = xAv;
+ vert[1] = yAv;
+ vert[2] = 0;
+ vert[3] = 0;
+ vert[4] = 0;
+ vert[5] = fillStyle[0];
+ vert[6] = fillStyle[1];
+ vert[7] = fillStyle[2];
+ vert[8] = fillStyle[3];
+ vert[9] = strokeStyle[0];
+ vert[10] = strokeStyle[1];
+ vert[11] = strokeStyle[2];
+ vert[12] = strokeStyle[3];
+ vert[13] = normalX;
+ vert[14] = normalY;
+ vert[15] = normalZ;
+ vertArray.unshift(vert);
+ for (i = 0; i < vertArray.length; i++) {
+ for (j = 0; j < 3; j++) {
+ fillVertArray.push(vertArray[i][j]);
+ }
+ for (j = 5; j < 9; j++) {
+ colorVertArray.push(vertArray[i][j]);
+ }
+ }
+ fill3D(fillVertArray, "TRIANGLE_FAN", colorVertArray);
+ }
+ };
+
+ /**
+ * Sets the current normal vector. This is for drawing three dimensional shapes and surfaces and
+ * specifies a vector perpendicular to the surface of the shape which determines how lighting affects
+ * it. Processing attempts to automatically assign normals to shapes, but since that's imperfect,
+ * this is a better option when you want more control. This function is identical to glNormal3f() in OpenGL.
+ *
+ * @param {float} nx x direction
+ * @param {float} ny y direction
+ * @param {float} nz z direction
+ *
+ * @see beginShape
+ * @see endShape
+ * @see lights
+ */
+ p.normal = function(nx, ny, nz) {
+ if (arguments.length !== 3 || !(typeof nx === "number" && typeof ny === "number" && typeof nz === "number")) {
+ throw "normal() requires three numeric arguments.";
+ }
+
+ normalX = nx;
+ normalY = ny;
+ normalZ = nz;
+
+ if (curShape !== 0) {
+ if (normalMode === PConstants.NORMAL_MODE_AUTO) {
+ normalMode = PConstants.NORMAL_MODE_SHAPE;
+ } else if (normalMode === PConstants.NORMAL_MODE_SHAPE) {
+ normalMode = PConstants.NORMAL_MODE_VERTEX;
+ }
+ }
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Raster drawing functions
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * Saves an image from the display window. Images are saved in TIFF, TARGA, JPEG, and PNG format
+ * depending on the extension within the filename parameter. For example, "image.tif" will have
+ * a TIFF image and "image.png" will save a PNG image. If no extension is included in the filename,
+ * the image will save in TIFF format and .tif will be added to the name. These files are saved to
+ * the sketch's folder, which may be opened by selecting "Show sketch folder" from the "Sketch" menu.
+ * It is not possible to use save() while running the program in a web browser. All images saved
+ * from the main drawing window will be opaque. To save images without a background, use createGraphics().
+ *
+ * @param {String} filename any sequence of letters and numbers
+ *
+ * @see saveFrame
+ * @see createGraphics
+ */
+ p.save = function(file, img) {
+ // file is unused at the moment
+ // may implement this differently in later release
+ if (img !== undef) {
+ return window.open(img.toDataURL(),"_blank");
+ }
+ return window.open(p.externals.canvas.toDataURL(),"_blank");
+ };
+
+ var saveNumber = 0;
+
+ p.saveFrame = function(file) {
+ if(file === undef) {
+ // use default name template if parameter is not specified
+ file = "screen-####.png";
+ }
+ // Increment changeable part: screen-0000.png, screen-0001.png, ...
+ var frameFilename = file.replace(/#+/, function(all) {
+ var s = "" + (saveNumber++);
+ while(s.length < all.length) {
+ s = "0" + s;
+ }
+ return s;
+ });
+ p.save(frameFilename);
+ };
+
+ var utilityContext2d = document.createElement("canvas").getContext("2d");
+
+ var canvasDataCache = [undef, undef, undef]; // we need three for now
+
+ function getCanvasData(obj, w, h) {
+ var canvasData = canvasDataCache.shift();
+
+ if (canvasData === undef) {
+ canvasData = {};
+ canvasData.canvas = document.createElement("canvas");
+ canvasData.context = canvasData.canvas.getContext('2d');
+ }
+
+ canvasDataCache.push(canvasData);
+
+ var canvas = canvasData.canvas, context = canvasData.context,
+ width = w || obj.width, height = h || obj.height;
+
+ canvas.width = width;
+ canvas.height = height;
+
+ if (!obj) {
+ context.clearRect(0, 0, width, height);
+ } else if ("data" in obj) { // ImageData
+ context.putImageData(obj, 0, 0);
+ } else {
+ context.clearRect(0, 0, width, height);
+ context.drawImage(obj, 0, 0, width, height);
+ }
+ return canvasData;
+ }
+
+ /**
+ * Handle the sketch code for pixels[] and pixels.length
+ * parser code converts pixels[] to getPixels()
+ * or setPixels(), .length becomes getLength()
+ */
+ function buildPixelsObject(pImage) {
+ return {
+
+ getLength: (function(aImg) {
+ return function() {
+ if (aImg.isRemote) {
+ throw "Image is loaded remotely. Cannot get length.";
+ } else {
+ return aImg.imageData.data.length ? aImg.imageData.data.length/4 : 0;
+ }
+ };
+ }(pImage)),
+
+ getPixel: (function(aImg) {
+ return function(i) {
+ var offset = i*4,
+ data = aImg.imageData.data;
+
+ if (aImg.isRemote) {
+ throw "Image is loaded remotely. Cannot get pixels.";
+ }
+
+ return (data[offset+3] << 24) & PConstants.ALPHA_MASK |
+ (data[offset] << 16) & PConstants.RED_MASK |
+ (data[offset+1] << 8) & PConstants.GREEN_MASK |
+ data[offset+2] & PConstants.BLUE_MASK;
+ };
+ }(pImage)),
+
+ setPixel: (function(aImg) {
+ return function(i, c) {
+ var offset = i*4,
+ data = aImg.imageData.data;
+
+ if (aImg.isRemote) {
+ throw "Image is loaded remotely. Cannot set pixel.";
+ }
+
+ data[offset+0] = (c & PConstants.RED_MASK) >>> 16;
+ data[offset+1] = (c & PConstants.GREEN_MASK) >>> 8;
+ data[offset+2] = (c & PConstants.BLUE_MASK);
+ data[offset+3] = (c & PConstants.ALPHA_MASK) >>> 24;
+ aImg.__isDirty = true;
+ };
+ }(pImage)),
+
+ toArray: (function(aImg) {
+ return function() {
+ var arr = [],
+ data = aImg.imageData.data,
+ length = aImg.width * aImg.height;
+
+ if (aImg.isRemote) {
+ throw "Image is loaded remotely. Cannot get pixels.";
+ }
+
+ for (var i = 0, offset = 0; i < length; i++, offset += 4) {
+ arr.push( (data[offset+3] << 24) & PConstants.ALPHA_MASK |
+ (data[offset] << 16) & PConstants.RED_MASK |
+ (data[offset+1] << 8) & PConstants.GREEN_MASK |
+ data[offset+2] & PConstants.BLUE_MASK );
+ }
+ return arr;
+ };
+ }(pImage)),
+
+ set: (function(aImg) {
+ return function(arr) {
+ var offset,
+ data,
+ c;
+ if (this.isRemote) {
+ throw "Image is loaded remotely. Cannot set pixels.";
+ }
+
+ data = aImg.imageData.data;
+ for (var i = 0, aL = arr.length; i < aL; i++) {
+ c = arr[i];
+ offset = i*4;
+
+ data[offset+0] = (c & PConstants.RED_MASK) >>> 16;
+ data[offset+1] = (c & PConstants.GREEN_MASK) >>> 8;
+ data[offset+2] = (c & PConstants.BLUE_MASK);
+ data[offset+3] = (c & PConstants.ALPHA_MASK) >>> 24;
+ }
+ aImg.__isDirty = true;
+ };
+ }(pImage))
+
+ };
+ }
+
+ /**
+ * Datatype for storing images. Processing can display .gif, .jpg, .tga, and .png images. Images may be
+ * displayed in 2D and 3D space. Before an image is used, it must be loaded with the loadImage() function.
+ * The PImage object contains fields for the width and height of the image, as well as an array called
+ * pixels[] which contains the values for every pixel in the image. A group of methods, described below,
+ * allow easy access to the image's pixels and alpha channel and simplify the process of compositing.
+ * Before using the pixels[] array, be sure to use the loadPixels() method on the image to make sure that the
+ * pixel data is properly loaded. To create a new image, use the createImage() function (do not use new PImage()).
+ *
+ * @param {int} width image width
+ * @param {int} height image height
+ * @param {MODE} format Either RGB, ARGB, ALPHA (grayscale alpha channel)
+ *
+ * @returns {PImage}
+ *
+ * @see loadImage
+ * @see imageMode
+ * @see createImage
+ */
+ var PImage = function(aWidth, aHeight, aFormat) {
+
+ // Keep track of whether or not the cached imageData has been touched.
+ this.__isDirty = false;
+
+ if (aWidth instanceof HTMLImageElement) {
+ // convert an <img> to a PImage
+ this.fromHTMLImageData(aWidth);
+ } else if (aHeight || aFormat) {
+ this.width = aWidth || 1;
+ this.height = aHeight || 1;
+
+ // Stuff a canvas into sourceImg so image() calls can use drawImage like an <img>
+ var canvas = this.sourceImg = document.createElement("canvas");
+ canvas.width = this.width;
+ canvas.height = this.height;
+
+ var imageData = this.imageData = canvas.getContext('2d').createImageData(this.width, this.height);
+ this.format = (aFormat === PConstants.ARGB || aFormat === PConstants.ALPHA) ? aFormat : PConstants.RGB;
+ if (this.format === PConstants.RGB) {
+ // Set the alpha channel of an RGB image to opaque.
+ for (var i = 3, data = this.imageData.data, len = data.length; i < len; i += 4) {
+ data[i] = 255;
+ }
+ }
+
+ this.__isDirty = true;
+ this.updatePixels();
+ } else {
+ this.width = 0;
+ this.height = 0;
+ this.imageData = utilityContext2d.createImageData(1, 1);
+ this.format = PConstants.ARGB;
+ }
+
+ this.pixels = buildPixelsObject(this);
+ };
+ PImage.prototype = {
+
+ /**
+ * Temporary hack to deal with cross-Processing-instance created PImage. See
+ * tickets #1623 and #1644.
+ */
+ __isPImage: true,
+
+ /**
+ * @member PImage
+ * Updates the image with the data in its pixels[] array. Use in conjunction with loadPixels(). If
+ * you're only reading pixels from the array, there's no need to call updatePixels().
+ * Certain renderers may or may not seem to require loadPixels() or updatePixels(). However, the rule
+ * is that any time you want to manipulate the pixels[] array, you must first call loadPixels(), and
+ * after changes have been made, call updatePixels(). Even if the renderer may not seem to use this
+ * function in the current Processing release, this will always be subject to change.
+ * Currently, none of the renderers use the additional parameters to updatePixels().
+ */
+ updatePixels: function() {
+ var canvas = this.sourceImg;
+ if (canvas && canvas instanceof HTMLCanvasElement && this.__isDirty) {
+ canvas.getContext('2d').putImageData(this.imageData, 0, 0);
+ }
+ this.__isDirty = false;
+ },
+
+ fromHTMLImageData: function(htmlImg) {
+ // convert an <img> to a PImage
+ var canvasData = getCanvasData(htmlImg);
+ try {
+ var imageData = canvasData.context.getImageData(0, 0, htmlImg.width, htmlImg.height);
+ this.fromImageData(imageData);
+ } catch(e) {
+ if (htmlImg.width && htmlImg.height) {
+ this.isRemote = true;
+ this.width = htmlImg.width;
+ this.height = htmlImg.height;
+ }
+ }
+ this.sourceImg = htmlImg;
+ },
+
+ 'get': function(x, y, w, h) {
+ if (!arguments.length) {
+ return p.get(this);
+ }
+ if (arguments.length === 2) {
+ return p.get(x, y, this);
+ }
+ if (arguments.length === 4) {
+ return p.get(x, y, w, h, this);
+ }
+ },
+
+ /**
+ * @member PImage
+ * Changes the color of any pixel or writes an image directly into the image. The x and y parameter
+ * specify the pixel or the upper-left corner of the image. The color parameter specifies the color value.
+ * Setting the color of a single pixel with set(x, y) is easy, but not as fast as putting the data
+ * directly into pixels[]. The equivalent statement to "set(x, y, #000000)" using pixels[] is
+ * "pixels[y*width+x] = #000000". Processing requires calling loadPixels() to load the display window
+ * data into the pixels[] array before getting the values and calling updatePixels() to update the window.
+ *
+ * @param {int} x x-coordinate of the pixel or upper-left corner of the image
+ * @param {int} y y-coordinate of the pixel or upper-left corner of the image
+ * @param {color} color any value of the color datatype
+ *
+ * @see get
+ * @see pixels[]
+ * @see copy
+ */
+ 'set': function(x, y, c) {
+ p.set(x, y, c, this);
+ this.__isDirty = true;
+ },
+
+ /**
+ * @member PImage
+ * Blends a region of pixels into the image specified by the img parameter. These copies utilize full
+ * alpha channel support and a choice of the following modes to blend the colors of source pixels (A)
+ * with the ones of pixels in the destination image (B):
+ * BLEND - linear interpolation of colours: C = A*factor + B
+ * ADD - additive blending with white clip: C = min(A*factor + B, 255)
+ * SUBTRACT - subtractive blending with black clip: C = max(B - A*factor, 0)
+ * DARKEST - only the darkest colour succeeds: C = min(A*factor, B)
+ * LIGHTEST - only the lightest colour succeeds: C = max(A*factor, B)
+ * DIFFERENCE - subtract colors from underlying image.
+ * EXCLUSION - similar to DIFFERENCE, but less extreme.
+ * MULTIPLY - Multiply the colors, result will always be darker.
+ * SCREEN - Opposite multiply, uses inverse values of the colors.
+ * OVERLAY - A mix of MULTIPLY and SCREEN. Multiplies dark values, and screens light values.
+ * HARD_LIGHT - SCREEN when greater than 50% gray, MULTIPLY when lower.
+ * SOFT_LIGHT - Mix of DARKEST and LIGHTEST. Works like OVERLAY, but not as harsh.
+ * DODGE - Lightens light tones and increases contrast, ignores darks. Called "Color Dodge" in Illustrator and Photoshop.
+ * BURN - Darker areas are applied, increasing contrast, ignores lights. Called "Color Burn" in Illustrator and Photoshop.
+ * All modes use the alpha information (highest byte) of source image pixels as the blending factor.
+ * If the source and destination regions are different sizes, the image will be automatically resized to
+ * match the destination size. If the srcImg parameter is not used, the display window is used as the source image.
+ * This function ignores imageMode().
+ *
+ * @param {int} x X coordinate of the source's upper left corner
+ * @param {int} y Y coordinate of the source's upper left corner
+ * @param {int} width source image width
+ * @param {int} height source image height
+ * @param {int} dx X coordinate of the destinations's upper left corner
+ * @param {int} dy Y coordinate of the destinations's upper left corner
+ * @param {int} dwidth destination image width
+ * @param {int} dheight destination image height
+ * @param {PImage} srcImg an image variable referring to the source image
+ * @param {MODE} MODE Either BLEND, ADD, SUBTRACT, LIGHTEST, DARKEST, DIFFERENCE, EXCLUSION,
+ * MULTIPLY, SCREEN, OVERLAY, HARD_LIGHT, SOFT_LIGHT, DODGE, BURN
+ *
+ * @see alpha
+ * @see copy
+ */
+ blend: function(srcImg, x, y, width, height, dx, dy, dwidth, dheight, MODE) {
+ if (arguments.length === 9) {
+ p.blend(this, srcImg, x, y, width, height, dx, dy, dwidth, dheight, this);
+ } else if (arguments.length === 10) {
+ p.blend(srcImg, x, y, width, height, dx, dy, dwidth, dheight, MODE, this);
+ }
+ delete this.sourceImg;
+ },
+
+ /**
+ * @member PImage
+ * Copies a region of pixels from one image into another. If the source and destination regions
+ * aren't the same size, it will automatically resize source pixels to fit the specified target region.
+ * No alpha information is used in the process, however if the source image has an alpha channel set,
+ * it will be copied as well. This function ignores imageMode().
+ *
+ * @param {int} sx X coordinate of the source's upper left corner
+ * @param {int} sy Y coordinate of the source's upper left corner
+ * @param {int} swidth source image width
+ * @param {int} sheight source image height
+ * @param {int} dx X coordinate of the destinations's upper left corner
+ * @param {int} dy Y coordinate of the destinations's upper left corner
+ * @param {int} dwidth destination image width
+ * @param {int} dheight destination image height
+ * @param {PImage} srcImg an image variable referring to the source image
+ *
+ * @see alpha
+ * @see blend
+ */
+ copy: function(srcImg, sx, sy, swidth, sheight, dx, dy, dwidth, dheight) {
+ if (arguments.length === 8) {
+ p.blend(this, srcImg, sx, sy, swidth, sheight, dx, dy, dwidth, PConstants.REPLACE, this);
+ } else if (arguments.length === 9) {
+ p.blend(srcImg, sx, sy, swidth, sheight, dx, dy, dwidth, dheight, PConstants.REPLACE, this);
+ }
+ delete this.sourceImg;
+ },
+
+ /**
+ * @member PImage
+ * Filters an image as defined by one of the following modes:
+ * THRESHOLD - converts the image to black and white pixels depending if they are above or below
+ * the threshold defined by the level parameter. The level must be between 0.0 (black) and 1.0(white).
+ * If no level is specified, 0.5 is used.
+ * GRAY - converts any colors in the image to grayscale equivalents
+ * INVERT - sets each pixel to its inverse value
+ * POSTERIZE - limits each channel of the image to the number of colors specified as the level parameter
+ * BLUR - executes a Guassian blur with the level parameter specifying the extent of the blurring.
+ * If no level parameter is used, the blur is equivalent to Guassian blur of radius 1.
+ * OPAQUE - sets the alpha channel to entirely opaque.
+ * ERODE - reduces the light areas with the amount defined by the level parameter.
+ * DILATE - increases the light areas with the amount defined by the level parameter
+ *
+ * @param {MODE} MODE Either THRESHOLD, GRAY, INVERT, POSTERIZE, BLUR, OPAQUE, ERODE, or DILATE
+ * @param {int|float} param in the range from 0 to 1
+ */
+ filter: function(mode, param) {
+ if (arguments.length === 2) {
+ p.filter(mode, param, this);
+ } else if (arguments.length === 1) {
+ // no param specified, send null to show its invalid
+ p.filter(mode, null, this);
+ }
+ delete this.sourceImg;
+ },
+
+ /**
+ * @member PImage
+ * Saves the image into a file. Images are saved in TIFF, TARGA, JPEG, and PNG format depending on
+ * the extension within the filename parameter. For example, "image.tif" will have a TIFF image and
+ * "image.png" will save a PNG image. If no extension is included in the filename, the image will save
+ * in TIFF format and .tif will be added to the name. These files are saved to the sketch's folder,
+ * which may be opened by selecting "Show sketch folder" from the "Sketch" menu. It is not possible to
+ * use save() while running the program in a web browser.
+ * To save an image created within the code, rather than through loading, it's necessary to make the
+ * image with the createImage() function so it is aware of the location of the program and can therefore
+ * save the file to the right place. See the createImage() reference for more information.
+ *
+ * @param {String} filename a sequence of letters and numbers
+ */
+ save: function(file){
+ p.save(file,this);
+ },
+
+ /**
+ * @member PImage
+ * Resize the image to a new width and height. To make the image scale proportionally, use 0 as the
+ * value for the wide or high parameter.
+ *
+ * @param {int} wide the resized image width
+ * @param {int} high the resized image height
+ *
+ * @see get
+ */
+ resize: function(w, h) {
+ if (this.isRemote) { // Remote images cannot access imageData
+ throw "Image is loaded remotely. Cannot resize.";
+ }
+ if (this.width !== 0 || this.height !== 0) {
+ // make aspect ratio if w or h is 0
+ if (w === 0 && h !== 0) {
+ w = Math.floor(this.width / this.height * h);
+ } else if (h === 0 && w !== 0) {
+ h = Math.floor(this.height / this.width * w);
+ }
+ // put 'this.imageData' into a new canvas
+ var canvas = getCanvasData(this.imageData).canvas;
+ // pull imageData object out of canvas into ImageData object
+ var imageData = getCanvasData(canvas, w, h).context.getImageData(0, 0, w, h);
+ // set this as new pimage
+ this.fromImageData(imageData);
+ }
+ },
+
+ /**
+ * @member PImage
+ * Masks part of an image from displaying by loading another image and using it as an alpha channel.
+ * This mask image should only contain grayscale data, but only the blue color channel is used. The
+ * mask image needs to be the same size as the image to which it is applied.
+ * In addition to using a mask image, an integer array containing the alpha channel data can be
+ * specified directly. This method is useful for creating dynamically generated alpha masks. This
+ * array must be of the same length as the target image's pixels array and should contain only grayscale
+ * data of values between 0-255.
+ *
+ * @param {PImage} maskImg any PImage object used as the alpha channel for "img", needs to be same
+ * size as "img"
+ * @param {int[]} maskArray any array of Integer numbers used as the alpha channel, needs to be same
+ * length as the image's pixel array
+ */
+ mask: function(mask) {
+ var obj = this.toImageData(),
+ i,
+ size;
+
+ if (mask instanceof PImage || mask.__isPImage) {
+ if (mask.width === this.width && mask.height === this.height) {
+ mask = mask.toImageData();
+
+ for (i = 2, size = this.width * this.height * 4; i < size; i += 4) {
+ // using it as an alpha channel
+ obj.data[i + 1] = mask.data[i];
+ // but only the blue color channel
+ }
+ } else {
+ throw "mask must have the same dimensions as PImage.";
+ }
+ } else if (mask instanceof Array) {
+ if (this.width * this.height === mask.length) {
+ for (i = 0, size = mask.length; i < size; ++i) {
+ obj.data[i * 4 + 3] = mask[i];
+ }
+ } else {
+ throw "mask array must be the same length as PImage pixels array.";
+ }
+ }
+
+ this.fromImageData(obj);
+ },
+
+ // These are intentionally left blank for PImages, we work live with pixels and draw as necessary
+ /**
+ * @member PImage
+ * Loads the pixel data for the image into its pixels[] array. This function must always be called
+ * before reading from or writing to pixels[].
+ * Certain renderers may or may not seem to require loadPixels() or updatePixels(). However, the
+ * rule is that any time you want to manipulate the pixels[] array, you must first call loadPixels(),
+ * and after changes have been made, call updatePixels(). Even if the renderer may not seem to use
+ * this function in the current Processing release, this will always be subject to change.
+ */
+ loadPixels: noop,
+
+ toImageData: function() {
+ if (this.isRemote) {
+ return this.sourceImg;
+ }
+
+ if (!this.__isDirty) {
+ return this.imageData;
+ }
+
+ var canvasData = getCanvasData(this.sourceImg);
+ return canvasData.context.getImageData(0, 0, this.width, this.height);
+ },
+
+ toDataURL: function() {
+ if (this.isRemote) { // Remote images cannot access imageData
+ throw "Image is loaded remotely. Cannot create dataURI.";
+ }
+ var canvasData = getCanvasData(this.imageData);
+ return canvasData.canvas.toDataURL();
+ },
+
+ fromImageData: function(canvasImg) {
+ var w = canvasImg.width,
+ h = canvasImg.height,
+ canvas = document.createElement('canvas'),
+ ctx = canvas.getContext('2d');
+
+ this.width = canvas.width = w;
+ this.height = canvas.height = h;
+
+ ctx.putImageData(canvasImg, 0, 0);
+
+ // changed for 0.9
+ this.format = PConstants.ARGB;
+
+ this.imageData = canvasImg;
+ this.sourceImg = canvas;
+ }
+ };
+
+ p.PImage = PImage;
+
+ /**
+ * Creates a new PImage (the datatype for storing images). This provides a fresh buffer of pixels to play
+ * with. Set the size of the buffer with the width and height parameters. The format parameter defines how
+ * the pixels are stored. See the PImage reference for more information.
+ * Be sure to include all three parameters, specifying only the width and height (but no format) will
+ * produce a strange error.
+ * Advanced users please note that createImage() should be used instead of the syntax new PImage().
+ *
+ * @param {int} width image width
+ * @param {int} height image height
+ * @param {MODE} format Either RGB, ARGB, ALPHA (grayscale alpha channel)
+ *
+ * @returns {PImage}
+ *
+ * @see PImage
+ * @see PGraphics
+ */
+ p.createImage = function(w, h, mode) {
+ return new PImage(w,h,mode);
+ };
+
+ // Loads an image for display. Type is an extension. Callback is fired on load.
+ /**
+ * Loads an image into a variable of type PImage. Four types of images ( .gif, .jpg, .tga, .png) images may
+ * be loaded. To load correctly, images must be located in the data directory of the current sketch. In most
+ * cases, load all images in setup() to preload them at the start of the program. Loading images inside draw()
+ * will reduce the speed of a program.
+ * The filename parameter can also be a URL to a file found online. For security reasons, a Processing sketch
+ * found online can only download files from the same server from which it came. Getting around this restriction
+ * requires a signed applet.
+ * The extension parameter is used to determine the image type in cases where the image filename does not end
+ * with a proper extension. Specify the extension as the second parameter to loadImage(), as shown in the
+ * third example on this page.
+ * If an image is not loaded successfully, the null value is returned and an error message will be printed to
+ * the console. The error message does not halt the program, however the null value may cause a NullPointerException
+ * if your code does not check whether the value returned from loadImage() is null.
+ * Depending on the type of error, a PImage object may still be returned, but the width and height of the image
+ * will be set to -1. This happens if bad image data is returned or cannot be decoded properly. Sometimes this happens
+ * with image URLs that produce a 403 error or that redirect to a password prompt, because loadImage() will attempt
+ * to interpret the HTML as image data.
+ *
+ * @param {String} filename name of file to load, can be .gif, .jpg, .tga, or a handful of other image
+ * types depending on your platform.
+ * @param {String} extension the type of image to load, for example "png", "gif", "jpg"
+ *
+ * @returns {PImage}
+ *
+ * @see PImage
+ * @see image
+ * @see imageMode
+ * @see background
+ */
+ p.loadImage = function(file, type, callback) {
+ // if type is specified, we just ignore it
+
+ var pimg;
+ // if image is in the preloader cache return a new PImage
+ if (curSketch.imageCache.images[file]) {
+ pimg = new PImage(curSketch.imageCache.images[file]);
+ pimg.loaded = true;
+ return pimg;
+ }
+ // else async load it
+ pimg = new PImage();
+ var img = document.createElement('img');
+
+ pimg.sourceImg = img;
+
+ img.onload = (function(aImage, aPImage, aCallback) {
+ var image = aImage;
+ var pimg = aPImage;
+ var callback = aCallback;
+ return function() {
+ // change the <img> object into a PImage now that its loaded
+ pimg.fromHTMLImageData(image);
+ pimg.loaded = true;
+ if (callback) {
+ callback();
+ }
+ };
+ }(img, pimg, callback));
+
+ img.src = file; // needs to be called after the img.onload function is declared or it wont work in opera
+ return pimg;
+ };
+
+ // async loading of large images, same functionality as loadImage above
+ /**
+ * This function load images on a separate thread so that your sketch does not freeze while images load during
+ * setup(). While the image is loading, its width and height will be 0. If an error occurs while loading the image,
+ * its width and height will be set to -1. You'll know when the image has loaded properly because its width and
+ * height will be greater than 0. Asynchronous image loading (particularly when downloading from a server) can
+ * dramatically improve performance.
+ * The extension parameter is used to determine the image type in cases where the image filename does not end
+ * with a proper extension. Specify the extension as the second parameter to requestImage().
+ *
+ * @param {String} filename name of file to load, can be .gif, .jpg, .tga, or a handful of other image
+ * types depending on your platform.
+ * @param {String} extension the type of image to load, for example "png", "gif", "jpg"
+ *
+ * @returns {PImage}
+ *
+ * @see PImage
+ * @see loadImage
+ */
+ p.requestImage = p.loadImage;
+
+ function get$2(x,y) {
+ var data;
+ // return the color at x,y (int) of curContext
+ if (x >= p.width || x < 0 || y < 0 || y >= p.height) {
+ // x,y is outside image return transparent black
+ return 0;
+ }
+
+ // loadPixels() has been called
+ if (isContextReplaced) {
+ var offset = ((0|x) + p.width * (0|y)) * 4;
+ data = p.imageData.data;
+ return (data[offset + 3] << 24) & PConstants.ALPHA_MASK |
+ (data[offset] << 16) & PConstants.RED_MASK |
+ (data[offset + 1] << 8) & PConstants.GREEN_MASK |
+ data[offset + 2] & PConstants.BLUE_MASK;
+ }
+
+ // x,y is inside canvas space
+ data = p.toImageData(0|x, 0|y, 1, 1).data;
+ return (data[3] << 24) & PConstants.ALPHA_MASK |
+ (data[0] << 16) & PConstants.RED_MASK |
+ (data[1] << 8) & PConstants.GREEN_MASK |
+ data[2] & PConstants.BLUE_MASK;
+ }
+ function get$3(x,y,img) {
+ if (img.isRemote) { // Remote images cannot access imageData
+ throw "Image is loaded remotely. Cannot get x,y.";
+ }
+ // PImage.get(x,y) was called, return the color (int) at x,y of img
+ var offset = y * img.width * 4 + (x * 4),
+ data = img.imageData.data;
+ return (data[offset + 3] << 24) & PConstants.ALPHA_MASK |
+ (data[offset] << 16) & PConstants.RED_MASK |
+ (data[offset + 1] << 8) & PConstants.GREEN_MASK |
+ data[offset + 2] & PConstants.BLUE_MASK;
+ }
+ function get$4(x, y, w, h) {
+ // return a PImage of w and h from cood x,y of curContext
+ var c = new PImage(w, h, PConstants.ARGB);
+ c.fromImageData(p.toImageData(x, y, w, h));
+ return c;
+ }
+ function get$5(x, y, w, h, img) {
+ if (img.isRemote) { // Remote images cannot access imageData
+ throw "Image is loaded remotely. Cannot get x,y,w,h.";
+ }
+ // PImage.get(x,y,w,h) was called, return x,y,w,h PImage of img
+ // offset start point needs to be *4
+ var c = new PImage(w, h, PConstants.ARGB), cData = c.imageData.data,
+ imgWidth = img.width, imgHeight = img.height, imgData = img.imageData.data;
+ // Don't need to copy pixels from the image outside ranges.
+ var startRow = Math.max(0, -y), startColumn = Math.max(0, -x),
+ stopRow = Math.min(h, imgHeight - y), stopColumn = Math.min(w, imgWidth - x);
+ for (var i = startRow; i < stopRow; ++i) {
+ var sourceOffset = ((y + i) * imgWidth + (x + startColumn)) * 4;
+ var targetOffset = (i * w + startColumn) * 4;
+ for (var j = startColumn; j < stopColumn; ++j) {
+ cData[targetOffset++] = imgData[sourceOffset++];
+ cData[targetOffset++] = imgData[sourceOffset++];
+ cData[targetOffset++] = imgData[sourceOffset++];
+ cData[targetOffset++] = imgData[sourceOffset++];
+ }
+ }
+ c.__isDirty = true;
+ return c;
+ }
+
+ // Gets a single pixel or block of pixels from the current Canvas Context or a PImage
+ /**
+ * Reads the color of any pixel or grabs a section of an image. If no parameters are specified, the entire
+ * image is returned. Get the value of one pixel by specifying an x,y coordinate. Get a section of the display
+ * window by specifying an additional width and height parameter. If the pixel requested is outside of the image
+ * window, black is returned. The numbers returned are scaled according to the current color ranges, but only RGB
+ * values are returned by this function. For example, even though you may have drawn a shape with colorMode(HSB),
+ * the numbers returned will be in RGB.
+ * Getting the color of a single pixel with get(x, y) is easy, but not as fast as grabbing the data directly
+ * from pixels[]. The equivalent statement to "get(x, y)" using pixels[] is "pixels[y*width+x]". Processing
+ * requires calling loadPixels() to load the display window data into the pixels[] array before getting the values.
+ * This function ignores imageMode().
+ *
+ * @param {int} x x-coordinate of the pixel
+ * @param {int} y y-coordinate of the pixel
+ * @param {int} width width of pixel rectangle to get
+ * @param {int} height height of pixel rectangle to get
+ *
+ * @returns {Color|PImage}
+ *
+ * @see set
+ * @see pixels[]
+ * @see imageMode
+ */
+ p.get = function(x, y, w, h, img) {
+ // for 0 2 and 4 arguments use curContext, otherwise PImage.get was called
+ if (img !== undefined) {
+ return get$5(x, y, w, h, img);
+ }
+ if (h !== undefined) {
+ return get$4(x, y, w, h);
+ }
+ if (w !== undefined) {
+ return get$3(x, y, w);
+ }
+ if (y !== undefined) {
+ return get$2(x, y);
+ }
+ if (x !== undefined) {
+ // PImage.get() was called, return a new PImage
+ return get$5(0, 0, x.width, x.height, x);
+ }
+
+ return get$4(0, 0, p.width, p.height);
+ };
+
+ /**
+ * Creates and returns a new <b>PGraphics</b> object of the types P2D, P3D, and JAVA2D. Use this class if you need to draw
+ * into an off-screen graphics buffer. It's not possible to use <b>createGraphics()</b> with OPENGL, because it doesn't
+ * allow offscreen use. The DXF and PDF renderers require the filename parameter. <br /><br /> It's important to call
+ * any drawing commands between beginDraw() and endDraw() statements. This is also true for any commands that affect
+ * drawing, such as smooth() or colorMode().<br /><br /> Unlike the main drawing surface which is completely opaque,
+ * surfaces created with createGraphics() can have transparency. This makes it possible to draw into a graphics and
+ * maintain the alpha channel.
+ *
+ * @param {int} width width in pixels
+ * @param {int} height height in pixels
+ * @param {int} renderer Either P2D, P3D, JAVA2D, PDF, DXF
+ * @param {String} filename the name of the file (not supported yet)
+ */
+ p.createGraphics = function(w, h, render) {
+ var pg = new Processing();
+ pg.size(w, h, render);
+ pg.background(0,0);
+ return pg;
+ };
+
+ // pixels caching
+ function resetContext() {
+ if(isContextReplaced) {
+ curContext = originalContext;
+ isContextReplaced = false;
+
+ p.updatePixels();
+ }
+ }
+ function SetPixelContextWrapper() {
+ function wrapFunction(newContext, name) {
+ function wrapper() {
+ resetContext();
+ curContext[name].apply(curContext, arguments);
+ }
+ newContext[name] = wrapper;
+ }
+ function wrapProperty(newContext, name) {
+ function getter() {
+ resetContext();
+ return curContext[name];
+ }
+ function setter(value) {
+ resetContext();
+ curContext[name] = value;
+ }
+ p.defineProperty(newContext, name, { get: getter, set: setter });
+ }
+ for(var n in curContext) {
+ if(typeof curContext[n] === 'function') {
+ wrapFunction(this, n);
+ } else {
+ wrapProperty(this, n);
+ }
+ }
+ }
+ function replaceContext() {
+ if(isContextReplaced) {
+ return;
+ }
+ p.loadPixels();
+ if(proxyContext === null) {
+ originalContext = curContext;
+ proxyContext = new SetPixelContextWrapper();
+ }
+ isContextReplaced = true;
+ curContext = proxyContext;
+ setPixelsCached = 0;
+ }
+
+ function set$3(x, y, c) {
+ if (x < p.width && x >= 0 && y >= 0 && y < p.height) {
+ replaceContext();
+ p.pixels.setPixel((0|x)+p.width*(0|y), c);
+ if(++setPixelsCached > maxPixelsCached) {
+ resetContext();
+ }
+ }
+ }
+ function set$4(x, y, obj, img) {
+ if (img.isRemote) { // Remote images cannot access imageData
+ throw "Image is loaded remotely. Cannot set x,y.";
+ }
+ var c = p.color.toArray(obj);
+ var offset = y * img.width * 4 + (x*4);
+ var data = img.imageData.data;
+ data[offset] = c[0];
+ data[offset+1] = c[1];
+ data[offset+2] = c[2];
+ data[offset+3] = c[3];
+ }
+
+ // Paints a pixel array into the canvas
+ /**
+ * Changes the color of any pixel or writes an image directly into the display window. The x and y parameters
+ * specify the pixel to change and the color parameter specifies the color value. The color parameter is affected
+ * by the current color mode (the default is RGB values from 0 to 255). When setting an image, the x and y
+ * parameters define the coordinates for the upper-left corner of the image.
+ * Setting the color of a single pixel with set(x, y) is easy, but not as fast as putting the data directly
+ * into pixels[]. The equivalent statement to "set(x, y, #000000)" using pixels[] is "pixels[y*width+x] = #000000".
+ * You must call loadPixels() to load the display window data into the pixels[] array before setting the values
+ * and calling updatePixels() to update the window with any changes. This function ignores imageMode().
+ *
+ * @param {int} x x-coordinate of the pixel
+ * @param {int} y y-coordinate of the pixel
+ * @param {Color} obj any value of the color datatype
+ * @param {PImage} img any valid variable of type PImage
+ *
+ * @see get
+ * @see pixels[]
+ * @see imageMode
+ */
+ p.set = function(x, y, obj, img) {
+ var color, oldFill;
+ if (arguments.length === 3) {
+ // called p.set(), was it with a color or a img ?
+ if (typeof obj === "number") {
+ set$3(x, y, obj);
+ } else if (obj instanceof PImage || obj.__isPImage) {
+ p.image(obj, x, y);
+ }
+ } else if (arguments.length === 4) {
+ // PImage.set(x,y,c) was called, set coordinate x,y color to c of img
+ set$4(x, y, obj, img);
+ }
+ };
+ p.imageData = {};
+
+ // handle the sketch code for pixels[]
+ // parser code converts pixels[] to getPixels() or setPixels(),
+ // .length becomes getLength()
+ /**
+ * Array containing the values for all the pixels in the display window. These values are of the color datatype.
+ * This array is the size of the display window. For example, if the image is 100x100 pixels, there will be 10000
+ * values and if the window is 200x300 pixels, there will be 60000 values. The index value defines the position
+ * of a value within the array. For example, the statment color b = pixels[230] will set the variable b to be
+ * equal to the value at that location in the array.
+ * Before accessing this array, the data must loaded with the loadPixels() function. After the array data has
+ * been modified, the updatePixels() function must be run to update the changes.
+ *
+ * @param {int} index must not exceed the size of the array
+ *
+ * @see loadPixels
+ * @see updatePixels
+ * @see get
+ * @see set
+ * @see PImage
+ */
+ p.pixels = {
+ getLength: function() { return p.imageData.data.length ? p.imageData.data.length/4 : 0; },
+ getPixel: function(i) {
+ var offset = i*4, data = p.imageData.data;
+ return (data[offset+3] << 24) & 0xff000000 |
+ (data[offset+0] << 16) & 0x00ff0000 |
+ (data[offset+1] << 8) & 0x0000ff00 |
+ data[offset+2] & 0x000000ff;
+ },
+ setPixel: function(i,c) {
+ var offset = i*4, data = p.imageData.data;
+ data[offset+0] = (c & 0x00ff0000) >>> 16; // RED_MASK
+ data[offset+1] = (c & 0x0000ff00) >>> 8; // GREEN_MASK
+ data[offset+2] = (c & 0x000000ff); // BLUE_MASK
+ data[offset+3] = (c & 0xff000000) >>> 24; // ALPHA_MASK
+ },
+ toArray: function() {
+ var arr = [], length = p.imageData.width * p.imageData.height, data = p.imageData.data;
+ for (var i = 0, offset = 0; i < length; i++, offset += 4) {
+ arr.push((data[offset+3] << 24) & 0xff000000 |
+ (data[offset+0] << 16) & 0x00ff0000 |
+ (data[offset+1] << 8) & 0x0000ff00 |
+ data[offset+2] & 0x000000ff);
+ }
+ return arr;
+ },
+ set: function(arr) {
+ for (var i = 0, aL = arr.length; i < aL; i++) {
+ this.setPixel(i, arr[i]);
+ }
+ }
+ };
+
+ // Gets a 1-Dimensional pixel array from Canvas
+ /**
+ * Loads the pixel data for the display window into the pixels[] array. This function must always be called
+ * before reading from or writing to pixels[].
+ * Certain renderers may or may not seem to require loadPixels() or updatePixels(). However, the rule is that
+ * any time you want to manipulate the pixels[] array, you must first call loadPixels(), and after changes
+ * have been made, call updatePixels(). Even if the renderer may not seem to use this function in the current
+ * Processing release, this will always be subject to change.
+ *
+ * @see pixels[]
+ * @see updatePixels
+ */
+ p.loadPixels = function() {
+ p.imageData = drawing.$ensureContext().getImageData(0, 0, p.width, p.height);
+ };
+
+ // Draws a 1-Dimensional pixel array to Canvas
+ /**
+ * Updates the display window with the data in the pixels[] array. Use in conjunction with loadPixels(). If
+ * you're only reading pixels from the array, there's no need to call updatePixels() unless there are changes.
+ * Certain renderers may or may not seem to require loadPixels() or updatePixels(). However, the rule is that
+ * any time you want to manipulate the pixels[] array, you must first call loadPixels(), and after changes
+ * have been made, call updatePixels(). Even if the renderer may not seem to use this function in the current
+ * Processing release, this will always be subject to change.
+ * Currently, none of the renderers use the additional parameters to updatePixels(), however this may be
+ * implemented in the future.
+ *
+ * @see loadPixels
+ * @see pixels[]
+ */
+ p.updatePixels = function() {
+ if (p.imageData) {
+ drawing.$ensureContext().putImageData(p.imageData, 0, 0);
+ }
+ };
+
+ /**
+ * Set various hints and hacks for the renderer. This is used to handle obscure rendering features that cannot be
+ * implemented in a consistent manner across renderers. Many options will often graduate to standard features
+ * instead of hints over time.
+ * hint(ENABLE_OPENGL_4X_SMOOTH) - Enable 4x anti-aliasing for OpenGL. This can help force anti-aliasing if
+ * it has not been enabled by the user. On some graphics cards, this can also be set by the graphics driver's
+ * control panel, however not all cards make this available. This hint must be called immediately after the
+ * size() command because it resets the renderer, obliterating any settings and anything drawn (and like size(),
+ * re-running the code that came before it again).
+ * hint(DISABLE_OPENGL_2X_SMOOTH) - In Processing 1.0, Processing always enables 2x smoothing when the OpenGL
+ * renderer is used. This hint disables the default 2x smoothing and returns the smoothing behavior found in
+ * earlier releases, where smooth() and noSmooth() could be used to enable and disable smoothing, though the
+ * quality was inferior.
+ * hint(ENABLE_NATIVE_FONTS) - Use the native version fonts when they are installed, rather than the bitmapped
+ * version from a .vlw file. This is useful with the JAVA2D renderer setting, as it will improve font rendering
+ * speed. This is not enabled by default, because it can be misleading while testing because the type will look
+ * great on your machine (because you have the font installed) but lousy on others' machines if the identical
+ * font is unavailable. This option can only be set per-sketch, and must be called before any use of textFont().
+ * hint(DISABLE_DEPTH_TEST) - Disable the zbuffer, allowing you to draw on top of everything at will. When depth
+ * testing is disabled, items will be drawn to the screen sequentially, like a painting. This hint is most often
+ * used to draw in 3D, then draw in 2D on top of it (for instance, to draw GUI controls in 2D on top of a 3D
+ * interface). Starting in release 0149, this will also clear the depth buffer. Restore the default with
+ * hint(ENABLE_DEPTH_TEST), but note that with the depth buffer cleared, any 3D drawing that happens later in
+ * draw() will ignore existing shapes on the screen.
+ * hint(ENABLE_DEPTH_SORT) - Enable primitive z-sorting of triangles and lines in P3D and OPENGL. This can slow
+ * performance considerably, and the algorithm is not yet perfect. Restore the default with hint(DISABLE_DEPTH_SORT).
+ * hint(DISABLE_OPENGL_ERROR_REPORT) - Speeds up the OPENGL renderer setting by not checking for errors while
+ * running. Undo with hint(ENABLE_OPENGL_ERROR_REPORT).
+ * As of release 0149, unhint() has been removed in favor of adding additional ENABLE/DISABLE constants to reset
+ * the default behavior. This prevents the double negatives, and also reinforces which hints can be enabled or disabled.
+ *
+ * @param {MODE} item constant: name of the hint to be enabled or disabled
+ *
+ * @see PGraphics
+ * @see createGraphics
+ * @see size
+ */
+ p.hint = function(which) {
+ var curContext = drawing.$ensureContext();
+ if (which === PConstants.DISABLE_DEPTH_TEST) {
+ curContext.disable(curContext.DEPTH_TEST);
+ curContext.depthMask(false);
+ curContext.clear(curContext.DEPTH_BUFFER_BIT);
+ }
+ else if (which === PConstants.ENABLE_DEPTH_TEST) {
+ curContext.enable(curContext.DEPTH_TEST);
+ curContext.depthMask(true);
+ }
+ else if (which === PConstants.ENABLE_OPENGL_2X_SMOOTH ||
+ which === PConstants.ENABLE_OPENGL_4X_SMOOTH){
+ renderSmooth = true;
+ }
+ else if (which === PConstants.DISABLE_OPENGL_2X_SMOOTH){
+ renderSmooth = false;
+ }
+ };
+
+ /**
+ * The background() function sets the color used for the background of the Processing window.
+ * The default background is light gray. In the <b>draw()</b> function, the background color is used to clear the display window at the beginning of each frame.
+ * An image can also be used as the background for a sketch, however its width and height must be the same size as the sketch window.
+ * To resize an image 'b' to the size of the sketch window, use b.resize(width, height).
+ * Images used as background will ignore the current <b>tint()</b> setting.
+ * For the main drawing surface, the alpha value will be ignored. However,
+ * alpha can be used on PGraphics objects from <b>createGraphics()</b>. This is
+ * the only way to set all the pixels partially transparent, for instance.
+ * If the 'gray' parameter is passed in the function sets the background to a grayscale value, based on the
+ * current colorMode.
+ * <p>
+ * Note that background() should be called before any transformations occur,
+ * because some implementations may require the current transformation matrix
+ * to be identity before drawing.
+ *
+ * @param {int|float} gray specifies a value between white and black
+ * @param {int|float} value1 red or hue value (depending on the current color mode)
+ * @param {int|float} value2 green or saturation value (depending on the current color mode)
+ * @param {int|float} value3 blue or brightness value (depending on the current color mode)
+ * @param {int|float} alpha opacity of the background
+ * @param {Color} color any value of the color datatype
+ * @param {int} hex color value in hexadecimal notation (i.e. #FFCC00 or 0xFFFFCC00)
+ * @param {PImage} image an instance of a PImage to use as a background
+ *
+ * @see #stroke()
+ * @see #fill()
+ * @see #tint()
+ * @see #colorMode()
+ */
+ var backgroundHelper = function(arg1, arg2, arg3, arg4) {
+ var obj;
+
+ if (arg1 instanceof PImage || arg1.__isPImage) {
+ obj = arg1;
+
+ if (!obj.loaded) {
+ throw "Error using image in background(): PImage not loaded.";
+ }
+ if(obj.width !== p.width || obj.height !== p.height){
+ throw "Background image must be the same dimensions as the canvas.";
+ }
+ } else {
+ obj = p.color(arg1, arg2, arg3, arg4);
+ }
+
+ backgroundObj = obj;
+ };
+
+ Drawing2D.prototype.background = function(arg1, arg2, arg3, arg4) {
+ if (arg1 !== undef) {
+ backgroundHelper(arg1, arg2, arg3, arg4);
+ }
+
+ if (backgroundObj instanceof PImage || backgroundObj.__isPImage) {
+ saveContext();
+ curContext.setTransform(1, 0, 0, 1, 0, 0);
+ p.image(backgroundObj, 0, 0);
+ restoreContext();
+ } else {
+ saveContext();
+ curContext.setTransform(1, 0, 0, 1, 0, 0);
+
+ // If the background is transparent
+ if (p.alpha(backgroundObj) !== colorModeA) {
+ curContext.clearRect(0,0, p.width, p.height);
+ }
+ curContext.fillStyle = p.color.toString(backgroundObj);
+ curContext.fillRect(0, 0, p.width, p.height);
+ isFillDirty = true;
+ restoreContext();
+ }
+ };
+
+ Drawing3D.prototype.background = function(arg1, arg2, arg3, arg4) {
+ if (arguments.length > 0) {
+ backgroundHelper(arg1, arg2, arg3, arg4);
+ }
+
+ var c = p.color.toGLArray(backgroundObj);
+ curContext.clearColor(c[0], c[1], c[2], c[3]);
+ curContext.clear(curContext.COLOR_BUFFER_BIT | curContext.DEPTH_BUFFER_BIT);
+
+ // An image as a background in 3D is not implemented yet
+ };
+
+ // Draws an image to the Canvas
+ /**
+ * Displays images to the screen. The images must be in the sketch's "data" directory to load correctly. Select "Add
+ * file..." from the "Sketch" menu to add the image. Processing currently works with GIF, JPEG, and Targa images. The
+ * color of an image may be modified with the tint() function and if a GIF has transparency, it will maintain its
+ * transparency. The img parameter specifies the image to display and the x and y parameters define the location of
+ * the image from its upper-left corner. The image is displayed at its original size unless the width and height
+ * parameters specify a different size. The imageMode() function changes the way the parameters work. A call to
+ * imageMode(CORNERS) will change the width and height parameters to define the x and y values of the opposite
+ * corner of the image.
+ *
+ * @param {PImage} img the image to display
+ * @param {int|float} x x-coordinate of the image
+ * @param {int|float} y y-coordinate of the image
+ * @param {int|float} width width to display the image
+ * @param {int|float} height height to display the image
+ *
+ * @see loadImage
+ * @see PImage
+ * @see imageMode
+ * @see tint
+ * @see background
+ * @see alpha
+ */
+ Drawing2D.prototype.image = function(img, x, y, w, h) {
+ // Fix fractional positions
+ x = Math.round(x);
+ y = Math.round(y);
+
+ if (img.width > 0) {
+ var wid = w || img.width;
+ var hgt = h || img.height;
+
+ var bounds = imageModeConvert(x || 0, y || 0, w || img.width, h || img.height, arguments.length < 4);
+ var fastImage = !!img.sourceImg && curTint === null;
+ if (fastImage) {
+ var htmlElement = img.sourceImg;
+ if (img.__isDirty) {
+ img.updatePixels();
+ }
+ // Using HTML element's width and height in case if the image was resized.
+ curContext.drawImage(htmlElement, 0, 0,
+ htmlElement.width, htmlElement.height, bounds.x, bounds.y, bounds.w, bounds.h);
+ } else {
+ var obj = img.toImageData();
+
+ // Tint the image
+ if (curTint !== null) {
+ curTint(obj);
+ img.__isDirty = true;
+ }
+
+ curContext.drawImage(getCanvasData(obj).canvas, 0, 0,
+ img.width, img.height, bounds.x, bounds.y, bounds.w, bounds.h);
+ }
+ }
+ };
+
+ Drawing3D.prototype.image = function(img, x, y, w, h) {
+ if (img.width > 0) {
+ // Fix fractional positions
+ x = Math.round(x);
+ y = Math.round(y);
+ w = w || img.width;
+ h = h || img.height;
+
+ p.beginShape(p.QUADS);
+ p.texture(img);
+ p.vertex(x, y, 0, 0, 0);
+ p.vertex(x, y+h, 0, 0, h);
+ p.vertex(x+w, y+h, 0, w, h);
+ p.vertex(x+w, y, 0, w, 0);
+ p.endShape();
+ }
+ };
+
+ /**
+ * The tint() function sets the fill value for displaying images. Images can be tinted to
+ * specified colors or made transparent by setting the alpha.
+ * <br><br>To make an image transparent, but not change it's color,
+ * use white as the tint color and specify an alpha value. For instance,
+ * tint(255, 128) will make an image 50% transparent (unless
+ * <b>colorMode()</b> has been used).
+ *
+ * <br><br>When using hexadecimal notation to specify a color, use "#" or
+ * "0x" before the values (e.g. #CCFFAA, 0xFFCCFFAA). The # syntax uses six
+ * digits to specify a color (the way colors are specified in HTML and CSS).
+ * When using the hexadecimal notation starting with "0x", the hexadecimal
+ * value must be specified with eight characters; the first two characters
+ * define the alpha component and the remainder the red, green, and blue
+ * components.
+ * <br><br>The value for the parameter "gray" must be less than or equal
+ * to the current maximum value as specified by <b>colorMode()</b>.
+ * The default maximum value is 255.
+ * <br><br>The tint() method is also used to control the coloring of
+ * textures in 3D.
+ *
+ * @param {int|float} gray any valid number
+ * @param {int|float} alpha opacity of the image
+ * @param {int|float} value1 red or hue value
+ * @param {int|float} value2 green or saturation value
+ * @param {int|float} value3 blue or brightness value
+ * @param {int|float} color any value of the color datatype
+ * @param {int} hex color value in hexadecimal notation (i.e. #FFCC00 or 0xFFFFCC00)
+ *
+ * @see #noTint()
+ * @see #image()
+ */
+ p.tint = function(a1, a2, a3, a4) {
+ var tintColor = p.color(a1, a2, a3, a4);
+ var r = p.red(tintColor) / colorModeX;
+ var g = p.green(tintColor) / colorModeY;
+ var b = p.blue(tintColor) / colorModeZ;
+ var a = p.alpha(tintColor) / colorModeA;
+ curTint = function(obj) {
+ var data = obj.data,
+ length = 4 * obj.width * obj.height;
+ for (var i = 0; i < length;) {
+ data[i++] *= r;
+ data[i++] *= g;
+ data[i++] *= b;
+ data[i++] *= a;
+ }
+ };
+ // for overriding the color buffer when 3d rendering
+ curTint3d = function(data){
+ for (var i = 0; i < data.length;) {
+ data[i++] = r;
+ data[i++] = g;
+ data[i++] = b;
+ data[i++] = a;
+ }
+ };
+ };
+
+ /**
+ * The noTint() function removes the current fill value for displaying images and reverts to displaying images with their original hues.
+ *
+ * @see #tint()
+ * @see #image()
+ */
+ p.noTint = function() {
+ curTint = null;
+ curTint3d = null;
+ };
+
+ /**
+ * Copies a region of pixels from the display window to another area of the display window and copies a region of pixels from an
+ * image used as the srcImg parameter into the display window. If the source and destination regions aren't the same size, it will
+ * automatically resize the source pixels to fit the specified target region. No alpha information is used in the process, however
+ * if the source image has an alpha channel set, it will be copied as well. This function ignores imageMode().
+ *
+ * @param {int} x X coordinate of the source's upper left corner
+ * @param {int} y Y coordinate of the source's upper left corner
+ * @param {int} width source image width
+ * @param {int} height source image height
+ * @param {int} dx X coordinate of the destination's upper left corner
+ * @param {int} dy Y coordinate of the destination's upper left corner
+ * @param {int} dwidth destination image width
+ * @param {int} dheight destination image height
+ * @param {PImage} srcImg image variable referring to the source image
+ *
+ * @see blend
+ * @see get
+ */
+ p.copy = function(src, sx, sy, sw, sh, dx, dy, dw, dh) {
+ if (dh === undef) {
+ // shift everything, and introduce p
+ dh = dw;
+ dw = dy;
+ dy = dx;
+ dx = sh;
+ sh = sw;
+ sw = sy;
+ sy = sx;
+ sx = src;
+ src = p;
+ }
+ p.blend(src, sx, sy, sw, sh, dx, dy, dw, dh, PConstants.REPLACE);
+ };
+
+ /**
+ * Blends a region of pixels from one image into another (or in itself again) with full alpha channel support. There
+ * is a choice of the following modes to blend the source pixels (A) with the ones of pixels in the destination image (B):
+ * BLEND - linear interpolation of colours: C = A*factor + B
+ * ADD - additive blending with white clip: C = min(A*factor + B, 255)
+ * SUBTRACT - subtractive blending with black clip: C = max(B - A*factor, 0)
+ * DARKEST - only the darkest colour succeeds: C = min(A*factor, B)
+ * LIGHTEST - only the lightest colour succeeds: C = max(A*factor, B)
+ * DIFFERENCE - subtract colors from underlying image.
+ * EXCLUSION - similar to DIFFERENCE, but less extreme.
+ * MULTIPLY - Multiply the colors, result will always be darker.
+ * SCREEN - Opposite multiply, uses inverse values of the colors.
+ * OVERLAY - A mix of MULTIPLY and SCREEN. Multiplies dark values, and screens light values.
+ * HARD_LIGHT - SCREEN when greater than 50% gray, MULTIPLY when lower.
+ * SOFT_LIGHT - Mix of DARKEST and LIGHTEST. Works like OVERLAY, but not as harsh.
+ * DODGE - Lightens light tones and increases contrast, ignores darks. Called "Color Dodge" in Illustrator and Photoshop.
+ * BURN - Darker areas are applied, increasing contrast, ignores lights. Called "Color Burn" in Illustrator and Photoshop.
+ * All modes use the alpha information (highest byte) of source image pixels as the blending factor. If the source and
+ * destination regions are different sizes, the image will be automatically resized to match the destination size. If the
+ * srcImg parameter is not used, the display window is used as the source image. This function ignores imageMode().
+ *
+ * @param {int} x X coordinate of the source's upper left corner
+ * @param {int} y Y coordinate of the source's upper left corner
+ * @param {int} width source image width
+ * @param {int} height source image height
+ * @param {int} dx X coordinate of the destination's upper left corner
+ * @param {int} dy Y coordinate of the destination's upper left corner
+ * @param {int} dwidth destination image width
+ * @param {int} dheight destination image height
+ * @param {PImage} srcImg image variable referring to the source image
+ * @param {PImage} MODE Either BLEND, ADD, SUBTRACT, LIGHTEST, DARKEST, DIFFERENCE, EXCLUSION, MULTIPLY, SCREEN,
+ * OVERLAY, HARD_LIGHT, SOFT_LIGHT, DODGE, BURN
+ * @see filter
+ */
+ p.blend = function(src, sx, sy, sw, sh, dx, dy, dw, dh, mode, pimgdest) {
+ if (src.isRemote) {
+ throw "Image is loaded remotely. Cannot blend image.";
+ }
+
+ if (mode === undef) {
+ // shift everything, and introduce p
+ mode = dh;
+ dh = dw;
+ dw = dy;
+ dy = dx;
+ dx = sh;
+ sh = sw;
+ sw = sy;
+ sy = sx;
+ sx = src;
+ src = p;
+ }
+
+ var sx2 = sx + sw,
+ sy2 = sy + sh,
+ dx2 = dx + dw,
+ dy2 = dy + dh,
+ dest = pimgdest || p;
+
+ // check if pimgdest is there and pixels, if so this was a call from pimg.blend
+ if (pimgdest === undef || mode === undef) {
+ p.loadPixels();
+ }
+
+ src.loadPixels();
+
+ if (src === p && p.intersect(sx, sy, sx2, sy2, dx, dy, dx2, dy2)) {
+ p.blit_resize(p.get(sx, sy, sx2 - sx, sy2 - sy), 0, 0, sx2 - sx - 1, sy2 - sy - 1,
+ dest.imageData.data, dest.width, dest.height, dx, dy, dx2, dy2, mode);
+ } else {
+ p.blit_resize(src, sx, sy, sx2, sy2, dest.imageData.data, dest.width, dest.height, dx, dy, dx2, dy2, mode);
+ }
+
+ if (pimgdest === undef) {
+ p.updatePixels();
+ }
+ };
+
+ // helper function for filter()
+ var buildBlurKernel = function(r) {
+ var radius = p.floor(r * 3.5), i;
+ radius = (radius < 1) ? 1 : ((radius < 248) ? radius : 248);
+ if (p.shared.blurRadius !== radius) {
+ p.shared.blurRadius = radius;
+ p.shared.blurKernelSize = 1 + (p.shared.blurRadius<<1);
+ p.shared.blurKernel = new Float32Array(p.shared.blurKernelSize);
+ var sharedBlurKernal = p.shared.blurKernel;
+ var sharedBlurKernelSize = p.shared.blurKernelSize;
+ var sharedBlurRadius = p.shared.blurRadius;
+ // init blurKernel
+ for (i = 0; i < sharedBlurKernelSize; i++) {
+ sharedBlurKernal[i] = 0;
+ }
+ var radiusiSquared = (radius - 1) * (radius - 1);
+ for (i = 1; i < radius; i++) {
+ sharedBlurKernal[radius + i] = sharedBlurKernal[radius-i] = radiusiSquared;
+ }
+ sharedBlurKernal[radius] = radius * radius;
+ }
+ };
+
+ var blurARGB = function(r, aImg) {
+ var sum, cr, cg, cb, ca, c, m;
+ var read, ri, ym, ymi, bk0;
+ var wh = aImg.pixels.getLength();
+ var r2 = new Float32Array(wh);
+ var g2 = new Float32Array(wh);
+ var b2 = new Float32Array(wh);
+ var a2 = new Float32Array(wh);
+ var yi = 0;
+ var x, y, i, offset;
+
+ buildBlurKernel(r);
+
+ var aImgHeight = aImg.height;
+ var aImgWidth = aImg.width;
+ var sharedBlurKernelSize = p.shared.blurKernelSize;
+ var sharedBlurRadius = p.shared.blurRadius;
+ var sharedBlurKernal = p.shared.blurKernel;
+ var pix = aImg.imageData.data;
+
+ for (y = 0; y < aImgHeight; y++) {
+ for (x = 0; x < aImgWidth; x++) {
+ cb = cg = cr = ca = sum = 0;
+ read = x - sharedBlurRadius;
+ if (read<0) {
+ bk0 = -read;
+ read = 0;
+ } else {
+ if (read >= aImgWidth) {
+ break;
+ }
+ bk0=0;
+ }
+ for (i = bk0; i < sharedBlurKernelSize; i++) {
+ if (read >= aImgWidth) {
+ break;
+ }
+ offset = (read + yi) *4;
+ m = sharedBlurKernal[i];
+ ca += m * pix[offset + 3];
+ cr += m * pix[offset];
+ cg += m * pix[offset + 1];
+ cb += m * pix[offset + 2];
+ sum += m;
+ read++;
+ }
+ ri = yi + x;
+ a2[ri] = ca / sum;
+ r2[ri] = cr / sum;
+ g2[ri] = cg / sum;
+ b2[ri] = cb / sum;
+ }
+ yi += aImgWidth;
+ }
+
+ yi = 0;
+ ym = -sharedBlurRadius;
+ ymi = ym*aImgWidth;
+
+ for (y = 0; y < aImgHeight; y++) {
+ for (x = 0; x < aImgWidth; x++) {
+ cb = cg = cr = ca = sum = 0;
+ if (ym<0) {
+ bk0 = ri = -ym;
+ read = x;
+ } else {
+ if (ym >= aImgHeight) {
+ break;
+ }
+ bk0 = 0;
+ ri = ym;
+ read = x + ymi;
+ }
+ for (i = bk0; i < sharedBlurKernelSize; i++) {
+ if (ri >= aImgHeight) {
+ break;
+ }
+ m = sharedBlurKernal[i];
+ ca += m * a2[read];
+ cr += m * r2[read];
+ cg += m * g2[read];
+ cb += m * b2[read];
+ sum += m;
+ ri++;
+ read += aImgWidth;
+ }
+ offset = (x + yi) *4;
+ pix[offset] = cr / sum;
+ pix[offset + 1] = cg / sum;
+ pix[offset + 2] = cb / sum;
+ pix[offset + 3] = ca / sum;
+ }
+ yi += aImgWidth;
+ ymi += aImgWidth;
+ ym++;
+ }
+ };
+
+ // helper funtion for ERODE and DILATE modes of filter()
+ var dilate = function(isInverted, aImg) {
+ var currIdx = 0;
+ var maxIdx = aImg.pixels.getLength();
+ var out = new Int32Array(maxIdx);
+ var currRowIdx, maxRowIdx, colOrig, colOut, currLum;
+ var idxRight, idxLeft, idxUp, idxDown,
+ colRight, colLeft, colUp, colDown,
+ lumRight, lumLeft, lumUp, lumDown;
+
+ if (!isInverted) {
+ // erosion (grow light areas)
+ while (currIdx<maxIdx) {
+ currRowIdx = currIdx;
+ maxRowIdx = currIdx + aImg.width;
+ while (currIdx < maxRowIdx) {
+ colOrig = colOut = aImg.pixels.getPixel(currIdx);
+ idxLeft = currIdx - 1;
+ idxRight = currIdx + 1;
+ idxUp = currIdx - aImg.width;
+ idxDown = currIdx + aImg.width;
+ if (idxLeft < currRowIdx) {
+ idxLeft = currIdx;
+ }
+ if (idxRight >= maxRowIdx) {
+ idxRight = currIdx;
+ }
+ if (idxUp < 0) {
+ idxUp = 0;
+ }
+ if (idxDown >= maxIdx) {
+ idxDown = currIdx;
+ }
+ colUp = aImg.pixels.getPixel(idxUp);
+ colLeft = aImg.pixels.getPixel(idxLeft);
+ colDown = aImg.pixels.getPixel(idxDown);
+ colRight = aImg.pixels.getPixel(idxRight);
+
+ // compute luminance
+ currLum = 77*(colOrig>>16&0xff) + 151*(colOrig>>8&0xff) + 28*(colOrig&0xff);
+ lumLeft = 77*(colLeft>>16&0xff) + 151*(colLeft>>8&0xff) + 28*(colLeft&0xff);
+ lumRight = 77*(colRight>>16&0xff) + 151*(colRight>>8&0xff) + 28*(colRight&0xff);
+ lumUp = 77*(colUp>>16&0xff) + 151*(colUp>>8&0xff) + 28*(colUp&0xff);
+ lumDown = 77*(colDown>>16&0xff) + 151*(colDown>>8&0xff) + 28*(colDown&0xff);
+
+ if (lumLeft > currLum) {
+ colOut = colLeft;
+ currLum = lumLeft;
+ }
+ if (lumRight > currLum) {
+ colOut = colRight;
+ currLum = lumRight;
+ }
+ if (lumUp > currLum) {
+ colOut = colUp;
+ currLum = lumUp;
+ }
+ if (lumDown > currLum) {
+ colOut = colDown;
+ currLum = lumDown;
+ }
+ out[currIdx++] = colOut;
+ }
+ }
+ } else {
+ // dilate (grow dark areas)
+ while (currIdx < maxIdx) {
+ currRowIdx = currIdx;
+ maxRowIdx = currIdx + aImg.width;
+ while (currIdx < maxRowIdx) {
+ colOrig = colOut = aImg.pixels.getPixel(currIdx);
+ idxLeft = currIdx - 1;
+ idxRight = currIdx + 1;
+ idxUp = currIdx - aImg.width;
+ idxDown = currIdx + aImg.width;
+ if (idxLeft < currRowIdx) {
+ idxLeft = currIdx;
+ }
+ if (idxRight >= maxRowIdx) {
+ idxRight = currIdx;
+ }
+ if (idxUp < 0) {
+ idxUp = 0;
+ }
+ if (idxDown >= maxIdx) {
+ idxDown = currIdx;
+ }
+ colUp = aImg.pixels.getPixel(idxUp);
+ colLeft = aImg.pixels.getPixel(idxLeft);
+ colDown = aImg.pixels.getPixel(idxDown);
+ colRight = aImg.pixels.getPixel(idxRight);
+
+ // compute luminance
+ currLum = 77*(colOrig>>16&0xff) + 151*(colOrig>>8&0xff) + 28*(colOrig&0xff);
+ lumLeft = 77*(colLeft>>16&0xff) + 151*(colLeft>>8&0xff) + 28*(colLeft&0xff);
+ lumRight = 77*(colRight>>16&0xff) + 151*(colRight>>8&0xff) + 28*(colRight&0xff);
+ lumUp = 77*(colUp>>16&0xff) + 151*(colUp>>8&0xff) + 28*(colUp&0xff);
+ lumDown = 77*(colDown>>16&0xff) + 151*(colDown>>8&0xff) + 28*(colDown&0xff);
+
+ if (lumLeft < currLum) {
+ colOut = colLeft;
+ currLum = lumLeft;
+ }
+ if (lumRight < currLum) {
+ colOut = colRight;
+ currLum = lumRight;
+ }
+ if (lumUp < currLum) {
+ colOut = colUp;
+ currLum = lumUp;
+ }
+ if (lumDown < currLum) {
+ colOut = colDown;
+ currLum = lumDown;
+ }
+ out[currIdx++]=colOut;
+ }
+ }
+ }
+ aImg.pixels.set(out);
+ //p.arraycopy(out,0,pixels,0,maxIdx);
+ };
+
+ /**
+ * Filters the display window as defined by one of the following modes:
+ * THRESHOLD - converts the image to black and white pixels depending if they are above or below the threshold
+ * defined by the level parameter. The level must be between 0.0 (black) and 1.0(white). If no level is specified, 0.5 is used.
+ * GRAY - converts any colors in the image to grayscale equivalents
+ * INVERT - sets each pixel to its inverse value
+ * POSTERIZE - limits each channel of the image to the number of colors specified as the level parameter
+ * BLUR - executes a Guassian blur with the level parameter specifying the extent of the blurring. If no level parameter is
+ * used, the blur is equivalent to Guassian blur of radius 1.
+ * OPAQUE - sets the alpha channel to entirely opaque.
+ * ERODE - reduces the light areas with the amount defined by the level parameter.
+ * DILATE - increases the light areas with the amount defined by the level parameter.
+ *
+ * @param {MODE} MODE Either THRESHOLD, GRAY, INVERT, POSTERIZE, BLUR, OPAQUE, ERODE, or DILATE
+ * @param {int|float} level defines the quality of the filter
+ *
+ * @see blend
+ */
+ p.filter = function(kind, param, aImg){
+ var img, col, lum, i;
+
+ if (arguments.length === 3) {
+ aImg.loadPixels();
+ img = aImg;
+ } else {
+ p.loadPixels();
+ img = p;
+ }
+
+ if (param === undef) {
+ param = null;
+ }
+ if (img.isRemote) { // Remote images cannot access imageData
+ throw "Image is loaded remotely. Cannot filter image.";
+ }
+ // begin filter process
+ var imglen = img.pixels.getLength();
+ switch (kind) {
+ case PConstants.BLUR:
+ var radius = param || 1; // if no param specified, use 1 (default for p5)
+ blurARGB(radius, img);
+ break;
+
+ case PConstants.GRAY:
+ if (img.format === PConstants.ALPHA) { //trouble
+ // for an alpha image, convert it to an opaque grayscale
+ for (i = 0; i < imglen; i++) {
+ col = 255 - img.pixels.getPixel(i);
+ img.pixels.setPixel(i,(0xff000000 | (col << 16) | (col << 8) | col));
+ }
+ img.format = PConstants.RGB; //trouble
+ } else {
+ for (i = 0; i < imglen; i++) {
+ col = img.pixels.getPixel(i);
+ lum = (77*(col>>16&0xff) + 151*(col>>8&0xff) + 28*(col&0xff))>>8;
+ img.pixels.setPixel(i,((col & PConstants.ALPHA_MASK) | lum<<16 | lum<<8 | lum));
+ }
+ }
+ break;
+
+ case PConstants.INVERT:
+ for (i = 0; i < imglen; i++) {
+ img.pixels.setPixel(i, (img.pixels.getPixel(i) ^ 0xffffff));
+ }
+ break;
+
+ case PConstants.POSTERIZE:
+ if (param === null) {
+ throw "Use filter(POSTERIZE, int levels) instead of filter(POSTERIZE)";
+ }
+ var levels = p.floor(param);
+ if ((levels < 2) || (levels > 255)) {
+ throw "Levels must be between 2 and 255 for filter(POSTERIZE, levels)";
+ }
+ var levels1 = levels - 1;
+ for (i = 0; i < imglen; i++) {
+ var rlevel = (img.pixels.getPixel(i) >> 16) & 0xff;
+ var glevel = (img.pixels.getPixel(i) >> 8) & 0xff;
+ var blevel = img.pixels.getPixel(i) & 0xff;
+ rlevel = (((rlevel * levels) >> 8) * 255) / levels1;
+ glevel = (((glevel * levels) >> 8) * 255) / levels1;
+ blevel = (((blevel * levels) >> 8) * 255) / levels1;
+ img.pixels.setPixel(i, ((0xff000000 & img.pixels.getPixel(i)) | (rlevel << 16) | (glevel << 8) | blevel));
+ }
+ break;
+
+ case PConstants.OPAQUE:
+ for (i = 0; i < imglen; i++) {
+ img.pixels.setPixel(i, (img.pixels.getPixel(i) | 0xff000000));
+ }
+ img.format = PConstants.RGB; //trouble
+ break;
+
+ case PConstants.THRESHOLD:
+ if (param === null) {
+ param = 0.5;
+ }
+ if ((param < 0) || (param > 1)) {
+ throw "Level must be between 0 and 1 for filter(THRESHOLD, level)";
+ }
+ var thresh = p.floor(param * 255);
+ for (i = 0; i < imglen; i++) {
+ var max = p.max((img.pixels.getPixel(i) & PConstants.RED_MASK) >> 16, p.max((img.pixels.getPixel(i) & PConstants.GREEN_MASK) >> 8, (img.pixels.getPixel(i) & PConstants.BLUE_MASK)));
+ img.pixels.setPixel(i, ((img.pixels.getPixel(i) & PConstants.ALPHA_MASK) | ((max < thresh) ? 0x000000 : 0xffffff)));
+ }
+ break;
+
+ case PConstants.ERODE:
+ dilate(true, img);
+ break;
+
+ case PConstants.DILATE:
+ dilate(false, img);
+ break;
+ }
+ img.updatePixels();
+ };
+
+
+ // shared variables for blit_resize(), filter_new_scanline(), filter_bilinear(), filter()
+ // change this in the future to not be exposed to p
+ p.shared = {
+ fracU: 0,
+ ifU: 0,
+ fracV: 0,
+ ifV: 0,
+ u1: 0,
+ u2: 0,
+ v1: 0,
+ v2: 0,
+ sX: 0,
+ sY: 0,
+ iw: 0,
+ iw1: 0,
+ ih1: 0,
+ ul: 0,
+ ll: 0,
+ ur: 0,
+ lr: 0,
+ cUL: 0,
+ cLL: 0,
+ cUR: 0,
+ cLR: 0,
+ srcXOffset: 0,
+ srcYOffset: 0,
+ r: 0,
+ g: 0,
+ b: 0,
+ a: 0,
+ srcBuffer: null,
+ blurRadius: 0,
+ blurKernelSize: 0,
+ blurKernel: null
+ };
+
+ p.intersect = function(sx1, sy1, sx2, sy2, dx1, dy1, dx2, dy2) {
+ var sw = sx2 - sx1 + 1;
+ var sh = sy2 - sy1 + 1;
+ var dw = dx2 - dx1 + 1;
+ var dh = dy2 - dy1 + 1;
+ if (dx1 < sx1) {
+ dw += dx1 - sx1;
+ if (dw > sw) {
+ dw = sw;
+ }
+ } else {
+ var w = sw + sx1 - dx1;
+ if (dw > w) {
+ dw = w;
+ }
+ }
+ if (dy1 < sy1) {
+ dh += dy1 - sy1;
+ if (dh > sh) {
+ dh = sh;
+ }
+ } else {
+ var h = sh + sy1 - dy1;
+ if (dh > h) {
+ dh = h;
+ }
+ }
+ return ! (dw <= 0 || dh <= 0);
+ };
+
+ var blendFuncs = {};
+ blendFuncs[PConstants.BLEND] = p.modes.blend;
+ blendFuncs[PConstants.ADD] = p.modes.add;
+ blendFuncs[PConstants.SUBTRACT] = p.modes.subtract;
+ blendFuncs[PConstants.LIGHTEST] = p.modes.lightest;
+ blendFuncs[PConstants.DARKEST] = p.modes.darkest;
+ blendFuncs[PConstants.REPLACE] = p.modes.replace;
+ blendFuncs[PConstants.DIFFERENCE] = p.modes.difference;
+ blendFuncs[PConstants.EXCLUSION] = p.modes.exclusion;
+ blendFuncs[PConstants.MULTIPLY] = p.modes.multiply;
+ blendFuncs[PConstants.SCREEN] = p.modes.screen;
+ blendFuncs[PConstants.OVERLAY] = p.modes.overlay;
+ blendFuncs[PConstants.HARD_LIGHT] = p.modes.hard_light;
+ blendFuncs[PConstants.SOFT_LIGHT] = p.modes.soft_light;
+ blendFuncs[PConstants.DODGE] = p.modes.dodge;
+ blendFuncs[PConstants.BURN] = p.modes.burn;
+
+ p.blit_resize = function(img, srcX1, srcY1, srcX2, srcY2, destPixels,
+ screenW, screenH, destX1, destY1, destX2, destY2, mode) {
+ var x, y;
+ if (srcX1 < 0) {
+ srcX1 = 0;
+ }
+ if (srcY1 < 0) {
+ srcY1 = 0;
+ }
+ if (srcX2 >= img.width) {
+ srcX2 = img.width - 1;
+ }
+ if (srcY2 >= img.height) {
+ srcY2 = img.height - 1;
+ }
+ var srcW = srcX2 - srcX1;
+ var srcH = srcY2 - srcY1;
+ var destW = destX2 - destX1;
+ var destH = destY2 - destY1;
+
+ if (destW <= 0 || destH <= 0 || srcW <= 0 || srcH <= 0 || destX1 >= screenW ||
+ destY1 >= screenH || srcX1 >= img.width || srcY1 >= img.height) {
+ return;
+ }
+
+ var dx = Math.floor(srcW / destW * PConstants.PRECISIONF);
+ var dy = Math.floor(srcH / destH * PConstants.PRECISIONF);
+
+ var pshared = p.shared;
+
+ pshared.srcXOffset = Math.floor(destX1 < 0 ? -destX1 * dx : srcX1 * PConstants.PRECISIONF);
+ pshared.srcYOffset = Math.floor(destY1 < 0 ? -destY1 * dy : srcY1 * PConstants.PRECISIONF);
+ if (destX1 < 0) {
+ destW += destX1;
+ destX1 = 0;
+ }
+ if (destY1 < 0) {
+ destH += destY1;
+ destY1 = 0;
+ }
+ destW = Math.min(destW, screenW - destX1);
+ destH = Math.min(destH, screenH - destY1);
+
+ var destOffset = destY1 * screenW + destX1;
+ var destColor;
+
+ pshared.srcBuffer = img.imageData.data;
+ pshared.iw = img.width;
+ pshared.iw1 = img.width - 1;
+ pshared.ih1 = img.height - 1;
+
+ // cache for speed
+ var filterBilinear = p.filter_bilinear,
+ filterNewScanline = p.filter_new_scanline,
+ blendFunc = blendFuncs[mode],
+ blendedColor,
+ idx,
+ cULoffset,
+ cURoffset,
+ cLLoffset,
+ cLRoffset,
+ ALPHA_MASK = PConstants.ALPHA_MASK,
+ RED_MASK = PConstants.RED_MASK,
+ GREEN_MASK = PConstants.GREEN_MASK,
+ BLUE_MASK = PConstants.BLUE_MASK,
+ PREC_MAXVAL = PConstants.PREC_MAXVAL,
+ PRECISIONB = PConstants.PRECISIONB,
+ PREC_RED_SHIFT = PConstants.PREC_RED_SHIFT,
+ PREC_ALPHA_SHIFT = PConstants.PREC_ALPHA_SHIFT,
+ srcBuffer = pshared.srcBuffer,
+ min = Math.min;
+
+ for (y = 0; y < destH; y++) {
+
+ pshared.sX = pshared.srcXOffset;
+ pshared.fracV = pshared.srcYOffset & PREC_MAXVAL;
+ pshared.ifV = PREC_MAXVAL - pshared.fracV;
+ pshared.v1 = (pshared.srcYOffset >> PRECISIONB) * pshared.iw;
+ pshared.v2 = min((pshared.srcYOffset >> PRECISIONB) + 1, pshared.ih1) * pshared.iw;
+
+ for (x = 0; x < destW; x++) {
+ idx = (destOffset + x) * 4;
+
+ destColor = (destPixels[idx + 3] << 24) &
+ ALPHA_MASK | (destPixels[idx] << 16) &
+ RED_MASK | (destPixels[idx + 1] << 8) &
+ GREEN_MASK | destPixels[idx + 2] & BLUE_MASK;
+
+ pshared.fracU = pshared.sX & PREC_MAXVAL;
+ pshared.ifU = PREC_MAXVAL - pshared.fracU;
+ pshared.ul = (pshared.ifU * pshared.ifV) >> PRECISIONB;
+ pshared.ll = (pshared.ifU * pshared.fracV) >> PRECISIONB;
+ pshared.ur = (pshared.fracU * pshared.ifV) >> PRECISIONB;
+ pshared.lr = (pshared.fracU * pshared.fracV) >> PRECISIONB;
+ pshared.u1 = (pshared.sX >> PRECISIONB);
+ pshared.u2 = min(pshared.u1 + 1, pshared.iw1);
+
+ cULoffset = (pshared.v1 + pshared.u1) * 4;
+ cURoffset = (pshared.v1 + pshared.u2) * 4;
+ cLLoffset = (pshared.v2 + pshared.u1) * 4;
+ cLRoffset = (pshared.v2 + pshared.u2) * 4;
+
+ pshared.cUL = (srcBuffer[cULoffset + 3] << 24) &
+ ALPHA_MASK | (srcBuffer[cULoffset] << 16) &
+ RED_MASK | (srcBuffer[cULoffset + 1] << 8) &
+ GREEN_MASK | srcBuffer[cULoffset + 2] & BLUE_MASK;
+
+ pshared.cUR = (srcBuffer[cURoffset + 3] << 24) &
+ ALPHA_MASK | (srcBuffer[cURoffset] << 16) &
+ RED_MASK | (srcBuffer[cURoffset + 1] << 8) &
+ GREEN_MASK | srcBuffer[cURoffset + 2] & BLUE_MASK;
+
+ pshared.cLL = (srcBuffer[cLLoffset + 3] << 24) &
+ ALPHA_MASK | (srcBuffer[cLLoffset] << 16) &
+ RED_MASK | (srcBuffer[cLLoffset + 1] << 8) &
+ GREEN_MASK | srcBuffer[cLLoffset + 2] & BLUE_MASK;
+
+ pshared.cLR = (srcBuffer[cLRoffset + 3] << 24) &
+ ALPHA_MASK | (srcBuffer[cLRoffset] << 16) &
+ RED_MASK | (srcBuffer[cLRoffset + 1] << 8) &
+ GREEN_MASK | srcBuffer[cLRoffset + 2] & BLUE_MASK;
+
+ pshared.r = ((pshared.ul * ((pshared.cUL & RED_MASK) >> 16) +
+ pshared.ll * ((pshared.cLL & RED_MASK) >> 16) +
+ pshared.ur * ((pshared.cUR & RED_MASK) >> 16) +
+ pshared.lr * ((pshared.cLR & RED_MASK) >> 16)) << PREC_RED_SHIFT) & RED_MASK;
+ pshared.g = ((pshared.ul * (pshared.cUL & GREEN_MASK) +
+ pshared.ll * (pshared.cLL & GREEN_MASK) +
+ pshared.ur * (pshared.cUR & GREEN_MASK) +
+ pshared.lr * (pshared.cLR & GREEN_MASK)) >>> PRECISIONB) & GREEN_MASK;
+ pshared.b = (pshared.ul * (pshared.cUL & BLUE_MASK) +
+ pshared.ll * (pshared.cLL & BLUE_MASK) +
+ pshared.ur * (pshared.cUR & BLUE_MASK) +
+ pshared.lr * (pshared.cLR & BLUE_MASK)) >>> PRECISIONB;
+ pshared.a = ((pshared.ul * ((pshared.cUL & ALPHA_MASK) >>> 24) +
+ pshared.ll * ((pshared.cLL & ALPHA_MASK) >>> 24) +
+ pshared.ur * ((pshared.cUR & ALPHA_MASK) >>> 24) +
+ pshared.lr * ((pshared.cLR & ALPHA_MASK) >>> 24)) << PREC_ALPHA_SHIFT) & ALPHA_MASK;
+
+ blendedColor = blendFunc(destColor, (pshared.a | pshared.r | pshared.g | pshared.b));
+
+ destPixels[idx] = (blendedColor & RED_MASK) >>> 16;
+ destPixels[idx + 1] = (blendedColor & GREEN_MASK) >>> 8;
+ destPixels[idx + 2] = (blendedColor & BLUE_MASK);
+ destPixels[idx + 3] = (blendedColor & ALPHA_MASK) >>> 24;
+
+ pshared.sX += dx;
+ }
+ destOffset += screenW;
+ pshared.srcYOffset += dy;
+ }
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // Font handling
+ ////////////////////////////////////////////////////////////////////////////
+
+ /**
+ * loadFont() Loads a font into a variable of type PFont.
+ *
+ * @param {String} name filename of the font to load
+ * @param {int|float} size option font size (used internally)
+ *
+ * @returns {PFont} new PFont object
+ *
+ * @see #PFont
+ * @see #textFont
+ * @see #text
+ * @see #createFont
+ */
+ p.loadFont = function(name, size) {
+ if (name === undef) {
+ throw("font name required in loadFont.");
+ }
+ if (name.indexOf(".svg") === -1) {
+ if (size === undef) {
+ size = curTextFont.size;
+ }
+ return PFont.get(name, size);
+ }
+ // If the font is a glyph, calculate by SVG table
+ var font = p.loadGlyphs(name);
+
+ return {
+ name: name,
+ css: '12px sans-serif',
+ glyph: true,
+ units_per_em: font.units_per_em,
+ horiz_adv_x: 1 / font.units_per_em * font.horiz_adv_x,
+ ascent: font.ascent,
+ descent: font.descent,
+ width: function(str) {
+ var width = 0;
+ var len = str.length;
+ for (var i = 0; i < len; i++) {
+ try {
+ width += parseFloat(p.glyphLook(p.glyphTable[name], str[i]).horiz_adv_x);
+ }
+ catch(e) {
+ Processing.debug(e);
+ }
+ }
+ return width / p.glyphTable[name].units_per_em;
+ }
+ };
+ };
+
+ /**
+ * createFont() Loads a font into a variable of type PFont.
+ * Smooth and charset are ignored in Processing.js.
+ *
+ * @param {String} name filename of the font to load
+ * @param {int|float} size font size in pixels
+ * @param {boolean} smooth not used in Processing.js
+ * @param {char[]} charset not used in Processing.js
+ *
+ * @returns {PFont} new PFont object
+ *
+ * @see #PFont
+ * @see #textFont
+ * @see #text
+ * @see #loadFont
+ */
+ p.createFont = function(name, size) {
+ // because Processing.js only deals with real fonts,
+ // createFont is simply a wrapper for loadFont/2
+ return p.loadFont(name, size);
+ };
+
+ /**
+ * textFont() Sets the current font.
+ *
+ * @param {PFont} pfont the PFont to load as current text font
+ * @param {int|float} size optional font size in pixels
+ *
+ * @see #createFont
+ * @see #loadFont
+ * @see #PFont
+ * @see #text
+ */
+ p.textFont = function(pfont, size) {
+ if (size !== undef) {
+ // If we're using an SVG glyph font, don't load from cache
+ if (!pfont.glyph) {
+ pfont = PFont.get(pfont.name, size);
+ }
+ curTextSize = size;
+ }
+ curTextFont = pfont;
+ curFontName = curTextFont.name;
+ curTextAscent = curTextFont.ascent;
+ curTextDescent = curTextFont.descent;
+ curTextLeading = curTextFont.leading;
+ var curContext = drawing.$ensureContext();
+ curContext.font = curTextFont.css;
+ };
+
+ /**
+ * textSize() Sets the current font size in pixels.
+ *
+ * @param {int|float} size font size in pixels
+ *
+ * @see #textFont
+ * @see #loadFont
+ * @see #PFont
+ * @see #text
+ */
+ p.textSize = function(size) {
+ curTextFont = PFont.get(curFontName, size);
+ curTextSize = size;
+ // recache metrics
+ curTextAscent = curTextFont.ascent;
+ curTextDescent = curTextFont.descent;
+ curTextLeading = curTextFont.leading;
+ var curContext = drawing.$ensureContext();
+ curContext.font = curTextFont.css;
+ };
+
+ /**
+ * textAscent() returns the maximum height a character extends above the baseline of the
+ * current font at its current size, in pixels.
+ *
+ * @returns {float} height of the current font above the baseline, at its current size, in pixels
+ *
+ * @see #textDescent
+ */
+ p.textAscent = function() {
+ return curTextAscent;
+ };
+
+ /**
+ * textDescent() returns the maximum depth a character will protrude below the baseline of
+ * the current font at its current size, in pixels.
+ *
+ * @returns {float} depth of the current font below the baseline, at its current size, in pixels
+ *
+ * @see #textAscent
+ */
+ p.textDescent = function() {
+ return curTextDescent;
+ };
+
+ /**
+ * textLeading() Sets the current font's leading, which is the distance
+ * from baseline to baseline over consecutive lines, with additional vertical
+ * spacing taking into account. Usually this value is 1.2 or 1.25 times the
+ * textsize, but this value can be changed to effect vertically compressed
+ * or stretched text.
+ *
+ * @param {int|float} the desired baseline-to-baseline size in pixels
+ */
+ p.textLeading = function(leading) {
+ curTextLeading = leading;
+ };
+
+ /**
+ * textAlign() Sets the current alignment for drawing text.
+ *
+ * @param {int} ALIGN Horizontal alignment, either LEFT, CENTER, or RIGHT
+ * @param {int} YALIGN optional vertical alignment, either TOP, BOTTOM, CENTER, or BASELINE
+ *
+ * @see #loadFont
+ * @see #PFont
+ * @see #text
+ */
+ p.textAlign = function(xalign, yalign) {
+ horizontalTextAlignment = xalign;
+ verticalTextAlignment = yalign || PConstants.BASELINE;
+ };
+
+ /**
+ * toP5String converts things with arbitrary data type into
+ * string values, for text rendering.
+ *
+ * @param {any} any object that can be converted into a string
+ *
+ * @return {String} the string representation of the input
+ */
+ function toP5String(obj) {
+ if(obj instanceof String) {
+ return obj;
+ }
+ if(typeof obj === 'number') {
+ // check if an int
+ if(obj === (0 | obj)) {
+ return obj.toString();
+ }
+ return p.nf(obj, 0, 3);
+ }
+ if(obj === null || obj === undef) {
+ return "";
+ }
+ return obj.toString();
+ }
+
+ /**
+ * textWidth() Calculates and returns the width of any character or text string in pixels.
+ *
+ * @param {char|String} str char or String to be measured
+ *
+ * @return {float} width of char or String in pixels
+ *
+ * @see #loadFont
+ * @see #PFont
+ * @see #text
+ * @see #textFont
+ */
+ Drawing2D.prototype.textWidth = function(str) {
+ var lines = toP5String(str).split(/\r?\n/g), width = 0;
+ var i, linesCount = lines.length;
+
+ curContext.font = curTextFont.css;
+ for (i = 0; i < linesCount; ++i) {
+ width = Math.max(width, curTextFont.measureTextWidth(lines[i]));
+ }
+ return width | 0;
+ };
+
+ Drawing3D.prototype.textWidth = function(str) {
+ var lines = toP5String(str).split(/\r?\n/g), width = 0;
+ var i, linesCount = lines.length;
+ if (textcanvas === undef) {
+ textcanvas = document.createElement("canvas");
+ }
+
+ var textContext = textcanvas.getContext("2d");
+ textContext.font = curTextFont.css;
+
+ for (i = 0; i < linesCount; ++i) {
+ width = Math.max(width, textContext.measureText(lines[i]).width);
+ }
+ return width | 0;
+ };
+
+ // A lookup table for characters that can not be referenced by Object
+ p.glyphLook = function(font, chr) {
+ try {
+ switch (chr) {
+ case "1":
+ return font.one;
+ case "2":
+ return font.two;
+ case "3":
+ return font.three;
+ case "4":
+ return font.four;
+ case "5":
+ return font.five;
+ case "6":
+ return font.six;
+ case "7":
+ return font.seven;
+ case "8":
+ return font.eight;
+ case "9":
+ return font.nine;
+ case "0":
+ return font.zero;
+ case " ":
+ return font.space;
+ case "$":
+ return font.dollar;
+ case "!":
+ return font.exclam;
+ case '"':
+ return font.quotedbl;
+ case "#":
+ return font.numbersign;
+ case "%":
+ return font.percent;
+ case "&":
+ return font.ampersand;
+ case "'":
+ return font.quotesingle;
+ case "(":
+ return font.parenleft;
+ case ")":
+ return font.parenright;
+ case "*":
+ return font.asterisk;
+ case "+":
+ return font.plus;
+ case ",":
+ return font.comma;
+ case "-":
+ return font.hyphen;
+ case ".":
+ return font.period;
+ case "/":
+ return font.slash;
+ case "_":
+ return font.underscore;
+ case ":":
+ return font.colon;
+ case ";":
+ return font.semicolon;
+ case "<":
+ return font.less;
+ case "=":
+ return font.equal;
+ case ">":
+ return font.greater;
+ case "?":
+ return font.question;
+ case "@":
+ return font.at;
+ case "[":
+ return font.bracketleft;
+ case "\\":
+ return font.backslash;
+ case "]":
+ return font.bracketright;
+ case "^":
+ return font.asciicircum;
+ case "`":
+ return font.grave;
+ case "{":
+ return font.braceleft;
+ case "|":
+ return font.bar;
+ case "}":
+ return font.braceright;
+ case "~":
+ return font.asciitilde;
+ // If the character is not 'special', access it by object reference
+ default:
+ return font[chr];
+ }
+ } catch(e) {
+ Processing.debug(e);
+ }
+ };
+
+ // Print some text to the Canvas
+ Drawing2D.prototype.text$line = function(str, x, y, z, align) {
+ var textWidth = 0, xOffset = 0;
+ // If the font is a standard Canvas font...
+ if (!curTextFont.glyph) {
+ if (str && ("fillText" in curContext)) {
+ if (isFillDirty) {
+ curContext.fillStyle = p.color.toString(currentFillColor);
+ isFillDirty = false;
+ }
+
+ // horizontal offset/alignment
+ if(align === PConstants.RIGHT || align === PConstants.CENTER) {
+ textWidth = curTextFont.measureTextWidth(str);
+
+ if(align === PConstants.RIGHT) {
+ xOffset = -textWidth;
+ } else { // if(align === PConstants.CENTER)
+ xOffset = -textWidth/2;
+ }
+ }
+
+ curContext.fillText(str, x+xOffset, y);
+ }
+ } else {
+ // If the font is a Batik SVG font...
+ var font = p.glyphTable[curFontName];
+ saveContext();
+ curContext.translate(x, y + curTextSize);
+
+ // horizontal offset/alignment
+ if(align === PConstants.RIGHT || align === PConstants.CENTER) {
+ textWidth = font.width(str);
+
+ if(align === PConstants.RIGHT) {
+ xOffset = -textWidth;
+ } else { // if(align === PConstants.CENTER)
+ xOffset = -textWidth/2;
+ }
+ }
+
+ var upem = font.units_per_em,
+ newScale = 1 / upem * curTextSize;
+
+ curContext.scale(newScale, newScale);
+
+ for (var i=0, len=str.length; i < len; i++) {
+ // Test character against glyph table
+ try {
+ p.glyphLook(font, str[i]).draw();
+ } catch(e) {
+ Processing.debug(e);
+ }
+ }
+ restoreContext();
+ }
+ };
+
+ Drawing3D.prototype.text$line = function(str, x, y, z, align) {
+ // handle case for 3d text
+ if (textcanvas === undef) {
+ textcanvas = document.createElement("canvas");
+ }
+ var oldContext = curContext;
+ curContext = textcanvas.getContext("2d");
+ curContext.font = curTextFont.css;
+ var textWidth = curTextFont.measureTextWidth(str);
+ textcanvas.width = textWidth;
+ textcanvas.height = curTextSize;
+ curContext = textcanvas.getContext("2d"); // refreshes curContext
+ curContext.font = curTextFont.css;
+ curContext.textBaseline="top";
+
+ // paint on 2D canvas
+ Drawing2D.prototype.text$line(str,0,0,0,PConstants.LEFT);
+
+ // use it as a texture
+ var aspect = textcanvas.width/textcanvas.height;
+ curContext = oldContext;
+
+ curContext.bindTexture(curContext.TEXTURE_2D, textTex);
+ curContext.texImage2D(curContext.TEXTURE_2D, 0, curContext.RGBA, curContext.RGBA, curContext.UNSIGNED_BYTE, textcanvas);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_MAG_FILTER, curContext.LINEAR);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_MIN_FILTER, curContext.LINEAR);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_WRAP_T, curContext.CLAMP_TO_EDGE);
+ curContext.texParameteri(curContext.TEXTURE_2D, curContext.TEXTURE_WRAP_S, curContext.CLAMP_TO_EDGE);
+ // If we don't have a power of two texture, we can't mipmap it.
+ // curContext.generateMipmap(curContext.TEXTURE_2D);
+
+ // horizontal offset/alignment
+ var xOffset = 0;
+ if (align === PConstants.RIGHT) {
+ xOffset = -textWidth;
+ } else if(align === PConstants.CENTER) {
+ xOffset = -textWidth/2;
+ }
+ var model = new PMatrix3D();
+ var scalefactor = curTextSize * 0.5;
+ model.translate(x+xOffset-scalefactor/2, y-scalefactor, z);
+ model.scale(-aspect*scalefactor, -scalefactor, scalefactor);
+ model.translate(-1, -1, -1);
+ model.transpose();
+
+ var view = new PMatrix3D();
+ view.scale(1, -1, 1);
+ view.apply(modelView.array());
+ view.transpose();
+
+ curContext.useProgram(programObject2D);
+ vertexAttribPointer("aVertex2d", programObject2D, "aVertex", 3, textBuffer);
+ vertexAttribPointer("aTextureCoord2d", programObject2D, "aTextureCoord", 2, textureBuffer);
+ uniformi("uSampler2d", programObject2D, "uSampler", [0]);
+
+ uniformi("uIsDrawingText2d", programObject2D, "uIsDrawingText", true);
+
+ uniformMatrix("uModel2d", programObject2D, "uModel", false, model.array());
+ uniformMatrix("uView2d", programObject2D, "uView", false, view.array());
+ uniformf("uColor2d", programObject2D, "uColor", fillStyle);
+ curContext.bindBuffer(curContext.ELEMENT_ARRAY_BUFFER, indexBuffer);
+ curContext.drawElements(curContext.TRIANGLES, 6, curContext.UNSIGNED_SHORT, 0);
+ };
+
+
+ /**
+ * unbounded text function (z is an optional argument)
+ */
+ function text$4(str, x, y, z) {
+ var lines, linesCount;
+ if(str.indexOf('\n') < 0) {
+ lines = [str];
+ linesCount = 1;
+ } else {
+ lines = str.split(/\r?\n/g);
+ linesCount = lines.length;
+ }
+ // handle text line-by-line
+
+ var yOffset = 0;
+ if(verticalTextAlignment === PConstants.TOP) {
+ yOffset = curTextAscent + curTextDescent;
+ } else if(verticalTextAlignment === PConstants.CENTER) {
+ yOffset = curTextAscent/2 - (linesCount-1)*curTextLeading/2;
+ } else if(verticalTextAlignment === PConstants.BOTTOM) {
+ yOffset = -(curTextDescent + (linesCount-1)*curTextLeading);
+ }
+
+ for(var i=0;i<linesCount;++i) {
+ var line = lines[i];
+ drawing.text$line(line, x, y + yOffset, z, horizontalTextAlignment);
+ yOffset += curTextLeading;
+ }
+ }
+
+
+ /**
+ * box-bounded text function (z is an optional argument)
+ */
+ function text$6(str, x, y, width, height, z) {
+ // 'fail' on 0-valued dimensions
+ if (str.length === 0 || width === 0 || height === 0) {
+ return;
+ }
+ // also 'fail' if the text height is larger than the bounding height
+ if(curTextSize > height) {
+ return;
+ }
+
+ var spaceMark = -1;
+ var start = 0;
+ var lineWidth = 0;
+ var drawCommands = [];
+
+ // run through text, character-by-character
+ for (var charPos=0, len=str.length; charPos < len; charPos++)
+ {
+ var currentChar = str[charPos];
+ var spaceChar = (currentChar === " ");
+ var letterWidth = curTextFont.measureTextWidth(currentChar);
+
+ // if we aren't looking at a newline, and the text still fits, keep processing
+ if (currentChar !== "\n" && (lineWidth + letterWidth <= width)) {
+ if (spaceChar) { spaceMark = charPos; }
+ lineWidth += letterWidth;
+ }
+
+ // if we're looking at a newline, or the text no longer fits, push the section that fit into the drawcommand list
+ else
+ {
+ if (spaceMark + 1 === start) {
+ if(charPos>0) {
+ // Whole line without spaces so far.
+ spaceMark = charPos;
+ } else {
+ // 'fail', because the line can't even fit the first character
+ return;
+ }
+ }
+
+ if (currentChar === "\n") {
+ drawCommands.push({text:str.substring(start, charPos), width: lineWidth});
+ start = charPos + 1;
+ } else {
+ // current is not a newline, which means the line doesn't fit in box. push text.
+ // In Processing 1.5.1, the space is also pushed, so we push up to spaceMark+1,
+ // rather than up to spaceMark, as was the case for Processing 1.5 and earlier.
+ drawCommands.push({text:str.substring(start, spaceMark+1), width: lineWidth});
+ start = spaceMark + 1;
+ }
+
+ // newline + return
+ lineWidth = 0;
+ charPos = start - 1;
+ }
+ }
+
+ // push the remaining text
+ if (start < len) {
+ drawCommands.push({text:str.substring(start), width: lineWidth});
+ }
+
+ // resolve horizontal alignment
+ var xOffset = 1,
+ yOffset = curTextAscent;
+ if (horizontalTextAlignment === PConstants.CENTER) {
+ xOffset = width/2;
+ } else if (horizontalTextAlignment === PConstants.RIGHT) {
+ xOffset = width;
+ }
+
+ // resolve vertical alignment
+ var linesCount = drawCommands.length,
+ visibleLines = Math.min(linesCount, Math.floor(height/curTextLeading));
+ if(verticalTextAlignment === PConstants.TOP) {
+ yOffset = curTextAscent + curTextDescent;
+ } else if(verticalTextAlignment === PConstants.CENTER) {
+ yOffset = (height/2) - curTextLeading * (visibleLines/2 - 1);
+ } else if(verticalTextAlignment === PConstants.BOTTOM) {
+ yOffset = curTextDescent + curTextLeading;
+ }
+
+ var command,
+ drawCommand,
+ leading;
+ for (command = 0; command < linesCount; command++) {
+ leading = command * curTextLeading;
+ // stop if not enough space for one more line draw
+ if (yOffset + leading > height - curTextDescent) {
+ break;
+ }
+ drawCommand = drawCommands[command];
+ drawing.text$line(drawCommand.text, x + xOffset, y + yOffset + leading, z, horizontalTextAlignment);
+ }
+ }
+
+ /**
+ * text() Draws text to the screen.
+ *
+ * @param {String|char|int|float} data the alphanumeric symbols to be displayed
+ * @param {int|float} x x-coordinate of text
+ * @param {int|float} y y-coordinate of text
+ * @param {int|float} z optional z-coordinate of text
+ * @param {String} stringdata optional letters to be displayed
+ * @param {int|float} width optional width of text box
+ * @param {int|float} height optional height of text box
+ *
+ * @see #textAlign
+ * @see #textMode
+ * @see #loadFont
+ * @see #PFont
+ * @see #textFont
+ */
+ p.text = function() {
+ if (textMode === PConstants.SHAPE) {
+ // TODO: requires beginRaw function
+ return;
+ }
+ if (arguments.length === 3) { // for text( str, x, y)
+ text$4(toP5String(arguments[0]), arguments[1], arguments[2], 0);
+ } else if (arguments.length === 4) { // for text( str, x, y, z)
+ text$4(toP5String(arguments[0]), arguments[1], arguments[2], arguments[3]);
+ } else if (arguments.length === 5) { // for text( str, x, y , width, height)
+ text$6(toP5String(arguments[0]), arguments[1], arguments[2], arguments[3], arguments[4], 0);
+ } else if (arguments.length === 6) { // for text( stringdata, x, y , width, height, z)
+ text$6(toP5String(arguments[0]), arguments[1], arguments[2], arguments[3], arguments[4], arguments[5]);
+ }
+ };
+
+ /**
+ * Sets the way text draws to the screen. In the default configuration (the MODEL mode), it's possible to rotate,
+ * scale, and place letters in two and three dimensional space. <br /><br /> Changing to SCREEN mode draws letters
+ * directly to the front of the window and greatly increases rendering quality and speed when used with the P2D and
+ * P3D renderers. textMode(SCREEN) with OPENGL and JAVA2D (the default) renderers will generally be slower, though
+ * pixel accurate with P2D and P3D. With textMode(SCREEN), the letters draw at the actual size of the font (in pixels)
+ * and therefore calls to <b>textSize()</b> will not affect the size of the letters. To create a font at the size you
+ * desire, use the "Create font..." option in the Tools menu, or use the createFont() function. When using textMode(SCREEN),
+ * any z-coordinate passed to a text() command will be ignored, because your computer screen is...flat!
+ *
+ * @param {int} MODE Either MODEL, SCREEN or SHAPE (not yet supported)
+ *
+ * @see loadFont
+ * @see PFont
+ * @see text
+ * @see textFont
+ * @see createFont
+ */
+ p.textMode = function(mode){
+ textMode = mode;
+ };
+
+ // Load Batik SVG Fonts and parse to pre-def objects for quick rendering
+ p.loadGlyphs = function(url) {
+ var x, y, cx, cy, nx, ny, d, a, lastCom, lenC, horiz_adv_x, getXY = '[0-9\\-]+', path;
+
+ // Return arrays of SVG commands and coords
+ // get this to use p.matchAll() - will need to work around the lack of null return
+ var regex = function(needle, hay) {
+ var i = 0,
+ results = [],
+ latest, regexp = new RegExp(needle, "g");
+ latest = results[i] = regexp.exec(hay);
+ while (latest) {
+ i++;
+ latest = results[i] = regexp.exec(hay);
+ }
+ return results;
+ };
+
+ var buildPath = function(d) {
+ var c = regex("[A-Za-z][0-9\\- ]+|Z", d);
+ var beforePathDraw = function() {
+ saveContext();
+ return drawing.$ensureContext();
+ };
+ var afterPathDraw = function() {
+ executeContextFill();
+ executeContextStroke();
+ restoreContext();
+ };
+
+ // Begin storing path object
+ path = "return {draw:function(){var curContext=beforePathDraw();curContext.beginPath();";
+
+ x = 0;
+ y = 0;
+ cx = 0;
+ cy = 0;
+ nx = 0;
+ ny = 0;
+ d = 0;
+ a = 0;
+ lastCom = "";
+ lenC = c.length - 1;
+
+ // Loop through SVG commands translating to canvas eqivs functions in path object
+ for (var j = 0; j < lenC; j++) {
+ var com = c[j][0], xy = regex(getXY, com);
+
+ switch (com[0]) {
+ case "M":
+ //curContext.moveTo(x,-y);
+ x = parseFloat(xy[0][0]);
+ y = parseFloat(xy[1][0]);
+ path += "curContext.moveTo(" + x + "," + (-y) + ");";
+ break;
+
+ case "L":
+ //curContext.lineTo(x,-y);
+ x = parseFloat(xy[0][0]);
+ y = parseFloat(xy[1][0]);
+ path += "curContext.lineTo(" + x + "," + (-y) + ");";
+ break;
+
+ case "H":
+ //curContext.lineTo(x,-y)
+ x = parseFloat(xy[0][0]);
+ path += "curContext.lineTo(" + x + "," + (-y) + ");";
+ break;
+
+ case "V":
+ //curContext.lineTo(x,-y);
+ y = parseFloat(xy[0][0]);
+ path += "curContext.lineTo(" + x + "," + (-y) + ");";
+ break;
+
+ case "T":
+ //curContext.quadraticCurveTo(cx,-cy,nx,-ny);
+ nx = parseFloat(xy[0][0]);
+ ny = parseFloat(xy[1][0]);
+
+ if (lastCom === "Q" || lastCom === "T") {
+ d = Math.sqrt(Math.pow(x - cx, 2) + Math.pow(cy - y, 2));
+ a = Math.PI + Math.atan2(cx - x, cy - y);
+ cx = x + (Math.sin(a) * (d));
+ cy = y + (Math.cos(a) * (d));
+ } else {
+ cx = x;
+ cy = y;
+ }
+
+ path += "curContext.quadraticCurveTo(" + cx + "," + (-cy) + "," + nx + "," + (-ny) + ");";
+ x = nx;
+ y = ny;
+ break;
+
+ case "Q":
+ //curContext.quadraticCurveTo(cx,-cy,nx,-ny);
+ cx = parseFloat(xy[0][0]);
+ cy = parseFloat(xy[1][0]);
+ nx = parseFloat(xy[2][0]);
+ ny = parseFloat(xy[3][0]);
+ path += "curContext.quadraticCurveTo(" + cx + "," + (-cy) + "," + nx + "," + (-ny) + ");";
+ x = nx;
+ y = ny;
+ break;
+
+ case "Z":
+ //curContext.closePath();
+ path += "curContext.closePath();";
+ break;
+ }
+ lastCom = com[0];
+ }
+
+ path += "afterPathDraw();";
+ path += "curContext.translate(" + horiz_adv_x + ",0);";
+ path += "}}";
+
+ return ((new Function("beforePathDraw", "afterPathDraw", path))(beforePathDraw, afterPathDraw));
+ };
+
+ // Parse SVG font-file into block of Canvas commands
+ var parseSVGFont = function(svg) {
+ // Store font attributes
+ var font = svg.getElementsByTagName("font");
+ p.glyphTable[url].horiz_adv_x = font[0].getAttribute("horiz-adv-x");
+
+ var font_face = svg.getElementsByTagName("font-face")[0];
+ p.glyphTable[url].units_per_em = parseFloat(font_face.getAttribute("units-per-em"));
+ p.glyphTable[url].ascent = parseFloat(font_face.getAttribute("ascent"));
+ p.glyphTable[url].descent = parseFloat(font_face.getAttribute("descent"));
+
+ var glyph = svg.getElementsByTagName("glyph"),
+ len = glyph.length;
+
+ // Loop through each glyph in the SVG
+ for (var i = 0; i < len; i++) {
+ // Store attributes for this glyph
+ var unicode = glyph[i].getAttribute("unicode");
+ var name = glyph[i].getAttribute("glyph-name");
+ horiz_adv_x = glyph[i].getAttribute("horiz-adv-x");
+ if (horiz_adv_x === null) {
+ horiz_adv_x = p.glyphTable[url].horiz_adv_x;
+ }
+ d = glyph[i].getAttribute("d");
+ // Split path commands in glpyh
+ if (d !== undef) {
+ path = buildPath(d);
+ // Store glyph data to table object
+ p.glyphTable[url][name] = {
+ name: name,
+ unicode: unicode,
+ horiz_adv_x: horiz_adv_x,
+ draw: path.draw
+ };
+ }
+ } // finished adding glyphs to table
+ };
+
+ // Load and parse Batik SVG font as XML into a Processing Glyph object
+ var loadXML = function() {
+ var xmlDoc;
+
+ try {
+ xmlDoc = document.implementation.createDocument("", "", null);
+ }
+ catch(e_fx_op) {
+ Processing.debug(e_fx_op.message);
+ return;
+ }
+
+ try {
+ xmlDoc.async = false;
+ xmlDoc.load(url);
+ parseSVGFont(xmlDoc.getElementsByTagName("svg")[0]);
+ }
+ catch(e_sf_ch) {
+ // Google Chrome, Safari etc.
+ Processing.debug(e_sf_ch);
+ try {
+ var xmlhttp = new window.XMLHttpRequest();
+ xmlhttp.open("GET", url, false);
+ xmlhttp.send(null);
+ parseSVGFont(xmlhttp.responseXML.documentElement);
+ }
+ catch(e) {
+ Processing.debug(e_sf_ch);
+ }
+ }
+ };
+
+ // Create a new object in glyphTable to store this font
+ p.glyphTable[url] = {};
+
+ // Begin loading the Batik SVG font...
+ loadXML(url);
+
+ // Return the loaded font for attribute grabbing
+ return p.glyphTable[url];
+ };
+
+ /**
+ * Gets the sketch parameter value. The parameter can be defined as the canvas attribute with
+ * the "data-processing-" prefix or provided in the pjs directive (e.g. param-test="52").
+ * The function tries the canvas attributes, then the pjs directive content.
+ *
+ * @param {String} name The name of the param to read.
+ *
+ * @returns {String} The parameter value, or null if parameter is not defined.
+ */
+ p.param = function(name) {
+ // trying attribute that was specified in CANVAS
+ var attributeName = "data-processing-" + name;
+ if (curElement.hasAttribute(attributeName)) {
+ return curElement.getAttribute(attributeName);
+ }
+ // trying child PARAM elements of the CANVAS
+ for (var i = 0, len = curElement.childNodes.length; i < len; ++i) {
+ var item = curElement.childNodes.item(i);
+ if (item.nodeType !== 1 || item.tagName.toLowerCase() !== "param") {
+ continue;
+ }
+ if (item.getAttribute("name") === name) {
+ return item.getAttribute("value");
+ }
+ }
+ // fallback to default params
+ if (curSketch.params.hasOwnProperty(name)) {
+ return curSketch.params[name];
+ }
+ return null;
+ };
+
+ ////////////////////////////////////////////////////////////////////////////
+ // 2D/3D methods wiring utils
+ ////////////////////////////////////////////////////////////////////////////
+ function wireDimensionalFunctions(mode) {
+ // Drawing2D/Drawing3D
+ if (mode === '3D') {
+ drawing = new Drawing3D();
+ } else if (mode === '2D') {
+ drawing = new Drawing2D();
+ } else {
+ drawing = new DrawingPre();
+ }
+
+ // Wire up functions (Use DrawingPre properties names)
+ for (var i in DrawingPre.prototype) {
+ if (DrawingPre.prototype.hasOwnProperty(i) && i.indexOf("$") < 0) {
+ p[i] = drawing[i];
+ }
+ }
+
+ // Run initialization
+ drawing.$init();
+ }
+
+ function createDrawingPreFunction(name) {
+ return function() {
+ wireDimensionalFunctions("2D");
+ return drawing[name].apply(this, arguments);
+ };
+ }
+ DrawingPre.prototype.translate = createDrawingPreFunction("translate");
+ DrawingPre.prototype.transform = createDrawingPreFunction("transform");
+ DrawingPre.prototype.scale = createDrawingPreFunction("scale");
+ DrawingPre.prototype.pushMatrix = createDrawingPreFunction("pushMatrix");
+ DrawingPre.prototype.popMatrix = createDrawingPreFunction("popMatrix");
+ DrawingPre.prototype.resetMatrix = createDrawingPreFunction("resetMatrix");
+ DrawingPre.prototype.applyMatrix = createDrawingPreFunction("applyMatrix");
+ DrawingPre.prototype.rotate = createDrawingPreFunction("rotate");
+ DrawingPre.prototype.rotateZ = createDrawingPreFunction("rotateZ");
+ DrawingPre.prototype.shearX = createDrawingPreFunction("shearX");
+ DrawingPre.prototype.shearY = createDrawingPreFunction("shearY");
+ DrawingPre.prototype.redraw = createDrawingPreFunction("redraw");
+ DrawingPre.prototype.toImageData = createDrawingPreFunction("toImageData");
+ DrawingPre.prototype.ambientLight = createDrawingPreFunction("ambientLight");
+ DrawingPre.prototype.directionalLight = createDrawingPreFunction("directionalLight");
+ DrawingPre.prototype.lightFalloff = createDrawingPreFunction("lightFalloff");
+ DrawingPre.prototype.lightSpecular = createDrawingPreFunction("lightSpecular");
+ DrawingPre.prototype.pointLight = createDrawingPreFunction("pointLight");
+ DrawingPre.prototype.noLights = createDrawingPreFunction("noLights");
+ DrawingPre.prototype.spotLight = createDrawingPreFunction("spotLight");
+ DrawingPre.prototype.beginCamera = createDrawingPreFunction("beginCamera");
+ DrawingPre.prototype.endCamera = createDrawingPreFunction("endCamera");
+ DrawingPre.prototype.frustum = createDrawingPreFunction("frustum");
+ DrawingPre.prototype.box = createDrawingPreFunction("box");
+ DrawingPre.prototype.sphere = createDrawingPreFunction("sphere");
+ DrawingPre.prototype.ambient = createDrawingPreFunction("ambient");
+ DrawingPre.prototype.emissive = createDrawingPreFunction("emissive");
+ DrawingPre.prototype.shininess = createDrawingPreFunction("shininess");
+ DrawingPre.prototype.specular = createDrawingPreFunction("specular");
+ DrawingPre.prototype.fill = createDrawingPreFunction("fill");
+ DrawingPre.prototype.stroke = createDrawingPreFunction("stroke");
+ DrawingPre.prototype.strokeWeight = createDrawingPreFunction("strokeWeight");
+ DrawingPre.prototype.smooth = createDrawingPreFunction("smooth");
+ DrawingPre.prototype.noSmooth = createDrawingPreFunction("noSmooth");
+ DrawingPre.prototype.point = createDrawingPreFunction("point");
+ DrawingPre.prototype.vertex = createDrawingPreFunction("vertex");
+ DrawingPre.prototype.endShape = createDrawingPreFunction("endShape");
+ DrawingPre.prototype.bezierVertex = createDrawingPreFunction("bezierVertex");
+ DrawingPre.prototype.curveVertex = createDrawingPreFunction("curveVertex");
+ DrawingPre.prototype.curve = createDrawingPreFunction("curve");
+ DrawingPre.prototype.line = createDrawingPreFunction("line");
+ DrawingPre.prototype.bezier = createDrawingPreFunction("bezier");
+ DrawingPre.prototype.rect = createDrawingPreFunction("rect");
+ DrawingPre.prototype.ellipse = createDrawingPreFunction("ellipse");
+ DrawingPre.prototype.background = createDrawingPreFunction("background");
+ DrawingPre.prototype.image = createDrawingPreFunction("image");
+ DrawingPre.prototype.textWidth = createDrawingPreFunction("textWidth");
+ DrawingPre.prototype.text$line = createDrawingPreFunction("text$line");
+ DrawingPre.prototype.$ensureContext = createDrawingPreFunction("$ensureContext");
+ DrawingPre.prototype.$newPMatrix = createDrawingPreFunction("$newPMatrix");
+
+ DrawingPre.prototype.size = function(aWidth, aHeight, aMode) {
+ wireDimensionalFunctions(aMode === PConstants.WEBGL ? "3D" : "2D");
+ p.size(aWidth, aHeight, aMode);
+ };
+
+ DrawingPre.prototype.$init = noop;
+
+ Drawing2D.prototype.$init = function() {
+ // Setup default 2d canvas context.
+ // Moving this here removes the number of times we need to check the 3D variable
+ p.size(p.width, p.height);
+
+ curContext.lineCap = 'round';
+
+ // Set default stroke and fill color
+ p.noSmooth();
+ p.disableContextMenu();
+ };
+ Drawing3D.prototype.$init = function() {
+ // For ref/perf test compatibility until those are fixed
+ p.use3DContext = true;
+ p.disableContextMenu();
+ };
+
+ DrawingShared.prototype.$ensureContext = function() {
+ return curContext;
+ };
+
+ //////////////////////////////////////////////////////////////////////////
+ // Keyboard Events
+ //////////////////////////////////////////////////////////////////////////
+
+ // In order to catch key events in a canvas, it needs to be "specially focusable",
+ // by assigning it a tabindex. If no tabindex is specified on-page, set this to 0.
+ if (!curElement.getAttribute("tabindex")) {
+ curElement.setAttribute("tabindex", 0);
+ }
+
+ function getKeyCode(e) {
+ var code = e.which || e.keyCode;
+ switch (code) {
+ case 13: // ENTER
+ return 10;
+ case 91: // META L (Saf/Mac)
+ case 93: // META R (Saf/Mac)
+ case 224: // META (FF/Mac)
+ return 157;
+ case 57392: // CONTROL (Op/Mac)
+ return 17;
+ case 46: // DELETE
+ return 127;
+ case 45: // INSERT
+ return 155;
+ }
+ return code;
+ }
+
+ function getKeyChar(e) {
+ var c = e.which || e.keyCode;
+ var anyShiftPressed = e.shiftKey || e.ctrlKey || e.altKey || e.metaKey;
+ switch (c) {
+ case 13:
+ c = anyShiftPressed ? 13 : 10; // RETURN vs ENTER (Mac)
+ break;
+ case 8:
+ c = anyShiftPressed ? 127 : 8; // DELETE vs BACKSPACE (Mac)
+ break;
+ }
+ return new Char(c);
+ }
+
+ function suppressKeyEvent(e) {
+ if (typeof e.preventDefault === "function") {
+ e.preventDefault();
+ } else if (typeof e.stopPropagation === "function") {
+ e.stopPropagation();
+ }
+ return false;
+ }
+
+ function updateKeyPressed() {
+ var ch;
+ for (ch in pressedKeysMap) {
+ if (pressedKeysMap.hasOwnProperty(ch)) {
+ p.__keyPressed = true;
+ return;
+ }
+ }
+ p.__keyPressed = false;
+ }
+
+ function resetKeyPressed() {
+ p.__keyPressed = false;
+ pressedKeysMap = [];
+ lastPressedKeyCode = null;
+ }
+
+ function simulateKeyTyped(code, c) {
+ pressedKeysMap[code] = c;
+ lastPressedKeyCode = null;
+ p.key = c;
+ p.keyCode = code;
+ p.keyPressed();
+ p.keyCode = 0;
+ p.keyTyped();
+ updateKeyPressed();
+ }
+
+ function handleKeydown(e) {
+ var code = getKeyCode(e);
+ if (code === PConstants.DELETE) {
+ simulateKeyTyped(code, new Char(127));
+ return;
+ }
+ if (codedKeys.indexOf(code) < 0) {
+ lastPressedKeyCode = code;
+ return;
+ }
+ var c = new Char(PConstants.CODED);
+ p.key = c;
+ p.keyCode = code;
+ pressedKeysMap[code] = c;
+ p.keyPressed();
+ lastPressedKeyCode = null;
+ updateKeyPressed();
+ return suppressKeyEvent(e);
+ }
+
+ function handleKeypress(e) {
+ if (lastPressedKeyCode === null) {
+ return; // processed in handleKeydown
+ }
+ var code = lastPressedKeyCode, c = getKeyChar(e);
+ simulateKeyTyped(code, c);
+ return suppressKeyEvent(e);
+ }
+
+ function handleKeyup(e) {
+ var code = getKeyCode(e), c = pressedKeysMap[code];
+ if (c === undef) {
+ return; // no keyPressed event was generated.
+ }
+ p.key = c;
+ p.keyCode = code;
+ p.keyReleased();
+ delete pressedKeysMap[code];
+ updateKeyPressed();
+ }
+
+ // Send aCode Processing syntax to be converted to JavaScript
+ if (!pgraphicsMode) {
+ if (aCode instanceof Processing.Sketch) {
+ // Use sketch as is
+ curSketch = aCode;
+ } else if (typeof aCode === "function") {
+ // Wrap function with default sketch parameters
+ curSketch = new Processing.Sketch(aCode);
+ } else if (!aCode) {
+ // Empty sketch
+ curSketch = new Processing.Sketch(function (){});
+ } else {
+ //#if PARSER
+ // Compile the code
+ curSketch = Processing.compile(aCode);
+ //#else
+ // throw "PJS compile is not supported";
+ //#endif
+ }
+
+ // Expose internal field for diagnostics and testing
+ p.externals.sketch = curSketch;
+
+ wireDimensionalFunctions();
+
+ // the onfocus and onblur events are handled in two parts.
+ // 1) the p.focused property is handled per sketch
+ curElement.onfocus = function() {
+ p.focused = true;
+ };
+
+ curElement.onblur = function() {
+ p.focused = false;
+ if (!curSketch.options.globalKeyEvents) {
+ resetKeyPressed();
+ }
+ };
+
+ // 2) looping status is handled per page, based on the pauseOnBlur @pjs directive
+ if (curSketch.options.pauseOnBlur) {
+ attachEventHandler(window, 'focus', function() {
+ if (doLoop) {
+ p.loop();
+ }
+ });
+
+ attachEventHandler(window, 'blur', function() {
+ if (doLoop && loopStarted) {
+ p.noLoop();
+ doLoop = true; // make sure to keep this true after the noLoop call
+ }
+ resetKeyPressed();
+ });
+ }
+
+ // if keyboard events should be handled globally, the listeners should
+ // be bound to the document window, rather than to the current canvas
+ var keyTrigger = curSketch.options.globalKeyEvents ? window : curElement;
+ attachEventHandler(keyTrigger, "keydown", handleKeydown);
+ attachEventHandler(keyTrigger, "keypress", handleKeypress);
+ attachEventHandler(keyTrigger, "keyup", handleKeyup);
+
+ // Step through the libraries that were attached at doc load...
+ for (var i in Processing.lib) {
+ if (Processing.lib.hasOwnProperty(i)) {
+ if(Processing.lib[i].hasOwnProperty("attach")) {
+ // use attach function if present
+ Processing.lib[i].attach(p);
+ } else if(Processing.lib[i] instanceof Function) {
+ // Init the libraries in the context of this p_instance (legacy)
+ Processing.lib[i].call(this);
+ }
+ }
+ }
+
+ // sketch execute test interval, used to reschedule
+ // an execute when preloads have not yet finished.
+ var retryInterval = 100;
+
+ var executeSketch = function(processing) {
+ // Don't start until all specified images and fonts in the cache are preloaded
+ if (!(curSketch.imageCache.pending || PFont.preloading.pending(retryInterval))) {
+ // the opera preload cache can only be cleared once we start
+ if (window.opera) {
+ var link,
+ element,
+ operaCache=curSketch.imageCache.operaCache;
+ for (link in operaCache) {
+ if(operaCache.hasOwnProperty(link)) {
+ element = operaCache[link];
+ if (element !== null) {
+ document.body.removeChild(element);
+ }
+ delete(operaCache[link]);
+ }
+ }
+ }
+
+ curSketch.attach(processing, defaultScope);
+
+ // pass a reference to the p instance for this sketch.
+ curSketch.onLoad(processing);
+
+ // Run void setup()
+ if (processing.setup) {
+ processing.setup();
+ // if any transforms were performed in setup reset to identity matrix
+ // so draw loop is unpolluted
+ processing.resetMatrix();
+ curSketch.onSetup();
+ }
+
+ // some pixels can be cached, flushing
+ resetContext();
+
+ if (processing.draw) {
+ if (!doLoop) {
+ processing.redraw();
+ } else {
+ processing.loop();
+ }
+ }
+ } else {
+ window.setTimeout(function() { executeSketch(processing); }, retryInterval);
+ }
+ };
+
+ // Only store an instance of non-createGraphics instances.
+ addInstance(this);
+
+ // The parser adds custom methods to the processing context
+ // this renames p to processing so these methods will run
+ executeSketch(p);
+ } else {
+ // No executable sketch was specified
+ // or called via createGraphics
+ curSketch = new Processing.Sketch();
+
+ wireDimensionalFunctions();
+
+ // Hack to make PGraphics work again after splitting size()
+ p.size = function(w, h, render) {
+ if (render && render === PConstants.WEBGL) {
+ wireDimensionalFunctions('3D');
+ } else {
+ wireDimensionalFunctions('2D');
+ }
+
+ p.size(w, h, render);
+ };
+ }
+ };
+
+ // Place-holder for overridable debugging function
+ Processing.debug = (function() {
+ if ("console" in window) {
+ return function(msg) {
+ window.console.log('Processing.js: ' + msg);
+ };
+ }
+ return noop;
+ }());
+
+ // bind prototype
+ Processing.prototype = defaultScope;
+
+ /**
+ * instance store and lookup
+ */
+ Processing.instances = processingInstances;
+ Processing.getInstanceById = function(name) {
+ return processingInstances[processingInstanceIds[name]];
+ };
+
+ // Unsupported Processing File and I/O operations.
+ (function(Processing) {
+ var unsupportedP5 = ("open() createOutput() createInput() BufferedReader selectFolder() " +
+ "dataPath() createWriter() selectOutput() beginRecord() " +
+ "saveStream() endRecord() selectInput() saveBytes() createReader() " +
+ "beginRaw() endRaw() PrintWriter delay()").split(" "),
+ count = unsupportedP5.length,
+ prettyName,
+ p5Name;
+
+ function createUnsupportedFunc(n) {
+ return function() {
+ throw "Processing.js does not support " + n + ".";
+ };
+ }
+
+ while (count--) {
+ prettyName = unsupportedP5[count];
+ p5Name = prettyName.replace("()", "");
+ Processing[p5Name] = createUnsupportedFunc(prettyName);
+ }
+ }(defaultScope));
+
+ // we're done. Return our object.
+ return Processing;
+};
+
+},{}],28:[function(require,module,exports){
+// Base source files
+var source = {
+ virtEquals: require("./Helpers/virtEquals"),
+ virtHashCode: require("./Helpers/virtHashCode"),
+ ObjectIterator: require("./Helpers/ObjectIterator"),
+ PConstants: require("./Helpers/PConstants"),
+ ArrayList: require("./Objects/ArrayList"),
+ HashMap: require("./Objects/HashMap"),
+ PVector: require("./Objects/PVector"),
+ PFont: require("./Objects/PFont"),
+ Char: require("./Objects/Char"),
+ XMLAttribute: require("./Objects/XMLAttribute"),
+ XMLElement: require("./Objects/XMLElement"),
+ PMatrix2D: require("./Objects/PMatrix2D"),
+ PMatrix3D: require("./Objects/PMatrix3D"),
+ PShape: require("./Objects/PShape"),
+ colors: require("./Objects/webcolors"),
+ PShapeSVG: require("./Objects/PShapeSVG"),
+ CommonFunctions: require("./P5Functions/commonFunctions"),
+ defaultScope: require("./Helpers/defaultScope"),
+ Processing: require("./Processing"),
+ setupParser: require("./Parser/Parser"),
+ finalize: require("./Helpers/finalizeProcessing")
+};
+
+// Additional code that gets tacked onto "p" during
+// instantiation of a Processing sketch.
+source.extend = {
+ withMath: require("./P5Functions/Math.js"),
+ withProxyFunctions: require("./P5Functions/JavaProxyFunctions")(source.virtHashCode, source.virtEquals),
+ withTouch: require("./P5Functions/touchmouse"),
+ withCommonFunctions: source.CommonFunctions.withCommonFunctions
+};
+
+/**
+ * Processing.js building function
+ */
+module.exports = function buildProcessingJS(Browser, testHarness) {
+ var noop = function(){},
+ virtEquals = source.virtEquals,
+ virtHashCode = source.virtHashCode,
+ PConstants = source.PConstants,
+ CommonFunctions = source.CommonFunctions,
+ ObjectIterator = source.ObjectIterator,
+ Char = source.Char,
+ XMLAttribute = source.XMLAttribute(),
+
+ ArrayList = source.ArrayList({
+ virtHashCode: virtHashCode,
+ virtEquals: virtEquals
+ }),
+
+ HashMap = source.HashMap({
+ virtHashCode: virtHashCode,
+ virtEquals: virtEquals
+ }),
+
+ PVector = source.PVector({
+ PConstants: PConstants
+ }),
+
+ PFont = source.PFont({
+ Browser: Browser,
+ noop: noop
+ }),
+
+ XMLElement = source.XMLElement({
+ Browser: Browser,
+ XMLAttribute: XMLAttribute
+ }),
+
+ PMatrix2D = source.PMatrix2D({
+ p:CommonFunctions
+ }),
+
+ PMatrix3D = source.PMatrix3D({
+ p:CommonFunctions
+ }),
+
+ PShape = source.PShape({
+ PConstants: PConstants,
+ PMatrix2D: PMatrix2D,
+ PMatrix3D: PMatrix3D
+ }),
+
+ PShapeSVG = source.PShapeSVG({
+ CommonFunctions: CommonFunctions,
+ PConstants: PConstants,
+ PShape: PShape,
+ XMLElement: XMLElement,
+ colors: source.colors
+ }),
+
+ defaultScope = source.defaultScope({
+ ArrayList: ArrayList,
+ HashMap: HashMap,
+ PVector: PVector,
+ PFont: PFont,
+ PShapeSVG: PShapeSVG,
+ ObjectIterator: ObjectIterator,
+ PConstants: PConstants,
+ Char: Char,
+ XMLElement: XMLElement,
+ XML: XMLElement
+ }),
+
+ Processing = source.Processing({
+ defaultScope: defaultScope,
+ Browser: Browser,
+ extend: source.extend,
+ noop: noop
+ });
+
+ // set up the Processing syntax parser
+ Processing = source.setupParser(Processing, {
+ Browser: Browser,
+ aFunctions: testHarness,
+ defaultScope: defaultScope
+ });
+
+ // finalise the Processing object
+ Processing = source.finalize(Processing, {
+ version: require('../package.json').version,
+ isDomPresent: false || Browser.isDomPresent,
+ window: Browser.window,
+ document: Browser.document,
+ noop: noop
+ });
+
+ // done.
+ return Processing;
+};
+
+},{"../package.json":2,"./Helpers/ObjectIterator":3,"./Helpers/PConstants":4,"./Helpers/defaultScope":6,"./Helpers/finalizeProcessing":7,"./Helpers/virtEquals":8,"./Helpers/virtHashCode":9,"./Objects/ArrayList":10,"./Objects/Char":11,"./Objects/HashMap":12,"./Objects/PFont":13,"./Objects/PMatrix2D":14,"./Objects/PMatrix3D":15,"./Objects/PShape":16,"./Objects/PShapeSVG":17,"./Objects/PVector":18,"./Objects/XMLAttribute":19,"./Objects/XMLElement":20,"./Objects/webcolors":21,"./P5Functions/JavaProxyFunctions":22,"./P5Functions/Math.js":23,"./P5Functions/commonFunctions":24,"./P5Functions/touchmouse":25,"./Parser/Parser":26,"./Processing":27}]},{},[1]);