define("dojo/_base/declare", ["./kernel", "../has", "./lang"], function(dojo, has, lang){ // module: // dojo/_base/declare // summary: // This module defines dojo.declare. var mix = lang.mixin, op = Object.prototype, opts = op.toString, xtor = new Function, counter = 0, cname = "constructor"; function err(msg, cls){ throw new Error("declare" + (cls ? " " + cls : "") + ": " + msg); } // C3 Method Resolution Order (see http://www.python.org/download/releases/2.3/mro/) function c3mro(bases, className){ var result = [], roots = [{cls: 0, refs: []}], nameMap = {}, clsCount = 1, l = bases.length, i = 0, j, lin, base, top, proto, rec, name, refs; // build a list of bases naming them if needed for(; i < l; ++i){ base = bases[i]; if(!base){ err("mixin #" + i + " is unknown. Did you use dojo.require to pull it in?", className); }else if(opts.call(base) != "[object Function]"){ err("mixin #" + i + " is not a callable constructor.", className); } lin = base._meta ? base._meta.bases : [base]; top = 0; // add bases to the name map for(j = lin.length - 1; j >= 0; --j){ proto = lin[j].prototype; if(!proto.hasOwnProperty("declaredClass")){ proto.declaredClass = "uniqName_" + (counter++); } name = proto.declaredClass; if(!nameMap.hasOwnProperty(name)){ nameMap[name] = {count: 0, refs: [], cls: lin[j]}; ++clsCount; } rec = nameMap[name]; if(top && top !== rec){ rec.refs.push(top); ++top.count; } top = rec; } ++top.count; roots[0].refs.push(top); } // remove classes without external references recursively while(roots.length){ top = roots.pop(); result.push(top.cls); --clsCount; // optimization: follow a single-linked chain while(refs = top.refs, refs.length == 1){ top = refs[0]; if(!top || --top.count){ // branch or end of chain => do not end to roots top = 0; break; } result.push(top.cls); --clsCount; } if(top){ // branch for(i = 0, l = refs.length; i < l; ++i){ top = refs[i]; if(!--top.count){ roots.push(top); } } } } if(clsCount){ err("can't build consistent linearization", className); } // calculate the superclass offset base = bases[0]; result[0] = base ? base._meta && base === result[result.length - base._meta.bases.length] ? base._meta.bases.length : 1 : 0; return result; } function inherited(args, a, f){ var name, chains, bases, caller, meta, base, proto, opf, pos, cache = this._inherited = this._inherited || {}; // crack arguments if(typeof args == "string"){ name = args; args = a; a = f; } f = 0; caller = args.callee; name = name || caller.nom; if(!name){ err("can't deduce a name to call inherited()", this.declaredClass); } meta = this.constructor._meta; bases = meta.bases; pos = cache.p; if(name != cname){ // method if(cache.c !== caller){ // cache bust pos = 0; base = bases[0]; meta = base._meta; if(meta.hidden[name] !== caller){ // error detection chains = meta.chains; if(chains && typeof chains[name] == "string"){ err("calling chained method with inherited: " + name, this.declaredClass); } // find caller do{ meta = base._meta; proto = base.prototype; if(meta && (proto[name] === caller && proto.hasOwnProperty(name) || meta.hidden[name] === caller)){ break; } }while(base = bases[++pos]); // intentional assignment pos = base ? pos : -1; } } // find next base = bases[++pos]; if(base){ proto = base.prototype; if(base._meta && proto.hasOwnProperty(name)){ f = proto[name]; }else{ opf = op[name]; do{ proto = base.prototype; f = proto[name]; if(f && (base._meta ? proto.hasOwnProperty(name) : f !== opf)){ break; } }while(base = bases[++pos]); // intentional assignment } } f = base && f || op[name]; }else{ // constructor if(cache.c !== caller){ // cache bust pos = 0; meta = bases[0]._meta; if(meta && meta.ctor !== caller){ // error detection chains = meta.chains; if(!chains || chains.constructor !== "manual"){ err("calling chained constructor with inherited", this.declaredClass); } // find caller while(base = bases[++pos]){ // intentional assignment meta = base._meta; if(meta && meta.ctor === caller){ break; } } pos = base ? pos : -1; } } // find next while(base = bases[++pos]){ // intentional assignment meta = base._meta; f = meta ? meta.ctor : base; if(f){ break; } } f = base && f; } // cache the found super method cache.c = f; cache.p = pos; // now we have the result if(f){ return a === true ? f : f.apply(this, a || args); } // intentionally no return if a super method was not found } function getInherited(name, args){ if(typeof name == "string"){ return this.__inherited(name, args, true); } return this.__inherited(name, true); } function inherited__debug(args, a1, a2){ var f = this.getInherited(args, a1); if(f){ return f.apply(this, a2 || a1 || args); } // intentionally no return if a super method was not found } var inheritedImpl = dojo.config.isDebug ? inherited__debug : inherited; // emulation of "instanceof" function isInstanceOf(cls){ var bases = this.constructor._meta.bases; for(var i = 0, l = bases.length; i < l; ++i){ if(bases[i] === cls){ return true; } } return this instanceof cls; } function mixOwn(target, source){ // add props adding metadata for incoming functions skipping a constructor for(var name in source){ if(name != cname && source.hasOwnProperty(name)){ target[name] = source[name]; } } if(has("bug-for-in-skips-shadowed")){ for(var extraNames= lang._extraNames, i= extraNames.length; i;){ name = extraNames[--i]; if(name != cname && source.hasOwnProperty(name)){ target[name] = source[name]; } } } } // implementation of safe mixin function function safeMixin(target, source){ var name, t; // add props adding metadata for incoming functions skipping a constructor for(name in source){ t = source[name]; if((t !== op[name] || !(name in op)) && name != cname){ if(opts.call(t) == "[object Function]"){ // non-trivial function method => attach its name t.nom = name; } target[name] = t; } } if(has("bug-for-in-skips-shadowed")){ for(var extraNames= lang._extraNames, i= extraNames.length; i;){ name = extraNames[--i]; t = source[name]; if((t !== op[name] || !(name in op)) && name != cname){ if(opts.call(t) == "[object Function]"){ // non-trivial function method => attach its name t.nom = name; } target[name] = t; } } } return target; } function extend(source){ declare.safeMixin(this.prototype, source); return this; } // chained constructor compatible with the legacy dojo.declare() function chainedConstructor(bases, ctorSpecial){ return function(){ var a = arguments, args = a, a0 = a[0], f, i, m, l = bases.length, preArgs; if(!(this instanceof a.callee)){ // not called via new, so force it return applyNew(a); } //this._inherited = {}; // perform the shaman's rituals of the original dojo.declare() // 1) call two types of the preamble if(ctorSpecial && (a0 && a0.preamble || this.preamble)){ // full blown ritual preArgs = new Array(bases.length); // prepare parameters preArgs[0] = a; for(i = 0;;){ // process the preamble of the 1st argument a0 = a[0]; if(a0){ f = a0.preamble; if(f){ a = f.apply(this, a) || a; } } // process the preamble of this class f = bases[i].prototype; f = f.hasOwnProperty("preamble") && f.preamble; if(f){ a = f.apply(this, a) || a; } // one peculiarity of the preamble: // it is called if it is not needed, // e.g., there is no constructor to call // let's watch for the last constructor // (see ticket #9795) if(++i == l){ break; } preArgs[i] = a; } } // 2) call all non-trivial constructors using prepared arguments for(i = l - 1; i >= 0; --i){ f = bases[i]; m = f._meta; f = m ? m.ctor : f; if(f){ f.apply(this, preArgs ? preArgs[i] : a); } } // 3) continue the original ritual: call the postscript f = this.postscript; if(f){ f.apply(this, args); } }; } // chained constructor compatible with the legacy dojo.declare() function singleConstructor(ctor, ctorSpecial){ return function(){ var a = arguments, t = a, a0 = a[0], f; if(!(this instanceof a.callee)){ // not called via new, so force it return applyNew(a); } //this._inherited = {}; // perform the shaman's rituals of the original dojo.declare() // 1) call two types of the preamble if(ctorSpecial){ // full blown ritual if(a0){ // process the preamble of the 1st argument f = a0.preamble; if(f){ t = f.apply(this, t) || t; } } f = this.preamble; if(f){ // process the preamble of this class f.apply(this, t); // one peculiarity of the preamble: // it is called even if it is not needed, // e.g., there is no constructor to call // let's watch for the last constructor // (see ticket #9795) } } // 2) call a constructor if(ctor){ ctor.apply(this, a); } // 3) continue the original ritual: call the postscript f = this.postscript; if(f){ f.apply(this, a); } }; } // plain vanilla constructor (can use inherited() to call its base constructor) function simpleConstructor(bases){ return function(){ var a = arguments, i = 0, f, m; if(!(this instanceof a.callee)){ // not called via new, so force it return applyNew(a); } //this._inherited = {}; // perform the shaman's rituals of the original dojo.declare() // 1) do not call the preamble // 2) call the top constructor (it can use this.inherited()) for(; f = bases[i]; ++i){ // intentional assignment m = f._meta; f = m ? m.ctor : f; if(f){ f.apply(this, a); break; } } // 3) call the postscript f = this.postscript; if(f){ f.apply(this, a); } }; } function chain(name, bases, reversed){ return function(){ var b, m, f, i = 0, step = 1; if(reversed){ i = bases.length - 1; step = -1; } for(; b = bases[i]; i += step){ // intentional assignment m = b._meta; f = (m ? m.hidden : b.prototype)[name]; if(f){ f.apply(this, arguments); } } }; } // forceNew(ctor) // return a new object that inherits from ctor.prototype but // without actually running ctor on the object. function forceNew(ctor){ // create object with correct prototype using a do-nothing // constructor xtor.prototype = ctor.prototype; var t = new xtor; xtor.prototype = null; // clean up return t; } // applyNew(args) // just like 'new ctor()' except that the constructor and its arguments come // from args, which must be an array or an arguments object function applyNew(args){ // create an object with ctor's prototype but without // calling ctor on it. var ctor = args.callee, t = forceNew(ctor); // execute the real constructor on the new object ctor.apply(t, args); return t; } function declare(className, superclass, props){ // crack parameters if(typeof className != "string"){ props = superclass; superclass = className; className = ""; } props = props || {}; var proto, i, t, ctor, name, bases, chains, mixins = 1, parents = superclass; // build a prototype if(opts.call(superclass) == "[object Array]"){ // C3 MRO bases = c3mro(superclass, className); t = bases[0]; mixins = bases.length - t; superclass = bases[mixins]; }else{ bases = [0]; if(superclass){ if(opts.call(superclass) == "[object Function]"){ t = superclass._meta; bases = bases.concat(t ? t.bases : superclass); }else{ err("base class is not a callable constructor.", className); } }else if(superclass !== null){ err("unknown base class. Did you use dojo.require to pull it in?", className); } } if(superclass){ for(i = mixins - 1;; --i){ proto = forceNew(superclass); if(!i){ // stop if nothing to add (the last base) break; } // mix in properties t = bases[i]; (t._meta ? mixOwn : mix)(proto, t.prototype); // chain in new constructor ctor = new Function; ctor.superclass = superclass; ctor.prototype = proto; superclass = proto.constructor = ctor; } }else{ proto = {}; } // add all properties declare.safeMixin(proto, props); // add constructor t = props.constructor; if(t !== op.constructor){ t.nom = cname; proto.constructor = t; } // collect chains and flags for(i = mixins - 1; i; --i){ // intentional assignment t = bases[i]._meta; if(t && t.chains){ chains = mix(chains || {}, t.chains); } } if(proto["-chains-"]){ chains = mix(chains || {}, proto["-chains-"]); } // build ctor t = !chains || !chains.hasOwnProperty(cname); bases[0] = ctor = (chains && chains.constructor === "manual") ? simpleConstructor(bases) : (bases.length == 1 ? singleConstructor(props.constructor, t) : chainedConstructor(bases, t)); // add meta information to the constructor ctor._meta = {bases: bases, hidden: props, chains: chains, parents: parents, ctor: props.constructor}; ctor.superclass = superclass && superclass.prototype; ctor.extend = extend; ctor.prototype = proto; proto.constructor = ctor; // add "standard" methods to the prototype proto.getInherited = getInherited; proto.isInstanceOf = isInstanceOf; proto.inherited = inheritedImpl; proto.__inherited = inherited; // add name if specified if(className){ proto.declaredClass = className; lang.setObject(className, ctor); } // build chains and add them to the prototype if(chains){ for(name in chains){ if(proto[name] && typeof chains[name] == "string" && name != cname){ t = proto[name] = chain(name, bases, chains[name] === "after"); t.nom = name; } } } // chained methods do not return values // no need to chain "invisible" functions return ctor; // Function } /*===== dojo.declare = function(className, superclass, props){ // summary: // Create a feature-rich constructor from compact notation. // className: String?: // The optional name of the constructor (loosely, a "class") // stored in the "declaredClass" property in the created prototype. // It will be used as a global name for a created constructor. // superclass: Function|Function[]: // May be null, a Function, or an Array of Functions. This argument // specifies a list of bases (the left-most one is the most deepest // base). // props: Object: // An object whose properties are copied to the created prototype. // Add an instance-initialization function by making it a property // named "constructor". // returns: // New constructor function. // description: // Create a constructor using a compact notation for inheritance and // prototype extension. // // Mixin ancestors provide a type of multiple inheritance. // Prototypes of mixin ancestors are copied to the new class: // changes to mixin prototypes will not affect classes to which // they have been mixed in. // // Ancestors can be compound classes created by this version of // dojo.declare. In complex cases all base classes are going to be // linearized according to C3 MRO algorithm // (see http://www.python.org/download/releases/2.3/mro/ for more // details). // // "className" is cached in "declaredClass" property of the new class, // if it was supplied. The immediate super class will be cached in // "superclass" property of the new class. // // Methods in "props" will be copied and modified: "nom" property // (the declared name of the method) will be added to all copied // functions to help identify them for the internal machinery. Be // very careful, while reusing methods: if you use the same // function under different names, it can produce errors in some // cases. // // It is possible to use constructors created "manually" (without // dojo.declare) as bases. They will be called as usual during the // creation of an instance, their methods will be chained, and even // called by "this.inherited()". // // Special property "-chains-" governs how to chain methods. It is // a dictionary, which uses method names as keys, and hint strings // as values. If a hint string is "after", this method will be // called after methods of its base classes. If a hint string is // "before", this method will be called before methods of its base // classes. // // If "constructor" is not mentioned in "-chains-" property, it will // be chained using the legacy mode: using "after" chaining, // calling preamble() method before each constructor, if available, // and calling postscript() after all constructors were executed. // If the hint is "after", it is chained as a regular method, but // postscript() will be called after the chain of constructors. // "constructor" cannot be chained "before", but it allows // a special hint string: "manual", which means that constructors // are not going to be chained in any way, and programmer will call // them manually using this.inherited(). In the latter case // postscript() will be called after the construction. // // All chaining hints are "inherited" from base classes and // potentially can be overridden. Be very careful when overriding // hints! Make sure that all chained methods can work in a proposed // manner of chaining. // // Once a method was chained, it is impossible to unchain it. The // only exception is "constructor". You don't need to define a // method in order to supply a chaining hint. // // If a method is chained, it cannot use this.inherited() because // all other methods in the hierarchy will be called automatically. // // Usually constructors and initializers of any kind are chained // using "after" and destructors of any kind are chained as // "before". Note that chaining assumes that chained methods do not // return any value: any returned value will be discarded. // // example: // | dojo.declare("my.classes.bar", my.classes.foo, { // | // properties to be added to the class prototype // | someValue: 2, // | // initialization function // | constructor: function(){ // | this.myComplicatedObject = new ReallyComplicatedObject(); // | }, // | // other functions // | someMethod: function(){ // | doStuff(); // | } // | }); // // example: // | var MyBase = dojo.declare(null, { // | // constructor, properties, and methods go here // | // ... // | }); // | var MyClass1 = dojo.declare(MyBase, { // | // constructor, properties, and methods go here // | // ... // | }); // | var MyClass2 = dojo.declare(MyBase, { // | // constructor, properties, and methods go here // | // ... // | }); // | var MyDiamond = dojo.declare([MyClass1, MyClass2], { // | // constructor, properties, and methods go here // | // ... // | }); // // example: // | var F = function(){ console.log("raw constructor"); }; // | F.prototype.method = function(){ // | console.log("raw method"); // | }; // | var A = dojo.declare(F, { // | constructor: function(){ // | console.log("A.constructor"); // | }, // | method: function(){ // | console.log("before calling F.method..."); // | this.inherited(arguments); // | console.log("...back in A"); // | } // | }); // | new A().method(); // | // will print: // | // raw constructor // | // A.constructor // | // before calling F.method... // | // raw method // | // ...back in A // // example: // | var A = dojo.declare(null, { // | "-chains-": { // | destroy: "before" // | } // | }); // | var B = dojo.declare(A, { // | constructor: function(){ // | console.log("B.constructor"); // | }, // | destroy: function(){ // | console.log("B.destroy"); // | } // | }); // | var C = dojo.declare(B, { // | constructor: function(){ // | console.log("C.constructor"); // | }, // | destroy: function(){ // | console.log("C.destroy"); // | } // | }); // | new C().destroy(); // | // prints: // | // B.constructor // | // C.constructor // | // C.destroy // | // B.destroy // // example: // | var A = dojo.declare(null, { // | "-chains-": { // | constructor: "manual" // | } // | }); // | var B = dojo.declare(A, { // | constructor: function(){ // | // ... // | // call the base constructor with new parameters // | this.inherited(arguments, [1, 2, 3]); // | // ... // | } // | }); // // example: // | var A = dojo.declare(null, { // | "-chains-": { // | m1: "before" // | }, // | m1: function(){ // | console.log("A.m1"); // | }, // | m2: function(){ // | console.log("A.m2"); // | } // | }); // | var B = dojo.declare(A, { // | "-chains-": { // | m2: "after" // | }, // | m1: function(){ // | console.log("B.m1"); // | }, // | m2: function(){ // | console.log("B.m2"); // | } // | }); // | var x = new B(); // | x.m1(); // | // prints: // | // B.m1 // | // A.m1 // | x.m2(); // | // prints: // | // A.m2 // | // B.m2 return new Function(); // Function }; =====*/ /*===== dojo.safeMixin = function(target, source){ // summary: // Mix in properties skipping a constructor and decorating functions // like it is done by dojo.declare. // target: Object // Target object to accept new properties. // source: Object // Source object for new properties. // description: // This function is used to mix in properties like lang.mixin does, // but it skips a constructor property and decorates functions like // dojo.declare does. // // It is meant to be used with classes and objects produced with // dojo.declare. Functions mixed in with dojo.safeMixin can use // this.inherited() like normal methods. // // This function is used to implement extend() method of a constructor // produced with dojo.declare(). // // example: // | var A = dojo.declare(null, { // | m1: function(){ // | console.log("A.m1"); // | }, // | m2: function(){ // | console.log("A.m2"); // | } // | }); // | var B = dojo.declare(A, { // | m1: function(){ // | this.inherited(arguments); // | console.log("B.m1"); // | } // | }); // | B.extend({ // | m2: function(){ // | this.inherited(arguments); // | console.log("B.m2"); // | } // | }); // | var x = new B(); // | dojo.safeMixin(x, { // | m1: function(){ // | this.inherited(arguments); // | console.log("X.m1"); // | }, // | m2: function(){ // | this.inherited(arguments); // | console.log("X.m2"); // | } // | }); // | x.m2(); // | // prints: // | // A.m1 // | // B.m1 // | // X.m1 }; =====*/ /*===== Object.inherited = function(name, args, newArgs){ // summary: // Calls a super method. // name: String? // The optional method name. Should be the same as the caller's // name. Usually "name" is specified in complex dynamic cases, when // the calling method was dynamically added, undecorated by // dojo.declare, and it cannot be determined. // args: Arguments // The caller supply this argument, which should be the original // "arguments". // newArgs: Object? // If "true", the found function will be returned without // executing it. // If Array, it will be used to call a super method. Otherwise // "args" will be used. // returns: // Whatever is returned by a super method, or a super method itself, // if "true" was specified as newArgs. // description: // This method is used inside method of classes produced with // dojo.declare to call a super method (next in the chain). It is // used for manually controlled chaining. Consider using the regular // chaining, because it is faster. Use "this.inherited()" only in // complex cases. // // This method cannot me called from automatically chained // constructors including the case of a special (legacy) // constructor chaining. It cannot be called from chained methods. // // If "this.inherited()" cannot find the next-in-chain method, it // does nothing and returns "undefined". The last method in chain // can be a default method implemented in Object, which will be // called last. // // If "name" is specified, it is assumed that the method that // received "args" is the parent method for this call. It is looked // up in the chain list and if it is found the next-in-chain method // is called. If it is not found, the first-in-chain method is // called. // // If "name" is not specified, it will be derived from the calling // method (using a methoid property "nom"). // // example: // | var B = dojo.declare(A, { // | method1: function(a, b, c){ // | this.inherited(arguments); // | }, // | method2: function(a, b){ // | return this.inherited(arguments, [a + b]); // | } // | }); // | // next method is not in the chain list because it is added // | // manually after the class was created. // | B.prototype.method3 = function(){ // | console.log("This is a dynamically-added method."); // | this.inherited("method3", arguments); // | }; // example: // | var B = dojo.declare(A, { // | method: function(a, b){ // | var super = this.inherited(arguments, true); // | // ... // | if(!super){ // | console.log("there is no super method"); // | return 0; // | } // | return super.apply(this, arguments); // | } // | }); return {}; // Object } =====*/ /*===== Object.getInherited = function(name, args){ // summary: // Returns a super method. // name: String? // The optional method name. Should be the same as the caller's // name. Usually "name" is specified in complex dynamic cases, when // the calling method was dynamically added, undecorated by // dojo.declare, and it cannot be determined. // args: Arguments // The caller supply this argument, which should be the original // "arguments". // returns: // Returns a super method (Function) or "undefined". // description: // This method is a convenience method for "this.inherited()". // It uses the same algorithm but instead of executing a super // method, it returns it, or "undefined" if not found. // // example: // | var B = dojo.declare(A, { // | method: function(a, b){ // | var super = this.getInherited(arguments); // | // ... // | if(!super){ // | console.log("there is no super method"); // | return 0; // | } // | return super.apply(this, arguments); // | } // | }); return {}; // Object } =====*/ /*===== Object.isInstanceOf = function(cls){ // summary: // Checks the inheritance chain to see if it is inherited from this // class. // cls: Function // Class constructor. // returns: // "true", if this object is inherited from this class, "false" // otherwise. // description: // This method is used with instances of classes produced with // dojo.declare to determine of they support a certain interface or // not. It models "instanceof" operator. // // example: // | var A = dojo.declare(null, { // | // constructor, properties, and methods go here // | // ... // | }); // | var B = dojo.declare(null, { // | // constructor, properties, and methods go here // | // ... // | }); // | var C = dojo.declare([A, B], { // | // constructor, properties, and methods go here // | // ... // | }); // | var D = dojo.declare(A, { // | // constructor, properties, and methods go here // | // ... // | }); // | // | var a = new A(), b = new B(), c = new C(), d = new D(); // | // | console.log(a.isInstanceOf(A)); // true // | console.log(b.isInstanceOf(A)); // false // | console.log(c.isInstanceOf(A)); // true // | console.log(d.isInstanceOf(A)); // true // | // | console.log(a.isInstanceOf(B)); // false // | console.log(b.isInstanceOf(B)); // true // | console.log(c.isInstanceOf(B)); // true // | console.log(d.isInstanceOf(B)); // false // | // | console.log(a.isInstanceOf(C)); // false // | console.log(b.isInstanceOf(C)); // false // | console.log(c.isInstanceOf(C)); // true // | console.log(d.isInstanceOf(C)); // false // | // | console.log(a.isInstanceOf(D)); // false // | console.log(b.isInstanceOf(D)); // false // | console.log(c.isInstanceOf(D)); // false // | console.log(d.isInstanceOf(D)); // true return {}; // Object } =====*/ /*===== Object.extend = function(source){ // summary: // Adds all properties and methods of source to constructor's // prototype, making them available to all instances created with // constructor. This method is specific to constructors created with // dojo.declare. // source: Object // Source object which properties are going to be copied to the // constructor's prototype. // description: // Adds source properties to the constructor's prototype. It can // override existing properties. // // This method is similar to dojo.extend function, but it is specific // to constructors produced by dojo.declare. It is implemented // using dojo.safeMixin, and it skips a constructor property, // and properly decorates copied functions. // // example: // | var A = dojo.declare(null, { // | m1: function(){}, // | s1: "Popokatepetl" // | }); // | A.extend({ // | m1: function(){}, // | m2: function(){}, // | f1: true, // | d1: 42 // | }); }; =====*/ dojo.safeMixin = declare.safeMixin = safeMixin; dojo.declare = declare; return declare; });