/** * Handles building of classes * * Copyright (C) 2011, 2012, 2013, 2014 Free Software Foundation, Inc. * * This file is part of GNU ease.js. * * ease.js is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * * TODO: This module is currently being tested /indirectly/ by the class * tests. This is because of a refactoring. All of this logic used to * be part of the class module. Test this module directly, but keep * the existing class tests in tact for a higher-level test. */ var util = require( './util' ), Warning = require( './warn' ).Warning, Symbol = require( './util/Symbol' ), hasOwn = Object.prototype.hasOwnProperty, /** * IE contains a nasty enumeration "bug" (poor implementation) that makes * toString unenumerable. This means that, if you do obj.toString = foo, * toString will NOT show up in `for` or hasOwnProperty(). This is a problem. * * This test will determine if this poor implementation exists. */ enum_bug = ( Object.prototype.propertyIsEnumerable.call( { toString: function() {} }, 'toString' ) === false ) ? true : false, /** * Hash of reserved members * * These methods cannot be defined in the class. They are for internal use * only. We must check both properties and methods to ensure that neither is * defined. * * @type {Object.} */ reserved_members = { '__initProps': true, 'constructor': true, }, /** * Hash of methods that must be public * * Notice that this is a list of /methods/, not members, because this check * is performed only for methods. This is for performance reasons. We do not * have a situation where we will want to check for properties as well. * * @type {Object.} */ public_methods = { '__construct': true, '__mixin': true, 'toString': true, '__toString': true, }, /** * Symbol used to encapsulate internal data * * Note that this is intentionally generated *outside* the ClassBuilder * instance; this ensures that it is properly encapsulated and will not * be exposed on the Classbuilder instance (which would defeat the * purpose). */ _priv = Symbol() ; /** * Initializes class builder with given member builder * * The 'new' keyword is not required when instantiating this constructor. * * @param {Object} member_builder member builder * * @param {VisibilityObjectFactory} visibility_factory visibility object * generator * * @constructor */ module.exports = exports = function ClassBuilder( warn_handler, member_builder, visibility_factory ) { // allow ommitting the 'new' keyword if ( !( this instanceof exports ) ) { // module.exports for Closure Compiler return new module.exports( warn_handler, member_builder, visibility_factory ); } /** * Determines how warnings should be handled * @type {WarningHandler} */ this._warnHandler = warn_handler; /** * Used for building class members * @type {Object} */ this._memberBuilder = member_builder; /** * Generates visibility object * @type {VisibilityObjectFactory} */ this._visFactory = visibility_factory; /** * Class id counter, to be increment on each new definition * @type {number} */ this._classId = 0; /** * Instance id counter, to be incremented on each new instance * @type {number} */ this._instanceId = 0; /** * A flag to let the system know that we are currently attempting to access * a static property from within a method. This means that the caller should * be given access to additional levels of visibility. * * @type {boolean} */ this._spropInternal = false; }; /** * Default class implementation * * @return undefined */ exports.ClassBase = function Class() {}; // the base class has the class identifier 0 util.defineSecureProp( exports.ClassBase, '__cid', 0 ); /** * Default static property method * * This simply returns undefined, signifying that the property was not found. * * @param {string} prop requested property * * @return {undefined} */ exports.ClassBase.$ = function( prop, val ) { if ( val !== undefined ) { throw ReferenceError( "Cannot set value of undeclared static property '" + prop + "'" ); } return undefined; }; /** * Returns a hash of the reserved members * * The returned object is a copy of the original. It cannot be used to modify * the internal list of reserved members. * * @return {Object.} reserved members */ exports.getReservedMembers = function() { // return a copy of the reserved members return util.clone( reserved_members, true ); }; /** * Returns a hash of the forced-public methods * * The returned object is a copy of the original. It cannot be used to modify * the internal list of reserved members. * * @return {Object.} forced-public methods */ exports.getForcedPublicMethods = function() { return util.clone( public_methods, true ); }; /** * Returns reference to metadata for the requested class * * Since a reference is returned (rather than a copy), the returned object can * be modified to alter the metadata. * * @param {Function|Object} cls class from which to retrieve metadata * * @return {__class_meta} or null if unavailable */ exports.getMeta = function( cls ) { return ( cls[ _priv ] || {} ).meta || null; } /** * Allow OBJ to assume an identity as a class * * This is useful to use objects in situations where classes are expected, * as it eliminates the need for handling of special cases. * * This is intended for internal use---there are no guarantees as to what * methods ease.js may expect that a class-like object incorporate. That * guarantee may exist in the future, but until then, stay away. * * @param {Object} obj object to masquerade as an ease.js class * * @return {Object} OBJ */ exports.masquerade = function( obj ) { // XXX: this is duplicated; abstract util.defineSecureProp( obj, _priv, {} ); createMeta( obj, exports.ClassBase ); return obj; }; /** * Determines if the class is an instance of the given type * * The given type can be a class, interface, trait or any other type of object. * It may be used in place of the 'instanceof' operator and contains additional * enhancements that the operator is unable to provide due to prototypal * restrictions. * * @param {Object} type expected type * @param {Object} instance instance to check * * @return {boolean} true if instance is an instance of type, otherwise false */ exports.isInstanceOf = function( type, instance ) { var meta, implemented, i; if ( !( type && instance ) ) { return false; } // defer check to type, falling back to a more primitive check; this // also allows extending ease.js' type system return !!( type.__isInstanceOf || _instChk )( type, instance ); } /** * Wrapper around ECMAScript instanceof check * * This will not throw an error if TYPE is not a function. * * Note that a try/catch is used instead of checking first to see if TYPE is * a function; this is due to the implementation of, notably, IE, which * allows instanceof to be used on some DOM objects with typeof `object'. * These same objects have typeof `function' in other browsers. * * @param {*} type constructor to check against * @param {Object} instance instance to examine * * @return {boolean} whether INSTANCE is an instance of TYPE */ function _instChk( type, instance ) { try { // check prototype chain (will throw an error if type is not a // constructor) if ( instance instanceof type ) { return true; } } catch ( e ) {} return false; } /** * Mimics class inheritance * * This method will mimic inheritance by setting up the prototype with the * provided base class (or, by default, Class) and copying the additional * properties atop of it. * * The class to inherit from (the first argument) is optional. If omitted, the * first argument will be considered to be the properties list. * * @param {Function|Object} _ parent or definition object * @param {Object=} __ definition object if parent was provided * * @return {Function} extended class */ exports.prototype.build = function extend( _, __ ) { var build = this; var a = arguments, an = a.length, props = ( ( an > 0 ) ? a[ an - 1 ] : 0 ) || {}, base = ( ( an > 1 ) ? a[ an - 2 ] : 0 ) || exports.ClassBase, prototype = this._getBase( base ), cname = '', autoa = false, prop_init = this._memberBuilder.initMembers(), members = this._memberBuilder.initMembers( prototype ), static_members = { methods: this._memberBuilder.initMembers(), props: this._memberBuilder.initMembers(), }, // constructor may be different than base pmeta = exports.getMeta( prototype.constructor ) || {}, abstract_methods = util.clone( pmeta.abstractMethods ) || { __length: 0 }, virtual_members = util.clone( pmeta.virtualMembers ) || {} ; // prevent extending final classes (TODO: abstract this check) if ( base.___$$final$$ === true ) { throw Error( "Cannot extend final class " + ( base[ _priv ].meta.name || '(anonymous)' ) ); } // grab the name, if one was provided if ( cname = props.__name ) { // we no longer need it delete props.__name; } // gobble up auto-abstract flag if present if ( ( autoa = props.___$$auto$abstract$$ ) !== undefined ) { delete props.___$$auto$abstract$$; } // IE has problems with toString() if ( enum_bug ) { if ( props.toString !== Object.prototype.toString ) { props.__toString = props.toString; } } // increment class identifier this._classId++; // if we are inheriting from a prototype, we must make sure that all // properties initialized by the ctor are implicitly public; otherwise, // proxying will fail to take place // TODO: see Class.isA TODO if ( ( prototype[ _priv ] || {} ).vis === undefined ) { this._discoverProtoProps( prototype, prop_init ); } // build the various class components (XXX: this is temporary; needs // refactoring) try { this.buildMembers( props, this._classId, base, prop_init, { all: members, 'abstract': abstract_methods, 'static': static_members, 'virtual': virtual_members, }, function( inst ) { return new_class.___$$svis$$; } ); } catch ( e ) { // intercept warnings /only/ if ( e instanceof Warning ) { this._warnHandler.handle( e ); } else { throw e; } } // reference to the parent prototype (for more experienced users) prototype.___$$parent$$ = base.prototype; // set up the new class var new_class = this.createCtor( cname, abstract_methods, members ); // closure to hold static initialization to be used later by subtypes this.initStaticVisibilityObj( new_class ); var _self = this; var staticInit = function( ctor, inheriting ) { _self.attachStatic( ctor, static_members, base, inheriting ); } staticInit( new_class, false ); this._attachPropInit( prototype, prop_init, members, new_class, this._classId ); new_class.prototype = prototype; new_class.prototype.constructor = new_class; new_class.___$$props$$ = prop_init; new_class.___$$methods$$ = members; new_class.___$$sinit$$ = staticInit; attachFlags( new_class, props ); validateAbstract( new_class, cname, abstract_methods, autoa ); // We reduce the overall cost of this definition by defining it on the // prototype rather than during instantiation. While this does increase the // amount of time it takes to access the property through the prototype // chain, it takes much more time to define the property in this manner. // Therefore, we can save a substantial amount of time by defining it on the // prototype rather than on each new instance via __initProps(). util.defineSecureProp( prototype, '__self', new_class.___$$svis$$ ); // create internal metadata for the new class var meta = createMeta( new_class, base, pmeta ); meta.abstractMethods = abstract_methods; meta.virtualMembers = virtual_members; meta.name = cname; attachAbstract( new_class, abstract_methods ); attachId( new_class, this._classId ); // returns a new instance of the class without invoking the constructor // (intended for use in prototype chains) new_class.asPrototype = function() { new_class[ _priv ].extending = true; var inst = new new_class(); new_class[ _priv ].extending = false; return inst; }; return new_class; }; exports.prototype._getBase = function( base ) { var type = ( typeof base ); switch ( type ) { // constructor (we could also check to ensure that the return value of // the constructor is an object, but that is not our concern) case 'function': return ( base[ _priv ] ) ? base.asPrototype() : new base(); // we can use objects as the prototype directly case 'object': return base; } // scalars throw TypeError( 'Must extend from Class, constructor or object' ); }; /** * Discovers public properties on the given object and create an associated * property * * This allows inheriting from a prototype that uses properties by ensuring * that we properly proxy to that property. Otherwise, assigning the value * on the private visibilit object would mask the underlying value rather * than modifying it, leading to an inconsistent and incorrect state. * * This assumes that the object has already been initialized with all the * properties. This may not be the case if the prototype constructor does * not do so, in which case there is nothing we can do. * * This does not recurse on the prototype chian. * * For a more detailed description of this issue, see the interoperability * test case for classes. * * @param {Object} obj object from which to gather properties * @param {Object} prop_init destination property object * * @return {undefined} */ exports.prototype._discoverProtoProps = function( obj, prop_init ) { var hasOwn = Object.hasOwnProperty, pub = prop_init[ 'public' ]; for ( var field in obj ) { var value = obj[ field ]; // we are not interested in the objtype chain, nor are we // interested in functions (which are methods and need not be // proxied) if ( !( hasOwn.call( obj, field ) ) || typeof value === 'function' ) { continue; } this._memberBuilder.buildProp( prop_init, null, field, value, {} ); } }; exports.prototype.buildMembers = function buildMembers( props, class_id, base, prop_init, memberdest, staticInstLookup ) { var context = { _cb: this, // arguments prop_init: prop_init, class_id: class_id, base: base, staticInstLookup: staticInstLookup, defs: {}, // holds member builder state state: {}, // TODO: there does not seem to be tests for these guys; perhaps // this can be rectified with the reflection implementation members: memberdest.all, abstract_methods: memberdest['abstract'], static_members: memberdest['static'], virtual_members: memberdest['virtual'], }; // default member handlers for parser var handlers = { each: _parseEach, property: _parseProp, getset: _parseGetSet, method: _parseMethod, }; // a custom parser may be provided to hook the below property parser; // this can be done to save time on post-processing, or alter the // default behavior of the parser if ( props.___$$parser$$ ) { // this isn't something that we actually want to parse var parser = props.___$$parser$$; delete props.___$$parser$$; // TODO: this is recreated every call! var hjoin = function( name, orig ) { handlers[ name ] = function() { var args = [], i = arguments.length; while ( i-- ) args[ i ] = arguments[ i ]; // invoke the custom handler with the original handler as // its last argument (which the custom handler may choose // not to invoke at all) args.push( orig ); parser[ name ].apply( context, args ); }; }; // this avoids a performance penalty unless the above property is // set parser.each && hjoin( 'each', handlers.each ); parser.property && hjoin( 'property', handlers.property ); parser.getset && hjoin( 'getset', handlers.getset ); parser.method && hjoin( 'method', handlers.method ); } // parse members and process accumulated member state util.propParse( props, handlers, context ); this._memberBuilder.end( context.state ); } function _parseEach( name, value, keywords ) { var defs = this.defs; // disallow use of our internal __initProps() method if ( reserved_members[ name ] === true ) { throw Error( name + " is reserved" ); } // if a member was defined multiple times in the same class // declaration, throw an error (unless the `weak' keyword is // provided, which exists to accomodate this situation) if ( hasOwn.call( defs, name ) && !( keywords['weak'] || defs[ name ].weak ) ) { throw Error( "Cannot redefine method '" + name + "' in same declaration" ); } // keep track of the definitions (only during class declaration) // to catch duplicates defs[ name ] = keywords; } function _parseProp( name, value, keywords ) { var dest = ( keywordStatic( keywords ) ) ? this.static_members.props : this.prop_init; // build a new property, passing in the other members to compare // against for preventing nonsensical overrides this._cb._memberBuilder.buildProp( dest, null, name, value, keywords, this.base ); } function _parseGetSet( name, get, set, keywords ) { var dest = ( keywordStatic( keywords ) ) ? this.static_members.methods : this.members, is_static = keywordStatic( keywords ), instLookup = ( ( is_static ) ? this.staticInstLookup : exports.getMethodInstance ); this._cb._memberBuilder.buildGetterSetter( dest, null, name, get, set, keywords, instLookup, this.class_id, this.base ); } function _parseMethod( name, func, is_abstract, keywords ) { var is_static = keywordStatic( keywords ), dest = ( is_static ) ? this.static_members.methods : this.members, instLookup = ( is_static ) ? this.staticInstLookup : exports.getMethodInstance ; // constructor check if ( public_methods[ name ] === true ) { if ( keywords[ 'protected' ] || keywords[ 'private' ] ) { throw TypeError( name + " must be public" ); } } var used = this._cb._memberBuilder.buildMethod( dest, null, name, func, keywords, instLookup, this.class_id, this.base, this.state ); // do nothing more if we didn't end up using this definition // (this may be the case, for example, with weak members) if ( !used ) { return; } // note the concrete method check; this ensures that weak // abstract methods will not count if a concrete method of the // smae name has already been seen if ( is_abstract ) { this.abstract_methods[ name ] = true; this.abstract_methods.__length++; } else if ( ( hasOwn.call( this.abstract_methods, name ) ) && ( is_abstract === false ) ) { // if this was a concrete method, then it should no longer // be marked as abstract delete this.abstract_methods[ name ]; this.abstract_methods.__length--; } if ( keywords['virtual'] ) { this.virtual_members[ name ] = true; } } /** * Validates abstract class requirements * * We permit an `auto' flag for internal use only that will cause the * abstract flag to be automatically set if the class should be marked as * abstract, instead of throwing an error; this should be used sparingly and * never exposed via a public API (for explicit use), as it goes against the * self-documentation philosophy. * * @param {function()} ctor class * @param {string} cname class name * @param {{__length}} abstract_methods object containing abstract methods * @param {boolean} auto automatically flag as abstract * * @return {undefined} */ function validateAbstract( ctor, cname, abstract_methods, auto ) { if ( ctor.___$$abstract$$ ) { if ( !auto && ( abstract_methods.__length === 0 ) ) { throw TypeError( "Class " + ( cname || "(anonymous)" ) + " was declared as " + "abstract, but contains no abstract members" ); } } else if ( abstract_methods.__length > 0 ) { if ( auto ) { ctor.___$$abstract$$ = true; return; } throw TypeError( "Class " + ( cname || "(anonymous)" ) + " contains abstract " + "members and must therefore be declared abstract" ); } } /** * Creates the constructor for a new class * * This constructor will call the __constructor method for concrete classes * and throw an exception for abstract classes (to prevent instantiation). * * @param {string} cname class name (may be empty) * @param {Array.} abstract_methods list of abstract methods * @param {Object} members class members * * @return {Function} constructor */ exports.prototype.createCtor = function( cname, abstract_methods, members ) { var new_class; if ( abstract_methods.__length === 0 ) { new_class = this.createConcreteCtor( cname, members ); } else { new_class = this.createAbstractCtor( cname ); } util.defineSecureProp( new_class, _priv, {} ); return new_class; } /** * Creates the constructor for a new concrete class * * This constructor will call the __constructor method of the class, if * available. * * @param {string} cname class name (may be empty) * @param {Object} members class members * * @return {function()} constructor */ exports.prototype.createConcreteCtor = function( cname, members ) { var args = null, _self = this; /** * Constructor function to be returned * * The name is set to ClassInstance because some debuggers (e.g. v8) will * show the name of this function for constructor instances rather than * invoking the toString() method * * @constructor * * Suppressing due to complaints for using __initProps * @suppress {checkTypes} */ function ClassInstance() { if ( !( this instanceof ClassInstance ) ) { // store arguments to be passed to constructor and // instantiate new object args = arguments; return new ClassInstance(); } initInstance( this ); this.__initProps(); // If we're extending, we don't actually want to invoke any class // construction logic. The above is sufficient to use this class in a // prototype, so stop here. if ( ClassInstance[ _priv ].extending ) { return; } // generate and store unique instance id attachInstanceId( this, ++_self._instanceId ); // FIXME: this is a bit of a kluge for determining whether the ctor // should be invoked before a child prector... var haspre = ( typeof this.___$$ctor$pre$$ === 'function' ); if ( haspre && ClassInstance.prototype.hasOwnProperty( '___$$ctor$pre$$' ) ) { // FIXME: we're exposing _priv to something that can be // malicously set by the user this.___$$ctor$pre$$( _priv ); haspre = false; } // call the constructor, if one was provided if ( typeof this.__construct === 'function' ) { // note that since 'this' refers to the new class (even // subtypes), and since we're using apply with 'this', the // constructor will be applied to subtypes without a problem this.__construct.apply( this, ( args || arguments ) ); } // FIXME: see above if ( haspre ) { this.___$$ctor$pre$$( _priv ); } if ( typeof this.___$$ctor$post$$ === 'function' ) { this.___$$ctor$post$$( _priv ); } args = null; // attach any instance properties/methods (done after // constructor to ensure they are not overridden) attachInstanceOf( this ); // Provide a more intuitive string representation of the class // instance. If a toString() method was already supplied for us, // use that one instead. if ( !( hasOwn.call( members[ 'public' ], 'toString' ) ) ) { // use __toString if available (see enum_bug), otherwise use // our own defaults this.toString = members[ 'public' ].__toString || ( ( cname ) ? function() { return '#<' + cname + '>'; } : function() { return '#'; } ) ; } }; // provide a more intuitive string representation ClassInstance.toString = ( cname ) ? function() { return cname; } : function() { return '(Class)'; } ; return ClassInstance; } /** * Creates the constructor for a new abstract class * * Calling this constructor will cause an exception to be thrown, as abstract * classes cannot be instantiated. * * @param {string} cname class name (may be empty) * * @return {function()} constructor */ exports.prototype.createAbstractCtor = function( cname ) { var _self = this; var __abstract_self = function() { if ( !__abstract_self[ _priv ].extending ) { throw Error( "Abstract class " + ( cname || '(anonymous)' ) + " cannot be instantiated" ); } }; __abstract_self.toString = ( cname ) ? function() { return cname; } : function() { return '(AbstractClass)'; } ; return __abstract_self; } /** * Attaches __initProps() method to the class prototype * * The __initProps() method will initialize class properties for that instance, * ensuring that their data is not shared with other instances (this is not a * problem with primitive data types). * * The method will also initialize any parent properties (recursive) to ensure * that subtypes do not have a referencing issue, and subtype properties take * precedence over those of the parent. * * @param {Object} prototype prototype to attach method to * @param {Object} properties properties to initialize * * @param {{public: Object, protected: Object, private: Object}} members * * @param {function()} ctor class * @param {number} cid class id * * @return {undefined} */ exports.prototype._attachPropInit = function( prototype, properties, members, ctor, cid ) { var _self = this; util.defineSecureProp( prototype, '__initProps', function( inherit ) { // defaults to false inherit = !!inherit; var iid = this.__iid, parent = prototype.___$$parent$$, vis = this[ _priv ].vis; // first initialize the parent's properties, so that ours will overwrite // them var parent_init = parent && parent.__initProps; if ( typeof parent_init === 'function' ) { // call the parent prop_init, letting it know that it's been // inherited so that it does not initialize private members or // perform other unnecessary tasks parent_init.call( this, true ); } // this will return our property proxy, if supported by our environment, // otherwise just a normal object with everything merged in var inst_props = _self._visFactory.createPropProxy( this, vis, properties[ 'public' ] ); // Copies all public and protected members into inst_props and stores // private in a separate object, which adds inst_props to its prototype // chain and is returned. This is stored in a property referenced by the // class id, so that the private members can be swapped on each method // request, depending on calling context. var vis = vis[ cid ] = _self._visFactory.setup( inst_props, properties, members ); // provide a means to access the actual instance (rather than the // property/visibility object) internally (this will translate to // this.__inst from within a method), but only if we're on our final // object (not a parent) if ( !inherit ) { util.defineSecureProp( vis, '__inst', this ); } }); } /** * Determines if the given keywords should result in a static member * * A member will be considered static if the static or const keywords are given. * * @param {Object} keywords keywords to scan * * @return {boolean} true if to be static, otherwise false */ function keywordStatic( keywords ) { return ( keywords[ 'static' ] || keywords[ 'const' ] ) ? true : false ; } /** * Creates and populates the static visibility object * * @param {Function} ctor class * * @return {undefined} */ exports.prototype.initStaticVisibilityObj = function( ctor ) { var _self = this; /** * the object will simply be another layer in the prototype chain to * prevent protected/private members from being mixed in with the public * * @constructor */ var sobj = function() {}; sobj.prototype = ctor; var sobji = new sobj(); // override __self on the instance's visibility object, giving internal // methods access to the restricted static methods ctor.___$$svis$$ = sobji; // Override the class-level accessor method to allow the system to know we // are within a method. An internal flag is necessary, rather than using an // argument or binding, because those two options are exploitable. An // internal flag cannot be modified by conventional means. sobji.$ = function() { _self._spropInternal = true; var val = ctor.$.apply( ctor, arguments ); _self._spropInternal = false; return val; }; } /** * Attaches static members to a constructor (class) * * Static methods will be assigned to the constructor itself. Properties, on the * other hand, will be assigned to ctor.$. The reason for this is because JS * engines pre-ES5 support no means of sharing references to primitives. Static * properties of subtypes should share references to the static properties of * their parents. * * @param {function()} ctor class * @param {Object} members static members * @param {function()} base base class inheriting from * @param {boolean} inheriting true if inheriting static members, * otherwise false (setting own static * members) * * @return {undefined} */ exports.prototype.attachStatic = function( ctor, members, base, inheriting ) { var methods = members.methods, props = members.props, _self = this ; // "Inherit" the parent's static methods by running the parent's static // initialization method. It is important that we do this before anything, // because this will recursively inherit all members in order, permitting // overrides. var baseinit = base.___$$sinit$$; if ( baseinit ) { baseinit( ctor, true ); } // initialize static property if not yet defined if ( !inheriting ) { ctor.___$$sprops$$ = props; // provide a method to access static properties util.defineSecureProp( ctor, '$', function( prop, val ) { // we use hasOwnProperty to ensure that undefined values will not // cause us to continue checking the parent, thereby potentially // failing to set perfectly legal values var found = false, // Determine if we were invoked in the context of a class. If // so, use that. Otherwise, use ourself. context = ( this.___$$sprops$$ ) ? this : ctor, // We are in a subtype if the context does not match the // constructor. This works because, when invoked for the first // time, this method is not bound to the constructor. In such a // case, we default the context to the constructor and pass that // down the line to each recursive call. Therefore, recursive // calls to subtypes will have a context mismatch. in_subtype = ( context !== ctor ) ; // Attempt to locate the property. First, we check public. If not // available and we are internal (within a method), we can move on // to check other levels of visibility. `found` will contain the // visibility level the property was found in, or false. found = hasOwn.call( props[ 'public' ], prop ) && 'public'; if ( !found && _self._spropInternal ) { // Check for protected/private. We only check for private // properties if we are not currently checking the properties of // a subtype. This works because the context is passed to each // recursive call. found = hasOwn.call( props[ 'protected' ], prop ) && 'protected' || !in_subtype && hasOwn.call( props[ 'private' ], prop ) && 'private' ; } // if we don't own the property, let the parent(s) handle it if ( found === false ) { // TODO: This check is simple, but quick. It may be worth // setting a flag on the class during definition to specify if // it's extending from a non-class base. return ( base.__cid && base.$ || exports.ClassBase.$ ).apply( context, arguments ); } var prop_item = props[ found ][ prop ]; // if a value was provided, this method should be treated as a // setter rather than a getter (we *must* test using // arguments.length to ensure that setting to undefined works) if ( arguments.length > 1 ) { // if const, disallow modification if ( prop_item[ 1 ][ 'const' ] ) { throw TypeError( "Cannot modify constant property '" + prop + "'" ); } prop_item[ 0 ] = val; return context; } else { // return the value return prop_item[ 0 ]; } } ); } // copy over public static methods util.copyTo( ctor, methods[ 'public' ], true ); util.copyTo( ctor.___$$svis$$, methods[ 'protected' ], true ); // private methods should not be inherited by subtypes if ( !inheriting ) { util.copyTo( ctor.___$$svis$$, methods[ 'private' ], true ); } } /** * Initializes class metadata for the given class * * DYNMETA is used only when CPARENT's metadata are flagged as "lazy", * meaning that the data are not available at the time of its definition, * but are available now as DYNMETA. * * @param {Function} func class to initialize metadata for * @param {Function} cparent class parent * @param {?Object} dynmeta dynamic metadata * * @return {undefined} * * Suppressed due to warnings for use of __cid * @suppress {checkTypes} */ function createMeta( func, cparent, dynmeta ) { var id = func.__cid, parent_meta = ( cparent[ _priv ] ? exports.getMeta( cparent ) : undefined ); // copy the parent prototype's metadata if it exists (inherit metadata) if ( parent_meta ) { return func[ _priv ].meta = util.clone( // "lazy" metadata are unavailable at the time of definition parent_meta._lazy ? dynmeta : parent_meta, true ); } // create empty return func[ _priv ].meta = { implemented: [], }; } /** * Attaches an instance identifier to a class instance * * @param {Object} instance class instance * @param {number} iid instance id * * @return {undefined} */ function attachInstanceId( instance, iid ) { util.defineSecureProp( instance, '__iid', iid ); } /** * Initializes class instance * * This process will create the instance visibility object that will contain * private and protected members. The class instance is part of the prototype * chain. This will be passed to all methods when invoked, permitting them to * access the private and protected members while keeping them encapsulated. * * For each instance, there is always a base. The base will contain a proxy to * the public members on the instance itself. The base will also contain all * protected members. * * Atop the base object is a private member object, with the base as its * prototype. There exists a private member object for the instance itself and * one for each supertype. This is stored by the class id (cid) as the key. This * permits the private member object associated with the class of the method * call to be bound to that method. For example, if a parent method is called, * that call must be invoked in the context of the parent, so the private * members of the parent must be made available. * * The resulting structure looks something like this: * class_instance = { iid: { cid: {} } } * * @param {Object} instance instance to initialize * * @return {undefined} */ function initInstance( instance ) { /** @constructor */ var prot = function() {}; prot.prototype = instance; // initialize our *own* private metadata store; do not use the // prototype's util.defineSecureProp( instance, _priv, {} ); // add the visibility objects to the data object for this class instance instance[ _priv ].vis = new prot(); } /** * Attaches partially applied isInstanceOf() method to class instance * * @param {Object} instance class instance to attach method to * * @return {undefined} */ function attachInstanceOf( instance ) { var method = function( type ) { return module.exports.isInstanceOf( type, instance ); }; // TODO: To improve performance (defineSecureProp can be costly), simply // define a normal prop and freeze the class afterward. The class shouldn't // have any mutable methods. util.defineSecureProp( instance, 'isInstanceOf', method ); util.defineSecureProp( instance, 'isA', method ); } /** * Returns the instance object associated with the given method * * The instance object contains the protected members. This object can be passed * as the context when calling a method in order to give that method access to * those members. * * One level above the instance object on the prototype chain is the object * containing the private members. This is swappable, depending on the class id * associated with the provided method call. This allows methods that were not * overridden by the subtype to continue to use the private members of the * supertype. * * @param {function()} inst instance that the method is being called from * @param {number} cid class id * * @return {Object|null} instance object if found, otherwise null * * @suppress {checkTypes} */ exports.getMethodInstance = function( inst, cid ) { if ( inst === undefined ) { return null; } var iid = inst.__iid, priv = inst[ _priv ], data; return ( iid && priv && ( data = priv.vis ) ) ? data[ cid ] : null ; } /** * Attaches isAbstract() method to the class * * @param {Function} func function (class) to attach method to * @param {Array} methods abstract method names * * @return {undefined} */ function attachAbstract( func, methods ) { var is_abstract = ( methods.__length > 0 ) ? true: false; /** * Returns whether the class contains abstract methods (and is therefore * abstract) * * @return {boolean} true if class is abstract, otherwise false */ util.defineSecureProp( func, 'isAbstract', function() { return is_abstract; }); } /** * Attaches the unique id to the class and its prototype * * The unique identifier is used internally to match a class and its instances * with the class metadata. Exposing the id breaks encapsulation to a degree, * but is a lesser evil when compared to exposing all metadata. * * @param {function()} ctor constructor (class) to attach method to * @param {number} id id to assign * * @return {undefined} */ function attachId( ctor, id ) { util.defineSecureProp( ctor, '__cid', id ); util.defineSecureProp( ctor.prototype, '__cid', id ); } /** * Sets class flags * * @param {Function} ctor class to flag * @param {Object} props class properties * * @return {undefined} */ function attachFlags( ctor, props ) { ctor.___$$final$$ = !!( props.___$$final$$ ); ctor.___$$abstract$$ = !!( props.___$$abstract$$ ); // The properties are no longer needed. Set to undefined rather than delete // (v8 performance) props.___$$final$$ = props.___$$abstract$$ = undefined; }