/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ "use strict"; let {Cu} = require("chrome"); let Services = require("Services"); let promise = require("sdk/core/promise"); let {Class} = require("sdk/core/heritage"); let {EventTarget} = require("sdk/event/target"); let events = require("sdk/event/core"); let object = require("sdk/util/object"); // Waiting for promise.done() to be added, see bug 851321 function promiseDone(err) { console.error(err); return promise.reject(err); } /** * Types: named marshallers/demarshallers. * * Types provide a 'write' function that takes a js representation and * returns a protocol representation, and a "read" function that * takes a protocol representation and returns a js representation. * * The read and write methods are also passed a context object that * represent the actor or front requesting the translation. * * Types are referred to with a typestring. Basic types are * registered by name using addType, and more complex types can * be generated by adding detail to the type name. */ let types = Object.create(null); exports.types = types; let registeredTypes = new Map(); let registeredLifetimes = new Map(); /** * Return the type object associated with a given typestring. * If passed a type object, it will be returned unchanged. * * Types can be registered with addType, or can be created on * the fly with typestrings. Examples: * * boolean * threadActor * threadActor#detail * array:threadActor * array:array:threadActor#detail * * @param [typestring|type] type * Either a typestring naming a type or a type object. * * @returns a type object. */ types.getType = function(type) { if (!type) { return types.Primitive; } if (typeof(type) !== "string") { return type; } // If already registered, we're done here. let reg = registeredTypes.get(type); if (reg) return reg; // New type, see if it's a collection/lifetime type: let sep = type.indexOf(":"); if (sep >= 0) { let collection = type.substring(0, sep); let subtype = types.getType(type.substring(sep + 1)); if (collection === "array") { return types.addArrayType(subtype); } else if (collection === "nullable") { return types.addNullableType(subtype); } if (registeredLifetimes.has(collection)) { return types.addLifetimeType(collection, subtype); } throw Error("Unknown collection type: " + collection); } // Not a collection, might be actor detail let pieces = type.split("#", 2); if (pieces.length > 1) { return types.addActorDetail(type, pieces[0], pieces[1]); } // Might be a lazily-loaded type if (type === "longstring") { require("devtools/server/actors/string"); return registeredTypes.get("longstring"); } throw Error("Unknown type: " + type); } /** * Don't allow undefined when writing primitive types to packets. If * you want to allow undefined, use a nullable type. */ function identityWrite(v) { if (v === undefined) { throw Error("undefined passed where a value is required"); } return v; } /** * Add a type to the type system. * * When registering a type, you can provide `read` and `write` methods. * * The `read` method will be passed a JS object value from the JSON * packet and must return a native representation. The `write` method will * be passed a native representation and should provide a JSONable value. * * These methods will both be passed a context. The context is the object * performing or servicing the request - on the server side it will be * an Actor, on the client side it will be a Front. * * @param typestring name * Name to register * @param object typeObject * An object whose properties will be stored in the type, including * the `read` and `write` methods. * @param object options * Can specify `thawed` to prevent the type from being frozen. * * @returns a type object that can be used in protocol definitions. */ types.addType = function(name, typeObject={}, options={}) { if (registeredTypes.has(name)) { throw Error("Type '" + name + "' already exists."); } let type = object.merge({ name: name, primitive: !(typeObject.read || typeObject.write), read: identityWrite, write: identityWrite }, typeObject); registeredTypes.set(name, type); if (!options.thawed) { Object.freeze(type); } return type; }; /** * Add an array type to the type system. * * getType() will call this function if provided an "array:" * typestring. * * @param type subtype * The subtype to be held by the array. */ types.addArrayType = function(subtype) { subtype = types.getType(subtype); let name = "array:" + subtype.name; // Arrays of primitive types are primitive types themselves. if (subtype.primitive) { return types.addType(name); } return types.addType(name, { read: (v, ctx) => [subtype.read(i, ctx) for (i of v)], write: (v, ctx) => [subtype.write(i, ctx) for (i of v)] }); }; /** * Add a dict type to the type system. This allows you to serialize * a JS object that contains non-primitive subtypes. * * Properties of the value that aren't included in the specializations * will be serialized as primitive values. * * @param object specializations * A dict of property names => type */ types.addDictType = function(name, specializations) { return types.addType(name, { read: (v, ctx) => { let ret = {}; for (let prop in v) { if (prop in specializations) { ret[prop] = types.getType(specializations[prop]).read(v[prop], ctx); } else { ret[prop] = v[prop]; } } return ret; }, write: (v, ctx) => { let ret = {}; for (let prop in v) { if (prop in specializations) { ret[prop] = types.getType(specializations[prop]).write(v[prop], ctx); } else { ret[prop] = v[prop]; } } return ret; } }) } /** * Register an actor type with the type system. * * Types are marshalled differently when communicating server->client * than they are when communicating client->server. The server needs * to provide useful information to the client, so uses the actor's * `form` method to get a json representation of the actor. When * making a request from the client we only need the actor ID string. * * This function can be called before the associated actor has been * constructed, but the read and write methods won't work until * the associated addActorImpl or addActorFront methods have been * called during actor/front construction. * * @param string name * The typestring to register. */ types.addActorType = function(name) { let type = types.addType(name, { _actor: true, read: (v, ctx, detail) => { // If we're reading a request on the server side, just // find the actor registered with this actorID. if (ctx instanceof Actor) { return ctx.conn.getActor(v); } // Reading a response on the client side, check for an // existing front on the connection, and create the front // if it isn't found. let actorID = typeof(v) === "string" ? v : v.actor; let front = ctx.conn.getActor(actorID); if (front) { front.form(v, detail, ctx); } else { front = new type.frontClass(ctx.conn, v, detail, ctx) front.actorID = actorID; ctx.marshallPool().manage(front); } return front; }, write: (v, ctx, detail) => { // If returning a response from the server side, make sure // the actor is added to a parent object and return its form. if (v instanceof Actor) { if (!v.actorID) { ctx.marshallPool().manage(v); } return v.form(detail); } // Writing a request from the client side, just send the actor id. return v.actorID; }, }, { // We usually freeze types, but actor types are updated when clients are // created, so don't freeze yet. thawed: true }); return type; } types.addNullableType = function(subtype) { subtype = types.getType(subtype); return types.addType("nullable:" + subtype.name, { read: (value, ctx) => { if (value == null) { return value; } return subtype.read(value, ctx); }, write: (value, ctx) => { if (value == null) { return value; } return subtype.write(value, ctx); } }); } /** * Register an actor detail type. This is just like an actor type, but * will pass a detail hint to the actor's form method during serialization/ * deserialization. * * This is called by getType() when passed an 'actorType#detail' string. * * @param string name * The typestring to register this type as. * @param type actorType * The actor type you'll be detailing. * @param string detail * The detail to pass. */ types.addActorDetail = function(name, actorType, detail) { actorType = types.getType(actorType); if (!actorType._actor) { throw Error("Details only apply to actor types, tried to add detail '" + detail + "'' to " + actorType.name + "\n"); } return types.addType(name, { _actor: true, read: (v, ctx) => actorType.read(v, ctx, detail), write: (v, ctx) => actorType.write(v, ctx, detail) }); } /** * Register an actor lifetime. This lets the type system find a parent * actor that differs from the actor fulfilling the request. * * @param string name * The lifetime name to use in typestrings. * @param string prop * The property of the actor that holds the parent that should be used. */ types.addLifetime = function(name, prop) { if (registeredLifetimes.has(name)) { throw Error("Lifetime '" + name + "' already registered."); } registeredLifetimes.set(name, prop); } /** * Register a lifetime type. This creates an actor type tied to the given * lifetime. * * This is called by getType() when passed a ':' * typestring. * * @param string lifetime * A lifetime string previously regisered with addLifetime() * @param type subtype * An actor type */ types.addLifetimeType = function(lifetime, subtype) { subtype = types.getType(subtype); if (!subtype._actor) { throw Error("Lifetimes only apply to actor types, tried to apply lifetime '" + lifetime + "'' to " + subtype.name); } let prop = registeredLifetimes.get(lifetime); return types.addType(lifetime + ":" + subtype.name, { read: (value, ctx) => subtype.read(value, ctx[prop]), write: (value, ctx) => subtype.write(value, ctx[prop]) }) } // Add a few named primitive types. types.Primitive = types.addType("primitive"); types.String = types.addType("string"); types.Number = types.addType("number"); types.Boolean = types.addType("boolean"); types.JSON = types.addType("json"); /** * Request/Response templates and generation * * Request packets are specified as json templates with * Arg and Option placeholders where arguments should be * placed. * * Reponse packets are also specified as json templates, * with a RetVal placeholder where the return value should be * placed. */ /** * Placeholder for simple arguments. * * @param number index * The argument index to place at this position. * @param type type * The argument should be marshalled as this type. * @constructor */ let Arg = Class({ initialize: function(index, type) { this.index = index; this.type = types.getType(type); }, write: function(arg, ctx) { return this.type.write(arg, ctx); }, read: function(v, ctx, outArgs) { outArgs[this.index] = this.type.read(v, ctx); } }); exports.Arg = Arg; /** * Placeholder for an options argument value that should be hoisted * into the packet. * * If provided in a method specification: * * { optionArg: Option(1)} * * Then arguments[1].optionArg will be placed in the packet in this * value's place. * * @param number index * The argument index of the options value. * @param type type * The argument should be marshalled as this type. * @constructor */ let Option = Class({ extends: Arg, initialize: function(index, type) { Arg.prototype.initialize.call(this, index, type) }, write: function(arg, ctx, name) { if (!arg) { return undefined; } let v = arg[name] || undefined; if (v === undefined) { return undefined; } return this.type.write(v, ctx); }, read: function(v, ctx, outArgs, name) { if (outArgs[this.index] === undefined) { outArgs[this.index] = {}; } if (v === undefined) { return; } outArgs[this.index][name] = this.type.read(v, ctx); } }); exports.Option = Option; /** * Placeholder for return values in a response template. * * @param type type * The return value should be marshalled as this type. */ let RetVal = Class({ initialize: function(type) { this.type = types.getType(type); }, write: function(v, ctx) { return this.type.write(v, ctx); }, read: function(v, ctx) { return this.type.read(v, ctx); } }); exports.RetVal = RetVal; /* Template handling functions */ /** * Get the value at a given path, or undefined if not found. */ function getPath(obj, path) { for (let name of path) { if (!(name in obj)) { return undefined; } obj = obj[name]; } return obj; } /** * Find Placeholders in the template and save them along with their * paths. */ function findPlaceholders(template, constructor, path=[], placeholders=[]) { if (!template || typeof(template) != "object") { return placeholders; } if (template instanceof constructor) { placeholders.push({ placeholder: template, path: [p for (p of path)] }); return placeholders; } for (let name in template) { path.push(name); findPlaceholders(template[name], constructor, path, placeholders); path.pop(); } return placeholders; } /** * Manages a request template. * * @param object template * The request template. * @construcor */ let Request = Class({ initialize: function(template={}) { this.type = template.type; this.template = template; this.args = findPlaceholders(template, Arg); }, /** * Write a request. * * @param array fnArgs * The function arguments to place in the request. * @param object ctx * The object making the request. * @returns a request packet. */ write: function(fnArgs, ctx) { let str = JSON.stringify(this.template, (key, value) => { if (value instanceof Arg) { return value.write(fnArgs[value.index], ctx, key); } return value; }); return JSON.parse(str); }, /** * Read a request. * * @param object packet * The request packet. * @param object ctx * The object making the request. * @returns an arguments array */ read: function(packet, ctx) { let fnArgs = []; for (let templateArg of this.args) { let arg = templateArg.placeholder; let path = templateArg.path; let name = path[path.length - 1]; arg.read(getPath(packet, path), ctx, fnArgs, name); } return fnArgs; }, }); /** * Manages a response template. * * @param object template * The response template. * @construcor */ let Response = Class({ initialize: function(template={}) { this.template = template; let placeholders = findPlaceholders(template, RetVal); if (placeholders.length > 1) { throw Error("More than one RetVal specified in response"); } let placeholder = placeholders.shift(); if (placeholder) { this.retVal = placeholder.placeholder; this.path = placeholder.path; } }, /** * Write a response for the given return value. * * @param val ret * The return value. * @param object ctx * The object writing the response. */ write: function(ret, ctx) { return JSON.parse(JSON.stringify(this.template, function(key, value) { if (value instanceof RetVal) { return value.write(ret, ctx); } return value; })); }, /** * Read a return value from the given response. * * @param object packet * The response packet. * @param object ctx * The object reading the response. */ read: function(packet, ctx) { if (!this.retVal) { return undefined; } let v = getPath(packet, this.path); return this.retVal.read(v, ctx); } }); /** * Actor and Front implementations */ /** * A protocol object that can manage the lifetime of other protocol * objects. */ let Pool = Class({ extends: EventTarget, /** * Pools are used on both sides of the connection to help coordinate * lifetimes. * * @param optional conn * Either a DebuggerServerConnection or a DebuggerClient. Must have * addActorPool, removeActorPool, and poolFor. * conn can be null if the subclass provides a conn property. * @constructor */ initialize: function(conn) { if (conn) { this.conn = conn; } }, /** * Return the parent pool for this client. */ parent: function() { return this.conn.poolFor(this.actorID) }, /** * Override this if you want actors returned by this actor * to belong to a different actor by default. */ marshallPool: function() { return this; }, /** * Pool is the base class for all actors, even leaf nodes. * If the child map is actually referenced, go ahead and create * the stuff needed by the pool. */ __poolMap: null, get _poolMap() { if (this.__poolMap) return this.__poolMap; this.__poolMap = new Map(); this.conn.addActorPool(this); return this.__poolMap; }, /** * Add an actor as a child of this pool. */ manage: function(actor) { if (!actor.actorID) { actor.actorID = this.conn.allocID(actor.actorPrefix || actor.typeName); } this._poolMap.set(actor.actorID, actor); return actor; }, /** * Remove an actor as a child of this pool. */ unmanage: function(actor) { this.__poolMap.delete(actor.actorID); }, // true if the given actor ID exists in the pool. has: function(actorID) this.__poolMap && this._poolMap.has(actorID), // The actor for a given actor id stored in this pool actor: function(actorID) this.__poolMap ? this._poolMap.get(actorID) : null, // Same as actor, should update debugger connection to use 'actor' // and then remove this. get: function(actorID) this.__poolMap ? this._poolMap.get(actorID) : null, // True if this pool has no children. isEmpty: function() !this.__poolMap || this._poolMap.size == 0, /** * Destroy this item, removing it from a parent if it has one, * and destroying all children if necessary. */ destroy: function() { let parent = this.parent(); if (parent) { parent.unmanage(this); } if (!this.__poolMap) { return; } for (let actor of this.__poolMap.values()) { // Self-owned actors are ok, but don't need destroying twice. if (actor === this) { continue; } let destroy = actor.destroy; if (destroy) { // Disconnect destroy while we're destroying in case of (misbehaving) // circular ownership. actor.destroy = null; destroy.call(actor); actor.destroy = destroy; } }; this.conn.removeActorPool(this, true); this.__poolMap.clear(); this.__poolMap = null; }, /** * For getting along with the debugger server pools, should be removable * eventually. */ cleanup: function() { this.destroy(); } }); exports.Pool = Pool; /** * An actor in the actor tree. */ let Actor = Class({ extends: Pool, // Will contain the actor's ID actorID: null, /** * Initialize an actor. * * @param optional conn * Either a DebuggerServerConnection or a DebuggerClient. Must have * addActorPool, removeActorPool, and poolFor. * conn can be null if the subclass provides a conn property. * @constructor */ initialize: function(conn) { Pool.prototype.initialize.call(this, conn); // Forward events to the connection. if (this._actorSpec && this._actorSpec.events) { for (let key of this._actorSpec.events.keys()) { let name = key; let sendEvent = this._sendEvent.bind(this, name) this.on(name, (...args) => { sendEvent.apply(null, args); }); } } }, _sendEvent: function(name, ...args) { if (!this._actorSpec.events.has(name)) { // It's ok to emit events that don't go over the wire. return; } let request = this._actorSpec.events.get(name); let packet = request.write(args, this); packet.from = packet.from || this.actorID; this.conn.send(packet); }, destroy: function() { Pool.prototype.destroy.call(this); this.actorID = null; }, /** * Override this method in subclasses to serialize the actor. * @param [optional] string hint * Optional string to customize the form. * @returns A jsonable object. */ form: function(hint) { return { actor: this.actorID } }, writeError: function(err) { console.error(err); if (err.stack) { dump(err.stack); } this.conn.send({ from: this.actorID, error: "unknownError", message: err.toString() }); }, _queueResponse: function(create) { let pending = this._pendingResponse || promise.resolve(null); let response = create(pending); this._pendingResponse = response; } }); exports.Actor = Actor; /** * Tags a prtotype method as an actor method implementation. * * @param function fn * The implementation function, will be returned. * @param spec * The method specification, with the following (optional) properties: * request (object): a request template. * response (object): a response template. * oneway (bool): 'true' if no response should be sent. * telemetry (string): Telemetry probe ID for measuring completion time. */ exports.method = function(fn, spec={}) { fn._methodSpec = Object.freeze(spec); if (spec.request) Object.freeze(spec.request); if (spec.response) Object.freeze(spec.response); return fn; } /** * Process an actor definition from its prototype and generate * request handlers. */ let actorProto = function(actorProto) { if (actorProto._actorSpec) { throw new Error("actorProto called twice on the same actor prototype!"); } let protoSpec = { methods: [], }; // Find method specifications attached to prototype properties. for (let name of Object.getOwnPropertyNames(actorProto)) { let desc = Object.getOwnPropertyDescriptor(actorProto, name); if (!desc.value) { continue; } if (desc.value._methodSpec) { let frozenSpec = desc.value._methodSpec; let spec = {}; spec.name = frozenSpec.name || name; spec.request = Request(object.merge({type: spec.name}, frozenSpec.request || undefined)); spec.response = Response(frozenSpec.response || undefined); spec.telemetry = frozenSpec.telemetry; spec.release = frozenSpec.release; spec.oneway = frozenSpec.oneway; protoSpec.methods.push(spec); } } // Find event specifications if (actorProto.events) { protoSpec.events = new Map(); for (let name in actorProto.events) { let eventRequest = actorProto.events[name]; Object.freeze(eventRequest); protoSpec.events.set(name, Request(object.merge({type: name}, eventRequest))); } } // Generate request handlers for each method definition actorProto.requestTypes = Object.create(null); protoSpec.methods.forEach(spec => { let handler = function(packet, conn) { try { let args = spec.request.read(packet, this); let ret = this[spec.name].apply(this, args); if (spec.oneway) { // No need to send a response. return; } let sendReturn = (ret) => { let response = spec.response.write(ret, this); response.from = this.actorID; // If spec.release has been specified, destroy the object. if (spec.release) { try { this.destroy(); } catch(e) { this.writeError(e); return; } } conn.send(response); }; this._queueResponse(p => { return p .then(() => ret) .then(sendReturn) .then(null, this.writeError.bind(this)); }) } catch(e) { this._queueResponse(p => { return p.then(() => this.writeError(e)); }); } }; actorProto.requestTypes[spec.request.type] = handler; }); actorProto._actorSpec = protoSpec; return actorProto; } /** * Create an actor class for the given actor prototype. * * @param object proto * The object prototype. Must have a 'typeName' property, * should have method definitions, can have event definitions. */ exports.ActorClass = function(proto) { if (!proto.typeName) { throw Error("Actor prototype must have a typeName member."); } proto.extends = Actor; if (!registeredTypes.has(proto.typeName)) { types.addActorType(proto.typeName); } return Class(actorProto(proto)); }; /** * Base class for client-side actor fronts. */ let Front = Class({ extends: Pool, actorID: null, /** * The base class for client-side actor fronts. * * @param optional conn * Either a DebuggerServerConnection or a DebuggerClient. Must have * addActorPool, removeActorPool, and poolFor. * conn can be null if the subclass provides a conn property. * @param optional form * The json form provided by the server. * @constructor */ initialize: function(conn=null, form=null, detail=null, context=null) { Pool.prototype.initialize.call(this, conn); this._requests = []; if (form) { this.actorID = form.actor; this.form(form, detail, context); } }, destroy: function() { // Reject all outstanding requests, they won't make sense after // the front is destroyed. while (this._requests && this._requests.length > 0) { let deferred = this._requests.shift(); deferred.reject(new Error("Connection closed")); } Pool.prototype.destroy.call(this); this.actorID = null; }, /** * @returns a promise that will resolve to the actorID this front * represents. */ actor: function() { return promise.resolve(this.actorID) }, toString: function() { return "[Front for " + this.typeName + "/" + this.actorID + "]" }, /** * Update the actor from its representation. * Subclasses should override this. */ form: function(form) {}, /** * Send a packet on the connection. */ send: function(packet) { if (packet.to) { this.conn._transport.send(packet); } else { this.actor().then(actorID => { packet.to = actorID; this.conn._transport.send(packet); }); } }, /** * Send a two-way request on the connection. */ request: function(packet) { let deferred = promise.defer(); this._requests.push(deferred); this.send(packet); return deferred.promise; }, /** * Handler for incoming packets from the client's actor. */ onPacket: function(packet) { // Pick off event packets if (this._clientSpec.events && this._clientSpec.events.has(packet.type)) { let event = this._clientSpec.events.get(packet.type); let args = event.request.read(packet, this); if (event.pre) { event.pre.forEach((pre) => pre.apply(this, args)); } events.emit.apply(null, [this, event.name].concat(args)); return; } // Remaining packets must be responses. if (this._requests.length === 0) { let msg = "Unexpected packet " + this.actorID + ", " + JSON.stringify(packet); let err = Error(msg); console.error(err); throw err; } let deferred = this._requests.shift(); if (packet.error) { deferred.reject(packet.error); } else { deferred.resolve(packet); } } }); exports.Front = Front; /** * A method tagged with preEvent will be called after recieving a packet * for that event, and before the front emits the event. */ exports.preEvent = function(eventName, fn) { fn._preEvent = eventName; return fn; } /** * Mark a method as a custom front implementation, replacing the generated * front method. * * @param function fn * The front implementation, will be returned. * @param object options * Options object: * impl (string): If provided, the generated front method will be * stored as this property on the prototype. */ exports.custom = function(fn, options={}) { fn._customFront = options; return fn; } function prototypeOf(obj) { return typeof(obj) === "function" ? obj.prototype : obj; } /** * Process a front definition from its prototype and generate * request methods. */ let frontProto = function(proto) { let actorType = prototypeOf(proto.actorType); if (proto._actorSpec) { throw new Error("frontProto called twice on the same front prototype!"); } proto._actorSpec = actorType._actorSpec; proto.typeName = actorType.typeName; // Generate request methods. let methods = proto._actorSpec.methods; methods.forEach(spec => { let name = spec.name; // If there's already a property by this name in the front, it must // be a custom front method. if (name in proto) { let custom = proto[spec.name]._customFront; if (custom === undefined) { throw Error("Existing method for " + spec.name + " not marked customFront while processing " + actorType.typeName + "."); } // If the user doesn't need the impl don't generate it. if (!custom.impl) { return; } name = custom.impl; } proto[name] = function(...args) { let histogram, startTime; if (spec.telemetry) { if (spec.oneway) { // That just doesn't make sense. throw Error("Telemetry specified for a oneway request"); } let transportType = this.conn.localTransport ? "LOCAL_" : "REMOTE_"; let histogramId = "DEVTOOLS_DEBUGGER_RDP_" + transportType + spec.telemetry + "_MS"; try { histogram = Services.telemetry.getHistogramById(histogramId); startTime = new Date(); } catch(ex) { // XXX: Is this expected in xpcshell tests? console.error(ex); spec.telemetry = false; } } let packet = spec.request.write(args, this); if (spec.oneway) { // Fire-and-forget oneway packets. this.send(packet); return undefined; } return this.request(packet).then(response => { let ret = spec.response.read(response, this); if (histogram) { histogram.add(+new Date - startTime); } return ret; }).then(null, promiseDone); } // Release methods should call the destroy function on return. if (spec.release) { let fn = proto[name]; proto[name] = function(...args) { return fn.apply(this, args).then(result => { this.destroy(); return result; }) } } }); // Process event specifications proto._clientSpec = {}; let events = proto._actorSpec.events; if (events) { // This actor has events, scan the prototype for preEvent handlers... let preHandlers = new Map(); for (let name of Object.getOwnPropertyNames(proto)) { let desc = Object.getOwnPropertyDescriptor(proto, name); if (!desc.value) { continue; } if (desc.value._preEvent) { let preEvent = desc.value._preEvent; if (!events.has(preEvent)) { throw Error("preEvent for event that doesn't exist: " + preEvent); } let handlers = preHandlers.get(preEvent); if (!handlers) { handlers = []; preHandlers.set(preEvent, handlers); } handlers.push(desc.value); } } proto._clientSpec.events = new Map(); for (let [name, request] of events) { proto._clientSpec.events.set(request.type, { name: name, request: request, pre: preHandlers.get(name) }); } } return proto; } /** * Create a front class for the given actor class, with the given prototype. * * @param ActorClass actorType * The actor class you're creating a front for. * @param object proto * The object prototype. Must have a 'typeName' property, * should have method definitions, can have event definitions. */ exports.FrontClass = function(actorType, proto) { proto.actorType = actorType; proto.extends = Front; let cls = Class(frontProto(proto)); registeredTypes.get(cls.prototype.typeName).frontClass = cls; return cls; }