/* 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"; const {classes: Cc, interfaces: Ci, utils: Cu, results: Cr} = Components; Cu.import("resource://gre/modules/Services.jsm"); Cu.import("resource://gre/modules/XPCOMUtils.jsm"); const PC_CONTRACT = "@mozilla.org/dom/peerconnection;1"; const WEBRTC_GLOBAL_CONTRACT = "@mozilla.org/dom/webrtcglobalinformation1"; const PC_OBS_CONTRACT = "@mozilla.org/dom/peerconnectionobserver;1"; const PC_ICE_CONTRACT = "@mozilla.org/dom/rtcicecandidate;1"; const PC_SESSION_CONTRACT = "@mozilla.org/dom/rtcsessiondescription;1"; const PC_MANAGER_CONTRACT = "@mozilla.org/dom/peerconnectionmanager;1"; const PC_STATS_CONTRACT = "@mozilla.org/dom/rtcstatsreport;1"; const PC_CID = Components.ID("{00e0e20d-1494-4776-8e0e-0f0acbea3c79}"); const WEBRTC_GLOBAL_CID = Components.ID("{f6063d11-f467-49ad-9765-e7923050dc08}"); const PC_OBS_CID = Components.ID("{d1748d4c-7f6a-4dc5-add6-d55b7678537e}"); const PC_ICE_CID = Components.ID("{02b9970c-433d-4cc2-923d-f7028ac66073}"); const PC_SESSION_CID = Components.ID("{1775081b-b62d-4954-8ffe-a067bbf508a7}"); const PC_MANAGER_CID = Components.ID("{7293e901-2be3-4c02-b4bd-cbef6fc24f78}"); const PC_STATS_CID = Components.ID("{7fe6e18b-0da3-4056-bf3b-440ef3809e06}"); // Global list of PeerConnection objects, so they can be cleaned up when // a page is torn down. (Maps inner window ID to an array of PC objects). function GlobalPCList() { this._list = {}; this._networkdown = false; // XXX Need to query current state somehow Services.obs.addObserver(this, "inner-window-destroyed", true); Services.obs.addObserver(this, "profile-change-net-teardown", true); Services.obs.addObserver(this, "network:offline-about-to-go-offline", true); Services.obs.addObserver(this, "network:offline-status-changed", true); } GlobalPCList.prototype = { QueryInterface: XPCOMUtils.generateQI([Ci.nsIObserver, Ci.nsISupportsWeakReference, Ci.IPeerConnectionManager]), classID: PC_MANAGER_CID, _xpcom_factory: { createInstance: function(outer, iid) { if (outer) { throw Cr.NS_ERROR_NO_AGGREGATION; } return _globalPCList.QueryInterface(iid); } }, addPC: function(pc) { let winID = pc._winID; if (this._list[winID]) { this._list[winID].push(Cu.getWeakReference(pc)); } else { this._list[winID] = [Cu.getWeakReference(pc)]; } this.removeNullRefs(winID); }, removeNullRefs: function(winID) { if (this._list[winID] === undefined) { return; } this._list[winID] = this._list[winID].filter( function (e,i,a) { return e.get() !== null; }); if (this._list[winID].length === 0) { delete this._list[winID]; } }, hasActivePeerConnection: function(winID) { this.removeNullRefs(winID); return this._list[winID] ? true : false; }, observe: function(subject, topic, data) { let cleanupPcRef = function(pcref) { let pc = pcref.get(); if (pc) { pc._pc.close(); delete pc._observer; pc._pc = null; } }; let cleanupWinId = function(list, winID) { if (list.hasOwnProperty(winID)) { list[winID].forEach(cleanupPcRef); delete list[winID]; } }; if (topic == "inner-window-destroyed") { cleanupWinId(this._list, subject.QueryInterface(Ci.nsISupportsPRUint64).data); } else if (topic == "profile-change-net-teardown" || topic == "network:offline-about-to-go-offline") { // Delete all peerconnections on shutdown - mostly synchronously (we // need them to be done deleting transports and streams before we // return)! All socket operations must be queued to STS thread // before we return to here. // Also kill them if "Work Offline" is selected - more can be created // while offline, but attempts to connect them should fail. for (let winId in this._list) { cleanupWinId(this._list, winId); } this._networkdown = true; } else if (topic == "network:offline-status-changed") { if (data == "offline") { // this._list shold be empty here this._networkdown = true; } else if (data == "online") { this._networkdown = false; } } }, getStatsForEachPC: function(callback, errorCallback) { for (let winId in this._list) { if (this._list.hasOwnProperty(winId)) { this.removeNullRefs(winId); if (this._list[winId]) { this._list[winId].forEach(function(pcref) { pcref.get().getStatsInternal(null, callback, errorCallback); }); } } } }, getLoggingFromFirstPC: function(pattern, callback, errorCallback) { for (let winId in this._list) { this.removeNullRefs(winId); if (this._list[winId]) { // We expect removeNullRefs to not leave us with an empty array here let pcref = this._list[winId][0]; pcref.get().getLogging(pattern, callback, errorCallback); return; } } }, }; let _globalPCList = new GlobalPCList(); function WebrtcGlobalInformation() { } WebrtcGlobalInformation.prototype = { classDescription: "WebrtcGlobalInformation", classID: WEBRTC_GLOBAL_CID, contractID: WEBRTC_GLOBAL_CONTRACT, QueryInterface: XPCOMUtils.generateQI([Ci.nsISupports]), getAllStats: function(successCallback, failureCallback) { if (_globalPCList) { _globalPCList.getStatsForEachPC(successCallback, failureCallback); } else { failureCallback("No global PeerConnection list"); } }, getCandPairLogs: function(candPairId, callback, errorCallback) { let pattern = 'CAND-PAIR(' + candPairId + ')'; if (_globalPCList) { _globalPCList.getLoggingFromFirstPC(pattern, callback, errorCallback); } else { errorCallback("No global PeerConnection list"); } }, }; function RTCIceCandidate() { this.candidate = this.sdpMid = this.sdpMLineIndex = null; } RTCIceCandidate.prototype = { classDescription: "mozRTCIceCandidate", classID: PC_ICE_CID, contractID: PC_ICE_CONTRACT, QueryInterface: XPCOMUtils.generateQI([Ci.nsISupports, Ci.nsIDOMGlobalPropertyInitializer]), init: function(win) { this._win = win; }, __init: function(dict) { this.candidate = dict.candidate; this.sdpMid = dict.sdpMid; this.sdpMLineIndex = ("sdpMLineIndex" in dict)? dict.sdpMLineIndex : null; } }; function RTCSessionDescription() { this.type = this.sdp = null; } RTCSessionDescription.prototype = { classDescription: "mozRTCSessionDescription", classID: PC_SESSION_CID, contractID: PC_SESSION_CONTRACT, QueryInterface: XPCOMUtils.generateQI([Ci.nsISupports, Ci.nsIDOMGlobalPropertyInitializer]), init: function(win) { this._win = win; }, __init: function(dict) { this.type = dict.type; this.sdp = dict.sdp; } }; function RTCStatsReport(win, report, pcid) { this._win = win; this.report = report; this.mozPcid = pcid; } RTCStatsReport.prototype = { classDescription: "RTCStatsReport", classID: PC_STATS_CID, contractID: PC_STATS_CONTRACT, QueryInterface: XPCOMUtils.generateQI([Ci.nsISupports, Ci.nsIDOMGlobalPropertyInitializer]), forEach: function(cb, thisArg) { for (var key in this.report) { if (this.report.hasOwnProperty(key)) { cb.call(thisArg || this, this.get(key), key, this.report); } } }, get: function(key) { function publify(win, obj) { let props = {}; for (let k in obj) { props[k] = {enumerable:true, configurable:true, writable:true, value:obj[k]}; } let pubobj = Cu.createObjectIn(win); Object.defineProperties(pubobj, props); Cu.makeObjectPropsNormal(pubobj); return pubobj; } // Return a content object rather than a wrapped chrome one. return publify(this._win, this.report[key]); }, has: function(key) { return this.report[key] !== undefined; } }; function RTCPeerConnection() { this._queue = []; this._pc = null; this._observer = null; this._closed = false; this._onCreateOfferSuccess = null; this._onCreateOfferFailure = null; this._onCreateAnswerSuccess = null; this._onCreateAnswerFailure = null; this._onGetStatsSuccess = null; this._onGetStatsFailure = null; this._onGetLoggingSuccess = null; this._onGetLoggingFailure = null; this._pendingType = null; this._localType = null; this._remoteType = null; this._trickleIce = false; /** * Everytime we get a request from content, we put it in the queue. If * there are no pending operations though, we will execute it immediately. * In PeerConnectionObserver, whenever we are notified that an operation * has finished, we will check the queue for the next operation and execute * if neccesary. The _pending flag indicates whether an operation is currently * in progress. */ this._pending = false; // States this._iceGatheringState = this._iceConnectionState = "new"; } RTCPeerConnection.prototype = { classDescription: "mozRTCPeerConnection", classID: PC_CID, contractID: PC_CONTRACT, QueryInterface: XPCOMUtils.generateQI([Ci.nsISupports, Ci.nsIDOMGlobalPropertyInitializer]), init: function(win) { this._win = win; }, __init: function(rtcConfig) { this._trickleIce = Services.prefs.getBoolPref("media.peerconnection.trickle_ice"); if (!rtcConfig.iceServers || !Services.prefs.getBoolPref("media.peerconnection.use_document_iceservers")) { rtcConfig = {iceServers: JSON.parse(Services.prefs.getCharPref("media.peerconnection.default_iceservers"))}; } this._mustValidateRTCConfiguration(rtcConfig, "RTCPeerConnection constructor passed invalid RTCConfiguration"); if (_globalPCList._networkdown) { throw new this._win.DOMError("", "Can't create RTCPeerConnections when the network is down"); } this.makeGetterSetterEH("onaddstream"); this.makeGetterSetterEH("onicecandidate"); this.makeGetterSetterEH("onnegotiationneeded"); this.makeGetterSetterEH("onsignalingstatechange"); this.makeGetterSetterEH("onremovestream"); this.makeGetterSetterEH("ondatachannel"); this.makeGetterSetterEH("onconnection"); this.makeGetterSetterEH("onclosedconnection"); this.makeGetterSetterEH("oniceconnectionstatechange"); this._pc = new this._win.PeerConnectionImpl(); this.__DOM_IMPL__._innerObject = this; this._observer = new this._win.PeerConnectionObserver(this.__DOM_IMPL__); this._winID = this._win.QueryInterface(Ci.nsIInterfaceRequestor) .getInterface(Ci.nsIDOMWindowUtils).currentInnerWindowID; // Add a reference to the PeerConnection to global list (before init). _globalPCList.addPC(this); this._queueOrRun({ func: this._initialize, args: [rtcConfig], // If not trickling, suppress start. wait: !this._trickleIce }); }, _initialize: function(rtcConfig) { this._getPC().initialize(this._observer, this._win, rtcConfig, Services.tm.currentThread); }, _getPC: function() { if (!this._pc) { throw new this._win.DOMError("", "RTCPeerConnection is gone (did you enter Offline mode?)"); } return this._pc; }, /** * Add a function to the queue or run it immediately if the queue is empty. * Argument is an object with the func, args and wait properties; wait should * be set to true if the function has a success/error callback that will * call _executeNext, false if it doesn't have a callback. */ _queueOrRun: function(obj) { this._checkClosed(); if (!this._pending) { if (obj.type !== undefined) { this._pendingType = obj.type; } obj.func.apply(this, obj.args); if (obj.wait) { this._pending = true; } } else { this._queue.push(obj); } }, // Pick the next item from the queue and run it. _executeNext: function() { if (this._queue.length) { let obj = this._queue.shift(); if (obj.type !== undefined) { this._pendingType = obj.type; } obj.func.apply(this, obj.args); if (!obj.wait) { this._executeNext(); } } else { this._pending = false; } }, /** * An RTCConfiguration looks like this: * * { "iceServers": [ { url:"stun:stun.example.org" }, * { url:"turn:turn.example.org", * username:"jib", credential:"mypass"} ] } * * WebIDL normalizes structure for us, so we test well-formed stun/turn urls, * but not validity of servers themselves, before passing along to C++. * ErrorMsg is passed in to detail which array-entry failed, if any. */ _mustValidateRTCConfiguration: function(rtcConfig, errorMsg) { var errorCtor = this._win.DOMError; function nicerNewURI(uriStr, errorMsg) { let ios = Cc['@mozilla.org/network/io-service;1'].getService(Ci.nsIIOService); try { return ios.newURI(uriStr, null, null); } catch (e if (e.result == Cr.NS_ERROR_MALFORMED_URI)) { throw new errorCtor("", errorMsg + " - malformed URI: " + uriStr); } } function mustValidateServer(server) { if (!server.url) { throw new errorCtor("", errorMsg + " - missing url"); } let url = nicerNewURI(server.url, errorMsg); if (url.scheme in { turn:1, turns:1 }) { if (!server.username) { throw new errorCtor("", errorMsg + " - missing username: " + server.url); } if (!server.credential) { throw new errorCtor("", errorMsg + " - missing credential: " + server.url); } } else if (!(url.scheme in { stun:1, stuns:1 })) { throw new errorCtor("", errorMsg + " - improper scheme: " + url.scheme); } } if (rtcConfig.iceServers) { let len = rtcConfig.iceServers.length; for (let i=0; i < len; i++) { mustValidateServer (rtcConfig.iceServers[i], errorMsg); } } }, /** * MediaConstraints look like this: * * { * mandatory: {"OfferToReceiveAudio": true, "OfferToReceiveVideo": true }, * optional: [{"VoiceActivityDetection": true}, {"FooBar": 10}] * } * * WebIDL normalizes the top structure for us, but the mandatory constraints * member comes in as a raw object so we can detect unknown constraints. * We compare its members against ones we support, and fail if not found. */ _mustValidateConstraints: function(constraints, errorMsg) { if (constraints.mandatory) { let supported; try { // Passing the raw constraints.mandatory here validates its structure supported = this._observer.getSupportedConstraints(constraints.mandatory); } catch (e) { throw new this._win.DOMError("", errorMsg + " - " + e.message); } for (let constraint of Object.keys(constraints.mandatory)) { if (!(constraint in supported)) { throw new this._win.DOMError("", errorMsg + " - unknown mandatory constraint: " + constraint); } } } if (constraints.optional) { let len = constraints.optional.length; for (let i = 0; i < len; i++) { let constraints_per_entry = 0; for (let constraint in Object.keys(constraints.optional[i])) { if (constraints_per_entry) { throw new this._win.DOMError("", errorMsg + " - optional constraint must be single key/value pair"); } constraints_per_entry += 1; } } } }, // Ideally, this should be of the form _checkState(state), // where the state is taken from an enumeration containing // the valid peer connection states defined in the WebRTC // spec. See Bug 831756. _checkClosed: function() { if (this._closed) { throw new this._win.DOMError("", "Peer connection is closed"); } }, dispatchEvent: function(event) { this.__DOM_IMPL__.dispatchEvent(event); }, // Log error message to web console and window.onerror, if present. reportError: function(msg, file, line) { this.reportMsg(msg, file, line, Ci.nsIScriptError.exceptionFlag); }, reportWarning: function(msg, file, line) { this.reportMsg(msg, file, line, Ci.nsIScriptError.warningFlag); }, reportMsg: function(msg, file, line, flag) { let scriptErrorClass = Cc["@mozilla.org/scripterror;1"]; let scriptError = scriptErrorClass.createInstance(Ci.nsIScriptError); scriptError.initWithWindowID(msg, file, null, line, 0, flag, "content javascript", this._winID); let console = Cc["@mozilla.org/consoleservice;1"]. getService(Ci.nsIConsoleService); console.logMessage(scriptError); if (flag != Ci.nsIScriptError.warningFlag) { // Safely call onerror directly if present (necessary for testing) try { if (typeof this._win.onerror === "function") { this._win.onerror(msg, file, line); } } catch(e) { // If onerror itself throws, service it. try { let scriptError = scriptErrorClass.createInstance(Ci.nsIScriptError); scriptError.initWithWindowID(e.message, e.fileName, null, e.lineNumber, 0, Ci.nsIScriptError.exceptionFlag, "content javascript", this._winID); console.logMessage(scriptError); } catch(e) {} } } }, getEH: function(type) { return this.__DOM_IMPL__.getEventHandler(type); }, setEH: function(type, handler) { this.__DOM_IMPL__.setEventHandler(type, handler); }, makeGetterSetterEH: function(name) { Object.defineProperty(this, name, { get:function() { return this.getEH(name); }, set:function(h) { return this.setEH(name, h); } }); }, createOffer: function(onSuccess, onError, constraints) { if (!constraints) { constraints = {}; } this._mustValidateConstraints(constraints, "createOffer passed invalid constraints"); this._queueOrRun({ func: this._createOffer, args: [onSuccess, onError, constraints], wait: true }); }, _createOffer: function(onSuccess, onError, constraints) { this._onCreateOfferSuccess = onSuccess; this._onCreateOfferFailure = onError; this._getPC().createOffer(constraints); }, _createAnswer: function(onSuccess, onError, constraints, provisional) { this._onCreateAnswerSuccess = onSuccess; this._onCreateAnswerFailure = onError; if (!this.remoteDescription) { this._observer.onCreateAnswerError(Ci.IPeerConnection.kInvalidState, "setRemoteDescription not called"); return; } if (this.remoteDescription.type != "offer") { this._observer.onCreateAnswerError(Ci.IPeerConnection.kInvalidState, "No outstanding offer"); return; } // TODO: Implement provisional answer. this._getPC().createAnswer(constraints); }, createAnswer: function(onSuccess, onError, constraints, provisional) { if (!constraints) { constraints = {}; } this._mustValidateConstraints(constraints, "createAnswer passed invalid constraints"); if (!provisional) { provisional = false; } this._queueOrRun({ func: this._createAnswer, args: [onSuccess, onError, constraints, provisional], wait: true }); }, setLocalDescription: function(desc, onSuccess, onError) { let type; switch (desc.type) { case "offer": type = Ci.IPeerConnection.kActionOffer; break; case "answer": type = Ci.IPeerConnection.kActionAnswer; break; case "pranswer": throw new this._win.DOMError("", "pranswer not yet implemented"); default: throw new this._win.DOMError("", "Invalid type " + desc.type + " provided to setLocalDescription"); } this._queueOrRun({ func: this._setLocalDescription, args: [type, desc.sdp, onSuccess, onError], wait: true, type: desc.type }); }, _setLocalDescription: function(type, sdp, onSuccess, onError) { this._onSetLocalDescriptionSuccess = onSuccess; this._onSetLocalDescriptionFailure = onError; this._getPC().setLocalDescription(type, sdp); }, setRemoteDescription: function(desc, onSuccess, onError) { let type; switch (desc.type) { case "offer": type = Ci.IPeerConnection.kActionOffer; break; case "answer": type = Ci.IPeerConnection.kActionAnswer; break; case "pranswer": throw new this._win.DOMError("", "pranswer not yet implemented"); default: throw new this._win.DOMError("", "Invalid type " + desc.type + " provided to setRemoteDescription"); } this._queueOrRun({ func: this._setRemoteDescription, args: [type, desc.sdp, onSuccess, onError], wait: true, type: desc.type }); }, _setRemoteDescription: function(type, sdp, onSuccess, onError) { this._onSetRemoteDescriptionSuccess = onSuccess; this._onSetRemoteDescriptionFailure = onError; this._getPC().setRemoteDescription(type, sdp); }, updateIce: function(config, constraints) { throw new this._win.DOMError("", "updateIce not yet implemented"); }, addIceCandidate: function(cand, onSuccess, onError) { if (!cand.candidate && !cand.sdpMLineIndex) { throw new this._win.DOMError("", "Invalid candidate passed to addIceCandidate!"); } this._onAddIceCandidateSuccess = onSuccess || null; this._onAddIceCandidateError = onError || null; this._queueOrRun({ func: this._addIceCandidate, args: [cand], wait: true }); }, _addIceCandidate: function(cand) { this._getPC().addIceCandidate(cand.candidate, cand.sdpMid || "", (cand.sdpMLineIndex === null)? 0 : cand.sdpMLineIndex + 1); }, addStream: function(stream, constraints) { if (!constraints) { constraints = {}; } this._mustValidateConstraints(constraints, "addStream passed invalid constraints"); if (stream.currentTime === undefined) { throw new this._win.DOMError("", "Invalid stream passed to addStream!"); } this._queueOrRun({ func: this._addStream, args: [stream, constraints], wait: false }); }, _addStream: function(stream, constraints) { this._getPC().addStream(stream, constraints); }, removeStream: function(stream) { //Bug 844295: Not implementing this functionality. throw new this._win.DOMError("", "removeStream not yet implemented"); }, getStreamById: function(id) { throw new this._win.DOMError("", "getStreamById not yet implemented"); }, close: function() { this._queueOrRun({ func: this._close, args: [false], wait: false }); this._closed = true; this.changeIceConnectionState("closed"); }, _close: function() { this._getPC().close(); }, getLocalStreams: function() { this._checkClosed(); return this._getPC().getLocalStreams(); }, getRemoteStreams: function() { this._checkClosed(); return this._getPC().getRemoteStreams(); }, get localDescription() { this._checkClosed(); let sdp = this._getPC().localDescription; if (sdp.length == 0) { return null; } return new this._win.mozRTCSessionDescription({ type: this._localType, sdp: sdp }); }, get remoteDescription() { this._checkClosed(); let sdp = this._getPC().remoteDescription; if (sdp.length == 0) { return null; } return new this._win.mozRTCSessionDescription({ type: this._remoteType, sdp: sdp }); }, get iceGatheringState() { return this._iceGatheringState; }, get iceConnectionState() { return this._iceConnectionState; }, get signalingState() { // checking for our local pc closed indication // before invoking the pc methods. if(this._closed) { return "closed"; } return { "SignalingInvalid": "", "SignalingStable": "stable", "SignalingHaveLocalOffer": "have-local-offer", "SignalingHaveRemoteOffer": "have-remote-offer", "SignalingHaveLocalPranswer": "have-local-pranswer", "SignalingHaveRemotePranswer": "have-remote-pranswer", "SignalingClosed": "closed" }[this._getPC().signalingState]; }, changeIceGatheringState: function(state) { this._iceGatheringState = state; }, changeIceConnectionState: function(state) { this._iceConnectionState = state; this.dispatchEvent(new this._win.Event("iceconnectionstatechange")); }, getStats: function(selector, onSuccess, onError) { this._queueOrRun({ func: this._getStats, args: [selector, onSuccess, onError, false], wait: true }); }, getStatsInternal: function(selector, onSuccess, onError) { this._queueOrRun({ func: this._getStats, args: [selector, onSuccess, onError, true], wait: true }); }, _getStats: function(selector, onSuccess, onError, internal) { this._onGetStatsSuccess = onSuccess; this._onGetStatsFailure = onError; this._getPC().getStats(selector, internal); }, getLogging: function(pattern, onSuccess, onError) { this._queueOrRun({ func: this._getLogging, args: [pattern, onSuccess, onError], wait: true }); }, _getLogging: function(pattern, onSuccess, onError) { this._onGetLoggingSuccess = onSuccess; this._onGetLoggingFailure = onError; this._getPC().getLogging(pattern); }, createDataChannel: function(label, dict) { this._checkClosed(); if (dict == undefined) { dict = {}; } if (dict.maxRetransmitNum != undefined) { dict.maxRetransmits = dict.maxRetransmitNum; this.reportWarning("Deprecated RTCDataChannelInit dictionary entry maxRetransmitNum used!", null, 0); } if (dict.outOfOrderAllowed != undefined) { dict.ordered = !dict.outOfOrderAllowed; // the meaning is swapped with the name change this.reportWarning("Deprecated RTCDataChannelInit dictionary entry outOfOrderAllowed used!", null, 0); } if (dict.preset != undefined) { dict.negotiated = dict.preset; this.reportWarning("Deprecated RTCDataChannelInit dictionary entry preset used!", null, 0); } if (dict.stream != undefined) { dict.id = dict.stream; this.reportWarning("Deprecated RTCDataChannelInit dictionary entry stream used!", null, 0); } if (dict.maxRetransmitTime != undefined && dict.maxRetransmits != undefined) { throw new this._win.DOMError("", "Both maxRetransmitTime and maxRetransmits cannot be provided"); } let protocol; if (dict.protocol == undefined) { protocol = ""; } else { protocol = dict.protocol; } // Must determine the type where we still know if entries are undefined. let type; if (dict.maxRetransmitTime != undefined) { type = Ci.IPeerConnection.kDataChannelPartialReliableTimed; } else if (dict.maxRetransmits != undefined) { type = Ci.IPeerConnection.kDataChannelPartialReliableRexmit; } else { type = Ci.IPeerConnection.kDataChannelReliable; } // Synchronous since it doesn't block. let channel = this._getPC().createDataChannel( label, protocol, type, !dict.ordered, dict.maxRetransmitTime, dict.maxRetransmits, dict.negotiated ? true : false, dict.id != undefined ? dict.id : 0xFFFF ); return channel; }, connectDataConnection: function(localport, remoteport, numstreams) { if (numstreams == undefined || numstreams <= 0) { numstreams = 16; } this._queueOrRun({ func: this._connectDataConnection, args: [localport, remoteport, numstreams], wait: false }); }, _connectDataConnection: function(localport, remoteport, numstreams) { this._getPC().connectDataConnection(localport, remoteport, numstreams); } }; function RTCError(code, message) { this.name = this.reasonName[Math.min(code, this.reasonName.length - 1)]; this.message = (typeof message === "string")? message : this.name; this.__exposedProps__ = { name: "rw", message: "rw" }; } RTCError.prototype = { // These strings must match those defined in the WebRTC spec. reasonName: [ "NO_ERROR", // Should never happen -- only used for testing "INVALID_CONSTRAINTS_TYPE", "INVALID_CANDIDATE_TYPE", "INVALID_MEDIASTREAM_TRACK", "INVALID_STATE", "INVALID_SESSION_DESCRIPTION", "INCOMPATIBLE_SESSION_DESCRIPTION", "INCOMPATIBLE_CONSTRAINTS", "INCOMPATIBLE_MEDIASTREAMTRACK", "INTERNAL_ERROR" ] }; // This is a separate object because we don't want to expose it to DOM. function PeerConnectionObserver() { this._dompc = null; } PeerConnectionObserver.prototype = { classDescription: "PeerConnectionObserver", classID: PC_OBS_CID, contractID: PC_OBS_CONTRACT, QueryInterface: XPCOMUtils.generateQI([Ci.nsISupports, Ci.nsIDOMGlobalPropertyInitializer]), init: function(win) { this._win = win; }, __init: function(dompc) { this._dompc = dompc._innerObject; }, dispatchEvent: function(event) { this._dompc.dispatchEvent(event); }, callCB: function(callback, arg) { if (callback) { try { callback(arg); } catch(e) { // A content script (user-provided) callback threw an error. We don't // want this to take down peerconnection, but we still want the user // to see it, so we catch it, report it, and move on. this._dompc.reportError(e.message, e.fileName, e.lineNumber); } } }, onCreateOfferSuccess: function(sdp) { this.callCB(this._dompc._onCreateOfferSuccess, new this._dompc._win.mozRTCSessionDescription({ type: "offer", sdp: sdp })); this._dompc._executeNext(); }, onCreateOfferError: function(code, message) { this.callCB(this._dompc._onCreateOfferFailure, new RTCError(code, message)); this._dompc._executeNext(); }, onCreateAnswerSuccess: function(sdp) { this.callCB (this._dompc._onCreateAnswerSuccess, new this._dompc._win.mozRTCSessionDescription({ type: "answer", sdp: sdp })); this._dompc._executeNext(); }, onCreateAnswerError: function(code, message) { this.callCB(this._dompc._onCreateAnswerFailure, new RTCError(code, message)); this._dompc._executeNext(); }, onSetLocalDescriptionSuccess: function() { this._dompc._localType = this._dompc._pendingType; this._dompc._pendingType = null; this.callCB(this._dompc._onSetLocalDescriptionSuccess); if (this._dompc._iceGatheringState == "complete") { // If we are not trickling or we completed gathering prior // to setLocal, then trigger a call of onicecandidate here. this.foundIceCandidate(null); } this._dompc._executeNext(); }, onSetRemoteDescriptionSuccess: function() { this._dompc._remoteType = this._dompc._pendingType; this._dompc._pendingType = null; this.callCB(this._dompc._onSetRemoteDescriptionSuccess); this._dompc._executeNext(); }, onSetLocalDescriptionError: function(code, message) { this._dompc._pendingType = null; this.callCB(this._dompc._onSetLocalDescriptionFailure, new RTCError(code, message)); this._dompc._executeNext(); }, onSetRemoteDescriptionError: function(code, message) { this._dompc._pendingType = null; this.callCB(this._dompc._onSetRemoteDescriptionFailure, new RTCError(code, message)); this._dompc._executeNext(); }, onAddIceCandidateSuccess: function() { this._dompc._pendingType = null; this.callCB(this._dompc._onAddIceCandidateSuccess); this._dompc._executeNext(); }, onAddIceCandidateError: function(code, message) { this._dompc._pendingType = null; this.callCB(this._dompc._onAddIceCandidateError, new RTCError(code, message)); this._dompc._executeNext(); }, onIceCandidate: function(level, mid, candidate) { this.foundIceCandidate(new this._dompc._win.mozRTCIceCandidate( { candidate: candidate, sdpMid: mid, sdpMLineIndex: level - 1 } )); }, // This method is primarily responsible for updating iceConnectionState. // This state is defined in the WebRTC specification as follows: // // iceConnectionState: // ------------------- // new The ICE Agent is gathering addresses and/or waiting for // remote candidates to be supplied. // // checking The ICE Agent has received remote candidates on at least // one component, and is checking candidate pairs but has not // yet found a connection. In addition to checking, it may // also still be gathering. // // connected The ICE Agent has found a usable connection for all // components but is still checking other candidate pairs to // see if there is a better connection. It may also still be // gathering. // // completed The ICE Agent has finished gathering and checking and found // a connection for all components. Open issue: it is not // clear how the non controlling ICE side knows it is in the // state. // // failed The ICE Agent is finished checking all candidate pairs and // failed to find a connection for at least one component. // Connections may have been found for some components. // // disconnected Liveness checks have failed for one or more components. // This is more aggressive than failed, and may trigger // intermittently (and resolve itself without action) on a // flaky network. // // closed The ICE Agent has shut down and is no longer responding to // STUN requests. handleIceConnectionStateChange: function(iceConnectionState) { var histogram = Services.telemetry.getHistogramById("WEBRTC_ICE_SUCCESS_RATE"); if (iceConnectionState === 'failed') { histogram.add(false); } if (this._dompc.iceConnectionState === 'checking' && (iceConnectionState === 'completed' || iceConnectionState === 'connected')) { histogram.add(true); } this._dompc.changeIceConnectionState(iceConnectionState); }, // This method is responsible for updating iceGatheringState. This // state is defined in the WebRTC specification as follows: // // iceGatheringState: // ------------------ // new The object was just created, and no networking has occurred // yet. // // gathering The ICE engine is in the process of gathering candidates for // this RTCPeerConnection. // // complete The ICE engine has completed gathering. Events such as adding // a new interface or a new TURN server will cause the state to // go back to gathering. // handleIceGatheringStateChange: function(gatheringState) { this._dompc.changeIceGatheringState(gatheringState); if (gatheringState === "complete") { if (!this._dompc._trickleIce) { // If we are not trickling, then the queue is in a pending state // waiting for ICE gathering and executeNext frees it this._dompc._executeNext(); } else if (this._dompc.localDescription) { // If we are trickling but we have already done setLocal, // then we need to send a final foundIceCandidate(null) to indicate // that we are done gathering. this.foundIceCandidate(null); } } }, onStateChange: function(state) { switch (state) { case "SignalingState": this.callCB(this._dompc.onsignalingstatechange, this._dompc.signalingState); break; case "IceConnectionState": this.handleIceConnectionStateChange(this._dompc._pc.iceConnectionState); break; case "IceGatheringState": this.handleIceGatheringStateChange(this._dompc._pc.iceGatheringState); break; case "SdpState": // No-op break; case "ReadyState": // No-op break; case "SipccState": // No-op break; default: this._dompc.reportWarning("Unhandled state type: " + state, null, 0); break; } }, onGetStatsSuccess: function(dict) { function appendStats(stats, report) { if (stats) { stats.forEach(function(stat) { report[stat.id] = stat; }); } } let report = {}; appendStats(dict.rtpStreamStats, report); appendStats(dict.inboundRTPStreamStats, report); appendStats(dict.outboundRTPStreamStats, report); appendStats(dict.mediaStreamTrackStats, report); appendStats(dict.mediaStreamStats, report); appendStats(dict.transportStats, report); appendStats(dict.iceComponentStats, report); appendStats(dict.iceCandidatePairStats, report); appendStats(dict.iceCandidateStats, report); appendStats(dict.codecStats, report); this.callCB(this._dompc._onGetStatsSuccess, this._dompc._win.RTCStatsReport._create(this._dompc._win, new RTCStatsReport(this._dompc._win, report, dict.pcid))); this._dompc._executeNext(); }, onGetStatsError: function(code, message) { this.callCB(this._dompc._onGetStatsFailure, new RTCError(code, message)); this._dompc._executeNext(); }, onGetLoggingSuccess: function(logs) { this.callCB(this._dompc._onGetLoggingSuccess, logs); this._dompc._executeNext(); }, onGetLoggingError: function(code, message) { this.callCB(this._dompc._onGetLoggingFailure, new RTCError(code, message)); this._dompc._executeNext(); }, onAddStream: function(stream) { this.dispatchEvent(new this._dompc._win.MediaStreamEvent("addstream", { stream: stream })); }, onRemoveStream: function(stream, type) { this.dispatchEvent(new this._dompc._win.MediaStreamEvent("removestream", { stream: stream })); }, foundIceCandidate: function(cand) { this.dispatchEvent(new this._dompc._win.RTCPeerConnectionIceEvent("icecandidate", { candidate: cand } )); }, notifyDataChannel: function(channel) { this.dispatchEvent(new this._dompc._win.RTCDataChannelEvent("datachannel", { channel: channel })); }, notifyConnection: function() { this.dispatchEvent(new this._dompc._win.Event("connection")); }, notifyClosedConnection: function() { this.dispatchEvent(new this._dompc._win.Event("closedconnection")); }, getSupportedConstraints: function(dict) { return dict; }, }; this.NSGetFactory = XPCOMUtils.generateNSGetFactory( [GlobalPCList, RTCIceCandidate, RTCSessionDescription, RTCPeerConnection, RTCStatsReport, PeerConnectionObserver, WebrtcGlobalInformation] );