gecko-dev/dom/simplepush/PushService.jsm
2016-05-17 12:04:11 +02:00

1852 lines
60 KiB
JavaScript

/* jshint moz: true, esnext: true */
/* 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";
// Don't modify this, instead set services.push.debug.
var gDebuggingEnabled = false;
function debug(s) {
if (gDebuggingEnabled)
dump("-*- PushService.jsm: " + s + "\n");
}
const Cc = Components.classes;
const Ci = Components.interfaces;
const Cu = Components.utils;
const Cr = Components.results;
Cu.import("resource://gre/modules/XPCOMUtils.jsm");
Cu.import("resource://gre/modules/Services.jsm");
Cu.import("resource://gre/modules/IndexedDBHelper.jsm");
Cu.import("resource://gre/modules/Timer.jsm");
Cu.import("resource://gre/modules/Preferences.jsm");
Cu.import("resource://gre/modules/Promise.jsm");
Cu.importGlobalProperties(["indexedDB"]);
XPCOMUtils.defineLazyServiceGetter(this, "gDNSService",
"@mozilla.org/network/dns-service;1",
"nsIDNSService");
XPCOMUtils.defineLazyModuleGetter(this, "AlarmService",
"resource://gre/modules/AlarmService.jsm");
XPCOMUtils.defineLazyServiceGetter(this, "gPowerManagerService",
"@mozilla.org/power/powermanagerservice;1",
"nsIPowerManagerService");
var threadManager = Cc["@mozilla.org/thread-manager;1"].getService(Ci.nsIThreadManager);
this.EXPORTED_SYMBOLS = ["PushService"];
const prefs = new Preferences("services.push.");
// Set debug first so that all debugging actually works.
gDebuggingEnabled = prefs.get("debug");
const kPUSHDB_DB_NAME = "push";
const kPUSHDB_DB_VERSION = 1; // Change this if the IndexedDB format changes
const kPUSHDB_STORE_NAME = "push";
const kUDP_WAKEUP_WS_STATUS_CODE = 4774; // WebSocket Close status code sent
// by server to signal that it can
// wake client up using UDP.
const kCHILD_PROCESS_MESSAGES = ["Push:Register", "Push:Unregister",
"Push:Registrations"];
// This is a singleton
this.PushDB = function PushDB() {
debug("PushDB()");
// set the indexeddb database
this.initDBHelper(kPUSHDB_DB_NAME, kPUSHDB_DB_VERSION,
[kPUSHDB_STORE_NAME]);
};
this.PushDB.prototype = {
__proto__: IndexedDBHelper.prototype,
upgradeSchema: function(aTransaction, aDb, aOldVersion, aNewVersion) {
debug("PushDB.upgradeSchema()");
let objectStore = aDb.createObjectStore(kPUSHDB_STORE_NAME,
{ keyPath: "channelID" });
// index to fetch records based on endpoints. used by unregister
objectStore.createIndex("pushEndpoint", "pushEndpoint", { unique: true });
// index to fetch records per manifest, so we can identify endpoints
// associated with an app. Since an app can have multiple endpoints
// uniqueness cannot be enforced
objectStore.createIndex("manifestURL", "manifestURL", { unique: false });
},
/*
* @param aChannelRecord
* The record to be added.
* @param aSuccessCb
* Callback function to invoke with result ID.
* @param aErrorCb [optional]
* Callback function to invoke when there was an error.
*/
put: function(aChannelRecord, aSuccessCb, aErrorCb) {
debug("put()");
this.newTxn(
"readwrite",
kPUSHDB_STORE_NAME,
function txnCb(aTxn, aStore) {
debug("Going to put " + aChannelRecord.channelID);
aStore.put(aChannelRecord).onsuccess = function setTxnResult(aEvent) {
debug("Request successful. Updated record ID: " +
aEvent.target.result);
};
},
aSuccessCb,
aErrorCb
);
},
/*
* @param aChannelID
* The ID of record to be deleted.
* @param aSuccessCb
* Callback function to invoke with result.
* @param aErrorCb [optional]
* Callback function to invoke when there was an error.
*/
delete: function(aChannelID, aSuccessCb, aErrorCb) {
debug("delete()");
this.newTxn(
"readwrite",
kPUSHDB_STORE_NAME,
function txnCb(aTxn, aStore) {
debug("Going to delete " + aChannelID);
aStore.delete(aChannelID);
},
aSuccessCb,
aErrorCb
);
},
getByPushEndpoint: function(aPushEndpoint, aSuccessCb, aErrorCb) {
debug("getByPushEndpoint()");
this.newTxn(
"readonly",
kPUSHDB_STORE_NAME,
function txnCb(aTxn, aStore) {
aTxn.result = undefined;
let index = aStore.index("pushEndpoint");
index.get(aPushEndpoint).onsuccess = function setTxnResult(aEvent) {
aTxn.result = aEvent.target.result;
debug("Fetch successful " + aEvent.target.result);
}
},
aSuccessCb,
aErrorCb
);
},
getByChannelID: function(aChannelID, aSuccessCb, aErrorCb) {
debug("getByChannelID()");
this.newTxn(
"readonly",
kPUSHDB_STORE_NAME,
function txnCb(aTxn, aStore) {
aTxn.result = undefined;
aStore.get(aChannelID).onsuccess = function setTxnResult(aEvent) {
aTxn.result = aEvent.target.result;
debug("Fetch successful " + aEvent.target.result);
}
},
aSuccessCb,
aErrorCb
);
},
getAllByManifestURL: function(aManifestURL, aSuccessCb, aErrorCb) {
debug("getAllByManifestURL()");
if (!aManifestURL) {
if (typeof aErrorCb == "function") {
aErrorCb("PushDB.getAllByManifestURL: Got undefined aManifestURL");
}
return;
}
let self = this;
this.newTxn(
"readonly",
kPUSHDB_STORE_NAME,
function txnCb(aTxn, aStore) {
let index = aStore.index("manifestURL");
let range = IDBKeyRange.only(aManifestURL);
aTxn.result = [];
index.openCursor(range).onsuccess = function(event) {
let cursor = event.target.result;
if (cursor) {
debug(cursor.value.manifestURL + " " + cursor.value.channelID);
aTxn.result.push(cursor.value);
cursor.continue();
}
}
},
aSuccessCb,
aErrorCb
);
},
getAllChannelIDs: function(aSuccessCb, aErrorCb) {
debug("getAllChannelIDs()");
this.newTxn(
"readonly",
kPUSHDB_STORE_NAME,
function txnCb(aTxn, aStore) {
aStore.mozGetAll().onsuccess = function(event) {
aTxn.result = event.target.result;
}
},
aSuccessCb,
aErrorCb
);
},
drop: function(aSuccessCb, aErrorCb) {
debug("drop()");
this.newTxn(
"readwrite",
kPUSHDB_STORE_NAME,
function txnCb(aTxn, aStore) {
aStore.clear();
},
aSuccessCb(),
aErrorCb()
);
}
};
/**
* A proxy between the PushService and the WebSocket. The listener is used so
* that the PushService can silence messages from the WebSocket by setting
* PushWebSocketListener._pushService to null. This is required because
* a WebSocket can continue to send messages or errors after it has been
* closed but the PushService may not be interested in these. It's easier to
* stop listening than to have checks at specific points.
*/
this.PushWebSocketListener = function(pushService) {
this._pushService = pushService;
}
this.PushWebSocketListener.prototype = {
onStart: function(context) {
if (!this._pushService)
return;
this._pushService._wsOnStart(context);
},
onStop: function(context, statusCode) {
if (!this._pushService)
return;
this._pushService._wsOnStop(context, statusCode);
},
onAcknowledge: function(context, size) {
// EMPTY
},
onBinaryMessageAvailable: function(context, message) {
// EMPTY
},
onMessageAvailable: function(context, message) {
if (!this._pushService)
return;
this._pushService._wsOnMessageAvailable(context, message);
},
onServerClose: function(context, aStatusCode, aReason) {
if (!this._pushService)
return;
this._pushService._wsOnServerClose(context, aStatusCode, aReason);
}
}
// websocket states
// websocket is off
const STATE_SHUT_DOWN = 0;
// Websocket has been opened on client side, waiting for successful open.
// (_wsOnStart)
const STATE_WAITING_FOR_WS_START = 1;
// Websocket opened, hello sent, waiting for server reply (_handleHelloReply).
const STATE_WAITING_FOR_HELLO = 2;
// Websocket operational, handshake completed, begin protocol messaging.
const STATE_READY = 3;
/**
* The implementation of the SimplePush system. This runs in the B2G parent
* process and is started on boot. It uses WebSockets to communicate with the
* server and PushDB (IndexedDB) for persistence.
*/
this.PushService = {
observe: function observe(aSubject, aTopic, aData) {
switch (aTopic) {
/*
* We need to call uninit() on shutdown to clean up things that modules aren't very good
* at automatically cleaning up, so we don't get shutdown leaks on browser shutdown.
*/
case "xpcom-shutdown":
this.uninit();
case "network-active-changed": /* On B2G. */
case "network:offline-status-changed": /* On desktop. */
// In case of network-active-changed, always disconnect existing
// connections. In case of offline-status changing from offline to
// online, it is likely that these statements will be no-ops.
if (this._udpServer) {
this._udpServer.close();
// Set to null since this is checked in _listenForUDPWakeup()
this._udpServer = null;
}
this._shutdownWS();
// Try to connect if network-active-changed or the offline-status
// changed to online.
if (aTopic === "network-active-changed" || aData === "online") {
this._startListeningIfChannelsPresent();
}
break;
case "nsPref:changed":
if (aData == "services.push.serverURL") {
debug("services.push.serverURL changed! websocket. new value " +
prefs.get("serverURL"));
this._shutdownWS();
} else if (aData == "services.push.connection.enabled") {
if (prefs.get("connection.enabled")) {
this._startListeningIfChannelsPresent();
} else {
this._shutdownWS();
}
} else if (aData == "services.push.debug") {
gDebuggingEnabled = prefs.get("debug");
}
break;
case "timer-callback":
if (aSubject == this._requestTimeoutTimer) {
if (Object.keys(this._pendingRequests).length == 0) {
this._requestTimeoutTimer.cancel();
}
// Set to true if at least one request timed out.
let requestTimedOut = false;
for (let channelID in this._pendingRequests) {
let duration = Date.now() - this._pendingRequests[channelID].ctime;
// If any of the registration requests time out, all the ones after it
// also made to fail, since we are going to be disconnecting the socket.
if (requestTimedOut || duration > this._requestTimeout) {
debug("Request timeout: Removing " + channelID);
requestTimedOut = true;
this._pendingRequests[channelID]
.deferred.reject({status: 0, error: "TimeoutError"});
delete this._pendingRequests[channelID];
for (let i = this._requestQueue.length - 1; i >= 0; --i)
if (this._requestQueue[i][1].channelID == channelID)
this._requestQueue.splice(i, 1);
}
}
// The most likely reason for a registration request timing out is
// that the socket has disconnected. Best to reconnect.
if (requestTimedOut) {
this._shutdownWS();
this._reconnectAfterBackoff();
}
}
break;
case "webapps-clear-data":
debug("webapps-clear-data");
let data = aSubject.QueryInterface(Ci.mozIApplicationClearPrivateDataParams);
if (!data) {
debug("webapps-clear-data: Failed to get information about application");
return;
}
// Only remove push registrations for apps.
if (data.browserOnly) {
return;
}
let appsService = Cc["@mozilla.org/AppsService;1"]
.getService(Ci.nsIAppsService);
let manifestURL = appsService.getManifestURLByLocalId(data.appId);
if (!manifestURL) {
debug("webapps-clear-data: No manifest URL found for " + data.appId);
return;
}
this._db.getAllByManifestURL(manifestURL, function(records) {
debug("Got " + records.length);
for (let i = 0; i < records.length; i++) {
this._db.delete(records[i].channelID, null, function() {
debug("webapps-clear-data: " + manifestURL +
" Could not delete entry " + records[i].channelID);
});
// courtesy, but don't establish a connection
// just for it
if (this._ws) {
debug("Had a connection, so telling the server");
this._send("unregister", {channelID: records[i].channelID});
}
}
}.bind(this), function() {
debug("webapps-clear-data: Error in getAllByManifestURL(" + manifestURL + ")");
});
break;
}
},
get _UAID() {
return prefs.get("userAgentID");
},
set _UAID(newID) {
if (typeof(newID) !== "string") {
debug("Got invalid, non-string UAID " + newID +
". Not updating userAgentID");
return;
}
debug("New _UAID: " + newID);
prefs.set("userAgentID", newID);
},
// keeps requests buffered if the websocket disconnects or is not connected
_requestQueue: [],
_ws: null,
_pendingRequests: {},
_currentState: STATE_SHUT_DOWN,
_requestTimeout: 0,
_requestTimeoutTimer: null,
_retryFailCount: 0,
/**
* According to the WS spec, servers should immediately close the underlying
* TCP connection after they close a WebSocket. This causes wsOnStop to be
* called with error NS_BASE_STREAM_CLOSED. Since the client has to keep the
* WebSocket up, it should try to reconnect. But if the server closes the
* WebSocket because it will wake up the client via UDP, then the client
* shouldn't re-establish the connection. If the server says that it will
* wake up the client over UDP, this is set to true in wsOnServerClose. It is
* checked in wsOnStop.
*/
_willBeWokenUpByUDP: false,
/**
* Holds if the adaptive ping is enabled. This is read on init().
* If adaptive ping is enabled, a new ping is calculed each time we receive
* a pong message, trying to maximize network resources while minimizing
* cellular signalling storms.
*/
_adaptiveEnabled: false,
/**
* This saves a flag about if we need to recalculate a new ping, based on:
* 1) the gap between the maximum working ping and the first ping that
* gives an error (timeout) OR
* 2) we have reached the pref of the maximum value we allow for a ping
* (services.push.adaptive.upperLimit)
*/
_recalculatePing: true,
/**
* This map holds a (pingInterval, triedTimes) of each pingInterval tried.
* It is used to check if the pingInterval has been tested enough to know that
* is incorrect and is above the limit the network allow us to keep the
* connection open.
*/
_pingIntervalRetryTimes: {},
/**
* Holds the lastGoodPingInterval for our current connection.
*/
_lastGoodPingInterval: 0,
/**
* Maximum ping interval that we can reach.
*/
_upperLimit: 0,
/**
* Sends a message to the Push Server through an open websocket.
* typeof(msg) shall be an object
*/
_wsSendMessage: function(msg) {
if (!this._ws) {
debug("No WebSocket initialized. Cannot send a message.");
return;
}
msg = JSON.stringify(msg);
debug("Sending message: " + msg);
this._ws.sendMsg(msg);
},
init: function() {
debug("init()");
if (!prefs.get("enabled"))
return null;
this._db = new PushDB();
let ppmm = Cc["@mozilla.org/parentprocessmessagemanager;1"]
.getService(Ci.nsIMessageBroadcaster);
kCHILD_PROCESS_MESSAGES.forEach(function addMessage(msgName) {
ppmm.addMessageListener(msgName, this);
}.bind(this));
this._alarmID = null;
this._requestTimeout = prefs.get("requestTimeout");
this._adaptiveEnabled = prefs.get('adaptive.enabled');
this._upperLimit = prefs.get('adaptive.upperLimit');
this._startListeningIfChannelsPresent();
Services.obs.addObserver(this, "xpcom-shutdown", false);
Services.obs.addObserver(this, "webapps-clear-data", false);
// On B2G the NetworkManager interface fires a network-active-changed
// event.
//
// The "active network" is based on priority - i.e. Wi-Fi has higher
// priority than data. The PushService should just use the preferred
// network, and not care about all interface changes.
// network-active-changed is not fired when the network goes offline, but
// socket connections time out. The check for Services.io.offline in
// _beginWSSetup() prevents unnecessary retries. When the network comes
// back online, network-active-changed is fired.
//
// On non-B2G platforms, the offline-status-changed event is used to know
// when to (dis)connect. It may not fire if the underlying OS changes
// networks; in such a case we rely on timeout.
//
// On B2G both events fire, one after the other, when the network goes
// online, so we explicitly check for the presence of NetworkManager and
// don't add an observer for offline-status-changed on B2G.
Services.obs.addObserver(this, this._getNetworkStateChangeEventName(), false);
// This is only used for testing. Different tests require connecting to
// slightly different URLs.
prefs.observe("serverURL", this);
// Used to monitor if the user wishes to disable Push.
prefs.observe("connection.enabled", this);
// Debugging
prefs.observe("debug", this);
this._started = true;
},
_shutdownWS: function() {
debug("shutdownWS()");
this._currentState = STATE_SHUT_DOWN;
this._willBeWokenUpByUDP = false;
if (this._wsListener)
this._wsListener._pushService = null;
try {
this._ws.close(0, null);
} catch (e) {}
this._ws = null;
this._waitingForPong = false;
this._stopAlarm();
},
uninit: function() {
if (!this._started)
return;
debug("uninit()");
prefs.ignore("debug", this);
prefs.ignore("connection.enabled", this);
prefs.ignore("serverURL", this);
Services.obs.removeObserver(this, this._getNetworkStateChangeEventName());
Services.obs.removeObserver(this, "webapps-clear-data", false);
Services.obs.removeObserver(this, "xpcom-shutdown", false);
if (this._db) {
this._db.close();
this._db = null;
}
if (this._udpServer) {
this._udpServer.close();
this._udpServer = null;
}
// All pending requests (ideally none) are dropped at this point. We
// shouldn't have any applications performing registration/unregistration
// or receiving notifications.
this._shutdownWS();
// At this point, profile-change-net-teardown has already fired, so the
// WebSocket has been closed with NS_ERROR_ABORT (if it was up) and will
// try to reconnect. Stop the timer.
this._stopAlarm();
if (this._requestTimeoutTimer) {
this._requestTimeoutTimer.cancel();
}
debug("shutdown complete!");
},
/**
* How retries work: The goal is to ensure websocket is always up on
* networks not supporting UDP. So the websocket should only be shutdown if
* onServerClose indicates UDP wakeup. If WS is closed due to socket error,
* _reconnectAfterBackoff() is called. The retry alarm is started and when
* it times out, beginWSSetup() is called again.
*
* On a successful connection, the alarm is cancelled in
* wsOnMessageAvailable() when the ping alarm is started.
*
* If we are in the middle of a timeout (i.e. waiting), but
* a register/unregister is called, we don't want to wait around anymore.
* _sendRequest will automatically call beginWSSetup(), which will cancel the
* timer. In addition since the state will have changed, even if a pending
* timer event comes in (because the timer fired the event before it was
* cancelled), so the connection won't be reset.
*/
_reconnectAfterBackoff: function() {
debug("reconnectAfterBackoff()");
//Calculate new ping interval
this._calculateAdaptivePing(true /* wsWentDown */);
// Calculate new timeout, but cap it to pingInterval.
let retryTimeout = prefs.get("retryBaseInterval") *
Math.pow(2, this._retryFailCount);
retryTimeout = Math.min(retryTimeout, prefs.get("pingInterval"));
this._retryFailCount++;
debug("Retry in " + retryTimeout + " Try number " + this._retryFailCount);
this._setAlarm(retryTimeout);
},
/**
* We need to calculate a new ping based on:
* 1) Latest good ping
* 2) A safe gap between 1) and the calculated new ping (which is
* by default, 1 minute)
*
* This is for 3G networks, whose connections keepalives differ broadly,
* for example:
* 1) Movistar Spain: 29 minutes
* 2) VIVO Brazil: 5 minutes
* 3) Movistar Colombia: XXX minutes
*
* So a fixed ping is not good for us for two reasons:
* 1) We might lose the connection, so we need to reconnect again (wasting
* resources)
* 2) We use a lot of network signaling just for pinging.
*
* This algorithm tries to search the best value between a disconnection and a
* valid ping, to ensure better battery life and network resources usage.
*
* The value is saved in services.push.pingInterval
* @param wsWentDown [Boolean] if the WebSocket was closed or it is still alive
*
*/
_calculateAdaptivePing: function(wsWentDown) {
debug('_calculateAdaptivePing()');
if (!this._adaptiveEnabled) {
debug('Adaptive ping is disabled');
return;
}
if (this._retryFailCount > 0) {
debug('Push has failed to connect to the Push Server ' +
this._retryFailCount + ' times. ' +
'Do not calculate a new pingInterval now');
return;
}
if (!this._recalculatePing && !wsWentDown) {
debug('We do not need to recalculate the ping now, based on previous data');
return;
}
// Save actual state of the network
let ns = this._getNetworkInformation();
if (ns.ip) {
// mobile
debug('mobile');
let oldNetwork = prefs.get('adaptive.mobile');
let newNetwork = 'mobile-' + ns.mcc + '-' + ns.mnc;
// Mobile networks differ, reset all intervals and pings
if (oldNetwork !== newNetwork) {
// Network differ, reset all values
debug('Mobile networks differ. Old network is ' + oldNetwork +
' and new is ' + newNetwork);
prefs.set('adaptive.mobile', newNetwork);
//We reset the upper bound member
this._recalculatePing = true;
this._pingIntervalRetryTimes = {};
// Put default values
let defaultPing = prefs.get('pingInterval.default');
prefs.set('pingInterval', defaultPing);
this._lastGoodPingInterval = defaultPing;
} else {
// Mobile network is the same, let's just update things
prefs.set('pingInterval', prefs.get('pingInterval.mobile'));
this._lastGoodPingInterval = prefs.get('adaptive.lastGoodPingInterval.mobile');
}
} else {
// wifi
debug('wifi');
prefs.set('pingInterval', prefs.get('pingInterval.wifi'));
this._lastGoodPingInterval = prefs.get('adaptive.lastGoodPingInterval.wifi');
}
let nextPingInterval;
let lastTriedPingInterval = prefs.get('pingInterval');
if (wsWentDown) {
debug('The WebSocket was disconnected, calculating next ping');
// If we have not tried this pingInterval yet, initialize
this._pingIntervalRetryTimes[lastTriedPingInterval] =
(this._pingIntervalRetryTimes[lastTriedPingInterval] || 0) + 1;
// Try the pingInterval at least 3 times, just to be sure that the
// calculated interval is not valid.
if (this._pingIntervalRetryTimes[lastTriedPingInterval] < 2) {
debug('pingInterval= ' + lastTriedPingInterval + ' tried only ' +
this._pingIntervalRetryTimes[lastTriedPingInterval] + ' times');
return;
}
// Latest ping was invalid, we need to lower the limit to limit / 2
nextPingInterval = Math.floor(lastTriedPingInterval / 2);
// If the new ping interval is close to the last good one, we are near
// optimum, so stop calculating.
if (nextPingInterval - this._lastGoodPingInterval < prefs.get('adaptive.gap')) {
debug('We have reached the gap, we have finished the calculation');
debug('nextPingInterval=' + nextPingInterval);
debug('lastGoodPing=' + this._lastGoodPingInterval);
nextPingInterval = this._lastGoodPingInterval;
this._recalculatePing = false;
} else {
debug('We need to calculate next time');
this._recalculatePing = true;
}
} else {
debug('The WebSocket is still up');
this._lastGoodPingInterval = lastTriedPingInterval;
nextPingInterval = Math.floor(lastTriedPingInterval * 1.5);
}
// Check if we have reached the upper limit
if (this._upperLimit < nextPingInterval) {
debug('Next ping will be bigger than the configured upper limit, capping interval');
this._recalculatePing = false;
this._lastGoodPingInterval = lastTriedPingInterval;
nextPingInterval = lastTriedPingInterval;
}
debug('Setting the pingInterval to ' + nextPingInterval);
prefs.set('pingInterval', nextPingInterval);
//Save values for our current network
if (ns.ip) {
prefs.set('pingInterval.mobile', nextPingInterval);
prefs.set('adaptive.lastGoodPingInterval.mobile', this._lastGoodPingInterval);
} else {
prefs.set('pingInterval.wifi', nextPingInterval);
prefs.set('adaptive.lastGoodPingInterval.wifi', this._lastGoodPingInterval);
}
},
_beginWSSetup: function() {
debug("beginWSSetup()");
if (this._currentState != STATE_SHUT_DOWN) {
debug("_beginWSSetup: Not in shutdown state! Current state " +
this._currentState);
return;
}
if (!prefs.get("connection.enabled")) {
debug("_beginWSSetup: connection.enabled is not set to true. Aborting.");
return;
}
// Stop any pending reconnects scheduled for the near future.
this._stopAlarm();
if (Services.io.offline) {
debug("Network is offline.");
return;
}
let serverURL = prefs.get("serverURL");
if (!serverURL) {
debug("No services.push.serverURL found!");
return;
}
let uri;
try {
uri = Services.io.newURI(serverURL, null, null);
} catch(e) {
debug("Error creating valid URI from services.push.serverURL (" +
serverURL + ")");
return;
}
if (uri.scheme === "wss") {
this._ws = Cc["@mozilla.org/network/protocol;1?name=wss"]
.createInstance(Ci.nsIWebSocketChannel);
this._ws.initLoadInfo(null, // aLoadingNode
Services.scriptSecurityManager.getSystemPrincipal(),
null, // aTriggeringPrincipal
Ci.nsILoadInfo.SEC_ALLOW_CROSS_ORIGIN_DATA_IS_NULL,
Ci.nsIContentPolicy.TYPE_WEBSOCKET);
}
else if (uri.scheme === "ws") {
debug("Push over an insecure connection (ws://) is not allowed!");
return;
}
else {
debug("Unsupported websocket scheme " + uri.scheme);
return;
}
debug("serverURL: " + uri.spec);
this._wsListener = new PushWebSocketListener(this);
this._ws.protocol = "push-notification";
try {
// Grab a wakelock before we open the socket to ensure we don't go to sleep
// before connection the is opened.
this._ws.asyncOpen(uri, serverURL, 0, this._wsListener, null);
this._acquireWakeLock();
this._currentState = STATE_WAITING_FOR_WS_START;
} catch(e) {
debug("Error opening websocket. asyncOpen failed!");
this._shutdownWS();
this._reconnectAfterBackoff();
}
},
_startListeningIfChannelsPresent: function() {
// Check to see if we need to do anything.
this._db.getAllChannelIDs(function(channelIDs) {
if (channelIDs.length > 0) {
this._beginWSSetup();
}
}.bind(this));
},
/** |delay| should be in milliseconds. */
_setAlarm: function(delay) {
// Bug 909270: Since calls to AlarmService.add() are async, calls must be
// 'queued' to ensure only one alarm is ever active.
if (this._settingAlarm) {
// onSuccess will handle the set. Overwriting the variable enforces the
// last-writer-wins semantics.
this._queuedAlarmDelay = delay;
this._waitingForAlarmSet = true;
return;
}
// Stop any existing alarm.
this._stopAlarm();
this._settingAlarm = true;
AlarmService.add(
{
date: new Date(Date.now() + delay),
ignoreTimezone: true
},
this._onAlarmFired.bind(this),
function onSuccess(alarmID) {
this._alarmID = alarmID;
debug("Set alarm " + delay + " in the future " + this._alarmID);
this._settingAlarm = false;
if (this._waitingForAlarmSet) {
this._waitingForAlarmSet = false;
this._setAlarm(this._queuedAlarmDelay);
}
}.bind(this)
)
},
_stopAlarm: function() {
if (this._alarmID !== null) {
debug("Stopped existing alarm " + this._alarmID);
AlarmService.remove(this._alarmID);
this._alarmID = null;
}
},
/**
* There is only one alarm active at any time. This alarm has 3 intervals
* corresponding to 3 tasks.
*
* 1) Reconnect on ping timeout.
* If we haven't received any messages from the server by the time this
* alarm fires, the connection is closed and PushService tries to
* reconnect, repurposing the alarm for (3).
*
* 2) Send a ping.
* The protocol sends a ping ({}) on the wire every pingInterval ms. Once
* it sends the ping, the alarm goes to task (1) which is waiting for
* a pong. If data is received after the ping is sent,
* _wsOnMessageAvailable() will reset the ping alarm (which cancels
* waiting for the pong). So as long as the connection is fine, pong alarm
* never fires.
*
* 3) Reconnect after backoff.
* The alarm is set by _reconnectAfterBackoff() and increases in duration
* every time we try and fail to connect. When it triggers, websocket
* setup begins again. On successful socket setup, the socket starts
* receiving messages. The alarm now goes to (2) where it monitors the
* WebSocket by sending a ping. Since incoming data is a sign of the
* connection being up, the ping alarm is reset every time data is
* received.
*/
_onAlarmFired: function() {
// Conditions are arranged in decreasing specificity.
// i.e. when _waitingForPong is true, other conditions are also true.
if (this._waitingForPong) {
debug("Did not receive pong in time. Reconnecting WebSocket.");
this._shutdownWS();
this._reconnectAfterBackoff();
}
else if (this._currentState == STATE_READY) {
// Send a ping.
// Bypass the queue; we don't want this to be kept pending.
// Watch out for exception in case the socket has disconnected.
// When this happens, we pretend the ping was sent and don't specially
// handle the exception, as the lack of a pong will lead to the socket
// being reset.
try {
this._wsSendMessage({});
} catch (e) {
}
this._waitingForPong = true;
this._setAlarm(prefs.get("requestTimeout"));
}
else if (this._alarmID !== null) {
debug("reconnect alarm fired.");
// Reconnect after back-off.
// The check for a non-null _alarmID prevents a situation where the alarm
// fires, but _shutdownWS() is called from another code-path (e.g.
// network state change) and we don't want to reconnect.
//
// It also handles the case where _beginWSSetup() is called from another
// code-path.
//
// alarmID will be non-null only when no shutdown/connect is
// called between _reconnectAfterBackoff() setting the alarm and the
// alarm firing.
// Websocket is shut down. Backoff interval expired, try to connect.
this._beginWSSetup();
}
},
_acquireWakeLock: function() {
if (!this._socketWakeLock) {
debug("Acquiring Socket Wakelock");
this._socketWakeLock = gPowerManagerService.newWakeLock("cpu");
}
if (!this._socketWakeLockTimer) {
debug("Creating Socket WakeLock Timer");
this._socketWakeLockTimer = Cc["@mozilla.org/timer;1"].createInstance(Ci.nsITimer);
}
debug("Setting Socket WakeLock Timer");
this._socketWakeLockTimer
.initWithCallback(this._releaseWakeLock.bind(this),
// Allow the same time for socket setup as we do for
// requests after the setup. Fudge it a bit since
// timers can be a little off and we don't want to go
// to sleep just as the socket connected.
this._requestTimeout + 1000,
Ci.nsITimer.ONE_SHOT);
},
_releaseWakeLock: function() {
debug("Releasing Socket WakeLock");
if (this._socketWakeLockTimer) {
this._socketWakeLockTimer.cancel();
}
if (this._socketWakeLock) {
this._socketWakeLock.unlock();
this._socketWakeLock = null;
}
},
/**
* Protocol handler invoked by server message.
*/
_handleHelloReply: function(reply) {
debug("handleHelloReply()");
if (this._currentState != STATE_WAITING_FOR_HELLO) {
debug("Unexpected state " + this._currentState +
"(expected STATE_WAITING_FOR_HELLO)");
this._shutdownWS();
return;
}
if (typeof reply.uaid !== "string") {
debug("No UAID received or non string UAID received");
this._shutdownWS();
return;
}
if (reply.uaid === "") {
debug("Empty UAID received!");
this._shutdownWS();
return;
}
// To avoid sticking extra large values sent by an evil server into prefs.
if (reply.uaid.length > 128) {
debug("UAID received from server was too long: " +
reply.uaid);
this._shutdownWS();
return;
}
function finishHandshake() {
this._UAID = reply.uaid;
this._currentState = STATE_READY;
this._processNextRequestInQueue();
}
// By this point we've got a UAID from the server that we are ready to
// accept.
//
// If we already had a valid UAID before, we have to ask apps to
// re-register.
if (this._UAID && this._UAID != reply.uaid) {
debug("got new UAID: all re-register");
this._notifyAllAppsRegister()
.then(this._dropRegistrations.bind(this))
.then(finishHandshake.bind(this));
return;
}
// otherwise we are good to go
finishHandshake.bind(this)();
},
/**
* Protocol handler invoked by server message.
*/
_handleRegisterReply: function(reply) {
debug("handleRegisterReply()");
if (typeof reply.channelID !== "string" ||
typeof this._pendingRequests[reply.channelID] !== "object")
return;
let tmp = this._pendingRequests[reply.channelID];
delete this._pendingRequests[reply.channelID];
if (Object.keys(this._pendingRequests).length == 0 &&
this._requestTimeoutTimer)
this._requestTimeoutTimer.cancel();
if (reply.status == 200) {
tmp.deferred.resolve(reply);
} else {
tmp.deferred.reject(reply);
}
},
/**
* Protocol handler invoked by server message.
*/
_handleNotificationReply: function(reply) {
debug("handleNotificationReply()");
if (typeof reply.updates !== 'object') {
debug("No 'updates' field in response. Type = " + typeof reply.updates);
return;
}
debug("Reply updates: " + reply.updates.length);
for (let i = 0; i < reply.updates.length; i++) {
let update = reply.updates[i];
debug("Update: " + update.channelID + ": " + update.version);
if (typeof update.channelID !== "string") {
debug("Invalid update literal at index " + i);
continue;
}
if (update.version === undefined) {
debug("update.version does not exist");
continue;
}
let version = update.version;
if (typeof version === "string") {
version = parseInt(version, 10);
}
if (typeof version === "number" && version >= 0) {
// FIXME(nsm): this relies on app update notification being infallible!
// eventually fix this
this._receivedUpdate(update.channelID, version);
this._sendAck(update.channelID, version);
}
}
},
// FIXME(nsm): batch acks for efficiency reasons.
_sendAck: function(channelID, version) {
debug("sendAck()");
this._send('ack', {
updates: [{channelID: channelID, version: version}]
});
},
/*
* Must be used only by request/response style calls over the websocket.
*/
_sendRequest: function(action, data) {
debug("sendRequest() " + action);
if (typeof data.channelID !== "string") {
debug("Received non-string channelID");
return Promise.reject("Received non-string channelID");
}
let deferred = Promise.defer();
if (Object.keys(this._pendingRequests).length == 0) {
// start the timer since we now have at least one request
if (!this._requestTimeoutTimer)
this._requestTimeoutTimer = Cc["@mozilla.org/timer;1"]
.createInstance(Ci.nsITimer);
this._requestTimeoutTimer.init(this,
this._requestTimeout,
Ci.nsITimer.TYPE_REPEATING_SLACK);
}
this._pendingRequests[data.channelID] = { deferred: deferred,
ctime: Date.now() };
this._send(action, data);
return deferred.promise;
},
_send: function(action, data) {
debug("send()");
this._requestQueue.push([action, data]);
debug("Queued " + action);
this._processNextRequestInQueue();
},
_processNextRequestInQueue: function() {
debug("_processNextRequestInQueue()");
if (this._requestQueue.length == 0) {
debug("Request queue empty");
return;
}
if (this._currentState != STATE_READY) {
if (!this._ws) {
// This will end up calling processNextRequestInQueue().
this._beginWSSetup();
}
else {
// We have a socket open so we are just waiting for hello to finish.
// That will call processNextRequestInQueue().
}
return;
}
let [action, data] = this._requestQueue.shift();
data.messageType = action;
if (!this._ws) {
// If our websocket is not ready and our state is STATE_READY we may as
// well give up all assumptions about the world and start from scratch
// again. Discard the message itself, let the timeout notify error to
// the app.
debug("This should never happen!");
this._shutdownWS();
}
this._wsSendMessage(data);
// Process the next one as soon as possible.
setTimeout(this._processNextRequestInQueue.bind(this), 0);
},
_receivedUpdate: function(aChannelID, aLatestVersion) {
debug("Updating: " + aChannelID + " -> " + aLatestVersion);
let compareRecordVersionAndNotify = function(aPushRecord) {
debug("compareRecordVersionAndNotify()");
if (!aPushRecord) {
debug("No record for channel ID " + aChannelID);
return;
}
if (aPushRecord.version == null ||
aPushRecord.version < aLatestVersion) {
debug("Version changed, notifying app and updating DB");
aPushRecord.version = aLatestVersion;
this._notifyApp(aPushRecord);
this._updatePushRecord(aPushRecord)
.then(
null,
function(e) {
debug("Error updating push record");
}
);
}
else {
debug("No significant version change: " + aLatestVersion);
}
}
let recoverNoSuchChannelID = function(aChannelIDFromServer) {
debug("Could not get channelID " + aChannelIDFromServer + " from DB");
}
this._db.getByChannelID(aChannelID,
compareRecordVersionAndNotify.bind(this),
recoverNoSuchChannelID.bind(this));
},
// Fires a push-register system message to all applications that have
// registrations.
_notifyAllAppsRegister: function() {
debug("notifyAllAppsRegister()");
let deferred = Promise.defer();
// records are objects describing the registrations as stored in IndexedDB.
function wakeupRegisteredApps(records) {
// Pages to be notified.
// wakeupTable[manifestURL] -> [ pageURL ]
let wakeupTable = {};
for (let i = 0; i < records.length; i++) {
let record = records[i];
if (!(record.manifestURL in wakeupTable))
wakeupTable[record.manifestURL] = [];
wakeupTable[record.manifestURL].push(record.pageURL);
}
let messenger = Cc["@mozilla.org/system-message-internal;1"]
.getService(Ci.nsISystemMessagesInternal);
for (let manifestURL in wakeupTable) {
wakeupTable[manifestURL].forEach(function(pageURL) {
messenger.sendMessage('push-register', {},
Services.io.newURI(pageURL, null, null),
Services.io.newURI(manifestURL, null, null));
});
}
deferred.resolve();
}
this._db.getAllChannelIDs(wakeupRegisteredApps, deferred.reject);
return deferred.promise;
},
_notifyApp: function(aPushRecord) {
if (!aPushRecord || !aPushRecord.pageURL || !aPushRecord.manifestURL) {
debug("notifyApp() something is undefined. Dropping notification");
return;
}
debug("notifyApp() " + aPushRecord.pageURL +
" " + aPushRecord.manifestURL);
let pageURI = Services.io.newURI(aPushRecord.pageURL, null, null);
let manifestURI = Services.io.newURI(aPushRecord.manifestURL, null, null);
let message = {
pushEndpoint: aPushRecord.pushEndpoint,
version: aPushRecord.version
};
let messenger = Cc["@mozilla.org/system-message-internal;1"]
.getService(Ci.nsISystemMessagesInternal);
messenger.sendMessage('push', message, pageURI, manifestURI);
},
_updatePushRecord: function(aPushRecord) {
debug("updatePushRecord()");
let deferred = Promise.defer();
this._db.put(aPushRecord, deferred.resolve, deferred.reject);
return deferred.promise;
},
_dropRegistrations: function() {
let deferred = Promise.defer();
this._db.drop(deferred.resolve, deferred.reject);
return deferred.promise;
},
receiveMessage: function(aMessage) {
debug("receiveMessage(): " + aMessage.name);
if (kCHILD_PROCESS_MESSAGES.indexOf(aMessage.name) == -1) {
debug("Invalid message from child " + aMessage.name);
return;
}
let mm = aMessage.target.QueryInterface(Ci.nsIMessageSender);
let json = aMessage.data;
this[aMessage.name.slice("Push:".length).toLowerCase()](json, mm);
},
/**
* Called on message from the child process. aPageRecord is an object sent by
* navigator.push, identifying the sending page and other fields.
*/
register: function(aPageRecord, aMessageManager) {
debug("register()");
let uuidGenerator = Cc["@mozilla.org/uuid-generator;1"]
.getService(Ci.nsIUUIDGenerator);
// generateUUID() gives a UUID surrounded by {...}, slice them off.
let channelID = uuidGenerator.generateUUID().toString().slice(1, -1);
this._sendRequest("register", {channelID: channelID})
.then(
this._onRegisterSuccess.bind(this, aPageRecord, channelID),
this._onRegisterError.bind(this, aPageRecord, aMessageManager)
)
.then(
function(message) {
aMessageManager.sendAsyncMessage("PushService:Register:OK", message);
},
function(message) {
aMessageManager.sendAsyncMessage("PushService:Register:KO", message);
});
},
/**
* Exceptions thrown in _onRegisterSuccess are caught by the promise obtained
* from _sendRequest, causing the promise to be rejected instead.
*/
_onRegisterSuccess: function(aPageRecord, generatedChannelID, data) {
debug("_onRegisterSuccess()");
let deferred = Promise.defer();
let message = { requestID: aPageRecord.requestID };
if (typeof data.channelID !== "string") {
debug("Invalid channelID " + message);
message["error"] = "Invalid channelID received";
throw message;
}
else if (data.channelID != generatedChannelID) {
debug("Server replied with different channelID " + data.channelID +
" than what UA generated " + generatedChannelID);
message["error"] = "Server sent 200 status code but different channelID";
throw message;
}
try {
Services.io.newURI(data.pushEndpoint, null, null);
}
catch (e) {
debug("Invalid pushEndpoint " + data.pushEndpoint);
message["error"] = "Invalid pushEndpoint " + data.pushEndpoint;
throw message;
}
let record = {
channelID: data.channelID,
pushEndpoint: data.pushEndpoint,
pageURL: aPageRecord.pageURL,
manifestURL: aPageRecord.manifestURL,
version: null
};
this._updatePushRecord(record)
.then(
function() {
message["pushEndpoint"] = data.pushEndpoint;
deferred.resolve(message);
},
function(error) {
// Unable to save.
this._send("unregister", {channelID: record.channelID});
message["error"] = error;
deferred.reject(message);
}
);
return deferred.promise;
},
/**
* Exceptions thrown in _onRegisterError are caught by the promise obtained
* from _sendRequest, causing the promise to be rejected instead.
*/
_onRegisterError: function(aPageRecord, aMessageManager, reply) {
debug("_onRegisterError()");
if (!reply.error) {
debug("Called without valid error message!");
}
throw { requestID: aPageRecord.requestID, error: reply.error };
},
/**
* Called on message from the child process.
*
* Why is the record being deleted from the local database before the server
* is told?
*
* Unregistration is for the benefit of the app and the AppServer
* so that the AppServer does not keep pinging a channel the UserAgent isn't
* watching The important part of the transaction in this case is left to the
* app, to tell its server of the unregistration. Even if the request to the
* PushServer were to fail, it would not affect correctness of the protocol,
* and the server GC would just clean up the channelID eventually. Since the
* appserver doesn't ping it, no data is lost.
*
* If rather we were to unregister at the server and update the database only
* on success: If the server receives the unregister, and deletes the
* channelID, but the response is lost because of network failure, the
* application is never informed. In addition the application may retry the
* unregister when it fails due to timeout at which point the server will say
* it does not know of this unregistration. We'll have to make the
* registration/unregistration phases have retries and attempts to resend
* messages from the server, and have the client acknowledge. On a server,
* data is cheap, reliable notification is not.
*/
unregister: function(aPageRecord, aMessageManager) {
debug("unregister()");
let fail = function(error) {
debug("unregister() fail() error " + error);
let message = {requestID: aPageRecord.requestID, error: error};
aMessageManager.sendAsyncMessage("PushService:Unregister:KO", message);
}
this._db.getByPushEndpoint(aPageRecord.pushEndpoint, function(record) {
// If the endpoint didn't exist, let's just fail.
if (record === undefined) {
fail("NotFoundError");
return;
}
// Non-owner tried to unregister, say success, but don't do anything.
if (record.manifestURL !== aPageRecord.manifestURL) {
aMessageManager.sendAsyncMessage("PushService:Unregister:OK", {
requestID: aPageRecord.requestID,
pushEndpoint: aPageRecord.pushEndpoint
});
return;
}
this._db.delete(record.channelID, function() {
// Let's be nice to the server and try to inform it, but we don't care
// about the reply.
this._send("unregister", {channelID: record.channelID});
aMessageManager.sendAsyncMessage("PushService:Unregister:OK", {
requestID: aPageRecord.requestID,
pushEndpoint: aPageRecord.pushEndpoint
});
}.bind(this), fail);
}.bind(this), fail);
},
/**
* Called on message from the child process
*/
registrations: function(aPageRecord, aMessageManager) {
debug("registrations()");
if (aPageRecord.manifestURL) {
this._db.getAllByManifestURL(aPageRecord.manifestURL,
this._onRegistrationsSuccess.bind(this, aPageRecord, aMessageManager),
this._onRegistrationsError.bind(this, aPageRecord, aMessageManager));
}
else {
this._onRegistrationsError(aPageRecord, aMessageManager);
}
},
_onRegistrationsSuccess: function(aPageRecord,
aMessageManager,
pushRecords) {
let registrations = [];
pushRecords.forEach(function(pushRecord) {
registrations.push({
__exposedProps__: { pushEndpoint: 'r', version: 'r' },
pushEndpoint: pushRecord.pushEndpoint,
version: pushRecord.version
});
});
aMessageManager.sendAsyncMessage("PushService:Registrations:OK", {
requestID: aPageRecord.requestID,
registrations: registrations
});
},
_onRegistrationsError: function(aPageRecord, aMessageManager) {
aMessageManager.sendAsyncMessage("PushService:Registrations:KO", {
requestID: aPageRecord.requestID,
error: "Database error"
});
},
// begin Push protocol handshake
_wsOnStart: function(context) {
debug("wsOnStart()");
this._releaseWakeLock();
if (this._currentState != STATE_WAITING_FOR_WS_START) {
debug("NOT in STATE_WAITING_FOR_WS_START. Current state " +
this._currentState + ". Skipping");
return;
}
// Since we've had a successful connection reset the retry fail count.
this._retryFailCount = 0;
let data = {
messageType: "hello",
}
if (this._UAID)
data["uaid"] = this._UAID;
this._getNetworkState((networkState) => {
if (networkState.ip) {
// Opening an available UDP port.
this._listenForUDPWakeup();
// Host-port is apparently a thing.
data["wakeup_hostport"] = {
ip: networkState.ip,
port: this._udpServer && this._udpServer.port
};
data["mobilenetwork"] = {
mcc: networkState.mcc,
mnc: networkState.mnc,
netid: networkState.netid
};
}
this._wsSendMessage(data);
this._currentState = STATE_WAITING_FOR_HELLO;
});
},
/**
* This statusCode is not the websocket protocol status code, but the TCP
* connection close status code.
*
* If we do not explicitly call ws.close() then statusCode is always
* NS_BASE_STREAM_CLOSED, even on a successful close.
*/
_wsOnStop: function(context, statusCode) {
debug("wsOnStop()");
this._releaseWakeLock();
if (statusCode != Cr.NS_OK &&
!(statusCode == Cr.NS_BASE_STREAM_CLOSED && this._willBeWokenUpByUDP)) {
debug("Socket error " + statusCode);
this._reconnectAfterBackoff();
}
// Bug 896919. We always shutdown the WebSocket, even if we need to
// reconnect. This works because _reconnectAfterBackoff() is "async"
// (there is a minimum delay of the pref retryBaseInterval, which by default
// is 5000ms), so that function will open the WebSocket again.
this._shutdownWS();
},
_wsOnMessageAvailable: function(context, message) {
debug("wsOnMessageAvailable() " + message);
this._waitingForPong = false;
let reply = undefined;
try {
reply = JSON.parse(message);
} catch(e) {
debug("Parsing JSON failed. text : " + message);
return;
}
// If we are not waiting for a hello message, reset the retry fail count
if (this._currentState != STATE_WAITING_FOR_HELLO) {
debug('Reseting _retryFailCount and _pingIntervalRetryTimes');
this._retryFailCount = 0;
this._pingIntervalRetryTimes = {};
}
let doNotHandle = false;
if ((message === '{}') ||
(reply.messageType === undefined) ||
(reply.messageType === "ping") ||
(typeof reply.messageType != "string")) {
debug('Pong received');
this._calculateAdaptivePing(false);
doNotHandle = true;
}
// Reset the ping timer. Note: This path is executed at every step of the
// handshake, so this alarm does not need to be set explicitly at startup.
this._setAlarm(prefs.get("pingInterval"));
// If it is a ping, do not handle the message.
if (doNotHandle) {
return;
}
// A whitelist of protocol handlers. Add to these if new messages are added
// in the protocol.
let handlers = ["Hello", "Register", "Notification"];
// Build up the handler name to call from messageType.
// e.g. messageType == "register" -> _handleRegisterReply.
let handlerName = reply.messageType[0].toUpperCase() +
reply.messageType.slice(1).toLowerCase();
if (handlers.indexOf(handlerName) == -1) {
debug("No whitelisted handler " + handlerName + ". messageType: " +
reply.messageType);
return;
}
let handler = "_handle" + handlerName + "Reply";
if (typeof this[handler] !== "function") {
debug("Handler whitelisted but not implemented! " + handler);
return;
}
this[handler](reply);
},
/**
* The websocket should never be closed. Since we don't call ws.close(),
* _wsOnStop() receives error code NS_BASE_STREAM_CLOSED (see comment in that
* function), which calls reconnect and re-establishes the WebSocket
* connection.
*
* If the server said it'll use UDP for wakeup, we set _willBeWokenUpByUDP
* and stop reconnecting in _wsOnStop().
*/
_wsOnServerClose: function(context, aStatusCode, aReason) {
debug("wsOnServerClose() " + aStatusCode + " " + aReason);
// Switch over to UDP.
if (aStatusCode == kUDP_WAKEUP_WS_STATUS_CODE) {
debug("Server closed with promise to wake up");
this._willBeWokenUpByUDP = true;
// TODO: there should be no pending requests
}
},
/**
* This method should be called only if the device is on a mobile network!
*/
_listenForUDPWakeup: function() {
debug("listenForUDPWakeup()");
if (this._udpServer) {
debug("UDP Server already running");
return;
}
if (!prefs.get("udp.wakeupEnabled")) {
debug("UDP support disabled");
return;
}
this._udpServer = Cc["@mozilla.org/network/udp-socket;1"]
.createInstance(Ci.nsIUDPSocket);
this._udpServer.init(-1, false, Services.scriptSecurityManager.getSystemPrincipal());
this._udpServer.asyncListen(this);
debug("listenForUDPWakeup listening on " + this._udpServer.port);
return this._udpServer.port;
},
/**
* Called by UDP Server Socket. As soon as a ping is recieved via UDP,
* reconnect the WebSocket and get the actual data.
*/
onPacketReceived: function(aServ, aMessage) {
debug("Recv UDP datagram on port: " + this._udpServer.port);
this._beginWSSetup();
},
/**
* Called by UDP Server Socket if the socket was closed for some reason.
*
* If this happens, we reconnect the WebSocket to not miss out on
* notifications.
*/
onStopListening: function(aServ, aStatus) {
debug("UDP Server socket was shutdown. Status: " + aStatus);
this._udpServer = undefined;
this._beginWSSetup();
},
/**
* Returns information about MCC-MNC and the IP of the current connection.
*/
_getNetworkInformation: function() {
debug("getNetworkInformation()");
try {
if (!prefs.get("udp.wakeupEnabled")) {
debug("UDP support disabled, we do not send any carrier info");
throw new Error("UDP disabled");
}
let nm = Cc["@mozilla.org/network/manager;1"].getService(Ci.nsINetworkManager);
if (nm.activeNetworkInfo &&
nm.activeNetworkInfo.type == Ci.nsINetworkInfo.NETWORK_TYPE_MOBILE) {
let iccService = Cc["@mozilla.org/icc/iccservice;1"].getService(Ci.nsIIccService);
// TODO: Bug 927721 - PushService for multi-sim
// In Multi-sim, there is more than one client in iccService. Each
// client represents a icc handle. To maintain backward compatibility
// with single sim, we always use client 0 for now. Adding support
// for multiple sim will be addressed in bug 927721, if needed.
let clientId = 0;
let icc = iccService.getIccByServiceId(clientId);
let iccInfo = icc && icc.iccInfo;
if (iccInfo) {
debug("Running on mobile data");
let ips = {};
let prefixLengths = {};
nm.activeNetworkInfo.getAddresses(ips, prefixLengths);
return {
mcc: iccInfo.mcc,
mnc: iccInfo.mnc,
ip: ips.value[0]
}
}
}
} catch (e) {
debug("Error recovering mobile network information: " + e);
}
debug("Running on wifi");
return {
mcc: 0,
mnc: 0,
ip: undefined
};
},
/**
* Get mobile network information to decide if the client is capable of being
* woken up by UDP (which currently just means having an mcc and mnc along
* with an IP, and optionally a netid).
*/
_getNetworkState: function(callback) {
debug("getNetworkState()");
if (typeof callback !== 'function') {
throw new Error("No callback method. Aborting push agent !");
}
var networkInfo = this._getNetworkInformation();
if (networkInfo.ip) {
this._getMobileNetworkId(networkInfo, function(netid) {
debug("Recovered netID = " + netid);
callback({
mcc: networkInfo.mcc,
mnc: networkInfo.mnc,
ip: networkInfo.ip,
netid: netid
});
});
} else {
callback(networkInfo);
}
},
// utility function used to add/remove observers in init() and shutdown()
_getNetworkStateChangeEventName: function() {
try {
Cc["@mozilla.org/network/manager;1"].getService(Ci.nsINetworkManager);
return "network-active-changed";
} catch (e) {
return "network:offline-status-changed";
}
},
/*
* Get the mobile network ID (netid)
*
* @param networkInfo
* Network information object { mcc, mnc, ip, port }
* @param callback
* Callback function to invoke with the netid or null if not found
*/
_getMobileNetworkId: function(networkInfo, callback) {
if (typeof callback !== 'function') {
return;
}
function queryDNSForDomain(domain) {
debug("[_getMobileNetworkId:queryDNSForDomain] Querying DNS for " +
domain);
let netIDDNSListener = {
onLookupComplete: function(aRequest, aRecord, aStatus) {
if (aRecord) {
let netid = aRecord.getNextAddrAsString();
debug("[_getMobileNetworkId:queryDNSForDomain] NetID found: " +
netid);
callback(netid);
} else {
debug("[_getMobileNetworkId:queryDNSForDomain] NetID not found");
callback(null);
}
}
};
gDNSService.asyncResolve(domain, 0, netIDDNSListener,
threadManager.currentThread);
return [];
}
debug("[_getMobileNetworkId:queryDNSForDomain] Getting mobile network ID");
let netidAddress = "wakeup.mnc" + ("00" + networkInfo.mnc).slice(-3) +
".mcc" + ("00" + networkInfo.mcc).slice(-3) + ".3gppnetwork.org";
queryDNSForDomain(netidAddress, callback);
}
}