/* Copyright 2012 Mozilla Foundation and Mozilla contributors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ "use strict"; const {classes: Cc, interfaces: Ci, utils: Cu, results: Cr} = Components; Cu.import("resource://gre/modules/XPCOMUtils.jsm"); Cu.import("resource://gre/modules/Services.jsm"); Cu.import("resource://gre/modules/Sntp.jsm"); Cu.import("resource://gre/modules/systemlibs.js"); Cu.import("resource://gre/modules/Promise.jsm"); Cu.import("resource://gre/modules/FileUtils.jsm"); XPCOMUtils.defineLazyGetter(this, "RIL", function () { let obj = {}; Cu.import("resource://gre/modules/ril_consts.js", obj); return obj; }); // Ril quirk to attach data registration on demand. let RILQUIRKS_DATA_REGISTRATION_ON_DEMAND = libcutils.property_get("ro.moz.ril.data_reg_on_demand", "false") == "true"; // Ril quirk to control the uicc/data subscription. let RILQUIRKS_SUBSCRIPTION_CONTROL = libcutils.property_get("ro.moz.ril.subscription_control", "false") == "true"; // Ril quirk to always turn the radio off for the client without SIM card // except hw default client. let RILQUIRKS_RADIO_OFF_WO_CARD = libcutils.property_get("ro.moz.ril.radio_off_wo_card", "false") == "true"; // Ril quirk to enable IPv6 protocol/roaming protocol in APN settings. let RILQUIRKS_HAVE_IPV6 = libcutils.property_get("ro.moz.ril.ipv6", "false") == "true"; const RADIOINTERFACELAYER_CID = Components.ID("{2d831c8d-6017-435b-a80c-e5d422810cea}"); const RADIOINTERFACE_CID = Components.ID("{6a7c91f0-a2b3-4193-8562-8969296c0b54}"); const RILNETWORKINTERFACE_CID = Components.ID("{3bdd52a9-3965-4130-b569-0ac5afed045e}"); const NS_XPCOM_SHUTDOWN_OBSERVER_ID = "xpcom-shutdown"; const kNetworkConnStateChangedTopic = "network-connection-state-changed"; const kSmsReceivedObserverTopic = "sms-received"; const kSilentSmsReceivedObserverTopic = "silent-sms-received"; const kSmsSendingObserverTopic = "sms-sending"; const kSmsSentObserverTopic = "sms-sent"; const kSmsFailedObserverTopic = "sms-failed"; const kSmsDeliverySuccessObserverTopic = "sms-delivery-success"; const kSmsDeliveryErrorObserverTopic = "sms-delivery-error"; const kMozSettingsChangedObserverTopic = "mozsettings-changed"; const kSysMsgListenerReadyObserverTopic = "system-message-listener-ready"; const kSysClockChangeObserverTopic = "system-clock-change"; const kScreenStateChangedTopic = "screen-state-changed"; const kSettingsClockAutoUpdateEnabled = "time.clock.automatic-update.enabled"; const kSettingsClockAutoUpdateAvailable = "time.clock.automatic-update.available"; const kSettingsTimezoneAutoUpdateEnabled = "time.timezone.automatic-update.enabled"; const kSettingsTimezoneAutoUpdateAvailable = "time.timezone.automatic-update.available"; const NS_PREFBRANCH_PREFCHANGE_TOPIC_ID = "nsPref:changed"; const kPrefRilNumRadioInterfaces = "ril.numRadioInterfaces"; const kPrefRilDebuggingEnabled = "ril.debugging.enabled"; const DOM_MOBILE_MESSAGE_DELIVERY_RECEIVED = "received"; const DOM_MOBILE_MESSAGE_DELIVERY_SENDING = "sending"; const DOM_MOBILE_MESSAGE_DELIVERY_SENT = "sent"; const DOM_MOBILE_MESSAGE_DELIVERY_ERROR = "error"; const RADIO_POWER_OFF_TIMEOUT = 30000; const SMS_HANDLED_WAKELOCK_TIMEOUT = 5000; const HW_DEFAULT_CLIENT_ID = 0; const INT32_MAX = 2147483647; const NETWORK_TYPE_UNKNOWN = Ci.nsINetworkInterface.NETWORK_TYPE_UNKNOWN; const NETWORK_TYPE_WIFI = Ci.nsINetworkInterface.NETWORK_TYPE_WIFI; const NETWORK_TYPE_MOBILE = Ci.nsINetworkInterface.NETWORK_TYPE_MOBILE; const NETWORK_TYPE_MOBILE_MMS = Ci.nsINetworkInterface.NETWORK_TYPE_MOBILE_MMS; const NETWORK_TYPE_MOBILE_SUPL = Ci.nsINetworkInterface.NETWORK_TYPE_MOBILE_SUPL; const NETWORK_TYPE_MOBILE_IMS = Ci.nsINetworkInterface.NETWORK_TYPE_MOBILE_IMS; const NETWORK_TYPE_MOBILE_DUN = Ci.nsINetworkInterface.NETWORK_TYPE_MOBILE_DUN; const RIL_IPC_ICCMANAGER_MSG_NAMES = [ "RIL:GetRilContext", "RIL:SendStkResponse", "RIL:SendStkMenuSelection", "RIL:SendStkTimerExpiration", "RIL:SendStkEventDownload", "RIL:GetCardLockEnabled", "RIL:UnlockCardLock", "RIL:SetCardLockEnabled", "RIL:ChangeCardLockPassword", "RIL:GetCardLockRetryCount", "RIL:IccOpenChannel", "RIL:IccExchangeAPDU", "RIL:IccCloseChannel", "RIL:ReadIccContacts", "RIL:UpdateIccContact", "RIL:RegisterIccMsg", "RIL:MatchMvno" ]; // set to true in ril_consts.js to see debug messages var DEBUG = RIL.DEBUG_RIL; function updateDebugFlag() { // Read debug setting from pref let debugPref; try { debugPref = Services.prefs.getBoolPref(kPrefRilDebuggingEnabled); } catch (e) { debugPref = false; } DEBUG = RIL.DEBUG_RIL || debugPref; } updateDebugFlag(); function debug(s) { dump("-*- RadioInterfaceLayer: " + s + "\n"); } XPCOMUtils.defineLazyServiceGetter(this, "gPowerManagerService", "@mozilla.org/power/powermanagerservice;1", "nsIPowerManagerService"); XPCOMUtils.defineLazyServiceGetter(this, "gMobileMessageService", "@mozilla.org/mobilemessage/mobilemessageservice;1", "nsIMobileMessageService"); XPCOMUtils.defineLazyServiceGetter(this, "gSmsService", "@mozilla.org/sms/smsservice;1", "nsISmsService"); XPCOMUtils.defineLazyServiceGetter(this, "gMobileMessageDatabaseService", "@mozilla.org/mobilemessage/rilmobilemessagedatabaseservice;1", "nsIRilMobileMessageDatabaseService"); XPCOMUtils.defineLazyServiceGetter(this, "ppmm", "@mozilla.org/parentprocessmessagemanager;1", "nsIMessageBroadcaster"); XPCOMUtils.defineLazyServiceGetter(this, "gSettingsService", "@mozilla.org/settingsService;1", "nsISettingsService"); XPCOMUtils.defineLazyServiceGetter(this, "gSystemMessenger", "@mozilla.org/system-message-internal;1", "nsISystemMessagesInternal"); XPCOMUtils.defineLazyServiceGetter(this, "gNetworkManager", "@mozilla.org/network/manager;1", "nsINetworkManager"); XPCOMUtils.defineLazyServiceGetter(this, "gTimeService", "@mozilla.org/time/timeservice;1", "nsITimeService"); XPCOMUtils.defineLazyServiceGetter(this, "gSystemWorkerManager", "@mozilla.org/telephony/system-worker-manager;1", "nsISystemWorkerManager"); XPCOMUtils.defineLazyServiceGetter(this, "gTelephonyService", "@mozilla.org/telephony/telephonyservice;1", "nsIGonkTelephonyService"); XPCOMUtils.defineLazyServiceGetter(this, "gMobileConnectionService", "@mozilla.org/mobileconnection/mobileconnectionservice;1", "nsIGonkMobileConnectionService"); XPCOMUtils.defineLazyServiceGetter(this, "gCellBroadcastService", "@mozilla.org/cellbroadcast/gonkservice;1", "nsIGonkCellBroadcastService"); XPCOMUtils.defineLazyServiceGetter(this, "gSmsMessenger", "@mozilla.org/ril/system-messenger-helper;1", "nsISmsMessenger"); XPCOMUtils.defineLazyServiceGetter(this, "gIccMessenger", "@mozilla.org/ril/system-messenger-helper;1", "nsIIccMessenger"); XPCOMUtils.defineLazyGetter(this, "gStkCmdFactory", function() { let stk = {}; Cu.import("resource://gre/modules/StkProactiveCmdFactory.jsm", stk); return stk.StkProactiveCmdFactory; }); XPCOMUtils.defineLazyGetter(this, "WAP", function() { let wap = {}; Cu.import("resource://gre/modules/WapPushManager.js", wap); return wap; }); XPCOMUtils.defineLazyGetter(this, "PhoneNumberUtils", function() { let ns = {}; Cu.import("resource://gre/modules/PhoneNumberUtils.jsm", ns); return ns.PhoneNumberUtils; }); XPCOMUtils.defineLazyGetter(this, "gMessageManager", function() { return { QueryInterface: XPCOMUtils.generateQI([Ci.nsIMessageListener, Ci.nsIObserver]), ril: null, // Manage message targets in terms of topic. Only the authorized and // registered contents can receive related messages. targetsByTopic: {}, topics: [], targetMessageQueue: [], ready: false, init: function(ril) { this.ril = ril; Services.obs.addObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID, false); Services.obs.addObserver(this, kSysMsgListenerReadyObserverTopic, false); this._registerMessageListeners(); }, _shutdown: function() { this.ril = null; Services.obs.removeObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID); this._unregisterMessageListeners(); }, _registerMessageListeners: function() { ppmm.addMessageListener("child-process-shutdown", this); for (let msgName of RIL_IPC_ICCMANAGER_MSG_NAMES) { ppmm.addMessageListener(msgName, this); } }, _unregisterMessageListeners: function() { ppmm.removeMessageListener("child-process-shutdown", this); for (let msgName of RIL_IPC_ICCMANAGER_MSG_NAMES) { ppmm.removeMessageListener(msgName, this); } ppmm = null; }, _registerMessageTarget: function(topic, target) { let targets = this.targetsByTopic[topic]; if (!targets) { targets = this.targetsByTopic[topic] = []; let list = this.topics; if (list.indexOf(topic) == -1) { list.push(topic); } } if (targets.indexOf(target) != -1) { if (DEBUG) debug("Already registered this target!"); return; } targets.push(target); if (DEBUG) debug("Registered " + topic + " target: " + target); }, _unregisterMessageTarget: function(topic, target) { if (topic == null) { // Unregister the target for every topic when no topic is specified. for (let type of this.topics) { this._unregisterMessageTarget(type, target); } return; } // Unregister the target for a specified topic. let targets = this.targetsByTopic[topic]; if (!targets) { return; } let index = targets.indexOf(target); if (index != -1) { targets.splice(index, 1); if (DEBUG) debug("Unregistered " + topic + " target: " + target); } }, _enqueueTargetMessage: function(topic, message, options) { let msg = { topic : topic, message : message, options : options }; // Remove previous queued message with the same message type and client Id // , only one message per (message type + client Id) is allowed in queue. let messageQueue = this.targetMessageQueue; for(let i = 0; i < messageQueue.length; i++) { if (messageQueue[i].message === message && messageQueue[i].options.clientId === options.clientId) { messageQueue.splice(i, 1); break; } } messageQueue.push(msg); }, _sendTargetMessage: function(topic, message, options) { if (!this.ready) { this._enqueueTargetMessage(topic, message, options); return; } let targets = this.targetsByTopic[topic]; if (!targets) { return; } for (let target of targets) { target.sendAsyncMessage(message, options); } }, _resendQueuedTargetMessage: function() { this.ready = true; // Here uses this._sendTargetMessage() to resend message, which will // enqueue message if listener is not ready. // So only resend after listener is ready, or it will cause infinate loop and // hang the system. // Dequeue and resend messages. for each (let msg in this.targetMessageQueue) { this._sendTargetMessage(msg.topic, msg.message, msg.options); } this.targetMessageQueue = null; }, /** * nsIMessageListener interface methods. */ receiveMessage: function(msg) { if (DEBUG) debug("Received '" + msg.name + "' message from content process"); if (msg.name == "child-process-shutdown") { // By the time we receive child-process-shutdown, the child process has // already forgotten its permissions so we need to unregister the target // for every permission. this._unregisterMessageTarget(null, msg.target); return null; } if (RIL_IPC_ICCMANAGER_MSG_NAMES.indexOf(msg.name) != -1) { if (!msg.target.assertPermission("mobileconnection")) { if (DEBUG) { debug("IccManager message " + msg.name + " from a content process with no 'mobileconnection' privileges."); } return null; } } else { if (DEBUG) debug("Ignoring unknown message type: " + msg.name); return null; } switch (msg.name) { case "RIL:RegisterIccMsg": this._registerMessageTarget("icc", msg.target); return null; } let clientId = msg.json.clientId || 0; let radioInterface = this.ril.getRadioInterface(clientId); if (!radioInterface) { if (DEBUG) debug("No such radio interface: " + clientId); return null; } return radioInterface.receiveMessage(msg); }, /** * nsIObserver interface methods. */ observe: function(subject, topic, data) { switch (topic) { case kSysMsgListenerReadyObserverTopic: Services.obs.removeObserver(this, kSysMsgListenerReadyObserverTopic); this._resendQueuedTargetMessage(); break; case NS_XPCOM_SHUTDOWN_OBSERVER_ID: this._shutdown(); break; } }, sendIccMessage: function(message, clientId, data) { this._sendTargetMessage("icc", message, { clientId: clientId, data: data }); } }; }); XPCOMUtils.defineLazyGetter(this, "gRadioEnabledController", function() { let _ril = null; let _pendingMessages = []; // For queueing "setRadioEnabled" message. let _isProcessingPending = false; let _timer = null; let _request = null; let _deactivatingDeferred = {}; let _initializedCardState = {}; let _allCardStateInitialized = !RILQUIRKS_RADIO_OFF_WO_CARD; return { init: function(ril) { _ril = ril; }, receiveCardState: function(clientId) { if (_allCardStateInitialized) { return; } if (DEBUG) debug("RadioControl: receive cardState from " + clientId); _initializedCardState[clientId] = true; if (Object.keys(_initializedCardState).length == _ril.numRadioInterfaces) { _allCardStateInitialized = true; this._startProcessingPending(); } }, setRadioEnabled: function(clientId, data, callback) { if (DEBUG) debug("setRadioEnabled: " + clientId + ": " + JSON.stringify(data)); let message = { clientId: clientId, data: data, callback: callback }; _pendingMessages.push(message); this._startProcessingPending(); }, isDeactivatingDataCalls: function() { return _request !== null; }, finishDeactivatingDataCalls: function(clientId) { if (DEBUG) debug("RadioControl: finishDeactivatingDataCalls: " + clientId); let deferred = _deactivatingDeferred[clientId]; if (deferred) { deferred.resolve(); } }, notifyRadioStateChanged: function(clientId, radioState) { gMobileConnectionService.notifyRadioStateChanged(clientId, radioState); }, _startProcessingPending: function() { if (!_isProcessingPending) { if (DEBUG) debug("RadioControl: start dequeue"); _isProcessingPending = true; this._processNextMessage(); } }, _processNextMessage: function() { if (_pendingMessages.length === 0 || !_allCardStateInitialized) { if (DEBUG) debug("RadioControl: stop dequeue"); _isProcessingPending = false; return; } let msg = _pendingMessages.shift(); this._handleMessage(msg); }, _getNumCards: function() { let numCards = 0; for (let i = 0, N = _ril.numRadioInterfaces; i < N; ++i) { if (_ril.getRadioInterface(i).isCardPresent()) { numCards++; } } return numCards; }, _isRadioAbleToEnableAtClient: function(clientId, numCards) { if (!RILQUIRKS_RADIO_OFF_WO_CARD) { return true; } // We could only turn on the radio for clientId if // 1. a SIM card is presented or // 2. it is the default clientId and there is no any SIM card at any client. if (_ril.getRadioInterface(clientId).isCardPresent()) { return true; } numCards = numCards == null ? this._getNumCards() : numCards; if (clientId === HW_DEFAULT_CLIENT_ID && numCards === 0) { return true; } return false; }, _isValidStateForSetRadioEnabled: function(radioState) { return radioState == Ci.nsIMobileConnection.MOBILE_RADIO_STATE_ENABLED || radioState == Ci.nsIMobileConnection.MOBILE_RADIO_STATE_DISABLED; }, _isDummyForSetRadioEnabled: function(radioState, data) { return (radioState == Ci.nsIMobileConnection.MOBILE_RADIO_STATE_ENABLED && data.enabled) || (radioState == Ci.nsIMobileConnection.MOBILE_RADIO_STATE_DISABLED && !data.enabled); }, _handleMessage: function(message) { if (DEBUG) debug("RadioControl: handleMessage: " + JSON.stringify(message)); let clientId = message.clientId || 0; let connection = gMobileConnectionService.getItemByServiceId(clientId); let radioState = connection && connection.radioState; if (!this._isValidStateForSetRadioEnabled(radioState)) { message.data.errorMsg = "InvalidStateError"; message.callback(message.data); this._processNextMessage(); return; } if (this._isDummyForSetRadioEnabled(radioState, message.data)) { message.callback(message.data); this._processNextMessage(); return; } if (message.data.enabled) { if (this._isRadioAbleToEnableAtClient(clientId)) { this._setRadioEnabledInternal(message); } else { // Not really do it but respond success. message.callback(message.data); } this._processNextMessage(); } else { _request = this._setRadioEnabledInternal.bind(this, message); // In 2G network, modem takes 35+ seconds to process deactivate data // call request if device has active voice call (please see bug 964974 // for more details). Therefore we should hangup all active voice calls // first. And considering some DSDS architecture, toggling one radio may // toggle both, so we send hangUpAll to all clients. for (let i = 0, N = _ril.numRadioInterfaces; i < N; ++i) { let iface = _ril.getRadioInterface(i); iface.workerMessenger.send("hangUpAll"); } // In some DSDS architecture with only one modem, toggling one radio may // toggle both. Therefore, for safely turning off, we should first // explicitly deactivate all data calls from all clients. this._deactivateDataCalls().then(() => { if (DEBUG) debug("RadioControl: deactivation done"); this._executeRequest(); }); this._createTimer(); } }, _setRadioEnabledInternal: function(message) { let clientId = message.clientId || 0; let enabled = message.data.enabled || false; let radioInterface = _ril.getRadioInterface(clientId); this.notifyRadioStateChanged(clientId, enabled ? Ci.nsIMobileConnection.MOBILE_RADIO_STATE_ENABLING : Ci.nsIMobileConnection.MOBILE_RADIO_STATE_DISABLING); radioInterface.workerMessenger.send("setRadioEnabled", message.data, (function(response) { if (response.errorMsg) { // Request fails. Rollback to the original radioState. this.notifyRadioStateChanged(clientId, enabled ? Ci.nsIMobileConnection.MOBILE_RADIO_STATE_DISABLED : Ci.nsIMobileConnection.MOBILE_RADIO_STATE_ENABLED); } message.callback(response); return false; }).bind(this)); }, _deactivateDataCalls: function() { if (DEBUG) debug("RadioControl: deactivating data calls..."); _deactivatingDeferred = {}; let promise = Promise.resolve(); for (let i = 0, N = _ril.numRadioInterfaces; i < N; ++i) { promise = promise.then(this._deactivateDataCallsForClient(i)); } return promise; }, _deactivateDataCallsForClient: function(clientId) { return function() { let deferred = _deactivatingDeferred[clientId] = Promise.defer(); let dataConnectionHandler = gDataConnectionManager.getConnectionHandler(clientId); dataConnectionHandler.deactivateDataCalls(); return deferred.promise; }; }, _createTimer: function() { if (!_timer) { _timer = Cc["@mozilla.org/timer;1"].createInstance(Ci.nsITimer); } _timer.initWithCallback(this._executeRequest.bind(this), RADIO_POWER_OFF_TIMEOUT, Ci.nsITimer.TYPE_ONE_SHOT); }, _cancelTimer: function() { if (_timer) { _timer.cancel(); } }, _executeRequest: function() { if (typeof _request === "function") { if (DEBUG) debug("RadioControl: executeRequest"); this._cancelTimer(); _request(); _request = null; } this._processNextMessage(); }, }; }); XPCOMUtils.defineLazyGetter(this, "gDataConnectionManager", function () { return { QueryInterface: XPCOMUtils.generateQI([Ci.nsIObserver, Ci.nsISettingsServiceCallback]), _connectionHandlers: null, // Flag to determine the data state to start with when we boot up. It // corresponds to the 'ril.data.enabled' setting from the UI. _dataEnabled: false, // Flag to record the default client id for data call. It corresponds to // the 'ril.data.defaultServiceId' setting from the UI. _dataDefaultClientId: -1, // Flag to record the current default client id for data call. // It differs from _dataDefaultClientId in that it is set only when // the switch of client id process is done. _currentDataClientId: -1, // Pending function to execute when we are notified that another data call has // been disconnected. _pendingDataCallRequest: null, debug: function(s) { dump("-*- DataConnectionManager: " + s + "\n"); }, init: function(ril) { if (!ril) { return; } this._connectionHandlers = []; for (let clientId = 0; clientId < ril.numRadioInterfaces; clientId++) { let radioInterface = ril.getRadioInterface(clientId); this._connectionHandlers.push( new DataConnectionHandler(clientId, radioInterface)); } let lock = gSettingsService.createLock(); // Read the APN data from the settings DB. lock.get("ril.data.apnSettings", this); // Read the data enabled setting from DB. lock.get("ril.data.enabled", this); lock.get("ril.data.roaming_enabled", this); // Read the default client id for data call. lock.get("ril.data.defaultServiceId", this); Services.obs.addObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID, false); Services.obs.addObserver(this, kMozSettingsChangedObserverTopic, false); }, getConnectionHandler: function(clientId) { return this._connectionHandlers[clientId]; }, isSwitchingDataClientId: function() { return this._pendingDataCallRequest !== null; }, notifyDataCallStateChange: function(clientId) { if (!this.isSwitchingDataClientId() || clientId != this._currentDataClientId) { return; } let connHandler = this._connectionHandlers[this._currentDataClientId]; if (connHandler.allDataDisconnected() && typeof this._pendingDataCallRequest === "function") { if (DEBUG) { this.debug("All data calls disconnected, process pending data settings."); } this._pendingDataCallRequest(); this._pendingDataCallRequest = null; } }, _handleDataClientIdChange: function(newDefault) { if (this._dataDefaultClientId === newDefault) { return; } this._dataDefaultClientId = newDefault; // This is to handle boot up stage. if (this._currentDataClientId == -1) { this._currentDataClientId = this._dataDefaultClientId; let connHandler = this._connectionHandlers[this._currentDataClientId]; let radioInterface = connHandler.radioInterface; if (RILQUIRKS_DATA_REGISTRATION_ON_DEMAND || RILQUIRKS_SUBSCRIPTION_CONTROL) { radioInterface.setDataRegistration(true); } if (this._dataEnabled) { let settings = connHandler.dataCallSettings; settings.oldEnabled = settings.enabled; settings.enabled = true; connHandler.updateRILNetworkInterface(); } return; } let oldConnHandler = this._connectionHandlers[this._currentDataClientId]; let oldIface = oldConnHandler.radioInterface; let oldSettings = oldConnHandler.dataCallSettings; let newConnHandler = this._connectionHandlers[this._dataDefaultClientId]; let newIface = newConnHandler.radioInterface; let newSettings = newConnHandler.dataCallSettings; let applyPendingDataSettings = (function() { if (RILQUIRKS_DATA_REGISTRATION_ON_DEMAND || RILQUIRKS_SUBSCRIPTION_CONTROL) { oldIface.setDataRegistration(false) .then(() => { if (this._dataEnabled) { newSettings.oldEnabled = newSettings.enabled; newSettings.enabled = true; } this._currentDataClientId = this._dataDefaultClientId; return newIface.setDataRegistration(true); }) .then(() => newConnHandler.updateRILNetworkInterface()); return; } if (this._dataEnabled) { newSettings.oldEnabled = newSettings.enabled; newSettings.enabled = true; } this._currentDataClientId = this._dataDefaultClientId; newConnHandler.updateRILNetworkInterface(); }).bind(this); if (this._dataEnabled) { oldSettings.oldEnabled = oldSettings.enabled; oldSettings.enabled = false; } if (oldConnHandler.deactivateDataCalls()) { this._pendingDataCallRequest = applyPendingDataSettings; if (DEBUG) { this.debug("_handleDataClientIdChange: existing data call(s) active" + ", wait for them to get disconnected."); } return; } applyPendingDataSettings(); }, _shutdown: function() { for (let handler of this._connectionHandlers) { handler.shutdown(); } this._connectionHandlers = null; Services.obs.removeObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID); Services.obs.removeObserver(this, kMozSettingsChangedObserverTopic); }, /** * nsISettingsServiceCallback */ handle: function(name, result) { switch(name) { case "ril.data.apnSettings": if (DEBUG) { this.debug("'ril.data.apnSettings' is now " + JSON.stringify(result)); } if (!result) { break; } for (let clientId in this._connectionHandlers) { let handler = this._connectionHandlers[clientId]; let apnSetting = result[clientId]; if (handler && apnSetting) { handler.updateApnSettings(apnSetting); handler.updateRILNetworkInterface(); } } break; case "ril.data.enabled": if (DEBUG) { this.debug("'ril.data.enabled' is now " + result); } if (this._dataEnabled === result) { break; } this._dataEnabled = result; if (DEBUG) { this.debug("Default id for data call: " + this._dataDefaultClientId); } if (this._dataDefaultClientId === -1) { // We haven't got the default id for data from db. break; } let connHandler = this._connectionHandlers[this._dataDefaultClientId]; let settings = connHandler.dataCallSettings; settings.oldEnabled = settings.enabled; settings.enabled = result; connHandler.updateRILNetworkInterface(); break; case "ril.data.roaming_enabled": if (DEBUG) { this.debug("'ril.data.roaming_enabled' is now " + result); this.debug("Default id for data call: " + this._dataDefaultClientId); } for (let clientId = 0; clientId < this._connectionHandlers.length; clientId++) { let connHandler = this._connectionHandlers[clientId]; let settings = connHandler.dataCallSettings; settings.roamingEnabled = Array.isArray(result) ? result[clientId] : result; } if (this._dataDefaultClientId === -1) { // We haven't got the default id for data from db. break; } this._connectionHandlers[this._dataDefaultClientId].updateRILNetworkInterface(); break; case "ril.data.defaultServiceId": result = result || 0; if (DEBUG) { this.debug("'ril.data.defaultServiceId' is now " + result); } this._handleDataClientIdChange(result); break; } }, handleError: function(errorMessage) { if (DEBUG) { this.debug("There was an error while reading RIL settings."); } }, /** * nsIObserver interface methods. */ observe: function(subject, topic, data) { switch (topic) { case kMozSettingsChangedObserverTopic: if ("wrappedJSObject" in subject) { subject = subject.wrappedJSObject; } this.handle(subject.key, subject.value); break; case NS_XPCOM_SHUTDOWN_OBSERVER_ID: this._shutdown(); break; } }, }; }); // Initialize shared preference "ril.numRadioInterfaces" according to system // property. try { Services.prefs.setIntPref(kPrefRilNumRadioInterfaces, (function() { // When Gonk property "ro.moz.ril.numclients" is not set, return 1; if // explicitly set to any number larger-equal than 0, return num; else, return // 1 for compatibility. try { let numString = libcutils.property_get("ro.moz.ril.numclients", "1"); let num = parseInt(numString, 10); if (num >= 0) { return num; } } catch (e) {} return 1; })()); } catch (e) {} function IccInfo() {} IccInfo.prototype = { QueryInterface: XPCOMUtils.generateQI([Ci.nsIIccInfo]), // nsIIccInfo iccType: null, iccid: null, mcc: null, mnc: null, spn: null, isDisplayNetworkNameRequired: null, isDisplaySpnRequired: null }; function GsmIccInfo() {} GsmIccInfo.prototype = { __proto__: IccInfo.prototype, QueryInterface: XPCOMUtils.generateQI([Ci.nsIGsmIccInfo, Ci.nsIIccInfo]), // nsIGsmIccInfo msisdn: null }; function CdmaIccInfo() {} CdmaIccInfo.prototype = { __proto__: IccInfo.prototype, QueryInterface: XPCOMUtils.generateQI([Ci.nsICdmaIccInfo, Ci.nsIIccInfo]), // nsICdmaIccInfo mdn: null, prlVersion: 0 }; function DataConnectionHandler(clientId, radioInterface) { // Initial owning attributes. this.clientId = clientId; this.radioInterface = radioInterface; this.dataCallSettings = { oldEnabled: false, enabled: false, roamingEnabled: false }; this._dataCalls = []; // This map is used to collect all the apn types and its corresponding // RILNetworkInterface. this.dataNetworkInterfaces = new Map(); } DataConnectionHandler.prototype = { clientId: 0, radioInterface: null, // Data calls setting. dataCallSettings: null, dataNetworkInterfaces: null, _dataCalls: null, // Apn settings to be setup after data call are cleared. _pendingApnSettings: null, debug: function(s) { dump("-*- DataConnectionHandler[" + this.clientId + "]: " + s + "\n"); }, shutdown: function() { // Shutdown all RIL network interfaces this.dataNetworkInterfaces.forEach(function(networkInterface) { gNetworkManager.unregisterNetworkInterface(networkInterface); networkInterface.shutdown(); networkInterface = null; }); this.dataNetworkInterfaces.clear(); this._dataCalls = []; this.clientId = null; this.radioInterface = null; }, /** * Check if we get all necessary APN data. */ _validateApnSetting: function(apnSetting) { return (apnSetting && apnSetting.apn && apnSetting.types && apnSetting.types.length); }, _convertApnType: function(apnType) { switch(apnType) { case "default": return NETWORK_TYPE_MOBILE; case "mms": return NETWORK_TYPE_MOBILE_MMS; case "supl": return NETWORK_TYPE_MOBILE_SUPL; case "ims": return NETWORK_TYPE_MOBILE_IMS; case "dun": return NETWORK_TYPE_MOBILE_DUN; default: return NETWORK_TYPE_UNKNOWN; } }, _compareDataCallOptions: function(dataCall, newDataCall) { return dataCall.apnProfile.apn == newDataCall.apn && dataCall.apnProfile.user == newDataCall.user && dataCall.apnProfile.password == newDataCall.passwd && dataCall.chappap == newDataCall.chappap && dataCall.pdptype == newDataCall.pdptype; }, _deliverDataCallMessage: function(name, args) { for (let i = 0; i < this._dataCalls.length; i++) { let datacall = this._dataCalls[i]; // Send message only to the DataCall that matches the data call options. // Currently, args always contain only one datacall info. if (!this._compareDataCallOptions(datacall, args[0])) { continue; } // Do not deliver message to DataCall that contains cid but mistmaches // with the cid in the current message. if (args[0].cid !== undefined && datacall.linkInfo.cid != null && args[0].cid != datacall.linkInfo.cid) { continue; } try { let handler = datacall[name]; if (typeof handler !== "function") { throw new Error("No handler for " + name); } handler.apply(datacall, args); } catch (e) { if (DEBUG) { this.debug("Handler for " + name + " threw an exception: " + e); } } } }, /** * This function will do the following steps: * 1. Clear the cached APN settings in the RIL. * 2. Combine APN, user name, and password as the key of |byApn| object to * refer to the corresponding APN setting. * 3. Use APN type as the index of |byType| object to refer to the * corresponding APN setting. * 4. Create RilNetworkInterface for each APN setting created at step 2. */ _setupApnSettings: function(newApnSettings) { if (!newApnSettings) { return; } if (DEBUG) this.debug("setupApnSettings: " + JSON.stringify(newApnSettings)); // Shutdown all network interfaces and clear data calls. this.dataNetworkInterfaces.forEach(function(networkInterface) { gNetworkManager.unregisterNetworkInterface(networkInterface); networkInterface.shutdown(); networkInterface = null; }); this.dataNetworkInterfaces.clear(); this._dataCalls = []; // Cache the APN settings by APNs and by types in the RIL. for (let inputApnSetting of newApnSettings) { if (!this._validateApnSetting(inputApnSetting)) { continue; } // Use APN type as the key of dataNetworkInterfaces to refer to the // corresponding RILNetworkInterface. for (let i = 0; i < inputApnSetting.types.length; i++) { let apnType = inputApnSetting.types[i]; let networkType = this._convertApnType(apnType); if (networkType === NETWORK_TYPE_UNKNOWN) { if (DEBUG) this.debug("Invalid apn type: " + apnType); continue; } if (DEBUG) this.debug("Preparing RILNetworkInterface for type: " + apnType); // Create DataCall for RILNetworkInterface or reuse one that is shareable. let dataCall; for (let i = 0; i < this._dataCalls.length; i++) { if (this._dataCalls[i].canHandleApn(inputApnSetting)) { if (DEBUG) this.debug("Found shareable DataCall, reusing it."); dataCall = this._dataCalls[i]; break; } } if (!dataCall) { if (DEBUG) this.debug("No shareable DataCall found, creating one."); dataCall = new DataCall(this.clientId, inputApnSetting); this._dataCalls.push(dataCall); } try { let networkInterface = new RILNetworkInterface(this, networkType, inputApnSetting, dataCall); gNetworkManager.registerNetworkInterface(networkInterface); this.dataNetworkInterfaces.set(networkType, networkInterface); } catch (e) { if (DEBUG) { this.debug("Error setting up RILNetworkInterface for type " + apnType + ": " + e); } } } } }, /** * Check if all data is disconnected. */ allDataDisconnected: function() { for (let i = 0; i < this._dataCalls.length; i++) { let dataCall = this._dataCalls[i]; if (dataCall.state != RIL.GECKO_NETWORK_STATE_UNKNOWN && dataCall.state != RIL.GECKO_NETWORK_STATE_DISCONNECTED) { return false; } } return true; }, updateApnSettings: function(newApnSettings) { if (!newApnSettings) { return; } if (this._pendingApnSettings) { // Change of apn settings in process, just update to the newest. this._pengingApnSettings = newApnSettings; return; } let isDeactivatingDataCalls = false; this.dataNetworkInterfaces.forEach(function(networkInterface) { // Clear all existing connections. if (networkInterface.state == RIL.GECKO_NETWORK_STATE_CONNECTED) { networkInterface.disconnect(); isDeactivatingDataCalls = true; } }); if (isDeactivatingDataCalls) { // Defer apn settings setup until all data calls are cleared. this._pendingApnSettings = newApnSettings; return; } this._setupApnSettings(newApnSettings); }, updateRILNetworkInterface: function() { let networkInterface = this.dataNetworkInterfaces.get(NETWORK_TYPE_MOBILE); if (!networkInterface) { if (DEBUG) { this.debug("No network interface for default data."); } return; } let connection = gMobileConnectionService.getItemByServiceId(this.clientId); // This check avoids data call connection if the radio is not ready // yet after toggling off airplane mode. let radioState = connection && connection.radioState; if (radioState != Ci.nsIMobileConnection.MOBILE_RADIO_STATE_ENABLED) { if (DEBUG) { this.debug("RIL is not ready for data connection: radio's not ready"); } return; } // We only watch at "ril.data.enabled" flag changes for connecting or // disconnecting the data call. If the value of "ril.data.enabled" is // true and any of the remaining flags change the setting application // should turn this flag to false and then to true in order to reload // the new values and reconnect the data call. if (this.dataCallSettings.oldEnabled === this.dataCallSettings.enabled) { if (DEBUG) { this.debug("No changes for ril.data.enabled flag. Nothing to do."); } return; } let dataInfo = connection && connection.data; let isRegistered = dataInfo && dataInfo.state == RIL.GECKO_MOBILE_CONNECTION_STATE_REGISTERED; let haveDataConnection = dataInfo && dataInfo.type != RIL.GECKO_MOBILE_CONNECTION_STATE_UNKNOWN; if (!isRegistered || !haveDataConnection) { if (DEBUG) { this.debug("RIL is not ready for data connection: Phone's not " + "registered or doesn't have data connection."); } return; } let wifi_active = false; if (gNetworkManager.active && gNetworkManager.active.type == NETWORK_TYPE_WIFI) { wifi_active = true; } let defaultDataCallConnected = networkInterface.connected; // We have moved part of the decision making into DataCall, the rest will be // moved after Bug 904514 - [meta] NetworkManager enhancement. if (networkInterface.enabled && (!this.dataCallSettings.enabled || (dataInfo.roaming && !this.dataCallSettings.roamingEnabled))) { if (DEBUG) { this.debug("Data call settings: disconnect data call."); } networkInterface.disconnect(); return; } if (networkInterface.enabled && wifi_active) { if (DEBUG) { this.debug("Disconnect data call when Wifi is connected."); } networkInterface.disconnect(); return; } if (!this.dataCallSettings.enabled || defaultDataCallConnected) { if (DEBUG) { this.debug("Data call settings: nothing to do."); } return; } if (dataInfo.roaming && !this.dataCallSettings.roamingEnabled) { if (DEBUG) { this.debug("We're roaming, but data roaming is disabled."); } return; } if (wifi_active) { if (DEBUG) { this.debug("Don't connect data call when Wifi is connected."); } return; } if (this._pendingApnSettings) { if (DEBUG) this.debug("We're changing apn settings, ignore any changes."); return; } if (gRadioEnabledController.isDeactivatingDataCalls()) { // We're changing the radio power currently, ignore any changes. return; } if (DEBUG) { this.debug("Data call settings: connect data call."); } networkInterface.connect(); }, _isMobileNetworkType: function(networkType) { if (networkType === NETWORK_TYPE_MOBILE || networkType === NETWORK_TYPE_MOBILE_MMS || networkType === NETWORK_TYPE_MOBILE_SUPL || networkType === NETWORK_TYPE_MOBILE_IMS || networkType === NETWORK_TYPE_MOBILE_DUN) { return true; } return false; }, getDataCallStateByType: function(networkType) { if (!this._isMobileNetworkType(networkType)) { if (DEBUG) this.debug(networkType + " is not a mobile network type!"); throw Cr.NS_ERROR_INVALID_ARG; } let networkInterface = this.dataNetworkInterfaces.get(networkType); if (!networkInterface) { return RIL.GECKO_NETWORK_STATE_UNKNOWN; } return networkInterface.state; }, setupDataCallByType: function(networkType) { if (DEBUG) { this.debug("setupDataCallByType: " + networkType); } if (!this._isMobileNetworkType(networkType)) { if (DEBUG) this.debug(networkType + " is not a mobile network type!"); throw Cr.NS_ERROR_INVALID_ARG; } let networkInterface = this.dataNetworkInterfaces.get(networkType); if (!networkInterface) { if (DEBUG) { this.debug("No network interface for type: " + networkType); } return; } networkInterface.connect(); }, deactivateDataCallByType: function(networkType) { if (DEBUG) { this.debug("deactivateDataCallByType: " + networkType); } if (!this._isMobileNetworkType(networkType)) { if (DEBUG) this.debug(networkType + " is not a mobile network type!"); throw Cr.NS_ERROR_INVALID_ARG; } let networkInterface = this.dataNetworkInterfaces.get(networkType); if (!networkInterface) { if (DEBUG) { this.debug("No network interface for type: " + networkType); } return; } networkInterface.disconnect(); }, deactivateDataCalls: function() { let dataDisconnecting = false; this.dataNetworkInterfaces.forEach(function(networkInterface) { if (networkInterface.enabled) { if (networkInterface.state == RIL.GECKO_NETWORK_STATE_CONNECTED) { dataDisconnecting = true; } networkInterface.disconnect(); } }); // No data calls exist. It's safe to proceed the pending radio power off // request. if (gRadioEnabledController.isDeactivatingDataCalls() && !dataDisconnecting) { gRadioEnabledController.finishDeactivatingDataCalls(this.clientId); } return dataDisconnecting; }, /** * Handle data errors. */ handleDataCallError: function(message) { // Notify data call error only for data APN let networkInterface = this.dataNetworkInterfaces.get(NETWORK_TYPE_MOBILE); if (networkInterface && networkInterface.enabled) { let dataCall = networkInterface.dataCall; // If there is a cid, compare cid; otherwise it is probably an error on // data call setup. if (message.cid !== undefined) { if (message.cid == dataCall.linkInfo.cid) { gMobileConnectionService.notifyDataError(this.clientId, message); } } else { if (this._compareDataCallOptions(dataCall, message)) { gMobileConnectionService.notifyDataError(this.clientId, message); } } } this._deliverDataCallMessage("dataCallError", [message]); }, /** * Handle data call state changes. */ handleDataCallState: function(datacall) { this._deliverDataCallMessage("dataCallStateChanged", [datacall]); // Process pending radio power off request after all data calls // are disconnected. if (datacall.state == RIL.GECKO_NETWORK_STATE_DISCONNECTED && this.allDataDisconnected()) { if (gRadioEnabledController.isDeactivatingDataCalls()) { if (DEBUG) { this.debug("All data connections are disconnected."); } gRadioEnabledController.finishDeactivatingDataCalls(this.clientId); } if (this._pendingApnSettings) { if (DEBUG) { this.debug("Setup pending apn settings."); } this._setupApnSettings(this._pendingApnSettings); this._pendingApnSettings = null; this.updateRILNetworkInterface(); } if (gDataConnectionManager.isSwitchingDataClientId()) { gDataConnectionManager.notifyDataCallStateChange(this.clientId); } } }, }; function RadioInterfaceLayer() { let workerMessenger = new WorkerMessenger(); workerMessenger.init(); this.setWorkerDebugFlag = workerMessenger.setDebugFlag.bind(workerMessenger); let numIfaces = this.numRadioInterfaces; if (DEBUG) debug(numIfaces + " interfaces"); this.radioInterfaces = []; for (let clientId = 0; clientId < numIfaces; clientId++) { this.radioInterfaces.push(new RadioInterface(clientId, workerMessenger)); } Services.obs.addObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID, false); Services.prefs.addObserver(kPrefRilDebuggingEnabled, this, false); gMessageManager.init(this); gRadioEnabledController.init(this); gDataConnectionManager.init(this); } RadioInterfaceLayer.prototype = { classID: RADIOINTERFACELAYER_CID, classInfo: XPCOMUtils.generateCI({classID: RADIOINTERFACELAYER_CID, classDescription: "RadioInterfaceLayer", interfaces: [Ci.nsIRadioInterfaceLayer]}), QueryInterface: XPCOMUtils.generateQI([Ci.nsIRadioInterfaceLayer, Ci.nsIObserver]), /** * nsIObserver interface methods. */ observe: function(subject, topic, data) { switch (topic) { case NS_XPCOM_SHUTDOWN_OBSERVER_ID: for (let radioInterface of this.radioInterfaces) { radioInterface.shutdown(); } this.radioInterfaces = null; Services.obs.removeObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID); break; case NS_PREFBRANCH_PREFCHANGE_TOPIC_ID: if (data === kPrefRilDebuggingEnabled) { updateDebugFlag(); this.setWorkerDebugFlag(DEBUG); } break; } }, /** * nsIRadioInterfaceLayer interface methods. */ getRadioInterface: function(clientId) { return this.radioInterfaces[clientId]; }, getClientIdForEmergencyCall: function() { // Select the client with sim card first. for (let cid = 0; cid < this.numRadioInterfaces; ++cid) { if (this.getRadioInterface(cid).isCardPresent()) { return cid; } } // Use the defualt client if no card presents. return HW_DEFAULT_CLIENT_ID; }, setMicrophoneMuted: function(muted) { for (let clientId = 0; clientId < this.numRadioInterfaces; clientId++) { let radioInterface = this.radioInterfaces[clientId]; radioInterface.workerMessenger.send("setMute", { muted: muted }); } } }; XPCOMUtils.defineLazyGetter(RadioInterfaceLayer.prototype, "numRadioInterfaces", function() { try { return Services.prefs.getIntPref(kPrefRilNumRadioInterfaces); } catch(e) {} return 1; }); function WorkerMessenger() { // Initial owning attributes. this.radioInterfaces = []; this.tokenCallbackMap = {}; this.worker = new ChromeWorker("resource://gre/modules/ril_worker.js"); this.worker.onerror = this.onerror.bind(this); this.worker.onmessage = this.onmessage.bind(this); } WorkerMessenger.prototype = { radioInterfaces: null, worker: null, // This gets incremented each time we send out a message. token: 1, // Maps tokens we send out with messages to the message callback. tokenCallbackMap: null, init: function() { let options = { debug: DEBUG, quirks: { callstateExtraUint32: libcutils.property_get("ro.moz.ril.callstate_extra_int", "false") === "true", v5Legacy: libcutils.property_get("ro.moz.ril.v5_legacy", "true") === "true", requestUseDialEmergencyCall: libcutils.property_get("ro.moz.ril.dial_emergency_call", "false") === "true", simAppStateExtraFields: libcutils.property_get("ro.moz.ril.simstate_extra_field", "false") === "true", extraUint2ndCall: libcutils.property_get("ro.moz.ril.extra_int_2nd_call", "false") == "true", haveQueryIccLockRetryCount: libcutils.property_get("ro.moz.ril.query_icc_count", "false") == "true", sendStkProfileDownload: libcutils.property_get("ro.moz.ril.send_stk_profile_dl", "false") == "true", dataRegistrationOnDemand: RILQUIRKS_DATA_REGISTRATION_ON_DEMAND, subscriptionControl: RILQUIRKS_SUBSCRIPTION_CONTROL } }; this.send(null, "setInitialOptions", options); }, setDebugFlag: function(aDebug) { let options = { debug: aDebug }; this.send(null, "setDebugFlag", options); }, debug: function(aClientId, aMessage) { // We use the same debug subject with RadioInterface's here. dump("-*- RadioInterface[" + aClientId + "]: " + aMessage + "\n"); }, onerror: function(event) { if (DEBUG) { this.debug("X", "Got an error: " + event.filename + ":" + event.lineno + ": " + event.message + "\n"); } event.preventDefault(); }, /** * Process the incoming message from the RIL worker. */ onmessage: function(event) { let message = event.data; let clientId = message.rilMessageClientId; if (clientId === null) { return; } if (DEBUG) { this.debug(clientId, "Received message from worker: " + JSON.stringify(message)); } let token = message.rilMessageToken; if (token == null) { // That's an unsolicited message. Pass to RadioInterface directly. let radioInterface = this.radioInterfaces[clientId]; radioInterface.handleUnsolicitedWorkerMessage(message); return; } let callback = this.tokenCallbackMap[message.rilMessageToken]; if (!callback) { if (DEBUG) this.debug(clientId, "Ignore orphan token: " + message.rilMessageToken); return; } let keep = false; try { keep = callback(message); } catch(e) { if (DEBUG) this.debug(clientId, "callback throws an exception: " + e); } if (!keep) { delete this.tokenCallbackMap[message.rilMessageToken]; } }, registerClient: function(aClientId, aRadioInterface) { if (DEBUG) this.debug(aClientId, "Starting RIL Worker"); // Keep a reference so that we can dispatch unsolicited messages to it. this.radioInterfaces[aClientId] = aRadioInterface; this.send(null, "registerClient", { clientId: aClientId }); gSystemWorkerManager.registerRilWorker(aClientId, this.worker); }, /** * Send arbitrary message to worker. * * @param rilMessageType * A text message type. * @param message [optional] * An optional message object to send. * @param callback [optional] * An optional callback function which is called when worker replies * with an message containing a "rilMessageToken" attribute of the * same value we passed. This callback function accepts only one * parameter -- the reply from worker. It also returns a boolean * value true to keep current token-callback mapping and wait for * another worker reply, or false to remove the mapping. */ send: function(clientId, rilMessageType, message, callback) { message = message || {}; message.rilMessageClientId = clientId; message.rilMessageToken = this.token; this.token++; if (callback) { // Only create the map if callback is provided. For sending a request // and intentionally leaving the callback undefined, that reply will // be dropped in |this.onmessage| because of that orphan token. // // For sending a request that never replied at all, we're fine with this // because no callback shall be passed and we leave nothing to be cleaned // up later. this.tokenCallbackMap[message.rilMessageToken] = callback; } message.rilMessageType = rilMessageType; this.worker.postMessage(message); }, /** * Send message to worker and return worker reply to RILContentHelper. * * @param msg * A message object from ppmm. * @param rilMessageType * A text string for worker message type. * @param ipcType [optinal] * A text string for ipc message type. "msg.name" if omitted. * * @TODO: Bug 815526 - deprecate RILContentHelper. */ sendWithIPCMessage: function(clientId, msg, rilMessageType, ipcType) { this.send(clientId, rilMessageType, msg.json.data, (function(reply) { ipcType = ipcType || msg.name; msg.target.sendAsyncMessage(ipcType, { clientId: clientId, data: reply }); return false; }).bind(this)); } }; function RadioInterface(aClientId, aWorkerMessenger) { this.clientId = aClientId; this.workerMessenger = { send: aWorkerMessenger.send.bind(aWorkerMessenger, aClientId), sendWithIPCMessage: aWorkerMessenger.sendWithIPCMessage.bind(aWorkerMessenger, aClientId), }; aWorkerMessenger.registerClient(aClientId, this); this.rilContext = { cardState: Ci.nsIIccProvider.CARD_STATE_UNKNOWN, iccInfo: null, imsi: null }; this.operatorInfo = {}; let lock = gSettingsService.createLock(); // Read the "time.clock.automatic-update.enabled" setting to see if // we need to adjust the system clock time by NITZ or SNTP. lock.get(kSettingsClockAutoUpdateEnabled, this); // Read the "time.timezone.automatic-update.enabled" setting to see if // we need to adjust the system timezone by NITZ. lock.get(kSettingsTimezoneAutoUpdateEnabled, this); // Set "time.clock.automatic-update.available" to false when starting up. this.setClockAutoUpdateAvailable(false); // Set "time.timezone.automatic-update.available" to false when starting up. this.setTimezoneAutoUpdateAvailable(false); Services.obs.addObserver(this, kMozSettingsChangedObserverTopic, false); Services.obs.addObserver(this, kSysClockChangeObserverTopic, false); Services.obs.addObserver(this, kScreenStateChangedTopic, false); Services.obs.addObserver(this, kNetworkConnStateChangedTopic, false); this.portAddressedSmsApps = {}; this.portAddressedSmsApps[WAP.WDP_PORT_PUSH] = this.handleSmsWdpPortPush.bind(this); this._receivedSmsSegmentsMap = {}; this._sntp = new Sntp(this.setClockBySntp.bind(this), Services.prefs.getIntPref("network.sntp.maxRetryCount"), Services.prefs.getIntPref("network.sntp.refreshPeriod"), Services.prefs.getIntPref("network.sntp.timeout"), Services.prefs.getCharPref("network.sntp.pools").split(";"), Services.prefs.getIntPref("network.sntp.port")); } RadioInterface.prototype = { classID: RADIOINTERFACE_CID, classInfo: XPCOMUtils.generateCI({classID: RADIOINTERFACE_CID, classDescription: "RadioInterface", interfaces: [Ci.nsIRadioInterface]}), QueryInterface: XPCOMUtils.generateQI([Ci.nsIRadioInterface, Ci.nsIObserver, Ci.nsISettingsServiceCallback]), // A private wrapped WorkerMessenger instance. workerMessenger: null, debug: function(s) { dump("-*- RadioInterface[" + this.clientId + "]: " + s + "\n"); }, shutdown: function() { // Release the CPU wake lock for handling the received SMS. this._releaseSmsHandledWakeLock(); Services.obs.removeObserver(this, kMozSettingsChangedObserverTopic); Services.obs.removeObserver(this, kSysClockChangeObserverTopic); Services.obs.removeObserver(this, kScreenStateChangedTopic); Services.obs.removeObserver(this, kNetworkConnStateChangedTopic); }, /** * A utility function to copy objects. The srcInfo may contain * "rilMessageType", should ignore it. */ updateInfo: function(srcInfo, destInfo) { for (let key in srcInfo) { if (key === "rilMessageType") { continue; } destInfo[key] = srcInfo[key]; } }, /** * A utility function to compare objects. The srcInfo may contain * "rilMessageType", should ignore it. */ isInfoChanged: function(srcInfo, destInfo) { if (!destInfo) { return true; } for (let key in srcInfo) { if (key === "rilMessageType") { continue; } if (srcInfo[key] !== destInfo[key]) { return true; } } return false; }, isCardPresent: function() { let cardState = this.rilContext.cardState; return cardState !== Ci.nsIIccProvider.CARD_STATE_UNDETECTED && cardState !== Ci.nsIIccProvider.CARD_STATE_UNKNOWN; }, /** * Process a message from the content process. */ receiveMessage: function(msg) { switch (msg.name) { case "RIL:GetRilContext": // This message is sync. return this.rilContext; case "RIL:GetCardLockEnabled": this.workerMessenger.sendWithIPCMessage(msg, "iccGetCardLockEnabled", "RIL:GetCardLockResult"); break; case "RIL:UnlockCardLock": this.workerMessenger.sendWithIPCMessage(msg, "iccUnlockCardLock", "RIL:SetUnlockCardLockResult"); break; case "RIL:SetCardLockEnabled": this.workerMessenger.sendWithIPCMessage(msg, "iccSetCardLockEnabled", "RIL:SetUnlockCardLockResult"); break; case "RIL:ChangeCardLockPassword": this.workerMessenger.sendWithIPCMessage(msg, "iccChangeCardLockPassword", "RIL:SetUnlockCardLockResult"); break; case "RIL:GetCardLockRetryCount": this.workerMessenger.sendWithIPCMessage(msg, "iccGetCardLockRetryCount", "RIL:CardLockRetryCount"); break; case "RIL:SendStkResponse": this.workerMessenger.send("sendStkTerminalResponse", msg.json.data); break; case "RIL:SendStkMenuSelection": this.workerMessenger.send("sendStkMenuSelection", msg.json.data); break; case "RIL:SendStkTimerExpiration": this.workerMessenger.send("sendStkTimerExpiration", msg.json.data); break; case "RIL:SendStkEventDownload": this.workerMessenger.send("sendStkEventDownload", msg.json.data); break; case "RIL:IccOpenChannel": this.workerMessenger.sendWithIPCMessage(msg, "iccOpenChannel"); break; case "RIL:IccCloseChannel": this.workerMessenger.sendWithIPCMessage(msg, "iccCloseChannel"); break; case "RIL:IccExchangeAPDU": this.workerMessenger.sendWithIPCMessage(msg, "iccExchangeAPDU"); break; case "RIL:ReadIccContacts": this.workerMessenger.sendWithIPCMessage(msg, "readICCContacts"); break; case "RIL:UpdateIccContact": this.workerMessenger.sendWithIPCMessage(msg, "updateICCContact"); break; case "RIL:MatchMvno": this.matchMvno(msg.target, msg.json.data); break; } return null; }, handleUnsolicitedWorkerMessage: function(message) { let connHandler = gDataConnectionManager.getConnectionHandler(this.clientId); switch (message.rilMessageType) { case "audioStateChanged": gTelephonyService.notifyAudioStateChanged(this.clientId, message.state); break; case "callRing": gTelephonyService.notifyCallRing(); break; case "callStateChange": gTelephonyService.notifyCallStateChanged(this.clientId, message.call); break; case "callDisconnected": gTelephonyService.notifyCallDisconnected(this.clientId, message.call); break; case "conferenceCallStateChanged": gTelephonyService.notifyConferenceCallStateChanged(message.state); break; case "cdmaCallWaiting": gTelephonyService.notifyCdmaCallWaiting(this.clientId, message.waitingCall); break; case "suppSvcNotification": gTelephonyService.notifySupplementaryService(this.clientId, message.callIndex, message.notification); break; case "ussdreceived": gTelephonyService.notifyUssdReceived(this.clientId, message.message, message.sessionEnded); break; case "datacallerror": connHandler.handleDataCallError(message); break; case "datacallstatechange": let addresses = []; for (let i = 0; i < message.addresses.length; i++) { let [address, prefixLength] = message.addresses[i].split("/"); // From AOSP hardware/ril/include/telephony/ril.h, that address prefix // is said to be OPTIONAL, but we never met such case before. addresses.push({ address: address, prefixLength: prefixLength ? parseInt(prefixLength, 10) : 0 }); } message.addresses = addresses; connHandler.handleDataCallState(message); break; case "emergencyCbModeChange": gMobileConnectionService.notifyEmergencyCallbackModeChanged(this.clientId, message.active, message.timeoutMs); break; case "networkinfochanged": gMobileConnectionService.notifyNetworkInfoChanged(this.clientId, message); if (message[RIL.NETWORK_INFO_DATA_REGISTRATION_STATE]) { connHandler.updateRILNetworkInterface(); } break; case "networkselectionmodechange": gMobileConnectionService.notifyNetworkSelectModeChanged(this.clientId, message.mode); break; case "voiceregistrationstatechange": gMobileConnectionService.notifyVoiceInfoChanged(this.clientId, message); break; case "dataregistrationstatechange": gMobileConnectionService.notifyDataInfoChanged(this.clientId, message); connHandler.updateRILNetworkInterface(); break; case "signalstrengthchange": gMobileConnectionService.notifySignalStrengthChanged(this.clientId, message); break; case "operatorchange": gMobileConnectionService.notifyOperatorChanged(this.clientId, message); break; case "otastatuschange": gMobileConnectionService.notifyOtaStatusChanged(this.clientId, message.status); break; case "radiostatechange": // gRadioEnabledController should know the radio state for each client, // so notify gRadioEnabledController here. gRadioEnabledController.notifyRadioStateChanged(this.clientId, message.radioState); break; case "cardstatechange": this.rilContext.cardState = message.cardState; gRadioEnabledController.receiveCardState(this.clientId); gMessageManager.sendIccMessage("RIL:CardStateChanged", this.clientId, message); break; case "sms-received": this.handleSmsMultipart(message); break; case "cellbroadcast-received": this.handleCellbroadcastMessageReceived(message); break; case "nitzTime": this.handleNitzTime(message); break; case "iccinfochange": this.handleIccInfoChange(message); break; case "iccimsi": this.rilContext.imsi = message.imsi; break; case "iccmbdn": this.handleIccMbdn(message); break; case "iccmwis": this.handleIccMwis(message.mwi); break; case "stkcommand": this.handleStkProactiveCommand(message); break; case "stksessionend": gMessageManager.sendIccMessage("RIL:StkSessionEnd", this.clientId, null); break; case "cdma-info-rec-received": this.handleCdmaInformationRecords(message.records); break; default: throw new Error("Don't know about this message type: " + message.rilMessageType); } }, /** * Get phone number from iccInfo. * * If the icc card is gsm card, the phone number is in msisdn. * @see nsIGsmIccInfo * * Otherwise, the phone number is in mdn. * @see nsICdmaIccInfo */ getPhoneNumber: function() { let iccInfo = this.rilContext.iccInfo; if (!iccInfo) { return null; } // After moving SMS code out of RadioInterfaceLayer, we could use // |iccInfo instanceof Ci.nsIGsmIccInfo| here. // TODO: Bug 873351 - B2G SMS: move SMS code out of RadioInterfaceLayer to // SmsService let number = (iccInfo instanceof GsmIccInfo) ? iccInfo.msisdn : iccInfo.mdn; // Workaround an xpconnect issue with undefined string objects. // See bug 808220 if (number === undefined || number === "undefined") { return null; } return number; }, /** * A utility function to get the ICC ID of the SIM card (if installed). */ getIccId: function() { let iccInfo = this.rilContext.iccInfo; if (!iccInfo) { return null; } let iccId = iccInfo.iccid; // Workaround an xpconnect issue with undefined string objects. // See bug 808220 if (iccId === undefined || iccId === "undefined") { return null; } return iccId; }, // Matches the mvnoData pattern with imsi. Characters 'x' and 'X' are skipped // and not compared. E.g., if the mvnoData passed is '310260x10xxxxxx', // then the function returns true only if imsi has the same first 6 digits, // 8th and 9th digit. isImsiMatches: function(mvnoData) { let imsi = this.rilContext.imsi; // This should not be an error, but a mismatch. if (mvnoData.length > imsi.length) { return false; } for (let i = 0; i < mvnoData.length; i++) { let c = mvnoData[i]; if ((c !== 'x') && (c !== 'X') && (c !== imsi[i])) { return false; } } return true; }, matchMvno: function(target, message) { if (DEBUG) this.debug("matchMvno: " + JSON.stringify(message)); if (!message || !message.mvnoType || !message.mvnoData) { message.errorMsg = RIL.GECKO_ERROR_INVALID_PARAMETER; } if (!message.errorMsg) { switch (message.mvnoType) { case "imsi": if (!this.rilContext.imsi) { message.errorMsg = RIL.GECKO_ERROR_GENERIC_FAILURE; break; } message.result = this.isImsiMatches(message.mvnoData); break; case "spn": let spn = this.rilContext.iccInfo && this.rilContext.iccInfo.spn; if (!spn) { message.errorMsg = RIL.GECKO_ERROR_GENERIC_FAILURE; break; } message.result = spn == message.mvnoData; break; case "gid": this.workerMessenger.send("getGID1", null, (function(response) { let gid = response.gid1; let mvnoDataLength = message.mvnoData.length; if (!gid) { message.errorMsg = RIL.GECKO_ERROR_GENERIC_FAILURE; } else if (mvnoDataLength > gid.length) { message.result = false; } else { message.result = gid.substring(0, mvnoDataLength).toLowerCase() == message.mvnoData.toLowerCase(); } target.sendAsyncMessage("RIL:MatchMvno", { clientId: this.clientId, data: message }); }).bind(this)); return; default: message.errorMsg = RIL.GECKO_ERROR_MODE_NOT_SUPPORTED; } } target.sendAsyncMessage("RIL:MatchMvno", { clientId: this.clientId, data: message }); }, setDataRegistration: function(attach) { let deferred = Promise.defer(); this.workerMessenger.send("setDataRegistration", {attach: attach}, (function(response) { // Always resolve to proceed with the following steps. deferred.resolve(response.errorMsg ? response.errorMsg : null); }).bind(this)); return deferred.promise; }, /** * TODO: Bug 911713 - B2G NetworkManager: Move policy control logic to * NetworkManager */ updateRILNetworkInterface: function() { let connHandler = gDataConnectionManager.getConnectionHandler(this.clientId); connHandler.updateRILNetworkInterface(); }, /** * Handle WDP port push PDU. Constructor WDP bearer information and deliver * to WapPushManager. * * @param message * A SMS message. */ handleSmsWdpPortPush: function(message) { if (message.encoding != RIL.PDU_DCS_MSG_CODING_8BITS_ALPHABET) { if (DEBUG) { this.debug("Got port addressed SMS but not encoded in 8-bit alphabet." + " Drop!"); } return; } let options = { bearer: WAP.WDP_BEARER_GSM_SMS_GSM_MSISDN, sourceAddress: message.sender, sourcePort: message.originatorPort, destinationAddress: this.rilContext.iccInfo.msisdn, destinationPort: message.destinationPort, serviceId: this.clientId }; WAP.WapPushManager.receiveWdpPDU(message.fullData, message.fullData.length, 0, options); }, _convertSmsMessageClass: function(aMessageClass) { let index = RIL.GECKO_SMS_MESSAGE_CLASSES.indexOf(aMessageClass); if (index < 0) { throw new Error("Invalid MessageClass: " + aMessageClass); } return index; }, _convertSmsDelivery: function(aDelivery) { let index = [DOM_MOBILE_MESSAGE_DELIVERY_RECEIVED, DOM_MOBILE_MESSAGE_DELIVERY_SENDING, DOM_MOBILE_MESSAGE_DELIVERY_SENT, DOM_MOBILE_MESSAGE_DELIVERY_ERROR].indexOf(aDelivery); if (index < 0) { throw new Error("Invalid Delivery: " + aDelivery); } return index; }, _convertSmsDeliveryStatus: function(aDeliveryStatus) { let index = [RIL.GECKO_SMS_DELIVERY_STATUS_NOT_APPLICABLE, RIL.GECKO_SMS_DELIVERY_STATUS_SUCCESS, RIL.GECKO_SMS_DELIVERY_STATUS_PENDING, RIL.GECKO_SMS_DELIVERY_STATUS_ERROR].indexOf(aDeliveryStatus); if (index < 0) { throw new Error("Invalid DeliveryStatus: " + aDeliveryStatus); } return index; }, /** * A helper to broadcast the system message to launch registered apps * like Costcontrol, Notification and Message app... etc. * * @param aName * The system message name. * @param aDomMessage * The nsIDOMMozSmsMessage object. */ broadcastSmsSystemMessage: function(aNotificationType, aDomMessage) { if (DEBUG) this.debug("Broadcasting the SMS system message: " + aNotificationType); // Sadly we cannot directly broadcast the aDomMessage object // because the system message mechamism will rewrap the object // based on the content window, which needs to know the properties. try { gSmsMessenger.notifySms(aNotificationType, aDomMessage.id, aDomMessage.threadId, aDomMessage.iccId, this._convertSmsDelivery( aDomMessage.delivery), this._convertSmsDeliveryStatus( aDomMessage.deliveryStatus), aDomMessage.sender, aDomMessage.receiver, aDomMessage.body, this._convertSmsMessageClass( aDomMessage.messageClass), aDomMessage.timestamp, aDomMessage.sentTimestamp, aDomMessage.deliveryTimestamp, aDomMessage.read); } catch (e) { if (DEBUG) { this.debug("Failed to broadcastSmsSystemMessage: " + e); } } }, // The following attributes/functions are used for acquiring/releasing the // CPU wake lock when the RIL handles the received SMS. Note that we need // a timer to bound the lock's life cycle to avoid exhausting the battery. _smsHandledWakeLock: null, _smsHandledWakeLockTimer: null, _acquireSmsHandledWakeLock: function() { if (!this._smsHandledWakeLock) { if (DEBUG) this.debug("Acquiring a CPU wake lock for handling SMS."); this._smsHandledWakeLock = gPowerManagerService.newWakeLock("cpu"); } if (!this._smsHandledWakeLockTimer) { if (DEBUG) this.debug("Creating a timer for releasing the CPU wake lock."); this._smsHandledWakeLockTimer = Cc["@mozilla.org/timer;1"].createInstance(Ci.nsITimer); } if (DEBUG) this.debug("Setting the timer for releasing the CPU wake lock."); this._smsHandledWakeLockTimer .initWithCallback(this._releaseSmsHandledWakeLock.bind(this), SMS_HANDLED_WAKELOCK_TIMEOUT, Ci.nsITimer.TYPE_ONE_SHOT); }, _releaseSmsHandledWakeLock: function() { if (DEBUG) this.debug("Releasing the CPU wake lock for handling SMS."); if (this._smsHandledWakeLockTimer) { this._smsHandledWakeLockTimer.cancel(); } if (this._smsHandledWakeLock) { this._smsHandledWakeLock.unlock(); this._smsHandledWakeLock = null; } }, /** * Hash map for received multipart sms fragments. Messages are hashed with * its sender address and concatenation reference number. Three additional * attributes `segmentMaxSeq`, `receivedSegments`, `segments` are inserted. */ _receivedSmsSegmentsMap: null, /** * Helper for processing received multipart SMS. * * @return null for handled segments, and an object containing full message * body/data once all segments are received. */ _processReceivedSmsSegment: function(aSegment) { // Directly replace full message body for single SMS. if (!(aSegment.segmentMaxSeq && (aSegment.segmentMaxSeq > 1))) { if (aSegment.encoding == RIL.PDU_DCS_MSG_CODING_8BITS_ALPHABET) { aSegment.fullData = aSegment.data; } else { aSegment.fullBody = aSegment.body; } return aSegment; } // Handle Concatenation for Class 0 SMS let hash = aSegment.sender + ":" + aSegment.segmentRef + ":" + aSegment.segmentMaxSeq; let seq = aSegment.segmentSeq; let options = this._receivedSmsSegmentsMap[hash]; if (!options) { options = aSegment; this._receivedSmsSegmentsMap[hash] = options; options.receivedSegments = 0; options.segments = []; } else if (options.segments[seq]) { // Duplicated segment? if (DEBUG) { this.debug("Got duplicated segment no." + seq + " of a multipart SMS: " + JSON.stringify(aSegment)); } return null; } if (options.receivedSegments > 0) { // Update received timestamp. options.timestamp = aSegment.timestamp; } if (options.encoding == RIL.PDU_DCS_MSG_CODING_8BITS_ALPHABET) { options.segments[seq] = aSegment.data; } else { options.segments[seq] = aSegment.body; } options.receivedSegments++; // The port information is only available in 1st segment for CDMA WAP Push. // If the segments of a WAP Push are not received in sequence // (e.g., SMS with seq == 1 is not the 1st segment received by the device), // we have to retrieve the port information from 1st segment and // save it into the cached options. if (aSegment.teleservice === RIL.PDU_CDMA_MSG_TELESERIVCIE_ID_WAP && seq === 1) { if (!options.originatorPort && aSegment.originatorPort) { options.originatorPort = aSegment.originatorPort; } if (!options.destinationPort && aSegment.destinationPort) { options.destinationPort = aSegment.destinationPort; } } if (options.receivedSegments < options.segmentMaxSeq) { if (DEBUG) { this.debug("Got segment no." + seq + " of a multipart SMS: " + JSON.stringify(options)); } return null; } // Remove from map delete this._receivedSmsSegmentsMap[hash]; // Rebuild full body if (options.encoding == RIL.PDU_DCS_MSG_CODING_8BITS_ALPHABET) { // Uint8Array doesn't have `concat`, so we have to merge all segements // by hand. let fullDataLen = 0; for (let i = 1; i <= options.segmentMaxSeq; i++) { fullDataLen += options.segments[i].length; } options.fullData = new Uint8Array(fullDataLen); for (let d= 0, i = 1; i <= options.segmentMaxSeq; i++) { let data = options.segments[i]; for (let j = 0; j < data.length; j++) { options.fullData[d++] = data[j]; } } } else { options.fullBody = options.segments.join(""); } // Remove handy fields after completing the concatenation. delete options.receivedSegments; delete options.segments; if (DEBUG) { this.debug("Got full multipart SMS: " + JSON.stringify(options)); } return options; }, /** * Helper to create Savable SmsSegment. */ _createSavableSmsSegment: function(aMessage) { // We precisely define what data fields to be stored into // DB here for better data migration. let segment = {}; segment.messageType = aMessage.messageType; segment.teleservice = aMessage.teleservice; segment.SMSC = aMessage.SMSC; segment.sentTimestamp = aMessage.sentTimestamp; segment.timestamp = Date.now(); segment.sender = aMessage.sender; segment.pid = aMessage.pid; segment.encoding = aMessage.encoding; segment.messageClass = aMessage.messageClass; segment.iccId = this.getIccId(); if (aMessage.header) { segment.segmentRef = aMessage.header.segmentRef; segment.segmentSeq = aMessage.header.segmentSeq; segment.segmentMaxSeq = aMessage.header.segmentMaxSeq; segment.originatorPort = aMessage.header.originatorPort; segment.destinationPort = aMessage.header.destinationPort; } segment.mwiPresent = (aMessage.mwi)? true: false; segment.mwiDiscard = (segment.mwiPresent)? aMessage.mwi.discard: false; segment.mwiMsgCount = (segment.mwiPresent)? aMessage.mwi.msgCount: 0; segment.mwiActive = (segment.mwiPresent)? aMessage.mwi.active: false; segment.serviceCategory = aMessage.serviceCategory; segment.language = aMessage.language; segment.data = aMessage.data; segment.body = aMessage.body; return segment; }, /** * Helper to purge complete message. * * We remove unnessary fields defined in _createSavableSmsSegment() after * completing the concatenation. */ _purgeCompleteSmsMessage: function(aMessage) { // Purge concatenation info delete aMessage.segmentRef; delete aMessage.segmentSeq; delete aMessage.segmentMaxSeq; // Purge partial message body delete aMessage.data; delete aMessage.body; }, /** * handle concatenation of received SMS. */ handleSmsMultipart: function(aMessage) { if (DEBUG) this.debug("handleSmsMultipart: " + JSON.stringify(aMessage)); this._acquireSmsHandledWakeLock(); let segment = this._createSavableSmsSegment(aMessage); let isMultipart = (segment.segmentMaxSeq && (segment.segmentMaxSeq > 1)); let messageClass = segment.messageClass; let handleReceivedAndAck = function(aRvOfIncompleteMsg, aCompleteMessage) { if (aCompleteMessage) { this._purgeCompleteSmsMessage(aCompleteMessage); if (this.handleSmsReceived(aCompleteMessage)) { this.sendAckSms(Cr.NS_OK, aCompleteMessage); } // else Ack will be sent after further process in handleSmsReceived. } else { this.sendAckSms(aRvOfIncompleteMsg, segment); } }.bind(this); // No need to access SmsSegmentStore for Class 0 SMS and Single SMS. if (!isMultipart || (messageClass == RIL.GECKO_SMS_MESSAGE_CLASSES[RIL.PDU_DCS_MSG_CLASS_0])) { // `When a mobile terminated message is class 0 and the MS has the // capability of displaying short messages, the MS shall display the // message immediately and send an acknowledgement to the SC when the // message has successfully reached the MS irrespective of whether // there is memory available in the (U)SIM or ME. The message shall // not be automatically stored in the (U)SIM or ME.` // ~ 3GPP 23.038 clause 4 handleReceivedAndAck(Cr.NS_OK, // ACK OK For Incomplete Class 0 this._processReceivedSmsSegment(segment)); } else { gMobileMessageDatabaseService .saveSmsSegment(segment, function notifyResult(aRv, aCompleteMessage) { handleReceivedAndAck(aRv, // Ack according to the result after saving aCompleteMessage); }); } }, portAddressedSmsApps: null, handleSmsReceived: function(message) { if (DEBUG) this.debug("handleSmsReceived: " + JSON.stringify(message)); if (message.messageType == RIL.PDU_CDMA_MSG_TYPE_BROADCAST) { this.handleCellbroadcastMessageReceived(message); return true; } // Dispatch to registered handler if application port addressing is // available. Note that the destination port can possibly be zero when // representing a UDP/TCP port. if (message.destinationPort != null) { let handler = this.portAddressedSmsApps[message.destinationPort]; if (handler) { handler(message); } return true; } if (message.encoding == RIL.PDU_DCS_MSG_CODING_8BITS_ALPHABET) { // Don't know how to handle binary data yet. return true; } message.type = "sms"; message.sender = message.sender || null; message.receiver = this.getPhoneNumber(); message.body = message.fullBody = message.fullBody || null; if (gSmsService.isSilentNumber(message.sender)) { message.id = -1; message.threadId = 0; message.delivery = DOM_MOBILE_MESSAGE_DELIVERY_RECEIVED; message.deliveryStatus = RIL.GECKO_SMS_DELIVERY_STATUS_SUCCESS; message.read = false; let domMessage = gMobileMessageService.createSmsMessage(message.id, message.threadId, message.iccId, message.delivery, message.deliveryStatus, message.sender, message.receiver, message.body, message.messageClass, message.timestamp, message.sentTimestamp, 0, message.read); Services.obs.notifyObservers(domMessage, kSilentSmsReceivedObserverTopic, null); return true; } if (message.mwiPresent) { let mwi = { discard: message.mwiDiscard, msgCount: message.mwiMsgCount, active: message.mwiActive }; this.workerMessenger.send("updateMwis", { mwi: mwi }); mwi.returnNumber = message.sender; mwi.returnMessage = message.fullBody; this.handleIccMwis(mwi); // Dicarded MWI comes without text body. // Hence, we discard it here after notifying the MWI status. if (message.mwiDiscard) { return true; } } let notifyReceived = function notifyReceived(rv, domMessage) { let success = Components.isSuccessCode(rv); this.sendAckSms(rv, message); if (!success) { // At this point we could send a message to content to notify the user // that storing an incoming SMS failed, most likely due to a full disk. if (DEBUG) { this.debug("Could not store SMS, error code " + rv); } return; } this.broadcastSmsSystemMessage( Ci.nsISmsMessenger.NOTIFICATION_TYPE_RECEIVED, domMessage); Services.obs.notifyObservers(domMessage, kSmsReceivedObserverTopic, null); }.bind(this); if (message.messageClass != RIL.GECKO_SMS_MESSAGE_CLASSES[RIL.PDU_DCS_MSG_CLASS_0]) { gMobileMessageDatabaseService.saveReceivedMessage(message, notifyReceived); } else { message.id = -1; message.threadId = 0; message.delivery = DOM_MOBILE_MESSAGE_DELIVERY_RECEIVED; message.deliveryStatus = RIL.GECKO_SMS_DELIVERY_STATUS_SUCCESS; message.read = false; let domMessage = gMobileMessageService.createSmsMessage(message.id, message.threadId, message.iccId, message.delivery, message.deliveryStatus, message.sender, message.receiver, message.body, message.messageClass, message.timestamp, message.sentTimestamp, 0, message.read); notifyReceived(Cr.NS_OK, domMessage); } // SMS ACK will be sent in notifyReceived. Return false here. return false; }, /** * Handle ACK response of received SMS. */ sendAckSms: function(aRv, aMessage) { if (aMessage.messageClass === RIL.GECKO_SMS_MESSAGE_CLASSES[RIL.PDU_DCS_MSG_CLASS_2]) { return; } let result = RIL.PDU_FCS_OK; if (!Components.isSuccessCode(aRv)) { if (DEBUG) this.debug("Failed to handle received sms: " + aRv); result = (aRv === Cr.NS_ERROR_FILE_NO_DEVICE_SPACE) ? RIL.PDU_FCS_MEMORY_CAPACITY_EXCEEDED : RIL.PDU_FCS_UNSPECIFIED; } this.workerMessenger.send("ackSMS", { result: result }); }, /** * Set the setting value of "time.clock.automatic-update.available". */ setClockAutoUpdateAvailable: function(value) { gSettingsService.createLock().set(kSettingsClockAutoUpdateAvailable, value, null); }, /** * Set the setting value of "time.timezone.automatic-update.available". */ setTimezoneAutoUpdateAvailable: function(value) { gSettingsService.createLock().set(kSettingsTimezoneAutoUpdateAvailable, value, null); }, /** * Set the system clock by NITZ. */ setClockByNitz: function(message) { // To set the system clock time. Note that there could be a time diff // between when the NITZ was received and when the time is actually set. gTimeService.set( message.networkTimeInMS + (Date.now() - message.receiveTimeInMS)); }, /** * Set the system time zone by NITZ. */ setTimezoneByNitz: function(message) { // To set the sytem timezone. Note that we need to convert the time zone // value to a UTC repesentation string in the format of "UTC(+/-)hh:mm". // Ex, time zone -480 is "UTC+08:00"; time zone 630 is "UTC-10:30". // // We can unapply the DST correction if we want the raw time zone offset: // message.networkTimeZoneInMinutes -= message.networkDSTInMinutes; if (message.networkTimeZoneInMinutes != (new Date()).getTimezoneOffset()) { let absTimeZoneInMinutes = Math.abs(message.networkTimeZoneInMinutes); let timeZoneStr = "UTC"; timeZoneStr += (message.networkTimeZoneInMinutes > 0 ? "-" : "+"); timeZoneStr += ("0" + Math.floor(absTimeZoneInMinutes / 60)).slice(-2); timeZoneStr += ":"; timeZoneStr += ("0" + absTimeZoneInMinutes % 60).slice(-2); gSettingsService.createLock().set("time.timezone", timeZoneStr, null); } }, /** * Handle the NITZ message. */ handleNitzTime: function(message) { // Got the NITZ info received from the ril_worker. this.setClockAutoUpdateAvailable(true); this.setTimezoneAutoUpdateAvailable(true); // Cache the latest NITZ message whenever receiving it. this._lastNitzMessage = message; // Set the received NITZ clock if the setting is enabled. if (this._clockAutoUpdateEnabled) { this.setClockByNitz(message); } // Set the received NITZ timezone if the setting is enabled. if (this._timezoneAutoUpdateEnabled) { this.setTimezoneByNitz(message); } }, /** * Set the system clock by SNTP. */ setClockBySntp: function(offset) { // Got the SNTP info. this.setClockAutoUpdateAvailable(true); if (!this._clockAutoUpdateEnabled) { return; } if (this._lastNitzMessage) { if (DEBUG) debug("SNTP: NITZ available, discard SNTP"); return; } gTimeService.set(Date.now() + offset); }, handleIccMbdn: function(message) { let service = Cc["@mozilla.org/voicemail/voicemailservice;1"] .getService(Ci.nsIGonkVoicemailService); service.notifyInfoChanged(this.clientId, message.number, message.alphaId); }, handleIccMwis: function(mwi) { let service = Cc["@mozilla.org/voicemail/voicemailservice;1"] .getService(Ci.nsIGonkVoicemailService); service.notifyStatusChanged(this.clientId, mwi.active, mwi.msgCount, mwi.returnNumber, mwi.returnMessage); }, handleIccInfoChange: function(message) { let oldSpn = this.rilContext.iccInfo ? this.rilContext.iccInfo.spn : null; if (!message || !message.iccid) { // Card is not detected, clear iccInfo to null. this.rilContext.iccInfo = null; } else { if (!this.rilContext.iccInfo) { if (message.iccType === "ruim" || message.iccType === "csim") { this.rilContext.iccInfo = new CdmaIccInfo(); } else if (message.iccType === "sim" || message.iccType === "usim") { this.rilContext.iccInfo = new GsmIccInfo(); } else { this.rilContext.iccInfo = new IccInfo(); } } if (!this.isInfoChanged(message, this.rilContext.iccInfo)) { return; } this.updateInfo(message, this.rilContext.iccInfo); } // RIL:IccInfoChanged corresponds to a DOM event that gets fired only // when iccInfo has changed. gMessageManager.sendIccMessage("RIL:IccInfoChanged", this.clientId, message.iccid ? message : null); // In bug 864489, icc related code will be move to gonk IccProvider, we may // need a better way to notify icc change to MobileConnectionService. gMobileConnectionService.notifyIccChanged(this.clientId, message.iccid || null); // Update lastKnownSimMcc. if (message.mcc) { try { Services.prefs.setCharPref("ril.lastKnownSimMcc", message.mcc.toString()); } catch (e) {} } // Update lastKnownHomeNetwork. if (message.mcc && message.mnc) { let lastKnownHomeNetwork = message.mcc + "-" + message.mnc; // Append spn information if available. if (message.spn) { lastKnownHomeNetwork += "-" + message.spn; } gMobileConnectionService.notifyLastHomeNetworkChanged(this.clientId, lastKnownHomeNetwork); } // If spn becomes available, we should check roaming again. if (!oldSpn && message.spn) { gMobileConnectionService.notifySpnAvailable(this.clientId); } }, handleStkProactiveCommand: function(message) { if (DEBUG) this.debug("handleStkProactiveCommand " + JSON.stringify(message)); let iccId = this.rilContext.iccInfo && this.rilContext.iccInfo.iccid; if (iccId) { gIccMessenger .notifyStkProactiveCommand(iccId, gStkCmdFactory.createCommand(message)); } gMessageManager.sendIccMessage("RIL:StkCommand", this.clientId, message); }, _convertCbGsmGeographicalScope: function(aGeographicalScope) { return (aGeographicalScope != null) ? aGeographicalScope : Ci.nsICellBroadcastService.GSM_GEOGRAPHICAL_SCOPE_INVALID; }, _convertCbMessageClass: function(aMessageClass) { let index = RIL.GECKO_SMS_MESSAGE_CLASSES.indexOf(aMessageClass); return (index != -1) ? index : Ci.nsICellBroadcastService.GSM_MESSAGE_CLASS_NORMAL; }, _convertCbEtwsWarningType: function(aWarningType) { return (aWarningType != null) ? aWarningType : Ci.nsICellBroadcastService.GSM_ETWS_WARNING_INVALID; }, handleCellbroadcastMessageReceived: function(aMessage) { let etwsInfo = aMessage.etws; let hasEtwsInfo = etwsInfo != null; let serviceCategory = (aMessage.serviceCategory) ? aMessage.serviceCategory : Ci.nsICellBroadcastService.CDMA_SERVICE_CATEGORY_INVALID; gCellBroadcastService .notifyMessageReceived(this.clientId, this._convertCbGsmGeographicalScope(aMessage.geographicalScope), aMessage.messageCode, aMessage.messageId, aMessage.language, aMessage.fullBody, this._convertCbMessageClass(aMessage.messageClass), Date.now(), serviceCategory, hasEtwsInfo, (hasEtwsInfo) ? this._convertCbEtwsWarningType(etwsInfo.warningType) : Ci.nsICellBroadcastService.GSM_ETWS_WARNING_INVALID, hasEtwsInfo ? etwsInfo.emergencyUserAlert : false, hasEtwsInfo ? etwsInfo.popup : false); }, handleCdmaInformationRecords: function(aRecords) { if (DEBUG) this.debug("cdma-info-rec-received: " + JSON.stringify(aRecords)); let clientId = this.clientId; aRecords.forEach(function(aRecord) { if (aRecord.display) { gMobileConnectionService .notifyCdmaInfoRecDisplay(clientId, aRecord.display); return; } if (aRecord.calledNumber) { gMobileConnectionService .notifyCdmaInfoRecCalledPartyNumber(clientId, aRecord.calledNumber.type, aRecord.calledNumber.plan, aRecord.calledNumber.number, aRecord.calledNumber.pi, aRecord.calledNumber.si); return; } if (aRecord.callingNumber) { gMobileConnectionService .notifyCdmaInfoRecCallingPartyNumber(clientId, aRecord.callingNumber.type, aRecord.callingNumber.plan, aRecord.callingNumber.number, aRecord.callingNumber.pi, aRecord.callingNumber.si); return; } if (aRecord.connectedNumber) { gMobileConnectionService .notifyCdmaInfoRecConnectedPartyNumber(clientId, aRecord.connectedNumber.type, aRecord.connectedNumber.plan, aRecord.connectedNumber.number, aRecord.connectedNumber.pi, aRecord.connectedNumber.si); return; } if (aRecord.signal) { gMobileConnectionService .notifyCdmaInfoRecSignal(clientId, aRecord.signal.type, aRecord.signal.alertPitch, aRecord.signal.signal); return; } if (aRecord.redirect) { gMobileConnectionService .notifyCdmaInfoRecRedirectingNumber(clientId, aRecord.redirect.type, aRecord.redirect.plan, aRecord.redirect.number, aRecord.redirect.pi, aRecord.redirect.si, aRecord.redirect.reason); return; } if (aRecord.lineControl) { gMobileConnectionService .notifyCdmaInfoRecLineControl(clientId, aRecord.lineControl.polarityIncluded, aRecord.lineControl.toggle, aRecord.lineControl.reverse, aRecord.lineControl.powerDenial); return; } if (aRecord.clirCause) { gMobileConnectionService .notifyCdmaInfoRecClir(clientId, aRecord.clirCause); return; } if (aRecord.audioControl) { gMobileConnectionService .notifyCdmaInfoRecAudioControl(clientId, aRecord.audioControl.upLink, aRecord.audioControl.downLink); return; } }); }, // nsIObserver observe: function(subject, topic, data) { switch (topic) { case kMozSettingsChangedObserverTopic: if ("wrappedJSObject" in subject) { subject = subject.wrappedJSObject; } this.handleSettingsChange(subject.key, subject.value, subject.isInternalChange); break; case kSysClockChangeObserverTopic: let offset = parseInt(data, 10); if (this._lastNitzMessage) { this._lastNitzMessage.receiveTimeInMS += offset; } this._sntp.updateOffset(offset); break; case kNetworkConnStateChangedTopic: let network = subject.QueryInterface(Ci.nsINetworkInterface); if (network.state != Ci.nsINetworkInterface.NETWORK_STATE_CONNECTED) { return; } // SNTP can only update when we have mobile or Wifi connections. if (network.type != NETWORK_TYPE_WIFI && network.type != NETWORK_TYPE_MOBILE) { return; } // If the network comes from RIL, make sure the RIL service is matched. if (subject instanceof Ci.nsIRilNetworkInterface) { network = subject.QueryInterface(Ci.nsIRilNetworkInterface); if (network.serviceId != this.clientId) { return; } } // SNTP won't update unless the SNTP is already expired. if (this._sntp.isExpired()) { this._sntp.request(); } break; case kScreenStateChangedTopic: this.workerMessenger.send("setScreenState", { on: (data === "on") }); break; } }, // Flag to determine whether to update system clock automatically. It // corresponds to the "time.clock.automatic-update.enabled" setting. _clockAutoUpdateEnabled: null, // Flag to determine whether to update system timezone automatically. It // corresponds to the "time.clock.automatic-update.enabled" setting. _timezoneAutoUpdateEnabled: null, // Remember the last NITZ message so that we can set the time based on // the network immediately when users enable network-based time. _lastNitzMessage: null, // Object that handles SNTP. _sntp: null, // Cell Broadcast settings values. _cellBroadcastSearchList: null, handleSettingsChange: function(aName, aResult, aIsInternalSetting) { // Don't allow any content processes to modify the setting // "time.clock.automatic-update.available" except for the chrome process. if (aName === kSettingsClockAutoUpdateAvailable && !aIsInternalSetting) { let isClockAutoUpdateAvailable = this._lastNitzMessage !== null || this._sntp.isAvailable(); if (aResult !== isClockAutoUpdateAvailable) { if (DEBUG) { debug("Content processes cannot modify 'time.clock.automatic-update.available'. Restore!"); } // Restore the setting to the current value. this.setClockAutoUpdateAvailable(isClockAutoUpdateAvailable); } } // Don't allow any content processes to modify the setting // "time.timezone.automatic-update.available" except for the chrome // process. if (aName === kSettingsTimezoneAutoUpdateAvailable && !aIsInternalSetting) { let isTimezoneAutoUpdateAvailable = this._lastNitzMessage !== null; if (aResult !== isTimezoneAutoUpdateAvailable) { if (DEBUG) { this.debug("Content processes cannot modify 'time.timezone.automatic-update.available'. Restore!"); } // Restore the setting to the current value. this.setTimezoneAutoUpdateAvailable(isTimezoneAutoUpdateAvailable); } } this.handle(aName, aResult); }, // nsISettingsServiceCallback handle: function(aName, aResult) { switch(aName) { case kSettingsClockAutoUpdateEnabled: this._clockAutoUpdateEnabled = aResult; if (!this._clockAutoUpdateEnabled) { break; } // Set the latest cached NITZ time if it's available. if (this._lastNitzMessage) { this.setClockByNitz(this._lastNitzMessage); } else if (gNetworkManager.active && gNetworkManager.active.state == Ci.nsINetworkInterface.NETWORK_STATE_CONNECTED) { // Set the latest cached SNTP time if it's available. if (!this._sntp.isExpired()) { this.setClockBySntp(this._sntp.getOffset()); } else { // Or refresh the SNTP. this._sntp.request(); } } else { // Set a sane minimum time. let buildTime = libcutils.property_get("ro.build.date.utc", "0") * 1000; let file = FileUtils.File("/system/b2g/b2g"); if (file.lastModifiedTime > buildTime) { buildTime = file.lastModifiedTime; } if (buildTime > Date.now()) { gTimeService.set(buildTime); } } break; case kSettingsTimezoneAutoUpdateEnabled: this._timezoneAutoUpdateEnabled = aResult; if (this._timezoneAutoUpdateEnabled) { // Apply the latest cached NITZ for timezone if it's available. if (this._timezoneAutoUpdateEnabled && this._lastNitzMessage) { this.setTimezoneByNitz(this._lastNitzMessage); } } break; } }, handleError: function(aErrorMessage) { if (DEBUG) { this.debug("There was an error while reading RIL settings."); } }, // nsIRadioInterface rilContext: null, /** * List of tuples of national language identifier pairs. * * TODO: Support static/runtime settings, see bug 733331. */ enabledGsmTableTuples: [ [RIL.PDU_NL_IDENTIFIER_DEFAULT, RIL.PDU_NL_IDENTIFIER_DEFAULT], ], /** * Use 16-bit reference number for concatenated outgoint messages. * * TODO: Support static/runtime settings, see bug 733331. */ segmentRef16Bit: false, /** * Get valid SMS concatenation reference number. */ _segmentRef: 0, get nextSegmentRef() { let ref = this._segmentRef++; this._segmentRef %= (this.segmentRef16Bit ? 65535 : 255); // 0 is not a valid SMS concatenation reference number. return ref + 1; }, /** * Calculate encoded length using specified locking/single shift table * * @param message * message string to be encoded. * @param langTable * locking shift table string. * @param langShiftTable * single shift table string. * @param strict7BitEncoding * Optional. Enable Latin characters replacement with corresponding * ones in GSM SMS 7-bit default alphabet. * * @return encoded length in septets. * * @note that the algorithm used in this function must match exactly with * GsmPDUHelper#writeStringAsSeptets. */ _countGsm7BitSeptets: function(message, langTable, langShiftTable, strict7BitEncoding) { let length = 0; for (let msgIndex = 0; msgIndex < message.length; msgIndex++) { let c = message.charAt(msgIndex); if (strict7BitEncoding) { c = RIL.GSM_SMS_STRICT_7BIT_CHARMAP[c] || c; } let septet = langTable.indexOf(c); // According to 3GPP TS 23.038, section 6.1.1 General notes, "The // characters marked '1)' are not used but are displayed as a space." if (septet == RIL.PDU_NL_EXTENDED_ESCAPE) { continue; } if (septet >= 0) { length++; continue; } septet = langShiftTable.indexOf(c); if (septet < 0) { if (!strict7BitEncoding) { return -1; } // Bug 816082, when strict7BitEncoding is enabled, we should replace // characters that can't be encoded with GSM 7-Bit alphabets with '*'. c = "*"; if (langTable.indexOf(c) >= 0) { length++; } else if (langShiftTable.indexOf(c) >= 0) { length += 2; } else { // We can't even encode a '*' character with current configuration. return -1; } continue; } // According to 3GPP TS 23.038 B.2, "This code represents a control // character and therefore must not be used for language specific // characters." if (septet == RIL.PDU_NL_RESERVED_CONTROL) { continue; } // The character is not found in locking shfit table, but could be // encoded as with single shift table. Note that it's // still possible for septet to has the value of PDU_NL_EXTENDED_ESCAPE, // but we can display it as a space in this case as said in previous // comment. length += 2; } return length; }, /** * Calculate user data length of specified message string encoded in GSM 7Bit * alphabets. * * @param message * a message string to be encoded. * @param strict7BitEncoding * Optional. Enable Latin characters replacement with corresponding * ones in GSM SMS 7-bit default alphabet. * * @return null or an options object with attributes `dcs`, * `userDataHeaderLength`, `encodedFullBodyLength`, `langIndex`, * `langShiftIndex`, `segmentMaxSeq` set. * * @see #_calculateUserDataLength(). */ _calculateUserDataLength7Bit: function(message, strict7BitEncoding) { let options = null; let minUserDataSeptets = Number.MAX_VALUE; for (let i = 0; i < this.enabledGsmTableTuples.length; i++) { let [langIndex, langShiftIndex] = this.enabledGsmTableTuples[i]; const langTable = RIL.PDU_NL_LOCKING_SHIFT_TABLES[langIndex]; const langShiftTable = RIL.PDU_NL_SINGLE_SHIFT_TABLES[langShiftIndex]; let bodySeptets = this._countGsm7BitSeptets(message, langTable, langShiftTable, strict7BitEncoding); if (bodySeptets < 0) { continue; } let headerLen = 0; if (langIndex != RIL.PDU_NL_IDENTIFIER_DEFAULT) { headerLen += 3; // IEI + len + langIndex } if (langShiftIndex != RIL.PDU_NL_IDENTIFIER_DEFAULT) { headerLen += 3; // IEI + len + langShiftIndex } // Calculate full user data length, note the extra byte is for header len let headerSeptets = Math.ceil((headerLen ? headerLen + 1 : 0) * 8 / 7); let segmentSeptets = RIL.PDU_MAX_USER_DATA_7BIT; if ((bodySeptets + headerSeptets) > segmentSeptets) { headerLen += this.segmentRef16Bit ? 6 : 5; headerSeptets = Math.ceil((headerLen + 1) * 8 / 7); segmentSeptets -= headerSeptets; } let segments = Math.ceil(bodySeptets / segmentSeptets); let userDataSeptets = bodySeptets + headerSeptets * segments; if (userDataSeptets >= minUserDataSeptets) { continue; } minUserDataSeptets = userDataSeptets; options = { dcs: RIL.PDU_DCS_MSG_CODING_7BITS_ALPHABET, encodedFullBodyLength: bodySeptets, userDataHeaderLength: headerLen, langIndex: langIndex, langShiftIndex: langShiftIndex, segmentMaxSeq: segments, segmentChars: segmentSeptets, }; } return options; }, /** * Calculate user data length of specified message string encoded in UCS2. * * @param message * a message string to be encoded. * * @return an options object with attributes `dcs`, `userDataHeaderLength`, * `encodedFullBodyLength`, `segmentMaxSeq` set. * * @see #_calculateUserDataLength(). */ _calculateUserDataLengthUCS2: function(message) { let bodyChars = message.length; let headerLen = 0; let headerChars = Math.ceil((headerLen ? headerLen + 1 : 0) / 2); let segmentChars = RIL.PDU_MAX_USER_DATA_UCS2; if ((bodyChars + headerChars) > segmentChars) { headerLen += this.segmentRef16Bit ? 6 : 5; headerChars = Math.ceil((headerLen + 1) / 2); segmentChars -= headerChars; } let segments = Math.ceil(bodyChars / segmentChars); return { dcs: RIL.PDU_DCS_MSG_CODING_16BITS_ALPHABET, encodedFullBodyLength: bodyChars * 2, userDataHeaderLength: headerLen, segmentMaxSeq: segments, segmentChars: segmentChars, }; }, /** * Calculate user data length and its encoding. * * @param message * a message string to be encoded. * @param strict7BitEncoding * Optional. Enable Latin characters replacement with corresponding * ones in GSM SMS 7-bit default alphabet. * * @return an options object with some or all of following attributes set: * * @param dcs * Data coding scheme. One of the PDU_DCS_MSG_CODING_*BITS_ALPHABET * constants. * @param userDataHeaderLength * Length of embedded user data header, in bytes. The whole header * size will be userDataHeaderLength + 1; 0 for no header. * @param encodedFullBodyLength * Length of the message body when encoded with the given DCS. For * UCS2, in bytes; for 7-bit, in septets. * @param langIndex * Table index used for normal 7-bit encoded character lookup. * @param langShiftIndex * Table index used for escaped 7-bit encoded character lookup. * @param segmentMaxSeq * Max sequence number of a multi-part messages, or 1 for single one. * This number might not be accurate for a multi-part message until * it's processed by #_fragmentText() again. */ _calculateUserDataLength: function(message, strict7BitEncoding) { let options = this._calculateUserDataLength7Bit(message, strict7BitEncoding); if (!options) { options = this._calculateUserDataLengthUCS2(message); } if (DEBUG) this.debug("_calculateUserDataLength: " + JSON.stringify(options)); return options; }, /** * Fragment GSM 7-Bit encodable string for transmission. * * @param text * text string to be fragmented. * @param langTable * locking shift table string. * @param langShiftTable * single shift table string. * @param segmentSeptets * Number of available spetets per segment. * @param strict7BitEncoding * Optional. Enable Latin characters replacement with corresponding * ones in GSM SMS 7-bit default alphabet. * * @return an array of objects. See #_fragmentText() for detailed definition. */ _fragmentText7Bit: function(text, langTable, langShiftTable, segmentSeptets, strict7BitEncoding) { let ret = []; let body = "", len = 0; // If the message is empty, we only push the empty message to ret. if (text.length === 0) { ret.push({ body: text, encodedBodyLength: text.length, }); return ret; } for (let i = 0, inc = 0; i < text.length; i++) { let c = text.charAt(i); if (strict7BitEncoding) { c = RIL.GSM_SMS_STRICT_7BIT_CHARMAP[c] || c; } let septet = langTable.indexOf(c); if (septet == RIL.PDU_NL_EXTENDED_ESCAPE) { continue; } if (septet >= 0) { inc = 1; } else { septet = langShiftTable.indexOf(c); if (septet == RIL.PDU_NL_RESERVED_CONTROL) { continue; } inc = 2; if (septet < 0) { if (!strict7BitEncoding) { throw new Error("Given text cannot be encoded with GSM 7-bit Alphabet!"); } // Bug 816082, when strict7BitEncoding is enabled, we should replace // characters that can't be encoded with GSM 7-Bit alphabets with '*'. c = "*"; if (langTable.indexOf(c) >= 0) { inc = 1; } } } if ((len + inc) > segmentSeptets) { ret.push({ body: body, encodedBodyLength: len, }); body = c; len = inc; } else { body += c; len += inc; } } if (len) { ret.push({ body: body, encodedBodyLength: len, }); } return ret; }, /** * Fragment UCS2 encodable string for transmission. * * @param text * text string to be fragmented. * @param segmentChars * Number of available characters per segment. * * @return an array of objects. See #_fragmentText() for detailed definition. */ _fragmentTextUCS2: function(text, segmentChars) { let ret = []; // If the message is empty, we only push the empty message to ret. if (text.length === 0) { ret.push({ body: text, encodedBodyLength: text.length, }); return ret; } for (let offset = 0; offset < text.length; offset += segmentChars) { let str = text.substr(offset, segmentChars); ret.push({ body: str, encodedBodyLength: str.length * 2, }); } return ret; }, /** * Fragment string for transmission. * * Fragment input text string into an array of objects that contains * attributes `body`, substring for this segment, `encodedBodyLength`, * length of the encoded segment body in septets. * * @param text * Text string to be fragmented. * @param options * Optional pre-calculated option object. The output array will be * stored at options.segments if there are multiple segments. * @param strict7BitEncoding * Optional. Enable Latin characters replacement with corresponding * ones in GSM SMS 7-bit default alphabet. * * @return Populated options object. */ _fragmentText: function(text, options, strict7BitEncoding) { if (!options) { options = this._calculateUserDataLength(text, strict7BitEncoding); } if (options.dcs == RIL.PDU_DCS_MSG_CODING_7BITS_ALPHABET) { const langTable = RIL.PDU_NL_LOCKING_SHIFT_TABLES[options.langIndex]; const langShiftTable = RIL.PDU_NL_SINGLE_SHIFT_TABLES[options.langShiftIndex]; options.segments = this._fragmentText7Bit(text, langTable, langShiftTable, options.segmentChars, strict7BitEncoding); } else { options.segments = this._fragmentTextUCS2(text, options.segmentChars); } // Re-sync options.segmentMaxSeq with actual length of returning array. options.segmentMaxSeq = options.segments.length; return options; }, getSegmentInfoForText: function(text, request) { let strict7BitEncoding; try { strict7BitEncoding = Services.prefs.getBoolPref("dom.sms.strict7BitEncoding"); } catch (e) { strict7BitEncoding = false; } let options = this._fragmentText(text, null, strict7BitEncoding); let charsInLastSegment; if (options.segmentMaxSeq) { let lastSegment = options.segments[options.segmentMaxSeq - 1]; charsInLastSegment = lastSegment.encodedBodyLength; if (options.dcs == RIL.PDU_DCS_MSG_CODING_16BITS_ALPHABET) { // In UCS2 encoding, encodedBodyLength is in octets. charsInLastSegment /= 2; } } else { charsInLastSegment = 0; } request.notifySegmentInfoForTextGot(options.segmentMaxSeq, options.segmentChars, options.segmentChars - charsInLastSegment); }, getSmscAddress: function(request) { this.workerMessenger.send("getSmscAddress", null, (function(response) { if (!response.errorMsg) { request.notifyGetSmscAddress(response.smscAddress); } else { request.notifyGetSmscAddressFailed(Ci.nsIMobileMessageCallback.NOT_FOUND_ERROR); } }).bind(this)); }, sendSMS: function(number, message, silent, request) { let strict7BitEncoding; try { strict7BitEncoding = Services.prefs.getBoolPref("dom.sms.strict7BitEncoding"); } catch (e) { strict7BitEncoding = false; } let options = this._fragmentText(message, null, strict7BitEncoding); options.number = PhoneNumberUtils.normalize(number); let requestStatusReport; try { requestStatusReport = Services.prefs.getBoolPref("dom.sms.requestStatusReport"); } catch (e) { requestStatusReport = true; } options.requestStatusReport = requestStatusReport && !silent; if (options.segmentMaxSeq > 1) { options.segmentRef16Bit = this.segmentRef16Bit; options.segmentRef = this.nextSegmentRef; } let notifyResult = (function notifyResult(rv, domMessage) { if (!Components.isSuccessCode(rv)) { if (DEBUG) this.debug("Error! Fail to save sending message! rv = " + rv); request.notifySendMessageFailed( gMobileMessageDatabaseService.translateCrErrorToMessageCallbackError(rv), domMessage); Services.obs.notifyObservers(domMessage, kSmsFailedObserverTopic, null); return; } if (!silent) { Services.obs.notifyObservers(domMessage, kSmsSendingObserverTopic, null); } let connection = gMobileConnectionService.getItemByServiceId(this.clientId); // If the radio is disabled or the SIM card is not ready, just directly // return with the corresponding error code. let errorCode; let radioState = connection && connection.radioState; if (!PhoneNumberUtils.isPlainPhoneNumber(options.number)) { if (DEBUG) this.debug("Error! Address is invalid when sending SMS: " + options.number); errorCode = Ci.nsIMobileMessageCallback.INVALID_ADDRESS_ERROR; } else if (radioState == Ci.nsIMobileConnection.MOBILE_RADIO_STATE_UNKNOWN || radioState == Ci.nsIMobileConnection.MOBILE_RADIO_STATE_DISABLED) { if (DEBUG) this.debug("Error! Radio is disabled when sending SMS."); errorCode = Ci.nsIMobileMessageCallback.RADIO_DISABLED_ERROR; } else if (this.rilContext.cardState != Ci.nsIIccProvider.CARD_STATE_READY) { if (DEBUG) this.debug("Error! SIM card is not ready when sending SMS."); errorCode = Ci.nsIMobileMessageCallback.NO_SIM_CARD_ERROR; } if (errorCode) { if (silent) { request.notifySendMessageFailed(errorCode, domMessage); return; } gMobileMessageDatabaseService .setMessageDeliveryByMessageId(domMessage.id, null, DOM_MOBILE_MESSAGE_DELIVERY_ERROR, RIL.GECKO_SMS_DELIVERY_STATUS_ERROR, null, function notifyResult(rv, domMessage) { // TODO bug 832140 handle !Components.isSuccessCode(rv) request.notifySendMessageFailed(errorCode, domMessage); Services.obs.notifyObservers(domMessage, kSmsFailedObserverTopic, null); }); return; } // Keep current SMS message info for sent/delivered notifications let context = { request: request, sms: domMessage, requestStatusReport: options.requestStatusReport, silent: silent }; // This is the entry point starting to send SMS. this.workerMessenger.send("sendSMS", options, (function(context, response) { if (response.errorMsg) { // Failed to send SMS out. let error = Ci.nsIMobileMessageCallback.UNKNOWN_ERROR; switch (response.errorMsg) { case RIL.ERROR_RADIO_NOT_AVAILABLE: error = Ci.nsIMobileMessageCallback.NO_SIGNAL_ERROR; break; case RIL.ERROR_FDN_CHECK_FAILURE: error = Ci.nsIMobileMessageCallback.FDN_CHECK_ERROR; break; } if (context.silent) { // There is no way to modify nsIDOMMozSmsMessage attributes as they // are read only so we just create a new sms instance to send along // with the notification. let sms = context.sms; context.request.notifySendMessageFailed( error, gMobileMessageService.createSmsMessage(sms.id, sms.threadId, sms.iccId, DOM_MOBILE_MESSAGE_DELIVERY_ERROR, RIL.GECKO_SMS_DELIVERY_STATUS_ERROR, sms.sender, sms.receiver, sms.body, sms.messageClass, sms.timestamp, 0, 0, sms.read)); return false; } gMobileMessageDatabaseService .setMessageDeliveryByMessageId(context.sms.id, null, DOM_MOBILE_MESSAGE_DELIVERY_ERROR, RIL.GECKO_SMS_DELIVERY_STATUS_ERROR, null, function notifyResult(rv, domMessage) { // TODO bug 832140 handle !Components.isSuccessCode(rv) context.request.notifySendMessageFailed(error, domMessage); Services.obs.notifyObservers(domMessage, kSmsFailedObserverTopic, null); }); return false; } // End of send failure. if (response.deliveryStatus) { // Message delivery. gMobileMessageDatabaseService .setMessageDeliveryByMessageId(context.sms.id, null, context.sms.delivery, response.deliveryStatus, null, (function notifyResult(rv, domMessage) { // TODO bug 832140 handle !Components.isSuccessCode(rv) let topic = (response.deliveryStatus == RIL.GECKO_SMS_DELIVERY_STATUS_SUCCESS) ? kSmsDeliverySuccessObserverTopic : kSmsDeliveryErrorObserverTopic; // Broadcasting a "sms-delivery-success" system message to open apps. if (topic == kSmsDeliverySuccessObserverTopic) { this.broadcastSmsSystemMessage( Ci.nsISmsMessenger.NOTIFICATION_TYPE_DELIVERY_SUCCESS, domMessage); } // Notifying observers the delivery status is updated. Services.obs.notifyObservers(domMessage, topic, null); }).bind(this)); // Send transaction has ended completely. return false; } // End of message delivery. // Message sent. if (context.silent) { // There is no way to modify nsIDOMMozSmsMessage attributes as they // are read only so we just create a new sms instance to send along // with the notification. let sms = context.sms; context.request.notifyMessageSent( gMobileMessageService.createSmsMessage(sms.id, sms.threadId, sms.iccId, DOM_MOBILE_MESSAGE_DELIVERY_SENT, sms.deliveryStatus, sms.sender, sms.receiver, sms.body, sms.messageClass, sms.timestamp, Date.now(), 0, sms.read)); // We don't wait for SMS-DELIVER-REPORT for silent one. return false; } gMobileMessageDatabaseService .setMessageDeliveryByMessageId(context.sms.id, null, DOM_MOBILE_MESSAGE_DELIVERY_SENT, context.sms.deliveryStatus, null, (function notifyResult(rv, domMessage) { // TODO bug 832140 handle !Components.isSuccessCode(rv) if (context.requestStatusReport) { context.sms = domMessage; } this.broadcastSmsSystemMessage( Ci.nsISmsMessenger.NOTIFICATION_TYPE_SENT, domMessage); context.request.notifyMessageSent(domMessage); Services.obs.notifyObservers(domMessage, kSmsSentObserverTopic, null); }).bind(this)); // Only keep current context if we have requested for delivery report. return context.requestStatusReport; }).bind(this, context)); // End of |workerMessenger.send| callback. }).bind(this); // End of DB saveSendingMessage callback. let sendingMessage = { type: "sms", sender: this.getPhoneNumber(), receiver: number, body: message, deliveryStatusRequested: options.requestStatusReport, timestamp: Date.now(), iccId: this.getIccId() }; if (silent) { let delivery = DOM_MOBILE_MESSAGE_DELIVERY_SENDING; let deliveryStatus = RIL.GECKO_SMS_DELIVERY_STATUS_PENDING; let domMessage = gMobileMessageService.createSmsMessage(-1, // id 0, // threadId sendingMessage.iccId, delivery, deliveryStatus, sendingMessage.sender, sendingMessage.receiver, sendingMessage.body, "normal", // message class sendingMessage.timestamp, 0, 0, false); notifyResult(Cr.NS_OK, domMessage); return; } let id = gMobileMessageDatabaseService.saveSendingMessage( sendingMessage, notifyResult); }, // TODO: Bug 928861 - B2G NetworkManager: Provide a more generic function // for connecting setupDataCallByType: function(networkType) { let connHandler = gDataConnectionManager.getConnectionHandler(this.clientId); connHandler.setupDataCallByType(networkType); }, // TODO: Bug 928861 - B2G NetworkManager: Provide a more generic function // for connecting deactivateDataCallByType: function(networkType) { let connHandler = gDataConnectionManager.getConnectionHandler(this.clientId); connHandler.deactivateDataCallByType(networkType); }, // TODO: Bug 904514 - [meta] NetworkManager enhancement getDataCallStateByType: function(networkType) { let connHandler = gDataConnectionManager.getConnectionHandler(this.clientId); return connHandler.getDataCallStateByType(networkType); }, sendWorkerMessage: function(rilMessageType, message, callback) { // Special handler for setRadioEnabled. if (rilMessageType === "setRadioEnabled") { // Forward it to gRadioEnabledController. gRadioEnabledController.setRadioEnabled(this.clientId, message, callback.handleResponse); return; } if (callback) { this.workerMessenger.send(rilMessageType, message, function(response) { return callback.handleResponse(response); }); } else { this.workerMessenger.send(rilMessageType, message); } }, }; function DataCall(clientId, apnSetting) { this.clientId = clientId; this.apnProfile = { apn: apnSetting.apn, user: apnSetting.user, password: apnSetting.password, authType: apnSetting.authtype, protocol: apnSetting.protocol, roaming_protocol: apnSetting.roaming_protocol }; this.linkInfo = { cid: null, ifname: null, ips: [], prefixLengths: [], dnses: [], gateways: [] }; this.state = RIL.GECKO_NETWORK_STATE_UNKNOWN; this.requestedNetworkIfaces = []; } DataCall.prototype = { /** * Standard values for the APN connection retry process * Retry funcion: time(secs) = A * numer_of_retries^2 + B */ NETWORK_APNRETRY_FACTOR: 8, NETWORK_APNRETRY_ORIGIN: 3, NETWORK_APNRETRY_MAXRETRIES: 10, // Event timer for connection retries timer: null, // APN failed connections. Retry counter apnRetryCounter: 0, // Array to hold RILNetworkInterfaces that requested this DataCall. requestedNetworkIfaces: null, // Holds the pdp type sent to ril worker. pdptype: null, // Holds the authentication type sent to ril worker. chappap: null, dataCallError: function(message) { if (DEBUG) { this.debug("Data call error on APN " + message.apn + ": " + message.errorMsg + " (" + message.status + "), retry time: " + message.suggestedRetryTime); } this.state = RIL.GECKO_NETWORK_STATE_DISCONNECTED; if (this.requestedNetworkIfaces.length === 0) { if (DEBUG) this.debug("This DataCall is not requested anymore."); return; } // For suggestedRetryTime, the value of INT32_MAX(0x7fffffff) means no retry. if (message.suggestedRetryTime === INT32_MAX || this.isPermanentFail(message.status, message.errorMsg)) { if (DEBUG) this.debug("Data call error: no retry needed."); return; } this.retry(message.suggestedRetryTime); }, dataCallStateChanged: function(datacall) { if (DEBUG) { this.debug("Data call ID: " + datacall.cid + ", interface name: " + datacall.ifname + ", APN name: " + datacall.apn + ", state: " + datacall.state); } if (this.state == datacall.state && datacall.state != RIL.GECKO_NETWORK_STATE_CONNECTED) { return; } switch (datacall.state) { case RIL.GECKO_NETWORK_STATE_CONNECTED: if (this.state == RIL.GECKO_NETWORK_STATE_CONNECTING) { this.apnRetryCounter = 0; this.linkInfo.cid = datacall.cid; if (this.requestedNetworkIfaces.length === 0) { if (DEBUG) { this.debug("State is connected, but no network interface requested" + " this DataCall"); } this.deactivate(); return; } this.linkInfo.ifname = datacall.ifname; for (let entry of datacall.addresses) { this.linkInfo.ips.push(entry.address); this.linkInfo.prefixLengths.push(entry.prefixLength); } this.linkInfo.gateways = datacall.gateways.slice(); this.linkInfo.dnses = datacall.dnses.slice(); } else if (this.state == RIL.GECKO_NETWORK_STATE_CONNECTED) { // configuration changed. let changed = false; if (this.linkInfo.ips.length != datacall.addresses.length) { changed = true; this.linkInfo.ips = []; this.linkInfo.prefixLengths = []; for (let entry of datacall.addresses) { this.linkInfo.ips.push(entry.address); this.linkInfo.prefixLengths.push(entry.prefixLength); } } let reduceFunc = function(aRhs, aChanged, aElement, aIndex) { return aChanged || (aElement != aRhs[aIndex]); }; for (let field of ["gateways", "dnses"]) { let lhs = this.linkInfo[field], rhs = datacall[field]; if (lhs.length != rhs.length || lhs.reduce(reduceFunc.bind(null, rhs), false)) { changed = true; this.linkInfo[field] = rhs.slice(); } } if (!changed) { return; } } break; case RIL.GECKO_NETWORK_STATE_DISCONNECTED: case RIL.GECKO_NETWORK_STATE_UNKNOWN: if (this.state == RIL.GECKO_NETWORK_STATE_CONNECTED) { // Notify first on unexpected data call disconnection. this.state = datacall.state; for (let i = 0; i < this.requestedNetworkIfaces.length; i++) { this.requestedNetworkIfaces[i].notifyRILNetworkInterface(); } } this.reset(); if (this.requestedNetworkIfaces.length > 0) { if (DEBUG) { this.debug("State is disconnected/unknown, but this DataCall is" + " requested."); } this.setup(); return; } break; } this.state = datacall.state; for (let i = 0; i < this.requestedNetworkIfaces.length; i++) { this.requestedNetworkIfaces[i].notifyRILNetworkInterface(); } }, // Helpers debug: function(s) { dump("-*- DataCall[" + this.clientId + ":" + this.apnProfile.apn + "]: " + s + "\n"); }, get connected() { return this.state == RIL.GECKO_NETWORK_STATE_CONNECTED; }, isPermanentFail: function(dataFailCause, errorMsg) { // Check ril.h for 'no retry' data call fail causes. if (errorMsg === RIL.GECKO_ERROR_RADIO_NOT_AVAILABLE || errorMsg === RIL.GECKO_ERROR_INVALID_PARAMETER || dataFailCause === RIL.DATACALL_FAIL_OPERATOR_BARRED || dataFailCause === RIL.DATACALL_FAIL_MISSING_UKNOWN_APN || dataFailCause === RIL.DATACALL_FAIL_UNKNOWN_PDP_ADDRESS_TYPE || dataFailCause === RIL.DATACALL_FAIL_USER_AUTHENTICATION || dataFailCause === RIL.DATACALL_FAIL_ACTIVATION_REJECT_GGSN || dataFailCause === RIL.DATACALL_FAIL_SERVICE_OPTION_NOT_SUPPORTED || dataFailCause === RIL.DATACALL_FAIL_SERVICE_OPTION_NOT_SUBSCRIBED || dataFailCause === RIL.DATACALL_FAIL_NSAPI_IN_USE || dataFailCause === RIL.DATACALL_FAIL_ONLY_IPV4_ALLOWED || dataFailCause === RIL.DATACALL_FAIL_ONLY_IPV6_ALLOWED || dataFailCause === RIL.DATACALL_FAIL_PROTOCOL_ERRORS || dataFailCause === RIL.DATACALL_FAIL_RADIO_POWER_OFF || dataFailCause === RIL.DATACALL_FAIL_TETHERED_CALL_ACTIVE) { return true; } return false; }, inRequestedTypes: function(type) { for (let i = 0; i < this.requestedNetworkIfaces.length; i++) { if (this.requestedNetworkIfaces[i].type == type) { return true; } } return false; }, canHandleApn: function(apnSetting) { let isIdentical = this.apnProfile.apn == apnSetting.apn && (this.apnProfile.user || '') == (apnSetting.user || '') && (this.apnProfile.password || '') == (apnSetting.password || '') && (this.apnProfile.authType || '') == (apnSetting.authtype || ''); if (RILQUIRKS_HAVE_IPV6) { isIdentical = isIdentical && (this.apnProfile.protocol || '') == (apnSetting.protocol || '') && (this.apnProfile.roaming_protocol || '') == (apnSetting.roaming_protocol || ''); } return isIdentical; }, reset: function() { this.linkInfo.cid = null; this.linkInfo.ifname = null; this.linkInfo.ips = []; this.linkInfo.prefixLengths = []; this.linkInfo.dnses = []; this.linkInfo.gateways = []; this.state = RIL.GECKO_NETWORK_STATE_UNKNOWN; this.chappap = null; this.pdptype = null; }, connect: function(networkInterface) { if (DEBUG) this.debug("connect: " + networkInterface.type); if (this.requestedNetworkIfaces.indexOf(networkInterface) == -1) { this.requestedNetworkIfaces.push(networkInterface); } if (this.state == RIL.GECKO_NETWORK_STATE_CONNECTING || this.state == RIL.GECKO_NETWORK_STATE_DISCONNECTING) { return; } if (this.state == RIL.GECKO_NETWORK_STATE_CONNECTED) { // This needs to run asynchronously, to behave the same way as the case of // non-shared apn, see bug 1059110. Services.tm.currentThread.dispatch(function(state) { // Do not notify if state changed while this event was being dispatched, // the state probably was notified already or need not to be notified. if (networkInterface.state == state) { networkInterface.notifyRILNetworkInterface(); } }.bind(null, RIL.GECKO_NETWORK_STATE_CONNECTED), Ci.nsIEventTarget.DISPATCH_NORMAL); return; } // If retry mechanism is running on background, stop it since we are going // to setup data call now. if (this.timer) { this.timer.cancel(); } this.setup(); }, setup: function() { if (DEBUG) { this.debug("Going to set up data connection with APN " + this.apnProfile.apn); } let connection = gMobileConnectionService.getItemByServiceId(this.clientId); let dataInfo = connection && connection.data; if (dataInfo == null || dataInfo.state != RIL.GECKO_MOBILE_CONNECTION_STATE_REGISTERED || dataInfo.type == RIL.GECKO_MOBILE_CONNECTION_STATE_UNKNOWN) { return; } let radioTechType = dataInfo.type; let radioTechnology = RIL.GECKO_RADIO_TECH.indexOf(radioTechType); let authType = RIL.RIL_DATACALL_AUTH_TO_GECKO.indexOf(this.apnProfile.authType); // Use the default authType if the value in database is invalid. // For the case that user might not select the authentication type. if (authType == -1) { if (DEBUG) { this.debug("Invalid authType " + this.apnProfile.authtype); } authType = RIL.RIL_DATACALL_AUTH_TO_GECKO.indexOf(RIL.GECKO_DATACALL_AUTH_DEFAULT); } this.chappap = authType; let pdpType = RIL.GECKO_DATACALL_PDP_TYPE_IP; if (RILQUIRKS_HAVE_IPV6) { pdpType = !dataInfo.roaming ? this.apnProfile.protocol : this.apnProfile.roaming_protocol; if (RIL.RIL_DATACALL_PDP_TYPES.indexOf(pdpType) < 0) { if (DEBUG) { this.debug("Invalid pdpType '" + pdpType + "', using '" + RIL.GECKO_DATACALL_PDP_TYPE_DEFAULT + "'"); } pdpType = RIL.GECKO_DATACALL_PDP_TYPE_DEFAULT; } } this.pdptype = pdpType; let radioInterface = this.gRIL.getRadioInterface(this.clientId); radioInterface.sendWorkerMessage("setupDataCall", { radioTech: radioTechnology, apn: this.apnProfile.apn, user: this.apnProfile.user, passwd: this.apnProfile.password, chappap: authType, pdptype: pdpType }); this.state = RIL.GECKO_NETWORK_STATE_CONNECTING; }, retry: function(suggestedRetryTime) { let apnRetryTimer; // We will retry the connection in increasing times // based on the function: time = A * numer_of_retries^2 + B if (this.apnRetryCounter >= this.NETWORK_APNRETRY_MAXRETRIES) { this.apnRetryCounter = 0; this.timer = null; if (DEBUG) this.debug("Too many APN Connection retries - STOP retrying"); return; } // If there is a valid suggestedRetryTime, override the retry timer. if (suggestedRetryTime !== undefined && suggestedRetryTime >= 0) { apnRetryTimer = suggestedRetryTime / 1000; } else { apnRetryTimer = this.NETWORK_APNRETRY_FACTOR * (this.apnRetryCounter * this.apnRetryCounter) + this.NETWORK_APNRETRY_ORIGIN; } this.apnRetryCounter++; if (DEBUG) { this.debug("Data call - APN Connection Retry Timer (secs-counter): " + apnRetryTimer + "-" + this.apnRetryCounter); } if (this.timer == null) { // Event timer for connection retries this.timer = Cc["@mozilla.org/timer;1"].createInstance(Ci.nsITimer); } this.timer.initWithCallback(this, apnRetryTimer * 1000, Ci.nsITimer.TYPE_ONE_SHOT); }, disconnect: function(networkInterface) { if (DEBUG) this.debug("disconnect: " + networkInterface.type); let index = this.requestedNetworkIfaces.indexOf(networkInterface); if (index != -1) { this.requestedNetworkIfaces.splice(index, 1); if (this.state == RIL.GECKO_NETWORK_STATE_DISCONNECTED || this.state == RIL.GECKO_NETWORK_STATE_UNKNOWN) { if (this.timer) { this.timer.cancel(); } this.reset(); return; } // Notify the DISCONNECTED event immediately after network interface is // removed from requestedNetworkIfaces, to make the DataCall, shared or // not, to have the same behavior. Services.tm.currentThread.dispatch(function(state) { // Do not notify if state changed while this event was being dispatched, // the state probably was notified already or need not to be notified. if (networkInterface.state == state) { networkInterface.notifyRILNetworkInterface(); } }.bind(null, RIL.GECKO_NETWORK_STATE_DISCONNECTED), Ci.nsIEventTarget.DISPATCH_NORMAL); } // Only deactivate data call if no more network interface needs this // DataCall and if state is CONNECTED, for other states, we simply remove // the network interface from requestedNetworkIfaces. if (this.requestedNetworkIfaces.length > 0 || this.state != RIL.GECKO_NETWORK_STATE_CONNECTED) { return; } this.deactivate(); }, deactivate: function() { let reason = RIL.DATACALL_DEACTIVATE_NO_REASON; if (DEBUG) { this.debug("Going to disconnet data connection cid " + this.linkInfo.cid); } let radioInterface = this.gRIL.getRadioInterface(this.clientId); radioInterface.sendWorkerMessage("deactivateDataCall", { cid: this.linkInfo.cid, reason: reason }); this.state = RIL.GECKO_NETWORK_STATE_DISCONNECTING; }, // Entry method for timer events. Used to reconnect to a failed APN notify: function(timer) { this.setup(); }, shutdown: function() { if (this.timer) { this.timer.cancel(); this.timer = null; } } }; function RILNetworkInterface(dataConnectionHandler, type, apnSetting, dataCall) { if (!dataCall) { throw new Error("No dataCall for RILNetworkInterface: " + type); } this.dataConnectionHandler = dataConnectionHandler; this.type = type; this.apnSetting = apnSetting; this.dataCall = dataCall; this.enabled = false; } RILNetworkInterface.prototype = { classID: RILNETWORKINTERFACE_CID, classInfo: XPCOMUtils.generateCI({classID: RILNETWORKINTERFACE_CID, classDescription: "RILNetworkInterface", interfaces: [Ci.nsINetworkInterface, Ci.nsIRilNetworkInterface]}), QueryInterface: XPCOMUtils.generateQI([Ci.nsINetworkInterface, Ci.nsIRilNetworkInterface]), // Hold reference to DataCall object which is determined at initilization. dataCall: null, // If this RILNetworkInterface type is enabled or not. enabled: null, /** * nsINetworkInterface Implementation */ get state() { if (!this.dataCall.inRequestedTypes(this.type)) { return Ci.nsINetworkInterface.NETWORK_STATE_DISCONNECTED; } return this.dataCall.state; }, type: null, get name() { return this.dataCall.linkInfo.ifname; }, get httpProxyHost() { return this.apnSetting.proxy || ""; }, get httpProxyPort() { return this.apnSetting.port || ""; }, getAddresses: function(ips, prefixLengths) { let linkInfo = this.dataCall.linkInfo; ips.value = linkInfo.ips.slice(); prefixLengths.value = linkInfo.prefixLengths.slice(); return linkInfo.ips.length; }, getGateways: function(count) { let linkInfo = this.dataCall.linkInfo; if (count) { count.value = linkInfo.gateways.length; } return linkInfo.gateways.slice(); }, getDnses: function(count) { let linkInfo = this.dataCall.linkInfo; if (count) { count.value = linkInfo.dnses.length; } return linkInfo.dnses.slice(); }, /** * nsIRilNetworkInterface Implementation */ get serviceId() { return this.dataConnectionHandler.clientId; }, get iccId() { let iccInfo = this.dataConnectionHandler.radioInterface.rilContext.iccInfo; return iccInfo && iccInfo.iccid; }, get mmsc() { if (this.type != NETWORK_TYPE_MOBILE_MMS) { if (DEBUG) this.debug("Error! Only MMS network can get MMSC."); throw Cr.NS_ERROR_UNEXPECTED; } let mmsc = this.apnSetting.mmsc; if (!mmsc) { try { mmsc = Services.prefs.getCharPref("ril.mms.mmsc"); } catch (e) { mmsc = ""; } } return mmsc; }, get mmsProxy() { if (this.type != NETWORK_TYPE_MOBILE_MMS) { if (DEBUG) this.debug("Error! Only MMS network can get MMS proxy."); throw Cr.NS_ERROR_UNEXPECTED; } let proxy = this.apnSetting.mmsproxy; if (!proxy) { try { proxy = Services.prefs.getCharPref("ril.mms.mmsproxy"); } catch (e) { proxy = ""; } } return proxy; }, get mmsPort() { if (this.type != NETWORK_TYPE_MOBILE_MMS) { if (DEBUG) this.debug("Error! Only MMS network can get MMS port."); throw Cr.NS_ERROR_UNEXPECTED; } let port = this.apnSetting.mmsport; if (!port) { try { port = Services.prefs.getIntPref("ril.mms.mmsport"); } catch (e) { port = -1; } } return port; }, // Helpers debug: function(s) { dump("-*- RILNetworkInterface[" + this.dataConnectionHandler.clientId + ":" + this.type + "]: " + s + "\n"); }, apnSetting: null, get connected() { return this.state == Ci.nsINetworkInterface.NETWORK_STATE_CONNECTED; }, notifyRILNetworkInterface: function() { if (DEBUG) { this.debug("notifyRILNetworkInterface type: " + this.type + ", state: " + this.state); } gNetworkManager.updateNetworkInterface(this); }, connect: function() { this.enabled = true; this.dataCall.connect(this); }, disconnect: function() { if (!this.enabled) { return; } this.enabled = false; this.dataCall.disconnect(this); }, shutdown: function() { this.dataCall.shutdown(); this.dataCall = null; } }; XPCOMUtils.defineLazyServiceGetter(DataCall.prototype, "gRIL", "@mozilla.org/ril;1", "nsIRadioInterfaceLayer"); this.NSGetFactory = XPCOMUtils.generateNSGetFactory([RadioInterfaceLayer]);