gecko-dev/dom/system/gonk/ril_worker.js
2015-09-23 15:35:32 +08:00

15222 lines
482 KiB
JavaScript

/* 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.
*/
/**
* This file implements the RIL worker thread. It communicates with
* the main thread to provide a high-level API to the phone's RIL
* stack, and with the RIL IPC thread to communicate with the RIL
* device itself. These communication channels use message events as
* known from Web Workers:
*
* - postMessage()/"message" events for main thread communication
*
* - postRILMessage()/"RILMessageEvent" events for RIL IPC thread
* communication.
*
* The two main objects in this file represent individual parts of this
* communication chain:
*
* - RILMessageEvent -> Buf -> RIL -> postMessage() -> nsIRadioInterfaceLayer
* - nsIRadioInterfaceLayer -> postMessage() -> RIL -> Buf -> postRILMessage()
*
* Note: The code below is purposely lean on abstractions to be as lean in
* terms of object allocations. As a result, it may look more like C than
* JavaScript, and that's intended.
*/
/* global BufObject */
/* global TelephonyRequestQueue */
"use strict";
importScripts("ril_consts.js");
importScripts("resource://gre/modules/workers/require.js");
importScripts("ril_worker_buf_object.js");
importScripts("ril_worker_telephony_request_queue.js");
// set to true in ril_consts.js to see debug messages
var DEBUG = DEBUG_WORKER;
var GLOBAL = this;
if (!this.debug) {
// Debugging stub that goes nowhere.
this.debug = function debug(message) {
dump("RIL Worker: " + message + "\n");
};
}
// Timeout value for emergency callback mode.
const EMERGENCY_CB_MODE_TIMEOUT_MS = 300000; // 5 mins = 300000 ms.
const ICC_MAX_LINEAR_FIXED_RECORDS = 0xfe;
const GET_CURRENT_CALLS_RETRY_MAX = 3;
var RILQUIRKS_CALLSTATE_EXTRA_UINT32;
var RILQUIRKS_REQUEST_USE_DIAL_EMERGENCY_CALL;
var RILQUIRKS_SIM_APP_STATE_EXTRA_FIELDS;
var RILQUIRKS_SIGNAL_EXTRA_INT32;
var RILQUIRKS_AVAILABLE_NETWORKS_EXTRA_STRING;
// Needed for call-waiting on Peak device
var RILQUIRKS_EXTRA_UINT32_2ND_CALL;
// On the emulator we support querying the number of lock retries
var RILQUIRKS_HAVE_QUERY_ICC_LOCK_RETRY_COUNT;
// Ril quirk to Send STK Profile Download
var RILQUIRKS_SEND_STK_PROFILE_DOWNLOAD;
// Ril quirk to attach data registration on demand.
var RILQUIRKS_DATA_REGISTRATION_ON_DEMAND;
// Ril quirk to control the uicc/data subscription.
var RILQUIRKS_SUBSCRIPTION_CONTROL;
// Ril quirk to describe the SMSC address format.
var RILQUIRKS_SMSC_ADDRESS_FORMAT;
/**
* The RIL state machine.
*
* This object communicates with rild via parcels and with the main thread
* via post messages. It maintains state about the radio, ICC, calls, etc.
* and acts upon state changes accordingly.
*/
function RilObject(aContext) {
this.context = aContext;
this.telephonyRequestQueue = new TelephonyRequestQueue(this);
this.currentConferenceState = CALL_STATE_UNKNOWN;
this._pendingSentSmsMap = {};
this.pendingNetworkType = {};
this._receivedSmsCbPagesMap = {};
this._getCurrentCallsRetryCount = 0;
}
RilObject.prototype = {
context: null,
/**
* RIL version.
*/
version: null,
/**
* Call state of current conference group.
*/
currentConferenceState: null,
/**
* Outgoing messages waiting for SMS-STATUS-REPORT.
*/
_pendingSentSmsMap: null,
/**
* Marker object.
*/
pendingNetworkType: null,
/**
* Global Cell Broadcast switch.
*/
cellBroadcastDisabled: false,
/**
* Parsed Cell Broadcast search lists.
* cellBroadcastConfigs.MMI should be preserved over rild reset.
*/
cellBroadcastConfigs: null,
mergedCellBroadcastConfig: null,
_receivedSmsCbPagesMap: null,
initRILState: function() {
/**
* One of the RADIO_STATE_* constants.
*/
this.radioState = GECKO_RADIOSTATE_UNKNOWN;
/**
* True if we are on a CDMA phone.
*/
this._isCdma = false;
/**
* True if we are in emergency callback mode.
*/
this._isInEmergencyCbMode = false;
/**
* Set when radio is ready but radio tech is unknown. That is, we are
* waiting for REQUEST_VOICE_RADIO_TECH
*/
this._waitingRadioTech = false;
/**
* Card state
*/
this.cardState = GECKO_CARDSTATE_UNINITIALIZED;
/**
* Strings
*/
this.IMEI = null;
this.IMEISV = null;
this.ESN = null;
this.MEID = null;
/**
* ICC information that is not exposed to Gaia.
*/
this.iccInfoPrivate = {};
/**
* ICC information, such as MSISDN, MCC, MNC, SPN...etc.
*/
this.iccInfo = {};
/**
* CDMA specific information. ex. CDMA Network ID, CDMA System ID... etc.
*/
this.cdmaHome = null;
/**
* Application identification for apps in ICC.
*/
this.aid = null;
/**
* Application type for apps in ICC.
*/
this.appType = null;
this.networkSelectionMode = GECKO_NETWORK_SELECTION_UNKNOWN;
this.voiceRegistrationState = {};
this.dataRegistrationState = {};
/**
* List of strings identifying the network operator.
*/
this.operator = null;
/**
* String containing the baseband version.
*/
this.basebandVersion = null;
// Clean up currentCalls: rild might have restarted.
this.sendChromeMessage({
rilMessageType: "currentCalls",
calls: {}
});
// Don't clean up this._pendingSentSmsMap
// because on rild restart: we may continue with the pending segments.
/**
* Whether or not the multiple requests in requestNetworkInfo() are currently
* being processed
*/
this._processingNetworkInfo = false;
/**
* Multiple requestNetworkInfo() in a row before finishing the first
* request, hence we need to fire requestNetworkInfo() again after
* gathering all necessary stuffs. This is to make sure that ril_worker
* gets precise network information.
*/
this._needRepollNetworkInfo = false;
/**
* Pending messages to be send in batch from requestNetworkInfo()
*/
this._pendingNetworkInfo = {rilMessageType: "networkinfochanged"};
/**
* Cell Broadcast Search Lists.
*/
let cbmmi = this.cellBroadcastConfigs && this.cellBroadcastConfigs.MMI;
this.cellBroadcastConfigs = {
MMI: cbmmi || null
};
this.mergedCellBroadcastConfig = null;
/**
* True when the request to report SMS Memory Status is pending.
*/
this.pendingToReportSmsMemoryStatus = false;
this.smsStorageAvailable = true;
},
/**
* Parse an integer from a string, falling back to a default value
* if the the provided value is not a string or does not contain a valid
* number.
*
* @param string
* String to be parsed.
* @param defaultValue [optional]
* Default value to be used.
* @param radix [optional]
* A number that represents the numeral system to be used. Default 10.
*/
parseInt: function(string, defaultValue, radix) {
let number = parseInt(string, radix || 10);
if (!isNaN(number)) {
return number;
}
if (defaultValue === undefined) {
defaultValue = null;
}
return defaultValue;
},
/**
* Outgoing requests to the RIL. These can be triggered from the
* main thread via messages that look like this:
*
* {rilMessageType: "methodName",
* extra: "parameters",
* go: "here"}
*
* So if one of the following methods takes arguments, it takes only one,
* an object, which then contains all of the parameters as attributes.
* The "@param" documentation is to be interpreted accordingly.
*/
/**
* Retrieve the ICC's status.
*/
getICCStatus: function() {
this.context.Buf.simpleRequest(REQUEST_GET_SIM_STATUS);
},
/**
* Helper function for unlocking ICC locks.
*/
iccUnlockCardLock: function(options) {
switch (options.lockType) {
case GECKO_CARDLOCK_PIN:
this.enterICCPIN(options);
break;
case GECKO_CARDLOCK_PIN2:
this.enterICCPIN2(options);
break;
case GECKO_CARDLOCK_PUK:
this.enterICCPUK(options);
break;
case GECKO_CARDLOCK_PUK2:
this.enterICCPUK2(options);
break;
case GECKO_CARDLOCK_NCK:
case GECKO_CARDLOCK_NSCK:
case GECKO_CARDLOCK_NCK1:
case GECKO_CARDLOCK_NCK2:
case GECKO_CARDLOCK_HNCK:
case GECKO_CARDLOCK_CCK:
case GECKO_CARDLOCK_SPCK:
case GECKO_CARDLOCK_PCK:
case GECKO_CARDLOCK_RCCK:
case GECKO_CARDLOCK_RSPCK:
case GECKO_CARDLOCK_NCK_PUK:
case GECKO_CARDLOCK_NSCK_PUK:
case GECKO_CARDLOCK_NCK1_PUK:
case GECKO_CARDLOCK_NCK2_PUK:
case GECKO_CARDLOCK_HNCK_PUK:
case GECKO_CARDLOCK_CCK_PUK:
case GECKO_CARDLOCK_SPCK_PUK:
case GECKO_CARDLOCK_PCK_PUK:
case GECKO_CARDLOCK_RCCK_PUK: // Fall through.
case GECKO_CARDLOCK_RSPCK_PUK:
this.enterDepersonalization(options);
break;
default:
options.errorMsg = GECKO_ERROR_REQUEST_NOT_SUPPORTED;
this.sendChromeMessage(options);
}
},
/**
* Enter a PIN to unlock the ICC.
*
* @param password
* String containing the PIN.
* @param [optional] aid
* AID value.
*/
enterICCPIN: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_ENTER_SIM_PIN, options);
Buf.writeInt32(2);
Buf.writeString(options.password);
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Enter a PIN2 to unlock the ICC.
*
* @param password
* String containing the PIN2.
* @param [optional] aid
* AID value.
*/
enterICCPIN2: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_ENTER_SIM_PIN2, options);
Buf.writeInt32(2);
Buf.writeString(options.password);
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Requests a network personalization be deactivated.
*
* @param personlization
* One of CARD_PERSOSUBSTATE_*
* @param password
* String containing the password.
*/
enterDepersonalization: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_ENTER_NETWORK_DEPERSONALIZATION_CODE, options);
Buf.writeInt32(1);
Buf.writeString(options.password);
Buf.sendParcel();
},
/**
* Change the current ICC PIN number.
*
* @param password
* String containing the old PIN value
* @param newPassword
* String containing the new PIN value
* @param [optional] aid
* AID value.
*/
changeICCPIN: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_CHANGE_SIM_PIN, options);
Buf.writeInt32(3);
Buf.writeString(options.password);
Buf.writeString(options.newPassword);
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Change the current ICC PIN2 number.
*
* @param password
* String containing the old PIN2 value
* @param newPassword
* String containing the new PIN2 value
* @param [optional] aid
* AID value.
*/
changeICCPIN2: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_CHANGE_SIM_PIN2, options);
Buf.writeInt32(3);
Buf.writeString(options.password);
Buf.writeString(options.newPassword);
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Supplies ICC PUK and a new PIN to unlock the ICC.
*
* @param password
* String containing the PUK value.
* @param newPassword
* String containing the new PIN value.
* @param [optional] aid
* AID value.
*/
enterICCPUK: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_ENTER_SIM_PUK, options);
Buf.writeInt32(3);
Buf.writeString(options.password);
Buf.writeString(options.newPin);
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Supplies ICC PUK2 and a new PIN2 to unlock the ICC.
*
* @param password
* String containing the PUK2 value.
* @param newPassword
* String containing the new PIN2 value.
* @param [optional] aid
* AID value.
*/
enterICCPUK2: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_ENTER_SIM_PUK2, options);
Buf.writeInt32(3);
Buf.writeString(options.password);
Buf.writeString(options.newPin);
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Helper function for changing ICC locks.
*/
iccChangeCardLockPassword: function(options) {
switch (options.lockType) {
case GECKO_CARDLOCK_PIN:
this.changeICCPIN(options);
break;
case GECKO_CARDLOCK_PIN2:
this.changeICCPIN2(options);
break;
default:
options.errorMsg = GECKO_ERROR_REQUEST_NOT_SUPPORTED;
this.sendChromeMessage(options);
}
},
/**
* Helper function for setting the state of ICC locks.
*/
iccSetCardLockEnabled: function(options) {
switch (options.lockType) {
case GECKO_CARDLOCK_PIN: // Fall through.
case GECKO_CARDLOCK_FDN:
options.facility = GECKO_CARDLOCK_TO_FACILITY[options.lockType];
break;
default:
options.errorMsg = GECKO_ERROR_REQUEST_NOT_SUPPORTED;
this.sendChromeMessage(options);
return;
}
options.serviceClass = ICC_SERVICE_CLASS_VOICE |
ICC_SERVICE_CLASS_DATA |
ICC_SERVICE_CLASS_FAX;
this.setICCFacilityLock(options);
},
/**
* Helper function for fetching the state of ICC locks.
*/
iccGetCardLockEnabled: function(options) {
switch (options.lockType) {
case GECKO_CARDLOCK_PIN: // Fall through.
case GECKO_CARDLOCK_FDN:
options.facility = GECKO_CARDLOCK_TO_FACILITY[options.lockType];
break;
default:
options.errorMsg = GECKO_ERROR_REQUEST_NOT_SUPPORTED;
this.sendChromeMessage(options);
return;
}
options.password = ""; // For query no need to provide pin.
options.serviceClass = ICC_SERVICE_CLASS_VOICE |
ICC_SERVICE_CLASS_DATA |
ICC_SERVICE_CLASS_FAX;
this.queryICCFacilityLock(options);
},
/**
* Helper function for fetching the number of unlock retries of ICC locks.
*
* We only query the retry count when we're on the emulator. The phones do
* not support the request id and their rild doesn't return an error.
*/
iccGetCardLockRetryCount: function(options) {
if (!RILQUIRKS_HAVE_QUERY_ICC_LOCK_RETRY_COUNT) {
// Only the emulator supports this request.
options.errorMsg = GECKO_ERROR_REQUEST_NOT_SUPPORTED;
this.sendChromeMessage(options);
return;
}
switch (options.lockType) {
case GECKO_CARDLOCK_PIN:
case GECKO_CARDLOCK_PIN2:
case GECKO_CARDLOCK_PUK:
case GECKO_CARDLOCK_PUK2:
case GECKO_CARDLOCK_NCK:
case GECKO_CARDLOCK_NSCK:
case GECKO_CARDLOCK_CCK: // Fall through.
case GECKO_CARDLOCK_SPCK:
// TODO: Bug 1116072: identify the mapping between RIL_PERSOSUBSTATE_SIM_SIM
// @ ril.h and TS 27.007, clause 8.65 for GECKO_CARDLOCK_SPCK.
options.selCode = GECKO_CARDLOCK_TO_SEL_CODE[options.lockType];
break;
default:
options.errorMsg = GECKO_ERROR_REQUEST_NOT_SUPPORTED;
this.sendChromeMessage(options);
return;
}
this.queryICCLockRetryCount(options);
},
/**
* Query ICC lock retry count.
*
* @param selCode
* One of ICC_SEL_CODE_*.
* @param serviceClass
* One of ICC_SERVICE_CLASS_*.
*/
queryICCLockRetryCount: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_GET_UNLOCK_RETRY_COUNT, options);
Buf.writeInt32(1);
Buf.writeString(options.selCode);
Buf.sendParcel();
},
/**
* Query ICC facility lock.
*
* @param facility
* One of ICC_CB_FACILITY_*.
* @param password
* Password for the facility, or "" if not required.
* @param serviceClass
* One of ICC_SERVICE_CLASS_*.
* @param [optional] aid
* AID value.
*/
queryICCFacilityLock: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_QUERY_FACILITY_LOCK, options);
Buf.writeInt32(4);
Buf.writeString(options.facility);
Buf.writeString(options.password);
Buf.writeString(options.serviceClass.toString());
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Set ICC facility lock.
*
* @param facility
* One of ICC_CB_FACILITY_*.
* @param enabled
* true to enable, false to disable.
* @param password
* Password for the facility, or "" if not required.
* @param serviceClass
* One of ICC_SERVICE_CLASS_*.
* @param [optional] aid
* AID value.
*/
setICCFacilityLock: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_FACILITY_LOCK, options);
Buf.writeInt32(5);
Buf.writeString(options.facility);
Buf.writeString(options.enabled ? "1" : "0");
Buf.writeString(options.password);
Buf.writeString(options.serviceClass.toString());
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Request an ICC I/O operation.
*
* See TS 27.007 "restricted SIM" operation, "AT Command +CRSM".
* The sequence is in the same order as how libril reads this parcel,
* see the struct RIL_SIM_IO_v5 or RIL_SIM_IO_v6 defined in ril.h
*
* @param command
* The I/O command, one of the ICC_COMMAND_* constants.
* @param fileId
* The file to operate on, one of the ICC_EF_* constants.
* @param pathId
* String type, check the 'pathid' parameter from TS 27.007 +CRSM.
* @param p1, p2, p3
* Arbitrary integer parameters for the command.
* @param [optional] dataWriter
* The function for writing string parameter for the ICC_COMMAND_UPDATE_RECORD.
* @param [optional] pin2
* String containing the PIN2.
* @param [optional] aid
* AID value.
*/
iccIO: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SIM_IO, options);
Buf.writeInt32(options.command);
Buf.writeInt32(options.fileId);
Buf.writeString(options.pathId);
Buf.writeInt32(options.p1);
Buf.writeInt32(options.p2);
Buf.writeInt32(options.p3);
// Write data.
if (options.command == ICC_COMMAND_UPDATE_RECORD &&
options.dataWriter) {
options.dataWriter(options.p3);
} else {
Buf.writeString(null);
}
// Write pin2.
if (options.command == ICC_COMMAND_UPDATE_RECORD &&
options.pin2) {
Buf.writeString(options.pin2);
} else {
Buf.writeString(null);
}
Buf.writeString(options.aid || this.aid);
Buf.sendParcel();
},
/**
* Get IMSI.
*
* @param [optional] aid
* AID value.
*/
getIMSI: function(aid) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_GET_IMSI);
Buf.writeInt32(1);
Buf.writeString(aid || this.aid);
Buf.sendParcel();
},
/**
* Retrieve ICC's GID1 field.
*/
getGID1: function(options) {
options.gid1 = this.iccInfoPrivate.gid1;
this.sendChromeMessage(options);
},
/**
* Read UICC Phonebook contacts.
*
* @param contactType
* One of GECKO_CARDCONTACT_TYPE_*.
* @param requestId
* Request id from RadioInterfaceLayer.
*/
readICCContacts: function(options) {
if (!this.appType) {
options.errorMsg = CONTACT_ERR_REQUEST_NOT_SUPPORTED;
this.sendChromeMessage(options);
return;
}
this.context.ICCContactHelper.readICCContacts(
this.appType,
options.contactType,
function onsuccess(contacts) {
for (let i = 0; i < contacts.length; i++) {
let contact = contacts[i];
let pbrIndex = contact.pbrIndex || 0;
let recordIndex = pbrIndex * ICC_MAX_LINEAR_FIXED_RECORDS + contact.recordId;
contact.contactId = this.iccInfo.iccid + recordIndex;
}
// Reuse 'options' to get 'requestId' and 'contactType'.
options.contacts = contacts;
this.sendChromeMessage(options);
}.bind(this),
function onerror(errorMsg) {
options.errorMsg = errorMsg;
this.sendChromeMessage(options);
}.bind(this));
},
/**
* Update UICC Phonebook.
*
* @param contactType One of GECKO_CARDCONTACT_TYPE_*.
* @param contact The contact will be updated.
* @param pin2 PIN2 is required for updating FDN.
* @param requestId Request id from RadioInterfaceLayer.
*/
updateICCContact: function(options) {
let onsuccess = function onsuccess(updatedContact) {
let recordIndex =
updatedContact.pbrIndex * ICC_MAX_LINEAR_FIXED_RECORDS + updatedContact.recordId;
updatedContact.contactId = this.iccInfo.iccid + recordIndex;
options.contact = updatedContact;
// Reuse 'options' to get 'requestId' and 'contactType'.
this.sendChromeMessage(options);
}.bind(this);
let onerror = function onerror(errorMsg) {
options.errorMsg = errorMsg;
this.sendChromeMessage(options);
}.bind(this);
if (!this.appType || !options.contact) {
onerror(CONTACT_ERR_REQUEST_NOT_SUPPORTED );
return;
}
let contact = options.contact;
let iccid = this.iccInfo.iccid;
let isValidRecordId = false;
if (typeof contact.contactId === "string" &&
contact.contactId.startsWith(iccid)) {
let recordIndex = contact.contactId.substring(iccid.length);
contact.pbrIndex = Math.floor(recordIndex / ICC_MAX_LINEAR_FIXED_RECORDS);
contact.recordId = recordIndex % ICC_MAX_LINEAR_FIXED_RECORDS;
isValidRecordId = contact.recordId > 0 && contact.recordId < 0xff;
}
if (DEBUG) {
this.context.debug("Update ICC Contact " + JSON.stringify(contact));
}
let ICCContactHelper = this.context.ICCContactHelper;
// If contact has 'recordId' property, updates corresponding record.
// If not, inserts the contact into a free record.
if (isValidRecordId) {
ICCContactHelper.updateICCContact(
this.appType, options.contactType, contact, options.pin2, onsuccess, onerror);
} else {
ICCContactHelper.addICCContact(
this.appType, options.contactType, contact, options.pin2, onsuccess, onerror);
}
},
/**
* Check if operator name needs to be overriden by current voiceRegistrationState
* , EFOPL and EFPNN. See 3GPP TS 31.102 clause 4.2.58 EFPNN and 4.2.59 EFOPL
* for detail.
*
* @return true if operator name is overridden, false otherwise.
*/
overrideICCNetworkName: function() {
if (!this.operator) {
return false;
}
// We won't get network name using PNN and OPL if voice registration isn't
// ready.
if (!this.voiceRegistrationState.cell ||
this.voiceRegistrationState.cell.gsmLocationAreaCode == -1) {
return false;
}
let ICCUtilsHelper = this.context.ICCUtilsHelper;
let networkName = ICCUtilsHelper.getNetworkNameFromICC(
this.operator.mcc,
this.operator.mnc,
this.voiceRegistrationState.cell.gsmLocationAreaCode);
if (!networkName) {
return false;
}
if (DEBUG) {
this.context.debug("Operator names will be overriden: " +
"longName = " + networkName.fullName + ", " +
"shortName = " + networkName.shortName);
}
this.operator.longName = networkName.fullName;
this.operator.shortName = networkName.shortName;
this._sendNetworkInfoMessage(NETWORK_INFO_OPERATOR, this.operator);
return true;
},
/**
* Request the phone's radio to be enabled or disabled.
*
* @param enabled
* Boolean indicating the desired state.
*/
setRadioEnabled: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_RADIO_POWER, options);
Buf.writeInt32(1);
Buf.writeInt32(options.enabled ? 1 : 0);
Buf.sendParcel();
},
/**
* Query call waiting status.
*
*/
queryCallWaiting: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_QUERY_CALL_WAITING, options);
Buf.writeInt32(1);
// As per 3GPP TS 24.083, section 1.6 UE doesn't need to send service
// class parameter in call waiting interrogation to network.
Buf.writeInt32(ICC_SERVICE_CLASS_NONE);
Buf.sendParcel();
},
/**
* Set call waiting status.
*
* @param enabled
* Boolean indicating the desired waiting status.
* @param serviceClass
* One of ICC_SERVICE_CLASS_* constants.
*/
setCallWaiting: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_CALL_WAITING, options);
Buf.writeInt32(2);
Buf.writeInt32(options.enabled ? 1 : 0);
Buf.writeInt32(options.serviceClass);
Buf.sendParcel();
},
/**
* Queries current CLIP status.
*/
queryCLIP: function(options) {
this.context.Buf.simpleRequest(REQUEST_QUERY_CLIP, options);
},
/**
* Queries current CLIR status.
*
*/
getCLIR: function(options) {
this.context.Buf.simpleRequest(REQUEST_GET_CLIR, options);
},
/**
* Enables or disables the presentation of the calling line identity (CLI) to
* the called party when originating a call.
*
* @param options.clirMode
* One of the CLIR_* constants.
*/
setCLIR: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_CLIR, options);
Buf.writeInt32(1);
Buf.writeInt32(options.clirMode);
Buf.sendParcel();
},
/**
* Set screen state.
*
* @param on
* Boolean indicating whether the screen should be on or off.
*/
setScreenState: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SCREEN_STATE);
Buf.writeInt32(1);
Buf.writeInt32(options.on ? 1 : 0);
Buf.sendParcel();
},
getVoiceRegistrationState: function() {
this.context.Buf.simpleRequest(REQUEST_VOICE_REGISTRATION_STATE);
},
getVoiceRadioTechnology: function() {
this.context.Buf.simpleRequest(REQUEST_VOICE_RADIO_TECH);
},
getDataRegistrationState: function() {
this.context.Buf.simpleRequest(REQUEST_DATA_REGISTRATION_STATE);
},
getOperator: function() {
this.context.Buf.simpleRequest(REQUEST_OPERATOR);
},
/**
* Set the preferred network type.
*
* @param options An object contains a valid value of
* RIL_PREFERRED_NETWORK_TYPE_TO_GECKO as its `type` attribute.
*/
setPreferredNetworkType: function(options) {
let networkType = options.type;
if (networkType < 0 || networkType >= RIL_PREFERRED_NETWORK_TYPE_TO_GECKO.length) {
options.errorMsg = GECKO_ERROR_INVALID_PARAMETER;
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_PREFERRED_NETWORK_TYPE, options);
Buf.writeInt32(1);
Buf.writeInt32(networkType);
Buf.sendParcel();
},
/**
* Get the preferred network type.
*/
getPreferredNetworkType: function(options) {
this.context.Buf.simpleRequest(REQUEST_GET_PREFERRED_NETWORK_TYPE, options);
},
/**
* Request neighboring cell ids in GSM network.
*/
getNeighboringCellIds: function(options) {
this.context.Buf.simpleRequest(REQUEST_GET_NEIGHBORING_CELL_IDS, options);
},
/**
* Request all of the current cell information known to the radio.
*/
getCellInfoList: function(options) {
this.context.Buf.simpleRequest(REQUEST_GET_CELL_INFO_LIST, options);
},
/**
* Request various states about the network.
*/
requestNetworkInfo: function() {
if (this._processingNetworkInfo) {
if (DEBUG) {
this.context.debug("Network info requested, but we're already " +
"requesting network info.");
}
this._needRepollNetworkInfo = true;
return;
}
if (DEBUG) this.context.debug("Requesting network info");
this._processingNetworkInfo = true;
this.getVoiceRegistrationState();
this.getDataRegistrationState(); //TODO only GSM
this.getOperator();
this.getNetworkSelectionMode();
this.getSignalStrength();
},
/**
* Get the available networks
*/
getAvailableNetworks: function(options) {
if (DEBUG) this.context.debug("Getting available networks");
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_QUERY_AVAILABLE_NETWORKS, options);
Buf.sendParcel();
},
/**
* Request the radio's network selection mode
*/
getNetworkSelectionMode: function() {
if (DEBUG) this.context.debug("Getting network selection mode");
this.context.Buf.simpleRequest(REQUEST_QUERY_NETWORK_SELECTION_MODE);
},
/**
* Tell the radio to automatically choose a voice/data network
*/
selectNetworkAuto: function(options) {
if (DEBUG) this.context.debug("Setting automatic network selection");
this.context.Buf.simpleRequest(REQUEST_SET_NETWORK_SELECTION_AUTOMATIC, options);
},
/**
* Set the roaming preference mode
*/
setRoamingPreference: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_CDMA_SET_ROAMING_PREFERENCE, options);
Buf.writeInt32(1);
Buf.writeInt32(options.mode);
Buf.sendParcel();
},
/**
* Get the roaming preference mode
*/
queryRoamingPreference: function(options) {
this.context.Buf.simpleRequest(REQUEST_CDMA_QUERY_ROAMING_PREFERENCE, options);
},
/**
* Set the voice privacy mode
*/
setVoicePrivacyMode: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE, options);
Buf.writeInt32(1);
Buf.writeInt32(options.enabled ? 1 : 0);
Buf.sendParcel();
},
/**
* Get the voice privacy mode
*/
queryVoicePrivacyMode: function(options) {
this.context.Buf.simpleRequest(REQUEST_CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE, options);
},
/**
* Open Logical UICC channel (aid) for Secure Element access
*/
iccOpenChannel: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SIM_OPEN_CHANNEL, options);
Buf.writeString(options.aid);
Buf.sendParcel();
},
/**
* Exchange APDU data on an open Logical UICC channel
*/
iccExchangeAPDU: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SIM_TRANSMIT_APDU_CHANNEL, options);
Buf.writeInt32(options.channel);
Buf.writeInt32(options.apdu.cla);
Buf.writeInt32(options.apdu.command);
Buf.writeInt32(options.apdu.p1);
Buf.writeInt32(options.apdu.p2);
Buf.writeInt32(options.apdu.p3);
Buf.writeString(options.apdu.data);
Buf.sendParcel();
},
/**
* Close Logical UICC channel
*/
iccCloseChannel: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SIM_CLOSE_CHANNEL, options);
Buf.writeInt32(1);
Buf.writeInt32(options.channel);
Buf.sendParcel();
},
/**
* Get UICC service state
*/
getIccServiceState: function(options) {
switch (options.service) {
case GECKO_CARDSERVICE_FDN:
let ICCUtilsHelper = this.context.ICCUtilsHelper;
options.result = ICCUtilsHelper.isICCServiceAvailable("FDN");
break;
default:
options.errorMsg = GECKO_ERROR_REQUEST_NOT_SUPPORTED;
break;
}
this.sendChromeMessage(options);
},
/**
* Enable/Disable UICC subscription
*/
setUiccSubscription: function(options) {
if (DEBUG) {
this.context.debug("setUiccSubscription: " + JSON.stringify(options));
}
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_UICC_SUBSCRIPTION, options);
Buf.writeInt32(this.context.clientId);
Buf.writeInt32(options.appIndex);
Buf.writeInt32(this.context.clientId);
Buf.writeInt32(options.enabled ? 1 : 0);
Buf.sendParcel();
},
/**
* Tell the radio to choose a specific voice/data network
*/
selectNetwork: function(options) {
if (DEBUG) {
this.context.debug("Setting manual network selection: " +
options.mcc + ", " + options.mnc);
}
let numeric = (options.mcc && options.mnc) ? options.mcc + options.mnc : null;
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_NETWORK_SELECTION_MANUAL, options);
Buf.writeString(numeric);
Buf.sendParcel();
},
/**
* Get the signal strength.
*/
getSignalStrength: function() {
this.context.Buf.simpleRequest(REQUEST_SIGNAL_STRENGTH);
},
getIMEI: function(options) {
// A device's IMEI can't change, so we only need to request it once.
if (this.IMEI) {
if (options && options.rilMessageType) {
options.imei = this.IMEI;
this.sendChromeMessage(options);
}
return;
}
this.context.Buf.simpleRequest(REQUEST_GET_IMEI, options);
},
getIMEISV: function() {
this.context.Buf.simpleRequest(REQUEST_GET_IMEISV);
},
getDeviceIdentity: function() {
this.context.Buf.simpleRequest(REQUEST_DEVICE_IDENTITY);
},
getBasebandVersion: function() {
this.context.Buf.simpleRequest(REQUEST_BASEBAND_VERSION);
},
sendExitEmergencyCbModeRequest: function(options) {
this.context.Buf.simpleRequest(REQUEST_EXIT_EMERGENCY_CALLBACK_MODE, options);
},
getCdmaSubscription: function() {
this.context.Buf.simpleRequest(REQUEST_CDMA_SUBSCRIPTION);
},
exitEmergencyCbMode: function(options) {
// The function could be called by an API from RadioInterfaceLayer or by
// ril_worker itself. From ril_worker, we won't pass the parameter
// 'options'. In this case, it is marked as internal.
if (!options) {
options = {internal: true};
}
this._cancelEmergencyCbModeTimeout();
this.sendExitEmergencyCbModeRequest(options);
},
/**
* Dial a non-emergency number.
*
* @param isEmergency
* Whether the number is an emergency number.
* @param number
* String containing the number to dial.
* @param clirMode
* Integer for showing/hidding the caller Id to the called party.
* @param uusInfo
* Integer doing something XXX TODO
*/
dial: function(options) {
if (options.isEmergency) {
options.request = RILQUIRKS_REQUEST_USE_DIAL_EMERGENCY_CALL ?
REQUEST_DIAL_EMERGENCY_CALL : REQUEST_DIAL;
} else {
options.request = REQUEST_DIAL;
// Exit emergency callback mode when user dial a non-emergency call.
if (this._isInEmergencyCbMode) {
this.exitEmergencyCbMode();
}
}
this.telephonyRequestQueue.push(options.request, () => {
let Buf = this.context.Buf;
Buf.newParcel(options.request, options);
Buf.writeString(options.number);
Buf.writeInt32(options.clirMode || 0);
Buf.writeInt32(options.uusInfo || 0);
// TODO Why do we need this extra 0? It was put it in to make this
// match the format of the binary message.
Buf.writeInt32(0);
Buf.sendParcel();
});
},
/**
* CDMA flash.
*
* @param featureStr (optional)
* Dialing number when the command is used for three-way-calling
*/
cdmaFlash: function(options) {
let Buf = this.context.Buf;
options.request = REQUEST_CDMA_FLASH;
Buf.newParcel(options.request, options);
Buf.writeString(options.featureStr || "");
Buf.sendParcel();
},
/**
* Hang up the phone.
*
* @param callIndex
* Call index (1-based) as reported by REQUEST_GET_CURRENT_CALLS.
*/
hangUpCall: function(options) {
this.telephonyRequestQueue.push(REQUEST_HANGUP, () => {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_HANGUP, options);
Buf.writeInt32(1);
Buf.writeInt32(options.callIndex);
Buf.sendParcel();
});
},
hangUpForeground: function(options) {
this.telephonyRequestQueue.push(REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND, () => {
this.context.Buf.simpleRequest(REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND,
options);
});
},
hangUpBackground: function(options) {
this.telephonyRequestQueue.push(REQUEST_HANGUP_WAITING_OR_BACKGROUND, () => {
this.context.Buf.simpleRequest(REQUEST_HANGUP_WAITING_OR_BACKGROUND,
options);
});
},
switchActiveCall: function(options) {
this.telephonyRequestQueue.push(REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE, () => {
this.context.Buf.simpleRequest(REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE,
options);
});
},
udub: function(options) {
this.telephonyRequestQueue.push(REQUEST_UDUB, () => {
this.context.Buf.simpleRequest(REQUEST_UDUB, options);
});
},
answerCall: function(options) {
this.telephonyRequestQueue.push(REQUEST_ANSWER, () => {
this.context.Buf.simpleRequest(REQUEST_ANSWER, options);
});
},
conferenceCall: function(options) {
this.telephonyRequestQueue.push(REQUEST_CONFERENCE, () => {
this.context.Buf.simpleRequest(REQUEST_CONFERENCE, options);
});
},
separateCall: function(options) {
this.telephonyRequestQueue.push(REQUEST_SEPARATE_CONNECTION, () => {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SEPARATE_CONNECTION, options);
Buf.writeInt32(1);
Buf.writeInt32(options.callIndex);
Buf.sendParcel();
});
},
/**
* Get current calls.
*/
getCurrentCalls: function(options) {
this.telephonyRequestQueue.push(REQUEST_GET_CURRENT_CALLS, () => {
this.context.Buf.simpleRequest(REQUEST_GET_CURRENT_CALLS, options);
});
},
/**
* Mute or unmute the radio.
*
* @param mute
* Boolean to indicate whether to mute or unmute the radio.
*/
setMute: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_MUTE);
Buf.writeInt32(1);
Buf.writeInt32(options.muted ? 1 : 0);
Buf.sendParcel();
},
/**
* Send an SMS.
*
* The `options` parameter object should contain the following attributes:
*
* @param number
* String containing the recipient number.
* @param body
* String containing the message text.
* @param envelopeId
* Numeric value identifying the sms request.
*/
sendSMS: function(options) {
options.langIndex = options.langIndex || PDU_NL_IDENTIFIER_DEFAULT;
options.langShiftIndex = options.langShiftIndex || PDU_NL_IDENTIFIER_DEFAULT;
if (!options.segmentSeq) {
// Fist segment to send
options.segmentSeq = 1;
options.body = options.segments[0].body;
options.encodedBodyLength = options.segments[0].encodedBodyLength;
}
let Buf = this.context.Buf;
if (this._isCdma) {
Buf.newParcel(REQUEST_CDMA_SEND_SMS, options);
this.context.CdmaPDUHelper.writeMessage(options);
} else {
Buf.newParcel(REQUEST_SEND_SMS, options);
Buf.writeInt32(2);
Buf.writeString(options.SMSC);
this.context.GsmPDUHelper.writeMessage(options);
}
Buf.sendParcel();
},
/**
* Acknowledge the receipt and handling of an SMS.
*
* @param success
* Boolean indicating whether the message was successfuly handled.
* @param cause
* SMS_* constant indicating the reason for unsuccessful handling.
*/
acknowledgeGsmSms: function(success, cause) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SMS_ACKNOWLEDGE);
Buf.writeInt32(2);
Buf.writeInt32(success ? 1 : 0);
Buf.writeInt32(cause);
Buf.sendParcel();
},
/**
* Acknowledge the receipt and handling of an SMS.
*
* @param success
* Boolean indicating whether the message was successfuly handled.
*/
ackSMS: function(options) {
if (options.result == PDU_FCS_RESERVED) {
return;
}
if (this._isCdma) {
this.acknowledgeCdmaSms(options.result == PDU_FCS_OK, options.result);
} else {
this.acknowledgeGsmSms(options.result == PDU_FCS_OK, options.result);
}
},
/**
* Acknowledge the receipt and handling of a CDMA SMS.
*
* @param success
* Boolean indicating whether the message was successfuly handled.
* @param cause
* SMS_* constant indicating the reason for unsuccessful handling.
*/
acknowledgeCdmaSms: function(success, cause) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_CDMA_SMS_ACKNOWLEDGE);
Buf.writeInt32(success ? 0 : 1);
Buf.writeInt32(cause);
Buf.sendParcel();
},
/**
* Update received MWI into EF_MWIS.
*/
updateMwis: function(options) {
if (this.context.ICCUtilsHelper.isICCServiceAvailable("MWIS")) {
this.context.SimRecordHelper.updateMWIS(options.mwi);
}
},
/**
* Report SMS storage status to modem.
*/
_updateSmsMemoryStatus: function() {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_REPORT_SMS_MEMORY_STATUS);
Buf.writeInt32(1);
Buf.writeInt32(this.smsStorageAvailable ? 1 : 0);
Buf.sendParcel();
},
reportSmsMemoryStatus: function(options) {
this.pendingToReportSmsMemoryStatus = true;
this.smsStorageAvailable = options.isAvailable;
this._updateSmsMemoryStatus();
},
setCellBroadcastDisabled: function(options) {
this.cellBroadcastDisabled = options.disabled;
// If |this.mergedCellBroadcastConfig| is null, either we haven't finished
// reading required SIM files, or no any channel is ever configured. In
// the former case, we'll call |this.updateCellBroadcastConfig()| later
// with correct configs; in the latter case, we don't bother resetting CB
// to disabled again.
if (this.mergedCellBroadcastConfig) {
this.updateCellBroadcastConfig();
}
},
setCellBroadcastSearchList: function(options) {
let getSearchListStr = function(aSearchList) {
if (typeof aSearchList === "string" || aSearchList instanceof String) {
return aSearchList;
}
// TODO: Set search list for CDMA/GSM individually. Bug 990926
let prop = this._isCdma ? "cdma" : "gsm";
return aSearchList && aSearchList[prop];
}.bind(this);
try {
let str = getSearchListStr(options.searchList);
this.cellBroadcastConfigs.MMI = this._convertCellBroadcastSearchList(str);
} catch (e) {
if (DEBUG) {
this.context.debug("Invalid Cell Broadcast search list: " + e);
}
options.errorMsg = GECKO_ERROR_UNSPECIFIED_ERROR;
}
this.sendChromeMessage(options);
if (options.errorMsg) {
return;
}
this._mergeAllCellBroadcastConfigs();
},
updateCellBroadcastConfig: function() {
let activate = !this.cellBroadcastDisabled &&
(this.mergedCellBroadcastConfig != null) &&
(this.mergedCellBroadcastConfig.length > 0);
if (activate) {
this.setSmsBroadcastConfig(this.mergedCellBroadcastConfig);
} else {
// It's unnecessary to set config first if we're deactivating.
this.setSmsBroadcastActivation(false);
}
},
setGsmSmsBroadcastConfig: function(config) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_GSM_SET_BROADCAST_SMS_CONFIG);
let numConfigs = config ? config.length / 2 : 0;
Buf.writeInt32(numConfigs);
for (let i = 0; i < config.length;) {
// convert [from, to) to [from, to - 1]
Buf.writeInt32(config[i++]);
Buf.writeInt32(config[i++] - 1);
Buf.writeInt32(0x00);
Buf.writeInt32(0xFF);
Buf.writeInt32(1);
}
Buf.sendParcel();
},
/**
* Send CDMA SMS broadcast config.
*
* @see 3GPP2 C.R1001 Sec. 9.2 and 9.3
*/
setCdmaSmsBroadcastConfig: function(config) {
let Buf = this.context.Buf;
// |config| is an array of half-closed range: [[from, to), [from, to), ...].
// It will be further decomposed, ex: [1, 4) => 1, 2, 3.
Buf.newParcel(REQUEST_CDMA_SET_BROADCAST_SMS_CONFIG);
let numConfigs = 0;
for (let i = 0; i < config.length; i += 2) {
numConfigs += (config[i+1] - config[i]);
}
Buf.writeInt32(numConfigs);
for (let i = 0; i < config.length;) {
let begin = config[i++];
let end = config[i++];
for (let j = begin; j < end; ++j) {
Buf.writeInt32(j);
Buf.writeInt32(0); // Language Indicator: Unknown or unspecified.
Buf.writeInt32(1);
}
}
Buf.sendParcel();
},
setSmsBroadcastConfig: function(config) {
if (this._isCdma) {
this.setCdmaSmsBroadcastConfig(config);
} else {
this.setGsmSmsBroadcastConfig(config);
}
},
setSmsBroadcastActivation: function(activate) {
let parcelType = this._isCdma ? REQUEST_CDMA_SMS_BROADCAST_ACTIVATION :
REQUEST_GSM_SMS_BROADCAST_ACTIVATION;
let Buf = this.context.Buf;
Buf.newParcel(parcelType);
Buf.writeInt32(1);
// See hardware/ril/include/telephony/ril.h, 0 - Activate, 1 - Turn off.
Buf.writeInt32(activate ? 0 : 1);
Buf.sendParcel();
},
/**
* Start a DTMF Tone.
*
* @param dtmfChar
* DTMF signal to send, 0-9, *, +
*/
startTone: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_DTMF_START, options);
Buf.writeString(options.dtmfChar);
Buf.sendParcel();
},
stopTone: function() {
this.context.Buf.simpleRequest(REQUEST_DTMF_STOP);
},
/**
* Send a DTMF tone.
*
* @param dtmfChar
* DTMF signal to send, 0-9, *, +
*/
sendTone: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_DTMF);
Buf.writeString(options.dtmfChar);
Buf.sendParcel();
},
/**
* Get the Short Message Service Center address.
*/
getSmscAddress: function(options) {
this.context.Buf.simpleRequest(REQUEST_GET_SMSC_ADDRESS, options);
},
/**
* Set the Short Message Service Center address.
*
* @param smscAddress
* Number part of the SMSC address.
* @param typeOfNumber
* Type of number in integer, as defined in
* |Table 10.5.118: Called party BCD number| of 3GPP TS 24.008.
* @param numberPlanIdentification
* The index of number plan identification value in
* CALLED_PARTY_BCD_NPI array.
*/
setSmscAddress: function(options) {
let ton = options.typeOfNumber;
let npi = CALLED_PARTY_BCD_NPI[options.numberPlanIdentification];
// If any of the mandatory arguments is not available, return an error
// immediately.
if (ton === undefined || npi === undefined || !options.smscAddress) {
options.errorMsg = GECKO_ERROR_INVALID_PARAMETER;
this.sendChromeMessage(options);
return;
}
// Remove all illegal characters in the number string for user-input fault
// tolerance.
let numStart = options.smscAddress[0] === "+" ? 1 : 0;
let number = options.smscAddress.substring(0, numStart) +
options.smscAddress.substring(numStart)
.replace(/[^0-9*#abc]/ig, "");
// If the filtered number is an empty string, return an error immediately.
if (number.length === 0) {
options.errorMsg = GECKO_ERROR_INVALID_PARAMETER;
this.sendChromeMessage(options);
return;
}
// Init parcel.
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_SMSC_ADDRESS, options);
// +---+-----------+---------------+
// | 1 | TON | NPI |
// +---+-----------+---------------+
let tosca = (0x1 << 7) + (ton << 4) + npi;
if (RILQUIRKS_SMSC_ADDRESS_FORMAT === "pdu") {
let pduHelper = this.context.GsmPDUHelper;
// Remove the preceding '+', and covert the special BCD digits defined in
// |Called party BCD number| of 3GPP TS 24.008 to corresponding
// hexadecimal values (refer the following table).
//
// +=========+=======+=====+
// | value | digit | hex |
// +========================
// | 1 0 1 0 | * | 0xA |
// | 1 0 1 1 | # | 0xB |
// | 1 1 0 0 | a | 0xC |
// | 1 1 0 1 | b | 0xD |
// | 1 1 1 0 | c | 0xE |
// +=========+=======+=====+
//
// The replace order is reversed intentionally, because if the digits are
// replaced in ascending order, "#" will be converted to "b" and then be
// converted again to "d", which generates incorrect result.
let pureNumber = number.substring(numStart)
.replace(/c/ig, "e")
.replace(/b/ig, "d")
.replace(/a/ig, "c")
.replace(/\#/g, "b")
.replace(/\*/g, "a");
// address length and string length
let length = Math.ceil(pureNumber.length / 2) + 1; // +1 octet for TOA
let strlen = length * 2 + 2; // +2 semi-octets for length octet
Buf.writeInt32(strlen);
pduHelper.writeHexOctet(length);
pduHelper.writeHexOctet(tosca);
pduHelper.writeSwappedNibbleBCD(pureNumber);
Buf.writeStringDelimiter(strlen);
} else /* RILQUIRKS_SMSC_ADDRESS_FORMAT === "text" */ {
let sca;
sca = '"' + number + '"' + ',' + tosca;
Buf.writeString(sca);
}
Buf.sendParcel();
},
/**
* Setup a data call.
*
* @param radioTech
* Integer to indicate radio technology.
* DATACALL_RADIOTECHNOLOGY_CDMA => CDMA.
* DATACALL_RADIOTECHNOLOGY_GSM => GSM.
* @param apn
* String containing the name of the APN to connect to.
* @param user
* String containing the username for the APN.
* @param passwd
* String containing the password for the APN.
* @param chappap
* Integer containing CHAP/PAP auth type.
* DATACALL_AUTH_NONE => PAP and CHAP is never performed.
* DATACALL_AUTH_PAP => PAP may be performed.
* DATACALL_AUTH_CHAP => CHAP may be performed.
* DATACALL_AUTH_PAP_OR_CHAP => PAP / CHAP may be performed.
* @param pdptype
* String containing PDP type to request. ("IP", "IPV6", ...)
*/
setupDataCall: function(options) {
// From ./hardware/ril/include/telephony/ril.h:
// ((const char **)data)[0] Radio technology to use: 0-CDMA, 1-GSM/UMTS, 2...
// for values above 2 this is RIL_RadioTechnology + 2.
//
// From frameworks/base/telephony/java/com/android/internal/telephony/DataConnection.java:
// if the mRilVersion < 6, radio technology must be GSM/UMTS or CDMA.
// Otherwise, it must be + 2
//
// See also bug 901232 and 867873
let radioTech = options.radioTech + 2;
let Buf = this.context.Buf;
let token = Buf.newParcel(REQUEST_SETUP_DATA_CALL, options);
Buf.writeInt32(7);
Buf.writeString(radioTech.toString());
Buf.writeString(DATACALL_PROFILE_DEFAULT.toString());
Buf.writeString(options.apn);
Buf.writeString(options.user);
Buf.writeString(options.passwd);
Buf.writeString(options.chappap.toString());
Buf.writeString(options.pdptype);
Buf.sendParcel();
return token;
},
/**
* Deactivate a data call.
*
* @param cid
* String containing CID.
* @param reason
* One of DATACALL_DEACTIVATE_* constants.
*/
deactivateDataCall: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_DEACTIVATE_DATA_CALL, options);
Buf.writeInt32(2);
Buf.writeString(options.cid.toString());
Buf.writeString(options.reason !== undefined ?
options.reason.toString() :
DATACALL_DEACTIVATE_NO_REASON.toString());
Buf.sendParcel();
},
/**
* Get a list of data calls.
*/
getDataCallList: function(options) {
this.context.Buf.simpleRequest(REQUEST_DATA_CALL_LIST, options);
},
_attachDataRegistration: false,
/**
* Manually attach/detach data registration.
*
* @param attach
* Boolean value indicating attach or detach.
*/
setDataRegistration: function(options) {
this._attachDataRegistration = options.attach;
if (RILQUIRKS_DATA_REGISTRATION_ON_DEMAND) {
let request = options.attach ? RIL_REQUEST_GPRS_ATTACH :
RIL_REQUEST_GPRS_DETACH;
this.context.Buf.simpleRequest(request, options);
return;
} else if (RILQUIRKS_SUBSCRIPTION_CONTROL && options.attach) {
this.context.Buf.simpleRequest(REQUEST_SET_DATA_SUBSCRIPTION, options);
return;
}
// We don't really send a request to rild, so instantly reply success to
// RadioInterfaceLayer.
this.sendChromeMessage(options);
},
/**
* Get failure casue code for the most recently failed PDP context.
*/
getFailCause: function(options) {
this.context.Buf.simpleRequest(REQUEST_LAST_CALL_FAIL_CAUSE, options);
},
/**
* Send USSD.
*
* @param ussd
* String containing the USSD code.
*/
sendUSSD: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SEND_USSD, options);
Buf.writeString(options.ussd);
Buf.sendParcel();
},
/**
* Cancel pending USSD.
*/
cancelUSSD: function(options) {
this.context.Buf.simpleRequest(REQUEST_CANCEL_USSD, options);
},
/**
* Queries current call forward rules.
*
* @param reason
* One of CALL_FORWARD_REASON_* constants.
* @param serviceClass
* One of ICC_SERVICE_CLASS_* constants.
* @param number
* Phone number of forwarding address.
*/
queryCallForwardStatus: function(options) {
let Buf = this.context.Buf;
let number = options.number || "";
Buf.newParcel(REQUEST_QUERY_CALL_FORWARD_STATUS, options);
Buf.writeInt32(CALL_FORWARD_ACTION_QUERY_STATUS);
Buf.writeInt32(options.reason);
Buf.writeInt32(options.serviceClass || ICC_SERVICE_CLASS_NONE);
Buf.writeInt32(this._toaFromString(number));
Buf.writeString(number);
Buf.writeInt32(0);
Buf.sendParcel();
},
/**
* Configures call forward rule.
*
* @param action
* One of CALL_FORWARD_ACTION_* constants.
* @param reason
* One of CALL_FORWARD_REASON_* constants.
* @param serviceClass
* One of ICC_SERVICE_CLASS_* constants.
* @param number
* Phone number of forwarding address.
* @param timeSeconds
* Time in seconds to wait beforec all is forwarded.
*/
setCallForward: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_SET_CALL_FORWARD, options);
Buf.writeInt32(options.action);
Buf.writeInt32(options.reason);
Buf.writeInt32(options.serviceClass);
Buf.writeInt32(this._toaFromString(options.number));
Buf.writeString(options.number);
Buf.writeInt32(options.timeSeconds);
Buf.sendParcel();
},
/**
* Queries current call barring rules.
*
* @param program
* One of CALL_BARRING_PROGRAM_* constants.
* @param serviceClass
* One of ICC_SERVICE_CLASS_* constants.
*/
queryCallBarringStatus: function(options) {
options.facility = CALL_BARRING_PROGRAM_TO_FACILITY[options.program];
options.password = ""; // For query no need to provide it.
// For some operators, querying specific serviceClass doesn't work. We use
// serviceClass 0 instead, and then process the response to extract the
// answer for queryServiceClass.
options.queryServiceClass = options.serviceClass;
options.serviceClass = 0;
this.queryICCFacilityLock(options);
},
/**
* Configures call barring rule.
*
* @param program
* One of CALL_BARRING_PROGRAM_* constants.
* @param enabled
* Enable or disable the call barring.
* @param password
* Barring password.
* @param serviceClass
* One of ICC_SERVICE_CLASS_* constants.
*/
setCallBarring: function(options) {
options.facility = CALL_BARRING_PROGRAM_TO_FACILITY[options.program];
this.setICCFacilityLock(options);
},
/**
* Change call barring facility password.
*
* @param pin
* Old password.
* @param newPin
* New password.
*/
changeCallBarringPassword: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_CHANGE_BARRING_PASSWORD, options);
Buf.writeInt32(3);
// Set facility to ICC_CB_FACILITY_BA_ALL by following TS.22.030 clause
// 6.5.4 and Table B.1.
Buf.writeString(ICC_CB_FACILITY_BA_ALL);
Buf.writeString(options.pin);
Buf.writeString(options.newPin);
Buf.sendParcel();
},
/**
* Handle STK CALL_SET_UP request.
*
* @param hasConfirmed
* Does use have confirmed the call requested from ICC?
*/
stkHandleCallSetup: function(options) {
let Buf = this.context.Buf;
Buf.newParcel(REQUEST_STK_HANDLE_CALL_SETUP_REQUESTED_FROM_SIM);
Buf.writeInt32(1);
Buf.writeInt32(options.hasConfirmed ? 1 : 0);
Buf.sendParcel();
},
/**
* Send STK Profile Download.
*
* @param profile Profile supported by ME.
*/
sendStkTerminalProfile: function(profile) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
Buf.newParcel(REQUEST_STK_SET_PROFILE);
Buf.writeInt32(profile.length * 2);
for (let i = 0; i < profile.length; i++) {
GsmPDUHelper.writeHexOctet(profile[i]);
}
Buf.writeInt32(0);
Buf.sendParcel();
},
/**
* Send STK terminal response.
*
* @param command
* @param deviceIdentities
* @param resultCode
* @param [optional] additionalInformation
* @param [optional] itemIdentifier
* @param [optional] input
* @param [optional] isYesNo
* @param [optional] hasConfirmed
* @param [optional] localInfo
* @param [optional] timer
*/
sendStkTerminalResponse: function(response) {
if (response.hasConfirmed !== undefined) {
this.stkHandleCallSetup(response);
return;
}
let Buf = this.context.Buf;
let ComprehensionTlvHelper = this.context.ComprehensionTlvHelper;
let GsmPDUHelper = this.context.GsmPDUHelper;
let command = response.command;
Buf.newParcel(REQUEST_STK_SEND_TERMINAL_RESPONSE);
// 1st mark for Parcel size
Buf.startCalOutgoingSize(function(size) {
// Parcel size is in string length, which costs 2 uint8 per char.
Buf.writeInt32(size / 2);
});
// Command Details
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_COMMAND_DETAILS |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(3);
if (command) {
GsmPDUHelper.writeHexOctet(command.commandNumber);
GsmPDUHelper.writeHexOctet(command.typeOfCommand);
GsmPDUHelper.writeHexOctet(command.commandQualifier);
} else {
GsmPDUHelper.writeHexOctet(0x00);
GsmPDUHelper.writeHexOctet(0x00);
GsmPDUHelper.writeHexOctet(0x00);
}
// Device Identifier
// According to TS102.223/TS31.111 section 6.8 Structure of
// TERMINAL RESPONSE, "For all SIMPLE-TLV objects with Min=N,
// the ME should set the CR(comprehension required) flag to
// comprehension not required.(CR=0)"
// Since DEVICE_IDENTITIES and DURATION TLVs have Min=N,
// the CR flag is not set.
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_DEVICE_ID);
GsmPDUHelper.writeHexOctet(2);
GsmPDUHelper.writeHexOctet(STK_DEVICE_ID_ME);
GsmPDUHelper.writeHexOctet(STK_DEVICE_ID_SIM);
// Result
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_RESULT |
COMPREHENSIONTLV_FLAG_CR);
if ("additionalInformation" in response) {
// In |12.12 Result| TS 11.14, the length of additional information is
// varied and all possible values are addressed in 12.12.1-11 of TS 11.14
// and 8.12.1-13 in TS 31.111.
// However,
// 1. Only SEND SS requires info with more than 1 octet.
// 2. In rild design, SEND SS is expected to be handled by modem and
// UNSOLICITED_STK_EVENT_NOTIFY will be sent to application layer to
// indicate appropriate messages to users. TR is not required in this
// case.
// Hence, we simplify the structure of |additionalInformation| to a
// numeric value instead of a octet array.
GsmPDUHelper.writeHexOctet(2);
GsmPDUHelper.writeHexOctet(response.resultCode);
GsmPDUHelper.writeHexOctet(response.additionalInformation);
} else {
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(response.resultCode);
}
// Item Identifier
if (response.itemIdentifier != null) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_ITEM_ID |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(response.itemIdentifier);
}
// No need to process Text data if user requests help information.
if (response.resultCode != STK_RESULT_HELP_INFO_REQUIRED) {
let text;
let coding = command.options.isUCS2 ?
STK_TEXT_CODING_UCS2 :
(command.options.isPacked ?
STK_TEXT_CODING_GSM_7BIT_PACKED :
STK_TEXT_CODING_GSM_8BIT);
if (response.isYesNo !== undefined) {
// Tag: GET_INKEY
// When the ME issues a successful TERMINAL RESPONSE for a GET INKEY
// ("Yes/No") command with command qualifier set to "Yes/No", it shall
// supply the value '01' when the answer is "positive" and the value
// '00' when the answer is "negative" in the Text string data object.
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_TEXT_STRING |
COMPREHENSIONTLV_FLAG_CR);
// Length: 2
GsmPDUHelper.writeHexOctet(2);
// Value: Coding, Yes/No.
GsmPDUHelper.writeHexOctet(coding);
GsmPDUHelper.writeHexOctet(response.isYesNo ? 0x01 : 0x00);
} else {
if (response.input !== undefined) {
ComprehensionTlvHelper.writeTextStringTlv(response.input, coding);
}
}
}
// Duration
if (response.resultCode === STK_RESULT_NO_RESPONSE_FROM_USER) {
// In TS102 223, 6.4.2 GET INKEY, "if the UICC requests a variable timeout,
// the terminal shall wait until either the user enters a single character
// or the timeout expires. The timer starts when the text is displayed on
// the screen and stops when the TERMINAL RESPONSE is sent. The terminal
// shall pass the total display text duration (command execution duration)
// to the UICC using the TERMINAL RESPONSE. The time unit of the response
// is identical to the time unit of the requested variable timeout."
let duration = command && command.options && command.options.duration;
if (duration) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_DURATION);
GsmPDUHelper.writeHexOctet(2);
GsmPDUHelper.writeHexOctet(duration.timeUnit);
GsmPDUHelper.writeHexOctet(duration.timeInterval);
}
}
// Local Information
if (response.localInfo) {
let localInfo = response.localInfo;
// Location Infomation
if (localInfo.locationInfo) {
ComprehensionTlvHelper.writeLocationInfoTlv(localInfo.locationInfo);
}
// IMEI
if (localInfo.imei != null) {
let imei = localInfo.imei;
if (imei.length == 15) {
imei = imei + "0";
}
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_IMEI);
GsmPDUHelper.writeHexOctet(8);
for (let i = 0; i < imei.length / 2; i++) {
GsmPDUHelper.writeHexOctet(parseInt(imei.substr(i * 2, 2), 16));
}
}
// Date and Time Zone
if (localInfo.date != null) {
ComprehensionTlvHelper.writeDateTimeZoneTlv(localInfo.date);
}
// Language
if (localInfo.language) {
ComprehensionTlvHelper.writeLanguageTlv(localInfo.language);
}
}
// Timer
if (response.timer) {
let timer = response.timer;
if (timer.timerId) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_TIMER_IDENTIFIER);
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(timer.timerId);
}
if (timer.timerValue) {
ComprehensionTlvHelper.writeTimerValueTlv(timer.timerValue, false);
}
}
// Calculate and write Parcel size to 1st mark
Buf.stopCalOutgoingSize();
Buf.writeInt32(0);
Buf.sendParcel();
},
/**
* Send STK Envelope(Menu Selection) command.
*
* @param itemIdentifier
* @param helpRequested
*/
sendStkMenuSelection: function(command) {
command.tag = BER_MENU_SELECTION_TAG;
command.deviceId = {
sourceId :STK_DEVICE_ID_KEYPAD,
destinationId: STK_DEVICE_ID_SIM
};
this.sendICCEnvelopeCommand(command);
},
/**
* Send STK Envelope(Timer Expiration) command.
*
* @param timer
*/
sendStkTimerExpiration: function(command) {
command.tag = BER_TIMER_EXPIRATION_TAG;
command.deviceId = {
sourceId: STK_DEVICE_ID_ME,
destinationId: STK_DEVICE_ID_SIM
};
command.timerId = command.timer.timerId;
command.timerValue = command.timer.timerValue;
this.sendICCEnvelopeCommand(command);
},
/**
* Send STK Envelope(Event Download) command.
* @param event
*/
sendStkEventDownload: function(command) {
command.tag = BER_EVENT_DOWNLOAD_TAG;
command.eventList = command.event.eventType;
switch (command.eventList) {
case STK_EVENT_TYPE_LOCATION_STATUS:
command.deviceId = {
sourceId :STK_DEVICE_ID_ME,
destinationId: STK_DEVICE_ID_SIM
};
command.locationStatus = command.event.locationStatus;
// Location info should only be provided when locationStatus is normal.
if (command.locationStatus == STK_SERVICE_STATE_NORMAL) {
command.locationInfo = command.event.locationInfo;
}
break;
case STK_EVENT_TYPE_MT_CALL:
command.deviceId = {
sourceId: STK_DEVICE_ID_NETWORK,
destinationId: STK_DEVICE_ID_SIM
};
command.transactionId = 0;
command.address = command.event.number;
break;
case STK_EVENT_TYPE_CALL_DISCONNECTED:
command.cause = command.event.error;
// Fall through.
case STK_EVENT_TYPE_CALL_CONNECTED:
command.deviceId = {
sourceId: (command.event.isIssuedByRemote ?
STK_DEVICE_ID_NETWORK : STK_DEVICE_ID_ME),
destinationId: STK_DEVICE_ID_SIM
};
command.transactionId = 0;
break;
case STK_EVENT_TYPE_USER_ACTIVITY:
command.deviceId = {
sourceId: STK_DEVICE_ID_ME,
destinationId: STK_DEVICE_ID_SIM
};
break;
case STK_EVENT_TYPE_IDLE_SCREEN_AVAILABLE:
command.deviceId = {
sourceId: STK_DEVICE_ID_DISPLAY,
destinationId: STK_DEVICE_ID_SIM
};
break;
case STK_EVENT_TYPE_LANGUAGE_SELECTION:
command.deviceId = {
sourceId: STK_DEVICE_ID_ME,
destinationId: STK_DEVICE_ID_SIM
};
command.language = command.event.language;
break;
case STK_EVENT_TYPE_BROWSER_TERMINATION:
command.deviceId = {
sourceId: STK_DEVICE_ID_ME,
destinationId: STK_DEVICE_ID_SIM
};
command.terminationCause = command.event.terminationCause;
break;
}
this.sendICCEnvelopeCommand(command);
},
/**
* Send REQUEST_STK_SEND_ENVELOPE_COMMAND to ICC.
*
* @param tag
* @patam deviceId
* @param [optioanl] itemIdentifier
* @param [optional] helpRequested
* @param [optional] eventList
* @param [optional] locationStatus
* @param [optional] locationInfo
* @param [optional] address
* @param [optional] transactionId
* @param [optional] cause
* @param [optional] timerId
* @param [optional] timerValue
* @param [optional] terminationCause
*/
sendICCEnvelopeCommand: function(options) {
if (DEBUG) {
this.context.debug("Stk Envelope " + JSON.stringify(options));
}
let Buf = this.context.Buf;
let ComprehensionTlvHelper = this.context.ComprehensionTlvHelper;
let GsmPDUHelper = this.context.GsmPDUHelper;
Buf.newParcel(REQUEST_STK_SEND_ENVELOPE_COMMAND);
// 1st mark for Parcel size
Buf.startCalOutgoingSize(function(size) {
// Parcel size is in string length, which costs 2 uint8 per char.
Buf.writeInt32(size / 2);
});
// Write a BER-TLV
GsmPDUHelper.writeHexOctet(options.tag);
// 2nd mark for BER length
Buf.startCalOutgoingSize(function(size) {
// BER length is in number of hexOctets, which costs 4 uint8 per hexOctet.
GsmPDUHelper.writeHexOctet(size / 4);
});
// Event List
if (options.eventList != null) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_EVENT_LIST |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(options.eventList);
}
// Device Identifies
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_DEVICE_ID |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(2);
GsmPDUHelper.writeHexOctet(options.deviceId.sourceId);
GsmPDUHelper.writeHexOctet(options.deviceId.destinationId);
// Item Identifier
if (options.itemIdentifier != null) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_ITEM_ID |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(options.itemIdentifier);
}
// Help Request
if (options.helpRequested) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_HELP_REQUEST |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(0);
// Help Request doesn't have value
}
// Location Status
if (options.locationStatus != null) {
let len = options.locationStatus.length;
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_LOCATION_STATUS |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(options.locationStatus);
}
// Location Info
if (options.locationInfo) {
ComprehensionTlvHelper.writeLocationInfoTlv(options.locationInfo);
}
// Transaction Id
if (options.transactionId != null) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_TRANSACTION_ID |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(options.transactionId);
}
// Address
if (options.address) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_ADDRESS |
COMPREHENSIONTLV_FLAG_CR);
let addressLength = options.address[0] == '+' ? options.address.length - 1
: options.address.length;
ComprehensionTlvHelper.writeLength(
Math.ceil(addressLength / 2) + 1 // address BCD + TON
);
this.context.ICCPDUHelper.writeDiallingNumber(options.address);
}
// Cause of disconnection.
if (options.cause != null) {
ComprehensionTlvHelper.writeCauseTlv(options.cause);
}
// Timer Identifier
if (options.timerId != null) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_TIMER_IDENTIFIER |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(options.timerId);
}
// Timer Value
if (options.timerValue != null) {
ComprehensionTlvHelper.writeTimerValueTlv(options.timerValue, true);
}
// Language
if (options.language) {
ComprehensionTlvHelper.writeLanguageTlv(options.language);
}
// Browser Termination
if (options.terminationCause != null) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_BROWSER_TERMINATION_CAUSE |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(1);
GsmPDUHelper.writeHexOctet(options.terminationCause);
}
// Calculate and write BER length to 2nd mark
Buf.stopCalOutgoingSize();
// Calculate and write Parcel size to 1st mark
Buf.stopCalOutgoingSize();
Buf.writeInt32(0);
Buf.sendParcel();
},
/**
* Report STK Service is running.
*/
reportStkServiceIsRunning: function() {
this.context.Buf.simpleRequest(REQUEST_REPORT_STK_SERVICE_IS_RUNNING);
},
/**
* Process ICC status.
*/
_processICCStatus: function(iccStatus) {
// If |_waitingRadioTech| is true, we should not get app information because
// the |_isCdma| flag is not ready yet. Otherwise we may use wrong index to
// get app information, especially for the case that icc card has both cdma
// and gsm subscription.
if (this._waitingRadioTech) {
return;
}
// When |iccStatus.cardState| is not CARD_STATE_PRESENT, set cardState to
// undetected.
if (iccStatus.cardState !== CARD_STATE_PRESENT) {
if (this.cardState !== GECKO_CARDSTATE_UNDETECTED) {
this.operator = null;
// We should send |cardstatechange| before |iccinfochange|, otherwise we
// may lost cardstatechange event when icc card becomes undetected.
this.cardState = GECKO_CARDSTATE_UNDETECTED;
this.sendChromeMessage({rilMessageType: "cardstatechange",
cardState: this.cardState});
this.iccInfo = {iccType: null};
this.context.ICCUtilsHelper.handleICCInfoChange();
}
return;
}
if (RILQUIRKS_SUBSCRIPTION_CONTROL) {
// All appIndex is -1 means the subscription is not activated yet.
// Note that we don't support "ims" for now, so we don't take it into
// account.
let neetToActivate = iccStatus.cdmaSubscriptionAppIndex === -1 &&
iccStatus.gsmUmtsSubscriptionAppIndex === -1;
if (neetToActivate &&
// Note: setUiccSubscription works abnormally when RADIO is OFF,
// which causes SMS function broken in Flame.
// See bug 1008557 for detailed info.
this.radioState === GECKO_RADIOSTATE_ENABLED) {
for (let i = 0; i < iccStatus.apps.length; i++) {
this.setUiccSubscription({appIndex: i, enabled: true});
}
}
}
let newCardState;
let index = this._isCdma ? iccStatus.cdmaSubscriptionAppIndex
: iccStatus.gsmUmtsSubscriptionAppIndex;
let app = iccStatus.apps[index];
if (app) {
// fetchICCRecords will need to read aid, so read aid here.
this.aid = app.aid;
this.appType = app.app_type;
this.iccInfo.iccType = GECKO_CARD_TYPE[this.appType];
switch (app.app_state) {
case CARD_APPSTATE_ILLEGAL:
newCardState = GECKO_CARDSTATE_ILLEGAL;
break;
case CARD_APPSTATE_PIN:
newCardState = GECKO_CARDSTATE_PIN_REQUIRED;
break;
case CARD_APPSTATE_PUK:
newCardState = GECKO_CARDSTATE_PUK_REQUIRED;
break;
case CARD_APPSTATE_SUBSCRIPTION_PERSO:
newCardState = PERSONSUBSTATE[app.perso_substate];
break;
case CARD_APPSTATE_READY:
newCardState = GECKO_CARDSTATE_READY;
break;
case CARD_APPSTATE_UNKNOWN:
case CARD_APPSTATE_DETECTED:
// Fall through.
default:
newCardState = GECKO_CARDSTATE_UNKNOWN;
}
let pin1State = app.pin1_replaced ? iccStatus.universalPINState :
app.pin1;
if (pin1State === CARD_PINSTATE_ENABLED_PERM_BLOCKED) {
newCardState = GECKO_CARDSTATE_PERMANENT_BLOCKED;
}
} else {
// Having incorrect app information, set card state to unknown.
newCardState = GECKO_CARDSTATE_UNKNOWN;
}
let ICCRecordHelper = this.context.ICCRecordHelper;
// Try to get iccId only when cardState left GECKO_CARDSTATE_UNDETECTED.
if (iccStatus.cardState === CARD_STATE_PRESENT &&
(this.cardState === GECKO_CARDSTATE_UNINITIALIZED ||
this.cardState === GECKO_CARDSTATE_UNDETECTED)) {
ICCRecordHelper.readICCID();
}
if (this.cardState == newCardState) {
return;
}
// This was moved down from CARD_APPSTATE_READY
this.requestNetworkInfo();
if (newCardState == GECKO_CARDSTATE_READY) {
// For type SIM, we need to check EF_phase first.
// Other types of ICC we can send Terminal_Profile immediately.
if (this.appType == CARD_APPTYPE_SIM) {
this.context.SimRecordHelper.readSimPhase();
} else if (RILQUIRKS_SEND_STK_PROFILE_DOWNLOAD) {
this.sendStkTerminalProfile(STK_SUPPORTED_TERMINAL_PROFILE);
}
ICCRecordHelper.fetchICCRecords();
}
this.cardState = newCardState;
this.sendChromeMessage({rilMessageType: "cardstatechange",
cardState: this.cardState});
},
/**
* Helper for processing responses of functions such as enterICC* and changeICC*.
*/
_processEnterAndChangeICCResponses: function(length, options) {
options.retryCount = length ? this.context.Buf.readInt32List()[0] : -1;
this.sendChromeMessage(options);
},
// We combine all of the NETWORK_INFO_MESSAGE_TYPES into one "networkinfochange"
// message to the RadioInterfaceLayer, so we can avoid sending multiple
// VoiceInfoChanged events for both operator / voice_data_registration
//
// State management here is a little tricky. We need to know both:
// 1. Whether or not a response was received for each of the
// NETWORK_INFO_MESSAGE_TYPES
// 2. The outbound message that corresponds with that response -- but this
// only happens when internal state changes (i.e. it isn't guaranteed)
//
// To collect this state, each message response function first calls
// _receivedNetworkInfo, to mark the response as received. When the
// final response is received, a call to _sendPendingNetworkInfo is placed
// on the next tick of the worker thread.
//
// Since the original call to _receivedNetworkInfo happens at the top
// of the response handler, this gives the final handler a chance to
// queue up it's "changed" message by calling _sendNetworkInfoMessage if/when
// the internal state has actually changed.
_sendNetworkInfoMessage: function(type, message) {
if (!this._processingNetworkInfo) {
// We only combine these messages in the case of the combined request
// in requestNetworkInfo()
this.sendChromeMessage(message);
return;
}
if (DEBUG) {
this.context.debug("Queuing " + type + " network info message: " +
JSON.stringify(message));
}
this._pendingNetworkInfo[type] = message;
},
_receivedNetworkInfo: function(type) {
if (DEBUG) this.context.debug("Received " + type + " network info.");
if (!this._processingNetworkInfo) {
return;
}
let pending = this._pendingNetworkInfo;
// We still need to track states for events that aren't fired.
if (!(type in pending)) {
pending[type] = this.pendingNetworkType;
}
// Pending network info is ready to be sent when no more messages
// are waiting for responses, but the combined payload hasn't been sent.
for (let i = 0; i < NETWORK_INFO_MESSAGE_TYPES.length; i++) {
let msgType = NETWORK_INFO_MESSAGE_TYPES[i];
if (!(msgType in pending)) {
if (DEBUG) {
this.context.debug("Still missing some more network info, not " +
"notifying main thread.");
}
return;
}
}
// Do a pass to clean up the processed messages that didn't create
// a response message, so we don't have unused keys in the outbound
// networkinfochanged message.
for (let key in pending) {
if (pending[key] == this.pendingNetworkType) {
delete pending[key];
}
}
if (DEBUG) {
this.context.debug("All pending network info has been received: " +
JSON.stringify(pending));
}
// Send the message on the next tick of the worker's loop, so we give the
// last message a chance to call _sendNetworkInfoMessage first.
setTimeout(this._sendPendingNetworkInfo.bind(this), 0);
},
_sendPendingNetworkInfo: function() {
this.sendChromeMessage(this._pendingNetworkInfo);
this._processingNetworkInfo = false;
for (let i = 0; i < NETWORK_INFO_MESSAGE_TYPES.length; i++) {
delete this._pendingNetworkInfo[NETWORK_INFO_MESSAGE_TYPES[i]];
}
if (this._needRepollNetworkInfo) {
this._needRepollNetworkInfo = false;
this.requestNetworkInfo();
}
},
/**
* Normalize the signal strength in dBm to the signal level from 0 to 100.
*
* @param signal
* The signal strength in dBm to normalize.
* @param min
* The signal strength in dBm maps to level 0.
* @param max
* The signal strength in dBm maps to level 100.
*
* @return level
* The signal level from 0 to 100.
*/
_processSignalLevel: function(signal, min, max) {
if (signal <= min) {
return 0;
}
if (signal >= max) {
return 100;
}
return Math.floor((signal - min) * 100 / (max - min));
},
/**
* Process LTE signal strength to the signal info object.
*
* @param signal
* The signal object reported from RIL/modem.
*
* @return The object of signal strength info.
* Or null if invalid signal input.
*
* TODO: Bug 982013: reconsider the format of signal strength APIs for
* GSM/CDMA/LTE to expose details, such as rsrp and rsnnr,
* individually.
*/
_processLteSignal: function(signal) {
let info = {
voice: {
signalStrength: null,
relSignalStrength: null
},
data: {
signalStrength: null,
relSignalStrength: null
}
};
// Referring to AOSP, use lteRSRP for signalStrength in dBm.
let signalStrength = (signal.lteRSRP === undefined || signal.lteRSRP === 0x7FFFFFFF) ?
null : signal.lteRSRP;
info.voice.signalStrength = info.data.signalStrength = signalStrength;
// Referring to AOSP, first determine signalLevel based on RSRP and RSSNR,
// then on lteSignalStrength if RSRP and RSSNR are invalid.
let rsrpLevel = -1;
let rssnrLevel = -1;
if (signal.lteRSRP !== undefined &&
signal.lteRSRP !== 0x7FFFFFFF &&
signal.lteRSRP >= 44 &&
signal.lteRSRP <= 140) {
rsrpLevel = this._processSignalLevel(signal.lteRSRP * -1, -115, -85);
}
if (signal.lteRSSNR !== undefined &&
signal.lteRSSNR !== 0x7FFFFFFF &&
signal.lteRSSNR >= -200 &&
signal.lteRSSNR <= 300) {
rssnrLevel = this._processSignalLevel(signal.lteRSSNR, -30, 130);
}
if (rsrpLevel !== -1 && rssnrLevel !== -1) {
info.voice.relSignalStrength = info.data.relSignalStrength =
Math.min(rsrpLevel, rssnrLevel);
return info;
}
let level = Math.max(rsrpLevel, rssnrLevel);
if (level !== -1) {
info.voice.relSignalStrength = info.data.relSignalStrength = level;
return info;
}
// Valid values are 0-63 as defined in TS 27.007 clause 8.69.
if (signal.lteSignalStrength !== undefined &&
signal.lteSignalStrength >= 0 &&
signal.lteSignalStrength <= 63) {
level = this._processSignalLevel(signal.lteSignalStrength, 0, 12);
info.voice.relSignalStrength = info.data.relSignalStrength = level;
return info;
}
return null;
},
_processSignalStrength: function(signal) {
let info = {
voice: {
signalStrength: null,
relSignalStrength: null
},
data: {
signalStrength: null,
relSignalStrength: null
}
};
// During startup, |radioTech| is not yet defined, so we need to
// check it separately.
if (("radioTech" in this.voiceRegistrationState) &&
!this._isGsmTechGroup(this.voiceRegistrationState.radioTech)) {
// CDMA RSSI.
// Valid values are positive integers. This value is the actual RSSI value
// multiplied by -1. Example: If the actual RSSI is -75, then this
// response value will be 75.
if (signal.cdmaDBM && signal.cdmaDBM > 0) {
let signalStrength = -1 * signal.cdmaDBM;
info.voice.signalStrength = signalStrength;
// -105 and -70 are referred to AOSP's implementation. These values are
// not constants and can be customized based on different requirement.
let signalLevel = this._processSignalLevel(signalStrength, -105, -70);
info.voice.relSignalStrength = signalLevel;
}
// EVDO RSSI.
// Valid values are positive integers. This value is the actual RSSI value
// multiplied by -1. Example: If the actual RSSI is -75, then this
// response value will be 75.
if (signal.evdoDBM && signal.evdoDBM > 0) {
let signalStrength = -1 * signal.evdoDBM;
info.data.signalStrength = signalStrength;
// -105 and -70 are referred to AOSP's implementation. These values are
// not constants and can be customized based on different requirement.
let signalLevel = this._processSignalLevel(signalStrength, -105, -70);
info.data.relSignalStrength = signalLevel;
}
} else {
// Check LTE level first, and check GSM/UMTS level next if LTE one is not
// valid.
let lteInfo = this._processLteSignal(signal);
if (lteInfo) {
info = lteInfo;
} else {
// GSM signal strength.
// Valid values are 0-31 as defined in TS 27.007 8.5.
// 0 : -113 dBm or less
// 1 : -111 dBm
// 2...30: -109...-53 dBm
// 31 : -51 dBm
if (signal.gsmSignalStrength &&
signal.gsmSignalStrength >= 0 &&
signal.gsmSignalStrength <= 31) {
let signalStrength = -113 + 2 * signal.gsmSignalStrength;
info.voice.signalStrength = info.data.signalStrength = signalStrength;
// -115 and -85 are referred to AOSP's implementation. These values are
// not constants and can be customized based on different requirement.
let signalLevel = this._processSignalLevel(signalStrength, -110, -85);
info.voice.relSignalStrength = info.data.relSignalStrength = signalLevel;
}
}
}
info.rilMessageType = "signalstrengthchange";
this._sendNetworkInfoMessage(NETWORK_INFO_SIGNAL, info);
},
/**
* Process the network registration flags.
*
* @return true if the state changed, false otherwise.
*/
_processCREG: function(curState, newState) {
let changed = false;
let regState = this.parseInt(newState[0], NETWORK_CREG_STATE_UNKNOWN);
if (curState.regState === undefined || curState.regState !== regState) {
changed = true;
curState.regState = regState;
curState.state = NETWORK_CREG_TO_GECKO_MOBILE_CONNECTION_STATE[regState];
curState.connected = regState == NETWORK_CREG_STATE_REGISTERED_HOME ||
regState == NETWORK_CREG_STATE_REGISTERED_ROAMING;
curState.roaming = regState == NETWORK_CREG_STATE_REGISTERED_ROAMING;
curState.emergencyCallsOnly = !curState.connected;
}
if (!curState.cell) {
curState.cell = {};
}
// From TS 23.003, 0000 and 0xfffe are indicated that no valid LAI exists
// in MS. So we still need to report the '0000' as well.
let lac = this.parseInt(newState[1], -1, 16);
if (curState.cell.gsmLocationAreaCode === undefined ||
curState.cell.gsmLocationAreaCode !== lac) {
curState.cell.gsmLocationAreaCode = lac;
changed = true;
}
let cid = this.parseInt(newState[2], -1, 16);
if (curState.cell.gsmCellId === undefined ||
curState.cell.gsmCellId !== cid) {
curState.cell.gsmCellId = cid;
changed = true;
}
let radioTech = (newState[3] === undefined ?
NETWORK_CREG_TECH_UNKNOWN :
this.parseInt(newState[3], NETWORK_CREG_TECH_UNKNOWN));
if (curState.radioTech === undefined || curState.radioTech !== radioTech) {
changed = true;
curState.radioTech = radioTech;
curState.type = GECKO_RADIO_TECH[radioTech] || null;
}
return changed;
},
_processVoiceRegistrationState: function(state) {
let rs = this.voiceRegistrationState;
let stateChanged = this._processCREG(rs, state);
if (stateChanged && rs.connected) {
this.getSmscAddress();
}
let cell = rs.cell;
if (this._isCdma) {
// Some variables below are not used. Comment them instead of removing to
// keep the information about state[x].
let cdmaBaseStationId = this.parseInt(state[4], -1);
let cdmaBaseStationLatitude = this.parseInt(state[5], -2147483648);
let cdmaBaseStationLongitude = this.parseInt(state[6], -2147483648);
// let cssIndicator = this.parseInt(state[7]);
let cdmaSystemId = this.parseInt(state[8], -1);
let cdmaNetworkId = this.parseInt(state[9], -1);
// let roamingIndicator = this.parseInt(state[10]);
// let systemIsInPRL = this.parseInt(state[11]);
// let defaultRoamingIndicator = this.parseInt(state[12]);
// let reasonForDenial = this.parseInt(state[13]);
if (cell.cdmaBaseStationId !== cdmaBaseStationId ||
cell.cdmaBaseStationLatitude !== cdmaBaseStationLatitude ||
cell.cdmaBaseStationLongitude !== cdmaBaseStationLongitude ||
cell.cdmaSystemId !== cdmaSystemId ||
cell.cdmaNetworkId !== cdmaNetworkId) {
stateChanged = true;
cell.cdmaBaseStationId = cdmaBaseStationId;
cell.cdmaBaseStationLatitude = cdmaBaseStationLatitude;
cell.cdmaBaseStationLongitude = cdmaBaseStationLongitude;
cell.cdmaSystemId = cdmaSystemId;
cell.cdmaNetworkId = cdmaNetworkId;
}
}
if (stateChanged) {
rs.rilMessageType = "voiceregistrationstatechange";
this._sendNetworkInfoMessage(NETWORK_INFO_VOICE_REGISTRATION_STATE, rs);
}
},
_processDataRegistrationState: function(state) {
let rs = this.dataRegistrationState;
let stateChanged = this._processCREG(rs, state);
if (stateChanged) {
rs.rilMessageType = "dataregistrationstatechange";
this._sendNetworkInfoMessage(NETWORK_INFO_DATA_REGISTRATION_STATE, rs);
}
},
_processOperator: function(operatorData) {
if (operatorData.length < 3) {
if (DEBUG) {
this.context.debug("Expected at least 3 strings for operator.");
}
}
if (!this.operator) {
this.operator = {
rilMessageType: "operatorchange",
longName: null,
shortName: null
};
}
let [longName, shortName, networkTuple] = operatorData;
let thisTuple = (this.operator.mcc || "") + (this.operator.mnc || "");
if (this.operator.longName !== longName ||
this.operator.shortName !== shortName ||
thisTuple !== networkTuple) {
this.operator.mcc = null;
this.operator.mnc = null;
if (networkTuple) {
try {
this._processNetworkTuple(networkTuple, this.operator);
} catch (e) {
if (DEBUG) this.context.debug("Error processing operator tuple: " + e);
}
} else {
// According to ril.h, the operator fields will be NULL when the operator
// is not currently registered. We can avoid trying to parse the numeric
// tuple in that case.
if (DEBUG) {
this.context.debug("Operator is currently unregistered");
}
}
this.operator.longName = longName;
this.operator.shortName = shortName;
let ICCUtilsHelper = this.context.ICCUtilsHelper;
if (ICCUtilsHelper.updateDisplayCondition()) {
ICCUtilsHelper.handleICCInfoChange();
}
// NETWORK_INFO_OPERATOR message will be sent out by overrideICCNetworkName
// itself if operator name is overridden after checking, or we have to
// do it by ourself.
if (!this.overrideICCNetworkName()) {
this._sendNetworkInfoMessage(NETWORK_INFO_OPERATOR, this.operator);
}
}
},
_processSuppSvcNotification: function(info) {
if (DEBUG) {
this.context.debug("handle supp svc notification: " + JSON.stringify(info));
}
if (info.notificationType !== 1) {
// We haven't supported MO intermediate result code, i.e.
// info.notificationType === 0, which refers to code1 defined in 3GPP
// 27.007 7.17. We only support partial MT unsolicited result code,
// referring to code2, for now.
return;
}
let notification = null;
switch (info.code) {
case SUPP_SVC_NOTIFICATION_CODE2_PUT_ON_HOLD:
case SUPP_SVC_NOTIFICATION_CODE2_RETRIEVED:
notification = GECKO_SUPP_SVC_NOTIFICATION_FROM_CODE2[info.code];
break;
default:
// Notification type not supported.
return;
}
let message = {rilMessageType: "suppSvcNotification",
number: info.number, // could be empty.
notification: notification};
this.sendChromeMessage(message);
},
_cancelEmergencyCbModeTimeout: function() {
if (this._exitEmergencyCbModeTimeoutID) {
clearTimeout(this._exitEmergencyCbModeTimeoutID);
this._exitEmergencyCbModeTimeoutID = null;
}
},
_handleChangedEmergencyCbMode: function(active) {
this._isInEmergencyCbMode = active;
// Clear the existed timeout event.
this._cancelEmergencyCbModeTimeout();
// Start a new timeout event when entering the mode.
if (active) {
this._exitEmergencyCbModeTimeoutID = setTimeout(
this.exitEmergencyCbMode.bind(this), EMERGENCY_CB_MODE_TIMEOUT_MS);
}
let message = {rilMessageType: "emergencyCbModeChange",
active: active,
timeoutMs: EMERGENCY_CB_MODE_TIMEOUT_MS};
this.sendChromeMessage(message);
},
_updateNetworkSelectionMode: function(mode) {
if (this.networkSelectionMode === mode) {
return;
}
let options = {
rilMessageType: "networkselectionmodechange",
mode: mode
};
this.networkSelectionMode = mode;
this._sendNetworkInfoMessage(NETWORK_INFO_NETWORK_SELECTION_MODE, options);
},
_processNetworks: function() {
let strings = this.context.Buf.readStringList();
let networks = [];
for (let i = 0; i < strings.length;
i += RILQUIRKS_AVAILABLE_NETWORKS_EXTRA_STRING ? 5 : 4) {
let network = {
longName: strings[i],
shortName: strings[i + 1],
mcc: null,
mnc: null,
state: null
};
let networkTuple = strings[i + 2];
try {
this._processNetworkTuple(networkTuple, network);
} catch (e) {
if (DEBUG) this.context.debug("Error processing operator tuple: " + e);
}
let state = strings[i + 3];
network.state = RIL_QAN_STATE_TO_GECKO_STATE[state];
networks.push(network);
}
return networks;
},
/**
* The "numeric" portion of the operator info is a tuple
* containing MCC (country code) and MNC (network code).
* AFAICT, MCC should always be 3 digits, making the remaining
* portion the MNC.
*/
_processNetworkTuple: function(networkTuple, network) {
let tupleLen = networkTuple.length;
if (tupleLen == 5 || tupleLen == 6) {
network.mcc = networkTuple.substr(0, 3);
network.mnc = networkTuple.substr(3);
} else {
network.mcc = null;
network.mnc = null;
throw new Error("Invalid network tuple (should be 5 or 6 digits): " + networkTuple);
}
},
/**
* Check if GSM radio access technology group.
*/
_isGsmTechGroup: function(radioTech) {
if (!radioTech) {
return true;
}
switch(radioTech) {
case NETWORK_CREG_TECH_GPRS:
case NETWORK_CREG_TECH_EDGE:
case NETWORK_CREG_TECH_UMTS:
case NETWORK_CREG_TECH_HSDPA:
case NETWORK_CREG_TECH_HSUPA:
case NETWORK_CREG_TECH_HSPA:
case NETWORK_CREG_TECH_LTE:
case NETWORK_CREG_TECH_HSPAP:
case NETWORK_CREG_TECH_GSM:
case NETWORK_CREG_TECH_DCHSPAP_1:
case NETWORK_CREG_TECH_DCHSPAP_2:
return true;
}
return false;
},
/**
* Process radio technology change.
*/
_processRadioTech: function(radioTech) {
let isCdma = !this._isGsmTechGroup(radioTech);
this.radioTech = radioTech;
if (DEBUG) {
this.context.debug("Radio tech is set to: " + GECKO_RADIO_TECH[radioTech] +
", it is a " + (isCdma?"cdma":"gsm") + " technology");
}
// We should request SIM information when
// 1. Radio state has been changed, so we are waiting for radioTech or
// 2. isCdma is different from this._isCdma.
if (this._waitingRadioTech || isCdma != this._isCdma) {
this._isCdma = isCdma;
this._waitingRadioTech = false;
if (this._isCdma) {
this.getDeviceIdentity();
} else {
this.getIMEI();
this.getIMEISV();
}
this.getICCStatus();
}
},
/**
* Helper for returning the TOA for the given dial string.
*/
_toaFromString: function(number) {
let toa = TOA_UNKNOWN;
if (number && number.length > 0 && number[0] == '+') {
toa = TOA_INTERNATIONAL;
}
return toa;
},
/**
* @param message A decoded SMS-DELIVER message.
*
* @see 3GPP TS 31.111 section 7.1.1
*/
dataDownloadViaSMSPP: function(message) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
let options = {
pid: message.pid,
dcs: message.dcs,
encoding: message.encoding,
};
Buf.newParcel(REQUEST_STK_SEND_ENVELOPE_WITH_STATUS, options);
Buf.seekIncoming(-1 * (Buf.getCurrentParcelSize() - Buf.getReadAvailable()
- 2 * Buf.UINT32_SIZE)); // Skip response_type & request_type.
let messageStringLength = Buf.readInt32(); // In semi-octets
let smscLength = GsmPDUHelper.readHexOctet(); // In octets, inclusive of TOA
let tpduLength = (messageStringLength / 2) - (smscLength + 1); // In octets
// Device identities: 4 bytes
// Address: 0 or (2 + smscLength)
// SMS TPDU: (2 or 3) + tpduLength
let berLen = 4 +
(smscLength ? (2 + smscLength) : 0) +
(tpduLength <= 127 ? 2 : 3) + tpduLength; // In octets
let parcelLength = (berLen <= 127 ? 2 : 3) + berLen; // In octets
Buf.writeInt32(parcelLength * 2); // In semi-octets
// Write a BER-TLV
GsmPDUHelper.writeHexOctet(BER_SMS_PP_DOWNLOAD_TAG);
if (berLen > 127) {
GsmPDUHelper.writeHexOctet(0x81);
}
GsmPDUHelper.writeHexOctet(berLen);
// Device Identifies-TLV
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_DEVICE_ID |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(0x02);
GsmPDUHelper.writeHexOctet(STK_DEVICE_ID_NETWORK);
GsmPDUHelper.writeHexOctet(STK_DEVICE_ID_SIM);
// Address-TLV
if (smscLength) {
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_ADDRESS);
GsmPDUHelper.writeHexOctet(smscLength);
Buf.copyIncomingToOutgoing(Buf.PDU_HEX_OCTET_SIZE * smscLength);
}
// SMS TPDU-TLV
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_SMS_TPDU |
COMPREHENSIONTLV_FLAG_CR);
if (tpduLength > 127) {
GsmPDUHelper.writeHexOctet(0x81);
}
GsmPDUHelper.writeHexOctet(tpduLength);
Buf.copyIncomingToOutgoing(Buf.PDU_HEX_OCTET_SIZE * tpduLength);
// Write 2 string delimitors for the total string length must be even.
Buf.writeStringDelimiter(0);
Buf.sendParcel();
},
/**
* @param success A boolean value indicating the result of previous
* SMS-DELIVER message handling.
* @param responsePduLen ICC IO response PDU length in octets.
* @param options An object that contains four attributes: `pid`, `dcs`,
* `encoding` and `responsePduLen`.
*
* @see 3GPP TS 23.040 section 9.2.2.1a
*/
acknowledgeIncomingGsmSmsWithPDU: function(success, responsePduLen, options) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
Buf.newParcel(REQUEST_ACKNOWLEDGE_INCOMING_GSM_SMS_WITH_PDU);
// Two strings.
Buf.writeInt32(2);
// String 1: Success
Buf.writeString(success ? "1" : "0");
// String 2: RP-ACK/RP-ERROR PDU
Buf.writeInt32(2 * (responsePduLen + (success ? 5 : 6))); // In semi-octet
// 1. TP-MTI & TP-UDHI
GsmPDUHelper.writeHexOctet(PDU_MTI_SMS_DELIVER);
if (!success) {
// 2. TP-FCS
GsmPDUHelper.writeHexOctet(PDU_FCS_USIM_DATA_DOWNLOAD_ERROR);
}
// 3. TP-PI
GsmPDUHelper.writeHexOctet(PDU_PI_USER_DATA_LENGTH |
PDU_PI_DATA_CODING_SCHEME |
PDU_PI_PROTOCOL_IDENTIFIER);
// 4. TP-PID
GsmPDUHelper.writeHexOctet(options.pid);
// 5. TP-DCS
GsmPDUHelper.writeHexOctet(options.dcs);
// 6. TP-UDL
if (options.encoding == PDU_DCS_MSG_CODING_7BITS_ALPHABET) {
GsmPDUHelper.writeHexOctet(Math.floor(responsePduLen * 8 / 7));
} else {
GsmPDUHelper.writeHexOctet(responsePduLen);
}
// TP-UD
Buf.copyIncomingToOutgoing(Buf.PDU_HEX_OCTET_SIZE * responsePduLen);
// Write 2 string delimitors for the total string length must be even.
Buf.writeStringDelimiter(0);
Buf.sendParcel();
},
/**
* @param message A decoded SMS-DELIVER message.
*/
writeSmsToSIM: function(message) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
Buf.newParcel(REQUEST_WRITE_SMS_TO_SIM);
// Write EFsms Status
Buf.writeInt32(EFSMS_STATUS_FREE);
Buf.seekIncoming(-1 * (Buf.getCurrentParcelSize() - Buf.getReadAvailable()
- 2 * Buf.UINT32_SIZE)); // Skip response_type & request_type.
let messageStringLength = Buf.readInt32(); // In semi-octets
let smscLength = GsmPDUHelper.readHexOctet(); // In octets, inclusive of TOA
let pduLength = (messageStringLength / 2) - (smscLength + 1); // In octets
// 1. Write PDU first.
if (smscLength > 0) {
Buf.seekIncoming(smscLength * Buf.PDU_HEX_OCTET_SIZE);
}
// Write EFsms PDU string length
Buf.writeInt32(2 * pduLength); // In semi-octets
if (pduLength) {
Buf.copyIncomingToOutgoing(Buf.PDU_HEX_OCTET_SIZE * pduLength);
}
// Write 2 string delimitors for the total string length must be even.
Buf.writeStringDelimiter(0);
// 2. Write SMSC
// Write EFsms SMSC string length
Buf.writeInt32(2 * (smscLength + 1)); // Plus smscLength itself, in semi-octets
// Write smscLength
GsmPDUHelper.writeHexOctet(smscLength);
// Write TOA & SMSC Address
if (smscLength) {
Buf.seekIncoming(-1 * (Buf.getCurrentParcelSize() - Buf.getReadAvailable()
- 2 * Buf.UINT32_SIZE // Skip response_type, request_type.
- 2 * Buf.PDU_HEX_OCTET_SIZE)); // Skip messageStringLength & smscLength.
Buf.copyIncomingToOutgoing(Buf.PDU_HEX_OCTET_SIZE * smscLength);
}
// Write 2 string delimitors for the total string length must be even.
Buf.writeStringDelimiter(0);
Buf.sendParcel();
},
/**
* Helper to delegate the received sms segment to RadioInterface to process.
*
* @param message
* Received sms message.
*
* @return MOZ_FCS_WAIT_FOR_EXPLICIT_ACK
*/
_processSmsMultipart: function(message) {
message.rilMessageType = "sms-received";
this.sendChromeMessage(message);
return MOZ_FCS_WAIT_FOR_EXPLICIT_ACK;
},
/**
* Helper for processing SMS-STATUS-REPORT PDUs.
*
* @param length
* Length of SMS string in the incoming parcel.
*
* @return A failure cause defined in 3GPP 23.040 clause 9.2.3.22.
*/
_processSmsStatusReport: function(length) {
let [message, result] = this.context.GsmPDUHelper.processReceivedSms(length);
if (!message) {
if (DEBUG) this.context.debug("invalid SMS-STATUS-REPORT");
return PDU_FCS_UNSPECIFIED;
}
let options = this._pendingSentSmsMap[message.messageRef];
if (!options) {
if (DEBUG) this.context.debug("no pending SMS-SUBMIT message");
return PDU_FCS_OK;
}
let status = message.status;
// 3GPP TS 23.040 9.2.3.15 `The MS shall interpret any reserved values as
// "Service Rejected"(01100011) but shall store them exactly as received.`
if ((status >= 0x80)
|| ((status >= PDU_ST_0_RESERVED_BEGIN)
&& (status < PDU_ST_0_SC_SPECIFIC_BEGIN))
|| ((status >= PDU_ST_1_RESERVED_BEGIN)
&& (status < PDU_ST_1_SC_SPECIFIC_BEGIN))
|| ((status >= PDU_ST_2_RESERVED_BEGIN)
&& (status < PDU_ST_2_SC_SPECIFIC_BEGIN))
|| ((status >= PDU_ST_3_RESERVED_BEGIN)
&& (status < PDU_ST_3_SC_SPECIFIC_BEGIN))
) {
status = PDU_ST_3_SERVICE_REJECTED;
}
// Pending. Waiting for next status report.
if ((status >>> 5) == 0x01) {
if (DEBUG) this.context.debug("SMS-STATUS-REPORT: delivery still pending");
return PDU_FCS_OK;
}
delete this._pendingSentSmsMap[message.messageRef];
let deliveryStatus = ((status >>> 5) === 0x00)
? GECKO_SMS_DELIVERY_STATUS_SUCCESS
: GECKO_SMS_DELIVERY_STATUS_ERROR;
this.sendChromeMessage({
rilMessageType: options.rilMessageType,
rilMessageToken: options.rilMessageToken,
deliveryStatus: deliveryStatus
});
return PDU_FCS_OK;
},
/**
* Helper for processing CDMA SMS Delivery Acknowledgment Message
*
* @param message
* decoded SMS Delivery ACK message from CdmaPDUHelper.
*
* @return A failure cause defined in 3GPP 23.040 clause 9.2.3.22.
*/
_processCdmaSmsStatusReport: function(message) {
let options = this._pendingSentSmsMap[message.msgId];
if (!options) {
if (DEBUG) this.context.debug("no pending SMS-SUBMIT message");
return PDU_FCS_OK;
}
if (message.errorClass === 2) {
if (DEBUG) {
this.context.debug("SMS-STATUS-REPORT: delivery still pending, " +
"msgStatus: " + message.msgStatus);
}
return PDU_FCS_OK;
}
delete this._pendingSentSmsMap[message.msgId];
if (message.errorClass === -1 && message.body) {
// Process as normal incoming SMS, if errorClass is invalid
// but message body is available.
return this._processSmsMultipart(message);
}
let deliveryStatus = (message.errorClass === 0)
? GECKO_SMS_DELIVERY_STATUS_SUCCESS
: GECKO_SMS_DELIVERY_STATUS_ERROR;
this.sendChromeMessage({
rilMessageType: options.rilMessageType,
rilMessageToken: options.rilMessageToken,
deliveryStatus: deliveryStatus
});
return PDU_FCS_OK;
},
/**
* Helper for processing CDMA SMS WAP Push Message
*
* @param message
* decoded WAP message from CdmaPDUHelper.
*
* @return A failure cause defined in 3GPP 23.040 clause 9.2.3.22.
*/
_processCdmaSmsWapPush: function(message) {
if (!message.data) {
if (DEBUG) this.context.debug("no data inside WAP Push message.");
return PDU_FCS_OK;
}
// See 6.5. MAPPING OF WDP TO CDMA SMS in WAP-295-WDP.
//
// Field | Length (bits)
// -----------------------------------------
// MSG_TYPE | 8
// TOTAL_SEGMENTS | 8
// SEGMENT_NUMBER | 8
// DATAGRAM | (NUM_FIELDS - 3) * 8
let index = 0;
if (message.data[index++] !== 0) {
if (DEBUG) this.context.debug("Ignore a WAP Message which is not WDP.");
return PDU_FCS_OK;
}
// 1. Originator Address in SMS-TL + Message_Id in SMS-TS are used to identify a unique WDP datagram.
// 2. TOTAL_SEGMENTS, SEGMENT_NUMBER are used to verify that a complete
// datagram has been received and is ready to be passed to a higher layer.
message.header = {
segmentRef: message.msgId,
segmentMaxSeq: message.data[index++],
segmentSeq: message.data[index++] + 1 // It's zero-based in CDMA WAP Push.
};
if (message.header.segmentSeq > message.header.segmentMaxSeq) {
if (DEBUG) this.context.debug("Wrong WDP segment info.");
return PDU_FCS_OK;
}
// Ports are only specified in 1st segment.
if (message.header.segmentSeq == 1) {
message.header.originatorPort = message.data[index++] << 8;
message.header.originatorPort |= message.data[index++];
message.header.destinationPort = message.data[index++] << 8;
message.header.destinationPort |= message.data[index++];
}
message.data = message.data.subarray(index);
return this._processSmsMultipart(message);
},
/**
* Helper for processing sent multipart SMS.
*/
_processSentSmsSegment: function(options) {
// Setup attributes for sending next segment
let next = options.segmentSeq;
options.body = options.segments[next].body;
options.encodedBodyLength = options.segments[next].encodedBodyLength;
options.segmentSeq = next + 1;
this.sendSMS(options);
},
/**
* Helper for processing result of send SMS.
*
* @param length
* Length of SMS string in the incoming parcel.
* @param options
* Sms information.
*/
_processSmsSendResult: function(length, options) {
if (options.errorMsg) {
if (DEBUG) {
this.context.debug("_processSmsSendResult: errorMsg = " +
options.errorMsg);
}
this.sendChromeMessage({
rilMessageType: options.rilMessageType,
rilMessageToken: options.rilMessageToken,
errorMsg: options.errorMsg,
});
return;
}
let Buf = this.context.Buf;
options.messageRef = Buf.readInt32();
options.ackPDU = Buf.readString();
options.errorCode = Buf.readInt32();
if ((options.segmentMaxSeq > 1)
&& (options.segmentSeq < options.segmentMaxSeq)) {
// Not last segment
this._processSentSmsSegment(options);
} else {
// Last segment sent with success.
if (options.requestStatusReport) {
if (DEBUG) {
this.context.debug("waiting SMS-STATUS-REPORT for messageRef " +
options.messageRef);
}
this._pendingSentSmsMap[options.messageRef] = options;
}
this.sendChromeMessage({
rilMessageType: options.rilMessageType,
rilMessageToken: options.rilMessageToken,
});
}
},
_processReceivedSmsCbPage: function(original) {
if (original.numPages <= 1) {
if (original.body) {
original.fullBody = original.body;
delete original.body;
} else if (original.data) {
original.fullData = original.data;
delete original.data;
}
return original;
}
// Hash = <serial>:<mcc>:<mnc>:<lac>:<cid>
let hash = original.serial + ":" + this.iccInfo.mcc + ":"
+ this.iccInfo.mnc + ":";
switch (original.geographicalScope) {
case CB_GSM_GEOGRAPHICAL_SCOPE_CELL_WIDE_IMMEDIATE:
case CB_GSM_GEOGRAPHICAL_SCOPE_CELL_WIDE:
hash += this.voiceRegistrationState.cell.gsmLocationAreaCode + ":"
+ this.voiceRegistrationState.cell.gsmCellId;
break;
case CB_GSM_GEOGRAPHICAL_SCOPE_LOCATION_AREA_WIDE:
hash += this.voiceRegistrationState.cell.gsmLocationAreaCode + ":";
break;
default:
hash += ":";
break;
}
let index = original.pageIndex;
let options = this._receivedSmsCbPagesMap[hash];
if (!options) {
options = original;
this._receivedSmsCbPagesMap[hash] = options;
options.receivedPages = 0;
options.pages = [];
} else if (options.pages[index]) {
// Duplicated page?
if (DEBUG) {
this.context.debug("Got duplicated page no." + index +
" of a multipage SMSCB: " + JSON.stringify(original));
}
return null;
}
if (options.encoding == PDU_DCS_MSG_CODING_8BITS_ALPHABET) {
options.pages[index] = original.data;
delete original.data;
} else {
options.pages[index] = original.body;
delete original.body;
}
options.receivedPages++;
if (options.receivedPages < options.numPages) {
if (DEBUG) {
this.context.debug("Got page no." + index + " of a multipage SMSCB: " +
JSON.stringify(options));
}
return null;
}
// Remove from map
delete this._receivedSmsCbPagesMap[hash];
// Rebuild full body
if (options.encoding == PDU_DCS_MSG_CODING_8BITS_ALPHABET) {
// Uint8Array doesn't have `concat`, so we have to merge all pages by hand.
let fullDataLen = 0;
for (let i = 1; i <= options.numPages; i++) {
fullDataLen += options.pages[i].length;
}
options.fullData = new Uint8Array(fullDataLen);
for (let d= 0, i = 1; i <= options.numPages; i++) {
let data = options.pages[i];
for (let j = 0; j < data.length; j++) {
options.fullData[d++] = data[j];
}
}
} else {
options.fullBody = options.pages.join("");
}
if (DEBUG) {
this.context.debug("Got full multipage SMSCB: " + JSON.stringify(options));
}
return options;
},
_mergeCellBroadcastConfigs: function(list, from, to) {
if (!list) {
return [from, to];
}
for (let i = 0, f1, t1; i < list.length;) {
f1 = list[i++];
t1 = list[i++];
if (to == f1) {
// ...[from]...[to|f1]...(t1)
list[i - 2] = from;
return list;
}
if (to < f1) {
// ...[from]...(to)...[f1] or ...[from]...(to)[f1]
if (i > 2) {
// Not the first range pair, merge three arrays.
return list.slice(0, i - 2).concat([from, to]).concat(list.slice(i - 2));
} else {
return [from, to].concat(list);
}
}
if (from > t1) {
// ...[f1]...(t1)[from] or ...[f1]...(t1)...[from]
continue;
}
// Have overlap or merge-able adjacency with [f1]...(t1). Replace it
// with [min(from, f1)]...(max(to, t1)).
let changed = false;
if (from < f1) {
// [from]...[f1]...(t1) or [from][f1]...(t1)
// Save minimum from value.
list[i - 2] = from;
changed = true;
}
if (to <= t1) {
// [from]...[to](t1) or [from]...(to|t1)
// Can't have further merge-able adjacency. Return.
return list;
}
// Try merging possible next adjacent range.
let j = i;
for (let f2, t2; j < list.length;) {
f2 = list[j++];
t2 = list[j++];
if (to > t2) {
// [from]...[f2]...[t2]...(to) or [from]...[f2]...[t2](to)
// Merge next adjacent range again.
continue;
}
if (to < t2) {
if (to < f2) {
// [from]...(to)[f2] or [from]...(to)...[f2]
// Roll back and give up.
j -= 2;
} else if (to < t2) {
// [from]...[to|f2]...(t2), or [from]...[f2]...[to](t2)
// Merge to [from]...(t2) and give up.
to = t2;
}
}
break;
}
// Save maximum to value.
list[i - 1] = to;
if (j != i) {
// Remove merged adjacent ranges.
let ret = list.slice(0, i);
if (j < list.length) {
ret = ret.concat(list.slice(j));
}
return ret;
}
return list;
}
// Append to the end.
list.push(from);
list.push(to);
return list;
},
_isCellBroadcastConfigReady: function() {
if (!("MMI" in this.cellBroadcastConfigs)) {
return false;
}
// CBMI should be ready in GSM.
if (!this._isCdma &&
(!("CBMI" in this.cellBroadcastConfigs) ||
!("CBMID" in this.cellBroadcastConfigs) ||
!("CBMIR" in this.cellBroadcastConfigs))) {
return false;
}
return true;
},
/**
* Merge all members of cellBroadcastConfigs into mergedCellBroadcastConfig.
*/
_mergeAllCellBroadcastConfigs: function() {
if (!this._isCellBroadcastConfigReady()) {
if (DEBUG) {
this.context.debug("cell broadcast configs not ready, waiting ...");
}
return;
}
// Prepare cell broadcast config. CBMI* are only used in GSM.
let usedCellBroadcastConfigs = {MMI: this.cellBroadcastConfigs.MMI};
if (!this._isCdma) {
usedCellBroadcastConfigs.CBMI = this.cellBroadcastConfigs.CBMI;
usedCellBroadcastConfigs.CBMID = this.cellBroadcastConfigs.CBMID;
usedCellBroadcastConfigs.CBMIR = this.cellBroadcastConfigs.CBMIR;
}
if (DEBUG) {
this.context.debug("Cell Broadcast search lists: " +
JSON.stringify(usedCellBroadcastConfigs));
}
let list = null;
for each (let ll in usedCellBroadcastConfigs) {
if (ll == null) {
continue;
}
for (let i = 0; i < ll.length; i += 2) {
list = this._mergeCellBroadcastConfigs(list, ll[i], ll[i + 1]);
}
}
if (DEBUG) {
this.context.debug("Cell Broadcast search lists(merged): " +
JSON.stringify(list));
}
this.mergedCellBroadcastConfig = list;
this.updateCellBroadcastConfig();
},
/**
* Check whether search list from settings is settable by MMI, that is,
* whether the range is bounded in any entries of CB_NON_MMI_SETTABLE_RANGES.
*/
_checkCellBroadcastMMISettable: function(from, to) {
if ((to <= from) || (from >= 65536) || (from < 0)) {
return false;
}
if (!this._isCdma) {
// GSM not settable ranges.
for (let i = 0, f, t; i < CB_NON_MMI_SETTABLE_RANGES.length;) {
f = CB_NON_MMI_SETTABLE_RANGES[i++];
t = CB_NON_MMI_SETTABLE_RANGES[i++];
if ((from < t) && (to > f)) {
// Have overlap.
return false;
}
}
}
return true;
},
/**
* Convert Cell Broadcast settings string into search list.
*/
_convertCellBroadcastSearchList: function(searchListStr) {
let parts = searchListStr && searchListStr.split(",");
if (!parts) {
return null;
}
let list = null;
let result, from, to;
for (let range of parts) {
// Match "12" or "12-34". The result will be ["12", "12", null] or
// ["12-34", "12", "34"].
result = range.match(/^(\d+)(?:-(\d+))?$/);
if (!result) {
throw "Invalid format";
}
from = parseInt(result[1], 10);
to = (result[2]) ? parseInt(result[2], 10) + 1 : from + 1;
if (!this._checkCellBroadcastMMISettable(from, to)) {
throw "Invalid range";
}
if (list == null) {
list = [];
}
list.push(from);
list.push(to);
}
return list;
},
/**
* Handle incoming messages from the main UI thread.
*
* @param message
* Object containing the message. Messages are supposed
*/
handleChromeMessage: function(message) {
if (DEBUG) {
this.context.debug("Received chrome message " + JSON.stringify(message));
}
let method = this[message.rilMessageType];
if (typeof method != "function") {
if (DEBUG) {
this.context.debug("Don't know what to do with message " +
JSON.stringify(message));
}
return;
}
method.call(this, message);
},
/**
* Process STK Proactive Command.
*/
processStkProactiveCommand: function() {
let Buf = this.context.Buf;
let length = Buf.readInt32();
let berTlv;
try {
berTlv = this.context.BerTlvHelper.decode(length / 2);
} catch (e) {
if (DEBUG) this.context.debug("processStkProactiveCommand : " + e);
this.sendStkTerminalResponse({
resultCode: STK_RESULT_CMD_DATA_NOT_UNDERSTOOD});
return;
}
Buf.readStringDelimiter(length);
let ctlvs = berTlv.value;
let ctlv = this.context.StkProactiveCmdHelper.searchForTag(
COMPREHENSIONTLV_TAG_COMMAND_DETAILS, ctlvs);
if (!ctlv) {
this.sendStkTerminalResponse({
resultCode: STK_RESULT_CMD_DATA_NOT_UNDERSTOOD});
throw new Error("Can't find COMMAND_DETAILS ComprehensionTlv");
}
let cmdDetails = ctlv.value;
if (DEBUG) {
this.context.debug("commandNumber = " + cmdDetails.commandNumber +
" typeOfCommand = " + cmdDetails.typeOfCommand.toString(16) +
" commandQualifier = " + cmdDetails.commandQualifier);
}
// STK_CMD_MORE_TIME need not to propagate event to chrome.
if (cmdDetails.typeOfCommand == STK_CMD_MORE_TIME) {
this.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_OK});
return;
}
this.context.StkCommandParamsFactory.createParam(cmdDetails,
ctlvs,
(aResult) => {
cmdDetails.options = aResult;
cmdDetails.rilMessageType = "stkcommand";
this.sendChromeMessage(cmdDetails);
});
},
sendDefaultResponse: function(options) {
if (!options.rilMessageType) {
return;
}
this.sendChromeMessage(options);
},
/**
* Send messages to the main thread.
*/
sendChromeMessage: function(message) {
message.rilMessageClientId = this.context.clientId;
postMessage(message);
},
/**
* Handle incoming requests from the RIL. We find the method that
* corresponds to the request type. Incidentally, the request type
* _is_ the method name, so that's easy.
*/
handleParcel: function(request_type, length, options) {
let method = this[request_type];
if (typeof method == "function") {
if (DEBUG) this.context.debug("Handling parcel as " + method.name);
method.call(this, length, options);
}
if (this.telephonyRequestQueue.isValidRequest(request_type)) {
this.telephonyRequestQueue.pop(request_type);
}
}
};
RilObject.prototype[REQUEST_GET_SIM_STATUS] = function REQUEST_GET_SIM_STATUS(length, options) {
if (options.errorMsg) {
return;
}
let iccStatus = {};
let Buf = this.context.Buf;
iccStatus.cardState = Buf.readInt32(); // CARD_STATE_*
iccStatus.universalPINState = Buf.readInt32(); // CARD_PINSTATE_*
iccStatus.gsmUmtsSubscriptionAppIndex = Buf.readInt32();
iccStatus.cdmaSubscriptionAppIndex = Buf.readInt32();
iccStatus.imsSubscriptionAppIndex = Buf.readInt32();
let apps_length = Buf.readInt32();
if (apps_length > CARD_MAX_APPS) {
apps_length = CARD_MAX_APPS;
}
iccStatus.apps = [];
for (let i = 0 ; i < apps_length ; i++) {
iccStatus.apps.push({
app_type: Buf.readInt32(), // CARD_APPTYPE_*
app_state: Buf.readInt32(), // CARD_APPSTATE_*
perso_substate: Buf.readInt32(), // CARD_PERSOSUBSTATE_*
aid: Buf.readString(),
app_label: Buf.readString(),
pin1_replaced: Buf.readInt32(),
pin1: Buf.readInt32(),
pin2: Buf.readInt32()
});
if (RILQUIRKS_SIM_APP_STATE_EXTRA_FIELDS) {
Buf.readInt32();
Buf.readInt32();
Buf.readInt32();
Buf.readInt32();
}
}
if (DEBUG) this.context.debug("iccStatus: " + JSON.stringify(iccStatus));
this._processICCStatus(iccStatus);
};
RilObject.prototype[REQUEST_ENTER_SIM_PIN] = function REQUEST_ENTER_SIM_PIN(length, options) {
this._processEnterAndChangeICCResponses(length, options);
};
RilObject.prototype[REQUEST_ENTER_SIM_PUK] = function REQUEST_ENTER_SIM_PUK(length, options) {
this._processEnterAndChangeICCResponses(length, options);
};
RilObject.prototype[REQUEST_ENTER_SIM_PIN2] = function REQUEST_ENTER_SIM_PIN2(length, options) {
this._processEnterAndChangeICCResponses(length, options);
};
RilObject.prototype[REQUEST_ENTER_SIM_PUK2] = function REQUEST_ENTER_SIM_PUK(length, options) {
this._processEnterAndChangeICCResponses(length, options);
};
RilObject.prototype[REQUEST_CHANGE_SIM_PIN] = function REQUEST_CHANGE_SIM_PIN(length, options) {
this._processEnterAndChangeICCResponses(length, options);
};
RilObject.prototype[REQUEST_CHANGE_SIM_PIN2] = function REQUEST_CHANGE_SIM_PIN2(length, options) {
this._processEnterAndChangeICCResponses(length, options);
};
RilObject.prototype[REQUEST_ENTER_NETWORK_DEPERSONALIZATION_CODE] =
function REQUEST_ENTER_NETWORK_DEPERSONALIZATION_CODE(length, options) {
this._processEnterAndChangeICCResponses(length, options);
};
RilObject.prototype[REQUEST_GET_CURRENT_CALLS] = function REQUEST_GET_CURRENT_CALLS(length, options) {
// Retry getCurrentCalls several times when error occurs.
if (options.errorMsg) {
if (this._getCurrentCallsRetryCount < GET_CURRENT_CALLS_RETRY_MAX) {
this._getCurrentCallsRetryCount++;
this.getCurrentCalls(options);
} else {
this.sendDefaultResponse(options);
}
return;
}
this._getCurrentCallsRetryCount = 0;
let Buf = this.context.Buf;
let calls_length = 0;
// The RIL won't even send us the length integer if there are no active calls.
// So only read this integer if the parcel actually has it.
if (length) {
calls_length = Buf.readInt32();
}
let calls = {};
for (let i = 0; i < calls_length; i++) {
let call = {};
// Extra uint32 field to get correct callIndex and rest of call data for
// call waiting feature.
if (RILQUIRKS_EXTRA_UINT32_2ND_CALL && i > 0) {
Buf.readInt32();
}
call.state = Buf.readInt32(); // CALL_STATE_*
call.callIndex = Buf.readInt32(); // GSM index (1-based)
call.toa = Buf.readInt32();
call.isMpty = Boolean(Buf.readInt32());
call.isMT = Boolean(Buf.readInt32());
call.als = Buf.readInt32();
call.isVoice = Boolean(Buf.readInt32());
call.isVoicePrivacy = Boolean(Buf.readInt32());
if (RILQUIRKS_CALLSTATE_EXTRA_UINT32) {
Buf.readInt32();
}
call.number = Buf.readString();
call.numberPresentation = Buf.readInt32(); // CALL_PRESENTATION_*
call.name = Buf.readString();
call.namePresentation = Buf.readInt32();
call.uusInfo = null;
let uusInfoPresent = Buf.readInt32();
if (uusInfoPresent == 1) {
call.uusInfo = {
type: Buf.readInt32(),
dcs: Buf.readInt32(),
userData: null //XXX TODO byte array?!?
};
}
if (call.isVoice) {
calls[call.callIndex] = call;
}
}
options.calls = calls;
options.rilMessageType = options.rilMessageType || "currentCalls";
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_DIAL] = function REQUEST_DIAL(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_DIAL_EMERGENCY_CALL] = function REQUEST_DIAL_EMERGENCY_CALL(length, options) {
RilObject.prototype[REQUEST_DIAL].call(this, length, options);
};
RilObject.prototype[REQUEST_GET_IMSI] = function REQUEST_GET_IMSI(length, options) {
if (options.errorMsg) {
return;
}
this.iccInfoPrivate.imsi = this.context.Buf.readString();
if (DEBUG) {
this.context.debug("IMSI: " + this.iccInfoPrivate.imsi);
}
options.rilMessageType = "iccimsi";
options.imsi = this.iccInfoPrivate.imsi;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_HANGUP] = function REQUEST_HANGUP(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_HANGUP_WAITING_OR_BACKGROUND] = function REQUEST_HANGUP_WAITING_OR_BACKGROUND(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND] = function REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE] = function REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_CONFERENCE] = function REQUEST_CONFERENCE(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_UDUB] = function REQUEST_UDUB(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_LAST_CALL_FAIL_CAUSE] = function REQUEST_LAST_CALL_FAIL_CAUSE(length, options) {
// Treat it as CALL_FAIL_ERROR_UNSPECIFIED if the request failed.
let failCause = CALL_FAIL_ERROR_UNSPECIFIED;
if (!options.errorMsg) {
let Buf = this.context.Buf;
let num = length ? Buf.readInt32() : 0;
if (num) {
let causeNum = Buf.readInt32();
failCause = RIL_CALL_FAILCAUSE_TO_GECKO_CALL_ERROR[causeNum] || failCause;
}
if (DEBUG) this.context.debug("Last call fail cause: " + failCause);
}
options.failCause = failCause;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SIGNAL_STRENGTH] = function REQUEST_SIGNAL_STRENGTH(length, options) {
this._receivedNetworkInfo(NETWORK_INFO_SIGNAL);
if (options.errorMsg) {
return;
}
let Buf = this.context.Buf;
let signal = {};
signal.gsmSignalStrength = Buf.readInt32();
signal.gsmBitErrorRate = Buf.readInt32();
if (RILQUIRKS_SIGNAL_EXTRA_INT32) {
Buf.readInt32();
}
signal.cdmaDBM = Buf.readInt32();
signal.cdmaECIO = Buf.readInt32();
signal.evdoDBM = Buf.readInt32();
signal.evdoECIO = Buf.readInt32();
signal.evdoSNR = Buf.readInt32();
signal.lteSignalStrength = Buf.readInt32();
signal.lteRSRP = Buf.readInt32();
signal.lteRSRQ = Buf.readInt32();
signal.lteRSSNR = Buf.readInt32();
signal.lteCQI = Buf.readInt32();
if (DEBUG) this.context.debug("signal strength: " + JSON.stringify(signal));
this._processSignalStrength(signal);
};
RilObject.prototype[REQUEST_VOICE_REGISTRATION_STATE] = function REQUEST_VOICE_REGISTRATION_STATE(length, options) {
this._receivedNetworkInfo(NETWORK_INFO_VOICE_REGISTRATION_STATE);
if (options.errorMsg) {
return;
}
let state = this.context.Buf.readStringList();
if (DEBUG) this.context.debug("voice registration state: " + state);
this._processVoiceRegistrationState(state);
};
RilObject.prototype[REQUEST_DATA_REGISTRATION_STATE] = function REQUEST_DATA_REGISTRATION_STATE(length, options) {
this._receivedNetworkInfo(NETWORK_INFO_DATA_REGISTRATION_STATE);
if (options.errorMsg) {
return;
}
let state = this.context.Buf.readStringList();
this._processDataRegistrationState(state);
};
RilObject.prototype[REQUEST_OPERATOR] = function REQUEST_OPERATOR(length, options) {
this._receivedNetworkInfo(NETWORK_INFO_OPERATOR);
if (options.errorMsg) {
return;
}
let operatorData = this.context.Buf.readStringList();
if (DEBUG) this.context.debug("Operator: " + operatorData);
this._processOperator(operatorData);
};
RilObject.prototype[REQUEST_RADIO_POWER] = function REQUEST_RADIO_POWER(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_DTMF] = null;
RilObject.prototype[REQUEST_SEND_SMS] = function REQUEST_SEND_SMS(length, options) {
this._processSmsSendResult(length, options);
};
RilObject.prototype[REQUEST_SEND_SMS_EXPECT_MORE] = null;
RilObject.prototype[REQUEST_SETUP_DATA_CALL] = function REQUEST_SETUP_DATA_CALL(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
let version = Buf.readInt32();
// Skip number of data calls.
Buf.readInt32();
this.readDataCall(options, version);
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SIM_IO] = function REQUEST_SIM_IO(length, options) {
if (options.errorMsg) {
if (options.onerror) {
options.onerror(options.errorMsg);
}
return;
}
let Buf = this.context.Buf;
options.sw1 = Buf.readInt32();
options.sw2 = Buf.readInt32();
// See 3GPP TS 11.11, clause 9.4.1 for operation success results.
if (options.sw1 !== ICC_STATUS_NORMAL_ENDING &&
options.sw1 !== ICC_STATUS_NORMAL_ENDING_WITH_EXTRA &&
options.sw1 !== ICC_STATUS_WITH_SIM_DATA &&
options.sw1 !== ICC_STATUS_WITH_RESPONSE_DATA) {
if (DEBUG) {
this.context.debug("ICC I/O Error EF id = 0x" + options.fileId.toString(16) +
", command = 0x" + options.command.toString(16) +
", sw1 = 0x" + options.sw1.toString(16) +
", sw2 = 0x" + options.sw2.toString(16));
}
if (options.onerror) {
// We can get fail cause from sw1/sw2 (See TS 11.11 clause 9.4.1 and
// ISO 7816-4 clause 6). But currently no one needs this information,
// so simply reports "GenericFailure" for now.
options.onerror(GECKO_ERROR_GENERIC_FAILURE);
}
return;
}
this.context.ICCIOHelper.processICCIO(options);
};
RilObject.prototype[REQUEST_SEND_USSD] = function REQUEST_SEND_USSD(length, options) {
if (DEBUG) {
this.context.debug("REQUEST_SEND_USSD " + JSON.stringify(options));
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_CANCEL_USSD] = function REQUEST_CANCEL_USSD(length, options) {
if (DEBUG) {
this.context.debug("REQUEST_CANCEL_USSD" + JSON.stringify(options));
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_GET_CLIR] = function REQUEST_GET_CLIR(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
let bufLength = Buf.readInt32();
if (!bufLength || bufLength < 2) {
options.errorMsg = GECKO_ERROR_GENERIC_FAILURE;
this.sendChromeMessage(options);
return;
}
options.n = Buf.readInt32(); // Will be TS 27.007 +CLIR parameter 'n'.
options.m = Buf.readInt32(); // Will be TS 27.007 +CLIR parameter 'm'.
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SET_CLIR] = function REQUEST_SET_CLIR(length, options) {
if (options.rilMessageType == null) {
// The request was made by ril_worker itself automatically. Don't report.
return;
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_QUERY_CALL_FORWARD_STATUS] =
function REQUEST_QUERY_CALL_FORWARD_STATUS(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
let rulesLength = 0;
if (length) {
rulesLength = Buf.readInt32();
}
if (!rulesLength) {
options.errorMsg = GECKO_ERROR_GENERIC_FAILURE;
this.sendChromeMessage(options);
return;
}
let rules = new Array(rulesLength);
for (let i = 0; i < rulesLength; i++) {
let rule = {};
rule.active = Buf.readInt32() == 1; // CALL_FORWARD_STATUS_*
rule.reason = Buf.readInt32(); // CALL_FORWARD_REASON_*
rule.serviceClass = Buf.readInt32();
rule.toa = Buf.readInt32();
rule.number = Buf.readString();
rule.timeSeconds = Buf.readInt32();
rules[i] = rule;
}
options.rules = rules;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SET_CALL_FORWARD] =
function REQUEST_SET_CALL_FORWARD(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_QUERY_CALL_WAITING] =
function REQUEST_QUERY_CALL_WAITING(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
let results = Buf.readInt32List();
let enabled = (results[0] === 1);
options.serviceClass = enabled ? results[1] : ICC_SERVICE_CLASS_NONE;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SET_CALL_WAITING] = function REQUEST_SET_CALL_WAITING(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SMS_ACKNOWLEDGE] = null;
RilObject.prototype[REQUEST_GET_IMEI] = function REQUEST_GET_IMEI(length, options) {
this.IMEI = this.context.Buf.readString();
// If the request wasn't made by ril_worker itself, we send the IMEI back to
// chrome.
if (options.rilMessageType) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
options.imei = this.IMEI;
this.sendChromeMessage(options);
}
};
RilObject.prototype[REQUEST_GET_IMEISV] = function REQUEST_GET_IMEISV(length, options) {
if (options.errorMsg) {
return;
}
this.IMEISV = this.context.Buf.readString();
};
RilObject.prototype[REQUEST_ANSWER] = function REQUEST_ANSWER(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_DEACTIVATE_DATA_CALL] = function REQUEST_DEACTIVATE_DATA_CALL(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_QUERY_FACILITY_LOCK] = function REQUEST_QUERY_FACILITY_LOCK(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
if (!length) {
options.errorMsg = GECKO_ERROR_GENERIC_FAILURE;
this.sendChromeMessage(options);
return;
}
// Buf.readInt32List()[0] for Call Barring is a bit vector of services.
options.serviceClass = this.context.Buf.readInt32List()[0];
if (options.queryServiceClass) {
options.enabled = (options.serviceClass & options.queryServiceClass) ? true : false;
options.serviceClass = options.queryServiceClass;
} else {
options.enabled = options.serviceClass ? true : false;
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SET_FACILITY_LOCK] = function REQUEST_SET_FACILITY_LOCK(length, options) {
options.retryCount = length ? this.context.Buf.readInt32List()[0] : -1;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_CHANGE_BARRING_PASSWORD] =
function REQUEST_CHANGE_BARRING_PASSWORD(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_QUERY_NETWORK_SELECTION_MODE] = function REQUEST_QUERY_NETWORK_SELECTION_MODE(length, options) {
this._receivedNetworkInfo(NETWORK_INFO_NETWORK_SELECTION_MODE);
if (options.errorMsg) {
return;
}
let mode = this.context.Buf.readInt32List();
let selectionMode;
switch (mode[0]) {
case NETWORK_SELECTION_MODE_AUTOMATIC:
selectionMode = GECKO_NETWORK_SELECTION_AUTOMATIC;
break;
case NETWORK_SELECTION_MODE_MANUAL:
selectionMode = GECKO_NETWORK_SELECTION_MANUAL;
break;
default:
selectionMode = GECKO_NETWORK_SELECTION_UNKNOWN;
break;
}
this._updateNetworkSelectionMode(selectionMode);
};
RilObject.prototype[REQUEST_SET_NETWORK_SELECTION_AUTOMATIC] = function REQUEST_SET_NETWORK_SELECTION_AUTOMATIC(length, options) {
if (!options.errorMsg) {
this._updateNetworkSelectionMode(GECKO_NETWORK_SELECTION_AUTOMATIC);
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SET_NETWORK_SELECTION_MANUAL] = function REQUEST_SET_NETWORK_SELECTION_MANUAL(length, options) {
if (!options.errorMsg) {
this._updateNetworkSelectionMode(GECKO_NETWORK_SELECTION_MANUAL);
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_QUERY_AVAILABLE_NETWORKS] = function REQUEST_QUERY_AVAILABLE_NETWORKS(length, options) {
if (!options.errorMsg) {
options.networks = this._processNetworks();
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_DTMF_START] = function REQUEST_DTMF_START(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_DTMF_STOP] = null;
RilObject.prototype[REQUEST_BASEBAND_VERSION] = function REQUEST_BASEBAND_VERSION(length, options) {
if (options.errorMsg) {
return;
}
this.basebandVersion = this.context.Buf.readString();
if (DEBUG) this.context.debug("Baseband version: " + this.basebandVersion);
};
RilObject.prototype[REQUEST_SEPARATE_CONNECTION] = function REQUEST_SEPARATE_CONNECTION(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_SET_MUTE] = null;
RilObject.prototype[REQUEST_GET_MUTE] = null;
RilObject.prototype[REQUEST_QUERY_CLIP] = function REQUEST_QUERY_CLIP(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
let bufLength = Buf.readInt32();
if (!bufLength) {
options.errorMsg = GECKO_ERROR_GENERIC_FAILURE;
this.sendChromeMessage(options);
return;
}
options.provisioned = Buf.readInt32();
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_LAST_DATA_CALL_FAIL_CAUSE] = null;
/**
* V6:
* # addresses - A space-delimited list of addresses with optional "/" prefix
* length.
* # dnses - A space-delimited list of DNS server addresses.
* # gateways - A space-delimited list of default gateway addresses.
*
* V10:
* # pcscf - A space-delimited list of Proxy Call State Control Function
* addresses.
*/
RilObject.prototype.readDataCall = function(options, version) {
if (!options) {
options = {};
}
let Buf = this.context.Buf;
options.failCause = Buf.readInt32(); // DATACALL_FAIL_*
options.suggestedRetryTime = Buf.readInt32();
options.cid = Buf.readInt32().toString();
options.active = Buf.readInt32(); // DATACALL_ACTIVE_*
options.type = Buf.readString();
options.ifname = Buf.readString();
options.addresses = Buf.readString();
options.dnses = Buf.readString();
options.gateways = Buf.readString();
if (version >= 10) {
options.pcscf = Buf.readString();
}
if (version >= 11) {
let mtu = Buf.readInt32();
options.mtu = (mtu > 0) ? mtu : -1 ;
}
return options;
};
RilObject.prototype[REQUEST_DATA_CALL_LIST] = function REQUEST_DATA_CALL_LIST(length, options) {
if (options.errorMsg) {
if (options.rilMessageType) {
this.sendChromeMessage(options);
}
return;
}
if (!options.rilMessageType) {
// This is an unsolicited data call list changed.
options.rilMessageType = "datacalllistchanged";
}
if (!length) {
options.datacalls = [];
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
let version = Buf.readInt32();
let num = Buf.readInt32();
let datacalls = [];
for (let i = 0; i < num; i++) {
let datacall;
datacall = this.readDataCall({}, version);
datacalls.push(datacall);
}
options.datacalls = datacalls;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_RESET_RADIO] = null;
RilObject.prototype[REQUEST_OEM_HOOK_RAW] = null;
RilObject.prototype[REQUEST_OEM_HOOK_STRINGS] = null;
RilObject.prototype[REQUEST_SCREEN_STATE] = null;
RilObject.prototype[REQUEST_SET_SUPP_SVC_NOTIFICATION] = null;
RilObject.prototype[REQUEST_WRITE_SMS_TO_SIM] = function REQUEST_WRITE_SMS_TO_SIM(length, options) {
if (options.errorMsg) {
// `The MS shall return a "protocol error, unspecified" error message if
// the short message cannot be stored in the (U)SIM, and there is other
// message storage available at the MS` ~ 3GPP TS 23.038 section 4. Here
// we assume we always have indexed db as another storage.
this.acknowledgeGsmSms(false, PDU_FCS_PROTOCOL_ERROR);
} else {
this.acknowledgeGsmSms(true, PDU_FCS_OK);
}
};
RilObject.prototype[REQUEST_DELETE_SMS_ON_SIM] = null;
RilObject.prototype[REQUEST_SET_BAND_MODE] = null;
RilObject.prototype[REQUEST_QUERY_AVAILABLE_BAND_MODE] = null;
RilObject.prototype[REQUEST_STK_GET_PROFILE] = null;
RilObject.prototype[REQUEST_STK_SET_PROFILE] = null;
RilObject.prototype[REQUEST_STK_SEND_ENVELOPE_COMMAND] = null;
RilObject.prototype[REQUEST_STK_SEND_TERMINAL_RESPONSE] = null;
RilObject.prototype[REQUEST_STK_HANDLE_CALL_SETUP_REQUESTED_FROM_SIM] = null;
RilObject.prototype[REQUEST_EXPLICIT_CALL_TRANSFER] = null;
RilObject.prototype[REQUEST_SET_PREFERRED_NETWORK_TYPE] = function REQUEST_SET_PREFERRED_NETWORK_TYPE(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_GET_PREFERRED_NETWORK_TYPE] = function REQUEST_GET_PREFERRED_NETWORK_TYPE(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
options.type = this.context.Buf.readInt32List()[0];
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_GET_NEIGHBORING_CELL_IDS] = function REQUEST_GET_NEIGHBORING_CELL_IDS(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let radioTech = this.voiceRegistrationState.radioTech;
if (radioTech == undefined || radioTech == NETWORK_CREG_TECH_UNKNOWN) {
options.errorMsg = "RadioTechUnavailable";
this.sendChromeMessage(options);
return;
}
if (!this._isGsmTechGroup(radioTech) || radioTech == NETWORK_CREG_TECH_LTE) {
options.errorMsg = "UnsupportedRadioTech";
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
let neighboringCellIds = [];
let num = Buf.readInt32();
for (let i = 0; i < num; i++) {
let cellId = {};
cellId.networkType = GECKO_RADIO_TECH[radioTech];
cellId.signalStrength = Buf.readInt32();
let cid = Buf.readString();
// pad cid string with leading "0"
let length = cid.length;
if (length > 8) {
continue;
}
if (length < 8) {
for (let j = 0; j < (8-length); j++) {
cid = "0" + cid;
}
}
switch (radioTech) {
case NETWORK_CREG_TECH_GPRS:
case NETWORK_CREG_TECH_EDGE:
case NETWORK_CREG_TECH_GSM:
cellId.gsmCellId = this.parseInt(cid.substring(4), -1, 16);
cellId.gsmLocationAreaCode = this.parseInt(cid.substring(0, 4), -1, 16);
break;
case NETWORK_CREG_TECH_UMTS:
case NETWORK_CREG_TECH_HSDPA:
case NETWORK_CREG_TECH_HSUPA:
case NETWORK_CREG_TECH_HSPA:
case NETWORK_CREG_TECH_HSPAP:
case NETWORK_CREG_TECH_DCHSPAP_1:
case NETWORK_CREG_TECH_DCHSPAP_2:
cellId.wcdmaPsc = this.parseInt(cid, -1, 16);
break;
}
neighboringCellIds.push(cellId);
}
options.result = neighboringCellIds;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_GET_CELL_INFO_LIST] = function REQUEST_GET_CELL_INFO_LIST(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
let cellInfoList = [];
let num = Buf.readInt32();
for (let i = 0; i < num; i++) {
let cellInfo = {};
cellInfo.type = Buf.readInt32();
cellInfo.registered = Buf.readInt32() ? true : false;
cellInfo.timestampType = Buf.readInt32();
cellInfo.timestamp = Buf.readInt64();
switch(cellInfo.type) {
case CELL_INFO_TYPE_GSM:
case CELL_INFO_TYPE_WCDMA:
cellInfo.mcc = Buf.readInt32();
cellInfo.mnc = Buf.readInt32();
cellInfo.lac = Buf.readInt32();
cellInfo.cid = Buf.readInt32();
if (cellInfo.type == CELL_INFO_TYPE_WCDMA) {
cellInfo.psc = Buf.readInt32();
}
cellInfo.signalStrength = Buf.readInt32();
cellInfo.bitErrorRate = Buf.readInt32();
break;
case CELL_INFO_TYPE_CDMA:
cellInfo.networkId = Buf.readInt32();
cellInfo.systemId = Buf.readInt32();
cellInfo.basestationId = Buf.readInt32();
cellInfo.longitude = Buf.readInt32();
cellInfo.latitude = Buf.readInt32();
cellInfo.cdmaDbm = Buf.readInt32();
cellInfo.cdmaEcio = Buf.readInt32();
cellInfo.evdoDbm = Buf.readInt32();
cellInfo.evdoEcio = Buf.readInt32();
cellInfo.evdoSnr = Buf.readInt32();
break;
case CELL_INFO_TYPE_LTE:
cellInfo.mcc = Buf.readInt32();
cellInfo.mnc = Buf.readInt32();
cellInfo.cid = Buf.readInt32();
cellInfo.pcid = Buf.readInt32();
cellInfo.tac = Buf.readInt32();
cellInfo.signalStrength = Buf.readInt32();
cellInfo.rsrp = Buf.readInt32();
cellInfo.rsrq = Buf.readInt32();
cellInfo.rssnr = Buf.readInt32();
cellInfo.cqi = Buf.readInt32();
break;
}
cellInfoList.push(cellInfo);
}
options.result = cellInfoList;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SET_LOCATION_UPDATES] = null;
RilObject.prototype[REQUEST_CDMA_SET_SUBSCRIPTION_SOURCE] = null;
RilObject.prototype[REQUEST_CDMA_SET_ROAMING_PREFERENCE] = function REQUEST_CDMA_SET_ROAMING_PREFERENCE(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_CDMA_QUERY_ROAMING_PREFERENCE] = function REQUEST_CDMA_QUERY_ROAMING_PREFERENCE(length, options) {
if (!options.errorMsg) {
options.mode = this.context.Buf.readInt32List()[0];
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SET_TTY_MODE] = null;
RilObject.prototype[REQUEST_QUERY_TTY_MODE] = null;
RilObject.prototype[REQUEST_CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE] = function REQUEST_CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE] = function REQUEST_CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let enabled = this.context.Buf.readInt32List();
options.enabled = enabled[0] ? true : false;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_CDMA_FLASH] = function REQUEST_CDMA_FLASH(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_CDMA_BURST_DTMF] = null;
RilObject.prototype[REQUEST_CDMA_VALIDATE_AND_WRITE_AKEY] = null;
RilObject.prototype[REQUEST_CDMA_SEND_SMS] = function REQUEST_CDMA_SEND_SMS(length, options) {
this._processSmsSendResult(length, options);
};
RilObject.prototype[REQUEST_CDMA_SMS_ACKNOWLEDGE] = null;
RilObject.prototype[REQUEST_GSM_GET_BROADCAST_SMS_CONFIG] = null;
RilObject.prototype[REQUEST_GSM_SET_BROADCAST_SMS_CONFIG] = function REQUEST_GSM_SET_BROADCAST_SMS_CONFIG(length, options) {
if (options.errorMsg) {
return;
}
this.setSmsBroadcastActivation(true);
};
RilObject.prototype[REQUEST_GSM_SMS_BROADCAST_ACTIVATION] = null;
RilObject.prototype[REQUEST_CDMA_GET_BROADCAST_SMS_CONFIG] = null;
RilObject.prototype[REQUEST_CDMA_SET_BROADCAST_SMS_CONFIG] = function REQUEST_CDMA_SET_BROADCAST_SMS_CONFIG(length, options) {
if (options.errorMsg) {
return;
}
this.setSmsBroadcastActivation(true);
};
RilObject.prototype[REQUEST_CDMA_SMS_BROADCAST_ACTIVATION] = null;
RilObject.prototype[REQUEST_CDMA_SUBSCRIPTION] = function REQUEST_CDMA_SUBSCRIPTION(length, options) {
if (options.errorMsg) {
return;
}
let result = this.context.Buf.readStringList();
this.iccInfo.mdn = result[0];
// The result[1] is Home SID. (Already be handled in readCDMAHome())
// The result[2] is Home NID. (Already be handled in readCDMAHome())
// The result[3] is MIN.
this.iccInfo.prlVersion = parseInt(result[4], 10);
this.context.ICCUtilsHelper.handleICCInfoChange();
};
RilObject.prototype[REQUEST_CDMA_WRITE_SMS_TO_RUIM] = null;
RilObject.prototype[REQUEST_CDMA_DELETE_SMS_ON_RUIM] = null;
RilObject.prototype[REQUEST_DEVICE_IDENTITY] = function REQUEST_DEVICE_IDENTITY(length, options) {
if (options.errorMsg) {
return;
}
let result = this.context.Buf.readStringList();
// The result[0] is for IMEI. (Already be handled in REQUEST_GET_IMEI)
// The result[1] is for IMEISV. (Already be handled in REQUEST_GET_IMEISV)
// They are both ignored.
this.ESN = result[2];
this.MEID = result[3];
};
RilObject.prototype[REQUEST_EXIT_EMERGENCY_CALLBACK_MODE] = function REQUEST_EXIT_EMERGENCY_CALLBACK_MODE(length, options) {
if (options.internal) {
return;
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_GET_SMSC_ADDRESS] = function REQUEST_GET_SMSC_ADDRESS(length, options) {
if (!options.rilMessageType || options.rilMessageType !== "getSmscAddress") {
return;
}
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let tosca = TOA_UNKNOWN;
let smsc = "";
let Buf = this.context.Buf;
if (RILQUIRKS_SMSC_ADDRESS_FORMAT === "pdu") {
let pduHelper = this.context.GsmPDUHelper;
let strlen = Buf.readInt32();
let length = pduHelper.readHexOctet();
// As defined in |8.2.5.2 Destination address element| of 3GPP TS 24.011,
// the value of length field can not exceed 11. Since the content might be
// filled with 12 'F' when SMSC is cleared, we don't parse the TOA and
// address fields if reported length exceeds 11 here. Instead, keep the
// default value (TOA_UNKNOWN with an empty address) in this case.
const MAX_LENGTH = 11
if (length <= MAX_LENGTH) {
tosca = pduHelper.readHexOctet();
// Read and covert the decimal values back to special BCD digits defined in
// |Called party BCD number| of 3GPP TS 24.008 (refer the following table).
//
// +=========+=======+=====+
// | value | digit | hex |
// +========================
// | 1 0 1 0 | * | 0xA |
// | 1 0 1 1 | # | 0xB |
// | 1 1 0 0 | a | 0xC |
// | 1 1 0 1 | b | 0xD |
// | 1 1 1 0 | c | 0xE |
// +=========+=======+=====+
smsc = pduHelper.readSwappedNibbleBcdString(length - 1, true)
.replace(/a/ig, "*")
.replace(/b/ig, "#")
.replace(/c/ig, "a")
.replace(/d/ig, "b")
.replace(/e/ig, "c");
Buf.readStringDelimiter(strlen);
}
} else /* RILQUIRKS_SMSC_ADDRESS_FORMAT === "text" */ {
let text = Buf.readString();
let segments = text.split(",", 2);
// Parse TOA only if it presents since some devices might omit the TOA
// segment in the reported SMSC address. If TOA does not present, keep the
// default value TOA_UNKNOWN.
if (segments.length === 2) {
tosca = this.parseInt(segments[1], TOA_UNKNOWN, 10);
}
smsc = segments[0].replace(/\"/g, "");
}
// Convert the NPI value to the corresponding index of CALLED_PARTY_BCD_NPI
// array. If the value does not present in the array, use
// CALLED_PARTY_BCD_NPI_ISDN.
let npi = CALLED_PARTY_BCD_NPI.indexOf(tosca & 0xf);
if (npi === -1) {
npi = CALLED_PARTY_BCD_NPI.indexOf(CALLED_PARTY_BCD_NPI_ISDN);
}
// Extract TON.
let ton = (tosca & 0x70) >> 4;
// Ensure + sign if TON is international, and vice versa.
const TON_INTERNATIONAL = (TOA_INTERNATIONAL & 0x70) >> 4;
if (ton === TON_INTERNATIONAL && smsc.charAt(0) !== "+") {
smsc = "+" + smsc;
} else if (smsc.charAt(0) === "+" && ton !== TON_INTERNATIONAL) {
if (DEBUG) {
this.context.debug("SMSC address number begins with '+' while the TON is not international. Change TON to international.");
}
ton = TON_INTERNATIONAL;
}
options.smscAddress = smsc;
options.typeOfNumber = ton;
options.numberPlanIdentification = npi;
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SET_SMSC_ADDRESS] = function REQUEST_SET_SMSC_ADDRESS(length, options) {
if (!options.rilMessageType || options.rilMessageType !== "setSmscAddress") {
return;
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_REPORT_SMS_MEMORY_STATUS] = function REQUEST_REPORT_SMS_MEMORY_STATUS(length, options) {
this.pendingToReportSmsMemoryStatus = !!options.errorMsg;
};
RilObject.prototype[REQUEST_REPORT_STK_SERVICE_IS_RUNNING] = null;
RilObject.prototype[REQUEST_CDMA_GET_SUBSCRIPTION_SOURCE] = null;
RilObject.prototype[REQUEST_ISIM_AUTHENTICATION] = null;
RilObject.prototype[REQUEST_ACKNOWLEDGE_INCOMING_GSM_SMS_WITH_PDU] = null;
RilObject.prototype[REQUEST_STK_SEND_ENVELOPE_WITH_STATUS] = function REQUEST_STK_SEND_ENVELOPE_WITH_STATUS(length, options) {
if (options.errorMsg) {
this.acknowledgeGsmSms(false, PDU_FCS_UNSPECIFIED);
return;
}
let Buf = this.context.Buf;
let sw1 = Buf.readInt32();
let sw2 = Buf.readInt32();
if ((sw1 == ICC_STATUS_SAT_BUSY) && (sw2 === 0x00)) {
this.acknowledgeGsmSms(false, PDU_FCS_USAT_BUSY);
return;
}
let success = ((sw1 == ICC_STATUS_NORMAL_ENDING) && (sw2 === 0x00))
|| (sw1 == ICC_STATUS_NORMAL_ENDING_WITH_EXTRA);
let messageStringLength = Buf.readInt32(); // In semi-octets
let responsePduLen = messageStringLength / 2; // In octets
if (!responsePduLen) {
this.acknowledgeGsmSms(success, success ? PDU_FCS_OK
: PDU_FCS_USIM_DATA_DOWNLOAD_ERROR);
return;
}
this.acknowledgeIncomingGsmSmsWithPDU(success, responsePduLen, options);
};
RilObject.prototype[REQUEST_VOICE_RADIO_TECH] = function REQUEST_VOICE_RADIO_TECH(length, options) {
if (options.errorMsg) {
if (DEBUG) {
this.context.debug("Error when getting voice radio tech: " +
options.errorMsg);
}
return;
}
let radioTech = this.context.Buf.readInt32List();
this._processRadioTech(radioTech[0]);
};
RilObject.prototype[REQUEST_SET_UNSOL_CELL_INFO_LIST_RATE] = null;
RilObject.prototype[REQUEST_SET_INITIAL_ATTACH_APN] = null;
RilObject.prototype[REQUEST_IMS_REGISTRATION_STATE] = null;
RilObject.prototype[REQUEST_IMS_SEND_SMS] = null;
RilObject.prototype[REQUEST_SIM_TRANSMIT_APDU_BASIC] = null;
RilObject.prototype[REQUEST_SIM_OPEN_CHANNEL] = function REQUEST_SIM_OPEN_CHANNEL(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
options.channel = this.context.Buf.readInt32List()[0];
// onwards may optionally contain the select response for the open channel
// command with one byte per integer.
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_SIM_CLOSE_CHANNEL] = function REQUEST_SIM_CLOSE_CHANNEL(length, options) {
this.sendDefaultResponse(options);
};
RilObject.prototype[REQUEST_SIM_TRANSMIT_APDU_CHANNEL] = function REQUEST_SIM_TRANSMIT_APDU_CHANNEL(length, options) {
if (options.errorMsg) {
this.sendChromeMessage(options);
return;
}
let Buf = this.context.Buf;
options.sw1 = Buf.readInt32();
options.sw2 = Buf.readInt32();
options.simResponse = Buf.readString();
if (DEBUG) {
this.context.debug("Setting return values for RIL[REQUEST_SIM_TRANSMIT_APDU_CHANNEL]: [" +
options.sw1 + "," +
options.sw2 + ", " +
options.simResponse + "]");
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_NV_READ_ITEM] = null;
RilObject.prototype[REQUEST_NV_WRITE_ITEM] = null;
RilObject.prototype[REQUEST_NV_WRITE_CDMA_PRL] = null;
RilObject.prototype[REQUEST_NV_RESET_CONFIG] = null;
RilObject.prototype[REQUEST_SET_UICC_SUBSCRIPTION] = function REQUEST_SET_UICC_SUBSCRIPTION(length, options) {
// Resend data subscription after uicc subscription.
if (this._attachDataRegistration) {
this.setDataRegistration({attach: true});
}
};
RilObject.prototype[REQUEST_ALLOW_DATA] = null;
RilObject.prototype[REQUEST_GET_HARDWARE_CONFIG] = null;
RilObject.prototype[REQUEST_SIM_AUTHENTICATION] = null;
RilObject.prototype[REQUEST_GET_DC_RT_INFO] = null;
RilObject.prototype[REQUEST_SET_DC_RT_INFO_RATE] = null;
RilObject.prototype[REQUEST_SET_DATA_PROFILE] = null;
RilObject.prototype[REQUEST_SHUTDOWN] = null;
RilObject.prototype[REQUEST_SET_DATA_SUBSCRIPTION] = function REQUEST_SET_DATA_SUBSCRIPTION(length, options) {
if (!options.rilMessageType) {
// The request was made by ril_worker itself. Don't report.
return;
}
this.sendChromeMessage(options);
};
RilObject.prototype[REQUEST_GET_UNLOCK_RETRY_COUNT] = function REQUEST_GET_UNLOCK_RETRY_COUNT(length, options) {
options.retryCount = length ? this.context.Buf.readInt32List()[0] : -1;
this.sendChromeMessage(options);
};
RilObject.prototype[RIL_REQUEST_GPRS_ATTACH] = function RIL_REQUEST_GPRS_ATTACH(length, options) {
if (!options.rilMessageType) {
// The request was made by ril_worker itself. Don't report.
return;
}
this.sendChromeMessage(options);
};
RilObject.prototype[RIL_REQUEST_GPRS_DETACH] = function RIL_REQUEST_GPRS_DETACH(length, options) {
this.sendChromeMessage(options);
};
RilObject.prototype[UNSOLICITED_RESPONSE_RADIO_STATE_CHANGED] = function UNSOLICITED_RESPONSE_RADIO_STATE_CHANGED() {
let radioState = this.context.Buf.readInt32();
let newState;
switch (radioState) {
case RADIO_STATE_UNAVAILABLE:
newState = GECKO_RADIOSTATE_UNKNOWN;
break;
case RADIO_STATE_OFF:
newState = GECKO_RADIOSTATE_DISABLED;
break;
default:
newState = GECKO_RADIOSTATE_ENABLED;
}
if (DEBUG) {
this.context.debug("Radio state changed from '" + this.radioState +
"' to '" + newState + "'");
}
if (this.radioState == newState) {
return;
}
if (radioState == RADIO_STATE_ON) {
// This value is defined in RIL v7, we will retrieve radio tech by another
// request. We leave _isCdma untouched, and it will be set once we get the
// radio technology.
this._waitingRadioTech = true;
this.getVoiceRadioTechnology();
}
if ((this.radioState == GECKO_RADIOSTATE_UNKNOWN ||
this.radioState == GECKO_RADIOSTATE_DISABLED) &&
newState == GECKO_RADIOSTATE_ENABLED) {
// The radio became available, let's get its info.
if (!this._waitingRadioTech) {
if (this._isCdma) {
this.getDeviceIdentity();
} else {
this.getIMEI();
this.getIMEISV();
}
}
this.getBasebandVersion();
this.updateCellBroadcastConfig();
if ((RILQUIRKS_DATA_REGISTRATION_ON_DEMAND ||
RILQUIRKS_SUBSCRIPTION_CONTROL) &&
this._attachDataRegistration) {
this.setDataRegistration({attach: true});
}
if (this.pendingToReportSmsMemoryStatus) {
this._updateSmsMemoryStatus();
}
}
this.radioState = newState;
this.sendChromeMessage({
rilMessageType: "radiostatechange",
radioState: newState
});
// If the radio is up and on, so let's query the card state.
// On older RILs only if the card is actually ready, though.
// If _waitingRadioTech is set, we don't need to get icc status now.
if (radioState == RADIO_STATE_UNAVAILABLE ||
radioState == RADIO_STATE_OFF ||
this._waitingRadioTech) {
return;
}
this.getICCStatus();
};
RilObject.prototype[UNSOLICITED_RESPONSE_CALL_STATE_CHANGED] = function UNSOLICITED_RESPONSE_CALL_STATE_CHANGED() {
this.getCurrentCalls();
};
RilObject.prototype[UNSOLICITED_RESPONSE_VOICE_NETWORK_STATE_CHANGED] = function UNSOLICITED_RESPONSE_VOICE_NETWORK_STATE_CHANGED() {
if (DEBUG) {
this.context.debug("Network state changed, re-requesting phone state and " +
"ICC status");
}
this.getICCStatus();
this.requestNetworkInfo();
};
RilObject.prototype[UNSOLICITED_RESPONSE_NEW_SMS] = function UNSOLICITED_RESPONSE_NEW_SMS(length) {
let [message, result] = this.context.GsmPDUHelper.processReceivedSms(length);
if (message) {
result = this._processSmsMultipart(message);
}
if (result == PDU_FCS_RESERVED || result == MOZ_FCS_WAIT_FOR_EXPLICIT_ACK) {
return;
}
// Not reserved FCS values, send ACK now.
this.acknowledgeGsmSms(result == PDU_FCS_OK, result);
};
RilObject.prototype[UNSOLICITED_RESPONSE_NEW_SMS_STATUS_REPORT] = function UNSOLICITED_RESPONSE_NEW_SMS_STATUS_REPORT(length) {
let result = this._processSmsStatusReport(length);
this.acknowledgeGsmSms(result == PDU_FCS_OK, result);
};
RilObject.prototype[UNSOLICITED_RESPONSE_NEW_SMS_ON_SIM] = function UNSOLICITED_RESPONSE_NEW_SMS_ON_SIM(length) {
let recordNumber = this.context.Buf.readInt32List()[0];
this.context.SimRecordHelper.readSMS(
recordNumber,
function onsuccess(message) {
if (message && message.simStatus === 3) { //New Unread SMS
this._processSmsMultipart(message);
}
}.bind(this),
function onerror(errorMsg) {
if (DEBUG) {
this.context.debug("Failed to Read NEW SMS on SIM #" + recordNumber +
", errorMsg: " + errorMsg);
}
});
};
RilObject.prototype[UNSOLICITED_ON_USSD] = function UNSOLICITED_ON_USSD() {
let [typeCode, message] = this.context.Buf.readStringList();
if (DEBUG) {
this.context.debug("On USSD. Type Code: " + typeCode + " Message: " + message);
}
this.sendChromeMessage({rilMessageType: "ussdreceived",
message: message,
// Per ril.h the USSD session is assumed to persist if
// the type code is "1", otherwise the current session
// (if any) is assumed to have terminated.
sessionEnded: typeCode !== "1"});
};
RilObject.prototype[UNSOLICITED_ON_USSD_REQUEST] = null;
RilObject.prototype[UNSOLICITED_NITZ_TIME_RECEIVED] = function UNSOLICITED_NITZ_TIME_RECEIVED() {
let dateString = this.context.Buf.readString();
// The data contained in the NITZ message is
// in the form "yy/mm/dd,hh:mm:ss(+/-)tz,dt"
// for example: 12/02/16,03:36:08-20,00,310410
// See also bug 714352 - Listen for NITZ updates from rild.
if (DEBUG) this.context.debug("DateTimeZone string " + dateString);
let now = Date.now();
let year = parseInt(dateString.substr(0, 2), 10);
let month = parseInt(dateString.substr(3, 2), 10);
let day = parseInt(dateString.substr(6, 2), 10);
let hours = parseInt(dateString.substr(9, 2), 10);
let minutes = parseInt(dateString.substr(12, 2), 10);
let seconds = parseInt(dateString.substr(15, 2), 10);
// Note that |tz| is in 15-min units.
let tz = parseInt(dateString.substr(17, 3), 10);
// Note that |dst| is in 1-hour units and is already applied in |tz|.
let dst = parseInt(dateString.substr(21, 2), 10);
let timeInMS = Date.UTC(year + PDU_TIMESTAMP_YEAR_OFFSET, month - 1, day,
hours, minutes, seconds);
if (isNaN(timeInMS)) {
if (DEBUG) this.context.debug("NITZ failed to convert date");
return;
}
this.sendChromeMessage({rilMessageType: "nitzTime",
networkTimeInMS: timeInMS,
networkTimeZoneInMinutes: -(tz * 15),
networkDSTInMinutes: -(dst * 60),
receiveTimeInMS: now});
};
RilObject.prototype[UNSOLICITED_SIGNAL_STRENGTH] = function UNSOLICITED_SIGNAL_STRENGTH(length) {
this[REQUEST_SIGNAL_STRENGTH](length, {});
};
RilObject.prototype[UNSOLICITED_DATA_CALL_LIST_CHANGED] = function UNSOLICITED_DATA_CALL_LIST_CHANGED(length) {
this[REQUEST_DATA_CALL_LIST](length, {});
};
RilObject.prototype[UNSOLICITED_SUPP_SVC_NOTIFICATION] = function UNSOLICITED_SUPP_SVC_NOTIFICATION(length) {
let Buf = this.context.Buf;
let info = {};
info.notificationType = Buf.readInt32();
info.code = Buf.readInt32();
info.index = Buf.readInt32();
info.type = Buf.readInt32();
info.number = Buf.readString();
this._processSuppSvcNotification(info);
};
RilObject.prototype[UNSOLICITED_STK_SESSION_END] = function UNSOLICITED_STK_SESSION_END() {
this.sendChromeMessage({rilMessageType: "stksessionend"});
};
RilObject.prototype[UNSOLICITED_STK_PROACTIVE_COMMAND] = function UNSOLICITED_STK_PROACTIVE_COMMAND() {
this.processStkProactiveCommand();
};
RilObject.prototype[UNSOLICITED_STK_EVENT_NOTIFY] = function UNSOLICITED_STK_EVENT_NOTIFY() {
this.processStkProactiveCommand();
};
RilObject.prototype[UNSOLICITED_STK_CALL_SETUP] = null;
RilObject.prototype[UNSOLICITED_SIM_SMS_STORAGE_FULL] = null;
RilObject.prototype[UNSOLICITED_SIM_REFRESH] = null;
RilObject.prototype[UNSOLICITED_CALL_RING] = function UNSOLICITED_CALL_RING() {
let Buf = this.context.Buf;
let info = {rilMessageType: "callRing"};
let isCDMA = false; //XXX TODO hard-code this for now
if (isCDMA) {
info.isPresent = Buf.readInt32();
info.signalType = Buf.readInt32();
info.alertPitch = Buf.readInt32();
info.signal = Buf.readInt32();
}
// At this point we don't know much other than the fact there's an incoming
// call, but that's enough to bring up the Phone app already. We'll know
// details once we get a call state changed notification and can then
// dispatch DOM events etc.
this.sendChromeMessage(info);
};
RilObject.prototype[UNSOLICITED_RESPONSE_SIM_STATUS_CHANGED] = function UNSOLICITED_RESPONSE_SIM_STATUS_CHANGED() {
this.getICCStatus();
};
RilObject.prototype[UNSOLICITED_RESPONSE_CDMA_NEW_SMS] = function UNSOLICITED_RESPONSE_CDMA_NEW_SMS(length) {
let [message, result] = this.context.CdmaPDUHelper.processReceivedSms(length);
if (message) {
if (message.teleservice === PDU_CDMA_MSG_TELESERIVCIE_ID_WAP) {
result = this._processCdmaSmsWapPush(message);
} else if (message.subMsgType === PDU_CDMA_MSG_TYPE_DELIVER_ACK) {
result = this._processCdmaSmsStatusReport(message);
} else {
result = this._processSmsMultipart(message);
}
}
if (result == PDU_FCS_RESERVED || result == MOZ_FCS_WAIT_FOR_EXPLICIT_ACK) {
return;
}
// Not reserved FCS values, send ACK now.
this.acknowledgeCdmaSms(result == PDU_FCS_OK, result);
};
RilObject.prototype[UNSOLICITED_RESPONSE_NEW_BROADCAST_SMS] = function UNSOLICITED_RESPONSE_NEW_BROADCAST_SMS(length) {
let message;
try {
message =
this.context.GsmPDUHelper.readCbMessage(this.context.Buf.readInt32());
} catch (e) {
if (DEBUG) {
this.context.debug("Failed to parse Cell Broadcast message: " + e);
}
return;
}
message = this._processReceivedSmsCbPage(message);
if (!message) {
return;
}
message.rilMessageType = "cellbroadcast-received";
this.sendChromeMessage(message);
};
RilObject.prototype[UNSOLICITED_CDMA_RUIM_SMS_STORAGE_FULL] = null;
RilObject.prototype[UNSOLICITED_RESTRICTED_STATE_CHANGED] = null;
RilObject.prototype[UNSOLICITED_ENTER_EMERGENCY_CALLBACK_MODE] = function UNSOLICITED_ENTER_EMERGENCY_CALLBACK_MODE() {
this._handleChangedEmergencyCbMode(true);
};
RilObject.prototype[UNSOLICITED_CDMA_CALL_WAITING] = function UNSOLICITED_CDMA_CALL_WAITING(length) {
let Buf = this.context.Buf;
let call = {};
call.number = Buf.readString();
call.numberPresentation = Buf.readInt32();
call.name = Buf.readString();
call.namePresentation = Buf.readInt32();
call.isPresent = Buf.readInt32();
call.signalType = Buf.readInt32();
call.alertPitch = Buf.readInt32();
call.signal = Buf.readInt32();
this.sendChromeMessage({rilMessageType: "cdmaCallWaiting",
waitingCall: call});
};
RilObject.prototype[UNSOLICITED_CDMA_OTA_PROVISION_STATUS] = function UNSOLICITED_CDMA_OTA_PROVISION_STATUS() {
let status =
CDMA_OTA_PROVISION_STATUS_TO_GECKO[this.context.Buf.readInt32List()[0]];
if (!status) {
return;
}
this.sendChromeMessage({rilMessageType: "otastatuschange",
status: status});
};
RilObject.prototype[UNSOLICITED_CDMA_INFO_REC] = function UNSOLICITED_CDMA_INFO_REC(length) {
this.sendChromeMessage({
rilMessageType: "cdma-info-rec-received",
records: this.context.CdmaPDUHelper.decodeInformationRecord()
});
};
RilObject.prototype[UNSOLICITED_OEM_HOOK_RAW] = null;
RilObject.prototype[UNSOLICITED_RINGBACK_TONE] = null;
RilObject.prototype[UNSOLICITED_RESEND_INCALL_MUTE] = null;
RilObject.prototype[UNSOLICITED_CDMA_SUBSCRIPTION_SOURCE_CHANGED] = null;
RilObject.prototype[UNSOLICITED_CDMA_PRL_CHANGED] = function UNSOLICITED_CDMA_PRL_CHANGED(length) {
let version = this.context.Buf.readInt32List()[0];
if (version !== this.iccInfo.prlVersion) {
this.iccInfo.prlVersion = version;
this.context.ICCUtilsHelper.handleICCInfoChange();
}
};
RilObject.prototype[UNSOLICITED_EXIT_EMERGENCY_CALLBACK_MODE] = function UNSOLICITED_EXIT_EMERGENCY_CALLBACK_MODE() {
this._handleChangedEmergencyCbMode(false);
};
RilObject.prototype[UNSOLICITED_RIL_CONNECTED] = function UNSOLICITED_RIL_CONNECTED(length) {
// Prevent response id collision between UNSOLICITED_RIL_CONNECTED and
// UNSOLICITED_VOICE_RADIO_TECH_CHANGED for Akami on gingerbread branch.
if (!length) {
return;
}
this.version = this.context.Buf.readInt32List()[0];
if (DEBUG) {
this.context.debug("Detected RIL version " + this.version);
}
this.initRILState();
// rild might have restarted, ensure data call list.
this.getDataCallList();
// Always ensure that we are not in emergency callback mode when init.
this.exitEmergencyCbMode();
// Reset radio in the case that b2g restart (or crash).
this.setRadioEnabled({enabled: false});
};
RilObject.prototype[UNSOLICITED_VOICE_RADIO_TECH_CHANGED] = function UNSOLICITED_VOICE_RADIO_TECH_CHANGED(length) {
// This unsolicited response will be sent when the technology of a multi-tech
// modem is changed, ex. switch between gsm and cdma.
// TODO: We may need to do more on updating data when switching between gsm
// and cdma mode, e.g. IMEI, ESN, iccInfo, iccType ... etc.
// See Bug 866038.
this._processRadioTech(this.context.Buf.readInt32List()[0]);
};
RilObject.prototype[UNSOLICITED_CELL_INFO_LIST] = null;
RilObject.prototype[UNSOLICITED_RESPONSE_IMS_NETWORK_STATE_CHANGED] = null;
RilObject.prototype[UNSOLICITED_UICC_SUBSCRIPTION_STATUS_CHANGED] = null;
RilObject.prototype[UNSOLICITED_SRVCC_STATE_NOTIFY] = null;
RilObject.prototype[UNSOLICITED_HARDWARE_CONFIG_CHANGED] = null;
RilObject.prototype[UNSOLICITED_DC_RT_INFO_CHANGED] = null;
/**
* This object exposes the functionality to parse and serialize PDU strings
*
* A PDU is a string containing a series of hexadecimally encoded octets
* or nibble-swapped binary-coded decimals (BCDs). It contains not only the
* message text but information about the sender, the SMS service center,
* timestamp, etc.
*/
function GsmPDUHelperObject(aContext) {
this.context = aContext;
}
GsmPDUHelperObject.prototype = {
context: null,
/**
* Read one character (2 bytes) from a RIL string and decode as hex.
*
* @return the nibble as a number.
*/
readHexNibble: function() {
let nibble = this.context.Buf.readUint16();
if (nibble >= 48 && nibble <= 57) {
nibble -= 48; // ASCII '0'..'9'
} else if (nibble >= 65 && nibble <= 70) {
nibble -= 55; // ASCII 'A'..'F'
} else if (nibble >= 97 && nibble <= 102) {
nibble -= 87; // ASCII 'a'..'f'
} else {
throw "Found invalid nibble during PDU parsing: " +
String.fromCharCode(nibble);
}
return nibble;
},
/**
* Encode a nibble as one hex character in a RIL string (2 bytes).
*
* @param nibble
* The nibble to encode (represented as a number)
*/
writeHexNibble: function(nibble) {
nibble &= 0x0f;
if (nibble < 10) {
nibble += 48; // ASCII '0'
} else {
nibble += 55; // ASCII 'A'
}
this.context.Buf.writeUint16(nibble);
},
/**
* Read a hex-encoded octet (two nibbles).
*
* @return the octet as a number.
*/
readHexOctet: function() {
return (this.readHexNibble() << 4) | this.readHexNibble();
},
/**
* Write an octet as two hex-encoded nibbles.
*
* @param octet
* The octet (represented as a number) to encode.
*/
writeHexOctet: function(octet) {
this.writeHexNibble(octet >> 4);
this.writeHexNibble(octet);
},
/**
* Read an array of hex-encoded octets.
*/
readHexOctetArray: function(length) {
let array = new Uint8Array(length);
for (let i = 0; i < length; i++) {
array[i] = this.readHexOctet();
}
return array;
},
/**
* Helper to write data into a temporary buffer for easier length encoding when
* the number of octets for the length encoding is varied.
*
* @param writeFunction
* Function of how the data to be written into temporary buffer.
*
* @return array of written octets.
**/
writeWithBuffer: function(writeFunction) {
let buf = [];
let writeHexOctet = this.writeHexOctet;
this.writeHexOctet = function(octet) {
buf.push(octet);
}
try {
writeFunction();
} catch (e) {
if (DEBUG) {
debug("Error when writeWithBuffer: " + e);
}
buf = [];
} finally {
this.writeHexOctet = writeHexOctet;
}
return buf;
},
/**
* Convert an octet (number) to a BCD number.
*
* Any nibbles that are not in the BCD range count as 0.
*
* @param octet
* The octet (a number, as returned by getOctet())
*
* @return the corresponding BCD number.
*/
octetToBCD: function(octet) {
return ((octet & 0xf0) <= 0x90) * ((octet >> 4) & 0x0f) +
((octet & 0x0f) <= 0x09) * (octet & 0x0f) * 10;
},
/**
* Convert a BCD number to an octet (number)
*
* Only take two digits with absolute value.
*
* @param bcd
*
* @return the corresponding octet.
*/
BCDToOctet: function(bcd) {
bcd = Math.abs(bcd);
return ((bcd % 10) << 4) + (Math.floor(bcd / 10) % 10);
},
/**
* Convert a semi-octet (number) to a GSM BCD char, or return empty
* string if invalid semiOctet and suppressException is set to true.
*
* @param semiOctet
* Nibble to be converted to.
* @param suppressException [optional]
* Suppress exception if invalid semiOctet and suppressException is set
* to true.
*
* @return GSM BCD char, or empty string.
*/
bcdChars: "0123456789",
semiOctetToBcdChar: function(semiOctet, suppressException) {
if (semiOctet >= this.bcdChars.length) {
if (suppressException) {
return "";
} else {
throw new RangeError();
}
}
return this.bcdChars.charAt(semiOctet);
},
/**
* Convert a semi-octet (number) to a GSM extended BCD char, or return empty
* string if invalid semiOctet and suppressException is set to true.
*
* @param semiOctet
* Nibble to be converted to.
* @param suppressException [optional]
* Suppress exception if invalid semiOctet and suppressException is set
* to true.
*
* @return GSM extended BCD char, or empty string.
*/
extendedBcdChars: "0123456789*#,;",
semiOctetToExtendedBcdChar: function(semiOctet, suppressException) {
if (semiOctet >= this.extendedBcdChars.length) {
if (suppressException) {
return "";
} else {
throw new RangeError();
}
}
return this.extendedBcdChars.charAt(semiOctet);
},
/**
* Convert string to a GSM extended BCD string
*/
stringToExtendedBcd: function(string) {
return string.replace(/[^0-9*#,]/g, "")
.replace(/\*/g, "a")
.replace(/\#/g, "b")
.replace(/\,/g, "c");
},
/**
* Read a *swapped nibble* binary coded decimal (BCD)
*
* @param pairs
* Number of nibble *pairs* to read.
*
* @return the decimal as a number.
*/
readSwappedNibbleBcdNum: function(pairs) {
let number = 0;
for (let i = 0; i < pairs; i++) {
let octet = this.readHexOctet();
// Ignore 'ff' octets as they're often used as filler.
if (octet == 0xff) {
continue;
}
// If the first nibble is an "F" , only the second nibble is to be taken
// into account.
if ((octet & 0xf0) == 0xf0) {
number *= 10;
number += octet & 0x0f;
continue;
}
number *= 100;
number += this.octetToBCD(octet);
}
return number;
},
/**
* Read a *swapped nibble* binary coded decimal (BCD) string
*
* @param pairs
* Number of nibble *pairs* to read.
* @param suppressException [optional]
* Suppress exception if invalid semiOctet and suppressException is set
* to true.
*
* @return The BCD string.
*/
readSwappedNibbleBcdString: function(pairs, suppressException) {
let str = "";
for (let i = 0; i < pairs; i++) {
let nibbleH = this.readHexNibble();
let nibbleL = this.readHexNibble();
if (nibbleL == 0x0F) {
break;
}
str += this.semiOctetToBcdChar(nibbleL, suppressException);
if (nibbleH != 0x0F) {
str += this.semiOctetToBcdChar(nibbleH, suppressException);
}
}
return str;
},
/**
* Read a *swapped nibble* extended binary coded decimal (BCD) string
*
* @param pairs
* Number of nibble *pairs* to read.
* @param suppressException [optional]
* Suppress exception if invalid semiOctet and suppressException is set
* to true.
*
* @return The BCD string.
*/
readSwappedNibbleExtendedBcdString: function(pairs, suppressException) {
let str = "";
for (let i = 0; i < pairs; i++) {
let nibbleH = this.readHexNibble();
let nibbleL = this.readHexNibble();
if (nibbleL == 0x0F) {
break;
}
str += this.semiOctetToExtendedBcdChar(nibbleL, suppressException);
if (nibbleH != 0x0F) {
str += this.semiOctetToExtendedBcdChar(nibbleH, suppressException);
}
}
return str;
},
/**
* Write numerical data as swapped nibble BCD.
*
* @param data
* Data to write (as a string or a number)
*/
writeSwappedNibbleBCD: function(data) {
data = data.toString();
if (data.length % 2) {
data += "F";
}
let Buf = this.context.Buf;
for (let i = 0; i < data.length; i += 2) {
Buf.writeUint16(data.charCodeAt(i + 1));
Buf.writeUint16(data.charCodeAt(i));
}
},
/**
* Write numerical data as swapped nibble BCD.
* If the number of digit of data is even, add '0' at the beginning.
*
* @param data
* Data to write (as a string or a number)
*/
writeSwappedNibbleBCDNum: function(data) {
data = data.toString();
if (data.length % 2) {
data = "0" + data;
}
let Buf = this.context.Buf;
for (let i = 0; i < data.length; i += 2) {
Buf.writeUint16(data.charCodeAt(i + 1));
Buf.writeUint16(data.charCodeAt(i));
}
},
/**
* Read user data, convert to septets, look up relevant characters in a
* 7-bit alphabet, and construct string.
*
* @param length
* Number of septets to read (*not* octets)
* @param paddingBits
* Number of padding bits in the first byte of user data.
* @param langIndex
* Table index used for normal 7-bit encoded character lookup.
* @param langShiftIndex
* Table index used for escaped 7-bit encoded character lookup.
*
* @return a string.
*/
readSeptetsToString: function(length, paddingBits, langIndex, langShiftIndex) {
let ret = "";
let byteLength = Math.ceil((length * 7 + paddingBits) / 8);
/**
* |<- last byte in header ->|
* |<- incompleteBits ->|<- last header septet->|
* +===7===|===6===|===5===|===4===|===3===|===2===|===1===|===0===|
*
* |<- 1st byte in user data ->|
* |<- data septet 1 ->|<-paddingBits->|
* +===7===|===6===|===5===|===4===|===3===|===2===|===1===|===0===|
*
* |<- 2nd byte in user data ->|
* |<- data spetet 2 ->|<-ds1->|
* +===7===|===6===|===5===|===4===|===3===|===2===|===1===|===0===|
*/
let data = 0;
let dataBits = 0;
if (paddingBits) {
data = this.readHexOctet() >> paddingBits;
dataBits = 8 - paddingBits;
--byteLength;
}
let escapeFound = false;
const langTable = PDU_NL_LOCKING_SHIFT_TABLES[langIndex];
const langShiftTable = PDU_NL_SINGLE_SHIFT_TABLES[langShiftIndex];
do {
// Read as much as fits in 32bit word
let bytesToRead = Math.min(byteLength, dataBits ? 3 : 4);
for (let i = 0; i < bytesToRead; i++) {
data |= this.readHexOctet() << dataBits;
dataBits += 8;
--byteLength;
}
// Consume available full septets
for (; dataBits >= 7; dataBits -= 7) {
let septet = data & 0x7F;
data >>>= 7;
if (escapeFound) {
escapeFound = false;
if (septet == PDU_NL_EXTENDED_ESCAPE) {
// According to 3GPP TS 23.038, section 6.2.1.1, NOTE 1, "On
// receipt of this code, a receiving entity shall display a space
// until another extensiion table is defined."
ret += " ";
} else if (septet == PDU_NL_RESERVED_CONTROL) {
// According to 3GPP TS 23.038 B.2, "This code represents a control
// character and therefore must not be used for language specific
// characters."
ret += " ";
} else {
ret += langShiftTable[septet];
}
} else if (septet == PDU_NL_EXTENDED_ESCAPE) {
escapeFound = true;
// <escape> is not an effective character
--length;
} else {
ret += langTable[septet];
}
}
} while (byteLength);
if (ret.length != length) {
/**
* If num of effective characters does not equal to the length of read
* string, cut the tail off. This happens when the last octet of user
* data has following layout:
*
* |<- penultimate octet in user data ->|
* |<- data septet N ->|<- dsN-1 ->|
* +===7===|===6===|===5===|===4===|===3===|===2===|===1===|===0===|
*
* |<- last octet in user data ->|
* |<- fill bits ->|<-dsN->|
* +===7===|===6===|===5===|===4===|===3===|===2===|===1===|===0===|
*
* The fill bits in the last octet may happen to form a full septet and
* be appended at the end of result string.
*/
ret = ret.slice(0, length);
}
return ret;
},
writeStringAsSeptets: function(message, paddingBits, langIndex, langShiftIndex) {
const langTable = PDU_NL_LOCKING_SHIFT_TABLES[langIndex];
const langShiftTable = PDU_NL_SINGLE_SHIFT_TABLES[langShiftIndex];
let dataBits = paddingBits;
let data = 0;
for (let i = 0; i < message.length; i++) {
let c = message.charAt(i);
let septet = langTable.indexOf(c);
if (septet == PDU_NL_EXTENDED_ESCAPE) {
continue;
}
if (septet >= 0) {
data |= septet << dataBits;
dataBits += 7;
} else {
septet = langShiftTable.indexOf(c);
if (septet == -1) {
throw new Error("'" + c + "' is not in 7 bit alphabet "
+ langIndex + ":" + langShiftIndex + "!");
}
if (septet == PDU_NL_RESERVED_CONTROL) {
continue;
}
data |= PDU_NL_EXTENDED_ESCAPE << dataBits;
dataBits += 7;
data |= septet << dataBits;
dataBits += 7;
}
for (; dataBits >= 8; dataBits -= 8) {
this.writeHexOctet(data & 0xFF);
data >>>= 8;
}
}
if (dataBits !== 0) {
this.writeHexOctet(data & 0xFF);
}
},
writeStringAs8BitUnpacked: function(text) {
const langTable = PDU_NL_LOCKING_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
const langShiftTable = PDU_NL_SINGLE_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
let len = text ? text.length : 0;
for (let i = 0; i < len; i++) {
let c = text.charAt(i);
let octet = langTable.indexOf(c);
if (octet == -1) {
octet = langShiftTable.indexOf(c);
if (octet == -1) {
// Fallback to ASCII space.
octet = langTable.indexOf(' ');
} else {
this.writeHexOctet(PDU_NL_EXTENDED_ESCAPE);
}
}
this.writeHexOctet(octet);
}
},
/**
* Read user data and decode as a UCS2 string.
*
* @param numOctets
* Number of octets to be read as UCS2 string.
*
* @return a string.
*/
readUCS2String: function(numOctets) {
let str = "";
let length = numOctets / 2;
for (let i = 0; i < length; ++i) {
let code = (this.readHexOctet() << 8) | this.readHexOctet();
str += String.fromCharCode(code);
}
if (DEBUG) this.context.debug("Read UCS2 string: " + str);
return str;
},
/**
* Write user data as a UCS2 string.
*
* @param message
* Message string to encode as UCS2 in hex-encoded octets.
*/
writeUCS2String: function(message) {
for (let i = 0; i < message.length; ++i) {
let code = message.charCodeAt(i);
this.writeHexOctet((code >> 8) & 0xFF);
this.writeHexOctet(code & 0xFF);
}
},
/**
* Read 1 + UDHL octets and construct user data header.
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.040 9.2.3.24
*/
readUserDataHeader: function(msg) {
/**
* A header object with properties contained in received message.
* The properties set include:
*
* length: totoal length of the header, default 0.
* langIndex: used locking shift table index, default
* PDU_NL_IDENTIFIER_DEFAULT.
* langShiftIndex: used locking shift table index, default
* PDU_NL_IDENTIFIER_DEFAULT.
*
*/
let header = {
length: 0,
langIndex: PDU_NL_IDENTIFIER_DEFAULT,
langShiftIndex: PDU_NL_IDENTIFIER_DEFAULT
};
header.length = this.readHexOctet();
if (DEBUG) this.context.debug("Read UDH length: " + header.length);
let dataAvailable = header.length;
while (dataAvailable >= 2) {
let id = this.readHexOctet();
let length = this.readHexOctet();
if (DEBUG) this.context.debug("Read UDH id: " + id + ", length: " + length);
dataAvailable -= 2;
switch (id) {
case PDU_IEI_CONCATENATED_SHORT_MESSAGES_8BIT: {
let ref = this.readHexOctet();
let max = this.readHexOctet();
let seq = this.readHexOctet();
dataAvailable -= 3;
if (max && seq && (seq <= max)) {
header.segmentRef = ref;
header.segmentMaxSeq = max;
header.segmentSeq = seq;
}
break;
}
case PDU_IEI_APPLICATION_PORT_ADDRESSING_SCHEME_8BIT: {
let dstp = this.readHexOctet();
let orip = this.readHexOctet();
dataAvailable -= 2;
if ((dstp < PDU_APA_RESERVED_8BIT_PORTS)
|| (orip < PDU_APA_RESERVED_8BIT_PORTS)) {
// 3GPP TS 23.040 clause 9.2.3.24.3: "A receiving entity shall
// ignore any information element where the value of the
// Information-Element-Data is Reserved or not supported"
break;
}
header.destinationPort = dstp;
header.originatorPort = orip;
break;
}
case PDU_IEI_APPLICATION_PORT_ADDRESSING_SCHEME_16BIT: {
let dstp = (this.readHexOctet() << 8) | this.readHexOctet();
let orip = (this.readHexOctet() << 8) | this.readHexOctet();
dataAvailable -= 4;
if ((dstp >= PDU_APA_VALID_16BIT_PORTS) ||
(orip >= PDU_APA_VALID_16BIT_PORTS)) {
// 3GPP TS 23.040 clause 9.2.3.24.4: "A receiving entity shall
// ignore any information element where the value of the
// Information-Element-Data is Reserved or not supported"
// Bug 1130292, some carriers set originatorPort to reserved port
// numbers for wap push. We rise this as a warning in debug message
// instead of ingoring this IEI to allow user to receive Wap Push
// under these carriers.
this.context.debug("Warning: Invalid port numbers [dstp, orip]: " +
JSON.stringify([dstp, orip]));
}
header.destinationPort = dstp;
header.originatorPort = orip;
break;
}
case PDU_IEI_CONCATENATED_SHORT_MESSAGES_16BIT: {
let ref = (this.readHexOctet() << 8) | this.readHexOctet();
let max = this.readHexOctet();
let seq = this.readHexOctet();
dataAvailable -= 4;
if (max && seq && (seq <= max)) {
header.segmentRef = ref;
header.segmentMaxSeq = max;
header.segmentSeq = seq;
}
break;
}
case PDU_IEI_NATIONAL_LANGUAGE_SINGLE_SHIFT:
let langShiftIndex = this.readHexOctet();
--dataAvailable;
if (langShiftIndex < PDU_NL_SINGLE_SHIFT_TABLES.length) {
header.langShiftIndex = langShiftIndex;
}
break;
case PDU_IEI_NATIONAL_LANGUAGE_LOCKING_SHIFT:
let langIndex = this.readHexOctet();
--dataAvailable;
if (langIndex < PDU_NL_LOCKING_SHIFT_TABLES.length) {
header.langIndex = langIndex;
}
break;
case PDU_IEI_SPECIAL_SMS_MESSAGE_INDICATION:
let msgInd = this.readHexOctet() & 0xFF;
let msgCount = this.readHexOctet();
dataAvailable -= 2;
/*
* TS 23.040 V6.8.1 Sec 9.2.3.24.2
* bits 1 0 : basic message indication type
* bits 4 3 2 : extended message indication type
* bits 6 5 : Profile id
* bit 7 : storage type
*/
let storeType = msgInd & PDU_MWI_STORE_TYPE_BIT;
let mwi = msg.mwi;
if (!mwi) {
mwi = msg.mwi = {};
}
if (storeType == PDU_MWI_STORE_TYPE_STORE) {
// Store message because TP_UDH indicates so, note this may override
// the setting in DCS, but that is expected
mwi.discard = false;
} else if (mwi.discard === undefined) {
// storeType == PDU_MWI_STORE_TYPE_DISCARD
// only override mwi.discard here if it hasn't already been set
mwi.discard = true;
}
mwi.msgCount = msgCount & 0xFF;
mwi.active = mwi.msgCount > 0;
if (DEBUG) {
this.context.debug("MWI in TP_UDH received: " + JSON.stringify(mwi));
}
break;
default:
if (DEBUG) {
this.context.debug("readUserDataHeader: unsupported IEI(" + id +
"), " + length + " bytes.");
}
// Read out unsupported data
if (length) {
let octets;
if (DEBUG) octets = new Uint8Array(length);
for (let i = 0; i < length; i++) {
let octet = this.readHexOctet();
if (DEBUG) octets[i] = octet;
}
dataAvailable -= length;
if (DEBUG) {
this.context.debug("readUserDataHeader: " + Array.slice(octets));
}
}
break;
}
}
if (dataAvailable !== 0) {
throw new Error("Illegal user data header found!");
}
msg.header = header;
},
/**
* Write out user data header.
*
* @param options
* Options containing information for user data header write-out. The
* `userDataHeaderLength` property must be correctly pre-calculated.
*/
writeUserDataHeader: function(options) {
this.writeHexOctet(options.userDataHeaderLength);
if (options.segmentMaxSeq > 1) {
if (options.segmentRef16Bit) {
this.writeHexOctet(PDU_IEI_CONCATENATED_SHORT_MESSAGES_16BIT);
this.writeHexOctet(4);
this.writeHexOctet((options.segmentRef >> 8) & 0xFF);
} else {
this.writeHexOctet(PDU_IEI_CONCATENATED_SHORT_MESSAGES_8BIT);
this.writeHexOctet(3);
}
this.writeHexOctet(options.segmentRef & 0xFF);
this.writeHexOctet(options.segmentMaxSeq & 0xFF);
this.writeHexOctet(options.segmentSeq & 0xFF);
}
if (options.dcs == PDU_DCS_MSG_CODING_7BITS_ALPHABET) {
if (options.langIndex != PDU_NL_IDENTIFIER_DEFAULT) {
this.writeHexOctet(PDU_IEI_NATIONAL_LANGUAGE_LOCKING_SHIFT);
this.writeHexOctet(1);
this.writeHexOctet(options.langIndex);
}
if (options.langShiftIndex != PDU_NL_IDENTIFIER_DEFAULT) {
this.writeHexOctet(PDU_IEI_NATIONAL_LANGUAGE_SINGLE_SHIFT);
this.writeHexOctet(1);
this.writeHexOctet(options.langShiftIndex);
}
}
},
/**
* Read SM-TL Address.
*
* @param len
* Length of useful semi-octets within the Address-Value field. For
* example, the lenth of "12345" should be 5, and 4 for "1234".
*
* @see 3GPP TS 23.040 9.1.2.5
*/
readAddress: function(len) {
// Address Length
if (!len || (len < 0)) {
if (DEBUG) {
this.context.debug("PDU error: invalid sender address length: " + len);
}
return null;
}
if (len % 2 == 1) {
len += 1;
}
if (DEBUG) this.context.debug("PDU: Going to read address: " + len);
// Type-of-Address
let toa = this.readHexOctet();
let addr = "";
if ((toa & 0xF0) == PDU_TOA_ALPHANUMERIC) {
addr = this.readSeptetsToString(Math.floor(len * 4 / 7), 0,
PDU_NL_IDENTIFIER_DEFAULT , PDU_NL_IDENTIFIER_DEFAULT );
return addr;
}
addr = this.readSwappedNibbleExtendedBcdString(len / 2);
if (addr.length <= 0) {
if (DEBUG) this.context.debug("PDU error: no number provided");
return null;
}
if ((toa & 0xF0) == (PDU_TOA_INTERNATIONAL)) {
addr = '+' + addr;
}
return addr;
},
/**
* Read TP-Protocol-Indicator(TP-PID).
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.040 9.2.3.9
*/
readProtocolIndicator: function(msg) {
// `The MS shall interpret reserved, obsolete, or unsupported values as the
// value 00000000 but shall store them exactly as received.`
msg.pid = this.readHexOctet();
msg.epid = msg.pid;
switch (msg.epid & 0xC0) {
case 0x40:
// Bit 7..0 = 01xxxxxx
switch (msg.epid) {
case PDU_PID_SHORT_MESSAGE_TYPE_0:
case PDU_PID_ANSI_136_R_DATA:
case PDU_PID_USIM_DATA_DOWNLOAD:
return;
}
break;
}
msg.epid = PDU_PID_DEFAULT;
},
/**
* Read TP-Data-Coding-Scheme(TP-DCS)
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.040 9.2.3.10, 3GPP TS 23.038 4.
*/
readDataCodingScheme: function(msg) {
let dcs = this.readHexOctet();
if (DEBUG) this.context.debug("PDU: read SMS dcs: " + dcs);
// No message class by default.
let messageClass = PDU_DCS_MSG_CLASS_NORMAL;
// 7 bit is the default fallback encoding.
let encoding = PDU_DCS_MSG_CODING_7BITS_ALPHABET;
switch (dcs & PDU_DCS_CODING_GROUP_BITS) {
case 0x40: // bits 7..4 = 01xx
case 0x50:
case 0x60:
case 0x70:
// Bit 5..0 are coded exactly the same as Group 00xx
case 0x00: // bits 7..4 = 00xx
case 0x10:
case 0x20:
case 0x30:
if (dcs & 0x10) {
messageClass = dcs & PDU_DCS_MSG_CLASS_BITS;
}
switch (dcs & 0x0C) {
case 0x4:
encoding = PDU_DCS_MSG_CODING_8BITS_ALPHABET;
break;
case 0x8:
encoding = PDU_DCS_MSG_CODING_16BITS_ALPHABET;
break;
}
break;
case 0xE0: // bits 7..4 = 1110
encoding = PDU_DCS_MSG_CODING_16BITS_ALPHABET;
// Bit 3..0 are coded exactly the same as Message Waiting Indication
// Group 1101.
// Fall through.
case 0xC0: // bits 7..4 = 1100
case 0xD0: // bits 7..4 = 1101
// Indiciates voicemail indicator set or clear
let active = (dcs & PDU_DCS_MWI_ACTIVE_BITS) == PDU_DCS_MWI_ACTIVE_VALUE;
// If TP-UDH is present, these values will be overwritten
switch (dcs & PDU_DCS_MWI_TYPE_BITS) {
case PDU_DCS_MWI_TYPE_VOICEMAIL:
let mwi = msg.mwi;
if (!mwi) {
mwi = msg.mwi = {};
}
mwi.active = active;
mwi.discard = (dcs & PDU_DCS_CODING_GROUP_BITS) == 0xC0;
mwi.msgCount = active ? GECKO_VOICEMAIL_MESSAGE_COUNT_UNKNOWN : 0;
if (DEBUG) {
this.context.debug("MWI in DCS received for voicemail: " +
JSON.stringify(mwi));
}
break;
case PDU_DCS_MWI_TYPE_FAX:
if (DEBUG) this.context.debug("MWI in DCS received for fax");
break;
case PDU_DCS_MWI_TYPE_EMAIL:
if (DEBUG) this.context.debug("MWI in DCS received for email");
break;
default:
if (DEBUG) this.context.debug("MWI in DCS received for \"other\"");
break;
}
break;
case 0xF0: // bits 7..4 = 1111
if (dcs & 0x04) {
encoding = PDU_DCS_MSG_CODING_8BITS_ALPHABET;
}
messageClass = dcs & PDU_DCS_MSG_CLASS_BITS;
break;
default:
// Falling back to default encoding.
break;
}
msg.dcs = dcs;
msg.encoding = encoding;
msg.messageClass = GECKO_SMS_MESSAGE_CLASSES[messageClass];
if (DEBUG) this.context.debug("PDU: message encoding is " + encoding + " bit.");
},
/**
* Read GSM TP-Service-Centre-Time-Stamp(TP-SCTS).
*
* @see 3GPP TS 23.040 9.2.3.11
*/
readTimestamp: function() {
let year = this.readSwappedNibbleBcdNum(1) + PDU_TIMESTAMP_YEAR_OFFSET;
let month = this.readSwappedNibbleBcdNum(1) - 1;
let day = this.readSwappedNibbleBcdNum(1);
let hour = this.readSwappedNibbleBcdNum(1);
let minute = this.readSwappedNibbleBcdNum(1);
let second = this.readSwappedNibbleBcdNum(1);
let timestamp = Date.UTC(year, month, day, hour, minute, second);
// If the most significant bit of the least significant nibble is 1,
// the timezone offset is negative (fourth bit from the right => 0x08):
// localtime = UTC + tzOffset
// therefore
// UTC = localtime - tzOffset
let tzOctet = this.readHexOctet();
let tzOffset = this.octetToBCD(tzOctet & ~0x08) * 15 * 60 * 1000;
tzOffset = (tzOctet & 0x08) ? -tzOffset : tzOffset;
timestamp -= tzOffset;
return timestamp;
},
/**
* Write GSM TP-Service-Centre-Time-Stamp(TP-SCTS).
*
* @see 3GPP TS 23.040 9.2.3.11
*/
writeTimestamp: function(date) {
this.writeSwappedNibbleBCDNum(date.getFullYear() - PDU_TIMESTAMP_YEAR_OFFSET);
// The value returned by getMonth() is an integer between 0 and 11.
// 0 is corresponds to January, 1 to February, and so on.
this.writeSwappedNibbleBCDNum(date.getMonth() + 1);
this.writeSwappedNibbleBCDNum(date.getDate());
this.writeSwappedNibbleBCDNum(date.getHours());
this.writeSwappedNibbleBCDNum(date.getMinutes());
this.writeSwappedNibbleBCDNum(date.getSeconds());
// the value returned by getTimezoneOffset() is the difference,
// in minutes, between UTC and local time.
// For example, if your time zone is UTC+10 (Australian Eastern Standard Time),
// -600 will be returned.
// In TS 23.040 9.2.3.11, the Time Zone field of TP-SCTS indicates
// the different between the local time and GMT.
// And expressed in quarters of an hours. (so need to divid by 15)
let zone = date.getTimezoneOffset() / 15;
let octet = this.BCDToOctet(zone);
// the bit3 of the Time Zone field represents the algebraic sign.
// (0: positive, 1: negative).
// For example, if the time zone is -0800 GMT,
// 480 will be returned by getTimezoneOffset().
// In this case, need to mark sign bit as 1. => 0x08
if (zone > 0) {
octet = octet | 0x08;
}
this.writeHexOctet(octet);
},
/**
* User data can be 7 bit (default alphabet) data, 8 bit data, or 16 bit
* (UCS2) data.
*
* @param msg
* message object for output.
* @param length
* length of user data to read in octets.
*/
readUserData: function(msg, length) {
if (DEBUG) {
this.context.debug("Reading " + length + " bytes of user data.");
}
let paddingBits = 0;
if (msg.udhi) {
this.readUserDataHeader(msg);
if (msg.encoding == PDU_DCS_MSG_CODING_7BITS_ALPHABET) {
let headerBits = (msg.header.length + 1) * 8;
let headerSeptets = Math.ceil(headerBits / 7);
length -= headerSeptets;
paddingBits = headerSeptets * 7 - headerBits;
} else {
length -= (msg.header.length + 1);
}
}
if (DEBUG) {
this.context.debug("After header, " + length + " septets left of user data");
}
msg.body = null;
msg.data = null;
if (length <= 0) {
// No data to read.
return;
}
switch (msg.encoding) {
case PDU_DCS_MSG_CODING_7BITS_ALPHABET:
// 7 bit encoding allows 140 octets, which means 160 characters
// ((140x8) / 7 = 160 chars)
if (length > PDU_MAX_USER_DATA_7BIT) {
if (DEBUG) {
this.context.debug("PDU error: user data is too long: " + length);
}
break;
}
let langIndex = msg.udhi ? msg.header.langIndex : PDU_NL_IDENTIFIER_DEFAULT;
let langShiftIndex = msg.udhi ? msg.header.langShiftIndex : PDU_NL_IDENTIFIER_DEFAULT;
msg.body = this.readSeptetsToString(length, paddingBits, langIndex,
langShiftIndex);
break;
case PDU_DCS_MSG_CODING_8BITS_ALPHABET:
msg.data = this.readHexOctetArray(length);
break;
case PDU_DCS_MSG_CODING_16BITS_ALPHABET:
msg.body = this.readUCS2String(length);
break;
}
},
/**
* Read extra parameters if TP-PI is set.
*
* @param msg
* message object for output.
*/
readExtraParams: function(msg) {
// Because each PDU octet is converted to two UCS2 char2, we should always
// get even messageStringLength in this#_processReceivedSms(). So, we'll
// always need two delimitors at the end.
if (this.context.Buf.getReadAvailable() <= 4) {
return;
}
// TP-Parameter-Indicator
let pi;
do {
// `The most significant bit in octet 1 and any other TP-PI octets which
// may be added later is reserved as an extension bit which when set to a
// 1 shall indicate that another TP-PI octet follows immediately
// afterwards.` ~ 3GPP TS 23.040 9.2.3.27
pi = this.readHexOctet();
} while (pi & PDU_PI_EXTENSION);
// `If the TP-UDL bit is set to "1" but the TP-DCS bit is set to "0" then
// the receiving entity shall for TP-DCS assume a value of 0x00, i.e. the
// 7bit default alphabet.` ~ 3GPP 23.040 9.2.3.27
msg.dcs = 0;
msg.encoding = PDU_DCS_MSG_CODING_7BITS_ALPHABET;
// TP-Protocol-Identifier
if (pi & PDU_PI_PROTOCOL_IDENTIFIER) {
this.readProtocolIndicator(msg);
}
// TP-Data-Coding-Scheme
if (pi & PDU_PI_DATA_CODING_SCHEME) {
this.readDataCodingScheme(msg);
}
// TP-User-Data-Length
if (pi & PDU_PI_USER_DATA_LENGTH) {
let userDataLength = this.readHexOctet();
this.readUserData(msg, userDataLength);
}
},
/**
* Read and decode a PDU-encoded message from the stream.
*
* TODO: add some basic sanity checks like:
* - do we have the minimum number of chars available
*/
readMessage: function() {
// An empty message object. This gets filled below and then returned.
let msg = {
// D:DELIVER, DR:DELIVER-REPORT, S:SUBMIT, SR:SUBMIT-REPORT,
// ST:STATUS-REPORT, C:COMMAND
// M:Mandatory, O:Optional, X:Unavailable
// D DR S SR ST C
SMSC: null, // M M M M M M
mti: null, // M M M M M M
udhi: null, // M M O M M M
sender: null, // M X X X X X
recipient: null, // X X M X M M
pid: null, // M O M O O M
epid: null, // M O M O O M
dcs: null, // M O M O O X
mwi: null, // O O O O O O
replace: false, // O O O O O O
header: null, // M M O M M M
body: null, // M O M O O O
data: null, // M O M O O O
sentTimestamp: null, // M X X X X X
status: null, // X X X X M X
scts: null, // X X X M M X
dt: null, // X X X X M X
};
// SMSC info
let smscLength = this.readHexOctet();
if (smscLength > 0) {
let smscTypeOfAddress = this.readHexOctet();
// Subtract the type-of-address octet we just read from the length.
msg.SMSC = this.readSwappedNibbleExtendedBcdString(smscLength - 1);
if ((smscTypeOfAddress >> 4) == (PDU_TOA_INTERNATIONAL >> 4)) {
msg.SMSC = '+' + msg.SMSC;
}
}
// First octet of this SMS-DELIVER or SMS-SUBMIT message
let firstOctet = this.readHexOctet();
// Message Type Indicator
msg.mti = firstOctet & 0x03;
// User data header indicator
msg.udhi = firstOctet & PDU_UDHI;
switch (msg.mti) {
case PDU_MTI_SMS_RESERVED:
// `If an MS receives a TPDU with a "Reserved" value in the TP-MTI it
// shall process the message as if it were an "SMS-DELIVER" but store
// the message exactly as received.` ~ 3GPP TS 23.040 9.2.3.1
case PDU_MTI_SMS_DELIVER:
return this.readDeliverMessage(msg);
case PDU_MTI_SMS_STATUS_REPORT:
return this.readStatusReportMessage(msg);
default:
return null;
}
},
/**
* Helper for processing received SMS parcel data.
*
* @param length
* Length of SMS string in the incoming parcel.
*
* @return Message parsed or null for invalid message.
*/
processReceivedSms: function(length) {
if (!length) {
if (DEBUG) this.context.debug("Received empty SMS!");
return [null, PDU_FCS_UNSPECIFIED];
}
let Buf = this.context.Buf;
// An SMS is a string, but we won't read it as such, so let's read the
// string length and then defer to PDU parsing helper.
let messageStringLength = Buf.readInt32();
if (DEBUG) this.context.debug("Got new SMS, length " + messageStringLength);
let message = this.readMessage();
if (DEBUG) this.context.debug("Got new SMS: " + JSON.stringify(message));
// Read string delimiters. See Buf.readString().
Buf.readStringDelimiter(length);
// Determine result
if (!message) {
return [null, PDU_FCS_UNSPECIFIED];
}
if (message.epid == PDU_PID_SHORT_MESSAGE_TYPE_0) {
// `A short message type 0 indicates that the ME must acknowledge receipt
// of the short message but shall discard its contents.` ~ 3GPP TS 23.040
// 9.2.3.9
return [null, PDU_FCS_OK];
}
if (message.messageClass == GECKO_SMS_MESSAGE_CLASSES[PDU_DCS_MSG_CLASS_2]) {
let RIL = this.context.RIL;
switch (message.epid) {
case PDU_PID_ANSI_136_R_DATA:
case PDU_PID_USIM_DATA_DOWNLOAD:
let ICCUtilsHelper = this.context.ICCUtilsHelper;
if (ICCUtilsHelper.isICCServiceAvailable("DATA_DOWNLOAD_SMS_PP")) {
// `If the service "data download via SMS Point-to-Point" is
// allocated and activated in the (U)SIM Service Table, ... then the
// ME shall pass the message transparently to the UICC using the
// ENVELOPE (SMS-PP DOWNLOAD).` ~ 3GPP TS 31.111 7.1.1.1
RIL.dataDownloadViaSMSPP(message);
// `the ME shall not display the message, or alert the user of a
// short message waiting.` ~ 3GPP TS 31.111 7.1.1.1
return [null, PDU_FCS_RESERVED];
}
// If the service "data download via SMS-PP" is not available in the
// (U)SIM Service Table, ..., then the ME shall store the message in
// EFsms in accordance with TS 31.102` ~ 3GPP TS 31.111 7.1.1.1
// Fall through.
default:
RIL.writeSmsToSIM(message);
break;
}
}
// TODO: Bug 739143: B2G SMS: Support SMS Storage Full event
if ((message.messageClass != GECKO_SMS_MESSAGE_CLASSES[PDU_DCS_MSG_CLASS_0]) && !true) {
// `When a mobile terminated message is class 0..., the MS shall display
// the message immediately and send a ACK to the SC ..., irrespective of
// whether there is memory available in the (U)SIM or ME.` ~ 3GPP 23.038
// clause 4.
if (message.messageClass == GECKO_SMS_MESSAGE_CLASSES[PDU_DCS_MSG_CLASS_2]) {
// `If all the short message storage at the MS is already in use, the
// MS shall return "memory capacity exceeded".` ~ 3GPP 23.038 clause 4.
return [null, PDU_FCS_MEMORY_CAPACITY_EXCEEDED];
}
return [null, PDU_FCS_UNSPECIFIED];
}
return [message, PDU_FCS_OK];
},
/**
* Read and decode a SMS-DELIVER PDU.
*
* @param msg
* message object for output.
*/
readDeliverMessage: function(msg) {
// - Sender Address info -
let senderAddressLength = this.readHexOctet();
msg.sender = this.readAddress(senderAddressLength);
// - TP-Protocolo-Identifier -
this.readProtocolIndicator(msg);
// - TP-Data-Coding-Scheme -
this.readDataCodingScheme(msg);
// - TP-Service-Center-Time-Stamp -
msg.sentTimestamp = this.readTimestamp();
// - TP-User-Data-Length -
let userDataLength = this.readHexOctet();
// - TP-User-Data -
if (userDataLength > 0) {
this.readUserData(msg, userDataLength);
}
return msg;
},
/**
* Read and decode a SMS-STATUS-REPORT PDU.
*
* @param msg
* message object for output.
*/
readStatusReportMessage: function(msg) {
// TP-Message-Reference
msg.messageRef = this.readHexOctet();
// TP-Recipient-Address
let recipientAddressLength = this.readHexOctet();
msg.recipient = this.readAddress(recipientAddressLength);
// TP-Service-Centre-Time-Stamp
msg.scts = this.readTimestamp();
// TP-Discharge-Time
msg.dt = this.readTimestamp();
// TP-Status
msg.status = this.readHexOctet();
this.readExtraParams(msg);
return msg;
},
/**
* Serialize a SMS-SUBMIT PDU message and write it to the output stream.
*
* This method expects that a data coding scheme has been chosen already
* and that the length of the user data payload in that encoding is known,
* too. Both go hand in hand together anyway.
*
* @param address
* String containing the address (number) of the SMS receiver
* @param userData
* String containing the message to be sent as user data
* @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 encodedBodyLength
* Length of the user data 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 requestStatusReport
* Request status report.
*/
writeMessage: function(options) {
if (DEBUG) {
this.context.debug("writeMessage: " + JSON.stringify(options));
}
let Buf = this.context.Buf;
let address = options.number;
let body = options.body;
let dcs = options.dcs;
let userDataHeaderLength = options.userDataHeaderLength;
let encodedBodyLength = options.encodedBodyLength;
let langIndex = options.langIndex;
let langShiftIndex = options.langShiftIndex;
// SMS-SUBMIT Format:
//
// PDU Type - 1 octet
// Message Reference - 1 octet
// DA - Destination Address - 2 to 12 octets
// PID - Protocol Identifier - 1 octet
// DCS - Data Coding Scheme - 1 octet
// VP - Validity Period - 0, 1 or 7 octets
// UDL - User Data Length - 1 octet
// UD - User Data - 140 octets
let addressFormat = PDU_TOA_ISDN; // 81
if (address[0] == '+') {
addressFormat = PDU_TOA_INTERNATIONAL | PDU_TOA_ISDN; // 91
address = address.substring(1);
}
//TODO validity is unsupported for now
let validity = 0;
let headerOctets = (userDataHeaderLength ? userDataHeaderLength + 1 : 0);
let paddingBits;
let userDataLengthInSeptets;
let userDataLengthInOctets;
if (dcs == PDU_DCS_MSG_CODING_7BITS_ALPHABET) {
let headerSeptets = Math.ceil(headerOctets * 8 / 7);
userDataLengthInSeptets = headerSeptets + encodedBodyLength;
userDataLengthInOctets = Math.ceil(userDataLengthInSeptets * 7 / 8);
paddingBits = headerSeptets * 7 - headerOctets * 8;
} else {
userDataLengthInOctets = headerOctets + encodedBodyLength;
paddingBits = 0;
}
let pduOctetLength = 4 + // PDU Type, Message Ref, address length + format
Math.ceil(address.length / 2) +
3 + // PID, DCS, UDL
userDataLengthInOctets;
if (validity) {
//TODO: add more to pduOctetLength
}
// Start the string. Since octets are represented in hex, we will need
// twice as many characters as octets.
Buf.writeInt32(pduOctetLength * 2);
// - PDU-TYPE-
// +--------+----------+---------+---------+--------+---------+
// | RP (1) | UDHI (1) | SRR (1) | VPF (2) | RD (1) | MTI (2) |
// +--------+----------+---------+---------+--------+---------+
// RP: 0 Reply path parameter is not set
// 1 Reply path parameter is set
// UDHI: 0 The UD Field contains only the short message
// 1 The beginning of the UD field contains a header in addition
// of the short message
// SRR: 0 A status report is not requested
// 1 A status report is requested
// VPF: bit4 bit3
// 0 0 VP field is not present
// 0 1 Reserved
// 1 0 VP field present an integer represented (relative)
// 1 1 VP field present a semi-octet represented (absolute)
// RD: Instruct the SMSC to accept(0) or reject(1) an SMS-SUBMIT
// for a short message still held in the SMSC which has the same
// MR and DA as a previously submitted short message from the
// same OA
// MTI: bit1 bit0 Message Type
// 0 0 SMS-DELIVER (SMSC ==> MS)
// 0 1 SMS-SUBMIT (MS ==> SMSC)
// PDU type. MTI is set to SMS-SUBMIT
let firstOctet = PDU_MTI_SMS_SUBMIT;
// Status-Report-Request
if (options.requestStatusReport) {
firstOctet |= PDU_SRI_SRR;
}
// Validity period
if (validity) {
//TODO: not supported yet, OR with one of PDU_VPF_*
}
// User data header indicator
if (headerOctets) {
firstOctet |= PDU_UDHI;
}
this.writeHexOctet(firstOctet);
// Message reference 00
this.writeHexOctet(0x00);
// - Destination Address -
this.writeHexOctet(address.length);
this.writeHexOctet(addressFormat);
this.writeSwappedNibbleBCD(address);
// - Protocol Identifier -
this.writeHexOctet(0x00);
// - Data coding scheme -
// For now it assumes bits 7..4 = 1111 except for the 16 bits use case
this.writeHexOctet(dcs);
// - Validity Period -
if (validity) {
this.writeHexOctet(validity);
}
// - User Data -
if (dcs == PDU_DCS_MSG_CODING_7BITS_ALPHABET) {
this.writeHexOctet(userDataLengthInSeptets);
} else {
this.writeHexOctet(userDataLengthInOctets);
}
if (headerOctets) {
this.writeUserDataHeader(options);
}
switch (dcs) {
case PDU_DCS_MSG_CODING_7BITS_ALPHABET:
this.writeStringAsSeptets(body, paddingBits, langIndex, langShiftIndex);
break;
case PDU_DCS_MSG_CODING_8BITS_ALPHABET:
// Unsupported.
break;
case PDU_DCS_MSG_CODING_16BITS_ALPHABET:
this.writeUCS2String(body);
break;
}
// End of the string. The string length is always even by definition, so
// we write two \0 delimiters.
Buf.writeUint16(0);
Buf.writeUint16(0);
},
/**
* Read GSM CBS message serial number.
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.041 section 9.4.1.2.1
*/
readCbSerialNumber: function(msg) {
let Buf = this.context.Buf;
msg.serial = Buf.readUint8() << 8 | Buf.readUint8();
msg.geographicalScope = (msg.serial >>> 14) & 0x03;
msg.messageCode = (msg.serial >>> 4) & 0x03FF;
msg.updateNumber = msg.serial & 0x0F;
},
/**
* Read GSM CBS message message identifier.
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.041 section 9.4.1.2.2
*/
readCbMessageIdentifier: function(msg) {
let Buf = this.context.Buf;
msg.messageId = Buf.readUint8() << 8 | Buf.readUint8();
},
/**
* Read ETWS information from message identifier and serial Number
* @param msg
* message object for output.
*
* @see 3GPP TS 23.041 section 9.4.1.2.1 & 9.4.1.2.2
*/
readCbEtwsInfo: function(msg) {
if ((msg.format != CB_FORMAT_ETWS)
&& (msg.messageId >= CB_GSM_MESSAGEID_ETWS_BEGIN)
&& (msg.messageId <= CB_GSM_MESSAGEID_ETWS_END)) {
// `In the case of transmitting CBS message for ETWS, a part of
// Message Code can be used to command mobile terminals to activate
// emergency user alert and message popup in order to alert the users.`
msg.etws = {
emergencyUserAlert: msg.messageCode & 0x0200 ? true : false,
popup: msg.messageCode & 0x0100 ? true : false
};
let warningType = msg.messageId - CB_GSM_MESSAGEID_ETWS_BEGIN;
if (warningType < CB_ETWS_WARNING_TYPE_NAMES.length) {
msg.etws.warningType = warningType;
}
}
},
/**
* Read CBS Data Coding Scheme.
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.038 section 5.
*/
readCbDataCodingScheme: function(msg) {
let dcs = this.context.Buf.readUint8();
if (DEBUG) this.context.debug("PDU: read CBS dcs: " + dcs);
let language = null, hasLanguageIndicator = false;
// `Any reserved codings shall be assumed to be the GSM 7bit default
// alphabet.`
let encoding = PDU_DCS_MSG_CODING_7BITS_ALPHABET;
let messageClass = PDU_DCS_MSG_CLASS_NORMAL;
switch (dcs & PDU_DCS_CODING_GROUP_BITS) {
case 0x00: // 0000
language = CB_DCS_LANG_GROUP_1[dcs & 0x0F];
break;
case 0x10: // 0001
switch (dcs & 0x0F) {
case 0x00:
hasLanguageIndicator = true;
break;
case 0x01:
encoding = PDU_DCS_MSG_CODING_16BITS_ALPHABET;
hasLanguageIndicator = true;
break;
}
break;
case 0x20: // 0010
language = CB_DCS_LANG_GROUP_2[dcs & 0x0F];
break;
case 0x40: // 01xx
case 0x50:
//case 0x60: Text Compression, not supported
//case 0x70: Text Compression, not supported
case 0x90: // 1001
encoding = (dcs & 0x0C);
if (encoding == 0x0C) {
encoding = PDU_DCS_MSG_CODING_7BITS_ALPHABET;
}
messageClass = (dcs & PDU_DCS_MSG_CLASS_BITS);
break;
case 0xF0:
encoding = (dcs & 0x04) ? PDU_DCS_MSG_CODING_8BITS_ALPHABET
: PDU_DCS_MSG_CODING_7BITS_ALPHABET;
switch(dcs & PDU_DCS_MSG_CLASS_BITS) {
case 0x01: messageClass = PDU_DCS_MSG_CLASS_USER_1; break;
case 0x02: messageClass = PDU_DCS_MSG_CLASS_USER_2; break;
case 0x03: messageClass = PDU_DCS_MSG_CLASS_3; break;
}
break;
case 0x30: // 0011 (Reserved)
case 0x80: // 1000 (Reserved)
case 0xA0: // 1010..1100 (Reserved)
case 0xB0:
case 0xC0:
break;
default:
throw new Error("Unsupported CBS data coding scheme: " + dcs);
}
msg.dcs = dcs;
msg.encoding = encoding;
msg.language = language;
msg.messageClass = GECKO_SMS_MESSAGE_CLASSES[messageClass];
msg.hasLanguageIndicator = hasLanguageIndicator;
},
/**
* Read GSM CBS message page parameter.
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.041 section 9.4.1.2.4
*/
readCbPageParameter: function(msg) {
let octet = this.context.Buf.readUint8();
msg.pageIndex = (octet >>> 4) & 0x0F;
msg.numPages = octet & 0x0F;
if (!msg.pageIndex || !msg.numPages) {
// `If a mobile receives the code 0000 in either the first field or the
// second field then it shall treat the CBS message exactly the same as a
// CBS message with page parameter 0001 0001 (i.e. a single page message).`
msg.pageIndex = msg.numPages = 1;
}
},
/**
* Read ETWS Primary Notification message warning type.
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.041 section 9.3.24
*/
readCbWarningType: function(msg) {
let Buf = this.context.Buf;
let word = Buf.readUint8() << 8 | Buf.readUint8();
msg.etws = {
warningType: (word >>> 9) & 0x7F,
popup: word & 0x80 ? true : false,
emergencyUserAlert: word & 0x100 ? true : false
};
},
/**
* Read GSM CB Data
*
* This parameter is a copy of the 'CBS-Message-Information-Page' as sent
* from the CBC to the BSC.
*
* @see 3GPP TS 23.041 section 9.4.1.2.5
*/
readGsmCbData: function(msg, length) {
let Buf = this.context.Buf;
let bufAdapter = {
context: this.context,
readHexOctet: function() {
return Buf.readUint8();
}
};
msg.body = null;
msg.data = null;
switch (msg.encoding) {
case PDU_DCS_MSG_CODING_7BITS_ALPHABET:
msg.body = this.readSeptetsToString.call(bufAdapter,
Math.floor(length * 8 / 7), 0,
PDU_NL_IDENTIFIER_DEFAULT,
PDU_NL_IDENTIFIER_DEFAULT);
if (msg.hasLanguageIndicator) {
msg.language = msg.body.substring(0, 2);
msg.body = msg.body.substring(3);
}
break;
case PDU_DCS_MSG_CODING_8BITS_ALPHABET:
msg.data = Buf.readUint8Array(length);
break;
case PDU_DCS_MSG_CODING_16BITS_ALPHABET:
if (msg.hasLanguageIndicator) {
msg.language = this.readSeptetsToString.call(bufAdapter, 2, 0,
PDU_NL_IDENTIFIER_DEFAULT,
PDU_NL_IDENTIFIER_DEFAULT);
length -= 2;
}
msg.body = this.readUCS2String.call(bufAdapter, length);
break;
}
if (msg.data || !msg.body) {
return;
}
// According to 9.3.19 CBS-Message-Information-Page in TS 23.041:
// "
// This parameter is of a fixed length of 82 octets and carries up to and
// including 82 octets of user information. Where the user information is
// less than 82 octets, the remaining octets must be filled with padding.
// "
// According to 6.2.1.1 GSM 7 bit Default Alphabet and 6.2.3 UCS2 in
// TS 23.038, the padding character is <CR>.
for (let i = msg.body.length - 1; i >= 0; i--) {
if (msg.body.charAt(i) !== '\r') {
msg.body = msg.body.substring(0, i + 1);
break;
}
}
},
/**
* Read UMTS CB Data
*
* Octet Number(s) Parameter
* 1 Number-of-Pages
* 2 - 83 CBS-Message-Information-Page 1
* 84 CBS-Message-Information-Length 1
* ...
* CBS-Message-Information-Page n
* CBS-Message-Information-Length n
*
* @see 3GPP TS 23.041 section 9.4.2.2.5
*/
readUmtsCbData: function(msg) {
let Buf = this.context.Buf;
let numOfPages = Buf.readUint8();
if (numOfPages < 0 || numOfPages > 15) {
throw new Error("Invalid numOfPages: " + numOfPages);
}
let bufAdapter = {
context: this.context,
readHexOctet: function() {
return Buf.readUint8();
}
};
let removePaddingCharactors = function (text) {
for (let i = text.length - 1; i >= 0; i--) {
if (text.charAt(i) !== '\r') {
return text.substring(0, i + 1);
}
}
return text;
};
let totalLength = 0, length, pageLengths = [];
for (let i = 0; i < numOfPages; i++) {
Buf.seekIncoming(CB_MSG_PAGE_INFO_SIZE);
length = Buf.readUint8();
totalLength += length;
pageLengths.push(length);
}
// Seek back to beginning of CB Data.
Buf.seekIncoming(-numOfPages * (CB_MSG_PAGE_INFO_SIZE + 1));
switch (msg.encoding) {
case PDU_DCS_MSG_CODING_7BITS_ALPHABET: {
let body;
msg.body = "";
for (let i = 0; i < numOfPages; i++) {
body = this.readSeptetsToString.call(bufAdapter,
Math.floor(pageLengths[i] * 8 / 7),
0,
PDU_NL_IDENTIFIER_DEFAULT,
PDU_NL_IDENTIFIER_DEFAULT);
if (msg.hasLanguageIndicator) {
if (!msg.language) {
msg.language = body.substring(0, 2);
}
body = body.substring(3);
}
msg.body += removePaddingCharactors(body);
// Skip padding octets
Buf.seekIncoming(CB_MSG_PAGE_INFO_SIZE - pageLengths[i]);
// Read the octet of CBS-Message-Information-Length
Buf.readUint8();
}
break;
}
case PDU_DCS_MSG_CODING_8BITS_ALPHABET: {
msg.data = new Uint8Array(totalLength);
for (let i = 0, j = 0; i < numOfPages; i++) {
for (let pageLength = pageLengths[i]; pageLength > 0; pageLength--) {
msg.data[j++] = Buf.readUint8();
}
// Skip padding octets
Buf.seekIncoming(CB_MSG_PAGE_INFO_SIZE - pageLengths[i]);
// Read the octet of CBS-Message-Information-Length
Buf.readUint8();
}
break;
}
case PDU_DCS_MSG_CODING_16BITS_ALPHABET: {
msg.body = "";
for (let i = 0; i < numOfPages; i++) {
let pageLength = pageLengths[i];
if (msg.hasLanguageIndicator) {
if (!msg.language) {
msg.language = this.readSeptetsToString.call(bufAdapter,
2,
0,
PDU_NL_IDENTIFIER_DEFAULT,
PDU_NL_IDENTIFIER_DEFAULT);
} else {
Buf.readUint16();
}
pageLength -= 2;
}
msg.body += removePaddingCharactors(
this.readUCS2String.call(bufAdapter, pageLength));
// Skip padding octets
Buf.seekIncoming(CB_MSG_PAGE_INFO_SIZE - pageLengths[i]);
// Read the octet of CBS-Message-Information-Length
Buf.readUint8();
}
break;
}
}
},
/**
* Read Cell GSM/ETWS/UMTS Broadcast Message.
*
* @param pduLength
* total length of the incoming PDU in octets.
*/
readCbMessage: function(pduLength) {
// Validity GSM ETWS UMTS
let msg = {
// Internally used in ril_worker:
serial: null, // O O O
updateNumber: null, // O O O
format: null, // O O O
dcs: 0x0F, // O X O
encoding: PDU_DCS_MSG_CODING_7BITS_ALPHABET, // O X O
hasLanguageIndicator: false, // O X O
data: null, // O X O
body: null, // O X O
pageIndex: 1, // O X X
numPages: 1, // O X X
// DOM attributes:
geographicalScope: null, // O O O
messageCode: null, // O O O
messageId: null, // O O O
language: null, // O X O
fullBody: null, // O X O
fullData: null, // O X O
messageClass: GECKO_SMS_MESSAGE_CLASSES[PDU_DCS_MSG_CLASS_NORMAL], // O x O
etws: null // ? O ?
/*{
warningType: null, // X O X
popup: false, // X O X
emergencyUserAlert: false, // X O X
}*/
};
if (pduLength <= CB_MESSAGE_SIZE_ETWS) {
msg.format = CB_FORMAT_ETWS;
return this.readEtwsCbMessage(msg);
}
if (pduLength <= CB_MESSAGE_SIZE_GSM) {
msg.format = CB_FORMAT_GSM;
return this.readGsmCbMessage(msg, pduLength);
}
if (pduLength >= CB_MESSAGE_SIZE_UMTS_MIN &&
pduLength <= CB_MESSAGE_SIZE_UMTS_MAX) {
msg.format = CB_FORMAT_UMTS;
return this.readUmtsCbMessage(msg);
}
throw new Error("Invalid PDU Length: " + pduLength);
},
/**
* Read UMTS CBS Message.
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.041 section 9.4.2
* @see 3GPP TS 25.324 section 10.2
*/
readUmtsCbMessage: function(msg) {
let Buf = this.context.Buf;
let type = Buf.readUint8();
if (type != CB_UMTS_MESSAGE_TYPE_CBS) {
throw new Error("Unsupported UMTS Cell Broadcast message type: " + type);
}
this.readCbMessageIdentifier(msg);
this.readCbSerialNumber(msg);
this.readCbEtwsInfo(msg);
this.readCbDataCodingScheme(msg);
this.readUmtsCbData(msg);
return msg;
},
/**
* Read GSM Cell Broadcast Message.
*
* @param msg
* message object for output.
* @param pduLength
* total length of the incomint PDU in octets.
*
* @see 3GPP TS 23.041 clause 9.4.1.2
*/
readGsmCbMessage: function(msg, pduLength) {
this.readCbSerialNumber(msg);
this.readCbMessageIdentifier(msg);
this.readCbEtwsInfo(msg);
this.readCbDataCodingScheme(msg);
this.readCbPageParameter(msg);
// GSM CB message header takes 6 octets.
this.readGsmCbData(msg, pduLength - 6);
return msg;
},
/**
* Read ETWS Primary Notification Message.
*
* @param msg
* message object for output.
*
* @see 3GPP TS 23.041 clause 9.4.1.3
*/
readEtwsCbMessage: function(msg) {
this.readCbSerialNumber(msg);
this.readCbMessageIdentifier(msg);
this.readCbWarningType(msg);
// Octet 7..56 is Warning Security Information. However, according to
// section 9.4.1.3.6, `The UE shall ignore this parameter.` So we just skip
// processing it here.
return msg;
},
/**
* Read network name.
*
* @param len Length of the information element.
* @return
* {
* networkName: network name.
* shouldIncludeCi: Should Country's initials included in text string.
* }
* @see TS 24.008 clause 10.5.3.5a.
*/
readNetworkName: function(len) {
// According to TS 24.008 Sec. 10.5.3.5a, the first octet is:
// bit 8: must be 1.
// bit 5-7: Text encoding.
// 000 - GSM default alphabet.
// 001 - UCS2 (16 bit).
// else - reserved.
// bit 4: MS should add the letters for Country's Initials and a space
// to the text string if this bit is true.
// bit 1-3: number of spare bits in last octet.
let codingInfo = this.readHexOctet();
if (!(codingInfo & 0x80)) {
return null;
}
let textEncoding = (codingInfo & 0x70) >> 4;
let shouldIncludeCountryInitials = !!(codingInfo & 0x08);
let spareBits = codingInfo & 0x07;
let resultString;
switch (textEncoding) {
case 0:
// GSM Default alphabet.
resultString = this.readSeptetsToString(
Math.floor(((len - 1) * 8 - spareBits) / 7), 0,
PDU_NL_IDENTIFIER_DEFAULT,
PDU_NL_IDENTIFIER_DEFAULT);
break;
case 1:
// UCS2 encoded.
resultString = this.context.ICCPDUHelper.readAlphaIdentifier(len - 1);
break;
default:
// Not an available text coding.
return null;
}
// TODO - Bug 820286: According to shouldIncludeCountryInitials, add
// country initials to the resulting string.
return resultString;
}
};
/**
* Provide buffer with bitwise read/write function so make encoding/decoding easier.
*/
function BitBufferHelperObject(/* unused */aContext) {
this.readBuffer = [];
this.writeBuffer = [];
}
BitBufferHelperObject.prototype = {
readCache: 0,
readCacheSize: 0,
readBuffer: null,
readIndex: 0,
writeCache: 0,
writeCacheSize: 0,
writeBuffer: null,
// Max length is 32 because we use integer as read/write cache.
// All read/write functions are implemented based on bitwise operation.
readBits: function(length) {
if (length <= 0 || length > 32) {
return null;
}
if (length > this.readCacheSize) {
let bytesToRead = Math.ceil((length - this.readCacheSize) / 8);
for(let i = 0; i < bytesToRead; i++) {
this.readCache = (this.readCache << 8) | (this.readBuffer[this.readIndex++] & 0xFF);
this.readCacheSize += 8;
}
}
let bitOffset = (this.readCacheSize - length),
resultMask = (1 << length) - 1,
result = 0;
result = (this.readCache >> bitOffset) & resultMask;
this.readCacheSize -= length;
return result;
},
backwardReadPilot: function(length) {
if (length <= 0) {
return;
}
// Zero-based position.
let bitIndexToRead = this.readIndex * 8 - this.readCacheSize - length;
if (bitIndexToRead < 0) {
return;
}
// Update readIndex, readCache, readCacheSize accordingly.
let readBits = bitIndexToRead % 8;
this.readIndex = Math.floor(bitIndexToRead / 8) + ((readBits) ? 1 : 0);
this.readCache = (readBits) ? this.readBuffer[this.readIndex - 1] : 0;
this.readCacheSize = (readBits) ? (8 - readBits) : 0;
},
writeBits: function(value, length) {
if (length <= 0 || length > 32) {
return;
}
let totalLength = length + this.writeCacheSize;
// 8-byte cache not full
if (totalLength < 8) {
let valueMask = (1 << length) - 1;
this.writeCache = (this.writeCache << length) | (value & valueMask);
this.writeCacheSize += length;
return;
}
// Deal with unaligned part
if (this.writeCacheSize) {
let mergeLength = 8 - this.writeCacheSize,
valueMask = (1 << mergeLength) - 1;
this.writeCache = (this.writeCache << mergeLength) | ((value >> (length - mergeLength)) & valueMask);
this.writeBuffer.push(this.writeCache & 0xFF);
length -= mergeLength;
}
// Aligned part, just copy
while (length >= 8) {
length -= 8;
this.writeBuffer.push((value >> length) & 0xFF);
}
// Rest part is saved into cache
this.writeCacheSize = length;
this.writeCache = value & ((1 << length) - 1);
return;
},
// Drop what still in read cache and goto next 8-byte alignment.
// There might be a better naming.
nextOctetAlign: function() {
this.readCache = 0;
this.readCacheSize = 0;
},
// Flush current write cache to Buf with padding 0s.
// There might be a better naming.
flushWithPadding: function() {
if (this.writeCacheSize) {
this.writeBuffer.push(this.writeCache << (8 - this.writeCacheSize));
}
this.writeCache = 0;
this.writeCacheSize = 0;
},
startWrite: function(dataBuffer) {
this.writeBuffer = dataBuffer;
this.writeCache = 0;
this.writeCacheSize = 0;
},
startRead: function(dataBuffer) {
this.readBuffer = dataBuffer;
this.readCache = 0;
this.readCacheSize = 0;
this.readIndex = 0;
},
getWriteBufferSize: function() {
return this.writeBuffer.length;
},
overwriteWriteBuffer: function(position, data) {
let writeLength = data.length;
if (writeLength + position >= this.writeBuffer.length) {
writeLength = this.writeBuffer.length - position;
}
for (let i = 0; i < writeLength; i++) {
this.writeBuffer[i + position] = data[i];
}
}
};
/**
* Helper for CDMA PDU
*
* Currently, some function are shared with GsmPDUHelper, they should be
* moved from GsmPDUHelper to a common object shared among GsmPDUHelper and
* CdmaPDUHelper.
*/
function CdmaPDUHelperObject(aContext) {
this.context = aContext;
}
CdmaPDUHelperObject.prototype = {
context: null,
// 1..........C
// Only "1234567890*#" is defined in C.S0005-D v2.0
dtmfChars: ".1234567890*#...",
/**
* Entry point for SMS encoding, the options object is made compatible
* with existing writeMessage() of GsmPDUHelper, but less key is used.
*
* Current used key in options:
* @param number
* String containing the address (number) of the SMS receiver
* @param body
* String containing the message to be sent, segmented part
* @param dcs
* Data coding scheme. One of the PDU_DCS_MSG_CODING_*BITS_ALPHABET
* constants.
* @param encodedBodyLength
* Length of the user data when encoded with the given DCS. For UCS2,
* in bytes; for 7-bit, in septets.
* @param requestStatusReport
* Request status report.
* @param segmentRef
* Reference number of concatenated SMS message
* @param segmentMaxSeq
* Total number of concatenated SMS message
* @param segmentSeq
* Sequence number of concatenated SMS message
*/
writeMessage: function(options) {
if (DEBUG) {
this.context.debug("cdma_writeMessage: " + JSON.stringify(options));
}
// Get encoding
options.encoding = this.gsmDcsToCdmaEncoding(options.dcs);
// Common Header
if (options.segmentMaxSeq > 1) {
this.writeInt(PDU_CDMA_MSG_TELESERIVCIE_ID_WEMT);
} else {
this.writeInt(PDU_CDMA_MSG_TELESERIVCIE_ID_SMS);
}
this.writeInt(0);
this.writeInt(PDU_CDMA_MSG_CATEGORY_UNSPEC);
// Just fill out address info in byte, rild will encap them for us
let addrInfo = this.encodeAddr(options.number);
this.writeByte(addrInfo.digitMode);
this.writeByte(addrInfo.numberMode);
this.writeByte(addrInfo.numberType);
this.writeByte(addrInfo.numberPlan);
this.writeByte(addrInfo.address.length);
for (let i = 0; i < addrInfo.address.length; i++) {
this.writeByte(addrInfo.address[i]);
}
// Subaddress, not supported
this.writeByte(0); // Subaddress : Type
this.writeByte(0); // Subaddress : Odd
this.writeByte(0); // Subaddress : length
// User Data
let encodeResult = this.encodeUserData(options);
this.writeByte(encodeResult.length);
for (let i = 0; i < encodeResult.length; i++) {
this.writeByte(encodeResult[i]);
}
encodeResult = null;
},
/**
* Data writters
*/
writeInt: function(value) {
this.context.Buf.writeInt32(value);
},
writeByte: function(value) {
this.context.Buf.writeInt32(value & 0xFF);
},
/**
* Transform GSM DCS to CDMA encoding.
*/
gsmDcsToCdmaEncoding: function(encoding) {
switch (encoding) {
case PDU_DCS_MSG_CODING_7BITS_ALPHABET:
return PDU_CDMA_MSG_CODING_7BITS_ASCII;
case PDU_DCS_MSG_CODING_8BITS_ALPHABET:
return PDU_CDMA_MSG_CODING_OCTET;
case PDU_DCS_MSG_CODING_16BITS_ALPHABET:
return PDU_CDMA_MSG_CODING_UNICODE;
}
throw new Error("gsmDcsToCdmaEncoding(): Invalid GSM SMS DCS value: " + encoding);
},
/**
* Encode address into CDMA address format, as a byte array.
*
* @see 3GGP2 C.S0015-B 2.0, 3.4.3.3 Address Parameters
*
* @param address
* String of address to be encoded
*/
encodeAddr: function(address) {
let result = {};
result.numberType = PDU_CDMA_MSG_ADDR_NUMBER_TYPE_UNKNOWN;
result.numberPlan = PDU_CDMA_MSG_ADDR_NUMBER_TYPE_UNKNOWN;
if (address[0] === '+') {
address = address.substring(1);
}
// Try encode with DTMF first
result.digitMode = PDU_CDMA_MSG_ADDR_DIGIT_MODE_DTMF;
result.numberMode = PDU_CDMA_MSG_ADDR_NUMBER_MODE_ANSI;
result.address = [];
for (let i = 0; i < address.length; i++) {
let addrDigit = this.dtmfChars.indexOf(address.charAt(i));
if (addrDigit < 0) {
result.digitMode = PDU_CDMA_MSG_ADDR_DIGIT_MODE_ASCII;
result.numberMode = PDU_CDMA_MSG_ADDR_NUMBER_MODE_ASCII;
result.address = [];
break;
}
result.address.push(addrDigit);
}
// Address can't be encoded with DTMF, then use 7-bit ASCII
if (result.digitMode !== PDU_CDMA_MSG_ADDR_DIGIT_MODE_DTMF) {
if (address.indexOf("@") !== -1) {
result.numberType = PDU_CDMA_MSG_ADDR_NUMBER_TYPE_NATIONAL;
}
for (let i = 0; i < address.length; i++) {
result.address.push(address.charCodeAt(i) & 0x7F);
}
}
return result;
},
/**
* Encode SMS contents in options into CDMA userData field.
* Corresponding and required subparameters will be added automatically.
*
* @see 3GGP2 C.S0015-B 2.0, 3.4.3.7 Bearer Data
* 4.5 Bearer Data Parameters
*
* Current used key in options:
* @param body
* String containing the message to be sent, segmented part
* @param encoding
* Encoding method of CDMA, can be transformed from GSM DCS by function
* cdmaPduHelp.gsmDcsToCdmaEncoding()
* @param encodedBodyLength
* Length of the user data when encoded with the given DCS. For UCS2,
* in bytes; for 7-bit, in septets.
* @param requestStatusReport
* Request status report.
* @param segmentRef
* Reference number of concatenated SMS message
* @param segmentMaxSeq
* Total number of concatenated SMS message
* @param segmentSeq
* Sequence number of concatenated SMS message
*/
encodeUserData: function(options) {
let userDataBuffer = [];
this.context.BitBufferHelper.startWrite(userDataBuffer);
// Message Identifier
this.encodeUserDataMsgId(options);
// User Data
this.encodeUserDataMsg(options);
// Reply Option
this.encodeUserDataReplyOption(options);
return userDataBuffer;
},
/**
* User data subparameter encoder : Message Identifier
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.1 Message Identifier
*/
encodeUserDataMsgId: function(options) {
let BitBufferHelper = this.context.BitBufferHelper;
BitBufferHelper.writeBits(PDU_CDMA_MSG_USERDATA_MSG_ID, 8);
BitBufferHelper.writeBits(3, 8);
BitBufferHelper.writeBits(PDU_CDMA_MSG_TYPE_SUBMIT, 4);
BitBufferHelper.writeBits(1, 16); // TODO: How to get message ID?
if (options.segmentMaxSeq > 1) {
BitBufferHelper.writeBits(1, 1);
} else {
BitBufferHelper.writeBits(0, 1);
}
BitBufferHelper.flushWithPadding();
},
/**
* User data subparameter encoder : User Data
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.2 User Data
*/
encodeUserDataMsg: function(options) {
let BitBufferHelper = this.context.BitBufferHelper;
BitBufferHelper.writeBits(PDU_CDMA_MSG_USERDATA_BODY, 8);
// Reserve space for length
BitBufferHelper.writeBits(0, 8);
let lengthPosition = BitBufferHelper.getWriteBufferSize();
BitBufferHelper.writeBits(options.encoding, 5);
// Add user data header for message segement
let msgBody = options.body,
msgBodySize = (options.encoding === PDU_CDMA_MSG_CODING_7BITS_ASCII ?
options.encodedBodyLength :
msgBody.length);
if (options.segmentMaxSeq > 1) {
if (options.encoding === PDU_CDMA_MSG_CODING_7BITS_ASCII) {
BitBufferHelper.writeBits(msgBodySize + 7, 8); // Required length for user data header, in septet(7-bit)
BitBufferHelper.writeBits(5, 8); // total header length 5 bytes
BitBufferHelper.writeBits(PDU_IEI_CONCATENATED_SHORT_MESSAGES_8BIT, 8); // header id 0
BitBufferHelper.writeBits(3, 8); // length of element for id 0 is 3
BitBufferHelper.writeBits(options.segmentRef & 0xFF, 8); // Segement reference
BitBufferHelper.writeBits(options.segmentMaxSeq & 0xFF, 8); // Max segment
BitBufferHelper.writeBits(options.segmentSeq & 0xFF, 8); // Current segment
BitBufferHelper.writeBits(0, 1); // Padding to make header data septet(7-bit) aligned
} else {
if (options.encoding === PDU_CDMA_MSG_CODING_UNICODE) {
BitBufferHelper.writeBits(msgBodySize + 3, 8); // Required length for user data header, in 16-bit
} else {
BitBufferHelper.writeBits(msgBodySize + 6, 8); // Required length for user data header, in octet(8-bit)
}
BitBufferHelper.writeBits(5, 8); // total header length 5 bytes
BitBufferHelper.writeBits(PDU_IEI_CONCATENATED_SHORT_MESSAGES_8BIT, 8); // header id 0
BitBufferHelper.writeBits(3, 8); // length of element for id 0 is 3
BitBufferHelper.writeBits(options.segmentRef & 0xFF, 8); // Segement reference
BitBufferHelper.writeBits(options.segmentMaxSeq & 0xFF, 8); // Max segment
BitBufferHelper.writeBits(options.segmentSeq & 0xFF, 8); // Current segment
}
} else {
BitBufferHelper.writeBits(msgBodySize, 8);
}
// Encode message based on encoding method
const langTable = PDU_NL_LOCKING_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
const langShiftTable = PDU_NL_SINGLE_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
for (let i = 0; i < msgBody.length; i++) {
switch (options.encoding) {
case PDU_CDMA_MSG_CODING_OCTET: {
let msgDigit = msgBody.charCodeAt(i);
BitBufferHelper.writeBits(msgDigit, 8);
break;
}
case PDU_CDMA_MSG_CODING_7BITS_ASCII: {
let msgDigit = msgBody.charCodeAt(i),
msgDigitChar = msgBody.charAt(i);
if (msgDigit >= 32) {
BitBufferHelper.writeBits(msgDigit, 7);
} else {
msgDigit = langTable.indexOf(msgDigitChar);
if (msgDigit === PDU_NL_EXTENDED_ESCAPE) {
break;
}
if (msgDigit >= 0) {
BitBufferHelper.writeBits(msgDigit, 7);
} else {
msgDigit = langShiftTable.indexOf(msgDigitChar);
if (msgDigit == -1) {
throw new Error("'" + msgDigitChar + "' is not in 7 bit alphabet "
+ langIndex + ":" + langShiftIndex + "!");
}
if (msgDigit === PDU_NL_RESERVED_CONTROL) {
break;
}
BitBufferHelper.writeBits(PDU_NL_EXTENDED_ESCAPE, 7);
BitBufferHelper.writeBits(msgDigit, 7);
}
}
break;
}
case PDU_CDMA_MSG_CODING_UNICODE: {
let msgDigit = msgBody.charCodeAt(i);
BitBufferHelper.writeBits(msgDigit, 16);
break;
}
}
}
BitBufferHelper.flushWithPadding();
// Fill length
let currentPosition = BitBufferHelper.getWriteBufferSize();
BitBufferHelper.overwriteWriteBuffer(lengthPosition - 1, [currentPosition - lengthPosition]);
},
/**
* User data subparameter encoder : Reply Option
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.11 Reply Option
*/
encodeUserDataReplyOption: function(options) {
if (options.requestStatusReport) {
let BitBufferHelper = this.context.BitBufferHelper;
BitBufferHelper.writeBits(PDU_CDMA_MSG_USERDATA_REPLY_OPTION, 8);
BitBufferHelper.writeBits(1, 8);
BitBufferHelper.writeBits(0, 1); // USER_ACK_REQ
BitBufferHelper.writeBits(1, 1); // DAK_REQ
BitBufferHelper.flushWithPadding();
}
},
/**
* Entry point for SMS decoding, the returned object is made compatible
* with existing readMessage() of GsmPDUHelper
*/
readMessage: function() {
let message = {};
// Teleservice Identifier
message.teleservice = this.readInt();
// Message Type
let isServicePresent = this.readByte();
if (isServicePresent) {
message.messageType = PDU_CDMA_MSG_TYPE_BROADCAST;
} else {
if (message.teleservice) {
message.messageType = PDU_CDMA_MSG_TYPE_P2P;
} else {
message.messageType = PDU_CDMA_MSG_TYPE_ACK;
}
}
// Service Category
message.service = this.readInt();
// Originated Address
let addrInfo = {};
addrInfo.digitMode = (this.readInt() & 0x01);
addrInfo.numberMode = (this.readInt() & 0x01);
addrInfo.numberType = (this.readInt() & 0x01);
addrInfo.numberPlan = (this.readInt() & 0x01);
addrInfo.addrLength = this.readByte();
addrInfo.address = [];
for (let i = 0; i < addrInfo.addrLength; i++) {
addrInfo.address.push(this.readByte());
}
message.sender = this.decodeAddr(addrInfo);
// Originated Subaddress
addrInfo.Type = (this.readInt() & 0x07);
addrInfo.Odd = (this.readByte() & 0x01);
addrInfo.addrLength = this.readByte();
for (let i = 0; i < addrInfo.addrLength; i++) {
let addrDigit = this.readByte();
message.sender += String.fromCharCode(addrDigit);
}
// Bearer Data
this.decodeUserData(message);
// Bearer Data Sub-Parameter: User Data
let userData = message[PDU_CDMA_MSG_USERDATA_BODY];
[message.header, message.body, message.encoding, message.data] =
(userData) ? [userData.header, userData.body, userData.encoding, userData.data]
: [null, null, null, null];
// Bearer Data Sub-Parameter: Message Status
// Success Delivery (0) if both Message Status and User Data are absent.
// Message Status absent (-1) if only User Data is available.
let msgStatus = message[PDU_CDMA_MSG_USER_DATA_MSG_STATUS];
[message.errorClass, message.msgStatus] =
(msgStatus) ? [msgStatus.errorClass, msgStatus.msgStatus]
: ((message.body) ? [-1, -1] : [0, 0]);
// Transform message to GSM msg
let msg = {
SMSC: "",
mti: 0,
udhi: 0,
sender: message.sender,
recipient: null,
pid: PDU_PID_DEFAULT,
epid: PDU_PID_DEFAULT,
dcs: 0,
mwi: null,
replace: false,
header: message.header,
body: message.body,
data: message.data,
sentTimestamp: message[PDU_CDMA_MSG_USERDATA_TIMESTAMP],
language: message[PDU_CDMA_LANGUAGE_INDICATOR],
status: null,
scts: null,
dt: null,
encoding: message.encoding,
messageClass: GECKO_SMS_MESSAGE_CLASSES[PDU_DCS_MSG_CLASS_NORMAL],
messageType: message.messageType,
serviceCategory: message.service,
subMsgType: message[PDU_CDMA_MSG_USERDATA_MSG_ID].msgType,
msgId: message[PDU_CDMA_MSG_USERDATA_MSG_ID].msgId,
errorClass: message.errorClass,
msgStatus: message.msgStatus,
teleservice: message.teleservice
};
return msg;
},
/**
* Helper for processing received SMS parcel data.
*
* @param length
* Length of SMS string in the incoming parcel.
*
* @return Message parsed or null for invalid message.
*/
processReceivedSms: function(length) {
if (!length) {
if (DEBUG) this.context.debug("Received empty SMS!");
return [null, PDU_FCS_UNSPECIFIED];
}
let message = this.readMessage();
if (DEBUG) this.context.debug("Got new SMS: " + JSON.stringify(message));
// Determine result
if (!message) {
return [null, PDU_FCS_UNSPECIFIED];
}
return [message, PDU_FCS_OK];
},
/**
* Data readers
*/
readInt: function() {
return this.context.Buf.readInt32();
},
readByte: function() {
return (this.context.Buf.readInt32() & 0xFF);
},
/**
* Decode CDMA address data into address string
*
* @see 3GGP2 C.S0015-B 2.0, 3.4.3.3 Address Parameters
*
* Required key in addrInfo
* @param addrLength
* Length of address
* @param digitMode
* Address encoding method
* @param address
* Array of encoded address data
*/
decodeAddr: function(addrInfo) {
let result = "";
for (let i = 0; i < addrInfo.addrLength; i++) {
if (addrInfo.digitMode === PDU_CDMA_MSG_ADDR_DIGIT_MODE_DTMF) {
result += this.dtmfChars.charAt(addrInfo.address[i]);
} else {
result += String.fromCharCode(addrInfo.address[i]);
}
}
return result;
},
/**
* Read userData in parcel buffer and decode into message object.
* Each subparameter will be stored in corresponding key.
*
* @see 3GGP2 C.S0015-B 2.0, 3.4.3.7 Bearer Data
* 4.5 Bearer Data Parameters
*/
decodeUserData: function(message) {
let userDataLength = this.readInt();
while (userDataLength > 0) {
let id = this.readByte(),
length = this.readByte(),
userDataBuffer = [];
for (let i = 0; i < length; i++) {
userDataBuffer.push(this.readByte());
}
this.context.BitBufferHelper.startRead(userDataBuffer);
switch (id) {
case PDU_CDMA_MSG_USERDATA_MSG_ID:
message[id] = this.decodeUserDataMsgId();
break;
case PDU_CDMA_MSG_USERDATA_BODY:
message[id] = this.decodeUserDataMsg(message[PDU_CDMA_MSG_USERDATA_MSG_ID].userHeader);
break;
case PDU_CDMA_MSG_USERDATA_TIMESTAMP:
message[id] = this.decodeUserDataTimestamp();
break;
case PDU_CDMA_MSG_USERDATA_REPLY_OPTION:
message[id] = this.decodeUserDataReplyOption();
break;
case PDU_CDMA_LANGUAGE_INDICATOR:
message[id] = this.decodeLanguageIndicator();
break;
case PDU_CDMA_MSG_USERDATA_CALLBACK_NUMBER:
message[id] = this.decodeUserDataCallbackNumber();
break;
case PDU_CDMA_MSG_USER_DATA_MSG_STATUS:
message[id] = this.decodeUserDataMsgStatus();
break;
}
userDataLength -= (length + 2);
userDataBuffer = [];
}
},
/**
* User data subparameter decoder: Message Identifier
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.1 Message Identifier
*/
decodeUserDataMsgId: function() {
let result = {};
let BitBufferHelper = this.context.BitBufferHelper;
result.msgType = BitBufferHelper.readBits(4);
result.msgId = BitBufferHelper.readBits(16);
result.userHeader = BitBufferHelper.readBits(1);
return result;
},
/**
* Decode user data header, we only care about segment information
* on CDMA.
*
* This function is mostly copied from gsmPduHelper.readUserDataHeader() but
* change the read function, because CDMA user header decoding is't byte-wise
* aligned.
*/
decodeUserDataHeader: function(encoding) {
let BitBufferHelper = this.context.BitBufferHelper;
let header = {},
headerSize = BitBufferHelper.readBits(8),
userDataHeaderSize = headerSize + 1,
headerPaddingBits = 0;
// Calculate header size
if (encoding === PDU_DCS_MSG_CODING_7BITS_ALPHABET) {
// Length is in 7-bit
header.length = Math.ceil(userDataHeaderSize * 8 / 7);
// Calulate padding length
headerPaddingBits = (header.length * 7) - (userDataHeaderSize * 8);
} else if (encoding === PDU_DCS_MSG_CODING_8BITS_ALPHABET) {
header.length = userDataHeaderSize;
} else {
header.length = userDataHeaderSize / 2;
}
while (headerSize) {
let identifier = BitBufferHelper.readBits(8),
length = BitBufferHelper.readBits(8);
headerSize -= (2 + length);
switch (identifier) {
case PDU_IEI_CONCATENATED_SHORT_MESSAGES_8BIT: {
let ref = BitBufferHelper.readBits(8),
max = BitBufferHelper.readBits(8),
seq = BitBufferHelper.readBits(8);
if (max && seq && (seq <= max)) {
header.segmentRef = ref;
header.segmentMaxSeq = max;
header.segmentSeq = seq;
}
break;
}
case PDU_IEI_APPLICATION_PORT_ADDRESSING_SCHEME_8BIT: {
let dstp = BitBufferHelper.readBits(8),
orip = BitBufferHelper.readBits(8);
if ((dstp < PDU_APA_RESERVED_8BIT_PORTS)
|| (orip < PDU_APA_RESERVED_8BIT_PORTS)) {
// 3GPP TS 23.040 clause 9.2.3.24.3: "A receiving entity shall
// ignore any information element where the value of the
// Information-Element-Data is Reserved or not supported"
break;
}
header.destinationPort = dstp;
header.originatorPort = orip;
break;
}
case PDU_IEI_APPLICATION_PORT_ADDRESSING_SCHEME_16BIT: {
let dstp = (BitBufferHelper.readBits(8) << 8) | BitBufferHelper.readBits(8),
orip = (BitBufferHelper.readBits(8) << 8) | BitBufferHelper.readBits(8);
// 3GPP TS 23.040 clause 9.2.3.24.4: "A receiving entity shall
// ignore any information element where the value of the
// Information-Element-Data is Reserved or not supported"
if ((dstp < PDU_APA_VALID_16BIT_PORTS)
&& (orip < PDU_APA_VALID_16BIT_PORTS)) {
header.destinationPort = dstp;
header.originatorPort = orip;
}
break;
}
case PDU_IEI_CONCATENATED_SHORT_MESSAGES_16BIT: {
let ref = (BitBufferHelper.readBits(8) << 8) | BitBufferHelper.readBits(8),
max = BitBufferHelper.readBits(8),
seq = BitBufferHelper.readBits(8);
if (max && seq && (seq <= max)) {
header.segmentRef = ref;
header.segmentMaxSeq = max;
header.segmentSeq = seq;
}
break;
}
case PDU_IEI_NATIONAL_LANGUAGE_SINGLE_SHIFT: {
let langShiftIndex = BitBufferHelper.readBits(8);
if (langShiftIndex < PDU_NL_SINGLE_SHIFT_TABLES.length) {
header.langShiftIndex = langShiftIndex;
}
break;
}
case PDU_IEI_NATIONAL_LANGUAGE_LOCKING_SHIFT: {
let langIndex = BitBufferHelper.readBits(8);
if (langIndex < PDU_NL_LOCKING_SHIFT_TABLES.length) {
header.langIndex = langIndex;
}
break;
}
case PDU_IEI_SPECIAL_SMS_MESSAGE_INDICATION: {
let msgInd = BitBufferHelper.readBits(8) & 0xFF,
msgCount = BitBufferHelper.readBits(8);
/*
* TS 23.040 V6.8.1 Sec 9.2.3.24.2
* bits 1 0 : basic message indication type
* bits 4 3 2 : extended message indication type
* bits 6 5 : Profile id
* bit 7 : storage type
*/
let storeType = msgInd & PDU_MWI_STORE_TYPE_BIT;
header.mwi = {};
mwi = header.mwi;
if (storeType == PDU_MWI_STORE_TYPE_STORE) {
// Store message because TP_UDH indicates so, note this may override
// the setting in DCS, but that is expected
mwi.discard = false;
} else if (mwi.discard === undefined) {
// storeType == PDU_MWI_STORE_TYPE_DISCARD
// only override mwi.discard here if it hasn't already been set
mwi.discard = true;
}
mwi.msgCount = msgCount & 0xFF;
mwi.active = mwi.msgCount > 0;
if (DEBUG) {
this.context.debug("MWI in TP_UDH received: " + JSON.stringify(mwi));
}
break;
}
default:
// Drop unsupported id
for (let i = 0; i < length; i++) {
BitBufferHelper.readBits(8);
}
}
}
// Consume padding bits
if (headerPaddingBits) {
BitBufferHelper.readBits(headerPaddingBits);
}
return header;
},
getCdmaMsgEncoding: function(encoding) {
// Determine encoding method
switch (encoding) {
case PDU_CDMA_MSG_CODING_7BITS_ASCII:
case PDU_CDMA_MSG_CODING_IA5:
case PDU_CDMA_MSG_CODING_7BITS_GSM:
return PDU_DCS_MSG_CODING_7BITS_ALPHABET;
case PDU_CDMA_MSG_CODING_OCTET:
case PDU_CDMA_MSG_CODING_IS_91:
case PDU_CDMA_MSG_CODING_LATIN_HEBREW:
case PDU_CDMA_MSG_CODING_LATIN:
return PDU_DCS_MSG_CODING_8BITS_ALPHABET;
case PDU_CDMA_MSG_CODING_UNICODE:
case PDU_CDMA_MSG_CODING_SHIFT_JIS:
case PDU_CDMA_MSG_CODING_KOREAN:
return PDU_DCS_MSG_CODING_16BITS_ALPHABET;
}
return null;
},
decodeCdmaPDUMsg: function(encoding, msgType, msgBodySize) {
const langTable = PDU_NL_LOCKING_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
const langShiftTable = PDU_NL_SINGLE_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
let BitBufferHelper = this.context.BitBufferHelper;
let result = "";
let msgDigit;
switch (encoding) {
case PDU_CDMA_MSG_CODING_OCTET: // TODO : Require Test
while(msgBodySize > 0) {
msgDigit = String.fromCharCode(BitBufferHelper.readBits(8));
result += msgDigit;
msgBodySize--;
}
break;
case PDU_CDMA_MSG_CODING_IS_91: // TODO : Require Test
// Referenced from android code
switch (msgType) {
case PDU_CDMA_MSG_CODING_IS_91_TYPE_SMS:
case PDU_CDMA_MSG_CODING_IS_91_TYPE_SMS_FULL:
case PDU_CDMA_MSG_CODING_IS_91_TYPE_VOICEMAIL_STATUS:
while(msgBodySize > 0) {
msgDigit = String.fromCharCode(BitBufferHelper.readBits(6) + 0x20);
result += msgDigit;
msgBodySize--;
}
break;
case PDU_CDMA_MSG_CODING_IS_91_TYPE_CLI:
let addrInfo = {};
addrInfo.digitMode = PDU_CDMA_MSG_ADDR_DIGIT_MODE_DTMF;
addrInfo.numberMode = PDU_CDMA_MSG_ADDR_NUMBER_MODE_ANSI;
addrInfo.numberType = PDU_CDMA_MSG_ADDR_NUMBER_TYPE_UNKNOWN;
addrInfo.numberPlan = PDU_CDMA_MSG_ADDR_NUMBER_PLAN_UNKNOWN;
addrInfo.addrLength = msgBodySize;
addrInfo.address = [];
for (let i = 0; i < addrInfo.addrLength; i++) {
addrInfo.address.push(BitBufferHelper.readBits(4));
}
result = this.decodeAddr(addrInfo);
break;
}
// Fall through.
case PDU_CDMA_MSG_CODING_7BITS_ASCII:
case PDU_CDMA_MSG_CODING_IA5: // TODO : Require Test
while(msgBodySize > 0) {
msgDigit = BitBufferHelper.readBits(7);
if (msgDigit >= 32) {
msgDigit = String.fromCharCode(msgDigit);
} else {
if (msgDigit !== PDU_NL_EXTENDED_ESCAPE) {
msgDigit = langTable[msgDigit];
} else {
msgDigit = BitBufferHelper.readBits(7);
msgBodySize--;
msgDigit = langShiftTable[msgDigit];
}
}
result += msgDigit;
msgBodySize--;
}
break;
case PDU_CDMA_MSG_CODING_UNICODE:
while(msgBodySize > 0) {
msgDigit = String.fromCharCode(BitBufferHelper.readBits(16));
result += msgDigit;
msgBodySize--;
}
break;
case PDU_CDMA_MSG_CODING_7BITS_GSM: // TODO : Require Test
while(msgBodySize > 0) {
msgDigit = BitBufferHelper.readBits(7);
if (msgDigit !== PDU_NL_EXTENDED_ESCAPE) {
msgDigit = langTable[msgDigit];
} else {
msgDigit = BitBufferHelper.readBits(7);
msgBodySize--;
msgDigit = langShiftTable[msgDigit];
}
result += msgDigit;
msgBodySize--;
}
break;
case PDU_CDMA_MSG_CODING_LATIN: // TODO : Require Test
// Reference : http://en.wikipedia.org/wiki/ISO/IEC_8859-1
while(msgBodySize > 0) {
msgDigit = String.fromCharCode(BitBufferHelper.readBits(8));
result += msgDigit;
msgBodySize--;
}
break;
case PDU_CDMA_MSG_CODING_LATIN_HEBREW: // TODO : Require Test
// Reference : http://en.wikipedia.org/wiki/ISO/IEC_8859-8
while(msgBodySize > 0) {
msgDigit = BitBufferHelper.readBits(8);
if (msgDigit === 0xDF) {
msgDigit = String.fromCharCode(0x2017);
} else if (msgDigit === 0xFD) {
msgDigit = String.fromCharCode(0x200E);
} else if (msgDigit === 0xFE) {
msgDigit = String.fromCharCode(0x200F);
} else if (msgDigit >= 0xE0 && msgDigit <= 0xFA) {
msgDigit = String.fromCharCode(0x4F0 + msgDigit);
} else {
msgDigit = String.fromCharCode(msgDigit);
}
result += msgDigit;
msgBodySize--;
}
break;
case PDU_CDMA_MSG_CODING_SHIFT_JIS:
// Reference : http://msdn.microsoft.com/en-US/goglobal/cc305152.aspx
// http://demo.icu-project.org/icu-bin/convexp?conv=Shift_JIS
let shift_jis_message = [];
while (msgBodySize > 0) {
shift_jis_message.push(BitBufferHelper.readBits(8));
msgBodySize--;
}
let decoder = new TextDecoder("shift_jis");
result = decoder.decode(new Uint8Array(shift_jis_message));
break;
case PDU_CDMA_MSG_CODING_KOREAN:
case PDU_CDMA_MSG_CODING_GSM_DCS:
// Fall through.
default:
break;
}
return result;
},
/**
* User data subparameter decoder : User Data
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.2 User Data
*/
decodeUserDataMsg: function(hasUserHeader) {
let BitBufferHelper = this.context.BitBufferHelper;
let result = {},
encoding = BitBufferHelper.readBits(5),
msgType;
if (encoding === PDU_CDMA_MSG_CODING_IS_91) {
msgType = BitBufferHelper.readBits(8);
}
result.encoding = this.getCdmaMsgEncoding(encoding);
let msgBodySize = BitBufferHelper.readBits(8);
// For segmented SMS, a user header is included before sms content
if (hasUserHeader) {
result.header = this.decodeUserDataHeader(result.encoding);
// header size is included in body size, they are decoded
msgBodySize -= result.header.length;
}
// Store original payload if enconding is OCTET for further handling of WAP Push, etc.
if (encoding === PDU_CDMA_MSG_CODING_OCTET && msgBodySize > 0) {
result.data = new Uint8Array(msgBodySize);
for (let i = 0; i < msgBodySize; i++) {
result.data[i] = BitBufferHelper.readBits(8);
}
BitBufferHelper.backwardReadPilot(8 * msgBodySize);
}
// Decode sms content
result.body = this.decodeCdmaPDUMsg(encoding, msgType, msgBodySize);
return result;
},
decodeBcd: function(value) {
return ((value >> 4) & 0xF) * 10 + (value & 0x0F);
},
/**
* User data subparameter decoder : Time Stamp
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.4 Message Center Time Stamp
*/
decodeUserDataTimestamp: function() {
let BitBufferHelper = this.context.BitBufferHelper;
let year = this.decodeBcd(BitBufferHelper.readBits(8)),
month = this.decodeBcd(BitBufferHelper.readBits(8)) - 1,
date = this.decodeBcd(BitBufferHelper.readBits(8)),
hour = this.decodeBcd(BitBufferHelper.readBits(8)),
min = this.decodeBcd(BitBufferHelper.readBits(8)),
sec = this.decodeBcd(BitBufferHelper.readBits(8));
if (year >= 96 && year <= 99) {
year += 1900;
} else {
year += 2000;
}
let result = (new Date(year, month, date, hour, min, sec, 0)).valueOf();
return result;
},
/**
* User data subparameter decoder : Reply Option
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.11 Reply Option
*/
decodeUserDataReplyOption: function() {
let replyAction = this.context.BitBufferHelper.readBits(4),
result = { userAck: (replyAction & 0x8) ? true : false,
deliverAck: (replyAction & 0x4) ? true : false,
readAck: (replyAction & 0x2) ? true : false,
report: (replyAction & 0x1) ? true : false
};
return result;
},
/**
* User data subparameter decoder : Language Indicator
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.14 Language Indicator
*/
decodeLanguageIndicator: function() {
let language = this.context.BitBufferHelper.readBits(8);
let result = CB_CDMA_LANG_GROUP[language];
return result;
},
/**
* User data subparameter decoder : Call-Back Number
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.15 Call-Back Number
*/
decodeUserDataCallbackNumber: function() {
let BitBufferHelper = this.context.BitBufferHelper;
let digitMode = BitBufferHelper.readBits(1);
if (digitMode) {
let numberType = BitBufferHelper.readBits(3),
numberPlan = BitBufferHelper.readBits(4);
}
let numberFields = BitBufferHelper.readBits(8),
result = "";
for (let i = 0; i < numberFields; i++) {
if (digitMode === PDU_CDMA_MSG_ADDR_DIGIT_MODE_DTMF) {
let addrDigit = BitBufferHelper.readBits(4);
result += this.dtmfChars.charAt(addrDigit);
} else {
let addrDigit = BitBufferHelper.readBits(8);
result += String.fromCharCode(addrDigit);
}
}
return result;
},
/**
* User data subparameter decoder : Message Status
*
* @see 3GGP2 C.S0015-B 2.0, 4.5.21 Message Status
*/
decodeUserDataMsgStatus: function() {
let BitBufferHelper = this.context.BitBufferHelper;
let result = {
errorClass: BitBufferHelper.readBits(2),
msgStatus: BitBufferHelper.readBits(6)
};
return result;
},
/**
* Decode information record parcel.
*/
decodeInformationRecord: function() {
let Buf = this.context.Buf;
let records = [];
let numOfRecords = Buf.readInt32();
let type;
let record;
for (let i = 0; i < numOfRecords; i++) {
record = {};
type = Buf.readInt32();
switch (type) {
/*
* Every type is encaped by ril, except extended display
*/
case PDU_CDMA_INFO_REC_TYPE_DISPLAY:
case PDU_CDMA_INFO_REC_TYPE_EXTENDED_DISPLAY:
record.display = Buf.readString();
break;
case PDU_CDMA_INFO_REC_TYPE_CALLED_PARTY_NUMBER:
record.calledNumber = {};
record.calledNumber.number = Buf.readString();
record.calledNumber.type = Buf.readInt32();
record.calledNumber.plan = Buf.readInt32();
record.calledNumber.pi = Buf.readInt32();
record.calledNumber.si = Buf.readInt32();
break;
case PDU_CDMA_INFO_REC_TYPE_CALLING_PARTY_NUMBER:
record.callingNumber = {};
record.callingNumber.number = Buf.readString();
record.callingNumber.type = Buf.readInt32();
record.callingNumber.plan = Buf.readInt32();
record.callingNumber.pi = Buf.readInt32();
record.callingNumber.si = Buf.readInt32();
break;
case PDU_CDMA_INFO_REC_TYPE_CONNECTED_NUMBER:
record.connectedNumber = {};
record.connectedNumber.number = Buf.readString();
record.connectedNumber.type = Buf.readInt32();
record.connectedNumber.plan = Buf.readInt32();
record.connectedNumber.pi = Buf.readInt32();
record.connectedNumber.si = Buf.readInt32();
break;
case PDU_CDMA_INFO_REC_TYPE_SIGNAL:
record.signal = {};
if (!Buf.readInt32()) { // Non-zero if signal is present.
Buf.seekIncoming(3 * Buf.UINT32_SIZE);
continue;
}
record.signal.type = Buf.readInt32();
record.signal.alertPitch = Buf.readInt32();
record.signal.signal = Buf.readInt32();
break;
case PDU_CDMA_INFO_REC_TYPE_REDIRECTING_NUMBER:
record.redirect = {};
record.redirect.number = Buf.readString();
record.redirect.type = Buf.readInt32();
record.redirect.plan = Buf.readInt32();
record.redirect.pi = Buf.readInt32();
record.redirect.si = Buf.readInt32();
record.redirect.reason = Buf.readInt32();
break;
case PDU_CDMA_INFO_REC_TYPE_LINE_CONTROL:
record.lineControl = {};
record.lineControl.polarityIncluded = Buf.readInt32();
record.lineControl.toggle = Buf.readInt32();
record.lineControl.reverse = Buf.readInt32();
record.lineControl.powerDenial = Buf.readInt32();
break;
case PDU_CDMA_INFO_REC_TYPE_T53_CLIR:
record.clirCause = Buf.readInt32();
break;
case PDU_CDMA_INFO_REC_TYPE_T53_AUDIO_CONTROL:
record.audioControl = {};
record.audioControl.upLink = Buf.readInt32();
record.audioControl.downLink = Buf.readInt32();
break;
case PDU_CDMA_INFO_REC_TYPE_T53_RELEASE:
// Fall through
default:
throw new Error("UNSOLICITED_CDMA_INFO_REC(), Unsupported information record type " + type + "\n");
}
records.push(record);
}
return records;
}
};
/**
* Helper for processing ICC PDUs.
*/
function ICCPDUHelperObject(aContext) {
this.context = aContext;
}
ICCPDUHelperObject.prototype = {
context: null,
/**
* Read GSM 8-bit unpacked octets,
* which are default 7-bit alphabets with bit 8 set to 0.
*
* @param numOctets
* Number of octets to be read.
*/
read8BitUnpackedToString: function(numOctets) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let ret = "";
let escapeFound = false;
let i;
const langTable = PDU_NL_LOCKING_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
const langShiftTable = PDU_NL_SINGLE_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
for(i = 0; i < numOctets; i++) {
let octet = GsmPDUHelper.readHexOctet();
if (octet == 0xff) {
i++;
break;
}
if (escapeFound) {
escapeFound = false;
if (octet == PDU_NL_EXTENDED_ESCAPE) {
// According to 3GPP TS 23.038, section 6.2.1.1, NOTE 1, "On
// receipt of this code, a receiving entity shall display a space
// until another extensiion table is defined."
ret += " ";
} else if (octet == PDU_NL_RESERVED_CONTROL) {
// According to 3GPP TS 23.038 B.2, "This code represents a control
// character and therefore must not be used for language specific
// characters."
ret += " ";
} else {
ret += langShiftTable[octet];
}
} else if (octet == PDU_NL_EXTENDED_ESCAPE) {
escapeFound = true;
} else {
ret += langTable[octet];
}
}
let Buf = this.context.Buf;
Buf.seekIncoming((numOctets - i) * Buf.PDU_HEX_OCTET_SIZE);
return ret;
},
/**
* Write GSM 8-bit unpacked octets.
*
* @param numOctets Number of total octets to be writen, including trailing
* 0xff.
* @param str String to be written. Could be null.
*
* @return The string has been written into Buf.
*/
writeStringTo8BitUnpacked: function(numOctets, str) {
const langTable = PDU_NL_LOCKING_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
const langShiftTable = PDU_NL_SINGLE_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
let GsmPDUHelper = this.context.GsmPDUHelper;
// If the character is GSM extended alphabet, two octets will be written.
// So we need to keep track of number of octets to be written.
let i, j;
let len = str ? str.length : 0;
for (i = 0, j = 0; i < len && j < numOctets; i++) {
let c = str.charAt(i);
let octet = langTable.indexOf(c);
if (octet == -1) {
// Make sure we still have enough space to write two octets.
if (j + 2 > numOctets) {
break;
}
octet = langShiftTable.indexOf(c);
if (octet == -1) {
// Fallback to ASCII space.
octet = langTable.indexOf(' ');
} else {
GsmPDUHelper.writeHexOctet(PDU_NL_EXTENDED_ESCAPE);
j++;
}
}
GsmPDUHelper.writeHexOctet(octet);
j++;
}
// trailing 0xff
while (j++ < numOctets) {
GsmPDUHelper.writeHexOctet(0xff);
}
return (str) ? str.substring(0, i) : null;
},
/**
* Write UCS2 String on UICC.
* The default choose 0x81 or 0x82 encode, otherwise use 0x80 encode.
*
* @see TS 102.221, Annex A.
* @param numOctets
* Total number of octets to be written. This includes the length of
* alphaId and the length of trailing unused octets(0xff).
* @param str
* String to be written.
*
* @return The string has been written into Buf.
*/
writeICCUCS2String: function(numOctets, str) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let scheme = 0x80;
let basePointer;
if (str.length > 2) {
let min = 0xFFFF;
let max = 0;
for (let i = 0; i < str.length; i++) {
let code = str.charCodeAt(i);
// filter out GSM Default Alphabet character
if (code & 0xFF80) {
if (min > code) {
min = code;
}
if (max < code) {
max = code;
}
}
}
// 0x81 and 0x82 only support 'half-page', i.e., 128 characters.
if ((max - min) >= 0 && (max - min) < 128) {
// 0x81 base pointer is 0hhh hhhh h000 0000, and bit 16 is set to zero,
// therefore it can't compute 0x8000~0xFFFF.
// Since 0x81 only support 128 characters,
// either XX00~XX7f(bit 8 are 0) or XX80~XXff(bit 8 are 1)
if (((min & 0x7f80) == (max & 0x7f80)) &&
((max & 0x8000) == 0)) {
scheme = 0x81;
basePointer = min & 0x7f80;
} else {
scheme = 0x82;
basePointer = min;
}
}
}
switch (scheme) {
/**
* +------+---------+---------+---------+---------+------+------+
* | 0x80 | Ch1_msb | Ch1_lsb | Ch2_msb | Ch2_lsb | 0xff | 0xff |
* +------+---------+---------+---------+---------+------+------+
*/
case 0x80: {
// 0x80 support UCS2 0000~ffff
GsmPDUHelper.writeHexOctet(0x80);
numOctets--;
// Now the str is UCS2 string, each character will take 2 octets.
if (str.length * 2 > numOctets) {
str = str.substring(0, Math.floor(numOctets / 2));
}
GsmPDUHelper.writeUCS2String(str);
// trailing 0xff
for (let i = str.length * 2; i < numOctets; i++) {
GsmPDUHelper.writeHexOctet(0xff);
}
return str;
}
/**
* +------+-----+--------------+-----+-----+-----+--------+------+
* | 0x81 | len | base_pointer | Ch1 | Ch2 | ... | Ch_len | 0xff |
* +------+-----+--------------+-----+-----+-----+--------+------+
*
* len: The length of characters.
* base_pointer: 0hhh hhhh h000 0000
* Ch_n: bit 8 = 0
* GSM default alphabets
* bit 8 = 1
* UCS2 character whose char code is (Ch_n - base_pointer) | 0x80
*
*/
case 0x81: {
GsmPDUHelper.writeHexOctet(0x81);
if (str.length > (numOctets - 3)) {
str = str.substring(0, numOctets - 3);
}
GsmPDUHelper.writeHexOctet(str.length);
GsmPDUHelper.writeHexOctet((basePointer >> 7) & 0xff);
numOctets -= 3;
break;
}
/* +------+-----+------------------+------------------+-----+-----+-----+--------+
* | 0x82 | len | base_pointer_msb | base_pointer_lsb | Ch1 | Ch2 | ... | Ch_len |
* +------+-----+------------------+------------------+-----+-----+-----+--------+
*
* len: The length of characters.
* base_pointer_msb, base_pointer_lsn: base_pointer
* Ch_n: bit 8 = 0
* GSM default alphabets
* bit 8 = 1
* UCS2 character whose char code is (Ch_n - base_pointer) | 0x80
*/
case 0x82: {
GsmPDUHelper.writeHexOctet(0x82);
if (str.length > (numOctets - 4)) {
str = str.substring(0, numOctets - 4);
}
GsmPDUHelper.writeHexOctet(str.length);
GsmPDUHelper.writeHexOctet((basePointer >> 8) & 0xff);
GsmPDUHelper.writeHexOctet(basePointer & 0xff);
numOctets -= 4;
break;
}
}
if (scheme == 0x81 || scheme == 0x82) {
for (let i = 0; i < str.length; i++) {
let code = str.charCodeAt(i);
// bit 8 = 0,
// GSM default alphabets
if (code >> 8 == 0) {
GsmPDUHelper.writeHexOctet(code & 0x7F);
} else {
// bit 8 = 1,
// UCS2 character whose char code is (code - basePointer) | 0x80
GsmPDUHelper.writeHexOctet((code - basePointer) | 0x80);
}
}
// trailing 0xff
for (let i = 0; i < numOctets - str.length; i++) {
GsmPDUHelper.writeHexOctet(0xff);
}
}
return str;
},
/**
* Read UCS2 String on UICC.
*
* @see TS 101.221, Annex A.
* @param scheme
* Coding scheme for UCS2 on UICC. One of 0x80, 0x81 or 0x82.
* @param numOctets
* Number of octets to be read as UCS2 string.
*/
readICCUCS2String: function(scheme, numOctets) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
let str = "";
switch (scheme) {
/**
* +------+---------+---------+---------+---------+------+------+
* | 0x80 | Ch1_msb | Ch1_lsb | Ch2_msb | Ch2_lsb | 0xff | 0xff |
* +------+---------+---------+---------+---------+------+------+
*/
case 0x80:
let isOdd = numOctets % 2;
let i;
for (i = 0; i < numOctets - isOdd; i += 2) {
let code = (GsmPDUHelper.readHexOctet() << 8) | GsmPDUHelper.readHexOctet();
if (code == 0xffff) {
i += 2;
break;
}
str += String.fromCharCode(code);
}
// Skip trailing 0xff
Buf.seekIncoming((numOctets - i) * Buf.PDU_HEX_OCTET_SIZE);
break;
case 0x81: // Fall through
case 0x82:
/**
* +------+-----+--------+-----+-----+-----+--------+------+
* | 0x81 | len | offset | Ch1 | Ch2 | ... | Ch_len | 0xff |
* +------+-----+--------+-----+-----+-----+--------+------+
*
* len : The length of characters.
* offset : 0hhh hhhh h000 0000
* Ch_n: bit 8 = 0
* GSM default alphabets
* bit 8 = 1
* UCS2 character whose char code is (Ch_n & 0x7f) + offset
*
* +------+-----+------------+------------+-----+-----+-----+--------+
* | 0x82 | len | offset_msb | offset_lsb | Ch1 | Ch2 | ... | Ch_len |
* +------+-----+------------+------------+-----+-----+-----+--------+
*
* len : The length of characters.
* offset_msb, offset_lsn: offset
* Ch_n: bit 8 = 0
* GSM default alphabets
* bit 8 = 1
* UCS2 character whose char code is (Ch_n & 0x7f) + offset
*/
let len = GsmPDUHelper.readHexOctet();
let offset, headerLen;
if (scheme == 0x81) {
offset = GsmPDUHelper.readHexOctet() << 7;
headerLen = 2;
} else {
offset = (GsmPDUHelper.readHexOctet() << 8) | GsmPDUHelper.readHexOctet();
headerLen = 3;
}
for (let i = 0; i < len; i++) {
let ch = GsmPDUHelper.readHexOctet();
if (ch & 0x80) {
// UCS2
str += String.fromCharCode((ch & 0x7f) + offset);
} else {
// GSM 8bit
let count = 0, gotUCS2 = 0;
while ((i + count + 1 < len)) {
count++;
if (GsmPDUHelper.readHexOctet() & 0x80) {
gotUCS2 = 1;
break;
}
}
// Unread.
// +1 for the GSM alphabet indexed at i,
Buf.seekIncoming(-1 * (count + 1) * Buf.PDU_HEX_OCTET_SIZE);
str += this.read8BitUnpackedToString(count + 1 - gotUCS2);
i += count - gotUCS2;
}
}
// Skipping trailing 0xff
Buf.seekIncoming((numOctets - len - headerLen) * Buf.PDU_HEX_OCTET_SIZE);
break;
}
return str;
},
/**
* Read Alpha Id and Dialling number from TS TS 151.011 clause 10.5.1
*
* @param recordSize The size of linear fixed record.
*/
readAlphaIdDiallingNumber: function(recordSize) {
let Buf = this.context.Buf;
let length = Buf.readInt32();
let alphaLen = recordSize - ADN_FOOTER_SIZE_BYTES;
let alphaId = this.readAlphaIdentifier(alphaLen);
let number = this.readNumberWithLength();
// Skip unused octet, CCP
Buf.seekIncoming(Buf.PDU_HEX_OCTET_SIZE);
let extRecordNumber = this.context.GsmPDUHelper.readHexOctet();
Buf.readStringDelimiter(length);
let contact = null;
if (alphaId || number) {
contact = {alphaId: alphaId,
number: number,
extRecordNumber: extRecordNumber};
}
return contact;
},
/**
* Write Alpha Identifier and Dialling number from TS 151.011 clause 10.5.1
*
* @param recordSize The size of linear fixed record.
* @param alphaId Alpha Identifier to be written.
* @param number Dialling Number to be written.
* @param extRecordNumber The record identifier of the EXT.
*
* @return An object contains the alphaId and number
* that have been written into Buf.
*/
writeAlphaIdDiallingNumber: function(recordSize, alphaId, number, extRecordNumber) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
// Write String length
let strLen = recordSize * 2;
Buf.writeInt32(strLen);
let alphaLen = recordSize - ADN_FOOTER_SIZE_BYTES;
let writtenAlphaId = this.writeAlphaIdentifier(alphaLen, alphaId);
let writtenNumber = this.writeNumberWithLength(number);
// Write unused CCP octet 0xff.
GsmPDUHelper.writeHexOctet(0xff);
GsmPDUHelper.writeHexOctet((extRecordNumber != null) ? extRecordNumber : 0xff);
Buf.writeStringDelimiter(strLen);
return {alphaId: writtenAlphaId,
number: writtenNumber};
},
/**
* Read Alpha Identifier.
*
* @see TS 131.102
*
* @param numOctets
* Number of octets to be read.
*
* It uses either
* 1. SMS default 7-bit alphabet with bit 8 set to 0.
* 2. UCS2 string.
*
* Unused bytes should be set to 0xff.
*/
readAlphaIdentifier: function(numOctets) {
if (numOctets === 0) {
return "";
}
let temp;
// Read the 1st octet to determine the encoding.
if ((temp = this.context.GsmPDUHelper.readHexOctet()) == 0x80 ||
temp == 0x81 ||
temp == 0x82) {
numOctets--;
return this.readICCUCS2String(temp, numOctets);
} else {
let Buf = this.context.Buf;
Buf.seekIncoming(-1 * Buf.PDU_HEX_OCTET_SIZE);
return this.read8BitUnpackedToString(numOctets);
}
},
/**
* Write Alpha Identifier.
*
* @param numOctets
* Total number of octets to be written. This includes the length of
* alphaId and the length of trailing unused octets(0xff).
* @param alphaId
* Alpha Identifier to be written.
*
* @return The Alpha Identifier has been written into Buf.
*
* Unused octets will be written as 0xff.
*/
writeAlphaIdentifier: function(numOctets, alphaId) {
if (numOctets === 0) {
return null;
}
// If alphaId is empty or it's of GSM 8 bit.
if (!alphaId || this.context.ICCUtilsHelper.isGsm8BitAlphabet(alphaId)) {
return this.writeStringTo8BitUnpacked(numOctets, alphaId);
} else {
return this.writeICCUCS2String(numOctets, alphaId);
}
},
/**
* Read Dialling number.
*
* @see TS 131.102
*
* @param len
* The Length of BCD number.
*
* From TS 131.102, in EF_ADN, EF_FDN, the field 'Length of BCD number'
* means the total bytes should be allocated to store the TON/NPI and
* the dialing number.
* For example, if the dialing number is 1234567890,
* and the TON/NPI is 0x81,
* The field 'Length of BCD number' should be 06, which is
* 1 byte to store the TON/NPI, 0x81
* 5 bytes to store the BCD number 2143658709.
*
* Here the definition of the length is different from SMS spec,
* TS 23.040 9.1.2.5, which the length means
* "number of useful semi-octets within the Address-Value field".
*/
readDiallingNumber: function(len) {
if (DEBUG) this.context.debug("PDU: Going to read Dialling number: " + len);
if (len === 0) {
return "";
}
let GsmPDUHelper = this.context.GsmPDUHelper;
// TOA = TON + NPI
let toa = GsmPDUHelper.readHexOctet();
let number = GsmPDUHelper.readSwappedNibbleExtendedBcdString(len - 1);
if (number.length <= 0) {
if (DEBUG) this.context.debug("No number provided");
return "";
}
if ((toa >> 4) == (PDU_TOA_INTERNATIONAL >> 4)) {
number = '+' + number;
}
return number;
},
/**
* Write Dialling Number.
*
* @param number The Dialling number
*/
writeDiallingNumber: function(number) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let toa = PDU_TOA_ISDN; // 81
if (number[0] == '+') {
toa = PDU_TOA_INTERNATIONAL | PDU_TOA_ISDN; // 91
number = number.substring(1);
}
GsmPDUHelper.writeHexOctet(toa);
GsmPDUHelper.writeSwappedNibbleBCD(number);
},
readNumberWithLength: function() {
let Buf = this.context.Buf;
let number = "";
let numLen = this.context.GsmPDUHelper.readHexOctet();
if (numLen != 0xff) {
if (numLen > ADN_MAX_BCD_NUMBER_BYTES) {
if (DEBUG) {
this.context.debug(
"Error: invalid length of BCD number/SSC contents - " + numLen);
}
Buf.seekIncoming(ADN_MAX_BCD_NUMBER_BYTES * Buf.PDU_HEX_OCTET_SIZE);
return number;
}
number = this.readDiallingNumber(numLen);
Buf.seekIncoming((ADN_MAX_BCD_NUMBER_BYTES - numLen) * Buf.PDU_HEX_OCTET_SIZE);
} else {
Buf.seekIncoming(ADN_MAX_BCD_NUMBER_BYTES * Buf.PDU_HEX_OCTET_SIZE);
}
return number;
},
/**
* Write Number with Length
*
* @param number The value to be written.
*
* @return The number has been written into Buf.
*/
writeNumberWithLength: function(number) {
let GsmPDUHelper = this.context.GsmPDUHelper;
if (number) {
let numStart = number[0] == "+" ? 1 : 0;
let writtenNumber = number.substring(0, numStart) +
number.substring(numStart)
.replace(/[^0-9*#,]/g, "");
let numDigits = writtenNumber.length - numStart;
if (numDigits > ADN_MAX_NUMBER_DIGITS) {
writtenNumber = writtenNumber.substring(0, ADN_MAX_NUMBER_DIGITS + numStart);
numDigits = writtenNumber.length - numStart;
}
// +1 for TON/NPI
let numLen = Math.ceil(numDigits / 2) + 1;
GsmPDUHelper.writeHexOctet(numLen);
this.writeDiallingNumber(writtenNumber.replace(/\*/g, "a")
.replace(/\#/g, "b")
.replace(/\,/g, "c"));
// Write trailing 0xff of Dialling Number.
for (let i = 0; i < ADN_MAX_BCD_NUMBER_BYTES - numLen; i++) {
GsmPDUHelper.writeHexOctet(0xff);
}
return writtenNumber;
} else {
// +1 for numLen
for (let i = 0; i < ADN_MAX_BCD_NUMBER_BYTES + 1; i++) {
GsmPDUHelper.writeHexOctet(0xff);
}
return null;
}
}
};
function StkCommandParamsFactoryObject(aContext) {
this.context = aContext;
}
StkCommandParamsFactoryObject.prototype = {
context: null,
createParam: function(cmdDetails, ctlvs, onComplete) {
let method = this[cmdDetails.typeOfCommand];
if (typeof method != "function") {
if (DEBUG) {
this.context.debug("Unknown proactive command " +
cmdDetails.typeOfCommand.toString(16));
}
return;
}
method.call(this, cmdDetails, ctlvs, onComplete);
},
loadIcons: function(iconIdCtlvs, callback) {
if (!iconIdCtlvs ||
!this.context.ICCUtilsHelper.isICCServiceAvailable("IMG")) {
callback(null);
return;
}
let onerror = (function() {
callback(null);
}).bind(this);
let onsuccess = (function(aIcons) {
callback(aIcons);
}).bind(this);
this.context.IconLoader.loadIcons(iconIdCtlvs.map(aCtlv => aCtlv.value.identifier),
onsuccess,
onerror);
},
appendIconIfNecessary: function(iconIdCtlvs, result, onComplete) {
this.loadIcons(iconIdCtlvs, (aIcons) => {
if (aIcons) {
result.icons = aIcons[0];
result.iconSelfExplanatory =
iconIdCtlvs[0].value.qualifier == 0 ? true : false;
}
onComplete(result);
});
},
/**
* Construct a param for Refresh.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processRefresh: function(cmdDetails, ctlvs, onComplete) {
let refreshType = cmdDetails.commandQualifier;
switch (refreshType) {
case STK_REFRESH_FILE_CHANGE:
case STK_REFRESH_NAA_INIT_AND_FILE_CHANGE:
let ctlv = this.context.StkProactiveCmdHelper.searchForTag(
COMPREHENSIONTLV_TAG_FILE_LIST, ctlvs);
if (ctlv) {
let list = ctlv.value.fileList;
if (DEBUG) {
this.context.debug("Refresh, list = " + list);
}
this.context.ICCRecordHelper.fetchICCRecords();
}
break;
}
onComplete(null);
},
/**
* Construct a param for Poll Interval.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processPollInterval: function(cmdDetails, ctlvs, onComplete) {
// Duration is mandatory.
let ctlv = this.context.StkProactiveCmdHelper.searchForTag(
COMPREHENSIONTLV_TAG_DURATION, ctlvs);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Poll Interval: Required value missing : Duration");
}
onComplete(ctlv.value);
},
/**
* Construct a param for Poll Off.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processPollOff: function(cmdDetails, ctlvs, onComplete) {
onComplete(null);
},
/**
* Construct a param for Set Up Event list.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processSetUpEventList: function(cmdDetails, ctlvs, onComplete) {
// Event list is mandatory.
let ctlv = this.context.StkProactiveCmdHelper.searchForTag(
COMPREHENSIONTLV_TAG_EVENT_LIST, ctlvs);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Event List: Required value missing : Event List");
}
onComplete(ctlv.value || { eventList: null });
},
/**
* Construct a param for Setup Menu.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processSetupMenu: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let menu = {
// Help information available.
isHelpAvailable: !!(cmdDetails.commandQualifier & 0x80)
};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_ALPHA_ID,
COMPREHENSIONTLV_TAG_ITEM,
COMPREHENSIONTLV_TAG_ITEM_ID,
COMPREHENSIONTLV_TAG_NEXT_ACTION_IND,
COMPREHENSIONTLV_TAG_ICON_ID,
COMPREHENSIONTLV_TAG_ICON_ID_LIST
]);
// Alpha identifier is optional.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ALPHA_ID);
if (ctlv) {
menu.title = ctlv.value.identifier;
}
// Item data object for item 1 is mandatory.
let menuCtlvs = selectedCtlvs[COMPREHENSIONTLV_TAG_ITEM];
if (!menuCtlvs) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Menu: Required value missing : items");
}
menu.items = menuCtlvs.map(aCtlv => aCtlv.value);
// Item identifier is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ITEM_ID);
if (ctlv) {
menu.defaultItem = ctlv.value.identifier - 1;
}
// Items next action indicator is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_NEXT_ACTION_IND);
if (ctlv) {
menu.nextActionList = ctlv.value;
}
// Icon identifier is optional.
let iconIdCtlvs = null;
let menuIconCtlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ICON_ID);
if (menuIconCtlv) {
iconIdCtlvs = [menuIconCtlv];
}
// Item icon identifier list is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ICON_ID_LIST);
if (ctlv) {
if (!iconIdCtlvs) {
iconIdCtlvs = [];
};
let iconIdList = ctlv.value;
iconIdCtlvs = iconIdCtlvs.concat(iconIdList.identifiers.map((aId) => {
return {
value: { qualifier: iconIdList.qualifier, identifier: aId }
};
}));
}
this.loadIcons(iconIdCtlvs, (aIcons) => {
if (aIcons) {
if (menuIconCtlv) {
menu.iconSelfExplanatory =
(iconIdCtlvs.shift().value.qualifier == 0) ? true: false;
menu.icons = aIcons.shift();
}
for (let i = 0; i < aIcons.length; i++) {
menu.items[i].icons = aIcons[i];
menu.items[i].iconSelfExplanatory =
(iconIdCtlvs[i].value.qualifier == 0) ? true: false;
}
}
onComplete(menu);
});
},
/**
* Construct a param for Select Item.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processSelectItem: function(cmdDetails, ctlvs, onComplete) {
this.processSetupMenu(cmdDetails, ctlvs, (menu) => {
// The 1st bit and 2nd bit determines the presentation type.
menu.presentationType = cmdDetails.commandQualifier & 0x03;
onComplete(menu);
});
},
/**
* Construct a param for Display Text.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processDisplayText: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let textMsg = {
isHighPriority: !!(cmdDetails.commandQualifier & 0x01),
userClear: !!(cmdDetails.commandQualifier & 0x80)
};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_TEXT_STRING,
COMPREHENSIONTLV_TAG_IMMEDIATE_RESPONSE,
COMPREHENSIONTLV_TAG_DURATION,
COMPREHENSIONTLV_TAG_ICON_ID
]);
// Text string is mandatory.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_TEXT_STRING);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Display Text: Required value missing : Text String");
}
textMsg.text = ctlv.value.textString;
// Immediate response is optional.
textMsg.responseNeeded =
!!(selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_IMMEDIATE_RESPONSE));
// Duration is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_DURATION);
if (ctlv) {
textMsg.duration = ctlv.value;
}
// Icon identifier is optional.
this.appendIconIfNecessary(selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null,
textMsg,
onComplete);
},
/**
* Construct a param for Setup Idle Mode Text.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processSetUpIdleModeText: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let textMsg = {};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_TEXT_STRING,
COMPREHENSIONTLV_TAG_ICON_ID
]);
// Text string is mandatory.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_TEXT_STRING);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Set Up Idle Text: Required value missing : Text String");
}
textMsg.text = ctlv.value.textString;
// Icon identifier is optional.
this.appendIconIfNecessary(selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null,
textMsg,
onComplete);
},
/**
* Construct a param for Get Inkey.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processGetInkey: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let input = {
minLength: 1,
maxLength: 1,
isAlphabet: !!(cmdDetails.commandQualifier & 0x01),
isUCS2: !!(cmdDetails.commandQualifier & 0x02),
// Character sets defined in bit 1 and bit 2 are disable and
// the YES/NO reponse is required.
isYesNoRequested: !!(cmdDetails.commandQualifier & 0x04),
// Help information available.
isHelpAvailable: !!(cmdDetails.commandQualifier & 0x80)
};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_TEXT_STRING,
COMPREHENSIONTLV_TAG_DURATION,
COMPREHENSIONTLV_TAG_ICON_ID
]);
// Text string is mandatory.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_TEXT_STRING);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Get InKey: Required value missing : Text String");
}
input.text = ctlv.value.textString;
// Duration is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_DURATION);
if (ctlv) {
input.duration = ctlv.value;
}
// Icon identifier is optional.
this.appendIconIfNecessary(selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null,
input,
onComplete);
},
/**
* Construct a param for Get Input.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processGetInput: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let input = {
isAlphabet: !!(cmdDetails.commandQualifier & 0x01),
isUCS2: !!(cmdDetails.commandQualifier & 0x02),
// User input shall not be revealed
hideInput: !!(cmdDetails.commandQualifier & 0x04),
// User input in SMS packed format
isPacked: !!(cmdDetails.commandQualifier & 0x08),
// Help information available.
isHelpAvailable: !!(cmdDetails.commandQualifier & 0x80)
};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_TEXT_STRING,
COMPREHENSIONTLV_TAG_RESPONSE_LENGTH,
COMPREHENSIONTLV_TAG_DEFAULT_TEXT,
COMPREHENSIONTLV_TAG_ICON_ID
]);
// Text string is mandatory.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_TEXT_STRING);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Get Input: Required value missing : Text String");
}
input.text = ctlv.value.textString;
// Response length is mandatory.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_RESPONSE_LENGTH);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Get Input: Required value missing : Response Length");
}
input.minLength = ctlv.value.minLength;
input.maxLength = ctlv.value.maxLength;
// Default text is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_DEFAULT_TEXT);
if (ctlv) {
input.defaultText = ctlv.value.textString;
}
// Icon identifier is optional.
this.appendIconIfNecessary(selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null,
input,
onComplete);
},
/**
* Construct a param for SendSS/SMS/USSD/DTMF.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processEventNotify: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let textMsg = {};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_ALPHA_ID,
COMPREHENSIONTLV_TAG_ICON_ID
]);
// Alpha identifier is optional.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ALPHA_ID);
if (ctlv) {
textMsg.text = ctlv.value.identifier;
}
// According to section 6.4.10 of |ETSI TS 102 223|:
//
// - if the alpha identifier is provided by the UICC and is a null data
// object (i.e. length = '00' and no value part), this is an indication
// that the terminal should not give any information to the user on the
// fact that the terminal is sending a short message;
//
// - if the alpha identifier is not provided by the UICC, the terminal may
// give information to the user concerning what is happening.
//
// ICCPDUHelper reads alpha id as an empty string if the length is zero,
// hence we'll notify the caller when it's not an empty string.
if (textMsg.text !== "") {
// Icon identifier is optional.
this.appendIconIfNecessary(selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null,
textMsg,
onComplete);
}
},
/**
* Construct a param for Setup Call.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processSetupCall: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let call = {};
let confirmMessage = {};
let callMessage = {};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_ADDRESS,
COMPREHENSIONTLV_TAG_ALPHA_ID,
COMPREHENSIONTLV_TAG_ICON_ID,
COMPREHENSIONTLV_TAG_DURATION
]);
// Address is mandatory.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ADDRESS);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Set Up Call: Required value missing : Address");
}
call.address = ctlv.value.number;
// Alpha identifier (user confirmation phase) is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ALPHA_ID);
if (ctlv) {
confirmMessage.text = ctlv.value.identifier;
call.confirmMessage = confirmMessage;
}
// Alpha identifier (call set up phase) is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ALPHA_ID);
if (ctlv) {
callMessage.text = ctlv.value.identifier;
call.callMessage = callMessage;
}
// Duration is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_DURATION);
if (ctlv) {
call.duration = ctlv.value;
}
// Icon identifier is optional.
let iconIdCtlvs = selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null;
this.loadIcons(iconIdCtlvs, (aIcons) => {
if (aIcons) {
confirmMessage.icons = aIcons[0];
confirmMessage.iconSelfExplanatory =
(iconIdCtlvs[0].value.qualifier == 0) ? true: false;
call.confirmMessage = confirmMessage;
if (aIcons.length > 1) {
callMessage.icons = aIcons[1];
callMessage.iconSelfExplanatory =
(iconIdCtlvs[1].value.qualifier == 0) ? true: false;
call.callMessage = callMessage;
}
}
onComplete(call);
});
},
/**
* Construct a param for Launch Browser.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processLaunchBrowser: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let browser = {
mode: cmdDetails.commandQualifier & 0x03
};
let confirmMessage = {};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_URL,
COMPREHENSIONTLV_TAG_ALPHA_ID,
COMPREHENSIONTLV_TAG_ICON_ID
]);
// URL is mandatory.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_URL);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Launch Browser: Required value missing : URL");
}
browser.url = ctlv.value.url;
// Alpha identifier is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ALPHA_ID);
if (ctlv) {
confirmMessage.text = ctlv.value.identifier;
browser.confirmMessage = confirmMessage;
}
// Icon identifier is optional.
let iconIdCtlvs = selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null;
this.loadIcons(iconIdCtlvs, (aIcons) => {
if (aIcons) {
confirmMessage.icons = aIcons[0];
confirmMessage.iconSelfExplanatory =
(iconIdCtlvs[0].value.qualifier == 0) ? true: false;
browser.confirmMessage = confirmMessage;
}
onComplete(browser);
});
},
/**
* Construct a param for Play Tone.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processPlayTone: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let playTone = {
// The vibrate is only defined in TS 102.223.
isVibrate: !!(cmdDetails.commandQualifier & 0x01)
};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_ALPHA_ID,
COMPREHENSIONTLV_TAG_TONE,
COMPREHENSIONTLV_TAG_DURATION,
COMPREHENSIONTLV_TAG_ICON_ID
]);
// Alpha identifier is optional.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ALPHA_ID);
if (ctlv) {
playTone.text = ctlv.value.identifier;
}
// Tone is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_TONE);
if (ctlv) {
playTone.tone = ctlv.value.tone;
}
// Duration is optional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_DURATION);
if (ctlv) {
playTone.duration = ctlv.value;
}
// Icon identifier is optional.
this.appendIconIfNecessary(selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null,
playTone,
onComplete);
},
/**
* Construct a param for Provide Local Information.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processProvideLocalInfo: function(cmdDetails, ctlvs, onComplete) {
let provideLocalInfo = {
localInfoType: cmdDetails.commandQualifier
};
onComplete(provideLocalInfo);
},
/**
* Construct a param for Timer Management.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processTimerManagement: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let timer = {
timerAction: cmdDetails.commandQualifier
};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_TIMER_IDENTIFIER,
COMPREHENSIONTLV_TAG_TIMER_VALUE
]);
// Timer identifier is mandatory.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_TIMER_IDENTIFIER);
if (!ctlv) {
this.context.RIL.sendStkTerminalResponse({
command: cmdDetails,
resultCode: STK_RESULT_REQUIRED_VALUES_MISSING});
throw new Error("Stk Timer Management: Required value missing : Timer Identifier");
}
timer.timerId = ctlv.value.timerId;
// Timer value is conditional.
ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_TIMER_VALUE);
if (ctlv) {
timer.timerValue = ctlv.value.timerValue;
}
onComplete(timer);
},
/**
* Construct a param for BIP commands.
*
* @param cmdDetails
* The value object of CommandDetails TLV.
* @param ctlvs
* The all TLVs in this proactive command.
* @param onComplete
* Callback to be called when complete.
*/
processBipMessage: function(cmdDetails, ctlvs, onComplete) {
let StkProactiveCmdHelper = this.context.StkProactiveCmdHelper;
let bipMsg = {};
let selectedCtlvs = StkProactiveCmdHelper.searchForSelectedTags(ctlvs, [
COMPREHENSIONTLV_TAG_ALPHA_ID,
COMPREHENSIONTLV_TAG_ICON_ID
]);
// Alpha identifier is optional.
let ctlv = selectedCtlvs.retrieve(COMPREHENSIONTLV_TAG_ALPHA_ID);
if (ctlv) {
bipMsg.text = ctlv.value.identifier;
}
// Icon identifier is optional.
this.appendIconIfNecessary(selectedCtlvs[COMPREHENSIONTLV_TAG_ICON_ID] || null,
bipMsg,
onComplete);
}
};
StkCommandParamsFactoryObject.prototype[STK_CMD_REFRESH] = function STK_CMD_REFRESH(cmdDetails, ctlvs, onComplete) {
return this.processRefresh(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_POLL_INTERVAL] = function STK_CMD_POLL_INTERVAL(cmdDetails, ctlvs, onComplete) {
return this.processPollInterval(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_POLL_OFF] = function STK_CMD_POLL_OFF(cmdDetails, ctlvs, onComplete) {
return this.processPollOff(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_PROVIDE_LOCAL_INFO] = function STK_CMD_PROVIDE_LOCAL_INFO(cmdDetails, ctlvs, onComplete) {
return this.processProvideLocalInfo(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SET_UP_EVENT_LIST] = function STK_CMD_SET_UP_EVENT_LIST(cmdDetails, ctlvs, onComplete) {
return this.processSetUpEventList(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SET_UP_MENU] = function STK_CMD_SET_UP_MENU(cmdDetails, ctlvs, onComplete) {
return this.processSetupMenu(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SELECT_ITEM] = function STK_CMD_SELECT_ITEM(cmdDetails, ctlvs, onComplete) {
return this.processSelectItem(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_DISPLAY_TEXT] = function STK_CMD_DISPLAY_TEXT(cmdDetails, ctlvs, onComplete) {
return this.processDisplayText(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SET_UP_IDLE_MODE_TEXT] = function STK_CMD_SET_UP_IDLE_MODE_TEXT(cmdDetails, ctlvs, onComplete) {
return this.processSetUpIdleModeText(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_GET_INKEY] = function STK_CMD_GET_INKEY(cmdDetails, ctlvs, onComplete) {
return this.processGetInkey(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_GET_INPUT] = function STK_CMD_GET_INPUT(cmdDetails, ctlvs, onComplete) {
return this.processGetInput(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SEND_SS] = function STK_CMD_SEND_SS(cmdDetails, ctlvs, onComplete) {
return this.processEventNotify(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SEND_USSD] = function STK_CMD_SEND_USSD(cmdDetails, ctlvs, onComplete) {
return this.processEventNotify(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SEND_SMS] = function STK_CMD_SEND_SMS(cmdDetails, ctlvs, onComplete) {
return this.processEventNotify(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SEND_DTMF] = function STK_CMD_SEND_DTMF(cmdDetails, ctlvs, onComplete) {
return this.processEventNotify(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SET_UP_CALL] = function STK_CMD_SET_UP_CALL(cmdDetails, ctlvs, onComplete) {
return this.processSetupCall(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_LAUNCH_BROWSER] = function STK_CMD_LAUNCH_BROWSER(cmdDetails, ctlvs, onComplete) {
return this.processLaunchBrowser(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_PLAY_TONE] = function STK_CMD_PLAY_TONE(cmdDetails, ctlvs, onComplete) {
return this.processPlayTone(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_TIMER_MANAGEMENT] = function STK_CMD_TIMER_MANAGEMENT(cmdDetails, ctlvs, onComplete) {
return this.processTimerManagement(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_OPEN_CHANNEL] = function STK_CMD_OPEN_CHANNEL(cmdDetails, ctlvs, onComplete) {
return this.processBipMessage(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_CLOSE_CHANNEL] = function STK_CMD_CLOSE_CHANNEL(cmdDetails, ctlvs, onComplete) {
return this.processBipMessage(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_RECEIVE_DATA] = function STK_CMD_RECEIVE_DATA(cmdDetails, ctlvs, onComplete) {
return this.processBipMessage(cmdDetails, ctlvs, onComplete);
};
StkCommandParamsFactoryObject.prototype[STK_CMD_SEND_DATA] = function STK_CMD_SEND_DATA(cmdDetails, ctlvs, onComplete) {
return this.processBipMessage(cmdDetails, ctlvs, onComplete);
};
function StkProactiveCmdHelperObject(aContext) {
this.context = aContext;
}
StkProactiveCmdHelperObject.prototype = {
context: null,
retrieve: function(tag, length) {
let method = this[tag];
if (typeof method != "function") {
if (DEBUG) {
this.context.debug("Unknown comprehension tag " + tag.toString(16));
}
let Buf = this.context.Buf;
Buf.seekIncoming(length * Buf.PDU_HEX_OCTET_SIZE);
return null;
}
return method.call(this, length);
},
/**
* Command Details.
*
* | Byte | Description | Length |
* | 1 | Command details Tag | 1 |
* | 2 | Length = 03 | 1 |
* | 3 | Command number | 1 |
* | 4 | Type of Command | 1 |
* | 5 | Command Qualifier | 1 |
*/
retrieveCommandDetails: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let cmdDetails = {
commandNumber: GsmPDUHelper.readHexOctet(),
typeOfCommand: GsmPDUHelper.readHexOctet(),
commandQualifier: GsmPDUHelper.readHexOctet()
};
return cmdDetails;
},
/**
* Device Identities.
*
* | Byte | Description | Length |
* | 1 | Device Identity Tag | 1 |
* | 2 | Length = 02 | 1 |
* | 3 | Source device Identity | 1 |
* | 4 | Destination device Id | 1 |
*/
retrieveDeviceId: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let deviceId = {
sourceId: GsmPDUHelper.readHexOctet(),
destinationId: GsmPDUHelper.readHexOctet()
};
return deviceId;
},
/**
* Alpha Identifier.
*
* | Byte | Description | Length |
* | 1 | Alpha Identifier Tag | 1 |
* | 2 ~ (Y-1)+2 | Length (X) | Y |
* | (Y-1)+3 ~ | Alpha identfier | X |
* | (Y-1)+X+2 | | |
*/
retrieveAlphaId: function(length) {
let alphaId = {
identifier: this.context.ICCPDUHelper.readAlphaIdentifier(length)
};
return alphaId;
},
/**
* Duration.
*
* | Byte | Description | Length |
* | 1 | Response Length Tag | 1 |
* | 2 | Lenth = 02 | 1 |
* | 3 | Time unit | 1 |
* | 4 | Time interval | 1 |
*/
retrieveDuration: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let duration = {
timeUnit: GsmPDUHelper.readHexOctet(),
timeInterval: GsmPDUHelper.readHexOctet(),
};
return duration;
},
/**
* Address.
*
* | Byte | Description | Length |
* | 1 | Alpha Identifier Tag | 1 |
* | 2 ~ (Y-1)+2 | Length (X) | Y |
* | (Y-1)+3 | TON and NPI | 1 |
* | (Y-1)+4 ~ | Dialling number | X |
* | (Y-1)+X+2 | | |
*/
retrieveAddress: function(length) {
let address = {
number : this.context.ICCPDUHelper.readDiallingNumber(length)
};
return address;
},
/**
* Text String.
*
* | Byte | Description | Length |
* | 1 | Text String Tag | 1 |
* | 2 ~ (Y-1)+2 | Length (X) | Y |
* | (Y-1)+3 | Data coding scheme | 1 |
* | (Y-1)+4~ | Text String | X |
* | (Y-1)+X+2 | | |
*/
retrieveTextString: function(length) {
if (!length) {
// null string.
return {textString: null};
}
let GsmPDUHelper = this.context.GsmPDUHelper;
let text = {
codingScheme: GsmPDUHelper.readHexOctet()
};
length--; // -1 for the codingScheme.
switch (text.codingScheme & 0x0c) {
case STK_TEXT_CODING_GSM_7BIT_PACKED:
text.textString =
GsmPDUHelper.readSeptetsToString(Math.floor(length * 8 / 7), 0, 0, 0);
break;
case STK_TEXT_CODING_GSM_8BIT:
text.textString =
this.context.ICCPDUHelper.read8BitUnpackedToString(length);
break;
case STK_TEXT_CODING_UCS2:
text.textString = GsmPDUHelper.readUCS2String(length);
break;
}
return text;
},
/**
* Tone.
*
* | Byte | Description | Length |
* | 1 | Tone Tag | 1 |
* | 2 | Lenth = 01 | 1 |
* | 3 | Tone | 1 |
*/
retrieveTone: function(length) {
let tone = {
tone: this.context.GsmPDUHelper.readHexOctet(),
};
return tone;
},
/**
* Item.
*
* | Byte | Description | Length |
* | 1 | Item Tag | 1 |
* | 2 ~ (Y-1)+2 | Length (X) | Y |
* | (Y-1)+3 | Identifier of item | 1 |
* | (Y-1)+4 ~ | Text string of item | X |
* | (Y-1)+X+2 | | |
*/
retrieveItem: function(length) {
// TS 102.223 ,clause 6.6.7 SET-UP MENU
// If the "Item data object for item 1" is a null data object
// (i.e. length = '00' and no value part), this is an indication to the ME
// to remove the existing menu from the menu system in the ME.
if (!length) {
return null;
}
let item = {
identifier: this.context.GsmPDUHelper.readHexOctet(),
text: this.context.ICCPDUHelper.readAlphaIdentifier(length - 1)
};
return item;
},
/**
* Item Identifier.
*
* | Byte | Description | Length |
* | 1 | Item Identifier Tag | 1 |
* | 2 | Lenth = 01 | 1 |
* | 3 | Identifier of Item chosen | 1 |
*/
retrieveItemId: function(length) {
let itemId = {
identifier: this.context.GsmPDUHelper.readHexOctet()
};
return itemId;
},
/**
* Response Length.
*
* | Byte | Description | Length |
* | 1 | Response Length Tag | 1 |
* | 2 | Lenth = 02 | 1 |
* | 3 | Minimum length of response | 1 |
* | 4 | Maximum length of response | 1 |
*/
retrieveResponseLength: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let rspLength = {
minLength : GsmPDUHelper.readHexOctet(),
maxLength : GsmPDUHelper.readHexOctet()
};
return rspLength;
},
/**
* File List.
*
* | Byte | Description | Length |
* | 1 | File List Tag | 1 |
* | 2 ~ (Y-1)+2 | Length (X) | Y |
* | (Y-1)+3 | Number of files | 1 |
* | (Y-1)+4 ~ | Files | X |
* | (Y-1)+X+2 | | |
*/
retrieveFileList: function(length) {
let num = this.context.GsmPDUHelper.readHexOctet();
let fileList = "";
length--; // -1 for the num octet.
for (let i = 0; i < 2 * length; i++) {
// Didn't use readHexOctet here,
// otherwise 0x00 will be "0", not "00"
fileList += String.fromCharCode(this.context.Buf.readUint16());
}
return {
fileList: fileList
};
},
/**
* Default Text.
*
* Same as Text String.
*/
retrieveDefaultText: function(length) {
return this.retrieveTextString(length);
},
/**
* Event List.
*/
retrieveEventList: function(length) {
if (!length) {
// null means an indication to ME to remove the existing list of events
// in ME.
return null;
}
let GsmPDUHelper = this.context.GsmPDUHelper;
let eventList = [];
for (let i = 0; i < length; i++) {
eventList.push(GsmPDUHelper.readHexOctet());
}
return {
eventList: eventList
};
},
/**
* Icon Id.
*
* | Byte | Description | Length |
* | 1 | Icon Identifier Tag | 1 |
* | 2 | Length = 02 | 1 |
* | 3 | Icon qualifier | 1 |
* | 4 | Icon identifier | 1 |
*/
retrieveIconId: function(length) {
if (!length) {
return null;
}
let iconId = {
qualifier: this.context.GsmPDUHelper.readHexOctet(),
identifier: this.context.GsmPDUHelper.readHexOctet()
};
return iconId;
},
/**
* Icon Id List.
*
* | Byte | Description | Length |
* | 1 | Icon Identifier Tag | 1 |
* | 2 | Length = X | 1 |
* | 3 | Icon qualifier | 1 |
* | 4~ | Icon identifier | X-1 |
* | 4+X-2 | | |
*/
retrieveIconIdList: function(length) {
if (!length) {
return null;
}
let iconIdList = {
qualifier: this.context.GsmPDUHelper.readHexOctet(),
identifiers: []
};
for (let i = 0; i < length - 1; i++) {
iconIdList.identifiers.push(this.context.GsmPDUHelper.readHexOctet());
}
return iconIdList;
},
/**
* Timer Identifier.
*
* | Byte | Description | Length |
* | 1 | Timer Identifier Tag | 1 |
* | 2 | Length = 01 | 1 |
* | 3 | Timer Identifier | 1 |
*/
retrieveTimerId: function(length) {
let id = {
timerId: this.context.GsmPDUHelper.readHexOctet()
};
return id;
},
/**
* Timer Value.
*
* | Byte | Description | Length |
* | 1 | Timer Value Tag | 1 |
* | 2 | Length = 03 | 1 |
* | 3 | Hour | 1 |
* | 4 | Minute | 1 |
* | 5 | Second | 1 |
*/
retrieveTimerValue: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let value = {
timerValue: (GsmPDUHelper.readSwappedNibbleBcdNum(1) * 60 * 60) +
(GsmPDUHelper.readSwappedNibbleBcdNum(1) * 60) +
(GsmPDUHelper.readSwappedNibbleBcdNum(1))
};
return value;
},
/**
* Immediate Response.
*
* | Byte | Description | Length |
* | 1 | Immediate Response Tag | 1 |
* | 2 | Length = 00 | 1 |
*/
retrieveImmediaResponse: function(length) {
return {};
},
/**
* URL
*
* | Byte | Description | Length |
* | 1 | URL Tag | 1 |
* | 2 ~ (Y+1) | Length(X) | Y |
* | (Y+2) ~ | URL | X |
* | (Y+1+X) | | |
*/
retrieveUrl: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let s = "";
for (let i = 0; i < length; i++) {
s += String.fromCharCode(GsmPDUHelper.readHexOctet());
}
return {url: s};
},
/**
* Next Action Indicator List.
*
* | Byte | Description | Length |
* | 1 | Next Action tag | 1 |
* | 1 | Length(X) | 1 |
* | 3~ | Next Action List | X |
* | 3+X-1 | | |
*/
retrieveNextActionList: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let nextActionList = [];
for (let i = 0; i < length; i++) {
nextActionList.push(GsmPDUHelper.readHexOctet());
}
return nextActionList;
},
searchForTag: function(tag, ctlvs) {
let iter = Iterator(ctlvs);
for (let [index, ctlv] in iter) {
if ((ctlv.tag & ~COMPREHENSIONTLV_FLAG_CR) == tag) {
return ctlv;
}
}
return null;
},
searchForSelectedTags: function(ctlvs, tags) {
let ret = {
// Handy utility to de-queue the 1st ctlv of the specified tag.
retrieve: function(aTag) {
return (this[aTag]) ? this[aTag].shift() : null;
}
};
ctlvs.forEach((aCtlv) => {
tags.forEach((aTag) => {
if ((aCtlv.tag & ~COMPREHENSIONTLV_FLAG_CR) == aTag) {
if (!ret[aTag]) {
ret[aTag] = [];
}
ret[aTag].push(aCtlv);
}
});
});
return ret;
},
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_COMMAND_DETAILS] = function COMPREHENSIONTLV_TAG_COMMAND_DETAILS(length) {
return this.retrieveCommandDetails(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_DEVICE_ID] = function COMPREHENSIONTLV_TAG_DEVICE_ID(length) {
return this.retrieveDeviceId(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_ALPHA_ID] = function COMPREHENSIONTLV_TAG_ALPHA_ID(length) {
return this.retrieveAlphaId(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_DURATION] = function COMPREHENSIONTLV_TAG_DURATION(length) {
return this.retrieveDuration(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_ADDRESS] = function COMPREHENSIONTLV_TAG_ADDRESS(length) {
return this.retrieveAddress(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_TEXT_STRING] = function COMPREHENSIONTLV_TAG_TEXT_STRING(length) {
return this.retrieveTextString(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_TONE] = function COMPREHENSIONTLV_TAG_TONE(length) {
return this.retrieveTone(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_ITEM] = function COMPREHENSIONTLV_TAG_ITEM(length) {
return this.retrieveItem(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_ITEM_ID] = function COMPREHENSIONTLV_TAG_ITEM_ID(length) {
return this.retrieveItemId(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_RESPONSE_LENGTH] = function COMPREHENSIONTLV_TAG_RESPONSE_LENGTH(length) {
return this.retrieveResponseLength(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_FILE_LIST] = function COMPREHENSIONTLV_TAG_FILE_LIST(length) {
return this.retrieveFileList(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_DEFAULT_TEXT] = function COMPREHENSIONTLV_TAG_DEFAULT_TEXT(length) {
return this.retrieveDefaultText(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_EVENT_LIST] = function COMPREHENSIONTLV_TAG_EVENT_LIST(length) {
return this.retrieveEventList(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_ICON_ID] = function COMPREHENSIONTLV_TAG_ICON_ID(length) {
return this.retrieveIconId(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_ICON_ID_LIST] = function COMPREHENSIONTLV_TAG_ICON_ID_LIST(length) {
return this.retrieveIconIdList(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_TIMER_IDENTIFIER] = function COMPREHENSIONTLV_TAG_TIMER_IDENTIFIER(length) {
return this.retrieveTimerId(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_TIMER_VALUE] = function COMPREHENSIONTLV_TAG_TIMER_VALUE(length) {
return this.retrieveTimerValue(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_IMMEDIATE_RESPONSE] = function COMPREHENSIONTLV_TAG_IMMEDIATE_RESPONSE(length) {
return this.retrieveImmediaResponse(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_URL] = function COMPREHENSIONTLV_TAG_URL(length) {
return this.retrieveUrl(length);
};
StkProactiveCmdHelperObject.prototype[COMPREHENSIONTLV_TAG_NEXT_ACTION_IND] = function COMPREHENSIONTLV_TAG_NEXT_ACTION_IND(length) {
return this.retrieveNextActionList(length);
};
function ComprehensionTlvHelperObject(aContext) {
this.context = aContext;
}
ComprehensionTlvHelperObject.prototype = {
context: null,
/**
* Decode raw data to a Comprehension-TLV.
*/
decode: function() {
let GsmPDUHelper = this.context.GsmPDUHelper;
let hlen = 0; // For header(tag field + length field) length.
let temp = GsmPDUHelper.readHexOctet();
hlen++;
// TS 101.220, clause 7.1.1
let tag, cr;
switch (temp) {
// TS 101.220, clause 7.1.1
case 0x0: // Not used.
case 0xff: // Not used.
case 0x80: // Reserved for future use.
throw new Error("Invalid octet when parsing Comprehension TLV :" + temp);
case 0x7f: // Tag is three byte format.
// TS 101.220 clause 7.1.1.2.
// | Byte 1 | Byte 2 | Byte 3 |
// | | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | |
// | 0x7f |CR | Tag Value |
tag = (GsmPDUHelper.readHexOctet() << 8) | GsmPDUHelper.readHexOctet();
hlen += 2;
cr = (tag & 0x8000) !== 0;
tag &= ~0x8000;
break;
default: // Tag is single byte format.
tag = temp;
// TS 101.220 clause 7.1.1.1.
// | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 |
// |CR | Tag Value |
cr = (tag & 0x80) !== 0;
tag &= ~0x80;
}
// TS 101.220 clause 7.1.2, Length Encoding.
// Length | Byte 1 | Byte 2 | Byte 3 | Byte 4 |
// 0 - 127 | 00 - 7f | N/A | N/A | N/A |
// 128-255 | 81 | 80 - ff| N/A | N/A |
// 256-65535| 82 | 0100 - ffff | N/A |
// 65536- | 83 | 010000 - ffffff |
// 16777215
//
// Length errors: TS 11.14, clause 6.10.6
let length; // Data length.
temp = GsmPDUHelper.readHexOctet();
hlen++;
if (temp < 0x80) {
length = temp;
} else if (temp == 0x81) {
length = GsmPDUHelper.readHexOctet();
hlen++;
if (length < 0x80) {
throw new Error("Invalid length in Comprehension TLV :" + length);
}
} else if (temp == 0x82) {
length = (GsmPDUHelper.readHexOctet() << 8) | GsmPDUHelper.readHexOctet();
hlen += 2;
if (lenth < 0x0100) {
throw new Error("Invalid length in 3-byte Comprehension TLV :" + length);
}
} else if (temp == 0x83) {
length = (GsmPDUHelper.readHexOctet() << 16) |
(GsmPDUHelper.readHexOctet() << 8) |
GsmPDUHelper.readHexOctet();
hlen += 3;
if (length < 0x010000) {
throw new Error("Invalid length in 4-byte Comprehension TLV :" + length);
}
} else {
throw new Error("Invalid octet in Comprehension TLV :" + temp);
}
let ctlv = {
tag: tag,
length: length,
value: this.context.StkProactiveCmdHelper.retrieve(tag, length),
cr: cr,
hlen: hlen
};
return ctlv;
},
decodeChunks: function(length) {
let chunks = [];
let index = 0;
while (index < length) {
let tlv = this.decode();
chunks.push(tlv);
index += tlv.length;
index += tlv.hlen;
}
return chunks;
},
/**
* Write Location Info Comprehension TLV.
*
* @param loc location Information.
*/
writeLocationInfoTlv: function(loc) {
let GsmPDUHelper = this.context.GsmPDUHelper;
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_LOCATION_INFO |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(loc.gsmCellId > 0xffff ? 9 : 7);
// From TS 11.14, clause 12.19
// "The mobile country code (MCC), the mobile network code (MNC),
// the location area code (LAC) and the cell ID are
// coded as in TS 04.08."
// And from TS 04.08 and TS 24.008,
// the format is as follows:
//
// MCC = MCC_digit_1 + MCC_digit_2 + MCC_digit_3
//
// 8 7 6 5 4 3 2 1
// +-------------+-------------+
// | MCC digit 2 | MCC digit 1 | octet 2
// | MNC digit 3 | MCC digit 3 | octet 3
// | MNC digit 2 | MNC digit 1 | octet 4
// +-------------+-------------+
//
// Also in TS 24.008
// "However a network operator may decide to
// use only two digits in the MNC in the LAI over the
// radio interface. In this case, bits 5 to 8 of octet 3
// shall be coded as '1111'".
// MCC & MNC, 3 octets
let mcc = loc.mcc, mnc;
if (loc.mnc.length == 2) {
mnc = "F" + loc.mnc;
} else {
mnc = loc.mnc[2] + loc.mnc[0] + loc.mnc[1];
}
GsmPDUHelper.writeSwappedNibbleBCD(mcc + mnc);
// LAC, 2 octets
GsmPDUHelper.writeHexOctet((loc.gsmLocationAreaCode >> 8) & 0xff);
GsmPDUHelper.writeHexOctet(loc.gsmLocationAreaCode & 0xff);
// Cell Id
if (loc.gsmCellId > 0xffff) {
// UMTS/WCDMA, gsmCellId is 28 bits.
GsmPDUHelper.writeHexOctet((loc.gsmCellId >> 24) & 0xff);
GsmPDUHelper.writeHexOctet((loc.gsmCellId >> 16) & 0xff);
GsmPDUHelper.writeHexOctet((loc.gsmCellId >> 8) & 0xff);
GsmPDUHelper.writeHexOctet(loc.gsmCellId & 0xff);
} else {
// GSM, gsmCellId is 16 bits.
GsmPDUHelper.writeHexOctet((loc.gsmCellId >> 8) & 0xff);
GsmPDUHelper.writeHexOctet(loc.gsmCellId & 0xff);
}
},
/**
* Given a geckoError string, this function translates it into cause value
* and write the value into buffer.
*
* @param geckoError Error string that is passed to gecko.
*/
writeCauseTlv: function(geckoError) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let cause = -1;
for (let errorNo in RIL_CALL_FAILCAUSE_TO_GECKO_CALL_ERROR) {
if (geckoError == RIL_CALL_FAILCAUSE_TO_GECKO_CALL_ERROR[errorNo]) {
cause = errorNo;
break;
}
}
// Causes specified in 10.5.4.11 of TS 04.08 are less than 128.
// we can ignore causes > 127 since Cause TLV is optional in
// STK_EVENT_TYPE_CALL_DISCONNECTED.
if (cause > 127) {
return;
}
cause = (cause == -1) ? ERROR_SUCCESS : cause;
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_CAUSE |
COMPREHENSIONTLV_FLAG_CR);
GsmPDUHelper.writeHexOctet(2); // For single cause value.
// TS 04.08, clause 10.5.4.11:
// Code Standard : Standard defined for GSM PLMNS
// Location: User
GsmPDUHelper.writeHexOctet(0x60);
// TS 04.08, clause 10.5.4.11: ext bit = 1 + 7 bits for cause.
// +-----------------+----------------------------------+
// | Ext = 1 (1 bit) | Cause (7 bits) |
// +-----------------+----------------------------------+
GsmPDUHelper.writeHexOctet(0x80 | cause);
},
writeDateTimeZoneTlv: function(date) {
let GsmPDUHelper = this.context.GsmPDUHelper;
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_DATE_TIME_ZONE);
GsmPDUHelper.writeHexOctet(7);
GsmPDUHelper.writeTimestamp(date);
},
writeLanguageTlv: function(language) {
let GsmPDUHelper = this.context.GsmPDUHelper;
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_LANGUAGE);
GsmPDUHelper.writeHexOctet(2);
// ISO 639-1, Alpha-2 code
// TS 123.038, clause 6.2.1, GSM 7 bit Default Alphabet
GsmPDUHelper.writeHexOctet(
PDU_NL_LOCKING_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT].indexOf(language[0]));
GsmPDUHelper.writeHexOctet(
PDU_NL_LOCKING_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT].indexOf(language[1]));
},
/**
* Write Timer Value Comprehension TLV.
*
* @param seconds length of time during of the timer.
* @param cr Comprehension Required or not
*/
writeTimerValueTlv: function(seconds, cr) {
let GsmPDUHelper = this.context.GsmPDUHelper;
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_TIMER_VALUE |
(cr ? COMPREHENSIONTLV_FLAG_CR : 0));
GsmPDUHelper.writeHexOctet(3);
// TS 102.223, clause 8.38
// +----------------+------------------+-------------------+
// | hours (1 byte) | minutes (1 btye) | seconds (1 byte) |
// +----------------+------------------+-------------------+
GsmPDUHelper.writeSwappedNibbleBCDNum(Math.floor(seconds / 60 / 60));
GsmPDUHelper.writeSwappedNibbleBCDNum(Math.floor(seconds / 60) % 60);
GsmPDUHelper.writeSwappedNibbleBCDNum(Math.floor(seconds) % 60);
},
writeTextStringTlv: function(text, coding) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let buf = GsmPDUHelper.writeWithBuffer(() => {
// Write Coding.
GsmPDUHelper.writeHexOctet(coding);
// Write Text String.
switch (coding) {
case STK_TEXT_CODING_UCS2:
GsmPDUHelper.writeUCS2String(text);
break;
case STK_TEXT_CODING_GSM_7BIT_PACKED:
GsmPDUHelper.writeStringAsSeptets(text, 0, 0, 0);
break;
case STK_TEXT_CODING_GSM_8BIT:
GsmPDUHelper.writeStringAs8BitUnpacked(text);
break;
}
});
let length = buf.length;
if (length) {
// Write Tag.
GsmPDUHelper.writeHexOctet(COMPREHENSIONTLV_TAG_TEXT_STRING |
COMPREHENSIONTLV_FLAG_CR);
// Write Length.
this.writeLength(length);
// Write Value.
for (let i = 0; i < length; i++) {
GsmPDUHelper.writeHexOctet(buf[i]);
}
}
},
getSizeOfLengthOctets: function(length) {
if (length >= 0x10000) {
return 4; // 0x83, len_1, len_2, len_3
} else if (length >= 0x100) {
return 3; // 0x82, len_1, len_2
} else if (length >= 0x80) {
return 2; // 0x81, len
} else {
return 1; // len
}
},
writeLength: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
// TS 101.220 clause 7.1.2, Length Encoding.
// Length | Byte 1 | Byte 2 | Byte 3 | Byte 4 |
// 0 - 127 | 00 - 7f | N/A | N/A | N/A |
// 128-255 | 81 | 80 - ff| N/A | N/A |
// 256-65535| 82 | 0100 - ffff | N/A |
// 65536- | 83 | 010000 - ffffff |
// 16777215
if (length < 0x80) {
GsmPDUHelper.writeHexOctet(length);
} else if (0x80 <= length && length < 0x100) {
GsmPDUHelper.writeHexOctet(0x81);
GsmPDUHelper.writeHexOctet(length);
} else if (0x100 <= length && length < 0x10000) {
GsmPDUHelper.writeHexOctet(0x82);
GsmPDUHelper.writeHexOctet((length >> 8) & 0xff);
GsmPDUHelper.writeHexOctet(length & 0xff);
} else if (0x10000 <= length && length < 0x1000000) {
GsmPDUHelper.writeHexOctet(0x83);
GsmPDUHelper.writeHexOctet((length >> 16) & 0xff);
GsmPDUHelper.writeHexOctet((length >> 8) & 0xff);
GsmPDUHelper.writeHexOctet(length & 0xff);
} else {
throw new Error("Invalid length value :" + length);
}
},
};
function BerTlvHelperObject(aContext) {
this.context = aContext;
}
BerTlvHelperObject.prototype = {
context: null,
/**
* Decode Ber TLV.
*
* @param dataLen
* The length of data in bytes.
*/
decode: function(dataLen) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let hlen = 0;
let tag = GsmPDUHelper.readHexOctet();
hlen++;
// The length is coded onto 1 or 2 bytes.
// Length | Byte 1 | Byte 2
// 0 - 127 | length ('00' to '7f') | N/A
// 128 - 255 | '81' | length ('80' to 'ff')
let length;
let temp = GsmPDUHelper.readHexOctet();
hlen++;
if (temp < 0x80) {
length = temp;
} else if (temp === 0x81) {
length = GsmPDUHelper.readHexOctet();
hlen++;
if (length < 0x80) {
throw new Error("Invalid length " + length);
}
} else {
throw new Error("Invalid length octet " + temp);
}
// Header + body length check.
if (dataLen - hlen !== length) {
throw new Error("Unexpected BerTlvHelper value length!!");
}
let method = this[tag];
if (typeof method != "function") {
throw new Error("Unknown Ber tag 0x" + tag.toString(16));
}
let value = method.call(this, length);
return {
tag: tag,
length: length,
value: value
};
},
/**
* Process the value part for FCP template TLV.
*
* @param length
* The length of data in bytes.
*/
processFcpTemplate: function(length) {
let tlvs = this.decodeChunks(length);
return tlvs;
},
/**
* Process the value part for proactive command TLV.
*
* @param length
* The length of data in bytes.
*/
processProactiveCommand: function(length) {
let ctlvs = this.context.ComprehensionTlvHelper.decodeChunks(length);
return ctlvs;
},
/**
* Decode raw data to a Ber-TLV.
*/
decodeInnerTlv: function() {
let GsmPDUHelper = this.context.GsmPDUHelper;
let tag = GsmPDUHelper.readHexOctet();
let length = GsmPDUHelper.readHexOctet();
return {
tag: tag,
length: length,
value: this.retrieve(tag, length)
};
},
decodeChunks: function(length) {
let chunks = [];
let index = 0;
while (index < length) {
let tlv = this.decodeInnerTlv();
if (tlv.value) {
chunks.push(tlv);
}
index += tlv.length;
// tag + length fields consume 2 bytes.
index += 2;
}
return chunks;
},
retrieve: function(tag, length) {
let method = this[tag];
if (typeof method != "function") {
if (DEBUG) {
this.context.debug("Unknown Ber tag : 0x" + tag.toString(16));
}
let Buf = this.context.Buf;
Buf.seekIncoming(length * Buf.PDU_HEX_OCTET_SIZE);
return null;
}
return method.call(this, length);
},
/**
* File Size Data.
*
* | Byte | Description | Length |
* | 1 | Tag | 1 |
* | 2 | Length | 1 |
* | 3 to X+24 | Number of allocated data bytes in the file | X |
* | | , excluding structural information | |
*/
retrieveFileSizeData: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let fileSizeData = 0;
for (let i = 0; i < length; i++) {
fileSizeData = fileSizeData << 8;
fileSizeData += GsmPDUHelper.readHexOctet();
}
return {fileSizeData: fileSizeData};
},
/**
* File Descriptor.
*
* | Byte | Description | Length |
* | 1 | Tag | 1 |
* | 2 | Length | 1 |
* | 3 | File descriptor byte | 1 |
* | 4 | Data coding byte | 1 |
* | 5 ~ 6 | Record length | 2 |
* | 7 | Number of records | 1 |
*/
retrieveFileDescriptor: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let fileDescriptorByte = GsmPDUHelper.readHexOctet();
let dataCodingByte = GsmPDUHelper.readHexOctet();
// See TS 102 221 Table 11.5, we only care the least 3 bits for the
// structure of file.
let fileStructure = fileDescriptorByte & 0x07;
let fileDescriptor = {
fileStructure: fileStructure
};
// byte 5 ~ 7 are mandatory for linear fixed and cyclic files, otherwise
// they are not applicable.
if (fileStructure === UICC_EF_STRUCTURE[EF_STRUCTURE_LINEAR_FIXED] ||
fileStructure === UICC_EF_STRUCTURE[EF_STRUCTURE_CYCLIC]) {
fileDescriptor.recordLength = (GsmPDUHelper.readHexOctet() << 8) +
GsmPDUHelper.readHexOctet();
fileDescriptor.numOfRecords = GsmPDUHelper.readHexOctet();
}
return fileDescriptor;
},
/**
* File identifier.
*
* | Byte | Description | Length |
* | 1 | Tag | 1 |
* | 2 | Length | 1 |
* | 3 ~ 4 | File identifier | 2 |
*/
retrieveFileIdentifier: function(length) {
let GsmPDUHelper = this.context.GsmPDUHelper;
return {fileId : (GsmPDUHelper.readHexOctet() << 8) +
GsmPDUHelper.readHexOctet()};
},
searchForNextTag: function(tag, iter) {
for (let [index, tlv] in iter) {
if (tlv.tag === tag) {
return tlv;
}
}
return null;
}
};
BerTlvHelperObject.prototype[BER_FCP_TEMPLATE_TAG] = function BER_FCP_TEMPLATE_TAG(length) {
return this.processFcpTemplate(length);
};
BerTlvHelperObject.prototype[BER_PROACTIVE_COMMAND_TAG] = function BER_PROACTIVE_COMMAND_TAG(length) {
return this.processProactiveCommand(length);
};
BerTlvHelperObject.prototype[BER_FCP_FILE_SIZE_DATA_TAG] = function BER_FCP_FILE_SIZE_DATA_TAG(length) {
return this.retrieveFileSizeData(length);
};
BerTlvHelperObject.prototype[BER_FCP_FILE_DESCRIPTOR_TAG] = function BER_FCP_FILE_DESCRIPTOR_TAG(length) {
return this.retrieveFileDescriptor(length);
};
BerTlvHelperObject.prototype[BER_FCP_FILE_IDENTIFIER_TAG] = function BER_FCP_FILE_IDENTIFIER_TAG(length) {
return this.retrieveFileIdentifier(length);
};
/**
* ICC Helper for getting EF path.
*/
function ICCFileHelperObject(aContext) {
this.context = aContext;
}
ICCFileHelperObject.prototype = {
context: null,
/**
* This function handles only EFs that are common to RUIM, SIM, USIM
* and other types of ICC cards.
*/
getCommonEFPath: function(fileId) {
switch (fileId) {
case ICC_EF_ICCID:
return EF_PATH_MF_SIM;
case ICC_EF_ADN:
case ICC_EF_SDN: // Fall through.
return EF_PATH_MF_SIM + EF_PATH_DF_TELECOM;
case ICC_EF_PBR:
return EF_PATH_MF_SIM + EF_PATH_DF_TELECOM + EF_PATH_DF_PHONEBOOK;
case ICC_EF_IMG:
return EF_PATH_MF_SIM + EF_PATH_DF_TELECOM + EF_PATH_GRAPHICS;
}
return null;
},
/**
* This function handles EFs for SIM.
*/
getSimEFPath: function(fileId) {
switch (fileId) {
case ICC_EF_FDN:
case ICC_EF_MSISDN:
case ICC_EF_SMS:
case ICC_EF_EXT1:
case ICC_EF_EXT2:
case ICC_EF_EXT3:
return EF_PATH_MF_SIM + EF_PATH_DF_TELECOM;
case ICC_EF_AD:
case ICC_EF_MBDN:
case ICC_EF_MWIS:
case ICC_EF_PLMNsel:
case ICC_EF_SPN:
case ICC_EF_SPDI:
case ICC_EF_SST:
case ICC_EF_PHASE:
case ICC_EF_CBMI:
case ICC_EF_CBMID:
case ICC_EF_CBMIR:
case ICC_EF_OPL:
case ICC_EF_PNN:
case ICC_EF_GID1:
case ICC_EF_CPHS_INFO:
case ICC_EF_CPHS_MBN:
return EF_PATH_MF_SIM + EF_PATH_DF_GSM;
default:
return null;
}
},
/**
* This function handles EFs for USIM.
*/
getUSimEFPath: function(fileId) {
switch (fileId) {
case ICC_EF_AD:
case ICC_EF_FDN:
case ICC_EF_MBDN:
case ICC_EF_MWIS:
case ICC_EF_UST:
case ICC_EF_MSISDN:
case ICC_EF_SPN:
case ICC_EF_SPDI:
case ICC_EF_CBMI:
case ICC_EF_CBMID:
case ICC_EF_CBMIR:
case ICC_EF_OPL:
case ICC_EF_PNN:
case ICC_EF_SMS:
case ICC_EF_GID1:
// CPHS spec was provided in 1997 based on SIM requirement, there is no
// detailed info about how these ICC_EF_CPHS_XXX are allocated in USIM.
// What we can do now is to follow what has been done in AOSP to have file
// path equal to MF_SIM/DF_GSM.
case ICC_EF_CPHS_INFO:
case ICC_EF_CPHS_MBN:
return EF_PATH_MF_SIM + EF_PATH_ADF_USIM;
default:
// The file ids in USIM phone book entries are decided by the
// card manufacturer. So if we don't match any of the cases
// above and if its a USIM return the phone book path.
return EF_PATH_MF_SIM + EF_PATH_DF_TELECOM + EF_PATH_DF_PHONEBOOK;
}
},
/**
* This function handles EFs for RUIM
*/
getRuimEFPath: function(fileId) {
switch(fileId) {
case ICC_EF_CSIM_IMSI_M:
case ICC_EF_CSIM_CDMAHOME:
case ICC_EF_CSIM_CST:
case ICC_EF_CSIM_SPN:
return EF_PATH_MF_SIM + EF_PATH_DF_CDMA;
case ICC_EF_FDN:
case ICC_EF_EXT1:
case ICC_EF_EXT2:
case ICC_EF_EXT3:
return EF_PATH_MF_SIM + EF_PATH_DF_TELECOM;
default:
return null;
}
},
/**
* Helper function for getting the pathId for the specific ICC record
* depeding on which type of ICC card we are using.
*
* @param fileId
* File id.
* @return The pathId or null in case of an error or invalid input.
*/
getEFPath: function(fileId) {
let path = this.getCommonEFPath(fileId);
if (path) {
return path;
}
switch (this.context.RIL.appType) {
case CARD_APPTYPE_SIM:
return this.getSimEFPath(fileId);
case CARD_APPTYPE_USIM:
return this.getUSimEFPath(fileId);
case CARD_APPTYPE_RUIM:
return this.getRuimEFPath(fileId);
default:
return null;
}
}
};
/**
* Helper for ICC IO functionalities.
*/
function ICCIOHelperObject(aContext) {
this.context = aContext;
}
ICCIOHelperObject.prototype = {
context: null,
/**
* Load EF with type 'Linear Fixed'.
*
* @param fileId
* The file to operate on, one of the ICC_EF_* constants.
* @param recordNumber [optional]
* The number of the record shall be loaded.
* @param recordSize [optional]
* The size of the record.
* @param callback [optional]
* The callback function shall be called when the record(s) is read.
* @param onerror [optional]
* The callback function shall be called when failure.
*/
loadLinearFixedEF: function(options) {
let cb;
let readRecord = (function(options) {
options.command = ICC_COMMAND_READ_RECORD;
options.p1 = options.recordNumber || 1; // Record number
options.p2 = READ_RECORD_ABSOLUTE_MODE;
options.p3 = options.recordSize;
options.callback = cb || options.callback;
this.context.RIL.iccIO(options);
}).bind(this);
options.structure = EF_STRUCTURE_LINEAR_FIXED;
options.pathId = this.context.ICCFileHelper.getEFPath(options.fileId);
if (options.recordSize) {
readRecord(options);
return;
}
cb = options.callback;
options.callback = readRecord;
this.getResponse(options);
},
/**
* Load next record from current record Id.
*/
loadNextRecord: function(options) {
options.p1++;
this.context.RIL.iccIO(options);
},
/**
* Update EF with type 'Linear Fixed'.
*
* @param fileId
* The file to operate on, one of the ICC_EF_* constants.
* @param recordNumber
* The number of the record shall be updated.
* @param dataWriter [optional]
* The function for writing string parameter for the ICC_COMMAND_UPDATE_RECORD.
* @param pin2 [optional]
* PIN2 is required when updating ICC_EF_FDN.
* @param callback [optional]
* The callback function shall be called when the record is updated.
* @param onerror [optional]
* The callback function shall be called when failure.
*/
updateLinearFixedEF: function(options) {
if (!options.fileId || !options.recordNumber) {
throw new Error("Unexpected fileId " + options.fileId +
" or recordNumber " + options.recordNumber);
}
options.structure = EF_STRUCTURE_LINEAR_FIXED;
options.pathId = this.context.ICCFileHelper.getEFPath(options.fileId);
let cb = options.callback;
options.callback = function callback(options) {
options.callback = cb;
options.command = ICC_COMMAND_UPDATE_RECORD;
options.p1 = options.recordNumber;
options.p2 = READ_RECORD_ABSOLUTE_MODE;
options.p3 = options.recordSize;
this.context.RIL.iccIO(options);
}.bind(this);
this.getResponse(options);
},
/**
* Load EF with type 'Transparent'.
*
* @param fileId
* The file to operate on, one of the ICC_EF_* constants.
* @param callback [optional]
* The callback function shall be called when the record(s) is read.
* @param onerror [optional]
* The callback function shall be called when failure.
*/
loadTransparentEF: function(options) {
options.structure = EF_STRUCTURE_TRANSPARENT;
let cb = options.callback;
options.callback = function callback(options) {
options.callback = cb;
options.command = ICC_COMMAND_READ_BINARY;
options.p2 = 0x00;
options.p3 = options.fileSize;
this.context.RIL.iccIO(options);
}.bind(this);
this.getResponse(options);
},
/**
* Use ICC_COMMAND_GET_RESPONSE to query the EF.
*
* @param fileId
* The file to operate on, one of the ICC_EF_* constants.
*/
getResponse: function(options) {
options.command = ICC_COMMAND_GET_RESPONSE;
options.pathId = options.pathId ||
this.context.ICCFileHelper.getEFPath(options.fileId);
if (!options.pathId) {
throw new Error("Unknown pathId for " + options.fileId.toString(16));
}
options.p1 = 0; // For GET_RESPONSE, p1 = 0
switch (this.context.RIL.appType) {
case CARD_APPTYPE_USIM:
options.p2 = GET_RESPONSE_FCP_TEMPLATE;
options.p3 = 0x00;
break;
// For RUIM, CSIM and ISIM, cf bug 955946: keep the old behavior
case CARD_APPTYPE_RUIM:
case CARD_APPTYPE_CSIM:
case CARD_APPTYPE_ISIM:
// For SIM, this is what we want
case CARD_APPTYPE_SIM:
default:
options.p2 = 0x00;
options.p3 = GET_RESPONSE_EF_SIZE_BYTES;
break;
}
this.context.RIL.iccIO(options);
},
/**
* Process ICC I/O response.
*/
processICCIO: function(options) {
let func = this[options.command];
func.call(this, options);
},
/**
* Process a ICC_COMMAND_GET_RESPONSE type command for REQUEST_SIM_IO.
*/
processICCIOGetResponse: function(options) {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
let peek = this.context.GsmPDUHelper.readHexOctet();
Buf.seekIncoming(-1 * Buf.PDU_HEX_OCTET_SIZE);
if (peek === BER_FCP_TEMPLATE_TAG) {
this.processUSimGetResponse(options, strLen / 2);
} else {
this.processSimGetResponse(options);
}
Buf.readStringDelimiter(strLen);
if (options.callback) {
options.callback(options);
}
},
/**
* Helper function for processing USIM get response.
*/
processUSimGetResponse: function(options, octetLen) {
let BerTlvHelper = this.context.BerTlvHelper;
let berTlv = BerTlvHelper.decode(octetLen);
// See TS 102 221 Table 11.4 for the content order of getResponse.
let iter = Iterator(berTlv.value);
let tlv = BerTlvHelper.searchForNextTag(BER_FCP_FILE_DESCRIPTOR_TAG,
iter);
if (!tlv ||
(tlv.value.fileStructure !== UICC_EF_STRUCTURE[options.structure])) {
throw new Error("Expected EF structure " +
UICC_EF_STRUCTURE[options.structure] +
" but read " + tlv.value.fileStructure);
}
if (tlv.value.fileStructure === UICC_EF_STRUCTURE[EF_STRUCTURE_LINEAR_FIXED] ||
tlv.value.fileStructure === UICC_EF_STRUCTURE[EF_STRUCTURE_CYCLIC]) {
options.recordSize = tlv.value.recordLength;
options.totalRecords = tlv.value.numOfRecords;
}
tlv = BerTlvHelper.searchForNextTag(BER_FCP_FILE_IDENTIFIER_TAG, iter);
if (!tlv || (tlv.value.fileId !== options.fileId)) {
throw new Error("Expected file ID " + options.fileId.toString(16) +
" but read " + fileId.toString(16));
}
tlv = BerTlvHelper.searchForNextTag(BER_FCP_FILE_SIZE_DATA_TAG, iter);
if (!tlv) {
throw new Error("Unexpected file size data");
}
options.fileSize = tlv.value.fileSizeData;
},
/**
* Helper function for processing SIM get response.
*/
processSimGetResponse: function(options) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
// The format is from TS 51.011, clause 9.2.1
// Skip RFU, data[0] data[1].
Buf.seekIncoming(2 * Buf.PDU_HEX_OCTET_SIZE);
// File size, data[2], data[3]
options.fileSize = (GsmPDUHelper.readHexOctet() << 8) |
GsmPDUHelper.readHexOctet();
// 2 bytes File id. data[4], data[5]
let fileId = (GsmPDUHelper.readHexOctet() << 8) |
GsmPDUHelper.readHexOctet();
if (fileId != options.fileId) {
throw new Error("Expected file ID " + options.fileId.toString(16) +
" but read " + fileId.toString(16));
}
// Type of file, data[6]
let fileType = GsmPDUHelper.readHexOctet();
if (fileType != TYPE_EF) {
throw new Error("Unexpected file type " + fileType);
}
// Skip 1 byte RFU, data[7],
// 3 bytes Access conditions, data[8] data[9] data[10],
// 1 byte File status, data[11],
// 1 byte Length of the following data, data[12].
Buf.seekIncoming(((RESPONSE_DATA_STRUCTURE - RESPONSE_DATA_FILE_TYPE - 1) *
Buf.PDU_HEX_OCTET_SIZE));
// Read Structure of EF, data[13]
let efStructure = GsmPDUHelper.readHexOctet();
if (efStructure != options.structure) {
throw new Error("Expected EF structure " + options.structure +
" but read " + efStructure);
}
// Length of a record, data[14].
// Only available for LINEAR_FIXED and CYCLIC.
if (efStructure == EF_STRUCTURE_LINEAR_FIXED ||
efStructure == EF_STRUCTURE_CYCLIC) {
options.recordSize = GsmPDUHelper.readHexOctet();
options.totalRecords = options.fileSize / options.recordSize;
} else {
Buf.seekIncoming(1 * Buf.PDU_HEX_OCTET_SIZE);
}
},
/**
* Process a ICC_COMMAND_READ_RECORD type command for REQUEST_SIM_IO.
*/
processICCIOReadRecord: function(options) {
if (options.callback) {
options.callback(options);
}
},
/**
* Process a ICC_COMMAND_READ_BINARY type command for REQUEST_SIM_IO.
*/
processICCIOReadBinary: function(options) {
if (options.callback) {
options.callback(options);
}
},
/**
* Process a ICC_COMMAND_UPDATE_RECORD type command for REQUEST_SIM_IO.
*/
processICCIOUpdateRecord: function(options) {
if (options.callback) {
options.callback(options);
}
},
};
ICCIOHelperObject.prototype[ICC_COMMAND_SEEK] = null;
ICCIOHelperObject.prototype[ICC_COMMAND_READ_BINARY] = function ICC_COMMAND_READ_BINARY(options) {
this.processICCIOReadBinary(options);
};
ICCIOHelperObject.prototype[ICC_COMMAND_READ_RECORD] = function ICC_COMMAND_READ_RECORD(options) {
this.processICCIOReadRecord(options);
};
ICCIOHelperObject.prototype[ICC_COMMAND_GET_RESPONSE] = function ICC_COMMAND_GET_RESPONSE(options) {
this.processICCIOGetResponse(options);
};
ICCIOHelperObject.prototype[ICC_COMMAND_UPDATE_BINARY] = null;
ICCIOHelperObject.prototype[ICC_COMMAND_UPDATE_RECORD] = function ICC_COMMAND_UPDATE_RECORD(options) {
this.processICCIOUpdateRecord(options);
};
/**
* Helper for ICC records.
*/
function ICCRecordHelperObject(aContext) {
this.context = aContext;
// Cache the possible free record id for all files, use fileId as key.
this._freeRecordIds = {};
}
ICCRecordHelperObject.prototype = {
context: null,
/**
* Fetch ICC records.
*/
fetchICCRecords: function() {
switch (this.context.RIL.appType) {
case CARD_APPTYPE_SIM:
case CARD_APPTYPE_USIM:
this.context.SimRecordHelper.fetchSimRecords();
break;
case CARD_APPTYPE_RUIM:
this.context.RuimRecordHelper.fetchRuimRecords();
break;
}
},
/**
* Read the ICCID.
*/
readICCID: function() {
function callback() {
let Buf = this.context.Buf;
let RIL = this.context.RIL;
let GsmPDUHelper = this.context.GsmPDUHelper;
let strLen = Buf.readInt32();
let octetLen = strLen / 2;
RIL.iccInfo.iccid =
GsmPDUHelper.readSwappedNibbleBcdString(octetLen, true);
// Consumes the remaining buffer if any.
let unReadBuffer = this.context.Buf.getReadAvailable() -
this.context.Buf.PDU_HEX_OCTET_SIZE;
if (unReadBuffer > 0) {
this.context.Buf.seekIncoming(unReadBuffer);
}
Buf.readStringDelimiter(strLen);
if (DEBUG) this.context.debug("ICCID: " + RIL.iccInfo.iccid);
if (RIL.iccInfo.iccid) {
this.context.ICCUtilsHelper.handleICCInfoChange();
RIL.reportStkServiceIsRunning();
}
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_ICCID,
callback: callback.bind(this)
});
},
/**
* Read ICC ADN like EF, i.e. EF_ADN, EF_FDN.
*
* @param fileId EF id of the ADN, FDN or SDN.
* @param extFileId EF id of the EXT.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readADNLike: function(fileId, extFileId, onsuccess, onerror) {
let ICCIOHelper = this.context.ICCIOHelper;
function callback(options) {
let loadNextContactRecord = () => {
if (options.p1 < options.totalRecords) {
ICCIOHelper.loadNextRecord(options);
return;
}
if (DEBUG) {
for (let i = 0; i < contacts.length; i++) {
this.context.debug("contact [" + i + "] " +
JSON.stringify(contacts[i]));
}
}
if (onsuccess) {
onsuccess(contacts);
}
};
let contact =
this.context.ICCPDUHelper.readAlphaIdDiallingNumber(options.recordSize);
if (contact) {
let record = {
recordId: options.p1,
alphaId: contact.alphaId,
number: contact.number
};
contacts.push(record);
if (extFileId && contact.extRecordNumber != 0xff) {
this.readExtension(extFileId, contact.extRecordNumber, (number) => {
if (number) {
record.number += number;
}
loadNextContactRecord();
}, () => loadNextContactRecord());
return;
}
}
loadNextContactRecord();
}
let contacts = [];
ICCIOHelper.loadLinearFixedEF({fileId: fileId,
callback: callback.bind(this),
onerror: onerror});
},
/**
* Update ICC ADN like EFs, like EF_ADN, EF_FDN.
*
* @param fileId EF id of the ADN or FDN.
* @param extRecordNumber The record identifier of the EXT.
* @param contact The contact will be updated. (Shall have recordId property)
* @param pin2 PIN2 is required when updating ICC_EF_FDN.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateADNLike: function(fileId, extRecordNumber, contact, pin2, onsuccess, onerror) {
let updatedContact;
function dataWriter(recordSize) {
updatedContact = this.context.ICCPDUHelper.writeAlphaIdDiallingNumber(recordSize,
contact.alphaId,
contact.number,
extRecordNumber);
}
function callback(options) {
if (onsuccess) {
onsuccess(updatedContact);
}
}
if (!contact || !contact.recordId) {
if (onerror) onerror(GECKO_ERROR_INVALID_PARAMETER);
return;
}
this.context.ICCIOHelper.updateLinearFixedEF({
fileId: fileId,
recordNumber: contact.recordId,
dataWriter: dataWriter.bind(this),
pin2: pin2,
callback: callback.bind(this),
onerror: onerror
});
},
/**
* Read USIM/RUIM Phonebook.
*
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readPBR: function(onsuccess, onerror) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
let ICCIOHelper = this.context.ICCIOHelper;
let ICCUtilsHelper = this.context.ICCUtilsHelper;
let RIL = this.context.RIL;
function callback(options) {
let strLen = Buf.readInt32();
let octetLen = strLen / 2, readLen = 0;
let pbrTlvs = [];
while (readLen < octetLen) {
let tag = GsmPDUHelper.readHexOctet();
if (tag == 0xff) {
readLen++;
Buf.seekIncoming((octetLen - readLen) * Buf.PDU_HEX_OCTET_SIZE);
break;
}
let tlvLen = GsmPDUHelper.readHexOctet();
let tlvs = ICCUtilsHelper.decodeSimTlvs(tlvLen);
pbrTlvs.push({tag: tag,
length: tlvLen,
value: tlvs});
readLen += tlvLen + 2; // +2 for tag and tlvLen
}
Buf.readStringDelimiter(strLen);
if (pbrTlvs.length > 0) {
let pbr = ICCUtilsHelper.parsePbrTlvs(pbrTlvs);
// EF_ADN is mandatory if and only if DF_PHONEBOOK is present.
if (!pbr.adn) {
if (onerror) onerror("Cannot access ADN.");
return;
}
pbrs.push(pbr);
}
if (options.p1 < options.totalRecords) {
ICCIOHelper.loadNextRecord(options);
} else {
if (onsuccess) {
RIL.iccInfoPrivate.pbrs = pbrs;
onsuccess(pbrs);
}
}
}
if (RIL.iccInfoPrivate.pbrs) {
onsuccess(RIL.iccInfoPrivate.pbrs);
return;
}
let pbrs = [];
ICCIOHelper.loadLinearFixedEF({fileId : ICC_EF_PBR,
callback: callback.bind(this),
onerror: onerror});
},
/**
* Cache EF_IAP record size.
*/
_iapRecordSize: null,
/**
* Read ICC EF_IAP. (Index Administration Phonebook)
*
* @see TS 131.102, clause 4.4.2.2
*
* @param fileId EF id of the IAP.
* @param recordNumber The number of the record shall be loaded.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readIAP: function(fileId, recordNumber, onsuccess, onerror) {
function callback(options) {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
let octetLen = strLen / 2;
this._iapRecordSize = options.recordSize;
let iap = this.context.GsmPDUHelper.readHexOctetArray(octetLen);
Buf.readStringDelimiter(strLen);
if (onsuccess) {
onsuccess(iap);
}
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
recordSize: this._iapRecordSize,
callback: callback.bind(this),
onerror: onerror
});
},
/**
* Update USIM/RUIM Phonebook EF_IAP.
*
* @see TS 131.102, clause 4.4.2.13
*
* @param fileId EF id of the IAP.
* @param recordNumber The identifier of the record shall be updated.
* @param iap The IAP value to be written.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateIAP: function(fileId, recordNumber, iap, onsuccess, onerror) {
let dataWriter = function dataWriter(recordSize) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
// Write String length
let strLen = recordSize * 2;
Buf.writeInt32(strLen);
for (let i = 0; i < iap.length; i++) {
GsmPDUHelper.writeHexOctet(iap[i]);
}
Buf.writeStringDelimiter(strLen);
}.bind(this);
this.context.ICCIOHelper.updateLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
dataWriter: dataWriter,
callback: onsuccess,
onerror: onerror
});
},
/**
* Cache EF_Email record size.
*/
_emailRecordSize: null,
/**
* Read USIM/RUIM Phonebook EF_EMAIL.
*
* @see TS 131.102, clause 4.4.2.13
*
* @param fileId EF id of the EMAIL.
* @param fileType The type of the EMAIL, one of the ICC_USIM_TYPE* constants.
* @param recordNumber The number of the record shall be loaded.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readEmail: function(fileId, fileType, recordNumber, onsuccess, onerror) {
function callback(options) {
let Buf = this.context.Buf;
let ICCPDUHelper = this.context.ICCPDUHelper;
let strLen = Buf.readInt32();
let octetLen = strLen / 2;
let email = null;
this._emailRecordSize = options.recordSize;
// Read contact's email
//
// | Byte | Description | Length | M/O
// | 1 ~ X | E-mail Address | X | M
// | X+1 | ADN file SFI | 1 | C
// | X+2 | ADN file Record Identifier | 1 | C
// Note: The fields marked as C above are mandatort if the file
// is not type 1 (as specified in EF_PBR)
if (fileType == ICC_USIM_TYPE1_TAG) {
email = ICCPDUHelper.read8BitUnpackedToString(octetLen);
} else {
email = ICCPDUHelper.read8BitUnpackedToString(octetLen - 2);
// Consumes the remaining buffer
Buf.seekIncoming(2 * Buf.PDU_HEX_OCTET_SIZE); // For ADN SFI and Record Identifier
}
Buf.readStringDelimiter(strLen);
if (onsuccess) {
onsuccess(email);
}
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
recordSize: this._emailRecordSize,
callback: callback.bind(this),
onerror: onerror
});
},
/**
* Update USIM/RUIM Phonebook EF_EMAIL.
*
* @see TS 131.102, clause 4.4.2.13
*
* @param pbr Phonebook Reference File.
* @param recordNumber The identifier of the record shall be updated.
* @param email The value to be written.
* @param adnRecordId The record Id of ADN, only needed if the fileType of Email is TYPE2.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateEmail: function(pbr, recordNumber, email, adnRecordId, onsuccess, onerror) {
let fileId = pbr[USIM_PBR_EMAIL].fileId;
let fileType = pbr[USIM_PBR_EMAIL].fileType;
let writtenEmail;
let dataWriter = function dataWriter(recordSize) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
let ICCPDUHelper = this.context.ICCPDUHelper;
// Write String length
let strLen = recordSize * 2;
Buf.writeInt32(strLen);
if (fileType == ICC_USIM_TYPE1_TAG) {
writtenEmail = ICCPDUHelper.writeStringTo8BitUnpacked(recordSize, email);
} else {
writtenEmail = ICCPDUHelper.writeStringTo8BitUnpacked(recordSize - 2, email);
GsmPDUHelper.writeHexOctet(pbr.adn.sfi || 0xff);
GsmPDUHelper.writeHexOctet(adnRecordId);
}
Buf.writeStringDelimiter(strLen);
}.bind(this);
let callback = (options) => {
if (onsuccess) {
onsuccess(writtenEmail);
}
}
this.context.ICCIOHelper.updateLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
dataWriter: dataWriter,
callback: callback,
onerror: onerror
});
},
/**
* Cache EF_ANR record size.
*/
_anrRecordSize: null,
/**
* Read USIM/RUIM Phonebook EF_ANR.
*
* @see TS 131.102, clause 4.4.2.9
*
* @param fileId EF id of the ANR.
* @param fileType One of the ICC_USIM_TYPE* constants.
* @param recordNumber The number of the record shall be loaded.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readANR: function(fileId, fileType, recordNumber, onsuccess, onerror) {
function callback(options) {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
let number = null;
this._anrRecordSize = options.recordSize;
// Skip EF_AAS Record ID.
Buf.seekIncoming(1 * Buf.PDU_HEX_OCTET_SIZE);
number = this.context.ICCPDUHelper.readNumberWithLength();
// Skip 2 unused octets, CCP and EXT1.
Buf.seekIncoming(2 * Buf.PDU_HEX_OCTET_SIZE);
// For Type 2 there are two extra octets.
if (fileType == ICC_USIM_TYPE2_TAG) {
// Skip 2 unused octets, ADN SFI and Record Identifier.
Buf.seekIncoming(2 * Buf.PDU_HEX_OCTET_SIZE);
}
Buf.readStringDelimiter(strLen);
if (onsuccess) {
onsuccess(number);
}
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
recordSize: this._anrRecordSize,
callback: callback.bind(this),
onerror: onerror
});
},
/**
* Update USIM/RUIM Phonebook EF_ANR.
*
* @see TS 131.102, clause 4.4.2.9
*
* @param pbr Phonebook Reference File.
* @param recordNumber The identifier of the record shall be updated.
* @param number The value to be written.
* @param adnRecordId The record Id of ADN, only needed if the fileType of Email is TYPE2.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateANR: function(pbr, recordNumber, number, adnRecordId, onsuccess, onerror) {
let fileId = pbr[USIM_PBR_ANR0].fileId;
let fileType = pbr[USIM_PBR_ANR0].fileType;
let writtenNumber;
let dataWriter = function dataWriter(recordSize) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
// Write String length
let strLen = recordSize * 2;
Buf.writeInt32(strLen);
// EF_AAS record Id. Unused for now.
GsmPDUHelper.writeHexOctet(0xff);
writtenNumber = this.context.ICCPDUHelper.writeNumberWithLength(number);
// Write unused octets 0xff, CCP and EXT1.
GsmPDUHelper.writeHexOctet(0xff);
GsmPDUHelper.writeHexOctet(0xff);
// For Type 2 there are two extra octets.
if (fileType == ICC_USIM_TYPE2_TAG) {
GsmPDUHelper.writeHexOctet(pbr.adn.sfi || 0xff);
GsmPDUHelper.writeHexOctet(adnRecordId);
}
Buf.writeStringDelimiter(strLen);
}.bind(this);
let callback = (options) => {
if (onsuccess) {
onsuccess(writtenNumber);
}
}
this.context.ICCIOHelper.updateLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
dataWriter: dataWriter,
callback: callback,
onerror: onerror
});
},
/**
* Cache the possible free record id for all files.
*/
_freeRecordIds: null,
/**
* Find free record id.
*
* @param fileId EF id.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
findFreeRecordId: function(fileId, onsuccess, onerror) {
let ICCIOHelper = this.context.ICCIOHelper;
function callback(options) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
let strLen = Buf.readInt32();
let octetLen = strLen / 2;
let readLen = 0;
while (readLen < octetLen) {
let octet = GsmPDUHelper.readHexOctet();
readLen++;
if (octet != 0xff) {
break;
}
}
let nextRecord = (options.p1 % options.totalRecords) + 1;
if (readLen == octetLen) {
// Find free record, assume next record is probably free.
this._freeRecordIds[fileId] = nextRecord;
if (onsuccess) {
onsuccess(options.p1);
}
return;
} else {
Buf.seekIncoming((octetLen - readLen) * Buf.PDU_HEX_OCTET_SIZE);
}
Buf.readStringDelimiter(strLen);
if (nextRecord !== recordNumber) {
options.p1 = nextRecord;
this.context.RIL.iccIO(options);
} else {
// No free record found.
delete this._freeRecordIds[fileId];
if (DEBUG) {
this.context.debug(CONTACT_ERR_NO_FREE_RECORD_FOUND);
}
onerror(CONTACT_ERR_NO_FREE_RECORD_FOUND);
}
}
// Start searching free records from the possible one.
let recordNumber = this._freeRecordIds[fileId] || 1;
ICCIOHelper.loadLinearFixedEF({fileId: fileId,
recordNumber: recordNumber,
callback: callback.bind(this),
onerror: onerror});
},
/**
* Read Extension Number from TS 151.011 clause 10.5.10, TS 31.102, clause 4.4.2.4
*
* @param fileId EF Extension id
* @param recordNumber The number of the record shall be loaded.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readExtension: function(fileId, recordNumber, onsuccess, onerror) {
let callback = (options) => {
let Buf = this.context.Buf;
let length = Buf.readInt32();
let recordType = this.context.GsmPDUHelper.readHexOctet();
let number = "";
// TS 31.102, clause 4.4.2.4 EFEXT1
// Case 1, Extension1 record is additional data
if (recordType & 0x02) {
let numLen = this.context.GsmPDUHelper.readHexOctet();
if (numLen != 0xff) {
if (numLen > EXT_MAX_BCD_NUMBER_BYTES) {
if (DEBUG) {
this.context.debug(
"Error: invalid length of BCD number/SSC contents - " + numLen);
}
// +1 to skip Identifier
Buf.seekIncoming((EXT_MAX_BCD_NUMBER_BYTES + 1) * Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(length);
onerror();
return;
}
number = this.context.GsmPDUHelper.readSwappedNibbleExtendedBcdString(numLen);
if (DEBUG) this.context.debug("Contact Extension Number: "+ number);
Buf.seekIncoming((EXT_MAX_BCD_NUMBER_BYTES - numLen) * Buf.PDU_HEX_OCTET_SIZE);
} else {
Buf.seekIncoming(EXT_MAX_BCD_NUMBER_BYTES * Buf.PDU_HEX_OCTET_SIZE);
}
} else {
// Don't support Case 2, Extension1 record is Called Party Subaddress.
// +1 skip numLen
Buf.seekIncoming((EXT_MAX_BCD_NUMBER_BYTES + 1) * Buf.PDU_HEX_OCTET_SIZE);
}
// Skip Identifier
Buf.seekIncoming(Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(length);
onsuccess(number);
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
callback: callback,
onerror: onerror
});
},
/**
* Update Extension.
*
* @param fileId EF id of the EXT.
* @param recordNumber The number of the record shall be updated.
* @param number Dialling Number to be written.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateExtension: function(fileId, recordNumber, number, onsuccess, onerror) {
let dataWriter = (recordSize) => {
let GsmPDUHelper = this.context.GsmPDUHelper;
// Write String length
let strLen = recordSize * 2;
let Buf = this.context.Buf;
Buf.writeInt32(strLen);
// We don't support extension chain.
if (number.length > EXT_MAX_NUMBER_DIGITS) {
number = number.substring(0, EXT_MAX_NUMBER_DIGITS);
}
let numLen = Math.ceil(number.length / 2);
// Write Extension record
GsmPDUHelper.writeHexOctet(0x02);
GsmPDUHelper.writeHexOctet(numLen);
GsmPDUHelper.writeSwappedNibbleBCD(number);
// Write trailing 0xff of Extension data.
for (let i = 0; i < EXT_MAX_BCD_NUMBER_BYTES - numLen; i++) {
GsmPDUHelper.writeHexOctet(0xff);
}
// Write trailing 0xff for Identifier.
GsmPDUHelper.writeHexOctet(0xff);
Buf.writeStringDelimiter(strLen);
};
this.context.ICCIOHelper.updateLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
dataWriter: dataWriter,
callback: onsuccess,
onerror: onerror
});
},
/**
* Clean an EF record.
*
* @param fileId EF id.
* @param recordNumber The number of the record shall be updated.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
cleanEFRecord: function(fileId, recordNumber, onsuccess, onerror) {
let dataWriter = (recordSize) => {
let GsmPDUHelper = this.context.GsmPDUHelper;
let Buf = this.context.Buf;
// Write String length
let strLen = recordSize * 2;
Buf.writeInt32(strLen);
// Write record to 0xff
for (let i = 0; i < recordSize; i++) {
GsmPDUHelper.writeHexOctet(0xff);
}
Buf.writeStringDelimiter(strLen);
}
this.context.ICCIOHelper.updateLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
dataWriter: dataWriter,
callback: onsuccess,
onerror: onerror
});
},
/**
* Get ADNLike extension record number.
*
* @param fileId EF id of the ADN or FDN.
* @param recordNumber EF record id of the ADN or FDN.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
getADNLikeExtensionRecordNumber: function(fileId, recordNumber, onsuccess, onerror) {
let callback = (options) => {
let Buf = this.context.Buf;
let length = Buf.readInt32();
// Skip alphaLen, numLen, BCD Number, CCP octets.
Buf.seekIncoming((options.recordSize -1) * Buf.PDU_HEX_OCTET_SIZE);
let extRecordNumber = this.context.GsmPDUHelper.readHexOctet();
Buf.readStringDelimiter(length);
onsuccess(extRecordNumber);
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: fileId,
recordNumber: recordNumber,
callback: callback,
onerror: onerror
});
},
};
/**
* Helper for (U)SIM Records.
*/
function SimRecordHelperObject(aContext) {
this.context = aContext;
}
SimRecordHelperObject.prototype = {
context: null,
/**
* Fetch (U)SIM records.
*/
fetchSimRecords: function() {
this.context.RIL.getIMSI();
this.readAD();
// CPHS was widely introduced in Europe during GSM(2G) era to provide easier
// access to carrier's core service like voicemail, call forwarding, manual
// PLMN selection, and etc.
// Addition EF like EF_CPHS_MBN, EF_CPHS_CPHS_CFF, EF_CPHS_VWI, etc are
// introduced to support these feature.
// In USIM, the replancement of these EFs are provided. (EF_MBDN, EF_MWIS, ...)
// However, some carriers in Europe still rely on these EFs.
this.readCphsInfo(() => this.readSST(),
(aErrorMsg) => {
this.context.debug("Failed to read CPHS_INFO: " + aErrorMsg);
this.readSST();
});
},
/**
* Read EF_phase.
* This EF is only available in SIM.
*/
readSimPhase: function() {
function callback() {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
let GsmPDUHelper = this.context.GsmPDUHelper;
let phase = GsmPDUHelper.readHexOctet();
// If EF_phase is coded '03' or greater, an ME supporting STK shall
// perform the PROFILE DOWNLOAD procedure.
if (RILQUIRKS_SEND_STK_PROFILE_DOWNLOAD &&
phase >= ICC_PHASE_2_PROFILE_DOWNLOAD_REQUIRED) {
this.context.RIL.sendStkTerminalProfile(STK_SUPPORTED_TERMINAL_PROFILE);
}
Buf.readStringDelimiter(strLen);
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_PHASE,
callback: callback.bind(this)
});
},
/**
* Read the MSISDN from the (U)SIM.
*/
readMSISDN: function() {
function callback(options) {
let RIL = this.context.RIL;
let contact =
this.context.ICCPDUHelper.readAlphaIdDiallingNumber(options.recordSize);
if (!contact ||
(RIL.iccInfo.msisdn !== undefined &&
RIL.iccInfo.msisdn === contact.number)) {
return;
}
RIL.iccInfo.msisdn = contact.number;
if (DEBUG) this.context.debug("MSISDN: " + RIL.iccInfo.msisdn);
this.context.ICCUtilsHelper.handleICCInfoChange();
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: ICC_EF_MSISDN,
callback: callback.bind(this)
});
},
/**
* Read the AD (Administrative Data) from the (U)SIM.
*/
readAD: function() {
function callback() {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
// Each octet is encoded into two chars.
let octetLen = strLen / 2;
let ad = this.context.GsmPDUHelper.readHexOctetArray(octetLen);
Buf.readStringDelimiter(strLen);
if (DEBUG) {
let str = "";
for (let i = 0; i < ad.length; i++) {
str += ad[i] + ", ";
}
this.context.debug("AD: " + str);
}
let ICCUtilsHelper = this.context.ICCUtilsHelper;
let RIL = this.context.RIL;
// TS 31.102, clause 4.2.18 EFAD
let mncLength = 0;
if (ad && ad[3]) {
mncLength = ad[3] & 0x0f;
if (mncLength != 0x02 && mncLength != 0x03) {
mncLength = 0;
}
}
// The 4th byte of the response is the length of MNC.
let mccMnc = ICCUtilsHelper.parseMccMncFromImsi(RIL.iccInfoPrivate.imsi,
mncLength);
if (mccMnc) {
RIL.iccInfo.mcc = mccMnc.mcc;
RIL.iccInfo.mnc = mccMnc.mnc;
ICCUtilsHelper.handleICCInfoChange();
}
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_AD,
callback: callback.bind(this)
});
},
/**
* Read the SPN (Service Provider Name) from the (U)SIM.
*/
readSPN: function() {
function callback() {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
// Each octet is encoded into two chars.
let octetLen = strLen / 2;
let spnDisplayCondition = this.context.GsmPDUHelper.readHexOctet();
// Minus 1 because the first octet is used to store display condition.
let spn = this.context.ICCPDUHelper.readAlphaIdentifier(octetLen - 1);
Buf.readStringDelimiter(strLen);
if (DEBUG) {
this.context.debug("SPN: spn = " + spn +
", spnDisplayCondition = " + spnDisplayCondition);
}
let RIL = this.context.RIL;
RIL.iccInfoPrivate.spnDisplayCondition = spnDisplayCondition;
RIL.iccInfo.spn = spn;
let ICCUtilsHelper = this.context.ICCUtilsHelper;
ICCUtilsHelper.updateDisplayCondition();
ICCUtilsHelper.handleICCInfoChange();
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_SPN,
callback: callback.bind(this)
});
},
readIMG: function(recordNumber, onsuccess, onerror) {
function callback(options) {
let RIL = this.context.RIL;
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
let strLen = Buf.readInt32();
// Each octet is encoded into two chars.
let octetLen = strLen / 2;
let numInstances = GsmPDUHelper.readHexOctet();
// Data length is defined as 9n+1 or 9n+2. See TS 31.102, sub-clause
// 4.6.1.1. However, it's likely to have padding appended so we have a
// rather loose check.
if (octetLen < (9 * numInstances + 1)) {
Buf.seekIncoming((octetLen - 1) * Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(strLen);
if (onerror) {
onerror();
}
return;
}
let imgDescriptors = [];
for (let i = 0; i < numInstances; i++) {
imgDescriptors[i] = {
width: GsmPDUHelper.readHexOctet(),
height: GsmPDUHelper.readHexOctet(),
codingScheme: GsmPDUHelper.readHexOctet(),
fileId: (GsmPDUHelper.readHexOctet() << 8) |
GsmPDUHelper.readHexOctet(),
offset: (GsmPDUHelper.readHexOctet() << 8) |
GsmPDUHelper.readHexOctet(),
dataLen: (GsmPDUHelper.readHexOctet() << 8) |
GsmPDUHelper.readHexOctet()
};
}
Buf.seekIncoming((octetLen - 9 * numInstances - 1) * Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(strLen);
let instances = [];
let currentInstance = 0;
let readNextInstance = (function(img) {
instances[currentInstance] = img;
currentInstance++;
if (currentInstance < numInstances) {
let imgDescriptor = imgDescriptors[currentInstance];
this.readIIDF(imgDescriptor.fileId,
imgDescriptor.offset,
imgDescriptor.dataLen,
imgDescriptor.codingScheme,
readNextInstance,
onerror);
} else {
if (onsuccess) {
onsuccess(instances);
}
}
}).bind(this);
this.readIIDF(imgDescriptors[0].fileId,
imgDescriptors[0].offset,
imgDescriptors[0].dataLen,
imgDescriptors[0].codingScheme,
readNextInstance,
onerror);
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: ICC_EF_IMG,
recordNumber: recordNumber,
callback: callback.bind(this),
onerror: onerror
});
},
readIIDF: function(fileId, offset, dataLen, codingScheme, onsuccess, onerror) {
// Valid fileId is '4FXX', see TS 31.102, clause 4.6.1.2.
if ((fileId >> 8) != 0x4F) {
if (onerror) {
onerror();
}
return;
}
function callback() {
let Buf = this.context.Buf;
let RIL = this.context.RIL;
let GsmPDUHelper = this.context.GsmPDUHelper;
let strLen = Buf.readInt32();
// Each octet is encoded into two chars.
let octetLen = strLen / 2;
if (octetLen < offset + dataLen) {
// Data length is not enough. See TS 31.102, clause 4.6.1.1, the
// paragraph "Bytes 8 and 9: Length of Image Instance Data."
Buf.seekIncoming(octetLen * Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(strLen);
if (onerror) {
onerror();
}
return;
}
Buf.seekIncoming(offset * Buf.PDU_HEX_OCTET_SIZE);
let rawData = {
width: GsmPDUHelper.readHexOctet(),
height: GsmPDUHelper.readHexOctet(),
codingScheme: codingScheme
};
switch (codingScheme) {
case ICC_IMG_CODING_SCHEME_BASIC:
rawData.body = GsmPDUHelper.readHexOctetArray(
dataLen - ICC_IMG_HEADER_SIZE_BASIC);
Buf.seekIncoming((octetLen - offset - dataLen) * Buf.PDU_HEX_OCTET_SIZE);
break;
case ICC_IMG_CODING_SCHEME_COLOR:
case ICC_IMG_CODING_SCHEME_COLOR_TRANSPARENCY:
rawData.bitsPerImgPoint = GsmPDUHelper.readHexOctet();
let num = GsmPDUHelper.readHexOctet();
// The value 0 shall be interpreted as 256. See TS 31.102, Annex B.2.
rawData.numOfClutEntries = (num === 0) ? 0x100 : num;
rawData.clutOffset = (GsmPDUHelper.readHexOctet() << 8) |
GsmPDUHelper.readHexOctet();
rawData.body = GsmPDUHelper.readHexOctetArray(
dataLen - ICC_IMG_HEADER_SIZE_COLOR);
Buf.seekIncoming((rawData.clutOffset - offset - dataLen) *
Buf.PDU_HEX_OCTET_SIZE);
let clut = GsmPDUHelper.readHexOctetArray(rawData.numOfClutEntries *
ICC_CLUT_ENTRY_SIZE);
rawData.clut = clut;
}
Buf.readStringDelimiter(strLen);
if (onsuccess) {
onsuccess(rawData);
}
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: fileId,
pathId: this.context.ICCFileHelper.getEFPath(ICC_EF_IMG),
callback: callback.bind(this),
onerror: onerror
});
},
/**
* Read the (U)SIM Service Table from the (U)SIM.
*/
readSST: function() {
function callback() {
let Buf = this.context.Buf;
let RIL = this.context.RIL;
let strLen = Buf.readInt32();
// Each octet is encoded into two chars.
let octetLen = strLen / 2;
let sst = this.context.GsmPDUHelper.readHexOctetArray(octetLen);
Buf.readStringDelimiter(strLen);
RIL.iccInfoPrivate.sst = sst;
if (DEBUG) {
let str = "";
for (let i = 0; i < sst.length; i++) {
str += sst[i] + ", ";
}
this.context.debug("SST: " + str);
}
let ICCUtilsHelper = this.context.ICCUtilsHelper;
if (ICCUtilsHelper.isICCServiceAvailable("MSISDN")) {
if (DEBUG) this.context.debug("MSISDN: MSISDN is available");
this.readMSISDN();
} else {
if (DEBUG) this.context.debug("MSISDN: MSISDN service is not available");
}
// Fetch SPN and PLMN list, if some of them are available.
if (ICCUtilsHelper.isICCServiceAvailable("SPN")) {
if (DEBUG) this.context.debug("SPN: SPN is available");
this.readSPN();
} else {
if (DEBUG) this.context.debug("SPN: SPN service is not available");
}
if (ICCUtilsHelper.isICCServiceAvailable("MDN")) {
if (DEBUG) this.context.debug("MDN: MDN available.");
this.readMBDN();
} else {
if (DEBUG) this.context.debug("MDN: MDN service is not available");
if (ICCUtilsHelper.isCphsServiceAvailable("MBN")) {
// read CPHS_MBN in advance if MBDN is not available.
this.readCphsMBN();
} else {
if (DEBUG) this.context.debug("CPHS_MBN: CPHS_MBN service is not available");
}
}
if (ICCUtilsHelper.isICCServiceAvailable("MWIS")) {
if (DEBUG) this.context.debug("MWIS: MWIS is available");
this.readMWIS();
} else {
if (DEBUG) this.context.debug("MWIS: MWIS is not available");
}
if (ICCUtilsHelper.isICCServiceAvailable("SPDI")) {
if (DEBUG) this.context.debug("SPDI: SPDI available.");
this.readSPDI();
} else {
if (DEBUG) this.context.debug("SPDI: SPDI service is not available");
}
if (ICCUtilsHelper.isICCServiceAvailable("PNN")) {
if (DEBUG) this.context.debug("PNN: PNN is available");
this.readPNN();
} else {
if (DEBUG) this.context.debug("PNN: PNN is not available");
}
if (ICCUtilsHelper.isICCServiceAvailable("OPL")) {
if (DEBUG) this.context.debug("OPL: OPL is available");
this.readOPL();
} else {
if (DEBUG) this.context.debug("OPL: OPL is not available");
}
if (ICCUtilsHelper.isICCServiceAvailable("GID1")) {
if (DEBUG) this.context.debug("GID1: GID1 is available");
this.readGID1();
} else {
if (DEBUG) this.context.debug("GID1: GID1 is not available");
}
if (ICCUtilsHelper.isICCServiceAvailable("CBMI")) {
this.readCBMI();
} else {
RIL.cellBroadcastConfigs.CBMI = null;
}
if (ICCUtilsHelper.isICCServiceAvailable("DATA_DOWNLOAD_SMS_CB")) {
this.readCBMID();
} else {
RIL.cellBroadcastConfigs.CBMID = null;
}
if (ICCUtilsHelper.isICCServiceAvailable("CBMIR")) {
this.readCBMIR();
} else {
RIL.cellBroadcastConfigs.CBMIR = null;
}
RIL._mergeAllCellBroadcastConfigs();
}
// ICC_EF_UST has the same value with ICC_EF_SST.
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_SST,
callback: callback.bind(this)
});
},
/**
* Read (U)SIM MBDN. (Mailbox Dialling Number)
*
* @see TS 131.102, clause 4.2.60
*/
readMBDN: function() {
function callback(options) {
let RIL = this.context.RIL;
let contact =
this.context.ICCPDUHelper.readAlphaIdDiallingNumber(options.recordSize);
if ((!contact ||
((!contact.alphaId || contact.alphaId == "") &&
(!contact.number || contact.number == ""))) &&
this.context.ICCUtilsHelper.isCphsServiceAvailable("MBN")) {
// read CPHS_MBN in advance if MBDN is invalid or empty.
this.readCphsMBN();
return;
}
if (!contact ||
(RIL.iccInfoPrivate.mbdn !== undefined &&
RIL.iccInfoPrivate.mbdn === contact.number)) {
return;
}
RIL.iccInfoPrivate.mbdn = contact.number;
if (DEBUG) {
this.context.debug("MBDN, alphaId=" + contact.alphaId +
" number=" + contact.number);
}
contact.rilMessageType = "iccmbdn";
RIL.sendChromeMessage(contact);
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: ICC_EF_MBDN,
callback: callback.bind(this)
});
},
/**
* Read ICC MWIS. (Message Waiting Indication Status)
*
* @see TS 31.102, clause 4.2.63 for USIM and TS 51.011, clause 10.3.45 for SIM.
*/
readMWIS: function() {
function callback(options) {
let Buf = this.context.Buf;
let RIL = this.context.RIL;
let strLen = Buf.readInt32();
// Each octet is encoded into two chars.
let octetLen = strLen / 2;
let mwis = this.context.GsmPDUHelper.readHexOctetArray(octetLen);
Buf.readStringDelimiter(strLen);
if (!mwis) {
return;
}
RIL.iccInfoPrivate.mwis = mwis; //Keep raw MWIS for updateMWIS()
let mwi = {};
// b8 b7 B6 b5 b4 b3 b2 b1 4.2.63, TS 31.102 version 11.6.0
// | | | | | | | |__ Voicemail
// | | | | | | |_____ Fax
// | | | | | |________ Electronic Mail
// | | | | |___________ Other
// | | | |______________ Videomail
// |__|__|_________________ RFU
mwi.active = ((mwis[0] & 0x01) != 0);
if (mwi.active) {
// In TS 23.040 msgCount is in the range from 0 to 255.
// The value 255 shall be taken to mean 255 or greater.
//
// However, There is no definition about 0 when MWI is active.
//
// Normally, when mwi is active, the msgCount must be larger than 0.
// Refer to other reference phone,
// 0 is usually treated as UNKNOWN for storing 2nd level MWI status (DCS).
mwi.msgCount = (mwis[1] === 0) ? GECKO_VOICEMAIL_MESSAGE_COUNT_UNKNOWN
: mwis[1];
} else {
mwi.msgCount = 0;
}
RIL.sendChromeMessage({ rilMessageType: "iccmwis",
mwi: mwi });
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: ICC_EF_MWIS,
recordNumber: 1, // Get 1st Subscriber Profile.
callback: callback.bind(this)
});
},
/**
* Update ICC MWIS. (Message Waiting Indication Status)
*
* @see TS 31.102, clause 4.2.63 for USIM and TS 51.011, clause 10.3.45 for SIM.
*/
updateMWIS: function(mwi) {
let RIL = this.context.RIL;
if (!RIL.iccInfoPrivate.mwis) {
return;
}
function dataWriter(recordSize) {
let mwis = RIL.iccInfoPrivate.mwis;
let msgCount =
(mwi.msgCount === GECKO_VOICEMAIL_MESSAGE_COUNT_UNKNOWN) ? 0 : mwi.msgCount;
[mwis[0], mwis[1]] = (mwi.active) ? [(mwis[0] | 0x01), msgCount]
: [(mwis[0] & 0xFE), 0];
let strLen = recordSize * 2;
let Buf = this.context.Buf;
Buf.writeInt32(strLen);
let GsmPDUHelper = this.context.GsmPDUHelper;
for (let i = 0; i < mwis.length; i++) {
GsmPDUHelper.writeHexOctet(mwis[i]);
}
Buf.writeStringDelimiter(strLen);
}
this.context.ICCIOHelper.updateLinearFixedEF({
fileId: ICC_EF_MWIS,
recordNumber: 1, // Update 1st Subscriber Profile.
dataWriter: dataWriter.bind(this)
});
},
/**
* Read the SPDI (Service Provider Display Information) from the (U)SIM.
*
* See TS 131.102 section 4.2.66 for USIM and TS 51.011 section 10.3.50
* for SIM.
*/
readSPDI: function() {
function callback() {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
let octetLen = strLen / 2;
let readLen = 0;
let endLoop = false;
let RIL = this.context.RIL;
RIL.iccInfoPrivate.SPDI = null;
let GsmPDUHelper = this.context.GsmPDUHelper;
while ((readLen < octetLen) && !endLoop) {
let tlvTag = GsmPDUHelper.readHexOctet();
let tlvLen = GsmPDUHelper.readHexOctet();
readLen += 2; // For tag and length fields.
switch (tlvTag) {
case SPDI_TAG_SPDI:
// The value part itself is a TLV.
continue;
case SPDI_TAG_PLMN_LIST:
// This PLMN list is what we want.
RIL.iccInfoPrivate.SPDI = this.readPLMNEntries(tlvLen / 3);
readLen += tlvLen;
endLoop = true;
break;
default:
// We don't care about its content if its tag is not SPDI nor
// PLMN_LIST.
endLoop = true;
break;
}
}
// Consume unread octets.
Buf.seekIncoming((octetLen - readLen) * Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(strLen);
if (DEBUG) {
this.context.debug("SPDI: " + JSON.stringify(RIL.iccInfoPrivate.SPDI));
}
let ICCUtilsHelper = this.context.ICCUtilsHelper;
if (ICCUtilsHelper.updateDisplayCondition()) {
ICCUtilsHelper.handleICCInfoChange();
}
}
// PLMN List is Servive 51 in USIM, EF_SPDI
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_SPDI,
callback: callback.bind(this)
});
},
_readCbmiHelper: function(which) {
let RIL = this.context.RIL;
function callback() {
let Buf = this.context.Buf;
let strLength = Buf.readInt32();
// Each Message Identifier takes two octets and each octet is encoded
// into two chars.
let numIds = strLength / 4, list = null;
if (numIds) {
list = [];
let GsmPDUHelper = this.context.GsmPDUHelper;
for (let i = 0, id; i < numIds; i++) {
id = GsmPDUHelper.readHexOctet() << 8 | GsmPDUHelper.readHexOctet();
// `Unused entries shall be set to 'FF FF'.`
if (id != 0xFFFF) {
list.push(id);
list.push(id + 1);
}
}
}
if (DEBUG) {
this.context.debug(which + ": " + JSON.stringify(list));
}
Buf.readStringDelimiter(strLength);
RIL.cellBroadcastConfigs[which] = list;
RIL._mergeAllCellBroadcastConfigs();
}
function onerror() {
RIL.cellBroadcastConfigs[which] = null;
RIL._mergeAllCellBroadcastConfigs();
}
let fileId = GLOBAL["ICC_EF_" + which];
this.context.ICCIOHelper.loadTransparentEF({
fileId: fileId,
callback: callback.bind(this),
onerror: onerror.bind(this)
});
},
/**
* Read EFcbmi (Cell Broadcast Message Identifier selection)
*
* @see 3GPP TS 31.102 v110.02.0 section 4.2.14 EFcbmi
* @see 3GPP TS 51.011 v5.0.0 section 10.3.13 EFcbmi
*/
readCBMI: function() {
this._readCbmiHelper("CBMI");
},
/**
* Read EFcbmid (Cell Broadcast Message Identifier for Data Download)
*
* @see 3GPP TS 31.102 v110.02.0 section 4.2.20 EFcbmid
* @see 3GPP TS 51.011 v5.0.0 section 10.3.26 EFcbmid
*/
readCBMID: function() {
this._readCbmiHelper("CBMID");
},
/**
* Read EFcbmir (Cell Broadcast Message Identifier Range selection)
*
* @see 3GPP TS 31.102 v110.02.0 section 4.2.22 EFcbmir
* @see 3GPP TS 51.011 v5.0.0 section 10.3.28 EFcbmir
*/
readCBMIR: function() {
let RIL = this.context.RIL;
function callback() {
let Buf = this.context.Buf;
let strLength = Buf.readInt32();
// Each Message Identifier range takes four octets and each octet is
// encoded into two chars.
let numIds = strLength / 8, list = null;
if (numIds) {
list = [];
let GsmPDUHelper = this.context.GsmPDUHelper;
for (let i = 0, from, to; i < numIds; i++) {
// `Bytes one and two of each range identifier equal the lower value
// of a cell broadcast range, bytes three and four equal the upper
// value of a cell broadcast range.`
from = GsmPDUHelper.readHexOctet() << 8 | GsmPDUHelper.readHexOctet();
to = GsmPDUHelper.readHexOctet() << 8 | GsmPDUHelper.readHexOctet();
// `Unused entries shall be set to 'FF FF'.`
if ((from != 0xFFFF) && (to != 0xFFFF)) {
list.push(from);
list.push(to + 1);
}
}
}
if (DEBUG) {
this.context.debug("CBMIR: " + JSON.stringify(list));
}
Buf.readStringDelimiter(strLength);
RIL.cellBroadcastConfigs.CBMIR = list;
RIL._mergeAllCellBroadcastConfigs();
}
function onerror() {
RIL.cellBroadcastConfigs.CBMIR = null;
RIL._mergeAllCellBroadcastConfigs();
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_CBMIR,
callback: callback.bind(this),
onerror: onerror.bind(this)
});
},
/**
* Read OPL (Operator PLMN List) from (U)SIM.
*
* See 3GPP TS 31.102 Sec. 4.2.59 for USIM
* 3GPP TS 51.011 Sec. 10.3.42 for SIM.
*/
readOPL: function() {
let ICCIOHelper = this.context.ICCIOHelper;
let opl = [];
function callback(options) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
let strLen = Buf.readInt32();
// The first 7 bytes are LAI (for UMTS) and the format of LAI is defined
// in 3GPP TS 23.003, Sec 4.1
// +-------------+---------+
// | Octet 1 - 3 | MCC/MNC |
// +-------------+---------+
// | Octet 4 - 7 | LAC |
// +-------------+---------+
let mccMnc = [GsmPDUHelper.readHexOctet(),
GsmPDUHelper.readHexOctet(),
GsmPDUHelper.readHexOctet()];
if (mccMnc[0] != 0xFF || mccMnc[1] != 0xFF || mccMnc[2] != 0xFF) {
let oplElement = {};
let semiOctets = [];
for (let i = 0; i < mccMnc.length; i++) {
semiOctets.push((mccMnc[i] & 0xf0) >> 4);
semiOctets.push(mccMnc[i] & 0x0f);
}
let reformat = [semiOctets[1], semiOctets[0], semiOctets[3],
semiOctets[5], semiOctets[4], semiOctets[2]];
let buf = "";
for (let i = 0; i < reformat.length; i++) {
if (reformat[i] != 0xF) {
buf += GsmPDUHelper.semiOctetToExtendedBcdChar(reformat[i]);
}
if (i === 2) {
// 0-2: MCC
oplElement.mcc = buf;
buf = "";
} else if (i === 5) {
// 3-5: MNC
oplElement.mnc = buf;
}
}
// LAC/TAC
oplElement.lacTacStart =
(GsmPDUHelper.readHexOctet() << 8) | GsmPDUHelper.readHexOctet();
oplElement.lacTacEnd =
(GsmPDUHelper.readHexOctet() << 8) | GsmPDUHelper.readHexOctet();
// PLMN Network Name Record Identifier
oplElement.pnnRecordId = GsmPDUHelper.readHexOctet();
if (DEBUG) {
this.context.debug("OPL: [" + (opl.length + 1) + "]: " +
JSON.stringify(oplElement));
}
opl.push(oplElement);
} else {
Buf.seekIncoming(5 * Buf.PDU_HEX_OCTET_SIZE);
}
Buf.readStringDelimiter(strLen);
let RIL = this.context.RIL;
if (options.p1 < options.totalRecords) {
ICCIOHelper.loadNextRecord(options);
} else {
RIL.iccInfoPrivate.OPL = opl;
RIL.overrideICCNetworkName();
}
}
ICCIOHelper.loadLinearFixedEF({fileId: ICC_EF_OPL,
callback: callback.bind(this)});
},
/**
* Read PNN (PLMN Network Name) from (U)SIM.
*
* See 3GPP TS 31.102 Sec. 4.2.58 for USIM
* 3GPP TS 51.011 Sec. 10.3.41 for SIM.
*/
readPNN: function() {
let ICCIOHelper = this.context.ICCIOHelper;
function callback(options) {
let pnnElement;
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
let octetLen = strLen / 2;
let readLen = 0;
let GsmPDUHelper = this.context.GsmPDUHelper;
while (readLen < octetLen) {
let tlvTag = GsmPDUHelper.readHexOctet();
if (tlvTag == 0xFF) {
// Unused byte
readLen++;
Buf.seekIncoming((octetLen - readLen) * Buf.PDU_HEX_OCTET_SIZE);
break;
}
// Needs this check to avoid initializing twice.
pnnElement = pnnElement || {};
let tlvLen = GsmPDUHelper.readHexOctet();
switch (tlvTag) {
case PNN_IEI_FULL_NETWORK_NAME:
pnnElement.fullName = GsmPDUHelper.readNetworkName(tlvLen);
break;
case PNN_IEI_SHORT_NETWORK_NAME:
pnnElement.shortName = GsmPDUHelper.readNetworkName(tlvLen);
break;
default:
Buf.seekIncoming(tlvLen * Buf.PDU_HEX_OCTET_SIZE);
break;
}
readLen += (tlvLen + 2); // +2 for tlvTag and tlvLen
}
Buf.readStringDelimiter(strLen);
pnn.push(pnnElement);
let RIL = this.context.RIL;
if (options.p1 < options.totalRecords) {
ICCIOHelper.loadNextRecord(options);
} else {
if (DEBUG) {
for (let i = 0; i < pnn.length; i++) {
this.context.debug("PNN: [" + i + "]: " + JSON.stringify(pnn[i]));
}
}
RIL.iccInfoPrivate.PNN = pnn;
RIL.overrideICCNetworkName();
}
}
let pnn = [];
ICCIOHelper.loadLinearFixedEF({fileId: ICC_EF_PNN,
callback: callback.bind(this)});
},
/**
* Read the list of PLMN (Public Land Mobile Network) entries
* We cannot directly rely on readSwappedNibbleBcdToString(),
* since it will no correctly handle some corner-cases that are
* not a problem in our case (0xFF 0xFF 0xFF).
*
* @param length The number of PLMN records.
* @return An array of string corresponding to the PLMNs.
*/
readPLMNEntries: function(length) {
let plmnList = [];
// Each PLMN entry has 3 bytes.
if (DEBUG) {
this.context.debug("PLMN entries length = " + length);
}
let GsmPDUHelper = this.context.GsmPDUHelper;
let index = 0;
while (index < length) {
// Unused entries will be 0xFFFFFF, according to EF_SPDI
// specs (TS 131 102, section 4.2.66)
try {
let plmn = [GsmPDUHelper.readHexOctet(),
GsmPDUHelper.readHexOctet(),
GsmPDUHelper.readHexOctet()];
if (DEBUG) {
this.context.debug("Reading PLMN entry: [" + index + "]: '" + plmn + "'");
}
if (plmn[0] != 0xFF &&
plmn[1] != 0xFF &&
plmn[2] != 0xFF) {
let semiOctets = [];
for (let idx = 0; idx < plmn.length; idx++) {
semiOctets.push((plmn[idx] & 0xF0) >> 4);
semiOctets.push(plmn[idx] & 0x0F);
}
// According to TS 24.301, 9.9.3.12, the semi octets is arranged
// in format:
// Byte 1: MCC[2] | MCC[1]
// Byte 2: MNC[3] | MCC[3]
// Byte 3: MNC[2] | MNC[1]
// Therefore, we need to rearrange them.
let reformat = [semiOctets[1], semiOctets[0], semiOctets[3],
semiOctets[5], semiOctets[4], semiOctets[2]];
let buf = "";
let plmnEntry = {};
for (let i = 0; i < reformat.length; i++) {
if (reformat[i] != 0xF) {
buf += GsmPDUHelper.semiOctetToExtendedBcdChar(reformat[i]);
}
if (i === 2) {
// 0-2: MCC
plmnEntry.mcc = buf;
buf = "";
} else if (i === 5) {
// 3-5: MNC
plmnEntry.mnc = buf;
}
}
if (DEBUG) {
this.context.debug("PLMN = " + plmnEntry.mcc + ", " + plmnEntry.mnc);
}
plmnList.push(plmnEntry);
}
} catch (e) {
if (DEBUG) {
this.context.debug("PLMN entry " + index + " is invalid.");
}
break;
}
index ++;
}
return plmnList;
},
/**
* Read the SMS from the ICC.
*
* @param recordNumber The number of the record shall be loaded.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readSMS: function(recordNumber, onsuccess, onerror) {
function callback(options) {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
// TS 51.011, 10.5.3 EF_SMS
// b3 b2 b1
// 0 0 1 message received by MS from network; message read
// 0 1 1 message received by MS from network; message to be read
// 1 1 1 MS originating message; message to be sent
// 1 0 1 MS originating message; message sent to the network:
let GsmPDUHelper = this.context.GsmPDUHelper;
let status = GsmPDUHelper.readHexOctet();
let message = GsmPDUHelper.readMessage();
message.simStatus = status;
// Consumes the remaining buffer
Buf.seekIncoming(Buf.getReadAvailable() - Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(strLen);
if (message) {
onsuccess(message);
} else {
onerror("Failed to decode SMS on SIM #" + recordNumber);
}
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: ICC_EF_SMS,
recordNumber: recordNumber,
callback: callback.bind(this),
onerror: onerror
});
},
readGID1: function() {
function callback() {
let Buf = this.context.Buf;
let RIL = this.context.RIL;
RIL.iccInfoPrivate.gid1 = Buf.readString();
if (DEBUG) {
this.context.debug("GID1: " + RIL.iccInfoPrivate.gid1);
}
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_GID1,
callback: callback.bind(this)
});
},
/**
* Read CPHS Phase & Service Table from CPHS Info.
*
* @See B.3.1.1 CPHS Information in CPHS Phase 2.
*
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readCphsInfo: function(onsuccess, onerror) {
function callback() {
try {
let Buf = this.context.Buf;
let RIL = this.context.RIL;
let strLen = Buf.readInt32();
// Each octet is encoded into two chars.
let octetLen = strLen / 2;
let cphsInfo = this.context.GsmPDUHelper.readHexOctetArray(octetLen);
Buf.readStringDelimiter(strLen);
if (DEBUG) {
let str = "";
for (let i = 0; i < cphsInfo.length; i++) {
str += cphsInfo[i] + ", ";
}
this.context.debug("CPHS INFO: " + str);
}
/**
* CPHS INFORMATION
*
* Byte 1: CPHS Phase
* 01 phase 1
* 02 phase 2
* etc.
*
* Byte 2: CPHS Service Table
* +----+----+----+----+----+----+----+----+
* | b8 | b7 | b6 | b5 | b4 | b3 | b2 | b1 |
* +----+----+----+----+----+----+----+----+
* | ONSF | MBN | SST | CSP |
* | Phase 2 | ALL | Phase 1 | All |
* +----+----+----+----+----+----+----+----+
*
* Byte 3: CPHS Service Table continued
* +----+----+----+----+----+----+----+----+
* | b8 | b7 | b6 | b5 | b4 | b3 | b2 | b1 |
* +----+----+----+----+----+----+----+----+
* | RFU | RFU | RFU | INFO_NUM|
* | | | | Phase 2 |
* +----+----+----+----+----+----+----+----+
*/
let cphsPhase = cphsInfo[0];
if (cphsPhase == 1) {
// Clear 'Phase 2 only' services.
cphsInfo[1] &= 0x3F;
// We don't know whether Byte 3 is available in CPHS phase 1 or not.
// Add boundary check before accessing it.
if (cphsInfo.length > 2) {
cphsInfo[2] = 0x00;
}
} else if (cphsPhase == 2) {
// Clear 'Phase 1 only' services.
cphsInfo[1] &= 0xF3;
} else {
throw new Error("Unknown CPHS phase: " + cphsPhase);
}
RIL.iccInfoPrivate.cphsSt = cphsInfo.subarray(1);
onsuccess();
} catch(e) {
onerror(e.toString());
}
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_CPHS_INFO,
callback: callback.bind(this),
onerror: onerror
});
},
/**
* Read CPHS MBN. (Mailbox Numbers)
*
* @See B.4.2.2 Voice Message Retrieval and Indicator Clearing
*/
readCphsMBN: function() {
function callback(options) {
let RIL = this.context.RIL;
let contact =
this.context.ICCPDUHelper.readAlphaIdDiallingNumber(options.recordSize);
if (!contact ||
(RIL.iccInfoPrivate.mbdn !== undefined &&
RIL.iccInfoPrivate.mbdn === contact.number)) {
return;
}
RIL.iccInfoPrivate.mbdn = contact.number;
if (DEBUG) {
this.context.debug("CPHS_MDN, alphaId=" + contact.alphaId +
" number=" + contact.number);
}
contact.rilMessageType = "iccmbdn";
RIL.sendChromeMessage(contact);
}
this.context.ICCIOHelper.loadLinearFixedEF({
fileId: ICC_EF_CPHS_MBN,
callback: callback.bind(this)
});
}
};
function RuimRecordHelperObject(aContext) {
this.context = aContext;
}
RuimRecordHelperObject.prototype = {
context: null,
fetchRuimRecords: function() {
this.getIMSI_M();
this.readCST();
this.readCDMAHome();
this.context.RIL.getCdmaSubscription();
},
/**
* Get IMSI_M from CSIM/RUIM.
* See 3GPP2 C.S0065 Sec. 5.2.2
*/
getIMSI_M: function() {
function callback() {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
let encodedImsi = this.context.GsmPDUHelper.readHexOctetArray(strLen / 2);
Buf.readStringDelimiter(strLen);
if ((encodedImsi[CSIM_IMSI_M_PROGRAMMED_BYTE] & 0x80)) { // IMSI_M programmed
let RIL = this.context.RIL;
RIL.iccInfoPrivate.imsi = this.decodeIMSI(encodedImsi);
RIL.sendChromeMessage({rilMessageType: "iccimsi",
imsi: RIL.iccInfoPrivate.imsi});
let ICCUtilsHelper = this.context.ICCUtilsHelper;
let mccMnc = ICCUtilsHelper.parseMccMncFromImsi(RIL.iccInfoPrivate.imsi);
if (mccMnc) {
RIL.iccInfo.mcc = mccMnc.mcc;
RIL.iccInfo.mnc = mccMnc.mnc;
ICCUtilsHelper.handleICCInfoChange();
}
}
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_CSIM_IMSI_M,
callback: callback.bind(this)
});
},
/**
* Decode IMSI from IMSI_M
* See 3GPP2 C.S0005 Sec. 2.3.1
* +---+---------+------------+---+--------+---------+---+---------+--------+
* |RFU| MCC | programmed |RFU| MNC | MIN1 |RFU| MIN2 | CLASS |
* +---+---------+------------+---+--------+---------+---+---------+--------+
* | 6 | 10 bits | 8 bits | 1 | 7 bits | 24 bits | 6 | 10 bits | 8 bits |
* +---+---------+------------+---+--------+---------+---+---------+--------+
*/
decodeIMSI: function(encodedImsi) {
// MCC: 10 bits, 3 digits
let encodedMCC = ((encodedImsi[CSIM_IMSI_M_MCC_BYTE + 1] & 0x03) << 8) +
(encodedImsi[CSIM_IMSI_M_MCC_BYTE] & 0xff);
let mcc = this.decodeIMSIValue(encodedMCC, 3);
// MNC: 7 bits, 2 digits
let encodedMNC = encodedImsi[CSIM_IMSI_M_MNC_BYTE] & 0x7f;
let mnc = this.decodeIMSIValue(encodedMNC, 2);
// MIN2: 10 bits, 3 digits
let encodedMIN2 = ((encodedImsi[CSIM_IMSI_M_MIN2_BYTE + 1] & 0x03) << 8) +
(encodedImsi[CSIM_IMSI_M_MIN2_BYTE] & 0xff);
let min2 = this.decodeIMSIValue(encodedMIN2, 3);
// MIN1: 10+4+10 bits, 3+1+3 digits
let encodedMIN1First3 = ((encodedImsi[CSIM_IMSI_M_MIN1_BYTE + 2] & 0xff) << 2) +
((encodedImsi[CSIM_IMSI_M_MIN1_BYTE + 1] & 0xc0) >> 6);
let min1First3 = this.decodeIMSIValue(encodedMIN1First3, 3);
let encodedFourthDigit = (encodedImsi[CSIM_IMSI_M_MIN1_BYTE + 1] & 0x3c) >> 2;
if (encodedFourthDigit > 9) {
encodedFourthDigit = 0;
}
let fourthDigit = encodedFourthDigit.toString();
let encodedMIN1Last3 = ((encodedImsi[CSIM_IMSI_M_MIN1_BYTE + 1] & 0x03) << 8) +
(encodedImsi[CSIM_IMSI_M_MIN1_BYTE] & 0xff);
let min1Last3 = this.decodeIMSIValue(encodedMIN1Last3, 3);
return mcc + mnc + min2 + min1First3 + fourthDigit + min1Last3;
},
/**
* Decode IMSI Helper function
* See 3GPP2 C.S0005 section 2.3.1.1
*/
decodeIMSIValue: function(encoded, length) {
let offset = length === 3 ? 111 : 11;
let value = encoded + offset;
for (let base = 10, temp = value, i = 0; i < length; i++) {
if (temp % 10 === 0) {
value -= base;
}
temp = Math.floor(value / base);
base = base * 10;
}
let s = value.toString();
while (s.length < length) {
s = "0" + s;
}
return s;
},
/**
* Read CDMAHOME for CSIM.
* See 3GPP2 C.S0023 Sec. 3.4.8.
*/
readCDMAHome: function() {
let ICCIOHelper = this.context.ICCIOHelper;
function callback(options) {
let Buf = this.context.Buf;
let GsmPDUHelper = this.context.GsmPDUHelper;
let strLen = Buf.readInt32();
let tempOctet = GsmPDUHelper.readHexOctet();
cdmaHomeSystemId.push(((GsmPDUHelper.readHexOctet() & 0x7f) << 8) | tempOctet);
tempOctet = GsmPDUHelper.readHexOctet();
cdmaHomeNetworkId.push(((GsmPDUHelper.readHexOctet() & 0xff) << 8) | tempOctet);
// Consuming the last octet: band class.
Buf.seekIncoming(Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(strLen);
if (options.p1 < options.totalRecords) {
ICCIOHelper.loadNextRecord(options);
} else {
if (DEBUG) {
this.context.debug("CDMAHome system id: " +
JSON.stringify(cdmaHomeSystemId));
this.context.debug("CDMAHome network id: " +
JSON.stringify(cdmaHomeNetworkId));
}
this.context.RIL.cdmaHome = {
systemId: cdmaHomeSystemId,
networkId: cdmaHomeNetworkId
};
}
}
let cdmaHomeSystemId = [], cdmaHomeNetworkId = [];
ICCIOHelper.loadLinearFixedEF({fileId: ICC_EF_CSIM_CDMAHOME,
callback: callback.bind(this)});
},
/**
* Read CDMA Service Table.
* See 3GPP2 C.S0023 Sec. 3.4.18
*/
readCST: function() {
function callback() {
let Buf = this.context.Buf;
let RIL = this.context.RIL;
let strLen = Buf.readInt32();
// Each octet is encoded into two chars.
RIL.iccInfoPrivate.cst =
this.context.GsmPDUHelper.readHexOctetArray(strLen / 2);
Buf.readStringDelimiter(strLen);
if (DEBUG) {
let str = "";
for (let i = 0; i < RIL.iccInfoPrivate.cst.length; i++) {
str += RIL.iccInfoPrivate.cst[i] + ", ";
}
this.context.debug("CST: " + str);
}
if (this.context.ICCUtilsHelper.isICCServiceAvailable("SPN")) {
if (DEBUG) this.context.debug("SPN: SPN is available");
this.readSPN();
}
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_CSIM_CST,
callback: callback.bind(this)
});
},
readSPN: function() {
function callback() {
let Buf = this.context.Buf;
let strLen = Buf.readInt32();
let octetLen = strLen / 2;
let GsmPDUHelper = this.context.GsmPDUHelper;
let displayCondition = GsmPDUHelper.readHexOctet();
let codingScheme = GsmPDUHelper.readHexOctet();
// Skip one octet: language indicator.
Buf.seekIncoming(Buf.PDU_HEX_OCTET_SIZE);
let readLen = 3;
// SPN String ends up with 0xff.
let userDataBuffer = [];
while (readLen < octetLen) {
let octet = GsmPDUHelper.readHexOctet();
readLen++;
if (octet == 0xff) {
break;
}
userDataBuffer.push(octet);
}
this.context.BitBufferHelper.startRead(userDataBuffer);
let CdmaPDUHelper = this.context.CdmaPDUHelper;
let msgLen;
switch (CdmaPDUHelper.getCdmaMsgEncoding(codingScheme)) {
case PDU_DCS_MSG_CODING_7BITS_ALPHABET:
msgLen = Math.floor(userDataBuffer.length * 8 / 7);
break;
case PDU_DCS_MSG_CODING_8BITS_ALPHABET:
msgLen = userDataBuffer.length;
break;
case PDU_DCS_MSG_CODING_16BITS_ALPHABET:
msgLen = Math.floor(userDataBuffer.length / 2);
break;
}
let RIL = this.context.RIL;
RIL.iccInfo.spn = CdmaPDUHelper.decodeCdmaPDUMsg(codingScheme, null, msgLen);
if (DEBUG) {
this.context.debug("CDMA SPN: " + RIL.iccInfo.spn +
", Display condition: " + displayCondition);
}
RIL.iccInfoPrivate.spnDisplayCondition = displayCondition;
Buf.seekIncoming((octetLen - readLen) * Buf.PDU_HEX_OCTET_SIZE);
Buf.readStringDelimiter(strLen);
}
this.context.ICCIOHelper.loadTransparentEF({
fileId: ICC_EF_CSIM_SPN,
callback: callback.bind(this)
});
}
};
/**
* Helper functions for ICC utilities.
*/
function ICCUtilsHelperObject(aContext) {
this.context = aContext;
}
ICCUtilsHelperObject.prototype = {
context: null,
/**
* Get network names by using EF_OPL and EF_PNN
*
* @See 3GPP TS 31.102 sec. 4.2.58 and sec. 4.2.59 for USIM,
* 3GPP TS 51.011 sec. 10.3.41 and sec. 10.3.42 for SIM.
*
* @param mcc The mobile country code of the network.
* @param mnc The mobile network code of the network.
* @param lac The location area code of the network.
*/
getNetworkNameFromICC: function(mcc, mnc, lac) {
let RIL = this.context.RIL;
let iccInfoPriv = RIL.iccInfoPrivate;
let iccInfo = RIL.iccInfo;
let pnnEntry;
if (!mcc || !mnc || lac == null || lac < 0) {
return null;
}
// We won't get network name if there is no PNN file.
if (!iccInfoPriv.PNN) {
return null;
}
if (!this.isICCServiceAvailable("OPL")) {
// When OPL is not present:
// According to 3GPP TS 31.102 Sec. 4.2.58 and 3GPP TS 51.011 Sec. 10.3.41,
// If EF_OPL is not present, the first record in this EF is used for the
// default network name when registered to the HPLMN.
// If we haven't get pnnEntry assigned, we should try to assign default
// value to it.
if (mcc == iccInfo.mcc && mnc == iccInfo.mnc) {
pnnEntry = iccInfoPriv.PNN[0];
}
} else {
let GsmPDUHelper = this.context.GsmPDUHelper;
let wildChar = GsmPDUHelper.extendedBcdChars.charAt(0x0d);
// According to 3GPP TS 31.102 Sec. 4.2.59 and 3GPP TS 51.011 Sec. 10.3.42,
// the ME shall use this EF_OPL in association with the EF_PNN in place
// of any network name stored within the ME's internal list and any network
// name received when registered to the PLMN.
let length = iccInfoPriv.OPL ? iccInfoPriv.OPL.length : 0;
for (let i = 0; i < length; i++) {
let unmatch = false;
let opl = iccInfoPriv.OPL[i];
// Try to match the MCC/MNC. Besides, A BCD value of 'D' in any of the
// MCC and/or MNC digits shall be used to indicate a "wild" value for
// that corresponding MCC/MNC digit.
if (opl.mcc.indexOf(wildChar) !== -1) {
for (let j = 0; j < opl.mcc.length; j++) {
if (opl.mcc[j] !== wildChar && opl.mcc[j] !== mcc[j]) {
unmatch = true;
break;
}
}
if (unmatch) {
continue;
}
} else {
if (mcc !== opl.mcc) {
continue;
}
}
if (mnc.length !== opl.mnc.length) {
continue;
}
if (opl.mnc.indexOf(wildChar) !== -1) {
for (let j = 0; j < opl.mnc.length; j++) {
if (opl.mnc[j] !== wildChar && opl.mnc[j] !== mnc[j]) {
unmatch = true;
break;
}
}
if (unmatch) {
continue;
}
} else {
if (mnc !== opl.mnc) {
continue;
}
}
// Try to match the location area code. If current local area code is
// covered by lac range that specified in the OPL entry, use the PNN
// that specified in the OPL entry.
if ((opl.lacTacStart === 0x0 && opl.lacTacEnd == 0xFFFE) ||
(opl.lacTacStart <= lac && opl.lacTacEnd >= lac)) {
if (opl.pnnRecordId === 0) {
// See 3GPP TS 31.102 Sec. 4.2.59 and 3GPP TS 51.011 Sec. 10.3.42,
// A value of '00' indicates that the name is to be taken from other
// sources.
return null;
}
pnnEntry = iccInfoPriv.PNN[opl.pnnRecordId - 1];
break;
}
}
}
if (!pnnEntry) {
return null;
}
// Return a new object to avoid global variable, PNN, be modified by accident.
return { fullName: pnnEntry.fullName || "",
shortName: pnnEntry.shortName || "" };
},
/**
* This will compute the spnDisplay field of the network.
* See TS 22.101 Annex A and TS 51.011 10.3.11 for details.
*
* @return True if some of iccInfo is changed in by this function.
*/
updateDisplayCondition: function() {
let RIL = this.context.RIL;
// If EFspn isn't existed in SIM or it haven't been read yet, we should
// just set isDisplayNetworkNameRequired = true and
// isDisplaySpnRequired = false
let iccInfo = RIL.iccInfo;
let iccInfoPriv = RIL.iccInfoPrivate;
let displayCondition = iccInfoPriv.spnDisplayCondition;
let origIsDisplayNetworkNameRequired = iccInfo.isDisplayNetworkNameRequired;
let origIsDisplaySPNRequired = iccInfo.isDisplaySpnRequired;
if (displayCondition === undefined) {
iccInfo.isDisplayNetworkNameRequired = true;
iccInfo.isDisplaySpnRequired = false;
} else if (RIL._isCdma) {
// CDMA family display rule.
let cdmaHome = RIL.cdmaHome;
let cell = RIL.voiceRegistrationState.cell;
let sid = cell && cell.cdmaSystemId;
let nid = cell && cell.cdmaNetworkId;
iccInfo.isDisplayNetworkNameRequired = false;
// If display condition is 0x0, we don't even need to check network id
// or system id.
if (displayCondition === 0x0) {
iccInfo.isDisplaySpnRequired = false;
} else {
// CDMA SPN Display condition dosen't specify whenever network name is
// reqired.
if (!cdmaHome ||
!cdmaHome.systemId ||
cdmaHome.systemId.length === 0 ||
cdmaHome.systemId.length != cdmaHome.networkId.length ||
!sid || !nid) {
// CDMA Home haven't been ready, or we haven't got the system id and
// network id of the network we register to, assuming we are in home
// network.
iccInfo.isDisplaySpnRequired = true;
} else {
// Determine if we are registered in the home service area.
// System ID and Network ID are described in 3GPP2 C.S0005 Sec. 2.6.5.2.
let inHomeArea = false;
for (let i = 0; i < cdmaHome.systemId.length; i++) {
let homeSid = cdmaHome.systemId[i],
homeNid = cdmaHome.networkId[i];
if (homeSid === 0 || homeNid === 0 // Reserved system id/network id
|| homeSid != sid) {
continue;
}
// According to 3GPP2 C.S0005 Sec. 2.6.5.2, NID number 65535 means
// all networks in the system should be considered as home.
if (homeNid == 65535 || homeNid == nid) {
inHomeArea = true;
break;
}
}
iccInfo.isDisplaySpnRequired = inHomeArea;
}
}
} else {
// GSM family display rule.
let operatorMnc = RIL.operator ? RIL.operator.mnc : -1;
let operatorMcc = RIL.operator ? RIL.operator.mcc : -1;
// First detect if we are on HPLMN or one of the PLMN
// specified by the SIM card.
let isOnMatchingPlmn = false;
// If the current network is the one defined as mcc/mnc
// in SIM card, it's okay.
if (iccInfo.mcc == operatorMcc && iccInfo.mnc == operatorMnc) {
isOnMatchingPlmn = true;
}
// Test to see if operator's mcc/mnc match mcc/mnc of PLMN.
if (!isOnMatchingPlmn && iccInfoPriv.SPDI) {
let iccSpdi = iccInfoPriv.SPDI; // PLMN list
for (let plmn in iccSpdi) {
let plmnMcc = iccSpdi[plmn].mcc;
let plmnMnc = iccSpdi[plmn].mnc;
isOnMatchingPlmn = (plmnMcc == operatorMcc) && (plmnMnc == operatorMnc);
if (isOnMatchingPlmn) {
break;
}
}
}
// See 3GPP TS 22.101 A.4 Service Provider Name indication, and TS 31.102
// clause 4.2.12 EF_SPN for detail.
if (isOnMatchingPlmn) {
// The first bit of display condition tells us if we should display
// registered PLMN.
if (DEBUG) {
this.context.debug("PLMN is HPLMN or PLMN " + "is in PLMN list");
}
// TS 31.102 Sec. 4.2.66 and TS 51.011 Sec. 10.3.50
// EF_SPDI contains a list of PLMNs in which the Service Provider Name
// shall be displayed.
iccInfo.isDisplaySpnRequired = true;
iccInfo.isDisplayNetworkNameRequired = (displayCondition & 0x01) !== 0;
} else {
// The second bit of display condition tells us if we should display
// registered PLMN.
if (DEBUG) {
this.context.debug("PLMN isn't HPLMN and PLMN isn't in PLMN list");
}
iccInfo.isDisplayNetworkNameRequired = true;
iccInfo.isDisplaySpnRequired = (displayCondition & 0x02) === 0;
}
}
if (DEBUG) {
this.context.debug("isDisplayNetworkNameRequired = " +
iccInfo.isDisplayNetworkNameRequired);
this.context.debug("isDisplaySpnRequired = " + iccInfo.isDisplaySpnRequired);
}
return ((origIsDisplayNetworkNameRequired !== iccInfo.isDisplayNetworkNameRequired) ||
(origIsDisplaySPNRequired !== iccInfo.isDisplaySpnRequired));
},
decodeSimTlvs: function(tlvsLen) {
let GsmPDUHelper = this.context.GsmPDUHelper;
let index = 0;
let tlvs = [];
while (index < tlvsLen) {
let simTlv = {
tag : GsmPDUHelper.readHexOctet(),
length : GsmPDUHelper.readHexOctet(),
};
simTlv.value = GsmPDUHelper.readHexOctetArray(simTlv.length);
tlvs.push(simTlv);
index += simTlv.length + 2; // The length of 'tag' and 'length' field.
}
return tlvs;
},
/**
* Parse those TLVs and convert it to an object.
*/
parsePbrTlvs: function(pbrTlvs) {
let pbr = {};
for (let i = 0; i < pbrTlvs.length; i++) {
let pbrTlv = pbrTlvs[i];
let anrIndex = 0;
for (let j = 0; j < pbrTlv.value.length; j++) {
let tlv = pbrTlv.value[j];
let tagName = USIM_TAG_NAME[tlv.tag];
// ANR could have multiple files. We save it as anr0, anr1,...etc.
if (tlv.tag == ICC_USIM_EFANR_TAG) {
tagName += anrIndex;
anrIndex++;
}
pbr[tagName] = tlv;
pbr[tagName].fileType = pbrTlv.tag;
pbr[tagName].fileId = (tlv.value[0] << 8) | tlv.value[1];
pbr[tagName].sfi = tlv.value[2];
// For Type 2, the order of files is in the same order in IAP.
if (pbrTlv.tag == ICC_USIM_TYPE2_TAG) {
pbr[tagName].indexInIAP = j;
}
}
}
return pbr;
},
/**
* Update the ICC information to RadioInterfaceLayer.
*/
handleICCInfoChange: function() {
let RIL = this.context.RIL;
RIL.iccInfo.rilMessageType = "iccinfochange";
RIL.sendChromeMessage(RIL.iccInfo);
},
/**
* Get whether specificed (U)SIM service is available.
*
* @param geckoService
* Service name like "ADN", "BDN", etc.
*
* @return true if the service is enabled, false otherwise.
*/
isICCServiceAvailable: function(geckoService) {
let RIL = this.context.RIL;
let serviceTable = RIL._isCdma ? RIL.iccInfoPrivate.cst:
RIL.iccInfoPrivate.sst;
let index, bitmask;
if (RIL.appType == CARD_APPTYPE_SIM || RIL.appType == CARD_APPTYPE_RUIM) {
/**
* Service id is valid in 1..N, and 2 bits are used to code each service.
*
* +----+-- --+----+----+
* | b8 | ... | b2 | b1 |
* +----+-- --+----+----+
*
* b1 = 0, service not allocated.
* 1, service allocated.
* b2 = 0, service not activated.
* 1, service activated.
*
* @see 3GPP TS 51.011 10.3.7.
*/
let simService;
if (RIL.appType == CARD_APPTYPE_SIM) {
simService = GECKO_ICC_SERVICES.sim[geckoService];
} else {
simService = GECKO_ICC_SERVICES.ruim[geckoService];
}
if (!simService) {
return false;
}
simService -= 1;
index = Math.floor(simService / 4);
bitmask = 2 << ((simService % 4) << 1);
} else if (RIL.appType == CARD_APPTYPE_USIM) {
/**
* Service id is valid in 1..N, and 1 bit is used to code each service.
*
* +----+-- --+----+----+
* | b8 | ... | b2 | b1 |
* +----+-- --+----+----+
*
* b1 = 0, service not avaiable.
* 1, service available.
*
* @see 3GPP TS 31.102 4.2.8.
*/
let usimService = GECKO_ICC_SERVICES.usim[geckoService];
if (!usimService) {
return false;
}
usimService -= 1;
index = Math.floor(usimService / 8);
bitmask = 1 << ((usimService % 8) << 0);
}
return (serviceTable !== null) &&
(index < serviceTable.length) &&
((serviceTable[index] & bitmask) !== 0);
},
/**
* Get whether specificed CPHS service is available.
*
* @param geckoService
* Service name like "MDN", etc.
*
* @return true if the service is enabled, false otherwise.
*/
isCphsServiceAvailable: function(geckoService) {
let RIL = this.context.RIL;
let serviceTable = RIL.iccInfoPrivate.cphsSt;
if (!(serviceTable instanceof Uint8Array)) {
return false;
}
/**
* Service id is valid in 1..N, and 2 bits are used to code each service.
*
* +----+-- --+----+----+
* | b8 | ... | b2 | b1 |
* +----+-- --+----+----+
*
* b1 = 0, service not allocated.
* 1, service allocated.
* b2 = 0, service not activated.
* 1, service activated.
*
* @See B.3.1.1 CPHS Information in CPHS Phase 2.
*/
let cphsService = GECKO_ICC_SERVICES.cphs[geckoService];
if (!cphsService) {
return false;
}
cphsService -= 1;
let index = Math.floor(cphsService / 4);
let bitmask = 2 << ((cphsService % 4) << 1);
return (index < serviceTable.length) &&
((serviceTable[index] & bitmask) !== 0);
},
/**
* Check if the string is of GSM default 7-bit coded alphabets with bit 8
* set to 0.
*
* @param str String to be checked.
*/
isGsm8BitAlphabet: function(str) {
if (!str) {
return false;
}
const langTable = PDU_NL_LOCKING_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
const langShiftTable = PDU_NL_SINGLE_SHIFT_TABLES[PDU_NL_IDENTIFIER_DEFAULT];
for (let i = 0; i < str.length; i++) {
let c = str.charAt(i);
let octet = langTable.indexOf(c);
if (octet == -1) {
octet = langShiftTable.indexOf(c);
if (octet == -1) {
return false;
}
}
}
return true;
},
/**
* Parse MCC/MNC from IMSI. If there is no available value for the length of
* mnc, it will use the data in MCC table to parse.
*
* @param imsi
* The imsi of icc.
* @param mncLength [optional]
* The length of mnc.
* Zero indicates we haven't got a valid mnc length.
*
* @return An object contains the parsing result of mcc and mnc.
* Or null if any error occurred.
*/
parseMccMncFromImsi: function(imsi, mncLength) {
if (!imsi) {
return null;
}
// MCC is the first 3 digits of IMSI.
let mcc = imsi.substr(0,3);
if (!mncLength) {
// Check the MCC/MNC table for MNC length = 3 first for the case we don't
// have the 4th byte data from EF_AD.
if (PLMN_HAVING_3DIGITS_MNC[mcc] &&
PLMN_HAVING_3DIGITS_MNC[mcc].indexOf(imsi.substr(3, 3)) !== -1) {
mncLength = 3;
} else {
// Check the MCC table to decide the length of MNC.
let index = MCC_TABLE_FOR_MNC_LENGTH_IS_3.indexOf(mcc);
mncLength = (index !== -1) ? 3 : 2;
}
}
let mnc = imsi.substr(3, mncLength);
if (DEBUG) {
this.context.debug("IMSI: " + imsi + " MCC: " + mcc + " MNC: " + mnc);
}
return { mcc: mcc, mnc: mnc};
},
};
/**
* Helper for ICC Contacts.
*/
function ICCContactHelperObject(aContext) {
this.context = aContext;
}
ICCContactHelperObject.prototype = {
context: null,
/**
* Helper function to check DF_PHONEBOOK.
*/
hasDfPhoneBook: function(appType) {
switch (appType) {
case CARD_APPTYPE_SIM:
return false;
case CARD_APPTYPE_USIM:
return true;
case CARD_APPTYPE_RUIM:
let ICCUtilsHelper = this.context.ICCUtilsHelper;
return ICCUtilsHelper.isICCServiceAvailable("ENHANCED_PHONEBOOK");
default:
return false;
}
},
/**
* Helper function to read ICC contacts.
*
* @param appType One of CARD_APPTYPE_*.
* @param contactType One of GECKO_CARDCONTACT_TYPE_*.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readICCContacts: function(appType, contactType, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
let ICCUtilsHelper = this.context.ICCUtilsHelper;
switch (contactType) {
case GECKO_CARDCONTACT_TYPE_ADN:
if (!this.hasDfPhoneBook(appType)) {
ICCRecordHelper.readADNLike(ICC_EF_ADN,
(ICCUtilsHelper.isICCServiceAvailable("EXT1")) ? ICC_EF_EXT1 : null,
onsuccess, onerror);
} else {
this.readUSimContacts(onsuccess, onerror);
}
break;
case GECKO_CARDCONTACT_TYPE_FDN:
if (!ICCUtilsHelper.isICCServiceAvailable("FDN")) {
onerror(CONTACT_ERR_CONTACT_TYPE_NOT_SUPPORTED);
break;
}
ICCRecordHelper.readADNLike(ICC_EF_FDN,
(ICCUtilsHelper.isICCServiceAvailable("EXT2")) ? ICC_EF_EXT2 : null,
onsuccess, onerror);
break;
case GECKO_CARDCONTACT_TYPE_SDN:
if (!ICCUtilsHelper.isICCServiceAvailable("SDN")) {
onerror(CONTACT_ERR_CONTACT_TYPE_NOT_SUPPORTED);
break;
}
ICCRecordHelper.readADNLike(ICC_EF_SDN,
(ICCUtilsHelper.isICCServiceAvailable("EXT3")) ? ICC_EF_EXT3 : null,
onsuccess, onerror);
break;
default:
if (DEBUG) {
this.context.debug("Unsupported contactType :" + contactType);
}
onerror(CONTACT_ERR_CONTACT_TYPE_NOT_SUPPORTED);
break;
}
},
/**
* Helper function to find free contact record.
*
* @param appType One of CARD_APPTYPE_*.
* @param contactType One of GECKO_CARDCONTACT_TYPE_*.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
findFreeICCContact: function(appType, contactType, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
switch (contactType) {
case GECKO_CARDCONTACT_TYPE_ADN:
if (!this.hasDfPhoneBook(appType)) {
ICCRecordHelper.findFreeRecordId(ICC_EF_ADN, onsuccess.bind(null, 0), onerror);
} else {
let gotPbrCb = function gotPbrCb(pbrs) {
this.findUSimFreeADNRecordId(pbrs, onsuccess, onerror);
}.bind(this);
ICCRecordHelper.readPBR(gotPbrCb, onerror);
}
break;
case GECKO_CARDCONTACT_TYPE_FDN:
ICCRecordHelper.findFreeRecordId(ICC_EF_FDN, onsuccess.bind(null, 0), onerror);
break;
default:
if (DEBUG) {
this.context.debug("Unsupported contactType :" + contactType);
}
onerror(CONTACT_ERR_CONTACT_TYPE_NOT_SUPPORTED);
break;
}
},
/**
* Cache the pbr index of the possible free record.
*/
_freePbrIndex: 0,
/**
* Find free ADN record id in USIM.
*
* @param pbrs All Phonebook Reference Files read.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
findUSimFreeADNRecordId: function(pbrs, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
function callback(pbrIndex, recordId) {
// Assume other free records are probably in the same phonebook set.
this._freePbrIndex = pbrIndex;
onsuccess(pbrIndex, recordId);
}
let nextPbrIndex = -1;
(function findFreeRecordId(pbrIndex) {
if (nextPbrIndex === this._freePbrIndex) {
// No free record found, reset the pbr index of free record.
this._freePbrIndex = 0;
if (DEBUG) {
this.context.debug(CONTACT_ERR_NO_FREE_RECORD_FOUND);
}
onerror(CONTACT_ERR_NO_FREE_RECORD_FOUND);
return;
}
let pbr = pbrs[pbrIndex];
nextPbrIndex = (pbrIndex + 1) % pbrs.length;
ICCRecordHelper.findFreeRecordId(
pbr.adn.fileId,
callback.bind(this, pbrIndex),
findFreeRecordId.bind(this, nextPbrIndex));
}).call(this, this._freePbrIndex);
},
/**
* Helper function to add a new ICC contact.
*
* @param appType One of CARD_APPTYPE_*.
* @param contactType One of GECKO_CARDCONTACT_TYPE_*.
* @param contact The contact will be added.
* @param pin2 PIN2 is required for FDN.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
addICCContact: function(appType, contactType, contact, pin2, onsuccess, onerror) {
let foundFreeCb = (function foundFreeCb(pbrIndex, recordId) {
contact.pbrIndex = pbrIndex;
contact.recordId = recordId;
this.updateICCContact(appType, contactType, contact, pin2, onsuccess, onerror);
}).bind(this);
// Find free record first.
this.findFreeICCContact(appType, contactType, foundFreeCb, onerror);
},
/**
* Helper function to update ICC contact.
*
* @param appType One of CARD_APPTYPE_*.
* @param contactType One of GECKO_CARDCONTACT_TYPE_*.
* @param contact The contact will be updated.
* @param pin2 PIN2 is required for FDN.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateICCContact: function(appType, contactType, contact, pin2, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
let ICCUtilsHelper = this.context.ICCUtilsHelper;
let updateContactCb = (updatedContact) => {
updatedContact.pbrIndex = contact.pbrIndex;
updatedContact.recordId = contact.recordId;
onsuccess(updatedContact);
}
switch (contactType) {
case GECKO_CARDCONTACT_TYPE_ADN:
if (!this.hasDfPhoneBook(appType)) {
if (ICCUtilsHelper.isICCServiceAvailable("EXT1")) {
this.updateADNLikeWithExtension(ICC_EF_ADN, ICC_EF_EXT1,
contact, null,
updateContactCb, onerror);
} else {
ICCRecordHelper.updateADNLike(ICC_EF_ADN, 0xff,
contact, null,
updateContactCb, onerror);
}
} else {
this.updateUSimContact(contact, updateContactCb, onerror);
}
break;
case GECKO_CARDCONTACT_TYPE_FDN:
if (!pin2) {
onerror(GECKO_ERROR_SIM_PIN2);
return;
}
if (!ICCUtilsHelper.isICCServiceAvailable("FDN")) {
onerror(CONTACT_ERR_CONTACT_TYPE_NOT_SUPPORTED);
break;
}
if (ICCUtilsHelper.isICCServiceAvailable("EXT2")) {
this.updateADNLikeWithExtension(ICC_EF_FDN, ICC_EF_EXT2,
contact, pin2,
updateContactCb, onerror);
} else {
ICCRecordHelper.updateADNLike(ICC_EF_FDN,
0xff,
contact, pin2,
updateContactCb, onerror);
}
break;
default:
if (DEBUG) {
this.context.debug("Unsupported contactType :" + contactType);
}
onerror(CONTACT_ERR_CONTACT_TYPE_NOT_SUPPORTED);
break;
}
},
/**
* Read contacts from USIM.
*
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readUSimContacts: function(onsuccess, onerror) {
let gotPbrCb = function gotPbrCb(pbrs) {
this.readAllPhonebookSets(pbrs, onsuccess, onerror);
}.bind(this);
this.context.ICCRecordHelper.readPBR(gotPbrCb, onerror);
},
/**
* Read all Phonebook sets.
*
* @param pbrs All Phonebook Reference Files read.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readAllPhonebookSets: function(pbrs, onsuccess, onerror) {
let allContacts = [], pbrIndex = 0;
let readPhonebook = function(contacts) {
if (contacts) {
allContacts = allContacts.concat(contacts);
}
let cLen = contacts ? contacts.length : 0;
for (let i = 0; i < cLen; i++) {
contacts[i].pbrIndex = pbrIndex;
}
pbrIndex++;
if (pbrIndex >= pbrs.length) {
if (onsuccess) {
onsuccess(allContacts);
}
return;
}
this.readPhonebookSet(pbrs[pbrIndex], readPhonebook, onerror);
}.bind(this);
this.readPhonebookSet(pbrs[pbrIndex], readPhonebook, onerror);
},
/**
* Read from Phonebook Reference File.
*
* @param pbr Phonebook Reference File to be read.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readPhonebookSet: function(pbr, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
let gotAdnCb = function gotAdnCb(contacts) {
this.readSupportedPBRFields(pbr, contacts, onsuccess, onerror);
}.bind(this);
ICCRecordHelper.readADNLike(pbr.adn.fileId,
(pbr.ext1) ? pbr.ext1.fileId : null, gotAdnCb, onerror);
},
/**
* Read supported Phonebook fields.
*
* @param pbr Phone Book Reference file.
* @param contacts Contacts stored on ICC.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readSupportedPBRFields: function(pbr, contacts, onsuccess, onerror) {
let fieldIndex = 0;
(function readField() {
let field = USIM_PBR_FIELDS[fieldIndex];
fieldIndex += 1;
if (!field) {
if (onsuccess) {
onsuccess(contacts);
}
return;
}
this.readPhonebookField(pbr, contacts, field, readField.bind(this), onerror);
}).call(this);
},
/**
* Read Phonebook field.
*
* @param pbr The phonebook reference file.
* @param contacts Contacts stored on ICC.
* @param field Phonebook field to be retrieved.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readPhonebookField: function(pbr, contacts, field, onsuccess, onerror) {
if (!pbr[field]) {
if (onsuccess) {
onsuccess(contacts);
}
return;
}
(function doReadContactField(n) {
if (n >= contacts.length) {
// All contact's fields are read.
if (onsuccess) {
onsuccess(contacts);
}
return;
}
// get n-th contact's field.
this.readContactField(pbr, contacts[n], field,
doReadContactField.bind(this, n + 1), onerror);
}).call(this, 0);
},
/**
* Read contact's field from USIM.
*
* @param pbr The phonebook reference file.
* @param contact The contact needs to get field.
* @param field Phonebook field to be retrieved.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
readContactField: function(pbr, contact, field, onsuccess, onerror) {
let gotRecordIdCb = function gotRecordIdCb(recordId) {
if (recordId == 0xff) {
if (onsuccess) {
onsuccess();
}
return;
}
let fileId = pbr[field].fileId;
let fileType = pbr[field].fileType;
let gotFieldCb = function gotFieldCb(value) {
if (value) {
// Move anr0 anr1,.. into anr[].
if (field.startsWith(USIM_PBR_ANR)) {
if (!contact[USIM_PBR_ANR]) {
contact[USIM_PBR_ANR] = [];
}
contact[USIM_PBR_ANR].push(value);
} else {
contact[field] = value;
}
}
if (onsuccess) {
onsuccess();
}
}.bind(this);
let ICCRecordHelper = this.context.ICCRecordHelper;
// Detect EF to be read, for anr, it could have anr0, anr1,...
let ef = field.startsWith(USIM_PBR_ANR) ? USIM_PBR_ANR : field;
switch (ef) {
case USIM_PBR_EMAIL:
ICCRecordHelper.readEmail(fileId, fileType, recordId, gotFieldCb, onerror);
break;
case USIM_PBR_ANR:
ICCRecordHelper.readANR(fileId, fileType, recordId, gotFieldCb, onerror);
break;
default:
if (DEBUG) {
this.context.debug("Unsupported field :" + field);
}
onerror(CONTACT_ERR_FIELD_NOT_SUPPORTED);
break;
}
}.bind(this);
this.getContactFieldRecordId(pbr, contact, field, gotRecordIdCb, onerror);
},
/**
* Get the recordId.
*
* If the fileType of field is ICC_USIM_TYPE1_TAG, use corresponding ADN recordId.
* otherwise get the recordId from IAP.
*
* @see TS 131.102, clause 4.4.2.2
*
* @param pbr The phonebook reference file.
* @param contact The contact will be updated.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
getContactFieldRecordId: function(pbr, contact, field, onsuccess, onerror) {
if (pbr[field].fileType == ICC_USIM_TYPE1_TAG) {
// If the file type is ICC_USIM_TYPE1_TAG, use corresponding ADN recordId.
if (onsuccess) {
onsuccess(contact.recordId);
}
} else if (pbr[field].fileType == ICC_USIM_TYPE2_TAG) {
// If the file type is ICC_USIM_TYPE2_TAG, the recordId shall be got from IAP.
let gotIapCb = function gotIapCb(iap) {
let indexInIAP = pbr[field].indexInIAP;
let recordId = iap[indexInIAP];
if (onsuccess) {
onsuccess(recordId);
}
}.bind(this);
this.context.ICCRecordHelper.readIAP(pbr.iap.fileId, contact.recordId,
gotIapCb, onerror);
} else {
if (DEBUG) {
this.context.debug("USIM PBR files in Type 3 format are not supported.");
}
onerror(CONTACT_ERR_REQUEST_NOT_SUPPORTED);
}
},
/**
* Update USIM contact.
*
* @param contact The contact will be updated.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateUSimContact: function(contact, onsuccess, onerror) {
let gotPbrCb = function gotPbrCb(pbrs) {
let pbr = pbrs[contact.pbrIndex];
if (!pbr) {
if (DEBUG) {
this.context.debug(CONTACT_ERR_CANNOT_ACCESS_PHONEBOOK);
}
onerror(CONTACT_ERR_CANNOT_ACCESS_PHONEBOOK);
return;
}
this.updatePhonebookSet(pbr, contact, onsuccess, onerror);
}.bind(this);
this.context.ICCRecordHelper.readPBR(gotPbrCb, onerror);
},
/**
* Update fields in Phonebook Reference File.
*
* @param pbr Phonebook Reference File to be read.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updatePhonebookSet: function(pbr, contact, onsuccess, onerror) {
let updateAdnCb = function(updatedContact) {
this.updateSupportedPBRFields(pbr, contact, (updatedContactField) => {
onsuccess(Object.assign(updatedContact, updatedContactField));
}, onerror);
}.bind(this);
if (pbr.ext1) {
this.updateADNLikeWithExtension(pbr.adn.fileId, pbr.ext1.fileId,
contact, null, updateAdnCb, onerror);
} else {
this.context.ICCRecordHelper.updateADNLike(pbr.adn.fileId, 0xff, contact,
null, updateAdnCb, onerror);
}
},
/**
* Update supported Phonebook fields.
*
* @param pbr Phone Book Reference file.
* @param contact Contact to be updated.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateSupportedPBRFields: function(pbr, contact, onsuccess, onerror) {
let fieldIndex = 0;
let contactField = {};
(function updateField() {
let field = USIM_PBR_FIELDS[fieldIndex];
fieldIndex += 1;
if (!field) {
if (onsuccess) {
onsuccess(contactField);
}
return;
}
// Check if PBR has this field.
if (!pbr[field]) {
updateField.call(this);
return;
}
this.updateContactField(pbr, contact, field, (fieldEntry) => {
contactField = Object.assign(contactField, fieldEntry);
updateField.call(this);
}, (errorMsg) => {
// Bug 1194149, there are some sim cards without sufficient
// Type 2 USIM contact fields record. We allow user continue
// importing contacts.
if (errorMsg === CONTACT_ERR_NO_FREE_RECORD_FOUND) {
updateField.call(this);
return;
}
onerror(errorMsg);
});
}).call(this);
},
/**
* Update contact's field from USIM.
*
* @param pbr The phonebook reference file.
* @param contact The contact needs to be updated.
* @param field Phonebook field to be updated.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateContactField: function(pbr, contact, field, onsuccess, onerror) {
if (pbr[field].fileType === ICC_USIM_TYPE1_TAG) {
this.updateContactFieldType1(pbr, contact, field, onsuccess, onerror);
} else if (pbr[field].fileType === ICC_USIM_TYPE2_TAG) {
this.updateContactFieldType2(pbr, contact, field, onsuccess, onerror);
} else {
if (DEBUG) {
this.context.debug("USIM PBR files in Type 3 format are not supported.");
}
onerror(CONTACT_ERR_REQUEST_NOT_SUPPORTED);
}
},
/**
* Update Type 1 USIM contact fields.
*
* @param pbr The phonebook reference file.
* @param contact The contact needs to be updated.
* @param field Phonebook field to be updated.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateContactFieldType1: function(pbr, contact, field, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
if (field === USIM_PBR_EMAIL) {
ICCRecordHelper.updateEmail(pbr, contact.recordId, contact.email, null,
(updatedEmail) => {
onsuccess({email: updatedEmail});
}, onerror);
} else if (field === USIM_PBR_ANR0) {
let anr = Array.isArray(contact.anr) ? contact.anr[0] : null;
ICCRecordHelper.updateANR(pbr, contact.recordId, anr, null,
(updatedANR) => {
// ANR could have multiple files. If we support more than one anr,
// we will save it as anr0, anr1,...etc.
onsuccess((updatedANR) ? {anr: [updatedANR]} : null);
}, onerror);
} else {
if (DEBUG) {
this.context.debug("Unsupported field :" + field);
}
onerror(CONTACT_ERR_FIELD_NOT_SUPPORTED);
}
},
/**
* Update Type 2 USIM contact fields.
*
* @param pbr The phonebook reference file.
* @param contact The contact needs to be updated.
* @param field Phonebook field to be updated.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateContactFieldType2: function(pbr, contact, field, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
// Case 1 : EF_IAP[adnRecordId] doesn't have a value(0xff)
// Find a free recordId for EF_field
// Update field with that free recordId.
// Update IAP.
//
// Case 2: EF_IAP[adnRecordId] has a value
// update EF_field[iap[field.indexInIAP]]
let gotIapCb = function gotIapCb(iap) {
let recordId = iap[pbr[field].indexInIAP];
if (recordId === 0xff) {
// If the value in IAP[index] is 0xff, which means the contact stored on
// the SIM doesn't have the additional attribute (email or anr).
// So if the contact to be updated doesn't have the attribute either,
// we don't have to update it.
if ((field === USIM_PBR_EMAIL && contact.email) ||
(field === USIM_PBR_ANR0 &&
(Array.isArray(contact.anr) && contact.anr[0]))) {
// Case 1.
this.addContactFieldType2(pbr, contact, field, onsuccess, onerror);
} else {
if (onsuccess) {
onsuccess();
}
}
return;
}
// Case 2.
if (field === USIM_PBR_EMAIL) {
ICCRecordHelper.updateEmail(pbr, recordId, contact.email, contact.recordId,
(updatedEmail) => {
onsuccess({email: updatedEmail});
}, onerror);
} else if (field === USIM_PBR_ANR0) {
let anr = Array.isArray(contact.anr) ? contact.anr[0] : null;
ICCRecordHelper.updateANR(pbr, recordId, anr, contact.recordId,
(updatedANR) => {
// ANR could have multiple files. If we support more than one anr,
// we will save it as anr0, anr1,...etc.
onsuccess((updatedANR) ? {anr: [updatedANR]} : null);
}, onerror);
} else {
if (DEBUG) {
this.context.debug("Unsupported field :" + field);
}
onerror(CONTACT_ERR_FIELD_NOT_SUPPORTED);
}
}.bind(this);
ICCRecordHelper.readIAP(pbr.iap.fileId, contact.recordId, gotIapCb, onerror);
},
/**
* Add Type 2 USIM contact fields.
*
* @param pbr The phonebook reference file.
* @param contact The contact needs to be updated.
* @param field Phonebook field to be updated.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
addContactFieldType2: function(pbr, contact, field, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
let successCb = function successCb(recordId) {
let updateCb = function updateCb(contactField) {
this.updateContactFieldIndexInIAP(pbr, contact.recordId, field, recordId, () => {
onsuccess(contactField);
}, onerror);
}.bind(this);
if (field === USIM_PBR_EMAIL) {
ICCRecordHelper.updateEmail(pbr, recordId, contact.email, contact.recordId,
(updatedEmail) => {
updateCb({email: updatedEmail});
}, onerror);
} else if (field === USIM_PBR_ANR0) {
ICCRecordHelper.updateANR(pbr, recordId, contact.anr[0], contact.recordId,
(updatedANR) => {
// ANR could have multiple files. If we support more than one anr,
// we will save it as anr0, anr1,...etc.
updateCb((updatedANR) ? {anr: [updatedANR]} : null);
}, onerror);
}
}.bind(this);
let errorCb = function errorCb(errorMsg) {
if (DEBUG) {
this.context.debug(errorMsg + " USIM field " + field);
}
onerror(errorMsg);
}.bind(this);
ICCRecordHelper.findFreeRecordId(pbr[field].fileId, successCb, errorCb);
},
/**
* Update IAP value.
*
* @param pbr The phonebook reference file.
* @param recordNumber The record identifier of EF_IAP.
* @param field Phonebook field.
* @param value The value of 'field' in IAP.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*
*/
updateContactFieldIndexInIAP: function(pbr, recordNumber, field, value, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
let gotIAPCb = function gotIAPCb(iap) {
iap[pbr[field].indexInIAP] = value;
ICCRecordHelper.updateIAP(pbr.iap.fileId, recordNumber, iap, onsuccess, onerror);
}.bind(this);
ICCRecordHelper.readIAP(pbr.iap.fileId, recordNumber, gotIAPCb, onerror);
},
/**
* Update ICC ADN like EFs with Extension, like EF_ADN, EF_FDN.
*
* @param fileId EF id of the ADN or FDN.
* @param extFileId EF id of the EXT.
* @param contact The contact will be updated. (Shall have recordId property)
* @param pin2 PIN2 is required when updating ICC_EF_FDN.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
updateADNLikeWithExtension: function(fileId, extFileId, contact, pin2, onsuccess, onerror) {
let ICCRecordHelper = this.context.ICCRecordHelper;
let extNumber;
if (contact.number) {
let numStart = contact.number[0] == "+" ? 1 : 0;
let number = contact.number.substring(0, numStart) +
this.context.GsmPDUHelper.stringToExtendedBcd(
contact.number.substring(numStart));
extNumber = number.substr(numStart + ADN_MAX_NUMBER_DIGITS,
EXT_MAX_NUMBER_DIGITS);
}
ICCRecordHelper.getADNLikeExtensionRecordNumber(fileId, contact.recordId,
(extRecordNumber) => {
let updateADNLike = (extRecordNumber) => {
ICCRecordHelper.updateADNLike(fileId, extRecordNumber, contact,
pin2, (updatedContact) => {
if (extNumber && extRecordNumber != 0xff) {
updatedContact.number = updatedContact.number.concat(extNumber);
}
onsuccess(updatedContact);
}, onerror);
};
let updateExtension = (extRecordNumber) => {
ICCRecordHelper.updateExtension(extFileId, extRecordNumber, extNumber,
() => updateADNLike(extRecordNumber),
() => updateADNLike(0xff));
};
if (extNumber) {
if (extRecordNumber != 0xff) {
updateExtension(extRecordNumber);
return;
}
ICCRecordHelper.findFreeRecordId(extFileId,
(extRecordNumber) => updateExtension(extRecordNumber),
(errorMsg) => {
if (DEBUG) {
this.context.debug("Couldn't find free extension record Id for " + extFileId + ": " + errorMsg);
}
updateADNLike(0xff);
});
return;
}
if (extRecordNumber != 0xff) {
ICCRecordHelper.cleanEFRecord(extFileId, extRecordNumber,
() => updateADNLike(0xff), onerror);
return;
}
updateADNLike(0xff);
}, onerror);
},
};
function IconLoaderObject(aContext) {
this.context = aContext;
}
IconLoaderObject.prototype = {
context: null,
/**
* Load icons.
*
* @param recordNumbers Array of the record identifiers of EF_IMG.
* @param onsuccess Callback to be called when success.
* @param onerror Callback to be called when error.
*/
loadIcons: function(recordNumbers, onsuccess, onerror) {
if (!recordNumbers || !recordNumbers.length) {
if (onerror) {
onerror();
}
return;
}
this._start({
recordNumbers: recordNumbers,
onsuccess: onsuccess,
onerror: onerror});
},
_start: function(options) {
let callback = (function(icons) {
if (!options.icons) {
options.icons = [];
}
for (let i = 0; i < icons.length; i++) {
icons[i] = this._parseRawData(icons[i]);
}
options.icons[options.currentRecordIndex] = icons;
options.currentRecordIndex++;
let recordNumbers = options.recordNumbers;
if (options.currentRecordIndex < recordNumbers.length) {
let recordNumber = recordNumbers[options.currentRecordIndex];
this.context.SimRecordHelper.readIMG(recordNumber,
callback,
options.onerror);
} else {
if (options.onsuccess) {
options.onsuccess(options.icons);
}
}
}).bind(this);
options.currentRecordIndex = 0;
this.context.SimRecordHelper.readIMG(options.recordNumbers[0],
callback,
options.onerror);
},
_parseRawData: function(rawData) {
let codingScheme = rawData.codingScheme;
switch (codingScheme) {
case ICC_IMG_CODING_SCHEME_BASIC:
return this._decodeBasicImage(rawData.width, rawData.height, rawData.body);
case ICC_IMG_CODING_SCHEME_COLOR:
case ICC_IMG_CODING_SCHEME_COLOR_TRANSPARENCY:
return this._decodeColorImage(codingScheme,
rawData.width, rawData.height,
rawData.bitsPerImgPoint,
rawData.numOfClutEntries,
rawData.clut, rawData.body);
}
return null;
},
_decodeBasicImage: function(width, height, body) {
let numOfPixels = width * height;
let pixelIndex = 0;
let currentByteIndex = 0;
let currentByte = 0x00;
const BLACK = 0x000000FF;
const WHITE = 0xFFFFFFFF;
let pixels = [];
while (pixelIndex < numOfPixels) {
// Reassign data and index for every byte (8 bits).
if (pixelIndex % 8 == 0) {
currentByte = body[currentByteIndex++];
}
let bit = (currentByte >> (7 - (pixelIndex % 8))) & 0x01;
pixels[pixelIndex++] = bit ? WHITE : BLACK;
}
return {pixels: pixels,
codingScheme: GECKO_IMG_CODING_SCHEME_BASIC,
width: width,
height: height};
},
_decodeColorImage: function(codingScheme, width, height, bitsPerImgPoint,
numOfClutEntries, clut, body) {
let mask = 0xff >> (8 - bitsPerImgPoint);
let bitsStartOffset = 8 - bitsPerImgPoint;
let bitIndex = bitsStartOffset;
let numOfPixels = width * height;
let pixelIndex = 0;
let currentByteIndex = 0;
let currentByte = body[currentByteIndex++];
let pixels = [];
while (pixelIndex < numOfPixels) {
// Reassign data and index for every byte (8 bits).
if (bitIndex < 0) {
currentByte = body[currentByteIndex++];
bitIndex = bitsStartOffset;
}
let clutEntry = ((currentByte >> bitIndex) & mask);
let clutIndex = clutEntry * ICC_CLUT_ENTRY_SIZE;
let alpha = codingScheme == ICC_IMG_CODING_SCHEME_COLOR_TRANSPARENCY &&
clutEntry == numOfClutEntries - 1;
pixels[pixelIndex++] = alpha ? 0x00
: (clut[clutIndex] << 24 |
clut[clutIndex + 1] << 16 |
clut[clutIndex + 2] << 8 |
0xFF) >>> 0;
bitIndex -= bitsPerImgPoint;
}
return {pixels: pixels,
codingScheme: ICC_IMG_CODING_SCHEME_TO_GECKO[codingScheme],
width: width,
height: height};
},
};
/**
* Global stuff.
*/
function Context(aClientId) {
this.clientId = aClientId;
this.Buf = new BufObject(this);
this.RIL = new RilObject(this);
this.RIL.initRILState();
}
Context.prototype = {
clientId: null,
Buf: null,
RIL: null,
debug: function(aMessage) {
GLOBAL.debug("[" + this.clientId + "] " + aMessage);
}
};
(function() {
let lazySymbols = [
"BerTlvHelper", "BitBufferHelper", "CdmaPDUHelper",
"ComprehensionTlvHelper", "GsmPDUHelper", "ICCContactHelper",
"ICCFileHelper", "ICCIOHelper", "ICCPDUHelper", "ICCRecordHelper",
"ICCUtilsHelper", "RuimRecordHelper", "SimRecordHelper",
"StkCommandParamsFactory", "StkProactiveCmdHelper", "IconLoader",
];
for (let i = 0; i < lazySymbols.length; i++) {
let symbol = lazySymbols[i];
Object.defineProperty(Context.prototype, symbol, {
get: function() {
let real = new GLOBAL[symbol + "Object"](this);
Object.defineProperty(this, symbol, {
value: real,
enumerable: true
});
return real;
},
configurable: true,
enumerable: true
});
}
})();
var ContextPool = {
_contexts: [],
handleRilMessage: function(aClientId, aUint8Array) {
let context = this._contexts[aClientId];
context.Buf.processIncoming(aUint8Array);
},
handleChromeMessage: function(aMessage) {
let clientId = aMessage.rilMessageClientId;
if (clientId != null) {
let context = this._contexts[clientId];
context.RIL.handleChromeMessage(aMessage);
return;
}
if (DEBUG) debug("Received global chrome message " + JSON.stringify(aMessage));
let method = this[aMessage.rilMessageType];
if (typeof method != "function") {
if (DEBUG) {
debug("Don't know what to do");
}
return;
}
method.call(this, aMessage);
},
setInitialOptions: function(aOptions) {
DEBUG = DEBUG_WORKER || aOptions.debug;
let quirks = aOptions.quirks;
RILQUIRKS_CALLSTATE_EXTRA_UINT32 = quirks.callstateExtraUint32;
RILQUIRKS_REQUEST_USE_DIAL_EMERGENCY_CALL = quirks.requestUseDialEmergencyCall;
RILQUIRKS_SIM_APP_STATE_EXTRA_FIELDS = quirks.simAppStateExtraFields;
RILQUIRKS_EXTRA_UINT32_2ND_CALL = quirks.extraUint2ndCall;
RILQUIRKS_HAVE_QUERY_ICC_LOCK_RETRY_COUNT = quirks.haveQueryIccLockRetryCount;
RILQUIRKS_SEND_STK_PROFILE_DOWNLOAD = quirks.sendStkProfileDownload;
RILQUIRKS_DATA_REGISTRATION_ON_DEMAND = quirks.dataRegistrationOnDemand;
RILQUIRKS_SUBSCRIPTION_CONTROL = quirks.subscriptionControl;
RILQUIRKS_SIGNAL_EXTRA_INT32 = quirks.signalExtraInt;
RILQUIRKS_AVAILABLE_NETWORKS_EXTRA_STRING = quirks.availableNetworkExtraStr;
RILQUIRKS_SMSC_ADDRESS_FORMAT = quirks.smscAddressFormat;
},
setDebugFlag: function(aOptions) {
DEBUG = DEBUG_WORKER || aOptions.debug;
},
registerClient: function(aOptions) {
let clientId = aOptions.clientId;
this._contexts[clientId] = new Context(clientId);
},
};
function onRILMessage(aClientId, aUint8Array) {
ContextPool.handleRilMessage(aClientId, aUint8Array);
}
onmessage = function onmessage(event) {
ContextPool.handleChromeMessage(event.data);
};
onerror = function onerror(event) {
if (DEBUG) debug("onerror" + event.message + "\n");
};