The state machine starts in {@link IdleState} state. When the {@link SMSDispatcher} receives a * new SMS from the radio, it calls {@link #dispatchNormalMessage}, * which sends a message to the state machine, causing the wakelock to be acquired in * {@link #haltedProcessMessage}, which transitions to {@link DeliveringState} state, where the message * is saved to the raw table, then acknowledged via the {@link SMSDispatcher} which called us. * *
After saving the SMS, if the message is complete (either single-part or the final segment * of a multi-part SMS), we broadcast the completed PDUs as an ordered broadcast, then transition to * {@link WaitingState} state to wait for the broadcast to complete. When the local * {@link BroadcastReceiver} is called with the result, it sends {@link #EVENT_BROADCAST_COMPLETE} * to the state machine, causing us to either broadcast the next pending message (if one has * arrived while waiting for the broadcast to complete), or to transition back to the halted state * after all messages are processed. Then the wakelock is released and we wait for the next SMS. */ public abstract class InboundSmsHandler extends StateMachine { protected static final boolean DBG = true; private static final boolean VDBG = false; // STOPSHIP if true, logs user data /** Query projection for checking for duplicate message segments. */ private static final String[] PDU_PROJECTION = { "pdu" }; /** Query projection for combining concatenated message segments. */ private static final String[] PDU_SEQUENCE_PORT_PROJECTION = { "pdu", "sequence", "destination_port" }; static final int PDU_COLUMN = 0; static final int SEQUENCE_COLUMN = 1; static final int DESTINATION_PORT_COLUMN = 2; static final int DATE_COLUMN = 3; static final int REFERENCE_NUMBER_COLUMN = 4; static final int COUNT_COLUMN = 5; static final int ADDRESS_COLUMN = 6; static final int ID_COLUMN = 7; static final String SELECT_BY_ID = "_id=?"; static final String SELECT_BY_REFERENCE = "address=? AND reference_number=? AND count=?"; /** New SMS received as an AsyncResult. */ public static final int EVENT_NEW_SMS = 1; /** Message type containing a {@link InboundSmsTracker} ready to broadcast to listeners. */ static final int EVENT_BROADCAST_SMS = 2; /** Message from resultReceiver notifying {@link WaitingState} of a completed broadcast. */ static final int EVENT_BROADCAST_COMPLETE = 3; /** Sent on exit from {@link WaitingState} to return to idle after sending all broadcasts. */ static final int EVENT_RETURN_TO_IDLE = 4; /** Release wakelock after a short timeout when returning to idle state. */ static final int EVENT_RELEASE_WAKELOCK = 5; /** Sent by {@link SmsBroadcastUndelivered} after cleaning the raw table. */ static final int EVENT_START_ACCEPTING_SMS = 6; /** Update phone object */ static final int EVENT_UPDATE_PHONE_OBJECT = 7; /** Wakelock release delay when returning to idle state. */ private static final int WAKELOCK_TIMEOUT = 3000; /** URI for raw table of SMS provider. */ private static final Uri sRawUri = Uri.withAppendedPath(Telephony.Sms.CONTENT_URI, "raw"); protected final Context mContext; private final ContentResolver mResolver; /** Special handler for WAP push messages. */ private final WapPushOverSms mWapPush; /** Wake lock to ensure device stays awake while dispatching the SMS intents. */ final PowerManager.WakeLock mWakeLock; /** DefaultState throws an exception or logs an error for unhandled message types. */ final DefaultState mDefaultState = new DefaultState(); /** Startup state. Waiting for {@link SmsBroadcastUndelivered} to complete. */ final StartupState mStartupState = new StartupState(); /** Idle state. Waiting for messages to process. */ final IdleState mIdleState = new IdleState(); /** Delivering state. Saves the PDU in the raw table and acknowledges to SMSC. */ final DeliveringState mDeliveringState = new DeliveringState(); /** Broadcasting state. Waits for current broadcast to complete before delivering next. */ final WaitingState mWaitingState = new WaitingState(); /** Helper class to check whether storage is available for incoming messages. */ protected SmsStorageMonitor mStorageMonitor; private final boolean mSmsReceiveDisabled; protected PhoneBase mPhone; protected CellBroadcastHandler mCellBroadcastHandler; /** * Create a new SMS broadcast helper. * @param name the class name for logging * @param context the context of the phone app * @param storageMonitor the SmsStorageMonitor to check for storage availability */ protected InboundSmsHandler(String name, Context context, SmsStorageMonitor storageMonitor, PhoneBase phone, CellBroadcastHandler cellBroadcastHandler) { super(name); mContext = context; mStorageMonitor = storageMonitor; mPhone = phone; mCellBroadcastHandler = cellBroadcastHandler; mResolver = context.getContentResolver(); mWapPush = new WapPushOverSms(context); boolean smsCapable = mContext.getResources().getBoolean( com.android.internal.R.bool.config_sms_capable); mSmsReceiveDisabled = !SystemProperties.getBoolean( TelephonyProperties.PROPERTY_SMS_RECEIVE, smsCapable); PowerManager pm = (PowerManager) mContext.getSystemService(Context.POWER_SERVICE); mWakeLock = pm.newWakeLock(PowerManager.PARTIAL_WAKE_LOCK, name); mWakeLock.acquire(); // wake lock released after we enter idle state addState(mDefaultState); addState(mStartupState, mDefaultState); addState(mIdleState, mDefaultState); addState(mDeliveringState, mDefaultState); addState(mWaitingState, mDeliveringState); setInitialState(mStartupState); if (DBG) log("created InboundSmsHandler"); } /** * Tell the state machine to quit after processing all messages. */ public void dispose() { quit(); } /** * Update the phone object when it changes. */ public void updatePhoneObject(PhoneBase phone) { sendMessage(EVENT_UPDATE_PHONE_OBJECT, phone); } /** * Dispose of the WAP push object and release the wakelock. */ @Override protected void onQuitting() { mWapPush.dispose(); while (mWakeLock.isHeld()) { mWakeLock.release(); } } /** * This parent state throws an exception (for debug builds) or prints an error for unhandled * message types. */ class DefaultState extends State { @Override public boolean processMessage(Message msg) { switch (msg.what) { case EVENT_UPDATE_PHONE_OBJECT: { onUpdatePhoneObject((PhoneBase) msg.obj); break; } default: { String errorText = "processMessage: unhandled message type " + msg.what; if (Build.IS_DEBUGGABLE) { throw new RuntimeException(errorText); } else { loge(errorText); } break; } } return HANDLED; } } /** * The Startup state waits for {@link SmsBroadcastUndelivered} to process the raw table and * notify the state machine to broadcast any complete PDUs that might not have been broadcast. */ class StartupState extends State { @Override public boolean processMessage(Message msg) { switch (msg.what) { case EVENT_NEW_SMS: case EVENT_BROADCAST_SMS: deferMessage(msg); return HANDLED; case EVENT_START_ACCEPTING_SMS: transitionTo(mIdleState); return HANDLED; case EVENT_BROADCAST_COMPLETE: case EVENT_RETURN_TO_IDLE: case EVENT_RELEASE_WAKELOCK: default: // let DefaultState handle these unexpected message types return NOT_HANDLED; } } } /** * In the idle state the wakelock is released until a new SM arrives, then we transition * to Delivering mode to handle it, acquiring the wakelock on exit. */ class IdleState extends State { @Override public void enter() { if (DBG) log("entering Idle state"); sendMessageDelayed(EVENT_RELEASE_WAKELOCK, WAKELOCK_TIMEOUT); } @Override public void exit() { mWakeLock.acquire(); if (DBG) log("acquired wakelock, leaving Idle state"); } @Override public boolean processMessage(Message msg) { if (DBG) log("Idle state processing message type " + msg.what); switch (msg.what) { case EVENT_NEW_SMS: case EVENT_BROADCAST_SMS: deferMessage(msg); transitionTo(mDeliveringState); return HANDLED; case EVENT_RELEASE_WAKELOCK: mWakeLock.release(); if (DBG) { if (mWakeLock.isHeld()) { // this is okay as long as we call release() for every acquire() log("mWakeLock is still held after release"); } else { log("mWakeLock released"); } } return HANDLED; case EVENT_RETURN_TO_IDLE: // already in idle state; ignore return HANDLED; case EVENT_BROADCAST_COMPLETE: case EVENT_START_ACCEPTING_SMS: default: // let DefaultState handle these unexpected message types return NOT_HANDLED; } } } /** * In the delivering state, the inbound SMS is processed and stored in the raw table. * The message is acknowledged before we exit this state. If there is a message to broadcast, * transition to {@link WaitingState} state to send the ordered broadcast and wait for the * results. When all messages have been processed, the halting state will release the wakelock. */ class DeliveringState extends State { @Override public void enter() { if (DBG) log("entering Delivering state"); } @Override public void exit() { if (DBG) log("leaving Delivering state"); } @Override public boolean processMessage(Message msg) { switch (msg.what) { case EVENT_NEW_SMS: // handle new SMS from RIL handleNewSms((AsyncResult) msg.obj); sendMessage(EVENT_RETURN_TO_IDLE); return HANDLED; case EVENT_BROADCAST_SMS: // if any broadcasts were sent, transition to waiting state if (processMessagePart((InboundSmsTracker) msg.obj)) { transitionTo(mWaitingState); } return HANDLED; case EVENT_RETURN_TO_IDLE: // return to idle after processing all other messages transitionTo(mIdleState); return HANDLED; case EVENT_RELEASE_WAKELOCK: mWakeLock.release(); // decrement wakelock from previous entry to Idle if (!mWakeLock.isHeld()) { // wakelock should still be held until 3 seconds after we enter Idle loge("mWakeLock released while delivering/broadcasting!"); } return HANDLED; // we shouldn't get this message type in this state, log error and halt. case EVENT_BROADCAST_COMPLETE: case EVENT_START_ACCEPTING_SMS: default: // let DefaultState handle these unexpected message types return NOT_HANDLED; } } } /** * The waiting state delegates handling of new SMS to parent {@link DeliveringState}, but * defers handling of the {@link #EVENT_BROADCAST_SMS} phase until after the current * result receiver sends {@link #EVENT_BROADCAST_COMPLETE}. Before transitioning to * {@link DeliveringState}, {@link #EVENT_RETURN_TO_IDLE} is sent to transition to * {@link IdleState} after any deferred {@link #EVENT_BROADCAST_SMS} messages are handled. */ class WaitingState extends State { @Override public boolean processMessage(Message msg) { switch (msg.what) { case EVENT_BROADCAST_SMS: // defer until the current broadcast completes deferMessage(msg); return HANDLED; case EVENT_BROADCAST_COMPLETE: // return to idle after handling all deferred messages sendMessage(EVENT_RETURN_TO_IDLE); transitionTo(mDeliveringState); return HANDLED; case EVENT_RETURN_TO_IDLE: // not ready to return to idle; ignore return HANDLED; default: // parent state handles the other message types return NOT_HANDLED; } } } void handleNewSms(AsyncResult ar) { if (ar.exception != null) { loge("Exception processing incoming SMS: " + ar.exception); return; } int result; try { SmsMessage sms = (SmsMessage) ar.result; result = dispatchMessage(sms.mWrappedSmsMessage); } catch (RuntimeException ex) { loge("Exception dispatching message", ex); result = Intents.RESULT_SMS_GENERIC_ERROR; } // RESULT_OK means that the SMS will be acknowledged by special handling, // e.g. for SMS-PP data download. Any other result, we should ack here. if (result != Activity.RESULT_OK) { boolean handled = (result == Intents.RESULT_SMS_HANDLED); notifyAndAcknowledgeLastIncomingSms(handled, result, null); } } /** * Process an SMS message from the RIL, calling subclass methods to handle 3GPP and * 3GPP2-specific message types. * * @param smsb the SmsMessageBase object from the RIL * @return a result code from {@link android.provider.Telephony.Sms.Intents}, * or {@link Activity#RESULT_OK} for delayed acknowledgment to SMSC */ public int dispatchMessage(SmsMessageBase smsb) { // If sms is null, there was a parsing error. if (smsb == null) { loge("dispatchSmsMessage: message is null"); return Intents.RESULT_SMS_GENERIC_ERROR; } if (mSmsReceiveDisabled) { // Device doesn't support receiving SMS, log("Received short message on device which doesn't support " + "receiving SMS. Ignored."); return Intents.RESULT_SMS_HANDLED; } return dispatchMessageRadioSpecific(smsb); } /** * Process voicemail notification, SMS-PP data download, CDMA CMAS, CDMA WAP push, and other * 3GPP/3GPP2-specific messages. Regular SMS messages are handled by calling the shared * {@link #dispatchNormalMessage} from this class. * * @param smsb the SmsMessageBase object from the RIL * @return a result code from {@link android.provider.Telephony.Sms.Intents}, * or {@link Activity#RESULT_OK} for delayed acknowledgment to SMSC */ protected abstract int dispatchMessageRadioSpecific(SmsMessageBase smsb); /** * Send an acknowledge message to the SMSC. * @param success indicates that last message was successfully received. * @param result result code indicating any error * @param response callback message sent when operation completes. */ protected abstract void acknowledgeLastIncomingSms(boolean success, int result, Message response); /** * Called when the phone changes the default method updates mPhone * mStorageMonitor and mCellBroadcastHandler.updatePhoneObject. * Override if different or other behavior is desired. * * @param phone */ protected void onUpdatePhoneObject(PhoneBase phone) { mPhone = phone; mStorageMonitor = mPhone.mSmsStorageMonitor; log("onUpdatePhoneObject: phone=" + mPhone.getClass().getSimpleName()); } /** * Notify interested apps if the framework has rejected an incoming SMS, * and send an acknowledge message to the network. * @param success indicates that last message was successfully received. * @param result result code indicating any error * @param response callback message sent when operation completes. */ void notifyAndAcknowledgeLastIncomingSms(boolean success, int result, Message response) { if (!success) { // broadcast SMS_REJECTED_ACTION intent Intent intent = new Intent(Intents.SMS_REJECTED_ACTION); intent.putExtra("result", result); mContext.sendBroadcast(intent, android.Manifest.permission.RECEIVE_SMS); } acknowledgeLastIncomingSms(success, result, response); } /** * Return true if this handler is for 3GPP2 messages; false for 3GPP format. * @return true for the 3GPP2 handler; false for the 3GPP handler */ protected abstract boolean is3gpp2(); /** * Dispatch a normal incoming SMS. This is called from {@link #dispatchMessageRadioSpecific} * if no format-specific handling was required. Saves the PDU to the SMS provider raw table, * creates an {@link InboundSmsTracker}, then sends it to the state machine as an * {@link #EVENT_BROADCAST_SMS}. Returns {@link Intents#RESULT_SMS_HANDLED} or an error value. * * @param sms the message to dispatch * @return {@link Intents#RESULT_SMS_HANDLED} if the message was accepted, or an error status */ protected int dispatchNormalMessage(SmsMessageBase sms) { SmsHeader smsHeader = sms.getUserDataHeader(); InboundSmsTracker tracker; if ((smsHeader == null) || (smsHeader.concatRef == null)) { // Message is not concatenated. int destPort = -1; if (smsHeader != null && smsHeader.portAddrs != null) { // The message was sent to a port. destPort = smsHeader.portAddrs.destPort; if (DBG) log("destination port: " + destPort); } tracker = new InboundSmsTracker(sms.getPdu(), sms.getTimestampMillis(), destPort, is3gpp2(), false); } else { // Create a tracker for this message segment. SmsHeader.ConcatRef concatRef = smsHeader.concatRef; SmsHeader.PortAddrs portAddrs = smsHeader.portAddrs; int destPort = (portAddrs != null ? portAddrs.destPort : -1); tracker = new InboundSmsTracker(sms.getPdu(), sms.getTimestampMillis(), destPort, is3gpp2(), sms.getOriginatingAddress(), concatRef.refNumber, concatRef.seqNumber, concatRef.msgCount, false); } if (VDBG) log("created tracker: " + tracker); return addTrackerToRawTableAndSendMessage(tracker); } /** * Helper to add the tracker to the raw table and then send a message to broadcast it, if * successful. Returns the SMS intent status to return to the SMSC. * @param tracker the tracker to save to the raw table and then deliver * @return {@link Intents#RESULT_SMS_HANDLED} or {@link Intents#RESULT_SMS_GENERIC_ERROR} * or {@link Intents#RESULT_SMS_DUPLICATED} */ protected int addTrackerToRawTableAndSendMessage(InboundSmsTracker tracker) { switch(addTrackerToRawTable(tracker)) { case Intents.RESULT_SMS_HANDLED: sendMessage(EVENT_BROADCAST_SMS, tracker); return Intents.RESULT_SMS_HANDLED; case Intents.RESULT_SMS_DUPLICATED: return Intents.RESULT_SMS_HANDLED; case Intents.RESULT_SMS_GENERIC_ERROR: default: return Intents.RESULT_SMS_GENERIC_ERROR; } } /** * Process the inbound SMS segment. If the message is complete, send it as an ordered * broadcast to interested receivers and return true. If the message is a segment of an * incomplete multi-part SMS, return false. * @param tracker the tracker containing the message segment to process * @return true if an ordered broadcast was sent; false if waiting for more message segments */ boolean processMessagePart(InboundSmsTracker tracker) { int messageCount = tracker.getMessageCount(); byte[][] pdus; int destPort = tracker.getDestPort(); if (messageCount == 1) { // single-part message pdus = new byte[][]{tracker.getPdu()}; } else { // multi-part message Cursor cursor = null; try { // used by several query selection arguments String address = tracker.getAddress(); String refNumber = Integer.toString(tracker.getReferenceNumber()); String count = Integer.toString(tracker.getMessageCount()); // query for all segments and broadcast message if we have all the parts String[] whereArgs = {address, refNumber, count}; cursor = mResolver.query(sRawUri, PDU_SEQUENCE_PORT_PROJECTION, SELECT_BY_REFERENCE, whereArgs, null); int cursorCount = cursor.getCount(); if (cursorCount < messageCount) { // Wait for the other message parts to arrive. It's also possible for the last // segment to arrive before processing the EVENT_BROADCAST_SMS for one of the // earlier segments. In that case, the broadcast will be sent as soon as all // segments are in the table, and any later EVENT_BROADCAST_SMS messages will // get a row count of 0 and return. return false; } // All the parts are in place, deal with them pdus = new byte[messageCount][]; while (cursor.moveToNext()) { // subtract offset to convert sequence to 0-based array index int index = cursor.getInt(SEQUENCE_COLUMN) - tracker.getIndexOffset(); pdus[index] = HexDump.hexStringToByteArray(cursor.getString(PDU_COLUMN)); // Read the destination port from the first segment (needed for CDMA WAP PDU). // It's not a bad idea to prefer the port from the first segment in other cases. if (index == 0 && !cursor.isNull(DESTINATION_PORT_COLUMN)) { int port = cursor.getInt(DESTINATION_PORT_COLUMN); // strip format flags and convert to real port number, or -1 port = InboundSmsTracker.getRealDestPort(port); if (port != -1) { destPort = port; } } } } catch (SQLException e) { loge("Can't access multipart SMS database", e); return false; } finally { if (cursor != null) { cursor.close(); } } } BroadcastReceiver resultReceiver = new SmsBroadcastReceiver(tracker); if (destPort == SmsHeader.PORT_WAP_PUSH) { // Build up the data stream ByteArrayOutputStream output = new ByteArrayOutputStream(); for (byte[] pdu : pdus) { // 3GPP needs to extract the User Data from the PDU; 3GPP2 has already done this if (!tracker.is3gpp2()) { SmsMessage msg = SmsMessage.createFromPdu(pdu, SmsConstants.FORMAT_3GPP); pdu = msg.getUserData(); } output.write(pdu, 0, pdu.length); } int result = mWapPush.dispatchWapPdu(output.toByteArray(), resultReceiver, this); if (DBG) log("dispatchWapPdu() returned " + result); // result is Activity.RESULT_OK if an ordered broadcast was sent return (result == Activity.RESULT_OK); } Intent intent; if (destPort == -1) { intent = new Intent(Intents.SMS_DELIVER_ACTION); // Direct the intent to only the default SMS app. If we can't find a default SMS app // then sent it to all broadcast receivers. ComponentName componentName = SmsApplication.getDefaultSmsApplication(mContext, true); if (componentName != null) { // Deliver SMS message only to this receiver intent.setComponent(componentName); log("Delivering SMS to: " + componentName.getPackageName() + " " + componentName.getClassName()); } } else { Uri uri = Uri.parse("sms://localhost:" + destPort); intent = new Intent(Intents.DATA_SMS_RECEIVED_ACTION, uri); } intent.putExtra("pdus", pdus); intent.putExtra("format", tracker.getFormat()); dispatchIntent(intent, android.Manifest.permission.RECEIVE_SMS, AppOpsManager.OP_RECEIVE_SMS, resultReceiver); return true; } /** * Dispatch the intent with the specified permission, appOp, and result receiver, using * this state machine's handler thread to run the result receiver. * * @param intent the intent to broadcast * @param permission receivers are required to have this permission * @param appOp app op that is being performed when dispatching to a receiver */ void dispatchIntent(Intent intent, String permission, int appOp, BroadcastReceiver resultReceiver) { intent.addFlags(Intent.FLAG_RECEIVER_NO_ABORT); mContext.sendOrderedBroadcast(intent, permission, appOp, resultReceiver, getHandler(), Activity.RESULT_OK, null, null); } /** * Helper for {@link SmsBroadcastUndelivered} to delete an old message in the raw table. */ void deleteFromRawTable(String deleteWhere, String[] deleteWhereArgs) { int rows = mResolver.delete(sRawUri, deleteWhere, deleteWhereArgs); if (rows == 0) { loge("No rows were deleted from raw table!"); } else if (DBG) { log("Deleted " + rows + " rows from raw table."); } } /** * Insert a message PDU into the raw table so we can acknowledge it immediately. * If the device crashes before the broadcast to listeners completes, it will be delivered * from the raw table on the next device boot. For single-part messages, the deleteWhere * and deleteWhereArgs fields of the tracker will be set to delete the correct row after * the ordered broadcast completes. * * @param tracker the tracker to add to the raw table * @return true on success; false on failure to write to database */ private int addTrackerToRawTable(InboundSmsTracker tracker) { if (tracker.getMessageCount() != 1) { // check for duplicate message segments Cursor cursor = null; try { // sequence numbers are 1-based except for CDMA WAP, which is 0-based int sequence = tracker.getSequenceNumber(); // convert to strings for query String address = tracker.getAddress(); String refNumber = Integer.toString(tracker.getReferenceNumber()); String count = Integer.toString(tracker.getMessageCount()); String seqNumber = Integer.toString(sequence); // set the delete selection args for multi-part message String[] deleteWhereArgs = {address, refNumber, count}; tracker.setDeleteWhere(SELECT_BY_REFERENCE, deleteWhereArgs); // Check for duplicate message segments cursor = mResolver.query(sRawUri, PDU_PROJECTION, "address=? AND reference_number=? AND count=? AND sequence=?", new String[] {address, refNumber, count, seqNumber}, null); // moveToNext() returns false if no duplicates were found if (cursor.moveToNext()) { loge("Discarding duplicate message segment, refNumber=" + refNumber + " seqNumber=" + seqNumber); String oldPduString = cursor.getString(PDU_COLUMN); byte[] pdu = tracker.getPdu(); byte[] oldPdu = HexDump.hexStringToByteArray(oldPduString); if (!Arrays.equals(oldPdu, tracker.getPdu())) { loge("Warning: dup message segment PDU of length " + pdu.length + " is different from existing PDU of length " + oldPdu.length); } return Intents.RESULT_SMS_DUPLICATED; // reject message } cursor.close(); } catch (SQLException e) { loge("Can't access multipart SMS database", e); return Intents.RESULT_SMS_GENERIC_ERROR; // reject message } finally { if (cursor != null) { cursor.close(); } } } ContentValues values = tracker.getContentValues(); if (VDBG) log("adding content values to raw table: " + values.toString()); Uri newUri = mResolver.insert(sRawUri, values); if (DBG) log("URI of new row -> " + newUri); try { long rowId = ContentUris.parseId(newUri); if (tracker.getMessageCount() == 1) { // set the delete selection args for single-part message tracker.setDeleteWhere(SELECT_BY_ID, new String[]{Long.toString(rowId)}); } return Intents.RESULT_SMS_HANDLED; } catch (Exception e) { loge("error parsing URI for new row: " + newUri, e); return Intents.RESULT_SMS_GENERIC_ERROR; } } /** * Returns whether the default message format for the current radio technology is 3GPP2. * @return true if the radio technology uses 3GPP2 format by default, false for 3GPP format */ static boolean isCurrentFormat3gpp2() { int activePhone = TelephonyManager.getDefault().getCurrentPhoneType(); return (PHONE_TYPE_CDMA == activePhone); } /** * Handler for an {@link InboundSmsTracker} broadcast. Deletes PDUs from the raw table and * logs the broadcast duration (as an error if the other receivers were especially slow). */ private final class SmsBroadcastReceiver extends BroadcastReceiver { private final String mDeleteWhere; private final String[] mDeleteWhereArgs; private long mBroadcastTimeNano; SmsBroadcastReceiver(InboundSmsTracker tracker) { mDeleteWhere = tracker.getDeleteWhere(); mDeleteWhereArgs = tracker.getDeleteWhereArgs(); mBroadcastTimeNano = System.nanoTime(); } @Override public void onReceive(Context context, Intent intent) { String action = intent.getAction(); if (action.equals(Intents.SMS_DELIVER_ACTION)) { // Now dispatch the notification only intent intent.setAction(Intents.SMS_RECEIVED_ACTION); intent.setComponent(null); dispatchIntent(intent, android.Manifest.permission.RECEIVE_SMS, AppOpsManager.OP_RECEIVE_SMS, this); } else if (action.equals(Intents.WAP_PUSH_DELIVER_ACTION)) { // Now dispatch the notification only intent intent.setAction(Intents.WAP_PUSH_RECEIVED_ACTION); intent.setComponent(null); dispatchIntent(intent, android.Manifest.permission.RECEIVE_SMS, AppOpsManager.OP_RECEIVE_SMS, this); } else { // Now that the intents have been deleted we can clean up the PDU data. if (!Intents.DATA_SMS_RECEIVED_ACTION.equals(action) && !Intents.DATA_SMS_RECEIVED_ACTION.equals(action) && !Intents.WAP_PUSH_RECEIVED_ACTION.equals(action)) { loge("unexpected BroadcastReceiver action: " + action); } int rc = getResultCode(); if ((rc != Activity.RESULT_OK) && (rc != Intents.RESULT_SMS_HANDLED)) { loge("a broadcast receiver set the result code to " + rc + ", deleting from raw table anyway!"); } else if (DBG) { log("successful broadcast, deleting from raw table."); } deleteFromRawTable(mDeleteWhere, mDeleteWhereArgs); sendMessage(EVENT_BROADCAST_COMPLETE); int durationMillis = (int) ((System.nanoTime() - mBroadcastTimeNano) / 1000000); if (durationMillis >= 5000) { loge("Slow ordered broadcast completion time: " + durationMillis + " ms"); } else if (DBG) { log("ordered broadcast completed in: " + durationMillis + " ms"); } } } } /** * Log with debug level. * @param s the string to log */ @Override protected void log(String s) { Rlog.d(getName(), s); } /** * Log with error level. * @param s the string to log */ @Override protected void loge(String s) { Rlog.e(getName(), s); } /** * Log with error level. * @param s the string to log * @param e is a Throwable which logs additional information. */ @Override protected void loge(String s, Throwable e) { Rlog.e(getName(), s, e); } }