List of usage examples for java.nio.channels DatagramChannel validOps
public final int validOps()
From source file:org.openhab.binding.tcp.AbstractDatagramChannelBinding.java
/** * @{inheritDoc}//from ww w . j a va 2s. c o m */ @Override protected void execute() { // Cycle through the Items and setup channels if required for (P provider : providers) { for (String itemName : provider.getItemNames()) { for (Command aCommand : ((P) provider).getAllCommands(itemName)) { String remoteHost = ((P) provider).getHost(itemName, aCommand); String remotePort = ((P) provider).getPortAsString(itemName, aCommand); Direction direction = ((P) provider).getDirection(itemName, aCommand); InetSocketAddress remoteAddress = null; if (!(remoteHost.equals("*") || remotePort.equals("*"))) { remoteAddress = new InetSocketAddress(remoteHost, Integer.parseInt(remotePort)); } Channel newChannel = null; Channel existingChannel = null; if (useAddressMask && (remoteHost.equals("*") || remotePort.equals("*"))) { newChannel = new Channel(itemName, aCommand, remoteHost, remotePort, ((P) provider).getDirection(itemName, aCommand), false, null, false, null); existingChannel = channels.get(itemName, aCommand, direction, remoteHost, remotePort); } else { newChannel = new Channel(itemName, aCommand, remoteAddress, ((P) provider).getDirection(itemName, aCommand), false, null, false, null); existingChannel = channels.get(itemName, aCommand, direction, remoteAddress); } if (existingChannel == null) { if (direction == Direction.IN) { boolean assigned = false; if (useAddressMask && (remoteHost.equals("*") || remotePort.equals("*"))) { logger.warn( "When using address masks we will not verify if we are already listening to similar incoming connections"); logger.info("We will accept data coming from the remote end {}:{}", remoteHost, remotePort); } else { if (channels.contains(itemName, aCommand, Direction.IN, remoteAddress)) { logger.warn("We already listen for incoming connections from {}", remoteAddress); } else { if (itemShareChannels) { Channel firstChannel = channels.getFirstServed(itemName, direction, remoteAddress); if (firstChannel != null) { newChannel.channel = firstChannel.channel; assigned = true; } } if (bindingShareChannels) { Channel firstChannel = channels.getFirstServed(direction, remoteAddress); if (firstChannel != null) { newChannel.channel = firstChannel.channel; assigned = true; } } if (directionsShareChannels) { Channel firstChannel = channels.getFirstServed(remoteAddress); if (firstChannel != null) { newChannel.channel = firstChannel.channel; assigned = true; } } } } if (!assigned) { newChannel.channel = listenerChannel; } if (useAddressMask && (remoteHost.equals("*") || remotePort.equals("*"))) { logger.info("We will accept data coming from the remote end with mask {}:{}", remoteHost, remotePort); } else { logger.info("We will accept data coming from the remote end {}", remoteAddress); } logger.debug("Setting up the inbound channel {}", newChannel); channels.add(newChannel); } else if (direction == Direction.OUT) { boolean assigned = false; if (useAddressMask && (remoteHost.equals("*") || remotePort.equals("*"))) { logger.error( "We do not accept outgoing connections for Items that do use address masks"); } else { channels.add(newChannel); if (newChannel.channel == null) { if (itemShareChannels) { Channel firstChannel = channels.getFirstServed(itemName, direction, remoteAddress); if (firstChannel != null) { newChannel.channel = firstChannel.channel; assigned = true; } } if (bindingShareChannels) { Channel firstChannel = channels.getFirstServed(direction, remoteAddress); if (firstChannel != null) { newChannel.channel = firstChannel.channel; assigned = true; } } // I think it is better not to share incoming connections with outgoing connections (in the case of the // UDP binding) // if(directionsShareChannels) { // Channel firstChannel = channels.getFirstServed(remoteAddress); // if(firstChannel != null) { // newChannel.channel = firstChannel.channel; // assigned = true; // } // if (assigned) { logger.debug("Setting up the outbound assigned channel {} ", newChannel); } } synchronized (this) { if (!assigned || newChannel.channel == null) { DatagramChannel newDatagramChannel = null; try { newDatagramChannel = DatagramChannel.open(); } catch (IOException e2) { logger.error("An exception occurred while opening a channel: {}", e2.getMessage()); } try { newDatagramChannel.configureBlocking(false); //setKeepAlive(true); } catch (IOException e) { logger.error("An exception occurred while configuring a channel: {}", e.getMessage()); } synchronized (selector) { selector.wakeup(); try { newDatagramChannel.register(selector, newDatagramChannel.validOps()); } catch (ClosedChannelException e1) { logger.error( "An exception occurred while registering a selector: {}", e1.getMessage()); } } newChannel.channel = newDatagramChannel; logger.debug("Setting up the outbound channel {}", newChannel); try { logger.info("'Connecting' the channel {} ", newChannel); newDatagramChannel.connect(remoteAddress); } catch (IOException e) { logger.error("An exception occurred while connecting a channel: {}", e.getMessage()); } } else { logger.info("There is already an active channel {} for the remote end {}", newChannel.channel, newChannel.remote); } } } } } } } } // Check on channels for which we have to process data synchronized (selector) { try { // Wait for an event selector.selectNow(); } catch (IOException e) { logger.error("An exception occurred while Selecting ({})", e.getMessage()); } } // Get list of selection keys with pending events Iterator<SelectionKey> it = selector.selectedKeys().iterator(); // Process each key at a time while (it.hasNext()) { SelectionKey selKey = (SelectionKey) it.next(); it.remove(); if (selKey.isValid()) { DatagramChannel theDatagramChannel = (DatagramChannel) selKey.channel(); Channel theChannel = channels.get(theDatagramChannel); if (selKey.isReadable()) { InetSocketAddress clientAddress = null; ByteBuffer readBuffer = ByteBuffer.allocate(maximumBufferSize); int numberBytesRead = 0; boolean error = false; if (selKey == listenerKey) { try { clientAddress = (InetSocketAddress) theDatagramChannel.receive(readBuffer); logger.debug("Received {} on the listener port from {}", new String(readBuffer.array()), clientAddress); numberBytesRead = readBuffer.position(); } catch (Exception e) { error = true; } } else { try { //TODO: Additional code to split readBuffer in multiple parts, in case the data send by the remote end is not correctly fragemented. Could be handed of to implementation class if for example, the buffer needs to be split based on a special character like line feed or carriage return numberBytesRead = theDatagramChannel.read(readBuffer); logger.debug("Received {} bytes ({}) on the channel {}->{}", new Object[] { numberBytesRead, new String(readBuffer.array()), theDatagramChannel.getLocalAddress(), theDatagramChannel.getRemoteAddress() }); } catch (NotYetConnectedException e) { try { logger.warn("The channel for {} has no connection pending ({})", theDatagramChannel.getRemoteAddress(), e.getMessage()); } catch (IOException e1) { logger.error( "An exception occurred while getting the remote address of channel {} ({})", theDatagramChannel, e1.getMessage()); } error = true; } catch (IOException e) { // If some other I/O error occurs try { logger.warn("The channel for {} has encountered an unknown IO Exception: {}", theDatagramChannel.getRemoteAddress(), e.getMessage()); } catch (IOException e1) { logger.error( "An exception occurred while getting the remote address of channel {} ({})", theDatagramChannel, e1.getMessage()); } error = true; } } if (numberBytesRead == -1) { try { if (selKey != listenerKey) { theDatagramChannel.close(); } } catch (IOException e) { try { logger.warn("The channel for {} is closed ({})", theDatagramChannel.getRemoteAddress(), e.getMessage()); } catch (IOException e1) { logger.error( "An exception occurred while getting the remote address of channel {} ({})", theDatagramChannel, e1.getMessage()); } } error = true; } if (error) { if (selKey != listenerKey) { Scheduler scheduler = null; try { scheduler = StdSchedulerFactory.getDefaultScheduler(); } catch (SchedulerException e1) { logger.error("An exception occurred while getting the Quartz scheduler: {}", e1.getMessage()); } JobDataMap map = new JobDataMap(); map.put("Channel", theChannel); map.put("Binding", this); JobDetail job = null; Trigger trigger = null; job = newJob(ReconnectJob.class) .withIdentity(Integer.toHexString(hashCode()) + "-Reconnect-" + Long.toString(System.currentTimeMillis()), this.toString()) .usingJobData(map).build(); trigger = newTrigger() .withIdentity(Integer.toHexString(hashCode()) + "-Reconnect-" + Long.toString(System.currentTimeMillis()), this.toString()) .startAt(futureDate(reconnectInterval, IntervalUnit.SECOND)).build(); try { if (job != null && trigger != null && selKey != listenerKey) { if (!theChannel.isReconnecting) { channels.setAllReconnecting(theDatagramChannel, true); scheduler.scheduleJob(job, trigger); } } } catch (SchedulerException e) { logger.error( "An exception occurred while scheduling a job with the Quartz Scheduler {}", e.getMessage()); } } } else { ArrayList<Channel> channelsToServe = new ArrayList<Channel>(); if (selKey == listenerKey) { channelsToServe = channels.getAll(Direction.IN, clientAddress); if (channelsToServe.size() == 0) { logger.warn( "Received data {} from an undefined remote end {}. We will not process it", new String(readBuffer.array()), clientAddress); } } else { channelsToServe = channels.getAll(theDatagramChannel); } if (channelsToServe.size() > 0) { readBuffer.flip(); if (channels.isBlocking(theDatagramChannel)) { // if we are in a blocking operation, we get are now finished and we have to reset the flag. The read buffer will be returned to the instance // that initiated the write opreation - it has to parse the buffer itself //find the Channel with this DGC that is holding a Blocking flag theChannel = channels.getBlocking(theDatagramChannel); theChannel.buffer = readBuffer; } else { for (Channel aChannel : channelsToServe) { if (useAddressMask) { aChannel.lastRemote = clientAddress; } // if not, then we parse the buffer as ususal parseChanneledBuffer(aChannel, readBuffer); } } } else { try { if (selKey == listenerKey) { logger.warn( "No channel is active or defined for the data we received from {}. It will be discarded.", clientAddress); } else { logger.warn( "No channel is active or defined for the data we received from {}. It will be discarded.", theDatagramChannel.getRemoteAddress()); } } catch (IOException e) { logger.error( "An exception occurred while getting the remote address of channel {} ({})", theDatagramChannel, e.getMessage()); } } } } else if (selKey.isWritable()) { WriteBufferElement theElement = null; if (selKey == listenerKey) { Iterator<WriteBufferElement> iterator = writeQueue.iterator(); while (iterator.hasNext()) { WriteBufferElement anElement = iterator.next(); if (anElement.channel.channel.equals(listenerChannel)) { theElement = anElement; break; } } } //check if any of the Channel using the DatagramChannel is blocking the DGC in a R/W operation boolean isBlocking = channels.isBlocking(theDatagramChannel); if (isBlocking) { // if this channel is already flagged as being in a blocked write/read operation, we skip this selKey } else { if (selKey != listenerKey) { Iterator<WriteBufferElement> iterator = writeQueue.iterator(); while (iterator.hasNext()) { WriteBufferElement anElement = iterator.next(); if (anElement.channel.channel.equals(theDatagramChannel)) { theElement = anElement; break; } } } if (theElement != null && theElement.buffer != null) { logger.debug("Picked {} from the queue", theElement); if (theElement.isBlocking) { theElement.channel.isBlocking = true; } boolean error = false; theElement.buffer.rewind(); if (selKey == listenerKey) { try { if (useAddressMask && theElement.channel.remote == null) { if (theElement.channel.lastRemote != null) { logger.debug( "Sending {} for the masked inbound channel {}:{} to the remote address {}", new Object[] { new String(theElement.buffer.array()), theElement.channel.host, theElement.channel.port, theElement.channel.lastRemote }); listenerChannel.send(theElement.buffer, theElement.channel.lastRemote); } else { logger.warn("I do not know where to send the data {}", new String(theElement.buffer.array())); } } else { logger.debug( "Sending {} for the inbound channel {}:{} to the remote address {}", new Object[] { new String(theElement.buffer.array()), theElement.channel.host, theElement.channel.port, theElement.channel.remote }); listenerChannel.send(theElement.buffer, theElement.channel.remote); } } catch (IOException e) { if (theElement.channel.lastRemote != null) { logger.error( "An exception occurred while sending data to the remote end {} ({})", theElement.channel.lastRemote, e.getMessage()); } else { logger.error( "An exception occurred while sending data to the remote end {} ({})", theElement.channel.remote, e.getMessage()); } } } else { try { logger.debug( "Sending {} for the outbound channel {}:{} to the remote address {}", new Object[] { new String(theElement.buffer.array()), theElement.channel.host, theElement.channel.port, theElement.channel.remote }); theDatagramChannel.write(theElement.buffer); } catch (NotYetConnectedException e) { logger.warn("The channel for {} has no connection pending ({})", theElement.channel.remote, e.getMessage()); error = true; } catch (ClosedChannelException e) { // If some other I/O error occurs logger.warn("The channel for {} is closed ({})", theElement.channel.remote, e.getMessage()); error = true; } catch (IOException e) { // If some other I/O error occurs logger.warn("The channel for {} has encountered an unknown IO Exception: {}", theElement.channel.remote, e.getMessage()); error = true; } } if (error) { if (selKey != listenerKey) { Scheduler scheduler = null; try { scheduler = StdSchedulerFactory.getDefaultScheduler(); } catch (SchedulerException e1) { logger.error("An exception occurred while getting the Quartz scheduler: {}", e1.getMessage()); } JobDataMap map = new JobDataMap(); map.put("Channel", theElement.channel); map.put("Binding", this); JobDetail job = null; Trigger trigger = null; job = newJob(ReconnectJob.class) .withIdentity( Integer.toHexString(hashCode()) + "-Reconnect-" + Long.toString(System.currentTimeMillis()), this.toString()) .usingJobData(map).build(); trigger = newTrigger() .withIdentity( Integer.toHexString(hashCode()) + "-Reconnect-" + Long.toString(System.currentTimeMillis()), this.toString()) .startAt(futureDate(reconnectInterval, IntervalUnit.SECOND)).build(); try { if (job != null && trigger != null && selKey != listenerKey) { if (!theElement.channel.isReconnecting) { channels.setAllReconnecting(theElement.channel.channel, true); scheduler.scheduleJob(job, trigger); } } } catch (SchedulerException e) { logger.error( "An exception occurred while scheduling a job with the Quartz Scheduler {}", e.getMessage()); } } } else { if (theElement != null) { writeQueue.remove(theElement); } } } } } } } }