/*
* JBoss, Home of Professional Open Source.
* Copyright 2014 Red Hat, Inc., and individual contributors
* as indicated by the @author tags.
*
* 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.
*/
package io.undertow.server.protocol.framed;
import static org.xnio.IoUtils.safeClose;
import java.io.IOException;
import java.net.InetSocketAddress;
import java.net.SocketAddress;
import java.nio.ByteBuffer;
import java.nio.channels.ClosedChannelException;
import java.util.ArrayDeque;
import java.util.ArrayList;
import java.util.Deque;
import java.util.HashSet;
import java.util.LinkedList;
import java.util.List;
import java.util.ListIterator;
import java.util.Set;
import java.util.concurrent.CopyOnWriteArrayList;
import java.util.concurrent.LinkedBlockingDeque;
import java.util.concurrent.RejectedExecutionException;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.AtomicIntegerFieldUpdater;
import org.xnio.Buffers;
import org.xnio.ChannelExceptionHandler;
import org.xnio.ChannelListener;
import org.xnio.ChannelListener.Setter;
import org.xnio.ChannelListeners;
import org.xnio.IoUtils;
import org.xnio.Option;
import org.xnio.OptionMap;
import org.xnio.StreamConnection;
import org.xnio.XnioIoThread;
import org.xnio.XnioWorker;
import org.xnio.channels.CloseableChannel;
import org.xnio.channels.ConnectedChannel;
import org.xnio.channels.StreamSinkChannel;
import org.xnio.channels.StreamSourceChannel;
import org.xnio.channels.SuspendableWriteChannel;
import io.undertow.UndertowLogger;
import io.undertow.UndertowMessages;
import io.undertow.UndertowOptions;
import io.undertow.conduits.IdleTimeoutConduit;
import io.undertow.connector.ByteBufferPool;
import io.undertow.connector.PooledByteBuffer;
import io.undertow.util.ReferenceCountedPooled;
/**
* A {@link org.xnio.channels.ConnectedChannel} which can be used to send and receive Frames.
* <p>
* This provides a common base for framed protocols such as websockets and SPDY
*
* @author Stuart Douglas
*/
public abstract class AbstractFramedChannel<C extends AbstractFramedChannel<C, R, S>, R extends AbstractFramedStreamSourceChannel<C, R, S>, S extends AbstractFramedStreamSinkChannel<C, R, S>> implements ConnectedChannel {
/**
* The maximum number of buffers we will queue before suspending reads and
* waiting for the buffers to be consumed
*
* TODO: make the configurable
*/
private final int maxQueuedBuffers;
private final StreamConnection channel;
private final IdleTimeoutConduit idleTimeoutConduit;
private final ChannelListener.SimpleSetter<C> closeSetter;
private final ChannelListener.SimpleSetter<C> receiveSetter;
private final ByteBufferPool bufferPool;
/**
* Frame priority implementation. This is used to determine the order in which frames get sent
*/
private final FramePriority<C, R, S> framePriority;
/**
* List of frames that are ready to send
*/
private final List<S> pendingFrames = new LinkedList<>();
/**
* Frames that are not yet read to send.
*/
private final Deque<S> heldFrames = new ArrayDeque<>();
/**
* new frames to be sent. These will be added to either the pending or held frames list
* depending on the {@link #framePriority} implementation in use.
*/
private final Deque<S> newFrames = new LinkedBlockingDeque<>();
private volatile long frameDataRemaining;
private volatile R receiver;
private volatile boolean receivesSuspended = true;
@SuppressWarnings("unused")
private volatile int readsBroken = 0;
@SuppressWarnings("unused")
private volatile int writesBroken = 0;
private static final AtomicIntegerFieldUpdater<AbstractFramedChannel> readsBrokenUpdater = AtomicIntegerFieldUpdater.newUpdater(AbstractFramedChannel.class, "readsBroken");
private static final AtomicIntegerFieldUpdater<AbstractFramedChannel> writesBrokenUpdater = AtomicIntegerFieldUpdater.newUpdater(AbstractFramedChannel.class, "writesBroken");
private volatile ReferenceCountedPooled readData = null;
private final List<ChannelListener<C>> closeTasks = new CopyOnWriteArrayList<>();
private volatile boolean flushingSenders = false;
private final Set<AbstractFramedStreamSourceChannel<C, R, S>> receivers = new HashSet<>();
@SuppressWarnings("unused")
private volatile int outstandingBuffers;
private volatile AtomicIntegerFieldUpdater<AbstractFramedChannel> outstandingBuffersUpdater = AtomicIntegerFieldUpdater.newUpdater(AbstractFramedChannel.class, "outstandingBuffers");
private final LinkedBlockingDeque<Runnable> taskRunQueue = new LinkedBlockingDeque<>();
private final OptionMap settings;
/**
* If this is true then the flush() method must be called to queue writes. This is provided to support batching
*/
private volatile boolean requireExplicitFlush = false;
private volatile boolean readChannelDone = false;
private final ReferenceCountedPooled.FreeNotifier freeNotifier = new ReferenceCountedPooled.FreeNotifier() {
@Override
public void freed() {
int res = outstandingBuffersUpdater.decrementAndGet(AbstractFramedChannel.this);
if(!receivesSuspended && res == maxQueuedBuffers - 1) {
synchronized (AbstractFramedChannel.this) {
if(outstandingBuffersUpdater.get(AbstractFramedChannel.this) < maxQueuedBuffers) {
if(UndertowLogger.REQUEST_IO_LOGGER.isTraceEnabled()) {
UndertowLogger.REQUEST_IO_LOGGER.tracef("Resuming reads on %s as buffers have been consumed", AbstractFramedChannel.this);
}
channel.getSourceChannel().resumeReads();
}
}
}
}
};
private static final ChannelListener<AbstractFramedChannel> DRAIN_LISTENER = new ChannelListener<AbstractFramedChannel>() {
@Override
public void handleEvent(AbstractFramedChannel channel) {
try {
AbstractFramedStreamSourceChannel stream = channel.receive();
if(stream != null) {
UndertowLogger.REQUEST_IO_LOGGER.debugf("Draining channel %s as no receive listener has been set", stream);
stream.getReadSetter().set(ChannelListeners.drainListener(Long.MAX_VALUE, null, null));
stream.wakeupReads();
}
} catch (IOException e) {
IoUtils.safeClose(channel);
}
}
};
/**
* Create a new {@link io.undertow.server.protocol.framed.AbstractFramedChannel}
* 8
* @param connectedStreamChannel The {@link org.xnio.channels.ConnectedStreamChannel} over which the Frames should get send and received.
* Be aware that it already must be "upgraded".
* @param bufferPool The {@link ByteBufferPool} which will be used to acquire {@link ByteBuffer}'s from.
* @param framePriority
* @param settings The settings
*/
protected AbstractFramedChannel(final StreamConnection connectedStreamChannel, ByteBufferPool bufferPool, FramePriority<C, R, S> framePriority, final PooledByteBuffer readData, OptionMap settings) {
this.framePriority = framePriority;
this.maxQueuedBuffers = settings.get(UndertowOptions.MAX_QUEUED_READ_BUFFERS, 10);
this.settings = settings;
if (readData != null) {
if(readData.getBuffer().hasRemaining()) {
this.readData = new ReferenceCountedPooled(readData, 1);
} else {
readData.close();
}
}
if(bufferPool == null) {
throw UndertowMessages.MESSAGES.argumentCannotBeNull("bufferPool");
}
if(connectedStreamChannel == null) {
throw UndertowMessages.MESSAGES.argumentCannotBeNull("connectedStreamChannel");
}
IdleTimeoutConduit idle = createIdleTimeoutChannel(connectedStreamChannel);
connectedStreamChannel.getSourceChannel().setConduit(idle);
connectedStreamChannel.getSinkChannel().setConduit(idle);
this.idleTimeoutConduit = idle;
this.channel = connectedStreamChannel;
this.bufferPool = bufferPool;
closeSetter = new ChannelListener.SimpleSetter<>();
receiveSetter = new ChannelListener.SimpleSetter<>();
channel.getSourceChannel().getReadSetter().set(null);
channel.getSourceChannel().suspendReads();
channel.getSourceChannel().getReadSetter().set(new FrameReadListener());
connectedStreamChannel.getSinkChannel().getWriteSetter().set(new FrameWriteListener());
FrameCloseListener closeListener = new FrameCloseListener();
connectedStreamChannel.getSinkChannel().getCloseSetter().set(closeListener);
connectedStreamChannel.getSourceChannel().getCloseSetter().set(closeListener);
}
protected IdleTimeoutConduit createIdleTimeoutChannel(StreamConnection connectedStreamChannel) {
return new IdleTimeoutConduit(connectedStreamChannel);
}
void runInIoThread(Runnable task) {
this.taskRunQueue.add(task);
try {
getIoThread().execute(new Runnable() {
@Override
public void run() {
while (!taskRunQueue.isEmpty()) {
taskRunQueue.poll().run();
}
}
});
} catch (RejectedExecutionException e) {
//thread is shutting down
while (!taskRunQueue.isEmpty()) {
taskRunQueue.poll().run();
}
}
}
/**
* Get the buffer pool for this connection.
*
* @return the buffer pool for this connection
*/
public ByteBufferPool getBufferPool() {
return bufferPool;
}
@Override
public SocketAddress getLocalAddress() {
return channel.getLocalAddress();
}
@Override
public <A extends SocketAddress> A getLocalAddress(Class<A> type) {
return channel.getLocalAddress(type);
}
@Override
public XnioWorker getWorker() {
return channel.getWorker();
}
@Override
public XnioIoThread getIoThread() {
return channel.getIoThread();
}
@Override
public boolean supportsOption(Option<?> option) {
return channel.supportsOption(option);
}
@Override
public <T> T getOption(Option<T> option) throws IOException {
return channel.getOption(option);
}
@Override
public <T> T setOption(Option<T> option, T value) throws IOException {
return channel.setOption(option, value);
}
@Override
public boolean isOpen() {
return channel.isOpen();
}
@Override
public SocketAddress getPeerAddress() {
return channel.getPeerAddress();
}
@Override
public <A extends SocketAddress> A getPeerAddress(Class<A> type) {
return channel.getPeerAddress(type);
}
/**
* Get the source address of the Channel.
*
* @return the source address of the Channel
*/
public InetSocketAddress getSourceAddress() {
return getPeerAddress(InetSocketAddress.class);
}
/**
* Get the destination address of the Channel.
*
* @return the destination address of the Channel
*/
public InetSocketAddress getDestinationAddress() {
return getLocalAddress(InetSocketAddress.class);
}
/**
* receive method, returns null if no frame is ready. Otherwise returns a
* channel that can be used to read the frame contents.
* <p>
* Calling this method can also have the side effect of making additional data available to
* existing source channels. In general if you suspend receives or don't have some other way
* of calling this method then it can prevent frame channels for being fully consumed.
*/
public synchronized R receive() throws IOException {
if (readChannelDone && receiver == null) {
//we have received the last frame, we just shut down and return
//it would probably make more sense to have the last channel responsible for this
//however it is much simpler just to have it here
if(readData != null) {
readData.close();
readData = null;
}
channel.getSourceChannel().suspendReads();
channel.getSourceChannel().shutdownReads();
return null;
}
ReferenceCountedPooled pooled = this.readData;
boolean hasData;
if (pooled == null) {
pooled = allocateReferenceCountedBuffer();
if (pooled == null) {
return null;
}
hasData = false;
} else if(pooled.isFreed()) {
//we attempt to re-used an existing buffer
if(!pooled.tryUnfree()) {
pooled = allocateReferenceCountedBuffer();
if (pooled == null) {
return null;
}
} else {
pooled.getBuffer().limit(pooled.getBuffer().capacity());
}
hasData = false;
} else {
hasData = pooled.getBuffer().hasRemaining();
}
boolean forceFree = false;
int read = 0;
try {
if (!hasData) {
pooled.getBuffer().clear();
read = channel.getSourceChannel().read(pooled.getBuffer());
if (read == 0) {
//no data, we just free the buffer
forceFree = true;
return null;
} else if (read == -1) {
forceFree = true;
readChannelDone = true;
lastDataRead();
return null;
} else if(isLastFrameReceived() && frameDataRemaining == 0) {
//we got data, although we should have received the last frame
forceFree = true;
markReadsBroken(new ClosedChannelException());
}
pooled.getBuffer().flip();
}
if (frameDataRemaining > 0) {
if (frameDataRemaining >= pooled.getBuffer().remaining()) {
frameDataRemaining -= pooled.getBuffer().remaining();
if(receiver != null) {
//we still create a pooled view, this means that if the buffer is still active we can re-used it
//which prevents attacks based on sending lots of small fragments
ByteBuffer buf = pooled.getBuffer().duplicate();
pooled.getBuffer().position(pooled.getBuffer().limit());
PooledByteBuffer frameData = pooled.createView(buf);
receiver.dataReady(null, frameData);
} else {
//we are dropping a frame
pooled.close();
readData = null;
}
if(frameDataRemaining == 0) {
receiver = null;
}
return null;
} else {
ByteBuffer buf = pooled.getBuffer().duplicate();
buf.limit((int) (buf.position() + frameDataRemaining));
pooled.getBuffer().position((int) (pooled.getBuffer().position() + frameDataRemaining));
frameDataRemaining = 0;
PooledByteBuffer frameData = pooled.createView(buf);
if(receiver != null) {
receiver.dataReady(null, frameData);
} else{
//we are dropping the frame
frameData.close();
}
receiver = null;
}
//if we read data into a frame we just return immediately, even if there is more remaining
//see https://issues.jboss.org/browse/UNDERTOW-410
//basically if we don't do this we loose some message ordering semantics
//as the second message may be processed before the first one
//this is problematic for HTTPS, where the read listener may also be invoked by a queued task
//and not by the selector mechanism
return null;
}
FrameHeaderData data = parseFrame(pooled.getBuffer());
if (data != null) {
PooledByteBuffer frameData;
if (data.getFrameLength() >= pooled.getBuffer().remaining()) {
frameDataRemaining = data.getFrameLength() - pooled.getBuffer().remaining();
frameData = pooled.createView(pooled.getBuffer().duplicate());
pooled.getBuffer().position(pooled.getBuffer().limit());
} else {
ByteBuffer buf = pooled.getBuffer().duplicate();
buf.limit((int) (buf.position() + data.getFrameLength()));
pooled.getBuffer().position((int) (pooled.getBuffer().position() + data.getFrameLength()));
frameData = pooled.createView(buf);
}
AbstractFramedStreamSourceChannel<?, ?, ?> existing = data.getExistingChannel();
if (existing != null) {
if (data.getFrameLength() > frameData.getBuffer().remaining()) {
receiver = (R) existing;
}
existing.dataReady(data, frameData);
if(isLastFrameReceived()) {
handleLastFrame(existing);
}
return null;
} else {
boolean moreData = data.getFrameLength() > frameData.getBuffer().remaining();
R newChannel = createChannel(data, frameData);
if (newChannel != null) {
if(!newChannel.isComplete()) {
receivers.add(newChannel);
}
if (moreData) {
receiver = newChannel;
}
if(isLastFrameReceived()) {
handleLastFrame(newChannel);
}
} else {
frameData.close();
}
return newChannel;
}
}
return null;
} catch (IOException|RuntimeException e) {
//something has code wrong with parsing, close the read side
//we don't close the write side, as the underlying implementation will most likely want to send an error
markReadsBroken(e);
forceFree = true;
throw e;
}finally {
//if the receive caused the channel to break the close listener may be have been called
//which will make readData null
if (readData != null) {
if (!pooled.getBuffer().hasRemaining() || forceFree) {
if(pooled.getBuffer().limit() * 2 > pooled.getBuffer().capacity() || forceFree) {
//if we have used more than half the buffer we don't allow it to be re-aquired
readData = null;
}
//even though this is freed we may un-free it if we get a new packet
//this prevents many small reads resulting in a large number of allocated buffers
pooled.close();
}
}
}
}
/**
* Called when the last frame has been received (note that their may still be data from the last frame than needs to be read)
* @param newChannel The channel that received the last frame
*/
private void handleLastFrame(AbstractFramedStreamSourceChannel newChannel) {
//make a defensive copy
Set<AbstractFramedStreamSourceChannel<C, R, S>> receivers = new HashSet<>(this.receivers);
for(AbstractFramedStreamSourceChannel<C, R, S> r : receivers) {
if(r != newChannel) {
r.markStreamBroken();
}
}
}
private ReferenceCountedPooled allocateReferenceCountedBuffer() {
if(maxQueuedBuffers > 0) {
int expect;
do {
expect = outstandingBuffersUpdater.get(this);
if (expect == maxQueuedBuffers) {
synchronized (this) {
//we need to re-read in a sync block, to prevent races
expect = outstandingBuffersUpdater.get(this);
if (expect == maxQueuedBuffers) {
if(UndertowLogger.REQUEST_IO_LOGGER.isTraceEnabled()) {
UndertowLogger.REQUEST_IO_LOGGER.tracef("Suspending reads on %s due to too many outstanding buffers", this);
}
channel.getSourceChannel().suspendReads();
return null;
}
}
}
} while (!outstandingBuffersUpdater.compareAndSet(this, expect, expect + 1));
}
PooledByteBuffer buf = bufferPool.allocate();
return this.readData = new ReferenceCountedPooled(buf, 1, maxQueuedBuffers > 0 ? freeNotifier : null);
}
/**
* Method than is invoked when read() returns -1.
*/
protected void lastDataRead() {
}
/**
* Method that creates the actual stream source channel implementation that is in use.
*
* @param frameHeaderData The header data, as returned by {@link #parseFrame(java.nio.ByteBuffer)}
* @param frameData Any additional data for the frame that has already been read. This may not be the complete frame contents
* @return A new stream source channel
*/
protected abstract R createChannel(FrameHeaderData frameHeaderData, PooledByteBuffer frameData) throws IOException;
/**
* Attempts to parse an incoming frame header from the data in the buffer.
*
* @param data The data that has been read from the channel
* @return The frame header data, or <code>null</code> if the data was incomplete
* @throws IOException If the data could not be parsed.
*/
protected abstract FrameHeaderData parseFrame(ByteBuffer data) throws IOException;
protected synchronized void recalculateHeldFrames() throws IOException {
if (!heldFrames.isEmpty()) {
framePriority.frameAdded(null, pendingFrames, heldFrames);
flushSenders();
}
}
/**
* Flushes all ready stream sink conduits to the channel.
* <p>
* Frames will be batched up, to allow them all to be written out via a gathering
* write. The {@link #framePriority} implementation will be invoked to decide which
* frames are eligible for sending and in what order.
*/
protected synchronized void flushSenders() {
if(flushingSenders) {
throw UndertowMessages.MESSAGES.recursiveCallToFlushingSenders();
}
flushingSenders = true;
try {
int toSend = 0;
while (!newFrames.isEmpty()) {
S frame = newFrames.poll();
frame.preWrite();
if (framePriority.insertFrame(frame, pendingFrames)) {
if (!heldFrames.isEmpty()) {
framePriority.frameAdded(frame, pendingFrames, heldFrames);
}
} else {
heldFrames.add(frame);
}
}
boolean finalFrame = false;
ListIterator<S> it = pendingFrames.listIterator();
while (it.hasNext()) {
S sender = it.next();
if (sender.isReadyForFlush()) {
++toSend;
} else {
break;
}
if (sender.isLastFrame()) {
finalFrame = true;
}
}
if (toSend == 0) {
//if there is nothing to send we just attempt a flush on the underlying channel
try {
if(channel.getSinkChannel().flush()) {
channel.getSinkChannel().suspendWrites();
}
} catch (IOException e) {
safeClose(channel);
markWritesBroken(e);
}
return;
}
ByteBuffer[] data = new ByteBuffer[toSend * 3];
int j = 0;
it = pendingFrames.listIterator();
try {
while (j < toSend) {
S next = it.next();
//todo: rather than adding empty buffers just store the offsets
SendFrameHeader frameHeader = next.getFrameHeader();
PooledByteBuffer frameHeaderByteBuffer = frameHeader.getByteBuffer();
ByteBuffer frameTrailerBuffer = frameHeader.getTrailer();
data[j * 3] = frameHeaderByteBuffer != null
? frameHeaderByteBuffer.getBuffer()
: Buffers.EMPTY_BYTE_BUFFER;
data[(j * 3) + 1] = next.getBuffer() == null ? Buffers.EMPTY_BYTE_BUFFER : next.getBuffer();
data[(j * 3) + 2] = frameTrailerBuffer != null ? frameTrailerBuffer : Buffers.EMPTY_BYTE_BUFFER;
++j;
}
long toWrite = Buffers.remaining(data);
long res;
do {
res = channel.getSinkChannel().write(data);
toWrite -= res;
} while (res > 0 && toWrite > 0);
int max = toSend;
while (max > 0) {
S sinkChannel = pendingFrames.get(0);
PooledByteBuffer frameHeaderByteBuffer = sinkChannel.getFrameHeader().getByteBuffer();
ByteBuffer frameTrailerBuffer = sinkChannel.getFrameHeader().getTrailer();
if (frameHeaderByteBuffer != null && frameHeaderByteBuffer.getBuffer().hasRemaining()
|| sinkChannel.getBuffer() != null && sinkChannel.getBuffer().hasRemaining()
|| frameTrailerBuffer != null && frameTrailerBuffer.hasRemaining()) {
break;
}
sinkChannel.flushComplete();
pendingFrames.remove(sinkChannel);
max--;
}
if (!pendingFrames.isEmpty() || !channel.getSinkChannel().flush()) {
channel.getSinkChannel().resumeWrites();
} else {
channel.getSinkChannel().suspendWrites();
}
if (pendingFrames.isEmpty() && finalFrame) {
//all data has been sent. Close gracefully
channel.getSinkChannel().shutdownWrites();
if (!channel.getSinkChannel().flush()) {
channel.getSinkChannel().setWriteListener(ChannelListeners.flushingChannelListener(null, null));
channel.getSinkChannel().resumeWrites();
}
}
} catch (IOException e) {
safeClose(channel);
markWritesBroken(e);
}
} finally {
flushingSenders = false;
if(!newFrames.isEmpty()) {
runInIoThread(new Runnable() {
@Override
public void run() {
flushSenders();
}
});
}
}
}
void awaitWritable() throws IOException {
this.channel.getSinkChannel().awaitWritable();
}
void awaitWritable(long time, TimeUnit unit) throws IOException {
this.channel.getSinkChannel().awaitWritable(time, unit);
}
/**
* Queues a new frame to be sent, and attempts a flush if this is the first frame in the new frame queue.
* <p>
* Depending on the {@link FramePriority} implementation in use the channel may or may not be added to the actual
* pending queue
*
* @param channel The channel
*/
protected void queueFrame(final S channel) throws IOException {
assert !newFrames.contains(channel);
if (isWritesBroken() || !this.channel.getSinkChannel().isOpen() || channel.isBroken() || !channel.isOpen()) {
IoUtils.safeClose(channel);
throw UndertowMessages.MESSAGES.channelIsClosed();
}
newFrames.add(channel);
if (!requireExplicitFlush || channel.isBufferFull()) {
flush();
}
}
public void flush() {
if (!flushingSenders) {
if(channel.getIoThread() == Thread.currentThread()) {
flushSenders();
} else {
runInIoThread(new Runnable() {
@Override
public void run() {
flushSenders();
}
});
}
}
}
/**
* Returns true if the protocol specific final frame has been received.
*
* @return <code>true</code> If the last frame has been received
*/
protected abstract boolean isLastFrameReceived();
/**
* @return <code>true</code> If the last frame has been sent
*/
protected abstract boolean isLastFrameSent();
/**
* Method that is invoked when the read side of the channel is broken. This generally happens on a protocol error.
*/
protected abstract void handleBrokenSourceChannel(Throwable e);
/**
* Method that is invoked when then write side of a channel is broken. This generally happens on a protocol error.
*/
protected abstract void handleBrokenSinkChannel(Throwable e);
/**
* Return the {@link org.xnio.ChannelListener.Setter} which will holds the {@link org.xnio.ChannelListener} that gets notified once a frame was
* received.
*/
public Setter<C> getReceiveSetter() {
return receiveSetter;
}
/**
* Suspend the receive of new frames via {@link #receive()}
*/
public synchronized void suspendReceives() {
receivesSuspended = true;
if (receiver == null) {
channel.getSourceChannel().suspendReads();
}
}
/**
* Resume the receive of new frames via {@link #receive()}
*/
public synchronized void resumeReceives() {
receivesSuspended = false;
if (readData != null && !readData.isFreed()) {
channel.getSourceChannel().wakeupReads();
} else {
channel.getSourceChannel().resumeReads();
}
}
public boolean isReceivesResumed() {
return !receivesSuspended;
}
/**
* Forcibly closes the {@link io.undertow.server.protocol.framed.AbstractFramedChannel}.
*/
@Override
public void close() throws IOException {
if(UndertowLogger.REQUEST_IO_LOGGER.isTraceEnabled()) {
UndertowLogger.REQUEST_IO_LOGGER.tracef(new ClosedChannelException(), "Channel %s is being closed", this);
}
safeClose(channel);
if(readData != null) {
readData.close();
readData = null;
}
closeSubChannels();
}
@Override
public Setter<? extends AbstractFramedChannel> getCloseSetter() {
return closeSetter;
}
/**
* Called when a source sub channel fails to fulfil its contract, and leaves the channel in an inconsistent state.
* <p>
* The underlying read side will be forcibly closed.
*
* @param cause The possibly null cause
*/
@SuppressWarnings({"unchecked", "rawtypes"})
protected void markReadsBroken(Throwable cause) {
if (readsBrokenUpdater.compareAndSet(this, 0, 1)) {
if(UndertowLogger.REQUEST_IO_LOGGER.isDebugEnabled()) {
UndertowLogger.REQUEST_IO_LOGGER.debugf(new ClosedChannelException(), "Marking reads broken on channel %s", this);
}
if(receiver != null) {
receiver.markStreamBroken();
}
for(AbstractFramedStreamSourceChannel<C, R, S> r : new ArrayList<>(receivers)) {
r.markStreamBroken();
}
handleBrokenSourceChannel(cause);
safeClose(channel.getSourceChannel());
closeSubChannels();
}
}
/**
* Method that is called when the channel is being forcibly closed, and all sub stream sink/source
* channels should also be forcibly closed.
*/
protected abstract void closeSubChannels();
/**
* Called when a sub channel fails to fulfil its contract, and leaves the channel in an inconsistent state.
* <p>
* The underlying channel will be closed, and any sub channels that have writes resumed will have their
* listeners notified. It is expected that these listeners will then attempt to use the channel, and their standard
* error handling logic will take over.
*
* @param cause The possibly null cause
*/
@SuppressWarnings({"unchecked", "rawtypes"})
protected void markWritesBroken(Throwable cause) {
if (writesBrokenUpdater.compareAndSet(this, 0, 1)) {
if(UndertowLogger.REQUEST_IO_LOGGER.isDebugEnabled()) {
UndertowLogger.REQUEST_IO_LOGGER.debugf(new ClosedChannelException(), "Marking writes broken on channel %s", this);
}
handleBrokenSinkChannel(cause);
safeClose(channel.getSinkChannel());
synchronized (this) {
for (final S channel : pendingFrames) {
channel.markBroken();
}
pendingFrames.clear();
for (final S channel : newFrames) {
channel.markBroken();
}
newFrames.clear();
for (final S channel : heldFrames) {
channel.markBroken();
}
heldFrames.clear();
}
}
}
protected boolean isWritesBroken() {
return writesBrokenUpdater.get(this) != 0;
}
protected boolean isReadsBroken() {
return readsBrokenUpdater.get(this) != 0;
}
void resumeWrites() {
channel.getSinkChannel().resumeWrites();
}
void suspendWrites() {
channel.getSinkChannel().suspendWrites();
}
void wakeupWrites() {
channel.getSinkChannel().wakeupWrites();
}
StreamSourceChannel getSourceChannel() {
return channel.getSourceChannel();
}
void notifyFrameReadComplete(AbstractFramedStreamSourceChannel<C, R, S> channel) {
}
void notifyClosed(AbstractFramedStreamSourceChannel<C, R, S> channel) {
synchronized (AbstractFramedChannel.this) {
receivers.remove(channel);
}
}
/**
* {@link org.xnio.ChannelListener} which delegates the read notification to the appropriate listener
*/
private final class FrameReadListener implements ChannelListener<StreamSourceChannel> {
@SuppressWarnings({"unchecked", "rawtypes"})
@Override
public void handleEvent(final StreamSourceChannel channel) {
//clear the task queue before reading
while (!taskRunQueue.isEmpty()) {
taskRunQueue.poll().run();
}
final R receiver = AbstractFramedChannel.this.receiver;
if ((readChannelDone || receivesSuspended) && receiver == null) {
channel.suspendReads();
return;
} else {
ChannelListener listener = receiveSetter.get();
if(listener == null) {
listener = DRAIN_LISTENER;
}
UndertowLogger.REQUEST_IO_LOGGER.tracef("Invoking receive listener", receiver);
ChannelListeners.invokeChannelListener(AbstractFramedChannel.this, listener);
}
if (readData != null && !readData.isFreed() && channel.isOpen()) {
try {
runInIoThread(new Runnable() {
@Override
public void run() {
ChannelListeners.invokeChannelListener(channel, FrameReadListener.this);
}
});
} catch (RejectedExecutionException e) {
IoUtils.safeClose(AbstractFramedChannel.this);
}
}
}
}
private class FrameWriteListener implements ChannelListener<StreamSinkChannel> {
@Override
public void handleEvent(final StreamSinkChannel channel) {
flushSenders();
}
}
/**
* close listener, just goes through and activates any sub channels to make sure their listeners are invoked
*/
private class FrameCloseListener implements ChannelListener<CloseableChannel> {
private boolean sinkClosed;
private boolean sourceClosed;
@Override
public void handleEvent(final CloseableChannel c) {
if (Thread.currentThread() != c.getIoThread() && !c.getWorker().isShutdown()) {
runInIoThread(new Runnable() {
@Override
public void run() {
ChannelListeners.invokeChannelListener(c, FrameCloseListener.this);
}
});
return;
}
if(c instanceof StreamSinkChannel) {
sinkClosed = true;
} else if(c instanceof StreamSourceChannel) {
sourceClosed = true;
}
if(!sourceClosed || !sinkClosed) {
return; //both sides need to be closed
} else if(readData != null && !readData.isFreed()) {
//we make sure there is no data left to receive, if there is then we invoke the receive listener
runInIoThread(new Runnable() {
@Override
public void run() {
while (readData != null && !readData.isFreed()) {
int rem = readData.getBuffer().remaining();
ChannelListener listener = receiveSetter.get();
if(listener == null) {
listener = DRAIN_LISTENER;
}
ChannelListeners.invokeChannelListener(AbstractFramedChannel.this, listener);
if(!AbstractFramedChannel.this.isOpen()) {
break;
}
if (readData != null && rem == readData.getBuffer().remaining()) {
break;//make sure we are making progress
}
}
handleEvent(c);
}
});
return;
}
R receiver = AbstractFramedChannel.this.receiver;
try {
if (receiver != null && receiver.isOpen() && receiver.isReadResumed()) {
ChannelListeners.invokeChannelListener(receiver, ((SimpleSetter) receiver.getReadSetter()).get());
}
final List<S> pendingFrames;
final List<S> newFrames;
final List<S> heldFrames;
final List<AbstractFramedStreamSourceChannel<C, R, S>> receivers;
synchronized (AbstractFramedChannel.this) {
pendingFrames = new ArrayList<>(AbstractFramedChannel.this.pendingFrames);
newFrames = new ArrayList<>(AbstractFramedChannel.this.newFrames);
heldFrames = new ArrayList<>(AbstractFramedChannel.this.heldFrames);
receivers = new ArrayList<>(AbstractFramedChannel.this.receivers);
}
for (final S channel : pendingFrames) {
//if this was a clean shutdown there should not be any senders
channel.markBroken();
}
for (final S channel : newFrames) {
//if this was a clean shutdown there should not be any senders
channel.markBroken();
}
for (final S channel : heldFrames) {
//if this was a clean shutdown there should not be any senders
channel.markBroken();
}
for (AbstractFramedStreamSourceChannel<C, R, S> r : receivers) {
IoUtils.safeClose(r);
}
} finally {
try {
for (ChannelListener<C> task : closeTasks) {
ChannelListeners.invokeChannelListener((C) AbstractFramedChannel.this, task);
}
} finally {
synchronized (AbstractFramedChannel.this) {
closeSubChannels();
if (readData != null) {
readData.close();
readData = null;
}
}
ChannelListeners.invokeChannelListener((C) AbstractFramedChannel.this, closeSetter.get());
}
}
}
}
public void setIdleTimeout(long timeout) {
idleTimeoutConduit.setIdleTimeout(timeout);
}
public long getIdleTimeout() {
return idleTimeoutConduit.getIdleTimeout();
}
protected FramePriority<C, R, S> getFramePriority() {
return framePriority;
}
public void addCloseTask(final ChannelListener<C> task) {
closeTasks.add(task);
}
@Override
public String toString() {
return getClass().getSimpleName() + " peer " + channel.getPeerAddress() + " local " + channel.getLocalAddress() + "[ " + (receiver == null ? "No Receiver" : receiver.toString()) + " " + pendingFrames.toString() + " -- " + heldFrames.toString() + " -- " + newFrames.toString() + "]";
}
protected StreamConnection getUnderlyingConnection() {
return channel;
}
protected ChannelExceptionHandler<SuspendableWriteChannel> writeExceptionHandler() {
return new ChannelExceptionHandler<SuspendableWriteChannel>() {
@Override
public void handleException(SuspendableWriteChannel channel, IOException exception) {
markWritesBroken(exception);
}
};
}
public boolean isRequireExplicitFlush() {
return requireExplicitFlush;
}
public void setRequireExplicitFlush(boolean requireExplicitFlush) {
this.requireExplicitFlush = requireExplicitFlush;
}
protected OptionMap getSettings() {
return settings;
}
}