-
ServletOutputStreamImpl
-
servletRequestContext: ServletRequestContext
-
pooledBuffer: PooledByteBuffer
-
buffer: ByteBuffer
-
bufferSize: Integer
-
channel: StreamSinkChannel
-
written: long
-
state: int
-
asyncContext: AsyncContextImpl
-
listener: WriteListener
-
internalListener: WriteChannelListener
-
buffersToWrite: ByteBuffer[]
-
pendingFile: FileChannel
-
FLAG_CLOSED: int
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FLAG_WRITE_STARTED: int
-
FLAG_READY: int
-
FLAG_DELEGATE_SHUTDOWN: int
-
FLAG_IN_CALLBACK: int
-
MAX_BUFFERS_TO_ALLOCATE: int
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stateUpdater: AtomicIntegerFieldUpdater<ServletOutputStreamImpl>
-
ServletOutputStreamImpl(ServletRequestContext): void
-
ServletOutputStreamImpl(ServletRequestContext, int): void
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write(int): void
-
write(byte[]): void
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write(byte[], int, int): void
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writeTooLargeForBuffer(byte[], int, int, ByteBuffer): void
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writeAsync(byte[], int, int): void
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write(ByteBuffer[]): void
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write(ByteBuffer): void
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updateWritten(long): void
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updateWrittenAsync(long): void
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flushBufferAsync(boolean): boolean
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underlyingBuffer(): ByteBuffer
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flush(): void
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flushInternal(): void
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transferFrom(FileChannel): void
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writeBufferBlocking(boolean): void
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close(): void
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closeAsync(): void
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createChannel(): void
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buffer(): ByteBuffer
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resetBuffer(): void
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setBufferSize(int): void
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isClosed(): boolean
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isReady(): boolean
-
setWriteListener(WriteListener): void
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getServletRequestContext(): ServletRequestContext
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WriteChannelListener
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setFlags(int): void
-
clearFlags(int): void
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/*
* 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.servlet.spec;
import static org.xnio.Bits.allAreClear;
import static org.xnio.Bits.anyAreClear;
import static org.xnio.Bits.anyAreSet;
import java.io.IOException;
import java.nio.ByteBuffer;
import java.nio.channels.FileChannel;
import java.util.concurrent.atomic.AtomicIntegerFieldUpdater;
import javax.servlet.DispatcherType;
import javax.servlet.ServletOutputStream;
import javax.servlet.ServletRequest;
import javax.servlet.WriteListener;
import io.undertow.UndertowLogger;
import org.xnio.Buffers;
import org.xnio.ChannelListener;
import org.xnio.IoUtils;
import org.xnio.channels.Channels;
import org.xnio.channels.StreamSinkChannel;
import io.undertow.connector.ByteBufferPool;
import io.undertow.connector.PooledByteBuffer;
import io.undertow.io.BufferWritableOutputStream;
import io.undertow.servlet.UndertowServletMessages;
import io.undertow.servlet.handlers.ServletRequestContext;
import io.undertow.util.Headers;
This stream essentially has two modes. When it is being used in standard blocking mode then
it will buffer in the pooled buffer. If the stream is closed before the buffer is full it will
set a content-length header if one has not been explicitly set.
If a content-length header was present when the stream was created then it will automatically
close and flush itself once the appropriate amount of data has been written.
Once the listener has been set it goes into async mode, and writes become non blocking. Most methods
have two different code paths, based on if the listener has been set or not
Once the write listener has been set operations must only be invoked on this stream from the write
listener callback. Attempting to invoke from a different thread will result in an IllegalStateException.
Async listener tasks are queued in the AsyncContextImpl. At most one lister can be active at one time, which simplifies the thread safety requirements.
Author: Stuart Douglas
/**
* This stream essentially has two modes. When it is being used in standard blocking mode then
* it will buffer in the pooled buffer. If the stream is closed before the buffer is full it will
* set a content-length header if one has not been explicitly set.
* <p>
* If a content-length header was present when the stream was created then it will automatically
* close and flush itself once the appropriate amount of data has been written.
* <p>
* Once the listener has been set it goes into async mode, and writes become non blocking. Most methods
* have two different code paths, based on if the listener has been set or not
* <p>
* Once the write listener has been set operations must only be invoked on this stream from the write
* listener callback. Attempting to invoke from a different thread will result in an IllegalStateException.
* <p>
* Async listener tasks are queued in the {@link AsyncContextImpl}. At most one lister can be active at
* one time, which simplifies the thread safety requirements.
*
* @author Stuart Douglas
*/
public class ServletOutputStreamImpl extends ServletOutputStream implements BufferWritableOutputStream {
private final ServletRequestContext servletRequestContext;
private PooledByteBuffer pooledBuffer;
private ByteBuffer buffer;
private Integer bufferSize;
private StreamSinkChannel channel;
private long written;
private volatile int state;
private AsyncContextImpl asyncContext;
private WriteListener listener;
private WriteChannelListener internalListener;
buffers that are queued up to be written via async writes. This will include buffer as the first element, and maybe a user supplied buffer that did not fit /**
* buffers that are queued up to be written via async writes. This will include
* {@link #buffer} as the first element, and maybe a user supplied buffer that
* did not fit
*/
private ByteBuffer[] buffersToWrite;
private FileChannel pendingFile;
private static final int FLAG_CLOSED = 1;
private static final int FLAG_WRITE_STARTED = 1 << 1;
private static final int FLAG_READY = 1 << 2;
private static final int FLAG_DELEGATE_SHUTDOWN = 1 << 3;
private static final int FLAG_IN_CALLBACK = 1 << 4;
//TODO: should this be configurable?
private static final int MAX_BUFFERS_TO_ALLOCATE = 6;
private static final AtomicIntegerFieldUpdater<ServletOutputStreamImpl> stateUpdater = AtomicIntegerFieldUpdater.newUpdater(ServletOutputStreamImpl.class, "state");
Construct a new instance. No write timeout is configured.
/**
* Construct a new instance. No write timeout is configured.
*/
public ServletOutputStreamImpl(final ServletRequestContext servletRequestContext) {
this.servletRequestContext = servletRequestContext;
}
Construct a new instance. No write timeout is configured.
/**
* Construct a new instance. No write timeout is configured.
*/
public ServletOutputStreamImpl(final ServletRequestContext servletRequestContext, int bufferSize) {
this.bufferSize = bufferSize;
this.servletRequestContext = servletRequestContext;
}
{@inheritDoc}
/**
* {@inheritDoc}
*/
public void write(final int b) throws IOException {
write(new byte[]{(byte) b}, 0, 1);
}
{@inheritDoc}
/**
* {@inheritDoc}
*/
public void write(final byte[] b) throws IOException {
write(b, 0, b.length);
}
{@inheritDoc}
/**
* {@inheritDoc}
*/
public void write(final byte[] b, final int off, final int len) throws IOException {
if (anyAreSet(state, FLAG_CLOSED) || servletRequestContext.getOriginalResponse().isTreatAsCommitted()) {
throw UndertowServletMessages.MESSAGES.streamIsClosed();
}
if (len < 1) {
return;
}
if (listener == null) {
ByteBuffer buffer = buffer();
if (buffer.remaining() < len) {
writeTooLargeForBuffer(b, off, len, buffer);
} else {
buffer.put(b, off, len);
if (buffer.remaining() == 0) {
writeBufferBlocking(false);
}
}
updateWritten(len);
} else {
writeAsync(b, off, len);
}
}
private void writeTooLargeForBuffer(byte[] b, int off, int len, ByteBuffer buffer) throws IOException {
//so what we have will not fit.
//We allocate multiple buffers up to MAX_BUFFERS_TO_ALLOCATE
//and put it in them
//if it still dopes not fit we loop, re-using these buffers
StreamSinkChannel channel = this.channel;
if (channel == null) {
this.channel = channel = servletRequestContext.getExchange().getResponseChannel();
}
final ByteBufferPool bufferPool = servletRequestContext.getExchange().getConnection().getByteBufferPool();
ByteBuffer[] buffers = new ByteBuffer[MAX_BUFFERS_TO_ALLOCATE + 1];
PooledByteBuffer[] pooledBuffers = new PooledByteBuffer[MAX_BUFFERS_TO_ALLOCATE];
try {
buffers[0] = buffer;
int bytesWritten = 0;
int rem = buffer.remaining();
buffer.put(b, bytesWritten + off, rem);
buffer.flip();
bytesWritten += rem;
int bufferCount = 1;
for (int i = 0; i < MAX_BUFFERS_TO_ALLOCATE; ++i) {
PooledByteBuffer pooled = bufferPool.allocate();
pooledBuffers[bufferCount - 1] = pooled;
buffers[bufferCount++] = pooled.getBuffer();
ByteBuffer cb = pooled.getBuffer();
int toWrite = len - bytesWritten;
if (toWrite > cb.remaining()) {
rem = cb.remaining();
cb.put(b, bytesWritten + off, rem);
cb.flip();
bytesWritten += rem;
} else {
cb.put(b, bytesWritten + off, toWrite);
bytesWritten = len;
cb.flip();
break;
}
}
Channels.writeBlocking(channel, buffers, 0, bufferCount);
while (bytesWritten < len) {
//ok, it did not fit, loop and loop and loop until it is done
bufferCount = 0;
for (int i = 0; i < MAX_BUFFERS_TO_ALLOCATE + 1; ++i) {
ByteBuffer cb = buffers[i];
cb.clear();
bufferCount++;
int toWrite = len - bytesWritten;
if (toWrite > cb.remaining()) {
rem = cb.remaining();
cb.put(b, bytesWritten + off, rem);
cb.flip();
bytesWritten += rem;
} else {
cb.put(b, bytesWritten + off, toWrite);
bytesWritten = len;
cb.flip();
break;
}
}
Channels.writeBlocking(channel, buffers, 0, bufferCount);
}
buffer.clear();
} finally {
for (int i = 0; i < pooledBuffers.length; ++i) {
PooledByteBuffer p = pooledBuffers[i];
if (p == null) {
break;
}
p.close();
}
}
}
private void writeAsync(byte[] b, int off, int len) throws IOException {
if (anyAreClear(state, FLAG_READY)) {
throw UndertowServletMessages.MESSAGES.streamNotReady();
}
//even though we are in async mode we are still buffering
try {
ByteBuffer buffer = buffer();
if (buffer.remaining() > len) {
buffer.put(b, off, len);
} else {
buffer.flip();
final ByteBuffer userBuffer = ByteBuffer.wrap(b, off, len);
final ByteBuffer[] bufs = new ByteBuffer[]{buffer, userBuffer};
long toWrite = Buffers.remaining(bufs);
long res;
long written = 0;
createChannel();
setFlags(FLAG_WRITE_STARTED);
do {
res = channel.write(bufs);
written += res;
if (res == 0) {
//write it out with a listener
//but we need to copy any extra data
final ByteBuffer copy = ByteBuffer.allocate(userBuffer.remaining());
copy.put(userBuffer);
copy.flip();
this.buffersToWrite = new ByteBuffer[]{buffer, copy};
clearFlags(FLAG_READY);
return;
}
} while (written < toWrite);
buffer.clear();
}
} finally {
updateWrittenAsync(len);
}
}
@Override
public void write(ByteBuffer[] buffers) throws IOException {
if (anyAreSet(state, FLAG_CLOSED) || servletRequestContext.getOriginalResponse().isTreatAsCommitted()) {
throw UndertowServletMessages.MESSAGES.streamIsClosed();
}
int len = 0;
for (ByteBuffer buf : buffers) {
len += buf.remaining();
}
if (len < 1) {
return;
}
if (listener == null) {
//if we have received the exact amount of content write it out in one go
//this is a common case when writing directly from a buffer cache.
if (this.written == 0 && len == servletRequestContext.getOriginalResponse().getContentLength()) {
if (channel == null) {
channel = servletRequestContext.getExchange().getResponseChannel();
}
Channels.writeBlocking(channel, buffers, 0, buffers.length);
setFlags(FLAG_WRITE_STARTED);
} else {
ByteBuffer buffer = buffer();
if (len < buffer.remaining()) {
Buffers.copy(buffer, buffers, 0, buffers.length);
} else {
if (channel == null) {
channel = servletRequestContext.getExchange().getResponseChannel();
}
if (buffer.position() == 0) {
Channels.writeBlocking(channel, buffers, 0, buffers.length);
} else {
final ByteBuffer[] newBuffers = new ByteBuffer[buffers.length + 1];
buffer.flip();
newBuffers[0] = buffer;
System.arraycopy(buffers, 0, newBuffers, 1, buffers.length);
Channels.writeBlocking(channel, newBuffers, 0, newBuffers.length);
buffer.clear();
}
setFlags(FLAG_WRITE_STARTED);
}
}
updateWritten(len);
} else {
if (anyAreClear(state, FLAG_READY)) {
throw UndertowServletMessages.MESSAGES.streamNotReady();
}
//even though we are in async mode we are still buffering
try {
ByteBuffer buffer = buffer();
if (buffer.remaining() > len) {
Buffers.copy(buffer, buffers, 0, buffers.length);
} else {
final ByteBuffer[] bufs = new ByteBuffer[buffers.length + 1];
buffer.flip();
bufs[0] = buffer;
System.arraycopy(buffers, 0, bufs, 1, buffers.length);
long toWrite = Buffers.remaining(bufs);
long res;
long written = 0;
createChannel();
setFlags(FLAG_WRITE_STARTED);
do {
res = channel.write(bufs);
written += res;
if (res == 0) {
//write it out with a listener
//but we need to copy any extra data
//TODO: should really allocate from the pool here
final ByteBuffer copy = ByteBuffer.allocate((int) Buffers.remaining(buffers));
Buffers.copy(copy, buffers, 0, buffers.length);
copy.flip();
this.buffersToWrite = new ByteBuffer[]{buffer, copy};
clearFlags(FLAG_READY);
channel.resumeWrites();
return;
}
} while (written < toWrite);
buffer.clear();
}
} finally {
updateWrittenAsync(len);
}
}
}
@Override
public void write(ByteBuffer byteBuffer) throws IOException {
write(new ByteBuffer[]{byteBuffer});
}
void updateWritten(final long len) throws IOException {
this.written += len;
long contentLength = servletRequestContext.getOriginalResponse().getContentLength();
if (contentLength != -1 && this.written >= contentLength) {
close();
}
}
void updateWrittenAsync(final long len) throws IOException {
this.written += len;
long contentLength = servletRequestContext.getOriginalResponse().getContentLength();
if (contentLength != -1 && this.written >= contentLength) {
setFlags(FLAG_CLOSED);
//if buffersToWrite is set we are already flushing
//so we don't have to do anything
if (buffersToWrite == null && pendingFile == null) {
if (flushBufferAsync(true)) {
channel.shutdownWrites();
setFlags(FLAG_DELEGATE_SHUTDOWN);
channel.flush();
if (pooledBuffer != null) {
pooledBuffer.close();
buffer = null;
pooledBuffer = null;
}
}
}
}
}
private boolean flushBufferAsync(final boolean writeFinal) throws IOException {
ByteBuffer[] bufs = buffersToWrite;
if (bufs == null) {
ByteBuffer buffer = this.buffer;
if (buffer == null || buffer.position() == 0) {
return true;
}
buffer.flip();
bufs = new ByteBuffer[]{buffer};
}
long toWrite = Buffers.remaining(bufs);
if (toWrite == 0) {
//we clear the buffer, so it can be written to again
buffer.clear();
return true;
}
setFlags(FLAG_WRITE_STARTED);
createChannel();
long res;
long written = 0;
do {
if (writeFinal) {
res = channel.writeFinal(bufs);
} else {
res = channel.write(bufs);
}
written += res;
if (res == 0) {
//write it out with a listener
clearFlags(FLAG_READY);
buffersToWrite = bufs;
channel.resumeWrites();
return false;
}
} while (written < toWrite);
buffer.clear();
return true;
}
Returns the underlying buffer. If this has not been created yet then
it is created.
Callers that use this method must call updateWritten(long) to update the written amount.
This allows the buffer to be filled directly, which can be more efficient.
This method is basically a hack that should only be used by the print writer
Returns: The underlying buffer
/**
* Returns the underlying buffer. If this has not been created yet then
* it is created.
* <p>
* Callers that use this method must call {@link #updateWritten(long)} to update the written
* amount.
* <p>
* This allows the buffer to be filled directly, which can be more efficient.
* <p>
* This method is basically a hack that should only be used by the print writer
*
* @return The underlying buffer
*/
ByteBuffer underlyingBuffer() {
if (anyAreSet(state, FLAG_CLOSED)) {
return null;
}
return buffer();
}
{@inheritDoc}
/**
* {@inheritDoc}
*/
public void flush() throws IOException {
//according to the servlet spec we ignore a flush from within an include
if (servletRequestContext.getOriginalRequest().getDispatcherType() == DispatcherType.INCLUDE ||
servletRequestContext.getOriginalResponse().isTreatAsCommitted()) {
return;
}
if (servletRequestContext.getDeployment().getDeploymentInfo().isIgnoreFlush() &&
servletRequestContext.getExchange().isRequestComplete() &&
servletRequestContext.getOriginalResponse().getHeader(Headers.TRANSFER_ENCODING_STRING) == null) {
//we mark the stream as flushed, but don't actually flush
//because in most cases flush just kills performance
//we only do this if the request is fully read, so that http tunneling scenarios still work
servletRequestContext.getOriginalResponse().setIgnoredFlushPerformed(true);
return;
}
flushInternal();
}
{@inheritDoc}
/**
* {@inheritDoc}
*/
public void flushInternal() throws IOException {
if (listener == null) {
if (anyAreSet(state, FLAG_CLOSED)) {
//just return
return;
}
if (buffer != null && buffer.position() != 0) {
writeBufferBlocking(false);
}
if (channel == null) {
channel = servletRequestContext.getExchange().getResponseChannel();
}
Channels.flushBlocking(channel);
} else {
if (anyAreClear(state, FLAG_READY)) {
return;
}
createChannel();
if (buffer == null || buffer.position() == 0) {
//nothing to flush, we just flush the underlying stream
//it does not matter if this succeeds or not
channel.flush();
return;
}
//we have some data in the buffer, we can just write it out
//if the write fails we just compact, rather than changing the ready state
setFlags(FLAG_WRITE_STARTED);
buffer.flip();
long res;
do {
res = channel.write(buffer);
} while (buffer.hasRemaining() && res != 0);
if (!buffer.hasRemaining()) {
channel.flush();
}
buffer.compact();
}
}
@Override
public void transferFrom(FileChannel source) throws IOException {
if (anyAreSet(state, FLAG_CLOSED) || servletRequestContext.getOriginalResponse().isTreatAsCommitted()) {
throw UndertowServletMessages.MESSAGES.streamIsClosed();
}
if (listener == null) {
if (buffer != null && buffer.position() != 0) {
writeBufferBlocking(false);
}
if (channel == null) {
channel = servletRequestContext.getExchange().getResponseChannel();
}
long position = source.position();
long count = source.size() - position;
Channels.transferBlocking(channel, source, position, count);
updateWritten(count);
} else {
setFlags(FLAG_WRITE_STARTED);
createChannel();
long pos = 0;
try {
long size = source.size();
pos = source.position();
while (size - pos > 0) {
long ret = channel.transferFrom(pendingFile, pos, size - pos);
if (ret <= 0) {
clearFlags(FLAG_READY);
pendingFile = source;
source.position(pos);
channel.resumeWrites();
return;
}
pos += ret;
}
} finally {
updateWrittenAsync(pos - source.position());
}
}
}
private void writeBufferBlocking(final boolean writeFinal) throws IOException {
if (channel == null) {
channel = servletRequestContext.getExchange().getResponseChannel();
}
buffer.flip();
while (buffer.hasRemaining()) {
if (writeFinal) {
channel.writeFinal(buffer);
} else {
channel.write(buffer);
}
if (buffer.hasRemaining()) {
channel.awaitWritable();
}
}
buffer.clear();
setFlags(FLAG_WRITE_STARTED);
}
{@inheritDoc}
/**
* {@inheritDoc}
*/
public void close() throws IOException {
if (servletRequestContext.getOriginalRequest().getDispatcherType() == DispatcherType.INCLUDE ||
servletRequestContext.getOriginalResponse().isTreatAsCommitted()) {
return;
}
if (listener == null) {
if (anyAreSet(state, FLAG_CLOSED)) return;
setFlags(FLAG_CLOSED);
clearFlags(FLAG_READY);
if (allAreClear(state, FLAG_WRITE_STARTED) && channel == null && servletRequestContext.getOriginalResponse().getHeader(Headers.CONTENT_LENGTH_STRING) == null) {
if (servletRequestContext.getOriginalResponse().getHeader(Headers.TRANSFER_ENCODING_STRING) == null) {
if (buffer == null) {
servletRequestContext.getExchange().getResponseHeaders().put(Headers.CONTENT_LENGTH, "0");
} else {
servletRequestContext.getExchange().getResponseHeaders().put(Headers.CONTENT_LENGTH, Integer.toString(buffer.position()));
}
}
}
try {
if (buffer != null) {
writeBufferBlocking(true);
}
if (channel == null) {
channel = servletRequestContext.getExchange().getResponseChannel();
}
setFlags(FLAG_DELEGATE_SHUTDOWN);
StreamSinkChannel channel = this.channel;
if (channel != null) { //mock requests
channel.shutdownWrites();
Channels.flushBlocking(channel);
}
} catch (IOException | RuntimeException | Error e) {
IoUtils.safeClose(this.channel);
throw e;
} finally {
if (pooledBuffer != null) {
pooledBuffer.close();
buffer = null;
} else {
buffer = null;
}
}
} else {
closeAsync();
}
}
Closes the channel, and flushes any data out using async IO
This is used in two situations, if an output stream is not closed when a
request is done, and when performing a close on a stream that is in async
mode
Throws: - IOException –
/**
* Closes the channel, and flushes any data out using async IO
* <p>
* This is used in two situations, if an output stream is not closed when a
* request is done, and when performing a close on a stream that is in async
* mode
*
* @throws IOException
*/
public void closeAsync() throws IOException {
if (anyAreSet(state, FLAG_CLOSED) || servletRequestContext.getOriginalResponse().isTreatAsCommitted()) {
return;
}
if (!servletRequestContext.getExchange().isInIoThread()) {
servletRequestContext.getExchange().getIoThread().execute(new Runnable() {
@Override
public void run() {
try {
closeAsync();
} catch (IOException e) {
UndertowLogger.REQUEST_IO_LOGGER.closeAsyncFailed(e);
}
}
});
return;
}
try {
setFlags(FLAG_CLOSED);
clearFlags(FLAG_READY);
if (allAreClear(state, FLAG_WRITE_STARTED) && channel == null) {
if (servletRequestContext.getOriginalResponse().getHeader(Headers.TRANSFER_ENCODING_STRING) == null) {
if (buffer == null) {
servletRequestContext.getOriginalResponse().setHeader(Headers.CONTENT_LENGTH, "0");
} else {
servletRequestContext.getOriginalResponse().setHeader(Headers.CONTENT_LENGTH, Integer.toString(buffer.position()));
}
}
}
createChannel();
if (buffer != null) {
if (!flushBufferAsync(true)) {
return;
}
if (pooledBuffer != null) {
pooledBuffer.close();
buffer = null;
} else {
buffer = null;
}
}
channel.shutdownWrites();
setFlags(FLAG_DELEGATE_SHUTDOWN);
if (!channel.flush()) {
channel.resumeWrites();
}
} catch (IOException | RuntimeException | Error e) {
if (pooledBuffer != null) {
pooledBuffer.close();
pooledBuffer = null;
buffer = null;
}
throw e;
}
}
private void createChannel() {
if (channel == null) {
channel = servletRequestContext.getExchange().getResponseChannel();
if (internalListener != null) {
channel.getWriteSetter().set(internalListener);
}
}
}
private ByteBuffer buffer() {
ByteBuffer buffer = this.buffer;
if (buffer != null) {
return buffer;
}
if (bufferSize != null) {
this.buffer = ByteBuffer.allocateDirect(bufferSize);
return this.buffer;
} else {
this.pooledBuffer = servletRequestContext.getExchange().getConnection().getByteBufferPool().allocate();
this.buffer = pooledBuffer.getBuffer();
return this.buffer;
}
}
public void resetBuffer() {
if (allAreClear(state, FLAG_WRITE_STARTED)) {
if (pooledBuffer != null) {
pooledBuffer.close();
pooledBuffer = null;
}
buffer = null;
this.written = 0;
} else {
throw UndertowServletMessages.MESSAGES.responseAlreadyCommited();
}
}
public void setBufferSize(final int size) {
if (buffer != null || servletRequestContext.getOriginalResponse().isTreatAsCommitted()) {
throw UndertowServletMessages.MESSAGES.contentHasBeenWritten();
}
this.bufferSize = size;
}
public boolean isClosed() {
return anyAreSet(state, FLAG_CLOSED);
}
@Override
public boolean isReady() {
if (listener == null) {
//TODO: is this the correct behaviour?
throw UndertowServletMessages.MESSAGES.streamNotInAsyncMode();
}
if (!anyAreSet(state, FLAG_READY)) {
if (channel != null) {
channel.resumeWrites();
}
return false;
}
return true;
}
@Override
public void setWriteListener(final WriteListener writeListener) {
if (writeListener == null) {
throw UndertowServletMessages.MESSAGES.listenerCannotBeNull();
}
if (listener != null) {
throw UndertowServletMessages.MESSAGES.listenerAlreadySet();
}
final ServletRequest servletRequest = servletRequestContext.getOriginalRequest();
if (!servletRequest.isAsyncStarted()) {
throw UndertowServletMessages.MESSAGES.asyncNotStarted();
}
asyncContext = (AsyncContextImpl) servletRequest.getAsyncContext();
listener = writeListener;
//we register the write listener on the underlying connection
//so we don't have to force the creation of the response channel
//under normal circumstances this will break write listener delegation
this.internalListener = new WriteChannelListener();
if (this.channel != null) {
this.channel.getWriteSetter().set(internalListener);
}
//we resume from an async task, after the request has been dispatched
asyncContext.addAsyncTask(new Runnable() {
@Override
public void run() {
if (channel == null) {
servletRequestContext.getExchange().getIoThread().execute(new Runnable() {
@Override
public void run() {
internalListener.handleEvent(null);
}
});
} else {
channel.resumeWrites();
}
}
});
}
ServletRequestContext getServletRequestContext() {
return servletRequestContext;
}
private class WriteChannelListener implements ChannelListener<StreamSinkChannel> {
@Override
public void handleEvent(final StreamSinkChannel aChannel) {
//flush the channel if it is closed
if (anyAreSet(state, FLAG_DELEGATE_SHUTDOWN)) {
try {
//either it will work, and the channel is closed
//or it won't, and we continue with writes resumed
channel.flush();
return;
} catch (Throwable t) {
handleError(t);
return;
}
}
//if there is data still to write
if (buffersToWrite != null) {
long toWrite = Buffers.remaining(buffersToWrite);
long written = 0;
long res;
if (toWrite > 0) { //should always be true, but just to be defensive
do {
try {
res = channel.write(buffersToWrite);
written += res;
if (res == 0) {
return;
}
} catch (Throwable t) {
handleError(t);
return;
}
} while (written < toWrite);
}
buffersToWrite = null;
buffer.clear();
}
if (pendingFile != null) {
try {
long size = pendingFile.size();
long pos = pendingFile.position();
while (size - pos > 0) {
long ret = channel.transferFrom(pendingFile, pos, size - pos);
if (ret <= 0) {
pendingFile.position(pos);
return;
}
pos += ret;
}
pendingFile = null;
} catch (Throwable t) {
handleError(t);
return;
}
}
if (anyAreSet(state, FLAG_CLOSED)) {
try {
if (pooledBuffer != null) {
pooledBuffer.close();
buffer = null;
} else {
buffer = null;
}
channel.shutdownWrites();
setFlags(FLAG_DELEGATE_SHUTDOWN);
channel.flush();
} catch (Throwable t) {
handleError(t);
return;
}
} else {
if (asyncContext.isDispatched()) {
//this is no longer an async request
//we just return for now
//TODO: what do we do here? Revert back to blocking mode?
channel.suspendWrites();
return;
}
setFlags(FLAG_READY);
try {
setFlags(FLAG_IN_CALLBACK);
//if the stream is still ready then we do not resume writes
//this is per spec, we only call the listener once for each time
//isReady returns true
if (channel != null) {
channel.suspendWrites();
}
servletRequestContext.getCurrentServletContext().invokeOnWritePossible(servletRequestContext.getExchange(), listener);
} catch (Throwable e) {
IoUtils.safeClose(channel);
} finally {
clearFlags(FLAG_IN_CALLBACK);
}
}
}
private void handleError(final Throwable t) {
try {
servletRequestContext.getCurrentServletContext().invokeRunnable(servletRequestContext.getExchange(), new Runnable() {
@Override
public void run() {
listener.onError(t);
}
});
} finally {
IoUtils.safeClose(channel, servletRequestContext.getExchange().getConnection());
if (pooledBuffer != null) {
pooledBuffer.close();
pooledBuffer = null;
buffer = null;
}
}
}
}
private void setFlags(int flags) {
int old;
do {
old = state;
} while (!stateUpdater.compareAndSet(this, old, old | flags));
}
private void clearFlags(int flags) {
int old;
do {
old = state;
} while (!stateUpdater.compareAndSet(this, old, old & ~flags));
}
}