io.netty.channel.ChannelOutboundBuffer Maven / Gradle / Ivy
Go to download
Show more of this group Show more artifacts with this name
Show all versions of redisson-all Show documentation
Show all versions of redisson-all Show documentation
Easy Redis Java client and Real-Time Data Platform. Valkey compatible. Sync/Async/RxJava3/Reactive API. Client side caching. Over 50 Redis based Java objects and services: JCache API, Apache Tomcat, Hibernate, Spring, Set, Multimap, SortedSet, Map, List, Queue, Deque, Semaphore, Lock, AtomicLong, Map Reduce, Bloom filter, Scheduler, RPC
/*
* Copyright 2013 The Netty Project
*
* The Netty Project licenses this file to you 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:
*
* https://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.netty.channel;
import io.netty.buffer.AbstractReferenceCountedByteBuf;
import io.netty.buffer.ByteBuf;
import io.netty.buffer.ByteBufHolder;
import io.netty.buffer.Unpooled;
import io.netty.channel.socket.nio.NioSocketChannel;
import io.netty.util.Recycler.EnhancedHandle;
import io.netty.util.ReferenceCountUtil;
import io.netty.util.concurrent.FastThreadLocal;
import io.netty.util.internal.InternalThreadLocalMap;
import io.netty.util.internal.ObjectPool;
import io.netty.util.internal.ObjectPool.Handle;
import io.netty.util.internal.ObjectPool.ObjectCreator;
import io.netty.util.internal.ObjectUtil;
import io.netty.util.internal.PromiseNotificationUtil;
import io.netty.util.internal.SystemPropertyUtil;
import io.netty.util.internal.logging.InternalLogger;
import io.netty.util.internal.logging.InternalLoggerFactory;
import java.nio.ByteBuffer;
import java.nio.channels.ClosedChannelException;
import java.util.Arrays;
import java.util.concurrent.atomic.AtomicIntegerFieldUpdater;
import java.util.concurrent.atomic.AtomicLongFieldUpdater;
import static java.lang.Math.min;
/**
* (Transport implementors only) an internal data structure used by {@link AbstractChannel} to store its pending
* outbound write requests.
*
* All methods must be called by a transport implementation from an I/O thread, except the following ones:
*
* - {@link #isWritable()}
* - {@link #getUserDefinedWritability(int)} and {@link #setUserDefinedWritability(int, boolean)}
*
*
*/
public final class ChannelOutboundBuffer {
// Assuming a 64-bit JVM:
// - 16 bytes object header
// - 6 reference fields
// - 2 long fields
// - 2 int fields
// - 1 boolean field
// - padding
static final int CHANNEL_OUTBOUND_BUFFER_ENTRY_OVERHEAD =
SystemPropertyUtil.getInt("io.netty.transport.outboundBufferEntrySizeOverhead", 96);
private static final InternalLogger logger = InternalLoggerFactory.getInstance(ChannelOutboundBuffer.class);
private static final FastThreadLocal NIO_BUFFERS = new FastThreadLocal() {
@Override
protected ByteBuffer[] initialValue() throws Exception {
return new ByteBuffer[1024];
}
};
private final Channel channel;
// Entry(flushedEntry) --> ... Entry(unflushedEntry) --> ... Entry(tailEntry)
//
// The Entry that is the first in the linked-list structure that was flushed
private Entry flushedEntry;
// The Entry which is the first unflushed in the linked-list structure
private Entry unflushedEntry;
// The Entry which represents the tail of the buffer
private Entry tailEntry;
// The number of flushed entries that are not written yet
private int flushed;
private int nioBufferCount;
private long nioBufferSize;
private boolean inFail;
private static final AtomicLongFieldUpdater TOTAL_PENDING_SIZE_UPDATER =
AtomicLongFieldUpdater.newUpdater(ChannelOutboundBuffer.class, "totalPendingSize");
@SuppressWarnings("UnusedDeclaration")
private volatile long totalPendingSize;
private static final AtomicIntegerFieldUpdater UNWRITABLE_UPDATER =
AtomicIntegerFieldUpdater.newUpdater(ChannelOutboundBuffer.class, "unwritable");
@SuppressWarnings("UnusedDeclaration")
private volatile int unwritable;
private volatile Runnable fireChannelWritabilityChangedTask;
ChannelOutboundBuffer(AbstractChannel channel) {
this.channel = channel;
}
/**
* Add given message to this {@link ChannelOutboundBuffer}. The given {@link ChannelPromise} will be notified once
* the message was written.
*/
public void addMessage(Object msg, int size, ChannelPromise promise) {
Entry entry = Entry.newInstance(msg, size, total(msg), promise);
if (tailEntry == null) {
flushedEntry = null;
} else {
Entry tail = tailEntry;
tail.next = entry;
}
tailEntry = entry;
if (unflushedEntry == null) {
unflushedEntry = entry;
}
// Touch the message to make it easier to debug buffer leaks.
// this save both checking against the ReferenceCounted interface
// and makes better use of virtual calls vs interface ones
if (msg instanceof AbstractReferenceCountedByteBuf) {
((AbstractReferenceCountedByteBuf) msg).touch();
} else {
ReferenceCountUtil.touch(msg);
}
// increment pending bytes after adding message to the unflushed arrays.
// See https://github.com/netty/netty/issues/1619
incrementPendingOutboundBytes(entry.pendingSize, false);
}
/**
* Add a flush to this {@link ChannelOutboundBuffer}. This means all previous added messages are marked as flushed
* and so you will be able to handle them.
*/
public void addFlush() {
// There is no need to process all entries if there was already a flush before and no new messages
// where added in the meantime.
//
// See https://github.com/netty/netty/issues/2577
Entry entry = unflushedEntry;
if (entry != null) {
if (flushedEntry == null) {
// there is no flushedEntry yet, so start with the entry
flushedEntry = entry;
}
do {
flushed ++;
if (!entry.promise.setUncancellable()) {
// Was cancelled so make sure we free up memory and notify about the freed bytes
int pending = entry.cancel();
decrementPendingOutboundBytes(pending, false, true);
}
entry = entry.next;
} while (entry != null);
// All flushed so reset unflushedEntry
unflushedEntry = null;
}
}
/**
* Increment the pending bytes which will be written at some point.
* This method is thread-safe!
*/
void incrementPendingOutboundBytes(long size) {
incrementPendingOutboundBytes(size, true);
}
private void incrementPendingOutboundBytes(long size, boolean invokeLater) {
if (size == 0) {
return;
}
long newWriteBufferSize = TOTAL_PENDING_SIZE_UPDATER.addAndGet(this, size);
if (newWriteBufferSize > channel.config().getWriteBufferHighWaterMark()) {
setUnwritable(invokeLater);
}
}
/**
* Decrement the pending bytes which will be written at some point.
* This method is thread-safe!
*/
void decrementPendingOutboundBytes(long size) {
decrementPendingOutboundBytes(size, true, true);
}
private void decrementPendingOutboundBytes(long size, boolean invokeLater, boolean notifyWritability) {
if (size == 0) {
return;
}
long newWriteBufferSize = TOTAL_PENDING_SIZE_UPDATER.addAndGet(this, -size);
if (notifyWritability && newWriteBufferSize < channel.config().getWriteBufferLowWaterMark()) {
setWritable(invokeLater);
}
}
private static long total(Object msg) {
if (msg instanceof ByteBuf) {
return ((ByteBuf) msg).readableBytes();
}
if (msg instanceof FileRegion) {
return ((FileRegion) msg).count();
}
if (msg instanceof ByteBufHolder) {
return ((ByteBufHolder) msg).content().readableBytes();
}
return -1;
}
/**
* Return the current message to write or {@code null} if nothing was flushed before and so is ready to be written.
*/
public Object current() {
Entry entry = flushedEntry;
if (entry == null) {
return null;
}
return entry.msg;
}
/**
* Return the current message flush progress.
* @return {@code 0} if nothing was flushed before for the current message or there is no current message
*/
public long currentProgress() {
Entry entry = flushedEntry;
if (entry == null) {
return 0;
}
return entry.progress;
}
/**
* Notify the {@link ChannelPromise} of the current message about writing progress.
*/
public void progress(long amount) {
Entry e = flushedEntry;
assert e != null;
ChannelPromise p = e.promise;
long progress = e.progress + amount;
e.progress = progress;
assert p != null;
final Class> promiseClass = p.getClass();
// fast-path to save O(n) ChannelProgressivePromise's type check on OpenJDK
if (promiseClass == VoidChannelPromise.class || promiseClass == DefaultChannelPromise.class) {
return;
}
// this is going to save from type pollution due to https://bugs.openjdk.org/browse/JDK-8180450
if (p instanceof DefaultChannelProgressivePromise) {
((DefaultChannelProgressivePromise) p).tryProgress(progress, e.total);
} else if (p instanceof ChannelProgressivePromise) {
((ChannelProgressivePromise) p).tryProgress(progress, e.total);
}
}
/**
* Will remove the current message, mark its {@link ChannelPromise} as success and return {@code true}. If no
* flushed message exists at the time this method is called it will return {@code false} to signal that no more
* messages are ready to be handled.
*/
public boolean remove() {
Entry e = flushedEntry;
if (e == null) {
clearNioBuffers();
return false;
}
Object msg = e.msg;
ChannelPromise promise = e.promise;
int size = e.pendingSize;
removeEntry(e);
// only release message, notify and decrement if it was not canceled before.
if (!e.cancelled) {
// this save both checking against the ReferenceCounted interface
// and makes better use of virtual calls vs interface ones
if (msg instanceof AbstractReferenceCountedByteBuf) {
try {
// release now as it is flushed.
((AbstractReferenceCountedByteBuf) msg).release();
} catch (Throwable t) {
logger.warn("Failed to release a ByteBuf: {}", msg, t);
}
} else {
ReferenceCountUtil.safeRelease(msg);
}
safeSuccess(promise);
decrementPendingOutboundBytes(size, false, true);
}
// recycle the entry
e.unguardedRecycle();
return true;
}
/**
* Will remove the current message, mark its {@link ChannelPromise} as failure using the given {@link Throwable}
* and return {@code true}. If no flushed message exists at the time this method is called it will return
* {@code false} to signal that no more messages are ready to be handled.
*/
public boolean remove(Throwable cause) {
return remove0(cause, true);
}
private boolean remove0(Throwable cause, boolean notifyWritability) {
Entry e = flushedEntry;
if (e == null) {
clearNioBuffers();
return false;
}
Object msg = e.msg;
ChannelPromise promise = e.promise;
int size = e.pendingSize;
removeEntry(e);
if (!e.cancelled) {
// only release message, fail and decrement if it was not canceled before.
ReferenceCountUtil.safeRelease(msg);
safeFail(promise, cause);
decrementPendingOutboundBytes(size, false, notifyWritability);
}
// recycle the entry
e.unguardedRecycle();
return true;
}
private void removeEntry(Entry e) {
if (-- flushed == 0) {
// processed everything
flushedEntry = null;
if (e == tailEntry) {
tailEntry = null;
unflushedEntry = null;
}
} else {
flushedEntry = e.next;
}
}
/**
* Removes the fully written entries and update the reader index of the partially written entry.
* This operation assumes all messages in this buffer is {@link ByteBuf}.
*/
public void removeBytes(long writtenBytes) {
for (;;) {
Object msg = current();
if (!(msg instanceof ByteBuf)) {
assert writtenBytes == 0;
break;
}
final ByteBuf buf = (ByteBuf) msg;
final int readerIndex = buf.readerIndex();
final int readableBytes = buf.writerIndex() - readerIndex;
if (readableBytes <= writtenBytes) {
if (writtenBytes != 0) {
progress(readableBytes);
writtenBytes -= readableBytes;
}
remove();
} else { // readableBytes > writtenBytes
if (writtenBytes != 0) {
buf.readerIndex(readerIndex + (int) writtenBytes);
progress(writtenBytes);
}
break;
}
}
clearNioBuffers();
}
// Clear all ByteBuffer from the array so these can be GC'ed.
// See https://github.com/netty/netty/issues/3837
private void clearNioBuffers() {
int count = nioBufferCount;
if (count > 0) {
nioBufferCount = 0;
Arrays.fill(NIO_BUFFERS.get(), 0, count, null);
}
}
/**
* Returns an array of direct NIO buffers if the currently pending messages are made of {@link ByteBuf} only.
* {@link #nioBufferCount()} and {@link #nioBufferSize()} will return the number of NIO buffers in the returned
* array and the total number of readable bytes of the NIO buffers respectively.
*
* Note that the returned array is reused and thus should not escape
* {@link AbstractChannel#doWrite(ChannelOutboundBuffer)}.
* Refer to {@link NioSocketChannel#doWrite(ChannelOutboundBuffer)} for an example.
*
*/
public ByteBuffer[] nioBuffers() {
return nioBuffers(Integer.MAX_VALUE, Integer.MAX_VALUE);
}
/**
* Returns an array of direct NIO buffers if the currently pending messages are made of {@link ByteBuf} only.
* {@link #nioBufferCount()} and {@link #nioBufferSize()} will return the number of NIO buffers in the returned
* array and the total number of readable bytes of the NIO buffers respectively.
*
* Note that the returned array is reused and thus should not escape
* {@link AbstractChannel#doWrite(ChannelOutboundBuffer)}.
* Refer to {@link NioSocketChannel#doWrite(ChannelOutboundBuffer)} for an example.
*
* @param maxCount The maximum amount of buffers that will be added to the return value.
* @param maxBytes A hint toward the maximum number of bytes to include as part of the return value. Note that this
* value maybe exceeded because we make a best effort to include at least 1 {@link ByteBuffer}
* in the return value to ensure write progress is made.
*/
public ByteBuffer[] nioBuffers(int maxCount, long maxBytes) {
assert maxCount > 0;
assert maxBytes > 0;
long nioBufferSize = 0;
int nioBufferCount = 0;
final InternalThreadLocalMap threadLocalMap = InternalThreadLocalMap.get();
ByteBuffer[] nioBuffers = NIO_BUFFERS.get(threadLocalMap);
Entry entry = flushedEntry;
while (isFlushedEntry(entry) && entry.msg instanceof ByteBuf) {
if (!entry.cancelled) {
ByteBuf buf = (ByteBuf) entry.msg;
final int readerIndex = buf.readerIndex();
final int readableBytes = buf.writerIndex() - readerIndex;
if (readableBytes > 0) {
if (maxBytes - readableBytes < nioBufferSize && nioBufferCount != 0) {
// If the nioBufferSize + readableBytes will overflow maxBytes, and there is at least one entry
// we stop populate the ByteBuffer array. This is done for 2 reasons:
// 1. bsd/osx don't allow to write more bytes then Integer.MAX_VALUE with one writev(...) call
// and so will return 'EINVAL', which will raise an IOException. On Linux it may work depending
// on the architecture and kernel but to be safe we also enforce the limit here.
// 2. There is no sense in putting more data in the array than is likely to be accepted by the
// OS.
//
// See also:
// - https://www.freebsd.org/cgi/man.cgi?query=write&sektion=2
// - https://linux.die.net//man/2/writev
break;
}
nioBufferSize += readableBytes;
int count = entry.count;
if (count == -1) {
//noinspection ConstantValueVariableUse
entry.count = count = buf.nioBufferCount();
}
int neededSpace = min(maxCount, nioBufferCount + count);
if (neededSpace > nioBuffers.length) {
nioBuffers = expandNioBufferArray(nioBuffers, neededSpace, nioBufferCount);
NIO_BUFFERS.set(threadLocalMap, nioBuffers);
}
if (count == 1) {
ByteBuffer nioBuf = entry.buf;
if (nioBuf == null) {
// cache ByteBuffer as it may need to create a new ByteBuffer instance if its a
// derived buffer
entry.buf = nioBuf = buf.internalNioBuffer(readerIndex, readableBytes);
}
nioBuffers[nioBufferCount++] = nioBuf;
} else {
// The code exists in an extra method to ensure the method is not too big to inline as this
// branch is not very likely to get hit very frequently.
nioBufferCount = nioBuffers(entry, buf, nioBuffers, nioBufferCount, maxCount);
}
if (nioBufferCount >= maxCount) {
break;
}
}
}
entry = entry.next;
}
this.nioBufferCount = nioBufferCount;
this.nioBufferSize = nioBufferSize;
return nioBuffers;
}
private static int nioBuffers(Entry entry, ByteBuf buf, ByteBuffer[] nioBuffers, int nioBufferCount, int maxCount) {
ByteBuffer[] nioBufs = entry.bufs;
if (nioBufs == null) {
// cached ByteBuffers as they may be expensive to create in terms
// of Object allocation
entry.bufs = nioBufs = buf.nioBuffers();
}
for (int i = 0; i < nioBufs.length && nioBufferCount < maxCount; ++i) {
ByteBuffer nioBuf = nioBufs[i];
if (nioBuf == null) {
break;
} else if (!nioBuf.hasRemaining()) {
continue;
}
nioBuffers[nioBufferCount++] = nioBuf;
}
return nioBufferCount;
}
private static ByteBuffer[] expandNioBufferArray(ByteBuffer[] array, int neededSpace, int size) {
int newCapacity = array.length;
do {
// double capacity until it is big enough
// See https://github.com/netty/netty/issues/1890
newCapacity <<= 1;
if (newCapacity < 0) {
throw new IllegalStateException();
}
} while (neededSpace > newCapacity);
ByteBuffer[] newArray = new ByteBuffer[newCapacity];
System.arraycopy(array, 0, newArray, 0, size);
return newArray;
}
/**
* Returns the number of {@link ByteBuffer} that can be written out of the {@link ByteBuffer} array that was
* obtained via {@link #nioBuffers()}. This method MUST be called after {@link #nioBuffers()}
* was called.
*/
public int nioBufferCount() {
return nioBufferCount;
}
/**
* Returns the number of bytes that can be written out of the {@link ByteBuffer} array that was
* obtained via {@link #nioBuffers()}. This method MUST be called after {@link #nioBuffers()}
* was called.
*/
public long nioBufferSize() {
return nioBufferSize;
}
/**
* Returns {@code true} if and only if {@linkplain #totalPendingWriteBytes() the total number of pending bytes} did
* not exceed the write watermark of the {@link Channel} and
* no {@linkplain #setUserDefinedWritability(int, boolean) user-defined writability flag} has been set to
* {@code false}.
*/
public boolean isWritable() {
return unwritable == 0;
}
/**
* Returns {@code true} if and only if the user-defined writability flag at the specified index is set to
* {@code true}.
*/
public boolean getUserDefinedWritability(int index) {
return (unwritable & writabilityMask(index)) == 0;
}
/**
* Sets a user-defined writability flag at the specified index.
*/
public void setUserDefinedWritability(int index, boolean writable) {
if (writable) {
setUserDefinedWritability(index);
} else {
clearUserDefinedWritability(index);
}
}
private void setUserDefinedWritability(int index) {
final int mask = ~writabilityMask(index);
for (;;) {
final int oldValue = unwritable;
final int newValue = oldValue & mask;
if (UNWRITABLE_UPDATER.compareAndSet(this, oldValue, newValue)) {
if (oldValue != 0 && newValue == 0) {
fireChannelWritabilityChanged(true);
}
break;
}
}
}
private void clearUserDefinedWritability(int index) {
final int mask = writabilityMask(index);
for (;;) {
final int oldValue = unwritable;
final int newValue = oldValue | mask;
if (UNWRITABLE_UPDATER.compareAndSet(this, oldValue, newValue)) {
if (oldValue == 0 && newValue != 0) {
fireChannelWritabilityChanged(true);
}
break;
}
}
}
private static int writabilityMask(int index) {
if (index < 1 || index > 31) {
throw new IllegalArgumentException("index: " + index + " (expected: 1~31)");
}
return 1 << index;
}
private void setWritable(boolean invokeLater) {
for (;;) {
final int oldValue = unwritable;
final int newValue = oldValue & ~1;
if (UNWRITABLE_UPDATER.compareAndSet(this, oldValue, newValue)) {
if (oldValue != 0 && newValue == 0) {
fireChannelWritabilityChanged(invokeLater);
}
break;
}
}
}
private void setUnwritable(boolean invokeLater) {
for (;;) {
final int oldValue = unwritable;
final int newValue = oldValue | 1;
if (UNWRITABLE_UPDATER.compareAndSet(this, oldValue, newValue)) {
if (oldValue == 0) {
fireChannelWritabilityChanged(invokeLater);
}
break;
}
}
}
private void fireChannelWritabilityChanged(boolean invokeLater) {
final ChannelPipeline pipeline = channel.pipeline();
if (invokeLater) {
Runnable task = fireChannelWritabilityChangedTask;
if (task == null) {
fireChannelWritabilityChangedTask = task = new Runnable() {
@Override
public void run() {
pipeline.fireChannelWritabilityChanged();
}
};
}
channel.eventLoop().execute(task);
} else {
pipeline.fireChannelWritabilityChanged();
}
}
/**
* Returns the number of flushed messages in this {@link ChannelOutboundBuffer}.
*/
public int size() {
return flushed;
}
/**
* Returns {@code true} if there are flushed messages in this {@link ChannelOutboundBuffer} or {@code false}
* otherwise.
*/
public boolean isEmpty() {
return flushed == 0;
}
void failFlushed(Throwable cause, boolean notify) {
// Make sure that this method does not reenter. A listener added to the current promise can be notified by the
// current thread in the tryFailure() call of the loop below, and the listener can trigger another fail() call
// indirectly (usually by closing the channel.)
//
// See https://github.com/netty/netty/issues/1501
if (inFail) {
return;
}
try {
inFail = true;
for (;;) {
if (!remove0(cause, notify)) {
break;
}
}
} finally {
inFail = false;
}
}
void close(final Throwable cause, final boolean allowChannelOpen) {
if (inFail) {
channel.eventLoop().execute(new Runnable() {
@Override
public void run() {
close(cause, allowChannelOpen);
}
});
return;
}
inFail = true;
if (!allowChannelOpen && channel.isOpen()) {
throw new IllegalStateException("close() must be invoked after the channel is closed.");
}
if (!isEmpty()) {
throw new IllegalStateException("close() must be invoked after all flushed writes are handled.");
}
// Release all unflushed messages.
try {
Entry e = unflushedEntry;
while (e != null) {
// Just decrease; do not trigger any events via decrementPendingOutboundBytes()
int size = e.pendingSize;
TOTAL_PENDING_SIZE_UPDATER.addAndGet(this, -size);
if (!e.cancelled) {
ReferenceCountUtil.safeRelease(e.msg);
safeFail(e.promise, cause);
}
e = e.unguardedRecycleAndGetNext();
}
} finally {
inFail = false;
}
clearNioBuffers();
}
void close(ClosedChannelException cause) {
close(cause, false);
}
private static void safeSuccess(ChannelPromise promise) {
// Only log if the given promise is not of type VoidChannelPromise as trySuccess(...) is expected to return
// false.
PromiseNotificationUtil.trySuccess(promise, null, promise instanceof VoidChannelPromise ? null : logger);
}
private static void safeFail(ChannelPromise promise, Throwable cause) {
// Only log if the given promise is not of type VoidChannelPromise as tryFailure(...) is expected to return
// false.
PromiseNotificationUtil.tryFailure(promise, cause, promise instanceof VoidChannelPromise ? null : logger);
}
@Deprecated
public void recycle() {
// NOOP
}
public long totalPendingWriteBytes() {
return totalPendingSize;
}
/**
* Get how many bytes can be written until {@link #isWritable()} returns {@code false}.
* This quantity will always be non-negative. If {@link #isWritable()} is {@code false} then 0.
*/
public long bytesBeforeUnwritable() {
// +1 because writability doesn't change until the threshold is crossed (not equal to).
long bytes = channel.config().getWriteBufferHighWaterMark() - totalPendingSize + 1;
// If bytes is negative we know we are not writable, but if bytes is non-negative we have to check writability.
// Note that totalPendingSize and isWritable() use different volatile variables that are not synchronized
// together. totalPendingSize will be updated before isWritable().
return bytes > 0 && isWritable() ? bytes : 0;
}
/**
* Get how many bytes must be drained from the underlying buffer until {@link #isWritable()} returns {@code true}.
* This quantity will always be non-negative. If {@link #isWritable()} is {@code true} then 0.
*/
public long bytesBeforeWritable() {
// +1 because writability doesn't change until the threshold is crossed (not equal to).
long bytes = totalPendingSize - channel.config().getWriteBufferLowWaterMark() + 1;
// If bytes is negative we know we are writable, but if bytes is non-negative we have to check writability.
// Note that totalPendingSize and isWritable() use different volatile variables that are not synchronized
// together. totalPendingSize will be updated before isWritable().
return bytes <= 0 || isWritable() ? 0 : bytes;
}
/**
* Call {@link MessageProcessor#processMessage(Object)} for each flushed message
* in this {@link ChannelOutboundBuffer} until {@link MessageProcessor#processMessage(Object)}
* returns {@code false} or there are no more flushed messages to process.
*/
public void forEachFlushedMessage(MessageProcessor processor) throws Exception {
ObjectUtil.checkNotNull(processor, "processor");
Entry entry = flushedEntry;
if (entry == null) {
return;
}
do {
if (!entry.cancelled) {
if (!processor.processMessage(entry.msg)) {
return;
}
}
entry = entry.next;
} while (isFlushedEntry(entry));
}
private boolean isFlushedEntry(Entry e) {
return e != null && e != unflushedEntry;
}
public interface MessageProcessor {
/**
* Will be called for each flushed message until it either there are no more flushed messages or this
* method returns {@code false}.
*/
boolean processMessage(Object msg) throws Exception;
}
static final class Entry {
private static final ObjectPool RECYCLER = ObjectPool.newPool(new ObjectCreator() {
@Override
public Entry newObject(Handle handle) {
return new Entry(handle);
}
});
private final EnhancedHandle handle;
Entry next;
Object msg;
ByteBuffer[] bufs;
ByteBuffer buf;
ChannelPromise promise;
long progress;
long total;
int pendingSize;
int count = -1;
boolean cancelled;
private Entry(Handle handle) {
this.handle = (EnhancedHandle) handle;
}
static Entry newInstance(Object msg, int size, long total, ChannelPromise promise) {
Entry entry = RECYCLER.get();
entry.msg = msg;
entry.pendingSize = size + CHANNEL_OUTBOUND_BUFFER_ENTRY_OVERHEAD;
entry.total = total;
entry.promise = promise;
return entry;
}
int cancel() {
if (!cancelled) {
cancelled = true;
int pSize = pendingSize;
// release message and replace with an empty buffer
ReferenceCountUtil.safeRelease(msg);
msg = Unpooled.EMPTY_BUFFER;
pendingSize = 0;
total = 0;
progress = 0;
bufs = null;
buf = null;
return pSize;
}
return 0;
}
void unguardedRecycle() {
next = null;
bufs = null;
buf = null;
msg = null;
promise = null;
progress = 0;
total = 0;
pendingSize = 0;
count = -1;
cancelled = false;
handle.unguardedRecycle(this);
}
Entry unguardedRecycleAndGetNext() {
Entry next = this.next;
unguardedRecycle();
return next;
}
}
}
© 2015 - 2024 Weber Informatics LLC | Privacy Policy