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/*
 * 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:
 *
 *   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.netty.channel;

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;
import io.netty.util.Recycler.Handle;
import io.netty.util.ReferenceCountUtil;
import io.netty.util.concurrent.FastThreadLocal;
import io.netty.util.internal.InternalThreadLocalMap;
import io.netty.util.internal.PlatformDependent;
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;

/**
 * (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 #size()} and {@link #isEmpty()}
  • *
  • {@link #isWritable()}
  • *
  • {@link #getUserDefinedWritability(int)} and {@link #setUserDefinedWritability(int, boolean)}
  • *
*

*/ public final class ChannelOutboundBuffer { // Assuming a 64-bit JVM: // - 16 bytes object header // - 8 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; tailEntry = entry; } else { Entry tail = tailEntry; tail.next = entry; tailEntry = entry; } if (unflushedEntry == null) { unflushedEntry = entry; } // 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; } /** * 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; if (p instanceof ChannelProgressivePromise) { long progress = e.progress + amount; e.progress = progress; ((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); if (!e.cancelled) { // only release message, notify and decrement if it was not canceled before. ReferenceCountUtil.safeRelease(msg); safeSuccess(promise); decrementPendingOutboundBytes(size, false, true); } // recycle the entry e.recycle(); 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.recycle(); 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() { 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 (Integer.MAX_VALUE - readableBytes < nioBufferSize) { // If the nioBufferSize + readableBytes will overflow an Integer we stop populate the // ByteBuffer array. This is done as 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. // This said writing more the Integer.MAX_VALUE is not a good idea anyway. // // See also: // - https://www.freebsd.org/cgi/man.cgi?query=write&sektion=2 // - http://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 = 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 { 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(); } nioBufferCount = fillBufferArray(nioBufs, nioBuffers, nioBufferCount); } } } entry = entry.next; } this.nioBufferCount = nioBufferCount; this.nioBufferSize = nioBufferSize; return nioBuffers; } private static int fillBufferArray(ByteBuffer[] nioBufs, ByteBuffer[] nioBuffers, int nioBufferCount) { for (ByteBuffer nioBuf: nioBufs) { if (nioBuf == null) { break; } 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 && newValue != 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.recycleAndGetNext(); } } 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() { long bytes = channel.config().getWriteBufferHighWaterMark() - totalPendingSize; // 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(). if (bytes > 0) { return isWritable() ? bytes : 0; } return 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() { long bytes = totalPendingSize - channel.config().getWriteBufferLowWaterMark(); // 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(). if (bytes > 0) { return isWritable() ? 0 : bytes; } return 0; } /** * 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 { if (processor == null) { throw new NullPointerException("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 Recycler RECYCLER = new Recycler() { @Override protected Entry newObject(Handle handle) { return new Entry(handle); } }; private final Handle 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 = 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 recycle() { next = null; bufs = null; buf = null; msg = null; promise = null; progress = 0; total = 0; pendingSize = 0; count = -1; cancelled = false; RECYCLER.recycle(this, handle); } Entry recycleAndGetNext() { Entry next = this.next; recycle(); return next; } } }




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