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/*
 * Copyright 2016 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.kqueue;

import io.netty.buffer.ByteBuf;
import io.netty.buffer.ByteBufAllocator;
import io.netty.channel.Channel;
import io.netty.channel.ChannelConfig;
import io.netty.channel.ChannelFuture;
import io.netty.channel.ChannelFutureListener;
import io.netty.channel.ChannelMetadata;
import io.netty.channel.ChannelOutboundBuffer;
import io.netty.channel.ChannelPipeline;
import io.netty.channel.ChannelPromise;
import io.netty.channel.DefaultFileRegion;
import io.netty.channel.EventLoop;
import io.netty.channel.FileRegion;
import io.netty.channel.internal.ChannelUtils;
import io.netty.channel.socket.DuplexChannel;
import io.netty.channel.unix.IovArray;
import io.netty.channel.unix.SocketWritableByteChannel;
import io.netty.channel.unix.UnixChannelUtil;
import io.netty.util.internal.StringUtil;
import io.netty.util.internal.UnstableApi;
import io.netty.util.internal.logging.InternalLogger;
import io.netty.util.internal.logging.InternalLoggerFactory;

import java.io.IOException;
import java.net.SocketAddress;
import java.nio.ByteBuffer;
import java.nio.channels.WritableByteChannel;
import java.util.concurrent.Executor;

import static io.netty.channel.internal.ChannelUtils.MAX_BYTES_PER_GATHERING_WRITE_ATTEMPTED_LOW_THRESHOLD;
import static io.netty.channel.internal.ChannelUtils.WRITE_STATUS_SNDBUF_FULL;

@UnstableApi
public abstract class AbstractKQueueStreamChannel extends AbstractKQueueChannel implements DuplexChannel {
    private static final InternalLogger logger = InternalLoggerFactory.getInstance(AbstractKQueueStreamChannel.class);
    private static final ChannelMetadata METADATA = new ChannelMetadata(false, 16);
    private static final String EXPECTED_TYPES =
            " (expected: " + StringUtil.simpleClassName(ByteBuf.class) + ", " +
                    StringUtil.simpleClassName(DefaultFileRegion.class) + ')';
    private WritableByteChannel byteChannel;
    private final Runnable flushTask = new Runnable() {
        @Override
        public void run() {
            // Calling flush0 directly to ensure we not try to flush messages that were added via write(...) in the
            // meantime.
            ((AbstractKQueueUnsafe) unsafe()).flush0();
        }
    };

    AbstractKQueueStreamChannel(Channel parent, BsdSocket fd, boolean active) {
        super(parent, fd, active);
    }

    AbstractKQueueStreamChannel(Channel parent, BsdSocket fd, SocketAddress remote) {
        super(parent, fd, remote);
    }

    AbstractKQueueStreamChannel(BsdSocket fd) {
        this(null, fd, isSoErrorZero(fd));
    }

    @Override
    protected AbstractKQueueUnsafe newUnsafe() {
        return new KQueueStreamUnsafe();
    }

    @Override
    public ChannelMetadata metadata() {
        return METADATA;
    }

    /**
     * Write bytes form the given {@link ByteBuf} to the underlying {@link java.nio.channels.Channel}.
     * @param in the collection which contains objects to write.
     * @param buf the {@link ByteBuf} from which the bytes should be written
     * @return The value that should be decremented from the write quantum which starts at
     * {@link ChannelConfig#getWriteSpinCount()}. The typical use cases are as follows:
     * 
    *
  • 0 - if no write was attempted. This is appropriate if an empty {@link ByteBuf} (or other empty content) * is encountered
  • *
  • 1 - if a single call to write data was made to the OS
  • *
  • {@link ChannelUtils#WRITE_STATUS_SNDBUF_FULL} - if an attempt to write data was made to the OS, but no * data was accepted
  • *
*/ private int writeBytes(ChannelOutboundBuffer in, ByteBuf buf) throws Exception { int readableBytes = buf.readableBytes(); if (readableBytes == 0) { in.remove(); return 0; } if (buf.hasMemoryAddress() || buf.nioBufferCount() == 1) { return doWriteBytes(in, buf); } else { ByteBuffer[] nioBuffers = buf.nioBuffers(); return writeBytesMultiple(in, nioBuffers, nioBuffers.length, readableBytes, config().getMaxBytesPerGatheringWrite()); } } private void adjustMaxBytesPerGatheringWrite(long attempted, long written, long oldMaxBytesPerGatheringWrite) { // By default we track the SO_SNDBUF when ever it is explicitly set. However some OSes may dynamically change // SO_SNDBUF (and other characteristics that determine how much data can be written at once) so we should try // make a best effort to adjust as OS behavior changes. if (attempted == written) { if (attempted << 1 > oldMaxBytesPerGatheringWrite) { config().setMaxBytesPerGatheringWrite(attempted << 1); } } else if (attempted > MAX_BYTES_PER_GATHERING_WRITE_ATTEMPTED_LOW_THRESHOLD && written < attempted >>> 1) { config().setMaxBytesPerGatheringWrite(attempted >>> 1); } } /** * Write multiple bytes via {@link IovArray}. * @param in the collection which contains objects to write. * @param array The array which contains the content to write. * @return The value that should be decremented from the write quantum which starts at * {@link ChannelConfig#getWriteSpinCount()}. The typical use cases are as follows: *
    *
  • 0 - if no write was attempted. This is appropriate if an empty {@link ByteBuf} (or other empty content) * is encountered
  • *
  • 1 - if a single call to write data was made to the OS
  • *
  • {@link ChannelUtils#WRITE_STATUS_SNDBUF_FULL} - if an attempt to write data was made to the OS, but * no data was accepted
  • *
* @throws IOException If an I/O exception occurs during write. */ private int writeBytesMultiple(ChannelOutboundBuffer in, IovArray array) throws IOException { final long expectedWrittenBytes = array.size(); assert expectedWrittenBytes != 0; final int cnt = array.count(); assert cnt != 0; final long localWrittenBytes = socket.writevAddresses(array.memoryAddress(0), cnt); if (localWrittenBytes > 0) { adjustMaxBytesPerGatheringWrite(expectedWrittenBytes, localWrittenBytes, array.maxBytes()); in.removeBytes(localWrittenBytes); return 1; } return WRITE_STATUS_SNDBUF_FULL; } /** * Write multiple bytes via {@link ByteBuffer} array. * @param in the collection which contains objects to write. * @param nioBuffers The buffers to write. * @param nioBufferCnt The number of buffers to write. * @param expectedWrittenBytes The number of bytes we expect to write. * @param maxBytesPerGatheringWrite The maximum number of bytes we should attempt to write. * @return The value that should be decremented from the write quantum which starts at * {@link ChannelConfig#getWriteSpinCount()}. The typical use cases are as follows: *
    *
  • 0 - if no write was attempted. This is appropriate if an empty {@link ByteBuf} (or other empty content) * is encountered
  • *
  • 1 - if a single call to write data was made to the OS
  • *
  • {@link ChannelUtils#WRITE_STATUS_SNDBUF_FULL} - if an attempt to write data was made to the OS, but * no data was accepted
  • *
* @throws IOException If an I/O exception occurs during write. */ private int writeBytesMultiple( ChannelOutboundBuffer in, ByteBuffer[] nioBuffers, int nioBufferCnt, long expectedWrittenBytes, long maxBytesPerGatheringWrite) throws IOException { assert expectedWrittenBytes != 0; if (expectedWrittenBytes > maxBytesPerGatheringWrite) { expectedWrittenBytes = maxBytesPerGatheringWrite; } final long localWrittenBytes = socket.writev(nioBuffers, 0, nioBufferCnt, expectedWrittenBytes); if (localWrittenBytes > 0) { adjustMaxBytesPerGatheringWrite(expectedWrittenBytes, localWrittenBytes, maxBytesPerGatheringWrite); in.removeBytes(localWrittenBytes); return 1; } return WRITE_STATUS_SNDBUF_FULL; } /** * Write a {@link DefaultFileRegion} * @param in the collection which contains objects to write. * @param region the {@link DefaultFileRegion} from which the bytes should be written * @return The value that should be decremented from the write quantum which starts at * {@link ChannelConfig#getWriteSpinCount()}. The typical use cases are as follows: *
    *
  • 0 - if no write was attempted. This is appropriate if an empty {@link ByteBuf} (or other empty content) * is encountered
  • *
  • 1 - if a single call to write data was made to the OS
  • *
  • {@link ChannelUtils#WRITE_STATUS_SNDBUF_FULL} - if an attempt to write data was made to the OS, but * no data was accepted
  • *
*/ private int writeDefaultFileRegion(ChannelOutboundBuffer in, DefaultFileRegion region) throws Exception { final long regionCount = region.count(); final long offset = region.transferred(); if (offset >= regionCount) { in.remove(); return 0; } final long flushedAmount = socket.sendFile(region, region.position(), offset, regionCount - offset); if (flushedAmount > 0) { in.progress(flushedAmount); if (region.transferred() >= regionCount) { in.remove(); } return 1; } else if (flushedAmount == 0) { validateFileRegion(region, offset); } return WRITE_STATUS_SNDBUF_FULL; } /** * Write a {@link FileRegion} * @param in the collection which contains objects to write. * @param region the {@link FileRegion} from which the bytes should be written * @return The value that should be decremented from the write quantum which starts at * {@link ChannelConfig#getWriteSpinCount()}. The typical use cases are as follows: *
    *
  • 0 - if no write was attempted. This is appropriate if an empty {@link ByteBuf} (or other empty content) * is encountered
  • *
  • 1 - if a single call to write data was made to the OS
  • *
  • {@link ChannelUtils#WRITE_STATUS_SNDBUF_FULL} - if an attempt to write data was made to the OS, but no * data was accepted
  • *
*/ private int writeFileRegion(ChannelOutboundBuffer in, FileRegion region) throws Exception { if (region.transferred() >= region.count()) { in.remove(); return 0; } if (byteChannel == null) { byteChannel = new KQueueSocketWritableByteChannel(); } final long flushedAmount = region.transferTo(byteChannel, region.transferred()); if (flushedAmount > 0) { in.progress(flushedAmount); if (region.transferred() >= region.count()) { in.remove(); } return 1; } return WRITE_STATUS_SNDBUF_FULL; } @Override protected void doWrite(ChannelOutboundBuffer in) throws Exception { int writeSpinCount = config().getWriteSpinCount(); do { final int msgCount = in.size(); // Do gathering write if the outbound buffer entries start with more than one ByteBuf. if (msgCount > 1 && in.current() instanceof ByteBuf) { writeSpinCount -= doWriteMultiple(in); } else if (msgCount == 0) { // Wrote all messages. writeFilter(false); // Return here so we don't set the WRITE flag. return; } else { // msgCount == 1 writeSpinCount -= doWriteSingle(in); } // We do not break the loop here even if the outbound buffer was flushed completely, // because a user might have triggered another write and flush when we notify his or her // listeners. } while (writeSpinCount > 0); if (writeSpinCount == 0) { // It is possible that we have set the write filter, woken up by KQUEUE because the socket is writable, and // then use our write quantum. In this case we no longer want to set the write filter because the socket is // still writable (as far as we know). We will find out next time we attempt to write if the socket is // writable and set the write filter if necessary. writeFilter(false); // We used our writeSpin quantum, and should try to write again later. eventLoop().execute(flushTask); } else { // Underlying descriptor can not accept all data currently, so set the WRITE flag to be woken up // when it can accept more data. writeFilter(true); } } /** * Attempt to write a single object. * @param in the collection which contains objects to write. * @return The value that should be decremented from the write quantum which starts at * {@link ChannelConfig#getWriteSpinCount()}. The typical use cases are as follows: *
    *
  • 0 - if no write was attempted. This is appropriate if an empty {@link ByteBuf} (or other empty content) * is encountered
  • *
  • 1 - if a single call to write data was made to the OS
  • *
  • {@link ChannelUtils#WRITE_STATUS_SNDBUF_FULL} - if an attempt to write data was made to the OS, but no * data was accepted
  • *
* @throws Exception If an I/O error occurs. */ protected int doWriteSingle(ChannelOutboundBuffer in) throws Exception { // The outbound buffer contains only one message or it contains a file region. Object msg = in.current(); if (msg instanceof ByteBuf) { return writeBytes(in, (ByteBuf) msg); } else if (msg instanceof DefaultFileRegion) { return writeDefaultFileRegion(in, (DefaultFileRegion) msg); } else if (msg instanceof FileRegion) { return writeFileRegion(in, (FileRegion) msg); } else { // Should never reach here. throw new Error(); } } /** * Attempt to write multiple {@link ByteBuf} objects. * @param in the collection which contains objects to write. * @return The value that should be decremented from the write quantum which starts at * {@link ChannelConfig#getWriteSpinCount()}. The typical use cases are as follows: *
    *
  • 0 - if no write was attempted. This is appropriate if an empty {@link ByteBuf} (or other empty content) * is encountered
  • *
  • 1 - if a single call to write data was made to the OS
  • *
  • {@link ChannelUtils#WRITE_STATUS_SNDBUF_FULL} - if an attempt to write data was made to the OS, but no * data was accepted
  • *
* @throws Exception If an I/O error occurs. */ private int doWriteMultiple(ChannelOutboundBuffer in) throws Exception { final long maxBytesPerGatheringWrite = config().getMaxBytesPerGatheringWrite(); IovArray array = ((KQueueEventLoop) eventLoop()).cleanArray(); array.maxBytes(maxBytesPerGatheringWrite); in.forEachFlushedMessage(array); if (array.count() >= 1) { // TODO: Handle the case where cnt == 1 specially. return writeBytesMultiple(in, array); } // cnt == 0, which means the outbound buffer contained empty buffers only. in.removeBytes(0); return 0; } @Override protected Object filterOutboundMessage(Object msg) { if (msg instanceof ByteBuf) { ByteBuf buf = (ByteBuf) msg; return UnixChannelUtil.isBufferCopyNeededForWrite(buf)? newDirectBuffer(buf) : buf; } if (msg instanceof FileRegion) { return msg; } throw new UnsupportedOperationException( "unsupported message type: " + StringUtil.simpleClassName(msg) + EXPECTED_TYPES); } @UnstableApi @Override protected final void doShutdownOutput() throws Exception { socket.shutdown(false, true); } @Override public boolean isOutputShutdown() { return socket.isOutputShutdown(); } @Override public boolean isInputShutdown() { return socket.isInputShutdown(); } @Override public boolean isShutdown() { return socket.isShutdown(); } @Override public ChannelFuture shutdownOutput() { return shutdownOutput(newPromise()); } @Override public ChannelFuture shutdownOutput(final ChannelPromise promise) { EventLoop loop = eventLoop(); if (loop.inEventLoop()) { ((AbstractUnsafe) unsafe()).shutdownOutput(promise); } else { loop.execute(new Runnable() { @Override public void run() { ((AbstractUnsafe) unsafe()).shutdownOutput(promise); } }); } return promise; } @Override public ChannelFuture shutdownInput() { return shutdownInput(newPromise()); } @Override public ChannelFuture shutdownInput(final ChannelPromise promise) { EventLoop loop = eventLoop(); if (loop.inEventLoop()) { shutdownInput0(promise); } else { loop.execute(new Runnable() { @Override public void run() { shutdownInput0(promise); } }); } return promise; } private void shutdownInput0(ChannelPromise promise) { try { socket.shutdown(true, false); } catch (Throwable cause) { promise.setFailure(cause); return; } promise.setSuccess(); } @Override public ChannelFuture shutdown() { return shutdown(newPromise()); } @Override public ChannelFuture shutdown(final ChannelPromise promise) { ChannelFuture shutdownOutputFuture = shutdownOutput(); if (shutdownOutputFuture.isDone()) { shutdownOutputDone(shutdownOutputFuture, promise); } else { shutdownOutputFuture.addListener(new ChannelFutureListener() { @Override public void operationComplete(final ChannelFuture shutdownOutputFuture) throws Exception { shutdownOutputDone(shutdownOutputFuture, promise); } }); } return promise; } private void shutdownOutputDone(final ChannelFuture shutdownOutputFuture, final ChannelPromise promise) { ChannelFuture shutdownInputFuture = shutdownInput(); if (shutdownInputFuture.isDone()) { shutdownDone(shutdownOutputFuture, shutdownInputFuture, promise); } else { shutdownInputFuture.addListener(new ChannelFutureListener() { @Override public void operationComplete(ChannelFuture shutdownInputFuture) throws Exception { shutdownDone(shutdownOutputFuture, shutdownInputFuture, promise); } }); } } private static void shutdownDone(ChannelFuture shutdownOutputFuture, ChannelFuture shutdownInputFuture, ChannelPromise promise) { Throwable shutdownOutputCause = shutdownOutputFuture.cause(); Throwable shutdownInputCause = shutdownInputFuture.cause(); if (shutdownOutputCause != null) { if (shutdownInputCause != null) { logger.debug("Exception suppressed because a previous exception occurred.", shutdownInputCause); } promise.setFailure(shutdownOutputCause); } else if (shutdownInputCause != null) { promise.setFailure(shutdownInputCause); } else { promise.setSuccess(); } } class KQueueStreamUnsafe extends AbstractKQueueUnsafe { // Overridden here just to be able to access this method from AbstractKQueueStreamChannel @Override protected Executor prepareToClose() { return super.prepareToClose(); } @Override void readReady(final KQueueRecvByteAllocatorHandle allocHandle) { final ChannelConfig config = config(); if (shouldBreakReadReady(config)) { clearReadFilter0(); return; } final ChannelPipeline pipeline = pipeline(); final ByteBufAllocator allocator = config.getAllocator(); allocHandle.reset(config); readReadyBefore(); ByteBuf byteBuf = null; boolean close = false; try { do { // we use a direct buffer here as the native implementations only be able // to handle direct buffers. byteBuf = allocHandle.allocate(allocator); allocHandle.lastBytesRead(doReadBytes(byteBuf)); if (allocHandle.lastBytesRead() <= 0) { // nothing was read, release the buffer. byteBuf.release(); byteBuf = null; close = allocHandle.lastBytesRead() < 0; if (close) { // There is nothing left to read as we received an EOF. readPending = false; } break; } allocHandle.incMessagesRead(1); readPending = false; pipeline.fireChannelRead(byteBuf); byteBuf = null; if (shouldBreakReadReady(config)) { // We need to do this for two reasons: // // - If the input was shutdown in between (which may be the case when the user did it in the // fireChannelRead(...) method we should not try to read again to not produce any // miss-leading exceptions. // // - If the user closes the channel we need to ensure we not try to read from it again as // the filedescriptor may be re-used already by the OS if the system is handling a lot of // concurrent connections and so needs a lot of filedescriptors. If not do this we risk // reading data from a filedescriptor that belongs to another socket then the socket that // was "wrapped" by this Channel implementation. break; } } while (allocHandle.continueReading()); allocHandle.readComplete(); pipeline.fireChannelReadComplete(); if (close) { shutdownInput(false); } } catch (Throwable t) { handleReadException(pipeline, byteBuf, t, close, allocHandle); } finally { readReadyFinally(config); } } private void handleReadException(ChannelPipeline pipeline, ByteBuf byteBuf, Throwable cause, boolean close, KQueueRecvByteAllocatorHandle allocHandle) { if (byteBuf != null) { if (byteBuf.isReadable()) { readPending = false; pipeline.fireChannelRead(byteBuf); } else { byteBuf.release(); } } if (!failConnectPromise(cause)) { allocHandle.readComplete(); pipeline.fireChannelReadComplete(); pipeline.fireExceptionCaught(cause); if (close || cause instanceof IOException) { shutdownInput(false); } } } } private final class KQueueSocketWritableByteChannel extends SocketWritableByteChannel { KQueueSocketWritableByteChannel() { super(socket); } @Override protected ByteBufAllocator alloc() { return AbstractKQueueStreamChannel.this.alloc(); } } }




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