Examples with Channel org.apache.flink.shaded.netty4.io.netty.channel.Channel used on opensource projects

Example 76 with Channel

use of org.apache.flink.shaded.netty4.io.netty.channel.Channel in project riposte by Nike-Inc.

the class StreamingAsyncHttpClient method streamDownstreamCall.

/**
 * TODO: Fully document me.
 * <br/>
 * NOTE: The returned CompletableFuture will only be completed successfully if the connection to the downstream
 * server was successful and the initialRequestChunk was successfully written out. This has implications for
 * initialRequestChunk regarding releasing its reference count (i.e. calling {@link
 * io.netty.util.ReferenceCountUtil#release(Object)} and passing in initialRequestChunk). If the returned
 * CompletableFuture is successful it means initialRequestChunk's reference count will already be reduced by one
 * relative to when this method was called because it will have been passed to a successful {@link
 * ChannelHandlerContext#writeAndFlush(Object)} method call.
 * <p/>
 * Long story short - assume initialRequestChunk is an object with a reference count of x:
 * <ul>
 *     <li>
 *         If the returned CompletableFuture is successful, then when it completes successfully
 *         initialRequestChunk's reference count will be x - 1
 *     </li>
 *     <li>
 *         If the returned CompletableFuture is *NOT* successful, then when it completes initialRequestChunk's
 *         reference count will still be x
 *     </li>
 * </ul>
 */
public CompletableFuture<StreamingChannel> streamDownstreamCall(String downstreamHost, int downstreamPort, HttpRequest initialRequestChunk, boolean isSecureHttpsCall, boolean relaxedHttpsValidation, StreamingCallback callback, long downstreamCallTimeoutMillis, boolean performSubSpanAroundDownstreamCalls, boolean addTracingHeadersToDownstreamCall, ChannelHandlerContext ctx) {
    CompletableFuture<StreamingChannel> streamingChannel = new CompletableFuture<>();
    // set host header. include port in value when it is a non-default port
    boolean isDefaultPort = (downstreamPort == 80 && !isSecureHttpsCall) || (downstreamPort == 443 && isSecureHttpsCall);
    String hostHeaderValue = (isDefaultPort) ? downstreamHost : downstreamHost + ":" + downstreamPort;
    initialRequestChunk.headers().set(HttpHeaders.Names.HOST, hostHeaderValue);
    long beforeConnectionStartTimeNanos = System.nanoTime();
    // Create a connection to the downstream server.
    ChannelPool pool = getPooledChannelFuture(downstreamHost, downstreamPort);
    Future<Channel> channelFuture = pool.acquire();
    // Add a listener that kicks off the downstream call once the connection is completed.
    channelFuture.addListener(future -> {
        Pair<Deque<Span>, Map<String, String>> originalThreadInfo = null;
        try {
            long connectionSetupTimeNanos = System.nanoTime() - beforeConnectionStartTimeNanos;
            HttpProcessingState httpProcessingState = ChannelAttributes.getHttpProcessingStateForChannel(ctx).get();
            if (httpProcessingState != null) {
                RequestInfo<?> requestInfo = httpProcessingState.getRequestInfo();
                if (requestInfo != null) {
                    requestInfo.addRequestAttribute(DOWNSTREAM_CALL_CONNECTION_SETUP_TIME_NANOS_REQUEST_ATTR_KEY, connectionSetupTimeNanos);
                }
            }
            // Setup tracing and MDC so our log messages have the correct distributed trace info, etc.
            originalThreadInfo = linkTracingAndMdcToCurrentThread(ctx);
            if (logger.isDebugEnabled()) {
                logger.debug("CONNECTION SETUP TIME NANOS: {}", connectionSetupTimeNanos);
            }
            if (!future.isSuccess()) {
                try {
                    // We did not connect to the downstream host successfully. Notify the callback.
                    streamingChannel.completeExceptionally(new WrapperException("Unable to connect to downstream host: " + downstreamHost, future.cause()));
                } finally {
                    Channel ch = channelFuture.getNow();
                    if (ch != null) {
                        // We likely will never reach here since the channel future was not successful, however if
                        // we *do* manage to get here somehow, then mark the channel broken and release it back
                        // to the pool.
                        markChannelAsBroken(ch);
                        pool.release(ch);
                    }
                }
                return;
            }
            // noinspection ConstantConditions
            if (performSubSpanAroundDownstreamCalls) {
                // Add the subspan.
                String spanName = getSubspanSpanName(initialRequestChunk.getMethod().name(), downstreamHost + ":" + downstreamPort + initialRequestChunk.getUri());
                if (Tracer.getInstance().getCurrentSpan() == null) {
                    // There is no parent span to start a subspan from, so we have to start a new span for this call
                    // rather than a subspan.
                    // TODO: Set this to CLIENT once we have that ability in the wingtips API for request root spans
                    Tracer.getInstance().startRequestWithRootSpan(spanName);
                } else {
                    // There was at least one span on the stack, so we can start a subspan for this call.
                    Tracer.getInstance().startSubSpan(spanName, Span.SpanPurpose.CLIENT);
                }
            }
            Deque<Span> distributedSpanStackToUse = Tracer.getInstance().getCurrentSpanStackCopy();
            Map<String, String> mdcContextToUse = MDC.getCopyOfContextMap();
            Span spanForDownstreamCall = (distributedSpanStackToUse == null) ? null : distributedSpanStackToUse.peek();
            // Add distributed trace headers to the downstream call if desired and we have a current span.
            if (addTracingHeadersToDownstreamCall && spanForDownstreamCall != null) {
                HttpRequestTracingUtils.propagateTracingHeaders((headerKey, headerValue) -> {
                    if (headerValue != null) {
                        initialRequestChunk.headers().set(headerKey, headerValue);
                    }
                }, spanForDownstreamCall);
            }
            Channel ch = channelFuture.getNow();
            if (logger.isDebugEnabled())
                logger.debug("Channel ID of the Channel pulled from the pool: {}", ch.toString());
            // We may not be in the right thread to modify the channel pipeline and write data. If we're in the
            // wrong thread we can get deadlock type situations. By running the relevant bits in the channel's
            // event loop we're guaranteed it will be run in the correct thread.
            ch.eventLoop().execute(runnableWithTracingAndMdc(() -> {
                BiConsumer<String, Throwable> prepChannelErrorHandler = (errorMessage, cause) -> {
                    try {
                        streamingChannel.completeExceptionally(new WrapperException(errorMessage, cause));
                    } finally {
                        // This channel may be permanently busted depending on the error, so mark it broken and let
                        // the pool close it and clean it up.
                        markChannelAsBroken(ch);
                        pool.release(ch);
                    }
                };
                try {
                    ObjectHolder<Boolean> callActiveHolder = new ObjectHolder<>();
                    callActiveHolder.heldObject = true;
                    ObjectHolder<Boolean> lastChunkSentDownstreamHolder = new ObjectHolder<>();
                    lastChunkSentDownstreamHolder.heldObject = false;
                    // noinspection ConstantConditions
                    prepChannelForDownstreamCall(pool, ch, callback, distributedSpanStackToUse, mdcContextToUse, isSecureHttpsCall, relaxedHttpsValidation, performSubSpanAroundDownstreamCalls, downstreamCallTimeoutMillis, callActiveHolder, lastChunkSentDownstreamHolder);
                    logInitialRequestChunk(initialRequestChunk, downstreamHost, downstreamPort);
                    // Send the HTTP request.
                    ChannelFuture writeFuture = ch.writeAndFlush(initialRequestChunk);
                    // After the initial chunk has been sent we'll open the floodgates
                    // for any further chunk streaming
                    writeFuture.addListener(completedWriteFuture -> {
                        if (completedWriteFuture.isSuccess())
                            streamingChannel.complete(new StreamingChannel(ch, pool, callActiveHolder, lastChunkSentDownstreamHolder, distributedSpanStackToUse, mdcContextToUse));
                        else {
                            prepChannelErrorHandler.accept("Writing the first HttpRequest chunk to the downstream service failed.", completedWriteFuture.cause());
                            // noinspection UnnecessaryReturnStatement
                            return;
                        }
                    });
                } catch (SSLException | NoSuchAlgorithmException | KeyStoreException ex) {
                    prepChannelErrorHandler.accept("Error setting up SSL context for downstream call", ex);
                    // noinspection UnnecessaryReturnStatement
                    return;
                } catch (Throwable t) {
                    // If we don't catch and handle this here it gets swallowed since we're in a Runnable
                    prepChannelErrorHandler.accept("An unexpected error occurred while prepping the channel pipeline for the downstream call", t);
                    // noinspection UnnecessaryReturnStatement
                    return;
                }
            }, ctx));
        } catch (Throwable ex) {
            try {
                String errorMsg = "Error occurred attempting to send first chunk (headers/etc) downstream";
                Exception errorToFire = new WrapperException(errorMsg, ex);
                logger.warn(errorMsg, errorToFire);
                streamingChannel.completeExceptionally(errorToFire);
            } finally {
                Channel ch = channelFuture.getNow();
                if (ch != null) {
                    // Depending on where the error was thrown the channel may or may not exist. If it does exist,
                    // then assume it's unusable, mark it as broken, and let the pool close it and remove it.
                    markChannelAsBroken(ch);
                    pool.release(ch);
                }
            }
        } finally {
            // Unhook the tracing and MDC stuff from this thread now that we're done.
            unlinkTracingAndMdcFromCurrentThread(originalThreadInfo);
        }
    });
    return streamingChannel;
}

Example 77 with Channel

use of org.apache.flink.shaded.netty4.io.netty.channel.Channel in project riposte by Nike-Inc.

the class StreamingAsyncHttpClient method prepChannelForDownstreamCall.

protected void prepChannelForDownstreamCall(ChannelPool pool, Channel ch, StreamingCallback callback, Deque<Span> distributedSpanStackToUse, Map<String, String> mdcContextToUse, boolean isSecureHttpsCall, boolean relaxedHttpsValidation, boolean performSubSpanAroundDownstreamCalls, long downstreamCallTimeoutMillis, ObjectHolder<Boolean> callActiveHolder, ObjectHolder<Boolean> lastChunkSentDownstreamHolder) throws SSLException, NoSuchAlgorithmException, KeyStoreException {
    ChannelHandler chunkSenderHandler = new SimpleChannelInboundHandler<HttpObject>() {

        @Override
        protected void channelRead0(ChannelHandlerContext downstreamCallCtx, HttpObject msg) throws Exception {
            try {
                // the call is fully processed should not trigger the behavior a second time.
                if (callActiveHolder.heldObject) {
                    if (msg instanceof LastHttpContent) {
                        lastChunkSentDownstreamHolder.heldObject = true;
                        if (performSubSpanAroundDownstreamCalls) {
                            // Complete the subspan.
                            runnableWithTracingAndMdc(() -> {
                                if (distributedSpanStackToUse == null || distributedSpanStackToUse.size() < 2)
                                    Tracer.getInstance().completeRequestSpan();
                                else
                                    Tracer.getInstance().completeSubSpan();
                            }, distributedSpanStackToUse, mdcContextToUse).run();
                        }
                    }
                    HttpObject msgToPass = msg;
                    if (msg instanceof HttpResponse) {
                        // We can't pass the original HttpResponse back to the callback due to intricacies of how
                        // Netty handles determining the last chunk. If we do, and the callback ends up writing
                        // the message out to the client (which happens during proxy routing for example), then
                        // msg's headers might get modified - potentially causing this channel pipeline to
                        // never send a LastHttpContent, which will in turn cause an indefinite hang.
                        HttpResponse origHttpResponse = (HttpResponse) msg;
                        HttpResponse httpResponse = (msg instanceof FullHttpResponse) ? new DefaultFullHttpResponse(origHttpResponse.getProtocolVersion(), origHttpResponse.getStatus(), ((FullHttpResponse) msg).content()) : new DefaultHttpResponse(origHttpResponse.getProtocolVersion(), origHttpResponse.getStatus());
                        httpResponse.headers().add(origHttpResponse.headers());
                        msgToPass = httpResponse;
                    }
                    callback.messageReceived(msgToPass);
                } else {
                    if (shouldLogBadMessagesAfterRequestFinishes) {
                        runnableWithTracingAndMdc(() -> logger.warn("Received HttpObject msg when call was not active: {}", String.valueOf(msg)), distributedSpanStackToUse, mdcContextToUse).run();
                    }
                }
            } finally {
                if (msg instanceof LastHttpContent) {
                    releaseChannelBackToPoolIfCallIsActive(ch, pool, callActiveHolder, "last content chunk sent", distributedSpanStackToUse, mdcContextToUse);
                }
            }
        }
    };
    Consumer<Throwable> doErrorHandlingConsumer = (cause) -> {
        Pair<Deque<Span>, Map<String, String>> originalThreadInfo = null;
        try {
            // Setup tracing and MDC so our log messages have the correct distributed trace info, etc.
            originalThreadInfo = linkTracingAndMdcToCurrentThread(distributedSpanStackToUse, mdcContextToUse);
            // call is fully processed should not trigger the behavior a second time.
            if (callActiveHolder.heldObject) {
                if (performSubSpanAroundDownstreamCalls) {
                    if (distributedSpanStackToUse == null || distributedSpanStackToUse.size() < 2)
                        Tracer.getInstance().completeRequestSpan();
                    else
                        Tracer.getInstance().completeSubSpan();
                }
                Tracer.getInstance().unregisterFromThread();
                if (cause instanceof Errors.NativeIoException) {
                    // NativeIoExceptions are often setup to not have stack traces which is bad for debugging.
                    // Wrap it in a NativeIoExceptionWrapper that maps to a 503 since this is likely a busted
                    // connection and a second attempt should work.
                    cause = new NativeIoExceptionWrapper("Caught a NativeIoException in the downstream streaming call pipeline. Wrapped it in a " + "NativeIoExceptionWrapper so that it maps to a 503 and provides a usable stack trace " + "in the logs.", (Errors.NativeIoException) cause);
                }
                callback.unrecoverableErrorOccurred(cause, true);
            } else {
                if (cause instanceof DownstreamIdleChannelTimeoutException) {
                    logger.debug("A channel used for downstream calls will be closed because it was idle too long. " + "This is normal behavior and does not indicate a downstream call failure: {}", cause.toString());
                } else {
                    logger.warn("Received exception in downstream call pipeline after the call was finished. " + "Not necessarily anything to worry about but in case it helps debugging the " + "exception was: {}", cause.toString());
                }
            }
        } finally {
            // Mark the channel as broken so it will be closed and removed from the pool when it is returned.
            markChannelAsBroken(ch);
            // Release it back to the pool if possible/necessary so the pool can do its usual cleanup.
            releaseChannelBackToPoolIfCallIsActive(ch, pool, callActiveHolder, "error received in downstream pipeline: " + cause.toString(), distributedSpanStackToUse, mdcContextToUse);
            // No matter what the cause is we want to make sure the channel is closed. Doing this raw ch.close()
            // here will catch the cases where this channel does not have an active call but still needs to be
            // closed (e.g. an idle channel timeout that happens in-between calls).
            ch.close();
            // Unhook the tracing and MDC stuff from this thread now that we're done.
            unlinkTracingAndMdcFromCurrentThread(originalThreadInfo);
        }
    };
    ChannelHandler errorHandler = new ChannelInboundHandlerAdapter() {

        @Override
        public void exceptionCaught(ChannelHandlerContext downstreamCallCtx, Throwable cause) throws Exception {
            doErrorHandlingConsumer.accept(cause);
        }

        @Override
        public void channelInactive(ChannelHandlerContext ctx) throws Exception {
            if (logger.isDebugEnabled()) {
                runnableWithTracingAndMdc(() -> logger.debug("Downstream channel closing. call_active={}, last_chunk_sent_downstream={}, channel_id={}", callActiveHolder.heldObject, lastChunkSentDownstreamHolder.heldObject, ctx.channel().toString()), distributedSpanStackToUse, mdcContextToUse).run();
            }
            // We only care if the channel was closed while the call was active.
            if (callActiveHolder.heldObject)
                doErrorHandlingConsumer.accept(new DownstreamChannelClosedUnexpectedlyException(ch));
            super.channelInactive(ctx);
        }
    };
    // Set up the HTTP client pipeline.
    ChannelPipeline p = ch.pipeline();
    List<String> registeredHandlerNames = p.names();
    // couldn't be removed at that time because it wasn't in the channel's eventLoop.
    if (registeredHandlerNames.contains(DOWNSTREAM_IDLE_CHANNEL_TIMEOUT_HANDLER_NAME)) {
        ChannelHandler idleHandler = p.get(DOWNSTREAM_IDLE_CHANNEL_TIMEOUT_HANDLER_NAME);
        if (idleHandler != null)
            p.remove(idleHandler);
    }
    if (debugChannelLifecycleLoggingEnabled && !registeredHandlerNames.contains(DEBUG_LOGGER_HANDLER_NAME)) {
        // Add the channel debug logger if desired.
        p.addFirst(DEBUG_LOGGER_HANDLER_NAME, new LoggingHandler(DOWNSTREAM_CLIENT_CHANNEL_DEBUG_LOGGER_NAME, LogLevel.DEBUG));
    }
    // Add/replace a downstream call timeout detector.
    addOrReplacePipelineHandler(new DownstreamIdleChannelTimeoutHandler(downstreamCallTimeoutMillis, () -> callActiveHolder.heldObject, true, "StreamingAsyncHttpClientChannel-call-timeout", distributedSpanStackToUse, mdcContextToUse), DOWNSTREAM_CALL_TIMEOUT_HANDLER_NAME, p, registeredHandlerNames);
    if (isSecureHttpsCall) {
        // SSL call. Make sure we add the SSL handler if necessary.
        if (!registeredHandlerNames.contains(SSL_HANDLER_NAME)) {
            if (clientSslCtx == null) {
                if (relaxedHttpsValidation) {
                    clientSslCtx = SslContextBuilder.forClient().trustManager(InsecureTrustManagerFactory.INSTANCE).build();
                } else {
                    TrustManagerFactory tmf = TrustManagerFactory.getInstance(TrustManagerFactory.getDefaultAlgorithm());
                    tmf.init((KeyStore) null);
                    clientSslCtx = SslContextBuilder.forClient().trustManager(tmf).build();
                }
            }
            p.addAfter(DOWNSTREAM_CALL_TIMEOUT_HANDLER_NAME, SSL_HANDLER_NAME, clientSslCtx.newHandler(ch.alloc()));
        }
    } else {
        // Not an SSL call. Remove the SSL handler if it's there.
        if (registeredHandlerNames.contains(SSL_HANDLER_NAME))
            p.remove(SSL_HANDLER_NAME);
    }
    // The HttpClientCodec handler deals with HTTP codec stuff so you don't have to. Set it up if it hasn't already
    // been setup, and inspect it to make sure it's in a "ready to handle a new request" state. Some rare
    // and currently unknown edgecases can cause us to hit this point with the HttpClientCodec in an unclean
    // state, and if we barrel forward without cleaning this up the call will fail.
    boolean pipelineContainsHttpClientCodec = registeredHandlerNames.contains(HTTP_CLIENT_CODEC_HANDLER_NAME);
    boolean existingHttpClientCodecIsInBadState = false;
    if (pipelineContainsHttpClientCodec) {
        HttpClientCodec currentCodec = (HttpClientCodec) p.get(HTTP_CLIENT_CODEC_HANDLER_NAME);
        int currentHttpClientCodecInboundState = determineHttpClientCodecInboundState(currentCodec);
        if (currentHttpClientCodecInboundState != 0) {
            runnableWithTracingAndMdc(() -> logger.warn("HttpClientCodec inbound state was not 0. It will be replaced with a fresh HttpClientCodec. " + "bad_httpclientcodec_inbound_state={}", currentHttpClientCodecInboundState), distributedSpanStackToUse, mdcContextToUse).run();
            existingHttpClientCodecIsInBadState = true;
        } else {
            int currentHttpClientCodecOutboundState = determineHttpClientCodecOutboundState(currentCodec);
            if (currentHttpClientCodecOutboundState != 0) {
                runnableWithTracingAndMdc(() -> logger.warn("HttpClientCodec outbound state was not 0. It will be replaced with a fresh HttpClientCodec. " + "bad_httpclientcodec_outbound_state={}", currentHttpClientCodecOutboundState), distributedSpanStackToUse, mdcContextToUse).run();
                existingHttpClientCodecIsInBadState = true;
            }
        }
    }
    // or replace it if it was in a bad state.
    if (!pipelineContainsHttpClientCodec || existingHttpClientCodecIsInBadState) {
        addOrReplacePipelineHandler(new HttpClientCodec(4096, 8192, 8192, true), HTTP_CLIENT_CODEC_HANDLER_NAME, p, registeredHandlerNames);
    }
    // Update the chunk sender handler and error handler to the newly created versions that know about the correct
    // callback, dtrace info, etc to use for this request.
    addOrReplacePipelineHandler(chunkSenderHandler, CHUNK_SENDER_HANDLER_NAME, p, registeredHandlerNames);
    addOrReplacePipelineHandler(errorHandler, ERROR_HANDLER_NAME, p, registeredHandlerNames);
}

Example 78 with Channel

use of org.apache.flink.shaded.netty4.io.netty.channel.Channel in project pravega by pravega.

the class ClientConnectionInboundHandler method sendAsync.

@Override
public void sendAsync(List<Append> appends, CompletedCallback callback) {
    recentMessage.set(true);
    Channel ch;
    try {
        ch = getChannel();
    } catch (ConnectionFailedException e) {
        callback.complete(new ConnectionFailedException("Connection to " + connectionName + " is not established."));
        return;
    }
    PromiseCombiner combiner = new PromiseCombiner();
    for (Append append : appends) {
        batchSizeTracker.recordAppend(append.getEventNumber(), append.getData().readableBytes());
        combiner.add(ch.write(append));
    }
    ch.flush();
    ChannelPromise promise = ch.newPromise();
    promise.addListener(new GenericFutureListener<Future<? super Void>>() {

        @Override
        public void operationComplete(Future<? super Void> future) throws Exception {
            Throwable cause = future.cause();
            callback.complete(cause == null ? null : new ConnectionFailedException(cause));
        }
    });
    combiner.finish(promise);
}

Example 79 with Channel

use of org.apache.flink.shaded.netty4.io.netty.channel.Channel in project pravega by pravega.

the class ClientConnectionInboundHandler method channelRegistered.

@Override
public void channelRegistered(ChannelHandlerContext ctx) throws Exception {
    super.channelRegistered(ctx);
    Channel c = ctx.channel();
    channel.set(c);
    // release all futures waiting for channel registration to complete.
    registeredFutureLatch.release(null);
    log.info("Connection established {} ", ctx);
    c.write(new WireCommands.Hello(WireCommands.WIRE_VERSION, WireCommands.OLDEST_COMPATIBLE_VERSION), c.voidPromise());
    ScheduledFuture<?> old = keepAliveFuture.getAndSet(c.eventLoop().scheduleWithFixedDelay(new KeepAliveTask(), 20, 10, TimeUnit.SECONDS));
    if (old != null) {
        old.cancel(false);
    }
}

Example 80 with Channel

use of org.apache.flink.shaded.netty4.io.netty.channel.Channel in project pravega by pravega.

the class ConnectionFactoryImpl method establishConnection.

@Override
public CompletableFuture<ClientConnection> establishConnection(PravegaNodeUri location, ReplyProcessor rp) {
    Preconditions.checkNotNull(location);
    Exceptions.checkNotClosed(closed.get(), this);
    final SslContext sslCtx;
    if (clientConfig.isEnableTls()) {
        try {
            SslContextBuilder sslCtxFactory = SslContextBuilder.forClient();
            if (Strings.isNullOrEmpty(clientConfig.getTrustStore())) {
                sslCtxFactory = sslCtxFactory.trustManager(FingerprintTrustManagerFactory.getInstance(FingerprintTrustManagerFactory.getDefaultAlgorithm()));
            } else {
                sslCtxFactory = SslContextBuilder.forClient().trustManager(new File(clientConfig.getTrustStore()));
            }
            sslCtx = sslCtxFactory.build();
        } catch (SSLException | NoSuchAlgorithmException e) {
            throw new RuntimeException(e);
        }
    } else {
        sslCtx = null;
    }
    AppendBatchSizeTracker batchSizeTracker = new AppendBatchSizeTrackerImpl();
    ClientConnectionInboundHandler handler = new ClientConnectionInboundHandler(location.getEndpoint(), rp, batchSizeTracker);
    Bootstrap b = new Bootstrap();
    b.group(group).channel(nio ? NioSocketChannel.class : EpollSocketChannel.class).option(ChannelOption.TCP_NODELAY, true).handler(new ChannelInitializer<SocketChannel>() {

        @Override
        public void initChannel(SocketChannel ch) throws Exception {
            ChannelPipeline p = ch.pipeline();
            if (sslCtx != null) {
                SslHandler sslHandler = sslCtx.newHandler(ch.alloc(), location.getEndpoint(), location.getPort());
                if (clientConfig.isValidateHostName()) {
                    SSLEngine sslEngine = sslHandler.engine();
                    SSLParameters sslParameters = sslEngine.getSSLParameters();
                    sslParameters.setEndpointIdentificationAlgorithm("HTTPS");
                    sslEngine.setSSLParameters(sslParameters);
                }
                p.addLast(sslHandler);
            }
            // p.addLast(new LoggingHandler(LogLevel.INFO));
            p.addLast(new ExceptionLoggingHandler(location.getEndpoint()), new CommandEncoder(batchSizeTracker), new LengthFieldBasedFrameDecoder(WireCommands.MAX_WIRECOMMAND_SIZE, 4, 4), new CommandDecoder(), handler);
        }
    });
    // Start the client.
    CompletableFuture<ClientConnection> connectionComplete = new CompletableFuture<>();
    try {
        b.connect(location.getEndpoint(), location.getPort()).addListener(new ChannelFutureListener() {

            @Override
            public void operationComplete(ChannelFuture future) {
                if (future.isSuccess()) {
                    // since ChannelFuture is complete future.channel() is not a blocking call.
                    Channel ch = future.channel();
                    log.debug("Connect operation completed for channel:{}, local address:{}, remote address:{}", ch.id(), ch.localAddress(), ch.remoteAddress());
                    // Once a channel is closed the channel group implementation removes it.
                    allChannels.add(ch);
                    connectionComplete.complete(handler);
                } else {
                    connectionComplete.completeExceptionally(new ConnectionFailedException(future.cause()));
                }
            }
        });
    } catch (Exception e) {
        connectionComplete.completeExceptionally(new ConnectionFailedException(e));
    }
    // check if channel is registered.
    CompletableFuture<Void> channelRegisteredFuture = new CompletableFuture<>();
    handler.completeWhenRegistered(channelRegisteredFuture);
    return connectionComplete.thenCombine(channelRegisteredFuture, (clientConnection, v) -> clientConnection);
}