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/**
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF 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 org.apache.hadoop.ipc;
import io.prestosql.hadoop.$internal.com.google.common.annotations.VisibleForTesting;
import io.prestosql.hadoop.$internal.com.google.common.base.Preconditions;
import io.prestosql.hadoop.$internal.com.google.common.util.concurrent.ThreadFactoryBuilder;
import org.apache.hadoop.classification.InterfaceAudience;
import org.apache.hadoop.classification.InterfaceAudience.Public;
import org.apache.hadoop.classification.InterfaceStability;
import org.apache.hadoop.classification.InterfaceStability.Unstable;
import org.apache.hadoop.conf.Configuration;
import org.apache.hadoop.fs.CommonConfigurationKeys;
import org.apache.hadoop.fs.CommonConfigurationKeysPublic;
import org.apache.hadoop.io.IOUtils;
import org.apache.hadoop.io.Writable;
import org.apache.hadoop.io.WritableUtils;
import org.apache.hadoop.io.retry.RetryPolicies;
import org.apache.hadoop.io.retry.RetryPolicy;
import org.apache.hadoop.io.retry.RetryPolicy.RetryAction;
import org.apache.hadoop.ipc.RPC.RpcKind;
import org.apache.hadoop.ipc.Server.AuthProtocol;
import org.apache.hadoop.ipc.protobuf.IpcConnectionContextProtos.IpcConnectionContextProto;
import org.apache.hadoop.ipc.protobuf.RpcHeaderProtos.RpcRequestHeaderProto;
import org.apache.hadoop.ipc.protobuf.RpcHeaderProtos.RpcRequestHeaderProto.OperationProto;
import org.apache.hadoop.ipc.protobuf.RpcHeaderProtos.RpcResponseHeaderProto;
import org.apache.hadoop.ipc.protobuf.RpcHeaderProtos.RpcResponseHeaderProto.RpcErrorCodeProto;
import org.apache.hadoop.ipc.protobuf.RpcHeaderProtos.RpcResponseHeaderProto.RpcStatusProto;
import org.apache.hadoop.net.ConnectTimeoutException;
import org.apache.hadoop.net.NetUtils;
import org.apache.hadoop.security.KerberosInfo;
import org.apache.hadoop.security.SaslRpcClient;
import org.apache.hadoop.security.SaslRpcServer.AuthMethod;
import org.apache.hadoop.security.SecurityUtil;
import org.apache.hadoop.security.UserGroupInformation;
import org.apache.hadoop.util.ProtoUtil;
import org.apache.hadoop.util.StringUtils;
import org.apache.hadoop.util.Time;
import org.apache.hadoop.util.concurrent.AsyncGet;
import io.prestosql.hadoop.$internal.htrace.core.Span;
import io.prestosql.hadoop.$internal.htrace.core.Tracer;
import io.prestosql.hadoop.$internal.org.slf4j.Logger;
import io.prestosql.hadoop.$internal.org.slf4j.LoggerFactory;
import javax.net.SocketFactory;
import javax.security.sasl.Sasl;
import java.io.*;
import java.net.*;
import java.nio.ByteBuffer;
import java.security.PrivilegedExceptionAction;
import java.util.*;
import java.util.Map.Entry;
import java.util.concurrent.*;
import java.util.concurrent.atomic.AtomicBoolean;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicLong;
import java.util.concurrent.atomic.AtomicReference;
import static org.apache.hadoop.ipc.RpcConstants.CONNECTION_CONTEXT_CALL_ID;
import static org.apache.hadoop.ipc.RpcConstants.PING_CALL_ID;
/** A client for an IPC service. IPC calls take a single {@link Writable} as a
* parameter, and return a {@link Writable} as their value. A service runs on
* a port and is defined by a parameter class and a value class.
*
* @see Server
*/
@Public
@InterfaceStability.Evolving
public class Client implements AutoCloseable {
public static final Logger LOG = LoggerFactory.getLogger(Client.class);
/** A counter for generating call IDs. */
private static final AtomicInteger callIdCounter = new AtomicInteger();
private static final ThreadLocal callId = new ThreadLocal();
private static final ThreadLocal retryCount = new ThreadLocal();
private static final ThreadLocal EXTERNAL_CALL_HANDLER
= new ThreadLocal<>();
private static final ThreadLocal>
ASYNC_RPC_RESPONSE = new ThreadLocal<>();
private static final ThreadLocal asynchronousMode =
new ThreadLocal() {
@Override
protected Boolean initialValue() {
return false;
}
};
@SuppressWarnings("unchecked")
@Unstable
public static AsyncGet
getAsyncRpcResponse() {
return (AsyncGet) ASYNC_RPC_RESPONSE.get();
}
/** Set call id and retry count for the next call. */
public static void setCallIdAndRetryCount(int cid, int rc,
Object externalHandler) {
Preconditions.checkArgument(cid != RpcConstants.INVALID_CALL_ID);
Preconditions.checkState(callId.get() == null);
Preconditions.checkArgument(rc != RpcConstants.INVALID_RETRY_COUNT);
callId.set(cid);
retryCount.set(rc);
EXTERNAL_CALL_HANDLER.set(externalHandler);
}
private ConcurrentMap connections =
new ConcurrentHashMap<>();
private Class extends Writable> valueClass; // class of call values
private AtomicBoolean running = new AtomicBoolean(true); // if client runs
final private Configuration conf;
private SocketFactory socketFactory; // how to create sockets
private int refCount = 1;
private final int connectionTimeout;
private final boolean fallbackAllowed;
private final boolean bindToWildCardAddress;
private final byte[] clientId;
private final int maxAsyncCalls;
private final AtomicInteger asyncCallCounter = new AtomicInteger(0);
/**
* Executor on which IPC calls' parameters are sent.
* Deferring the sending of parameters to a separate
* thread isolates them from thread interruptions in the
* calling code.
*/
private final ExecutorService sendParamsExecutor;
private final static ClientExecutorServiceFactory clientExcecutorFactory =
new ClientExecutorServiceFactory();
private static class ClientExecutorServiceFactory {
private int executorRefCount = 0;
private ExecutorService clientExecutor = null;
/**
* Get Executor on which IPC calls' parameters are sent.
* If the internal reference counter is zero, this method
* creates the instance of Executor. If not, this method
* just returns the reference of clientExecutor.
*
* @return An ExecutorService instance
*/
synchronized ExecutorService refAndGetInstance() {
if (executorRefCount == 0) {
clientExecutor = Executors.newCachedThreadPool(
new ThreadFactoryBuilder()
.setDaemon(true)
.setNameFormat("IPC Parameter Sending Thread #%d")
.build());
}
executorRefCount++;
return clientExecutor;
}
/**
* Cleanup Executor on which IPC calls' parameters are sent.
* If reference counter is zero, this method discards the
* instance of the Executor. If not, this method
* just decrements the internal reference counter.
*
* @return An ExecutorService instance if it exists.
* Null is returned if not.
*/
synchronized ExecutorService unrefAndCleanup() {
executorRefCount--;
assert(executorRefCount >= 0);
if (executorRefCount == 0) {
clientExecutor.shutdown();
try {
if (!clientExecutor.awaitTermination(1, TimeUnit.MINUTES)) {
clientExecutor.shutdownNow();
}
} catch (InterruptedException e) {
LOG.warn("Interrupted while waiting for clientExecutor" +
" to stop");
clientExecutor.shutdownNow();
Thread.currentThread().interrupt();
}
clientExecutor = null;
}
return clientExecutor;
}
};
/**
* set the ping interval value in configuration
*
* @param conf Configuration
* @param pingInterval the ping interval
*/
public static final void setPingInterval(Configuration conf,
int pingInterval) {
conf.setInt(CommonConfigurationKeys.IPC_PING_INTERVAL_KEY, pingInterval);
}
/**
* Get the ping interval from configuration;
* If not set in the configuration, return the default value.
*
* @param conf Configuration
* @return the ping interval
*/
public static final int getPingInterval(Configuration conf) {
return conf.getInt(CommonConfigurationKeys.IPC_PING_INTERVAL_KEY,
CommonConfigurationKeys.IPC_PING_INTERVAL_DEFAULT);
}
/**
* The time after which a RPC will timeout.
* If ping is not enabled (via ipc.client.ping), then the timeout value is the
* same as the pingInterval.
* If ping is enabled, then there is no timeout value.
*
* @param conf Configuration
* @return the timeout period in milliseconds. -1 if no timeout value is set
* @deprecated use {@link #getRpcTimeout(Configuration)} instead
*/
@Deprecated
final public static int getTimeout(Configuration conf) {
int timeout = getRpcTimeout(conf);
if (timeout > 0) {
return timeout;
}
if (!conf.getBoolean(CommonConfigurationKeys.IPC_CLIENT_PING_KEY,
CommonConfigurationKeys.IPC_CLIENT_PING_DEFAULT)) {
return getPingInterval(conf);
}
return -1;
}
/**
* The time after which a RPC will timeout.
*
* @param conf Configuration
* @return the timeout period in milliseconds.
*/
public static final int getRpcTimeout(Configuration conf) {
int timeout =
conf.getInt(CommonConfigurationKeys.IPC_CLIENT_RPC_TIMEOUT_KEY,
CommonConfigurationKeys.IPC_CLIENT_RPC_TIMEOUT_DEFAULT);
return (timeout < 0) ? 0 : timeout;
}
/**
* set the connection timeout value in configuration
*
* @param conf Configuration
* @param timeout the socket connect timeout value
*/
public static final void setConnectTimeout(Configuration conf, int timeout) {
conf.setInt(CommonConfigurationKeys.IPC_CLIENT_CONNECT_TIMEOUT_KEY, timeout);
}
@VisibleForTesting
public static final ExecutorService getClientExecutor() {
return Client.clientExcecutorFactory.clientExecutor;
}
/**
* Increment this client's reference count
*
*/
synchronized void incCount() {
refCount++;
}
/**
* Decrement this client's reference count
*
*/
synchronized void decCount() {
refCount--;
}
/**
* Return if this client has no reference
*
* @return true if this client has no reference; false otherwise
*/
synchronized boolean isZeroReference() {
return refCount==0;
}
/** Check the rpc response header. */
void checkResponse(RpcResponseHeaderProto header) throws IOException {
if (header == null) {
throw new EOFException("Response is null.");
}
if (header.hasClientId()) {
// check client IDs
final byte[] id = header.getClientId().toByteArray();
if (!Arrays.equals(id, RpcConstants.DUMMY_CLIENT_ID)) {
if (!Arrays.equals(id, clientId)) {
throw new IOException("Client IDs not matched: local ID="
+ StringUtils.byteToHexString(clientId) + ", ID in response="
+ StringUtils.byteToHexString(header.getClientId().toByteArray()));
}
}
}
}
Call createCall(RPC.RpcKind rpcKind, Writable rpcRequest) {
return new Call(rpcKind, rpcRequest);
}
/**
* Class that represents an RPC call
*/
static class Call {
final int id; // call id
final int retry; // retry count
final Writable rpcRequest; // the serialized rpc request
Writable rpcResponse; // null if rpc has error
IOException error; // exception, null if success
final RPC.RpcKind rpcKind; // Rpc EngineKind
boolean done; // true when call is done
private final Object externalHandler;
private Call(RPC.RpcKind rpcKind, Writable param) {
this.rpcKind = rpcKind;
this.rpcRequest = param;
final Integer id = callId.get();
if (id == null) {
this.id = nextCallId();
} else {
callId.set(null);
this.id = id;
}
final Integer rc = retryCount.get();
if (rc == null) {
this.retry = 0;
} else {
this.retry = rc;
}
this.externalHandler = EXTERNAL_CALL_HANDLER.get();
}
@Override
public String toString() {
return getClass().getSimpleName() + id;
}
/** Indicate when the call is complete and the
* value or error are available. Notifies by default. */
protected synchronized void callComplete() {
this.done = true;
notify(); // notify caller
if (externalHandler != null) {
synchronized (externalHandler) {
externalHandler.notify();
}
}
}
/** Set the exception when there is an error.
* Notify the caller the call is done.
*
* @param error exception thrown by the call; either local or remote
*/
public synchronized void setException(IOException error) {
this.error = error;
callComplete();
}
/** Set the return value when there is no error.
* Notify the caller the call is done.
*
* @param rpcResponse return value of the rpc call.
*/
public synchronized void setRpcResponse(Writable rpcResponse) {
this.rpcResponse = rpcResponse;
callComplete();
}
public synchronized Writable getRpcResponse() {
return rpcResponse;
}
}
/** Thread that reads responses and notifies callers. Each connection owns a
* socket connected to a remote address. Calls are multiplexed through this
* socket: responses may be delivered out of order. */
private class Connection extends Thread {
private InetSocketAddress server; // server ip:port
private final ConnectionId remoteId; // connection id
private AuthMethod authMethod; // authentication method
private AuthProtocol authProtocol;
private int serviceClass;
private SaslRpcClient saslRpcClient;
private Socket socket = null; // connected socket
private IpcStreams ipcStreams;
private final int maxResponseLength;
private final int rpcTimeout;
private int maxIdleTime; //connections will be culled if it was idle for
//maxIdleTime msecs
private final RetryPolicy connectionRetryPolicy;
private final int maxRetriesOnSasl;
private int maxRetriesOnSocketTimeouts;
private final boolean tcpNoDelay; // if T then disable Nagle's Algorithm
private final boolean tcpLowLatency; // if T then use low-delay QoS
private final boolean doPing; //do we need to send ping message
private final int pingInterval; // how often sends ping to the server
private final int soTimeout; // used by ipc ping and rpc timeout
private byte[] pingRequest; // ping message
// currently active calls
private Hashtable calls = new Hashtable();
private AtomicLong lastActivity = new AtomicLong();// last I/O activity time
private AtomicBoolean shouldCloseConnection = new AtomicBoolean(); // indicate if the connection is closed
private IOException closeException; // close reason
private final Object sendRpcRequestLock = new Object();
private AtomicReference connectingThread = new AtomicReference<>();
public Connection(ConnectionId remoteId, int serviceClass) throws IOException {
this.remoteId = remoteId;
this.server = remoteId.getAddress();
if (server.isUnresolved()) {
throw NetUtils.wrapException(server.getHostName(),
server.getPort(),
null,
0,
new UnknownHostException());
}
this.maxResponseLength = remoteId.conf.getInt(
CommonConfigurationKeys.IPC_MAXIMUM_RESPONSE_LENGTH,
CommonConfigurationKeys.IPC_MAXIMUM_RESPONSE_LENGTH_DEFAULT);
this.rpcTimeout = remoteId.getRpcTimeout();
this.maxIdleTime = remoteId.getMaxIdleTime();
this.connectionRetryPolicy = remoteId.connectionRetryPolicy;
this.maxRetriesOnSasl = remoteId.getMaxRetriesOnSasl();
this.maxRetriesOnSocketTimeouts = remoteId.getMaxRetriesOnSocketTimeouts();
this.tcpNoDelay = remoteId.getTcpNoDelay();
this.tcpLowLatency = remoteId.getTcpLowLatency();
this.doPing = remoteId.getDoPing();
if (doPing) {
// construct a RPC header with the callId as the ping callId
ResponseBuffer buf = new ResponseBuffer();
RpcRequestHeaderProto pingHeader = ProtoUtil
.makeRpcRequestHeader(RpcKind.RPC_PROTOCOL_BUFFER,
OperationProto.RPC_FINAL_PACKET, PING_CALL_ID,
RpcConstants.INVALID_RETRY_COUNT, clientId);
pingHeader.writeDelimitedTo(buf);
pingRequest = buf.toByteArray();
}
this.pingInterval = remoteId.getPingInterval();
if (rpcTimeout > 0) {
// effective rpc timeout is rounded up to multiple of pingInterval
// if pingInterval < rpcTimeout.
this.soTimeout = (doPing && pingInterval < rpcTimeout) ?
pingInterval : rpcTimeout;
} else {
this.soTimeout = pingInterval;
}
this.serviceClass = serviceClass;
if (LOG.isDebugEnabled()) {
LOG.debug("The ping interval is " + this.pingInterval + " ms.");
}
UserGroupInformation ticket = remoteId.getTicket();
// try SASL if security is enabled or if the ugi contains tokens.
// this causes a SIMPLE client with tokens to attempt SASL
boolean trySasl = UserGroupInformation.isSecurityEnabled() ||
(ticket != null && !ticket.getTokens().isEmpty());
this.authProtocol = trySasl ? AuthProtocol.SASL : AuthProtocol.NONE;
this.setName("IPC Client (" + socketFactory.hashCode() +") connection to " +
server.toString() +
" from " + ((ticket==null)?"an unknown user":ticket.getUserName()));
this.setDaemon(true);
}
/** Update lastActivity with the current time. */
private void touch() {
lastActivity.set(Time.now());
}
/**
* Add a call to this connection's call queue and notify
* a listener; synchronized.
* Returns false if called during shutdown.
* @param call to add
* @return true if the call was added.
*/
private synchronized boolean addCall(Call call) {
if (shouldCloseConnection.get())
return false;
calls.put(call.id, call);
notify();
return true;
}
/** This class sends a ping to the remote side when timeout on
* reading. If no failure is detected, it retries until at least
* a byte is read.
*/
private class PingInputStream extends FilterInputStream {
/* constructor */
protected PingInputStream(InputStream in) {
super(in);
}
/* Process timeout exception
* if the connection is not going to be closed or
* the RPC is not timed out yet, send a ping.
*/
private void handleTimeout(SocketTimeoutException e, int waiting)
throws IOException {
if (shouldCloseConnection.get() || !running.get() ||
(0 < rpcTimeout && rpcTimeout <= waiting)) {
throw e;
} else {
sendPing();
}
}
/** Read a byte from the stream.
* Send a ping if timeout on read. Retries if no failure is detected
* until a byte is read.
* @throws IOException for any IO problem other than socket timeout
*/
@Override
public int read() throws IOException {
int waiting = 0;
do {
try {
return super.read();
} catch (SocketTimeoutException e) {
waiting += soTimeout;
handleTimeout(e, waiting);
}
} while (true);
}
/** Read bytes into a buffer starting from offset off
* Send a ping if timeout on read. Retries if no failure is detected
* until a byte is read.
*
* @return the total number of bytes read; -1 if the connection is closed.
*/
@Override
public int read(byte[] buf, int off, int len) throws IOException {
int waiting = 0;
do {
try {
return super.read(buf, off, len);
} catch (SocketTimeoutException e) {
waiting += soTimeout;
handleTimeout(e, waiting);
}
} while (true);
}
}
private synchronized void disposeSasl() {
if (saslRpcClient != null) {
try {
saslRpcClient.dispose();
saslRpcClient = null;
} catch (IOException ignored) {
}
}
}
private synchronized boolean shouldAuthenticateOverKrb() throws IOException {
UserGroupInformation loginUser = UserGroupInformation.getLoginUser();
UserGroupInformation currentUser = UserGroupInformation.getCurrentUser();
UserGroupInformation realUser = currentUser.getRealUser();
if (authMethod == AuthMethod.KERBEROS && loginUser != null &&
// Make sure user logged in using Kerberos either keytab or TGT
loginUser.hasKerberosCredentials() &&
// relogin only in case it is the login user (e.g. JT)
// or superuser (like oozie).
(loginUser.equals(currentUser) || loginUser.equals(realUser))) {
return true;
}
return false;
}
private synchronized AuthMethod setupSaslConnection(IpcStreams streams)
throws IOException {
// Do not use Client.conf here! We must use ConnectionId.conf, since the
// Client object is cached and shared between all RPC clients, even those
// for separate services.
saslRpcClient = new SaslRpcClient(remoteId.getTicket(),
remoteId.getProtocol(), remoteId.getAddress(), remoteId.conf);
return saslRpcClient.saslConnect(streams);
}
/**
* Update the server address if the address corresponding to the host
* name has changed.
*
* @return true if an addr change was detected.
* @throws IOException when the hostname cannot be resolved.
*/
private synchronized boolean updateAddress() throws IOException {
// Do a fresh lookup with the old host name.
InetSocketAddress currentAddr = NetUtils.createSocketAddrForHost(
server.getHostName(), server.getPort());
if (!server.equals(currentAddr)) {
LOG.warn("Address change detected. Old: " + server.toString() +
" New: " + currentAddr.toString());
server = currentAddr;
return true;
}
return false;
}
private synchronized void setupConnection(
UserGroupInformation ticket) throws IOException {
short ioFailures = 0;
short timeoutFailures = 0;
while (true) {
try {
this.socket = socketFactory.createSocket();
this.socket.setTcpNoDelay(tcpNoDelay);
this.socket.setKeepAlive(true);
if (tcpLowLatency) {
/*
* This allows intermediate switches to shape IPC traffic
* differently from Shuffle/HDFS DataStreamer traffic.
*
* IPTOS_RELIABILITY (0x04) | IPTOS_LOWDELAY (0x10)
*
* Prefer to optimize connect() speed & response latency over net
* throughput.
*/
this.socket.setTrafficClass(0x04 | 0x10);
this.socket.setPerformancePreferences(1, 2, 0);
}
/*
* Bind the socket to the host specified in the principal name of the
* client, to ensure Server matching address of the client connection
* to host name in principal passed.
*/
InetSocketAddress bindAddr = null;
if (ticket != null && ticket.hasKerberosCredentials()) {
KerberosInfo krbInfo =
remoteId.getProtocol().getAnnotation(KerberosInfo.class);
if (krbInfo != null) {
String principal = ticket.getUserName();
String host = SecurityUtil.getHostFromPrincipal(principal);
// If host name is a valid local address then bind socket to it
InetAddress localAddr = NetUtils.getLocalInetAddress(host);
if (localAddr != null) {
this.socket.setReuseAddress(true);
localAddr = NetUtils.bindToLocalAddress(localAddr,
bindToWildCardAddress);
LOG.debug("Binding {} to {}", principal,
(bindToWildCardAddress) ? "0.0.0.0" : localAddr);
this.socket.bind(new InetSocketAddress(localAddr, 0));
}
}
}
NetUtils.connect(this.socket, server, bindAddr, connectionTimeout);
this.socket.setSoTimeout(soTimeout);
return;
} catch (ConnectTimeoutException toe) {
/* Check for an address change and update the local reference.
* Reset the failure counter if the address was changed
*/
if (updateAddress()) {
timeoutFailures = ioFailures = 0;
}
handleConnectionTimeout(timeoutFailures++,
maxRetriesOnSocketTimeouts, toe);
} catch (IOException ie) {
if (updateAddress()) {
timeoutFailures = ioFailures = 0;
}
handleConnectionFailure(ioFailures++, ie);
}
}
}
/**
* If multiple clients with the same principal try to connect to the same
* server at the same time, the server assumes a replay attack is in
* progress. This is a feature of kerberos. In order to work around this,
* what is done is that the client backs off randomly and tries to initiate
* the connection again. The other problem is to do with ticket expiry. To
* handle that, a relogin is attempted.
*/
private synchronized void handleSaslConnectionFailure(
final int currRetries, final int maxRetries, final Exception ex,
final Random rand, final UserGroupInformation ugi) throws IOException,
InterruptedException {
ugi.doAs(new PrivilegedExceptionAction() {
@Override
public Object run() throws IOException, InterruptedException {
final short MAX_BACKOFF = 5000;
closeConnection();
disposeSasl();
if (shouldAuthenticateOverKrb()) {
if (currRetries < maxRetries) {
if(LOG.isDebugEnabled()) {
LOG.debug("Exception encountered while connecting to "
+ "the server : " + ex);
}
// try re-login
if (UserGroupInformation.isLoginKeytabBased()) {
UserGroupInformation.getLoginUser().reloginFromKeytab();
} else if (UserGroupInformation.isLoginTicketBased()) {
UserGroupInformation.getLoginUser().reloginFromTicketCache();
}
// have granularity of milliseconds
//we are sleeping with the Connection lock held but since this
//connection instance is being used for connecting to the server
//in question, it is okay
Thread.sleep((rand.nextInt(MAX_BACKOFF) + 1));
return null;
} else {
String msg = "Couldn't setup connection for "
+ UserGroupInformation.getLoginUser().getUserName() + " to "
+ remoteId;
LOG.warn(msg, ex);
throw (IOException) new IOException(msg).initCause(ex);
}
} else {
LOG.warn("Exception encountered while connecting to "
+ "the server : " + ex);
}
if (ex instanceof RemoteException)
throw (RemoteException) ex;
throw new IOException(ex);
}
});
}
/** Connect to the server and set up the I/O streams. It then sends
* a header to the server and starts
* the connection thread that waits for responses.
*/
private synchronized void setupIOstreams(
AtomicBoolean fallbackToSimpleAuth) {
if (socket != null || shouldCloseConnection.get()) {
return;
}
UserGroupInformation ticket = remoteId.getTicket();
if (ticket != null) {
final UserGroupInformation realUser = ticket.getRealUser();
if (realUser != null) {
ticket = realUser;
}
}
try {
connectingThread.set(Thread.currentThread());
if (LOG.isDebugEnabled()) {
LOG.debug("Connecting to "+server);
}
Span span = Tracer.getCurrentSpan();
if (span != null) {
span.addTimelineAnnotation("IPC client connecting to " + server);
}
short numRetries = 0;
Random rand = null;
while (true) {
setupConnection(ticket);
ipcStreams = new IpcStreams(socket, maxResponseLength);
writeConnectionHeader(ipcStreams);
if (authProtocol == AuthProtocol.SASL) {
try {
authMethod = ticket
.doAs(new PrivilegedExceptionAction() {
@Override
public AuthMethod run()
throws IOException, InterruptedException {
return setupSaslConnection(ipcStreams);
}
});
} catch (IOException ex) {
if (saslRpcClient == null) {
// whatever happened -it can't be handled, so rethrow
throw ex;
}
// otherwise, assume a connection problem
authMethod = saslRpcClient.getAuthMethod();
if (rand == null) {
rand = new Random();
}
handleSaslConnectionFailure(numRetries++, maxRetriesOnSasl, ex,
rand, ticket);
continue;
}
if (authMethod != AuthMethod.SIMPLE) {
// Sasl connect is successful. Let's set up Sasl i/o streams.
ipcStreams.setSaslClient(saslRpcClient);
// for testing
remoteId.saslQop =
(String)saslRpcClient.getNegotiatedProperty(Sasl.QOP);
LOG.debug("Negotiated QOP is :" + remoteId.saslQop);
if (fallbackToSimpleAuth != null) {
fallbackToSimpleAuth.set(false);
}
} else if (UserGroupInformation.isSecurityEnabled()) {
if (!fallbackAllowed) {
throw new IOException("Server asks us to fall back to SIMPLE " +
"auth, but this client is configured to only allow secure " +
"connections.");
}
if (fallbackToSimpleAuth != null) {
fallbackToSimpleAuth.set(true);
}
}
}
if (doPing) {
ipcStreams.setInputStream(new PingInputStream(ipcStreams.in));
}
writeConnectionContext(remoteId, authMethod);
// update last activity time
touch();
span = Tracer.getCurrentSpan();
if (span != null) {
span.addTimelineAnnotation("IPC client connected to " + server);
}
// start the receiver thread after the socket connection has been set
// up
start();
return;
}
} catch (Throwable t) {
if (t instanceof IOException) {
markClosed((IOException)t);
} else {
markClosed(new IOException("Couldn't set up IO streams: " + t, t));
}
close();
} finally {
connectingThread.set(null);
}
}
private void closeConnection() {
if (socket == null) {
return;
}
// close the current connection
try {
socket.close();
} catch (IOException e) {
LOG.warn("Not able to close a socket", e);
}
// set socket to null so that the next call to setupIOstreams
// can start the process of connect all over again.
socket = null;
}
/* Handle connection failures due to timeout on connect
*
* If the current number of retries is equal to the max number of retries,
* stop retrying and throw the exception; Otherwise backoff 1 second and
* try connecting again.
*
* This Method is only called from inside setupIOstreams(), which is
* synchronized. Hence the sleep is synchronized; the locks will be retained.
*
* @param curRetries current number of retries
* @param maxRetries max number of retries allowed
* @param ioe failure reason
* @throws IOException if max number of retries is reached
*/
private void handleConnectionTimeout(
int curRetries, int maxRetries, IOException ioe) throws IOException {
closeConnection();
// throw the exception if the maximum number of retries is reached
if (curRetries >= maxRetries) {
throw ioe;
}
LOG.info("Retrying connect to server: " + server + ". Already tried "
+ curRetries + " time(s); maxRetries=" + maxRetries);
}
private void handleConnectionFailure(int curRetries, IOException ioe
) throws IOException {
closeConnection();
final RetryAction action;
try {
action = connectionRetryPolicy.shouldRetry(ioe, curRetries, 0, true);
} catch(Exception e) {
throw e instanceof IOException? (IOException)e: new IOException(e);
}
if (action.action == RetryAction.RetryDecision.FAIL) {
if (action.reason != null) {
if (LOG.isDebugEnabled()) {
LOG.debug("Failed to connect to server: " + server + ": "
+ action.reason, ioe);
}
}
throw ioe;
}
// Throw the exception if the thread is interrupted
if (Thread.currentThread().isInterrupted()) {
LOG.warn("Interrupted while trying for connection");
throw ioe;
}
try {
Thread.sleep(action.delayMillis);
} catch (InterruptedException e) {
throw (IOException)new InterruptedIOException("Interrupted: action="
+ action + ", retry policy=" + connectionRetryPolicy).initCause(e);
}
LOG.info("Retrying connect to server: " + server + ". Already tried "
+ curRetries + " time(s); retry policy is " + connectionRetryPolicy);
}
/**
* Write the connection header - this is sent when connection is established
* +----------------------------------+
* | "hrpc" 4 bytes |
* +----------------------------------+
* | Version (1 byte) |
* +----------------------------------+
* | Service Class (1 byte) |
* +----------------------------------+
* | AuthProtocol (1 byte) |
* +----------------------------------+
*/
private void writeConnectionHeader(IpcStreams streams)
throws IOException {
// Write out the header, version and authentication method.
// The output stream is buffered but we must not flush it yet. The
// connection setup protocol requires the client to send multiple
// messages before reading a response.
//
// insecure: send header+context+call, read
// secure : send header+negotiate, read, (sasl), context+call, read
//
// The client must flush only when it's prepared to read. Otherwise
// "broken pipe" exceptions occur if the server closes the connection
// before all messages are sent.
final DataOutputStream out = streams.out;
synchronized (out) {
out.write(RpcConstants.HEADER.array());
out.write(RpcConstants.CURRENT_VERSION);
out.write(serviceClass);
out.write(authProtocol.callId);
}
}
/* Write the connection context header for each connection
* Out is not synchronized because only the first thread does this.
*/
private void writeConnectionContext(ConnectionId remoteId,
AuthMethod authMethod)
throws IOException {
// Write out the ConnectionHeader
IpcConnectionContextProto message = ProtoUtil.makeIpcConnectionContext(
RPC.getProtocolName(remoteId.getProtocol()),
remoteId.getTicket(),
authMethod);
RpcRequestHeaderProto connectionContextHeader = ProtoUtil
.makeRpcRequestHeader(RpcKind.RPC_PROTOCOL_BUFFER,
OperationProto.RPC_FINAL_PACKET, CONNECTION_CONTEXT_CALL_ID,
RpcConstants.INVALID_RETRY_COUNT, clientId);
// do not flush. the context and first ipc call request must be sent
// together to avoid possibility of broken pipes upon authz failure.
// see writeConnectionHeader
final ResponseBuffer buf = new ResponseBuffer();
connectionContextHeader.writeDelimitedTo(buf);
message.writeDelimitedTo(buf);
synchronized (ipcStreams.out) {
ipcStreams.sendRequest(buf.toByteArray());
}
}
/* wait till someone signals us to start reading RPC response or
* it is idle too long, it is marked as to be closed,
* or the client is marked as not running.
*
* Return true if it is time to read a response; false otherwise.
*/
private synchronized boolean waitForWork() {
if (calls.isEmpty() && !shouldCloseConnection.get() && running.get()) {
long timeout = maxIdleTime-
(Time.now()-lastActivity.get());
if (timeout>0) {
try {
wait(timeout);
} catch (InterruptedException e) {}
}
}
if (!calls.isEmpty() && !shouldCloseConnection.get() && running.get()) {
return true;
} else if (shouldCloseConnection.get()) {
return false;
} else if (calls.isEmpty()) { // idle connection closed or stopped
markClosed(null);
return false;
} else { // get stopped but there are still pending requests
markClosed((IOException)new IOException().initCause(
new InterruptedException()));
return false;
}
}
public InetSocketAddress getRemoteAddress() {
return server;
}
/* Send a ping to the server if the time elapsed
* since last I/O activity is equal to or greater than the ping interval
*/
private synchronized void sendPing() throws IOException {
long curTime = Time.now();
if ( curTime - lastActivity.get() >= pingInterval) {
lastActivity.set(curTime);
synchronized (ipcStreams.out) {
ipcStreams.sendRequest(pingRequest);
ipcStreams.flush();
}
}
}
@Override
public void run() {
if (LOG.isDebugEnabled())
LOG.debug(getName() + ": starting, having connections "
+ connections.size());
try {
while (waitForWork()) {//wait here for work - read or close connection
receiveRpcResponse();
}
} catch (Throwable t) {
// This truly is unexpected, since we catch IOException in receiveResponse
// -- this is only to be really sure that we don't leave a client hanging
// forever.
LOG.warn("Unexpected error reading responses on connection " + this, t);
markClosed(new IOException("Error reading responses", t));
}
close();
if (LOG.isDebugEnabled())
LOG.debug(getName() + ": stopped, remaining connections "
+ connections.size());
}
/** Initiates a rpc call by sending the rpc request to the remote server.
* Note: this is not called from the Connection thread, but by other
* threads.
* @param call - the rpc request
*/
public void sendRpcRequest(final Call call)
throws InterruptedException, IOException {
if (shouldCloseConnection.get()) {
return;
}
// Serialize the call to be sent. This is done from the actual
// caller thread, rather than the sendParamsExecutor thread,
// so that if the serialization throws an error, it is reported
// properly. This also parallelizes the serialization.
//
// Format of a call on the wire:
// 0) Length of rest below (1 + 2)
// 1) RpcRequestHeader - is serialized Delimited hence contains length
// 2) RpcRequest
//
// Items '1' and '2' are prepared here.
RpcRequestHeaderProto header = ProtoUtil.makeRpcRequestHeader(
call.rpcKind, OperationProto.RPC_FINAL_PACKET, call.id, call.retry,
clientId);
final ResponseBuffer buf = new ResponseBuffer();
header.writeDelimitedTo(buf);
RpcWritable.wrap(call.rpcRequest).writeTo(buf);
synchronized (sendRpcRequestLock) {
Future> senderFuture = sendParamsExecutor.submit(new Runnable() {
@Override
public void run() {
try {
synchronized (ipcStreams.out) {
if (shouldCloseConnection.get()) {
return;
}
if (LOG.isDebugEnabled()) {
LOG.debug(getName() + " sending #" + call.id
+ " " + call.rpcRequest);
}
// RpcRequestHeader + RpcRequest
ipcStreams.sendRequest(buf.toByteArray());
ipcStreams.flush();
}
} catch (IOException e) {
// exception at this point would leave the connection in an
// unrecoverable state (eg half a call left on the wire).
// So, close the connection, killing any outstanding calls
markClosed(e);
} finally {
//the buffer is just an in-memory buffer, but it is still polite to
// close early
IOUtils.closeStream(buf);
}
}
});
try {
senderFuture.get();
} catch (ExecutionException e) {
Throwable cause = e.getCause();
// cause should only be a RuntimeException as the Runnable above
// catches IOException
if (cause instanceof RuntimeException) {
throw (RuntimeException) cause;
} else {
throw new RuntimeException("unexpected checked exception", cause);
}
}
}
}
/* Receive a response.
* Because only one receiver, so no synchronization on in.
*/
private void receiveRpcResponse() {
if (shouldCloseConnection.get()) {
return;
}
touch();
try {
ByteBuffer bb = ipcStreams.readResponse();
RpcWritable.Buffer packet = RpcWritable.Buffer.wrap(bb);
RpcResponseHeaderProto header =
packet.getValue(RpcResponseHeaderProto.getDefaultInstance());
checkResponse(header);
int callId = header.getCallId();
if (LOG.isDebugEnabled())
LOG.debug(getName() + " got value #" + callId);
RpcStatusProto status = header.getStatus();
if (status == RpcStatusProto.SUCCESS) {
Writable value = packet.newInstance(valueClass, conf);
final Call call = calls.remove(callId);
call.setRpcResponse(value);
}
// verify that packet length was correct
if (packet.remaining() > 0) {
throw new RpcClientException("RPC response length mismatch");
}
if (status != RpcStatusProto.SUCCESS) { // Rpc Request failed
final String exceptionClassName = header.hasExceptionClassName() ?
header.getExceptionClassName() :
"ServerDidNotSetExceptionClassName";
final String errorMsg = header.hasErrorMsg() ?
header.getErrorMsg() : "ServerDidNotSetErrorMsg" ;
final RpcErrorCodeProto erCode =
(header.hasErrorDetail() ? header.getErrorDetail() : null);
if (erCode == null) {
LOG.warn("Detailed error code not set by server on rpc error");
}
RemoteException re = new RemoteException(exceptionClassName, errorMsg, erCode);
if (status == RpcStatusProto.ERROR) {
final Call call = calls.remove(callId);
call.setException(re);
} else if (status == RpcStatusProto.FATAL) {
// Close the connection
markClosed(re);
}
}
} catch (IOException e) {
markClosed(e);
}
}
private synchronized void markClosed(IOException e) {
if (shouldCloseConnection.compareAndSet(false, true)) {
closeException = e;
notifyAll();
}
}
private void interruptConnectingThread() {
Thread connThread = connectingThread.get();
if (connThread != null) {
connThread.interrupt();
}
}
/** Close the connection. */
private synchronized void close() {
if (!shouldCloseConnection.get()) {
LOG.error("The connection is not in the closed state");
return;
}
// We have marked this connection as closed. Other thread could have
// already known it and replace this closedConnection with a new one.
// We should only remove this closedConnection.
connections.remove(remoteId, this);
// close the streams and therefore the socket
IOUtils.closeStream(ipcStreams);
disposeSasl();
// clean up all calls
if (closeException == null) {
if (!calls.isEmpty()) {
LOG.warn(
"A connection is closed for no cause and calls are not empty");
// clean up calls anyway
closeException = new IOException("Unexpected closed connection");
cleanupCalls();
}
} else {
// log the info
if (LOG.isDebugEnabled()) {
LOG.debug("closing ipc connection to " + server + ": " +
closeException.getMessage(),closeException);
}
// cleanup calls
cleanupCalls();
}
closeConnection();
if (LOG.isDebugEnabled())
LOG.debug(getName() + ": closed");
}
/* Cleanup all calls and mark them as done */
private void cleanupCalls() {
Iterator> itor = calls.entrySet().iterator() ;
while (itor.hasNext()) {
Call c = itor.next().getValue();
itor.remove();
c.setException(closeException); // local exception
}
}
}
/** Construct an IPC client whose values are of the given {@link Writable}
* class. */
public Client(Class extends Writable> valueClass, Configuration conf,
SocketFactory factory) {
this.valueClass = valueClass;
this.conf = conf;
this.socketFactory = factory;
this.connectionTimeout = conf.getInt(CommonConfigurationKeys.IPC_CLIENT_CONNECT_TIMEOUT_KEY,
CommonConfigurationKeys.IPC_CLIENT_CONNECT_TIMEOUT_DEFAULT);
this.fallbackAllowed = conf.getBoolean(CommonConfigurationKeys.IPC_CLIENT_FALLBACK_TO_SIMPLE_AUTH_ALLOWED_KEY,
CommonConfigurationKeys.IPC_CLIENT_FALLBACK_TO_SIMPLE_AUTH_ALLOWED_DEFAULT);
this.bindToWildCardAddress = conf
.getBoolean(CommonConfigurationKeys.IPC_CLIENT_BIND_WILDCARD_ADDR_KEY,
CommonConfigurationKeys.IPC_CLIENT_BIND_WILDCARD_ADDR_DEFAULT);
this.clientId = ClientId.getClientId();
this.sendParamsExecutor = clientExcecutorFactory.refAndGetInstance();
this.maxAsyncCalls = conf.getInt(
CommonConfigurationKeys.IPC_CLIENT_ASYNC_CALLS_MAX_KEY,
CommonConfigurationKeys.IPC_CLIENT_ASYNC_CALLS_MAX_DEFAULT);
}
/**
* Construct an IPC client with the default SocketFactory
* @param valueClass
* @param conf
*/
public Client(Class extends Writable> valueClass, Configuration conf) {
this(valueClass, conf, NetUtils.getDefaultSocketFactory(conf));
}
/** Return the socket factory of this client
*
* @return this client's socket factory
*/
SocketFactory getSocketFactory() {
return socketFactory;
}
/** Stop all threads related to this client. No further calls may be made
* using this client. */
public void stop() {
if (LOG.isDebugEnabled()) {
LOG.debug("Stopping client");
}
if (!running.compareAndSet(true, false)) {
return;
}
// wake up all connections
for (Connection conn : connections.values()) {
conn.interrupt();
conn.interruptConnectingThread();
}
// wait until all connections are closed
while (!connections.isEmpty()) {
try {
Thread.sleep(100);
} catch (InterruptedException e) {
}
}
clientExcecutorFactory.unrefAndCleanup();
}
/**
* Make a call, passing rpcRequest
, to the IPC server defined by
* remoteId
, returning the rpc respond.
*
* @param rpcKind
* @param rpcRequest - contains serialized method and method parameters
* @param remoteId - the target rpc server
* @param fallbackToSimpleAuth - set to true or false during this method to
* indicate if a secure client falls back to simple auth
* @returns the rpc response
* Throws exceptions if there are network problems or if the remote code
* threw an exception.
*/
public Writable call(RPC.RpcKind rpcKind, Writable rpcRequest,
ConnectionId remoteId, AtomicBoolean fallbackToSimpleAuth)
throws IOException {
return call(rpcKind, rpcRequest, remoteId, RPC.RPC_SERVICE_CLASS_DEFAULT,
fallbackToSimpleAuth);
}
private void checkAsyncCall() throws IOException {
if (isAsynchronousMode()) {
if (asyncCallCounter.incrementAndGet() > maxAsyncCalls) {
asyncCallCounter.decrementAndGet();
String errMsg = String.format(
"Exceeded limit of max asynchronous calls: %d, " +
"please configure %s to adjust it.",
maxAsyncCalls,
CommonConfigurationKeys.IPC_CLIENT_ASYNC_CALLS_MAX_KEY);
throw new AsyncCallLimitExceededException(errMsg);
}
}
}
/**
* Make a call, passing rpcRequest
, to the IPC server defined by
* remoteId
, returning the rpc response.
*
* @param rpcKind
* @param rpcRequest - contains serialized method and method parameters
* @param remoteId - the target rpc server
* @param serviceClass - service class for RPC
* @param fallbackToSimpleAuth - set to true or false during this method to
* indicate if a secure client falls back to simple auth
* @returns the rpc response
* Throws exceptions if there are network problems or if the remote code
* threw an exception.
*/
Writable call(RPC.RpcKind rpcKind, Writable rpcRequest,
ConnectionId remoteId, int serviceClass,
AtomicBoolean fallbackToSimpleAuth) throws IOException {
final Call call = createCall(rpcKind, rpcRequest);
final Connection connection = getConnection(remoteId, call, serviceClass,
fallbackToSimpleAuth);
try {
checkAsyncCall();
try {
connection.sendRpcRequest(call); // send the rpc request
} catch (RejectedExecutionException e) {
throw new IOException("connection has been closed", e);
} catch (InterruptedException e) {
Thread.currentThread().interrupt();
LOG.warn("interrupted waiting to send rpc request to server", e);
throw new IOException(e);
}
} catch(Exception e) {
if (isAsynchronousMode()) {
releaseAsyncCall();
}
throw e;
}
if (isAsynchronousMode()) {
final AsyncGet asyncGet
= new AsyncGet() {
@Override
public Writable get(long timeout, TimeUnit unit)
throws IOException, TimeoutException{
boolean done = true;
try {
final Writable w = getRpcResponse(call, connection, timeout, unit);
if (w == null) {
done = false;
throw new TimeoutException(call + " timed out "
+ timeout + " " + unit);
}
return w;
} finally {
if (done) {
releaseAsyncCall();
}
}
}
@Override
public boolean isDone() {
synchronized (call) {
return call.done;
}
}
};
ASYNC_RPC_RESPONSE.set(asyncGet);
return null;
} else {
return getRpcResponse(call, connection, -1, null);
}
}
/**
* Check if RPC is in asynchronous mode or not.
*
* @returns true, if RPC is in asynchronous mode, otherwise false for
* synchronous mode.
*/
@Unstable
public static boolean isAsynchronousMode() {
return asynchronousMode.get();
}
/**
* Set RPC to asynchronous or synchronous mode.
*
* @param async
* true, RPC will be in asynchronous mode, otherwise false for
* synchronous mode
*/
@Unstable
public static void setAsynchronousMode(boolean async) {
asynchronousMode.set(async);
}
private void releaseAsyncCall() {
asyncCallCounter.decrementAndGet();
}
@VisibleForTesting
int getAsyncCallCount() {
return asyncCallCounter.get();
}
/** @return the rpc response or, in case of timeout, null. */
private Writable getRpcResponse(final Call call, final Connection connection,
final long timeout, final TimeUnit unit) throws IOException {
synchronized (call) {
while (!call.done) {
try {
AsyncGet.Util.wait(call, timeout, unit);
if (timeout >= 0 && !call.done) {
return null;
}
} catch (InterruptedException ie) {
Thread.currentThread().interrupt();
throw new InterruptedIOException("Call interrupted");
}
}
if (call.error != null) {
if (call.error instanceof RemoteException) {
call.error.fillInStackTrace();
throw call.error;
} else { // local exception
InetSocketAddress address = connection.getRemoteAddress();
throw NetUtils.wrapException(address.getHostName(),
address.getPort(),
NetUtils.getHostname(),
0,
call.error);
}
} else {
return call.getRpcResponse();
}
}
}
// for unit testing only
@InterfaceAudience.Private
@InterfaceStability.Unstable
Set getConnectionIds() {
return connections.keySet();
}
/** Get a connection from the pool, or create a new one and add it to the
* pool. Connections to a given ConnectionId are reused. */
private Connection getConnection(ConnectionId remoteId,
Call call, int serviceClass, AtomicBoolean fallbackToSimpleAuth)
throws IOException {
if (!running.get()) {
// the client is stopped
throw new IOException("The client is stopped");
}
Connection connection;
/* we could avoid this allocation for each RPC by having a
* connectionsId object and with set() method. We need to manage the
* refs for keys in HashMap properly. For now its ok.
*/
while (true) {
// These lines below can be shorten with computeIfAbsent in Java8
connection = connections.get(remoteId);
if (connection == null) {
connection = new Connection(remoteId, serviceClass);
Connection existing = connections.putIfAbsent(remoteId, connection);
if (existing != null) {
connection = existing;
}
}
if (connection.addCall(call)) {
break;
} else {
// This connection is closed, should be removed. But other thread could
// have already known this closedConnection, and replace it with a new
// connection. So we should call conditional remove to make sure we only
// remove this closedConnection.
connections.remove(remoteId, connection);
}
}
// If the server happens to be slow, the method below will take longer to
// establish a connection.
connection.setupIOstreams(fallbackToSimpleAuth);
return connection;
}
/**
* This class holds the address and the user ticket. The client connections
* to servers are uniquely identified by
*/
@InterfaceAudience.LimitedPrivate({"HDFS", "MapReduce"})
@InterfaceStability.Evolving
public static class ConnectionId {
InetSocketAddress address;
UserGroupInformation ticket;
final Class> protocol;
private static final int PRIME = 16777619;
private final int rpcTimeout;
private final int maxIdleTime; //connections will be culled if it was idle for
//maxIdleTime msecs
private final RetryPolicy connectionRetryPolicy;
private final int maxRetriesOnSasl;
// the max. no. of retries for socket connections on time out exceptions
private final int maxRetriesOnSocketTimeouts;
private final boolean tcpNoDelay; // if T then disable Nagle's Algorithm
private final boolean tcpLowLatency; // if T then use low-delay QoS
private final boolean doPing; //do we need to send ping message
private final int pingInterval; // how often sends ping to the server in msecs
private String saslQop; // here for testing
private final Configuration conf; // used to get the expected kerberos principal name
ConnectionId(InetSocketAddress address, Class> protocol,
UserGroupInformation ticket, int rpcTimeout,
RetryPolicy connectionRetryPolicy, Configuration conf) {
this.protocol = protocol;
this.address = address;
this.ticket = ticket;
this.rpcTimeout = rpcTimeout;
this.connectionRetryPolicy = connectionRetryPolicy;
this.maxIdleTime = conf.getInt(
CommonConfigurationKeysPublic.IPC_CLIENT_CONNECTION_MAXIDLETIME_KEY,
CommonConfigurationKeysPublic.IPC_CLIENT_CONNECTION_MAXIDLETIME_DEFAULT);
this.maxRetriesOnSasl = conf.getInt(
CommonConfigurationKeys.IPC_CLIENT_CONNECT_MAX_RETRIES_ON_SASL_KEY,
CommonConfigurationKeys.IPC_CLIENT_CONNECT_MAX_RETRIES_ON_SASL_DEFAULT);
this.maxRetriesOnSocketTimeouts = conf.getInt(
CommonConfigurationKeysPublic.IPC_CLIENT_CONNECT_MAX_RETRIES_ON_SOCKET_TIMEOUTS_KEY,
CommonConfigurationKeysPublic.IPC_CLIENT_CONNECT_MAX_RETRIES_ON_SOCKET_TIMEOUTS_DEFAULT);
this.tcpNoDelay = conf.getBoolean(
CommonConfigurationKeysPublic.IPC_CLIENT_TCPNODELAY_KEY,
CommonConfigurationKeysPublic.IPC_CLIENT_TCPNODELAY_DEFAULT);
this.tcpLowLatency = conf.getBoolean(
CommonConfigurationKeysPublic.IPC_CLIENT_LOW_LATENCY,
CommonConfigurationKeysPublic.IPC_CLIENT_LOW_LATENCY_DEFAULT
);
this.doPing = conf.getBoolean(
CommonConfigurationKeys.IPC_CLIENT_PING_KEY,
CommonConfigurationKeys.IPC_CLIENT_PING_DEFAULT);
this.pingInterval = (doPing ? Client.getPingInterval(conf) : 0);
this.conf = conf;
}
InetSocketAddress getAddress() {
return address;
}
Class> getProtocol() {
return protocol;
}
UserGroupInformation getTicket() {
return ticket;
}
private int getRpcTimeout() {
return rpcTimeout;
}
int getMaxIdleTime() {
return maxIdleTime;
}
public int getMaxRetriesOnSasl() {
return maxRetriesOnSasl;
}
/** max connection retries on socket time outs */
public int getMaxRetriesOnSocketTimeouts() {
return maxRetriesOnSocketTimeouts;
}
/** disable nagle's algorithm */
boolean getTcpNoDelay() {
return tcpNoDelay;
}
/** use low-latency QoS bits over TCP */
boolean getTcpLowLatency() {
return tcpLowLatency;
}
boolean getDoPing() {
return doPing;
}
int getPingInterval() {
return pingInterval;
}
@VisibleForTesting
String getSaslQop() {
return saslQop;
}
/**
* Returns a ConnectionId object.
* @param addr Remote address for the connection.
* @param protocol Protocol for RPC.
* @param ticket UGI
* @param rpcTimeout timeout
* @param conf Configuration object
* @return A ConnectionId instance
* @throws IOException
*/
static ConnectionId getConnectionId(InetSocketAddress addr,
Class> protocol, UserGroupInformation ticket, int rpcTimeout,
RetryPolicy connectionRetryPolicy, Configuration conf) throws IOException {
if (connectionRetryPolicy == null) {
final int max = conf.getInt(
CommonConfigurationKeysPublic.IPC_CLIENT_CONNECT_MAX_RETRIES_KEY,
CommonConfigurationKeysPublic.IPC_CLIENT_CONNECT_MAX_RETRIES_DEFAULT);
final int retryInterval = conf.getInt(
CommonConfigurationKeysPublic.IPC_CLIENT_CONNECT_RETRY_INTERVAL_KEY,
CommonConfigurationKeysPublic
.IPC_CLIENT_CONNECT_RETRY_INTERVAL_DEFAULT);
connectionRetryPolicy = RetryPolicies.retryUpToMaximumCountWithFixedSleep(
max, retryInterval, TimeUnit.MILLISECONDS);
}
return new ConnectionId(addr, protocol, ticket, rpcTimeout,
connectionRetryPolicy, conf);
}
static boolean isEqual(Object a, Object b) {
return a == null ? b == null : a.equals(b);
}
@Override
public boolean equals(Object obj) {
if (obj == this) {
return true;
}
if (obj instanceof ConnectionId) {
ConnectionId that = (ConnectionId) obj;
return isEqual(this.address, that.address)
&& this.doPing == that.doPing
&& this.maxIdleTime == that.maxIdleTime
&& isEqual(this.connectionRetryPolicy, that.connectionRetryPolicy)
&& this.pingInterval == that.pingInterval
&& isEqual(this.protocol, that.protocol)
&& this.rpcTimeout == that.rpcTimeout
&& this.tcpNoDelay == that.tcpNoDelay
&& isEqual(this.ticket, that.ticket);
}
return false;
}
@Override
public int hashCode() {
int result = connectionRetryPolicy.hashCode();
result = PRIME * result + ((address == null) ? 0 : address.hashCode());
result = PRIME * result + (doPing ? 1231 : 1237);
result = PRIME * result + maxIdleTime;
result = PRIME * result + pingInterval;
result = PRIME * result + ((protocol == null) ? 0 : protocol.hashCode());
result = PRIME * result + rpcTimeout;
result = PRIME * result + (tcpNoDelay ? 1231 : 1237);
result = PRIME * result + ((ticket == null) ? 0 : ticket.hashCode());
return result;
}
@Override
public String toString() {
return address.toString();
}
}
/**
* Returns the next valid sequential call ID by incrementing an atomic counter
* and masking off the sign bit. Valid call IDs are non-negative integers in
* the range [ 0, 2^31 - 1 ]. Negative numbers are reserved for special
* purposes. The values can overflow back to 0 and be reused. Note that prior
* versions of the client did not mask off the sign bit, so a server may still
* see a negative call ID if it receives connections from an old client.
*
* @return next call ID
*/
public static int nextCallId() {
return callIdCounter.getAndIncrement() & 0x7FFFFFFF;
}
@Override
@Unstable
public void close() throws Exception {
stop();
}
/** Manages the input and output streams for an IPC connection.
* Only exposed for use by SaslRpcClient.
*/
@InterfaceAudience.Private
public static class IpcStreams implements Closeable, Flushable {
private DataInputStream in;
public DataOutputStream out;
private int maxResponseLength;
private boolean firstResponse = true;
IpcStreams(Socket socket, int maxResponseLength) throws IOException {
this.maxResponseLength = maxResponseLength;
setInputStream(
new BufferedInputStream(NetUtils.getInputStream(socket)));
setOutputStream(
new BufferedOutputStream(NetUtils.getOutputStream(socket)));
}
void setSaslClient(SaslRpcClient client) throws IOException {
// Wrap the input stream in a BufferedInputStream to fill the buffer
// before reading its length (HADOOP-14062).
setInputStream(new BufferedInputStream(client.getInputStream(in)));
setOutputStream(client.getOutputStream(out));
}
private void setInputStream(InputStream is) {
this.in = (is instanceof DataInputStream)
? (DataInputStream)is : new DataInputStream(is);
}
private void setOutputStream(OutputStream os) {
this.out = (os instanceof DataOutputStream)
? (DataOutputStream)os : new DataOutputStream(os);
}
public ByteBuffer readResponse() throws IOException {
int length = in.readInt();
if (firstResponse) {
firstResponse = false;
// pre-rpcv9 exception, almost certainly a version mismatch.
if (length == -1) {
in.readInt(); // ignore fatal/error status, it's fatal for us.
throw new RemoteException(WritableUtils.readString(in),
WritableUtils.readString(in));
}
}
if (length <= 0) {
throw new RpcException("RPC response has invalid length");
}
if (maxResponseLength > 0 && length > maxResponseLength) {
throw new RpcException("RPC response exceeds maximum data length");
}
ByteBuffer bb = ByteBuffer.allocate(length);
in.readFully(bb.array());
return bb;
}
public void sendRequest(byte[] buf) throws IOException {
out.write(buf);
}
@Override
public void flush() throws IOException {
out.flush();
}
@Override
public void close() {
IOUtils.closeStream(out);
IOUtils.closeStream(in);
}
}
}