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package org.eclipse.jetty.server;

import java.io.IOException;
import java.net.Socket;
import java.nio.ByteBuffer;
import java.nio.channels.ClosedByInterruptException;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.HashSet;
import java.util.LinkedHashMap;
import java.util.List;
import java.util.Map;
import java.util.Set;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.CountDownLatch;
import java.util.concurrent.Executor;
import java.util.concurrent.Future;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.locks.Condition;

import org.eclipse.jetty.io.ArrayByteBufferPool;
import org.eclipse.jetty.io.ByteBufferPool;
import org.eclipse.jetty.io.EndPoint;
import org.eclipse.jetty.io.ssl.SslConnection;
import org.eclipse.jetty.util.ProcessorUtils;
import org.eclipse.jetty.util.StringUtil;
import org.eclipse.jetty.util.annotation.ManagedAttribute;
import org.eclipse.jetty.util.annotation.ManagedObject;
import org.eclipse.jetty.util.component.ContainerLifeCycle;
import org.eclipse.jetty.util.component.Dumpable;
import org.eclipse.jetty.util.component.Graceful;
import org.eclipse.jetty.util.log.Log;
import org.eclipse.jetty.util.log.Logger;
import org.eclipse.jetty.util.ssl.SslContextFactory;
import org.eclipse.jetty.util.thread.Locker;
import org.eclipse.jetty.util.thread.ScheduledExecutorScheduler;
import org.eclipse.jetty.util.thread.Scheduler;
import org.eclipse.jetty.util.thread.ThreadPoolBudget;

An abstract implementation of Connector that provides a ConnectionFactory mechanism for creating Connection instances for various protocols (HTTP, SSL, etc).

Connector Services

The abstract connector manages the dependent services needed by all specific connector instances:
  • The Executor service is used to run all active tasks needed by this connector such as accepting connections or handle HTTP requests. The default is to use the Server.getThreadPool() as an executor.
  • The Scheduler service is used to monitor the idle timeouts of all connections and is also made available to the connections to time such things as asynchronous request timeouts. The default is to use a new ScheduledExecutorScheduler instance.
  • The ByteBufferPool service is made available to all connections to be used to acquire and release ByteBuffer instances from a pool. The default is to use a new ArrayByteBufferPool instance.
These services are managed as aggregate beans by the ContainerLifeCycle super class and may either be managed or unmanaged beans.

Connection Factories

The connector keeps a collection of ConnectionFactory instances, each of which are known by their protocol name. The protocol name may be a real protocol (e.g. "http/1.1" or "h2") or it may be a private name that represents a special connection factory. For example, the name "SSL-http/1.1" is used for an SslConnectionFactory that has been instantiated with the HttpConnectionFactory as it's next protocol.

Configuring Connection Factories

The collection of available ConnectionFactory may be constructor injected or modified with the methods addConnectionFactory(ConnectionFactory), removeConnectionFactory(String) and setConnectionFactories(Collection<ConnectionFactory>). Only a single ConnectionFactory instance may be configured per protocol name, so if two factories with the same ConnectionFactory.getProtocol() are set, then the second will replace the first.

The protocol factory used for newly accepted connections is specified by the method setDefaultProtocol(String) or defaults to the protocol of the first configured factory.

Each Connection factory type is responsible for the configuration of the protocols that it accepts. Thus to configure the HTTP protocol, you pass a HttpConfiguration instance to the HttpConnectionFactory (or other factories that can also provide HTTP Semantics). Similarly the SslConnectionFactory is configured by passing it a SslContextFactory and a next protocol name.

Connection Factory Operation

ConnectionFactorys may simply create a Connection instance to support a specific protocol. For example, the HttpConnectionFactory will create a HttpConnection instance that can handle http/1.1, http/1.0 and http/0.9.

ConnectionFactorys may also create a chain of Connection instances, using other ConnectionFactory instances. For example, the SslConnectionFactory is configured with a next protocol name, so that once it has accepted a connection and created an SslConnection, it then used the next ConnectionFactory from the connector using the getConnectionFactory(String) method, to create a Connection instance that will handle the unencrypted bytes from the SslConnection. If the next protocol is "http/1.1", then the SslConnectionFactory will have a protocol name of "SSL-http/1.1" and lookup "http/1.1" for the protocol to run over the SSL connection.

ConnectionFactorys may also create temporary Connection instances that will exchange bytes over the connection to determine what is the next protocol to use. For example the ALPN protocol is an extension of SSL to allow a protocol to be specified during the SSL handshake. ALPN is used by the HTTP/2 protocol to negotiate the protocol that the client and server will speak. Thus to accept a HTTP/2 connection, the connector will be configured with ConnectionFactorys for "SSL-ALPN", "h2", "http/1.1" with the default protocol being "SSL-ALPN". Thus a newly accepted connection uses "SSL-ALPN", which specifies a SSLConnectionFactory with "ALPN" as the next protocol. Thus an SSL connection instance is created chained to an ALPN connection instance. The ALPN connection then negotiates with the client to determined the next protocol, which could be "h2" or the default of "http/1.1". Once the next protocol is determined, the ALPN connection calls getConnectionFactory(String) to create a connection instance that will replace the ALPN connection as the connection chained to the SSL connection.

Acceptors

The connector will execute a number of acceptor tasks to the Exception service passed to the constructor. The acceptor tasks run in a loop while the connector is running and repeatedly call the abstract accept(int) method. The implementation of the accept method must:
  1. block waiting for new connections
  2. accept the connection (eg socket accept)
  3. perform any configuration of the connection (eg. socket configuration)
  4. call the getDefaultConnectionFactory() ConnectionFactory.newConnection(Connector, EndPoint) method to create a new Connection instance.
The default number of acceptor tasks is the minimum of 1 and the number of available CPUs divided by 8. Having more acceptors may reduce the latency for servers that see a high rate of new connections (eg HTTP/1.0 without keep-alive). Typically the default is sufficient for modern persistent protocols (HTTP/1.1, HTTP/2 etc.)
/** * <p>An abstract implementation of {@link Connector} that provides a {@link ConnectionFactory} mechanism * for creating {@link org.eclipse.jetty.io.Connection} instances for various protocols (HTTP, SSL, etc).</p> * * <h2>Connector Services</h2> * The abstract connector manages the dependent services needed by all specific connector instances: * <ul> * <li>The {@link Executor} service is used to run all active tasks needed by this connector such as accepting connections * or handle HTTP requests. The default is to use the {@link Server#getThreadPool()} as an executor. * </li> * <li>The {@link Scheduler} service is used to monitor the idle timeouts of all connections and is also made available * to the connections to time such things as asynchronous request timeouts. The default is to use a new * {@link ScheduledExecutorScheduler} instance. * </li> * <li>The {@link ByteBufferPool} service is made available to all connections to be used to acquire and release * {@link ByteBuffer} instances from a pool. The default is to use a new {@link ArrayByteBufferPool} instance. * </li> * </ul> * These services are managed as aggregate beans by the {@link ContainerLifeCycle} super class and * may either be managed or unmanaged beans. * * <h2>Connection Factories</h2> * The connector keeps a collection of {@link ConnectionFactory} instances, each of which are known by their * protocol name. The protocol name may be a real protocol (e.g. "http/1.1" or "h2") or it may be a private name * that represents a special connection factory. For example, the name "SSL-http/1.1" is used for * an {@link SslConnectionFactory} that has been instantiated with the {@link HttpConnectionFactory} as it's * next protocol. * * <h2>Configuring Connection Factories</h2> * The collection of available {@link ConnectionFactory} may be constructor injected or modified with the * methods {@link #addConnectionFactory(ConnectionFactory)}, {@link #removeConnectionFactory(String)} and * {@link #setConnectionFactories(Collection)}. Only a single {@link ConnectionFactory} instance may be configured * per protocol name, so if two factories with the same {@link ConnectionFactory#getProtocol()} are set, then * the second will replace the first. * <p> * The protocol factory used for newly accepted connections is specified by * the method {@link #setDefaultProtocol(String)} or defaults to the protocol of the first configured factory. * <p> * Each Connection factory type is responsible for the configuration of the protocols that it accepts. Thus to * configure the HTTP protocol, you pass a {@link HttpConfiguration} instance to the {@link HttpConnectionFactory} * (or other factories that can also provide HTTP Semantics). Similarly the {@link SslConnectionFactory} is * configured by passing it a {@link SslContextFactory} and a next protocol name. * * <h2>Connection Factory Operation</h2> * {@link ConnectionFactory}s may simply create a {@link org.eclipse.jetty.io.Connection} instance to support a specific * protocol. For example, the {@link HttpConnectionFactory} will create a {@link HttpConnection} instance * that can handle http/1.1, http/1.0 and http/0.9. * <p> * {@link ConnectionFactory}s may also create a chain of {@link org.eclipse.jetty.io.Connection} instances, using other {@link ConnectionFactory} instances. * For example, the {@link SslConnectionFactory} is configured with a next protocol name, so that once it has accepted * a connection and created an {@link SslConnection}, it then used the next {@link ConnectionFactory} from the * connector using the {@link #getConnectionFactory(String)} method, to create a {@link org.eclipse.jetty.io.Connection} instance that * will handle the unencrypted bytes from the {@link SslConnection}. If the next protocol is "http/1.1", then the * {@link SslConnectionFactory} will have a protocol name of "SSL-http/1.1" and lookup "http/1.1" for the protocol * to run over the SSL connection. * <p> * {@link ConnectionFactory}s may also create temporary {@link org.eclipse.jetty.io.Connection} instances that will exchange bytes * over the connection to determine what is the next protocol to use. For example the ALPN protocol is an extension * of SSL to allow a protocol to be specified during the SSL handshake. ALPN is used by the HTTP/2 protocol to * negotiate the protocol that the client and server will speak. Thus to accept a HTTP/2 connection, the * connector will be configured with {@link ConnectionFactory}s for "SSL-ALPN", "h2", "http/1.1" * with the default protocol being "SSL-ALPN". Thus a newly accepted connection uses "SSL-ALPN", which specifies a * SSLConnectionFactory with "ALPN" as the next protocol. Thus an SSL connection instance is created chained to an ALPN * connection instance. The ALPN connection then negotiates with the client to determined the next protocol, which * could be "h2" or the default of "http/1.1". Once the next protocol is determined, the ALPN connection * calls {@link #getConnectionFactory(String)} to create a connection instance that will replace the ALPN connection as * the connection chained to the SSL connection. * <h2>Acceptors</h2> * The connector will execute a number of acceptor tasks to the {@link Exception} service passed to the constructor. * The acceptor tasks run in a loop while the connector is running and repeatedly call the abstract {@link #accept(int)} method. * The implementation of the accept method must: * <ol> * <li>block waiting for new connections</li> * <li>accept the connection (eg socket accept)</li> * <li>perform any configuration of the connection (eg. socket configuration)</li> * <li>call the {@link #getDefaultConnectionFactory()} {@link ConnectionFactory#newConnection(Connector, org.eclipse.jetty.io.EndPoint)} * method to create a new Connection instance.</li> * </ol> * The default number of acceptor tasks is the minimum of 1 and the number of available CPUs divided by 8. Having more acceptors may reduce * the latency for servers that see a high rate of new connections (eg HTTP/1.0 without keep-alive). Typically the default is * sufficient for modern persistent protocols (HTTP/1.1, HTTP/2 etc.) */
@ManagedObject("Abstract implementation of the Connector Interface") public abstract class AbstractConnector extends ContainerLifeCycle implements Connector, Dumpable { protected static final Logger LOG = Log.getLogger(AbstractConnector.class); private final Locker _locker = new Locker(); private final Condition _setAccepting = _locker.newCondition(); private final Map<String, ConnectionFactory> _factories = new LinkedHashMap<>(); // Order is important on server side, so we use a LinkedHashMap private final Server _server; private final Executor _executor; private final Scheduler _scheduler; private final ByteBufferPool _byteBufferPool; private final Thread[] _acceptors; private final Set<EndPoint> _endpoints = Collections.newSetFromMap(new ConcurrentHashMap<>()); private final Set<EndPoint> _immutableEndPoints = Collections.unmodifiableSet(_endpoints); private final Graceful.Shutdown _shutdown = new Graceful.Shutdown(); private CountDownLatch _stopping; private long _idleTimeout = 30000; private String _defaultProtocol; private ConnectionFactory _defaultConnectionFactory; private String _name; private int _acceptorPriorityDelta = -2; private boolean _accepting = true; private ThreadPoolBudget.Lease _lease;
Params:
  • server – The server this connector will be added to. Must not be null.
  • executor – An executor for this connector or null to use the servers executor
  • scheduler – A scheduler for this connector or null to either a Scheduler set as a server bean or if none set, then a new ScheduledExecutorScheduler instance.
  • pool – A buffer pool for this connector or null to either a ByteBufferPool set as a server bean or none set, the new ArrayByteBufferPool instance.
  • acceptors – the number of acceptor threads to use, or -1 for a default value. If 0, then no acceptor threads will be launched and some other mechanism will need to be used to accept new connections.
  • factories – The Connection Factories to use.
/** * @param server The server this connector will be added to. Must not be null. * @param executor An executor for this connector or null to use the servers executor * @param scheduler A scheduler for this connector or null to either a {@link Scheduler} set as a server bean or if none set, then a new {@link ScheduledExecutorScheduler} instance. * @param pool A buffer pool for this connector or null to either a {@link ByteBufferPool} set as a server bean or none set, the new {@link ArrayByteBufferPool} instance. * @param acceptors the number of acceptor threads to use, or -1 for a default value. If 0, then no acceptor threads will be launched and some other mechanism will need to be used to accept new connections. * @param factories The Connection Factories to use. */
public AbstractConnector( Server server, Executor executor, Scheduler scheduler, ByteBufferPool pool, int acceptors, ConnectionFactory... factories) { _server = server; _executor = executor != null ? executor : _server.getThreadPool(); if (scheduler == null) scheduler = _server.getBean(Scheduler.class); _scheduler = scheduler != null ? scheduler : new ScheduledExecutorScheduler(String.format("Connector-Scheduler-%x", hashCode()), false); if (pool == null) pool = _server.getBean(ByteBufferPool.class); _byteBufferPool = pool != null ? pool : new ArrayByteBufferPool(); addBean(_server, false); addBean(_executor); if (executor == null) unmanage(_executor); // inherited from server addBean(_scheduler); addBean(_byteBufferPool); for (ConnectionFactory factory : factories) { addConnectionFactory(factory); } int cores = ProcessorUtils.availableProcessors(); if (acceptors < 0) acceptors = Math.max(1, Math.min(4, cores / 8)); if (acceptors > cores) LOG.warn("Acceptors should be <= availableProcessors: " + this); _acceptors = new Thread[acceptors]; } @Override public Server getServer() { return _server; } @Override public Executor getExecutor() { return _executor; } @Override public ByteBufferPool getByteBufferPool() { return _byteBufferPool; } @Override @ManagedAttribute("The connection idle timeout in milliseconds") public long getIdleTimeout() { return _idleTimeout; }

Sets the maximum Idle time for a connection, which roughly translates to the Socket.setSoTimeout(int) call, although with NIO implementations other mechanisms may be used to implement the timeout.

The max idle time is applied:

  • When waiting for a new message to be received on a connection
  • When waiting for a new message to be sent on a connection

This value is interpreted as the maximum time between some progress being made on the connection. So if a single byte is read or written, then the timeout is reset.

Params:
  • idleTimeout – the idle timeout
/** * <p>Sets the maximum Idle time for a connection, which roughly translates to the {@link Socket#setSoTimeout(int)} * call, although with NIO implementations other mechanisms may be used to implement the timeout.</p> * <p>The max idle time is applied:</p> * <ul> * <li>When waiting for a new message to be received on a connection</li> * <li>When waiting for a new message to be sent on a connection</li> * </ul> * <p>This value is interpreted as the maximum time between some progress being made on the connection. * So if a single byte is read or written, then the timeout is reset.</p> * * @param idleTimeout the idle timeout */
public void setIdleTimeout(long idleTimeout) { _idleTimeout = idleTimeout; }
Returns:Returns the number of acceptor threads.
/** * @return Returns the number of acceptor threads. */
@ManagedAttribute("number of acceptor threads") public int getAcceptors() { return _acceptors.length; } @Override protected void doStart() throws Exception { _shutdown.cancel(); if (_defaultProtocol == null) throw new IllegalStateException("No default protocol for " + this); _defaultConnectionFactory = getConnectionFactory(_defaultProtocol); if (_defaultConnectionFactory == null) throw new IllegalStateException("No protocol factory for default protocol '" + _defaultProtocol + "' in " + this); SslConnectionFactory ssl = getConnectionFactory(SslConnectionFactory.class); if (ssl != null) { String next = ssl.getNextProtocol(); ConnectionFactory cf = getConnectionFactory(next); if (cf == null) throw new IllegalStateException("No protocol factory for SSL next protocol: '" + next + "' in " + this); } _lease = ThreadPoolBudget.leaseFrom(getExecutor(), this, _acceptors.length); super.doStart(); _stopping = new CountDownLatch(_acceptors.length); for (int i = 0; i < _acceptors.length; i++) { Acceptor a = new Acceptor(i); addBean(a); getExecutor().execute(a); } LOG.info("Started {}", this); } protected void interruptAcceptors() { try (Locker.Lock lock = _locker.lock()) { for (Thread thread : _acceptors) { if (thread != null) thread.interrupt(); } } } @Override public Future<Void> shutdown() { return _shutdown.shutdown(); } @Override public boolean isShutdown() { return _shutdown.isShutdown(); } @Override protected void doStop() throws Exception { if (_lease != null) _lease.close(); // Tell the acceptors we are stopping interruptAcceptors(); // If we have a stop timeout long stopTimeout = getStopTimeout(); CountDownLatch stopping = _stopping; if (stopTimeout > 0 && stopping != null && getAcceptors() > 0) stopping.await(stopTimeout, TimeUnit.MILLISECONDS); _stopping = null; super.doStop(); for (Acceptor a : getBeans(Acceptor.class)) { removeBean(a); } LOG.info("Stopped {}", this); } public void join() throws InterruptedException { join(0); } public void join(long timeout) throws InterruptedException { try (Locker.Lock lock = _locker.lock()) { for (Thread thread : _acceptors) { if (thread != null) thread.join(timeout); } } } protected abstract void accept(int acceptorID) throws IOException, InterruptedException;
Returns:Is the connector accepting new connections
/** * @return Is the connector accepting new connections */
public boolean isAccepting() { try (Locker.Lock lock = _locker.lock()) { return _accepting; } } public void setAccepting(boolean accepting) { try (Locker.Lock lock = _locker.lock()) { _accepting = accepting; _setAccepting.signalAll(); } } @Override public ConnectionFactory getConnectionFactory(String protocol) { try (Locker.Lock lock = _locker.lock()) { return _factories.get(StringUtil.asciiToLowerCase(protocol)); } } @Override public <T> T getConnectionFactory(Class<T> factoryType) { try (Locker.Lock lock = _locker.lock()) { for (ConnectionFactory f : _factories.values()) { if (factoryType.isAssignableFrom(f.getClass())) return (T)f; } return null; } } public void addConnectionFactory(ConnectionFactory factory) { if (isRunning()) throw new IllegalStateException(getState()); Set<ConnectionFactory> toRemove = new HashSet<>(); for (String key : factory.getProtocols()) { key = StringUtil.asciiToLowerCase(key); ConnectionFactory old = _factories.remove(key); if (old != null) { if (old.getProtocol().equals(_defaultProtocol)) _defaultProtocol = null; toRemove.add(old); } _factories.put(key, factory); } // keep factories still referenced for (ConnectionFactory f : _factories.values()) { toRemove.remove(f); } // remove old factories for (ConnectionFactory old : toRemove) { removeBean(old); if (LOG.isDebugEnabled()) LOG.debug("{} removed {}", this, old); } // add new Bean addBean(factory); if (_defaultProtocol == null) _defaultProtocol = factory.getProtocol(); if (LOG.isDebugEnabled()) LOG.debug("{} added {}", this, factory); } public void addFirstConnectionFactory(ConnectionFactory factory) { if (isRunning()) throw new IllegalStateException(getState()); List<ConnectionFactory> existings = new ArrayList<>(_factories.values()); _factories.clear(); addConnectionFactory(factory); for (ConnectionFactory existing : existings) { addConnectionFactory(existing); } _defaultProtocol = factory.getProtocol(); } public void addIfAbsentConnectionFactory(ConnectionFactory factory) { if (isRunning()) throw new IllegalStateException(getState()); String key = StringUtil.asciiToLowerCase(factory.getProtocol()); if (_factories.containsKey(key)) { if (LOG.isDebugEnabled()) LOG.debug("{} addIfAbsent ignored {}", this, factory); } else { _factories.put(key, factory); addBean(factory); if (_defaultProtocol == null) _defaultProtocol = factory.getProtocol(); if (LOG.isDebugEnabled()) LOG.debug("{} addIfAbsent added {}", this, factory); } } public ConnectionFactory removeConnectionFactory(String protocol) { if (isRunning()) throw new IllegalStateException(getState()); ConnectionFactory factory = _factories.remove(StringUtil.asciiToLowerCase(protocol)); removeBean(factory); return factory; } @Override public Collection<ConnectionFactory> getConnectionFactories() { return _factories.values(); } public void setConnectionFactories(Collection<ConnectionFactory> factories) { if (isRunning()) throw new IllegalStateException(getState()); List<ConnectionFactory> existing = new ArrayList<>(_factories.values()); for (ConnectionFactory factory : existing) { removeConnectionFactory(factory.getProtocol()); } for (ConnectionFactory factory : factories) { if (factory != null) addConnectionFactory(factory); } } @ManagedAttribute("The priority delta to apply to acceptor threads") public int getAcceptorPriorityDelta() { return _acceptorPriorityDelta; }
Set the acceptor thread priority delta.

This allows the acceptor thread to run at a different priority. Typically this would be used to lower the priority to give preference to handling previously accepted connections rather than accepting new connections

Params:
  • acceptorPriorityDelta – the acceptor priority delta
/** * Set the acceptor thread priority delta. * <p>This allows the acceptor thread to run at a different priority. * Typically this would be used to lower the priority to give preference * to handling previously accepted connections rather than accepting * new connections</p> * * @param acceptorPriorityDelta the acceptor priority delta */
public void setAcceptorPriorityDelta(int acceptorPriorityDelta) { int old = _acceptorPriorityDelta; _acceptorPriorityDelta = acceptorPriorityDelta; if (old != acceptorPriorityDelta && isStarted()) { for (Thread thread : _acceptors) { thread.setPriority(Math.max(Thread.MIN_PRIORITY, Math.min(Thread.MAX_PRIORITY, thread.getPriority() - old + acceptorPriorityDelta))); } } } @Override @ManagedAttribute("Protocols supported by this connector") public List<String> getProtocols() { return new ArrayList<>(_factories.keySet()); } public void clearConnectionFactories() { if (isRunning()) throw new IllegalStateException(getState()); _factories.clear(); } @ManagedAttribute("This connector's default protocol") public String getDefaultProtocol() { return _defaultProtocol; } public void setDefaultProtocol(String defaultProtocol) { _defaultProtocol = StringUtil.asciiToLowerCase(defaultProtocol); if (isRunning()) _defaultConnectionFactory = getConnectionFactory(_defaultProtocol); } @Override public ConnectionFactory getDefaultConnectionFactory() { if (isStarted()) return _defaultConnectionFactory; return getConnectionFactory(_defaultProtocol); } protected boolean handleAcceptFailure(Throwable ex) { if (isRunning()) { if (ex instanceof InterruptedException) { LOG.debug(ex); return true; } if (ex instanceof ClosedByInterruptException) { LOG.debug(ex); return false; } LOG.warn(ex); try { // Arbitrary sleep to avoid spin looping. // Subclasses may decide for a different // sleep policy or closing the connector. Thread.sleep(1000); return true; } catch (Throwable x) { LOG.ignore(x); } return false; } else { LOG.ignore(ex); return false; } } private class Acceptor implements Runnable { private final int _id; private String _name; private Acceptor(int id) { _id = id; } @Override public void run() { final Thread thread = Thread.currentThread(); String name = thread.getName(); _name = String.format("%s-acceptor-%d@%x-%s", name, _id, hashCode(), AbstractConnector.this.toString()); thread.setName(_name); int priority = thread.getPriority(); if (_acceptorPriorityDelta != 0) thread.setPriority(Math.max(Thread.MIN_PRIORITY, Math.min(Thread.MAX_PRIORITY, priority + _acceptorPriorityDelta))); _acceptors[_id] = thread; try { while (isRunning()) { try (Locker.Lock lock = _locker.lock()) { if (!_accepting && isRunning()) { _setAccepting.await(); continue; } } catch (InterruptedException e) { continue; } try { accept(_id); } catch (Throwable x) { if (!handleAcceptFailure(x)) break; } } } finally { thread.setName(name); if (_acceptorPriorityDelta != 0) thread.setPriority(priority); synchronized (AbstractConnector.this) { _acceptors[_id] = null; } CountDownLatch stopping = _stopping; if (stopping != null) stopping.countDown(); } } @Override public String toString() { String name = _name; if (name == null) return String.format("acceptor-%d@%x", _id, hashCode()); return name; } } @Override public Collection<EndPoint> getConnectedEndPoints() { return _immutableEndPoints; } protected void onEndPointOpened(EndPoint endp) { _endpoints.add(endp); } protected void onEndPointClosed(EndPoint endp) { _endpoints.remove(endp); } @Override public Scheduler getScheduler() { return _scheduler; } @Override public String getName() { return _name; }
Set a connector name. A context may be configured with virtual hosts in the form "@contextname" and will only serve requests from the named connector,
Params:
  • name – A connector name.
/** * Set a connector name. A context may be configured with * virtual hosts in the form "@contextname" and will only serve * requests from the named connector, * * @param name A connector name. */
public void setName(String name) { _name = name; } @Override public String toString() { return String.format("%s@%x{%s,%s}", _name == null ? getClass().getSimpleName() : _name, hashCode(), getDefaultProtocol(), getProtocols()); } }