/*
 * 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.tomcat.util.net;

import java.io.IOException;
import java.io.OutputStreamWriter;
import java.net.InetAddress;
import java.net.InetSocketAddress;
import java.net.NetworkInterface;
import java.net.SocketException;
import java.util.ArrayList;
import java.util.Enumeration;
import java.util.HashMap;
import java.util.List;
import java.util.Set;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import java.util.concurrent.Executor;
import java.util.concurrent.RejectedExecutionException;
import java.util.concurrent.ScheduledExecutorService;
import java.util.concurrent.ScheduledThreadPoolExecutor;
import java.util.concurrent.TimeUnit;

import javax.management.MalformedObjectNameException;
import javax.management.ObjectName;

import org.apache.juli.logging.Log;
import org.apache.tomcat.util.ExceptionUtils;
import org.apache.tomcat.util.IntrospectionUtils;
import org.apache.tomcat.util.collections.SynchronizedStack;
import org.apache.tomcat.util.modeler.Registry;
import org.apache.tomcat.util.net.Acceptor.AcceptorState;
import org.apache.tomcat.util.res.StringManager;
import org.apache.tomcat.util.threads.LimitLatch;
import org.apache.tomcat.util.threads.ResizableExecutor;
import org.apache.tomcat.util.threads.TaskQueue;
import org.apache.tomcat.util.threads.TaskThreadFactory;
import org.apache.tomcat.util.threads.ThreadPoolExecutor;

Author:
Mladen Turk, Remy Maucherat
Type parameters:
<S> – The type used by the socket wrapper associated with this endpoint.
           May be the same as U.
<U> – The type of the underlying socket used by this endpoint. May be
           the same as S./**
 * @param <S> The type used by the socket wrapper associated with this endpoint.
 *            May be the same as U.
 * @param <U> The type of the underlying socket used by this endpoint. May be
 *            the same as S.
 *
 * @author Mladen Turk
 * @author Remy Maucherat
 */
public abstract class AbstractEndpoint<S,U> {

    // -------------------------------------------------------------- Constants

    protected static final StringManager sm = StringManager.getManager(AbstractEndpoint.class);

    public static interface Handler<S> {

        
Different types of socket states to react upon.
/**
         * Different types of socket states to react upon.
         */
        public enum SocketState {
            // TODO Add a new state to the AsyncStateMachine and remove
            //      ASYNC_END (if possible)
            OPEN, CLOSED, LONG, ASYNC_END, SENDFILE, UPGRADING, UPGRADED, SUSPENDED
        }


        
Process the provided socket with the given current status.
Params:
socket – The socket to process
status – The current socket status
Returns:
The state of the socket after processing/**
         * Process the provided socket with the given current status.
         *
         * @param socket The socket to process
         * @param status The current socket status
         *
         * @return The state of the socket after processing
         */
        public SocketState process(SocketWrapperBase<S> socket,
                SocketEvent status);


        
Obtain the GlobalRequestProcessor associated with the handler.
Returns:
the GlobalRequestProcessor/**
         * Obtain the GlobalRequestProcessor associated with the handler.
         *
         * @return the GlobalRequestProcessor
         */
        public Object getGlobal();


        
Obtain the currently open sockets.
Returns:
The sockets for which the handler is tracking a currently
        open connection/**
         * Obtain the currently open sockets.
         *
         * @return The sockets for which the handler is tracking a currently
         *         open connection
         */
        public Set<S> getOpenSockets();

        
Release any resources associated with the given SocketWrapper.
Params:
socketWrapper – The socketWrapper to release resources for/**
         * Release any resources associated with the given SocketWrapper.
         *
         * @param socketWrapper The socketWrapper to release resources for
         */
        public void release(SocketWrapperBase<S> socketWrapper);


        
Inform the handler that the endpoint has stopped accepting any new
connections. Typically, the endpoint will be stopped shortly
afterwards but it is possible that the endpoint will be resumed so
the handler should not assume that a stop will follow.
/**
         * Inform the handler that the endpoint has stopped accepting any new
         * connections. Typically, the endpoint will be stopped shortly
         * afterwards but it is possible that the endpoint will be resumed so
         * the handler should not assume that a stop will follow.
         */
        public void pause();


        
Recycle resources associated with the handler.
/**
         * Recycle resources associated with the handler.
         */
        public void recycle();
    }

    protected enum BindState {
        UNBOUND, BOUND_ON_INIT, BOUND_ON_START, SOCKET_CLOSED_ON_STOP
    }


    public static long toTimeout(long timeout) {
        // Many calls can't do infinite timeout so use Long.MAX_VALUE if timeout is <= 0
        return (timeout > 0) ? timeout : Long.MAX_VALUE;
    }

    // ----------------------------------------------------------------- Fields

    
Running state of the endpoint.
/**
     * Running state of the endpoint.
     */
    protected volatile boolean running = false;


    
Will be set to true whenever the endpoint is paused.
/**
     * Will be set to true whenever the endpoint is paused.
     */
    protected volatile boolean paused = false;

    
Are we using an internal executor
/**
     * Are we using an internal executor
     */
    protected volatile boolean internalExecutor = true;


    
counter for nr of connections handled by an endpoint
/**
     * counter for nr of connections handled by an endpoint
     */
    private volatile LimitLatch connectionLimitLatch = null;

    
Socket properties
/**
     * Socket properties
     */
    protected final SocketProperties socketProperties = new SocketProperties();
    public SocketProperties getSocketProperties() {
        return socketProperties;
    }

    
Thread used to accept new connections and pass them to worker threads.
/**
     * Thread used to accept new connections and pass them to worker threads.
     */
    protected Acceptor<U> acceptor;

    
Cache for SocketProcessor objects
/**
     * Cache for SocketProcessor objects
     */
    protected SynchronizedStack<SocketProcessorBase<S>> processorCache;

    private ObjectName oname = null;

    // ----------------------------------------------------------------- Properties

    private String defaultSSLHostConfigName = SSLHostConfig.DEFAULT_SSL_HOST_NAME;
    public String getDefaultSSLHostConfigName() {
        return defaultSSLHostConfigName;
    }
    public void setDefaultSSLHostConfigName(String defaultSSLHostConfigName) {
        this.defaultSSLHostConfigName = defaultSSLHostConfigName;
    }


    protected ConcurrentMap<String,SSLHostConfig> sslHostConfigs = new ConcurrentHashMap<>();
    
Add the given SSL Host configuration.
Params:
sslHostConfig – The configuration to add
Throws:
IllegalArgumentException – If the host name is not valid or if a
                                 configuration has already been provided
                                 for that host/**
     * Add the given SSL Host configuration.
     *
     * @param sslHostConfig The configuration to add
     *
     * @throws IllegalArgumentException If the host name is not valid or if a
     *                                  configuration has already been provided
     *                                  for that host
     */
    public void addSslHostConfig(SSLHostConfig sslHostConfig) throws IllegalArgumentException {
        addSslHostConfig(sslHostConfig, false);
    }
    
Add the given SSL Host configuration, optionally replacing the existing
configuration for the given host.
Params:
sslHostConfig – The configuration to add
replace –  If true replacement of an existing configuration is permitted, otherwise any such attempted replacement will trigger an exception
Throws:
IllegalArgumentException – If the host name is not valid or if a
                                 configuration has already been provided
                                 for that host and replacement is not
                                 allowed/**
     * Add the given SSL Host configuration, optionally replacing the existing
     * configuration for the given host.
     *
     * @param sslHostConfig The configuration to add
     * @param replace       If {@code true} replacement of an existing
     *                      configuration is permitted, otherwise any such
     *                      attempted replacement will trigger an exception
     *
     * @throws IllegalArgumentException If the host name is not valid or if a
     *                                  configuration has already been provided
     *                                  for that host and replacement is not
     *                                  allowed
     */
    public void addSslHostConfig(SSLHostConfig sslHostConfig, boolean replace) throws IllegalArgumentException {
        String key = sslHostConfig.getHostName();
        if (key == null || key.length() == 0) {
            throw new IllegalArgumentException(sm.getString("endpoint.noSslHostName"));
        }
        if (bindState != BindState.UNBOUND && bindState != BindState.SOCKET_CLOSED_ON_STOP &&
                isSSLEnabled()) {
            try {
                createSSLContext(sslHostConfig);
            } catch (Exception e) {
                throw new IllegalArgumentException(e);
            }
        }
        if (replace) {
            SSLHostConfig previous = sslHostConfigs.put(key, sslHostConfig);
            if (previous != null) {
                unregisterJmx(sslHostConfig);
            }
            registerJmx(sslHostConfig);

            // Do not release any SSLContexts associated with a replaced
            // SSLHostConfig. They may still be in used by existing connections
            // and releasing them would break the connection at best. Let GC
            // handle the clean up.
        } else {
            SSLHostConfig duplicate = sslHostConfigs.putIfAbsent(key, sslHostConfig);
            if (duplicate != null) {
                releaseSSLContext(sslHostConfig);
                throw new IllegalArgumentException(sm.getString("endpoint.duplicateSslHostName", key));
            }
            registerJmx(sslHostConfig);
        }
    }
    
Removes the SSL host configuration for the given host name, if such a
configuration exists.
Params:
hostName –  The host name associated with the SSL host configuration
                 to remove
Returns:
 The SSL host configuration that was removed, if any/**
     * Removes the SSL host configuration for the given host name, if such a
     * configuration exists.
     *
     * @param hostName  The host name associated with the SSL host configuration
     *                  to remove
     *
     * @return  The SSL host configuration that was removed, if any
     */
    public SSLHostConfig removeSslHostConfig(String hostName) {
        if (hostName == null) {
            return null;
        }
        // Host names are case insensitive
        if (hostName.equalsIgnoreCase(getDefaultSSLHostConfigName())) {
            throw new IllegalArgumentException(
                    sm.getString("endpoint.removeDefaultSslHostConfig", hostName));
        }
        SSLHostConfig sslHostConfig = sslHostConfigs.remove(hostName);
        unregisterJmx(sslHostConfig);
        return sslHostConfig;
    }
    
Re-read the configuration files for the SSL host and replace the existing
SSL configuration with the updated settings. Note this replacement will
happen even if the settings remain unchanged.
Params:
hostName – The SSL host for which the configuration should be
                reloaded. This must match a current SSL host/**
     * Re-read the configuration files for the SSL host and replace the existing
     * SSL configuration with the updated settings. Note this replacement will
     * happen even if the settings remain unchanged.
     *
     * @param hostName The SSL host for which the configuration should be
     *                 reloaded. This must match a current SSL host
     */
    public void reloadSslHostConfig(String hostName) {
        SSLHostConfig sslHostConfig = sslHostConfigs.get(hostName);
        if (sslHostConfig == null) {
            throw new IllegalArgumentException(
                    sm.getString("endpoint.unknownSslHostName", hostName));
        }
        addSslHostConfig(sslHostConfig, true);
    }
    
Re-read the configuration files for all SSL hosts and replace the
existing SSL configuration with the updated settings. Note this
replacement will happen even if the settings remain unchanged.
/**
     * Re-read the configuration files for all SSL hosts and replace the
     * existing SSL configuration with the updated settings. Note this
     * replacement will happen even if the settings remain unchanged.
     */
    public void reloadSslHostConfigs() {
        for (String hostName : sslHostConfigs.keySet()) {
            reloadSslHostConfig(hostName);
        }
    }
    public SSLHostConfig[] findSslHostConfigs() {
        return sslHostConfigs.values().toArray(new SSLHostConfig[0]);
    }

    
Create the SSLContextfor the the given SSLHostConfig.
Params:
sslHostConfig – The SSLHostConfig for which the SSLContext should be
                     created
Throws:
Exception – If the SSLContext cannot be created for the given
                  SSLHostConfig/**
     * Create the SSLContextfor the the given SSLHostConfig.
     *
     * @param sslHostConfig The SSLHostConfig for which the SSLContext should be
     *                      created
     * @throws Exception If the SSLContext cannot be created for the given
     *                   SSLHostConfig
     */
    protected abstract void createSSLContext(SSLHostConfig sslHostConfig) throws Exception;


    protected void destroySsl() throws Exception {
        if (isSSLEnabled()) {
            for (SSLHostConfig sslHostConfig : sslHostConfigs.values()) {
                releaseSSLContext(sslHostConfig);
            }
        }
    }


    
Release the SSLContext, if any, associated with the SSLHostConfig.
Params:
sslHostConfig – The SSLHostConfig for which the SSLContext should be
                     released/**
     * Release the SSLContext, if any, associated with the SSLHostConfig.
     *
     * @param sslHostConfig The SSLHostConfig for which the SSLContext should be
     *                      released
     */
    protected void releaseSSLContext(SSLHostConfig sslHostConfig) {
        for (SSLHostConfigCertificate certificate : sslHostConfig.getCertificates(true)) {
            if (certificate.getSslContext() != null) {
                SSLContext sslContext = certificate.getSslContext();
                if (sslContext != null) {
                    sslContext.destroy();
                }
            }
        }
    }



    protected SSLHostConfig getSSLHostConfig(String sniHostName) {
        SSLHostConfig result = null;

        if (sniHostName != null) {
            // First choice - direct match
            result = sslHostConfigs.get(sniHostName);
            if (result != null) {
                return result;
            }
            // Second choice, wildcard match
            int indexOfDot = sniHostName.indexOf('.');
            if (indexOfDot > -1) {
                result = sslHostConfigs.get("*" + sniHostName.substring(indexOfDot));
            }
        }

        // Fall-back. Use the default
        if (result == null) {
            result = sslHostConfigs.get(getDefaultSSLHostConfigName());
        }
        if (result == null) {
            // Should never happen.
            throw new IllegalStateException();
        }
        return result;
    }


    
Has the user requested that send file be used where possible?
/**
     * Has the user requested that send file be used where possible?
     */
    private boolean useSendfile = true;
    public boolean getUseSendfile() {
        return useSendfile;
    }
    public void setUseSendfile(boolean useSendfile) {
        this.useSendfile = useSendfile;
    }


    
Time to wait for the internal executor (if used) to terminate when the
endpoint is stopped in milliseconds. Defaults to 5000 (5 seconds).
/**
     * Time to wait for the internal executor (if used) to terminate when the
     * endpoint is stopped in milliseconds. Defaults to 5000 (5 seconds).
     */
    private long executorTerminationTimeoutMillis = 5000;

    public long getExecutorTerminationTimeoutMillis() {
        return executorTerminationTimeoutMillis;
    }

    public void setExecutorTerminationTimeoutMillis(
            long executorTerminationTimeoutMillis) {
        this.executorTerminationTimeoutMillis = executorTerminationTimeoutMillis;
    }


    
Acceptor thread count.
/**
     * Acceptor thread count.
     */
    protected int acceptorThreadCount = 1;

    
NO-OP.
Params:
acceptorThreadCount – Unused
Deprecated:
Will be removed in Tomcat 10./**
     * NO-OP.
     *
     * @param acceptorThreadCount Unused
     *
     * @deprecated Will be removed in Tomcat 10.
     */
    @Deprecated
    public void setAcceptorThreadCount(int acceptorThreadCount) {}

    
Always returns 1.
Returns:
Always 1.
Deprecated:
Will be removed in Tomcat 10./**
     * Always returns 1.
     *
     * @return Always 1.
     *
     * @deprecated Will be removed in Tomcat 10.
     */
    @Deprecated
    public int getAcceptorThreadCount() { return 1; }


    
Priority of the acceptor threads.
/**
     * Priority of the acceptor threads.
     */
    protected int acceptorThreadPriority = Thread.NORM_PRIORITY;
    public void setAcceptorThreadPriority(int acceptorThreadPriority) {
        this.acceptorThreadPriority = acceptorThreadPriority;
    }
    public int getAcceptorThreadPriority() { return acceptorThreadPriority; }


    private int maxConnections = 10000;
    public void setMaxConnections(int maxCon) {
        this.maxConnections = maxCon;
        LimitLatch latch = this.connectionLimitLatch;
        if (latch != null) {
            // Update the latch that enforces this
            if (maxCon == -1) {
                releaseConnectionLatch();
            } else {
                latch.setLimit(maxCon);
            }
        } else if (maxCon > 0) {
            initializeConnectionLatch();
        }
    }

    public int  getMaxConnections() { return this.maxConnections; }

    
Return the current count of connections handled by this endpoint, if the
connections are counted (which happens when the maximum count of
connections is limited), or -1 if they are not. This
property is added here so that this value can be inspected through JMX.
It is visible on "ThreadPool" MBean.
The count is incremented by the Acceptor before it tries to accept a
new connection. Until the limit is reached and thus the count cannot be
incremented,  this value is more by 1 (the count of acceptors) than the
actual count of connections that are being served.
Returns:
The count/**
     * Return the current count of connections handled by this endpoint, if the
     * connections are counted (which happens when the maximum count of
     * connections is limited), or <code>-1</code> if they are not. This
     * property is added here so that this value can be inspected through JMX.
     * It is visible on "ThreadPool" MBean.
     *
     * <p>The count is incremented by the Acceptor before it tries to accept a
     * new connection. Until the limit is reached and thus the count cannot be
     * incremented,  this value is more by 1 (the count of acceptors) than the
     * actual count of connections that are being served.
     *
     * @return The count
     */
    public long getConnectionCount() {
        LimitLatch latch = connectionLimitLatch;
        if (latch != null) {
            return latch.getCount();
        }
        return -1;
    }

    
External Executor based thread pool.
/**
     * External Executor based thread pool.
     */
    private Executor executor = null;
    public void setExecutor(Executor executor) {
        this.executor = executor;
        this.internalExecutor = (executor == null);
    }
    public Executor getExecutor() { return executor; }


    
External Executor based thread pool for utility tasks.
/**
     * External Executor based thread pool for utility tasks.
     */
    private ScheduledExecutorService utilityExecutor = null;
    public void setUtilityExecutor(ScheduledExecutorService utilityExecutor) {
        this.utilityExecutor = utilityExecutor;
    }
    public ScheduledExecutorService getUtilityExecutor() {
        if (utilityExecutor == null) {
            getLog().warn(sm.getString("endpoint.warn.noUtilityExecutor"));
            utilityExecutor = new ScheduledThreadPoolExecutor(1);
        }
        return utilityExecutor;
    }


    
Server socket port.
/**
     * Server socket port.
     */
    private int port = -1;
    public int getPort() { return port; }
    public void setPort(int port ) { this.port=port; }


    private int portOffset = 0;
    public int getPortOffset() { return portOffset; }
    public void setPortOffset(int portOffset ) {
        if (portOffset < 0) {
            throw new IllegalArgumentException(
                    sm.getString("endpoint.portOffset.invalid", Integer.valueOf(portOffset)));
        }
        this.portOffset = portOffset;
    }


    public int getPortWithOffset() {
        // Zero is a special case and negative values are invalid
        int port = getPort();
        if (port > 0) {
            return port + getPortOffset();
        }
        return port;
    }


    public final int getLocalPort() {
        try {
            InetSocketAddress localAddress = getLocalAddress();
            if (localAddress == null) {
                return -1;
            }
            return localAddress.getPort();
        } catch (IOException ioe) {
            return -1;
        }
    }


    
Address for the server socket.
/**
     * Address for the server socket.
     */
    private InetAddress address;
    public InetAddress getAddress() { return address; }
    public void setAddress(InetAddress address) { this.address = address; }


    
Obtain the network address the server socket is bound to. This primarily
exists to enable the correct address to be used when unlocking the server
socket since it removes the guess-work involved if no address is
specifically set.
Throws:
IOException – If there is a problem determining the currently bound
                    socket
Returns:
The network address that the server socket is listening on or
        null if the server socket is not currently bound./**
     * Obtain the network address the server socket is bound to. This primarily
     * exists to enable the correct address to be used when unlocking the server
     * socket since it removes the guess-work involved if no address is
     * specifically set.
     *
     * @return The network address that the server socket is listening on or
     *         null if the server socket is not currently bound.
     *
     * @throws IOException If there is a problem determining the currently bound
     *                     socket
     */
    protected abstract InetSocketAddress getLocalAddress() throws IOException;


    
Allows the server developer to specify the acceptCount (backlog) that
should be used for server sockets. By default, this value
is 100.
/**
     * Allows the server developer to specify the acceptCount (backlog) that
     * should be used for server sockets. By default, this value
     * is 100.
     */
    private int acceptCount = 100;
    public void setAcceptCount(int acceptCount) { if (acceptCount > 0) this.acceptCount = acceptCount; }
    public int getAcceptCount() { return acceptCount; }

    
Controls when the Endpoint binds the port. true, the default binds the port on init() and unbinds it on destroy(). If set to false the port is bound on start() and unbound on stop(). /**
     * Controls when the Endpoint binds the port. <code>true</code>, the default
     * binds the port on {@link #init()} and unbinds it on {@link #destroy()}.
     * If set to <code>false</code> the port is bound on {@link #start()} and
     * unbound on {@link #stop()}.
     */
    private boolean bindOnInit = true;
    public boolean getBindOnInit() { return bindOnInit; }
    public void setBindOnInit(boolean b) { this.bindOnInit = b; }
    private volatile BindState bindState = BindState.UNBOUND;

    
Keepalive timeout, if not set the soTimeout is used.
/**
     * Keepalive timeout, if not set the soTimeout is used.
     */
    private Integer keepAliveTimeout = null;
    public int getKeepAliveTimeout() {
        if (keepAliveTimeout == null) {
            return getConnectionTimeout();
        } else {
            return keepAliveTimeout.intValue();
        }
    }
    public void setKeepAliveTimeout(int keepAliveTimeout) {
        this.keepAliveTimeout = Integer.valueOf(keepAliveTimeout);
    }


    
Socket TCP no delay.
Returns:
The current TCP no delay setting for sockets created by this
        endpoint/**
     * Socket TCP no delay.
     *
     * @return The current TCP no delay setting for sockets created by this
     *         endpoint
     */
    public boolean getTcpNoDelay() { return socketProperties.getTcpNoDelay();}
    public void setTcpNoDelay(boolean tcpNoDelay) { socketProperties.setTcpNoDelay(tcpNoDelay); }


    
Socket linger.
Returns:
The current socket linger time for sockets created by this
        endpoint/**
     * Socket linger.
     *
     * @return The current socket linger time for sockets created by this
     *         endpoint
     */
    public int getConnectionLinger() { return socketProperties.getSoLingerTime(); }
    public void setConnectionLinger(int connectionLinger) {
        socketProperties.setSoLingerTime(connectionLinger);
        socketProperties.setSoLingerOn(connectionLinger>=0);
    }


    
Socket timeout.
Returns:
The current socket timeout for sockets created by this endpoint/**
     * Socket timeout.
     *
     * @return The current socket timeout for sockets created by this endpoint
     */
    public int getConnectionTimeout() { return socketProperties.getSoTimeout(); }
    public void setConnectionTimeout(int soTimeout) { socketProperties.setSoTimeout(soTimeout); }

    
SSL engine.
/**
     * SSL engine.
     */
    private boolean SSLEnabled = false;
    public boolean isSSLEnabled() { return SSLEnabled; }
    public void setSSLEnabled(boolean SSLEnabled) { this.SSLEnabled = SSLEnabled; }

    
Identifies if the endpoint supports ALPN. Note that a return value of
true implies that isSSLEnabled() will also return true.
Returns:
true if the endpoint supports ALPN in its current
        configuration, otherwise false./**
     * Identifies if the endpoint supports ALPN. Note that a return value of
     * <code>true</code> implies that {@link #isSSLEnabled()} will also return
     * <code>true</code>.
     *
     * @return <code>true</code> if the endpoint supports ALPN in its current
     *         configuration, otherwise <code>false</code>.
     */
    public abstract boolean isAlpnSupported();

    private int minSpareThreads = 10;
    public void setMinSpareThreads(int minSpareThreads) {
        this.minSpareThreads = minSpareThreads;
        Executor executor = this.executor;
        if (internalExecutor && executor instanceof java.util.concurrent.ThreadPoolExecutor) {
            // The internal executor should always be an instance of
            // j.u.c.ThreadPoolExecutor but it may be null if the endpoint is
            // not running.
            // This check also avoids various threading issues.
            ((java.util.concurrent.ThreadPoolExecutor) executor).setCorePoolSize(minSpareThreads);
        }
    }
    public int getMinSpareThreads() {
        return Math.min(getMinSpareThreadsInternal(), getMaxThreads());
    }
    private int getMinSpareThreadsInternal() {
        if (internalExecutor) {
            return minSpareThreads;
        } else {
            return -1;
        }
    }


    
Maximum amount of worker threads.
/**
     * Maximum amount of worker threads.
     */
    private int maxThreads = 200;
    public void setMaxThreads(int maxThreads) {
        this.maxThreads = maxThreads;
        Executor executor = this.executor;
        if (internalExecutor && executor instanceof java.util.concurrent.ThreadPoolExecutor) {
            // The internal executor should always be an instance of
            // j.u.c.ThreadPoolExecutor but it may be null if the endpoint is
            // not running.
            // This check also avoids various threading issues.
            ((java.util.concurrent.ThreadPoolExecutor) executor).setMaximumPoolSize(maxThreads);
        }
    }
    public int getMaxThreads() {
        if (internalExecutor) {
            return maxThreads;
        } else {
            return -1;
        }
    }


    
Priority of the worker threads.
/**
     * Priority of the worker threads.
     */
    protected int threadPriority = Thread.NORM_PRIORITY;
    public void setThreadPriority(int threadPriority) {
        // Can't change this once the executor has started
        this.threadPriority = threadPriority;
    }
    public int getThreadPriority() {
        if (internalExecutor) {
            return threadPriority;
        } else {
            return -1;
        }
    }


    
Max keep alive requests
/**
     * Max keep alive requests
     */
    private int maxKeepAliveRequests=100; // as in Apache HTTPD server
    public int getMaxKeepAliveRequests() {
        return maxKeepAliveRequests;
    }
    public void setMaxKeepAliveRequests(int maxKeepAliveRequests) {
        this.maxKeepAliveRequests = maxKeepAliveRequests;
    }


    
Name of the thread pool, which will be used for naming child threads.
/**
     * Name of the thread pool, which will be used for naming child threads.
     */
    private String name = "TP";
    public void setName(String name) { this.name = name; }
    public String getName() { return name; }


    
Name of domain to use for JMX registration.
/**
     * Name of domain to use for JMX registration.
     */
    private String domain;
    public void setDomain(String domain) { this.domain = domain; }
    public String getDomain() { return domain; }


    
The default is true - the created threads will be
 in daemon mode. If set to false, the control thread
 will not be daemon - and will keep the process alive.
/**
     * The default is true - the created threads will be
     *  in daemon mode. If set to false, the control thread
     *  will not be daemon - and will keep the process alive.
     */
    private boolean daemon = true;
    public void setDaemon(boolean b) { daemon = b; }
    public boolean getDaemon() { return daemon; }


    
Expose asynchronous IO capability.
/**
     * Expose asynchronous IO capability.
     */
    private boolean useAsyncIO = true;
    public void setUseAsyncIO(boolean useAsyncIO) { this.useAsyncIO = useAsyncIO; }
    public boolean getUseAsyncIO() { return useAsyncIO; }


    protected abstract boolean getDeferAccept();


    protected final List<String> negotiableProtocols = new ArrayList<>();
    public void addNegotiatedProtocol(String negotiableProtocol) {
        negotiableProtocols.add(negotiableProtocol);
    }
    public boolean hasNegotiableProtocols() {
        return (negotiableProtocols.size() > 0);
    }


    
Handling of accepted sockets.
/**
     * Handling of accepted sockets.
     */
    private Handler<S> handler = null;
    public void setHandler(Handler<S> handler ) { this.handler = handler; }
    public Handler<S> getHandler() { return handler; }


    
Attributes provide a way for configuration to be passed to sub-components without the ProtocolHandler being aware of the properties available on those sub-components. /**
     * Attributes provide a way for configuration to be passed to sub-components
     * without the {@link org.apache.coyote.ProtocolHandler} being aware of the
     * properties available on those sub-components.
     */
    protected HashMap<String, Object> attributes = new HashMap<>();

    
Generic property setter called when a property for which a specific setter already exists within the ProtocolHandler needs to be made available to sub-components. The specific setter will call this method to populate the attributes. 
Params:
name –  Name of property to set
value – The value to set the property to/**
     * Generic property setter called when a property for which a specific
     * setter already exists within the
     * {@link org.apache.coyote.ProtocolHandler} needs to be made available to
     * sub-components. The specific setter will call this method to populate the
     * attributes.
     *
     * @param name  Name of property to set
     * @param value The value to set the property to
     */
    public void setAttribute(String name, Object value) {
        if (getLog().isTraceEnabled()) {
            getLog().trace(sm.getString("endpoint.setAttribute", name, value));
        }
        attributes.put(name, value);
    }
    
Used by sub-components to retrieve configuration information.
Params:
key – The name of the property for which the value should be
           retrieved
Returns:
The value of the specified property/**
     * Used by sub-components to retrieve configuration information.
     *
     * @param key The name of the property for which the value should be
     *            retrieved
     *
     * @return The value of the specified property
     */
    public Object getAttribute(String key) {
        Object value = attributes.get(key);
        if (getLog().isTraceEnabled()) {
            getLog().trace(sm.getString("endpoint.getAttribute", key, value));
        }
        return value;
    }



    public boolean setProperty(String name, String value) {
        setAttribute(name, value);
        final String socketName = "socket.";
        try {
            if (name.startsWith(socketName)) {
                return IntrospectionUtils.setProperty(socketProperties, name.substring(socketName.length()), value);
            } else {
                return IntrospectionUtils.setProperty(this,name,value,false);
            }
        }catch ( Exception x ) {
            getLog().error(sm.getString("endpoint.setAttributeError", name, value), x);
            return false;
        }
    }
    public String getProperty(String name) {
        String value = (String) getAttribute(name);
        final String socketName = "socket.";
        if (value == null && name.startsWith(socketName)) {
            Object result = IntrospectionUtils.getProperty(socketProperties, name.substring(socketName.length()));
            if (result != null) {
                value = result.toString();
            }
        }
        return value;
    }

    
Return the amount of threads that are managed by the pool.
Returns:
the amount of threads that are managed by the pool/**
     * Return the amount of threads that are managed by the pool.
     *
     * @return the amount of threads that are managed by the pool
     */
    public int getCurrentThreadCount() {
        Executor executor = this.executor;
        if (executor != null) {
            if (executor instanceof ThreadPoolExecutor) {
                return ((ThreadPoolExecutor) executor).getPoolSize();
            } else if (executor instanceof ResizableExecutor) {
                return ((ResizableExecutor) executor).getPoolSize();
            } else {
                return -1;
            }
        } else {
            return -2;
        }
    }

    
Return the amount of threads that are in use
Returns:
the amount of threads that are in use/**
     * Return the amount of threads that are in use
     *
     * @return the amount of threads that are in use
     */
    public int getCurrentThreadsBusy() {
        Executor executor = this.executor;
        if (executor != null) {
            if (executor instanceof ThreadPoolExecutor) {
                return ((ThreadPoolExecutor) executor).getActiveCount();
            } else if (executor instanceof ResizableExecutor) {
                return ((ResizableExecutor) executor).getActiveCount();
            } else {
                return -1;
            }
        } else {
            return -2;
        }
    }

    public boolean isRunning() {
        return running;
    }

    public boolean isPaused() {
        return paused;
    }


    public void createExecutor() {
        internalExecutor = true;
        TaskQueue taskqueue = new TaskQueue();
        TaskThreadFactory tf = new TaskThreadFactory(getName() + "-exec-", daemon, getThreadPriority());
        executor = new ThreadPoolExecutor(getMinSpareThreads(), getMaxThreads(), 60, TimeUnit.SECONDS,taskqueue, tf);
        taskqueue.setParent( (ThreadPoolExecutor) executor);
    }

    public void shutdownExecutor() {
        Executor executor = this.executor;
        if (executor != null && internalExecutor) {
            this.executor = null;
            if (executor instanceof ThreadPoolExecutor) {
                //this is our internal one, so we need to shut it down
                ThreadPoolExecutor tpe = (ThreadPoolExecutor) executor;
                tpe.shutdownNow();
                long timeout = getExecutorTerminationTimeoutMillis();
                if (timeout > 0) {
                    try {
                        tpe.awaitTermination(timeout, TimeUnit.MILLISECONDS);
                    } catch (InterruptedException e) {
                        // Ignore
                    }
                    if (tpe.isTerminating()) {
                        getLog().warn(sm.getString("endpoint.warn.executorShutdown", getName()));
                    }
                }
                TaskQueue queue = (TaskQueue) tpe.getQueue();
                queue.setParent(null);
            }
        }
    }

    
Unlock the server socket acceptor threads using bogus connections.
/**
     * Unlock the server socket acceptor threads using bogus connections.
     */
    private void unlockAccept() {
        // Only try to unlock the acceptor if it is necessary
        if (acceptor == null || acceptor.getState() != AcceptorState.RUNNING) {
            return;
        }

        InetSocketAddress unlockAddress = null;
        InetSocketAddress localAddress = null;
        try {
            localAddress = getLocalAddress();
        } catch (IOException ioe) {
            getLog().debug(sm.getString("endpoint.debug.unlock.localFail", getName()), ioe);
        }
        if (localAddress == null) {
            getLog().warn(sm.getString("endpoint.debug.unlock.localNone", getName()));
            return;
        }

        try {
            unlockAddress = getUnlockAddress(localAddress);

            try (java.net.Socket s = new java.net.Socket()) {
                int stmo = 2 * 1000;
                int utmo = 2 * 1000;
                if (getSocketProperties().getSoTimeout() > stmo)
                    stmo = getSocketProperties().getSoTimeout();
                if (getSocketProperties().getUnlockTimeout() > utmo)
                    utmo = getSocketProperties().getUnlockTimeout();
                s.setSoTimeout(stmo);
                s.setSoLinger(getSocketProperties().getSoLingerOn(),getSocketProperties().getSoLingerTime());
                if (getLog().isDebugEnabled()) {
                    getLog().debug("About to unlock socket for:" + unlockAddress);
                }
                s.connect(unlockAddress,utmo);
                if (getDeferAccept()) {
                    /*
                     * In the case of a deferred accept / accept filters we need to
                     * send data to wake up the accept. Send OPTIONS * to bypass
                     * even BSD accept filters. The Acceptor will discard it.
                     */
                    OutputStreamWriter sw;

                    sw = new OutputStreamWriter(s.getOutputStream(), "ISO-8859-1");
                    sw.write("OPTIONS * HTTP/1.0\r\n" +
                            "User-Agent: Tomcat wakeup connection\r\n\r\n");
                    sw.flush();
                }
                if (getLog().isDebugEnabled()) {
                    getLog().debug("Socket unlock completed for:" + unlockAddress);
                }
            }
            // Wait for upto 1000ms acceptor threads to unlock
            long waitLeft = 1000;
            while (waitLeft > 0 &&
                    acceptor.getState() == AcceptorState.RUNNING) {
                Thread.sleep(5);
                waitLeft -= 5;
            }
        } catch(Throwable t) {
            ExceptionUtils.handleThrowable(t);
            if (getLog().isDebugEnabled()) {
                getLog().debug(sm.getString(
                        "endpoint.debug.unlock.fail", String.valueOf(getPortWithOffset())), t);
            }
        }
    }


    private static InetSocketAddress getUnlockAddress(InetSocketAddress localAddress) throws SocketException {
        if (localAddress.getAddress().isAnyLocalAddress()) {
            // Need a local address of the same type (IPv4 or IPV6) as the
            // configured bind address since the connector may be configured
            // to not map between types.
            InetAddress loopbackUnlockAddress = null;
            InetAddress linkLocalUnlockAddress = null;

            Enumeration<NetworkInterface> networkInterfaces = NetworkInterface.getNetworkInterfaces();
            while (networkInterfaces.hasMoreElements()) {
                NetworkInterface networkInterface = networkInterfaces.nextElement();
                Enumeration<InetAddress> inetAddresses = networkInterface.getInetAddresses();
                while (inetAddresses.hasMoreElements()) {
                    InetAddress inetAddress = inetAddresses.nextElement();
                    if (localAddress.getAddress().getClass().isAssignableFrom(inetAddress.getClass())) {
                        if (inetAddress.isLoopbackAddress()) {
                            if (loopbackUnlockAddress == null) {
                                loopbackUnlockAddress = inetAddress;
                            }
                        } else if (inetAddress.isLinkLocalAddress()) {
                            if (linkLocalUnlockAddress == null) {
                                linkLocalUnlockAddress = inetAddress;
                            }
                        } else {
                            // Use a non-link local, non-loop back address by default
                            return new InetSocketAddress(inetAddress, localAddress.getPort());
                        }
                    }
                }
            }
            // Prefer loop back over link local since on some platforms (e.g.
            // OSX) some link local addresses are not included when listening on
            // all local addresses.
            if (loopbackUnlockAddress != null) {
                return new InetSocketAddress(loopbackUnlockAddress, localAddress.getPort());
            }
            if (linkLocalUnlockAddress != null) {
                return new InetSocketAddress(linkLocalUnlockAddress, localAddress.getPort());
            }
            // Fallback
            return new InetSocketAddress("localhost", localAddress.getPort());
        } else {
            return localAddress;
        }
    }


    // ---------------------------------------------- Request processing methods

    
Process the given SocketWrapper with the given status. Used to trigger
processing as if the Poller (for those endpoints that have one)
selected the socket.
Params:
socketWrapper – The socket wrapper to process
event –         The socket event to be processed
dispatch –      Should the processing be performed on a new
                         container thread
Returns:
if processing was triggered successfully/**
     * Process the given SocketWrapper with the given status. Used to trigger
     * processing as if the Poller (for those endpoints that have one)
     * selected the socket.
     *
     * @param socketWrapper The socket wrapper to process
     * @param event         The socket event to be processed
     * @param dispatch      Should the processing be performed on a new
     *                          container thread
     *
     * @return if processing was triggered successfully
     */
    public boolean processSocket(SocketWrapperBase<S> socketWrapper,
            SocketEvent event, boolean dispatch) {
        try {
            if (socketWrapper == null) {
                return false;
            }
            SocketProcessorBase<S> sc = null;
            if (processorCache != null) {
                sc = processorCache.pop();
            }
            if (sc == null) {
                sc = createSocketProcessor(socketWrapper, event);
            } else {
                sc.reset(socketWrapper, event);
            }
            Executor executor = getExecutor();
            if (dispatch && executor != null) {
                executor.execute(sc);
            } else {
                sc.run();
            }
        } catch (RejectedExecutionException ree) {
            getLog().warn(sm.getString("endpoint.executor.fail", socketWrapper) , ree);
            return false;
        } catch (Throwable t) {
            ExceptionUtils.handleThrowable(t);
            // This means we got an OOM or similar creating a thread, or that
            // the pool and its queue are full
            getLog().error(sm.getString("endpoint.process.fail"), t);
            return false;
        }
        return true;
    }


    protected abstract SocketProcessorBase<S> createSocketProcessor(
            SocketWrapperBase<S> socketWrapper, SocketEvent event);


    // ------------------------------------------------------- Lifecycle methods

    /*
     * NOTE: There is no maintenance of state or checking for valid transitions
     * within this class other than ensuring that bind/unbind are called in the
     * right place. It is expected that the calling code will maintain state and
     * prevent invalid state transitions.
     */

    public abstract void bind() throws Exception;
    public abstract void unbind() throws Exception;
    public abstract void startInternal() throws Exception;
    public abstract void stopInternal() throws Exception;


    private void bindWithCleanup() throws Exception {
        try {
            bind();
        } catch (Throwable t) {
            // Ensure open sockets etc. are cleaned up if something goes
            // wrong during bind
            ExceptionUtils.handleThrowable(t);
            unbind();
            throw t;
        }
    }


    public final void init() throws Exception {
        if (bindOnInit) {
            bindWithCleanup();
            bindState = BindState.BOUND_ON_INIT;
        }
        if (this.domain != null) {
            // Register endpoint (as ThreadPool - historical name)
            oname = new ObjectName(domain + ":type=ThreadPool,name=\"" + getName() + "\"");
            Registry.getRegistry(null, null).registerComponent(this, oname, null);

            ObjectName socketPropertiesOname = new ObjectName(domain +
                    ":type=ThreadPool,name=\"" + getName() + "\",subType=SocketProperties");
            socketProperties.setObjectName(socketPropertiesOname);
            Registry.getRegistry(null, null).registerComponent(socketProperties, socketPropertiesOname, null);

            for (SSLHostConfig sslHostConfig : findSslHostConfigs()) {
                registerJmx(sslHostConfig);
            }
        }
    }


    private void registerJmx(SSLHostConfig sslHostConfig) {
        if (domain == null) {
            // Before init the domain is null
            return;
        }
        ObjectName sslOname = null;
        try {
            sslOname = new ObjectName(domain + ":type=SSLHostConfig,ThreadPool=\"" +
                    getName() + "\",name=" + ObjectName.quote(sslHostConfig.getHostName()));
            sslHostConfig.setObjectName(sslOname);
            try {
                Registry.getRegistry(null, null).registerComponent(sslHostConfig, sslOname, null);
            } catch (Exception e) {
                getLog().warn(sm.getString("endpoint.jmxRegistrationFailed", sslOname), e);
            }
        } catch (MalformedObjectNameException e) {
            getLog().warn(sm.getString("endpoint.invalidJmxNameSslHost",
                    sslHostConfig.getHostName()), e);
        }

        for (SSLHostConfigCertificate sslHostConfigCert : sslHostConfig.getCertificates()) {
            ObjectName sslCertOname = null;
            try {
                sslCertOname = new ObjectName(domain +
                        ":type=SSLHostConfigCertificate,ThreadPool=\"" + getName() +
                        "\",Host=" + ObjectName.quote(sslHostConfig.getHostName()) +
                        ",name=" + sslHostConfigCert.getType());
                sslHostConfigCert.setObjectName(sslCertOname);
                try {
                    Registry.getRegistry(null, null).registerComponent(
                            sslHostConfigCert, sslCertOname, null);
                } catch (Exception e) {
                    getLog().warn(sm.getString("endpoint.jmxRegistrationFailed", sslCertOname), e);
                }
            } catch (MalformedObjectNameException e) {
                getLog().warn(sm.getString("endpoint.invalidJmxNameSslHostCert",
                        sslHostConfig.getHostName(), sslHostConfigCert.getType()), e);
            }
        }
    }


    private void unregisterJmx(SSLHostConfig sslHostConfig) {
        Registry registry = Registry.getRegistry(null, null);
        registry.unregisterComponent(sslHostConfig.getObjectName());
        for (SSLHostConfigCertificate sslHostConfigCert : sslHostConfig.getCertificates()) {
            registry.unregisterComponent(sslHostConfigCert.getObjectName());
        }
    }


    public final void start() throws Exception {
        if (bindState == BindState.UNBOUND) {
            bindWithCleanup();
            bindState = BindState.BOUND_ON_START;
        }
        startInternal();
    }


    protected void startAcceptorThread() {
        acceptor = new Acceptor<>(this);
        String threadName = getName() + "-Acceptor";
        acceptor.setThreadName(threadName);
        Thread t = new Thread(acceptor, threadName);
        t.setPriority(getAcceptorThreadPriority());
        t.setDaemon(getDaemon());
        t.start();
    }


    
Pause the endpoint, which will stop it accepting new connections and
unlock the acceptor.
/**
     * Pause the endpoint, which will stop it accepting new connections and
     * unlock the acceptor.
     */
    public void pause() {
        if (running && !paused) {
            paused = true;
            releaseConnectionLatch();
            unlockAccept();
            getHandler().pause();
        }
    }

    
Resume the endpoint, which will make it start accepting new connections
again.
/**
     * Resume the endpoint, which will make it start accepting new connections
     * again.
     */
    public void resume() {
        if (running) {
            paused = false;
        }
    }

    public final void stop() throws Exception {
        stopInternal();
        if (bindState == BindState.BOUND_ON_START || bindState == BindState.SOCKET_CLOSED_ON_STOP) {
            unbind();
            bindState = BindState.UNBOUND;
        }
    }

    public final void destroy() throws Exception {
        if (bindState == BindState.BOUND_ON_INIT) {
            unbind();
            bindState = BindState.UNBOUND;
        }
        Registry registry = Registry.getRegistry(null, null);
        registry.unregisterComponent(oname);
        registry.unregisterComponent(socketProperties.getObjectName());
        for (SSLHostConfig sslHostConfig : findSslHostConfigs()) {
            unregisterJmx(sslHostConfig);
        }
    }


    protected abstract Log getLog();

    protected LimitLatch initializeConnectionLatch() {
        if (maxConnections==-1) return null;
        if (connectionLimitLatch==null) {
            connectionLimitLatch = new LimitLatch(getMaxConnections());
        }
        return connectionLimitLatch;
    }

    private void releaseConnectionLatch() {
        LimitLatch latch = connectionLimitLatch;
        if (latch!=null) latch.releaseAll();
        connectionLimitLatch = null;
    }

    protected void countUpOrAwaitConnection() throws InterruptedException {
        if (maxConnections==-1) return;
        LimitLatch latch = connectionLimitLatch;
        if (latch!=null) latch.countUpOrAwait();
    }

    protected long countDownConnection() {
        if (maxConnections==-1) return -1;
        LimitLatch latch = connectionLimitLatch;
        if (latch!=null) {
            long result = latch.countDown();
            if (result<0) {
                getLog().warn(sm.getString("endpoint.warn.incorrectConnectionCount"));
            }
            return result;
        } else return -1;
    }


    
Close the server socket (to prevent further connections) if the server socket was originally bound on start() (rather than on init()). 
See Also:
getBindOnInit()/**
     * Close the server socket (to prevent further connections) if the server
     * socket was originally bound on {@link #start()} (rather than on
     * {@link #init()}).
     *
     * @see #getBindOnInit()
     */
    public final void closeServerSocketGraceful() {
        if (bindState == BindState.BOUND_ON_START) {
            bindState = BindState.SOCKET_CLOSED_ON_STOP;
            try {
                doCloseServerSocket();
            } catch (IOException ioe) {
                getLog().warn(sm.getString("endpoint.serverSocket.closeFailed", getName()), ioe);
            }
        }
    }


    
Actually close the server socket but don't perform any other clean-up.
Throws:
IOException – If an error occurs closing the socket/**
     * Actually close the server socket but don't perform any other clean-up.
     *
     * @throws IOException If an error occurs closing the socket
     */
    protected abstract void doCloseServerSocket() throws IOException;

    protected abstract U serverSocketAccept() throws Exception;

    protected abstract boolean setSocketOptions(U socket);

    
Close the socket when the connection has to be immediately closed when
an error occurs while configuring the accepted socket, allocating
a wrapper for the socket, or trying to dispatch it for processing.
Params:
socket – The newly accepted socket/**
     * Close the socket when the connection has to be immediately closed when
     * an error occurs while configuring the accepted socket, allocating
     * a wrapper for the socket, or trying to dispatch it for processing.
     * @param socket The newly accepted socket
     */
    protected abstract void closeSocket(U socket);

    protected void destroySocket(U socket) {
        closeSocket(socket);
    }
}