Source Code of ch.ethz.ssh2.Connection

package ch.ethz.ssh2;

import java.io.CharArrayWriter;
import java.io.File;
import java.io.FileReader;
import java.io.IOException;
import java.net.SocketTimeoutException;
import java.security.SecureRandom;
import java.util.Vector;

import ch.ethz.ssh2.auth.AuthenticationManager;
import ch.ethz.ssh2.channel.ChannelManager;
import ch.ethz.ssh2.crypto.CryptoWishList;
import ch.ethz.ssh2.crypto.cipher.BlockCipherFactory;
import ch.ethz.ssh2.crypto.digest.MAC;
import ch.ethz.ssh2.transport.KexManager;
import ch.ethz.ssh2.transport.TransportManager;
import ch.ethz.ssh2.util.TimeoutService;
import ch.ethz.ssh2.util.TimeoutService.TimeoutToken;

/**
 * A <code>Connection</code> is used to establish an encrypted TCP/IP
 * connection to a SSH-2 server.
 * <p>
 * Typically, one
 * <ol>
 * <li>creates a {@link #Connection(String) Connection} object.</li>
 * <li>calls the {@link #connect() connect()} method.</li>
 * <li>calls some of the authentication methods (e.g., {@link #authenticateWithPublicKey(String, File, String) authenticateWithPublicKey()}).</li>
 * <li>calls one or several times the {@link #openSession() openSession()} method.</li>
 * <li>finally, one must close the connection and release resources with the {@link #close() close()} method.</li>
 * </ol>
 *
 * @author Christian Plattner, plattner@inf.ethz.ch
 * @version $Id: Connection.java,v 1.28 2006/09/12 15:35:26 cplattne Exp $
 */

public class Connection
{
  /**
   * The identifier presented to the SSH-2 server.
   */
  public final static String identification = "Ganymed Build_210";

  /* Will be used to generate all random data needed for the current connection.
   * Note: SecureRandom.nextBytes() is thread safe.
   */

  private SecureRandom generator;

  /**
   * Unless you know what you are doing, you will never need this.
   *
   * @return The list of supported cipher algorithms by this implementation.
   */
  public static synchronized String[] getAvailableCiphers()
  {
    return BlockCipherFactory.getDefaultCipherList();
  }

  /**
   * Unless you know what you are doing, you will never need this.
   *
   * @return The list of supported MAC algorthims by this implementation.
   */
  public static synchronized String[] getAvailableMACs()
  {
    return MAC.getMacList();
  }

  /**
   * Unless you know what you are doing, you will never need this.
   *
   * @return The list of supported server host key algorthims by this implementation.
   */
  public static synchronized String[] getAvailableServerHostKeyAlgorithms()
  {
    return KexManager.getDefaultServerHostkeyAlgorithmList();
  }

  private AuthenticationManager am;

  private boolean authenticated = false;
  private ChannelManager cm;

  private CryptoWishList cryptoWishList = new CryptoWishList();

  private DHGexParameters dhgexpara = new DHGexParameters();

  private final String hostname;

  private final int port;

  private TransportManager tm;

  private boolean tcpNoDelay = false;

  private ProxyData proxyData = null;

  private Vector connectionMonitors = new Vector();

  /**
   * Prepares a fresh <code>Connection</code> object which can then be used
   * to establish a connection to the specified SSH-2 server.
   * <p>
   * Same as {@link #Connection(String, int) Connection(hostname, 22)}.
   *
   * @param hostname the hostname of the SSH-2 server.
   */
  public Connection(String hostname)
  {
    this(hostname, 22);
  }

  /**
   * Prepares a fresh <code>Connection</code> object which can then be used
   * to establish a connection to the specified SSH-2 server.
   *
   * @param hostname
   *            the host where we later want to connect to.
   * @param port
   *            port on the server, normally 22.
   */
  public Connection(String hostname, int port)
  {
    this.hostname = hostname;
    this.port = port;
  }

  /**
   * After a successful connect, one has to authenticate oneself. This method
   * is based on DSA (it uses DSA to sign a challenge sent by the server).
   * <p>
   * If the authentication phase is complete, <code>true</code> will be
   * returned. If the server does not accept the request (or if further
   * authentication steps are needed), <code>false</code> is returned and
   * one can retry either by using this or any other authentication method
   * (use the <code>getRemainingAuthMethods</code> method to get a list of
   * the remaining possible methods).
   *
   * @param user
   *            A <code>String</code> holding the username.
   * @param pem
   *            A <code>String</code> containing the DSA private key of the
   *            user in OpenSSH key format (PEM, you can't miss the
   *            "-----BEGIN DSA PRIVATE KEY-----" tag). The string may contain
   *            linefeeds.
   * @param password
   *            If the PEM string is 3DES encrypted ("DES-EDE3-CBC"), then you
   *            must specify the password. Otherwise, this argument will be
   *            ignored and can be set to <code>null</code>.
   *
   * @return whether the connection is now authenticated.
   * @throws IOException
   *
   * @deprecated You should use one of the {@link #authenticateWithPublicKey(String, File, String) authenticateWithPublicKey()}
   *           methods, this method is just a wrapper for it and will
   *            disappear in future builds.
   *
   */
  public synchronized boolean authenticateWithDSA(String user, String pem, String password) throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("Connection is not established!");

    if (authenticated)
      throw new IllegalStateException("Connection is already authenticated!");

    if (am == null)
      am = new AuthenticationManager(tm);

    if (cm == null)
      cm = new ChannelManager(tm);

    if (user == null)
      throw new IllegalArgumentException("user argument is null");

    if (pem == null)
      throw new IllegalArgumentException("pem argument is null");

    authenticated = am.authenticatePublicKey(user, pem.toCharArray(), password, getOrCreateSecureRND());

    return authenticated;
  }

  /**
   * A wrapper that calls {@link #authenticateWithKeyboardInteractive(String, String[], InteractiveCallback)
   * authenticateWithKeyboardInteractivewith} a <code>null</code> submethod list.
   *
   * @param user
   *            A <code>String</code> holding the username.
   * @param cb
   *            An <code>InteractiveCallback</code> which will be used to
   *            determine the responses to the questions asked by the server.
   * @return whether the connection is now authenticated.
   * @throws IOException
   */
  public synchronized boolean authenticateWithKeyboardInteractive(String user, InteractiveCallback cb)
      throws IOException
  {
    return authenticateWithKeyboardInteractive(user, null, cb);
  }

  /**
   * After a successful connect, one has to authenticate oneself. This method
   * is based on "keyboard-interactive", specified in
   * draft-ietf-secsh-auth-kbdinteract-XX. Basically, you have to define a
   * callback object which will be feeded with challenges generated by the
   * server. Answers are then sent back to the server. It is possible that the
   * callback will be called several times during the invocation of this
   * method (e.g., if the server replies to the callback's answer(s) with
   * another challenge...)
   * <p>
   * If the authentication phase is complete, <code>true</code> will be
   * returned. If the server does not accept the request (or if further
   * authentication steps are needed), <code>false</code> is returned and
   * one can retry either by using this or any other authentication method
   * (use the <code>getRemainingAuthMethods</code> method to get a list of
   * the remaining possible methods).
   * <p>
   * Note: some SSH servers advertise "keyboard-interactive", however, any
   * interactive request will be denied (without having sent any challenge to
   * the client).
   *
   * @param user
   *            A <code>String</code> holding the username.
   * @param submethods
   *            An array of submethod names, see
   *            draft-ietf-secsh-auth-kbdinteract-XX. May be <code>null</code>
   *            to indicate an empty list.
   * @param cb
   *            An <code>InteractiveCallback</code> which will be used to
   *            determine the responses to the questions asked by the server.
   *
   * @return whether the connection is now authenticated.
   * @throws IOException
   */
  public synchronized boolean authenticateWithKeyboardInteractive(String user, String[] submethods,
      InteractiveCallback cb) throws IOException
  {
    if (cb == null)
      throw new IllegalArgumentException("Callback may not ne NULL!");

    if (tm == null)
      throw new IllegalStateException("Connection is not established!");

    if (authenticated)
      throw new IllegalStateException("Connection is already authenticated!");

    if (am == null)
      am = new AuthenticationManager(tm);

    if (cm == null)
      cm = new ChannelManager(tm);

    if (user == null)
      throw new IllegalArgumentException("user argument is null");

    authenticated = am.authenticateInteractive(user, submethods, cb);

    return authenticated;
  }

  /**
   * After a successfull connect, one has to authenticate oneself. This method
   * sends username and password to the server.
   * <p>
   * If the authentication phase is complete, <code>true</code> will be
   * returned. If the server does not accept the request (or if further
   * authentication steps are needed), <code>false</code> is returned and
   * one can retry either by using this or any other authentication method
   * (use the <code>getRemainingAuthMethods</code> method to get a list of
   * the remaining possible methods).
   * <p>
   * Note: if this method fails, then please double-check that it is actually
   * offered by the server (use {@link #getRemainingAuthMethods(String) getRemainingAuthMethods()}.
   * <p>
   * Often, password authentication is disabled, but users are not aware of it.
   * Many servers only offer "publickey" and "keyboard-interactive". However,
   * even though "keyboard-interactive" *feels* like password authentication
   * (e.g., when using the putty or openssh clients) it is *not* the same mechanism.
   *
   * @param user
   * @param password
   * @return if the connection is now authenticated.
   * @throws IOException
   */
  public synchronized boolean authenticateWithPassword(String user, String password) throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("Connection is not established!");

    if (authenticated)
      throw new IllegalStateException("Connection is already authenticated!");

    if (am == null)
      am = new AuthenticationManager(tm);

    if (cm == null)
      cm = new ChannelManager(tm);

    if (user == null)
      throw new IllegalArgumentException("user argument is null");

    if (password == null)
      throw new IllegalArgumentException("password argument is null");

    authenticated = am.authenticatePassword(user, password);

    return authenticated;
  }

  /**
   * After a successful connect, one has to authenticate oneself.
   * The authentication method "publickey" works by signing a challenge
   * sent by the server. The signature is either DSA or RSA based - it
   * just depends on the type of private key you specify, either a DSA
   * or RSA private key in PEM format. And yes, this is may seem to be a
   * little confusing, the method is called "publickey" in the SSH-2 protocol
   * specification, however since we need to generate a signature, you
   * actually have to supply a private key =).
   * <p>
   * The private key contained in the PEM file may also be encrypted ("Proc-Type: 4,ENCRYPTED").
   * The library supports DES-CBC and DES-EDE3-CBC encryption, as well
   * as the more exotic PEM encrpytions AES-128-CBC, AES-192-CBC and AES-256-CBC.
   * <p>
   * If the authentication phase is complete, <code>true</code> will be
   * returned. If the server does not accept the request (or if further
   * authentication steps are needed), <code>false</code> is returned and
   * one can retry either by using this or any other authentication method
   * (use the <code>getRemainingAuthMethods</code> method to get a list of
   * the remaining possible methods).
   * <p>
   * NOTE PUTTY USERS: Event though your key file may start with "-----BEGIN..."
   * it is not in the expected format. You have to convert it to the OpenSSH
   * key format by using the "puttygen" tool (can be downloaded from the Putty
   * website). Simply load your key and then use the "Conversions/Export OpenSSH key"
   * functionality to get a proper PEM file.
   *
   * @param user
   *            A <code>String</code> holding the username.
   * @param pemPrivateKey
   *            A <code>char[]</code> containing a DSA or RSA private key of the
   *            user in OpenSSH key format (PEM, you can't miss the
   *            "-----BEGIN DSA PRIVATE KEY-----" or "-----BEGIN RSA PRIVATE KEY-----"
   *            tag). The char array may contain linebreaks/linefeeds.
   * @param password
   *            If the PEM structure is encrypted ("Proc-Type: 4,ENCRYPTED") then
   *            you must specify a password. Otherwise, this argument will be ignored
   *            and can be set to <code>null</code>.
   *
   * @return whether the connection is now authenticated.
   * @throws IOException
   */
  public synchronized boolean authenticateWithPublicKey(String user, char[] pemPrivateKey, String password)
      throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("Connection is not established!");

    if (authenticated)
      throw new IllegalStateException("Connection is already authenticated!");

    if (am == null)
      am = new AuthenticationManager(tm);

    if (cm == null)
      cm = new ChannelManager(tm);

    if (user == null)
      throw new IllegalArgumentException("user argument is null");

    if (pemPrivateKey == null)
      throw new IllegalArgumentException("pemPrivateKey argument is null");

    authenticated = am.authenticatePublicKey(user, pemPrivateKey, password, getOrCreateSecureRND());

    return authenticated;
  }

  /**
   * A convenience wrapper function which reads in a private key (PEM format, either DSA or RSA)
   * and then calls <code>authenticateWithPublicKey(String, char[], String)</code>.
   * <p>
   * NOTE PUTTY USERS: Event though your key file may start with "-----BEGIN..."
   * it is not in the expected format. You have to convert it to the OpenSSH
   * key format by using the "puttygen" tool (can be downloaded from the Putty
   * website). Simply load your key and then use the "Conversions/Export OpenSSH key"
   * functionality to get a proper PEM file.
   *
   * @param user
   *            A <code>String</code> holding the username.
   * @param pemFile
   *            A <code>File</code> object pointing to a file containing a DSA or RSA
   *            private key of the user in OpenSSH key format (PEM, you can't miss the
   *            "-----BEGIN DSA PRIVATE KEY-----" or "-----BEGIN RSA PRIVATE KEY-----"
   *            tag).
   * @param password
   *            If the PEM file is encrypted then you must specify the password.
   *            Otherwise, this argument will be ignored and can be set to <code>null</code>.
   *
   * @return whether the connection is now authenticated.
   * @throws IOException
   */
  public synchronized boolean authenticateWithPublicKey(String user, File pemFile, String password)
      throws IOException
  {
    if (pemFile == null)
      throw new IllegalArgumentException("pemFile argument is null");

    char[] buff = new char[256];

    CharArrayWriter cw = new CharArrayWriter();

    FileReader fr = new FileReader(pemFile);

    while (true)
    {
      int len = fr.read(buff);
      if (len < 0)
        break;
      cw.write(buff, 0, len);
    }

    fr.close();

    return authenticateWithPublicKey(user, cw.toCharArray(), password);
  }

  /**
   * Add a {@link ConnectionMonitor} to this connection. Can be invoked at any time,
   * but it is best to add connection monitors before invoking
   * <code>connect()</code> to avoid glitches (e.g., you add a connection monitor after
   * a successful connect(), but the connection has died in the mean time. Then,
   * your connection monitor won't be notified.)
   * <p>
   * You can add as many monitors as you like.
   *
   * @see ConnectionMonitor
   *
   * @param cmon An object implementing the <code>ConnectionMonitor</code> interface.
   */
  public synchronized void addConnectionMonitor(ConnectionMonitor cmon)
  {
    if (cmon == null)
      throw new IllegalArgumentException("cmon argument is null");

    connectionMonitors.addElement(cmon);

    if (tm != null)
      tm.setConnectionMonitors(connectionMonitors);
  }

  /**
   * Close the connection to the SSH-2 server. All assigned sessions will be
   * closed, too. Can be called at any time. Don't forget to call this once
   * you don't need a connection anymore - otherwise the receiver thread may
   * run forever.
   */
  public synchronized void close()
  {
    Throwable t = new Throwable("Closed due to user request.");
    close(t, false);
  }

  private void close(Throwable t, boolean hard)
  {
    if (cm != null)
      cm.closeAllChannels();

    if (tm != null)
    {
      tm.close(t, hard == false);
      tm = null;
    }
    am = null;
    cm = null;
    authenticated = false;
  }

  /**
   * Same as {@link #connect(ServerHostKeyVerifier, int, int) connect(null, 0, 0)}.
   *
   * @return see comments for the {@link #connect(ServerHostKeyVerifier, int, int) connect(ServerHostKeyVerifier, int, int)} method.
   * @throws IOException
   */
  public synchronized ConnectionInfo connect() throws IOException
  {
    return connect(null, 0, 0);
  }

  /**
   * Same as {@link #connect(ServerHostKeyVerifier, int, int) connect(verifier, 0, 0)}.
   *
   * @return see comments for the {@link #connect(ServerHostKeyVerifier, int, int) connect(ServerHostKeyVerifier, int, int)} method.
   * @throws IOException
   */
  public synchronized ConnectionInfo connect(ServerHostKeyVerifier verifier) throws IOException
  {
    return connect(verifier, 0, 0);
  }

  /**
   * Connect to the SSH-2 server and, as soon as the server has presented its
   * host key, use the {@link ServerHostKeyVerifier#verifyServerHostKey(String,
   * int, String, byte[]) ServerHostKeyVerifier.verifyServerHostKey()}
   * method of the <code>verifier</code> to ask for permission to proceed.
   * If <code>verifier</code> is <code>null</code>, then any host key will be
   * accepted - this is NOT recommended, since it makes man-in-the-middle attackes
   * VERY easy (somebody could put a proxy SSH server between you and the real server).
   * <p>
   * Note: The verifier will be called before doing any crypto calculations
   * (i.e., diffie-hellman). Therefore, if you don't like the presented host key then
   * no CPU cycles are wasted (and the evil server has less information about us).
   * <p>
   * However, it is still possible that the server presented a fake host key: the server
   * cheated (typically a sign for a man-in-the-middle attack) and is not able to generate
   * a signature that matches its host key. Don't worry, the library will detect such
   * a scenario later when checking the signature (the signature cannot be checked before
   * having completed the diffie-hellman exchange).
   * <p>
   * Note 2: The  {@link ServerHostKeyVerifier#verifyServerHostKey(String,
   * int, String, byte[]) ServerHostKeyVerifier.verifyServerHostKey()} method
   * will *NOT* be called from the current thread, the call is being made from a
   * background thread (there is a background dispatcher thread for every
   * established connection).
   * <p>
   * Note 3: This method will block as long as the key exchange of the underlying connection
   * has not been completed (and you have not specified any timeouts).
   * <p>
   * Note 4: If you want to re-use a connection object that was successfully connected,
   * then you must call the {@link #close()} method before invoking <code>connect()</code> again.
   *
   * @param verifier
   *            An object that implements the
   *            {@link ServerHostKeyVerifier} interface. Pass <code>null</code>
   *            to accept any server host key - NOT recommended.
   *
   * @param connectTimeout
   *            Connect the underlying TCP socket to the server with the given timeout
   *            value (non-negative, in milliseconds). Zero means no timeout. If a proxy is being
   *            used (see {@link #setProxyData(ProxyData)}), then this timeout is used for the
   *            connection establishment to the proxy.
   *
   * @param kexTimeout
   *            Timeout for complete connection establishment (non-negative,
   *            in milliseconds). Zero means no timeout. The timeout counts from the
   *            moment you invoke the connect() method and is cancelled as soon as the
   *            first key-exchange round has finished. It is possible that
   *            the timeout event will be fired during the invocation of the
   *            <code>verifier</code> callback, but it will only have an effect after
   *            the <code>verifier</code> returns.
   *
   * @return A {@link ConnectionInfo} object containing the details of
   *            the established connection.
   *
   * @throws IOException
   *            If any problem occurs, e.g., the server's host key is not
   *            accepted by the <code>verifier</code> or there is problem during
   *            the initial crypto setup (e.g., the signature sent by the server is wrong).
   *            <p>
   *            In case of a timeout (either connectTimeout or kexTimeout)
   *            a SocketTimeoutException is thrown.
   *            <p>
   *            An exception may also be thrown if the connection was already successfully
   *            connected (no matter if the connection broke in the mean time) and you invoke
   *            <code>connect()</code> again without having called {@link #close()} first.
   *            <p>
   *            If a HTTP proxy is being used and the proxy refuses the connection,
   *            then a {@link HTTPProxyException} may be thrown, which
   *            contains the details returned by the proxy. If the proxy is buggy and does
   *            not return a proper HTTP response, then a normal IOException is thrown instead.
   */
  public synchronized ConnectionInfo connect(ServerHostKeyVerifier verifier, int connectTimeout, int kexTimeout)
      throws IOException
  {
    final class TimeoutState
    {
      boolean isCancelled = false;
      boolean timeoutSocketClosed = false;
    }

    if (tm != null)
      throw new IOException("Connection to " + hostname + " is already in connected state!");

    if (connectTimeout < 0)
      throw new IllegalArgumentException("connectTimeout must be non-negative!");

    if (kexTimeout < 0)
      throw new IllegalArgumentException("kexTimeout must be non-negative!");

    final TimeoutState state = new TimeoutState();

    tm = new TransportManager(hostname, port);

    tm.setConnectionMonitors(connectionMonitors);

    /* Make sure that the runnable below will observe the new value of "tm"
     * and "state" (the runnable will be executed in a different thread, which
     * may be already running, that is why we need a memory barrier here).
     * See also the comment in Channel.java if you
     * are interested in the details.
     *
     * OKOK, this is paranoid since adding the runnable to the todo list
     * of the TimeoutService will ensure that all writes have been flushed
     * before the Runnable reads anything
     * (there is a synchronized block in TimeoutService.addTimeoutHandler).
     */

    synchronized (tm)
    {
      /* We could actually synchronize on anything. */
    }

    try
    {
      TimeoutToken token = null;

      if (kexTimeout > 0)
      {
        final Runnable timeoutHandler = new Runnable()
        {
          public void run()
          {
            synchronized (state)
            {
              if (state.isCancelled)
                return;
              state.timeoutSocketClosed = true;
              tm.close(new SocketTimeoutException("The connect timeout expired"), false);
            }
          }
        };

        long timeoutHorizont = System.currentTimeMillis() + kexTimeout;

        token = TimeoutService.addTimeoutHandler(timeoutHorizont, timeoutHandler);
      }

      try
      {
        tm.initialize(cryptoWishList, verifier, dhgexpara, connectTimeout, getOrCreateSecureRND(), proxyData);
      }
      catch (SocketTimeoutException se)
      {
        throw (SocketTimeoutException) new SocketTimeoutException(
            "The connect() operation on the socket timed out.").initCause(se);
      }

      tm.setTcpNoDelay(tcpNoDelay);

      /* Wait until first KEX has finished */

      ConnectionInfo ci = tm.getConnectionInfo(1);

      /* Now try to cancel the timeout, if needed */

      if (token != null)
      {
        TimeoutService.cancelTimeoutHandler(token);

        /* Were we too late? */

        synchronized (state)
        {
          if (state.timeoutSocketClosed)
            throw new IOException("This exception will be replaced by the one below =)");
          /* Just in case the "cancelTimeoutHandler" invocation came just a little bit
           * too late but the handler did not enter the semaphore yet - we can
           * still stop it.
           */
          state.isCancelled = true;
        }
      }

      return ci;
    }
    catch (SocketTimeoutException ste)
    {
      throw ste;
    }
    catch (IOException e1)
    {
      /* This will also invoke any registered connection monitors */
      close(new Throwable("There was a problem during connect."), false);

      synchronized (state)
      {
        /* Show a clean exception, not something like "the socket is closed!?!" */
        if (state.timeoutSocketClosed)
          throw new SocketTimeoutException("The kexTimeout (" + kexTimeout + " ms) expired.");
      }

      /* Do not wrap a HTTPProxyException */
      if (e1 instanceof HTTPProxyException)
        throw e1;

      throw (IOException) new IOException("There was a problem while connecting to " + hostname + ":" + port)
          .initCause(e1);
    }
  }

  /**
   * Creates a new {@link LocalPortForwarder}.
   * A <code>LocalPortForwarder</code> forwards TCP/IP connections that arrive at a local
   * port via the secure tunnel to another host (which may or may not be
   * identical to the remote SSH-2 server).
   * <p>
   * This method must only be called after one has passed successfully the authentication step.
   * There is no limit on the number of concurrent forwardings.
   *
   * @param local_port the local port the LocalPortForwarder shall bind to.
   * @param host_to_connect target address (IP or hostname)
   * @param port_to_connect target port
   * @return A {@link LocalPortForwarder} object.
   * @throws IOException
   */
  public synchronized LocalPortForwarder createLocalPortForwarder(int local_port, String host_to_connect,
      int port_to_connect) throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("Cannot forward ports, you need to establish a connection first.");

    if (!authenticated)
      throw new IllegalStateException("Cannot forward ports, connection is not authenticated.");

    return new LocalPortForwarder(cm, local_port, host_to_connect, port_to_connect);
  }

  /**
   * Creates a new {@link LocalStreamForwarder}.
   * A <code>LocalStreamForwarder</code> manages an Input/Outputstream pair
   * that is being forwarded via the secure tunnel into a TCP/IP connection to another host
   * (which may or may not be identical to the remote SSH-2 server).
   *
   * @param host_to_connect
   * @param port_to_connect
   * @return A {@link LocalStreamForwarder} object.
   * @throws IOException
   */
  public synchronized LocalStreamForwarder createLocalStreamForwarder(String host_to_connect, int port_to_connect)
      throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("Cannot forward, you need to establish a connection first.");

    if (!authenticated)
      throw new IllegalStateException("Cannot forward, connection is not authenticated.");

    return new LocalStreamForwarder(cm, host_to_connect, port_to_connect);
  }

  /**
   * Create a very basic {@link SCPClient} that can be used to copy
   * files from/to the SSH-2 server.
   * <p>
   * Works only after one has passed successfully the authentication step.
   * There is no limit on the number of concurrent SCP clients.
   * <p>
   * Note: This factory method will probably disappear in the future.
   *
   * @return A {@link SCPClient} object.
   * @throws IOException
   */
  public synchronized SCPClient createSCPClient() throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("Cannot create SCP client, you need to establish a connection first.");

    if (!authenticated)
      throw new IllegalStateException("Cannot create SCP client, connection is not authenticated.");

    return new SCPClient(this);
  }

  /**
   * Force an asynchronous key re-exchange (the call does not block). The
   * latest values set for MAC, Cipher and DH group exchange parameters will
   * be used. If a key exchange is currently in progress, then this method has
   * the only effect that the so far specified parameters will be used for the
   * next (server driven) key exchange.
   * <p>
   * Note: This implementation will never start a key exchange (other than the initial one)
   * unless you or the SSH-2 server ask for it.
   *
   * @throws IOException
   *             In case of any failure behind the scenes.
   */
  public synchronized void forceKeyExchange() throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("You need to establish a connection first.");

    tm.forceKeyExchange(cryptoWishList, dhgexpara);
  }

  /**
   * Returns the hostname that was passed to the constructor.
   *
   * @return the hostname
   */
  public synchronized String getHostname()
  {
    return hostname;
  }

  /**
   * Returns the port that was passed to the constructor.
   *
   * @return the TCP port
   */
  public synchronized int getPort()
  {
    return port;
  }

  /**
   * Returns a {@link ConnectionInfo} object containing the details of
   * the connection. Can be called as soon as the connection has been
   * established (successfully connected).
   *
   * @return A {@link ConnectionInfo} object.
   * @throws IOException
   *             In case of any failure behind the scenes.
   */
  public synchronized ConnectionInfo getConnectionInfo() throws IOException
  {
    if (tm == null)
      throw new IllegalStateException(
          "Cannot get details of connection, you need to establish a connection first.");
    return tm.getConnectionInfo(1);
  }

  /**
   * After a successful connect, one has to authenticate oneself. This method
   * can be used to tell which authentication methods are supported by the
   * server at a certain stage of the authentication process (for the given
   * username).
   * <p>
   * Note 1: the username will only be used if no authentication step was done
   * so far (it will be used to ask the server for a list of possible
   * authentication methods). Otherwise, this method ignores the user name and
   * returns a cached method list (which is based on the information contained
   * in the last negative server response).
   * <p>
   * Note 2: the server may return method names that are not supported by this
   * implementation.
   * <p>
   * After a successful authentication, this method must not be called
   * anymore.
   *
   * @param user
   *            A <code>String</code> holding the username.
   *
   * @return a (possibly emtpy) array holding authentication method names.
   * @throws IOException
   */
  public synchronized String[] getRemainingAuthMethods(String user) throws IOException
  {
    if (user == null)
      throw new IllegalArgumentException("user argument may not be NULL!");

    if (tm == null)
      throw new IllegalStateException("Connection is not established!");

    if (authenticated)
      throw new IllegalStateException("Connection is already authenticated!");

    if (am == null)
      am = new AuthenticationManager(tm);

    if (cm == null)
      cm = new ChannelManager(tm);

    return am.getRemainingMethods(user);
  }

  /**
   * Determines if the authentication phase is complete. Can be called at any
   * time.
   *
   * @return <code>true</code> if no further authentication steps are
   *         needed.
   */
  public synchronized boolean isAuthenticationComplete()
  {
    return authenticated;
  }

  /**
   * Returns true if there was at least one failed authentication request and
   * the last failed authentication request was marked with "partial success"
   * by the server. This is only needed in the rare case of SSH-2 server setups
   * that cannot be satisfied with a single successful authentication request
   * (i.e., multiple authentication steps are needed.)
   * <p>
   * If you are interested in the details, then have a look at
   * draft-ietf-secsh-userauth-XX.txt.
   *
   * @return if the there was a failed authentication step and the last one
   *         was marked as a "partial success".
   */
  public synchronized boolean isAuthenticationPartialSuccess()
  {
    if (am == null)
      return false;

    return am.getPartialSuccess();
  }

  /**
   * Checks if a specified authentication method is available. This method is
   * actually just a wrapper for {@link #getRemainingAuthMethods(String)
   * getRemainingAuthMethods()}.
   *
   * @param user
   *            A <code>String</code> holding the username.
   * @param method
   *            An authentication method name (e.g., "publickey", "password",
   *            "keyboard-interactive") as specified by the SSH-2 standard.
   * @return if the specified authentication method is currently available.
   * @throws IOException
   */
  public synchronized boolean isAuthMethodAvailable(String user, String method) throws IOException
  {
    if (method == null)
      throw new IllegalArgumentException("method argument may not be NULL!");

    String methods[] = getRemainingAuthMethods(user);

    for (int i = 0; i < methods.length; i++)
    {
      if (methods[i].compareTo(method) == 0)
        return true;
    }

    return false;
  }

  private final SecureRandom getOrCreateSecureRND()
  {
    if (generator == null)
      generator = new SecureRandom();

    return generator;
  }

  /**
   * Open a new {@link Session} on this connection. Works only after one has passed
   * successfully the authentication step. There is no limit on the number of
   * concurrent sessions.
   *
   * @return A {@link Session} object.
   * @throws IOException
   */
  public synchronized Session openSession() throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("Cannot open session, you need to establish a connection first.");

    if (!authenticated)
      throw new IllegalStateException("Cannot open session, connection is not authenticated.");

    return new Session(cm, getOrCreateSecureRND());
  }

  /**
   * Removes duplicates from a String array, keeps only first occurence
   * of each element. Does not destroy order of elements; can handle nulls.
   * Uses a very efficient O(N^2) algorithm =)
   *
   * @param list a String array.
   * @return a cleaned String array.
   */
  private String[] removeDuplicates(String[] list)
  {
    if ((list == null) || (list.length < 2))
      return list;

    String[] list2 = new String[list.length];

    int count = 0;

    for (int i = 0; i < list.length; i++)
    {
      boolean duplicate = false;

      String element = list[i];

      for (int j = 0; j < count; j++)
      {
        if (((element == null) && (list2[j] == null)) || ((element != null) && (element.equals(list2[j]))))
        {
          duplicate = true;
          break;
        }
      }

      if (duplicate)
        continue;

      list2[count++] = list[i];
    }

    if (count == list2.length)
      return list2;

    String[] tmp = new String[count];
    System.arraycopy(list2, 0, tmp, 0, count);

    return tmp;
  }

  /**
   * Unless you know what you are doing, you will never need this.
   *
   * @param ciphers
   */
  public synchronized void setClient2ServerCiphers(String[] ciphers)
  {
    if ((ciphers == null) || (ciphers.length == 0))
      throw new IllegalArgumentException();
    ciphers = removeDuplicates(ciphers);
    BlockCipherFactory.checkCipherList(ciphers);
    cryptoWishList.c2s_enc_algos = ciphers;
  }

  /**
   * Unless you know what you are doing, you will never need this.
   *
   * @param macs
   */
  public synchronized void setClient2ServerMACs(String[] macs)
  {
    if ((macs == null) || (macs.length == 0))
      throw new IllegalArgumentException();
    macs = removeDuplicates(macs);
    MAC.checkMacList(macs);
    cryptoWishList.c2s_mac_algos = macs;
  }

  /**
   * Sets the parameters for the diffie-hellman group exchange. Unless you
   * know what you are doing, you will never need this. Default values are
   * defined in the {@link DHGexParameters} class.
   *
   * @param dgp {@link DHGexParameters}, non null.
   *
   */
  public synchronized void setDHGexParameters(DHGexParameters dgp)
  {
    if (dgp == null)
      throw new IllegalArgumentException();

    dhgexpara = dgp;
  }

  /**
   * Unless you know what you are doing, you will never need this.
   *
   * @param ciphers
   */
  public synchronized void setServer2ClientCiphers(String[] ciphers)
  {
    if ((ciphers == null) || (ciphers.length == 0))
      throw new IllegalArgumentException();
    ciphers = removeDuplicates(ciphers);
    BlockCipherFactory.checkCipherList(ciphers);
    cryptoWishList.s2c_enc_algos = ciphers;
  }

  /**
   * Unless you know what you are doing, you will never need this.
   *
   * @param macs
   */
  public synchronized void setServer2ClientMACs(String[] macs)
  {
    if ((macs == null) || (macs.length == 0))
      throw new IllegalArgumentException();

    macs = removeDuplicates(macs);
    MAC.checkMacList(macs);
    cryptoWishList.s2c_mac_algos = macs;
  }

  /**
   * Define the set of allowed server host key algorithms to be used for
   * the following key exchange operations.
   * <p>
   * Unless you know what you are doing, you will never need this.
   *
   * @param algos An array of allowed server host key algorithms.
   *   SSH-2 defines <code>ssh-dss</code> and <code>ssh-rsa</code>.
   *   The entries of the array must be ordered after preference, i.e.,
   *  the entry at index 0 is the most preferred one. You must specify
   *  at least one entry.
   */
  public synchronized void setServerHostKeyAlgorithms(String[] algos)
  {
    if ((algos == null) || (algos.length == 0))
      throw new IllegalArgumentException();

    algos = removeDuplicates(algos);
    KexManager.checkServerHostkeyAlgorithmsList(algos);
    cryptoWishList.serverHostKeyAlgorithms = algos;
  }

  /**
   * Enable/disable TCP_NODELAY (disable/enable Nagle's algorithm) on the underlying socket.
   * <p>
   * Can be called at any time. If the connection has not yet been established
   * then the passed value will be stored and set after the socket has been set up.
   * The default value that will be used is <code>false</code>.
   *
   * @param enable the argument passed to the <code>Socket.setTCPNoDelay()</code> method.
   * @throws IOException
   */
  public synchronized void setTCPNoDelay(boolean enable) throws IOException
  {
    tcpNoDelay = enable;

    if (tm != null)
      tm.setTcpNoDelay(enable);
  }

  /**
   * Used to tell the library that the connection shall be established through a proxy server.
   * It only makes sense to call this method before calling the {@link #connect() connect()}
   * method.
   * <p>
   * At the moment, only HTTP proxies are supported.
   * <p>
   * Note: This method can be called any number of times. The {@link #connect() connect()}
   * method will use the value set in the last preceding invocation of this method.
   *
   * @see HTTPProxyData
   *
   * @param proxyData Connection information about the proxy. If <code>null</code>, then
   *                  no proxy will be used (non surprisingly, this is also the default).
   */
  public synchronized void setProxyData(ProxyData proxyData)
  {
    this.proxyData = proxyData;
  }

  /**
   * Request a remote port forwarding.
   * If successful, then forwarded connections will be redirected to the given target address.
   * You can cancle a requested remote port forwarding by calling
   * {@link #cancelRemotePortForwarding(int) cancelRemotePortForwarding()}.
   * <p>
   * A call of this method will block until the peer either agreed or disagreed to your request-
   * <p>
   * Note 1: this method typically fails if you
   * <ul>
   * <li>pass a port number for which the used remote user has not enough permissions (i.e., port
   * &lt; 1024)</li>
   * <li>or pass a port number that is already in use on the remote server</li>
   * <li>or if remote port forwarding is disabled on the server.</li>
   * </ul>
   * <p>
   * Note 2: (from the openssh man page): By default, the listening socket on the server will be
   * bound to the loopback interface only. This may be overriden by specifying a bind address.
   * Specifying a remote bind address will only succeed if the server's <b>GatewayPorts</b> option
   * is enabled (see sshd_config(5)).
   *
   * @param bindAddress address to bind to on the server:
   *                    <ul>
   *                    <li>"" means that connections are to be accepted on all protocol families
   *                    supported by the SSH implementation</li>
   *                    <li>"0.0.0.0" means to listen on all IPv4 addresses</li>
   *                    <li>"::" means to listen on all IPv6 addresses</li>
   *                    <li>"localhost" means to listen on all protocol families supported by the SSH
   *                    implementation on loopback addresses only, [RFC3330] and RFC3513]</li>
   *                    <li>"127.0.0.1" and "::1" indicate listening on the loopback interfaces for
   *                    IPv4 and IPv6 respectively</li>
   *                    </ul>
   * @param bindPort port number to bind on the server (must be &gt; 0)
   * @param targetAddress the target address (IP or hostname)
   * @param targetPort the target port
   * @throws IOException
   */
  public synchronized void requestRemotePortForwarding(String bindAddress, int bindPort, String targetAddress,
      int targetPort) throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("You need to establish a connection first.");

    if (!authenticated)
      throw new IllegalStateException("The connection is not authenticated.");

    if ((bindAddress == null) || (targetAddress == null) || (bindPort <= 0) || (targetPort <= 0))
      throw new IllegalArgumentException();

    cm.requestGlobalForward(bindAddress, bindPort, targetAddress, targetPort);
  }

  /**
   * Cancel an earlier requested remote port forwarding.
   * Currently active forwardings will not be affected (e.g., disrupted).
   * Note that further connection forwarding requests may be received until
   * this method has returned.
   *
   * @param bindPort the allocated port number on the server
   * @throws IOException if the remote side refuses the cancel request or another low
   *         level error occurs (e.g., the underlying connection is closed)
   */
  public synchronized void cancelRemotePortForwarding(int bindPort) throws IOException
  {
    if (tm == null)
      throw new IllegalStateException("You need to establish a connection first.");

    if (!authenticated)
      throw new IllegalStateException("The connection is not authenticated.");

    cm.requestCancelGlobalForward(bindPort);
  }

  /**
   * Provide your own instance of SecureRandom. Can be used, e.g., if you
   * want to seed the used SecureRandom generator manually.
   * <p>
   * The SecureRandom instance is used during key exchanges, public key authentication,
   * x11 cookie generation and the like.
   *
   * @param rnd a SecureRandom instance
   */
  public synchronized void setSecureRandom(SecureRandom rnd)
  {
    if (rnd == null)
      throw new IllegalArgumentException();

    this.generator = rnd;
  }
}