node/lib/tls.js

// Copyright Joyent, Inc. and other Node contributors.
//
// Permission is hereby granted, free of charge, to any person obtaining a
// copy of this software and associated documentation files (the
// "Software"), to deal in the Software without restriction, including
// without limitation the rights to use, copy, modify, merge, publish,
// distribute, sublicense, and/or sell copies of the Software, and to permit
// persons to whom the Software is furnished to do so, subject to the
// following conditions:
//
// The above copyright notice and this permission notice shall be included
// in all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
// OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN
// NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
// DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
// OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE
// USE OR OTHER DEALINGS IN THE SOFTWARE.

var crypto = require('crypto');
var util = require('util');
var net = require('net');
var events = require('events');
var stream = require('stream');
var END_OF_FILE = 42;
var assert = require('assert').ok;

var debug;
if (process.env.NODE_DEBUG && /tls/.test(process.env.NODE_DEBUG)) {
  debug = function(a) { console.error('TLS:', a); };
} else {
  debug = function() { };
}


var Connection = null;
try {
  Connection = process.binding('crypto').Connection;
} catch (e) {
  throw new Error('node.js not compiled with openssl crypto support.');
}

// Convert protocols array into valid OpenSSL protocols list
// ("\x06spdy/2\x08http/1.1\x08http/1.0")
function convertNPNProtocols(NPNProtocols, out) {
  // If NPNProtocols is Array - translate it into buffer
  if (Array.isArray(NPNProtocols)) {
    var buff = new Buffer(NPNProtocols.reduce(function(p, c) {
      return p + 1 + Buffer.byteLength(c);
    }, 0));

    NPNProtocols.reduce(function(offset, c) {
      var clen = Buffer.byteLength(c);
      buff[offset] = clen;
      buff.write(c, offset + 1);

      return offset + 1 + clen;
    }, 0);

    NPNProtocols = buff;
  }

  // If it's already a Buffer - store it
  if (Buffer.isBuffer(NPNProtocols)) {
    out.NPNProtocols = NPNProtocols;
  }
}

// Base class of both CleartextStream and EncryptedStream
function CryptoStream(pair) {
  stream.Stream.call(this);

  this.pair = pair;

  this.readable = this.writable = true;

  this._paused = false;
  this._needDrain = false;
  this._pending = [];
  this._pendingCallbacks = [];
  this._pendingBytes = 0;
}
util.inherits(CryptoStream, stream.Stream);


CryptoStream.prototype.write = function(data /* , encoding, cb */) {
  if (this == this.pair.cleartext) {
    debug('cleartext.write called with ' + data.length + ' bytes');
  } else {
    debug('encrypted.write called with ' + data.length + ' bytes');
  }

  if (!this.writable) {
    throw new Error('CryptoStream is not writable');
  }

  var encoding, cb;

  // parse arguments
  if (typeof arguments[1] == 'string') {
    encoding = arguments[1];
    cb = arguments[2];
  } else {
    cb = arguments[1];
  }


  // Transform strings into buffers.
  if (typeof data == 'string') {
    data = new Buffer(data, encoding);
  }

  debug((this === this.pair.cleartext ? 'clear' : 'encrypted') + 'In data');

  this._pending.push(data);
  this._pendingCallbacks.push(cb);
  this._pendingBytes += data.length;

  this.pair._writeCalled = true;
  this.pair.cycle();

  // In the following cases, write() should return a false,
  // then this stream should eventually emit 'drain' event.
  //
  // 1. There are pending data more than 128k bytes.
  // 2. A forward stream shown below is paused.
  //    A) EncryptedStream for CleartextStream.write().
  //    B) CleartextStream for EncryptedStream.write().
  //
  if (!this._needDrain) {
    if (this._pendingBytes >= 128 * 1024) {
      this._needDrain = true;
    } else {
      if (this === this.pair.cleartext) {
        this._needDrain = this.pair.encrypted._paused;
      } else {
        this._needDrain = this.pair.cleartext._paused;
      }
    }
  }
  return !this._needDrain;
};


CryptoStream.prototype.pause = function() {
  debug('paused ' + (this == this.pair.cleartext ? 'cleartext' : 'encrypted'));
  this._paused = true;
};


CryptoStream.prototype.resume = function() {
  debug('resume ' + (this == this.pair.cleartext ? 'cleartext' : 'encrypted'));
  this._paused = false;
  this.pair.cycle();
};


CryptoStream.prototype.setTimeout = function(n) {
  if (this.socket) this.socket.setTimeout(n);
};


CryptoStream.prototype.setNoDelay = function() {
  if (this.socket) this.socket.setNoDelay();
};


CryptoStream.prototype.setEncoding = function(encoding) {
  var StringDecoder = require('string_decoder').StringDecoder; // lazy load
  this._decoder = new StringDecoder(encoding);
};


// Example:
// C=US\nST=CA\nL=SF\nO=Joyent\nOU=Node.js\nCN=ca1\nemailAddress=ry@clouds.org
function parseCertString(s) {
  var out = {};
  var parts = s.split('\n');
  for (var i = 0, len = parts.length; i < len; i++) {
    var sepIndex = parts[i].indexOf('=');
    if (sepIndex > 0) {
      var key = parts[i].slice(0, sepIndex);
      var value = parts[i].slice(sepIndex + 1);
      out[key] = value;
    }
  }
  return out;
}


CryptoStream.prototype.getPeerCertificate = function() {
  if (this.pair.ssl) {
    var c = this.pair.ssl.getPeerCertificate();

    if (c) {
      if (c.issuer) c.issuer = parseCertString(c.issuer);
      if (c.subject) c.subject = parseCertString(c.subject);
      return c;
    }
  }

  return null;
};

CryptoStream.prototype.getSession = function() {
  if (this.pair.ssl) {
    return this.pair.ssl.getSession();
  }

  return null;
};

CryptoStream.prototype.isSessionReused = function() {
  if (this.pair.ssl) {
    return this.pair.ssl.isSessionReused();
  }

  return null;
};

CryptoStream.prototype.getCipher = function(err) {
  if (this.pair.ssl) {
    return this.pair.ssl.getCurrentCipher();
  } else {
    return null;
  }
};


CryptoStream.prototype.end = function(d) {
  if (this.pair._doneFlag) return;
  if (!this.writable) return;

  if (d) {
    this.write(d);
  }

  this._pending.push(END_OF_FILE);
  this._pendingCallbacks.push(null);

  // If this is an encrypted stream then we need to disable further 'data'
  // events.

  this.writable = false;

  this.pair.cycle();
};


CryptoStream.prototype.destroySoon = function(err) {
  if (this.writable) {
    this.end();
  } else {
    this.destroy();
  }
};


CryptoStream.prototype.destroy = function(err) {
  if (this.pair._doneFlag) return;
  this.pair.destroy();
};


CryptoStream.prototype._done = function() {
  this._doneFlag = true;

  if (this.pair.cleartext._doneFlag &&
      this.pair.encrypted._doneFlag &&
      !this.pair._doneFlag) {
    // If both streams are done:
    this.pair.destroy();
  }
};


// readyState is deprecated. Don't use it.
Object.defineProperty(CryptoStream.prototype, 'readyState', {
  get: function() {
    if (this._connecting) {
      return 'opening';
    } else if (this.readable && this.writable) {
      return 'open';
    } else if (this.readable && !this.writable) {
      return 'readOnly';
    } else if (!this.readable && this.writable) {
      return 'writeOnly';
    } else {
      return 'closed';
    }
  }
});


// Move decrypted, clear data out into the application.
// From the user's perspective this occurs as a 'data' event
// on the pair.cleartext.
// also
// Move encrypted data to the stream. From the user's perspective this
// occurs as a 'data' event on the pair.encrypted. Usually the application
// will have some code which pipes the stream to a socket:
//
//   pair.encrypted.on('data', function (d) {
//     socket.write(d);
//   });
//
CryptoStream.prototype._push = function() {
  if (this == this.pair.encrypted && !this.writable) {
    // If the encrypted side got EOF, we do not attempt
    // to write out data anymore.
    return;
  }

  while (!this._paused) {
    var bytesRead = 0;
    var chunkBytes = 0;
    var pool = new Buffer(16 * 4096); // alloc every time?

    do {
      chunkBytes = this._pusher(pool, bytesRead, pool.length - bytesRead);

      if (this.pair.ssl && this.pair.ssl.error) {
        this.pair.error();
        return;
      }

      this.pair.maybeInitFinished();

      if (chunkBytes >= 0) {
        bytesRead += chunkBytes;
      }

    } while (chunkBytes > 0 && bytesRead < pool.length);

    assert(bytesRead >= 0);

    // Bail out if we didn't read any data.
    if (bytesRead == 0) {
      if (this._internallyPendingBytes() == 0 && this._destroyAfterPush) {
        this._done();
      }
      return;
    }

    var chunk = pool.slice(0, bytesRead);

    if (this === this.pair.cleartext) {
      debug('cleartext emit "data" with ' + bytesRead + ' bytes');
    } else {
      debug('encrypted emit "data" with ' + bytesRead + ' bytes');
    }

    if (this._decoder) {
      var string = this._decoder.write(chunk);
      if (string.length) this.emit('data', string);
    } else {
      this.emit('data', chunk);
    }

    // Optimization: emit the original buffer with end points
    if (this.ondata) this.ondata(pool, 0, bytesRead);
  }
};


// Push in any clear data coming from the application.
// This arrives via some code like this:
//
//   pair.cleartext.write("hello world");
//
// also
//
// Push in incoming encrypted data from the socket.
// This arrives via some code like this:
//
//   socket.on('data', function (d) {
//     pair.encrypted.write(d)
//   });
//
CryptoStream.prototype._pull = function() {
  var havePending = this._pending.length > 0;

  assert(havePending || this._pendingBytes == 0);

  while (this._pending.length > 0) {
    if (!this.pair.ssl) break;

    var tmp = this._pending.shift();
    var cb = this._pendingCallbacks.shift();

    assert(this._pending.length === this._pendingCallbacks.length);

    if (tmp === END_OF_FILE) {
      // Sending EOF
      if (this === this.pair.encrypted) {
        debug('end encrypted ' + this.pair.fd);
        this.pair.cleartext._destroyAfterPush = true;
      } else {
        // CleartextStream
        assert(this === this.pair.cleartext);
        debug('end cleartext');

        this.pair.ssl.shutdown();

        // TODO check if we get EAGAIN From shutdown, would have to do it
        // again. should unshift END_OF_FILE back onto pending and wait for
        // next cycle.

        this.pair.encrypted._destroyAfterPush = true;
      }
      this.pair.cycle();
      this._done();
      return;
    }

    if (tmp.length == 0) continue;

    var rv = this._puller(tmp);

    if (this.pair.ssl && this.pair.ssl.error) {
      this.pair.error();
      return;
    }

    this.pair.maybeInitFinished();

    if (rv === 0 || rv < 0) {
      this._pending.unshift(tmp);
      this._pendingCallbacks.unshift(cb);
      break;
    }

    this._pendingBytes -= tmp.length;
    assert(this._pendingBytes >= 0);

    if (cb) cb();

    assert(rv === tmp.length);
  }

  // If pending data has cleared, 'drain' event should be emitted
  // after write() returns a false.
  // Except when a forward stream shown below is paused.
  //   A) EncryptedStream for CleartextStream._pull().
  //   B) CleartextStream for EncryptedStream._pull().
  //
  if (this._needDrain && this._pending.length === 0) {
    var paused;
    if (this === this.pair.cleartext) {
      paused = this.pair.encrypted._paused;
    } else {
      paused = this.pair.cleartext._paused;
    }
    if (!paused) {
      debug('drain ' + (this === this.pair.cleartext ? 'clear' : 'encrypted'));
      var self = this;
      process.nextTick(function() {
        if (typeof self.ondrain === 'function') {
          self.ondrain();
        }
        self.emit('drain');
      });
      this._needDrain = false;
      if (this.__destroyOnDrain) this.end();
    }
  }
};


function CleartextStream(pair) {
  CryptoStream.call(this, pair);
}
util.inherits(CleartextStream, CryptoStream);


CleartextStream.prototype._internallyPendingBytes = function() {
  if (this.pair.ssl) {
    return this.pair.ssl.clearPending();
  } else {
    return 0;
  }
};


CleartextStream.prototype._puller = function(b) {
  debug('clearIn ' + b.length + ' bytes');
  return this.pair.ssl.clearIn(b, 0, b.length);
};


CleartextStream.prototype._pusher = function(pool, offset, length) {
  debug('reading from clearOut');
  if (!this.pair.ssl) return -1;
  return this.pair.ssl.clearOut(pool, offset, length);
};

CleartextStream.prototype.address = function() {
  return this.socket && this.socket.address();
};

CleartextStream.prototype.__defineGetter__('remoteAddress', function() {
  return this.socket && this.socket.remoteAddress;
});


CleartextStream.prototype.__defineGetter__('remotePort', function() {
  return this.socket && this.socket.remotePort;
});


function EncryptedStream(pair) {
  CryptoStream.call(this, pair);
}
util.inherits(EncryptedStream, CryptoStream);


EncryptedStream.prototype._internallyPendingBytes = function() {
  if (this.pair.ssl) {
    return this.pair.ssl.encPending();
  } else {
    return 0;
  }
};


EncryptedStream.prototype._puller = function(b) {
  debug('writing from encIn');
  return this.pair.ssl.encIn(b, 0, b.length);
};


EncryptedStream.prototype._pusher = function(pool, offset, length) {
  debug('reading from encOut');
  if (!this.pair.ssl) return -1;
  return this.pair.ssl.encOut(pool, offset, length);
};


/**
 * Provides a pair of streams to do encrypted communication.
 */

function SecurePair(credentials, isServer, requestCert, rejectUnauthorized,
                    options) {
  if (!(this instanceof SecurePair)) {
    return new SecurePair(credentials,
                          isServer,
                          requestCert,
                          rejectUnauthorized,
                          options);
  }

  var self = this;

  options || (options = {});

  events.EventEmitter.call(this);

  this._secureEstablished = false;
  this._isServer = isServer ? true : false;
  this._encWriteState = true;
  this._clearWriteState = true;
  this._doneFlag = false;

  if (!credentials) {
    this.credentials = crypto.createCredentials();
  } else {
    this.credentials = credentials;
  }

  if (!this._isServer) {
    // For clients, we will always have either a given ca list or be using
    // default one
    requestCert = true;
  }

  this._secureEstablished = false;
  this._rejectUnauthorized = rejectUnauthorized ? true : false;
  this._requestCert = requestCert ? true : false;

  this.ssl = new Connection(this.credentials.context,
      this._isServer ? true : false,
      this._isServer ? this._requestCert : options.servername,
      this._rejectUnauthorized);

  if (process.features.tls_sni) {
    if (this._isServer && options.SNICallback) {
      this.ssl.setSNICallback(options.SNICallback);
    }
    this.servername = null;
  }

  if (process.features.tls_npn && options.NPNProtocols) {
    this.ssl.setNPNProtocols(options.NPNProtocols);
    this.npnProtocol = null;
  }

  /* Acts as a r/w stream to the cleartext side of the stream. */
  this.cleartext = new CleartextStream(this);

  /* Acts as a r/w stream to the encrypted side of the stream. */
  this.encrypted = new EncryptedStream(this);

  process.nextTick(function() {
    /* The Connection may be destroyed by an abort call */
    if (self.ssl) {
      self.ssl.start();
    }
    self.cycle();
  });
}

util.inherits(SecurePair, events.EventEmitter);


exports.createSecurePair = function(credentials,
                                    isServer,
                                    requestCert,
                                    rejectUnauthorized) {
  var pair = new SecurePair(credentials,
                            isServer,
                            requestCert,
                            rejectUnauthorized);
  return pair;
};




/* Attempt to cycle OpenSSLs buffers in various directions.
 *
 * An SSL Connection can be viewed as four separate piplines,
 * interacting with one has no connection to the behavoir of
 * any of the other 3 -- This might not sound reasonable,
 * but consider things like mid-stream renegotiation of
 * the ciphers.
 *
 * The four pipelines, using terminology of the client (server is just
 * reversed):
 *  (1) Encrypted Output stream (Writing encrypted data to peer)
 *  (2) Encrypted Input stream (Reading encrypted data from peer)
 *  (3) Cleartext Output stream (Decrypted content from the peer)
 *  (4) Cleartext Input stream (Cleartext content to send to the peer)
 *
 * This function attempts to pull any available data out of the Cleartext
 * input stream (4), and the Encrypted input stream (2).  Then it pushes any
 * data available from the cleartext output stream (3), and finally from the
 * Encrypted output stream (1)
 *
 * It is called whenever we do something with OpenSSL -- post reciving
 * content, trying to flush, trying to change ciphers, or shutting down the
 * connection.
 *
 * Because it is also called everywhere, we also check if the connection has
 * completed negotiation and emit 'secure' from here if it has.
 */
SecurePair.prototype.cycle = function(depth) {
  if (this._doneFlag) return;

  depth = depth ? depth : 0;

  if (depth == 0) this._writeCalled = false;

  var established = this._secureEstablished;

  if (!this.cycleEncryptedPullLock) {
    this.cycleEncryptedPullLock = true;
    debug('encrypted._pull');
    this.encrypted._pull();
    this.cycleEncryptedPullLock = false;
  }

  if (!this.cycleCleartextPullLock) {
    this.cycleCleartextPullLock = true;
    debug('cleartext._pull');
    this.cleartext._pull();
    this.cycleCleartextPullLock = false;
  }

  if (!this.cycleCleartextPushLock) {
    this.cycleCleartextPushLock = true;
    debug('cleartext._push');
    this.cleartext._push();
    this.cycleCleartextPushLock = false;
  }

  if (!this.cycleEncryptedPushLock) {
    this.cycleEncryptedPushLock = true;
    debug('encrypted._push');
    this.encrypted._push();
    this.cycleEncryptedPushLock = false;
  }

  if ((!established && this._secureEstablished) ||
      (depth == 0 && this._writeCalled)) {
    // If we were not established but now we are, let's cycle again.
    // Or if there is some data to write...
    this.cycle(depth + 1);
  }
};


SecurePair.prototype.maybeInitFinished = function() {
  if (this.ssl && !this._secureEstablished && this.ssl.isInitFinished()) {
    if (process.features.tls_npn) {
      this.npnProtocol = this.ssl.getNegotiatedProtocol();
    }

    if (process.features.tls_sni) {
      this.servername = this.ssl.getServername();
    }

    this._secureEstablished = true;
    debug('secure established');
    this.emit('secure');
  }
};


SecurePair.prototype.destroy = function() {
  var self = this;

  if (!this._doneFlag) {
    this._doneFlag = true;
    this.ssl.error = null;
    this.ssl.close();
    this.ssl = null;

    self.encrypted.writable = self.encrypted.readable = false;
    self.cleartext.writable = self.cleartext.readable = false;

    process.nextTick(function() {
      self.cleartext.emit('end');
      self.encrypted.emit('close');
      self.cleartext.emit('close');
    });
  }
};


SecurePair.prototype.error = function() {
  if (!this._secureEstablished) {
    this.destroy();
  } else {
    var err = this.ssl.error;
    this.ssl.error = null;

    if (this._isServer &&
        this._rejectUnauthorized &&
        /peer did not return a certificate/.test(err.message)) {
      // Not really an error.
      this.destroy();
    } else {
      this.cleartext.emit('error', err);
    }
  }
};

// TODO: support anonymous (nocert) and PSK


// AUTHENTICATION MODES
//
// There are several levels of authentication that TLS/SSL supports.
// Read more about this in "man SSL_set_verify".
//
// 1. The server sends a certificate to the client but does not request a
// cert from the client. This is common for most HTTPS servers. The browser
// can verify the identity of the server, but the server does not know who
// the client is. Authenticating the client is usually done over HTTP using
// login boxes and cookies and stuff.
//
// 2. The server sends a cert to the client and requests that the client
// also send it a cert. The client knows who the server is and the server is
// requesting the client also identify themselves. There are several
// outcomes:
//
//   A) verifyError returns null meaning the client's certificate is signed
//   by one of the server's CAs. The server know's the client idenity now
//   and the client is authorized.
//
//   B) For some reason the client's certificate is not acceptable -
//   verifyError returns a string indicating the problem. The server can
//   either (i) reject the client or (ii) allow the client to connect as an
//   unauthorized connection.
//
// The mode is controlled by two boolean variables.
//
// requestCert
//   If true the server requests a certificate from client connections. For
//   the common HTTPS case, users will want this to be false, which is what
//   it defaults to.
//
// rejectUnauthorized
//   If true clients whose certificates are invalid for any reason will not
//   be allowed to make connections. If false, they will simply be marked as
//   unauthorized but secure communication will continue. By default this is
//   false.
//
//
//
// Options:
// - requestCert. Send verify request. Default to false.
// - rejectUnauthorized. Boolean, default to false.
// - key. string.
// - cert: string.
// - ca: string or array of strings.
//
// emit 'secureConnection'
//   function (cleartextStream, encryptedStream) { }
//
//   'cleartextStream' has the boolean property 'authorized' to determine if
//   it was verified by the CA. If 'authorized' is false, a property
//   'authorizationError' is set on cleartextStream and has the possible
//   values:
//
//   "UNABLE_TO_GET_ISSUER_CERT", "UNABLE_TO_GET_CRL",
//   "UNABLE_TO_DECRYPT_CERT_SIGNATURE", "UNABLE_TO_DECRYPT_CRL_SIGNATURE",
//   "UNABLE_TO_DECODE_ISSUER_PUBLIC_KEY", "CERT_SIGNATURE_FAILURE",
//   "CRL_SIGNATURE_FAILURE", "CERT_NOT_YET_VALID" "CERT_HAS_EXPIRED",
//   "CRL_NOT_YET_VALID", "CRL_HAS_EXPIRED" "ERROR_IN_CERT_NOT_BEFORE_FIELD",
//   "ERROR_IN_CERT_NOT_AFTER_FIELD", "ERROR_IN_CRL_LAST_UPDATE_FIELD",
//   "ERROR_IN_CRL_NEXT_UPDATE_FIELD", "OUT_OF_MEM",
//   "DEPTH_ZERO_SELF_SIGNED_CERT", "SELF_SIGNED_CERT_IN_CHAIN",
//   "UNABLE_TO_GET_ISSUER_CERT_LOCALLY", "UNABLE_TO_VERIFY_LEAF_SIGNATURE",
//   "CERT_CHAIN_TOO_LONG", "CERT_REVOKED" "INVALID_CA",
//   "PATH_LENGTH_EXCEEDED", "INVALID_PURPOSE" "CERT_UNTRUSTED",
//   "CERT_REJECTED"
//
//
// TODO:
// cleartext.credentials (by mirroring from pair object)
// cleartext.getCertificate() (by mirroring from pair.credentials.context)
function Server(/* [options], listener */) {
  var options, listener;
  if (typeof arguments[0] == 'object') {
    options = arguments[0];
    listener = arguments[1];
  } else if (typeof arguments[0] == 'function') {
    options = {};
    listener = arguments[0];
  }

  if (!(this instanceof Server)) return new Server(options, listener);

  var self = this;

  // Handle option defaults:
  this.setOptions(options);

  var sharedCreds = crypto.createCredentials({
    key: self.key,
    passphrase: self.passphrase,
    cert: self.cert,
    ca: self.ca,
    ciphers: self.ciphers || 'RC4-SHA:AES128-SHA:AES256-SHA',
    secureProtocol: self.secureProtocol,
    secureOptions: self.secureOptions,
    crl: self.crl,
    sessionIdContext: self.sessionIdContext
  });

  // constructor call
  net.Server.call(this, function(socket) {
    var creds = crypto.createCredentials(null, sharedCreds.context);

    var pair = new SecurePair(creds,
                              true,
                              self.requestCert,
                              self.rejectUnauthorized,
                              {
                                NPNProtocols: self.NPNProtocols,
                                SNICallback: self.SNICallback
                              });

    var cleartext = pipe(pair, socket);
    cleartext._controlReleased = false;

    pair.on('secure', function() {
      pair.cleartext.authorized = false;
      pair.cleartext.npnProtocol = pair.npnProtocol;
      pair.cleartext.servername = pair.servername;

      if (!self.requestCert) {
        cleartext._controlReleased = true;
        self.emit('secureConnection', pair.cleartext, pair.encrypted);
      } else {
        var verifyError = pair.ssl.verifyError();
        if (verifyError) {
          pair.cleartext.authorizationError = verifyError;

          if (self.rejectUnauthorized) {
            socket.destroy();
            pair.destroy();
          } else {
            cleartext._controlReleased = true;
            self.emit('secureConnection', pair.cleartext, pair.encrypted);
          }
        } else {
          pair.cleartext.authorized = true;
          cleartext._controlReleased = true;
          self.emit('secureConnection', pair.cleartext, pair.encrypted);
        }
      }
    });
  });

  if (listener) {
    this.on('secureConnection', listener);
  }
}

util.inherits(Server, net.Server);
exports.Server = Server;
exports.createServer = function(options, listener) {
  return new Server(options, listener);
};


Server.prototype.setOptions = function(options) {
  if (typeof options.requestCert == 'boolean') {
    this.requestCert = options.requestCert;
  } else {
    this.requestCert = false;
  }

  if (typeof options.rejectUnauthorized == 'boolean') {
    this.rejectUnauthorized = options.rejectUnauthorized;
  } else {
    this.rejectUnauthorized = false;
  }

  if (options.key) this.key = options.key;
  if (options.passphrase) this.passphrase = options.passphrase;
  if (options.cert) this.cert = options.cert;
  if (options.ca) this.ca = options.ca;
  if (options.secureProtocol) this.secureProtocol = options.secureProtocol;
  if (options.crl) this.crl = options.crl;
  if (options.ciphers) this.ciphers = options.ciphers;
  if (options.secureProtocol) this.secureProtocol = options.secureProtocol;
  if (options.secureOptions) this.secureOptions = options.secureOptions;
  if (options.NPNProtocols) convertNPNProtocols(options.NPNProtocols, this);
  if (options.SNICallback) {
    this.SNICallback = options.SNICallback;
  } else {
    this.SNICallback = this.SNICallback.bind(this);
  }
  if (options.sessionIdContext) {
    this.sessionIdContext = options.sessionIdContext;
  } else if (this.requestCert) {
    this.sessionIdContext = crypto.createHash('md5')
                                  .update(process.argv.join(' '))
                                  .digest('hex');
  }
};

// SNI Contexts High-Level API
Server.prototype._contexts = [];
Server.prototype.addContext = function(servername, credentials) {
  if (!servername) {
    throw 'Servername is required parameter for Server.addContext';
  }

  var re = new RegExp('^' +
                      servername.replace(/([\.^$+?\-\\[\]{}])/g, '\\$1')
                                .replace(/\*/g, '.*') +
                      '$');
  this._contexts.push([re, crypto.createCredentials(credentials).context]);
};

Server.prototype.SNICallback = function(servername) {
  var ctx;

  this._contexts.some(function(elem) {
    if (servername.match(elem[0]) !== null) {
      ctx = elem[1];
      return true;
    }
  });

  return ctx;
};


// Target API:
//
//  var s = tls.connect(8000, "google.com", options, function() {
//    if (!s.authorized) {
//      s.destroy();
//      return;
//    }
//
//    // s.socket;
//
//    s.end("hello world\n");
//  });
//
//
// TODO:  make port, host part of options!
exports.connect = function(port /* host, options, cb */) {
  // parse args
  var host, options = {}, cb;
  for (var i = 1; i < arguments.length; i++) {
    switch (typeof arguments[i]) {
      case 'string':
        host = arguments[i];
        break;

      case 'object':
        options = arguments[i];
        break;

      case 'function':
        cb = arguments[i];
        break;
    }
  }

  var socket = new net.Stream();

  var sslcontext = crypto.createCredentials(options);

  convertNPNProtocols(options.NPNProtocols, this);
  var pair = new SecurePair(sslcontext, false, true,
                            options.rejectUnauthorized === true ? true : false,
                            {
                              NPNProtocols: this.NPNProtocols,
                              servername: options.servername || host
                            });

  if (options.session) {
    pair.ssl.setSession(options.session);
  }

  var cleartext = pipe(pair, socket);
  if (cb) {
    cleartext.on('secureConnect', cb);
  }

  socket.connect(port, host);

  pair.on('secure', function() {
    var verifyError = pair.ssl.verifyError();

    cleartext.npnProtocol = pair.npnProtocol;

    if (verifyError) {
      cleartext.authorized = false;
      cleartext.authorizationError = verifyError;

      if (pair._rejectUnauthorized) {
        cleartext.emit('error', verifyError);
        pair.destroy();
      } else {
        cleartext.emit('secureConnect');
      }
    } else {
      cleartext.authorized = true;
      cleartext.emit('secureConnect');
    }
  });

  cleartext._controlReleased = true;
  return cleartext;
};


function pipe(pair, socket) {
  pair.encrypted.pipe(socket);
  socket.pipe(pair.encrypted);

  pair.fd = socket.fd;
  var cleartext = pair.cleartext;
  cleartext.socket = socket;
  cleartext.encrypted = pair.encrypted;
  cleartext.authorized = false;

  function onerror(e) {
    if (cleartext._controlReleased) {
      cleartext.emit('error', e);
    }
  }

  function onclose() {
    socket.removeListener('error', onerror);
    socket.removeListener('end', onclose);
    socket.removeListener('timeout', ontimeout);
  }

  function ontimeout() {
    cleartext.emit('timeout');
  }

  socket.on('error', onerror);
  socket.on('close', onclose);
  socket.on('timeout', ontimeout);

  return cleartext;
}