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var crypto = require('crypto');
var util = require('util');
var net = require('net');
var events = require('events');
var stream = require('stream');
var assert = process.assert;
var debug;
if (process.env.NODE_DEBUG && /tls/.test(process.env.NODE_DEBUG)) {
debug = function() { util.error.apply(this, arguments); };
} 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.');
}
// Base class of both CleartextStream and EncryptedStream
function CryptoStream (pair) {
stream.Stream.call(this);
this.pair = pair;
this.readable = this.writable = true;
this._writeState = true;
this._pending = [];
this._pendingCallbacks = [];
}
util.inherits(CryptoStream, stream.Stream);
CryptoStream.prototype.write = function(data /* , encoding, cb */) {
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('clearIn data');
this._pending.push(data);
this._pendingCallbacks.push(cb);
this.pair._cycle();
return this._writeState;
};
CryptoStream.prototype.pause = function() {
debug('paused cleartext');
this._writeState = false;
};
CryptoStream.prototype.resume = function() {
debug('resumed cleartext');
this._writeState = true;
};
CryptoStream.prototype.setTimeout = function(n) {
if (this.socket) this.socket.setTimeout(n);
};
function parseCertString (s) {
// EG '/C=US/ST=CA/L=SF/O=Joyent/OU=Node.js/CN=ca1/emailAddress=ry@tinyclouds.org'
var out = {};
var parts = s.split('/');
// Note: can always skip the first one.
for (var i = 1; i < parts.length; 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.getCipher = function(err) {
if (this.pair._ssl) {
return this.pair._ssl.getCurrentCipher();
} else {
return null;
}
};
CryptoStream.prototype.end = function(d) {
if (this.pair._done) return;
if (d) {
this.write(d);
this.pair._cycle();
}
// Sending EOF
debug('cleartext end');
this.pair._ssl.shutdown();
this.pair._cycle();
this.pair._destroy();
};
CryptoStream.prototype.destroySoon = function(err) {
if (this.pair._done) return;
this.pair._cycle();
if (this._pending.length) {
this.__destroyOnDrain = true;
} else {
this.end();
}
};
CryptoStream.prototype.destroy = function(err) {
if (this.pair._done) return;
this.pair._destroy();
};
// 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._blow = function() {
var bytesRead;
var pool;
var chunkBytes;
var chunk;
do {
bytesRead = 0;
chunkBytes = 0;
pool = new Buffer(4096); // alloc every time?
pool.used = 0;
do {
try {
chunkBytes = this._blower(pool,
pool.used + bytesRead,
pool.length - pool.used - bytesRead);
} catch (e) {
if (this.pair._secureEstablished) {
this.pair._error(e);
} else {
this.pair._destroy();
}
return;
}
if (chunkBytes >= 0) {
bytesRead += chunkBytes;
}
} while ((chunkBytes > 0) && (pool.used + bytesRead < pool.length));
if (bytesRead > 0) {
if (this._events && this._events['data']) {
chunk = pool.slice(0, bytesRead);
this.emit('data', chunk);
}
// Optimization: emit the original buffer with end points
if (this.ondata) this.ondata(pool, 0, bytesRead);
}
} while (bytesRead > 0 && this._writeState === true);
};
// 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._suck = function() {
var tmp, cb, rv;
var havePending = this._pending.length > 0;
while (this._pending.length > 0) {
tmp = this._pending.shift();
cb = this._pendingCallbacks.shift();
assert(this._pending.length === this._pendingCallbacks.length);
try {
rv = this._sucker(tmp);
} catch (e) {
if (this.pair._secureEstablished) {
this.pair._error(e);
} else {
this.pair._destroy();
}
return;
}
if (rv === 0) {
this._pending.unshift(tmp);
this._pendingCallbacks.unshift(cb);
break;
}
if (cb) cb();
assert(rv === tmp.length);
}
// If we've cleared all of incoming encrypted data, emit drain.
if (havePending && this._pending && this._pending.length === 0) {
debug('drain');
this.emit('drain');
if (this.__destroyOnDrain) this.end();
}
};
function CleartextStream (pair) {
CryptoStream.call(this, pair);
}
util.inherits(CleartextStream, CryptoStream);
CleartextStream.prototype._sucker = function(b) {
debug('writng from clearIn');
return this.pair._ssl.clearIn(b, 0, b.length);
};
CleartextStream.prototype._blower = function(pool, offset, length) {
debug('reading from clearOut');
if (!this.pair._ssl) return -1;
return this.pair._ssl.clearOut(pool, offset, length);
};
function EncryptedStream (pair) {
CryptoStream.call(this, pair);
}
util.inherits(EncryptedStream, CryptoStream);
EncryptedStream.prototype._sucker = function(b) {
debug('writing from encIn');
return this.pair._ssl.encIn(b, 0, b.length);
};
EncryptedStream.prototype._blower = 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) {
if (!(this instanceof SecurePair)) {
return new SecurePair(credentials,
isServer,
requestCert,
rejectUnauthorized);
}
var self = this;
events.EventEmitter.call(this);
this._secureEstablished = false;
this._isServer = isServer ? true : false;
this._encWriteState = true;
this._clearWriteState = true;
this._done = false;
var crypto = require('crypto');
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._requestCert,
this._rejectUnauthorized);
/* 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() {
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() {
if (this._done) {
return;
}
this.encrypted._suck();
this.cleartext._suck();
this.cleartext._blow();
this.encrypted._blow();
if (this._ssl && !this._secureEstablished && this._ssl.isInitFinished()) {
this._secureEstablished = true;
debug('secure established');
this.emit('secure');
this._cycle();
}
};
SecurePair.prototype._destroy = function(err) {
if (!this._done) {
this._done = true;
this._ssl.close();
this._ssl = null;
this.encrypted.emit('end');
this.encrypted.emit('close');
this.cleartext.emit('end');
this.cleartext.emit('close');
}
this._cycle();
};
SecurePair.prototype._error = function(err) {
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)
14 years ago
function Server(/* [options], listener */) {
var options, listener;
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if (typeof arguments[0] == 'object') {
options = arguments[0];
listener = arguments[1];
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} else if (typeof arguments[0] == 'function') {
options = {};
listener = arguments[0];
}
if (!(this instanceof Server)) return new Server(options, listener);
var self = this;
// constructor call
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net.Server.call(this, function(socket) {
var creds = crypto.createCredentials(
{ key: self.key, cert: self.cert, ca: self.ca });
//creds.context.setCiphers('RC4-SHA:AES128-SHA:AES256-SHA');
var pair = new SecurePair(creds,
true,
self.requestCert,
self.rejectUnauthorized);
pair.encrypted.pipe(socket);
socket.pipe(pair.encrypted);
pair.cleartext.socket = socket;
pair.on('secure', function() {
pair.cleartext.authorized = false;
if (!self.requestCert) {
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 {
self.emit('secureConnection', pair.cleartext, pair.encrypted);
}
} else {
pair.cleartext.authorized = true;
self.emit('secureConnection', pair.cleartext, pair.encrypted);
}
}
});
});
if (listener) {
this.on('secureConnection', listener);
}
// Handle option defaults:
this.setOptions(options);
}
util.inherits(Server, net.Server);
exports.Server = Server;
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exports.createServer = function(options, listener) {
return new Server(options, listener);
};
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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.cert) this.cert = options.cert;
if (options.ca) this.ca = options.ca;
};
// Target API:
//
// var s = tls.connect(8000, "google.com", options, function() {
// if (!s.authorized) {
// s.destroy();
// return;
// }
//
// // s.socket;
//
// s.end("hello world\n");
// });
//
exports.connect = function(port /* host, options, cb */) {
// parse args
var host, options = {}, cb;
switch (typeof arguments[1]) {
case 'string':
host = arguments[1];
if (typeof arguments[2] == 'object') {
options = arguments[2];
if (typeof arguments[3] == 'function') cb = arguments[3];
} else if (typeof arguments[2] == 'function') {
cb = arguments[2];
}
break;
case 'object':
options = arguments[1];
if (typeof arguments[2] == 'function') cb = arguments[2];
break;
case 'function':
cb = arguments[1];
break;
default:
break;
}
var socket = new net.Stream();
var sslcontext = crypto.createCredentials(options);
//sslcontext.context.setCiphers('RC4-SHA:AES128-SHA:AES256-SHA');
var pair = new SecurePair(sslcontext, false);
pair.encrypted.pipe(socket);
socket.pipe(pair.encrypted);
var cleartext = pair.cleartext;
cleartext.socket = socket;
cleartext.encrypted = pair.encrypted;
cleartext.authorized = false;
socket.connect(port, host);
pair.on('secure', function() {
var verifyError = pair._ssl.verifyError();
if (verifyError) {
cleartext.authorized = false;
cleartext.authorizationError = verifyError;
} else {
cleartext.authorized = true;
}
if (cb) cb();
});
return cleartext;
};