'use strict'; const assert = require('assert'); const EventEmitter = require('events'); const stream = require('stream'); const tls = require('tls'); const util = require('util'); const common = require('_tls_common'); const debug = util.debuglog('tls-legacy'); const Buffer = require('buffer').Buffer; const Timer = process.binding('timer_wrap').Timer; var Connection = null; try { Connection = process.binding('crypto').Connection; } catch (e) { throw new Error('Node.js is not compiled with openssl crypto support'); } function SlabBuffer() { this.create(); } SlabBuffer.prototype.create = function create() { this.isFull = false; this.pool = new Buffer(tls.SLAB_BUFFER_SIZE); this.offset = 0; this.remaining = this.pool.length; }; SlabBuffer.prototype.use = function use(context, fn, size) { if (this.remaining === 0) { this.isFull = true; return 0; } var actualSize = this.remaining; if (size !== null) actualSize = Math.min(size, actualSize); var bytes = fn.call(context, this.pool, this.offset, actualSize); if (bytes > 0) { this.offset += bytes; this.remaining -= bytes; } assert(this.remaining >= 0); return bytes; }; var slabBuffer = null; // Base class of both CleartextStream and EncryptedStream function CryptoStream(pair, options) { stream.Duplex.call(this, options); this.pair = pair; this._pending = null; this._pendingEncoding = ''; this._pendingCallback = null; this._doneFlag = false; this._retryAfterPartial = false; this._halfRead = false; this._sslOutCb = null; this._resumingSession = false; this._reading = true; this._destroyed = false; this._ended = false; this._finished = false; this._opposite = null; if (slabBuffer === null) slabBuffer = new SlabBuffer(); this._buffer = slabBuffer; this.once('finish', onCryptoStreamFinish); // net.Socket calls .onend too this.once('end', onCryptoStreamEnd); } util.inherits(CryptoStream, stream.Duplex); function onCryptoStreamFinish() { this._finished = true; if (this === this.pair.cleartext) { debug('cleartext.onfinish'); if (this.pair.ssl) { // Generate close notify // NOTE: first call checks if client has sent us shutdown, // second call enqueues shutdown into the BIO. if (this.pair.ssl.shutdownSSL() !== 1) { if (this.pair.ssl && this.pair.ssl.error) return this.pair.error(); this.pair.ssl.shutdownSSL(); } if (this.pair.ssl && this.pair.ssl.error) return this.pair.error(); } } else { debug('encrypted.onfinish'); } // Try to read just to get sure that we won't miss EOF if (this._opposite.readable) this._opposite.read(0); if (this._opposite._ended) { this._done(); // No half-close, sorry if (this === this.pair.cleartext) this._opposite._done(); } } function onCryptoStreamEnd() { this._ended = true; if (this === this.pair.cleartext) { debug('cleartext.onend'); } else { debug('encrypted.onend'); } } // NOTE: Called once `this._opposite` is set. CryptoStream.prototype.init = function init() { var self = this; this._opposite.on('sslOutEnd', function() { if (self._sslOutCb) { var cb = self._sslOutCb; self._sslOutCb = null; cb(null); } }); }; CryptoStream.prototype._write = function write(data, encoding, cb) { assert(this._pending === null); // Black-hole data if (!this.pair.ssl) return cb(null); // When resuming session don't accept any new data. // And do not put too much data into openssl, before writing it from encrypted // side. // // TODO(indutny): Remove magic number, use watermark based limits if (!this._resumingSession && this._opposite._internallyPendingBytes() < 128 * 1024) { // Write current buffer now var written; if (this === this.pair.cleartext) { debug('cleartext.write called with %d bytes', data.length); written = this.pair.ssl.clearIn(data, 0, data.length); } else { debug('encrypted.write called with %d bytes', data.length); written = this.pair.ssl.encIn(data, 0, data.length); } // Handle and report errors if (this.pair.ssl && this.pair.ssl.error) { return cb(this.pair.error(true)); } // Force SSL_read call to cycle some states/data inside OpenSSL this.pair.cleartext.read(0); // Cycle encrypted data if (this.pair.encrypted._internallyPendingBytes()) this.pair.encrypted.read(0); // Get ALPN, NPN and Server name when ready this.pair.maybeInitFinished(); // Whole buffer was written if (written === data.length) { if (this === this.pair.cleartext) { debug('cleartext.write succeed with ' + written + ' bytes'); } else { debug('encrypted.write succeed with ' + written + ' bytes'); } // Invoke callback only when all data read from opposite stream if (this._opposite._halfRead) { assert(this._sslOutCb === null); this._sslOutCb = cb; } else { cb(null); } return; } else if (written !== 0 && written !== -1) { assert(!this._retryAfterPartial); this._retryAfterPartial = true; this._write(data.slice(written), encoding, cb); this._retryAfterPartial = false; return; } } else { debug('cleartext.write queue is full'); // Force SSL_read call to cycle some states/data inside OpenSSL this.pair.cleartext.read(0); } // No write has happened this._pending = data; this._pendingEncoding = encoding; this._pendingCallback = cb; if (this === this.pair.cleartext) { debug('cleartext.write queued with %d bytes', data.length); } else { debug('encrypted.write queued with %d bytes', data.length); } }; CryptoStream.prototype._writePending = function writePending() { const data = this._pending; const encoding = this._pendingEncoding; const cb = this._pendingCallback; this._pending = null; this._pendingEncoding = ''; this._pendingCallback = null; this._write(data, encoding, cb); }; CryptoStream.prototype._read = function read(size) { // XXX: EOF?! if (!this.pair.ssl) return this.push(null); // Wait for session to be resumed // Mark that we're done reading, but don't provide data or EOF if (this._resumingSession || !this._reading) return this.push(''); var out; if (this === this.pair.cleartext) { debug('cleartext.read called with %d bytes', size); out = this.pair.ssl.clearOut; } else { debug('encrypted.read called with %d bytes', size); out = this.pair.ssl.encOut; } var bytesRead = 0; const start = this._buffer.offset; var last = start; do { assert(last === this._buffer.offset); var read = this._buffer.use(this.pair.ssl, out, size - bytesRead); if (read > 0) { bytesRead += read; } last = this._buffer.offset; // Handle and report errors if (this.pair.ssl && this.pair.ssl.error) { this.pair.error(); break; } } while (read > 0 && !this._buffer.isFull && bytesRead < size && this.pair.ssl !== null); // Get ALPN, NPN and Server name when ready this.pair.maybeInitFinished(); // Create new buffer if previous was filled up var pool = this._buffer.pool; if (this._buffer.isFull) this._buffer.create(); assert(bytesRead >= 0); if (this === this.pair.cleartext) { debug('cleartext.read succeed with %d bytes', bytesRead); } else { debug('encrypted.read succeed with %d bytes', bytesRead); } // Try writing pending data if (this._pending !== null) this._writePending(); if (this._opposite._pending !== null) this._opposite._writePending(); if (bytesRead === 0) { // EOF when cleartext has finished and we have nothing to read if (this._opposite._finished && this._internallyPendingBytes() === 0 || this.pair.ssl && this.pair.ssl.receivedShutdown) { // Perform graceful shutdown this._done(); // No half-open, sorry! if (this === this.pair.cleartext) { this._opposite._done(); // EOF this.push(null); } else if (!this.pair.ssl || !this.pair.ssl.receivedShutdown) { // EOF this.push(null); } } else { // Bail out this.push(''); } } else { // Give them requested data this.push(pool.slice(start, start + bytesRead)); } // Let users know that we've some internal data to read var halfRead = this._internallyPendingBytes() !== 0; // Smart check to avoid invoking 'sslOutEnd' in the most of the cases if (this._halfRead !== halfRead) { this._halfRead = halfRead; // Notify listeners about internal data end if (!halfRead) { if (this === this.pair.cleartext) { debug('cleartext.sslOutEnd'); } else { debug('encrypted.sslOutEnd'); } this.emit('sslOutEnd'); } } }; CryptoStream.prototype.setTimeout = function(timeout, callback) { if (this.socket) this.socket.setTimeout(timeout, callback); }; CryptoStream.prototype.setNoDelay = function(noDelay) { if (this.socket) this.socket.setNoDelay(noDelay); }; CryptoStream.prototype.setKeepAlive = function(enable, initialDelay) { if (this.socket) this.socket.setKeepAlive(enable, initialDelay); }; CryptoStream.prototype.__defineGetter__('bytesWritten', function() { return this.socket ? this.socket.bytesWritten : 0; }); CryptoStream.prototype.getPeerCertificate = function(detailed) { if (this.pair.ssl) { return common.translatePeerCertificate( this.pair.ssl.getPeerCertificate(detailed)); } 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(chunk, encoding) { if (this === this.pair.cleartext) { debug('cleartext.end'); } else { debug('encrypted.end'); } // Write pending data first if (this._pending !== null) this._writePending(); this.writable = false; stream.Duplex.prototype.end.call(this, chunk, encoding); }; CryptoStream.prototype.destroySoon = function(err) { if (this === this.pair.cleartext) { debug('cleartext.destroySoon'); } else { debug('encrypted.destroySoon'); } if (this.writable) this.end(); if (this._writableState.finished && this._opposite._ended) { this.destroy(); } else { // Wait for both `finish` and `end` events to ensure that all data that // was written on this side was read from the other side. var self = this; var waiting = 1; var finish = function() { if (--waiting === 0) self.destroy(); }; this._opposite.once('end', finish); if (!this._finished) { this.once('finish', finish); ++waiting; } } }; CryptoStream.prototype.destroy = function(err) { if (this._destroyed) return; this._destroyed = true; this.readable = this.writable = false; // Destroy both ends if (this === this.pair.cleartext) { debug('cleartext.destroy'); } else { debug('encrypted.destroy'); } this._opposite.destroy(); process.nextTick(destroyNT, this, err ? true : false); }; function destroyNT(self, hadErr) { // Force EOF self.push(null); // Emit 'close' event self.emit('close', hadErr); } CryptoStream.prototype._done = function() { this._doneFlag = true; if (this === this.pair.encrypted && !this.pair._secureEstablished) return this.pair.error(); 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'; } } }); function CleartextStream(pair, options) { CryptoStream.call(this, pair, options); // This is a fake kludge to support how the http impl sits // on top of net Sockets var self = this; this._handle = { readStop: function() { self._reading = false; }, readStart: function() { if (self._reading && self._readableState.length > 0) return; self._reading = true; self.read(0); if (self._opposite.readable) self._opposite.read(0); } }; } util.inherits(CleartextStream, CryptoStream); CleartextStream.prototype._internallyPendingBytes = function() { if (this.pair.ssl) { return this.pair.ssl.clearPending(); } else { return 0; } }; CleartextStream.prototype.address = function() { return this.socket && this.socket.address(); }; CleartextStream.prototype.__defineGetter__('remoteAddress', function() { return this.socket && this.socket.remoteAddress; }); CleartextStream.prototype.__defineGetter__('remoteFamily', function() { return this.socket && this.socket.remoteFamily; }); CleartextStream.prototype.__defineGetter__('remotePort', function() { return this.socket && this.socket.remotePort; }); CleartextStream.prototype.__defineGetter__('localAddress', function() { return this.socket && this.socket.localAddress; }); CleartextStream.prototype.__defineGetter__('localPort', function() { return this.socket && this.socket.localPort; }); function EncryptedStream(pair, options) { CryptoStream.call(this, pair, options); } util.inherits(EncryptedStream, CryptoStream); EncryptedStream.prototype._internallyPendingBytes = function() { if (this.pair.ssl) { return this.pair.ssl.encPending(); } else { return 0; } }; function onhandshakestart() { debug('onhandshakestart'); var self = this; var ssl = self.ssl; var now = Timer.now(); assert(now >= ssl.lastHandshakeTime); if ((now - ssl.lastHandshakeTime) >= tls.CLIENT_RENEG_WINDOW * 1000) { ssl.handshakes = 0; } var first = (ssl.lastHandshakeTime === 0); ssl.lastHandshakeTime = now; if (first) return; if (++ssl.handshakes > tls.CLIENT_RENEG_LIMIT) { // Defer the error event to the next tick. We're being called from OpenSSL's // state machine and OpenSSL is not re-entrant. We cannot allow the user's // callback to destroy the connection right now, it would crash and burn. setImmediate(function() { var err = new Error('TLS session renegotiation attack detected'); if (self.cleartext) self.cleartext.emit('error', err); }); } } function onhandshakedone() { // for future use debug('onhandshakedone'); } function onclienthello(hello) { const self = this; var once = false; this._resumingSession = true; function callback(err, session) { if (once) return; once = true; if (err) return self.socket.destroy(err); setImmediate(function() { self.ssl.loadSession(session); self.ssl.endParser(); // Cycle data self._resumingSession = false; self.cleartext.read(0); self.encrypted.read(0); }); } if (hello.sessionId.length <= 0 || !this.server || !this.server.emit('resumeSession', hello.sessionId, callback)) { callback(null, null); } } function onnewsession(key, session) { if (!this.server) return; var self = this; var once = false; if (!self.server.emit('newSession', key, session, done)) done(); function done() { if (once) return; once = true; if (self.ssl) self.ssl.newSessionDone(); } } function onocspresponse(resp) { this.emit('OCSPResponse', resp); } /** * Provides a pair of streams to do encrypted communication. */ function SecurePair(context, isServer, requestCert, rejectUnauthorized, options) { if (!(this instanceof SecurePair)) { return new SecurePair(context, isServer, requestCert, rejectUnauthorized, options); } options || (options = {}); EventEmitter.call(this); this.server = options.server; this._secureEstablished = false; this._isServer = isServer ? true : false; this._encWriteState = true; this._clearWriteState = true; this._doneFlag = false; this._destroying = false; if (!context) { this.credentials = tls.createSecureContext(); } else { this.credentials = context; } if (!this._isServer) { // For clients, we will always have either a given ca list or be using // default one requestCert = true; } 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 (this._isServer) { this.ssl.onhandshakestart = () => onhandshakestart.call(this); this.ssl.onhandshakedone = () => onhandshakedone.call(this); this.ssl.onclienthello = (hello) => onclienthello.call(this, hello); this.ssl.onnewsession = (key, session) => onnewsession.call(this, key, session); this.ssl.lastHandshakeTime = 0; this.ssl.handshakes = 0; } else { this.ssl.onocspresponse = (resp) => onocspresponse.call(this, resp); } 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; } if (process.features.tls_alpn && options.ALPNProtocols) { // keep reference in secureContext not to be GC-ed this.ssl._secureContext.alpnBuffer = options.ALPNProtocols; this.ssl.setALPNrotocols(this.ssl._secureContext.alpnBuffer); this.alpnProtocol = null; } /* Acts as a r/w stream to the cleartext side of the stream. */ this.cleartext = new CleartextStream(this, options.cleartext); /* Acts as a r/w stream to the encrypted side of the stream. */ this.encrypted = new EncryptedStream(this, options.encrypted); /* Let streams know about each other */ this.cleartext._opposite = this.encrypted; this.encrypted._opposite = this.cleartext; this.cleartext.init(); this.encrypted.init(); process.nextTick(securePairNT, this, options); } util.inherits(SecurePair, EventEmitter); function securePairNT(self, options) { /* The Connection may be destroyed by an abort call */ if (self.ssl) { self.ssl.start(); if (options.requestOCSP) self.ssl.requestOCSP(); /* In case of cipher suite failures - SSL_accept/SSL_connect may fail */ if (self.ssl && self.ssl.error) self.error(); } } exports.createSecurePair = function(context, isServer, requestCert, rejectUnauthorized, options) { var pair = new SecurePair(context, isServer, requestCert, rejectUnauthorized, options); return pair; }; 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_alpn) { this.alpnProtocol = this.ssl.getALPNNegotiatedProtocol(); } if (process.features.tls_sni) { this.servername = this.ssl.getServername(); } this._secureEstablished = true; debug('secure established'); this.emit('secure'); } }; SecurePair.prototype.destroy = function() { if (this._destroying) return; if (!this._doneFlag) { debug('SecurePair.destroy'); this._destroying = true; // SecurePair should be destroyed only after it's streams this.cleartext.destroy(); this.encrypted.destroy(); this._doneFlag = true; this.ssl.error = null; this.ssl.close(); this.ssl = null; } }; SecurePair.prototype.error = function(returnOnly) { var err = this.ssl.error; this.ssl.error = null; if (!this._secureEstablished) { // Emit ECONNRESET instead of zero return if (!err || err.message === 'ZERO_RETURN') { var connReset = new Error('socket hang up'); connReset.code = 'ECONNRESET'; connReset.sslError = err && err.message; err = connReset; } this.destroy(); if (!returnOnly) this.emit('error', err); } else if (this._isServer && this._rejectUnauthorized && /peer did not return a certificate/.test(err.message)) { // Not really an error. this.destroy(); } else { if (!returnOnly) this.cleartext.emit('error', err); } return err; }; exports.pipe = function pipe(pair, socket) { pair.encrypted.pipe(socket); socket.pipe(pair.encrypted); pair.encrypted.on('close', function() { process.nextTick(pipeCloseNT, pair, socket); }); pair.fd = socket.fd; var cleartext = pair.cleartext; cleartext.socket = socket; cleartext.encrypted = pair.encrypted; cleartext.authorized = false; // cycle the data whenever the socket drains, so that // we can pull some more into it. normally this would // be handled by the fact that pipe() triggers read() calls // on writable.drain, but CryptoStreams are a bit more // complicated. Since the encrypted side actually gets // its data from the cleartext side, we have to give it a // light kick to get in motion again. socket.on('drain', function() { if (pair.encrypted._pending) pair.encrypted._writePending(); if (pair.cleartext._pending) pair.cleartext._writePending(); pair.encrypted.read(0); pair.cleartext.read(0); }); function onerror(e) { if (cleartext._controlReleased) { cleartext.emit('error', e); } } function onclose() { socket.removeListener('error', onerror); socket.removeListener('timeout', ontimeout); } function ontimeout() { cleartext.emit('timeout'); } socket.on('error', onerror); socket.on('close', onclose); socket.on('timeout', ontimeout); return cleartext; }; function pipeCloseNT(pair, socket) { // Encrypted should be unpiped from socket to prevent possible // write after destroy. pair.encrypted.unpipe(socket); socket.destroySoon(); }