/**************************************************************************** ** ** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). ** All rights reserved. ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the QtNetwork module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the Technology Preview License Agreement accompanying ** this package. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** ** ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ //#define QSSLSOCKET_DEBUG #include "qsslsocket_openssl_p.h" #include "qsslsocket_openssl_symbols_p.h" #include "qsslsocket.h" #include "qsslcertificate_p.h" #include "qsslcipher_p.h" #include #include #include #include #include #include #include #include #include #include static void initNetworkResources() { // Initialize resources Q_INIT_RESOURCE(network); } QT_BEGIN_NAMESPACE // Useful defines #define SSL_ERRORSTR() QString::fromLocal8Bit(q_ERR_error_string(q_ERR_get_error(), NULL)) /* \internal From OpenSSL's thread(3) manual page: OpenSSL can safely be used in multi-threaded applications provided that at least two callback functions are set. locking_function(int mode, int n, const char *file, int line) is needed to perform locking on shared data structures. (Note that OpenSSL uses a number of global data structures that will be implicitly shared when-whenever ever multiple threads use OpenSSL.) Multi-threaded applications will crash at random if it is not set. ... ... id_function(void) is a function that returns a thread ID. It is not needed on Windows nor on platforms where getpid() returns a different ID for each thread (most notably Linux) */ class QOpenSslLocks { public: inline QOpenSslLocks() : initLocker(QMutex::Recursive), locksLocker(QMutex::Recursive) { QMutexLocker locker(&locksLocker); int numLocks = q_CRYPTO_num_locks(); locks = new QMutex *[numLocks]; memset(locks, 0, numLocks * sizeof(QMutex *)); } inline ~QOpenSslLocks() { QMutexLocker locker(&locksLocker); for (int i = 0; i < q_CRYPTO_num_locks(); ++i) delete locks[i]; delete [] locks; QSslSocketPrivate::deinitialize(); } inline QMutex *lock(int num) { QMutexLocker locker(&locksLocker); QMutex *tmp = locks[num]; if (!tmp) tmp = locks[num] = new QMutex(QMutex::Recursive); return tmp; } QMutex *globalLock() { return &locksLocker; } QMutex *initLock() { return &initLocker; } private: QMutex initLocker; QMutex locksLocker; QMutex **locks; }; Q_GLOBAL_STATIC(QOpenSslLocks, openssl_locks) extern "C" { static void locking_function(int mode, int lockNumber, const char *, int) { QMutex *mutex = openssl_locks()->lock(lockNumber); // Lock or unlock it if (mode & CRYPTO_LOCK) mutex->lock(); else mutex->unlock(); } static unsigned long id_function() { return (quintptr)QThread::currentThreadId(); } } // extern "C" QSslSocketBackendPrivate::QSslSocketBackendPrivate() : ssl(0), ctx(0), pkey(0), readBio(0), writeBio(0), session(0) { // Calls SSL_library_init(). ensureInitialized(); } QSslSocketBackendPrivate::~QSslSocketBackendPrivate() { } QSslCipher QSslSocketBackendPrivate::QSslCipher_from_SSL_CIPHER(SSL_CIPHER *cipher) { QSslCipher ciph; char buf [256]; QString descriptionOneLine = QString::fromLatin1(q_SSL_CIPHER_description(cipher, buf, sizeof(buf))); QStringList descriptionList = descriptionOneLine.split(QLatin1String(" "), QString::SkipEmptyParts); if (descriptionList.size() > 5) { // ### crude code. ciph.d->isNull = false; ciph.d->name = descriptionList.at(0); QString protoString = descriptionList.at(1); ciph.d->protocolString = protoString; ciph.d->protocol = QSsl::UnknownProtocol; if (protoString == QLatin1String("SSLv3")) ciph.d->protocol = QSsl::SslV3; else if (protoString == QLatin1String("SSLv2")) ciph.d->protocol = QSsl::SslV2; else if (protoString == QLatin1String("TLSv1")) ciph.d->protocol = QSsl::TlsV1; if (descriptionList.at(2).startsWith(QLatin1String("Kx="))) ciph.d->keyExchangeMethod = descriptionList.at(2).mid(3); if (descriptionList.at(3).startsWith(QLatin1String("Au="))) ciph.d->authenticationMethod = descriptionList.at(3).mid(3); if (descriptionList.at(4).startsWith(QLatin1String("Enc="))) ciph.d->encryptionMethod = descriptionList.at(4).mid(4); ciph.d->exportable = (descriptionList.size() > 6 && descriptionList.at(6) == QLatin1String("export")); ciph.d->bits = cipher->strength_bits; ciph.d->supportedBits = cipher->alg_bits; } return ciph; } // ### This list is shared between all threads, and protected by a // mutex. Investigate using thread local storage instead. struct QSslErrorList { QMutex mutex; QList > errors; }; Q_GLOBAL_STATIC(QSslErrorList, _q_sslErrorList) static int q_X509Callback(int ok, X509_STORE_CTX *ctx) { if (!ok) { // Store the error and at which depth the error was detected. _q_sslErrorList()->errors << qMakePair(ctx->error, ctx->error_depth); } // Always return OK to allow verification to continue. We're handle the // errors gracefully after collecting all errors, after verification has // completed. return 1; } bool QSslSocketBackendPrivate::initSslContext() { Q_Q(QSslSocket); // Create and initialize SSL context. Accept SSLv2, SSLv3 and TLSv1. bool client = (mode == QSslSocket::SslClientMode); bool reinitialized = false; init_context: switch (configuration.protocol) { case QSsl::SslV2: ctx = q_SSL_CTX_new(client ? q_SSLv2_client_method() : q_SSLv2_server_method()); break; case QSsl::SslV3: ctx = q_SSL_CTX_new(client ? q_SSLv3_client_method() : q_SSLv3_server_method()); break; case QSsl::AnyProtocol: default: ctx = q_SSL_CTX_new(client ? q_SSLv23_client_method() : q_SSLv23_server_method()); break; case QSsl::TlsV1: ctx = q_SSL_CTX_new(client ? q_TLSv1_client_method() : q_TLSv1_server_method()); break; } if (!ctx) { // After stopping Flash 10 the SSL library looses its ciphers. Try re-adding them // by re-initializing the library. if (!reinitialized) { reinitialized = true; if (q_SSL_library_init() == 1) goto init_context; } // ### Bad error code q->setErrorString(QSslSocket::tr("Error creating SSL context (%1)").arg(SSL_ERRORSTR())); q->setSocketError(QAbstractSocket::UnknownSocketError); emit q->error(QAbstractSocket::UnknownSocketError); return false; } // Enable all bug workarounds. q_SSL_CTX_set_options(ctx, SSL_OP_ALL); // Initialize ciphers QByteArray cipherString; int first = true; QList ciphers = configuration.ciphers; if (ciphers.isEmpty()) ciphers = defaultCiphers(); foreach (const QSslCipher &cipher, ciphers) { if (first) first = false; else cipherString.append(':'); cipherString.append(cipher.name().toLatin1()); } if (!q_SSL_CTX_set_cipher_list(ctx, cipherString.data())) { // ### Bad error code q->setErrorString(QSslSocket::tr("Invalid or empty cipher list (%1)").arg(SSL_ERRORSTR())); q->setSocketError(QAbstractSocket::UnknownSocketError); emit q->error(QAbstractSocket::UnknownSocketError); return false; } // Add all our CAs to this store. foreach (const QSslCertificate &caCertificate, q->caCertificates()) q_X509_STORE_add_cert(ctx->cert_store, (X509 *)caCertificate.handle()); // Register a custom callback to get all verification errors. X509_STORE_set_verify_cb_func(ctx->cert_store, q_X509Callback); if (!configuration.localCertificate.isNull()) { // Require a private key as well. if (configuration.privateKey.isNull()) { q->setErrorString(QSslSocket::tr("Cannot provide a certificate with no key, %1").arg(SSL_ERRORSTR())); emit q->error(QAbstractSocket::UnknownSocketError); return false; } // Load certificate if (!q_SSL_CTX_use_certificate(ctx, (X509 *)configuration.localCertificate.handle())) { q->setErrorString(QSslSocket::tr("Error loading local certificate, %1").arg(SSL_ERRORSTR())); emit q->error(QAbstractSocket::UnknownSocketError); return false; } // Load private key pkey = q_EVP_PKEY_new(); // before we were using EVP_PKEY_assign_R* functions and did not use EVP_PKEY_free. // this lead to a memory leak. Now we use the *_set1_* functions which do not // take ownership of the RSA/DSA key instance because the QSslKey already has ownership. if (configuration.privateKey.algorithm() == QSsl::Rsa) q_EVP_PKEY_set1_RSA(pkey, (RSA *)configuration.privateKey.handle()); else q_EVP_PKEY_set1_DSA(pkey, (DSA *)configuration.privateKey.handle()); if (!q_SSL_CTX_use_PrivateKey(ctx, pkey)) { q->setErrorString(QSslSocket::tr("Error loading private key, %1").arg(SSL_ERRORSTR())); emit q->error(QAbstractSocket::UnknownSocketError); return false; } // Check if the certificate matches the private key. if (!q_SSL_CTX_check_private_key(ctx)) { q->setErrorString(QSslSocket::tr("Private key does not certify public key, %1").arg(SSL_ERRORSTR())); emit q->error(QAbstractSocket::UnknownSocketError); return false; } } // Initialize peer verification. if (configuration.peerVerifyMode == QSslSocket::VerifyNone) { q_SSL_CTX_set_verify(ctx, SSL_VERIFY_NONE, 0); } else { q_SSL_CTX_set_verify(ctx, SSL_VERIFY_PEER, q_X509Callback); } // Set verification depth. if (configuration.peerVerifyDepth != 0) q_SSL_CTX_set_verify_depth(ctx, configuration.peerVerifyDepth); // Create and initialize SSL session if (!(ssl = q_SSL_new(ctx))) { // ### Bad error code q->setErrorString(QSslSocket::tr("Error creating SSL session, %1").arg(SSL_ERRORSTR())); q->setSocketError(QAbstractSocket::UnknownSocketError); emit q->error(QAbstractSocket::UnknownSocketError); return false; } // Clear the session. q_SSL_clear(ssl); errorList.clear(); // Initialize memory BIOs for encryption and decryption. readBio = q_BIO_new(q_BIO_s_mem()); writeBio = q_BIO_new(q_BIO_s_mem()); if (!readBio || !writeBio) { // ### Bad error code q->setErrorString(QSslSocket::tr("Error creating SSL session: %1").arg(SSL_ERRORSTR())); q->setSocketError(QAbstractSocket::UnknownSocketError); emit q->error(QAbstractSocket::UnknownSocketError); return false; } // Assign the bios. q_SSL_set_bio(ssl, readBio, writeBio); if (mode == QSslSocket::SslClientMode) q_SSL_set_connect_state(ssl); else q_SSL_set_accept_state(ssl); return true; } /*! \internal */ void QSslSocketPrivate::deinitialize() { q_CRYPTO_set_id_callback(0); q_CRYPTO_set_locking_callback(0); } /*! \internal Declared static in QSslSocketPrivate, makes sure the SSL libraries have been initialized. */ bool QSslSocketPrivate::ensureInitialized() { if (!q_resolveOpenSslSymbols()) return false; // Check if the library itself needs to be initialized. QMutexLocker locker(openssl_locks()->initLock()); static int q_initialized = false; if (!q_initialized) { q_initialized = true; // Initialize resources initNetworkResources(); // Initialize OpenSSL. q_CRYPTO_set_id_callback(id_function); q_CRYPTO_set_locking_callback(locking_function); if (q_SSL_library_init() != 1) return false; q_SSL_load_error_strings(); q_OpenSSL_add_all_algorithms(); // Initialize OpenSSL's random seed. if (!q_RAND_status()) { struct { int msec; int sec; void *stack; } randomish; int attempts = 500; do { if (attempts < 500) { #ifdef Q_OS_UNIX struct timespec ts = {0, 33333333}; nanosleep(&ts, 0); #else Sleep(3); #endif randomish.msec = attempts; } randomish.stack = (void *)&randomish; randomish.msec = QTime::currentTime().msec(); randomish.sec = QTime::currentTime().second(); q_RAND_seed((const char *)&randomish, sizeof(randomish)); } while (!q_RAND_status() && --attempts); if (!attempts) return false; } resetDefaultCiphers(); setDefaultCaCertificates(systemCaCertificates()); } return true; } /*! \internal Declared static in QSslSocketPrivate, backend-dependent loading of application-wide global ciphers. */ void QSslSocketPrivate::resetDefaultCiphers() { SSL_CTX *myCtx = q_SSL_CTX_new(q_SSLv23_client_method()); SSL *mySsl = q_SSL_new(myCtx); QList ciphers; STACK_OF(SSL_CIPHER) *supportedCiphers = q_SSL_get_ciphers(mySsl); for (int i = 0; i < q_sk_SSL_CIPHER_num(supportedCiphers); ++i) { if (SSL_CIPHER *cipher = q_sk_SSL_CIPHER_value(supportedCiphers, i)) { if (cipher->valid) { QSslCipher ciph = QSslSocketBackendPrivate::QSslCipher_from_SSL_CIPHER(cipher); if (!ciph.isNull()) { if (!ciph.name().toLower().startsWith(QLatin1String("adh"))) ciphers << ciph; } } } } q_SSL_CTX_free(myCtx); q_SSL_free(mySsl); setDefaultSupportedCiphers(ciphers); setDefaultCiphers(ciphers); } QList QSslSocketPrivate::systemCaCertificates() { // Qt provides a default bundle of certificates QFile caBundle(QLatin1String(":/trolltech/network/ssl/qt-ca-bundle.crt")); if (caBundle.open(QIODevice::ReadOnly | QIODevice::Text)) return QSslCertificate::fromDevice(&caBundle); // Unreachable; return no bundle. return QList(); } void QSslSocketBackendPrivate::startClientEncryption() { if (!initSslContext()) { // ### report error: internal OpenSSL failure return; } // Start connecting. This will place outgoing data in the BIO, so we // follow up with calling transmit(). startHandshake(); transmit(); } void QSslSocketBackendPrivate::startServerEncryption() { if (!initSslContext()) { // ### report error: internal OpenSSL failure return; } // Start connecting. This will place outgoing data in the BIO, so we // follow up with calling transmit(). startHandshake(); transmit(); } /*! \internal Transmits encrypted data between the BIOs and the socket. */ void QSslSocketBackendPrivate::transmit() { Q_Q(QSslSocket); // If we don't have any SSL context, don't bother transmitting. if (!ssl) return; bool transmitting; do { transmitting = false; // If the connection is secure, we can transfer data from the write // buffer (in plain text) to the write BIO through SSL_write. if (connectionEncrypted && !writeBuffer.isEmpty()) { qint64 totalBytesWritten = 0; int nextDataBlockSize; while ((nextDataBlockSize = writeBuffer.nextDataBlockSize()) > 0) { int writtenBytes = q_SSL_write(ssl, writeBuffer.readPointer(), nextDataBlockSize); if (writtenBytes <= 0) { // ### Better error handling. q->setErrorString(QSslSocket::tr("Unable to write data: %1").arg(SSL_ERRORSTR())); q->setSocketError(QAbstractSocket::UnknownSocketError); emit q->error(QAbstractSocket::UnknownSocketError); return; } #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: encrypted" << writtenBytes << "bytes"; #endif writeBuffer.free(writtenBytes); totalBytesWritten += writtenBytes; if (writtenBytes < nextDataBlockSize) { // break out of the writing loop and try again after we had read transmitting = true; break; } } if (totalBytesWritten > 0) { // Don't emit bytesWritten() recursively. if (!emittedBytesWritten) { emittedBytesWritten = true; emit q->bytesWritten(totalBytesWritten); emittedBytesWritten = false; } } } // Check if we've got any data to be written to the socket. QVarLengthArray data; int pendingBytes; while (plainSocket->isValid() && (pendingBytes = q_BIO_pending(writeBio)) > 0) { // Read encrypted data from the write BIO into a buffer. data.resize(pendingBytes); int encryptedBytesRead = q_BIO_read(writeBio, data.data(), pendingBytes); // Write encrypted data from the buffer to the socket. plainSocket->write(data.constData(), encryptedBytesRead); #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: wrote" << encryptedBytesRead << "encrypted bytes to the socket"; #endif transmitting = true; } // Check if we've got any data to be read from the socket. if (!connectionEncrypted || !readBufferMaxSize || readBuffer.size() < readBufferMaxSize) while ((pendingBytes = plainSocket->bytesAvailable()) > 0) { // Read encrypted data from the socket into a buffer. data.resize(pendingBytes); // just peek() here because q_BIO_write could write less data than expected int encryptedBytesRead = plainSocket->peek(data.data(), pendingBytes); #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: read" << encryptedBytesRead << "encrypted bytes from the socket"; #endif // Write encrypted data from the buffer into the read BIO. int writtenToBio = q_BIO_write(readBio, data.constData(), encryptedBytesRead); // do the actual read() here and throw away the results. if (writtenToBio > 0) { // ### TODO: make this cheaper by not making it memcpy. E.g. make it work with data=0x0 or make it work with seek plainSocket->read(data.data(), writtenToBio); } else { // ### Better error handling. q->setErrorString(QSslSocket::tr("Unable to decrypt data: %1").arg(SSL_ERRORSTR())); q->setSocketError(QAbstractSocket::UnknownSocketError); emit q->error(QAbstractSocket::UnknownSocketError); return; } transmitting = true; } // If the connection isn't secured yet, this is the time to retry the // connect / accept. if (!connectionEncrypted) { #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: testing encryption"; #endif if (startHandshake()) { #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: encryption established"; #endif connectionEncrypted = true; transmitting = true; } else if (plainSocket->state() != QAbstractSocket::ConnectedState) { #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: connection lost"; #endif break; } else { #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: encryption not done yet"; #endif } } // If the request is small and the remote host closes the transmission // after sending, there's a chance that startHandshake() will already // have triggered a shutdown. if (!ssl) continue; // We always read everything from the SSL decryption buffers, even if // we have a readBufferMaxSize. There's no point in leaving data there // just so that readBuffer.size() == readBufferMaxSize. int readBytes = 0; data.resize(4096); ::memset(data.data(), 0, data.size()); do { // Don't use SSL_pending(). It's very unreliable. if ((readBytes = q_SSL_read(ssl, data.data(), data.size())) > 0) { #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: decrypted" << readBytes << "bytes"; #endif char *ptr = readBuffer.reserve(readBytes); ::memcpy(ptr, data.data(), readBytes); if (readyReadEmittedPointer) *readyReadEmittedPointer = true; emit q->readyRead(); transmitting = true; continue; } // Error. switch (q_SSL_get_error(ssl, readBytes)) { case SSL_ERROR_WANT_READ: case SSL_ERROR_WANT_WRITE: // Out of data. break; case SSL_ERROR_ZERO_RETURN: // The remote host closed the connection. #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::transmit: remote disconnect"; #endif plainSocket->disconnectFromHost(); break; default: // ### Handle errors better. q->setErrorString(QSslSocket::tr("Error while reading: %1").arg(SSL_ERRORSTR())); q->setSocketError(QAbstractSocket::UnknownSocketError); emit q->error(QAbstractSocket::UnknownSocketError); break; } } while (ssl && readBytes > 0); } while (ssl && ctx && transmitting); } static QSslError _q_OpenSSL_to_QSslError(int errorCode, const QSslCertificate &cert) { QSslError error; switch (errorCode) { case X509_V_OK: // X509_V_OK is also reported if the peer had no certificate. break; case X509_V_ERR_UNABLE_TO_GET_ISSUER_CERT: error = QSslError(QSslError::UnableToGetIssuerCertificate, cert); break; case X509_V_ERR_UNABLE_TO_DECRYPT_CERT_SIGNATURE: error = QSslError(QSslError::UnableToDecryptCertificateSignature, cert); break; case X509_V_ERR_UNABLE_TO_DECODE_ISSUER_PUBLIC_KEY: error = QSslError(QSslError::UnableToDecodeIssuerPublicKey, cert); break; case X509_V_ERR_CERT_SIGNATURE_FAILURE: error = QSslError(QSslError::CertificateSignatureFailed, cert); break; case X509_V_ERR_CERT_NOT_YET_VALID: error = QSslError(QSslError::CertificateNotYetValid, cert); break; case X509_V_ERR_CERT_HAS_EXPIRED: error = QSslError(QSslError::CertificateExpired, cert); break; case X509_V_ERR_ERROR_IN_CERT_NOT_BEFORE_FIELD: error = QSslError(QSslError::InvalidNotBeforeField, cert); break; case X509_V_ERR_ERROR_IN_CERT_NOT_AFTER_FIELD: error = QSslError(QSslError::InvalidNotAfterField, cert); break; case X509_V_ERR_DEPTH_ZERO_SELF_SIGNED_CERT: error = QSslError(QSslError::SelfSignedCertificate, cert); break; case X509_V_ERR_SELF_SIGNED_CERT_IN_CHAIN: error = QSslError(QSslError::SelfSignedCertificateInChain, cert); break; case X509_V_ERR_UNABLE_TO_GET_ISSUER_CERT_LOCALLY: error = QSslError(QSslError::UnableToGetLocalIssuerCertificate, cert); break; case X509_V_ERR_UNABLE_TO_VERIFY_LEAF_SIGNATURE: error = QSslError(QSslError::UnableToVerifyFirstCertificate, cert); break; case X509_V_ERR_CERT_REVOKED: error = QSslError(QSslError::CertificateRevoked, cert); break; case X509_V_ERR_INVALID_CA: error = QSslError(QSslError::InvalidCaCertificate, cert); break; case X509_V_ERR_PATH_LENGTH_EXCEEDED: error = QSslError(QSslError::PathLengthExceeded, cert); break; case X509_V_ERR_INVALID_PURPOSE: error = QSslError(QSslError::InvalidPurpose, cert); break; case X509_V_ERR_CERT_UNTRUSTED: error = QSslError(QSslError::CertificateUntrusted, cert); break; case X509_V_ERR_CERT_REJECTED: error = QSslError(QSslError::CertificateRejected, cert); break; default: error = QSslError(QSslError::UnspecifiedError, cert); break; } return error; } bool QSslSocketBackendPrivate::startHandshake() { Q_Q(QSslSocket); // Check if the connection has been established. Get all errors from the // verification stage. _q_sslErrorList()->mutex.lock(); _q_sslErrorList()->errors.clear(); int result = (mode == QSslSocket::SslClientMode) ? q_SSL_connect(ssl) : q_SSL_accept(ssl); const QList > &lastErrors = _q_sslErrorList()->errors; for (int i = 0; i < lastErrors.size(); ++i) { const QPair ¤tError = lastErrors.at(i); // Initialize the peer certificate chain in order to find which certificate caused this error if (configuration.peerCertificateChain.isEmpty()) configuration.peerCertificateChain = STACKOFX509_to_QSslCertificates(q_SSL_get_peer_cert_chain(ssl)); emit q->peerVerifyError(_q_OpenSSL_to_QSslError(currentError.first, configuration.peerCertificateChain.value(currentError.second))); if (q->state() != QAbstractSocket::ConnectedState) break; } errorList << lastErrors; _q_sslErrorList()->mutex.unlock(); // Connection aborted during handshake phase. if (q->state() != QAbstractSocket::ConnectedState) return false; // Check if we're encrypted or not. if (result <= 0) { switch (q_SSL_get_error(ssl, result)) { case SSL_ERROR_WANT_READ: case SSL_ERROR_WANT_WRITE: // The handshake is not yet complete. break; default: // ### Handle errors better q->setErrorString(QSslSocket::tr("Error during SSL handshake: %1").arg(SSL_ERRORSTR())); q->setSocketError(QAbstractSocket::SslHandshakeFailedError); #ifdef QSSLSOCKET_DEBUG qDebug() << "QSslSocketBackendPrivate::startHandshake: error!" << q->errorString(); #endif emit q->error(QAbstractSocket::SslHandshakeFailedError); q->abort(); } return false; } // Store the peer certificate and chain. For clients, the peer certificate // chain includes the peer certificate; for servers, it doesn't. Both the // peer certificate and the chain may be empty if the peer didn't present // any certificate. if (configuration.peerCertificateChain.isEmpty()) configuration.peerCertificateChain = STACKOFX509_to_QSslCertificates(q_SSL_get_peer_cert_chain(ssl)); X509 *x509 = q_SSL_get_peer_certificate(ssl); configuration.peerCertificate = QSslCertificatePrivate::QSslCertificate_from_X509(x509); q_X509_free(x509); // Start translating errors. QList errors; bool doVerifyPeer = configuration.peerVerifyMode == QSslSocket::VerifyPeer || (configuration.peerVerifyMode == QSslSocket::AutoVerifyPeer && mode == QSslSocket::SslClientMode); // Check the peer certificate itself. First try the subject's common name // (CN) as a wildcard, then try all alternate subject name DNS entries the // same way. if (!configuration.peerCertificate.isNull()) { // but only if we're a client connecting to a server // if we're the server, don't check CN if (mode == QSslSocket::SslClientMode) { QString peerName = (verificationPeerName.isEmpty () ? q->peerName() : verificationPeerName); QString commonName = configuration.peerCertificate.subjectInfo(QSslCertificate::CommonName); QRegExp regexp(commonName, Qt::CaseInsensitive, QRegExp::Wildcard); if (!regexp.exactMatch(peerName)) { bool matched = false; foreach (const QString &altName, configuration.peerCertificate .alternateSubjectNames().values(QSsl::DnsEntry)) { regexp.setPattern(altName); if (regexp.exactMatch(peerName)) { matched = true; break; } } if (!matched) { // No matches in common names or alternate names. QSslError error(QSslError::HostNameMismatch, configuration.peerCertificate); errors << error; emit q->peerVerifyError(error); if (q->state() != QAbstractSocket::ConnectedState) return false; } } } } else { // No peer certificate presented. Report as error if the socket // expected one. if (doVerifyPeer) { QSslError error(QSslError::NoPeerCertificate); errors << error; emit q->peerVerifyError(error); if (q->state() != QAbstractSocket::ConnectedState) return false; } } // Translate errors from the error list into QSslErrors. for (int i = 0; i < errorList.size(); ++i) { const QPair &errorAndDepth = errorList.at(i); int err = errorAndDepth.first; int depth = errorAndDepth.second; errors << _q_OpenSSL_to_QSslError(err, configuration.peerCertificateChain.value(depth)); } if (!errors.isEmpty()) { sslErrors = errors; emit q->sslErrors(errors); bool doEmitSslError; if (!ignoreErrorsList.empty()) { // check whether the errors we got are all in the list of expected errors // (applies only if the method QSslSocket::ignoreSslErrors(const QList &errors) // was called) doEmitSslError = false; for (int a = 0; a < errors.count(); a++) { if (!ignoreErrorsList.contains(errors.at(a))) { doEmitSslError = true; break; } } } else { // if QSslSocket::ignoreSslErrors(const QList &errors) was not called and // we get an SSL error, emit a signal unless we ignored all errors (by calling // QSslSocket::ignoreSslErrors() ) doEmitSslError = !ignoreAllSslErrors; } // check whether we need to emit an SSL handshake error if (doVerifyPeer && doEmitSslError) { q->setErrorString(sslErrors.first().errorString()); q->setSocketError(QAbstractSocket::SslHandshakeFailedError); emit q->error(QAbstractSocket::SslHandshakeFailedError); plainSocket->disconnectFromHost(); return false; } } else { sslErrors.clear(); } // if we have a max read buffer size, reset the plain socket's to 1k if (readBufferMaxSize) plainSocket->setReadBufferSize(1024); connectionEncrypted = true; emit q->encrypted(); if (autoStartHandshake && pendingClose) { pendingClose = false; q->disconnectFromHost(); } return true; } void QSslSocketBackendPrivate::disconnectFromHost() { if (ssl) { q_SSL_shutdown(ssl); transmit(); } plainSocket->disconnectFromHost(); } void QSslSocketBackendPrivate::disconnected() { if (ssl) { q_SSL_free(ssl); ssl = 0; } if (ctx) { q_SSL_CTX_free(ctx); ctx = 0; } if (pkey) { q_EVP_PKEY_free(pkey); pkey = 0; } } QSslCipher QSslSocketBackendPrivate::sessionCipher() const { if (!ssl || !ctx) return QSslCipher(); #if OPENSSL_VERSION_NUMBER >= 0x10000000L // FIXME This is fairly evil, but needed to keep source level compatibility // with the OpenSSL 0.9.x implementation at maximum -- some other functions // don't take a const SSL_CIPHER* when they should SSL_CIPHER *sessionCipher = const_cast(q_SSL_get_current_cipher(ssl)); #else SSL_CIPHER *sessionCipher = q_SSL_get_current_cipher(ssl); #endif return sessionCipher ? QSslCipher_from_SSL_CIPHER(sessionCipher) : QSslCipher(); } QList QSslSocketBackendPrivate::STACKOFX509_to_QSslCertificates(STACK_OF(X509) *x509) { ensureInitialized(); QList certificates; for (int i = 0; i < q_sk_X509_num(x509); ++i) { if (X509 *entry = q_sk_X509_value(x509, i)) certificates << QSslCertificatePrivate::QSslCertificate_from_X509(entry); } return certificates; } QT_END_NAMESPACE