/**************************************************************************** ** ** 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. ** ** ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include QT_BEGIN_NAMESPACE #include "../../3rdparty/des/des.cpp" static QByteArray qNtlmPhase1(); static QByteArray qNtlmPhase3(QAuthenticatorPrivate *ctx, const QByteArray& phase2data); /*! \class QAuthenticator \brief The QAuthenticator class provides an authentication object. \since 4.3 \reentrant \ingroup network \inmodule QtNetwork The QAuthenticator class is usually used in the \l{QNetworkAccessManager::}{authenticationRequired()} and \l{QNetworkAccessManager::}{proxyAuthenticationRequired()} signals of QNetworkAccessManager and QAbstractSocket. The class provides a way to pass back the required authentication information to the socket when accessing services that require authentication. QAuthenticator supports the following authentication methods: \list \o Basic \o NTLM version 1 \o Digest-MD5 \endlist Note that, in particular, NTLM version 2 is not supported. \section1 Options In addition to the username and password required for authentication, a QAuthenticator object can also contain additional options. The options() function can be used to query incoming options sent by the server; the setOption() function can be used to set outgoing options, to be processed by the authenticator calculation. The options accepted and provided depend on the authentication type (see method()). The following tables list known incoming options as well as accepted outgoing options. The list of incoming options is not exhaustive, since servers may include additional information at any time. The list of outgoing options is exhaustive, however, and no unknown options will be treated or sent back to the server. \section2 Basic \table \header \o Option \o Direction \o Description \row \o \tt{realm} \o Incoming \o Contains the realm of the authentication, the same as realm() \endtable The Basic authentication mechanism supports no outgoing options. \section2 NTLM version 1 The NTLM authentication mechanism currently supports no incoming or outgoing options. \section2 Digest-MD5 \table \header \o Option \o Direction \o Description \row \o \tt{realm} \o Incoming \o Contains the realm of the authentication, the same as realm() \endtable The Digest-MD5 authentication mechanism supports no outgoing options. \sa QSslSocket */ /*! Constructs an empty authentication object */ QAuthenticator::QAuthenticator() : d(0) { } /*! Destructs the object */ QAuthenticator::~QAuthenticator() { if (d && !d->ref.deref()) delete d; } /*! Constructs a copy of \a other. */ QAuthenticator::QAuthenticator(const QAuthenticator &other) : d(other.d) { if (d) d->ref.ref(); } /*! Assigns the contents of \a other to this authenticator. */ QAuthenticator &QAuthenticator::operator=(const QAuthenticator &other) { if (d == other.d) return *this; detach(); d->user = other.d->user; d->password = other.d->password; return *this; } /*! Returns true if this authenticator is identical to \a other; otherwise returns false. */ bool QAuthenticator::operator==(const QAuthenticator &other) const { if (d == other.d) return true; return d->user == other.d->user && d->password == other.d->password && d->realm == other.d->realm && d->method == other.d->method && d->options == other.d->options; } /*! \fn bool QAuthenticator::operator!=(const QAuthenticator &other) const Returns true if this authenticator is different from \a other; otherwise returns false. */ /*! returns the user used for authentication. */ QString QAuthenticator::user() const { return d ? d->user : QString(); } /*! Sets the \a user used for authentication. */ void QAuthenticator::setUser(const QString &user) { detach(); int separatorPosn = 0; separatorPosn = user.indexOf(QLatin1String("\\")); if (separatorPosn == -1) { //No domain name present d->user = user; } else { //domain name is present d->realm = user.left(separatorPosn); d->user = user.mid(separatorPosn+1); } } /*! returns the password used for authentication. */ QString QAuthenticator::password() const { return d ? d->password : QString(); } /*! Sets the \a password used for authentication. */ void QAuthenticator::setPassword(const QString &password) { detach(); d->password = password; } /*! \internal */ void QAuthenticator::detach() { if (!d) { d = new QAuthenticatorPrivate; d->ref = 1; return; } qAtomicDetach(d); d->phase = QAuthenticatorPrivate::Start; } /*! returns the realm requiring authentication. */ QString QAuthenticator::realm() const { return d ? d->realm : QString(); } /*! \since 4.7 Returns the value related to option \a opt if it was set by the server. See \l{QAuthenticator#Options} for more information on incoming options. If option \a opt isn't found, an invalid QVariant will be returned. \sa options(), QAuthenticator#Options */ QVariant QAuthenticator::option(const QString &opt) const { return d ? d->options.value(opt) : QVariant(); } /*! \since 4.7 Returns all incoming options set in this QAuthenticator object by parsing the server reply. See \l{QAuthenticator#Options} for more information on incoming options. \sa option(), QAuthenticator#Options */ QVariantHash QAuthenticator::options() const { return d ? d->options : QVariantHash(); } /*! \since 4.7 Sets the outgoing option \a opt to value \a value. See \l{QAuthenticator#Options} for more information on outgoing options. \sa options(), option(), QAuthenticator#Options */ void QAuthenticator::setOption(const QString &opt, const QVariant &value) { detach(); d->options.insert(opt, value); } /*! Returns true if the authenticator is null. */ bool QAuthenticator::isNull() const { return !d; } QAuthenticatorPrivate::QAuthenticatorPrivate() : ref(0) , method(None) , phase(Start) , nonceCount(0) { cnonce = QCryptographicHash::hash(QByteArray::number(qrand(), 16) + QByteArray::number(qrand(), 16), QCryptographicHash::Md5).toHex(); nonceCount = 0; } #ifndef QT_NO_HTTP void QAuthenticatorPrivate::parseHttpResponse(const QHttpResponseHeader &header, bool isProxy) { const QList > values = header.values(); QList > rawValues; QList >::const_iterator it, end; for (it = values.constBegin(), end = values.constEnd(); it != end; ++it) rawValues.append(qMakePair(it->first.toLatin1(), it->second.toUtf8())); // continue in byte array form parseHttpResponse(rawValues, isProxy); } #endif void QAuthenticatorPrivate::parseHttpResponse(const QList > &values, bool isProxy) { const char *search = isProxy ? "proxy-authenticate" : "www-authenticate"; method = None; /* Fun from the HTTP 1.1 specs, that we currently ignore: User agents are advised to take special care in parsing the WWW- Authenticate field value as it might contain more than one challenge, or if more than one WWW-Authenticate header field is provided, the contents of a challenge itself can contain a comma-separated list of authentication parameters. */ QByteArray headerVal; for (int i = 0; i < values.size(); ++i) { const QPair ¤t = values.at(i); if (current.first.toLower() != search) continue; QByteArray str = current.second.toLower(); if (method < Basic && str.startsWith("basic")) { method = Basic; headerVal = current.second.mid(6); } else if (method < Ntlm && str.startsWith("ntlm")) { method = Ntlm; headerVal = current.second.mid(5); } else if (method < DigestMd5 && str.startsWith("digest")) { method = DigestMd5; headerVal = current.second.mid(7); } } challenge = headerVal.trimmed(); QHash options = parseDigestAuthenticationChallenge(challenge); switch(method) { case Basic: if(realm.isEmpty()) this->options[QLatin1String("realm")] = realm = QString::fromLatin1(options.value("realm")); if (user.isEmpty()) phase = Done; break; case Ntlm: // #### extract from header break; case DigestMd5: { if(realm.isEmpty()) this->options[QLatin1String("realm")] = realm = QString::fromLatin1(options.value("realm")); if (options.value("stale").toLower() == "true") phase = Start; if (user.isEmpty()) phase = Done; break; } default: realm.clear(); challenge = QByteArray(); phase = Invalid; } } QByteArray QAuthenticatorPrivate::calculateResponse(const QByteArray &requestMethod, const QByteArray &path) { QByteArray response; const char *methodString = 0; switch(method) { case QAuthenticatorPrivate::None: methodString = ""; phase = Done; break; case QAuthenticatorPrivate::Plain: response = '\0' + user.toUtf8() + '\0' + password.toUtf8(); phase = Done; break; case QAuthenticatorPrivate::Basic: methodString = "Basic "; response = user.toLatin1() + ':' + password.toLatin1(); response = response.toBase64(); phase = Done; break; case QAuthenticatorPrivate::Login: if (challenge.contains("VXNlciBOYW1lAA==")) { response = user.toUtf8().toBase64(); phase = Phase2; } else if (challenge.contains("UGFzc3dvcmQA")) { response = password.toUtf8().toBase64(); phase = Done; } break; case QAuthenticatorPrivate::CramMd5: break; case QAuthenticatorPrivate::DigestMd5: methodString = "Digest "; response = digestMd5Response(challenge, requestMethod, path); phase = Done; break; case QAuthenticatorPrivate::Ntlm: methodString = "NTLM "; if (challenge.isEmpty()) { response = qNtlmPhase1().toBase64(); if (user.isEmpty()) phase = Done; else phase = Phase2; } else { response = qNtlmPhase3(this, QByteArray::fromBase64(challenge)).toBase64(); phase = Done; } break; } return QByteArray(methodString) + response; } // ---------------------------- Digest Md5 code ---------------------------------------- QHash QAuthenticatorPrivate::parseDigestAuthenticationChallenge(const QByteArray &challenge) { QHash options; // parse the challenge const char *d = challenge.constData(); const char *end = d + challenge.length(); while (d < end) { while (d < end && (*d == ' ' || *d == '\n' || *d == '\r')) ++d; const char *start = d; while (d < end && *d != '=') ++d; QByteArray key = QByteArray(start, d - start); ++d; if (d >= end) break; bool quote = (*d == '"'); if (quote) ++d; if (d >= end) break; start = d; QByteArray value; while (d < end) { bool backslash = false; if (*d == '\\' && d < end - 1) { ++d; backslash = true; } if (!backslash) { if (quote) { if (*d == '"') break; } else { if (*d == ',') break; } } value += *d; ++d; } while (d < end && *d != ',') ++d; ++d; options[key] = value; } QByteArray qop = options.value("qop"); if (!qop.isEmpty()) { QList qopoptions = qop.split(','); if (!qopoptions.contains("auth")) return QHash(); // #### can't do auth-int currently // if (qop.contains("auth-int")) // qop = "auth-int"; // else if (qop.contains("auth")) // qop = "auth"; // else // qop = QByteArray(); options["qop"] = "auth"; } return options; } /* Digest MD5 implementation Code taken from RFC 2617 Currently we don't support the full SASL authentication mechanism (which includes cyphers) */ /* calculate request-digest/response-digest as per HTTP Digest spec */ static QByteArray digestMd5ResponseHelper( const QByteArray &alg, const QByteArray &userName, const QByteArray &realm, const QByteArray &password, const QByteArray &nonce, /* nonce from server */ const QByteArray &nonceCount, /* 8 hex digits */ const QByteArray &cNonce, /* client nonce */ const QByteArray &qop, /* qop-value: "", "auth", "auth-int" */ const QByteArray &method, /* method from the request */ const QByteArray &digestUri, /* requested URL */ const QByteArray &hEntity /* H(entity body) if qop="auth-int" */ ) { QCryptographicHash hash(QCryptographicHash::Md5); hash.addData(userName); hash.addData(":", 1); hash.addData(realm); hash.addData(":", 1); hash.addData(password); QByteArray ha1 = hash.result(); if (alg.toLower() == "md5-sess") { hash.reset(); // RFC 2617 contains an error, it was: // hash.addData(ha1); // but according to the errata page at http://www.rfc-editor.org/errata_list.php, ID 1649, it // must be the following line: hash.addData(ha1.toHex()); hash.addData(":", 1); hash.addData(nonce); hash.addData(":", 1); hash.addData(cNonce); ha1 = hash.result(); }; ha1 = ha1.toHex(); // calculate H(A2) hash.reset(); hash.addData(method); hash.addData(":", 1); hash.addData(digestUri); if (qop.toLower() == "auth-int") { hash.addData(":", 1); hash.addData(hEntity); } QByteArray ha2hex = hash.result().toHex(); // calculate response hash.reset(); hash.addData(ha1); hash.addData(":", 1); hash.addData(nonce); hash.addData(":", 1); if (!qop.isNull()) { hash.addData(nonceCount); hash.addData(":", 1); hash.addData(cNonce); hash.addData(":", 1); hash.addData(qop); hash.addData(":", 1); } hash.addData(ha2hex); return hash.result().toHex(); } QByteArray QAuthenticatorPrivate::digestMd5Response(const QByteArray &challenge, const QByteArray &method, const QByteArray &path) { QHash options = parseDigestAuthenticationChallenge(challenge); ++nonceCount; QByteArray nonceCountString = QByteArray::number(nonceCount, 16); while (nonceCountString.length() < 8) nonceCountString.prepend('0'); QByteArray nonce = options.value("nonce"); QByteArray opaque = options.value("opaque"); QByteArray qop = options.value("qop"); // qDebug() << "calculating digest: method=" << method << "path=" << path; QByteArray response = digestMd5ResponseHelper(options.value("algorithm"), user.toLatin1(), realm.toLatin1(), password.toLatin1(), nonce, nonceCountString, cnonce, qop, method, path, QByteArray()); QByteArray credentials; credentials += "username=\"" + user.toLatin1() + "\", "; credentials += "realm=\"" + realm.toLatin1() + "\", "; credentials += "nonce=\"" + nonce + "\", "; credentials += "uri=\"" + path + "\", "; if (!opaque.isEmpty()) credentials += "opaque=\"" + opaque + "\", "; credentials += "response=\"" + response + '\"'; if (!options.value("algorithm").isEmpty()) credentials += ", algorithm=" + options.value("algorithm"); if (!options.value("qop").isEmpty()) { credentials += ", qop=" + qop + ", "; credentials += "nc=" + nonceCountString + ", "; credentials += "cnonce=\"" + cnonce + '\"'; } return credentials; } // ---------------------------- Digest Md5 code ---------------------------------------- /* * NTLM message flags. * * Copyright (c) 2004 Andrey Panin * * This software is released under the MIT license. */ /* * Indicates that Unicode strings are supported for use in security * buffer data. */ #define NTLMSSP_NEGOTIATE_UNICODE 0x00000001 /* * Indicates that OEM strings are supported for use in security buffer data. */ #define NTLMSSP_NEGOTIATE_OEM 0x00000002 /* * Requests that the server's authentication realm be included in the * Type 2 message. */ #define NTLMSSP_REQUEST_TARGET 0x00000004 /* * Specifies that authenticated communication between the client and server * should carry a digital signature (message integrity). */ #define NTLMSSP_NEGOTIATE_SIGN 0x00000010 /* * Specifies that authenticated communication between the client and server * should be encrypted (message confidentiality). */ #define NTLMSSP_NEGOTIATE_SEAL 0x00000020 /* * Indicates that datagram authentication is being used. */ #define NTLMSSP_NEGOTIATE_DATAGRAM 0x00000040 /* * Indicates that the LAN Manager session key should be * used for signing and sealing authenticated communications. */ #define NTLMSSP_NEGOTIATE_LM_KEY 0x00000080 /* * Indicates that NTLM authentication is being used. */ #define NTLMSSP_NEGOTIATE_NTLM 0x00000200 /* * Sent by the client in the Type 1 message to indicate that the name of the * domain in which the client workstation has membership is included in the * message. This is used by the server to determine whether the client is * eligible for local authentication. */ #define NTLMSSP_NEGOTIATE_DOMAIN_SUPPLIED 0x00001000 /* * Sent by the client in the Type 1 message to indicate that the client * workstation's name is included in the message. This is used by the server * to determine whether the client is eligible for local authentication. */ #define NTLMSSP_NEGOTIATE_WORKSTATION_SUPPLIED 0x00002000 /* * Sent by the server to indicate that the server and client are on the same * machine. Implies that the client may use the established local credentials * for authentication instead of calculating a response to the challenge. */ #define NTLMSSP_NEGOTIATE_LOCAL_CALL 0x00004000 /* * Indicates that authenticated communication between the client and server * should be signed with a "dummy" signature. */ #define NTLMSSP_NEGOTIATE_ALWAYS_SIGN 0x00008000 /* * Sent by the server in the Type 2 message to indicate that the target * authentication realm is a domain. */ #define NTLMSSP_TARGET_TYPE_DOMAIN 0x00010000 /* * Sent by the server in the Type 2 message to indicate that the target * authentication realm is a server. */ #define NTLMSSP_TARGET_TYPE_SERVER 0x00020000 /* * Sent by the server in the Type 2 message to indicate that the target * authentication realm is a share. Presumably, this is for share-level * authentication. Usage is unclear. */ #define NTLMSSP_TARGET_TYPE_SHARE 0x00040000 /* * Indicates that the NTLM2 signing and sealing scheme should be used for * protecting authenticated communications. Note that this refers to a * particular session security scheme, and is not related to the use of * NTLMv2 authentication. */ #define NTLMSSP_NEGOTIATE_NTLM2 0x00080000 /* * Sent by the server in the Type 2 message to indicate that it is including * a Target Information block in the message. The Target Information block * is used in the calculation of the NTLMv2 response. */ #define NTLMSSP_NEGOTIATE_TARGET_INFO 0x00800000 /* * Indicates that 128-bit encryption is supported. */ #define NTLMSSP_NEGOTIATE_128 0x20000000 /* * Indicates that the client will provide an encrypted master session key in * the "Session Key" field of the Type 3 message. This is used in signing and * sealing, and is RC4-encrypted using the previous session key as the * encryption key. */ #define NTLMSSP_NEGOTIATE_KEY_EXCHANGE 0x40000000 /* * Indicates that 56-bit encryption is supported. */ #define NTLMSSP_NEGOTIATE_56 0x80000000 /* * AvId values */ #define AVTIMESTAMP 7 //#define NTLMV1_CLIENT //************************Global variables*************************** const int blockSize = 64; //As per RFC2104 Block-size is 512 bits const int nDigestLen = 16; //Trunctaion Length of the Hmac-Md5 digest const quint8 respversion = 1; const quint8 hirespversion = 1; /* usage: // fill up ctx with what we know. QByteArray response = qNtlmPhase1(ctx); // send response (b64 encoded??) // get response from server (b64 decode?) Phase2Block pb; qNtlmDecodePhase2(response, pb); response = qNtlmPhase3(ctx, pb); // send response (b64 encoded??) */ /* TODO: - Fix unicode handling - add v2 handling */ class QNtlmBuffer { public: QNtlmBuffer() : len(0), maxLen(0), offset(0) {} quint16 len; quint16 maxLen; quint32 offset; enum { Size = 8 }; }; class QNtlmPhase1BlockBase { public: char magic[8]; quint32 type; quint32 flags; QNtlmBuffer domain; QNtlmBuffer workstation; enum { Size = 32 }; }; // ################# check paddings class QNtlmPhase2BlockBase { public: char magic[8]; quint32 type; QNtlmBuffer targetName; quint32 flags; unsigned char challenge[8]; quint32 context[2]; QNtlmBuffer targetInfo; enum { Size = 48 }; }; class QNtlmPhase3BlockBase { public: char magic[8]; quint32 type; QNtlmBuffer lmResponse; QNtlmBuffer ntlmResponse; QNtlmBuffer domain; QNtlmBuffer user; QNtlmBuffer workstation; QNtlmBuffer sessionKey; quint32 flags; enum { Size = 64 }; }; static void qStreamNtlmBuffer(QDataStream& ds, const QByteArray& s) { ds.writeRawData(s.constData(), s.size()); } static void qStreamNtlmString(QDataStream& ds, const QString& s, bool unicode) { if (!unicode) { qStreamNtlmBuffer(ds, s.toLatin1()); return; } const ushort *d = s.utf16(); for (int i = 0; i < s.length(); ++i) ds << d[i]; } static int qEncodeNtlmBuffer(QNtlmBuffer& buf, int offset, const QByteArray& s) { buf.len = s.size(); buf.maxLen = buf.len; buf.offset = (offset + 1) & ~1; return buf.offset + buf.len; } static int qEncodeNtlmString(QNtlmBuffer& buf, int offset, const QString& s, bool unicode) { if (!unicode) return qEncodeNtlmBuffer(buf, offset, s.toLatin1()); buf.len = 2 * s.length(); buf.maxLen = buf.len; buf.offset = (offset + 1) & ~1; return buf.offset + buf.len; } static QDataStream& operator<<(QDataStream& s, const QNtlmBuffer& b) { s << b.len << b.maxLen << b.offset; return s; } static QDataStream& operator>>(QDataStream& s, QNtlmBuffer& b) { s >> b.len >> b.maxLen >> b.offset; return s; } class QNtlmPhase1Block : public QNtlmPhase1BlockBase { // request public: QNtlmPhase1Block() { qstrncpy(magic, "NTLMSSP", 8); type = 1; flags = NTLMSSP_NEGOTIATE_UNICODE | NTLMSSP_NEGOTIATE_NTLM | NTLMSSP_REQUEST_TARGET; } // extracted QString domainStr, workstationStr; }; class QNtlmPhase2Block : public QNtlmPhase2BlockBase { // challenge public: QNtlmPhase2Block() { magic[0] = 0; type = 0xffffffff; } // extracted QString targetNameStr, targetInfoStr; QByteArray targetInfoBuff; }; class QNtlmPhase3Block : public QNtlmPhase3BlockBase { // response public: QNtlmPhase3Block() { qstrncpy(magic, "NTLMSSP", 8); type = 3; flags = NTLMSSP_NEGOTIATE_UNICODE | NTLMSSP_NEGOTIATE_NTLM | NTLMSSP_NEGOTIATE_TARGET_INFO; } // extracted QByteArray lmResponseBuf, ntlmResponseBuf; QString domainStr, userStr, workstationStr, sessionKeyStr; QByteArray v2Hash; }; static QDataStream& operator<<(QDataStream& s, const QNtlmPhase1Block& b) { bool unicode = (b.flags & NTLMSSP_NEGOTIATE_UNICODE); s.writeRawData(b.magic, sizeof(b.magic)); s << b.type; s << b.flags; s << b.domain; s << b.workstation; if (!b.domainStr.isEmpty()) qStreamNtlmString(s, b.domainStr, unicode); if (!b.workstationStr.isEmpty()) qStreamNtlmString(s, b.workstationStr, unicode); return s; } static QDataStream& operator<<(QDataStream& s, const QNtlmPhase3Block& b) { bool unicode = (b.flags & NTLMSSP_NEGOTIATE_UNICODE); s.writeRawData(b.magic, sizeof(b.magic)); s << b.type; s << b.lmResponse; s << b.ntlmResponse; s << b.domain; s << b.user; s << b.workstation; s << b.sessionKey; s << b.flags; if (!b.domainStr.isEmpty()) qStreamNtlmString(s, b.domainStr, unicode); qStreamNtlmString(s, b.userStr, unicode); if (!b.workstationStr.isEmpty()) qStreamNtlmString(s, b.workstationStr, unicode); // Send auth info qStreamNtlmBuffer(s, b.lmResponseBuf); qStreamNtlmBuffer(s, b.ntlmResponseBuf); return s; } static QByteArray qNtlmPhase1() { QByteArray rc; QDataStream ds(&rc, QIODevice::WriteOnly); ds.setByteOrder(QDataStream::LittleEndian); QNtlmPhase1Block pb; ds << pb; return rc; } static QByteArray qStringAsUcs2Le(const QString& src) { QByteArray rc(2*src.length(), 0); const unsigned short *s = src.utf16(); unsigned short *d = (unsigned short*)rc.data(); for (int i = 0; i < src.length(); ++i) { d[i] = qToLittleEndian(s[i]); } return rc; } static QString qStringFromUcs2Le(const QByteArray& src) { Q_ASSERT(src.size() % 2 == 0); unsigned short *d = (unsigned short*)src.data(); for (int i = 0; i < src.length() / 2; ++i) { d[i] = qFromLittleEndian(d[i]); } return QString((const QChar *)src.data(), src.size()/2); } #ifdef NTLMV1_CLIENT static QByteArray qEncodeNtlmResponse(const QAuthenticatorPrivate *ctx, const QNtlmPhase2Block& ch) { QCryptographicHash md4(QCryptographicHash::Md4); QByteArray asUcs2Le = qStringAsUcs2Le(ctx->password); md4.addData(asUcs2Le.data(), asUcs2Le.size()); unsigned char md4hash[22]; memset(md4hash, 0, sizeof(md4hash)); QByteArray hash = md4.result(); Q_ASSERT(hash.size() == 16); memcpy(md4hash, hash.constData(), 16); QByteArray rc(24, 0); deshash((unsigned char *)rc.data(), md4hash, (unsigned char *)ch.challenge); deshash((unsigned char *)rc.data() + 8, md4hash + 7, (unsigned char *)ch.challenge); deshash((unsigned char *)rc.data() + 16, md4hash + 14, (unsigned char *)ch.challenge); hash.fill(0); return rc; } static QByteArray qEncodeLmResponse(const QAuthenticatorPrivate *ctx, const QNtlmPhase2Block& ch) { QByteArray hash(21, 0); QByteArray key(14, 0); qstrncpy(key.data(), ctx->password.toUpper().toLatin1(), 14); const char *block = "KGS!@#$%"; deshash((unsigned char *)hash.data(), (unsigned char *)key.data(), (unsigned char *)block); deshash((unsigned char *)hash.data() + 8, (unsigned char *)key.data() + 7, (unsigned char *)block); key.fill(0); QByteArray rc(24, 0); deshash((unsigned char *)rc.data(), (unsigned char *)hash.data(), ch.challenge); deshash((unsigned char *)rc.data() + 8, (unsigned char *)hash.data() + 7, ch.challenge); deshash((unsigned char *)rc.data() + 16, (unsigned char *)hash.data() + 14, ch.challenge); hash.fill(0); return rc; } #endif /********************************************************************* * Function Name: qEncodeHmacMd5 * Params: * key: Type - QByteArray * - It is the Authentication key * message: Type - QByteArray * - This is the actual message which will be encoded * using HMacMd5 hash algorithm * * Return Value: * hmacDigest: Type - QByteArray * * Description: * This function will be used to encode the input message using * HMacMd5 hash algorithm. * * As per the RFC2104 the HMacMd5 algorithm can be specified * --------------------------------------- * MD5(K XOR opad, MD5(K XOR ipad, text)) * --------------------------------------- * *********************************************************************/ QByteArray qEncodeHmacMd5(QByteArray &key, const QByteArray &message) { Q_ASSERT_X(!(message.isEmpty()),"qEncodeHmacMd5", "Empty message check"); Q_ASSERT_X(!(key.isEmpty()),"qEncodeHmacMd5", "Empty key check"); QCryptographicHash hash(QCryptographicHash::Md5); QByteArray hMsg; QByteArray iKeyPad(blockSize, 0x36); QByteArray oKeyPad(blockSize, 0x5c); hash.reset(); // Adjust the key length to blockSize if(blockSize < key.length()) { hash.addData(key); key = hash.result(); //MD5 will always return 16 bytes length output } //Key will be <= 16 or 20 bytes as hash function (MD5 or SHA hash algorithms) //key size can be max of Block size only key = key.leftJustified(blockSize,0,true); //iKeyPad, oKeyPad and key are all of same size "blockSize" //xor of iKeyPad with Key and store the result into iKeyPad for(int i = 0; iv2Hash.size() == 0) { QCryptographicHash md4(QCryptographicHash::Md4); QByteArray passUnicode = qStringAsUcs2Le(ctx->password); md4.addData(passUnicode.data(), passUnicode.size()); QByteArray hashKey = md4.result(); Q_ASSERT(hashKey.size() == 16); // Assuming the user and domain is always unicode in challenge QByteArray message = qStringAsUcs2Le(ctx->user.toUpper()) + qStringAsUcs2Le(ctx->realm); phase3->v2Hash = qEncodeHmacMd5(hashKey, message); } return phase3->v2Hash; } static QByteArray clientChallenge(const QAuthenticatorPrivate *ctx) { Q_ASSERT(ctx->cnonce.size() >= 8); QByteArray clientCh = ctx->cnonce.right(8); return clientCh; } // caller has to ensure a valid targetInfoBuff static bool qExtractServerTime(const QByteArray& targetInfoBuff, quint64 *serverTime) { Q_ASSERT(serverTime != 0); bool retValue = false; QDataStream ds(targetInfoBuff); ds.setByteOrder(QDataStream::LittleEndian); quint16 avId; quint16 avLen; ds >> avId; ds >> avLen; while(avId != 0) { if(avId == AVTIMESTAMP) { QByteArray timeArray(avLen, 0); //avLen size of QByteArray is allocated ds.readRawData(timeArray.data(), avLen); bool ok; *serverTime = timeArray.toHex().toLongLong(&ok, 16); retValue = true; break; } ds.skipRawData(avLen); ds >> avId; ds >> avLen; } return retValue; } static QByteArray qEncodeNtlmv2Response(const QAuthenticatorPrivate *ctx, const QNtlmPhase2Block& ch, QNtlmPhase3Block *phase3) { Q_ASSERT(phase3 != 0); // return value stored in phase3 qCreatev2Hash(ctx, phase3); QByteArray temp; QDataStream ds(&temp, QIODevice::WriteOnly); ds.setByteOrder(QDataStream::LittleEndian); ds << respversion; ds << hirespversion; //Reserved QByteArray reserved1(6, 0); ds.writeRawData(reserved1.constData(), reserved1.size()); quint64 time = 0; //if server sends time, use it instead of current time if(!(ch.targetInfo.len && qExtractServerTime(ch.targetInfoBuff, &time))) { QDateTime currentTime(QDate::currentDate(), QTime::currentTime(), Qt::UTC); // number of seconds between 1601 and epoc(1970) // 369 years, 89 leap years // ((369 * 365) + 89) * 24 * 3600 = 11644473600 time = Q_UINT64_C(currentTime.toTime_t() + 11644473600); // represented as 100 nano seconds time = Q_UINT64_C(time * 10000000); } ds << time; //8 byte client challenge QByteArray clientCh = clientChallenge(ctx); ds.writeRawData(clientCh.constData(), clientCh.size()); //Reserved QByteArray reserved2(4, 0); ds.writeRawData(reserved2.constData(), reserved2.size()); if (ch.targetInfo.len > 0) { ds.writeRawData(ch.targetInfoBuff.constData(), ch.targetInfoBuff.size()); } //Reserved QByteArray reserved3(4, 0); ds.writeRawData(reserved3.constData(), reserved3.size()); QByteArray message((const char*)ch.challenge, sizeof(ch.challenge)); message.append(temp); QByteArray ntChallengeResp = qEncodeHmacMd5(phase3->v2Hash, message); ntChallengeResp.append(temp); return ntChallengeResp; } static QByteArray qEncodeLmv2Response(const QAuthenticatorPrivate *ctx, const QNtlmPhase2Block& ch, QNtlmPhase3Block *phase3) { Q_ASSERT(phase3 != 0); // return value stored in phase3 qCreatev2Hash(ctx, phase3); QByteArray message((const char*)ch.challenge, sizeof(ch.challenge)); QByteArray clientCh = clientChallenge(ctx); message.append(clientCh); QByteArray lmChallengeResp = qEncodeHmacMd5(phase3->v2Hash, message); lmChallengeResp.append(clientCh); return lmChallengeResp; } static bool qNtlmDecodePhase2(const QByteArray& data, QNtlmPhase2Block& ch) { Q_ASSERT(QNtlmPhase2BlockBase::Size == sizeof(QNtlmPhase2BlockBase)); if (data.size() < QNtlmPhase2BlockBase::Size) return false; QDataStream ds(data); ds.setByteOrder(QDataStream::LittleEndian); if (ds.readRawData(ch.magic, 8) < 8) return false; if (strncmp(ch.magic, "NTLMSSP", 8) != 0) return false; ds >> ch.type; if (ch.type != 2) return false; ds >> ch.targetName; ds >> ch.flags; if (ds.readRawData((char *)ch.challenge, 8) < 8) return false; ds >> ch.context[0] >> ch.context[1]; ds >> ch.targetInfo; if (ch.targetName.len > 0) { if (ch.targetName.len + ch.targetName.offset >= (unsigned)data.size()) return false; ch.targetNameStr = qStringFromUcs2Le(data.mid(ch.targetName.offset, ch.targetName.len)); } if (ch.targetInfo.len > 0) { if (ch.targetInfo.len + ch.targetInfo.offset > (unsigned)data.size()) return false; ch.targetInfoBuff = data.mid(ch.targetInfo.offset, ch.targetInfo.len); } return true; } static QByteArray qNtlmPhase3(QAuthenticatorPrivate *ctx, const QByteArray& phase2data) { QNtlmPhase2Block ch; if (!qNtlmDecodePhase2(phase2data, ch)) return QByteArray(); QByteArray rc; QDataStream ds(&rc, QIODevice::WriteOnly); ds.setByteOrder(QDataStream::LittleEndian); QNtlmPhase3Block pb; bool unicode = ch.flags & NTLMSSP_NEGOTIATE_UNICODE; if(ctx->realm.isEmpty()) ctx->realm = ch.targetNameStr; pb.flags = NTLMSSP_NEGOTIATE_NTLM; if (unicode) pb.flags |= NTLMSSP_NEGOTIATE_UNICODE; else pb.flags |= NTLMSSP_NEGOTIATE_OEM; int offset = QNtlmPhase3BlockBase::Size; Q_ASSERT(QNtlmPhase3BlockBase::Size == sizeof(QNtlmPhase3BlockBase)); offset = qEncodeNtlmString(pb.domain, offset, ctx->realm, unicode); pb.domainStr = ctx->realm; offset = qEncodeNtlmString(pb.user, offset, ctx->user, unicode); pb.userStr = ctx->user; offset = qEncodeNtlmString(pb.workstation, offset, ctx->workstation, unicode); pb.workstationStr = ctx->workstation; // Get LM response #ifdef NTLMV1_CLIENT pb.lmResponseBuf = qEncodeLmResponse(ctx, ch); #else if (ch.targetInfo.len > 0) { pb.lmResponseBuf = QByteArray(); } else { pb.lmResponseBuf = qEncodeLmv2Response(ctx, ch, &pb); } #endif offset = qEncodeNtlmBuffer(pb.lmResponse, offset, pb.lmResponseBuf); // Get NTLM response #ifdef NTLMV1_CLIENT pb.ntlmResponseBuf = qEncodeNtlmResponse(ctx, ch); #else pb.ntlmResponseBuf = qEncodeNtlmv2Response(ctx, ch, &pb); #endif offset = qEncodeNtlmBuffer(pb.ntlmResponse, offset, pb.ntlmResponseBuf); // Encode and send ds << pb; return rc; } QT_END_NAMESPACE