/**************************************************************************** ** ** Copyright (C) 2016 The Qt Company Ltd. ** Copyright (C) 2017 Intel Corporation. ** Contact: https://www.qt.io/licensing/ ** ** This file is part of the test suite of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:GPL-EXCEPT$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and The Qt Company. For licensing terms ** and conditions see https://www.qt.io/terms-conditions. For further ** information use the contact form at https://www.qt.io/contact-us. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 3 as published by the Free Software ** Foundation with exceptions as appearing in the file LICENSE.GPL3-EXCEPT ** included in the packaging of this file. Please review the following ** information to ensure the GNU General Public License requirements will ** be met: https://www.gnu.org/licenses/gpl-3.0.html. ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../../../network-settings.h" #include "emulationdetector.h" #if defined(Q_OS_LINUX) #define SHOULD_CHECK_SYSCALL_SUPPORT #include #include #include #endif #ifdef Q_OS_UNIX # include #endif #if defined(Q_OS_LINUX) || defined(Q_OS_WIN) || defined(SO_NREAD) # define RELIABLE_BYTES_AVAILABLE #endif Q_DECLARE_METATYPE(QHostAddress) QT_FORWARD_DECLARE_CLASS(QUdpSocket) class tst_QUdpSocket : public QObject { Q_OBJECT private slots: void initTestCase_data(); void initTestCase(); void init(); void cleanup(); void constructing(); void unconnectedServerAndClientTest(); void broadcasting(); void loop_data(); void loop(); void ipv6Loop_data(); void ipv6Loop(); void dualStack(); void dualStackAutoBinding(); void dualStackNoIPv4onV6only(); void connectToHost(); void bindAndConnectToHost(); void pendingDatagramSize(); void writeDatagram(); void performance(); void bindMode(); void writeDatagramToNonExistingPeer_data(); void writeDatagramToNonExistingPeer(); void writeToNonExistingPeer_data(); void writeToNonExistingPeer(); void outOfProcessConnectedClientServerTest(); void outOfProcessUnconnectedClientServerTest(); void zeroLengthDatagram(); void multicastTtlOption_data(); void multicastTtlOption(); void multicastLoopbackOption_data(); void multicastLoopbackOption(); void multicastJoinBeforeBind_data(); void multicastJoinBeforeBind(); void multicastLeaveAfterClose_data(); void multicastLeaveAfterClose(); void setMulticastInterface_data(); void setMulticastInterface(); void multicast_data(); void multicast(); void echo_data(); void echo(); void linkLocalIPv6(); void linkLocalIPv4(); void readyRead(); void readyReadForEmptyDatagram(); void asyncReadDatagram(); void writeInHostLookupState(); protected slots: void empty_readyReadSlot(); void empty_connectedSlot(); void async_readDatagramSlot(); private: bool shouldSkipIpv6TestsForBrokenSetsockopt(); bool shouldWorkaroundLinuxKernelBug(); #ifdef SHOULD_CHECK_SYSCALL_SUPPORT bool ipv6SetsockoptionMissing(int level, int optname); #endif QNetworkInterface interfaceForGroup(const QHostAddress &multicastGroup); bool m_skipUnsupportedIPv6Tests; bool m_workaroundLinuxKernelBug; QList allAddresses; QHostAddress multicastGroup4, multicastGroup6; QVector linklocalMulticastGroups; QUdpSocket *m_asyncSender; QUdpSocket *m_asyncReceiver; }; #ifdef SHOULD_CHECK_SYSCALL_SUPPORT bool tst_QUdpSocket::ipv6SetsockoptionMissing(int level, int optname) { int testSocket; testSocket = socket(PF_INET6, SOCK_DGRAM, 0); // If we can't test here, assume it's not missing if (testSocket == -1) return false; bool result = false; if (setsockopt(testSocket, level, optname, nullptr, 0) == -1) if (errno == ENOPROTOOPT) result = true; close(testSocket); return result; } #endif //SHOULD_CHECK_SYSCALL_SUPPORT bool tst_QUdpSocket::shouldSkipIpv6TestsForBrokenSetsockopt() { #ifdef SHOULD_CHECK_SYSCALL_SUPPORT // Following parameters for setsockopt are not supported by all QEMU versions: if (ipv6SetsockoptionMissing(SOL_IPV6, IPV6_JOIN_GROUP) || ipv6SetsockoptionMissing(SOL_IPV6, IPV6_MULTICAST_HOPS) || ipv6SetsockoptionMissing(SOL_IPV6, IPV6_MULTICAST_IF) || ipv6SetsockoptionMissing(SOL_IPV6, IPV6_MULTICAST_LOOP) || ipv6SetsockoptionMissing(SOL_IPV6, IPV6_RECVHOPLIMIT)) { return true; } #endif //SHOULD_CHECK_SYSCALL_SUPPORT return false; } QNetworkInterface tst_QUdpSocket::interfaceForGroup(const QHostAddress &multicastGroup) { if (multicastGroup.protocol() == QAbstractSocket::IPv4Protocol) return QNetworkInterface(); QString scope = multicastGroup.scopeId(); if (!scope.isEmpty()) return QNetworkInterface::interfaceFromName(scope); static QNetworkInterface ipv6if = [=]() { // find any link local address in the allAddress list for (const QHostAddress &addr: qAsConst(allAddresses)) { if (addr.isLoopback()) continue; QString scope = addr.scopeId(); if (!scope.isEmpty()) { QNetworkInterface iface = QNetworkInterface::interfaceFromName(scope); qDebug() << "Will bind IPv6 sockets to" << iface; return iface; } } qWarning("interfaceForGroup(%s) could not find any link-local IPv6 address! " "Make sure this test is behind a check of QtNetworkSettings::hasIPv6().", qUtf8Printable(multicastGroup.toString())); return QNetworkInterface(); }(); return ipv6if; } bool tst_QUdpSocket::shouldWorkaroundLinuxKernelBug() { #ifdef Q_OS_LINUX const QVersionNumber version = QVersionNumber::fromString(QSysInfo::kernelVersion()); return version.majorVersion() == 4 && version.minorVersion() >= 6 && version.minorVersion() < 13; #else return false; #endif } static QHostAddress makeNonAny(const QHostAddress &address, QHostAddress::SpecialAddress preferForAny = QHostAddress::LocalHost) { if (address == QHostAddress::Any) return preferForAny; if (address == QHostAddress::AnyIPv4) return QHostAddress::LocalHost; if (address == QHostAddress::AnyIPv6) return QHostAddress::LocalHostIPv6; return address; } void tst_QUdpSocket::initTestCase_data() { // hack: we only enable the Socks5 over UDP tests on the old // test server, because they fail on the new one. See QTBUG-35490 bool newTestServer = true; #ifndef QT_TEST_SERVER QTcpSocket socket; socket.connectToHost(QtNetworkSettings::serverName(), 22); if (socket.waitForConnected(10000)) { socket.waitForReadyRead(5000); QByteArray ba = socket.readAll(); if (ba.startsWith("SSH-2.0-OpenSSH_5.8p1")) newTestServer = false; socket.disconnectFromHost(); } #endif QTest::addColumn("setProxy"); QTest::addColumn("proxyType"); QTest::newRow("WithoutProxy") << false << 0; #if QT_CONFIG(socks5) if (!newTestServer) QTest::newRow("WithSocks5Proxy") << true << int(QNetworkProxy::Socks5Proxy); #endif } void tst_QUdpSocket::initTestCase() { #ifdef QT_TEST_SERVER QVERIFY(QtNetworkSettings::verifyConnection(QtNetworkSettings::socksProxyServerName(), 1080)); QVERIFY(QtNetworkSettings::verifyConnection(QtNetworkSettings::echoServerName(), 7)); #else if (!QtNetworkSettings::verifyTestNetworkSettings()) QSKIP("No network test server available"); #endif allAddresses = QNetworkInterface::allAddresses(); m_skipUnsupportedIPv6Tests = shouldSkipIpv6TestsForBrokenSetsockopt(); // Create a pair of random multicast groups so we avoid clashing with any // other tst_qudpsocket running on the same network at the same time. quint64 r[2] = { // ff14:: is temporary, not prefix-based, admin-local qToBigEndian(Q_UINT64_C(0xff14) << 48), QRandomGenerator64::global()->generate64() }; multicastGroup6.setAddress(*reinterpret_cast(&r)); // 239.0.0.0/8 is "Organization-Local Scope" multicastGroup4.setAddress((239U << 24) | (r[1] & 0xffffff)); // figure out some link-local IPv6 multicast groups // ff12:: is temporary, not prefix-based, link-local r[0] = qToBigEndian(Q_UINT64_C(0xff12) << 48); QHostAddress llbase(*reinterpret_cast(&r)); for (const QHostAddress &a : qAsConst(allAddresses)) { QString scope = a.scopeId(); if (scope.isEmpty()) continue; llbase.setScopeId(scope); linklocalMulticastGroups << llbase; } qDebug() << "Will use multicast groups" << multicastGroup4 << multicastGroup6 << linklocalMulticastGroups; m_workaroundLinuxKernelBug = shouldWorkaroundLinuxKernelBug(); if (EmulationDetector::isRunningArmOnX86()) QSKIP("This test is unreliable due to QEMU emulation shortcomings."); } void tst_QUdpSocket::init() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) { #if QT_CONFIG(socks5) QFETCH_GLOBAL(int, proxyType); if (proxyType == QNetworkProxy::Socks5Proxy) { QNetworkProxy::setApplicationProxy(QNetworkProxy(QNetworkProxy::Socks5Proxy, QtNetworkSettings::socksProxyServerName(), 1080)); } #else QSKIP("No proxy support"); #endif // QT_CONFIG(socks5) } } void tst_QUdpSocket::cleanup() { #ifndef QT_NO_NETWORKPROXY QNetworkProxy::setApplicationProxy(QNetworkProxy::DefaultProxy); #endif // !QT_NO_NETWORKPROXY } //---------------------------------------------------------------------------------- void tst_QUdpSocket::constructing() { QUdpSocket socket; QVERIFY(socket.isSequential()); QVERIFY(!socket.isOpen()); QCOMPARE(socket.socketType(), QUdpSocket::UdpSocket); QCOMPARE((int) socket.bytesAvailable(), 0); QCOMPARE(socket.canReadLine(), false); QCOMPARE(socket.readLine(), QByteArray()); QCOMPARE(socket.socketDescriptor(), (qintptr)-1); QCOMPARE(socket.error(), QUdpSocket::UnknownSocketError); QCOMPARE(socket.errorString(), QString("Unknown error")); // Check the state of the socket api } void tst_QUdpSocket::unconnectedServerAndClientTest() { QUdpSocket serverSocket; qRegisterMetaType("QAbstractSocket::SocketState"); QSignalSpy stateChangedSpy(&serverSocket, SIGNAL(stateChanged(QAbstractSocket::SocketState))); QVERIFY2(serverSocket.bind(), serverSocket.errorString().toLatin1().constData()); QCOMPARE(stateChangedSpy.count(), 1); const char *message[] = {"Yo mista", "Yo", "Wassap"}; QHostAddress serverAddress = makeNonAny(serverSocket.localAddress()); for (int i = 0; i < 3; ++i) { QUdpSocket clientSocket; QCOMPARE(int(clientSocket.writeDatagram(message[i], strlen(message[i]), serverAddress, serverSocket.localPort())), int(strlen(message[i]))); char buf[1024]; QHostAddress host; quint16 port; QVERIFY2(serverSocket.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(serverSocket).constData()); QCOMPARE(int(serverSocket.readDatagram(buf, sizeof(buf), &host, &port)), int(strlen(message[i]))); buf[strlen(message[i])] = '\0'; QCOMPARE(QByteArray(buf), QByteArray(message[i])); QCOMPARE(port, clientSocket.localPort()); if (host.toIPv4Address()) // in case the sender is IPv4 mapped in IPv6 QCOMPARE(host.toIPv4Address(), makeNonAny(clientSocket.localAddress()).toIPv4Address()); else QCOMPARE(host, makeNonAny(clientSocket.localAddress())); } } //---------------------------------------------------------------------------------- void tst_QUdpSocket::broadcasting() { if (m_workaroundLinuxKernelBug) QSKIP("This test can fail due to linux kernel bug"); QFETCH_GLOBAL(bool, setProxy); if (setProxy) { #ifndef QT_NO_NETWORKPROXY QFETCH_GLOBAL(int, proxyType); if (proxyType == QNetworkProxy::Socks5Proxy) QSKIP("With socks5 Broadcast is not supported."); #else // !QT_NO_NETWORKPROXY QSKIP("No proxy support"); #endif // QT_NO_NETWORKPROXY } #ifdef Q_OS_AIX QSKIP("Broadcast does not work on darko"); #endif const char *message[] = {"Yo mista", "", "Yo", "Wassap"}; QList broadcastAddresses; foreach (QNetworkInterface iface, QNetworkInterface::allInterfaces()) { if ((iface.flags() & QNetworkInterface::CanBroadcast) && iface.flags() & QNetworkInterface::IsUp) { for (int i=0;i("peterMessage"); QTest::addColumn("paulMessage"); QTest::addColumn("success"); QTest::newRow("\"Almond!\" | \"Joy!\"") << QByteArray("Almond!") << QByteArray("Joy!") << true; QTest::newRow("\"A\" | \"B\"") << QByteArray("A") << QByteArray("B") << true; QTest::newRow("\"AB\" | \"B\"") << QByteArray("AB") << QByteArray("B") << true; QTest::newRow("\"AB\" | \"BB\"") << QByteArray("AB") << QByteArray("BB") << true; QTest::newRow("\"A\\0B\" | \"B\\0B\"") << QByteArray::fromRawData("A\0B", 3) << QByteArray::fromRawData("B\0B", 3) << true; QTest::newRow("\"(nil)\" | \"(nil)\"") << QByteArray() << QByteArray() << true; QTest::newRow("Bigmessage") << QByteArray(600, '@') << QByteArray(600, '@') << true; } void tst_QUdpSocket::loop() { QFETCH(QByteArray, peterMessage); QFETCH(QByteArray, paulMessage); QFETCH(bool, success); QUdpSocket peter; QUdpSocket paul; // make sure we bind to IPv4 QHostAddress localhost = QHostAddress::LocalHost; QVERIFY2(peter.bind(localhost), peter.errorString().toLatin1().constData()); QVERIFY2(paul.bind(localhost), paul.errorString().toLatin1().constData()); QHostAddress peterAddress = makeNonAny(peter.localAddress()); QHostAddress paulAddress = makeNonAny(paul.localAddress()); QCOMPARE(peter.writeDatagram(peterMessage.data(), peterMessage.length(), paulAddress, paul.localPort()), qint64(peterMessage.length())); QCOMPARE(paul.writeDatagram(paulMessage.data(), paulMessage.length(), peterAddress, peter.localPort()), qint64(paulMessage.length())); QVERIFY2(peter.waitForReadyRead(9000), QtNetworkSettings::msgSocketError(peter).constData()); QVERIFY2(paul.waitForReadyRead(9000), QtNetworkSettings::msgSocketError(paul).constData()); QNetworkDatagram peterDatagram = peter.receiveDatagram(paulMessage.length() * 2); QNetworkDatagram paulDatagram = paul.receiveDatagram(peterMessage.length() * 2); if (success) { QCOMPARE(peterDatagram.data().length(), qint64(paulMessage.length())); QCOMPARE(paulDatagram.data().length(), qint64(peterMessage.length())); } else { // this code path seems to never be executed QVERIFY(peterDatagram.data().length() != paulMessage.length()); QVERIFY(paulDatagram.data().length() != peterMessage.length()); } QCOMPARE(peterDatagram.data().left(paulMessage.length()), paulMessage); QCOMPARE(paulDatagram.data().left(peterMessage.length()), peterMessage); QCOMPARE(peterDatagram.senderAddress(), paulAddress); QCOMPARE(paulDatagram.senderAddress(), peterAddress); QCOMPARE(paulDatagram.senderPort(), int(peter.localPort())); QCOMPARE(peterDatagram.senderPort(), int(paul.localPort())); // Unlike for IPv6 with IPV6_PKTINFO, IPv4 has no standardized way of // obtaining the packet's destination addresses. The destinationAddress and // destinationPort calls could fail, so whitelist the OSes for which we // know we have an implementation. #if defined(Q_OS_LINUX) || defined(Q_OS_BSD4) || defined(Q_OS_WIN) QVERIFY(peterDatagram.destinationPort() != -1); QVERIFY(paulDatagram.destinationPort() != -1); #endif if (peterDatagram.destinationPort() == -1) { QCOMPARE(peterDatagram.destinationAddress().protocol(), QAbstractSocket::UnknownNetworkLayerProtocol); QCOMPARE(paulDatagram.destinationAddress().protocol(), QAbstractSocket::UnknownNetworkLayerProtocol); } else { QCOMPARE(peterDatagram.destinationAddress(), makeNonAny(peter.localAddress())); QCOMPARE(paulDatagram.destinationAddress(), makeNonAny(paul.localAddress())); QVERIFY(peterDatagram.destinationAddress().isEqual(makeNonAny(peter.localAddress()))); QVERIFY(paulDatagram.destinationAddress().isEqual(makeNonAny(paul.localAddress()))); } } //---------------------------------------------------------------------------------- void tst_QUdpSocket::ipv6Loop_data() { loop_data(); } void tst_QUdpSocket::ipv6Loop() { QFETCH(QByteArray, peterMessage); QFETCH(QByteArray, paulMessage); QFETCH(bool, success); QUdpSocket peter; QUdpSocket paul; int peterPort; int paulPort; if (!peter.bind(QHostAddress(QHostAddress::LocalHostIPv6), 0)) { QCOMPARE(peter.error(), QUdpSocket::UnsupportedSocketOperationError); return; } QVERIFY(paul.bind(QHostAddress(QHostAddress::LocalHostIPv6), 0)); QHostAddress peterAddress = makeNonAny(peter.localAddress()); QHostAddress paulAddress = makeNonAny(paul.localAddress()); peterPort = peter.localPort(); paulPort = paul.localPort(); QCOMPARE(peter.writeDatagram(peterMessage.data(), peterMessage.length(), QHostAddress("::1"), paulPort), qint64(peterMessage.length())); QCOMPARE(paul.writeDatagram(paulMessage.data(), paulMessage.length(), QHostAddress("::1"), peterPort), qint64(paulMessage.length())); QVERIFY(peter.waitForReadyRead(5000)); QVERIFY(paul.waitForReadyRead(5000)); QNetworkDatagram peterDatagram = peter.receiveDatagram(paulMessage.length() * 2); QNetworkDatagram paulDatagram = paul.receiveDatagram(peterMessage.length() * 2); if (success) { QCOMPARE(peterDatagram.data().length(), qint64(paulMessage.length())); QCOMPARE(paulDatagram.data().length(), qint64(peterMessage.length())); } else { // this code path seems to never be executed QVERIFY(peterDatagram.data().length() != paulMessage.length()); QVERIFY(paulDatagram.data().length() != peterMessage.length()); } QCOMPARE(peterDatagram.data().left(paulMessage.length()), paulMessage); QCOMPARE(paulDatagram.data().left(peterMessage.length()), peterMessage); QCOMPARE(peterDatagram.senderAddress(), paulAddress); QCOMPARE(paulDatagram.senderAddress(), peterAddress); QCOMPARE(paulDatagram.senderPort(), peterPort); QCOMPARE(peterDatagram.senderPort(), paulPort); // For IPv6, IPV6_PKTINFO is a mandatory feature (RFC 3542). QCOMPARE(peterDatagram.destinationAddress(), makeNonAny(peter.localAddress())); QCOMPARE(paulDatagram.destinationAddress(), makeNonAny(paul.localAddress())); QCOMPARE(peterDatagram.destinationPort(), peterPort); QCOMPARE(paulDatagram.destinationPort(), paulPort); } void tst_QUdpSocket::dualStack() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) QSKIP("test server SOCKS proxy doesn't support IPv6"); QUdpSocket dualSock; QByteArray dualData("dual"); QVERIFY(dualSock.bind(QHostAddress(QHostAddress::Any), 0)); QUdpSocket v4Sock; QByteArray v4Data("v4"); QVERIFY(v4Sock.bind(QHostAddress(QHostAddress::AnyIPv4), 0)); //test v4 -> dual QCOMPARE((int)v4Sock.writeDatagram(v4Data.constData(), v4Data.length(), QHostAddress(QHostAddress::LocalHost), dualSock.localPort()), v4Data.length()); QVERIFY2(dualSock.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(dualSock).constData()); QNetworkDatagram dgram = dualSock.receiveDatagram(100); QVERIFY(dgram.isValid()); QCOMPARE(dgram.data(), v4Data); QCOMPARE(dgram.senderPort(), int(v4Sock.localPort())); // receiving v4 on dual stack will receive as IPv6, so use isEqual() QVERIFY(dgram.senderAddress().isEqual(makeNonAny(v4Sock.localAddress(), QHostAddress::Null))); if (dualSock.localAddress().protocol() == QAbstractSocket::IPv4Protocol) QCOMPARE(dgram.senderAddress(), makeNonAny(v4Sock.localAddress(), QHostAddress::Null)); if (dgram.destinationPort() != -1) { QCOMPARE(dgram.destinationPort(), int(dualSock.localPort())); QVERIFY(dgram.destinationAddress().isEqual(dualSock.localAddress())); } else { qInfo("Getting IPv4 destination address failed."); } if (QtNetworkSettings::hasIPv6()) { QUdpSocket v6Sock; QByteArray v6Data("v6"); QVERIFY(v6Sock.bind(QHostAddress(QHostAddress::AnyIPv6), 0)); //test v6 -> dual QCOMPARE((int)v6Sock.writeDatagram(v6Data.constData(), v6Data.length(), QHostAddress(QHostAddress::LocalHostIPv6), dualSock.localPort()), v6Data.length()); QVERIFY2(dualSock.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(dualSock).constData()); dgram = dualSock.receiveDatagram(100); QVERIFY(dgram.isValid()); QCOMPARE(dgram.data(), v6Data); QCOMPARE(dgram.senderPort(), int(v6Sock.localPort())); QCOMPARE(dgram.senderAddress(), makeNonAny(v6Sock.localAddress(), QHostAddress::LocalHostIPv6)); QCOMPARE(dgram.destinationPort(), int(dualSock.localPort())); QCOMPARE(dgram.destinationAddress(), makeNonAny(dualSock.localAddress(), QHostAddress::LocalHostIPv6)); //test dual -> v6 QCOMPARE((int)dualSock.writeDatagram(dualData.constData(), dualData.length(), QHostAddress(QHostAddress::LocalHostIPv6), v6Sock.localPort()), dualData.length()); QVERIFY2(v6Sock.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(v6Sock).constData()); dgram = v6Sock.receiveDatagram(100); QVERIFY(dgram.isValid()); QCOMPARE(dgram.data(), dualData); QCOMPARE(dgram.senderPort(), int(dualSock.localPort())); QCOMPARE(dgram.senderAddress(), makeNonAny(dualSock.localAddress(), QHostAddress::LocalHostIPv6)); QCOMPARE(dgram.destinationPort(), int(v6Sock.localPort())); QCOMPARE(dgram.destinationAddress(), makeNonAny(v6Sock.localAddress(), QHostAddress::LocalHostIPv6)); } //test dual -> v4 QCOMPARE((int)dualSock.writeDatagram(dualData.constData(), dualData.length(), QHostAddress(QHostAddress::LocalHost), v4Sock.localPort()), dualData.length()); QVERIFY2(v4Sock.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(v4Sock).constData()); dgram = v4Sock.receiveDatagram(100); QVERIFY(dgram.isValid()); QCOMPARE(dgram.data(), dualData); QCOMPARE(dgram.senderPort(), int(dualSock.localPort())); QCOMPARE(dgram.senderAddress(), makeNonAny(dualSock.localAddress(), QHostAddress::LocalHost)); #if defined(Q_OS_LINUX) || defined(Q_OS_BSD4) || defined(Q_OS_WIN) QVERIFY(dgram.destinationPort() != -1); #endif if (dgram.destinationPort() != -1) { QCOMPARE(dgram.destinationPort(), int(v4Sock.localPort())); QCOMPARE(dgram.destinationAddress(), makeNonAny(v4Sock.localAddress(), QHostAddress::LocalHost)); } } void tst_QUdpSocket::dualStackAutoBinding() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) QSKIP("test server SOCKS proxy doesn't support IPv6"); if (!QtNetworkSettings::hasIPv6()) QSKIP("system doesn't support ipv6!"); QUdpSocket v4Sock; QVERIFY(v4Sock.bind(QHostAddress(QHostAddress::AnyIPv4), 0)); QUdpSocket v6Sock; QVERIFY(v6Sock.bind(QHostAddress(QHostAddress::AnyIPv6), 0)); QByteArray dualData("dual"); QHostAddress from; quint16 port; QByteArray buffer; int size; { //test an autobound socket can send to both v4 and v6 addresses (v4 first) QUdpSocket dualSock; QCOMPARE((int)dualSock.writeDatagram(dualData.constData(), dualData.length(), QHostAddress(QHostAddress::LocalHost), v4Sock.localPort()), dualData.length()); QVERIFY2(v4Sock.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(v4Sock).constData()); buffer.reserve(100); size = v4Sock.readDatagram(buffer.data(), 100, &from, &port); QCOMPARE((int)size, dualData.length()); buffer.resize(size); QCOMPARE(buffer, dualData); QCOMPARE((int)dualSock.writeDatagram(dualData.constData(), dualData.length(), QHostAddress(QHostAddress::LocalHostIPv6), v6Sock.localPort()), dualData.length()); QVERIFY2(v6Sock.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(v6Sock).constData()); buffer.reserve(100); size = v6Sock.readDatagram(buffer.data(), 100, &from, &port); QCOMPARE((int)size, dualData.length()); buffer.resize(size); QCOMPARE(buffer, dualData); } { //test an autobound socket can send to both v4 and v6 addresses (v6 first) QUdpSocket dualSock; QCOMPARE((int)dualSock.writeDatagram(dualData.constData(), dualData.length(), QHostAddress(QHostAddress::LocalHostIPv6), v6Sock.localPort()), dualData.length()); QVERIFY2(v6Sock.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(v6Sock).constData()); buffer.reserve(100); size = v6Sock.readDatagram(buffer.data(), 100, &from, &port); QCOMPARE((int)size, dualData.length()); buffer.resize(size); QCOMPARE(buffer, dualData); QCOMPARE((int)dualSock.writeDatagram(dualData.constData(), dualData.length(), QHostAddress(QHostAddress::LocalHost), v4Sock.localPort()), dualData.length()); QVERIFY2(v4Sock.waitForReadyRead(5000), QtNetworkSettings::msgSocketError(v4Sock).constData()); buffer.reserve(100); size = v4Sock.readDatagram(buffer.data(), 100, &from, &port); QCOMPARE((int)size, dualData.length()); buffer.resize(size); QCOMPARE(buffer, dualData); } } void tst_QUdpSocket::dualStackNoIPv4onV6only() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) QSKIP("test server SOCKS proxy doesn't support IPv6"); if (!QtNetworkSettings::hasIPv6()) QSKIP("system doesn't support ipv6!"); QUdpSocket v4Sock; QVERIFY(v4Sock.bind(QHostAddress(QHostAddress::AnyIPv4), 0)); QByteArray v4Data("v4"); QUdpSocket v6Sock; QVERIFY(v6Sock.bind(QHostAddress(QHostAddress::AnyIPv6), 0)); //test v4 -> v6 (should not be received as this is a v6 only socket) QCOMPARE((int)v4Sock.writeDatagram(v4Data.constData(), v4Data.length(), QHostAddress(QHostAddress::LocalHost), v6Sock.localPort()), v4Data.length()); QVERIFY(!v6Sock.waitForReadyRead(1000)); } void tst_QUdpSocket::empty_readyReadSlot() { QTestEventLoop::instance().exitLoop(); } void tst_QUdpSocket::empty_connectedSlot() { QTestEventLoop::instance().exitLoop(); } //---------------------------------------------------------------------------------- void tst_QUdpSocket::connectToHost() { QUdpSocket socket1; QUdpSocket socket2; QVERIFY2(socket1.bind(), socket1.errorString().toLatin1().constData()); socket2.connectToHost(makeNonAny(socket1.localAddress()), socket1.localPort()); QVERIFY(socket2.waitForConnected(5000)); } //---------------------------------------------------------------------------------- void tst_QUdpSocket::bindAndConnectToHost() { QUdpSocket socket1; QUdpSocket socket2; QUdpSocket dummysocket; // we use the dummy socket to use up a file descriptor dummysocket.bind(); QVERIFY2(socket2.bind(), socket2.errorString().toLatin1()); quint16 boundPort = socket2.localPort(); qintptr fd = socket2.socketDescriptor(); QVERIFY2(socket1.bind(), socket1.errorString().toLatin1().constData()); dummysocket.close(); socket2.connectToHost(makeNonAny(socket1.localAddress()), socket1.localPort()); QVERIFY(socket2.waitForConnected(5000)); QCOMPARE(socket2.localPort(), boundPort); QCOMPARE(socket2.socketDescriptor(), fd); } //---------------------------------------------------------------------------------- void tst_QUdpSocket::pendingDatagramSize() { if (m_workaroundLinuxKernelBug) QSKIP("This test can fail due to linux kernel bug"); QUdpSocket server; QVERIFY2(server.bind(), server.errorString().toLatin1().constData()); QHostAddress serverAddress = makeNonAny(server.localAddress()); QUdpSocket client; QVERIFY(client.writeDatagram("this is", 7, serverAddress, server.localPort()) == 7); QVERIFY(client.writeDatagram(0, 0, serverAddress, server.localPort()) == 0); QVERIFY(client.writeDatagram("3 messages", 10, serverAddress, server.localPort()) == 10); char c = 0; QVERIFY2(server.waitForReadyRead(), QtNetworkSettings::msgSocketError(server).constData()); if (server.hasPendingDatagrams()) { #if defined Q_OS_HPUX && defined __ia64 QEXPECT_FAIL("", "HP-UX 11i v2 can't determine the datagram size correctly.", Abort); #endif QCOMPARE(server.pendingDatagramSize(), qint64(7)); c = '\0'; QCOMPARE(server.readDatagram(&c, 1), qint64(1)); QCOMPARE(c, 't'); c = '\0'; } else QSKIP("does not have the 1st datagram"); if (server.hasPendingDatagrams()) { QCOMPARE(server.pendingDatagramSize(), qint64(0)); QCOMPARE(server.readDatagram(&c, 1), qint64(0)); QCOMPARE(c, '\0'); // untouched c = '\0'; } else QSKIP("does not have the 2nd datagram"); if (server.hasPendingDatagrams()) { QCOMPARE(server.pendingDatagramSize(), qint64(10)); QCOMPARE(server.readDatagram(&c, 1), qint64(1)); QCOMPARE(c, '3'); } else QSKIP("does not have the 3rd datagram"); } void tst_QUdpSocket::writeDatagram() { QUdpSocket server; QVERIFY2(server.bind(), server.errorString().toLatin1().constData()); QHostAddress serverAddress = makeNonAny(server.localAddress()); QUdpSocket client; qRegisterMetaType("QAbstractSocket::SocketError"); for(int i=0;;i++) { QSignalSpy errorspy(&client, SIGNAL(error(QAbstractSocket::SocketError))); QSignalSpy bytesspy(&client, SIGNAL(bytesWritten(qint64))); qint64 written = client.writeDatagram(QByteArray(i * 1024, 'w'), serverAddress, server.localPort()); if (written != i * 1024) { #if defined (Q_OS_HPUX) QSKIP("HP-UX 11.11 on hai (PA-RISC 64) truncates too long datagrams."); #endif QCOMPARE(bytesspy.count(), 0); QCOMPARE(errorspy.count(), 1); QCOMPARE(*static_cast(errorspy.at(0).at(0).constData()), int(QUdpSocket::DatagramTooLargeError)); QCOMPARE(client.error(), QUdpSocket::DatagramTooLargeError); break; } QCOMPARE(bytesspy.count(), 1); QCOMPARE(*static_cast(bytesspy.at(0).at(0).constData()), qint64(i * 1024)); QCOMPARE(errorspy.count(), 0); if (!server.waitForReadyRead(5000)) QSKIP(QString("UDP packet lost at size %1, unable to complete the test.").arg(i * 1024).toLatin1().data()); QCOMPARE(server.pendingDatagramSize(), qint64(i * 1024)); QCOMPARE(server.readDatagram(0, 0), qint64(0)); } } void tst_QUdpSocket::performance() { QByteArray arr(8192, '@'); QUdpSocket server; QVERIFY2(server.bind(), server.errorString().toLatin1().constData()); QHostAddress serverAddress = makeNonAny(server.localAddress()); QUdpSocket client; client.connectToHost(serverAddress, server.localPort()); QVERIFY(client.waitForConnected(10000)); QTime stopWatch; stopWatch.start(); qint64 nbytes = 0; while (stopWatch.elapsed() < 5000) { for (int i = 0; i < 100; ++i) { if (client.write(arr.data(), arr.size()) > 0) { do { nbytes += server.readDatagram(arr.data(), arr.size()); } while (server.hasPendingDatagrams()); } } } float secs = stopWatch.elapsed() / 1000.0; qDebug("\t%.2fMB/%.2fs: %.2fMB/s", float(nbytes / (1024.0*1024.0)), secs, float(nbytes / (1024.0*1024.0)) / secs); } void tst_QUdpSocket::bindMode() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) { #ifndef QT_NO_NETWORKPROXY QFETCH_GLOBAL(int, proxyType); if (proxyType == QNetworkProxy::Socks5Proxy) QSKIP("With socks5 explicit port binding is not supported."); #else // !QT_NO_NETWORKPROXY QSKIP("No proxy support"); #endif // QT_NO_NETWORKPROXY } QUdpSocket socket; QVERIFY2(socket.bind(), socket.errorString().toLatin1().constData()); QUdpSocket socket2; QVERIFY(!socket2.bind(socket.localPort())); #if defined(Q_OS_UNIX) QVERIFY(!socket2.bind(socket.localPort(), QUdpSocket::ReuseAddressHint)); socket.close(); QVERIFY2(socket.bind(0, QUdpSocket::ShareAddress), socket.errorString().toLatin1().constData()); QVERIFY2(socket2.bind(socket.localPort()), socket2.errorString().toLatin1().constData()); socket2.close(); QVERIFY2(socket2.bind(socket.localPort(), QUdpSocket::ReuseAddressHint), socket2.errorString().toLatin1().constData()); #else // Depending on the user's privileges, this or will succeed or // fail. Admins are allowed to reuse the address, but nobody else. if (!socket2.bind(socket.localPort(), QUdpSocket::ReuseAddressHint)) { qWarning("Failed to bind with QUdpSocket::ReuseAddressHint(%s), user isn't an administrator?", qPrintable(socket2.errorString())); } socket.close(); QVERIFY2(socket.bind(0, QUdpSocket::ShareAddress), socket.errorString().toLatin1().constData()); QVERIFY(!socket2.bind(socket.localPort())); socket.close(); QVERIFY2(socket.bind(0, QUdpSocket::DontShareAddress), socket.errorString().toLatin1().constData()); QVERIFY(!socket2.bind(socket.localPort())); QVERIFY(!socket2.bind(socket.localPort(), QUdpSocket::ReuseAddressHint)); #endif } void tst_QUdpSocket::writeDatagramToNonExistingPeer_data() { QTest::addColumn("bind"); QTest::addColumn("peerAddress"); QHostAddress localhost(QHostAddress::LocalHost); QList serverAddresses(QHostInfo::fromName(QtNetworkSettings::socksProxyServerName()).addresses()); if (serverAddresses.isEmpty()) return; QHostAddress remote = serverAddresses.first(); QTest::newRow("localhost-unbound") << false << localhost; QTest::newRow("localhost-bound") << true << localhost; QTest::newRow("remote-unbound") << false << remote; QTest::newRow("remote-bound") << true << remote; } void tst_QUdpSocket::writeDatagramToNonExistingPeer() { if (QHostInfo::fromName(QtNetworkSettings::socksProxyServerName()).addresses().isEmpty()) QFAIL("Could not find test server address"); QFETCH(bool, bind); QFETCH(QHostAddress, peerAddress); quint16 peerPort = 33533 + int(bind); QUdpSocket sUdp; QSignalSpy sReadyReadSpy(&sUdp, SIGNAL(readyRead())); if (bind) QVERIFY(sUdp.bind()); QCOMPARE(sUdp.writeDatagram("", 1, peerAddress, peerPort), qint64(1)); QTestEventLoop::instance().enterLoop(1); QCOMPARE(sReadyReadSpy.count(), 0); } void tst_QUdpSocket::writeToNonExistingPeer_data() { QTest::addColumn("peerAddress"); QHostAddress localhost(QHostAddress::LocalHost); QList serverAddresses(QHostInfo::fromName(QtNetworkSettings::socksProxyServerName()).addresses()); if (serverAddresses.isEmpty()) return; QHostAddress remote = serverAddresses.first(); // write (required to be connected) QTest::newRow("localhost") << localhost; QTest::newRow("remote") << remote; } void tst_QUdpSocket::writeToNonExistingPeer() { QSKIP("Connected-mode UDP sockets and their behaviour are erratic"); if (QHostInfo::fromName(QtNetworkSettings::socksProxyServerName()).addresses().isEmpty()) QFAIL("Could not find test server address"); QFETCH(QHostAddress, peerAddress); quint16 peerPort = 34534; qRegisterMetaType("QAbstractSocket::SocketError"); QUdpSocket sConnected; QSignalSpy sConnectedReadyReadSpy(&sConnected, SIGNAL(readyRead())); QSignalSpy sConnectedErrorSpy(&sConnected, SIGNAL(error(QAbstractSocket::SocketError))); sConnected.connectToHost(peerAddress, peerPort, QIODevice::ReadWrite); QVERIFY(sConnected.waitForConnected(10000)); // the first write succeeds... QCOMPARE(sConnected.write("", 1), qint64(1)); // the second one should fail! QTest::qSleep(1000); // do not process events QCOMPARE(sConnected.write("", 1), qint64(-1)); QCOMPARE(int(sConnected.error()), int(QUdpSocket::ConnectionRefusedError)); // the third one will succeed... QCOMPARE(sConnected.write("", 1), qint64(1)); QTestEventLoop::instance().enterLoop(1); QCOMPARE(sConnectedReadyReadSpy.count(), 0); QCOMPARE(sConnectedErrorSpy.count(), 1); QCOMPARE(int(sConnected.error()), int(QUdpSocket::ConnectionRefusedError)); // we should now get a read error QCOMPARE(sConnected.write("", 1), qint64(1)); QTest::qSleep(1000); // do not process events char buf[2]; QVERIFY(!sConnected.hasPendingDatagrams()); QCOMPARE(sConnected.bytesAvailable(), Q_INT64_C(0)); QCOMPARE(sConnected.pendingDatagramSize(), Q_INT64_C(-1)); QCOMPARE(sConnected.readDatagram(buf, 2), Q_INT64_C(-1)); QCOMPARE(int(sConnected.error()), int(QUdpSocket::ConnectionRefusedError)); QCOMPARE(sConnected.write("", 1), qint64(1)); QTest::qSleep(1000); // do not process events QCOMPARE(sConnected.read(buf, 2), Q_INT64_C(0)); QCOMPARE(int(sConnected.error()), int(QUdpSocket::ConnectionRefusedError)); // we should still be connected QCOMPARE(int(sConnected.state()), int(QUdpSocket::ConnectedState)); } void tst_QUdpSocket::outOfProcessConnectedClientServerTest() { #if !QT_CONFIG(process) QSKIP("No qprocess support", SkipAll); #else QProcess serverProcess; serverProcess.start(QLatin1String("clientserver/clientserver server 1 1"), QIODevice::ReadWrite | QIODevice::Text); QVERIFY2(serverProcess.waitForStarted(3000), qPrintable("Failed to start subprocess: " + serverProcess.errorString())); // Wait until the server has started and reports success. while (!serverProcess.canReadLine()) QVERIFY(serverProcess.waitForReadyRead(3000)); QByteArray serverGreeting = serverProcess.readLine(); QVERIFY(serverGreeting != QByteArray("XXX\n")); int serverPort = serverGreeting.trimmed().toInt(); QVERIFY(serverPort > 0 && serverPort < 65536); QProcess clientProcess; clientProcess.start(QString::fromLatin1("clientserver/clientserver connectedclient %1 %2") .arg(QLatin1String("127.0.0.1")).arg(serverPort), QIODevice::ReadWrite | QIODevice::Text); QVERIFY2(clientProcess.waitForStarted(3000), qPrintable("Failed to start subprocess: " + clientProcess.errorString())); // Wait until the server has started and reports success. while (!clientProcess.canReadLine()) QVERIFY(clientProcess.waitForReadyRead(3000)); QByteArray clientGreeting = clientProcess.readLine(); QCOMPARE(clientGreeting, QByteArray("ok\n")); // Let the client and server talk for 3 seconds QTest::qWait(3000); QStringList serverData = QString::fromLocal8Bit(serverProcess.readAll()).split("\n"); QStringList clientData = QString::fromLocal8Bit(clientProcess.readAll()).split("\n"); QVERIFY(serverData.size() > 5); QVERIFY(clientData.size() > 5); for (int i = 0; i < clientData.size() / 2; ++i) { QCOMPARE(clientData.at(i * 2), QString("readData()")); QCOMPARE(serverData.at(i * 3), QString("readData()")); QString cdata = clientData.at(i * 2 + 1); QString sdata = serverData.at(i * 3 + 1); QVERIFY(cdata.startsWith(QLatin1String("got "))); QCOMPARE(cdata.mid(4).trimmed().toInt(), sdata.mid(4).trimmed().toInt() * 2); QVERIFY(serverData.at(i * 3 + 2).startsWith(QLatin1String("sending "))); QCOMPARE(serverData.at(i * 3 + 2).trimmed().mid(8).toInt(), sdata.mid(4).trimmed().toInt() * 2); } clientProcess.kill(); QVERIFY(clientProcess.waitForFinished()); serverProcess.kill(); QVERIFY(serverProcess.waitForFinished()); #endif } void tst_QUdpSocket::outOfProcessUnconnectedClientServerTest() { #if !QT_CONFIG(process) QSKIP("No qprocess support", SkipAll); #else QProcess serverProcess; serverProcess.start(QLatin1String("clientserver/clientserver server 1 1"), QIODevice::ReadWrite | QIODevice::Text); QVERIFY2(serverProcess.waitForStarted(3000), qPrintable("Failed to start subprocess: " + serverProcess.errorString())); // Wait until the server has started and reports success. while (!serverProcess.canReadLine()) QVERIFY(serverProcess.waitForReadyRead(3000)); QByteArray serverGreeting = serverProcess.readLine(); QVERIFY(serverGreeting != QByteArray("XXX\n")); int serverPort = serverGreeting.trimmed().toInt(); QVERIFY(serverPort > 0 && serverPort < 65536); QProcess clientProcess; clientProcess.start(QString::fromLatin1("clientserver/clientserver unconnectedclient %1 %2") .arg(QLatin1String("127.0.0.1")).arg(serverPort), QIODevice::ReadWrite | QIODevice::Text); QVERIFY2(clientProcess.waitForStarted(3000), qPrintable("Failed to start subprocess: " + clientProcess.errorString())); // Wait until the server has started and reports success. while (!clientProcess.canReadLine()) QVERIFY(clientProcess.waitForReadyRead(3000)); QByteArray clientGreeting = clientProcess.readLine(); QCOMPARE(clientGreeting, QByteArray("ok\n")); // Let the client and server talk for 3 seconds QTest::qWait(3000); QStringList serverData = QString::fromLocal8Bit(serverProcess.readAll()).split("\n"); QStringList clientData = QString::fromLocal8Bit(clientProcess.readAll()).split("\n"); QVERIFY(serverData.size() > 5); QVERIFY(clientData.size() > 5); for (int i = 0; i < clientData.size() / 2; ++i) { QCOMPARE(clientData.at(i * 2), QString("readData()")); QCOMPARE(serverData.at(i * 3), QString("readData()")); QString cdata = clientData.at(i * 2 + 1); QString sdata = serverData.at(i * 3 + 1); QVERIFY(cdata.startsWith(QLatin1String("got "))); QCOMPARE(cdata.mid(4).trimmed().toInt(), sdata.mid(4).trimmed().toInt() * 2); QVERIFY(serverData.at(i * 3 + 2).startsWith(QLatin1String("sending "))); QCOMPARE(serverData.at(i * 3 + 2).trimmed().mid(8).toInt(), sdata.mid(4).trimmed().toInt() * 2); } clientProcess.kill(); QVERIFY(clientProcess.waitForFinished()); serverProcess.kill(); QVERIFY(serverProcess.waitForFinished()); #endif } void tst_QUdpSocket::zeroLengthDatagram() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) return; QUdpSocket receiver; QVERIFY(receiver.bind()); QVERIFY(!receiver.waitForReadyRead(100)); QVERIFY(!receiver.hasPendingDatagrams()); QUdpSocket sender; QCOMPARE(sender.writeDatagram(QNetworkDatagram(QByteArray(), QHostAddress::LocalHost, receiver.localPort())), qint64(0)); QVERIFY2(receiver.waitForReadyRead(1000), QtNetworkSettings::msgSocketError(receiver).constData()); QVERIFY(receiver.hasPendingDatagrams()); char buf; QCOMPARE(receiver.readDatagram(&buf, 1), qint64(0)); } void tst_QUdpSocket::multicastTtlOption_data() { QTest::addColumn("bindAddress"); QTest::addColumn("ttl"); QTest::addColumn("expected"); QList addresses; addresses += QHostAddress(QHostAddress::AnyIPv4); addresses += QHostAddress(QHostAddress::AnyIPv6); foreach (const QHostAddress &address, addresses) { const QByteArray addressB = address.toString().toLatin1(); QTest::newRow((addressB + " 0").constData()) << address << 0 << 0; QTest::newRow((addressB + " 1").constData()) << address << 1 << 1; QTest::newRow((addressB + " 2").constData()) << address << 2 << 2; QTest::newRow((addressB + " 128").constData()) << address << 128 << 128; QTest::newRow((addressB + " 255").constData()) << address << 255 << 255; QTest::newRow((addressB + " 1024").constData()) << address << 1024 << 1; } } void tst_QUdpSocket::multicastTtlOption() { #ifdef Q_OS_WINRT QSKIP("WinRT does not support multicast."); #endif QFETCH_GLOBAL(bool, setProxy); QFETCH(QHostAddress, bindAddress); QFETCH(int, ttl); QFETCH(int, expected); if (setProxy) { // UDP multicast does not work with proxies expected = 0; } // Some syscalls needed for ipv6 udp multicasting are not functional if (m_skipUnsupportedIPv6Tests) { if (bindAddress.protocol() == QAbstractSocket::IPv6Protocol) { QSKIP("Syscalls needed for ipv6 udp multicasting missing functionality"); } } QUdpSocket udpSocket; // bind, but ignore the result, we are only interested in initializing the socket (void) udpSocket.bind(bindAddress, 0); udpSocket.setSocketOption(QUdpSocket::MulticastTtlOption, ttl); QCOMPARE(udpSocket.socketOption(QUdpSocket::MulticastTtlOption).toInt(), expected); } void tst_QUdpSocket::multicastLoopbackOption_data() { QTest::addColumn("bindAddress"); QTest::addColumn("loopback"); QTest::addColumn("expected"); QList addresses; addresses += QHostAddress(QHostAddress::AnyIPv4); addresses += QHostAddress(QHostAddress::AnyIPv6); foreach (const QHostAddress &address, addresses) { const QByteArray addressB = address.toString().toLatin1(); QTest::newRow((addressB + " 0").constData()) << address << 0 << 0; QTest::newRow((addressB + " 1").constData()) << address << 1 << 1; QTest::newRow((addressB + " 2").constData()) << address << 2 << 1; QTest::newRow((addressB + " 0 again").constData()) << address << 0 << 0; QTest::newRow((addressB + " 2 again").constData()) << address << 2 << 1; QTest::newRow((addressB + " 0 last time").constData()) << address << 0 << 0; QTest::newRow((addressB + " 1 again").constData()) << address << 1 << 1; } } void tst_QUdpSocket::multicastLoopbackOption() { #ifdef Q_OS_WINRT QSKIP("WinRT does not support multicast."); #endif QFETCH_GLOBAL(bool, setProxy); QFETCH(QHostAddress, bindAddress); QFETCH(int, loopback); QFETCH(int, expected); if (setProxy) { // UDP multicast does not work with proxies expected = 0; } // Some syscalls needed for ipv6 udp multicasting are not functional if (m_skipUnsupportedIPv6Tests) { if (bindAddress.protocol() == QAbstractSocket::IPv6Protocol) { QSKIP("Syscalls needed for ipv6 udp multicasting missing functionality"); } } QUdpSocket udpSocket; // bind, but ignore the result, we are only interested in initializing the socket (void) udpSocket.bind(bindAddress, 0); udpSocket.setSocketOption(QUdpSocket::MulticastLoopbackOption, loopback); QCOMPARE(udpSocket.socketOption(QUdpSocket::MulticastLoopbackOption).toInt(), expected); } void tst_QUdpSocket::multicastJoinBeforeBind_data() { QTest::addColumn("groupAddress"); QTest::newRow("valid ipv4 group address") << multicastGroup4; QTest::newRow("invalid ipv4 group address") << QHostAddress(QHostAddress::Broadcast); QTest::newRow("valid ipv6 group address") << multicastGroup6; for (const QHostAddress &a : qAsConst(linklocalMulticastGroups)) QTest::addRow("valid ipv6 %s-link group address", a.scopeId().toLatin1().constData()) << a; QTest::newRow("invalid ipv6 group address") << QHostAddress(QHostAddress::AnyIPv6); } void tst_QUdpSocket::multicastJoinBeforeBind() { #ifdef Q_OS_WINRT QSKIP("WinRT does not support multicast."); #endif QFETCH(QHostAddress, groupAddress); QUdpSocket udpSocket; // cannot join group before binding QTest::ignoreMessage(QtWarningMsg, "QUdpSocket::joinMulticastGroup() called on a QUdpSocket when not in QUdpSocket::BoundState"); QVERIFY(!udpSocket.joinMulticastGroup(groupAddress)); } void tst_QUdpSocket::multicastLeaveAfterClose_data() { QTest::addColumn("groupAddress"); QTest::newRow("ipv4") << multicastGroup4; QTest::newRow("ipv6") << multicastGroup6; for (const QHostAddress &a : qAsConst(linklocalMulticastGroups)) QTest::addRow("ipv6-link-%s", a.scopeId().toLatin1().constData()) << a; } void tst_QUdpSocket::multicastLeaveAfterClose() { #ifdef Q_OS_WINRT QSKIP("WinRT does not support multicast."); #endif QFETCH_GLOBAL(bool, setProxy); QFETCH(QHostAddress, groupAddress); if (setProxy) QSKIP("UDP Multicast does not work with proxies"); if (!QtNetworkSettings::hasIPv6() && groupAddress.protocol() == QAbstractSocket::IPv6Protocol) QSKIP("system doesn't support ipv6!"); // Some syscalls needed for ipv6 udp multicasting are not functional if (m_skipUnsupportedIPv6Tests) { if (groupAddress.protocol() == QAbstractSocket::IPv6Protocol) { QSKIP("Syscalls needed for ipv6 udp multicasting missing functionality"); } } QUdpSocket udpSocket; QHostAddress bindAddress = QHostAddress::AnyIPv4; if (groupAddress.protocol() == QAbstractSocket::IPv6Protocol) bindAddress = QHostAddress::AnyIPv6; QVERIFY2(udpSocket.bind(bindAddress, 0), qPrintable(udpSocket.errorString())); QVERIFY2(udpSocket.joinMulticastGroup(groupAddress, interfaceForGroup(groupAddress)), qPrintable(udpSocket.errorString())); udpSocket.close(); QTest::ignoreMessage(QtWarningMsg, "QUdpSocket::leaveMulticastGroup() called on a QUdpSocket when not in QUdpSocket::BoundState"); QVERIFY(!udpSocket.leaveMulticastGroup(groupAddress)); } void tst_QUdpSocket::setMulticastInterface_data() { QTest::addColumn("iface"); QTest::addColumn("address"); QList interfaces = QNetworkInterface::allInterfaces(); foreach (const QNetworkInterface &iface, interfaces) { if ((iface.flags() & QNetworkInterface::IsUp) == 0) continue; foreach (const QNetworkAddressEntry &entry, iface.addressEntries()) { const QByteArray testName = iface.name().toLatin1() + ':' + entry.ip().toString().toLatin1(); QTest::newRow(testName.constData()) << iface << entry.ip(); } } } void tst_QUdpSocket::setMulticastInterface() { #ifdef Q_OS_WINRT QSKIP("WinRT does not support multicast."); #endif QFETCH_GLOBAL(bool, setProxy); QFETCH(QNetworkInterface, iface); QFETCH(QHostAddress, address); // Some syscalls needed for udp multicasting are not functional if (m_skipUnsupportedIPv6Tests) { QSKIP("Syscalls needed for udp multicasting missing functionality"); } QUdpSocket udpSocket; // bind initializes the socket bool bound = udpSocket.bind((address.protocol() == QAbstractSocket::IPv6Protocol ? QHostAddress(QHostAddress::AnyIPv6) : QHostAddress(QHostAddress::AnyIPv4)), 0); if (!bound) QTest::ignoreMessage(QtWarningMsg, "QUdpSocket::setMulticastInterface() called on a QUdpSocket when not in QUdpSocket::BoundState"); udpSocket.setMulticastInterface(iface); if (!bound) QTest::ignoreMessage(QtWarningMsg, "QUdpSocket::multicastInterface() called on a QUdpSocket when not in QUdpSocket::BoundState"); QNetworkInterface iface2 = udpSocket.multicastInterface(); if (!setProxy) { QVERIFY(iface2.isValid()); QCOMPARE(iface.name(), iface2.name()); } else { QVERIFY(!iface2.isValid()); } } void tst_QUdpSocket::multicast_data() { QHostAddress anyAddress = QHostAddress(QHostAddress::AnyIPv4); QHostAddress groupAddress = multicastGroup4; QHostAddress any6Address = QHostAddress(QHostAddress::AnyIPv6); QHostAddress group6Address = multicastGroup6; QHostAddress dualAddress = QHostAddress(QHostAddress::Any); QTest::addColumn("bindAddress"); QTest::addColumn("bindResult"); QTest::addColumn("groupAddress"); QTest::addColumn("joinResult"); QTest::newRow("valid bind, group ipv4 address") << anyAddress << true << groupAddress << true; QTest::newRow("valid bind, invalid group ipv4 address") << anyAddress << true << anyAddress << false; QTest::newRow("valid bind, group ipv6 address") << any6Address << true << group6Address << true; for (const QHostAddress &a : qAsConst(linklocalMulticastGroups)) QTest::addRow("valid bind, %s-link group ipv6 address", a.scopeId().toLatin1().constData()) << any6Address << true << a << true; QTest::newRow("valid bind, invalid group ipv6 address") << any6Address << true << any6Address << false; QTest::newRow("dual bind, group ipv4 address") << dualAddress << true << groupAddress << false; QTest::newRow("dual bind, group ipv6 address") << dualAddress << true << group6Address << true; for (const QHostAddress &a : qAsConst(linklocalMulticastGroups)) QTest::addRow("dual bind, %s-link group ipv6 address", a.scopeId().toLatin1().constData()) << dualAddress << true << a << true; } void tst_QUdpSocket::multicast() { #ifdef Q_OS_WINRT QSKIP("WinRT does not support multicast."); #endif QFETCH_GLOBAL(bool, setProxy); QFETCH(QHostAddress, bindAddress); QFETCH(bool, bindResult); QFETCH(QHostAddress, groupAddress); QFETCH(bool, joinResult); if (groupAddress.protocol() == QAbstractSocket::IPv6Protocol && !QtNetworkSettings::hasIPv6()) QSKIP("system doesn't support ipv6!"); if (setProxy) { // UDP multicast does not work with proxies return; } // Some syscalls needed for ipv6 udp multicasting are not functional if (m_skipUnsupportedIPv6Tests) { if (groupAddress.protocol() == QAbstractSocket::IPv6Protocol) { QSKIP("Syscalls needed for ipv6 udp multicasting missing functionality"); } } QUdpSocket receiver; // bind first, then verify that we can join the multicast group QVERIFY2(receiver.bind(bindAddress, 0) == bindResult, qPrintable(receiver.errorString())); if (!bindResult) return; if (bindAddress == QHostAddress::Any && groupAddress.protocol() == QAbstractSocket::IPv4Protocol) { QCOMPARE(joinResult, false); QTest::ignoreMessage(QtWarningMsg, "QAbstractSocket: cannot bind to QHostAddress::Any (or an IPv6 address) and join an IPv4 multicast group;" " bind to QHostAddress::AnyIPv4 instead if you want to do this"); } QVERIFY2(receiver.joinMulticastGroup(groupAddress, interfaceForGroup(groupAddress)) == joinResult, qPrintable(receiver.errorString())); if (!joinResult) return; QList datagrams = QList() << QByteArray("0123") << QByteArray("4567") << QByteArray("89ab") << QByteArray("cdef"); QUdpSocket sender; sender.bind(); foreach (const QByteArray &datagram, datagrams) { QNetworkDatagram dgram(datagram, groupAddress, receiver.localPort()); dgram.setInterfaceIndex(interfaceForGroup(groupAddress).index()); QCOMPARE(int(sender.writeDatagram(dgram)), int(datagram.size())); } QVERIFY2(receiver.waitForReadyRead(), QtNetworkSettings::msgSocketError(receiver).constData()); QVERIFY(receiver.hasPendingDatagrams()); QList receivedDatagrams; while (receiver.hasPendingDatagrams()) { QNetworkDatagram dgram = receiver.receiveDatagram(); receivedDatagrams << dgram.data(); QVERIFY2(allAddresses.contains(dgram.senderAddress()), dgram.senderAddress().toString().toLatin1()); QCOMPARE(dgram.senderPort(), int(sender.localPort())); if (!dgram.destinationAddress().isNull()) { QCOMPARE(dgram.destinationAddress(), groupAddress); QCOMPARE(dgram.destinationPort(), int(receiver.localPort())); } int ttl = dgram.hopLimit(); if (ttl != -1) QVERIFY(ttl != 0); } QCOMPARE(receivedDatagrams, datagrams); QVERIFY2(receiver.leaveMulticastGroup(groupAddress, interfaceForGroup(groupAddress)), qPrintable(receiver.errorString())); } void tst_QUdpSocket::echo_data() { QTest::addColumn("connect"); QTest::newRow("writeDatagram") << false; QTest::newRow("write") << true; } void tst_QUdpSocket::echo() { QFETCH(bool, connect); QHostInfo info = QHostInfo::fromName(QtNetworkSettings::echoServerName()); QVERIFY(info.addresses().count()); QHostAddress remote = info.addresses().first(); QUdpSocket sock; if (connect) { sock.connectToHost(remote, 7); QVERIFY(sock.waitForConnected(10000)); } else { sock.bind(); } QByteArray out(30, 'x'); QByteArray in; int successes = 0; for (int i=0;i<10;i++) { if (connect) { sock.write(out); } else { sock.writeDatagram(out, remote, 7); } if (sock.waitForReadyRead(1000)) { while (sock.hasPendingDatagrams()) { QHostAddress from; quint16 port; if (connect) { in = sock.read(sock.pendingDatagramSize()); } else { in.resize(sock.pendingDatagramSize()); sock.readDatagram(in.data(), in.length(), &from, &port); } if (in==out) successes++; } } if (!sock.isValid()) QFAIL(sock.errorString().toLatin1().constData()); qDebug() << "packets in" << successes << "out" << i; QTest::qWait(50); //choke to avoid triggering flood/DDoS protections on echo service } QVERIFY2(successes >= 9, QByteArray::number(successes).constData()); } void tst_QUdpSocket::linkLocalIPv6() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) return; QList addresses; QSet scopes; QHostAddress localMask("fe80::"); foreach (const QNetworkInterface& iface, QNetworkInterface::allInterfaces()) { //Windows preallocates link local addresses to interfaces that are down. //These may or may not work depending on network driver if (iface.flags() & QNetworkInterface::IsUp) { #if defined(Q_OS_WIN) // Do not add the Teredo Tunneling Pseudo Interface on Windows. if (iface.humanReadableName().contains("Teredo")) continue; #elif defined(Q_OS_DARWIN) // Do not add "utun" interfaces on macOS: nothing ever gets received // (we don't know why) if (iface.name().startsWith("utun")) continue; #endif foreach (QNetworkAddressEntry addressEntry, iface.addressEntries()) { QHostAddress addr(addressEntry.ip()); if (!addr.scopeId().isEmpty() && addr.isInSubnet(localMask, 64)) { scopes << addr.scopeId(); addresses << addr; qDebug() << addr; } } } } if (addresses.isEmpty()) QSKIP("No IPv6 link local addresses"); QList sockets; quint16 port = 0; foreach (const QHostAddress& addr, addresses) { QUdpSocket *s = new QUdpSocket; QVERIFY2(s->bind(addr, port), addr.toString().toLatin1() + '/' + QByteArray::number(port) + ": " + qPrintable(s->errorString())); port = s->localPort(); //bind same port, different networks sockets << s; } QByteArray testData("hello"); foreach (QUdpSocket *s, sockets) { QUdpSocket neutral; QVERIFY(neutral.bind(QHostAddress(QHostAddress::AnyIPv6))); QSignalSpy neutralReadSpy(&neutral, SIGNAL(readyRead())); QSignalSpy spy(s, SIGNAL(readyRead())); QVERIFY(s->writeDatagram(testData, s->localAddress(), neutral.localPort())); QTRY_VERIFY(neutralReadSpy.count() > 0); //note may need to accept a firewall prompt QNetworkDatagram dgram = neutral.receiveDatagram(testData.length() * 2); QVERIFY(dgram.isValid()); QCOMPARE(dgram.senderAddress(), s->localAddress()); QCOMPARE(dgram.senderPort(), int(s->localPort())); QCOMPARE(dgram.destinationAddress(), s->localAddress()); QCOMPARE(dgram.destinationPort(), int(neutral.localPort())); QCOMPARE(dgram.data().length(), testData.length()); QCOMPARE(dgram.data(), testData); QVERIFY(neutral.writeDatagram(dgram.makeReply(testData))); QTRY_VERIFY(spy.count() > 0); //note may need to accept a firewall prompt dgram = s->receiveDatagram(testData.length() * 2); QCOMPARE(dgram.data(), testData); //sockets bound to other interfaces shouldn't have received anything foreach (QUdpSocket *s2, sockets) { QCOMPARE((int)s2->bytesAvailable(), 0); } //Sending to the same address with different scope should normally fail //However it will pass if there is a route between two interfaces, //e.g. connected to a home/office network via wired and wireless interfaces //which is a reasonably common case. //So this is not auto tested. } qDeleteAll(sockets); } void tst_QUdpSocket::linkLocalIPv4() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) return; QList addresses; QHostAddress localMask("169.254.0.0"); foreach (const QNetworkInterface& iface, QNetworkInterface::allInterfaces()) { //Windows preallocates link local addresses to interfaces that are down. //These may or may not work depending on network driver (they do not work for the Bluetooth PAN driver) if (iface.flags() & QNetworkInterface::IsUp) { #if defined(Q_OS_WIN) // Do not add the Teredo Tunneling Pseudo Interface on Windows. if (iface.humanReadableName().contains("Teredo")) continue; #elif defined(Q_OS_DARWIN) // Do not add "utun" interfaces on macOS: nothing ever gets received // (we don't know why) if (iface.name().startsWith("utun")) continue; #endif foreach (QNetworkAddressEntry addr, iface.addressEntries()) { if (addr.ip().isInSubnet(localMask, 16)) { addresses << addr.ip(); qDebug() << "Found IPv4 link local address" << addr.ip(); } } } } if (addresses.isEmpty()) QSKIP("No IPv4 link local addresses"); QList sockets; quint16 port = 0; foreach (const QHostAddress& addr, addresses) { QUdpSocket *s = new QUdpSocket; QVERIFY2(s->bind(addr, port), qPrintable(s->errorString())); port = s->localPort(); //bind same port, different networks sockets << s; } QUdpSocket neutral; QVERIFY(neutral.bind(QHostAddress(QHostAddress::AnyIPv4))); QByteArray testData("hello"); foreach (QUdpSocket *s, sockets) { QVERIFY(s->writeDatagram(testData, s->localAddress(), neutral.localPort())); QVERIFY2(neutral.waitForReadyRead(10000), QtNetworkSettings::msgSocketError(neutral).constData()); QNetworkDatagram dgram = neutral.receiveDatagram(testData.length() * 2); QVERIFY(dgram.isValid()); QCOMPARE(dgram.senderAddress(), s->localAddress()); QCOMPARE(dgram.senderPort(), int(s->localPort())); QCOMPARE(dgram.data().length(), testData.length()); QCOMPARE(dgram.data(), testData); // Unlike for IPv6 with IPV6_PKTINFO, IPv4 has no standardized way of // obtaining the packet's destination addresses. The destinationAddress // and destinationPort calls could fail, so whitelist the OSes we know // we have an implementation. #if defined(Q_OS_LINUX) || defined(Q_OS_BSD4) || defined(Q_OS_WIN) QVERIFY(dgram.destinationPort() != -1); #endif if (dgram.destinationPort() == -1) { QCOMPARE(dgram.destinationAddress().protocol(), QAbstractSocket::UnknownNetworkLayerProtocol); } else { QCOMPARE(dgram.destinationAddress(), s->localAddress()); QCOMPARE(dgram.destinationPort(), int(neutral.localPort())); } QVERIFY(neutral.writeDatagram(dgram.makeReply(testData))); QVERIFY2(s->waitForReadyRead(10000), QtNetworkSettings::msgSocketError(*s).constData()); dgram = s->receiveDatagram(testData.length() * 2); QVERIFY(dgram.isValid()); QCOMPARE(dgram.data(), testData); //sockets bound to other interfaces shouldn't have received anything foreach (QUdpSocket *s2, sockets) { QCOMPARE((int)s2->bytesAvailable(), 0); } } qDeleteAll(sockets); } void tst_QUdpSocket::readyRead() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) return; char buf[1]; QUdpSocket sender, receiver; QVERIFY(receiver.bind(QHostAddress(QHostAddress::AnyIPv4), 0)); quint16 port = receiver.localPort(); QVERIFY(port != 0); QSignalSpy spy(&receiver, SIGNAL(readyRead())); // send a datagram to that port sender.writeDatagram("aa", makeNonAny(receiver.localAddress()), port); // wait a little // if QTBUG-43857 is still going, we'll live-lock on socket notifications from receiver's socket QTest::qWait(100); // make sure only one signal was emitted QCOMPARE(spy.count(), 1); QVERIFY(receiver.hasPendingDatagrams()); #ifdef RELIABLE_BYTES_AVAILABLE QCOMPARE(receiver.bytesAvailable(), qint64(2)); #endif QCOMPARE(receiver.pendingDatagramSize(), qint64(2)); // write another datagram sender.writeDatagram("ab", makeNonAny(receiver.localAddress()), port); // no new signal should be emitted because we haven't read the first datagram yet QTest::qWait(100); QCOMPARE(spy.count(), 1); QVERIFY(receiver.hasPendingDatagrams()); QVERIFY(receiver.bytesAvailable() >= 1); // most likely is 1, but it could be 1 + 2 in the future QCOMPARE(receiver.pendingDatagramSize(), qint64(2)); // read all the datagrams (we could read one only, but we can't be sure the OS is queueing) while (receiver.hasPendingDatagrams()) receiver.readDatagram(buf, sizeof buf); // write a new datagram and ensure the signal is emitted now sender.writeDatagram("abc", makeNonAny(receiver.localAddress()), port); QTest::qWait(100); QCOMPARE(spy.count(), 2); QVERIFY(receiver.hasPendingDatagrams()); #ifdef RELIABLE_BYTES_AVAILABLE QCOMPARE(receiver.bytesAvailable(), qint64(3)); #endif QCOMPARE(receiver.pendingDatagramSize(), qint64(3)); } void tst_QUdpSocket::readyReadForEmptyDatagram() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) return; QUdpSocket sender, receiver; QVERIFY(receiver.bind(QHostAddress(QHostAddress::AnyIPv4), 0)); quint16 port = receiver.localPort(); QVERIFY(port != 0); connect(&receiver, SIGNAL(readyRead()), SLOT(empty_readyReadSlot())); // send an empty datagram to that port sender.writeDatagram("", makeNonAny(receiver.localAddress()), port); // ensure that we got a readyRead, despite bytesAvailable() == 0 QTestEventLoop::instance().enterLoop(1); QVERIFY(!QTestEventLoop::instance().timeout()); char buf[1]; QVERIFY(receiver.hasPendingDatagrams()); QCOMPARE(receiver.pendingDatagramSize(), qint64(0)); #ifdef RELIABLE_BYTES_AVAILABLE QCOMPARE(receiver.bytesAvailable(), qint64(0)); #endif QCOMPARE(receiver.readDatagram(buf, sizeof buf), qint64(0)); } void tst_QUdpSocket::async_readDatagramSlot() { char buf[1]; QVERIFY(m_asyncReceiver->hasPendingDatagrams()); QCOMPARE(m_asyncReceiver->pendingDatagramSize(), qint64(1)); #ifdef RELIABLE_BYTES_AVAILABLE QCOMPARE(m_asyncReceiver->bytesAvailable(), qint64(1)); #endif QCOMPARE(m_asyncReceiver->readDatagram(buf, sizeof(buf)), qint64(1)); if (buf[0] == '2') { QTestEventLoop::instance().exitLoop(); return; } m_asyncSender->writeDatagram("2", makeNonAny(m_asyncReceiver->localAddress()), m_asyncReceiver->localPort()); // wait a little to ensure that the datagram we've just sent // will be delivered on receiver side. QTest::qSleep(100); } void tst_QUdpSocket::asyncReadDatagram() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) return; m_asyncSender = new QUdpSocket; m_asyncReceiver = new QUdpSocket; QVERIFY(m_asyncReceiver->bind(QHostAddress(QHostAddress::AnyIPv4), 0)); quint16 port = m_asyncReceiver->localPort(); QVERIFY(port != 0); QSignalSpy spy(m_asyncReceiver, SIGNAL(readyRead())); connect(m_asyncReceiver, SIGNAL(readyRead()), SLOT(async_readDatagramSlot())); m_asyncSender->writeDatagram("1", makeNonAny(m_asyncReceiver->localAddress()), port); QTestEventLoop::instance().enterLoop(1); QVERIFY(!QTestEventLoop::instance().timeout()); QCOMPARE(spy.count(), 2); delete m_asyncSender; delete m_asyncReceiver; } void tst_QUdpSocket::writeInHostLookupState() { QFETCH_GLOBAL(bool, setProxy); if (setProxy) return; QUdpSocket socket; socket.connectToHost("nosuchserver.qt-project.org", 80); QCOMPARE(socket.state(), QUdpSocket::HostLookupState); QVERIFY(!socket.putChar('0')); } QTEST_MAIN(tst_QUdpSocket) #include "tst_qudpsocket.moc"