Esempio n. 1
0
    pingBiDir(Ice.Identity id, Ice.Current current)
    {
        PingReplyPrx p = PingReplyPrxHelper.uncheckedCast(current.con.createProxy(id));

        p.replyAsync().ContinueWith(
            (t) =>
        {
            test(Thread.CurrentThread.Name.Contains("Ice.ThreadPool.Server"));
        },
            p.ice_scheduler()).Wait();
    }
Esempio n. 2
0
    public static void allTests(Ice.Communicator communicator)
    {
        communicator.getProperties().setProperty("ReplyAdapter.Endpoints", "udp -p 12030");
        Ice.ObjectAdapter adapter = communicator.createObjectAdapter("ReplyAdapter");
        PingReplyI        replyI  = new PingReplyI();

        Test.PingReplyPrx reply =
            (Test.PingReplyPrx)Test.PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
        adapter.activate();

        Console.Out.Write("testing udp... ");
        Console.Out.Flush();
        Ice.ObjectPrx    @base = communicator.stringToProxy("test:udp -p 12010").ice_datagram();
        Test.TestIntfPrx obj   = Test.TestIntfPrxHelper.uncheckedCast(@base);

        int  nRetry = 5;
        bool ret    = false;

        while (nRetry-- > 0)
        {
            replyI.reset();
            obj.ping(reply);
            obj.ping(reply);
            obj.ping(reply);
            ret = replyI.waitReply(3, 2000);
            if (ret)
            {
                break; // Success
            }

            // If the 3 datagrams were not received within the 2 seconds, we try again to
            // receive 3 new datagrams using a new object. We give up after 5 retries.
            replyI = new PingReplyI();
            reply  = (Test.PingReplyPrx)Test.PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
        }
        test(ret == true);

        if (communicator.getProperties().getPropertyAsInt("Ice.Override.Compress") == 0)
        {
            //
            // Only run this test if compression is disabled, the test expect fixed message size
            // to be sent over the wire.
            //
            byte[] seq = null;
            try
            {
                seq = new byte[1024];
                while (true)
                {
                    seq = new byte[seq.Length * 2 + 10];
                    replyI.reset();
                    obj.sendByteSeq(seq, reply);
                    replyI.waitReply(1, 10000);
                }
            }
            catch (Ice.DatagramLimitException)
            {
                //
                // The server's Ice.UDP.RcvSize property is set to 16384, which means that DatagramLimitException
                // will be throw when try to send a packet bigger than that. However, Mono 2.10 bug in setting Socket
                // options could cause the RcvSize/SndSize to contain an arbitrary value so the test might fail
                // with smaller message sizes.
                //
                test(seq.Length > 16384 || IceInternal.AssemblyUtil.runtime_ == IceInternal.AssemblyUtil.Runtime.Mono);
            }
            obj.ice_getConnection().close(false);
            communicator.getProperties().setProperty("Ice.UDP.SndSize", "64000");
            seq = new byte[50000];
            try
            {
                replyI.reset();
                obj.sendByteSeq(seq, reply);

                bool b = replyI.waitReply(1, 500);
                //
                // The server's Ice.UDP.RcvSize property is set to 16384, which means this packet
                // should not be delivered. However, Mono 2.10 bug in setting Socket options could
                // cause the RcvSize/SndSize to contain an arbitrary value so the packet might
                // be delivered successfully.
                //
                test(!b || IceInternal.AssemblyUtil.runtime_ == IceInternal.AssemblyUtil.Runtime.Mono);
            }
            catch (Ice.DatagramLimitException)
            {
                //
                // Mono 2.10 bug in setting Socket options could cause the RcvSize/SndSize to contain
                // an arbitrary value so the message send might fail if the effetive SndSize is minor
                // than expected.
                //
                test(IceInternal.AssemblyUtil.runtime_ == IceInternal.AssemblyUtil.Runtime.Mono);
            }
            catch (Ice.LocalException ex)
            {
                Console.Out.WriteLine(ex);
                test(false);
            }
        }

        Console.Out.WriteLine("ok");

        Console.Out.Write("testing udp multicast... ");
        Console.Out.Flush();
        string endpoint;

        if (communicator.getProperties().getProperty("Ice.IPv6").Equals("1"))
        {
            if (IceInternal.AssemblyUtil.osx_)
            {
                endpoint = "udp -h \"ff15::1:1\" -p 12020 --interface \"::1\"";
            }
            else
            {
                endpoint = "udp -h \"ff15::1:1\" -p 12020";
            }
        }
        else
        {
            endpoint = "udp -h 239.255.1.1 -p 12020";
        }
        @base = communicator.stringToProxy("test -d:" + endpoint);
        TestIntfPrx objMcast = Test.TestIntfPrxHelper.uncheckedCast(@base);

        nRetry = 5;
        while (nRetry-- > 0)
        {
            replyI.reset();
            objMcast.ping(reply);
            ret = replyI.waitReply(5, 5000);
            if (ret)
            {
                break;
            }
            replyI = new PingReplyI();
            reply  = (Test.PingReplyPrx)Test.PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
        }
        if (!ret)
        {
            Console.Out.WriteLine("failed (is a firewall enabled?)");
        }
        else
        {
            Console.Out.WriteLine("ok");
        }

        Console.Out.Write("testing udp bi-dir connection... ");
        Console.Out.Flush();
        obj.ice_getConnection().setAdapter(adapter);
        objMcast.ice_getConnection().setAdapter(adapter);
        nRetry = 5;
        while (nRetry-- > 0)
        {
            replyI.reset();
            obj.pingBiDir(reply.ice_getIdentity());
            obj.pingBiDir(reply.ice_getIdentity());
            obj.pingBiDir(reply.ice_getIdentity());
            ret = replyI.waitReply(3, 2000);
            if (ret)
            {
                break; // Success
            }
            replyI = new PingReplyI();
            reply  = (PingReplyPrx)PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
        }
        test(ret);
        Console.Out.WriteLine("ok");

        //
        // Sending the replies back on the multicast UDP connection doesn't work for most
        // platform (it works for OS X Leopard but not Snow Leopard, doesn't work on SLES,
        // Windows...). For Windows, see UdpTransceiver constructor for the details. So
        // we don't run this test.
        //
//         Console.Out.Write("testing udp bi-dir connection... ");
//         nRetry = 5;
//         while(nRetry-- > 0)
//         {
//             replyI.reset();
//             objMcast.pingBiDir(reply.ice_getIdentity());
//             ret = replyI.waitReply(5, 2000);
//             if(ret)
//             {
//                 break; // Success
//             }
//             replyI = new PingReplyI();
//             reply = (PingReplyPrx)PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
//         }

//         if(!ret)
//         {
//             Console.Out.WriteLine("failed (is a firewall enabled?)");
//         }
//         else
//         {
//             Console.Out.WriteLine("ok");
//         }
    }
Esempio n. 3
0
    public static void allTests(TestCommon.Application app)
    {
        Ice.Communicator communicator = app.communicator();
        communicator.getProperties().setProperty("ReplyAdapter.Endpoints", "udp");
        Ice.ObjectAdapter adapter = communicator.createObjectAdapter("ReplyAdapter");
        PingReplyI        replyI  = new PingReplyI();

        Test.PingReplyPrx reply =
            (Test.PingReplyPrx)Test.PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
        adapter.activate();

        Console.Out.Write("testing udp... ");
        Console.Out.Flush();
        Ice.ObjectPrx    @base = communicator.stringToProxy("test:" + app.getTestEndpoint(0, "udp")).ice_datagram();
        Test.TestIntfPrx obj   = Test.TestIntfPrxHelper.uncheckedCast(@base);

        int  nRetry = 5;
        bool ret    = false;

        while (nRetry-- > 0)
        {
            replyI.reset();
            obj.ping(reply);
            obj.ping(reply);
            obj.ping(reply);
            ret = replyI.waitReply(3, 2000);
            if (ret)
            {
                break; // Success
            }

            // If the 3 datagrams were not received within the 2 seconds, we try again to
            // receive 3 new datagrams using a new object. We give up after 5 retries.
            replyI = new PingReplyI();
            reply  = (Test.PingReplyPrx)Test.PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
        }
        test(ret == true);

        if (communicator.getProperties().getPropertyAsInt("Ice.Override.Compress") == 0)
        {
            //
            // Only run this test if compression is disabled, the test expect fixed message size
            // to be sent over the wire.
            //
            byte[] seq = null;
            try
            {
                seq = new byte[1024];
                while (true)
                {
                    seq = new byte[seq.Length * 2 + 10];
                    replyI.reset();
                    obj.sendByteSeq(seq, reply);
                    replyI.waitReply(1, 10000);
                }
            }
            catch (Ice.DatagramLimitException)
            {
                //
                // The server's Ice.UDP.RcvSize property is set to 16384, which means that DatagramLimitException
                // will be throw when try to send a packet bigger than that.
                //
                test(seq.Length > 16384);
            }
            obj.ice_getConnection().close(Ice.ConnectionClose.GracefullyWithWait);
            communicator.getProperties().setProperty("Ice.UDP.SndSize", "64000");
            seq = new byte[50000];
            try
            {
                replyI.reset();
                obj.sendByteSeq(seq, reply);

                bool b = replyI.waitReply(1, 500);
                //
                // The server's Ice.UDP.RcvSize property is set to 16384, which means this packet
                // should not be delivered.
                //
                test(!b);
            }
            catch (Ice.DatagramLimitException)
            {
            }
            catch (Ice.LocalException ex)
            {
                Console.Out.WriteLine(ex);
                test(false);
            }
        }

        Console.Out.WriteLine("ok");

        Console.Out.Write("testing udp multicast... ");
        Console.Out.Flush();
        StringBuilder endpoint = new StringBuilder();

        if (communicator.getProperties().getProperty("Ice.IPv6").Equals("1"))
        {
            endpoint.Append("udp -h \"ff15::1:1\" --interface \"::1\" -p "); // Use loopback to prevent other machines to answer.
        }
        else
        {
            endpoint.Append("udp -h 239.255.1.1 --interface 127.0.0.1 -p "); // Use loopback to prevent other machines to answer.
        }
        endpoint.Append(app.getTestPort(10));
        @base = communicator.stringToProxy("test -d:" + endpoint.ToString());
        TestIntfPrx objMcast = Test.TestIntfPrxHelper.uncheckedCast(@base);

        nRetry = 5;
        while (nRetry-- > 0)
        {
            replyI.reset();
            objMcast.ping(reply);
            ret = replyI.waitReply(5, 5000);
            if (ret)
            {
                break;
            }
            replyI = new PingReplyI();
            reply  = (Test.PingReplyPrx)Test.PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
        }
        if (!ret)
        {
            Console.Out.WriteLine("failed (is a firewall enabled?)");
        }
        else
        {
            Console.Out.WriteLine("ok");
        }

        Console.Out.Write("testing udp bi-dir connection... ");
        Console.Out.Flush();
        obj.ice_getConnection().setAdapter(adapter);
        objMcast.ice_getConnection().setAdapter(adapter);
        nRetry = 5;
        while (nRetry-- > 0)
        {
            replyI.reset();
            obj.pingBiDir(reply.ice_getIdentity());
            obj.pingBiDir(reply.ice_getIdentity());
            obj.pingBiDir(reply.ice_getIdentity());
            ret = replyI.waitReply(3, 2000);
            if (ret)
            {
                break; // Success
            }
            replyI = new PingReplyI();
            reply  = (PingReplyPrx)PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
        }
        test(ret);
        Console.Out.WriteLine("ok");

        //
        // Sending the replies back on the multicast UDP connection doesn't work for most
        // platform (it works for macOS Leopard but not Snow Leopard, doesn't work on SLES,
        // Windows...). For Windows, see UdpTransceiver constructor for the details. So
        // we don't run this test.
        //
//         Console.Out.Write("testing udp bi-dir connection... ");
//         nRetry = 5;
//         while(nRetry-- > 0)
//         {
//             replyI.reset();
//             objMcast.pingBiDir(reply.ice_getIdentity());
//             ret = replyI.waitReply(5, 2000);
//             if(ret)
//             {
//                 break; // Success
//             }
//             replyI = new PingReplyI();
//             reply = (PingReplyPrx)PingReplyPrxHelper.uncheckedCast(adapter.addWithUUID(replyI)).ice_datagram();
//         }

//         if(!ret)
//         {
//             Console.Out.WriteLine("failed (is a firewall enabled?)");
//         }
//         else
//         {
//             Console.Out.WriteLine("ok");
//         }
    }