Exemple #1
0
TrustManager::TrustManager(const Ice::CommunicatorPtr& communicator) :
    _communicator(communicator)
{
    Ice::PropertiesPtr properties = communicator->getProperties();
    _traceLevel = properties->getPropertyAsInt("IceSSL.Trace.Security");
    string key;
    try
    {
        key = "IceSSL.TrustOnly";
        _all = parse(properties->getProperty(key));
        key = "IceSSL.TrustOnly.Client";
        _client = parse(properties->getProperty(key));
        key = "IceSSL.TrustOnly.Server";
        _allServer = parse(properties->getProperty(key));
        Ice::PropertyDict dict = properties->getPropertiesForPrefix("IceSSL.TrustOnly.Server.");
        for(Ice::PropertyDict::const_iterator p = dict.begin(); p != dict.end(); ++p)
        {
            string name = p->first.substr(string("IceSSL.TrustOnly.Server.").size());
            key = p->first;
            _server[name] = parse(p->second);
        }
    }
    catch(const ParseException& e)
    {
        Ice::PluginInitializationException ex(__FILE__, __LINE__);
        ex.reason = "IceSSL: invalid property " + key  + ":\n" + e.reason;
        throw ex;
    }
}
Exemple #2
0
NodeI::NodeI(const Ice::ObjectAdapterPtr& adapter,
             NodeSessionManager& sessions,
             const ActivatorPtr& activator,
             const IceUtil::TimerPtr& timer,
             const TraceLevelsPtr& traceLevels,
             const NodePrx& proxy,
             const string& name,
             const UserAccountMapperPrx& mapper,
             const string& instanceName) :
    _communicator(adapter->getCommunicator()),
    _adapter(adapter),
    _sessions(sessions),
    _activator(activator),
    _timer(timer),
    _traceLevels(traceLevels),
    _name(name),
    _proxy(proxy),
    _redirectErrToOut(false),
    _allowEndpointsOverride(false),
    _waitTime(0),
    _instanceName(instanceName),
    _userAccountMapper(mapper),
    _platform("IceGrid.Node", _communicator, _traceLevels),
    _fileCache(new FileCache(_communicator)),
    _serial(1),
    _consistencyCheckDone(false)
{
    Ice::PropertiesPtr props = _communicator->getProperties();

    const_cast<string&>(_dataDir) = _platform.getDataDir();
    const_cast<string&>(_serversDir) = _dataDir + "/servers";
    const_cast<string&>(_tmpDir) = _dataDir + "/tmp";
    const_cast<Ice::Int&>(_waitTime) = props->getPropertyAsIntWithDefault("IceGrid.Node.WaitTime", 60);
    const_cast<string&>(_outputDir) = props->getProperty("IceGrid.Node.Output");
    const_cast<bool&>(_redirectErrToOut) = props->getPropertyAsInt("IceGrid.Node.RedirectErrToOut") > 0;
    const_cast<bool&>(_allowEndpointsOverride) = props->getPropertyAsInt("IceGrid.Node.AllowEndpointsOverride") > 0;

    //
    // Parse the properties override property.
    //
    vector<string> overrides = props->getPropertyAsList("IceGrid.Node.PropertiesOverride");
    if(!overrides.empty())
    {
        for(vector<string>::iterator p = overrides.begin(); p != overrides.end(); ++p)
        {
            if(p->find("--") != 0)
            {
                *p = "--" + *p;
            }
        }

        Ice::PropertiesPtr p = Ice::createProperties();
        p->parseCommandLineOptions("", overrides);
        Ice::PropertyDict propDict = p->getPropertiesForPrefix("");
        for(Ice::PropertyDict::const_iterator q = propDict.begin(); q != propDict.end(); ++q)
        {
            _propertiesOverride.push_back(createProperty(q->first, q->second));
        }
    }
}
Exemple #3
0
static PyObject*
propertiesStr(PropertiesObject* self)
{
    assert(self->properties);

    Ice::PropertyDict dict;
    try
    {
        dict = (*self->properties)->getPropertiesForPrefix("");
    }
    catch(const Ice::Exception& ex)
    {
        setPythonException(ex);
        return 0;
    }

    string str;
    for(Ice::PropertyDict::const_iterator p = dict.begin(); p != dict.end(); ++p)
    {
        if(p != dict.begin())
        {
            str.append("\n");
        }
        str.append(p->first + "=" + p->second);
    }

    return createString(str);
}
Exemple #4
0
ZEND_METHOD(Ice_Properties, __toString)
{
    if(ZEND_NUM_ARGS() > 0)
    {
        WRONG_PARAM_COUNT;
    }

    Ice::PropertiesPtr _this = Wrapper<Ice::PropertiesPtr>::value(getThis() TSRMLS_CC);
    assert(_this);

    try
    {
        Ice::PropertyDict val = _this->getPropertiesForPrefix("");
        string str;
        for(Ice::PropertyDict::const_iterator p = val.begin(); p != val.end(); ++p)
        {
            if(p != val.begin())
            {
                str.append("\n");
            }
            str.append(p->first + "=" + p->second);
        }
        RETURN_STRINGL(STRCAST(str.c_str()), static_cast<int>(str.length()), 1);
    }
    catch(const IceUtil::Exception& ex)
    {
        throwException(ex TSRMLS_CC);
        RETURN_NULL();
    }
}
void
IcePy::UpdateCallbackWrapper::updated(const Ice::PropertyDict& dict)
{
    AdoptThread adoptThread; // Ensure the current thread is able to call into Python.

    PyObjectHandle result = PyDict_New();
    if(result.get())
    {
        for(Ice::PropertyDict::const_iterator p = dict.begin(); p != dict.end(); ++p)
        {
            PyObjectHandle key = createString(p->first);
            PyObjectHandle val = createString(p->second);
            if(!val.get() || PyDict_SetItem(result.get(), key.get(), val.get()) < 0)
            {
                return;
            }
        }
    }

    PyObjectHandle obj = PyObject_CallMethod(_callback, STRCAST("updated"), STRCAST("O"), result.get());
    if(!obj.get())
    {
        assert(PyErr_Occurred());
        throw AbortMarshaling();
    }
}
Exemple #6
0
  int
  Controller::load_camera_config(Ice::PropertyDict pd, int cam) {
    for(Ice::PropertyDict::const_iterator it = pd.begin(); it != pd.end(); it++) {

		std::istringstream sTemp;
      if((*it).first.compare("rgbdManualCalibrator.Config.Position.X")==0) {
	this->cameras[cam].position.X=(float)atof((*it).second.c_str());
	this->lastx = this->cameras[cam].position.X;
      }
      else if((*it).first.compare("rgbdManualCalibrator.Config.Position.Y")==0) {
	this->cameras[cam].position.Y=(float)atof((*it).second.c_str());
	this->lasty = this->cameras[cam].position.Y;
      }
      else if((*it).first.compare("rgbdManualCalibrator.Config.Position.Z")==0) {
	this->cameras[cam].position.Z=(float)atof((*it).second.c_str());
	this->lastz = this->cameras[cam].position.Z;
      }
      else if((*it).first.compare("rgbdManualCalibrator.Config.Position.H")==0) {
	this->cameras[cam].position.H=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.FOAPosition.X")==0) {
	this->cameras[cam].foa.X=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.FOAPosition.Y")==0) {
	this->cameras[cam].foa.Y=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.FOAPosition.Z")==0) {
	this->cameras[cam].foa.Z=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.FOAPosition.H")==0) {
	this->cameras[cam].foa.H=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.Roll")==0) {
	this->cameras[cam].roll=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.Fx")==0) {
	this->cameras[cam].fdistx=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.Fy")==0) {
	this->cameras[cam].fdisty=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.Skew")==0) {
	this->cameras[cam].skew=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.U0")==0) {
	this->cameras[cam].u0=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.V0")==0) {
	this->cameras[cam].v0=(float)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.Columns")==0) {
	this->cameras[cam].columns=(int)atof((*it).second.c_str());
      } 
      else if((*it).first.compare("rgbdManualCalibrator.Config.Rows")==0) {
	this->cameras[cam].rows=(int)atof((*it).second.c_str());
      } 
    }
  }
Exemple #7
0
void
PropsClient::show(const Ice::PropertiesAdminPrx& admin)
{
    Ice::PropertyDict props = admin->getPropertiesForPrefix("Demo");
    cout << "Server's current settings:" << endl;
    for(Ice::PropertyDict::iterator p = props.begin(); p != props.end(); ++p)
    {
        cout << "  " << p->first << "=" << p->second << endl;
    }
}
Exemple #8
0
static PyObject*
communicatorProxyToProperty(CommunicatorObject* self, PyObject* args)
{
    //
    // We don't want to accept None here, so we can specify ProxyType and force
    // the caller to supply a proxy object.
    //
    PyObject* proxyObj;
    PyObject* strObj;
    if(!PyArg_ParseTuple(args, STRCAST("O!O"), &ProxyType, &proxyObj, &strObj))
    {
        return 0;
    }

    Ice::ObjectPrx proxy = getProxy(proxyObj);
    string str;
    if(!getStringArg(strObj, "property", str))
    {
        return 0;
    }

    assert(self->communicator);
    Ice::PropertyDict dict;
    try
    {
        dict = (*self->communicator)->proxyToProperty(proxy, str);
    }
    catch(const Ice::Exception& ex)
    {
        setPythonException(ex);
        return 0;
    }

    PyObjectHandle result = PyDict_New();
    if(result.get())
    {
        for(Ice::PropertyDict::iterator p = dict.begin(); p != dict.end(); ++p)
        {
            PyObjectHandle key = createString(p->first);
            PyObjectHandle val = createString(p->second);
            if(!val.get() || PyDict_SetItem(result.get(), key.get(), val.get()) < 0)
            {
                return 0;
            }
        }
    }

    return result.release();
}
Exemple #9
0
MurmurIce::MurmurIce() {
	count = 0;

	if (meta->mp.qsIceEndpoint.isEmpty())
		return;

	Ice::PropertiesPtr ipp = Ice::createProperties();

	::Meta::mp.qsSettings->beginGroup("Ice");
	foreach(const QString &v, ::Meta::mp.qsSettings->childKeys()) {
		ipp->setProperty(u8(v), u8(::Meta::mp.qsSettings->value(v).toString()));
	}
	::Meta::mp.qsSettings->endGroup();

	Ice::PropertyDict props = ippProperties->getPropertiesForPrefix("");
	Ice::PropertyDict::iterator i;
	for (i=props.begin(); i != props.end(); ++i) {
		ipp->setProperty((*i).first, (*i).second);
	}
	ipp->setProperty("Ice.ImplicitContext", "Shared");

	Ice::InitializationData idd;
	idd.properties = ipp;

	try {
		communicator = Ice::initialize(idd);
		if (! meta->mp.qsIceSecretWrite.isEmpty()) {
			::Ice::ImplicitContextPtr impl = communicator->getImplicitContext();
			if (impl)
				impl->put("secret", u8(meta->mp.qsIceSecretWrite));
		}
		adapter = communicator->createObjectAdapterWithEndpoints("Murmur", qPrintable(meta->mp.qsIceEndpoint));
		MetaPtr m = new MetaI;
		MetaPrx mprx = MetaPrx::uncheckedCast(adapter->add(m, communicator->stringToIdentity("Meta")));
		adapter->addServantLocator(new ServerLocator(), "s");

		iopServer = new ServerI;

		adapter->activate();
		foreach(const Ice::EndpointPtr ep, mprx->ice_getEndpoints()) {
			qWarning("MurmurIce: Endpoint \"%s\" running", qPrintable(u8(ep->toString())));
		}

		meta->connectListener(this);
	} catch (Ice::Exception &e) {
		qCritical("MurmurIce: Initialization failed: %s", qPrintable(u8(e.ice_name())));
	}
}
Exemple #10
0
static PyObject*
propertiesGetPropertiesForPrefix(PropertiesObject* self, PyObject* args)
{
    PyObject* prefixObj;
    if(!PyArg_ParseTuple(args, STRCAST("O"), &prefixObj))
    {
        return 0;
    }

    string prefix;
    if(!getStringArg(prefixObj, "prefix", prefix))
    {
        return 0;
    }

    assert(self->properties);
    Ice::PropertyDict dict;
    try
    {
        dict = (*self->properties)->getPropertiesForPrefix(prefix);
    }
    catch(const Ice::Exception& ex)
    {
        setPythonException(ex);
        return 0;
    }

    PyObjectHandle result = PyDict_New();
    if(result.get())
    {
        for(Ice::PropertyDict::iterator p = dict.begin(); p != dict.end(); ++p)
        {
            PyObjectHandle key = createString(p->first);
            PyObjectHandle val = createString(p->second);
            if(!val.get() || PyDict_SetItem(result.get(), key.get(), val.get()) < 0)
            {
                return 0;
            }
        }
    }

    return result.release();
}
    std::map<string, string> client::getPropertyMap(const Ice::PropertiesPtr& properties) const {

        Ice::PropertiesPtr props;
        if (!properties) {
            props = getProperties();
        } else {
            props = properties;
        }

        std::map<string, string> pm;
        Ice::PropertyDict omeroProperties = props->getPropertiesForPrefix("omero");
        Ice::PropertyDict::const_iterator beg = omeroProperties.begin();
        Ice::PropertyDict::const_iterator end = omeroProperties.end();
        while (beg != end) {
            pm[(*beg).first] = (*beg).second;
            beg++;
        }
        Ice::PropertyDict iceProperties = props->getPropertiesForPrefix("Ice");
        beg = iceProperties.begin();
        end = iceProperties.end();
        while (beg != end) {
            pm[(*beg).first] = (*beg).second;
            beg++;
        }
        return pm;
    }
Exemple #12
0
TrustManager::TrustManager(const Ice::CommunicatorPtr& communicator) :
    _communicator(communicator)
{
    Ice::PropertiesPtr properties = communicator->getProperties();
    _traceLevel = properties->getPropertyAsInt("IceSSL.Trace.Security");
    string key;
    try
    {
        key = "IceSSL.TrustOnly";
        parse(properties->getProperty(key), _rejectAll, _acceptAll);
        key = "IceSSL.TrustOnly.Client";
        parse(properties->getProperty(key), _rejectClient, _acceptClient);
        key = "IceSSL.TrustOnly.Server";
        parse(properties->getProperty(key), _rejectAllServer, _acceptAllServer);
        Ice::PropertyDict dict = properties->getPropertiesForPrefix("IceSSL.TrustOnly.Server.");
        for(Ice::PropertyDict::const_iterator p = dict.begin(); p != dict.end(); ++p)
        {
            string name = p->first.substr(string("IceSSL.TrustOnly.Server.").size());
            key = p->first;
            list<DistinguishedName> reject, accept;
            parse(p->second, reject, accept);
            if(!reject.empty())
            {
                _rejectServer[name] = reject;
            }
            if(!accept.empty())
            {
                _acceptServer[name] = accept;
            }
        }
    }
    catch(const ParseException& e)
    {
        Ice::PluginInitializationException ex(__FILE__, __LINE__);
        ex.reason = "IceSSL: invalid property " + key  + ":\n" + e.reason;
        throw ex;
    }
}
Exemple #13
0
orca::ComponentData
getComponentData( const Context& context )
{
    orca::ComponentData compData;
    compData.name = context.name();

    Ice::PropertyDict providesProps =
        context.properties()->getPropertiesForPrefix(context.tag()+".Provides");
    orca::ProvidedInterface provided;
    for ( Ice::PropertyDict::iterator i=providesProps.begin(); i!=providesProps.end(); ++i ) {
        provided.name = i->second;
        provided.id = "unknown";
        compData.provides.push_back( provided );
    }

    // special cases: add standard interfaces (depending on startup flags)
    // first, add the Home interface itself
//     std::string homeIdentity = "orca." + context.name().platform + "." + context.name().component + "/Home";
//     provided.name = homeIdentity;
//     provided.id = "::orca::Home";
//     compData.provides.push_back( provided );
//
//     if ( interfaceFlag_& TracerInterface ) {
//         provided.name = "tracer";
//         provided.id = "::orca::Tracer";
//         compData.provides.push_back( provided );
//     }
//
//     if ( interfaceFlag_& StatusInterface ) {
//         provided.name = "status";
//         provided.id = "::orca::Status";
//         compData.provides.push_back( provided );
//     }

    // NOTE: this will not work if the config file uses long notation for req. interfaces
    Ice::PropertyDict requiresProps =
        context.properties()->getPropertiesForPrefix(context.tag()+".Requires");
    orca::RequiredInterface required;
    for ( Ice::PropertyDict::iterator i=requiresProps.begin(); i!=requiresProps.end(); ++i ) {
        required.name = orcaice::toInterfaceName( i->second );
        required.id = "unknown";
        compData.requires.push_back( required );
    }

    return compData;
}
Exemple #14
0
void
ServiceI::start(
    const string& name,
    const CommunicatorPtr& communicator,
    const StringSeq& /*args*/)
{
    PropertiesPtr properties = communicator->getProperties();

    validateProperties(name, properties, communicator->getLogger());

    int id = properties->getPropertyAsIntWithDefault(name + ".NodeId", -1);

    // If we are using a replicated deployment and if the topic
    // manager thread pool max size is not set then ensure it is set
    // to some suitably high number. This ensures no deadlocks in the
    // replicated case due to call forwarding from replicas to
    // coordinators.
    if(id != -1 && properties->getProperty(name + ".TopicManager.ThreadPool.SizeMax").empty())
    {
        properties->setProperty(name + ".TopicManager.ThreadPool.SizeMax", "100");
    }

    Ice::ObjectAdapterPtr topicAdapter = communicator->createObjectAdapter(name + ".TopicManager");
    Ice::ObjectAdapterPtr publishAdapter = communicator->createObjectAdapter(name + ".Publish");

    //
    // We use the name of the service for the name of the database environment.
    //
    string instanceName = properties->getPropertyWithDefault(name + ".InstanceName", "IceStorm");
    Identity topicManagerId;
    topicManagerId.category = instanceName;
    topicManagerId.name = "TopicManager";

    if(properties->getPropertyAsIntWithDefault(name+ ".Transient", 0) > 0)
    {
        _instance = new Instance(instanceName, name, communicator, publishAdapter, topicAdapter, 0);
        try
        {
            TransientTopicManagerImplPtr manager = new TransientTopicManagerImpl(_instance);
            _managerProxy = TopicManagerPrx::uncheckedCast(topicAdapter->add(manager, topicManagerId));
        }
        catch(const Ice::Exception& ex)
        {
            _instance = 0;

            LoggerOutputBase s;
            s << "exception while starting IceStorm service " << name << ":\n";
            s << ex;

            IceBox::FailureException e(__FILE__, __LINE__);
            e.reason = s.str();
            throw e;
        }
        topicAdapter->activate();
        publishAdapter->activate();
        return;
    }

    if(id == -1) // No replication.
    {
        _instance = new Instance(instanceName, name, communicator, publishAdapter, topicAdapter);

        try
        {
            _manager = new TopicManagerImpl(_instance);
            _managerProxy = TopicManagerPrx::uncheckedCast(topicAdapter->add(_manager->getServant(), topicManagerId));
        }
        catch(const Ice::Exception& ex)
        {
            _instance = 0;

            LoggerOutputBase s;
            s << "exception while starting IceStorm service " << name << ":\n";
            s << ex;

            IceBox::FailureException e(__FILE__, __LINE__);
            e.reason = s.str();
            throw e;
        }
    }
    else
    {
        // Here we want to create a map of id -> election node
        // proxies.
        map<int, NodePrx> nodes;

        string topicManagerAdapterId = properties->getProperty(name + ".TopicManager.AdapterId");

        // We support two possible deployments. The first is a manual
        // deployment, the second is IceGrid.
        //
        // Here we check for the manual deployment
        const string prefix = name + ".Nodes.";
        Ice::PropertyDict props = properties->getPropertiesForPrefix(prefix);
        if(!props.empty())
        {
            for(Ice::PropertyDict::const_iterator p = props.begin(); p != props.end(); ++p)
            {
                int nodeid = atoi(p->first.substr(prefix.size()).c_str());
                nodes[nodeid] = NodePrx::uncheckedCast(communicator->propertyToProxy(p->first));
            }
        }
        else
        {
            // If adapter id's are defined for the topic manager or
            // node adapters then we consider this an IceGrid based
            // deployment.
            string nodeAdapterId = properties->getProperty(name + ".Node.AdapterId");

            // Validate first that the adapter ids match for the node
            // and the topic manager otherwise some other deployment
            // is being used.
            const string suffix = ".TopicManager";
            if(topicManagerAdapterId.empty() || nodeAdapterId.empty() ||
               topicManagerAdapterId.replace(
                   topicManagerAdapterId.find(suffix), suffix.size(), ".Node") != nodeAdapterId)
            {
                Ice::Error error(communicator->getLogger());
                error << "deployment error: `" << topicManagerAdapterId << "' prefix does not match `"
                      << nodeAdapterId << "'";
                throw IceBox::FailureException(__FILE__, __LINE__, "IceGrid deployment is incorrect");
            }

            // Determine the set of node id and node proxies.
            //
            // This is determined by locating all topic manager
            // replicas, and then working out the node for that
            // replica.
            //
            // We work out the node id by removing the instance
            // name. The node id must follow.
            //
            IceGrid::LocatorPrx locator = IceGrid::LocatorPrx::checkedCast(communicator->getDefaultLocator());
            assert(locator);
            IceGrid::QueryPrx query = locator->getLocalQuery();
            Ice::ObjectProxySeq replicas = query->findAllReplicas(
                communicator->stringToProxy(instanceName + "/TopicManager"));

            for(Ice::ObjectProxySeq::const_iterator p = replicas.begin(); p != replicas.end(); ++p)
            {
                string adapterid = (*p)->ice_getAdapterId();

                // Replace TopicManager with the node endpoint.
                adapterid = adapterid.replace(adapterid.find(suffix), suffix.size(), ".Node");

                // The adapter id must start with the instance name.
                if(adapterid.find(instanceName) != 0)
                {
                    Ice::Error error(communicator->getLogger());
                    error << "deployment error: `" << adapterid << "' does not start with `" << instanceName << "'";
                    throw IceBox::FailureException(__FILE__, __LINE__, "IceGrid deployment is incorrect");
                }

                // The node id follows. We find the first digit (the
                // start of the node id, and then the end of the
                // digits).
                string::size_type start = instanceName.size();
                while(start < adapterid.size() && !IceUtilInternal::isDigit(adapterid[start]))
                {
                    ++start;
                }
                string::size_type end = start;
                while(end < adapterid.size() && IceUtilInternal::isDigit(adapterid[end]))
                {
                    ++end;
                }
                if(start == end)
                {
                    // We must have at least one digit, otherwise there is
                    // some sort of deployment error.
                    Ice::Error error(communicator->getLogger());
                    error << "deployment error: node id does not follow instance name. instance name:"
                          << instanceName << " adapter id: " << adapterid;
                    throw IceBox::FailureException(__FILE__, __LINE__, "IceGrid deployment is incorrect");
                }

                int nodeid = atoi(adapterid.substr(start, end-start).c_str());
                ostringstream os;
                os << "node" << nodeid;
                Ice::Identity id;
                id.category = instanceName;
                id.name = os.str();

                nodes[nodeid] = NodePrx::uncheckedCast((*p)->ice_adapterId(adapterid)->ice_identity(id));
            }
        }

        if(nodes.size() < 3)
        {
            Ice::Error error(communicator->getLogger());
            error << "Replication requires at least 3 Nodes";
            throw IceBox::FailureException(__FILE__, __LINE__, "Replication requires at least 3 Nodes");
        }

        try
        {
            // If the node thread pool size is not set then initialize
            // to the number of nodes + 1 and disable thread pool size
            // warnings.
            if(properties->getProperty(name + ".Node.ThreadPool.Size").empty())
            {
                ostringstream os;
                os << nodes.size() + 1;
                properties->setProperty(name + ".Node.ThreadPool.Size", os.str());
                properties->setProperty(name + ".Node.ThreadPool.SizeWarn", "0");
            }
            if(properties->getProperty(name + ".Node.MessageSizeMax").empty())
            {
                properties->setProperty(name + ".Node.MessageSizeMax", "0"); // No limit on data exchanged internally
            }

            Ice::ObjectAdapterPtr nodeAdapter = communicator->createObjectAdapter(name + ".Node");

            _instance = new Instance(instanceName, name, communicator, publishAdapter, topicAdapter,
                                     nodeAdapter, nodes[id]);
            _instance->observers()->setMajority(static_cast<unsigned int>(nodes.size())/2);

            // Trace replication information.
            TraceLevelsPtr traceLevels = _instance->traceLevels();
            if(traceLevels->election > 0)
            {
                Ice::Trace out(traceLevels->logger, traceLevels->electionCat);
                out << "I am node " << id << "\n";
                for(map<int, NodePrx>::const_iterator p = nodes.begin(); p != nodes.end(); ++p)
                {
                    out << "\tnode: " << p->first << " proxy: " << p->second->ice_toString() << "\n";
                }
            }

            if(topicManagerAdapterId.empty())
            {
                // We're not using an IceGrid deployment. Here we need
                // a proxy which is used to create proxies to the
                // replicas later.
                _managerProxy = TopicManagerPrx::uncheckedCast(topicAdapter->createProxy(topicManagerId));
            }
            else
            {
                // If we're using IceGrid deployment we need to create
                // indirect proxies.
                _managerProxy = TopicManagerPrx::uncheckedCast(topicAdapter->createIndirectProxy(topicManagerId));
            }

            _manager = new TopicManagerImpl(_instance);
            topicAdapter->add(_manager->getServant(), topicManagerId);

            ostringstream os; // The node object identity.
            os << "node" << id;
            Ice::Identity nodeid;
            nodeid.category = instanceName;
            nodeid.name = os.str();

            NodeIPtr node = new NodeI(_instance, _manager, _managerProxy, id, nodes);
            _instance->setNode(node);
            nodeAdapter->add(node, nodeid);
            nodeAdapter->activate();

            node->start();
        }
        catch(const Ice::Exception& ex)
        {
            _instance = 0;

            LoggerOutputBase s;
            s << "exception while starting IceStorm service " << name << ":\n";
            s << ex;

            IceBox::FailureException e(__FILE__, __LINE__);
            e.reason = s.str();
            throw e;
        }
    }

    topicAdapter->add(new FinderI(TopicManagerPrx::uncheckedCast(topicAdapter->createProxy(topicManagerId))),
                      communicator->stringToIdentity("IceStorm/Finder"));

    topicAdapter->activate();
    publishAdapter->activate();
}
Exemple #15
0
Test::MyClassPrx
allTests(const Ice::CommunicatorPtr& communicator)
{
    cout << "testing stringToProxy... " << flush;
    string ref = "test:default -p 12010";
    Ice::ObjectPrx base = communicator->stringToProxy(ref);
    test(base);

    Ice::ObjectPrx b1 = communicator->stringToProxy("test");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getAdapterId().empty() && b1->ice_getFacet().empty());
    b1 = communicator->stringToProxy("test ");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet().empty());
    b1 = communicator->stringToProxy(" test ");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet().empty());
    b1 = communicator->stringToProxy(" test");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet().empty());
    b1 = communicator->stringToProxy("'test -f facet'");
    test(b1->ice_getIdentity().name == "test -f facet" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet().empty());
    try
    {
        b1 = communicator->stringToProxy("\"test -f facet'");
        test(false);
    }
    catch(const Ice::ProxyParseException&)
    {
    }
    b1 = communicator->stringToProxy("\"test -f facet\"");
    test(b1->ice_getIdentity().name == "test -f facet" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet().empty());
    b1 = communicator->stringToProxy("\"test -f facet@test\"");
    test(b1->ice_getIdentity().name == "test -f facet@test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet().empty());
    b1 = communicator->stringToProxy("\"test -f facet@test @test\"");
    test(b1->ice_getIdentity().name == "test -f facet@test @test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet().empty());
    try
    {
        b1 = communicator->stringToProxy("test test");
        test(false);
    }
    catch(const Ice::ProxyParseException&)
    {
    }
    b1 = communicator->stringToProxy("test\\040test");
    test(b1->ice_getIdentity().name == "test test" && b1->ice_getIdentity().category.empty());
    try
    {
        b1 = communicator->stringToProxy("test\\777");
        test(false);
    }
    catch(const Ice::IdentityParseException&)
    {
    }
    b1 = communicator->stringToProxy("test\\40test");
    test(b1->ice_getIdentity().name == "test test");

    // Test some octal and hex corner cases.
    b1 = communicator->stringToProxy("test\\4test");
    test(b1->ice_getIdentity().name == "test\4test");
    b1 = communicator->stringToProxy("test\\04test");
    test(b1->ice_getIdentity().name == "test\4test");
    b1 = communicator->stringToProxy("test\\004test");
    test(b1->ice_getIdentity().name == "test\4test");
    b1 = communicator->stringToProxy("test\\1114test");
    test(b1->ice_getIdentity().name == "test\1114test");

    b1 = communicator->stringToProxy("test\\b\\f\\n\\r\\t\\'\\\"\\\\test");
    test(b1->ice_getIdentity().name == "test\b\f\n\r\t\'\"\\test" && b1->ice_getIdentity().category.empty());

    b1 = communicator->stringToProxy("category/test");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category == "category" &&
         b1->ice_getAdapterId().empty());

    b1 = communicator->stringToProxy("");
    test(!b1);
    b1 = communicator->stringToProxy("\"\"");
    test(!b1);
    try
    {
        b1 = communicator->stringToProxy("\"\" test"); // Invalid trailing characters.
        test(false);
    }
    catch(const Ice::ProxyParseException&)
    {
    }
    try
    {
        b1 = communicator->stringToProxy("test:"); // Missing endpoint.
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    b1 = communicator->stringToProxy("test@adapter");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getAdapterId() == "adapter");
    try
    {
        b1 = communicator->stringToProxy("id@adapter test");
        test(false);
    }
    catch(const Ice::ProxyParseException&)
    {
    }
    b1 = communicator->stringToProxy("category/test@adapter");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category == "category" &&
         b1->ice_getAdapterId() == "adapter");
    b1 = communicator->stringToProxy("category/test@adapter:tcp");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category == "category" &&
         b1->ice_getAdapterId() == "adapter:tcp");
    b1 = communicator->stringToProxy("'category 1/test'@adapter");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category == "category 1" &&
         b1->ice_getAdapterId() == "adapter");
    b1 = communicator->stringToProxy("'category/test 1'@adapter");
    test(b1->ice_getIdentity().name == "test 1" && b1->ice_getIdentity().category == "category" &&
         b1->ice_getAdapterId() == "adapter");
    b1 = communicator->stringToProxy("'category/test'@'adapter 1'");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category == "category" &&
         b1->ice_getAdapterId() == "adapter 1");
    b1 = communicator->stringToProxy("\"category \\/test@foo/test\"@adapter");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category == "category /test@foo" &&
         b1->ice_getAdapterId() == "adapter");
    b1 = communicator->stringToProxy("\"category \\/test@foo/test\"@\"adapter:tcp\"");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category == "category /test@foo" &&
         b1->ice_getAdapterId() == "adapter:tcp");

    b1 = communicator->stringToProxy("id -f facet");
    test(b1->ice_getIdentity().name == "id" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet() == "facet");
    b1 = communicator->stringToProxy("id -f 'facet x'");
    test(b1->ice_getIdentity().name == "id" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet() == "facet x");
    b1 = communicator->stringToProxy("id -f \"facet x\"");
    test(b1->ice_getIdentity().name == "id" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet() == "facet x");
    try
    {
        b1 = communicator->stringToProxy("id -f \"facet x");
        test(false);
    }
    catch(const Ice::ProxyParseException&)
    {
    }
    try
    {
        b1 = communicator->stringToProxy("id -f \'facet x");
        test(false);
    }
    catch(const Ice::ProxyParseException&)
    {
    }
    b1 = communicator->stringToProxy("test -f facet:tcp");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet() == "facet" && b1->ice_getAdapterId().empty());
    b1 = communicator->stringToProxy("test -f \"facet:tcp\"");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet() == "facet:tcp" && b1->ice_getAdapterId().empty());
    b1 = communicator->stringToProxy("test -f facet@test");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet() == "facet" && b1->ice_getAdapterId() == "test");
    b1 = communicator->stringToProxy("test -f 'facet@test'");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet() == "facet@test" && b1->ice_getAdapterId().empty());
    b1 = communicator->stringToProxy("test -f 'facet@test'@test");
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getFacet() == "facet@test" && b1->ice_getAdapterId() == "test");
    try
    {
        b1 = communicator->stringToProxy("test -f facet@test @test");
        test(false);
    }
    catch(const Ice::ProxyParseException&)
    {
    }
    b1 = communicator->stringToProxy("test");
    test(b1->ice_isTwoway());
    b1 = communicator->stringToProxy("test -t");
    test(b1->ice_isTwoway());
    b1 = communicator->stringToProxy("test -o");
    test(b1->ice_isOneway());
    b1 = communicator->stringToProxy("test -O");
    test(b1->ice_isBatchOneway());
    b1 = communicator->stringToProxy("test -d");
    test(b1->ice_isDatagram());
    b1 = communicator->stringToProxy("test -D");
    test(b1->ice_isBatchDatagram());
    b1 = communicator->stringToProxy("test");
    test(!b1->ice_isSecure());
    b1 = communicator->stringToProxy("test -s");
    test(b1->ice_isSecure());

    test(b1->ice_getEncodingVersion() == Ice::currentEncoding);

    b1 = communicator->stringToProxy("test -e 1.0");
    test(b1->ice_getEncodingVersion().major == 1 && b1->ice_getEncodingVersion().minor == 0);

    b1 = communicator->stringToProxy("test -e 6.5");
    test(b1->ice_getEncodingVersion().major == 6 && b1->ice_getEncodingVersion().minor == 5);

    b1 = communicator->stringToProxy("test -p 1.0 -e 1.0");
    test(b1->ice_toString() == "test -t -e 1.0");

    b1 = communicator->stringToProxy("test -p 6.5 -e 1.0");
    test(b1->ice_toString() == "test -t -p 6.5 -e 1.0");

    try
    {
        b1 = communicator->stringToProxy("test:tcp@adapterId");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }
    // This is an unknown endpoint warning, not a parse exception.
    //
    //try
    //{
    //   b1 = communicator->stringToProxy("test -f the:facet:tcp");
    //   test(false);
    //}
    //catch(const Ice::EndpointParseException&)
    //{
    //}
    try
    {
        b1 = communicator->stringToProxy("test::tcp");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    //
    // Test for bug ICE-5543: escaped escapes in stringToIdentity
    //
    Ice::Identity id = { "test", ",X2QNUAzSBcJ_e$AV;E\\" };
    Ice::Identity id2 = communicator->stringToIdentity(communicator->identityToString(id));
    test(id == id2);

    id.name = "test";
    id.category = ",X2QNUAz\\SB\\/cJ_e$AV;E\\\\";
    id2 = communicator->stringToIdentity(communicator->identityToString(id));
    test(id == id2);

    cout << "ok" << endl;

    cout << "testing propertyToProxy... " << flush;
    Ice::PropertiesPtr prop = communicator->getProperties();
    string propertyPrefix = "Foo.Proxy";
    prop->setProperty(propertyPrefix, "test:default -p 12010");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getIdentity().name == "test" && b1->ice_getIdentity().category.empty() &&
         b1->ice_getAdapterId().empty() && b1->ice_getFacet().empty());

    string property;

    property = propertyPrefix + ".Locator";
    test(!b1->ice_getLocator());
    prop->setProperty(property, "locator:default -p 10000");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getLocator() && b1->ice_getLocator()->ice_getIdentity().name == "locator");
    prop->setProperty(property, "");

    property = propertyPrefix + ".LocatorCacheTimeout";
    test(b1->ice_getLocatorCacheTimeout() == -1);
    prop->setProperty(property, "1");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getLocatorCacheTimeout() == 1);
    prop->setProperty(property, "");

    // Now retest with an indirect proxy.
    prop->setProperty(propertyPrefix, "test");
    property = propertyPrefix + ".Locator";
    prop->setProperty(property, "locator:default -p 10000");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getLocator() && b1->ice_getLocator()->ice_getIdentity().name == "locator");
    prop->setProperty(property, "");

    property = propertyPrefix + ".LocatorCacheTimeout";
    test(b1->ice_getLocatorCacheTimeout() == -1);
    prop->setProperty(property, "1");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getLocatorCacheTimeout() == 1);
    prop->setProperty(property, "");

    // This cannot be tested so easily because the property is cached
    // on communicator initialization.
    //
    //prop->setProperty("Ice.Default.LocatorCacheTimeout", "60");
    //b1 = communicator->propertyToProxy(propertyPrefix);
    //test(b1->ice_getLocatorCacheTimeout() == 60);
    //prop->setProperty("Ice.Default.LocatorCacheTimeout", "");

    prop->setProperty(propertyPrefix, "test:default -p 12010");

    property = propertyPrefix + ".Router";
    test(!b1->ice_getRouter());
    prop->setProperty(property, "router:default -p 10000");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getRouter() && b1->ice_getRouter()->ice_getIdentity().name == "router");
    prop->setProperty(property, "");

    property = propertyPrefix + ".PreferSecure";
    test(!b1->ice_isPreferSecure());
    prop->setProperty(property, "1");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_isPreferSecure());
    prop->setProperty(property, "");

    property = propertyPrefix + ".ConnectionCached";
    test(b1->ice_isConnectionCached());
    prop->setProperty(property, "0");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(!b1->ice_isConnectionCached());
    prop->setProperty(property, "");

    property = propertyPrefix + ".InvocationTimeout";
    test(b1->ice_getInvocationTimeout() == -1);
    prop->setProperty(property, "1000");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getInvocationTimeout() == 1000);
    prop->setProperty(property, "");

    property = propertyPrefix + ".EndpointSelection";
    test(b1->ice_getEndpointSelection() == Ice::Random);
    prop->setProperty(property, "Random");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getEndpointSelection() == Ice::Random);
    prop->setProperty(property, "Ordered");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getEndpointSelection() == Ice::Ordered);
    prop->setProperty(property, "");

    property = propertyPrefix + ".CollocationOptimized";
    test(b1->ice_isCollocationOptimized());
    prop->setProperty(property, "0");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(!b1->ice_isCollocationOptimized());
    prop->setProperty(property, "");

    property = propertyPrefix + ".Context.c1";
    test(b1->ice_getContext()["c1"].empty());
    prop->setProperty(property, "TEST");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getContext()["c1"] == "TEST");

    property = propertyPrefix + ".Context.c2";
    test(b1->ice_getContext()["c2"].empty());
    prop->setProperty(property, "TEST");
    b1 = communicator->propertyToProxy(propertyPrefix);
    test(b1->ice_getContext()["c2"] == "TEST");

    prop->setProperty(propertyPrefix + ".Context.c1", "");
    prop->setProperty(propertyPrefix + ".Context.c2", "");

    cout << "ok" << endl;

    cout << "testing proxyToProperty... " << flush;

    b1 = communicator->stringToProxy("test");
    b1 = b1->ice_collocationOptimized(true);
    b1 = b1->ice_connectionCached(true);
    b1 = b1->ice_preferSecure(false);
    b1 = b1->ice_endpointSelection(Ice::Ordered);
    b1 = b1->ice_locatorCacheTimeout(100);
    b1 = b1->ice_invocationTimeout(1234);
    Ice::EncodingVersion v = { 1, 0 };
    b1 = b1->ice_encodingVersion(v);
    Ice::ObjectPrx router = communicator->stringToProxy("router");
    router = router->ice_collocationOptimized(false);
    router = router->ice_connectionCached(true);
    router = router->ice_preferSecure(true);
    router = router->ice_endpointSelection(Ice::Random);
    router = router->ice_locatorCacheTimeout(200);
    router = router->ice_invocationTimeout(1500);

    Ice::ObjectPrx locator = communicator->stringToProxy("locator");
    locator = locator->ice_collocationOptimized(true);
    locator = locator->ice_connectionCached(false);
    locator = locator->ice_preferSecure(true);
    locator = locator->ice_endpointSelection(Ice::Random);
    locator = locator->ice_locatorCacheTimeout(300);
    locator = locator->ice_invocationTimeout(1500);

    locator = locator->ice_router(Ice::RouterPrx::uncheckedCast(router));
    b1 = b1->ice_locator(Ice::LocatorPrx::uncheckedCast(locator));

    Ice::PropertyDict proxyProps = communicator->proxyToProperty(b1, "Test");
    test(proxyProps.size() == 21);

    test(proxyProps["Test"] == "test -t -e 1.0");
    test(proxyProps["Test.CollocationOptimized"] == "1");
    test(proxyProps["Test.ConnectionCached"] == "1");
    test(proxyProps["Test.PreferSecure"] == "0");
    test(proxyProps["Test.EndpointSelection"] == "Ordered");
    test(proxyProps["Test.LocatorCacheTimeout"] == "100");
    test(proxyProps["Test.InvocationTimeout"] == "1234");

    test(proxyProps["Test.Locator"] == "locator -t -e " + Ice::encodingVersionToString(Ice::currentEncoding));
    // Locator collocation optimization is always disabled.
    //test(proxyProps["Test.Locator.CollocationOptimized"] == "1");
    test(proxyProps["Test.Locator.ConnectionCached"] == "0");
    test(proxyProps["Test.Locator.PreferSecure"] == "1");
    test(proxyProps["Test.Locator.EndpointSelection"] == "Random");
    test(proxyProps["Test.Locator.LocatorCacheTimeout"] == "300");
    test(proxyProps["Test.Locator.InvocationTimeout"] == "1500");

    test(proxyProps["Test.Locator.Router"] == "router -t -e " + Ice::encodingVersionToString(Ice::currentEncoding));
    test(proxyProps["Test.Locator.Router.CollocationOptimized"] == "0");
    test(proxyProps["Test.Locator.Router.ConnectionCached"] == "1");
    test(proxyProps["Test.Locator.Router.PreferSecure"] == "1");
    test(proxyProps["Test.Locator.Router.EndpointSelection"] == "Random");
    test(proxyProps["Test.Locator.Router.LocatorCacheTimeout"] == "200");
    test(proxyProps["Test.Locator.Router.InvocationTimeout"] == "1500");

    cout << "ok" << endl;

    cout << "testing ice_getCommunicator... " << flush;
    test(base->ice_getCommunicator() == communicator);
    cout << "ok" << endl;

    cout << "testing proxy methods... " << flush;
    test(communicator->identityToString(base->ice_identity(communicator->stringToIdentity("other"))->ice_getIdentity())
         == "other");
    test(base->ice_facet("facet")->ice_getFacet() == "facet");
    test(base->ice_adapterId("id")->ice_getAdapterId() == "id");
    test(base->ice_twoway()->ice_isTwoway());
    test(base->ice_oneway()->ice_isOneway());
    test(base->ice_batchOneway()->ice_isBatchOneway());
    test(base->ice_datagram()->ice_isDatagram());
    test(base->ice_batchDatagram()->ice_isBatchDatagram());
    test(base->ice_secure(true)->ice_isSecure());
    test(!base->ice_secure(false)->ice_isSecure());
    test(base->ice_collocationOptimized(true)->ice_isCollocationOptimized());
    test(!base->ice_collocationOptimized(false)->ice_isCollocationOptimized());
    test(base->ice_preferSecure(true)->ice_isPreferSecure());
    test(!base->ice_preferSecure(false)->ice_isPreferSecure());
    test(base->ice_encodingVersion(Ice::Encoding_1_0)->ice_getEncodingVersion() == Ice::Encoding_1_0);
    test(base->ice_encodingVersion(Ice::Encoding_1_1)->ice_getEncodingVersion() == Ice::Encoding_1_1);
    test(base->ice_encodingVersion(Ice::Encoding_1_0)->ice_getEncodingVersion() != Ice::Encoding_1_1);

    try
    {
        base->ice_timeout(0);
        test(false);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
    }

    try
    {
        base->ice_timeout(-1);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
        test(false);
    }

    try
    {
        base->ice_timeout(-2);
        test(false);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
    }

    try
    {
        base->ice_invocationTimeout(0);
        test(false);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
    }

    try
    {
        base->ice_invocationTimeout(-1);
        base->ice_invocationTimeout(-2);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
        test(false);
    }

    try
    {
        base->ice_invocationTimeout(-3);
        test(false);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
    }

    try
    {
        base->ice_locatorCacheTimeout(0);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
        test(false);
    }

    try
    {
        base->ice_locatorCacheTimeout(-1);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
        test(false);
    }

    try
    {
        base->ice_locatorCacheTimeout(-2);
        test(false);
    }
    catch(const IceUtil::IllegalArgumentException&)
    {
    }

    cout << "ok" << endl;

    cout << "testing proxy comparison... " << flush;

    test(communicator->stringToProxy("foo") == communicator->stringToProxy("foo"));
    test(communicator->stringToProxy("foo") != communicator->stringToProxy("foo2"));
    test(communicator->stringToProxy("foo") < communicator->stringToProxy("foo2"));
    test(!(communicator->stringToProxy("foo2") < communicator->stringToProxy("foo")));

    Ice::ObjectPrx compObj = communicator->stringToProxy("foo");

    test(compObj->ice_facet("facet") == compObj->ice_facet("facet"));
    test(compObj->ice_facet("facet") != compObj->ice_facet("facet1"));
    test(compObj->ice_facet("facet") < compObj->ice_facet("facet1"));
    test(!(compObj->ice_facet("facet") < compObj->ice_facet("facet")));

    test(compObj->ice_oneway() == compObj->ice_oneway());
    test(compObj->ice_oneway() != compObj->ice_twoway());
    test(compObj->ice_twoway() < compObj->ice_oneway());
    test(!(compObj->ice_oneway() < compObj->ice_twoway()));

    test(compObj->ice_secure(true) == compObj->ice_secure(true));
    test(compObj->ice_secure(false) != compObj->ice_secure(true));
    test(compObj->ice_secure(false) < compObj->ice_secure(true));
    test(!(compObj->ice_secure(true) < compObj->ice_secure(false)));

    test(compObj->ice_collocationOptimized(true) == compObj->ice_collocationOptimized(true));
    test(compObj->ice_collocationOptimized(false) != compObj->ice_collocationOptimized(true));
    test(compObj->ice_collocationOptimized(false) < compObj->ice_collocationOptimized(true));
    test(!(compObj->ice_collocationOptimized(true) < compObj->ice_collocationOptimized(false)));

    test(compObj->ice_connectionCached(true) == compObj->ice_connectionCached(true));
    test(compObj->ice_connectionCached(false) != compObj->ice_connectionCached(true));
    test(compObj->ice_connectionCached(false) < compObj->ice_connectionCached(true));
    test(!(compObj->ice_connectionCached(true) < compObj->ice_connectionCached(false)));

    test(compObj->ice_endpointSelection(Ice::Random) == compObj->ice_endpointSelection(Ice::Random));
    test(compObj->ice_endpointSelection(Ice::Random) != compObj->ice_endpointSelection(Ice::Ordered));
    test(compObj->ice_endpointSelection(Ice::Random) < compObj->ice_endpointSelection(Ice::Ordered));
    test(!(compObj->ice_endpointSelection(Ice::Ordered) < compObj->ice_endpointSelection(Ice::Random)));

    test(compObj->ice_connectionId("id2") == compObj->ice_connectionId("id2"));
    test(compObj->ice_connectionId("id1") != compObj->ice_connectionId("id2"));
    test(compObj->ice_connectionId("id1") < compObj->ice_connectionId("id2"));
    test(!(compObj->ice_connectionId("id2") < compObj->ice_connectionId("id1")));

    test(compObj->ice_connectionId("id1")->ice_getConnectionId() == "id1");
    test(compObj->ice_connectionId("id2")->ice_getConnectionId() == "id2");

    test(compObj->ice_compress(true) == compObj->ice_compress(true));
    test(compObj->ice_compress(false) != compObj->ice_compress(true));
    test(compObj->ice_compress(false) < compObj->ice_compress(true));
    test(!(compObj->ice_compress(true) < compObj->ice_compress(false)));

    test(compObj->ice_timeout(20) == compObj->ice_timeout(20));
    test(compObj->ice_timeout(10) != compObj->ice_timeout(20));
    test(compObj->ice_timeout(10) < compObj->ice_timeout(20));
    test(!(compObj->ice_timeout(20) < compObj->ice_timeout(10)));

    Ice::LocatorPrx loc1 = Ice::LocatorPrx::uncheckedCast(communicator->stringToProxy("loc1:default -p 10000"));
    Ice::LocatorPrx loc2 = Ice::LocatorPrx::uncheckedCast(communicator->stringToProxy("loc2:default -p 10000"));
    test(compObj->ice_locator(0) == compObj->ice_locator(0));
    test(compObj->ice_locator(loc1) == compObj->ice_locator(loc1));
    test(compObj->ice_locator(loc1) != compObj->ice_locator(0));
    test(compObj->ice_locator(0) != compObj->ice_locator(loc2));
    test(compObj->ice_locator(loc1) != compObj->ice_locator(loc2));
    test(compObj->ice_locator(0) < compObj->ice_locator(loc1));
    test(!(compObj->ice_locator(loc1) < compObj->ice_locator(0)));
    test(compObj->ice_locator(loc1) < compObj->ice_locator(loc2));
    test(!(compObj->ice_locator(loc2) < compObj->ice_locator(loc1)));

    Ice::RouterPrx rtr1 = Ice::RouterPrx::uncheckedCast(communicator->stringToProxy("rtr1:default -p 10000"));
    Ice::RouterPrx rtr2 = Ice::RouterPrx::uncheckedCast(communicator->stringToProxy("rtr2:default -p 10000"));
    test(compObj->ice_router(0) == compObj->ice_router(0));
    test(compObj->ice_router(rtr1) == compObj->ice_router(rtr1));
    test(compObj->ice_router(rtr1) != compObj->ice_router(0));
    test(compObj->ice_router(0) != compObj->ice_router(rtr2));
    test(compObj->ice_router(rtr1) != compObj->ice_router(rtr2));
    test(compObj->ice_router(0) < compObj->ice_router(rtr1));
    test(!(compObj->ice_router(rtr1) < compObj->ice_router(0)));
    test(compObj->ice_router(rtr1) < compObj->ice_router(rtr2));
    test(!(compObj->ice_router(rtr2) < compObj->ice_router(rtr1)));

    Ice::Context ctx1;
    ctx1["ctx1"] = "v1";
    Ice::Context ctx2;
    ctx2["ctx2"] = "v2";
    test(compObj->ice_context(Ice::Context()) == compObj->ice_context(Ice::Context()));
    test(compObj->ice_context(ctx1) == compObj->ice_context(ctx1));
    test(compObj->ice_context(ctx1) != compObj->ice_context(Ice::Context()));
    test(compObj->ice_context(Ice::Context()) != compObj->ice_context(ctx2));
    test(compObj->ice_context(ctx1) != compObj->ice_context(ctx2));
    test(compObj->ice_context(ctx1) < compObj->ice_context(ctx2));
    test(!(compObj->ice_context(ctx2) < compObj->ice_context(ctx1)));

    test(compObj->ice_preferSecure(true) == compObj->ice_preferSecure(true));
    test(compObj->ice_preferSecure(true) != compObj->ice_preferSecure(false));
    test(compObj->ice_preferSecure(false) < compObj->ice_preferSecure(true));
    test(!(compObj->ice_preferSecure(true) < compObj->ice_preferSecure(false)));

    Ice::ObjectPrx compObj1 = communicator->stringToProxy("foo:tcp -h 127.0.0.1 -p 10000");
    Ice::ObjectPrx compObj2 = communicator->stringToProxy("foo:tcp -h 127.0.0.1 -p 10001");
    test(compObj1 != compObj2);
    test(compObj1 < compObj2);
    test(!(compObj2 < compObj1));

    compObj1 = communicator->stringToProxy("foo@MyAdapter1");
    compObj2 = communicator->stringToProxy("foo@MyAdapter2");
    test(compObj1 != compObj2);
    test(compObj1 < compObj2);
    test(!(compObj2 < compObj1));

    test(compObj1->ice_locatorCacheTimeout(20) == compObj1->ice_locatorCacheTimeout(20));
    test(compObj1->ice_locatorCacheTimeout(10) != compObj1->ice_locatorCacheTimeout(20));
    test(compObj1->ice_locatorCacheTimeout(10) < compObj1->ice_locatorCacheTimeout(20));
    test(!(compObj1->ice_locatorCacheTimeout(20) < compObj1->ice_locatorCacheTimeout(10)));

    test(compObj1->ice_invocationTimeout(20) == compObj1->ice_invocationTimeout(20));
    test(compObj1->ice_invocationTimeout(10) != compObj1->ice_invocationTimeout(20));
    test(compObj1->ice_invocationTimeout(10) < compObj1->ice_invocationTimeout(20));
    test(!(compObj1->ice_invocationTimeout(20) < compObj1->ice_invocationTimeout(10)));

    compObj1 = communicator->stringToProxy("foo:tcp -h 127.0.0.1 -p 1000");
    compObj2 = communicator->stringToProxy("foo@MyAdapter1");
    test(compObj1 != compObj2);
    test(compObj1 < compObj2);
    test(!(compObj2 < compObj1));

    Ice::EndpointSeq endpts1 = communicator->stringToProxy("foo:tcp -h 127.0.0.1 -p 10000")->ice_getEndpoints();
    Ice::EndpointSeq endpts2 = communicator->stringToProxy("foo:tcp -h 127.0.0.1 -p 10001")->ice_getEndpoints();
    test(endpts1 != endpts2);
    test(endpts1 < endpts2);
    test(!(endpts2 < endpts1));
    test(endpts1 == communicator->stringToProxy("foo:tcp -h 127.0.0.1 -p 10000")->ice_getEndpoints());

    test(compObj1->ice_encodingVersion(Ice::Encoding_1_0) == compObj1->ice_encodingVersion(Ice::Encoding_1_0));
    test(compObj1->ice_encodingVersion(Ice::Encoding_1_0) != compObj1->ice_encodingVersion(Ice::Encoding_1_1));
    test(compObj->ice_encodingVersion(Ice::Encoding_1_0) < compObj->ice_encodingVersion(Ice::Encoding_1_1));
    test(!(compObj->ice_encodingVersion(Ice::Encoding_1_1) < compObj->ice_encodingVersion(Ice::Encoding_1_0)));

    //
    // TODO: Ideally we should also test comparison of fixed proxies.
    //

    cout << "ok" << endl;

    cout << "testing checked cast... " << flush;
    Test::MyClassPrx cl = Test::MyClassPrx::checkedCast(base);
    test(cl);

    Test::MyDerivedClassPrx derived = Test::MyDerivedClassPrx::checkedCast(cl);
    test(derived);
    test(cl == base);
    test(derived == base);
    test(cl == derived);

    Ice::LocatorPrx loc = Ice::LocatorPrx::checkedCast(base);
    test(loc == 0);

    //
    // Upcasting
    //
    Test::MyClassPrx cl2 = Test::MyClassPrx::checkedCast(derived);
    Ice::ObjectPrx obj = Ice::ObjectPrx::checkedCast(derived);
    test(cl2);
    test(obj);
    test(cl2 == obj);
    test(cl2 == derived);

    //
    // Now with alternate API
    //
    cl = checkedCast<Test::MyClassPrx>(base);
    test(cl);
    derived = checkedCast<Test::MyDerivedClassPrx>(cl);
    test(derived);
    test(cl == base);
    test(derived == base);
    test(cl == derived);

    loc = checkedCast<Ice::LocatorPrx>(base);
    test(loc == 0);

    cl2 = checkedCast<Test::MyClassPrx>(derived);
    obj = checkedCast<Ice::ObjectPrx>(derived);
    test(cl2);
    test(obj);
    test(cl2 == obj);
    test(cl2 == derived);

    cout << "ok" << endl;

    cout << "testing checked cast with context... " << flush;
    Ice::Context c = cl->getContext();
    test(c.size() == 0);

    c["one"] = "hello";
    c["two"] = "world";
    cl = Test::MyClassPrx::checkedCast(base, c);
    Ice::Context c2 = cl->getContext();
    test(c == c2);

    //
    // Now with alternate API
    //
    cl = checkedCast<Test::MyClassPrx>(base);
    c = cl->getContext();
    test(c.size() == 0);

    cl = checkedCast<Test::MyClassPrx>(base, c);
    c2 = cl->getContext();
    test(c == c2);

    cout << "ok" << endl;

    cout << "testing encoding versioning... " << flush;
    string ref20 = "test -e 2.0:default -p 12010";
    Test::MyClassPrx cl20 = Test::MyClassPrx::uncheckedCast(communicator->stringToProxy(ref20));
    try
    {
        cl20->ice_ping();
        test(false);
    }
    catch(const Ice::UnsupportedEncodingException&)
    {
        // Server 2.0 endpoint doesn't support 1.1 version.
    }

    string ref10 = "test -e 1.0:default -p 12010";
    Test::MyClassPrx cl10 = Test::MyClassPrx::uncheckedCast(communicator->stringToProxy(ref10));
    cl10->ice_ping();
    cl10->ice_encodingVersion(Ice::Encoding_1_0)->ice_ping();
    cl->ice_encodingVersion(Ice::Encoding_1_0)->ice_ping();

    // 1.3 isn't supported but since a 1.3 proxy supports 1.1, the
    // call will use the 1.1 encoding
    string ref13 = "test -e 1.3:default -p 12010";
    Test::MyClassPrx cl13 = Test::MyClassPrx::uncheckedCast(communicator->stringToProxy(ref13));
    cl13->ice_ping();
    cl13->end_ice_ping(cl13->begin_ice_ping());

    try
    {
        // Send request with bogus 1.2 encoding.
        Ice::EncodingVersion version = { 1, 2 };
        Ice::OutputStreamPtr out = Ice::createOutputStream(communicator);
        out->startEncapsulation();
        out->endEncapsulation();
        vector<Ice::Byte> inEncaps;
        out->finished(inEncaps);
        inEncaps[4] = version.major;
        inEncaps[5] = version.minor;
        vector<Ice::Byte> outEncaps;
        cl->ice_invoke("ice_ping", Ice::Normal, inEncaps, outEncaps);
        test(false);
    }
    catch(const Ice::UnknownLocalException& ex)
    {
        // The server thrown an UnsupportedEncodingException
        test(ex.unknown.find("UnsupportedEncodingException") != string::npos);
    }

    try
    {
        // Send request with bogus 2.0 encoding.
        Ice::EncodingVersion version = { 2, 0 };
        Ice::OutputStreamPtr out = Ice::createOutputStream(communicator);
        out->startEncapsulation();
        out->endEncapsulation();
        vector<Ice::Byte> inEncaps;
        out->finished(inEncaps);
        inEncaps[4] = version.major;
        inEncaps[5] = version.minor;
        vector<Ice::Byte> outEncaps;
        cl->ice_invoke("ice_ping", Ice::Normal, inEncaps, outEncaps);
        test(false);
    }
    catch(const Ice::UnknownLocalException& ex)
    {
        // The server thrown an UnsupportedEncodingException
        test(ex.unknown.find("UnsupportedEncodingException") != string::npos);
    }

    cout << "ok" << endl;

    cout << "testing protocol versioning... " << flush;

    ref20 = "test -p 2.0:default -p 12010";
    cl20 = Test::MyClassPrx::uncheckedCast(communicator->stringToProxy(ref20));
    try
    {
        cl20->ice_ping();
        test(false);
    }
    catch(const Ice::UnsupportedProtocolException&)
    {
        // Server 2.0 proxy doesn't support 1.0 version.
    }

    ref10 = "test -p 1.0:default -p 12010";
    cl10 = Test::MyClassPrx::uncheckedCast(communicator->stringToProxy(ref10));
    cl10->ice_ping();

    // 1.3 isn't supported but since a 1.3 proxy supports 1.0, the
    // call will use the 1.0 encoding
    ref13 = "test -p 1.3:default -p 12010";
    cl13 = Test::MyClassPrx::uncheckedCast(communicator->stringToProxy(ref13));
    cl13->ice_ping();
    cl13->end_ice_ping(cl13->begin_ice_ping());

    cout << "ok" <<endl;

    cout << "testing opaque endpoints... " << flush;

    try
    {
        // Invalid -x option
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t 99 -v abc -x abc");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Missing -t and -v
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Repeated -t
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t 1 -t 1 -v abc");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Repeated -v
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t 1 -v abc -v abc");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Missing -t
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -v abc");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Missing -v
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t 1");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Missing arg for -t
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t -v abc");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Missing arg for -v
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t 1 -v");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Not a number for -t
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t x -v abc");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // < 0 for -t
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t -1 -v abc");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    try
    {
        // Invalid char for -v
        Ice::ObjectPrx p = communicator->stringToProxy("id:opaque -t 99 -v x?c");
        test(false);
    }
    catch(const Ice::EndpointParseException&)
    {
    }

    // Legal TCP endpoint expressed as opaque endpoint
    Ice::ObjectPrx p1 = communicator->stringToProxy("test -e 1.1:opaque -e 1.0 -t 1 -v CTEyNy4wLjAuMeouAAAQJwAAAA==");
    string pstr = communicator->proxyToString(p1);
    test(pstr == "test -t -e 1.1:tcp -h 127.0.0.1 -p 12010 -t 10000");

    // Opaque endpoint encoded with 1.1 encoding.
    Ice::ObjectPrx p2 = communicator->stringToProxy("test -e 1.1:opaque -e 1.1 -t 1 -v CTEyNy4wLjAuMeouAAAQJwAAAA==");
    test(communicator->proxyToString(p2) == "test -t -e 1.1:tcp -h 127.0.0.1 -p 12010 -t 10000");

    if(communicator->getProperties()->getPropertyAsInt("Ice.IPv6") == 0)
    {
        // Working?
#ifndef ICE_OS_WINRT
        const bool ssl = communicator->getProperties()->getProperty("Ice.Default.Protocol") == "ssl";
#else
        const bool ssl = true;
#endif
        const bool tcp = communicator->getProperties()->getProperty("Ice.Default.Protocol") == "tcp";
        if(tcp)
        {
            p1->ice_encodingVersion(Ice::Encoding_1_0)->ice_ping();
        }

        // Two legal TCP endpoints expressed as opaque endpoints
        p1 = communicator->stringToProxy("test -e 1.0:opaque -e 1.0 -t 1 -v CTEyNy4wLjAuMeouAAAQJwAAAA==:opaque -e 1.0 -t 1 -v CTEyNy4wLjAuMusuAAAQJwAAAA==");
        pstr = communicator->proxyToString(p1);
        test(pstr == "test -t -e 1.0:tcp -h 127.0.0.1 -p 12010 -t 10000:tcp -h 127.0.0.2 -p 12011 -t 10000");

        //
        // Test that an SSL endpoint and a nonsense endpoint get written
        // back out as an opaque endpoint.
        //
        p1 = communicator->stringToProxy(
                "test -e 1.0:opaque -e 1.0 -t 2 -v CTEyNy4wLjAuMREnAAD/////AA==:opaque -e 1.0 -t 99 -v abch");
        pstr = communicator->proxyToString(p1);
        if(ssl)
        {
            test(pstr == "test -t -e 1.0:ssl -h 127.0.0.1 -p 10001 -t infinite:opaque -t 99 -e 1.0 -v abch");
        }
        else if(tcp)
        {
            test(pstr ==
                 "test -t -e 1.0:opaque -t 2 -e 1.0 -v CTEyNy4wLjAuMREnAAD/////AA==:opaque -t 99 -e 1.0 -v abch");
        }

        //
        // Try to invoke on the endpoint to verify that we get a
        // NoEndpointException (or ConnectionRefusedException when
        // running with SSL).
        //
        if(ssl)
        {
            try
            {
                p1->ice_encodingVersion(Ice::Encoding_1_0)->ice_ping();
                test(false);
            }
            catch(const Ice::ConnectFailedException&)
            {
            }
        }

        //
        // Test that the proxy with an SSL endpoint and a nonsense
        // endpoint (which the server doesn't understand either) can be
        // sent over the wire and returned by the server without losing
        // the opaque endpoints.
        //
        Ice::ObjectPrx p2 = derived->echo(p1);
        pstr = communicator->proxyToString(p2);
        if(ssl)
        {
            test(pstr == "test -t -e 1.0:ssl -h 127.0.0.1 -p 10001 -t infinite:opaque -t 99 -e 1.0 -v abch");
        }
        else if(tcp)
        {
            test(pstr ==
                 "test -t -e 1.0:opaque -t 2 -e 1.0 -v CTEyNy4wLjAuMREnAAD/////AA==:opaque -t 99 -e 1.0 -v abch");
        }
    }

    cout << "ok" << endl;

    return cl;
}
Exemple #16
0
PlatformInfo::PlatformInfo(const string& prefix, 
                           const Ice::CommunicatorPtr& communicator, 
                           const TraceLevelsPtr& traceLevels) : 
    _traceLevels(traceLevels)
{
    //
    // Initialization of the necessary data structures to get the load average.
    //
#if defined(_WIN32)
    _terminated = false;
    _usages1.insert(_usages1.end(), 1 * 60 / 5, 0); // 1 sample every 5 seconds during 1 minutes.
    _usages5.insert(_usages5.end(), 5 * 60 / 5, 0); // 1 sample every 5 seconds during 5 minutes.
    _usages15.insert(_usages15.end(), 15 * 60 / 5, 0); // 1 sample every 5 seconds during 15 minutes.
    _last1Total = 0;
    _last5Total = 0;
    _last15Total = 0;
#elif defined(_AIX)
    struct nlist nl;
    nl.n_name = "avenrun";
    nl.n_value = 0;
    if(knlist(&nl, 1, sizeof(nl)) == 0)
    {
        _kmem = open("/dev/kmem", O_RDONLY);

        //
        // Give up root permissions to minimize security risks, it's
        // only needed to access /dev/kmem.
        //
        setuid(getuid());
        setgid(getgid());
    }
    else
    {
        _kmem = -1;
    }
#endif

    //
    // Get the number of cores/threads. E.g. a quad-core CPU with 2 threads per core will return 8.
    //
#if defined(_WIN32)
    SYSTEM_INFO sysInfo;
    GetSystemInfo(&sysInfo);
    _nProcessorThreads = sysInfo.dwNumberOfProcessors;
#elif defined(__FreeBSD__)
    static int ncpu[2] = { CTL_HW, HW_NCPU };
    size_t sz = sizeof(_nProcessorThreads);
    if(sysctl(ncpu, 2, &_nProcessorThreads, &sz, 0, 0) == -1)
    {
        Ice::SyscallException ex(__FILE__, __LINE__);
        ex.error = IceInternal::getSystemErrno();
        throw ex;
    }
#else
    _nProcessorThreads = static_cast<int>(sysconf(_SC_NPROCESSORS_ONLN));
#endif

    //
    // Get the rest of the node information.
    //
#ifdef _WIN32
    _os = "Windows";
    char hostname[MAX_COMPUTERNAME_LENGTH + 1];
    unsigned long size = sizeof(hostname);
    if(GetComputerName(hostname, &size))
    {
        _hostname = hostname;
    }
    OSVERSIONINFO osInfo;
    osInfo.dwOSVersionInfoSize = sizeof(OSVERSIONINFO);
    GetVersionEx(&osInfo);
    ostringstream os;
    os << osInfo.dwMajorVersion << "." << osInfo.dwMinorVersion;
    _release = os.str();
    _version = osInfo.szCSDVersion;

    switch(sysInfo.wProcessorArchitecture)
    {
    case PROCESSOR_ARCHITECTURE_AMD64:
        _machine = "x64";
        break;
    case PROCESSOR_ARCHITECTURE_IA64:
        _machine = "IA64";
        break;
    case PROCESSOR_ARCHITECTURE_INTEL:
        _machine = "x86";
        break;
    default:
        _machine = "unknown";
        break;
    };
#else
    struct utsname utsinfo;
    uname(&utsinfo);
    _os = utsinfo.sysname;
    _hostname = utsinfo.nodename;
    _release = utsinfo.release;
    _version = utsinfo.version;
    _machine = utsinfo.machine;
#endif

    Ice::PropertiesPtr properties = communicator->getProperties();

    //
    // Try to obtain the number of processor sockets.
    //
    _nProcessorSockets = properties->getPropertyAsIntWithDefault("IceGrid.Node.ProcessorSocketCount", 0);
    if(_nProcessorSockets == 0)
    {
#if defined(_WIN32)
        _nProcessorSockets = getSocketCount(_traceLevels->logger);
#elif defined(__linux)
        IceUtilInternal::ifstream is(string("/proc/cpuinfo"));
        set<string> ids;
        
        int nprocessor = 0;
        while(is)
        {
            string line;
            getline(is, line);
            if(line.find("processor") == 0)
            {
                nprocessor++;
            }
            else if(line.find("physical id") == 0)
            {
                nprocessor--;
                ids.insert(line);
            }
        }
        _nProcessorSockets = nprocessor + ids.size();
#else
        // Not supported
        _nProcessorSockets = 1;
#endif
    }

    string endpointsPrefix;
    if(prefix == "IceGrid.Registry")
    {
        _name = properties->getPropertyWithDefault("IceGrid.Registry.ReplicaName", "Master");
        endpointsPrefix = prefix + ".Client";
    }
    else
    {
        _name = properties->getProperty(prefix + ".Name");
        endpointsPrefix = prefix;
    }

    Ice::PropertyDict props = properties->getPropertiesForPrefix(endpointsPrefix);
    Ice::PropertyDict::const_iterator p = props.find(endpointsPrefix + ".PublishedEndpoints");
    if(p != props.end())
    {
        _endpoints = p->second;
    }
    else
    {
        _endpoints = properties->getProperty(endpointsPrefix + ".Endpoints");
    }

    string cwd;
    if(IceUtilInternal::getcwd(cwd) != 0)
    {
        throw "cannot get the current directory:\n" + IceUtilInternal::lastErrorToString();
    }
    _cwd = string(cwd);

    _dataDir = properties->getProperty(prefix + ".Data");    
    if(!IceUtilInternal::isAbsolutePath(_dataDir))
    {
        _dataDir = _cwd + '/' + _dataDir;
    }
    if(_dataDir[_dataDir.length() - 1] == '/')
    {
        _dataDir = _dataDir.substr(0, _dataDir.length() - 1);
    }
}
Exemple #17
0
void
allTests(const Ice::CommunicatorPtr& communicator)
{
    string ref = "DemoIceBox/admin:default -p 9996 -t 10000";
    Ice::ObjectPrx admin = communicator->stringToProxy(ref);

    TestFacetPrx facet;

    cout << "testing custom facet... " << flush;
    {
        //
        // Test: Verify that the custom facet is present.
        //
        facet = Test::TestFacetPrx::checkedCast(admin, "TestFacet");
        facet->ice_ping();
    }
    cout << "ok" << endl;

    cout << "testing properties facet... " << flush;
    {
        Ice::PropertiesAdminPrx pa =
            Ice::PropertiesAdminPrx::checkedCast(admin, "IceBox.Service.TestService.Properties");

        //
        // Test: PropertiesAdmin::getProperty()
        //
        test(pa->getProperty("Prop1") == "1");
        test(pa->getProperty("Bogus") == "");

        //
        // Test: PropertiesAdmin::getProperties()
        //
        Ice::PropertyDict pd = pa->getPropertiesForPrefix("");
        test(pd.size() == 5);
        test(pd["Prop1"] == "1");
        test(pd["Prop2"] == "2");
        test(pd["Prop3"] == "3");
        test(pd["Ice.Config"] == "config.service");
        test(pd["Ice.ProgramName"] == "IceBox-TestService");

        Ice::PropertyDict changes;

        //
        // Test: PropertiesAdmin::setProperties()
        //
        Ice::PropertyDict setProps;
        setProps["Prop1"] = "10"; // Changed
        setProps["Prop2"] = "20"; // Changed
        setProps["Prop3"] = ""; // Removed
        setProps["Prop4"] = "4"; // Added
        setProps["Prop5"] = "5"; // Added
        pa->setProperties(setProps);
        test(pa->getProperty("Prop1") == "10");
        test(pa->getProperty("Prop2") == "20");
        test(pa->getProperty("Prop3") == "");
        test(pa->getProperty("Prop4") == "4");
        test(pa->getProperty("Prop5") == "5");
        changes = facet->getChanges();
        test(changes.size() == 5);
        test(changes["Prop1"] == "10");
        test(changes["Prop2"] == "20");
        test(changes["Prop3"] == "");
        test(changes["Prop4"] == "4");
        test(changes["Prop5"] == "5");
        pa->setProperties(setProps);
        changes = facet->getChanges();
        test(changes.empty());
    }
    cout << "ok" << endl;

    cout << "testing metrics admin facet... " << flush;
    {
        IceMX::MetricsAdminPrx ma = IceMX::MetricsAdminPrx::checkedCast(admin, "IceBox.Service.TestService.Metrics");

        Ice::PropertiesAdminPrx pa =
            Ice::PropertiesAdminPrx::checkedCast(admin, "IceBox.Service.TestService.Properties");

        Ice::StringSeq views;
        Ice::StringSeq disabledViews;
        views = ma->getMetricsViewNames(disabledViews);
        test(views.empty());

        Ice::PropertyDict setProps;
        setProps["IceMX.Metrics.Debug.GroupBy"] = "id";
        setProps["IceMX.Metrics.All.GroupBy"] = "none";
        setProps["IceMX.Metrics.Parent.GroupBy"] = "parent";
        pa->setProperties(setProps);
        pa->setProperties(Ice::PropertyDict());

        views = ma->getMetricsViewNames(disabledViews);
        test(views.size() == 3);
        
        // Make sure that the IceBox communicator metrics admin is a separate instance.
        test(IceMX::MetricsAdminPrx::checkedCast(admin, "Metrics")->getMetricsViewNames(disabledViews).empty());
    }
    cout << "ok" << endl;
}
Exemple #18
0
int
PropsClient::run(int argc, char* argv[])
{
    if(argc > 1)
    {
        cerr << appName() << ": too many arguments" << endl;
        return EXIT_FAILURE;
    }

    PropsPrx props = PropsPrx::checkedCast(communicator()->propertyToProxy("Props.Proxy"));
    if(!props)
    {
        cerr << argv[0] << ": invalid proxy" << endl;
        return EXIT_FAILURE;
    }

    Ice::PropertiesAdminPrx admin =
        Ice::PropertiesAdminPrx::checkedCast(communicator()->propertyToProxy("Admin.Proxy"));

    Ice::PropertyDict batch1;
    batch1["Demo.Prop1"] = "1";
    batch1["Demo.Prop2"] = "2";
    batch1["Demo.Prop3"] = "3";

    Ice::PropertyDict batch2;
    batch2["Demo.Prop1"] = "10";
    batch2["Demo.Prop2"] = ""; // An empty value removes this property
    batch2["Demo.Prop3"] = "30";

    show(admin);
    menu();

    char c = 'x';
    do
    {
        try
        {
            cout << "==> ";
            cin >> c;
            if(c == '1' || c == '2')
            {
                Ice::PropertyDict dict = c == '1' ? batch1 : batch2;
                cout << "Sending:" << endl;
                for(Ice::PropertyDict::iterator p = dict.begin(); p != dict.end(); ++p)
                {
                    if(p->first.find("Demo") == 0)
                    {
                        cout << "  " << p->first << "=" << p->second << endl;
                    }
                }
                cout << endl;

                admin->setProperties(dict);

                cout << "Changes:" << endl;
                Ice::PropertyDict changes = props->getChanges();
                if(changes.empty())
                {
                    cout << "  None." << endl;
                }
                else
                {
                    for(Ice::PropertyDict::iterator p = changes.begin(); p != changes.end(); ++p)
                    {
                        cout << "  " << p->first;
                        if(p->second.empty())
                        {
                            cout << " was removed" << endl;
                        }
                        else
                        {
                            cout << " is now " << p->second << endl;
                        }
                    }
                }
            }
            else if(c == 'c')
            {
                show(admin);
            }
            else if(c == 's')
            {
                props->shutdown();
            }
            else if(c == 'x')
            {
                // Nothing to do
            }
            else if(c == '?')
            {
                menu();
            }
            else
            {
                cout << "unknown command `" << c << "'" << endl;
                menu();
            }
        }
        catch(const Ice::Exception& ex)
        {
            cerr << ex << endl;
        }
    }
    while(cin.good() && c != 'x');

    return EXIT_SUCCESS;
}