void Update() override final {
		if (lastActivated >= 0) {
			InputPort<AnyType>* port = static_cast<InputPort<AnyType>*>(GetInput(lastActivated));
			GetOutput<0>().Set(*port->Get());
			lastActivated = -1;
		}
	}
 void updateHook() {
     dummyInPort.read(dataVar);
     dummyOutPort.write(dataVar);
     dataInPort.read(dataVar);
     dataOutPort.write(dataVar);
     //log(Info) << "Worker relaying data!" << endlog();
 }
Exemple #3
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void Connection::mouseReleaseEvent(QGraphicsSceneMouseEvent *event)
{
    QGraphicsObject::mouseReleaseEvent(event);
    if (drag_state == CONNECTED)
        return;

    ungrabMouse();
    clearFocus();
    setFlag(QGraphicsItem::ItemIsFocusable, false);

    InputPort* target = gscene()->getInputPortAt(endPos());
    Datum* datum = target ? target->getDatum() : NULL;
    if (target && datum->acceptsLink(link))
    {
        datum->addLink(link);
        drag_state = CONNECTED;

        connect(endInspector(), &NodeInspector::moved,
                this, &Connection::onInspectorMoved);
        connect(endInspector(), &NodeInspector::hiddenChanged,
                this, &Connection::onHiddenChanged);

        App::instance()->pushStack(new UndoAddLinkCommand(link));
    }
    else
    {
        link->deleteLater();
    }

    prepareGeometryChange();
}
void Connection::mouseReleaseEvent(QGraphicsSceneMouseEvent *event)
{
    QGraphicsObject::mouseReleaseEvent(event);
    if (drag_state == CONNECTED)
        return;

    ungrabMouse();
    clearFocus();
    setFlag(QGraphicsItem::ItemIsFocusable, false);

    InputPort* t = gscene()->getInputPortAt(endPos());
    Datum* datum = target ? target->getDatum() : NULL;
    if (t && datum->acceptsLink(source->getDatum()))
    {
        target = t;
        t->install(this);

        datum->installLink(source->getDatum());
        drag_state = CONNECTED;
        App::instance()->pushStack(
                new UndoAddLinkCommand(source->getDatum(), datum));
        onPortsMoved();

        emit(changed());
    }
    else
    {
        deleteLater();
    }

    prepareGeometryChange();
}
void
ConnectionInterface::PushConsumer ( InputPort& consumer )
{
        if ( _consumers.find ( consumer.GetID() ) == _consumers.end() ) {
                consumer.Plug ( *this );
                _consumers[ consumer.GetID() ] = &consumer;
        } else {
                //TODO _THROW_ exception
        }
}
void CorbaMQueueIPCTest::testPortBufferConnection()
{
    // This test assumes that there is a buffer connection mw1 => server => mr1 of size 3
    // Check if connection succeeded both ways:
    BOOST_CHECK( mw1->connected() );
    BOOST_CHECK( mr1->connected() );

    double value = 0;

    // Check if no-data works
    BOOST_CHECK( !mr1->read(value) );

    // Check if writing works
    ASSERT_PORT_SIGNALLING(mw1->write(1.0), mr1);
    ASSERT_PORT_SIGNALLING(mw1->write(2.0), mr1);
    ASSERT_PORT_SIGNALLING(mw1->write(3.0), mr1);
    // There are two connections between mw1 and mr1. We first flush one of the
    // two, and then the second one (normal multi-writer single-reader
    // behaviour)
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 1.0, value );
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 2.0, value );
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 3.0, value );
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 1.0, value );
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 2.0, value );
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 3.0, value );
    BOOST_CHECK_EQUAL( mr1->read(value), OldData );
}
void
ConnectionInterface::DisconnectConsumer ( InputPort& inputPort )
{
        ConsumersMap::iterator it = _consumers.find ( inputPort.GetID() );
        if ( it != _consumers.end() ) {
                inputPort.UnPlug ( true );
                _consumers.erase ( it );
        } else {
                //TODO _THROW_ exception
        }
}
InputPort* NodeInspector::inputPort(const Datum* d) const
{
    for (auto row : rows)
        for (auto a : row->childItems())
        {
            InputPort* p = dynamic_cast<InputPort*>(a);
            if (p && p->getDatum() == d)
                return p;
        }
    return NULL;
}
        virtual void disconnect(bool forward)
        {
            InputPort<T>* port = this->port;
            this->port = 0;

            if (forward)
            {
                if (port)
                    port->removeConnection(cid);
            }
            else
                base::ChannelElement<T>::disconnect(false);
        }
Exemple #10
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wxString
MethodSameAs::GetType(const OutputPort *output) const
{
	Node *node = static_cast<Node *>(output->GetParent());
	for (List<InputPort *>::Iterator i = node->InputIterator(); !i; i++)
	{
		InputPort *input = *i;
		if (input->GetLuaId() == m_id)
		{
			return input->GetType();
		}
	}
	return wxT("?");
}
Exemple #11
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		void updateHook() {
            double input_sample;
            if ( input.read(input_sample) ) {
                current += this->engine()->getActivity()->getPeriod()*input_sample /inertia.value();
            }
            output.write( current );
		}
Exemple #12
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void updateHook()
{
    if(NewData==posInc_in.read(posIncData) && NewData==deltaInc_in.read(deltaIncData))
    {
        /*for(int i=0; i<number_of_drives; i++)
        {
            std::cout << "POS INC" << posIncData[i] << std::endl;
        }*/
        computedPwm_out.write(computePwmValue(posIncData,deltaIncData));
    }
    /*else
        std::cout << "NO DATA" << std::endl;
    */


}
 static bool createStream(InputPort<T>& input_port, ConnPolicy const& policy)
 {
     StreamConnID *sid = new StreamConnID(policy.name_id);
     RTT::base::ChannelElementBase::shared_ptr outhalf = buildChannelOutput( input_port, sid );
     if ( createAndCheckStream(input_port, policy, outhalf, sid) )
         return true;
     input_port.removeConnection(sid);
     return false;
 }
Exemple #14
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void CorbaTest::testPortDataConnection()
{
    // This test assumes that there is a data connection mo1 => mi2
    // Check if connection succeeded both ways:
    BOOST_CHECK( mo1->connected() );
    BOOST_CHECK( mi2->connected() );

    double value = 0;

    // Check if no-data works
    BOOST_CHECK_EQUAL( mi2->read(value), NoData );

    // Check if writing works (including signalling)
    ASSERT_PORT_SIGNALLING(mo1->write(1.0), mi2)
    BOOST_CHECK( mi2->read(value) );
    BOOST_CHECK_EQUAL( 1.0, value );
    ASSERT_PORT_SIGNALLING(mo1->write(2.0), mi2);
    BOOST_CHECK( mi2->read(value) );
    BOOST_CHECK_EQUAL( 2.0, value );
}
void CorbaMQueueIPCTest::testPortDataConnection()
{
    // This test assumes that there is a data connection mw1 => server => mr1
    // Check if connection succeeded both ways:
    BOOST_CHECK( mw1->connected() );
    BOOST_CHECK( mr1->connected() );

    double value = 0;

    // Check if no-data works
    BOOST_CHECK( !mr1->read(value) );

    // Check if writing works (including signalling)
    ASSERT_PORT_SIGNALLING(mw1->write(1.0), mr1)
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 1.0, value );
    ASSERT_PORT_SIGNALLING(mw1->write(2.0), mr1);
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 2.0, value );
}
Exemple #16
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int
InputPort::LuaGetSource(lua_State *L)
{
    ShaderObject *obj = *(ShaderObject **)lua_touserdata(L, lua_upvalueindex(1));
    InputPort *input = dynamic_cast<InputPort *>(obj);
    OutputPort *source = input->GetSource();
    if (source != NULL)
    {
        source->PushLua(L);
    }
    else
    {
        lua_newtable(L);
        lua_pushcfunction(L, ::LuaUID);
        lua_setfield(L, -2, "uid");
        lua_pushcfunction(L, ::LuaGetType);
        lua_setfield(L, -2, "get_type");
    }
    return 1;
}
void CorbaTest::testPortBufferConnection()
{
    // This test assumes that there is a buffer connection mo => mi of size 3
    // Check if connection succeeded both ways:
    BOOST_CHECK( mo->connected() );
    BOOST_CHECK( mi->connected() );

    double value = 0;

    // Check if no-data works
    BOOST_CHECK_EQUAL( mi->read(value), NoData );

    // Check if writing works
    ASSERT_PORT_SIGNALLING(mo->write(1.0), mi);
    ASSERT_PORT_SIGNALLING(mo->write(2.0), mi);
    ASSERT_PORT_SIGNALLING(mo->write(3.0), mi);
    ASSERT_PORT_SIGNALLING(mo->write(4.0), 0);
    BOOST_CHECK( mi->read(value) );
    BOOST_CHECK_EQUAL( 1.0, value );
    BOOST_CHECK( mi->read(value) );
    BOOST_CHECK_EQUAL( 2.0, value );
    BOOST_CHECK( mi->read(value) );
    BOOST_CHECK_EQUAL( 3.0, value );
    BOOST_CHECK_EQUAL( mi->read(value), OldData );
}
void CorbaMQueueIPCTest::testPortBufferConnection()
{
    // This test assumes that there is a buffer connection mw1 => server => mr1 of size 3
    // Check if connection succeeded both ways:
    BOOST_CHECK( mw1->connected() );
    BOOST_CHECK( mr1->connected() );

    double value = 0;

    // Check if no-data works
    BOOST_CHECK( !mr1->read(value) );

    // Check if writing works
    ASSERT_PORT_SIGNALLING(mw1->write(1.0), mr1);
    ASSERT_PORT_SIGNALLING(mw1->write(2.0), mr1);
    ASSERT_PORT_SIGNALLING(mw1->write(3.0), mr1);
    // it will be emptied too fast by mqueue.
    //ASSERT_PORT_SIGNALLING(mw1->write(4.0), 0);
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 1.0, value );
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 2.0, value );
    BOOST_CHECK( mr1->read(value) );
    BOOST_CHECK_EQUAL( 3.0, value );
    BOOST_CHECK_EQUAL( mr1->read(value), OldData );
}
Exemple #19
0
InputPort* Canvas::getInputPortNear(QPointF pos, Link* link) const
{
    float distance = INFINITY;
    InputPort* port = NULL;

    for (auto i : scene->items())
    {
        InputPort* p = dynamic_cast<InputPort*>(i);
        if (p && (link == NULL || p->getDatum()->acceptsLink(link)))
        {
            QPointF delta = p->mapToScene(p->boundingRect().center()) - pos;
            float d = QPointF::dotProduct(delta, delta);
            if (d < distance)
            {
                distance = d;
                port = p;
            }
        }
    }

    return port;
}
	void Update() override final {
		if (lastActivated >= 0 && activationMap == 0b11'1111) {
			InputPort<AnyType>* port = static_cast<InputPort<AnyType>*>(GetInput(lastActivated+1));
			GetOutput<0>().Set(*port->Get());
		}
	}
Exemple #21
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 InputPortSource(InputPort<T>& port)
     : port(&port), mvalue() { 
     port.getDataSample( mvalue );
 }
Exemple #22
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 bool evaluate() const
 {
     return port->read(mvalue, false) == NewData;
 }
Exemple #23
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 void reset() { port->clear(); }
void MaterialShaderGraph::AssembleShaderCode() {
	std::vector<ShaderNode> shaderNodes(m_nodes.size());
	std::vector<std::vector<MaterialShaderParameter>> shaderNodeParams(m_nodes.size());
	std::vector<eMaterialShaderParamType> shaderNodeReturns(m_nodes.size());
	std::vector<std::string> functions(m_nodes.size());

	// collect individual shader codes and set number of input params for each node
	for (size_t i = 0; i < m_nodes.size(); ++i) {
		MaterialShader* shader = m_nodes[i].get();
		functions[i] = shader->GetShaderCode();
		ExtractShaderParameters(functions[i], "main", shaderNodeReturns[i], shaderNodeParams[i]);

		for (auto p : shaderNodeParams[i]) {
			if (p.type == eMaterialShaderParamType::UNKNOWN) {
				throw InvalidArgumentException("Parameter of unknown type.");
			}
		}

		shaderNodes[i].SetNumInputs(shaderNodeParams[i].size());
	}

	// link nodes together
	for (const auto& link : m_links) {
		ShaderNode& source = shaderNodes[link.sourceNode];
		ShaderNode& sink = shaderNodes[link.sinkNode];
		if (sink.GetNumInputs() <= link.sinkPort) {
			throw InvalidArgumentException("Invalid link: port does not have that many inputs.");
		}
		bool isLinked = source.GetOutput(0)->Link(sink.GetInput(link.sinkPort));
		if (!isLinked) {
			throw InvalidArgumentException("Invalid link: duplicate input to a single port.");
		}
	}

	// create output port LUT
	std::unordered_map<OutputPortBase*, size_t> outputLut;
	for (size_t i = 0; i < shaderNodes.size(); ++i) {
		outputLut.insert({ shaderNodes[i].GetOutput(0), i });
	}

	// get the sink node
	size_t sinkNodeIdx = -1;
	for (size_t i = 0; i < shaderNodes.size(); ++i) {
		if (shaderNodes[i].GetOutput(0)->begin() == shaderNodes[i].GetOutput(0)->end()) {
			if (sinkNodeIdx != -1) {
				throw InvalidArgumentException("Invalid graph: multiple sink nodes.");
			}
			sinkNodeIdx = i;
		}
	}
	if (sinkNodeIdx == -1) {
		throw InvalidArgumentException("Invalid graph: no sink nodes, contains circle.");
	}

	// run backwards DFS from sink node
	// - get topological order
	// - get list of free params
	struct FreeParam {
		size_t node, input;
		std::string name;
	};
	std::vector<size_t> topologicalOrder;
	std::vector<bool> visited(shaderNodes.size(), false);
	std::vector<FreeParam> freeParams;
	auto VisitNode = [&](size_t node, auto& self) {
		if (visited[node]) {
			return;
		}
		visited[node] = true;

		for (int i = 0; i < shaderNodes[node].GetNumInputs(); ++i) {
			auto* input = shaderNodes[node].GetInput(i);
			if (input->GetLink() != nullptr) {
				auto* linkOutput = input->GetLink();
				size_t linkNode = outputLut[linkOutput];
				self(linkNode, self);
			}
			else {
				std::stringstream ss;
				ss << m_nodes[node]->GetName() << "__" << shaderNodeParams[node][i].name;
				static_cast<InputPort<std::string>*>(input)->Set(ss.str());
				freeParams.push_back({ node, (size_t)i, ss.str() });
			}
		}

		std::stringstream ss;
		ss << "main_" << topologicalOrder.size();
		shaderNodes[node].SetFunctionName(ss.str());
		functions[node] = std::regex_replace(functions[node], std::regex("main"), ss.str());
		topologicalOrder.push_back(node);
		shaderNodes[node].SetFunctionReturn(GetParameterString(shaderNodeReturns[node]));
	};

	// attach final input port to sink node, and update according to topological order
	InputPort<std::string> finalCodePort;
	shaderNodes[sinkNodeIdx].GetOutput(0)->Link(&finalCodePort);
	VisitNode(sinkNodeIdx, VisitNode);
	for (auto idx : topologicalOrder) {
		shaderNodes[idx].Update();
	}

	// assemble resulting code
	std::stringstream finalCode;
	// sub-functions
	for (auto node : topologicalOrder) {
		finalCode << functions[node] << "\n";
	}
	finalCode << "\n\n";
	// signature
	std::string returnType = GetParameterString(shaderNodeReturns[*--topologicalOrder.end()]);
	finalCode << returnType << " main(";
	bool firstParam = true;
	for (auto& p : freeParams) {
		if (!firstParam)
			finalCode << ", ";
		finalCode << GetParameterString(shaderNodeParams[p.node][p.input].type) << " ";
		finalCode << p.name;
		firstParam = false;
	}
	finalCode << ") {\n";
	finalCode << "\n";
	// preambles
	for (auto idx : topologicalOrder) {
		finalCode << "    " << shaderNodes[idx].GetPreamble() << "\n";
	}
	finalCode << "\n";
	// return statement
	finalCode << "return " << finalCodePort.Get() << ";\n";
	finalCode << "}\n";


	m_source = finalCode.str();
}
  void getNextPose(brics_actuator::CartesianPose* curr_next)
  {

    //    cout<<"curr: "<<curr_next->orientation.x<<","<<curr_next->orientation.y<<","<<curr_next->orientation.z<<","<<curr_next->orientation.w<<","<<endl;
    //    relative_position_port->read(relative_position);
    measured_position_port->read(measured_position);

    //    curr_next->position.x += 0.001;
    dummy_x=(measured_position.position.x  - goal[0])*Kp+Ki*int_x;
    dummy_y=(measured_position.position.y  - goal[1])*Kp+Ki*int_y;
    dummy_z=(measured_position.position.z  - goal[2])*Kp+Ki*int_z;
    dummy_ox = (-curr_next->orientation.x + goal[3])*Kp+Ki*int_ox;
    dummy_oy = (-curr_next->orientation.y + goal[4])*Kp+Ki*int_oy;
    dummy_oz = (-curr_next->orientation.z + goal[5])*Kp+Ki*int_oz;
    dummy_ow = (-curr_next->orientation.w + goal[6])*Kp+Ki*int_ow;

    if (abs(dummy_x) > STEP_POS) {
      dummy_x=SIGN(dummy_x)*STEP_POS;
    }
    if (abs(dummy_y )> STEP_POS) {
      dummy_y=SIGN(dummy_y)*STEP_POS;
    }
    if (abs(dummy_z )> STEP_POS) {
      dummy_z=SIGN(dummy_z)*STEP_POS;
    }
    if (abs(dummy_ox )> STEP_OR) {
      dummy_ox=SIGN(dummy_ox)*STEP_OR;
    }
    if (abs(dummy_oy )> STEP_OR) {
      dummy_oy=SIGN(dummy_oy)*STEP_OR;
    }
    if (abs(dummy_oz )> STEP_OR) {
      dummy_oz=SIGN(dummy_oz)*STEP_OR;
    }
    if (abs(dummy_ow )> STEP_OR) {
      dummy_ow=SIGN(dummy_ow)*STEP_OR;
    }

//    log(Error)<<sqrt(  )<<endlog();
//    cout<<sqrt( (measured_position.position.x-goal[0]) *(measured_position.position.x-goal[0])   + (measured_position.position.y-goal[1]) *(measured_position.position.y -goal[1]) + (measured_position.position.z-goal[2]) *(measured_position.position.z-goal[2]) )<<endl;

    if(sqrt((measured_position.position.x-goal[0]) *(measured_position.position.x-goal[0])   + (measured_position.position.y-goal[1]) *(measured_position.position.y -goal[1]) + (measured_position.position.z-goal[2]) *(measured_position.position.z-goal[2])) < 0.3)
    {

//      ((Property<tFriKrlData>)getOwner()->getPeer("KULRobot")->properties()->getProperty("toKRL")).value().intData[1]=3;

//      ((Property<tFriKrlData>)getPeer("KULRobot")->getProperty("toKRL")).value().intData[1]=3;
      if(this->getOwner()->hasPeer("KULRobot")){
            this->getOwner()->getPeer("KULRobot")->properties()->getPropertyType<tFriKrlData>("toKRL")->value().intData[1]=3;
      }
      log(Warning)<<"Grasp position reached."<<endlog();
    }

    if(sqrt(dummy_x*dummy_x + dummy_y*dummy_y + dummy_z*dummy_z) < 0.01)
    {

//      ((Property<tFriKrlData>)getOwner()->getPeer("KULRobot")->properties()->getProperty("toKRL")).value().intData[1]=3;

//      ((Property<tFriKrlData>)getPeer("KULRobot")->getProperty("toKRL")).value().intData[1]=3;
      if(this->getOwner()->hasPeer("KULRobot")){
            this->getOwner()->getPeer("KULRobot")->properties()->getPropertyType<tFriKrlData>("toKRL")->value().intData[1]=3;
      }
      log(Warning)<<"Grasp position reached."<<endlog();
    }




    //        cout<<dummy_x<<","<<dummy_y<<","<<dummy_z<<","<<dummy_ox<<","<<dummy_oy<<","<<dummy_oz<<endl;


    curr_next->position.x +=dummy_x; //+Kd*(measured_position.position.x - 0.02427-prev_error_x)/0.005;

    curr_next->position.y +=dummy_y; //+Kd*(measured_position.position.y - 0.02427-prev_error_y)/0.005;
    curr_next->position.z += dummy_z;//+Kd*(measured_position.position.z - 0.02427-prev_error_z)/0.005;

    curr_next->orientation.x += dummy_ox;
    curr_next->orientation.y += dummy_oy;
    curr_next->orientation.z += dummy_oz;
    curr_next->orientation.w += dummy_ow;





    int_x=int_x+dummy_x*0.005;
    int_y=int_y+dummy_y*0.005;
    int_z=int_z+dummy_z*0.005;

    int_ox=int_ox+dummy_ox*0.005;
    int_oy=int_oy+dummy_oy*0.005;
    int_oz=int_oz+dummy_oz*0.005;
    int_ow=int_ow+dummy_ow*0.005;
    prev_error_x=dummy_x;
    prev_error_y=dummy_y;
    prev_error_z=dummy_z;


    //    (*curr_next) = measured_position;

    //    PID_return=calcDesiredIncremenPID(relative_position.position.x,x,dt);
    //    next->position.x=measured_position.position.x+PID_return.desInc;
    //    x.integral=PID_return.integral;
    //    x.prev_error=relative_position.position.x;
    //
    //    PID_return=calcDesiredIncremenPID(relative_position.position.y,y,dt);
    //    next->position.y=measured_position.position.y+PID_return.desInc;
    //    y.integral=PID_return.integral;
    //    y.prev_error=relative_position.position.y;
    //
    //    PID_return=calcDesiredIncremenPID(relative_position.position.z,z,dt);
    //    next->position.z=measured_position.position.z+PID_return.desInc;
    //    z.integral=PID_return.integral;
    //    z.prev_error=relative_position.position.z;
    //
    //    PID_return=calcDesiredIncremenPID(relative_position.orientation.wx,wx,dt);
    //    next->orientation.wx=measured_position.orientation.wx+PID_return.desInc;
    //    wx.integral=PID_return.integral;
    //    wx.prev_error=relative_position.orientation.wx;
    //
    //    PID_return=calcDesiredIncremenPID(relative_position.orientation.wy,wy,dt);
    //    next->orientation.wy=measured_position.orientation.wy+PID_return.desInc;
    //    wy.integral=PID_return.integral;
    //    wy.prev_error=relative_position.orientation.wy;
    //
    //    PID_return=calcDesiredIncremenPID(relative_position.orientation.wz,wz,dt);
    //    next->orientation.wz=measured_position.orientation.wz+PID_return.desInc;
    //    wz.integral=PID_return.integral;
    //    wz.prev_error=relative_position.orientation.wz;
    //
    //    PID_return=calcDesiredIncremenPID(relative_position.orientation.ww,ww,dt);
    //    next->orientation.ww=measured_position.orientation.ww+PID_return.desInc;
    //    ww.integral=PID_return.integral;
    //    ww.prev_error=relative_position.orientation.ww;

  }
 /**
  * Creates the connection end that represents the output and attach
  * it to the input.
  * @param port The start point.
  * @param output_id Each connection must be identified by an ID that
  * represents the other end. This id is passed to the input port \a port.
  * @return
  */
 ConnOutputEndpoint(InputPort<T>* port, ConnID* output_id )
     : port(port), cid(output_id->clone())
 {
     port->addConnection(output_id, this );
 }
Exemple #27
0
void CorbaTest::testPortDisconnected()
{
    BOOST_CHECK( !mo1->connected() );
    BOOST_CHECK( !mi2->connected() );
}
void CorbaMQueueIPCTest::testPortDisconnected()
{
    BOOST_CHECK( !mw1->connected() );
    BOOST_CHECK( !mr1->connected() );
}