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* @author ETSI / STF405
* @version $URL$
* $Id$
* @desc Module containing functions for GeoNetworking
// Libcommon
import from LibCommon_BasicTypesAndValues all;
import from LibCommon_VerdictControl {type FncRetCode;}
import from LibCommon_Sync {altstep all};
// LibIts
import from LibIts_TestSystem all;
import from LibIts_Interface all;
* @desc Create Facility component and connects GeoNetworking port
* @remark Only used when ItsFa is a PTC
* @param p_ptcDenm returned Facility component variable
function f_ptcGeoNetworkingUp(out ItsNt p_ptcGeoNetworking) {
p_ptcGeoNetworking := ItsNt.create("GeoNetworking Tester");
// map ports
map(p_ptcGeoNetworking:geoNetworkingPort, system:geoNetworkingPort);
* @desc Wait for component to finish and unmap GeoNetworking ports
* @remark Only used when ItsFa is a PTC
* @param p_camPtc Facility component variable
function f_ptcGeoNetworkingDown(in ItsNt p_ptcGeoNetworking) runs on ItsMtc {
log("*** f_ptcGeoNetworkingDown: ERROR: Timeout while waiting for component ***");
setverdict(inconc);
}
}
unmap(p_ptcGeoNetworking:geoNetworkingPort);
group geoConfigurationFunctions {
/**
* @desc This configuration features:
* - one ITS node (IUT)
* - two ITS nodes (nodeA, nodeB)
* - Area1 which only includes NodeB and IUT
* - Area2 which only includes NodeB
* NodeB being close to the area center
*/
function f_cf01Up() runs on ItsNt {
// Variables
var PositionTable v_positionTable := {};
var GeoAreaTable v_areaTable := {};
var LongPosVector v_iutLongPosVector := f_getIutLongPosVector();
var LongPosVector v_nodeALongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeA_longitudeFactor, c_compNodeA_latitudeFactor);
var LongPosVector v_nodeBLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeB_longitudeFactor, c_compNodeB_latitudeFactor);
var LongPosVector v_nodeDLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeD_longitudeFactor, c_compNodeD_latitudeFactor);
// Map
map(self:geoNetworkingPort, system:geoNetworkingPort);
// Position table
f_addPosition(v_positionTable, c_compIut, v_iutLongPosVector);
f_addPosition(v_positionTable, c_compNodeA, v_nodeALongPosVector);
f_addPosition(v_positionTable, c_compNodeB, v_nodeBLongPosVector);
// Area table
f_addArea(v_areaTable, c_area1,
f_computeSquareArea(v_nodeDLongPosVector, float2int(1.1 * f_distance(v_nodeBLongPosVector, v_nodeDLongPosVector))));
f_addArea(v_areaTable, c_area2,
f_computeSquareArea(v_nodeBLongPosVector, float2int(1.1 * f_distance(v_nodeBLongPosVector, v_nodeDLongPosVector))));
f_initialiseComponent(v_positionTable, v_areaTable, c_compNodeB);
*/
function f_cf01Down() runs on ItsNt {
// Map
unmap(self:geoNetworkingPort, system:geoNetworkingPort);
} // end f_cf01Down
/**
* @desc This configuration features:
* - one ITS node (IUT)
* - one ITS node (NodeB)
* - one ITS node (NodeD)
* - Area1 which only includes NodeB, NodeD and IUT
* - Area2 which only includes NodeB and NodeD
* NodeB being close to the area center
function f_cf02Up(out ItsNt p_nodeB, out ItsNt p_nodeD) runs on ItsMtc {
// Variables
var PositionTable v_positionTable := {};
var GeoAreaTable v_areaTable := {};
var LongPosVector v_iutLongPosVector := f_getIutLongPosVector();
var LongPosVector v_nodeBLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeB_longitudeFactor, c_compNodeB_latitudeFactor);
var LongPosVector v_nodeCLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeC_longitudeFactor, c_compNodeC_latitudeFactor);
var LongPosVector v_nodeDLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeD_longitudeFactor, c_compNodeD_latitudeFactor);
// Create
p_nodeB := ItsNt.create(c_compNodeB) alive;
// Map
map(p_nodeB:geoNetworkingPort, system:geoNetworkingPort);
map(p_nodeD:geoNetworkingPort, system:geoNetworkingPort);
// Connect
connect(p_nodeB:syncPort, self:syncPort);
f_addPosition(v_positionTable, c_compIut, v_iutLongPosVector);
f_addPosition(v_positionTable, c_compNodeB, v_nodeBLongPosVector);
f_addPosition(v_positionTable, c_compNodeD, v_nodeDLongPosVector);
// Area table
f_addArea(v_areaTable, c_area1,
f_computeSquareArea(v_nodeDLongPosVector, float2int(1.1 * f_distance(v_nodeBLongPosVector, v_nodeDLongPosVector))));
f_addArea(v_areaTable, c_area2,
f_computeSquareArea(v_nodeBLongPosVector, float2int(1.1 * f_distance(v_nodeBLongPosVector, v_nodeDLongPosVector))));
p_nodeB.start(f_initialiseComponent(v_positionTable, v_areaTable, c_compNodeB));
p_nodeD.start(f_initialiseComponent(v_positionTable, v_areaTable, c_compNodeD));
function f_cf02Down(in ItsNt p_nodeB, in ItsNt p_nodeD) runs on ItsMtc {
// Map
unmap(p_nodeB:geoNetworkingPort, system:geoNetworkingPort);
unmap(p_nodeD:geoNetworkingPort, system:geoNetworkingPort);
// Connect
disconnect(p_nodeB:syncPort, self:syncPort);
} // end f_cf02Down
/**
* @desc This configuration features:
* - one ITS node (IUT)
* - one ITS node (NodeA)
* - one ITS node in direction of NodeA (NodeB)
* - one ITS node not in direction of NodeA (NodeC)
* - Area1 which only includes NodeB and IUT
* - Area2 which only includes NodeB
* NodeB being close to the area center
function f_cf03Up(out ItsNt p_nodeB, out ItsNt p_nodeC) runs on ItsMtc {
// Variables
var PositionTable v_positionTable := {};
var GeoAreaTable v_areaTable := {};
var LongPosVector v_iutLongPosVector := f_getIutLongPosVector();
var LongPosVector v_nodeALongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeA_longitudeFactor, c_compNodeA_latitudeFactor);
var LongPosVector v_nodeBLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeB_longitudeFactor, c_compNodeB_latitudeFactor);
var LongPosVector v_nodeCLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeC_longitudeFactor, c_compNodeC_latitudeFactor);
var LongPosVector v_nodeDLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeD_longitudeFactor, c_compNodeD_latitudeFactor);
// Create
p_nodeB := ItsNt.create(c_compNodeB) alive;
p_nodeC := ItsNt.create(c_compNodeC) alive;
// Map
map(p_nodeB:geoNetworkingPort, system:geoNetworkingPort);
map(p_nodeC:geoNetworkingPort, system:geoNetworkingPort);
// Connect
connect(p_nodeB:syncPort, self:syncPort);
connect(p_nodeC:syncPort, self:syncPort);
// Position table
f_addPosition(v_positionTable, c_compIut, v_iutLongPosVector);
f_addPosition(v_positionTable, c_compNodeA, v_nodeALongPosVector);
f_addPosition(v_positionTable, c_compNodeB, v_nodeBLongPosVector);
f_addPosition(v_positionTable, c_compNodeC, v_nodeCLongPosVector);
// Area table
f_addArea(v_areaTable, c_area1,
f_computeSquareArea(v_nodeDLongPosVector, float2int(1.1 * f_distance(v_nodeBLongPosVector, v_nodeDLongPosVector))));
f_addArea(v_areaTable, c_area2,
f_computeSquareArea(v_nodeBLongPosVector, float2int(1.1 * f_distance(v_nodeBLongPosVector, v_nodeDLongPosVector))));
p_nodeB.start(f_initialiseComponent(v_positionTable, v_areaTable, c_compNodeB));
p_nodeC.start(f_initialiseComponent(v_positionTable, v_areaTable, c_compNodeC));
p_nodeB.done;
p_nodeC.done;
} // end f_cf03Up
/**
* @desc Deletes configuration cf03
* @param p_nodeA
* @param p_nodeB
* @param p_nodeC
*/
function f_cf03Down(in ItsNt p_nodeB, in ItsNt p_nodeC) runs on ItsMtc {
// Map
unmap(p_nodeB:geoNetworkingPort, system:geoNetworkingPort);
unmap(p_nodeC:geoNetworkingPort, system:geoNetworkingPort);
// Connect
disconnect(p_nodeB:syncPort, self:syncPort);
disconnect(p_nodeC:syncPort, self:syncPort);
} // end f_cf03Down
/**
* @desc This configuration features:
* - one ITS node (IUT)
* - one ITS node (NodeA)
* - one ITS node in direction of NodeA and having
* shortest distance to NodeA (NodeB)
* - one ITS node in direction of NodeA (NodeD)
* - one ITS node not in direction of NodeA (NodeC)
* - Area1 which only includes NodeB, NodeD and IUT
* - Area2 which only includes NodeA, NodeB and NodeD
* NodeB being close to the area center
function f_cf04Up(out ItsNt p_nodeB, out ItsNt p_nodeC, out ItsNt p_nodeD) runs on ItsMtc {
// Variables
var PositionTable v_positionTable := {};
var GeoAreaTable v_areaTable := {};
var LongPosVector v_iutLongPosVector := f_getIutLongPosVector();
var LongPosVector v_nodeALongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeA_longitudeFactor, c_compNodeA_latitudeFactor);
var LongPosVector v_nodeBLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeB_longitudeFactor, c_compNodeB_latitudeFactor);
var LongPosVector v_nodeCLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeC_longitudeFactor, c_compNodeC_latitudeFactor);
var LongPosVector v_nodeDLongPosVector := f_computePosition(v_iutLongPosVector, c_compNodeD_longitudeFactor, c_compNodeD_latitudeFactor);
// Create
p_nodeB := ItsNt.create(c_compNodeB) alive;
p_nodeC := ItsNt.create(c_compNodeC) alive;
p_nodeD := ItsNt.create(c_compNodeD) alive;
// Map
map(p_nodeB:geoNetworkingPort, system:geoNetworkingPort);
map(p_nodeC:geoNetworkingPort, system:geoNetworkingPort);
map(p_nodeD:geoNetworkingPort, system:geoNetworkingPort);
// Connect
connect(p_nodeB:syncPort, self:syncPort);
connect(p_nodeC:syncPort, self:syncPort);
connect(p_nodeD:syncPort, self:syncPort);
// Position table
f_addPosition(v_positionTable, c_compIut, v_iutLongPosVector);
f_addPosition(v_positionTable, c_compNodeA, v_nodeALongPosVector);
f_addPosition(v_positionTable, c_compNodeB, v_nodeBLongPosVector);
f_addPosition(v_positionTable, c_compNodeC, v_nodeCLongPosVector);
f_addPosition(v_positionTable, c_compNodeD, v_nodeDLongPosVector);
// Area table
f_addArea(v_areaTable, c_area1,
f_computeSquareArea(v_nodeDLongPosVector, float2int(1.1 * f_distance(v_nodeBLongPosVector, v_nodeDLongPosVector))));
f_addArea(v_areaTable, c_area2,
f_computeSquareArea(v_nodeBLongPosVector, float2int(1.1 * f_distance(v_nodeBLongPosVector, v_nodeDLongPosVector))));
p_nodeB.start(f_initialiseComponent(v_positionTable, v_areaTable, c_compNodeB));
p_nodeC.start(f_initialiseComponent(v_positionTable, v_areaTable, c_compNodeC));
p_nodeD.start(f_initialiseComponent(v_positionTable, v_areaTable, c_compNodeD));
p_nodeB.done;
p_nodeC.done;
p_nodeD.done;
} // end f_cf04Up
/**
* @desc Deletes configuration cf04
* @param p_nodeB
* @param p_nodeC
* @param p_nodeD
*/
function f_cf04Down(in ItsNt p_nodeB, in ItsNt p_nodeC, in ItsNt p_nodeD) runs on ItsMtc {
// Map
unmap(p_nodeB:geoNetworkingPort, system:geoNetworkingPort);
unmap(p_nodeC:geoNetworkingPort, system:geoNetworkingPort);
unmap(p_nodeD:geoNetworkingPort, system:geoNetworkingPort);
// Connect
disconnect(p_nodeB:syncPort, self:syncPort);
disconnect(p_nodeC:syncPort, self:syncPort);
disconnect(p_nodeD:syncPort, self:syncPort);
} // end f_cf04Down
function f_initialiseComponent(
in PositionTable p_positionTable,
in charstring p_componentName)
runs on ItsNt {
vc_positionTable := p_positionTable;
vc_componentName := p_componentName;
} // end f_initialiseComponent
function f_startBeingNeighbour() runs on ItsNt {
activate(a_neighbourDefault());
tepelmann
committed
f_acTriggerEvent(m_startBeaconing(m_beaconHeader(f_getPosition(vc_componentName)).beaconHeader));
} // end f_startBeingNeighbour
function f_stopBeingNeighbour() runs on ItsNt {
deactivate; // FIXME: probably too brutal
activate(a_default());
} // end f_stopBeingNeighbour
} // end geoConfigurationFunctions
group geoPositionFunctions {
function f_addPosition(
in LongPosVector p_positionValue
) {
key := p_positionKey,
position := p_positionValue
};
in charstring p_positionKey
) runs on ItsNt
return LongPosVector {
var LongPosVector v_return;
var integer i := 0;
for (i:=0; i<lengthof(vc_positionTable); i:=i+1) {
if (vc_positionTable[i].key == p_positionKey) {
v_return := vc_positionTable[i].position;
}
}
return v_return;
}
/**
* @desc Gives the IUT position within the minimum update frequency of local position vector (LPV) in ms
* @see PICS_GN_MINIMUM_UPDATE_FREQUENCY_LPV
*/
function f_getPositionWithinMinUpdateFreq(
in PositionTable p_positionTable,
in charstring p_positionKey)
return LongPosVector {
var LongPosVector v_return := valueof(m_dummyLongPosVector);
// TODO
function f_computePosition(
in LongPosVector p_refPosition,
in integer p_longitudeFactor,
in integer p_latitudeFactor
) return LongPosVector {
var LongPosVector v_return := p_refPosition;
v_return.latitude := v_return.latitude + p_latitudeFactor * PX_DISTANCE_UNIT;
v_return.longitude := v_return.longitude + p_longitudeFactor * PX_DISTANCE_UNIT;
function f_addArea(
inout GeoAreaTable p_geoAreaTable,
in charstring p_areaKey,
in GeoArea p_geoArea
) {
p_geoAreaTable[lengthof(p_geoAreaTable)] := {
key := p_areaKey,
geoArea := p_geoArea
};
}
function f_getArea(
in charstring p_areaName
) runs on ItsNt
return GeoArea {
var GeoArea v_return;
var integer i := 0;
for (i:=0; i<lengthof(vc_areaTable); i:=i+1) {
if (vc_areaTable[i].key == p_areaName) {
v_return := vc_areaTable[i].geoArea;
function f_getGeoBroadcastArea(in charstring p_areaName) runs on ItsNt
return GeoBroadcastArea {
return f_geoArea2geoBroadcastArea(f_getArea(p_areaName));
function f_getGeoAnycastArea(in charstring p_areaName) runs on ItsNt
return GeoAnycastArea {
return f_geoArea2geoAnycastArea(f_getArea(p_areaName));
}
function f_geoArea2geoBroadcastArea(GeoArea p_area)
return GeoBroadcastArea {
var GeoBroadcastArea v_broadcastArea;
if (p_area.shape == e_geoCircle) {
v_broadcastArea.geoBroadcastSubType := e_geoBroadcastCircle;
}
else if (p_area.shape == e_geoRect) {
v_broadcastArea.geoBroadcastSubType := e_geoBroadcastRect;
}
else if (p_area.shape == e_geoElip) {
v_broadcastArea.geoBroadcastSubType := e_geoBroadcastElip;
}
else {
v_broadcastArea.geoBroadcastSubType := e_reserved;
}
v_broadcastArea.geoBroadcastArea := p_area.area;
return v_broadcastArea;
function f_geoArea2geoAnycastArea(GeoArea p_area)
return GeoAnycastArea {
var GeoAnycastArea v_anycastArea;
if (p_area.shape == e_geoCircle) {
v_anycastArea.geoAnycastSubType := e_geoAnycastCircle;
}
else if (p_area.shape == e_geoRect) {
v_anycastArea.geoAnycastSubType := e_geoAnycastRect;
}
else if (p_area.shape == e_geoElip) {
v_anycastArea.geoAnycastSubType := e_geoAnycastElip;
}
else {
v_anycastArea.geoAnycastSubType := e_reserved;
}
v_anycastArea.geoAnycastArea := p_area.area;
return v_anycastArea;
}
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function f_computeSquareArea(
in LongPosVector p_centerLongPosVector,
in UInt16 p_distanceA
) return GeoArea {
var GeoArea v_geoArea;
v_geoArea := {
shape := e_geoRect,
area := {
geoAreaPosLatitude := p_centerLongPosVector.latitude,
geoAreaPosLongitude := p_centerLongPosVector.longitude,
distanceA := p_distanceA,
distanceB := p_distanceA,
angle := 0
}
}
return v_geoArea;
}
function f_distance(
in LongPosVector p_pointA,
in LongPosVector p_pointB
) return float {
return fx_computeDistance(p_pointA.latitude, p_pointA.longitude, p_pointB.latitude, p_pointB.longitude);
}
* @desc The base default.
*/
altstep a_default() runs on ItsNt {
var LongPosVector v_iutLongPosVector;
[] a_receiveLsRequest(
[] geoNetworkingPort.receive {
setverdict (inconc, "*** INCONC: Received an unexpected message ***");
//TODO shall stop be called here?
stop;
}
[] tc_wait.timeout {
setverdict (inconc, "*** INCONC: Timeout while awaiting reaction of the IUT prior to Upper Tester action ***");
//TODO shall stop be called here?
stop;
}
[] tc_ac.timeout {
setverdict (inconc, "*** INCONC: Timeout while awaiting the reception of a message ***");
//TODO shall stop be called here?
stop;
}
f_poDefault();
log("*** a_default: INFO: TEST COMPONENT NOW STOPPING ITSELF! ***");
stop;
}
altstep a_neighbourDefault() runs on ItsNt {
[] a_receiveLsRequestAndReply(
?, f_getPosition(vc_componentName).gnAddr,
f_getPosition(vc_componentName),
f_poNeighbour();
log("*** a_neighbourDefault: INFO: TEST COMPONENT NOW STOPPING ITSELF! ***");
stop;
}
[] a_default() {
}
}
group geoGeoUnicastAltsteps {
/**
* @desc Receive GeoUnicast packet
*/
altstep a_receiveGeoUnicast(
in template (present) LongPosVector p_senderLongPosVec,
in template (present) ShortPosVector p_destinationShortPosVec,
in template (present) UInt16 p_seqNumber
) runs on ItsNt {
[] geoNetworkingPort.receive(mw_geoNwInd(mw_geoNwPdu(mw_geoUnicastHeader(
p_senderLongPosVec,
p_destinationShortPosVec,
p_seqNumber)))) {
}
}
/**
* @desc Receive GeoUnicast packet for specific destination
*/
altstep a_receiveGeoUnicastWithDestination(in template (present) ShortPosVector p_destinationShortPosVec) runs on ItsNt {
[] a_receiveGeoUnicast(?, p_destinationShortPosVec, ?) {}
/**
* @desc Receive any GeoUnicast packet
*/
group geoGeoBroadcastAltsteps {
/**
* @desc Receive GeoBroadcast packet
*/
altstep a_receiveGeoBroadcast(
in template (present) LongPosVector p_srcLongPosVec,
in template (present) LongPosVector p_senderLongPosVec,
in template (present) UInt16 p_seqNumber
) runs on ItsNt {
[] geoNetworkingPort.receive(mw_geoNwInd(mw_geoNwPdu(mw_geoBroadcastHeader(
p_srcLongPosVec,
/**
* @desc Receive GeoBroadcast packet with specific Area and HopLimit
*/
altstep a_receiveGeoBroadcastWithAreaWithHopLimit(
in template (present) LongPosVector p_srcLongPosVec,
in template (present) LongPosVector p_senderLongPosVec,
in template (present) UInt16 p_seqNumber,
in template (present) GeoBroadcastArea p_broadcastArea,
in template (present) UInt8 p_hopLimit
) runs on ItsNt {
[] geoNetworkingPort.receive(mw_geoNwInd(mw_geoNwPdu(mw_geoBroadcastHeaderWithAreaWithHopLimit(
p_srcLongPosVec,
p_senderLongPosVec,
p_seqNumber,
p_broadcastArea,
p_hopLimit
)))) {
}
}
/**
* @desc Receive GeoBroadcast packet for specific Geobroadcast Area
*/
altstep a_receiveGeoBroadcastWithArea(
in template (present) LongPosVector p_srcLongPosVec,
in template (present) LongPosVector p_senderLongPosVec,
in template (present) GeoBroadcastArea p_broadcastArea
) runs on ItsNt {
[] geoNetworkingPort.receive(mw_geoNwInd(mw_geoNwPdu(mw_geoBroadcastHeaderWithArea(
p_srcLongPosVec,
p_seqNumber,
p_broadcastArea
)))) {
}
}
} // end geoGeoBroadcastAltsteps
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group geoGeoAnycastAltsteps {
/**
* @desc Receive GeoAnycast packet
*/
altstep a_receiveGeoAnycast(
in template (present) LongPosVector p_srcLongPosVec,
in template (present) LongPosVector p_senderLongPosVec,
in template (present) UInt16 p_seqNumber
) runs on ItsNt {
[] geoNetworkingPort.receive(mw_geoNwInd(mw_geoNwPdu(mw_geoAnycastHeader(
p_srcLongPosVec,
p_senderLongPosVec,
p_seqNumber
)))) {
}
}
/**
* @desc Receive GeoAnycast packet with specific Area and HopLimit
*/
altstep a_receiveGeoAnycastWithAreaWithHopLimit(
in template (present) LongPosVector p_srcLongPosVec,
in template (present) LongPosVector p_senderLongPosVec,
in template (present) UInt16 p_seqNumber,
in template (present) GeoAnycastArea p_anycastArea,
in template (present) UInt8 p_hopLimit
) runs on ItsNt {
[] geoNetworkingPort.receive(mw_geoNwInd(mw_geoNwPdu(mw_geoAnycastHeaderWithAreaWithHopLimit(
p_srcLongPosVec,
p_senderLongPosVec,
p_seqNumber,
p_anycastArea,
p_hopLimit
)))) {
}
}
/**
* @desc Receive GeoAnycast packet for specific GeoAnycast Area
*/
altstep a_receiveGeoAnycastWithArea(
in template (present) LongPosVector p_srcLongPosVec,
in template (present) LongPosVector p_senderLongPosVec,
in template (present) UInt16 p_seqNumber,
in template (present) GeoAnycastArea p_anycastArea
) runs on ItsNt {
[] geoNetworkingPort.receive(mw_geoNwInd(mw_geoNwPdu(mw_geoAnycastHeaderWithArea(
p_srcLongPosVec,
p_senderLongPosVec,
p_seqNumber,
p_anycastArea
)))) {
}
}
} // end geoGeoAnycastAltsteps
group geoLocationServiceAltsteps {
/**
* @desc Receive Location Service Request
*/
altstep a_receiveLsRequest(
in template (present) UInt16 p_seqNumber,
in template (present) GN_Address p_gnAddress,
var GeoNetworkingInd v_msg;
[] geoNetworkingPort.receive(
mw_geoNwInd(
mw_geoNwPdu(
mw_lsRequestHeader(
p_seqNumber,
p_gnAddress
)
)
)
) -> value v_msg {
p_reqSrcPosVector := valueof(v_msg.msgIn.header.lsRequestHeader.srcPosVector);
}
/**
* @desc Receive any Location Service Request
*/
altstep a_receiveAnyLsRequest() runs on ItsNt {
var LongPosVector v_reqSrcPosVector;
[] a_receiveLsRequest(?, ?, v_reqSrcPosVector) {}
}
/**
* @desc Receive Location Service Request and send Location Service Reply
*/
altstep a_receiveLsRequestAndReply(
in template (present) UInt16 p_reqSeqNumber,
in template (value) GN_Address p_gnAddress,
in template (value) LongPosVector p_repSrcPosVector,
in template (value) LongPosVector p_repSenderPosVector
var LongPosVector v_repDstPosVector;
[] a_receiveLsRequest(p_reqSeqNumber, p_gnAddress, v_repDstPosVector) {
f_sendGeoNetMessage(m_geoNwReq(m_geoNwPdu(
f_longPosVector2ShortPosVector(v_repDstPosVector),
}
}
} // end geoLocationServiceAltsteps
} // end geoAltsteps
group preambles {
/**
* @desc The default preamble.
*/
function f_prDefault() runs on ItsNt {
activate(a_default());
}
function f_prNonNeighbour() runs on ItsNt {
f_prDefault();
}
function f_prNeighbour() runs on ItsNt {
/**
* @desc Brings the IUT into an initial state.
* @return
*/
initComponent.start(f_utInitializeIut());
initComponent.done;
setverdict(pass);
}
function f_handleLocationService(
in template (present) UInt16 p_reqSeqNumber,
in template (value) GN_Address p_gnAddress,
in template (value) LongPosVector p_repSrcPosVector,
in template (value) LongPosVector p_repSenderPosVector
) runs on ItsNt {
tc_ac.start;
alt {
[] a_receiveLsRequestAndReply(p_reqSeqNumber, p_gnAddress, p_repSrcPosVector, p_repSenderPosVector) {
tc_ac.stop;
}
}
}
function f_processLocationService(
in template (value) LongPosVector p_reqSrcPosVector,
in template (value) UInt16 p_reqSeqNumber,
in template (value) GN_Address p_gnAddress,
) runs on ItsNt return FncRetCode {
var FncRetCode v_ret := e_error;
var GeoNetworkingInd v_msg;
f_sendGeoNetMessage(
m_geoNwReq(
m_geoNwPdu(
m_lsRequestHeader(
p_reqSrcPosVector,
p_reqSrcPosVector,
p_reqSeqNumber,
p_gnAddress
)
)
)
);
tc_ac.start;
alt {
[] geoNetworkingPort.receive(
mw_geoNwInd(
mw_geoNwPdu(
mw_lsReplyHeader(
p_reqSeqNumber,
?,
f_longPosVector2ShortPosVector(valueof(p_reqSrcPosVector))
)
)
)
) -> value v_msg {
tc_ac.stop;
p_repSrcPosVector := valueof(v_msg.msgIn.header.lsRequestHeader.srcPosVector);
v_ret := e_success;
}
}
return v_ret;
}
} // end preambles
group postambles {
/**
* @desc The default postamble.
*/
function f_poDefault() runs on ItsNt {
setverdict(pass);
}
function f_poNeighbour() runs on ItsNt {
/**
* @desc Requests to bring the IUT in an initial state
* @return
*/
utPort.send(UtGNInitialize:{});
tc_ac.start;
alt {
[] utPort.receive(UtGNResult:true) {
setverdict (pass, "IUT initialized");
}
[] utPort.receive {
setverdict (inconc, "IUT could not be initialized");
stop;
}
[] tc_ac.timeout {
setverdict (inconc, "IUT could not be initialized in time");
stop;
}
}
}
/**
* @desc Triggers event from the application layer
* @param p_event The event to trigger.
* @return
*/
function f_utTriggerEvent(template (value) UtGNEvent p_event) runs on ItsNt return FncRetCode {
var FncRetCode v_ret := e_success;
var template (value) UtGNTrigger v_utMsg := { p_event };
utPort.send(v_utMsg);
return v_ret;
/**
* @desc Checks that the event was indicated at the application layer
* @param p_event The event to check.
* @return
*/
function f_utCheckEvent(template (value) GeoNetworkingPacket p_event) runs on ItsNt return FncRetCode {
var FncRetCode v_ret := e_success;
var template (value) UtGNCheck v_utMsg := { p_event };
utPort.send(v_utMsg);
tc_ac.start;
alt {
[] utPort.receive(UtGNResult:true) {
setverdict (pass, "Event correctly indicated at application layer");
v_ret := e_success;
}
[] utPort.receive {
setverdict (fail, "Event not correctly indicated at application layer");
v_ret := e_error;
}
[] tc_ac.timeout {
setverdict (inconc, "Timeout while waiting for event check result");
v_ret := e_timeout;
}
}
return v_ret;
}
} // end upperTester
/**
* @desc Triggers event in the test system adaptation.
* @param p_event The event to trigger
* @return
function f_acTriggerEvent(template (value) AcGNEvent p_event) runs on ItsNt return FncRetCode {
var FncRetCode v_ret := e_success;
}
group commonFunctions {
/**