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import from LibCommon_VerdictControl all;
import from LibCommon_Sync all;
import from LibCommon_BasicTypesAndValues all;
import from LibCommon_DataStrings all;
import from LibCommon_Time all;
// LibIts
import from ITS_Container language "ASN.1:1997" all;
import from LibItsCommon_TestSystem all;
import from LibItsCommon_Functions all;
import from LibItsExternal_TypesAndValues all;
// LibItsGeoNetworking
import from LibItsGeoNetworking_TypesAndValues all;
import from LibItsGeoNetworking_Templates all;
import from LibItsGeoNetworking_Pixits all;
import from LibItsGeoNetworking_TestSystem all;
// LibItsGeoNetworking
import from LibItsDenm_Templates all;
// LibItsSecurity
import from LibItsSecurity_TypesAndValues all;
// AtsInterop
import from ItsAutoInterop_TypesAndValues all;
import from ItsAutoInterop_Templates all;
import from ItsAutoInterop_Functions all;
import from ItsAutoInterop_Pics all;
import from ItsAutoInterop_Pixits all;
import from ItsAutoInterop_TestSystem all;
/**
* @desc Verify complete forwarding message scenario (GREEDY, GREEDY, GREEDY)
* <pre>
* Pics Selection:
* Config Id: CF-01
* Initial conditions:
* with {
* itsGnNonAreaForwardingAlgorithm of EUT1 set to GREEDY
* itsGnNonAreaForwardingAlgorithm of EUT2 set to GREEDY
* itsGnNonAreaForwardingAlgorithm of EUT3 set to GREEDY
* itsGnNonAreaForwardingAlgorithm of EUT4 is SIMPLE
* }
* Expected behaviour:
* ensure that {
* when {
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* EUT1 is requested to send DEN message
* encapsulated in a GBC packet
* containing Basic Header
* containing RHL field
* indicating a value > 1
* containing DestinationArea
* indicating the TARGET_GEOAREA
* }
* then {
* EUT1 sends a GBC packet
* containing Basic Header
* containing RHL field
* containing DestinationArea
* indicating the TARGET_GEOAREA
* containing Payload
* containing the DEN message
* encapsulated in a LL packet
* containing a destination MAC address
* indicating the EUT2 address
* }
* when {
* EUT2 receives the GBC packet from EUT1
* }
* then {
* EUT2 sends a GBC packet
* containing Basic Header
* containing RHL field
* indicating value decreased by 1
* containing DestinationArea
* indicating the TARGET_GEOAREA
* containing Payload
* containing the DEN message
* encapsulated in a LL packet
* containing a destination MAC address
* indicating the EUT4 address
* and EUT3 does not receive the GBC packet from EUT1
* }
* when {
* EUT4 receives the GBC packet from EUT2
* containing Basic Header
* containing RHL field
* indicating value decreased by 1
* containing DestinationArea
* indicating the TARGET_GEOAREA
* containing Payload
* containing the DEN message
* }
* then {
* EUT4 provides the DEN message to upper layers
* and EUT4 sends a GBC packet
* containing Basic Header
* containing RHL field
* indicating value decreased by 1
* containing DestinationArea
* indicating the TARGET_GEOAREA
* containing Payload
* containing the DEN message
* encapsulated in a LL packet
* containing a destination MAC address
* indicating broadcast address
* }
* when {
* EUT2 receives the GBC packet from EUT4
* }
* then {
* EUT2 discards the GBC packet
* }
* when {
* EUT3 receives the GBC packet from EUT4
* EUT3 discards the GBC packet
* @see Draft ETSI TS yyy xxx-2 V0.0.8 (2017-03) TD_AUTO_IOT_DENM_MFW_BV_01
* @reference ETSI EN 302 636-4-1 Clauses D & E2
*/
testcase TC_AUTO_IOT_DENM_MFW_BV_01() runs on ItsAutoInteropGeoNetworkingMtc system ItsAutoInteropGeoNetworkingSystem {
// Local variables
var ItsAutoInteropGeonetworking v_eut1;
var ItsAutoInteropGeonetworking v_eut2;
var ItsAutoInteropGeonetworking v_eut3;
var ItsAutoInteropGeonetworking v_eut4;
// Test control
/*if (not PICS_GN_LS_FWD) {
log("*** " & testcasename() & ": PICS_GN_LS_FWD required for executing the TC ***");
setverdict(inconc);
stop;
}*/
// Test component configuration
f_mtcCf01Up(v_eut1, v_eut2, v_eut3, v_eut4);
// Preamble
// Start components
v_eut1.start(f_TC_AUTO_IOT_DENM_MFW_BV_01_eut1(v_eut1, PX_EUT1_ID));
v_eut2.start(f_TC_AUTO_IOT_DENM_MFW_BV_01_eut2(v_eut2, PX_EUT2_ID));
v_eut3.start(f_TC_AUTO_IOT_DENM_MFW_BV_01_eut3(v_eut3, PX_EUT3_ID));
v_eut4.start(f_TC_AUTO_IOT_DENM_MFW_BV_01_eut4(v_eut4, PX_EUT4_ID));
// Synchronization
f_serverSyncNClientsAndStop(4, {c_prDone, c_tbDone, c_poDone});
// Cleanup
f_mtcCf01Down(v_eut1, v_eut2, v_eut3, v_eut4);
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} // End of TC_AUTO_IOT_DENM_MFW_BV_01
group g_TC_AUTO_IOT_DENM_MFW_BV_01 {
/**
* @desc Behavior function for EUT1 (TC_AUTO_IOT_DENM_MFW_BV_01)
*/
function f_TC_AUTO_IOT_DENM_MFW_BV_01_eut1(
in ItsAutoInteropGeonetworking p_eut,
in integer p_eut_id
) runs on ItsAutoInteropGeonetworking {
// Local variables
var GeoNetworkingInd v_gnInd;
var template (value) Payload v_payload;
// Test component configuration
f_cfPtcUp(p_eut);
// Preamble
f_prDefault();
f_selfOrClientSyncAndVerdict(c_prDone, e_success);
// Test Body
tc_ac.start;
alt {
[] geoNetworkingPort.receive( // Filter broadcasted DENM
mw_geoNwInd_withLinkLayerDestination(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[p_eut_id].stationId
))),
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)) -> value v_gnInd { // Receives the triggered DENM message
tc_ac.stop;
// Re-send DEN message to EUT2s
eutGeoNetworkingPort.send(
m_forward_geoNetworkingInd(
v_gnInd
));
tc_ac.start;
repeat;
}
[] geoNetworkingPort.receive(
mw_geoNwInd_withLinkLayerDestination(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
complement(PX_EUT_DESC[p_eut_id].stationId)
))),
?
)) -> value v_gnInd { // Receives a broadcast MAC address
tc_ac.stop;
log("*** " & testcasename() & ": FAIL: Unexpected DEN message received ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_error);
}
// TODO Check unexpected messages on eutGeoNetworkingPort port
[] eutGeoNetworkingPort.receive { // TODO Use a default
tc_ac.stop;
tc_ac.start;
repeat;
}
[] geoNetworkingPort.receive { // TODO Use a default
tc_ac.stop;
tc_ac.start;
repeat;
}
[] tc_ac.timeout {
log("*** " & testcasename() & ": PASS: Forwarding message scenario (GREEDY, GREEDY, GREEDY) succeed ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_success);
}
}
// Postamble
f_poDefault();
f_cfPtcDown(p_eut);
} // End of f_TC_AUTO_IOT_DENM_MFW_BV_01_eut1
/**
* @desc Behavior function for EUT2 (TC_AUTO_IOT_DENM_MFW_BV_01)
*/
function f_TC_AUTO_IOT_DENM_MFW_BV_01_eut2(
in ItsAutoInteropGeonetworking p_eut,
in integer p_eut_id
) runs on ItsAutoInteropGeonetworking {
// Local variables
var EutGeoNetworking v_eutGeoNw;
// Test component configuration
f_cfPtcUp(p_eut);
// Preamble
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f_selfOrClientSyncAndVerdict(c_prDone, e_success);
// Test Body
tc_ac.start;
alt {
[] eutGeoNetworkingPort.receive(
mw_eutGeoNwInd(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[0].stationId
))))) -> value v_eutGeoNw { // Unexpected DEN message
tc_ac.stop;
// Now, we have to check for EUT4 to broadcast the DENM message
tc_ac.start;
repeat;
}
[] eutGeoNetworkingPort.receive(
mw_eutGeoNwInd_withLinkLayerDestination(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[3].stationId
))),
c_llBroadcast
)) -> value v_eutGeoNw { // Receives a broadcast MAC address from EUT4
tc_ac.stop;
log("*** " & testcasename() & ": PASS: DEN message was broadcasted by EUT4 ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_success);
}
[] eutGeoNetworkingPort.receive { // TODO Use a default
tc_ac.stop;
tc_ac.start;
repeat;
}
[] geoNetworkingPort.receive { // TODO Use a default
tc_ac.stop;
tc_ac.start;
repeat;
}
[] tc_ac.timeout {
log("*** " & testcasename() & ": FAIL: Forwarding message scenario (GREEDY, GREEDY, GREEDY) is incomplete ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_error);
}
} // End of 'alt' statement
// Postamble
f_poDefault();
f_cfPtcDown(p_eut);
} // End of f_TC_AUTO_IOT_DENM_MFW_BV_01_eut2
/**
* @desc Behavior function for EUT3 (TC_AUTO_IOT_DENM_MFW_BV_01)
*/
function f_TC_AUTO_IOT_DENM_MFW_BV_01_eut3(
in ItsAutoInteropGeonetworking p_eut,
in integer p_eut_id
) runs on ItsAutoInteropGeonetworking {
// Local variables
var EutGeoNetworking v_eutGeoNw;
// Test component configuration
f_cfPtcUp(p_eut);
// Preamble
f_selfOrClientSyncAndVerdict(c_prDone, e_success);
// Test Body
tc_ac.start;
alt {
[] eutGeoNetworkingPort.receive(
mw_eutGeoNwInd_withLinkLayerDestination(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[3].stationId
))),
c_llBroadcast
)) -> value v_eutGeoNw { // Receives a broadcast MAC address from EUT4
tc_ac.stop;
log("*** " & testcasename() & ": PASS: DEN message was broadcasted by EUT4 ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_success);
}
[] eutGeoNetworkingPort.receive { // TODO Use a default
tc_ac.stop;
tc_ac.start;
repeat;
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}
[] geoNetworkingPort.receive { // TODO Use a default
tc_ac.stop;
tc_ac.start;
repeat;
}
[] tc_ac.timeout {
log("*** " & testcasename() & ": FAIL: Forwarding message scenario (GREEDY, GREEDY, GREEDY) is incomplete ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_error);
}
} // End of 'alt' statement
// Postamble
f_poDefault();
f_cfPtcDown(p_eut);
} // End of f_TC_AUTO_IOT_DENM_MFW_BV_01_eut3
/**
* @desc Behavior function for EUT4 (TC_AUTO_IOT_DENM_MFW_BV_01)
*/
function f_TC_AUTO_IOT_DENM_MFW_BV_01_eut4(
in ItsAutoInteropGeonetworking p_eut,
in integer p_eut_id
) runs on ItsAutoInteropGeonetworking {
// Local variables
var GeoNetworkingInd v_gnInd;
var EutGeoNetworking v_eutGeoNw;
var integer v_denm_counter := 0;
// Test component configuration
f_cfPtcUp(p_eut);
// Preamble
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f_selfOrClientSyncAndVerdict(c_prDone, e_success);
// Test Body
tc_ac.start;
alt {
[] eutGeoNetworkingPort.receive(
mw_eutGeoNwInd_withLinkLayerDestination(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[0].stationId
))),
PX_EUT_DESC[p_eut_id].ll_mac_address
)) -> value v_eutGeoNw { // Receive a DEN message from EUT2
tc_ac.stop;
// Now check that EUT4 brodcasts the DENM message
tc_ac.start;
repeat;
}
[] geoNetworkingPort.receive(
mw_geoNwInd_withLinkLayerDestination(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[3].stationId
))),
c_llBroadcast
)) -> value v_gnInd { // EUT4 has brodcasted the DENM message
tc_ac.stop;
// Re-send DEN message to the other EUTs
eutGeoNetworkingPort.send(
m_forward_geoNetworkingInd(
v_gnInd
));
log("*** " & testcasename() & ": PASS: Forwarding message scenario (GREEDY, GREEDY, GREEDY) succeed ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_success);
}
[] eutGeoNetworkingPort.receive { // TODO Use a default
tc_ac.stop;
tc_ac.start;
repeat;
}
[] geoNetworkingPort.receive { // TODO Use a default
tc_ac.stop;
tc_ac.start;
repeat;
}
[] tc_ac.timeout {
log("*** " & testcasename() & ": FAIL: Forwarding message scenario (GREEDY, GREEDY, GREEDY) is incomplete ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_error);
}
} // End of 'alt' statement
// Postamble
f_poDefault();
f_cfPtcDown(p_eut);
} // End of f_TC_AUTO_IOT_DENM_MFW_BV_01_eut4
} // End of group g_TC_AUTO_IOT_DENM_MFW_BV_01
/**
* @desc Verify complete Road Works Warning scenario
* <pre>
* Pics Selection:
* Config Id: CF-02
* Initial conditions:
* with {
* EUT1 having sent Road Work Warning DEN messages D1
* containing a �speedLimit�
* indicating the value 30
* containing a �drivingLaneStatus�
* indicating the value �0001�B
* containing a �trafficFlowRule�
* indicating the value �passToRight�
* and EUT1 having sent a DEN message D2
* containing a �speedLimit�
* containing a �drivingLaneStatus�
* indicating the value �0011�B
* containing a �trafficFlowRule
* indicating the value �passToRight�
* and EUT1 having sent a DEN message D3
* containing a �speedLimit�
* indicating the value 30
* containing a �drivingLaneStatus�
* indicating the value �0101�B
* containing a �trafficFlowRule�
* indicating the value �passToLeft�
* and EUT2 having received the DEN messages D1, D2 and D3
* }
* Expected behaviour:
* ensure that {
* when {
* EUT2 reaches the position POS0
* EUT2 already indicates the speed limit information
* EUT2 reaches the position POS1
* EUT2 still indicates the speed limit information
* and EUT2 already indicates the most outer lane closed
* and EUT2 already indicates the hardshoulder opened
* EUT2 reaches the position POS2
* EUT2 still indicates the speed limit information
* and EUT2 already indicates the two most outer lanes closed
* and EUT2 already indicates the hardshoulder opened
* EUT2 reaches the position POS3
* EUT2 still indicates the speed limit information
* and EUT2 already indicates the most right lane closed
* and EUT2 already indicates the hardshoulder closed
* EUT2 reaches the position POS4
* EUT2 stops indicating the speed limit information
* and EUT2 stops indicating the lanes status
* @see Draft ETSI TS yyy xxx-2 V0.0.8 (2017-03) TD_AUTO_IOT_DENM_RWW_BV_01
* @reference ETSI EN 302 637-3 [5]
*/
testcase TC_AUTO_IOT_DENM_RWW_BV_01() runs on ItsAutoInteropGeoNetworkingMtc system ItsAutoInteropGeoNetworkingSystem {
// Local variables
var ItsAutoInteropGeonetworking v_eut1;
var ItsAutoInteropGeonetworking v_eut2;
// Test control
/*if (not PICS_GN_LS_FWD) {
log("*** " & testcasename() & ": PICS_GN_LS_FWD required for executing the TC ***");
setverdict(inconc);
stop;
}*/
// Test component configuration
// Preamble
// Start components
v_eut1.start(f_TC_AUTO_IOT_DENM_RWW_BV_01_eut1(v_eut1, PX_EUT1_ID));
v_eut2.start(f_TC_AUTO_IOT_DENM_RWW_BV_01_eut2(v_eut2, PX_EUT2_ID));
// Synchronization
f_serverSyncNClientsAndStop(2, {c_prDone, c_tbDone, c_poDone});
// Cleanup
} // End of TC_AUTO_IOT_DENM_RWW_BV_01
group g_TC_AUTO_IOT_DENM_RWW_BV_01 {
/**
* @desc Behavior function for EUT1 (TC_AUTO_IOT_DENM_RWW_BV_01)
*/
function f_TC_AUTO_IOT_DENM_RWW_BV_01_eut1(
in ItsAutoInteropGeonetworking p_eut,
in integer p_eut_id
) runs on ItsAutoInteropGeonetworking {
// Local variables
var GeoNetworkingInd v_gnInd;
// Test component configuration
f_cfPtcUp(p_eut);
// Preamble
// Nothing to do
f_selfOrClientSyncAndVerdict(c_prDone, e_success);
// Test Body
tc_ac.start;
alt {
[] geoNetworkingPort.receive(
mw_geoNwInd(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[p_eut_id].stationId,
mw_denm(
mw_denmMgmtCon_with_relevances(
?,
-,
-,
-,
-,
-,
-,
-
),
mw_situation(
CauseCodeType_roadworks_,
?
))))))) -> value v_gnInd { // Receive a DEN message
tc_ac.stop;
// Re-send DEN message to the other EUTs
eutGeoNetworkingPort.send(
m_forward_geoNetworkingInd(
v_gnInd
));
tc_ac.start;
repeat;
}
[] tc_ac.timeout {
log("*** " & testcasename() & ": PASS: Test done ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_success);
}
} // End of 'alt' statement
// Postamble
f_poDefault();
f_cfPtcDown(p_eut);
} // End of f_TC_AUTO_IOT_DENM_RWW_BV_01_eut1
/**
* @desc Behavior function for EUT2 (TC_AUTO_IOT_DENM_RWW_BV_01)
*/
function f_TC_AUTO_IOT_DENM_RWW_BV_01_eut2(
in ItsAutoInteropGeonetworking p_eut,
in integer p_eut_id
) runs on ItsAutoInteropGeonetworking {
// Local variables
var EutGeoNetworking v_eutGeoNw;
var HmiSignageEventInd v_hmiSignageEventInd;
var integer v_counter; // DEN message counter
var ThreeDLocation v_nextPosition2reach := PICS_POS0; // The different position to reach
var float v_distance; // The vehicle position calculated using GN messages
var integer v_isOnPosition := -1; // Set to unknown position
// Test component configuration
f_cfPtcUp(p_eut);
// Preamble
// Wait for EUT_1 DEN messages
v_counter := 0;
tc_ac.start;
alt {
[] eutGeoNetworkingPort.receive(
mw_eutGeoNwInd(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
?,
mw_denm(
mw_denmMgmtCon_with_relevances(
?,
-,
-,
-,
-,
-,
-,
-
),
mw_situation(
CauseCodeType_roadworks_,
?
))))))) -> value v_eutGeoNw { // Receive a DEN message
tc_ac.stop;
v_counter := v_counter + 1;
if (v_counter < 3) {
tc_ac.start;
} else {
log("*** " & testcasename() & ": INFO: EUT2 (vehicle) receives RWW DENMs D1, D2 and D3 ***");
f_selfOrClientSyncAndVerdict(c_prDone, e_success);
}
}
[] tc_ac.timeout {
log("*** " & testcasename() & ":FAIL: EUT2 (vehicle) does not receive RWW DENMs D1, D2 and D3 ***");
f_selfOrClientSyncAndVerdict(c_prDone, e_error);
}
} // End of 'alt' statement
// Test Body
tc_wait.start;
alt {
[] eutGeoNetworkingPort.receive(
mw_eutGeoNwInd_withLinkLayerDestination(
mw_geoNwPdu(
mw_geoNwShbPacketWithNextHeader_cam(
?,
?,
e_btpB,
mw_cam_stationId(
-,
PX_EUT_DESC[p_eut_id].stationId
))),
c_llBroadcast
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)) -> value v_eutGeoNw {
// Compute distance from v_nextPosition2reach
v_distance := f_distance(
v_eutGeoNw.msg.gnPacket.packet.extendedHeader.shbHeader.srcPosVector,
valueof(m_longPosVector(v_nextPosition2reach))
);
select (v_isOnPosition) {
case (-1) {
if (v_distance <= PX_EPSILON_DISTANCE) { // Position PICS_POS1 was reached
v_isOnPosition := 0;
v_nextPosition2reach := PICS_POS1;
tc_noac.start;
}
}
case (0) {
if (v_distance <= PX_EPSILON_DISTANCE) { // Position PICS_POS2 was reached
v_isOnPosition := 1;
v_nextPosition2reach := PICS_POS2;
tc_noac.start;
}
}
case (1) {
if (v_distance <= PX_EPSILON_DISTANCE) { // Position PICS_POS3 was reached
v_isOnPosition := 2;
v_nextPosition2reach := PICS_POS3;
tc_noac.start;
}
}
case (2) {
if (v_distance <= PX_EPSILON_DISTANCE) { // Position PICS_POS4 was reached
v_isOnPosition := 3;
v_nextPosition2reach := PICS_POS4;
tc_noac.start;
}
}
case else {
tc_noac.start;
}
} // End of 'select' statement
[v_isOnPosition == 0] hmiPort.receive(
mw_hmiSignageEventInd_roadworks_limitedspeed
log("*** " & testcasename() & ": INFO: EUT2 reaches position ", v_isOnPosition, " ***");
tc_noac.stop;
repeat; // Continue
HmiSignageEventInd:?/*TODO*/
) -> value v_hmiSignageEventInd {
log("*** " & testcasename() & ": INFO: EUT2 reaches position ", v_isOnPosition, " ***");
tc_noac.stop;
repeat; // Continue
HmiSignageEventInd:?/*TODO*/
) -> value v_hmiSignageEventInd {
log("*** " & testcasename() & ": INFO: EUT2 reaches position ", v_isOnPosition, " ***");
tc_noac.stop;
repeat; // Continue
HmiSignageEventInd:?/*TODO*/
) -> value v_hmiSignageEventInd {
log("*** " & testcasename() & ": PASS: Road Works Warning scenario complete ***");
tc_noac.stop;
repeat; // Continue
[] tc_noac.timeout {
log("*** " & testcasename() & ": FAIL: Road Works Warning scenario failure in position ", v_isOnPosition, " ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_success);
log("*** " & testcasename() & ": INCONC: Road Works Warning scenario is incomplet ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_timeout);
}
} // End of 'alt' statement
// Postamble
f_poDefault();
f_cfPtcDown(p_eut);
} // End of f_TC_AUTO_IOT_DENM_RWW_BV_01_eut2
} // End of group g_TC_AUTO_IOT_DENM_RWW_BV_01
/**
* @desc Verify complete Road hazard Signals scenario
* with {
* EUT1 having sent Road Work Warning DEN messages D
* containing a management
* containing eventPosition
* indicating POS1
* containing relevanceDistance
* indicating lessThan100m
* containing relevanceTrafficDirection
* indicating allTrafficDirections
* containing situation
* containing eventType
* containing causeCode
* indicating a valid CAUSE_CODE (Table 4)
* containing subCauseCode
* indicating a valid SUB_CAUSE_CODE (Table 5)
* }
* ensure that {
* when {
* EUT2 reaches the position POS0
* }
* then {
* EUT2 already indicates the Road Hazard information
* }
* }
* @see Draft ETSI TS yyy xxx-2 V0.0.8 (2017-03) TD_AUTO_IOT_DENM_RHS_BV_01
* @reference ETSI EN 302 637-3 [5]
testcase TC_AUTO_IOT_DENM_RHS_BV_01() runs on ItsAutoInteropGeoNetworkingMtc system ItsAutoInteropGeoNetworkingSystem {
// Local variables
var ItsAutoInteropGeonetworking v_eut1;
var ItsAutoInteropGeonetworking v_eut2;
// Test control
/*if (not PICS_GN_LS_FWD) {
log("*** " & testcasename() & ": PICS_GN_LS_FWD required for executing the TC ***");
setverdict(inconc);
stop;
}*/
// Test component configuration
f_mtcCf02Up(v_eut1, v_eut2);
// Preamble
// Start components
v_eut1.start(f_TC_AUTO_IOT_DENM_RHS_BV_01_eut1(v_eut1, PX_EUT1_ID));
v_eut2.start(f_TC_AUTO_IOT_DENM_RHS_BV_01_eut2(v_eut2, PX_EUT2_ID));
f_serverSyncNClientsAndStop(2, {c_prDone, c_tbDone, c_poDone});
f_mtcCf02Down(v_eut1, v_eut2);
} // End of TC_AUTO_IOT_DENM_RHS_BV_01
group g_TC_AUTO_IOT_DENM_RHS_BV_01 {
* @desc Behavior function for EUT1 (TC_AUTO_IOT_DENM_RHS_BV_01)
function f_TC_AUTO_IOT_DENM_RHS_BV_01_eut1(
in ItsAutoInteropGeonetworking p_eut,
in integer p_eut_id
) runs on ItsAutoInteropGeonetworking {
// Local variables
var GeoNetworkingInd v_gnInd;
// Test component configuration
f_cfPtcUp(p_eut);
// Preamble
f_prDefault();
f_selfOrClientSyncAndVerdict(c_prDone, e_success);
// Test Body
tc_ac.start;
alt {
[] geoNetworkingPort.receive(
mw_geoNwInd(
mw_geoNwTsbPacketWithNextHeader_denm(
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[p_eut_id].stationId
))))) -> value v_gnInd { // Receive a DEN message
tc_ac.stop;
// Re-send DEN message to the other EUTs
eutGeoNetworkingPort.send(
m_forward_geoNetworkingInd(
v_gnInd
));
[] tc_ac.timeout {
log("*** " & testcasename() & ": PASS: Test done ***");
f_selfOrClientSyncAndVerdict(c_tbDone, e_success);
}
} // End of 'alt' statement
// Postamble
f_poDefault();
f_cfPtcDown(p_eut);
} // End of f_TC_AUTO_IOT_DENM_RHS_BV_01_eut1
/**
* @desc Behavior function for EUT2 (TC_AUTO_IOT_DENM_RHS_BV_01)
*/
function f_TC_AUTO_IOT_DENM_RHS_BV_01_eut2(
in ItsAutoInteropGeonetworking p_eut,
in integer p_eut_id
) runs on ItsAutoInteropGeonetworking {
// Local variables
var EutGeoNetworking v_eutGeoNw;
// Test component configuration
f_cfPtcUp(p_eut);
// Preamble
f_prDefault();
tc_ac.start;
alt {
[] eutGeoNetworkingPort.receive(
mw_eutGeoNwInd(
mw_geoNwPdu(
mw_geoNwTsbPacketWithNextHeader_denm(
?,
?,
e_btpB,
mw_denm_stationId(
PX_EUT_DESC[PX_EUT1_ID].stationId,
mw_denm(
mw_denmMgmtCon_with_relevances(
mw_anyActionId,
-,
-,
-,
-,
-,
lessThan100m,
allTrafficDirections
),
mw_situation(
PX_DENM_CAUSE_VA,
PX_DENM_SUBCAUSE_VA
))))))) {
log("*** " & testcasename() & ": INCONC: Expected DEN message not received ***");
f_selfOrClientSyncAndVerdict(c_prDone, e_timeout);
}
} // End of 'alt' statement
// Test Body
tc_ac.start;
alt {
[] eutGeoNetworkingPort.receive(
mw_eutGeoNwInd(
mw_geoNwPdu(
mw_geoNwShbPacketWithNextHeader_cam(
?,
?,
mw_cam_stationId(
-,
PX_EUT_DESC[p_eut_id].stationId