本文整理汇总了C++中TPosition::VerticalAccuracy方法的典型用法代码示例。如果您正苦于以下问题:C++ TPosition::VerticalAccuracy方法的具体用法?C++ TPosition::VerticalAccuracy怎么用?C++ TPosition::VerticalAccuracy使用的例子?那么恭喜您, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在类TPosition
的用法示例。
在下文中一共展示了TPosition::VerticalAccuracy方法的10个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的C++代码示例。
示例1: ComparePositions
void CTe_LbsLocationMonitorSuiteStepBase::ComparePositions(TPosition& aLeft, TPosition& aRight)
{
TEST(aLeft.HorizontalAccuracy() == aRight.HorizontalAccuracy());
TEST(aLeft.VerticalAccuracy() == aRight.VerticalAccuracy());
TEST(aLeft.Latitude() == aRight.Latitude());
TEST(aLeft.Longitude() == aRight.Longitude());
TEST(aLeft.Altitude() == aRight.Altitude());
}
示例2:
void CT_LbsClientPosTp2::CheckPositionL(TPosition& aPos)
{
if (aPos.Time() != TTime(KPositionTime) ||
aPos.HorizontalAccuracy() != KHorizontalAcc ||
aPos.VerticalAccuracy() != KVerticalAcc ||
aPos.Latitude() != KLatitude ||
aPos.Longitude() != KLongitude ||
aPos.Altitude() != KAltitude)
{
_LIT(KErrPosition, "Wrong position returned");
LogErrorAndLeaveL(KErrPosition);
}
}
示例3: PrintPosInfo
EXPORT_C void MTe_LbsPsyStaticData::PrintPosInfo(const TPositionInfo& aPosInfo) const
{
_LIT(KTimeFormat, "%H:%T:%S.%C");
TBuf<100> cTimeStr;
INFO_PRINTF2(_L("classSize=%d"), aPosInfo.PositionClassSize());
INFO_PRINTF2(_L("classType=0x%x"), aPosInfo.PositionClassType());
INFO_PRINTF2(_L("moduleId=0x%x"), aPosInfo.ModuleId());
INFO_PRINTF2(_L("updateType=%d"), aPosInfo.UpdateType());
INFO_PRINTF2(_L("positionMode=%d"), aPosInfo.PositionMode());
INFO_PRINTF2(_L("positionModeReason=%d"), aPosInfo.PositionModeReason());
TPosition pos;
aPosInfo.GetPosition(pos);
INFO_PRINTF2(_L("pos altitude=%f"), pos.Altitude());
INFO_PRINTF2(_L("pos latitude=%f"), pos.Latitude());
INFO_PRINTF2(_L("pos longitude=%f"), pos.Longitude());
INFO_PRINTF2(_L("pos datum=0x%x"), pos.Datum());
INFO_PRINTF2(_L("pos horAccuracy=%f"), pos.HorizontalAccuracy());
INFO_PRINTF2(_L("pos verAccuracy=%f"), pos.VerticalAccuracy());
TRAP_IGNORE(pos.Time().FormatL(cTimeStr, KTimeFormat);)
示例4: CheckPositionClearsL
// ---------------------------------------------------------
// CPosPSYClearPositionDataTest::CheckPositionClearsL
//
// (other items were commented in a header).
// ---------------------------------------------------------
//
void CPosPSYClearPositionDataTest::CheckPositionClearsL(
const TDesC& aPositionType)
{
TPosition position;
iPosInfo->GetPosition(position);
TBool allIsCleared = ETrue;
if (position.Time() == KTime)
{
_LIT(KError, "Time not cleared for ");
AddMessageL(KError, aPositionType, EErrorMessage);
allIsCleared = EFalse;
}
if (!Math::IsNaN(position.HorizontalAccuracy()))
{
if (position.HorizontalAccuracy() == KHorizontalAccuracy)
{
_LIT(KError, "Horizontal Accuracy not cleared for ");
AddMessageL(KError, aPositionType, EErrorMessage);
allIsCleared = EFalse;
}
}
if (!Math::IsNaN(position.VerticalAccuracy()))
{
if (position.VerticalAccuracy() == KVerticalAccuracy)
{
_LIT(KError, "Vertical Accuracy not cleared for ");
AddMessageL(KError, aPositionType, EErrorMessage);
allIsCleared = EFalse;
}
}
if (!Math::IsNaN(position.Latitude()))
{
if (position.Latitude() == KLatitude)
{
_LIT(KError, "Latitude not cleared for ");
AddMessageL(KError, aPositionType, EErrorMessage);
allIsCleared = EFalse;
}
}
if (!Math::IsNaN(position.Longitude()))
{
if (position.Longitude() == KLongitude)
{
_LIT(KError, "Longitude not cleared for ");
AddMessageL(KError, aPositionType, EErrorMessage);
allIsCleared = EFalse;
}
}
if (!Math::IsNaN(position.Altitude()))
{
if (position.Altitude() == KAltitude)
{
_LIT(KError, "Altitude not cleared for ");
AddMessageL(KError, aPositionType, EErrorMessage);
allIsCleared = EFalse;
}
}
if (allIsCleared)
{
_LIT(KInfo, "All TPositionInfo fields were cleared for ");
AddMessageL(KInfo, aPositionType, EInfoMessage);
}
}
示例5: ProcessNetworkPositionUpdate
void CT_LbsHybridUEAssistedMTLRTimeout::ProcessNetworkPositionUpdate(TUint /*aRequestId*/, const TPositionInfo& aPosInfo)
{
if(iState==EPrivacyCheckOk)
{
iState=ERefLocReceived;
INFO_PRINTF1(_L(">>CT_LbsHybridUEAssistedMTLRTimeout::ProcessNetworkPositionUpdate(RefPosition)"));
}
else if(iState==ERefLocReceived)
{
// Test for $update,1,2,51.5015,-0.105,50,2,3*
TPosition getPos;
aPosInfo.GetPosition(getPos);
if(getPos.Latitude()==51.5015 && getPos.Longitude()==-0.105 && getPos.Altitude()==50 && getPos.HorizontalAccuracy()==2 && getPos.VerticalAccuracy()==3)
{
INFO_PRINTF1(_L(">>CT_LbsHybridUEAssistedMTLRTimeout::ProcessNetworkPositionUpdate(GpsPosition)"));
iState=EGpsLocReceived;
}
}
ReturnToTestStep();
}
示例6: Compare_PosInfo
EXPORT_C TBool T_LbsUtils::Compare_PosInfo(const TPositionInfoBase& aPosInfoSideA, const TPositionInfoBase& aPosInfoSideB, TComparisonAccuracyType aCmpAccuracy)
{
// TODO compare base class items, such as module id, position mode, etc.
TUint32 typeA = aPosInfoSideA.PositionClassType();
TUint32 typeB = aPosInfoSideB.PositionClassType();
// Compare TPositionInfo type items.
if(typeA & typeB & EPositionInfoClass)
{
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Both positions are of type EPositionInfoClass");
const TPositionInfo& posInfoSideA = reinterpret_cast<const TPositionInfo&>(aPosInfoSideA);
const TPositionInfo& posInfoSideB = reinterpret_cast<const TPositionInfo&>(aPosInfoSideB);
TPosition posSideA;
TPosition posSideB;
posInfoSideA.GetPosition(posSideA);
posInfoSideB.GetPosition(posSideB);
// Carry out an exact check when comparing items.
if (EExactAccuracy == aCmpAccuracy)
{
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Comparing positions for exact match");
// Compare latitude.
if (Math::IsNaN(posSideA.Latitude()) && Math::IsNaN(posSideB.Latitude()))
;
else if (posSideA.Latitude() != posSideB.Latitude())
{
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Positions don't match!");
TESTLOG3(ELogP1, "Latitudes %d and %d respectively", posSideA.Latitude(), posSideB.Latitude());
return EFalse;
}
// Compare longitude.
if (Math::IsNaN(posSideA.Longitude()) && Math::IsNaN(posSideB.Longitude()))
;
else if (posSideA.Longitude() != posSideB.Longitude())
{
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Positions don't match!");
TESTLOG3(ELogP1, "Longitudes %d and %d respectively", posSideA.Longitude(), posSideB.Longitude());
return EFalse;
}
// Compare altitude.
if (Math::IsNaN(posSideA.Altitude()) && Math::IsNaN(posSideB.Altitude()))
;
else if (posSideA.Altitude() != posSideB.Altitude())
{
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Positions don't match!");
TESTLOG3(ELogP1, "Altitudes %d and %d respectively", posSideA.Altitude(), posSideB.Altitude());
return EFalse;
}
// Compare datum.
if (posSideA.Datum() != posSideB.Datum())
{
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Positions don't match!");
TESTLOG3(ELogP1, "Datums %d and %d respectively", posSideA.Datum(), posSideB.Datum());
return EFalse;
}
// Compare horizontal accuracy.
if (Math::IsNaN(posSideA.HorizontalAccuracy()) && Math::IsNaN(posSideB.HorizontalAccuracy()))
;
else if (posSideA.HorizontalAccuracy() != posSideB.HorizontalAccuracy())
{
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Positions don't match!");
TESTLOG3(ELogP1, "Horizontal Accuracies %d and %d respectively", posSideA.HorizontalAccuracy(), posSideB.HorizontalAccuracy());
return EFalse;
}
// Compare vertical accuracy.
if (Math::IsNaN(posSideA.VerticalAccuracy()) && Math::IsNaN(posSideB.VerticalAccuracy()))
;
else if (posSideA.VerticalAccuracy() != posSideB.VerticalAccuracy())
{
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Positions don't match!");
TESTLOG3(ELogP1, "Vertical Accuracies %d and %d respectively", posSideA.VerticalAccuracy(), posSideB.VerticalAccuracy());
return EFalse;
}
}
else
{
// Check latitude + longitude using horz accuracy.
TReal horzAct = posSideA.HorizontalAccuracy(); // Use the verify accuracy value (which is side A).
TReal distance ;
TESTLOG(ELogP1, "T_LbsUtils::Compare_PosInfo() Comparing positions for 'rough' match");
// if(NAN != horzAct)
{
// The following is a temporary patch until TPositionInfo.Distance() is implemented:
/*
from http://www.movable-type.co.uk/scripts/GIS-FAQ-5.1.html
presuming a spherical Earth with radius R (see below), and the locations of the two points in spherical coordinates (longitude and latitude) are lon1,lat1 and lon2,lat2 then the
Haversine Formula (from R.W. Sinnott, "Virtues of the Haversine", Sky and Telescope, vol. 68, no. 2, 1984, p. 159):
dlon = lon2 - lon1
dlat = lat2 - lat1
//.........这里部分代码省略.........
示例7: DeliverPositionerResults
void XQLocationPrivate::DeliverPositionerResults(TPositionSatelliteInfo aPositionInfo)
{
TPosition pos;
aPositionInfo.GetPosition(pos);
// Handle speed reporting
float speed = 0;
if (speedAvailable) {
// Positioning module is able to offer speed information
TCourse course;
aPositionInfo.GetCourse(course);
speed = course.Speed();
if (isnan(speed)) {
speed = 0;
}
} else {
// Positioning module does not offer speed information
// => Speed is calculated using position information & timestamps
TTime posTime;
TTimeIntervalSeconds interval;
for (int i = iPositions.Count()-1 ; i >= 0; i--) {
if (pos.Time().SecondsFrom(iPositions[i].Time(),interval) == KErrNone) {
if (interval.Int() > 10) {
pos.Speed(iPositions[i], speed);
break;
}
}
}
while (iPositions.Count() > 0) {
if (pos.Time().SecondsFrom(iPositions[0].Time(),interval) == KErrNone) {
if (interval.Int() > 60) {
iPositions.Remove(0);
} else {
break;
}
}
}
if (iPositions.Count() > 0) {
if (pos.Time().SecondsFrom(iPositions[iPositions.Count()-1].Time(),interval) == KErrNone) {
if (interval.Int() > 1) {
iPositions.Append(pos);
}
}
} else {
iPositions.Append(pos);
}
// Accept speed from range 0.01 m/s (0.036 km/h) to 200 m/s (720 km/h)
if (speed < 0.01 || speed > 200) {
speed = 0;
}
}
if (speed != iPreviousSpeed) {
emit ipParent->speedChanged(speed);
}
iPreviousSpeed = speed;
// Handle satellite information reporting
if (satelliteInfoAvailable) {
if (aPositionInfo.NumSatellitesInView() != iPreviousNumSatellitesInView) {
emit ipParent->numberOfSatellitesInViewChanged(aPositionInfo.NumSatellitesInView());
}
iPreviousNumSatellitesInView = aPositionInfo.NumSatellitesInView();
if (aPositionInfo.NumSatellitesUsed() != iPreviousNumSatellitesUsed) {
emit ipParent->numberOfSatellitesUsedChanged(aPositionInfo.NumSatellitesUsed());
}
iPreviousNumSatellitesUsed = aPositionInfo.NumSatellitesUsed();
}
// Handle position information reporting
if (iPreviousPosition.Latitude() != pos.Latitude() ||
iPreviousPosition.Longitude() != pos.Longitude() ||
iPreviousPosition.Altitude() != pos.Altitude()) {
if (!isnan(pos.Latitude()) || !isnan(pos.Longitude()) || !isnan(pos.Altitude())) {
emit ipParent->locationChanged(pos.Latitude(),pos.Longitude(),pos.Altitude(),speed);
}
if (iPreviousPosition.Latitude() != pos.Latitude()) {
if (!isnan(pos.Latitude())) {
emit ipParent->latitudeChanged(pos.Latitude(),pos.HorizontalAccuracy());
}
}
if (iPreviousPosition.Longitude() != pos.Longitude()) {
if (!isnan(pos.Longitude())) {
emit ipParent->longitudeChanged(pos.Longitude(),pos.HorizontalAccuracy());
}
}
if (iPreviousPosition.Altitude() != pos.Altitude()) {
if (!isnan(pos.Altitude())) {
emit ipParent->altitudeChanged(pos.Altitude(),pos.VerticalAccuracy());
}
}
}
iPreviousPosition = pos;
if (iSingleUpdate) {
stopUpdates();
iSingleUpdate = EFalse;
}
}
示例8: TestStepResult
//.........这里部分代码省略.........
// Set plugin to use.
TUid pluginUid;
if(iParent.iSharedData->iTestModuleInUse)
{
pluginUid = TUid::Uid(KSimpleAssistanceDataProviderPluginUidValue);
}
else
{
pluginUid = TUid::Uid(KSuplAssistanceDataProviderPluginUidValue);
}
if (!iNetSim.SetAssistanceDataProvider(pluginUid))
{
INFO_PRINTF1(_L("Failed test, can't set NetSim's assistance data plugin uid."));
SetTestStepResult(EFail);
iNetSim.Close();
return TestStepResult();
}
if (!iNetSim.SetReferenceLocation(srcPos))
{
INFO_PRINTF1(_L("Failed test, can't set NetSim's reference location."));
SetTestStepResult(EFail);
iNetSim.Close();
return TestStepResult();
}
// Set the MaxFix time required by the network.
TTimeIntervalMicroSeconds maxFixTime(150*1000000);
TLbsNetPosRequestQuality netPosQuality;
netPosQuality.SetMaxFixTime(maxFixTime);
netPosQuality.SetMinHorizontalAccuracy(srcPos.HorizontalAccuracy());
netPosQuality.SetMinVerticalAccuracy(srcPos.VerticalAccuracy());
if (!iNetSim.SetQuality(netPosQuality))
{
INFO_PRINTF1(_L("Failed test, can't set NetSim's quality."));
SetTestStepResult(EFail);
iNetSim.Close();
return TestStepResult();
}
//Timeout for Transmit Location
TLbsTransmitPositionOptions transmitOptions;
transmitOptions.SetTimeOut(120*1000000);
iTransmitPositioner.SetTransmitOptions(transmitOptions);
// Kick off the keep alive timer.
TTimeIntervalMicroSeconds32 interval(KLbsKeepAlivePeriod);
iKeepAliveTimer->SetTimer(interval);
if(iTestCaseId == 3)
{
const TInt32 time=1000;
iNetSim.SetResponseTime(time, ETrue); //TBD
}
CActiveScheduler::Start();
err = iStatus.Int();
switch(iTestCaseId)
{
case 1:
case 7:
break;
示例9: dt
void PsyUtils::TPositionInfo2QGeoPositionInfo(TPositionInfoBase &aPosInfoBase, QGeoPositionInfo& aQPosInfo)
{
if (aPosInfoBase.PositionClassType() & EPositionInfoClass ||
aPosInfoBase.PositionClassType() & EPositionSatelliteInfoClass) {
TPositionInfo *posInfo = static_cast<TPositionInfo*>(&aPosInfoBase);
TPosition pos;
QGeoCoordinate coord;
posInfo->GetPosition(pos);
coord.setLatitude(pos.Latitude());
coord.setLongitude(pos.Longitude());
coord.setAltitude(pos.Altitude());
//store the QGeoCoordinate values
aQPosInfo.setCoordinate(coord);
TDateTime datetime = pos.Time().DateTime();
QDateTime dt(QDate(datetime.Year() , datetime.Month() + 1, datetime.Day() + 1),
QTime(datetime.Hour() , datetime.Minute(), datetime.Second(),
datetime.MicroSecond() / 1000),
Qt::UTC);
//store the time stamp
aQPosInfo.setTimestamp(dt);
//store the horizontal accuracy
aQPosInfo.setAttribute(QGeoPositionInfo::HorizontalAccuracy, pos.HorizontalAccuracy());
//store the vertical accuracy
aQPosInfo.setAttribute(QGeoPositionInfo::VerticalAccuracy, pos.VerticalAccuracy());
if (aPosInfoBase.PositionClassType() & EPositionSatelliteInfoClass) {
TCourse course;
TPositionSatelliteInfo *satInfo = static_cast<TPositionSatelliteInfo*>(&aPosInfoBase);
satInfo->GetCourse(course);
aQPosInfo.setAttribute(QGeoPositionInfo::Direction, course.Heading());
aQPosInfo.setAttribute(QGeoPositionInfo::GroundSpeed, course.Speed());
aQPosInfo.setAttribute(QGeoPositionInfo::VerticalSpeed, course.VerticalSpeed());
}
}
if (aPosInfoBase.PositionClassType() & EPositionGenericInfoClass) {
HPositionGenericInfo *genInfo = static_cast<HPositionGenericInfo*>(&aPosInfoBase);
float val;
//check for the horizontal speed
if (genInfo->IsFieldAvailable(EPositionFieldHorizontalSpeed)) {
genInfo->GetValue(EPositionFieldHorizontalSpeed, val);
aQPosInfo.setAttribute(QGeoPositionInfo::GroundSpeed, val);
}
//check for the vertcal speed
if (genInfo->IsFieldAvailable(EPositionFieldVerticalSpeed)) {
genInfo->GetValue(EPositionFieldVerticalSpeed, val);
aQPosInfo.setAttribute(QGeoPositionInfo::VerticalSpeed, val);
}
//check for the magnetic variation
if (genInfo->IsFieldAvailable(EPositionFieldMagneticCourseError)) {
genInfo->GetValue(EPositionFieldMagneticCourseError, val);
aQPosInfo.setAttribute(QGeoPositionInfo::MagneticVariation, val);
}
//check for the heading
if (genInfo->IsFieldAvailable(EPositionFieldHeading)) {
genInfo->GetValue(EPositionFieldHeading, val);
aQPosInfo.setAttribute(QGeoPositionInfo::Direction, val);
}
}
}
示例10: options
//.........这里部分代码省略.........
TInt reason = KErrNone;
iProxy->CallL(ENetMsgProcessAssistanceData, &dataRequestMask, &assistanceData, &reason);
CleanupStack::PopAndDestroy(1); //assistanceData
// Assistance Data Notification End
// Network Location Request Start
// ProcessLocationRequest()
const TBool emergency(EFalse);
TLbsNetPosRequestQuality quality = ArgUtils::QualityAlpha2();
TLbsNetPosRequestMethod method = ArgUtils::RequestHybridMethod();
iProxy->CallL(ENetMsgProcessLocationRequest, &iSessionId, &emergency, &service, &quality, &method);
// Network Location Request Stop
//Start the timer
TTime timerStart;
timerStart.HomeTime();
// RequestAssistanceData(0)
TESTL(iProxy->WaitForResponse(KSmallTimeOut) == ENetMsgRequestAssistanceData);
TLbsAsistanceDataGroup dataGroup;
cleanupCnt = iProxy->GetArgsLC(ENetMsgRequestAssistanceData, &dataGroup);
TESTL(dataGroup == EAssistanceDataNone);
CleanupStack::PopAndDestroy(cleanupCnt);
// now wait for either to complete - but we will expect only the asynchrous request
// waiting for the REF position to complete with KErrNone
User::WaitForRequest(refPosStatus, transPosStatus);
TESTL(refPosStatus==KErrNone);
TESTL(transPosStatus.Int() == KRequestPending);
//Find the time elapsed from timer
TTimeIntervalMicroSeconds microseconds;
TTime timerStop;
timerStop.HomeTime();
microseconds = timerStop.MicroSecondsFrom(timerStart);
TInt64 timeElapsed = microseconds.Int64();
/*** NRH's Alpha2 timer expires. We enter Hybrid mode.***/
//Test that we do not get response before alpha2 has expired
TESTL(iProxy->WaitForResponse(KAlpha2Timeout-timeElapsed-KDelta) == ENetMsgTimeoutExpired);
TESTL(iProxy->WaitForResponse(2*KDelta) == ENetMsgRespondLocationRequest);
getSessionId = NULL;
TInt getReason = KErrNone;
TPositionSatelliteInfo* getPositionInfo = NULL;
cleanupCnt = iProxy->GetArgsLC(ENetMsgRespondLocationRequest, &getSessionId, &getReason, &getPositionInfo);
TESTL(getSessionId->SessionNum() == iSessionId.SessionNum());
TESTL(getReason==KErrNone);
CleanupStack::PopAndDestroy(cleanupCnt);
// no need for looping, we assume that the next update location from GPS will give accurate fix
quality = ArgUtils::Quality();
iProxy->CallL(ENetMsgProcessLocationRequest, &iSessionId, &emergency, &service, &quality, &method);
// RequestAssistanceData(0)
TESTL(iProxy->WaitForResponse(KSmallTimeOut) == ENetMsgRequestAssistanceData);
cleanupCnt = iProxy->GetArgsLC(ENetMsgRequestAssistanceData, &dataGroup);
TESTL(dataGroup == EAssistanceDataNone);
CleanupStack::PopAndDestroy(cleanupCnt);
// GPS positions meets required accuracy. This is sent immediately to protocol module
// The ini file should contain accurate gps fix for this test case to work
TESTL(iProxy->WaitForResponse(KTTimeout) == ENetMsgRespondLocationRequest);
getSessionId = NULL;
getReason = KErrNone;
getPositionInfo = NULL;
cleanupCnt = iProxy->GetArgsLC(ENetMsgRespondLocationRequest, &getSessionId, &getReason, &getPositionInfo);
TESTL(getSessionId->SessionNum() == iSessionId.SessionNum());
TESTL(getReason == KErrNone);
// Test position is the same as in the ini file data fed to the GPS module
// $update,1,2,51.5015,-0.105,50,2,3*
TPosition gpsPos;
getPositionInfo->GetPosition(gpsPos);
TESTL(gpsPos.Latitude()==51.5015 && gpsPos.Longitude()==-0.105 && gpsPos.Altitude()==50 && gpsPos.HorizontalAccuracy()==2 && gpsPos.VerticalAccuracy()==3);
CleanupStack::PopAndDestroy(cleanupCnt);
// Network Result Notification Start
// ProcessLocationUpdate()
//Final Network Position is the GPS position
TPositionInfo gpsPosInfo;
gpsPosInfo.SetPosition(gpsPos);
gpsPosInfo.SetUpdateType(EPositionUpdateGeneral);
gpsPosInfo.SetPositionMode(TPositionModuleInfo::ETechnologyNetwork | TPositionModuleInfo::ETechnologyAssisted);
gpsPosInfo.SetPositionModeReason(EPositionModeReasonNone);
iProxy->CallL(ENetMsgProcessLocationUpdate, &iSessionId, &gpsPosInfo);
// Network Result Notification Stop
// Session Complete Start
reason = KErrNone;
iProxy->CallL(ENetMsgProcessSessionComplete, &iSessionId, &reason);
MLbsNetworkProtocolObserver::TLbsNetProtocolServiceMask activeServiceMask = MLbsNetworkProtocolObserver::EServiceNone;
iProxy->CallL(ENetMsgProcessStatusUpdate, &activeServiceMask);
// Session Complete Stop
// the REF position request has completed, so now, after injecting the FNP and Session Complete
// we expect that the other request to complete with KErrNone
User::WaitForRequest(transPosStatus);
TESTL(transPosStatus==KErrNone);
return TestStepResult();
}