void RMmCustomAPI::FillFDDSpecificFrequencyMode(TMmCellInfo::TCellMeasuredResult& aCellMeasuredResult,TInt aOption,TInt aReadIndex)
{
TMmCellInfo::TFddInfo fddInfo;
if(aOption == 0)
{
fddInfo.iPrimaryCPICH = KPrimaryCPICH;
fddInfo.iCpichEcN0 = KCpichEcN0;
fddInfo.iCichRscp = KCichRscp;
fddInfo.iPathloss = KPathloss;
#ifdef _READ_FROM_FILE_
fddInfo.iPrimaryCPICH = GetParameterValue(22,aReadIndex);
fddInfo.iCpichEcN0 = GetParameterValue(23,aReadIndex);
fddInfo.iCichRscp = GetParameterValue(24,aReadIndex);
fddInfo.iPathloss = GetParameterValue(25,aReadIndex);
#endif
}
else
{
fddInfo.iPrimaryCPICH = -1;
fddInfo.iCpichEcN0 = -1;
fddInfo.iCichRscp = -1;
fddInfo.iPathloss = -1;
}
aCellMeasuredResult.iFddInfo = fddInfo;
}
void UParticleModuleParameterDynamic::SpawnEx(FParticleEmitterInstance* Owner, int32 Offset, float SpawnTime, struct FRandomStream* InRandomStream, FBaseParticle* ParticleBase)
{
SPAWN_INIT;
{
PARTICLE_ELEMENT(FEmitterDynamicParameterPayload, DynamicPayload);
DynamicPayload.DynamicParameterValue[0] = GetParameterValue(DynamicParams[0], Particle, Owner, InRandomStream);
DynamicPayload.DynamicParameterValue[1] = GetParameterValue(DynamicParams[1], Particle, Owner, InRandomStream);
DynamicPayload.DynamicParameterValue[2] = GetParameterValue(DynamicParams[2], Particle, Owner, InRandomStream);
DynamicPayload.DynamicParameterValue[3] = GetParameterValue(DynamicParams[3], Particle, Owner, InRandomStream);
}
}
RMmCustomAPI::TMmCellInfo::TNmr RMmCustomAPI::GetTNmr()
{
RMmCustomAPI::TMmCellInfo::TNmr tNmr;
tNmr.iARFCN = iInitialTNmr;
tNmr.iBSIC = iInitialTNmr;
tNmr.RxLEV = iInitialTNmr;
iInitialTNmr++;
#ifdef _READ_FROM_FILE_
tNmr.iARFCN = GetParameterValue(6,iInitialTNmr);
tNmr.iBSIC = GetParameterValue(7,iInitialTNmr);
tNmr.RxLEV = GetParameterValue(8,iInitialTNmr);
#endif
return tNmr;
}
void RMmCustomAPI::ConstructL()
{
iFileError = iFs.Connect();
iRTimer.CreateLocal();
iSUPLNwMode = ESUPLWCDMA;
#ifdef _READ_FROM_FILE_
iSUPLNwMode = (TSUPLNwMode)GetParameterValue(1);
#endif
iInitialTNmr = 0;
iSUPLFrequecyMode = EFDD;
iSUPLFrequecyMode = ETDD;
#ifdef _READ_FROM_FILE_
iSUPLFrequecyMode = (TSUPLFrequecyMode)GetParameterValue(16);
#endif
iNoOfCells = GetParameterValue(2);
}
void RMmCustomAPI::FillTDDSpecificFrequencyMode(TMmCellInfo::TCellMeasuredResult& aCellMeasuredResult,TInt aOption,TInt aReadIndex)
{
TMmCellInfo::TTddInfo tddInfo;
if(aOption == 0)
{
tddInfo.iCellParamID = KCellParamID;
tddInfo.iProposedTGSN= KProposedTGSN;
tddInfo.iPrimaryCcpchRscp = KPrimaryCcpchRscp;
tddInfo.iPathloss = KPathloss;
tddInfo.iProposedTGSN= -1;
tddInfo.iPrimaryCcpchRscp = -1;
tddInfo.iPathloss = -1;
#ifdef _READ_FROM_FILE_
tddInfo.iCellParamID = GetParameterValue(26,aReadIndex);
tddInfo.iProposedTGSN= GetParameterValue(27,aReadIndex);
tddInfo.iPrimaryCcpchRscp = GetParameterValue(28,aReadIndex);
tddInfo.iPathloss = GetParameterValue(29,aReadIndex);
#endif
for(TInt i = 0;i < KMaxTimeSlotIscpAmount; i++ )
{
#ifdef _READ_FROM_FILE_
tddInfo.iTimeslotISCP[ i ] = GetParameterValue(30,i+1);
#endif
}
}
else
{
tddInfo.iCellParamID = -1;
tddInfo.iProposedTGSN= -1;
tddInfo.iPrimaryCcpchRscp = -1;
tddInfo.iPathloss = -1;
for(TInt i = 0;i < KMaxTimeSlotIscpAmount; i++ )
{
tddInfo.iTimeslotISCP[ i ] = -1;
}
}
aCellMeasuredResult.iTddInfo = tddInfo;
}
void RMmCustomAPI::FillFrequencyMode(TMmCellInfo::TFrequencyInfo& aFrequencyInfo,TInt aUsedFor,TInt aInnerOuter)
{
if( iSUPLFrequecyMode == EFDD)
{
aFrequencyInfo.iFddUL = KFddUL; // 0..16383 In case of fdd( iFddUL, iFddDL),
aFrequencyInfo.iFddUL = -1;
aFrequencyInfo.iFddDL = KFddDL; // 0..16383 iFddUL is optional while iFddDL is mandatory.
#ifdef _READ_FROM_FILE_
if(aInnerOuter == 0)
{
aFrequencyInfo.iFddUL = GetParameterValue(12,aUsedFor);
aFrequencyInfo.iFddDL = GetParameterValue(13,aUsedFor);
}
else
{
aFrequencyInfo.iFddUL = GetParameterValue(17,aUsedFor);
aFrequencyInfo.iFddDL = GetParameterValue(18,aUsedFor);
}
#endif
}
else
{
aFrequencyInfo.iTddNt = KTddDt; // 0..16383
aFrequencyInfo.iFddUL = -1;
aFrequencyInfo.iFddDL = -1;
#ifdef _READ_FROM_FILE_
if(aInnerOuter == 0)
aFrequencyInfo.iTddNt = GetParameterValue(14,aUsedFor);
else
aFrequencyInfo.iTddNt = GetParameterValue(19,aUsedFor);
#endif
}
}
void RMmCustomAPI::FillMeasureRequestList(TMmCellInfo::TWCDMACellInfo& aWcdmaCellInfo)
{
// for(TInt i = 0; i < KMaxFrequency; i++)
iTotalCellCount = 1;
iCellMeasuredResults = GetParameterValue(3);
iCount = 1;
for(TInt i = 0; i < iNoOfCells; i++)
{
aWcdmaCellInfo.iNwkMeasureReport[i] = GetMeasureRequest((i + 1) * iCount);
iCount++;
}
}
void RMmCustomAPI::FillGSMCellInfo ( TMmCellInfo& aCellInfo )
{
aCellInfo.iGsmCellInfo.iTA = KTA;
#ifdef _READ_FROM_FILE_
aCellInfo.iGsmCellInfo.iTA = GetParameterValue(9);
#endif
iInitialTNmr = 0;
for(TInt i = 0; i < KMaxNmrAmount; i++)
{
aCellInfo.iGsmCellInfo.iNmr[i] = GetTNmr();
}
aCellInfo.iMode = TMmCellInfo::EGSM;
}
void RMmCustomAPI::FillWCDMACellInfo ( TMmCellInfo& aCellInfo )
{
TMmCellInfo::TWCDMACellInfo wcdmaCellInfo;
TMmCellInfo::TFrequencyInfo frequencyInfo;
FillMeasureRequestList(wcdmaCellInfo);
FillFrequencyMode(frequencyInfo,1,0); // 0 means Freq info used for wcdmaCellInfo struct
aCellInfo.iMode = TMmCellInfo::EWCDMA;
wcdmaCellInfo.iPrimaryScrambilingCode = KPrimaryScrambilingCode;
#ifdef _READ_FROM_FILE_
wcdmaCellInfo.iPrimaryScrambilingCode = GetParameterValue(15);
#endif
wcdmaCellInfo.iFrequencyInfo = frequencyInfo;
aCellInfo.iWcdmaCellInfo = wcdmaCellInfo;
}
RMmCustomAPI::TMmCellInfo::TNetworkMeasureReport RMmCustomAPI::GetMeasureRequest(TInt /*i*/)
{
TMmCellInfo::TNetworkMeasureReport measureReport;
TMmCellInfo::TFrequencyInfo frequencyInfo;
FillFrequencyMode(frequencyInfo,iCount,1);// 1 means Freq info used for MeasuredResults struct
measureReport.iCarrierRSSI = KCarrierRSSI;
measureReport.iCarrierRSSI = -1;
#ifdef _READ_FROM_FILE_
measureReport.iCarrierRSSI = GetParameterValue(20,iCount);
#endif
measureReport.iFrequencyInfo = frequencyInfo;
FillCellMeasuredResultsList(measureReport);
return measureReport;
}
void dynModuleExecutionImpl::GetAllParameters()
{
std::vector<ModuleParameterGroup>::iterator itGroup;
itGroup = m_Module->GetParameterGroups().begin();
while (itGroup != m_Module->GetParameterGroups().end())
{
std::vector<ModuleParameter>::iterator itParam;
itParam = itGroup->GetParameters().begin();
while (itParam != itGroup->GetParameters().end())
{
GetParameterValue( &(*itParam) );
++itParam;
}
++itGroup;
}
}
status_t
ESDSinkNode::GetConfigurationFor(BMessage * into_message)
{
CALLED();
BParameter *parameter = NULL;
void *buffer;
size_t size = 128;
bigtime_t last_change;
status_t err;
if (!into_message)
return B_BAD_VALUE;
buffer = malloc(size);
for(int32 i=0; i<fWeb->CountParameters(); i++) {
parameter = fWeb->ParameterAt(i);
if(parameter->Type() != BParameter::B_CONTINUOUS_PARAMETER
&& parameter->Type() != BParameter::B_DISCRETE_PARAMETER)
continue;
PRINT(("getting parameter %li\n", parameter->ID()));
size = 128;
while((err = GetParameterValue(parameter->ID(), &last_change, buffer, &size))==B_NO_MEMORY) {
size += 128;
free(buffer);
buffer = malloc(size);
}
if(err == B_OK && size > 0) {
into_message->AddInt32("parameterID", parameter->ID());
into_message->AddData("parameterData", B_RAW_TYPE, buffer, size, false);
} else {
PRINT(("parameter %li err : %s\n", parameter->ID(), strerror(err)));
}
}
//PRINT_OBJECT(*into_message);
return B_OK;
}
RMmCustomAPI::TMmCellInfo::TCellMeasuredResult RMmCustomAPI::GetCellMeasuredResults(TInt aReadIndex)
{
TMmCellInfo::TCellMeasuredResult cellMeasuredResult;
cellMeasuredResult.iCID = KMeasuredCID;
#ifdef _READ_FROM_FILE_
cellMeasuredResult.iCID = GetParameterValue(21,aReadIndex);
#endif
if( iSUPLFrequecyMode == EFDD)
{
FillFDDSpecificFrequencyMode(cellMeasuredResult,0,aReadIndex);
FillTDDSpecificFrequencyMode(cellMeasuredResult,-1,aReadIndex);
}
else
{
FillTDDSpecificFrequencyMode(cellMeasuredResult,0,aReadIndex);
FillFDDSpecificFrequencyMode(cellMeasuredResult,-1,aReadIndex);
}
return cellMeasuredResult;
}
void UParticleModuleParameterDynamic::Update(FParticleEmitterInstance* Owner, int32 Offset, float DeltaTime)
{
if (UpdateFlags == EDPU_UPDATE_NONE)
{
// Nothing to do here - they are all spawntime only
return;
}
if ((Owner == NULL) || (Owner->ActiveParticles <= 0) ||
(Owner->ParticleData == NULL) || (Owner->ParticleIndices == NULL))
{
return;
}
//
int32 ParameterIndex = ParticleDynamicParameter_GetIndexFromFlag(UpdateFlags);
FPlatformMisc::Prefetch(Owner->ParticleData, (Owner->ParticleIndices[0] * Owner->ParticleStride));
FPlatformMisc::Prefetch(Owner->ParticleData, (Owner->ParticleIndices[0] * Owner->ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
switch (UpdateFlags)
{
case EDPU_UPDATE_0:
case EDPU_UPDATE_1:
case EDPU_UPDATE_2:
case EDPU_UPDATE_3:
{
// Only one parameter is updating...
check(ParameterIndex != INDEX_NONE);
FEmitterDynamicParameter& DynParam = DynamicParams[ParameterIndex];
if (bUsesVelocity == false)
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[ParameterIndex] = GetParameterValue_UserSet(DynParam, Particle, Owner, NULL);
}
END_UPDATE_LOOP;
}
else
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[ParameterIndex] = GetParameterValue(DynParam, Particle, Owner, NULL);
}
END_UPDATE_LOOP;
}
}
break;
case EDPU_UPDATE_01:
{
// Just 0 and 1 need to be updated...
FEmitterDynamicParameter& DynParam0 = DynamicParams[0];
FEmitterDynamicParameter& DynParam1 = DynamicParams[1];
if (bUsesVelocity == false)
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[0] = GetParameterValue_UserSet(DynParam0, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[1] = GetParameterValue_UserSet(DynParam1, Particle, Owner, NULL);
}
END_UPDATE_LOOP;
}
else
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[0] = GetParameterValue(DynParam0, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[1] = GetParameterValue(DynParam1, Particle, Owner, NULL);
}
END_UPDATE_LOOP;
}
}
break;
case EDPU_UPDATE_012:
{
// Just 0, 1 and 2 need to be updated...
FEmitterDynamicParameter& DynParam0 = DynamicParams[0];
FEmitterDynamicParameter& DynParam1 = DynamicParams[1];
FEmitterDynamicParameter& DynParam2 = DynamicParams[2];
if (bUsesVelocity == false)
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[0] = GetParameterValue_UserSet(DynParam0, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[1] = GetParameterValue_UserSet(DynParam1, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[2] = GetParameterValue_UserSet(DynParam2, Particle, Owner, NULL);
}
END_UPDATE_LOOP;
}
else
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[0] = GetParameterValue(DynParam0, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[1] = GetParameterValue(DynParam1, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[2] = GetParameterValue(DynParam2, Particle, Owner, NULL);
}
END_UPDATE_LOOP;
}
}
break;
case EDPU_UPDATE_ALL:
{
FEmitterDynamicParameter& DynParam0 = DynamicParams[0];
FEmitterDynamicParameter& DynParam1 = DynamicParams[1];
FEmitterDynamicParameter& DynParam2 = DynamicParams[2];
FEmitterDynamicParameter& DynParam3 = DynamicParams[3];
if (bUsesVelocity == false)
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[0] = GetParameterValue_UserSet(DynParam0, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[1] = GetParameterValue_UserSet(DynParam1, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[2] = GetParameterValue_UserSet(DynParam2, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[3] = GetParameterValue_UserSet(DynParam3, Particle, Owner, NULL);
}
END_UPDATE_LOOP;
}
else
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[0] = GetParameterValue(DynParam0, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[1] = GetParameterValue(DynParam1, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[2] = GetParameterValue(DynParam2, Particle, Owner, NULL);
DynamicPayload.DynamicParameterValue[3] = GetParameterValue(DynParam3, Particle, Owner, NULL);
}
END_UPDATE_LOOP;
}
}
break;
default:
{
FEmitterDynamicParameter& DynParam0 = DynamicParams[0];
FEmitterDynamicParameter& DynParam1 = DynamicParams[1];
FEmitterDynamicParameter& DynParam2 = DynamicParams[2];
FEmitterDynamicParameter& DynParam3 = DynamicParams[3];
if (bUsesVelocity == false)
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[0] = (UpdateFlags & EDPU_UPDATE_0) ? GetParameterValue_UserSet(DynParam0, Particle, Owner, NULL) : DynamicPayload.DynamicParameterValue[0];
DynamicPayload.DynamicParameterValue[1] = (UpdateFlags & EDPU_UPDATE_1) ? GetParameterValue_UserSet(DynParam1, Particle, Owner, NULL) : DynamicPayload.DynamicParameterValue[1];
DynamicPayload.DynamicParameterValue[2] = (UpdateFlags & EDPU_UPDATE_2) ? GetParameterValue_UserSet(DynParam2, Particle, Owner, NULL) : DynamicPayload.DynamicParameterValue[2];
DynamicPayload.DynamicParameterValue[3] = (UpdateFlags & EDPU_UPDATE_3) ? GetParameterValue_UserSet(DynParam3, Particle, Owner, NULL) : DynamicPayload.DynamicParameterValue[3];
}
END_UPDATE_LOOP;
}
else
{
BEGIN_UPDATE_LOOP;
{
FEmitterDynamicParameterPayload& DynamicPayload = *((FEmitterDynamicParameterPayload*)(ParticleBase + CurrentOffset));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride));
FPlatformMisc::Prefetch(ParticleData, (ParticleIndices[i+1] * ParticleStride) + PLATFORM_CACHE_LINE_SIZE);
DynamicPayload.DynamicParameterValue[0] = (UpdateFlags & EDPU_UPDATE_0) ? GetParameterValue(DynParam0, Particle, Owner, NULL) : DynamicPayload.DynamicParameterValue[0];
DynamicPayload.DynamicParameterValue[1] = (UpdateFlags & EDPU_UPDATE_1) ? GetParameterValue(DynParam1, Particle, Owner, NULL) : DynamicPayload.DynamicParameterValue[1];
DynamicPayload.DynamicParameterValue[2] = (UpdateFlags & EDPU_UPDATE_2) ? GetParameterValue(DynParam2, Particle, Owner, NULL) : DynamicPayload.DynamicParameterValue[2];
DynamicPayload.DynamicParameterValue[3] = (UpdateFlags & EDPU_UPDATE_3) ? GetParameterValue(DynParam3, Particle, Owner, NULL) : DynamicPayload.DynamicParameterValue[3];
}
END_UPDATE_LOOP;
}
}
break;
}
}
const char* csTerrainModifiableDataFeederProperties::GetParameterValue (size_t index)
{ return GetParameterValue (GetParameterName (index)); }
