void DFO_XYArrayToTable:: DoStatusChk()
{
FuncObjC::DoStatusChk();
CheckInputFO(inputXYArrayObjRef, "input XY");
if (interpolateToCommonX)
CheckInputFO(interpolateToCommonXObjRef, "interpolate input XY");
}
void DFO_RealToVariableArray:: DoStatusChk()
{
outputVarDO.Reset("Combined reals");
// base class check
FuncObjC::DoStatusChk();
// check input objects
nrealSel = 0;
for (int i = 0; i < maxRealSel; i++)
if (realSelData[i].doReal)
{
if (IsNull(realSelData[i].realID))
SetObjErrMsg("variable ID not set for real");
if (!CheckInputFO(realSelData[i].realObjRef, "Real"))
return;
DO_Real* tmpDO = static_cast<DO_Real*>(GetInPortData(realSelData[i].realObjRef));
realSelData[i].realDataDO = tmpDO;
nrealSel++;
}
if (nrealSel == 0)
{
SetObjErrMsg("no reals selected");
return;
}
}
void UncertInput::DoStatusChk()
{
for (int i = 0; i < maxMetricSel; i++)
inputMetrics[i].useMetric = (!SampleControlStatics::IsMonteCarlo() && inputMetrics[i].uncertOnMetric);
int numMetrics = GetNMetrics();
if (numMetrics < 1)
SetObjErrMsg("no metrics selected ???");
/*MetricSelection& currMetric = inputMetrics[currSelectedMetric];
if (!currMetric.uncertOnMetric)
SetObjErrMsg("current metric not selected ???");*/
FuncObjC::DoStatusChk();
for (int i = 0; i < maxMetricSel; i++)
{
if (!inputMetrics[i].useMetric)
continue;
if (!CheckInputFO(inputMetrics[i].metricObject, "Selected metric"))
{
if (!inputMetrics[i].metricObject.IsNull())
{
char errMsg[255];
MakeString(errMsg, "SelMetricErr:", inputMetrics[i].metricObject.objRef->GetID(), ":", inputMetrics[i].metricObject.objRef->GetStatusMsg(), 255);
SetObjErrMsg(errMsg);
}
}
}
lastMetricVal.Alloc(numMetrics);
}
void DFO_CalcConfidenceGrid:: DoStatusChk()
{
FuncObjC::DoStatusChk();
if (!CheckInputFO(inputGridResultsObjRef, "test grid input source"))
return;
inputGridResultsDC = static_cast<DO_GridData*>(GetInPortData(inputGridResultsObjRef))->gridData;
if (inputGridResultsDC->IsEmpty())
{
SetObjErrMsg("no output ???");
return;
}
if (!autoBestCase)
{
if ((bestCaseXIndex < 0) || (bestCaseXIndex >= inputGridResultsDC->xData.Size()))
{
SetObjErrMsg("best fit case X index out of range");
return;
}
if ((bestCaseYIndex < 0) || (bestCaseYIndex >= inputGridResultsDC->yData.Size()))
{
SetObjErrMsg("best fit case Y index out of range");
return;
}
}
}
void DFO_SingleFit::DoAllocCheck()
{
if (CheckInputFO(fieldDataObjRef, "field data source"))
{
inputXY = static_cast<DO_XYData*>(GetInPortData(fieldDataObjRef))->xyData;
if (limitInput)
{
fieldDataDC = &limitedXY;
}
else
{
fieldDataDC = inputXY;
}
// allocation is OK as long as input is set
fitResultsDC.nfitAlloc = inputXY->Size();
//fitResultsDC.okToAlloc = (fitResultsDC.nfitAlloc > 2);
fitResultsDC.okToAlloc = (fitResultsDC.nfitAlloc > 0);
}
/* else
{
if (fieldDataObjRef.objRef != 0)
{
char debugMsg[120];
MakeString(debugMsg, "DfO_SingleFit ****", fieldDataObjRef.objRef->GetID(), "::", fieldDataObjRef.objRef->GetStatusMsg(), 120);
SetObjErrMsg(debugMsg);
}
}
*/
}
void DFO_TableTranspose:: DoStatusChk()
{
FuncObjC::DoStatusChk();
if (CheckInputFO(inputTableObjRef, "table input data source"))
{
inputTableDC = static_cast<DO_TableData*>(GetInPortData(inputTableObjRef))->tableData;
ninputRows = inputTableDC->GetNRows();
ninputCols = inputTableDC->GetNCols();
if ((ninputCols < 1) || (ninputRows < 1))
SetObjErrMsg("No input table columns or rows");
if ((ninputRows < 2) && (ninputCols < 2))
SetObjErrMsg("table must have more than 1 entry");
if (skipXColumn)
{
if (xcolumnIndex >= ninputCols)
SetObjErrMsg("X column index out of range");
if (ninputCols == 1)
SetObjErrMsg("no data after X column is removed");
}
}
}
void DFO_Derivative:: DoStatusChk()
{
// set flags for data to use
*useDerivativeCheckRef = isMaster && derivativeDC.useSuperTime;
*windowPctSpanCheckRef = isMaster &&
((derivativeDC.derivativeCalcType == dctLogPctWindow) ||
(derivativeDC.derivativeCalcType == dctLinPctWindow));
*windowValSpanCheckRef = isMaster &&
((derivativeDC.derivativeCalcType == dctLogValWindow) ||
(derivativeDC.derivativeCalcType == dctLinValWindow));
FuncObjC::DoStatusChk();
outputTPDC.SetID("derivative");
if (CheckInputFO(inputTPObjRef, "Input P(t)"))
tpDataDC = static_cast<DO_XYData*>(GetInPortData(inputTPObjRef))->xyData;
derivativeDO.timeProcess = 0;
if ((!isMaster) && (CheckInputFO(masterObjRef, "Master spec")))
{
DO_Derivative* inputDO = static_cast<DO_Derivative*>(GetInPortData(masterObjRef));
derivativeDC = *(inputDO->derivative);
windowPctSpanMS.enteredRealValue = derivativeDC.windowPctSpan;
windowValSpanMS.enteredRealValue = derivativeDC.windowValSpan;
derivativeDO.timeProcess = inputDO->timeProcess;
}
if (isMaster)
{
// get data
if (derivativeDC.useSuperTime && CheckInputFO(timeProcessObjRef, "Input time process"))
derivativeDO.timeProcess = static_cast<DO_TimeProcess*>(GetInPortData(timeProcessObjRef))->timeProcess;
if (*windowPctSpanCheckRef)
{
windowPctSpanMS.DoCheck("Window % lin/log span", *this);
derivativeDC.windowPctSpan = windowPctSpanMS.GetLimitedValue(1.0, 85.0);
}
if (*windowValSpanCheckRef)
{
windowValSpanMS.DoCheck("Window val lin/log span", *this);
derivativeDC.windowValSpan = windowValSpanMS.GetLimitedValue(0.001, 1000.0);
}
}
}
void DFO_ExtractSequenceInterval:: DoStatusChk()
{
*endCheckRef = setStartAndEnd;
FuncObjC::DoStatusChk();
startSeqMS.SetTypeLabel("Start sequence");
endSeqMS.SetTypeLabel("End sequence");
xyOutputData.SetID("sequence");
// check input objects
CheckInputFO(xyInputDataObjRef, "XY data source");
CheckInputFO(seqTimesObjRef, "Sequence time data source");
startSeqMS.DoCheck("Start sequence", *this);
if (setStartAndEnd)
endSeqMS.DoCheck("End sequence", *this);
if (StatusNotOK())
return;
xyInputDataDC = static_cast<DO_XYData*>(GetInPortData(xyInputDataObjRef))->xyData;
sequenceTimesDC = static_cast<DO_SequenceTimes*>(GetInPortData(seqTimesObjRef))->seqTimes;
startSeq = startSeqMS.GetCurrentIndex();
if (setStartAndEnd)
{
endSeq = endSeqMS.GetCurrentIndex();
if (endSeq < startSeq)
{
int tmp = startSeq;
startSeq = endSeq;
endSeq = tmp;
}
}
else
endSeq = startSeq;
int maxSeq = sequenceTimesDC->Size();
if ((startSeq < 0) || (endSeq >= sequenceTimesDC->Size()))
SetObjErrMsg("Sequence out of range");
}
void PFO_2DTableHistogram:: DoStatusChk()
{
objTableData = 0;
// base class check
PlotObjC::DoStatusChk();
// check input objects
if (!CheckInputFO(tableDataObjRef, "Table Data"))
return;
objTableData = ((DO_TableData*) GetInPortData(tableDataObjRef))->tableData;
// check parameters
int maxCol = objTableData->GetNCols();
if (xDataIndx >= maxCol)
SetObjErrMsg("X index out of range for current table");
int nSeries = 0;
for ( int i = 0; i < maxTableHistogram; i++)
if (seriesData[i].doHistogram && (seriesData[i].tableColIndx < maxCol))
nSeries++;
if (nSeries == 0)
SetObjErrMsg("no series set to plot");
// set up output
seriesLegendData.Clear();
if (nSeries > 0)
{
seriesLegendData.Alloc(nSeries);
// for (int i = 0; i < maxTableHistogram; i++)
// if (seriesData[i].doHistogram && (seriesData[i].tableColIndx < maxCol))
// seriesLegendData.AddSeries(seriesData[i].GetLabel(
// objTableData->columnDesc[seriesData[i].tableColIndx]),
// seriesData[i]);
}
if (cursorReport != 0)
recalcOnViewChange = cursorReport->showReport;
/*
startRow = 0;
if (!plotAllRows)
{
if (lastNRows <1 )
SetObjErrMsg("at least one row must be plotted");
startRow = objTableData->dataTable[xDataIndx].Size() - lastNRows;
if (startRow < 0)
startRow = 0;
}
*/
}
void DFO_BlendColorMap:: DoStatusChk()
{
blendColorMap.ncolorMap = 0;
FuncObjC::DoStatusChk();
tValMS.Reset("Blend T value");
tValMS.DoCheck("Blend T value master", *this);
// get data
if ((! CheckInputFO(input1ObjRef, "Color map A")) ||
(! CheckInputFO(input2ObjRef, "Color map B")))
return;
colorMap1 = static_cast<DO_ColorMap*>(GetInPortData(input1ObjRef))->colorMapData;
colorMap2 = static_cast<DO_ColorMap*>(GetInPortData(input2ObjRef))->colorMapData;
if (colorMap1->ncolorMap != colorMap2->ncolorMap)
{
SetObjErrMsg("Both input color maps must be the same size");
return;
}
blendColorMap.AddColorMaps(*colorMap1, *colorMap2);
}
void DFO_SelectVariable:: DoStatusChk()
{
DFO_SelectBase::DoStatusChk();
indexMS.SetTypeLabel("Selected Variable");
if (!CheckInputFO(varDataArrayObjRef, "Data source"))
return;
varDataDO = static_cast<DO_VariableArray*>(GetInPortData(varDataArrayObjRef));
if (IndexRangeOK(varDataDO->variableArrayData->Size()))
{
indexMS.indexDO.SetValueLabel((*varDataDO->variableArrayData)[indexMS.GetCurrentIndex()].varID);
}
}
void PlotDefC:: DoStatusChk()
{
FuncObjC::DoStatusChk();
if (plotPenSetObjRef.objRef == 0)
plotPenSetObjRef.SetDefault(typeid(DO_PenSet));
if (CheckInputFO(plotPenSetObjRef, "Pen set"))
{
defaultPenSetDO = *((DO_PenSet*) GetInPortData(plotPenSetObjRef));
defaultPenSet = defaultPenSetDO.penSetData;
}
else
{
defaultPenSet = 0;
defaultPenSetDO = DO_PenSet();
}
}
void CaptureOutputFO::DoStatusChk()
{
xyDataDO.xyData = 0;
FuncObjC::DoStatusChk();
if (!CheckInputFO(xyArrayObjRef, "Input array"))
return;
DO_XYDataArray* dataDO = static_cast<DO_XYDataArray*>(GetInPortData(xyArrayObjRef));
if (dataDO->xyDataArray->IsEmpty())
{
SetObjErrMsg("no entries in input array ??");
return;
}
if (dcIndex > dataDO->xyDataArray->UpperBound())
dcIndex = 0;
xyDataDO.xyData = &(*dataDO->xyDataArray)[dcIndex];
}
void PFO_GridContour::DoStatusChk()
{
contourLines.DeAlloc();
PSC_3DGridData::StatusChkSetup(*this);
PlotObjC::DoStatusChk();
PSC_ContourSpec::DoStatusChk(*this);
CheckInputFO(dataObjRef, "Grid Data");
if (StatusNotOK())
return;
gridData = static_cast<DO_GridData*> (GetInPortData(dataObjRef))->gridData;
PSC_3DGridData::DoStatusChk(*this, *gridData);
// check and set triang
SC_Triangulation& currTri = gridData->GetTriangulation();
if (!currTri.TriangulationOK())
SetObjErrMsg("cannot triangulate ??");
}
void DFO_CreateXYArray:: DoStatusChk()
{
// check input objects
nSelected = 0;
for (int i = 0; i < maxXYDataDesc; i++)
if (xyData[i].doXY)
{
// we still build the array even if the input is not OK
if (CheckInputFO(xyData[i].xyObjRef, "XY"))
xyData[i].xyDataDC = static_cast<DO_XYData*>(GetInPortData(xyData[i].xyObjRef))->xyData;
else
xyData[i].xyDataDC = 0;
nSelected++;
}
// slight kluge -- reset status to clear any errors from XY check
// base class check
FuncObjC::DoStatusChk();
// only error ...
if (nSelected == 0)
SetObjErrMsg("no XY selected");
}
void PFO_CovarLimMatrix:: DoStatusChk()
{
// base class check
PFO_ColorBase::DoStatusChk();
if (!CheckInputFO(inputDataObjRef, "Covariance Data"))
return;
DO_CovarArray* objData = static_cast<DO_CovarArray*>(GetInPortData(inputDataObjRef));
covarArrayDC = objData->covarArrayData;
covarHeaderDC = objData->covarHeader;
maxCovar = covarArrayDC->Size();
if (plotWithColorMap)
{
if (!ColorAttributeIsDiag())
{
colorData.AllocAndSetSize(maxCovar);
for (int i = 0; i < maxCovar; i++)
{
if (colorAttribute == caIndx)
colorData[i] = double(i);
else if (colorAttribute == caSSE)
colorData[i] = (*covarArrayDC)[i].sumSquaredError;
}
if (limitIsMaster && autoLimits)
rangeLimit.InitLimit(colorData);
CheckRangeLimits();
}
if (colorAttribute == caIndx)
colorLimitDO.SetValueLabel("Index");
else if (colorAttribute == caSSE)
colorLimitDO.SetValueLabel("SSE");
else if (colorAttribute == caMainDiag)
colorLimitDO.SetValueLabel("Main Diagonal Length");
else if (colorAttribute == caOffDiag)
colorLimitDO.SetValueLabel("Off Diagonal Length");
}
bestEstSymbol.symbolPen = covarPen;
int num = 1;
if (plotEllipse && plotBestEst)
num = 2;
seriesLegendData.Alloc(num);
if (plotEllipse || plotBestEst)
{
PSC_SeriesSpec temp;
temp.seriesPen = covarPen;
//ellipse line legend
if (plotEllipse)
{
temp.seriesPlotType = psl_LineOnly;
temp.lineThickness = covarLineThk;
static const char* defStr[] = {"99.0% confidence limits",
"95.4% confidence limits",
"90.0% confidence limits",
"68.3% confidence limits"};
seriesLegendData.AddSeries(legendOverride.GetLabel(defStr[int(cLimits)]), temp);
}
if (plotBestEst)
{
//best estimate legend
temp.seriesPlotType = psl_SymbolOnly;
temp.symbolType = bestEstSymbol.symbolType;
temp.symbolSize = bestEstSymbol.symbolSize;
static const char* symStr = "best estimate";
seriesLegendData.AddSeries(legendOverride.GetLabel(symStr), temp);
}
}
else
seriesLegendData.Clear();
}
void UFO_WriteXY::DoStatusChk()
{
FuncObjC::DoStatusChk();
CheckInputFO(xyObjRef, "XY data");
mpiFiles.StdCheckAndUpdate(*this);
}
void PFO_Scatterplot:: DoStatusChk()
{
// base class check
PlotObjC::DoStatusChk();
// check input objects
if (!CheckInputFO(scatterDataObjRef, "Scatterplot data"))
return;
const DO_SAPlotTable* scatterDO = static_cast<DO_SAPlotTable*>(GetInPortData(scatterDataObjRef));
nplotDV = scatterDO->nDV;
nplotIV = scatterDO->nIV;
if ((nplotDV == 0) || (nplotIV == 0))
SetObjErrMsg("not a scatter data table (maybe grid lines?)");
else if (plotDVIndx >= nplotDV)
SetObjErrMsg("DV to plot out of range");
else if (plotIVIndx >= nplotIV)
SetObjErrMsg("IV to plot out of range");
if (StatusNotOK())
return;
scatterDataDC = scatterDO->tableData;
dvLabel = scatterDataDC->columnDesc[plotDVIndx + nplotIV];
ivLabel = scatterDataDC->columnDesc[plotIVIndx];
if (plotXGridLines)
{
if (!CheckInputFO(xgridLineObjRef, "X grid lines"))
return;
const DO_SAPlotTable* xgridDO = static_cast<DO_SAPlotTable*>(GetInPortData(xgridLineObjRef));
if (nplotIV != xgridDO->nIV)
SetObjErrMsg("X grid line incompatible with scatter data");
xGridLinesDC = xgridDO->tableData;
}
else
xGridLinesDC = 0;
if (plotYGridLines)
{
if (!CheckInputFO(ygridLineObjRef, "Y grid lines"))
return;
const DO_SAPlotTable* ygridDO = static_cast<DO_SAPlotTable*>(GetInPortData(ygridLineObjRef));
if ((nplotDV != ygridDO->nDV))
SetObjErrMsg("Y grid line incompatible with scatter data");
yGridLinesDC = ygridDO->tableData;
}
else
yGridLinesDC = 0;
seriesLegendData.Clear();
if (StatusNotOK())
return;
char legTitle[80];
MakeString(legTitle, dvLabel, "/", ivLabel, 80);
seriesLegendData.AddSeries(legTitle, scatterSpec);
}
