vector<ImportDescriptor*> SioImporter::getImportDescriptors(const string& filename)
{
vector<ImportDescriptor*> descriptors;
if (filename.empty() == false)
{
// Read the header values
FileResource pFile(filename.c_str(), "rb");
SioFile sioFile;
bool bSuccess = sioFile.deserialize(pFile.get());
if (bSuccess == false)
{
return descriptors;
}
if (sioFile.mOriginalVersion == 9)
{
mVersion9Sio = true;
}
// Create the import descriptor
ImportDescriptor* pImportDescriptor = mpModel->createImportDescriptor(filename, "RasterElement", NULL);
if (pImportDescriptor != NULL)
{
RasterDataDescriptor* pDescriptor =
dynamic_cast<RasterDataDescriptor*>(pImportDescriptor->getDataDescriptor());
if (pDescriptor != NULL)
{
FactoryResource<RasterFileDescriptor> pFileDescriptor;
if (pFileDescriptor.get() != NULL)
{
// Filename
pFileDescriptor->setFilename(filename);
// Endian
pFileDescriptor->setEndian(sioFile.mEndian);
// Rows
vector<DimensionDescriptor> rows;
for (int i = 0; i < sioFile.mRows; ++i)
{
DimensionDescriptor rowDim;
// Do not set an active number since the user has not selected the rows to load
if (static_cast<unsigned int>(i) < sioFile.mOrigRowNumbers.size())
{
rowDim.setOriginalNumber(sioFile.mOrigRowNumbers[i]);
}
else
{
rowDim.setOriginalNumber(i);
}
rowDim.setOnDiskNumber(i);
rows.push_back(rowDim);
}
pDescriptor->setRows(rows);
pFileDescriptor->setRows(rows);
// Columns
vector<DimensionDescriptor> columns;
for (int i = 0; i < sioFile.mColumns; ++i)
{
DimensionDescriptor columnDim;
// Do not set an active number since the user has not selected the rows to load
if (static_cast<unsigned int>(i) < sioFile.mOrigColumnNumbers.size())
{
columnDim.setOriginalNumber(sioFile.mOrigColumnNumbers[i]);
}
else
{
columnDim.setOriginalNumber(i);
}
columnDim.setOnDiskNumber(i);
columns.push_back(columnDim);
}
pDescriptor->setColumns(columns);
pFileDescriptor->setColumns(columns);
// Bands
vector<DimensionDescriptor> bands;
for (int i = 0; i < (sioFile.mBands - sioFile.mBadBands); ++i)
{
DimensionDescriptor bandDim;
// Do not set an active number since the user has not selected the rows to load
if (static_cast<unsigned int>(i) < sioFile.mOrigBandNumbers.size())
{
bandDim.setOriginalNumber(sioFile.mOrigBandNumbers[i]);
}
else
{
bandDim.setOriginalNumber(i);
}
bandDim.setOnDiskNumber(i);
bands.push_back(bandDim);
}
pDescriptor->setBands(bands);
pFileDescriptor->setBands(bands);
// Bits per pixel
pFileDescriptor->setBitsPerElement(sioFile.mBitsPerElement);
// Data type
pDescriptor->setDataType(sioFile.mDataType);
pDescriptor->setValidDataTypes(vector<EncodingType>(1, sioFile.mDataType));
// Interleave format
pDescriptor->setInterleaveFormat(BIP);
pFileDescriptor->setInterleaveFormat(BIP);
// Bad values
if (sioFile.mBadValues.empty() == true)
{
if ((sioFile.mDataType != FLT4BYTES) && (sioFile.mDataType != FLT8COMPLEX) &&
(sioFile.mDataType != FLT8BYTES))
{
vector<int> badValues;
badValues.push_back(0);
pDescriptor->setBadValues(badValues);
}
}
// Header bytes
pFileDescriptor->setHeaderBytes(28);
// Trailer bytes
struct stat statBuffer;
if (stat(filename.c_str(), &statBuffer) == 0)
{
double dataBytes = 28 + (sioFile.mRows * sioFile.mColumns * (sioFile.mBands - sioFile.mBadBands) *
(sioFile.mBitsPerElement / 8));
pFileDescriptor->setTrailerBytes(static_cast<unsigned int>(statBuffer.st_size - dataBytes));
}
// Units
FactoryResource<Units> pUnits;
pUnits->setUnitType(sioFile.mUnitType);
pUnits->setUnitName(sioFile.mUnitName);
pUnits->setRangeMin(sioFile.mRangeMin);
pUnits->setRangeMax(sioFile.mRangeMax);
pUnits->setScaleFromStandard(sioFile.mScale);
pDescriptor->setUnits(pUnits.get());
pFileDescriptor->setUnits(pUnits.get());
// GCPs
GcpPoint gcpLowerLeft;
gcpLowerLeft.mPixel.mX = 0.0;
gcpLowerLeft.mPixel.mY = 0.0;
GcpPoint gcpLowerRight;
gcpLowerRight.mPixel.mX = sioFile.mColumns - 1.0;
gcpLowerRight.mPixel.mY = 0.0;
GcpPoint gcpUpperLeft;
gcpUpperLeft.mPixel.mX = 0.0;
gcpUpperLeft.mPixel.mY = sioFile.mRows - 1.0;
GcpPoint gcpUpperRight;
gcpUpperRight.mPixel.mX = sioFile.mColumns - 1.0;
gcpUpperRight.mPixel.mY = sioFile.mRows - 1.0;
GcpPoint gcpCenter;
gcpCenter.mPixel.mX = sioFile.mColumns / 2.0 - 0.5;
gcpCenter.mPixel.mY = sioFile.mRows / 2.0 - 0.5;
bool bValidGcps = false;
for (int i = ORIGINAL_SENSOR; i < INVALID_LAST_ENUM_ITEM_FLAG; ++i)
{
if (sioFile.mParameters[i].eParameter_Initialized == true)
{
switch (i)
{
case UPPER_LEFT_CORNER_LAT:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpUpperLeft.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpUpperLeft.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case UPPER_LEFT_CORNER_LONG:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpUpperLeft.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpUpperLeft.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case LOWER_LEFT_CORNER_LAT:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpLowerLeft.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpLowerLeft.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case LOWER_LEFT_CORNER_LONG:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpLowerLeft.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpLowerLeft.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case UPPER_RIGHT_CORNER_LAT:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpUpperRight.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpUpperRight.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case UPPER_RIGHT_CORNER_LONG:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpUpperRight.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpUpperRight.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case LOWER_RIGHT_CORNER_LAT:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpLowerRight.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpLowerRight.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case LOWER_RIGHT_CORNER_LONG:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpLowerRight.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpLowerRight.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case CENTER_LAT:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpCenter.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpCenter.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
case CENTER_LONG:
if ((sioFile.mVersion == 5) || (sioFile.mVersion == 6))
{
gcpCenter.mCoordinate.mX = sioFile.mParameters[i].uParameter_Value.dData;
}
else if ((sioFile.mVersion == 7) || (sioFile.mVersion == 8))
{
gcpCenter.mCoordinate.mY = sioFile.mParameters[i].uParameter_Value.dData;
}
bValidGcps = true;
break;
default:
break;
}
}
}
if (bValidGcps == true)
{
list<GcpPoint> gcps;
gcps.push_back(gcpLowerLeft);
gcps.push_back(gcpLowerRight);
gcps.push_back(gcpUpperLeft);
gcps.push_back(gcpUpperRight);
gcps.push_back(gcpCenter);
pFileDescriptor->setGcps(gcps);
}
// Classification
pDescriptor->setClassification(sioFile.mpClassification.get());
// Metadata
pDescriptor->setMetadata(sioFile.mpMetadata.get());
DynamicObject* pMetadata = pDescriptor->getMetadata();
if (pMetadata != NULL)
{
vector<double> startWavelengths(sioFile.mStartWavelengths.size());
copy(sioFile.mStartWavelengths.begin(), sioFile.mStartWavelengths.end(), startWavelengths.begin());
vector<double> endWavelengths(sioFile.mEndWavelengths.size());
copy(sioFile.mEndWavelengths.begin(), sioFile.mEndWavelengths.end(), endWavelengths.begin());
vector<double> centerWavelengths(sioFile.mCenterWavelengths.size());
copy(sioFile.mCenterWavelengths.begin(), sioFile.mCenterWavelengths.end(), centerWavelengths.begin());
string pStartPath[] = { SPECIAL_METADATA_NAME, BAND_METADATA_NAME,
START_WAVELENGTHS_METADATA_NAME, END_METADATA_NAME };
pMetadata->setAttributeByPath(pStartPath, startWavelengths);
string pEndPath[] = { SPECIAL_METADATA_NAME, BAND_METADATA_NAME,
END_WAVELENGTHS_METADATA_NAME, END_METADATA_NAME };
pMetadata->setAttributeByPath(pEndPath, endWavelengths);
string pCenterPath[] = { SPECIAL_METADATA_NAME, BAND_METADATA_NAME,
CENTER_WAVELENGTHS_METADATA_NAME, END_METADATA_NAME };
pMetadata->setAttributeByPath(pCenterPath, centerWavelengths);
}
// File descriptor
pDescriptor->setFileDescriptor(pFileDescriptor.get());
}
}
descriptors.push_back(pImportDescriptor);
}
}
return descriptors;
}
void SpectralLibraryMatchResults::createAverageSignature()
{
Service<DesktopServices> pDesktop;
const RasterElement* pRaster = getRasterElementForCurrentPage();
if (pRaster == NULL)
{
pDesktop->showMessageBox("Spectral Library Match",
"Unable to determine the RasterElement for the current page.");
return;
}
std::vector<Signature*> signatures = getSelectedSignatures();
if (signatures.empty())
{
pDesktop->showMessageBox("Spectral Library Match",
"No signatures are selected for use in generating an average signature.");
return;
}
// now need to get the resampled sigs from the library
SpectralLibraryManager* pLibMgr(NULL);
std::vector<PlugIn*> plugIns =
Service<PlugInManagerServices>()->getPlugInInstances(SpectralLibraryMatch::getNameLibraryManagerPlugIn());
if (!plugIns.empty())
{
pLibMgr = dynamic_cast<SpectralLibraryManager*>(plugIns.front());
}
if (pLibMgr == NULL)
{
pDesktop->showMessageBox("Spectral Library Match",
"Unable to access the Spectral Library Manager.");
return;
}
const RasterDataDescriptor* pDesc = dynamic_cast<const RasterDataDescriptor*>(pRaster->getDataDescriptor());
if (pDesc == NULL)
{
pDesktop->showMessageBox("Spectral Library Match",
"Unable to access the RasterDataDescriptor for the RasterElement of the current page.");
return;
}
unsigned int numBands = pDesc->getBandCount();
std::vector<double> averageValues(numBands, 0);
std::vector<double> values;
for (std::vector<Signature*>::iterator it = signatures.begin(); it != signatures.end(); ++it)
{
if (pLibMgr->getResampledSignatureValues(pRaster, *it, values) == false)
{
pDesktop->showMessageBox("Spectral Library Match",
"Unable to access the resampled signature values for " + (*it)->getDisplayName(true));
return;
}
for (unsigned int band = 0; band < numBands; ++band)
{
averageValues[band] += values[band];
}
}
unsigned int numSigs = signatures.size();
for (unsigned int band = 0; band < numBands; ++band)
{
averageValues[band] /= static_cast<double>(numSigs);
}
QString avgName = QInputDialog::getText(pDesktop->getMainWidget(), "Spectral Library Match",
"Enter the name to use for the average signature:");
if (avgName.isEmpty())
{
return;
}
ModelResource<Signature> pAvgSig(avgName.toStdString(), const_cast<RasterElement*>(pRaster));
pAvgSig->setData("Reflectance", averageValues);
const DynamicObject* pMetaData = pRaster->getMetadata();
FactoryResource<Wavelengths> pWavelengths;
pWavelengths->initializeFromDynamicObject(pMetaData, false);
const std::vector<double>& centerValues = pWavelengths->getCenterValues();
pAvgSig->setData("Wavelength", centerValues);
SignatureDataDescriptor* pSigDesc = dynamic_cast<SignatureDataDescriptor*>(pAvgSig->getDataDescriptor());
VERIFYNRV(pSigDesc != NULL);
FactoryResource<Units> pUnits;
const Units* pRasterUnits = pDesc->getUnits();
pUnits->setUnitName(pRasterUnits->getUnitName());
pUnits->setUnitType(pRasterUnits->getUnitType());
pUnits->setScaleFromStandard(1.0); // the rescaled values are already corrected for the original scaling factor
pUnits->setRangeMin(pRasterUnits->getRangeMin());
pUnits->setRangeMax(pRasterUnits->getRangeMax());
pSigDesc->setUnits("Reflectance", pUnits.get());
pAvgSig.release();
}
bool EditDataDescriptor::execute(PlugInArgList* pInArgList, PlugInArgList* pOutArgList)
{
StepResource pStep("Execute Wizard Item", "app", "055486F4-A9DB-4FDA-9AA7-75D1917E2C87");
pStep->addProperty("Item", getName());
mpStep = pStep.get();
if (extractInputArgs(pInArgList) == false)
{
return false;
}
// Set the values in the data descriptor
VERIFY(mpDescriptor != NULL);
// File descriptor
if (mpFileDescriptor != NULL)
{
mpDescriptor->setFileDescriptor(mpFileDescriptor);
}
// Processing location
if (mpProcessingLocation != NULL)
{
mpDescriptor->setProcessingLocation(*mpProcessingLocation);
}
RasterDataDescriptor* pRasterDescriptor = dynamic_cast<RasterDataDescriptor*>(mpDescriptor);
RasterFileDescriptor* pRasterFileDescriptor = dynamic_cast<RasterFileDescriptor*>(mpFileDescriptor);
SignatureDataDescriptor* pSignatureDescriptor = dynamic_cast<SignatureDataDescriptor*>(mpDescriptor);
SignatureFileDescriptor* pSignatureFileDescriptor = dynamic_cast<SignatureFileDescriptor*>(mpFileDescriptor);
if (pRasterDescriptor != NULL)
{
if (pRasterFileDescriptor != NULL)
{
// Set the rows and columns to match the rows and columns in the file descriptor before creating the subset
const vector<DimensionDescriptor>& rows = pRasterFileDescriptor->getRows();
pRasterDescriptor->setRows(rows);
const vector<DimensionDescriptor>& columns = pRasterFileDescriptor->getColumns();
pRasterDescriptor->setColumns(columns);
const vector<DimensionDescriptor>& bands = pRasterFileDescriptor->getBands();
pRasterDescriptor->setBands(bands);
}
// Data type
if (mpDataType != NULL)
{
pRasterDescriptor->setDataType(*mpDataType);
}
// InterleaveFormat
if (mpInterleave != NULL)
{
pRasterDescriptor->setInterleaveFormat(*mpInterleave);
}
// Bad values
if (mpBadValues != NULL)
{
pRasterDescriptor->setBadValues(*mpBadValues);
}
// Rows
if ((mpStartRow != NULL) || (mpEndRow != NULL) || (mpRowSkipFactor != NULL))
{
// We need to obtain this origRows from the FileDescriptor if present since an importer
// may generate a subset by default in which case the DataDescriptor will not contain all
// the rows and subsetting will not work correctly. We
// can't just set mpFileDescriptor = pRasterDescriptor->getFileDescriptor() since we only
// want to replace the DataDescriptor's row list if one of the subset options is specified
const RasterFileDescriptor* pFileDesc(pRasterFileDescriptor);
if (pFileDesc == NULL)
{
pFileDesc = dynamic_cast<const RasterFileDescriptor*>(pRasterDescriptor->getFileDescriptor());
}
const vector<DimensionDescriptor>& origRows = (pFileDesc != NULL) ?
pFileDesc->getRows() : pRasterDescriptor->getRows();
unsigned int startRow = 0;
if (mpStartRow != NULL)
{
startRow = *mpStartRow;
}
else if (origRows.empty() == false)
{
startRow = origRows.front().getOriginalNumber() + 1;
}
unsigned int endRow = 0;
if (mpEndRow != NULL)
{
endRow = *mpEndRow;
}
else if (origRows.empty() == false)
{
endRow = origRows.back().getOriginalNumber() + 1;
}
unsigned int rowSkip = 0;
if (mpRowSkipFactor != NULL)
{
rowSkip = *mpRowSkipFactor;
}
vector<DimensionDescriptor> rows;
for (unsigned int i = 0; i < origRows.size(); ++i)
{
DimensionDescriptor rowDim = origRows[i];
unsigned int originalNumber = rowDim.getOriginalNumber() + 1;
if ((originalNumber >= startRow) && (originalNumber <= endRow))
{
rows.push_back(rowDim);
i += rowSkip;
}
}
pRasterDescriptor->setRows(rows);
}
// Columns
if ((mpStartColumn != NULL) || (mpEndColumn != NULL) || (mpColumnSkipFactor != NULL))
{
// We need to obtain this origColumns from the FileDescriptor if present since an importer
// may generate a subset by default in which case the DataDescriptor will not contain all
// the columns and subsetting will not work correctly. We
// can't just set mpFileDescriptor = pRasterDescriptor->getFileDescriptor() since we only
// want to replace the DataDescriptor's column list if one of the subset options is specified
const RasterFileDescriptor* pFileDesc(pRasterFileDescriptor);
if (pFileDesc == NULL)
{
pFileDesc = dynamic_cast<const RasterFileDescriptor*>(pRasterDescriptor->getFileDescriptor());
}
const vector<DimensionDescriptor>& origColumns = (pFileDesc != NULL) ?
pFileDesc->getColumns() : pRasterDescriptor->getColumns();
unsigned int startColumn = 0;
if (mpStartColumn != NULL)
{
startColumn = *mpStartColumn;
}
else if (origColumns.empty() == false)
{
startColumn = origColumns.front().getOriginalNumber() + 1;
}
unsigned int endColumn = 0;
if (mpEndColumn != NULL)
{
endColumn = *mpEndColumn;
}
else if (origColumns.empty() == false)
{
endColumn = origColumns.back().getOriginalNumber() + 1;
}
unsigned int columnSkip = 0;
if (mpColumnSkipFactor != NULL)
{
columnSkip = *mpColumnSkipFactor;
}
vector<DimensionDescriptor> columns;
for (unsigned int i = 0; i < origColumns.size(); ++i)
{
DimensionDescriptor columnDim = origColumns[i];
unsigned int originalNumber = columnDim.getOriginalNumber() + 1;
if ((originalNumber >= startColumn) && (originalNumber <= endColumn))
{
columns.push_back(columnDim);
i += columnSkip;
}
}
pRasterDescriptor->setColumns(columns);
}
// Bands
if ((mpStartBand != NULL) || (mpEndBand != NULL) || (mpBandSkipFactor != NULL) || (mpBadBandsFile != NULL))
{
// We need to obtain this origBands from the FileDescriptor if present since an importer
// may generate a subset by default in which case the DataDescriptor will not contain all
// the bands and subsetting (especially by bad band file) will not work correctly. We
// can't just set mpFileDescriptor = pRasterDescriptor->getFileDescriptor() since we only
// want to replace the DataDescriptor's band list if one of the subset options is specified
const RasterFileDescriptor* pFileDesc(pRasterFileDescriptor);
if (pFileDesc == NULL)
{
pFileDesc = dynamic_cast<const RasterFileDescriptor*>(pRasterDescriptor->getFileDescriptor());
}
const vector<DimensionDescriptor>& origBands = (pFileDesc != NULL) ?
pFileDesc->getBands() : pRasterDescriptor->getBands();
unsigned int startBand = 0;
if (mpStartBand != NULL)
{
startBand = *mpStartBand;
}
else if (origBands.empty() == false)
{
startBand = origBands.front().getOriginalNumber() + 1;
}
unsigned int endBand = 0;
if (mpEndBand != NULL)
{
endBand = *mpEndBand;
}
else if (origBands.empty() == false)
{
endBand = origBands.back().getOriginalNumber() + 1;
}
unsigned int bandSkip = 0;
if (mpBandSkipFactor != NULL)
{
bandSkip = *mpBandSkipFactor;
}
// Get the bad bands from the file
vector<unsigned int> badBands;
if (mpBadBandsFile != NULL)
{
string filename = *mpBadBandsFile;
if (filename.empty() == false)
{
FILE* pFile = fopen(filename.c_str(), "rb");
if (pFile != NULL)
{
char line[1024];
while (fgets(line, 1024, pFile) != NULL)
{
unsigned int bandNumber = 0;
int iValues = sscanf(line, "%u", &bandNumber);
if (iValues == 1)
{
badBands.push_back(bandNumber);
}
}
fclose(pFile);
}
}
}
vector<DimensionDescriptor> bands;
for (unsigned int i = 0; i < origBands.size(); ++i)
{
DimensionDescriptor bandDim = origBands[i];
unsigned int originalNumber = bandDim.getOriginalNumber() + 1;
if ((originalNumber >= startBand) && (originalNumber <= endBand))
{
bool bBad = false;
for (unsigned int j = 0; j < badBands.size(); ++j)
{
unsigned int badBandNumber = badBands[j];
if (originalNumber == badBandNumber)
{
bBad = true;
break;
}
}
if (bBad == false)
{
bands.push_back(bandDim);
i += bandSkip;
}
}
}
pRasterDescriptor->setBands(bands);
}
// X pixel size
if (mpPixelSizeX != NULL)
{
pRasterDescriptor->setXPixelSize(*mpPixelSizeX);
}
// Y pixel size
if (mpPixelSizeY != NULL)
{
pRasterDescriptor->setYPixelSize(*mpPixelSizeY);
}
// Units
if ((mpUnitsName != NULL) || (mpUnitsType != NULL) ||
(mpUnitsScale != NULL) || (mpUnitsRangeMin != NULL) || (mpUnitsRangeMax != NULL))
{
const Units* pOrigUnits = pRasterDescriptor->getUnits();
FactoryResource<Units> pUnits;
VERIFY(pUnits.get() != NULL);
// Name
if (mpUnitsName != NULL)
{
pUnits->setUnitName(*mpUnitsName);
}
else if (pOrigUnits != NULL)
{
pUnits->setUnitName(pOrigUnits->getUnitName());
}
// Type
if (mpUnitsType != NULL)
{
pUnits->setUnitType(*mpUnitsType);
}
else if (pOrigUnits != NULL)
{
pUnits->setUnitType(pOrigUnits->getUnitType());
}
// Scale
if (mpUnitsScale != NULL)
{
pUnits->setScaleFromStandard(*mpUnitsScale);
}
else if (pOrigUnits != NULL)
{
pUnits->setScaleFromStandard(pOrigUnits->getScaleFromStandard());
}
// Range minimum
if (mpUnitsRangeMin != NULL)
{
pUnits->setRangeMin(*mpUnitsRangeMin);
}
else if (pOrigUnits != NULL)
{
pUnits->setRangeMin(pOrigUnits->getRangeMin());
}
// Range maximum
if (mpUnitsRangeMax != NULL)
{
pUnits->setRangeMax(*mpUnitsRangeMax);
}
else if (pOrigUnits != NULL)
{
pUnits->setRangeMax(pOrigUnits->getRangeMax());
}
pRasterDescriptor->setUnits(pUnits.get());
}
// Display mode
if (mpDisplayMode != NULL)
{
pRasterDescriptor->setDisplayMode(*mpDisplayMode);
}
// Display bands
// Gray
if (mpGrayBand != NULL)
{
DimensionDescriptor band = pRasterDescriptor->getOriginalBand(*mpGrayBand - 1);
pRasterDescriptor->setDisplayBand(GRAY, band);
}
// Red
if (mpRedBand != NULL)
{
DimensionDescriptor band = pRasterDescriptor->getOriginalBand(*mpRedBand - 1);
pRasterDescriptor->setDisplayBand(RED, band);
}
// Green
if (mpGreenBand != NULL)
{
DimensionDescriptor band = pRasterDescriptor->getOriginalBand(*mpGreenBand - 1);
pRasterDescriptor->setDisplayBand(GREEN, band);
}
// Blue
if (mpBlueBand != NULL)
{
DimensionDescriptor band = pRasterDescriptor->getOriginalBand(*mpBlueBand - 1);
pRasterDescriptor->setDisplayBand(BLUE, band);
}
}
else if (pSignatureDescriptor != NULL)
{
if (mpComponentName != NULL)
{
const Units* pOrigUnits = pSignatureDescriptor->getUnits(*mpComponentName);
FactoryResource<Units> pUnits;
if (pOrigUnits != NULL)
{
*pUnits = *pOrigUnits;
}
if (mpUnitsName != NULL)
{
pUnits->setUnitName(*mpUnitsName);
}
if (mpUnitsType != NULL)
{
pUnits->setUnitType(*mpUnitsType);
}
if (mpUnitsScale != NULL)
{
pUnits->setScaleFromStandard(*mpUnitsScale);
}
if (mpUnitsRangeMin != NULL)
{
pUnits->setRangeMin(*mpUnitsRangeMin);
}
if (mpUnitsRangeMax != NULL)
{
pUnits->setRangeMax(*mpUnitsRangeMax);
}
pSignatureDescriptor->setUnits(*mpComponentName, pUnits.get());
}
}
reportComplete();
return true;
}
