def process(self, _edObject=None):
        EDPluginExec.process(self)
        EDVerbose.DEBUG("EDPluginExecReadImageHeaderPilatus2Mv10.process")
        xsDataInputReadImageHeader = self.getDataInput()
        xsDataFile = xsDataInputReadImageHeader.getImage()
        strPath = xsDataFile.getPath().getValue()
        dictPilatus2MHeader = self.readHeaderPilatus2M(strPath)
        if (dictPilatus2MHeader is None):
            strErrorMessage = "EDPluginExecReadImageHeaderPilatus2Mv10.process : Cannot read header : %s" % strPath
            EDVerbose.error(strErrorMessage)
            self.addErrorMessage(strErrorMessage)
            self.setFailure()
        else:
            xsDataExperimentalCondition = XSDataExperimentalCondition()
            xsDataDetector = XSDataDetector()

            iNoPixelsX = 1475
            iNoPixelsY = 1679
            xsDataDetector.setNumberPixelX(XSDataInteger(iNoPixelsX))
            xsDataDetector.setNumberPixelY(XSDataInteger(iNoPixelsY))
            # Pixel size
            listPixelSizeXY = dictPilatus2MHeader[ "Pixel_size"   ].split(" ")
            fPixelSizeX = float(listPixelSizeXY[0]) * 1000
            xsDataDetector.setPixelSizeX(XSDataLength(fPixelSizeX))
            fPixelSizeY = float(listPixelSizeXY[3]) * 1000
            xsDataDetector.setPixelSizeY(XSDataLength(fPixelSizeY))
            # Beam position
            listBeamPosition = dictPilatus2MHeader["Beam_xy"].replace("(", " ").replace(")", " ").replace(",", " ").split()
            fBeamPositionX = float(listBeamPosition[1]) * fPixelSizeX
            fBeamPositionY = float(listBeamPosition[0]) * fPixelSizeY
            xsDataDetector.setBeamPositionX(XSDataLength(fBeamPositionX))
            xsDataDetector.setBeamPositionY(XSDataLength(fBeamPositionY))
            fDistance = float(dictPilatus2MHeader[ "Detector_distance" ].split(" ")[0]) * 1000
            xsDataDetector.setDistance(XSDataLength(fDistance))
#            xsDataDetector.setNumberBytesInHeader(XSDataInteger(float(dictPilatus2MHeader[ "header_size"   ])))
            xsDataDetector.setSerialNumber(XSDataString(dictPilatus2MHeader[ "Detector:"   ]))
#            #xsDataDetector.setBin(                 XSDataString(   dictPilatus2MHeader[ "BIN" ] ) ) )
#            #xsDataDetector.setDataType(            XSDataString(   dictPilatus2MHeader[ "TYPE" ] ) ) )
#            #xsDataDetector.setByteOrder(           XSDataString(   dictPilatus2MHeader[ "BYTE_ORDER" ] ) ) )
#            xsDataDetector.setImageSaturation(XSDataInteger(int(dictPilatus2MHeader[ "saturation_level" ])))
            xsDataDetector.setName(XSDataString("PILATUS2 3M"))
            xsDataDetector.setType(XSDataString("pilatus2m"))
            xsDataExperimentalCondition.setDetector(xsDataDetector)

            # Beam object

            xsDataBeam = XSDataBeam()
            xsDataBeam.setWavelength(XSDataWavelength(float(dictPilatus2MHeader[ "Wavelength" ].split(" ")[0])))
            xsDataBeam.setExposureTime(XSDataTime(float(dictPilatus2MHeader[ "Exposure_time" ].split(" ")[0])))
            xsDataExperimentalCondition.setBeam(xsDataBeam)

            # Goniostat object
            xsDataGoniostat = XSDataGoniostat()
            fRotationAxisStart = float(dictPilatus2MHeader[ "Start_angle" ].split(" ")[0])
            fOscillationWidth = float(dictPilatus2MHeader[ "Angle_increment" ].split(" ")[0])
            xsDataGoniostat.setRotationAxisStart(XSDataAngle(fRotationAxisStart))
            xsDataGoniostat.setRotationAxisEnd(XSDataAngle(fRotationAxisStart + fOscillationWidth))
            xsDataGoniostat.setOscillationWidth(XSDataAngle(fOscillationWidth))
            xsDataExperimentalCondition.setGoniostat(xsDataGoniostat)
#
            # Create the image object
            xsDataImage = XSDataImage()
            xsDataImage.setPath(XSDataString(strPath))
            if "DateTime" in dictPilatus2MHeader:
                strTimeStamp = dictPilatus2MHeader[ "DateTime" ]
                xsDataImage.setDate(XSDataString(strTimeStamp))
            iImageNumber = EDUtilsImage.getImageNumber(strPath)
            xsDataImage.setNumber(XSDataInteger(iImageNumber))

            xsDataSubWedge = XSDataSubWedge()
            xsDataSubWedge.setExperimentalCondition(xsDataExperimentalCondition)
            xsDataSubWedge.addImage(xsDataImage)

            self.__xsDataResultReadImageHeader = XSDataResultReadImageHeader()
            self.__xsDataResultReadImageHeader.setSubWedge(xsDataSubWedge)
    def process(self, _edObject=None):
        EDPluginExec.process(self)
        EDVerbose.DEBUG("*** EDPluginExecReadImageHeaderADSCv10.process")
        xsDataInputReadImageHeader = self.getDataInput()
        xsDataFile = xsDataInputReadImageHeader.getImage()
        strPath = xsDataFile.getPath().getValue()
        strAbsolutePath = os.path.abspath(strPath)
        dictHeader = self.readHeaderADSC(strPath)
        if (dictHeader is None):
            strErrorMessage = "EDPluginExecReadImageHeaderADSCv10.process : error when reading header from %s" % strAbsolutePath
            EDVerbose.error(strErrorMessage)
            self.addErrorMessage(strErrorMessage)
            self.setFailure()
        else:
            xsDataExperimentalCondition = XSDataExperimentalCondition()
            xsDataDetector = XSDataDetector()

            xsDataDetector.setBeamPositionX(XSDataLength(float(dictHeader[ "BEAM_CENTER_X" ])))
            xsDataDetector.setBeamPositionY(XSDataLength(float(dictHeader[ "BEAM_CENTER_Y" ])))
            xsDataDetector.setDistance(XSDataLength(float(dictHeader[ "DISTANCE"   ])))
            fPixelSize = float(dictHeader[ "PIXEL_SIZE"   ])
            xsDataDetector.setPixelSizeX(XSDataLength(fPixelSize))
            xsDataDetector.setPixelSizeY(XSDataLength(fPixelSize))
            if "TWOTHETA" in dictHeader.keys():
                xsDataDetector.setTwoTheta(XSDataAngle(float(dictHeader[ "TWOTHETA"   ])))
            xsDataDetector.setNumberBytesInHeader(XSDataInteger(float(dictHeader[ "HEADER_BYTES"   ])))
            xsDataDetector.setSerialNumber(XSDataString(dictHeader[ "DETECTOR_SN"   ]))
            xsDataDetector.setNumberPixelX(XSDataInteger(int(dictHeader[ "SIZE1"   ])))
            xsDataDetector.setNumberPixelY(XSDataInteger(int(dictHeader[ "SIZE2"   ])))
            xsDataDetector.setBin(XSDataString(dictHeader[ "BIN" ]))
            xsDataDetector.setDataType(XSDataString(dictHeader[ "TYPE" ]))
            xsDataDetector.setByteOrder(XSDataString(dictHeader[ "BYTE_ORDER" ]))
            if "CCD_IMAGE_SATURATION" in dictHeader.keys():
                xsDataDetector.setImageSaturation(XSDataInteger(int(dictHeader[ "CCD_IMAGE_SATURATION" ])))

            # Determine type of detector...
            iNoPixelsX = xsDataDetector.getNumberPixelX().getValue()
            iNoPixelsY = xsDataDetector.getNumberPixelY().getValue()
            if (iNoPixelsX == 2304 and iNoPixelsY == 2304):
                xsDataDetector.setName(XSDataString("ADSC Q4"))
                xsDataDetector.setType(XSDataString("q4"))
            elif (iNoPixelsX == 1152 and iNoPixelsY == 1152):
                xsDataDetector.setName(XSDataString("ADSC Q4 bin 2x2"))
                xsDataDetector.setType(XSDataString("q4-2x"))
            elif (iNoPixelsX == 4096 and iNoPixelsY == 4096):
                xsDataDetector.setName(XSDataString("ADSC Q210"))
                xsDataDetector.setType(XSDataString("q210"))
            elif (iNoPixelsX == 2048 and iNoPixelsY == 2048):
                xsDataDetector.setName(XSDataString("ADSC Q210 bin 2x2"))
                xsDataDetector.setType(XSDataString("q210-2x"))
            elif (iNoPixelsX == 6144 and iNoPixelsY == 6144):
                xsDataDetector.setName(XSDataString("ADSC Q315"))
                xsDataDetector.setType(XSDataString("q315"))
            elif (iNoPixelsX == 3072 and iNoPixelsY == 3072):
                xsDataDetector.setName(XSDataString("ADSC Q315 bin 2x2"))
                xsDataDetector.setType(XSDataString("q315-2x"))
            else:
                strErrorMessage = EDMessage.ERROR_DATA_HANDLER_02 % ("EDPluginExecReadImageHeaderADSCv10.process", "Unknown detector type")
                EDVerbose.error(strErrorMessage)
                self.addErrorMessage(strErrorMessage)
                raise RuntimeError, strErrorMessage

            xsDataExperimentalCondition.setDetector(xsDataDetector)

            # Beam object

            xsDataBeam = XSDataBeam()
            xsDataBeam.setWavelength(XSDataWavelength(float(dictHeader[ "WAVELENGTH" ])))
            xsDataBeam.setExposureTime(XSDataTime(float(dictHeader[ "TIME" ])))
            xsDataExperimentalCondition.setBeam(xsDataBeam)

            # Goniostat object
            xsDataGoniostat = XSDataGoniostat()
            fRotationAxisStart = float(dictHeader[ "OSC_START" ])
            fOscillationWidth = float(dictHeader[ "OSC_RANGE" ])
            xsDataGoniostat.setRotationAxisStart(XSDataAngle(fRotationAxisStart))
            xsDataGoniostat.setRotationAxisEnd(XSDataAngle(fRotationAxisStart + fOscillationWidth))
            xsDataGoniostat.setOscillationWidth(XSDataAngle(fOscillationWidth))
            strRotationAxis = None
            if ("AXIS" in dictHeader.keys()):
                strRotationAxis = dictHeader[ "AXIS" ]
            elif ("OSC_AXIS" in dictHeader.keys()):
                strRotationAxis = dictHeader[ "OSC_AXIS" ]
            else:
                strErrorMessage = "EDPluginExecReadImageHeaderADSCv10.process : Neither AXIS nor OSC_AXIS header item found."
                EDVerbose.error(strErrorMessage)
                self.addErrorMessage(strErrorMessage)
                self.setFailure()
            xsDataGoniostat.setRotationAxis(XSDataString(strRotationAxis))
            xsDataExperimentalCondition.setGoniostat(xsDataGoniostat)

            # Create the image object
            xsDataImage = XSDataImage()
            xsDataImage.setPath(XSDataString(strAbsolutePath))
            xsDataImage.setDate(XSDataString(dictHeader[ "DATE" ]))
            strFileName = os.path.basename(strPath)
            iImageNumber = EDUtilsImage.getImageNumber(strFileName)
            xsDataImage.setNumber(XSDataInteger(iImageNumber))

            xsDataSubWedge = XSDataSubWedge()
            xsDataSubWedge.setExperimentalCondition(xsDataExperimentalCondition)
            xsDataSubWedge.addImage(xsDataImage)

            self.__xsDataResultReadImageHeader = XSDataResultReadImageHeader()
            self.__xsDataResultReadImageHeader.setSubWedge(xsDataSubWedge)
    def process(self, _edObject=None):
        EDPluginExec.process(self)
        self.DEBUG("EDPluginExecReadImageHeaderEiger4Mv10.process")
        xsDataInputReadImageHeader = self.getDataInput()
        xsDataFile = xsDataInputReadImageHeader.getImage()
        strPath = xsDataFile.getPath().getValue()
        dictEiger4MHeader = self.readHeaderEiger4M(strPath)
        if (dictEiger4MHeader is None):
            strErrorMessage = "EDPluginExecReadImageHeaderEiger4Mv10.process : Cannot read header : %s" % strPath
            self.error(strErrorMessage)
            self.addErrorMessage(strErrorMessage)
            self.setFailure()
        else:
            xsDataExperimentalCondition = XSDataExperimentalCondition()
            xsDataDetector = XSDataDetector()

            iNoPixelsX = 2070
            iNoPixelsY = 2167
            xsDataDetector.setNumberPixelX(XSDataInteger(iNoPixelsX))
            xsDataDetector.setNumberPixelY(XSDataInteger(iNoPixelsY))
            # Pixel size
            listPixelSizeXY = dictEiger4MHeader[ "Pixel_size"   ].split(" ")
            fPixelSizeX = float(listPixelSizeXY[0]) * 1000
            xsDataDetector.setPixelSizeX(XSDataLength(fPixelSizeX))
            fPixelSizeY = float(listPixelSizeXY[3]) * 1000
            xsDataDetector.setPixelSizeY(XSDataLength(fPixelSizeY))
            # Beam position
            listBeamPosition = dictEiger4MHeader["Beam_xy"].replace("(", " ").replace(")", " ").replace(",", " ").split()
            fBeamPositionX = float(listBeamPosition[1]) * fPixelSizeX
            fBeamPositionY = float(listBeamPosition[0]) * fPixelSizeY
            xsDataDetector.setBeamPositionX(XSDataLength(fBeamPositionX))
            xsDataDetector.setBeamPositionY(XSDataLength(fBeamPositionY))
            fDistance = float(dictEiger4MHeader[ "Detector_distance" ].split(" ")[0]) * 1000
            xsDataDetector.setDistance(XSDataLength(fDistance))
#            xsDataDetector.setNumberBytesInHeader(XSDataInteger(float(dictEiger4MHeader[ "header_size"   ])))
            xsDataDetector.setSerialNumber(XSDataString(dictEiger4MHeader[ "Detector:"   ]))
#            #xsDataDetector.setBin(                 XSDataString(   dictEiger4MHeader[ "BIN" ] ) ) )
#            #xsDataDetector.setDataType(            XSDataString(   dictEiger4MHeader[ "TYPE" ] ) ) )
#            #xsDataDetector.setByteOrder(           XSDataString(   dictEiger4MHeader[ "BYTE_ORDER" ] ) ) )
#            xsDataDetector.setImageSaturation(XSDataInteger(int(dictEiger4MHeader[ "saturation_level" ])))
            xsDataDetector.setName(XSDataString("EIGER 4M"))
            xsDataDetector.setType(XSDataString("eiger4m"))
            xsDataExperimentalCondition.setDetector(xsDataDetector)

            # Beam object

            xsDataBeam = XSDataBeam()
            xsDataBeam.setWavelength(XSDataWavelength(float(dictEiger4MHeader[ "Wavelength" ].split(" ")[0])))
            xsDataBeam.setExposureTime(XSDataTime(float(dictEiger4MHeader[ "Exposure_time" ].split(" ")[0])))
            xsDataExperimentalCondition.setBeam(xsDataBeam)

            # Goniostat object
            xsDataGoniostat = XSDataGoniostat()
            fRotationAxisStart = float(dictEiger4MHeader[ "Start_angle" ].split(" ")[0])
            fOscillationWidth = float(dictEiger4MHeader[ "Angle_increment" ].split(" ")[0])
            xsDataGoniostat.setRotationAxisStart(XSDataAngle(fRotationAxisStart))
            xsDataGoniostat.setRotationAxisEnd(XSDataAngle(fRotationAxisStart + fOscillationWidth))
            xsDataGoniostat.setOscillationWidth(XSDataAngle(fOscillationWidth))
            xsDataExperimentalCondition.setGoniostat(xsDataGoniostat)
#
            # Create the image object
            xsDataImage = XSDataImage()
            xsDataImage.setPath(XSDataString(strPath))
            if "DateTime" in dictEiger4MHeader:
                strTimeStamp = dictEiger4MHeader[ "DateTime" ]
                xsDataImage.setDate(XSDataString(strTimeStamp))
            iImageNumber = EDUtilsImage.getImageNumber(strPath)
            xsDataImage.setNumber(XSDataInteger(iImageNumber))

            xsDataSubWedge = XSDataSubWedge()
            xsDataSubWedge.setExperimentalCondition(xsDataExperimentalCondition)
            xsDataSubWedge.addImage(xsDataImage)

            self.__xsDataResultReadImageHeader = XSDataResultReadImageHeader()
            self.__xsDataResultReadImageHeader.setSubWedge(xsDataSubWedge)
    def testSetDataModelInput(self):
        edPluginStrategy = self.createPlugin()
        strPathToTestConfigFile = os.path.join(self.getPluginTestsDataHome(),
                                               "XSConfiguration_ESRF.xml")
        edConfiguration = EDConfiguration(strPathToTestConfigFile)
        dictItem = edConfiguration.get(edPluginStrategy.getPluginName())
        edPluginStrategy.setConfig(dictItem)
        edPluginStrategy.configure()

        xsDataStrategy = XSDataInputStrategy()

        # Beam

        xsExperimentalCondition = XSDataExperimentalCondition()

        xsBeam = XSDataBeam()
        xsBeam.setFlux(XSDataFlux(1e+12))
        xsBeam.setWavelength(XSDataWavelength(2.41))
        xsBeam.setSize(XSDataSize(x=XSDataLength(0.1), y=XSDataLength(0.1)))
        xsBeam.setExposureTime(XSDataTime(1))

        xsExperimentalCondition.setBeam(xsBeam)

        # Detector and Exposure Time

        xsDataDetector = XSDataDetector()
        xsDataDetector.setType(XSDataString("q210-2x"))
        xsExperimentalCondition.setDetector(xsDataDetector)

        xsDataGoniostat = XSDataGoniostat()
        xsDataGoniostat.setRotationAxis(XSDataString("phi"))
        xsExperimentalCondition.setGoniostat(xsDataGoniostat)

        xsDataStrategy.setExperimentalCondition(xsExperimentalCondition)

        # Best Files
        bestFileContentDat = EDUtilsFile.readFile(
            os.path.join(self.strDataPath, "bestfile.dat"))
        xsDataStrategy.setBestFileContentDat(XSDataString(bestFileContentDat))
        bestFileContentPar = EDUtilsFile.readFile(
            os.path.join(self.strDataPath, "bestfile.par"))
        xsDataStrategy.setBestFileContentPar(XSDataString(bestFileContentPar))
        bestFileContentHKL = EDUtilsFile.readFile(
            os.path.join(self.strDataPath, "bestfile1.hkl"))
        xsDataStrategy.addBestFileContentHKL(XSDataString(bestFileContentHKL))

        # Crystal

        xsDataSampleCrystalMM = XSDataSampleCrystalMM()
        xsDataStructure = XSDataStructure()
        xsDataComposition = XSDataChemicalCompositionMM()

        xsDataChain = XSDataChain()
        xsDataChain.setType(XSDataString("protein"))
        xsDataChain.setNumberOfCopies(XSDataDouble(2))
        xsDataAtomicComposition = XSDataAtomicComposition()
        xsDataAtom1 = XSDataAtom()
        xsDataAtom1.setSymbol(XSDataString("Se"))
        xsDataAtom1.setNumberOf(XSDataDouble(4))
        xsDataAtomicComposition.addAtom(xsDataAtom1)

        xsDataChain.setHeavyAtoms(xsDataAtomicComposition)
        xsDataChain.setNumberOfMonomers(XSDataDouble(100))
        xsDataStructure.addChain(xsDataChain)

        xsDataChain2 = XSDataChain()
        xsDataChain2.setType(XSDataString("rna"))
        xsDataChain2.setNumberOfCopies(XSDataDouble(1))
        xsDataChain2.setNumberOfMonomers(XSDataDouble(60))
        xsDataStructure.addChain(xsDataChain2)

        xsDataLigand = XSDataLigand()
        xsDataLigand.setNumberOfCopies(XSDataDouble(2))
        xsDataLigand.setNumberOfLightAtoms(XSDataDouble(42))
        xsDataAtomicComposition = XSDataAtomicComposition()
        xsDataAtom2 = XSDataAtom()
        xsDataAtom2.setSymbol(XSDataString("Fe"))
        xsDataAtom2.setNumberOf(XSDataDouble(1))
        xsDataAtomicComposition.addAtom(xsDataAtom2)
        xsDataLigand.setHeavyAtoms(xsDataAtomicComposition)
        xsDataStructure.addLigand(xsDataLigand)
        xsDataStructure.setNumberOfCopiesInAsymmetricUnit(XSDataDouble(0.25))

        xsDataSolvent = XSDataSolvent()
        xsDataAtomicComposition = XSDataAtomicComposition()

        xsDataAtom3 = XSDataAtom()
        xsDataAtom3.setSymbol(XSDataString("Na"))
        xsDataAtom3.setConcentration(XSDataDouble(1000))
        xsDataAtom4 = XSDataAtom()
        xsDataAtom4.setSymbol(XSDataString("Cl"))
        xsDataAtom4.setConcentration(XSDataDouble(1000))

        xsDataAtomicComposition.addAtom(xsDataAtom3)
        xsDataAtomicComposition.addAtom(xsDataAtom4)
        xsDataSolvent.setAtoms(xsDataAtomicComposition)

        xsDataComposition.setStructure(xsDataStructure)
        xsDataComposition.setSolvent(xsDataSolvent)
        xsDataSampleCrystalMM.setChemicalComposition(xsDataComposition)

        xsDataSampleCrystalMM.setSize(
            XSDataSize(XSDataLength(0.1), XSDataLength(0.1),
                       XSDataLength(0.1)))

        xsDataCrystal = XSDataCrystal()
        xsDataCell = XSDataCell(angle_alpha=XSDataAngle(90.0),
                                angle_beta=XSDataAngle(90.0),
                                angle_gamma=XSDataAngle(90.0),
                                length_a=XSDataLength(78.9),
                                length_b=XSDataLength(95.162),
                                length_c=XSDataLength(104.087))
        xsDataCrystal.setCell(xsDataCell)

        xsDataSpaceGroup = XSDataSpaceGroup()
        xsDataSpaceGroup.setITNumber(XSDataInteger(16))
        xsDataCrystal.setSpaceGroup(xsDataSpaceGroup)

        xsDataSampleCrystalMM.setSusceptibility(XSDataDouble(1.5))

        xsDataStrategy.setCrystalRefined(xsDataCrystal)

        xsDataStrategy.setSample(xsDataSampleCrystalMM)

        xsDataStrategy.exportToFile(self.strObtainedInputFile)

        pyStrExpectedInput = self.readAndParseFile(self.strReferenceInputFile)
        pyStrObtainedInput = self.readAndParseFile(self.strObtainedInputFile)

        xsDataInputExpected = XSDataInputStrategy.parseString(
            pyStrExpectedInput)
        xsDataInputObtained = XSDataInputStrategy.parseString(
            pyStrObtainedInput)

        EDAssert.equal(xsDataInputExpected.marshal(),
                       xsDataInputObtained.marshal())
    def testSetDataModelInput(self):
        edPluginStrategy = self.createPlugin()
        strPathToTestConfigFile = os.path.join(self.getPluginTestsDataHome(), "XSConfiguration_ESRF.xml")
        edConfiguration = EDConfiguration(strPathToTestConfigFile)
        dictItem = edConfiguration.get(edPluginStrategy.getPluginName())
        edPluginStrategy.setConfig(dictItem)
        edPluginStrategy.configure()

        xsDataStrategy = XSDataInputStrategy()

        # Beam

        xsExperimentalCondition = XSDataExperimentalCondition()

        xsBeam = XSDataBeam()
        xsBeam.setFlux(XSDataFlux(1e+12))
        xsBeam.setWavelength(XSDataWavelength(2.41))
        xsBeam.setSize(XSDataSize(x=XSDataLength(0.1), y=XSDataLength(0.1)))
        xsBeam.setExposureTime(XSDataTime(1))

        xsExperimentalCondition.setBeam(xsBeam)

        # Detector and Exposure Time

        xsDataDetector = XSDataDetector()
        xsDataDetector.setType(XSDataString("q210-2x"))
        xsExperimentalCondition.setDetector(xsDataDetector)

        xsDataGoniostat = XSDataGoniostat()
        xsDataGoniostat.setRotationAxis(XSDataString("phi"))
        xsExperimentalCondition.setGoniostat(xsDataGoniostat)

        xsDataStrategy.setExperimentalCondition(xsExperimentalCondition)


        # Best Files
        bestFileContentDat = EDUtilsFile.readFile(os.path.join(self.strDataPath, "bestfile.dat"))
        xsDataStrategy.setBestFileContentDat(XSDataString(bestFileContentDat))
        bestFileContentPar = EDUtilsFile.readFile(os.path.join(self.strDataPath, "bestfile.par"))
        xsDataStrategy.setBestFileContentPar(XSDataString(bestFileContentPar))
        bestFileContentHKL = EDUtilsFile.readFile(os.path.join(self.strDataPath, "bestfile1.hkl"))
        xsDataStrategy.addBestFileContentHKL(XSDataString(bestFileContentHKL))

        # Crystal

        xsDataSampleCrystalMM = XSDataSampleCrystalMM()
        xsDataStructure = XSDataStructure()
        xsDataComposition = XSDataChemicalCompositionMM()

        xsDataChain = XSDataChain()
        xsDataChain.setType(XSDataString("protein"))
        xsDataChain.setNumberOfCopies(XSDataDouble(2))
        xsDataAtomicComposition = XSDataAtomicComposition()
        xsDataAtom1 = XSDataAtom()
        xsDataAtom1.setSymbol(XSDataString("Se"))
        xsDataAtom1.setNumberOf(XSDataDouble(4))
        xsDataAtomicComposition.addAtom(xsDataAtom1)

        xsDataChain.setHeavyAtoms(xsDataAtomicComposition)
        xsDataChain.setNumberOfMonomers(XSDataDouble(100))
        xsDataStructure.addChain(xsDataChain)

        xsDataChain2 = XSDataChain()
        xsDataChain2.setType(XSDataString("rna"))
        xsDataChain2.setNumberOfCopies(XSDataDouble(1))
        xsDataChain2.setNumberOfMonomers(XSDataDouble(60))
        xsDataStructure.addChain(xsDataChain2)

        xsDataLigand = XSDataLigand()
        xsDataLigand.setNumberOfCopies(XSDataDouble(2))
        xsDataLigand.setNumberOfLightAtoms(XSDataDouble(42))
        xsDataAtomicComposition = XSDataAtomicComposition()
        xsDataAtom2 = XSDataAtom()
        xsDataAtom2.setSymbol(XSDataString("Fe"))
        xsDataAtom2.setNumberOf(XSDataDouble(1))
        xsDataAtomicComposition.addAtom(xsDataAtom2)
        xsDataLigand.setHeavyAtoms(xsDataAtomicComposition)
        xsDataStructure.addLigand(xsDataLigand)
        xsDataStructure.setNumberOfCopiesInAsymmetricUnit(XSDataDouble(0.25))

        xsDataSolvent = XSDataSolvent()
        xsDataAtomicComposition = XSDataAtomicComposition()

        xsDataAtom3 = XSDataAtom()
        xsDataAtom3.setSymbol(XSDataString("Na"))
        xsDataAtom3.setConcentration(XSDataDouble(1000))
        xsDataAtom4 = XSDataAtom()
        xsDataAtom4.setSymbol(XSDataString("Cl"))
        xsDataAtom4.setConcentration(XSDataDouble(1000))

        xsDataAtomicComposition.addAtom(xsDataAtom3)
        xsDataAtomicComposition.addAtom(xsDataAtom4)
        xsDataSolvent.setAtoms(xsDataAtomicComposition)

        xsDataComposition.setStructure(xsDataStructure)
        xsDataComposition.setSolvent(xsDataSolvent)
        xsDataSampleCrystalMM.setChemicalComposition(xsDataComposition)

        xsDataSampleCrystalMM.setSize(XSDataSize(XSDataLength(0.1), XSDataLength(0.1), XSDataLength(0.1)))

        xsDataCrystal = XSDataCrystal()
        xsDataCell = XSDataCell(angle_alpha=XSDataAngle(90.0),
                                angle_beta=XSDataAngle(90.0),
                                angle_gamma=XSDataAngle(90.0),
                                length_a=XSDataLength(78.9),
                                length_b=XSDataLength(95.162),
                                length_c=XSDataLength(104.087))
        xsDataCrystal.setCell(xsDataCell)

        xsDataSpaceGroup = XSDataSpaceGroup()
        xsDataSpaceGroup.setITNumber(XSDataInteger(16))
        xsDataCrystal.setSpaceGroup(xsDataSpaceGroup)

        xsDataSampleCrystalMM.setSusceptibility(XSDataDouble(1.5))

        xsDataStrategy.setCrystalRefined(xsDataCrystal)

        xsDataStrategy.setSample(xsDataSampleCrystalMM)

        xsDataStrategy.exportToFile(self.strObtainedInputFile)

        pyStrExpectedInput = self.readAndParseFile (self.strReferenceInputFile)
        pyStrObtainedInput = self.readAndParseFile (self.strObtainedInputFile)

        xsDataInputExpected = XSDataInputStrategy.parseString(pyStrExpectedInput)
        xsDataInputObtained = XSDataInputStrategy.parseString(pyStrObtainedInput)

        EDAssert.equal(xsDataInputExpected.marshal(), xsDataInputObtained.marshal())
    def testSetDataModelInput(self):
        from XSDataCCP4iv1_1 import XSDataInputCCP4i
        xsDataInputCCP4i = XSDataInputCCP4i()

        # Beam
        from XSDataCommon import XSDataFlux
        from XSDataCommon import XSDataSize
        from XSDataCommon import XSDataLength
        from XSDataCommon import XSDataFloat

        from XSDataMXv1 import XSDataBeam
        from XSDataMXv1 import XSDataExperimentalCondition

        xsExperimentalCondition = XSDataExperimentalCondition()

        xsBeam = XSDataBeam()
        xsBeam.setFlux(XSDataFlux(1e+12))
        xsBeam.setSize(XSDataSize(XSDataLength(0.1), XSDataLength(0.1)))
        xsBeam.setMinExposureTimePerImage(XSDataFloat(0.1))
        xsExperimentalCondition.setBeam(xsBeam)

        # Goniostat
        from XSDataCommon import XSDataSpeed
        from XSDataCommon import XSDataAngle

        from XSDataMXv1 import XSDataGoniostat

        xsDataGoniostat = XSDataGoniostat()
        xsDataGoniostat.setMaxOscillationSpeed(XSDataSpeed(0.2))
        xsDataGoniostat.setMinOscillationWidth(XSDataAngle(0.1))
        xsExperimentalCondition.setGoniostat(xsDataGoniostat)
        xsDataInputCCP4i.setExperimentalCondition(xsExperimentalCondition)

        # Sample
        from XSDataCommon import XSDataString
        from XSDataCommon import XSDataFloat
        from XSDataCommon import XSDataString

        from XSDataMXv1 import XSDataStructure
        from XSDataMXv1 import XSDataChain
        from XSDataMXv1 import XSDataAtom
        from XSDataMXv1 import XSDataLigand
        from XSDataMXv1 import XSDataSampleCrystalMM
        from XSDataMXv1 import XSDataChemicalCompositionMM
        from XSDataMXv1 import XSDataAtomicComposition
        from XSDataMXv1 import XSDataSolvent

        xsDataSampleCrystalMM = XSDataSampleCrystalMM()
        xsDataStructure = XSDataStructure()
        xsDataComposition = XSDataChemicalCompositionMM()

        xsDataChain = XSDataChain()
        xsDataChain.setType(XSDataString("protein"))
        xsDataChain.setNumberOfCopies(XSDataFloat(2))
        xsDataAtomicComposition = XSDataAtomicComposition()
        xsDataAtom1 = XSDataAtom()
        xsDataAtom1.setSymbol(XSDataString("Se"))
        xsDataAtom1.setNumberOf(XSDataFloat(4))
        xsDataAtomicComposition.addAtom(xsDataAtom1)

        xsDataChain.setHeavyAtoms(xsDataAtomicComposition)
        xsDataChain.setNumberOfMonomers(XSDataFloat(100))
        xsDataStructure.addChain(xsDataChain)

        xsDataChain2 = XSDataChain()
        xsDataChain2.setType(XSDataString("rna"))
        xsDataChain2.setNumberOfCopies(XSDataFloat(1))
        xsDataChain2.setNumberOfMonomers(XSDataFloat(60))
        xsDataStructure.addChain(xsDataChain2)

        xsDataLigand = XSDataLigand()
        xsDataLigand.setNumberOfCopies(XSDataFloat(2))
        xsDataLigand.setNumberOfLightAtoms(XSDataFloat(42))
        xsDataAtomicComposition = XSDataAtomicComposition()
        xsDataAtom2 = XSDataAtom()
        xsDataAtom2.setSymbol(XSDataString("Fe"))
        xsDataAtom2.setNumberOf(XSDataFloat(1))
        xsDataAtomicComposition.addAtom(xsDataAtom2)
        xsDataLigand.setHeavyAtoms(xsDataAtomicComposition)
        xsDataStructure.addLigand(xsDataLigand)
        xsDataStructure.setNumberOfCopiesInAsymmetricUnit(XSDataFloat(0.25))

        xsDataSolvent = XSDataSolvent()
        xsDataAtomicComposition = XSDataAtomicComposition()

        xsDataAtom3 = XSDataAtom()
        xsDataAtom3.setSymbol(XSDataString("Na"))
        xsDataAtom3.setConcentration(XSDataFloat(1000))
        xsDataAtom4 = XSDataAtom()
        xsDataAtom4.setSymbol(XSDataString("Cl"))
        xsDataAtom4.setConcentration(XSDataFloat(1000))

        xsDataAtomicComposition.addAtom(xsDataAtom3)
        xsDataAtomicComposition.addAtom(xsDataAtom4)
        xsDataSolvent.setAtoms(xsDataAtomicComposition)

        xsDataComposition.setStructure(xsDataStructure)
        xsDataComposition.setSolvent(xsDataSolvent)
        xsDataSampleCrystalMM.setChemicalComposition(xsDataComposition)

        xsDataSampleCrystalMM.setSize(XSDataSize(XSDataLength(0.2), XSDataLength(0.2), XSDataLength(0.2)))
        xsDataSampleCrystalMM.setSusceptibility(XSDataFloat(1.5))
        xsDataSampleCrystalMM.setShape(XSDataFloat(2))

        xsDataInputCCP4i.setSample(xsDataSampleCrystalMM)

        from XSDataMXv1 import XSDataDiffractionPlan

        xsDataDiffractionPlan = XSDataDiffractionPlan()

        xsDataDiffractionPlan.setAimedCompleteness(XSDataFloat(95.5))
        xsDataDiffractionPlan.setAimedIOverSigmaAtHighestResolution(XSDataFloat(2.5))
        xsDataDiffractionPlan.setAimedMultiplicity(XSDataFloat(95.5))
        xsDataDiffractionPlan.setAimedResolution(XSDataFloat(3))
        xsDataDiffractionPlan.setComplexity(XSDataString("full"))
        xsDataDiffractionPlan.setForcedSpaceGroup(XSDataString("P222"))
        xsDataDiffractionPlan.setMaxExposureTimePerDataCollection(XSDataFloat(10000))

        xsDataInputCCP4i.setDiffractionPlan(xsDataDiffractionPlan)

        from XSDataCommon import XSDataFile

        listInputDataFile = []
        xsDataFile = XSDataFile(XSDataString(self.strXSDataGenerateTemplateFile))
        listInputDataFile.append(xsDataFile)
        xsDataInputCCP4i.setDataFile(listInputDataFile)
    def process(self, _edObject=None):
        EDPluginExec.process(self)
        EDVerbose.DEBUG("EDPluginExecReadImageHeaderMARCCDv10.process")
        xsDataInputReadImageHeader = self.getDataInput()
        xsDataFile = xsDataInputReadImageHeader.getImage()
        strPath = xsDataFile.getPath().getValue()
        dictMARCCDHeader = self.readHeaderMarccd(strPath)
        if (dictMARCCDHeader is None):
            strErrorMessage = "EDPluginExecReadImageHeaderMARCCDv10.process : Cannot read header : %s" % strPath
            EDVerbose.error(strErrorMessage)
            self.addErrorMessage(strErrorMessage)
            self.setFailure()
        else:
            xsDataExperimentalCondition = XSDataExperimentalCondition()
            xsDataDetector = XSDataDetector()

            iNoPixelsX = int(dictMARCCDHeader[ "nslow"   ])
            iNoPixelsY = int(dictMARCCDHeader[ "nfast"   ])
            xsDataDetector.setNumberPixelX(XSDataInteger(iNoPixelsX))
            xsDataDetector.setNumberPixelY(XSDataInteger(iNoPixelsY))
            fPixelSizeX = float(dictMARCCDHeader[ "pixelsize_x"   ]) / 1000.0
            xsDataDetector.setPixelSizeX(XSDataLength(fPixelSizeX))
            fPixelSizeY = float(dictMARCCDHeader[ "pixelsize_y"   ]) / 1000.0
            xsDataDetector.setPixelSizeY(XSDataLength(fPixelSizeY))
            fBeamPositionX = float(dictMARCCDHeader[ "beam_x" ]) / 1000.0
            fBeamPositionY = float(dictMARCCDHeader[ "beam_y" ]) / 1000.0
            # Fix for bug 397 - check if the beam position is close to the centre of the image
            fTwoTheta = float(dictMARCCDHeader[ "end_twotheta"   ]) / 1000.0
            xsDataDetector.setTwoTheta(XSDataAngle(fTwoTheta))
            if (abs(fTwoTheta) < 0.1):
                if (abs(fBeamPositionX / (fPixelSizeX / 1000.0) - iNoPixelsX / 2.0) > (2 * iNoPixelsX)):
                    fBeamPositionX = fBeamPositionX * fPixelSizeX / 1000.0
                    fBeamPositionY = fBeamPositionY * fPixelSizeY / 1000.0
            xsDataDetector.setBeamPositionX(XSDataLength(fBeamPositionX))
            xsDataDetector.setBeamPositionY(XSDataLength(fBeamPositionY))
            fDistance = float(dictMARCCDHeader[ "xtal_to_detector"   ]) / 1000.0
            if (abs(fDistance) < 0.1):
                fDistanceStart = float(dictMARCCDHeader[ "start_xtal_to_detector"   ]) / 1000.0
                fDistanceEnd = float(dictMARCCDHeader[ "end_xtal_to_detector"   ]) / 1000.0
                if (abs(fDistanceStart - fDistanceEnd) < 0.1):
                    fDistance = fDistanceStart
                else:
                    # Somethings very wrong with the distances...
                    strErrorMessage = "EDPluginExecReadImageHeaderMARCCDv10.process : Inconsistency in MAR CCD image header: start_xtal_to_detector = %d, end_xtal_to_detector = %d" % \
                                                                           (fDistanceStart, fDistanceEnd)
                    EDVerbose.error(strErrorMessage)
                    self.addErrorMessage(strErrorMessage)
                    self.setFailure()
            xsDataDetector.setDistance(XSDataLength(fDistance))
            xsDataDetector.setNumberBytesInHeader(XSDataInteger(float(dictMARCCDHeader[ "header_size"   ])))
            # xsDataDetector.setSerialNumber(        XSDataInteger(  dictMARCCDHeader[ "DETECTOR_SN"   ] ) ) )
            # xsDataDetector.setBin(                 XSDataString(   dictMARCCDHeader[ "BIN" ] ) ) )
            # xsDataDetector.setDataType(            XSDataString(   dictMARCCDHeader[ "TYPE" ] ) ) )
            # xsDataDetector.setByteOrder(           XSDataString(   dictMARCCDHeader[ "BYTE_ORDER" ] ) ) )
            xsDataDetector.setImageSaturation(XSDataInteger(int(dictMARCCDHeader[ "saturation_level" ])))
            # Determine type of detector...
            if (iNoPixelsX == 2048 and iNoPixelsY == 2048):
                xsDataDetector.setName(XSDataString("MAR CCD 165"))
                xsDataDetector.setType(XSDataString("mar165"))
            elif (iNoPixelsX == 3072 and iNoPixelsY == 3072):
                xsDataDetector.setName(XSDataString("MAR CCD 225"))
                xsDataDetector.setType(XSDataString("mar225"))
            elif (iNoPixelsX == 4096 and iNoPixelsY == 4096):
                xsDataDetector.setName(XSDataString("MAR CCD 325"))
                xsDataDetector.setType(XSDataString("mar325"))
            else:
                strErrorMessage = EDMessage.ERROR_DATA_HANDLER_02 % ("EDPluginExecReadImageHeaderMARCCDv10.process", "Unknown detector type")
                EDVerbose.error(strErrorMessage)
                self.addErrorMessage(strErrorMessage)
                raise RuntimeError, strErrorMessage

            xsDataExperimentalCondition.setDetector(xsDataDetector)

            # Beam object

            xsDataBeam = XSDataBeam()
            xsDataBeam.setWavelength(XSDataWavelength(float(dictMARCCDHeader[ "source_wavelength" ]) / 100000.0))
            xsDataBeam.setExposureTime(XSDataTime(float(dictMARCCDHeader[ "exposure_time" ]) / 1000.0))
            xsDataExperimentalCondition.setBeam(xsDataBeam)

            # Goniostat object
            xsDataGoniostat = XSDataGoniostat()
            fRotationAxisStart = float(dictMARCCDHeader[ "start_phi" ]) / 1000.0
            fOscillationWidth = float(dictMARCCDHeader[ "rotation_range" ]) / 1000.0
            xsDataGoniostat.setRotationAxisStart(XSDataAngle(fRotationAxisStart))
            xsDataGoniostat.setRotationAxisEnd(XSDataAngle(fRotationAxisStart + fOscillationWidth))
            xsDataGoniostat.setOscillationWidth(XSDataAngle(fOscillationWidth))
            xsDataExperimentalCondition.setGoniostat(xsDataGoniostat)

            # Create the image object
            xsDataImage = XSDataImage()
            xsDataImage.setPath(XSDataString(strPath))
            strTimeStamp = dictMARCCDHeader[ "acquire_timestamp" ]
            xsDataImage.setDate(XSDataString(strTimeStamp))
            iImageNumber = EDUtilsImage.getImageNumber(strPath)
            xsDataImage.setNumber(XSDataInteger(iImageNumber))

            xsDataSubWedge = XSDataSubWedge()
            xsDataSubWedge.setExperimentalCondition(xsDataExperimentalCondition)
            xsDataSubWedge.addImage(xsDataImage)

            self.__xsDataResultReadImageHeader = XSDataResultReadImageHeader()
            self.__xsDataResultReadImageHeader.setSubWedge(xsDataSubWedge)
Esempio n. 8
0
    def process(self, _edObject=None):
        EDPluginExec.process(self)
        EDVerbose.DEBUG("EDPluginExecReadImageHeaderMARCCDv10.process")
        xsDataInputReadImageHeader = self.getDataInput()
        xsDataFile = xsDataInputReadImageHeader.getImage()
        strPath = xsDataFile.getPath().getValue()
        dictMARCCDHeader = self.readHeaderMarccd(strPath)
        if (dictMARCCDHeader is None):
            strErrorMessage = "EDPluginExecReadImageHeaderMARCCDv10.process : Cannot read header : %s" % strPath
            EDVerbose.error(strErrorMessage)
            self.addErrorMessage(strErrorMessage)
            self.setFailure()
        else:
            xsDataExperimentalCondition = XSDataExperimentalCondition()
            xsDataDetector = XSDataDetector()

            iNoPixelsX = int(dictMARCCDHeader["nslow"])
            iNoPixelsY = int(dictMARCCDHeader["nfast"])
            xsDataDetector.setNumberPixelX(XSDataInteger(iNoPixelsX))
            xsDataDetector.setNumberPixelY(XSDataInteger(iNoPixelsY))
            fPixelSizeX = float(dictMARCCDHeader["pixelsize_x"]) / 1000.0
            xsDataDetector.setPixelSizeX(XSDataLength(fPixelSizeX))
            fPixelSizeY = float(dictMARCCDHeader["pixelsize_y"]) / 1000.0
            xsDataDetector.setPixelSizeY(XSDataLength(fPixelSizeY))
            fBeamPositionX = float(dictMARCCDHeader["beam_x"]) / 1000.0
            fBeamPositionY = float(dictMARCCDHeader["beam_y"]) / 1000.0
            # Fix for bug 397 - check if the beam position is close to the centre of the image
            fTwoTheta = float(dictMARCCDHeader["end_twotheta"]) / 1000.0
            xsDataDetector.setTwoTheta(XSDataAngle(fTwoTheta))
            if (abs(fTwoTheta) < 0.1):
                if (abs(fBeamPositionX /
                        (fPixelSizeX / 1000.0) - iNoPixelsX / 2.0) >
                    (2 * iNoPixelsX)):
                    fBeamPositionX = fBeamPositionX * fPixelSizeX / 1000.0
                    fBeamPositionY = fBeamPositionY * fPixelSizeY / 1000.0
            xsDataDetector.setBeamPositionX(XSDataLength(fBeamPositionX))
            xsDataDetector.setBeamPositionY(XSDataLength(fBeamPositionY))
            fDistance = float(dictMARCCDHeader["xtal_to_detector"]) / 1000.0
            if (abs(fDistance) < 0.1):
                fDistanceStart = float(
                    dictMARCCDHeader["start_xtal_to_detector"]) / 1000.0
                fDistanceEnd = float(
                    dictMARCCDHeader["end_xtal_to_detector"]) / 1000.0
                if (abs(fDistanceStart - fDistanceEnd) < 0.1):
                    fDistance = fDistanceStart
                else:
                    # Somethings very wrong with the distances...
                    strErrorMessage = "EDPluginExecReadImageHeaderMARCCDv10.process : Inconsistency in MAR CCD image header: start_xtal_to_detector = %d, end_xtal_to_detector = %d" % \
                                                                           (fDistanceStart, fDistanceEnd)
                    EDVerbose.error(strErrorMessage)
                    self.addErrorMessage(strErrorMessage)
                    self.setFailure()
            xsDataDetector.setDistance(XSDataLength(fDistance))
            xsDataDetector.setNumberBytesInHeader(
                XSDataInteger(float(dictMARCCDHeader["header_size"])))
            #xsDataDetector.setSerialNumber(        XSDataInteger(  dictMARCCDHeader[ "DETECTOR_SN"   ] ) ) )
            #xsDataDetector.setBin(                 XSDataString(   dictMARCCDHeader[ "BIN" ] ) ) )
            #xsDataDetector.setDataType(            XSDataString(   dictMARCCDHeader[ "TYPE" ] ) ) )
            #xsDataDetector.setByteOrder(           XSDataString(   dictMARCCDHeader[ "BYTE_ORDER" ] ) ) )
            xsDataDetector.setImageSaturation(
                XSDataInteger(int(dictMARCCDHeader["saturation_level"])))
            # Determine type of detector...
            if (iNoPixelsX == 2048 and iNoPixelsY == 2048):
                xsDataDetector.setName(XSDataString("MAR CCD 165"))
                xsDataDetector.setType(XSDataString("mar165"))
            elif (iNoPixelsX == 3072 and iNoPixelsY == 3072):
                xsDataDetector.setName(XSDataString("MAR CCD 225"))
                xsDataDetector.setType(XSDataString("mar225"))
            elif (iNoPixelsX == 4096 and iNoPixelsY == 4096):
                xsDataDetector.setName(XSDataString("MAR CCD 325"))
                xsDataDetector.setType(XSDataString("mar325"))
            else:
                strErrorMessage = EDMessage.ERROR_DATA_HANDLER_02 % (
                    "EDPluginExecReadImageHeaderMARCCDv10.process",
                    "Unknown detector type")
                EDVerbose.error(strErrorMessage)
                self.addErrorMessage(strErrorMessage)
                raise RuntimeError, strErrorMessage

            xsDataExperimentalCondition.setDetector(xsDataDetector)

            # Beam object

            xsDataBeam = XSDataBeam()
            xsDataBeam.setWavelength(
                XSDataWavelength(
                    float(dictMARCCDHeader["source_wavelength"]) / 100000.0))
            xsDataBeam.setExposureTime(
                XSDataTime(float(dictMARCCDHeader["exposure_time"]) / 1000.0))
            xsDataExperimentalCondition.setBeam(xsDataBeam)

            # Goniostat object
            xsDataGoniostat = XSDataGoniostat()
            fRotationAxisStart = float(dictMARCCDHeader["start_phi"]) / 1000.0
            fOscillationWidth = float(
                dictMARCCDHeader["rotation_range"]) / 1000.0
            xsDataGoniostat.setRotationAxisStart(
                XSDataAngle(fRotationAxisStart))
            xsDataGoniostat.setRotationAxisEnd(
                XSDataAngle(fRotationAxisStart + fOscillationWidth))
            xsDataGoniostat.setOscillationWidth(XSDataAngle(fOscillationWidth))
            xsDataExperimentalCondition.setGoniostat(xsDataGoniostat)

            # Create the image object
            xsDataImage = XSDataImage()
            xsDataImage.setPath(XSDataString(strPath))
            strTimeStamp = dictMARCCDHeader["acquire_timestamp"]
            xsDataImage.setDate(XSDataString(strTimeStamp))
            iImageNumber = EDUtilsImage.getImageNumber(strPath)
            xsDataImage.setNumber(XSDataInteger(iImageNumber))

            xsDataSubWedge = XSDataSubWedge()
            xsDataSubWedge.setExperimentalCondition(
                xsDataExperimentalCondition)
            xsDataSubWedge.addImage(xsDataImage)

            self.__xsDataResultReadImageHeader = XSDataResultReadImageHeader()
            self.__xsDataResultReadImageHeader.setSubWedge(xsDataSubWedge)