Ejemplo n.º 1
0
    def PyExec(self):
        in_Runs = self.getProperty("RunNumbers").value
        progress = Progress(self, 0., .25, 3)
        finalUnits = self.getPropertyValue("FinalUnits")

        # default arguments for AlignAndFocusPowder
        self.alignAndFocusArgs = {'TMax': 50000,
                                  'RemovePromptPulseWidth': 1600,
                                  'PreserveEvents': False,
                                  'Dspacing': True,  # binning parameters in d-space
                                  'Params': self.getProperty("Binning").value,
                                  }

        # workspace for loading metadata only to be used in LoadDiffCal and
        # CreateGroupingWorkspace
        metaWS = None

        # either type of file-based calibration is stored in the same variable
        calib = self.getProperty("Calibration").value
        detcalFile = None
        if calib == "Calibration File":
            metaWS = self._loadMetaWS(in_Runs[0])
            LoadDiffCal(Filename=self.getPropertyValue("CalibrationFilename"),
                        WorkspaceName='SNAP',
                        InputWorkspace=metaWS,
                        MakeGroupingWorkspace=False, MakeMaskWorkspace=False)
            self.alignAndFocusArgs['CalibrationWorkspace'] = 'SNAP_cal'
        elif calib == 'DetCal File':
            detcalFile = ','.join(self.getProperty('DetCalFilename').value)
        progress.report('loaded calibration')

        norm = self.getProperty("Normalization").value

        if norm == "From Processed Nexus":
            norm_File = self.getProperty("NormalizationFilename").value
            normalizationWS = 'normWS'
            LoadNexusProcessed(Filename=norm_File, OutputWorkspace=normalizationWS)
            progress.report('loaded normalization')
        elif norm == "From Workspace":
            normalizationWS = str(self.getProperty("NormalizationWorkspace").value)
            progress.report('')
        else:
            normalizationWS = None
            progress.report('')

        self.alignAndFocusArgs['GroupingWorkspace'] = self._generateGrouping(in_Runs[0], metaWS, progress)
        self.alignAndFocusArgs['MaskWorkspace'] = self._getMaskWSname(in_Runs[0], metaWS)  # can be empty string

        if metaWS is not None:
            DeleteWorkspace(Workspace=metaWS)

        Process_Mode = self.getProperty("ProcessingMode").value

        prefix = self.getProperty("OptionalPrefix").value

        Tag = 'SNAP'
        progStart = .25
        progDelta = (1.-progStart)/len(in_Runs)

        # --------------------------- PROCESS BACKGROUND ----------------------
        if not self.getProperty('Background').isDefault:
            progDelta = (1. - progStart) / (len(in_Runs) + 1)  # redefine to account for background

            background = 'SNAP_{}'.format(self.getProperty('Background').value)
            self.log().notice("processing run background {}".format(background))
            background, unfocussedBkgd = self._alignAndFocus(background,
                                                             background+'_bkgd_red',
                                                             detCalFilename=detcalFile,
                                                             withUnfocussed=(Process_Mode == 'Set-Up'),
                                                             progStart=progStart, progDelta=progDelta)
        else:
            background = None
            unfocussedBkgd = ''

        # --------------------------- REDUCE DATA -----------------------------

        for i, runnumber in enumerate(in_Runs):
            self.log().notice("processing run %s" % runnumber)
            self.log().information(str(self.get_IPTS_Local(runnumber)))

            # put together output names
            new_Tag = Tag
            if len(prefix) > 0:
                new_Tag = prefix + '_' + new_Tag
            basename = '%s_%s_%s' % (new_Tag, runnumber, self.alignAndFocusArgs['GroupingWorkspace'])
            self.log().warning('{}:{}:{}'.format(i, new_Tag, basename))
            redWS, unfocussedWksp = self._alignAndFocus('SNAP_{}'.format(runnumber),
                                                        basename + '_red',
                                                        detCalFilename=detcalFile,
                                                        withUnfocussed=(Process_Mode == 'Set-Up'),
                                                        progStart=progStart, progDelta=progDelta*.5)
            progStart += .5 * progDelta

            # subtract the background if it was supplied
            if background:
                self.log().information('subtracting {} from {}'.format(background, redWS))
                Minus(LHSWorkspace=redWS, RHSWorkspace=background, OutputWorkspace=redWS)
                # intentionally don't subtract the unfocussed workspace since it hasn't been normalized by counting time

            # the rest takes up .25 percent of the run processing
            progress = Progress(self, progStart, progStart+.25*progDelta, 2)

            # AlignAndFocusPowder leaves the data in time-of-flight
            ConvertUnits(InputWorkspace=redWS, OutputWorkspace=redWS, Target='dSpacing', EMode='Elastic')

            # Edit instrument geometry to make final workspace smaller on disk
            det_table = PreprocessDetectorsToMD(Inputworkspace=redWS,
                                                OutputWorkspace='__SNAP_det_table')
            polar = np.degrees(det_table.column('TwoTheta'))
            azi = np.degrees(det_table.column('Azimuthal'))
            EditInstrumentGeometry(Workspace=redWS, L2=det_table.column('L2'),
                                   Polar=polar, Azimuthal=azi)
            mtd.remove('__SNAP_det_table')
            progress.report('simplify geometry')

            # AlignAndFocus doesn't necessarily rebin the data correctly
            if Process_Mode == "Set-Up":
                Rebin(InputWorkspace=unfocussedWksp, Params=self.alignAndFocusArgs['Params'],
                      Outputworkspace=unfocussedWksp)
                if background:
                    Rebin(InputWorkspace=unfocussedBkgd, Params=self.alignAndFocusArgs['Params'],
                          Outputworkspace=unfocussedBkgd)
            # normalize the data as requested
            normalizationWS = self._generateNormalization(redWS, norm, normalizationWS)
            normalizedWS = None
            if normalizationWS is not None:
                normalizedWS = basename + '_nor'
                Divide(LHSWorkspace=redWS, RHSWorkspace=normalizationWS,
                       OutputWorkspace=normalizedWS)
                ReplaceSpecialValues(Inputworkspace=normalizedWS,
                                     OutputWorkspace=normalizedWS,
                                     NaNValue='0', NaNError='0',
                                     InfinityValue='0', InfinityError='0')
                progress.report('normalized')
            else:
                progress.report()

            # rename everything as appropriate and determine output workspace name
            if normalizedWS is None:
                outputWksp = redWS
            else:
                outputWksp = normalizedWS

                if norm == "Extracted from Data" and Process_Mode == "Production":
                        DeleteWorkspace(Workspace=redWS)
                        DeleteWorkspace(Workspace=normalizationWS)

            # Save requested formats
            saveDir = self.getPropertyValue("OutputDirectory").strip()
            if len(saveDir) <= 0:
                self.log().notice('Using default save location')
                saveDir = os.path.join(self.get_IPTS_Local(runnumber), 'shared', 'data')
            self._save(saveDir, basename, outputWksp)

            # set workspace as an output so it gets history
            ConvertUnits(InputWorkspace=str(outputWksp), OutputWorkspace=str(outputWksp), Target=finalUnits,
                         EMode='Elastic')
            self._exportWorkspace('OutputWorkspace_' + str(outputWksp), outputWksp)

            # declare some things as extra outputs in set-up
            if Process_Mode != "Production":
                propprefix = 'OutputWorkspace_{:d}_'.format(i)
                propNames = [propprefix + it for it in ['d', 'norm', 'normalizer']]
                wkspNames = ['%s_%s_d' % (new_Tag, runnumber),
                             basename + '_red',
                             '%s_%s_normalizer' % (new_Tag, runnumber)]
                for (propName, wkspName) in zip(propNames, wkspNames):
                    self._exportWorkspace(propName, wkspName)

        if background:
            ConvertUnits(InputWorkspace=str(background), OutputWorkspace=str(background), Target=finalUnits,
                         EMode='Elastic')
            prefix = 'OutputWorkspace_{}'.format(len(in_Runs))
            propNames = [prefix + it for it in ['', '_d']]
            wkspNames = [background, unfocussedBkgd]
            for (propName, wkspName) in zip(propNames, wkspNames):
                self._exportWorkspace(propName, wkspName)
Ejemplo n.º 2
0
    def PyExec(self):
        in_Runs = self.getProperty("RunNumbers").value
        maskWSname = self._getMaskWSname()
        progress = Progress(self, 0., .25, 3)

        # default arguments for AlignAndFocusPowder
        alignAndFocusArgs = {'TMax': 50000,
                             'RemovePromptPulseWidth': 1600,
                             'PreserveEvents': False,
                             'Dspacing': True,  # binning parameters in d-space
                             'Params': self.getProperty("Binning").value}

        # workspace for loading metadata only to be used in LoadDiffCal and
        # CreateGroupingWorkspace
        metaWS = None

        # either type of file-based calibration is stored in the same variable
        calib = self.getProperty("Calibration").value
        detcalFile = None
        if calib == "Calibration File":
            metaWS = self._loadMetaWS(in_Runs[0])
            LoadDiffCal(Filename=self.getPropertyValue("CalibrationFilename"),
                        WorkspaceName='SNAP',
                        InputWorkspace=metaWS,
                        MakeGroupingWorkspace=False, MakeMaskWorkspace=False)
            alignAndFocusArgs['CalibrationWorkspace'] = 'SNAP_cal'
        elif calib == 'DetCal File':
            detcalFile = ','.join(self.getProperty('DetCalFilename').value)
        progress.report('loaded calibration')

        norm = self.getProperty("Normalization").value

        if norm == "From Processed Nexus":
            norm_File = self.getProperty("NormalizationFilename").value
            normalizationWS = 'normWS'
            LoadNexusProcessed(Filename=norm_File, OutputWorkspace=normalizationWS)
            progress.report('loaded normalization')
        elif norm == "From Workspace":
            normalizationWS = str(self.getProperty("NormalizationWorkspace").value)
            progress.report('')
        else:
            normalizationWS = None
            progress.report('')

        group = self._generateGrouping(in_Runs[0], metaWS, progress)

        if metaWS is not None:
            DeleteWorkspace(Workspace=metaWS)

        Process_Mode = self.getProperty("ProcessingMode").value

        prefix = self.getProperty("OptionalPrefix").value

        # --------------------------- REDUCE DATA -----------------------------

        Tag = 'SNAP'
        if self.getProperty("LiveData").value:
            Tag = 'Live'

        progStart = .25
        progDelta = (1.-progStart)/len(in_Runs)
        for i, runnumber in enumerate(in_Runs):
            self.log().notice("processing run %s" % runnumber)
            self.log().information(str(self.get_IPTS_Local(runnumber)))

            # put together output names
            new_Tag = Tag
            if len(prefix) > 0:
                new_Tag += '_' + prefix
            basename = '%s_%s_%s' % (new_Tag, runnumber, group)

            if self.getProperty("LiveData").value:
                raise RuntimeError('Live data is not currently supported')
            else:
                Load(Filename='SNAP' + str(runnumber), OutputWorkspace=basename + '_red', startProgress=progStart,
                     endProgress=progStart + .25 * progDelta)
                progStart += .25 * progDelta
            redWS = basename + '_red'

            # overwrite geometry with detcal files
            if calib == 'DetCal File':
                LoadIsawDetCal(InputWorkspace=redWS, Filename=detcalFile)

            # create unfocussed data if in set-up mode
            if Process_Mode == "Set-Up":
                unfocussedWksp = '{}_{}_d'.format(new_Tag, runnumber)
            else:
                unfocussedWksp = ''

            AlignAndFocusPowder(InputWorkspace=redWS, OutputWorkspace=redWS,
                                MaskWorkspace=maskWSname,  # can be empty string
                                GroupingWorkspace=group,
                                UnfocussedWorkspace=unfocussedWksp,  # can be empty string
                                startProgress=progStart,
                                endProgress=progStart + .5 * progDelta,
                                **alignAndFocusArgs)
            progStart += .5 * progDelta

            # the rest takes up .25 percent of the run processing
            progress = Progress(self, progStart, progStart+.25*progDelta, 2)

            # AlignAndFocusPowder leaves the data in time-of-flight
            ConvertUnits(InputWorkspace=redWS, OutputWorkspace=redWS, Target='dSpacing', EMode='Elastic')

            # Edit instrument geometry to make final workspace smaller on disk
            det_table = PreprocessDetectorsToMD(Inputworkspace=redWS,
                                                OutputWorkspace='__SNAP_det_table')
            polar = np.degrees(det_table.column('TwoTheta'))
            azi = np.degrees(det_table.column('Azimuthal'))
            EditInstrumentGeometry(Workspace=redWS, L2=det_table.column('L2'),
                                   Polar=polar, Azimuthal=azi)
            mtd.remove('__SNAP_det_table')
            progress.report('simplify geometry')

            # AlignAndFocus doesn't necessarily rebin the data correctly
            if Process_Mode == "Set-Up":
                Rebin(InputWorkspace=unfocussedWksp, Params=alignAndFocusArgs['Params'],
                      Outputworkspace=unfocussedWksp)

            NormaliseByCurrent(InputWorkspace=redWS, OutputWorkspace=redWS)

            # normalize the data as requested
            normalizationWS = self._generateNormalization(redWS, norm, normalizationWS)
            normalizedWS = None
            if normalizationWS is not None:
                normalizedWS = basename + '_nor'
                Divide(LHSWorkspace=redWS, RHSWorkspace=normalizationWS,
                       OutputWorkspace=normalizedWS)
                ReplaceSpecialValues(Inputworkspace=normalizedWS,
                                     OutputWorkspace=normalizedWS,
                                     NaNValue='0', NaNError='0',
                                     InfinityValue='0', InfinityError='0')
                progress.report('normalized')
            else:
                progress.report()

            # rename everything as appropriate and determine output workspace name
            if normalizedWS is None:
                outputWksp = redWS
            else:
                outputWksp = normalizedWS

                if norm == "Extracted from Data" and Process_Mode == "Production":
                        DeleteWorkspace(Workspace=redWS)
                        DeleteWorkspace(Workspace=normalizationWS)

            # Save requested formats
            saveDir = self.getPropertyValue("OutputDirectory").strip()
            if len(saveDir) <= 0:
                self.log().notice('Using default save location')
                saveDir = os.path.join(self.get_IPTS_Local(runnumber), 'shared', 'data')
            self._save(saveDir, basename, outputWksp)

            # set workspace as an output so it gets history
            propertyName = 'OutputWorkspace_'+str(outputWksp)
            self.declareProperty(WorkspaceProperty(
                propertyName, outputWksp, Direction.Output))
            self.setProperty(propertyName, outputWksp)

            # declare some things as extra outputs in set-up
            if Process_Mode != "Production":
                prefix = 'OuputWorkspace_{:d}_'.format(i)
                propNames = [prefix + it for it in ['d', 'norm', 'normalizer']]
                wkspNames = ['%s_%s_d' % (new_Tag, runnumber),
                             basename + '_red',
                             '%s_%s_normalizer' % (new_Tag, runnumber)]
                for (propName, wkspName) in zip(propNames, wkspNames):
                    if mtd.doesExist(wkspName):
                        self.declareProperty(WorkspaceProperty(propName,
                                                               wkspName,
                                                               Direction.Output))
                        self.setProperty(propName, wkspName)
Ejemplo n.º 3
0
    def PyExec(self):
        in_Runs = self.getProperty("RunNumbers").value
        progress = Progress(self, 0., .25, 3)
        finalUnits = self.getPropertyValue("FinalUnits")
        self.chunkSize = self.getProperty('MaxChunkSize').value

        # default arguments for AlignAndFocusPowder
        self.alignAndFocusArgs = {'Tmin': 0,
                                  'TMax': 50000,
                                  'RemovePromptPulseWidth': 1600,
                                  'PreserveEvents': False,
                                  'Dspacing': True,  # binning parameters in d-space
                                  'Params': self.getProperty("Binning").value,
                                  }

        # workspace for loading metadata only to be used in LoadDiffCal and
        # CreateGroupingWorkspace
        metaWS = None

        # either type of file-based calibration is stored in the same variable
        calib = self.getProperty("Calibration").value
        detcalFile = None
        if calib == "Calibration File":
            metaWS = self._loadMetaWS(in_Runs[0])
            LoadDiffCal(Filename=self.getPropertyValue("CalibrationFilename"),
                        WorkspaceName='SNAP',
                        InputWorkspace=metaWS,
                        MakeGroupingWorkspace=False, MakeMaskWorkspace=False)
            self.alignAndFocusArgs['CalibrationWorkspace'] = 'SNAP_cal'
        elif calib == 'DetCal File':
            detcalFile = ','.join(self.getProperty('DetCalFilename').value)
        progress.report('loaded calibration')

        norm = self.getProperty("Normalization").value

        if norm == "From Processed Nexus":
            norm_File = self.getProperty("NormalizationFilename").value
            normalizationWS = 'normWS'
            LoadNexusProcessed(Filename=norm_File, OutputWorkspace=normalizationWS)
            progress.report('loaded normalization')
        elif norm == "From Workspace":
            normalizationWS = str(self.getProperty("NormalizationWorkspace").value)
            progress.report('')
        else:
            normalizationWS = None
            progress.report('')

        self.alignAndFocusArgs['GroupingWorkspace'] = self._generateGrouping(in_Runs[0], metaWS, progress)
        self.alignAndFocusArgs['MaskWorkspace'] = self._getMaskWSname(in_Runs[0], metaWS)  # can be empty string

        if metaWS is not None:
            DeleteWorkspace(Workspace=metaWS)

        Process_Mode = self.getProperty("ProcessingMode").value

        prefix = self.getProperty("OptionalPrefix").value

        Tag = 'SNAP'
        progStart = .25
        progDelta = (1.-progStart)/len(in_Runs)

        # --------------------------- PROCESS BACKGROUND ----------------------
        if not self.getProperty('Background').isDefault:
            progDelta = (1. - progStart) / (len(in_Runs) + 1)  # redefine to account for background

            background = 'SNAP_{}'.format(self.getProperty('Background').value)
            self.log().notice("processing run background {}".format(background))
            background, unfocussedBkgd = self._alignAndFocus(background,
                                                             background+'_bkgd_red',
                                                             detCalFilename=detcalFile,
                                                             withUnfocussed=(Process_Mode == 'Set-Up'),
                                                             progStart=progStart, progDelta=progDelta)
        else:
            background = None
            unfocussedBkgd = ''

        # --------------------------- REDUCE DATA -----------------------------

        for i, runnumber in enumerate(in_Runs):
            self.log().notice("processing run %s" % runnumber)

            # put together output names
            new_Tag = Tag
            if len(prefix) > 0:
                new_Tag = prefix + '_' + new_Tag
            basename = '%s_%s_%s' % (new_Tag, runnumber, self.alignAndFocusArgs['GroupingWorkspace'])
            self.log().warning('{}:{}:{}'.format(i, new_Tag, basename))
            redWS, unfocussedWksp = self._alignAndFocus('SNAP_{}'.format(runnumber),
                                                        basename + '_red',
                                                        detCalFilename=detcalFile,
                                                        withUnfocussed=(Process_Mode == 'Set-Up'),
                                                        progStart=progStart, progDelta=progDelta*.5)
            progStart += .5 * progDelta

            # subtract the background if it was supplied
            if background:
                self.log().information('subtracting {} from {}'.format(background, redWS))
                Minus(LHSWorkspace=redWS, RHSWorkspace=background, OutputWorkspace=redWS)
                # intentionally don't subtract the unfocussed workspace since it hasn't been normalized by counting time

            # the rest takes up .25 percent of the run processing
            progress = Progress(self, progStart, progStart+.25*progDelta, 2)

            # AlignAndFocusPowder leaves the data in time-of-flight
            ConvertUnits(InputWorkspace=redWS, OutputWorkspace=redWS, Target='dSpacing', EMode='Elastic')

            # Edit instrument geometry to make final workspace smaller on disk
            det_table = PreprocessDetectorsToMD(Inputworkspace=redWS,
                                                OutputWorkspace='__SNAP_det_table')
            polar = np.degrees(det_table.column('TwoTheta'))
            azi = np.degrees(det_table.column('Azimuthal'))
            EditInstrumentGeometry(Workspace=redWS, L2=det_table.column('L2'),
                                   Polar=polar, Azimuthal=azi)
            mtd.remove('__SNAP_det_table')
            progress.report('simplify geometry')

            # AlignAndFocus doesn't necessarily rebin the data correctly
            if Process_Mode == "Set-Up":
                Rebin(InputWorkspace=unfocussedWksp, Params=self.alignAndFocusArgs['Params'],
                      Outputworkspace=unfocussedWksp)
                if background:
                    Rebin(InputWorkspace=unfocussedBkgd, Params=self.alignAndFocusArgs['Params'],
                          Outputworkspace=unfocussedBkgd)
            # normalize the data as requested
            normalizationWS = self._generateNormalization(redWS, norm, normalizationWS)
            normalizedWS = None
            if normalizationWS is not None:
                normalizedWS = basename + '_nor'
                Divide(LHSWorkspace=redWS, RHSWorkspace=normalizationWS,
                       OutputWorkspace=normalizedWS)
                ReplaceSpecialValues(Inputworkspace=normalizedWS,
                                     OutputWorkspace=normalizedWS,
                                     NaNValue='0', NaNError='0',
                                     InfinityValue='0', InfinityError='0')
                progress.report('normalized')
            else:
                progress.report()

            # rename everything as appropriate and determine output workspace name
            if normalizedWS is None:
                outputWksp = redWS
            else:
                outputWksp = normalizedWS

                if norm == "Extracted from Data" and Process_Mode == "Production":
                        DeleteWorkspace(Workspace=redWS)
                        DeleteWorkspace(Workspace=normalizationWS)

            # Save requested formats - function checks that saving is requested
            self._save(runnumber, basename, outputWksp)

            # set workspace as an output so it gets history
            ConvertUnits(InputWorkspace=str(outputWksp), OutputWorkspace=str(outputWksp), Target=finalUnits,
                         EMode='Elastic')
            self._exportWorkspace('OutputWorkspace_' + str(outputWksp), outputWksp)

            # declare some things as extra outputs in set-up
            if Process_Mode != "Production":
                propprefix = 'OutputWorkspace_{:d}_'.format(i)
                propNames = [propprefix + it for it in ['d', 'norm', 'normalizer']]
                wkspNames = ['%s_%s_d' % (new_Tag, runnumber),
                             basename + '_red',
                             '%s_%s_normalizer' % (new_Tag, runnumber)]
                for (propName, wkspName) in zip(propNames, wkspNames):
                    self._exportWorkspace(propName, wkspName)

        if background:
            ConvertUnits(InputWorkspace=str(background), OutputWorkspace=str(background), Target=finalUnits,
                         EMode='Elastic')
            prefix = 'OutputWorkspace_{}'.format(len(in_Runs))
            propNames = [prefix + it for it in ['', '_d']]
            wkspNames = [background, unfocussedBkgd]
            for (propName, wkspName) in zip(propNames, wkspNames):
                self._exportWorkspace(propName, wkspName)
Ejemplo n.º 4
0
    def PyExec(self):
        in_Runs = self.getProperty("RunNumbers").value
        maskWSname = self._getMaskWSname()
        progress = Progress(self, 0., .25, 3)

        # default arguments for AlignAndFocusPowder
        alignAndFocusArgs = {
            'TMax': 50000,
            'RemovePromptPulseWidth': 1600,
            'PreserveEvents': False,
            'Dspacing': True,  # binning parameters in d-space
            'Params': self.getProperty("Binning").value
        }

        # workspace for loading metadata only to be used in LoadDiffCal and
        # CreateGroupingWorkspace
        metaWS = None

        # either type of file-based calibration is stored in the same variable
        calib = self.getProperty("Calibration").value
        detcalFile = None
        if calib == "Calibration File":
            metaWS = self._loadMetaWS(in_Runs[0])
            LoadDiffCal(Filename=self.getPropertyValue("CalibrationFilename"),
                        WorkspaceName='SNAP',
                        InputWorkspace=metaWS,
                        MakeGroupingWorkspace=False,
                        MakeMaskWorkspace=False)
            alignAndFocusArgs['CalibrationWorkspace'] = 'SNAP_cal'
        elif calib == 'DetCal File':
            detcalFile = ','.join(self.getProperty('DetCalFilename').value)
        progress.report('loaded calibration')

        norm = self.getProperty("Normalization").value

        if norm == "From Processed Nexus":
            norm_File = self.getProperty("NormalizationFilename").value
            normalizationWS = 'normWS'
            LoadNexusProcessed(Filename=norm_File,
                               OutputWorkspace=normalizationWS)
            progress.report('loaded normalization')
        elif norm == "From Workspace":
            normalizationWS = str(
                self.getProperty("NormalizationWorkspace").value)
            progress.report('')
        else:
            normalizationWS = None
            progress.report('')

        group = self._generateGrouping(in_Runs[0], metaWS, progress)

        if metaWS is not None:
            DeleteWorkspace(Workspace=metaWS)

        Process_Mode = self.getProperty("ProcessingMode").value

        prefix = self.getProperty("OptionalPrefix").value

        # --------------------------- REDUCE DATA -----------------------------

        Tag = 'SNAP'
        if self.getProperty("LiveData").value:
            Tag = 'Live'

        progStart = .25
        progDelta = (1. - progStart) / len(in_Runs)
        for i, runnumber in enumerate(in_Runs):
            self.log().notice("processing run %s" % runnumber)
            self.log().information(str(self.get_IPTS_Local(runnumber)))

            # put together output names
            new_Tag = Tag
            if len(prefix) > 0:
                new_Tag += '_' + prefix
            basename = '%s_%s_%s' % (new_Tag, runnumber, group)

            if self.getProperty("LiveData").value:
                raise RuntimeError('Live data is not currently supported')
            else:
                Load(Filename='SNAP' + str(runnumber),
                     OutputWorkspace=basename + '_red',
                     startProgress=progStart,
                     endProgress=progStart + .25 * progDelta)
                progStart += .25 * progDelta
            redWS = basename + '_red'

            # overwrite geometry with detcal files
            if calib == 'DetCal File':
                LoadIsawDetCal(InputWorkspace=redWS, Filename=detcalFile)

            # create unfocussed data if in set-up mode
            if Process_Mode == "Set-Up":
                unfocussedWksp = '{}_{}_d'.format(new_Tag, runnumber)
            else:
                unfocussedWksp = ''

            AlignAndFocusPowder(
                InputWorkspace=redWS,
                OutputWorkspace=redWS,
                MaskWorkspace=maskWSname,  # can be empty string
                GroupingWorkspace=group,
                UnfocussedWorkspace=unfocussedWksp,  # can be empty string
                startProgress=progStart,
                endProgress=progStart + .5 * progDelta,
                **alignAndFocusArgs)
            progStart += .5 * progDelta

            # the rest takes up .25 percent of the run processing
            progress = Progress(self, progStart, progStart + .25 * progDelta,
                                2)

            # AlignAndFocusPowder leaves the data in time-of-flight
            ConvertUnits(InputWorkspace=redWS,
                         OutputWorkspace=redWS,
                         Target='dSpacing',
                         EMode='Elastic')

            # Edit instrument geometry to make final workspace smaller on disk
            det_table = PreprocessDetectorsToMD(
                Inputworkspace=redWS, OutputWorkspace='__SNAP_det_table')
            polar = np.degrees(det_table.column('TwoTheta'))
            azi = np.degrees(det_table.column('Azimuthal'))
            EditInstrumentGeometry(Workspace=redWS,
                                   L2=det_table.column('L2'),
                                   Polar=polar,
                                   Azimuthal=azi)
            mtd.remove('__SNAP_det_table')
            progress.report('simplify geometry')

            # AlignAndFocus doesn't necessarily rebin the data correctly
            if Process_Mode == "Set-Up":
                Rebin(InputWorkspace=unfocussedWksp,
                      Params=alignAndFocusArgs['Params'],
                      Outputworkspace=unfocussedWksp)

            NormaliseByCurrent(InputWorkspace=redWS, OutputWorkspace=redWS)

            # normalize the data as requested
            normalizationWS = self._generateNormalization(
                redWS, norm, normalizationWS)
            normalizedWS = None
            if normalizationWS is not None:
                normalizedWS = basename + '_nor'
                Divide(LHSWorkspace=redWS,
                       RHSWorkspace=normalizationWS,
                       OutputWorkspace=normalizedWS)
                ReplaceSpecialValues(Inputworkspace=normalizedWS,
                                     OutputWorkspace=normalizedWS,
                                     NaNValue='0',
                                     NaNError='0',
                                     InfinityValue='0',
                                     InfinityError='0')
                progress.report('normalized')
            else:
                progress.report()

            # rename everything as appropriate and determine output workspace name
            if normalizedWS is None:
                outputWksp = redWS
            else:
                outputWksp = normalizedWS

                if norm == "Extracted from Data" and Process_Mode == "Production":
                    DeleteWorkspace(Workspace=redWS)
                    DeleteWorkspace(Workspace=normalizationWS)

            # Save requested formats
            saveDir = self.getPropertyValue("OutputDirectory").strip()
            if len(saveDir) <= 0:
                self.log().notice('Using default save location')
                saveDir = os.path.join(self.get_IPTS_Local(runnumber),
                                       'shared', 'data')
            self._save(saveDir, basename, outputWksp)

            # set workspace as an output so it gets history
            propertyName = 'OutputWorkspace_' + str(outputWksp)
            self.declareProperty(
                WorkspaceProperty(propertyName, outputWksp, Direction.Output))
            self.setProperty(propertyName, outputWksp)

            # declare some things as extra outputs in set-up
            if Process_Mode != "Production":
                prefix = 'OuputWorkspace_{:d}_'.format(i)
                propNames = [prefix + it for it in ['d', 'norm', 'normalizer']]
                wkspNames = [
                    '%s_%s_d' % (new_Tag, runnumber), basename + '_red',
                    '%s_%s_normalizer' % (new_Tag, runnumber)
                ]
                for (propName, wkspName) in zip(propNames, wkspNames):
                    if mtd.doesExist(wkspName):
                        self.declareProperty(
                            WorkspaceProperty(propName, wkspName,
                                              Direction.Output))
                        self.setProperty(propName, wkspName)
Ejemplo n.º 5
0
    def PyExec(self):
        # Retrieve all relevant notice

        in_Runs = self.getProperty("RunNumbers").value

        maskWSname = self._getMaskWSname()

        calib = self.getProperty("Calibration").value
        if calib == "Calibration File":
            cal_File = self.getProperty("CalibrationFilename").value

        params = self.getProperty("Binning").value
        norm = self.getProperty("Normalization").value

        if norm == "From Processed Nexus":
            norm_File = self.getProperty("Normalization filename").value
            normWS = LoadNexusProcessed(Filename=norm_File)
        elif norm == "From Workspace":
            normWS = self.getProperty("NormalizationWorkspace").value
        else:
            normWS = None

        group_to_real = {'Banks':'Group', 'Modules':'bank', '2_4 Grouping':'2_4_Grouping'}
        group = self.getProperty("GroupDetectorsBy").value
        real_name = group_to_real.get(group, group)

        if not mtd.doesExist(group):
            if group == "2_4 Grouping":
                group = real_name
                LoadDetectorsGroupingFile(InputFile=r'/SNS/SNAP/shared/libs/SNAP_group_2_4.xml',
                                          OutputWorkspace=group)
            else:
                CreateGroupingWorkspace(InstrumentName='SNAP', GroupDetectorsBy=real_name,
                                        OutputWorkspace=group)

        Process_Mode = self.getProperty("ProcessingMode").value

        prefix = self.getProperty("OptionalPrefix").value

        # --------------------------- REDUCE DATA -----------------------------

        Tag = 'SNAP'
        for r in in_Runs:
            self.log().notice("processing run %s" % r)
            self.log().information(str(self.get_IPTS_Local(r)))
            if self.getProperty("LiveData").value:
                Tag = 'Live'
                WS = LoadPreNexusLive(Instrument='SNAP')
            else:
                WS = Load(Filename='SNAP' + str(r), Outputworkspace='WS')
                WS = NormaliseByCurrent(InputWorkspace=WS,
                                        Outputworkspace='WS')

            WS = CompressEvents(InputWorkspace=WS, Outputworkspace='WS')
            WS = CropWorkspace(InputWorkspace='WS',
                               OutputWorkspace='WS', XMax=50000)
            WS = RemovePromptPulse(InputWorkspace=WS, OutputWorkspace='WS',
                                   Width='1600', Frequency='60.4')

            if maskWSname is not None:
                WS = MaskDetectors(Workspace=WS, MaskedWorkspace=maskWSname)

            if calib == "Convert Units":
                WS_d = ConvertUnits(InputWorkspace='WS',
                                    Target='dSpacing', Outputworkspace='WS_d')
            else:
                self.log().notice("\n calibration file : %s" % cal_File)
                WS_d = AlignDetectors(
                    InputWorkspace='WS', CalibrationFile=cal_File, Outputworkspace='WS_d')

            WS_d = Rebin(InputWorkspace=WS_d, Params=params,
                         Outputworkspace='WS_d')

            WS_red = DiffractionFocussing(InputWorkspace=WS_d, GroupingWorkspace=group,
                                          PreserveEvents=False)

            normWS = self._generateNormalization(WS_red, norm, normWS)
            WS_nor = None
            if normWS is not None:
                WS_nor = Divide(LHSWorkspace=WS_red, RHSWorkspace=normWS)
                WS_nor = ReplaceSpecialValues(Inputworkspace=WS_nor,
                                              NaNValue='0', NaNError='0',
                                              InfinityValue='0', InfinityError='0')

            new_Tag = Tag
            if len(prefix) > 0:
                new_Tag += '_' + prefix

            # Edit instrument geomety to make final workspace smaller on disk
            det_table = PreprocessDetectorsToMD(Inputworkspace='WS_red',
                                                OutputWorkspace='__SNAP_det_table')
            polar = np.degrees(det_table.column('TwoTheta'))
            azi = np.degrees(det_table.column('Azimuthal'))
            EditInstrumentGeometry(Workspace="WS_red", L2=det_table.column('L2'),
                                   Polar=polar, Azimuthal=azi)
            if WS_nor is not None:
                EditInstrumentGeometry(Workspace="WS_nor", L2=det_table.column('L2'),
                                       Polar=polar, Azimuthal=azi)
            mtd.remove('__SNAP_det_table')

            # Save requested formats
            basename = '%s_%s_%s' % (new_Tag, r, group)
            self._save(r, basename, norm)

            # temporary workspace no longer needed
            DeleteWorkspace(Workspace='WS')

            # rename everything as appropriate and determine output workspace name
            RenameWorkspace(Inputworkspace='WS_d',
                            OutputWorkspace='%s_%s_d' % (new_Tag, r))
            RenameWorkspace(Inputworkspace='WS_red',
                            OutputWorkspace=basename + '_red')
            if norm == 'None':
                outputWksp = basename + '_red'
            else:
                outputWksp = basename + '_nor'
                RenameWorkspace(Inputworkspace='WS_nor',
                                OutputWorkspace=basename + '_nor')
            if norm == "Extracted from Data":
                RenameWorkspace(Inputworkspace='peak_clip_WS',
                                OutputWorkspace='%s_%s_normalizer' % (new_Tag, r))

            # delte some things in production
            if Process_Mode == "Production":
                DeleteWorkspace(Workspace='%s_%s_d' % (new_Tag, r)) # was 'WS_d'

                if norm != "None":
                    DeleteWorkspace(Workspace=basename + '_red') # was 'WS_red'

                if norm == "Extracted from Data":
                    DeleteWorkspace(Workspace='%s_%s_normalizer' % (new_Tag, r)) # was 'peak_clip_WS'

            propertyName = 'OutputWorkspace'
            self.declareProperty(WorkspaceProperty(
                propertyName, outputWksp, Direction.Output))
            self.setProperty(propertyName, outputWksp)
Ejemplo n.º 6
0
def create_absorption_input(
    filename,
    props,
    num_wl_bins=1000,
    material=None,
    geometry=None,
    environment=None,
    opt_wl_min=0,
    opt_wl_max=Property.EMPTY_DBL,
    metaws=None,
):
    """
    Create an input workspace for carpenter or other absorption corrections

    :param filename: Input file to retrieve properties from the sample log
    :param props: PropertyManager of run characterizations, obtained from PDDetermineCharacterizations
    :param num_wl_bins: The number of wavelength bins used for absorption correction
    :param material: Optional material to use in SetSample
    :param geometry: Optional geometry to use in SetSample
    :param environment: Optional environment to use in SetSample
    :param opt_wl_min: Optional minimum wavelength. If specified, this is used instead of from the props
    :param opt_wl_max: Optional maximum wavelength. If specified, this is used instead of from the props
    :param metaws: Optional workspace name with metadata to use for donor workspace instead of reading from filename
    :return: Name of the donor workspace created
    """
    if props is None:
        raise RuntimeError(
            "props is required to create donor workspace, props is None")

    if not isinstance(props, PropertyManager):
        raise RuntimeError("props must be a PropertyManager object")

    log = Logger('CreateAbsorptionInput')

    # Load from file if no workspace with metadata has been given, otherwise avoid a duplicate load with the metaws
    absName = metaws
    if metaws is None:
        absName = '__{}_abs'.format(_getBasename(filename))
        allowed_log = ",".join([
            'SampleFormula', 'SampleDensity',
            "BL11A:CS:ITEMS:HeightInContainerUnits", "SampleContainer",
            "SampleMass"
        ])
        Load(Filename=filename,
             OutputWorkspace=absName,
             MetaDataOnly=True,
             AllowList=allowed_log)

    # first attempt to get the wavelength range from the properties file
    wl_min, wl_max = props['wavelength_min'].value, props[
        'wavelength_max'].value
    # override that with what was given as parameters to the algorithm
    if opt_wl_min > 0.:
        wl_min = opt_wl_min
    if opt_wl_max != Property.EMPTY_DBL:
        wl_max = opt_wl_max

    # if it isn't found by this point, guess it from the time-of-flight range
    if (wl_min == wl_max == 0.):
        tof_min = props['tof_min'].value
        tof_max = props['tof_max'].value
        if tof_min >= 0. and tof_max > tof_min:
            log.information('TOF range is {} to {} microseconds'.format(
                tof_min, tof_max))

            # determine L1
            instr = mtd[absName].getInstrument()
            L1 = instr.getSource().getDistance(instr.getSample())
            # determine L2 range
            PreprocessDetectorsToMD(InputWorkspace=absName,
                                    OutputWorkspace=absName + '_dets',
                                    GetMaskState=False)
            L2 = mtd[absName + '_dets'].column('L2')
            Lmin = np.min(L2) + L1
            Lmax = np.max(L2) + L1
            DeleteWorkspace(Workspace=absName + '_dets')

            log.information('Distance range is {} to {} meters'.format(
                Lmin, Lmax))

            # wavelength is h*TOF / m_n * L  values copied from Kernel/PhysicalConstants.h
            usec_to_sec = 1.e-6
            meter_to_angstrom = 1.e10
            h_m_n = meter_to_angstrom * usec_to_sec * 6.62606896e-34 / 1.674927211e-27
            wl_min = h_m_n * tof_min / Lmax
            wl_max = h_m_n * tof_max / Lmin

    # there isn't a good way to guess it so error out
    if wl_max <= wl_min:
        DeleteWorkspace(Workspace=absName)  # no longer needed
        raise RuntimeError('Invalid wavelength range min={}A max={}A'.format(
            wl_min, wl_max))
    log.information('Using wavelength range min={}A max={}A'.format(
        wl_min, wl_max))

    absorptionWS = WorkspaceFactory.create(
        mtd[absName],
        NVectors=mtd[absName].getNumberHistograms(),
        XLength=num_wl_bins + 1,
        YLength=num_wl_bins)
    xaxis = np.arange(0., float(num_wl_bins + 1)) * (wl_max - wl_min) / (
        num_wl_bins) + wl_min
    for i in range(absorptionWS.getNumberHistograms()):
        absorptionWS.setX(i, xaxis)
    absorptionWS.getAxis(0).setUnit('Wavelength')

    # this effectively deletes the metadata only workspace
    AnalysisDataService.addOrReplace(absName, absorptionWS)

    # Set ChemicalFormula, and either SampleMassDensity or Mass, if SampleMassDensity not set
    if material is not None:
        if (not material['ChemicalFormula']) and ("SampleFormula"
                                                  in absorptionWS.run()):
            material['ChemicalFormula'] = absorptionWS.run(
            )['SampleFormula'].lastValue().strip()
        if ("SampleMassDensity" not in material or
                not material['SampleMassDensity']) and ("SampleDensity"
                                                        in absorptionWS.run()):
            if (absorptionWS.run()['SampleDensity'].lastValue() != 1.0) and (
                    absorptionWS.run()['SampleDensity'].lastValue() != 0.0):
                material['SampleMassDensity'] = absorptionWS.run(
                )['SampleDensity'].lastValue()
            else:
                material['Mass'] = absorptionWS.run()['SampleMass'].lastValue()

    # Set height for computing density if height not set
    if geometry is None:
        geometry = {}

    if geometry is not None:
        if "Height" not in geometry or not geometry['Height']:
            # Check units - SetSample expects cm
            if absorptionWS.run(
            )['BL11A:CS:ITEMS:HeightInContainerUnits'].lastValue() == "mm":
                conversion = 0.1
            elif absorptionWS.run(
            )['BL11A:CS:ITEMS:HeightInContainerUnits'].lastValue() == "cm":
                conversion = 1.0
            else:
                raise ValueError(
                    "HeightInContainerUnits expects cm or mm; specified units not recognized: ",
                    absorptionWS.run()
                    ['BL11A:CS:ITEMS:HeightInContainerUnits'].lastValue())

            geometry['Height'] = absorptionWS.run(
            )['BL11A:CS:ITEMS:HeightInContainer'].lastValue() * conversion

    # Set container if not set
    if environment is not None:
        if environment['Container'] == "":
            environment['Container'] = absorptionWS.run(
            )['SampleContainer'].lastValue().replace(" ", "")

    # Make sure one is set before calling SetSample
    if material or geometry or environment is not None:
        setup_sample(absName, material, geometry, environment)

    return absName
Ejemplo n.º 7
0
 def _getDetWS(self, input_workspace):
     """ Precalculates the detector workspace for ConvertToMD - workaround for bug for indirect geometry """
     wsdet = str(uuid.uuid4().hex)
     wsdet = PreprocessDetectorsToMD(OutputWorkspace=wsdet, StoreInADS=False, InputWorkspace=input_workspace)
     return wsdet