def toENDF6( self, MT, endfMFList, flags, targetInfo ) :
LAW, LEP = 1, 2
EInInterpolation = gndToENDF6Module.axisToEndfInterpolationFlag( self.axes[1] )
E_ins = [ [ EpCl.value, {} ] for EpCl in self[0].EpP ]
for l_EEpCl in self :
for indexE, EpCl in enumerate( l_EEpCl ) :
if( EpCl.value != E_ins[indexE][0] ) :
raise Exception( "E_in = %s not in list E_ins" % EpCl.value )
for Ep, Cl in EpCl :
if( Ep not in E_ins[indexE][1] ) :
E_ins[indexE][1][Ep] = []
for l in xrange( l_EEpCl.l ) : E_ins[indexE][1][Ep].append( 0. )
E_ins[indexE][1][Ep].append( Cl )
ENDFDataList = [ endfFormatsModule.endfContLine( 0, 0, 1, LEP, 1, len( E_ins ) ) ]
ENDFDataList += endfFormatsModule.endfInterpolationList( [ len( E_ins ), EInInterpolation ] )
for Es in E_ins :
NA, data = 0, []
for key in sorted( Es[1] ) :
LegendreSeries = Es[1][key]
NA = max( len( LegendreSeries ) , NA )
data += [ key ] + LegendreSeries
ENDFDataList.append( endfFormatsModule.endfContLine( 0, Es[0], 0, NA - 1, len( data ), len( data ) / ( NA + 1 ) ) )
ENDFDataList += endfFormatsModule.endfDataList( data )
gndToENDF6Module.toENDF6_MF6( MT, endfMFList, flags, targetInfo, LAW, self.productFrame, ENDFDataList )
def toENDF6( self, flags, targetInfo ) :
MT = 5
EInInterpolation = gndToENDF6Module.gndToENDF2PlusDInterpolationFlag( self.interpolation, self.interpolationQualifier )
EpInterpolation0 = gndToENDF6Module.gndToENDF2PlusDInterpolationFlag( self[0].interpolation, self[0].interpolationQualifier )
if( EpInterpolation0 == 1 ) : # flat interpolation
LEP = 1
elif( EpInterpolation0 == 2 ) : # lin-lin interpolation
LEP = 2
else :
raise 'hell - fix me'
ENDFDataList = [ endfFormatsModule.endfContLine( 0, 0, 1, LEP, 1, len( self ) ) ]
ENDFDataList += endfFormatsModule.endfInterpolationList( [ len( self ), EInInterpolation ] )
energyInFactor = PQUModule.PQU( 1, self.axes[3].unit ).getValueAs( 'eV' )
energyPFactor = PQUModule.PQU( 1, self.axes[2].unit ).getValueAs( 'eV' )
for energyIn in self :
if( not( isinstance( energyIn, multiD_XYsModule.XYs2d ) ) ) : raise 'hell - fix me'
EpInterpolation = gndToENDF6Module.gndToENDF2PlusDInterpolationFlag( energyIn.interpolation, energyIn.interpolationQualifier )
if( EpInterpolation != EpInterpolation0 ) : raise 'hell - fix me'
NA, data = 0, []
for energy_p in energyIn :
if( not( isinstance( energy_p, series1dModule.LegendreSeries ) ) ) : raise 'hell - fix me'
NA = max( len( energy_p ) , NA )
coefficients = [ coefficient / energyPFactor for coefficient in energy_p ]
data += [ energy_p.value * energyPFactor ] + coefficients
ENDFDataList.append( endfFormatsModule.endfContLine( 0, energyIn.value * energyInFactor, 0, NA - 1, len( data ), len( data ) / ( NA + 1 ) ) )
ENDFDataList += endfFormatsModule.endfDataList( data )
LAW = 1
return( LAW, ENDFDataList )
def toENDF6(self, MT, endfMFList, flags, targetInfo):
endfMFList[1][MT] = [
endfFormatsModule.endfHeadLine(targetInfo['ZA'], targetInfo['mass'], 0,
1, 0, 0)
]
endfMFList[1][MT] += [
endfFormatsModule.endfHeadLine(0, 0, 0, 0, len(self), 0)
]
endfMFList[1][MT] += endfFormatsModule.endfDataList(
self.coefficients) + [endfFormatsModule.endfSENDLineNumber()]
def toENDF6(self, MT, endfMFList, flags, targetInfo):
data = []
for xy in self.copyDataToXYs(xUnitTo='eV', yUnitTo='eV'):
data += xy
NE = len(self)
EInInterpolation = gndToENDF6Module.gndToENDFInterpolationFlag(
self.interpolation)
ENDFDataList = [ endfFormatsModule.endfContLine( 0, 0, 0, 0, 1, NE ) ] + \
endfFormatsModule.endfInterpolationList( [ NE, EInInterpolation ] )
ENDFDataList += endfFormatsModule.endfDataList(data)
return (standardsModule.frames.labToken, ENDFDataList)
def toENDF6(self, MT, endfMFList, flags, targetInfo):
if (MT == 502): MT = self.ancestor.ENDFMT
Z = targetInfo['ZA'] / 1000
endfInterpolation = gndToENDF6Module.gndToENDFInterpolationFlag(
self.interpolation)
data = []
for xy in self.copyDataToXYs(xUnitTo='eV', yUnitTo=''):
data += xy
endfMFList[27][MT] = [ endfFormatsModule.endfHeadLine( targetInfo['ZA'], targetInfo['mass'], 0, 0, 0, 0 ),
endfFormatsModule.endfContLine( 0, Z, 0, 0, 1, len( data ) / 2 ) ] + \
endfFormatsModule.endfInterpolationList( ( len( data ) / 2, endfInterpolation ) ) + \
endfFormatsModule.endfDataList( data ) + [ endfFormatsModule.endfSENDLineNumber( ) ]
def LTP_oneSubParsing(LTP, LIDP, nuclear, interferenceReal,
interferenceImaginary, lineData):
if LIDP:
NL = len(nuclear) - 1
NW = 3 * NL + 3
else:
NL = (len(nuclear) - 1) // 2
NW = 4 * NL + 3
lineData.append(
endfFormatsModule.endfContLine(0, nuclear.value, LTP, 0, NW, NL))
legendreDat = nuclear.coefficients
for j, r in enumerate(interferenceReal.coefficients):
legendreDat.append(r)
legendreDat.append(interferenceImaginary[j])
lineData += endfFormatsModule.endfDataList(legendreDat)
def toENDF6(self, MT, endfMFList, flags, targetInfo):
fSubform = self.fSubform.data
rSubform = self.rSubform.data
aSubform = self.aSubform
if (not (aSubform.isEmptyASubform())): raise 'hell - FIXME'
outgoingInterpolation = set([val.interpolation for val in fSubform] +
[val.interpolation for val in rSubform])
if len(outgoingInterpolation) != 1:
raise NotImplementedError(
"Only one outgoing interpolation supported when writing Kalbach-Mann to ENDF-6"
)
LEP = {'flat': 1, 'lin-lin': 2}[outgoingInterpolation.pop()]
ENDFDataList = [
endfFormatsModule.endfContLine(0, 0, 2, LEP, 1, len(fSubform))
]
ENDFDataList += endfFormatsModule.endfInterpolationList([len(fSubform), 2])
EInUnit = fSubform.axes[2].unit
EpUnit = fSubform.axes[1].unit
fUnit = fSubform.axes[0].unit
EInFactor = PQUModule.PQU(1, EInUnit).getValueAs('eV')
EpFactor = PQUModule.PQU(1, EpUnit).getValueAs('eV')
fFactor = PQUModule.PQU(1, fUnit).getValueAs('1/eV')
for i1, fAtEnergy in enumerate(fSubform):
rAtEnergy = rSubform[i1]
if (not (isinstance(fAtEnergy, XYsModule.XYs1d))): raise 'hell - FIXME'
if (not (isinstance(rAtEnergy, XYsModule.XYs1d))): raise 'hell - FIXME'
value = fAtEnergy.value
if (value != rAtEnergy.value): raise 'hell - FIXME'
value *= EInFactor
coefficients = []
for i1, (Ep1, f1) in enumerate(fAtEnergy):
Ep2, r1 = rAtEnergy[i1]
if (Ep1 != Ep2): raise 'hell - FIXME'
coefficients += [EpFactor * Ep1, fFactor * f1, r1]
length = len(coefficients)
ENDFDataList += [
endfFormatsModule.endfContLine(0, value, 0, 1, length, length / 3)
]
ENDFDataList += endfFormatsModule.endfDataList(coefficients)
gndToENDF6Module.toENDF6_MF6(MT, endfMFList, flags, targetInfo, 1,
self.productFrame, ENDFDataList)
def toENDF6( self, MT, endfMFList, flags, targetInfo ) :
EInInterpolation = gndToENDF6Module.axisToEndfInterpolationFlag( self.axes[0] )
independent, dependent, qualifier = self.axes[1].interpolation.getInterpolationTokens( )
if( dependent == standardsModule.interpolation.flatToken ) :
LEP = 1 # interpolation for Eout
else :
LEP = 2
ENDFDataList = [ endfFormatsModule.endfContLine( 0, 0, 1, LEP, 1, len( self ) ) ]
ENDFDataList += endfFormatsModule.endfInterpolationList( [ len( self ), EInInterpolation ] )
for energy_in in self :
NA, data = 0, []
for w_xys_LegendreSeries in energy_in :
NA = max( len( w_xys_LegendreSeries) , NA )
data += [ w_xys_LegendreSeries.value ] + w_xys_LegendreSeries.coefficients
ENDFDataList.append( endfFormatsModule.endfContLine( 0, energy_in.value, 0, NA - 1, len( data ), len( data ) / ( NA + 1 ) ) )
ENDFDataList += endfFormatsModule.endfDataList( data )
LAW = 1
gndToENDF6Module.toENDF6_MF6( MT, endfMFList, flags, targetInfo, LAW, self.productFrame, ENDFDataList )
def toENDF6List(self, targetInfo):
interpolationFlatData, multiplicityFlatData = [], []
counter = 0
lastX, lastY = None, None
for region in self:
ENDFInterpolation = gndToENDF6Module.gndToENDFInterpolationFlag(
region.interpolation)
data = region.copyDataToXYs(xUnitTo='eV')
if (lastX is not None):
if (lastY == data[0][1]): data = data[1:]
counter += len(data)
interpolationFlatData.append(counter)
interpolationFlatData.append(ENDFInterpolation)
for xy in data:
multiplicityFlatData += xy
lastX, lastY = data[-1]
return (interpolationFlatData, counter,
endfFormatsModule.endfDataList(multiplicityFlatData))
def toENDF6(self, MT, endfMFList, targetInfo, level, LR):
"""
Convert self into ENDF format
:param int MT: The ENDF reaction designator, MT
:param endfMFList:
:param targetInfo:
:param level:
:param LR:
"""
ZA, mass, QI, QM = targetInfo['ZA'], targetInfo['mass'], targetInfo[
'Q'], targetInfo['QM']
if ('EFL' in targetInfo):
QM = QI
QI = targetInfo['EFL']
else:
if (QM is None):
if (MT in (2, 5)):
QM = QI
elif (MT == 4): # Q should be 0 except for excited-state targets:
QM = 0
if (hasattr(targetInfo['reactionSuite'].target,
'getLevelIndex')):
if (targetInfo['reactionSuite'].target.getLevelIndex() >
0):
QM = QI
else:
QM = QI + level
interpolationFlatData, crossSectionFlatData = self[
targetInfo['style']].toENDF6Data(MT, endfMFList, targetInfo, level)
MF = targetInfo['crossSectionMF']
endfMFList[MF][MT] = [endfFormatsModule.endfHeadLine(ZA, mass, 0, 0, 0, 0)]
endfMFList[MF][MT].append(
endfFormatsModule.endfContLine(QM, QI, 0, LR,
len(interpolationFlatData) / 2,
len(crossSectionFlatData) / 2))
endfMFList[MF][MT] += endfFormatsModule.endfInterpolationList(
interpolationFlatData)
endfMFList[MF][MT] += endfFormatsModule.endfDataList(crossSectionFlatData)
endfMFList[MF][MT].append(endfFormatsModule.endfSENDLineNumber())
def toAngularLegendre(angularSubform, targetInfo, insertSENDL):
"""This should only be called from this module."""
NM = 0
interpolation = gndToENDF6Module.gndToENDFInterpolationFlag(
angularSubform.interpolation)
energyConversionFactor = PQUModule.PQU(
1, angularSubform.axes[-1].unit).getValueAs('eV')
ENDFDataList = []
start = 0
if targetInfo.get('skipFirstEnergy'): start = 1
for energy in angularSubform[start:]:
NW, NL = len(energy) - 1, 0
if (targetInfo['doMF4AsMF6']): NL = NW
ENDFDataList.append(
endfFormatsModule.endfContLine(
0, energy.value * energyConversionFactor, 0, 0, NW, NL))
ENDFDataList += endfFormatsModule.endfDataList(energy.coefficients[1:])
NM = max(NM, len(energy.coefficients[1:]))
if (insertSENDL):
ENDFDataList.append(endfFormatsModule.endfSENDLineNumber())
return (interpolation, len(angularSubform[start:]), 0, 1, NM, ENDFDataList)
def toENDF6(self, MT, endfMFList, flags, targetInfo):
n, data = self.order + 1, {}
for i in xrange(n):
data[i] = []
for index, label in enumerate(self.labels):
d = self.data[label][i][0]
u = 0
if (self.hasUncertainties): u = self.data[label][i][1]
data[i].append(d)
data[i].append(u)
list = []
for i in xrange(n):
list += data[i]
endfMFList[MT][458] = [
endfFormatsModule.endfContLine(targetInfo['ZA'], targetInfo['mass'], 0,
0, 0, 0)
]
endfMFList[MT][458].append(
endfFormatsModule.endfContLine(0, 0, 0, self.order, 18 * n, 9 * n))
endfMFList[MT][458] += endfFormatsModule.endfDataList(list)
endfMFList[MT][458].append(endfFormatsModule.endfSENDLineNumber())
def toENDF6(self, MT, endfMFList, flags, targetInfo, energyUnit='eV'):
if (MT == 502): MT = self.ancestor.ENDFMT
Z = targetInfo['ZA'] / 1000
endfInterpolation, data = [], []
counter, lastX, lastY = 0, None, None
for region in self:
ENDFInterpolation = gndToENDF6Module.gndToENDFInterpolationFlag(
region.interpolation)
regionData = region.copyDataToXYs(xUnitTo=energyUnit, yUnitTo='')
if (lastX is not None):
if (lastY == regionData[0][1]): del regionData[0]
counter += len(regionData)
endfInterpolation.append(counter)
endfInterpolation.append(ENDFInterpolation)
for xy in regionData:
data += xy
lastX, lastY = regionData[-1]
endfMFList[27][MT] = [ endfFormatsModule.endfHeadLine( targetInfo['ZA'], targetInfo['mass'], 0, 0, 0, 0 ),
endfFormatsModule.endfContLine( 0, Z, 0, 0, len( endfInterpolation ) / 2, len( data ) / 2 ) ] + \
endfFormatsModule.endfInterpolationList( endfInterpolation ) + \
endfFormatsModule.endfDataList( data ) + [ endfFormatsModule.endfSENDLineNumber( ) ]
def toENDF6( self, MT, endfMFList, flags, targetInfo ) :
"""
In ENDF MF=6, some distributions should really be treated as uncorrelated: NBodyPhaseSpace, and also
Legendre expansions when only L=0 is listed.
For GND we split these into uncorrelated angular (isotropic) and energy distributions.
Must put back in original format when writing back to ENDF.
"""
frame = self.productFrame
energySubform = self.energySubform.data
angularSubform = self.angularSubform.data
if( isinstance( energySubform, energyModule.NBodyPhaseSpace ) ) :
energySubform.toENDF6( MT, endfMFList, flags, targetInfo )
elif( isinstance( energySubform, energyModule.energyLoss ) ) :
frame, ENDFDataList = energySubform.toENDF6( MT, endfMFList, flags, targetInfo )
gndToENDF6Module.toENDF6_MF6( MT, endfMFList, flags, targetInfo, 8, frame, ENDFDataList )
elif( targetInfo['product'].getAttribute( 'ENDFconversionFlag' ) in [ 'MF6', 'MF26' ] ) :
if( isinstance( energySubform, energyModule.constant ) ) :
# BRB - this needs to be checked.
if( targetInfo['product'].name != 'gamma' ) : raise ValueError( 'This logic is only for discete gammas' )
energyForm = energyModule.form( self.label, frame, energySubform )
angularForm = angularModule.form( self.label, frame, angularSubform )
energyForm.toENDF6( MT, endfMFList, flags, targetInfo )
angularForm.toENDF6( MT, endfMFList, flags, targetInfo )
elif( isinstance( angularSubform, angularModule.isotropic ) ) : # Change to energyAngular with Legendre
if( not( isinstance( energySubform, energyModule.XYs2d ) ) ) : raise 'hell - fix me'
axes = axesModule.axes( rank = 4 )
axes[3] = axesModule.axis( 'energy_in', 3, 'eV' )
axes[2] = axesModule.axis( 'energy_out', 2, 'eV' )
axes[1] = axesModule.axis( 'l', 1, '' )
axes[0] = axesModule.axis( 'C_l(energy_out|energy_in)', 0, '1/eV' )
energyAngularSubform = energyAngularModule.XYs3d( axes = axes, interpolation = energySubform.interpolation,
interpolationQualifier = energySubform.interpolationQualifier )
EInFactor = PQUModule.PQU( 1, energySubform.axes[2].unit ).getValueAs( 'eV' )
for EIn in energySubform :
if isinstance( EIn, regionsModule.regions1d ):
# writing to MF6 LAW=1, LANG=1 doesn't support multiple regions, must recombine.
if( len( set( [ ein.interpolation for ein in EIn ] ) ) != 1 ) :
raise NotImplemented, "ENDF MF6 LAW=1 LANG=1 doesn't support multiple E' interpolations!"
xyvals = EIn[0].copyDataToXYs()
for region in EIn[1:]:
xynew = region.copyDataToXYs()
xynew[0][0] *= 1.00000001
xyvals.extend( xynew )
EIn_copy = EIn[0].copy( value=EIn.value, axes=EIn.axes )
EIn_copy.setData( xyvals )
EIn = EIn_copy
multiD_2d = energyAngularModule.XYs2d( value = EIn.value * EInFactor, interpolation = EIn.interpolation )
EpCls = EIn.copyDataToXYs( xUnitTo = 'eV', yUnitTo = '1/eV' )
for e_out, Cls in EpCls :
multiD_2d.append( energyAngularModule.Legendre( [ Cls ], value = e_out ) )
energyAngularSubform.append( multiD_2d )
form = energyAngularModule.form( '', self.productFrame, energyAngularSubform )
if( targetInfo.dict.get( "gammaToENDF6" ) ) : return( form )
form.toENDF6( MT, endfMFList, flags, targetInfo )
elif( isinstance( energySubform, energyModule.XYs2d ) and isinstance( angularSubform, angularModule.XYs2d ) ) :
LANG, LEP = 12, 2
if( energySubform.interpolation == standardsModule.interpolation.flatToken ) :
LEP = 1 # interpolation for E_out
LANG = 11
elif( energySubform.interpolation in (standardsModule.interpolation.loglinToken,
standardsModule.interpolation.loglogToken ) ) :
LANG = 14
MF6 = [ endfFormatsModule.endfContLine( 0, 0, LANG, LEP, 1, len( energySubform ) ) ]
EInInterpolation = gndToENDF6Module.gndToENDFInterpolationFlag( energySubform.interpolation )
MF6 += endfFormatsModule.endfInterpolationList( [ len( energySubform ), EInInterpolation ] )
for indexE, EEpP in enumerate( energySubform ) :
EMuP = angularSubform[indexE]
if( EEpP.value != EMuP.value ) : raise Exception( "EEpP.value = %s != EMuP.value = %s" % ( EEpP.value, EMuP.value ) )
NA, NEP = 2 * len( EMuP ), len( EEpP )
MF6.append( endfFormatsModule.endfContLine( 0, EEpP.value, 0, NA, NEP * ( NA + 2 ), NEP ) )
data = []
for EpP in EEpP :
data = [ EpP[0], EpP[1] ]
for muP in EMuP : data += muP
MF6 += endfFormatsModule.endfDataList( data )
LAW = 1
gndToENDF6Module.toENDF6_MF6( MT, endfMFList, flags, targetInfo, LAW, frame, MF6 )
else :
raise Exception( 'uncorrelated.toENDF6 not supported for energy subform = %s and angular subform = %s' %
( energySubform.label, angularSubform.label ) )
else : # original data is in uncorrelated form
if( MT not in [ 527, 528 ] ) :
angularForm = angularModule.form( "", frame, self.angularSubform.data )
angularForm.toENDF6( MT, endfMFList, flags, targetInfo )
energyForm = energyModule.form( "", frame, self.energySubform.data )
energyForm.toENDF6( MT, endfMFList, flags, targetInfo )
if( MT == 527 ) : endfMFList[26][MT][0]
