tubeIndexes = t.tubeIndexes
return self.factory.he3tubekernel(pressure, tubeIndexes, t.tubeLength,
t.npixels, t.axisDirection,
t.pixel0position)
# 3. the handler to call python bindings
def he3tubekernel(self, pressure, tubeIndexes, tubeLength, npixels,
axisDirection, pixel0position):
import mccomponents.mccomponentsbp as b
import mccomposite.mccompositebp as b1
#c representation of tube indexes
ctubeIndexes = b.vector_int(0)
for ind in tubeIndexes:
ctubeIndexes.append(ind)
axisDirection = b1.Vector(*axisDirection)
pixel0position = b1.Vector(*pixel0position)
cz2c = b.Z2Channel(tubeLength, npixels, axisDirection, pixel0position)
return b.He3TubeKernel(pressure, ctubeIndexes, cz2c, self.t2c, self.mca)
import mccomponents.homogeneous_scatterer as hs
# 4. register the new class and handlers
hs.register(He3TubeKernel, onHe3TubeKernel,
{'BoostPythonBinding': he3tubekernel})
tubeIndexes = t.tubeIndexes
return self.factory.he3tubekernel(
pressure, tubeIndexes,
t.tubeLength, t.npixels, t.axisDirection, t.pixel0position)
# 3. the handler to call python bindings
def he3tubekernel(self, pressure, tubeIndexes,
tubeLength, npixels, axisDirection, pixel0position):
import mccomponents.mccomponentsbp as b
import mccomposite.mccompositebp as b1
#c representation of tube indexes
ctubeIndexes = b.vector_int(0)
for ind in tubeIndexes: ctubeIndexes.append( ind )
axisDirection = b1.Vector(*axisDirection)
pixel0position = b1.Vector(*pixel0position)
cz2c = b.Z2Channel(tubeLength, npixels, axisDirection, pixel0position)
return b.He3TubeKernel( pressure, ctubeIndexes, cz2c, self.t2c, self.mca )
import mccomponents.homogeneous_scatterer as hs
# 4. register the new class and handlers
hs.register (
He3TubeKernel, onHe3TubeKernel,
{'BoostPythonBinding':he3tubekernel} )
abs, sctt = self._unitsRemover.remove_unit( (abs, sctt), 1./units.length.meter )
return self.factory.sqekernel(
abs, sctt,
csqe, Qrange, Erange )
# 3. the handler to call python bindings
def sqekernel(self, absorption_cross_section, scattering_cross_section,
sqe, Qrange, Erange):
import mccomponents.mccomponentsbp as b
Emin, Emax = Erange
Qmin, Qmax = Qrange
return b.SQEkernel(
absorption_cross_section, scattering_cross_section,
sqe, Qmin, Qmax, Emin, Emax )
import mccomponents.homogeneous_scatterer as hs
# 4. register the new class and handlers
hs.register (
SQEkernel, onSQEkernel,
{'BoostPythonBinding':sqekernel} )
# version
__id__ = "$Id$"
# End of file
def register():
hs.register (
NeutronPrinter, onNeutronPrinter,
{'BoostPythonBinding':neutronprinter} )
def identify(self, visitor):
return visitor.onEventModeMCA(self)
pass # end of EventModeMCA
# 2. the handler to construct c++ engine
def onEventModeMCA(self, mca):
return self.factory.eventmodemca( mca.outfilename, mca.detectorDims )
def bp_eventmodemca( self, outfilename, detectorDims ):
import mccomponents.mccomponentsbp as b
dims = b.vector_uint( 0 )
for dim in detectorDims: dims.append(dim)
return b.EventModeMCA( outfilename, dims )
# 4. register the new class and handlers
import mccomponents.homogeneous_scatterer as mh
mh.register(EventModeMCA, onEventModeMCA,
{'BoostPythonBinding': bp_eventmodemca})
# version
__id__ = "$Id$"
# End of file
assert shape[0] == int( (qend-qbegin)/qstep )
assert shape[1] == int( (eend-ebegin)/estep )
size = shape[0] * shape[1]
import mccomponents.mccomponentsbp as b
svector = b.vector_double( size )
s.shape = -1,
svector[:] = s
fxy = b.new_fxy(
qbegin, qend, qstep,
ebegin, eend, estep,
svector)
return b.GridSQE( fxy )
import mccomponents.homogeneous_scatterer as hs
# 4. register the new class and handlers
hs.register (
GridSQE, onGridSQE,
{'BoostPythonBinding':gridsqe} )
# version
__id__ = "$Id$"
# End of file
def register():
hs.register(NeutronPrinter, onNeutronPrinter,
{'BoostPythonBinding': neutronprinter})
return self.factory.gridsqe(qbegin, qend, qstep, ebegin, eend, estep, s)
# 3. the handler to call python bindings
def gridsqe(self, qbegin, qend, qstep, ebegin, eend, estep, s):
shape = s.shape
assert len(shape) == 2
assert shape[0] == int((qend - qbegin) / qstep)
assert shape[1] == int((eend - ebegin) / estep)
size = shape[0] * shape[1]
import mccomponents.mccomponentsbp as b
svector = b.vector_double(size)
s.shape = -1,
svector[:] = s
fxy = b.new_fxy(qbegin, qend, qstep, ebegin, eend, estep, svector)
return b.GridSQE(fxy)
import mccomponents.homogeneous_scatterer as hs
# 4. register the new class and handlers
hs.register(GridSQE, onGridSQE, {'BoostPythonBinding': gridsqe})
# version
__id__ = "$Id$"
# End of file
dearr = energies[1:] - energies[:-1]
#make sure bin sizes are all the same
import numpy
assert numpy.all( numpy.abs( dearr-de ) < 1e-7*de )
n = eaxis.size()
Z = doshist.data().storage().asNumarray()
return self.factory.linearlyinterpolateddos(
e0, de, n, Z )
# 3. the handler to call python bindings
def linearlyinterpolateddos_bp_handler(self, e0, de, n, Z):
return linearlyinterpolateddos_bp(e0, de, n, Z)
import mccomponents.homogeneous_scatterer as hs
# 4. register the new class and handlers
hs.register (
LinearlyInterpolatedDOS, onLinearlyInterpolatedDOS,
{'BoostPythonBinding':linearlyinterpolateddos_bp_handler} )
# version
__id__ = "$Id$"
# End of file
#register new type
# 2. the handler of engine renderer
def onDWFromDOS(self, dwfromDOS):
dos = dwfromDOS.dos
cdos = dos.identify(self)
mass = dwfromDOS.mass
temperature = dwfromDOS.temperature
return self.factory.dwfromDOS(cdos, mass, temperature, dwfromDOS.nsampling)
# 3. the handler to call python bindings
def dwfromDOS_bp_handler(self, dos, mass, temperature, nsampling):
from mccomponents import mccomponentsbp as bp
ret = bp.DWFromDOS_dbl(dos, nsampling)
ret.calc_DW_core(mass, temperature)
return ret
import mccomponents.homogeneous_scatterer as hs
# 4. register the new class and handlers
hs.register(DWFromDOS, onDWFromDOS,
{'BoostPythonBinding': dwfromDOS_bp_handler})
# version
__id__ = "$Id$"
# End of file
cdos = dos.identify(self)
mass = dwfromDOS.mass
temperature = dwfromDOS.temperature
return self.factory.dwfromDOS(
cdos, mass, temperature, dwfromDOS.nsampling )
# 3. the handler to call python bindings
def dwfromDOS_bp_handler(self, dos, mass, temperature, nsampling):
from mccomponents import mccomponentsbp as bp
ret = bp.DWFromDOS_dbl(dos, nsampling)
ret.calc_DW_core( mass, temperature )
return ret
import mccomponents.homogeneous_scatterer as hs
# 4. register the new class and handlers
hs.register (
DWFromDOS, onDWFromDOS,
{'BoostPythonBinding':dwfromDOS_bp_handler} )
# version
__id__ = "$Id$"
# End of file
