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diff --git a/Models/Feynrules/tests/newvertices.py b/Models/Feynrules/tests/newvertices.py
--- a/Models/Feynrules/tests/newvertices.py
+++ b/Models/Feynrules/tests/newvertices.py
@@ -1,768 +1,826 @@
#! /usr/bin/env python
from __future__ import with_statement
import cmath, string, os, sys, fileinput
from optparse import OptionParser
# set up the option parser for command line input
parser = OptionParser(usage="%prog -d [UFO model directory] -n [custom model nametag]")
parser.add_option("-d", "--directory", dest="MODELDIR",
default="Model", help="UFO model directory.")
parser.add_option("-n", "--name", dest="MODELNAME",
default="FeynRulesModel", help="custom model nametag.")
opts, args = parser.parse_args()
# check if the given "Model" path exists
if(os.path.exists(os.getcwd() + '/'+opts.MODELDIR) is False):
print 'Path', os.getcwd() + '/'+ opts.MODELDIR, 'does not exist, exiting'
sys.exit()
# if the Model path exists, then import the UFO FeynRules module
FR = __import__(opts.MODELDIR)
# check if a function is a number
def is_number(s):
try:
float(s)
return True
except ValueError:
return False
# function that replaces ** with pow(,): used in PyMathToThePEGMath below
def powstring(stringrep,power):
- return 'pow(' + stringrep.replace('**','') + ',' + power + ')'
+ #if(stringrep[0] == '('):
+ # return 'pow(' + stringrep[0:len(stringrep)-2] + stringrep[len(stringrep)-3:len(stringrep)].replace('**','') + ',' + power + ')'
+ #else:
+ return 'pow(' + stringrep[0:len(stringrep)-3] + stringrep[len(stringrep)-3:len(stringrep)+1].replace('**','') + ',' + power + ')'
+
+def BrackParams(stringin):
+ # to take care of the ** powers over brackets (), append new "parameters" of type (xxxx)
+ # th = acos(1/sqrt(1 + (-pow(MM1,2) + pow(MM2,2) + sqrt(4*pow(MM12,4) + (pow(MM1,2) - pow(MM2,2))**2))**2/(4.*pow(MM12,4))));
+ # start by finding the positions of the left and right brackets
+ stringbrack = stringin
+ d_string_length = len(stringbrack)
+ brack_pos_left = []
+ brack_pos_right = []
+ for ll in range(0,d_string_length):
+ if(stringbrack[ll] is '('):
+ brack_pos_left.append(ll)
+ if(stringbrack[ll] is ')'):
+ brack_pos_right.append(ll)
+
+ paramsin_brack = []
+ # loop over the left bracket positions, moving left, and count the number of right brackets
+ for le in brack_pos_left:
+ LRNUM = -1
+ # print 'brack_pos_left', le
+ # loop over the input string starting from the position of the bracket
+ # count the left and right brackets to the right of the left bracket
+ # left brackets are negative, right brackets are positive
+ # the matched bracket is found when the left + right = LRNUM = 0
+ for lm in range(le+1,d_string_length):
+ if(lm in brack_pos_left):
+ LRNUM = LRNUM - 1
+ if(lm in brack_pos_right):
+ LRNUM = LRNUM + 1
+ if(LRNUM is 0):
+ #print 'BRACKET', le, 'matched with', lm, stringbrack
+ #print 'appending', stringbrack[le:lm+1]
+ paramsin_brack.append(stringbrack[le:lm+1])
+ break
+
+ # sort the paramsin_brack according to length, from longest to shortest
+ # insert to start of string
+ paramsin_brack.sort(key=len, reverse=True)
+ # for iii in range(0,len(paramsin_brack)):
+ #paramsin.insert(0,paramsin_brack[iii])
+ return paramsin_brack
+
+def PyMathToThePEGMath(stringin, paramsin):
+ stringout = PyMathToThePEGMath_nb(stringin, paramsin)
+ paramsbrack = BrackParams(stringout)
+ print 'paramsbrack', paramsbrack
+ if(paramsbrack is not []):
+ stringreturn = PyMathToThePEGMath_nb(stringout, paramsbrack)
+ return stringreturn
# function that converts the vertex expressions in Python math format to
# format that can be calculated using ThePEG
-def PyMathToThePEGMath(stringin, paramsin):
-
- # add '**' to the end of paramsin[ss], the array of given parameters of the model
- for ss in range(0,len(paramsin)):
- paramsin[ss] = paramsin[ss] + '**'
-
+def PyMathToThePEGMath_nb(stringin, paramsin):
+
# define an array that contains the numbers 0-9 in string form
numbersarray = ['0','1','2','3','4','5','6','7','8','9']
# define counters and variables used to detect the positions of powers
ii = 0
pos = ''
posnew = ''
powpos = ''
pow_ddg = 0
power = ''
+
+
+ # add '**' to the end of paramsin[ss], the array of given parameters of the model
+ for ss in range(0,len(paramsin)):
+ paramsin[ss] = paramsin[ss] + '**'
+
+ #print 'in progress', stringin
+
+ #print 'paramsin', paramsin
powerchange = []
- initial_len_paramsin = len(paramsin)
- # to take care of the ** powers over brackets (), append new "parameters" of type (xxxx)
- # th = acos(1/sqrt(1 + (-pow(MM1,2) + pow(MM2,2) + sqrt(4*pow(MM12,4) + (pow(MM1,2) - pow(MM2,2))**2))**2/(4.*pow(MM12,4))));
-
-
# loop over the array of the model parameters and search for them in the given mathematical expression
# each time a new position with the ** notation is found, replace with the C++ pow(,) notation
for xx in range(0,len(paramsin)):
# powerchange contains information on the positions
# of necessary changes. OBSOLETE: for testing purposes only
powerchange.append([])
# reset counter for next variable and position variables
ii = 0
pos = 0
posnew = 0
# save the length of the string at the beginning of the loop for a parameter
initial_string_length = len(stringin)
# scan the string from right to left
while (initial_string_length-ii >= 0):
# set the new position of the found
posnew = stringin.find(paramsin[xx],initial_string_length-ii)
+ #print 'param found', posnew, paramsin[xx]
# if the position is new, do stuff
if(posnew is not pos and posnew is not -1):
# get the position of the power
powpos = posnew + len(paramsin[xx])
# check if power is single or double digit
# i.e. -> assuming there are no powers beyond "99"
power = stringin[powpos]
if(powpos+1 < initial_string_length):
if(stringin[powpos+1] in numbersarray):
#print 'power is double digit ', (stringin[powpos+1])
pow_ddg = 1
power = stringin[powpos] + stringin[powpos+1]
powerchange[xx].append([ posnew, power ])
# do the replacement of the ** to pow(,)
stringin = stringin[:posnew] + stringin[posnew:posnew+len(paramsin[xx])+len(power)].replace(paramsin[xx]+power,powstring(paramsin[xx],power)) + stringin[posnew+len(paramsin[xx])+len(power):]
+ print 'in progress', stringin
# reset position variable for next point in string
# increment the counter for the position in string
pos = posnew
ii += 1
# do replacements of 'complex'
# integers multiplying stuff (add the "."
stringin = stringin.replace('complex','Complex')
stringin = stringin.replace('cmath.pi', 'M_PI')
stringin = stringin.replace('cmath.', '')
stringin = stringin.replace('-(','(-1.)*(')
for nn in range(0,len(numbersarray)):
numbersnn = numbersarray[nn]
stringin = stringin.replace(numbersnn +' *', numbersnn +'. *')
stringin = stringin.replace(numbersnn+'*Complex',numbersnn+'.*Complex')
+
+
# print 'final string:'
- # print stringin
+ # print 'final string', stringin, paramsin
# reset the parameters with ** for next run of function and return
for ss in range(0,len(paramsin)):
paramsin[ss] = paramsin[ss].replace('**','')
return stringin
# function that replaces alphaS (aS)-dependent variables
# with their explicit form which also contains strongCoupling
def aStoStrongCoup(stringin, paramstoreplace, paramstoreplace_expressions):
print stringin
for xx in range(0,len(paramstoreplace)):
print paramstoreplace[xx], paramstoreplace_expressions[xx]
stringout = stringin.replace(paramstoreplace[xx], '(' + PyMathToThePEGMath(paramstoreplace_expressions[xx],allparams) + ')')
stringout = stringout.replace('aS', '(sqr(strongCoupling(q2))/(4.0*Constants::pi))')
print 'resulting string', stringout
return stringout
# function that replaces alphaEW (aEW)-dependent variables
# with their explicit form which also contains weakCoupling
def aEWtoWeakCoup(stringin, paramstoreplace, paramstoreplace_expressions):
print stringin
for xx in range(0,len(paramstoreplace)):
print paramstoreplace[xx], paramstoreplace_expressions[xx]
stringout = stringin.replace(paramstoreplace[xx], '(' + PyMathToThePEGMath(paramstoreplace_expressions[xx],allparams) + ')')
- stringout = stringout.replace('aEW', '(sqr(weakCoupling(q2))/(4.0*Constants::pi))')
+ stringout = stringout.replace('aEWM1', '(1/(sqr(electroMagneticCoupling(q2))/(4.0*Constants::pi)))')
print 'resulting string', stringout
return stringout
# function to get template
def getTemplate(basename):
with open('../%s.template' % basename, 'r') as f:
templateText = f.read()
return string.Template( templateText )
# write a filename
def writeFile(filename, text):
with open(filename,'w') as f:
f.write(text)
class CheckUnique:
def __init__(self):
self.val = None
def __call__(self,val):
if self.val is None:
self.val = val
else:
assert( val == self.val )
##################################################
##################################################
##################################################
# get templates for Model header and .cc file,
# Herwig++ run input file
MODEL_H = getTemplate('Model.h')
MODEL_CC = getTemplate('Model.cc')
MODEL_HWIN = getTemplate('LHC-FR.in')
# get the Model name from the arguments
ModelName = opts.MODELNAME
# copy the Makefile-FR to current directory,
# replace with the ModelName for compilation
os.system('cp ../Makefile-FR Makefile')
for line in fileinput.input('Makefile', inplace = 1):
print line.replace("FeynRulesModel.so", ModelName+".so"),
# define arrays and variables
allplist = ""
parmdecls = []
parmgetters = []
parmconstr = []
parmextinter = []
parmfuncmap = []
paramsforev = []
paramstoreplace_ = []
paramstoreplace_expressions_ = []
# get external parameters for printing
parmsubs = dict( [ (p.name, float(p.value))
for p in FR.all_parameters
if p.nature == 'external' ] )
#print parmsubs
#print
# evaluate python cmath
def evaluate(x):
return eval(x,
{'cmath':cmath,
'complexconjugate':FR.function_library.complexconjugate},
parmsubs)
# get internal, external and all params into arrays
internal = [ p
for p in FR.all_parameters
if p.nature == 'internal' ]
external = [ p
for p in FR.all_parameters
if p.nature == 'external' ]
allparams = [ p.name
for p in FR.all_parameters ]
#print 'external parms:'
#print external
#print
#print 'internal parms:'
#print internal
#print
paramstoreplaceEW_ = []
paramstoreplaceEW_expressions_ = []
# calculate internal parameters
for p in internal:
print p.name,'=',p.value
if('aS' in p.value and p.name is not 'aS'):
print 'PARAM', p.name, 'contains aS'
print p.value
paramstoreplace_.append(p.name)
paramstoreplace_expressions_.append(p.value)
- if('aEW' in p.value and p.name is not 'aEW'):
+ if('aEWM1' in p.value and p.name is not 'aEWM1'):
print 'PARAM', p.name, 'contains aEW'
print p.value
paramstoreplaceEW_.append(p.name)
paramstoreplaceEW_expressions_.append(p.value)
#if(is_number(p.value)):
newval = evaluate(p.value)
parmsubs.update( { p.name : newval } )
#print parmsubs
#print
# put external parameters into list of parameters to be interfaced
for p in external:
print p.name,'=',p.value
extinter = '%s' % (p.name)
#print 'NUMBER OF PARAMS', len(FR.all_parameters)
#print 'PARAMETER NAMES'
# more arrays used for substitution in templates
paramvertexcalc = []
paramsforstream = []
parmmodelconstr = []
parmnumber = 0
# loop over parameters and fill in template stuff according to internal/external and complex/real
# WARNING: Complex external parameter input not tested!
for p in FR.all_parameters:
value = parmsubs[p.name]
extinter = ''
print p.name
if (p.nature == 'external' and p.type == 'real'):
#extinter = '%s' % (p.name)
extinter = 'static Parameter<%s, double> interfaceg%s' % (ModelName, p.name)
extinter += '\n'+' ("%s",' % (p.name)
extinter += '\n'+' "The interface to the parameter %s",' % (p.name)
extinter += '\n'+' &%s::%s, %s, -10000., 10000.,' % (ModelName, p.name, value)
extinter += '\n'+' false, false, Interface::limited);\n'
if (p.nature == 'external' and p.type == 'complex'):
#extinter = '%s' % (p.name)
extinter = 'static Parameter<%s, Complex> interfaceg%s' % (ModelName, p.name)
extinter += '\n'+' ("%s",' % (p.name)
extinter += '\n'+' "The interface to the parameter %s",' % (p.name)
extinter += '\n'+' false, false, Interface::limited);\n'
if p.type == 'real':
try:
assert( value.imag < 1.0e-16 )
value = value.real
except:
pass
parmsubs[p.name] = value
decl = ' double %s;' % p.name
constr = '%s(%s)' % (p.name, value)
if(p.nature == 'external'):
modelconstr = 'set ' + ModelName + ':%s %s' % (p.name, value)
getter = ' double %s_() const { return %s; }' % (p.name, p.name)
funcmap = ' case %s: return %s_();' % (parmnumber, p.name)
forev = '%s' % p.name
funcvertex = '%s = hw%s_ptr->%s_();' % (p.name, ModelName, p.name)
parmnumber += 1
elif p.type == 'complex':
value = complex(value)
parmsubs[p.name] = value
decl = ' Complex %s;' % p.name
constr = '%s(%s,%s)' % (p.name, value.real, value.imag)
if(p.nature == 'external'):
modelconstr = 'set ' + ModelName + ':%s (%s,%s)' % (p.name, value.real, value.imag)
getter = ' Complex %s_() const { return %s; }' % (p.name, p.name)
funcmap = ' case %s: return %s_();' % (parmnumber, p.name)
forev = '%s' % p.name
funcvertex = '%s = hw%s_ptr->%s_();' % (p.name, ModelName, p.name)
parmnumber += 1
else:
raise Exception('Unknown data type "%s".' % p.type)
if(p.name == 'aS'):
funcvertex = '%s = (sqr(strongCoupling(q2))/(4.0*Constants::pi));' % p.name
+ if(p.name == 'aEWM1'):
+ funcvertex = '%s = ((4.0*Constants::pi)/sqr(electroMagneticCoupling(q2)));' % p.name
if(p.lhablock == None):
funcvertex = p.name +' = ' + PyMathToThePEGMath(p.value, allparams) + ';'
print 'NO LHABLOCK:', p.name, funcvertex
# do calc in C++, add interfaces for externals
paramvertexcalc.append(funcvertex)
parmdecls.append(decl)
parmgetters.append(getter)
parmconstr.append(constr)
if(p.nature == 'external'):
parmmodelconstr.append(modelconstr)
parmextinter.append(extinter)
parmfuncmap.append(funcmap)
paramsforev.append(forev)
paramsforstream.append(forev)
if extinter != '':
parmextinter.append('\n')
parmtextsubs = { 'parmgetters' : '\n'.join(parmgetters),
'parmdecls' : '\n'.join(parmdecls),
'parmconstr' : ': ' + ',\n '.join(parmconstr),
'getters' : '',
'decls' : '',
'addVertex' : '',
'ostream' : '\n\t<< '.join(paramsforstream),
'istream' : '\n\t>> '.join(paramsforstream),
'refs' : '',
'parmextinter': ''.join(parmextinter),
'num_params': len(FR.all_parameters),
'parmfuncmap': '\n'.join(parmfuncmap),
'paramsforev': ','.join(paramsforev),
'ModelName': ModelName
}
for k,v in parmtextsubs.iteritems():
print k
print v
print
# write the files from templates according to the above subs
writeFile( ModelName + '.h', MODEL_H.substitute(parmtextsubs) )
writeFile( ModelName +'.cc', MODEL_CC.substitute(parmtextsubs) )
writeFile( 'LHC-' + ModelName +'.in', MODEL_HWIN.substitute(parmtextsubs) )
##################################################
##################################################
##################################################
# ignore these, they're in Hw++ already # TODO reset Hw++ settings instead
SMPARTICLES = {
1:'d',
2:'u',
3:'s',
4:'c',
5:'b',
6:'t',
11:'e-',
12:'nu_e',
13:'mu-',
14:'nu_mu',
15:'tau-',
16:'nu_tau',
21:'g',
22:'gamma',
23:'Z0',
24:'W+',
-1:'dbar',
-2:'ubar',
-3:'sbar',
-4:'cbar',
-5:'bbar',
-6:'tbar',
-11:'e+',
-12:'nu_ebar',
-13:'mu+',
-14:'nu_mubar',
-15:'tau+',
-16:'nu_taubar',
-24:'W-',
}
particleT = string.Template(
"""
create ThePEG::ParticleData $name
setup $name $pdg_code $name $mass $width $wcut $ctau $charge $color $spin 0
insert /Herwig/NewPhysics/NewModel:DecayParticles 0 $name
"""
)
class ParticleConverter:
'Convert a FR particle to extract the information ThePEG needs.'
def __init__(self,p):
self.name = p.name
self.pdg_code = p.pdg_code
self.spin = p.spin
self.color = p.color
self.selfconjugate = 0
if self.color == 1:
self.color = 0
self.mass = parmsubs[str(p.mass)]
self.width = parmsubs[str(p.width)]
try:
self.mass = self.mass.real
except:
pass
hbarc = 197.3269631e-15 # GeV mm (I hope ;-) )
if self.width != 0: self.ctau = hbarc / self.width
else: self.ctau = 0
self.wcut = 10 * self.width
self.charge = int(3 * p.charge)
def subs(self):
return self.__dict__
def get_all_thepeg_particles():
plist = ''
antis = {}
for p in FR.all_particles:
if p.spin == -1 or p.goldstoneboson:
continue
if p.pdg_code in SMPARTICLES:
#add stuff to plist to set params
pass
else:
if p.pdg_code == 25:
plist += """
set /Herwig/Particles/h0:Mass_generator NULL
set /Herwig/Particles/h0:Width_generator NULL
rm /Herwig/Masses/HiggsMass
rm /Herwig/Widths/HiggsWidth
"""
subs = ParticleConverter(p).subs()
plist += particleT.substitute(subs)
pdg, name = subs['pdg_code'], subs['name']
if -pdg in antis:
plist += 'makeanti %s %s\n' % (antis[-pdg], name)
else:
antis[pdg] = name
selfconjugate = 1
return plist
def get_lorentztag(spin):
'Produce a ThePEG spin tag for the given numeric FR spins.'
spins = { 1 : 'S', 2 : 'F', 3 : 'V', -1 : 'U', 5 : 'T' }
result = [ spins[s] for s in spin ]
def spinsort(a,b):
"Helper function for ThePEG's FVST spin tag ordering."
if a == b: return 0
for letter in 'FVST':
if a == letter: return -1
if b == letter: return 1
result = sorted(result, cmp=spinsort)
return ''.join(result)
##################################################
##################################################
##################################################
# get vertex template
VERTEX = getTemplate('Vertex.cc')
def produce_vertex_file(subs):
newname = ModelName + subs['classname'] + '.cc'
writeFile( newname, VERTEX.substitute(subs) )
# loop over all vertices
for v in FR.all_vertices:
print v.name
print map(str,v.particles)
print '---------------'
v.include = 1
### Spin structure
unique = CheckUnique()
for l in v.lorentz:
lt = get_lorentztag(l.spins)
unique( lt )
if 'T' in lt: spind = 'Tensor'
elif 'S' in lt: spind = 'Scalar'
elif 'V' in lt: spind = 'Vector'
elif 'U' in lt: spind = 'Ghost'
### Particle ids #################### sort order? ####################
plistarray = ['','']
plistarray[0] = ','.join([ str(p.pdg_code) for p in v.particles ])
plist = ','.join([ str(p.pdg_code) for p in v.particles ])
print plist
# Check if the Vertex is self-conjugate or not
pdgcode = [0,0,0,0]
notsmvertex = False
# print 'printing particles in vertex'
for i in range(len(v.particles)):
# print v.particles[i].pdg_code
pdgcode[i] = v.particles[i].pdg_code
if(pdgcode[i] not in SMPARTICLES):
notsmvertex = True
# treat replacement of SM vertices with BSM vertices?
if(notsmvertex == False):
print 'VERTEX INCLUDED IN STANDARD MODEL!'
# v.include = 0
#continue
selfconjugate = 0
for j in range(len(pdgcode)):
for k in range(len(pdgcode)):
if( j != k and j != 0 and abs(pdgcode[j]) == abs(pdgcode[k])):
selfconjugate = 1
print 'self-conjugate vertex'
# print pdgcode[j]
# if the Vertex is not self-conjugate, then add the conjugate vertex
# automatically
scfac = [1,1,1,1]
if(selfconjugate == 0):
#first find the self-conjugate particles
for u in range(len(v.particles)):
if(v.particles[u].selfconjugate == 0):
scfac[u] = -1
# print 'particle ', v.particles[u].pdg_code, ' found not to be self-conjugate'
if(selfconjugate == 0):
plistarray[1] += str(scfac[1] * v.particles[1].pdg_code) + ',' + str(scfac[0] * v.particles[0].pdg_code) + ',' + str(scfac[2] * v.particles[2].pdg_code)
if(len(v.particles) is 4):
plistarray[1] += ',' + str(scfac[3] * v.particles[3].pdg_code)
#print 'Conjugate vertex:', plistarray[1]
### Colour structure
if v.color == '1': qcdord = '0'
else: qcdord = ''
### classname
classname = 'V_%03d' % int(v.name[2:])
### parse couplings
unique_qcd = CheckUnique()
unique_qed = CheckUnique()
coup_left = []
coup_right = []
coup_norm = []
for (ci,li),C in v.couplings.iteritems():
qed = C.order.get('QED',0)
qcd = C.order.get('QCD',0)
# WARNING: FIX FOR CASES WHEN BOTH ARE ZERO
# Is there a better way to treat this?
if(qed == 0 and qcd == 0):
qed = 1
unique_qcd( qed )
unique_qed( qcd )
L = v.lorentz[li]
if lt in ['FFS','FFV']:
print 'PRINTING LORENTZ STRUCTURE'
print L.structure
for lor in map(string.strip, L.structure.split('+')):
breakdown = lor.split('*')
prefactor='1'
print 'breakdown', breakdown, 'length', len(breakdown)
if len(breakdown) == 3:
prefactor = breakdown[0]
breakdown = breakdown[1:]
if len(breakdown) == 2:
assert(breakdown[0][:5] == 'Gamma')
if breakdown[1][:5] == 'ProjM':
print 'LEFT HANDED'
coup_left.append(prefactor+' * '+C.value)
elif breakdown[1][:5] == 'ProjP':
print 'RIGHT HANDED'
coup_right.append(prefactor+' * '+C.value)
else:
coup_left.append(C.value)
coup_right.append(C.value)
if len(breakdown) == 1:
if breakdown[0][:5] == 'ProjM':
print 'LEFT HANDED'
coup_left.append(prefactor+' * '+C.value)
elif breakdown[0][:5] == 'ProjP':
print 'RIGHT HANDED'
coup_right.append(prefactor+' * '+C.value)
else:
coup_left.append(C.value)
coup_right.append(C.value)
else:
coup_norm.append(C.value)
print 'Colour :',v.color[ci]
print 'Lorentz %s:'%L.name, L.spins, L.structure
print 'Coupling %s:'%C.name, C.value, '\nQED=%s'%qed, 'QCD=%s'%qcd
print '---------------'
leftcontent = ' + '.join(coup_left) if len(coup_left)!=0 else '0j'
rightcontent = ' + '.join(coup_right) if len(coup_right)!=0 else '0j'
normcontent = ' + '.join(coup_norm) if len(coup_norm)!=0 else '1.'
print 'Left:',leftcontent
print 'Right:',rightcontent
print 'Norm:',normcontent
print '---------------'
#leftexplicit = complex(evaluate(leftcontent))
#rightexplicit = complex(evaluate(rightcontent))
# normexplicit = complex(evaluate(normcontent))
leftdebug = ''
rightdebug = ''
normdebug = ''
### do we need left/right?
if 'FF' in lt:
leftcalc = aStoStrongCoup(PyMathToThePEGMath(leftcontent, allparams), paramstoreplace_, paramstoreplace_expressions_)
rightcalc = aStoStrongCoup(PyMathToThePEGMath(rightcontent, allparams), paramstoreplace_, paramstoreplace_expressions_)
left = 'left(' + leftcalc + ');'
right = 'right(' + rightcalc + ');'
#leftdebug = 'left(Complex(%s,%s));' % (leftexplicit.real,leftexplicit.imag)
#rightdebug = 'right(Complex(%s,%s));' % (rightexplicit.real,rightexplicit.imag)
else:
left = ''
right = ''
leftcalc = ''
rightcalc = ''
leftdebug = ''
rightdebug = ''
normcalc = aStoStrongCoup(PyMathToThePEGMath(normcontent, allparams), paramstoreplace_, paramstoreplace_expressions_)
norm = 'norm(' + normcalc + ');'
#normdebug = 'norm(Complex(%s,%s));' % (normexplicit.real,normexplicit.imag)
if(plistarray[1] is ''):
plist2 = ''
else:
plist2 = 'addToList(%s);' % plistarray[1]
if('q2' in norm or 'q2' in left or 'q2' in right):
q2var = ' q2'
else:
q2var = ''
### assemble dictionary and fill template
subs = { 'lorentztag' : lt, # ok
'classname' : classname, # ok
'left' : left, # doesn't always exist in base
'right' : right, # doesn't always exist in base
'norm' : norm, # needs norm, too
#################### need survey which different setter methods exist in base classes
'addToPlist' : 'addToList(%s);' % plistarray[0], # ok
'addToPlist2' : plist2, # ok
'parameters' : '',
'setCouplings' : '',
'qedorder' : qed,
'qcdorder' : qcd,
'q2' : q2var,
'couplingptrs' : ',tcPDPtr'*len(v.particles),
'spindirectory' : spind,
'ModelName' : ModelName,
'num_params' : len(FR.all_parameters),
'leftcontent' : leftcontent,
'rightcontent' : rightcontent,
'normcontent' : normcontent,
'leftcalc': leftcalc,
'rightcalc' : rightcalc,
'normcalc' : normcalc,
'paramdecl': '\n'.join(parmdecls),
'ostream' : ' << '.join(paramsforstream),
'istream' : ' >> '.join(paramsforstream),
'paramvertexcalc': '\n\t'.join(paramvertexcalc),
'leftdebug': leftdebug,
'rightdebug' : rightdebug,
'normdebug' : normdebug
} # ok
print plistarray[0]
# if plist in allplist:
# print 'PLIST IN ALLPLIST'
if( L.spins[0] != -1 and L.spins[1] != -1 and L.spins[2] != -1 and plistarray[0] not in allplist and plistarray[1] not in allplist):
produce_vertex_file(subs)
allplist += plistarray[0]
allplist += plistarray[1]
elif( L.spins[0] != -1 and L.spins[1] != -1 and L.spins[2] != -1 and selfconjugate):
produce_vertex_file(subs)
allplist += plistarray[0]
else:
print 'VERTEX ALREADY INCLUDED'
v.include = 0
print '============================================================'
##################################################
##################################################
##################################################
vertexline = string.Template("""\
create $classname $name
insert ${ModelName}:ExtraVertices 0 $name
""")
def get_vertices():
vlist = 'library ' + ModelName + '.so\n'
for v in FR.all_vertices:
for l in v.lorentz:
lt = get_lorentztag(l.spins)
print lt
if("U" not in lt and v.include == 1):
vlist += vertexline.substitute(
{ 'classname' : 'Herwig::' + ModelName + 'V_%03d' % int(v.name[2:]),
'name' : '/Herwig/' + ModelName + '/%s'%v.name, 'ModelName' : ModelName } )
return vlist
modelfilesubs = { 'plist' : get_all_thepeg_particles(),
'vlist' : get_vertices(),
'setcouplings': '\n'.join(parmmodelconstr),
'ModelName': ModelName
}
print get_all_thepeg_particles()
MODELINFILE = getTemplate('FR.model')
writeFile( ModelName +'.model', MODELINFILE.substitute(modelfilesubs) )
print len(FR.all_vertices)

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