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catima/catima.pyx
2018-01-18 19:20:42 +01:00

496 lines
15 KiB
Cython

"""
catima python module
~~~~~~~~~~~
This module provides interface to the catima c++ library
:copyright: (c) 2017 by Andrej Prochazka
:licence: GNU Affero General Public License, see LICENCE for more details
"""
cimport catimac
from enum import IntEnum
import numpy
cdef class Material:
cdef catimac.Material cbase
def __cinit__(self, elements=None, thickness=None, density=None):
self.cbase = catimac.Material()
if(elements and (isinstance(elements[0],float) or isinstance(elements[0],int))):
self.cbase.add_element(elements[0],elements[1],elements[2])
if(elements and isinstance(elements[0],list)):
for e in elements:
self.cbase.add_element(e[0],e[1],e[2])
self.cbase.calculate()
if(not thickness is None):
self.thickness(thickness)
if(not density is None):
self.density(density)
cdef from_c(self, catimac.Material &other):
self.cbase = other
cdef catimac.Material getc(self):
cdef catimac.Material res
res = self.cbase
return res
def copy(self):
res = Material()
res.cbase = self.cbase
return res
def add_element(self, a, z , s):
self.cbase.add_element(a, z, s)
def ncomponents(self):
return self.cbase.ncomponents()
def molar_mass(self):
return self.cbase.M()
def M(self):
return self.cbase.M()
def density(self, val=None):
if(val is None):
return self.cbase.density()
else:
return self.cbase.density(val)
def thickness(self, val=None):
if(val is None):
return self.cbase.thickness()
else:
return self.cbase.thickness(val)
class material(IntEnum):
PLASTIC = 201
AIR = 202
CH2 = 203
LH2 = 204
LD2 = 205
WATER = 206
DIAMOND = 207
GLASS = 208
ALMG3 = 209
ARCO2_30 = 210
CF4 = 211
ISOBUTANE = 212
KAPTON = 213
MYLAR = 214
NAF = 215
P10 = 216
POLYOLEFIN = 217
CMO2 = 218
SUPRASIL = 219
HAVAR = 220
STEEL = 221
METHANE = 222
def get_material(int matid):
res = Material()
cdef catimac.Material cres = catimac.get_material(matid);
res.from_c(cres)
return res
cdef class Target:
cdef catimac.Target cbase
def __cinit__(self,a,z,stn):
self.cbase.A = a
self.cbase.Z = z
self.cbase.stn = stn
def A(self):
return self.cbase.A
def Z(self):
return self.cbase.Z
def stn(self):
return self.cbase.stn
cdef class Layers:
cdef public:
materials
def __init__(self):
self.materials=[]
def add(self,Material m):
self.materials.append(m.copy())
def num(self):
return len(self.materials)
def get(self, key):
return self.materials[key]
def __getitem__(self, key):
if(isinstance(key,int) and key<self.num()):
return self.get(key)
return None
def __add__(self, other):
res = Layers()
for e in self.materials:
res.add(e)
if(isinstance(other,Layers)):
for e in other.materials:
res.add(e)
if(isinstance(other,Material)):
res.add(other.copy())
return res
cdef catimac.Layers getc(self):
cdef catimac.Layers res
#for l in self.materials:
# res.add(l.getc())
return res
cdef class Projectile:
cdef catimac.Projectile cbase
def __cinit__(self, A, Z, Q=None,T=None):
self.cbase.A = A
self.cbase.Z = Z
self.cbase.Q = Z
if(Q):
self.cbase.Q = Q
if(T):
self.cbase.T = T
def T(self,val=None):
if(val is None):
return self.cbase.T
self.cbase.T = val;
def __call__(self,val=None):
if(val is None):
return self.cbase.T
else:
self.T(val)
return self
def A(self):
return self.cbase.A
def Z(self):
return self.cbase.Z
def Q(self):
return self.cbase.Q
cdef class Result:
cdef public double Ein
cdef public double Eout
cdef public double Eloss
cdef public double range
cdef public double dEdxi
cdef public double dEdxo
cdef public double sigma_E
cdef public double sigma_a
cdef public double sigma_r
cdef public double tof
def __init__(self):
self.Ein=0.0
self.Eout=0.0
self.Eloss=0.0
self.range=0.0
self.dEdxi=0.0
self.dEdxo=0.0
self.sigma_E=0.0
self.sigma_a=0.0
self.sigma_r=0.0
self.tof=0.0
def get_dict(self):
return {"Ein":self.Ein,
"Eout":self.Eout,
"Eloss":self.Eloss,
"range":self.range,
"dEdxi":self.dEdxi,
"dEdxo":self.dEdxo,
"sigma_E":self.sigma_E,
"sigma_a":self.sigma_a,
"sigma_r":self.sigma_r,
"tof":self.tof,
}
def __getitem__(self,key):
d = self.get_dict()
if(key in d):
return d[key]
cdef setc(self,catimac.Result &val):
self.Ein=val.Ein
self.Eout=val.Eout
self.Eloss=val.Eloss
self.range=val.range
self.dEdxi=val.dEdxi
self.dEdxo=val.dEdxo
self.sigma_E=val.sigma_E
self.sigma_a=val.sigma_a
self.sigma_r=val.sigma_r
self.tof=val.tof
cdef class MultiResult:
cdef public Result total_result
cdef public results
cdef public total
def __init__(self):
self.total_result = Result()
self.results = []
self.total = {}
cdef setc(self, catimac.MultiResult &val):
self.total_result.setc(val.total_result)
for e in val.results:
self.results.append(e)
self.total = self.total_result.get_dict()
def __getitem__(self,key):
if(isinstance(key,int) and key<len(self.results)):
return self.results[key]
if(isinstance(key,str) and key in self.total):
return self.total[key]
return None
def getJSON(self):
res = {}
res["result"] = self.total
res["partial"] = []
for r in self.results:
res["partial"].append(r)
return res
class z_eff_type(IntEnum):
none = 0,
pierce_blann = 1
anthony_landorf = 2
hubert = 3
winger = 4
schiwietz = 5
global_code = 6
atima14 = 7
class omega_type(IntEnum):
atima = 0,
bohr = 1
class skip_calculation(IntEnum):
skip_none = 0
skip_tof = 1
skip_sigma_a = 2
skip_sigma_r = 4
class corrections(IntEnum):
no_barkas = 1
no_lindhard = 2
no_shell_correction = 4
cdef class Config:
cdef catimac.Config cbase
def __cinit__(self):
#self.cbase = catimac.Config()
self.cbase.z_effective = z_eff_type.pierce_blann
self.cbase.skip = 0
self.cbase.dedx = 0
self.cbase.dedx_straggling = omega_type.atima
def z_effective(self, val=None):
if(val is None):
return self.cbase.z_effective
else:
self.cbase.z_effective = val
def skip_calculation(self, val=None):
if(val is None):
return self.cbase.skip
else:
self.cbase.skip = val
def dedx(self, val=None):
if(val is None):
return self.cbase.dedx
else:
self.cbase.dedx = val
def dedx_straggling(self, val=None):
if(val is None):
return self.cbase.dedx_straggling
else:
self.cbase.dedx_straggling = val
def print_info(self):
print("z_effective = %s"%z_eff_type(self.cbase.z_effective))
print("dedx_straggling = %s"%omega_type(self.cbase.dedx_straggling))
default_config = Config()
def calculate(Projectile projectile, material, energy = None, config=default_config):
if(not energy is None):
projectile.T(energy)
if(isinstance(material,Material)):
return calculate_material(projectile, material, config = config)
if(isinstance(material,Layers)):
return calculate_layers(projectile, material, config = config)
def calculate_material(Projectile projectile, Material material, energy = None, Config config = default_config):
if(not energy is None):
projectile.T(energy)
cdef catimac.Result cres = catimac.calculate(projectile.cbase,material.cbase,config.cbase)
res = Result()
res.setc(cres)
return res
def calculate_layers(Projectile projectile, Layers layers, energy = None, Config config = default_config):
cdef catimac.Layers clayers
clayers = catimac.Layers()
clayers = get_clayers(layers)
if(not energy is None):
projectile.T(energy)
cdef catimac.MultiResult cres = catimac.calculate(projectile.cbase, clayers, config.cbase)
res = MultiResult()
res.setc(cres)
return res
cdef catimac.Layers get_clayers(Layers layers):
cdef catimac.Layers res
cdef catimac.Material m
for l in layers.materials:
m = get_cmaterial(l)
res.add(m)
return res
cdef catimac.Material get_cmaterial(Material material):
cdef catimac.Material res
res = material.cbase
return res
def projectile_range(Projectile projectile, Material material, energy = None, Config config = default_config):
if(isinstance(energy,numpy.ndarray)):
res = numpy.empty(energy.size)
for i,e in enumerate(energy):
res[i] = catimac.range(projectile.cbase, e, material.cbase, config.cbase)
return res
if(energy is None):
energy = projectile.T()
return catimac.range(projectile.cbase, energy, material.cbase, config.cbase);
def dedx_from_range(Projectile projectile, Material material, energy = None, Config config = default_config):
if(isinstance(energy,numpy.ndarray)):
res = numpy.empty(energy.size)
for i,e in enumerate(energy):
res[i] = catimac.dedx_from_range(projectile.cbase, e, material.cbase, config.cbase)
return res
if(energy is None):
energy = projectile.T()
return catimac.dedx_from_range(projectile.cbase, energy, material.cbase, config.cbase);
def domega2de(Projectile projectile, Material material, energy = None, Config config = default_config):
if(isinstance(energy,numpy.ndarray)):
res = numpy.empty(energy.size)
for i,e in enumerate(energy):
res[i] = catimac.domega2de(projectile.cbase, e, material.cbase, config.cbase)
return res
if(energy is None):
energy = projectile.T()
return catimac.domega2de(projectile.cbase, energy, material.cbase, config.cbase);
def da2de(Projectile projectile, Material material, energy = None, Config config = default_config):
if(isinstance(energy,numpy.ndarray)):
res = numpy.empty(energy.size)
for i,e in enumerate(energy):
res[i] = catimac.da2de(projectile.cbase, e, material.cbase, config.cbase)
return res
if(energy is None):
energy = projectile.T()
return catimac.da2de(projectile.cbase, energy, material.cbase, config.cbase);
def dedx(Projectile projectile, Material material, energy = None, Config config = default_config):
if(isinstance(energy,numpy.ndarray)):
res = numpy.empty(energy.size)
for i,e in enumerate(energy):
res[i] = catimac.dedx(projectile.cbase, e, material.cbase, config.cbase)
return res
if(energy is None):
energy = projectile.T()
return catimac.dedx(projectile.cbase, energy, material.cbase, config.cbase)
def domega2dx(Projectile projectile, Material material, energy = None, Config config = default_config):
if(isinstance(energy,numpy.ndarray)):
res = numpy.empty(energy.size)
for i,e in enumerate(energy):
res[i] = catimac.domega2dx(projectile.cbase, e, material.cbase, config.cbase)
return res
if(energy is None):
energy = projectile.T()
return catimac.domega2dx(projectile.cbase, energy, material.cbase, config.cbase)
def energy_out(Projectile projectile, Material material, energy = None, Config config = default_config):
if(isinstance(energy,numpy.ndarray)):
res = numpy.empty(energy.size)
for i,e in enumerate(energy):
res[i] = catimac.energy_out(projectile.cbase, e, material.cbase, config.cbase)
return res
if(energy is None):
energy = projectile.T()
return catimac.energy_out(projectile.cbase, energy, material.cbase, config.cbase)
def z_effective(Projectile p, Target t, Config c = default_config):
return catimac.z_effective(p.cbase, t.cbase, c.cbase)
def z_eff_Pierce_Blann(double z, double beta):
return catimac.z_eff_Pierce_Blann(z,beta)
def z_eff_Anthony_Landford(double pz, double beta, double tz):
return catimac.z_eff_Anthony_Landford(pz, beta, tz);
def z_eff_Hubert(double pz, double E, double tz):
return catimac.z_eff_Hubert(pz, E, tz);
def z_eff_Winger(double pz, double beta, double tz):
return catimac.z_eff_Winger(pz, beta, tz);
def z_eff_global(double pz, double E, double tz):
return catimac.z_eff_global(pz, E, tz);
def z_eff_atima14(double pz, double E, double tz):
return catimac.z_eff_atima14(pz, E, tz);
def z_eff_Schiwietz(double pz, double beta, double tz):
return catimac.z_eff_Schiwietz(pz, beta, tz);
def gamma_from_T(double T):
return catimac.gamma_from_T(T);
def beta_from_T(double T):
return catimac.beta_from_T(T);
def get_data(Projectile projectile, Material material, Config config = default_config):
data = catimac.get_data(projectile.cbase, material.cbase, config.cbase)
return [data.range,data.range_straggling,data.angular_variance]
# constants
max_datapoints = catimac.max_datapoints
max_storage_data = catimac.max_storage_data
logEmin = catimac.logEmin
logEmax = catimac.logEmax
def energy_table(unsigned int i):
if(i<catimac.energy_table.num):
return catimac.energy_table(i)
else:
return -1.0
def get_energy_table():
r = [catimac.energy_table(x) for x in range(catimac.energy_table.num)]
return r
def storage_info():
res = []
for i in range(catimac.max_storage_data):
data = catimac._storage.Get(i)
if(data.p.A>0 and data.p.Z>0 and data.m.ncomponents()>0):
matter = []
for j in range(data.m.ncomponents()):
e = data.m.get_element(j)
matter.append([e.A,e.Z,e.stn])
res.append({"projectile":[data.p.A,data.p.Z],"matter":matter})
return res
def catima_info():
print("CATIMA version = 1.0")
print("number of energy points = %g"%max_datapoints)
print("min energy point = 10^%g MeV/u"%logEmin)
print("max energy point = 10^%g MeV/u"%logEmax)