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convert.py
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convert.py
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"""
Convert models to and from sasview.
"""
from __future__ import print_function, division
import math
import warnings
import numpy as np
from .conversion_table import CONVERSION_TABLE
from .core import load_model_info
# List of models which SasView versions don't contain the explicit 'scale' argument.
# When converting such a model, please update this list.
MODELS_WITHOUT_SCALE = [
'teubner_strey',
'broad_peak',
'two_lorentzian',
"two_power_law",
'gauss_lorentz_gel',
'be_polyelectrolyte',
'correlation_length',
'fractal_core_shell',
'binary_hard_sphere',
'raspberry'
]
# List of models which SasView versions don't contain the explicit 'background' argument.
# When converting such a model, please update this list.
MODELS_WITHOUT_BACKGROUND = [
'guinier',
]
MODELS_WITHOUT_VOLFRACTION = [
'fractal',
'vesicle',
'multilayer_vesicle',
]
MAGNETIC_SASVIEW_MODELS = [
'core_shell',
'core_multi_shell',
'cylinder',
'parallelepiped',
'sphere',
]
# Convert new style names for polydispersity info to old style names
PD_DOT = [
("_pd", ".width"),
("_pd_n", ".npts"),
("_pd_nsigma", ".nsigmas"),
("_pd_type", ".type"),
(".lower", ".lower"),
(".upper", ".upper"),
(".fittable", ".fittable"),
(".std", ".std"),
(".units", ".units"),
("", "")
]
def _rescale(par, scale):
return [pk*scale for pk in par] if isinstance(par, list) else par*scale
def _is_sld(model_info, par):
"""
Return True if parameter is a magnetic magnitude or SLD parameter.
"""
if par.startswith('M0:'):
return True
if '_pd' in par or '.' in par:
return False
for p in model_info.parameters.call_parameters:
if p.id == par:
return p.type == 'sld'
# check through kernel parameters in case it is a named as a vector
for p in model_info.parameters.kernel_parameters:
if p.id == par:
return p.type == 'sld'
return False
def _rescale_sld(model_info, pars, scale):
"""
rescale all sld parameters in the new model definition by *scale* so the
numbers are nicer. Relies on the fact that all sld parameters in the
new model definition end with sld. For backward conversion use
*scale=1e-6*. For forward conversion use *scale=1e6*.
"""
return dict((par, (_rescale(v, scale) if _is_sld(model_info, par) else v))
for par, v in pars.items())
def _get_translation_table(model_info, version=(3, 1, 2)):
conv_param = CONVERSION_TABLE.get(version, {}).get(model_info.id, [None, {}])
translation = conv_param[1].copy()
for p in model_info.parameters.kernel_parameters:
if p.length > 1:
newid = p.id
oldid = translation.get(p.id, p.id)
translation.pop(newid, None)
for k in range(1, p.length+1):
if newid+str(k) not in translation:
translation[newid+str(k)] = oldid+str(k)
# Remove control parameter from the result
control_pars = [p.id for p in model_info.parameters.kernel_parameters
if p.is_control]
if control_pars:
control_id = control_pars[0]
translation[control_id] = "CONTROL"
return translation
# ========= FORWARD CONVERSION sasview 3.x => sasmodels ===========
def _dot_pd_to_underscore_pd(par):
if par.endswith(".width"):
return par[:-6]+"_pd"
elif par.endswith(".type"):
return par[:-5]+"_pd_type"
elif par.endswith(".nsigmas"):
return par[:-8]+"_pd_nsigma"
elif par.endswith(".npts"):
return par[:-5]+"_pd_n"
else:
return par
def _pd_to_underscores(pars):
return dict((_dot_pd_to_underscore_pd(k), v) for k, v in pars.items())
def _convert_pars(pars, mapping):
"""
Rename the parameters and any associated polydispersity attributes.
"""
newpars = pars.copy()
for new, old in mapping.items():
if old == new:
continue
if old is None:
continue
for _, dot in PD_DOT:
source = old+dot
if source in newpars:
if new is not None:
target = new+dot
else:
target = None
if source != target:
if target:
newpars[target] = pars[old+dot]
del newpars[source]
return newpars
def _conversion_target(model_name, version=(3, 1, 2)):
"""
Find the sasmodel name which translates into the sasview name.
Note: *CoreShellEllipsoidModel* translates into *core_shell_ellipsoid:1*.
This is necessary since there is only one variant in sasmodels for the
two variants in sasview.
"""
for sasmodels_name, sasview_dict in \
CONVERSION_TABLE.get(version, {}).items():
if sasview_dict[0] == model_name:
return sasmodels_name
return None
def _hand_convert(name, oldpars, version=(3, 1, 2)):
if version == (3, 1, 2):
oldpars = _hand_convert_3_1_2_to_4_1(name, oldpars)
if version < (4, 2, 0):
oldpars = _rename_magnetic_pars(oldpars)
if version <= (5, 0, 4):
oldpars = _rename_magnetic_angles(oldpars)
return oldpars
def _rename_magnetic_pars(pars):
"""
Change from M0:par to par_M0, etc.
"""
keys = list(pars.items())
for k in keys:
if k.startswith('M0:'):
pars[k[3:]+'_M0'] = pars.pop(k)
elif k.startswith('mtheta:'):
pars[k[7:]+'_mtheta'] = pars.pop(k)
elif k.startswith('mphi:'):
pars[k[5:]+'_mphi'] = pars.pop(k)
elif k.startswith('up:'):
pars['up_'+k[3:]] = pars.pop(k)
return pars
def _rename_magnetic_angles(pars):
"""
Change name of magnetic angle.
"""
if 'up_angle' in pars:
pars['up_theta'] = 90
pars['up_phi'] = pars['up_angle']
pars.pop('up_angle')
return pars
def _hand_convert_3_1_2_to_4_1(name, oldpars):
if name == 'core_shell_parallelepiped':
# Make sure pd on rim parameters defaults to zero
# ... probably not necessary.
oldpars['rimA.width'] = 0.0
oldpars['rimB.width'] = 0.0
oldpars['rimC.width'] = 0.0
elif name == 'core_shell_ellipsoid:1':
# Reverse translation (from new to old), from core_shell_ellipsoid.c
# equat_shell = equat_core + thick_shell
# polar_core = equat_core * x_core
# polar_shell = equat_core * x_core + thick_shell*x_polar_shell
# Forward translation (from old to new), inverting reverse translation:
# thick_shell = equat_shell - equat_core
# x_core = polar_core / equat_core
# x_polar_shell = (polar_shell - polar_core)/(equat_shell - equat_core)
# Auto translation (old <=> new) happens after hand_convert
# equat_shell <=> thick_shell
# polar_core <=> x_core
# polar_shell <=> x_polar_shell
# So...
equat_core, equat_shell = oldpars['equat_core'], oldpars['equat_shell']
polar_core, polar_shell = oldpars['polar_core'], oldpars['polar_shell']
oldpars['equat_shell'] = equat_shell - equat_core
oldpars['polar_core'] = polar_core / equat_core
oldpars['polar_shell'] = (polar_shell-polar_core)/(equat_shell-equat_core)
elif name == 'hollow_cylinder':
# now uses radius and thickness
thickness = oldpars['radius'] - oldpars['core_radius']
oldpars['radius'] = thickness
if 'radius.width' in oldpars:
pd = oldpars['radius.width']*oldpars['radius']/thickness
oldpars['radius.width'] = pd
elif name == 'multilayer_vesicle':
if 'scale' in oldpars:
oldpars['volfraction'] = oldpars['scale']
oldpars['scale'] = 1.0
if 'scale.lower' in oldpars:
oldpars['volfraction.lower'] = oldpars['scale.lower']
if 'scale.upper' in oldpars:
oldpars['volfraction.upper'] = oldpars['scale.upper']
if 'scale.fittable' in oldpars:
oldpars['volfraction.fittable'] = oldpars['scale.fittable']
if 'scale.std' in oldpars:
oldpars['volfraction.std'] = oldpars['scale.std']
if 'scale.units' in oldpars:
oldpars['volfraction.units'] = oldpars['scale.units']
elif name == 'pearl_necklace':
pass
#_remove_pd(oldpars, 'num_pearls', name)
#_remove_pd(oldpars, 'thick_string', name)
elif name == 'polymer_micelle':
if 'ndensity' in oldpars:
oldpars['ndensity'] /= 1e15
if 'ndensity.lower' in oldpars:
oldpars['ndensity.lower'] /= 1e15
if 'ndensity.upper' in oldpars:
oldpars['ndensity.upper'] /= 1e15
elif name == 'rpa':
# convert scattering lengths from femtometers to centimeters
for p in "L1", "L2", "L3", "L4":
if p in oldpars:
oldpars[p] /= 1e-13
if p + ".lower" in oldpars:
oldpars[p + ".lower"] /= 1e-13
if p + ".upper" in oldpars:
oldpars[p + ".upper"] /= 1e-13
elif name == 'spherical_sld':
j = 0
while "func_inter" + str(j) in oldpars:
name = "func_inter" + str(j)
new_name = "shape" + str(j + 1)
if oldpars[name] == 'Erf(|nu|*z)':
oldpars[new_name] = int(0)
elif oldpars[name] == 'RPower(z^|nu|)':
oldpars[new_name] = int(1)
elif oldpars[name] == 'LPower(z^|nu|)':
oldpars[new_name] = int(2)
elif oldpars[name] == 'RExp(-|nu|*z)':
oldpars[new_name] = int(3)
elif oldpars[name] == 'LExp(-|nu|*z)':
oldpars[new_name] = int(4)
else:
oldpars[new_name] = int(0)
oldpars.pop(name)
oldpars['n_shells'] = str(j + 1)
j += 1
elif name == 'teubner_strey':
# basically undoing the entire Teubner-Strey calculations here.
# drho = (sld_a - sld_b)
# k = 2.0*math.pi*xi/d
# a2 = (1.0 + k**2)**2
# c1 = 2.0 * xi**2 * (1.0 - k**2)
# c2 = xi**4
# prefactor = 8.0*math.pi*phi*(1.0-phi)*drho**2*c2/xi
# scale = 1e-4*prefactor
# oldpars['scale'] = a2/scale
# oldpars['c1'] = c1/scale
# oldpars['c2'] = c2/scale
# need xi, d, sld_a, sld_b, phi=volfraction_a
# assume contrast is 1.0e-6, scale=1, background=0
sld_a, sld_b = 1.0, 0.
drho = sld_a - sld_b
# find xi
p_scale = oldpars['scale']
p_c1 = oldpars['c1']
p_c2 = oldpars['c2']
i_1 = 0.5*p_c1/p_c2
i_2 = math.sqrt(math.fabs(p_scale/p_c2))
i_3 = 2/(i_1 + i_2)
xi = math.sqrt(math.fabs(i_3))
# find d from xi
k = math.sqrt(math.fabs(1 - 0.5*p_c1/p_c2*xi**2))
d = 2*math.pi*xi/k
# solve quadratic phi (1-phi) = xi/(1e-4 8 pi drho^2 c2)
# favour volume fraction in [0, 0.5]
c = xi / (1e-4 * 8.0 * math.pi * drho**2 * p_c2)
phi = 0.5 - math.sqrt(0.25 - c)
# scale sld_a by 1e-6 because the translator will scale it back
oldpars.update(volfraction_a=phi, xi=xi, d=d, sld_a=sld_a*1e-6,
sld_b=sld_b, scale=1.0)
oldpars.pop('c1')
oldpars.pop('c2')
return oldpars
def convert_model(name, pars, use_underscore=False, model_version=(3, 1, 2)):
"""
Convert model from old style parameter names to new style.
"""
newpars = pars
keys = sorted(CONVERSION_TABLE.keys())
for i, version in enumerate(keys):
# Don't allow indices outside list
next_i = i + 1
if next_i == len(keys):
next_i = i
# If the save state is from a later version, skip the check
if model_version <= keys[next_i]:
newname = _conversion_target(name, version)
else:
newname = None
# If no conversion is found, move on
if newname is None:
newname = name
continue
if ':' in newname: # core_shell_ellipsoid:1
model_info = load_model_info(newname[:-2])
# Know the table exists and isn't multiplicity so grab it directly
# Can't use _get_translation_table since that will return the 'bare'
# version.
translation = CONVERSION_TABLE.get(version, {})[newname][1]
else:
model_info = load_model_info(newname)
translation = _get_translation_table(model_info, version)
newpars = _hand_convert(newname, newpars, version)
newpars = _convert_pars(newpars, translation)
# TODO: Still not convinced this is the best check
if not model_info.structure_factor and version == (3, 1, 2):
newpars = _rescale_sld(model_info, newpars, 1e6)
newpars.setdefault('scale', 1.0)
newpars.setdefault('background', 0.0)
newpars.setdefault('up_theta', 90.0)
if use_underscore:
newpars = _pd_to_underscores(newpars)
name = newname
return newname, newpars
# ========= BACKWARD CONVERSION sasmodels => sasview 3.x ===========
def _revert_pars(pars, mapping):
"""
Rename the parameters and any associated polydispersity attributes.
"""
newpars = pars.copy()
for new, old in mapping.items():
for underscore, dot in PD_DOT:
if old and old+underscore == new+dot:
continue
if new+underscore in newpars:
if old is not None:
newpars[old+dot] = pars[new+underscore]
del newpars[new+underscore]
for k in list(newpars.keys()):
for underscore, dot in PD_DOT[1:]: # skip "" => ""
if k.endswith(underscore):
newpars[k[:-len(underscore)]+dot] = newpars[k]
del newpars[k]
return newpars
def revert_name(model_info):
"""Translate model name back to the name used in SasView 3.x"""
oldname, _ = CONVERSION_TABLE.get(model_info.id, [None, {}])
return oldname
def _remove_pd(pars, key, name):
"""
Remove polydispersity from the parameter list.
Note: operates in place
"""
# Bumps style parameter names
width = pars.pop(key+".width", 0.0)
n_points = pars.pop(key+".npts", 0)
if width != 0.0 and n_points != 0:
warnings.warn("parameter %s not polydisperse in sasview %s"%(key, name))
pars.pop(key+".nsigmas", None)
pars.pop(key+".type", None)
return pars
def _trim_vectors(model_info, pars, oldpars):
_, translation = CONVERSION_TABLE.get(model_info.id, [None, {}])
for p in model_info.parameters.kernel_parameters:
if p.length_control is not None:
n = int(pars[p.length_control])
oldname = translation.get(p.id, p.id)
for k in range(n+1, p.length+1):
for _, old in PD_DOT:
oldpars.pop(oldname+str(k)+old, None)
return oldpars
def revert_pars(model_info, pars):
"""
Convert model from new style parameter names to old style.
"""
if model_info.composition is not None:
composition_type, parts = model_info.composition
if composition_type == 'product':
translation = _get_translation_table(parts[0])
# structure factor models include scale:scale_factor mapping
translation.update(_get_translation_table(parts[1]))
else:
raise NotImplementedError("cannot convert to sasview sum")
else:
translation = _get_translation_table(model_info)
oldpars = _revert_pars(_rescale_sld(model_info, pars, 1e-6), translation)
oldpars = _trim_vectors(model_info, pars, oldpars)
# Make sure the control parameter is an integer
if "CONTROL" in oldpars:
oldpars["CONTROL"] = int(oldpars["CONTROL"])
# Note: update compare.constrain_pars to match
name = model_info.id
if name in MODELS_WITHOUT_SCALE or model_info.structure_factor:
if oldpars.pop('scale', 1.0) != 1.0:
warnings.warn("parameter scale not used in sasview %s"%name)
if name in MODELS_WITHOUT_BACKGROUND or model_info.structure_factor:
if oldpars.pop('background', 0.0) != 0.0:
warnings.warn("parameter background not used in sasview %s"%name)
# Remove magnetic parameters from non-magnetic sasview models
if name not in MAGNETIC_SASVIEW_MODELS:
oldpars = dict((k, v) for k, v in oldpars.items() if ':' not in k)
# If it is a product model P*S, then check the individual forms for special
# cases. Note: despite the structure factor alone not having scale or
# background, the product model does, so this is below the test for
# models without scale or background.
namelist = name.split('*') if '*' in name else [name]
for name in namelist:
if name in MODELS_WITHOUT_VOLFRACTION:
del oldpars['volfraction']
elif name == 'core_multi_shell':
# kill extra shells
for k in range(5, 11):
oldpars.pop('sld_shell'+str(k), 0)
oldpars.pop('thick_shell'+str(k), 0)
oldpars.pop('mtheta:sld'+str(k), 0)
oldpars.pop('mphi:sld'+str(k), 0)
oldpars.pop('M0:sld'+str(k), 0)
_remove_pd(oldpars, 'sld_shell'+str(k), 'sld')
_remove_pd(oldpars, 'thick_shell'+str(k), 'thickness')
elif name == 'core_shell_parallelepiped':
_remove_pd(oldpars, 'rimA', name)
_remove_pd(oldpars, 'rimB', name)
_remove_pd(oldpars, 'rimC', name)
elif name == 'hollow_cylinder':
# now uses radius and thickness
thickness = oldpars['core_radius']
oldpars['radius'] += thickness
oldpars['radius.width'] *= thickness/oldpars['radius']
#elif name in ['mono_gauss_coil', 'poly_gauss_coil']:
# del oldpars['i_zero']
elif name == 'onion':
oldpars.pop('n_shells', None)
elif name == 'pearl_necklace':
_remove_pd(oldpars, 'num_pearls', name)
_remove_pd(oldpars, 'thick_string', name)
elif name == 'polymer_micelle':
if 'ndensity' in oldpars:
oldpars['ndensity'] *= 1e15
elif name == 'rpa':
# convert scattering lengths from femtometers to centimeters
for p in "L1", "L2", "L3", "L4":
if p in oldpars:
oldpars[p] *= 1e-13
if pars['case_num'] < 2:
for k in ("a", "b"):
for p in ("L", "N", "Phi", "b", "v"):
oldpars.pop(p+k, None)
for k in "Kab,Kac,Kad,Kbc,Kbd".split(','):
oldpars.pop(k, None)
elif pars['case_num'] < 5:
for k in ("a",):
for p in ("L", "N", "Phi", "b", "v"):
oldpars.pop(p+k, None)
for k in "Kab,Kac,Kad".split(','):
oldpars.pop(k, None)
elif name == 'spherical_sld':
oldpars["CONTROL"] -= 1
# remove polydispersity from shells
for k in range(1, 11):
_remove_pd(oldpars, 'thick_flat'+str(k), 'thickness')
_remove_pd(oldpars, 'thick_inter'+str(k), 'interface')
# remove extra shells
for k in range(int(pars['n_shells']), 11):
oldpars.pop('sld_flat'+str(k), 0)
oldpars.pop('thick_flat'+str(k), 0)
oldpars.pop('thick_inter'+str(k), 0)
oldpars.pop('func_inter'+str(k), 0)
oldpars.pop('nu_inter'+str(k), 0)
elif name == 'stacked_disks':
_remove_pd(oldpars, 'n_stacking', name)
elif name == 'teubner_strey':
# basically redoing the entire Teubner-Strey calculations here.
volfraction = oldpars.pop('volfraction_a')
xi = oldpars.pop('xi')
d = oldpars.pop('d')
sld_a = oldpars.pop('sld_a')
sld_b = oldpars.pop('sld_b')
drho = 1e6*(sld_a - sld_b) # conversion autoscaled these
k = 2.0*math.pi*xi/d
a2 = (1.0 + k**2)**2
c1 = 2.0 * xi**2 * (1.0 - k**2)
c2 = xi**4
prefactor = 8.0*math.pi*volfraction*(1.0-volfraction)*drho**2*c2/xi
scale = 1e-4*prefactor
oldpars['scale'] = a2/scale
oldpars['c1'] = c1/scale
oldpars['c2'] = c2/scale
#print("convert from",list(sorted(pars)))
#print("convert to",list(sorted(oldpars.items())))
return oldpars
def constrain_new_to_old(model_info, pars):
"""
Restrict parameter values to those that will match sasview.
"""
name = model_info.id
# Note: update convert.revert_model to match
if name in MODELS_WITHOUT_SCALE or model_info.structure_factor:
pars['scale'] = 1
if name in MODELS_WITHOUT_BACKGROUND or model_info.structure_factor:
pars['background'] = 0
# sasview multiplies background by structure factor
if '*' in name:
pars['background'] = 0
# Shut off magnetism when comparing non-magnetic sasview models
if name not in MAGNETIC_SASVIEW_MODELS:
suppress_magnetism = False
for key in pars.keys():
if key.startswith("M0:"):
suppress_magnetism = suppress_magnetism or (pars[key] != 0)
pars[key] = 0
if suppress_magnetism:
warnings.warn("suppressing magnetism for comparison with sasview")
# Shut off theta polydispersity since algorithm has changed
if 'theta_pd_n' in pars:
if pars['theta_pd_n'] != 0:
warnings.warn("suppressing theta polydispersity for comparison with sasview")
pars['theta_pd_n'] = 0
# If it is a product model P*S, then check the individual forms for special
# cases. Note: despite the structure factor alone not having scale or
# background, the product model does, so this is below the test for
# models without scale or background.
namelist = name.split('*') if '*' in name else [name]
for name in namelist:
if name in MODELS_WITHOUT_VOLFRACTION:
pars['volfraction'] = 1
if name == 'core_multi_shell':
pars['n'] = min(math.ceil(pars['n']), 4)
elif name == 'gel_fit':
pars['scale'] = 1
elif name == 'line':
pars['scale'] = 1
pars['background'] = 0
elif name == 'mono_gauss_coil':
pars['scale'] = 1
elif name == 'onion':
pars['n_shells'] = math.ceil(pars['n_shells'])
elif name == 'pearl_necklace':
pars['string_thickness_pd_n'] = 0
pars['number_of_pearls_pd_n'] = 0
elif name == 'poly_gauss_coil':
pars['scale'] = 1
elif name == 'rpa':
pars['case_num'] = int(pars['case_num'])
elif name == 'spherical_sld':
pars['n_shells'] = math.ceil(pars['n_shells'])
pars['n_steps'] = math.ceil(pars['n_steps'])
for k in range(1, 11):
pars['shape%d'%k] = math.trunc(pars['shape%d'%k]+0.5)
for k in range(2, 11):
pars['thickness%d_pd_n'%k] = 0
pars['interface%d_pd_n'%k] = 0
elif name == 'teubner_strey':
pars['scale'] = 1
if pars['volfraction_a'] > 0.5:
pars['volfraction_a'] = 1.0 - pars['volfraction_a']
elif name == 'unified_power_Rg':
pars['level'] = int(pars['level'])
def _check_one(name, seed=None):
"""
Generate a random set of parameters for *name*, and check that they can
be converted back to SasView 3.x and forward again to sasmodels. Raises
an error if the parameters are changed.
"""
from . import compare
model_info = load_model_info(name)
old_name = revert_name(model_info)
if old_name is None:
return
pars = compare.get_pars(model_info)
if seed is not None:
np.random.seed(seed)
pars = compare.randomize_pars(model_info, pars)
if name == "teubner_strey":
# T-S model is underconstrained, so fix the assumptions.
pars['sld_a'], pars['sld_b'] = 1.0, 0.0
compare.constrain_pars(model_info, pars)
constrain_new_to_old(model_info, pars)
old_pars = revert_pars(model_info, pars)
new_name, new_pars = convert_model(old_name, old_pars, use_underscore=True)
if 1:
print("==== %s in ====="%name)
print(str(compare.parlist(model_info, pars, True)))
print("==== %s ====="%old_name)
for k, v in sorted(old_pars.items()):
print(k, v)
print("==== %s out ====="%new_name)
print(str(compare.parlist(model_info, new_pars, True)))
assert name == new_name, "%r != %r"%(name, new_name)
for k, v in new_pars.items():
assert k in pars, "%s: %r appeared from conversion"%(name, k)
if isinstance(v, float):
assert abs(v-pars[k]) <= abs(1e-12*v), \
"%s: %r %s != %s"%(name, k, v, pars[k])
else:
assert v == pars[k], "%s: %r %s != %s"%(name, k, v, pars[k])
for k, v in pars.items():
assert k in pars, "%s: %r not converted"%(name, k)
def test_backward_forward():
"""
Test conversion of model parameters from 4.x to 3.x and back.
"""
from .core import list_models
for name in list_models('all'):
_check_one(name, seed=1)