product.py @ f88e248

core_shell_microgelscostrafo411magnetic_modelticket-1257-vesicle-productticket_1156ticket_1265_superballticket_822_more_unit_tests

Last change on this file since f88e248 was f88e248, checked in by Paul Kienzle <pkienzle@…>, 7 years ago
product: fix collision resolution for parameters in both S and P
Property mode set to `100644`
File size: 11.4 KB

Line
1	"""
2	Product model
3	-------------
4
5	The product model multiplies the structure factor by the form factor,
6	modulated by the effective radius of the form. The resulting model
7	has a attributes of both the model description (with parameters, etc.)
8	and the module evaluator (with call, release, etc.).
9
10	To use it, first load form factor P and structure factor S, then create
11	make_product_info(P, S).
12	"""
13	from __future__ import print_function, division
14
15	from copy import copy
16	import numpy as np # type: ignore
17
18	from .modelinfo import Parameter, ParameterTable, ModelInfo
19	from .kernel import KernelModel, Kernel
20	from .details import make_details, dispersion_mesh
21
22	try:
23	from typing import Tuple
24	except ImportError:
25	pass
26
27	# TODO: make estimates available to constraints
28	#ESTIMATED_PARAMETERS = [
29	# ["est_radius_effective", "A", 0.0, [0, np.inf], "", "Estimated effective radius"],
30	# ["est_volume_ratio", "", 1.0, [0, np.inf], "", "Estimated volume ratio"],
31	#]
32
33	ER_ID = "radius_effective"
34	VF_ID = "volfraction"
35
36	# TODO: core_shell_sphere model has suppressed the volume ratio calculation
37	# revert it after making VR and ER available at run time as constraints.
38	def make_product_info(p_info, s_info):
39	# type: (ModelInfo, ModelInfo) -> ModelInfo
40	"""
41	Create info block for product model.
42	"""
43	# Make sure effective radius is the first parameter and
44	# make sure volume fraction is the second parameter of the
45	# structure factor calculator. Structure factors should not
46	# have any magnetic parameters
47	if not s_info.parameters.kernel_parameters[0].id == ER_ID:
48	raise TypeError("S needs %s as first parameter"%ER_ID)
49	if not s_info.parameters.kernel_parameters[1].id == VF_ID:
50	raise TypeError("S needs %s as second parameter"%VF_ID)
51	if not s_info.parameters.magnetism_index == []:
52	raise TypeError("S should not have SLD parameters")
53	p_id, p_name, p_pars = p_info.id, p_info.name, p_info.parameters
54	s_id, s_name, s_pars = s_info.id, s_info.name, s_info.parameters
55
56	# Create list of parameters for the combined model. Skip the first
57	# parameter of S, which we verified above is effective radius. If there
58	# are any names in P that overlap with those in S, modify the name in S
59	# to distinguish it.
60	p_set = set(p.id for p in p_pars.kernel_parameters)
61	s_list = [(_tag_parameter(par) if par.id in p_set else par)
62	for par in s_pars.kernel_parameters[1:]]
63	# Check if still a collision after renaming. This could happen if for
64	# example S has volfrac and P has both volfrac and volfrac_S.
65	if any(p.id in p_set for p in s_list):
66	raise TypeError("name collision: P has P.name and P.name_S while S has S.name")
67
68	translate_name = dict((old.id, new.id) for old, new
69	in zip(s_pars.kernel_parameters[1:], s_list))
70	demo = {}
71	demo.update(p_info.demo.items())
72	demo.update((translate_name[k], v) for k, v in s_info.demo.items()
73	if k not in ("background", "scale") and not k.startswith(ER_ID))
74	combined_pars = p_pars.kernel_parameters + s_list
75	parameters = ParameterTable(combined_pars)
76	parameters.max_pd = p_pars.max_pd + s_pars.max_pd
77
78	model_info = ModelInfo()
79	model_info.id = '*'.join((p_id, s_id))
80	model_info.name = '*'.join((p_name, s_name))
81	model_info.filename = None
82	model_info.title = 'Product of %s and %s'%(p_name, s_name)
83	model_info.description = model_info.title
84	model_info.docs = model_info.title
85	model_info.category = "custom"
86	model_info.parameters = parameters
87	#model_info.single = p_info.single and s_info.single
88	model_info.structure_factor = False
89	model_info.variant_info = None
90	#model_info.tests = []
91	#model_info.source = []
92	# Iq, Iqxy, form_volume, ER, VR and sesans
93	# Remember the component info blocks so we can build the model
94	model_info.composition = ('product', [p_info, s_info])
95	model_info.demo = demo
96
97	## Show the parameter table with the demo values
98	#from .compare import get_pars, parlist
99	#print("==== %s ====="%model_info.name)
100	#values = get_pars(model_info, use_demo=True)
101	#print(parlist(model_info, values, is2d=True))
102	return model_info
103
104	def _tag_parameter(par):
105	"""
106	Tag the parameter name with _S to indicate that the parameter comes from
107	the structure factor parameter set. This is only necessary if the
108	form factor model includes a parameter of the same name as a parameter
109	in the structure factor.
110	"""
111	par = copy(par)
112	# Protect against a vector parameter in S by appending the vector length
113	# to the renamed parameter. Note: haven't tested this since no existing
114	# structure factor models contain vector parameters.
115	vector_length = par.name[len(par.id):]
116	par.id = par.id + "_S"
117	par.name = par.id + vector_length
118	return par
119
120	class ProductModel(KernelModel):
121	def __init__(self, model_info, P, S):
122	# type: (ModelInfo, KernelModel, KernelModel) -> None
123	self.info = model_info
124	self.P = P
125	self.S = S
126
127	def make_kernel(self, q_vectors):
128	# type: (List[np.ndarray]) -> Kernel
129	# Note: may be sending the q_vectors to the GPU twice even though they
130	# are only needed once. It would mess up modularity quite a bit to
131	# handle this optimally, especially since there are many cases where
132	# separate q vectors are needed (e.g., form in python and structure
133	# in opencl; or both in opencl, but one in single precision and the
134	# other in double precision).
135	p_kernel = self.P.make_kernel(q_vectors)
136	s_kernel = self.S.make_kernel(q_vectors)
137	return ProductKernel(self.info, p_kernel, s_kernel)
138
139	def release(self):
140	# type: (None) -> None
141	"""
142	Free resources associated with the model.
143	"""
144	self.P.release()
145	self.S.release()
146
147
148	class ProductKernel(Kernel):
149	def __init__(self, model_info, p_kernel, s_kernel):
150	# type: (ModelInfo, Kernel, Kernel) -> None
151	self.info = model_info
152	self.p_kernel = p_kernel
153	self.s_kernel = s_kernel
154	self.dtype = p_kernel.dtype
155	self.results = [] # type: List[np.ndarray]
156
157	def __call__(self, call_details, values, cutoff, magnetic):
158	# type: (CallDetails, np.ndarray, float, bool) -> np.ndarray
159	p_info, s_info = self.info.composition[1]
160
161	# if there are magnetic parameters, they will only be on the
162	# form factor P, not the structure factor S.
163	nmagnetic = len(self.info.parameters.magnetism_index)
164	if nmagnetic:
165	spin_index = self.info.parameters.npars + 2
166	magnetism = values[spin_index: spin_index+3+3*nmagnetic]
167	else:
168	magnetism = []
169	nvalues = self.info.parameters.nvalues
170	nweights = call_details.num_weights
171	weights = values[nvalues:nvalues + 2*nweights]
172
173	# Construct the calling parameters for P.
174	p_npars = p_info.parameters.npars
175	p_length = call_details.length[:p_npars]
176	p_offset = call_details.offset[:p_npars]
177	p_details = make_details(p_info, p_length, p_offset, nweights)
178	# Set p scale to the volume fraction in s, which is the first of the
179	# 'S' parameters in the parameter list, or 2+np in 0-origin.
180	volfrac = values[2+p_npars]
181	p_values = [[volfrac, 0.0], values[2:2+p_npars], magnetism, weights]
182	spacer = (32 - sum(len(v) for v in p_values)%32)%32
183	p_values.append([0.]*spacer)
184	p_values = np.hstack(p_values).astype(self.p_kernel.dtype)
185
186	# Call ER and VR for P since these are needed for S.
187	p_er, p_vr = calc_er_vr(p_info, p_details, p_values)
188	s_vr = (volfrac/p_vr if p_vr != 0. else volfrac)
189	#print("volfrac:%g p_er:%g p_vr:%g s_vr:%g"%(volfrac,p_er,p_vr,s_vr))
190
191	# Construct the calling parameters for S.
192	# The effective radius is not in the combined parameter list, so
193	# the number of 'S' parameters is one less than expected. The
194	# computed effective radius needs to be added into the weights
195	# vector, especially since it is a polydisperse parameter in the
196	# stand-alone structure factor models. We will added it at the
197	# end so the remaining offsets don't need to change.
198	s_npars = s_info.parameters.npars-1
199	s_length = call_details.length[p_npars:p_npars+s_npars]
200	s_offset = call_details.offset[p_npars:p_npars+s_npars]
201	s_length = np.hstack((1, s_length))
202	s_offset = np.hstack((nweights, s_offset))
203	s_details = make_details(s_info, s_length, s_offset, nweights+1)
204	v, w = weights[:nweights], weights[nweights:]
205	s_values = [
206	# scale=1, background=0, radius_effective=p_er, volfraction=s_vr
207	[1., 0., p_er, s_vr],
208	# structure factor parameters start after scale, background and
209	# all the form factor parameters. Skip the volfraction parameter
210	# as well, since it is computed elsewhere, and go to the end of the
211	# parameter list.
212	values[2+p_npars+1:2+p_npars+s_npars],
213	# no magnetism parameters to include for S
214	# add er into the (value, weights) pairs
215	v, [p_er], w, [1.0]
216	]
217	spacer = (32 - sum(len(v) for v in s_values)%32)%32
218	s_values.append([0.]*spacer)
219	s_values = np.hstack(s_values).astype(self.s_kernel.dtype)
220
221	# Call the kernels
222	p_result = self.p_kernel(p_details, p_values, cutoff, magnetic)
223	s_result = self.s_kernel(s_details, s_values, cutoff, False)
224
225	#print("p_npars",p_npars,s_npars,p_er,s_vr,values[2+p_npars+1:2+p_npars+s_npars])
226	#call_details.show(values)
227	#print("values", values)
228	#p_details.show(p_values)
229	#print("=>", p_result)
230	#s_details.show(s_values)
231	#print("=>", s_result)
232
233	# remember the parts for plotting later
234	self.results = [p_result, s_result]
235
236	#import pylab as plt
237	#plt.subplot(211); plt.loglog(self.p_kernel.q_input.q, p_result, '-')
238	#plt.subplot(212); plt.loglog(self.s_kernel.q_input.q, s_result, '-')
239	#plt.figure()
240
241	return values[0](p_results_result) + values[1]
242
243	def release(self):
244	# type: () -> None
245	self.p_kernel.release()
246	self.s_kernel.release()
247
248
249	def calc_er_vr(model_info, call_details, values):
250	# type: (ModelInfo, ParameterSet) -> Tuple[float, float]
251
252	if model_info.ER is None and model_info.VR is None:
253	return 1.0, 1.0
254
255	nvalues = model_info.parameters.nvalues
256	value = values[nvalues:nvalues + call_details.num_weights]
257	weight = values[nvalues + call_details.num_weights: nvalues + 2*call_details.num_weights]
258	npars = model_info.parameters.npars
259	pairs = [(value[offset:offset+length], weight[offset:offset+length])
260	for p, offset, length
261	in zip(model_info.parameters.call_parameters[2:2+npars],
262	call_details.offset,
263	call_details.length)
264	if p.type == 'volume']
265	value, weight = dispersion_mesh(model_info, pairs)
266
267	if model_info.ER is not None:
268	individual_radii = model_info.ER(*value)
269	radius_effective = np.sum(weight*individual_radii) / np.sum(weight)
270	else:
271	radius_effective = 1.0
272
273	if model_info.VR is not None:
274	whole, part = model_info.VR(*value)
275	volume_ratio = np.sum(weightpart)/np.sum(weightwhole)
276	else:
277	volume_ratio = 1.0
278
279	return radius_effective, volume_ratio

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source: sasmodels/sasmodels/product.py @ f88e248

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