CFractalModel.cpp @ 2605da22

ESS_GUIESS_GUI_DocsESS_GUI_batch_fittingESS_GUI_bumps_abstractionESS_GUI_iss1116ESS_GUI_iss879ESS_GUI_iss959ESS_GUI_openclESS_GUI_orderingESS_GUI_sync_sascalccostrafo411magnetic_scattrelease-4.1.1release-4.1.2release-4.2.2release_4.0.1ticket-1009ticket-1094-headlessticket-1242-2d-resolutionticket-1243ticket-1249ticket885unittest-saveload

Last change on this file since 2605da22 was 2605da22, checked in by Mathieu Doucet <doucetm@…>, 12 years ago
Re #4 Still a few more warnings
Property mode set to `100644`
File size: 20.0 KB

Line
1	/**
2	This software was developed by the University of Tennessee as part of the
3	Distributed Data Analysis of Neutron Scattering Experiments (DANSE)
4	project funded by the US National Science Foundation.
5
6	If you use DANSE applications to do scientific research that leads to
7	publication, we ask that you acknowledge the use of the software with the
8	following sentence:
9
10	"This work benefited from DANSE software developed under NSF award DMR-0520547."
11
12	copyright 2008, University of Tennessee
13	*/
14
15	/** CFractalModel
16	*
17	* C extension
18	*
19	* WARNING: THIS FILE WAS GENERATED BY WRAPPERGENERATOR.PY
20	* DO NOT MODIFY THIS FILE, MODIFY fractal.h
21	* AND RE-RUN THE GENERATOR SCRIPT
22	*
23	*/
24	#define NO_IMPORT_ARRAY
25	#define PY_ARRAY_UNIQUE_SYMBOL PyArray_API_sans
26
27	extern "C" {
28	#include <Python.h>
29	#include <arrayobject.h>
30	#include "structmember.h"
31	#include <stdio.h>
32	#include <stdlib.h>
33	#include <math.h>
34	#include <time.h>
35	#include "fractal.h"
36	}
37
38	#include "models.hh"
39	#include "dispersion_visitor.hh"
40
41	/// Error object for raised exceptions
42	static PyObject * CFractalModelError = NULL;
43
44
45	// Class definition
46	typedef struct {
47	PyObject_HEAD
48	/// Parameters
49	PyObject * params;
50	/// Dispersion parameters
51	PyObject * dispersion;
52	/// Underlying model object
53	FractalModel * model;
54	/// Log for unit testing
55	PyObject * log;
56	} CFractalModel;
57
58
59	static void
60	CFractalModel_dealloc(CFractalModel* self)
61	{
62	Py_DECREF(self->params);
63	Py_DECREF(self->dispersion);
64	Py_DECREF(self->log);
65	delete self->model;
66	self->ob_type->tp_free((PyObject*)self);
67
68
69	}
70
71	static PyObject *
72	CFractalModel_new(PyTypeObject type, PyObject args, PyObject *kwds)
73	{
74	CFractalModel *self;
75
76	self = (CFractalModel *)type->tp_alloc(type, 0);
77
78	return (PyObject *)self;
79	}
80
81	static int
82	CFractalModel_init(CFractalModel self, PyObject args, PyObject *kwds)
83	{
84	if (self != NULL) {
85
86	// Create parameters
87	self->params = PyDict_New();
88	self->dispersion = PyDict_New();
89	self->model = new FractalModel();
90
91	// Initialize parameter dictionary
92	PyDict_SetItemString(self->params,"scale",Py_BuildValue("d",0.050000000000));
93	PyDict_SetItemString(self->params,"fractal_dim",Py_BuildValue("d",2.000000000000));
94	PyDict_SetItemString(self->params,"sldSolv",Py_BuildValue("d",0.000006350000));
95	PyDict_SetItemString(self->params,"cor_length",Py_BuildValue("d",100.000000000000));
96	PyDict_SetItemString(self->params,"background",Py_BuildValue("d",0.000000000000));
97	PyDict_SetItemString(self->params,"radius",Py_BuildValue("d",5.000000000000));
98	PyDict_SetItemString(self->params,"sldBlock",Py_BuildValue("d",0.000002000000));
99	// Initialize dispersion / averaging parameter dict
100	DispersionVisitor* visitor = new DispersionVisitor();
101	PyObject * disp_dict;
102	disp_dict = PyDict_New();
103	self->model->radius.dispersion->accept_as_source(visitor, self->model->radius.dispersion, disp_dict);
104	PyDict_SetItemString(self->dispersion, "radius", disp_dict);
105
106
107
108	// Create empty log
109	self->log = PyDict_New();
110
111
112
113	}
114	return 0;
115	}
116
117	static char name_params[] = "params";
118	static char def_params[] = "Parameters";
119	static char name_dispersion[] = "dispersion";
120	static char def_dispersion[] = "Dispersion parameters";
121	static char name_log[] = "log";
122	static char def_log[] = "Log";
123
124	static PyMemberDef CFractalModel_members[] = {
125	{name_params, T_OBJECT, offsetof(CFractalModel, params), 0, def_params},
126	{name_dispersion, T_OBJECT, offsetof(CFractalModel, dispersion), 0, def_dispersion},
127	{name_log, T_OBJECT, offsetof(CFractalModel, log), 0, def_log},
128	{NULL} /* Sentinel */
129	};
130
131	/** Read double from PyObject
132	@param p PyObject
133	@return double
134	*/
135	double CFractalModel_readDouble(PyObject *p) {
136	if (PyFloat_Check(p)==1) {
137	return (double)(((PyFloatObject *)(p))->ob_fval);
138	} else if (PyInt_Check(p)==1) {
139	return (double)(((PyIntObject *)(p))->ob_ival);
140	} else if (PyLong_Check(p)==1) {
141	return (double)PyLong_AsLong(p);
142	} else {
143	return 0.0;
144	}
145	}
146	/**
147	* Function to call to evaluate model
148	* @param args: input numpy array q[]
149	* @return: numpy array object
150	*/
151
152	static PyObject evaluateOneDim(FractalModel model, PyArrayObject *q){
153	PyArrayObject *result;
154
155	// Check validity of array q , q must be of dimension 1, an array of double
156	if (q->nd != 1 \|\| q->descr->type_num != PyArray_DOUBLE)
157	{
158	//const char * message= "Invalid array: q->nd=%d,type_num=%d\n",q->nd,q->descr->type_num;
159	//PyErr_SetString(PyExc_ValueError , message);
160	return NULL;
161	}
162	result = (PyArrayObject )PyArray_FromDims(q->nd, (int )(q->dimensions),
163	PyArray_DOUBLE);
164	if (result == NULL) {
165	const char * message= "Could not create result ";
166	PyErr_SetString(PyExc_RuntimeError , message);
167	return NULL;
168	}
169	for (int i = 0; i < q->dimensions[0]; i++){
170	double q_value = (double )(q->data + i*q->strides[0]);
171	double result_value = (double )(result->data + i*result->strides[0]);
172	result_value =(model)(q_value);
173	}
174	return PyArray_Return(result);
175	}
176
177	/**
178	* Function to call to evaluate model
179	* @param args: input numpy array [x[],y[]]
180	* @return: numpy array object
181	*/
182	static PyObject * evaluateTwoDimXY( FractalModel* model,
183	PyArrayObject x, PyArrayObject y)
184	{
185	PyArrayObject *result;
186	int i, x_len, y_len, dims[1];
187	//check validity of input vectors
188	if (x->nd != 1 \|\| x->descr->type_num != PyArray_DOUBLE
189	\|\| y->nd != 1 \|\| y->descr->type_num != PyArray_DOUBLE
190	\|\| y->dimensions[0] != x->dimensions[0]){
191	const char * message= "evaluateTwoDimXY expect 2 numpy arrays";
192	PyErr_SetString(PyExc_ValueError , message);
193	return NULL;
194	}
195
196	if (PyArray_Check(x) && PyArray_Check(y)) {
197
198	x_len = dims[0]= x->dimensions[0];
199	y_len = dims[0]= y->dimensions[0];
200
201	// Make a new double matrix of same dims
202	result=(PyArrayObject *) PyArray_FromDims(1,dims,NPY_DOUBLE);
203	if (result == NULL){
204	const char * message= "Could not create result ";
205	PyErr_SetString(PyExc_RuntimeError , message);
206	return NULL;
207	}
208
209	/* Do the calculation. */
210	for ( i=0; i< x_len; i++) {
211	double x_value = (double )(x->data + i*x->strides[0]);
212	double y_value = (double )(y->data + i*y->strides[0]);
213	double result_value = (double )(result->data +
214	i*result->strides[0]);
215	result_value = (model)(x_value, y_value);
216	}
217	return PyArray_Return(result);
218
219	}else{
220	PyErr_SetString(CFractalModelError,
221	"CFractalModel.evaluateTwoDimXY couldn't run.");
222	return NULL;
223	}
224	}
225	/**
226	* evalDistribution function evaluate a model function with input vector
227	* @param args: input q as vector or [qx, qy] where qx, qy are vectors
228	*
229	*/
230	static PyObject * evalDistribution(CFractalModel self, PyObject args){
231	PyObject qx, qy;
232	PyArrayObject * pars;
233	int npars ,mpars;
234
235	// Get parameters
236
237	// Reader parameter dictionary
238	self->model->scale = PyFloat_AsDouble( PyDict_GetItemString(self->params, "scale") );
239	self->model->fractal_dim = PyFloat_AsDouble( PyDict_GetItemString(self->params, "fractal_dim") );
240	self->model->sldSolv = PyFloat_AsDouble( PyDict_GetItemString(self->params, "sldSolv") );
241	self->model->cor_length = PyFloat_AsDouble( PyDict_GetItemString(self->params, "cor_length") );
242	self->model->background = PyFloat_AsDouble( PyDict_GetItemString(self->params, "background") );
243	self->model->radius = PyFloat_AsDouble( PyDict_GetItemString(self->params, "radius") );
244	self->model->sldBlock = PyFloat_AsDouble( PyDict_GetItemString(self->params, "sldBlock") );
245	// Read in dispersion parameters
246	PyObject* disp_dict;
247	DispersionVisitor* visitor = new DispersionVisitor();
248	disp_dict = PyDict_GetItemString(self->dispersion, "radius");
249	self->model->radius.dispersion->accept_as_destination(visitor, self->model->radius.dispersion, disp_dict);
250
251
252	// Get input and determine whether we have to supply a 1D or 2D return value.
253	if ( !PyArg_ParseTuple(args,"O",&pars) ) {
254	PyErr_SetString(CFractalModelError,
255	"CFractalModel.evalDistribution expects a q value.");
256	return NULL;
257	}
258	// Check params
259
260	if(PyArray_Check(pars)==1) {
261
262	// Length of list should 1 or 2
263	npars = pars->nd;
264	if(npars==1) {
265	// input is a numpy array
266	if (PyArray_Check(pars)) {
267	return evaluateOneDim(self->model, (PyArrayObject*)pars);
268	}
269	}else{
270	PyErr_SetString(CFractalModelError,
271	"CFractalModel.evalDistribution expect numpy array of one dimension.");
272	return NULL;
273	}
274	}else if( PyList_Check(pars)==1) {
275	// Length of list should be 2 for I(qx,qy)
276	mpars = PyList_GET_SIZE(pars);
277	if(mpars!=2) {
278	PyErr_SetString(CFractalModelError,
279	"CFractalModel.evalDistribution expects a list of dimension 2.");
280	return NULL;
281	}
282	qx = PyList_GET_ITEM(pars,0);
283	qy = PyList_GET_ITEM(pars,1);
284	if (PyArray_Check(qx) && PyArray_Check(qy)) {
285	return evaluateTwoDimXY(self->model, (PyArrayObject*)qx,
286	(PyArrayObject*)qy);
287	}else{
288	PyErr_SetString(CFractalModelError,
289	"CFractalModel.evalDistribution expect 2 numpy arrays in list.");
290	return NULL;
291	}
292	}
293	PyErr_SetString(CFractalModelError,
294	"CFractalModel.evalDistribution couln't be run.");
295	return NULL;
296
297	}
298
299	/**
300	* Function to call to evaluate model
301	* @param args: input q or [q,phi]
302	* @return: function value
303	*/
304	static PyObject * run(CFractalModel self, PyObject args) {
305	double q_value, phi_value;
306	PyObject* pars;
307	int npars;
308
309	// Get parameters
310
311	// Reader parameter dictionary
312	self->model->scale = PyFloat_AsDouble( PyDict_GetItemString(self->params, "scale") );
313	self->model->fractal_dim = PyFloat_AsDouble( PyDict_GetItemString(self->params, "fractal_dim") );
314	self->model->sldSolv = PyFloat_AsDouble( PyDict_GetItemString(self->params, "sldSolv") );
315	self->model->cor_length = PyFloat_AsDouble( PyDict_GetItemString(self->params, "cor_length") );
316	self->model->background = PyFloat_AsDouble( PyDict_GetItemString(self->params, "background") );
317	self->model->radius = PyFloat_AsDouble( PyDict_GetItemString(self->params, "radius") );
318	self->model->sldBlock = PyFloat_AsDouble( PyDict_GetItemString(self->params, "sldBlock") );
319	// Read in dispersion parameters
320	PyObject* disp_dict;
321	DispersionVisitor* visitor = new DispersionVisitor();
322	disp_dict = PyDict_GetItemString(self->dispersion, "radius");
323	self->model->radius.dispersion->accept_as_destination(visitor, self->model->radius.dispersion, disp_dict);
324
325
326	// Get input and determine whether we have to supply a 1D or 2D return value.
327	if ( !PyArg_ParseTuple(args,"O",&pars) ) {
328	PyErr_SetString(CFractalModelError,
329	"CFractalModel.run expects a q value.");
330	return NULL;
331	}
332
333	// Check params
334	if( PyList_Check(pars)==1) {
335
336	// Length of list should be 2 for I(q,phi)
337	npars = PyList_GET_SIZE(pars);
338	if(npars!=2) {
339	PyErr_SetString(CFractalModelError,
340	"CFractalModel.run expects a double or a list of dimension 2.");
341	return NULL;
342	}
343	// We have a vector q, get the q and phi values at which
344	// to evaluate I(q,phi)
345	q_value = CFractalModel_readDouble(PyList_GET_ITEM(pars,0));
346	phi_value = CFractalModel_readDouble(PyList_GET_ITEM(pars,1));
347	// Skip zero
348	if (q_value==0) {
349	return Py_BuildValue("d",0.0);
350	}
351	return Py_BuildValue("d",(*(self->model)).evaluate_rphi(q_value,phi_value));
352
353	} else {
354
355	// We have a scalar q, we will evaluate I(q)
356	q_value = CFractalModel_readDouble(pars);
357
358	return Py_BuildValue("d",(*(self->model))(q_value));
359	}
360	}
361	/**
362	* Function to call to calculate_ER
363	* @return: effective radius value
364	*/
365	static PyObject * calculate_ER(CFractalModel *self) {
366
367	// Get parameters
368
369	// Reader parameter dictionary
370	self->model->scale = PyFloat_AsDouble( PyDict_GetItemString(self->params, "scale") );
371	self->model->fractal_dim = PyFloat_AsDouble( PyDict_GetItemString(self->params, "fractal_dim") );
372	self->model->sldSolv = PyFloat_AsDouble( PyDict_GetItemString(self->params, "sldSolv") );
373	self->model->cor_length = PyFloat_AsDouble( PyDict_GetItemString(self->params, "cor_length") );
374	self->model->background = PyFloat_AsDouble( PyDict_GetItemString(self->params, "background") );
375	self->model->radius = PyFloat_AsDouble( PyDict_GetItemString(self->params, "radius") );
376	self->model->sldBlock = PyFloat_AsDouble( PyDict_GetItemString(self->params, "sldBlock") );
377	// Read in dispersion parameters
378	PyObject* disp_dict;
379	DispersionVisitor* visitor = new DispersionVisitor();
380	disp_dict = PyDict_GetItemString(self->dispersion, "radius");
381	self->model->radius.dispersion->accept_as_destination(visitor, self->model->radius.dispersion, disp_dict);
382
383
384	return Py_BuildValue("d",(*(self->model)).calculate_ER());
385
386	}
387	/**
388	* Function to call to evaluate model in cartesian coordinates
389	* @param args: input q or [qx, qy]]
390	* @return: function value
391	*/
392	static PyObject * runXY(CFractalModel self, PyObject args) {
393	double qx_value, qy_value;
394	PyObject* pars;
395	int npars;
396
397	// Get parameters
398
399	// Reader parameter dictionary
400	self->model->scale = PyFloat_AsDouble( PyDict_GetItemString(self->params, "scale") );
401	self->model->fractal_dim = PyFloat_AsDouble( PyDict_GetItemString(self->params, "fractal_dim") );
402	self->model->sldSolv = PyFloat_AsDouble( PyDict_GetItemString(self->params, "sldSolv") );
403	self->model->cor_length = PyFloat_AsDouble( PyDict_GetItemString(self->params, "cor_length") );
404	self->model->background = PyFloat_AsDouble( PyDict_GetItemString(self->params, "background") );
405	self->model->radius = PyFloat_AsDouble( PyDict_GetItemString(self->params, "radius") );
406	self->model->sldBlock = PyFloat_AsDouble( PyDict_GetItemString(self->params, "sldBlock") );
407	// Read in dispersion parameters
408	PyObject* disp_dict;
409	DispersionVisitor* visitor = new DispersionVisitor();
410	disp_dict = PyDict_GetItemString(self->dispersion, "radius");
411	self->model->radius.dispersion->accept_as_destination(visitor, self->model->radius.dispersion, disp_dict);
412
413
414	// Get input and determine whether we have to supply a 1D or 2D return value.
415	if ( !PyArg_ParseTuple(args,"O",&pars) ) {
416	PyErr_SetString(CFractalModelError,
417	"CFractalModel.run expects a q value.");
418	return NULL;
419	}
420
421	// Check params
422	if( PyList_Check(pars)==1) {
423
424	// Length of list should be 2 for I(qx, qy))
425	npars = PyList_GET_SIZE(pars);
426	if(npars!=2) {
427	PyErr_SetString(CFractalModelError,
428	"CFractalModel.run expects a double or a list of dimension 2.");
429	return NULL;
430	}
431	// We have a vector q, get the qx and qy values at which
432	// to evaluate I(qx,qy)
433	qx_value = CFractalModel_readDouble(PyList_GET_ITEM(pars,0));
434	qy_value = CFractalModel_readDouble(PyList_GET_ITEM(pars,1));
435	return Py_BuildValue("d",(*(self->model))(qx_value,qy_value));
436
437	} else {
438
439	// We have a scalar q, we will evaluate I(q)
440	qx_value = CFractalModel_readDouble(pars);
441
442	return Py_BuildValue("d",(*(self->model))(qx_value));
443	}
444	}
445
446	static PyObject * reset(CFractalModel self, PyObject args) {
447
448
449	return Py_BuildValue("d",0.0);
450	}
451
452	static PyObject * set_dispersion(CFractalModel self, PyObject args) {
453	PyObject * disp;
454	const char * par_name;
455
456	if ( !PyArg_ParseTuple(args,"sO", &par_name, &disp) ) {
457	PyErr_SetString(CFractalModelError,
458	"CFractalModel.set_dispersion expects a DispersionModel object.");
459	return NULL;
460	}
461	void *temp = PyCObject_AsVoidPtr(disp);
462	DispersionModel * dispersion = static_cast<DispersionModel *>(temp);
463
464
465	// Ugliness necessary to go from python to C
466	// TODO: refactor this
467	if (!strcmp(par_name, "radius")) {
468	self->model->radius.dispersion = dispersion;
469	} else {
470	PyErr_SetString(CFractalModelError,
471	"CFractalModel.set_dispersion expects a valid parameter name.");
472	return NULL;
473	}
474
475	DispersionVisitor* visitor = new DispersionVisitor();
476	PyObject * disp_dict = PyDict_New();
477	dispersion->accept_as_source(visitor, dispersion, disp_dict);
478	PyDict_SetItemString(self->dispersion, par_name, disp_dict);
479	return Py_BuildValue("i",1);
480	}
481
482
483	static PyMethodDef CFractalModel_methods[] = {
484	{"run", (PyCFunction)run , METH_VARARGS,
485	"Evaluate the model at a given Q or Q, phi"},
486	{"runXY", (PyCFunction)runXY , METH_VARARGS,
487	"Evaluate the model at a given Q or Qx, Qy"},
488	{"calculate_ER", (PyCFunction)calculate_ER , METH_VARARGS,
489	"Evaluate the model at a given Q or Q, phi"},
490
491	{"evalDistribution", (PyCFunction)evalDistribution , METH_VARARGS,
492	"Evaluate the model at a given Q or Qx, Qy vector "},
493	{"reset", (PyCFunction)reset , METH_VARARGS,
494	"Reset pair correlation"},
495	{"set_dispersion", (PyCFunction)set_dispersion , METH_VARARGS,
496	"Set the dispersion model for a given parameter"},
497	{NULL}
498	};
499
500	static PyTypeObject CFractalModelType = {
501	PyObject_HEAD_INIT(NULL)
502	0, /ob_size/
503	"CFractalModel", /tp_name/
504	sizeof(CFractalModel), /tp_basicsize/
505	0, /tp_itemsize/
506	(destructor)CFractalModel_dealloc, /tp_dealloc/
507	0, /tp_print/
508	0, /tp_getattr/
509	0, /tp_setattr/
510	0, /tp_compare/
511	0, /tp_repr/
512	0, /tp_as_number/
513	0, /tp_as_sequence/
514	0, /tp_as_mapping/
515	0, /tp_hash /
516	0, /tp_call/
517	0, /tp_str/
518	0, /tp_getattro/
519	0, /tp_setattro/
520	0, /tp_as_buffer/
521	Py_TPFLAGS_DEFAULT \| Py_TPFLAGS_BASETYPE, /tp_flags/
522	"CFractalModel objects", /* tp_doc */
523	0, /* tp_traverse */
524	0, /* tp_clear */
525	0, /* tp_richcompare */
526	0, /* tp_weaklistoffset */
527	0, /* tp_iter */
528	0, /* tp_iternext */
529	CFractalModel_methods, /* tp_methods */
530	CFractalModel_members, /* tp_members */
531	0, /* tp_getset */
532	0, /* tp_base */
533	0, /* tp_dict */
534	0, /* tp_descr_get */
535	0, /* tp_descr_set */
536	0, /* tp_dictoffset */
537	(initproc)CFractalModel_init, /* tp_init */
538	0, /* tp_alloc */
539	CFractalModel_new, /* tp_new */
540	};
541
542
543	//static PyMethodDef module_methods[] = {
544	// {NULL}
545	//};
546
547	/**
548	* Function used to add the model class to a module
549	* @param module: module to add the class to
550	*/
551	void addCFractalModel(PyObject *module) {
552	PyObject *d;
553
554	if (PyType_Ready(&CFractalModelType) < 0)
555	return;
556
557	Py_INCREF(&CFractalModelType);
558	PyModule_AddObject(module, "CFractalModel", (PyObject *)&CFractalModelType);
559
560	d = PyModule_GetDict(module);
561	static char error_name[] = "CFractalModel.error";
562	CFractalModelError = PyErr_NewException(error_name, NULL, NULL);
563	PyDict_SetItemString(d, "CFractalModelError", CFractalModelError);
564	}
565

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source: sasview/sansmodels/src/sans/models/c_models/CFractalModel.cpp @ 2605da22

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