onion.c @ ef70686

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 ef70686 was 3be94e8, checked in by Mathieu Doucet <doucetm@…>, 13 years ago
Re #5 fixing problem with malloc
Property mode set to `100644`
File size: 8.1 KB

Rev	Line
[e096270]	1	/**
[0164899a]	2	* Scattering model for a onion
[e096270]	3	*/
	4
	5	#include <math.h>
	6	#include "onion.h"
	7	#include <stdio.h>
	8	#include <stdlib.h>
[0164899a]	9	// some details can be found in sld_cal.c
[e096270]	10	double so_kernel(double dp[], double q) {
[c25f1fa]	11	int n = dp[0];
[e096270]	12	double scale = dp[1];
[339ce67]	13	double rad_core0 = dp[2];
	14	double sld_core0 = dp[3];
[e096270]	15	double sld_solv = dp[4];
	16	double background = dp[5];
	17	int i,j;
[890ac7f1]	18	double bes,fun,alpha,f,vol,vol_pre,vol_sub,qr,r,contr,f2;
	19	double sign;
	20	double pi;
	21	double r0 = 0.0;
[e096270]	22
[c25f1fa]	23	double *sld_out;
	24	double *slope;
	25	double *sld_in;
	26	double *thick;
	27	double *A;
	28	int *fun_type;
[36cbbe74]	29
[3be94e8]	30	sld_out = (double)malloc((n+2)sizeof(double));
	31	slope = (double)malloc((n+2)sizeof(double));
	32	sld_in = (double)malloc((n+2)sizeof(double));
	33	thick = (double)malloc((n+2)sizeof(double));
	34	A = (double)malloc((n+2)sizeof(double));
	35	fun_type = (int)malloc((n+2)sizeof(int));
[36cbbe74]	36
[e096270]	37	for (i =1; i<=n; i++){
	38	sld_out[i] = dp[i+5];
	39	sld_in[i] = dp[i+15];
	40	A[i] = dp[i+25];
	41	thick[i] = dp[i+35];
	42	fun_type[i] = dp[i+45];
	43	}
[339ce67]	44	sld_out[0] = sld_core0;
[e096270]	45	sld_out[n+1] = sld_solv;
[339ce67]	46	sld_in[0] = sld_core0;
[e096270]	47	sld_in[n+1] = sld_solv;
[339ce67]	48	thick[0] = rad_core0;
[e096270]	49	thick[n+1] = 1e+10;
	50	A[0] = 0.0;
	51	A[n+1] = 0.0;
	52	fun_type[0] = 0;
	53	fun_type[n+1] = 0;
	54
	55
	56	pi = 4.0*atan(1.0);
	57	f = 0.0;
	58	r = 0.0;
[a1b2471]	59	vol = 0.0;
	60	vol_pre = 0.0;
	61	vol_sub = 0.0;
[e096270]	62
	63	for (i =0; i<= n+1; i++){
	64	if (thick[i] == 0.0){
	65	continue;
	66	}
	67	if (fun_type[i]== 0 ){
	68	slope[i] = 0.0;
	69	A[i] = 0.0;
	70	}
[a1b2471]	71	vol_pre = vol;
[e096270]	72	switch(fun_type[i]){
	73	case 2 :
	74	r0 = r;
	75	if (A[i] == 0.0){
	76	slope[i] = 0.0;
	77	}
	78	else{
[339ce67]	79	slope[i] = (sld_out[i]-sld_in[i])/(exp(A[i])-1.0);
[e096270]	80	}
	81	for (j=0; j<2; j++){
	82	if ( i == 0 && j == 0){
	83	continue;
	84	}
	85	if (i == n+1 && j == 1){
	86	continue;
	87	}
	88	if ( j == 1){
	89	sign = 1.0;
	90	r += thick[i];
	91	}
	92	else{
	93	sign = -1.0;
	94	}
	95	qr = q * r;
	96	alpha = A[i] * r/thick[i];
	97	fun = 0.0;
	98	if(qr == 0.0){
	99	fun = sign * 1.0;
	100	bes = sign * 1.0;
	101	}
	102	else{
	103	if (fabs(A[i]) > 0.0 ){
	104	fun = 3.0 * ((alphaalpha - qr qr) * sin(qr) - 2.0 * alpha * qr * cos(qr))/ ((alpha * alpha + qr * qr) * (alpha * alpha + qr * qr) * qr);
	105	fun = fun - 3.0 * (alpha * sin(qr) - qr * cos(qr)) / ((alpha * alpha + qr * qr) * qr);
	106	fun = - sign *fun;
	107	bes = sign * 3.0 * (sin(qr) - qr * cos(qr)) / (qr * qr * qr);
	108	}
	109	else {
	110	fun = sign * 3.0 * (sin(qr) - qr * cos(qr)) / (qr * qr * qr);
	111	bes = sign * 3.0 * (sin(qr) - qr * cos(qr)) / (qr * qr * qr);
	112	}
	113	}
	114	contr = slope[i]exp(A[i](r-r0)/thick[i]);
	115
	116	vol = 4.0 * pi / 3.0 * r * r * r;
[0164899a]	117	//if (j == 1 && fabs(sld_in[i]-sld_solv) < 1e-04*fabs(sld_solv) && A[i]==0.0){
	118	// vol_sub += (vol_pre - vol);
	119	//}
[e096270]	120	f += vol * (contr * (fun) + (sld_in[i]-slope[i]) * bes);
	121	}
	122	break;
	123	default :
	124	if (fun_type[i]==0){
	125	slope[i] = 0.0;
	126	}
	127	else{
	128	slope[i]= (sld_out[i] -sld_in[i])/thick[i];
	129	}
	130	contr = sld_in[i]-slope[i]*r;
	131	for (j=0; j<2; j++){
	132	if ( i == 0 && j == 0){
	133	continue;
	134	}
	135	if (i == n+1 && j == 1){
	136	continue;
	137	}
	138	if ( j == 1){
	139	sign = 1.0;
	140	r += thick[i];
	141	}
	142	else{
	143	sign = -1.0;
	144	}
	145
	146	qr = q * r;
	147	fun = 0.0;
	148	if(qr == 0.0){
	149	bes = sign * 1.0;
	150	}
	151	else{
	152	bes = sign * 3.0 * (sin(qr) - qr * cos(qr)) / (qr * qr * qr);
	153	if (fabs(slope[i]) > 0.0 ){
	154	fun = sign * 3.0 * r * (2.0qrsin(qr)-((qrqr)-2.0)cos(qr))/(qr * qr * qr * qr);
	155	}
	156	}
	157	vol = 4.0 * pi / 3.0 * r * r * r;
[0164899a]	158	//if (j == 1 && fabs(sld_in[i]-sld_solv) < 1e-04*fabs(sld_solv) && fun_type[i]==0){
	159	// vol_sub += (vol_pre - vol);
	160	//}
[e096270]	161	f += vol * (bes * contr + fun * slope[i]);
	162	}
	163	break;
	164	}
	165
	166	}
[0164899a]	167	//vol += vol_sub;
[e096270]	168	f2 = f * f / vol * 1.0e8;
	169	f2 *= scale;
	170	f2 += background;
[c25f1fa]	171
	172	free(sld_out);
	173	free(slope);
	174	free(sld_in);
	175	free(thick);
	176	free(A);
	177	free(fun_type);
	178
[e096270]	179	return (f2);
	180	}
	181	/**
	182	* Function to evaluate 1D scattering function
	183	* @param pars: parameters of the sphere
	184	* @param q: q-value
	185	* @return: function value
	186	*/
	187	double onion_analytical_1D(OnionParameters *pars, double q) {
	188	double dp[56];
	189
	190	dp[0] = pars->n_shells;
	191	dp[1] = pars->scale;
[339ce67]	192	dp[2] = pars->rad_core0;
	193	dp[3] = pars->sld_core0;
[e096270]	194	dp[4] = pars->sld_solv;
	195	dp[5] = pars->background;
	196
	197	dp[6] = pars->sld_out_shell1;
	198	dp[7] = pars->sld_out_shell2;
	199	dp[8] = pars->sld_out_shell3;
	200	dp[9] = pars->sld_out_shell4;
	201	dp[10] = pars->sld_out_shell5;
	202	dp[11] = pars->sld_out_shell6;
	203	dp[12] = pars->sld_out_shell7;
	204	dp[13] = pars->sld_out_shell8;
	205	dp[14] = pars->sld_out_shell9;
	206	dp[15] = pars->sld_out_shell10;
	207
	208	dp[16] = pars->sld_in_shell1;
	209	dp[17] = pars->sld_in_shell2;
	210	dp[18] = pars->sld_in_shell3;
	211	dp[19] = pars->sld_in_shell4;
	212	dp[20] = pars->sld_in_shell5;
	213	dp[21] = pars->sld_in_shell6;
	214	dp[22] = pars->sld_in_shell7;
	215	dp[23] = pars->sld_in_shell8;
	216	dp[24] = pars->sld_in_shell9;
	217	dp[25] = pars->sld_in_shell10;
	218
	219	dp[26] = pars->A_shell1;
	220	dp[27] = pars->A_shell2;
	221	dp[28] = pars->A_shell3;
	222	dp[29] = pars->A_shell4;
	223	dp[30] = pars->A_shell5;
	224	dp[31] = pars->A_shell6;
	225	dp[32] = pars->A_shell7;
	226	dp[33] = pars->A_shell8;
	227	dp[34] = pars->A_shell9;
	228	dp[35] = pars->A_shell10;
	229
	230	dp[36] = pars->thick_shell1;
	231	dp[37] = pars->thick_shell2;
	232	dp[38] = pars->thick_shell3;
	233	dp[39] = pars->thick_shell4;
	234	dp[40] = pars->thick_shell5;
	235	dp[41] = pars->thick_shell6;
	236	dp[42] = pars->thick_shell7;
	237	dp[43] = pars->thick_shell8;
	238	dp[44] = pars->thick_shell9;
	239	dp[45] = pars->thick_shell10;
	240
	241	dp[46] = pars->func_shell1;
	242	dp[47] = pars->func_shell2;
	243	dp[48] = pars->func_shell3;
	244	dp[49] = pars->func_shell4;
	245	dp[50] = pars->func_shell5;
	246	dp[51] = pars->func_shell6;
	247	dp[52] = pars->func_shell7;
	248	dp[53] = pars->func_shell8;
	249	dp[54] = pars->func_shell9;
	250	dp[55] = pars->func_shell10;
	251
	252	return so_kernel(dp, q);
	253	}
	254
	255	/**
	256	* Function to evaluate 2D scattering function
	257	* @param pars: parameters of the sphere
	258	* @param q: q-value
	259	* @return: function value
	260	*/
	261	double onion_analytical_2D(OnionParameters *pars, double q, double phi) {
	262	return onion_analytical_1D(pars,q);
	263	}
	264
	265	double onion_analytical_2DXY(OnionParameters *pars, double qx, double qy){
	266	return onion_analytical_1D(pars,sqrt(qxqx+qyqy));
	267	}

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source: sasview/sansmodels/src/sans/models/c_extensions/onion.c @ ef70686

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