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silly docs.
[CommonLispStat.git] / lib / functions.c
bloba6b42ecbabc16d6166c996357c7f54f12c8bef87
1 /* functions - callbacks for Bayes routines in XLISP-STAT and S */
2 /* XLISP-STAT 2.1 Copyright (c) 1990, by Luke Tierney */
3 /* Additions to Xlisp 2.1, Copyright (c) 1989 by David Michael Betz */
4 /* You may give out copies of this software; for conditions see the */
5 /* file COPYING included with this distribution. */
6
7 #include <stdio.h>
8 #include "xmath.h"
9
10 #define PRINTSTR(s) printf(s)
11
12 extern void *S_alloc(), *calloc(), *realloc();
13 extern double macheps();
14 char *minresultstring();
15
16 extern void choldecomp();
17
18 extern void minsupplyvalues(double , double *, double **,
19 double *, double **);
20 extern void minimize();
21 extern void minresults(double *, double *, double *, double *, double **,
22 double *, double **, int *, int *, double *);
23 extern void minsetup(int n, int k,
24 int *ffun(), int *gfun(),
25 double *x, double typf, double *typx, char *work);
26 /* int (*ffun)(), (*gfun)();*/
27 extern void minsetoptions(double , double, double, int , int , int , int);
28
29 extern void choldecomp();
30
31
32
33 /* next 2 from cbayes.c */
34 extern void Recover(char *, char *);
35 extern void call_S(char *fun, long narg, char **args, char **mode, long *length,char **names,
36 long nvals, char **values);
37
38 /* next 2 from derivatives.c */
39 /*
40 extern void numergrad(int n, double *x, double *grad, double *fsum,
41 int *ffun(), double h, double *typx);
42 extern void numerhess(int n, double *x, double **hess, double f,
43 double *fsum, void ffun(),
44 double h, double *typx);
45 */
46 extern void numergrad(int , double *, double *, double *,
47 int ffun(double *, double *, double *, double **),
48 double , double *);
49 extern void numerhess(int , double *, double **, double ,
50 double *,
51 int ffun(double *, double *, double *, double **),
52 double , double *);
53
54 /* next from minimize */
55 extern int minworkspacesize(int, int);
56
57 /************************************************************************/
58 /** **/
59 /** Definitions and Globals **/
60 /** **/
61 /************************************************************************/
62
63 /* #define NULL 0L already defined in stddef */
64
65 #define nil 0L
66 #define TRUE 1
67 #define FALSE 0
68
69 #define ROOT2PI 2.50662827463100050241
70 #define PI_INV .31830988618379067153
71
72 #define GRADTOL_POWER 1.0 / 3.0
73 #define H_POWER 1.0 / 6.0
74
75 /*typedef double **RMatrix, *RVector;*/
76
77 typedef struct{
78 char *f, **sf, **g;
79 int n, k;
80 int change_sign, fderivs;
81 int *gderivs;
82 double typf, h, dflt;
83 double *typx, *fsum, *cvals, *ctarget;
84 double **gfsum;
85 } Fundata;
86
87 static Fundata func, gfuncs, cfuncs;
88
89 /************************************************************************/
90 /** **/
91 /** Memory Utilities **/
92 /** **/
93 /************************************************************************/
94
95 /* this function is used to maintain a statically allocated piece of */
96 /* memory of a specified size. If a larger piece is needed the pointer */
97 /* is realloced. This allows functions using memory allocation to be */
98 /* called repeatedly (but not recursively) from within the same call */
99 /* from S. It attempts to avoid the danger of dangling callocs. */
100
101 void static
102 makespace(pptr, size)
103 char **pptr;
104 int size;
105 {
106 if (size <= 0) return;
107 if (*pptr == nil) *pptr = calloc(size, 1);
108 else *pptr = realloc(*pptr, size);
109 if (size > 0 && *pptr == nil) Recover("memory allocation failed", NULL);
110 }
111
112 /************************************************************************/
113 /** **/
114 /** Functions Evaluation Routines **/
115 /** **/
116 /************************************************************************/
117
118 /*
119 * All Hessian evaluations by numerical derivatives assume the gradient is
120 * evaluated first at the same location. The results are cached away.
121 */
122
123 /* install log posterior function */
124 static void
125 install_func(char *f, char **sf, int n, int change_sign, /*?? */
126 double typf, double h, double *typx, double dflt)
127 {
128 int i;
129 static int inited = FALSE;
130
131 if (! inited) {
132 func.typx = nil;
133 func.fsum = nil;
134 inited = TRUE;
135 }
136 makespace(&func.typx, n * sizeof(double));
137 makespace(&func.fsum, n * sizeof(double));
138
139 func.f = f;
140 func.sf = sf;
141 func.n = n;
142 func.change_sign = change_sign;
143 func.typf = (typf > 0.0) ? typf : 1.0;
144 func.h = (h > 0.0) ? h : pow(macheps(), H_POWER);
145 for (i = 0; i < n; i++)
146 func.typx[i] = (typx != nil && typx[i] > 0.0) ? typx[i] : 1.0;
147 func.dflt = dflt;
148 func.fderivs = 0;
149 }
150
151 /* install tilt functions */
152 static void
153 install_gfuncs(char **g, int n, int k, int change_sign, double h, double *typx)
154 {
155 int i;
156 static int inited = FALSE;
157 static double *gfsumdata = nil;
158
159 if (! inited) {
160 gfuncs.typx = nil;
161 gfuncs.gfsum = nil;
162 gfuncs.gderivs = nil;
163 inited = TRUE;
164 }
165 makespace(&gfuncs.typx, n * sizeof(double));
166 makespace(&gfuncs.gfsum, k * sizeof(double *));
167 makespace(&gfsumdata, k * n * sizeof(double));
168 makespace(&gfuncs.gderivs, k *sizeof(int));
169
170 gfuncs.g = g;
171 gfuncs.n = n;
172 gfuncs.k = k;
173 gfuncs.change_sign = change_sign;
174 gfuncs.h = (h > 0.0) ? h : pow(macheps(), H_POWER);
175 for (i = 0; i < n; i++)
176 gfuncs.typx[i] = (typx != nil && typx[i] > 0.0) ? typx[i] : 1.0;
177 for (i = 0; i < k; i++) gfuncs.gfsum[i] = gfsumdata + i * n;
178 return;
179 }
180
181 /* install constraint functions */
182 static void
183 install_cfuncs(char **g, int n, int k, double *ctarget, double h, double *typx)
184 {
185 int i;
186 static int inited = FALSE;
187
188 if (! inited) {
189 cfuncs.typx = nil;
190 cfuncs.fsum = nil;
191 cfuncs.gderivs = nil;
192 inited = TRUE;
193 }
194 makespace(&cfuncs.typx, n * sizeof(double));
195 makespace(&cfuncs.fsum, n * sizeof(double));
196 makespace(&cfuncs.gderivs, k * sizeof(int));
197
198 cfuncs.g = g;
199 cfuncs.n = n;
200 cfuncs.k = k;
201 cfuncs.h = (h > 0.0) ? h : pow(macheps(), H_POWER);
202 for (i = 0; i < n; i++)
203 cfuncs.typx[i] = (typx != nil && typx[i] > 0.0) ? typx[i] : 1.0;
204 cfuncs.ctarget = ctarget;
205 return;
206 }
207
208 static int
209 in_support(char **ff, int n, double *x)
210 {
211 char *args[1], *values[1];
212 int *result;
213 char *mode[1];
214 long length[1];
215
216 if (ff == nil || ff[0] == nil) {
217 return(TRUE);
218 } else {
219 mode[0] = "double";
220 length[0] =n;
221 args[0] = (char *) x;
222 call_S(ff[0], 1L, args, mode, length, 0L, 1L, values);
223 result = (int *) values[0];
224 return(result[0]);
225 }
226 }
227
228 /* callback for logposterior evaluation */
229 static int
230 evalfunc(double *x, double *pval, double *grad, double **hess)
231 {
232 char *args[1], *values[3];
233 double *result, val;
234 char *mode[1];
235 long length[1];
236 int i, j;
237
238 for (i = 0; i < 3; i++) values[i] = nil;
239
240 if (in_support(func.sf, func.n, x)) {
241 if (pval != nil || func.fderivs > 0 || hess != nil) {
242 mode[0] = "double";
243 length[0] = func.n;
244 args[0] = (char *) x;
245 call_S(func.f, 1L, args, mode, length, 0L, 3L, values);
246 result = (double *) values[0];
247 val = (! func.change_sign) ? result[0] : -result[0];
248 if (pval != nil) *pval = val;
249 if (values[2] != nil) func.fderivs = 2;
250 else if (values[1] != nil) func.fderivs = 1;
251 else func.fderivs = 0;
252 }
253 if (grad != nil) {
254 if (func.fderivs > 0) {
255 result = (double *) values[1];
256 for (i = 0; i < func.n; i++)
257 grad[i] = (! func.change_sign) ? result[i] : -result[i];
258 }
259 else {
260 numergrad(func.n, x, grad, func.fsum, evalfunc, func.h, func.typx);
261 }
262 }
263 if (hess != nil) {
264 if (func.fderivs == 2) {
265 result = (double *) values[2];
266 for (i = 0; i < func.n; i++)
267 for (j = 0; j < func.n; j++)
268 hess[i][j] = (! func.change_sign) ? result[i + j * func.n]
269 : -result[i + j * func.n];
270 }
271 else {
272 if (func.fderivs == 1) /* kludge to get fsum for analytic gradients */
273 numergrad(func.n, x, func.fsum, func.fsum,
274 evalfunc, func.h, func.typx);
275 numerhess(func.n, x, hess, val, func.fsum, evalfunc, func.h, func.typx);
276 }
277 }
278 return(TRUE);
279 } else {
280 if (pval != nil) {
281 *pval = func.dflt;
282 }
283 return(FALSE);
284 }
285 return(TRUE);
286 }
287
288
289 /* callback for tilt function evaluation */
290 static int which_gfunc;
291
292 static int
293 evalgfunc(double *x, double *pval, double *grad, double **hess)
294 {
295 char *args[1], *values[3];
296 double *result, val;
297 char *mode[1];
298 long length[1];
299 int i, j;
300
301 for (i = 0; i < 3; i++) values[i] = nil;
302
303 if (pval != nil || gfuncs.gderivs[which_gfunc] > 0 || hess != nil) {
304 mode[0] = "double";
305 length[0] = gfuncs.n;
306 args[0] = (char *) x;
307 call_S(gfuncs.g[which_gfunc], 1L, args, mode, length, 0L, 3L, values);
308 result = (double *) values[0];
309 val = result[0];
310 if (pval != nil) *pval = result[0];
311 if (values[2] != nil) gfuncs.gderivs[which_gfunc] = 2;
312 else if (values[1] != nil) gfuncs.gderivs[which_gfunc] = 1;
313 else gfuncs.gderivs[which_gfunc] = 0;
314 }
315 if (grad != nil) {
316 if (gfuncs.gderivs[which_gfunc] > 0) {
317 result = (double *) values[1];
318 for (i = 0; i < gfuncs.n; i++) grad[i] = result[i];
319 }
320 else {
321 numergrad(gfuncs.n, x, grad, gfuncs.gfsum[which_gfunc], evalgfunc,
322 gfuncs.h, gfuncs.typx);
323 }
324 }
325 if (hess != nil) {
326 if (gfuncs.gderivs[which_gfunc] == 2) {
327 result = (double *) values[2];
328 for (i = 0; i < gfuncs.n; i++)
329 for (j = 0; j < gfuncs.n; j++)
330 hess[i][j] = result[i + j * gfuncs.n];
331 }
332 else {
333 /* kludge to get fsum if analytic gradient used */
334 if (gfuncs.gderivs[which_gfunc] == 1)
335 numergrad(gfuncs.n, x, gfuncs.gfsum[which_gfunc],
336 gfuncs.gfsum[which_gfunc], evalgfunc, gfuncs.h, gfuncs.typx);
337 numerhess(gfuncs.n, x, hess, val, gfuncs.gfsum[which_gfunc], evalgfunc,
338 gfuncs.h, gfuncs.typx);
339 }
340 }
341 return(TRUE);
342 }
343
344 /* callback for constraint function evaluation */
345 static int which_cfunc;
346
347 static int
348 evalcfunc(double *x, double *pval, double *grad, double **hess)
349 {
350 char *args[1], *values[3];
351 double *result, val;
352 char *mode[1];
353 long length[1];
354 int i, j;
355
356 if (pval != nil || cfuncs.gderivs[which_cfunc] > 0 || hess != nil) {
357 mode[0] = "double";
358 length[0] = cfuncs.n;
359 args[0] = (char *) x;
360 call_S(cfuncs.g[which_cfunc], 1L, args, mode, length, 0L, 3L, values);
361 result = (double *) values[0];
362 val = result[0];
363 if (pval != nil) {
364 *pval = result[0];
365 if (cfuncs.ctarget != nil) *pval -= cfuncs.ctarget[which_cfunc];
366 }
367 if (values[2] != nil) cfuncs.gderivs[which_cfunc] = 2;
368 else if (values[1] != nil) cfuncs.gderivs[which_cfunc] = 1;
369 else cfuncs.gderivs[which_cfunc] = 0;
370 }
371 if (grad != nil) {
372 if (cfuncs.gderivs[which_cfunc] > 0) {
373 result = (double *) values[1];
374 for (i = 0; i <cfuncs.n; i++) grad[i] = result[i];
375 }
376 else {
377 numergrad(cfuncs.n, x, grad, cfuncs.fsum, evalcfunc,
378 cfuncs.h, cfuncs.typx);
379 }
380 }
381 if (hess != nil) {
382 if (cfuncs.gderivs[which_cfunc] == 2) {
383 result = (double *) values[2];
384 for (i = 0; i <cfuncs.n; i++)
385 for (j = 0; j <cfuncs.n; j++)
386 hess[i][j] = result[i + j * cfuncs.n];
387 }
388 else {
389 /* kludge to get fsum if analytic gradient used */
390 if (cfuncs.gderivs[which_cfunc] == 1)
391 numergrad(cfuncs.n, x, cfuncs.fsum, cfuncs.fsum, evalcfunc,
392 cfuncs.h, cfuncs.typx);
393 numerhess(cfuncs.n, x, hess, val, cfuncs.fsum, evalcfunc,
394 cfuncs.h, cfuncs.typx);
395 }
396 }
397 return(TRUE);
398 }
399
400 /* S front end for logposterior evaluation */
401 void
402 evalfront(char **ff, int *n, double *x, double *val, double *grad,
403 double *phess, double *h, double *typx)
404 {
405 int i;
406 static double **hess = nil;
407
408 install_func(ff[0], nil, *n, FALSE, 1.0, *h, typx, 0.0);
409 if (phess == nil) hess = nil;
410 else {
411 makespace(&hess, *n * sizeof(double *));
412 for (i = 0; i < *n; i++, phess += *n) hess[i] = phess;
413 }
414 evalfunc(x, val, grad, hess);
415 }
416
417 /* S front end for tilt function evaluation */
418 void
419 gevalfront(char **gg, int *n, int *m, double *x, double *h,
420 double *typx, double *val, double *grad)
421 {
422 int i;
423
424 install_gfuncs(gg, *n, *m, FALSE, *h, typx);
425 for (i = 0; i < *m; i++, val++) {
426 which_gfunc = i;
427 evalgfunc(x, val, grad, nil);
428 if (grad != nil) grad += *n;
429 }
430 return;
431 }
432
433 /************************************************************************/
434 /** **/
435 /** Derivative Scaling Routines **/
436 /** **/
437 /************************************************************************/
438
439 /*
440 void
441 derivscalefront(char **ff, int *n, double *x, double *h, double *typx, double *tol, int *info)
442 {
443 int i;
444
445 if (*tol <= 0.0) *tol = pow(macheps(), GRADTOL_POWER);
446
447 install_func(ff[0], nil, *n, TRUE, 1.0, *h, typx, 0.0);
448 *info = check_derivs(x, *tol);
449
450 *h = func.h;
451 for (i = 0; i < *n; i++) typx[i] = func.typx[i];
452 return;
453 }
454
455
456 static int
457 check_derivs(double *x, double drvtol)
458 {
459 static double *grad = nil, work = nil;
460 static double **hess = nil;
461 int i, error;
462
463 grad = (double *) S_alloc(func.n, sizeof(double));
464 hess = (double **) S_alloc(func.n, sizeof(double *));
465 work = (double *) S_alloc(func.n + func.n * func.n, sizeof(double));
466
467 for (i = 0; i < func.n; i++) {
468 hess[i] = work;
469 work += func.n;
470 }
471
472 error = derivscale(func.n, x, grad, hess, func.fsum, evalfunc,
473 &func.h, func.typx, drvtol, work);
474 return(error);
475 }
476 */
477
478 /************************************************************************/
479 /** **/
480 /** Importance Sampling Routines **/
481 /** **/
482 /************************************************************************/
483
484 /* joint density of normal-cauchy mixture */
485 static double
486 dncmix(double *x, int n, double p)
487 {
488 int i;
489 double dens;
490
491 for (i = 0, dens = 1.0; i < n; i++) {
492 dens *= p * exp(-0.5 * x[i] * x[i]) / ROOT2PI
493 + (1 - p) * PI_INV / (1.0 + x[i] * x[i]);
494 }
495 return(dens);
496 }
497
498 /*
499 * S front end for computing sample from transformed normal-cauchy
500 * mixture and importance sampling weights
501 */
502 void
503 samplefront(char **ff, char **sf, char **rf,
504 double *p, int *n,
505 double *x, double *ch, int *N, double *y, double *w)
506 {
507 double val;
508 int i, j, k;
509 char *args[2], *values[1];
510 double *result, mval, c, dens, m;
511 char *mode[2];
512 long length[2];
513
514 /* get the random variables */
515 mode[0] = "double"; mode[1] = "double";
516 length[0] = 1; length[1] = 1;
517 m = *N * *n; args[0] = (char *) &m; args[1] = (char *) p;
518 call_S(rf[0], 2L, args, mode, length, 0L, 1L, values);
519 result = (double *) values[0];
520 for (i = 0; i < m; i++) y[i] = result[i];
521
522 /* construct the sample and the weights */
523 install_func(ff[0], sf, *n, FALSE, 1.0, -1.0, nil, 0.0);
524 c = 1.0 / pow(ROOT2PI, (double) *n);
525 evalfunc(x, &mval, nil, nil);
526 for (i = 0; i < *N; i++, y += *n) {
527 dens = dncmix(y, *n, *p);
528 for (j = 0; j < *n; j++) {
529 val = x[j];
530 for (k = j; k < *n; k++) val += y[k] * ch[j + *n * k];
531 y[j] = val;
532 }
533 if (evalfunc(y, &val, nil, nil)) w[i] = exp(val - mval) * c / dens;
534 else w[i] = 0.0;
535 }
536 return;
537 }
538
539
540 /************************************************************************/
541 /** **/
542 /** Maximization Routines **/
543 /** **/
544 /************************************************************************/
545
546 typedef struct {
547 int n, m, k, itnlimit, backtrack, verbose, vals_suppl, exptilt;
548 int count, termcode;
549 } MaxIPars;
550
551 typedef struct {
552 double typf, h, gradtol, steptol, maxstep, dflt, tilt, newtilt, hessadd;
553 } MaxDPars;
554
555 struct {
556 double tilt;
557 double *gval;
558 double **ggrad, **ghess;
559 int exptilt;
560 double *tscale;
561 } tiltinfo;
562
563 static void
564 add_tilt(double *x, double *pval, double *grad, double **hess,
565 double tilt, int exptilt)
566 {
567 int i, j, k, n = func.n, m = gfuncs.k;
568 double *gval, *ggrad, **ghess, etilt;
569
570 if (m == 0) return;
571
572 if (gfuncs.change_sign) tilt = -tilt;
573
574 for (k = 0; k < m; k++) {
575 gval = (pval != nil) ? tiltinfo.gval + k : nil;
576 ggrad = (grad != nil) ? tiltinfo.ggrad[k] : nil;
577 ghess = (hess != nil) ? tiltinfo.ghess : nil;
578
579 which_gfunc = k;
580 evalgfunc(x, gval, ggrad, ghess);
581
582 if (exptilt) {
583 etilt = (tiltinfo.tscale != nil) ? tilt / tiltinfo.tscale[k] : tilt;
584 if (pval != nil) *pval += etilt * *gval;
585 if (grad != nil)
586 for (i = 0; i < n; i++) grad[i] += etilt * ggrad[i];
587 if (hess != nil)
588 for (i = 0; i < n; i++)
589 for (j = 0; j < n; j++) hess[i][j] += etilt * ghess[i][j];
590 }
591 else {
592 gval = tiltinfo.gval;
593 ggrad = tiltinfo.ggrad[k];
594 ghess = tiltinfo.ghess;
595 if (gval[k] <= 0.0) Recover("nonpositive function value", NULL);
596 if (pval != nil) *pval += tilt * log(gval[k]);
597 if (grad != nil)
598 for (i = 0; i < n; i++) grad[i] += tilt * ggrad[i] / gval[k];
599 if (hess != nil)
600 for (i = 0; i < n; i++)
601 for (j = 0; j < n; j++)
602 hess[i][j] +=
603 tilt * (ghess[i][j] / gval[k]
604 - (ggrad[i] / gval[k]) * (ggrad[j] / gval[k]));
605 }
606 }
607 }
608
609 static void
610 set_tilt_info(int n, int m,
611 double tilt, int exptilt, double *tscale)
612 {
613 static double *hessdata = nil, *graddata = nil;
614 int i;
615 static int inited = FALSE;
616
617 if (! inited) {
618 tiltinfo.gval = nil;
619 tiltinfo.ggrad = nil;
620 tiltinfo.ghess = nil;
621 inited = TRUE;
622 }
623 makespace(&tiltinfo.gval, n * sizeof(double));
624 makespace(&tiltinfo.ggrad, m * sizeof(double *));
625 makespace(&tiltinfo.ghess, n * sizeof(double *));
626 makespace(&graddata, n * m * sizeof(double));
627 makespace(&hessdata, n * n * sizeof(double));
628
629 tiltinfo.tilt = tilt;
630 tiltinfo.exptilt = exptilt;
631 for (i = 0; i < m; i++) tiltinfo.ggrad[i] = graddata + i * n;
632 for (i = 0; i < n; i++) tiltinfo.ghess[i] = hessdata + i * n;
633 tiltinfo.tscale = tscale;
634 }
635
636
637 static void
638 minfunc(double *x, double *pval, double *grad, double **hess)
639 {
640 int k = gfuncs.k;
641
642 if (evalfunc(x, pval, grad, hess) && (k > 0))
643 add_tilt(x, pval, grad, hess, tiltinfo.tilt, tiltinfo.exptilt);
644 }
645
646 void
647 constfunc(double *x, double *vals, double **jac, double **hess)
648 {
649 int i, k = cfuncs.k;
650 double *pvali, *jaci;
651
652 for (i = 0; i < k; i++) {
653 pvali = (vals != nil) ? vals + i : nil;
654 jaci = (jac != nil) ? jac[i] : nil;
655 which_cfunc = i;
656 evalcfunc(x, pvali, jaci, nil);
657 }
658 }
659
660 void
661 maxfront(char **ff, char **gf, char **cf,
662 double *x, double *typx, double *fvals, double *gvals, double *cvals, double *ctarget,
663 MaxIPars *ipars, MaxDPars *dpars,
664 double *tscale, char **msg)
665 {
666 static char *work = nil;
667 static double **H = nil, **cJ = nil;
668 double *pf, *grad, *c;
669 int i, n, m, k;
670 void (*cfun)();
671
672 if (ipars->verbose > 0) PRINTSTR("maximizing...\n");
673
674 n = ipars->n;
675 m = ipars->m;
676 k = ipars->k;
677 if (k >= n) Recover("too many constraints", NULL);
678
679 makespace(&H, n * sizeof(double *));
680 makespace(&work, minworkspacesize(n, k));
681
682 pf = fvals; fvals++;
683 grad = fvals; fvals += n;
684 for (i = 0; i < n; i++, fvals += n) H[i] = fvals;
685 set_tilt_info(n, m, dpars->newtilt, ipars->exptilt, tscale);
686
687 if (k == 0) {
688 c = nil;
689 cJ = nil;
690 cfun = nil;
691 } else {
692 c = cvals;
693 cvals += k;
694 makespace(&cJ, k * sizeof(double *));
695 for (i = 0; i < k; i++) cJ[i] = cvals + i * n;
696 cfun = &constfunc; /* AJR: pointer to constfunc? */
697 }
698
699 install_func(ff[0], nil, n, TRUE, dpars->typf, dpars->h, typx, dpars->dflt);
700 install_gfuncs(gf, n, m, TRUE, dpars->h, typx);
701 install_cfuncs(cf, n, k, ctarget, dpars->h, typx);
702
703 minsetup(n, k, &minfunc, &cfun, x, dpars->typf, typx, work); /* AJR: FIXME arg 3,4 */
704 minsetoptions(dpars->gradtol, dpars->steptol, dpars->maxstep,
705 ipars->itnlimit, ipars->verbose, ipars->backtrack, TRUE);
706
707 if (ipars->vals_suppl) {
708 for (i = 0; i < k; i++) c[i] -= ctarget[i];
709 if (dpars->newtilt != dpars->tilt) {
710 add_tilt(x, pf, grad, H, dpars->newtilt - dpars->tilt, ipars->exptilt);
711 dpars->tilt = dpars->newtilt;
712 }
713 minsupplyvalues(*pf, grad, H, c, cJ);
714 }
715
716 minimize();
717 minresults(x, pf, nil, grad, H, c, cJ, &ipars->count, &ipars->termcode,
718 &dpars->hessadd);
719 msg[0] = minresultstring(ipars->termcode);
720
721 for (i = 0; i < k; i++) c[i] += ctarget[i];
722 ipars->vals_suppl = TRUE;
723 }
724
725 /************************************************************************/
726 /** **/
727 /** Log Laplace Approximation **/
728 /** **/
729 /************************************************************************/
730
731 void
732 loglapdet(double *fvals, double *cvals, MaxIPars *ipars, MaxDPars *dpars,
733 double *val, int *detonly)
734 {
735 int i, j, l, n = ipars->n, k = ipars->k;
736 double f = -fvals[0], *hessdata = fvals + n + 1, *cgraddata = cvals + k;
737 double ldL, ldcv, maxadd;
738 static double **hess = nil, **cgrad = nil;
739
740 if (k >= n) Recover("too many constraints", NULL);
741
742 makespace(&hess, n * sizeof(double *));
743 makespace(&cgrad, k * sizeof(double *));
744
745 for (i = 0; i < n; i++) hess[i] = hessdata + i * n;
746 for (i = 0; i < k; i++) cgrad[i] = cgraddata + i * n;
747
748 choldecomp(hess, n, 0.0, &maxadd);
749 /**** do something if not pos. definite ****/
750
751 for (i = 0, ldL = 0.0; i < n; i++) ldL += log(hess[i][i]);
752
753 if (k > 0) {
754 /* forward solve for (L^-1) cgrad^T */
755 for (l = 0; l < k; l++) {
756 for (i = 0; i < n; i++) {
757 if (hess[i][i] != 0.0) cgrad[l][i] /= hess[i][i];
758 for (j = i + 1; j < n; j++) cgrad[l][j] -= hess[j][i] * cgrad[l][i];
759 }
760 }
761
762 /* compute sigma and stdev */
763 for (i = 0; i < k; i++) {
764 for (j = i; j < k; j++) {
765 for (l = 0, hess[i][j] = 0.0; l < n; l++)
766 hess[i][j] += cgrad[i][l] * cgrad[j][l];
767 hess[j][i] = hess[i][j];
768 }
769 }
770
771 choldecomp(hess, k, 0.0, &maxadd);
772 /**** do something if not pos. definite ****/
773 for (i = 0, ldcv = 0.0; i < k; i++) ldcv += log(hess[i][i]);
774 }
775 else ldcv = 0.0;
776
777 *val = (n - k) * log(ROOT2PI) - ldL - ldcv;
778 if (! *detonly) *val += f;
779 }
780
781 #ifdef SBAYES
782
783 loglapfront(fvals, cvals, ipars, dpars, val)
784 double *fvals, *cvals;
785 MaxIPars *ipars;
786 MaxDPars *dpars;
787 double *val;
788 {
789 int detonly = FALSE;
790
791 loglapdet(fvals, cvals, ipars, dpars, val, &detonly);
792 }
793
794 /************************************************************************/
795 /** **/
796 /** First Order Moments **/
797 /** **/
798 /************************************************************************/
799
800 moms1front(gf, n, m, x, hessdata, mean, stdev, sigmadata, h, typx)
801 char *gf;
802 int *n, *m;
803 double *x, *hessdata, *mean, *stdev, *sigmadata, *h, *typx;
804 {
805 int i, j, k;
806 double *hess, *sigma, *delg;
807 double *delgdata, maxadd;
808
809 hess = (double **) S_alloc(*n, sizeof(double *));
810 sigma = (double **) S_alloc(*m, sizeof(double *));
811 delg = (double **) S_alloc(*m, sizeof(double *));
812 delgdata = (double *) S_alloc(*m * *n, sizeof(double));
813
814 for (i = 0; i < *n; i++) hess[i] = hessdata + i * *n;
815 for (i = 0; i < *m; i++) sigma[i] = sigmadata + i * *m;
816 for (i = 0; i < *m; i++) delg[i] = delgdata + i * *n;
817
818 gevalfront(gf, n, m, x, h, typx, mean, delgdata);
819
820 /* get the cholesky decomposition L of the hessian */
821 choldecomp(hess, *n, 0.0, &maxadd);
822
823 /* forward solve for (L^-1) delg^T */
824 for (k = 0; k < *m; k++) {
825 for (i = 0; i < *n; i++) {
826 if (hess[i][i] != 0.0) delg[k][i] /= hess[i][i];
827 for (j = i + 1; j < *n; j++) delg[k][j] -= hess[j][i] * delg[k][i];
828 }
829 }
830
831 /* compute sigma and stdev */
832 for (i = 0; i < *m; i++) {
833 for (j = i; j < *m; j++) {
834 for (k = 0, sigma[i][j] = 0.0; k < *n; k++)
835 sigma[i][j] += delg[i][k] * delg[j][k];
836 sigma[j][i] = sigma[i][j];
837 }
838 stdev[i] = sqrt(sigma[i][i]);
839 }
840 }
841
842 /************************************************************************/
843 /** **/
844 /** Second Order Moments **/
845 /** **/
846 /************************************************************************/
847
848 typedef struct {
849 MaxIPars max;
850 int full, covar;
851 } MomIPars;
852
853 typedef struct {
854 MaxDPars max;
855 double mgfdel;
856 } MomDPars;
857
858 moms2front(ff, gf, gnum, x, typx, fvals, gvals, ipars, dpars,
859 mean, stdev, sigmadata)
860 char **ff, **gf;
861 int *gnum;
862 double *x, *typx, *fvals, *gvals, *mean, *stdev, *sigmadata;
863 MomIPars *ipars;
864 MomDPars *dpars;
865 {
866 char *msg;
867 double h, loglap0, loglap1, loglap2;
868 double *tilts, *fvals1, *gvals1, *x1;
869 MomDPars dp1, *dpars1 = &dp1;
870 MomIPars ip1, *ipars1 = &ip1;
871 int i, n, m;
872
873 n = ipars->max.n;
874 m = *gnum;
875 h = dpars->max.h;
876
877 tilts = (double *) S_alloc(m, sizeof(double));
878 x1 = (double *) S_alloc(n, sizeof(double));
879 fvals1 = (double *) S_alloc(1 + n + n * n, sizeof(double));
880 gvals1 = (double *) S_alloc(m + n * m, sizeof(double));
881
882 maxfront(ff, nil, nil, x, typx, fvals, gvals, nil, nil,
883 ipars, dpars, nil, &msg);
884 copypars(x, fvals, gvals, ipars, dpars, x1, fvals1, gvals1, ipars1, dpars1);
885 loglapfront(fvals1, nil, ipars1, dpars1, &loglap0);
886 copypars(x, fvals, gvals, ipars, dpars, x1, fvals1, gvals1, ipars1, dpars1);
887 moms1front(gf, &n, &m, x1, fvals1 + n + 1, mean, stdev, sigmadata, &h, typx);
888
889 if (ipars->full) {
890 for (i = 0; i < m; i++) {
891 copypars(x, fvals, gvals, ipars, dpars,
892 x1, fvals1, gvals1, ipars1, dpars1);
893 ipars1->max.m = 1;
894 ipars1->max.exptilt = FALSE;
895 dpars1->max.newtilt = 1.0;
896 maxfront(ff, gf + i, nil, x1, typx, fvals1, gvals1, nil, nil,
897 ipars1, dpars1, nil, &msg);
898 loglapfront(fvals1, nil, ipars1, dpars1, &loglap1);
899 loglap1 -= loglap0;
900
901 copypars(x, fvals, gvals, ipars, dpars,
902 x1, fvals1, gvals1, ipars1, dpars1);
903 ipars1->max.m = 1;
904 ipars1->max.exptilt = FALSE;
905 dpars1->max.newtilt = 2.0;
906 maxfront(ff, gf + i, nil, x1, typx, fvals1, gvals1, nil, nil,
907 ipars1, dpars1, nil, &msg);
908 loglapfront(fvals1, nil, ipars1, dpars1, &loglap2);
909 loglap2 -= loglap0;
910
911 mean[i] = exp(loglap1);
912 stdev[i] = sqrt(exp(loglap2) - exp(2.0 * loglap1));
913 if (ipars->covar) sigmadata[i + i * m] = stdev[i] * stdev[i];
914 }
915 if (ipars->covar) {
916 char *cgf[2];
917 int j;
918
919 for (i = 0; i < m; i++) {
920 for (j = i + 1; j < m; j++) {
921 cgf[0] = gf[i];
922 cgf[1] = gf[j];
923 copypars(x, fvals, gvals, ipars, dpars,
924 x1, fvals1, gvals1, ipars1, dpars1);
925 ipars1->max.m = 2;
926 ipars1->max.exptilt = FALSE;
927 dpars1->max.newtilt = 1.0;
928 maxfront(ff, gf + i, nil, x1, typx, fvals1, gvals1, nil, nil,
929 ipars1, dpars1, nil, &msg);
930 loglapfront(fvals1, nil, ipars1, dpars1, &loglap1);
931 loglap1 -= loglap0;
932
933 sigmadata[i + j * m] = exp(loglap1) - mean[i] * mean[j];
934 sigmadata[j + i * m] = sigmadata[i + j * m];
935 }
936 }
937 }
938 }
939 else {
940 for (i = 0; i < m; i++)
941 tilts[i] = (stdev[i] > 0.0) ? dpars->mgfdel / stdev[i] : dpars->mgfdel;
942
943 for (i = 0; i < m; i++) {
944 copypars(x, fvals, gvals, ipars, dpars,
945 x1, fvals1, gvals1, ipars1, dpars1);
946 ipars1->max.m = 1;
947 ipars1->max.exptilt = TRUE;
948 dpars1->max.newtilt = tilts[i];
949 maxfront(ff, gf + i, nil, x1, typx, fvals1, gvals1, nil, nil,
950 ipars1, dpars1, nil, &msg);
951 loglapfront(fvals1, nil, ipars1, dpars1, &loglap1);
952 loglap1 -= loglap0;
953
954 copypars(x, fvals, gvals, ipars, dpars,
955 x1, fvals1, gvals1, ipars1, dpars1);
956 ipars1->max.m = 1;
957 ipars1->max.exptilt = TRUE;
958 dpars1->max.newtilt = -tilts[i];
959 maxfront(ff, gf + i, nil, x1, typx, fvals1, gvals1, nil, nil,
960 ipars1, dpars1, nil, &msg);
961 loglapfront(fvals1, nil, ipars1, dpars1, &loglap2);
962 loglap2 -= loglap0;
963
964 mean[i] = (loglap1 - loglap2) / (2.0 * tilts[i]);
965 stdev[i] = sqrt((loglap1 + loglap2) / (tilts[i] * tilts[i]));
966 if (ipars->covar) sigmadata[i + i * m] = stdev[i] * stdev[i];
967 }
968 if (ipars->covar) {
969 char *cgf[2];
970 double ctilt, tscale[2];
971 int j;
972
973 ctilt = dpars->mgfdel;
974 for (i = 0; i < m; i++) {
975 for (j = i + 1; j < m; j++) {
976 cgf[0] = gf[i];
977 cgf[1] = gf[j];
978 tscale[0] = stdev[i] > 0 ? stdev[i] : 1.0;
979 tscale[1] = stdev[j] > 0 ? stdev[j] : 1.0;
980
981 copypars(x, fvals, gvals, ipars, dpars,
982 x1, fvals1, gvals1, ipars1, dpars1);
983 ipars1->max.m = 2;
984 ipars1->max.exptilt = TRUE;
985 dpars1->max.newtilt = ctilt;
986 maxfront(ff, cgf, nil, x1, typx, fvals1, gvals1, nil, nil,
987 ipars1, dpars1, tscale, &msg);
988 loglapfront(fvals1, nil, ipars1, dpars1, &loglap1);
989 loglap1 -= loglap0;
990
991 copypars(x, fvals, gvals, ipars, dpars,
992 x1, fvals1, gvals1, ipars1, dpars1);
993 ipars1->max.m = 2;
994 ipars1->max.exptilt = TRUE;
995 dpars1->max.newtilt = -ctilt;
996 maxfront(ff, cgf, nil, x1, typx, fvals1, gvals1, nil, nil,
997 ipars1, dpars1, tscale, &msg);
998 loglapfront(fvals1, nil, ipars1, dpars1, &loglap2);
999 loglap2 -= loglap0;
1000
1001 sigmadata[i + j * m] = stdev[i] * stdev[j]
1002 * ((loglap2 + loglap1) /(2 * ctilt * ctilt) - 1.0);
1003 sigmadata[j + i * m] = sigmadata[i + j * m];
1004 }
1005 }
1006 }
1007 }
1008 }
1009
1010 static copypars(x, f, g, ip, dp, x1, f1, g1, ip1, dp1)
1011 double *x, *f, *g, *x1, *f1, *g1;
1012 MomIPars *ip, *ip1;
1013 MomDPars *dp, *dp1;
1014 {
1015 int i, n, m, nf, ng;
1016
1017 n = ip->max.n;
1018 m = ip->max.m;
1019 nf = 1 + n + n * n;
1020 ng = m + n * m;
1021
1022 for (i = 0; i < n; i++) x1[i] = x[i];
1023 for (i = 0; i < nf; i++) f1[i] = f[i];
1024 for (i = 0; i < ng; i++) g1[i] = g[i];
1025 *ip1 = *ip;
1026 *dp1 = *dp;
1027 }
1028
1029 /************************************************************************/
1030 /** **/
1031 /** Laplace Margins **/
1032 /** **/
1033 /************************************************************************/
1034
1035 lapmar1front(ff, gf, x, typx, fvals, ipars, dpars, xmar, ymar, nmar)
1036 char **ff, **gf;
1037 double *x, *typx, *fvals, *xmar, *ymar;
1038 MaxIPars *ipars;
1039 MaxDPars *dpars;
1040 int *nmar;
1041 {
1042 char *msg;
1043 int i, n, m, mindex;
1044 double h, loglap0, loglap1, xmode, stdev, sigmadata, ctarget[1];
1045 double *fvals1, *x1, *cvals, *cvals1, *fvals2, *x2, *cvals2;
1046 MaxDPars dp1, dp2, *dpars1 = &dp1, *dpars2 = &dp2;
1047 MaxIPars ip1, ip2, *ipars1 = &ip1, *ipars2 = &ip2;
1048
1049 n = ipars->n;
1050 m = 1;
1051 h = dpars->h;
1052
1053 x1 = (double *) S_alloc(n + 1, sizeof(double));
1054 fvals1 = (double *) S_alloc(1 + n + n * n, sizeof(double));
1055 cvals = (double *) S_alloc(m + n * m, sizeof(double));
1056 cvals1 = (double *) S_alloc(m + n * m, sizeof(double));
1057 x2 = (double *) S_alloc(n + 1, sizeof(double));
1058 fvals2 = (double *) S_alloc(1 + n + n * n, sizeof(double));
1059 cvals2 = (double *) S_alloc(m + n * m, sizeof(double));
1060
1061 maxfront(ff, nil, nil, x, typx, fvals, nil, nil, nil,
1062 ipars, dpars, nil, &msg);
1063 cpmarpars(x, fvals, cvals, ipars, dpars, x1, fvals1, cvals1, ipars1, dpars1);
1064 loglapfront(fvals1, nil, ipars1, dpars1, &loglap0);
1065 cpmarpars(x, fvals, cvals, ipars, dpars, x1, fvals1, cvals1, ipars1, dpars1);
1066 moms1front(gf, &n, &m, x1, fvals1 + n + 1, &xmode, &stdev, &sigmadata,
1067 &h, typx);
1068
1069 ipars->k = 1;
1070 ipars->vals_suppl = FALSE;
1071 ctarget[0] = xmode;
1072 maxfront(ff, nil, gf, x, typx, fvals, nil, cvals, ctarget,
1073 ipars, dpars, nil, &msg);
1074
1075 for (mindex = 0; mindex < *nmar && xmar[mindex] <= xmode; mindex++);
1076
1077 cpmarpars(x, fvals, cvals, ipars, dpars, x1, fvals1, cvals1, ipars1, dpars1);
1078 for (i = mindex; i >= 0; i--) {
1079 ctarget[0] = xmar[i];
1080 maxfront(ff, nil, gf, x1, typx, fvals1, nil, cvals1, ctarget,
1081 ipars1, dpars1, nil, &msg);
1082 cpmarpars(x1, fvals1, cvals1, ipars1, dpars1, x2,
1083 fvals2, cvals2, ipars2, dpars2);
1084 loglapfront(fvals2, cvals2, ipars2, dpars2, &loglap1);
1085 ymar[i] = exp(loglap1 - loglap0);
1086 }
1087 cpmarpars(x, fvals, cvals, ipars, dpars, x1, fvals1, cvals1, ipars1, dpars1);
1088 for (i = mindex + 1; i < *nmar; i++) {
1089 ctarget[0] = xmar[i];
1090 maxfront(ff, nil, gf, x1, typx, fvals1, nil, cvals1, ctarget,
1091 ipars1, dpars1, nil, &msg);
1092 cpmarpars(x1, fvals1, cvals1, ipars1, dpars1, x2,
1093 fvals2, cvals2, ipars2, dpars2);
1094 loglapfront(fvals2, cvals2, ipars2, dpars2, &loglap1);
1095 ymar[i] = exp(loglap1 - loglap0);
1096 }
1097 }
1098
1099 static cpmarpars(x, f, g, ip, dp, x1, f1, g1, ip1, dp1)
1100 double *x, *f, *g, *x1, *f1, *g1;
1101 MaxIPars *ip, *ip1;
1102 MaxDPars *dp, *dp1;
1103 {
1104 int i, n, k, nf, ng;
1105
1106 n = ip->n;
1107 k = ip->k;
1108 nf = 1 + n + n * n;
1109 ng = k + n * k;
1110
1111 for (i = 0; i < n; i++) x1[i] = x[i];
1112 for (i = 0; i < nf; i++) f1[i] = f[i];
1113 for (i = 0; i < ng; i++) g1[i] = g[i];
1114 *ip1 = *ip;
1115 *dp1 = *dp;
1116 }
1117 #endif /* SBAYES */
1118
1119 /*
1120 TODO
1121
1122 get hessian from gradiant for analytical gradiants
1123
1124 avoid repeated derivative calls in mimimize.
1125
1126 2d margins
1127
1128 use pos. definiteness info in margins
1129
1130 */
XLispStat port to CommonLisp