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exp_family.cpp @ 739

Revision 739, 13.2 kB (checked in by mido, 14 years ago)
the rest of h to cpp movements, with exception of from_setting and validate to avoid conflicts with Sarka
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Line
1	#include <math.h>
2
3	#include <itpp/base/bessel.h>
4	#include "exp_family.h"
5
6	namespace bdm {
7
8	Uniform_RNG UniRNG;
9	Normal_RNG NorRNG;
10	Gamma_RNG GamRNG;
11
12	using std::cout;
13
14	///////////
15
16	void BMEF::bayes ( const vec &yt, const vec &cond ) {
17	this->bayes_weighted ( yt, cond, 1.0 );
18	};
19
20	void egiw::set_parameters ( int dimx0, ldmat V0, double nu0 ) {
21	dimx = dimx0;
22	nPsi = V0.rows() - dimx;
23	dim = dimx * ( dimx + nPsi ); // size(R) + size(Theta)
24
25	V = V0;
26	if ( nu0 < 0 ) {
27	nu = 0.1 + nPsi + 2 * dimx + 2; // +2 assures finite expected value of R
28	// terms before that are sufficient for finite normalization
29	} else {
30	nu = nu0;
31	}
32	}
33
34	vec egiw::sample() const {
35	mat M;
36	chmat R;
37	sample_mat ( M, R );
38
39	return concat ( cvectorize ( M ), cvectorize ( R.to_mat() ) );
40	}
41
42	mat egiw::sample_mat ( int n ) const {
43	// TODO - correct approach - convert to product of norm * Wishart
44	mat M;
45	ldmat Vz;
46	ldmat Lam;
47	factorize ( M, Vz, Lam );
48
49	chmat ChLam ( Lam.to_mat() );
50	chmat iChLam;
51	ChLam.inv ( iChLam );
52
53	eWishartCh Omega; //inverse Wishart, result is R,
54	Omega.set_parameters ( iChLam, nu - 2nPsi - dimx ); // 2nPsi is there to match numercial simulations - check if analytically correct
55
56	mat OmChi;
57	mat Z ( M.rows(), M.cols() );
58
59	mat Mi;
60	mat RChiT;
61	mat tmp ( dimension(), n );
62	for ( int i = 0; i < n; i++ ) {
63	OmChi = Omega.sample_mat();
64	RChiT = inv ( OmChi );
65	Z = randn ( M.rows(), M.cols() );
66	Mi = M + RChiT * Z * inv ( Vz._L().T() * diag ( sqrt ( Vz._D() ) ) );
67
68	tmp.set_col ( i, concat ( cvectorize ( Mi ), cvectorize ( RChiT*RChiT.T() ) ) );
69	}
70	return tmp;
71	}
72
73	void egiw::sample_mat ( mat &Mi, chmat &Ri ) const {
74
75	// TODO - correct approach - convert to product of norm * Wishart
76	mat M;
77	ldmat Vz;
78	ldmat Lam;
79	factorize ( M, Vz, Lam );
80
81	chmat Ch;
82	Ch.setCh ( Lam._L() *diag ( sqrt ( Lam._D() ) ) );
83	chmat iCh;
84	Ch.inv ( iCh );
85
86	eWishartCh Omega; //inverse Wishart, result is R,
87	Omega.set_parameters ( iCh, nu - 2nPsi - dimx ); // 2nPsi is there to match numercial simulations - check if analytically correct
88
89	chmat Omi;
90	Omi.setCh ( Omega.sample_mat() );
91
92	mat Z = randn ( M.rows(), M.cols() );
93	Mi = M + Omi._Ch() * Z * inv ( Vz._L() * diag ( sqrt ( Vz._D() ) ) );
94	Omi.inv ( Ri );
95	}
96
97	double egiw::evallog_nn ( const vec &val ) const {
98	int vend = val.length() - 1;
99
100	if ( dimx == 1 ) { //same as the following, just quicker.
101	double r = val ( vend ); //last entry!
102	if ( r < 0 ) return -inf;
103	vec Psi ( nPsi + dimx );
104	Psi ( 0 ) = -1.0;
105	Psi.set_subvector ( 1, val ( 0, vend - 1 ) ); // fill the rest
106
107	double Vq = V.qform ( Psi );
108	return -0.5* ( nu*log ( r ) + Vq / r );
109	} else {
110	mat Th = reshape ( val ( 0, nPsi * dimx - 1 ), nPsi, dimx );
111	fsqmat R ( reshape ( val ( nPsi*dimx, vend ), dimx, dimx ) );
112	double ldetR = R.logdet();
113	if ( ldetR ) return -inf;
114	mat Tmp = concat_vertical ( -eye ( dimx ), Th );
115	fsqmat iR ( dimx );
116	R.inv ( iR );
117
118	return -0.5* ( nuldetR + trace ( iR.to_mat() Tmp.T() V.to_mat() Tmp ) );
119	}
120	}
121
122	double egiw::lognc() const {
123	const vec& D = V._D();
124
125	double m = nu - nPsi - dimx - 1;
126	#define log2 0.693147180559945286226763983
127	#define logpi 1.144729885849400163877476189
128	#define log2pi 1.83787706640935
129	#define Inf std::numeric_limits<double>::infinity()
130
131	double nkG = 0.5 * dimx * ( -nPsi * log2pi + sum ( log ( D ( dimx, D.length() - 1 ) ) ) );
132	// temporary for lgamma in Wishart
133	double lg = 0;
134	for ( int i = 0; i < dimx; i++ ) {
135	lg += lgamma ( 0.5 * ( m - i ) );
136	}
137
138	double nkW = 0.5 * ( m * sum ( log ( D ( 0, dimx - 1 ) ) ) ) \
139	- 0.5 * dimx * ( m * log2 + 0.5 * ( dimx - 1 ) * log2pi ) - lg;
140
141	// bdm_assert_debug ( ( ( -nkG - nkW ) > -Inf ) && ( ( -nkG - nkW ) < Inf ), "ARX improper" );
142	if ( -nkG - nkW == Inf ) {
143	cout << "??" << endl;
144	}
145	return -nkG - nkW;
146	}
147
148	vec egiw::est_theta() const {
149	if ( dimx == 1 ) {
150	const mat &L = V._L();
151	int end = L.rows() - 1;
152
153	mat iLsub = ltuinv ( L ( dimx, end, dimx, end ) );
154
155	vec L0 = L.get_col ( 0 );
156
157	return iLsub * L0 ( 1, end );
158	} else {
159	bdm_error ( "ERROR: est_theta() not implemented for dimx>1" );
160	return vec();
161	}
162	}
163
164	void egiw::factorize ( mat &M, ldmat &Vz, ldmat &Lam ) const {
165	const mat &L = V._L();
166	const vec &D = V._D();
167	int end = L.rows() - 1;
168
169	Vz = ldmat ( L ( dimx, end, dimx, end ), D ( dimx, end ) );
170	mat iLsub = ltuinv ( Vz._L() );
171	// set mean value
172	mat Lpsi = L ( dimx, end, 0, dimx - 1 );
173	M = iLsub * Lpsi;
174
175	Lam = ldmat ( L ( 0, dimx - 1, 0, dimx - 1 ), D ( 0, dimx - 1 ) ); //exp val of R
176	if ( 1 ) { // test with Peterka
177	mat VF = V.to_mat();
178	mat Vf = VF ( 0, dimx - 1, 0, dimx - 1 );
179	mat Vzf = VF ( dimx, end, 0, dimx - 1 );
180	mat VZ = VF ( dimx, end, dimx, end );
181
182	mat Lam2 = Vf - Vzf.T() * inv ( VZ ) * Vzf;
183	}
184	}
185
186	ldmat egiw::est_theta_cov() const {
187	if ( dimx == 1 ) {
188	const mat &L = V._L();
189	const vec &D = V._D();
190	int end = D.length() - 1;
191
192	mat Lsub = L ( 1, end, 1, end );
193	// mat Dsub = diag ( D ( 1, end ) );
194
195	ldmat LD ( inv ( Lsub ).T(), 1.0 / D ( 1, end ) );
196	return LD;
197
198	} else {
199	bdm_error ( "ERROR: est_theta_cov() not implemented for dimx>1" );
200	return ldmat();
201	}
202
203	}
204
205	vec egiw::mean() const {
206
207	if ( dimx == 1 ) {
208	const vec &D = V._D();
209	int end = D.length() - 1;
210
211	vec m ( dim );
212	m.set_subvector ( 0, est_theta() );
213	m ( end ) = D ( 0 ) / ( nu - nPsi - 2 * dimx - 2 );
214	return m;
215	} else {
216	mat M;
217	mat R;
218	mean_mat ( M, R );
219	return concat ( cvectorize ( M ), cvectorize ( R ) );
220	}
221
222	}
223
224	vec egiw::variance() const {
225	int l = V.rows();
226	// cut out rest of lower-right part of V
227	const ldmat tmp ( V, linspace ( dimx, l - 1 ) );
228	// invert it
229	ldmat itmp ( l );
230	tmp.inv ( itmp );
231
232	// following Wikipedia notation
233	// m=nu-nPsi-dimx-1, p=dimx
234	double mp1p = nu - nPsi - 2 * dimx; // m-p+1
235	double mp1m = mp1p - 2; // m-p-1
236
237	if ( dimx == 1 ) {
238	double cove = V._D() ( 0 ) / mp1m ;
239
240	vec var ( l );
241	var.set_subvector ( 0, diag ( itmp.to_mat() ) *cove );
242	var ( l - 1 ) = cove * cove / ( mp1m - 2 );
243	return var;
244	} else {
245	ldmat Vll ( V, linspace ( 0, dimx - 1 ) ); // top-left part of V
246	mat Y = Vll.to_mat();
247	mat varY ( Y.rows(), Y.cols() );
248
249	double denom = ( mp1p - 1 ) * mp1m * mp1m * ( mp1m - 2 ); // (m-p)(m-p-1)^2(m-p-3)
250
251	int i, j;
252	for ( i = 0; i < Y.rows(); i++ ) {
253	for ( j = 0; j < Y.cols(); j++ ) {
254	varY ( i, j ) = ( mp1p * Y ( i, j ) * Y ( i, j ) + mp1m * Y ( i, i ) * Y ( j, j ) ) / denom;
255	}
256	}
257	vec mean_dR = diag ( Y ) / mp1m; // corresponds to cove
258	vec var_th = diag ( itmp.to_mat() );
259	vec var_Th ( mean_dR.length() *var_th.length() );
260	// diagonal of diag(mean_dR) \kron diag(var_th)
261	for ( int i = 0; i < mean_dR.length(); i++ ) {
262	var_Th.set_subvector ( ivar_th.length(), var_thmean_dR ( i ) );
263	}
264
265	return concat ( var_Th, cvectorize ( varY ) );
266	}
267	}
268
269	void egiw::mean_mat ( mat &M, mat&R ) const {
270	const mat &L = V._L();
271	const vec &D = V._D();
272	int end = L.rows() - 1;
273
274	ldmat ldR ( L ( 0, dimx - 1, 0, dimx - 1 ), D ( 0, dimx - 1 ) / ( nu - nPsi - 2*dimx - 2 ) ); //exp val of R
275	mat iLsub = ltuinv ( L ( dimx, end, dimx, end ) );
276
277	// set mean value
278	mat Lpsi = L ( dimx, end, 0, dimx - 1 );
279	M = iLsub * Lpsi;
280	R = ldR.to_mat() ;
281	}
282
283	void egiw::log_register ( bdm::logger& L, const string& prefix ) {
284	if ( log_level == 3 ) {
285	root::log_register ( L, prefix );
286	logrec->ids.set_length ( 2 );
287	int th_dim = dimension() - dimx * ( dimx + 1 ) / 2;
288	logrec->ids ( 0 ) = L.add_vector ( RV ( "", th_dim ), prefix + logrec->L.prefix_sep() + "mean" );
289	logrec->ids ( 1 ) = L.add_vector ( RV ( "", th_dim * th_dim ), prefix + logrec->L.prefix_sep() + "variance" );
290	} else {
291	epdf::log_register ( L, prefix );
292	}
293	}
294
295	void egiw::log_write() const {
296	if ( log_level == 3 ) {
297	mat M;
298	ldmat Lam;
299	ldmat Vz;
300	factorize ( M, Vz, Lam );
301	logrec->L.log_vector ( logrec->ids ( 0 ), est_theta() );
302	logrec->L.log_vector ( logrec->ids ( 1 ), cvectorize ( est_theta_cov().to_mat() ) );
303	} else {
304	epdf::log_write();
305	}
306
307	}
308
309	void multiBM::bayes ( const vec &yt, const vec &cond ) {
310	if ( frg < 1.0 ) {
311	beta *= frg;
312	last_lognc = est.lognc();
313	}
314	beta += yt;
315	if ( evalll ) {
316	ll = est.lognc() - last_lognc;
317	}
318	}
319
320	double multiBM::logpred ( const vec &yt ) const {
321	eDirich pred ( est );
322	vec &beta = pred._beta();
323
324	double lll;
325	if ( frg < 1.0 ) {
326	beta *= frg;
327	lll = pred.lognc();
328	} else if ( evalll ) {
329	lll = last_lognc;
330	} else {
331	lll = pred.lognc();
332	}
333
334	beta += yt;
335	return pred.lognc() - lll;
336	}
337	void multiBM::flatten ( const BMEF* B ) {
338	const multiBM* E = dynamic_cast<const multiBM*> ( B );
339	// sum(beta) should be equal to sum(B.beta)
340	const vec &Eb = E->beta;//const_cast<multiBM*> ( E )->_beta();
341	beta *= ( sum ( Eb ) / sum ( beta ) );
342	if ( evalll ) {
343	last_lognc = est.lognc();
344	}
345	}
346
347	vec egamma::sample() const {
348	vec smp ( dim );
349	int i;
350
351	for ( i = 0; i < dim; i++ ) {
352	if ( beta ( i ) > std::numeric_limits<double>::epsilon() ) {
353	GamRNG.setup ( alpha ( i ), beta ( i ) );
354	} else {
355	GamRNG.setup ( alpha ( i ), std::numeric_limits<double>::epsilon() );
356	}
357	#pragma omp critical
358	smp ( i ) = GamRNG();
359	}
360
361	return smp;
362	}
363
364	// mat egamma::sample ( int N ) const {
365	// mat Smp ( rv.count(),N );
366	// int i,j;
367	//
368	// for ( i=0; i<rv.count(); i++ ) {
369	// GamRNG.setup ( alpha ( i ),beta ( i ) );
370	//
371	// for ( j=0; j<N; j++ ) {
372	// Smp ( i,j ) = GamRNG();
373	// }
374	// }
375	//
376	// return Smp;
377	// }
378
379	double egamma::evallog ( const vec &val ) const {
380	double res = 0.0; //the rest will be added
381	int i;
382
383	if ( any ( val <= 0. ) ) return -inf;
384	if ( any ( beta <= 0. ) ) return -inf;
385	for ( i = 0; i < dim; i++ ) {
386	res += ( alpha ( i ) - 1 ) * std::log ( val ( i ) ) - beta ( i ) * val ( i );
387	}
388	double tmp = res - lognc();;
389	bdm_assert_debug ( std::isfinite ( tmp ), "Infinite value" );
390	return tmp;
391	}
392
393	double egamma::lognc() const {
394	double res = 0.0; //will be added
395	int i;
396
397	for ( i = 0; i < dim; i++ ) {
398	res += lgamma ( alpha ( i ) ) - alpha ( i ) * std::log ( beta ( i ) ) ;
399	}
400
401	return res;
402	}
403
404	void mgamma::set_parameters ( double k0, const vec &beta0 ) {
405	k = k0;
406	iepdf.set_parameters ( k * ones ( beta0.length() ), beta0 );
407	dimc = iepdf.dimension();
408	dim = iepdf.dimension();
409	}
410
411	void eEmp::resample ( ivec &ind, RESAMPLING_METHOD method ) {
412	ind = zeros_i ( n );
413	ivec N_babies = zeros_i ( n );
414	vec cumDist = cumsum ( w );
415	vec u ( n );
416	int i, j, parent;
417	double u0;
418
419	switch ( method ) {
420	case MULTINOMIAL:
421	u ( n - 1 ) = pow ( UniRNG.sample(), 1.0 / n );
422
423	for ( i = n - 2; i >= 0; i-- ) {
424	u ( i ) = u ( i + 1 ) * pow ( UniRNG.sample(), 1.0 / ( i + 1 ) );
425	}
426
427	break;
428
429	case STRATIFIED:
430
431	for ( i = 0; i < n; i++ ) {
432	u ( i ) = ( i + UniRNG.sample() ) / n;
433	}
434
435	break;
436
437	case SYSTEMATIC:
438	u0 = UniRNG.sample();
439
440	for ( i = 0; i < n; i++ ) {
441	u ( i ) = ( i + u0 ) / n;
442	}
443
444	break;
445
446	default:
447	bdm_error ( "PF::resample(): Unknown resampling method" );
448	}
449
450	// U is now full
451	j = 0;
452
453	for ( i = 0; i < n; i++ ) {
454	while ( u ( i ) > cumDist ( j ) ) j++;
455
456	N_babies ( j ) ++;
457	}
458	// We have assigned new babies for each Particle
459	// Now, we fill the resulting index such that:
460	// * particles with at least one baby should not move *
461	// This assures that reassignment can be done inplace;
462
463	// find the first parent;
464	parent = 0;
465	while ( N_babies ( parent ) == 0 ) parent++;
466
467	// Build index
468	for ( i = 0; i < n; i++ ) {
469	if ( N_babies ( i ) > 0 ) {
470	ind ( i ) = i;
471	N_babies ( i ) --; //this index was now replicated;
472	} else {
473	// test if the parent has been fully replicated
474	// if yes, find the next one
475	while ( ( N_babies ( parent ) == 0 ) \|\| ( N_babies ( parent ) == 1 && parent > i ) ) parent++;
476
477	// Replicate parent
478	ind ( i ) = parent;
479
480	N_babies ( parent ) --; //this index was now replicated;
481	}
482
483	}
484
485	// copy the internals according to ind
486	for ( i = 0; i < n; i++ ) {
487	if ( ind ( i ) != i ) {
488	samples ( i ) = samples ( ind ( i ) );
489	}
490	w ( i ) = 1.0 / n;
491	}
492	}
493
494	void eEmp::set_statistics ( const vec &w0, const epdf &epdf0 ) {
495	dim = epdf0.dimension();
496	w = w0;
497	w /= sum ( w0 );//renormalize
498	n = w.length();
499	samples.set_size ( n );
500
501	for ( int i = 0; i < n; i++ ) {
502	samples ( i ) = epdf0.sample();
503	}
504	}
505
506	void eEmp::set_samples ( const epdf* epdf0 ) {
507	w = 1;
508	w /= sum ( w );//renormalize
509
510	for ( int i = 0; i < n; i++ ) {
511	samples ( i ) = epdf0->sample();
512	}
513	}
514
515	void migamma_ref::from_setting ( const Setting &set ) {
516	vec ref;
517	UI::get ( ref, set, "ref" , UI::compulsory );
518	set_parameters ( set["k"], ref, set["l"] );
519	}
520
521	void mlognorm::from_setting ( const Setting &set ) {
522	vec mu0;
523	UI::get ( mu0, set, "mu0", UI::compulsory );
524	set_parameters ( mu0.length(), set["k"] );
525	condition ( mu0 );
526	}
527
528	void mlstudent::condition ( const vec &cond ) {
529	if ( cond.length() > 0 ) {
530	iepdf._mu() = A * cond + mu_const;
531	} else {
532	iepdf._mu() = mu_const;
533	}
534	double zeta;
535	//ugly hack!
536	if ( ( cond.length() + 1 ) == Lambda.rows() ) {
537	zeta = Lambda.invqform ( concat ( cond, vec_1 ( 1.0 ) ) );
538	} else {
539	zeta = Lambda.invqform ( cond );
540	}
541	_R = Re;
542	_R *= ( 1 + zeta );// / ( nu ); << nu is in Re!!!!!!
543	}
544
545	void eEmp::qbounds ( vec &lb, vec &ub, double perc ) const {
546	// lb in inf so than it will be pushed below;
547	lb.set_size ( dim );
548	ub.set_size ( dim );
549	lb = std::numeric_limits<double>::infinity();
550	ub = -std::numeric_limits<double>::infinity();
551	int j;
552	for ( int i = 0; i < n; i++ ) {
553	for ( j = 0; j < dim; j++ ) {
554	if ( samples ( i ) ( j ) < lb ( j ) ) {
555	lb ( j ) = samples ( i ) ( j );
556	}
557	if ( samples ( i ) ( j ) > ub ( j ) ) {
558	ub ( j ) = samples ( i ) ( j );
559	}
560	}
561	}
562	}
563
564
565	};

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