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robustlib.h @ 1376

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1	/*!
2	\file
3	\brief Robust Bayesian auto-regression model
4	\author Jan Sindelar.
5	*/
6
7	#ifndef ROBUST_H
8	#define ROBUST_H
9
10	#include <stat/exp_family.h>
11	#include <itpp/itbase.h>
12	#include <itpp/base/random.h>
13	#include <map>
14	#include <limits>
15	#include <vector>
16	#include <list>
17	#include <set>
18	#include <algorithm>
19
20	using namespace bdm;
21	using namespace std;
22	using namespace itpp;
23
24	const double max_range = 5;//numeric_limits<double>::max()/10e-10;
25
26	/// An enumeration of possible actions performed on the polyhedrons. We can merge them or split them.
27	enum actions {MERGE, SPLIT};
28
29	// Forward declaration of polyhedron, vertex and emlig
30	class polyhedron;
31	class vertex;
32	class emlig;
33
34	/*
35	class t_simplex
36	{
37	public:
38	set<vertex*> minima;
39
40	set<vertex*> simplex;
41
42	t_simplex(vertex* origin_vertex)
43	{
44	simplex.insert(origin_vertex);
45	minima.insert(origin_vertex);
46	}
47	};*/
48
49	/// A class representing a single condition that can be added to the emlig. A condition represents data entries in a statistical model.
50	class condition
51	{
52	public:
53	/// Value of the condition representing the data
54	vec value;
55
56	/// Mulitplicity of the given condition may represent multiple occurences of same data entry.
57	int multiplicity;
58
59	/// Default constructor of condition class takes the value of data entry and creates a condition with multiplicity 1 (first occurence of the data).
60	condition(vec value)
61	{
62	this->value = value;
63	multiplicity = 1;
64	}
65	};
66
67	class simplex
68	{
69
70
71	public:
72
73	set<vertex*> vertices;
74
75	double probability;
76
77	vector<multimap<double,double>> positive_gamma_parameters;
78
79	vector<multimap<double,double>> negative_gamma_parameters;
80
81	double positive_gamma_sum;
82
83	double negative_gamma_sum;
84
85	double min_beta;
86
87
88	simplex(set<vertex*> vertices)
89	{
90	this->vertices.insert(vertices.begin(),vertices.end());
91	probability = 0;
92	}
93
94	simplex(vertex* vertex)
95	{
96	this->vertices.insert(vertex);
97	probability = 0;
98	}
99
100	void clear_gammas()
101	{
102	positive_gamma_parameters.clear();
103	negative_gamma_parameters.clear();
104
105	positive_gamma_sum = 0;
106	negative_gamma_sum = 0;
107
108	min_beta = numeric_limits<double>::max();
109	}
110
111	void insert_gamma(int order, double weight, double beta)
112	{
113	if(weight>=0)
114	{
115	while(positive_gamma_parameters.size()<order+1)
116	{
117	multimap<double,double> map;
118	positive_gamma_parameters.push_back(map);
119	}
120
121	positive_gamma_sum += weight;
122
123	positive_gamma_parameters[order].insert(pair<double,double>(weight,beta));
124	}
125	else
126	{
127	while(negative_gamma_parameters.size()<order+1)
128	{
129	multimap<double,double> map;
130	negative_gamma_parameters.push_back(map);
131	}
132
133	negative_gamma_sum -= weight;
134
135	negative_gamma_parameters[order].insert(pair<double,double>(-weight,beta));
136	}
137
138	if(beta < min_beta)
139	{
140	min_beta = beta;
141	}
142	}
143	};
144
145
146	/// A class describing a single polyhedron of the split complex. From a collection of such classes a Hasse diagram
147	/// of the structure in the exponent of a Laplace-Inverse-Gamma density will be created.
148	class polyhedron
149	{
150	/// A property having a value of 1 usually, with higher value only if the polyhedron arises as a coincidence of
151	/// more than just the necessary number of conditions. For example if a newly created line passes through an already
152	/// existing point, the points multiplicity will rise by 1.
153	int multiplicity;
154
155	/// A property representing the position of the polyhedron related to current condition with relation to which we
156	/// are splitting the parameter space (new data has arrived). This property is setup within a classification procedure and
157	/// is only valid while the new condition is being added. It has to be reset when new condition is added and new classification
158	/// has to be performed.
159	int split_state;
160
161	/// A property representing the position of the polyhedron related to current condition with relation to which we
162	/// are merging the parameter space (data is being deleted usually due to a moving window model which is more adaptive and
163	/// steps in for the forgetting in a classical Gaussian AR model). This property is setup within a classification procedure and
164	/// is only valid while the new condition is being removed. It has to be reset when new condition is removed and new classification
165	/// has to be performed.
166	int merge_state;
167
168
169
170	public:
171	/// A pointer to the multi-Laplace inverse gamma distribution this polyhedron belongs to.
172	emlig* my_emlig;
173
174	/// A list of polyhedrons parents within the Hasse diagram.
175	list<polyhedron*> parents;
176
177	/// A list of polyhedrons children withing the Hasse diagram.
178	list<polyhedron*> children;
179
180	/// All the vertices of the given polyhedron
181	set<vertex*> vertices;
182
183	/// The conditions that gave birth to the polyhedron. If some of them is removed, the polyhedron ceases to exist.
184	set<condition*> parentconditions;
185
186	/// A list used for storing children that lie in the positive region related to a certain condition
187	list<polyhedron*> positivechildren;
188
189	/// A list used for storing children that lie in the negative region related to a certain condition
190	list<polyhedron*> negativechildren;
191
192	/// Children intersecting the condition
193	list<polyhedron*> neutralchildren;
194
195	/// A set of grandchildren of the polyhedron that when new condition is added lie exactly on the condition hyperplane. These grandchildren
196	/// behave differently from other grandchildren, when the polyhedron is split. New grandchild is not necessarily created on the crossection of
197	/// the polyhedron and new condition.
198	set<polyhedron*> totallyneutralgrandchildren;
199
200	/// A set of children of the polyhedron that when new condition is added lie exactly on the condition hyperplane. These children
201	/// behave differently from other children, when the polyhedron is split. New child is not necessarily created on the crossection of
202	/// the polyhedron and new condition.
203	set<polyhedron*> totallyneutralchildren;
204
205	/// Reverse relation to the totallyneutralgrandchildren set is needed for merging of already existing polyhedrons to keep
206	/// totallyneutralgrandchildren list up to date.
207	set<polyhedron*> grandparents;
208
209	/// Vertices of the polyhedron classified as positive related to an added condition. When the polyhderon is split by the new condition,
210	/// these vertices will belong to the positive part of the splitted polyhedron.
211	set<vertex*> positiveneutralvertices;
212
213	/// Vertices of the polyhedron classified as negative related to an added condition. When the polyhderon is split by the new condition,
214	/// these vertices will belong to the negative part of the splitted polyhedron.
215	set<vertex*> negativeneutralvertices;
216
217	/// A bool specifying if the polyhedron lies exactly on the newly added condition or not.
218	bool totally_neutral;
219
220	/// When two polyhedrons are merged, there always exists a child lying on the former border of the polyhedrons. This child manages the merge
221	/// of the two polyhedrons. This property gives us the address of the mediator child.
222	polyhedron* mergechild;
223
224	/// If the polyhedron serves as a mergechild for two of its parents, we need to have the address of the parents to access them. This
225	/// is the pointer to the positive parent being merged.
226	polyhedron* positiveparent;
227
228	/// If the polyhedron serves as a mergechild for two of its parents, we need to have the address of the parents to access them. This
229	/// is the pointer to the negative parent being merged.
230	polyhedron* negativeparent;
231
232	/// Adressing withing the statistic. Next_poly is a pointer to the next polyhedron in the statistic on the same level (if this is a point,
233	/// next_poly will be a point etc.).
234	polyhedron* next_poly;
235
236	/// Adressing withing the statistic. Prev_poly is a pointer to the previous polyhedron in the statistic on the same level (if this is a point,
237	/// next_poly will be a point etc.).
238	polyhedron* prev_poly;
239
240	/// A property counting the number of messages obtained from children within a classification procedure of position of the polyhedron related
241	/// an added/removed condition. If the message counter reaches the number of children, we know the polyhedrons' position has been fully classified.
242	int message_counter;
243
244	/// List of triangulation polyhedrons of the polyhedron given by their relative vertices.
245	set<simplex*> triangulation;
246
247	/// A list of relative addresses serving for Hasse diagram construction.
248	list<int> kids_rel_addresses;
249
250	/// Default constructor
251	polyhedron()
252	{
253	multiplicity = 1;
254
255	message_counter = 0;
256
257	totally_neutral = NULL;
258
259	mergechild = NULL;
260	}
261
262	/// Setter for raising multiplicity
263	void raise_multiplicity()
264	{
265	multiplicity++;
266	}
267
268	/// Setter for lowering multiplicity
269	void lower_multiplicity()
270	{
271	multiplicity--;
272	}
273
274	int get_multiplicity()
275	{
276	return multiplicity;
277	}
278
279	/// An obligatory operator, when the class is used within a C++ STL structure like a vector
280	int operator==(polyhedron polyhedron2)
281	{
282	return true;
283	}
284
285	/// An obligatory operator, when the class is used within a C++ STL structure like a vector
286	int operator<(polyhedron polyhedron2)
287	{
288	return false;
289	}
290
291
292	/// A setter of state of current polyhedron relative to the action specified in the argument. The three possible states of the
293	/// polyhedron are -1 - NEGATIVE, 0 - NEUTRAL, 1 - POSITIVE. Neutral state means that either the state has been reset or the polyhedron is
294	/// ready to be split/merged.
295	int set_state(double state_indicator, actions action)
296	{
297	switch(action)
298	{
299	case MERGE:
300	merge_state = (int)sign(state_indicator);
301	return merge_state;
302	case SPLIT:
303	split_state = (int)sign(state_indicator);
304	return split_state;
305	}
306	}
307
308	/// A getter of state of current polyhedron relative to the action specified in the argument. The three possible states of the
309	/// polyhedron are -1 - NEGATIVE, 0 - NEUTRAL, 1 - POSITIVE. Neutral state means that either the state has been reset or the polyhedron is
310	/// ready to be split/merged.
311	int get_state(actions action)
312	{
313	switch(action)
314	{
315	case MERGE:
316	return merge_state;
317	break;
318	case SPLIT:
319	return split_state;
320	break;
321	}
322	}
323
324	/// Method for obtaining the number of children of given polyhedron.
325	int number_of_children()
326	{
327	return children.size();
328	}
329
330	/// A method for triangulation of given polyhedron.
331	double triangulate(bool should_integrate);
332	};
333
334
335	/// A class for representing 0-dimensional polyhedron - a vertex. It will be located in the bottom row of the Hasse
336	/// diagram representing a complex of polyhedrons. It has its coordinates in the parameter space.
337	class vertex : public polyhedron
338	{
339	/// A dynamic array representing coordinates of the vertex
340	vec coordinates;
341
342	public:
343	/// A property specifying the value of the density (ted nevim, jestli je to jakoby log nebo ne) above the vertex.
344	double function_value;
345
346	/// Default constructor
347	vertex();
348
349	/// Constructor of a vertex from a set of coordinates
350	vertex(vec coordinates)
351	{
352	this->coordinates = coordinates;
353
354	vertices.insert(this);
355
356	simplex* vert_simplex = new simplex(vertices);
357
358	triangulation.insert(vert_simplex);
359	}
360
361	/// A method that widens the set of coordinates of given vertex. It is used when a complex in a parameter
362	/// space of certain dimension is established, but the dimension is not known when the vertex is created.
363	void push_coordinate(double coordinate)
364	{
365	coordinates = concat(coordinates,coordinate);
366	}
367
368	/// A method obtaining the set of coordinates of a vertex. These coordinates are not obtained as a pointer
369	/// (not given by reference), but a new copy is created (they are given by value).
370	vec get_coordinates()
371	{
372	return coordinates;
373	}
374
375	};
376
377
378	/// A class representing a polyhedron in a top row of the complex. Such polyhedron has a condition that differen tiates
379	/// it from polyhedrons in other rows.
380	class toprow : public polyhedron
381	{
382
383	public:
384	double probability;
385
386	vertex* minimal_vertex;
387
388	/// A condition used for determining the function of a Laplace-Inverse-Gamma density resulting from Bayesian estimation
389	vec condition_sum;
390
391	int condition_order;
392
393	/// Default constructor
394	toprow(){};
395
396	/// Constructor creating a toprow from the condition
397	toprow(condition *condition, int condition_order)
398	{
399	this->condition_sum = condition->value;
400	this->condition_order = condition_order;
401	}
402
403	toprow(vec condition_sum, int condition_order)
404	{
405	this->condition_sum = condition_sum;
406	this->condition_order = condition_order;
407	}
408
409	double integrate_simplex(simplex* simplex, char c);
410
411	};
412
413
414
415
416
417
418
419	class c_statistic
420	{
421
422	public:
423	polyhedron* end_poly;
424	polyhedron* start_poly;
425
426	vector<polyhedron*> rows;
427
428	vector<polyhedron*> row_ends;
429
430	c_statistic()
431	{
432	end_poly = new polyhedron();
433	start_poly = new polyhedron();
434	};
435
436	~c_statistic()
437	{
438	delete end_poly;
439	delete start_poly;
440	}
441
442	void append_polyhedron(int row, polyhedron* appended_start, polyhedron* appended_end)
443	{
444	if(row>((int)rows.size())-1)
445	{
446	if(row>rows.size())
447	{
448	throw new exception("You are trying to append a polyhedron whose children are not in the statistic yet!");
449	return;
450	}
451
452	rows.push_back(end_poly);
453	row_ends.push_back(end_poly);
454	}
455
456	// POSSIBLE FAILURE: the function is not checking if start and end are connected
457
458	if(rows[row] != end_poly)
459	{
460	appended_start->prev_poly = row_ends[row];
461	row_ends[row]->next_poly = appended_start;
462
463	}
464	else if((row>0 && rows[row-1]!=end_poly)\|\|row==0)
465	{
466	appended_start->prev_poly = start_poly;
467	rows[row]= appended_start;
468	}
469	else
470	{
471	throw new exception("Wrong polyhedron insertion into statistic: missing intermediary polyhedron!");
472	}
473
474	appended_end->next_poly = end_poly;
475	row_ends[row] = appended_end;
476	}
477
478	void append_polyhedron(int row, polyhedron* appended_poly)
479	{
480	append_polyhedron(row,appended_poly,appended_poly);
481	}
482
483	void insert_polyhedron(int row, polyhedron* inserted_poly, polyhedron* following_poly)
484	{
485	if(following_poly != end_poly)
486	{
487	inserted_poly->next_poly = following_poly;
488	inserted_poly->prev_poly = following_poly->prev_poly;
489
490	if(following_poly->prev_poly == start_poly)
491	{
492	rows[row] = inserted_poly;
493	}
494	else
495	{
496	inserted_poly->prev_poly->next_poly = inserted_poly;
497	}
498
499	following_poly->prev_poly = inserted_poly;
500	}
501	else
502	{
503	this->append_polyhedron(row, inserted_poly);
504	}
505
506	}
507
508
509
510
511	void delete_polyhedron(int row, polyhedron* deleted_poly)
512	{
513	if(deleted_poly->prev_poly != start_poly)
514	{
515	deleted_poly->prev_poly->next_poly = deleted_poly->next_poly;
516	}
517	else
518	{
519	rows[row] = deleted_poly->next_poly;
520	}
521
522	if(deleted_poly->next_poly!=end_poly)
523	{
524	deleted_poly->next_poly->prev_poly = deleted_poly->prev_poly;
525	}
526	else
527	{
528	row_ends[row] = deleted_poly->prev_poly;
529	}
530
531
532
533	deleted_poly->next_poly = NULL;
534	deleted_poly->prev_poly = NULL;
535	}
536
537	int size()
538	{
539	return rows.size();
540	}
541
542	polyhedron* get_end()
543	{
544	return end_poly;
545	}
546
547	polyhedron* get_start()
548	{
549	return start_poly;
550	}
551
552	int row_size(int row)
553	{
554	if(this->size()>row && row>=0)
555	{
556	int row_size = 0;
557
558	for(polyhedron* row_poly = rows[row]; row_poly!=end_poly; row_poly=row_poly->next_poly)
559	{
560	row_size++;
561	}
562
563	return row_size;
564	}
565	else
566	{
567	throw new exception("There is no row to obtain size from!");
568	}
569	}
570	};
571
572
573	class my_ivec : public ivec
574	{
575	public:
576	my_ivec():ivec(){};
577
578	my_ivec(ivec origin):ivec()
579	{
580	this->ins(0,origin);
581	}
582
583	bool operator>(const my_ivec &second) const
584	{
585	return max(*this)>max(second);
586
587	/*
588	int size1 = this->size();
589	int size2 = second.size();
590
591	int counter1 = 0;
592	while(0==0)
593	{
594	if((*this)[counter1]==0)
595	{
596	size1--;
597	}
598
599	if((*this)[counter1]!=0)
600	break;
601
602	counter1++;
603	}
604
605	int counter2 = 0;
606	while(0==0)
607	{
608	if(second[counter2]==0)
609	{
610	size2--;
611	}
612
613	if(second[counter2]!=0)
614	break;
615
616	counter2++;
617	}
618
619	if(size1!=size2)
620	{
621	return size1>size2;
622	}
623	else
624	{
625	for(int i = 0;i<size1;i++)
626	{
627	if((*this)[counter1+i]!=second[counter2+i])
628	{
629	return (*this)[counter1+i]>second[counter2+i];
630	}
631	}
632
633	return false;
634	}*/
635	}
636
637
638	bool operator==(const my_ivec &second) const
639	{
640	return max(*this)==max(second);
641
642	/*
643	int size1 = this->size();
644	int size2 = second.size();
645
646	int counter = 0;
647	while(0==0)
648	{
649	if((*this)[counter]==0)
650	{
651	size1--;
652	}
653
654	if((*this)[counter]!=0)
655	break;
656
657	counter++;
658	}
659
660	counter = 0;
661	while(0==0)
662	{
663	if(second[counter]==0)
664	{
665	size2--;
666	}
667
668	if(second[counter]!=0)
669	break;
670
671	counter++;
672	}
673
674	if(size1!=size2)
675	{
676	return false;
677	}
678	else
679	{
680	for(int i=0;i<size1;i++)
681	{
682	if((*this)[size()-1-i]!=second[second.size()-1-i])
683	{
684	return false;
685	}
686	}
687
688	return true;
689	}*/
690	}
691
692	bool operator<(const my_ivec &second) const
693	{
694	return !(((this)>second)\|\|((this)==second));
695	}
696
697	bool operator!=(const my_ivec &second) const
698	{
699	return !((*this)==second);
700	}
701
702	bool operator<=(const my_ivec &second) const
703	{
704	return !((*this)>second);
705	}
706
707	bool operator>=(const my_ivec &second) const
708	{
709	return !((*this)<second);
710	}
711
712	my_ivec right(my_ivec original)
713	{
714
715	}
716	};
717
718
719
720
721
722
723
724	//! Conditional(e) Multicriteria-Laplace-Inverse-Gamma distribution density
725	class emlig // : eEF
726	{
727
728	/// A statistic in a form of a Hasse diagram representing a complex of convex polyhedrons obtained as a result
729	/// of data update from Bayesian estimation or set by the user if this emlig is a prior density
730
731
732	vector<list<polyhedron*>> for_splitting;
733
734	vector<list<polyhedron*>> for_merging;
735
736	list<condition*> conditions;
737
738	double normalization_factor;
739
740	int condition_order;
741
742	double last_log_nc;
743
744
745
746	void alter_toprow_conditions(condition *condition, bool should_be_added)
747	{
748	for(polyhedron* horiz_ref = statistic.rows[statistic.size()-1];horiz_ref!=statistic.get_end();horiz_ref=horiz_ref->next_poly)
749	{
750	set<vertex*>::iterator vertex_ref = horiz_ref->vertices.begin();
751
752	do
753	{
754	vertex_ref++;
755
756	if(vertex_ref==horiz_ref->vertices.end())
757	{
758	return;
759	}
760	}
761	while((vertex_ref)->parentconditions.find(condition)!=(vertex_ref)->parentconditions.end());
762
763
764
765	vec appended_coords = (*vertex_ref)->get_coordinates();
766	appended_coords.ins(0,-1.0);
767
768	double product = appended_coords*condition->value;
769
770	if(should_be_added)
771	{
772	((toprow*) horiz_ref)->condition_order++;
773
774	if(product>0)
775	{
776	((toprow*) horiz_ref)->condition_sum += condition->value;
777	}
778	else
779	{
780	((toprow*) horiz_ref)->condition_sum -= condition->value;
781	}
782	}
783	else
784	{
785	((toprow*) horiz_ref)->condition_order--;
786
787	if(product<0)
788	{
789	((toprow*) horiz_ref)->condition_sum += condition->value;
790	}
791	else
792	{
793	((toprow*) horiz_ref)->condition_sum -= condition->value;
794	}
795	}
796	}
797	}
798
799
800
801	void send_state_message(polyhedron* sender, condition toadd, condition toremove, int level)
802	{
803
804	bool shouldmerge = (toremove != NULL);
805	bool shouldsplit = (toadd != NULL);
806
807	if(shouldsplit\|\|shouldmerge)
808	{
809	for(list<polyhedron*>::iterator parent_iterator = sender->parents.begin();parent_iterator!=sender->parents.end();parent_iterator++)
810	{
811	polyhedron* current_parent = *parent_iterator;
812
813	current_parent->message_counter++;
814
815	bool is_last = (current_parent->message_counter == current_parent->number_of_children());
816	bool is_first = (current_parent->message_counter == 1);
817
818	bool out_of_the_game = true;
819
820	if(shouldmerge)
821	{
822	int child_state = sender->get_state(MERGE);
823	int parent_state = current_parent->get_state(MERGE);
824
825	if(parent_state == 0\|\|is_first)
826	{
827	parent_state = current_parent->set_state(child_state, MERGE);
828	}
829
830	if(child_state == 0)
831	{
832	if(current_parent->mergechild == NULL)
833	{
834	current_parent->mergechild = sender;
835	}
836	}
837
838	if(is_last)
839	{
840	if(level == number_of_parameters-1)
841	{
842	if(parent_state == 1)
843	{
844	((toprow*)current_parent)->condition_sum-=toremove->value;
845	}
846
847	if(parent_state == -1)
848	{
849	((toprow*)current_parent)->condition_sum+=toremove->value;
850	}
851	}
852
853	((toprow*)current_parent)->condition_order--;
854
855
856	if(current_parent->mergechild != NULL)
857	{
858	out_of_the_game = false;
859
860	if(current_parent->mergechild->get_multiplicity()==1)
861	{
862	if(parent_state > 0)
863	{
864	current_parent->mergechild->positiveparent = current_parent;
865	}
866
867	if(parent_state < 0)
868	{
869	current_parent->mergechild->negativeparent = current_parent;
870	}
871	}
872	else
873	{
874	out_of_the_game = true;
875	}
876	}
877
878	if(out_of_the_game)
879	{
880	//current_parent->set_state(0,MERGE);
881
882	if((level == number_of_parameters - 1) && (!shouldsplit))
883	{
884	toprow* cur_par_toprow = ((toprow*)current_parent);
885	cur_par_toprow->probability = 0.0;
886
887	//set<simplex*> new_triangulation;
888
889	for(set<simplex*>::iterator s_ref = current_parent->triangulation.begin();s_ref!=current_parent->triangulation.end();s_ref++)
890	{
891	double cur_prob = cur_par_toprow->integrate_simplex((*s_ref),'C');
892
893	cur_par_toprow->probability += cur_prob;
894
895	//new_triangulation.insert(pair<double,set<vertex>>(cur_prob,(t_ref).second));
896	}
897
898	normalization_factor += cur_par_toprow->probability;
899
900	//current_parent->triangulation.clear();
901	//current_parent->triangulation.insert(new_triangulation.begin(),new_triangulation.end());
902	}
903	}
904
905	if(parent_state == 0)
906	{
907	for_merging[level+1].push_back(current_parent);
908	//current_parent->parentconditions.erase(toremove);
909	}
910
911
912	}
913	}
914
915	if(shouldsplit)
916	{
917	current_parent->totallyneutralgrandchildren.insert(sender->totallyneutralchildren.begin(),sender->totallyneutralchildren.end());
918
919	for(set<polyhedron*>::iterator tot_child_ref = sender->totallyneutralchildren.begin();tot_child_ref!=sender->totallyneutralchildren.end();tot_child_ref++)
920	{
921	(*tot_child_ref)->grandparents.insert(current_parent);
922	}
923
924	if(current_parent->totally_neutral == NULL)
925	{
926	current_parent->totally_neutral = sender->totally_neutral;
927	}
928	else
929	{
930	current_parent->totally_neutral = current_parent->totally_neutral && sender->totally_neutral;
931	}
932
933	switch(sender->get_state(SPLIT))
934	{
935	case 1:
936	current_parent->positivechildren.push_back(sender);
937	current_parent->positiveneutralvertices.insert(sender->vertices.begin(),sender->vertices.end());
938	break;
939	case 0:
940	current_parent->neutralchildren.push_back(sender);
941
942	if(level!=0)
943	{
944	current_parent->positiveneutralvertices.insert(sender->positiveneutralvertices.begin(),sender->positiveneutralvertices.end());
945	current_parent->negativeneutralvertices.insert(sender->negativeneutralvertices.begin(),sender->negativeneutralvertices.end());
946	}
947	else
948	{
949	current_parent->positiveneutralvertices.insert(*sender->vertices.begin());
950	current_parent->negativeneutralvertices.insert(*sender->vertices.begin());
951	}
952
953	if(sender->totally_neutral)
954	{
955	current_parent->totallyneutralchildren.insert(sender);
956	}
957
958	break;
959	case -1:
960	current_parent->negativechildren.push_back(sender);
961	current_parent->negativeneutralvertices.insert(sender->vertices.begin(),sender->vertices.end());
962	break;
963	}
964
965	if(is_last)
966	{
967
968	if((current_parent->negativechildren.size()>0&&current_parent->positivechildren.size()>0)
969	\|\|(current_parent->neutralchildren.size()>0&&current_parent->totallyneutralchildren.empty()))
970	{
971	for_splitting[level+1].push_back(current_parent);
972
973	current_parent->set_state(0, SPLIT);
974	}
975	else
976	{
977	if(current_parent->negativechildren.size()>0)
978	{
979	current_parent->set_state(-1, SPLIT);
980
981	if(level == number_of_parameters-1)
982	{
983	((toprow*)current_parent)->condition_sum-=toadd->value;
984	}
985
986	}
987	else if(current_parent->positivechildren.size()>0)
988	{
989	current_parent->set_state(1, SPLIT);
990
991	if(level == number_of_parameters-1)
992	{
993	((toprow*)current_parent)->condition_sum+=toadd->value;
994	}
995	}
996	else
997	{
998	current_parent->raise_multiplicity();
999	current_parent->totally_neutral = true;
1000	current_parent->parentconditions.insert(toadd);
1001	}
1002
1003	((toprow*)current_parent)->condition_order++;
1004
1005	if(level == number_of_parameters - 1 && current_parent->mergechild == NULL)
1006	{
1007	toprow* cur_par_toprow = ((toprow*)current_parent);
1008	cur_par_toprow->probability = 0.0;
1009
1010	//map<double,set<vertex*>> new_triangulation;
1011
1012	for(set<simplex*>::iterator s_ref = current_parent->triangulation.begin();s_ref!=current_parent->triangulation.end();s_ref++)
1013	{
1014	double cur_prob = cur_par_toprow->integrate_simplex((*s_ref),'C');
1015
1016	cur_par_toprow->probability += cur_prob;
1017
1018	//new_triangulation.insert(pair<double,set<vertex>>(cur_prob,(t_ref).second));
1019	}
1020
1021	normalization_factor += cur_par_toprow->probability;
1022
1023	//current_parent->triangulation.clear();
1024	//current_parent->triangulation.insert(new_triangulation.begin(),new_triangulation.end());
1025	}
1026
1027	if(out_of_the_game)
1028	{
1029	current_parent->positivechildren.clear();
1030	current_parent->negativechildren.clear();
1031	current_parent->neutralchildren.clear();
1032	//current_parent->totallyneutralchildren.clear();
1033	current_parent->totallyneutralgrandchildren.clear();
1034	// current_parent->grandparents.clear();
1035	current_parent->positiveneutralvertices.clear();
1036	current_parent->negativeneutralvertices.clear();
1037	current_parent->totally_neutral = NULL;
1038	current_parent->kids_rel_addresses.clear();
1039	}
1040	}
1041	}
1042	}
1043
1044	if(is_last)
1045	{
1046	current_parent->mergechild = NULL;
1047	current_parent->message_counter = 0;
1048
1049	send_state_message(current_parent,toadd,toremove,level+1);
1050	}
1051
1052	}
1053
1054	sender->totallyneutralchildren.clear();
1055	}
1056	}
1057
1058	public:
1059	c_statistic statistic;
1060
1061	vertex* minimal_vertex;
1062
1063	double min_ll;
1064
1065	double log_nc;
1066
1067
1068
1069	vector<multiset<my_ivec>> correction_factors;
1070
1071	int number_of_parameters;
1072
1073	/// A default constructor creates an emlig with predefined statistic representing only the range of the given
1074	/// parametric space, where the number of parameters of the needed model is given as a parameter to the constructor.
1075	emlig(int number_of_parameters, double soft_prior_parameter)
1076	{
1077	this->number_of_parameters = number_of_parameters;
1078
1079	condition_order = number_of_parameters+2;
1080
1081	create_statistic(number_of_parameters, soft_prior_parameter);
1082
1083	//step_me(10);
1084
1085	min_ll = numeric_limits<double>::max();
1086
1087
1088	double normalization_factor = 0;
1089	int counter = 0;
1090	for(polyhedron* top_ref = statistic.rows[number_of_parameters];top_ref!=statistic.get_end();top_ref=top_ref->next_poly)
1091	{
1092	counter++;
1093	toprow* cur_toprow = (toprow*)top_ref;
1094
1095	set<simplex*>::iterator cur_simplex = cur_toprow->triangulation.begin();
1096	normalization_factor += cur_toprow->integrate_simplex(*cur_simplex,'X');
1097	}
1098
1099	log_nc = log(normalization_factor) + logfact(condition_order-number_of_parameters-2)-(condition_order-number_of_parameters-2)*log(2.0);
1100
1101	/*
1102	cout << "part1: " << log(normalization_factor) << endl;
1103	cout << "part2: " << logfact(condition_order-number_of_parameters-2) << endl;
1104	pause(1);
1105	*/
1106
1107
1108	}
1109
1110	/// A constructor for creating an emlig when the user wants to create the statistic by himself. The creation of a
1111	/// statistic is needed outside the constructor. Used for a user defined prior distribution on the parameters.
1112	emlig(c_statistic statistic, int condition_order)
1113	{
1114	this->statistic = statistic;
1115
1116	min_ll = numeric_limits<double>::max();
1117
1118	this->condition_order = condition_order;
1119	}
1120
1121
1122	void step_me(int marker)
1123	{
1124	set<int> orders;
1125
1126	for(int i = 0;i<statistic.size();i++)
1127	{
1128	//int zero = 0;
1129	//int one = 0;
1130	//int two = 0;
1131
1132	for(polyhedron* horiz_ref = statistic.rows[i];horiz_ref!=statistic.get_end();horiz_ref=horiz_ref->next_poly)
1133	{
1134
1135
1136	if(i==statistic.size()-1)
1137	{
1138	orders.insert(((toprow*)horiz_ref)->condition_order);
1139
1140	/*
1141	cout << ((toprow)horiz_ref)->condition_sum << " " << ((toprow)horiz_ref)->probability << endl;
1142	cout << "Condition: " << ((toprow*)horiz_ref)->condition_sum << endl;
1143	cout << "Order:" << ((toprow)horiz_ref)->condition_order << endl;/
1144	}
1145
1146
1147	// cout << "Stepped." << endl;
1148
1149	if(marker==101)
1150	{
1151	if(!(horiz_ref).negativechildren.empty()\|\|!(horiz_ref).positivechildren.empty()\|\|!(horiz_ref).neutralchildren.empty()\|\|!(horiz_ref).kids_rel_addresses.empty()\|\|!(horiz_ref).mergechild==NULL\|\|!(horiz_ref).negativeneutralvertices.empty())
1152	{
1153	cout << "Cleaning error!" << endl;
1154	}
1155
1156	}
1157
1158	/*
1159	for(set<simplex>::iterator sim_ref = (horiz_ref).triangulation.begin();sim_ref!=(*horiz_ref).triangulation.end();sim_ref++)
1160	{
1161	if((*sim_ref)->vertices.size()!=i+1)
1162	{
1163	cout << "Something is wrong." << endl;
1164	}
1165	}
1166	*/
1167
1168	/*
1169	if(i==0)
1170	{
1171	cout << ((vertex*)horiz_ref)->get_coordinates() << endl;
1172	}
1173	*/
1174
1175	/*
1176	char* string = "Checkpoint";
1177
1178
1179	if((*horiz_ref).parentconditions.size()==0)
1180	{
1181	zero++;
1182	}
1183	else if((*horiz_ref).parentconditions.size()==1)
1184	{
1185	one++;
1186	}
1187	else
1188	{
1189	two++;
1190	}
1191	*/
1192
1193	}
1194	}
1195
1196
1197	/*
1198	list<vec> table_entries;
1199	for(polyhedron* horiz_ref = statistic.rows[statistic.size()-1];horiz_ref!=statistic.row_ends[statistic.size()-1];horiz_ref=horiz_ref->next_poly)
1200	{
1201	toprow current_toprow = (toprow)(horiz_ref);
1202	for(list<set<vertex*>>::iterator tri_ref = current_toprow->triangulation.begin();tri_ref!=current_toprow->triangulation.end();tri_ref++)
1203	{
1204	for(set<vertex>::iterator vert_ref = (tri_ref).begin();vert_ref!=(*tri_ref).end();vert_ref++)
1205	{
1206	vec table_entry = vec();
1207
1208	table_entry.ins(0,(vert_ref)->get_coordinates()current_toprow->condition.get(1,current_toprow->condition.size()-1)-current_toprow->condition.get(0,0));
1209
1210	table_entry.ins(0,(*vert_ref)->get_coordinates());
1211
1212	table_entries.push_back(table_entry);
1213	}
1214	}
1215	}
1216
1217	unique(table_entries.begin(),table_entries.end());
1218
1219
1220
1221	for(list<vec>::iterator entry_ref = table_entries.begin();entry_ref!=table_entries.end();entry_ref++)
1222	{
1223	ofstream myfile;
1224	myfile.open("robust_data.txt", ios::out \| ios::app);
1225	if (myfile.is_open())
1226	{
1227	for(int i = 0;i<(*entry_ref).size();i++)
1228	{
1229	myfile << (*entry_ref)[i] << ";";
1230	}
1231	myfile << endl;
1232
1233	myfile.close();
1234	}
1235	else
1236	{
1237	cout << "File problem." << endl;
1238	}
1239	}
1240	*/
1241
1242
1243	return;
1244	}
1245
1246	int statistic_rowsize(int row)
1247	{
1248	return statistic.row_size(row);
1249	}
1250
1251	void add_condition(vec toadd)
1252	{
1253	vec null_vector = "";
1254
1255	add_and_remove_condition(toadd, null_vector);
1256	}
1257
1258
1259	void remove_condition(vec toremove)
1260	{
1261	vec null_vector = "";
1262
1263	add_and_remove_condition(null_vector, toremove);
1264	}
1265
1266	void add_and_remove_condition(vec toadd, vec toremove)
1267	{
1268
1269	//step_me(0);
1270	normalization_factor = 0;
1271	min_ll = numeric_limits<double>::max();
1272
1273	bool should_remove = (toremove.size() != 0);
1274	bool should_add = (toadd.size() != 0);
1275
1276	if(should_remove)
1277	{
1278	condition_order--;
1279	}
1280
1281	if(should_add)
1282	{
1283	condition_order++;
1284	}
1285
1286	for_splitting.clear();
1287	for_merging.clear();
1288
1289	for(int i = 0;i<statistic.size();i++)
1290	{
1291	list<polyhedron*> empty_split;
1292	list<polyhedron*> empty_merge;
1293
1294	for_splitting.push_back(empty_split);
1295	for_merging.push_back(empty_merge);
1296	}
1297
1298	list<condition*>::iterator toremove_ref = conditions.end();
1299	bool condition_should_be_added = should_add;
1300
1301	for(list<condition*>::iterator ref = conditions.begin();ref!=conditions.end();ref++)
1302	{
1303	if(should_remove)
1304	{
1305	if((*ref)->value == toremove)
1306	{
1307	if((*ref)->multiplicity>1)
1308	{
1309	(*ref)->multiplicity--;
1310
1311	alter_toprow_conditions(*ref,false);
1312
1313	should_remove = false;
1314	}
1315	else
1316	{
1317	toremove_ref = ref;
1318	}
1319	}
1320	}
1321
1322	if(should_add)
1323	{
1324	if((*ref)->value == toadd)
1325	{
1326	(*ref)->multiplicity++;
1327
1328	alter_toprow_conditions(*ref,true);
1329
1330	should_add = false;
1331
1332	condition_should_be_added = false;
1333	}
1334	}
1335	}
1336
1337	condition* condition_to_remove = NULL;
1338
1339	if(toremove_ref!=conditions.end())
1340	{
1341	condition_to_remove = *toremove_ref;
1342	conditions.erase(toremove_ref);
1343	}
1344
1345	condition* condition_to_add = NULL;
1346
1347	if(condition_should_be_added)
1348	{
1349	condition* new_condition = new condition(toadd);
1350
1351	conditions.push_back(new_condition);
1352	condition_to_add = new_condition;
1353	}
1354
1355	for(polyhedron* horizontal_position = statistic.rows[0];horizontal_position!=statistic.get_end();horizontal_position=horizontal_position->next_poly)
1356	{
1357	vertex* current_vertex = (vertex*)horizontal_position;
1358
1359	if(should_add\|\|should_remove)
1360	{
1361	vec appended_coords = current_vertex->get_coordinates();
1362	appended_coords.ins(0,-1.0);
1363
1364	if(should_add)
1365	{
1366	double local_condition = 0;// = toadd*(appended_coords.first/=appended_coords.second);
1367
1368	local_condition = appended_coords*toadd;
1369
1370	// cout << "Vertex multiplicity: "<< current_vertex->get_multiplicity() << endl;
1371
1372	current_vertex->set_state(local_condition,SPLIT);
1373
1374	/// \TODO There should be a rounding error tolerance used here to insure we are not having too many points because of rounding error.
1375	if(local_condition == 0)
1376	{
1377	cout << "Condition to add: " << toadd << endl;
1378	cout << "Vertex coords: " << appended_coords << endl;
1379
1380	current_vertex->totally_neutral = true;
1381
1382	current_vertex->raise_multiplicity();
1383	current_vertex->parentconditions.insert(condition_to_add);
1384	}
1385	else
1386	{
1387	current_vertex->totally_neutral = false;
1388	}
1389	}
1390
1391	if(should_remove)
1392	{
1393	set<condition*>::iterator cond_ref;
1394
1395	for(cond_ref = current_vertex->parentconditions.begin();cond_ref!=current_vertex->parentconditions.end();cond_ref++)
1396	{
1397	if(*cond_ref == condition_to_remove)
1398	{
1399	break;
1400	}
1401	}
1402
1403	if(cond_ref!=current_vertex->parentconditions.end())
1404	{
1405	current_vertex->parentconditions.erase(cond_ref);
1406	current_vertex->set_state(0,MERGE);
1407	for_merging[0].push_back(current_vertex);
1408	}
1409	else
1410	{
1411	double local_condition = toremove*appended_coords;
1412	current_vertex->set_state(local_condition,MERGE);
1413	}
1414	}
1415	}
1416
1417	send_state_message(current_vertex, condition_to_add, condition_to_remove, 0);
1418
1419	}
1420
1421	// step_me(1);
1422
1423	if(should_remove)
1424	{
1425	/*
1426	for(int i = 0;i<for_merging.size();i++)
1427	{
1428	for(list<polyhedron*>::iterator merge_ref = for_merging[i].begin();merge_ref!=for_merging[i].end();merge_ref++)
1429	{
1430
1431	for(list<polyhedron>::iterator par_ref = (merge_ref)->children.begin();par_ref!=(*merge_ref)->children.end();par_ref++)
1432	{
1433	if(find((par_ref)->parents.begin(),(par_ref)->parents.end(),(merge_ref))==(par_ref)->parents.end())
1434	{
1435	cout << "Parent/child relations are not matched!" << endl;
1436	}
1437	}
1438
1439	//cout << (*merge_ref)->get_state(MERGE) << ",";
1440	}
1441
1442	// cout << endl;
1443	}
1444	*/
1445
1446
1447
1448	cout << "Merging." << endl;
1449
1450	set<vertex*> vertices_to_be_reduced;
1451
1452	int k = 1;
1453
1454	for(vector<list<polyhedron*>>::iterator vert_ref = for_merging.begin();vert_ref<for_merging.end();vert_ref++)
1455	{
1456	for(list<polyhedron>::iterator merge_ref = (vert_ref).begin();merge_ref!=(*vert_ref).end();merge_ref++)
1457	{
1458	if((*merge_ref)->get_multiplicity()>1)
1459	{
1460	(*merge_ref)->parentconditions.erase(condition_to_remove);
1461
1462	if(k==1)
1463	{
1464	vertices_to_be_reduced.insert((vertex)(merge_ref));
1465	}
1466	else
1467	{
1468	(*merge_ref)->lower_multiplicity();
1469	}
1470
1471	if((merge_ref)->get_state(SPLIT)!=0\|\|(merge_ref)->totally_neutral)
1472	{
1473	(*merge_ref)->positivechildren.clear();
1474	(*merge_ref)->negativechildren.clear();
1475	(*merge_ref)->neutralchildren.clear();
1476	(*merge_ref)->totallyneutralgrandchildren.clear();
1477	(*merge_ref)->positiveneutralvertices.clear();
1478	(*merge_ref)->negativeneutralvertices.clear();
1479	(*merge_ref)->totally_neutral = NULL;
1480	(*merge_ref)->kids_rel_addresses.clear();
1481	}
1482	}
1483	else
1484	{
1485	bool will_be_split = false;
1486
1487	toprow* current_positive = (toprow)(merge_ref)->positiveparent;
1488	toprow* current_negative = (toprow)(merge_ref)->negativeparent;
1489
1490	if(current_positive->totally_neutral!=current_negative->totally_neutral)
1491	{
1492	throw new exception("Both polyhedrons must be totally neutral if they should be merged!");
1493	}
1494
1495	//current_positive->condition_sum -= toremove;
1496	//current_positive->condition_order--;
1497
1498	current_positive->parentconditions.erase(condition_to_remove);
1499
1500	current_positive->children.insert(current_positive->children.end(),current_negative->children.begin(),current_negative->children.end());
1501	current_positive->children.remove(*merge_ref);
1502
1503	for(list<polyhedron*>::iterator child_ref = current_negative->children.begin();child_ref!=current_negative->children.end();child_ref++)
1504	{
1505	(*child_ref)->parents.remove(current_negative);
1506	(*child_ref)->parents.push_back(current_positive);
1507	}
1508
1509	// current_positive->parents.insert(current_positive->parents.begin(),current_negative->parents.begin(),current_negative->parents.end());
1510	// unique(current_positive->parents.begin(),current_positive->parents.end());
1511
1512	for(list<polyhedron*>::iterator parent_ref = current_negative->parents.begin();parent_ref!=current_negative->parents.end();parent_ref++)
1513	{
1514	(*parent_ref)->children.remove(current_negative);
1515
1516	switch(current_negative->get_state(SPLIT))
1517	{
1518	case -1:
1519	(*parent_ref)->negativechildren.remove(current_negative);
1520	break;
1521	case 0:
1522	(*parent_ref)->neutralchildren.remove(current_negative);
1523	break;
1524	case 1:
1525	(*parent_ref)->positivechildren.remove(current_negative);
1526	break;
1527	}
1528	//(*parent_ref)->children.push_back(current_positive);
1529	}
1530
1531	if(current_positive->get_state(SPLIT)!=0&&current_negative->get_state(SPLIT)==0)
1532	{
1533	for(list<polyhedron*>::iterator parent_ref = current_positive->parents.begin();parent_ref!=current_positive->parents.end();parent_ref++)
1534	{
1535	if(current_positive->get_state(SPLIT)==1)
1536	{
1537	(*parent_ref)->positivechildren.remove(current_positive);
1538	}
1539	else
1540	{
1541	(*parent_ref)->negativechildren.remove(current_positive);
1542	}
1543
1544	(*parent_ref)->neutralchildren.push_back(current_positive);
1545	}
1546
1547	current_positive->set_state(0,SPLIT);
1548	for_splitting[k].push_back(current_positive);
1549
1550	will_be_split = true;
1551	}
1552
1553	if((current_positive->get_state(SPLIT)==0&&!current_positive->totally_neutral)\|\|(current_negative->get_state(SPLIT)==0&&!current_negative->totally_neutral))
1554	{
1555	current_positive->negativechildren.insert(current_positive->negativechildren.end(),current_negative->negativechildren.begin(),current_negative->negativechildren.end());
1556
1557	current_positive->positivechildren.insert(current_positive->positivechildren.end(),current_negative->positivechildren.begin(),current_negative->positivechildren.end());
1558
1559	current_positive->neutralchildren.insert(current_positive->neutralchildren.end(),current_negative->neutralchildren.begin(),current_negative->neutralchildren.end());
1560
1561	switch((*merge_ref)->get_state(SPLIT))
1562	{
1563	case -1:
1564	current_positive->negativechildren.remove(*merge_ref);
1565	break;
1566	case 0:
1567	current_positive->neutralchildren.remove(*merge_ref);
1568	break;
1569	case 1:
1570	current_positive->positivechildren.remove(*merge_ref);
1571	break;
1572	}
1573
1574	/*
1575	current_positive->totallyneutralchildren.insert(current_negative->totallyneutralchildren.begin(),current_negative->totallyneutralchildren.end());
1576
1577	current_positive->totallyneutralchildren.erase(*merge_ref);
1578	*/
1579
1580	current_positive->totallyneutralgrandchildren.insert(current_negative->totallyneutralgrandchildren.begin(),current_negative->totallyneutralgrandchildren.end());
1581
1582	current_positive->negativeneutralvertices.insert(current_negative->negativeneutralvertices.begin(),current_negative->negativeneutralvertices.end());
1583	current_positive->positiveneutralvertices.insert(current_negative->positiveneutralvertices.begin(),current_negative->positiveneutralvertices.end());
1584
1585	will_be_split = true;
1586	}
1587	else
1588	{
1589	current_positive->positivechildren.clear();
1590	current_positive->negativechildren.clear();
1591	current_positive->neutralchildren.clear();
1592	// current_positive->totallyneutralchildren.clear();
1593	current_positive->totallyneutralgrandchildren.clear();
1594	current_positive->positiveneutralvertices.clear();
1595	current_positive->negativeneutralvertices.clear();
1596	current_positive->totally_neutral = NULL;
1597	current_positive->kids_rel_addresses.clear();
1598	}
1599
1600	current_positive->vertices.insert(current_negative->vertices.begin(),current_negative->vertices.end());
1601
1602
1603	for(set<vertex>::iterator vert_ref = (merge_ref)->vertices.begin();vert_ref!=(*merge_ref)->vertices.end();vert_ref++)
1604	{
1605	if((*vert_ref)->get_multiplicity()==1)
1606	{
1607	current_positive->vertices.erase(*vert_ref);
1608
1609	if(will_be_split)
1610	{
1611	current_positive->negativeneutralvertices.erase(*vert_ref);
1612	current_positive->positiveneutralvertices.erase(*vert_ref);
1613	}
1614	}
1615	}
1616
1617	if(current_negative->get_state(SPLIT)==0&&!current_negative->totally_neutral)
1618	{
1619	for_splitting[k].remove(current_negative);
1620	}
1621
1622
1623
1624	if(current_positive->totally_neutral)
1625	{
1626	for(set<polyhedron*>::iterator grand_ref = current_negative->grandparents.begin();grand_ref!=current_negative->grandparents.end();grand_ref++)
1627	{
1628	(*grand_ref)->totallyneutralgrandchildren.erase(current_negative);
1629	(*grand_ref)->totallyneutralgrandchildren.insert(current_positive);
1630	}
1631	}
1632
1633	current_positive->grandparents.clear();
1634
1635	normalization_factor += current_positive->triangulate(k==for_splitting.size()-1 && !will_be_split);
1636
1637	statistic.delete_polyhedron(k,current_negative);
1638
1639	delete current_negative;
1640
1641	for(list<polyhedron>::iterator child_ref = (merge_ref)->children.begin();child_ref!=(*merge_ref)->children.end();child_ref++)
1642	{
1643	(child_ref)->parents.remove(merge_ref);
1644	}
1645
1646	/*
1647	for(list<polyhedron>::iterator parent_ref = (merge_ref)->parents.begin();parent_ref!=(*merge_ref)->parents.end();parent_ref++)
1648	{
1649	(parent_ref)->positivechildren.remove(merge_ref);
1650	(parent_ref)->negativechildren.remove(merge_ref);
1651	(parent_ref)->neutralchildren.remove(merge_ref);
1652	(parent_ref)->children.remove(merge_ref);
1653	}
1654	*/
1655
1656	for(set<polyhedron>::iterator grand_ch_ref = (merge_ref)->totallyneutralgrandchildren.begin();grand_ch_ref!=(*merge_ref)->totallyneutralgrandchildren.end();grand_ch_ref++)
1657	{
1658	(grand_ch_ref)->grandparents.erase(merge_ref);
1659	}
1660
1661
1662	for(set<polyhedron>::iterator grand_p_ref = (merge_ref)->grandparents.begin();grand_p_ref!=(*merge_ref)->grandparents.end();grand_p_ref++)
1663	{
1664	(grand_p_ref)->totallyneutralgrandchildren.erase(merge_ref);
1665	}
1666
1667	statistic.delete_polyhedron(k-1,*merge_ref);
1668
1669	for_splitting[k-1].remove(*merge_ref);
1670	//for_merging[k].remove(*loc_merge_ref);
1671
1672	if(k==1)
1673	{
1674	vertices_to_be_reduced.insert((vertex)(merge_ref));
1675	}
1676	/*
1677	else
1678	{
1679	delete (*loc_merge_ref);
1680	}
1681	*/
1682	}
1683	}
1684
1685	k++;
1686
1687	}
1688
1689	for(int i = 1;i<for_merging.size();i++)
1690	{
1691	for(list<polyhedron*>::iterator merge_ref = for_merging[i].begin();merge_ref!=for_merging[i].end();merge_ref++)
1692	{
1693	delete (*merge_ref);
1694	}
1695	}
1696
1697	for(set<vertex*>::iterator vert_ref = vertices_to_be_reduced.begin();vert_ref!=vertices_to_be_reduced.end();vert_ref++)
1698	{
1699	if((*vert_ref)->get_multiplicity()>1)
1700	{
1701	(*vert_ref)->lower_multiplicity();
1702	}
1703	else
1704	{
1705	delete (*vert_ref);
1706	}
1707	}
1708
1709	delete condition_to_remove;
1710	}
1711
1712
1713	vector<int> sizevector;
1714	for(int s = 0;s<statistic.size();s++)
1715	{
1716	sizevector.push_back(statistic.row_size(s));
1717	cout << statistic.row_size(s) << ", ";
1718	}
1719
1720
1721	cout << endl;
1722
1723	if(should_add)
1724	{
1725	cout << "Splitting." << endl;
1726
1727	int k = 1;
1728	int counter = 0;
1729
1730	vector<list<polyhedron*>>::iterator beginning_ref = ++for_splitting.begin();
1731
1732	for(vector<list<polyhedron*>>::iterator vert_ref = beginning_ref;vert_ref<for_splitting.end();vert_ref++)
1733	{
1734
1735	for(list<polyhedron*>::reverse_iterator split_ref = vert_ref->rbegin();split_ref != vert_ref->rend();split_ref++)
1736	{
1737	counter++;
1738
1739	polyhedron* new_totally_neutral_child;
1740
1741	polyhedron* current_polyhedron = (*split_ref);
1742
1743	if(vert_ref == beginning_ref)
1744	{
1745	vec coordinates1 = ((vertex)((current_polyhedron->children.begin())))->get_coordinates();
1746	vec coordinates2 = ((vertex)((++current_polyhedron->children.begin())))->get_coordinates();
1747
1748	vec extended_coord2 = coordinates2;
1749	extended_coord2.ins(0,-1.0);
1750
1751	double t = (-toaddextended_coord2)/(toadd(1,toadd.size()-1)(coordinates1-coordinates2));
1752
1753	vec new_coordinates = (1-t)coordinates2+tcoordinates1;
1754
1755	// cout << "c1:" << coordinates1 << endl << "c2:" << coordinates2 << endl << "nc:" << new_coordinates << endl;
1756
1757	vertex* neutral_vertex = new vertex(new_coordinates);
1758
1759	new_totally_neutral_child = neutral_vertex;
1760	}
1761	else
1762	{
1763	toprow* neutral_toprow = new toprow();
1764
1765	neutral_toprow->condition_sum = ((toprow*)current_polyhedron)->condition_sum; // tohle tu bylo driv: zeros(number_of_parameters+1);
1766	neutral_toprow->condition_order = ((toprow*)current_polyhedron)->condition_order+1;
1767
1768	new_totally_neutral_child = neutral_toprow;
1769	}
1770
1771	new_totally_neutral_child->parentconditions.insert(current_polyhedron->parentconditions.begin(),current_polyhedron->parentconditions.end());
1772	new_totally_neutral_child->parentconditions.insert(condition_to_add);
1773
1774	new_totally_neutral_child->my_emlig = this;
1775
1776	new_totally_neutral_child->children.insert(new_totally_neutral_child->children.end(),
1777	current_polyhedron->totallyneutralgrandchildren.begin(),
1778	current_polyhedron->totallyneutralgrandchildren.end());
1779
1780
1781
1782	// cout << ((toprow*)current_polyhedron)->condition << endl << toadd << endl;
1783	vec cur_pos_condition = ((toprow*)current_polyhedron)->condition_sum;
1784	vec cur_neg_condition = ((toprow*)current_polyhedron)->condition_sum;
1785
1786	if(k == number_of_parameters)
1787	{
1788	cur_pos_condition = cur_pos_condition + toadd;
1789	cur_neg_condition = cur_neg_condition - toadd;
1790	}
1791
1792	toprow* positive_poly = new toprow(cur_pos_condition, ((toprow*)current_polyhedron)->condition_order+1);
1793	toprow* negative_poly = new toprow(cur_neg_condition, ((toprow*)current_polyhedron)->condition_order+1);
1794
1795	positive_poly->my_emlig = this;
1796	negative_poly->my_emlig = this;
1797
1798	positive_poly->parentconditions.insert(current_polyhedron->parentconditions.begin(),current_polyhedron->parentconditions.end());
1799	negative_poly->parentconditions.insert(current_polyhedron->parentconditions.begin(),current_polyhedron->parentconditions.end());
1800
1801	for(set<polyhedron*>::iterator grand_ref = current_polyhedron->totallyneutralgrandchildren.begin(); grand_ref != current_polyhedron->totallyneutralgrandchildren.end();grand_ref++)
1802	{
1803	(*grand_ref)->parents.push_back(new_totally_neutral_child);
1804
1805	// tohle tu nebylo. ma to tu byt?
1806	//positive_poly->totallyneutralgrandchildren.insert(*grand_ref);
1807	//negative_poly->totallyneutralgrandchildren.insert(*grand_ref);
1808
1809	//(*grand_ref)->grandparents.insert(positive_poly);
1810	//(*grand_ref)->grandparents.insert(negative_poly);
1811
1812	new_totally_neutral_child->vertices.insert((grand_ref)->vertices.begin(),(grand_ref)->vertices.end());
1813	}
1814
1815	positive_poly->children.push_back(new_totally_neutral_child);
1816	negative_poly->children.push_back(new_totally_neutral_child);
1817
1818
1819	for(list<polyhedron*>::iterator parent_ref = current_polyhedron->parents.begin();parent_ref!=current_polyhedron->parents.end();parent_ref++)
1820	{
1821	(*parent_ref)->totallyneutralgrandchildren.insert(new_totally_neutral_child);
1822	// new_totally_neutral_child->grandparents.insert(*parent_ref);
1823
1824	(*parent_ref)->neutralchildren.remove(current_polyhedron);
1825	(*parent_ref)->children.remove(current_polyhedron);
1826
1827	(*parent_ref)->children.push_back(positive_poly);
1828	(*parent_ref)->children.push_back(negative_poly);
1829	(*parent_ref)->positivechildren.push_back(positive_poly);
1830	(*parent_ref)->negativechildren.push_back(negative_poly);
1831	}
1832
1833	positive_poly->parents.insert(positive_poly->parents.end(),
1834	current_polyhedron->parents.begin(),
1835	current_polyhedron->parents.end());
1836
1837	negative_poly->parents.insert(negative_poly->parents.end(),
1838	current_polyhedron->parents.begin(),
1839	current_polyhedron->parents.end());
1840
1841
1842
1843	new_totally_neutral_child->parents.push_back(positive_poly);
1844	new_totally_neutral_child->parents.push_back(negative_poly);
1845
1846	for(list<polyhedron*>::iterator child_ref = current_polyhedron->positivechildren.begin();child_ref!=current_polyhedron->positivechildren.end();child_ref++)
1847	{
1848	(*child_ref)->parents.remove(current_polyhedron);
1849	(*child_ref)->parents.push_back(positive_poly);
1850	}
1851
1852	positive_poly->children.insert(positive_poly->children.end(),
1853	current_polyhedron->positivechildren.begin(),
1854	current_polyhedron->positivechildren.end());
1855
1856	for(list<polyhedron*>::iterator child_ref = current_polyhedron->negativechildren.begin();child_ref!=current_polyhedron->negativechildren.end();child_ref++)
1857	{
1858	(*child_ref)->parents.remove(current_polyhedron);
1859	(*child_ref)->parents.push_back(negative_poly);
1860	}
1861
1862	negative_poly->children.insert(negative_poly->children.end(),
1863	current_polyhedron->negativechildren.begin(),
1864	current_polyhedron->negativechildren.end());
1865
1866	positive_poly->vertices.insert(current_polyhedron->positiveneutralvertices.begin(),current_polyhedron->positiveneutralvertices.end());
1867	positive_poly->vertices.insert(new_totally_neutral_child->vertices.begin(),new_totally_neutral_child->vertices.end());
1868
1869	negative_poly->vertices.insert(current_polyhedron->negativeneutralvertices.begin(),current_polyhedron->negativeneutralvertices.end());
1870	negative_poly->vertices.insert(new_totally_neutral_child->vertices.begin(),new_totally_neutral_child->vertices.end());
1871
1872	new_totally_neutral_child->triangulate(false);
1873
1874	normalization_factor += positive_poly->triangulate(k==for_splitting.size()-1);
1875	normalization_factor += negative_poly->triangulate(k==for_splitting.size()-1);
1876
1877	statistic.append_polyhedron(k-1, new_totally_neutral_child);
1878
1879
1880
1881	statistic.insert_polyhedron(k, positive_poly, current_polyhedron);
1882	statistic.insert_polyhedron(k, negative_poly, current_polyhedron);
1883
1884	statistic.delete_polyhedron(k, current_polyhedron);
1885
1886	delete current_polyhedron;
1887	}
1888
1889	k++;
1890	}
1891	}
1892
1893	/*
1894	vector<int> sizevector;
1895	//sizevector.clear();
1896	for(int s = 0;s<statistic.size();s++)
1897	{
1898	sizevector.push_back(statistic.row_size(s));
1899	cout << statistic.row_size(s) << ", ";
1900	}
1901
1902	cout << endl;
1903	*/
1904
1905	// cout << "Normalization factor: " << normalization_factor << endl;
1906
1907	log_nc = log(normalization_factor) + logfact(condition_order-number_of_parameters-2)-(condition_order-number_of_parameters-2)*log(2.0);
1908
1909	if(condition_order == 20)
1910	step_me(88);
1911
1912	//cout << "Factorial factor: " << condition_order-number_of_parameters-2 << endl;
1913
1914	/*
1915	cout << "part1: " << log(normalization_factor) << endl;
1916	cout << "part2: " << logfact(condition_order-number_of_parameters-2) << endl;
1917	pause(1);
1918	*/
1919
1920
1921	/*
1922	for(polyhedron* topr_ref = statistic.rows[statistic.size()-1];topr_ref!=statistic.row_ends[statistic.size()-1]->next_poly;topr_ref=topr_ref->next_poly)
1923	{
1924	cout << ((toprow*)topr_ref)->condition << endl;
1925	}
1926	*/
1927
1928	// step_me(101);
1929
1930	}
1931
1932	void set_correction_factors(int order)
1933	{
1934	for(int remaining_order = correction_factors.size();remaining_order<order;remaining_order++)
1935	{
1936	multiset<my_ivec> factor_templates;
1937	multiset<my_ivec> final_factors;
1938
1939	my_ivec orig_template = my_ivec();
1940
1941	for(int i = 1;i<number_of_parameters-remaining_order+1;i++)
1942	{
1943	bool in_cycle = false;
1944	for(int j = 0;j<=remaining_order;j++) {
1945
1946	multiset<my_ivec>::iterator fac_ref = factor_templates.begin();
1947
1948	do
1949	{
1950	my_ivec current_template;
1951	if(!in_cycle)
1952	{
1953	current_template = orig_template;
1954	in_cycle = true;
1955	}
1956	else
1957	{
1958	current_template = (*fac_ref);
1959	fac_ref++;
1960	}
1961
1962	current_template.ins(current_template.size(),i);
1963
1964	// cout << "template:" << current_template << endl;
1965
1966	if(current_template.size()==remaining_order+1)
1967	{
1968	final_factors.insert(current_template);
1969	}
1970	else
1971	{
1972	factor_templates.insert(current_template);
1973	}
1974	}
1975	while(fac_ref!=factor_templates.end());
1976	}
1977	}
1978
1979	correction_factors.push_back(final_factors);
1980
1981	}
1982	}
1983
1984	pair<vec,simplex*> choose_simplex()
1985	{
1986	double rnumber = randu();
1987
1988	// cout << "RND:" << rnumber << endl;
1989
1990	// This could be more efficient (log n), but map::upper_bound() doesn't let me dereference returned iterator
1991	double prob_sum = 0;
1992	toprow* sampled_toprow;
1993	for(polyhedron* top_ref = statistic.rows[number_of_parameters];top_ref!=statistic.end_poly;top_ref=top_ref->next_poly)
1994	{
1995	// cout << "CDF:"<< (*top_ref).first << endl;
1996
1997	toprow* current_toprow = ((toprow*)top_ref);
1998
1999	prob_sum += current_toprow->probability;
2000
2001	if(prob_sum >= rnumber*normalization_factor)
2002	{
2003	sampled_toprow = (toprow*)top_ref;
2004	break;
2005	}
2006	else
2007	{
2008	if(top_ref->next_poly==statistic.end_poly)
2009	{
2010	cout << "Error.";
2011	}
2012	}
2013	}
2014
2015	//// cout << "Toprow/Count: " << toprow_count << "/" << ordered_toprows.size() << endl;
2016	// cout << &sampled_toprow << ";";
2017
2018	rnumber = randu();
2019
2020	set<simplex*>::iterator s_ref;
2021	prob_sum = 0;
2022	for(s_ref = sampled_toprow->triangulation.begin();s_ref!=sampled_toprow->triangulation.end();s_ref++)
2023	{
2024	prob_sum += (*s_ref)->probability;
2025
2026	if(prob_sum/sampled_toprow->probability >= rnumber)
2027	break;
2028	}
2029
2030	return pair<vec,simplex>(sampled_toprow->condition_sum,s_ref);
2031	}
2032
2033	pair<double,double> choose_sigma(simplex* sampled_simplex)
2034	{
2035	double sigma = 0;
2036	double pg_sum;
2037	double ng_sum;
2038	do
2039	{
2040	double rnumber = randu();
2041
2042
2043	double sum_g = 0;
2044	for(int i = 0;i<sampled_simplex->positive_gamma_parameters.size();i++)
2045	{
2046	for(multimap<double,double>::iterator g_ref = sampled_simplex->positive_gamma_parameters[i].begin();g_ref != sampled_simplex->positive_gamma_parameters[i].end();g_ref++)
2047	{
2048	sum_g += (*g_ref).first/sampled_simplex->positive_gamma_sum;
2049
2050
2051	if(sum_g>rnumber)
2052	{
2053	//itpp::Gamma_RNG* gamma = new itpp::Gamma_RNG(conditions.size()-number_of_parameters,1/(*g_ref).second);
2054	//sigma = 1/(*gamma)();
2055
2056	GamRNG.setup(conditions.size()-number_of_parameters,(*g_ref).second);
2057
2058	sigma = 1/GamRNG();
2059
2060	// cout << "Sigma mean: " << (*g_ref).second/(conditions.size()-number_of_parameters-1) << endl;
2061	break;
2062	}
2063	}
2064
2065	if(sigma!=0)
2066	{
2067	break;
2068	}
2069	}
2070
2071	rnumber = randu();
2072
2073	pg_sum = 0;
2074	for(vector<multimap<double,double>>::iterator v_ref = sampled_simplex->positive_gamma_parameters.begin();v_ref!=sampled_simplex->positive_gamma_parameters.end();v_ref++)
2075	{
2076	for(multimap<double,double>::iterator pg_ref = (v_ref).begin();pg_ref!=(v_ref).end();pg_ref++)
2077	{
2078	pg_sum += exp((sampled_simplex->min_beta-(pg_ref).second)/sigma)pow((pg_ref).second/sigma,(int)conditions.size())(pg_ref).second/fact(conditions.size())(*pg_ref).first;
2079	}
2080	}
2081
2082	ng_sum = 0;
2083	for(vector<multimap<double,double>>::iterator v_ref = sampled_simplex->negative_gamma_parameters.begin();v_ref!=sampled_simplex->negative_gamma_parameters.end();v_ref++)
2084	{
2085	for(multimap<double,double>::iterator ng_ref = (v_ref).begin();ng_ref!=(v_ref).end();ng_ref++)
2086	{
2087	ng_sum += exp((sampled_simplex->min_beta-(ng_ref).second)/sigma)pow((ng_ref).second/sigma,(int)conditions.size())(ng_ref).second/fact(conditions.size())(*ng_ref).first;
2088	}
2089	}
2090	}
2091	while(pg_sum-ng_sum<0);
2092
2093	return pair<double,double>((pg_sum-ng_sum)/pg_sum,sigma);
2094	}
2095
2096	mat sample_mat(int n)
2097	{
2098
2099	/// \TODO tady je to spatne, tady nesmi byt conditions.size(), viz RARX.bayes()
2100	if(conditions.size()-2-number_of_parameters>=0)
2101	{
2102	mat sample_mat;
2103	map<double,toprow*> ordered_toprows;
2104	double sum_a = 0;
2105
2106	//cout << "Likelihoods of toprows:" << endl;
2107
2108	for(polyhedron* top_ref = statistic.rows[number_of_parameters];top_ref!=statistic.end_poly;top_ref=top_ref->next_poly)
2109	{
2110	toprow* current_top = (toprow*)top_ref;
2111
2112	sum_a+=current_top->probability;
2113	/*
2114	cout << current_top->probability << " ";
2115
2116	for(set<vertex>::iterator vert_ref = (top_ref).vertices.begin();vert_ref!=(*top_ref).vertices.end();vert_ref++)
2117	{
2118	cout << round(100(vert_ref)->get_coordinates())/100 << " ; ";
2119	}
2120	*/
2121
2122	// cout << endl;
2123	ordered_toprows.insert(pair<double,toprow*>(sum_a,current_top));
2124	}
2125
2126	// cout << "Sum N: " << normalization_factor << endl;
2127
2128	while(sample_mat.cols()<n)
2129	{
2130	//// cout << "*************************************" << endl;
2131
2132
2133
2134	double rnumber = randu()*sum_a;
2135
2136	// cout << "RND:" << rnumber << endl;
2137
2138	// This could be more efficient (log n), but map::upper_bound() doesn't let me dereference returned iterator
2139	int toprow_count = 0;
2140	toprow* sampled_toprow;
2141	for(map<double,toprow*>::iterator top_ref = ordered_toprows.begin();top_ref!=ordered_toprows.end();top_ref++)
2142	{
2143	// cout << "CDF:"<< (*top_ref).first << endl;
2144	toprow_count++;
2145
2146	if((*top_ref).first >= rnumber)
2147	{
2148	sampled_toprow = (*top_ref).second;
2149	break;
2150	}
2151	}
2152
2153	//// cout << "Toprow/Count: " << toprow_count << "/" << ordered_toprows.size() << endl;
2154	// cout << &sampled_toprow << ";";
2155
2156	rnumber = randu();
2157
2158	set<simplex*>::iterator s_ref;
2159	double sum_b = 0;
2160	int simplex_count = 0;
2161	for(s_ref = sampled_toprow->triangulation.begin();s_ref!=sampled_toprow->triangulation.end();s_ref++)
2162	{
2163	simplex_count++;
2164
2165	sum_b += (*s_ref)->probability;
2166
2167	if(sum_b/sampled_toprow->probability >= rnumber)
2168	break;
2169	}
2170
2171	//// cout << "Simplex/Count: " << simplex_count << "/" << sampled_toprow->triangulation.size() << endl;
2172	//// cout << "Simplex factor: " << (*s_ref)->probability << endl;
2173	//// cout << "Toprow factor: " << sampled_toprow->probability << endl;
2174	//// cout << "Emlig factor: " << normalization_factor << endl;
2175	// cout << &(*tri_ref) << endl;
2176
2177	int number_of_runs = 0;
2178	bool have_sigma = false;
2179	double sigma = 0;
2180	do
2181	{
2182	rnumber = randu();
2183
2184	double sum_g = 0;
2185	for(int i = 0;i<(*s_ref)->positive_gamma_parameters.size();i++)
2186	{
2187	for(multimap<double,double>::iterator g_ref = (s_ref)->positive_gamma_parameters[i].begin();g_ref != (s_ref)->positive_gamma_parameters[i].end();g_ref++)
2188	{
2189	sum_g += (g_ref).first/(s_ref)->positive_gamma_sum;
2190
2191
2192	if(sum_g>rnumber)
2193	{
2194	//itpp::Gamma_RNG* gamma = new itpp::Gamma_RNG(conditions.size()-number_of_parameters,1/(*g_ref).second);
2195	//sigma = 1/(*gamma)();
2196
2197	GamRNG.setup(conditions.size()-number_of_parameters,(*g_ref).second);
2198
2199	sigma = 1/GamRNG();
2200
2201	// cout << "Sigma mean: " << (*g_ref).second/(conditions.size()-number_of_parameters-1) << endl;
2202	break;
2203	}
2204	}
2205
2206	if(sigma!=0)
2207	{
2208	break;
2209	}
2210	}
2211
2212	rnumber = randu();
2213
2214	double pg_sum = 0;
2215	for(vector<multimap<double,double>>::iterator v_ref = (s_ref)->positive_gamma_parameters.begin();v_ref!=(s_ref)->positive_gamma_parameters.end();v_ref++)
2216	{
2217	for(multimap<double,double>::iterator pg_ref = (v_ref).begin();pg_ref!=(v_ref).end();pg_ref++)
2218	{
2219	pg_sum += exp(((s_ref)->min_beta-(pg_ref).second)/sigma)pow((pg_ref).second/sigma,(int)conditions.size()-number_of_parameters-1)(pg_ref).second/fact(conditions.size()-number_of_parameters-1)(pg_ref).first;
2220	}
2221	}
2222
2223	double ng_sum = 0;
2224	for(vector<multimap<double,double>>::iterator v_ref = (s_ref)->negative_gamma_parameters.begin();v_ref!=(s_ref)->negative_gamma_parameters.end();v_ref++)
2225	{
2226	for(multimap<double,double>::iterator ng_ref = (v_ref).begin();ng_ref!=(v_ref).end();ng_ref++)
2227	{
2228	ng_sum += exp(((s_ref)->min_beta-(ng_ref).second)/sigma)pow((ng_ref).second/sigma,(int)conditions.size()-number_of_parameters-1)(ng_ref).second/fact(conditions.size()-number_of_parameters-1)(ng_ref).first;
2229	}
2230	}
2231
2232	if((pg_sum-ng_sum)/pg_sum>rnumber)
2233	{
2234	have_sigma = true;
2235	}
2236
2237	number_of_runs++;
2238	}
2239	while(!have_sigma);
2240
2241	//// cout << "Sigma: " << sigma << endl;
2242	//// cout << "Nr. of sigma runs: " << number_of_runs << endl;
2243
2244	int dimension = (*s_ref)->vertices.size()-1;
2245
2246	mat jacobian(dimension,dimension);
2247	vec gradient = sampled_toprow->condition_sum.right(dimension);
2248
2249	vertex* base_vert = (s_ref)->vertices.begin();
2250
2251	//// cout << "Base vertex coords(should be close to est. param.): " << base_vert->get_coordinates() << endl;
2252
2253	int row_count = 0;
2254
2255	for(set<vertex>::iterator vert_ref = ++(s_ref)->vertices.begin();vert_ref!=(*s_ref)->vertices.end();vert_ref++)
2256	{
2257	vec current_coords = (*vert_ref)->get_coordinates();
2258
2259	//// cout << "Coords of vertex[" << row_count << "]: " << current_coords << endl;
2260
2261	vec relative_coords = current_coords-base_vert->get_coordinates();
2262
2263	jacobian.set_row(row_count,relative_coords);
2264
2265	row_count++;
2266	}
2267
2268	//// cout << "Jacobian: " << jacobian << endl;
2269
2270	//// cout << "Gradient before trafo:" << gradient << endl;
2271
2272	gradient = jacobian*gradient;
2273
2274	//// cout << "Gradient after trafo:" << gradient << endl;
2275
2276	// vec normal_gradient = gradient/sqrt(gradient*gradient);
2277	// cout << gradient << endl;
2278	// cout << normal_gradient << endl;
2279	// cout << sqrt(gradient*gradient) << endl;
2280
2281	mat rotation_matrix = eye(dimension);
2282
2283
2284
2285	for(int i = 1;i<dimension;i++)
2286	{
2287	vec x_axis = zeros(dimension);
2288	x_axis.set(0,1);
2289
2290	x_axis = rotation_matrix*x_axis;
2291
2292	double t = abs(gradient[i]/gradient*x_axis);
2293
2294	double sin_theta = sign(gradient[i])*t/sqrt(1+pow(t,2));
2295	double cos_theta = sign(gradient*x_axis)/sqrt(1+pow(t,2));
2296
2297	mat partial_rotation = eye(dimension);
2298
2299	partial_rotation.set(0,0,cos_theta);
2300	partial_rotation.set(i,i,cos_theta);
2301
2302	partial_rotation.set(0,i,sin_theta);
2303	partial_rotation.set(i,0,-sin_theta);
2304
2305	rotation_matrix = rotation_matrix*partial_rotation;
2306
2307	}
2308
2309	// cout << rotation_matrix << endl;
2310
2311	mat extended_rotation = rotation_matrix;
2312	extended_rotation.ins_col(0,zeros(extended_rotation.rows()));
2313
2314	//// cout << "Extended rotation: " << extended_rotation << endl;
2315
2316	vec minima = itpp::min(extended_rotation,2);
2317	vec maxima = itpp::max(extended_rotation,2);
2318
2319	//// cout << "Minima: " << minima << endl;
2320	//// cout << "Maxima: " << maxima << endl;
2321
2322	vec sample_coordinates;
2323	bool is_inside = true;
2324
2325	vec new_sample;
2326	sample_coordinates = new_sample;
2327
2328	for(int j = 0;j<number_of_parameters;j++)
2329	{
2330	rnumber = randu();
2331
2332	double coordinate;
2333
2334	if(j==0)
2335	{
2336	vec new_gradient = rotation_matrix*gradient;
2337
2338	//// cout << "New gradient(should have only first component nonzero):" << new_gradient << endl;
2339
2340	// cout << "Max: " << maxima[0] << " Min: " << minima[0] << " Grad:" << new_gradient[0] << endl;
2341
2342	double log_bracket = 1-rnumber(1-exp(new_gradient[0]/sigma(minima[0]-maxima[0])));
2343
2344	coordinate = minima[0]-sigma/new_gradient[0]*log(log_bracket);
2345	}
2346	else
2347	{
2348	coordinate = minima[j]+rnumber*(maxima[j]-minima[j]);
2349	}
2350
2351	sample_coordinates.ins(j,coordinate);
2352	}
2353
2354	//// cout << "Sampled coordinates(gradient direction): " << sample_coordinates << endl;
2355
2356	sample_coordinates = rotation_matrix.T()*sample_coordinates;
2357
2358	//// cout << "Sampled coordinates(backrotated direction):" << sample_coordinates << endl;
2359
2360
2361	for(int j = 0;j<sample_coordinates.size();j++)
2362	{
2363	if(sample_coordinates[j]<0)
2364	{
2365	is_inside = false;
2366	}
2367	}
2368
2369	double above_criterion = ones(sample_coordinates.size())*sample_coordinates;
2370
2371	if(above_criterion>1)
2372	{
2373	is_inside = false;
2374	}
2375
2376	if(is_inside)
2377	{
2378	sample_coordinates = jacobian.T()sample_coordinates+(base_vert).get_coordinates();
2379
2380	sample_coordinates.ins(0,sigma);
2381
2382	//// cout << "Sampled coordinates(parameter space):" << sample_coordinates << endl;
2383
2384	sample_mat.ins_col(0,sample_coordinates);
2385
2386	// cout << sample_mat.cols() << ",";
2387	}
2388
2389	// cout << sampled_toprow->condition_sum.right(sampled_toprow->condition_sum.size()-1)*min_grad->get_coordinates()-sampled_toprow->condition_sum[0] << endl;
2390	// cout << sampled_toprow->condition_sum.right(sampled_toprow->condition_sum.size()-1)*max_grad->get_coordinates()-sampled_toprow->condition_sum[0] << endl;
2391
2392
2393	}
2394
2395	cout << endl;
2396	return sample_mat;
2397	}
2398	else
2399	{
2400	throw new exception("You are trying to sample from density that is not determined (parameters can't be integrated out)!");
2401
2402	return 0;
2403	}
2404
2405
2406	}
2407
2408	pair<vec,mat> importance_sample(int n)
2409	{
2410	vec probabilities;
2411	mat samples;
2412
2413	for(int i = 0;i<n;i++)
2414	{
2415	pair<vec,simplex*> condition_and_simplex = choose_simplex();
2416
2417	pair<double,double> probability_and_sigma = choose_sigma(condition_and_simplex.second);
2418
2419	int dimension = condition_and_simplex.second->vertices.size()-1;
2420
2421	mat jacobian(dimension,dimension);
2422	vec gradient = condition_and_simplex.first.right(dimension);
2423
2424	vertex* base_vert = *condition_and_simplex.second->vertices.begin();
2425
2426	//// cout << "Base vertex coords(should be close to est. param.): " << base_vert->get_coordinates() << endl;
2427
2428	int row_count = 0;
2429
2430	for(set<vertex*>::iterator vert_ref = ++condition_and_simplex.second->vertices.begin();vert_ref!=condition_and_simplex.second->vertices.end();vert_ref++)
2431	{
2432	vec current_coords = (*vert_ref)->get_coordinates();
2433
2434	//// cout << "Coords of vertex[" << row_count << "]: " << current_coords << endl;
2435
2436	vec relative_coords = current_coords-base_vert->get_coordinates();
2437
2438	jacobian.set_row(row_count,relative_coords);
2439
2440	row_count++;
2441	}
2442
2443	//// cout << "Jacobian: " << jacobian << endl;
2444
2445	/// \todo Is this correct? Are the random coordinates really jointly uniform? I don't know.
2446	vec sample_coords;
2447	double sampling_diff = 1;
2448	for(int j = 0;j<number_of_parameters;j++)
2449	{
2450	double rnumber = randu()*sampling_diff;
2451
2452	sample_coords.ins(0,rnumber);
2453
2454	sampling_diff -= rnumber;
2455	}
2456
2457	sample_coords = jacobian.T()sample_coords+(base_vert).get_coordinates();
2458
2459	vec extended_coords = sample_coords;
2460	extended_coords.ins(0,-1.0);
2461
2462	double exponent = extended_coords*condition_and_simplex.first;
2463	double sample_prob = 1/condition_and_simplex.second->probability/pow(probability_and_sigma.second,(int)conditions.size()-number_of_parameters)exp((-1)/probability_and_sigma.secondexponent);
2464	sample_prob *= probability_and_sigma.first;
2465
2466	sample_coords.ins(0,probability_and_sigma.second);
2467
2468	samples.ins_col(0,sample_coords);
2469	probabilities.ins(0,sample_prob);
2470	}
2471
2472	return pair<vec,mat>(probabilities,samples);
2473	}
2474
2475	int logfact(int factor)
2476	{
2477	if(factor>1)
2478	{
2479	return log((double)factor)+logfact(factor-1);
2480	}
2481	else
2482	{
2483	return 0;
2484	}
2485	}
2486	protected:
2487
2488	/// A method for creating plain default statistic representing only the range of the parameter space.
2489	void create_statistic(int number_of_parameters, double soft_prior_parameter)
2490	{
2491	/*
2492	for(int i = 0;i<number_of_parameters;i++)
2493	{
2494	vec condition_vec = zeros(number_of_parameters+1);
2495	condition_vec[i+1] = 1;
2496
2497	condition* new_condition = new condition(condition_vec);
2498
2499	conditions.push_back(new_condition);
2500	}
2501	*/
2502
2503	// An empty vector of coordinates.
2504	vec origin_coord;
2505
2506	// We create an origin - this point will have all the coordinates zero, but now it has an empty vector of coords.
2507	vertex *origin = new vertex(origin_coord);
2508
2509	origin->my_emlig = this;
2510
2511	/*
2512	// As a statistic, we have to create a vector of vectors of polyhedron pointers. It will then represent the Hasse
2513	// diagram. First we create a vector of polyhedrons..
2514	list<polyhedron*> origin_vec;
2515
2516	// ..we fill it with the origin..
2517	origin_vec.push_back(origin);
2518
2519	// ..and we fill the statistic with the created vector.
2520	statistic.push_back(origin_vec);
2521	*/
2522
2523	statistic = *(new c_statistic());
2524
2525	statistic.append_polyhedron(0, origin);
2526
2527	// Now we have a statistic for a zero dimensional space. Regarding to how many dimensional space we need to
2528	// describe, we have to widen the descriptional default statistic. We use an iterative procedure as follows:
2529	for(int i=0;i<number_of_parameters;i++)
2530	{
2531	// We first will create two new vertices. These will be the borders of the parameter space in the dimension
2532	// of newly added parameter. Therefore they will have all coordinates except the last one zero. We get the
2533	// right amount of zero cooridnates by reading them from the origin
2534	vec origin_coord = origin->get_coordinates();
2535
2536
2537
2538	// And we incorporate the nonzero coordinates into the new cooordinate vectors
2539	vec origin_coord1 = concat(origin_coord,-max_range);
2540	vec origin_coord2 = concat(origin_coord,max_range);
2541
2542
2543	// Now we create the points
2544	vertex* new_point1 = new vertex(origin_coord1);
2545	vertex* new_point2 = new vertex(origin_coord2);
2546
2547	new_point1->my_emlig = this;
2548	new_point2->my_emlig = this;
2549
2550	//*********************************************************************************************************
2551	// The algorithm for recursive build of a new Hasse diagram representing the space structure from the old
2552	// diagram works so that you create two copies of the old Hasse diagram, you shift them up one level (points
2553	// will be segments, segments will be areas etc.) and you connect each one of the original copied polyhedrons
2554	// with its offspring by a parent-child relation. Also each of the segments in the first (second) copy is
2555	// connected to the first (second) newly created vertex by a parent-child relation.
2556	//*********************************************************************************************************
2557
2558
2559	/*
2560	// Create the vectors of vectors of pointers to polyhedrons to hold the copies of the old Hasse diagram
2561	vector<vector<polyhedron*>> new_statistic1;
2562	vector<vector<polyhedron*>> new_statistic2;
2563	*/
2564
2565	c_statistic* new_statistic1 = new c_statistic();
2566	c_statistic* new_statistic2 = new c_statistic();
2567
2568
2569	// Copy the statistic by rows
2570	for(int j=0;j<statistic.size();j++)
2571	{
2572
2573
2574	// an element counter
2575	int element_number = 0;
2576
2577	/*
2578	vector<polyhedron*> supportnew_1;
2579	vector<polyhedron*> supportnew_2;
2580
2581	new_statistic1.push_back(supportnew_1);
2582	new_statistic2.push_back(supportnew_2);
2583	*/
2584
2585	// for each polyhedron in the given row
2586	for(polyhedron* horiz_ref = statistic.rows[j];horiz_ref!=statistic.get_end();horiz_ref=horiz_ref->next_poly)
2587	{
2588	// Append an extra zero coordinate to each of the vertices for the new dimension
2589	// If vert_ref is at the first index => we loop through vertices
2590	if(j == 0)
2591	{
2592	// cast the polyhedron pointer to a vertex pointer and push a zero to its vector of coordinates
2593	((vertex*) horiz_ref)->push_coordinate(0);
2594	}
2595	/*
2596	else
2597	{
2598	((toprow) (horiz_ref))->condition.ins(0,0);
2599	}*/
2600
2601	// if it has parents
2602	if(!horiz_ref->parents.empty())
2603	{
2604	// save the relative address of this child in a vector kids_rel_addresses of all its parents.
2605	// This information will later be used for copying the whole Hasse diagram with each of the
2606	// relations contained within.
2607	for(list<polyhedron*>::iterator parent_ref = horiz_ref->parents.begin();parent_ref != horiz_ref->parents.end();parent_ref++)
2608	{
2609	(*parent_ref)->kids_rel_addresses.push_back(element_number);
2610	}
2611	}
2612
2613	// **************************************************************************************************
2614	// Here we begin creating a new polyhedron, which will be a copy of the old one. Each such polyhedron
2615	// will be created as a toprow, but this information will be later forgotten and only the polyhedrons
2616	// in the top row of the Hasse diagram will be considered toprow for later use.
2617	// **************************************************************************************************
2618
2619	// First we create vectors specifying a toprow condition. In the case of a preconstructed statistic
2620	// this condition will be a vector of zeros. There are two vectors, because we need two copies of
2621	// the original Hasse diagram.
2622	vec vec1;
2623	vec vec2;
2624	if(!horiz_ref->kids_rel_addresses.empty())
2625	{
2626	vec1 = ((toprow*)horiz_ref)->condition_sum;
2627	vec1.ins(vec1.size(),-soft_prior_parameter);
2628
2629	vec2 = ((toprow*)horiz_ref)->condition_sum;
2630	vec2.ins(vec2.size(),soft_prior_parameter);
2631	}
2632	else
2633	{
2634	vec1.ins(0,-soft_prior_parameter);
2635	vec2.ins(0,soft_prior_parameter);
2636
2637	vec1.ins(0,0);
2638	vec2.ins(0,0);
2639	}
2640
2641	// cout << vec1 << endl;
2642	// cout << vec2 << endl;
2643
2644
2645	// We create a new toprow with the previously specified condition.
2646	toprow* current_copy1 = new toprow(vec1, this->condition_order);
2647	toprow* current_copy2 = new toprow(vec2, this->condition_order);
2648
2649	current_copy1->my_emlig = this;
2650	current_copy2->my_emlig = this;
2651
2652	// The vertices of the copies will be inherited, because there will be a parent/child relation
2653	// between each polyhedron and its offspring (comming from the copy) and a parent has all the
2654	// vertices of its child plus more.
2655	for(set<vertex*>::iterator vertex_ref = horiz_ref->vertices.begin();vertex_ref!=horiz_ref->vertices.end();vertex_ref++)
2656	{
2657	current_copy1->vertices.insert(*vertex_ref);
2658	current_copy2->vertices.insert(*vertex_ref);
2659	}
2660
2661	// The only new vertex of the offspring should be the newly created point.
2662	current_copy1->vertices.insert(new_point1);
2663	current_copy2->vertices.insert(new_point2);
2664
2665	// This method guarantees that each polyhedron is already triangulated, therefore its triangulation
2666	// is only one set of vertices and it is the set of all its vertices.
2667	simplex* t_simplex1 = new simplex(current_copy1->vertices);
2668	simplex* t_simplex2 = new simplex(current_copy2->vertices);
2669
2670	current_copy1->triangulation.insert(t_simplex1);
2671	current_copy2->triangulation.insert(t_simplex2);
2672
2673	// Now we have copied the polyhedron and we have to copy all of its relations. Because we are copying
2674	// in the Hasse diagram from bottom up, we always have to copy the parent/child relations to all the
2675	// kids and when we do that and know the child, in the child we will remember the parent we came from.
2676	// This way all the parents/children relations are saved in both the parent and the child.
2677	if(!horiz_ref->kids_rel_addresses.empty())
2678	{
2679	for(list<int>::iterator kid_ref = horiz_ref->kids_rel_addresses.begin();kid_ref!=horiz_ref->kids_rel_addresses.end();kid_ref++)
2680	{
2681	polyhedron* new_kid1 = new_statistic1->rows[j-1];
2682	polyhedron* new_kid2 = new_statistic2->rows[j-1];
2683
2684	// THIS IS NOT EFFECTIVE: It could be improved by having the list indexed for new_statistic, but
2685	// not indexed for statistic. Hopefully this will not cause a big slowdown - happens only offline.
2686	if(*kid_ref)
2687	{
2688	for(int k = 1;k<=(*kid_ref);k++)
2689	{
2690	new_kid1=new_kid1->next_poly;
2691	new_kid2=new_kid2->next_poly;
2692	}
2693	}
2694
2695	// find the child and save the relation to the parent
2696	current_copy1->children.push_back(new_kid1);
2697	current_copy2->children.push_back(new_kid2);
2698
2699	// in the child save the parents' address
2700	new_kid1->parents.push_back(current_copy1);
2701	new_kid2->parents.push_back(current_copy2);
2702	}
2703
2704	// Here we clear the parents kids_rel_addresses vector for later use (when we need to widen the
2705	// Hasse diagram again)
2706	horiz_ref->kids_rel_addresses.clear();
2707	}
2708	// If there were no children previously, we are copying a polyhedron that has been a vertex before.
2709	// In this case it is a segment now and it will have a relation to its mother (copywise) and to the
2710	// newly created point. Here we create the connection to the new point, again from both sides.
2711	else
2712	{
2713	// Add the address of the new point in the former vertex
2714	current_copy1->children.push_back(new_point1);
2715	current_copy2->children.push_back(new_point2);
2716
2717	// Add the address of the former vertex in the new point
2718	new_point1->parents.push_back(current_copy1);
2719	new_point2->parents.push_back(current_copy2);
2720	}
2721
2722	// Save the mother in its offspring
2723	current_copy1->children.push_back(horiz_ref);
2724	current_copy2->children.push_back(horiz_ref);
2725
2726	// Save the offspring in its mother
2727	horiz_ref->parents.push_back(current_copy1);
2728	horiz_ref->parents.push_back(current_copy2);
2729
2730
2731	// Add the copies into the relevant statistic. The statistic will later be appended to the previous
2732	// Hasse diagram
2733	new_statistic1->append_polyhedron(j,current_copy1);
2734	new_statistic2->append_polyhedron(j,current_copy2);
2735
2736	// Raise the count in the vector of polyhedrons
2737	element_number++;
2738
2739	}
2740
2741	}
2742
2743	/*
2744	statistic.begin()->push_back(new_point1);
2745	statistic.begin()->push_back(new_point2);
2746	*/
2747
2748	statistic.append_polyhedron(0, new_point1);
2749	statistic.append_polyhedron(0, new_point2);
2750
2751	// Merge the new statistics into the old one. This will either be the final statistic or we will
2752	// reenter the widening loop.
2753	for(int j=0;j<new_statistic1->size();j++)
2754	{
2755	/*
2756	if(j+1==statistic.size())
2757	{
2758	list<polyhedron*> support;
2759	statistic.push_back(support);
2760	}
2761
2762	(statistic.begin()+j+1)->insert((statistic.begin()+j+1)->end(),new_statistic1[j].begin(),new_statistic1[j].end());
2763	(statistic.begin()+j+1)->insert((statistic.begin()+j+1)->end(),new_statistic2[j].begin(),new_statistic2[j].end());
2764	*/
2765	statistic.append_polyhedron(j+1,new_statistic1->rows[j],new_statistic1->row_ends[j]);
2766	statistic.append_polyhedron(j+1,new_statistic2->rows[j],new_statistic2->row_ends[j]);
2767	}
2768	}
2769
2770	/*
2771	vector<list<toprow*>> toprow_statistic;
2772	int line_count = 0;
2773
2774	for(vector<list<polyhedron*>>::iterator polyhedron_ref = ++statistic.begin(); polyhedron_ref!=statistic.end();polyhedron_ref++)
2775	{
2776	list<toprow*> support_list;
2777	toprow_statistic.push_back(support_list);
2778
2779	for(list<polyhedron*>::iterator polyhedron_ref2 = polyhedron_ref->begin(); polyhedron_ref2 != polyhedron_ref->end(); polyhedron_ref2++)
2780	{
2781	toprow* support_top = (toprow)(polyhedron_ref2);
2782
2783	toprow_statistic[line_count].push_back(support_top);
2784	}
2785
2786	line_count++;
2787	}*/
2788
2789	/*
2790	vector<int> sizevector;
2791	for(int s = 0;s<statistic.size();s++)
2792	{
2793	sizevector.push_back(statistic.row_size(s));
2794	}
2795	*/
2796
2797	}
2798
2799	};
2800
2801
2802
2803	//! Robust Bayesian AR model for Multicriteria-Laplace-Inverse-Gamma density
2804	class RARX //: public BM
2805	{
2806	private:
2807	bool has_constant;
2808
2809	int window_size;
2810
2811	list<vec> conditions;
2812
2813	public:
2814	emlig* posterior;
2815
2816	RARX(int number_of_parameters, const int window_size, bool has_constant)//:BM()
2817	{
2818	this->has_constant = has_constant;
2819
2820	posterior = new emlig(number_of_parameters,0.001);
2821
2822	this->window_size = window_size;
2823	};
2824
2825	void bayes(itpp::vec yt)
2826	{
2827	if(has_constant)
2828	{
2829	int c_size = yt.size();
2830
2831	yt.ins(c_size,1.0);
2832	}
2833
2834	if(yt.size() == posterior->number_of_parameters+1)
2835	{
2836	conditions.push_back(yt);
2837	}
2838	else
2839	{
2840	throw new exception("Wrong condition size for bayesian data update!");
2841	}
2842
2843	//posterior->step_me(0);
2844
2845	/// \TODO tohle je spatne, tady musi byt jiny vypocet poctu podminek, kdyby nejaka byla multiplicitni, tak tohle bude spatne
2846	if(conditions.size()>window_size && window_size!=0)
2847	{
2848	posterior->add_and_remove_condition(yt,conditions.front());
2849	conditions.pop_front();
2850
2851	//posterior->step_me(1);
2852	}
2853	else
2854	{
2855	posterior->add_condition(yt);
2856	}
2857
2858
2859
2860	}
2861
2862	};
2863
2864
2865
2866	#endif //TRAGE_H

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