18f0de5486
git-svn-id: https://yap.svn.sf.net/svnroot/yap/trunk@1245 b08c6af1-5177-4d33-ba66-4b1c6b8b522a
421 lines
12 KiB
Prolog
421 lines
12 KiB
Prolog
/***********************************
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Variable Elimination in Prolog
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How to do it
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Three steps:
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build the graph:
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- for all variables, find out
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all tables they connect to;
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multiply their size
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order by size
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*********************************/
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:- module(vel, [vel/3,
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check_if_vel_done/1]).
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:- attribute size/1, posterior/4, all_diffs/1.
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:- use_module(library(ordsets), [ord_union/3]).
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:- use_module(library('clpbn/xbif'), [clpbn2xbif/3]).
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:- use_module(library('clpbn/graphviz'), [clpbn2gviz/4]).
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:- use_module(library('clpbn/utils'), [
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clpbn_not_var_member/2,
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check_for_hidden_vars/3]).
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:- use_module(library(lists),
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[
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append/3,
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member/2
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]).
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check_if_vel_done(Var) :-
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get_atts(Var, [size(_)]), !.
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vel(LVs0,Vs0,AllDiffs) :-
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sort(LVs0,LVs1),
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get_rid_of_ev_vars(LVs1,LVs),
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do_vel(LVs,Vs0,AllDiffs).
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do_vel([],_,_) :- !.
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do_vel(LVs,Vs0,AllDiffs) :-
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check_for_hidden_vars(Vs0, Vs0, Vs1),
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sort(Vs1,Vs),
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find_all_clpbn_vars(Vs, LV0, LVi, Tables0),
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find_all_table_deps(Tables0, LV0),
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(clpbn:output(xbif(XBifStream)) -> clpbn2xbif(XBifStream,vel,Vs) ; true),
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(clpbn:output(gviz(XBifStream)) -> clpbn2gviz(XBifStream,vel,Vs,LVs) ; true),
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process(LVi, LVs, tab(Dist,_,_)),
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Dist =.. [_|Ps0],
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normalise(Ps0,Ps),
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bind_vals(LVs,Ps,AllDiffs).
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%
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% some variables might already have evidence in the data-base.
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%
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get_rid_of_ev_vars([],[]).
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get_rid_of_ev_vars([V|LVs0],LVs) :-
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clpbn:get_atts(V, [evidence(Ev)]), !,
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put_atts(V, [posterior([],Ev,[],[])]), !,
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get_rid_of_ev_vars(LVs0,LVs).
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get_rid_of_ev_vars([V|LVs0],[V|LVs]) :-
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get_rid_of_ev_vars(LVs0,LVs).
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find_all_clpbn_vars([], [], [], []) :- !.
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find_all_clpbn_vars([V|Vs], [Var|LV], ProcessedVars, [table(I,Table,Parents,Sizes)|Tables]) :-
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var_with_deps(V, Table, Parents, Sizes, Ev, Vals), !,
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% variables with evidence should not be processed.
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(var(Ev) ->
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Var = var(V,I,Sz,Vals,Parents,Ev,_,_),
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get_dist_size(V,Sz),
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ProcessedVars = [Var|ProcessedVars0]
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;
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ProcessedVars = ProcessedVars0
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),
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find_all_clpbn_vars(Vs, LV, ProcessedVars0, Tables).
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var_with_deps(V, Table, Deps, Sizes, Ev, Vals) :-
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clpbn:get_atts(V, [dist(Vals,OTable,Parents)]),
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( clpbn:get_atts(V, [evidence(Ev)]) -> true ; true),
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reorder_table([V|Parents],Sizes0,OTable,Deps0,Table0),
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simplify_evidence(Deps0, Table0, Deps0, Sizes0, Table, Deps, Sizes).
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get_sizes([], []).
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get_sizes([V|Deps], [Sz|Sizes]) :-
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get_dist_size(V,Sz),
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get_sizes(Deps, Sizes).
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reorder_table(Vs0, Sizes, T0, Vs, TF) :-
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get_sizes(Vs0, Szs),
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numb_vars(Vs0, Szs, _, VPs0, VLs0),
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keysort(VLs0, VLs),
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compute_new_factors(VLs, _, Vs, Sizes),
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get_factors(VLs0,Fs),
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length(T0,L),
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functor(TF,t,L),
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copy_to_new_array(T0, 0, VPs0, Fs, TF).
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numb_vars([], [], 1, [], []).
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numb_vars([V|Vs], [L|Ls], A0, [Ai|VPs], [V-(L,_)|VLs]) :-
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numb_vars(Vs, Ls, Ai, VPs, VLs),
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A0 is Ai*L.
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compute_new_factors([], 1, [], []).
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compute_new_factors([V-(L,F)|VLs], NF, [V|Vs], [L|Szs]) :-
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compute_new_factors(VLs, F, Vs, Szs),
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NF is F*L.
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get_factors([],[]).
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get_factors([_-(_,F)|VLs0],[F|Fs]) :-
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get_factors(VLs0,Fs).
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copy_to_new_array([], _, _, _, _).
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copy_to_new_array([P|Ps], I, F0s, Fs, S) :-
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convert_factor(F0s, Fs, I, N),
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I1 is I+1,
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N1 is N+1,
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arg(N1,S,P),
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copy_to_new_array(Ps, I1, F0s, Fs, S).
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convert_factor([], [], _, 0).
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convert_factor([F0|F0s], [F|Fs], I, OUT) :-
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X is I//F0,
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NI is I mod F0,
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NEXT is F*X,
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convert_factor(F0s, Fs, NI, OUT1),
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OUT is OUT1+NEXT.
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find_all_table_deps(Tables0, LV) :-
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find_dep_graph(Tables0, DepGraph0),
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sort(DepGraph0, DepGraph),
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add_table_deps_to_variables(LV, DepGraph).
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find_dep_graph([], []).
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find_dep_graph([table(I,Tab,Deps,Sizes)|Tables], DepGraph) :-
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add_table_deps(Deps, I, Deps, Tab, Sizes, DepGraph0, DepGraph),
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find_dep_graph(Tables, DepGraph0).
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add_table_deps([], _, _, _, _, DepGraph, DepGraph).
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add_table_deps([V|Deps], I, Deps0, Table, Sizes, DepGraph0, [V-tab(Table,Deps0,Sizes)|DepGraph]) :-
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add_table_deps(Deps, I, Deps0, Table, Sizes, DepGraph0, DepGraph).
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add_table_deps_to_variables([], []).
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add_table_deps_to_variables([var(V,_,_,_,_,_,Deps,K)|LV], DepGraph) :-
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steal_deps_for_variable(DepGraph, V, NDepGraph, Deps),
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compute_size(Deps,[],K),
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% ( clpbn:get_atts(V,[key(Key)]) -> write(Key:K), nl ; true),
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add_table_deps_to_variables(LV, NDepGraph).
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steal_deps_for_variable([V-Info|DepGraph], V0, NDepGraph, [Info|Deps]) :-
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V == V0, !,
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steal_deps_for_variable(DepGraph, V0, NDepGraph, Deps).
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steal_deps_for_variable(DepGraph, _, DepGraph, []).
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compute_size([],Vs,K) :-
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% use sizes now
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% length(Vs,K).
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multiply_sizes(Vs,1,K).
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compute_size([tab(_,Vs,_)|Tabs],Vs0,K) :-
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ord_union(Vs,Vs0,VsI),
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compute_size(Tabs,VsI,K).
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multiply_sizes([],K,K).
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multiply_sizes([V|Vs],K0,K) :-
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get_dist_size(V, Sz),
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KI is K0*Sz,
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multiply_sizes(Vs,KI,K).
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process(LV0, InputVs, Out) :-
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find_best(LV0, V0, -1, V, WorkTables, LVI, InputVs),
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V \== V0, !,
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multiply_tables(WorkTables, Table),
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propagate_evidence(V, Evs),
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project(V,Table,NewTable,Evs),
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include(LVI,NewTable,V,LV2),
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process(LV2, InputVs, Out).
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process(LV0, _, Out) :-
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fetch_tables(LV0, WorkTables),
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multiply_tables(WorkTables, Out).
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find_best([], V, _TF, V, _, [], _).
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%:-
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% clpbn:get_atts(V,[key(K)]), write(chosen:K:TF), nl.
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% root_with_single_child
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%find_best([var(V,I,_,_,[],Ev,[Dep],K)|LV], _, _, V, [Dep], LVF, Inputs) :- !.
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find_best([var(V,I,Sz,Vals,Parents,Ev,Deps,K)|LV], _, Threshold, VF, NWorktables, LVF, Inputs) :-
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( K < Threshold ; Threshold < 0),
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clpbn_not_var_member(Inputs, V), !,
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find_best(LV, V, K, VF, WorkTables,LV0, Inputs),
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(V == VF ->
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LVF = LV0, Deps = NWorktables
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;
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LVF = [var(V,I,Sz,Vals,Parents,Ev,Deps,K)|LV0], WorkTables = NWorktables
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).
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find_best([V|LV], V0, Threshold, VF, WorkTables, [V|LVF], Inputs) :-
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find_best(LV, V0, Threshold, VF, WorkTables, LVF, Inputs).
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multiply_tables([Table], Table) :- !.
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multiply_tables([tab(Tab1,Deps1,Szs1), tab(Tab2,Deps2,Sz2)| Tables], Out) :-
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multiply_table(Tab1, Deps1, Szs1, Tab2, Deps2, Sz2, NTab, NDeps, NSz),
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multiply_tables([tab(NTab,NDeps,NSz)| Tables], Out).
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simplify_evidence([], Table, Deps, Sizes, Table, Deps, Sizes).
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simplify_evidence([V|VDeps], Table0, Deps0, Sizes0, Table, Deps, Sizes) :-
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clpbn:get_atts(V, [evidence(Ev)]),
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clpbn:get_atts(V, [dist(Out,_,_)]),
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generate_szs_with_evidence(Out,Ev,Evs),
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project(V,tab(Table0,Deps0,Sizes0),tab(NewTable,Deps1,Sizes1),Evs),
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simplify_evidence(VDeps, NewTable, Deps1, Sizes1, Table, Deps, Sizes).
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simplify_evidence([_|VDeps], Table0, Deps0, Sizes0, Table, Deps, Sizes) :-
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simplify_evidence(VDeps, Table0, Deps0, Sizes0, Table, Deps, Sizes).
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propagate_evidence(V, Evs) :-
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clpbn:get_atts(V, [evidence(Ev),dist(Out,_,_)]), !,
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generate_szs_with_evidence(Out,Ev,Evs).
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propagate_evidence(_, _).
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generate_szs_with_evidence([],_,[]).
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generate_szs_with_evidence([Ev|Out],Ev,[ok|Evs]) :- !,
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generate_szs_with_evidence(Out,Ev,Evs).
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generate_szs_with_evidence([_|Out],Ev,[not_ok|Evs]) :-
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generate_szs_with_evidence(Out,Ev,Evs).
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fetch_tables([], []).
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fetch_tables([var(_,_,_,_,_,_,Deps,_)|LV0], Tables) :-
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append(Deps,Tables0,Tables),
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fetch_tables(LV0, Tables0).
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multiply_table(Tab1, Deps1, Szs1, Tab2, Deps2, Szs2, NTab, NDeps, NSzs) :-
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deps_union(Deps1,Szs1,Fs10,Deps2,Szs2,Fs20,NDeps,NSzs),
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factors(NSzs, Fs, Total),
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factors(Fs10, Fs1, _),
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factors(Fs20, Fs2, _),
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elements(0, Total, Fs, Fs1, Fs2, Tab1, Tab2, LTab),
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NTab =.. [t|LTab].
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deps_union([],[],[],[],[],[],[],[]) :- !.
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deps_union([],[],Fs1,[V2|Deps2],[Sz|Szs2],[Sz|Szs2],[V2|Deps2],[Sz|Szs2]) :- !,
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mk_zeros([Sz|Szs2],Fs1).
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deps_union([V1|Deps1],[Sz|Szs1],[Sz|Szs1],[],[],Fs2,[V1|Deps1],[Sz|Szs1]) :- !,
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mk_zeros([Sz|Szs1],Fs2).
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deps_union([V1|Deps1],[Sz|Szs1],[Sz|Fs1],[V2|Deps2],[Sz|Szs2],[Sz|Fs2],[V1|NDeps],[Sz|NSzs]) :- V1 == V2, !,
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deps_union(Deps1,Szs1,Fs1,Deps2,Szs2,Fs2,NDeps,NSzs).
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deps_union([V1|Deps1],[Sz1|Szs1],[Sz1|Fs1],[V2|Deps2],Szs2,[0|Fs2],[V1|NDeps],[Sz1|NSzs]) :- V1 @< V2, !,
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deps_union(Deps1,Szs1,Fs1,[V2|Deps2],Szs2,Fs2,NDeps,NSzs).
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deps_union([V1|Deps1],Szs1,[0|Fs1],[V2|Deps2],[Sz|Szs2],[Sz|Fs2],[V2|NDeps],[Sz|NSzs]) :-
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deps_union([V1|Deps1],Szs1,Fs1,Deps2,Szs2,Fs2,NDeps,NSzs).
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mk_zeros([],[]).
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mk_zeros([_|Szs],[0|Fs]) :-
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mk_zeros(Szs,Fs).
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factors([], [], 1).
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factors([0|Ls], [0|NLs], Prod) :- !,
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factors(Ls, NLs, Prod).
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factors([N|Ls], [Prod0|NLs], Prod) :-
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factors(Ls, NLs, Prod0),
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Prod is Prod0*N.
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elements(Total, Total, _, _, _, _, _, []) :- !.
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elements(I, Total, Fs, Fs1, Fs2, Tab1, Tab2, [El|Els]) :-
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element(Fs, I, 1, Fs1, 1, Fs2, Tab1, Tab2, El),
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I1 is I+1,
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elements(I1, Total, Fs, Fs1, Fs2, Tab1, Tab2, Els).
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element([], _, P1, [], P2, [], Tab1, Tab2, El) :-
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arg(P1, Tab1, El1),
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arg(P2, Tab2, El2),
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El is El1*El2.
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element([F|Fs], I, P1, [F1|Fs1], P2, [F2|Fs2], Tab1, Tab2, El) :-
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FF is I // F,
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NP1 is P1+F1*FF,
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NP2 is P2+F2*FF,
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NI is I mod F,
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element(Fs, NI, NP1, Fs1, NP2, Fs2, Tab1, Tab2, El).
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%
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project(V,tab(Table,Deps,Szs),tab(NewTable,NDeps,NSzs),Evs) :-
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functor(Table,_,Max),
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find_projection_factor(Deps, V, NDeps, Szs, NSzs, F, Sz),
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OLoop is Max//(Sz*F),
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project_outer_loop(0,OLoop,F,Sz,Table,Evs,NTabl),
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NewTable =.. [t|NTabl].
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find_projection_factor([V|Deps], V1, Deps, [Sz|Szs], Szs, F, Sz) :-
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V == V1, !,
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mult(Szs, 1, F).
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find_projection_factor([V|Deps], V1, [V|NDeps], [Sz|Szs], [Sz|NSzs], F, NSz) :-
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find_projection_factor(Deps, V1, NDeps, Szs, NSzs, F, NSz).
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mult([], F, F).
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mult([Sz|Szs], Sz0, F) :-
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SzI is Sz0*Sz,
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mult(Szs, SzI, F).
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project_outer_loop(OLoop,OLoop,_,_,_,_,[]) :- !.
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project_outer_loop(I,OLoop,F,Sz,Table,Evs,NTabl) :-
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Base is I*Sz*F,
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project_mid_loop(0,F,Base,Sz,Table,Evs,NTabl,NTabl0),
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I1 is I+1,
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project_outer_loop(I1,OLoop,F,Sz,Table,Evs,NTabl0).
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project_mid_loop(F,F,_,_,_,_,NTabl,NTabl) :- !.
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project_mid_loop(I,F,Base,Sz,Table,Evs,[Ent|NTablF],NTabl0) :-
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I1 is I+1,
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NBase is I+Base,
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project_inner_loop(0,Sz,Evs,NBase,F,Table,0.0,Ent),
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project_mid_loop(I1,F,Base,Sz,Table,Evs,NTablF,NTabl0).
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project_inner_loop(Sz,Sz,[],_,_,_,Ent,Ent) :- !.
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project_inner_loop(I,Sz,[ok|Evs],NBase,F,Table,Ent0,Ent) :- !,
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I1 is I+1,
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Pos is NBase+I*F+1,
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arg(Pos,Table,E1),
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Ent1 is E1+Ent0,
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project_inner_loop(I1,Sz,Evs,NBase,F,Table,Ent1,Ent).
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project_inner_loop(I,Sz,[_|Evs],NBase,F,Table,Ent0,Ent) :- !,
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I1 is I+1,
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project_inner_loop(I1,Sz,Evs,NBase,F,Table,Ent0,Ent).
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include([],_,_,[]).
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include([var(V,P,VSz,D,Parents,Ev,Tabs,Est)|LV],tab(T,Vs,Sz),V1,[var(V,P,VSz,D,Parents,Ev,Tabs,Est)|NLV]) :-
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clpbn_not_var_member(Vs,V), !,
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include(LV,tab(T,Vs,Sz),V1,NLV).
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include([var(V,P,VSz,D,Parents,Ev,Tabs,_)|LV],Table,NV,[var(V,P,VSz,D,Parents,Ev,NTabs,NEst)|NLV]) :-
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update_tables(Tabs,NTabs,Table,NV),
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compute_size(NTabs, [], NEst),
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% ( clpbn:get_atts(V,[key(Key)]) -> write(Key:NEst), nl ; true),
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include(LV,Table,NV,NLV).
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update_tables([],[Table],Table,_).
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update_tables([tab(Tab0,Vs,Sz)|Tabs],[tab(Tab0,Vs,Sz)|NTabs],Table,V) :-
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clpbn_not_var_member(Vs,V), !,
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update_tables(Tabs,NTabs,Table,V).
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update_tables([_|Tabs],NTabs,Table,V) :-
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update_tables(Tabs,NTabs,Table,V).
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bind_vals([],_,_) :- !.
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% simple case, we want a distribution on a single variable.
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%bind_vals([V],Ps) :- !,
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% clpbn:get_atts(V, [dist(Vals,_,_)]),
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% put_atts(V, posterior([V], Vals, Ps)).
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% complex case, we want a joint distribution, do it on a leader.
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% should split on cliques ?
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bind_vals(Vs,Ps,AllDiffs) :-
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get_all_combs(Vs, Vals),
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Vs = [V|_],
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put_atts(V, posterior(Vs, Vals, Ps,AllDiffs)).
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get_all_combs(Vs, Vals) :-
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get_all_doms(Vs,Ds),
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findall(L,ms(Ds,L),Vals).
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get_all_doms([], []).
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get_all_doms([V|Vs], [D|Ds]) :-
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clpbn:get_atts(V, [dist(D,_,_)]),
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get_all_doms(Vs, Ds).
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ms([], []).
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ms([H|L], [El|Els]) :-
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member(El,H),
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ms(L, Els).
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normalise(Ps0,Ps) :-
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add_all(Ps0,0.0,Sum),
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divide_by_sum(Ps0,Sum,Ps).
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add_all([],Sum,Sum).
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add_all([P|Ps0],Sum0,Sum) :-
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SumI is Sum0+P,
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add_all(Ps0,SumI,Sum).
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|
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divide_by_sum([],_,[]).
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divide_by_sum([P|Ps0],Sum,[PN|Ps]) :-
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PN is P/Sum,
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divide_by_sum(Ps0,Sum,Ps).
|
|
|
|
|
|
%
|
|
% what is actually output
|
|
%
|
|
attribute_goal(V, G) :-
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|
get_atts(V, [posterior(Vs,Vals,Ps,AllDiffs)]), !,
|
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massage_out(Vs, Vals, Ps, G, AllDiffs, V).
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|
|
|
massage_out([], Ev, _, V=Ev, _, V) :- !.
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|
massage_out(Vs, [D], [P], p(CEqs)=P, AllDiffs, _) :- !,
|
|
gen_eqs(Vs,D,Eqs),
|
|
add_alldiffs(AllDiffs,Eqs,CEqs).
|
|
massage_out(Vs, [D|Ds], [P|Ps], (p(CEqs)=P,G) , AllDiffs, V) :-
|
|
gen_eqs(Vs,D,Eqs),
|
|
add_alldiffs(AllDiffs,Eqs,CEqs),
|
|
massage_out(Vs, Ds, Ps, G, AllDiffs, V).
|
|
|
|
gen_eqs([V], [D], (V=D)) :- !.
|
|
gen_eqs([V], D, (V=D)) :- !.
|
|
gen_eqs([V|Vs], [D|Ds], ((V=D),Eqs)) :-
|
|
gen_eqs(Vs,Ds,Eqs).
|
|
|
|
add_alldiffs([],Eqs,Eqs).
|
|
add_alldiffs(AllDiffs,Eqs,(Eqs/alldiff(AllDiffs))).
|
|
|
|
|
|
get_dist_size(V,Sz) :-
|
|
get_atts(V, [size(Sz)]), !.
|
|
get_dist_size(V,Sz) :-
|
|
clpbn:get_atts(V, [dist(Vals,_,_)]), !,
|
|
length(Vals,Sz),
|
|
put_atts(V, [size(Sz)]).
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|
|