This repository has been archived on 2023-08-20. You can view files and clone it, but cannot push or open issues or pull requests.
yap-6.3/packages/CLPBN/clpbn.yap
2010-06-30 17:54:58 +02:00

418 lines
11 KiB
Prolog

:- module(clpbn, [{}/1,
clpbn_flag/2,
set_clpbn_flag/2,
clpbn_flag/3,
clpbn_key/2,
clpbn_init_solver/4,
clpbn_run_solver/3,
clpbn_init_solver/5,
clpbn_run_solver/4,
clpbn_init_graph/1,
op( 500, xfy, with)]).
:- use_module(library(atts)).
:- use_module(library(lists)).
:- use_module(library(terms)).
%
% avoid the overhead of using goal_expansion/2.
%
:- multifile
user:term_expansion/2.
:- dynamic
user:term_expansion/2.
:- attribute key/1, dist/2, evidence/1, starter/0.
:- use_module('clpbn/vel',
[vel/3,
check_if_vel_done/1,
init_vel_solver/4,
run_vel_solver/3
]).
:- use_module('clpbn/jt',
[jt/3,
init_jt_solver/4,
run_jt_solver/3
]).
:- use_module('clpbn/bnt',
[do_bnt/3,
check_if_bnt_done/1
]).
:- use_module('clpbn/gibbs',
[gibbs/3,
check_if_gibbs_done/1,
init_gibbs_solver/4,
run_gibbs_solver/3
]).
:- use_module('clpbn/pgrammar',
[init_pcg_solver/4,
run_pcg_solver/3,
pcg_init_graph/0
]).
:- use_module('clpbn/graphs',
[
clpbn2graph/1
]).
:- use_module('clpbn/dists',
[
dist/4,
get_dist/4,
get_evidence_position/3,
get_evidence_from_position/3,
additive_dists/6
]).
:- use_module('clpbn/evidence',
[
store_evidence/1,
add_evidence/2,
incorporate_evidence/2,
check_stored_evidence/2,
put_evidence/2
]).
:- use_module('clpbn/utils',
[
sort_vars_by_key/3
]).
:- use_module('clpbn/graphviz',
[clpbn2gviz/4]).
:- dynamic solver/1,output/1,use/1,suppress_attribute_display/1, parameter_softening/1, em_solver/1.
solver(vel).
em_solver(vel).
%output(xbif(user_error)).
%output(gviz(user_error)).
output(no).
suppress_attribute_display(false).
parameter_softening(m_estimate(10)).
clpbn_flag(Flag,Option) :-
clpbn_flag(Flag, Option, Option).
set_clpbn_flag(Flag,Option) :-
clpbn_flag(Flag, _, Option).
clpbn_flag(output,Before,After) :-
retract(output(Before)),
assert(output(After)).
clpbn_flag(solver,Before,After) :-
retract(solver(Before)),
assert(solver(After)).
clpbn_flag(em_solver,Before,After) :-
retract(em_solver(Before)),
assert(em_solver(After)).
clpbn_flag(bnt_solver,Before,After) :-
retract(bnt:bnt_solver(Before)),
assert(bnt:bnt_solver(After)).
clpbn_flag(bnt_path,Before,After) :-
retract(bnt:bnt_path(Before)),
assert(bnt:bnt_path(After)).
clpbn_flag(bnt_model,Before,After) :-
retract(bnt:bnt_model(Before)),
assert(bnt:bnt_model(After)).
clpbn_flag(suppress_attribute_display,Before,After) :-
retract(suppress_attribute_display(Before)),
assert(suppress_attribute_display(After)).
clpbn_flag(parameter_softening,Before,After) :-
retract(parameter_softening(Before)),
assert(parameter_softening(After)).
{_} :-
solver(none), !.
{Var = Key with Dist} :-
put_atts(El,[key(Key),dist(DistInfo,Parents)]),
dist(Dist, DistInfo, Key, Parents),
add_evidence(Var,Key,DistInfo,El)
% ,writeln({Var = Key with Dist})
.
check_constraint(Constraint, _, _, Constraint) :- var(Constraint), !.
check_constraint((A->D), _, _, (A->D)) :- var(A), !.
check_constraint((([A|B].L)->D), Vars, NVars, (([A|B].NL)->D)) :- !,
check_cpt_input_vars(L, Vars, NVars, NL).
check_constraint(Dist, _, _, Dist).
check_cpt_input_vars([], _, _, []).
check_cpt_input_vars([V|L], Vars, NVars, [NV|NL]) :-
replace_var(Vars, V, NVars, NV),
check_cpt_input_vars(L, Vars, NVars, NL).
replace_var([], V, [], V).
replace_var([V|_], V0, [NV|_], NV) :- V == V0, !.
replace_var([_|Vars], V, [_|NVars], NV) :-
replace_var(Vars, V, NVars, NV).
add_evidence(V,Key,Distinfo,NV) :-
nonvar(V), !,
get_evidence_position(V, Distinfo, Pos),
check_stored_evidence(Key, Pos),
clpbn:put_atts(NV,evidence(Pos)).
add_evidence(V,K,_,V) :-
add_evidence(K,V).
clpbn_marginalise(V, Dist) :-
attributes:all_attvars(AVars),
project_attributes([V], AVars),
clpbn_display:get_atts(V, posterior(_,_,Dist,_)).
%
% called by top-level
% or by call_residue/2
%
project_attributes(GVars, AVars) :-
suppress_attribute_display(false),
AVars = [_|_],
solver(Solver),
( GVars = [_|_] ; Solver = graphs), !,
clpbn_vars(AVars, DiffVars, AllVars),
get_clpbn_vars(GVars,CLPBNGVars0),
simplify_query_vars(CLPBNGVars0, CLPBNGVars),
(output(xbif(XBifStream)) -> clpbn2xbif(XBifStream,vel,AllVars) ; true),
(output(gviz(XBifStream)) -> clpbn2gviz(XBifStream,sort,AllVars,GVars) ; true),
(
Solver = graphs
->
write_out(Solver, [[]], AllVars, DiffVars)
;
write_out(Solver, [CLPBNGVars], AllVars, DiffVars)
).
project_attributes(_, _).
clpbn_vars(AVars, DiffVars, AllVars) :-
sort_vars_by_key(AVars,SortedAVars,DiffVars),
incorporate_evidence(SortedAVars, AllVars).
get_clpbn_vars([],[]).
get_clpbn_vars([V|GVars],[V|CLPBNGVars]) :-
get_atts(V, [key(_)]), !,
get_clpbn_vars(GVars,CLPBNGVars).
get_clpbn_vars([_|GVars],CLPBNGVars) :-
get_clpbn_vars(GVars,CLPBNGVars).
simplify_query_vars(LVs0, LVs) :-
sort(LVs0,LVs1),
get_rid_of_ev_vars(LVs1,LVs).
%
% some variables might already have evidence in the data-base.
%
get_rid_of_ev_vars([],[]).
get_rid_of_ev_vars([V|LVs0],LVs) :-
clpbn:get_atts(V, [dist(Id,_),evidence(Pos)]), !,
get_evidence_from_position(Ev, Id, Pos),
clpbn_display:put_atts(V, [posterior([],Ev,[],[])]), !,
get_rid_of_ev_vars(LVs0,LVs).
get_rid_of_ev_vars([V|LVs0],[V|LVs]) :-
get_rid_of_ev_vars(LVs0,LVs).
% do nothing if we don't have query variables to compute.
write_out(graphs, _, AVars, _) :-
clpbn2graph(AVars).
write_out(vel, GVars, AVars, DiffVars) :-
vel(GVars, AVars, DiffVars).
write_out(jt, GVars, AVars, DiffVars) :-
jt(GVars, AVars, DiffVars).
write_out(gibbs, GVars, AVars, DiffVars) :-
gibbs(GVars, AVars, DiffVars).
write_out(bnt, GVars, AVars, DiffVars) :-
do_bnt(GVars, AVars, DiffVars).
get_bnode(Var, Goal) :-
get_atts(Var, [key(Key),dist(Dist,Parents)]),
get_dist(Dist,_,Domain,CPT),
(Parents = [] -> X = tab(Domain,CPT) ; X = tab(Domain,CPT,Parents)),
dist_goal(X, Key, Goal0),
include_evidence(Var, Goal0, Key, Goali),
include_starter(Var, Goali, Key, Goal).
include_evidence(Var, Goal0, Key, ((Key:-Ev),Goal0)) :-
get_atts(Var, [evidence(Ev)]), !.
include_evidence(_, Goal0, _, Goal0).
include_starter(Var, Goal0, Key, ((:-Key),Goal0)) :-
get_atts(Var, [starter]), !.
include_starter(_, Goal0, _, Goal0).
dist_goal(Dist, Key, (Key=NDist)) :-
term_variables(Dist, DVars),
process_vars(DVars, DKeys),
my_copy_term(Dist,DVars, NDist,DKeys).
my_copy_term(V, DVars, Key, DKeys) :-
find_var(DVars, V, Key, DKeys).
my_copy_term(A, _, A, _) :- atomic(A), !.
my_copy_term(T, Vs, NT, Ks) :-
T =.. [Na|As],
my_copy_terms(As, Vs, NAs, Ks),
NT =.. [Na|NAs].
my_copy_terms([], _, [], _).
my_copy_terms([A|As], Vs, [NA|NAs], Ks) :-
my_copy_term(A, Vs, NA, Ks),
my_copy_terms(As, Vs, NAs, Ks).
find_var([V1|_], V, Key, [Key|_]) :- V1 == V, !.
find_var([_|DVars], V, Key, [_|DKeys]) :-
find_var(DVars, V, Key, DKeys).
process_vars([], []).
process_vars([V|Vs], [K|Ks]) :-
process_var(V, K),
process_vars(Vs, Ks).
process_var(V, K) :- get_atts(V, [key(K)]), !.
% oops: this variable has no attributes.
process_var(V, _) :- throw(error(instantiation_error,clpbn(attribute_goal(V)))).
%
% unify a CLPBN variable with something.
%
verify_attributes(Var, T, Goal) :-
get_atts(Var, [key(Key),dist(Dist,Parents)]), !,
/* oops, someone trying to bind a clpbn constrained variable */
bind_clpbn(T, Var, Key, Dist, Parents, Goal).
verify_attributes(_, _, []).
bind_clpbn(T, Var, _, _, _, do_not_bind_variable([put_evidence(T,Var)])) :-
nonvar(T),
!.
bind_clpbn(T, Var, Key, Dist, Parents, []) :- var(T),
get_atts(T, [key(Key1),dist(Dist1,Parents1)]),
(
bind_clpbns(Key, Dist, Parents, Key1, Dist1, Parents1)
->
(
get_atts(T, [evidence(Ev1)]) ->
bind_evidence_from_extra_var(Ev1,Var)
;
get_atts(Var, [evidence(Ev)]) ->
bind_evidence_from_extra_var(Ev,T)
;
true
)
;
fail
).
bind_clpbn(_, Var, _, _, _, _, []) :-
use(bnt),
check_if_bnt_done(Var), !.
bind_clpbn(_, Var, _, _, _, _, []) :-
use(vel),
check_if_vel_done(Var), !.
bind_clpbn(_, Var, _, _, _, _, []) :-
use(jt),
check_if_vel_done(Var), !.
bind_clpbn(T, Var, Key0, _, _, _, []) :-
get_atts(Var, [key(Key)]), !,
(
Key = Key0 -> true
;
% let us not loose whatever we had.
put_evidence(T,Var)
).
fresh_attvar(Var, NVar) :-
get_atts(Var, LAtts),
put_atts(NVar, LAtts).
% I will now allow two CLPBN variables to be bound together.
%bind_clpbns(Key, Dist, Parents, Key, Dist, Parents).
bind_clpbns(Key, Dist, _Parents, Key1, Dist1, _Parents1) :-
Key == Key1, !,
get_dist(Dist,_Type,_Domain,_Table),
get_dist(Dist1,_Type1,_Domain1,_Table1),
Dist = Dist1.
bind_clpbns(Key, _, _, _, Key1, _, _, _) :-
Key\=Key1, !, fail.
bind_clpbns(_, _, _, _, _, _, _, _) :-
format(user_error, 'unification of two bayesian vars not supported~n', []).
same_parents([],[]).
same_parents([P|Parents],[P1|Parents1]) :-
same_node(P,P1),
same_parents(Parents,Parents1).
same_node(P,P1) :- P == P1, !.
same_node(P,P1) :-
get_atts( P,[key(K)]),
get_atts(P1,[key(K)]),
P = P1.
bind_evidence_from_extra_var(Ev1,Var) :-
get_atts(Var, [evidence(Ev0)]), !,
Ev0 = Ev1.
bind_evidence_from_extra_var(Ev1,Var) :-
put_atts(Var, [evidence(Ev1)]).
user:term_expansion((A :- {}), ( :- true )) :- !, % evidence
prolog_load_context(module, M),
store_evidence(M:A).
clpbn_key(Var,Key) :-
get_atts(Var, [key(Key)]).
%
% This is a routine to start a solver, called by the learning procedures (ie, em).
% LVs is a list of lists of variables one is interested in eventually marginalising out
% Vs0 gives the original graph
% AllDiffs gives variables that are not fully constrainted, ie, we don't fully know
% the key. In this case, we assume different instances will be bound to different
% values at the end of the day.
%
clpbn_init_solver(LVs, Vs0, VarsWithUnboundKeys, State) :-
solver(Solver),
clpbn_init_solver(Solver, LVs, Vs0, VarsWithUnboundKeys, State).
clpbn_init_solver(gibbs, LVs, Vs0, VarsWithUnboundKeys, State) :-
init_gibbs_solver(LVs, Vs0, VarsWithUnboundKeys, State).
clpbn_init_solver(vel, LVs, Vs0, VarsWithUnboundKeys, State) :-
init_vel_solver(LVs, Vs0, VarsWithUnboundKeys, State).
clpbn_init_solver(jt, LVs, Vs0, VarsWithUnboundKeys, State) :-
init_jt_solver(LVs, Vs0, VarsWithUnboundKeys, State).
clpbn_init_solver(pcg, LVs, Vs0, VarsWithUnboundKeys, State) :-
init_pcg_solver(LVs, Vs0, VarsWithUnboundKeys, State).
%
% LVs is the list of lists of variables to marginalise
% Vs is the full graph
% Ps are the probabilities on LVs.
%
%
clpbn_run_solver(LVs, LPs, State) :-
solver(Solver),
clpbn_run_solver(Solver, LVs, LPs, State).
clpbn_run_solver(gibbs, LVs, LPs, State) :-
run_gibbs_solver(LVs, LPs, State).
clpbn_run_solver(vel, LVs, LPs, State) :-
run_vel_solver(LVs, LPs, State).
clpbn_run_solver(jt, LVs, LPs, State) :-
run_jt_solver(LVs, LPs, State).
clpbn_run_solver(pcg, LVs, LPs, State) :-
run_pcg_solver(LVs, LPs, State).
add_keys(Key1+V1,_Key2,Key1+V1).
clpbn_init_graph(pcg) :- !,
pcg_init_graph.
clpbn_init_graph(_).