182 lines
4.8 KiB
Prolog
182 lines
4.8 KiB
Prolog
|
|
:- module(bdd, [bdd_new/2,
|
|
bdd_new/3,
|
|
bdd_from_list/3,
|
|
mtbdd_new/2,
|
|
mtbdd_new/3,
|
|
bdd_eval/2,
|
|
mtbdd_eval/2,
|
|
bdd_tree/2,
|
|
bdd_size/2,
|
|
bdd_print/2,
|
|
bdd_to_probability_sum_product/2,
|
|
bdd_close/1,
|
|
mtbdd_close/1]).
|
|
|
|
:- use_module(library(lists)).
|
|
|
|
:- use_module(library(rbtrees)).
|
|
|
|
:- use_module(library(simpbool)).
|
|
|
|
tell_warning :-
|
|
print_message(warning,functionality(cudd)).
|
|
|
|
:- catch(load_foreign_files([cudd], [], init_cudd),_,fail) -> true ; tell_warning.
|
|
|
|
bdd_new(T, Bdd) :-
|
|
term_variables(T, Vars),
|
|
bdd_new(T, Vars, Bdd).
|
|
|
|
bdd_new(T, Vars, cudd(M,X,VS,TrueVars)) :-
|
|
term_variables(Vars, TrueVars),
|
|
VS =.. [vs|TrueVars],
|
|
findall(Manager-Cudd, set_bdd(T, VS, Manager, Cudd), [M-X]).
|
|
|
|
bdd_from_list(List, Vars, cudd(M,X,VS,TrueVars)) :-
|
|
term_variables(Vars, TrueVars),
|
|
VS =.. [vs|TrueVars],
|
|
findall(Manager-Cudd, set_bdd_from_list(List, VS, Manager, Cudd), [M-X]).
|
|
|
|
set_bdd(T, VS, Manager, Cudd) :-
|
|
numbervars(VS,0,_),
|
|
( ground(T)
|
|
->
|
|
term_to_cudd(T,Manager,Cudd)
|
|
;
|
|
writeln(throw(error(instantiation_error,T)))
|
|
).
|
|
|
|
set_bdd_from_list(T0, VS, Manager, Cudd) :-
|
|
numbervars(VS,0,_),
|
|
generate_releases(T0, Manager, T),
|
|
% T0 = T,
|
|
% writeln_list(T),
|
|
list_to_cudd(T,Manager,_Cudd0,Cudd).
|
|
|
|
generate_releases(T0, Manager, T) :-
|
|
rb_empty(RB0),
|
|
reverse(T0, [H|R]),
|
|
add_releases(R, RB0, [H], Manager, T).
|
|
|
|
add_releases([], _, RR, _M, RR).
|
|
add_releases([(X = Ts)|R], RB0, RR0, M, RR) :-
|
|
term_variables(Ts, Vs), !,
|
|
add_variables(Vs, RB0, RR0, M, RBF, RRI),
|
|
add_releases(R, RBF, [(X=Ts)|RRI], M, RR).
|
|
|
|
add_variables([], RB, RR, _M, RB, RR).
|
|
add_variables([V|Vs], RB0, RR0, M, RBF, RRF) :-
|
|
rb_lookup(V, _, RB0), !,
|
|
add_variables(Vs, RB0, RR0, M, RBF, RRF).
|
|
add_variables([V|Vs], RB0, RR0, M, RBF, RRF) :-
|
|
rb_insert(RB0, V, _, RB1),
|
|
add_variables(Vs, RB1, [release_node(M,V)|RR0], M, RBF, RRF).
|
|
|
|
|
|
writeln_list([]).
|
|
writeln_list(B.Bindings) :-
|
|
writeln(B),
|
|
writeln_list(Bindings).
|
|
|
|
%list_to_cudd(H._List,_Manager,_Cudd0,_CuddF) :- writeln(l:H), fail.
|
|
list_to_cudd([],_Manager,Cudd,Cudd) :- writeln('X').
|
|
list_to_cudd(release_node(M,cudd(V)).T, Manager, Cudd0, CuddF) :- !,
|
|
write('-'), flush_output,
|
|
cudd_release_node(M,V),
|
|
list_to_cudd(T, Manager, Cudd0, CuddF).
|
|
list_to_cudd((V=0*_Par).T, Manager, _Cudd0, CuddF) :- !,
|
|
write('0'), flush_output,
|
|
term_to_cudd(0, Manager, Cudd),
|
|
V = cudd(Cudd),
|
|
list_to_cudd(T, Manager, Cudd, CuddF).
|
|
list_to_cudd((V=0).T, Manager, _Cudd0, CuddF) :- !,
|
|
write('0'), flush_output,
|
|
term_to_cudd(0, Manager, Cudd),
|
|
V = cudd(Cudd),
|
|
list_to_cudd(T, Manager, Cudd, CuddF).
|
|
list_to_cudd((V=_Tree*0).T, Manager, _Cudd0, CuddF) :- !,
|
|
write('0'), flush_output,
|
|
term_to_cudd(0, Manager, Cudd),
|
|
V = cudd(Cudd),
|
|
list_to_cudd(T, Manager, Cudd, CuddF).
|
|
list_to_cudd((V=Tree*1).T, Manager, _Cudd0, CuddF) :- !,
|
|
write('.'), flush_output,
|
|
term_to_cudd(Tree, Manager, Cudd),
|
|
V = cudd(Cudd),
|
|
list_to_cudd(T, Manager, Cudd, CuddF).
|
|
list_to_cudd((V=Tree).T, Manager, _Cudd0, CuddF) :-
|
|
write('.'), flush_output,
|
|
( ground(Tree) -> true ; throw(error(instantiation_error(Tree))) ),
|
|
term_to_cudd(Tree, Manager, Cudd),
|
|
V = cudd(Cudd),
|
|
list_to_cudd(T, Manager, Cudd, CuddF).
|
|
|
|
mtbdd_new(T, Mtbdd) :-
|
|
term_variables(T, Vars),
|
|
mtbdd_new(T, Vars, Mtbdd).
|
|
|
|
mtbdd_new(T, Vars, add(M,X,VS,Vars)) :-
|
|
VS =.. [vs|Vars],
|
|
functor(VS,vs,Sz),
|
|
findall(Manager-Cudd, (numbervars(VS,0,_),term_to_add(T,Sz,Manager,Cudd)), [M-X]).
|
|
|
|
bdd_eval(cudd(M, X, Vars, _), Val) :-
|
|
cudd_eval(M, X, Vars, Val).
|
|
bdd_eval(add(M, X, Vars, _), Val) :-
|
|
add_eval(M, X, Vars, Val).
|
|
|
|
mtbdd_eval(add(M,X, Vars, _), Val) :-
|
|
add_eval(M, X, Vars, Val).
|
|
|
|
bdd_tree(cudd(M, X, Vars, _), bdd(Dir, Tree, Vars)) :-
|
|
cudd_to_term(M, X, Vars, Dir, Tree).
|
|
bdd_tree(add(M, X, Vars, _), mtbdd(Tree, Vars)) :-
|
|
add_to_term(M, X, Vars, Tree).
|
|
|
|
mtbdd_tree(add(M,X,Vars, _), mtbdd(Dir, Tree, Vars)) :-
|
|
add_to_term(M, X, Vars, Dir, Tree).
|
|
|
|
bdd_to_probability_sum_product(cudd(M,X,_,Probs), Prob) :-
|
|
cudd_to_probability_sum_product(M, X, Probs, Prob).
|
|
|
|
bdd_close(cudd(M,_,_Vars, _)) :-
|
|
cudd_die(M).
|
|
bdd_close(add(M,_,_Vars, _)) :-
|
|
cudd_die(M).
|
|
|
|
bdd_size(cudd(M,Top,_Vars, _), Sz) :-
|
|
cudd_size(M,Top,Sz).
|
|
bdd_size(add(M,Top,_Vars, _), Sz) :-
|
|
cudd_size(M,Top,Sz).
|
|
|
|
bdd_print(cudd(M,Top,_Vars, _), File) :-
|
|
cudd_print(M, Top, File).
|
|
bdd_print(add(M,Top,_Vars, _), File) :-
|
|
cudd_print(M, Top, File).
|
|
|
|
mtbdd_close(add(M,_,_Vars,_)) :-
|
|
cudd_die(M).
|
|
|
|
/* algorithm to compute probabilitie in Prolog */
|
|
bdd_to_sp(bdd(Dir, Tree, _Vars, IVars), Binds, Prob) :-
|
|
findall(P, sp(Dir, Tree, IVars, Binds, P), [Prob]).
|
|
|
|
sp(Dir, Tree, Vars, Vars, P) :-
|
|
run_sp(Tree),
|
|
fetch(Tree, Dir, P).
|
|
|
|
run_sp([]).
|
|
run_sp(pp(P,X,L,R).Tree) :-
|
|
run_sp(Tree),
|
|
P is X*L+(1-X)*R.
|
|
run_sp(pn(P,X,L,R).Tree) :-
|
|
run_sp(Tree),
|
|
P is X*L+(1-X)*(1-R).
|
|
|
|
fetch(pp(P,_,_,_)._Tree, 1, P).
|
|
fetch(pp(P,_,_,_)._Tree, -1, N) :- N is 1-P.
|
|
fetch(pn(P,_,_,_)._Tree, 1, P).
|
|
fetch(pn(P,_,_,_)._Tree, -1, N) :- N is 1-P.
|
|
|