2010-03-18 15:11:21 +00:00
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/*==============================================================================
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* LPAD and CP-Logic reasoning suite
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* File best.pl
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* Goal oriented interpreter for LPADs based on SLDNF
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* Copyright (c) 2009, Stefano Bragaglia
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*============================================================================*/
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:- dynamic rule/4, def_rule/2.
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/* EXTERNAL FILE
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* -------------
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* The following libraries are required by the program to work fine.
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*/
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:- use_module(library(lists)).
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:- use_module(library(system)).
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:- use_module(library(ugraphs)).
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:- use_module(params).
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2010-03-21 10:49:19 +00:00
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:- use_module(tptree_lpad).
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2010-03-18 15:11:21 +00:00
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:- use_module(utility).
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% :- source.
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% :- yap_flag(single_var_warnings, on).
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/* SOLVING PREDICATES
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* ------------------
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* The predicates in this section solve any given problem with several class of
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* algorithms.
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*
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* Note: the original predicates (no more need and eligible to be deleted) have
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* been moved to the end of the file.
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*/
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/* solve(GoalsList, Prob, ResTime, BddTime)
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* ----------------------------------------
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* This predicate computes the probability of a given list of goals using an
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* exact algorithm. It also returns the number of handled BDDs (trivial but
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* present for simmetry with other solving predicates), CPUTime spent in
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* performing resolution and in handling the BDDs.
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*
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* INPUT
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* - GoalsList: given list of goal to work on.
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*
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* OUTPUT
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* - Prob: the resulting exact probability for the given list of goals.
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* - Count: number of BDDs handled by the algorithm (trivial, since it's always 1).
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* - ResTime: cpu time spent on performing resolution.
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* - BddTime: cpu time spent on handling BDDs.
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*/
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solve(GoalsList, Prob, ResTime, BddTime) :-
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% Resetting the clocks...
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statistics(walltime, [_, _]),
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% Performing resolution...
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findall(Deriv, exact(GoalsList, Deriv), List),
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% Taking elapsed times...
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statistics(walltime, [_, ElapResTime]),
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ResTime is ElapResTime/1000,
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% Building and solving equivalent bdds...
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init_ptree(1),
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fatto(List),
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insert_list_ptree(List, 1),
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bdd_ptree_map(1, 'bdd.txt', 'bdd.par', 'bdd.map'),
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delete_ptree(1),
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run_file('bdd.txt','bdd.par', Temp),
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(Temp == timeout ->
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Prob is -1.0;
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Prob is Temp),
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% Taking elapsed times
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statistics(walltime, [_, ElapBddTime]),
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BddTime is ElapBddTime/1000.
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/* exact(GoalsList, CIn, COut) takes a list of goals and an input C set
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and returns an output C set
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The C set is a list of triple (N, R, S) where
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- N is the index of the head atom used, starting from 0
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- R is the index of the non ground rule used, starting from 1
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- S is the substitution of rule R, in the form of a list whose elements
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are of the form 'VarName'=value
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*/
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exact(GoalsList, Deriv) :-
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exact(GoalsList, [], Deriv).
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exact([], C, C) :- !.
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exact([bagof(V, EV^G, L)|T], CIn, COut) :- !,
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list2and(GL, G),
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bagof((V, C), EV^exact(GL, CIn, C), LD),
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length(LD, N),
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build_initial_graph(N, GrIn),
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build_graph(LD, 0, GrIn, Gr),
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clique(Gr, Clique),
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build_Cset(LD, Clique, L, [], C1),
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remove_duplicates_eq(C1, C2),
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exact(T, C2, COut).
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exact([bagof(V, G, L)|T], CIn, COut) :- !,
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list2and(GL, G),
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bagof((V, C), exact(GL, CIn, C), LD),
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length(LD, N),
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build_initial_graph(N, GrIn),
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build_graph(LD, 0, GrIn, Gr),
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clique(Gr, Clique),
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build_Cset(LD, Clique, L, [], C1),
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remove_duplicates_eq(C1, C2),
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exact(T, C2, COut).
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exact([setof(V, EV^G, L)|T], CIn, COut) :- !,
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list2and(GL, G),
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setof((V, C), EV^exact(GL, CIn, C), LD),
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length(LD, N),
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build_initial_graph(N, GrIn),
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build_graph(LD, 0, GrIn, Gr),
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clique(Gr, Clique),
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build_Cset(LD, Clique, L1, [], C1),
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remove_duplicates(L1, L),
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exact(T, C1, COut).
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exact([setof(V, G, L)|T], CIn, COut) :- !,
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list2and(GL, G),
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setof((V, C), exact(GL, CIn, C), LD),
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length(LD, N),
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build_initial_graph(N, GrIn),
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build_graph(LD, 0, GrIn, Gr),
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clique(Gr, Clique),
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build_Cset(LD, Clique, L1, [], C1),
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remove_duplicates(L1, L),
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exact(T, C1, COut).
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exact([\+ H|T], CIn, COut) :-
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builtin(H), !,
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call((\+ H)),
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exact(T, CIn, COut).
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exact([\+ H |T], CIn, COut) :- !,
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list2and(HL, H),
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findall(D, find_deriv(HL, D), L),
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choose_clauses(CIn, L, C1),
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exact(T, C1, COut).
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exact([H|T], CIn, COut) :-
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builtin(H), !,
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call(H),
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exact(T, CIn, COut).
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exact([H|T], CIn, COut) :-
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def_rule(H, B),
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append(B, T, NG),
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exact(NG, CIn, COut).
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exact([H|T], CIn, COut) :-
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find_rule(H, (R, S, N), B, CIn),
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solve_pres(R, S, N, B, T, CIn, COut).
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solve_pres(R, S, N, B, T, CIn, COut) :-
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member_eq((N, R, S), CIn), !,
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append(B, T, NG),
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exact(NG, CIn, COut).
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solve_pres(R, S, N, B, T, CIn, COut) :-
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append(CIn, [(N, R, S)], C1),
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append(B, T, NG),
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exact(NG, C1, COut).
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/* find_rule(G, (R, S, N), Body, C)
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* --------------------------------
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* This predicate takes a goal G and the current C set and returns the index R
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* of a disjunctive rule resolving with G together with the index N of the
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* resolving head, the substitution S and the Body of the rule.
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*/
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find_rule(H, (R, S, N), Body, C) :-
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rule(H, _P, N, R, S, _NH, _Head, Body),
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not_already_present_with_a_different_head(N, R, S, C).
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/* run_file(BDDFile, BDDParFile, Prob)
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* -----------------------------------
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* This predicate calls for the resolution of a BDD via file.
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*/
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run_file(BDDFile, BDDParFile, Prob) :-
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ResultFile = 'result.txt',
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library_directory(Dir),
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setting(timeout, BDDTime),
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(BDDTime = no ->
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atomic_concat([Dir, '/LPADBDD -l ', BDDFile, ' -i ', BDDParFile,' > ', ResultFile], Command);
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atomic_concat([Dir, '/LPADBDD -l ', BDDFile, ' -i ', BDDParFile,' -t ', BDDTime,' > ', ResultFile], Command)),
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%statistics(walltime,_),
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shell(Command, Return),
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(Return =\= 0 ->
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Status = timeout,
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Prob = Status;
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see(ResultFile),
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read(elapsed_construction(_TimeConstruction)),
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read(probability(Prob)),
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read(elapsed_traversing(_TimeTraversing)),
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seen,
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%write(probability(Prob)),nl,
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%read(_),
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%delete_file(ResultFile),
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Status = ok
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% format("Construction time ~f traversing time ~f~Number",[TimeConstruction, TimeTraversing])
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).
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%statistics(walltime,[_,E3]),
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%format(user,'~w ms BDD processing~Number',[E3]),
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% format("Status ~a~Number",[Status]).
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/* insert_list_ptree([Head|Tail], Trie)
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* ------------------------------------
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* This predicate inserts the given list in a trie.
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*/
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insert_list_ptree([], _Trie).
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insert_list_ptree([Head|Tail], Trie) :-
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reverse(Head, Head1),
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insert_ptree(Head1, Trie),
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insert_list_ptree(Tail, Trie).
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