276 lines
8.9 KiB
Perl
276 lines
8.9 KiB
Perl
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/*==============================================================================
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* LPAD and CP-Logic reasoning suite
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* File: montecarlo.pl
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* Solves LPADs with Monte Carlo (main predicate: solve(Goals, Prob, Samples, ResTime, BddTime)
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* Copyright (c) 2009, Stefano Bragaglia
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*============================================================================*/
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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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:- dynamic rule/4, def_rule/2, randx/1, randy/1, randz/1.
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:- use_module(library(lists)).
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:- use_module(library(random)).
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:- use_module(library(ugraphs)).
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:- use_module(params).
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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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/* Starting seed. */
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randx(1).
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randy(1).
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randz(1).
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/* newsample
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* ---------
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* This predicate programmatically generates and sets a new seed for the
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* algorithm.
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*/
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newsample :-
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retract(randx(X)),
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randy(Y),
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randz(Z),
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(X =< 30269 ->
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SuccX is X + 1,
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assert(randx(SuccX));
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assert(randx(1)),
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retract(randy(_)),
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(Y =< 30307 ->
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SuccY is Y + 1,
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assert(randy(SuccY));
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assert(randy(1)),
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retract(randz(_)),
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(Z =< 30323 ->
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SuccZ is Z + 1,
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assert(randz(SuccZ));
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assert(randz(1))))),
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setrand(rand(X, Y, Z)).
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/* solve(Goals, Samples, Time, Lower, Prob, Upper)
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* -----------------------------------------------
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* This predicate calls the Monte Carlo solving method for the current problem.
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* It requires the Goals to fulfil and returns the number of Samples considered,
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* the Time required, the extimated Probability and the Lower and Upper bounds.
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*
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* INPUT
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* - Goals: given list of goals to fulfil.
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*
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* OUTPUT
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* - Samples: number of samples considered to solve the problem.
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* - Time: time required to solve the problem.
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* - Lower: lower end of the confidence interval.
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* - Prob: extimated probability.
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* - Upper: upper end of the confidence interval.
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*/
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solve(Goals, Samples, Time, Lower, Prob, Upper) :-
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% Retrieving functional parameters...
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setting(k, K),
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setting(min_error, MinError),
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% Resetting the clocks...
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statistics(walltime, [_, _]),
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% Performing resolution...
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montecarlo(0, 0, Goals, K, MinError, Samples, Lower, Prob, Upper),
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% Taking elapsed times...
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statistics(walltime, [_, ElapTime]),
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% Setting values...
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Time is ElapTime/1000.
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/* montecarlo(Count, Success, Goals, K, MinError, Samples, Lower, Prob, Upper)
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* ---------------------------------------------------------------------------
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* This tail recursive predicate solves the problem currently in memory with a
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* Monte Carlo approach.
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* It requires the number of samples and successes so far (Count and Success),
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* the desired list of Goals to fulfil, the number K of samples to consider at
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* once and the threshold MinError for the binomial proportion confidence
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* interval.
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* It returns the total number of Samples considered, the Lower and Upper ends
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* of the the binomial proportion confidence interval and the extimated Prob.
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*
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* INPUT
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* - Count: number of samples considered so far.
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* - Success: number of successfull samples considered so far.
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* - Goals: list of goals to fulfil.
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* - K: number of samples to consider at once.
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* - MinError: threshold for the binomial proportion confidence interval.
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*
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* OUTPUT
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* - Samples: total number of samples considered.
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* - Lower: lower end of the the binomial proportion confidence interval.
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* - Prob: extimated probability.
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* - Upper: upper end of the the binomial proportion confidence interval.
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*
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* NB: This method is based on the binomial proportion confidence interval and
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* the Brown's rule of thumb to avoid the case the sample proportion is
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* exactly 0.0 or 1.0 and doesn't make use of BDDs.
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*/
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montecarlo(Count, Success, Goals, K, MinError, Samples, Lower, Prob, Upper) :-
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/* Decomment the following line if you want to test the algorithm with an
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incremental seed for each sample.
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newsample,
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*/
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main(Goals, [], _Explan, Valid),
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N is Count + 1,
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S is Success + Valid,
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(N mod K =:= 0 ->
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% format("Advancement: ~t~d/~d~30+~n", [S, N]),
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P is S / N,
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D is N - S,
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Semi is 2 * sqrt(P * (1 - P) / N),
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Int is 2 * Semi,
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/* N * P > 5; N * S / N > 5; S > 5
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* N (1 - P) > 5; N (1 - S / N) > 5; N (N - S) / N > 5; N - S > 5
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*/
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((S > 5, D > 5, (Int < MinError; Int =:= 0)) ->
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Samples is N,
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Lower is P - Semi,
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Prob is P,
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Upper is P + Semi;
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montecarlo(N, S, Goals, K, MinError, Samples, Lower, Prob, Upper));
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montecarlo(N, S, Goals, K, MinError, Samples, Lower, Prob, Upper)).
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/* null
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* ----
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* This is dummy predicate to use sparingly when needed.
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* Typical uses are as spying predicate during tracing or as dead branch in
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* ( -> ; ) predicate.
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*/
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null.
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/* main(Goals, Explan0, Explan1, Valid)
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* ------------------------------------
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* This tail recursive predicate looks for a solution to the given Goals
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* starting from the given Explan0 and returns the final Explan and 1 (0 otherwise) if it is a
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* Valid sample for Montecarlo.
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*/
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main([], Explan, Explan, 1).
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main([\+ Goal|Tail], Explan0, Explan1, Valid) :-
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builtin(Goal), !,
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(call((\+ Goal)) ->
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main(Tail, Explan0, Explan1, Valid);
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Explan1 = Explan0,
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Valid = 0).
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main([Goal|Tail], Explan0, Explan1, Valid) :-
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builtin(Goal), !,
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(call(Goal) ->
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main(Tail, Explan0, Explan1, Valid);
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Explan1 = Explan0,
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Valid = 0).
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main([Goal|Tail], Explan0, Explan1, Valid) :-
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findall((IsSample, Goals, Step), explore([Goal|Tail], Explan0, IsSample, Goals, Step), List),
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cycle(List, Explan0, Explan1, Valid).
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/* explore([Goal|Tail], Explan, Valid, Goals, Step)
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* ------------------------------------------------
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* This predicate looks for a Body and the Step to reach it from the given Goal
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* and Explan and returns 1 (0 otherwise) if they are a Valid sample for
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* Montecarlo.
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* Please note that Body and Step are meaningfull only when Valid is 1.
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*
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* This comment has to be fixed.
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*/
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explore([Goal|Tail], _Explan, 1, Goals, []) :-
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def_rule(Goal, Body),
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append(Body, Tail, Goals).
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explore([Goal|Tail], Explan, Valid, Goals, Step) :-
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findrule(Goal, Explan, Valid, Body, (HeadID, RuleID, Subst)),
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append(Body, Tail, Goals),
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(member_eq((HeadID, RuleID, Subst), Explan) ->
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Step = [];
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Step = [(HeadID, RuleID, Subst)]).
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/* findrule(Goal, Explan, Valid, Body, (HeadID, RuleID, Subst))
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* ---------------------------------------------------------------
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* This predicate finds a rule that matches with the given Goal and Explan and
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* returns 1 (0 otherwise) if it is a Valid sample for Montecarlo.
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* If the sample is Valid, the other return parameters are also meaningfull and
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* are the Body and (RuleID, Subst, HeadIS) of the rule that matches with the
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* given Goal and Explan.
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*
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* This comment has to be fixed.
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*/
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findrule(Goal, Explan, Valid, Body, (HeadId, RuleId, Subst)) :-
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rule(Goal, _Prob, Required, RuleId, Subst, _Heads, HeadsList, Body),
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sample(HeadsList, HeadId),
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not_already_present_with_a_different_head(HeadId, RuleId, Subst, Explan),
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(HeadId =:= Required ->
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Valid = 1;
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Valid = 0).
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/* sample(Heads, RuleId, HeadId, Subst)
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* ------------------------------------
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* This tail recursive predicate samples a random head among the given Heads of
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* the given RuleId and returns its HeadId and Subst.
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*/
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sample(HeadList, HeadId) :-
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random(Prob),
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sample(HeadList, 0, 0, Prob, HeadId), !.
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sample([_HeadTerm:HeadProb|Tail], Index, Prev, Prob, HeadId) :-
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Succ is Index + 1,
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Next is Prev + HeadProb,
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(Prob =< Next ->
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HeadId = Index;
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sample(Tail, Succ, Next, Prob, HeadId)).
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/* cycle([(IsSample, Body, [Step])|Tail], Explan0, Explan1, Found)
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* -----------------------------------------------------------------
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* This tail recursive predicate analyzes the given Body and Step to reach it
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* and returns 0 as it's not a Valid sample for Montecarlo.
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* If it is Valid, it looks for a solution to the Body and the given Goals
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* starting from the Step and the given Explan and returns 1 if it finds a
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* Valid one.
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* If it does not find it, it considers the next Body and Step and returns their
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* Valid value.
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*
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* NB: This comment needs to be updated.
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*/
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cycle([], Explan, Explan, 0).
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cycle([(0, _Goals, Step)|Tail], Explan0, Explan1, IsSample) :- !,
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append(Step, Explan0, Explan2),
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cycle(Tail, Explan2, Explan1, IsSample).
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cycle([(1, Goals, Step)|Tail], Explan0, Explan1, IsSample) :-
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append(Step, Explan0, Explan),
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main(Goals, Explan, Explan2, Valid),
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(Valid == 1 ->
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Explan1 = Explan2,
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IsSample = 1;
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cycle(Tail, Explan2, Explan1, IsSample)).
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