File: wfs.chr

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swi-prolog 9.0.4%2Bdfsg-2
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:- module(wfs,[main/0, main/1]).

:- use_module(library(chr)).
:- use_module(library(lists)).

%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% Schrijf het programma waarvan je de wellfounded semantics wil bepalen
% hieronder onder de vorm van prog/1 feiten. Let erop dat je een conjunctie
% in de body tussen haakjes zet zodat prog/1 geparsed wordt, ipv prog/n.

/*

prog(p :- p).

prog(p :- \+ p).


prog(p :- (q, \+ r)).
prog(q :- (r, \+ p)).
prog(r :- (p, \+ q)).

prog(p :- r).
prog(r :- q).
prog(q :- \+ q).

prog(p :- r).
prog(r).

prog(p :- p).
prog(s :- \+ p).
prog(y :- (s, \+ x)).
prog(x :- y).
*/
prog(a :- a).
prog(b :- b).
prog(b :- \+ a).
prog(c :- \+ b).
prog(c :- c).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%


:- chr_constraint true/1, false/1, undefined/1, aclause/2, pos/2, neg/2, nbulit/2, nbplit/2, nbucl/2, phase2/0, true2/1, undefined2/1, aclause2/2, pos2/2, nbplit2/2, phase1/0, witness1/0, witness2/0.

true(At), aclause(Cl,At) \ pos(_,Cl) <=> true.

true(At), aclause(Cl,At) \ neg(_,Cl) <=> true.

false(At), aclause(Cl,At) \ pos(_,Cl) <=> true.

false(At), aclause(Cl,At) \ neg(_,Cl) <=> true.

true(At) \ nbucl(At,_) <=> true.

true(At) \ aclause(Cl,At), nbulit(Cl,_), nbplit(Cl,_) <=> true.

false(At) \ nbucl(At,_) <=> true.

nbucl(At,0) <=> false(At).

aclause(Cl,At), nbulit(Cl,0), nbplit(Cl,0) <=> true(At).

true(At) \ pos(At,Cl), nbulit(Cl,NU), nbplit(Cl,NP)
	<=>
		NU1 is NU - 1, nbulit(Cl,NU1),
		NP1 is NP - 1, nbplit(Cl,NP1).

false(At) \ neg(At,Cl), nbulit(Cl,NU)
	<=>
		NU1 is NU - 1, nbulit(Cl,NU1).

true(At) \ neg(At,Cl), aclause(Cl,OAt), nbulit(Cl,_), nbplit(Cl,_), nbucl(OAt,N)
	<=>
		N1 is N - 1, nbucl(OAt,N1).

false(At) \ pos(At,Cl), aclause(Cl,OAt), nbulit(Cl,_), nbplit(Cl,_), nbucl(OAt,N)
	<=>
		N1 is N - 1, nbucl(OAt,N1).

witness2 \ witness2 <=> true.
phase2, nbucl(At,_)  ==> witness2, undefined2(At).
phase2, pos(At,Cl)   ==> pos2(At,Cl).
phase2, aclause(Cl,At)    ==> aclause2(Cl,At).
phase2, nbplit(Cl,N) ==> nbplit2(Cl,N).
phase2, witness2 # ID <=> phase1 pragma passive(ID).
phase2 \ nbplit2(_,_) # ID <=> true pragma passive(ID).
phase2 \ aclause2(_,_) # ID <=> true pragma passive(ID).
phase2 <=> true.


true2(At), aclause2(Cl,At) \ pos2(_,Cl) <=> true.
true2(At) \ undefined2(At) <=> true.
aclause2(Cl,At), nbplit2(Cl,0) <=> true2(At).
true2(At) \ pos2(At,Cl), nbplit2(Cl,NP)
	<=>
		NP1 is NP - 1, nbplit2(Cl,NP1).

witness1 \ witness1 <=> true.
phase1, undefined2(At) # ID1 , aclause(Cl,At) # ID2 \ pos(_,Cl) # ID3 <=> true pragma passive(ID1), passive(ID2), passive(ID3).
phase1, undefined2(At) # ID1 , aclause(Cl,At) # ID2 \ neg(_,Cl) # ID3 <=> true pragma passive(ID1), passive(ID2), passive(ID3).
phase1, undefined2(At) # ID1 \ aclause(Cl,At) # ID2 , nbulit(Cl,_) # ID3, nbplit(Cl,_) # ID4 <=> true pragma passive(ID1), passive(ID2), passive(ID3), passive(ID4).
phase1 \ undefined2(At) # ID <=> witness1, false(At) pragma passive(ID).
phase1 \ true2(_) # ID <=> true pragma passive(ID).
phase1 \ aclause2(_,_) <=> true.
phase1 \ pos2(_,_) # ID <=> true pragma passive(ID).
phase1 \ nbplit2(_,_) # ID <=> true pragma passive(ID).
phase1, witness1 # ID  <=> phase2 pragma passive(ID).
phase1 \ nbucl(At,_) # ID <=> undefined(At) pragma passive(ID).
phase1 \ pos(_,_) # ID <=> true.
phase1 \ neg(_,_) # ID <=> true pragma passive(ID).
phase1 \ aclause(_,_) # ID <=>  true pragma passive(ID).
phase1 \ nbulit(_,_) # ID <=> true pragma passive(ID).
phase1 \ nbplit(_,_) # ID <=> true pragma passive(ID).
phase1 <=> true.

/*
	p :- r.
	r.
*/
program1 :-
	nbucl(p,1),		% aantal undefined clauses voor p
	pos(r,cl1),		% positief voorkomen van r in clause cl1
	aclause(cl1,p),		% clause cl1 defineert p
	nbulit(cl1,1),		% aantal undefined literals in cl1
	nbplit(cl1,1),		% aantal positieve undefined literals in cl1
	nbucl(r,1),
	aclause(cl2,r),
	nbulit(cl2,0),
	nbplit(cl2,0).

/*
	p :- not r.
	r.
*/
program2 :-
	nbucl(p,1),
	neg(r,cl1),
	aclause(cl1,p),
	nbulit(cl1,1),
	nbplit(cl1,1),
	nbucl(r,1),
	aclause(cl2,r),
	nbulit(cl2,0),
	nbplit(cl2,0).

/*
	p :- p.
*/
program3 :-
	nbucl(p,1),
	pos(p,cl1),
	aclause(cl1,p),
	nbulit(cl1,1),
	nbplit(cl1,1).

/*
	p :- not p.
*/
program4 :-
	nbucl(p,1),
	neg(p,cl1),
	aclause(cl1,p),
	nbulit(cl1,1),
	nbplit(cl1,0).

/*
	p :- q, not r.
	q :- r, not p.
	r :- p, not q.
*/

program5 :-
	nbucl(p,1),
	pos(p,cl3),
	neg(p,cl2),
	aclause(cl1,p),
	nbulit(cl1,2),
	nbplit(cl1,1),
	nbucl(q,1),
	pos(q,cl1),
	neg(q,cl3),
	aclause(cl2,q),
	nbulit(cl2,2),
	nbplit(cl2,1),
	nbucl(r,1),
	pos(r,cl2),
	neg(r,cl1),
	aclause(cl3,r),
	nbulit(cl3,2),
	nbplit(cl3,1).


main :-
	main(1000).

main(N) :-
	cputime(T1),
	loop(N),
	cputime(T2),
	T is T2 - T1,
	write(bench(wfs ,N , T,0,hprolog)),write('.'),nl.

loop(N) :-
	( N =< 0 ->
		true
	;
		( prog, fail ; true),
		M is N - 1,
		loop(M)
	).

prog :-
	findall(Clause,wfs:prog(Clause),Clauses),
	process(Clauses,1),
	setof(At,B^(wfs:prog(At :- B) ; wfs:prog(At), atom(At)),Ats),
	process_atoms(Ats),
	phase2.

process([],_).
process([C|Cs],N) :-
	( C = (HAt :- B) ->
		aclause(N,HAt),
		conj2list(B,Literals,[]),
		process_literals(Literals,N,NbULit,NbPLit),
		nbulit(N,NbULit),
		nbplit(N,NbPLit)
	;
		C = HAt,
		aclause(N,HAt),
		nbulit(N,0),
		nbplit(N,0)
	),
	N1 is N + 1,
	process(Cs,N1).

conj2list(G,L,T) :-
	( G = (G1,G2) ->
		conj2list(G1,L,T1),
		conj2list(G2,T1,T)
	;
		L = [G|T]
	).

process_literals([],_,0,0).
process_literals([L|R],Cl,U,P) :-
	process_literals(R,Cl,U1,P1),
	( L = (\+ At) ->
		neg(At,Cl),
		P = P1,
		U is U1 + 1
	;
		pos(L,Cl),
		P is P1 + 1,
		U is U1 + 1
	).

process_atoms([]).
process_atoms([A|As]) :-
	findall(A,wfs:prog(A :- _),L),
	length(L,N),
	nbucl(A,N),
	process_atoms(As).