examples/benchmarks/holmer/queens_8.pl - prolog-cafe - Git at Google

 % generated: 10 November 1989
 % option(s):
 %
 %   (queens) queens_8
 %
 %   from Sterling and Shapiro, "The Art of Prolog," page 211.
 %
 %   solve the 8 queens problem

 queens_8 :- queens(8,_), !.

 %   This program solves the N queens problem:  place N pieces on an N
 %   by N rectangular board so that no two pieces are on the same line
 %   - horizontal, vertical, or diagonal.  (N queens so placed on an N
 %   by N chessboard are unable to attack each other in a single move
 %   under the rules of chess.)  The strategy is incremental generate-
 %   and-test.
 %
 %   A solution is specified by a permutation of the list of numbers 1 to
 %   N.  The first element of the list is the row number for the queen in
 %   the first column, the second element is the row number for the queen
 %   in the second column, et cetera.  This scheme implicitly incorporates
 %   the observation that any solution of the problem has exactly one queen
 %   in each column.
 %
 %   The program distinguishes symmetric solutions.  For example,
 %
 %   ?- queens(4, Qs).
 %
 %   produces
 %
 %   Qs = [3,1,4,2] ;
 %
 %   Qs = [2,4,1,3]

 queens(N,Qs) :-
 	range(1,N,Ns),
 	queens(Ns,[],Qs).

 queens([],Qs,Qs).
 queens(UnplacedQs,SafeQs,Qs) :-
 	select(UnplacedQs,UnplacedQs1,Q),
 	not_attack(SafeQs,Q),
 	queens(UnplacedQs1,[Q|SafeQs],Qs).

 not_attack(Xs,X) :-
 	not_attack(Xs,X,1).

 not_attack([],_,_) :- !.
 not_attack([Y|Ys],X,N) :-
 	X =\= Y+N, X =\= Y-N,
 	N1 is N+1,
 	not_attack(Ys,X,N1).

 select([X|Xs],Xs,X).
 select([Y|Ys],[Y|Zs],X) :- select(Ys,Zs,X).

 range(N,N,[N]) :- !.
 range(M,N,[M|Ns]) :-
 	M < N,
 	M1 is M+1,
 	range(M1,N,Ns).
	% generated: 10 November 1989
	% option(s):
	%
	% (queens) queens_8
	%
	% from Sterling and Shapiro, "The Art of Prolog," page 211.
	%
	% solve the 8 queens problem

	queens_8 :- queens(8,_), !.

	% This program solves the N queens problem: place N pieces on an N
	% by N rectangular board so that no two pieces are on the same line
	% - horizontal, vertical, or diagonal. (N queens so placed on an N
	% by N chessboard are unable to attack each other in a single move
	% under the rules of chess.) The strategy is incremental generate-
	% and-test.
	%
	% A solution is specified by a permutation of the list of numbers 1 to
	% N. The first element of the list is the row number for the queen in
	% the first column, the second element is the row number for the queen
	% in the second column, et cetera. This scheme implicitly incorporates
	% the observation that any solution of the problem has exactly one queen
	% in each column.
	%
	% The program distinguishes symmetric solutions. For example,
	%
	% ?- queens(4, Qs).
	%
	% produces
	%
	% Qs = [3,1,4,2] ;
	%
	% Qs = [2,4,1,3]

	queens(N,Qs) :-
	range(1,N,Ns),
	queens(Ns,[],Qs).

	queens([],Qs,Qs).
	queens(UnplacedQs,SafeQs,Qs) :-
	select(UnplacedQs,UnplacedQs1,Q),
	not_attack(SafeQs,Q),
	queens(UnplacedQs1,[Q\|SafeQs],Qs).

	not_attack(Xs,X) :-
	not_attack(Xs,X,1).

	not_attack([],_,_) :- !.
	not_attack([Y\|Ys],X,N) :-
	X =\= Y+N, X =\= Y-N,
	N1 is N+1,
	not_attack(Ys,X,N1).

	select([X\|Xs],Xs,X).
	select([Y\|Ys],[Y\|Zs],X) :- select(Ys,Zs,X).

	range(N,N,[N]) :- !.
	range(M,N,[M\|Ns]) :-
	M < N,
	M1 is M+1,
	range(M1,N,Ns).