217 lines
6.9 KiB
Plaintext
217 lines
6.9 KiB
Plaintext
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% example adopted form:
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% File : Queens.Pl
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% Author : Richard A O'Keefe
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% Updated: 8 Feb 84
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% Purpose: Solve the N queens problem in Prolog.
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:- object(queens).
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:- uses(list).
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:- public(queens/1).
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:- mode(queens(+integer), one).
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:- private(forbidden/4).
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:- mode(forbidden(+integer, +integer, +integer, +integer), zero_or_one).
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:- private(least_room_to_move/4).
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:- mode(least_room_to_move(+list, -integer, -integer, -list), zero_or_more).
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:- private(lr2m/6).
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:- mode(lr2m(+list, +integer, +integer, -integer, -integer, -list), zero_or_more).
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:- private(make_initial_table/2).
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:- mode(make_initial_table(+integer, -list), zero_or_one).
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:- private(make_initial_table/3).
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:- mode(make_initial_table(+integer, +list, -list), zero_or_one).
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:- private(number_list/2).
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:- mode(number_list(+integer, -list), one).
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:- private(place/2).
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:- mode(place(+list, -list), zero_or_more).
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:- private(prune/4).
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:- mode(prune(+list, +integer, +integer, -list), zero_or_more).
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:- private(prune/5).
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:- mode(prune(+list, +integer, +integer, +integer, -list), zero_or_more).
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:- private(shorter/2).
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:- mode(shorter(+list, +list), zero_or_one).
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/* The N-queens problem is to place N queens on an NxN chessboard so
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that no two queens attack each other. Suppose we have a queen in
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(Row1,Col1) and a queen in (Row2,Col2). They attack each other if
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1. Same rank: Row1 = Row2.
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2. Same file: Col1 = Col2.
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3. Same NW-SE diagonal Row2 - Row1 = Col2 - Col1.
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4. Same SW-NE diagonal Row2 - Row1 = Col1 - Col2.
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We can express 3 and 4 another way:
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3. Row2 - Col2 = Row1 - Col1.
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4. Row2 + Col2 = Row1 + Col1.
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So each of the N queens has four numbers associated with it,
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(Row,Col,Dif,Sum), and any two queens must have different numbers
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in all these positions. The possible values are
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Row : 1 .. N
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Col : 1 .. N
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Sum : 1 .. 2N
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Dif : 1-N .. N-1
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The first question is, how shall we represent the board?
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It is sufficient to have a table indexed by rows, whose elements
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are the columns in which the corresponding queen is placed. For
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example, with rows horizontal and columns vertical
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1 2 3 4 -column / row
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+---+---+---+---+
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| | Q | | | 1
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+---+---+---+---+
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| | | | Q | 2
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+---+---+---+---+
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| Q | | | | 3
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+---+---+---+---+
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| | | Q | | 4
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+---+---+---+---+
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could be represented by board(2,4,1,3).
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How are we going to place the queens? The first idea that springs
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to mind is to place them one after another, but we can do better than
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that. Let us maintain a table of (QueenRow/PossibleColumns), and at
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each step pick the queen with the fewest possible columns, place it,
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and prune the remaining sets.
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Let's start by writing a predicate to generate this table. For N=4
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it will look like [1/[1,2,3,4], 2/[1,2,3,4], 3/[1,2,3,4], 4/[1,2,3,4]].
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*/
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make_initial_table(N, Table) :-
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number_list(N, PossibleColumns), % set of all possible columns
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make_initial_table(N, PossibleColumns, Table).
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make_initial_table(0, _, []) :- !.
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make_initial_table(N, PossibleColumns, [N/PossibleColumns|Table]) :-
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M is N-1,
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% in C-Prolog we could write succ(M, N) which would eliminate
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% the need for the cut in the previous clause
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make_initial_table(M, PossibleColumns, Table).
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number_list(0, []) :- !.
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number_list(N, [N| List]) :-
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M is N-1, % see previous comment
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number_list(M, List).
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/* This actually generates the reverse of what I said, so we'd get
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[4/[4,3,2,1], 3/[4,3,2,1], 2/[4,3,2,1], 1/[4,3,2,1]],
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but since it was to be a set of number/set pairs, that's ok.
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We shall only be operating on these sets an element at a time,
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so it the order doesn't matter.
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Now the problem is solved if there are no queens left to place.
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Otherwise, we pick the queen with the fewest possible columns,
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backtrack over those possible columns, prune the possible columns
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sets of the remaining queens, and recur.
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We are given a set of Row/PossCols pairs for the unplaced queens,
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and we are to return a set of Row-Col pairs saying where we put
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the queens.
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*/
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place([], []).
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place(UnplacedQueens, [Queen-Col|Placement]) :-
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least_room_to_move(UnplacedQueens, Queen, Columns, OtherQueens),
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list::member(Col, Columns), % backtrack over possible places
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prune(OtherQueens, Queen, Col, RemainingQueens),
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place(RemainingQueens, Placement).
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/* If you haven't done this sort of thing before, least_room_to_move
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can be quite tricky. The idea is the we wander down the list of
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pairs, keeping the current best pair apart, and when we find that
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there is a better pair we have to put the current pair back in the list.
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But because these are sets, it doesn't matter *where* the pairs go in
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the list. Note that we don't need a cut in the first clause of place/2
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because least_room_to_move will fail on an empty list.
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*/
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least_room_to_move([Q/C|Table], Qbest, Cbest, Rest) :-
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lr2m(Table, Q, C, Qbest, Cbest, Rest).
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/* This uses accumulator passing. I really have to explain this program
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to you in person.
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*/
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lr2m([], Q, C, Q, C, []).
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lr2m([NewQ/NewC|Table], OldQ, OldC, MinQ, MinC, [OldQ/OldC|Rest]) :-
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shorter(NewC, OldC),
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!,
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lr2m(Table, NewQ, NewC, MinQ, MinC, Rest).
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lr2m([Pair|Table], OldQ, OldC, MinQ, MinC, [Pair|Rest]) :-
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lr2m(Table, OldQ, OldC, MinQ, MinC, Rest).
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/* shorter(L1, L2) is true when the list L1 is strictly shorter than
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the list L2
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*/
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shorter([], [_|_]).
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shorter([_|L1], [_|L2]) :-
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shorter(L1, L2).
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/* Now we have to code prune. To prune all the queens, we prune each
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queen in turn.
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*/
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prune([], _, _, []).
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prune([Queen/Columns|Queens], Row, Col, [Queen/Pruned|RestPruned]) :-
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prune(Columns, Queen, Row, Col, Pruned),
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prune(Queens, Row, Col, RestPruned).
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/* To prune a single queen, we have to eliminate all the positions
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forbidden by the queen wee have just placed.
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*/
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prune([], _, _, _, []).
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prune([Col2|Cols], Row2, Row1, Col1, Permitted) :-
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forbidden(Row1, Col1, Row2, Col2),
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!,
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prune(Cols, Row2, Row1, Col1, Permitted).
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prune([Col2|Cols], Row2, Row1, Col1, [Col2|Permitted]) :-
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prune(Cols, Row2, Row1, Col1, Permitted).
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/* Finally, since we have ensured that two queens are automatically in
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different rows, we have only to check rules 2, 3, and 4.
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*/
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forbidden(_, Col, _, Col).
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forbidden(Row1, Col1, Row2, Col2) :-
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Row2 - Col2 =:= Row1 - Col1.
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forbidden(Row1, Col1, Row2, Col2) :-
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Row2 + Col2 =:= Row1 + Col1.
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/* The last thing left for us to do is to write the top level predicate
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that ties all the pieces together. Because the 'place' predicate
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may place the queens in any order, we keysort the list to make it more
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readable. I'm afraid I had that in mind when I decided that it would
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be a list of Row-Col pairs. I seem to recommend sorting for everything.
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Well, it IS a panacea.
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*/
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queens(N) :-
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make_initial_table(N, Table),
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place(Table, Placement),
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list::keysort(Placement, DisplayForm),
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write(DisplayForm), nl.
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:- end_object.
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