A best-first search program.
Source: PROLOG programming for artificial intelligence, 3rd Edition, Harlow, 2001, ISBN 0-201-40375-7.
Program source code: best-first.pl
% Figure 12.3 A best-first search program. :- op( 900, fy, not). % not Goal): negation as failure; % Note: This is often available as a built-in predicate, % often written as prefix operator "\+", e.g. \+ likes(mary,snakes) not Goal :- Goal, !, fail ; true. % bestfirst( Start, Solution): Solution is a path from Start to a goal bestfirst( Start, Solution) :- expand( [], l( Start, 0/0), 9999, _, yes, Solution). % Assume 9999 is greater than any f-value % expand( Path, Tree, Bound, Tree1, Solved, Solution): % Path is path between start node of search and subtree Tree, % Tree1 is Tree expanded within Bound, % if goal found then Solution is solution path and Solved = yes % Case 1: goal leaf-node, construct a solution path expand( P, l( N, _), _, _, yes, [N|P]) :- goal(N). % Case 2: leaf-node, f-value less than Bound % Generate successors and expand them within Bound. expand( P, l(N,F/G), Bound, Tree1, Solved, Sol) :- F =< Bound, ( bagof( M/C, ( s(N,M,C), not member(M,P) ), Succ), !, % Node N has successors succlist( G, Succ, Ts), % Make subtrees Ts bestf( Ts, F1), % f-value of best successor expand( P, t(N,F1/G,Ts), Bound, Tree1, Solved, Sol) ; Solved = never % N has no successors - dead end ) . % Case 3: non-leaf, f-value less than Bound % Expand the most promising subtree; depending on % results, procedure continue will decide how to proceed expand( P, t(N,F/G,[T|Ts]), Bound, Tree1, Solved, Sol) :- F =< Bound, bestf( Ts, BF), min( Bound, BF, Bound1), % Bound1 = min(Bound,BF) expand( [N|P], T, Bound1, T1, Solved1, Sol), continue( P, t(N,F/G,[T1|Ts]), Bound, Tree1, Solved1, Solved, Sol). % Case 4: non-leaf with empty subtrees % This is a dead end which will never be solved expand( _, t(_,_,[]), _, _, never, _) :- !. % Case 5: f-value greater than Bound % Tree may not grow. expand( _, Tree, Bound, Tree, no, _) :- f( Tree, F), F > Bound. % continue( Path, Tree, Bound, NewTree, SubtreeSolved, TreeSolved, Solution) continue( _, _, _, _, yes, yes, Sol). continue( P, t(N,F/G,[T1|Ts]), Bound, Tree1, no, Solved, Sol) :- insert( T1, Ts, NTs), bestf( NTs, F1), expand( P, t(N,F1/G,NTs), Bound, Tree1, Solved, Sol). continue( P, t(N,F/G,[_|Ts]), Bound, Tree1, never, Solved, Sol) :- bestf( Ts, F1), expand( P, t(N,F1/G,Ts), Bound, Tree1, Solved, Sol). % succlist( G0, [ Node1/Cost1, ...], [ l(BestNode,BestF/G), ...]): % make list of search leaves ordered by their F-values succlist( _, [], []). succlist( G0, [N/C | NCs], Ts) :- G is G0 + C, h( N, H), % Heuristic term h(N) F is G + H, succlist( G0, NCs, Ts1), insert( l(N,F/G), Ts1, Ts). % Insert T into list of trees Ts preserving order w.r.t. f-values insert( T, Ts, [T | Ts]) :- f( T, F), bestf( Ts, F1), F =< F1, !. insert( T, [T1 | Ts], [T1 | Ts1]) :- insert( T, Ts, Ts1). % Extract f-value f( l(_,F/_), F). % f-value of a leaf f( t(_,F/_,_), F). % f-value of a tree bestf( [T|_], F) :- % Best f-value of a list of trees f( T, F). bestf( [], 9999). % No trees: bad f-value min( X, Y, X) :- X =< Y, !. min( X, Y, Y).