Ok I have a Lisp implementation of BFS that I am trying to convert to do a hill climbing search.
Here is what my BFS code looks like:
; The list of lists is the queue that we pass BFS. the first entry and ; every other entry in the queue is a list. BFS uses each of these lists and ; the path to search. (defun shortest-path (start end net) (BFS end (list (list start)) net)) ;We pass BFS the end node, a queue containing the starting node and the graph ;being searched(net) (defun BFS (end queue net) (if (null queue) ;if the queue is empty BFS has not found a path so exit nil (expand-queue end (car queue) (cdr queue) net))) (defun expand-queue (end path queue net) (let ((node (car path))) (if (eql node end) ; If the current node is the goal node then flip the path ; and return that as the answer (reverse path) ; otherwise preform a new BFS search by appending the rest of ; the current queue to the result of the new-paths function (BFS end (append queue (new-paths path node net)) net)))) ; mapcar is called once for each member of the list new-paths is passed ; the results of this are collected into a list (defun new-paths (path node net) (mapcar #'(lambda (n) (cons n path)) (cdr (assoc node net))))
Now, I know that instead of always expanding the left node as I do in the BFS I need to expand the node that seems closest to the goal state.
The graph I am using looks like this:
(a (b 3) (c 1)) (b (a 3) (d 1))
I have a conversion function to make this work with the above BFS implementation, but now I need to turn this into Hill climbing using this graph format.
I'm just not sure where to begin, and have been trying things to no avail. I know I mainly need to change the
expand-queue function to expand the closest node, but I can't seem to make a function to determine which node is closest.
Thanks for the help!