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This is what I've written so far.



dfs_start(InititalState,Goal,Solution) :-

                         Check =.. [Goal,H],

dfs([H|T], Explored, Goal, Solution):-
           findall( X, (arc(H,X), \+ member(X,Explored), \+ member(X,[H|T]) ), Children),
           dfs(OpenList, [H|Explored], Goal, Solution).

I'm using the algorithm as described in the Russel-Norvig. I can't figure out how to create the entire path. I'm missing something here. And the Russel-Norvig, to me, is really cryptic about that.

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1 Answer 1

up vote 3 down vote accepted

So in dfs_start/3, you would like to refer to all nodes that were explored in dfs/4, yet dfs/4 has no argument to refer to these nodes. You therefore should introduce an additional argument that you can use for this:

dfs_start(InititalState, Goal, Es, Solution) :-
        dfs([InititalState], [], Es, Goal, Solution).

dfs([H|_], Es0, Es, Goal, H) :- call(Goal, H), reverse(Es0, Es).
dfs([H|T], Es0, Es, Goal, Solution):-
        findall(X, (arc(H, X),
                       \+ member(X, Es0),
                       \+ member(X, [H|T]) ), Children),
        append(Children, T, OpenList),
        dfs(OpenList, [H|Es0], Es, Goal, Solution).

Example query:

?- dfs_start(a, goal, Path, Solution).
Path = [a, b, c, k, f, l, d],
Solution = g ;

EDIT: From your comment, I now see what you want. This is easy: Just associate to each node in the open list the way it was reached:

dfs_start(Start, Goal, Path, Solution) :-
        dfs([Start-[]], [], Goal, Path, Solution).

dfs([H-Path0|_], _, Goal, Path, H) :- call(Goal, H), reverse([H|Path0], Path).
dfs([H-Path0|T], Es, Goal, Path, Solution):-
        findall(X-[H|Path0], (arc(H, X),
                       \+ member(X, Es),
                       \+ member(X-_, [H-_|T]) ), Children),
        append(Children, T, OpenList),
        dfs(OpenList, [H|Es], Goal, Path, Solution).

Example query:

?- dfs_start(a, goal, Path, Solution).
Path = [a, d, g],
Solution = g ;

Consider also that depth-first search is available in Prolog via built-in chronological backtracking, so while it may occasionally be useful to make it explicit (for example, as a starting point for more advanced search strategies), you can do it also with:

dfs_start(Start, Goal, Path) :- phrase(dfs(Start, [], Goal), Path).

dfs(Node, _, Goal)   --> [Node], { call(Goal, Node) }.
dfs(Node0, Es, Goal) --> [Node0],
        { arc(Node0, Node1), \+ member(Node1, Es) },
        dfs(Node1, [Node0|Es], Goal).

Example query:

?- dfs_start(a, goal, Path).
Path = [a, d, g] ;
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nope, as you can see the path should be a,d,g and not [a, b, c, k, f, l, d]. Explored is the so called "closed list", not the path to the solution from a. –  dierre Mar 13 '11 at 0:06
Could you please explain the notation X-_ ? Is it like X|_? –  dierre Mar 14 '11 at 6:42
X-_ is infix notation for the term -(X, _). I used the functor (-)/2 to build node-path pairs (i.e., nodes and associated paths). To check whether X is already in the open list including H, I do not care about the paths but only about the nodes, so the path can be anything, thus I use a free variable. –  mat Mar 14 '11 at 8:17
ah sorry, it's the normal minus associated to atoms...didn't get it in there. On the second example, what's -->? It's the first time I see it. –  dierre Mar 14 '11 at 12:47
(-->)/2 is DCG notation; a DCG always describes a list (in this case: the list of nodes in the path); you can read it declaratively by reading (,)/2 as "and then" within DCGs. For example, the path here consists either of Node (if it is a goal), or of Node0 and then the path described by dfs//3 starting from an adjacent node Node1. DCGs are often used when describing lists because they are so convenient for this. They are also used for parsing, where you describe what a list that can be parsed looks like, and then construct something else (like a syntax tree) from it. –  mat Mar 14 '11 at 15:20

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