Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I've been trying for a while now to implement a Dijkstra shortest path algorithm in JIProlog. There are a few implementations available online, such as here and here, but they all return the path as a list of nodes. This is problematic for my implementation, because I'm technically using a multigraph, where vertices can be connected by multiple edges. Therefore, I need an algorithm that returns a list of edges rather than a list of nodes.

I've been trying to adjust the first implementation I mentioned to track edges, but I get lost in the dijkstra_l/3 rule. Could someone help me? Thanks!

share|improve this question

1 Answer 1

up vote 1 down vote accepted

I answered some time ago to a similar question, with an implementation. Alas, that code doesn't work with the lastes SWI-Prlog, I've debugged and found that ord_memberchk (used for efficiency) has changed behaviour. I've replaced with memberchk and now is working...

I would suggest to use the output of the algorithm with a simple post processing pass that recovers the edges from nodes, selecting the smaller value. I've implemented as it dijkstra_edges/3

/*  File:    dijkstra_av.pl
    Author:  Carlo,,,
    Created: Aug  3 2012
    Modified:Oct 28 2012
    Purpose: learn graph programming with attribute variables

:- module(dijkstra_av, [dijkstra_av/3,

dijkstra_av(Graph, Start, Solution) :-
    setof(X, Y^D^(member(d(X,Y,D), Graph) ; member(d(Y,X,D), Graph)), Xs),
    length(Xs, L),
    length(Vs, L),
    aggregate_all(sum(D), member(d(_, _, D), Graph), Infinity),
    catch((algo(Graph, Infinity, Xs, Vs, Start, Solution),
          ), sol(Solution), true).

dijkstra_edges(Graph, Start, Edges) :-
    dijkstra_av(Graph, Start, Solution),
    maplist(nodes_to_edges(Graph), Solution, Edges).

nodes_to_edges(Graph, s(Node, Dist, Nodes), s(Node, Dist, Edges)) :-
    join_nodes(Graph, Nodes, Edges).

join_nodes(_Graph, [_Last], []).
join_nodes(Graph, [N,M|Ns], [e(N,M,D)|Es]) :-
    aggregate_all(min(X), member(d(N, M, X), Graph), D),
    join_nodes(Graph, [M|Ns], Es).

algo(Graph, Infinity, Xs, Vs, Start, Solution) :-
    pairs_keys_values(Ps, Xs, Vs),
    maplist(init_adjs(Ps), Graph),
    maplist(init_dist(Infinity), Ps),
    %ord_memberchk(Start-Sv, Ps),
    memberchk(Start-Sv, Ps),
    put_attr(Sv, dist, 0),
    maplist(solution(Start), Vs, Solution).

solution(Start, V, s(N, D, [Start|P])) :-
    get_attr(V, name, N),
    get_attr(V, dist, D),
    rpath(V, [], P).

rpath(V, X, P) :-
    get_attr(V, name, N),
    (   get_attr(V, previous, Q)
    ->  rpath(Q, [N|X], P)
    ;   P = X

init_dist(Infinity, N-V) :-
    put_attr(V, name, N),
    put_attr(V, dist, Infinity).

init_adjs(Ps, d(X, Y, D)) :-
    %ord_memberchk(X-Xv, Ps),
    %ord_memberchk(Y-Yv, Ps),
    memberchk(X-Xv, Ps),
    memberchk(Y-Yv, Ps),
    adj_add(Xv, Yv, D),
    adj_add(Yv, Xv, D).

adj_add(X, Y, D) :-
    (   get_attr(X, adjs, L)
    ->  put_attr(X, adjs, [Y-D|L])
    ;   put_attr(X, adjs, [Y-D])

main_loop([Q|Qs]) :-
    smallest_distance(Qs, Q, U, Qn),
    put_attr(U, assigned, true),
    get_attr(U, adjs, As),
    update_neighbours(As, U),

smallest_distance([A|Qs], C, M, [T|Qn]) :-
    get_attr(A, dist, Av),
    get_attr(C, dist, Cv),
    (   Av < Cv
    ->  (N,T) = (A,C)
    ;   (N,T) = (C,A)
    !, smallest_distance(Qs, N, M, Qn).
smallest_distance([], U, U, []).

update_neighbours([V-Duv|Vs], U) :-
    (   get_attr(V, assigned, true)
    ->  true
    ;   get_attr(U, dist, Du),
        get_attr(V, dist, Dv),
        Alt is Du + Duv,
        (   Alt < Dv
        ->  put_attr(V, dist, Alt),
        put_attr(V, previous, U)
        ;   true
    update_neighbours(Vs, U).
update_neighbours([], _).

:- begin_tests(dijkstra_av).


test(1) :-
    time(dijkstra_av(S, a, L)),
    maplist(writeln, L).

test(2) :-
    open('salesman.pl', read, F),
    readf(F, L),
    dijkstra_av(L, penzance, R),
    maplist(writeln, R).

readf(F, [d(X,Y,D)|R]) :-
    read(F, dist(X,Y,D)), !, readf(F, R).
readf(_, []).

test(3) :-
    nl, small(S),
    time(dijkstra_edges(S, a, Es)),
    maplist(writeln, Es).

:- end_tests(dijkstra_av).

test(3) shows the implementation, I've added some edge with higher values to verify, the output shows that these are correctly discarded:

share|improve this answer
Unfortunately, I have to use JIProlog, which doesn't support aggregate_all. I've tried importing it from the SWI-Prolog source, but then I also have to import all dependencies, and adjust all of those to JIP syntax, which seemed too far-fetched. But the note about post-processing is actually really helpful, so I'll mark your answer as the accepted answer. Thanks a lot for your work! –  roelandvanbeek Oct 28 '12 at 11:16
I'm glad to ear you find it useful! aggregate_all can be implemented easily with findall, but attribute variables (that JIProlog miss, I think), could be difficult... –  CapelliC Oct 28 '12 at 12:44

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.