# best structure Graph to implement Dijkstra in prolog

The question is simple. How can I struct my Graph in SWI prolog to implement the Dijkstra's algorithm?

I have found this but it's too slow for my job.

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That implementation isn't so bad:

``````?- time(dijkstra(penzance, Ss)).
% 3,778 inferences, 0,003 CPU in 0,003 seconds (99% CPU, 1102647 Lips)
Ss = [s(aberdeen, 682, [penzance, exeter, bristol, birmingham, manchester, carlisle, edinburgh|...]), s(aberystwyth, 352, [penzance, exeter, bristol, swansea, aberystwyth]), s(birmingham, 274, [penzance, exeter, bristol, birmingham]), s(brighton, 287, [penzance, exeter, portsmouth, brighton]), s(bristol, 188, [penzance, exeter, bristol]), s(cambridge, 339, [penzance, exeter|...]), s(cardiff, 322, [penzance|...]), s(carlisle, 474, [...|...]), s(..., ..., ...)|...].
``````

SWI-Prolog offers attributed variables, then this answer could be relevant to you. I hope I will post later today an implementation of dijkstra/2 using attribute variables.

edit well, I must say that first time programming with attribute variables is not too much easy.

I'm using the suggestion from the answer by @Mat I linked above, abusing of attribute variables to get constant time access to properties attached to data as required of algorithm. I've (blindly) implemented the wikipedia algorithm, here my effort:

``````/*  File:    dijkstra_av.pl
Author:  Carlo,,,
Created: Aug  3 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),
throw(sol(Solution))
), sol(Solution), true).

algo(Graph, Infinity, Xs, Vs, Start, Solution) :-
pairs_keys_values(Ps, Xs, Vs),
maplist(init_dist(Infinity), Ps),
ord_memberchk(Start-Sv, Ps),
put_attr(Sv, dist, 0),
time(main_loop(Vs)),
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),

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

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

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) :-
nl,
time(dijkstra_av([d(a,b,1),d(b,c,1),d(c,d,1),d(a,d,2)], a, L)),
maplist(writeln, L).

test(2) :-
close(F),
nl,
dijkstra_av(L, penzance, R),
maplist(writeln, R).

:- end_tests(dijkstra_av).
``````

To be true, I prefer the code you linked in the question. There is an obvious point to optimize, smallest_distance/4 now use a dumb linear scan, using an rbtree the runtime should be better. But attributed variables must be handled with care.

time/1 apparently show an improvement

``````% 2,278 inferences, 0,003 CPU in 0,003 seconds (97% CPU, 747050 Lips)
s(aberdeen,682,[penzance,exeter,bristol,birmingham,manchester,carlisle,edinburgh,aberdeen])
....
``````

but the graph is too small for any definitive assertion. Let we know if this snippet reduce the time required for your program.

File salesman.pl contains dist/3 facts, it's taken verbatim from the link in the question.

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