# Definition of a path/trail/walk

Many predicates define some kind of an acyclic path built from edges defined via a binary relation, quite similarly to defining transitive closure. A generic definition is thus called for.

Note that the notions defined in graph theory do not readily match what is commonly expected. Most notably, we are not interested in the edges' names.

Worse, also graph theory has changed a bit, introducing the notion of walk, noting

Traditionally, a path referred to what is now usually known as an open walk. Nowadays, when stated without any qualification, a path is usually understood to be simple, meaning that no vertices (and thus no edges) are repeated. (The term chain has also been used to refer to a walk in which all vertices and edges are distinct.)

So my question is: How to name and define this functionality?

What I have done so far is to define:

``````path(Rel_2, Path, X0,X)
``````

The first argument has to be the continuation of the relation. Then comes either the `Path` or the pair of vertices.

### Example usage

``````n(a, b).
n(b, c).
n(b, a).

?- path(n,Xs, a,X).
Xs = [a], X = a ;
Xs = [a, b], X = b ;
Xs = [a, b, c], X = c ;
false.
``````

### Implementation

``````:- meta_predicate path(2,?,?,?).

:- meta_predicate path(2,?,?,?,+).

path(R_2, [X0|Ys], X0,X) :-
path(R_2, Ys, X0,X, [X0]).

path(_R_2, [], X,X, _).
path(R_2, [X1|Ys], X0,X, Xs) :-
call(R_2, X0,X1),
non_member(X1, Xs),
path(R_2, Ys, X1,X, [X1|Xs]).

non_member(_E, []).
non_member(E, [X|Xs]) :-
dif(E,X),
non_member(E, Xs).
``````
• Is path/5 tail recursive? – pasaba por aqui May 30 '15 at 21:58
• @pasa: only if the goal `call(R_2, X0,X1)` is determinate. – false May 30 '15 at 22:18
• You should figure out a way to accept an answer for this question to increase its visibility on search results. I know it is there so I usually search for "[prolog] path trail" but it does not show up as high as it should in less specific searches, esp. considering how many votes the question itself has. – user1812457 May 27 '17 at 5:39
• @Boris: So far, 8̶0̶0̶ 850 have been spent for increased visibility. I only invest my points above 10k – false May 27 '17 at 10:39
• @XXX: That's a pity in any case. – false Jun 7 '17 at 11:36

How about defining `path/4` like this?

``````path(R_2, Xs, A,Z) :-                   % A path `Xs` from `A` to `Z` is ...
walk(R_2, Xs, A,Z),                  % ... a walk `Xs` from `A` to `Z` ...
all_dif(Xs).                         % ... with no duplicates in `Xs`.
``````

To aid universal termination, we swap the two goals in above conjunction ...

``````path(R_2, Xs, A,Z) :-
all_dif(Xs),                         % enforce disequality ASAP
walk(R_2, Xs, A,Z).
``````

... and use the following lazy implementation of `all_dif/1`:

```all_dif(Xs) :-                          % enforce pairwise term inequality
freeze(Xs, all_dif_aux(Xs,[])).      % (may be delayed)

all_dif_aux([], _).
all_dif_aux([E|Es], Vs) :-
maplist(dif(E), Vs),                 % is never delayed
freeze(Es, all_dif_aux(Es,[E|Vs])).  % (may be delayed)
```

`walk/4` is defined like `path/4` and `path/5` given by the OP:

``````:- meta_predicate walk(2, ?, ?, ?).
walk(R_2, [X0|Xs], X0,X) :-
walk_from_to_step(Xs, X0,X, R_2).

:- meta_predicate walk_from_to_step(?, ?, ?, 2).
walk_from_to_step([], X,X, _).
walk_from_to_step([X1|Xs], X0,X, R_2) :-
call(R_2, X0,X1),
walk_from_to_step(Xs, X1,X, R_2).
``````

IMO above `path/4` is simpler and more approachable, particularly for novices. Would you concur?

• `difs` is commonly called `all_different` or `alldifferent` – false Jul 30 '15 at 13:09
• @false. The best of both worlds! Thx! – repeat Jul 30 '15 at 15:12

I want to focus on naming the predicate.

• Unlike `maplist/2`, the argument order isn't of primary importance here.

• The predicate name should make the meaning of the respective arguments clear.

So far, I like `path_from_to_edges` best, but it has its pros and cons, too.

``````path_from_to_edges(Path,From,To,Edges_2) :-
path(Edges_2,Path,From,To).
``````

Let's pick it apart:

• pro: `path` is a noun, it cannot be mis-read a verb. To me, a list of vertices is implied.

• pro: `from` stands for a vertex, and so does `to`.

• con: `edges` is somewhat vague, but using lambdas here is the most versatile choice.

• con: According to Wikipedia, a path is a trail in which all vertices (except possibly the first and last) are distinct. So that would need to be clarified in the description.

Using lambdas for a lists of neighbor vertices `Ess`:

``````?- Ess  = [a-[b],b-[c,a]],
From = a,
path_from_to_edges(Path,From,To,\X^Y^(member(X-X_neibs,Ess),member(Y,X_neibs))).
Ess = [a-[b],b-[c,a]], From = a, To = a, Path = [a]     ;
Ess = [a-[b],b-[c,a]], From = a, To = b, Path = [a,b]   ;
Ess = [a-[b],b-[c,a]], From = a, To = c, Path = [a,b,c] ;
false.
``````

### Edit 2015-06-02

Another shot at better naming! This leans more on the side of `maplist/2`...

``````graph_path_from_to(P_2,Path,From,To) :-
path(P_2,Path,From,To).
``````

Here, `graph`, of course, is a noun, not a verb.

Regarding the meaning of "path": paths definitely should allow `From=To` and not exclude that by default (with pairwise term inequalities). It is easy to exclude this with an additional `dif(From,To)` goal, but not the other way round.

• `Edges` suggests a list of edges. – false Jun 2 '15 at 13:21
• Con: Goes against Richard O'Keefe's argument ordering which puts meta arguments very early. Also, chances are, that there is no variation on the meta argument, so one would never do `call(path_from_to_edges(Path,From,To), P_2)` like in `maplist(path_from_to_edges(Path,From,To),P_2s)` – false Jun 2 '15 at 13:25
• And `Edges` means list of `Edges` - although we do not have some – false Jun 2 '15 at 13:32

I do not see the reason to define in path/4 the arguments "start node" and "end node". It seems that a simple path/2 with the rule and the list of nodes must be enough.

If the user wants a list starting with some node (by example, 'a'), he can query the statement as: path( some_rule, ['a'|Q] ).

A user could, by example, request for path that have length 10 in the way: length(P,10), path( some_rule, P).

Some utility goals can be easily added, but they are not the main subject. Example, path/3 with start node is:

``````path( some_rule, [start|Q], start ) :-
path ( some_rule, [start|Q ] ).
``````

Addition of last node as argument could give the false idea that this argument drives the algorithm, but it doesn't. Assume by example:

``````n(a, b).
n(a, c).
n(a, d).
``````

and trace algorithm execution for the query:

``````[trace]  ?- path( n, P, X, d ).
Call: (6) path(n, _G1025, _G1026, d) ? creep
Call: (7) path(n, _G1107, _G1026, d, [_G1026]) ? creep
Exit: (7) path(n, [], d, d, [d]) ? creep
Exit: (6) path(n, [d], d, d) ? creep
P = [d],
X = d ;
Redo: (7) path(n, _G1107, _G1026, d, [_G1026]) ? creep
Call: (8) n(_G1026, _G1112) ? creep

Exit: (8) n(a, b) ? creep

Call: (8) non_member(b, [a]) ? creep
Call: (9) dif:dif(b, a) ? creep
Exit: (9) dif:dif(b, a) ? creep
Call: (9) non_member(b, []) ? creep
Exit: (9) non_member(b, []) ? creep
Exit: (8) non_member(b, [a]) ? creep
Call: (8) path(n, _G1113, b, d, [b, a]) ? creep
Call: (9) n(b, _G1118) ? creep
Fail: (9) n(b, _G1118) ? creep
Fail: (8) path(n, _G1113, b, d, [b, a]) ? creep
Redo: (9) non_member(b, []) ? creep
Fail: (9) non_member(b, []) ? creep
Fail: (8) non_member(b, [a]) ? creep
Redo: (8) n(_G1026, _G1112) ? creep

Exit: (8) n(a, c) ? creep

Call: (8) non_member(c, [a]) ? creep
Call: (9) dif:dif(c, a) ? creep
Exit: (9) dif:dif(c, a) ? creep
Call: (9) non_member(c, []) ? creep
Exit: (9) non_member(c, []) ? creep
Exit: (8) non_member(c, [a]) ? creep
Call: (8) path(n, _G1113, c, d, [c, a]) ? creep
Call: (9) n(c, _G1118) ? creep
Fail: (9) n(c, _G1118) ? creep
Fail: (8) path(n, _G1113, c, d, [c, a]) ? creep
Redo: (9) non_member(c, []) ? creep
Fail: (9) non_member(c, []) ? creep
Fail: (8) non_member(c, [a]) ? creep
Redo: (8) n(_G1026, _G1112) ? creep

Exit: (8) n(a, d) ? creep

Call: (8) non_member(d, [a]) ? creep
Call: (9) dif:dif(d, a) ? creep
Exit: (9) dif:dif(d, a) ? creep
Call: (9) non_member(d, []) ? creep
Exit: (9) non_member(d, []) ? creep
Exit: (8) non_member(d, [a]) ? creep
Call: (8) path(n, _G1113, d, d, [d, a]) ? creep
Exit: (8) path(n, [], d, d, [d, a]) ? creep
Exit: (7) path(n, [d], a, d, [a]) ? creep
Exit: (6) path(n, [a, d], a, d) ? creep
P = [a, d],
X = a .
``````

as you can see, in this case algorithm fails to brute force. For this reason, if algorithm is not improved, I suggest do not add "end node" as "path" argument.

• Not providing the extra two arguments makes many queries cumbersome. Like: What paths exist from `a` to `b`? This would read as: `Path = [a|_], path(connex, Path), last(Path, b)` contrast this to `path(connex, Path, a,b)` – false May 31 '15 at 11:46
• The example you provide shows that: a) start node is not necessary; end node is necessary only until a more efficient algorithm is used. – pasaba por aqui May 31 '15 at 14:10
• End case, and in general any intermediate or final condition, needs a better algorithm than the one provided in the original message. On going. – pasaba por aqui May 31 '15 at 14:49
• Fine! Then please provide some! – false May 31 '15 at 14:53
• ad addendum 2: That is an accurate observation. In fact the end node is a steadfast argument. However, for a complete search, nothing else can be expected! – false May 31 '15 at 15:18