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).
```

`call(R_2, X0,X1)`

is determinate. – false May 30 '15 at 22:18