# Prolog : Enumerate All Elements of Countably Infinite Results

Are there any prolog implementations that are able to enumerate all elements of countably infinite results?

Let's consider to enumerate all pairs of natural numbers. If we enumerate pairs in order {(0,0), (0,1), (1,0), (0,2), (1,1), (2,0), ...}, we can enumerate all pairs. However, if we enumerate pairs in order {(0,0), (0,1), (0,2), (0,3) ...} as the following GNU prolog program, we never reach pairs such as (1,1).

``````% cat nats.pl
nat(0).
nat(X1) :- nat(X), X1 is X + 1.

pair_of_nats(X, Y) :- nat(X), nat(Y).
% prolog
GNU Prolog 1.3.0
By Daniel Diaz
| ?- ['nats.pl'].
compiling /home/egi/prolog/nats.pl for byte code...
/home/egi/prolog/nats.pl compiled, 4 lines read - 762 bytes written, 9 ms

yes
| ?- pair_of_nats(X,Y).

X = 0
Y = 0 ? ;

X = 0
Y = 1 ? ;

X = 0
Y = 2 ? ;

X = 0
Y = 3 ?
``````
• Thanks! Are there any implementation that we can configure search algorithm from depth-first search to breadth-first search? I think in some case breadth-first search is useful and rewriting program for depth-first search makes program messy.
– egi
Commented Feb 10, 2015 at 5:51
• There are good reasons why the default strategy is depth first. The solutions you are after are not ordered in any trivial order, so it is reasonable to expect that you would need to describe, in your program, what it is exactly that you are after.
– user1812457
Commented Feb 10, 2015 at 13:16
• The answers offered so far are nice for generating pairs of natural numbers, but the more general problem I think will be inhibited by Prolog's search strategy as emphasized by @Boris. If you have two (or more) arbitrary predicates, `p1` and `p2`, that each generate a infinite series of solutions of some kind, I'm not sure there's a way in Prolog to explore their solutions in conjunction, breadth first, unless they have an explicit association with natural numbers (e.g., `p1(N,...)`, `p2(N,...)`), in which case the natural number method may be used to constrain the results on backtracking. Commented Feb 10, 2015 at 13:52

I first thought CappeliCs solution is fine. But then looking at lurkers
CLP(FD) solution, I think the following is a complete Prolog solution:

``````?- between(0, inf, X), between(0, X, A), B is X-A.
``````

Bye

P.S.: Here is an example run in SWI-Prolog:

``````Welcome to SWI-Prolog (Multi-threaded, 64 bits, Version 7.1.33)
Copyright (c) 1990-2015 University of Amsterdam, VU Amsterdam
?- [user].
pair((A, B)) :-
between(0, inf, X),
between(0, X, A),
B is X-A.

?- pair(P).
P = (0, 0) ;
P = (0, 1) ;
P = (1, 0) ;
P = (0, 2) ;
P = (1, 1) ;
P = (2, 0) ;
...
``````

The reason why it is not easily doable with this definition of `nat/1` that you have, is that the order you want requires a search of the proof tree that is neither depth first, nor breadth first. The answer by @CapelliC is a breadth first search. The answer by @lurker gives you the answers you are after.

If for one reason or another you don't want to use CLPFD, here is a solution in pure Prolog:

``````pairs(A, B) :-
pairs_1(0, 0, A, B).

pairs_1(A, B, A, B).
pairs_1(A, B, RA, RB) :-
(   succ(B1, B)
->  succ(A, A1),
pairs_1(A1, B1, RA, RB)
;   succ(A, B1),
pairs_1(0, B1, RA, RB)
).
``````

It simply describes how to "move" through the rational number matrix to enumerate all pairs of integers.

You can use CLPFD (constraint logic programming over finite domains) to generate all of the pairs:

``````nat(0).
nat(X1) :- nat(X), X1 is X + 1.

pairs((A, B)) :-
nat(X),
A + B #= X,
fd_labeling([A,B]).
``````

This approximately follows the traversal of the rational number matrix used in the classic Cantor's proof that the rationals are countable (running the same direction on each diagonal instead of alternating), resulting in:

``````| ?- pairs(P).

P = (0,0) ? ;

P = (0,1) ? ;

P = (1,0) ? ;

P = (0,2) ? ;

P = (1,1) ? ;

P = (2,0) ? ;

P = (0,3) ? ;

P = (1,2) ? ;

P = (2,1) ? ;

P = (3,0) ? ;

P = (0,4) ? ;
...
``````
• Your definition of `nat/1` is very inefficient: It has quadratic cost. Even `length(_,X)` is much faster. Try it with: `(nat(N),N = 10000)` and `(length(_,N),N = 10000)` Commented Feb 10, 2015 at 13:37
• As for `pairs/2`: `pairs((A,B)) :- A#>=0, B #>=0, X #>= 0, A+B #= X, length(_,X).` this is not only faster, terminates better, but also runs in SICStus and SWI. Commented Feb 10, 2015 at 13:44
• @false I was just echoing the OP's definition of `nat/1` for illustration. Not looking to offer a more efficient version, but the essence of the answer is what to do with `nat/1` once defined. And thanks for the suggested efficiency improvement on `pairs`. But it generates, `uncaught exception: error(type_error(integer,_#4195348(0..268435455)),(#=)/2)` in GNU Prolog. Commented Feb 10, 2015 at 13:56
• You would need to label "up" for the even and "down" for the odd sums to faithfully reconstructs Cantor's argument. Commented Feb 10, 2015 at 14:00
• @false yeah, you're right. As is, it's "sort of" following the Cantor traversal but not quite. Good catch. :) Commented Feb 10, 2015 at 14:04

I would suggest to use a generator with optional limited upper value, like between/3, instead of nat/1, to be able to saturate 'inner levels'. For instance

``````?- between(0,inf,A),between(0,A,B).
A = B, B = 0 ;
A = 1,
B = 0 ;
A = B, B = 1 ;
A = 2,
B = 0 ;
A = 2,
B = 1 ;
A = B, B = 2 ;
A = 3,
B = 0
....
``````

GNU Prolog doesn't allow `between(0,inf,A)`, so maybe add `current_prolog_flag(max_integer,Z)` and use `Z` instead of `inf`.

• One limit of this approach is that it would never generate `(A, B)` where `B > A`. Commented Feb 10, 2015 at 12:04
• `length(_,A)` The `inf` is SWI specific Commented Feb 10, 2015 at 13:40