# Prolog - rule(X) is true if it returns two or more results

Alright, been stuck on this one for a while:

rule1 outputs true if returns two or more results:

``````rule1(X) :-
rule2(X,_).
``````

How can I count the results, and then set a minimum for when it's true?

Thanks.

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Should be easy to encode using findall/3. –  ShiDoiSi Nov 15 '12 at 8:35

How can I count the results, and then set a minimum for when it's true?

It is not clear what you mean by results. So I will make some guesses. A result might be:

A solution. For example, the goal `member(X,[1,2,1])` has two solutions. Not three. In this case consider using either `setof/3` or a similar predicate. In any case, you should first understand `setof/3` before addressing the problem you have.

An answer. The goal `member(X,[1,2,1])` has three answers. The goal `member(X,[Y,Z])` has two answers, but infinitely many solutions.

So if you want to ensure that there are at least a certain number of answers, define:

```at_least(Goal, N) :-
\+ \+ call_nth(Goal, N).
```

with `call_nth/2` defined in another SO-answer.

Note that the other SO-answers are not correct: They either do not terminate or produce unexpected instantiations.

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thanks for explaining the difference between solution and answer. –  CapelliC Nov 15 '12 at 10:21
@chac: That distinction is key for clpfd! –  false Nov 15 '12 at 10:36

you can use library(aggregate) to count solutions

``````:- use_module(library(aggregate)).

% it's useful to declare this for modularization
:- meta_predicate at_least(0, +).

at_least(Predicate, Minimum) :-
aggregate_all(count, Predicate, N),
N >= Minimum.
``````

example:

``````?- at_least(member(_,[1,2,3]),3).
true.

?- at_least(member(_,[1,2,3]),4).
false.
``````

edit here is a more efficient way, using SWI-Prolog facilities for global variables

``````at_least(P, N) :-
nb_setval(at_least, 0),
P,
nb_getval(at_least, C),
S is C + 1,
( S >= N, ! ; nb_setval(at_least, S), fail ).
``````

with this definition, P is called just N times. (I introduce a service predicate m/2 that displays what it returns)

``````m(X, L) :- member(X, L), writeln(x:X).

?- at_least(m(X,[1,2,3]),2).
x:1
x:2
X = 2.
``````

edit accounting for @false comment, I tried

`````` ?- call_nth(m(X,[1,2,3]),2).
x:1
x:2
X = 2 ;
x:3
false.
``````

with call_nth from here.

From the practical point of view, I think nb_setval (vs nb_setarg) suffers the usual tradeoffs between global and local variables. I.e. for some task could be handly to know what's the limit hit to accept the condition. If this is not required, nb_setarg it's more clean.

Bottom line: the better way to do would clearly be using call_nth, with the 'trick' of double negation solving the undue variable instantiation.

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Your use of global variables is incorrect. And you produce unexpected substitutions (`X = 2`) in your query. –  false Nov 15 '12 at 9:32
Thank you. This helped a lot. –  John Dorian Nov 20 '12 at 3:08

I'm not quite sure what you are actually looking for, so my answer is based on some guesswork...

If you wanted to assert that there are two different answers for some X, you could try a direct way:

```rule1(X) :-
dif(Y1,Y2),
rule2(X,Y1),
rule2(X,Y2).
```

Let's try some concrete examples using `member/2`!

The first query gives us four answers but only two solutions: two answers are redundant.

```?- Zs = [1,2,1], dif(X,Y), member(X,Zs), member(Y,Zs).
Zs = [1,2,1], X = 1, Y = 2 ;
Zs = [1,2,1], X = 2, Y = 1 ;
Zs = [1,2,1], X = 2, Y = 1 ;            % redundant answer
Zs = [1,2,1], X = 1, Y = 2 ;            ℅ redundant answer
false.
```

The second query gives two answers: each answer represents an infinite number of solutions.

```?- Zs = [A,B], dif(X,Y), member(X,Zs), member(Y,Zs).
Zs = [X,Y], A = X, B = Y, dif(X,Y) ;
Zs = [Y,X], A = Y, B = X, dif(X,Y) ;
false.
```
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