# Predicate that pick elements which are on list twice not less not more

I'm trying to write a predicate `twice(El,L)` which will return `true.` when `El` is on list exactly twice. Here is what I have:

``````twice(El,L) :- select(El,L,L1), member(El,L1), \+ twice(El,L1).
``````

It works nice for `twice(2,[1,2,2,3,4])` but for `twice(X,[1,1,2,2,3,3])` it doubles every number `X = 1 ; X = 1 ; X = 2...` How could I avoid this without using any accumulator?

• it can perhaps be easier if you write another predicate `counts(List,Counts)` that will be true if `Counts` is a list of pairs `[Element,Count]` for each element of `List`. i.e. `counts([1,1,2,5,33,5,1,1,5,1,5,1],[[1,6],[2,1],[5,4],[33,1]])`. then `twice(Elem,List) :- member([Elem,2],List).` – fferri Jun 8 '15 at 15:02
• see here on counting occurrences in a list: stackoverflow.com/questions/9088062/… – fferri Jun 8 '15 at 15:14

You want to describe a sequence of elements. For such, there is a special formalism in Prolog called Definite Clause Grammars. Before using the formalism, let's try to figure out how a sequence with `E` occurring exactly twice looks like:

1. First, is a possibly empty sequence which does not contain `E`
2. then, there is one occurrence of `E`
3. then again a possibly empty sequence without `E`
4. then, there is the second occurrence of `E`
5. then again a possibly empty sequence without `E`.

Now, to put this into the DCG formalism

``````twice(E, L) :-
phrase(twice_occurring(E), L).  % Interface

twice_occurring(E) -->
seq_without(E),    % 1.
[E],               % 2.
seq_without(E),    % 3.
[E],               % 4.
seq_without(E).    % 5.

seq_without(_E) -->
[].
seq_without(E) -->
[X],
{dif(X,E)},
seq_without(E).
``````

Or, more compactly by using all//1 and avoiding auxiliary definitions:

``````twice(E, L) :-
phrase(( all(dif(E)), [E], all(dif(E)), [E], all(dif(E)) ), L).
``````

There is essentially only one drawback with these definitions: On current systems, they are not optimally implemented. See this if you want to know more.

Stay both logically pure and efficient by using `if_/3` and `(=)/3` by @false. It goes like this:

``````list_member1x([X|Xs],E) :-
if_(X=E, maplist(dif(E),Xs), list_member1x(Xs,E)).

list_member2x([X|Xs],E) :-
if_(X=E, list_member1x(Xs,E), list_member2x(Xs,E)).

twice(E,Xs) :-
list_member2x(Xs,E).
``````

That's it. Let's run some queries!

``````?- twice(E,[1,2,3,4,5,2,3,4]).
E = 2 ;
E = 3 ;
E = 4 ;
false.
``````

Now something a little more general:

``````?- twice(X,[A,B,C,D]).
A=X ,     B=X , dif(C,X), dif(D,X) ;
A=X , dif(B,X),     C=X , dif(D,X) ;
A=X , dif(B,X), dif(C,X),     D=X  ;
dif(A,X),     B=X ,     C=X , dif(D,X) ;
dif(A,X),     B=X , dif(C,X),     D=X  ;
dif(A,X), dif(B,X),     C=X ,     D=X  ;
false.
``````

Here are the queries the OP gave:

``````?- twice(2,[1,2,2,3,4]).
true.

?- twice(E,[1,1,2,2,3,3]).
E = 1 ;
E = 2 ;
E = 3 ;
false.
``````

### Edit

As an alternative, use `tcount/3` in combination with `(=)/3` like this:

``````twice(E,Xs) :- tcount(=(E),Xs,2).
``````

Try:

``````twice(E,L) :-
append(B1,[E|A1],L),
\+ member(E,B1),
append(B2,[E|A2],A1),
\+ member(E,B2),
\+ member(E,A2).
``````

In case that the list of number could be (partially) unbound, following variant solves the issues. It uses "dif" instead of "\=", "+". In addition, it is a few optimized ("append" and "member" have been joined to a single "appendchk"):

``````appendchk(L,L).
appendchk([E|Q2],[H|R]) :-
dif(H,E),
appendchk([E|Q2],R).

notmember(_,[]).
notmember(X,[H|Q]) :-
dif(X,H),
notmember(X,Q).

twice(E,L) :-
appendchk([E|A1],L),
appendchk([E|A2],A1),
notmember(E,A2).
``````

Examples:

``````twice(1,[1,2,3,4,2,3,2]).
false

twice(2,[1,2,3,4,2,3,2]).
false

twice(3,[1,2,3,4,2,3,2]).
true

twice(X,[1,2,3,4,2,3,2]).
X = 3
false

twice(X,[A,B]).
A = B, B = X

twice(X,[A,B,C]).
A = B, B = X,
dif(X, C)
A = C, C = X,
dif(B, X)
B = C, C = X,
dif(A, X)
``````
• `twice(E,[A,B])` correctly succeeds with `A = B`. But `twice(E,[A,B,C])` fails. – false Jun 8 '15 at 19:06
• `s(X)` for the nice & pure addendum! Pure code like that is much easier to debug: Simply look at the answers you got. – false Jun 10 '15 at 11:22
• BTW, what Prolog do you use? I suspect SWI, but somehow you removed all the `;` and `.` from SWI's answers. They are here to insist that you can re-enter them! – false Jun 10 '15 at 11:22
• @false: when I've made this test, I'd only a small tablet without any prolog, so I used "swish" at internet. In this GUI, some of the usual symbols are not present or lost at copy&paste; I do not understand the "s(X)" meaning. – pasaba por aqui Jun 10 '15 at 14:37
• `s(X)` means: successor of `X`. Other languages call this `+1`. – false Jun 10 '15 at 14:42

Here is how we can declare, courtesy library(aggregate), the required constraint:

``````twice(El, L) :-
aggregate(count, P^nth1(P,L,El), 2).
``````

Where list' elements are restricted to integers, library(clpfd) reification hint hosts another solution:

``````twice(El, L) :- vs_n_num(L,El,2).
% aggregate(count, P^nth1(P,L,El), 2).
``````
• Your first definition fails for `twice(e,[e,X])` but succeeds for `X=e, twice(e,[e,X])`. So whatever this aggregate provides, is not a pure relation. – false Jun 10 '15 at 11:28
• Your second definition is very weak: `vs_n_num([X,Y,Y],X,2).` succeeds with an inconsistency, while it could simply and quickly fail. In general, `library(clpfd)` is not very strong for equality and inequality. – false Jun 10 '15 at 11:33