# Permuted combinations of the elements of a list - Prolog

How can I generate all the possible combinations of the elements of a list?

For example, given the list [1,2,3], I want to design a predicate with the form `comb([1,2,3], L).` which should return the following answer for L:
`[1]`
`[2]`
`[3]`
`[1,2]`
`[2,1]`
`[1,3]`
`[3,1]`
`[2,3]`
`[3,2]`
`[1,2,3]`
`[1,3,2]`
`[2,1,3]`
`[2,3,1]`
`[3,1,2]`
`[3,2,1]`

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[1] isn't usually called a combination of [1,2,3]: I'm guessing this isn't what you mean. –  Charles Stewart Jan 2 '11 at 14:35

What you are asking for involves both combinations (selecting a subset) and permutations (rearranging the order) of a list.

Your example output implies that the empty list is not considered a valid solution, so we will exclude it in the implementation that follows. Reconsider if this was an oversight. Also this implementation produces the solutions in a different order than your example output.

``````comb(InList,Out) :-
splitSet(InList,_,SubList),
SubList = [_|_],     /* disallow empty list */
permute(SubList,Out).

splitSet([ ],[ ],[ ]).
splitSet([H|T],[H|L],R) :-
splitSet(T,L,R).
splitSet([H|T],L,[H|R]) :-
splitSet(T,L,R).

permute([ ],[ ]) :- !.
permute(L,[X|R]) :-
omit(X,L,M),
permute(M,R).

omit(H,[H|T],T).
omit(X,[H|L],[H|R]) :-
omit(X,L,R).
``````

Tested with Amzi! Prolog:

``````?- comb([1,2,3],L).

L = [3] ;

L = [2] ;

L = [2, 3] ;

L = [3, 2] ;

L = [1] ;

L = [1, 3] ;

L = [3, 1] ;

L = [1, 2] ;

L = [2, 1] ;

L = [1, 2, 3] ;

L = [1, 3, 2] ;

L = [2, 1, 3] ;

L = [2, 3, 1] ;

L = [3, 1, 2] ;

L = [3, 2, 1] ;
no
``````
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there is a predefined predicate called permutation ...

``````1 ?- permutation([1,2,3],L).
L = [1, 2, 3] ;
L = [2, 1, 3] ;
L = [2, 3, 1] ;
L = [1, 3, 2] ;
L = [3, 1, 2] ;
L = [3, 2, 1] .

2 ?- listing(permutation).
lists:permutation([], [], []).
lists:permutation([C|A], D, [_|B]) :-
permutation(A, E, B),
select(C, D, E).

lists:permutation(A, B) :-
permutation(A, B, B).

true.
``````

hope this helps ..

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Hint: This is easy to do if you have written a function inselt(X,Y,Z), which holds if any insertion of Y into X gives Z:

``````inselt([E|X], Y, [E|Z]) :- inselt (X,Y,Z).
inselt(X, Y, [Y|X]).
``````

Then comb/3 can be coded recursively using inselt/3.

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