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Let's take a permutation of numbers 1,2,3,4, which has only one cycle. For example it can be: 2,3,4,1. I was wondering, how I can generate using Prolog all this permutations. I know how generate all permutation using function select. But I can't come up with an idea, how generate only one-cycle permutation.

Maybe someone can give me a small prompt or adivce.

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Given n symbols, there are (n-1)! one-cycle permutations of those symbols. Why? – hardmath Dec 29 '11 at 18:31
read about Stirling numbers of the first kind, which count the number of permutations of n elements with k disjoint cycles. You should see the recurence, and this should help you, or I can explain you – xyz Dec 29 '11 at 20:14
Please do not remove your question from Stack Overflow. Some people takes time to make good answers, respect their work. – regilero Jan 10 '12 at 19:35

Couldn't you use the function for generating all permutations, and filter out the ones that aren't 'one-cycle permutations'? (Since I'm not at all clear on what 'one-cycle permutations' are, I'm afraid I can't help with writing that filter.)

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one-cycle([H|T], Permutation) :-
    permutation([H|T], Permutation),
    cycle(H, [H], [H|T], Permutation, Cycle),
    length(Cycle, CycleLength),
    length([H|T], ListLength),
    CycleLength =:= ListLength.

The cycle/5 predicate builds the cycle corresponding to the first argument you pass it. the second argument is an accumulator, initialized to [FirstArgument], the third and fourth one are the original List and Permutation, the last one is the result (the list containing the elements of the cycle).

cycle(Current, Acc, List, Permutation, Cycle) :-

The call to corresponds/4 retrieves the item that took the place of the first argument in the permutation :

    corresponds(Current, List, Permutation, R),

If this item is in the cycle we're building, it means we're done building the cycle, so we unify Cycle and the accumulator (Acc).

    (   member(R, Acc)
     -> Cycle = Acc

If not, we go on by calling recursively our predicate with the corresponding item we found and we add it to the accumulator, so that our building cycle now holds it :

     ;  cycle(R, [R|Acc], List, Permutation, Cycle)).

corresponds(N, [N|_], [R|_], R) :-
corresponds(N, [_|L], [_|P], R) :-
    corresponds(N, L, P, R).

Usage :

?- one-cycle([1, 2, 3, 4], P).
P = [2, 3, 4, 1] ;
P = [3, 1, 4, 2] ;
P = [3, 4, 2, 1] ;
P = [2, 4, 1, 3] ;
P = [4, 1, 2, 3] ;
P = [4, 3, 1, 2] ;
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about cycles and what means one-cycle you can read here: – xyz Dec 28 '11 at 14:39
something about the algorithm: we want find one-cycle permutation. So we have two lists L and P. P is the permutation of L with only one cycle. So, first we check if true: permutation(L,P). Then we can see, that head of L and head of P shoudn't be the same number. Next, let's take [1,2,3,4] and [4,1,2,3], so we see that if we choose head from L and from P we notice that 2,3,4 can't be the permutation of [1,2,3] (because of the definition of one cycle). – xyz Dec 28 '11 at 18:31
I added what I think is a correct solution, since now I understood what cycles are (at last :( ) – m09 Dec 28 '11 at 18:33
I just basically build one cycle, and if this cycle isn't of the size of the list then the permutation isn't a one-cycle one. What do you think of it ? – m09 Dec 28 '11 at 18:35
@xyz I tried to explain. Hope it helps. – m09 Dec 28 '11 at 19:12

My comment was intended as a hint for producing directly the single cycle permutations, rather than generating all permutations and filtering out the ones that consist of a single cycle.

We should perhaps clarify that two representations of permutations are frequently used. xyz writes "I know how [to] generate all permutation[s]," presumably meaning something like the code I gave in this 2006 forum post. Here all permutations are represented according to the way a list rearranges the items in some "standard order" list.

Obviously there are N! permutations of all kinds. How many of these are single cycle permutations? That question is easily answered by contemplating the other form useful for permutations, namely as a product of disjoint cycles. We need to distinguish between a cycle like (1,2,3,4) and the identity permutation [1,2,3,4]. Indeed the cycle (1,2,3,4) maps 1 to 2, 2 to 3, 3 to 4, and 4 back to 1, so rather than the identity permutation it would be [2,3,4,1] in its list representation.

Now a cycle loops back on itself, so it is arbitrary where we choose to begin the cycle notation. If we start at 1, for example, then the cycle is determined by the ordering of the following N-1 items. This shows there are (N-1)! permutations of N things that form a single cycle (necessarily of length N). Thus we can generate all single cycle permutations in cycle form easily enough, and the problem then reduces to converting from that cycle form to the list form of a permutation. [Note that in part Mog tackled the conversion going in the other direction: given a permutation as list, ferret out a cycle contained in that permutation (and see if it is full length).]

Here's my code for generating all the one-cycle list permutations of a given "standard order" list, oneCycle(Identity,Permuted):

oneCycle([H|T],P) :-

permute([ ],[ ]) :- !.
permute(L,[H|T]) :-

omit(X,[H|T],[H|Z]) :-

oneCycle2permute(_,[ ],[ ]) :- !.
oneCycle2permute(C,[I|Is],[P|Ps]) :-

mapCycle([X],X,X) :- !.
mapCycle([H|T],X,Y) :-

mapCycleAux(Y,[X],X,Y) :- !.
mapCycleAux(X,[Y|_],X,Y) :- !.
mapCycleAux(_,[X,Y|_],X,Y) :- !.
mapCycleAux(H,[_|T],X,Y) :-
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