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,
permute([ ],[ ]) :- !.
oneCycle2permute(_,[ ],[ ]) :- !.
mapCycle([X],X,X) :- !.
mapCycleAux(Y,[X],X,Y) :- !.
mapCycleAux(X,[Y|_],X,Y) :- !.
mapCycleAux(_,[X,Y|_],X,Y) :- !.