It might help if you point to the explanations that are lacking, but I'll try anyway...

The O(2^{k})-based solution uses the inclusion-exclusion principle. Given that there are *k* forbidden edges, there are *2*^{k} subsets of those edges, including the set itself and the empty set. For instance, if there were 3 forbidden edges: {A, B, C}, there would be 2^{3}=8 subsets: {}, {A}, {B}, {C}, {A,B}, {A,C}, {B,C}, {A,B,C}.

For each subset, you calculate the number of cycles that include at least all the edges in that subset . If the number of cycles containing edges *s* is *f(s)* and *S* is the set of all forbidden edges, then by the inclusion-exclusion principle, the number of cycles without any forbidden edges is:

```
sum, for each subset s of S: f(s) * (-1)^|s|
```

where |*s*| is the number of elements in *s*. Put another way, the sum of the number of cycles with any edges *minus* the number of cycles with at least 1 forbidden edge *plus* the number with at least 2 forbidden edges, ...

Calculating *f(s)* is not trivial -- at least I didn't find an easy way to do it. You might stop and ponder it before reading on.

To calculate *f(s)*, start with the number of permutations of the nodes not involved with any *s* nodes. If there are *m* such nodes, there are *m*! permutations, as you know. Call the number of permutations *c*.

Now examine the edges in *s* for chains. If there are any impossible combinations, such as a node involved with 3 edges or a subcycle within *s*, then *f(s)* is 0.

Otherwise, for each chain increment *m* by 1 and multiply *c* by *2m*. (There are *m* places to put the chain in the existing permutations and the factor of 2 is because the chain can be forwards or backwards.) Finally, *f(s)* is *c*/(*2m*). The last division converts permutations to cycles.