I'm hoping for suggestions on how to accomplish this:

Definition: An undirected graph G is definied by a set V of vertices and a set E of edges where each edge is a subset of V of size two, i.e. an unordered pair {u, v} of vertices. A cycle of length k in G is a sequenc v_1, ..., v_k of distinct vertices for which {v_1, v_2}, {v_2, v_3}, ..., {v_k-1, v_k}, {v_k, v_1} are all edges of G. A Hamiltonian cycle in G is a cycle of length n = |V|, i.e. a chcle that passes through each vertex of the graph exactly once. We call G Hamiltonian if it has a Hamiltonian cycle.

Problem: Provide a propositional logic formulation of the following decision problem: given an undi- rected graph G, is G Hamiltonian? The formulation will be checked by Z3.

The input format will be:

```
4
0 1
1 2
2 3
3 0
1 3
```

where the first number represents the number of vertices and the remaining pairs are all edges in G.

The output should be: 0 1 2 3

Obviously the output will always be some permutation of the numbers 1, ..., n-1 where n = |V| but I don't see how to work with integers using only Proposition Logic.

Any advice is appreciated.

Regards.

Here's a solution that works for the given input. If I could write a perl routine that would produce combinations (n Choose k) of edges then I could generalize this to any number of inputs:

```
(declare-const v0 Bool)
(declare-const v1 Bool)
(declare-const v2 Bool)
(declare-const v3 Bool)
(declare-const e1 Bool)
(declare-const e2 Bool)
(declare-const e3 Bool)
(declare-const e4 Bool)
(declare-const e5 Bool)
(assert (xor (and e1 e2 e3 e4) (and e1 e2 e3 e5) (and e1 e2 e4 e5) (and e1 e3 e4 e5) (and e2 e3 e4 e5)))
(assert (and v0 v1 v2 v3))
(assert (=> e1 (and v0 v1)))
(assert (=> e2 (and v1 v2)))
(assert (=> e3 (and v2 v3)))
(assert (=> e4 (and v3 v0)))
(assert (=> e5 (and v1 v3)))
(check-sat)
(get-model)
```