// TLE O(4^n n^2)

#pragma GCC target("avx2")
#pragma GCC optimize("O3")
#pragma GCC optimize("unroll-loops")

#include <algorithm>
#include <array>
#include <cassert>
#include <iostream>
#include <limits>
#include <utility>
#include <vector>

#ifdef _MSC_VER
#  include <intrin.h>
#else
#  include <x86intrin.h>
#endif

namespace library {
    namespace bits {
        template <typename T, std::enable_if_t<std::is_integral_v<T>, std::nullptr_t> = nullptr>
        T kth_bit(T v, size_t k) { return (v >> k) & 1; }
        template <typename T, std::enable_if_t<std::is_integral_v<T>, std::nullptr_t> = nullptr>
        size_t bit_length(const T v) {
            if constexpr (std::numeric_limits<std::make_unsigned_t<T>>::digits <= 32) {
                return 32 - __builtin_clz(v);
            } else {
                return 64 - __builtin_clzll(v);
            }
        }
        template <typename T, std::enable_if_t<std::is_integral_v<T>, std::nullptr_t> = nullptr>
        size_t popcount(const T v) {
            if constexpr (std::numeric_limits<std::make_unsigned_t<T>>::digits <= 32) {
                return __builtin_popcount(v);
            } else {
                return __builtin_popcountll(v);
            }
        }
        template <typename T, std::enable_if_t<std::is_integral_v<T>, std::nullptr_t> = nullptr>
        size_t count_tz(const T v) {
            if constexpr (std::numeric_limits<std::make_unsigned_t<T>>::digits <= 32) {
                return __builtin_ctz(v);
            } else {
                return __builtin_ctzll(v);
            }
        }

        // See https://www.intel.com/content/www/us/en/docs/intrinsics-guide/index.html#text=_pdep&ig_expand=4939
        template <typename T, std::enable_if_t<std::is_integral_v<T>, std::nullptr_t> = nullptr>
        __attribute__((target("bmi2"))) T pdep(const T src, const T mask) {
            /*
            T dst = 0;
            for (size_t i = 0, j = 0; i < BIT_NUM; ++i) {
                if (kth_bit(mask, i)) dst |= kth_bit(src, j) << i, ++j;
            }
            return dst;
            */
            if constexpr (std::numeric_limits<std::make_unsigned_t<T>>::digits <= 32) {
                return _pdep_u32(src, mask);
            } else {
                return _pdep_u64(src, mask);
            }
        }
    }

    namespace subset_transform {
        template <typename T> void zeta(std::vector<T>& x) {
            const size_t n = x.size();
            for (size_t b = 1; b < n; b *= 2) for (size_t l = 0; l < n; l += 2 * b) for (size_t i = l; i < l + b; ++i) {
                x[i + 1 * b] += x[i + 0 * b];
            }
        }
        template <typename T> void mobius(std::vector<T>& x) {
            const size_t n = x.size();
            for (size_t b = 1; b < n; b *= 2) for (size_t l = 0; l < n; l += 2 * b) for (size_t i = l; i < l + b; ++i) {
                x[i + 1 * b] -= x[i + 0 * b];
            }
        }
    }

    namespace set_power_series {
        namespace details {
            template <size_t N>
            void push_front(std::array<uint64_t, N> &a, uint64_t v) {
                for (size_t i = N; i --> 1;) a[i] = a[i - 1];
                a[0] = v;
            }
            template <size_t N>
            void muleq(std::array<uint64_t, N>& p, const std::array<uint64_t, N>& q, size_t siz) {
                for (size_t i = siz; i --> 0;) {
                    uint64_t val = 0;
                    for (size_t j = 0; j <= i; ++j) val += p[i - j] * q[j];
                    p[i] = val;
                }
            }

            template <size_t N, typename InputIterator>
            std::vector<std::array<uint64_t, N + 1>> add_rank(InputIterator first, InputIterator last) {
                const size_t n = last - first;
                std::vector<std::array<uint64_t, N + 1>> fs(n);
                for (size_t i = 0; i < n; ++i) {
                    fs[i][bits::popcount(i)] = first[i];
                }
                return fs;
            }
            template <size_t N>
            std::vector<std::array<uint64_t, N + 1>> add_rank(const std::vector<uint64_t> &a) {
                return add_rank<N>(a.begin(), a.end());
            }
            template <size_t N>
            std::vector<uint64_t> remove_rank(const std::vector<std::array<uint64_t, N + 1>>& polys) {
                const size_t n = polys.size();
                std::vector<uint64_t> a(n);
                for (size_t i = 0; i < n; ++i) a[i] = polys[i][bits::popcount(i)];
                return a;
            }
        }
        
        template <size_t N>
        std::vector<uint64_t> subset_exp(const std::vector<uint64_t>& f) {
            assert(f[0] == 0);
            const size_t n = bits::bit_length(f.size()) - 1;
            auto rf = details::add_rank<N>({ 1 });
            rf.reserve(size_t(1) << n);
            for (size_t k = 0; k < n; ++k) {
                auto rg = details::add_rank<N>(f.begin() + (1 << k), f.begin() + (1 << (k + 1)));
                {
                    const size_t n = rg.size();
                    for (size_t b = 1; b < n; b *= 2) for (size_t l = 0; l < n; l += 2 * b) for (size_t i = l; i < l + b; ++i) {
                        const size_t s = i, t = i + b;
                        for (size_t q = 0; q <= k; ++q) {
                            rg[t][q] += rg[s][q];
                        }
                    }
                }
                for (size_t j = 0; j < size_t(1) << k; ++j) {
                    details::push_front(rg[j], 1);
                    details::muleq(rg[j], rf[j], k + 2);
                    rf.push_back(rg[j]);
                }
            }
            {
                const size_t k = n;
                const size_t n = rf.size();
                for (size_t b = 1; b < n; b *= 2) for (size_t l = 0; l < n; l += 2 * b) for (size_t i = l; i < l + b; ++i) {
                    const size_t s = i, t = i + b;
                    for (size_t q = 0; q <= k; ++q) {
                        rf[t][q] -= rf[s][q];
                    }
                }
            }
            return details::remove_rank<N>(rf);
        }
    }
}

constexpr size_t N_MAX = 13;

using vertex = size_t;
using vertex_set = size_t;
using edge = std::pair<vertex, vertex>;
using Int = uint64_t;
using set_power_series = std::vector<Int>;

std::vector<Int> count_cycles(const size_t n, const size_t, const std::vector<edge>& edges) {
    // adjacency list
    std::vector adj(n, std::vector<vertex>{});
    for (const auto& [u, v] : edges) adj[u].push_back(v), adj[v].push_back(u);

    // "c" mentioned in the editorial
    std::vector<Int> c(1u << n);

    // dp[S: vertex set][v: vertex] := # simple paths from min S to v passing vertices in S (but not passing vertices not in S)
    std::vector dp(1u << n, std::vector<Int>(n));
    // base cases
    for (vertex v = 0; v < n; ++v) {
        dp[1u << v][v] = 1;
    }

    for (vertex_set S = 1; S < 1u << n; ++S) {
        // min S
        const vertex start = library::bits::count_tz(S);
        for (vertex cur = 0; cur < n; ++cur) for (const vertex nxt : adj[cur]) {
            if (start == nxt) {
                c[S] += dp[S][cur];
            } else if (start < nxt and not library::bits::kth_bit(S, nxt)) {
                const vertex_set T = S | (1u << nxt);
                dp[T][nxt] += dp[S][cur];
            }
        }
    }

    for (vertex_set S = 1; S < 1u << n; ++S) {
        const size_t card = library::bits::popcount(S);
        if (card == 1) c[S] = 1;
        if (card == 2) c[S] = 0;
        if (card >= 3) c[S] /= 2;
    }
    return c;
}

Int solve(const size_t n, const size_t m, const std::vector<edge> &edges) {
    // E[S: vertex set] := # edges connecting vertices in S.
    std::vector<Int> E(1u << n);
    for (const auto& [u, v] : edges) ++E[(1u << u) | (1u << v)];
    library::subset_transform::zeta(E);

    // "c" mentioned in the editorial
    const set_power_series c = count_cycles(n, m, edges);

    // "f" mentioned in the editorial
    set_power_series f(1u << n);
    for (vertex_set C = 1; C < 1u << n; ++C) if (c[C]) {
        // max C
        const vertex t = library::bits::bit_length(C) - 1;
        // {0, ..., t} - C
        const vertex_set S = ((1u << (t + 1)) - 1) ^ C;
        const size_t k = library::bits::popcount(S);
        // "g_C" mentioned in the editorial
        set_power_series g(1u << k);
        for (vertex_set A = 0; A < 1u << k; ++A) {
            // For more information about pdep, see https://www.intel.com/content/www/us/en/docs/intrinsics-guide/index.html#text=_pdep&ig_expand=4939.
            const vertex_set T = library::bits::pdep(A, S);
            g[A] = f[T] * (E[T | C] - E[T] - E[C]);
        }
        // "h_C" mentioned in the editorial
        const set_power_series h = library::set_power_series::subset_exp<N_MAX>(g);
        for (vertex_set A = 0; A < 1u << k; ++A) {
            const vertex_set X = library::bits::pdep(A, S) | C;
            f[X] += c[C] * h[A];
        }
    }
    return library::set_power_series::subset_exp<N_MAX>(f).back();
}

int main() {
    size_t n, m;
    std::cin >> n >> m;
    std::vector<edge> edges(m);
    for (auto &[u, v] : edges) {
        std::cin >> u >> v;
        --u, --v;
    }
    std::cout << solve(n, m, edges) << '\n';
}