蛮不错的一道题，遗憾就遗憾在数据范围会导致暴力轻松跑过。

最小生成树的两个性质：

• 不同的最小生成树，相同权值使用的边数一定相同。

• 不同的最小生成树，将其都去掉同一个权值的所有边，其连通性一致。

这样我们随便跑一个\(MST\)，就可以知道所有\(MST\)边的构造情况。由于性质二，我们可以考虑枚举每一种权值的所有边，保留所有非此权值的树边，看可以连出来多少种不同的最小生成树。也就是按照权值构造最小生成树，这个过程满足乘法原理。

#include <bits/stdc++.h>

using namespace std;

#define int long long

const int N = 100 + 5;

const int M = 1000 + 5;

const int Mod = 31011;

struct Len {

	int u, v, w;

	bool operator < (Len rhs) const {

		return w < rhs.w;

	}

}l[M];

vector <Len> v;

int n, m, S[N];

int find (int x) {

	return S[x] == x ? x : S[x] = find (S[x]);

}

vector <int> val, use, tot;

vector <int> :: iterator it;

void kruskal () {

	sort (l + 1, l + 1 + m);

	for (int i = 0; i <= n; ++i) S[i] = i;

	for (int i = 1; i <= m; ++i) {

		int fu = find (l[i].u);

		int fv = find (l[i].v);

		it = lower_bound (val.begin (), val.end (), l[i].w);

		if (it == val.end ()) {

			val.push_back (l[i].w);

			use.push_back (0);

			tot.push_back (1);

		} else {

			tot[it - val.begin ()]++;

		}

		if (fu != fv) {

			S[fu] = fv;

			it = lower_bound (val.begin (), val.end (), l[i].w);

			use[it - val.begin ()]++;

			v.push_back (l[i]);

		}

	}

}

int mat[N][N];

int gauss (int n) {

	int ret = 1;

	for (int i = 1; i <= n; ++i) {

		for (int k = i + 1; k <= n; ++k) {

			while (mat[k][i]) {

				int d = mat[i][i] / mat[k][i];

				for (int j = i; j <= n; ++j) {

					(((mat[i][j] -= d * mat[k][j]) %= Mod) += Mod) %= Mod;

				}

				swap (mat[i], mat[k]); ret = -ret;

			}

		}

		(((ret *= mat[i][i]) %= Mod) += Mod) %= Mod;

	}

	return abs (ret);

}

void add_edge (int u, int v) {

	mat[u][u]++;

	mat[v][v]++;

	mat[u][v]--;

	mat[v][u]--;

}

int sep[N]; 

int solve () {

	kruskal ();

	if (v.size () < n - 1) return 0;

	int ans = 1;

	for (int i = 0; i < val.size (); ++i) {

		memset (mat, 0, sizeof (mat));

		if (use[i] == 0 || tot[i] == use[i]) continue;

		for (int j = 0; j <= n; ++j) S[j] = j;

		for (int j = 0; j < v.size (); ++j) {

			if (v[j].w != val[i]) {

				S[find (v[j].u)] = find (v[j].v);

			}

		}

		int cnt = 0;

		for (int i = 1; i <= n; ++i) {

			sep[++cnt] = find (i);

		}

		sort (sep + 1, sep + 1 + cnt);

		cnt = unique (sep + 1, sep + 1 + cnt) - sep - 1;

		for (int j = 1; j <= m; ++j) {

			if (l[j].w == val[i]) {

				int fu = find (l[j].u);

				int fv = find (l[j].v);

				fu = lower_bound (sep + 1, sep + 1 + cnt, fu) - sep;

				fv = lower_bound (sep + 1, sep + 1 + cnt, fv) - sep;

				add_edge (fu, fv);

			}

		}

		(ans *= gauss (use[i])) %= Mod;

	}

	return ans;

}

signed main () {

//	freopen ("data.in", "r", stdin);

	cin >> n >> m;

	for (int i = 1; i <= m; ++i) {

		static int u, v, w;

		cin >> u >> v >> w;

		l[i] = (Len) {u, v, w};

	}

	cout << solve () << endl;

}