题目大意
求出(n)个点的简单(无重边无自环)有标号无向连通图数目。(nleq 130000)。
题解
题意非常简单,但做起来很难。这是道生成函数经典题,博主当做例题学习用的。博主看到题解后感到非常惊讶:生成函数还能这么玩!
步入正题。首先我们要定义生成函数(F(x)=sumlimits_{igeq 0}f_idfrac{x^i}{i!}),其中(f_i)表示(i)个点无向连通图数目。
定义生成函数(G(x)=sumlimits_{igeq 0}dfrac{F^i(x)}{i!})。观察发现,(G)的第(i)项系数表示表示的是(i)个连通块构成的若干个结点的图的方案数,(F(x))用( ext{EFG})是因为会牵扯到组合数选择要除掉各个对应的阶乘,(G(x))除掉(i!)的阶乘是因为(i)组中会重复。不难发现:(G(x))表示的是若干结点的无向图总数!
根据泰勒展开有:
[G(x)=e^{F(x)}
]
所以我们有:
[F(x)=ln G(x)
]
多项式求(ln)即可。
复杂度:( ext{O}(nlog n))。
归纳上面的思路:利用任意个点连通图的数目与任意个点图的数目列等式,然后反解连通图的数目,从而得到答案
代码
#include <bits/stdc++.h>
using namespace std;
const int maxn = 130000 + 5;
const int P = 1004535809, g = 3;
int inc(int a, int b) { return (a += b) >= P ? a-P : a; }
int qpow(int a, int b) {
int res = 1;
for (int i = a; b; i = 1ll*i*i%P, b >>= 1)
if (b & 1) res = 1ll*res*i%P;
return res;
}
int W[maxn << 3], inv[maxn << 2], fac[maxn << 2], ifac[maxn << 2];
void prework(int n) {
for (int i = 1; i < n; i <<= 1) {
W[i] = 1;
for (int j = 1, Wn = qpow(g, (P-1)/i>>1); j < i; j++) W[i+j] = 1ll*W[i+j-1]*Wn%P;
}
inv[1] = fac[0] = ifac[0] = 1;
for (int i = 2; i < n; i++) inv[i] = 1ll*(P-P/i)*inv[P%i]%P;
for (int i = 1; i < n; i++) fac[i] = 1ll*fac[i-1]*i%P, ifac[i] = 1ll*ifac[i-1]*inv[i]%P;
}
void ntt(int *a, int n, int opt) {
static int rev[maxn << 2];
for (int i = 1; i < n; i++)
if ((rev[i] = rev[i>>1]>>1|(i&1?n>>1:0)) > i) swap(a[i], a[rev[i]]);
for (int q = 1; q < n; q <<= 1)
for (int p = 0; p < n; p += q << 1)
for (int i = 0, t; i < q; i++)
t = 1ll*W[q+i]*a[p+q+i]%P, a[p+q+i] = inc(a[p+i], P-t), a[p+i] = inc(a[p+i], t);
if (~opt) return;
for (int i = 0; i < n; i++) a[i] = 1ll*a[i]*inv[n]%P;
reverse(a+1, a+n);
}
struct poly {
vector<int> A;
int len;
poly(int a0 = 0) : len(1) { A.push_back(a0); }
int &operator [] (int i) { return A[i]; }
void write() {
for (int i = 0; i < len; i++) printf("%d ", A[i]);
putchar('
');
}
void load(int *from, int n) {
A.resize(len = n);
memcpy(&A[0], from, sizeof(int) * len);
}
void cpyto(int *to, int n) {
memcpy(to, &A[0], sizeof(int) * min(len, n));
}
void resize(int n = 0) {
if (!n) { while (len > 1 && !A[len - 1]) len--; A.resize(len); } else A.resize(len = n, 0);
}
} F, G;
poly poly_inv(poly A) {
poly B = poly(qpow(A[0], P-2));
for (int len = 1; len < A.len; len <<= 1) {
static int x[maxn << 2], y[maxn << 2];
for (int i = 0; i < len << 2; i++) x[i] = y[i] = 0;
A.cpyto(x, len << 1), B.cpyto(y, len);
ntt(x, len << 2, 1), ntt(y, len << 2, 1);
for (int i = 0; i < len << 2; i++) x[i] = inc(y[i], inc(y[i], P-1ll*x[i]*y[i]%P*y[i]%P));
ntt(x, len << 2, -1);
B.load(x, len << 1);
}
return B.resize(A.len), B;
}
poly operator + (poly A, poly B) {
if (A.len < B.len) A.resize(B.len);
for (int i = 0; i < B.len; i++) A[i] = inc(A[i], B[i]);
return A.resize(), A;
}
poly operator - (poly A, poly B) {
if (A.len < B.len) A.resize(B.len);
for (int i = 0; i < B.len; i++) A[i] = inc(A[i], P-B[i]);
return A.resize(), A;
}
int getsize(int n) { int N = 1; while (N < n) N <<= 1; return N; }
poly operator * (poly A, poly B) {
static int x[maxn << 2], y[maxn << 2];
int len = getsize(A.len + B.len - 1);
for (int i = 0; i < len; i++) x[i] = y[i] = 0;
A.cpyto(x, A.len), B.cpyto(y, B.len);
ntt(x, len, 1), ntt(y, len, 1);
for (int i = 0; i < len; i++) x[i] = 1ll*x[i]*y[i]%P;
ntt(x, len, -1);
return A.load(x, A.len + B.len - 1), A.resize(), A;
}
poly poly_deri(poly A) {
for (int i = 0; i < A.len - 1; i++) A[i] = 1ll*A[i+1]*(i+1)%P;
return A[A.len - 1] = 0, A.resize(), A;
}
poly poly_int(poly A) {
for (int i = A.len - 1; i; i--) A[i] = 1ll*A[i-1]*inv[i]%P;
return A[0] = 0, A;
}
poly poly_ln(poly A) {
poly B = poly_deri(A) * poly_inv(A);
return B.resize(A.len), poly_int(B);
}
int n;
int main() {
scanf("%d", &n); prework((n+1)<<2);
G.resize(n+1);
for (int i = 1; i <= n; i++) G[i] = 1ll*qpow(2, 1ll*i*(i-1)/2%(P-1))*ifac[i]%P;
G[0] = 1;
F = poly_ln(G);
printf("%d", 1ll*F[n]*fac[n]%P);
return 0;
}