题意
给你一个\(n*m\)方格图,统计上面有多少个格点三角形,除了三个顶点,不覆盖其他的格点(包括边和内部).
答案对于\(998244353\)取模... (\(n,m \le 5 * 10^9\))
题解
这个题十分的巧妙... 集训时是大佬ztzshiwo出的..
据他所说,是不那么杜教筛的杜教筛QAQ
考试时候提示了一个皮克定理...
然而我还是只会暴力,正解是真的太神了啊QAQ.
我们考虑一个\(a*b\)的矩形,以它对顶点为端点的三角形,只当\(a \bot b\)时存在四个解.
这个我是听wearry证明的qwq 十分巧妙
所以我们要求的就是原图中每个矩形的贡献就行了...
此处\(n\),\(m\)都是要减一的... (至于为啥...手推就知道了QAQ)
\]
\]
\]
令$$\displaystyle S(i)=\sum_{i=1}^{n} i = \frac{n(n+1)}{2}$$.
\]
\]
\]
\]
\]
这个用根号分块就能做到\(\Theta (n+\sqrt {n})\)复杂度啦... 具体推导证明看我的一篇博客线性筛与莫比乌斯反演.
然而这并不能满分...fuck
所以就有杜教筛卡了30分.
\(\displaystyle \sum _{i=1}^{n} \mu(i)\)之前那篇博客杜教筛小结中有介绍.
然后就介绍另外两个套路求的东西吧..
令\(\displaystyle id(x)=x, mx(x)= \mu(i) i\). (然后之后默认把第一个字母大写记作前缀和比如\(\displaystyle Id(x)=\sum_{i=1}^{x} id(i) = \frac{x(x+1)}{2}\))
所以就有
\]
\]
\]
代入之前的套路式子就有
\]
然后就可以尝试推出\(\displaystyle \sum _{i=1}^{n} \mu(i) \cdot i \cdot i\).
这个也不麻烦QAQ...
然后本人比较懒 就直接用c++11
中的unordered_map
了(这个基于哈希算法)
有些地方有点细节\(5*10^9 * 5*10^9 = 2.5 * 10^{19}\)会爆long long
所以很多地方都要记得先取模!!!
代码
#include <bits/stdc++.h>
#define For(i, l, r) for(register ll i = (l), _end_ = (ll)(r); i <= _end_; ++i)
#define Fordown(i, r, l) for(register ll i = (r), _end_ = (ll)(l); i >= _end_; --i)
#define Set(a, v) memset(a, v, sizeof(a))
using namespace std;
typedef long long ll;
inline ll read() {
ll x = 0, fh = 1; char ch = getchar();
for (; !isdigit(ch); ch = getchar() ) if (ch == '-') fh = -1;
for (; isdigit(ch); ch = getchar() ) x = (x<<1) + (x<<3) + (ch ^ '0');
return x * fh;
}
void File() {
#ifdef zjp_shadow
freopen ("1456.in", "r", stdin);
freopen ("1456.out", "w", stdout);
#endif
}
const ll Mod = 998244353;
ll n, m;
const int N = 1e7 + 1e3;
int prime[N], cnt = 0;
int Limit = N - 1e3;
ll mux[N], muxx[N], mu[N];
bitset<N> is_prime;
void Init(int maxn) {
int res;
mu[1] = 1;
is_prime.set(); is_prime[0] = is_prime[1] = false;
For (i, 2, maxn) {
if (is_prime[i]) { prime[++cnt] = i; mu[i] = -1; }
For (j, 1, cnt) {
res = prime[j] * i;
if (res > maxn) break;
is_prime[res] = false;
if (i % prime[j]) mu[res] = -mu[i];
else { mu[res] = 0; break ; }
}
}
For (i, 1, maxn) {
mux[i] = mux[i - 1] + 1ll * mu[i] * i % Mod;
mux[i] = (mux[i] % Mod + Mod) % Mod;
muxx[i] = muxx[i - 1] + 1ll* mu[i] * i % Mod * i % Mod;
muxx[i] = (muxx[i] % Mod + Mod) % Mod;
mu[i] += mu[i - 1];
mu[i] = (mu[i] % Mod + Mod) % Mod;
}
}
ll fpm(ll x, ll power) { ll res = 1; x %= Mod; for (; power; power >>= 1, (x *= x) %= Mod) if (power & 1) (res *= x) %= Mod; return res; }
const ll inv2 = fpm(2, Mod - 2), inv6 = fpm(6, Mod - 2);
ll Sum(ll x) { x %= Mod; return (x + 1) * x % Mod * inv2 % Mod; }
ll sum1, sum2, sum3, sum4;
ll Nextx;
unordered_map<ll, ll> MU, MUX, MUXX;
ll mu_(ll x) {
if (x <= Limit) return mu[x];
if (MU.count(x)) return MU[x];
ll res = 1, Nextx;
For (i, 2, x) { Nextx = x / (x / i); (res += Mod - (Nextx - i + 1) * mu_(x / i) % Mod) %= Mod; i = Nextx; }
return (MU[x] = res);
}
inline ll Sum1(ll x) { x %= Mod; return x * (x + 1) % Mod * inv2 % Mod; }
ll mux_(ll x) {
if (x <= Limit) return mux[x];
if (MUX.count(x)) return MUX[x];
ll res = 1, Nextx;
For (i, 2, x) { Nextx = x / (x / i); (res += Mod - (Sum1(Nextx) - Sum1(i - 1) + Mod) * mux_(x / i) % Mod) %= Mod; i = Nextx; }
return (MUX[x] = res);
}
inline ll Sum2(ll x) { x %= Mod ; return x * (x + 1) % Mod * (2 * x + 1) % Mod * inv6 % Mod; }
ll muxx_(ll x) {
if (x <= Limit) return muxx[x];
if (MUXX.count(x)) return MUXX[x];
ll res = 1, Nextx;
For (i, 2, x) { Nextx = x / (x / i); (res += Mod - (Sum2(Nextx) - Sum2(i - 1) + Mod) * muxx_(x / i) % Mod) %= Mod; i = Nextx; }
return (MUXX[x] = res);
}
int main () {
File();
n = read(); m = read();
if (n > m) swap(n, m);
Init(Limit);
For (x, 1, n) {
Nextx = min(n / (n / x), m / (m / x));
(sum1 += (mu_(Nextx) - mu_(x - 1)) * (n / x) % Mod * (m / x) % Mod * n % Mod * m % Mod) %= Mod;
(sum2 += (mux_(Nextx) - mux_(x - 1)) * Sum(n / x) % Mod * (m / x) % Mod) %= Mod;
(sum3 += (mux_(Nextx) - mux_(x - 1)) * Sum(m / x) % Mod * (n / x) % Mod) %= Mod;
(sum4 += (muxx_(Nextx) - muxx_(x - 1)) * Sum(n / x) % Mod * Sum(m / x) % Mod) %= Mod;
x = Nextx;
}
ll ans = sum1 - 1ll * m * sum2 % Mod - 1ll * n * sum3 % Mod + sum4;
ans = (ans % Mod + Mod) % Mod;
ans = ans * 4ll % Mod;
printf ("%lld\n", ans);
return 0;
}