自然想到枚举\(gcd(a, b)\),不妨设其为\(d\),并且\(a = di, b = dj(a > b)\)
那么\(\frac{ab}{a + b} = \frac{dij}{i + j}\)
由于此时有\((i,j) = 1\),因此\((i, i + j) = (j, i + j) = 1\)
那么,当且仅当\(i + j | d\)时,\((i, j)\)数对对答案有贡献
对答案有多少的贡献呢?\(\frac{n}{i(i + j)}\) 没有想到这一步
理由是\(d = k(i + j)\),那么只需满足\(ki(i + j) \leq n\)
当\(i > \sqrt n\)时,\((i,j)\)对答案绝对没有贡献
所以答案为\(\sum \limits_{d = 1}^{\sqrt n} \sum \limits_{i = 1}^{\sqrt n / d} \sum \limits_{j} [(i, j) = 1]\frac{n}{i(i + j)}\)
莫比乌斯反演,得到
\(\sum \limits_{d = 1}^{\sqrt n} \mu(d) \sum \limits_{i = 1}^{\sqrt n / d} \sum \limits_{j} \frac{n}{d^2i(i + j)}\)
对内层数论分块统计答案即可一开始把不分块的复杂度算错了,以为能过
分析一下复杂度上界
首先考虑对于确定的\(d\),枚举\(i, j\)的复杂度
\(\sum \limits_{i = 1}^{\sqrt n / d} \sqrt \frac{n}{d^2 i} = \frac{\sqrt n}{d} * \sum \limits_{i = 1}^{\sqrt n / d} \frac{1}{\sqrt i}\)
用归纳法可以证明,右边那个东西\(\leq 2 \sqrt {\sqrt n / d}\)
所以对于一个\(d\)而言,需要\(\frac{n^{\frac{3}{4}}}{d^{\frac{3}{2}}}\)的复杂度
由于\(\frac{1}{1} + \frac{1}{2^{1.5}} + ... + \frac{1}{n^{1.5}} \leq 3\)
所以复杂度就是\(O(n^{\frac{3}{4}})\)
然后绝对跑不到这个上界....
#include <cmath>
#include <ctime>
#include <cstdio>
#include <cstring>
#include <iostream>
using namespace std;
#define ri register int
#define ll long long
#define rep(io, st, ed) for(ri io = st; io <= ed; io ++)
#define drep(io, ed, st) for(ri io = ed; io >= st; io --)
const int sid = 1e5 + 5;
ll ans;
int n, sq, tot;
int mu[sid], nop[sid], pr[sid];
inline void Sieve(int m) {
mu[1] = 1;
rep(i, 2, m) {
if(!nop[i]) {
pr[++ tot] = i;
mu[i] = -1;
}
rep(j, 1, tot) {
int p = i * pr[j];
if(p > m) break; nop[p] = 1;
if(i % pr[j] == 0) break;
mu[p] = -mu[i];
}
}
}
int main() {
cin >> n;
sq = sqrt(n) + 1;
Sieve(sq);
rep(d, 1, sq) {
if(!mu[d]) continue;
int p = d * d;
rep(i, 1, sq / d) {
int fs = n / d / d / i;
for(ri ii = i + 1, jj; ii <= (i << 1) - 1 && ii <= fs; ii = jj + 1) {
jj = min(fs / (fs / ii), (i << 1) - 1);
ans += 1ll * mu[d] * (jj - ii + 1) * (fs / ii);
}
}
}
printf("%lld\n", ans);
return 0;
}