Lucas的数论
reference
Pre
数论分块
默认向下取整时.
形如\(\sum\limits_{i=1}^n f\left( \frac{n}{i}\right)\)的求和,由于\(\frac{n}{r}\)的值只有\(\sqrt{n}\)个,可以直接数论分块上.
题解
记原式为\(S(n)\),有
\[S(n)=\sum_{i\rightarrow n}\sum_{j\rightarrow n}[\gcd{i,j}=1]\frac{n}{i}\frac{n}{j}
\]
\]
\[=\sum_k\mu (k)\sum_{i\rightarrow\frac{n}{k}}\sum_{d\rightarrow\frac{n}{k}}\frac{n}{ik}\frac{n}{dk}
\]
\]
记
\[F(n)=\sum_{i\rightarrow n}d(i)
\]
\]
则
\[S(n)=\sum_k\mu(k)F\left(\frac{n}{k}\right) ^2
\]
\]
那么
\[F(n)=\sum_{j=1}^n\lfloor \frac{n}{j}\rfloor
\]
\]
可以直接上数论分块.
那么$$S(n)$$也可以数论分块球了> <...
然后\(\mu\)函数的前缀和...就这样:
然后发现也可以数论分块+记忆化搜索搞一搞.
然后就莫名其妙地过了> <
#include <cstdio>
#include <cstring>
#include <cmath>
#include <algorithm>
#include <iostream>
#include <ext/rope>
#include <ext/pb_ds/tree_policy.hpp>
#include <ext/pb_ds/priority_queue.hpp>
#define fon(i,n) for(int i=0;i<n;++i)
#define fonx(i,f,n,s) for(int i=f;i<n;i+=s)
#define fonu(i,n) for(int i=1;i<n;i<<=1)
#define fong(i,s,n) for(int i=s;i<=n;++i)
#define debug true
#define pi 3.14159265358979323846264
#define mod 1000000007
typedef long long ll;
typedef unsigned long long ull;
struct __sieve{
int primes[1000000],primelen,spf[5000000+1],lm[5000000+1];
bool isk[5000000+1];
int lmer[5000000+1];
void operator()(){
lmer[1]=lm[1]=1;
fong(i,2,5000000){
if(!isk[i]) lm[i]=-1,primes[primelen++]=i;
fon(j,primelen){
int k=i*primes[j];
if(k>5000000) break;
isk[k]=1;
if(i%primes[j]) lm[k]=-lm[i]; else {
lm[k]=0;
break;
}
}
lmer[i]=lmer[i-1]+lm[i];
}
}
inline int operator[](int a){return lmer[a];}
} linear_sieve;
struct __hash{
#define hashmod 3001001
inline int hash(int n){
return ((n*405347)&1073741823)%hashmod;
}
int n[hashmod][3],h[hashmod],len;
inline int find(int N){
int p=hash(N);
int q=h[p];
while(p&&n[p][0]!=N) p=n[p][2];
return p?n[p][1]:-1;
}
inline void ins(int N,int p){
++len;
int q=hash(N);
n[len][0]=N,n[len][1]=p,n[len][2]=h[q],h[q]=len;
}
} hashmap;
int N,n;
int sumMiu(int a){
if(a<=5000000) return linear_sieve[a];
int res=hashmap.find(a);
if(~res) return res;
int t=1;
for (int l = 1, r = 2,n=a; r <= n; r ++){
r = std::min(n, n / (n / r));
int tmp = n / r;
t-=(r-l+mod)%mod*sumMiu(tmp)%mod;
t=(r<0)?t+mod:t;
l = r;
}
hashmap.ins(a,t);
return t;
}
int F(int n){
int ans = 0;
for (int l = 0, r = 1; r <= n; r ++){
r = std::min(n, n / (n / r));
int res = (n / r) % mod;
int tmp = (r - l + mod) % mod * res % mod;
ans += tmp;
if (ans >= mod) ans -= mod;
l = r;
}
return ans;
}
int main(){
#ifdef debug
freopen("mathP.in","r",stdin);
freopen("mathP.out","w",stdout);
#endif
scanf("%d",&n);
N=(int)pow((double)n,.5);
linear_sieve();
int ans=0;
for (int l = 0, r = 1; r <= n; r ++){
r = std::min(n, n / (n / r));
int res=F(n/r);
ans+=((ll)sumMiu(r)-sumMiu(l)+mod)%mod*res%mod*res%mod;
if(ans>=mod) ans-=mod;
l = r;
}
printf("%d\n",ans);
return 0;
}