Send a Table
Input: Standard Input
Output: Standard Output
When participating in programming contests, you sometimes face the following problem: You know how to calcutale the output for the given input values, but your algorithm is way too slow to ever pass the time limit. However hard you try, you just can't discover the proper break-off conditions that would bring down the number of iterations to within acceptable limits.
Now if the range of input values is not too big, there is a way out of this. Let your PC rattle for half an our and produce a table of answers for all possible input values, encode this table into a program, submit it to the judge, et voila: Accepted in 0.000 seconds! (Some would argue that this is cheating, but remember: In love and programming contests everything is permitted).
Faced with this problem during one programming contest, Jimmy decided to apply such a 'technique'. But however hard he tried, he wasn't able to squeeze all his pre-calculated values into a program small enough to pass the judge. The situation looked hopeless, until he discovered the following property regarding the answers: the answers where calculated from two integers, but whenever the two input values had a common factor, the answer could be easily derived from the answer for which the input values were divided by that factor. To put it in other words:
Say Jimmy had to calculate a function Answer(x, y) where x and y are both integers in the range [1, N]. When he knows Answer(x, y), he can easily derive Answer(k*x, k*y), where k is any integer from it by applying some simple calculations involving Answer(x, y) and k. For example if N=4, he only needs to know the answers for 11 out of the 16 possible input value combinations: Answer(1, 1), Answer(1, 2), Answer(2, 1), Answer(1, 3), Answer(2, 3), Answer(3, 2), Answer(3, 1), Answer(1, 4), Answer(3, 4), Answer(4, 3) and Answer(4, 1). The other 5 can be derived from them (Answer(2, 2), Answer(3, 3) and Answer(4, 4) from Answer(1, 1), Answer(2, 4) from Answer(1, 2), and Answer(4, 2) from Answer(2, 1)). Note that the function Answer is not symmetric, so Answer(3, 2) can not be derived from Answer(2, 3).
Now what we want you to do is: for any values of N from 1 upto and including 50000, give the number of function Jimmy has to pre-calculate.
For each line of input produce one line of output. This line contains an integer which indicates how many values Jimmy has to pre-calculate for a certain value of N.
2 5 0 |
3 19
|
题目分析:求1~n之间共有多少对互质的数。
如果用普通方法一个一个判断,时间复杂度是O(n^2),会超时。但是可以利用欧拉函数和筛法在O(nloglogn)时间内把50000内与每个数互质的正整数的个数求出来。当求有多少对时,只需令sum[n]*2 —1即可。
#include<stdio.h> #include<string.h> #define N 50010 int phi[N],n,sum[N]; void phi_table() { int i,j; memset(phi,0,sizeof(phi)); phi[1]=1; for(i=2;i<=N;i++) if(!phi[i]) for(j=i;j<=N;j+=i) /*筛法求欧拉函数值*/ { if(!phi[j]) phi[j]=j; phi[j]=phi[j]/i*(i-1); /*phi[j]保存不超过j且与j互质的正整数的个数*/ } sum[0]=0; for(i=1;i<=50000;i++) sum[i]=sum[i-1]+phi[i]; } int main() { phi_table(); int i; while(~scanf("%d",&n)&&n) { printf("%d\n",2*sum[n]-1); } return 0; } /*转化为有多少对时,2与1互质,但是(2,1)和(1,2)算2对,所以应该乘以2,但是(1,1)被算了两次,所以减去一次*/