普通算法:
void findZhishu()
{
int n,m,flag,i,j,num=0;
printf("n:");
scanf("%d",&n);
printf("从2到%d的质数如下:
",n);
clock_t bt = clock();
// printf("===now time:%lu===",bt);
for(i=2;i<=n;i++)//循环查找质数
{
flag=1;
m=(int)sqrt(i);
for(j=2;j<=m;j++)
{
if(i%j==0)//条件为真时表示不是质数,退出for循环
{
flag=0;
break;
}
}
if(flag==1)//条件为真时表示i是质数
{
num ++;
printf("%4d ",i);
if(num%10==0)//每行最多输出10个数
printf("
");
}
}
printf("
");
printf("===count:%d
",num);
printf("===used:%fS===",(float)(clock()-bt)/CLOCKS_PER_SEC);
printf("
");
}高效率算法(转载)
int Sieve()
{
int n;
clock_t bt = clock();
printf("n:");
scanf("%d",&n);
int i, j;
//素数数量统计
int count = 0;
// 分配素数标记空间,明白+1原因了吧,因为浪费了一个flag[0]
char* flag = (char*)malloc( n+1 );
// 干嘛用的,请仔细研究下文
int mpLen = 2*3*5*7*11*13;
char magicPattern[2*3*5*7*11*13]; // 奇怪的代码,why,思考无法代劳,想!
for (i=0; i<mpLen; i++)
{
magicPattern[i++] = 1;
magicPattern[i++] = 0;
magicPattern[i++] = 0;
magicPattern[i++] = 0;
magicPattern[i++] = 1;
magicPattern[i] = 0;
}
for (i=4; i<=mpLen; i+=5)
magicPattern[i] = 0;
for (i=6; i<=mpLen; i+=7)
magicPattern[i] = 0;
for (i=10; i<=mpLen; i+=11)
magicPattern[i] = 0;
for (i=12; i<=mpLen; i+=13)
magicPattern[i] = 0;
// 新的初始化方法,将2,3,5,7,11,13的倍数全干掉
// 而且采用memcpy以mpLen长的magicPattern来批量处理
int remainder = n%mpLen;
char* p = flag+1;
char* pstop = p+n-remainder;
while (p < pstop)
{
memcpy(p, magicPattern, mpLen);
p += mpLen;
}
if (remainder > 0)
{
memcpy(p, magicPattern, remainder);
}
flag[2] = 1;
flag[3] = 1;
flag[5] = 1;
flag[7] = 1;
flag[11] = 1;
flag[13] = 1;
// 从17开始filter,因为2,3,5,7,11,13的倍数早被kill了
// 到n/13止的,哈哈,少了好多吧
int stop = n/13;
for (i=17; i <= stop; i++)
{
// i是合数,请歇着吧,因为您的工作早有您的质因子代劳了
if (0 == flag[i]) continue;
// 从i的17倍开始过滤
int step = i*2;
for (j=i*17; j <= n; j+=step)
{
flag[j] = 0;
}
}
// 统计素数个数
for (i=2; i<=n; i++)
{
if (flag[i]){
count++;
printf("%d|", i);
}
}
// 因输出费时,且和算法核心相关不大,故略
// 释放内存,别忘了传说中的内存泄漏
free(flag);
printf("===count:%d",count);
printf("===used:%f",(float)(clock()-bt)/CLOCKS_PER_SEC);
return count;
}