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For a reference implementation of the sieve of Atkin, there is primegen by the creator of the sieve. Of course, there won't be an implementation of the sieve of Eratosthenes by its creator, but is there one implementation with benchmarks that is generally considered the "standard" implementation?

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closed as off-topic by Dukeling, phimuemue, gnat, mu 無, Liath Mar 28 at 7:55

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I'm not aware of any such reference (but there's a lot of stuff on the web and I can't claim to have read it all!). I'd start with rosettacode.org/wiki/Sieve_of_Eratosthenes for approaches in various languages. –  Jackson Jan 17 at 9:43
1  
I don't think algorithms, in general, have reference implementations. If they do, it's news to me. –  Dukeling Jan 17 at 9:46
    
    
Don't close this question, you trigger-happy! –  Boris Stitnicky Mar 28 at 7:01

1 Answer 1

Following was the standard in the 1990s (might need a new timer). My results from 1996 are included in:

http://home.iae.nl/users/mhx/nsieve.tbl

/****************** Start NSIEVE C Source Code ************************/

/****************************************************************/
/*                          NSIEVE                              */
/*                     C Program Source                         */
/*          Sieve benchmark for variable sized arrays           */
/*                 Version 1.2, 03 Apr 1992                     */
/*             Al Aburto (aburto@marlin.nosc.mil)               */
/*                      ('ala' on BIX)                          */
/*                                                              */
/*                                                              */
/* This Sieve of Eratosthenes program works with variable size  */
/* arrays. It is a straight forward extension of the original   */
/* Gilbreath version ( Gilbreath, Jim. "A High-Level Language   */
/* Benchmark." BYTE, September 1981, p. 180, and also Gilbreath,*/ 
/* Jim and Gary. "Eratosthenes Revisited: Once More Through the */
/* Sieve." BYTE January 1983, p. 283 ). Unlike the Sieve of     */
/* Gilbreath, NSIEVE uses register long variables, pointers,and */ 
/* large byte arrays via 'malloc()'.  Maximum array size is     */
/* currently set at 2.56 MBytes but this can be increased or    */
/* decreased by changing the program LIMIT constant.  NSIEVE    */
/* provides error checking to ensure correct operation.  Timer  */
/* routines are provided for several different systems. NSIEVE  */
/* results won't generally agree with the Gilbreath Sieve       */
/* results because NSIEVE specifically uses register long       */
/* variables. NSIEVE, and Sieve, are programs designed          */
/* specifically to generate and printout prime numbers (positive*/ 
/* integers which have no other integral factor other than      */
/* itself and unity, as 2,3,5,7,11, ... ). NSIEVE does not      */
/* conduct the 'typical' instructions one might expect from the */
/* mythical 'typical program'. NSIEVE results can be used to    */
/* gain a perspective into the relative performance of different*/
/* computer systems, but they can not be used in isolation to   */
/* categorize the general performance capabilities of any       */
/* computer system (no single benchmark program currently can do*/
/* this).                                                       */
/*                                                              */
/* The program uses a maximum array size of 2.56 MBytes. You can*/
/* increase or lower this value by changing the 'LIMIT' define  */
/* from 9 to a higher or lower value.  Some systems (IBM PC's   */
/* and clones) will be unable to work beyond 'LIMIT = 3' which  */
/* corresponds to an array size of only 40,000 bytes. Be careful*/
/* when specifying LIMIT > 3 for these systems as the system may*/ 
/* crash or hang-up. Normally NSIEVE will stop program execution*/  
/* when 'malloc()' fails.                                       */
/*                                                              */
/* The maximum array size is given by:                          */
/*              size = 5000 * ( 2 ** LIMIT ).                   */
/*                                                              */
/* The array 'Number_Of_Primes[LIMIT]' is intended to hold the  */
/* correct number of primes found for each array size up to     */
/* LIMIT = 20, but the array is only currently defined up to    */
/* LIMIT = 12.                                                  */
/*                                                              */
/* Program outputs to check for correct operation:              */
/*    Array Size  LIMIT    Primes Found      Last Prime         */
/*     (Bytes)                                                  */
/*         8191       0            1899           16381         */
/*        10000       1            2261           19997         */
/*        20000       2            4202           39989         */
/*        40000       3            7836           79999         */
/*        80000       4           14683          160001         */
/*       160000       5           27607          319993         */
/*       320000       6           52073          639997         */
/*       640000       7           98609         1279997         */
/*      1280000       8          187133         2559989         */
/*      2560000       9          356243         5119997         */
/*      5120000      10          679460        10239989         */
/*     10240000      11         1299068        20479999         */
/*     20480000      12         2488465        40960001         */
/*     40960000      13         -------        --------         */
/****************************************************************/

/****************************************************/
/* Example Compilation:                             */
/* (1) UNIX Systems:                                */
/*     cc -O -DUNIX nsieve.c -o nsieve              */
/*     cc -DUNIX nsieve.c -o nsieve                 */
/****************************************************/

#include <stdio.h>
#ifndef vax
#include <stdlib.h>
#endif
#include <math.h>
                     /***********************************************/
#define LIMIT 9      /* You may need to change this to '3' for PC's */
                     /* and Clones or you can experiment with higher*/
                     /* values, but '12' is currently the max.      */
                     /***********************************************/

                     /***********************************************/
                     /* You may just want to uncomment one of these */
                     /* to access the correct timer for your system.*/
                     /***********************************************/
/* #define UNIX      */
/* #define UNIX_Old  */
/* #define Amiga     */
/* #define BORLAND_C */
/* #define MSC       */

#ifdef Amiga
#include <exec/types.h>
#include <ctype.h>
#endif

#ifdef BORLAND_C
#include <ctype.h>
#include <dos.h>
#endif

#ifdef MSC
#include <ctype.h>
#endif

#ifndef TRUE
#define TRUE 1
#define FALSE 0
#endif

float nulltime,runtime,TimeArray[4];
float reftime,adjtime1,emips;
float hmips,lmips,smips[21];

long L_Prime,N_Prime;      /* Last Prime and Number of Primes Found */
long ErrorFlag;

long Number_Of_Primes[21]; /* List of Correct Number of Primes for */
                           /* each sieve array size.               */

long NLoops[21];

#ifdef xxxxxxxxxx
void main()
{

long  i,j,k,p;
float sumtime;


printf("\n   Sieve of Eratosthenes (Scaled to 10 Iterations)\n");
printf("   Version 1.2, 03 April 1992\n\n");
printf("   Array Size   Number   Last Prime    Linear");       
printf("     RunTime    MIPS\n");
printf("    (Bytes)   of Primes               Time(sec)");      
printf("    (Sec)\n");


                    /*******************************/
                    /* Number of        Array Size */
                    /* Primes Found      (Bytes)   */
Number_Of_Primes[0] =     1899;      /*       8191 */
Number_Of_Primes[1] =     2261;      /*      10000 */
Number_Of_Primes[2] =     4202;      /*      20000 */
Number_Of_Primes[3] =     7836;      /*      40000 */
Number_Of_Primes[4] =    14683;      /*      80000 */
Number_Of_Primes[5] =    27607;      /*     160000 */
Number_Of_Primes[6] =    52073;      /*     320000 */
Number_Of_Primes[7] =    98609;      /*     640000 */
Number_Of_Primes[8] =   187133;      /*    1280000 */
Number_Of_Primes[9] =   356243;      /*    2560000 */
Number_Of_Primes[10]=   679460;      /*    5120000 */
Number_Of_Primes[11]=  1299068;      /*   10240000 */
Number_Of_Primes[12]=  2488465;      /*   20480000 */
Number_Of_Primes[13]=        0;      /*   40960000 */
Number_Of_Primes[14]=        0;      /*   81920000 */
Number_Of_Primes[15]=        0;      /*  163840000 */

j = 8191;
k = 256;
p = 0;
SIEVE(j,k,p);

for( i=1 ; i<= 20 ; i++)
{
 NLoops[i] = 1;
}

p = 8;
if ( runtime > 0.125 ) p = 1;

NLoops[0] = 256 * p; 
NLoops[1] = 256 * p; 
NLoops[2] = 128 * p;
NLoops[3] =  64 * p;
NLoops[4] =  32 * p;
NLoops[5] =  16 * p;
NLoops[6] =   8 * p;
NLoops[7] =   4 * p;
NLoops[8] =   2 * p;
NLoops[9] =       p;
NLoops[10] =  p / 2;
NLoops[11] =  p / 4;

if ( p == 1 )
{
NLoops[10] = 1;
NLoops[11] = 1;
}

sumtime = 0.0;
i = 0;
j = 8191;
k = NLoops[0];
SIEVE(j,k,p);
sumtime = sumtime + runtime;
smips[i] = emips;

j = 5000;
ErrorFlag = 0;

for( i=1 ; i<= LIMIT ; i++)
{
   j = 2 * j;

   k = NLoops[i];

   SIEVE(j,k,p);
   smips[i] = emips;

   if( ErrorFlag == 0L )
   {
   if( N_Prime != Number_Of_Primes[i] )
   {
   printf("\n   Error --- Incorrect Number of Primes for Array: %ld\n",j);
   printf("   Number of  Primes  Found is: %ld\n",N_Prime);
   printf("   Correct Number of Primes is: %ld\n",Number_Of_Primes[i]);
   ErrorFlag = 1L;
   }
   }

   if( ErrorFlag > 0L ) break;

   sumtime = sumtime + runtime * ( 8191.0 / (float)j );

}

if( ErrorFlag == 2L )
{
printf("\n   Could Not Allocate Memory for Array Size: %ld\n",j);
}

sumtime = sumtime / (float)i;

j = LIMIT;
if( ErrorFlag == 1L) j = LIMIT - 1;

hmips = 0.0;
lmips = 1.0e+06;
for( i=0 ; i <= j ; i++)
{
if( smips[i] > hmips ) hmips = smips[i];
if( smips[i] < lmips ) lmips = smips[i];
}

printf("\n   Relative to 10 Iterations and the 8191 Array Size:\n");
printf("   Average RunTime = %8.3f (sec)\n",sumtime);
printf("   High  MIPS      = %8.1f\n",hmips);
printf("   Low   MIPS      = %8.1f\n\n",lmips);

}
#endif

main()
{
  SIEVE(8191,1000,0);
}

/**************************************/
/*  Sieve of Erathosthenes Program    */
/**************************************/

SIEVE(m,n,p)
long m,n,p;
{

register char *flags;
register long i,prime,k,ci;
register long count,size;

long  iter,j;

char *ptr;

#ifdef vax
char *malloc();
int   free(); 
#endif

size  = m - 1;
ptr   = malloc(m);

   ErrorFlag = 0L;
   N_Prime   = 0L;
   L_Prime   = 0L;

   if( !ptr )
     {
     ErrorFlag = 2L;
     return 0;
     }

   flags = ptr;

   dtime(TimeArray);
   dtime(TimeArray);
   nulltime = TimeArray[1];
   if ( nulltime < 0.0 ) nulltime = 0.0;

   j = 0;
                                                   /****************/
                                                   /* Instructions */
                                                   /*    *iter     */ 
                                                   /****************/
   dtime(TimeArray);
   for(iter=1 ; iter<=n ; iter++)                  
   {
   count = 0;                                        /* 1       */

   for(i=0 ; i<=size ; i++)                          /* 2       */
   {
   *(flags+i) = TRUE;                                /* 1*size  */
   }                                                 /* 3*size  */
                                                     /* 1       */
   ci = 0;                                           /* 1       */
     for(i=0 ; i<=size ; i++)                        /* 1       */
     {
       if(*(flags+i))                                /* 2*size  */
       {                                             /* 1*count */
       count++;                                      /* 1*count */
       prime = i + i + 3;                            /* 3*count */
         for(k = i + prime ; k<=size ; k+=prime)     /* 3*count */
         {
         ci = ci + 1;                                /* 1*ci    */
         *(flags+k)=FALSE;                           /* 1*ci    */
         }                                           /* 3*ci    */
                                                     /* 1*count */
       }
     }                                               /* 3*size  */
                                                     /* 1       */
   j = j + count;                                    /* 1       */
   }                                                 /* 4       */
   dtime(TimeArray);

   free(ptr);

   runtime = (TimeArray[1] - nulltime) * 10.0 / (float)n;

   if ( m == 8191 ) reftime = runtime;

   adjtime1 = reftime * ( (float)m / 8191.0 );

   emips = 9.0*(float)size+9.0*(float)count;
   emips = emips+5.0*(float)ci;
   emips = 1.0e-05*(emips/runtime);

   N_Prime = j / n;
   L_Prime = prime;

   if ( p != 0L )
   {
   printf("  %9ld   %8ld     %8ld  ",m,N_Prime,L_Prime);
   printf("%9.3f  %9.3f  %6.1f\n",adjtime1,runtime,emips);
   }

return 0;
}

/*********************************************************/
/* 'dtime()' outputs the elapsed time in seconds in p[1] */
/* from the first call to 'dtime()' to the next call.    */
/*********************************************************/

/******************************************************/
/* dtime function for the UNIX 'getrusage()' routine. */
/******************************************************/
#ifdef UNIX
#include <sys/time.h>
#include <sys/resource.h>

#ifdef hpux
#include <sys/syscall.h>
#define getrusage(a,b) syscall(SYS_getrusage,a,b)
#endif

struct rusage rusage;

dtime(p)
float p[];
{
   float q;

   q = p[2];

   getrusage(RUSAGE_SELF,&rusage);

   p[2] = (float)(rusage.ru_utime.tv_sec);
   p[2] = p[2] + (float)(rusage.ru_utime.tv_usec) / 1.0e+06;
   p[1] = p[2] - q;

   return 0;
}
#endif

/*****************************************************/
/* dtime function for the old UNIX 'times' routine.  */
/*****************************************************/
#ifdef UNIX_Old
#include <sys/times.h>
#include <sys/param.h>

#ifndef HZ
#define HZ 60
#endif

struct tms tms;

dtime(p)
float p[];
{

   float q;

   q = p[2];
   times(&tms);
   p[2] = (float)(tms.tms_utime) / (float)HZ;
   p[1] = p[2] - q;
   return 0;
}
#endif


/**********************************/
/*  dtime function for the Amiga  */
/**********************************/
#ifdef Amiga

#define HZ 50

dtime(p)
float p[];
{
   float q;

   struct tt {
      long days;
      long minutes;
      long ticks;
   } tt;

   q = p[2];

   DateStamp(&tt);

   p[2] = ((float)(tt.ticks+(tt.minutes*60L*(long)HZ)))/(float)HZ;
   p[1] = p[2] - q;
   return 0;
}
#endif


/***************************************************/
/*  dtime for IBM PC/PC-AT systems with Borland C  */
/***************************************************/
#ifdef BORLAND_C
#include <time.h>

#define HZ 100
struct time now;

dtime(p)
float p[];
{
   float q,v;

   q = p[2];

   gettime(&now);

   v = 60.0*(float)(now.ti_min);
   v = v +  (float)(now.ti_sec);
   v = v +  (float)(now.ti_hund) / (float)HZ;

   p[2] = v;
   p[1] = v - q;
   return 0;
}
#endif

/*****************************************************/
/* dtime() for IBM PC/PC-AT Systems with Microsoft C */
/*****************************************************/
#ifdef MSC
#include <time.h>

#define HZ CLK_TCK
clock_t tnow;

dtime(p)
float p[];
{
   float q;

   q = p[2];
   tnow = clock();
   p[2] = (float)tnow / (float)HZ;
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