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/*
** cleanbench.c
*/
/*******************************************
** BYTEmark (tm) **
** BYTE MAGAZINE'S NATIVE MODE BENCHMARKS **
** FOR CPU/FPU **
** ver 2.0 **
** Rick Grehan, BYTE Magazine **
********************************************
** REVISION HISTORY FOR BENCHMARKS
** 9/94 -- First beta. --RG
** 12/94 -- Bug discovered in some of the integer routines
** (IDEA, Huffman,...). Routines were not accurately counting
** the number of loops. Fixed. --RG (Thanks to Steve A.)
** 12/94 -- Added routines to calculate and display index
** values. Indexes based on DELL XPS 90 (90 MHz Pentium).
** 1/95 -- Added Mac time manager routines for more accurate
** timing on Macintosh (said to be good to 20 usecs) -- RG
** 1/95 -- Re-did all the #defines so they made more
** sense. See NMGLOBAL.H -- RG
** 3/95 -- Fixed memory leak in LU decomposition. Did not
** invalidate previous results, just made it easier to run.--RG
** 3/95 -- Added TOOLHELP.DLL timing routine to Windows timer. --RG
** 10/95 -- Added memory array & alignment; moved memory
** allocation out of LU Decomposition -- RG
**
** DISCLAIMER
** The source, executable, and documentation files that comprise
** the BYTEmark benchmarks are made available on an "as is" basis.
** This means that we at BYTE Magazine have made every reasonable
** effort to verify that the there are no errors in the source and
** executable code. We cannot, however, guarantee that the programs
** are error-free. Consequently, McGraw-HIll and BYTE Magazine make
** no claims in regard to the fitness of the source code, executable
** code, and documentation of the BYTEmark.
** Furthermore, BYTE Magazine, McGraw-Hill, and all employees
** of McGraw-Hill cannot be held responsible for any damages resulting
** from the use of this code or the results obtained from using
** this code.
*/
#include <stdio.h>
#include <stdlib.h>
#include <ctype.h>
#include <string.h>
#include <math.h>
#include "nmglobal.h"
#include "cleanbench.h"
#include "hardware.h"
/*************
**** main ****
*************/
int main(int argc, char *argv[]) {
double bmean; /* Benchmark mean */
double bstdev; /* Benchmark stdev */
double lx_memindex = 1.0; /* Linux memory index (mainly integer operations)*/
double lx_intindex = 1.0; /* Linux integer index */
double lx_fpindex = 1.0; /* Linux floating-point index */
double intindex = 1.0; /* Integer index */
double fpindex = 1.0; /* Floating-point index */
unsigned long bnumrun; /* # of runs */
int i; /* Index */
/*
** We presume all tests will be run unless told
** otherwise
*/
for (i = 0; i < NUMTESTS; i++) {
tests_to_do[i] = TRUE;
}
/*
** Initialize test data structures to default
** values.
*/
global_numsortstruct.arraysize=NUMARRAYSIZE;
global_strsortstruct.arraysize=STRINGARRAYSIZE;
global_bitopstruct.bitfieldarraysize=BITFARRAYSIZE;
global_emfloatstruct.arraysize=EMFARRAYSIZE;
global_ideastruct.arraysize=IDEAARRAYSIZE;
global_huffstruct.arraysize=HUFFARRAYSIZE;
puts("BYTEmark* Native Mode Benchmark ver. 2 (10/95)");
puts("Index-split by Andrew D. Balsa (11/97)");
puts("Linux/Unix* port by Uwe F. Mayer (12/96,11/97)");
puts("\nTEST : Iterations/sec. : Old Index : New Index");
puts(" : : Pentium 90* : AMD K6/233*");
puts("--------------------:------------------:-------------:------------");
for(i=0;i<NUMTESTS;i++)
{
if(tests_to_do[i])
{ printf("%s :",ftestnames[i]);
if (0!=bench_with_confidence(i,
&bmean,
&bstdev,
&bnumrun)){
puts("\n** WARNING: The current test result is NOT 95 % statistically certain.");
puts("** WARNING: The variation among the individual results is too large.");
printf(" :");
}
printf(" %15.5g : %9.2f : %9.2f\n",
bmean,bmean/bindex[i],bmean/lx_bindex[i]);
/*
** Gather integer or FP indexes
*/
if((i==4)||(i==8)||(i==9)){
/* FP index */
fpindex=fpindex*(bmean/bindex[i]);
/* Linux FP index */
lx_fpindex=lx_fpindex*(bmean/lx_bindex[i]);
}
else{
/* Integer index */
intindex=intindex*(bmean/bindex[i]);
if((i==0)||(i==3)||(i==6)||(i==7))
/* Linux integer index */
lx_intindex=lx_intindex*(bmean/lx_bindex[i]);
else
/* Linux memory index */
lx_memindex=lx_memindex*(bmean/lx_bindex[i]);
}
}
}
puts("==========================ORIGINAL BYTEMARK RESULTS==========================");
printf("INTEGER INDEX : %.3f\n",
pow(intindex,(double).142857));
printf("FLOATING-POINT INDEX: %.3f\n",
pow(fpindex,(double).33333));
puts("Baseline (MSDOS*) : Pentium* 90, 256 KB L2-cache, Watcom* compiler 10.0");
#ifdef __linux__
puts("==============================LINUX DATA BELOW===============================");
hardware();
#include "sysinfoc.c"
printf("MEMORY INDEX : %.3f\n",
pow(lx_memindex,(double).3333333333));
printf("INTEGER INDEX : %.3f\n",
pow(lx_intindex,(double).25));
printf("FLOATING-POINT INDEX: %.3f\n",
pow(lx_fpindex,(double).3333333333));
puts("Baseline (LINUX) : AMD K6/233*, 512 KB L2-cache, gcc 2.7.2.3, libc-5.4.38");
#endif
puts("* Trademarks are property of their respective holder.");
return 0;
}
/**************************
** bench_with_confidence **
***************************
** Given a benchmark id that indicates a function, this routine
** repeatedly calls that benchmark, seeking to collect and replace
** scores to get 5 that meet the confidence criteria.
**
** The above is mathematically questionable, as the statistical theory
** depends on independent observations, and if we exchange data points
** depending on what we already have then this certainly violates
** independence of the observations. Hence I changed this so that at
** most 30 observations are done, but none are deleted as we go
** along. We simply do more runs and hope to get a big enough sample
** size so that things stabilize. Uwe F. Mayer
**
** Return 0 if ok, -1 if failure. Returns mean
** and std. deviation of results if successful.
*/
static int bench_with_confidence(int fid, /* Function id */
double *mean, /* Mean of scores */
double *stdev, /* Standard deviation */
unsigned long *numtries) /* # of attempts */
{
double myscores[30]; /* Need at least 5 scores, use at most 30 */
double c_half_interval; /* Confidence half interval */
int i; /* Index */
/* double newscore; */ /* For improving confidence interval */
/*
** Get first 5 scores. Then begin confidence testing.
*/
for (i=0;i<5;i++)
{ (*funcpointer[fid])();
myscores[i]=getscore(fid);
}
*numtries=5; /* Show 5 attempts */
/*
** The system allows a maximum of 30 tries before it gives
** up. Since we've done 5 already, we'll allow 25 more.
*/
/*
** Enter loop to test for confidence criteria.
*/
while(1)
{
/*
** Calculate confidence. Should always return 0.
*/
if (0!=calc_confidence(myscores,
*numtries,
&c_half_interval,
mean,
stdev)) return(-1);
/*
** Is the length of the half interval 5% or less of mean?
** If so, we can go home. Otherwise, we have to continue.
*/
if(c_half_interval/ (*mean) <= (double)0.05)
break;
/* We now simply add a new test run and hope that the runs
finally stabilize, Uwe F. Mayer */
if(*numtries==30) return(-1);
(*funcpointer[fid])();
myscores[*numtries]=getscore(fid);
*numtries+=1;
}
return 0;
}
/********************
** calc_confidence **
*********************
** Given a set of numtries scores, calculate the confidence
** half-interval. We'll also return the sample mean and sample
** standard deviation.
** NOTE: This routines presumes a confidence of 95% and
** a confidence coefficient of .95
** returns 0 if there is an error, otherwise -1
*/
static int calc_confidence(double scores[], /* Array of scores */
int num_scores, /* number of scores in array */
double *c_half_interval, /* Confidence half-int */
double *smean, /* Standard mean */
double *sdev) /* Sample stand dev */
{
/* Here is a list of the student-t distribution up to 29 degrees of
freedom. The value at 0 is bogus, as there is no value for zero
degrees of freedom. */
double student_t[30]={0.0 , 12.706 , 4.303 , 3.182 , 2.776 , 2.571 ,
2.447 , 2.365 , 2.306 , 2.262 , 2.228 ,
2.201 , 2.179 , 2.160 , 2.145 , 2.131 ,
2.120 , 2.110 , 2.101 , 2.093 , 2.086 ,
2.080 , 2.074 , 2.069 , 2.064 , 2.060 ,
2.056 , 2.052 , 2.048 , 2.045 };
int i; /* Index */
if ((num_scores<2) || (num_scores>30)) {
puts("Internal error: calc_confidence called with an illegal number of scores");
return(-1);
}
/*
** First calculate mean.
*/
*smean=(double)0.0;
for(i=0;i<num_scores;i++){
*smean+=scores[i];
}
*smean/=(double)num_scores;
/* Get standard deviation */
*sdev=(double)0.0;
for(i=0;i<num_scores;i++) {
*sdev+=(scores[i]-(*smean))*(scores[i]-(*smean));
}
*sdev/=(double)(num_scores-1);
*sdev=sqrt(*sdev);
/* Now calculate the length of the confidence half-interval. For a
** confidence level of 95% our confidence coefficient gives us a
** multiplying factor of the upper .025 quartile of a t distribution
** with num_scores-1 degrees of freedom, and dividing by sqrt(number of
** observations). See any introduction to statistics.
*/
*c_half_interval=student_t[num_scores-1] * (*sdev) / sqrt((double)num_scores);
return(0);
}
/*************
** getscore **
**************
** Return the score for a particular benchmark.
*/
static double getscore(int fid) {
/*
** Fid tells us the function. This is really a matter of
** doing the proper coercion.
*/
switch(fid) {
case NUMSORT:
return(global_numsortstruct.results);
case STRINGSORT:
return(global_strsortstruct.results);
case BITFIELD:
return(global_bitopstruct.results);
case FPEMULATION:
return(global_emfloatstruct.results);
case FOURIER:
return(global_fourierstruct.results);
case ASSIGNMENT:
return(global_assignstruct.results);
case IDEA:
return(global_ideastruct.results);
case HUFFMAN:
return(global_huffstruct.results);
case NEURAL:
return(global_nnetstruct.results);
case LINEAR:
return(global_lustruct.results);
}
return 0.0;
}
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