-rw-r--r-- 10288 libcpucycles-20240114/cpucycles/wrapper.c raw
// version 20240114
// public domain
// djb
// includes some pieces adapted from supercop
// 20240114 djb: loosen 0.1 to 0.2 for FINDMULTIPLIER
// 20230115 djb: cpucycles_version()
// 20230106 djb: support "cpu MHz static" (ibm z15)
#include <time.h>
#include <sys/time.h>
#include <unistd.h>
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <inttypes.h>
#include <signal.h>
#include <setjmp.h>
#include "cpucycles.h"
#include "cpucycles_internal.h"
static int tracesetup = 0;
void cpucycles_tracesetup(void)
{
tracesetup = 1;
}
static jmp_buf crash_jmp;
static void crash(int s)
{
siglongjmp(crash_jmp,1);
}
int cpucycles_works(long long (*ticks)(void))
{
volatile int result = 0;
struct sigaction old_sigill;
struct sigaction old_sigfpe;
struct sigaction old_sigbus;
struct sigaction old_sigsegv;
struct sigaction crash_action;
memset(&crash_action,0,sizeof crash_action);
crash_action.sa_handler = crash;
sigaction(SIGILL,0,&old_sigill);
sigaction(SIGFPE,0,&old_sigfpe);
sigaction(SIGBUS,0,&old_sigbus);
sigaction(SIGSEGV,0,&old_sigsegv);
if (!sigsetjmp(crash_jmp,1)) {
sigaction(SIGILL,&crash_action,0);
sigaction(SIGFPE,&crash_action,0);
sigaction(SIGBUS,&crash_action,0);
sigaction(SIGSEGV,&crash_action,0);
ticks();
result = 1;
}
sigaction(SIGILL,&old_sigill,0);
sigaction(SIGFPE,&old_sigfpe,0);
sigaction(SIGBUS,&old_sigbus,0);
sigaction(SIGSEGV,&old_sigsegv,0);
return result;
}
static double osfreq(void)
{
FILE *f;
char *x;
double result;
int s;
f = fopen("/etc/cpucyclespersecond", "r");
if (f) {
s = fscanf(f,"%lf",&result);
fclose(f);
if (s > 0) return result;
}
f = fopen("/sys/devices/system/cpu/cpu0/cpufreq/scaling_setspeed", "r");
if (f) {
s = fscanf(f,"%lf",&result);
fclose(f);
if (s > 0) return 1000.0 * result;
}
f = fopen("/sys/devices/system/cpu/cpu0/cpufreq/scaling_max_freq", "r");
if (f) {
s = fscanf(f,"%lf",&result);
fclose(f);
if (s > 0) return 1000.0 * result;
}
f = fopen("/sys/devices/system/cpu/cpu0/clock_tick", "r");
if (f) {
s = fscanf(f,"%lf",&result);
fclose(f);
if (s > 0) return result;
}
f = fopen("/proc/cpuinfo","r");
if (f) {
for (;;) {
s = fscanf(f,"cpu MHz : %lf",&result);
if (s > 0) break;
if (s == 0) s = fscanf(f,"%*[^\n]\n");
if (s < 0) { result = 0; break; }
}
fclose(f);
if (result) return 1000000.0 * result;
}
f = fopen("/proc/cpuinfo","r");
if (f) {
for (;;) {
s = fscanf(f,"clock : %lf",&result);
if (s > 0) break;
if (s == 0) s = fscanf(f,"%*[^\n]\n");
if (s < 0) { result = 0; break; }
}
fclose(f);
if (result) return 1000000.0 * result;
}
f = fopen("/proc/cpuinfo","r");
if (f) {
for (;;) {
s = fscanf(f,"cpu MHz static : %lf",&result);
if (s > 0) break;
if (s == 0) s = fscanf(f,"%*[^\n]\n");
if (s < 0) { result = 0; break; }
}
fclose(f);
if (result) return 1000000.0 * result;
}
f = popen("sysctl hw.cpufrequency 2>/dev/null","r");
if (f) {
s = fscanf(f,"hw.cpufrequency: %lf",&result);
pclose(f);
if (s > 0) if (result > 0) return result;
}
f = popen("/usr/sbin/lsattr -E -l proc0 -a frequency 2>/dev/null","r");
if (f) {
s = fscanf(f,"frequency %lf",&result);
pclose(f);
if (s > 0) return result;
}
f = popen("/usr/sbin/psrinfo -v 2>/dev/null","r");
if (f) {
for (;;) {
s = fscanf(f," The %*s processor operates at %lf MHz",&result);
if (s > 0) break;
if (s == 0) s = fscanf(f,"%*[^\n]\n");
if (s < 0) { result = 0; break; }
}
pclose(f);
if (result) return 1000000.0 * result;
}
x = getenv("cpucyclespersecond");
if (x) {
s = sscanf(x,"%lf",&result);
if (s > 0) return result;
}
return 2399987654.0;
}
static long long persecond = 0;
static const char *implementation = "none";
long long (*cpucycles)(void) = cpucycles_init;
const char *cpucycles_implementation(void)
{
cpucycles();
return implementation;
}
long long cpucycles_persecond(void)
{
cpucycles();
return persecond;
}
const char *cpucycles_version(void)
{
return "20240114";
}
// ----- cycle counter scaled from ticks
static double cpucycles_scaled_scaling = 0;
static long long cpucycles_scaled_offset = 0;
static long long (*cpucycles_scaled_from)(void) = 0;
static long long cpucycles_scaled(void)
{
return (cpucycles_scaled_from()-cpucycles_scaled_offset)*cpucycles_scaled_scaling;
}
// ----- cycle counter extended from 32-bit ticks
static long long (*cpucycles_extend32_from)(void) = 0;
static uint32_t cpucycles_extend32_prev_ticks;
static long long cpucycles_extend32_prev_us;
static long long cpucycles_extend32_prev_cycles;
static void cpucycles_extend32_setup(void)
{
long long (*ticks)(void) = cpucycles_extend32_from;
cpucycles_extend32_prev_ticks = ticks();
cpucycles_extend32_prev_us = cpucycles_microseconds();
cpucycles_extend32_prev_cycles = 0;
}
static long long cpucycles_extend32(void)
{
long long (*ticks)(void) = cpucycles_extend32_from;
uint32_t new_ticks = ticks();
unsigned long long delta_ticks = new_ticks-cpucycles_extend32_prev_ticks;
long long new_us = cpucycles_microseconds();
long long delta_us = new_us-cpucycles_extend32_prev_us;
// assume that number of cycles cannot increase by 2^32 in 2ms
if (delta_us < 1000)
return cpucycles_extend32_prev_cycles+delta_ticks;
cpucycles_extend32_prev_ticks = new_ticks;
cpucycles_extend32_prev_us = new_us;
if (delta_us >= 2000) {
long long target = (delta_us*0.000001)*persecond;
while (delta_ticks+2147483648ULL < target)
delta_ticks += 4294967296ULL;
}
return cpucycles_extend32_prev_cycles += delta_ticks;
}
// ----- estimating cycles per tick
long long cpucycles_microseconds(void)
{
struct timeval t;
long long result;
gettimeofday(&t,(struct timezone *) 0);
result = t.tv_sec;
result *= 1000000;
result += t.tv_usec;
return result;
}
static double estimate_cyclespertick(long long (*ticks)(void))
{
long long t0,t1,us0,us1;
t0 = ticks();
us0 = cpucycles_microseconds();
do {
t1 = ticks();
us1 = cpucycles_microseconds();
} while (us1-us0 < 10000 || t1-t0 < 1000);
if (t1 <= t0) return 0;
t1 -= t0;
us1 -= us0;
return (persecond * 0.000001 * (double) us1) / (double) t1;
}
// ----- selecting an option
#include "options.inc"
#define CALLS 1000
#define ESTIMATES 3
long long cpucycles_init(void)
{
long long precision[NUMOPTIONS];
double scaling[NUMOPTIONS];
int only32[NUMOPTIONS];
long long bestprecision;
long long bestopt;
long long opt;
persecond = osfreq();
for (opt = 0;opt < NUMOPTIONS;++opt) {
long long freq = options[opt].ticks_setup();
long long tries;
precision[opt] = 0;
scaling[opt] = 0;
only32[opt] = 0;
if (freq > 0) {
scaling[opt] = persecond*1.0/freq;
} else if (freq == cpucycles_CYCLECOUNTER) {
scaling[opt] = 1.0;
} else if (freq == cpucycles_EXTEND32) {
only32[opt] = 1;
scaling[opt] = 1.0;
} else if (freq == cpucycles_MAYBECYCLECOUNTER) {
scaling[opt] = 1.0;
} else if (freq == cpucycles_FINDMULTIPLIER) {
int ok = 0;
double denom;
long long loop;
for (denom = 1;denom <= 1024;denom += denom) {
double est[ESTIMATES];
for (loop = 0;loop < ESTIMATES;++loop)
est[loop] = denom*estimate_cyclespertick(options[opt].ticks);
scaling[opt] = (double) (long long) est[0];
if (scaling[opt] < est[0]-0.5) scaling[opt] += 1;
if (scaling[opt] > est[0]+0.5) scaling[opt] -= 1;
ok = 1;
for (loop = 0;loop < ESTIMATES;++loop) {
if (est[loop]-scaling[opt] > 0.2) ok = 0;
if (scaling[opt]-est[loop] > 0.2) ok = 0;
}
if (ok) {
scaling[opt] /= denom;
break;
}
scaling[opt] = 0;
}
if (!ok) continue;
} else {
continue;
}
for (tries = 0;tries < 10;++tries) {
long long t[CALLS+1];
long long ok = 1;
long long i;
if (scaling[opt] == 1.0) {
for (i = 0;i <= CALLS;++i)
t[i] = options[opt].ticks();
} else {
double scalingopt = scaling[opt];
long long offset = options[opt].ticks();
for (i = 0;i <= CALLS;++i)
t[i] = (options[opt].ticks()-offset)*scalingopt;
}
for (i = 0;i < CALLS;++i)
if (t[i] > t[i+1])
ok = 0;
if (t[0] == t[CALLS])
ok = 0;
if (ok) {
long long smallestdiff = 0;
for (i = 0;i < CALLS;++i) {
long long diff = t[i+1]-t[i];
if (diff <= 0) continue;
if (smallestdiff == 0 || diff < smallestdiff)
smallestdiff = diff;
}
precision[opt] = smallestdiff;
// tilt selection towards more robust counters
if (freq != cpucycles_CYCLECOUNTER && freq != cpucycles_EXTEND32)
precision[opt] += 100;
if (freq > 0)
precision[opt] += 100;
break;
}
// otherwise keep trying
// since !ok can be caused by overflow
// or by core swap
}
}
if (tracesetup) {
for (opt = 0;opt < NUMOPTIONS;++opt)
printf("cpucycles tracesetup %lld %s precision %lld scaling %lf only32 %d\n"
,opt,options[opt].implementation,precision[opt],scaling[opt],only32[opt]);
}
bestopt = DEFAULTOPTION;
bestprecision = 0;
for (opt = 0;opt < NUMOPTIONS;++opt)
if (precision[opt] > 0)
if (!bestprecision || precision[opt] < bestprecision) {
bestopt = opt;
bestprecision = precision[opt];
}
implementation = options[bestopt].implementation;
if (scaling[bestopt] == 1.0) {
if (only32[bestopt]) {
cpucycles_extend32_from = options[bestopt].ticks;
cpucycles_extend32_setup();
cpucycles = cpucycles_extend32;
} else {
cpucycles = options[bestopt].ticks;
}
} else {
cpucycles_scaled_scaling = scaling[bestopt];
cpucycles_scaled_from = options[bestopt].ticks;
cpucycles_scaled_offset = cpucycles_scaled_from();
cpucycles = cpucycles_scaled;
}
return cpucycles();
}