* when ticks is at its maximum value.
*
* So we have
+ * max_ticks = MAX_CLOCK_SEC * 1000000000 * cycles_per_nsec
* max_ticks * clock_mult <= ULLONG_MAX
* max_ticks * MULTIPLIER / cycles_per_nsec <= ULLONG_MAX
- * MULTIPLIER <= ULLONG_MAX / max_ticks * cycles_per_nsec
+ * MULTIPLIER <= ULLONG_MAX * cycles_per_nsec / max_ticks
*
* Then choose the largest clock_shift that satisfies
- * 2^clock_shift <= ULLONG_MAX / max_ticks * cycles_per_nsec
+ * 2^clock_shift <= ULLONG_MAX * cycles_per_nsec / max_ticks
*
* Finally calculate the appropriate clock_mult associated with clock_shift
* clock_mult = 2^clock_shift / cycles_per_nsec
* 4) In the code below we have cycles_per_usec and use
* cycles_per_nsec = cycles_per_usec / 1000
*
+ *
+ * The code below implements 4 clock tick to nsec conversion strategies
+ *
+ * i) 64-bit arithmetic for the (ticks * clock_mult) product with the
+ * conversion valid for at most MAX_CLOCK_SEC
+ *
+ * ii) NOT IMPLEMENTED Use 64-bit integers to emulate 128-bit multiplication
+ * for the (ticks * clock_mult) product
+ *
+ * iii) 64-bit arithmetic with clock ticks to nsec conversion occurring in
+ * two stages. The first stage counts the number of discrete, large chunks
+ * of time that have elapsed. To this is added the time represented by
+ * the remaining clock ticks. The advantage of this strategy is better
+ * accuracy because the (ticks * clock_mult) product used for final
+ * fractional chunk
+ *
+ * iv) 64-bit arithmetic with the clock ticks to nsec conversion occuring in
+ * two stages. This is carried out using locks to update the number of
+ * large time chunks (MAX_CLOCK_SEC_2STAGE) that have elapsed.
+ *
+ * v) 128-bit arithmetic used for the clock ticks to nsec conversion.
+ *
*/
#include <stdio.h>
#include <limits.h>
#include <assert.h>
#include <stdlib.h>
+#include "lib/seqlock.h"
#define DEBUG 0
#define MAX_CLOCK_SEC 365*24*60*60ULL
-#define MAX_CLOCK_SEC64 60*60ULL
+#define MAX_CLOCK_SEC_2STAGE 60*60ULL
#define dprintf(...) if (DEBUG) { printf(__VA_ARGS__); }
enum {
- __CLOCK_64_BIT = 1 << 0,
- __CLOCK_128_BIT = 1 << 1,
+ __CLOCK64_BIT = 1 << 0,
+ __CLOCK128_BIT = 1 << 1,
__CLOCK_MULT_SHIFT = 1 << 2,
__CLOCK_EMULATE_128 = 1 << 3,
- __CLOCK_REDUCE = 1 << 4,
-
- CLOCK_64_MULT_SHIFT = __CLOCK_64_BIT | __CLOCK_MULT_SHIFT,
- CLOCK_64_EMULATE_128 = __CLOCK_64_BIT | __CLOCK_EMULATE_128,
- CLOCK_64_2STAGE = __CLOCK_64_BIT | __CLOCK_REDUCE,
- CLOCK_128_MULT_SHIFT = __CLOCK_128_BIT | __CLOCK_MULT_SHIFT,
+ __CLOCK_2STAGE = 1 << 4,
+ __CLOCK_LOCK = 1 << 5,
+
+ CLOCK64_MULT_SHIFT = __CLOCK64_BIT | __CLOCK_MULT_SHIFT,
+ CLOCK64_EMULATE_128 = __CLOCK64_BIT | __CLOCK_EMULATE_128,
+ CLOCK64_2STAGE = __CLOCK64_BIT | __CLOCK_2STAGE,
+ CLOCK64_LOCK = __CLOCK64_BIT | __CLOCK_LOCK,
+ CLOCK128_MULT_SHIFT = __CLOCK128_BIT | __CLOCK_MULT_SHIFT,
};
-unsigned int clock_shift;
-unsigned int max_cycles_shift;
-unsigned long long max_cycles_mask;
-unsigned long long *nsecs;
-unsigned long long clock_mult;
-unsigned long long nsecs_for_max_cycles;
-unsigned long long clock_mult64_128[2];
-__uint128_t clock_mult128;
+static struct seqlock clock_seqlock;
+static unsigned long long cycles_start;
+static unsigned long long elapsed_nsec;
+
+static unsigned int max_cycles_shift;
+static unsigned long long max_cycles_mask;
+static unsigned long long nsecs_for_max_cycles;
+
+static unsigned int clock_shift;
+static unsigned long long clock_mult;
+static unsigned long long *nsecs;
+static unsigned long long clock_mult64_128[2];
+static __uint128_t clock_mult128;
/*
* Functions for carrying out 128-bit
*
* a[0] has the less significant bits
* a[1] has the more significant bits
+ *
+ * NOT FULLY IMPLEMENTED
*/
-void do_mult(unsigned long long a[2], unsigned long long b, unsigned long long product[2])
+static void do_mult(unsigned long long a[2], unsigned long long b,
+ unsigned long long product[2])
{
product[0] = product[1] = 0;
return;
}
-void do_div(unsigned long long a[2], unsigned long long b, unsigned long long c[2])
+static void do_div(unsigned long long a[2], unsigned long long b,
+ unsigned long long c[2])
{
return;
}
-void do_shift64(unsigned long long a[2], unsigned int count)
+static void do_shift64(unsigned long long a[2], unsigned int count)
{
a[0] = a[1] >> (count-64);
a[1] = 0;
}
-void do_shift(unsigned long long a[2], unsigned int count)
+static void do_shift(unsigned long long a[2], unsigned int count)
{
if (count > 64)
do_shift64(a, count);
- else
+ else {
while (count--) {
a[0] >>= 1;
a[0] |= a[1] << 63;
a[1] >>= 1;
}
+ }
}
-unsigned long long get_nsec(int mode, unsigned long long t)
+static void update_clock(unsigned long long t)
+{
+ write_seqlock_begin(&clock_seqlock);
+ elapsed_nsec = (t >> max_cycles_shift) * nsecs_for_max_cycles;
+ cycles_start = t & ~max_cycles_mask;
+ write_seqlock_end(&clock_seqlock);
+}
+
+static unsigned long long _get_nsec(int mode, unsigned long long t)
{
switch(mode) {
- case CLOCK_64_MULT_SHIFT: {
- return (t * clock_mult) >> clock_shift;
- }
- case CLOCK_64_EMULATE_128: {
- unsigned long long product[2];
- do_mult(clock_mult64_128, t, product);
- do_shift(product, clock_shift);
- return product[0];
+ case CLOCK64_MULT_SHIFT:
+ return (t * clock_mult) >> clock_shift;
+ case CLOCK64_EMULATE_128: {
+ unsigned long long product[2] = { };
+
+ do_mult(clock_mult64_128, t, product);
+ do_shift(product, clock_shift);
+ return product[0];
}
- case CLOCK_64_2STAGE: {
- unsigned long long multiples, nsec;
- multiples = t >> max_cycles_shift;
- dprintf("multiples=%llu\n", multiples);
- nsec = multiples * nsecs_for_max_cycles;
- nsec += ((t & max_cycles_mask) * clock_mult) >> clock_shift;
- return nsec;
+ case CLOCK64_2STAGE: {
+ unsigned long long multiples, nsec;
+
+ multiples = t >> max_cycles_shift;
+ dprintf("multiples=%llu\n", multiples);
+ nsec = multiples * nsecs_for_max_cycles;
+ nsec += ((t & max_cycles_mask) * clock_mult) >> clock_shift;
+ return nsec;
}
- case CLOCK_128_MULT_SHIFT: {
- return (unsigned long long)((t * clock_mult128) >> clock_shift);
+ case CLOCK64_LOCK: {
+ unsigned int seq;
+ unsigned long long nsec;
+
+ do {
+ seq = read_seqlock_begin(&clock_seqlock);
+ nsec = elapsed_nsec;
+ nsec += ((t - cycles_start) * clock_mult) >> clock_shift;
+ } while (read_seqlock_retry(&clock_seqlock, seq));
+ return nsec;
}
- default: {
+ case CLOCK128_MULT_SHIFT:
+ return (unsigned long long)((t * clock_mult128) >> clock_shift);
+ default:
assert(0);
- }
}
}
-void calc_mult_shift(int mode, void *mult, unsigned int *shift, unsigned long long max_sec, unsigned long long cycles_per_usec)
+static unsigned long long get_nsec(int mode, unsigned long long t)
+{
+ if (mode == CLOCK64_LOCK) {
+ update_clock(t);
+ }
+
+ return _get_nsec(mode, t);
+}
+
+static void calc_mult_shift(int mode, void *mult, unsigned int *shift,
+ unsigned long long max_sec,
+ unsigned long long cycles_per_usec)
{
unsigned long long max_ticks;
max_ticks = max_sec * cycles_per_usec * 1000000ULL;
switch (mode) {
- case CLOCK_64_MULT_SHIFT: {
- unsigned long long max_mult, tmp;
- unsigned int sft = 0;
-
- /*
- * Calculate the largest multiplier that will not
- * produce a 64-bit overflow in the multiplication
- * step of the clock ticks to nsec conversion
- */
- max_mult = ULLONG_MAX / max_ticks;
- dprintf("max_ticks=%llu, __builtin_clzll=%d, max_mult=%llu\n", max_ticks, __builtin_clzll(max_ticks), max_mult);
-
- /*
- * Find the largest shift count that will produce
- * a multiplier less than max_mult
- */
- tmp = max_mult * cycles_per_usec / 1000;
- while (tmp > 1) {
- tmp >>= 1;
- sft++;
- dprintf("tmp=%llu, sft=%u\n", tmp, sft);
- }
+ case CLOCK64_MULT_SHIFT: {
+ unsigned long long max_mult, tmp;
+ unsigned int sft = 0;
+
+ /*
+ * Calculate the largest multiplier that will not
+ * produce a 64-bit overflow in the multiplication
+ * step of the clock ticks to nsec conversion
+ */
+ max_mult = ULLONG_MAX / max_ticks;
+ dprintf("max_ticks=%llu, __builtin_clzll=%d, max_mult=%llu\n", max_ticks, __builtin_clzll(max_ticks), max_mult);
+
+ /*
+ * Find the largest shift count that will produce
+ * a multiplier less than max_mult
+ */
+ tmp = max_mult * cycles_per_usec / 1000;
+ while (tmp > 1) {
+ tmp >>= 1;
+ sft++;
+ dprintf("tmp=%llu, sft=%u\n", tmp, sft);
+ }
- *shift = sft;
- *((unsigned long long *)mult) = (unsigned long long) ((1ULL << sft) * 1000 / cycles_per_usec);
- break;
+ *shift = sft;
+ *((unsigned long long *)mult) = (unsigned long long) ((1ULL << sft) * 1000 / cycles_per_usec);
+ break;
+ }
+ case CLOCK64_EMULATE_128: {
+ unsigned long long max_mult[2], tmp[2] = { };
+ unsigned int sft = 0;
+
+ /*
+ * Calculate the largest multiplier that will not
+ * produce a 128-bit overflow in the multiplication
+ * step of the clock ticks to nsec conversion,
+ * but use only 64-bit integers in the process
+ */
+ max_mult[0] = max_mult[1] = ULLONG_MAX;
+ do_div(max_mult, max_ticks, max_mult);
+ dprintf("max_ticks=%llu, __builtin_clzll=%d, max_mult=0x%016llx%016llx\n",
+ max_ticks, __builtin_clzll(max_ticks), max_mult[1], max_mult[0]);
+
+ /*
+ * Find the largest shift count that will produce
+ * a multiplier less than max_mult
+ */
+ do_div(max_mult, cycles_per_usec, tmp);
+ do_div(tmp, 1000ULL, tmp);
+ while (tmp[0] > 1 || tmp[1] > 1) {
+ do_shift(tmp, 1);
+ sft++;
+ dprintf("tmp=0x%016llx%016llx, sft=%u\n", tmp[1], tmp[0], sft);
}
- case CLOCK_64_EMULATE_128: {
- unsigned long long max_mult[2], tmp[2];
- unsigned int sft = 0;
-
- /*
- * Calculate the largest multiplier that will not
- * produce a 128-bit overflow in the multiplication
- * step of the clock ticks to nsec conversion,
- * but use only 64-bit integers in the process
- */
- max_mult[0] = max_mult[1] = ULLONG_MAX;
- do_div(max_mult, max_ticks, max_mult);
- dprintf("max_ticks=%llu, __builtin_clzll=%d, max_mult=0x%016llx%016llx\n",
- max_ticks, __builtin_clzll(max_ticks), max_mult[1], max_mult[0]);
-
- /*
- * Find the largest shift count that will produce
- * a multiplier less than max_mult
- */
- do_div(max_mult, cycles_per_usec, tmp);
- do_div(tmp, 1000ULL, tmp);
- while (tmp[0] > 1 || tmp[1] > 1) {
- do_shift(tmp, 1);
- sft++;
- dprintf("tmp=0x%016llx%016llx, sft=%u\n", tmp[1], tmp[0], sft);
- }
- *shift = sft;
-// *((unsigned long long *)mult) = (__uint128_t) (((__uint128_t)1 << sft) * 1000 / cycles_per_usec);
- break;
+ *shift = sft;
+// *((unsigned long long *)mult) = (__uint128_t) (((__uint128_t)1 << sft) * 1000 / cycles_per_usec);
+ break;
}
- case CLOCK_64_2STAGE: {
- unsigned long long tmp;
+ case CLOCK64_2STAGE: {
+ unsigned long long tmp;
/*
* This clock tick to nsec conversion requires two stages.
*
- * Stage 1: Determine how many ~MAX_CLOCK_SEC64 periods worth of clock ticks
+ * Stage 1: Determine how many ~MAX_CLOCK_SEC_2STAGE periods worth of clock ticks
* have elapsed and set nsecs to the appropriate value for those
- * ~MAX_CLOCK_SEC64 periods.
- * Stage 2: Subtract the ticks for the elapsed ~MAX_CLOCK_SEC64 periods from
+ * ~MAX_CLOCK_SEC_2STAGE periods.
+ * Stage 2: Subtract the ticks for the elapsed ~MAX_CLOCK_SEC_2STAGE periods from
* Stage 1. Convert remaining clock ticks to nsecs and add to previously
* set nsec value.
*
* To optimize the arithmetic operations, use the greatest power of 2 ticks
- * less than the number of ticks in MAX_CLOCK_SEC64 seconds.
+ * less than the number of ticks in MAX_CLOCK_SEC_2STAGE seconds.
*
*/
- // Use a period shorter than MAX_CLOCK_SEC here for better accuracy
- calc_mult_shift(CLOCK_64_MULT_SHIFT, mult, shift, MAX_CLOCK_SEC64, cycles_per_usec);
-
- // Find the greatest power of 2 clock ticks that is less than the ticks in MAX_CLOCK_SEC64
- max_cycles_shift = max_cycles_mask = 0;
- tmp = MAX_CLOCK_SEC64 * 1000000ULL * cycles_per_usec;
+ // Use a period shorter than MAX_CLOCK_SEC here for better accuracy
+ calc_mult_shift(CLOCK64_MULT_SHIFT, mult, shift, MAX_CLOCK_SEC_2STAGE, cycles_per_usec);
+
+ // Find the greatest power of 2 clock ticks that is less than the ticks in MAX_CLOCK_SEC_2STAGE
+ max_cycles_shift = max_cycles_mask = 0;
+ tmp = MAX_CLOCK_SEC_2STAGE * 1000000ULL * cycles_per_usec;
+ dprintf("tmp=%llu, max_cycles_shift=%u\n", tmp, max_cycles_shift);
+ while (tmp > 1) {
+ tmp >>= 1;
+ max_cycles_shift++;
dprintf("tmp=%llu, max_cycles_shift=%u\n", tmp, max_cycles_shift);
- while (tmp > 1) {
- tmp >>= 1;
- max_cycles_shift++;
- dprintf("tmp=%llu, max_cycles_shift=%u\n", tmp, max_cycles_shift);
- }
- // if use use (1ULL << max_cycles_shift) * 1000 / cycles_per_usec here we will
- // have a discontinuity every (1ULL << max_cycles_shift) cycles
- nsecs_for_max_cycles = (1ULL << max_cycles_shift) * *((unsigned long long *)mult) >> *shift;
+ }
+ // if use use (1ULL << max_cycles_shift) * 1000 / cycles_per_usec here we will
+ // have a discontinuity every (1ULL << max_cycles_shift) cycles
+ nsecs_for_max_cycles = (1ULL << max_cycles_shift) * *((unsigned long long *)mult) >> *shift;
- // Use a bitmask to calculate ticks % (1ULL << max_cycles_shift)
- for (tmp = 0; tmp < max_cycles_shift; tmp++)
- max_cycles_mask |= 1ULL << tmp;
+ // Use a bitmask to calculate ticks % (1ULL << max_cycles_shift)
+ for (tmp = 0; tmp < max_cycles_shift; tmp++)
+ max_cycles_mask |= 1ULL << tmp;
- dprintf("max_cycles_shift=%u, 2^max_cycles_shift=%llu, nsecs_for_max_cycles=%llu, max_cycles_mask=%016llx\n",
+ dprintf("max_cycles_shift=%u, 2^max_cycles_shift=%llu, nsecs_for_max_cycles=%llu, max_cycles_mask=%016llx\n",
max_cycles_shift, (1ULL << max_cycles_shift),
nsecs_for_max_cycles, max_cycles_mask);
- break;
+ break;
}
- case CLOCK_128_MULT_SHIFT: {
- __uint128_t max_mult, tmp;
- unsigned int sft = 0;
-
- /*
- * Calculate the largest multiplier that will not
- * produce a 128-bit overflow in the multiplication
- * step of the clock ticks to nsec conversion
- */
- max_mult = ((__uint128_t) ULLONG_MAX) << 64 | ULLONG_MAX;
- max_mult /= max_ticks;
- dprintf("max_ticks=%llu, __builtin_clzll=%d, max_mult=0x%016llx%016llx\n",
+ case CLOCK64_LOCK: {
+/*
+ * This clock tick to nsec conversion also requires two stages.
+ *
+ * Stage 1: Add to nsec the current running total of elapsed long periods
+ * Stage 2: Subtract from clock ticks the tick count corresponding to the
+ * most recently elapsed long period. Convert the remaining ticks to
+ * nsec and add to the previous nsec value.
+ *
+ * In practice the elapsed nsec from Stage 1 and the tick count subtracted
+ * in Stage 2 will be maintained in a separate thread.
+ *
+ */
+ calc_mult_shift(CLOCK64_2STAGE, mult, shift, MAX_CLOCK_SEC, cycles_per_usec);
+ cycles_start = 0;
+ break;
+ }
+ case CLOCK128_MULT_SHIFT: {
+ __uint128_t max_mult, tmp;
+ unsigned int sft = 0;
+
+ /*
+ * Calculate the largest multiplier that will not
+ * produce a 128-bit overflow in the multiplication
+ * step of the clock ticks to nsec conversion
+ */
+ max_mult = ((__uint128_t) ULLONG_MAX) << 64 | ULLONG_MAX;
+ max_mult /= max_ticks;
+ dprintf("max_ticks=%llu, __builtin_clzll=%d, max_mult=0x%016llx%016llx\n",
max_ticks, __builtin_clzll(max_ticks),
(unsigned long long) (max_mult >> 64),
(unsigned long long) max_mult);
- /*
- * Find the largest shift count that will produce
- * a multiplier less than max_mult
- */
- tmp = max_mult * cycles_per_usec / 1000;
- while (tmp > 1) {
- tmp >>= 1;
- sft++;
- dprintf("tmp=0x%016llx%016llx, sft=%u\n",
+ /*
+ * Find the largest shift count that will produce
+ * a multiplier less than max_mult
+ */
+ tmp = max_mult * cycles_per_usec / 1000;
+ while (tmp > 1) {
+ tmp >>= 1;
+ sft++;
+ dprintf("tmp=0x%016llx%016llx, sft=%u\n",
(unsigned long long) (tmp >> 64),
(unsigned long long) tmp, sft);
- }
+ }
- *shift = sft;
- *((__uint128_t *)mult) = (__uint128_t) (((__uint128_t)1 << sft) * 1000 / cycles_per_usec);
- break;
- }
- }
+ *shift = sft;
+ *((__uint128_t *)mult) = (__uint128_t) (((__uint128_t)1 << sft) * 1000 / cycles_per_usec);
+ break;
+ }
+ }
}
-int discontinuity(int mode, int delta_ticks, int delta_nsec, unsigned long long start, unsigned long len)
+static int discontinuity(int mode, int delta_ticks, int delta_nsec,
+ unsigned long long start, unsigned long len)
{
int i;
unsigned long mismatches = 0, bad_mismatches = 0;
#define LEN 1000000000ULL
#define NSEC_ONE_SEC 1000000000ULL
#define TESTLEN 9
-long long test_clock(int mode, int cycles_per_usec, int fast_test, int quiet, int delta_ticks, int delta_nsec)
+
+static long long test_clock(int mode, int cycles_per_usec, int fast_test,
+ int quiet, int delta_ticks, int delta_nsec)
{
int i;
long long delta;
max_ticks = MAX_CLOCK_SEC * (unsigned long long) cycles_per_usec * 1000000ULL;
switch(mode) {
- case CLOCK_64_MULT_SHIFT: {
- mult = &clock_mult;
- break;
- }
- case CLOCK_64_EMULATE_128: {
- mult = clock_mult64_128;
- break;
- }
- case CLOCK_64_2STAGE: {
- mult = &clock_mult;
- break;
- }
- case CLOCK_128_MULT_SHIFT: {
- mult = &clock_mult128;
- break;
- }
+ case CLOCK64_MULT_SHIFT:
+ mult = &clock_mult;
+ break;
+ case CLOCK64_EMULATE_128:
+ mult = clock_mult64_128;
+ break;
+ case CLOCK64_2STAGE:
+ mult = &clock_mult;
+ break;
+ case CLOCK64_LOCK:
+ mult = &clock_mult;
+ break;
+ case CLOCK128_MULT_SHIFT:
+ mult = &clock_mult128;
+ break;
+ default:
+ assert(0);
}
calc_mult_shift(mode, mult, &clock_shift, MAX_CLOCK_SEC, cycles_per_usec);
nsecs = get_nsec(mode, max_ticks);
delta = nsecs/1000000 - MAX_CLOCK_SEC*1000;
- if (mode == CLOCK_64_2STAGE) {
+ if (mode == CLOCK64_2STAGE) {
test_ns[0] = nsecs_for_max_cycles - 1;
test_ns[1] = nsecs_for_max_cycles;
test_ticks[0] = (1ULL << max_cycles_shift) - 1;
printf("cycles_per_usec=%d, delta_ticks=%d, delta_nsec=%d, max_ticks=%llu, shift=%u, 2^shift=%llu\n",
cycles_per_usec, delta_ticks, delta_nsec, max_ticks, clock_shift, (1ULL << clock_shift));
switch(mode) {
- case CLOCK_64_2STAGE:
- case CLOCK_64_MULT_SHIFT: {
+ case CLOCK64_LOCK:
+ case CLOCK64_2STAGE:
+ case CLOCK64_MULT_SHIFT: {
printf("clock_mult=%llu, clock_mult / 2^clock_shift=%f\n",
clock_mult, (double) clock_mult / (1ULL << clock_shift));
break;
}
- case CLOCK_64_EMULATE_128: {
+ case CLOCK64_EMULATE_128: {
printf("clock_mult=0x%016llx%016llx\n",
clock_mult64_128[1], clock_mult64_128[0]);
break;
}
- case CLOCK_128_MULT_SHIFT: {
+ case CLOCK128_MULT_SHIFT: {
printf("clock_mult=0x%016llx%016llx\n",
(unsigned long long) (clock_mult128 >> 64),
(unsigned long long) clock_mult128);
int main(int argc, char *argv[])
{
- int i, days;
- long long error;
- long long errors[10001];
- double mean;
-
nsecs = malloc(LEN * sizeof(unsigned long long));
- assert(nsecs != NULL);
- days = MAX_CLOCK_SEC / 60 / 60 / 24;
-
- test_clock(CLOCK_64_2STAGE, 3333, 1, 0, 0, 0);
-// test_clock(CLOCK_64_MULT_SHIFT, 3333, 1, 0, 0, 0);
-// test_clock(CLOCK_128_MULT_SHIFT, 3333, 1, 0, 0, 0);
-// Test 3 different clock types from 1000 to 10000 MHz
-// and calculate average error
-/*
- for (i = 1000, mean = 0.0; i <= 10000; i++) {
- error = test_clock(CLOCK_64_MULT_SHIFT, i, 1, 1, 0, 0);
- errors[i] = error > 0 ? error : -1LL * error;
- mean += (double) errors[i] / 9000;
- }
- printf(" 64-bit average error per %d days: %fms\n", days, mean);
-
- for (i = 1000, mean = 0.0; i <= 10000; i++) {
- error = test_clock(CLOCK_64_2STAGE, i, 1, 1, 0, 0);
- errors[i] = error > 0 ? error : -1LL * error;
- mean += (double) errors[i] / 9000;
- }
- printf(" 64-bit two-stage average error per %d days: %fms\n", days, mean);
-
- for (i = 1000, mean = 0.0; i <= 10000; i++) {
- error = test_clock(CLOCK_128_MULT_SHIFT, i, 1, 1, 0, 0);
- errors[i] = error > 0 ? error : -1LL * error;
- mean += (double) errors[i] / 9000;
- }
- printf(" 128-bit average error per %d days: %fms\n", days, mean);
-*/
- test_clock(CLOCK_64_2STAGE, 1000, 1, 0, 1, 1);
- test_clock(CLOCK_64_2STAGE, 1100, 1, 0, 11, 10);
- test_clock(CLOCK_64_2STAGE, 3000, 1, 0, 3, 1);
- test_clock(CLOCK_64_2STAGE, 3333, 1, 0, 3333, 1000);
- test_clock(CLOCK_64_2STAGE, 3392, 1, 0, 424, 125);
- test_clock(CLOCK_64_2STAGE, 4500, 1, 0, 9, 2);
- test_clock(CLOCK_64_2STAGE, 5000, 1, 0, 5, 1);
+ test_clock(CLOCK64_LOCK, 3333, 1, 0, 0, 0);
+ test_clock(CLOCK64_LOCK, 1000, 1, 0, 1, 1);
+ test_clock(CLOCK64_LOCK, 1100, 1, 0, 11, 10);
+ test_clock(CLOCK64_LOCK, 3000, 1, 0, 3, 1);
+ test_clock(CLOCK64_LOCK, 3333, 1, 0, 3333, 1000);
+ test_clock(CLOCK64_LOCK, 3392, 1, 0, 424, 125);
+ test_clock(CLOCK64_LOCK, 4500, 1, 0, 9, 2);
+ test_clock(CLOCK64_LOCK, 5000, 1, 0, 5, 1);
free(nsecs);
return 0;