/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 1999-2015. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* %CopyrightEnd%
*/
/*
* Support routines for the time
*/
/* #define ERTS_TIME_CORRECTION_PRINT */
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#define ERTS_WANT_TIMER_WHEEL_API
#include "erl_time.h"
#include "erl_driver.h"
#include "erl_nif.h"
static erts_smp_mtx_t erts_timeofday_mtx;
static erts_smp_mtx_t erts_get_time_mtx;
static SysTimes t_start; /* Used in elapsed_time_both */
static ErtsMonotonicTime prev_wall_clock_elapsed; /* Used in wall_clock_elapsed_time_both */
static ErtsMonotonicTime previous_now; /* Used in get_now */
static ErtsMonitor *time_offset_monitors = NULL;
static Uint no_time_offset_monitors = 0;
#ifdef DEBUG
static int time_sup_initialized = 0;
#endif
#define ERTS_MONOTONIC_TIME_KILO \
((ErtsMonotonicTime) 1000)
#define ERTS_MONOTONIC_TIME_MEGA \
(ERTS_MONOTONIC_TIME_KILO*ERTS_MONOTONIC_TIME_KILO)
#define ERTS_MONOTONIC_TIME_GIGA \
(ERTS_MONOTONIC_TIME_MEGA*ERTS_MONOTONIC_TIME_KILO)
#define ERTS_MONOTONIC_TIME_TERA \
(ERTS_MONOTONIC_TIME_GIGA*ERTS_MONOTONIC_TIME_KILO)
static void init_time_napi(void);
static void
schedule_send_time_offset_changed_notifications(ErtsMonotonicTime new_offset);
struct time_sup_read_only__ {
ErtsMonotonicTime (*get_time)(void);
int correction;
ErtsTimeWarpMode warp_mode;
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
ErtsMonotonicTime moffset;
int os_corrected_monotonic_time;
int os_monotonic_time_disable;
char *os_monotonic_time_func;
char *os_monotonic_time_clock_id;
int os_monotonic_time_locked;
Uint64 os_monotonic_time_resolution;
Uint64 os_monotonic_time_extended;
#endif
char *os_system_time_func;
char *os_system_time_clock_id;
int os_system_time_locked;
Uint64 os_system_time_resolution;
Uint64 os_system_time_extended;
struct {
ErtsMonotonicTime large_diff;
ErtsMonotonicTime small_diff;
} adj;
struct {
ErtsMonotonicTime error;
ErtsMonotonicTime resolution;
int intervals;
int use_avg;
} drift_adj;
};
typedef struct {
ErtsMonotonicTime drift; /* Correction for os monotonic drift */
ErtsMonotonicTime error; /* Correction for error between system times */
} ErtsMonotonicCorrection;
typedef struct {
ErtsMonotonicTime erl_mtime;
ErtsMonotonicTime os_mtime;
ErtsMonotonicCorrection correction;
} ErtsMonotonicCorrectionInstance;
#define ERTS_MAX_DRIFT_INTERVALS 50
typedef struct {
struct {
struct {
ErtsMonotonicTime sys;
ErtsMonotonicTime mon;
} diff;
struct {
ErtsMonotonicTime sys;
ErtsMonotonicTime mon;
} time;
} intervals[ERTS_MAX_DRIFT_INTERVALS];
struct {
ErtsMonotonicTime sys;
ErtsMonotonicTime mon;
} acc;
int ix;
int dirty_counter;
} ErtsMonotonicDriftData;
typedef struct {
ErtsMonotonicCorrectionInstance prev;
ErtsMonotonicCorrectionInstance curr;
} ErtsMonotonicCorrectionInstances;
typedef struct {
ErtsMonotonicCorrectionInstances insts;
ErtsMonotonicDriftData drift;
ErtsMonotonicTime last_check;
int short_check_interval;
} ErtsMonotonicCorrectionData;
struct time_sup_infrequently_changed__ {
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
struct {
erts_smp_rwmtx_t rwmtx;
ErtsTWheelTimer timer;
ErtsMonotonicCorrectionData cdata;
} parmon;
ErtsMonotonicTime minit;
#endif
ErtsSystemTime sinit;
ErtsMonotonicTime not_corrected_moffset;
erts_smp_atomic64_t offset;
ErtsMonotonicTime shadow_offset;
erts_smp_atomic32_t preliminary_offset;
};
struct time_sup_frequently_changed__ {
ErtsMonotonicTime last_not_corrected_time;
};
static struct {
union {
struct time_sup_read_only__ o;
char align__[ERTS_ALC_CACHE_LINE_ALIGN_SIZE(sizeof(struct time_sup_read_only__))];
} r;
union {
struct time_sup_infrequently_changed__ c;
char align__[ERTS_ALC_CACHE_LINE_ALIGN_SIZE(sizeof(struct time_sup_infrequently_changed__))];
} inf;
union {
struct time_sup_frequently_changed__ c;
char align__[ERTS_ALC_CACHE_LINE_ALIGN_SIZE(sizeof(struct time_sup_frequently_changed__))];
} f;
} time_sup erts_align_attribute(ERTS_CACHE_LINE_SIZE);
ErtsTimeSupData erts_time_sup__ erts_align_attribute(ERTS_CACHE_LINE_SIZE);
/*
* erts_get_approx_time() returns an *approximate* time
* in seconds. NOTE that this time may jump backwards!!!
*/
erts_approx_time_t
erts_get_approx_time(void)
{
ErtsSystemTime stime = erts_os_system_time();
return (erts_approx_time_t) ERTS_MONOTONIC_TO_SEC(stime);
}
static ERTS_INLINE void
init_time_offset(ErtsMonotonicTime offset)
{
erts_smp_atomic64_init_nob(&time_sup.inf.c.offset, (erts_aint64_t) offset);
}
static ERTS_INLINE void
set_time_offset(ErtsMonotonicTime offset)
{
erts_smp_atomic64_set_relb(&time_sup.inf.c.offset, (erts_aint64_t) offset);
}
static ERTS_INLINE ErtsMonotonicTime
get_time_offset(void)
{
return (ErtsMonotonicTime) erts_smp_atomic64_read_acqb(&time_sup.inf.c.offset);
}
static ERTS_INLINE void
update_last_mtime(ErtsSchedulerData *esdp, ErtsMonotonicTime mtime)
{
if (!esdp)
esdp = erts_get_scheduler_data();
if (esdp) {
ASSERT(mtime >= esdp->last_monotonic_time);
esdp->last_monotonic_time = mtime;
esdp->check_time_reds = 0;
}
}
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
/*
* Time correction adjustments made due to
* error between Erlang system time and OS
* system time:
* - Large adjustment ~1%
* - Small adjustment ~0.05%
*/
#define ERTS_TCORR_ERR_UNIT 2048
#define ERTS_TCORR_ERR_LARGE_ADJ 20
#define ERTS_TCORR_ERR_SMALL_ADJ 1
#define ERTS_INIT_SHORT_INTERVAL_COUNTER 10
#define ERTS_LONG_TIME_CORRECTION_CHECK ERTS_SEC_TO_MONOTONIC(60)
#define ERTS_SHORT_TIME_CORRECTION_CHECK ERTS_SEC_TO_MONOTONIC(15)
#define ERTS_TIME_DRIFT_MAX_ADJ_DIFF ERTS_USEC_TO_MONOTONIC(50)
#define ERTS_TIME_DRIFT_MIN_ADJ_DIFF ERTS_USEC_TO_MONOTONIC(5)
/*
* Maximum drift of the OS monotonic clock expected.
*
* We use 1 milli second per second. If the monotonic
* clock drifts more than this we will fail to adjust for
* drift, and error correction will kick in instead.
* If it is larger than this, one could argue that the
* primitive is to poor to be used...
*/
#define ERTS_MAX_MONOTONIC_DRIFT ERTS_MSEC_TO_MONOTONIC(1)
/*
* We assume that precision is 32 times worse than the
* resolution. This is a wild guess, but there are no
* practical way to determine actual precision.
*/
#define ERTS_ASSUMED_PRECISION_DROP 32
#define ERTS_MIN_MONOTONIC_DRIFT_MEASUREMENT \
(ERTS_SHORT_TIME_CORRECTION_CHECK - 2*ERTS_MAX_MONOTONIC_DRIFT)
static ERTS_INLINE ErtsMonotonicTime
calc_corrected_erl_mtime(ErtsMonotonicTime os_mtime,
ErtsMonotonicCorrectionInstance *cip,
ErtsMonotonicTime *os_mdiff_p,
int os_drift_corrected)
{
ErtsMonotonicTime erl_mtime, diff = os_mtime - cip->os_mtime;
ERTS_TIME_ASSERT(diff >= 0);
if (!os_drift_corrected)
diff += (cip->correction.drift*diff)/ERTS_MONOTONIC_TIME_UNIT;
erl_mtime = cip->erl_mtime;
erl_mtime += diff;
erl_mtime += cip->correction.error*(diff/ERTS_TCORR_ERR_UNIT);
if (os_mdiff_p)
*os_mdiff_p = diff;
return erl_mtime;
}
static ERTS_INLINE ErtsMonotonicTime
read_corrected_time(int os_drift_corrected)
{
ErtsMonotonicTime os_mtime;
ErtsMonotonicCorrectionInstance ci;
erts_smp_rwmtx_rlock(&time_sup.inf.c.parmon.rwmtx);
os_mtime = erts_os_monotonic_time();
if (os_mtime >= time_sup.inf.c.parmon.cdata.insts.curr.os_mtime)
ci = time_sup.inf.c.parmon.cdata.insts.curr;
else {
if (os_mtime < time_sup.inf.c.parmon.cdata.insts.prev.os_mtime)
erl_exit(ERTS_ABORT_EXIT,
"OS monotonic time stepped backwards\n");
ci = time_sup.inf.c.parmon.cdata.insts.prev;
}
erts_smp_rwmtx_runlock(&time_sup.inf.c.parmon.rwmtx);
return calc_corrected_erl_mtime(os_mtime, &ci, NULL,
os_drift_corrected);
}
static ErtsMonotonicTime get_os_drift_corrected_time(void)
{
return read_corrected_time(!0);
}
static ErtsMonotonicTime get_corrected_time(void)
{
return read_corrected_time(0);
}
#ifdef ERTS_TIME_CORRECTION_PRINT
static ERTS_INLINE void
print_correction(int change,
ErtsMonotonicTime sdiff,
ErtsMonotonicTime old_ecorr,
ErtsMonotonicTime old_dcorr,
ErtsMonotonicTime new_ecorr,
ErtsMonotonicTime new_dcorr,
Uint tmo)
{
ErtsMonotonicTime usec_sdiff;
if (sdiff < 0)
usec_sdiff = -1*ERTS_MONOTONIC_TO_USEC(-1*sdiff);
else
usec_sdiff = ERTS_MONOTONIC_TO_USEC(sdiff);
if (!change)
erts_fprintf(stderr,
"sdiff = %b64d usec : [ec=%b64d ppm, dc=%b64d ppb] : "
"tmo = %bpu msec\r\n",
usec_sdiff,
(1000000*old_ecorr) / ERTS_TCORR_ERR_UNIT,
(1000000000*old_dcorr) / ERTS_MONOTONIC_TIME_UNIT,
tmo);
else
erts_fprintf(stderr,
"sdiff = %b64d usec : [ec=%b64d ppm, dc=%b64d ppb] "
"-> [ec=%b64d ppm, dc=%b64d ppb] : tmo = %bpu msec\r\n",
usec_sdiff,
(1000000*old_ecorr) / ERTS_TCORR_ERR_UNIT,
(1000000000*old_dcorr) / ERTS_MONOTONIC_TIME_UNIT,
(1000000*new_ecorr) / ERTS_TCORR_ERR_UNIT,
(1000000000*new_dcorr) / ERTS_MONOTONIC_TIME_UNIT,
tmo);
}
#endif
static ERTS_INLINE ErtsMonotonicTime
get_timeout_pos(ErtsMonotonicTime now, ErtsMonotonicTime tmo)
{
ErtsMonotonicTime tpos;
tpos = ERTS_MONOTONIC_TO_CLKTCKS(now - 1);
tpos += ERTS_MSEC_TO_CLKTCKS(tmo);
tpos += 1;
return tpos;
}
static void
check_time_correction(void *vesdp)
{
int init_drift_adj = !vesdp;
ErtsSchedulerData *esdp = (ErtsSchedulerData *) vesdp;
ErtsMonotonicCorrection new_correction;
ErtsMonotonicCorrectionInstance ci;
ErtsMonotonicTime mdiff, sdiff, os_mtime, erl_mtime, os_stime,
erl_stime, time_offset, timeout_pos;
Uint timeout;
int os_drift_corrected = time_sup.r.o.os_corrected_monotonic_time;
int set_new_correction = 0, begin_short_intervals = 0;
erts_smp_rwmtx_rlock(&time_sup.inf.c.parmon.rwmtx);
erts_os_times(&os_mtime, &os_stime);
ci = time_sup.inf.c.parmon.cdata.insts.curr;
erts_smp_rwmtx_runlock(&time_sup.inf.c.parmon.rwmtx);
if (os_mtime < ci.os_mtime)
erl_exit(ERTS_ABORT_EXIT,
"OS monotonic time stepped backwards\n");
erl_mtime = calc_corrected_erl_mtime(os_mtime, &ci, &mdiff,
os_drift_corrected);
time_offset = get_time_offset();
erl_stime = erl_mtime + time_offset;
sdiff = erl_stime - os_stime;
if (time_sup.inf.c.shadow_offset) {
ERTS_TIME_ASSERT(time_sup.r.o.warp_mode == ERTS_SINGLE_TIME_WARP_MODE);
if (erts_smp_atomic32_read_nob(&time_sup.inf.c.preliminary_offset))
sdiff += time_sup.inf.c.shadow_offset;
else
time_sup.inf.c.shadow_offset = 0;
}
new_correction = ci.correction;
if (time_sup.r.o.warp_mode == ERTS_MULTI_TIME_WARP_MODE
&& (sdiff < -2*time_sup.r.o.adj.small_diff
|| 2*time_sup.r.o.adj.small_diff < sdiff)) {
/* System time diff exeeded limits; change time offset... */
time_offset -= sdiff;
sdiff = 0;
set_time_offset(time_offset);
schedule_send_time_offset_changed_notifications(time_offset);
begin_short_intervals = 1;
if (ci.correction.error != 0) {
set_new_correction = 1;
new_correction.error = 0;
}
}
else if ((time_sup.r.o.warp_mode == ERTS_SINGLE_TIME_WARP_MODE
&& erts_smp_atomic32_read_nob(&time_sup.inf.c.preliminary_offset))
&& (sdiff < -2*time_sup.r.o.adj.small_diff
|| 2*time_sup.r.o.adj.small_diff < sdiff)) {
/*
* System time diff exeeded limits; change shadow offset
* and let OS system time leap away from Erlang system
* time.
*/
time_sup.inf.c.shadow_offset -= sdiff;
sdiff = 0;
begin_short_intervals = 1;
if (ci.correction.error != 0) {
set_new_correction = 1;
new_correction.error = 0;
}
}
else if (ci.correction.error == 0) {
if (sdiff < -time_sup.r.o.adj.small_diff) {
set_new_correction = 1;
if (sdiff < -time_sup.r.o.adj.large_diff)
new_correction.error = ERTS_TCORR_ERR_LARGE_ADJ;
else
new_correction.error = ERTS_TCORR_ERR_SMALL_ADJ;
}
else if (sdiff > time_sup.r.o.adj.small_diff) {
set_new_correction = 1;
if (sdiff > time_sup.r.o.adj.large_diff)
new_correction.error = -ERTS_TCORR_ERR_LARGE_ADJ;
else
new_correction.error = -ERTS_TCORR_ERR_SMALL_ADJ;
}
}
else if (ci.correction.error > 0) {
if (sdiff < 0) {
if (ci.correction.error != ERTS_TCORR_ERR_LARGE_ADJ
&& sdiff < -time_sup.r.o.adj.large_diff) {
new_correction.error = ERTS_TCORR_ERR_LARGE_ADJ;
set_new_correction = 1;
}
}
else if (sdiff > time_sup.r.o.adj.small_diff) {
set_new_correction = 1;
if (sdiff > time_sup.r.o.adj.large_diff)
new_correction.error = -ERTS_TCORR_ERR_LARGE_ADJ;
else
new_correction.error = -ERTS_TCORR_ERR_SMALL_ADJ;
}
else {
set_new_correction = 1;
new_correction.error = 0;
}
}
else /* if (ci.correction.error < 0) */ {
if (0 < sdiff) {
if (ci.correction.error != -ERTS_TCORR_ERR_LARGE_ADJ
&& time_sup.r.o.adj.large_diff < sdiff) {
new_correction.error = -ERTS_TCORR_ERR_LARGE_ADJ;
set_new_correction = 1;
}
}
else if (sdiff < -time_sup.r.o.adj.small_diff) {
set_new_correction = 1;
if (sdiff < -time_sup.r.o.adj.large_diff)
new_correction.error = ERTS_TCORR_ERR_LARGE_ADJ;
else
new_correction.error = ERTS_TCORR_ERR_SMALL_ADJ;
}
else {
set_new_correction = 1;
new_correction.error = 0;
}
}
if (!os_drift_corrected) {
ErtsMonotonicDriftData *ddp = &time_sup.inf.c.parmon.cdata.drift;
int ix = ddp->ix;
ErtsMonotonicTime mtime_diff, old_os_mtime;
old_os_mtime = ddp->intervals[ix].time.mon;
mtime_diff = os_mtime - old_os_mtime;
if ((mtime_diff >= ERTS_MIN_MONOTONIC_DRIFT_MEASUREMENT)
| init_drift_adj) {
ErtsMonotonicTime drift_adj, drift_adj_diff, old_os_stime,
smtime_diff, stime_diff, mtime_acc, stime_acc,
avg_drift_adj, max_drift;
old_os_stime = ddp->intervals[ix].time.sys;
mtime_acc = ddp->acc.mon;
stime_acc = ddp->acc.sys;
avg_drift_adj = (((stime_acc - mtime_acc)
* ERTS_MONOTONIC_TIME_UNIT)
/ mtime_acc);
mtime_diff = os_mtime - old_os_mtime;
stime_diff = os_stime - old_os_stime;
smtime_diff = stime_diff - mtime_diff;
ix++;
if (ix >= time_sup.r.o.drift_adj.intervals)
ix = 0;
mtime_acc -= ddp->intervals[ix].diff.mon;
mtime_acc += mtime_diff;
stime_acc -= ddp->intervals[ix].diff.sys;
stime_acc += stime_diff;
ddp->intervals[ix].diff.mon = mtime_diff;
ddp->intervals[ix].diff.sys = stime_diff;
ddp->intervals[ix].time.mon = os_mtime;
ddp->intervals[ix].time.sys = os_stime;
ddp->ix = ix;
ddp->acc.mon = mtime_acc;
ddp->acc.sys = stime_acc;
max_drift = ERTS_MAX_MONOTONIC_DRIFT;
max_drift *= ERTS_MONOTONIC_TO_SEC(mtime_diff);
if (smtime_diff > time_sup.r.o.drift_adj.error + max_drift
|| smtime_diff < -1*time_sup.r.o.drift_adj.error - max_drift) {
dirty_intervals:
/*
* We had a leap in system time. Mark array as
* dirty to ensure that dirty values are rotated
* out before we use it again...
*/
ddp->dirty_counter = time_sup.r.o.drift_adj.intervals;
begin_short_intervals = 1;
}
else if (ddp->dirty_counter > 0) {
if (init_drift_adj) {
new_correction.drift = ((smtime_diff
* ERTS_MONOTONIC_TIME_UNIT)
/ mtime_diff);
set_new_correction = 1;
}
ddp->dirty_counter--;
}
else {
if (ddp->dirty_counter == 0) {
/* Force set new drift correction... */
set_new_correction = 1;
ddp->dirty_counter--;
}
if (time_sup.r.o.drift_adj.use_avg)
drift_adj = (((stime_acc - mtime_acc)
* ERTS_MONOTONIC_TIME_UNIT)
/ mtime_acc);
else
drift_adj = ((smtime_diff
* ERTS_MONOTONIC_TIME_UNIT)
/ mtime_diff);
drift_adj_diff = avg_drift_adj - drift_adj;
if (drift_adj_diff < -ERTS_TIME_DRIFT_MAX_ADJ_DIFF
|| ERTS_TIME_DRIFT_MAX_ADJ_DIFF < drift_adj_diff)
goto dirty_intervals;
drift_adj_diff = drift_adj - new_correction.drift;
if (drift_adj_diff) {
if (drift_adj_diff > ERTS_TIME_DRIFT_MAX_ADJ_DIFF)
drift_adj_diff = ERTS_TIME_DRIFT_MAX_ADJ_DIFF;
else if (drift_adj_diff < -ERTS_TIME_DRIFT_MAX_ADJ_DIFF)
drift_adj_diff = -ERTS_TIME_DRIFT_MAX_ADJ_DIFF;
new_correction.drift += drift_adj_diff;
if (drift_adj_diff < -ERTS_TIME_DRIFT_MIN_ADJ_DIFF
|| ERTS_TIME_DRIFT_MIN_ADJ_DIFF < drift_adj_diff) {
set_new_correction = 1;
}
}
}
}
}
begin_short_intervals |= set_new_correction;
if (begin_short_intervals) {
time_sup.inf.c.parmon.cdata.short_check_interval
= ERTS_INIT_SHORT_INTERVAL_COUNTER;
}
else if ((os_mtime - time_sup.inf.c.parmon.cdata.last_check
>= ERTS_SHORT_TIME_CORRECTION_CHECK - ERTS_MONOTONIC_TIME_UNIT)
&& time_sup.inf.c.parmon.cdata.short_check_interval > 0) {
time_sup.inf.c.parmon.cdata.short_check_interval--;
}
time_sup.inf.c.parmon.cdata.last_check = os_mtime;
if (new_correction.error == 0)
timeout = ERTS_MONOTONIC_TO_MSEC(ERTS_LONG_TIME_CORRECTION_CHECK);
else {
ErtsMonotonicTime ecorr = new_correction.error;
ErtsMonotonicTime abs_sdiff;
abs_sdiff = (sdiff < 0) ? -1*sdiff : sdiff;
if (ecorr < 0)
ecorr = -1*ecorr;
if (abs_sdiff > ecorr*(ERTS_LONG_TIME_CORRECTION_CHECK/ERTS_TCORR_ERR_UNIT))
timeout = ERTS_MONOTONIC_TO_MSEC(ERTS_LONG_TIME_CORRECTION_CHECK);
else {
timeout = ERTS_MONOTONIC_TO_MSEC((ERTS_TCORR_ERR_UNIT*abs_sdiff)/ecorr);
if (timeout < 10)
timeout = 10;
}
}
if (timeout > ERTS_MONOTONIC_TO_MSEC(ERTS_SHORT_TIME_CORRECTION_CHECK)
&& (time_sup.inf.c.parmon.cdata.short_check_interval
|| time_sup.inf.c.parmon.cdata.drift.dirty_counter >= 0)) {
timeout = ERTS_MONOTONIC_TO_MSEC(ERTS_SHORT_TIME_CORRECTION_CHECK);
}
timeout_pos = get_timeout_pos(erl_mtime, timeout);
#ifdef ERTS_TIME_CORRECTION_PRINT
print_correction(set_new_correction,
sdiff,
ci.correction.error,
ci.correction.drift,
new_correction.error,
new_correction.drift,
timeout);
#endif
if (set_new_correction) {
erts_smp_rwmtx_rwlock(&time_sup.inf.c.parmon.rwmtx);
os_mtime = erts_os_monotonic_time();
/* Save previous correction instance */
time_sup.inf.c.parmon.cdata.insts.prev = ci;
/*
* Current correction instance begin when
* OS monotonic time has increased two units.
*/
os_mtime += 2;
/*
* Erlang monotonic time corresponding to
* next OS monotonic time using previous
* correction.
*/
erl_mtime = calc_corrected_erl_mtime(os_mtime, &ci, NULL,
os_drift_corrected);
/*
* Save new current correction instance.
*/
time_sup.inf.c.parmon.cdata.insts.curr.erl_mtime = erl_mtime;
time_sup.inf.c.parmon.cdata.insts.curr.os_mtime = os_mtime;
time_sup.inf.c.parmon.cdata.insts.curr.correction = new_correction;
erts_smp_rwmtx_rwunlock(&time_sup.inf.c.parmon.rwmtx);
}
if (!esdp)
esdp = erts_get_scheduler_data();
erts_twheel_set_timer(esdp->timer_wheel,
&time_sup.inf.c.parmon.timer,
check_time_correction,
NULL,
(void *) esdp,
timeout_pos);
}
static ErtsMonotonicTime get_os_corrected_time(void)
{
ASSERT(time_sup.r.o.warp_mode == ERTS_MULTI_TIME_WARP_MODE);
return erts_os_monotonic_time() + time_sup.r.o.moffset;
}
static void
check_time_offset(void *vesdp)
{
ErtsSchedulerData *esdp = (ErtsSchedulerData *) vesdp;
ErtsMonotonicTime sdiff, os_mtime, erl_mtime, os_stime,
erl_stime, time_offset, timeout, timeout_pos;
ASSERT(time_sup.r.o.warp_mode == ERTS_MULTI_TIME_WARP_MODE);
erts_os_times(&os_mtime, &os_stime);
erl_mtime = os_mtime + time_sup.r.o.moffset;
time_offset = get_time_offset();
erl_stime = erl_mtime + time_offset;
sdiff = erl_stime - os_stime;
if ((sdiff < -2*time_sup.r.o.adj.small_diff
|| 2*time_sup.r.o.adj.small_diff < sdiff)) {
/* System time diff exeeded limits; change time offset... */
#ifdef ERTS_TIME_CORRECTION_PRINT
erts_fprintf(stderr, "sdiff = %b64d nsec -> 0 nsec\n",
ERTS_MONOTONIC_TO_NSEC(sdiff));
#endif
time_offset -= sdiff;
sdiff = 0;
set_time_offset(time_offset);
schedule_send_time_offset_changed_notifications(time_offset);
}
#ifdef ERTS_TIME_CORRECTION_PRINT
else erts_fprintf(stderr, "sdiff = %b64d nsec\n",
ERTS_MONOTONIC_TO_NSEC(sdiff));
#endif
timeout = ERTS_MONOTONIC_TO_MSEC(ERTS_LONG_TIME_CORRECTION_CHECK);
timeout_pos = get_timeout_pos(erl_mtime, timeout);
erts_twheel_set_timer(esdp->timer_wheel,
&time_sup.inf.c.parmon.timer,
check_time_offset,
NULL,
vesdp,
timeout_pos);
}
static void
init_check_time_correction(void *vesdp)
{
ErtsMonotonicDriftData *ddp;
ErtsMonotonicTime old_mtime, old_stime, mtime, stime, mtime_diff,
stime_diff, smtime_diff, max_drift;
int ix;
ddp = &time_sup.inf.c.parmon.cdata.drift;
ix = ddp->ix;
old_mtime = ddp->intervals[0].time.mon;
old_stime = ddp->intervals[0].time.sys;
erts_os_times(&mtime, &stime);
mtime_diff = mtime - old_mtime;
stime_diff = stime - old_stime;
smtime_diff = stime_diff - mtime_diff;
max_drift = ERTS_MAX_MONOTONIC_DRIFT;
max_drift *= ERTS_MONOTONIC_TO_SEC(mtime_diff);
if (smtime_diff > time_sup.r.o.drift_adj.error + max_drift
|| smtime_diff < -1*time_sup.r.o.drift_adj.error - max_drift) {
/* Had a system time leap... pretend no drift... */
stime_diff = mtime_diff;
}
/*
* We use old time values in order to trigger
* a drift adjustment, and repeat this interval
* in all slots...
*/
for (ix = 0; ix < time_sup.r.o.drift_adj.intervals; ix++) {
ddp->intervals[ix].diff.mon = mtime_diff;
ddp->intervals[ix].diff.sys = stime_diff;
ddp->intervals[ix].time.mon = old_mtime;
ddp->intervals[ix].time.sys = old_stime;
}
ddp->acc.sys = stime_diff*time_sup.r.o.drift_adj.intervals;
ddp->acc.mon = mtime_diff*time_sup.r.o.drift_adj.intervals;
ddp->ix = 0;
ddp->dirty_counter = time_sup.r.o.drift_adj.intervals;
check_time_correction(vesdp);
}
static ErtsMonotonicTime
finalize_corrected_time_offset(ErtsSystemTime *stimep)
{
ErtsMonotonicTime os_mtime;
ErtsMonotonicCorrectionInstance ci;
int os_drift_corrected = time_sup.r.o.os_corrected_monotonic_time;
erts_smp_rwmtx_rlock(&time_sup.inf.c.parmon.rwmtx);
erts_os_times(&os_mtime, stimep);
ci = time_sup.inf.c.parmon.cdata.insts.curr;
erts_smp_rwmtx_runlock(&time_sup.inf.c.parmon.rwmtx);
if (os_mtime < ci.os_mtime)
erl_exit(ERTS_ABORT_EXIT,
"OS monotonic time stepped backwards\n");
return calc_corrected_erl_mtime(os_mtime, &ci, NULL,
os_drift_corrected);
}
static void
late_init_time_correction(ErtsSchedulerData *esdp)
{
int quick_init_drift_adj;
void (*check_func)(void *);
ErtsMonotonicTime timeout, timeout_pos;
quick_init_drift_adj =
ERTS_MONOTONIC_TO_USEC(time_sup.r.o.drift_adj.error) == 0;
if (quick_init_drift_adj)
timeout = ERTS_MONOTONIC_TO_MSEC(ERTS_SHORT_TIME_CORRECTION_CHECK/10);
else
timeout = ERTS_MONOTONIC_TO_MSEC(ERTS_SHORT_TIME_CORRECTION_CHECK);
if (!time_sup.r.o.os_corrected_monotonic_time)
check_func = init_check_time_correction;
else if (time_sup.r.o.get_time == get_os_corrected_time) {
quick_init_drift_adj = 0;
check_func = check_time_offset;
}
else
check_func = check_time_correction;
timeout_pos = get_timeout_pos(erts_get_monotonic_time(esdp),
timeout);
erts_twheel_init_timer(&time_sup.inf.c.parmon.timer);
erts_twheel_set_timer(esdp->timer_wheel,
&time_sup.inf.c.parmon.timer,
check_func,
NULL,
(quick_init_drift_adj
? NULL
: esdp),
timeout_pos);
}
#endif /* ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT */
static ErtsMonotonicTime get_not_corrected_time(void)
{
ErtsMonotonicTime stime, mtime;
erts_smp_mtx_lock(&erts_get_time_mtx);
stime = erts_os_system_time();
mtime = stime - time_sup.inf.c.not_corrected_moffset;
if (mtime >= time_sup.f.c.last_not_corrected_time)
time_sup.f.c.last_not_corrected_time = mtime;
else {
mtime = time_sup.f.c.last_not_corrected_time;
if (time_sup.r.o.warp_mode == ERTS_MULTI_TIME_WARP_MODE) {
ErtsMonotonicTime new_offset = stime - mtime;
new_offset = ERTS_MONOTONIC_TO_USEC(new_offset);
new_offset = ERTS_USEC_TO_MONOTONIC(new_offset);
if (time_sup.inf.c.not_corrected_moffset != new_offset) {
time_sup.inf.c.not_corrected_moffset = new_offset;
set_time_offset(new_offset);
schedule_send_time_offset_changed_notifications(new_offset);
}
}
}
ASSERT(stime == mtime + time_sup.inf.c.not_corrected_moffset);
erts_smp_mtx_unlock(&erts_get_time_mtx);
return mtime;
}
int erts_check_time_adj_support(int time_correction,
ErtsTimeWarpMode time_warp_mode)
{
if (!time_correction)
return 1;
/* User wants time correction */
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
return !time_sup.r.o.os_monotonic_time_disable;
#else
return 0;
#endif
}
int
erts_has_time_correction(void)
{
return time_sup.r.o.correction;
}
void erts_init_sys_time_sup(void)
{
ErtsSysInitTimeResult sys_init_time_res
= ERTS_SYS_INIT_TIME_RESULT_INITER;
sys_init_time(&sys_init_time_res);
erts_time_sup__.r.o.monotonic_time_unit
= sys_init_time_res.os_monotonic_time_unit;
#ifndef SYS_CLOCK_RESOLUTION
erts_time_sup__.r.o.clktck_resolution
= sys_init_time_res.sys_clock_resolution;
erts_time_sup__.r.o.clktck_resolution *= 1000;
#endif
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
time_sup.r.o.os_monotonic_time_disable
= !sys_init_time_res.have_os_monotonic_time;
time_sup.r.o.os_corrected_monotonic_time =
sys_init_time_res.have_corrected_os_monotonic_time;
time_sup.r.o.os_monotonic_time_func
= sys_init_time_res.os_monotonic_time_info.func;
time_sup.r.o.os_monotonic_time_clock_id
= sys_init_time_res.os_monotonic_time_info.clock_id;
time_sup.r.o.os_monotonic_time_locked
= sys_init_time_res.os_monotonic_time_info.locked_use;
time_sup.r.o.os_monotonic_time_resolution
= sys_init_time_res.os_monotonic_time_info.resolution;
time_sup.r.o.os_monotonic_time_extended
= sys_init_time_res.os_monotonic_time_info.extended;
#endif
time_sup.r.o.os_system_time_func
= sys_init_time_res.os_system_time_info.func;
time_sup.r.o.os_system_time_clock_id
= sys_init_time_res.os_system_time_info.clock_id;
time_sup.r.o.os_system_time_locked
= sys_init_time_res.os_system_time_info.locked_use;
time_sup.r.o.os_system_time_resolution
= sys_init_time_res.os_system_time_info.resolution;
}
int
erts_init_time_sup(int time_correction, ErtsTimeWarpMode time_warp_mode)
{
ErtsMonotonicTime resolution, ilength, intervals, short_isecs;
#if !ERTS_COMPILE_TIME_MONOTONIC_TIME_UNIT
ErtsMonotonicTime abs_native_offset, native_offset;
#endif
init_time_napi();
erts_hl_timer_init();
ASSERT(ERTS_MONOTONIC_TIME_MIN < ERTS_MONOTONIC_TIME_MAX);
erts_smp_mtx_init(&erts_timeofday_mtx, "timeofday");
erts_smp_mtx_init(&erts_get_time_mtx, "get_time");
time_sup.r.o.correction = time_correction;
time_sup.r.o.warp_mode = time_warp_mode;
if (time_warp_mode == ERTS_SINGLE_TIME_WARP_MODE)
erts_smp_atomic32_init_nob(&time_sup.inf.c.preliminary_offset, 1);
else
erts_smp_atomic32_init_nob(&time_sup.inf.c.preliminary_offset, 0);
time_sup.inf.c.shadow_offset = 0;
#if !ERTS_COMPILE_TIME_MONOTONIC_TIME_UNIT
/*
* NOTE! erts_time_sup__.r.o.start *need* to be a multiple
* of ERTS_MONOTONIC_TIME_UNIT.
*/
#ifdef ARCH_32
erts_time_sup__.r.o.start = ((((ErtsMonotonicTime) 1) << 32)-1);
erts_time_sup__.r.o.start /= ERTS_MONOTONIC_TIME_UNIT;
erts_time_sup__.r.o.start *= ERTS_MONOTONIC_TIME_UNIT;
erts_time_sup__.r.o.start += ERTS_MONOTONIC_TIME_UNIT;
native_offset = erts_time_sup__.r.o.start - ERTS_MONOTONIC_BEGIN;
abs_native_offset = native_offset;
#else /* ARCH_64 */
if (ERTS_MONOTONIC_TIME_UNIT <= 10*1000*1000) {
erts_time_sup__.r.o.start = 0;
native_offset = -ERTS_MONOTONIC_BEGIN;
abs_native_offset = ERTS_MONOTONIC_BEGIN;
}
else {
erts_time_sup__.r.o.start = ((ErtsMonotonicTime) MIN_SMALL);
erts_time_sup__.r.o.start /= ERTS_MONOTONIC_TIME_UNIT;
erts_time_sup__.r.o.start *= ERTS_MONOTONIC_TIME_UNIT;
native_offset = erts_time_sup__.r.o.start - ERTS_MONOTONIC_BEGIN;
abs_native_offset = -1*native_offset;
}
#endif
erts_time_sup__.r.o.start_offset.native = native_offset;
erts_time_sup__.r.o.start_offset.nsec = (ErtsMonotonicTime)
erts_time_unit_conversion((Uint64) abs_native_offset,
(Uint32) ERTS_MONOTONIC_TIME_UNIT,
(Uint32) 1000*1000*1000);
erts_time_sup__.r.o.start_offset.usec = (ErtsMonotonicTime)
erts_time_unit_conversion((Uint64) abs_native_offset,
(Uint32) ERTS_MONOTONIC_TIME_UNIT,
(Uint32) 1000*1000);
erts_time_sup__.r.o.start_offset.msec = (ErtsMonotonicTime)
erts_time_unit_conversion((Uint64) abs_native_offset,
(Uint32) ERTS_MONOTONIC_TIME_UNIT,
(Uint32) 1000);
erts_time_sup__.r.o.start_offset.sec = (ErtsMonotonicTime)
erts_time_unit_conversion((Uint64) abs_native_offset,
(Uint32) ERTS_MONOTONIC_TIME_UNIT,
(Uint32) 1);
if (native_offset < 0) {
erts_time_sup__.r.o.start_offset.nsec *= -1;
erts_time_sup__.r.o.start_offset.usec *= -1;
erts_time_sup__.r.o.start_offset.msec *= -1;
erts_time_sup__.r.o.start_offset.sec *= -1;
}
#endif
resolution = time_sup.r.o.os_system_time_resolution;
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
if (resolution > time_sup.r.o.os_monotonic_time_resolution)
resolution = time_sup.r.o.os_monotonic_time_resolution;
#endif
time_sup.r.o.adj.large_diff = erts_time_sup__.r.o.monotonic_time_unit;
time_sup.r.o.adj.large_diff *= 50;
time_sup.r.o.adj.large_diff /= resolution;
if (time_sup.r.o.adj.large_diff < ERTS_USEC_TO_MONOTONIC(500))
time_sup.r.o.adj.large_diff = ERTS_USEC_TO_MONOTONIC(500);
time_sup.r.o.adj.small_diff = time_sup.r.o.adj.large_diff/10;
time_sup.r.o.drift_adj.resolution = resolution;
if (time_sup.r.o.os_corrected_monotonic_time) {
time_sup.r.o.drift_adj.use_avg = 0;
time_sup.r.o.drift_adj.intervals = 0;
time_sup.r.o.drift_adj.error = 0;
time_sup.inf.c.parmon.cdata.drift.dirty_counter = -1;
}
else {
/*
* Calculate length of the interval in seconds needed
* in order to get an error that is at most 1 micro second.
* If this interval is longer than the short time correction
* check interval we use the average of all values instead
* of the latest value.
*/
short_isecs = ERTS_MONOTONIC_TO_SEC(ERTS_SHORT_TIME_CORRECTION_CHECK);
ilength = ERTS_ASSUMED_PRECISION_DROP * ERTS_MONOTONIC_TIME_UNIT;
ilength /= (resolution * ERTS_USEC_TO_MONOTONIC(1));
time_sup.r.o.drift_adj.use_avg = ilength > short_isecs;
if (ilength == 0)
intervals = 5;
else {
intervals = ilength / short_isecs;
if (intervals > ERTS_MAX_DRIFT_INTERVALS)
intervals = ERTS_MAX_DRIFT_INTERVALS;
else if (intervals < 5)
intervals = 5;
}
time_sup.r.o.drift_adj.intervals = (int) intervals;
/*
* drift_adj.error equals maximum assumed error
* over a short time interval. We use this value also
* when examining a large interval. In this case the
* error will be smaller, but we do not want to
* recalculate this over and over again.
*/
time_sup.r.o.drift_adj.error = ERTS_MONOTONIC_TIME_UNIT;
time_sup.r.o.drift_adj.error *= ERTS_ASSUMED_PRECISION_DROP;
time_sup.r.o.drift_adj.error /= resolution * short_isecs;
}
#ifdef ERTS_TIME_CORRECTION_PRINT
erts_fprintf(stderr, "resolution = %b64d\n", resolution);
erts_fprintf(stderr, "adj large diff = %b64d usec\n",
ERTS_MONOTONIC_TO_USEC(time_sup.r.o.adj.large_diff));
erts_fprintf(stderr, "adj small diff = %b64d usec\n",
ERTS_MONOTONIC_TO_USEC(time_sup.r.o.adj.small_diff));
if (!time_sup.r.o.os_corrected_monotonic_time) {
erts_fprintf(stderr, "drift intervals = %d\n",
time_sup.r.o.drift_adj.intervals);
erts_fprintf(stderr, "drift adj error = %b64d usec\n",
ERTS_MONOTONIC_TO_USEC(time_sup.r.o.drift_adj.error));
erts_fprintf(stderr, "drift adj max diff = %b64d nsec\n",
ERTS_MONOTONIC_TO_NSEC(ERTS_TIME_DRIFT_MAX_ADJ_DIFF));
erts_fprintf(stderr, "drift adj min diff = %b64d nsec\n",
ERTS_MONOTONIC_TO_NSEC(ERTS_TIME_DRIFT_MIN_ADJ_DIFF));
}
#endif
if (ERTS_MONOTONIC_TIME_UNIT < ERTS_CLKTCK_RESOLUTION)
ERTS_INTERNAL_ERROR("Too small monotonic time time unit");
#ifndef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
time_sup.r.o.correction = 0;
#else
if (time_sup.r.o.os_monotonic_time_disable)
time_sup.r.o.correction = 0;
if (time_sup.r.o.correction) {
ErtsMonotonicCorrectionData *cdatap;
erts_smp_rwmtx_opt_t rwmtx_opts = ERTS_SMP_RWMTX_OPT_DEFAULT_INITER;
ErtsMonotonicTime offset;
erts_os_times(&time_sup.inf.c.minit,
&time_sup.inf.c.sinit);
time_sup.r.o.moffset = -1*time_sup.inf.c.minit;
time_sup.r.o.moffset += ERTS_MONOTONIC_BEGIN;
offset = time_sup.inf.c.sinit;
offset -= ERTS_MONOTONIC_BEGIN;
init_time_offset(offset);
rwmtx_opts.type = ERTS_SMP_RWMTX_TYPE_EXTREMELY_FREQUENT_READ;
rwmtx_opts.lived = ERTS_SMP_RWMTX_LONG_LIVED;
erts_smp_rwmtx_init_opt(&time_sup.inf.c.parmon.rwmtx,
&rwmtx_opts, "get_corrected_time");
cdatap = &time_sup.inf.c.parmon.cdata;
cdatap->drift.intervals[0].time.sys = time_sup.inf.c.sinit;
cdatap->drift.intervals[0].time.mon = time_sup.inf.c.minit;
cdatap->insts.curr.correction.drift = 0;
cdatap->insts.curr.correction.error = 0;
cdatap->insts.curr.erl_mtime = ERTS_MONOTONIC_BEGIN;
cdatap->insts.curr.os_mtime = time_sup.inf.c.minit;
cdatap->last_check = time_sup.inf.c.minit;
cdatap->short_check_interval = ERTS_INIT_SHORT_INTERVAL_COUNTER;
cdatap->insts.prev = cdatap->insts.curr;
if (!time_sup.r.o.os_corrected_monotonic_time)
time_sup.r.o.get_time = get_corrected_time;
else if (time_sup.r.o.warp_mode == ERTS_MULTI_TIME_WARP_MODE)
time_sup.r.o.get_time = get_os_corrected_time;
else
time_sup.r.o.get_time = get_os_drift_corrected_time;
}
else
#endif
{
ErtsMonotonicTime stime, offset;
time_sup.r.o.get_time = get_not_corrected_time;
stime = time_sup.inf.c.sinit = erts_os_system_time();
offset = stime - ERTS_MONOTONIC_BEGIN;
time_sup.inf.c.not_corrected_moffset = offset;
init_time_offset(offset);
time_sup.f.c.last_not_corrected_time = 0;
}
prev_wall_clock_elapsed = 0;
previous_now = ERTS_MONOTONIC_TO_USEC(get_time_offset());
#ifdef DEBUG
time_sup_initialized = 1;
#endif
return ERTS_CLKTCK_RESOLUTION/1000;
}
void
erts_late_init_time_sup(void)
{
erts_late_sys_init_time();
}
void
erts_sched_init_time_sup(ErtsSchedulerData *esdp)
{
esdp->timer_wheel = erts_create_timer_wheel(esdp);
esdp->next_tmo_ref = erts_get_next_timeout_reference(esdp->timer_wheel);
esdp->timer_service = erts_create_timer_service();
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
if (esdp->no == 1) {
/* A timer wheel to use must have beeen initialized */
if (time_sup.r.o.get_time != get_not_corrected_time)
late_init_time_correction(esdp);
}
#endif
}
ErtsTimeWarpMode erts_time_warp_mode(void)
{
return time_sup.r.o.warp_mode;
}
ErtsTimeOffsetState erts_time_offset_state(void)
{
switch (time_sup.r.o.warp_mode) {
case ERTS_NO_TIME_WARP_MODE:
return ERTS_TIME_OFFSET_FINAL;
case ERTS_SINGLE_TIME_WARP_MODE:
if (erts_smp_atomic32_read_nob(&time_sup.inf.c.preliminary_offset))
return ERTS_TIME_OFFSET_PRELIMINARY;
return ERTS_TIME_OFFSET_FINAL;
case ERTS_MULTI_TIME_WARP_MODE:
return ERTS_TIME_OFFSET_VOLATILE;
default:
ERTS_INTERNAL_ERROR("Invalid time warp mode");
return ERTS_TIME_OFFSET_VOLATILE;
}
}
/*
* erts_finalize_time_offset() will only change time offset
* the first time it is called when the emulator has been
* started in "single time warp" mode. Returns previous
* state:
* * ERTS_TIME_OFFSET_PRELIMINARY - Finalization performed
* * ERTS_TIME_OFFSET_FINAL - Already finialized; nothing changed
* * ERTS_TIME_OFFSET_VOLATILE - Not supported, either in
* * no correction mode (or multi time warp mode; not yet implemented).
*/
ErtsTimeOffsetState
erts_finalize_time_offset(void)
{
switch (time_sup.r.o.warp_mode) {
case ERTS_NO_TIME_WARP_MODE:
return ERTS_TIME_OFFSET_FINAL;
case ERTS_MULTI_TIME_WARP_MODE:
return ERTS_TIME_OFFSET_VOLATILE;
case ERTS_SINGLE_TIME_WARP_MODE: {
ErtsTimeOffsetState res = ERTS_TIME_OFFSET_FINAL;
erts_smp_mtx_lock(&erts_get_time_mtx);
if (erts_smp_atomic32_read_nob(&time_sup.inf.c.preliminary_offset)) {
ErtsMonotonicTime mtime, new_offset;
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
if (!time_sup.r.o.correction)
#endif
{
ErtsMonotonicTime stime = erts_os_system_time();
mtime = stime - time_sup.inf.c.not_corrected_moffset;
if (mtime >= time_sup.f.c.last_not_corrected_time) {
time_sup.f.c.last_not_corrected_time = mtime;
new_offset = time_sup.inf.c.not_corrected_moffset;
}
else {
mtime = time_sup.f.c.last_not_corrected_time;
ASSERT(time_sup.inf.c.not_corrected_moffset != stime - mtime);
new_offset = stime - mtime;
time_sup.inf.c.not_corrected_moffset = new_offset;
}
}
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
else {
ErtsSystemTime stime;
mtime = finalize_corrected_time_offset(&stime);
new_offset = stime - mtime;
}
#endif
new_offset = ERTS_MONOTONIC_TO_USEC(new_offset);
new_offset = ERTS_USEC_TO_MONOTONIC(new_offset);
set_time_offset(new_offset);
schedule_send_time_offset_changed_notifications(new_offset);
erts_smp_atomic32_set_nob(&time_sup.inf.c.preliminary_offset, 0);
res = ERTS_TIME_OFFSET_PRELIMINARY;
}
erts_smp_mtx_unlock(&erts_get_time_mtx);
return res;
}
default:
ERTS_INTERNAL_ERROR("Invalid time warp mode");
return ERTS_TIME_OFFSET_VOLATILE;
}
}
/* info functions */
void
elapsed_time_both(UWord *ms_user, UWord *ms_sys,
UWord *ms_user_diff, UWord *ms_sys_diff)
{
UWord prev_total_user, prev_total_sys;
UWord total_user, total_sys;
SysTimes now;
sys_times(&now);
total_user = (now.tms_utime * 1000) / SYS_CLK_TCK;
total_sys = (now.tms_stime * 1000) / SYS_CLK_TCK;
if (ms_user != NULL)
*ms_user = total_user;
if (ms_sys != NULL)
*ms_sys = total_sys;
erts_smp_mtx_lock(&erts_timeofday_mtx);
prev_total_user = (t_start.tms_utime * 1000) / SYS_CLK_TCK;
prev_total_sys = (t_start.tms_stime * 1000) / SYS_CLK_TCK;
t_start = now;
erts_smp_mtx_unlock(&erts_timeofday_mtx);
if (ms_user_diff != NULL)
*ms_user_diff = total_user - prev_total_user;
if (ms_sys_diff != NULL)
*ms_sys_diff = total_sys - prev_total_sys;
}
/* wall clock routines */
void
wall_clock_elapsed_time_both(UWord *ms_total, UWord *ms_diff)
{
ErtsMonotonicTime now, elapsed;
erts_smp_mtx_lock(&erts_timeofday_mtx);
now = time_sup.r.o.get_time();
update_last_mtime(NULL, now);
elapsed = ERTS_MONOTONIC_TO_MSEC(now);
*ms_total = (UWord) elapsed;
*ms_diff = (UWord) (elapsed - prev_wall_clock_elapsed);
prev_wall_clock_elapsed = elapsed;
erts_smp_mtx_unlock(&erts_timeofday_mtx);
}
/* get current time */
void
get_time(int *hour, int *minute, int *second)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_LOCALTIME_R
struct tm tmbuf;
#endif
the_clock = time((time_t *)0);
#ifdef HAVE_LOCALTIME_R
tm = localtime_r(&the_clock, &tmbuf);
#else
tm = localtime(&the_clock);
#endif
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
}
/* get current date */
void
get_date(int *year, int *month, int *day)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_LOCALTIME_R
struct tm tmbuf;
#endif
the_clock = time((time_t *)0);
#ifdef HAVE_LOCALTIME_R
tm = localtime_r(&the_clock, &tmbuf);
#else
tm = localtime(&the_clock);
#endif
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
}
/* get localtime */
void
get_localtime(int *year, int *month, int *day,
int *hour, int *minute, int *second)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_LOCALTIME_R
struct tm tmbuf;
#endif
the_clock = time((time_t *)0);
#ifdef HAVE_LOCALTIME_R
localtime_r(&the_clock, (tm = &tmbuf));
#else
tm = localtime(&the_clock);
#endif
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
}
/* get universaltime */
void
get_universaltime(int *year, int *month, int *day,
int *hour, int *minute, int *second)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_GMTIME_R
struct tm tmbuf;
#endif
the_clock = time((time_t *)0);
#ifdef HAVE_GMTIME_R
gmtime_r(&the_clock, (tm = &tmbuf));
#else
tm = gmtime(&the_clock);
#endif
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
}
/* days in month = 1, 2, ..., 12 */
static const int mdays[14] = {0, 31, 28, 31, 30, 31, 30,
31, 31, 30, 31, 30, 31};
#define IN_RANGE(a,x,b) (((a) <= (x)) && ((x) <= (b)))
#define is_leap_year(y) (((((y) % 4) == 0) && \
(((y) % 100) != 0)) || \
(((y) % 400) == 0))
/* This is the earliest year we are sure to be able to handle
on all platforms w/o problems */
#define BASEYEAR 1902
/* A more "clever" mktime
* return 1, if successful
* return -1, if not successful
*/
static int erl_mktime(time_t *c, struct tm *tm) {
time_t clock;
clock = mktime(tm);
if (clock != -1) {
*c = clock;
return 1;
}
/* in rare occasions mktime returns -1
* when a correct value has been entered
*
* decrease seconds with one second
* if the result is -2, epochs should be -1
*/
tm->tm_sec = tm->tm_sec - 1;
clock = mktime(tm);
tm->tm_sec = tm->tm_sec + 1;
*c = -1;
if (clock == -2) {
return 1;
}
return -1;
}
/*
* gregday
*
* Returns the number of days since Jan 1, 1600, if year is
* greater of equal to 1600 , and month [1-12] and day [1-31]
* are within range. Otherwise it returns -1.
*/
static time_t gregday(int year, int month, int day)
{
Sint ndays = 0;
Sint gyear, pyear, m;
/* number of days in previous years */
gyear = year - 1600;
if (gyear > 0) {
pyear = gyear - 1;
ndays = (pyear/4) - (pyear/100) + (pyear/400) + pyear*365 + 366;
}
/* number of days in all months preceeding month */
for (m = 1; m < month; m++)
ndays += mdays[m];
/* Extra day if leap year and March or later */
if (is_leap_year(year) && (month > 2))
ndays++;
ndays += day - 1;
return (time_t) (ndays - 135140); /* 135140 = Jan 1, 1970 */
}
#define SECONDS_PER_MINUTE (60)
#define SECONDS_PER_HOUR (60 * SECONDS_PER_MINUTE)
#define SECONDS_PER_DAY (24 * SECONDS_PER_HOUR)
int seconds_to_univ(Sint64 time, Sint *year, Sint *month, Sint *day,
Sint *hour, Sint *minute, Sint *second) {
Sint y,mi;
Sint days = time / SECONDS_PER_DAY;
Sint secs = time % SECONDS_PER_DAY;
Sint tmp;
if (secs < 0) {
days--;
secs += SECONDS_PER_DAY;
}
tmp = secs % SECONDS_PER_HOUR;
*hour = secs / SECONDS_PER_HOUR;
*minute = tmp / SECONDS_PER_MINUTE;
*second = tmp % SECONDS_PER_MINUTE;
days += 719468;
y = (10000*((Sint64)days) + 14780) / 3652425;
tmp = days - (365 * y + y/4 - y/100 + y/400);
if (tmp < 0) {
y--;
tmp = days - (365*y + y/4 - y/100 + y/400);
}
mi = (100 * tmp + 52)/3060;
*month = (mi + 2) % 12 + 1;
*year = y + (mi + 2) / 12;
*day = tmp - (mi * 306 + 5)/10 + 1;
return 1;
}
int univ_to_seconds(Sint year, Sint month, Sint day, Sint hour, Sint minute, Sint second, Sint64 *time) {
Sint days;
if (!(IN_RANGE(1600, year, INT_MAX - 1) &&
IN_RANGE(1, month, 12) &&
IN_RANGE(1, day, (mdays[month] +
(month == 2
&& (year % 4 == 0)
&& (year % 100 != 0 || year % 400 == 0)))) &&
IN_RANGE(0, hour, 23) &&
IN_RANGE(0, minute, 59) &&
IN_RANGE(0, second, 59))) {
return 0;
}
days = gregday(year, month, day);
*time = SECONDS_PER_DAY;
*time *= days; /* don't try overflow it, it hurts */
*time += SECONDS_PER_HOUR * hour;
*time += SECONDS_PER_MINUTE * minute;
*time += second;
return 1;
}
#if defined(HAVE_TIME2POSIX) && defined(HAVE_DECL_TIME2POSIX) && \
!HAVE_DECL_TIME2POSIX
extern time_t time2posix(time_t);
#endif
int
local_to_univ(Sint *year, Sint *month, Sint *day,
Sint *hour, Sint *minute, Sint *second, int isdst)
{
time_t the_clock;
struct tm *tm, t;
#ifdef HAVE_GMTIME_R
struct tm tmbuf;
#endif
if (!(IN_RANGE(BASEYEAR, *year, INT_MAX - 1) &&
IN_RANGE(1, *month, 12) &&
IN_RANGE(1, *day, (mdays[*month] +
(*month == 2
&& (*year % 4 == 0)
&& (*year % 100 != 0 || *year % 400 == 0)))) &&
IN_RANGE(0, *hour, 23) &&
IN_RANGE(0, *minute, 59) &&
IN_RANGE(0, *second, 59))) {
return 0;
}
t.tm_year = *year - 1900;
t.tm_mon = *month - 1;
t.tm_mday = *day;
t.tm_hour = *hour;
t.tm_min = *minute;
t.tm_sec = *second;
t.tm_isdst = isdst;
/* the nature of mktime makes this a bit interesting,
* up to four mktime calls could happen here
*/
if (erl_mktime(&the_clock, &t) < 0) {
if (isdst) {
/* If this is a timezone without DST and the OS (correctly)
refuses to give us a DST time, we simulate the Linux/Solaris
behaviour of giving the same data as if is_dst was not set. */
t.tm_isdst = 0;
if (erl_mktime(&the_clock, &t) < 0) {
/* Failed anyway, something else is bad - will be a badarg */
return 0;
}
} else {
/* Something else is the matter, badarg. */
return 0;
}
}
#ifdef HAVE_TIME2POSIX
the_clock = time2posix(the_clock);
#endif
#ifdef HAVE_GMTIME_R
tm = gmtime_r(&the_clock, &tmbuf);
#else
tm = gmtime(&the_clock);
#endif
if (!tm) {
return 0;
}
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
return 1;
}
#if defined(HAVE_POSIX2TIME) && defined(HAVE_DECL_POSIX2TIME) && \
!HAVE_DECL_POSIX2TIME
extern time_t posix2time(time_t);
#endif
int
univ_to_local(Sint *year, Sint *month, Sint *day,
Sint *hour, Sint *minute, Sint *second)
{
time_t the_clock;
struct tm *tm;
#ifdef HAVE_LOCALTIME_R
struct tm tmbuf;
#endif
if (!(IN_RANGE(BASEYEAR, *year, INT_MAX - 1) &&
IN_RANGE(1, *month, 12) &&
IN_RANGE(1, *day, (mdays[*month] +
(*month == 2
&& (*year % 4 == 0)
&& (*year % 100 != 0 || *year % 400 == 0)))) &&
IN_RANGE(0, *hour, 23) &&
IN_RANGE(0, *minute, 59) &&
IN_RANGE(0, *second, 59))) {
return 0;
}
the_clock = *second + 60 * (*minute + 60 * (*hour + 24 *
gregday(*year, *month, *day)));
#ifdef HAVE_POSIX2TIME
/*
* Addition from OpenSource - affects FreeBSD.
* No valid test case /PaN
*
* leap-second correction performed
* if system is configured so;
* do nothing if not
* See FreeBSD 6.x and 7.x
* /usr/src/lib/libc/stdtime/localtime.c
* for the details
*/
the_clock = posix2time(the_clock);
#endif
#ifdef HAVE_LOCALTIME_R
tm = localtime_r(&the_clock, &tmbuf);
#else
tm = localtime(&the_clock);
#endif
if (tm) {
*year = tm->tm_year + 1900;
*month = tm->tm_mon +1;
*day = tm->tm_mday;
*hour = tm->tm_hour;
*minute = tm->tm_min;
*second = tm->tm_sec;
return 1;
}
return 0;
}
/* get a timestamp */
void
get_now(Uint* megasec, Uint* sec, Uint* microsec)
{
ErtsMonotonicTime now_megasec, now_sec, now, mtime, time_offset;
mtime = time_sup.r.o.get_time();
time_offset = get_time_offset();
update_last_mtime(NULL, mtime);
now = ERTS_MONOTONIC_TO_USEC(mtime + time_offset);
erts_smp_mtx_lock(&erts_timeofday_mtx);
/* Make sure now time is later than last time */
if (now <= previous_now)
now = previous_now + 1;
previous_now = now;
erts_smp_mtx_unlock(&erts_timeofday_mtx);
now_megasec = now / ERTS_MONOTONIC_TIME_TERA;
now_sec = now / ERTS_MONOTONIC_TIME_MEGA;
*megasec = (Uint) now_megasec;
*sec = (Uint) (now_sec - now_megasec*ERTS_MONOTONIC_TIME_MEGA);
*microsec = (Uint) (now - now_sec*ERTS_MONOTONIC_TIME_MEGA);
ASSERT(((ErtsMonotonicTime) *megasec)*ERTS_MONOTONIC_TIME_TERA
+ ((ErtsMonotonicTime) *sec)*ERTS_MONOTONIC_TIME_MEGA
+ ((ErtsMonotonicTime) *microsec) == now);
}
ErtsMonotonicTime
erts_get_monotonic_time(ErtsSchedulerData *esdp)
{
ErtsMonotonicTime mtime = time_sup.r.o.get_time();
update_last_mtime(esdp, mtime);
return mtime;
}
ErtsMonotonicTime
erts_get_time_offset(void)
{
return get_time_offset();
}
static ERTS_INLINE void
make_timestamp_value(Uint* megasec, Uint* sec, Uint* microsec,
ErtsMonotonicTime mtime, ErtsMonotonicTime offset)
{
ErtsMonotonicTime stime, as;
Uint ms;
stime = ERTS_MONOTONIC_TO_USEC(mtime + offset);
as = stime / ERTS_MONOTONIC_TIME_MEGA;
*megasec = ms = (Uint) (stime / ERTS_MONOTONIC_TIME_TERA);
*sec = (Uint) (as - (((ErtsMonotonicTime) ms)
* ERTS_MONOTONIC_TIME_MEGA));
*microsec = (Uint) (stime - as*ERTS_MONOTONIC_TIME_MEGA);
ASSERT(((ErtsMonotonicTime) ms)*ERTS_MONOTONIC_TIME_TERA
+ ((ErtsMonotonicTime) *sec)*ERTS_MONOTONIC_TIME_MEGA
+ *microsec == stime);
}
void
erts_make_timestamp_value(Uint* megasec, Uint* sec, Uint* microsec,
ErtsMonotonicTime mtime, ErtsMonotonicTime offset)
{
make_timestamp_value(megasec, sec, microsec, mtime, offset);
}
void
get_sys_now(Uint* megasec, Uint* sec, Uint* microsec)
{
ErtsSystemTime stime = erts_os_system_time();
ErtsSystemTime ms, s, us;
us = ERTS_MONOTONIC_TO_USEC(stime);
s = us / (1000*1000);
ms = s / (1000*1000);
*megasec = (Uint) ms;
*sec = (Uint) (s - ms*(1000*1000));
*microsec = (Uint) (us - s*(1000*1000));
}
#ifdef HAVE_ERTS_NOW_CPU
void erts_get_now_cpu(Uint* megasec, Uint* sec, Uint* microsec) {
SysCpuTime t;
SysTimespec tp;
sys_get_proc_cputime(t, tp);
*microsec = (Uint)(tp.tv_nsec / 1000);
t = (tp.tv_sec / 1000000);
*megasec = (Uint)(t % 1000000);
*sec = (Uint)(tp.tv_sec % 1000000);
}
#endif
#include "big.h"
void
erts_monitor_time_offset(Eterm id, Eterm ref)
{
erts_smp_mtx_lock(&erts_get_time_mtx);
erts_add_monitor(&time_offset_monitors, MON_TIME_OFFSET, ref, id, NIL);
no_time_offset_monitors++;
erts_smp_mtx_unlock(&erts_get_time_mtx);
}
int
erts_demonitor_time_offset(Eterm ref)
{
int res;
ErtsMonitor *mon;
ASSERT(is_internal_ref(ref));
erts_smp_mtx_lock(&erts_get_time_mtx);
mon = erts_remove_monitor(&time_offset_monitors, ref);
if (!mon)
res = 0;
else {
ASSERT(no_time_offset_monitors > 0);
no_time_offset_monitors--;
res = 1;
}
erts_smp_mtx_unlock(&erts_get_time_mtx);
if (res)
erts_destroy_monitor(mon);
return res;
}
typedef struct {
Eterm pid;
Eterm ref;
Eterm heap[REF_THING_SIZE];
} ErtsTimeOffsetMonitorInfo;
typedef struct {
Uint ix;
ErtsTimeOffsetMonitorInfo *to_mon_info;
} ErtsTimeOffsetMonitorContext;
static void
save_time_offset_monitor(ErtsMonitor *mon, void *vcntxt)
{
ErtsTimeOffsetMonitorContext *cntxt;
Eterm *from_hp, *to_hp;
Uint mix;
int hix;
cntxt = (ErtsTimeOffsetMonitorContext *) vcntxt;
mix = (cntxt->ix)++;
cntxt->to_mon_info[mix].pid = mon->pid;
to_hp = &cntxt->to_mon_info[mix].heap[0];
ASSERT(is_internal_ref(mon->ref));
from_hp = internal_ref_val(mon->ref);
ASSERT(thing_arityval(*from_hp) + 1 == REF_THING_SIZE);
for (hix = 0; hix < REF_THING_SIZE; hix++)
to_hp[hix] = from_hp[hix];
cntxt->to_mon_info[mix].ref
= make_internal_ref(&cntxt->to_mon_info[mix].heap[0]);
}
static void
send_time_offset_changed_notifications(void *new_offsetp)
{
ErtsMonotonicTime new_offset;
ErtsTimeOffsetMonitorInfo *to_mon_info = NULL; /* Shut up faulty warning */
Uint no_monitors;
char *tmp = NULL;
#ifdef ARCH_64
new_offset = (ErtsMonotonicTime) new_offsetp;
#else
new_offset = *((ErtsMonotonicTime *) new_offsetp);
erts_free(ERTS_ALC_T_NEW_TIME_OFFSET, new_offsetp);
#endif
new_offset -= ERTS_MONOTONIC_OFFSET_NATIVE;
erts_smp_mtx_lock(&erts_get_time_mtx);
no_monitors = no_time_offset_monitors;
if (no_monitors) {
ErtsTimeOffsetMonitorContext cntxt;
Uint alloc_sz;
/* Monitor info array size */
alloc_sz = no_monitors*sizeof(ErtsTimeOffsetMonitorInfo);
/* + template max size */
alloc_sz += 6*sizeof(Eterm); /* 5-tuple */
alloc_sz += ERTS_MAX_SINT64_HEAP_SIZE*sizeof(Eterm); /* max offset size */
tmp = erts_alloc(ERTS_ALC_T_TMP, alloc_sz);
to_mon_info = (ErtsTimeOffsetMonitorInfo *) tmp;
cntxt.ix = 0;
cntxt.to_mon_info = to_mon_info;
erts_doforall_monitors(time_offset_monitors,
save_time_offset_monitor,
&cntxt);
ASSERT(cntxt.ix == no_monitors);
}
erts_smp_mtx_unlock(&erts_get_time_mtx);
if (no_monitors) {
Eterm *hp, *patch_refp, new_offset_term, message_template;
Uint mix, hsz;
/* Make message template */
hp = (Eterm *) (tmp + no_monitors*sizeof(ErtsTimeOffsetMonitorInfo));
hsz = 6; /* 5-tuple */
hsz += REF_THING_SIZE;
hsz += ERTS_SINT64_HEAP_SIZE(new_offset);
if (IS_SSMALL(new_offset))
new_offset_term = make_small(new_offset);
else
new_offset_term = erts_sint64_to_big(new_offset, &hp);
message_template = TUPLE5(hp,
am_CHANGE,
THE_NON_VALUE, /* Patch point for ref */
am_time_offset,
am_clock_service,
new_offset_term);
patch_refp = &hp[2];
ASSERT(*patch_refp == THE_NON_VALUE);
for (mix = 0; mix < no_monitors; mix++) {
Process *rp = erts_proc_lookup(to_mon_info[mix].pid);
if (rp) {
Eterm ref = to_mon_info[mix].ref;
ErtsProcLocks rp_locks = ERTS_PROC_LOCK_LINK;
erts_smp_proc_lock(rp, ERTS_PROC_LOCK_LINK);
if (erts_lookup_monitor(ERTS_P_MONITORS(rp), ref)) {
ErlHeapFragment *bp;
ErlOffHeap *ohp;
Eterm message;
hp = erts_alloc_message_heap(hsz, &bp, &ohp, rp, &rp_locks);
*patch_refp = ref;
ASSERT(hsz == size_object(message_template));
message = copy_struct(message_template, hsz, &hp, ohp);
erts_queue_message(rp, &rp_locks, bp, message, NIL);
}
erts_smp_proc_unlock(rp, rp_locks);
}
}
erts_free(ERTS_ALC_T_TMP, tmp);
}
}
static void
schedule_send_time_offset_changed_notifications(ErtsMonotonicTime new_offset)
{
#ifdef ARCH_64
void *new_offsetp = (void *) new_offset;
ASSERT(sizeof(void *) == sizeof(ErtsMonotonicTime));
#else
void *new_offsetp = erts_alloc(ERTS_ALC_T_NEW_TIME_OFFSET,
sizeof(ErtsMonotonicTime));
*((ErtsMonotonicTime *) new_offsetp) = new_offset;
#endif
erts_schedule_misc_aux_work(1,
send_time_offset_changed_notifications,
new_offsetp);
}
static ERTS_INLINE Eterm
make_time_val(Process *c_p, ErtsMonotonicTime time_val)
{
Sint64 val = (Sint64) time_val;
Eterm *hp;
Uint sz;
if (IS_SSMALL(val))
return make_small(val);
sz = ERTS_SINT64_HEAP_SIZE(val);
hp = HAlloc(c_p, sz);
return erts_sint64_to_big(val, &hp);
}
Eterm
erts_get_monotonic_start_time(struct process *c_p)
{
return make_time_val(c_p, ERTS_MONOTONIC_TIME_START_EXTERNAL);
}
Eterm
erts_get_monotonic_end_time(struct process *c_p)
{
return make_time_val(c_p, ERTS_MONOTONIC_TIME_END_EXTERNAL);
}
static Eterm
bld_monotonic_time_source(Uint **hpp, Uint *szp, Sint64 os_mtime)
{
#ifndef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
return NIL;
#else
int i = 0;
Eterm k[6];
Eterm v[6];
if (time_sup.r.o.os_monotonic_time_disable)
return NIL;
k[i] = erts_bld_atom(hpp, szp, "function");
v[i++] = erts_bld_atom(hpp, szp,
time_sup.r.o.os_monotonic_time_func);
if (time_sup.r.o.os_monotonic_time_clock_id) {
k[i] = erts_bld_atom(hpp, szp, "clock_id");
v[i++] = erts_bld_atom(hpp, szp,
time_sup.r.o.os_monotonic_time_clock_id);
}
k[i] = erts_bld_atom(hpp, szp, "resolution");
v[i++] = erts_bld_uint64(hpp, szp,
time_sup.r.o.os_monotonic_time_resolution);
k[i] = erts_bld_atom(hpp, szp, "extended");
v[i++] = time_sup.r.o.os_monotonic_time_extended ? am_yes : am_no;
k[i] = erts_bld_atom(hpp, szp, "parallel");
v[i++] = time_sup.r.o.os_monotonic_time_locked ? am_no : am_yes;
k[i] = erts_bld_atom(hpp, szp, "time");
v[i++] = erts_bld_sint64(hpp, szp, os_mtime);
return erts_bld_2tup_list(hpp, szp, (Sint) i, k, v);
#endif
}
Eterm
erts_monotonic_time_source(struct process *c_p)
{
Uint hsz = 0;
Eterm *hp = NULL;
Sint64 os_mtime = 0;
#ifdef ERTS_HAVE_OS_MONOTONIC_TIME_SUPPORT
if (!time_sup.r.o.os_monotonic_time_disable)
os_mtime = (Sint64) erts_os_monotonic_time();
#endif
bld_monotonic_time_source(NULL, &hsz, os_mtime);
if (hsz)
hp = HAlloc(c_p, hsz);
return bld_monotonic_time_source(&hp, NULL, os_mtime);
}
static Eterm
bld_system_time_source(Uint **hpp, Uint *szp, Sint64 os_stime)
{
int i = 0;
Eterm k[5];
Eterm v[5];
k[i] = erts_bld_atom(hpp, szp, "function");
v[i++] = erts_bld_atom(hpp, szp,
time_sup.r.o.os_system_time_func);
if (time_sup.r.o.os_system_time_clock_id) {
k[i] = erts_bld_atom(hpp, szp, "clock_id");
v[i++] = erts_bld_atom(hpp, szp,
time_sup.r.o.os_system_time_clock_id);
}
k[i] = erts_bld_atom(hpp, szp, "resolution");
v[i++] = erts_bld_uint64(hpp, szp,
time_sup.r.o.os_system_time_resolution);
k[i] = erts_bld_atom(hpp, szp, "parallel");
v[i++] = am_yes;
k[i] = erts_bld_atom(hpp, szp, "time");
v[i++] = erts_bld_sint64(hpp, szp, os_stime);
return erts_bld_2tup_list(hpp, szp, (Sint) i, k, v);
}
Eterm
erts_system_time_source(struct process *c_p)
{
Uint hsz = 0;
Eterm *hp = NULL;
Sint64 os_stime = (Sint64) erts_os_system_time();
bld_system_time_source(NULL, &hsz, os_stime);
if (hsz)
hp = HAlloc(c_p, hsz);
return bld_system_time_source(&hp, NULL, os_stime);
}
#include "bif.h"
static ERTS_INLINE Eterm
time_unit_conversion(Process *c_p, Eterm term, ErtsMonotonicTime val, ErtsMonotonicTime muloff)
{
ErtsMonotonicTime result;
BIF_RETTYPE ret;
if (val < 0)
goto trap_to_erlang_code;
/* Convert to common user specified time units */
switch (term) {
case am_seconds:
case make_small(1):
result = ERTS_MONOTONIC_TO_SEC(val) + muloff*ERTS_MONOTONIC_OFFSET_SEC;
ERTS_BIF_PREP_RET(ret, make_time_val(c_p, result));
break;
case am_milli_seconds:
case make_small(1000):
result = ERTS_MONOTONIC_TO_MSEC(val) + muloff*ERTS_MONOTONIC_OFFSET_MSEC;
ERTS_BIF_PREP_RET(ret, make_time_val(c_p, result));
break;
case am_micro_seconds:
case make_small(1000*1000):
result = ERTS_MONOTONIC_TO_USEC(val) + muloff*ERTS_MONOTONIC_OFFSET_USEC;
ERTS_BIF_PREP_RET(ret, make_time_val(c_p, result));
break;
#ifdef ARCH_64
case am_nano_seconds:
case make_small(1000*1000*1000):
result = ERTS_MONOTONIC_TO_NSEC(val) + muloff*ERTS_MONOTONIC_OFFSET_NSEC;
ERTS_BIF_PREP_RET(ret, make_time_val(c_p, result));
break;
#endif
default: {
Eterm value, native_res;
#ifndef ARCH_64
Sint user_res;
if (term == am_nano_seconds)
goto to_nano_seconds;
if (term_to_Sint(term, &user_res)) {
if (user_res == 1000*1000*1000) {
to_nano_seconds:
result = (ERTS_MONOTONIC_TO_NSEC(val)
+ muloff*ERTS_MONOTONIC_OFFSET_NSEC);
ERTS_BIF_PREP_RET(ret, make_time_val(c_p, result));
break;
}
if (user_res <= 0)
goto badarg;
}
#else
if (is_small(term)) {
if (signed_val(term) <= 0)
goto badarg;
}
#endif
else if (is_big(term)) {
if (big_sign(term))
goto badarg;
}
else {
badarg:
ERTS_BIF_PREP_ERROR(ret, c_p, BADARG);
break;
}
trap_to_erlang_code:
/* Do it in erlang code instead; pass along values to use... */
value = make_time_val(c_p, val + muloff*ERTS_MONOTONIC_OFFSET_NATIVE);
native_res = make_time_val(c_p, ERTS_MONOTONIC_TIME_UNIT);
ERTS_BIF_PREP_TRAP3(ret, erts_convert_time_unit_trap, c_p,
value, native_res, term);
break;
}
}
return ret;
}
/*
* Time Native API (drivers and NIFs)
*/
#define ERTS_NAPI_TIME_ERROR ((ErtsMonotonicTime) ERTS_NAPI_TIME_ERROR__)
static void
init_time_napi(void)
{
/* Verify that time native api constants are as expected... */
ASSERT(sizeof(ErtsMonotonicTime) == sizeof(ErlDrvTime));
ASSERT(ERL_DRV_TIME_ERROR == (ErlDrvTime) ERTS_NAPI_TIME_ERROR);
ASSERT(ERL_DRV_TIME_ERROR < (ErlDrvTime) 0);
ASSERT(ERTS_NAPI_SEC__ == (int) ERL_DRV_SEC);
ASSERT(ERTS_NAPI_MSEC__ == (int) ERL_DRV_MSEC);
ASSERT(ERTS_NAPI_USEC__ == (int) ERL_DRV_USEC);
ASSERT(ERTS_NAPI_NSEC__ == (int) ERL_DRV_NSEC);
ASSERT(sizeof(ErtsMonotonicTime) == sizeof(ErlNifTime));
ASSERT(ERL_NIF_TIME_ERROR == (ErlNifTime) ERTS_NAPI_TIME_ERROR);
ASSERT(ERL_NIF_TIME_ERROR < (ErlNifTime) 0);
ASSERT(ERTS_NAPI_SEC__ == (int) ERL_NIF_SEC);
ASSERT(ERTS_NAPI_MSEC__ == (int) ERL_NIF_MSEC);
ASSERT(ERTS_NAPI_USEC__ == (int) ERL_NIF_USEC);
ASSERT(ERTS_NAPI_NSEC__ == (int) ERL_NIF_NSEC);
}
ErtsMonotonicTime
erts_napi_monotonic_time(int time_unit)
{
ErtsSchedulerData *esdp;
ErtsMonotonicTime mtime;
/* At least for now only allow schedulers to do this... */
esdp = erts_get_scheduler_data();
if (!esdp)
return ERTS_NAPI_TIME_ERROR;
mtime = time_sup.r.o.get_time();
update_last_mtime(esdp, mtime);
switch (time_unit) {
case ERTS_NAPI_SEC__:
mtime = ERTS_MONOTONIC_TO_SEC(mtime);
mtime += ERTS_MONOTONIC_OFFSET_SEC;
break;
case ERTS_NAPI_MSEC__:
mtime = ERTS_MONOTONIC_TO_MSEC(mtime);
mtime += ERTS_MONOTONIC_OFFSET_MSEC;
break;
case ERTS_NAPI_USEC__:
mtime = ERTS_MONOTONIC_TO_USEC(mtime);
mtime += ERTS_MONOTONIC_OFFSET_USEC;
break;
case ERTS_NAPI_NSEC__:
mtime = ERTS_MONOTONIC_TO_NSEC(mtime);
mtime += ERTS_MONOTONIC_OFFSET_NSEC;
break;
default:
return ERTS_NAPI_TIME_ERROR;
}
return mtime;
}
ErtsMonotonicTime
erts_napi_time_offset(int time_unit)
{
ErtsSchedulerData *esdp;
ErtsSystemTime offs;
/* At least for now only allow schedulers to do this... */
esdp = erts_get_scheduler_data();
if (!esdp)
return ERTS_NAPI_TIME_ERROR;
offs = get_time_offset();
switch (time_unit) {
case ERTS_NAPI_SEC__:
offs = ERTS_MONOTONIC_TO_SEC(offs);
offs -= ERTS_MONOTONIC_OFFSET_SEC;
break;
case ERTS_NAPI_MSEC__:
offs = ERTS_MONOTONIC_TO_MSEC(offs);
offs -= ERTS_MONOTONIC_OFFSET_MSEC;
break;
case ERTS_NAPI_USEC__:
offs = ERTS_MONOTONIC_TO_USEC(offs);
offs -= ERTS_MONOTONIC_OFFSET_USEC;
break;
case ERTS_NAPI_NSEC__:
offs = ERTS_MONOTONIC_TO_NSEC(offs);
offs -= ERTS_MONOTONIC_OFFSET_NSEC;
break;
default:
return ERTS_NAPI_TIME_ERROR;
}
return offs;
}
ErtsMonotonicTime
erts_napi_convert_time_unit(ErtsMonotonicTime val, int from, int to)
{
ErtsMonotonicTime ffreq, tfreq, denom;
/*
* Convertion between time units using floor function.
*
* Note that this needs to work also for negative
* values. Ordinary integer division on a negative
* value will give ceiling...
*/
switch ((int) from) {
case ERTS_NAPI_SEC__: ffreq = 1; break;
case ERTS_NAPI_MSEC__: ffreq = 1000; break;
case ERTS_NAPI_USEC__: ffreq = 1000*1000; break;
case ERTS_NAPI_NSEC__: ffreq = 1000*1000*1000; break;
default: return ERTS_NAPI_TIME_ERROR;
}
switch ((int) to) {
case ERTS_NAPI_SEC__: tfreq = 1; break;
case ERTS_NAPI_MSEC__: tfreq = 1000; break;
case ERTS_NAPI_USEC__: tfreq = 1000*1000; break;
case ERTS_NAPI_NSEC__: tfreq = 1000*1000*1000; break;
default: return ERTS_NAPI_TIME_ERROR;
}
if (tfreq >= ffreq)
return val * (tfreq / ffreq);
denom = ffreq / tfreq;
if (val >= 0)
return val / denom;
return (val - (denom - 1)) / denom;
}
/* Built in functions */
BIF_RETTYPE monotonic_time_0(BIF_ALIST_0)
{
ErtsMonotonicTime mtime = time_sup.r.o.get_time();
update_last_mtime(ERTS_PROC_GET_SCHDATA(BIF_P), mtime);
mtime += ERTS_MONOTONIC_OFFSET_NATIVE;
BIF_RET(make_time_val(BIF_P, mtime));
}
BIF_RETTYPE monotonic_time_1(BIF_ALIST_1)
{
ErtsMonotonicTime mtime = time_sup.r.o.get_time();
update_last_mtime(ERTS_PROC_GET_SCHDATA(BIF_P), mtime);
BIF_RET(time_unit_conversion(BIF_P, BIF_ARG_1, mtime, 1));
}
BIF_RETTYPE system_time_0(BIF_ALIST_0)
{
ErtsMonotonicTime mtime, offset;
mtime = time_sup.r.o.get_time();
offset = get_time_offset();
update_last_mtime(ERTS_PROC_GET_SCHDATA(BIF_P), mtime);
BIF_RET(make_time_val(BIF_P, mtime + offset));
}
BIF_RETTYPE system_time_1(BIF_ALIST_0)
{
ErtsMonotonicTime mtime, offset;
mtime = time_sup.r.o.get_time();
offset = get_time_offset();
update_last_mtime(ERTS_PROC_GET_SCHDATA(BIF_P), mtime);
BIF_RET(time_unit_conversion(BIF_P, BIF_ARG_1, mtime + offset, 0));
}
BIF_RETTYPE erts_internal_time_unit_0(BIF_ALIST_0)
{
BIF_RET(make_time_val(BIF_P, ERTS_MONOTONIC_TIME_UNIT));
}
BIF_RETTYPE time_offset_0(BIF_ALIST_0)
{
ErtsMonotonicTime time_offset = get_time_offset();
time_offset -= ERTS_MONOTONIC_OFFSET_NATIVE;
BIF_RET(make_time_val(BIF_P, time_offset));
}
BIF_RETTYPE time_offset_1(BIF_ALIST_1)
{
BIF_RET(time_unit_conversion(BIF_P, BIF_ARG_1, get_time_offset(), -1));
}
BIF_RETTYPE timestamp_0(BIF_ALIST_0)
{
Eterm *hp, res;
ErtsMonotonicTime mtime, offset;
Uint mega_sec, sec, micro_sec;
mtime = time_sup.r.o.get_time();
offset = get_time_offset();
update_last_mtime(ERTS_PROC_GET_SCHDATA(BIF_P), mtime);
make_timestamp_value(&mega_sec, &sec, µ_sec, mtime, offset);
/*
* Mega seconds is the only value that potentially
* ever could be a bignum. However, that wont happen
* during at least the next 4 million years...
*
* (System time will also have wrapped in the
* 64-bit integer before we get there...)
*/
ASSERT(IS_USMALL(0, mega_sec));
ASSERT(IS_USMALL(0, sec));
ASSERT(IS_USMALL(0, micro_sec));
hp = HAlloc(BIF_P, 4);
res = TUPLE3(hp,
make_small(mega_sec),
make_small(sec),
make_small(micro_sec));
BIF_RET(res);
}
BIF_RETTYPE os_system_time_0(BIF_ALIST_0)
{
ErtsSystemTime stime = erts_os_system_time();
BIF_RET(make_time_val(BIF_P, stime));
}
BIF_RETTYPE os_system_time_1(BIF_ALIST_0)
{
ErtsSystemTime stime = erts_os_system_time();
BIF_RET(time_unit_conversion(BIF_P, BIF_ARG_1, stime, 0));
}