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phc2sys.c
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phc2sys.c
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/**
* @file phc2sys.c
* @brief Utility program to synchronize two clocks via a PPS.
* @note Copyright (C) 2012 Richard Cochran <[email protected]>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include <errno.h>
#include <fcntl.h>
#include <float.h>
#include <inttypes.h>
#include <limits.h>
#include <net/if.h>
#include <poll.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/ioctl.h>
#include <sys/queue.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <unistd.h>
#include <linux/pps.h>
#include <linux/ptp_clock.h>
#include "clockadj.h"
#include "clockcheck.h"
#include "contain.h"
#include "ds.h"
#include "fsm.h"
#include "missing.h"
#include "notification.h"
#include "ntpshm.h"
#include "phc.h"
#include "pi.h"
#include "pmc_agent.h"
#include "print.h"
#include "servo.h"
#include "sk.h"
#include "stats.h"
#include "sysoff.h"
#include "tlv.h"
#include "uds.h"
#include "util.h"
#include "version.h"
#define KP 0.7
#define KI 0.3
#define NS_PER_SEC 1000000000LL
#define PHC_PPS_OFFSET_LIMIT 10000000
#define MAX_DST_CLOCKS 128
struct clock {
LIST_ENTRY(clock) list;
LIST_ENTRY(clock) dst_list;
clockid_t clkid;
int phc_index;
int sysoff_method;
int is_utc;
int dest_only;
int state;
int new_state;
int sync_offset;
int leap_set;
int utc_offset_set;
struct servo *servo;
enum servo_state servo_state;
char *device;
const char *source_label;
struct stats *offset_stats;
struct stats *freq_stats;
struct stats *delay_stats;
struct clockcheck *sanity_check;
};
struct port {
LIST_ENTRY(port) list;
unsigned int number;
int state;
struct clock *clock;
};
struct phc2sys_private {
unsigned int stats_max_count;
int sanity_freq_limit;
enum servo_type servo_type;
int phc_readings;
double phc_interval;
int forced_sync_offset;
int kernel_leap;
int state_changed;
int free_running;
struct pmc_agent *agent;
LIST_HEAD(port_head, port) ports;
LIST_HEAD(clock_head, clock) clocks;
LIST_HEAD(dst_clock_head, clock) dst_clocks;
struct clock *master;
};
static struct config *phc2sys_config;
static int clock_handle_leap(struct phc2sys_private *priv,
struct clock *clock,
int64_t offset, uint64_t ts);
static struct servo *servo_add(struct phc2sys_private *priv,
struct clock *clock)
{
double ppb;
int max_ppb;
struct servo *servo;
clockadj_init(clock->clkid);
ppb = clockadj_get_freq(clock->clkid);
if (clock->clkid == CLOCK_REALTIME) {
sysclk_set_leap(0);
max_ppb = sysclk_max_freq();
} else {
max_ppb = phc_max_adj(clock->clkid);
if (!max_ppb) {
pr_err("clock is not adjustable");
return NULL;
}
}
servo = servo_create(phc2sys_config, priv->servo_type,
-ppb, max_ppb, 0);
if (!servo) {
pr_err("Failed to create servo");
return NULL;
}
servo_sync_interval(servo, priv->phc_interval);
return servo;
}
static struct clock *clock_add(struct phc2sys_private *priv, const char *device,
int phc_index)
{
struct clock *c;
clockid_t clkid = CLOCK_INVALID;
char phc_device[19];
if (device) {
if (phc_index >= 0) {
snprintf(phc_device, sizeof(phc_device), "/dev/ptp%d",
phc_index);
clkid = posix_clock_open(phc_device, &phc_index);
} else {
clkid = posix_clock_open(device, &phc_index);
}
if (clkid == CLOCK_INVALID)
return NULL;
}
c = calloc(1, sizeof(*c));
if (!c) {
pr_err("failed to allocate memory for a clock");
return NULL;
}
c->clkid = clkid;
c->phc_index = phc_index;
c->servo_state = SERVO_UNLOCKED;
c->device = device ? strdup(device) : NULL;
if (c->clkid == CLOCK_REALTIME) {
c->source_label = "sys";
c->is_utc = 1;
} else {
c->source_label = "phc";
}
if (priv->stats_max_count > 0) {
c->offset_stats = stats_create();
c->freq_stats = stats_create();
c->delay_stats = stats_create();
if (!c->offset_stats ||
!c->freq_stats ||
!c->delay_stats) {
pr_err("failed to create stats");
return NULL;
}
}
if (priv->sanity_freq_limit) {
c->sanity_check = clockcheck_create(priv->sanity_freq_limit);
if (!c->sanity_check) {
pr_err("failed to create clock check");
return NULL;
}
}
if (clkid != CLOCK_INVALID && clkid != CLOCK_REALTIME)
c->sysoff_method = sysoff_probe(CLOCKID_TO_FD(clkid),
priv->phc_readings);
LIST_INSERT_HEAD(&priv->clocks, c, list);
return c;
}
static void clock_cleanup(struct phc2sys_private *priv)
{
struct clock *c, *tmp;
LIST_FOREACH_SAFE(c, &priv->clocks, list, tmp) {
if (c->servo) {
servo_destroy(c->servo);
}
if (c->sanity_check) {
clockcheck_destroy(c->sanity_check);
}
if (c->delay_stats) {
stats_destroy(c->delay_stats);
}
if (c->freq_stats) {
stats_destroy(c->freq_stats);
}
if (c->offset_stats) {
stats_destroy(c->offset_stats);
}
if (c->device) {
free(c->device);
}
free(c);
}
}
static void port_cleanup(struct phc2sys_private *priv)
{
struct port *p, *tmp;
LIST_FOREACH_SAFE(p, &priv->ports, list, tmp) {
free(p);
}
}
static struct port *port_get(struct phc2sys_private *priv, unsigned int number)
{
struct port *p;
LIST_FOREACH(p, &priv->ports, list) {
if (p->number == number)
return p;
}
return NULL;
}
static struct port *port_add(struct phc2sys_private *priv, unsigned int number,
char *device, int phc_index)
{
struct port *p;
struct clock *c = NULL, *tmp;
p = port_get(priv, number);
if (p)
return p;
/* port is a new one, look whether we have the device already on
* a different port */
LIST_FOREACH(tmp, &priv->clocks, list) {
if (!strcmp(tmp->device, device)) {
c = tmp;
break;
}
}
if (!c) {
c = clock_add(priv, device, phc_index);
if (!c)
return NULL;
}
p = malloc(sizeof(*p));
if (!p) {
pr_err("failed to allocate memory for a port");
return NULL;
}
p->number = number;
p->clock = c;
LIST_INSERT_HEAD(&priv->ports, p, list);
return p;
}
static void clock_reinit(struct phc2sys_private *priv, struct clock *clock,
int new_state)
{
int err = -1, phc_index = -1, phc_switched = 0, timestamping;
char iface[IFNAMSIZ], phc_device[19];
enum port_state state;
struct port *p;
clockid_t clkid = CLOCK_INVALID;
LIST_FOREACH(p, &priv->ports, list) {
if (p->clock != clock) {
continue;
}
err = pmc_agent_query_port_properties(priv->agent, 1000,
p->number, &state,
×tamping, &phc_index,
iface);
if (!err) {
p->state = port_state_normalize(state);
}
break;
}
if (!err && timestamping != TS_SOFTWARE) {
/* Check if device changed */
if (strcmp(clock->device, iface)) {
free(clock->device);
clock->device = strdup(iface);
}
/* Check if phc index changed */
if (clock->phc_index != phc_index) {
snprintf(phc_device, sizeof(phc_device), "/dev/ptp%d",
phc_index);
clkid = posix_clock_open(phc_device, &phc_index);
if (clkid == CLOCK_INVALID)
return;
posix_clock_close(clock->clkid);
clock->clkid = clkid;
clock->phc_index = phc_index;
if (clock->servo) {
servo_destroy(clock->servo);
clock->servo = NULL;
}
phc_switched = 1;
}
}
if (new_state == PS_MASTER || phc_switched) {
if (clock->servo)
servo_reset(clock->servo);
clock->servo_state = SERVO_UNLOCKED;
if (clock->offset_stats) {
stats_reset(clock->offset_stats);
stats_reset(clock->freq_stats);
stats_reset(clock->delay_stats);
}
}
pr_debug("%s: state change %s -> %s", clock->device,
ps_str[clock->state], ps_str[new_state]);
}
static struct clock *find_dst_clock(struct phc2sys_private *priv,
int phc_index)
{
struct clock *c = NULL;
LIST_FOREACH(c, &priv->dst_clocks, dst_list) {
if (c->phc_index == phc_index) {
break;
}
}
return c;
}
static void reconfigure(struct phc2sys_private *priv)
{
struct clock *c, *rt = NULL, *src = NULL, *last = NULL, *dup = NULL;
int src_cnt = 0, dst_cnt = 0;
pr_info("reconfiguring after port state change");
priv->state_changed = 0;
while (priv->dst_clocks.lh_first != NULL) {
LIST_REMOVE(priv->dst_clocks.lh_first, dst_list);
}
LIST_FOREACH(c, &priv->clocks, list) {
if (c->clkid == CLOCK_REALTIME) {
rt = c;
continue;
}
if (c->new_state) {
clock_reinit(priv, c, c->new_state);
c->state = c->new_state;
c->new_state = 0;
}
switch (c->state) {
case PS_FAULTY:
case PS_DISABLED:
case PS_LISTENING:
case PS_PRE_MASTER:
case PS_MASTER:
case PS_PASSIVE:
dup = find_dst_clock(priv, c->phc_index);
if (!dup) {
pr_info("selecting %s for synchronization",
c->device);
dst_cnt++;
LIST_INSERT_HEAD(&priv->dst_clocks,
c, dst_list);
} else {
pr_info("skipping %s: %s has the same clock "
"and is already selected",
c->device, dup->device);
}
break;
case PS_UNCALIBRATED:
src_cnt++;
break;
case PS_SLAVE:
src = c;
src_cnt++;
break;
}
last = c;
}
if (src_cnt > 1) {
pr_info("multiple master clocks available, postponing sync...");
priv->master = NULL;
return;
}
if (src_cnt > 0 && !src) {
pr_info("master clock not ready, waiting...");
priv->master = NULL;
return;
}
if (!src_cnt && !dst_cnt) {
pr_info("no PHC ready, waiting...");
priv->master = NULL;
return;
}
if (dst_cnt > 1 && !src) {
if (!rt || rt->dest_only) {
priv->master = last;
/* Reset to original state in next reconfiguration. */
priv->master->new_state = priv->master->state;
priv->master->state = PS_SLAVE;
if (rt)
rt->state = PS_SLAVE;
pr_info("no source, selecting %s as the default clock",
last->device);
return;
}
}
if ((!src_cnt && (!rt || rt->dest_only)) ||
(!dst_cnt && !rt)) {
pr_info("nothing to synchronize");
priv->master = NULL;
return;
}
if (!src_cnt) {
src = rt;
rt->state = PS_SLAVE;
} else if (rt) {
if (rt->state != PS_MASTER) {
rt->state = PS_MASTER;
clock_reinit(priv, rt, rt->state);
}
LIST_INSERT_HEAD(&priv->dst_clocks, rt, dst_list);
pr_info("selecting %s for synchronization", rt->device);
}
priv->master = src;
pr_info("selecting %s as the master clock", src->device);
}
static int64_t get_sync_offset(struct phc2sys_private *priv, struct clock *dst)
{
int direction = priv->forced_sync_offset;
if (!direction)
direction = dst->is_utc - priv->master->is_utc;
return (int64_t)dst->sync_offset * NS_PER_SEC * direction;
}
static void update_clock_stats(struct clock *clock, unsigned int max_count,
int64_t offset, double freq, int64_t delay)
{
struct stats_result offset_stats, freq_stats, delay_stats;
stats_add_value(clock->offset_stats, offset);
stats_add_value(clock->freq_stats, freq);
if (delay >= 0)
stats_add_value(clock->delay_stats, delay);
if (stats_get_num_values(clock->offset_stats) < max_count)
return;
stats_get_result(clock->offset_stats, &offset_stats);
stats_get_result(clock->freq_stats, &freq_stats);
if (!stats_get_result(clock->delay_stats, &delay_stats)) {
pr_info("%s "
"rms %4.0f max %4.0f "
"freq %+6.0f +/- %3.0f "
"delay %5.0f +/- %3.0f",
clock->device,
offset_stats.rms, offset_stats.max_abs,
freq_stats.mean, freq_stats.stddev,
delay_stats.mean, delay_stats.stddev);
} else {
pr_info("%s "
"rms %4.0f max %4.0f "
"freq %+6.0f +/- %3.0f",
clock->device,
offset_stats.rms, offset_stats.max_abs,
freq_stats.mean, freq_stats.stddev);
}
stats_reset(clock->offset_stats);
stats_reset(clock->freq_stats);
stats_reset(clock->delay_stats);
}
static void update_clock(struct phc2sys_private *priv, struct clock *clock,
int64_t offset, uint64_t ts, int64_t delay)
{
enum servo_state state = SERVO_UNLOCKED;
double ppb = 0.0;
if (!clock->servo) {
clock->servo = servo_add(priv, clock);
if (!clock->servo)
return;
}
if (clock_handle_leap(priv, clock, offset, ts))
return;
offset += get_sync_offset(priv, clock);
if (priv->free_running)
goto report;
if (clock->sanity_check && clockcheck_sample(clock->sanity_check, ts))
servo_reset(clock->servo);
ppb = servo_sample(clock->servo, offset, ts, 1.0, &state);
clock->servo_state = state;
switch (state) {
case SERVO_UNLOCKED:
break;
case SERVO_JUMP:
if (clockadj_step(clock->clkid, -offset)) {
goto servo_unlock;
}
if (clock->sanity_check)
clockcheck_step(clock->sanity_check, -offset);
/* Fall through. */
case SERVO_LOCKED:
case SERVO_LOCKED_STABLE:
if (clock->sanity_check)
clockcheck_freq(clock->sanity_check,
clockadj_get_freq(clock->clkid));
if (clockadj_set_freq(clock->clkid, -ppb)) {
goto servo_unlock;
}
if (clock->clkid == CLOCK_REALTIME)
sysclk_set_sync();
if (clock->sanity_check)
clockcheck_set_freq(clock->sanity_check, -ppb);
break;
}
report:
if (clock->offset_stats) {
update_clock_stats(clock, priv->stats_max_count, offset, ppb, delay);
} else {
if (delay >= 0) {
pr_info("%s %s offset %9" PRId64 " s%d freq %+7.0f "
"delay %6" PRId64,
clock->device, priv->master->source_label,
offset, state, ppb, delay);
} else {
pr_info("%s %s offset %9" PRId64 " s%d freq %+7.0f",
clock->device, priv->master->source_label,
offset, state, ppb);
}
}
return;
servo_unlock:
servo_reset(clock->servo);
clock->servo_state = SERVO_UNLOCKED;
}
static void enable_pps_output(clockid_t src)
{
int enable = 1;
if (!phc_has_pps(src))
return;
if (ioctl(CLOCKID_TO_FD(src), PTP_ENABLE_PPS, enable) < 0)
pr_warning("failed to enable PPS output");
}
static int read_pps(int fd, int64_t *offset, uint64_t *ts)
{
struct pps_fdata pfd;
pfd.timeout.sec = 10;
pfd.timeout.nsec = 0;
pfd.timeout.flags = ~PPS_TIME_INVALID;
if (ioctl(fd, PPS_FETCH, &pfd)) {
pr_err("failed to fetch PPS: %m");
return 0;
}
*ts = pfd.info.assert_tu.sec * NS_PER_SEC;
*ts += pfd.info.assert_tu.nsec;
*offset = *ts % NS_PER_SEC;
if (*offset > NS_PER_SEC / 2)
*offset -= NS_PER_SEC;
return 1;
}
static int do_pps_loop(struct phc2sys_private *priv, struct clock *clock,
int fd)
{
int64_t pps_offset, phc_offset, phc_delay;
uint64_t pps_ts, phc_ts;
clockid_t src = priv->master->clkid;
int err;
priv->master->source_label = "pps";
if (src == CLOCK_INVALID) {
/* The sync offset can't be applied with PPS alone. */
pmc_agent_set_sync_offset(priv->agent, 0);
} else {
enable_pps_output(priv->master->clkid);
}
while (is_running()) {
if (!read_pps(fd, &pps_offset, &pps_ts)) {
continue;
}
/* If a PHC is available, use it to get the whole number
of seconds in the offset and PPS for the rest. */
if (src != CLOCK_INVALID) {
err = clockadj_compare(src, clock->clkid,
priv->phc_readings,
&phc_offset, &phc_ts,
&phc_delay);
if (err == -EBUSY)
continue;
if (err)
return -1;
/* Convert the time stamp to the PHC time. */
phc_ts -= phc_offset;
/* Check if it is close to the start of the second. */
if (phc_ts % NS_PER_SEC > PHC_PPS_OFFSET_LIMIT) {
pr_warning("PPS is not in sync with PHC"
" (0.%09lld)", phc_ts % NS_PER_SEC);
continue;
}
phc_ts = phc_ts / NS_PER_SEC * NS_PER_SEC;
pps_offset = pps_ts - phc_ts;
}
if (pmc_agent_update(priv->agent) < 0)
continue;
update_clock(priv, clock, pps_offset, pps_ts, -1);
}
close(fd);
return 0;
}
static int update_needed(struct clock *c)
{
switch (c->state) {
case PS_FAULTY:
case PS_DISABLED:
case PS_LISTENING:
case PS_PRE_MASTER:
case PS_MASTER:
case PS_PASSIVE:
return 1;
case PS_UNCALIBRATED:
case PS_SLAVE:
break;
}
return 0;
}
static int do_loop(struct phc2sys_private *priv)
{
struct timespec interval;
struct clock *clock;
uint64_t ts;
int64_t offset, delay;
int err;
interval.tv_sec = priv->phc_interval;
interval.tv_nsec = (priv->phc_interval - interval.tv_sec) * 1e9;
while (is_running()) {
clock_nanosleep(CLOCK_MONOTONIC, 0, &interval, NULL);
if (pmc_agent_update(priv->agent) < 0) {
continue;
}
if (priv->state_changed) {
/* force getting offset, as it may have
* changed after the port state change */
if (pmc_agent_query_utc_offset(priv->agent, 1000)) {
pr_err("failed to get UTC offset");
continue;
}
reconfigure(priv);
}
if (!priv->master)
continue;
LIST_FOREACH(clock, &priv->dst_clocks, dst_list) {
if (!update_needed(clock))
continue;
/* don't try to synchronize the clock to itself */
if (clock->clkid == priv->master->clkid ||
(clock->phc_index >= 0 &&
clock->phc_index == priv->master->phc_index) ||
!strcmp(clock->device, priv->master->device))
continue;
if (clock->clkid == CLOCK_REALTIME &&
priv->master->sysoff_method >= 0) {
/* use sysoff */
err = sysoff_measure(CLOCKID_TO_FD(priv->master->clkid),
priv->master->sysoff_method,
priv->phc_readings,
&offset, &ts, &delay);
} else if (priv->master->clkid == CLOCK_REALTIME &&
clock->sysoff_method >= 0) {
/* use reversed sysoff */
err = sysoff_measure(CLOCKID_TO_FD(clock->clkid),
clock->sysoff_method,
priv->phc_readings,
&offset, &ts, &delay);
if (!err) {
offset = -offset;
ts += offset;
}
} else {
/* use phc */
err = clockadj_compare(priv->master->clkid,
clock->clkid,
priv->phc_readings,
&offset, &ts, &delay);
}
if (err == -EBUSY)
continue;
if (err)
return -1;
update_clock(priv, clock, offset, ts, delay);
}
}
return 0;
}
static int clock_compute_state(struct phc2sys_private *priv,
struct clock *clock)
{
struct port *p;
int state = PS_DISABLED;
LIST_FOREACH(p, &priv->ports, list) {
if (p->clock != clock)
continue;
/* PS_SLAVE takes the highest precedence, PS_UNCALIBRATED
* after that, PS_MASTER is third, PS_PRE_MASTER fourth and
* all of that overrides PS_DISABLED, which corresponds
* nicely with the numerical values */
if (p->state > state)
state = p->state;
}
return state;
}
static int phc2sys_recv_subscribed(void *context, struct ptp_message *msg,
int excluded)
{
struct phc2sys_private *priv = (struct phc2sys_private *) context;
int mgt_id, state;
struct portDS *pds;
struct port *port;
struct clock *clock;
mgt_id = management_tlv_id(msg);
if (mgt_id == excluded)
return 0;
switch (mgt_id) {
case MID_PORT_DATA_SET:
pds = management_tlv_data(msg);
port = port_get(priv, pds->portIdentity.portNumber);
if (!port) {
pr_info("received data for unknown port %s",
pid2str(&pds->portIdentity));
return 1;
}
state = port_state_normalize(pds->portState);
if (port->state != state) {
pr_info("port %s changed state",
pid2str(&pds->portIdentity));
port->state = state;
clock = port->clock;
state = clock_compute_state(priv, clock);
if (clock->state != state || clock->new_state) {
clock->new_state = state;
priv->state_changed = 1;
}
}
return 1;
}
return 0;
}
static int auto_init_ports(struct phc2sys_private *priv, int add_rt)
{
int err, number_ports, phc_index, timestamping;
enum port_state state;
char iface[IFNAMSIZ];
struct clock *clock;
struct port *port;
unsigned int i;
while (1) {
if (!is_running()) {
return -1;
}
err = pmc_agent_query_dds(priv->agent, 1000);
if (!err) {
break;
}
if (err == -ETIMEDOUT) {
pr_notice("Waiting for ptp4l...");
} else {
return -1;
}
}
number_ports = pmc_agent_get_number_ports(priv->agent);
if (number_ports <= 0) {
pr_err("failed to get number of ports");
return -1;
}
err = pmc_agent_subscribe(priv->agent, 1000);
if (err) {
pr_err("failed to subscribe");
return -1;
}
for (i = 1; i <= number_ports; i++) {
err = pmc_agent_query_port_properties(priv->agent, 1000, i,
&state, ×tamping,
&phc_index, iface);
if (err == -ENODEV) {
/* port does not exist, ignore the port */
continue;
}
if (err) {
pr_err("failed to get port properties");
return -1;
}
if (timestamping == TS_SOFTWARE) {
/* ignore ports with software time stamping */
continue;
}
port = port_add(priv, i, iface, phc_index);
if (!port)
return -1;
port->state = port_state_normalize(state);
}
if (LIST_EMPTY(&priv->clocks)) {
pr_err("no suitable ports available");
return -1;
}
LIST_FOREACH(clock, &priv->clocks, list) {
clock->new_state = clock_compute_state(priv, clock);
}
priv->state_changed = 1;
if (add_rt) {
clock = clock_add(priv, "CLOCK_REALTIME", -1);
if (!clock)
return -1;
if (add_rt == 1)
clock->dest_only = 1;
}
/* get initial offset */
if (pmc_agent_query_utc_offset(priv->agent, 1000)) {
pr_err("failed to get UTC offset");
return -1;
}
return 0;
}
/* Returns: non-zero to skip clock update */
static int clock_handle_leap(struct phc2sys_private *priv, struct clock *clock,
int64_t offset, uint64_t ts)
{
int clock_leap, node_leap = pmc_agent_get_leap(priv->agent);
clock->sync_offset = pmc_agent_get_sync_offset(priv->agent);
if ((node_leap || clock->leap_set) &&
clock->is_utc != priv->master->is_utc) {
/* If the master clock is in UTC, get a time stamp from it, as
it is the clock which will include the leap second. */
if (priv->master->is_utc) {
struct timespec tp;
if (clock_gettime(priv->master->clkid, &tp)) {
pr_err("failed to read clock: %m");
return -1;
}
ts = tp.tv_sec * NS_PER_SEC + tp.tv_nsec;
}
/* If the clock will be stepped, the time stamp has to be the
new time. Ignore possible 1 second error in UTC offset. */
if (clock->is_utc && clock->servo_state == SERVO_UNLOCKED)
ts -= offset + get_sync_offset(priv, clock);
/* Suspend clock updates in the last second before midnight. */
if (is_utc_ambiguous(ts)) {
pr_info("clock update suspended due to leap second");
return 1;
}
clock_leap = leap_second_status(ts, clock->leap_set,
&node_leap,
&clock->sync_offset);
if (clock->leap_set != clock_leap) {
/* Only the system clock can leap. */
if (clock->clkid == CLOCK_REALTIME &&
priv->kernel_leap)
sysclk_set_leap(clock_leap);
else
servo_leap(clock->servo, clock_leap);
clock->leap_set = clock_leap;
}
}
if (pmc_agent_utc_offset_traceable(priv->agent) &&
clock->utc_offset_set != clock->sync_offset) {
if (clock->clkid == CLOCK_REALTIME)
sysclk_set_tai_offset(clock->sync_offset);
clock->utc_offset_set = clock->sync_offset;
}
return 0;
}
static bool hardpps_configured(int fd)
{
return fd >= 0;
}
static int phc2sys_static_src_configuration(struct phc2sys_private *priv,
const char *src_name)
{
struct clock *src;
src = clock_add(priv, src_name, -1);
if (!src) {
fprintf(stderr, "valid source clock must be selected.\n");
return -1;
}
src->state = PS_SLAVE;
priv->master = src;
return 0;
}
static int phc2sys_static_dst_configuration(struct phc2sys_private *priv,
const char *dst_name)
{