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clock.c
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clock.c
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/**
* @file clock.c
* @note Copyright (C) 2011 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 <linux/net_tstamp.h>
#include <poll.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <sys/queue.h>
#include "address.h"
#include "bmc.h"
#include "clock.h"
#include "clockadj.h"
#include "clockcheck.h"
#include "foreign.h"
#include "filter.h"
#include "hash.h"
#include "missing.h"
#include "msg.h"
#include "phc.h"
#include "port.h"
#include "servo.h"
#include "stats.h"
#include "print.h"
#include "rtnl.h"
#include "sk.h"
#include "tlv.h"
#include "tsproc.h"
#include "uds.h"
#include "util.h"
#define N_CLOCK_PFD (N_POLLFD + 1) /* one extra per port, for the fault timer */
#define POW2_41 ((double)(1ULL << 41))
struct port {
LIST_ENTRY(port) list;
};
struct freq_estimator {
tmv_t origin1;
tmv_t ingress1;
unsigned int max_count;
unsigned int count;
};
struct clock_stats {
struct stats *offset;
struct stats *freq;
struct stats *delay;
unsigned int max_count;
};
struct clock_subscriber {
LIST_ENTRY(clock_subscriber) list;
uint8_t events[EVENT_BITMASK_CNT];
struct PortIdentity targetPortIdentity;
struct address addr;
UInteger16 sequenceId;
time_t expiration;
};
struct clock {
enum clock_type type;
struct config *config;
clockid_t clkid;
struct servo *servo;
enum servo_type servo_type;
struct defaultDS dds;
struct dataset default_dataset;
struct currentDS cur;
struct parent_ds dad;
struct timePropertiesDS tds;
struct ClockIdentity ptl[PATH_TRACE_MAX];
struct foreign_clock *best;
struct ClockIdentity best_id;
LIST_HEAD(ports_head, port) ports;
struct port *uds_port;
struct pollfd *pollfd;
int pollfd_valid;
int nports; /* does not include the UDS port */
int last_port_number;
int sde;
struct hash *index2port;
int free_running;
int freq_est_interval;
int grand_master_capable; /* for 802.1AS only */
int utc_timescale;
int utc_offset_set;
int leap_set;
int kernel_leap;
int utc_offset; /* grand master role */
int current_utc_offset; /* UTC offset fallback */
int time_flags; /* grand master role */
int time_source; /* grand master role */
enum servo_state servo_state;
tmv_t master_offset;
tmv_t path_delay;
tmv_t ingress_ts;
struct tsproc *tsproc;
struct freq_estimator fest;
struct time_status_np status;
double nrr;
struct clock_description desc;
struct clock_stats stats;
int stats_interval;
struct clockcheck *sanity_check;
struct interface uds_interface;
LIST_HEAD(clock_subscribers_head, clock_subscriber) subscribers;
};
struct clock the_clock;
static void handle_state_decision_event(struct clock *c);
static int clock_resize_pollfd(struct clock *c, int new_nports);
static void clock_remove_port(struct clock *c, struct port *p);
static int cid_eq(struct ClockIdentity *a, struct ClockIdentity *b)
{
return 0 == memcmp(a, b, sizeof(*a));
}
#ifndef LIST_FOREACH_SAFE
#define LIST_FOREACH_SAFE(var, head, field, tvar) \
for ((var) = LIST_FIRST((head)); \
(var) && ((tvar) = LIST_NEXT((var), field), 1); \
(var) = (tvar))
#endif
static void remove_subscriber(struct clock_subscriber *s)
{
LIST_REMOVE(s, list);
free(s);
}
static void clock_update_subscription(struct clock *c, struct ptp_message *req,
uint8_t *bitmask, uint16_t duration)
{
struct clock_subscriber *s;
int i, remove = 1;
struct timespec now;
for (i = 0; i < EVENT_BITMASK_CNT; i++) {
if (bitmask[i]) {
remove = 0;
break;
}
}
LIST_FOREACH(s, &c->subscribers, list) {
if (!memcmp(&s->targetPortIdentity, &req->header.sourcePortIdentity,
sizeof(struct PortIdentity))) {
/* Found, update the transport address and event
* mask. */
if (!remove) {
s->addr = req->address;
memcpy(s->events, bitmask, EVENT_BITMASK_CNT);
clock_gettime(CLOCK_MONOTONIC, &now);
s->expiration = now.tv_sec + duration;
} else {
remove_subscriber(s);
}
return;
}
}
if (remove)
return;
/* Not present yet, add the subscriber. */
s = malloc(sizeof(*s));
if (!s) {
pr_err("failed to allocate memory for a subscriber");
return;
}
s->targetPortIdentity = req->header.sourcePortIdentity;
s->addr = req->address;
memcpy(s->events, bitmask, EVENT_BITMASK_CNT);
clock_gettime(CLOCK_MONOTONIC, &now);
s->expiration = now.tv_sec + duration;
s->sequenceId = 0;
LIST_INSERT_HEAD(&c->subscribers, s, list);
}
static void clock_get_subscription(struct clock *c, struct ptp_message *req,
uint8_t *bitmask, uint16_t *duration)
{
struct clock_subscriber *s;
struct timespec now;
LIST_FOREACH(s, &c->subscribers, list) {
if (!memcmp(&s->targetPortIdentity, &req->header.sourcePortIdentity,
sizeof(struct PortIdentity))) {
memcpy(bitmask, s->events, EVENT_BITMASK_CNT);
clock_gettime(CLOCK_MONOTONIC, &now);
if (s->expiration < now.tv_sec)
*duration = 0;
else
*duration = s->expiration - now.tv_sec;
return;
}
}
/* A client without entry means the client has no subscriptions. */
memset(bitmask, 0, EVENT_BITMASK_CNT);
*duration = 0;
}
static void clock_flush_subscriptions(struct clock *c)
{
struct clock_subscriber *s, *tmp;
LIST_FOREACH_SAFE(s, &c->subscribers, list, tmp) {
remove_subscriber(s);
}
}
static void clock_prune_subscriptions(struct clock *c)
{
struct clock_subscriber *s, *tmp;
struct timespec now;
clock_gettime(CLOCK_MONOTONIC, &now);
LIST_FOREACH_SAFE(s, &c->subscribers, list, tmp) {
if (s->expiration <= now.tv_sec) {
pr_info("subscriber %s timed out",
pid2str(&s->targetPortIdentity));
remove_subscriber(s);
}
}
}
void clock_send_notification(struct clock *c, struct ptp_message *msg,
int msglen, enum notification event)
{
unsigned int event_pos = event / 8;
uint8_t mask = 1 << (event % 8);
struct port *uds = c->uds_port;
struct clock_subscriber *s;
LIST_FOREACH(s, &c->subscribers, list) {
if (!(s->events[event_pos] & mask))
continue;
/* send event */
msg->header.sequenceId = htons(s->sequenceId);
s->sequenceId++;
msg->management.targetPortIdentity.clockIdentity =
s->targetPortIdentity.clockIdentity;
msg->management.targetPortIdentity.portNumber =
htons(s->targetPortIdentity.portNumber);
msg->address = s->addr;
port_forward_to(uds, msg);
}
}
void clock_destroy(struct clock *c)
{
struct port *p, *tmp;
clock_flush_subscriptions(c);
LIST_FOREACH_SAFE(p, &c->ports, list, tmp) {
clock_remove_port(c, p);
}
if (c->pollfd[0].fd >= 0) {
rtnl_close(c->pollfd[0].fd);
}
port_close(c->uds_port);
free(c->pollfd);
hash_destroy(c->index2port, NULL);
if (c->clkid != CLOCK_REALTIME) {
phc_close(c->clkid);
}
servo_destroy(c->servo);
tsproc_destroy(c->tsproc);
stats_destroy(c->stats.offset);
stats_destroy(c->stats.freq);
stats_destroy(c->stats.delay);
if (c->sanity_check)
clockcheck_destroy(c->sanity_check);
memset(c, 0, sizeof(*c));
msg_cleanup();
}
static int clock_fault_timeout(struct port *port, int set)
{
struct fault_interval i;
if (!set) {
pr_debug("clearing fault on port %d", port_number(port));
return port_set_fault_timer_lin(port, 0);
}
fault_interval(port, last_fault_type(port), &i);
if (i.type == FTMO_LINEAR_SECONDS) {
pr_debug("waiting %d seconds to clear fault on port %d",
i.val, port_number(port));
return port_set_fault_timer_lin(port, i.val);
} else if (i.type == FTMO_LOG2_SECONDS) {
pr_debug("waiting 2^{%d} seconds to clear fault on port %d",
i.val, port_number(port));
return port_set_fault_timer_log(port, 1, i.val);
}
pr_err("Unsupported fault interval type %d", i.type);
return -1;
}
static void clock_freq_est_reset(struct clock *c)
{
c->fest.origin1 = tmv_zero();
c->fest.ingress1 = tmv_zero();
c->fest.count = 0;
}
static void clock_link_status(void *ctx, int index, int linkup)
{
struct clock *c = ctx;
struct port *p;
char key[16];
snprintf(key, sizeof(key), "%d", index);
p = hash_lookup(c->index2port, key);
if (!p) {
return;
}
port_link_status_set(p, linkup);
if (linkup) {
port_dispatch(p, EV_FAULT_CLEARED, 0);
} else {
port_dispatch(p, EV_FAULT_DETECTED, 0);
/*
* A port going down can affect the BMCA result.
* Force a state decision event.
*/
c->sde = 1;
}
}
static void clock_management_send_error(struct port *p,
struct ptp_message *msg, int error_id)
{
if (port_management_error(port_identity(p), p, msg, error_id))
pr_err("failed to send management error status");
}
/* The 'p' and 'req' paremeters are needed for the GET actions that operate
* on per-client datasets. If such actions do not apply to the caller, it is
* allowed to pass both of them as NULL.
*/
static int clock_management_fill_response(struct clock *c, struct port *p,
struct ptp_message *req,
struct ptp_message *rsp, int id)
{
int datalen = 0, respond = 0;
struct management_tlv *tlv;
struct management_tlv_datum *mtd;
struct time_status_np *tsn;
struct grandmaster_settings_np *gsn;
struct subscribe_events_np *sen;
struct PTPText *text;
tlv = (struct management_tlv *) rsp->management.suffix;
tlv->type = TLV_MANAGEMENT;
tlv->id = id;
switch (id) {
case TLV_USER_DESCRIPTION:
text = (struct PTPText *) tlv->data;
text->length = c->desc.userDescription.length;
memcpy(text->text, c->desc.userDescription.text, text->length);
datalen = 1 + text->length;
respond = 1;
break;
case TLV_DEFAULT_DATA_SET:
memcpy(tlv->data, &c->dds, sizeof(c->dds));
datalen = sizeof(c->dds);
respond = 1;
break;
case TLV_CURRENT_DATA_SET:
memcpy(tlv->data, &c->cur, sizeof(c->cur));
datalen = sizeof(c->cur);
respond = 1;
break;
case TLV_PARENT_DATA_SET:
memcpy(tlv->data, &c->dad.pds, sizeof(c->dad.pds));
datalen = sizeof(c->dad.pds);
respond = 1;
break;
case TLV_TIME_PROPERTIES_DATA_SET:
memcpy(tlv->data, &c->tds, sizeof(c->tds));
datalen = sizeof(c->tds);
respond = 1;
break;
case TLV_PRIORITY1:
mtd = (struct management_tlv_datum *) tlv->data;
mtd->val = c->dds.priority1;
datalen = sizeof(*mtd);
respond = 1;
break;
case TLV_PRIORITY2:
mtd = (struct management_tlv_datum *) tlv->data;
mtd->val = c->dds.priority2;
datalen = sizeof(*mtd);
respond = 1;
break;
case TLV_DOMAIN:
mtd = (struct management_tlv_datum *) tlv->data;
mtd->val = c->dds.domainNumber;
datalen = sizeof(*mtd);
respond = 1;
break;
case TLV_SLAVE_ONLY:
mtd = (struct management_tlv_datum *) tlv->data;
mtd->val = c->dds.flags & DDS_SLAVE_ONLY;
datalen = sizeof(*mtd);
respond = 1;
break;
case TLV_CLOCK_ACCURACY:
mtd = (struct management_tlv_datum *) tlv->data;
mtd->val = c->dds.clockQuality.clockAccuracy;
datalen = sizeof(*mtd);
respond = 1;
break;
case TLV_TRACEABILITY_PROPERTIES:
mtd = (struct management_tlv_datum *) tlv->data;
mtd->val = c->tds.flags & (TIME_TRACEABLE|FREQ_TRACEABLE);
datalen = sizeof(*mtd);
respond = 1;
break;
case TLV_TIMESCALE_PROPERTIES:
mtd = (struct management_tlv_datum *) tlv->data;
mtd->val = c->tds.flags & PTP_TIMESCALE;
datalen = sizeof(*mtd);
respond = 1;
break;
case TLV_TIME_STATUS_NP:
tsn = (struct time_status_np *) tlv->data;
tsn->master_offset = c->master_offset;
tsn->ingress_time = tmv_to_nanoseconds(c->ingress_ts);
tsn->cumulativeScaledRateOffset =
(Integer32) (c->status.cumulativeScaledRateOffset +
c->nrr * POW2_41 - POW2_41);
tsn->scaledLastGmPhaseChange = c->status.scaledLastGmPhaseChange;
tsn->gmTimeBaseIndicator = c->status.gmTimeBaseIndicator;
tsn->lastGmPhaseChange = c->status.lastGmPhaseChange;
if (cid_eq(&c->dad.pds.grandmasterIdentity, &c->dds.clockIdentity))
tsn->gmPresent = 0;
else
tsn->gmPresent = 1;
tsn->gmIdentity = c->dad.pds.grandmasterIdentity;
datalen = sizeof(*tsn);
respond = 1;
break;
case TLV_GRANDMASTER_SETTINGS_NP:
gsn = (struct grandmaster_settings_np *) tlv->data;
gsn->clockQuality = c->dds.clockQuality;
gsn->utc_offset = c->utc_offset;
gsn->time_flags = c->time_flags;
gsn->time_source = c->time_source;
datalen = sizeof(*gsn);
respond = 1;
break;
case TLV_SUBSCRIBE_EVENTS_NP:
if (p != c->uds_port) {
/* Only the UDS port allowed. */
break;
}
sen = (struct subscribe_events_np *)tlv->data;
clock_get_subscription(c, req, sen->bitmask, &sen->duration);
respond = 1;
break;
}
if (respond) {
if (datalen % 2) {
tlv->data[datalen] = 0;
datalen++;
}
tlv->length = sizeof(tlv->id) + datalen;
rsp->header.messageLength += sizeof(*tlv) + datalen;
rsp->tlv_count = 1;
}
return respond;
}
static int clock_management_get_response(struct clock *c, struct port *p,
int id, struct ptp_message *req)
{
struct PortIdentity pid = port_identity(p);
struct ptp_message *rsp;
int respond;
rsp = port_management_reply(pid, p, req);
if (!rsp) {
return 0;
}
respond = clock_management_fill_response(c, p, req, rsp, id);
if (respond)
port_prepare_and_send(p, rsp, 0);
msg_put(rsp);
return respond;
}
static int clock_management_set(struct clock *c, struct port *p,
int id, struct ptp_message *req, int *changed)
{
int respond = 0;
struct management_tlv *tlv;
struct management_tlv_datum *mtd;
struct grandmaster_settings_np *gsn;
struct subscribe_events_np *sen;
tlv = (struct management_tlv *) req->management.suffix;
switch (id) {
case TLV_PRIORITY1:
mtd = (struct management_tlv_datum *) tlv->data;
c->dds.priority1 = mtd->val;
*changed = 1;
respond = 1;
break;
case TLV_PRIORITY2:
mtd = (struct management_tlv_datum *) tlv->data;
c->dds.priority2 = mtd->val;
*changed = 1;
respond = 1;
break;
case TLV_GRANDMASTER_SETTINGS_NP:
gsn = (struct grandmaster_settings_np *) tlv->data;
c->dds.clockQuality = gsn->clockQuality;
c->utc_offset = gsn->utc_offset;
c->time_flags = gsn->time_flags;
c->time_source = gsn->time_source;
*changed = 1;
respond = 1;
break;
case TLV_SUBSCRIBE_EVENTS_NP:
sen = (struct subscribe_events_np *)tlv->data;
clock_update_subscription(c, req, sen->bitmask,
sen->duration);
respond = 1;
break;
}
if (respond && !clock_management_get_response(c, p, id, req))
pr_err("failed to send management set response");
return respond ? 1 : 0;
}
static void clock_stats_update(struct clock_stats *s,
int64_t offset, double freq)
{
struct stats_result offset_stats, freq_stats, delay_stats;
stats_add_value(s->offset, offset);
stats_add_value(s->freq, freq);
if (stats_get_num_values(s->offset) < s->max_count)
return;
stats_get_result(s->offset, &offset_stats);
stats_get_result(s->freq, &freq_stats);
/* Path delay stats are updated separately, they may be empty. */
if (!stats_get_result(s->delay, &delay_stats)) {
pr_info("rms %4.0f max %4.0f "
"freq %+6.0f +/- %3.0f "
"delay %5.0f +/- %3.0f",
offset_stats.rms, offset_stats.max_abs,
freq_stats.mean, freq_stats.stddev,
delay_stats.mean, delay_stats.stddev);
} else {
pr_info("rms %4.0f max %4.0f "
"freq %+6.0f +/- %3.0f",
offset_stats.rms, offset_stats.max_abs,
freq_stats.mean, freq_stats.stddev);
}
stats_reset(s->offset);
stats_reset(s->freq);
stats_reset(s->delay);
}
static enum servo_state clock_no_adjust(struct clock *c, tmv_t ingress,
tmv_t origin)
{
double fui;
double ratio, freq;
struct freq_estimator *f = &c->fest;
enum servo_state state = SERVO_UNLOCKED;
/*
* The ratio of the local clock freqency to the master clock
* is estimated by:
*
* (ingress_2 - ingress_1) / (origin_2 - origin_1)
*
* Both of the origin time estimates include the path delay,
* but we assume that the path delay is in fact constant.
* By leaving out the path delay altogther, we can avoid the
* error caused by our imperfect path delay measurement.
*/
if (!f->ingress1) {
f->ingress1 = ingress;
f->origin1 = origin;
return state;
}
f->count++;
if (f->count < f->max_count) {
return state;
}
if (tmv_eq(ingress, f->ingress1)) {
pr_warning("bad timestamps in rate ratio calculation");
return state;
}
ratio = tmv_dbl(tmv_sub(origin, f->origin1)) /
tmv_dbl(tmv_sub(ingress, f->ingress1));
freq = (1.0 - ratio) * 1e9;
if (c->stats.max_count > 1) {
clock_stats_update(&c->stats,
tmv_to_nanoseconds(c->master_offset), freq);
} else {
pr_info("master offset %10" PRId64 " s%d freq %+7.0f "
"path delay %9" PRId64,
tmv_to_nanoseconds(c->master_offset), state, freq,
tmv_to_nanoseconds(c->path_delay));
}
fui = 1.0 + (c->status.cumulativeScaledRateOffset + 0.0) / POW2_41;
pr_debug("peer/local %.9f", c->nrr);
pr_debug("fup_info %.9f", fui);
pr_debug("product %.9f", fui * c->nrr);
pr_debug("sum-1 %.9f", fui + c->nrr - 1.0);
pr_debug("master/local %.9f", ratio);
pr_debug("diff %+.9f", ratio - (fui + c->nrr - 1.0));
f->ingress1 = ingress;
f->origin1 = origin;
f->count = 0;
return state;
}
static void clock_update_grandmaster(struct clock *c)
{
struct parentDS *pds = &c->dad.pds;
memset(&c->cur, 0, sizeof(c->cur));
memset(c->ptl, 0, sizeof(c->ptl));
pds->parentPortIdentity.clockIdentity = c->dds.clockIdentity;
pds->parentPortIdentity.portNumber = 0;
pds->grandmasterIdentity = c->dds.clockIdentity;
pds->grandmasterClockQuality = c->dds.clockQuality;
pds->grandmasterPriority1 = c->dds.priority1;
pds->grandmasterPriority2 = c->dds.priority2;
c->dad.path_length = 0;
c->tds.currentUtcOffset = c->utc_offset;
c->tds.flags = c->time_flags;
c->tds.timeSource = c->time_source;
}
static void clock_update_slave(struct clock *c)
{
struct parentDS *pds = &c->dad.pds;
struct ptp_message *msg = TAILQ_FIRST(&c->best->messages);
c->cur.stepsRemoved = 1 + c->best->dataset.stepsRemoved;
pds->parentPortIdentity = c->best->dataset.sender;
pds->grandmasterIdentity = msg->announce.grandmasterIdentity;
pds->grandmasterClockQuality = msg->announce.grandmasterClockQuality;
pds->grandmasterPriority1 = msg->announce.grandmasterPriority1;
pds->grandmasterPriority2 = msg->announce.grandmasterPriority2;
c->tds.currentUtcOffset = msg->announce.currentUtcOffset;
c->tds.flags = msg->header.flagField[1];
c->tds.timeSource = msg->announce.timeSource;
if (!(c->tds.flags & PTP_TIMESCALE)) {
pr_warning("foreign master not using PTP timescale");
}
if (c->tds.currentUtcOffset < c->current_utc_offset) {
pr_warning("running in a temporal vortex");
}
}
static int clock_utc_correct(struct clock *c, tmv_t ingress)
{
struct timespec offset;
int utc_offset, leap, clock_leap;
uint64_t ts;
if (!c->utc_timescale)
return 0;
if (c->tds.flags & UTC_OFF_VALID && c->tds.flags & TIME_TRACEABLE) {
utc_offset = c->tds.currentUtcOffset;
} else if (c->tds.currentUtcOffset > c->current_utc_offset) {
utc_offset = c->tds.currentUtcOffset;
} else {
utc_offset = c->current_utc_offset;
}
if (c->tds.flags & LEAP_61) {
leap = 1;
} else if (c->tds.flags & LEAP_59) {
leap = -1;
} else {
leap = 0;
}
/* Handle leap seconds. */
if ((leap || c->leap_set) && c->clkid == CLOCK_REALTIME) {
/* If the clock will be stepped, the time stamp has to be the
target time. Ignore possible 1 second error in utc_offset. */
if (c->servo_state == SERVO_UNLOCKED) {
ts = tmv_to_nanoseconds(tmv_sub(ingress,
c->master_offset));
if (c->tds.flags & PTP_TIMESCALE)
ts -= utc_offset * NS_PER_SEC;
} else {
ts = tmv_to_nanoseconds(ingress);
}
/* 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, c->leap_set,
&leap, &utc_offset);
if (c->leap_set != clock_leap) {
if (c->kernel_leap)
sysclk_set_leap(clock_leap);
else
servo_leap(c->servo, clock_leap);
c->leap_set = clock_leap;
}
}
/* Update TAI-UTC offset of the system clock if valid and traceable. */
if (c->tds.flags & UTC_OFF_VALID && c->tds.flags & TIME_TRACEABLE &&
c->utc_offset_set != utc_offset && c->clkid == CLOCK_REALTIME) {
sysclk_set_tai_offset(utc_offset);
c->utc_offset_set = utc_offset;
}
if (!(c->tds.flags & PTP_TIMESCALE))
return 0;
offset.tv_sec = utc_offset;
offset.tv_nsec = 0;
/* Local clock is UTC, but master is TAI. */
c->master_offset = tmv_add(c->master_offset, timespec_to_tmv(offset));
return 0;
}
static int forwarding(struct clock *c, struct port *p)
{
enum port_state ps = port_state(p);
switch (ps) {
case PS_MASTER:
case PS_GRAND_MASTER:
case PS_SLAVE:
case PS_UNCALIBRATED:
case PS_PRE_MASTER:
return 1;
default:
break;
}
if (p == c->uds_port && ps != PS_FAULTY) {
return 1;
}
return 0;
}
/* public methods */
UInteger8 clock_class(struct clock *c)
{
return c->dds.clockQuality.clockClass;
}
struct config *clock_config(struct clock *c)
{
return c->config;
}
static int clock_add_port(struct clock *c, int phc_index,
enum timestamp_type timestamping,
struct interface *iface)
{
struct port *p, *piter, *lastp = NULL;
int fd, index;
char key[16];
if (clock_resize_pollfd(c, c->nports + 1)) {
return -1;
}
p = port_open(phc_index, timestamping, ++c->last_port_number, iface, c);
if (!p) {
/* No need to shrink pollfd */
return -1;
}
LIST_FOREACH(piter, &c->ports, list) {
lastp = piter;
}
if (lastp) {
LIST_INSERT_AFTER(lastp, p, list);
} else {
LIST_INSERT_HEAD(&c->ports, p, list);
}
c->nports++;
clock_fda_changed(c);
/* Remember the index to port mapping, for link status tracking. */
fd = sk_interface_fd();
if (fd < 0) {
return -1;
}
index = sk_interface_index(fd, iface->name);
if (index < 0) {
close(fd);
return -1;
}
snprintf(key, sizeof(key), "%d", index);
if (hash_insert(c->index2port, key, p)) {
pr_err("failed to add port with index %d twice!", index);
close(fd);
return -1;
}
close(fd);
return 0;
}
static void clock_remove_port(struct clock *c, struct port *p)
{
/* Do not call clock_resize_pollfd, it's pointless to shrink
* the allocated memory at this point, clock_destroy will free
* it all anyway. This function is usable from other parts of
* the code, but even then we don't mind if pollfd is larger
* than necessary. */
LIST_REMOVE(p, list);
c->nports--;
clock_fda_changed(c);
port_close(p);
}
struct clock *clock_create(enum clock_type type, struct config *config,
const char *phc_device)
{
enum timestamp_type timestamping =
config_get_int(config, NULL, "time_stamping");
int fadj = 0, max_adj = 0, sw_ts = timestamping == TS_SOFTWARE ? 1 : 0;
enum servo_type servo = config_get_int(config, NULL, "clock_servo");
int phc_index, required_modes = 0;
struct clock *c = &the_clock;
struct port *p;
unsigned char oui[OUI_LEN];
char phc[32], *tmp;
struct interface *iface, *udsif = &c->uds_interface;
struct timespec ts;
int sfl;
clock_gettime(CLOCK_REALTIME, &ts);
srandom(ts.tv_sec ^ ts.tv_nsec);
if (c->nports)
clock_destroy(c);
switch (type) {
case CLOCK_TYPE_ORDINARY:
case CLOCK_TYPE_BOUNDARY:
c->type = type;
break;
case CLOCK_TYPE_P2P:
case CLOCK_TYPE_E2E:
case CLOCK_TYPE_MANAGEMENT:
return NULL;
}
/* Initialize the defaultDS. */
c->dds.clockQuality.clockClass =
config_get_int(config, NULL, "clockClass");
c->dds.clockQuality.clockAccuracy =
config_get_int(config, NULL, "clockAccuracy");
c->dds.clockQuality.offsetScaledLogVariance =
config_get_int(config, NULL, "offsetScaledLogVariance");
c->desc.productDescription.max_symbols = 64;
c->desc.revisionData.max_symbols = 32;
c->desc.userDescription.max_symbols = 128;
tmp = config_get_string(config, NULL, "productDescription");
if (count_char(tmp, ';') != 2 ||
static_ptp_text_set(&c->desc.productDescription, tmp)) {
pr_err("invalid productDescription '%s'", tmp);
return NULL;
}
tmp = config_get_string(config, NULL, "revisionData");
if (count_char(tmp, ';') != 2 ||
static_ptp_text_set(&c->desc.revisionData, tmp)) {
pr_err("invalid revisionData '%s'", tmp);
return NULL;
}
tmp = config_get_string(config, NULL, "userDescription");
if (static_ptp_text_set(&c->desc.userDescription, tmp)) {
pr_err("invalid userDescription '%s'", tmp);
return NULL;
}
tmp = config_get_string(config, NULL, "manufacturerIdentity");
if (OUI_LEN != sscanf(tmp, "%hhx:%hhx:%hhx", &oui[0], &oui[1], &oui[2])) {
pr_err("invalid manufacturerIdentity '%s'", tmp);
return NULL;
}
memcpy(c->desc.manufacturerIdentity, oui, OUI_LEN);
c->dds.domainNumber = config_get_int(config, NULL, "domainNumber");
if (config_get_int(config, NULL, "slaveOnly")) {
c->dds.flags |= DDS_SLAVE_ONLY;
}
if (config_get_int(config, NULL, "twoStepFlag")) {
c->dds.flags |= DDS_TWO_STEP_FLAG;
}
c->dds.priority1 = config_get_int(config, NULL, "priority1");
c->dds.priority2 = config_get_int(config, NULL, "priority2");
if (!config_get_int(config, NULL, "gmCapable") &&
c->dds.flags & DDS_SLAVE_ONLY) {
pr_err("Cannot mix 1588 slaveOnly with 802.1AS !gmCapable");
return NULL;
}
if (!config_get_int(config, NULL, "gmCapable") ||
c->dds.flags & DDS_SLAVE_ONLY) {
c->dds.clockQuality.clockClass = 255;
}
if (!(c->dds.flags & DDS_TWO_STEP_FLAG)) {
switch (timestamping) {
case TS_SOFTWARE:
case TS_LEGACY_HW:
pr_err("one step is only possible "
"with hardware time stamping");
return NULL;
case TS_HARDWARE:
timestamping = TS_ONESTEP;
if (config_set_int(config, "time_stamping", TS_ONESTEP))
return NULL;
break;
case TS_ONESTEP:
break;
}
}
/* Check the time stamping mode on each interface. */
switch (timestamping) {
case TS_SOFTWARE:
required_modes |= SOF_TIMESTAMPING_TX_SOFTWARE |
SOF_TIMESTAMPING_RX_SOFTWARE |
SOF_TIMESTAMPING_SOFTWARE;
break;
case TS_LEGACY_HW:
required_modes |= SOF_TIMESTAMPING_TX_HARDWARE |
SOF_TIMESTAMPING_RX_HARDWARE |
SOF_TIMESTAMPING_SYS_HARDWARE;
break;
case TS_HARDWARE:
case TS_ONESTEP:
required_modes |= SOF_TIMESTAMPING_TX_HARDWARE |
SOF_TIMESTAMPING_RX_HARDWARE |
SOF_TIMESTAMPING_RAW_HARDWARE;
break;
}
STAILQ_FOREACH(iface, &config->interfaces, list) {
if (iface->ts_info.valid &&
((iface->ts_info.so_timestamping & required_modes) != required_modes)) {
pr_err("interface '%s' does not support "
"requested timestamping mode", iface->name);
return NULL;
}
}
iface = STAILQ_FIRST(&config->interfaces);
/* determine PHC Clock index */
if (config_get_int(config, NULL, "free_running")) {
phc_index = -1;
} else if (timestamping == TS_SOFTWARE || timestamping == TS_LEGACY_HW) {