greybus: timesync: Add gb_timesync_frame_time_to_timespec()

This patch adds gb_timesync_to_timespec_by_svc() and
gb_timesync_to_timespec_by_interface() respectively. These routines will
convert from a given FrameTime to a ktime/timespec within an envelope of
about 17 seconds. The purpose of this routine is to enable reporting of a
FrameTime from a Module such as a Camera Module and to allow the AP to
then convert this timestamp into a Linux-native timestamp such as ktime.
This is useful and required in the v4l layer.

At 19.2MHz the accuracy of this conversion is about .3 femtoseconds per
count, which means at a 1 second offset from the reference the cumulative
error is about 1.59 nanoseconds. 1.59 nanoseconds is still less than 1
clock's worth of error @ 19.2MHz where each clock is 52.0833~ nanoseconds.

We're aiming for a maximum error rate of 30 nanoseconds which means at the
clock rate we are running at, the conversion from a FrameTime to a Linux
ktime/timespec can be plus-or-minus about 17 seconds from the reference
FrameTime/ktime pair before the routine will refuse to convert.

A realistic use-case for this routine is envisaged to be

- Greybus message received
- Some processing takes place - taking milliseconds
- Call into this routine is made
- Actual time between event in Module and conversion in AP < 1 second
- Error rate in conversion at 1.59 nanoseconds is less than 1 clock
  @ 19.2MHz

This routine is not designed to allow for conversions for events with
large gaps between the event time and the current reference time for
conversion. Since FrameTime can be a very large integer we cannot convert
an arbitrarily large FrameTime to ktime, the feeling and objective here is
to make an over-provisioned envelope that in practical terms can never be
exceeded by expected use-cases. To convert longer gaps more work would have
to be done but ultimately some limit needs to be imposed and right now 0.3
femotseconds per clock on MSM8994 is both accurate and generous.

Adds:
- timesync.c::gb_timesync_frame_time_to_timespec_by_svc(
						 struct gb_svc *,
						 u64 frame_time,
                                                 struct timespec *ts)
  - gb_svc is a pointer to a standard greybus SVC data structure
  - frame_time is a system FrameTime.
  - ts is an output parameter which represents the converted FrameTime
    as a CLOCK_MONOTONIC timespec value.
  - Returns 0 on success or a negative number indicating the type of
    error on failure.

- timesync.c::gb_timesync_frame_time_to_timespec_by_interface(
						 struct gb_interface *,
						 u64 frame_time,
                                                 struct timespec *ts)
  - gb_svc is a pointer to a standard greybus Interface data structure
  - frame_time is a system FrameTime.
  - ts is an output parameter which represents the converted FrameTime
    as a CLOCK_MONOTONIC timespec value.
  - Returns 0 on success or a negative number indicating the type of
    error on failure.

Signed-off-by: Bryan O'Donoghue <bryan.odonoghue@linaro.org>
Acked-by: Alex Elder <elder@linaro.org>
Signed-off-by: Greg Kroah-Hartman <gregkh@google.com>
This commit is contained in:
Bryan O'Donoghue 2016-06-05 14:03:29 +01:00 committed by Greg Kroah-Hartman
parent 6da7c88972
commit 00fdbae1a9
2 changed files with 247 additions and 25 deletions

View File

@ -7,6 +7,7 @@
* Released under the GPLv2 only.
*/
#include <linux/debugfs.h>
#include <linux/hrtimer.h>
#include "greybus.h"
#include "timesync.h"
#include "greybus_trace.h"
@ -30,9 +31,15 @@
#define GB_TIMESYNC_DELAYED_WORK_LONG msecs_to_jiffies(1000)
#define GB_TIMESYNC_DELAYED_WORK_SHORT msecs_to_jiffies(1)
#define GB_TIMESYNC_MAX_WAIT_SVC msecs_to_jiffies(5000)
#define GB_TIMESYNC_KTIME_UPDATE msecs_to_jiffies(1000)
#define GB_TIMESYNC_MAX_KTIME_CONVERSION 15
/* Reported nanoseconds per clock */
/* Reported nanoseconds/femtoseconds per clock */
static u64 gb_timesync_ns_per_clock;
static u64 gb_timesync_fs_per_clock;
/* Maximum difference we will accept converting FrameTime to ktime */
static u32 gb_timesync_max_ktime_diff;
/* Reported clock rate */
static unsigned long gb_timesync_clock_rate;
@ -46,6 +53,12 @@ static LIST_HEAD(gb_timesync_svc_list);
/* Synchronize parallel contexts accessing a valid timesync_svc pointer */
static DEFINE_MUTEX(gb_timesync_svc_list_mutex);
/* Structure to convert from FrameTime to timespec/ktime */
struct gb_timesync_frame_time_data {
u64 frame_time;
struct timespec ts;
};
struct gb_timesync_svc {
struct list_head list;
struct list_head interface_list;
@ -59,10 +72,12 @@ struct gb_timesync_svc {
struct workqueue_struct *work_queue;
wait_queue_head_t wait_queue;
struct delayed_work delayed_work;
struct timer_list ktime_timer;
/* The current local FrameTime */
u64 frame_time_offset;
u64 strobe_time[GB_TIMESYNC_MAX_STROBES];
struct gb_timesync_frame_time_data strobe_data[GB_TIMESYNC_MAX_STROBES];
struct gb_timesync_frame_time_data ktime_data;
/* The SVC FrameTime and relative AP FrameTime @ last TIMESYNC_PING */
u64 svc_ping_frame_time;
@ -101,6 +116,8 @@ enum gb_timesync_state {
GB_TIMESYNC_STATE_ACTIVE = 6,
};
static void gb_timesync_ktime_timer_fn(unsigned long data);
static u64 gb_timesync_adjust_count(struct gb_timesync_svc *timesync_svc,
u64 counts)
{
@ -220,6 +237,17 @@ static void gb_timesync_adjust_to_svc(struct gb_timesync_svc *svc,
}
}
/*
* Associate a FrameTime with a ktime timestamp represented as struct timespec
* Requires the calling context to hold timesync_svc->mutex
*/
static void gb_timesync_store_ktime(struct gb_timesync_svc *timesync_svc,
struct timespec ts, u64 frame_time)
{
timesync_svc->ktime_data.ts = ts;
timesync_svc->ktime_data.frame_time = frame_time;
}
/*
* Find the two pulses that best-match our expected inter-strobe gap and
* then calculate the difference between the SVC time at the second pulse
@ -229,24 +257,32 @@ static void gb_timesync_collate_frame_time(struct gb_timesync_svc *timesync_svc,
u64 *frame_time)
{
int i = 0;
u64 delta;
u64 delta, ap_frame_time;
u64 strobe_delay_ns = GB_TIMESYNC_STROBE_DELAY_US * NSEC_PER_USEC;
u64 least = 0;
for (i = 1; i < GB_TIMESYNC_MAX_STROBES; i++) {
delta = timesync_svc->strobe_time[i] -
timesync_svc->strobe_time[i - 1];
delta = timesync_svc->strobe_data[i].frame_time -
timesync_svc->strobe_data[i - 1].frame_time;
delta *= gb_timesync_ns_per_clock;
delta = gb_timesync_diff(delta, strobe_delay_ns);
if (!least || delta < least) {
least = delta;
gb_timesync_adjust_to_svc(timesync_svc, frame_time[i],
timesync_svc->strobe_time[i]);
timesync_svc->strobe_data[i].frame_time);
ap_frame_time = timesync_svc->strobe_data[i].frame_time;
ap_frame_time = gb_timesync_adjust_count(timesync_svc,
ap_frame_time);
gb_timesync_store_ktime(timesync_svc,
timesync_svc->strobe_data[i].ts,
ap_frame_time);
pr_debug("adjust %s local %llu svc %llu delta %llu\n",
timesync_svc->offset_down ? "down" : "up",
timesync_svc->strobe_time[i], frame_time[i],
delta);
timesync_svc->strobe_data[i].frame_time,
frame_time[i], delta);
}
}
}
@ -415,6 +451,119 @@ static void gb_timesync_authoritative(struct gb_timesync_svc *timesync_svc)
gb_timesync_set_state_atomic(timesync_svc, GB_TIMESYNC_STATE_PING);
}
static int __gb_timesync_get_status(struct gb_timesync_svc *timesync_svc)
{
int ret = -EINVAL;
switch (timesync_svc->state) {
case GB_TIMESYNC_STATE_INVALID:
case GB_TIMESYNC_STATE_INACTIVE:
ret = -ENODEV;
break;
case GB_TIMESYNC_STATE_INIT:
case GB_TIMESYNC_STATE_WAIT_SVC:
case GB_TIMESYNC_STATE_AUTHORITATIVE:
case GB_TIMESYNC_STATE_PING:
ret = -EAGAIN;
break;
case GB_TIMESYNC_STATE_ACTIVE:
ret = 0;
break;
}
return ret;
}
/*
* This routine takes a FrameTime and derives the difference with-respect
* to a reference FrameTime/ktime pair. It then returns the calculated
* ktime based on the difference between the supplied FrameTime and
* the reference FrameTime.
*
* The time difference is calculated to six decimal places. Taking 19.2MHz
* as an example this means we have 52.083333~ nanoseconds per clock or
* 52083333~ femtoseconds per clock.
*
* Naively taking the count difference and converting to
* seconds/nanoseconds would quickly see the 0.0833 component produce
* noticeable errors. For example a time difference of one second would
* loose 19200000 * 0.08333x nanoseconds or 1.59 seconds.
*
* In contrast calculating in femtoseconds the same example of 19200000 *
* 0.000000083333x nanoseconds per count of error is just 1.59 nanoseconds!
*
* Continuing the example of 19.2 MHz we cap the maximum error difference
* at a worst-case 0.3 microseconds over a potential calculation window of
* abount 15 seconds, meaning you can convert a FrameTime that is <= 15
* seconds older/younger than the reference time with a maximum error of
* 0.2385 useconds. Note 19.2MHz is an example frequency not a requirement.
*/
static int gb_timesync_to_timespec(struct gb_timesync_svc *timesync_svc,
u64 frame_time, struct timespec *ts)
{
unsigned long flags;
u64 delta_fs, counts;
u32 sec, nsec;
bool add;
int ret = 0;
mutex_lock(&timesync_svc->mutex);
spin_lock_irqsave(&timesync_svc->spinlock, flags);
ret = __gb_timesync_get_status(timesync_svc);
if (ret)
goto done;
/* Support calculating ktime upwards or downwards from the reference */
if (frame_time < timesync_svc->ktime_data.frame_time) {
add = false;
counts = timesync_svc->ktime_data.frame_time - frame_time;
} else {
add = true;
counts = frame_time - timesync_svc->ktime_data.frame_time;
}
/* Enforce the .23 of a usecond boundary @ 19.2MHz */
if (counts > gb_timesync_max_ktime_diff) {
ret = -EINVAL;
goto done;
}
/* Determine the time difference in femtoseconds */
delta_fs = counts * gb_timesync_fs_per_clock;
sec = delta_fs / FSEC_PER_SEC;
nsec = (delta_fs % FSEC_PER_SEC) / 1000000UL;
if (add) {
/* Add the calculated offset - overflow nanoseconds upwards */
ts->tv_sec = timesync_svc->ktime_data.ts.tv_sec + sec;
ts->tv_nsec = timesync_svc->ktime_data.ts.tv_nsec + nsec;
if (ts->tv_nsec >= NSEC_PER_SEC) {
ts->tv_sec++;
ts->tv_nsec -= NSEC_PER_SEC;
}
} else {
/* Subtract the difference over/underflow as necessary */
if (nsec > timesync_svc->ktime_data.ts.tv_nsec) {
sec++;
nsec = nsec + timesync_svc->ktime_data.ts.tv_nsec;
nsec %= NSEC_PER_SEC;
} else {
nsec = timesync_svc->ktime_data.ts.tv_nsec - nsec;
}
/* Cannot return a negative second value */
if (sec > timesync_svc->ktime_data.ts.tv_sec) {
ret = -EINVAL;
goto done;
}
ts->tv_sec = timesync_svc->ktime_data.ts.tv_sec - sec;
ts->tv_nsec = nsec;
}
done:
spin_unlock_irqrestore(&timesync_svc->spinlock, flags);
mutex_unlock(&timesync_svc->mutex);
return ret;
}
static size_t gb_timesync_log_frame_time(struct gb_timesync_svc *timesync_svc,
char *buf, size_t buflen)
{
@ -616,21 +765,7 @@ static int __gb_timesync_schedule_synchronous(
mutex_lock(&timesync_svc->mutex);
spin_lock_irqsave(&timesync_svc->spinlock, flags);
switch (timesync_svc->state) {
case GB_TIMESYNC_STATE_INVALID:
case GB_TIMESYNC_STATE_INACTIVE:
ret = -ENODEV;
break;
case GB_TIMESYNC_STATE_INIT:
case GB_TIMESYNC_STATE_WAIT_SVC:
case GB_TIMESYNC_STATE_AUTHORITATIVE:
case GB_TIMESYNC_STATE_PING:
ret = -EAGAIN;
break;
case GB_TIMESYNC_STATE_ACTIVE:
ret = 0;
break;
}
ret = __gb_timesync_get_status(timesync_svc);
spin_unlock_irqrestore(&timesync_svc->spinlock, flags);
mutex_unlock(&timesync_svc->mutex);
@ -810,7 +945,15 @@ int gb_timesync_svc_add(struct gb_svc *svc)
debugfs_remove(timesync_svc->frame_time_dentry);
destroy_workqueue(timesync_svc->work_queue);
kfree(timesync_svc);
goto done;
}
init_timer(&timesync_svc->ktime_timer);
timesync_svc->ktime_timer.function = gb_timesync_ktime_timer_fn;
timesync_svc->ktime_timer.expires = jiffies + GB_TIMESYNC_KTIME_UPDATE;
timesync_svc->ktime_timer.data = (unsigned long)timesync_svc;
add_timer(&timesync_svc->ktime_timer);
done:
mutex_unlock(&gb_timesync_svc_list_mutex);
return ret;
}
@ -830,6 +973,7 @@ void gb_timesync_svc_remove(struct gb_svc *svc)
mutex_lock(&timesync_svc->mutex);
gb_timesync_teardown(timesync_svc);
del_timer_sync(&timesync_svc->ktime_timer);
gb_timesync_hd_remove(timesync_svc, svc->hd);
list_for_each_entry_safe(timesync_interface, next,
@ -971,12 +1115,77 @@ done:
}
EXPORT_SYMBOL_GPL(gb_timesync_get_frame_time_by_svc);
/* Incrementally updates the conversion base from FrameTime to ktime */
static void gb_timesync_ktime_timer_fn(unsigned long data)
{
struct gb_timesync_svc *timesync_svc =
(struct gb_timesync_svc *)data;
unsigned long flags;
u64 frame_time;
struct timespec ts;
spin_lock_irqsave(&timesync_svc->spinlock, flags);
if (timesync_svc->state != GB_TIMESYNC_STATE_ACTIVE)
goto done;
ktime_get_ts(&ts);
frame_time = __gb_timesync_get_frame_time(timesync_svc);
gb_timesync_store_ktime(timesync_svc, ts, frame_time);
done:
spin_unlock_irqrestore(&timesync_svc->spinlock, flags);
mod_timer(&timesync_svc->ktime_timer,
jiffies + GB_TIMESYNC_KTIME_UPDATE);
}
int gb_timesync_to_timespec_by_svc(struct gb_svc *svc, u64 frame_time,
struct timespec *ts)
{
struct gb_timesync_svc *timesync_svc;
int ret = 0;
mutex_lock(&gb_timesync_svc_list_mutex);
timesync_svc = gb_timesync_find_timesync_svc(svc->hd);
if (!timesync_svc) {
ret = -ENODEV;
goto done;
}
ret = gb_timesync_to_timespec(timesync_svc, frame_time, ts);
done:
mutex_unlock(&gb_timesync_svc_list_mutex);
return ret;
}
EXPORT_SYMBOL_GPL(gb_timesync_to_timespec_by_svc);
int gb_timesync_to_timespec_by_interface(struct gb_interface *interface,
u64 frame_time, struct timespec *ts)
{
struct gb_timesync_svc *timesync_svc;
int ret = 0;
mutex_lock(&gb_timesync_svc_list_mutex);
timesync_svc = gb_timesync_find_timesync_svc(interface->hd);
if (!timesync_svc) {
ret = -ENODEV;
goto done;
}
ret = gb_timesync_to_timespec(timesync_svc, frame_time, ts);
done:
mutex_unlock(&gb_timesync_svc_list_mutex);
return ret;
}
EXPORT_SYMBOL_GPL(gb_timesync_to_timespec_by_interface);
void gb_timesync_irq(struct gb_timesync_svc *timesync_svc)
{
unsigned long flags;
u64 strobe_time;
bool strobe_is_ping = true;
struct timespec ts;
ktime_get_ts(&ts);
strobe_time = __gb_timesync_get_frame_time(timesync_svc);
spin_lock_irqsave(&timesync_svc->spinlock, flags);
@ -990,7 +1199,8 @@ void gb_timesync_irq(struct gb_timesync_svc *timesync_svc)
goto done_nolog;
}
timesync_svc->strobe_time[timesync_svc->strobe] = strobe_time;
timesync_svc->strobe_data[timesync_svc->strobe].frame_time = strobe_time;
timesync_svc->strobe_data[timesync_svc->strobe].ts = ts;
if (++timesync_svc->strobe == GB_TIMESYNC_MAX_STROBES) {
gb_timesync_set_state(timesync_svc,
@ -1016,9 +1226,17 @@ int __init gb_timesync_init(void)
}
gb_timesync_clock_rate = gb_timesync_platform_get_clock_rate();
/* Calculate nanoseconds and femtoseconds per clock */
gb_timesync_fs_per_clock = FSEC_PER_SEC / gb_timesync_clock_rate;
gb_timesync_ns_per_clock = NSEC_PER_SEC / gb_timesync_clock_rate;
pr_info("Time-Sync timer frequency %lu Hz\n", gb_timesync_clock_rate);
/* Calculate the maximum number of clocks we will convert to ktime */
gb_timesync_max_ktime_diff =
GB_TIMESYNC_MAX_KTIME_CONVERSION * gb_timesync_clock_rate;
pr_info("Time-Sync @ %lu Hz max ktime conversion +/- %d seconds\n",
gb_timesync_clock_rate, GB_TIMESYNC_MAX_KTIME_CONVERSION);
return 0;
}

View File

@ -31,6 +31,10 @@ void gb_timesync_svc_remove(struct gb_svc *svc);
u64 gb_timesync_get_frame_time_by_interface(struct gb_interface *interface);
u64 gb_timesync_get_frame_time_by_svc(struct gb_svc *svc);
int gb_timesync_to_timespec_by_svc(struct gb_svc *svc, u64 frame_time,
struct timespec *ts);
int gb_timesync_to_timespec_by_interface(struct gb_interface *interface,
u64 frame_time, struct timespec *ts);
int gb_timesync_schedule_synchronous(struct gb_interface *intf);
void gb_timesync_schedule_asynchronous(struct gb_interface *intf);