tmp_suning_uos_patched/include/linux/clocksource.h
john stultz 5eb6d20533 [PATCH] Time: Use clocksource abstraction for NTP adjustments
Instead of incrementing xtime by tick_nsec + ntp adjustments, use the
clocksource abstraction to increment and scale time.  Using the clocksource
abstraction allows other clocksources to be used consistently in the face of
late or lost ticks, while preserving the existing behavior via the jiffies
clocksource.

This removes the need to keep time_phase adjustments as we just use the
current_tick_length() function as the NTP interface and accumulate time using
shifted nanoseconds.

The basics of this design was by Roman Zippel, however it is my own
interpretation and implementation, so the credit should go to him and the
blame to me.

Signed-off-by: John Stultz <johnstul@us.ibm.com>
Signed-off-by: Andrew Morton <akpm@osdl.org>
Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2006-06-26 09:58:20 -07:00

279 lines
8.0 KiB
C

/* linux/include/linux/clocksource.h
*
* This file contains the structure definitions for clocksources.
*
* If you are not a clocksource, or timekeeping code, you should
* not be including this file!
*/
#ifndef _LINUX_CLOCKSOURCE_H
#define _LINUX_CLOCKSOURCE_H
#include <linux/types.h>
#include <linux/timex.h>
#include <linux/time.h>
#include <linux/list.h>
#include <asm/div64.h>
#include <asm/io.h>
/* clocksource cycle base type */
typedef u64 cycle_t;
/**
* struct clocksource - hardware abstraction for a free running counter
* Provides mostly state-free accessors to the underlying hardware.
*
* @name: ptr to clocksource name
* @list: list head for registration
* @rating: rating value for selection (higher is better)
* To avoid rating inflation the following
* list should give you a guide as to how
* to assign your clocksource a rating
* 1-99: Unfit for real use
* Only available for bootup and testing purposes.
* 100-199: Base level usability.
* Functional for real use, but not desired.
* 200-299: Good.
* A correct and usable clocksource.
* 300-399: Desired.
* A reasonably fast and accurate clocksource.
* 400-499: Perfect
* The ideal clocksource. A must-use where
* available.
* @read: returns a cycle value
* @mask: bitmask for two's complement
* subtraction of non 64 bit counters
* @mult: cycle to nanosecond multiplier
* @shift: cycle to nanosecond divisor (power of two)
* @update_callback: called when safe to alter clocksource values
* @is_continuous: defines if clocksource is free-running.
* @interval_cycles: Used internally by timekeeping core, please ignore.
* @interval_snsecs: Used internally by timekeeping core, please ignore.
*/
struct clocksource {
char *name;
struct list_head list;
int rating;
cycle_t (*read)(void);
cycle_t mask;
u32 mult;
u32 shift;
int (*update_callback)(void);
int is_continuous;
/* timekeeping specific data, ignore */
cycle_t interval_cycles;
u64 interval_snsecs;
};
/**
* clocksource_khz2mult - calculates mult from khz and shift
* @khz: Clocksource frequency in KHz
* @shift_constant: Clocksource shift factor
*
* Helper functions that converts a khz counter frequency to a timsource
* multiplier, given the clocksource shift value
*/
static inline u32 clocksource_khz2mult(u32 khz, u32 shift_constant)
{
/* khz = cyc/(Million ns)
* mult/2^shift = ns/cyc
* mult = ns/cyc * 2^shift
* mult = 1Million/khz * 2^shift
* mult = 1000000 * 2^shift / khz
* mult = (1000000<<shift) / khz
*/
u64 tmp = ((u64)1000000) << shift_constant;
tmp += khz/2; /* round for do_div */
do_div(tmp, khz);
return (u32)tmp;
}
/**
* clocksource_hz2mult - calculates mult from hz and shift
* @hz: Clocksource frequency in Hz
* @shift_constant: Clocksource shift factor
*
* Helper functions that converts a hz counter
* frequency to a timsource multiplier, given the
* clocksource shift value
*/
static inline u32 clocksource_hz2mult(u32 hz, u32 shift_constant)
{
/* hz = cyc/(Billion ns)
* mult/2^shift = ns/cyc
* mult = ns/cyc * 2^shift
* mult = 1Billion/hz * 2^shift
* mult = 1000000000 * 2^shift / hz
* mult = (1000000000<<shift) / hz
*/
u64 tmp = ((u64)1000000000) << shift_constant;
tmp += hz/2; /* round for do_div */
do_div(tmp, hz);
return (u32)tmp;
}
/**
* read_clocksource: - Access the clocksource's current cycle value
* @cs: pointer to clocksource being read
*
* Uses the clocksource to return the current cycle_t value
*/
static inline cycle_t read_clocksource(struct clocksource *cs)
{
return cs->read();
}
/**
* cyc2ns - converts clocksource cycles to nanoseconds
* @cs: Pointer to clocksource
* @cycles: Cycles
*
* Uses the clocksource and ntp ajdustment to convert cycle_ts to nanoseconds.
*
* XXX - This could use some mult_lxl_ll() asm optimization
*/
static inline s64 cyc2ns(struct clocksource *cs, cycle_t cycles)
{
u64 ret = (u64)cycles;
ret = (ret * cs->mult) >> cs->shift;
return ret;
}
/**
* calculate_clocksource_interval - Calculates a clocksource interval struct
*
* @c: Pointer to clocksource.
* @length_nsec: Desired interval length in nanoseconds.
*
* Calculates a fixed cycle/nsec interval for a given clocksource/adjustment
* pair and interval request.
*
* Unless you're the timekeeping code, you should not be using this!
*/
static inline void calculate_clocksource_interval(struct clocksource *c,
unsigned long length_nsec)
{
u64 tmp;
/* XXX - All of this could use a whole lot of optimization */
tmp = length_nsec;
tmp <<= c->shift;
tmp += c->mult/2;
do_div(tmp, c->mult);
c->interval_cycles = (cycle_t)tmp;
if(c->interval_cycles == 0)
c->interval_cycles = 1;
c->interval_snsecs = (u64)c->interval_cycles * c->mult;
}
/**
* error_aproximation - calculates an error adjustment for a given error
*
* @error: Error value (unsigned)
* @unit: Adjustment unit
*
* For a given error value, this function takes the adjustment unit
* and uses binary approximation to return a power of two adjustment value.
*
* This function is only for use by the the make_ntp_adj() function
* and you must hold a write on the xtime_lock when calling.
*/
static inline int error_aproximation(u64 error, u64 unit)
{
static int saved_adj = 0;
u64 adjusted_unit = unit << saved_adj;
if (error > (adjusted_unit * 2)) {
/* large error, so increment the adjustment factor */
saved_adj++;
} else if (error > adjusted_unit) {
/* just right, don't touch it */
} else if (saved_adj) {
/* small error, so drop the adjustment factor */
saved_adj--;
return 0;
}
return saved_adj;
}
/**
* make_ntp_adj - Adjusts the specified clocksource for a given error
*
* @clock: Pointer to clock to be adjusted
* @cycles_delta: Current unacounted cycle delta
* @error: Pointer to current error value
*
* Returns clock shifted nanosecond adjustment to be applied against
* the accumulated time value (ie: xtime).
*
* If the error value is large enough, this function calulates the
* (power of two) adjustment value, and adjusts the clock's mult and
* interval_snsecs values accordingly.
*
* However, since there may be some unaccumulated cycles, to avoid
* time inconsistencies we must adjust the accumulation value
* accordingly.
*
* This is not very intuitive, so the following proof should help:
* The basic timeofday algorithm: base + cycle * mult
* Thus:
* new_base + cycle * new_mult = old_base + cycle * old_mult
* new_base = old_base + cycle * old_mult - cycle * new_mult
* new_base = old_base + cycle * (old_mult - new_mult)
* new_base - old_base = cycle * (old_mult - new_mult)
* base_delta = cycle * (old_mult - new_mult)
* base_delta = cycle * (mult_delta)
*
* Where mult_delta is the adjustment value made to mult
*
*/
static inline s64 make_ntp_adj(struct clocksource *clock,
cycles_t cycles_delta, s64* error)
{
s64 ret = 0;
if (*error > ((s64)clock->interval_cycles+1)/2) {
/* calculate adjustment value */
int adjustment = error_aproximation(*error,
clock->interval_cycles);
/* adjust clock */
clock->mult += 1 << adjustment;
clock->interval_snsecs += clock->interval_cycles << adjustment;
/* adjust the base and error for the adjustment */
ret = -(cycles_delta << adjustment);
*error -= clock->interval_cycles << adjustment;
/* XXX adj error for cycle_delta offset? */
} else if ((-(*error)) > ((s64)clock->interval_cycles+1)/2) {
/* calculate adjustment value */
int adjustment = error_aproximation(-(*error),
clock->interval_cycles);
/* adjust clock */
clock->mult -= 1 << adjustment;
clock->interval_snsecs -= clock->interval_cycles << adjustment;
/* adjust the base and error for the adjustment */
ret = cycles_delta << adjustment;
*error += clock->interval_cycles << adjustment;
/* XXX adj error for cycle_delta offset? */
}
return ret;
}
/* used to install a new clocksource */
int register_clocksource(struct clocksource*);
void reselect_clocksource(void);
struct clocksource* get_next_clocksource(void);
#endif /* _LINUX_CLOCKSOURCE_H */