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2b15cb3d09
Thanks to roberto for providing pointers to wedge this into HEAD. Approved by: roberto
150 lines
4.5 KiB
C
150 lines
4.5 KiB
C
/*
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* clocktime - compute the NTP date from a day of year, hour, minute
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* and second.
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*/
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#include <config.h>
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#include "ntp_fp.h"
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#include "ntp_unixtime.h"
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#include "ntp_stdlib.h"
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#include "ntp_calendar.h"
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/*
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* We check that the time be within CLOSETIME seconds of the receive
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* time stamp. This is about 4 hours, which hopefully should be wide
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* enough to collect most data, while close enough to keep things from
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* getting confused.
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*/
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#define CLOSETIME (4u*60u*60u)
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/*
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* Since we try to match years, the result of a full search will not
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* change when we are already less than a half year from the receive
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* time stamp. Since the length of a year is variable we use a
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* slightly narrower limit; this might require a full evaluation near
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* the edge, but will make sure we always get the correct result.
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*/
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#define NEARTIME (182u * SECSPERDAY)
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/*
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* local calendar helpers
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*/
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static int32 ntp_to_year(u_int32);
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static u_int32 year_to_ntp(int32);
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/*
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* Take a time spec given as day-of-year, hour, minute and second as
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* well as a GMT offset in hours and convert it to a NTP time stamp in
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* '*ts_ui'. The value will be in the range (rec_ui-0.5yrs) to
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* (rec_ui+0.5yrs). A hint for the current start-of-year will be
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* read from '*yearstart'.
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*
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* On return '*ts_ui' will always the best matching solution, and
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* '*yearstart' will receive the associated start-of-year.
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*
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* The function will tell if the result in 'ts_ui' is in CLOSETIME
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* (+/-4hrs) around the receive time by returning a non-zero value.
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*
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* Note: The function puts no constraints on the value ranges for the
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* time specification, but evaluates the effective seconds in
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* 32-bit arithmetic.
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*/
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int
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clocktime(
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int yday , /* day-of-year */
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int hour , /* hour of day */
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int minute , /* minute of hour */
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int second , /* second of minute */
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int tzoff , /* hours west of GMT */
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u_int32 rec_ui , /* pivot value */
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u_long *yearstart, /* cached start-of-year, should be fixed to u_int32 */
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u_int32 *ts_ui ) /* effective time stamp */
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{
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u_int32 ystt[3]; /* year start */
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u_int32 test[3]; /* result time stamp */
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u_int32 diff[3]; /* abs difference to receive */
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int32 y, tmp, idx, min;
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/*
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* Compute the offset into the year in seconds. Note that
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* this could come out to be a negative number.
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*/
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tmp = ((int32)second +
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SECSPERMIN * ((int32)minute +
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MINSPERHR * ((int32)hour + (int32)tzoff +
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HRSPERDAY * ((int32)yday - 1))));
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/*
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* Based on the cached year start, do a first attempt. Be
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* happy and return if this gets us better than NEARTIME to
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* the receive time stamp. Do this only if the cached year
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* start is not zero, which will not happen after 1900 for the
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* next few thousand years.
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*/
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if (*yearstart) {
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/* -- get time stamp of potential solution */
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test[0] = (u_int32)(*yearstart) + tmp;
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/* -- calc absolute difference to receive time */
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diff[0] = test[0] - rec_ui;
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if (diff[0] >= 0x80000000u)
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diff[0] = ~diff[0] + 1;
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/* -- can't get closer if diff < NEARTIME */
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if (diff[0] < NEARTIME) {
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*ts_ui = test[0];
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return diff[0] < CLOSETIME;
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}
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}
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/*
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* Now the dance begins. Based on the receive time stamp and
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* the seconds offset in 'tmp', we make an educated guess
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* about the year to start with. This takes us on the spot
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* with a fuzz of +/-1 year.
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*
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* We calculate the effective timestamps for the three years
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* around the guess and select the entry with the minimum
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* absolute difference to the receive time stamp.
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*/
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y = ntp_to_year(rec_ui - tmp);
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for (idx = 0; idx < 3; idx++) {
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/* -- get year start of potential solution */
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ystt[idx] = year_to_ntp(y + idx - 1);
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/* -- get time stamp of potential solution */
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test[idx] = ystt[idx] + tmp;
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/* -- calc absolute difference to receive time */
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diff[idx] = test[idx] - rec_ui;
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if (diff[idx] >= 0x80000000u)
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diff[idx] = ~diff[idx] + 1;
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}
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/* -*- assume current year fits best, then search best fit */
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for (min = 1, idx = 0; idx < 3; idx++)
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if (diff[idx] < diff[min])
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min = idx;
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/* -*- store results and update year start */
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*ts_ui = test[min];
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*yearstart = ystt[min];
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/* -*- tell if we could get into CLOSETIME*/
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return diff[min] < CLOSETIME;
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}
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static int32
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ntp_to_year(
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u_int32 ntp)
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{
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vint64 t;
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ntpcal_split s;
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t = ntpcal_ntp_to_ntp(ntp, NULL);
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s = ntpcal_daysplit(&t);
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s = ntpcal_split_eradays(s.hi + DAY_NTP_STARTS - 1, NULL);
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return s.hi + 1;
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}
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static u_int32
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year_to_ntp(
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int32 year)
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{
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u_int32 days;
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days = ntpcal_days_in_years(year-1) - DAY_NTP_STARTS + 1;
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return days * SECSPERDAY;
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}
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