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HardenedBSD/contrib/ntp/include/timespecops.h
Cy Schubert 2d4e511ca2 MFV r358616: 
Update ntp-4.2.8p13 --> 4.2.8p14.

The advisory can be found at:
http://support.ntp.org/bin/view/Main/SecurityNotice#\
March_2020_ntp_4_2_8p14_NTP_Rele

No CVEs have been documented yet.

MFC after:	now
Security:	http://support.ntp.org/bin/view/Main/NtpBug3610
		http://support.ntp.org/bin/view/Main/NtpBug3596
		http://support.ntp.org/bin/view/Main/NtpBug3592
2020-03-04 21:45:12 +00:00

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/*
* timespecops.h -- calculations on 'struct timespec' values
*
* Written by Juergen Perlinger (perlinger@ntp.org) for the NTP project.
* The contents of 'html/copyright.html' apply.
*
* Rationale
* ---------
*
* Doing basic arithmetic on a 'struct timespec' is not exceedingly
* hard, but it requires tedious and repetitive code to keep the result
* normalised. We consider a timespec normalised when the nanosecond
* fraction is in the interval [0 .. 10^9[ ; there are multiple value
* pairs of seconds and nanoseconds that denote the same time interval,
* but the normalised representation is unique. No two different
* intervals can have the same normalised representation.
*
* Another topic is the representation of negative time intervals.
* There's more than one way to this, since both the seconds and the
* nanoseconds of a timespec are signed values. IMHO, the easiest way is
* to use a complement representation where the nanoseconds are still
* normalised, no matter what the sign of the seconds value. This makes
* normalisation easier, since the sign of the integer part is
* irrelevant, and it removes several sign decision cases during the
* calculations.
*
* As long as no signed integer overflow can occur with the nanosecond
* part of the operands, all operations work as expected and produce a
* normalised result.
*
* The exception to this are functions fix a '_fast' suffix, which do no
* normalisation on input data and therefore expect the input data to be
* normalised.
*
* Input and output operands may overlap; all input is consumed before
* the output is written to.
*/
#ifndef TIMESPECOPS_H
#define TIMESPECOPS_H
#include <sys/types.h>
#include <stdio.h>
#include <math.h>
#include "ntp.h"
#include "timetoa.h"
/* nanoseconds per second */
#define NANOSECONDS 1000000000
/* predicate: returns TRUE if the nanoseconds are in nominal range */
#define timespec_isnormal(x) \
((x)->tv_nsec >= 0 && (x)->tv_nsec < NANOSECONDS)
/* predicate: returns TRUE if the nanoseconds are out-of-bounds */
#define timespec_isdenormal(x) (!timespec_isnormal(x))
/* make sure nanoseconds are in nominal range */
extern struct timespec normalize_tspec(struct timespec x);
/* x = a + b */
static inline struct timespec
add_tspec(
struct timespec a,
struct timespec b
)
{
struct timespec x;
x = a;
x.tv_sec += b.tv_sec;
x.tv_nsec += b.tv_nsec;
return normalize_tspec(x);
}
/* x = a + b, b is fraction only */
static inline struct timespec
add_tspec_ns(
struct timespec a,
long b
)
{
struct timespec x;
x = a;
x.tv_nsec += b;
return normalize_tspec(x);
}
/* x = a - b */
static inline struct timespec
sub_tspec(
struct timespec a,
struct timespec b
)
{
struct timespec x;
x = a;
x.tv_sec -= b.tv_sec;
x.tv_nsec -= b.tv_nsec;
return normalize_tspec(x);
}
/* x = a - b, b is fraction only */
static inline struct timespec
sub_tspec_ns(
struct timespec a,
long b
)
{
struct timespec x;
x = a;
x.tv_nsec -= b;
return normalize_tspec(x);
}
/* x = -a */
static inline struct timespec
neg_tspec(
struct timespec a
)
{
struct timespec x;
x.tv_sec = -a.tv_sec;
x.tv_nsec = -a.tv_nsec;
return normalize_tspec(x);
}
/* x = abs(a) */
struct timespec abs_tspec(struct timespec a);
/*
* compare previously-normalised a and b
* return 1 / 0 / -1 if a < / == / > b
*/
extern int cmp_tspec(struct timespec a, struct timespec b);
/*
* compare possibly-denormal a and b
* return 1 / 0 / -1 if a < / == / > b
*/
static inline int
cmp_tspec_denorm(
struct timespec a,
struct timespec b
)
{
return cmp_tspec(normalize_tspec(a), normalize_tspec(b));
}
/*
* test previously-normalised a
* return 1 / 0 / -1 if a < / == / > 0
*/
extern int test_tspec(struct timespec a);
/*
* test possibly-denormal a
* return 1 / 0 / -1 if a < / == / > 0
*/
static inline int
test_tspec_denorm(
struct timespec a
)
{
return test_tspec(normalize_tspec(a));
}
/* return LIB buffer ptr to string rep */
static inline const char *
tspectoa(
struct timespec x
)
{
return format_time_fraction(x.tv_sec, x.tv_nsec, 9);
}
/*
* convert to l_fp type, relative and absolute
*/
/* convert from timespec duration to l_fp duration */
extern l_fp tspec_intv_to_lfp(struct timespec x);
/* x must be UN*X epoch, output will be in NTP epoch */
static inline l_fp
tspec_stamp_to_lfp(
struct timespec x
)
{
l_fp y;
y = tspec_intv_to_lfp(x);
y.l_ui += JAN_1970;
return y;
}
/* convert from l_fp type, relative signed/unsigned and absolute */
extern struct timespec lfp_intv_to_tspec(l_fp x);
extern struct timespec lfp_uintv_to_tspec(l_fp x);
/*
* absolute (timestamp) conversion. Input is time in NTP epoch, output
* is in UN*X epoch. The NTP time stamp will be expanded around the
* pivot time *p or the current time, if p is NULL.
*/
extern struct timespec lfp_stamp_to_tspec(l_fp x, const time_t *pivot);
#endif /* TIMESPECOPS_H */
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