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/*
* lib/crypto/os/c_ustime.c
*
* Copyright 1990,1991 by the Massachusetts Institute of Technology.
* All Rights Reserved.
*
* Export of this software from the United States of America may
* require a specific license from the United States Government.
* It is the responsibility of any person or organization contemplating
* export to obtain such a license before exporting.
*
* WITHIN THAT CONSTRAINT, permission to use, copy, modify, and
* distribute this software and its documentation for any purpose and
* without fee is hereby granted, provided that the above copyright
* notice appear in all copies and that both that copyright notice and
* this permission notice appear in supporting documentation, and that
* the name of M.I.T. not be used in advertising or publicity pertaining
* to distribution of the software without specific, written prior
* permission. Furthermore if you modify this software you must label
* your software as modified software and not distribute it in such a
* fashion that it might be confused with the original M.I.T. software.
* M.I.T. makes no representations about the suitability of
* this software for any purpose. It is provided "as is" without express
* or implied warranty.
*
*
* krb5_mstimeofday for BSD 4.3
*/
#define NEED_SOCKETS
#include "k5-int.h"
#ifdef macintosh
/* We're a Macintosh -- do Mac time things. */
/*
* This code is derived from kerberos/src/lib/des/mac_time.c from
* the Cygnus Support release of Kerberos V4:
*
* mac_time.c
* (Originally time_stuff.c)
* Copyright 1989 by the Massachusetts Institute of Technology.
* Macintosh ooperating system interface for Kerberos.
*/
#include <ConditionalMacros.h>
#include <script.h> /* Defines MachineLocation, used by getTimeZoneOffset */
#include <ToolUtils.h> /* Defines BitTst(), called by getTimeZoneOffset() */
#include <OSUtils.h> /* Defines GetDateTime */
#include <DriverServices.h> /* Nanosecond timing */
#include <CodeFragments.h> /* Check for presence of UpTime */
#include <Math64.h> /* 64-bit integer math */
/* Mac Cincludes */
#include <string.h>
#include <stddef.h>
static krb5_int32 last_sec = 0, last_usec = 0;
/* Check for availability of microseconds or better timer */
Boolean HaveAccurateTime ();
/* Convert nanoseconds to date and time */
void AbsoluteToSecsNanosecs (
AbsoluteTime eventTime, /* Value to convert */
UInt32 *eventSeconds, /* Result goes here */
UInt32 *residualNanoseconds /* Fractional second */
);
/*
* The Unix epoch is 1/1/70, the Mac epoch is 1/1/04.
*
* 70 - 4 = 66 year differential
*
* Thus the offset is:
*
* (66 yrs) * (365 days/yr) * (24 hours/day) * (60 mins/hour) * (60 secs/min)
* plus
* (17 leap days) * (24 hours/day) * (60 mins/hour) * (60 secs/min)
*
* Don't forget the offset from GMT.
*/
/* returns the offset in hours between the mac local time and the GMT */
/* unsigned krb5_int32 */
krb5_int32
getTimeZoneOffset()
{
MachineLocation macLocation;
long gmtDelta;
macLocation.u.gmtDelta=0L;
ReadLocation(&macLocation);
gmtDelta=macLocation.u.gmtDelta & 0x00FFFFFF;
if (BitTst((void *)&gmtDelta,23L))
gmtDelta |= 0xFF000000;
gmtDelta /= 3600L;
return(gmtDelta);
}
/* Returns the GMT in seconds (and fake microseconds) using the Unix epoch */
/*
* Note that unix timers are guaranteed that consecutive calls to timing functions will
* always return monotonically increasing values for time; even if called within one microsecond,
* they must increase from one call to another. We must preserve this property in this code,
* even though Mac UpTime does not make such guarantees... (actually it does, but it measures in
* units that can be finer than 1 microsecond, so conversion can cause repeat microsecond values
*/
krb5_error_code
krb5_crypto_us_timeofday(seconds, microseconds)
krb5_int32 *seconds, *microseconds;
{
krb5_int32 sec, usec;
time_t the_time;
GetDateTime (&the_time);
sec = the_time -
((66 * 365 * 24 * 60 * 60) + (17 * 24 * 60 * 60) +
(getTimeZoneOffset() * 60 * 60));
#if TARGET_CPU_PPC /* Only PPC has accurate time */
if (HaveAccurateTime ()) { /* Does hardware support accurate time? */
AbsoluteTime absoluteTime;
UInt32 nanoseconds;
absoluteTime = UpTime ();
AbsoluteToSecsNanosecs (absoluteTime, &sec, &nanoseconds);
usec = nanoseconds / 1000;
} else
#endif /* TARGET_CPU_PPC */
{
GetDateTime (&sec);
usec = 0;
}
/* Fix secs to UNIX epoch */
sec -= ((66 * 365 * 24 * 60 * 60) + (17 * 24 * 60 * 60) +
(getTimeZoneOffset() * 60 * 60));
/* Make sure that we are _not_ repeating */
if (sec < last_sec) { /* Seconds should be at least equal to last seconds */
sec = last_sec;
}
if (sec == last_sec) { /* Same seconds as last time? */
if (usec <= last_usec) { /* Yep, microseconds must be bigger than last time*/
usec = last_usec + 1;
}
if (usec >= 1000000) { /* handle 1e6 wraparound */
sec++;
usec = 0;
}
}
last_sec = sec; /* Remember for next time */
last_usec = usec;
*seconds = sec;
*microseconds = usec; /* Return the values */
return 0;
}
/* Check if we have microsecond or better timer */
Boolean HaveAccurateTime ()
{
static Boolean alreadyChecked = false;
static haveAccurateTime = false;
if (!alreadyChecked) {
alreadyChecked = true;
haveAccurateTime = false;
#if TARGET_CPU_PPC
if ((Ptr) UpTime != (Ptr) kUnresolvedCFragSymbolAddress) {
UInt32 minAbsoluteTimeDelta;
UInt32 theAbsoluteTimeToNanosecondNumerator;
UInt32 theAbsoluteTimeToNanosecondDenominator;
UInt32 theProcessorToAbsoluteTimeNumerator;
UInt32 theProcessorToAbsoluteTimeDenominator;
GetTimeBaseInfo (
&minAbsoluteTimeDelta,
&theAbsoluteTimeToNanosecondNumerator,
&theAbsoluteTimeToNanosecondDenominator,
&theProcessorToAbsoluteTimeNumerator,
&theProcessorToAbsoluteTimeDenominator);
/* minAbsoluteTimeDelta is the period in which Uptime is updated, in absolute time */
/* We convert it to nanoseconds and compare it with .5 microsecond */
if (minAbsoluteTimeDelta * theAbsoluteTimeToNanosecondNumerator <
500 * theAbsoluteTimeToNanosecondDenominator) {
haveAccurateTime = true;
}
}
#endif /* TARGET_CPU_PPC */
}
return haveAccurateTime;
}
/* Convert nanoseconds to date and time */
void AbsoluteToSecsNanosecs (
AbsoluteTime eventTime, /* Value to convert */
UInt32 *eventSeconds, /* Result goes here */
UInt32 *residualNanoseconds /* Fractional second */
)
{
UInt64 eventNanoseconds;
UInt64 eventSeconds64;
static const UInt64 kTenE9 = U64SetU (1000000000);
static UInt64 gNanosecondsAtStart = U64SetU (0);
/*
* If this is the first call, compute the offset between
* GetDateTime and UpTime.
*/
if (U64Compare (gNanosecondsAtStart, U64SetU (0)) == 0) {
UInt32 secondsAtStart;
AbsoluteTime absoluteTimeAtStart;
UInt64 upTimeAtStart;
UInt64 nanosecondsAtStart;
GetDateTime (&secondsAtStart);
upTimeAtStart = UnsignedWideToUInt64 (AbsoluteToNanoseconds (UpTime()));
nanosecondsAtStart = U64SetU (secondsAtStart);
nanosecondsAtStart = U64Multiply (nanosecondsAtStart, kTenE9);
gNanosecondsAtStart = U64Subtract (nanosecondsAtStart, upTimeAtStart);
}
/*
* Convert the event time (UpTime value) to nanoseconds and add
* the local time epoch.
*/
eventNanoseconds = UnsignedWideToUInt64 (AbsoluteToNanoseconds (eventTime));
eventNanoseconds = U64Add (gNanosecondsAtStart, eventNanoseconds);
/*
* eventSeconds = eventNanoseconds /= 10e9;
* residualNanoseconds = eventNanoseconds % 10e9;
* Finally, compute the local time (seconds) and fraction.
*/
eventSeconds64 = U64Div (eventNanoseconds, kTenE9);
eventNanoseconds = U64Subtract (eventNanoseconds, U64Multiply (eventSeconds64, kTenE9));
*eventSeconds = (UInt64ToUnsignedWide (eventSeconds64)).lo;
*residualNanoseconds = (UInt64ToUnsignedWide (eventNanoseconds)).lo;
}
#elif defined(_WIN32)
/* Microsoft Windows NT and 95 (32bit) */
/* This one works for WOW (Windows on Windows, ntvdm on Win-NT) */
#include <time.h>
#include <sys/timeb.h>
#include <string.h>
krb5_error_code
krb5_crypto_us_timeofday(seconds, microseconds)
register krb5_int32 *seconds, *microseconds;
{
struct _timeb timeptr;
krb5_int32 sec, usec;
static krb5_int32 last_sec = 0;
static krb5_int32 last_usec = 0;
_ftime(&timeptr); /* Get the current time */
sec = timeptr.time;
usec = timeptr.millitm * 1000;
if ((sec == last_sec) && (usec <= last_usec)) { /* Same as last time??? */
usec = ++last_usec;
if (usec >= 1000000) {
++sec;
usec = 0;
}
}
last_sec = sec; /* Remember for next time */
last_usec = usec;
*seconds = sec; /* Return the values */
*microseconds = usec;
return 0;
}
#elif defined (_MSDOS)
/*
* Originally written by John Gilmore, Cygnus Support, May '94.
* Public Domain.
*/
#include <time.h>
#include <sys/timeb.h>
#include <dos.h>
#include <string.h>
/*
* Time handling. Translate Unix time calls into Kerberos internal
* procedure calls.
*
* Due to the fact that DOS time can be unreliable we have reverted
* to using the AT hardware clock and converting it to Unix time.
*/
static time_t win_gettime ();
static long win_time_get_epoch(); /* Adjust for MSC 7.00 bug */
krb5_error_code
krb5_crypto_us_timeofday(seconds, microseconds)
register krb5_int32 *seconds, *microseconds;
{
krb5_int32 sec, usec;
static krb5_int32 last_sec = 0;
static krb5_int32 last_usec = 0;
sec = win_gettime (); /* Get the current time */
usec = 0; /* Can't do microseconds */
if (sec == last_sec) { /* Same as last time??? */
usec = ++last_usec; /* Yep, so do microseconds */
if (usec >= 1000000) {
++sec;
usec = 0;
}
}
last_sec = sec; /* Remember for next time */
last_usec = usec;
*seconds = sec; /* Return the values */
*microseconds = usec;
return 0;
}
static time_t
win_gettime () {
struct tm tm;
union _REGS inregs; /* For calling BIOS */
union _REGS outregs;
struct _timeb now;
time_t time;
long convert; /* MSC 7.00 bug work around */
_ftime(&now); /* Daylight savings time */
/* Get time from AT hardware clock INT 0x1A, AH=2 */
memset(&inregs, 0, sizeof(inregs));
inregs.h.ah = 2;
_int86(0x1a, &inregs, &outregs);
/* 0x13 = decimal 13, hence the decoding below */
tm.tm_sec = 10 * ((outregs.h.dh & 0xF0) >> 4) + (outregs.h.dh & 0x0F);
tm.tm_min = 10 * ((outregs.h.cl & 0xF0) >> 4) + (outregs.h.cl & 0x0F);
tm.tm_hour = 10 * ((outregs.h.ch & 0xF0) >> 4) + (outregs.h.ch & 0x0F);
/* Get date from AT hardware clock INT 0x1A, AH=4 */
memset(&inregs, 0, sizeof(inregs));
inregs.h.ah = 4;
_int86(0x1a, &inregs, &outregs);
tm.tm_mday = 10 * ((outregs.h.dl & 0xF0) >> 4) + (outregs.h.dl & 0x0F);
tm.tm_mon = 10 * ((outregs.h.dh & 0xF0) >> 4) + (outregs.h.dh & 0x0F) - 1;
tm.tm_year = 10 * ((outregs.h.cl & 0xF0) >> 4) + (outregs.h.cl & 0x0F);
tm.tm_year += 100 * ((10 * (outregs.h.ch & 0xF0) >> 4)
+ (outregs.h.ch & 0x0F) - 19);
tm.tm_wday = 0;
tm.tm_yday = 0;
tm.tm_isdst = now.dstflag;
time = mktime(&tm);
convert = win_time_get_epoch();
return time + convert;
}
/*
* This routine figures out the current time epoch and returns the
* conversion factor. It exists because
* Microloss screwed the pooch on the time() and _ftime() calls in
* its release 7.0 libraries. They changed the epoch to Dec 31, 1899!
* Idiots... We try to cope.
*/
static struct tm jan_1_70 = {0, 0, 0, 1, 0, 70};
static long epoch = 0;
static int epoch_set = 0;
long
win_time_get_epoch()
{
if (!epoch_set) {
epoch = 0 - mktime (&jan_1_70); /* Seconds til 1970 localtime */
epoch += _timezone; /* Seconds til 1970 GMT */
epoch_set = 1;
}
return epoch;
}
#else
/* We're a Unix machine -- do Unix time things. */
extern int errno;
static struct timeval last_tv = {0, 0};
krb5_error_code
krb5_crypto_us_timeofday(seconds, microseconds)
register krb5_int32 *seconds, *microseconds;
{
struct timeval tv;
if (gettimeofday(&tv, (struct timezone *)0) == -1) {
/* failed, return errno */
return (krb5_error_code) errno;
}
if ((tv.tv_sec == last_tv.tv_sec) && (tv.tv_usec == last_tv.tv_usec)) {
if (++last_tv.tv_usec >= 1000000) {
last_tv.tv_usec = 0;
last_tv.tv_sec++;
}
tv = last_tv;
} else
last_tv = tv;
*seconds = tv.tv_sec;
*microseconds = tv.tv_usec;
return 0;
}
#endif
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