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21. Date and Time

This chapter describes functions for manipulating dates and times, including functions for determining what time it is and conversion between different time representations.


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21.1 Time Basics

Discussing time in a technical manual can be difficult because the word “time” in English refers to lots of different things. In this manual, we use a rigorous terminology to avoid confusion, and the only thing we use the simple word “time” for is to talk about the abstract concept.

A calendar time is a point in the time continuum, for example November 4, 1990 at 18:02.5 UTC. Sometimes this is called “absolute time”.

We don't speak of a “date”, because that is inherent in a calendar time.

An interval is a contiguous part of the time continuum between two calendar times, for example the hour between 9:00 and 10:00 on July 4, 1980.

An elapsed time is the length of an interval, for example, 35 minutes. People sometimes sloppily use the word “interval” to refer to the elapsed time of some interval.

An amount of time is a sum of elapsed times, which need not be of any specific intervals. For example, the amount of time it takes to read a book might be 9 hours, independently of when and in how many sittings it is read.

A period is the elapsed time of an interval between two events, especially when they are part of a sequence of regularly repeating events.

CPU time is like calendar time, except that it is based on the subset of the time continuum when a particular process is actively using a CPU. CPU time is, therefore, relative to a process.

Processor time is an amount of time that a CPU is in use. In fact, it's a basic system resource, since there's a limit to how much can exist in any given interval (that limit is the elapsed time of the interval times the number of CPUs in the processor). People often call this CPU time, but we reserve the latter term in this manual for the definition above.


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21.2 Elapsed Time

One way to represent an elapsed time is with a simple arithmetic data type, as with the following function to compute the elapsed time between two calendar times. This function is declared in ‘time.h’.

Function: double difftime (time_t time1, time_t time0)

The difftime function returns the number of seconds of elapsed time between calendar time time1 and calendar time time0, as a value of type double. The difference ignores leap seconds unless leap second support is enabled.

In the GNU system, you can simply subtract time_t values. But on other systems, the time_t data type might use some other encoding where subtraction doesn't work directly.

The GNU C library provides two data types specifically for representing an elapsed time. They are used by various GNU C library functions, and you can use them for your own purposes too. They're exactly the same except that one has a resolution in microseconds, and the other, newer one, is in nanoseconds.

Data Type: struct timeval

The struct timeval structure represents an elapsed time. It is declared in ‘sys/time.h’ and has the following members:

long int tv_sec

This represents the number of whole seconds of elapsed time.

long int tv_usec

This is the rest of the elapsed time (a fraction of a second), represented as the number of microseconds. It is always less than one million.

Data Type: struct timespec

The struct timespec structure represents an elapsed time. It is declared in ‘time.h’ and has the following members:

long int tv_sec

This represents the number of whole seconds of elapsed time.

long int tv_nsec

This is the rest of the elapsed time (a fraction of a second), represented as the number of nanoseconds. It is always less than one billion.

It is often necessary to subtract two values of type struct timeval or struct timespec. Here is the best way to do this. It works even on some peculiar operating systems where the tv_sec member has an unsigned type.

 
/* Subtract the `struct timeval' values X and Y,
   storing the result in RESULT.
   Return 1 if the difference is negative, otherwise 0.  */

int
timeval_subtract (result, x, y)
     struct timeval *result, *x, *y;
{
  /* Perform the carry for the later subtraction by updating y. */
  if (x->tv_usec < y->tv_usec) {
    int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1;
    y->tv_usec -= 1000000 * nsec;
    y->tv_sec += nsec;
  }
  if (x->tv_usec - y->tv_usec > 1000000) {
    int nsec = (x->tv_usec - y->tv_usec) / 1000000;
    y->tv_usec += 1000000 * nsec;
    y->tv_sec -= nsec;
  }

  /* Compute the time remaining to wait.
     tv_usec is certainly positive. */
  result->tv_sec = x->tv_sec - y->tv_sec;
  result->tv_usec = x->tv_usec - y->tv_usec;

  /* Return 1 if result is negative. */
  return x->tv_sec < y->tv_sec;
}

Common functions that use struct timeval are gettimeofday and settimeofday.

There are no GNU C library functions specifically oriented toward dealing with elapsed times, but the calendar time, processor time, and alarm and sleeping functions have a lot to do with them.


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21.3 Processor And CPU Time

If you're trying to optimize your program or measure its efficiency, it's very useful to know how much processor time it uses. For that, calendar time and elapsed times are useless because a process may spend time waiting for I/O or for other processes to use the CPU. However, you can get the information with the functions in this section.

CPU time (see section Time Basics) is represented by the data type clock_t, which is a number of clock ticks. It gives the total amount of time a process has actively used a CPU since some arbitrary event. On the GNU system, that event is the creation of the process. While arbitrary in general, the event is always the same event for any particular process, so you can always measure how much time on the CPU a particular computation takes by examining the process' CPU time before and after the computation.

In the GNU system, clock_t is equivalent to long int and CLOCKS_PER_SEC is an integer value. But in other systems, both clock_t and the macro CLOCKS_PER_SEC can be either integer or floating-point types. Casting CPU time values to double, as in the example above, makes sure that operations such as arithmetic and printing work properly and consistently no matter what the underlying representation is.

Note that the clock can wrap around. On a 32bit system with CLOCKS_PER_SEC set to one million this function will return the same value approximately every 72 minutes.

For additional functions to examine a process' use of processor time, and to control it, See section Resource Usage And Limitation.


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21.3.1 CPU Time Inquiry

To get a process' CPU time, you can use the clock function. This facility is declared in the header file ‘time.h’.

In typical usage, you call the clock function at the beginning and end of the interval you want to time, subtract the values, and then divide by CLOCKS_PER_SEC (the number of clock ticks per second) to get processor time, like this:

 
#include <time.h>

clock_t start, end;
double cpu_time_used;

start = clock();
… /* Do the work. */
end = clock();
cpu_time_used = ((double) (end - start)) / CLOCKS_PER_SEC;

Do not use a single CPU time as an amount of time; it doesn't work that way. Either do a subtraction as shown above or query processor time directly. See section Processor Time Inquiry.

Different computers and operating systems vary wildly in how they keep track of CPU time. It's common for the internal processor clock to have a resolution somewhere between a hundredth and millionth of a second.

Macro: int CLOCKS_PER_SEC

The value of this macro is the number of clock ticks per second measured by the clock function. POSIX requires that this value be one million independent of the actual resolution.

Macro: int CLK_TCK

This is an obsolete name for CLOCKS_PER_SEC.

Data Type: clock_t

This is the type of the value returned by the clock function. Values of type clock_t are numbers of clock ticks.

Function: clock_t clock (void)

This function returns the calling process' current CPU time. If the CPU time is not available or cannot be represented, clock returns the value (clock_t)(-1).


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21.3.2 Processor Time Inquiry

The times function returns information about a process' consumption of processor time in a struct tms object, in addition to the process' CPU time. See section Time Basics. You should include the header file ‘sys/times.h’ to use this facility.

Data Type: struct tms

The tms structure is used to return information about process times. It contains at least the following members:

clock_t tms_utime

This is the total processor time the calling process has used in executing the instructions of its program.

clock_t tms_stime

This is the processor time the system has used on behalf of the calling process.

clock_t tms_cutime

This is the sum of the tms_utime values and the tms_cutime values of all terminated child processes of the calling process, whose status has been reported to the parent process by wait or waitpid; see Process Completion. In other words, it represents the total processor time used in executing the instructions of all the terminated child processes of the calling process, excluding child processes which have not yet been reported by wait or waitpid.

clock_t tms_cstime

This is similar to tms_cutime, but represents the total processor time system has used on behalf of all the terminated child processes of the calling process.

All of the times are given in numbers of clock ticks. Unlike CPU time, these are the actual amounts of time; not relative to any event. See section Creating a Process.

Function: clock_t times (struct tms *buffer)

The times function stores the processor time information for the calling process in buffer.

The return value is the calling process' CPU time (the same value you get from clock(). times returns (clock_t)(-1) to indicate failure.

Portability Note: The clock function described in CPU Time Inquiry is specified by the ISO C standard. The times function is a feature of POSIX.1. In the GNU system, the CPU time is defined to be equivalent to the sum of the tms_utime and tms_stime fields returned by times.


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21.4 Calendar Time

This section describes facilities for keeping track of calendar time. See section Time Basics.

The GNU C library represents calendar time three ways:


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21.4.1 Simple Calendar Time

This section describes the time_t data type for representing calendar time as simple time, and the functions which operate on simple time objects. These facilities are declared in the header file ‘time.h’.

Data Type: time_t

This is the data type used to represent simple time. Sometimes, it also represents an elapsed time. When interpreted as a calendar time value, it represents the number of seconds elapsed since 00:00:00 on January 1, 1970, Coordinated Universal Time. (This calendar time is sometimes referred to as the epoch.) POSIX requires that this count not include leap seconds, but on some systems this count includes leap seconds if you set TZ to certain values (see section Specifying the Time Zone with TZ).

Note that a simple time has no concept of local time zone. Calendar Time T is the same instant in time regardless of where on the globe the computer is.

In the GNU C library, time_t is equivalent to long int. In other systems, time_t might be either an integer or floating-point type.

The function difftime tells you the elapsed time between two simple calendar times, which is not always as easy to compute as just subtracting. See section Elapsed Time.

Function: time_t time (time_t *result)

The time function returns the current calendar time as a value of type time_t. If the argument result is not a null pointer, the calendar time value is also stored in *result. If the current calendar time is not available, the value (time_t)(-1) is returned.

Function: int stime (time_t *newtime)

stime sets the system clock, i.e., it tells the system that the current calendar time is newtime, where newtime is interpreted as described in the above definition of time_t.

settimeofday is a newer function which sets the system clock to better than one second precision. settimeofday is generally a better choice than stime. See section High-Resolution Calendar.

Only the superuser can set the system clock.

If the function succeeds, the return value is zero. Otherwise, it is -1 and errno is set accordingly:

EPERM

The process is not superuser.


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21.4.2 High-Resolution Calendar

The time_t data type used to represent simple times has a resolution of only one second. Some applications need more precision.

So, the GNU C library also contains functions which are capable of representing calendar times to a higher resolution than one second. The functions and the associated data types described in this section are declared in ‘sys/time.h’.

Data Type: struct timezone

The struct timezone structure is used to hold minimal information about the local time zone. It has the following members:

int tz_minuteswest

This is the number of minutes west of UTC.

int tz_dsttime

If nonzero, Daylight Saving Time applies during some part of the year.

The struct timezone type is obsolete and should never be used. Instead, use the facilities described in Functions and Variables for Time Zones.

Function: int gettimeofday (struct timeval *tp, struct timezone *tzp)

The gettimeofday function returns the current calendar time as the elapsed time since the epoch in the struct timeval structure indicated by tp. (see section Elapsed Time for a description of struct timeval). Information about the time zone is returned in the structure pointed at tzp. If the tzp argument is a null pointer, time zone information is ignored.

The return value is 0 on success and -1 on failure. The following errno error condition is defined for this function:

ENOSYS

The operating system does not support getting time zone information, and tzp is not a null pointer. The GNU operating system does not support using struct timezone to represent time zone information; that is an obsolete feature of 4.3 BSD. Instead, use the facilities described in Functions and Variables for Time Zones.

Function: int settimeofday (const struct timeval *tp, const struct timezone *tzp)

The settimeofday function sets the current calendar time in the system clock according to the arguments. As for gettimeofday, the calendar time is represented as the elapsed time since the epoch. As for gettimeofday, time zone information is ignored if tzp is a null pointer.

You must be a privileged user in order to use settimeofday.

Some kernels automatically set the system clock from some source such as a hardware clock when they start up. Others, including Linux, place the system clock in an “invalid” state (in which attempts to read the clock fail). A call of stime removes the system clock from an invalid state, and system startup scripts typically run a program that calls stime.

settimeofday causes a sudden jump forwards or backwards, which can cause a variety of problems in a system. Use adjtime (below) to make a smooth transition from one time to another by temporarily speeding up or slowing down the clock.

With a Linux kernel, adjtimex does the same thing and can also make permanent changes to the speed of the system clock so it doesn't need to be corrected as often.

The return value is 0 on success and -1 on failure. The following errno error conditions are defined for this function:

EPERM

This process cannot set the clock because it is not privileged.

ENOSYS

The operating system does not support setting time zone information, and tzp is not a null pointer.

Function: int adjtime (const struct timeval *delta, struct timeval *olddelta)

This function speeds up or slows down the system clock in order to make a gradual adjustment. This ensures that the calendar time reported by the system clock is always monotonically increasing, which might not happen if you simply set the clock.

The delta argument specifies a relative adjustment to be made to the clock time. If negative, the system clock is slowed down for a while until it has lost this much elapsed time. If positive, the system clock is speeded up for a while.

If the olddelta argument is not a null pointer, the adjtime function returns information about any previous time adjustment that has not yet completed.

This function is typically used to synchronize the clocks of computers in a local network. You must be a privileged user to use it.

With a Linux kernel, you can use the adjtimex function to permanently change the clock speed.

The return value is 0 on success and -1 on failure. The following errno error condition is defined for this function:

EPERM

You do not have privilege to set the time.

Portability Note: The gettimeofday, settimeofday, and adjtime functions are derived from BSD.

Symbols for the following function are declared in ‘sys/timex.h’.

Function: int adjtimex (struct timex *timex)

adjtimex is functionally identical to ntp_adjtime. See section High Accuracy Clock.

This function is present only with a Linux kernel.


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21.4.3 Broken-down Time

Calendar time is represented by the usual GNU C library functions as an elapsed time since a fixed base calendar time. This is convenient for computation, but has no relation to the way people normally think of calendar time. By contrast, broken-down time is a binary representation of calendar time separated into year, month, day, and so on. Broken-down time values are not useful for calculations, but they are useful for printing human readable time information.

A broken-down time value is always relative to a choice of time zone, and it also indicates which time zone that is.

The symbols in this section are declared in the header file ‘time.h’.

Data Type: struct tm

This is the data type used to represent a broken-down time. The structure contains at least the following members, which can appear in any order.

int tm_sec

This is the number of full seconds since the top of the minute (normally in the range 0 through 59, but the actual upper limit is 60, to allow for leap seconds if leap second support is available).

int tm_min

This is the number of full minutes since the top of the hour (in the range 0 through 59).

int tm_hour

This is the number of full hours past midnight (in the range 0 through 23).

int tm_mday

This is the ordinal day of the month (in the range 1 through 31). Watch out for this one! As the only ordinal number in the structure, it is inconsistent with the rest of the structure.

int tm_mon

This is the number of full calendar months since the beginning of the year (in the range 0 through 11). Watch out for this one! People usually use ordinal numbers for month-of-year (where January = 1).

int tm_year

This is the number of full calendar years since 1900.

int tm_wday

This is the number of full days since Sunday (in the range 0 through 6).

int tm_yday

This is the number of full days since the beginning of the year (in the range 0 through 365).

int tm_isdst

This is a flag that indicates whether Daylight Saving Time is (or was, or will be) in effect at the time described. The value is positive if Daylight Saving Time is in effect, zero if it is not, and negative if the information is not available.

long int tm_gmtoff

This field describes the time zone that was used to compute this broken-down time value, including any adjustment for daylight saving; it is the number of seconds that you must add to UTC to get local time. You can also think of this as the number of seconds east of UTC. For example, for U.S. Eastern Standard Time, the value is -5*60*60. The tm_gmtoff field is derived from BSD and is a GNU library extension; it is not visible in a strict ISO C environment.

const char *tm_zone

This field is the name for the time zone that was used to compute this broken-down time value. Like tm_gmtoff, this field is a BSD and GNU extension, and is not visible in a strict ISO C environment.

Function: struct tm * localtime (const time_t *time)

The localtime function converts the simple time pointed to by time to broken-down time representation, expressed relative to the user's specified time zone.

The return value is a pointer to a static broken-down time structure, which might be overwritten by subsequent calls to ctime, gmtime, or localtime. (But no other library function overwrites the contents of this object.)

The return value is the null pointer if time cannot be represented as a broken-down time; typically this is because the year cannot fit into an int.

Calling localtime has one other effect: it sets the variable tzname with information about the current time zone. See section Functions and Variables for Time Zones.

Using the localtime function is a big problem in multi-threaded programs. The result is returned in a static buffer and this is used in all threads. POSIX.1c introduced a variant of this function.

Function: struct tm * localtime_r (const time_t *time, struct tm *resultp)

The localtime_r function works just like the localtime function. It takes a pointer to a variable containing a simple time and converts it to the broken-down time format.

But the result is not placed in a static buffer. Instead it is placed in the object of type struct tm to which the parameter resultp points.

If the conversion is successful the function returns a pointer to the object the result was written into, i.e., it returns resultp.

Function: struct tm * gmtime (const time_t *time)

This function is similar to localtime, except that the broken-down time is expressed as Coordinated Universal Time (UTC) (formerly called Greenwich Mean Time (GMT)) rather than relative to a local time zone.

As for the localtime function we have the problem that the result is placed in a static variable. POSIX.1c also provides a replacement for gmtime.

Function: struct tm * gmtime_r (const time_t *time, struct tm *resultp)

This function is similar to localtime_r, except that it converts just like gmtime the given time as Coordinated Universal Time.

If the conversion is successful the function returns a pointer to the object the result was written into, i.e., it returns resultp.

Function: time_t mktime (struct tm *brokentime)

The mktime function is used to convert a broken-down time structure to a simple time representation. It also “normalizes” the contents of the broken-down time structure, by filling in the day of week and day of year based on the other date and time components.

The mktime function ignores the specified contents of the tm_wday and tm_yday members of the broken-down time structure. It uses the values of the other components to determine the calendar time; it's permissible for these components to have unnormalized values outside their normal ranges. The last thing that mktime does is adjust the components of the brokentime structure (including the tm_wday and tm_yday).

If the specified broken-down time cannot be represented as a simple time, mktime returns a value of (time_t)(-1) and does not modify the contents of brokentime.

Calling mktime also sets the variable tzname with information about the current time zone. See section Functions and Variables for Time Zones.

Function: time_t timelocal (struct tm *brokentime)

timelocal is functionally identical to mktime, but more mnemonically named. Note that it is the inverse of the localtime function.

Portability note: mktime is essentially universally available. timelocal is rather rare.

Function: time_t timegm (struct tm *brokentime)

timegm is functionally identical to mktime except it always takes the input values to be Coordinated Universal Time (UTC) regardless of any local time zone setting.

Note that timegm is the inverse of gmtime.

Portability note: mktime is essentially universally available. timegm is rather rare. For the most portable conversion from a UTC broken-down time to a simple time, set the TZ environment variable to UTC, call mktime, then set TZ back.


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21.4.4 High Accuracy Clock

The ntp_gettime and ntp_adjtime functions provide an interface to monitor and manipulate the system clock to maintain high accuracy time. For example, you can fine tune the speed of the clock or synchronize it with another time source.

A typical use of these functions is by a server implementing the Network Time Protocol to synchronize the clocks of multiple systems and high precision clocks.

These functions are declared in ‘sys/timex.h’.

Data Type: struct ntptimeval

This structure is used for information about the system clock. It contains the following members:

struct timeval time

This is the current calendar time, expressed as the elapsed time since the epoch. The struct timeval data type is described in Elapsed Time.

long int maxerror

This is the maximum error, measured in microseconds. Unless updated via ntp_adjtime periodically, this value will reach some platform-specific maximum value.

long int esterror

This is the estimated error, measured in microseconds. This value can be set by ntp_adjtime to indicate the estimated offset of the system clock from the true calendar time.

Function: int ntp_gettime (struct ntptimeval *tptr)

The ntp_gettime function sets the structure pointed to by tptr to current values. The elements of the structure afterwards contain the values the timer implementation in the kernel assumes. They might or might not be correct. If they are not a ntp_adjtime call is necessary.

The return value is 0 on success and other values on failure. The following errno error conditions are defined for this function:

TIME_ERROR

The precision clock model is not properly set up at the moment, thus the clock must be considered unsynchronized, and the values should be treated with care.

Data Type: struct timex

This structure is used to control and monitor the system clock. It contains the following members:

unsigned int modes

This variable controls whether and which values are set. Several symbolic constants have to be combined with binary or to specify the effective mode. These constants start with MOD_.

long int offset

This value indicates the current offset of the system clock from the true calendar time. The value is given in microseconds. If bit MOD_OFFSET is set in modes, the offset (and possibly other dependent values) can be set. The offset's absolute value must not exceed MAXPHASE.

long int frequency

This value indicates the difference in frequency between the true calendar time and the system clock. The value is expressed as scaled PPM (parts per million, 0.0001%). The scaling is 1 << SHIFT_USEC. The value can be set with bit MOD_FREQUENCY, but the absolute value must not exceed MAXFREQ.

long int maxerror

This is the maximum error, measured in microseconds. A new value can be set using bit MOD_MAXERROR. Unless updated via ntp_adjtime periodically, this value will increase steadily and reach some platform-specific maximum value.

long int esterror

This is the estimated error, measured in microseconds. This value can be set using bit MOD_ESTERROR.

int status

This variable reflects the various states of the clock machinery. There are symbolic constants for the significant bits, starting with STA_. Some of these flags can be updated using the MOD_STATUS bit.

long int constant

This value represents the bandwidth or stiffness of the PLL (phase locked loop) implemented in the kernel. The value can be changed using bit MOD_TIMECONST.

long int precision

This value represents the accuracy or the maximum error when reading the system clock. The value is expressed in microseconds.

long int tolerance

This value represents the maximum frequency error of the system clock in scaled PPM. This value is used to increase the maxerror every second.

struct timeval time

The current calendar time.

long int tick

The elapsed time between clock ticks in microseconds. A clock tick is a periodic timer interrupt on which the system clock is based.

long int ppsfreq

This is the first of a few optional variables that are present only if the system clock can use a PPS (pulse per second) signal to discipline the system clock. The value is expressed in scaled PPM and it denotes the difference in frequency between the system clock and the PPS signal.

long int jitter

This value expresses a median filtered average of the PPS signal's dispersion in microseconds.

int shift

This value is a binary exponent for the duration of the PPS calibration interval, ranging from PPS_SHIFT to PPS_SHIFTMAX.

long int stabil

This value represents the median filtered dispersion of the PPS frequency in scaled PPM.

long int jitcnt

This counter represents the number of pulses where the jitter exceeded the allowed maximum MAXTIME.

long int calcnt

This counter reflects the number of successful calibration intervals.

long int errcnt

This counter represents the number of calibration errors (caused by large offsets or jitter).

long int stbcnt

This counter denotes the number of of calibrations where the stability exceeded the threshold.

Function: int ntp_adjtime (struct timex *tptr)

The ntp_adjtime function sets the structure specified by tptr to current values.

In addition, ntp_adjtime updates some settings to match what you pass to it in *tptr. Use the modes element of *tptr to select what settings to update. You can set offset, freq, maxerror, esterror, status, constant, and tick.

modes = zero means set nothing.

Only the superuser can update settings.

The return value is 0 on success and other values on failure. The following errno error conditions are defined for this function:

TIME_ERROR

The high accuracy clock model is not properly set up at the moment, thus the clock must be considered unsynchronized, and the values should be treated with care. Another reason could be that the specified new values are not allowed.

EPERM

The process specified a settings update, but is not superuser.

For more details see RFC1305 (Network Time Protocol, Version 3) and related documents.

Portability note: Early versions of the GNU C library did not have this function but did have the synonymous adjtimex.


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21.4.5 Formatting Calendar Time

The functions described in this section format calendar time values as strings. These functions are declared in the header file ‘time.h’.

Function: char * asctime (const struct tm *brokentime)

The asctime function converts the broken-down time value that brokentime points to into a string in a standard format:

 
"Tue May 21 13:46:22 1991\n"

The abbreviations for the days of week are: ‘Sun’, ‘Mon’, ‘Tue’, ‘Wed’, ‘Thu’, ‘Fri’, and ‘Sat’.

The abbreviations for the months are: ‘Jan’, ‘Feb’, ‘Mar’, ‘Apr’, ‘May’, ‘Jun’, ‘Jul’, ‘Aug’, ‘Sep’, ‘Oct’, ‘Nov’, and ‘Dec’.

The return value points to a statically allocated string, which might be overwritten by subsequent calls to asctime or ctime. (But no other library function overwrites the contents of this string.)

Function: char * asctime_r (const struct tm *brokentime, char *buffer)

This function is similar to asctime but instead of placing the result in a static buffer it writes the string in the buffer pointed to by the parameter buffer. This buffer should have room for at least 26 bytes, including the terminating null.

If no error occurred the function returns a pointer to the string the result was written into, i.e., it returns buffer. Otherwise return NULL.

Function: char * ctime (const time_t *time)

The ctime function is similar to asctime, except that you specify the calendar time argument as a time_t simple time value rather than in broken-down local time format. It is equivalent to

 
asctime (localtime (time))

ctime sets the variable tzname, because localtime does so. See section Functions and Variables for Time Zones.

Function: char * ctime_r (const time_t *time, char *buffer)

This function is similar to ctime, but places the result in the string pointed to by buffer. It is equivalent to (written using gcc extensions, see (gcc)Statement Exprs section `Statement Exprs' in Porting and Using gcc):

 
({ struct tm tm; asctime_r (localtime_r (time, &tm), buf); })

If no error occurred the function returns a pointer to the string the result was written into, i.e., it returns buffer. Otherwise return NULL.

Function: size_t strftime (char *s, size_t size, const char *template, const struct tm *brokentime)

This function is similar to the sprintf function (see section Formatted Input), but the conversion specifications that can appear in the format template template are specialized for printing components of the date and time brokentime according to the locale currently specified for time conversion (see section Locales and Internationalization).

Ordinary characters appearing in the template are copied to the output string s; this can include multibyte character sequences. Conversion specifiers are introduced by a ‘%’ character, followed by an optional flag which can be one of the following. These flags are all GNU extensions. The first three affect only the output of numbers:

_

The number is padded with spaces.

-

The number is not padded at all.

0

The number is padded with zeros even if the format specifies padding with spaces.

^

The output uses uppercase characters, but only if this is possible (see section Case Conversion).

The default action is to pad the number with zeros to keep it a constant width. Numbers that do not have a range indicated below are never padded, since there is no natural width for them.

Following the flag an optional specification of the width is possible. This is specified in decimal notation. If the natural size of the output is of the field has less than the specified number of characters, the result is written right adjusted and space padded to the given size.

An optional modifier can follow the optional flag and width specification. The modifiers, which were first standardized by POSIX.2-1992 and by ISO C99, are:

E

Use the locale's alternate representation for date and time. This modifier applies to the %c, %C, %x, %X, %y and %Y format specifiers. In a Japanese locale, for example, %Ex might yield a date format based on the Japanese Emperors' reigns.

O

Use the locale's alternate numeric symbols for numbers. This modifier applies only to numeric format specifiers.

If the format supports the modifier but no alternate representation is available, it is ignored.

The conversion specifier ends with a format specifier taken from the following list. The whole ‘%’ sequence is replaced in the output string as follows:

%a

The abbreviated weekday name according to the current locale.

%A

The full weekday name according to the current locale.

%b

The abbreviated month name according to the current locale.

%B

The full month name according to the current locale.

Using %B together with %d produces grammatically incorrect results for some locales.

%c

The preferred calendar time representation for the current locale.

%C

The century of the year. This is equivalent to the greatest integer not greater than the year divided by 100.

This format was first standardized by POSIX.2-1992 and by ISO C99.

%d

The day of the month as a decimal number (range 01 through 31).

%D

The date using the format %m/%d/%y.

This format was first standardized by POSIX.2-1992 and by ISO C99.

%e

The day of the month like with %d, but padded with blank (range 1 through 31).

This format was first standardized by POSIX.2-1992 and by ISO C99.

%F

The date using the format %Y-%m-%d. This is the form specified in the ISO 8601 standard and is the preferred form for all uses.

This format was first standardized by ISO C99 and by POSIX.1-2001.

%g

The year corresponding to the ISO week number, but without the century (range 00 through 99). This has the same format and value as %y, except that if the ISO week number (see %V) belongs to the previous or next year, that year is used instead.

This format was first standardized by ISO C99 and by POSIX.1-2001.

%G

The year corresponding to the ISO week number. This has the same format and value as %Y, except that if the ISO week number (see %V) belongs to the previous or next year, that year is used instead.

This format was first standardized by ISO C99 and by POSIX.1-2001 but was previously available as a GNU extension.

%h

The abbreviated month name according to the current locale. The action is the same as for %b.

This format was first standardized by POSIX.2-1992 and by ISO C99.

%H

The hour as a decimal number, using a 24-hour clock (range 00 through 23).

%I

The hour as a decimal number, using a 12-hour clock (range 01 through 12).

%j

The day of the year as a decimal number (range 001 through 366).

%k

The hour as a decimal number, using a 24-hour clock like %H, but padded with blank (range 0 through 23).

This format is a GNU extension.

%l

The hour as a decimal number, using a 12-hour clock like %I, but padded with blank (range 1 through 12).

This format is a GNU extension.

%m

The month as a decimal number (range 01 through 12).

%M

The minute as a decimal number (range 00 through 59).

%n

A single ‘\n’ (newline) character.

This format was first standardized by POSIX.2-1992 and by ISO C99.

%p

Either ‘AM’ or ‘PM’, according to the given time value; or the corresponding strings for the current locale. Noon is treated as ‘PM’ and midnight as ‘AM’. In most locales ‘AM’/‘PM’ format is not supported, in such cases "%p" yields an empty string.

%P

Either ‘am’ or ‘pm’, according to the given time value; or the corresponding strings for the current locale, printed in lowercase characters. Noon is treated as ‘pm’ and midnight as ‘am’. In most locales ‘AM’/‘PM’ format is not supported, in such cases "%P" yields an empty string.

This format is a GNU extension.

%r

The complete calendar time using the AM/PM format of the current locale.

This format was first standardized by POSIX.2-1992 and by ISO C99. In the POSIX locale, this format is equivalent to %I:%M:%S %p.

%R

The hour and minute in decimal numbers using the format %H:%M.

This format was first standardized by ISO C99 and by POSIX.1-2001 but was previously available as a GNU extension.

%s

The number of seconds since the epoch, i.e., since 1970-01-01 00:00:00 UTC. Leap seconds are not counted unless leap second support is available.

This format is a GNU extension.

%S

The seconds as a decimal number (range 00 through 60).

%t

A single ‘\t’ (tabulator) character.

This format was first standardized by POSIX.2-1992 and by ISO C99.

%T

The time of day using decimal numbers using the format %H:%M:%S.

This format was first standardized by POSIX.2-1992 and by ISO C99.

%u

The day of the week as a decimal number (range 1 through 7), Monday being 1.

This format was first standardized by POSIX.2-1992 and by ISO C99.

%U

The week number of the current year as a decimal number (range 00 through 53), starting with the first Sunday as the first day of the first week. Days preceding the first Sunday in the year are considered to be in week 00.

%V

The ISO 8601:1988 week number as a decimal number (range 01 through 53). ISO weeks start with Monday and end with Sunday. Week 01 of a year is the first week which has the majority of its days in that year; this is equivalent to the week containing the year's first Thursday, and it is also equivalent to the week containing January 4. Week 01 of a year can contain days from the previous year. The week before week 01 of a year is the last week (52 or 53) of the previous year even if it contains days from the new year.

This format was first standardized by POSIX.2-1992 and by ISO C99.

%w

The day of the week as a decimal number (range 0 through 6), Sunday being 0.

%W

The week number of the current year as a decimal number (range 00 through 53), starting with the first Monday as the first day of the first week. All days preceding the first Monday in the year are considered to be in week 00.

%x

The preferred date representation for the current locale.

%X

The preferred time of day representation for the current locale.

%y

The year without a century as a decimal number (range 00 through 99). This is equivalent to the year modulo 100.

%Y

The year as a decimal number, using the Gregorian calendar. Years before the year 1 are numbered 0, -1, and so on.

%z

RFC 822/ISO 8601:1988 style numeric time zone (e.g., -0600 or +0100), or nothing if no time zone is determinable.

This format was first standardized by ISO C99 and by POSIX.1-2001 but was previously available as a GNU extension.

In the POSIX locale, a full RFC 822 timestamp is generated by the format ‘"%a, %d %b %Y %H:%M:%S %z"’ (or the equivalent ‘"%a, %d %b %Y %T %z"’).

%Z

The time zone abbreviation (empty if the time zone can't be determined).

%%

A literal ‘%’ character.

The size parameter can be used to specify the maximum number of characters to be stored in the array s, including the terminating null character. If the formatted time requires more than size characters, strftime returns zero and the contents of the array s are undefined. Otherwise the return value indicates the number of characters placed in the array s, not including the terminating null character.

Warning: This convention for the return value which is prescribed in ISO C can lead to problems in some situations. For certain format strings and certain locales the output really can be the empty string and this cannot be discovered by testing the return value only. E.g., in most locales the AM/PM time format is not supported (most of the world uses the 24 hour time representation). In such locales "%p" will return the empty string, i.e., the return value is zero. To detect situations like this something similar to the following code should be used:

 
buf[0] = '\1';
len = strftime (buf, bufsize, format, tp);
if (len == 0 && buf[0] != '\0')
  {
    /* Something went wrong in the strftime call.  */
    …
  }

If s is a null pointer, strftime does not actually write anything, but instead returns the number of characters it would have written.

According to POSIX.1 every call to strftime implies a call to tzset. So the contents of the environment variable TZ is examined before any output is produced.

For an example of strftime, see Time Functions Example.

Function: size_t wcsftime (wchar_t *s, size_t size, const wchar_t *template, const struct tm *brokentime)

The wcsftime function is equivalent to the strftime function with the difference that it operates on wide character strings. The buffer where the result is stored, pointed to by s, must be an array of wide characters. The parameter size which specifies the size of the output buffer gives the number of wide character, not the number of bytes.

Also the format string template is a wide character string. Since all characters needed to specify the format string are in the basic character set it is portably possible to write format strings in the C source code using the L"…" notation. The parameter brokentime has the same meaning as in the strftime call.

The wcsftime function supports the same flags, modifiers, and format specifiers as the strftime function.

The return value of wcsftime is the number of wide characters stored in s. When more characters would have to be written than can be placed in the buffer s the return value is zero, with the same problems indicated in the strftime documentation.


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21.4.6 Convert textual time and date information back

The ISO C standard does not specify any functions which can convert the output of the strftime function back into a binary format. This led to a variety of more-or-less successful implementations with different interfaces over the years. Then the Unix standard was extended by the addition of two functions: strptime and getdate. Both have strange interfaces but at least they are widely available.


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21.4.6.1 Interpret string according to given format

The first function is rather low-level. It is nevertheless frequently used in software since it is better known. Its interface and implementation are heavily influenced by the getdate function, which is defined and implemented in terms of calls to strptime.

Function: char * strptime (const char *s, const char *fmt, struct tm *tp)

The strptime function parses the input string s according to the format string fmt and stores its results in the structure tp.

The input string could be generated by a strftime call or obtained any other way. It does not need to be in a human-recognizable format; e.g. a date passed as "02:1999:9" is acceptable, even though it is ambiguous without context. As long as the format string fmt matches the input string the function will succeed.

The user has to make sure, though, that the input can be parsed in a unambiguous way. The string "1999112" can be parsed using the format "%Y%m%d" as 1999-1-12, 1999-11-2, or even 19991-1-2. It is necessary to add appropriate separators to reliably get results.

The format string consists of the same components as the format string of the strftime function. The only difference is that the flags _, -, 0, and ^ are not allowed. Several of the distinct formats of strftime do the same work in strptime since differences like case of the input do not matter. For reasons of symmetry all formats are supported, though.

The modifiers E and O are also allowed everywhere the strftime function allows them.

The formats are:

%a
%A

The weekday name according to the current locale, in abbreviated form or the full name.

%b
%B
%h

The month name according to the current locale, in abbreviated form or the full name.

%c

The date and time representation for the current locale.

%Ec

Like %c but the locale's alternative date and time format is used.

%C

The century of the year.

It makes sense to use this format only if the format string also contains the %y format.

%EC

The locale's representation of the period.

Unlike %C it sometimes makes sense to use this format since some cultures represent years relative to the beginning of eras instead of using the Gregorian years.

%d
%e

The day of the month as a decimal number (range 1 through 31). Leading zeroes are permitted but not required.

%Od
%Oe

Same as %d but using the locale's alternative numeric symbols.

Leading zeroes are permitted but not required.

%D

Equivalent to %m/%d/%y.

%F

Equivalent to %Y-%m-%d, which is the ISO 8601 date format.

This is a GNU extension following an ISO C99 extension to strftime.

%g

The year corresponding to the ISO week number, but without the century (range 00 through 99).

Note: Currently, this is not fully implemented. The format is recognized, input is consumed but no field in tm is set.

This format is a GNU extension following a GNU extension of strftime.

%G

The year corresponding to the ISO week number.

Note: Currently, this is not fully implemented. The format is recognized, input is consumed but no field in tm is set.

This format is a GNU extension following a GNU extension of strftime.

%H
%k

The hour as a decimal number, using a 24-hour clock (range 00 through 23).

%k is a GNU extension following a GNU extension of strftime.

%OH

Same as %H but using the locale's alternative numeric symbols.

%I
%l

The hour as a decimal number, using a 12-hour clock (range 01 through 12).

%l is a GNU extension following a GNU extension of strftime.

%OI

Same as %I but using the locale's alternative numeric symbols.

%j

The day of the year as a decimal number (range 1 through 366).

Leading zeroes are permitted but not required.

%m

The month as a decimal number (range 1 through 12).

Leading zeroes are permitted but not required.

%Om

Same as %m but using the locale's alternative numeric symbols.

%M

The minute as a decimal number (range 0 through 59).

Leading zeroes are permitted but not required.

%OM

Same as %M but using the locale's alternative numeric symbols.

%n
%t

Matches any white space.

%p
%P

The locale-dependent equivalent to ‘AM’ or ‘PM’.

This format is not useful unless %I or %l is also used. Another complication is that the locale might not define these values at all and therefore the conversion fails.

%P is a GNU extension following a GNU extension to strftime.

%r

The complete time using the AM/PM format of the current locale.

A complication is that the locale might not define this format at all and therefore the conversion fails.

%R

The hour and minute in decimal numbers using the format %H:%M.

%R is a GNU extension following a GNU extension to strftime.

%s

The number of seconds since the epoch, i.e., since 1970-01-01 00:00:00 UTC. Leap seconds are not counted unless leap second support is available.

%s is a GNU extension following a GNU extension to strftime.

%S

The seconds as a decimal number (range 0 through 60).

Leading zeroes are permitted but not required.

Note: The Unix specification says the upper bound on this value is 61, a result of a decision to allow double leap seconds. You will not see the value 61 because no minute has more than one leap second, but the myth persists.

%OS

Same as %S but using the locale's alternative numeric symbols.

%T

Equivalent to the use of %H:%M:%S in this place.

%u

The day of the week as a decimal number (range 1 through 7), Monday being 1.

Leading zeroes are permitted but not required.

Note: Currently, this is not fully implemented. The format is recognized, input is consumed but no field in tm is set.

%U

The week number of the current year as a decimal number (range 0 through 53).

Leading zeroes are permitted but not required.

%OU

Same as %U but using the locale's alternative numeric symbols.

%V

The ISO 8601:1988 week number as a decimal number (range 1 through 53).

Leading zeroes are permitted but not required.

Note: Currently, this is not fully implemented. The format is recognized, input is consumed but no field in tm is set.

%w

The day of the week as a decimal number (range 0 through 6), Sunday being 0.

Leading zeroes are permitted but not required.

Note: Currently, this is not fully implemented. The format is recognized, input is consumed but no field in tm is set.

%Ow

Same as %w but using the locale's alternative numeric symbols.

%W

The week number of the current year as a decimal number (range 0 through 53).

Leading zeroes are permitted but not required.

Note: Currently, this is not fully implemented. The format is recognized, input is consumed but no field in tm is set.

%OW

Same as %W but using the locale's alternative numeric symbols.

%x

The date using the locale's date format.

%Ex

Like %x but the locale's alternative data representation is used.

%X

The time using the locale's time format.

%EX

Like %X but the locale's alternative time representation is used.

%y

The year without a century as a decimal number (range 0 through 99).

Leading zeroes are permitted but not required.

Note that it is questionable to use this format without the %C format. The strptime function does regard input values in the range 68 to 99 as the years 1969 to 1999 and the values 0 to 68 as the years 2000 to 2068. But maybe this heuristic fails for some input data.

Therefore it is best to avoid %y completely and use %Y instead.

%Ey

The offset from %EC in the locale's alternative representation.

%Oy

The offset of the year (from %C) using the locale's alternative numeric symbols.

%Y

The year as a decimal number, using the Gregorian calendar.

%EY

The full alternative year representation.

%z

The offset from GMT in ISO 8601/RFC822 format.

%Z

The timezone name.

Note: Currently, this is not fully implemented. The format is recognized, input is consumed but no field in tm is set.

%%

A literal ‘%’ character.

All other characters in the format string must have a matching character in the input string. Exceptions are white spaces in the input string which can match zero or more whitespace characters in the format string.

Portability Note: The XPG standard advises applications to use at least one whitespace character (as specified by isspace) or other non-alphanumeric characters between any two conversion specifications. The GNU C Library does not have this limitation but other libraries might have trouble parsing formats like "%d%m%Y%H%M%S".

The strptime function processes the input string from right to left. Each of the three possible input elements (white space, literal, or format) are handled one after the other. If the input cannot be matched to the format string the function stops. The remainder of the format and input strings are not processed.

The function returns a pointer to the first character it was unable to process. If the input string contains more characters than required by the format string the return value points right after the last consumed input character. If the whole input string is consumed the return value points to the NULL byte at the end of the string. If an error occurs, i.e., strptime fails to match all of the format string, the function returns NULL.

The specification of the function in the XPG standard is rather vague, leaving out a few important pieces of information. Most importantly, it does not specify what happens to those elements of tm which are not directly initialized by the different formats. The implementations on different Unix systems vary here.

The GNU libc implementation does not touch those fields which are not directly initialized. Exceptions are the tm_wday and tm_yday elements, which are recomputed if any of the year, month, or date elements changed. This has two implications:

The following example shows a function which parses a string which is contains the date information in either US style or ISO 8601 form:

 
const char *
parse_date (const char *input, struct tm *tm)
{
  const char *cp;

  /* First clear the result structure.  */
  memset (tm, '\0', sizeof (*tm));

  /* Try the ISO format first.  */
  cp = strptime (input, "%F", tm);
  if (cp == NULL)
    {
      /* Does not match.  Try the US form.  */
      cp = strptime (input, "%D", tm);
    }

  return cp;
}

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21.4.6.2 A More User-friendly Way to Parse Times and Dates

The Unix standard defines another function for parsing date strings. The interface is weird, but if the function happens to suit your application it is just fine. It is problematic to use this function in multi-threaded programs or libraries, since it returns a pointer to a static variable, and uses a global variable and global state (an environment variable).

Variable: getdate_err

This variable of type int contains the error code of the last unsuccessful call to getdate. Defined values are:

1

The environment variable DATEMSK is not defined or null.

2

The template file denoted by the DATEMSK environment variable cannot be opened.

3

Information about the template file cannot retrieved.

4

The template file is not a regular file.

5

An I/O error occurred while reading the template file.

6

Not enough memory available to execute the function.

7

The template file contains no matching template.

8

The input date is invalid, but would match a template otherwise. This includes dates like February 31st, and dates which cannot be represented in a time_t variable.

Function: struct tm * getdate (const char *string)

The interface to getdate is the simplest possible for a function to parse a string and return the value. string is the input string and the result is returned in a statically-allocated variable.

The details about how the string is processed are hidden from the user. In fact, they can be outside the control of the program. Which formats are recognized is controlled by the file named by the environment variable DATEMSK. This file should contain lines of valid format strings which could be passed to strptime.

The getdate function reads these format strings one after the other and tries to match the input string. The first line which completely matches the input string is used.

Elements not initialized through the format string retain the values present at the time of the getdate function call.

The formats recognized by getdate are the same as for strptime. See above for an explanation. There are only a few extensions to the strptime behavior:

It should be noted that the format in the template file need not only contain format elements. The following is a list of possible format strings (taken from the Unix standard):

 
%m
%A %B %d, %Y %H:%M:%S
%A
%B
%m/%d/%y %I %p
%d,%m,%Y %H:%M
at %A the %dst of %B in %Y
run job at %I %p,%B %dnd
%A den %d. %B %Y %H.%M Uhr

As you can see, the template list can contain very specific strings like run job at %I %p,%B %dnd. Using the above list of templates and assuming the current time is Mon Sep 22 12:19:47 EDT 1986 we can obtain the following results for the given input.

Input

Match

Result

Mon

%a

Mon Sep 22 12:19:47 EDT 1986

Sun

%a

Sun Sep 28 12:19:47 EDT 1986

Fri

%a

Fri Sep 26 12:19:47 EDT 1986

September

%B

Mon Sep 1 12:19:47 EDT 1986

January

%B

Thu Jan 1 12:19:47 EST 1987

December

%B

Mon Dec 1 12:19:47 EST 1986

Sep Mon

%b %a

Mon Sep 1 12:19:47 EDT 1986

Jan Fri

%b %a

Fri Jan 2 12:19:47 EST 1987

Dec Mon

%b %a

Mon Dec 1 12:19:47 EST 1986

Jan Wed 1989

%b %a %Y

Wed Jan 4 12:19:47 EST 1989

Fri 9

%a %H

Fri Sep 26 09:00:00 EDT 1986

Feb 10:30

%b %H:%S

Sun Feb 1 10:00:30 EST 1987

10:30

%H:%M

Tue Sep 23 10:30:00 EDT 1986

13:30

%H:%M

Mon Sep 22 13:30:00 EDT 1986

The return value of the function is a pointer to a static variable of type struct tm, or a null pointer if an error occurred. The result is only valid until the next getdate call, making this function unusable in multi-threaded applications.

The errno variable is not changed. Error conditions are stored in the global variable getdate_err. See the description above for a list of the possible error values.

Warning: The getdate function should never be used in SUID-programs. The reason is obvious: using the DATEMSK environment variable you can get the function to open any arbitrary file and chances are high that with some bogus input (such as a binary file) the program will crash.

Function: int getdate_r (const char *string, struct tm *tp)

The getdate_r function is the reentrant counterpart of getdate. It does not use the global variable getdate_err to signal an error, but instead returns an error code. The same error codes as described in the getdate_err documentation above are used, with 0 meaning success.

Moreover, getdate_r stores the broken-down time in the variable of type struct tm pointed to by the second argument, rather than in a static variable.

This function is not defined in the Unix standard. Nevertheless it is available on some other Unix systems as well.

The warning against using getdate in SUID-programs applies to getdate_r as well.


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21.4.7 Specifying the Time Zone with TZ

In POSIX systems, a user can specify the time zone by means of the TZ environment variable. For information about how to set environment variables, see Environment Variables. The functions for accessing the time zone are declared in ‘time.h’.

You should not normally need to set TZ. If the system is configured properly, the default time zone will be correct. You might set TZ if you are using a computer over a network from a different time zone, and would like times reported to you in the time zone local to you, rather than what is local to the computer.

In POSIX.1 systems the value of the TZ variable can be in one of three formats. With the GNU C library, the most common format is the last one, which can specify a selection from a large database of time zone information for many regions of the world. The first two formats are used to describe the time zone information directly, which is both more cumbersome and less precise. But the POSIX.1 standard only specifies the details of the first two formats, so it is good to be familiar with them in case you come across a POSIX.1 system that doesn't support a time zone information database.

The first format is used when there is no Daylight Saving Time (or summer time) in the local time zone:

 
std offset

The std string specifies the name of the time zone. It must be three or more characters long and must not contain a leading colon, embedded digits, commas, nor plus and minus signs. There is no space character separating the time zone name from the offset, so these restrictions are necessary to parse the specification correctly.

The offset specifies the time value you must add to the local time to get a Coordinated Universal Time value. It has syntax like [+|-]hh[:mm[:ss]]. This is positive if the local time zone is west of the Prime Meridian and negative if it is east. The hour must be between 0 and 23, and the minute and seconds between 0 and 59.

For example, here is how we would specify Eastern Standard Time, but without any Daylight Saving Time alternative:

 
EST+5

The second format is used when there is Daylight Saving Time:

 
std offset dst [offset],start[/time],end[/time]

The initial std and offset specify the standard time zone, as described above. The dst string and offset specify the name and offset for the corresponding Daylight Saving Time zone; if the offset is omitted, it defaults to one hour ahead of standard time.

The remainder of the specification describes when Daylight Saving Time is in effect. The start field is when Daylight Saving Time goes into effect and the end field is when the change is made back to standard time. The following formats are recognized for these fields:

Jn

This specifies the Julian day, with n between 1 and 365. February 29 is never counted, even in leap years.

n

This specifies the Julian day, with n between 0 and 365. February 29 is counted in leap years.

Mm.w.d

This specifies day d of week w of month m. The day d must be between 0 (Sunday) and 6. The week w must be between 1 and 5; week 1 is the first week in which day d occurs, and week 5 specifies the last d day in the month. The month m should be between 1 and 12.

The time fields specify when, in the local time currently in effect, the change to the other time occurs. If omitted, the default is 02:00:00.

For example, here is how you would specify the Eastern time zone in the United States, including the appropriate Daylight Saving Time and its dates of applicability. The normal offset from UTC is 5 hours; since this is west of the prime meridian, the sign is positive. Summer time begins on the first Sunday in April at 2:00am, and ends on the last Sunday in October at 2:00am.

 
EST+5EDT,M4.1.0/2,M10.5.0/2

The schedule of Daylight Saving Time in any particular jurisdiction has changed over the years. To be strictly correct, the conversion of dates and times in the past should be based on the schedule that was in effect then. However, this format has no facilities to let you specify how the schedule has changed from year to year. The most you can do is specify one particular schedule—usually the present day schedule—and this is used to convert any date, no matter when. For precise time zone specifications, it is best to use the time zone information database (see below).

The third format looks like this:

 
:characters

Each operating system interprets this format differently; in the GNU C library, characters is the name of a file which describes the time zone.

If the TZ environment variable does not have a value, the operation chooses a time zone by default. In the GNU C library, the default time zone is like the specification ‘TZ=:/etc/localtime’ (or ‘TZ=:/usr/local/etc/localtime’, depending on how GNU C library was configured; see section Installing the GNU C Library). Other C libraries use their own rule for choosing the default time zone, so there is little we can say about them.

If characters begins with a slash, it is an absolute file name; otherwise the library looks for the file ‘/share/lib/zoneinfo/characters’. The ‘zoneinfo’ directory contains data files describing local time zones in many different parts of the world. The names represent major cities, with subdirectories for geographical areas; for example, ‘America/New_York’, ‘Europe/London’, ‘Asia/Hong_Kong’. These data files are installed by the system administrator, who also sets ‘/etc/localtime’ to point to the data file for the local time zone. The GNU C library comes with a large database of time zone information for most regions of the world, which is maintained by a community of volunteers and put in the public domain.


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21.4.8 Functions and Variables for Time Zones

Variable: char * tzname [2]

The array tzname contains two strings, which are the standard names of the pair of time zones (standard and Daylight Saving) that the user has selected. tzname[0] is the name of the standard time zone (for example, "EST"), and tzname[1] is the name for the time zone when Daylight Saving Time is in use (for example, "EDT"). These correspond to the std and dst strings (respectively) from the TZ environment variable. If Daylight Saving Time is never used, tzname[1] is the empty string.

The tzname array is initialized from the TZ environment variable whenever tzset, ctime, strftime, mktime, or localtime is called. If multiple abbreviations have been used (e.g. "EWT" and "EDT" for U.S. Eastern War Time and Eastern Daylight Time), the array contains the most recent abbreviation.

The tzname array is required for POSIX.1 compatibility, but in GNU programs it is better to use the tm_zone member of the broken-down time structure, since tm_zone reports the correct abbreviation even when it is not the latest one.

Though the strings are declared as char * the user must refrain from modifying these strings. Modifying the strings will almost certainly lead to trouble.

Function: void tzset (void)

The tzset function initializes the tzname variable from the value of the TZ environment variable. It is not usually necessary for your program to call this function, because it is called automatically when you use the other time conversion functions that depend on the time zone.

The following variables are defined for compatibility with System V Unix. Like tzname, these variables are set by calling tzset or the other time conversion functions.

Variable: long int timezone

This contains the difference between UTC and the latest local standard time, in seconds west of UTC. For example, in the U.S. Eastern time zone, the value is 5*60*60. Unlike the tm_gmtoff member of the broken-down time structure, this value is not adjusted for daylight saving, and its sign is reversed. In GNU programs it is better to use tm_gmtoff, since it contains the correct offset even when it is not the latest one.

Variable: int daylight

This variable has a nonzero value if Daylight Saving Time rules apply. A nonzero value does not necessarily mean that Daylight Saving Time is now in effect; it means only that Daylight Saving Time is sometimes in effect.


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21.4.9 Time Functions Example

Here is an example program showing the use of some of the calendar time functions.

 
#include <time.h>
#include <stdio.h>

#define SIZE 256

int
main (void)
{
  char buffer[SIZE];
  time_t curtime;
  struct tm *loctime;

  /* Get the current time. */
  curtime = time (NULL);

  /* Convert it to local time representation. */
  loctime = localtime (&curtime);

  /* Print out the date and time in the standard format. */
  fputs (asctime (loctime), stdout);

  /* Print it out in a nice format. */
  strftime (buffer, SIZE, "Today is %A, %B %d.\n", loctime);
  fputs (buffer, stdout);
  strftime (buffer, SIZE, "The time is %I:%M %p.\n", loctime);
  fputs (buffer, stdout);

  return 0;
}

It produces output like this:

 
Wed Jul 31 13:02:36 1991
Today is Wednesday, July 31.
The time is 01:02 PM.

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21.5 Setting an Alarm

The alarm and setitimer functions provide a mechanism for a process to interrupt itself in the future. They do this by setting a timer; when the timer expires, the process receives a signal.

Each process has three independent interval timers available:

You can only have one timer of each kind set at any given time. If you set a timer that has not yet expired, that timer is simply reset to the new value.

You should establish a handler for the appropriate alarm signal using signal or sigaction before issuing a call to setitimer or alarm. Otherwise, an unusual chain of events could cause the timer to expire before your program establishes the handler. In this case it would be terminated, since termination is the default action for the alarm signals. See section Signal Handling.

To be able to use the alarm function to interrupt a system call which might block otherwise indefinitely it is important to not set the SA_RESTART flag when registering the signal handler using sigaction. When not using sigaction things get even uglier: the signal function has to fixed semantics with respect to restarts. The BSD semantics for this function is to set the flag. Therefore, if sigaction for whatever reason cannot be used, it is necessary to use sysv_signal and not signal.

The setitimer function is the primary means for setting an alarm. This facility is declared in the header file ‘sys/time.h’. The alarm function, declared in ‘unistd.h’, provides a somewhat simpler interface for setting the real-time timer.

Data Type: struct itimerval

This structure is used to specify when a timer should expire. It contains the following members:

struct timeval it_interval

This is the period between successive timer interrupts. If zero, the alarm will only be sent once.

struct timeval it_value

This is the period between now and the first timer interrupt. If zero, the alarm is disabled.

The struct timeval data type is described in Elapsed Time.

Function: int setitimer (int which, struct itimerval *new, struct itimerval *old)

The setitimer function sets the timer specified by which according to new. The which argument can have a value of ITIMER_REAL, ITIMER_VIRTUAL, or ITIMER_PROF.

If old is not a null pointer, setitimer returns information about any previous unexpired timer of the same kind in the structure it points to.

The return value is 0 on success and -1 on failure. The following errno error conditions are defined for this function:

EINVAL

The timer period is too large.

Function: int getitimer (int which, struct itimerval *old)

The getitimer function stores information about the timer specified by which in the structure pointed at by old.

The return value and error conditions are the same as for setitimer.

ITIMER_REAL

This constant can be used as the which argument to the setitimer and getitimer functions to specify the real-time timer.

ITIMER_VIRTUAL

This constant can be used as the which argument to the setitimer and getitimer functions to specify the virtual timer.

ITIMER_PROF

This constant can be used as the which argument to the setitimer and getitimer functions to specify the profiling timer.

Function: unsigned int alarm (unsigned int seconds)

The alarm function sets the real-time timer to expire in seconds seconds. If you want to cancel any existing alarm, you can do this by calling alarm with a seconds argument of zero.

The return value indicates how many seconds remain before the previous alarm would have been sent. If there is no previous alarm, alarm returns zero.

The alarm function could be defined in terms of setitimer like this:

 
unsigned int
alarm (unsigned int seconds)
{
  struct itimerval old, new;
  new.it_interval.tv_usec = 0;
  new.it_interval.tv_sec = 0;
  new.it_value.tv_usec = 0;
  new.it_value.tv_sec = (long int) seconds;
  if (setitimer (ITIMER_REAL, &new, &old) < 0)
    return 0;
  else
    return old.it_value.tv_sec;
}

There is an example showing the use of the alarm function in Signal Handlers that Return.

If you simply want your process to wait for a given number of seconds, you should use the sleep function. See section Sleeping.

You shouldn't count on the signal arriving precisely when the timer expires. In a multiprocessing environment there is typically some amount of delay involved.

Portability Note: The setitimer and getitimer functions are derived from BSD Unix, while the alarm function is specified by the POSIX.1 standard. setitimer is more powerful than alarm, but alarm is more widely used.


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21.6 Sleeping

The function sleep gives a simple way to make the program wait for a short interval. If your program doesn't use signals (except to terminate), then you can expect sleep to wait reliably throughout the specified interval. Otherwise, sleep can return sooner if a signal arrives; if you want to wait for a given interval regardless of signals, use select (see section Waiting for Input or Output) and don't specify any descriptors to wait for.

Function: unsigned int sleep (unsigned int seconds)

The sleep function waits for seconds or until a signal is delivered, whichever happens first.

If sleep function returns because the requested interval is over, it returns a value of zero. If it returns because of delivery of a signal, its return value is the remaining time in the sleep interval.

The sleep function is declared in ‘unistd.h’.

Resist the temptation to implement a sleep for a fixed amount of time by using the return value of sleep, when nonzero, to call sleep again. This will work with a certain amount of accuracy as long as signals arrive infrequently. But each signal can cause the eventual wakeup time to be off by an additional second or so. Suppose a few signals happen to arrive in rapid succession by bad luck—there is no limit on how much this could shorten or lengthen the wait.

Instead, compute the calendar time at which the program should stop waiting, and keep trying to wait until that calendar time. This won't be off by more than a second. With just a little more work, you can use select and make the waiting period quite accurate. (Of course, heavy system load can cause additional unavoidable delays—unless the machine is dedicated to one application, there is no way you can avoid this.)

On some systems, sleep can do strange things if your program uses SIGALRM explicitly. Even if SIGALRM signals are being ignored or blocked when sleep is called, sleep might return prematurely on delivery of a SIGALRM signal. If you have established a handler for SIGALRM signals and a SIGALRM signal is delivered while the process is sleeping, the action taken might be just to cause sleep to return instead of invoking your handler. And, if sleep is interrupted by delivery of a signal whose handler requests an alarm or alters the handling of SIGALRM, this handler and sleep will interfere.

On the GNU system, it is safe to use sleep and SIGALRM in the same program, because sleep does not work by means of SIGALRM.

Function: int nanosleep (const struct timespec *requested_time, struct timespec *remaining)

If resolution to seconds is not enough the nanosleep function can be used. As the name suggests the sleep interval can be specified in nanoseconds. The actual elapsed time of the sleep interval might be longer since the system rounds the elapsed time you request up to the next integer multiple of the actual resolution the system can deliver.

*requested_time is the elapsed time of the interval you want to sleep.

The function returns as *remaining the elapsed time left in the interval for which you requested to sleep. If the interval completed without getting interrupted by a signal, this is zero.

struct timespec is described in See section Elapsed Time.

If the function returns because the interval is over the return value is zero. If the function returns -1 the global variable errno is set to the following values:

EINTR

The call was interrupted because a signal was delivered to the thread. If the remaining parameter is not the null pointer the structure pointed to by remaining is updated to contain the remaining elapsed time.

EINVAL

The nanosecond value in the requested_time parameter contains an illegal value. Either the value is negative or greater than or equal to 1000 million.

This function is a cancellation point in multi-threaded programs. This is a problem if the thread allocates some resources (like memory, file descriptors, semaphores or whatever) at the time nanosleep is called. If the thread gets canceled these resources stay allocated until the program ends. To avoid this calls to nanosleep should be protected using cancellation handlers.

The nanosleep function is declared in ‘time.h’.


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