Go to the previous, next section.
This chapter describes functions for manipulating dates and times, including functions for determining what the current time is and conversion between different time representations.
The time functions fall into three main categories:
If you're trying to optimize your program or measure its efficiency, it's
very useful to be able to know how much processor time or CPU
time it has used at any given point. Processor time is different from
actual wall clock time because it doesn't include any time spent waiting
for I/O or when some other process is running. Processor time is
represented by the data type clock_t, and is given as a number of
clock ticks relative to an arbitrary base time marking the beginning
of a single program invocation.
To get the elapsed CPU time used by a process, 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), like this:
#include <time.h> clock_t start, end; double elapsed; start = clock(); ... /* Do the work. */ end = clock(); elapsed = ((double) (end - start)) / CLOCKS_PER_SEC;
Different computers and operating systems vary wildly in how they keep track of processor time. It's common for the internal processor clock to have a resolution somewhere between hundredths and millionths of a second.
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 type of the macro CLOCKS_PER_SEC can be
either integer or floating-point types. Casting processor 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.
The value of this macro is the number of clock ticks per second measured
by the clock function.
This is an obsolete name for CLOCKS_PER_SEC.
This is the type of the value returned by the clock function.
Values of type clock_t are in units of clock ticks.
Function: clock_t clock (void)
This function returns the elapsed processor time. The base time is
arbitrary but doesn't change within a single process. If the processor
time is not available or cannot be represented, clock returns the
value (clock_t)(-1).
The times function returns more detailed information about
elapsed processor time in a struct tms object. You should
include the header file `sys/times.h' to use this facility.
The tms structure is used to return information about process
times. It contains at least the following members:
clock_t tms_utime
clock_t tms_stime
clock_t tms_cutime
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 section Process Completion. In other words, it represents
the total CPU time used in executing the instructions of all the terminated
child processes of the calling process.
clock_t tms_cstime
tms_cutime, but represents the total CPU time
used by the system on behalf of all the terminated child processes of the
calling process.
All of the times are given in clock ticks. These are absolute values; in a newly created process, they are all zero. 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 same as the value of clock(): the elapsed
real time relative to an arbitrary base. The base is a constant within a
particular process, and typically represents the time since system
start-up. A value of (clock_t)(-1) is returned to indicate failure.
Portability Note: The clock function described in
section Basic CPU Time Inquiry, is specified by the ANSI C standard. The
times function is a feature of POSIX.1. In the GNU system, the
value returned by the clock function is equivalent to the sum of
the tms_utime and tms_stime fields returned by
times.
This section describes facilities for keeping track of dates and times according to the Gregorian calendar.
There are three representations for date and time information:
time_t data type) is a compact
representation, typically giving the number of seconds elapsed since
some implementation-specific base time.
struct
timeval data type) that includes fractions of a second. Use this time
representation instead of ordinary calendar time when you need greater
precision.
struct
tm data type) represents the date and time as a set of components
specifying the year, month, and so on, for a specific time zone.
This time representation is usually used in conjunction with formatting
date and time values.
This section describes the time_t data type for representing
calendar time, and the functions which operate on calendar time objects.
These facilities are declared in the header file `time.h'.
This is the data type used to represent calendar time. In the GNU C
library and other POSIX-compliant implementations, time_t is
equivalent to long int. When interpreted as an absolute time
value, it represents the number of seconds elapsed since 00:00:00 on
January 1, 1970, Coordinated Universal Time. (This date is sometimes
referred to as the epoch.)
In other systems, time_t might be either an integer or
floating-point type.
Function: double difftime (time_t time1, time_t time0)
The difftime function returns the number of seconds elapsed
between time time1 and time time0, as a value of type
double.
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.
Function: time_t time (time_t *result)
The time function returns the current time as a value of type
time_t. If the argument result is not a null pointer, the
time value is also stored in *result. If the calendar
time is not available, the value (time_t)(-1) is returned.
The time_t data type used to represent calendar 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'.
The struct timeval structure represents a calendar time. It
has the following members:
long int tv_sec
time_t value.
long int tv_usec
Some times struct timeval values are user for time intervals. Then the
tv_sec member is the number of seconds in the interval, and
tv_usec is the number of addictional microseconds.
The struct timezone structure is used to hold minimal information
about the local time zone. It has the following members:
int tz_minuteswest
int tz_dsttime
It is often necessary to subtract two values of type struct
timeval. 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 = (y->tv_usec - x->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;
}
Function: int gettimeofday (struct timeval *tp, struct timezone *tzp)
The gettimeofday function returns the current date and time in the
struct timeval structure indicated by tp. 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
struct timezone to represent time zone
information. Use tzname et al instead. Say something
more helpful here.
Function: int settimeofday (const struct timeval *tp, const struct timezone *tzp)
The settimeofday function sets the current date and time
according to the arguments. 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.
The return value is 0 on success and -1 on failure. The
following errno error conditions are defined for this function:
EPERM
ENOSYS
Function: int adjtime (const struct timeval *delta, struct timeval *olddelta)
This function speeds up or slows down the system clock in order to make gradual adjustments in the current time. This ensures that the time reported by the system clock is always monotonically increasing, which might not happen if you simply set the current time.
The delta argument specifies a relative adjustment to be made to the current time. If negative, the system clock is slowed down for a while until it has lost this much 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.
The return value is 0 on success and -1 on failure. The
following errno error condition is defined for this function:
EPERM
Portability Note: The gettimeofday, settimeofday,
and adjtime functions are derived from BSD.
Calender time is represented as a number of seconds. This is convenient for calculation, but has no resemblance to the way people normally represent dates and times. By contrast, broken-down time is a binary representation 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.
A broken-down time value is always relative to a choice of local time zone, and it also indicates which time zone was used.
The symbols in this section are declared in the header file `time.h'.
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
0 to 59. (The actual upper limit is 61, to allow
for "leap seconds".)
int tm_min
0 to
59.
int tm_hour
0 to
23.
int tm_mday
1 to 31.
int tm_mon
0 to
11.
int tm_year
1900.
int tm_wday
0 to 6.
int tm_yday
0 to
365.
int tm_isdst
long int tm_gmtoff
timezone (see section Functions and Variables for Time Zones). You can
also think of this as the "number of seconds west" of GMT. The
tm_gmtoff field is a GNU library extension.
const char *tm_zone
Function: struct tm * localtime (const time_t *time)
The localtime function converts the calendar 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 any of the date and time functions. (But no other library function overwrites the contents of this object.)
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.
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)---that is, as
Greenwich Mean Time (GMT) rather than relative to the local time zone.
Recall that calendar times are always expressed in coordinated universal time.
Function: time_t mktime (struct tm *brokentime)
The mktime function is used to convert a broken-down time structure
to a calendar 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 compute the
calendar time; it's permissible for these components to have
unnormalized values outside of 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 calendar 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.
The functions described in this section format time values as strings. These functions are declared in the header file `time.h'.
Function: char * asctime (const struct tm *brokentime)
The asctime function writes the broken-down time value pointed at by
brokentime 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 any of the date and time functions. (But no other library function overwrites the contents of this string.)
Function: char * ctime (const time_t *time)
The ctime function is similar to asctime, except that
the time value is specified in calendar time (rather than 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: 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, and are replaced in the output string as follows:
%a
%A
%b
%B
%c
%d
01 to 31).
%H
00 to
23).
%I
01 to
12).
%j
001 to 366).
%m
01 to 12).
%M
%p
%S
%U
%W
%w
0.
%x
%X
%y
00 to
99).
%Y
%Z
%%
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, the excess characters are discarded. The return value from
strftime is the number of characters placed in the array s,
not including the terminating null character. If the value equals
size, it means that the array s was too small; you should
repeat the call, providing a bigger array.
For an example of strftime, see section Time Functions Example.
TZ
In the GNU system, a user can specify the time zone by means of the
TZ environment variable. For information about how to set
environment variables, see section Environment Variables. The functions for
accessing the time zone are declared in `time.h'.
The value of the TZ variable can be of one of three formats. 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 or embedded digits, commas, or plus or 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 one 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
24, and the minute and seconds between 0 and 59.
For example, here is how we would specify Eastern Standard Time, but without any daylight savings 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 savings time time zone; if the offset is omitted, it defaults to one hour ahead of standard time.
The remainder of the specification describes when daylight savings time is in effect. The start field is when daylight savings 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
1 and 365.
February 29 is never counted, even in leap years.
n
0 and 365.
February 29 is counted in leap years.
Mm.w.d
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 one 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 GMT 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/M10.5.0
The schedule of daylight savings 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, the system 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.
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. Each operating system has its
own rules for choosing the default time zone, so there is little we can
say about them.
The array tzname contains two strings, which are the standard
three-letter names of the pair of time zones (standard and daylight
savings) 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 savings time is in use (for
example, "EDT"). These correspond to the std and dst
strings (respectively) from the TZ environment variable.
The tzname array is initialized from the TZ environment
variable whenever tzset, ctime, strftime,
mktime, or localtime is called.
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. These variables are set by calling localtime.
This contains the difference between GMT and local standard time, in
seconds. For example, in the U.S. Eastern time zone, the value is
5*60*60.
This variable has a nonzero value if the standard U.S. daylight savings time rules apply.
Here is an example program showing the use of some of the local time and 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.
The alarm and setitimer functions provide a mechanism for a
process to interrupt itself at some future time. They do this by setting a
timer; when the timer expires, the process recieves a signal.
Each process has three independent interval timers available:
SIGALRM signal to the process when it expires.
SIGVTALRM signal to the process when it expires.
SIGPROF signal to the process when it expires.
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, and in that
case it would be terminated, since that is the default action for the alarm
signals. See section Signal Handling.
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.
This structure is used to specify when a timer should expire. It contains the following members:
struct timeval it_interval
struct timeval it_value
The struct timeval data type is described in section High-Resolution Calendar.
Function: int setitimer (int which, struct itimerval *old, struct itimerval *new)
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
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
setitimer and getitimer functions to specify the real-time
timer.
ITIMER_VIRTUAL
setitimer and getitimer functions to specify the virtual
timer.
ITIMER_PROF
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
section 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.
The function sleep gives a simple way to make the program wait
for short periods of time. If your program doesn't use signals (except
to terminate), then you can expect sleep to wait reliably for
the specified amount of time. Otherwise, sleep can return sooner
if a signal arrives; if you want to wait for a given period 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 time has
elapsed, 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 period.
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 time at which the program should stop waiting, and
keep trying to wait until that 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 unavoidable additional 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.
The function getrusage and the data type struct rusage
are used for examining the usage figures of a process. They are declared
in `sys/resource.h'.
Function: int getrusage (int processes, struct rusage *rusage)
This function reports the usage totals for processes specified by
processes, storing the information in *rusage.
In most systems, processes has only two valid values:
RUSAGE_SELF
RUSAGE_CHILDREN
In the GNU system, you can also inquire about a particular child process by specifying its process ID.
The return value of getrusage is zero for success, and -1
for failure.
EINVAL
One way of getting usage figures for a particular child process is with
the function wait4, which returns totals for a child when it
terminates. See section BSD Process Wait Functions.
This data type records a collection usage amounts for various sorts of resources. It has the following members, and possibly others:
struct timeval ru_utime
struct timeval ru_stime
long ru_majflt
long ru_inblock
long ru_oublock
long ru_msgsnd
long ru_msgrcv
long ru_nsignals
An additional historical function for examining usage figures,
vtimes, is supported but not documented here. It is declared in
`sys/vtimes.h'.
You can specify limits for the resource usage of a process. When the process tries to exceed a limit, it may get a signal, or the system call by which it tried to do so may fail, depending on the limit. Each process initially inherits its limit values from its parent, but it can subsequently change them.
The symbols in this section are defined in `sys/resource.h'.
Function: int getrlimit (int resource, struct rlimit *rlp)
Read the current value and the maximum value of resource resource
and store them in *rlp.
The return value is 0 on success and -1 on failure. The
only possible errno error condition is EFAULT.
Function: int setrlimit (int resource, struct rlimit *rlp)
Store the current value and the maximum value of resource resource
in *rlp.
The return value is 0 on success and -1 on failure. The
following errno error condition is possible:
EPERM
This structure is used with getrlimit to receive limit values,
and with setrlimit to specify limit values. It has two fields:
rlim_cur
rlim_max
In getrlimit, the structure is an output; it receives the current
values. In setrlimit, it specifies the new values.
Here is a list of resources that you can specify a limit for. Those that are sizes are measured in bytes.
RLIMIT_CPU
SIGXCPU. The value is
measured in seconds. See section Nonstandard Signals.
RLIMIT_FSIZE
SIGXFSZ. See section Nonstandard Signals.
RLIMIT_DATA
RLIMIT_STACK
SIGSEGV signal.
See section Program Error Signals.
RLIMIT_CORE
RLIMIT_RSS
RLIMIT_OPEN_FILES
EMFILE. See section Error Codes.
RLIM_NLIMITS
RLIM_NLIMITS.
This constant stands for a value of "infinity" when supplied as
the limit value in setrlimit.
Two historical functions for setting resource limits, ulimit and
vlimit, are not documented here. The latter is declared in
`sys/vlimit.h' and comes from BSD.
When several processes try to run, their respective priorities determine what share of the CPU each process gets. This section describes how you can read and set the priority of a process. All these functions and macros are declared in `sys/resource.h'.
The range of valid priority values depends on the operating system, but
typically it runs from -20 to 20. A lower priority value
means the process runs more often. These constants describe the range of
priority values:
Function: int getpriority (int class, int id)
Read the priority of a class of processes; class and id specify which ones (see below).
The return value is the priority value on success, and -1 on
failure. The following errno error condition are possible for
this function:
ESRCH
EINVAL
When the return value is -1, it could indicate failure, or it
could be the priority value. The only way to make certain is to set
errno = 0 before calling getpriority, then use errno
!= 0 afterward as the criterion for failure.
Function: int setpriority (int class, int id, int priority)
Read the priority of a class of processes; class and id specify which ones (see below).
The return value is 0 on success and -1 on failure. The
following errno error condition are defined for this function:
ESRCH
EINVAL
EPERM
EACCES
The arguments class and id together specify a set of processes you are interested in. These are the possible values for class:
PRIO_PROCESS
PRIO_PGRP
PRIO_USER
If the argument id is 0, it stands for the current process, current process group, or the current user, according to class.
Function: int nice (int increment)
Increment the priority of the current process by increment. The return value is not meaningful.
Here is an equivalent definition for nice:
int
nice (int increment)
{
int old = getpriority (PRIO_PROCESS, 0);
setpriority (PRIO_PROCESS, 0, old + increment);
}
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