1 @node Resource Usage And Limitation, Non-Local Exits, Date and Time, Top
2 @c %MENU% Functions for examining resource usage and getting and setting limits
3 @chapter Resource Usage And Limitation
4 This chapter describes functions for examining how much of various kinds of
5 resources (CPU time, memory, etc.) a process has used and getting and setting
6 limits on future usage.
9 * Resource Usage:: Measuring various resources used.
10 * Limits on Resources:: Specifying limits on resource usage.
11 * Priority:: Reading or setting process run priority.
12 * Memory Resources:: Querying memory available resources.
13 * Processor Resources:: Learn about the processors available.
18 @section Resource Usage
20 @pindex sys/resource.h
21 The function @code{getrusage} and the data type @code{struct rusage}
22 are used to examine the resource usage of a process. They are declared
23 in @file{sys/resource.h}.
25 @comment sys/resource.h
27 @deftypefun int getrusage (int @var{processes}, struct rusage *@var{rusage})
28 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
29 @c On HURD, this calls task_info 3 times. On UNIX, it's a syscall.
30 This function reports resource usage totals for processes specified by
31 @var{processes}, storing the information in @code{*@var{rusage}}.
33 In most systems, @var{processes} has only two valid values:
36 @comment sys/resource.h
39 Just the current process.
41 @comment sys/resource.h
44 All child processes (direct and indirect) that have already terminated.
47 The return value of @code{getrusage} is zero for success, and @code{-1}
52 The argument @var{processes} is not valid.
56 One way of getting resource usage for a particular child process is with
57 the function @code{wait4}, which returns totals for a child when it
58 terminates. @xref{BSD Wait Functions}.
60 @comment sys/resource.h
62 @deftp {Data Type} {struct rusage}
63 This data type stores various resource usage statistics. It has the
64 following members, and possibly others:
67 @item struct timeval ru_utime
68 Time spent executing user instructions.
70 @item struct timeval ru_stime
71 Time spent in operating system code on behalf of @var{processes}.
73 @item long int ru_maxrss
74 The maximum resident set size used, in kilobytes. That is, the maximum
75 number of kilobytes of physical memory that @var{processes} used
78 @item long int ru_ixrss
79 An integral value expressed in kilobytes times ticks of execution, which
80 indicates the amount of memory used by text that was shared with other
83 @item long int ru_idrss
84 An integral value expressed the same way, which is the amount of
85 unshared memory used for data.
87 @item long int ru_isrss
88 An integral value expressed the same way, which is the amount of
89 unshared memory used for stack space.
91 @item long int ru_minflt
92 The number of page faults which were serviced without requiring any I/O.
94 @item long int ru_majflt
95 The number of page faults which were serviced by doing I/O.
97 @item long int ru_nswap
98 The number of times @var{processes} was swapped entirely out of main memory.
100 @item long int ru_inblock
101 The number of times the file system had to read from the disk on behalf
104 @item long int ru_oublock
105 The number of times the file system had to write to the disk on behalf
108 @item long int ru_msgsnd
109 Number of IPC messages sent.
111 @item long int ru_msgrcv
112 Number of IPC messages received.
114 @item long int ru_nsignals
115 Number of signals received.
117 @item long int ru_nvcsw
118 The number of times @var{processes} voluntarily invoked a context switch
119 (usually to wait for some service).
121 @item long int ru_nivcsw
122 The number of times an involuntary context switch took place (because
123 a time slice expired, or another process of higher priority was
128 @code{vtimes} is a historical function that does some of what
129 @code{getrusage} does. @code{getrusage} is a better choice.
131 @code{vtimes} and its @code{vtimes} data structure are declared in
135 @comment sys/vtimes.h
136 @deftypefun int vtimes (struct vtimes *@var{current}, struct vtimes *@var{child})
137 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
138 @c Calls getrusage twice.
140 @code{vtimes} reports resource usage totals for a process.
142 If @var{current} is non-null, @code{vtimes} stores resource usage totals for
143 the invoking process alone in the structure to which it points. If
144 @var{child} is non-null, @code{vtimes} stores resource usage totals for all
145 past children (which have terminated) of the invoking process in the structure
148 @deftp {Data Type} {struct vtimes}
149 This data type contains information about the resource usage of a process.
150 Each member corresponds to a member of the @code{struct rusage} data type
155 User CPU time. Analogous to @code{ru_utime} in @code{struct rusage}
157 System CPU time. Analogous to @code{ru_stime} in @code{struct rusage}
159 Data and stack memory. The sum of the values that would be reported as
160 @code{ru_idrss} and @code{ru_isrss} in @code{struct rusage}
162 Shared memory. Analogous to @code{ru_ixrss} in @code{struct rusage}
164 Maximent resident set size. Analogous to @code{ru_maxrss} in
167 Major page faults. Analogous to @code{ru_majflt} in @code{struct rusage}
169 Minor page faults. Analogous to @code{ru_minflt} in @code{struct rusage}
171 Swap count. Analogous to @code{ru_nswap} in @code{struct rusage}
173 Disk reads. Analogous to @code{ru_inblk} in @code{struct rusage}
175 Disk writes. Analogous to @code{ru_oublk} in @code{struct rusage}
180 The return value is zero if the function succeeds; @code{-1} otherwise.
185 An additional historical function for examining resource usage,
186 @code{vtimes}, is supported but not documented here. It is declared in
189 @node Limits on Resources
190 @section Limiting Resource Usage
191 @cindex resource limits
192 @cindex limits on resource usage
195 You can specify limits for the resource usage of a process. When the
196 process tries to exceed a limit, it may get a signal, or the system call
197 by which it tried to do so may fail, depending on the resource. Each
198 process initially inherits its limit values from its parent, but it can
199 subsequently change them.
201 There are two per-process limits associated with a resource:
206 The current limit is the value the system will not allow usage to
207 exceed. It is also called the ``soft limit'' because the process being
208 limited can generally raise the current limit at will.
209 @cindex current limit
213 The maximum limit is the maximum value to which a process is allowed to
214 set its current limit. It is also called the ``hard limit'' because
215 there is no way for a process to get around it. A process may lower
216 its own maximum limit, but only the superuser may increase a maximum
218 @cindex maximum limit
222 @pindex sys/resource.h
223 The symbols for use with @code{getrlimit}, @code{setrlimit},
224 @code{getrlimit64}, and @code{setrlimit64} are defined in
225 @file{sys/resource.h}.
227 @comment sys/resource.h
229 @deftypefun int getrlimit (int @var{resource}, struct rlimit *@var{rlp})
230 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
231 @c Direct syscall on most systems.
232 Read the current and maximum limits for the resource @var{resource}
233 and store them in @code{*@var{rlp}}.
235 The return value is @code{0} on success and @code{-1} on failure. The
236 only possible @code{errno} error condition is @code{EFAULT}.
238 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
239 32-bit system this function is in fact @code{getrlimit64}. Thus, the
240 LFS interface transparently replaces the old interface.
243 @comment sys/resource.h
245 @deftypefun int getrlimit64 (int @var{resource}, struct rlimit64 *@var{rlp})
246 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
247 @c Direct syscall on most systems, wrapper to getrlimit otherwise.
248 This function is similar to @code{getrlimit} but its second parameter is
249 a pointer to a variable of type @code{struct rlimit64}, which allows it
250 to read values which wouldn't fit in the member of a @code{struct
253 If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
254 32-bit machine, this function is available under the name
255 @code{getrlimit} and so transparently replaces the old interface.
258 @comment sys/resource.h
260 @deftypefun int setrlimit (int @var{resource}, const struct rlimit *@var{rlp})
261 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
262 @c Direct syscall on most systems; lock-taking critical section on HURD.
263 Store the current and maximum limits for the resource @var{resource}
264 in @code{*@var{rlp}}.
266 The return value is @code{0} on success and @code{-1} on failure. The
267 following @code{errno} error condition is possible:
273 The process tried to raise a current limit beyond the maximum limit.
276 The process tried to raise a maximum limit, but is not superuser.
280 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
281 32-bit system this function is in fact @code{setrlimit64}. Thus, the
282 LFS interface transparently replaces the old interface.
285 @comment sys/resource.h
287 @deftypefun int setrlimit64 (int @var{resource}, const struct rlimit64 *@var{rlp})
288 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
289 @c Wrapper for setrlimit or direct syscall.
290 This function is similar to @code{setrlimit} but its second parameter is
291 a pointer to a variable of type @code{struct rlimit64} which allows it
292 to set values which wouldn't fit in the member of a @code{struct
295 If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
296 32-bit machine this function is available under the name
297 @code{setrlimit} and so transparently replaces the old interface.
300 @comment sys/resource.h
302 @deftp {Data Type} {struct rlimit}
303 This structure is used with @code{getrlimit} to receive limit values,
304 and with @code{setrlimit} to specify limit values for a particular process
305 and resource. It has two fields:
308 @item rlim_t rlim_cur
311 @item rlim_t rlim_max
315 For @code{getrlimit}, the structure is an output; it receives the current
316 values. For @code{setrlimit}, it specifies the new values.
319 For the LFS functions a similar type is defined in @file{sys/resource.h}.
321 @comment sys/resource.h
323 @deftp {Data Type} {struct rlimit64}
324 This structure is analogous to the @code{rlimit} structure above, but
325 its components have wider ranges. It has two fields:
328 @item rlim64_t rlim_cur
329 This is analogous to @code{rlimit.rlim_cur}, but with a different type.
331 @item rlim64_t rlim_max
332 This is analogous to @code{rlimit.rlim_max}, but with a different type.
337 Here is a list of resources for which you can specify a limit. Memory
338 and file sizes are measured in bytes.
341 @comment sys/resource.h
345 The maximum amount of CPU time the process can use. If it runs for
346 longer than this, it gets a signal: @code{SIGXCPU}. The value is
347 measured in seconds. @xref{Operation Error Signals}.
349 @comment sys/resource.h
353 The maximum size of file the process can create. Trying to write a
354 larger file causes a signal: @code{SIGXFSZ}. @xref{Operation Error
357 @comment sys/resource.h
361 The maximum size of data memory for the process. If the process tries
362 to allocate data memory beyond this amount, the allocation function
365 @comment sys/resource.h
369 The maximum stack size for the process. If the process tries to extend
370 its stack past this size, it gets a @code{SIGSEGV} signal.
371 @xref{Program Error Signals}.
373 @comment sys/resource.h
377 The maximum size core file that this process can create. If the process
378 terminates and would dump a core file larger than this, then no core
379 file is created. So setting this limit to zero prevents core files from
382 @comment sys/resource.h
386 The maximum amount of physical memory that this process should get.
387 This parameter is a guide for the system's scheduler and memory
388 allocator; the system may give the process more memory when there is a
391 @comment sys/resource.h
394 The maximum amount of memory that can be locked into physical memory (so
395 it will never be paged out).
397 @comment sys/resource.h
400 The maximum number of processes that can be created with the same user ID.
401 If you have reached the limit for your user ID, @code{fork} will fail
402 with @code{EAGAIN}. @xref{Creating a Process}.
404 @comment sys/resource.h
407 @vindex RLIMIT_NOFILE
410 The maximum number of files that the process can open. If it tries to
411 open more files than this, its open attempt fails with @code{errno}
412 @code{EMFILE}. @xref{Error Codes}. Not all systems support this limit;
413 GNU does, and 4.4 BSD does.
415 @comment sys/resource.h
419 The maximum size of total memory that this process should get. If the
420 process tries to allocate more memory beyond this amount with, for
421 example, @code{brk}, @code{malloc}, @code{mmap} or @code{sbrk}, the
422 allocation function fails.
424 @comment sys/resource.h
428 The number of different resource limits. Any valid @var{resource}
429 operand must be less than @code{RLIM_NLIMITS}.
432 @comment sys/resource.h
434 @deftypevr Constant rlim_t RLIM_INFINITY
435 This constant stands for a value of ``infinity'' when supplied as
436 the limit value in @code{setrlimit}.
440 The following are historical functions to do some of what the functions
441 above do. The functions above are better choices.
443 @code{ulimit} and the command symbols are declared in @file{ulimit.h}.
448 @deftypefun {long int} ulimit (int @var{cmd}, @dots{})
449 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
450 @c Wrapper for getrlimit, setrlimit or
451 @c sysconf(_SC_OPEN_MAX)->getdtablesize->getrlimit.
453 @code{ulimit} gets the current limit or sets the current and maximum
454 limit for a particular resource for the calling process according to the
457 If you are getting a limit, the command argument is the only argument.
458 If you are setting a limit, there is a second argument:
459 @code{long int} @var{limit} which is the value to which you are setting
462 The @var{cmd} values and the operations they specify are:
466 Get the current limit on the size of a file, in units of 512 bytes.
469 Set the current and maximum limit on the size of a file to @var{limit} *
474 There are also some other @var{cmd} values that may do things on some
475 systems, but they are not supported.
477 Only the superuser may increase a maximum limit.
479 When you successfully get a limit, the return value of @code{ulimit} is
480 that limit, which is never negative. When you successfully set a limit,
481 the return value is zero. When the function fails, the return value is
482 @code{-1} and @code{errno} is set according to the reason:
486 A process tried to increase a maximum limit, but is not superuser.
492 @code{vlimit} and its resource symbols are declared in @file{sys/vlimit.h}.
495 @comment sys/vlimit.h
497 @deftypefun int vlimit (int @var{resource}, int @var{limit})
498 @safety{@prelim{}@mtunsafe{@mtasurace{:setrlimit}}@asunsafe{}@acsafe{}}
499 @c It calls getrlimit and modifies the rlim_cur field before calling
500 @c setrlimit. There's a window for a concurrent call to setrlimit that
501 @c modifies e.g. rlim_max, which will be lost if running as super-user.
503 @code{vlimit} sets the current limit for a resource for a process.
505 @var{resource} identifies the resource:
509 Maximum CPU time. Same as @code{RLIMIT_CPU} for @code{setrlimit}.
511 Maximum file size. Same as @code{RLIMIT_FSIZE} for @code{setrlimit}.
513 Maximum data memory. Same as @code{RLIMIT_DATA} for @code{setrlimit}.
515 Maximum stack size. Same as @code{RLIMIT_STACK} for @code{setrlimit}.
517 Maximum core file size. Same as @code{RLIMIT_COR} for @code{setrlimit}.
519 Maximum physical memory. Same as @code{RLIMIT_RSS} for @code{setrlimit}.
522 The return value is zero for success, and @code{-1} with @code{errno} set
523 accordingly for failure:
527 The process tried to set its current limit beyond its maximum limit.
533 @section Process CPU Priority And Scheduling
534 @cindex process priority
536 @cindex priority of a process
538 When multiple processes simultaneously require CPU time, the system's
539 scheduling policy and process CPU priorities determine which processes
540 get it. This section describes how that determination is made and
541 @glibcadj{} functions to control it.
543 It is common to refer to CPU scheduling simply as scheduling and a
544 process' CPU priority simply as the process' priority, with the CPU
545 resource being implied. Bear in mind, though, that CPU time is not the
546 only resource a process uses or that processes contend for. In some
547 cases, it is not even particularly important. Giving a process a high
548 ``priority'' may have very little effect on how fast a process runs with
549 respect to other processes. The priorities discussed in this section
550 apply only to CPU time.
552 CPU scheduling is a complex issue and different systems do it in wildly
553 different ways. New ideas continually develop and find their way into
554 the intricacies of the various systems' scheduling algorithms. This
555 section discusses the general concepts, some specifics of systems
556 that commonly use @theglibc{}, and some standards.
558 For simplicity, we talk about CPU contention as if there is only one CPU
559 in the system. But all the same principles apply when a processor has
560 multiple CPUs, and knowing that the number of processes that can run at
561 any one time is equal to the number of CPUs, you can easily extrapolate
564 The functions described in this section are all defined by the POSIX.1
565 and POSIX.1b standards (the @code{sched@dots{}} functions are POSIX.1b).
566 However, POSIX does not define any semantics for the values that these
567 functions get and set. In this chapter, the semantics are based on the
568 Linux kernel's implementation of the POSIX standard. As you will see,
569 the Linux implementation is quite the inverse of what the authors of the
570 POSIX syntax had in mind.
573 * Absolute Priority:: The first tier of priority. Posix
574 * Realtime Scheduling:: Scheduling among the process nobility
575 * Basic Scheduling Functions:: Get/set scheduling policy, priority
576 * Traditional Scheduling:: Scheduling among the vulgar masses
577 * CPU Affinity:: Limiting execution to certain CPUs
582 @node Absolute Priority
583 @subsection Absolute Priority
584 @cindex absolute priority
585 @cindex priority, absolute
587 Every process has an absolute priority, and it is represented by a number.
588 The higher the number, the higher the absolute priority.
590 @cindex realtime CPU scheduling
591 On systems of the past, and most systems today, all processes have
592 absolute priority 0 and this section is irrelevant. In that case,
593 @xref{Traditional Scheduling}. Absolute priorities were invented to
594 accommodate realtime systems, in which it is vital that certain processes
595 be able to respond to external events happening in real time, which
596 means they cannot wait around while some other process that @emph{wants
597 to}, but doesn't @emph{need to} run occupies the CPU.
600 @cindex preemptive scheduling
601 When two processes are in contention to use the CPU at any instant, the
602 one with the higher absolute priority always gets it. This is true even if the
603 process with the lower priority is already using the CPU (i.e., the
604 scheduling is preemptive). Of course, we're only talking about
605 processes that are running or ``ready to run,'' which means they are
606 ready to execute instructions right now. When a process blocks to wait
607 for something like I/O, its absolute priority is irrelevant.
609 @cindex runnable process
610 @strong{NB:} The term ``runnable'' is a synonym for ``ready to run.''
612 When two processes are running or ready to run and both have the same
613 absolute priority, it's more interesting. In that case, who gets the
614 CPU is determined by the scheduling policy. If the processes have
615 absolute priority 0, the traditional scheduling policy described in
616 @ref{Traditional Scheduling} applies. Otherwise, the policies described
617 in @ref{Realtime Scheduling} apply.
619 You normally give an absolute priority above 0 only to a process that
620 can be trusted not to hog the CPU. Such processes are designed to block
621 (or terminate) after relatively short CPU runs.
623 A process begins life with the same absolute priority as its parent
624 process. Functions described in @ref{Basic Scheduling Functions} can
627 Only a privileged process can change a process' absolute priority to
628 something other than @code{0}. Only a privileged process or the
629 target process' owner can change its absolute priority at all.
631 POSIX requires absolute priority values used with the realtime
632 scheduling policies to be consecutive with a range of at least 32. On
633 Linux, they are 1 through 99. The functions
634 @code{sched_get_priority_max} and @code{sched_set_priority_min} portably
635 tell you what the range is on a particular system.
638 @subsubsection Using Absolute Priority
640 One thing you must keep in mind when designing real time applications is
641 that having higher absolute priority than any other process doesn't
642 guarantee the process can run continuously. Two things that can wreck a
643 good CPU run are interrupts and page faults.
645 Interrupt handlers live in that limbo between processes. The CPU is
646 executing instructions, but they aren't part of any process. An
647 interrupt will stop even the highest priority process. So you must
648 allow for slight delays and make sure that no device in the system has
649 an interrupt handler that could cause too long a delay between
650 instructions for your process.
652 Similarly, a page fault causes what looks like a straightforward
653 sequence of instructions to take a long time. The fact that other
654 processes get to run while the page faults in is of no consequence,
655 because as soon as the I/O is complete, the high priority process will
656 kick them out and run again, but the wait for the I/O itself could be a
657 problem. To neutralize this threat, use @code{mlock} or
660 There are a few ramifications of the absoluteness of this priority on a
661 single-CPU system that you need to keep in mind when you choose to set a
662 priority and also when you're working on a program that runs with high
663 absolute priority. Consider a process that has higher absolute priority
664 than any other process in the system and due to a bug in its program, it
665 gets into an infinite loop. It will never cede the CPU. You can't run
666 a command to kill it because your command would need to get the CPU in
667 order to run. The errant program is in complete control. It controls
668 the vertical, it controls the horizontal.
670 There are two ways to avoid this: 1) keep a shell running somewhere with
671 a higher absolute priority. 2) keep a controlling terminal attached to
672 the high priority process group. All the priority in the world won't
673 stop an interrupt handler from running and delivering a signal to the
674 process if you hit Control-C.
676 Some systems use absolute priority as a means of allocating a fixed
677 percentage of CPU time to a process. To do this, a super high priority
678 privileged process constantly monitors the process' CPU usage and raises
679 its absolute priority when the process isn't getting its entitled share
680 and lowers it when the process is exceeding it.
682 @strong{NB:} The absolute priority is sometimes called the ``static
683 priority.'' We don't use that term in this manual because it misses the
684 most important feature of the absolute priority: its absoluteness.
687 @node Realtime Scheduling
688 @subsection Realtime Scheduling
689 @cindex realtime scheduling
691 Whenever two processes with the same absolute priority are ready to run,
692 the kernel has a decision to make, because only one can run at a time.
693 If the processes have absolute priority 0, the kernel makes this decision
694 as described in @ref{Traditional Scheduling}. Otherwise, the decision
695 is as described in this section.
697 If two processes are ready to run but have different absolute priorities,
698 the decision is much simpler, and is described in @ref{Absolute
701 Each process has a scheduling policy. For processes with absolute
702 priority other than zero, there are two available:
706 First Come First Served
711 The most sensible case is where all the processes with a certain
712 absolute priority have the same scheduling policy. We'll discuss that
715 In Round Robin, processes share the CPU, each one running for a small
716 quantum of time (``time slice'') and then yielding to another in a
717 circular fashion. Of course, only processes that are ready to run and
718 have the same absolute priority are in this circle.
720 In First Come First Served, the process that has been waiting the
721 longest to run gets the CPU, and it keeps it until it voluntarily
722 relinquishes the CPU, runs out of things to do (blocks), or gets
723 preempted by a higher priority process.
725 First Come First Served, along with maximal absolute priority and
726 careful control of interrupts and page faults, is the one to use when a
727 process absolutely, positively has to run at full CPU speed or not at
730 Judicious use of @code{sched_yield} function invocations by processes
731 with First Come First Served scheduling policy forms a good compromise
732 between Round Robin and First Come First Served.
734 To understand how scheduling works when processes of different scheduling
735 policies occupy the same absolute priority, you have to know the nitty
736 gritty details of how processes enter and exit the ready to run list:
738 In both cases, the ready to run list is organized as a true queue, where
739 a process gets pushed onto the tail when it becomes ready to run and is
740 popped off the head when the scheduler decides to run it. Note that
741 ready to run and running are two mutually exclusive states. When the
742 scheduler runs a process, that process is no longer ready to run and no
743 longer in the ready to run list. When the process stops running, it
744 may go back to being ready to run again.
746 The only difference between a process that is assigned the Round Robin
747 scheduling policy and a process that is assigned First Come First Serve
748 is that in the former case, the process is automatically booted off the
749 CPU after a certain amount of time. When that happens, the process goes
750 back to being ready to run, which means it enters the queue at the tail.
751 The time quantum we're talking about is small. Really small. This is
752 not your father's timesharing. For example, with the Linux kernel, the
753 round robin time slice is a thousand times shorter than its typical
754 time slice for traditional scheduling.
756 A process begins life with the same scheduling policy as its parent process.
757 Functions described in @ref{Basic Scheduling Functions} can change it.
759 Only a privileged process can set the scheduling policy of a process
760 that has absolute priority higher than 0.
762 @node Basic Scheduling Functions
763 @subsection Basic Scheduling Functions
765 This section describes functions in @theglibc{} for setting the
766 absolute priority and scheduling policy of a process.
768 @strong{Portability Note:} On systems that have the functions in this
769 section, the macro _POSIX_PRIORITY_SCHEDULING is defined in
772 For the case that the scheduling policy is traditional scheduling, more
773 functions to fine tune the scheduling are in @ref{Traditional Scheduling}.
775 Don't try to make too much out of the naming and structure of these
776 functions. They don't match the concepts described in this manual
777 because the functions are as defined by POSIX.1b, but the implementation
778 on systems that use @theglibc{} is the inverse of what the POSIX
779 structure contemplates. The POSIX scheme assumes that the primary
780 scheduling parameter is the scheduling policy and that the priority
781 value, if any, is a parameter of the scheduling policy. In the
782 implementation, though, the priority value is king and the scheduling
783 policy, if anything, only fine tunes the effect of that priority.
785 The symbols in this section are declared by including file @file{sched.h}.
789 @deftp {Data Type} {struct sched_param}
790 This structure describes an absolute priority.
792 @item int sched_priority
793 absolute priority value
799 @deftypefun int sched_setscheduler (pid_t @var{pid}, int @var{policy}, const struct sched_param *@var{param})
800 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
801 @c Direct syscall, Linux only.
803 This function sets both the absolute priority and the scheduling policy
806 It assigns the absolute priority value given by @var{param} and the
807 scheduling policy @var{policy} to the process with Process ID @var{pid},
808 or the calling process if @var{pid} is zero. If @var{policy} is
809 negative, @code{sched_setscheduler} keeps the existing scheduling policy.
811 The following macros represent the valid values for @var{policy}:
815 Traditional Scheduling
822 @c The Linux kernel code (in sched.c) actually reschedules the process,
823 @c but it puts it at the head of the run queue, so I'm not sure just what
824 @c the effect is, but it must be subtle.
826 On success, the return value is @code{0}. Otherwise, it is @code{-1}
827 and @code{ERRNO} is set accordingly. The @code{errno} values specific
828 to this function are:
834 The calling process does not have @code{CAP_SYS_NICE} permission and
835 @var{policy} is not @code{SCHED_OTHER} (or it's negative and the
836 existing policy is not @code{SCHED_OTHER}.
839 The calling process does not have @code{CAP_SYS_NICE} permission and its
840 owner is not the target process' owner. I.e., the effective uid of the
841 calling process is neither the effective nor the real uid of process
843 @c We need a cross reference to the capabilities section, when written.
847 There is no process with pid @var{pid} and @var{pid} is not zero.
852 @var{policy} does not identify an existing scheduling policy.
855 The absolute priority value identified by *@var{param} is outside the
856 valid range for the scheduling policy @var{policy} (or the existing
857 scheduling policy if @var{policy} is negative) or @var{param} is
858 null. @code{sched_get_priority_max} and @code{sched_get_priority_min}
859 tell you what the valid range is.
862 @var{pid} is negative.
871 @deftypefun int sched_getscheduler (pid_t @var{pid})
872 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
873 @c Direct syscall, Linux only.
875 This function returns the scheduling policy assigned to the process with
876 Process ID (pid) @var{pid}, or the calling process if @var{pid} is zero.
878 The return value is the scheduling policy. See
879 @code{sched_setscheduler} for the possible values.
881 If the function fails, the return value is instead @code{-1} and
882 @code{errno} is set accordingly.
884 The @code{errno} values specific to this function are:
889 There is no process with pid @var{pid} and it is not zero.
892 @var{pid} is negative.
896 Note that this function is not an exact mate to @code{sched_setscheduler}
897 because while that function sets the scheduling policy and the absolute
898 priority, this function gets only the scheduling policy. To get the
899 absolute priority, use @code{sched_getparam}.
906 @deftypefun int sched_setparam (pid_t @var{pid}, const struct sched_param *@var{param})
907 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
908 @c Direct syscall, Linux only.
910 This function sets a process' absolute priority.
912 It is functionally identical to @code{sched_setscheduler} with
913 @var{policy} = @code{-1}.
915 @c in fact, that's how it's implemented in Linux.
921 @deftypefun int sched_getparam (pid_t @var{pid}, struct sched_param *@var{param})
922 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
923 @c Direct syscall, Linux only.
925 This function returns a process' absolute priority.
927 @var{pid} is the Process ID (pid) of the process whose absolute priority
930 @var{param} is a pointer to a structure in which the function stores the
931 absolute priority of the process.
933 On success, the return value is @code{0}. Otherwise, it is @code{-1}
934 and @code{ERRNO} is set accordingly. The @code{errno} values specific
935 to this function are:
940 There is no process with pid @var{pid} and it is not zero.
943 @var{pid} is negative.
952 @deftypefun int sched_get_priority_min (int @var{policy})
953 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
954 @c Direct syscall, Linux only.
956 This function returns the lowest absolute priority value that is
957 allowable for a process with scheduling policy @var{policy}.
959 On Linux, it is 0 for SCHED_OTHER and 1 for everything else.
961 On success, the return value is @code{0}. Otherwise, it is @code{-1}
962 and @code{ERRNO} is set accordingly. The @code{errno} values specific
963 to this function are:
967 @var{policy} does not identify an existing scheduling policy.
974 @deftypefun int sched_get_priority_max (int @var{policy})
975 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
976 @c Direct syscall, Linux only.
978 This function returns the highest absolute priority value that is
979 allowable for a process that with scheduling policy @var{policy}.
981 On Linux, it is 0 for SCHED_OTHER and 99 for everything else.
983 On success, the return value is @code{0}. Otherwise, it is @code{-1}
984 and @code{ERRNO} is set accordingly. The @code{errno} values specific
985 to this function are:
989 @var{policy} does not identify an existing scheduling policy.
996 @deftypefun int sched_rr_get_interval (pid_t @var{pid}, struct timespec *@var{interval})
997 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
998 @c Direct syscall, Linux only.
1000 This function returns the length of the quantum (time slice) used with
1001 the Round Robin scheduling policy, if it is used, for the process with
1002 Process ID @var{pid}.
1004 It returns the length of time as @var{interval}.
1005 @c We need a cross-reference to where timespec is explained. But that
1006 @c section doesn't exist yet, and the time chapter needs to be slightly
1007 @c reorganized so there is a place to put it (which will be right next
1008 @c to timeval, which is presently misplaced). 2000.05.07.
1010 With a Linux kernel, the round robin time slice is always 150
1011 microseconds, and @var{pid} need not even be a real pid.
1013 The return value is @code{0} on success and in the pathological case
1014 that it fails, the return value is @code{-1} and @code{errno} is set
1015 accordingly. There is nothing specific that can go wrong with this
1016 function, so there are no specific @code{errno} values.
1022 @deftypefun int sched_yield (void)
1023 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1024 @c Direct syscall on Linux; alias to swtch on HURD.
1026 This function voluntarily gives up the process' claim on the CPU.
1028 Technically, @code{sched_yield} causes the calling process to be made
1029 immediately ready to run (as opposed to running, which is what it was
1030 before). This means that if it has absolute priority higher than 0, it
1031 gets pushed onto the tail of the queue of processes that share its
1032 absolute priority and are ready to run, and it will run again when its
1033 turn next arrives. If its absolute priority is 0, it is more
1034 complicated, but still has the effect of yielding the CPU to other
1037 If there are no other processes that share the calling process' absolute
1038 priority, this function doesn't have any effect.
1040 To the extent that the containing program is oblivious to what other
1041 processes in the system are doing and how fast it executes, this
1042 function appears as a no-op.
1044 The return value is @code{0} on success and in the pathological case
1045 that it fails, the return value is @code{-1} and @code{errno} is set
1046 accordingly. There is nothing specific that can go wrong with this
1047 function, so there are no specific @code{errno} values.
1051 @node Traditional Scheduling
1052 @subsection Traditional Scheduling
1053 @cindex scheduling, traditional
1055 This section is about the scheduling among processes whose absolute
1056 priority is 0. When the system hands out the scraps of CPU time that
1057 are left over after the processes with higher absolute priority have
1058 taken all they want, the scheduling described herein determines who
1059 among the great unwashed processes gets them.
1062 * Traditional Scheduling Intro::
1063 * Traditional Scheduling Functions::
1066 @node Traditional Scheduling Intro
1067 @subsubsection Introduction To Traditional Scheduling
1069 Long before there was absolute priority (See @ref{Absolute Priority}),
1070 Unix systems were scheduling the CPU using this system. When Posix came
1071 in like the Romans and imposed absolute priorities to accommodate the
1072 needs of realtime processing, it left the indigenous Absolute Priority
1073 Zero processes to govern themselves by their own familiar scheduling
1076 Indeed, absolute priorities higher than zero are not available on many
1077 systems today and are not typically used when they are, being intended
1078 mainly for computers that do realtime processing. So this section
1079 describes the only scheduling many programmers need to be concerned
1082 But just to be clear about the scope of this scheduling: Any time a
1083 process with an absolute priority of 0 and a process with an absolute
1084 priority higher than 0 are ready to run at the same time, the one with
1085 absolute priority 0 does not run. If it's already running when the
1086 higher priority ready-to-run process comes into existence, it stops
1089 In addition to its absolute priority of zero, every process has another
1090 priority, which we will refer to as "dynamic priority" because it changes
1091 over time. The dynamic priority is meaningless for processes with
1092 an absolute priority higher than zero.
1094 The dynamic priority sometimes determines who gets the next turn on the
1095 CPU. Sometimes it determines how long turns last. Sometimes it
1096 determines whether a process can kick another off the CPU.
1098 In Linux, the value is a combination of these things, but mostly it is
1099 just determines the length of the time slice. The higher a process'
1100 dynamic priority, the longer a shot it gets on the CPU when it gets one.
1101 If it doesn't use up its time slice before giving up the CPU to do
1102 something like wait for I/O, it is favored for getting the CPU back when
1103 it's ready for it, to finish out its time slice. Other than that,
1104 selection of processes for new time slices is basically round robin.
1105 But the scheduler does throw a bone to the low priority processes: A
1106 process' dynamic priority rises every time it is snubbed in the
1107 scheduling process. In Linux, even the fat kid gets to play.
1109 The fluctuation of a process' dynamic priority is regulated by another
1110 value: The ``nice'' value. The nice value is an integer, usually in the
1111 range -20 to 20, and represents an upper limit on a process' dynamic
1112 priority. The higher the nice number, the lower that limit.
1114 On a typical Linux system, for example, a process with a nice value of
1115 20 can get only 10 milliseconds on the CPU at a time, whereas a process
1116 with a nice value of -20 can achieve a high enough priority to get 400
1119 The idea of the nice value is deferential courtesy. In the beginning,
1120 in the Unix garden of Eden, all processes shared equally in the bounty
1121 of the computer system. But not all processes really need the same
1122 share of CPU time, so the nice value gave a courteous process the
1123 ability to refuse its equal share of CPU time that others might prosper.
1124 Hence, the higher a process' nice value, the nicer the process is.
1125 (Then a snake came along and offered some process a negative nice value
1126 and the system became the crass resource allocation system we know
1129 Dynamic priorities tend upward and downward with an objective of
1130 smoothing out allocation of CPU time and giving quick response time to
1131 infrequent requests. But they never exceed their nice limits, so on a
1132 heavily loaded CPU, the nice value effectively determines how fast a
1135 In keeping with the socialistic heritage of Unix process priority, a
1136 process begins life with the same nice value as its parent process and
1137 can raise it at will. A process can also raise the nice value of any
1138 other process owned by the same user (or effective user). But only a
1139 privileged process can lower its nice value. A privileged process can
1140 also raise or lower another process' nice value.
1142 @glibcadj{} functions for getting and setting nice values are described in
1143 @xref{Traditional Scheduling Functions}.
1145 @node Traditional Scheduling Functions
1146 @subsubsection Functions For Traditional Scheduling
1148 @pindex sys/resource.h
1149 This section describes how you can read and set the nice value of a
1150 process. All these symbols are declared in @file{sys/resource.h}.
1152 The function and macro names are defined by POSIX, and refer to
1153 "priority," but the functions actually have to do with nice values, as
1154 the terms are used both in the manual and POSIX.
1156 The range of valid nice values depends on the kernel, but typically it
1157 runs from @code{-20} to @code{20}. A lower nice value corresponds to
1158 higher priority for the process. These constants describe the range of
1162 @comment sys/resource.h
1165 The lowest valid nice value.
1167 @comment sys/resource.h
1170 The highest valid nice value.
1173 @comment sys/resource.h
1175 @deftypefun int getpriority (int @var{class}, int @var{id})
1176 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1177 @c Direct syscall on UNIX. On HURD, calls _hurd_priority_which_map.
1178 Return the nice value of a set of processes; @var{class} and @var{id}
1179 specify which ones (see below). If the processes specified do not all
1180 have the same nice value, this returns the lowest value that any of them
1183 On success, the return value is @code{0}. Otherwise, it is @code{-1}
1184 and @code{ERRNO} is set accordingly. The @code{errno} values specific
1185 to this function are:
1189 The combination of @var{class} and @var{id} does not match any existing
1193 The value of @var{class} is not valid.
1196 If the return value is @code{-1}, it could indicate failure, or it could
1197 be the nice value. The only way to make certain is to set @code{errno =
1198 0} before calling @code{getpriority}, then use @code{errno != 0}
1199 afterward as the criterion for failure.
1202 @comment sys/resource.h
1204 @deftypefun int setpriority (int @var{class}, int @var{id}, int @var{niceval})
1205 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1206 @c Direct syscall on UNIX. On HURD, calls _hurd_priority_which_map.
1207 Set the nice value of a set of processes to @var{niceval}; @var{class}
1208 and @var{id} specify which ones (see below).
1210 The return value is @code{0} on success, and @code{-1} on
1211 failure. The following @code{errno} error condition are possible for
1216 The combination of @var{class} and @var{id} does not match any existing
1220 The value of @var{class} is not valid.
1223 The call would set the nice value of a process which is owned by a different
1224 user than the calling process (i.e., the target process' real or effective
1225 uid does not match the calling process' effective uid) and the calling
1226 process does not have @code{CAP_SYS_NICE} permission.
1229 The call would lower the process' nice value and the process does not have
1230 @code{CAP_SYS_NICE} permission.
1235 The arguments @var{class} and @var{id} together specify a set of
1236 processes in which you are interested. These are the possible values of
1240 @comment sys/resource.h
1243 One particular process. The argument @var{id} is a process ID (pid).
1245 @comment sys/resource.h
1248 All the processes in a particular process group. The argument @var{id} is
1249 a process group ID (pgid).
1251 @comment sys/resource.h
1254 All the processes owned by a particular user (i.e., whose real uid
1255 indicates the user). The argument @var{id} is a user ID (uid).
1258 If the argument @var{id} is 0, it stands for the calling process, its
1259 process group, or its owner (real uid), according to @var{class}.
1263 @deftypefun int nice (int @var{increment})
1264 @safety{@prelim{}@mtunsafe{@mtasurace{:setpriority}}@asunsafe{}@acsafe{}}
1265 @c Calls getpriority before and after setpriority, using the result of
1266 @c the first call to compute the argument for setpriority. This creates
1267 @c a window for a concurrent setpriority (or nice) call to be lost or
1268 @c exhibit surprising behavior.
1269 Increment the nice value of the calling process by @var{increment}.
1270 The return value is the new nice value on success, and @code{-1} on
1271 failure. In the case of failure, @code{errno} will be set to the
1272 same values as for @code{setpriority}.
1275 Here is an equivalent definition of @code{nice}:
1279 nice (int increment)
1281 int result, old = getpriority (PRIO_PROCESS, 0);
1282 result = setpriority (PRIO_PROCESS, 0, old + increment);
1284 return old + increment;
1293 @subsection Limiting execution to certain CPUs
1295 On a multi-processor system the operating system usually distributes
1296 the different processes which are runnable on all available CPUs in a
1297 way which allows the system to work most efficiently. Which processes
1298 and threads run can be to some extend be control with the scheduling
1299 functionality described in the last sections. But which CPU finally
1300 executes which process or thread is not covered.
1302 There are a number of reasons why a program might want to have control
1303 over this aspect of the system as well:
1307 One thread or process is responsible for absolutely critical work
1308 which under no circumstances must be interrupted or hindered from
1309 making process by other process or threads using CPU resources. In
1310 this case the special process would be confined to a CPU which no
1311 other process or thread is allowed to use.
1314 The access to certain resources (RAM, I/O ports) has different costs
1315 from different CPUs. This is the case in NUMA (Non-Uniform Memory
1316 Architecture) machines. Preferably memory should be accessed locally
1317 but this requirement is usually not visible to the scheduler.
1318 Therefore forcing a process or thread to the CPUs which have local
1319 access to the mostly used memory helps to significantly boost the
1323 In controlled runtimes resource allocation and book-keeping work (for
1324 instance garbage collection) is performance local to processors. This
1325 can help to reduce locking costs if the resources do not have to be
1326 protected from concurrent accesses from different processors.
1329 The POSIX standard up to this date is of not much help to solve this
1330 problem. The Linux kernel provides a set of interfaces to allow
1331 specifying @emph{affinity sets} for a process. The scheduler will
1332 schedule the thread or process on CPUs specified by the affinity
1333 masks. The interfaces which @theglibc{} define follow to some
1334 extend the Linux kernel interface.
1338 @deftp {Data Type} cpu_set_t
1339 This data set is a bitset where each bit represents a CPU. How the
1340 system's CPUs are mapped to bits in the bitset is system dependent.
1341 The data type has a fixed size; in the unlikely case that the number
1342 of bits are not sufficient to describe the CPUs of the system a
1343 different interface has to be used.
1345 This type is a GNU extension and is defined in @file{sched.h}.
1348 To manipulate the bitset, to set and reset bits, a number of macros is
1349 defined. Some of the macros take a CPU number as a parameter. Here
1350 it is important to never exceed the size of the bitset. The following
1351 macro specifies the number of bits in the @code{cpu_set_t} bitset.
1355 @deftypevr Macro int CPU_SETSIZE
1356 The value of this macro is the maximum number of CPUs which can be
1357 handled with a @code{cpu_set_t} object.
1360 The type @code{cpu_set_t} should be considered opaque; all
1361 manipulation should happen via the next four macros.
1365 @deftypefn Macro void CPU_ZERO (cpu_set_t *@var{set})
1366 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1370 This macro initializes the CPU set @var{set} to be the empty set.
1372 This macro is a GNU extension and is defined in @file{sched.h}.
1377 @deftypefn Macro void CPU_SET (int @var{cpu}, cpu_set_t *@var{set})
1378 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1383 This macro adds @var{cpu} to the CPU set @var{set}.
1385 The @var{cpu} parameter must not have side effects since it is
1386 evaluated more than once.
1388 This macro is a GNU extension and is defined in @file{sched.h}.
1393 @deftypefn Macro void CPU_CLR (int @var{cpu}, cpu_set_t *@var{set})
1394 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1399 This macro removes @var{cpu} from the CPU set @var{set}.
1401 The @var{cpu} parameter must not have side effects since it is
1402 evaluated more than once.
1404 This macro is a GNU extension and is defined in @file{sched.h}.
1409 @deftypefn Macro int CPU_ISSET (int @var{cpu}, const cpu_set_t *@var{set})
1410 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1415 This macro returns a nonzero value (true) if @var{cpu} is a member
1416 of the CPU set @var{set}, and zero (false) otherwise.
1418 The @var{cpu} parameter must not have side effects since it is
1419 evaluated more than once.
1421 This macro is a GNU extension and is defined in @file{sched.h}.
1425 CPU bitsets can be constructed from scratch or the currently installed
1426 affinity mask can be retrieved from the system.
1430 @deftypefun int sched_getaffinity (pid_t @var{pid}, size_t @var{cpusetsize}, cpu_set_t *@var{cpuset})
1431 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1432 @c Wrapped syscall to zero out past the kernel cpu set size; Linux
1435 This functions stores the CPU affinity mask for the process or thread
1436 with the ID @var{pid} in the @var{cpusetsize} bytes long bitmap
1437 pointed to by @var{cpuset}. If successful, the function always
1438 initializes all bits in the @code{cpu_set_t} object and returns zero.
1440 If @var{pid} does not correspond to a process or thread on the system
1441 the or the function fails for some other reason, it returns @code{-1}
1442 and @code{errno} is set to represent the error condition.
1446 No process or thread with the given ID found.
1449 The pointer @var{cpuset} is does not point to a valid object.
1452 This function is a GNU extension and is declared in @file{sched.h}.
1455 Note that it is not portably possible to use this information to
1456 retrieve the information for different POSIX threads. A separate
1457 interface must be provided for that.
1461 @deftypefun int sched_setaffinity (pid_t @var{pid}, size_t @var{cpusetsize}, const cpu_set_t *@var{cpuset})
1462 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1463 @c Wrapped syscall to detect attempts to set bits past the kernel cpu
1464 @c set size; Linux only.
1466 This function installs the @var{cpusetsize} bytes long affinity mask
1467 pointed to by @var{cpuset} for the process or thread with the ID @var{pid}.
1468 If successful the function returns zero and the scheduler will in future
1469 take the affinity information into account.
1471 If the function fails it will return @code{-1} and @code{errno} is set
1476 No process or thread with the given ID found.
1479 The pointer @var{cpuset} is does not point to a valid object.
1482 The bitset is not valid. This might mean that the affinity set might
1483 not leave a processor for the process or thread to run on.
1486 This function is a GNU extension and is declared in @file{sched.h}.
1490 @node Memory Resources
1491 @section Querying memory available resources
1493 The amount of memory available in the system and the way it is organized
1494 determines oftentimes the way programs can and have to work. For
1495 functions like @code{mmap} it is necessary to know about the size of
1496 individual memory pages and knowing how much memory is available enables
1497 a program to select appropriate sizes for, say, caches. Before we get
1498 into these details a few words about memory subsystems in traditional
1499 Unix systems will be given.
1502 * Memory Subsystem:: Overview about traditional Unix memory handling.
1503 * Query Memory Parameters:: How to get information about the memory
1507 @node Memory Subsystem
1508 @subsection Overview about traditional Unix memory handling
1510 @cindex address space
1511 @cindex physical memory
1512 @cindex physical address
1513 Unix systems normally provide processes virtual address spaces. This
1514 means that the addresses of the memory regions do not have to correspond
1515 directly to the addresses of the actual physical memory which stores the
1516 data. An extra level of indirection is introduced which translates
1517 virtual addresses into physical addresses. This is normally done by the
1518 hardware of the processor.
1520 @cindex shared memory
1521 Using a virtual address space has several advantage. The most important
1522 is process isolation. The different processes running on the system
1523 cannot interfere directly with each other. No process can write into
1524 the address space of another process (except when shared memory is used
1525 but then it is wanted and controlled).
1527 Another advantage of virtual memory is that the address space the
1528 processes see can actually be larger than the physical memory available.
1529 The physical memory can be extended by storage on an external media
1530 where the content of currently unused memory regions is stored. The
1531 address translation can then intercept accesses to these memory regions
1532 and make memory content available again by loading the data back into
1533 memory. This concept makes it necessary that programs which have to use
1534 lots of memory know the difference between available virtual address
1535 space and available physical memory. If the working set of virtual
1536 memory of all the processes is larger than the available physical memory
1537 the system will slow down dramatically due to constant swapping of
1538 memory content from the memory to the storage media and back. This is
1539 called ``thrashing''.
1543 @cindex page, memory
1544 A final aspect of virtual memory which is important and follows from
1545 what is said in the last paragraph is the granularity of the virtual
1546 address space handling. When we said that the virtual address handling
1547 stores memory content externally it cannot do this on a byte-by-byte
1548 basis. The administrative overhead does not allow this (leaving alone
1549 the processor hardware). Instead several thousand bytes are handled
1550 together and form a @dfn{page}. The size of each page is always a power
1551 of two byte. The smallest page size in use today is 4096, with 8192,
1552 16384, and 65536 being other popular sizes.
1554 @node Query Memory Parameters
1555 @subsection How to get information about the memory subsystem?
1557 The page size of the virtual memory the process sees is essential to
1558 know in several situations. Some programming interface (e.g.,
1559 @code{mmap}, @pxref{Memory-mapped I/O}) require the user to provide
1560 information adjusted to the page size. In the case of @code{mmap} is it
1561 necessary to provide a length argument which is a multiple of the page
1562 size. Another place where the knowledge about the page size is useful
1563 is in memory allocation. If one allocates pieces of memory in larger
1564 chunks which are then subdivided by the application code it is useful to
1565 adjust the size of the larger blocks to the page size. If the total
1566 memory requirement for the block is close (but not larger) to a multiple
1567 of the page size the kernel's memory handling can work more effectively
1568 since it only has to allocate memory pages which are fully used. (To do
1569 this optimization it is necessary to know a bit about the memory
1570 allocator which will require a bit of memory itself for each block and
1571 this overhead must not push the total size over the page size multiple.
1573 The page size traditionally was a compile time constant. But recent
1574 development of processors changed this. Processors now support
1575 different page sizes and they can possibly even vary among different
1576 processes on the same system. Therefore the system should be queried at
1577 runtime about the current page size and no assumptions (except about it
1578 being a power of two) should be made.
1580 @vindex _SC_PAGESIZE
1581 The correct interface to query about the page size is @code{sysconf}
1582 (@pxref{Sysconf Definition}) with the parameter @code{_SC_PAGESIZE}.
1583 There is a much older interface available, too.
1587 @deftypefun int getpagesize (void)
1588 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1589 @c Obtained from the aux vec at program startup time. GNU/Linux/m68k is
1590 @c the exception, with the possibility of a syscall.
1591 The @code{getpagesize} function returns the page size of the process.
1592 This value is fixed for the runtime of the process but can vary in
1593 different runs of the application.
1595 The function is declared in @file{unistd.h}.
1598 Widely available on @w{System V} derived systems is a method to get
1599 information about the physical memory the system has. The call
1601 @vindex _SC_PHYS_PAGES
1604 sysconf (_SC_PHYS_PAGES)
1608 returns the total number of pages of physical the system has.
1609 This does not mean all this memory is available. This information can
1612 @vindex _SC_AVPHYS_PAGES
1615 sysconf (_SC_AVPHYS_PAGES)
1618 These two values help to optimize applications. The value returned for
1619 @code{_SC_AVPHYS_PAGES} is the amount of memory the application can use
1620 without hindering any other process (given that no other process
1621 increases its memory usage). The value returned for
1622 @code{_SC_PHYS_PAGES} is more or less a hard limit for the working set.
1623 If all applications together constantly use more than that amount of
1624 memory the system is in trouble.
1626 @Theglibc{} provides in addition to these already described way to
1627 get this information two functions. They are declared in the file
1628 @file{sys/sysinfo.h}. Programmers should prefer to use the
1629 @code{sysconf} method described above.
1631 @comment sys/sysinfo.h
1633 @deftypefun {long int} get_phys_pages (void)
1634 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{} @asulock{}}@acunsafe{@aculock{} @acsfd{} @acsmem{}}}
1635 @c This fopens a /proc file and scans it for the requested information.
1636 The @code{get_phys_pages} function returns the total number of pages of
1637 physical the system has. To get the amount of memory this number has to
1638 be multiplied by the page size.
1640 This function is a GNU extension.
1643 @comment sys/sysinfo.h
1645 @deftypefun {long int} get_avphys_pages (void)
1646 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{} @asulock{}}@acunsafe{@aculock{} @acsfd{} @acsmem{}}}
1647 The @code{get_avphys_pages} function returns the number of available pages of
1648 physical the system has. To get the amount of memory this number has to
1649 be multiplied by the page size.
1651 This function is a GNU extension.
1654 @node Processor Resources
1655 @section Learn about the processors available
1657 The use of threads or processes with shared memory allows an application
1658 to take advantage of all the processing power a system can provide. If
1659 the task can be parallelized the optimal way to write an application is
1660 to have at any time as many processes running as there are processors.
1661 To determine the number of processors available to the system one can
1664 @vindex _SC_NPROCESSORS_CONF
1667 sysconf (_SC_NPROCESSORS_CONF)
1671 which returns the number of processors the operating system configured.
1672 But it might be possible for the operating system to disable individual
1673 processors and so the call
1675 @vindex _SC_NPROCESSORS_ONLN
1678 sysconf (_SC_NPROCESSORS_ONLN)
1682 returns the number of processors which are currently online (i.e.,
1685 For these two pieces of information @theglibc{} also provides
1686 functions to get the information directly. The functions are declared
1687 in @file{sys/sysinfo.h}.
1689 @comment sys/sysinfo.h
1691 @deftypefun int get_nprocs_conf (void)
1692 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{} @asulock{}}@acunsafe{@aculock{} @acsfd{} @acsmem{}}}
1693 @c This function reads from from /sys using dir streams (single user, so
1694 @c no @mtasurace issue), and on some arches, from /proc using streams.
1695 The @code{get_nprocs_conf} function returns the number of processors the
1696 operating system configured.
1698 This function is a GNU extension.
1701 @comment sys/sysinfo.h
1703 @deftypefun int get_nprocs (void)
1704 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{@acsfd{}}}
1705 @c This function reads from /proc using file descriptor I/O.
1706 The @code{get_nprocs} function returns the number of available processors.
1708 This function is a GNU extension.
1711 @cindex load average
1712 Before starting more threads it should be checked whether the processors
1713 are not already overused. Unix systems calculate something called the
1714 @dfn{load average}. This is a number indicating how many processes were
1715 running. This number is average over different periods of times
1716 (normally 1, 5, and 15 minutes).
1720 @deftypefun int getloadavg (double @var{loadavg}[], int @var{nelem})
1721 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{@acsfd{}}}
1722 @c Calls host_info on HURD; on Linux, opens /proc/loadavg, reads from
1723 @c it, closes it, without cancellation point, and calls strtod_l with
1724 @c the C locale to convert the strings to doubles.
1725 This function gets the 1, 5 and 15 minute load averages of the
1726 system. The values are placed in @var{loadavg}. @code{getloadavg} will
1727 place at most @var{nelem} elements into the array but never more than
1728 three elements. The return value is the number of elements written to
1729 @var{loadavg}, or -1 on error.
1731 This function is declared in @file{stdlib.h}.