#include <sys/resource.h>int getrusage(int who, struct rusage *r_usage);
The getrusage() function provides measures of the resources used by the current process or its terminated and waited-for child processes. If the value of the who
argument is RUSAGE_SELF, information is returned about resources used by the current process. If the value of the who argument is RUSAGE_CHILDREN,
information is returned about resources used by the terminated and waited-for children of the current process. If the child is never waited for (for instance, if the parent has SA_NOCLDWAIT set or sets
SIGCHLD to SIG_IGN), the resource information for the child process is discarded and not included in the resource
information provided by getrusage().
The r_usage argument is a pointer to an object of type struct rusage in which the returned information is stored. The members of rusage are as follows:
struct timeval ru_utime; /* user time used */ struct timeval ru_stime; /* system time used */ long ru_maxrss; /* maximum resident set size */ long ru_idrss; /* integral resident set size */ long ru_minflt; /* page faults not requiring physical I/O */ long ru_majflt; /* page faults requiring physical I/O */ long ru_nswap; /* swaps */ long ru_inblock; /* block input operations */ long ru_oublock; /* block output operations */ long ru_msgsnd; /* messages sent */ long ru_msgrcv; /* messages received */ long ru_nsignals; /* signals received */ long ru_nvcsw; /* voluntary context switches */ long ru_nivcsw; /* involuntary context switches */
The structure members are interpreted as follows:
The total amount of time spent executing in user mode. Time is given in seconds and microseconds.
The total amount of time spent executing in system mode. Time is given in seconds and microseconds.
The maximum resident set size. Size is given in pages (the size of a page, in bytes, is given by the getpagesize(3C) function). See the NOTES section of this page.
An “integral” value indicating the amount of memory in use by a process while the process is running. This value is the sum of the resident set sizes of the process running when a clock tick occurs. The value is given in pages times clock ticks. It does not take sharing into account. See the NOTES section of this page.
The number of page faults serviced which did not require any physical I/O activity. See the NOTES section of this page.
The number of page faults serviced which required physical I/O activity. This could include page ahead operations by the kernel. See the NOTES section of this page.
The number of times a process was swapped out of main memory.
The number of times the file system had to perform input in servicing a read(2) request.
The number of times the file system had to perform output in servicing a write(2) request.
The number of messages sent over sockets.
The number of messages received from sockets.
The number of signals delivered.
The number of times a context switch resulted due to a process voluntarily giving up the processor before its time slice was completed (usually to await availability of a resource).
The number of times a context switch resulted due to a higher priority process becoming runnable or because the current process exceeded its time slice.
Upon successful completion, getrusage() returns 0. Otherwise, -1 is returned and errno is set to indicate the error.
The getrusage() function will fail if:
The address specified by the r_usage argument is not in a valid portion of the process' address space.
The who parameter is not a valid value.
Only the timeval member of struct rusage are supported in this implementation.
The numbers ru_inblock and ru_oublock account only for real I/O, and are approximate measures at best. Data supplied by the cache mechanism is charged only to the first process to read and the last process to write the data.
The way resident set size is calculated is an approximation, and could misrepresent the true resident set size.
Page faults can be generated from a variety of sources and for a variety of reasons. The customary cause for a page fault is a direct reference by the program to a page which is not in memory. Now, however, the kernel can generate page faults on behalf of the user, for example, servicing read(2) and write(2) functions. Also, a page fault can be caused by an absent hardware translation to a page, even though the page is in physical memory.
In addition to hardware detected page faults, the kernel may cause pseudo page faults in order to perform some housekeeping. For example, the kernel may generate page faults, even if the pages exist in physical memory, in order to lock down pages involved in a raw I/O request.
By definition, major page faults require physical I/O, while minor page faults do not require physical I/O. For example, reclaiming the page from the free list would avoid I/O and generate a minor page fault. More commonly, minor page faults occur during process startup as references to pages which are already in memory. For example, if an address space faults on some “hot” executable or shared library, this results in a minor page fault for the address space. Also, any one doing a read(2) or write(2) to something that is in the page cache will get a minor page fault(s) as well.
There is no way to obtain information about a child process which has not yet terminated.