GETRLIMIT(2) | System Calls Manual | GETRLIMIT(2) |
getrlimit
,
setrlimit
— control maximum
system resource consumption
Standard C Library (libc, -lc)
#include
<sys/types.h>
#include <sys/time.h>
#include <sys/resource.h>
int
getrlimit
(int
resource, struct rlimit
*rlp);
int
setrlimit
(int
resource, const struct
rlimit *rlp);
Limits on the consumption of system resources by the current
process and each process it creates may be obtained with the
getrlimit
()
system call, and set with the
setrlimit
()
system call.
The resource argument is one of the following:
RLIMIT_AS
RLIMIT_CORE
RLIMIT_CPU
RLIMIT_DATA
RLIMIT_FSIZE
RLIMIT_KQUEUES
RLIMIT_MEMLOCK
RLIMIT_NOFILE
RLIMIT_NPROC
RLIMIT_NPTS
RLIMIT_RSS
Processes that exceed their set
RLIMIT_RSS
are not signalled or halted. The
limit is merely a hint to the VM daemon to prefer to deactivate pages
from processes that have exceeded their set
RLIMIT_RSS
.
RLIMIT_SBSIZE
RLIMIT_STACK
RLIMIT_SWAP
RLIMIT_VMEM
RLIMIT_AS
.A resource limit is specified as a soft limit and a hard limit. When a soft limit is exceeded, a process might or might not receive a signal. For example, signals are generated when the cpu time or file size is exceeded, but not if the address space or RSS limit is exceeded. A program that exceeds the soft limit is allowed to continue execution until it reaches the hard limit, or modifies its own resource limit. Even reaching the hard limit does not necessarily halt a process. For example, if the RSS hard limit is exceeded, nothing happens.
The rlimit structure is used to specify the hard and soft limits on a resource.
struct rlimit { rlim_t rlim_cur; /* current (soft) limit */ rlim_t rlim_max; /* maximum value for rlim_cur */ };
Only the super-user may raise the maximum limits. Other users may only alter rlim_cur within the range from 0 to rlim_max or (irreversibly) lower rlim_max.
An “infinite” value for a limit is defined as
RLIM_INFINITY
.
Because this information is stored in the per-process information,
this system call must be executed directly by the shell if it is to affect
all future processes created by the shell; limit
is
thus a built-in command to csh(1).
The system refuses to extend the data or stack space when the
limits would be exceeded in the normal way: a brk(2)
function fails if the data space limit is reached. When the stack limit is
reached, the process receives a segmentation fault
(SIGSEGV
); if this signal is not caught by a handler
using the signal stack, this signal will kill the process.
A file I/O operation that would create a file larger that the
process' soft limit will cause the write to fail and a signal
SIGXFSZ
to be generated; this normally terminates
the process, but may be caught. When the soft cpu time limit is exceeded, a
SIGXCPU
signal is sent to the offending process.
When most operations would allocate more virtual memory than
allowed by the soft limit of RLIMIT_AS
, the
operation fails with ENOMEM
and no signal is raised.
A notable exception is stack extension, described above. If stack extension
would allocate more virtual memory than allowed by the soft limit of
RLIMIT_AS
, a SIGSEGV
signal
will be delivered. The caller is free to raise the soft address space limit
up to the hard limit and retry the allocation.
Upon successful completion, the value 0 is returned; otherwise the value -1 is returned and the global variable errno is set to indicate the error.
The getrlimit
() and
setrlimit
() system calls will fail if:
csh(1), quota(1), quotactl(2), sigaction(2), sigaltstack(2), sysctl(3), ulimit(3)
The getrlimit
() system call appeared in
4.2BSD.
September 30, 2016 | Debian |