table of contents
MLOCK(2) | System Calls Manual | MLOCK(2) |
NAME¶
mlock
, munlock
— lock (unlock) physical pages in memory
LIBRARY¶
Standard C Library (libc, -lc)
SYNOPSIS¶
#include
<sys/mman.h>
int
mlock
(const
void *addr, size_t
len);
int
munlock
(const
void *addr, size_t
len);
DESCRIPTION¶
The
mlock
()
system call locks into memory the physical pages associated with the virtual
address range starting at addr for
len bytes. The
munlock
()
system call unlocks pages previously locked by one or more
mlock
() calls. For both, the
addr argument should be aligned to a multiple of the
page size. If the len argument is not a multiple of
the page size, it will be rounded up to be so. The entire range must be
allocated.
After an
mlock
()
system call, the indicated pages will cause neither a non-resident page nor
address-translation fault until they are unlocked. They may still cause
protection-violation faults or TLB-miss faults on architectures with
software-managed TLBs. The physical pages remain in memory until all locked
mappings for the pages are removed. Multiple processes may have the same
physical pages locked via their own virtual address mappings. A single
process may likewise have pages multiply-locked via different virtual
mappings of the same physical pages. Unlocking is performed explicitly by
munlock
()
or implicitly by a call to
munmap
()
which deallocates the unmapped address range. Locked mappings are not
inherited by the child process after a fork(2).
Since physical memory is a potentially scarce
resource, processes are limited in how much they can lock down. The amount
of memory that a single process can
mlock
() is
limited by both the per-process RLIMIT_MEMLOCK
resource limit and the system-wide “wired pages” limit
vm.max_user_wired.
vm.max_user_wired applies to the system as a whole, so
the amount available to a single process at any given time is the difference
between vm.max_user_wired and
vm.stats.vm.v_user_wire_count.
If security.bsd.unprivileged_mlock is set to 0 these calls are only available to the super-user.
RETURN VALUES¶
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.
If the call succeeds, all pages in the range become locked (unlocked); otherwise the locked status of all pages in the range remains unchanged.
ERRORS¶
The mlock
() system call will fail if:
- [
EPERM
] - security.bsd.unprivileged_mlock is set to 0 and the caller is not the super-user.
- [
EINVAL
] - The address range given wraps around zero.
- [
ENOMEM
] - Some portion of the indicated address range is not allocated. There was an error faulting/mapping a page. Locking the indicated range would exceed the per-process or system-wide limits for locked memory.
munlock
() system call will fail if:
- [
EPERM
] - security.bsd.unprivileged_mlock is set to 0 and the caller is not the super-user.
- [
EINVAL
] - The address range given wraps around zero.
- [
ENOMEM
] - Some or all of the address range specified by the addr and len arguments does not correspond to valid mapped pages in the address space of the process.
- [
ENOMEM
] - Locking the pages mapped by the specified range would exceed a limit on the amount of memory that the process may lock.
SEE ALSO¶
fork(2), mincore(2), minherit(2), mlockall(2), mmap(2), munlockall(2), munmap(2), setrlimit(2), getpagesize(3)
HISTORY¶
The mlock
() and
munlock
() system calls first appeared in
4.4BSD.
BUGS¶
Allocating too much wired memory can lead to a memory-allocation deadlock which requires a reboot to recover from.
The per-process and system-wide resource limits of locked memory apply to the amount of virtual memory locked, not the amount of locked physical pages. Hence two distinct locked mappings of the same physical page counts as 2 pages aginst the system limit, and also against the per-process limit if both mappings belong to the same physical map.
The per-process resource limit is not currently supported.
May 13, 2019 | Debian |