ZONE(9) | Kernel Developer's Manual | ZONE(9) |
uma_zcreate
,
uma_zalloc
, uma_zalloc_arg
,
uma_zalloc_domain
,
uma_zfree
, uma_zfree_arg
,
uma_zfree_domain
,
uma_zdestroy
,
uma_zone_set_max
,
uma_zone_get_max
,
uma_zone_get_cur
,
uma_zone_set_warning
,
uma_zone_set_maxaction
—
zone allocator
#include
<sys/param.h>
#include <sys/queue.h>
#include <vm/uma.h>
uma_zone_t
uma_zcreate
(char *name,
int size, uma_ctor ctor,
uma_dtor dtor, uma_init uminit,
uma_fini fini, int align,
uint16_t flags);
void *
uma_zalloc
(uma_zone_t
zone, int
flags);
void *
uma_zalloc_arg
(uma_zone_t
zone, void *arg,
int flags);
void *
uma_zalloc_domain
(uma_zone_t
zone, void *arg,
int domain,
int flags);
void
uma_zfree
(uma_zone_t
zone, void
*item);
void
uma_zfree_arg
(uma_zone_t
zone, void *item,
void *arg);
void
uma_zfree_domain
(uma_zone_t
zone, void *item,
void *arg);
void
uma_zdestroy
(uma_zone_t
zone);
int
uma_zone_set_max
(uma_zone_t
zone, int
nitems);
int
uma_zone_get_max
(uma_zone_t
zone);
int
uma_zone_get_cur
(uma_zone_t
zone);
void
uma_zone_set_warning
(uma_zone_t
zone, const char
*warning);
void
uma_zone_set_maxaction
(uma_zone_t
zone, void
(*maxaction)(uma_zone_t));
#include
<sys/sysctl.h>
SYSCTL_UMA_MAX
(parent,
nbr,
name,
access,
zone,
descr);
SYSCTL_ADD_UMA_MAX
(ctx,
parent,
nbr,
name,
access,
zone,
descr);
SYSCTL_UMA_CUR
(parent,
nbr,
name,
access,
zone,
descr);
SYSCTL_ADD_UMA_CUR
(ctx,
parent,
nbr,
name,
access,
zone,
descr);
The zone allocator provides an efficient interface for managing dynamically-sized collections of items of identical size. The zone allocator can work with preallocated zones as well as with runtime-allocated ones, and is therefore available much earlier in the boot process than other memory management routines. The zone allocator provides per-cpu allocation caches with linear scalability on SMP systems as well as round-robin and first-touch policies for NUMA systems.
A zone is an extensible collection of items of identical size. The zone allocator keeps track of which items are in use and which are not, and provides functions for allocating items from the zone and for releasing them back (which makes them available for later use).
After the first allocation of an item, it will have been cleared to zeroes, however subsequent allocations will retain the contents as of the last free.
The
uma_zcreate
()
function creates a new zone from which items may then be allocated from. The
name argument is a text name of the zone for debugging
and stats; this memory should not be freed until the zone has been
deallocated.
The ctor and
dtor arguments are callback functions that are called
by the uma subsystem at the time of the call to
uma_zalloc
()
and uma_zfree
() respectively. Their purpose is to
provide hooks for initializing or destroying things that need to be done at
the time of the allocation or release of a resource. A good usage for the
ctor and dtor callbacks might be
to adjust a global count of the number of objects allocated.
The uminit and
fini arguments are used to optimize the allocation of
objects from the zone. They are called by the uma subsystem whenever it
needs to allocate or free several items to satisfy requests or memory
pressure. A good use for the uminit and
fini callbacks might be to initialize and destroy
mutexes contained within the object. This would allow one to re-use already
initialized mutexes when an object is returned from the uma subsystem's
object cache. They are not called on each call to
uma_zalloc
()
and uma_zfree
() but rather in a batch mode on
several objects.
The flags argument of the
uma_zcreate
()
is a subset of the following flags:
UMA_ZONE_NOFREE
UMA_ZONE_NODUMP
UMA_ZONE_PCPU
sizeof
(struct
pcpu):
foo_zone = uma_zcreate(..., UMA_ZONE_PCPU); ... foo_base = uma_zalloc(foo_zone, ...); ... critical_enter(); foo_pcpu = (foo_t *)zpcpu_get(foo_base); /* do something with foo_pcpu */ critical_exit();
UMA_ZONE_OFFPAGE
UMA_ZONE_VTOSLAB
or
UMA_ZONE_HASH
, since subsystem requires a
mechanism to find a book-keeping structure to an item being freed. The
subsystem may choose to prefer offpage book-keeping for certain zones
implicitly.UMA_ZONE_ZINIT
UMA_ZONE_ZINIT
flag would not return zeroed memory
on every uma_zalloc
().UMA_ZONE_HASH
UMA_ZONE_VTOSLAB
UMA_ZONE_MALLOC
UMA_ZONE_VM
UMA_ZONE_NUMA
To allocate an item from a zone, simply call
uma_zalloc
()
with a pointer to that zone and set the flags argument
to selected flags as documented in malloc(9). It will
return a pointer to an item if successful, or NULL
in the rare case where all items in the zone are in use and the allocator is
unable to grow the zone and M_NOWAIT
is
specified.
Items are released back to the zone from which they
were allocated by calling
uma_zfree
()
with a pointer to the zone and a pointer to the item. If
item is NULL
, then
uma_zfree
() does nothing.
The variations
uma_zalloc_arg
()
and
uma_zfree_arg
()
allow callers to specify an argument for the ctor
and dtor
functions, respectively. The
uma_zalloc_domain
()
function allows callers to specify a fixed numa(9) domain
to allocate from. This uses a guaranteed but slow path in the allocator
which reduces concurrency. The
uma_zfree_domain
()
function should be used to return memory allocated in this fashion. This
function infers the domain from the pointer and does not require it as an
argument.
Created zones, which are empty, can be destroyed
using
uma_zdestroy
(),
freeing all memory that was allocated for the zone. All items allocated from
the zone with uma_zalloc
() must have been freed with
uma_zfree
() before.
The
uma_zone_set_max
()
function limits the number of items (and therefore memory) that can be
allocated to zone. The nitems
argument specifies the requested upper limit number of items. The effective
limit is returned to the caller, as it may end up being higher than
requested due to the implementation rounding up to ensure all memory pages
allocated to the zone are utilised to capacity. The limit applies to the
total number of items in the zone, which includes allocated items, free
items and free items in the per-cpu caches. On systems with more than one
CPU it may not be possible to allocate the specified number of items even
when there is no shortage of memory, because all of the remaining free items
may be in the caches of the other CPUs when the limit is hit.
The
uma_zone_get_max
()
function returns the effective upper limit number of items for a zone.
The
uma_zone_get_cur
()
function returns the approximate current occupancy of the zone. The returned
value is approximate because appropriate synchronisation to determine an
exact value is not performed by the implementation. This ensures low
overhead at the expense of potentially stale data being used in the
calculation.
The
uma_zone_set_warning
()
function sets a warning that will be printed on the system console when the
given zone becomes full and fails to allocate an item. The warning will be
printed no more often than every five minutes. Warnings can be turned off
globally by setting the vm.zone_warnings sysctl
tunable to 0.
The
uma_zone_set_maxaction
()
function sets a function that will be called when the given zone becomes
full and fails to allocate an item. The function will be called with the
zone locked. Also, the function that called the allocation function may have
held additional locks. Therefore, this function should do very little work
(similar to a signal handler).
The
SYSCTL_UMA_MAX
(parent,
nbr, name,
access, zone,
descr) macro declares a static
sysctl oid that exports the effective upper limit number
of items for a zone. The zone argument should be a
pointer to uma_zone_t. A read of the oid returns value
obtained through uma_zone_get_max
(). A write to the
oid sets new value via uma_zone_set_max
(). The
SYSCTL_ADD_UMA_MAX
(ctx,
parent, nbr,
name, access,
zone, descr) macro is provided
to create this type of oid dynamically.
The
SYSCTL_UMA_CUR
(parent,
nbr, name,
access, zone,
descr) macro declares a static read-only
sysctl oid that exports the approximate current occupancy
of the zone. The zone argument should be a pointer to
uma_zone_t. A read of the oid returns value obtained
through uma_zone_get_cur
(). The
SYSCTL_ADD_UMA_CUR
(ctx,
parent, nbr,
name, zone,
descr) macro is provided to create this type of oid
dynamically.
The uma_zalloc
() function returns a
pointer to an item, or NULL
if the zone ran out of
unused items and M_NOWAIT
was specified.
The memory that these allocation calls return is not executable.
The uma_zalloc
() function does not support the
M_EXEC
flag to allocate executable memory. Not all
platforms enforce a distinction between executable and non-executable
memory.
The zone allocator first appeared in FreeBSD 3.0. It was radically changed in FreeBSD 5.0 to function as a slab allocator.
The zone allocator was written by John S. Dyson. The zone allocator was rewritten in large parts by Jeff Roberson <jeff@FreeBSD.org> to function as a slab allocator.
This manual page was written by Dag-Erling Smørgrav <des@FreeBSD.org>. Changes for UMA by Jeroen Ruigrok van der Werven <asmodai@FreeBSD.org>.
June 13, 2018 | Debian |