Copyright (c)2006 YAMAMOTO Takashi,
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.Dd August 3, 2009 .Dt KMEM 9 .Os ------------------------------------------------------------
.Sh NAME .Nm kmem .Nd kernel wired memory allocator ------------------------------------------------------------
.Sh SYNOPSIS n sys/kmem.h - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
.Ft void * .Fn kmem_alloc \ "size_t size" "km_flag_t kmflags" .Ft void * .Fn kmem_zalloc \ "size_t size" "km_flag_t kmflags" .Ft void .Fn kmem_free \ "void *p" "size_t size" ------------------------------------------------------------
p .Cd "options DEBUG" .Sh DESCRIPTION .Fn kmem_alloc allocates kernel wired memory. It takes the following arguments. l -tag -width kmflags t Fa size Specify the size of allocation in bytes. t Fa kmflags Either of the following: l -tag -width KM_NOSLEEP t KM_SLEEP If the allocation cannot be satisfied immediately, sleep until enough memory is available. t KM_NOSLEEP Don't sleep. Immediately return .Dv NULL if there is not enough memory available. It should only be used when failure to allocate will not have harmful, user-visible effects.
p f -symbolic Use of .Dv KM_NOSLEEP is strongly discouraged as it can create transient, hard to debug failures that occur when the system is under memory pressure. .Ef
p In situations where it is not possible to sleep, for example because locks are held by the caller, the code path should be restructured to allow the allocation to be made in another place. .El .El
p The contents of allocated memory are uninitialized.
p Unlike Solaris, kmem_alloc(0, flags) is illegal.
p
------------------------------------------------------------
.Fn kmem_zalloc
is the equivalent of
.Fn kmem_alloc ,
except that it initializes the memory to zero.
p
------------------------------------------------------------
.Fn kmem_free
frees kernel wired memory allocated by
.Fn kmem_alloc
or
.Fn kmem_zalloc
so that it can be used for other purposes.
It takes the following arguments.
l -tag -width kmflags t Fa p The pointer to the memory being freed.
It must be the one returned by
.Fn kmem_alloc
or
.Fn kmem_zalloc .
t Fa size The size of the memory being freed, in bytes.
It must be the same as the
.Fa size
argument used for
.Fn kmem_alloc
or
.Fn kmem_zalloc
when the memory was allocated.
.El
p
Freeing
.Dv NULL
is illegal.
------------------------------------------------------------
.Sh NOTES
Making
.Dv KM_SLEEP
allocations while holding mutexes or reader/writer locks is discouraged, as the
caller can sleep for an unbounded amount of time in order to satisfy the
allocation.
This can in turn block other threads that wish to acquire locks held by the
caller.
p
For some locks this is permissible or even unavoidable.
For others, particularly locks that may be taken from soft interrupt context,
it is a serious problem.
As a general rule it is better not to allow this type of situation to develop.
One way to circumvent the problem is to make allocations speculative and part
of a retryable sequence.
For example:
d -literal retry:
/* speculative unlocked check */
if (need to allocate) {
new_item = kmem_alloc(sizeof(*new_item), KM_SLEEP);
} else {
new_item = NULL;
}
mutex_enter(lock);
/* check while holding lock for true status */
if (need to allocate) {
if (new_item == NULL) {
mutex_exit(lock);
goto retry;
}
consume(new_item);
new_item = NULL;
}
mutex_exit(lock);
if (new_item != NULL) {
/* did not use it after all */
kmem_free(new_item, sizeof(*new_item));
}
.Ed
------------------------------------------------------------
.Sh OPTIONS
Kernels compiled with the
.Dv DEBUG
option perform CPU intensive sanity checks on kmem operations,
and include the
.Dv kmguard
facility which can be enabled at runtime.
p .Dv kmguard adds additional, very high overhead runtime verification to kmem operations. To enable it, boot the system with the .Fl d option, which causes the debugger to be entered early during the kernel boot process. Issue commands such as the following: d -literal db\*[Gt] w kmem_guard_depth 0t30000 db\*[Gt] c .Ed
p This instructs .Dv kmguard to queue up to 60000 (30000*2) pages of unmapped KVA to catch use-after-free type errors. When .Fn kmem_free is called, memory backing a freed item is unmapped and the kernel VA space pushed onto a FIFO. The VA space will not be reused until another 30k items have been freed. Until reused the kernel will catch invalid accesses and panic with a page fault. Limitations: l -bullet t It has a severe impact on performance. t It is best used on a 64-bit machine with lots of RAM. t Allocations larger than PAGE_SIZE bypass the .Dv kmguard facility. .El
p
kmguard tries to catch the following types of bugs:
l -bullet t Overflow at time of occurrence, by means of a guard page.
t Underflow at
.Fn kmem_free ,
by using a canary value.
t Invalid pointer or size passed, at
.Fn kmem_free .
.El
.Sh RETURN VALUES
On success,
.Fn kmem_alloc
returns a pointer to allocated memory.
Otherwise, it returns
.Dv NULL .
------------------------------------------------------------
.Sh SEE ALSO
.Xr intro 9 ,
.Xr malloc 9 ,
.Xr memoryallocators 9
------------------------------------------------------------
.Sh CAVEATS
.Fn kmem_alloc
cannot be used from interrupt context, from a soft interrupt, or from
a callout.
Use
.Xr pool_cache 9
in these situations.
------------------------------------------------------------
.Sh SECURITY CONSIDERATION
As the allocated memory is uninitialized, it can contain security-sensitive
data left by its previous user.
It's the caller's responsibility not to expose it to the world.