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26.\" $FreeBSD$
27.\"
28.Dd August 20, 2020
29.Dt UMA 9
30.Os
31.Sh NAME
32.Nm UMA
33.Nd general-purpose kernel object allocator
34.Sh SYNOPSIS
35.In sys/param.h
36.In sys/queue.h
37.In vm/uma.h
38.Cd "options UMA_FIRSTTOUCH"
39.Cd "options UMA_XDOMAIN"
40.Bd -literal
41typedef int (*uma_ctor)(void *mem, int size, void *arg, int flags);
42typedef void (*uma_dtor)(void *mem, int size, void *arg);
43typedef int (*uma_init)(void *mem, int size, int flags);
44typedef void (*uma_fini)(void *mem, int size);
45typedef int (*uma_import)(void *arg, void **store, int count, int domain,
46    int flags);
47typedef void (*uma_release)(void *arg, void **store, int count);
48typedef void *(*uma_alloc)(uma_zone_t zone, vm_size_t size, int domain,
49    uint8_t *pflag, int wait);
50typedef void (*uma_free)(void *item, vm_size_t size, uint8_t pflag);
51
52.Ed
53.Ft uma_zone_t
54.Fo uma_zcreate
55.Fa "char *name" "int size"
56.Fa "uma_ctor ctor" "uma_dtor dtor" "uma_init zinit" "uma_fini zfini"
57.Fa "int align" "uint16_t flags"
58.Fc
59.Ft uma_zone_t
60.Fo uma_zcache_create
61.Fa "char *name" "int size"
62.Fa "uma_ctor ctor" "uma_dtor dtor" "uma_init zinit" "uma_fini zfini"
63.Fa "uma_import zimport" "uma_release zrelease"
64.Fa "void *arg" "int flags"
65.Fc
66.Ft uma_zone_t
67.Fo uma_zsecond_create
68.Fa "char *name"
69.Fa "uma_ctor ctor" "uma_dtor dtor" "uma_init zinit" "uma_fini zfini"
70.Fa "uma_zone_t master"
71.Fc
72.Ft void
73.Fn uma_zdestroy "uma_zone_t zone"
74.Ft "void *"
75.Fn uma_zalloc "uma_zone_t zone" "int flags"
76.Ft "void *"
77.Fn uma_zalloc_arg "uma_zone_t zone" "void *arg" "int flags"
78.Ft "void *"
79.Fn uma_zalloc_domain "uma_zone_t zone" "void *arg" "int domain" "int flags"
80.Ft "void *"
81.Fn uma_zalloc_pcpu "uma_zone_t zone" "int flags"
82.Ft "void *"
83.Fn uma_zalloc_pcpu_arg "uma_zone_t zone" "void *arg" "int flags"
84.Ft void
85.Fn uma_zfree "uma_zone_t zone" "void *item"
86.Ft void
87.Fn uma_zfree_arg "uma_zone_t zone" "void *item" "void *arg"
88.Ft void
89.Fn uma_zfree_pcpu "uma_zone_t zone" "void *item"
90.Ft void
91.Fn uma_zfree_pcpu_arg "uma_zone_t zone" "void *item" "void *arg"
92.Ft void
93.Fn uma_prealloc "uma_zone_t zone" "int nitems"
94.Ft void
95.Fn uma_zone_reserve "uma_zone_t zone" "int nitems"
96.Ft void
97.Fn uma_zone_reserve_kva "uma_zone_t zone" "int nitems"
98.Ft void
99.Fn uma_reclaim "int req"
100.Ft void
101.Fn uma_zone_reclaim "uma_zone_t zone" "int req"
102.Ft void
103.Fn uma_zone_set_allocf "uma_zone_t zone" "uma_alloc allocf"
104.Ft void
105.Fn uma_zone_set_freef "uma_zone_t zone" "uma_free freef"
106.Ft int
107.Fn uma_zone_set_max "uma_zone_t zone" "int nitems"
108.Ft void
109.Fn uma_zone_set_maxcache "uma_zone_t zone" "int nitems"
110.Ft int
111.Fn uma_zone_get_max "uma_zone_t zone"
112.Ft int
113.Fn uma_zone_get_cur "uma_zone_t zone"
114.Ft void
115.Fn uma_zone_set_warning "uma_zone_t zone" "const char *warning"
116.Ft void
117.Fn uma_zone_set_maxaction "uma_zone_t zone" "void (*maxaction)(uma_zone_t)"
118.Ft void
119.Fn uma_reclaim
120.In sys/sysctl.h
121.Fn SYSCTL_UMA_MAX parent nbr name access zone descr
122.Fn SYSCTL_ADD_UMA_MAX ctx parent nbr name access zone descr
123.Fn SYSCTL_UMA_CUR parent nbr name access zone descr
124.Fn SYSCTL_ADD_UMA_CUR ctx parent nbr name access zone descr
125.Sh DESCRIPTION
126UMA (Universal Memory Allocator) provides an efficient interface for managing
127dynamically-sized collections of items of identical size, referred to as zones.
128Zones keep track of which items are in use and which
129are not, and UMA provides functions for allocating items from a zone and
130for releasing them back, making them available for subsequent allocation requests.
131Zones maintain per-CPU caches with linear scalability on SMP
132systems as well as round-robin and first-touch policies for NUMA
133systems.
134The number of items cached per CPU is bounded, and each zone additionally
135maintains an unbounded cache of items that is used to quickly satisfy
136per-CPU cache allocation misses.
137.Pp
138Two types of zones exist: regular zones and cache zones.
139In a regular zone, items are allocated from a slab, which is one or more
140virtually contiguous memory pages that have been allocated from the kernel's
141page allocator.
142Internally, slabs are managed by a UMA keg, which is responsible for allocating
143slabs and keeping track of their usage by one or more zones.
144In typical usage, there is one keg per zone, so slabs are not shared among
145multiple zones.
146.Pp
147Normal zones import items from a keg, and release items back to that keg if
148requested.
149Cache zones do not have a keg, and instead use custom import and release
150methods.
151For example, some collections of kernel objects are statically allocated
152at boot-time, and the size of the collection does not change.
153A cache zone can be used to implement an efficient allocator for the objects in
154such a collection.
155.Pp
156The
157.Fn uma_zcreate
158and
159.Fn uma_zcache_create
160functions create a new regular zone and cache zone, respectively.
161The
162.Fn uma_zsecond_create
163function creates a regular zone which shares the keg of the zone
164specified by the
165.Fa master
166argument.
167The
168.Fa name
169argument is a text name of the zone for debugging and stats; this memory
170should not be freed until the zone has been deallocated.
171.Pp
172The
173.Fa ctor
174and
175.Fa dtor
176arguments are callback functions that are called by
177the UMA subsystem at the time of the call to
178.Fn uma_zalloc
179and
180.Fn uma_zfree
181respectively.
182Their purpose is to provide hooks for initializing or
183destroying things that need to be done at the time of the allocation
184or release of a resource.
185A good usage for the
186.Fa ctor
187and
188.Fa dtor
189callbacks might be to initialize a data structure embedded in the item,
190such as a
191.Xr queue 3
192head.
193.Pp
194The
195.Fa zinit
196and
197.Fa zfini
198arguments are used to optimize the allocation of items from the zone.
199They are called by the UMA subsystem whenever
200it needs to allocate or free items to satisfy requests or memory pressure.
201A good use for the
202.Fa zinit
203and
204.Fa zfini
205callbacks might be to
206initialize and destroy a mutex contained within an item.
207This would allow one to avoid destroying and re-initializing the mutex
208each time the item is freed and re-allocated.
209They are not called on each call to
210.Fn uma_zalloc
211and
212.Fn uma_zfree
213but rather when an item is imported into a zone's cache, and when a zone
214releases an item to the slab allocator, typically as a response to memory
215pressure.
216.Pp
217For
218.Fn uma_zcache_create ,
219the
220.Fa zimport
221and
222.Fa zrelease
223functions are called to import items into the zone and to release items
224from the zone, respectively.
225The
226.Fa zimport
227function should store pointers to items in the
228.Fa store
229array, which contains a maximum of
230.Fa count
231entries.
232The function must return the number of imported items, which may be less than
233the maximum.
234Similarly, the
235.Fa store
236parameter to the
237.Fa zrelease
238function contains an array of
239.Fa count
240pointers to items.
241The
242.Fa arg
243parameter passed to
244.Fn uma_zcache_create
245is provided to the import and release functions.
246The
247.Fa domain
248parameter to
249.Fa zimport
250specifies the requested
251.Xr numa 4
252domain for the allocation.
253It is either a NUMA domain number or the special value
254.Dv UMA_ANYDOMAIN .
255.Pp
256The
257.Fa flags
258argument of
259.Fn uma_zcreate
260and
261.Fn uma_zcache_create
262is a subset of the following flags:
263.Bl -tag -width "foo"
264.It Dv UMA_ZONE_NOFREE
265Slabs allocated to the zone's keg are never freed.
266.It Dv UMA_ZONE_NODUMP
267Pages belonging to the zone will not be included in minidumps.
268.It Dv UMA_ZONE_PCPU
269An allocation from zone would have
270.Va mp_ncpu
271shadow copies, that are privately assigned to CPUs.
272A CPU can address its private copy using base the allocation address plus
273a multiple of the current CPU ID and
274.Fn sizeof "struct pcpu" :
275.Bd -literal -offset indent
276foo_zone = uma_zcreate(..., UMA_ZONE_PCPU);
277 ...
278foo_base = uma_zalloc(foo_zone, ...);
279 ...
280critical_enter();
281foo_pcpu = (foo_t *)zpcpu_get(foo_base);
282/* do something with foo_pcpu */
283critical_exit();
284
285.Ed
286Note that
287.Dv M_ZERO
288cannot be used when allocating items from a PCPU zone.
289To obtain zeroed memory from a PCPU zone, use the
290.Fn uma_zalloc_pcpu
291function and its variants instead, and pass
292.Dv M_ZERO .
293.It Dv UMA_ZONE_NOTOUCH
294The UMA subsystem may not directly touch (i.e. read or write) the slab memory.
295Otherwise, by default, book-keeping of items within a slab may be done in the
296slab page itself, and
297.Dv INVARIANTS
298kernels may also do use-after-free checking by accessing the slab memory.
299.It Dv UMA_ZONE_ZINIT
300The zone will have its
301.Ft uma_init
302method set to internal method that initializes a new allocated slab
303to all zeros.
304Do not mistake
305.Ft uma_init
306method with
307.Ft uma_ctor .
308A zone with
309.Dv UMA_ZONE_ZINIT
310flag would not return zeroed memory on every
311.Fn uma_zalloc .
312.It Dv UMA_ZONE_NOTPAGE
313An allocator function will be supplied with
314.Fn uma_zone_set_allocf
315and the memory that it returns may not be kernel virtual memory backed by VM
316pages in the page array.
317.It Dv UMA_ZONE_MALLOC
318The zone is for the
319.Xr malloc 9
320subsystem.
321.It Dv UMA_ZONE_VM
322The zone is for the VM subsystem.
323.It Dv UMA_ZONE_NUMA
324The zone should use a first-touch NUMA policy rather than the round-robin
325default.
326If the
327.Dv UMA_FIRSTTOUCH
328kernel option is configured, all zones implicitly use a first-touch policy,
329and the
330.Dv UMA_ZONE_NUMA
331flag has no effect.
332The
333.Dv UMA_XDOMAIN
334kernel option, when configured, causes UMA to do the extra tracking to ensure
335that allocations from first-touch zones are always local.
336Otherwise, consumers that do not free memory on the same domain from which it
337was allocated will cause mixing in per-CPU caches.
338See
339.Xr numa 4
340for more details.
341.It Dv UMA_ZONE_CONTIG
342Items in this zone must be contiguous in physical address space.
343Items will follow normal alignment constraints and may span page boundaries
344between pages with contiguous physical addresses.
345.El
346.Pp
347Zones can be destroyed using
348.Fn uma_zdestroy ,
349freeing all memory that is cached in the zone.
350All items allocated from the zone must be freed to the zone before the zone
351may be safely destroyed.
352.Pp
353To allocate an item from a zone, simply call
354.Fn uma_zalloc
355with a pointer to that zone and set the
356.Fa flags
357argument to selected flags as documented in
358.Xr malloc 9 .
359It will return a pointer to an item if successful, or
360.Dv NULL
361in the rare case where all items in the zone are in use and the
362allocator is unable to grow the zone and
363.Dv M_NOWAIT
364is specified.
365.Pp
366Items are released back to the zone from which they were allocated by
367calling
368.Fn uma_zfree
369with a pointer to the zone and a pointer to the item.
370If
371.Fa item
372is
373.Dv NULL ,
374then
375.Fn uma_zfree
376does nothing.
377.Pp
378The variants
379.Fn uma_zalloc_arg
380and
381.Fn uma_zfree_arg
382allow callers to
383specify an argument for the
384.Dv ctor
385and
386.Dv dtor
387functions of the zone, respectively.
388The
389.Fn uma_zalloc_domain
390function allows callers to specify a fixed
391.Xr numa 4
392domain to allocate from.
393This uses a guaranteed but slow path in the allocator which reduces
394concurrency.
395.Pp
396The
397.Fn uma_prealloc
398function allocates slabs for the requested number of items, typically following
399the initial creation of a zone.
400Subsequent allocations from the zone will be satisfied using the pre-allocated
401slabs.
402Note that slab allocation is performed with the
403.Dv M_WAITOK
404flag, so
405.Fn uma_prealloc
406may sleep.
407.Pp
408The
409.Fn uma_zone_reserve
410function sets the number of reserved items for the zone.
411.Fn uma_zalloc
412and variants will ensure that the zone contains at least the reserved number
413of free items.
414Reserved items may be allocated by specifying
415.Dv M_USE_RESERVE
416in the allocation request flags.
417.Fn uma_zone_reserve
418does not perform any pre-allocation by itself.
419.Pp
420The
421.Fn uma_zone_reserve_kva
422function pre-allocates kernel virtual address space for the requested
423number of items.
424Subsequent allocations from the zone will be satisfied using the pre-allocated
425address space.
426Note that unlike
427.Fn uma_zone_reserve ,
428.Fn uma_zone_reserve_kva
429does not restrict the use of the pre-allocation to
430.Dv M_USE_RESERVE
431requests.
432.Pp
433The
434.Fn uma_reclaim
435and
436.Fn uma_zone_reclaim
437functions reclaim cached items from UMA zones, releasing unused memory.
438The
439.Fn uma_reclaim
440function reclaims items from all regular zones, while
441.Fn uma_zone_reclaim
442reclaims items only from the specified zone.
443The
444.Fa req
445parameter must be one of three values which specify how aggressively
446items are to be reclaimed:
447.Bl -tag -width indent
448.It Dv UMA_RECLAIM_TRIM
449Reclaim items only in excess of the zone's estimated working set size.
450The working set size is periodically updated and tracks the recent history
451of the zone's usage.
452.It Dv UMA_RECLAIM_DRAIN
453Reclaim all items from the unbounded cache.
454Free items in the per-CPU caches are left alone.
455.It Dv UMA_RECLAIM_DRAIN_CPU
456Reclaim all cached items.
457.El
458.Pp
459The
460.Fn uma_zone_set_allocf
461and
462.Fn uma_zone_set_freef
463functions allow a zone's default slab allocation and free functions to be
464overridden.
465This is useful if memory with special constraints such as attributes,
466alignment, or address ranges must be used.
467.Pp
468The
469.Fn uma_zone_set_max
470function limits the number of items
471.Pq and therefore memory
472that can be allocated to
473.Fa zone .
474The
475.Fa nitems
476argument specifies the requested upper limit number of items.
477The effective limit is returned to the caller, as it may end up being higher
478than requested due to the implementation rounding up to ensure all memory pages
479allocated to the zone are utilised to capacity.
480The limit applies to the total number of items in the zone, which includes
481allocated items, free items and free items in the per-cpu caches.
482On systems with more than one CPU it may not be possible to allocate
483the specified number of items even when there is no shortage of memory,
484because all of the remaining free items may be in the caches of the
485other CPUs when the limit is hit.
486.Pp
487The
488.Fn uma_zone_set_maxcache
489function limits the number of free items which may be cached in the zone.
490This limit applies to both the per-CPU caches and the cache of free buckets.
491.Pp
492The
493.Fn uma_zone_get_max
494function returns the effective upper limit number of items for a zone.
495.Pp
496The
497.Fn uma_zone_get_cur
498function returns an approximation of the number of items currently allocated
499from the zone.
500The returned value is approximate because appropriate synchronisation to
501determine an exact value is not performed by the implementation.
502This ensures low overhead at the expense of potentially stale data being used
503in the calculation.
504.Pp
505The
506.Fn uma_zone_set_warning
507function sets a warning that will be printed on the system console when the
508given zone becomes full and fails to allocate an item.
509The warning will be printed no more often than every five minutes.
510Warnings can be turned off globally by setting the
511.Va vm.zone_warnings
512sysctl tunable to
513.Va 0 .
514.Pp
515The
516.Fn uma_zone_set_maxaction
517function sets a function that will be called when the given zone becomes full
518and fails to allocate an item.
519The function will be called with the zone locked.
520Also, the function
521that called the allocation function may have held additional locks.
522Therefore,
523this function should do very little work (similar to a signal handler).
524.Pp
525The
526.Fn SYSCTL_UMA_MAX parent nbr name access zone descr
527macro declares a static
528.Xr sysctl 9
529oid that exports the effective upper limit number of items for a zone.
530The
531.Fa zone
532argument should be a pointer to
533.Vt uma_zone_t .
534A read of the oid returns value obtained through
535.Fn uma_zone_get_max .
536A write to the oid sets new value via
537.Fn uma_zone_set_max .
538The
539.Fn SYSCTL_ADD_UMA_MAX ctx parent nbr name access zone descr
540macro is provided to create this type of oid dynamically.
541.Pp
542The
543.Fn SYSCTL_UMA_CUR parent nbr name access zone descr
544macro declares a static read-only
545.Xr sysctl 9
546oid that exports the approximate current occupancy of the zone.
547The
548.Fa zone
549argument should be a pointer to
550.Vt uma_zone_t .
551A read of the oid returns value obtained through
552.Fn uma_zone_get_cur .
553The
554.Fn SYSCTL_ADD_UMA_CUR ctx parent nbr name zone descr
555macro is provided to create this type of oid dynamically.
556.Sh IMPLEMENTATION NOTES
557The memory that these allocation calls return is not executable.
558The
559.Fn uma_zalloc
560function does not support the
561.Dv M_EXEC
562flag to allocate executable memory.
563Not all platforms enforce a distinction between executable and
564non-executable memory.
565.Sh SEE ALSO
566.Xr numa 4 ,
567.Xr vmstat 8 ,
568.Xr malloc 9
569.Rs
570.%A Jeff Bonwick
571.%T "The Slab Allocator: An Object-Caching Kernel Memory Allocator"
572.%D 1994
573.Re
574.Sh HISTORY
575The zone allocator first appeared in
576.Fx 3.0 .
577It was radically changed in
578.Fx 5.0
579to function as a slab allocator.
580.Sh AUTHORS
581.An -nosplit
582The zone allocator was written by
583.An John S. Dyson .
584The zone allocator was rewritten in large parts by
585.An Jeff Roberson Aq Mt jeff@FreeBSD.org
586to function as a slab allocator.
587.Pp
588This manual page was written by
589.An Dag-Erling Sm\(/orgrav Aq Mt des@FreeBSD.org .
590Changes for UMA by
591.An Jeroen Ruigrok van der Werven Aq Mt asmodai@FreeBSD.org .
592