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kmem_cache_alloc(9f) [opensolaris man page]

kmem_cache_create(9F)					   Kernel Functions for Drivers 				     kmem_cache_create(9F)

NAME
kmem_cache_create, kmem_cache_alloc, kmem_cache_free, kmem_cache_destroy, kmem_cache_set_move - kernel memory cache allocator operations SYNOPSIS
#include <sys/types.h> #include <sys/kmem.h> kmem_cache_t *kmem_cache_create(char *name, size_t bufsize, size_t align, int (*constructor)(void *, void *, int), void (*destructor)(void *, void *), void (*reclaim)(void *), void *private, void *vmp, int cflags); void kmem_cache_destroy(kmem_cache_t *cp); void *kmem_cache_alloc(kmem_cache_t *cp, int kmflag); void kmem_cache_free(kmem_cache_t *cp, void *obj); void kmem_cache_set_move(kmem_cache_t *cp, kmem_cbrc_t (*move)(void *, void *, size_t *, void *)); [Synopsis for callback functions:] int (*constructor)(void *buf, void *user_arg, int kmflags); void (*destructor)(void *buf, void *user_arg); kmem_cbrc_t (*move)(void *old, void *new, size_t bufsize, void *user_arg); INTERFACE LEVEL
Solaris DDI specific (Solaris DDI) PARAMETERS
The parameters for the kmem_cache_* functions are as follows: name Descriptive name of a kstat(9S) structure of class kmem_cache. Names longer than 31 characters are truncated. bufsize Size of the objects it manages. align Required object alignment. constructor Pointer to an object constructor function. Parameters are defined below. destructor Pointer to an object destructor function. Parameters are defined below. reclaim Drivers should pass NULL. private Pass-through argument for constructor/destructor. vmp Drivers should pass NULL. cflags Drivers must pass 0. kmflag Possible flags are: KM_SLEEP Allow sleeping (blocking) until memory is available. KM_NOSLEEP Return NULL immediately if memory is not available. KM_PUSHPAGE Allow the allocation to use reserved memory. obj Pointer to the object allocated by kmem_cache_alloc(). move Pointer to an object relocation function. Parameters are defined below. The parameters for the callback constructor function are as follows: void *buf Pointer to the object to be constructed. void *user_arg The private parameter from the call to kmem_cache_create(); it is typically a pointer to the soft-state structure. int kmflags Propagated kmflag values. The parameters for the callback destructor function are as follows: void *buf Pointer to the object to be deconstructed. void *user_arg The private parameter from the call to kmem_cache_create(); it is typically a pointer to the soft-state structure. The parameters for the callback move() function are as follows: void *old Pointer to the object to be moved. void *new Pointer to the object that serves as the copy destination for the contents of the old parameter. size_t bufsize Size of the object to be moved. void *user_arg The private parameter from the call to kmem_cache_create(); it is typically a pointer to the soft-state structure. DESCRIPTION
In many cases, the cost of initializing and destroying an object exceeds the cost of allocating and freeing memory for it. The functions described here address this condition. Object caching is a technique for dealing with objects that are: o frequently allocated and freed, and o have setup and initialization costs. The idea is to allow the allocator and its clients to cooperate to preserve the invariant portion of an object's initial state, or con- structed state, between uses, so it does not have to be destroyed and re-created every time the object is used. For example, an object con- taining a mutex only needs to have mutex_init() applied once, the first time the object is allocated. The object can then be freed and reallocated many times without incurring the expense of mutex_destroy() and mutex_init() each time. An object's embedded locks, condition variables, reference counts, lists of other objects, and read-only data all generally qualify as constructed state. The essential require- ment is that the client must free the object (using kmem_cache_free()) in its constructed state. The allocator cannot enforce this, so pro- gramming errors will lead to hard-to-find bugs. A driver should call kmem_cache_create() at the time of _fini(9E) or attach(9E), and call the corresponding kmem_cache_destroy() at the time of _fini(9E) or detach(9E). kmem_cache_create() creates a cache of objects, each of size bufsize bytes, aligned on an align boundary. Drivers not requiring a specific alignment can pass 0. name identifies the cache for statistics and debugging. constructor and destructor convert plain memory into objects and back again; constructor can fail if it needs to allocate memory but cannot. private is a parameter passed to the constructor and destructor callbacks to support parameterized caches (for example, a pointer to an instance of the driver's soft-state structure). To facilitate debugging, kmem_cache_create() creates a kstat(9S) structure of class kmem_cache and name name. It returns an opaque pointer to the object cache. kmem_cache_alloc() gets an object from the cache. The object will be in its constructed state. kmflag has either KM_SLEEP or KM_NOSLEEP set, indicating whether it is acceptable to wait for memory if none is currently available. A small pool of reserved memory is available to allow the system to progress toward the goal of freeing additional memory while in a low memory situation. The KM_PUSHPAGE flag enables use of this reserved memory pool on an allocation. This flag can be used by drivers that implement strategy(9E) on memory allocations associated with a single I/O operation. The driver guarantees that the I/O operation will com- plete (or timeout) and, on completion, that the memory will be returned. The KM_PUSHPAGE flag should be used only in kmem_cache_alloc() calls. All allocations from a given cache should be consistent in their use of the flag. A driver that adheres to these restrictions can guarantee progress in a low memory situation without resorting to complex private allocation and queuing schemes. If KM_PUSHPAGE is speci- fied, KM_SLEEP can also be used without causing deadlock. kmem_cache_free() returns an object to the cache. The object must be in its constructed state. kmem_cache_destroy() destroys the cache and releases all associated resources. All allocated objects must have been previously freed. kmem_cache_set_move() registers a function that the allocator may call to move objects from sparsely allocated pages of memory so that the system can reclaim pages that are tied up by the client. Since caching objects of the same size and type already makes severe memory frag- mentation unlikely, there is generally no need to register such a function. The idea is to make it possible to limit worst-case fragmenta- tion in caches that exhibit a tendency to become highly fragmented. Only clients that allocate a mix of long- and short-lived objects from the same cache are prone to exhibit this tendency, making them candidates for a move() callback. The move() callback supplies the client with two addresses: the allocated object that the allocator wants to move and a buffer selected by the allocator for the client to use as the copy destination. The new parameter is an allocated, constructed object ready to receive the contents of the old parameter. The bufsize parameter supplies the size of the object, in case a single move function handles multiple caches whose objects differ only in size. Finally, the private parameter passed to the constructor and destructor is also passed to the move() callback. Only the client knows about its own data and when it is a good time to move it. The client cooperates with the allocator to return unused memory to the system, and the allocator accepts this help at the client's convenience. When asked to move an object, the client can respond with any of the following: typedef enum kmem_cbrc { KMEM_CBRC_YES, KMEM_CBRC_NO, KMEM_CBRC_LATER, KMEM_CBRC_DONT_NEED, KMEM_CBRC_DONT_KNOW } kmem_cbrc_t; The client must not explicitly free either of the objects passed to the move() callback, since the allocator wants to free them directly to the slab layer (bypassing the per-CPU magazine layer). The response tells the allocator which of the two object parameters to free: KMEM_CBRC_YES The client moved the object; the allocator frees the old parameter. KMEM_CBRC_NO The client refused to move the object; the allocator frees the new parameter (the unused copy destination). KMEM_CBRC_LATER The client is using the object and cannot move it now; the allocator frees the new parameter (the unused copy desti- nation). The client should use KMEM_CBRC_LATER instead of KMEM_CBRC_NO if the object is likely to become movable soon. KMEM_CBRC_DONT_NEED The client no longer needs the object; the allocator frees both the old and new parameters. This response is the client's opportunity to be a model citizen and give back as much as it can. KMEM_CBRC_DONT_KNOW The client does not know about the object because: a) the client has just allocated the object and has not yet put it wherever it expects to find known objects b) the client has removed the object from wherever it expects to find known objects and is about to free the object c) the client has freed the object In all of these cases above, the allocator frees the new parameter (the unused copy destination) and searches for the old parameter in the magazine layer. If the object is found, it is removed from the magazine layer and freed to the slab layer so that it will no longer tie up an entire page of memory. Any object passed to the move() callback is guaranteed to have been touched only by the allocator or by the client. Because memory patterns applied by the allocator always set at least one of the two lowest order bits, the bottom two bits of any pointer member (other than char * or short *, which may not be 8-byte aligned on all platforms) are available to the client for marking cached objects that the client is about to free. This way, the client can recognize known objects in the move() callback by the unmarked (valid) pointer value. If the client refuses to move an object with either KMEM_CBRC_NO or KMEM_CBRC_LATER, and that object later becomes movable, the client can notify the allocator by calling kmem_cache_move_notify(). Alternatively, the client can simply wait for the allocator to call back again with the same object address. Responding KMEM_CRBC_NO even once or responding KMEM_CRBC_LATER too many times for the same object makes the allocator less likely to call back again for that object. [Synopsis for notification function:] void kmem_cache_move_notify(kmem_cache_t *cp, void *obj); The parameters for the notification function are as follows: cp Pointer to the object cache. obj Pointer to the object that has become movable since an earlier refusal to move it. CONTEXT
Constructors can be invoked during any call to kmem_cache_alloc(), and will run in that context. Similarly, destructors can be invoked dur- ing any call to kmem_cache_free(), and can also be invoked during kmem_cache_destroy(). Therefore, the functions that a constructor or destructor invokes must be appropriate in that context. Furthermore, the allocator may also call the constructor and destructor on objects still under its control without client involvement. kmem_cache_create() and kmem_cache_destroy() must not be called from interrupt context. kmem_cache_create() can also block for available memory. kmem_cache_alloc() can be called from interrupt context only if the KM_NOSLEEP flag is set. It can be called from user or kernel context with any valid flag. kmem_cache_free() can be called from user, kernel, or interrupt context. kmem_cache_set_move() is called from the same context as kmem_cache_create(), immediately after kmem_cache_create() and before allocating any objects from the cache. The registered move() callback is always invoked in the same global callback thread dedicated for move requests, guaranteeing that no mat- ter how many clients register a move() function, the allocator never tries to move more than one object at a time. Neither the allocator nor the client can be assumed to know the object's whereabouts at the time of the callback. EXAMPLES
Example 1 Object Caching Consider the following data structure: struct foo { kmutex_t foo_lock; kcondvar_t foo_cv; struct bar *foo_barlist; int foo_refcnt; }; Assume that a foo structure cannot be freed until there are no outstanding references to it (foo_refcnt == 0) and all of its pending bar events (whatever they are) have completed (foo_barlist == NULL). The life cycle of a dynamically allocated foo would be something like this: foo = kmem_alloc(sizeof (struct foo), KM_SLEEP); mutex_init(&foo->foo_lock, ...); cv_init(&foo->foo_cv, ...); foo->foo_refcnt = 0; foo->foo_barlist = NULL; use foo; ASSERT(foo->foo_barlist == NULL); ASSERT(foo->foo_refcnt == 0); cv_destroy(&foo->foo_cv); mutex_destroy(&foo->foo_lock); kmem_free(foo); Notice that between each use of a foo object we perform a sequence of operations that constitutes nothing but expensive overhead. All of this overhead (that is, everything other than use foo above) can be eliminated by object caching. int foo_constructor(void *buf, void *arg, int tags) { struct foo *foo = buf; mutex_init(&foo->foo_lock, ...); cv_init(&foo->foo_cv, ...); foo->foo_refcnt = 0; foo->foo_barlist = NULL; return(0); } void foo_destructor(void *buf, void *arg) { struct foo *foo = buf; ASSERT(foo->foo_barlist == NULL); ASSERT(foo->foo_refcnt == 0); cv_destroy(&foo->foo_cv); mutex_destroy(&foo->foo_lock); } user_arg = ddi_get_soft_state(foo_softc, instance); (void) snprintf(buf, KSTAT_STRLEN, "foo%d_cache", ddi_get_instance(dip)); foo_cache = kmem_cache_create(buf, sizeof (struct foo), 0, foo_constructor, foo_destructor, NULL, user_arg, 0); To allocate, use, and free a foo object: foo = kmem_cache_alloc(foo_cache, KM_SLEEP); use foo; kmem_cache_free(foo_cache, foo); This makes foo allocation fast, because the allocator will usually do nothing more than fetch an already-constructed foo from the cache. foo_constructor and foo_destructor will be invoked only to populate and drain the cache, respectively. Example 2 Registering a Move Callback To register a move() callback: object_cache = kmem_cache_create(...); kmem_cache_set_move(object_cache, object_move); RETURN VALUES
If successful, the constructor function must return 0. If KM_NOSLEEP is set and memory cannot be allocated without sleeping, the construc- tor must return -1. kmem_cache_create() returns a pointer to the allocated cache. If successful, kmem_cache_alloc() returns a pointer to the allocated object. If KM_NOSLEEP is set and memory cannot be allocated without sleeping, kmem_cache_alloc() returns NULL. ATTRIBUTES
See attributes(5) for descriptions of the following attributes: +-----------------------------+-----------------------------+ | ATTRIBUTE TYPE | ATTRIBUTE VALUE | +-----------------------------+-----------------------------+ |Interface Stability |Committed | +-----------------------------+-----------------------------+ SEE ALSO
condvar(9F), kmem_alloc(9F), mutex(9F), kstat(9S) Writing Device Drivers The Slab Allocator: An Object-Caching Kernel Memory Allocator, Bonwick, J.; USENIX Summer 1994 Technical Conference(1994). Magazines and vmem: Extending the Slab Allocator to Many CPUs and Arbitrary Resources, Bonwick, J. and Adams, J.; USENIX 2001 Technical Conference(2001). NOTES
The constructor must be immediately reversible by the destructor, since the allocator may call the constructor and destructor on objects still under its control at any time without client involvement. The constructor must respect the kmflags argument by forwarding it to allocations made inside the constructor, and must not ASSERT anything about the given flags. The user argument forwarded to the constructor must be fully operational before it is passed to kmem_cache_create(). SunOS 5.11 24 Jun 2008 kmem_cache_create(9F)
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