The patch titled Subject: lib: objpool added: ring-array based lockless MPMC queue has been added to the -mm mm-nonmm-unstable branch. Its filename is lib-objpool-added-ring-array-based-lockless-mpmc-queue.patch This patch will shortly appear at https://git.kernel.org/pub/scm/linux/kernel/git/akpm/25-new.git/tree/patches/lib-objpool-added-ring-array-based-lockless-mpmc-queue.patch This patch will later appear in the mm-nonmm-unstable branch at git://git.kernel.org/pub/scm/linux/kernel/git/akpm/mm Before you just go and hit "reply", please: a) Consider who else should be cc'ed b) Prefer to cc a suitable mailing list as well c) Ideally: find the original patch on the mailing list and do a reply-to-all to that, adding suitable additional cc's *** Remember to use Documentation/process/submit-checklist.rst when testing your code *** The -mm tree is included into linux-next via the mm-everything branch at git://git.kernel.org/pub/scm/linux/kernel/git/akpm/mm and is updated there every 2-3 working days ------------------------------------------------------ From: wuqiang <wuqiang.matt@xxxxxxxxxxxxx> Subject: lib: objpool added: ring-array based lockless MPMC queue Date: Tue, 8 Nov 2022 15:14:40 +0800 Patch series "lib,kprobes: kretprobe scalability improvement", v6. This patch series introduces a scalable and lockless ring-array based object pool and replaces the original freelist (a LIFO queue based on singly linked list) to improve the scalability of kretprobed routines. This patch (of 6): The object pool is a scalable implementaion of high performance queue for objects allocation and reclamation, such as kretprobe instances. With leveraging per-cpu ring-array to mitigate the hot spots of memory contention, it could deliver near-linear scalability for high parallel scenarios. The ring-array is compactly managed in a single cache-line to benefit from warmed L1 cache for most cases (<= 4 objects per-core). The body of pre-allocated objects is stored in continuous cache-lines just after the ring-array. The object pool is interrupt safe. Both allocation and reclamation (object pop and push operations) can be preemptible or interruptable. It's best suited for following cases: 1) Memory allocation or reclamation are prohibited or too expensive 2) Consumers are of different priorities, such as irqs and threads Limitations: 1) Maximum objects (capacity) is determined during pool initializing 2) The memory of objects won't be freed until the poll is finalized 3) Object allocation (pop) may fail after trying all cpu slots 4) Object reclamation (push) won't fail but may take long time to finish for imbalanced scenarios. You can try larger max_entries to mitigate, or ( >= CPUS * nr_objs) to avoid Link: https://lkml.kernel.org/r/20221108071443.258794-1-wuqiang.matt@xxxxxxxxxxxxx Link: https://lkml.kernel.org/r/20221108071443.258794-2-wuqiang.matt@xxxxxxxxxxxxx Signed-off-by: wuqiang <wuqiang.matt@xxxxxxxxxxxxx> Cc: Anil S Keshavamurthy <anil.s.keshavamurthy@xxxxxxxxx> Cc: Dan Williams <dan.j.williams@xxxxxxxxx> Cc: David S. Miller <davem@xxxxxxxxxxxxx> Cc: Eric Biggers <ebiggers@xxxxxxxxxx> Cc: Josh Poimboeuf <jpoimboe@xxxxxxxxxx> Cc: Masami Hiramatsu (Google) <mhiramat@xxxxxxxxxx> Cc: "Naveen N. Rao" <naveen.n.rao@xxxxxxxxxxxxx> Cc: Peter Zijlstra <peterz@xxxxxxxxxxxxx> Cc: Sander Vanheule <sander@xxxxxxxxxxxxx> Cc: Steven Rostedt (VMware) <rostedt@xxxxxxxxxxx> Signed-off-by: Andrew Morton <akpm@xxxxxxxxxxxxxxxxxxxx> --- include/linux/objpool.h | 153 +++++++++++ lib/Makefile | 2 lib/objpool.c | 487 ++++++++++++++++++++++++++++++++++++++ 3 files changed, 641 insertions(+), 1 deletion(-) --- /dev/null +++ a/include/linux/objpool.h @@ -0,0 +1,153 @@ +/* SPDX-License-Identifier: GPL-2.0 */ + +#ifndef _LINUX_OBJPOOL_H +#define _LINUX_OBJPOOL_H + +#include <linux/types.h> + +/* + * objpool: ring-array based lockless MPMC queue + * + * Copyright: wuqiang.matt@xxxxxxxxxxxxx + * + * The object pool is a scalable implementaion of high performance queue + * for objects allocation and reclamation, such as kretprobe instances. + * + * With leveraging per-cpu ring-array to mitigate the hot spots of memory + * contention, it could deliver near-linear scalability for high parallel + * scenarios. The ring-array is compactly managed in a single cache-line + * to benefit from warmed L1 cache for most cases (<= 4 objects per-core). + * The body of pre-allocated objects is stored in continuous cache-lines + * just after the ring-array. + * + * The object pool is interrupt safe. Both allocation and reclamation + * (object pop and push operations) can be preemptible or interruptable. + * + * It's best suited for following cases: + * 1) Memory allocation or reclamation are prohibited or too expensive + * 2) Consumers are of different priorities, such as irqs and threads + * + * Limitations: + * 1) Maximum objects (capacity) is determined during pool initializing + * 2) The memory of objects won't be freed until the poll is finalized + * 3) Object allocation (pop) may fail after trying all cpu slots + * 4) Object reclamation (push) won't fail but may take long time to + * finish for imbalanced scenarios. You can try larger max_entries + * to mitigate, or ( >= CPUS * nr_objs) to avoid + */ + +/* + * objpool_slot: per-cpu ring array + * + * Represents a cpu-local array-based ring buffer, its size is specialized + * during initialization of object pool. + * + * The objpool_slot is allocated from local memory for NUMA system, and to + * be kept compact in a single cacheline. ages[] is stored just after the + * body of objpool_slot, and then entries[]. The Array of ages[] describes + * revision of each item, solely used to avoid ABA. And array of entries[] + * contains the pointers of objects. + * + * The default size of objpool_slot is a single cache-line, aka. 64 bytes. + * + * 64bit: + * 4 8 12 16 32 64 + * | head | tail | size | mask | ages[4] | ents[4]: (8 * 4) | objects + * + * 32bit: + * 4 8 12 16 32 48 64 + * | head | tail | size | mask | ages[4] | ents[4] | unused | objects + * + */ + +struct objpool_slot { + uint32_t head; /* head of ring array */ + uint32_t tail; /* tail of ring array */ + uint32_t size; /* array size, pow of 2 */ + uint32_t mask; /* size - 1 */ +} __attribute__((packed)); + +/* caller-specified object initial callback to setup each object, only called once */ +typedef int (*objpool_init_obj_cb)(void *context, void *obj); + +/* caller-specified cleanup callback for private objects/pool/context */ +typedef int (*objpool_release_cb)(void *context, void *ptr, uint32_t flags); + +/* called for object releasing: ptr points to an object */ +#define OBJPOOL_FLAG_NODE (0x00000001) +/* for user pool and context releasing, ptr could be NULL */ +#define OBJPOOL_FLAG_POOL (0x00001000) +/* the object or pool to be released is user-managed */ +#define OBJPOOL_FLAG_USER (0x00008000) + +/* + * objpool_head: object pooling metadata + */ + +struct objpool_head { + unsigned int obj_size; /* object & element size */ + unsigned int nr_objs; /* total objs (to be pre-allocated) */ + unsigned int nr_cpus; /* num of possible cpus */ + unsigned int capacity; /* max objects per cpuslot */ + unsigned long flags; /* flags for objpool management */ + gfp_t gfp; /* gfp flags for kmalloc & vmalloc */ + unsigned int pool_size; /* user pool size in byes */ + void *pool; /* user managed memory pool */ + struct objpool_slot **cpu_slots; /* array of percpu slots */ + unsigned int *slot_sizes; /* size in bytes of slots */ + objpool_release_cb release; /* resource cleanup callback */ + void *context; /* caller-provided context */ +}; + +#define OBJPOOL_FROM_VMALLOC (0x800000000) /* objpool allocated from vmalloc area */ +#define OBJPOOL_HAVE_OBJECTS (0x400000000) /* objects allocated along with objpool */ + +/* initialize object pool and pre-allocate objects */ +int objpool_init(struct objpool_head *head, unsigned int nr_objs, + unsigned int max_objs, unsigned int object_size, + gfp_t gfp, void *context, objpool_init_obj_cb objinit, + objpool_release_cb release); + +/* add objects in batch from user provided pool */ +int objpool_populate(struct objpool_head *head, void *pool, + unsigned int size, unsigned int object_size, + void *context, objpool_init_obj_cb objinit); + +/* add pre-allocated object (managed by user) to objpool */ +int objpool_add(void *obj, struct objpool_head *head); + +/* allocate an object from objects pool */ +void *objpool_pop(struct objpool_head *head); + +/* reclaim an object to objects pool */ +int objpool_push(void *node, struct objpool_head *head); + +/* cleanup the whole object pool (objects including) */ +void objpool_fini(struct objpool_head *head); + +/* whether the object is pre-allocated with percpu slots */ +static inline int objpool_is_inslot(void *obj, struct objpool_head *head) +{ + void *slot; + int i; + + if (!obj || !(head->flags & OBJPOOL_HAVE_OBJECTS)) + return 0; + + for (i = 0; i < head->nr_cpus; i++) { + slot = head->cpu_slots[i]; + if (obj >= slot && obj < slot + head->slot_sizes[i]) + return 1; + } + + return 0; +} + +/* whether the object is from user pool (batched adding) */ +static inline int objpool_is_inpool(void *obj, struct objpool_head *head) +{ + return (obj && head->pool && obj >= head->pool && + obj < head->pool + head->pool_size); +} + +#endif /* _LINUX_OBJPOOL_H */ --- a/lib/Makefile~lib-objpool-added-ring-array-based-lockless-mpmc-queue +++ a/lib/Makefile @@ -34,7 +34,7 @@ lib-y := ctype.o string.o vsprintf.o cmd is_single_threaded.o plist.o decompress.o kobject_uevent.o \ earlycpio.o seq_buf.o siphash.o dec_and_lock.o \ nmi_backtrace.o win_minmax.o memcat_p.o \ - buildid.o + buildid.o objpool.o lib-$(CONFIG_PRINTK) += dump_stack.o lib-$(CONFIG_SMP) += cpumask.o --- /dev/null +++ a/lib/objpool.c @@ -0,0 +1,487 @@ +// SPDX-License-Identifier: GPL-2.0 + +#include <linux/objpool.h> +#include <linux/slab.h> +#include <linux/vmalloc.h> +#include <linux/atomic.h> +#include <linux/prefetch.h> + +/* + * objpool: ring-array based lockless MPMC/FIFO queues + * + * Copyright: wuqiang.matt@xxxxxxxxxxxxx + */ + +/* compute the suitable num of objects to be managed by slot */ +static inline unsigned int __objpool_num_of_objs(unsigned int size) +{ + return rounddown_pow_of_two((size - sizeof(struct objpool_slot)) / + (sizeof(uint32_t) + sizeof(void *))); +} + +#define SLOT_AGES(s) ((uint32_t *)((char *)(s) + sizeof(struct objpool_slot))) +#define SLOT_ENTS(s) ((void **)((char *)(s) + sizeof(struct objpool_slot) + \ + sizeof(uint32_t) * (s)->size)) +#define SLOT_OBJS(s) ((void *)((char *)(s) + sizeof(struct objpool_slot) + \ + (sizeof(uint32_t) + sizeof(void *)) * (s)->size)) + +/* allocate and initialize percpu slots */ +static inline int +__objpool_init_percpu_slots(struct objpool_head *head, unsigned int nobjs, + void *context, objpool_init_obj_cb objinit) +{ + unsigned int i, j, n, size, objsz, nents = head->capacity; + + /* aligned object size by sizeof(void *) */ + objsz = ALIGN(head->obj_size, sizeof(void *)); + /* shall we allocate objects along with objpool_slot */ + if (objsz) + head->flags |= OBJPOOL_HAVE_OBJECTS; + + for (i = 0; i < head->nr_cpus; i++) { + struct objpool_slot *os; + + /* compute how many objects to be managed by this slot */ + n = nobjs / head->nr_cpus; + if (i < (nobjs % head->nr_cpus)) + n++; + size = sizeof(struct objpool_slot) + sizeof(void *) * nents + + sizeof(uint32_t) * nents + objsz * n; + + /* decide memory area for cpu-slot allocation */ + if (!i && !(head->gfp & GFP_ATOMIC) && size > PAGE_SIZE / 2) + head->flags |= OBJPOOL_FROM_VMALLOC; + + /* allocate percpu slot & objects from local memory */ + if (head->flags & OBJPOOL_FROM_VMALLOC) + os = __vmalloc_node(size, sizeof(void *), head->gfp, + cpu_to_node(i), __builtin_return_address(0)); + else + os = kmalloc_node(size, head->gfp, cpu_to_node(i)); + if (!os) + return -ENOMEM; + + /* initialize percpu slot for the i-th cpu */ + memset(os, 0, size); + os->size = head->capacity; + os->mask = os->size - 1; + head->cpu_slots[i] = os; + head->slot_sizes[i] = size; + + /* + * start from 2nd round to avoid conflict of 1st item. + * we assume that the head item is ready for retrieval + * iff head is equal to ages[head & mask]. but ages is + * initialized as 0, so in view of the caller of pop(), + * the 1st item (0th) is always ready, but fact could + * be: push() is stalled before the final update, thus + * the item being inserted will be lost forever. + */ + os->head = os->tail = head->capacity; + + if (!objsz) + continue; + + for (j = 0; j < n; j++) { + uint32_t *ages = SLOT_AGES(os); + void **ents = SLOT_ENTS(os); + void *obj = SLOT_OBJS(os) + j * objsz; + uint32_t ie = os->tail & os->mask; + + /* perform object initialization */ + if (objinit) { + int rc = objinit(context, obj); + if (rc) + return rc; + } + + /* add obj into the ring array */ + ents[ie] = obj; + ages[ie] = os->tail; + os->tail++; + head->nr_objs++; + } + } + + return 0; +} + +/* cleanup all percpu slots of the object pool */ +static inline void __objpool_fini_percpu_slots(struct objpool_head *head) +{ + unsigned int i; + + if (!head->cpu_slots) + return; + + for (i = 0; i < head->nr_cpus; i++) { + if (!head->cpu_slots[i]) + continue; + if (head->flags & OBJPOOL_FROM_VMALLOC) + vfree(head->cpu_slots[i]); + else + kfree(head->cpu_slots[i]); + } + kfree(head->cpu_slots); + head->cpu_slots = NULL; + head->slot_sizes = NULL; +} + +/** + * objpool_init: initialize object pool and pre-allocate objects + * + * args: + * @head: the object pool to be initialized, declared by caller + * @nr_objs: total objects to be pre-allocated by this object pool + * @max_objs: max entries (object pool capacity), use nr_objs if 0 + * @object_size: size of an object, no objects pre-allocated if 0 + * @gfp: flags for memory allocation (via kmalloc or vmalloc) + * @context: user context for object initialization callback + * @objinit: object initialization callback for extra setting-up + * @release: cleanup callback for private objects/pool/context + * + * return: + * 0 for success, otherwise error code + * + * All pre-allocated objects are to be zeroed. Caller could do extra + * initialization in objinit callback. The objinit callback will be + * called once and only once after the slot allocation. Then objpool + * won't touch any content of the objects since then. It's caller's + * duty to perform reinitialization after object allocation (pop) or + * clearance before object reclamation (push) if required. + */ +int objpool_init(struct objpool_head *head, unsigned int nr_objs, + unsigned int max_objs, unsigned int object_size, + gfp_t gfp, void *context, objpool_init_obj_cb objinit, + objpool_release_cb release) +{ + unsigned int nents, ncpus = num_possible_cpus(); + int rc; + + /* calculate percpu slot size (rounded to pow of 2) */ + if (max_objs < nr_objs) + max_objs = nr_objs; + nents = max_objs / ncpus; + if (nents < __objpool_num_of_objs(L1_CACHE_BYTES)) + nents = __objpool_num_of_objs(L1_CACHE_BYTES); + nents = roundup_pow_of_two(nents); + while (nents * ncpus < nr_objs) + nents = nents << 1; + + memset(head, 0, sizeof(struct objpool_head)); + head->nr_cpus = ncpus; + head->obj_size = object_size; + head->capacity = nents; + head->gfp = gfp & ~__GFP_ZERO; + head->context = context; + head->release = release; + + /* allocate array for percpu slots */ + head->cpu_slots = kzalloc(head->nr_cpus * sizeof(void *) + + head->nr_cpus * sizeof(uint32_t), head->gfp); + if (!head->cpu_slots) + return -ENOMEM; + head->slot_sizes = (uint32_t *)&head->cpu_slots[head->nr_cpus]; + + /* initialize per-cpu slots */ + rc = __objpool_init_percpu_slots(head, nr_objs, context, objinit); + if (rc) + __objpool_fini_percpu_slots(head); + + return rc; +} +EXPORT_SYMBOL_GPL(objpool_init); + +/* adding object to slot tail, the given slot must NOT be full */ +static inline int __objpool_add_slot(void *obj, struct objpool_slot *os) +{ + uint32_t *ages = SLOT_AGES(os); + void **ents = SLOT_ENTS(os); + uint32_t tail = atomic_inc_return((atomic_t *)&os->tail) - 1; + + WRITE_ONCE(ents[tail & os->mask], obj); + + /* order matters: obj must be updated before tail updating */ + smp_store_release(&ages[tail & os->mask], tail); + return 0; +} + +/* adding object to slot, abort if the slot was already full */ +static inline int __objpool_try_add_slot(void *obj, struct objpool_slot *os) +{ + uint32_t *ages = SLOT_AGES(os); + void **ents = SLOT_ENTS(os); + uint32_t head, tail; + + do { + /* perform memory loading for both head and tail */ + head = READ_ONCE(os->head); + tail = READ_ONCE(os->tail); + /* just abort if slot is full */ + if (tail >= head + os->size) + return -ENOENT; + /* try to extend tail by 1 using CAS to avoid races */ + if (try_cmpxchg_acquire(&os->tail, &tail, tail + 1)) + break; + } while (1); + + /* the tail-th of slot is reserved for the given obj */ + WRITE_ONCE(ents[tail & os->mask], obj); + /* update epoch id to make this object available for pop() */ + smp_store_release(&ages[tail & os->mask], tail); + return 0; +} + +/** + * objpool_populate: add objects from user provided pool in batch + * + * args: + * @head: object pool + * @pool: user buffer for pre-allocated objects + * @size: size of user buffer + * @object_size: size of object & element + * @context: user context for objinit callback + * @objinit: object initialization callback + * + * return: 0 or error code + */ +int objpool_populate(struct objpool_head *head, void *pool, + unsigned int size, unsigned int object_size, + void *context, objpool_init_obj_cb objinit) +{ + unsigned int n = head->nr_objs, used = 0, i; + + if (head->pool || !pool || size < object_size) + return -EINVAL; + if (head->obj_size && head->obj_size != object_size) + return -EINVAL; + if (head->context && context && head->context != context) + return -EINVAL; + if (head->nr_objs >= head->nr_cpus * head->capacity) + return -ENOENT; + + WARN_ON_ONCE(((unsigned long)pool) & (sizeof(void *) - 1)); + WARN_ON_ONCE(((uint32_t)object_size) & (sizeof(void *) - 1)); + + /* align object size by sizeof(void *) */ + head->obj_size = object_size; + object_size = ALIGN(object_size, sizeof(void *)); + if (object_size == 0) + return -EINVAL; + + while (used + object_size <= size) { + void *obj = pool + used; + + /* perform object initialization */ + if (objinit) { + int rc = objinit(context, obj); + if (rc) + return rc; + } + + /* insert obj to its corresponding objpool slot */ + i = (n + used * head->nr_cpus/size) % head->nr_cpus; + if (!__objpool_try_add_slot(obj, head->cpu_slots[i])) + head->nr_objs++; + + used += object_size; + } + + if (!used) + return -ENOENT; + + head->context = context; + head->pool = pool; + head->pool_size = size; + + return 0; +} +EXPORT_SYMBOL_GPL(objpool_populate); + +/** + * objpool_add: add pre-allocated object to objpool during pool + * initialization + * + * args: + * @obj: object pointer to be added to objpool + * @head: object pool to be inserted into + * + * return: + * 0 or error code + * + * objpool_add_node doesn't handle race conditions, can only be + * called during objpool initialization + */ +int objpool_add(void *obj, struct objpool_head *head) +{ + unsigned int i, cpu; + + if (!obj) + return -EINVAL; + if (head->nr_objs >= head->nr_cpus * head->capacity) + return -ENOENT; + + cpu = head->nr_objs % head->nr_cpus; + for (i = 0; i < head->nr_cpus; i++) { + if (!__objpool_try_add_slot(obj, head->cpu_slots[cpu])) { + head->nr_objs++; + return 0; + } + + if (++cpu >= head->nr_cpus) + cpu = 0; + } + + return -ENOENT; +} +EXPORT_SYMBOL_GPL(objpool_add); + +/** + * objpool_push: reclaim the object and return back to objects pool + * + * args: + * @obj: object pointer to be pushed to object pool + * @head: object pool + * + * return: + * 0 or error code: it fails only when objects pool are full + * + * objpool_push is non-blockable, and can be nested + */ +int objpool_push(void *obj, struct objpool_head *head) +{ + unsigned int cpu = raw_smp_processor_id() % head->nr_cpus; + + do { + if (head->nr_objs > head->capacity) { + if (!__objpool_try_add_slot(obj, head->cpu_slots[cpu])) + return 0; + } else { + if (!__objpool_add_slot(obj, head->cpu_slots[cpu])) + return 0; + } + if (++cpu >= head->nr_cpus) + cpu = 0; + } while (1); + + return -ENOENT; +} +EXPORT_SYMBOL_GPL(objpool_push); + +/* try to retrieve object from slot */ +static inline void *__objpool_try_get_slot(struct objpool_slot *os) +{ + uint32_t *ages = SLOT_AGES(os); + void **ents = SLOT_ENTS(os); + /* do memory load of head to local head */ + uint32_t head = smp_load_acquire(&os->head); + + /* loop if slot isn't empty */ + while (head != READ_ONCE(os->tail)) { + uint32_t id = head & os->mask, prev = head; + + /* do prefetching of object ents */ + prefetch(&ents[id]); + + /* + * check whether this item was ready for retrieval ? There's + * possibility * in theory * we might retrieve wrong object, + * in case ages[id] overflows when current task is sleeping, + * but it will take very very long to overflow an uint32_t + */ + if (smp_load_acquire(&ages[id]) == head) { + /* node must have been udpated by push() */ + void *node = READ_ONCE(ents[id]); + /* commit and move forward head of the slot */ + if (try_cmpxchg_release(&os->head, &head, head + 1)) + return node; + } + + /* re-load head from memory continue trying */ + head = READ_ONCE(os->head); + /* + * head stays unchanged, so it's very likely current pop() + * just preempted/interrupted an ongoing push() operation + */ + if (head == prev) + break; + } + + return NULL; +} + +/** + * objpool_pop: allocate an object from objects pool + * + * args: + * @oh: object pool + * + * return: + * object: NULL if failed (object pool is empty) + * + * objpool_pop can be nested, so can be used in any context. + */ +void *objpool_pop(struct objpool_head *head) +{ + unsigned int i, cpu; + void *obj = NULL; + + cpu = raw_smp_processor_id() % head->nr_cpus; + for (i = 0; i < head->nr_cpus; i++) { + struct objpool_slot *slot = head->cpu_slots[cpu]; + obj = __objpool_try_get_slot(slot); + if (obj) + break; + if (++cpu >= head->nr_cpus) + cpu = 0; + } + + return obj; +} +EXPORT_SYMBOL_GPL(objpool_pop); + +/** + * objpool_fini: cleanup the whole object pool (releasing all objects) + * + * args: + * @head: object pool to be released + * + */ +void objpool_fini(struct objpool_head *head) +{ + uint32_t i, flags; + + if (!head->cpu_slots) + return; + + if (!head->release) { + __objpool_fini_percpu_slots(head); + return; + } + + /* cleanup all objects remained in objpool */ + for (i = 0; i < head->nr_cpus; i++) { + void *obj; + do { + flags = OBJPOOL_FLAG_NODE; + obj = __objpool_try_get_slot(head->cpu_slots[i]); + if (!obj) + break; + if (!objpool_is_inpool(obj, head) && + !objpool_is_inslot(obj, head)) { + flags |= OBJPOOL_FLAG_USER; + } + head->release(head->context, obj, flags); + } while (obj); + } + + /* release percpu slots */ + __objpool_fini_percpu_slots(head); + + /* cleanup user private pool and related context */ + flags = OBJPOOL_FLAG_POOL; + if (head->pool) + flags |= OBJPOOL_FLAG_USER; + head->release(head->context, head->pool, flags); +} +EXPORT_SYMBOL_GPL(objpool_fini); _ Patches currently in -mm which might be from wuqiang.matt@xxxxxxxxxxxxx are lib-objpool-added-ring-array-based-lockless-mpmc-queue.patch lib-objpool-test-module-added.patch kprobes-kretprobe-scalability-improvement-with-objpool.patch kprobes-freelisth-removed.patch