| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Linus Torvalds | 585 | 20.40% | 2 | 2.70% |
| David Rientjes | 567 | 19.78% | 3 | 4.05% |
| Christoph Hellwig | 529 | 18.45% | 9 | 12.16% |
| Andrew Morton | 190 | 6.63% | 6 | 8.11% |
| Alasdair G. Kergon | 143 | 4.99% | 1 | 1.35% |
| Kent Overstreet | 142 | 4.95% | 2 | 2.70% |
| Matthew Dobson | 108 | 3.77% | 2 | 2.70% |
| Vlastimil Babka | 90 | 3.14% | 2 | 2.70% |
| Andrey Ryabinin | 83 | 2.90% | 3 | 4.05% |
| Andrey Konovalov | 80 | 2.79% | 5 | 6.76% |
| Yadan Fan | 54 | 1.88% | 2 | 2.70% |
| Alan Cox | 53 | 1.85% | 1 | 1.35% |
| Kees Cook | 52 | 1.81% | 1 | 1.35% |
| Tejun Heo | 47 | 1.64% | 4 | 5.41% |
| Prasanna Meda | 28 | 0.98% | 1 | 1.35% |
| Christoph Lameter | 17 | 0.59% | 1 | 1.35% |
| Miaohe Lin | 12 | 0.42% | 1 | 1.35% |
| Nicholas Piggin | 10 | 0.35% | 2 | 2.70% |
| Linus Torvalds (pre-git) | 10 | 0.35% | 6 | 8.11% |
| Pavel Mironchik | 8 | 0.28% | 1 | 1.35% |
| Catalin Marinas | 7 | 0.24% | 1 | 1.35% |
| Qian Cai | 6 | 0.21% | 1 | 1.35% |
| Benjamin LaHaise | 6 | 0.21% | 1 | 1.35% |
| Mikulas Patocka | 5 | 0.17% | 1 | 1.35% |
| Sebastian Ott | 5 | 0.17% | 1 | 1.35% |
| Al Viro | 4 | 0.14% | 1 | 1.35% |
| Pekka J Enberg | 4 | 0.14% | 1 | 1.35% |
| Fabio De Francesco | 4 | 0.14% | 1 | 1.35% |
| Suren Baghdasaryan | 3 | 0.10% | 1 | 1.35% |
| Mike Rapoport | 2 | 0.07% | 1 | 1.35% |
| Dmitriy Vyukov | 2 | 0.07% | 1 | 1.35% |
| Daniel Vetter | 2 | 0.07% | 1 | 1.35% |
| Johannes Thumshirn | 2 | 0.07% | 1 | 1.35% |
| Matthew Dawson | 2 | 0.07% | 1 | 1.35% |
| Thomas Weißschuh | 1 | 0.03% | 1 | 1.35% |
| Mel Gorman | 1 | 0.03% | 1 | 1.35% |
| Paul Gortmaker | 1 | 0.03% | 1 | 1.35% |
| Simon Arlott | 1 | 0.03% | 1 | 1.35% |
| Greg Kroah-Hartman | 1 | 0.03% | 1 | 1.35% |
| Total | 2867 | 74 |
// SPDX-License-Identifier: GPL-2.0 /* * memory buffer pool support. Such pools are mostly used * for guaranteed, deadlock-free memory allocations during * extreme VM load. * * started by Ingo Molnar, Copyright (C) 2001 * debugging by David Rientjes, Copyright (C) 2015 */ #include <linux/fault-inject.h> #include <linux/mm.h> #include <linux/slab.h> #include <linux/highmem.h> #include <linux/kasan.h> #include <linux/kmemleak.h> #include <linux/export.h> #include <linux/mempool.h> #include <linux/writeback.h> #include "slab.h" static DECLARE_FAULT_ATTR(fail_mempool_alloc); static DECLARE_FAULT_ATTR(fail_mempool_alloc_bulk); static int __init mempool_faul_inject_init(void) { int error; error = PTR_ERR_OR_ZERO(fault_create_debugfs_attr("fail_mempool_alloc", NULL, &fail_mempool_alloc)); if (error) return error; /* booting will fail on error return here, don't bother to cleanup */ return PTR_ERR_OR_ZERO( fault_create_debugfs_attr("fail_mempool_alloc_bulk", NULL, &fail_mempool_alloc_bulk)); } late_initcall(mempool_faul_inject_init); #ifdef CONFIG_SLUB_DEBUG_ON static void poison_error(struct mempool *pool, void *element, size_t size, size_t byte) { const int nr = pool->curr_nr; const int start = max_t(int, byte - (BITS_PER_LONG / 8), 0); const int end = min_t(int, byte + (BITS_PER_LONG / 8), size); int i; pr_err("BUG: mempool element poison mismatch\n"); pr_err("Mempool %p size %zu\n", pool, size); pr_err(" nr=%d @ %p: %s0x", nr, element, start > 0 ? "... " : ""); for (i = start; i < end; i++) pr_cont("%x ", *(u8 *)(element + i)); pr_cont("%s\n", end < size ? "..." : ""); dump_stack(); } static void __check_element(struct mempool *pool, void *element, size_t size) { u8 *obj = element; size_t i; for (i = 0; i < size; i++) { u8 exp = (i < size - 1) ? POISON_FREE : POISON_END; if (obj[i] != exp) { poison_error(pool, element, size, i); return; } } memset(obj, POISON_INUSE, size); } static void check_element(struct mempool *pool, void *element) { /* Skip checking: KASAN might save its metadata in the element. */ if (kasan_enabled()) return; /* Mempools backed by slab allocator */ if (pool->free == mempool_kfree) { __check_element(pool, element, (size_t)pool->pool_data); } else if (pool->free == mempool_free_slab) { __check_element(pool, element, kmem_cache_size(pool->pool_data)); } else if (pool->free == mempool_free_pages) { /* Mempools backed by page allocator */ int order = (int)(long)pool->pool_data; #ifdef CONFIG_HIGHMEM for (int i = 0; i < (1 << order); i++) { struct page *page = (struct page *)element; void *addr = kmap_local_page(page + i); __check_element(pool, addr, PAGE_SIZE); kunmap_local(addr); } #else void *addr = page_address((struct page *)element); __check_element(pool, addr, PAGE_SIZE << order); #endif } } static void __poison_element(void *element, size_t size) { u8 *obj = element; memset(obj, POISON_FREE, size - 1); obj[size - 1] = POISON_END; } static void poison_element(struct mempool *pool, void *element) { /* Skip poisoning: KASAN might save its metadata in the element. */ if (kasan_enabled()) return; /* Mempools backed by slab allocator */ if (pool->alloc == mempool_kmalloc) { __poison_element(element, (size_t)pool->pool_data); } else if (pool->alloc == mempool_alloc_slab) { __poison_element(element, kmem_cache_size(pool->pool_data)); } else if (pool->alloc == mempool_alloc_pages) { /* Mempools backed by page allocator */ int order = (int)(long)pool->pool_data; #ifdef CONFIG_HIGHMEM for (int i = 0; i < (1 << order); i++) { struct page *page = (struct page *)element; void *addr = kmap_local_page(page + i); __poison_element(addr, PAGE_SIZE); kunmap_local(addr); } #else void *addr = page_address((struct page *)element); __poison_element(addr, PAGE_SIZE << order); #endif } } #else /* CONFIG_SLUB_DEBUG_ON */ static inline void check_element(struct mempool *pool, void *element) { } static inline void poison_element(struct mempool *pool, void *element) { } #endif /* CONFIG_SLUB_DEBUG_ON */ static __always_inline bool kasan_poison_element(struct mempool *pool, void *element) { if (pool->alloc == mempool_alloc_slab || pool->alloc == mempool_kmalloc) return kasan_mempool_poison_object(element); else if (pool->alloc == mempool_alloc_pages) return kasan_mempool_poison_pages(element, (unsigned long)pool->pool_data); return true; } static void kasan_unpoison_element(struct mempool *pool, void *element) { if (pool->alloc == mempool_kmalloc) kasan_mempool_unpoison_object(element, (size_t)pool->pool_data); else if (pool->alloc == mempool_alloc_slab) kasan_mempool_unpoison_object(element, kmem_cache_size(pool->pool_data)); else if (pool->alloc == mempool_alloc_pages) kasan_mempool_unpoison_pages(element, (unsigned long)pool->pool_data); } static __always_inline void add_element(struct mempool *pool, void *element) { BUG_ON(pool->min_nr != 0 && pool->curr_nr >= pool->min_nr); poison_element(pool, element); if (kasan_poison_element(pool, element)) pool->elements[pool->curr_nr++] = element; } static void *remove_element(struct mempool *pool) { void *element = pool->elements[--pool->curr_nr]; BUG_ON(pool->curr_nr < 0); kasan_unpoison_element(pool, element); check_element(pool, element); return element; } /** * mempool_exit - exit a mempool initialized with mempool_init() * @pool: pointer to the memory pool which was initialized with * mempool_init(). * * Free all reserved elements in @pool and @pool itself. This function * only sleeps if the free_fn() function sleeps. * * May be called on a zeroed but uninitialized mempool (i.e. allocated with * kzalloc()). */ void mempool_exit(struct mempool *pool) { while (pool->curr_nr) { void *element = remove_element(pool); pool->free(element, pool->pool_data); } kfree(pool->elements); pool->elements = NULL; } EXPORT_SYMBOL(mempool_exit); /** * mempool_destroy - deallocate a memory pool * @pool: pointer to the memory pool which was allocated via * mempool_create(). * * Free all reserved elements in @pool and @pool itself. This function * only sleeps if the free_fn() function sleeps. */ void mempool_destroy(struct mempool *pool) { if (unlikely(!pool)) return; mempool_exit(pool); kfree(pool); } EXPORT_SYMBOL(mempool_destroy); int mempool_init_node(struct mempool *pool, int min_nr, mempool_alloc_t *alloc_fn, mempool_free_t *free_fn, void *pool_data, gfp_t gfp_mask, int node_id) { spin_lock_init(&pool->lock); pool->min_nr = min_nr; pool->pool_data = pool_data; pool->alloc = alloc_fn; pool->free = free_fn; init_waitqueue_head(&pool->wait); /* * max() used here to ensure storage for at least 1 element to support * zero minimum pool */ pool->elements = kmalloc_array_node(max(1, min_nr), sizeof(void *), gfp_mask, node_id); if (!pool->elements) return -ENOMEM; /* * First pre-allocate the guaranteed number of buffers, * also pre-allocate 1 element for zero minimum pool. */ while (pool->curr_nr < max(1, pool->min_nr)) { void *element; element = pool->alloc(gfp_mask, pool->pool_data); if (unlikely(!element)) { mempool_exit(pool); return -ENOMEM; } add_element(pool, element); } return 0; } EXPORT_SYMBOL(mempool_init_node); /** * mempool_init - initialize a memory pool * @pool: pointer to the memory pool that should be initialized * @min_nr: the minimum number of elements guaranteed to be * allocated for this pool. * @alloc_fn: user-defined element-allocation function. * @free_fn: user-defined element-freeing function. * @pool_data: optional private data available to the user-defined functions. * * Like mempool_create(), but initializes the pool in (i.e. embedded in another * structure). * * Return: %0 on success, negative error code otherwise. */ int mempool_init_noprof(struct mempool *pool, int min_nr, mempool_alloc_t *alloc_fn, mempool_free_t *free_fn, void *pool_data) { return mempool_init_node(pool, min_nr, alloc_fn, free_fn, pool_data, GFP_KERNEL, NUMA_NO_NODE); } EXPORT_SYMBOL(mempool_init_noprof); /** * mempool_create_node - create a memory pool * @min_nr: the minimum number of elements guaranteed to be * allocated for this pool. * @alloc_fn: user-defined element-allocation function. * @free_fn: user-defined element-freeing function. * @pool_data: optional private data available to the user-defined functions. * @gfp_mask: memory allocation flags * @node_id: numa node to allocate on * * this function creates and allocates a guaranteed size, preallocated * memory pool. The pool can be used from the mempool_alloc() and mempool_free() * functions. This function might sleep. Both the alloc_fn() and the free_fn() * functions might sleep - as long as the mempool_alloc() function is not called * from IRQ contexts. * * Return: pointer to the created memory pool object or %NULL on error. */ struct mempool *mempool_create_node_noprof(int min_nr, mempool_alloc_t *alloc_fn, mempool_free_t *free_fn, void *pool_data, gfp_t gfp_mask, int node_id) { struct mempool *pool; pool = kmalloc_node_noprof(sizeof(*pool), gfp_mask | __GFP_ZERO, node_id); if (!pool) return NULL; if (mempool_init_node(pool, min_nr, alloc_fn, free_fn, pool_data, gfp_mask, node_id)) { kfree(pool); return NULL; } return pool; } EXPORT_SYMBOL(mempool_create_node_noprof); /** * mempool_resize - resize an existing memory pool * @pool: pointer to the memory pool which was allocated via * mempool_create(). * @new_min_nr: the new minimum number of elements guaranteed to be * allocated for this pool. * * This function shrinks/grows the pool. In the case of growing, * it cannot be guaranteed that the pool will be grown to the new * size immediately, but new mempool_free() calls will refill it. * This function may sleep. * * Note, the caller must guarantee that no mempool_destroy is called * while this function is running. mempool_alloc() & mempool_free() * might be called (eg. from IRQ contexts) while this function executes. * * Return: %0 on success, negative error code otherwise. */ int mempool_resize(struct mempool *pool, int new_min_nr) { void *element; void **new_elements; unsigned long flags; BUG_ON(new_min_nr <= 0); might_sleep(); spin_lock_irqsave(&pool->lock, flags); if (new_min_nr <= pool->min_nr) { while (new_min_nr < pool->curr_nr) { element = remove_element(pool); spin_unlock_irqrestore(&pool->lock, flags); pool->free(element, pool->pool_data); spin_lock_irqsave(&pool->lock, flags); } pool->min_nr = new_min_nr; goto out_unlock; } spin_unlock_irqrestore(&pool->lock, flags); /* Grow the pool */ new_elements = kmalloc_array(new_min_nr, sizeof(*new_elements), GFP_KERNEL); if (!new_elements) return -ENOMEM; spin_lock_irqsave(&pool->lock, flags); if (unlikely(new_min_nr <= pool->min_nr)) { /* Raced, other resize will do our work */ spin_unlock_irqrestore(&pool->lock, flags); kfree(new_elements); goto out; } memcpy(new_elements, pool->elements, pool->curr_nr * sizeof(*new_elements)); kfree(pool->elements); pool->elements = new_elements; pool->min_nr = new_min_nr; while (pool->curr_nr < pool->min_nr) { spin_unlock_irqrestore(&pool->lock, flags); element = pool->alloc(GFP_KERNEL, pool->pool_data); if (!element) goto out; spin_lock_irqsave(&pool->lock, flags); if (pool->curr_nr < pool->min_nr) { add_element(pool, element); } else { spin_unlock_irqrestore(&pool->lock, flags); pool->free(element, pool->pool_data); /* Raced */ goto out; } } out_unlock: spin_unlock_irqrestore(&pool->lock, flags); out: return 0; } EXPORT_SYMBOL(mempool_resize); static unsigned int mempool_alloc_from_pool(struct mempool *pool, void **elems, unsigned int count, unsigned int allocated, gfp_t gfp_mask) { unsigned long flags; unsigned int i; spin_lock_irqsave(&pool->lock, flags); if (unlikely(pool->curr_nr < count - allocated)) goto fail; for (i = 0; i < count; i++) { if (!elems[i]) { elems[i] = remove_element(pool); allocated++; } } spin_unlock_irqrestore(&pool->lock, flags); /* Paired with rmb in mempool_free(), read comment there. */ smp_wmb(); /* * Update the allocation stack trace as this is more useful for * debugging. */ for (i = 0; i < count; i++) kmemleak_update_trace(elems[i]); return allocated; fail: if (gfp_mask & __GFP_DIRECT_RECLAIM) { DEFINE_WAIT(wait); prepare_to_wait(&pool->wait, &wait, TASK_UNINTERRUPTIBLE); spin_unlock_irqrestore(&pool->lock, flags); /* * Wait for someone else to return an element to @pool, but wake * up occasionally as memory pressure might have reduced even * and the normal allocation in alloc_fn could succeed even if * no element was returned. */ io_schedule_timeout(5 * HZ); finish_wait(&pool->wait, &wait); } else { /* We must not sleep if __GFP_DIRECT_RECLAIM is not set. */ spin_unlock_irqrestore(&pool->lock, flags); } return allocated; } /* * Adjust the gfp flags for mempool allocations, as we never want to dip into * the global emergency reserves or retry in the page allocator. * * The first pass also doesn't want to go reclaim, but the next passes do, so * return a separate subset for that first iteration. */ static inline gfp_t mempool_adjust_gfp(gfp_t *gfp_mask) { *gfp_mask |= __GFP_NOMEMALLOC | __GFP_NORETRY | __GFP_NOWARN; return *gfp_mask & ~(__GFP_DIRECT_RECLAIM | __GFP_IO); } /** * mempool_alloc_bulk - allocate multiple elements from a memory pool * @pool: pointer to the memory pool * @elems: partially or fully populated elements array * @count: number of entries in @elem that need to be allocated * @allocated: number of entries in @elem already allocated * * Allocate elements for each slot in @elem that is non-%NULL. This is done by * first calling into the alloc_fn supplied at pool initialization time, and * dipping into the reserved pool when alloc_fn fails to allocate an element. * * On return all @count elements in @elems will be populated. * * Return: Always 0. If it wasn't for %$#^$ alloc tags, it would return void. */ int mempool_alloc_bulk_noprof(struct mempool *pool, void **elems, unsigned int count, unsigned int allocated) { gfp_t gfp_mask = GFP_KERNEL; gfp_t gfp_temp = mempool_adjust_gfp(&gfp_mask); unsigned int i = 0; VM_WARN_ON_ONCE(count > pool->min_nr); might_alloc(gfp_mask); /* * If an error is injected, fail all elements in a bulk allocation so * that we stress the multiple elements missing path. */ if (should_fail_ex(&fail_mempool_alloc_bulk, 1, FAULT_NOWARN)) { pr_info("forcing mempool usage for %pS\n", (void *)_RET_IP_); goto use_pool; } repeat_alloc: /* * Try to allocate the elements using the allocation callback first as * that might succeed even when the caller's bulk allocation did not. */ for (i = 0; i < count; i++) { if (elems[i]) continue; elems[i] = pool->alloc(gfp_temp, pool->pool_data); if (unlikely(!elems[i])) goto use_pool; allocated++; } return 0; use_pool: allocated = mempool_alloc_from_pool(pool, elems, count, allocated, gfp_temp); gfp_temp = gfp_mask; goto repeat_alloc; } EXPORT_SYMBOL_GPL(mempool_alloc_bulk_noprof); /** * mempool_alloc - allocate an element from a memory pool * @pool: pointer to the memory pool * @gfp_mask: GFP_* flags. %__GFP_ZERO is not supported. * * Allocate an element from @pool. This is done by first calling into the * alloc_fn supplied at pool initialization time, and dipping into the reserved * pool when alloc_fn fails to allocate an element. * * This function only sleeps if the alloc_fn callback sleeps, or when waiting * for elements to become available in the pool. * * Return: pointer to the allocated element or %NULL when failing to allocate * an element. Allocation failure can only happen when @gfp_mask does not * include %__GFP_DIRECT_RECLAIM. */ void *mempool_alloc_noprof(struct mempool *pool, gfp_t gfp_mask) { gfp_t gfp_temp = mempool_adjust_gfp(&gfp_mask); void *element; VM_WARN_ON_ONCE(gfp_mask & __GFP_ZERO); might_alloc(gfp_mask); repeat_alloc: if (should_fail_ex(&fail_mempool_alloc, 1, FAULT_NOWARN)) { pr_info("forcing mempool usage for %pS\n", (void *)_RET_IP_); element = NULL; } else { element = pool->alloc(gfp_temp, pool->pool_data); } if (unlikely(!element)) { /* * Try to allocate an element from the pool. * * The first pass won't have __GFP_DIRECT_RECLAIM and won't * sleep in mempool_alloc_from_pool. Retry the allocation * with all flags set in that case. */ if (!mempool_alloc_from_pool(pool, &element, 1, 0, gfp_temp)) { if (gfp_temp != gfp_mask) { gfp_temp = gfp_mask; goto repeat_alloc; } if (gfp_mask & __GFP_DIRECT_RECLAIM) { goto repeat_alloc; } } } return element; } EXPORT_SYMBOL(mempool_alloc_noprof); /** * mempool_alloc_preallocated - allocate an element from preallocated elements * belonging to a memory pool * @pool: pointer to the memory pool * * This function is similar to mempool_alloc(), but it only attempts allocating * an element from the preallocated elements. It only takes a single spinlock_t * and immediately returns if no preallocated elements are available. * * Return: pointer to the allocated element or %NULL if no elements are * available. */ void *mempool_alloc_preallocated(struct mempool *pool) { void *element = NULL; mempool_alloc_from_pool(pool, &element, 1, 0, GFP_NOWAIT); return element; } EXPORT_SYMBOL(mempool_alloc_preallocated); /** * mempool_free_bulk - return elements to a mempool * @pool: pointer to the memory pool * @elems: elements to return * @count: number of elements to return * * Returns a number of elements from the start of @elem to @pool if @pool needs * replenishing and sets their slots in @elem to NULL. Other elements are left * in @elem. * * Return: number of elements transferred to @pool. Elements are always * transferred from the beginning of @elem, so the return value can be used as * an offset into @elem for the freeing the remaining elements in the caller. */ unsigned int mempool_free_bulk(struct mempool *pool, void **elems, unsigned int count) { unsigned long flags; unsigned int freed = 0; bool added = false; /* * Paired with the wmb in mempool_alloc(). The preceding read is * for @element and the following @pool->curr_nr. This ensures * that the visible value of @pool->curr_nr is from after the * allocation of @element. This is necessary for fringe cases * where @element was passed to this task without going through * barriers. * * For example, assume @p is %NULL at the beginning and one task * performs "p = mempool_alloc(...);" while another task is doing * "while (!p) cpu_relax(); mempool_free(p, ...);". This function * may end up using curr_nr value which is from before allocation * of @p without the following rmb. */ smp_rmb(); /* * For correctness, we need a test which is guaranteed to trigger * if curr_nr + #allocated == min_nr. Testing curr_nr < min_nr * without locking achieves that and refilling as soon as possible * is desirable. * * Because curr_nr visible here is always a value after the * allocation of @element, any task which decremented curr_nr below * min_nr is guaranteed to see curr_nr < min_nr unless curr_nr gets * incremented to min_nr afterwards. If curr_nr gets incremented * to min_nr after the allocation of @element, the elements * allocated after that are subject to the same guarantee. * * Waiters happen iff curr_nr is 0 and the above guarantee also * ensures that there will be frees which return elements to the * pool waking up the waiters. * * For zero-minimum pools, curr_nr < min_nr (0 < 0) never succeeds, * so waiters sleeping on pool->wait would never be woken by the * wake-up path of previous test. This explicit check ensures the * allocation of element when both min_nr and curr_nr are 0, and * any active waiters are properly awakened. */ if (unlikely(READ_ONCE(pool->curr_nr) < pool->min_nr)) { spin_lock_irqsave(&pool->lock, flags); while (pool->curr_nr < pool->min_nr && freed < count) { add_element(pool, elems[freed++]); added = true; } spin_unlock_irqrestore(&pool->lock, flags); } else if (unlikely(pool->min_nr == 0 && READ_ONCE(pool->curr_nr) == 0)) { /* Handle the min_nr = 0 edge case: */ spin_lock_irqsave(&pool->lock, flags); if (likely(pool->curr_nr == 0)) { add_element(pool, elems[freed++]); added = true; } spin_unlock_irqrestore(&pool->lock, flags); } if (unlikely(added) && wq_has_sleeper(&pool->wait)) wake_up(&pool->wait); return freed; } EXPORT_SYMBOL_GPL(mempool_free_bulk); /** * mempool_free - return an element to the pool. * @element: element to return * @pool: pointer to the memory pool * * Returns @element to @pool if it needs replenishing, else frees it using * the free_fn callback in @pool. * * This function only sleeps if the free_fn callback sleeps. */ void mempool_free(void *element, struct mempool *pool) { if (likely(element) && !mempool_free_bulk(pool, &element, 1)) pool->free(element, pool->pool_data); } EXPORT_SYMBOL(mempool_free); /* * A commonly used alloc and free fn. */ void *mempool_alloc_slab(gfp_t gfp_mask, void *pool_data) { struct kmem_cache *mem = pool_data; VM_BUG_ON(mem->ctor); return kmem_cache_alloc_noprof(mem, gfp_mask); } EXPORT_SYMBOL(mempool_alloc_slab); void mempool_free_slab(void *element, void *pool_data) { struct kmem_cache *mem = pool_data; kmem_cache_free(mem, element); } EXPORT_SYMBOL(mempool_free_slab); /* * A commonly used alloc and free fn that kmalloc/kfrees the amount of memory * specified by pool_data */ void *mempool_kmalloc(gfp_t gfp_mask, void *pool_data) { size_t size = (size_t)pool_data; return kmalloc_noprof(size, gfp_mask); } EXPORT_SYMBOL(mempool_kmalloc); void mempool_kfree(void *element, void *pool_data) { kfree(element); } EXPORT_SYMBOL(mempool_kfree); /* * A simple mempool-backed page allocator that allocates pages * of the order specified by pool_data. */ void *mempool_alloc_pages(gfp_t gfp_mask, void *pool_data) { int order = (int)(long)pool_data; return alloc_pages_noprof(gfp_mask, order); } EXPORT_SYMBOL(mempool_alloc_pages); void mempool_free_pages(void *element, void *pool_data) { int order = (int)(long)pool_data; __free_pages(element, order); } EXPORT_SYMBOL(mempool_free_pages);
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