// SPDX-License-Identifier: GPL-2.0 WITH Linux-syscall-note /* * * (C) COPYRIGHT 2015-2023 ARM Limited. All rights reserved. * * This program is free software and is provided to you under the terms of the * GNU General Public License version 2 as published by the Free Software * Foundation, and any use by you of this program is subject to the terms * of such GNU license. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you can access it online at * http://www.gnu.org/licenses/gpl-2.0.html. * */ #include #include #include #include #include #include #include #include #include #if KERNEL_VERSION(4, 11, 0) <= LINUX_VERSION_CODE #include #else #include #endif #define pool_dbg(pool, format, ...) \ dev_dbg(pool->kbdev->dev, "%s-pool [%zu/%zu]: " format, \ (pool->next_pool) ? "kctx" : "kbdev", \ kbase_mem_pool_size(pool), \ kbase_mem_pool_max_size(pool), \ ##__VA_ARGS__) #define NOT_DIRTY false #define NOT_RECLAIMED false static bool mali_kbase_mem_pool_order_pages_enabled = false; static void kbase_mem_pool_ordered_add_locked(struct kbase_mem_pool *pool, struct page *p); static struct page *kbase_mem_pool_ordered_spill( struct kbase_mem_pool *next_pool, struct page *p); static void kbase_mem_pool_ordered_free(struct kbase_mem_pool *pool, struct page *p, bool dirty); static void kbase_mem_pool_ordered_free_locked(struct kbase_mem_pool *pool, struct page *p, bool dirty); static void kbase_mem_pool_ordered_free_pages(struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, bool dirty, bool reclaimed); static void kbase_mem_pool_ordered_free_pages_locked( struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, bool dirty, bool reclaimed); static struct page *kbase_mem_pool_ordered_add_spill( struct kbase_mem_pool *pool, struct page *p); static struct page *kbase_mem_pool_ordered_add_spill_locked( struct kbase_mem_pool *pool, struct page *p); static void kbase_mem_pool_ordered_add_list_spill(struct kbase_mem_pool *pool, struct list_head *page_list, struct list_head *spillover_list); static void kbase_mem_pool_ordered_add_list_spill_locked( struct kbase_mem_pool *pool, struct list_head *page_list, struct list_head *spillover_list); static void kbase_mem_pool_ordered_add_array_spill(struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, struct list_head *spillover_list, bool zero, bool sync); static void kbase_mem_pool_ordered_add_array_spill_locked( struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, struct list_head *spillover_list, bool zero, bool sync); /** * can_alloc_page() - Check if the current thread can allocate a physical page * * @pool: Pointer to the memory pool. * @page_owner: Pointer to the task/process that created the Kbase context * for which a page needs to be allocated. It can be NULL if * the page won't be associated with Kbase context. * * This function checks if the current thread can make a request to kernel to * allocate a physical page. If the process that created the context is exiting or * is being killed, then there is no point in doing a page allocation. * * The check done by the function is particularly helpful when the system is running * low on memory. When a page is allocated from the context of a kernel thread, OoM * killer doesn't consider the kernel thread for killing and kernel keeps retrying * to allocate the page as long as the OoM killer is able to kill processes. * The check allows to quickly exit the page allocation loop once OoM * killer has initiated the killing of @page_owner, thereby unblocking the context * termination for @page_owner and freeing of GPU memory allocated by it. This helps * in preventing the kernel panic and also limits the number of innocent processes * that get killed. * * Return: true if the page can be allocated otherwise false. */ static inline bool can_alloc_page(struct kbase_mem_pool *pool, struct task_struct *page_owner) { if (page_owner && ((page_owner->flags & PF_EXITING) || fatal_signal_pending(page_owner))) { dev_info(pool->kbdev->dev, "%s : Process %s/%d exiting", __func__, page_owner->comm, task_pid_nr(page_owner)); return false; } return true; } static size_t kbase_mem_pool_capacity(struct kbase_mem_pool *pool) { ssize_t max_size = kbase_mem_pool_max_size(pool); ssize_t cur_size = kbase_mem_pool_size(pool); return max(max_size - cur_size, (ssize_t)0); } static bool kbase_mem_pool_is_full(struct kbase_mem_pool *pool) { return kbase_mem_pool_size(pool) >= kbase_mem_pool_max_size(pool); } static bool kbase_mem_pool_is_empty(struct kbase_mem_pool *pool) { return kbase_mem_pool_size(pool) == 0; } static bool set_pool_new_page_metadata(struct kbase_mem_pool *pool, struct page *p, struct list_head *page_list, size_t *list_size) { struct kbase_page_metadata *page_md = kbase_page_private(p); bool not_movable = false; lockdep_assert_held(&pool->pool_lock); /* Free the page instead of adding it to the pool if it's not movable. * Only update page status and add the page to the memory pool if * it is not isolated. */ if (!IS_ENABLED(CONFIG_PAGE_MIGRATION_SUPPORT)) not_movable = true; else { spin_lock(&page_md->migrate_lock); if (PAGE_STATUS_GET(page_md->status) == (u8)NOT_MOVABLE) { not_movable = true; } else if (!WARN_ON_ONCE(IS_PAGE_ISOLATED(page_md->status))) { page_md->status = PAGE_STATUS_SET(page_md->status, (u8)MEM_POOL); page_md->data.mem_pool.pool = pool; page_md->data.mem_pool.kbdev = pool->kbdev; list_add(&p->lru, page_list); (*list_size)++; } spin_unlock(&page_md->migrate_lock); } if (not_movable) { kbase_free_page_later(pool->kbdev, p); pool_dbg(pool, "skipping a not movable page\n"); } return not_movable; } static void kbase_mem_pool_add_locked(struct kbase_mem_pool *pool, struct page *p) { bool queue_work_to_free = false; if (mali_kbase_mem_pool_order_pages_enabled) { kbase_mem_pool_ordered_add_locked(pool, p); return; } lockdep_assert_held(&pool->pool_lock); if (!pool->order && kbase_is_page_migration_enabled()) { if (set_pool_new_page_metadata(pool, p, &pool->page_list, &pool->cur_size)) queue_work_to_free = true; } else { list_add(&p->lru, &pool->page_list); pool->cur_size++; } if (queue_work_to_free) { struct kbase_mem_migrate *mem_migrate = &pool->kbdev->mem_migrate; queue_work(mem_migrate->free_pages_workq, &mem_migrate->free_pages_work); } pool_dbg(pool, "added page\n"); } static void kbase_mem_pool_add(struct kbase_mem_pool *pool, struct page *p) { kbase_mem_pool_lock(pool); kbase_mem_pool_add_locked(pool, p); kbase_mem_pool_unlock(pool); } static void kbase_mem_pool_add_list_locked(struct kbase_mem_pool *pool, struct list_head *page_list, size_t nr_pages) { bool queue_work_to_free = false; lockdep_assert_held(&pool->pool_lock); if (!pool->order && kbase_is_page_migration_enabled()) { struct page *p, *tmp; list_for_each_entry_safe(p, tmp, page_list, lru) { list_del_init(&p->lru); if (set_pool_new_page_metadata(pool, p, &pool->page_list, &pool->cur_size)) queue_work_to_free = true; } } else { list_splice(page_list, &pool->page_list); pool->cur_size += nr_pages; } if (queue_work_to_free) { struct kbase_mem_migrate *mem_migrate = &pool->kbdev->mem_migrate; queue_work(mem_migrate->free_pages_workq, &mem_migrate->free_pages_work); } pool_dbg(pool, "added %zu pages\n", nr_pages); } static void kbase_mem_pool_add_list(struct kbase_mem_pool *pool, struct list_head *page_list, size_t nr_pages) { kbase_mem_pool_lock(pool); kbase_mem_pool_add_list_locked(pool, page_list, nr_pages); kbase_mem_pool_unlock(pool); } static struct page *kbase_mem_pool_remove_locked(struct kbase_mem_pool *pool, enum kbase_page_status status) { struct page *p; lockdep_assert_held(&pool->pool_lock); if (kbase_mem_pool_is_empty(pool)) return NULL; p = list_first_entry(&pool->page_list, struct page, lru); if (!pool->order && kbase_is_page_migration_enabled()) { struct kbase_page_metadata *page_md = kbase_page_private(p); spin_lock(&page_md->migrate_lock); WARN_ON(PAGE_STATUS_GET(page_md->status) != (u8)MEM_POOL); page_md->status = PAGE_STATUS_SET(page_md->status, (u8)status); spin_unlock(&page_md->migrate_lock); } list_del_init(&p->lru); pool->cur_size--; pool_dbg(pool, "removed page\n"); return p; } static struct page *kbase_mem_pool_remove(struct kbase_mem_pool *pool, enum kbase_page_status status) { struct page *p; kbase_mem_pool_lock(pool); p = kbase_mem_pool_remove_locked(pool, status); kbase_mem_pool_unlock(pool); return p; } static void kbase_mem_pool_sync_page(struct kbase_mem_pool *pool, struct page *p) { struct device *dev = pool->kbdev->dev; dma_addr_t dma_addr = pool->order ? kbase_dma_addr_as_priv(p) : kbase_dma_addr(p); dma_sync_single_for_device(dev, dma_addr, (PAGE_SIZE << pool->order), DMA_BIDIRECTIONAL); } static void kbase_mem_pool_zero_page(struct kbase_mem_pool *pool, struct page *p) { int i; for (i = 0; i < (1U << pool->order); i++) clear_highpage(p+i); kbase_mem_pool_sync_page(pool, p); } static void kbase_mem_pool_spill(struct kbase_mem_pool *next_pool, struct page *p) { if (mali_kbase_mem_pool_order_pages_enabled) { kbase_mem_pool_ordered_spill(next_pool, p); return; } /* Zero page before spilling */ kbase_mem_pool_zero_page(next_pool, p); kbase_mem_pool_add(next_pool, p); } struct page *kbase_mem_alloc_page(struct kbase_mem_pool *pool) { struct page *p; gfp_t gfp = __GFP_ZERO; struct kbase_device *const kbdev = pool->kbdev; struct device *const dev = kbdev->dev; dma_addr_t dma_addr; int i; /* don't warn on higher order failures */ if (pool->order) gfp |= GFP_HIGHUSER | __GFP_NOWARN; else gfp |= kbase_is_page_migration_enabled() ? GFP_HIGHUSER_MOVABLE : GFP_HIGHUSER; p = kbdev->mgm_dev->ops.mgm_alloc_page(kbdev->mgm_dev, pool->group_id, gfp, pool->order); if (!p) return NULL; dma_addr = dma_map_page(dev, p, 0, (PAGE_SIZE << pool->order), DMA_BIDIRECTIONAL); if (dma_mapping_error(dev, dma_addr)) { kbdev->mgm_dev->ops.mgm_free_page(kbdev->mgm_dev, pool->group_id, p, pool->order); return NULL; } /* Setup page metadata for 4KB pages when page migration is enabled */ if (!pool->order && kbase_is_page_migration_enabled()) { INIT_LIST_HEAD(&p->lru); if (!kbase_alloc_page_metadata(kbdev, p, dma_addr, pool->group_id)) { dma_unmap_page(dev, dma_addr, PAGE_SIZE, DMA_BIDIRECTIONAL); kbdev->mgm_dev->ops.mgm_free_page(kbdev->mgm_dev, pool->group_id, p, pool->order); return NULL; } } else { WARN_ON(dma_addr != page_to_phys(p)); for (i = 0; i < (1u << pool->order); i++) kbase_set_dma_addr_as_priv(p + i, dma_addr + PAGE_SIZE * i); } return p; } static void enqueue_free_pool_pages_work(struct kbase_mem_pool *pool) { struct kbase_mem_migrate *mem_migrate = &pool->kbdev->mem_migrate; if (!pool->order && kbase_is_page_migration_enabled()) queue_work(mem_migrate->free_pages_workq, &mem_migrate->free_pages_work); } void kbase_mem_pool_free_page(struct kbase_mem_pool *pool, struct page *p) { struct kbase_device *kbdev; if (WARN_ON(!pool)) return; if (WARN_ON(!p)) return; kbdev = pool->kbdev; if (!pool->order && kbase_is_page_migration_enabled()) { kbase_free_page_later(kbdev, p); pool_dbg(pool, "page to be freed to kernel later\n"); } else { int i; dma_addr_t dma_addr = kbase_dma_addr_as_priv(p); for (i = 0; i < (1u << pool->order); i++) kbase_clear_dma_addr_as_priv(p + i); dma_unmap_page(kbdev->dev, dma_addr, (PAGE_SIZE << pool->order), DMA_BIDIRECTIONAL); kbdev->mgm_dev->ops.mgm_free_page(kbdev->mgm_dev, pool->group_id, p, pool->order); pool_dbg(pool, "freed page to kernel\n"); } } static size_t kbase_mem_pool_shrink_locked(struct kbase_mem_pool *pool, size_t nr_to_shrink) { struct page *p; size_t i; lockdep_assert_held(&pool->pool_lock); for (i = 0; i < nr_to_shrink && !kbase_mem_pool_is_empty(pool); i++) { p = kbase_mem_pool_remove_locked(pool, FREE_IN_PROGRESS); kbase_mem_pool_free_page(pool, p); } /* Freeing of pages will be deferred when page migration is enabled. */ enqueue_free_pool_pages_work(pool); return i; } static size_t kbase_mem_pool_shrink(struct kbase_mem_pool *pool, size_t nr_to_shrink) { size_t nr_freed; kbase_mem_pool_lock(pool); nr_freed = kbase_mem_pool_shrink_locked(pool, nr_to_shrink); kbase_mem_pool_unlock(pool); return nr_freed; } int kbase_mem_pool_grow(struct kbase_mem_pool *pool, size_t nr_to_grow, struct task_struct *page_owner) { struct page *p; size_t i; kbase_mem_pool_lock(pool); pool->dont_reclaim = true; for (i = 0; i < nr_to_grow; i++) { if (pool->dying) { pool->dont_reclaim = false; kbase_mem_pool_shrink_locked(pool, nr_to_grow); kbase_mem_pool_unlock(pool); return -ENOMEM; } kbase_mem_pool_unlock(pool); if (unlikely(!can_alloc_page(pool, page_owner))) return -ENOMEM; p = kbase_mem_alloc_page(pool); if (!p) { kbase_mem_pool_lock(pool); pool->dont_reclaim = false; kbase_mem_pool_unlock(pool); return -ENOMEM; } kbase_mem_pool_lock(pool); kbase_mem_pool_add_locked(pool, p); } pool->dont_reclaim = false; kbase_mem_pool_unlock(pool); return 0; } KBASE_EXPORT_TEST_API(kbase_mem_pool_grow); void kbase_mem_pool_trim(struct kbase_mem_pool *pool, size_t new_size) { size_t cur_size; int err = 0; cur_size = kbase_mem_pool_size(pool); if (new_size > pool->max_size) new_size = pool->max_size; if (new_size < cur_size) kbase_mem_pool_shrink(pool, cur_size - new_size); else if (new_size > cur_size) err = kbase_mem_pool_grow(pool, new_size - cur_size, NULL); if (err) { size_t grown_size = kbase_mem_pool_size(pool); dev_warn(pool->kbdev->dev, "Mem pool not grown to the required size of %zu bytes, grown for additional %zu bytes instead!\n", (new_size - cur_size), (grown_size - cur_size)); } } void kbase_mem_pool_set_max_size(struct kbase_mem_pool *pool, size_t max_size) { size_t cur_size; size_t nr_to_shrink; kbase_mem_pool_lock(pool); pool->max_size = max_size; cur_size = kbase_mem_pool_size(pool); if (max_size < cur_size) { nr_to_shrink = cur_size - max_size; kbase_mem_pool_shrink_locked(pool, nr_to_shrink); } kbase_mem_pool_unlock(pool); } KBASE_EXPORT_TEST_API(kbase_mem_pool_set_max_size); static unsigned long kbase_mem_pool_reclaim_count_objects(struct shrinker *s, struct shrink_control *sc) { struct kbase_mem_pool *pool; size_t pool_size; pool = container_of(s, struct kbase_mem_pool, reclaim); kbase_mem_pool_lock(pool); if (pool->dont_reclaim && !pool->dying) { kbase_mem_pool_unlock(pool); /* Tell shrinker to skip reclaim * even though freeable pages are available */ return 0; } pool_size = kbase_mem_pool_size(pool); kbase_mem_pool_unlock(pool); return pool_size; } static unsigned long kbase_mem_pool_reclaim_scan_objects(struct shrinker *s, struct shrink_control *sc) { struct kbase_mem_pool *pool; unsigned long freed; pool = container_of(s, struct kbase_mem_pool, reclaim); kbase_mem_pool_lock(pool); if (pool->dont_reclaim && !pool->dying) { kbase_mem_pool_unlock(pool); /* Tell shrinker that reclaim can't be made and * do not attempt again for this reclaim context. */ return SHRINK_STOP; } pool_dbg(pool, "reclaim scan %ld:\n", sc->nr_to_scan); freed = kbase_mem_pool_shrink_locked(pool, sc->nr_to_scan); kbase_mem_pool_unlock(pool); pool_dbg(pool, "reclaim freed %ld pages\n", freed); return freed; } int kbase_mem_pool_init(struct kbase_mem_pool *pool, const struct kbase_mem_pool_config *config, unsigned int order, int group_id, struct kbase_device *kbdev, struct kbase_mem_pool *next_pool) { if (WARN_ON(group_id < 0) || WARN_ON(group_id >= MEMORY_GROUP_MANAGER_NR_GROUPS)) { return -EINVAL; } pool->cur_size = 0; pool->max_size = kbase_mem_pool_config_get_max_size(config); pool->order = order; pool->group_id = group_id; pool->kbdev = kbdev; pool->next_pool = next_pool; pool->dying = false; atomic_set(&pool->isolation_in_progress_cnt, 0); spin_lock_init(&pool->pool_lock); INIT_LIST_HEAD(&pool->page_list); pool->reclaim.count_objects = kbase_mem_pool_reclaim_count_objects; pool->reclaim.scan_objects = kbase_mem_pool_reclaim_scan_objects; pool->reclaim.seeks = DEFAULT_SEEKS; /* Kernel versions prior to 3.1 : * struct shrinker does not define batch */ pool->reclaim.batch = 0; #if KERNEL_VERSION(6, 0, 0) > LINUX_VERSION_CODE register_shrinker(&pool->reclaim); #else register_shrinker(&pool->reclaim, "mali-mem-pool"); #endif pool_dbg(pool, "initialized\n"); return 0; } KBASE_EXPORT_TEST_API(kbase_mem_pool_init); void kbase_mem_pool_mark_dying(struct kbase_mem_pool *pool) { kbase_mem_pool_lock(pool); pool->dying = true; kbase_mem_pool_unlock(pool); } void kbase_mem_pool_term(struct kbase_mem_pool *pool) { struct kbase_mem_pool *next_pool = pool->next_pool; struct page *p, *tmp; size_t nr_to_spill = 0; LIST_HEAD(spill_list); LIST_HEAD(free_list); int i; pool_dbg(pool, "terminate()\n"); unregister_shrinker(&pool->reclaim); kbase_mem_pool_lock(pool); pool->max_size = 0; if (next_pool && !kbase_mem_pool_is_full(next_pool)) { /* Spill to next pool (may overspill) */ nr_to_spill = kbase_mem_pool_capacity(next_pool); nr_to_spill = min(kbase_mem_pool_size(pool), nr_to_spill); /* Zero pages first without holding the next_pool lock */ for (i = 0; i < nr_to_spill; i++) { p = kbase_mem_pool_remove_locked(pool, SPILL_IN_PROGRESS); if (p) list_add(&p->lru, &spill_list); } } while (!kbase_mem_pool_is_empty(pool)) { /* Free remaining pages to kernel */ p = kbase_mem_pool_remove_locked(pool, FREE_IN_PROGRESS); if (p) list_add(&p->lru, &free_list); } kbase_mem_pool_unlock(pool); if (mali_kbase_mem_pool_order_pages_enabled) { if (next_pool && (!list_empty(&spill_list) || !list_empty(&free_list))) { list_splice_init(&free_list, &spill_list); list_for_each_entry(p, &spill_list, lru) kbase_mem_pool_zero_page(pool, p); kbase_mem_pool_ordered_add_list_spill( next_pool, &spill_list, &free_list); } } else { if (next_pool && nr_to_spill) { list_for_each_entry(p, &spill_list, lru) kbase_mem_pool_zero_page(pool, p); /* Add new page list to next_pool */ kbase_mem_pool_add_list(next_pool, &spill_list, nr_to_spill); pool_dbg(pool, "terminate() spilled %zu pages\n", nr_to_spill); } } list_for_each_entry_safe(p, tmp, &free_list, lru) { list_del_init(&p->lru); kbase_mem_pool_free_page(pool, p); } /* Freeing of pages will be deferred when page migration is enabled. */ enqueue_free_pool_pages_work(pool); /* Before returning wait to make sure there are no pages undergoing page isolation * which will require reference to this pool. */ if (kbase_is_page_migration_enabled()) { while (atomic_read(&pool->isolation_in_progress_cnt)) cpu_relax(); } pool_dbg(pool, "terminated\n"); } KBASE_EXPORT_TEST_API(kbase_mem_pool_term); struct page *kbase_mem_pool_alloc(struct kbase_mem_pool *pool) { struct page *p; do { pool_dbg(pool, "alloc()\n"); p = kbase_mem_pool_remove(pool, ALLOCATE_IN_PROGRESS); if (p) return p; pool = pool->next_pool; } while (pool); return NULL; } struct page *kbase_mem_pool_alloc_locked(struct kbase_mem_pool *pool) { lockdep_assert_held(&pool->pool_lock); pool_dbg(pool, "alloc_locked()\n"); return kbase_mem_pool_remove_locked(pool, ALLOCATE_IN_PROGRESS); } void kbase_mem_pool_free(struct kbase_mem_pool *pool, struct page *p, bool dirty) { struct kbase_mem_pool *next_pool = pool->next_pool; if (mali_kbase_mem_pool_order_pages_enabled) { kbase_mem_pool_ordered_free(pool, p, dirty); return; } pool_dbg(pool, "free()\n"); if (!kbase_mem_pool_is_full(pool)) { /* Add to our own pool */ if (dirty) kbase_mem_pool_sync_page(pool, p); kbase_mem_pool_add(pool, p); } else if (next_pool && !kbase_mem_pool_is_full(next_pool)) { /* Spill to next pool */ kbase_mem_pool_spill(next_pool, p); } else { /* Free page */ kbase_mem_pool_free_page(pool, p); /* Freeing of pages will be deferred when page migration is enabled. */ enqueue_free_pool_pages_work(pool); } } void kbase_mem_pool_free_locked(struct kbase_mem_pool *pool, struct page *p, bool dirty) { if (mali_kbase_mem_pool_order_pages_enabled) { kbase_mem_pool_ordered_free_locked(pool, p, dirty); return; } pool_dbg(pool, "free_locked()\n"); lockdep_assert_held(&pool->pool_lock); if (!kbase_mem_pool_is_full(pool)) { /* Add to our own pool */ if (dirty) kbase_mem_pool_sync_page(pool, p); kbase_mem_pool_add_locked(pool, p); } else { /* Free page */ kbase_mem_pool_free_page(pool, p); /* Freeing of pages will be deferred when page migration is enabled. */ enqueue_free_pool_pages_work(pool); } } int kbase_mem_pool_alloc_pages(struct kbase_mem_pool *pool, size_t nr_4k_pages, struct tagged_addr *pages, bool partial_allowed, struct task_struct *page_owner) { struct page *p; size_t nr_from_pool; size_t i = 0; int err = -ENOMEM; size_t nr_pages_internal; nr_pages_internal = nr_4k_pages / (1u << (pool->order)); if (nr_pages_internal * (1u << pool->order) != nr_4k_pages) return -EINVAL; pool_dbg(pool, "alloc_pages(4k=%zu):\n", nr_4k_pages); pool_dbg(pool, "alloc_pages(internal=%zu):\n", nr_pages_internal); /* Get pages from this pool */ kbase_mem_pool_lock(pool); nr_from_pool = min(nr_pages_internal, kbase_mem_pool_size(pool)); while (nr_from_pool--) { int j; p = kbase_mem_pool_remove_locked(pool, ALLOCATE_IN_PROGRESS); if (pool->order) { pages[i++] = as_tagged_tag(page_to_phys(p), HUGE_HEAD | HUGE_PAGE); for (j = 1; j < (1u << pool->order); j++) pages[i++] = as_tagged_tag(page_to_phys(p) + PAGE_SIZE * j, HUGE_PAGE); } else { pages[i++] = as_tagged(page_to_phys(p)); } } kbase_mem_pool_unlock(pool); if (i != nr_4k_pages && pool->next_pool) { /* Allocate via next pool */ err = kbase_mem_pool_alloc_pages(pool->next_pool, nr_4k_pages - i, pages + i, partial_allowed, page_owner); if (err < 0) goto err_rollback; i += err; } else { /* Get any remaining pages from kernel */ while (i != nr_4k_pages) { if (unlikely(!can_alloc_page(pool, page_owner))) goto err_rollback; p = kbase_mem_alloc_page(pool); if (!p) { if (partial_allowed) goto done; else goto err_rollback; } if (pool->order) { int j; pages[i++] = as_tagged_tag(page_to_phys(p), HUGE_PAGE | HUGE_HEAD); for (j = 1; j < (1u << pool->order); j++) { phys_addr_t phys; phys = page_to_phys(p) + PAGE_SIZE * j; pages[i++] = as_tagged_tag(phys, HUGE_PAGE); } } else { pages[i++] = as_tagged(page_to_phys(p)); } } } done: pool_dbg(pool, "alloc_pages(%zu) done\n", i); return i; err_rollback: kbase_mem_pool_free_pages(pool, i, pages, NOT_DIRTY, NOT_RECLAIMED); dev_warn(pool->kbdev->dev, "Failed allocation request for remaining %zu pages after obtaining %zu pages already.\n", nr_4k_pages, i); return err; } int kbase_mem_pool_alloc_pages_locked(struct kbase_mem_pool *pool, size_t nr_4k_pages, struct tagged_addr *pages) { struct page *p; size_t i; size_t nr_pages_internal; lockdep_assert_held(&pool->pool_lock); nr_pages_internal = nr_4k_pages / (1u << (pool->order)); if (nr_pages_internal * (1u << pool->order) != nr_4k_pages) return -EINVAL; pool_dbg(pool, "alloc_pages_locked(4k=%zu):\n", nr_4k_pages); pool_dbg(pool, "alloc_pages_locked(internal=%zu):\n", nr_pages_internal); if (kbase_mem_pool_size(pool) < nr_pages_internal) { pool_dbg(pool, "Failed alloc\n"); return -ENOMEM; } for (i = 0; i < nr_pages_internal; i++) { int j; p = kbase_mem_pool_remove_locked(pool, ALLOCATE_IN_PROGRESS); if (pool->order) { *pages++ = as_tagged_tag(page_to_phys(p), HUGE_HEAD | HUGE_PAGE); for (j = 1; j < (1u << pool->order); j++) { *pages++ = as_tagged_tag(page_to_phys(p) + PAGE_SIZE * j, HUGE_PAGE); } } else { *pages++ = as_tagged(page_to_phys(p)); } } return nr_4k_pages; } static void kbase_mem_pool_add_array(struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, bool zero, bool sync) { struct page *p; size_t nr_to_pool = 0; LIST_HEAD(new_page_list); size_t i; if (!nr_pages) return; pool_dbg(pool, "add_array(%zu, zero=%d, sync=%d):\n", nr_pages, zero, sync); /* Zero/sync pages first without holding the pool lock */ for (i = 0; i < nr_pages; i++) { if (unlikely(!as_phys_addr_t(pages[i]))) continue; if (is_huge_head(pages[i]) || !is_huge(pages[i])) { p = as_page(pages[i]); if (zero) kbase_mem_pool_zero_page(pool, p); else if (sync) kbase_mem_pool_sync_page(pool, p); list_add(&p->lru, &new_page_list); nr_to_pool++; } pages[i] = as_tagged(0); } /* Add new page list to pool */ kbase_mem_pool_add_list(pool, &new_page_list, nr_to_pool); pool_dbg(pool, "add_array(%zu) added %zu pages\n", nr_pages, nr_to_pool); } static void kbase_mem_pool_add_array_locked(struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, bool zero, bool sync) { struct page *p; size_t nr_to_pool = 0; LIST_HEAD(new_page_list); size_t i; lockdep_assert_held(&pool->pool_lock); if (!nr_pages) return; pool_dbg(pool, "add_array_locked(%zu, zero=%d, sync=%d):\n", nr_pages, zero, sync); /* Zero/sync pages first */ for (i = 0; i < nr_pages; i++) { if (unlikely(!as_phys_addr_t(pages[i]))) continue; if (is_huge_head(pages[i]) || !is_huge(pages[i])) { p = as_page(pages[i]); if (zero) kbase_mem_pool_zero_page(pool, p); else if (sync) kbase_mem_pool_sync_page(pool, p); list_add(&p->lru, &new_page_list); nr_to_pool++; } pages[i] = as_tagged(0); } /* Add new page list to pool */ kbase_mem_pool_add_list_locked(pool, &new_page_list, nr_to_pool); pool_dbg(pool, "add_array_locked(%zu) added %zu pages\n", nr_pages, nr_to_pool); } void kbase_mem_pool_free_pages(struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, bool dirty, bool reclaimed) { struct kbase_mem_pool *next_pool = pool->next_pool; struct page *p; size_t nr_to_pool; LIST_HEAD(to_pool_list); size_t i = 0; bool pages_released = false; if (mali_kbase_mem_pool_order_pages_enabled) { kbase_mem_pool_ordered_free_pages(pool, nr_pages, pages, dirty, reclaimed); return; } pool_dbg(pool, "free_pages(%zu):\n", nr_pages); if (!reclaimed) { /* Add to this pool */ nr_to_pool = kbase_mem_pool_capacity(pool); nr_to_pool = min(nr_pages, nr_to_pool); kbase_mem_pool_add_array(pool, nr_to_pool, pages, false, dirty); i += nr_to_pool; if (i != nr_pages && next_pool) { /* Spill to next pool (may overspill) */ nr_to_pool = kbase_mem_pool_capacity(next_pool); nr_to_pool = min(nr_pages - i, nr_to_pool); kbase_mem_pool_add_array(next_pool, nr_to_pool, pages + i, true, dirty); i += nr_to_pool; } } /* Free any remaining pages to kernel */ for (; i < nr_pages; i++) { if (unlikely(!as_phys_addr_t(pages[i]))) continue; if (is_huge(pages[i]) && !is_huge_head(pages[i])) { pages[i] = as_tagged(0); continue; } p = as_page(pages[i]); kbase_mem_pool_free_page(pool, p); pages[i] = as_tagged(0); pages_released = true; } /* Freeing of pages will be deferred when page migration is enabled. */ if (pages_released) enqueue_free_pool_pages_work(pool); pool_dbg(pool, "free_pages(%zu) done\n", nr_pages); } void kbase_mem_pool_free_pages_locked(struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, bool dirty, bool reclaimed) { struct page *p; size_t nr_to_pool; LIST_HEAD(to_pool_list); size_t i = 0; bool pages_released = false; if (mali_kbase_mem_pool_order_pages_enabled) { kbase_mem_pool_ordered_free_pages_locked(pool, nr_pages, pages, dirty, reclaimed); return; } lockdep_assert_held(&pool->pool_lock); pool_dbg(pool, "free_pages_locked(%zu):\n", nr_pages); if (!reclaimed) { /* Add to this pool */ nr_to_pool = kbase_mem_pool_capacity(pool); nr_to_pool = min(nr_pages, nr_to_pool); kbase_mem_pool_add_array_locked(pool, nr_to_pool, pages, false, dirty); i += nr_to_pool; } /* Free any remaining pages to kernel */ for (; i < nr_pages; i++) { if (unlikely(!as_phys_addr_t(pages[i]))) continue; if (is_huge(pages[i]) && !is_huge_head(pages[i])) { pages[i] = as_tagged(0); continue; } p = as_page(pages[i]); kbase_mem_pool_free_page(pool, p); pages[i] = as_tagged(0); pages_released = true; } /* Freeing of pages will be deferred when page migration is enabled. */ if (pages_released) enqueue_free_pool_pages_work(pool); pool_dbg(pool, "free_pages_locked(%zu) done\n", nr_pages); } static void kbase_mem_pool_ordered_add_locked(struct kbase_mem_pool *pool, struct page *p) { struct page* page_in_list; phys_addr_t page_phys_addr; bool added = false; lockdep_assert_held(&pool->pool_lock); page_phys_addr = page_to_phys(p); list_for_each_entry(page_in_list, &pool->page_list, lru) { if (page_phys_addr < page_to_phys(page_in_list)) { list_add_tail(&p->lru, &page_in_list->lru); added = true; break; } } if (!added) { list_add_tail(&p->lru, &pool->page_list); } pool->cur_size++; pool_dbg(pool, "added page\n"); } static struct page *kbase_mem_pool_ordered_spill( struct kbase_mem_pool *next_pool, struct page *p) { /* Zero page before spilling */ kbase_mem_pool_zero_page(next_pool, p); return kbase_mem_pool_ordered_add_spill(next_pool, p); } static void kbase_mem_pool_ordered_free(struct kbase_mem_pool *pool, struct page *p, bool dirty) { struct kbase_mem_pool *next_pool = pool->next_pool; struct page *spilled_page; pool_dbg(pool, "free()\n"); /* Add to our own pool */ if (dirty) kbase_mem_pool_sync_page(pool, p); spilled_page = kbase_mem_pool_ordered_add_spill(pool, p); if (next_pool && spilled_page) { /* Spill to next pool */ spilled_page = kbase_mem_pool_ordered_spill(next_pool, spilled_page); } if (spilled_page) { /* Free page */ kbase_mem_pool_free_page(pool, spilled_page); } } static void kbase_mem_pool_ordered_free_locked(struct kbase_mem_pool *pool, struct page *p, bool dirty) { struct page *spilled_page; pool_dbg(pool, "free_locked()\n"); lockdep_assert_held(&pool->pool_lock); /* Add to our own pool */ if (dirty) kbase_mem_pool_sync_page(pool, p); spilled_page = kbase_mem_pool_ordered_add_spill_locked(pool, p); if (spilled_page) { /* Free page */ kbase_mem_pool_free_page(pool, spilled_page); } } static void kbase_mem_pool_ordered_free_pages(struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, bool dirty, bool reclaimed) { struct kbase_mem_pool *next_pool = pool->next_pool; struct page *p; struct page *tmp; LIST_HEAD(to_pool_list); LIST_HEAD(spillover_list); pool_dbg(pool, "free_pages(%zu):\n", nr_pages); if (!reclaimed) { /* Add to this pool, spilling over to any next pool */ if (next_pool) { kbase_mem_pool_ordered_add_array_spill(pool, nr_pages, pages, &spillover_list, false, dirty); kbase_mem_pool_ordered_add_list_spill(next_pool, &spillover_list, &to_pool_list); } else { kbase_mem_pool_ordered_add_array_spill(pool, nr_pages, pages, &to_pool_list, false, dirty); } } /* Free any remaining pages to kernel */ list_for_each_entry_safe(p, tmp, &to_pool_list, lru) { list_del_init(&p->lru); kbase_mem_pool_free_page(pool, p); } pool_dbg(pool, "free_pages(%zu) done\n", nr_pages); } static void kbase_mem_pool_ordered_free_pages_locked( struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, bool dirty, bool reclaimed) { struct kbase_mem_pool *next_pool = pool->next_pool; struct page *p; struct page *tmp; LIST_HEAD(to_pool_list); LIST_HEAD(spillover_list); lockdep_assert_held(&pool->pool_lock); pool_dbg(pool, "free_pages_locked(%zu):\n", nr_pages); if (!reclaimed) { /* Add to this pool, spilling over to any next pool */ if (next_pool) { kbase_mem_pool_ordered_add_array_spill_locked(pool, nr_pages, pages, &spillover_list, false, dirty); kbase_mem_pool_ordered_add_list_spill_locked(next_pool, &spillover_list, &to_pool_list); } else { kbase_mem_pool_ordered_add_array_spill_locked(pool, nr_pages, pages, &to_pool_list, false, dirty); } } /* Free any remaining pages to kernel */ list_for_each_entry_safe(p, tmp, &to_pool_list, lru) { list_del_init(&p->lru); kbase_mem_pool_free_page(pool, p); } pool_dbg(pool, "free_pages_locked(%zu) done\n", nr_pages); } static struct page *kbase_mem_pool_ordered_add_spill( struct kbase_mem_pool *pool, struct page *p) { struct page *spilled_page; kbase_mem_pool_lock(pool); spilled_page = kbase_mem_pool_ordered_add_spill_locked(pool, p); kbase_mem_pool_unlock(pool); return spilled_page; } static struct page *kbase_mem_pool_ordered_add_spill_locked( struct kbase_mem_pool *pool, struct page *p) { struct page* spilled_page = NULL; lockdep_assert_held(&pool->pool_lock); kbase_mem_pool_add_locked(pool, p); if (pool->cur_size > kbase_mem_pool_max_size(pool)) { spilled_page = list_last_entry( &pool->page_list, struct page, lru); list_del_init(&spilled_page->lru); pool->cur_size--; } return spilled_page; } static void kbase_mem_pool_ordered_add_list_spill(struct kbase_mem_pool *pool, struct list_head *page_list, struct list_head *spillover_list) { kbase_mem_pool_lock(pool); kbase_mem_pool_ordered_add_list_spill_locked( pool, page_list, spillover_list); kbase_mem_pool_unlock(pool); } static void kbase_mem_pool_ordered_add_list_spill_locked( struct kbase_mem_pool *pool, struct list_head *page_list, struct list_head *spillover_list) { struct page* page; struct page* spilled_page; struct page* tmp; lockdep_assert_held(&pool->pool_lock); list_for_each_entry_safe(page, tmp, page_list, lru) { list_del_init(&page->lru); spilled_page = kbase_mem_pool_ordered_add_spill_locked( pool, page); if (spilled_page) { list_add(&spilled_page->lru, spillover_list); } } } static void kbase_mem_pool_ordered_add_array_spill( struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, struct list_head *spillover_list, bool zero, bool sync) { struct page *p; size_t nr_to_pool = 0; LIST_HEAD(new_page_list); size_t i; if (!nr_pages) return; pool_dbg(pool, "add_array(%zu, zero=%d, sync=%d):\n", nr_pages, zero, sync); /* Zero/sync pages first without holding the pool lock */ for (i = 0; i < nr_pages; i++) { if (unlikely(!as_phys_addr_t(pages[i]))) continue; if (is_huge_head(pages[i]) || !is_huge(pages[i])) { p = as_page(pages[i]); if (zero) kbase_mem_pool_zero_page(pool, p); else if (sync) kbase_mem_pool_sync_page(pool, p); list_add(&p->lru, &new_page_list); nr_to_pool++; } pages[i] = as_tagged(0); } /* Add new page list to pool */ kbase_mem_pool_ordered_add_list_spill( pool, &new_page_list, spillover_list); pool_dbg(pool, "add_array(%zu) added %zu pages\n", nr_pages, nr_to_pool); } static void kbase_mem_pool_ordered_add_array_spill_locked( struct kbase_mem_pool *pool, size_t nr_pages, struct tagged_addr *pages, struct list_head *spillover_list, bool zero, bool sync) { struct page *p; size_t nr_to_pool = 0; LIST_HEAD(new_page_list); size_t i; lockdep_assert_held(&pool->pool_lock); if (!nr_pages) return; pool_dbg(pool, "add_array(%zu, zero=%d, sync=%d):\n", nr_pages, zero, sync); /* Zero/sync pages first without holding the pool lock */ for (i = 0; i < nr_pages; i++) { if (unlikely(!as_phys_addr_t(pages[i]))) continue; if (is_huge_head(pages[i]) || !is_huge(pages[i])) { p = as_page(pages[i]); if (zero) kbase_mem_pool_zero_page(pool, p); else if (sync) kbase_mem_pool_sync_page(pool, p); list_add(&p->lru, &new_page_list); nr_to_pool++; } pages[i] = as_tagged(0); } /* Add new page list to pool */ kbase_mem_pool_ordered_add_list_spill_locked(pool, &new_page_list, spillover_list); pool_dbg(pool, "add_array(%zu) added %zu pages\n", nr_pages, nr_to_pool); }