/* SPDX-License-Identifier: BSD-3-Clause * Copyright(c) 2019 Intel Corporation */ #ifndef _RTE_STACK_LF_GENERIC_H_ #define _RTE_STACK_LF_GENERIC_H_ #include #include static __rte_always_inline unsigned int __rte_stack_lf_count(struct rte_stack *s) { /* stack_lf_push() and stack_lf_pop() do not update the list's contents * and stack_lf->len atomically, which can cause the list to appear * shorter than it actually is if this function is called while other * threads are modifying the list. * * However, given the inherently approximate nature of the get_count * callback -- even if the list and its size were updated atomically, * the size could change between when get_count executes and when the * value is returned to the caller -- this is acceptable. * * The stack_lf->len updates are placed such that the list may appear to * have fewer elements than it does, but will never appear to have more * elements. If the mempool is near-empty to the point that this is a * concern, the user should consider increasing the mempool size. */ return (unsigned int)rte_atomic64_read((rte_atomic64_t *) &s->stack_lf.used.len); } static __rte_always_inline void __rte_stack_lf_push_elems(struct rte_stack_lf_list *list, struct rte_stack_lf_elem *first, struct rte_stack_lf_elem *last, unsigned int num) { struct rte_stack_lf_head old_head; int success; old_head = list->head; do { struct rte_stack_lf_head new_head; /* An acquire fence (or stronger) is needed for weak memory * models to establish a synchronized-with relationship between * the list->head load and store-release operations (as part of * the rte_atomic128_cmp_exchange()). */ rte_smp_mb(); /* Swing the top pointer to the first element in the list and * make the last element point to the old top. */ new_head.top = first; new_head.cnt = old_head.cnt + 1; last->next = old_head.top; /* old_head is updated on failure */ success = rte_atomic128_cmp_exchange( (rte_int128_t *)&list->head, (rte_int128_t *)&old_head, (rte_int128_t *)&new_head, 1, __ATOMIC_RELEASE, __ATOMIC_RELAXED); } while (success == 0); rte_atomic64_add((rte_atomic64_t *)&list->len, num); } static __rte_always_inline struct rte_stack_lf_elem * __rte_stack_lf_pop_elems(struct rte_stack_lf_list *list, unsigned int num, void **obj_table, struct rte_stack_lf_elem **last) { struct rte_stack_lf_head old_head; int success = 0; /* Reserve num elements, if available */ while (1) { uint64_t len = rte_atomic64_read((rte_atomic64_t *)&list->len); /* Does the list contain enough elements? */ if (unlikely(len < num)) return NULL; if (rte_atomic64_cmpset((volatile uint64_t *)&list->len, len, len - num)) break; } old_head = list->head; /* Pop num elements */ do { struct rte_stack_lf_head new_head; struct rte_stack_lf_elem *tmp; unsigned int i; /* An acquire fence (or stronger) is needed for weak memory * models to ensure the LF LIFO element reads are properly * ordered with respect to the head pointer read. */ rte_smp_mb(); rte_prefetch0(old_head.top); tmp = old_head.top; /* Traverse the list to find the new head. A next pointer will * either point to another element or NULL; if a thread * encounters a pointer that has already been popped, the CAS * will fail. */ for (i = 0; i < num && tmp != NULL; i++) { rte_prefetch0(tmp->next); if (obj_table) obj_table[i] = tmp->data; if (last) *last = tmp; tmp = tmp->next; } /* If NULL was encountered, the list was modified while * traversing it. Retry. */ if (i != num) continue; new_head.top = tmp; new_head.cnt = old_head.cnt + 1; /* old_head is updated on failure */ success = rte_atomic128_cmp_exchange( (rte_int128_t *)&list->head, (rte_int128_t *)&old_head, (rte_int128_t *)&new_head, 1, __ATOMIC_RELEASE, __ATOMIC_RELAXED); } while (success == 0); return old_head.top; } #endif /* _RTE_STACK_LF_GENERIC_H_ */