/* SPDX-License-Identifier: BSD-3-Clause * * Copyright (c) 2020 Arm Limited * Copyright (c) 2007-2009 Kip Macy kmacy@freebsd.org * All rights reserved. * Derived from FreeBSD's bufring.h * Used as BSD-3 Licensed with permission from Kip Macy. */ #ifndef _RTE_RING_PEEK_ZC_H_ #define _RTE_RING_PEEK_ZC_H_ /** * @file * @b EXPERIMENTAL: this API may change without prior notice * It is not recommended to include this file directly. * Please include instead. * * Ring Peek Zero Copy APIs * These APIs make it possible to split public enqueue/dequeue API * into 3 parts: * - enqueue/dequeue start * - copy data to/from the ring * - enqueue/dequeue finish * Along with the advantages of the peek APIs, these APIs provide the ability * to avoid copying of the data to temporary area (for ex: array of mbufs * on the stack). * * Note that currently these APIs are available only for two sync modes: * 1) Single Producer/Single Consumer (RTE_RING_SYNC_ST) * 2) Serialized Producer/Serialized Consumer (RTE_RING_SYNC_MT_HTS). * It is user's responsibility to create/init ring with appropriate sync * modes selected. * * Following are some examples showing the API usage. * 1) * struct elem_obj {uint64_t a; uint32_t b, c;}; * struct elem_obj *obj; * * // Create ring with sync type RTE_RING_SYNC_ST or RTE_RING_SYNC_MT_HTS * // Reserve space on the ring * n = rte_ring_enqueue_zc_bulk_elem_start(r, sizeof(elem_obj), 1, &zcd, NULL); * * // Produce the data directly on the ring memory * obj = (struct elem_obj *)zcd->ptr1; * obj->a = rte_get_a(); * obj->b = rte_get_b(); * obj->c = rte_get_c(); * rte_ring_enqueue_zc_elem_finish(ring, n); * * 2) * // Create ring with sync type RTE_RING_SYNC_ST or RTE_RING_SYNC_MT_HTS * // Reserve space on the ring * n = rte_ring_enqueue_zc_burst_start(r, 32, &zcd, NULL); * * // Pkt I/O core polls packets from the NIC * if (n != 0) { * nb_rx = rte_eth_rx_burst(portid, queueid, zcd->ptr1, zcd->n1); * if (nb_rx == zcd->n1 && n != zcd->n1) * nb_rx = rte_eth_rx_burst(portid, queueid, * zcd->ptr2, n - zcd->n1); * * // Provide packets to the packet processing cores * rte_ring_enqueue_zc_finish(r, nb_rx); * } * * Note that between _start_ and _finish_ none other thread can proceed * with enqueue/dequeue operation till _finish_ completes. */ #ifdef __cplusplus extern "C" { #endif #include /** * Ring zero-copy information structure. * * This structure contains the pointers and length of the space * reserved on the ring storage. */ struct rte_ring_zc_data { /* Pointer to the first space in the ring */ void *ptr1; /* Pointer to the second space in the ring if there is wrap-around. * It contains valid value only if wrap-around happens. */ void *ptr2; /* Number of elements in the first pointer. If this is equal to * the number of elements requested, then ptr2 is NULL. * Otherwise, subtracting n1 from number of elements requested * will give the number of elements available at ptr2. */ unsigned int n1; } __rte_cache_aligned; static __rte_always_inline void __rte_ring_get_elem_addr(struct rte_ring *r, uint32_t head, uint32_t esize, uint32_t num, void **dst1, uint32_t *n1, void **dst2) { uint32_t idx, scale, nr_idx; uint32_t *ring = (uint32_t *)&r[1]; /* Normalize to uint32_t */ scale = esize / sizeof(uint32_t); idx = head & r->mask; nr_idx = idx * scale; *dst1 = ring + nr_idx; *n1 = num; if (idx + num > r->size) { *n1 = r->size - idx; *dst2 = ring; } else { *dst2 = NULL; } } /** * @internal This function moves prod head value. */ static __rte_always_inline unsigned int __rte_ring_do_enqueue_zc_elem_start(struct rte_ring *r, unsigned int esize, uint32_t n, enum rte_ring_queue_behavior behavior, struct rte_ring_zc_data *zcd, unsigned int *free_space) { uint32_t free, head, next; switch (r->prod.sync_type) { case RTE_RING_SYNC_ST: n = __rte_ring_move_prod_head(r, RTE_RING_SYNC_ST, n, behavior, &head, &next, &free); break; case RTE_RING_SYNC_MT_HTS: n = __rte_ring_hts_move_prod_head(r, n, behavior, &head, &free); break; case RTE_RING_SYNC_MT: case RTE_RING_SYNC_MT_RTS: default: /* unsupported mode, shouldn't be here */ RTE_ASSERT(0); n = 0; free = 0; return n; } __rte_ring_get_elem_addr(r, head, esize, n, &zcd->ptr1, &zcd->n1, &zcd->ptr2); if (free_space != NULL) *free_space = free - n; return n; } /** * Start to enqueue several objects on the ring. * Note that no actual objects are put in the queue by this function, * it just reserves space for the user on the ring. * User has to copy objects into the queue using the returned pointers. * User should call rte_ring_enqueue_zc_elem_finish to complete the * enqueue operation. * * @param r * A pointer to the ring structure. * @param esize * The size of ring element, in bytes. It must be a multiple of 4. * @param n * The number of objects to add in the ring. * @param zcd * Structure containing the pointers and length of the space * reserved on the ring storage. * @param free_space * If non-NULL, returns the amount of space in the ring after the * reservation operation has finished. * @return * The number of objects that can be enqueued, either 0 or n */ __rte_experimental static __rte_always_inline unsigned int rte_ring_enqueue_zc_bulk_elem_start(struct rte_ring *r, unsigned int esize, unsigned int n, struct rte_ring_zc_data *zcd, unsigned int *free_space) { return __rte_ring_do_enqueue_zc_elem_start(r, esize, n, RTE_RING_QUEUE_FIXED, zcd, free_space); } /** * Start to enqueue several pointers to objects on the ring. * Note that no actual pointers are put in the queue by this function, * it just reserves space for the user on the ring. * User has to copy pointers to objects into the queue using the * returned pointers. * User should call rte_ring_enqueue_zc_finish to complete the * enqueue operation. * * @param r * A pointer to the ring structure. * @param n * The number of objects to add in the ring. * @param zcd * Structure containing the pointers and length of the space * reserved on the ring storage. * @param free_space * If non-NULL, returns the amount of space in the ring after the * reservation operation has finished. * @return * The number of objects that can be enqueued, either 0 or n */ __rte_experimental static __rte_always_inline unsigned int rte_ring_enqueue_zc_bulk_start(struct rte_ring *r, unsigned int n, struct rte_ring_zc_data *zcd, unsigned int *free_space) { return rte_ring_enqueue_zc_bulk_elem_start(r, sizeof(uintptr_t), n, zcd, free_space); } /** * Start to enqueue several objects on the ring. * Note that no actual objects are put in the queue by this function, * it just reserves space for the user on the ring. * User has to copy objects into the queue using the returned pointers. * User should call rte_ring_enqueue_zc_elem_finish to complete the * enqueue operation. * * @param r * A pointer to the ring structure. * @param esize * The size of ring element, in bytes. It must be a multiple of 4. * @param n * The number of objects to add in the ring. * @param zcd * Structure containing the pointers and length of the space * reserved on the ring storage. * @param free_space * If non-NULL, returns the amount of space in the ring after the * reservation operation has finished. * @return * The number of objects that can be enqueued, either 0 or n */ __rte_experimental static __rte_always_inline unsigned int rte_ring_enqueue_zc_burst_elem_start(struct rte_ring *r, unsigned int esize, unsigned int n, struct rte_ring_zc_data *zcd, unsigned int *free_space) { return __rte_ring_do_enqueue_zc_elem_start(r, esize, n, RTE_RING_QUEUE_VARIABLE, zcd, free_space); } /** * Start to enqueue several pointers to objects on the ring. * Note that no actual pointers are put in the queue by this function, * it just reserves space for the user on the ring. * User has to copy pointers to objects into the queue using the * returned pointers. * User should call rte_ring_enqueue_zc_finish to complete the * enqueue operation. * * @param r * A pointer to the ring structure. * @param n * The number of objects to add in the ring. * @param zcd * Structure containing the pointers and length of the space * reserved on the ring storage. * @param free_space * If non-NULL, returns the amount of space in the ring after the * reservation operation has finished. * @return * The number of objects that can be enqueued, either 0 or n. */ __rte_experimental static __rte_always_inline unsigned int rte_ring_enqueue_zc_burst_start(struct rte_ring *r, unsigned int n, struct rte_ring_zc_data *zcd, unsigned int *free_space) { return rte_ring_enqueue_zc_burst_elem_start(r, sizeof(uintptr_t), n, zcd, free_space); } /** * Complete enqueuing several objects on the ring. * Note that number of objects to enqueue should not exceed previous * enqueue_start return value. * * @param r * A pointer to the ring structure. * @param n * The number of objects to add to the ring. */ __rte_experimental static __rte_always_inline void rte_ring_enqueue_zc_elem_finish(struct rte_ring *r, unsigned int n) { uint32_t tail; switch (r->prod.sync_type) { case RTE_RING_SYNC_ST: n = __rte_ring_st_get_tail(&r->prod, &tail, n); __rte_ring_st_set_head_tail(&r->prod, tail, n, 1); break; case RTE_RING_SYNC_MT_HTS: n = __rte_ring_hts_get_tail(&r->hts_prod, &tail, n); __rte_ring_hts_set_head_tail(&r->hts_prod, tail, n, 1); break; case RTE_RING_SYNC_MT: case RTE_RING_SYNC_MT_RTS: default: /* unsupported mode, shouldn't be here */ RTE_ASSERT(0); } } /** * Complete enqueuing several pointers to objects on the ring. * Note that number of objects to enqueue should not exceed previous * enqueue_start return value. * * @param r * A pointer to the ring structure. * @param n * The number of pointers to objects to add to the ring. */ __rte_experimental static __rte_always_inline void rte_ring_enqueue_zc_finish(struct rte_ring *r, unsigned int n) { rte_ring_enqueue_zc_elem_finish(r, n); } /** * @internal This function moves cons head value and copies up to *n* * objects from the ring to the user provided obj_table. */ static __rte_always_inline unsigned int __rte_ring_do_dequeue_zc_elem_start(struct rte_ring *r, uint32_t esize, uint32_t n, enum rte_ring_queue_behavior behavior, struct rte_ring_zc_data *zcd, unsigned int *available) { uint32_t avail, head, next; switch (r->cons.sync_type) { case RTE_RING_SYNC_ST: n = __rte_ring_move_cons_head(r, RTE_RING_SYNC_ST, n, behavior, &head, &next, &avail); break; case RTE_RING_SYNC_MT_HTS: n = __rte_ring_hts_move_cons_head(r, n, behavior, &head, &avail); break; case RTE_RING_SYNC_MT: case RTE_RING_SYNC_MT_RTS: default: /* unsupported mode, shouldn't be here */ RTE_ASSERT(0); n = 0; avail = 0; return n; } __rte_ring_get_elem_addr(r, head, esize, n, &zcd->ptr1, &zcd->n1, &zcd->ptr2); if (available != NULL) *available = avail - n; return n; } /** * Start to dequeue several objects from the ring. * Note that no actual objects are copied from the queue by this function. * User has to copy objects from the queue using the returned pointers. * User should call rte_ring_dequeue_zc_elem_finish to complete the * dequeue operation. * * @param r * A pointer to the ring structure. * @param esize * The size of ring element, in bytes. It must be a multiple of 4. * @param n * The number of objects to remove from the ring. * @param zcd * Structure containing the pointers and length of the space * reserved on the ring storage. * @param available * If non-NULL, returns the number of remaining ring entries after the * dequeue has finished. * @return * The number of objects that can be dequeued, either 0 or n. */ __rte_experimental static __rte_always_inline unsigned int rte_ring_dequeue_zc_bulk_elem_start(struct rte_ring *r, unsigned int esize, unsigned int n, struct rte_ring_zc_data *zcd, unsigned int *available) { return __rte_ring_do_dequeue_zc_elem_start(r, esize, n, RTE_RING_QUEUE_FIXED, zcd, available); } /** * Start to dequeue several pointers to objects from the ring. * Note that no actual pointers are removed from the queue by this function. * User has to copy pointers to objects from the queue using the * returned pointers. * User should call rte_ring_dequeue_zc_finish to complete the * dequeue operation. * * @param r * A pointer to the ring structure. * @param n * The number of objects to remove from the ring. * @param zcd * Structure containing the pointers and length of the space * reserved on the ring storage. * @param available * If non-NULL, returns the number of remaining ring entries after the * dequeue has finished. * @return * The number of objects that can be dequeued, either 0 or n. */ __rte_experimental static __rte_always_inline unsigned int rte_ring_dequeue_zc_bulk_start(struct rte_ring *r, unsigned int n, struct rte_ring_zc_data *zcd, unsigned int *available) { return rte_ring_dequeue_zc_bulk_elem_start(r, sizeof(uintptr_t), n, zcd, available); } /** * Start to dequeue several objects from the ring. * Note that no actual objects are copied from the queue by this function. * User has to copy objects from the queue using the returned pointers. * User should call rte_ring_dequeue_zc_elem_finish to complete the * dequeue operation. * * @param r * A pointer to the ring structure. * @param esize * The size of ring element, in bytes. It must be a multiple of 4. * This must be the same value used while creating the ring. Otherwise * the results are undefined. * @param n * The number of objects to dequeue from the ring. * @param zcd * Structure containing the pointers and length of the space * reserved on the ring storage. * @param available * If non-NULL, returns the number of remaining ring entries after the * dequeue has finished. * @return * The number of objects that can be dequeued, either 0 or n. */ __rte_experimental static __rte_always_inline unsigned int rte_ring_dequeue_zc_burst_elem_start(struct rte_ring *r, unsigned int esize, unsigned int n, struct rte_ring_zc_data *zcd, unsigned int *available) { return __rte_ring_do_dequeue_zc_elem_start(r, esize, n, RTE_RING_QUEUE_VARIABLE, zcd, available); } /** * Start to dequeue several pointers to objects from the ring. * Note that no actual pointers are removed from the queue by this function. * User has to copy pointers to objects from the queue using the * returned pointers. * User should call rte_ring_dequeue_zc_finish to complete the * dequeue operation. * * @param r * A pointer to the ring structure. * @param n * The number of objects to remove from the ring. * @param zcd * Structure containing the pointers and length of the space * reserved on the ring storage. * @param available * If non-NULL, returns the number of remaining ring entries after the * dequeue has finished. * @return * The number of objects that can be dequeued, either 0 or n. */ __rte_experimental static __rte_always_inline unsigned int rte_ring_dequeue_zc_burst_start(struct rte_ring *r, unsigned int n, struct rte_ring_zc_data *zcd, unsigned int *available) { return rte_ring_dequeue_zc_burst_elem_start(r, sizeof(uintptr_t), n, zcd, available); } /** * Complete dequeuing several objects from the ring. * Note that number of objects to dequeued should not exceed previous * dequeue_start return value. * * @param r * A pointer to the ring structure. * @param n * The number of objects to remove from the ring. */ __rte_experimental static __rte_always_inline void rte_ring_dequeue_zc_elem_finish(struct rte_ring *r, unsigned int n) { uint32_t tail; switch (r->cons.sync_type) { case RTE_RING_SYNC_ST: n = __rte_ring_st_get_tail(&r->cons, &tail, n); __rte_ring_st_set_head_tail(&r->cons, tail, n, 0); break; case RTE_RING_SYNC_MT_HTS: n = __rte_ring_hts_get_tail(&r->hts_cons, &tail, n); __rte_ring_hts_set_head_tail(&r->hts_cons, tail, n, 0); break; case RTE_RING_SYNC_MT: case RTE_RING_SYNC_MT_RTS: default: /* unsupported mode, shouldn't be here */ RTE_ASSERT(0); } } /** * Complete dequeuing several objects from the ring. * Note that number of objects to dequeued should not exceed previous * dequeue_start return value. * * @param r * A pointer to the ring structure. * @param n * The number of objects to remove from the ring. */ __rte_experimental static __rte_always_inline void rte_ring_dequeue_zc_finish(struct rte_ring *r, unsigned int n) { rte_ring_dequeue_elem_finish(r, n); } #ifdef __cplusplus } #endif #endif /* _RTE_RING_PEEK_ZC_H_ */