/* SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB */ /* * Copyright (c) 2016 Mellanox Technologies Ltd. All rights reserved. * Copyright (c) 2015 System Fabric Works, Inc. All rights reserved. */ #ifndef RXE_QUEUE_H #define RXE_QUEUE_H /* for definition of shared struct rxe_queue_buf */ #include /* implements a simple circular buffer that can optionally be * shared between user space and the kernel and can be resized * the requested element size is rounded up to a power of 2 * and the number of elements in the buffer is also rounded * up to a power of 2. Since the queue is empty when the * producer and consumer indices match the maximum capacity * of the queue is one less than the number of element slots * * Notes: * - Kernel space indices are always masked off to q->index_mask * before storing so do not need to be checked on reads. * - User space indices may be out of range and must be * masked before use when read. * - The kernel indices for shared queues must not be written * by user space so a local copy is used and a shared copy is * stored when the local copy changes. * - By passing the type in the parameter list separate from q * the compiler can eliminate the switch statement when the * actual queue type is known when the function is called. * In the performance path this is done. In less critical * paths just q->type is passed. */ /* type of queue */ enum queue_type { QUEUE_TYPE_KERNEL, QUEUE_TYPE_TO_USER, QUEUE_TYPE_FROM_USER, }; struct rxe_queue { struct rxe_dev *rxe; struct rxe_queue_buf *buf; struct rxe_mmap_info *ip; size_t buf_size; size_t elem_size; unsigned int log2_elem_size; u32 index_mask; enum queue_type type; /* private copy of index for shared queues between * kernel space and user space. Kernel reads and writes * this copy and then replicates to rxe_queue_buf * for read access by user space. */ u32 index; }; int do_mmap_info(struct rxe_dev *rxe, struct mminfo __user *outbuf, struct ib_udata *udata, struct rxe_queue_buf *buf, size_t buf_size, struct rxe_mmap_info **ip_p); void rxe_queue_reset(struct rxe_queue *q); struct rxe_queue *rxe_queue_init(struct rxe_dev *rxe, int *num_elem, unsigned int elem_size, enum queue_type type); int rxe_queue_resize(struct rxe_queue *q, unsigned int *num_elem_p, unsigned int elem_size, struct ib_udata *udata, struct mminfo __user *outbuf, /* Protect producers while resizing queue */ spinlock_t *producer_lock, /* Protect consumers while resizing queue */ spinlock_t *consumer_lock); void rxe_queue_cleanup(struct rxe_queue *queue); static inline int next_index(struct rxe_queue *q, int index) { return (index + 1) & q->buf->index_mask; } static inline int queue_empty(struct rxe_queue *q, enum queue_type type) { u32 prod; u32 cons; switch (type) { case QUEUE_TYPE_FROM_USER: /* protect user space index */ prod = smp_load_acquire(&q->buf->producer_index); cons = q->index; break; case QUEUE_TYPE_TO_USER: prod = q->index; /* protect user space index */ cons = smp_load_acquire(&q->buf->consumer_index); break; case QUEUE_TYPE_KERNEL: prod = q->buf->producer_index; cons = q->buf->consumer_index; break; } return ((prod - cons) & q->index_mask) == 0; } static inline int queue_full(struct rxe_queue *q, enum queue_type type) { u32 prod; u32 cons; switch (type) { case QUEUE_TYPE_FROM_USER: /* protect user space index */ prod = smp_load_acquire(&q->buf->producer_index); cons = q->index; break; case QUEUE_TYPE_TO_USER: prod = q->index; /* protect user space index */ cons = smp_load_acquire(&q->buf->consumer_index); break; case QUEUE_TYPE_KERNEL: prod = q->buf->producer_index; cons = q->buf->consumer_index; break; } return ((prod + 1 - cons) & q->index_mask) == 0; } static inline unsigned int queue_count(const struct rxe_queue *q, enum queue_type type) { u32 prod; u32 cons; switch (type) { case QUEUE_TYPE_FROM_USER: /* protect user space index */ prod = smp_load_acquire(&q->buf->producer_index); cons = q->index; break; case QUEUE_TYPE_TO_USER: prod = q->index; /* protect user space index */ cons = smp_load_acquire(&q->buf->consumer_index); break; case QUEUE_TYPE_KERNEL: prod = q->buf->producer_index; cons = q->buf->consumer_index; break; } return (prod - cons) & q->index_mask; } static inline void advance_producer(struct rxe_queue *q, enum queue_type type) { u32 prod; switch (type) { case QUEUE_TYPE_FROM_USER: pr_warn_once("Normally kernel should not write user space index\n"); /* protect user space index */ prod = smp_load_acquire(&q->buf->producer_index); prod = (prod + 1) & q->index_mask; /* same */ smp_store_release(&q->buf->producer_index, prod); break; case QUEUE_TYPE_TO_USER: prod = q->index; q->index = (prod + 1) & q->index_mask; q->buf->producer_index = q->index; break; case QUEUE_TYPE_KERNEL: prod = q->buf->producer_index; q->buf->producer_index = (prod + 1) & q->index_mask; break; } } static inline void advance_consumer(struct rxe_queue *q, enum queue_type type) { u32 cons; switch (type) { case QUEUE_TYPE_FROM_USER: cons = q->index; q->index = (cons + 1) & q->index_mask; q->buf->consumer_index = q->index; break; case QUEUE_TYPE_TO_USER: pr_warn_once("Normally kernel should not write user space index\n"); /* protect user space index */ cons = smp_load_acquire(&q->buf->consumer_index); cons = (cons + 1) & q->index_mask; /* same */ smp_store_release(&q->buf->consumer_index, cons); break; case QUEUE_TYPE_KERNEL: cons = q->buf->consumer_index; q->buf->consumer_index = (cons + 1) & q->index_mask; break; } } static inline void *producer_addr(struct rxe_queue *q, enum queue_type type) { u32 prod; switch (type) { case QUEUE_TYPE_FROM_USER: /* protect user space index */ prod = smp_load_acquire(&q->buf->producer_index); prod &= q->index_mask; break; case QUEUE_TYPE_TO_USER: prod = q->index; break; case QUEUE_TYPE_KERNEL: prod = q->buf->producer_index; break; } return q->buf->data + (prod << q->log2_elem_size); } static inline void *consumer_addr(struct rxe_queue *q, enum queue_type type) { u32 cons; switch (type) { case QUEUE_TYPE_FROM_USER: cons = q->index; break; case QUEUE_TYPE_TO_USER: /* protect user space index */ cons = smp_load_acquire(&q->buf->consumer_index); cons &= q->index_mask; break; case QUEUE_TYPE_KERNEL: cons = q->buf->consumer_index; break; } return q->buf->data + (cons << q->log2_elem_size); } static inline unsigned int producer_index(struct rxe_queue *q, enum queue_type type) { u32 prod; switch (type) { case QUEUE_TYPE_FROM_USER: /* protect user space index */ prod = smp_load_acquire(&q->buf->producer_index); prod &= q->index_mask; break; case QUEUE_TYPE_TO_USER: prod = q->index; break; case QUEUE_TYPE_KERNEL: prod = q->buf->producer_index; break; } return prod; } static inline unsigned int consumer_index(struct rxe_queue *q, enum queue_type type) { u32 cons; switch (type) { case QUEUE_TYPE_FROM_USER: cons = q->index; break; case QUEUE_TYPE_TO_USER: /* protect user space index */ cons = smp_load_acquire(&q->buf->consumer_index); cons &= q->index_mask; break; case QUEUE_TYPE_KERNEL: cons = q->buf->consumer_index; break; } return cons; } static inline void *addr_from_index(struct rxe_queue *q, unsigned int index) { return q->buf->data + ((index & q->index_mask) << q->buf->log2_elem_size); } static inline unsigned int index_from_addr(const struct rxe_queue *q, const void *addr) { return (((u8 *)addr - q->buf->data) >> q->log2_elem_size) & q->index_mask; } static inline void *queue_head(struct rxe_queue *q, enum queue_type type) { return queue_empty(q, type) ? NULL : consumer_addr(q, type); } #endif /* RXE_QUEUE_H */