/* * Copyright 2010-2011 Samy Al Bahra. * Copyright 2011 David Joseph. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifndef _CK_FIFO_H #define _CK_FIFO_H #include #include #include #include #include #include #ifndef CK_F_FIFO_SPSC #define CK_F_FIFO_SPSC struct ck_fifo_spsc_entry { void *value; struct ck_fifo_spsc_entry *next; }; typedef struct ck_fifo_spsc_entry ck_fifo_spsc_entry_t; struct ck_fifo_spsc { ck_spinlock_fas_t m_head; struct ck_fifo_spsc_entry *head; char pad[CK_MD_CACHELINE - sizeof(struct ck_fifo_spsc_entry *) - sizeof(ck_spinlock_fas_t)]; ck_spinlock_fas_t m_tail; struct ck_fifo_spsc_entry *tail; struct ck_fifo_spsc_entry *head_snapshot; struct ck_fifo_spsc_entry *garbage; }; typedef struct ck_fifo_spsc ck_fifo_spsc_t; CK_CC_INLINE static void ck_fifo_spsc_enqueue_lock(struct ck_fifo_spsc *fifo) { ck_spinlock_fas_lock(&fifo->m_tail); return; } CK_CC_INLINE static void ck_fifo_spsc_enqueue_unlock(struct ck_fifo_spsc *fifo) { ck_spinlock_fas_unlock(&fifo->m_tail); return; } CK_CC_INLINE static void ck_fifo_spsc_dequeue_lock(struct ck_fifo_spsc *fifo) { ck_spinlock_fas_lock(&fifo->m_head); return; } CK_CC_INLINE static void ck_fifo_spsc_dequeue_unlock(struct ck_fifo_spsc *fifo) { ck_spinlock_fas_unlock(&fifo->m_head); return; } CK_CC_INLINE static void ck_fifo_spsc_init(struct ck_fifo_spsc *fifo, struct ck_fifo_spsc_entry *stub) { ck_spinlock_fas_init(&fifo->m_head); ck_spinlock_fas_init(&fifo->m_tail); ck_pr_store_ptr(&stub->next, NULL); ck_pr_store_ptr(&fifo->head, stub); ck_pr_store_ptr(&fifo->tail, stub); ck_pr_store_ptr(&fifo->head_snapshot, stub); ck_pr_store_ptr(&fifo->garbage, stub); return; } CK_CC_INLINE static void ck_fifo_spsc_enqueue(struct ck_fifo_spsc *fifo, struct ck_fifo_spsc_entry *entry, void *value) { ck_pr_store_ptr(&entry->value, value); ck_pr_store_ptr(&entry->next, NULL); ck_pr_store_ptr(&fifo->tail->next, entry); ck_pr_fence_store(); ck_pr_store_ptr(&fifo->tail, entry); return; } CK_CC_INLINE static bool ck_fifo_spsc_dequeue(struct ck_fifo_spsc *fifo, void *value) { struct ck_fifo_spsc_entry *stub, *entry; void *store; /* * The head pointer is guaranteed to always point to a stub entry. * If the stub entry does not point to an entry, then the queue is * empty. */ stub = ck_pr_load_ptr(&fifo->head); ck_pr_fence_load(); entry = stub->next; if (entry == NULL) return (false); store = ck_pr_load_ptr(&entry->value); ck_pr_store_ptr(value, store); ck_pr_store_ptr(&fifo->head, entry); return (true); } /* * Recycle a node. This technique for recycling nodes is based on * Dmitriy Vyukov's work. */ CK_CC_INLINE static struct ck_fifo_spsc_entry * ck_fifo_spsc_recycle(struct ck_fifo_spsc *fifo) { struct ck_fifo_spsc_entry *p, *garbage; garbage = ck_pr_load_ptr(&fifo->garbage); p = ck_pr_load_ptr(&fifo->head_snapshot); if (garbage == p) { p = ck_pr_load_ptr(&fifo->head); ck_pr_store_ptr(&fifo->head_snapshot, p); if (garbage == p) return (NULL); } p = garbage; ck_pr_store_ptr(&fifo->garbage, garbage->next); return (p); } #define CK_FIFO_SPSC_ISEMPTY(f) ((f)->head->next == NULL) #define CK_FIFO_SPSC_FIRST(f) ((f)->head->next) #define CK_FIFO_SPSC_NEXT(m) ((m)->next) #define CK_FIFO_SPSC_FOREACH(fifo, entry) \ for ((entry) = CK_FIFO_SPSC_FIRST(fifo); \ (entry) != NULL; \ (entry) = CK_FIFO_SPSC_NEXT(entry)) #define CK_FIFO_SPSC_FOREACH_SAFE(fifo, entry, T) \ for ((entry) = CK_FIFO_SPSC_FIRST(fifo); \ (entry) != NULL && ((T) = (entry)->next, 1); \ (entry) = (T)) #endif /* CK_F_FIFO_SPSC */ #ifdef CK_F_PR_CAS_PTR_2 #ifndef CK_F_FIFO_MPMC #define CK_F_FIFO_MPMC struct ck_fifo_mpmc_entry; struct ck_fifo_mpmc_pointer { struct ck_fifo_mpmc_entry *pointer; char *generation CK_CC_PACKED; } CK_CC_ALIGN(16); struct ck_fifo_mpmc_entry { void *value; struct ck_fifo_mpmc_pointer next; }; typedef struct ck_fifo_mpmc_entry ck_fifo_mpmc_entry_t; struct ck_fifo_mpmc { struct ck_fifo_mpmc_pointer head; char pad[CK_MD_CACHELINE - sizeof(struct ck_fifo_mpmc_pointer)]; struct ck_fifo_mpmc_pointer tail; }; typedef struct ck_fifo_mpmc ck_fifo_mpmc_t; CK_CC_INLINE static void ck_fifo_mpmc_init(struct ck_fifo_mpmc *fifo, struct ck_fifo_mpmc_entry *stub) { ck_pr_store_ptr(&fifo->head.pointer, stub); ck_pr_store_ptr(&fifo->head.generation, 0); ck_pr_store_ptr(&fifo->tail.pointer, stub); ck_pr_store_ptr(&fifo->tail.generation, 0); ck_pr_store_ptr(&stub->next.pointer, NULL); ck_pr_store_ptr(&stub->next.generation, 0); return; } CK_CC_INLINE static void ck_fifo_mpmc_enqueue(struct ck_fifo_mpmc *fifo, struct ck_fifo_mpmc_entry *entry, void *value) { struct ck_fifo_mpmc_pointer tail, next, update; ck_backoff_t backoff = CK_BACKOFF_INITIALIZER; /* * Prepare the upcoming node and make sure to commit the updates * before publishing. */ entry->value = value; entry->next.pointer = NULL; entry->next.generation = 0; ck_pr_fence_store(); for (;;) { tail.generation = ck_pr_load_ptr(&fifo->tail.generation); tail.pointer = ck_pr_load_ptr(&fifo->tail.pointer); next.generation = ck_pr_load_ptr(&tail.pointer->next.generation); next.pointer = ck_pr_load_ptr(&tail.pointer->next.pointer); if (ck_pr_load_ptr(&fifo->tail.generation) != tail.generation) { ck_backoff_eb(&backoff); continue; } if (next.pointer != NULL) { /* * If the tail pointer has an entry following it then * it needs to be forwarded to the next entry. This * helps us guarantee we are always operating on the * last entry. */ update.pointer = next.pointer; update.generation = tail.generation + 1; ck_pr_cas_ptr_2(&fifo->tail, &tail, &update); } else { /* * Attempt to commit new entry to the end of the * current tail. */ update.pointer = entry; update.generation = next.generation + 1; if (ck_pr_cas_ptr_2(&tail.pointer->next, &next, &update) == true) break; ck_backoff_eb(&backoff); } } /* After a successful insert, forward the tail to the new entry. */ update.generation = tail.generation + 1; ck_pr_cas_ptr_2(&fifo->tail, &tail, &update); return; } CK_CC_INLINE static bool ck_fifo_mpmc_dequeue(struct ck_fifo_mpmc *fifo, void *value, ck_fifo_mpmc_entry_t **garbage) { struct ck_fifo_mpmc_pointer head, tail, next, update; ck_backoff_t backoff = CK_BACKOFF_INITIALIZER; for (;;) { head.generation = ck_pr_load_ptr(&fifo->head.generation); head.pointer = ck_pr_load_ptr(&fifo->head.pointer); tail.generation = ck_pr_load_ptr(&fifo->tail.generation); tail.pointer = ck_pr_load_ptr(&fifo->tail.pointer); next.generation = ck_pr_load_ptr(&head.pointer->next.generation); next.pointer = ck_pr_load_ptr(&head.pointer->next.pointer); update.pointer = next.pointer; if (head.pointer == tail.pointer) { /* * The head is guaranteed to always point at a stub * entry. If the stub entry has no references then the * queue is empty. */ if (next.pointer == NULL) return (false); /* Forward the tail pointer if necessary. */ update.generation = tail.generation + 1; ck_pr_cas_ptr_2(&fifo->tail, &tail, &update); } else { /* Save value before commit. */ *(void **)value = ck_pr_load_ptr(&next.pointer->value); /* Forward the head pointer to the next entry. */ update.generation = head.generation + 1; if (ck_pr_cas_ptr_2(&fifo->head, &head, &update) == true) break; ck_backoff_eb(&backoff); } } *garbage = head.pointer; return (true); } #define CK_FIFO_MPMC_ISEMPTY(f) ((f)->head.pointer->next.pointer == NULL) #define CK_FIFO_MPMC_FIRST(f) ((f)->head.pointer->next.pointer) #define CK_FIFO_MPMC_NEXT(m) ((m)->next.pointer) #define CK_FIFO_MPMC_FOREACH(fifo, entry) \ for ((entry) = CK_FIFO_MPMC_FIRST(fifo); \ (entry) != NULL; \ (entry) = CK_FIFO_MPMC_NEXT(entry)) #define CK_FIFO_MPMC_FOREACH_SAFE(fifo, entry, T) \ for ((entry) = CK_FIFO_MPMC_FIRST(fifo); \ (entry) != NULL && ((T) = (entry)->next.pointer, 1); \ (entry) = (T)) #endif /* CK_F_FIFO_MPMC */ #endif /* CK_F_PR_CAS_PTR_2 */ #endif /* _CK_FIFO_H */