numam-dpdk/lib/librte_ring/rte_ring.h
Bruce Richardson b744611555 ring: allow non power-of-2 sizes
The rte_rings traditionally have only supported having ring sizes as powers
of 2, with the actual usable space being the size - 1. In some cases, for
example, with an eventdev where we want to precisely control queue depths
for latency, we need to allow ring sizes which are not powers of two so we
add in an additional ring capacity value to allow that. For existing rings,
this value will be size-1, i.e. the same as the mask, but if the new
EXACT_SZ flag is passed on ring creation, the ring will have exactly the
usable space requested, although the underlying memory size may be bigger.

Signed-off-by: Bruce Richardson <bruce.richardson@intel.com>
Acked-by: Olivier Matz <olivier.matz@6wind.com>
2017-07-07 09:29:17 +02:00

1133 lines
35 KiB
C

/*-
* BSD LICENSE
*
* Copyright(c) 2010-2017 Intel Corporation. All rights reserved.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
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*
* * Redistributions of source code must retain the above copyright
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* from this software without specific prior written permission.
*
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/*
* Derived from FreeBSD's bufring.h
*
**************************************************************************
*
* Copyright (c) 2007-2009 Kip Macy kmacy@freebsd.org
* 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. The name of Kip Macy nor the names of other
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT OWNER 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 _RTE_RING_H_
#define _RTE_RING_H_
/**
* @file
* RTE Ring
*
* The Ring Manager is a fixed-size queue, implemented as a table of
* pointers. Head and tail pointers are modified atomically, allowing
* concurrent access to it. It has the following features:
*
* - FIFO (First In First Out)
* - Maximum size is fixed; the pointers are stored in a table.
* - Lockless implementation.
* - Multi- or single-consumer dequeue.
* - Multi- or single-producer enqueue.
* - Bulk dequeue.
* - Bulk enqueue.
*
* Note: the ring implementation is not preemptable. A lcore must not
* be interrupted by another task that uses the same ring.
*
*/
#ifdef __cplusplus
extern "C" {
#endif
#include <stdio.h>
#include <stdint.h>
#include <sys/queue.h>
#include <errno.h>
#include <rte_common.h>
#include <rte_memory.h>
#include <rte_lcore.h>
#include <rte_atomic.h>
#include <rte_branch_prediction.h>
#include <rte_memzone.h>
#include <rte_pause.h>
#define RTE_TAILQ_RING_NAME "RTE_RING"
enum rte_ring_queue_behavior {
RTE_RING_QUEUE_FIXED = 0, /* Enq/Deq a fixed number of items from a ring */
RTE_RING_QUEUE_VARIABLE /* Enq/Deq as many items as possible from ring */
};
#define RTE_RING_MZ_PREFIX "RG_"
/**< The maximum length of a ring name. */
#define RTE_RING_NAMESIZE (RTE_MEMZONE_NAMESIZE - \
sizeof(RTE_RING_MZ_PREFIX) + 1)
struct rte_memzone; /* forward declaration, so as not to require memzone.h */
#if RTE_CACHE_LINE_SIZE < 128
#define PROD_ALIGN (RTE_CACHE_LINE_SIZE * 2)
#define CONS_ALIGN (RTE_CACHE_LINE_SIZE * 2)
#else
#define PROD_ALIGN RTE_CACHE_LINE_SIZE
#define CONS_ALIGN RTE_CACHE_LINE_SIZE
#endif
/* structure to hold a pair of head/tail values and other metadata */
struct rte_ring_headtail {
volatile uint32_t head; /**< Prod/consumer head. */
volatile uint32_t tail; /**< Prod/consumer tail. */
uint32_t single; /**< True if single prod/cons */
};
/**
* An RTE ring structure.
*
* The producer and the consumer have a head and a tail index. The particularity
* of these index is that they are not between 0 and size(ring). These indexes
* are between 0 and 2^32, and we mask their value when we access the ring[]
* field. Thanks to this assumption, we can do subtractions between 2 index
* values in a modulo-32bit base: that's why the overflow of the indexes is not
* a problem.
*/
struct rte_ring {
/*
* Note: this field kept the RTE_MEMZONE_NAMESIZE size due to ABI
* compatibility requirements, it could be changed to RTE_RING_NAMESIZE
* next time the ABI changes
*/
char name[RTE_MEMZONE_NAMESIZE] __rte_cache_aligned; /**< Name of the ring. */
int flags; /**< Flags supplied at creation. */
const struct rte_memzone *memzone;
/**< Memzone, if any, containing the rte_ring */
uint32_t size; /**< Size of ring. */
uint32_t mask; /**< Mask (size-1) of ring. */
uint32_t capacity; /**< Usable size of ring */
/** Ring producer status. */
struct rte_ring_headtail prod __rte_aligned(PROD_ALIGN);
/** Ring consumer status. */
struct rte_ring_headtail cons __rte_aligned(CONS_ALIGN);
};
#define RING_F_SP_ENQ 0x0001 /**< The default enqueue is "single-producer". */
#define RING_F_SC_DEQ 0x0002 /**< The default dequeue is "single-consumer". */
/**
* Ring is to hold exactly requested number of entries.
* Without this flag set, the ring size requested must be a power of 2, and the
* usable space will be that size - 1. With the flag, the requested size will
* be rounded up to the next power of two, but the usable space will be exactly
* that requested. Worst case, if a power-of-2 size is requested, half the
* ring space will be wasted.
*/
#define RING_F_EXACT_SZ 0x0004
#define RTE_RING_SZ_MASK (unsigned)(0x0fffffff) /**< Ring size mask */
/* @internal defines for passing to the enqueue dequeue worker functions */
#define __IS_SP 1
#define __IS_MP 0
#define __IS_SC 1
#define __IS_MC 0
/**
* Calculate the memory size needed for a ring
*
* This function returns the number of bytes needed for a ring, given
* the number of elements in it. This value is the sum of the size of
* the structure rte_ring and the size of the memory needed by the
* objects pointers. The value is aligned to a cache line size.
*
* @param count
* The number of elements in the ring (must be a power of 2).
* @return
* - The memory size needed for the ring on success.
* - -EINVAL if count is not a power of 2.
*/
ssize_t rte_ring_get_memsize(unsigned count);
/**
* Initialize a ring structure.
*
* Initialize a ring structure in memory pointed by "r". The size of the
* memory area must be large enough to store the ring structure and the
* object table. It is advised to use rte_ring_get_memsize() to get the
* appropriate size.
*
* The ring size is set to *count*, which must be a power of two. Water
* marking is disabled by default. The real usable ring size is
* *count-1* instead of *count* to differentiate a free ring from an
* empty ring.
*
* The ring is not added in RTE_TAILQ_RING global list. Indeed, the
* memory given by the caller may not be shareable among dpdk
* processes.
*
* @param r
* The pointer to the ring structure followed by the objects table.
* @param name
* The name of the ring.
* @param count
* The number of elements in the ring (must be a power of 2).
* @param flags
* An OR of the following:
* - RING_F_SP_ENQ: If this flag is set, the default behavior when
* using ``rte_ring_enqueue()`` or ``rte_ring_enqueue_bulk()``
* is "single-producer". Otherwise, it is "multi-producers".
* - RING_F_SC_DEQ: If this flag is set, the default behavior when
* using ``rte_ring_dequeue()`` or ``rte_ring_dequeue_bulk()``
* is "single-consumer". Otherwise, it is "multi-consumers".
* @return
* 0 on success, or a negative value on error.
*/
int rte_ring_init(struct rte_ring *r, const char *name, unsigned count,
unsigned flags);
/**
* Create a new ring named *name* in memory.
*
* This function uses ``memzone_reserve()`` to allocate memory. Then it
* calls rte_ring_init() to initialize an empty ring.
*
* The new ring size is set to *count*, which must be a power of
* two. Water marking is disabled by default. The real usable ring size
* is *count-1* instead of *count* to differentiate a free ring from an
* empty ring.
*
* The ring is added in RTE_TAILQ_RING list.
*
* @param name
* The name of the ring.
* @param count
* The size of the ring (must be a power of 2).
* @param socket_id
* The *socket_id* argument is the socket identifier in case of
* NUMA. The value can be *SOCKET_ID_ANY* if there is no NUMA
* constraint for the reserved zone.
* @param flags
* An OR of the following:
* - RING_F_SP_ENQ: If this flag is set, the default behavior when
* using ``rte_ring_enqueue()`` or ``rte_ring_enqueue_bulk()``
* is "single-producer". Otherwise, it is "multi-producers".
* - RING_F_SC_DEQ: If this flag is set, the default behavior when
* using ``rte_ring_dequeue()`` or ``rte_ring_dequeue_bulk()``
* is "single-consumer". Otherwise, it is "multi-consumers".
* @return
* On success, the pointer to the new allocated ring. NULL on error with
* rte_errno set appropriately. Possible errno values include:
* - E_RTE_NO_CONFIG - function could not get pointer to rte_config structure
* - E_RTE_SECONDARY - function was called from a secondary process instance
* - EINVAL - count provided is not a power of 2
* - ENOSPC - the maximum number of memzones has already been allocated
* - EEXIST - a memzone with the same name already exists
* - ENOMEM - no appropriate memory area found in which to create memzone
*/
struct rte_ring *rte_ring_create(const char *name, unsigned count,
int socket_id, unsigned flags);
/**
* De-allocate all memory used by the ring.
*
* @param r
* Ring to free
*/
void rte_ring_free(struct rte_ring *r);
/**
* Dump the status of the ring to a file.
*
* @param f
* A pointer to a file for output
* @param r
* A pointer to the ring structure.
*/
void rte_ring_dump(FILE *f, const struct rte_ring *r);
/* the actual enqueue of pointers on the ring.
* Placed here since identical code needed in both
* single and multi producer enqueue functions */
#define ENQUEUE_PTRS(r, ring_start, prod_head, obj_table, n, obj_type) do { \
unsigned int i; \
const uint32_t size = (r)->size; \
uint32_t idx = prod_head & (r)->mask; \
obj_type *ring = (obj_type *)ring_start; \
if (likely(idx + n < size)) { \
for (i = 0; i < (n & ((~(unsigned)0x3))); i+=4, idx+=4) { \
ring[idx] = obj_table[i]; \
ring[idx+1] = obj_table[i+1]; \
ring[idx+2] = obj_table[i+2]; \
ring[idx+3] = obj_table[i+3]; \
} \
switch (n & 0x3) { \
case 3: \
ring[idx++] = obj_table[i++]; /* fallthrough */ \
case 2: \
ring[idx++] = obj_table[i++]; /* fallthrough */ \
case 1: \
ring[idx++] = obj_table[i++]; \
} \
} else { \
for (i = 0; idx < size; i++, idx++)\
ring[idx] = obj_table[i]; \
for (idx = 0; i < n; i++, idx++) \
ring[idx] = obj_table[i]; \
} \
} while (0)
/* the actual copy of pointers on the ring to obj_table.
* Placed here since identical code needed in both
* single and multi consumer dequeue functions */
#define DEQUEUE_PTRS(r, ring_start, cons_head, obj_table, n, obj_type) do { \
unsigned int i; \
uint32_t idx = cons_head & (r)->mask; \
const uint32_t size = (r)->size; \
obj_type *ring = (obj_type *)ring_start; \
if (likely(idx + n < size)) { \
for (i = 0; i < (n & (~(unsigned)0x3)); i+=4, idx+=4) {\
obj_table[i] = ring[idx]; \
obj_table[i+1] = ring[idx+1]; \
obj_table[i+2] = ring[idx+2]; \
obj_table[i+3] = ring[idx+3]; \
} \
switch (n & 0x3) { \
case 3: \
obj_table[i++] = ring[idx++]; /* fallthrough */ \
case 2: \
obj_table[i++] = ring[idx++]; /* fallthrough */ \
case 1: \
obj_table[i++] = ring[idx++]; \
} \
} else { \
for (i = 0; idx < size; i++, idx++) \
obj_table[i] = ring[idx]; \
for (idx = 0; i < n; i++, idx++) \
obj_table[i] = ring[idx]; \
} \
} while (0)
static __rte_always_inline void
update_tail(struct rte_ring_headtail *ht, uint32_t old_val, uint32_t new_val,
uint32_t single)
{
/*
* If there are other enqueues/dequeues in progress that preceded us,
* we need to wait for them to complete
*/
if (!single)
while (unlikely(ht->tail != old_val))
rte_pause();
ht->tail = new_val;
}
/**
* @internal This function updates the producer head for enqueue
*
* @param r
* A pointer to the ring structure
* @param is_sp
* Indicates whether multi-producer path is needed or not
* @param n
* The number of elements we will want to enqueue, i.e. how far should the
* head be moved
* @param behavior
* RTE_RING_QUEUE_FIXED: Enqueue a fixed number of items from a ring
* RTE_RING_QUEUE_VARIABLE: Enqueue as many items as possible from ring
* @param old_head
* Returns head value as it was before the move, i.e. where enqueue starts
* @param new_head
* Returns the current/new head value i.e. where enqueue finishes
* @param free_entries
* Returns the amount of free space in the ring BEFORE head was moved
* @return
* Actual number of objects enqueued.
* If behavior == RTE_RING_QUEUE_FIXED, this will be 0 or n only.
*/
static __rte_always_inline unsigned int
__rte_ring_move_prod_head(struct rte_ring *r, int is_sp,
unsigned int n, enum rte_ring_queue_behavior behavior,
uint32_t *old_head, uint32_t *new_head,
uint32_t *free_entries)
{
const uint32_t capacity = r->capacity;
unsigned int max = n;
int success;
do {
/* Reset n to the initial burst count */
n = max;
*old_head = r->prod.head;
const uint32_t cons_tail = r->cons.tail;
/*
* The subtraction is done between two unsigned 32bits value
* (the result is always modulo 32 bits even if we have
* *old_head > cons_tail). So 'free_entries' is always between 0
* and capacity (which is < size).
*/
*free_entries = (capacity + cons_tail - *old_head);
/* check that we have enough room in ring */
if (unlikely(n > *free_entries))
n = (behavior == RTE_RING_QUEUE_FIXED) ?
0 : *free_entries;
if (n == 0)
return 0;
*new_head = *old_head + n;
if (is_sp)
r->prod.head = *new_head, success = 1;
else
success = rte_atomic32_cmpset(&r->prod.head,
*old_head, *new_head);
} while (unlikely(success == 0));
return n;
}
/**
* @internal Enqueue several objects on the ring
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects).
* @param n
* The number of objects to add in the ring from the obj_table.
* @param behavior
* RTE_RING_QUEUE_FIXED: Enqueue a fixed number of items from a ring
* RTE_RING_QUEUE_VARIABLE: Enqueue as many items as possible from ring
* @param is_sp
* Indicates whether to use single producer or multi-producer head update
* @param free_space
* returns the amount of space after the enqueue operation has finished
* @return
* Actual number of objects enqueued.
* If behavior == RTE_RING_QUEUE_FIXED, this will be 0 or n only.
*/
static __rte_always_inline unsigned int
__rte_ring_do_enqueue(struct rte_ring *r, void * const *obj_table,
unsigned int n, enum rte_ring_queue_behavior behavior,
int is_sp, unsigned int *free_space)
{
uint32_t prod_head, prod_next;
uint32_t free_entries;
n = __rte_ring_move_prod_head(r, is_sp, n, behavior,
&prod_head, &prod_next, &free_entries);
if (n == 0)
goto end;
ENQUEUE_PTRS(r, &r[1], prod_head, obj_table, n, void *);
rte_smp_wmb();
update_tail(&r->prod, prod_head, prod_next, is_sp);
end:
if (free_space != NULL)
*free_space = free_entries - n;
return n;
}
/**
* @internal This function updates the consumer head for dequeue
*
* @param r
* A pointer to the ring structure
* @param is_sc
* Indicates whether multi-consumer path is needed or not
* @param n
* The number of elements we will want to enqueue, i.e. how far should the
* head be moved
* @param behavior
* RTE_RING_QUEUE_FIXED: Dequeue a fixed number of items from a ring
* RTE_RING_QUEUE_VARIABLE: Dequeue as many items as possible from ring
* @param old_head
* Returns head value as it was before the move, i.e. where dequeue starts
* @param new_head
* Returns the current/new head value i.e. where dequeue finishes
* @param entries
* Returns the number of entries in the ring BEFORE head was moved
* @return
* - Actual number of objects dequeued.
* If behavior == RTE_RING_QUEUE_FIXED, this will be 0 or n only.
*/
static __rte_always_inline unsigned int
__rte_ring_move_cons_head(struct rte_ring *r, int is_sc,
unsigned int n, enum rte_ring_queue_behavior behavior,
uint32_t *old_head, uint32_t *new_head,
uint32_t *entries)
{
unsigned int max = n;
int success;
/* move cons.head atomically */
do {
/* Restore n as it may change every loop */
n = max;
*old_head = r->cons.head;
const uint32_t prod_tail = r->prod.tail;
/* The subtraction is done between two unsigned 32bits value
* (the result is always modulo 32 bits even if we have
* cons_head > prod_tail). So 'entries' is always between 0
* and size(ring)-1. */
*entries = (prod_tail - *old_head);
/* Set the actual entries for dequeue */
if (n > *entries)
n = (behavior == RTE_RING_QUEUE_FIXED) ? 0 : *entries;
if (unlikely(n == 0))
return 0;
*new_head = *old_head + n;
if (is_sc)
r->cons.head = *new_head, success = 1;
else
success = rte_atomic32_cmpset(&r->cons.head, *old_head,
*new_head);
} while (unlikely(success == 0));
return n;
}
/**
* @internal Dequeue several objects from the ring
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects).
* @param n
* The number of objects to pull from the ring.
* @param behavior
* RTE_RING_QUEUE_FIXED: Dequeue a fixed number of items from a ring
* RTE_RING_QUEUE_VARIABLE: Dequeue as many items as possible from ring
* @param is_sc
* Indicates whether to use single consumer or multi-consumer head update
* @param available
* returns the number of remaining ring entries after the dequeue has finished
* @return
* - Actual number of objects dequeued.
* If behavior == RTE_RING_QUEUE_FIXED, this will be 0 or n only.
*/
static __rte_always_inline unsigned int
__rte_ring_do_dequeue(struct rte_ring *r, void **obj_table,
unsigned int n, enum rte_ring_queue_behavior behavior,
int is_sc, unsigned int *available)
{
uint32_t cons_head, cons_next;
uint32_t entries;
n = __rte_ring_move_cons_head(r, is_sc, n, behavior,
&cons_head, &cons_next, &entries);
if (n == 0)
goto end;
DEQUEUE_PTRS(r, &r[1], cons_head, obj_table, n, void *);
rte_smp_rmb();
update_tail(&r->cons, cons_head, cons_next, is_sc);
end:
if (available != NULL)
*available = entries - n;
return n;
}
/**
* Enqueue several objects on the ring (multi-producers safe).
*
* This function uses a "compare and set" instruction to move the
* producer index atomically.
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects).
* @param n
* The number of objects to add in the ring from the obj_table.
* @param free_space
* if non-NULL, returns the amount of space in the ring after the
* enqueue operation has finished.
* @return
* The number of objects enqueued, either 0 or n
*/
static __rte_always_inline unsigned int
rte_ring_mp_enqueue_bulk(struct rte_ring *r, void * const *obj_table,
unsigned int n, unsigned int *free_space)
{
return __rte_ring_do_enqueue(r, obj_table, n, RTE_RING_QUEUE_FIXED,
__IS_MP, free_space);
}
/**
* Enqueue several objects on a ring (NOT multi-producers safe).
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects).
* @param n
* The number of objects to add in the ring from the obj_table.
* @param free_space
* if non-NULL, returns the amount of space in the ring after the
* enqueue operation has finished.
* @return
* The number of objects enqueued, either 0 or n
*/
static __rte_always_inline unsigned int
rte_ring_sp_enqueue_bulk(struct rte_ring *r, void * const *obj_table,
unsigned int n, unsigned int *free_space)
{
return __rte_ring_do_enqueue(r, obj_table, n, RTE_RING_QUEUE_FIXED,
__IS_SP, free_space);
}
/**
* Enqueue several objects on a ring.
*
* This function calls the multi-producer or the single-producer
* version depending on the default behavior that was specified at
* ring creation time (see flags).
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects).
* @param n
* The number of objects to add in the ring from the obj_table.
* @param free_space
* if non-NULL, returns the amount of space in the ring after the
* enqueue operation has finished.
* @return
* The number of objects enqueued, either 0 or n
*/
static __rte_always_inline unsigned int
rte_ring_enqueue_bulk(struct rte_ring *r, void * const *obj_table,
unsigned int n, unsigned int *free_space)
{
return __rte_ring_do_enqueue(r, obj_table, n, RTE_RING_QUEUE_FIXED,
r->prod.single, free_space);
}
/**
* Enqueue one object on a ring (multi-producers safe).
*
* This function uses a "compare and set" instruction to move the
* producer index atomically.
*
* @param r
* A pointer to the ring structure.
* @param obj
* A pointer to the object to be added.
* @return
* - 0: Success; objects enqueued.
* - -ENOBUFS: Not enough room in the ring to enqueue; no object is enqueued.
*/
static __rte_always_inline int
rte_ring_mp_enqueue(struct rte_ring *r, void *obj)
{
return rte_ring_mp_enqueue_bulk(r, &obj, 1, NULL) ? 0 : -ENOBUFS;
}
/**
* Enqueue one object on a ring (NOT multi-producers safe).
*
* @param r
* A pointer to the ring structure.
* @param obj
* A pointer to the object to be added.
* @return
* - 0: Success; objects enqueued.
* - -ENOBUFS: Not enough room in the ring to enqueue; no object is enqueued.
*/
static __rte_always_inline int
rte_ring_sp_enqueue(struct rte_ring *r, void *obj)
{
return rte_ring_sp_enqueue_bulk(r, &obj, 1, NULL) ? 0 : -ENOBUFS;
}
/**
* Enqueue one object on a ring.
*
* This function calls the multi-producer or the single-producer
* version, depending on the default behaviour that was specified at
* ring creation time (see flags).
*
* @param r
* A pointer to the ring structure.
* @param obj
* A pointer to the object to be added.
* @return
* - 0: Success; objects enqueued.
* - -ENOBUFS: Not enough room in the ring to enqueue; no object is enqueued.
*/
static __rte_always_inline int
rte_ring_enqueue(struct rte_ring *r, void *obj)
{
return rte_ring_enqueue_bulk(r, &obj, 1, NULL) ? 0 : -ENOBUFS;
}
/**
* Dequeue several objects from a ring (multi-consumers safe).
*
* This function uses a "compare and set" instruction to move the
* consumer index atomically.
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects) that will be filled.
* @param n
* The number of objects to dequeue from the ring to the obj_table.
* @param available
* If non-NULL, returns the number of remaining ring entries after the
* dequeue has finished.
* @return
* The number of objects dequeued, either 0 or n
*/
static __rte_always_inline unsigned int
rte_ring_mc_dequeue_bulk(struct rte_ring *r, void **obj_table,
unsigned int n, unsigned int *available)
{
return __rte_ring_do_dequeue(r, obj_table, n, RTE_RING_QUEUE_FIXED,
__IS_MC, available);
}
/**
* Dequeue several objects from a ring (NOT multi-consumers safe).
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects) that will be filled.
* @param n
* The number of objects to dequeue from the ring to the obj_table,
* must be strictly positive.
* @param available
* If non-NULL, returns the number of remaining ring entries after the
* dequeue has finished.
* @return
* The number of objects dequeued, either 0 or n
*/
static __rte_always_inline unsigned int
rte_ring_sc_dequeue_bulk(struct rte_ring *r, void **obj_table,
unsigned int n, unsigned int *available)
{
return __rte_ring_do_dequeue(r, obj_table, n, RTE_RING_QUEUE_FIXED,
__IS_SC, available);
}
/**
* Dequeue several objects from a ring.
*
* This function calls the multi-consumers or the single-consumer
* version, depending on the default behaviour that was specified at
* ring creation time (see flags).
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects) that will be filled.
* @param n
* The number of objects to dequeue from the ring to the obj_table.
* @param available
* If non-NULL, returns the number of remaining ring entries after the
* dequeue has finished.
* @return
* The number of objects dequeued, either 0 or n
*/
static __rte_always_inline unsigned int
rte_ring_dequeue_bulk(struct rte_ring *r, void **obj_table, unsigned int n,
unsigned int *available)
{
return __rte_ring_do_dequeue(r, obj_table, n, RTE_RING_QUEUE_FIXED,
r->cons.single, available);
}
/**
* Dequeue one object from a ring (multi-consumers safe).
*
* This function uses a "compare and set" instruction to move the
* consumer index atomically.
*
* @param r
* A pointer to the ring structure.
* @param obj_p
* A pointer to a void * pointer (object) that will be filled.
* @return
* - 0: Success; objects dequeued.
* - -ENOENT: Not enough entries in the ring to dequeue; no object is
* dequeued.
*/
static __rte_always_inline int
rte_ring_mc_dequeue(struct rte_ring *r, void **obj_p)
{
return rte_ring_mc_dequeue_bulk(r, obj_p, 1, NULL) ? 0 : -ENOENT;
}
/**
* Dequeue one object from a ring (NOT multi-consumers safe).
*
* @param r
* A pointer to the ring structure.
* @param obj_p
* A pointer to a void * pointer (object) that will be filled.
* @return
* - 0: Success; objects dequeued.
* - -ENOENT: Not enough entries in the ring to dequeue, no object is
* dequeued.
*/
static __rte_always_inline int
rte_ring_sc_dequeue(struct rte_ring *r, void **obj_p)
{
return rte_ring_sc_dequeue_bulk(r, obj_p, 1, NULL) ? 0 : -ENOENT;
}
/**
* Dequeue one object from a ring.
*
* This function calls the multi-consumers or the single-consumer
* version depending on the default behaviour that was specified at
* ring creation time (see flags).
*
* @param r
* A pointer to the ring structure.
* @param obj_p
* A pointer to a void * pointer (object) that will be filled.
* @return
* - 0: Success, objects dequeued.
* - -ENOENT: Not enough entries in the ring to dequeue, no object is
* dequeued.
*/
static __rte_always_inline int
rte_ring_dequeue(struct rte_ring *r, void **obj_p)
{
return rte_ring_dequeue_bulk(r, obj_p, 1, NULL) ? 0 : -ENOENT;
}
/**
* Return the number of entries in a ring.
*
* @param r
* A pointer to the ring structure.
* @return
* The number of entries in the ring.
*/
static inline unsigned
rte_ring_count(const struct rte_ring *r)
{
uint32_t prod_tail = r->prod.tail;
uint32_t cons_tail = r->cons.tail;
uint32_t count = (prod_tail - cons_tail) & r->mask;
return (count > r->capacity) ? r->capacity : count;
}
/**
* Return the number of free entries in a ring.
*
* @param r
* A pointer to the ring structure.
* @return
* The number of free entries in the ring.
*/
static inline unsigned
rte_ring_free_count(const struct rte_ring *r)
{
return r->capacity - rte_ring_count(r);
}
/**
* Test if a ring is full.
*
* @param r
* A pointer to the ring structure.
* @return
* - 1: The ring is full.
* - 0: The ring is not full.
*/
static inline int
rte_ring_full(const struct rte_ring *r)
{
return rte_ring_free_count(r) == 0;
}
/**
* Test if a ring is empty.
*
* @param r
* A pointer to the ring structure.
* @return
* - 1: The ring is empty.
* - 0: The ring is not empty.
*/
static inline int
rte_ring_empty(const struct rte_ring *r)
{
return rte_ring_count(r) == 0;
}
/**
* Return the size of the ring.
*
* @param r
* A pointer to the ring structure.
* @return
* The size of the data store used by the ring.
* NOTE: this is not the same as the usable space in the ring. To query that
* use ``rte_ring_get_capacity()``.
*/
static inline unsigned int
rte_ring_get_size(const struct rte_ring *r)
{
return r->size;
}
/**
* Return the number of elements which can be stored in the ring.
*
* @param r
* A pointer to the ring structure.
* @return
* The usable size of the ring.
*/
static inline unsigned int
rte_ring_get_capacity(const struct rte_ring *r)
{
return r->capacity;
}
/**
* Dump the status of all rings on the console
*
* @param f
* A pointer to a file for output
*/
void rte_ring_list_dump(FILE *f);
/**
* Search a ring from its name
*
* @param name
* The name of the ring.
* @return
* The pointer to the ring matching the name, or NULL if not found,
* with rte_errno set appropriately. Possible rte_errno values include:
* - ENOENT - required entry not available to return.
*/
struct rte_ring *rte_ring_lookup(const char *name);
/**
* Enqueue several objects on the ring (multi-producers safe).
*
* This function uses a "compare and set" instruction to move the
* producer index atomically.
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects).
* @param n
* The number of objects to add in the ring from the obj_table.
* @param free_space
* if non-NULL, returns the amount of space in the ring after the
* enqueue operation has finished.
* @return
* - n: Actual number of objects enqueued.
*/
static __rte_always_inline unsigned
rte_ring_mp_enqueue_burst(struct rte_ring *r, void * const *obj_table,
unsigned int n, unsigned int *free_space)
{
return __rte_ring_do_enqueue(r, obj_table, n,
RTE_RING_QUEUE_VARIABLE, __IS_MP, free_space);
}
/**
* Enqueue several objects on a ring (NOT multi-producers safe).
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects).
* @param n
* The number of objects to add in the ring from the obj_table.
* @param free_space
* if non-NULL, returns the amount of space in the ring after the
* enqueue operation has finished.
* @return
* - n: Actual number of objects enqueued.
*/
static __rte_always_inline unsigned
rte_ring_sp_enqueue_burst(struct rte_ring *r, void * const *obj_table,
unsigned int n, unsigned int *free_space)
{
return __rte_ring_do_enqueue(r, obj_table, n,
RTE_RING_QUEUE_VARIABLE, __IS_SP, free_space);
}
/**
* Enqueue several objects on a ring.
*
* This function calls the multi-producer or the single-producer
* version depending on the default behavior that was specified at
* ring creation time (see flags).
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects).
* @param n
* The number of objects to add in the ring from the obj_table.
* @param free_space
* if non-NULL, returns the amount of space in the ring after the
* enqueue operation has finished.
* @return
* - n: Actual number of objects enqueued.
*/
static __rte_always_inline unsigned
rte_ring_enqueue_burst(struct rte_ring *r, void * const *obj_table,
unsigned int n, unsigned int *free_space)
{
return __rte_ring_do_enqueue(r, obj_table, n, RTE_RING_QUEUE_VARIABLE,
r->prod.single, free_space);
}
/**
* Dequeue several objects from a ring (multi-consumers safe). When the request
* objects are more than the available objects, only dequeue the actual number
* of objects
*
* This function uses a "compare and set" instruction to move the
* consumer index atomically.
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects) that will be filled.
* @param n
* The number of objects to dequeue from the ring to the obj_table.
* @param available
* If non-NULL, returns the number of remaining ring entries after the
* dequeue has finished.
* @return
* - n: Actual number of objects dequeued, 0 if ring is empty
*/
static __rte_always_inline unsigned
rte_ring_mc_dequeue_burst(struct rte_ring *r, void **obj_table,
unsigned int n, unsigned int *available)
{
return __rte_ring_do_dequeue(r, obj_table, n,
RTE_RING_QUEUE_VARIABLE, __IS_MC, available);
}
/**
* Dequeue several objects from a ring (NOT multi-consumers safe).When the
* request objects are more than the available objects, only dequeue the
* actual number of objects
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects) that will be filled.
* @param n
* The number of objects to dequeue from the ring to the obj_table.
* @param available
* If non-NULL, returns the number of remaining ring entries after the
* dequeue has finished.
* @return
* - n: Actual number of objects dequeued, 0 if ring is empty
*/
static __rte_always_inline unsigned
rte_ring_sc_dequeue_burst(struct rte_ring *r, void **obj_table,
unsigned int n, unsigned int *available)
{
return __rte_ring_do_dequeue(r, obj_table, n,
RTE_RING_QUEUE_VARIABLE, __IS_SC, available);
}
/**
* Dequeue multiple objects from a ring up to a maximum number.
*
* This function calls the multi-consumers or the single-consumer
* version, depending on the default behaviour that was specified at
* ring creation time (see flags).
*
* @param r
* A pointer to the ring structure.
* @param obj_table
* A pointer to a table of void * pointers (objects) that will be filled.
* @param n
* The number of objects to dequeue from the ring to the obj_table.
* @param available
* If non-NULL, returns the number of remaining ring entries after the
* dequeue has finished.
* @return
* - Number of objects dequeued
*/
static __rte_always_inline unsigned
rte_ring_dequeue_burst(struct rte_ring *r, void **obj_table,
unsigned int n, unsigned int *available)
{
return __rte_ring_do_dequeue(r, obj_table, n,
RTE_RING_QUEUE_VARIABLE,
r->cons.single, available);
}
#ifdef __cplusplus
}
#endif
#endif /* _RTE_RING_H_ */