numam-dpdk/lib/eventdev/rte_eventdev.h
Volodymyr Fialko c1749bc5ee eventdev: introduce event cryptodev vector type
Introduce ability to aggregate crypto operations processed by event
crypto adapter into single event containing rte_event_vector whose event
type is RTE_EVENT_TYPE_CRYPTODEV_VECTOR.

Application should set RTE_EVENT_CRYPTO_ADAPTER_EVENT_VECTOR in
rte_event_crypto_adapter_queue_conf::flag and provide vector configuration
with respect of rte_event_crypto_adapter_vector_limits, which could be
obtained by calling rte_event_crypto_adapter_vector_limits_get, to enable
vectorization.

The event crypto adapter would be responsible for vectorizing the crypto
operations based on provided response information in
rte_event_crypto_metadata::response_info.

Updated drivers and tests accordingly to new API.

Signed-off-by: Volodymyr Fialko <vfialko@marvell.com>
Acked-by: Akhil Goyal <gakhil@marvell.com>
2022-10-02 20:33:24 +02:00

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/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2016 Cavium, Inc.
* Copyright(c) 2016-2018 Intel Corporation.
* Copyright 2016 NXP
* All rights reserved.
*/
#ifndef _RTE_EVENTDEV_H_
#define _RTE_EVENTDEV_H_
/**
* @file
*
* RTE Event Device API
*
* In a polling model, lcores poll ethdev ports and associated rx queues
* directly to look for packet. In an event driven model, by contrast, lcores
* call the scheduler that selects packets for them based on programmer
* specified criteria. Eventdev library adds support for event driven
* programming model, which offer applications automatic multicore scaling,
* dynamic load balancing, pipelining, packet ingress order maintenance and
* synchronization services to simplify application packet processing.
*
* The Event Device API is composed of two parts:
*
* - The application-oriented Event API that includes functions to setup
* an event device (configure it, setup its queues, ports and start it), to
* establish the link between queues to port and to receive events, and so on.
*
* - The driver-oriented Event API that exports a function allowing
* an event poll Mode Driver (PMD) to simultaneously register itself as
* an event device driver.
*
* Event device components:
*
* +-----------------+
* | +-------------+ |
* +-------+ | | flow 0 | |
* |Packet | | +-------------+ |
* |event | | +-------------+ |
* | | | | flow 1 | |port_link(port0, queue0)
* +-------+ | +-------------+ | | +--------+
* +-------+ | +-------------+ o-----v-----o |dequeue +------+
* |Crypto | | | flow n | | | event +------->|Core 0|
* |work | | +-------------+ o----+ | port 0 | | |
* |done ev| | event queue 0 | | +--------+ +------+
* +-------+ +-----------------+ |
* +-------+ |
* |Timer | +-----------------+ | +--------+
* |expiry | | +-------------+ | +------o |dequeue +------+
* |event | | | flow 0 | o-----------o event +------->|Core 1|
* +-------+ | +-------------+ | +----o port 1 | | |
* Event enqueue | +-------------+ | | +--------+ +------+
* o-------------> | | flow 1 | | |
* enqueue( | +-------------+ | |
* queue_id, | | | +--------+ +------+
* flow_id, | +-------------+ | | | |dequeue |Core 2|
* sched_type, | | flow n | o-----------o event +------->| |
* event_type, | +-------------+ | | | port 2 | +------+
* subev_type, | event queue 1 | | +--------+
* event) +-----------------+ | +--------+
* | | |dequeue +------+
* +-------+ +-----------------+ | | event +------->|Core n|
* |Core | | +-------------+ o-----------o port n | | |
* |(SW) | | | flow 0 | | | +--------+ +--+---+
* |event | | +-------------+ | | |
* +-------+ | +-------------+ | | |
* ^ | | flow 1 | | | |
* | | +-------------+ o------+ |
* | | +-------------+ | |
* | | | flow n | | |
* | | +-------------+ | |
* | | event queue n | |
* | +-----------------+ |
* | |
* +-----------------------------------------------------------+
*
* Event device: A hardware or software-based event scheduler.
*
* Event: A unit of scheduling that encapsulates a packet or other datatype
* like SW generated event from the CPU, Crypto work completion notification,
* Timer expiry event notification etc as well as metadata.
* The metadata includes flow ID, scheduling type, event priority, event_type,
* sub_event_type etc.
*
* Event queue: A queue containing events that are scheduled by the event dev.
* An event queue contains events of different flows associated with scheduling
* types, such as atomic, ordered, or parallel.
*
* Event port: An application's interface into the event dev for enqueue and
* dequeue operations. Each event port can be linked with one or more
* event queues for dequeue operations.
*
* By default, all the functions of the Event Device API exported by a PMD
* are lock-free functions which assume to not be invoked in parallel on
* different logical cores to work on the same target object. For instance,
* the dequeue function of a PMD cannot be invoked in parallel on two logical
* cores to operates on same event port. Of course, this function
* can be invoked in parallel by different logical cores on different ports.
* It is the responsibility of the upper level application to enforce this rule.
*
* In all functions of the Event API, the Event device is
* designated by an integer >= 0 named the device identifier *dev_id*
*
* At the Event driver level, Event devices are represented by a generic
* data structure of type *rte_event_dev*.
*
* Event devices are dynamically registered during the PCI/SoC device probing
* phase performed at EAL initialization time.
* When an Event device is being probed, a *rte_event_dev* structure and
* a new device identifier are allocated for that device. Then, the
* event_dev_init() function supplied by the Event driver matching the probed
* device is invoked to properly initialize the device.
*
* The role of the device init function consists of resetting the hardware or
* software event driver implementations.
*
* If the device init operation is successful, the correspondence between
* the device identifier assigned to the new device and its associated
* *rte_event_dev* structure is effectively registered.
* Otherwise, both the *rte_event_dev* structure and the device identifier are
* freed.
*
* The functions exported by the application Event API to setup a device
* designated by its device identifier must be invoked in the following order:
* - rte_event_dev_configure()
* - rte_event_queue_setup()
* - rte_event_port_setup()
* - rte_event_port_link()
* - rte_event_dev_start()
*
* Then, the application can invoke, in any order, the functions
* exported by the Event API to schedule events, dequeue events, enqueue events,
* change event queue(s) to event port [un]link establishment and so on.
*
* Application may use rte_event_[queue/port]_default_conf_get() to get the
* default configuration to set up an event queue or event port by
* overriding few default values.
*
* If the application wants to change the configuration (i.e. call
* rte_event_dev_configure(), rte_event_queue_setup(), or
* rte_event_port_setup()), it must call rte_event_dev_stop() first to stop the
* device and then do the reconfiguration before calling rte_event_dev_start()
* again. The schedule, enqueue and dequeue functions should not be invoked
* when the device is stopped.
*
* Finally, an application can close an Event device by invoking the
* rte_event_dev_close() function.
*
* Each function of the application Event API invokes a specific function
* of the PMD that controls the target device designated by its device
* identifier.
*
* For this purpose, all device-specific functions of an Event driver are
* supplied through a set of pointers contained in a generic structure of type
* *event_dev_ops*.
* The address of the *event_dev_ops* structure is stored in the *rte_event_dev*
* structure by the device init function of the Event driver, which is
* invoked during the PCI/SoC device probing phase, as explained earlier.
*
* In other words, each function of the Event API simply retrieves the
* *rte_event_dev* structure associated with the device identifier and
* performs an indirect invocation of the corresponding driver function
* supplied in the *event_dev_ops* structure of the *rte_event_dev* structure.
*
* For performance reasons, the address of the fast-path functions of the
* Event driver is not contained in the *event_dev_ops* structure.
* Instead, they are directly stored at the beginning of the *rte_event_dev*
* structure to avoid an extra indirect memory access during their invocation.
*
* RTE event device drivers do not use interrupts for enqueue or dequeue
* operation. Instead, Event drivers export Poll-Mode enqueue and dequeue
* functions to applications.
*
* The events are injected to event device through *enqueue* operation by
* event producers in the system. The typical event producers are ethdev
* subsystem for generating packet events, CPU(SW) for generating events based
* on different stages of application processing, cryptodev for generating
* crypto work completion notification etc
*
* The *dequeue* operation gets one or more events from the event ports.
* The application process the events and send to downstream event queue through
* rte_event_enqueue_burst() if it is an intermediate stage of event processing,
* on the final stage, the application may use Tx adapter API for maintaining
* the ingress order and then send the packet/event on the wire.
*
* The point at which events are scheduled to ports depends on the device.
* For hardware devices, scheduling occurs asynchronously without any software
* intervention. Software schedulers can either be distributed
* (each worker thread schedules events to its own port) or centralized
* (a dedicated thread schedules to all ports). Distributed software schedulers
* perform the scheduling in rte_event_dequeue_burst(), whereas centralized
* scheduler logic need a dedicated service core for scheduling.
* The RTE_EVENT_DEV_CAP_DISTRIBUTED_SCHED capability flag is not set
* indicates the device is centralized and thus needs a dedicated scheduling
* thread that repeatedly calls software specific scheduling function.
*
* An event driven worker thread has following typical workflow on fastpath:
* \code{.c}
* while (1) {
* rte_event_dequeue_burst(...);
* (event processing)
* rte_event_enqueue_burst(...);
* }
* \endcode
*
*/
#ifdef __cplusplus
extern "C" {
#endif
#include <rte_common.h>
#include <rte_errno.h>
#include <rte_mbuf_pool_ops.h>
#include <rte_mempool.h>
#include "rte_eventdev_trace_fp.h"
struct rte_mbuf; /* we just use mbuf pointers; no need to include rte_mbuf.h */
struct rte_event;
/* Event device capability bitmap flags */
#define RTE_EVENT_DEV_CAP_QUEUE_QOS (1ULL << 0)
/**< Event scheduling prioritization is based on the priority and weight
* associated with each event queue. Events from a queue with highest priority
* is scheduled first. If the queues are of same priority, weight of the queues
* are considered to select a queue in a weighted round robin fashion.
* Subsequent dequeue calls from an event port could see events from the same
* event queue, if the queue is configured with an affinity count. Affinity
* count is the number of subsequent dequeue calls, in which an event port
* should use the same event queue if the queue is non-empty
*
* @see rte_event_queue_setup(), rte_event_queue_attr_set()
*/
#define RTE_EVENT_DEV_CAP_EVENT_QOS (1ULL << 1)
/**< Event scheduling prioritization is based on the priority associated with
* each event. Priority of each event is supplied in *rte_event* structure
* on each enqueue operation.
*
* @see rte_event_enqueue_burst()
*/
#define RTE_EVENT_DEV_CAP_DISTRIBUTED_SCHED (1ULL << 2)
/**< Event device operates in distributed scheduling mode.
* In distributed scheduling mode, event scheduling happens in HW or
* rte_event_dequeue_burst() or the combination of these two.
* If the flag is not set then eventdev is centralized and thus needs a
* dedicated service core that acts as a scheduling thread .
*
* @see rte_event_dequeue_burst()
*/
#define RTE_EVENT_DEV_CAP_QUEUE_ALL_TYPES (1ULL << 3)
/**< Event device is capable of enqueuing events of any type to any queue.
* If this capability is not set, the queue only supports events of the
* *RTE_SCHED_TYPE_* type that it was created with.
*
* @see RTE_SCHED_TYPE_* values
*/
#define RTE_EVENT_DEV_CAP_BURST_MODE (1ULL << 4)
/**< Event device is capable of operating in burst mode for enqueue(forward,
* release) and dequeue operation. If this capability is not set, application
* still uses the rte_event_dequeue_burst() and rte_event_enqueue_burst() but
* PMD accepts only one event at a time.
*
* @see rte_event_dequeue_burst() rte_event_enqueue_burst()
*/
#define RTE_EVENT_DEV_CAP_IMPLICIT_RELEASE_DISABLE (1ULL << 5)
/**< Event device ports support disabling the implicit release feature, in
* which the port will release all unreleased events in its dequeue operation.
* If this capability is set and the port is configured with implicit release
* disabled, the application is responsible for explicitly releasing events
* using either the RTE_EVENT_OP_FORWARD or the RTE_EVENT_OP_RELEASE event
* enqueue operations.
*
* @see rte_event_dequeue_burst() rte_event_enqueue_burst()
*/
#define RTE_EVENT_DEV_CAP_NONSEQ_MODE (1ULL << 6)
/**< Event device is capable of operating in none sequential mode. The path
* of the event is not necessary to be sequential. Application can change
* the path of event at runtime. If the flag is not set, then event each event
* will follow a path from queue 0 to queue 1 to queue 2 etc. If the flag is
* set, events may be sent to queues in any order. If the flag is not set, the
* eventdev will return an error when the application enqueues an event for a
* qid which is not the next in the sequence.
*/
#define RTE_EVENT_DEV_CAP_RUNTIME_PORT_LINK (1ULL << 7)
/**< Event device is capable of configuring the queue/port link at runtime.
* If the flag is not set, the eventdev queue/port link is only can be
* configured during initialization.
*/
#define RTE_EVENT_DEV_CAP_MULTIPLE_QUEUE_PORT (1ULL << 8)
/**< Event device is capable of setting up the link between multiple queue
* with single port. If the flag is not set, the eventdev can only map a
* single queue to each port or map a single queue to many port.
*/
#define RTE_EVENT_DEV_CAP_CARRY_FLOW_ID (1ULL << 9)
/**< Event device preserves the flow ID from the enqueued
* event to the dequeued event if the flag is set. Otherwise,
* the content of this field is implementation dependent.
*/
#define RTE_EVENT_DEV_CAP_MAINTENANCE_FREE (1ULL << 10)
/**< Event device *does not* require calls to rte_event_maintain().
* An event device that does not set this flag requires calls to
* rte_event_maintain() during periods when neither
* rte_event_dequeue_burst() nor rte_event_enqueue_burst() are called
* on a port. This will allow the event device to perform internal
* processing, such as flushing buffered events, return credits to a
* global pool, or process signaling related to load balancing.
*/
#define RTE_EVENT_DEV_CAP_RUNTIME_QUEUE_ATTR (1ULL << 11)
/**< Event device is capable of changing the queue attributes at runtime i.e
* after rte_event_queue_setup() or rte_event_start() call sequence. If this
* flag is not set, eventdev queue attributes can only be configured during
* rte_event_queue_setup().
*/
/* Event device priority levels */
#define RTE_EVENT_DEV_PRIORITY_HIGHEST 0
/**< Highest priority expressed across eventdev subsystem
* @see rte_event_queue_setup(), rte_event_enqueue_burst()
* @see rte_event_port_link()
*/
#define RTE_EVENT_DEV_PRIORITY_NORMAL 128
/**< Normal priority expressed across eventdev subsystem
* @see rte_event_queue_setup(), rte_event_enqueue_burst()
* @see rte_event_port_link()
*/
#define RTE_EVENT_DEV_PRIORITY_LOWEST 255
/**< Lowest priority expressed across eventdev subsystem
* @see rte_event_queue_setup(), rte_event_enqueue_burst()
* @see rte_event_port_link()
*/
/* Event queue scheduling weights */
#define RTE_EVENT_QUEUE_WEIGHT_HIGHEST 255
/**< Highest weight of an event queue
* @see rte_event_queue_attr_get(), rte_event_queue_attr_set()
*/
#define RTE_EVENT_QUEUE_WEIGHT_LOWEST 0
/**< Lowest weight of an event queue
* @see rte_event_queue_attr_get(), rte_event_queue_attr_set()
*/
/* Event queue scheduling affinity */
#define RTE_EVENT_QUEUE_AFFINITY_HIGHEST 255
/**< Highest scheduling affinity of an event queue
* @see rte_event_queue_attr_get(), rte_event_queue_attr_set()
*/
#define RTE_EVENT_QUEUE_AFFINITY_LOWEST 0
/**< Lowest scheduling affinity of an event queue
* @see rte_event_queue_attr_get(), rte_event_queue_attr_set()
*/
/**
* Get the total number of event devices that have been successfully
* initialised.
*
* @return
* The total number of usable event devices.
*/
uint8_t
rte_event_dev_count(void);
/**
* Get the device identifier for the named event device.
*
* @param name
* Event device name to select the event device identifier.
*
* @return
* Returns event device identifier on success.
* - <0: Failure to find named event device.
*/
int
rte_event_dev_get_dev_id(const char *name);
/**
* Return the NUMA socket to which a device is connected.
*
* @param dev_id
* The identifier of the device.
* @return
* The NUMA socket id to which the device is connected or
* a default of zero if the socket could not be determined.
* -(-EINVAL) dev_id value is out of range.
*/
int
rte_event_dev_socket_id(uint8_t dev_id);
/**
* Event device information
*/
struct rte_event_dev_info {
const char *driver_name; /**< Event driver name */
struct rte_device *dev; /**< Device information */
uint32_t min_dequeue_timeout_ns;
/**< Minimum supported global dequeue timeout(ns) by this device */
uint32_t max_dequeue_timeout_ns;
/**< Maximum supported global dequeue timeout(ns) by this device */
uint32_t dequeue_timeout_ns;
/**< Configured global dequeue timeout(ns) for this device */
uint8_t max_event_queues;
/**< Maximum event_queues supported by this device */
uint32_t max_event_queue_flows;
/**< Maximum supported flows in an event queue by this device*/
uint8_t max_event_queue_priority_levels;
/**< Maximum number of event queue priority levels by this device.
* Valid when the device has RTE_EVENT_DEV_CAP_QUEUE_QOS capability
*/
uint8_t max_event_priority_levels;
/**< Maximum number of event priority levels by this device.
* Valid when the device has RTE_EVENT_DEV_CAP_EVENT_QOS capability
*/
uint8_t max_event_ports;
/**< Maximum number of event ports supported by this device */
uint8_t max_event_port_dequeue_depth;
/**< Maximum number of events can be dequeued at a time from an
* event port by this device.
* A device that does not support bulk dequeue will set this as 1.
*/
uint32_t max_event_port_enqueue_depth;
/**< Maximum number of events can be enqueued at a time from an
* event port by this device.
* A device that does not support bulk enqueue will set this as 1.
*/
uint8_t max_event_port_links;
/**< Maximum number of queues that can be linked to a single event
* port by this device.
*/
int32_t max_num_events;
/**< A *closed system* event dev has a limit on the number of events it
* can manage at a time. An *open system* event dev does not have a
* limit and will specify this as -1.
*/
uint32_t event_dev_cap;
/**< Event device capabilities(RTE_EVENT_DEV_CAP_)*/
uint8_t max_single_link_event_port_queue_pairs;
/**< Maximum number of event ports and queues that are optimized for
* (and only capable of) single-link configurations supported by this
* device. These ports and queues are not accounted for in
* max_event_ports or max_event_queues.
*/
};
/**
* Retrieve the contextual information of an event device.
*
* @param dev_id
* The identifier of the device.
*
* @param[out] dev_info
* A pointer to a structure of type *rte_event_dev_info* to be filled with the
* contextual information of the device.
*
* @return
* - 0: Success, driver updates the contextual information of the event device
* - <0: Error code returned by the driver info get function.
*
*/
int
rte_event_dev_info_get(uint8_t dev_id, struct rte_event_dev_info *dev_info);
/**
* The count of ports.
*/
#define RTE_EVENT_DEV_ATTR_PORT_COUNT 0
/**
* The count of queues.
*/
#define RTE_EVENT_DEV_ATTR_QUEUE_COUNT 1
/**
* The status of the device, zero for stopped, non-zero for started.
*/
#define RTE_EVENT_DEV_ATTR_STARTED 2
/**
* Get an attribute from a device.
*
* @param dev_id Eventdev id
* @param attr_id The attribute ID to retrieve
* @param[out] attr_value A pointer that will be filled in with the attribute
* value if successful.
*
* @return
* - 0: Successfully retrieved attribute value
* - -EINVAL: Invalid device or *attr_id* provided, or *attr_value* is NULL
*/
int
rte_event_dev_attr_get(uint8_t dev_id, uint32_t attr_id,
uint32_t *attr_value);
/* Event device configuration bitmap flags */
#define RTE_EVENT_DEV_CFG_PER_DEQUEUE_TIMEOUT (1ULL << 0)
/**< Override the global *dequeue_timeout_ns* and use per dequeue timeout in ns.
* @see rte_event_dequeue_timeout_ticks(), rte_event_dequeue_burst()
*/
/** Event device configuration structure */
struct rte_event_dev_config {
uint32_t dequeue_timeout_ns;
/**< rte_event_dequeue_burst() timeout on this device.
* This value should be in the range of *min_dequeue_timeout_ns* and
* *max_dequeue_timeout_ns* which previously provided in
* rte_event_dev_info_get()
* The value 0 is allowed, in which case, default dequeue timeout used.
* @see RTE_EVENT_DEV_CFG_PER_DEQUEUE_TIMEOUT
*/
int32_t nb_events_limit;
/**< In a *closed system* this field is the limit on maximum number of
* events that can be inflight in the eventdev at a given time. The
* limit is required to ensure that the finite space in a closed system
* is not overwhelmed. The value cannot exceed the *max_num_events*
* as provided by rte_event_dev_info_get().
* This value should be set to -1 for *open system*.
*/
uint8_t nb_event_queues;
/**< Number of event queues to configure on this device.
* This value cannot exceed the *max_event_queues* which previously
* provided in rte_event_dev_info_get()
*/
uint8_t nb_event_ports;
/**< Number of event ports to configure on this device.
* This value cannot exceed the *max_event_ports* which previously
* provided in rte_event_dev_info_get()
*/
uint32_t nb_event_queue_flows;
/**< Number of flows for any event queue on this device.
* This value cannot exceed the *max_event_queue_flows* which previously
* provided in rte_event_dev_info_get()
*/
uint32_t nb_event_port_dequeue_depth;
/**< Maximum number of events can be dequeued at a time from an
* event port by this device.
* This value cannot exceed the *max_event_port_dequeue_depth*
* which previously provided in rte_event_dev_info_get().
* Ignored when device is not RTE_EVENT_DEV_CAP_BURST_MODE capable.
* @see rte_event_port_setup()
*/
uint32_t nb_event_port_enqueue_depth;
/**< Maximum number of events can be enqueued at a time from an
* event port by this device.
* This value cannot exceed the *max_event_port_enqueue_depth*
* which previously provided in rte_event_dev_info_get().
* Ignored when device is not RTE_EVENT_DEV_CAP_BURST_MODE capable.
* @see rte_event_port_setup()
*/
uint32_t event_dev_cfg;
/**< Event device config flags(RTE_EVENT_DEV_CFG_)*/
uint8_t nb_single_link_event_port_queues;
/**< Number of event ports and queues that will be singly-linked to
* each other. These are a subset of the overall event ports and
* queues; this value cannot exceed *nb_event_ports* or
* *nb_event_queues*. If the device has ports and queues that are
* optimized for single-link usage, this field is a hint for how many
* to allocate; otherwise, regular event ports and queues can be used.
*/
};
/**
* Configure an event device.
*
* This function must be invoked first before any other function in the
* API. This function can also be re-invoked when a device is in the
* stopped state.
*
* The caller may use rte_event_dev_info_get() to get the capability of each
* resources available for this event device.
*
* @param dev_id
* The identifier of the device to configure.
* @param dev_conf
* The event device configuration structure.
*
* @return
* - 0: Success, device configured.
* - <0: Error code returned by the driver configuration function.
*/
int
rte_event_dev_configure(uint8_t dev_id,
const struct rte_event_dev_config *dev_conf);
/* Event queue specific APIs */
/* Event queue configuration bitmap flags */
#define RTE_EVENT_QUEUE_CFG_ALL_TYPES (1ULL << 0)
/**< Allow ATOMIC,ORDERED,PARALLEL schedule type enqueue
*
* @see RTE_SCHED_TYPE_ORDERED, RTE_SCHED_TYPE_ATOMIC, RTE_SCHED_TYPE_PARALLEL
* @see rte_event_enqueue_burst()
*/
#define RTE_EVENT_QUEUE_CFG_SINGLE_LINK (1ULL << 1)
/**< This event queue links only to a single event port.
*
* @see rte_event_port_setup(), rte_event_port_link()
*/
/** Event queue configuration structure */
struct rte_event_queue_conf {
uint32_t nb_atomic_flows;
/**< The maximum number of active flows this queue can track at any
* given time. If the queue is configured for atomic scheduling (by
* applying the RTE_EVENT_QUEUE_CFG_ALL_TYPES flag to event_queue_cfg
* or RTE_SCHED_TYPE_ATOMIC flag to schedule_type), then the
* value must be in the range of [1, nb_event_queue_flows], which was
* previously provided in rte_event_dev_configure().
*/
uint32_t nb_atomic_order_sequences;
/**< The maximum number of outstanding events waiting to be
* reordered by this queue. In other words, the number of entries in
* this queues reorder buffer.When the number of events in the
* reorder buffer reaches to *nb_atomic_order_sequences* then the
* scheduler cannot schedule the events from this queue and invalid
* event will be returned from dequeue until one or more entries are
* freed up/released.
* If the queue is configured for ordered scheduling (by applying the
* RTE_EVENT_QUEUE_CFG_ALL_TYPES flag to event_queue_cfg or
* RTE_SCHED_TYPE_ORDERED flag to schedule_type), then the value must
* be in the range of [1, nb_event_queue_flows], which was
* previously supplied to rte_event_dev_configure().
*/
uint32_t event_queue_cfg;
/**< Queue cfg flags(EVENT_QUEUE_CFG_) */
uint8_t schedule_type;
/**< Queue schedule type(RTE_SCHED_TYPE_*).
* Valid when RTE_EVENT_QUEUE_CFG_ALL_TYPES bit is not set in
* event_queue_cfg.
*/
uint8_t priority;
/**< Priority for this event queue relative to other event queues.
* The requested priority should in the range of
* [RTE_EVENT_DEV_PRIORITY_HIGHEST, RTE_EVENT_DEV_PRIORITY_LOWEST].
* The implementation shall normalize the requested priority to
* event device supported priority value.
* Valid when the device has RTE_EVENT_DEV_CAP_QUEUE_QOS capability
*/
uint8_t weight;
/**< Weight of the event queue relative to other event queues.
* The requested weight should be in the range of
* [RTE_EVENT_DEV_WEIGHT_HIGHEST, RTE_EVENT_DEV_WEIGHT_LOWEST].
* The implementation shall normalize the requested weight to event
* device supported weight value.
* Valid when the device has RTE_EVENT_DEV_CAP_QUEUE_QOS capability.
*/
uint8_t affinity;
/**< Affinity of the event queue relative to other event queues.
* The requested affinity should be in the range of
* [RTE_EVENT_DEV_AFFINITY_HIGHEST, RTE_EVENT_DEV_AFFINITY_LOWEST].
* The implementation shall normalize the requested affinity to event
* device supported affinity value.
* Valid when the device has RTE_EVENT_DEV_CAP_QUEUE_QOS capability.
*/
};
/**
* Retrieve the default configuration information of an event queue designated
* by its *queue_id* from the event driver for an event device.
*
* This function intended to be used in conjunction with rte_event_queue_setup()
* where caller needs to set up the queue by overriding few default values.
*
* @param dev_id
* The identifier of the device.
* @param queue_id
* The index of the event queue to get the configuration information.
* The value must be in the range [0, nb_event_queues - 1]
* previously supplied to rte_event_dev_configure().
* @param[out] queue_conf
* The pointer to the default event queue configuration data.
* @return
* - 0: Success, driver updates the default event queue configuration data.
* - <0: Error code returned by the driver info get function.
*
* @see rte_event_queue_setup()
*
*/
int
rte_event_queue_default_conf_get(uint8_t dev_id, uint8_t queue_id,
struct rte_event_queue_conf *queue_conf);
/**
* Allocate and set up an event queue for an event device.
*
* @param dev_id
* The identifier of the device.
* @param queue_id
* The index of the event queue to setup. The value must be in the range
* [0, nb_event_queues - 1] previously supplied to rte_event_dev_configure().
* @param queue_conf
* The pointer to the configuration data to be used for the event queue.
* NULL value is allowed, in which case default configuration used.
*
* @see rte_event_queue_default_conf_get()
*
* @return
* - 0: Success, event queue correctly set up.
* - <0: event queue configuration failed
*/
int
rte_event_queue_setup(uint8_t dev_id, uint8_t queue_id,
const struct rte_event_queue_conf *queue_conf);
/**
* The priority of the queue.
*/
#define RTE_EVENT_QUEUE_ATTR_PRIORITY 0
/**
* The number of atomic flows configured for the queue.
*/
#define RTE_EVENT_QUEUE_ATTR_NB_ATOMIC_FLOWS 1
/**
* The number of atomic order sequences configured for the queue.
*/
#define RTE_EVENT_QUEUE_ATTR_NB_ATOMIC_ORDER_SEQUENCES 2
/**
* The cfg flags for the queue.
*/
#define RTE_EVENT_QUEUE_ATTR_EVENT_QUEUE_CFG 3
/**
* The schedule type of the queue.
*/
#define RTE_EVENT_QUEUE_ATTR_SCHEDULE_TYPE 4
/**
* The weight of the queue.
*/
#define RTE_EVENT_QUEUE_ATTR_WEIGHT 5
/**
* Affinity of the queue.
*/
#define RTE_EVENT_QUEUE_ATTR_AFFINITY 6
/**
* Get an attribute from a queue.
*
* @param dev_id
* Eventdev id
* @param queue_id
* Eventdev queue id
* @param attr_id
* The attribute ID to retrieve
* @param[out] attr_value
* A pointer that will be filled in with the attribute value if successful
*
* @return
* - 0: Successfully returned value
* - -EINVAL: invalid device, queue or attr_id provided, or attr_value was
* NULL
* - -EOVERFLOW: returned when attr_id is set to
* RTE_EVENT_QUEUE_ATTR_SCHEDULE_TYPE and event_queue_cfg is set to
* RTE_EVENT_QUEUE_CFG_ALL_TYPES
*/
int
rte_event_queue_attr_get(uint8_t dev_id, uint8_t queue_id, uint32_t attr_id,
uint32_t *attr_value);
/**
* Set an event queue attribute.
*
* @param dev_id
* Eventdev id
* @param queue_id
* Eventdev queue id
* @param attr_id
* The attribute ID to set
* @param attr_value
* The attribute value to set
*
* @return
* - 0: Successfully set attribute.
* - -EINVAL: invalid device, queue or attr_id.
* - -ENOTSUP: device does not support setting the event attribute.
* - <0: failed to set event queue attribute
*/
__rte_experimental
int
rte_event_queue_attr_set(uint8_t dev_id, uint8_t queue_id, uint32_t attr_id,
uint64_t attr_value);
/* Event port specific APIs */
/* Event port configuration bitmap flags */
#define RTE_EVENT_PORT_CFG_DISABLE_IMPL_REL (1ULL << 0)
/**< Configure the port not to release outstanding events in
* rte_event_dev_dequeue_burst(). If set, all events received through
* the port must be explicitly released with RTE_EVENT_OP_RELEASE or
* RTE_EVENT_OP_FORWARD. Must be unset if the device is not
* RTE_EVENT_DEV_CAP_IMPLICIT_RELEASE_DISABLE capable.
*/
#define RTE_EVENT_PORT_CFG_SINGLE_LINK (1ULL << 1)
/**< This event port links only to a single event queue.
*
* @see rte_event_port_setup(), rte_event_port_link()
*/
#define RTE_EVENT_PORT_CFG_HINT_PRODUCER (1ULL << 2)
/**< Hint that this event port will primarily enqueue events to the system.
* A PMD can optimize its internal workings by assuming that this port is
* primarily going to enqueue NEW events.
*
* Note that this flag is only a hint, so PMDs must operate under the
* assumption that any port can enqueue an event with any type of op.
*
* @see rte_event_port_setup()
*/
#define RTE_EVENT_PORT_CFG_HINT_CONSUMER (1ULL << 3)
/**< Hint that this event port will primarily dequeue events from the system.
* A PMD can optimize its internal workings by assuming that this port is
* primarily going to consume events, and not enqueue FORWARD or RELEASE
* events.
*
* Note that this flag is only a hint, so PMDs must operate under the
* assumption that any port can enqueue an event with any type of op.
*
* @see rte_event_port_setup()
*/
#define RTE_EVENT_PORT_CFG_HINT_WORKER (1ULL << 4)
/**< Hint that this event port will primarily pass existing events through.
* A PMD can optimize its internal workings by assuming that this port is
* primarily going to FORWARD events, and not enqueue NEW or RELEASE events
* often.
*
* Note that this flag is only a hint, so PMDs must operate under the
* assumption that any port can enqueue an event with any type of op.
*
* @see rte_event_port_setup()
*/
/** Event port configuration structure */
struct rte_event_port_conf {
int32_t new_event_threshold;
/**< A backpressure threshold for new event enqueues on this port.
* Use for *closed system* event dev where event capacity is limited,
* and cannot exceed the capacity of the event dev.
* Configuring ports with different thresholds can make higher priority
* traffic less likely to be backpressured.
* For example, a port used to inject NIC Rx packets into the event dev
* can have a lower threshold so as not to overwhelm the device,
* while ports used for worker pools can have a higher threshold.
* This value cannot exceed the *nb_events_limit*
* which was previously supplied to rte_event_dev_configure().
* This should be set to '-1' for *open system*.
*/
uint16_t dequeue_depth;
/**< Configure number of bulk dequeues for this event port.
* This value cannot exceed the *nb_event_port_dequeue_depth*
* which previously supplied to rte_event_dev_configure().
* Ignored when device is not RTE_EVENT_DEV_CAP_BURST_MODE capable.
*/
uint16_t enqueue_depth;
/**< Configure number of bulk enqueues for this event port.
* This value cannot exceed the *nb_event_port_enqueue_depth*
* which previously supplied to rte_event_dev_configure().
* Ignored when device is not RTE_EVENT_DEV_CAP_BURST_MODE capable.
*/
uint32_t event_port_cfg; /**< Port cfg flags(EVENT_PORT_CFG_) */
};
/**
* Retrieve the default configuration information of an event port designated
* by its *port_id* from the event driver for an event device.
*
* This function intended to be used in conjunction with rte_event_port_setup()
* where caller needs to set up the port by overriding few default values.
*
* @param dev_id
* The identifier of the device.
* @param port_id
* The index of the event port to get the configuration information.
* The value must be in the range [0, nb_event_ports - 1]
* previously supplied to rte_event_dev_configure().
* @param[out] port_conf
* The pointer to the default event port configuration data
* @return
* - 0: Success, driver updates the default event port configuration data.
* - <0: Error code returned by the driver info get function.
*
* @see rte_event_port_setup()
*
*/
int
rte_event_port_default_conf_get(uint8_t dev_id, uint8_t port_id,
struct rte_event_port_conf *port_conf);
/**
* Allocate and set up an event port for an event device.
*
* @param dev_id
* The identifier of the device.
* @param port_id
* The index of the event port to setup. The value must be in the range
* [0, nb_event_ports - 1] previously supplied to rte_event_dev_configure().
* @param port_conf
* The pointer to the configuration data to be used for the queue.
* NULL value is allowed, in which case default configuration used.
*
* @see rte_event_port_default_conf_get()
*
* @return
* - 0: Success, event port correctly set up.
* - <0: Port configuration failed
* - (-EDQUOT) Quota exceeded(Application tried to link the queue configured
* with RTE_EVENT_QUEUE_CFG_SINGLE_LINK to more than one event ports)
*/
int
rte_event_port_setup(uint8_t dev_id, uint8_t port_id,
const struct rte_event_port_conf *port_conf);
typedef void (*rte_eventdev_port_flush_t)(uint8_t dev_id,
struct rte_event event, void *arg);
/**< Callback function prototype that can be passed during
* rte_event_port_release(), invoked once per a released event.
*/
/**
* Quiesce any core specific resources consumed by the event port.
*
* Event ports are generally coupled with lcores, and a given Hardware
* implementation might require the PMD to store port specific data in the
* lcore.
* When the application decides to migrate the event port to another lcore
* or teardown the current lcore it may to call `rte_event_port_quiesce`
* to make sure that all the data associated with the event port are released
* from the lcore, this might also include any prefetched events.
* While releasing the event port from the lcore, this function calls the
* user-provided flush callback once per event.
*
* @note Invocation of this API does not affect the existing port configuration.
*
* @param dev_id
* The identifier of the device.
* @param port_id
* The index of the event port to setup. The value must be in the range
* [0, nb_event_ports - 1] previously supplied to rte_event_dev_configure().
* @param release_cb
* Callback function invoked once per flushed event.
* @param args
* Argument supplied to callback.
*/
__rte_experimental
void
rte_event_port_quiesce(uint8_t dev_id, uint8_t port_id,
rte_eventdev_port_flush_t release_cb, void *args);
/**
* The queue depth of the port on the enqueue side
*/
#define RTE_EVENT_PORT_ATTR_ENQ_DEPTH 0
/**
* The queue depth of the port on the dequeue side
*/
#define RTE_EVENT_PORT_ATTR_DEQ_DEPTH 1
/**
* The new event threshold of the port
*/
#define RTE_EVENT_PORT_ATTR_NEW_EVENT_THRESHOLD 2
/**
* The implicit release disable attribute of the port
*/
#define RTE_EVENT_PORT_ATTR_IMPLICIT_RELEASE_DISABLE 3
/**
* Get an attribute from a port.
*
* @param dev_id
* Eventdev id
* @param port_id
* Eventdev port id
* @param attr_id
* The attribute ID to retrieve
* @param[out] attr_value
* A pointer that will be filled in with the attribute value if successful
*
* @return
* - 0: Successfully returned value
* - (-EINVAL) Invalid device, port or attr_id, or attr_value was NULL
*/
int
rte_event_port_attr_get(uint8_t dev_id, uint8_t port_id, uint32_t attr_id,
uint32_t *attr_value);
/**
* Start an event device.
*
* The device start step is the last one and consists of setting the event
* queues to start accepting the events and schedules to event ports.
*
* On success, all basic functions exported by the API (event enqueue,
* event dequeue and so on) can be invoked.
*
* @param dev_id
* Event device identifier
* @return
* - 0: Success, device started.
* - -ESTALE : Not all ports of the device are configured
* - -ENOLINK: Not all queues are linked, which could lead to deadlock.
*/
int
rte_event_dev_start(uint8_t dev_id);
/**
* Stop an event device.
*
* This function causes all queued events to be drained, including those
* residing in event ports. While draining events out of the device, this
* function calls the user-provided flush callback (if one was registered) once
* per event.
*
* The device can be restarted with a call to rte_event_dev_start(). Threads
* that continue to enqueue/dequeue while the device is stopped, or being
* stopped, will result in undefined behavior. This includes event adapters,
* which must be stopped prior to stopping the eventdev.
*
* @param dev_id
* Event device identifier.
*
* @see rte_event_dev_stop_flush_callback_register()
*/
void
rte_event_dev_stop(uint8_t dev_id);
typedef void (*rte_eventdev_stop_flush_t)(uint8_t dev_id,
struct rte_event event, void *arg);
/**< Callback function called during rte_event_dev_stop(), invoked once per
* flushed event.
*/
/**
* Registers a callback function to be invoked during rte_event_dev_stop() for
* each flushed event. This function can be used to properly dispose of queued
* events, for example events containing memory pointers.
*
* The callback function is only registered for the calling process. The
* callback function must be registered in every process that can call
* rte_event_dev_stop().
*
* To unregister a callback, call this function with a NULL callback pointer.
*
* @param dev_id
* The identifier of the device.
* @param callback
* Callback function invoked once per flushed event.
* @param userdata
* Argument supplied to callback.
*
* @return
* - 0 on success.
* - -EINVAL if *dev_id* is invalid
*
* @see rte_event_dev_stop()
*/
int rte_event_dev_stop_flush_callback_register(uint8_t dev_id,
rte_eventdev_stop_flush_t callback, void *userdata);
/**
* Close an event device. The device cannot be restarted!
*
* @param dev_id
* Event device identifier
*
* @return
* - 0 on successfully closing device
* - <0 on failure to close device
* - (-EAGAIN) if device is busy
*/
int
rte_event_dev_close(uint8_t dev_id);
/**
* Event vector structure.
*/
struct rte_event_vector {
uint16_t nb_elem;
/**< Number of elements valid in this event vector. */
uint16_t elem_offset : 12;
/**< Offset into the vector array where valid elements start from. */
uint16_t rsvd : 3;
/**< Reserved for future use */
uint16_t attr_valid : 1;
/**< Indicates that the below union attributes have valid information.
*/
union {
/* Used by Rx/Tx adapter.
* Indicates that all the elements in this vector belong to the
* same port and queue pair when originating from Rx adapter,
* valid only when event type is ETHDEV_VECTOR or
* ETH_RX_ADAPTER_VECTOR.
* Can also be used to indicate the Tx adapter the destination
* port and queue of the mbufs in the vector
*/
struct {
uint16_t port;
/* Ethernet device port id. */
uint16_t queue;
/* Ethernet device queue id. */
};
};
/**< Union to hold common attributes of the vector array. */
uint64_t impl_opaque;
/* empty structures do not have zero size in C++ leading to compilation errors
* with clang about structure having different sizes in C and C++.
* Since these are all zero-sized arrays, we can omit the "union" wrapper for
* C++ builds, removing the warning.
*/
#ifndef __cplusplus
/**< Implementation specific opaque value.
* An implementation may use this field to hold implementation specific
* value to share between dequeue and enqueue operation.
* The application should not modify this field.
*/
union {
#endif
struct rte_mbuf *mbufs[0];
void *ptrs[0];
uint64_t u64s[0];
#ifndef __cplusplus
} __rte_aligned(16);
#endif
/**< Start of the vector array union. Depending upon the event type the
* vector array can be an array of mbufs or pointers or opaque u64
* values.
*/
} __rte_aligned(16);
/* Scheduler type definitions */
#define RTE_SCHED_TYPE_ORDERED 0
/**< Ordered scheduling
*
* Events from an ordered flow of an event queue can be scheduled to multiple
* ports for concurrent processing while maintaining the original event order.
* This scheme enables the user to achieve high single flow throughput by
* avoiding SW synchronization for ordering between ports which bound to cores.
*
* The source flow ordering from an event queue is maintained when events are
* enqueued to their destination queue within the same ordered flow context.
* An event port holds the context until application call
* rte_event_dequeue_burst() from the same port, which implicitly releases
* the context.
* User may allow the scheduler to release the context earlier than that
* by invoking rte_event_enqueue_burst() with RTE_EVENT_OP_RELEASE operation.
*
* Events from the source queue appear in their original order when dequeued
* from a destination queue.
* Event ordering is based on the received event(s), but also other
* (newly allocated or stored) events are ordered when enqueued within the same
* ordered context. Events not enqueued (e.g. released or stored) within the
* context are considered missing from reordering and are skipped at this time
* (but can be ordered again within another context).
*
* @see rte_event_queue_setup(), rte_event_dequeue_burst(), RTE_EVENT_OP_RELEASE
*/
#define RTE_SCHED_TYPE_ATOMIC 1
/**< Atomic scheduling
*
* Events from an atomic flow of an event queue can be scheduled only to a
* single port at a time. The port is guaranteed to have exclusive (atomic)
* access to the associated flow context, which enables the user to avoid SW
* synchronization. Atomic flows also help to maintain event ordering
* since only one port at a time can process events from a flow of an
* event queue.
*
* The atomic queue synchronization context is dedicated to the port until
* application call rte_event_dequeue_burst() from the same port,
* which implicitly releases the context. User may allow the scheduler to
* release the context earlier than that by invoking rte_event_enqueue_burst()
* with RTE_EVENT_OP_RELEASE operation.
*
* @see rte_event_queue_setup(), rte_event_dequeue_burst(), RTE_EVENT_OP_RELEASE
*/
#define RTE_SCHED_TYPE_PARALLEL 2
/**< Parallel scheduling
*
* The scheduler performs priority scheduling, load balancing, etc. functions
* but does not provide additional event synchronization or ordering.
* It is free to schedule events from a single parallel flow of an event queue
* to multiple events ports for concurrent processing.
* The application is responsible for flow context synchronization and
* event ordering (SW synchronization).
*
* @see rte_event_queue_setup(), rte_event_dequeue_burst()
*/
/* Event types to classify the event source */
#define RTE_EVENT_TYPE_ETHDEV 0x0
/**< The event generated from ethdev subsystem */
#define RTE_EVENT_TYPE_CRYPTODEV 0x1
/**< The event generated from crypodev subsystem */
#define RTE_EVENT_TYPE_TIMER 0x2
/**< The event generated from event timer adapter */
#define RTE_EVENT_TYPE_CPU 0x3
/**< The event generated from cpu for pipelining.
* Application may use *sub_event_type* to further classify the event
*/
#define RTE_EVENT_TYPE_ETH_RX_ADAPTER 0x4
/**< The event generated from event eth Rx adapter */
#define RTE_EVENT_TYPE_VECTOR 0x8
/**< Indicates that event is a vector.
* All vector event types should be a logical OR of EVENT_TYPE_VECTOR.
* This simplifies the pipeline design as one can split processing the events
* between vector events and normal event across event types.
* Example:
* if (ev.event_type & RTE_EVENT_TYPE_VECTOR) {
* // Classify and handle vector event.
* } else {
* // Classify and handle event.
* }
*/
#define RTE_EVENT_TYPE_ETHDEV_VECTOR \
(RTE_EVENT_TYPE_VECTOR | RTE_EVENT_TYPE_ETHDEV)
/**< The event vector generated from ethdev subsystem */
#define RTE_EVENT_TYPE_CPU_VECTOR (RTE_EVENT_TYPE_VECTOR | RTE_EVENT_TYPE_CPU)
/**< The event vector generated from cpu for pipelining. */
#define RTE_EVENT_TYPE_ETH_RX_ADAPTER_VECTOR \
(RTE_EVENT_TYPE_VECTOR | RTE_EVENT_TYPE_ETH_RX_ADAPTER)
/**< The event vector generated from eth Rx adapter. */
#define RTE_EVENT_TYPE_CRYPTODEV_VECTOR \
(RTE_EVENT_TYPE_VECTOR | RTE_EVENT_TYPE_CRYPTODEV)
/**< The event vector generated from cryptodev adapter. */
#define RTE_EVENT_TYPE_MAX 0x10
/**< Maximum number of event types */
/* Event enqueue operations */
#define RTE_EVENT_OP_NEW 0
/**< The event producers use this operation to inject a new event to the
* event device.
*/
#define RTE_EVENT_OP_FORWARD 1
/**< The CPU use this operation to forward the event to different event queue or
* change to new application specific flow or schedule type to enable
* pipelining.
*
* This operation must only be enqueued to the same port that the
* event to be forwarded was dequeued from.
*/
#define RTE_EVENT_OP_RELEASE 2
/**< Release the flow context associated with the schedule type.
*
* If current flow's scheduler type method is *RTE_SCHED_TYPE_ATOMIC*
* then this function hints the scheduler that the user has completed critical
* section processing in the current atomic context.
* The scheduler is now allowed to schedule events from the same flow from
* an event queue to another port. However, the context may be still held
* until the next rte_event_dequeue_burst() call, this call allows but does not
* force the scheduler to release the context early.
*
* Early atomic context release may increase parallelism and thus system
* performance, but the user needs to design carefully the split into critical
* vs non-critical sections.
*
* If current flow's scheduler type method is *RTE_SCHED_TYPE_ORDERED*
* then this function hints the scheduler that the user has done all that need
* to maintain event order in the current ordered context.
* The scheduler is allowed to release the ordered context of this port and
* avoid reordering any following enqueues.
*
* Early ordered context release may increase parallelism and thus system
* performance.
*
* If current flow's scheduler type method is *RTE_SCHED_TYPE_PARALLEL*
* or no scheduling context is held then this function may be an NOOP,
* depending on the implementation.
*
* This operation must only be enqueued to the same port that the
* event to be released was dequeued from.
*
*/
/**
* The generic *rte_event* structure to hold the event attributes
* for dequeue and enqueue operation
*/
RTE_STD_C11
struct rte_event {
/** WORD0 */
union {
uint64_t event;
/** Event attributes for dequeue or enqueue operation */
struct {
uint32_t flow_id:20;
/**< Targeted flow identifier for the enqueue and
* dequeue operation.
* The value must be in the range of
* [0, nb_event_queue_flows - 1] which
* previously supplied to rte_event_dev_configure().
*/
uint32_t sub_event_type:8;
/**< Sub-event types based on the event source.
* @see RTE_EVENT_TYPE_CPU
*/
uint32_t event_type:4;
/**< Event type to classify the event source.
* @see RTE_EVENT_TYPE_ETHDEV, (RTE_EVENT_TYPE_*)
*/
uint8_t op:2;
/**< The type of event enqueue operation - new/forward/
* etc.This field is not preserved across an instance
* and is undefined on dequeue.
* @see RTE_EVENT_OP_NEW, (RTE_EVENT_OP_*)
*/
uint8_t rsvd:4;
/**< Reserved for future use */
uint8_t sched_type:2;
/**< Scheduler synchronization type (RTE_SCHED_TYPE_*)
* associated with flow id on a given event queue
* for the enqueue and dequeue operation.
*/
uint8_t queue_id;
/**< Targeted event queue identifier for the enqueue or
* dequeue operation.
* The value must be in the range of
* [0, nb_event_queues - 1] which previously supplied to
* rte_event_dev_configure().
*/
uint8_t priority;
/**< Event priority relative to other events in the
* event queue. The requested priority should in the
* range of [RTE_EVENT_DEV_PRIORITY_HIGHEST,
* RTE_EVENT_DEV_PRIORITY_LOWEST].
* The implementation shall normalize the requested
* priority to supported priority value.
* Valid when the device has
* RTE_EVENT_DEV_CAP_EVENT_QOS capability.
*/
uint8_t impl_opaque;
/**< Implementation specific opaque value.
* An implementation may use this field to hold
* implementation specific value to share between
* dequeue and enqueue operation.
* The application should not modify this field.
*/
};
};
/** WORD1 */
union {
uint64_t u64;
/**< Opaque 64-bit value */
void *event_ptr;
/**< Opaque event pointer */
struct rte_mbuf *mbuf;
/**< mbuf pointer if dequeued event is associated with mbuf */
struct rte_event_vector *vec;
/**< Event vector pointer. */
};
};
/* Ethdev Rx adapter capability bitmap flags */
#define RTE_EVENT_ETH_RX_ADAPTER_CAP_INTERNAL_PORT 0x1
/**< This flag is sent when the packet transfer mechanism is in HW.
* Ethdev can send packets to the event device using internal event port.
*/
#define RTE_EVENT_ETH_RX_ADAPTER_CAP_MULTI_EVENTQ 0x2
/**< Adapter supports multiple event queues per ethdev. Every ethdev
* Rx queue can be connected to a unique event queue.
*/
#define RTE_EVENT_ETH_RX_ADAPTER_CAP_OVERRIDE_FLOW_ID 0x4
/**< The application can override the adapter generated flow ID in the
* event. This flow ID can be specified when adding an ethdev Rx queue
* to the adapter using the ev.flow_id member.
* @see struct rte_event_eth_rx_adapter_queue_conf::ev
* @see struct rte_event_eth_rx_adapter_queue_conf::rx_queue_flags
*/
#define RTE_EVENT_ETH_RX_ADAPTER_CAP_EVENT_VECTOR 0x8
/**< Adapter supports event vectorization per ethdev. */
/**
* Retrieve the event device's ethdev Rx adapter capabilities for the
* specified ethernet port
*
* @param dev_id
* The identifier of the device.
*
* @param eth_port_id
* The identifier of the ethernet device.
*
* @param[out] caps
* A pointer to memory filled with Rx event adapter capabilities.
*
* @return
* - 0: Success, driver provides Rx event adapter capabilities for the
* ethernet device.
* - <0: Error code returned by the driver function.
*
*/
int
rte_event_eth_rx_adapter_caps_get(uint8_t dev_id, uint16_t eth_port_id,
uint32_t *caps);
#define RTE_EVENT_TIMER_ADAPTER_CAP_INTERNAL_PORT (1ULL << 0)
/**< This flag is set when the timer mechanism is in HW. */
#define RTE_EVENT_TIMER_ADAPTER_CAP_PERIODIC (1ULL << 1)
/**< This flag is set if periodic mode is supported. */
/**
* Retrieve the event device's timer adapter capabilities.
*
* @param dev_id
* The identifier of the device.
*
* @param[out] caps
* A pointer to memory to be filled with event timer adapter capabilities.
*
* @return
* - 0: Success, driver provided event timer adapter capabilities.
* - <0: Error code returned by the driver function.
*/
int
rte_event_timer_adapter_caps_get(uint8_t dev_id, uint32_t *caps);
/* Crypto adapter capability bitmap flag */
#define RTE_EVENT_CRYPTO_ADAPTER_CAP_INTERNAL_PORT_OP_NEW 0x1
/**< Flag indicates HW is capable of generating events in
* RTE_EVENT_OP_NEW enqueue operation. Cryptodev will send
* packets to the event device as new events using an internal
* event port.
*/
#define RTE_EVENT_CRYPTO_ADAPTER_CAP_INTERNAL_PORT_OP_FWD 0x2
/**< Flag indicates HW is capable of generating events in
* RTE_EVENT_OP_FORWARD enqueue operation. Cryptodev will send
* packets to the event device as forwarded event using an
* internal event port.
*/
#define RTE_EVENT_CRYPTO_ADAPTER_CAP_INTERNAL_PORT_QP_EV_BIND 0x4
/**< Flag indicates HW is capable of mapping crypto queue pair to
* event queue.
*/
#define RTE_EVENT_CRYPTO_ADAPTER_CAP_SESSION_PRIVATE_DATA 0x8
/**< Flag indicates HW/SW supports a mechanism to store and retrieve
* the private data information along with the crypto session.
*/
#define RTE_EVENT_CRYPTO_ADAPTER_CAP_EVENT_VECTOR 0x10
/**< Flag indicates HW is capable of aggregating processed
* crypto operations into rte_event_vector.
*/
/**
* Retrieve the event device's crypto adapter capabilities for the
* specified cryptodev device
*
* @param dev_id
* The identifier of the device.
*
* @param cdev_id
* The identifier of the cryptodev device.
*
* @param[out] caps
* A pointer to memory filled with event adapter capabilities.
* It is expected to be pre-allocated & initialized by caller.
*
* @return
* - 0: Success, driver provides event adapter capabilities for the
* cryptodev device.
* - <0: Error code returned by the driver function.
*
*/
int
rte_event_crypto_adapter_caps_get(uint8_t dev_id, uint8_t cdev_id,
uint32_t *caps);
/* Ethdev Tx adapter capability bitmap flags */
#define RTE_EVENT_ETH_TX_ADAPTER_CAP_INTERNAL_PORT 0x1
/**< This flag is sent when the PMD supports a packet transmit callback
*/
#define RTE_EVENT_ETH_TX_ADAPTER_CAP_EVENT_VECTOR 0x2
/**< Indicates that the Tx adapter is capable of handling event vector of
* mbufs.
*/
/**
* Retrieve the event device's eth Tx adapter capabilities
*
* @param dev_id
* The identifier of the device.
*
* @param eth_port_id
* The identifier of the ethernet device.
*
* @param[out] caps
* A pointer to memory filled with eth Tx adapter capabilities.
*
* @return
* - 0: Success, driver provides eth Tx adapter capabilities.
* - <0: Error code returned by the driver function.
*
*/
int
rte_event_eth_tx_adapter_caps_get(uint8_t dev_id, uint16_t eth_port_id,
uint32_t *caps);
/**
* Converts nanoseconds to *timeout_ticks* value for rte_event_dequeue_burst()
*
* If the device is configured with RTE_EVENT_DEV_CFG_PER_DEQUEUE_TIMEOUT flag
* then application can use this function to convert timeout value in
* nanoseconds to implementations specific timeout value supplied in
* rte_event_dequeue_burst()
*
* @param dev_id
* The identifier of the device.
* @param ns
* Wait time in nanosecond
* @param[out] timeout_ticks
* Value for the *timeout_ticks* parameter in rte_event_dequeue_burst()
*
* @return
* - 0 on success.
* - -ENOTSUP if the device doesn't support timeouts
* - -EINVAL if *dev_id* is invalid or *timeout_ticks* is NULL
* - other values < 0 on failure.
*
* @see rte_event_dequeue_burst(), RTE_EVENT_DEV_CFG_PER_DEQUEUE_TIMEOUT
* @see rte_event_dev_configure()
*
*/
int
rte_event_dequeue_timeout_ticks(uint8_t dev_id, uint64_t ns,
uint64_t *timeout_ticks);
/**
* Link multiple source event queues supplied in *queues* to the destination
* event port designated by its *port_id* with associated service priority
* supplied in *priorities* on the event device designated by its *dev_id*.
*
* The link establishment shall enable the event port *port_id* from
* receiving events from the specified event queue(s) supplied in *queues*
*
* An event queue may link to one or more event ports.
* The number of links can be established from an event queue to event port is
* implementation defined.
*
* Event queue(s) to event port link establishment can be changed at runtime
* without re-configuring the device to support scaling and to reduce the
* latency of critical work by establishing the link with more event ports
* at runtime.
*
* @param dev_id
* The identifier of the device.
*
* @param port_id
* Event port identifier to select the destination port to link.
*
* @param queues
* Points to an array of *nb_links* event queues to be linked
* to the event port.
* NULL value is allowed, in which case this function links all the configured
* event queues *nb_event_queues* which previously supplied to
* rte_event_dev_configure() to the event port *port_id*
*
* @param priorities
* Points to an array of *nb_links* service priorities associated with each
* event queue link to event port.
* The priority defines the event port's servicing priority for
* event queue, which may be ignored by an implementation.
* The requested priority should in the range of
* [RTE_EVENT_DEV_PRIORITY_HIGHEST, RTE_EVENT_DEV_PRIORITY_LOWEST].
* The implementation shall normalize the requested priority to
* implementation supported priority value.
* NULL value is allowed, in which case this function links the event queues
* with RTE_EVENT_DEV_PRIORITY_NORMAL servicing priority
*
* @param nb_links
* The number of links to establish. This parameter is ignored if queues is
* NULL.
*
* @return
* The number of links actually established. The return value can be less than
* the value of the *nb_links* parameter when the implementation has the
* limitation on specific queue to port link establishment or if invalid
* parameters are specified in *queues*
* If the return value is less than *nb_links*, the remaining links at the end
* of link[] are not established, and the caller has to take care of them.
* If return value is less than *nb_links* then implementation shall update the
* rte_errno accordingly, Possible rte_errno values are
* (EDQUOT) Quota exceeded(Application tried to link the queue configured with
* RTE_EVENT_QUEUE_CFG_SINGLE_LINK to more than one event ports)
* (EINVAL) Invalid parameter
*
*/
int
rte_event_port_link(uint8_t dev_id, uint8_t port_id,
const uint8_t queues[], const uint8_t priorities[],
uint16_t nb_links);
/**
* Unlink multiple source event queues supplied in *queues* from the destination
* event port designated by its *port_id* on the event device designated
* by its *dev_id*.
*
* The unlink call issues an async request to disable the event port *port_id*
* from receiving events from the specified event queue *queue_id*.
* Event queue(s) to event port unlink establishment can be changed at runtime
* without re-configuring the device.
*
* @see rte_event_port_unlinks_in_progress() to poll for completed unlinks.
*
* @param dev_id
* The identifier of the device.
*
* @param port_id
* Event port identifier to select the destination port to unlink.
*
* @param queues
* Points to an array of *nb_unlinks* event queues to be unlinked
* from the event port.
* NULL value is allowed, in which case this function unlinks all the
* event queue(s) from the event port *port_id*.
*
* @param nb_unlinks
* The number of unlinks to establish. This parameter is ignored if queues is
* NULL.
*
* @return
* The number of unlinks successfully requested. The return value can be less
* than the value of the *nb_unlinks* parameter when the implementation has the
* limitation on specific queue to port unlink establishment or
* if invalid parameters are specified.
* If the return value is less than *nb_unlinks*, the remaining queues at the
* end of queues[] are not unlinked, and the caller has to take care of them.
* If return value is less than *nb_unlinks* then implementation shall update
* the rte_errno accordingly, Possible rte_errno values are
* (EINVAL) Invalid parameter
*/
int
rte_event_port_unlink(uint8_t dev_id, uint8_t port_id,
uint8_t queues[], uint16_t nb_unlinks);
/**
* Returns the number of unlinks in progress.
*
* This function provides the application with a method to detect when an
* unlink has been completed by the implementation.
*
* @see rte_event_port_unlink() to issue unlink requests.
*
* @param dev_id
* The identifier of the device.
*
* @param port_id
* Event port identifier to select port to check for unlinks in progress.
*
* @return
* The number of unlinks that are in progress. A return of zero indicates that
* there are no outstanding unlink requests. A positive return value indicates
* the number of unlinks that are in progress, but are not yet complete.
* A negative return value indicates an error, -EINVAL indicates an invalid
* parameter passed for *dev_id* or *port_id*.
*/
int
rte_event_port_unlinks_in_progress(uint8_t dev_id, uint8_t port_id);
/**
* Retrieve the list of source event queues and its associated service priority
* linked to the destination event port designated by its *port_id*
* on the event device designated by its *dev_id*.
*
* @param dev_id
* The identifier of the device.
*
* @param port_id
* Event port identifier.
*
* @param[out] queues
* Points to an array of *queues* for output.
* The caller has to allocate *RTE_EVENT_MAX_QUEUES_PER_DEV* bytes to
* store the event queue(s) linked with event port *port_id*
*
* @param[out] priorities
* Points to an array of *priorities* for output.
* The caller has to allocate *RTE_EVENT_MAX_QUEUES_PER_DEV* bytes to
* store the service priority associated with each event queue linked
*
* @return
* The number of links established on the event port designated by its
* *port_id*.
* - <0 on failure.
*
*/
int
rte_event_port_links_get(uint8_t dev_id, uint8_t port_id,
uint8_t queues[], uint8_t priorities[]);
/**
* Retrieve the service ID of the event dev. If the adapter doesn't use
* a rte_service function, this function returns -ESRCH.
*
* @param dev_id
* The identifier of the device.
*
* @param [out] service_id
* A pointer to a uint32_t, to be filled in with the service id.
*
* @return
* - 0: Success
* - <0: Error code on failure, if the event dev doesn't use a rte_service
* function, this function returns -ESRCH.
*/
int
rte_event_dev_service_id_get(uint8_t dev_id, uint32_t *service_id);
/**
* Dump internal information about *dev_id* to the FILE* provided in *f*.
*
* @param dev_id
* The identifier of the device.
*
* @param f
* A pointer to a file for output
*
* @return
* - 0: on success
* - <0: on failure.
*/
int
rte_event_dev_dump(uint8_t dev_id, FILE *f);
/** Maximum name length for extended statistics counters */
#define RTE_EVENT_DEV_XSTATS_NAME_SIZE 64
/**
* Selects the component of the eventdev to retrieve statistics from.
*/
enum rte_event_dev_xstats_mode {
RTE_EVENT_DEV_XSTATS_DEVICE,
RTE_EVENT_DEV_XSTATS_PORT,
RTE_EVENT_DEV_XSTATS_QUEUE,
};
/**
* A name-key lookup element for extended statistics.
*
* This structure is used to map between names and ID numbers
* for extended ethdev statistics.
*/
struct rte_event_dev_xstats_name {
char name[RTE_EVENT_DEV_XSTATS_NAME_SIZE];
};
/**
* Retrieve names of extended statistics of an event device.
*
* @param dev_id
* The identifier of the event device.
* @param mode
* The mode of statistics to retrieve. Choices include the device statistics,
* port statistics or queue statistics.
* @param queue_port_id
* Used to specify the port or queue number in queue or port mode, and is
* ignored in device mode.
* @param[out] xstats_names
* Block of memory to insert names into. Must be at least size in capacity.
* If set to NULL, function returns required capacity.
* @param[out] ids
* Block of memory to insert ids into. Must be at least size in capacity.
* If set to NULL, function returns required capacity. The id values returned
* can be passed to *rte_event_dev_xstats_get* to select statistics.
* @param size
* Capacity of xstats_names (number of names).
* @return
* - positive value lower or equal to size: success. The return value
* is the number of entries filled in the stats table.
* - positive value higher than size: error, the given statistics table
* is too small. The return value corresponds to the size that should
* be given to succeed. The entries in the table are not valid and
* shall not be used by the caller.
* - negative value on error:
* -ENODEV for invalid *dev_id*
* -EINVAL for invalid mode, queue port or id parameters
* -ENOTSUP if the device doesn't support this function.
*/
int
rte_event_dev_xstats_names_get(uint8_t dev_id,
enum rte_event_dev_xstats_mode mode,
uint8_t queue_port_id,
struct rte_event_dev_xstats_name *xstats_names,
unsigned int *ids,
unsigned int size);
/**
* Retrieve extended statistics of an event device.
*
* @param dev_id
* The identifier of the device.
* @param mode
* The mode of statistics to retrieve. Choices include the device statistics,
* port statistics or queue statistics.
* @param queue_port_id
* Used to specify the port or queue number in queue or port mode, and is
* ignored in device mode.
* @param ids
* The id numbers of the stats to get. The ids can be got from the stat
* position in the stat list from rte_event_dev_get_xstats_names(), or
* by using rte_event_dev_xstats_by_name_get().
* @param[out] values
* The values for each stats request by ID.
* @param n
* The number of stats requested
* @return
* - positive value: number of stat entries filled into the values array
* - negative value on error:
* -ENODEV for invalid *dev_id*
* -EINVAL for invalid mode, queue port or id parameters
* -ENOTSUP if the device doesn't support this function.
*/
int
rte_event_dev_xstats_get(uint8_t dev_id,
enum rte_event_dev_xstats_mode mode,
uint8_t queue_port_id,
const unsigned int ids[],
uint64_t values[], unsigned int n);
/**
* Retrieve the value of a single stat by requesting it by name.
*
* @param dev_id
* The identifier of the device
* @param name
* The stat name to retrieve
* @param[out] id
* If non-NULL, the numerical id of the stat will be returned, so that further
* requests for the stat can be got using rte_event_dev_xstats_get, which will
* be faster as it doesn't need to scan a list of names for the stat.
* If the stat cannot be found, the id returned will be (unsigned)-1.
* @return
* - positive value or zero: the stat value
* - negative value: -EINVAL if stat not found, -ENOTSUP if not supported.
*/
uint64_t
rte_event_dev_xstats_by_name_get(uint8_t dev_id, const char *name,
unsigned int *id);
/**
* Reset the values of the xstats of the selected component in the device.
*
* @param dev_id
* The identifier of the device
* @param mode
* The mode of the statistics to reset. Choose from device, queue or port.
* @param queue_port_id
* The queue or port to reset. 0 and positive values select ports and queues,
* while -1 indicates all ports or queues.
* @param ids
* Selects specific statistics to be reset. When NULL, all statistics selected
* by *mode* will be reset. If non-NULL, must point to array of at least
* *nb_ids* size.
* @param nb_ids
* The number of ids available from the *ids* array. Ignored when ids is NULL.
* @return
* - zero: successfully reset the statistics to zero
* - negative value: -EINVAL invalid parameters, -ENOTSUP if not supported.
*/
int
rte_event_dev_xstats_reset(uint8_t dev_id,
enum rte_event_dev_xstats_mode mode,
int16_t queue_port_id,
const uint32_t ids[],
uint32_t nb_ids);
/**
* Trigger the eventdev self test.
*
* @param dev_id
* The identifier of the device
* @return
* - 0: Selftest successful
* - -ENOTSUP if the device doesn't support selftest
* - other values < 0 on failure.
*/
int rte_event_dev_selftest(uint8_t dev_id);
/**
* Get the memory required per event vector based on the number of elements per
* vector.
* This should be used to create the mempool that holds the event vectors.
*
* @param name
* The name of the vector pool.
* @param n
* The number of elements in the mbuf pool.
* @param cache_size
* Size of the per-core object cache. See rte_mempool_create() for
* details.
* @param nb_elem
* The number of elements that a single event vector should be able to hold.
* @param socket_id
* The socket identifier where the memory should be allocated. The
* value can be *SOCKET_ID_ANY* if there is no NUMA constraint for the
* reserved zone
*
* @return
* The pointer to the newly allocated mempool, on success. NULL on error
* with rte_errno set appropriately. Possible rte_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 - cache size provided is too large, or priv_size is not aligned.
* - 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
* - ENAMETOOLONG - mempool name requested is too long.
*/
struct rte_mempool *
rte_event_vector_pool_create(const char *name, unsigned int n,
unsigned int cache_size, uint16_t nb_elem,
int socket_id);
#include <rte_eventdev_core.h>
static __rte_always_inline uint16_t
__rte_event_enqueue_burst(uint8_t dev_id, uint8_t port_id,
const struct rte_event ev[], uint16_t nb_events,
const event_enqueue_burst_t fn)
{
const struct rte_event_fp_ops *fp_ops;
void *port;
fp_ops = &rte_event_fp_ops[dev_id];
port = fp_ops->data[port_id];
#ifdef RTE_LIBRTE_EVENTDEV_DEBUG
if (dev_id >= RTE_EVENT_MAX_DEVS ||
port_id >= RTE_EVENT_MAX_PORTS_PER_DEV) {
rte_errno = EINVAL;
return 0;
}
if (port == NULL) {
rte_errno = EINVAL;
return 0;
}
#endif
rte_eventdev_trace_enq_burst(dev_id, port_id, ev, nb_events, (void *)fn);
/*
* Allow zero cost non burst mode routine invocation if application
* requests nb_events as const one
*/
if (nb_events == 1)
return (fp_ops->enqueue)(port, ev);
else
return fn(port, ev, nb_events);
}
/**
* Enqueue a burst of events objects or an event object supplied in *rte_event*
* structure on an event device designated by its *dev_id* through the event
* port specified by *port_id*. Each event object specifies the event queue on
* which it will be enqueued.
*
* The *nb_events* parameter is the number of event objects to enqueue which are
* supplied in the *ev* array of *rte_event* structure.
*
* Event operations RTE_EVENT_OP_FORWARD and RTE_EVENT_OP_RELEASE must only be
* enqueued to the same port that their associated events were dequeued from.
*
* The rte_event_enqueue_burst() function returns the number of
* events objects it actually enqueued. A return value equal to *nb_events*
* means that all event objects have been enqueued.
*
* @param dev_id
* The identifier of the device.
* @param port_id
* The identifier of the event port.
* @param ev
* Points to an array of *nb_events* objects of type *rte_event* structure
* which contain the event object enqueue operations to be processed.
* @param nb_events
* The number of event objects to enqueue, typically number of
* rte_event_port_attr_get(...RTE_EVENT_PORT_ATTR_ENQ_DEPTH...)
* available for this port.
*
* @return
* The number of event objects actually enqueued on the event device. The
* return value can be less than the value of the *nb_events* parameter when
* the event devices queue is full or if invalid parameters are specified in a
* *rte_event*. If the return value is less than *nb_events*, the remaining
* events at the end of ev[] are not consumed and the caller has to take care
* of them, and rte_errno is set accordingly. Possible errno values include:
* - EINVAL The port ID is invalid, device ID is invalid, an event's queue
* ID is invalid, or an event's sched type doesn't match the
* capabilities of the destination queue.
* - ENOSPC The event port was backpressured and unable to enqueue
* one or more events. This error code is only applicable to
* closed systems.
* @see rte_event_port_attr_get(), RTE_EVENT_PORT_ATTR_ENQ_DEPTH
*/
static inline uint16_t
rte_event_enqueue_burst(uint8_t dev_id, uint8_t port_id,
const struct rte_event ev[], uint16_t nb_events)
{
const struct rte_event_fp_ops *fp_ops;
fp_ops = &rte_event_fp_ops[dev_id];
return __rte_event_enqueue_burst(dev_id, port_id, ev, nb_events,
fp_ops->enqueue_burst);
}
/**
* Enqueue a burst of events objects of operation type *RTE_EVENT_OP_NEW* on
* an event device designated by its *dev_id* through the event port specified
* by *port_id*.
*
* Provides the same functionality as rte_event_enqueue_burst(), expect that
* application can use this API when the all objects in the burst contains
* the enqueue operation of the type *RTE_EVENT_OP_NEW*. This specialized
* function can provide the additional hint to the PMD and optimize if possible.
*
* The rte_event_enqueue_new_burst() result is undefined if the enqueue burst
* has event object of operation type != RTE_EVENT_OP_NEW.
*
* @param dev_id
* The identifier of the device.
* @param port_id
* The identifier of the event port.
* @param ev
* Points to an array of *nb_events* objects of type *rte_event* structure
* which contain the event object enqueue operations to be processed.
* @param nb_events
* The number of event objects to enqueue, typically number of
* rte_event_port_attr_get(...RTE_EVENT_PORT_ATTR_ENQ_DEPTH...)
* available for this port.
*
* @return
* The number of event objects actually enqueued on the event device. The
* return value can be less than the value of the *nb_events* parameter when
* the event devices queue is full or if invalid parameters are specified in a
* *rte_event*. If the return value is less than *nb_events*, the remaining
* events at the end of ev[] are not consumed and the caller has to take care
* of them, and rte_errno is set accordingly. Possible errno values include:
* - EINVAL The port ID is invalid, device ID is invalid, an event's queue
* ID is invalid, or an event's sched type doesn't match the
* capabilities of the destination queue.
* - ENOSPC The event port was backpressured and unable to enqueue
* one or more events. This error code is only applicable to
* closed systems.
* @see rte_event_port_attr_get(), RTE_EVENT_PORT_ATTR_ENQ_DEPTH
* @see rte_event_enqueue_burst()
*/
static inline uint16_t
rte_event_enqueue_new_burst(uint8_t dev_id, uint8_t port_id,
const struct rte_event ev[], uint16_t nb_events)
{
const struct rte_event_fp_ops *fp_ops;
fp_ops = &rte_event_fp_ops[dev_id];
return __rte_event_enqueue_burst(dev_id, port_id, ev, nb_events,
fp_ops->enqueue_new_burst);
}
/**
* Enqueue a burst of events objects of operation type *RTE_EVENT_OP_FORWARD*
* on an event device designated by its *dev_id* through the event port
* specified by *port_id*.
*
* Provides the same functionality as rte_event_enqueue_burst(), expect that
* application can use this API when the all objects in the burst contains
* the enqueue operation of the type *RTE_EVENT_OP_FORWARD*. This specialized
* function can provide the additional hint to the PMD and optimize if possible.
*
* The rte_event_enqueue_new_burst() result is undefined if the enqueue burst
* has event object of operation type != RTE_EVENT_OP_FORWARD.
*
* @param dev_id
* The identifier of the device.
* @param port_id
* The identifier of the event port.
* @param ev
* Points to an array of *nb_events* objects of type *rte_event* structure
* which contain the event object enqueue operations to be processed.
* @param nb_events
* The number of event objects to enqueue, typically number of
* rte_event_port_attr_get(...RTE_EVENT_PORT_ATTR_ENQ_DEPTH...)
* available for this port.
*
* @return
* The number of event objects actually enqueued on the event device. The
* return value can be less than the value of the *nb_events* parameter when
* the event devices queue is full or if invalid parameters are specified in a
* *rte_event*. If the return value is less than *nb_events*, the remaining
* events at the end of ev[] are not consumed and the caller has to take care
* of them, and rte_errno is set accordingly. Possible errno values include:
* - EINVAL The port ID is invalid, device ID is invalid, an event's queue
* ID is invalid, or an event's sched type doesn't match the
* capabilities of the destination queue.
* - ENOSPC The event port was backpressured and unable to enqueue
* one or more events. This error code is only applicable to
* closed systems.
* @see rte_event_port_attr_get(), RTE_EVENT_PORT_ATTR_ENQ_DEPTH
* @see rte_event_enqueue_burst()
*/
static inline uint16_t
rte_event_enqueue_forward_burst(uint8_t dev_id, uint8_t port_id,
const struct rte_event ev[], uint16_t nb_events)
{
const struct rte_event_fp_ops *fp_ops;
fp_ops = &rte_event_fp_ops[dev_id];
return __rte_event_enqueue_burst(dev_id, port_id, ev, nb_events,
fp_ops->enqueue_forward_burst);
}
/**
* Dequeue a burst of events objects or an event object from the event port
* designated by its *event_port_id*, on an event device designated
* by its *dev_id*.
*
* rte_event_dequeue_burst() does not dictate the specifics of scheduling
* algorithm as each eventdev driver may have different criteria to schedule
* an event. However, in general, from an application perspective scheduler may
* use the following scheme to dispatch an event to the port.
*
* 1) Selection of event queue based on
* a) The list of event queues are linked to the event port.
* b) If the device has RTE_EVENT_DEV_CAP_QUEUE_QOS capability then event
* queue selection from list is based on event queue priority relative to
* other event queue supplied as *priority* in rte_event_queue_setup()
* c) If the device has RTE_EVENT_DEV_CAP_EVENT_QOS capability then event
* queue selection from the list is based on event priority supplied as
* *priority* in rte_event_enqueue_burst()
* 2) Selection of event
* a) The number of flows available in selected event queue.
* b) Schedule type method associated with the event
*
* The *nb_events* parameter is the maximum number of event objects to dequeue
* which are returned in the *ev* array of *rte_event* structure.
*
* The rte_event_dequeue_burst() function returns the number of events objects
* it actually dequeued. A return value equal to *nb_events* means that all
* event objects have been dequeued.
*
* The number of events dequeued is the number of scheduler contexts held by
* this port. These contexts are automatically released in the next
* rte_event_dequeue_burst() invocation if the port supports implicit
* releases, or invoking rte_event_enqueue_burst() with RTE_EVENT_OP_RELEASE
* operation can be used to release the contexts early.
*
* Event operations RTE_EVENT_OP_FORWARD and RTE_EVENT_OP_RELEASE must only be
* enqueued to the same port that their associated events were dequeued from.
*
* @param dev_id
* The identifier of the device.
* @param port_id
* The identifier of the event port.
* @param[out] ev
* Points to an array of *nb_events* objects of type *rte_event* structure
* for output to be populated with the dequeued event objects.
* @param nb_events
* The maximum number of event objects to dequeue, typically number of
* rte_event_port_dequeue_depth() available for this port.
*
* @param timeout_ticks
* - 0 no-wait, returns immediately if there is no event.
* - >0 wait for the event, if the device is configured with
* RTE_EVENT_DEV_CFG_PER_DEQUEUE_TIMEOUT then this function will wait until
* at least one event is available or *timeout_ticks* time.
* if the device is not configured with RTE_EVENT_DEV_CFG_PER_DEQUEUE_TIMEOUT
* then this function will wait until the event available or
* *dequeue_timeout_ns* ns which was previously supplied to
* rte_event_dev_configure()
*
* @return
* The number of event objects actually dequeued from the port. The return
* value can be less than the value of the *nb_events* parameter when the
* event port's queue is not full.
*
* @see rte_event_port_dequeue_depth()
*/
static inline uint16_t
rte_event_dequeue_burst(uint8_t dev_id, uint8_t port_id, struct rte_event ev[],
uint16_t nb_events, uint64_t timeout_ticks)
{
const struct rte_event_fp_ops *fp_ops;
void *port;
fp_ops = &rte_event_fp_ops[dev_id];
port = fp_ops->data[port_id];
#ifdef RTE_LIBRTE_EVENTDEV_DEBUG
if (dev_id >= RTE_EVENT_MAX_DEVS ||
port_id >= RTE_EVENT_MAX_PORTS_PER_DEV) {
rte_errno = EINVAL;
return 0;
}
if (port == NULL) {
rte_errno = EINVAL;
return 0;
}
#endif
rte_eventdev_trace_deq_burst(dev_id, port_id, ev, nb_events);
/*
* Allow zero cost non burst mode routine invocation if application
* requests nb_events as const one
*/
if (nb_events == 1)
return (fp_ops->dequeue)(port, ev, timeout_ticks);
else
return (fp_ops->dequeue_burst)(port, ev, nb_events,
timeout_ticks);
}
#define RTE_EVENT_DEV_MAINT_OP_FLUSH (1 << 0)
/**< Force an immediately flush of any buffered events in the port,
* potentially at the cost of additional overhead.
*
* @see rte_event_maintain()
*/
/**
* Maintain an event device.
*
* This function is only relevant for event devices which do not have
* the @ref RTE_EVENT_DEV_CAP_MAINTENANCE_FREE flag set. Such devices
* require an application thread using a particular port to
* periodically call rte_event_maintain() on that port during periods
* which it is neither attempting to enqueue events to nor dequeue
* events from the port. rte_event_maintain() is a low-overhead
* function and should be called at a high rate (e.g., in the
* application's poll loop).
*
* No port may be left unmaintained.
*
* At the application thread's convenience, rte_event_maintain() may
* (but is not required to) be called even during periods when enqueue
* or dequeue functions are being called, at the cost of a slight
* increase in overhead.
*
* rte_event_maintain() may be called on event devices which have set
* @ref RTE_EVENT_DEV_CAP_MAINTENANCE_FREE, in which case it is a
* no-operation.
*
* @param dev_id
* The identifier of the device.
* @param port_id
* The identifier of the event port.
* @param op
* 0, or @ref RTE_EVENT_DEV_MAINT_OP_FLUSH.
* @return
* - 0 on success.
* - -EINVAL if *dev_id*, *port_id*, or *op* is invalid.
*
* @see RTE_EVENT_DEV_CAP_MAINTENANCE_FREE
*/
__rte_experimental
static inline int
rte_event_maintain(uint8_t dev_id, uint8_t port_id, int op)
{
const struct rte_event_fp_ops *fp_ops;
void *port;
fp_ops = &rte_event_fp_ops[dev_id];
port = fp_ops->data[port_id];
#ifdef RTE_LIBRTE_EVENTDEV_DEBUG
if (dev_id >= RTE_EVENT_MAX_DEVS ||
port_id >= RTE_EVENT_MAX_PORTS_PER_DEV)
return -EINVAL;
if (port == NULL)
return -EINVAL;
if (op & (~RTE_EVENT_DEV_MAINT_OP_FLUSH))
return -EINVAL;
#endif
rte_eventdev_trace_maintain(dev_id, port_id, op);
if (fp_ops->maintain != NULL)
fp_ops->maintain(port, op);
return 0;
}
#ifdef __cplusplus
}
#endif
#endif /* _RTE_EVENTDEV_H_ */