a2248c87e2
The index description isn't right, correct it as the Programmer's guide said. Also correct the guide's figure description about 'Dequeue First Step'. Fixes:4a22e6ee3d
("doc: refactor figure numbers into references") Fixes:af75078fec
("first public release") Cc: stable@dpdk.org Signed-off-by: Haiyue Wang <haiyue.wang@intel.com>
504 lines
16 KiB
ReStructuredText
504 lines
16 KiB
ReStructuredText
.. SPDX-License-Identifier: BSD-3-Clause
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Copyright(c) 2010-2014 Intel Corporation.
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.. _Ring_Library:
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Ring Library
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============
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The ring allows the management of queues.
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Instead of having a linked list of infinite size, the rte_ring has the following properties:
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* FIFO
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* Maximum size is fixed, the objects are stored in a table
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* Objects can be pointers or elements of multiple of 4 byte size
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* Lockless implementation
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* Multi-consumer or single-consumer dequeue
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* Multi-producer or single-producer enqueue
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* Bulk dequeue - Dequeues the specified count of objects if successful; otherwise fails
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* Bulk enqueue - Enqueues the specified count of objects if successful; otherwise fails
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* Burst dequeue - Dequeue the maximum available objects if the specified count cannot be fulfilled
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* Burst enqueue - Enqueue the maximum available objects if the specified count cannot be fulfilled
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The advantages of this data structure over a linked list queue are as follows:
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* Faster; only requires a single 32 bit Compare-And-Swap instruction instead of several pointer size Compare-And-Swap instructions.
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* Simpler than a full lockless queue.
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* Adapted to bulk enqueue/dequeue operations.
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As objects are stored in a table, a dequeue of several objects will not produce as many cache misses as in a linked queue.
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Also, a bulk dequeue of many objects does not cost more than a dequeue of a simple object.
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The disadvantages:
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* Size is fixed
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* Having many rings costs more in terms of memory than a linked list queue. An empty ring contains at least N objects.
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A simplified representation of a Ring is shown in with consumer and producer head and tail pointers to objects stored in the data structure.
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.. _figure_ring1:
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.. figure:: img/ring1.*
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Ring Structure
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References for Ring Implementation in FreeBSD*
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----------------------------------------------
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The following code was added in FreeBSD 8.0, and is used in some network device drivers (at least in Intel drivers):
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* `bufring.h in FreeBSD <http://svn.freebsd.org/viewvc/base/release/8.0.0/sys/sys/buf_ring.h?revision=199625&view=markup>`_
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* `bufring.c in FreeBSD <http://svn.freebsd.org/viewvc/base/release/8.0.0/sys/kern/subr_bufring.c?revision=199625&view=markup>`_
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Lockless Ring Buffer in Linux*
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------------------------------
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The following is a link describing the `Linux Lockless Ring Buffer Design <http://lwn.net/Articles/340400/>`_.
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Additional Features
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-------------------
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Name
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~~~~
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A ring is identified by a unique name.
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It is not possible to create two rings with the same name (rte_ring_create() returns NULL if this is attempted).
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Use Cases
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---------
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Use cases for the Ring library include:
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* Communication between applications in the DPDK
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* Used by memory pool allocator
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Anatomy of a Ring Buffer
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------------------------
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This section explains how a ring buffer operates.
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The ring structure is composed of two head and tail couples; one is used by producers and one is used by the consumers.
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The figures of the following sections refer to them as prod_head, prod_tail, cons_head and cons_tail.
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Each figure represents a simplified state of the ring, which is a circular buffer.
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The content of the function local variables is represented on the top of the figure,
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and the content of ring structure is represented on the bottom of the figure.
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Single Producer Enqueue
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~~~~~~~~~~~~~~~~~~~~~~~
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This section explains what occurs when a producer adds an object to the ring.
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In this example, only the producer head and tail (prod_head and prod_tail) are modified,
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and there is only one producer.
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The initial state is to have a prod_head and prod_tail pointing at the same location.
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Enqueue First Step
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^^^^^^^^^^^^^^^^^^
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First, *ring->prod_head* and ring->cons_tail are copied in local variables.
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The prod_next local variable points to the next element of the table, or several elements after in case of bulk enqueue.
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If there is not enough room in the ring (this is detected by checking cons_tail), it returns an error.
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.. _figure_ring-enqueue1:
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.. figure:: img/ring-enqueue1.*
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Enqueue first step
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Enqueue Second Step
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^^^^^^^^^^^^^^^^^^^
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The second step is to modify *ring->prod_head* in ring structure to point to the same location as prod_next.
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The added object is copied in the ring (obj4).
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.. _figure_ring-enqueue2:
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.. figure:: img/ring-enqueue2.*
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Enqueue second step
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Enqueue Last Step
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^^^^^^^^^^^^^^^^^
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Once the object is added in the ring, ring->prod_tail in the ring structure is modified to point to the same location as *ring->prod_head*.
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The enqueue operation is finished.
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.. _figure_ring-enqueue3:
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.. figure:: img/ring-enqueue3.*
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Enqueue last step
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Single Consumer Dequeue
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~~~~~~~~~~~~~~~~~~~~~~~
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This section explains what occurs when a consumer dequeues an object from the ring.
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In this example, only the consumer head and tail (cons_head and cons_tail) are modified and there is only one consumer.
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The initial state is to have a cons_head and cons_tail pointing at the same location.
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Dequeue First Step
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^^^^^^^^^^^^^^^^^^
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First, ring->cons_head and ring->prod_tail are copied in local variables.
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The cons_next local variable points to the next element of the table, or several elements after in the case of bulk dequeue.
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If there are not enough objects in the ring (this is detected by checking prod_tail), it returns an error.
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.. _figure_ring-dequeue1:
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.. figure:: img/ring-dequeue1.*
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Dequeue first step
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Dequeue Second Step
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^^^^^^^^^^^^^^^^^^^
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The second step is to modify ring->cons_head in the ring structure to point to the same location as cons_next.
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The dequeued object (obj1) is copied in the pointer given by the user.
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.. _figure_ring-dequeue2:
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.. figure:: img/ring-dequeue2.*
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Dequeue second step
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Dequeue Last Step
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^^^^^^^^^^^^^^^^^
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Finally, ring->cons_tail in the ring structure is modified to point to the same location as ring->cons_head.
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The dequeue operation is finished.
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.. _figure_ring-dequeue3:
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.. figure:: img/ring-dequeue3.*
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Dequeue last step
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Multiple Producers Enqueue
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~~~~~~~~~~~~~~~~~~~~~~~~~~
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This section explains what occurs when two producers concurrently add an object to the ring.
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In this example, only the producer head and tail (prod_head and prod_tail) are modified.
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The initial state is to have a prod_head and prod_tail pointing at the same location.
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Multiple Producers Enqueue First Step
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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On both cores, *ring->prod_head* and ring->cons_tail are copied in local variables.
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The prod_next local variable points to the next element of the table,
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or several elements after in the case of bulk enqueue.
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If there is not enough room in the ring (this is detected by checking cons_tail), it returns an error.
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.. _figure_ring-mp-enqueue1:
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.. figure:: img/ring-mp-enqueue1.*
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Multiple producer enqueue first step
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Multiple Producers Enqueue Second Step
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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The second step is to modify ring->prod_head in the ring structure to point to the same location as prod_next.
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This operation is done using a Compare And Swap (CAS) instruction, which does the following operations atomically:
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* If ring->prod_head is different to local variable prod_head,
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the CAS operation fails, and the code restarts at first step.
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* Otherwise, ring->prod_head is set to local prod_next,
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the CAS operation is successful, and processing continues.
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In the figure, the operation succeeded on core 1, and step one restarted on core 2.
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.. _figure_ring-mp-enqueue2:
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.. figure:: img/ring-mp-enqueue2.*
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Multiple producer enqueue second step
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Multiple Producers Enqueue Third Step
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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The CAS operation is retried on core 2 with success.
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The core 1 updates one element of the ring(obj4), and the core 2 updates another one (obj5).
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.. _figure_ring-mp-enqueue3:
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.. figure:: img/ring-mp-enqueue3.*
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Multiple producer enqueue third step
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Multiple Producers Enqueue Fourth Step
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Each core now wants to update ring->prod_tail.
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A core can only update it if ring->prod_tail is equal to the prod_head local variable.
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This is only true on core 1. The operation is finished on core 1.
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.. _figure_ring-mp-enqueue4:
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.. figure:: img/ring-mp-enqueue4.*
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Multiple producer enqueue fourth step
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Multiple Producers Enqueue Last Step
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Once ring->prod_tail is updated by core 1, core 2 is allowed to update it too.
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The operation is also finished on core 2.
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.. _figure_ring-mp-enqueue5:
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.. figure:: img/ring-mp-enqueue5.*
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Multiple producer enqueue last step
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Modulo 32-bit Indexes
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~~~~~~~~~~~~~~~~~~~~~
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In the preceding figures, the prod_head, prod_tail, cons_head and cons_tail indexes are represented by arrows.
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In the actual implementation, these values are not between 0 and size(ring)-1 as would be assumed.
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The indexes are between 0 and 2^32 -1, and we mask their value when we access the object table (the ring itself).
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32-bit modulo also implies that operations on indexes (such as, add/subtract) will automatically do 2^32 modulo
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if the result overflows the 32-bit number range.
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The following are two examples that help to explain how indexes are used in a ring.
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.. note::
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To simplify the explanation, operations with modulo 16-bit are used instead of modulo 32-bit.
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In addition, the four indexes are defined as unsigned 16-bit integers,
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as opposed to unsigned 32-bit integers in the more realistic case.
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.. _figure_ring-modulo1:
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.. figure:: img/ring-modulo1.*
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Modulo 32-bit indexes - Example 1
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This ring contains 11000 entries.
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.. _figure_ring-modulo2:
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.. figure:: img/ring-modulo2.*
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Modulo 32-bit indexes - Example 2
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This ring contains 12536 entries.
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.. note::
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For ease of understanding, we use modulo 65536 operations in the above examples.
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In real execution cases, this is redundant for low efficiency, but is done automatically when the result overflows.
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The code always maintains a distance between producer and consumer between 0 and size(ring)-1.
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Thanks to this property, we can do subtractions between 2 index values in a modulo-32bit base:
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that's why the overflow of the indexes is not a problem.
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At any time, entries and free_entries are between 0 and size(ring)-1,
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even if only the first term of subtraction has overflowed:
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.. code-block:: c
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uint32_t entries = (prod_tail - cons_head);
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uint32_t free_entries = (mask + cons_tail -prod_head);
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Producer/consumer synchronization modes
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---------------------------------------
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rte_ring supports different synchronization modes for producers and consumers.
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These modes can be specified at ring creation/init time via ``flags``
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parameter.
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That should help users to configure ring in the most suitable way for his
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specific usage scenarios.
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Currently supported modes:
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.. _Ring_Library_MPMC_Mode:
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MP/MC (default one)
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~~~~~~~~~~~~~~~~~~~
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Multi-producer (/multi-consumer) mode. This is a default enqueue (/dequeue)
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mode for the ring. In this mode multiple threads can enqueue (/dequeue)
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objects to (/from) the ring. For 'classic' DPDK deployments (with one thread
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per core) this is usually the most suitable and fastest synchronization mode.
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As a well known limitation - it can perform quite pure on some overcommitted
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scenarios.
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.. _Ring_Library_SPSC_Mode:
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SP/SC
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~~~~~
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Single-producer (/single-consumer) mode. In this mode only one thread at a time
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is allowed to enqueue (/dequeue) objects to (/from) the ring.
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.. _Ring_Library_MT_RTS_Mode:
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MP_RTS/MC_RTS
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~~~~~~~~~~~~~
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Multi-producer (/multi-consumer) with Relaxed Tail Sync (RTS) mode.
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The main difference from the original MP/MC algorithm is that
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tail value is increased not by every thread that finished enqueue/dequeue,
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but only by the last one.
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That allows threads to avoid spinning on ring tail value,
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leaving actual tail value change to the last thread at a given instance.
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That technique helps to avoid the Lock-Waiter-Preemption (LWP) problem on tail
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update and improves average enqueue/dequeue times on overcommitted systems.
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To achieve that RTS requires 2 64-bit CAS for each enqueue(/dequeue) operation:
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one for head update, second for tail update.
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In comparison the original MP/MC algorithm requires one 32-bit CAS
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for head update and waiting/spinning on tail value.
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.. _Ring_Library_MT_HTS_Mode:
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MP_HTS/MC_HTS
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~~~~~~~~~~~~~
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Multi-producer (/multi-consumer) with Head/Tail Sync (HTS) mode.
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In that mode enqueue/dequeue operation is fully serialized:
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at any given moment only one enqueue/dequeue operation can proceed.
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This is achieved by allowing a thread to proceed with changing ``head.value``
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only when ``head.value == tail.value``.
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Both head and tail values are updated atomically (as one 64-bit value).
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To achieve that 64-bit CAS is used by head update routine.
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That technique also avoids the Lock-Waiter-Preemption (LWP) problem on tail
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update and helps to improve ring enqueue/dequeue behavior in overcommitted
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scenarios. Another advantage of fully serialized producer/consumer -
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it provides the ability to implement MT safe peek API for rte_ring.
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Ring Peek API
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-------------
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For ring with serialized producer/consumer (HTS sync mode) it is possible
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to split public enqueue/dequeue API into two phases:
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* enqueue/dequeue start
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* enqueue/dequeue finish
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That allows user to inspect objects in the ring without removing them
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from it (aka MT safe peek) and reserve space for the objects in the ring
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before actual enqueue.
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Note that this API is available only for two sync modes:
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* Single Producer/Single Consumer (SP/SC)
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* Multi-producer/Multi-consumer with Head/Tail Sync (HTS)
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It is a user responsibility to create/init ring with appropriate sync modes
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selected. As an example of usage:
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.. code-block:: c
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/* read 1 elem from the ring: */
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uint32_t n = rte_ring_dequeue_bulk_start(ring, &obj, 1, NULL);
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if (n != 0) {
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/* examine object */
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if (object_examine(obj) == KEEP)
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/* decided to keep it in the ring. */
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rte_ring_dequeue_finish(ring, 0);
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else
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/* decided to remove it from the ring. */
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rte_ring_dequeue_finish(ring, n);
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}
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Note that between ``_start_`` and ``_finish_`` none other thread can proceed
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with enqueue(/dequeue) operation till ``_finish_`` completes.
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Ring Peek Zero Copy API
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-----------------------
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Along with the advantages of the peek APIs, zero copy APIs provide the ability
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to copy the data to the ring memory directly without the need for temporary
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storage (for ex: array of mbufs on the stack).
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These APIs make it possible to split public enqueue/dequeue API into 3 phases:
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* enqueue/dequeue start
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* copy data to/from the ring
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* enqueue/dequeue finish
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Note that this API is available only for two sync modes:
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* Single Producer/Single Consumer (SP/SC)
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* Multi-producer/Multi-consumer with Head/Tail Sync (HTS)
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It is a user responsibility to create/init ring with appropriate sync modes.
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Following is an example of usage:
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.. code-block:: c
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/* Reserve space on the ring */
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n = rte_ring_enqueue_zc_burst_start(r, 32, &zcd, NULL);
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/* Pkt I/O core polls packets from the NIC */
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if (n != 0) {
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nb_rx = rte_eth_rx_burst(portid, queueid, zcd->ptr1, zcd->n1);
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if (nb_rx == zcd->n1 && n != zcd->n1)
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nb_rx += rte_eth_rx_burst(portid, queueid, zcd->ptr2,
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n - zcd->n1);
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/* Provide packets to the packet processing cores */
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rte_ring_enqueue_zc_finish(r, nb_rx);
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}
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Note that between ``_start_`` and ``_finish_`` no other thread can proceed
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with enqueue(/dequeue) operation till ``_finish_`` completes.
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References
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----------
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* `bufring.h in FreeBSD <http://svn.freebsd.org/viewvc/base/release/8.0.0/sys/sys/buf_ring.h?revision=199625&view=markup>`_ (version 8)
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* `bufring.c in FreeBSD <http://svn.freebsd.org/viewvc/base/release/8.0.0/sys/kern/subr_bufring.c?revision=199625&view=markup>`_ (version 8)
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* `Linux Lockless Ring Buffer Design <http://lwn.net/Articles/340400/>`_
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