5630257fcc
Signed-off-by: Ferruh Yigit <ferruh.yigit@intel.com> Acked-by: Bruce Richardson <bruce.richardson@intel.com>
76 lines
4.5 KiB
ReStructuredText
76 lines
4.5 KiB
ReStructuredText
.. SPDX-License-Identifier: BSD-3-Clause
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Copyright(c) 2010-2014 Intel Corporation.
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Thread Safety of DPDK Functions
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===============================
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The DPDK is comprised of several libraries.
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Some of the functions in these libraries can be safely called from multiple threads simultaneously, while others cannot.
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This section allows the developer to take these issues into account when building their own application.
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The run-time environment of the DPDK is typically a single thread per logical core.
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In some cases, it is not only multi-threaded, but multi-process.
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Typically, it is best to avoid sharing data structures between threads and/or processes where possible.
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Where this is not possible, then the execution blocks must access the data in a thread- safe manner.
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Mechanisms such as atomics or locking can be used that will allow execution blocks to operate serially.
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However, this can have an effect on the performance of the application.
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Fast-Path APIs
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--------------
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Applications operating in the data plane are performance sensitive but
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certain functions within those libraries may not be safe to call from multiple threads simultaneously.
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The hash, LPM and mempool libraries and RX/TX in the PMD are examples of this.
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The hash and LPM libraries are, by design, thread unsafe in order to maintain performance.
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However, if required the developer can add layers on top of these libraries to provide thread safety.
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Locking is not needed in all situations, and in both the hash and LPM libraries,
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lookups of values can be performed in parallel in multiple threads.
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Adding, removing or modifying values, however,
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cannot be done in multiple threads without using locking when a single hash or LPM table is accessed.
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Another alternative to locking would be to create multiple instances of these tables allowing each thread its own copy.
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The RX and TX of the PMD are the most critical aspects of a DPDK application
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and it is recommended that no locking be used as it will impact performance.
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Note, however, that these functions can safely be used from multiple threads
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when each thread is performing I/O on a different NIC queue.
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If multiple threads are to use the same hardware queue on the same NIC port,
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then locking, or some other form of mutual exclusion, is necessary.
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The ring library is based on a lockless ring-buffer algorithm that maintains its original design for thread safety.
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Moreover, it provides high performance for either multi- or single-consumer/producer enqueue/dequeue operations.
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The mempool library is based on the DPDK lockless ring library and therefore is also multi-thread safe.
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Performance Insensitive API
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---------------------------
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Outside of the performance sensitive areas described in Section 25.1,
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the DPDK provides a thread-safe API for most other libraries.
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For example, malloc and memzone functions are safe for use in multi-threaded and multi-process environments.
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The setup and configuration of the PMD is not performance sensitive, but is not thread safe either.
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It is possible that the multiple read/writes during PMD setup and configuration could be corrupted in a multi-thread environment.
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Since this is not performance sensitive, the developer can choose to add their own layer to provide thread-safe setup and configuration.
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It is expected that, in most applications, the initial configuration of the network ports would be done by a single thread at startup.
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Library Initialization
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----------------------
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It is recommended that DPDK libraries are initialized in the main thread at application startup
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rather than subsequently in the forwarding threads.
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However, the DPDK performs checks to ensure that libraries are only initialized once.
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If initialization is attempted more than once, an error is returned.
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In the multi-process case, the configuration information of shared memory will only be initialized by the master process.
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Thereafter, both master and secondary processes can allocate/release any objects of memory that finally rely on rte_malloc or memzones.
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Interrupt Thread
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----------------
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The DPDK works almost entirely in Linux user space in polling mode.
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For certain infrequent operations, such as receiving a PMD link status change notification,
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callbacks may be called in an additional thread outside the main DPDK processing threads.
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These function callbacks should avoid manipulating DPDK objects that are also managed by the normal DPDK threads,
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and if they need to do so,
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it is up to the application to provide the appropriate locking or mutual exclusion restrictions around those objects.
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