84ba341cb0
Remove redundant information from section Performance issue isolation.
Re-word for section header for packet capture.
Fixes: 08db7bde16
("doc: add guide for debug and troubleshoot")
Signed-off-by: Vipin Varghese <vipin.varghese@intel.com>
Acked-by: John McNamara <john.mcnamara@intel.com>
461 lines
15 KiB
ReStructuredText
461 lines
15 KiB
ReStructuredText
.. SPDX-License-Identifier: BSD-3-Clause
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Copyright(c) 2018 Intel Corporation.
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Debug & Troubleshoot guide
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==========================
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DPDK applications can be designed to have simple or complex pipeline processing
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stages making use of single or multiple threads. Applications can use poll mode
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hardware devices which helps in offloading CPU cycles too. It is common to find
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solutions designed with
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* single or multiple primary processes
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* single primary and single secondary
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* single primary and multiple secondaries
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In all the above cases, it is tedious to isolate, debug, and understand various
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behaviors which occur randomly or periodically. The goal of the guide is to
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consolidate a few commonly seen issues for reference. Then, isolate to identify
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the root cause through step by step debug at various stages.
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.. note::
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It is difficult to cover all possible issues; in a single attempt. With
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feedback and suggestions from the community, more cases can be covered.
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Application Overview
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--------------------
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By making use of the application model as a reference, we can discuss multiple
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causes of issues in the guide. Let us assume the sample makes use of a single
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primary process, with various processing stages running on multiple cores. The
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application may also make uses of Poll Mode Driver, and libraries like service
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cores, mempool, mbuf, eventdev, cryptodev, QoS, and ethdev.
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The overview of an application modeled using PMD is shown in
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:numref:`dtg_sample_app_model`.
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.. _dtg_sample_app_model:
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.. figure:: img/dtg_sample_app_model.*
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Overview of pipeline stage of an application
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Bottleneck Analysis
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-------------------
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A couple of factors that lead the design decision could be the platform, scale
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factor, and target. This distinct preference leads to multiple combinations,
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that are built using PMD and libraries of DPDK. While the compiler, library
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mode, and optimization flags are the components are to be constant, that
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affects the application too.
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Is there mismatch in packet (received < desired) rate?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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RX Port and associated core :numref:`dtg_rx_rate`.
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.. _dtg_rx_rate:
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.. figure:: img/dtg_rx_rate.*
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RX packet rate compared against received rate.
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#. Is the configuration for the RX setup correctly?
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* Identify if port Speed and Duplex is matching to desired values with
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``rte_eth_link_get``.
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* Check ``DEV_RX_OFFLOAD_JUMBO_FRAME`` is set with ``rte_eth_dev_info_get``.
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* Check promiscuous mode if the drops do not occur for unique MAC address
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with ``rte_eth_promiscuous_get``.
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#. Is the drop isolated to certain NIC only?
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* Make use of ``rte_eth_dev_stats`` to identify the drops cause.
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* If there are mbuf drops, check nb_desc for RX descriptor as it might not
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be sufficient for the application.
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* If ``rte_eth_dev_stats`` shows drops are on specific RX queues, ensure RX
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lcore threads has enough cycles for ``rte_eth_rx_burst`` on the port queue
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pair.
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* If there are redirect to a specific port queue pair with, ensure RX lcore
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threads gets enough cycles.
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* Check the RSS configuration ``rte_eth_dev_rss_hash_conf_get`` if the
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spread is not even and causing drops.
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* If PMD stats are not updating, then there might be offload or configuration
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which is dropping the incoming traffic.
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#. Is there drops still seen?
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* If there are multiple port queue pair, it might be the RX thread, RX
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distributor, or event RX adapter not having enough cycles.
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* If there are drops seen for RX adapter or RX distributor, try using
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``rte_prefetch_non_temporal`` which intimates the core that the mbuf in the
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cache is temporary.
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Is there packet drops at receive or transmit?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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RX-TX port and associated cores :numref:`dtg_rx_tx_drop`.
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.. _dtg_rx_tx_drop:
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.. figure:: img/dtg_rx_tx_drop.*
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RX-TX drops
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#. At RX
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* Identify if there are multiple RX queue configured for port by
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``nb_rx_queues`` using ``rte_eth_dev_info_get``.
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* Using ``rte_eth_dev_stats`` fetch drops in q_errors, check if RX thread
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is configured to fetch packets from the port queue pair.
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* Using ``rte_eth_dev_stats`` shows drops in ``rx_nombuf``, check if RX
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thread has enough cycles to consume the packets from the queue.
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#. At TX
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* If the TX rate is falling behind the application fill rate, identify if
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there are enough descriptors with ``rte_eth_dev_info_get`` for TX.
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* Check the ``nb_pkt`` in ``rte_eth_tx_burst`` is done for multiple packets.
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* Check ``rte_eth_tx_burst`` invokes the vector function call for the PMD.
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* If oerrors are getting incremented, TX packet validations are failing.
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Check if there queue specific offload failures.
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* If the drops occur for large size packets, check MTU and multi-segment
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support configured for NIC.
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Is there object drops in producer point for the ring library?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Producer point for ring :numref:`dtg_producer_ring`.
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.. _dtg_producer_ring:
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.. figure:: img/dtg_producer_ring.*
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Producer point for Rings
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#. Performance issue isolation at producer
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* Use ``rte_ring_dump`` to validate for all single producer flag is set to
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``RING_F_SP_ENQ``.
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* There should be sufficient ``rte_ring_free_count`` at any point in time.
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* Extreme stalls in dequeue stage of the pipeline will cause
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``rte_ring_full`` to be true.
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Is there object drops in consumer point for the ring library?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Consumer point for ring :numref:`dtg_consumer_ring`.
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.. _dtg_consumer_ring:
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.. figure:: img/dtg_consumer_ring.*
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Consumer point for Rings
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#. Performance issue isolation at consumer
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* Use ``rte_ring_dump`` to validate for all single consumer flag is set to
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``RING_F_SC_DEQ``.
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* If the desired burst dequeue falls behind the actual dequeue, the enqueue
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stage is not filling up the ring as required.
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* Extreme stall in the enqueue will lead to ``rte_ring_empty`` to be true.
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Is there a variance in packet or object processing rate in the pipeline?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Memory objects close to NUMA :numref:`dtg_mempool`.
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.. _dtg_mempool:
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.. figure:: img/dtg_mempool.*
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Memory objects have to be close to the device per NUMA.
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#. Stall in processing pipeline can be attributes of MBUF release delays.
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These can be narrowed down to
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* Heavy processing cycles at single or multiple processing stages.
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* Cache is spread due to the increased stages in the pipeline.
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* CPU thread responsible for TX is not able to keep up with the burst of
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traffic.
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* Extra cycles to linearize multi-segment buffer and software offload like
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checksum, TSO, and VLAN strip.
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* Packet buffer copy in fast path also results in stalls in MBUF release if
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not done selectively.
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* Application logic sets ``rte_pktmbuf_refcnt_set`` to higher than the
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desired value and frequently uses ``rte_pktmbuf_prefree_seg`` and does
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not release MBUF back to mempool.
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#. Lower performance between the pipeline processing stages can be
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* The NUMA instance for packets or objects from NIC, mempool, and ring
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should be the same.
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* Drops on a specific socket are due to insufficient objects in the pool.
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Use ``rte_mempool_get_count`` or ``rte_mempool_avail_count`` to monitor
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when drops occurs.
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* Try prefetching the content in processing pipeline logic to minimize the
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stalls.
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#. Performance issue can be due to special cases
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* Check if MBUF continuous with ``rte_pktmbuf_is_contiguous`` as certain
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offload requires the same.
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* Use ``rte_mempool_cache_create`` for user threads require access to
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mempool objects.
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* If the variance is absent for larger huge pages, then try rte_mem_lock_page
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on the objects, packets, lookup tables to isolate the issue.
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Is there a variance in cryptodev performance?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Crypto device and PMD :numref:`dtg_crypto`.
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.. _dtg_crypto:
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.. figure:: img/dtg_crypto.*
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CRYPTO and interaction with PMD device.
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#. Performance issue isolation for enqueue
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* Ensure cryptodev, resources and enqueue is running on NUMA cores.
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* Isolate if the cause of errors for err_count using ``rte_cryptodev_stats``.
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* Parallelize enqueue thread for varied multiple queue pair.
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#. Performance issue isolation for dequeue
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* Ensure cryptodev, resources and dequeue are running on NUMA cores.
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* Isolate if the cause of errors for err_count using ``rte_cryptodev_stats``.
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* Parallelize dequeue thread for varied multiple queue pair.
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#. Performance issue isolation for crypto operation
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* If the cryptodev software-assist is in use, ensure the library is built
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with right (SIMD) flags or check if the queue pair using CPU ISA for
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feature_flags AVX|SSE|NEON using ``rte_cryptodev_info_get``.
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* If the cryptodev hardware-assist is in use, ensure both firmware and
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drivers are up to date.
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#. Configuration issue isolation
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* Identify cryptodev instances with ``rte_cryptodev_count`` and
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``rte_cryptodev_info_get``.
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Is user functions performance is not as expected?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Custom worker function :numref:`dtg_distributor_worker`.
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.. _dtg_distributor_worker:
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.. figure:: img/dtg_distributor_worker.*
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Custom worker function performance drops.
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#. Performance issue isolation
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* The functions running on CPU cores without context switches are the
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performing scenarios. Identify lcore with ``rte_lcore`` and lcore index
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mapping with CPU using ``rte_lcore_index``.
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* Use ``rte_thread_get_affinity`` to isolate functions running on the same
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CPU core.
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#. Configuration issue isolation
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* Identify core role using ``rte_eal_lcore_role`` to identify RTE, OFF and
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SERVICE. Check performance functions are mapped to run on the cores.
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* For high-performance execution logic ensure running it on correct NUMA
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and non-master core.
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* Analyze run logic with ``rte_dump_stack``, ``rte_dump_registers`` and
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``rte_memdump`` for more insights.
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* Make use of objdump to ensure opcode is matching to the desired state.
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Is the execution cycles for dynamic service functions are not frequent?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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service functions on service cores :numref:`dtg_service`.
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.. _dtg_service:
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.. figure:: img/dtg_service.*
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functions running on service cores
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#. Performance issue isolation
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* Services configured for parallel execution should have
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``rte_service_lcore_count`` should be equal to
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``rte_service_lcore_count_services``.
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* A service to run parallel on all cores should return
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``RTE_SERVICE_CAP_MT_SAFE`` for ``rte_service_probe_capability`` and
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``rte_service_map_lcore_get`` returns unique lcore.
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* If service function execution cycles for dynamic service functions are
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not frequent?
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* If services share the lcore, overall execution should fit budget.
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#. Configuration issue isolation
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* Check if service is running with ``rte_service_runstate_get``.
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* Generic debug via ``rte_service_dump``.
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Is there a bottleneck in the performance of eventdev?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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#. Check for generic configuration
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* Ensure the event devices created are right NUMA using
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``rte_event_dev_count`` and ``rte_event_dev_socket_id``.
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* Check for event stages if the events are looped back into the same queue.
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* If the failure is on the enqueue stage for events, check if queue depth
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with ``rte_event_dev_info_get``.
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#. If there are performance drops in the enqueue stage
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* Use ``rte_event_dev_dump`` to dump the eventdev information.
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* Periodically checks stats for queue and port to identify the starvation.
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* Check the in-flight events for the desired queue for enqueue and dequeue.
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Is there a variance in traffic manager?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Traffic Manager on TX interface :numref:`dtg_qos_tx`.
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.. _dtg_qos_tx:
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.. figure:: img/dtg_qos_tx.*
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Traffic Manager just before TX.
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#. Identify the cause for a variance from expected behavior, is due to
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insufficient CPU cycles. Use ``rte_tm_capabilities_get`` to fetch features
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for hierarchies, WRED and priority schedulers to be offloaded hardware.
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#. Undesired flow drops can be narrowed down to WRED, priority, and rates
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limiters.
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#. Isolate the flow in which the undesired drops occur. Use
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``rte_tn_get_number_of_leaf_node`` and flow table to ping down the leaf
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where drops occur.
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#. Check the stats using ``rte_tm_stats_update`` and ``rte_tm_node_stats_read``
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for drops for hierarchy, schedulers and WRED configurations.
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Is the packet in the unexpected format?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Packet capture before and after processing :numref:`dtg_pdump`.
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.. _dtg_pdump:
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.. figure:: img/dtg_pdump.*
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Capture points of Traffic at RX-TX.
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#. To isolate the possible packet corruption in the processing pipeline,
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carefully staged capture packets are to be implemented.
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* First, isolate at NIC entry and exit.
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Use pdump in primary to allow secondary to access port-queue pair. The
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packets get copied over in RX|TX callback by the secondary process using
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ring buffers.
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* Second, isolate at pipeline entry and exit.
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Using hooks or callbacks capture the packet middle of the pipeline stage
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to copy the packets, which can be shared to the secondary debug process
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via user-defined custom rings.
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.. note::
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Use similar analysis to objects and metadata corruption.
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Does the issue still persist?
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The issue can be further narrowed down to the following causes.
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#. If there are vendor or application specific metadata, check for errors due
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to META data error flags. Dumping private meta-data in the objects can give
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insight into details for debugging.
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#. If there are multi-process for either data or configuration, check for
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possible errors in the secondary process where the configuration fails and
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possible data corruption in the data plane.
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#. Random drops in the RX or TX when opening other application is an indication
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of the effect of a noisy neighbor. Try using the cache allocation technique
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to minimize the effect between applications.
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How to develop a custom code to debug?
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--------------------------------------
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#. For an application that runs as the primary process only, debug functionality
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is added in the same process. These can be invoked by timer call-back,
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service core and signal handler.
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#. For the application that runs as multiple processes. debug functionality in
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a standalone secondary process.
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