6a094e3285
This patch implements the Forwarding Information Base (FIB) library in l3fwd using the function calls and infrastructure introduced in the previous patch. Signed-off-by: Conor Walsh <conor.walsh@intel.com> Acked-by: Konstantin Ananyev <konstantin.ananyev@intel.com> Acked-by: Vladimir Medvedkin <vladimir.medvedkin@intel.com>
429 lines
17 KiB
ReStructuredText
429 lines
17 KiB
ReStructuredText
.. SPDX-License-Identifier: BSD-3-Clause
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Copyright(c) 2010-2014 Intel Corporation.
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L3 Forwarding Sample Application
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================================
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The L3 Forwarding application is a simple example of packet processing using
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DPDK to demonstrate usage of poll and event mode packet I/O mechanism.
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The application performs L3 forwarding.
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Overview
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--------
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The application demonstrates the use of the hash, LPM and FIB libraries in DPDK
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to implement packet forwarding using poll or event mode PMDs for packet I/O.
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The initialization and run-time paths are very similar to those of the
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:doc:`l2_forward_real_virtual` and :doc:`l2_forward_event`.
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The main difference from the L2 Forwarding sample application is that optionally
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packet can be Rx/Tx from/to eventdev instead of port directly and forwarding
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decision is made based on information read from the input packet.
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Eventdev can optionally use S/W or H/W (if supported by platform) scheduler
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implementation for packet I/O based on run time parameters.
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The lookup method is hash-based, LPM-based or FIB-based
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and is selected at run time.
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When the selected lookup method is hash-based,
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a hash object is used to emulate the flow classification stage.
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The hash object is used in correlation with a flow table to map each input packet to its flow at runtime.
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The hash lookup key is represented by a DiffServ 5-tuple composed of the following fields read from the input packet:
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Source IP Address, Destination IP Address, Protocol, Source Port and Destination Port.
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The ID of the output interface for the input packet is read from the identified flow table entry.
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The set of flows used by the application is statically configured and loaded into the hash at initialization time.
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When the selected lookup method is LPM or FIB based,
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an LPM or FIB object is used to emulate the forwarding stage for IPv4 packets.
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The LPM or FIB object is used as the routing table
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to identify the next hop for each input packet at runtime.
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The LPM and FIB lookup keys are represented by the destination IP address field
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read from the input packet.
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The ID of the output interface for the input packet is the next hop
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returned by the LPM or FIB lookup.
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The set of LPM and FIB rules used by the application is statically configured
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and loaded into the LPM or FIB object at initialization time.
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In the sample application, hash-based and FIB-based forwarding supports
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both IPv4 and IPv6.
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LPM-based forwarding supports IPv4 only.
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Compiling the Application
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-------------------------
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To compile the sample application see :doc:`compiling`.
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The application is located in the ``l3fwd`` sub-directory.
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Running the Application
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-----------------------
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The application has a number of command line options::
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./dpdk-l3fwd [EAL options] -- -p PORTMASK
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[-P]
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[--lookup LOOKUP_METHOD]
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--config(port,queue,lcore)[,(port,queue,lcore)]
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[--eth-dest=X,MM:MM:MM:MM:MM:MM]
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[--enable-jumbo [--max-pkt-len PKTLEN]]
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[--no-numa]
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[--hash-entry-num]
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[--ipv6]
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[--parse-ptype]
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[--per-port-pool]
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[--mode]
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[--eventq-sched]
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[--event-eth-rxqs]
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[-E]
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[-L]
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Where,
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* ``-p PORTMASK:`` Hexadecimal bitmask of ports to configure
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* ``-P:`` Optional, sets all ports to promiscuous mode so that packets are accepted regardless of the packet's Ethernet MAC destination address.
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Without this option, only packets with the Ethernet MAC destination address set to the Ethernet address of the port are accepted.
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* ``--lookup:`` Optional, select the lookup method.
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Accepted options:
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``em`` (Exact Match),
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``lpm`` (Longest Prefix Match),
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``fib`` (Forwarding Information Base).
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Default is ``lpm``.
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* ``--config (port,queue,lcore)[,(port,queue,lcore)]:`` Determines which queues from which ports are mapped to which cores.
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* ``--eth-dest=X,MM:MM:MM:MM:MM:MM:`` Optional, ethernet destination for port X.
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* ``--enable-jumbo:`` Optional, enables jumbo frames.
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* ``--max-pkt-len:`` Optional, under the premise of enabling jumbo, maximum packet length in decimal (64-9600).
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* ``--no-numa:`` Optional, disables numa awareness.
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* ``--hash-entry-num:`` Optional, specifies the hash entry number in hexadecimal to be setup.
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* ``--ipv6:`` Optional, set if running ipv6 packets.
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* ``--parse-ptype:`` Optional, set to use software to analyze packet type. Without this option, hardware will check the packet type.
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* ``--per-port-pool:`` Optional, set to use independent buffer pools per port. Without this option, single buffer pool is used for all ports.
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* ``--mode:`` Optional, Packet transfer mode for I/O, poll or eventdev.
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* ``--eventq-sched:`` Optional, Event queue synchronization method, Ordered, Atomic or Parallel. Only valid if --mode=eventdev.
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* ``--event-eth-rxqs:`` Optional, Number of ethernet RX queues per device. Only valid if --mode=eventdev.
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* ``-E:`` Optional, enable exact match,
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legacy flag, please use ``--lookup=em`` instead.
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* ``-L:`` Optional, enable longest prefix match,
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legacy flag, please use ``--lookup=lpm`` instead.
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For example, consider a dual processor socket platform with 8 physical cores, where cores 0-7 and 16-23 appear on socket 0,
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while cores 8-15 and 24-31 appear on socket 1.
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To enable L3 forwarding between two ports, assuming that both ports are in the same socket, using two cores, cores 1 and 2,
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(which are in the same socket too), use the following command:
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.. code-block:: console
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./<build_dir>/examples/dpdk-l3fwd -l 1,2 -n 4 -- -p 0x3 --config="(0,0,1),(1,0,2)"
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In this command:
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* The -l option enables cores 1, 2
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* The -p option enables ports 0 and 1
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* The --config option enables one queue on each port and maps each (port,queue) pair to a specific core.
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The following table shows the mapping in this example:
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+----------+-----------+-----------+-------------------------------------+
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| **Port** | **Queue** | **lcore** | **Description** |
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+----------+-----------+-----------+-------------------------------------+
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| 0 | 0 | 1 | Map queue 0 from port 0 to lcore 1. |
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+----------+-----------+-----------+-------------------------------------+
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| 1 | 0 | 2 | Map queue 0 from port 1 to lcore 2. |
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+----------+-----------+-----------+-------------------------------------+
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To use eventdev mode with sync method **ordered** on above mentioned environment,
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Following is the sample command:
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.. code-block:: console
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./<build_dir>/examples/dpdk-l3fwd -l 0-3 -n 4 -a <event device> -- -p 0x3 --eventq-sched=ordered
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or
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.. code-block:: console
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./<build_dir>/examples/dpdk-l3fwd -l 0-3 -n 4 -a <event device> \
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-- -p 0x03 --mode=eventdev --eventq-sched=ordered
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In this command:
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* -a option allows the event device supported by platform.
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The syntax used to indicate this device may vary based on platform.
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* The --mode option defines PMD to be used for packet I/O.
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* The --eventq-sched option enables synchronization menthod of event queue so that packets will be scheduled accordingly.
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If application uses S/W scheduler, it uses following DPDK services:
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* Software scheduler
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* Rx adapter service function
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* Tx adapter service function
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Application needs service cores to run above mentioned services. Service cores
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must be provided as EAL parameters along with the --vdev=event_sw0 to enable S/W
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scheduler. Following is the sample command:
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.. code-block:: console
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./<build_dir>/examples/dpdk-l3fwd -l 0-7 -s 0xf0000 -n 4 --vdev event_sw0 -- -p 0x3 --mode=eventdev --eventq-sched=ordered
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In case of eventdev mode, *--config* option is not used for ethernet port
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configuration. Instead each ethernet port will be configured with mentioned
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setup:
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* Single Rx/Tx queue
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* Each Rx queue will be connected to event queue via Rx adapter.
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* Each Tx queue will be connected via Tx adapter.
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Refer to the *DPDK Getting Started Guide* for general information on running applications and
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the Environment Abstraction Layer (EAL) options.
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.. _l3_fwd_explanation:
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Explanation
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-----------
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The following sections provide some explanation of the sample application code. As mentioned in the overview section,
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the initialization and run-time paths are very similar to those of the :doc:`l2_forward_real_virtual` and :doc:`l2_forward_event`.
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The following sections describe aspects that are specific to the L3 Forwarding sample application.
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Hash Initialization
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~~~~~~~~~~~~~~~~~~~
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The hash object is created and loaded with the pre-configured entries read from a global array,
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and then generate the expected 5-tuple as key to keep consistence with those of real flow
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for the convenience to execute hash performance test on 4M/8M/16M flows.
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.. note::
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The Hash initialization will setup both ipv4 and ipv6 hash table,
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and populate the either table depending on the value of variable ipv6.
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To support the hash performance test with up to 8M single direction flows/16M bi-direction flows,
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populate_ipv4_many_flow_into_table() function will populate the hash table with specified hash table entry number(default 4M).
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.. note::
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Value of global variable ipv6 can be specified with --ipv6 in the command line.
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Value of global variable hash_entry_number,
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which is used to specify the total hash entry number for all used ports in hash performance test,
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can be specified with --hash-entry-num VALUE in command line, being its default value 4.
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.. code-block:: c
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#if (APP_LOOKUP_METHOD == APP_LOOKUP_EXACT_MATCH)
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static void
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setup_hash(int socketid)
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{
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// ...
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if (hash_entry_number != HASH_ENTRY_NUMBER_DEFAULT) {
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if (ipv6 == 0) {
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/* populate the ipv4 hash */
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populate_ipv4_many_flow_into_table(ipv4_l3fwd_lookup_struct[socketid], hash_entry_number);
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} else {
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/* populate the ipv6 hash */
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populate_ipv6_many_flow_into_table( ipv6_l3fwd_lookup_struct[socketid], hash_entry_number);
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}
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} else
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if (ipv6 == 0) {
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/* populate the ipv4 hash */
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populate_ipv4_few_flow_into_table(ipv4_l3fwd_lookup_struct[socketid]);
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} else {
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/* populate the ipv6 hash */
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populate_ipv6_few_flow_into_table(ipv6_l3fwd_lookup_struct[socketid]);
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}
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}
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}
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#endif
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LPM Initialization
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~~~~~~~~~~~~~~~~~~
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The LPM object is created and loaded with the pre-configured entries read from a global array.
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.. code-block:: c
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#if (APP_LOOKUP_METHOD == APP_LOOKUP_LPM)
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static void
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setup_lpm(int socketid)
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{
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unsigned i;
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int ret;
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char s[64];
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/* create the LPM table */
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snprintf(s, sizeof(s), "IPV4_L3FWD_LPM_%d", socketid);
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ipv4_l3fwd_lookup_struct[socketid] = rte_lpm_create(s, socketid, IPV4_L3FWD_LPM_MAX_RULES, 0);
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if (ipv4_l3fwd_lookup_struct[socketid] == NULL)
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rte_exit(EXIT_FAILURE, "Unable to create the l3fwd LPM table"
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" on socket %d\n", socketid);
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/* populate the LPM table */
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for (i = 0; i < IPV4_L3FWD_NUM_ROUTES; i++) {
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/* skip unused ports */
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if ((1 << ipv4_l3fwd_route_array[i].if_out & enabled_port_mask) == 0)
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continue;
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ret = rte_lpm_add(ipv4_l3fwd_lookup_struct[socketid], ipv4_l3fwd_route_array[i].ip,
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ipv4_l3fwd_route_array[i].depth, ipv4_l3fwd_route_array[i].if_out);
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if (ret < 0) {
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rte_exit(EXIT_FAILURE, "Unable to add entry %u to the "
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"l3fwd LPM table on socket %d\n", i, socketid);
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}
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printf("LPM: Adding route 0x%08x / %d (%d)\n",
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(unsigned)ipv4_l3fwd_route_array[i].ip, ipv4_l3fwd_route_array[i].depth, ipv4_l3fwd_route_array[i].if_out);
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}
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}
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#endif
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FIB Initialization
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~~~~~~~~~~~~~~~~~~
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The FIB object is created and loaded with the pre-configured entries
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read from a global array.
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The abridged code snippet below shows the FIB initialization for IPv4,
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the full setup function including the IPv6 setup can be seen in the app code.
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.. literalinclude:: ../../../examples/l3fwd/l3fwd_fib.c
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:language: c
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:start-after: Function to setup fib.
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:end-before: Create the fib IPv6 table.
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Packet Forwarding for Hash-based Lookups
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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For each input packet, the packet forwarding operation is done by the l3fwd_simple_forward()
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or simple_ipv4_fwd_4pkts() function for IPv4 packets or the simple_ipv6_fwd_4pkts() function for IPv6 packets.
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The l3fwd_simple_forward() function provides the basic functionality for both IPv4 and IPv6 packet forwarding
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for any number of burst packets received,
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and the packet forwarding decision (that is, the identification of the output interface for the packet)
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for hash-based lookups is done by the get_ipv4_dst_port() or get_ipv6_dst_port() function.
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The get_ipv4_dst_port() function is shown below:
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.. code-block:: c
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static inline uint8_t
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get_ipv4_dst_port(void *ipv4_hdr, uint16_t portid, lookup_struct_t *ipv4_l3fwd_lookup_struct)
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{
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int ret = 0;
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union ipv4_5tuple_host key;
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ipv4_hdr = (uint8_t *)ipv4_hdr + offsetof(struct rte_ipv4_hdr, time_to_live);
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m128i data = _mm_loadu_si128(( m128i*)(ipv4_hdr));
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/* Get 5 tuple: dst port, src port, dst IP address, src IP address and protocol */
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key.xmm = _mm_and_si128(data, mask0);
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/* Find destination port */
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ret = rte_hash_lookup(ipv4_l3fwd_lookup_struct, (const void *)&key);
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return (uint8_t)((ret < 0)? portid : ipv4_l3fwd_out_if[ret]);
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}
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The get_ipv6_dst_port() function is similar to the get_ipv4_dst_port() function.
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The simple_ipv4_fwd_4pkts() and simple_ipv6_fwd_4pkts() function are optimized for continuous 4 valid ipv4 and ipv6 packets,
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they leverage the multiple buffer optimization to boost the performance of forwarding packets with the exact match on hash table.
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The key code snippet of simple_ipv4_fwd_4pkts() is shown below:
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.. code-block:: c
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static inline void
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simple_ipv4_fwd_4pkts(struct rte_mbuf* m[4], uint16_t portid, struct lcore_conf *qconf)
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{
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// ...
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data[0] = _mm_loadu_si128(( m128i*)(rte_pktmbuf_mtod(m[0], unsigned char *) + sizeof(struct rte_ether_hdr) + offsetof(struct rte_ipv4_hdr, time_to_live)));
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data[1] = _mm_loadu_si128(( m128i*)(rte_pktmbuf_mtod(m[1], unsigned char *) + sizeof(struct rte_ether_hdr) + offsetof(struct rte_ipv4_hdr, time_to_live)));
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data[2] = _mm_loadu_si128(( m128i*)(rte_pktmbuf_mtod(m[2], unsigned char *) + sizeof(struct rte_ether_hdr) + offsetof(struct rte_ipv4_hdr, time_to_live)));
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data[3] = _mm_loadu_si128(( m128i*)(rte_pktmbuf_mtod(m[3], unsigned char *) + sizeof(struct rte_ether_hdr) + offsetof(struct rte_ipv4_hdr, time_to_live)));
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key[0].xmm = _mm_and_si128(data[0], mask0);
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key[1].xmm = _mm_and_si128(data[1], mask0);
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key[2].xmm = _mm_and_si128(data[2], mask0);
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key[3].xmm = _mm_and_si128(data[3], mask0);
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const void *key_array[4] = {&key[0], &key[1], &key[2],&key[3]};
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rte_hash_lookup_bulk(qconf->ipv4_lookup_struct, &key_array[0], 4, ret);
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dst_port[0] = (ret[0] < 0)? portid:ipv4_l3fwd_out_if[ret[0]];
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dst_port[1] = (ret[1] < 0)? portid:ipv4_l3fwd_out_if[ret[1]];
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dst_port[2] = (ret[2] < 0)? portid:ipv4_l3fwd_out_if[ret[2]];
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dst_port[3] = (ret[3] < 0)? portid:ipv4_l3fwd_out_if[ret[3]];
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// ...
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}
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The simple_ipv6_fwd_4pkts() function is similar to the simple_ipv4_fwd_4pkts() function.
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Known issue: IP packets with extensions or IP packets which are not TCP/UDP cannot work well at this mode.
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Packet Forwarding for LPM-based Lookups
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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For each input packet, the packet forwarding operation is done by the l3fwd_simple_forward() function,
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but the packet forwarding decision (that is, the identification of the output interface for the packet)
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for LPM-based lookups is done by the get_ipv4_dst_port() function below:
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.. code-block:: c
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static inline uint16_t
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get_ipv4_dst_port(struct rte_ipv4_hdr *ipv4_hdr, uint16_t portid, lookup_struct_t *ipv4_l3fwd_lookup_struct)
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{
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uint8_t next_hop;
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return ((rte_lpm_lookup(ipv4_l3fwd_lookup_struct, rte_be_to_cpu_32(ipv4_hdr->dst_addr), &next_hop) == 0)? next_hop : portid);
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}
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Packet Forwarding for FIB-based Lookups
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The FIB library was designed to process multiple packets at once,
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it does not have separate functions for single and bulk lookups.
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``rte_fib_lookup_bulk`` is used for IPv4 lookups
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and ``rte_fib6_lookup_bulk`` for IPv6.
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Various examples of these functions being used
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can be found in the sample app code.
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Eventdev Driver Initialization
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Eventdev driver initialization is same as L2 forwarding eventdev application.
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Refer :doc:`l2_forward_event` for more details.
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