.. SPDX-License-Identifier: BSD-3-Clause Copyright(c) 2015 Intel Corporation. RX/TX Callbacks Sample Application ================================== The RX/TX Callbacks sample application is a packet forwarding application that demonstrates the use of user defined callbacks on received and transmitted packets. The application performs a simple latency check, using callbacks, to determine the time packets spend within the application. In the sample application a user defined callback is applied to all received packets to add a timestamp. A separate callback is applied to all packets prior to transmission to calculate the elapsed time, in CPU cycles. If hardware timestamping is supported by the NIC, the sample application will also display the average latency since the packet was timestamped in hardware, on top of the latency since the packet was received and processed by the RX callback. Compiling the Application ------------------------- To compile the sample application see :doc:`compiling`. The application is located in the ``rxtx_callbacks`` sub-directory. The callbacks feature requires that the ``CONFIG_RTE_ETHDEV_RXTX_CALLBACKS`` setting is on in the ``config/common_`` config file that applies to the target. This is generally on by default: .. code-block:: console CONFIG_RTE_ETHDEV_RXTX_CALLBACKS=y Running the Application ----------------------- To run the example in a ``linux`` environment: .. code-block:: console ./build/rxtx_callbacks -l 1 -n 4 -- [-t] Use -t to enable hardware timestamping. If not supported by the NIC, an error will be displayed. Refer to *DPDK Getting Started Guide* for general information on running applications and the Environment Abstraction Layer (EAL) options. Explanation ----------- The ``rxtx_callbacks`` application is mainly a simple forwarding application based on the :doc:`skeleton`. See that section of the documentation for more details of the forwarding part of the application. The sections below explain the additional RX/TX callback code. The Main Function ~~~~~~~~~~~~~~~~~ The ``main()`` function performs the application initialization and calls the execution threads for each lcore. This function is effectively identical to the ``main()`` function explained in :doc:`skeleton`. The ``lcore_main()`` function is also identical. The main difference is in the user defined ``port_init()`` function where the callbacks are added. This is explained in the next section: The Port Initialization Function ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The main functional part of the port initialization is shown below with comments: .. code-block:: c static inline int port_init(uint16_t port, struct rte_mempool *mbuf_pool) { struct rte_eth_conf port_conf = port_conf_default; const uint16_t rx_rings = 1, tx_rings = 1; struct rte_ether_addr addr; int retval; uint16_t q; /* Configure the Ethernet device. */ retval = rte_eth_dev_configure(port, rx_rings, tx_rings, &port_conf); if (retval != 0) return retval; /* Allocate and set up 1 RX queue per Ethernet port. */ for (q = 0; q < rx_rings; q++) { retval = rte_eth_rx_queue_setup(port, q, RX_RING_SIZE, rte_eth_dev_socket_id(port), NULL, mbuf_pool); if (retval < 0) return retval; } /* Allocate and set up 1 TX queue per Ethernet port. */ for (q = 0; q < tx_rings; q++) { retval = rte_eth_tx_queue_setup(port, q, TX_RING_SIZE, rte_eth_dev_socket_id(port), NULL); if (retval < 0) return retval; } /* Start the Ethernet port. */ retval = rte_eth_dev_start(port); if (retval < 0) return retval; /* Enable RX in promiscuous mode for the Ethernet device. */ retval = rte_eth_promiscuous_enable(port); if (retval != 0) return retval; /* Add the callbacks for RX and TX.*/ rte_eth_add_rx_callback(port, 0, add_timestamps, NULL); rte_eth_add_tx_callback(port, 0, calc_latency, NULL); return 0; } The RX and TX callbacks are added to the ports/queues as function pointers: .. code-block:: c rte_eth_add_rx_callback(port, 0, add_timestamps, NULL); rte_eth_add_tx_callback(port, 0, calc_latency, NULL); More than one callback can be added and additional information can be passed to callback function pointers as a ``void*``. In the examples above ``NULL`` is used. The ``add_timestamps()`` and ``calc_latency()`` functions are explained below. The add_timestamps() Callback ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The ``add_timestamps()`` callback is added to the RX port and is applied to all packets received: .. code-block:: c static uint16_t add_timestamps(uint16_t port __rte_unused, uint16_t qidx __rte_unused, struct rte_mbuf **pkts, uint16_t nb_pkts, void *_ __rte_unused) { unsigned i; uint64_t now = rte_rdtsc(); for (i = 0; i < nb_pkts; i++) pkts[i]->udata64 = now; return nb_pkts; } The DPDK function ``rte_rdtsc()`` is used to add a cycle count timestamp to each packet (see the *cycles* section of the *DPDK API Documentation* for details). The calc_latency() Callback ~~~~~~~~~~~~~~~~~~~~~~~~~~~ The ``calc_latency()`` callback is added to the TX port and is applied to all packets prior to transmission: .. code-block:: c static uint16_t calc_latency(uint16_t port __rte_unused, uint16_t qidx __rte_unused, struct rte_mbuf **pkts, uint16_t nb_pkts, void *_ __rte_unused) { uint64_t cycles = 0; uint64_t now = rte_rdtsc(); unsigned i; for (i = 0; i < nb_pkts; i++) cycles += now - pkts[i]->udata64; latency_numbers.total_cycles += cycles; latency_numbers.total_pkts += nb_pkts; if (latency_numbers.total_pkts > (100 * 1000 * 1000ULL)) { printf("Latency = %"PRIu64" cycles\n", latency_numbers.total_cycles / latency_numbers.total_pkts); latency_numbers.total_cycles = latency_numbers.total_pkts = 0; } return nb_pkts; } The ``calc_latency()`` function accumulates the total number of packets and the total number of cycles used. Once more than 100 million packets have been transmitted the average cycle count per packet is printed out and the counters are reset.