* Provides a faster mechanism to interface with the kernel net stack and eliminates system calls
-* Facilitates the DPDK using standard Linux* userspace net tools (tcpdump, ftp, and so on)
+* Facilitates the DPDK using standard Linux* userspace net tools (tshark, rsync, and so on)
* Eliminate the copy_to_user and copy_from_user operations on packets.
The Kernel NIC Interface sample application is a simple example that demonstrates the use
of the DPDK to create a path for packets to go through the Linux* kernel.
This is done by creating one or more kernel net devices for each of the DPDK ports.
-The application allows the use of standard Linux tools (ethtool, ifconfig, tcpdump) with the DPDK ports and
+The application allows the use of standard Linux tools (ethtool, iproute, tshark) with the DPDK ports and
also the exchange of packets between the DPDK application and the Linux* kernel.
+The Kernel NIC Interface sample application requires that the
+KNI kernel module ``rte_kni`` be loaded into the kernel. See
+:doc:`../prog_guide/kernel_nic_interface` for more information on loading
+the ``rte_kni`` kernel module.
+
Overview
--------
-The Kernel NIC Interface sample application uses two threads in user space for each physical NIC port being used,
-and allocates one or more KNI device for each physical NIC port with kernel module's support.
-For a physical NIC port, one thread reads from the port and writes to KNI devices,
-and another thread reads from KNI devices and writes the data unmodified to the physical NIC port.
-It is recommended to configure one KNI device for each physical NIC port.
-If configured with more than one KNI devices for a physical NIC port,
-it is just for performance testing, or it can work together with VMDq support in future.
+The Kernel NIC Interface sample application ``kni`` allocates one or more
+KNI interfaces for each physical NIC port. For each physical NIC port,
+``kni`` uses two DPDK threads in user space; one thread reads from the port and
+writes to the corresponding KNI interfaces and the other thread reads from
+the KNI interfaces and writes the data unmodified to the physical NIC port.
+
+It is recommended to configure one KNI interface for each physical NIC port.
+The application can be configured with more than one KNI interface for
+each physical NIC port for performance testing or it can work together with
+VMDq support in future.
-The packet flow through the Kernel NIC Interface application is as shown in the following figure.
+The packet flow through the Kernel NIC Interface application is as shown
+in the following figure.
.. _figure_kernel_nic:
Kernel NIC Application Packet Flow
+If link monitoring is enabled with the ``-m`` command line flag, one
+additional pthread is launched which will check the link status of each
+physical NIC port and will update the carrier status of the corresponding
+KNI interface(s) to match the physical NIC port's state. This means that
+the KNI interface(s) will be disabled automatically when the Ethernet link
+goes down and enabled when the Ethernet link goes up.
+
+If link monitoring is enabled, the ``rte_kni`` kernel module should be loaded
+such that the :ref:`default carrier state <kni_default_carrier_state>` is
+set to *off*. This ensures that the KNI interface is only enabled *after*
+the Ethernet link of the corresponding NIC port has reached the linkup state.
+
+If link monitoring is not enabled, the ``rte_kni`` kernel module should be
+loaded with the :ref:`default carrier state <kni_default_carrier_state>`
+set to *on*. This sets the carrier state of the KNI interfaces to *on*
+when the KNI interfaces are enabled without regard to the actual link state
+of the corresponding NIC port. This is useful for testing in loopback
+mode where the NIC port may not be physically connected to anything.
+
Compiling the Application
-------------------------
To compile the sample application see :doc:`compiling`.
-The application is located in the ``kni`` sub-directory.
+The application is located in the ``examples/kni`` sub-directory.
.. note::
- This application is intended as a linuxapp only.
+ This application is intended as a linux only.
-Loading the Kernel Module
--------------------------
+Running the kni Example Application
+-----------------------------------
-Loading the KNI kernel module without any parameter is the typical way a DPDK application
-gets packets into and out of the kernel net stack.
-This way, only one kernel thread is created for all KNI devices for packet receiving in kernel side:
+The ``kni`` example application requires a number of command line options:
.. code-block:: console
- #insmod rte_kni.ko
+ dpdk-kni [EAL options] -- -p PORTMASK --config="(port,lcore_rx,lcore_tx[,lcore_kthread,...])[,(port,lcore_rx,lcore_tx[,lcore_kthread,...])]" [-P] [-m]
-Pinning the kernel thread to a specific core can be done using a taskset command such as following:
+Where:
-.. code-block:: console
+* ``-p PORTMASK``:
- #taskset -p 100000 `pgrep --fl kni_thread | awk '{print $1}'`
+ Hexadecimal bitmask of ports to configure.
-This command line tries to pin the specific kni_thread on the 20th lcore (lcore numbering starts at 0),
-which means it needs to check if that lcore is available on the board.
-This command must be sent after the application has been launched, as insmod does not start the kni thread.
+* ``--config="(port,lcore_rx,lcore_tx[,lcore_kthread,...])[,(port,lcore_rx,lcore_tx[,lcore_kthread,...])]"``:
-For optimum performance,
-the lcore in the mask must be selected to be on the same socket as the lcores used in the KNI application.
+ Determines which lcores the Rx and Tx DPDK tasks, and (optionally)
+ the KNI kernel thread(s) are bound to for each physical port.
-To provide flexibility of performance, the kernel module of the KNI,
-located in the kmod sub-directory of the DPDK target directory,
-can be loaded with parameter of kthread_mode as follows:
+* ``-P``:
-* #insmod rte_kni.ko kthread_mode=single
+ Optional flag to set all ports to promiscuous mode so that packets are
+ accepted regardless of the packet's Ethernet MAC destination address.
+ Without this option, only packets with the Ethernet MAC destination
+ address set to the Ethernet address of the port are accepted.
- This mode will create only one kernel thread for all KNI devices for packet receiving in kernel side.
- By default, it is in this single kernel thread mode.
- It can set core affinity for this kernel thread by using Linux command taskset.
+* ``-m``:
-* #insmod rte_kni.ko kthread_mode =multiple
+ Optional flag to enable monitoring and updating of the Ethernet
+ carrier state. With this option set, a thread will be started which
+ will periodically check the Ethernet link status of the physical
+ Ethernet ports and set the carrier state of the corresponding KNI
+ network interface to match it. This means that the KNI interface will
+ be disabled automatically when the Ethernet link goes down and enabled
+ when the Ethernet link goes up.
- This mode will create a kernel thread for each KNI device for packet receiving in kernel side.
- The core affinity of each kernel thread is set when creating the KNI device.
- The lcore ID for each kernel thread is provided in the command line of launching the application.
- Multiple kernel thread mode can provide scalable higher performance.
+Refer to *DPDK Getting Started Guide* for general information on running
+applications and the Environment Abstraction Layer (EAL) options.
-To measure the throughput in a loopback mode, the kernel module of the KNI,
-located in the kmod sub-directory of the DPDK target directory,
-can be loaded with parameters as follows:
+The ``-c coremask`` or ``-l corelist`` parameter of the EAL options must
+include the lcores specified by ``lcore_rx`` and ``lcore_tx`` for each port,
+but does not need to include lcores specified by ``lcore_kthread`` as those
+cores are used to pin the kernel threads in the ``rte_kni`` kernel module.
-* #insmod rte_kni.ko lo_mode=lo_mode_fifo
+The ``--config`` parameter must include a set of
+``(port,lcore_rx,lcore_tx,[lcore_kthread,...])`` values for each physical
+port specified in the ``-p PORTMASK`` parameter.
- This loopback mode will involve ring enqueue/dequeue operations in kernel space.
+The optional ``lcore_kthread`` lcore ID parameter in ``--config`` can be
+specified zero, one or more times for each physical port.
-* #insmod rte_kni.ko lo_mode=lo_mode_fifo_skb
+If no lcore ID is specified for ``lcore_kthread``, one KNI interface will
+be created for the physical port ``port`` and the KNI kernel thread(s)
+will have no specific core affinity.
- This loopback mode will involve ring enqueue/dequeue operations and sk buffer copies in kernel space.
+If one or more lcore IDs are specified for ``lcore_kthread``, a KNI interface
+will be created for each lcore ID specified, bound to the physical port
+``port``. If the ``rte_kni`` kernel module is loaded in :ref:`multiple
+kernel thread <kni_kernel_thread_mode>` mode, a kernel thread will be created
+for each KNI interface and bound to the specified core. If the ``rte_kni``
+kernel module is loaded in :ref:`single kernel thread <kni_kernel_thread_mode>`
+mode, only one kernel thread is started for all KNI interfaces. The kernel
+thread will be bound to the first ``lcore_kthread`` lcore ID specified.
-Running the Application
------------------------
+Example Configurations
+~~~~~~~~~~~~~~~~~~~~~~~
-The application requires a number of command line options:
+The following commands will first load the ``rte_kni`` kernel module in
+:ref:`multiple kernel thread <kni_kernel_thread_mode>` mode. The ``kni``
+application is then started using two ports; Port 0 uses lcore 4 for the
+Rx task, lcore 6 for the Tx task, and will create a single KNI interface
+``vEth0_0`` with the kernel thread bound to lcore 8. Port 1 uses lcore
+5 for the Rx task, lcore 7 for the Tx task, and will create a single KNI
+interface ``vEth1_0`` with the kernel thread bound to lcore 9.
.. code-block:: console
- kni [EAL options] -- -P -p PORTMASK --config="(port,lcore_rx,lcore_tx[,lcore_kthread,...])[,port,lcore_rx,lcore_tx[,lcore_kthread,...]]"
+ # rmmod rte_kni
+ # insmod <build_dir>/kernel/linux/kni/rte_kni.ko kthread_mode=multiple
+ # ./<build-dir>/examples/dpdk-kni -l 4-7 -n 4 -- -P -p 0x3 -m --config="(0,4,6,8),(1,5,7,9)"
-Where:
-
-* -P: Set all ports to promiscuous mode so that packets are accepted regardless of the packet's Ethernet MAC destination address.
- Without this option, only packets with the Ethernet MAC destination address set to the Ethernet address of the port are accepted.
+The following example is identical, except an additional ``lcore_kthread``
+core is specified per physical port. In this case, ``kni`` will create
+four KNI interfaces: ``vEth0_0``/``vEth0_1`` bound to physical port 0 and
+``vEth1_0``/``vEth1_1`` bound to physical port 1.
-* -p PORTMASK: Hexadecimal bitmask of ports to configure.
+The kernel thread for each interface will be bound as follows:
-* --config="(port,lcore_rx, lcore_tx[,lcore_kthread, ...]) [, port,lcore_rx, lcore_tx[,lcore_kthread, ...]]":
- Determines which lcores of RX, TX, kernel thread are mapped to which ports.
+ * ``vEth0_0`` - bound to lcore 8.
+ * ``vEth0_1`` - bound to lcore 10.
+ * ``vEth1_0`` - bound to lcore 9.
+ * ``vEth1_1`` - bound to lcore 11
-Refer to *DPDK Getting Started Guide* for general information on running applications and the Environment Abstraction Layer (EAL) options.
+.. code-block:: console
-The -c coremask or -l corelist parameter of the EAL options should include the lcores indicated by the lcore_rx and lcore_tx,
-but does not need to include lcores indicated by lcore_kthread as they are used to pin the kernel thread on.
-The -p PORTMASK parameter should include the ports indicated by the port in --config, neither more nor less.
+ # rmmod rte_kni
+ # insmod <build_dir>/kernel/linux/kni/rte_kni.ko kthread_mode=multiple
+ # ./<build-dir>/examples/dpdk-kni -l 4-7 -n 4 -- -P -p 0x3 -m --config="(0,4,6,8,10),(1,5,7,9,11)"
-The lcore_kthread in --config can be configured none, one or more lcore IDs.
-In multiple kernel thread mode, if configured none, a KNI device will be allocated for each port,
-while no specific lcore affinity will be set for its kernel thread.
-If configured one or more lcore IDs, one or more KNI devices will be allocated for each port,
-while specific lcore affinity will be set for its kernel thread.
-In single kernel thread mode, if configured none, a KNI device will be allocated for each port.
-If configured one or more lcore IDs,
-one or more KNI devices will be allocated for each port while
-no lcore affinity will be set as there is only one kernel thread for all KNI devices.
+The following example can be used to test the interface between the ``kni``
+test application and the ``rte_kni`` kernel module. In this example,
+the ``rte_kni`` kernel module is loaded in :ref:`single kernel thread
+mode <kni_kernel_thread_mode>`, :ref:`loopback mode <kni_loopback_mode>`
+enabled, and the :ref:`default carrier state <kni_default_carrier_state>`
+is set to *on* so that the corresponding physical NIC port does not have
+to be connected in order to use the KNI interface. One KNI interface
+``vEth0_0`` is created for port 0 and one KNI interface ``vEth1_0`` is
+created for port 1. Since ``rte_kni`` is loaded in "single kernel thread"
+mode, the one kernel thread is bound to lcore 8.
-For example, to run the application with two ports served by six lcores, one lcore of RX, one lcore of TX,
-and one lcore of kernel thread for each port:
+Since the physical NIC ports are not being used, link monitoring can be
+disabled by **not** specifying the ``-m`` flag to ``kni``:
.. code-block:: console
- ./build/kni -l 4-7 -n 4 -- -P -p 0x3 --config="(0,4,6,8),(1,5,7,9)"
+ # rmmod rte_kni
+ # insmod <build_dir>/kernel/linux/kni/rte_kni.ko lo_mode=lo_mode_fifo carrier=on
+ # ./<build-dir>/examples/dpdk-kni -l 4-7 -n 4 -- -P -p 0x3 --config="(0,4,6,8),(1,5,7,9)"
KNI Operations
--------------
-Once the KNI application is started, one can use different Linux* commands to manage the net interfaces.
-If more than one KNI devices configured for a physical port,
-only the first KNI device will be paired to the physical device.
-Operations on other KNI devices will not affect the physical port handled in user space application.
+Once the ``kni`` application is started, the user can use the normal
+Linux commands to manage the KNI interfaces as if they were any other
+Linux network interface.
-Assigning an IP address:
+Enable KNI interface and assign an IP address:
.. code-block:: console
- #ifconfig vEth0_0 192.168.0.1
+ # ip addr add dev vEth0_0 192.168.0.1
-Displaying the NIC registers:
+Show KNI interface configuration and statistics:
.. code-block:: console
- #ethtool -d vEth0_0
+ # ip -s -d addr show vEth0_0
-Dumping the network traffic:
+The user can also check and reset the packet statistics inside the ``kni``
+application by sending the app the USR1 and USR2 signals:
.. code-block:: console
- #tcpdump -i vEth0_0
-
-Change the MAC address:
+ # Print statistics
+ # pkill -USR1 kni
-.. code-block:: console
-
- #ifconfig vEth0_0 hw ether 0C:01:02:03:04:08
-
-When the DPDK userspace application is closed, all the KNI devices are deleted from Linux*.
-
-Explanation
------------
-
-The following sections provide some explanation of code.
-
-Initialization
-~~~~~~~~~~~~~~
+ # Zero statistics
+ # pkill -USR2 kni
-Setup of mbuf pool, driver and queues is similar to the setup done in the :doc:`l2_forward_real_virtual`..
-In addition, one or more kernel NIC interfaces are allocated for each
-of the configured ports according to the command line parameters.
+Dump network traffic:
-The code for allocating the kernel NIC interfaces for a specific port is as follows:
+.. code-block:: console
-.. code-block:: c
+ # tshark -n -i vEth0_0
- static int
- kni_alloc(uint16_t port_id)
- {
- uint8_t i;
- struct rte_kni *kni;
- struct rte_kni_conf conf;
- struct kni_port_params **params = kni_port_params_array;
+The normal Linux commands can also be used to change the MAC address and
+MTU size used by the physical NIC which corresponds to the KNI interface.
+However, if more than one KNI interface is configured for a physical port,
+these commands will only work on the first KNI interface for that port.
- if (port_id >= RTE_MAX_ETHPORTS || !params[port_id])
- return -1;
+Change the MAC address:
- params[port_id]->nb_kni = params[port_id]->nb_lcore_k ? params[port_id]->nb_lcore_k : 1;
+.. code-block:: console
- for (i = 0; i < params[port_id]->nb_kni; i++) {
+ # ip link set dev vEth0_0 lladdr 0C:01:02:03:04:08
- /* Clear conf at first */
+Change the MTU size:
- memset(&conf, 0, sizeof(conf));
- if (params[port_id]->nb_lcore_k) {
- snprintf(conf.name, RTE_KNI_NAMESIZE, "vEth%u_%u", port_id, i);
- conf.core_id = params[port_id]->lcore_k[i];
- conf.force_bind = 1;
- } else
- snprintf(conf.name, RTE_KNI_NAMESIZE, "vEth%u", port_id);
- conf.group_id = (uint16_t)port_id;
- conf.mbuf_size = MAX_PACKET_SZ;
+.. code-block:: console
- /*
- * The first KNI device associated to a port
- * is the master, for multiple kernel thread
- * environment.
- */
+ # ip link set dev vEth0_0 mtu 1450
- if (i == 0) {
- struct rte_kni_ops ops;
- struct rte_eth_dev_info dev_info;
+Limited ethtool support:
- memset(&dev_info, 0, sizeof(dev_info)); rte_eth_dev_info_get(port_id, &dev_info);
+.. code-block:: console
- conf.addr = dev_info.pci_dev->addr;
- conf.id = dev_info.pci_dev->id;
+ # ethtool -i vEth0_0
- /* Get the interface default mac address */
- rte_eth_macaddr_get(port_id, (struct ether_addr *)&conf.mac_addr);
+When the ``kni`` application is closed, all the KNI interfaces are deleted
+from the Linux kernel.
- memset(&ops, 0, sizeof(ops));
+Explanation
+-----------
- ops.port_id = port_id;
- ops.change_mtu = kni_change_mtu;
- ops.config_network_if = kni_config_network_interface;
- ops.config_mac_address = kni_config_mac_address;
+The following sections provide some explanation of code.
- kni = rte_kni_alloc(pktmbuf_pool, &conf, &ops);
- } else
- kni = rte_kni_alloc(pktmbuf_pool, &conf, NULL);
+Initialization
+~~~~~~~~~~~~~~
- if (!kni)
- rte_exit(EXIT_FAILURE, "Fail to create kni for "
- "port: %d\n", port_id);
+Setup of mbuf pool, driver and queues is similar to the setup done in the :doc:`l2_forward_real_virtual`..
+In addition, one or more kernel NIC interfaces are allocated for each
+of the configured ports according to the command line parameters.
- params[port_id]->kni[i] = kni;
- }
- return 0;
- }
+The code for allocating the kernel NIC interfaces for a specific port is
+in the function ``kni_alloc``.
The other step in the initialization process that is unique to this sample application
is the association of each port with lcores for RX, TX and kernel threads.
* Other lcores for pinning the kernel threads on one by one
-This is done by using the`kni_port_params_array[]` array, which is indexed by the port ID.
-The code is as follows:
-
-.. code-block:: console
-
- static int
- parse_config(const char *arg)
- {
- const char *p, *p0 = arg;
- char s[256], *end;
- unsigned size;
- enum fieldnames {
- FLD_PORT = 0,
- FLD_LCORE_RX,
- FLD_LCORE_TX,
- _NUM_FLD = KNI_MAX_KTHREAD + 3,
- };
- int i, j, nb_token;
- char *str_fld[_NUM_FLD];
- unsigned long int_fld[_NUM_FLD];
- uint16_t port_id, nb_kni_port_params = 0;
-
- memset(&kni_port_params_array, 0, sizeof(kni_port_params_array));
-
- while (((p = strchr(p0, '(')) != NULL) && nb_kni_port_params < RTE_MAX_ETHPORTS) {
- p++;
- if ((p0 = strchr(p, ')')) == NULL)
- goto fail;
-
- size = p0 - p;
-
- if (size >= sizeof(s)) {
- printf("Invalid config parameters\n");
- goto fail;
- }
-
- snprintf(s, sizeof(s), "%.*s", size, p);
- nb_token = rte_strsplit(s, sizeof(s), str_fld, _NUM_FLD, ',');
-
- if (nb_token <= FLD_LCORE_TX) {
- printf("Invalid config parameters\n");
- goto fail;
- }
-
- for (i = 0; i < nb_token; i++) {
- errno = 0;
- int_fld[i] = strtoul(str_fld[i], &end, 0);
- if (errno != 0 || end == str_fld[i]) {
- printf("Invalid config parameters\n");
- goto fail;
- }
- }
-
- i = 0;
- port_id = (uint8_t)int_fld[i++];
-
- if (port_id >= RTE_MAX_ETHPORTS) {
- printf("Port ID %u could not exceed the maximum %u\n", port_id, RTE_MAX_ETHPORTS);
- goto fail;
- }
-
- if (kni_port_params_array[port_id]) {
- printf("Port %u has been configured\n", port_id);
- goto fail;
- }
-
- kni_port_params_array[port_id] = (struct kni_port_params*)rte_zmalloc("KNI_port_params", sizeof(struct kni_port_params), RTE_CACHE_LINE_SIZE);
- kni_port_params_array[port_id]->port_id = port_id;
- kni_port_params_array[port_id]->lcore_rx = (uint8_t)int_fld[i++];
- kni_port_params_array[port_id]->lcore_tx = (uint8_t)int_fld[i++];
-
- if (kni_port_params_array[port_id]->lcore_rx >= RTE_MAX_LCORE || kni_port_params_array[port_id]->lcore_tx >= RTE_MAX_LCORE) {
- printf("lcore_rx %u or lcore_tx %u ID could not "
- "exceed the maximum %u\n",
- kni_port_params_array[port_id]->lcore_rx, kni_port_params_array[port_id]->lcore_tx, RTE_MAX_LCORE);
- goto fail;
- }
-
- for (j = 0; i < nb_token && j < KNI_MAX_KTHREAD; i++, j++)
- kni_port_params_array[port_id]->lcore_k[j] = (uint8_t)int_fld[i];
- kni_port_params_array[port_id]->nb_lcore_k = j;
- }
-
- print_config();
-
- return 0;
-
- fail:
-
- for (i = 0; i < RTE_MAX_ETHPORTS; i++) {
- if (kni_port_params_array[i]) {
- rte_free(kni_port_params_array[i]);
- kni_port_params_array[i] = NULL;
- }
- }
-
- return -1;
-
- }
+This is done by using the ``kni_port_params_array[]`` array, which is indexed by the port ID.
+The code is in the function ``parse_config``.
Packet Forwarding
~~~~~~~~~~~~~~~~~
This function first checks the lcore_id against the user provided lcore_rx and lcore_tx
to see if this lcore is reading from or writing to kernel NIC interfaces.
-For the case that reads from a NIC port and writes to the kernel NIC interfaces,
+For the case that reads from a NIC port and writes to the kernel NIC interfaces (``kni_ingress``),
the packet reception is the same as in L2 Forwarding sample application
(see :ref:`l2_fwd_app_rx_tx_packets`).
-The packet transmission is done by sending mbufs into the kernel NIC interfaces by rte_kni_tx_burst().
+The packet transmission is done by sending mbufs into the kernel NIC interfaces by ``rte_kni_tx_burst()``.
The KNI library automatically frees the mbufs after the kernel successfully copied the mbufs.
-.. code-block:: c
-
- /**
- * Interface to burst rx and enqueue mbufs into rx_q
- */
-
- static void
- kni_ingress(struct kni_port_params *p)
- {
- uint8_t i, nb_kni, port_id;
- unsigned nb_rx, num;
- struct rte_mbuf *pkts_burst[PKT_BURST_SZ];
-
- if (p == NULL)
- return;
-
- nb_kni = p->nb_kni;
- port_id = p->port_id;
-
- for (i = 0; i < nb_kni; i++) {
- /* Burst rx from eth */
- nb_rx = rte_eth_rx_burst(port_id, 0, pkts_burst, PKT_BURST_SZ);
- if (unlikely(nb_rx > PKT_BURST_SZ)) {
- RTE_LOG(ERR, APP, "Error receiving from eth\n");
- return;
- }
-
- /* Burst tx to kni */
- num = rte_kni_tx_burst(p->kni[i], pkts_burst, nb_rx);
- kni_stats[port_id].rx_packets += num;
- rte_kni_handle_request(p->kni[i]);
-
- if (unlikely(num < nb_rx)) {
- /* Free mbufs not tx to kni interface */
- kni_burst_free_mbufs(&pkts_burst[num], nb_rx - num);
- kni_stats[port_id].rx_dropped += nb_rx - num;
- }
- }
- }
-
-For the other case that reads from kernel NIC interfaces and writes to a physical NIC port, packets are retrieved by reading
-mbufs from kernel NIC interfaces by `rte_kni_rx_burst()`.
+For the other case that reads from kernel NIC interfaces
+and writes to a physical NIC port (``kni_egress``),
+packets are retrieved by reading mbufs from kernel NIC interfaces by ``rte_kni_rx_burst()``.
The packet transmission is the same as in the L2 Forwarding sample application
(see :ref:`l2_fwd_app_rx_tx_packets`).
-
-.. code-block:: c
-
- /**
- * Interface to dequeue mbufs from tx_q and burst tx
- */
-
- static void
-
- kni_egress(struct kni_port_params *p)
- {
- uint8_t i, nb_kni, port_id;
- unsigned nb_tx, num;
- struct rte_mbuf *pkts_burst[PKT_BURST_SZ];
-
- if (p == NULL)
- return;
-
- nb_kni = p->nb_kni;
- port_id = p->port_id;
-
- for (i = 0; i < nb_kni; i++) {
- /* Burst rx from kni */
- num = rte_kni_rx_burst(p->kni[i], pkts_burst, PKT_BURST_SZ);
- if (unlikely(num > PKT_BURST_SZ)) {
- RTE_LOG(ERR, APP, "Error receiving from KNI\n");
- return;
- }
-
- /* Burst tx to eth */
-
- nb_tx = rte_eth_tx_burst(port_id, 0, pkts_burst, (uint16_t)num);
-
- kni_stats[port_id].tx_packets += nb_tx;
-
- if (unlikely(nb_tx < num)) {
- /* Free mbufs not tx to NIC */
- kni_burst_free_mbufs(&pkts_burst[nb_tx], num - nb_tx);
- kni_stats[port_id].tx_dropped += num - nb_tx;
- }
- }
- }
-
-Callbacks for Kernel Requests
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-
-To execute specific PMD operations in user space requested by some Linux* commands,
-callbacks must be implemented and filled in the struct rte_kni_ops structure.
-Currently, setting a new MTU, change in MAC address, configuring promiscusous mode and
-configuring the network interface(up/down) re supported.
-Default implementation for following is available in rte_kni library.
-Application may choose to not implement following callbacks:
-
-- ``config_mac_address``
-- ``config_promiscusity``
-
-
-.. code-block:: c
-
- static struct rte_kni_ops kni_ops = {
- .change_mtu = kni_change_mtu,
- .config_network_if = kni_config_network_interface,
- .config_mac_address = kni_config_mac_address,
- .config_promiscusity = kni_config_promiscusity,
- };
-
- /* Callback for request of changing MTU */
-
- static int
- kni_change_mtu(uint16_t port_id, unsigned new_mtu)
- {
- int ret;
- struct rte_eth_conf conf;
-
- if (port_id >= rte_eth_dev_count()) {
- RTE_LOG(ERR, APP, "Invalid port id %d\n", port_id);
- return -EINVAL;
- }
-
- RTE_LOG(INFO, APP, "Change MTU of port %d to %u\n", port_id, new_mtu);
-
- /* Stop specific port */
-
- rte_eth_dev_stop(port_id);
-
- memcpy(&conf, &port_conf, sizeof(conf));
-
- /* Set new MTU */
-
- if (new_mtu > ETHER_MAX_LEN)
- conf.rxmode.jumbo_frame = 1;
- else
- conf.rxmode.jumbo_frame = 0;
-
- /* mtu + length of header + length of FCS = max pkt length */
-
- conf.rxmode.max_rx_pkt_len = new_mtu + KNI_ENET_HEADER_SIZE + KNI_ENET_FCS_SIZE;
-
- ret = rte_eth_dev_configure(port_id, 1, 1, &conf);
- if (ret < 0) {
- RTE_LOG(ERR, APP, "Fail to reconfigure port %d\n", port_id);
- return ret;
- }
-
- /* Restart specific port */
-
- ret = rte_eth_dev_start(port_id);
- if (ret < 0) {
- RTE_LOG(ERR, APP, "Fail to restart port %d\n", port_id);
- return ret;
- }
-
- return 0;
- }
-
- /* Callback for request of configuring network interface up/down */
-
- static int
- kni_config_network_interface(uint16_t port_id, uint8_t if_up)
- {
- int ret = 0;
-
- if (port_id >= rte_eth_dev_count() || port_id >= RTE_MAX_ETHPORTS) {
- RTE_LOG(ERR, APP, "Invalid port id %d\n", port_id);
- return -EINVAL;
- }
-
- RTE_LOG(INFO, APP, "Configure network interface of %d %s\n",
-
- port_id, if_up ? "up" : "down");
-
- if (if_up != 0) {
- /* Configure network interface up */
- rte_eth_dev_stop(port_id);
- ret = rte_eth_dev_start(port_id);
- } else /* Configure network interface down */
- rte_eth_dev_stop(port_id);
-
- if (ret < 0)
- RTE_LOG(ERR, APP, "Failed to start port %d\n", port_id);
- return ret;
- }
-
- /* Callback for request of configuring device mac address */
-
- static int
- kni_config_mac_address(uint16_t port_id, uint8_t mac_addr[])
- {
- .....
- }
-
- /* Callback for request of configuring promiscuous mode */
-
- static int
- kni_config_promiscusity(uint16_t port_id, uint8_t to_on)
- {
- .....
- }