ESP-NETIF Custom I/O Driver =========================== This section outlines implementing a new I/O driver with esp-netif connection capabilities. By convention the I/O driver has to register itself as an esp-netif driver and thus holds a dependency on esp-netif component and is responsible for providing data path functions, post-attach callback and in most cases also default event handlers to define network interface actions based on driver's lifecycle transitions. Packet input/output ^^^^^^^^^^^^^^^^^^^ As shown in the diagram, the following three API functions for the packet data path must be defined for connecting with esp-netif: * :cpp:func:`esp_netif_transmit()` * :cpp:func:`esp_netif_free_rx_buffer()` * :cpp:func:`esp_netif_receive()` The first two functions for transmitting and freeing the rx buffer are provided as callbacks, i.e. they get called from esp-netif (and its underlying TCP/IP stack) and I/O driver provides their implementation. The receiving function on the other hand gets called from the I/O driver, so that the driver's code simply calls :cpp:func:`esp_netif_receive()` on a new data received event. Post attach callback ^^^^^^^^^^^^^^^^^^^^ A final part of the network interface initialization consists of attaching the esp-netif instance to the I/O driver, by means of calling the following API: .. code:: c esp_err_t esp_netif_attach(esp_netif_t *esp_netif, esp_netif_iodriver_handle driver_handle); It is assumed that the ``esp_netif_iodriver_handle`` is a pointer to driver's object, a struct derived from ``struct esp_netif_driver_base_s``, so that the first member of I/O driver structure must be this base structure with pointers to * post-attach function callback * related esp-netif instance As a consequence the I/O driver has to create an instance of the struct per below: .. code:: c typedef struct my_netif_driver_s { esp_netif_driver_base_t base; /*!< base structure reserved as esp-netif driver */ driver_impl *h; /*!< handle of driver implementation */ } my_netif_driver_t; with actual values of ``my_netif_driver_t::base.post_attach`` and the actual drivers handle ``my_netif_driver_t::h``. So when the :cpp:func:`esp_netif_attach()` gets called from the initialization code, the post-attach callback from I/O driver's code gets executed to mutually register callbacks between esp-netif and I/O driver instances. Typically the driver is started as well in the post-attach callback. An example of a simple post-attach callback is outlined below: .. code:: c static esp_err_t my_post_attach_start(esp_netif_t * esp_netif, void * args) { my_netif_driver_t *driver = args; const esp_netif_driver_ifconfig_t driver_ifconfig = { .driver_free_rx_buffer = my_free_rx_buf, .transmit = my_transmit, .handle = driver->driver_impl }; driver->base.netif = esp_netif; ESP_ERROR_CHECK(esp_netif_set_driver_config(esp_netif, &driver_ifconfig)); my_driver_start(driver->driver_impl); return ESP_OK; } Default handlers ^^^^^^^^^^^^^^^^ I/O drivers also typically provide default definitions of lifecycle behaviour of related network interfaces based on state transitions of I/O drivers. For example *driver start* ``->`` *network start*, etc. An example of such a default handler is provided below: .. code:: c esp_err_t my_driver_netif_set_default_handlers(my_netif_driver_t *driver, esp_netif_t * esp_netif) { driver_set_event_handler(driver->driver_impl, esp_netif_action_start, MY_DRV_EVENT_START, esp_netif); driver_set_event_handler(driver->driver_impl, esp_netif_action_stop, MY_DRV_EVENT_STOP, esp_netif); return ESP_OK; } Network stack connection ------------------------ The packet data path functions for transmitting and freeing the rx buffer (defined in the I/O driver) are called from the esp-netif, specifically from its TCP/IP stack connecting layer. The following API reference outlines these network stack interaction with the esp-netif. .. include-build-file:: inc/esp_netif_net_stack.inc