ESP-NETIF
The purpose of the ESP-NETIF library is twofold:
It provides an abstraction layer for the application on top of the TCP/IP stack. This allows applications to choose between IP stacks in the future.
The APIs it provides are thread-safe, even if the underlying TCP/IP stack APIs are not.
ESP-IDF currently implements ESP-NETIF for the lwIP TCP/IP stack only. However, the adapter itself is TCP/IP implementation-agnostic and allows different implementations.
It is also possible to use a custom TCP/IP stack with ESP-IDF, provided it implements BSD API. For more information on building ESP-IDF without lwIP, please refer to components/esp_netif_stack/README.md.
Some ESP-NETIF API functions are intended to be called by application code, for example, to get or set interface IP addresses, and configure DHCP. Other functions are intended for internal ESP-IDF use by the network driver layer.
In many cases, applications do not need to call ESP-NETIF APIs directly as they are called by the default network event handlers.
ESP-NETIF Architecture
| (A) USER CODE |
| Apps |
.................| init settings events |
. +----------------------------------------+
. . | *
. . | *
--------+ +===========================+ * +-----------------------+
| | new/config get/set/apps | * | init |
| | |...*.....| Apps (DHCP, SNTP) |
| |---------------------------| * | |
init | | |**** | |
start |************| event handler |*********| DHCP |
stop | | | | |
| |---------------------------| | |
| | | | NETIF |
+-----| | | +-----------------+ |
| glue|---<----|---| esp_netif_transmit |--<------| netif_output | |
| | | | | | | |
| |--->----|---| esp_netif_receive |-->------| netif_input | |
| | | | | + ----------------+ |
| |...<....|...| esp_netif_free_rx_buffer |...<.....| packet buffer |
+-----| | | | | | |
| | | | | | (D) |
(B) | | | | (C) | +-----------------------+
--------+ | | +===========================+
COMMUNICATION | | NETWORK STACK
DRIVER | | ESP-NETIF
| | +------------------+
| | +---------------------------+.........| open/close |
| | | | | |
| -<--| l2tap_write |-----<---| write |
| | | | |
---->--| esp_vfs_l2tap_eth_filter |----->---| read |
| | | |
| (E) | +------------------+
+---------------------------+
USER CODE
ESP-NETIF L2 TAP
Data and Event Flow in the Diagram
........
Initialization line from user code to ESP-NETIF and communication driver--<--->--
Data packets going from communication media to TCP/IP stack and back********
Events aggregated in ESP-NETIF propagate to the driver, user code, and network stack|
User settings and runtime configuration
ESP-NETIF Interaction
A) User Code, Boilerplate
Overall application interaction with a specific IO driver for communication media and configured TCP/IP network stack is abstracted using ESP-NETIF APIs and is outlined as below:
Initialization code
Initializes IO driver
Creates a new instance of ESP-NETIF and configure it with
ESP-NETIF specific options (flags, behavior, name)
Network stack options (netif init and input functions, not publicly available)
IO driver specific options (transmit, free rx buffer functions, IO driver handle)
Attaches the IO driver handle to the ESP-NETIF instance created in the above steps
Configures event handlers
Use default handlers for common interfaces defined in IO drivers; or define a specific handler for customized behavior or new interfaces
Register handlers for app-related events (such as IP lost or acquired)
Interaction with network interfaces using ESP-NETIF API
Gets and sets TCP/IP-related parameters (DHCP, IP, etc)
Receives IP events (connect or disconnect)
Controls application lifecycle (set interface up or down)
B) Communication Driver, IO Driver, and Media Driver
Communication driver plays these two important roles in relation to ESP-NETIF:
Event handlers: Defines behavior patterns of interaction with ESP-NETIF (e.g., ethernet link-up -> turn netif on)
Glue IO layer: Adapts the input or output functions to use ESP-NETIF transmit, receive, and free receive buffer
Installs driver_transmit to the appropriate ESP-NETIF object so that outgoing packets from the network stack are passed to the IO driver
Calls
esp_netif_receive()
to pass incoming data to the network stack
C) ESP-NETIF
ESP-NETIF serves as an intermediary between an IO driver and a network stack, connecting the packet data path between the two. It provides a set of interfaces for attaching a driver to an ESP-NETIF object at runtime and configures a network stack during compiling. Additionally, a set of APIs is provided to control the network interface lifecycle and its TCP/IP properties. As an overview, the ESP-NETIF public interface can be divided into six groups:
Initialization APIs (to create and configure ESP-NETIF instance)
Input or Output API (for passing data between IO driver and network stack)
Event or Action API
Used for network interface lifecycle management
ESP-NETIF provides building blocks for designing event handlers
Setters and Getters API for basic network interface properties
Network stack abstraction API: enabling user interaction with TCP/IP stack
Set interface up or down
DHCP server and client API
DNS API
Driver conversion utilities API
D) Network Stack
The network stack has no public interaction with application code with regard to public interfaces and shall be fully abstracted by ESP-NETIF API.
E) ESP-NETIF L2 TAP Interface
The ESP-NETIF L2 TAP interface is a mechanism in ESP-IDF used to access Data Link Layer (L2 per OSI/ISO) for frame reception and transmission from the user application. Its typical usage in the embedded world might be the implementation of non-IP-related protocols, e.g., PTP, Wake on LAN. Note that only Ethernet (IEEE 802.3) is currently supported.
From a user perspective, the ESP-NETIF L2 TAP interface is accessed using file descriptors of VFS, which provides file-like interfacing (using functions like open()
, read()
, write()
, etc). To learn more, refer to Virtual Filesystem Component.
There is only one ESP-NETIF L2 TAP interface device (path name) available. However multiple file descriptors with different configurations can be opened at a time since the ESP-NETIF L2 TAP interface can be understood as a generic entry point to the Layer 2 infrastructure. What is important is then the specific configuration of the particular file descriptor. It can be configured to give access to a specific Network Interface identified by if_key
(e.g., ETH_DEF) and to filter only specific frames based on their type (e.g., Ethernet type in the case of IEEE 802.3). Filtering only specific frames is crucial since the ESP-NETIF L2 TAP needs to exist along with the IP stack and so the IP-related traffic (IP, ARP, etc.) should not be passed directly to the user application. Even though this option is still configurable, it is not recommended in standard use cases. Filtering is also advantageous from the perspective of the user's application, as it only gets access to the frame types it is interested in, and the remaining traffic is either passed to other L2 TAP file descriptors or to the IP stack.
ESP-NETIF L2 TAP Interface Usage Manual
Initialization
To be able to use the ESP-NETIF L2 TAP interface, it needs to be enabled in Kconfig by CONFIG_ESP_NETIF_L2_TAP first and then registered by esp_vfs_l2tap_intf_register()
prior usage of any VFS function.
open()
Once the ESP-NETIF L2 TAP is registered, it can be opened at path name "/dev/net/tap". The same path name can be opened multiple times up to CONFIG_ESP_NETIF_L2_TAP_MAX_FDS and multiple file descriptors with a different configuration may access the Data Link Layer frames.
The ESP-NETIF L2 TAP can be opened with the O_NONBLOCK
file status flag to make sure the read()
does not block. Note that the write()
may block in the current implementation when accessing a Network interface since it is a shared resource among multiple ESP-NETIF L2 TAP file descriptors and IP stack, and there is currently no queuing mechanism deployed. The file status flag can be retrieved and modified using fcntl()
.
On success, open()
returns the new file descriptor (a nonnegative integer). On error, -1 is returned, and errno
is set to indicate the error.
ioctl()
The newly opened ESP-NETIF L2 TAP file descriptor needs to be configured prior to its usage since it is not bounded to any specific Network Interface and no frame type filter is configured. The following configuration options are available to do so:
L2TAP_S_INTF_DEVICE
- bounds the file descriptor to a specific Network Interface that is identified by itsif_key
. ESP-NETIF Network Interfaceif_key
is passed toioctl()
as the third parameter. Note that default Network Interfacesif_key
's used in ESP-IDF can be found in esp_netif/include/esp_netif_defaults.h.
L2TAP_S_DEVICE_DRV_HNDL
- is another way to bound the file descriptor to a specific Network Interface. In this case, the Network interface is identified directly by IO Driver handle (e.g.,esp_eth_handle_t
in case of Ethernet). The IO Driver handle is passed toioctl()
as the third parameter.
L2TAP_S_RCV_FILTER
- sets the filter to frames with the type to be passed to the file descriptor. In the case of Ethernet frames, the frames are to be filtered based on the Length and Ethernet type field. In case the filter value is set less than or equal to 0x05DC, the Ethernet type field is considered to represent IEEE802.3 Length Field, and all frames with values in interval <0, 0x05DC> at that field are passed to the file descriptor. The IEEE802.2 logical link control (LLC) resolution is then expected to be performed by the user's application. In case the filter value is set greater than 0x05DC, the Ethernet type field is considered to represent protocol identification and only frames that are equal to the set value are to be passed to the file descriptor.
All above-set configuration options have a getter counterpart option to read the current settings.
Warning
The file descriptor needs to be firstly bounded to a specific Network Interface by L2TAP_S_INTF_DEVICE
or L2TAP_S_DEVICE_DRV_HNDL
to make L2TAP_S_RCV_FILTER
option available.
Note
VLAN-tagged frames are currently not recognized. If the user needs to process VLAN-tagged frames, they need a set filter to be equal to the VLAN tag (i.e., 0x8100 or 0x88A8) and process the VLAN-tagged frames in the user application.
Note
L2TAP_S_DEVICE_DRV_HNDL
is particularly useful when the user's application does not require the usage of an IP stack and so ESP-NETIF is not required to be initialized too. As a result, Network Interface cannot be identified by its if_key
and hence it needs to be identified directly by its IO Driver handle.
ioctl()
returns 0. On error, -1 is returned, and errno
is set to indicate the error.fcntl()
fcntl()
is used to manipulate with properties of opened ESP-NETIF L2 TAP file descriptor.
The following commands manipulate the status flags associated with the file descriptor:
F_GETFD
- the function returns the file descriptor flags, and the third argument is ignored.
F_SETFD
- sets the file descriptor flags to the value specified by the third argument. Zero is returned.
ioctl()
returns 0. On error, -1 is returned, and errno
is set to indicate the error.read()
Opened and configured ESP-NETIF L2 TAP file descriptor can be accessed by read()
to get inbound frames. The read operation can be either blocking or non-blocking based on the actual state of the O_NONBLOCK
file status flag. When the file status flag is set to blocking, the read operation waits until a frame is received and the context is switched to other tasks. When the file status flag is set to non-blocking, the read operation returns immediately. In such case, either a frame is returned if it was already queued or the function indicates the queue is empty. The number of queued frames associated with one file descriptor is limited by CONFIG_ESP_NETIF_L2_TAP_RX_QUEUE_SIZE Kconfig option. Once the number of queued frames reached a configured threshold, the newly arrived frames are dropped until the queue has enough room to accept incoming traffic (Tail Drop queue management).
read()
returns the number of bytes read. Zero is returned when the size of the destination buffer is 0. On error, -1 is returned, and errno
is set to indicate the error.O_NONBLOCK
), and the read would block.write()
A raw Data Link Layer frame can be sent to Network Interface via opened and configured ESP-NETIF L2 TAP file descriptor. The user's application is responsible to construct the whole frame except for fields which are added automatically by the physical interface device. The following fields need to be constructed by the user's application in case of an Ethernet link: source/destination MAC addresses, Ethernet type, actual protocol header, and user data. The length of these fields is as follows:
Destination MAC |
Source MAC |
Type/Length |
Payload (protocol header/data) |
---|---|---|---|
6 B |
6 B |
2 B |
0-1486 B |
In other words, there is no additional frame processing performed by the ESP-NETIF L2 TAP interface. It only checks the Ethernet type of the frame is the same as the filter configured in the file descriptor. If the Ethernet type is different, an error is returned and the frame is not sent. Note that the write()
may block in the current implementation when accessing a Network interface since it is a shared resource among multiple ESP-NETIF L2 TAP file descriptors and IP stack, and there is currently no queuing mechanism deployed.
write()
returns the number of bytes written. Zero is returned when the size of the input buffer is 0. On error, -1 is returned, and errno
is set to indicate the error.close()
Opened ESP-NETIF L2 TAP file descriptor can be closed by the close()
to free its allocated resources. The ESP-NETIF L2 TAP implementation of close()
may block. On the other hand, it is thread-safe and can be called from a different task than the file descriptor is actually used. If such a situation occurs and one task is blocked in the I/O operation and another task tries to close the file descriptor, the first task is unblocked. The first's task read operation then ends with an error.
close()
returns zero. On error, -1 is returned, and errno
is set to indicate the error.select()
Select is used in a standard way, just CONFIG_VFS_SUPPORT_SELECT needs to be enabled to make the select()
function available.
SNTP API
You can find a brief introduction to SNTP in general, its initialization code, and basic modes in Section SNTP Time Synchronization in System Time.
This section provides more details about specific use cases of the SNTP service, with statically configured servers, or use the DHCP-provided servers, or both. The workflow is usually very simple:
Initialize and configure the service using
esp_netif_sntp_init()
. This operations can only be called once (unless the SNTP service has been destroyed byesp_netif_sntp_deinit()
)Start the service via
esp_netif_sntp_start()
. This step is not needed if we auto-started the service in the previous step (default). It is useful to start the service explicitly after connecting if we want to use the DHCP-obtained NTP servers. Please note, this option needs to be enabled before connecting, but the SNTP service should be started after.Wait for the system time to synchronize using
esp_netif_sntp_sync_wait()
(only if needed).Stop and destroy the service using
esp_netif_sntp_deinit()
.
Basic Mode with Statically Defined Server(s)
Initialize the module with the default configuration after connecting to the network. Note that it is possible to provide multiple NTP servers in the configuration struct:
esp_sntp_config_t config = ESP_NETIF_SNTP_DEFAULT_CONFIG_MULTIPLE(2,
ESP_SNTP_SERVER_LIST("time.windows.com", "pool.ntp.org" ) );
esp_netif_sntp_init(&config);
Note
If we want to configure multiple SNTP servers, we have to update the lwIP configuration CONFIG_LWIP_SNTP_MAX_SERVERS.
Use DHCP-Obtained SNTP Server(s)
First of all, we have to enable the lwIP configuration option CONFIG_LWIP_DHCP_GET_NTP_SRV. Then we have to initialize the SNTP module with the DHCP option and without the NTP server:
esp_sntp_config_t config = ESP_NETIF_SNTP_DEFAULT_CONFIG_MULTIPLE(0, {} );
config.start = false; // start the SNTP service explicitly
config.server_from_dhcp = true; // accept the NTP offer from the DHCP server
esp_netif_sntp_init(&config);
Then, once we are connected, we could start the service using:
esp_netif_sntp_start();
Note
It is also possible to start the service during initialization (default config.start=true
). This would likely to cause the initial SNTP request to fail (since we are not connected yet) and lead to some back-off time for subsequent requests.
Use Both Static and Dynamic Servers
Very similar to the scenario above (DHCP provided SNTP server), but in this configuration, we need to make sure that the static server configuration is refreshed when obtaining NTP servers by DHCP. The underlying lwIP code cleans up the rest of the list of NTP servers when the DHCP-provided information gets accepted. Thus the ESP-NETIF SNTP module saves the statically configured server(s) and reconfigures them after obtaining a DHCP lease.
The typical configuration now looks as per below, providing the specific IP_EVENT
to update the config and index of the first server to reconfigure (for example setting config.index_of_first_server=1
would keep the DHCP provided server at index 0, and the statically configured server at index 1).
esp_sntp_config_t config = ESP_NETIF_SNTP_DEFAULT_CONFIG("pool.ntp.org");
config.start = false; // start the SNTP service explicitly (after connecting)
config.server_from_dhcp = true; // accept the NTP offers from DHCP server
config.renew_servers_after_new_IP = true; // let esp-netif update the configured SNTP server(s) after receiving the DHCP lease
config.index_of_first_server = 1; // updates from server num 1, leaving server 0 (from DHCP) intact
config.ip_event_to_renew = IP_EVENT_STA_GOT_IP; // IP event on which we refresh the configuration
Then we start the service normally with esp_netif_sntp_start()
.
ESP-NETIF Programmer's Manual
Please refer to the following example to understand the initialization process of the default interface:
Wi-Fi Access Point: wifi/getting_started/softAP/main/softap_example_main.c
For more specific cases, please consult this guide: ESP-NETIF Custom I/O Driver.
API Reference
Header File
This header file can be included with:
#include "esp_netif.h"
This header file is a part of the API provided by the
esp_netif
component. To declare that your component depends onesp_netif
, add the following to your CMakeLists.txt:REQUIRES esp_netif
or
PRIV_REQUIRES esp_netif
Functions
-
esp_err_t esp_netif_init(void)
Initialize the underlying TCP/IP stack.
Note
This function should be called exactly once from application code, when the application starts up.
- Returns
ESP_OK on success
ESP_FAIL if initializing failed
-
esp_err_t esp_netif_deinit(void)
Deinitialize the esp-netif component (and the underlying TCP/IP stack)
Note: Deinitialization is not supported yet
- Returns
ESP_ERR_INVALID_STATE if esp_netif not initialized
ESP_ERR_NOT_SUPPORTED otherwise
-
esp_netif_t *esp_netif_new(const esp_netif_config_t *esp_netif_config)
Creates an instance of new esp-netif object based on provided config.
- Parameters
esp_netif_config -- [in] pointer esp-netif configuration
- Returns
pointer to esp-netif object on success
NULL otherwise
-
void esp_netif_destroy(esp_netif_t *esp_netif)
Destroys the esp_netif object.
- Parameters
esp_netif -- [in] pointer to the object to be deleted
-
esp_err_t esp_netif_set_driver_config(esp_netif_t *esp_netif, const esp_netif_driver_ifconfig_t *driver_config)
Configures driver related options of esp_netif object.
- Parameters
esp_netif -- [inout] pointer to the object to be configured
driver_config -- [in] pointer esp-netif io driver related configuration
- Returns
ESP_OK on success
ESP_ERR_ESP_NETIF_INVALID_PARAMS if invalid parameters provided
-
esp_err_t esp_netif_attach(esp_netif_t *esp_netif, esp_netif_iodriver_handle driver_handle)
Attaches esp_netif instance to the io driver handle.
Calling this function enables connecting specific esp_netif object with already initialized io driver to update esp_netif object with driver specific configuration (i.e. calls post_attach callback, which typically sets io driver callbacks to esp_netif instance and starts the driver)
- Parameters
esp_netif -- [inout] pointer to esp_netif object to be attached
driver_handle -- [in] pointer to the driver handle
- Returns
ESP_OK on success
ESP_ERR_ESP_NETIF_DRIVER_ATTACH_FAILED if driver's pot_attach callback failed
-
esp_err_t esp_netif_receive(esp_netif_t *esp_netif, void *buffer, size_t len, void *eb)
Passes the raw packets from communication media to the appropriate TCP/IP stack.
This function is called from the configured (peripheral) driver layer. The data are then forwarded as frames to the TCP/IP stack.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
buffer -- [in] Received data
len -- [in] Length of the data frame
eb -- [in] Pointer to internal buffer (used in Wi-Fi driver)
- Returns
ESP_OK
-
void esp_netif_action_start(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon IO driver start event Creates network interface, if AUTOUP enabled turns the interface on, if DHCPS enabled starts dhcp server.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
void esp_netif_action_stop(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon IO driver stop event.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
void esp_netif_action_connected(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon IO driver connected event.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
void esp_netif_action_disconnected(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon IO driver disconnected event.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
void esp_netif_action_got_ip(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon network got IP event.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
void esp_netif_action_join_ip6_multicast_group(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon IPv6 multicast group join.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
void esp_netif_action_leave_ip6_multicast_group(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon IPv6 multicast group leave.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
void esp_netif_action_add_ip6_address(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon IPv6 address added by the underlying stack.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
void esp_netif_action_remove_ip6_address(void *esp_netif, esp_event_base_t base, int32_t event_id, void *data)
Default building block for network interface action upon IPv6 address removed by the underlying stack.
Note
This API can be directly used as event handler
- Parameters
esp_netif -- [in] Handle to esp-netif instance
base -- The base type of the event
event_id -- The specific ID of the event
data -- Optional data associated with the event
-
esp_err_t esp_netif_set_default_netif(esp_netif_t *esp_netif)
Manual configuration of the default netif.
This API overrides the automatic configuration of the default interface based on the route_prio If the selected netif is set default using this API, no other interface could be set-default disregarding its route_prio number (unless the selected netif gets destroyed)
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
ESP_OK on success
-
esp_netif_t *esp_netif_get_default_netif(void)
Getter function of the default netif.
This API returns the selected default netif.
- Returns
Handle to esp-netif instance of the default netif.
-
esp_err_t esp_netif_join_ip6_multicast_group(esp_netif_t *esp_netif, const esp_ip6_addr_t *addr)
Cause the TCP/IP stack to join a IPv6 multicast group.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
addr -- [in] The multicast group to join
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_MLD6_FAILED
ESP_ERR_NO_MEM
-
esp_err_t esp_netif_leave_ip6_multicast_group(esp_netif_t *esp_netif, const esp_ip6_addr_t *addr)
Cause the TCP/IP stack to leave a IPv6 multicast group.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
addr -- [in] The multicast group to leave
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_MLD6_FAILED
ESP_ERR_NO_MEM
-
esp_err_t esp_netif_set_mac(esp_netif_t *esp_netif, uint8_t mac[])
Set the mac address for the interface instance.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
mac -- [in] Desired mac address for the related network interface
- Returns
ESP_OK - success
ESP_ERR_ESP_NETIF_IF_NOT_READY - interface status error
ESP_ERR_NOT_SUPPORTED - mac not supported on this interface
-
esp_err_t esp_netif_get_mac(esp_netif_t *esp_netif, uint8_t mac[])
Get the mac address for the interface instance.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
mac -- [out] Resultant mac address for the related network interface
- Returns
ESP_OK - success
ESP_ERR_ESP_NETIF_IF_NOT_READY - interface status error
ESP_ERR_NOT_SUPPORTED - mac not supported on this interface
-
esp_err_t esp_netif_set_hostname(esp_netif_t *esp_netif, const char *hostname)
Set the hostname of an interface.
The configured hostname overrides the default configuration value CONFIG_LWIP_LOCAL_HOSTNAME. Please note that when the hostname is altered after interface started/connected the changes would only be reflected once the interface restarts/reconnects
- Parameters
esp_netif -- [in] Handle to esp-netif instance
hostname -- [in] New hostname for the interface. Maximum length 32 bytes.
- Returns
ESP_OK - success
ESP_ERR_ESP_NETIF_IF_NOT_READY - interface status error
ESP_ERR_ESP_NETIF_INVALID_PARAMS - parameter error
-
esp_err_t esp_netif_get_hostname(esp_netif_t *esp_netif, const char **hostname)
Get interface hostname.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
hostname -- [out] Returns a pointer to the hostname. May be NULL if no hostname is set. If set non-NULL, pointer remains valid (and string may change if the hostname changes).
- Returns
ESP_OK - success
ESP_ERR_ESP_NETIF_IF_NOT_READY - interface status error
ESP_ERR_ESP_NETIF_INVALID_PARAMS - parameter error
-
bool esp_netif_is_netif_up(esp_netif_t *esp_netif)
Test if supplied interface is up or down.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
true - Interface is up
false - Interface is down
-
esp_err_t esp_netif_get_ip_info(esp_netif_t *esp_netif, esp_netif_ip_info_t *ip_info)
Get interface's IP address information.
If the interface is up, IP information is read directly from the TCP/IP stack. If the interface is down, IP information is read from a copy kept in the ESP-NETIF instance
- Parameters
esp_netif -- [in] Handle to esp-netif instance
ip_info -- [out] If successful, IP information will be returned in this argument.
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
-
esp_err_t esp_netif_get_old_ip_info(esp_netif_t *esp_netif, esp_netif_ip_info_t *ip_info)
Get interface's old IP information.
Returns an "old" IP address previously stored for the interface when the valid IP changed.
If the IP lost timer has expired (meaning the interface was down for longer than the configured interval) then the old IP information will be zero.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
ip_info -- [out] If successful, IP information will be returned in this argument.
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
-
esp_err_t esp_netif_set_ip_info(esp_netif_t *esp_netif, const esp_netif_ip_info_t *ip_info)
Set interface's IP address information.
This function is mainly used to set a static IP on an interface.
If the interface is up, the new IP information is set directly in the TCP/IP stack.
The copy of IP information kept in the ESP-NETIF instance is also updated (this copy is returned if the IP is queried while the interface is still down.)
Note
DHCP client/server must be stopped (if enabled for this interface) before setting new IP information.
Note
Calling this interface for may generate a SYSTEM_EVENT_STA_GOT_IP or SYSTEM_EVENT_ETH_GOT_IP event.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
ip_info -- [in] IP information to set on the specified interface
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_DHCP_NOT_STOPPED If DHCP server or client is still running
-
esp_err_t esp_netif_set_old_ip_info(esp_netif_t *esp_netif, const esp_netif_ip_info_t *ip_info)
Set interface old IP information.
This function is called from the DHCP client (if enabled), before a new IP is set. It is also called from the default handlers for the SYSTEM_EVENT_STA_CONNECTED and SYSTEM_EVENT_ETH_CONNECTED events.
Calling this function stores the previously configured IP, which can be used to determine if the IP changes in the future.
If the interface is disconnected or down for too long, the "IP lost timer" will expire (after the configured interval) and set the old IP information to zero.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
ip_info -- [in] Store the old IP information for the specified interface
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
-
int esp_netif_get_netif_impl_index(esp_netif_t *esp_netif)
Get net interface index from network stack implementation.
Note
This index could be used in
setsockopt()
to bind socket with multicast interface- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
implementation specific index of interface represented with supplied esp_netif
-
esp_err_t esp_netif_get_netif_impl_name(esp_netif_t *esp_netif, char *name)
Get net interface name from network stack implementation.
Note
This name could be used in
setsockopt()
to bind socket with appropriate interface- Parameters
esp_netif -- [in] Handle to esp-netif instance
name -- [out] Interface name as specified in underlying TCP/IP stack. Note that the actual name will be copied to the specified buffer, which must be allocated to hold maximum interface name size (6 characters for lwIP)
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
-
esp_err_t esp_netif_napt_enable(esp_netif_t *esp_netif)
Enable NAPT on an interface.
Note
Enable operation can be performed only on one interface at a time. NAPT cannot be enabled on multiple interfaces according to this implementation.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
ESP_OK
ESP_FAIL
ESP_ERR_NOT_SUPPORTED
-
esp_err_t esp_netif_napt_disable(esp_netif_t *esp_netif)
Disable NAPT on an interface.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
ESP_OK
ESP_FAIL
ESP_ERR_NOT_SUPPORTED
-
esp_err_t esp_netif_dhcps_option(esp_netif_t *esp_netif, esp_netif_dhcp_option_mode_t opt_op, esp_netif_dhcp_option_id_t opt_id, void *opt_val, uint32_t opt_len)
Set or Get DHCP server option.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
opt_op -- [in] ESP_NETIF_OP_SET to set an option, ESP_NETIF_OP_GET to get an option.
opt_id -- [in] Option index to get or set, must be one of the supported enum values.
opt_val -- [inout] Pointer to the option parameter.
opt_len -- [in] Length of the option parameter.
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STOPPED
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STARTED
-
esp_err_t esp_netif_dhcpc_option(esp_netif_t *esp_netif, esp_netif_dhcp_option_mode_t opt_op, esp_netif_dhcp_option_id_t opt_id, void *opt_val, uint32_t opt_len)
Set or Get DHCP client option.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
opt_op -- [in] ESP_NETIF_OP_SET to set an option, ESP_NETIF_OP_GET to get an option.
opt_id -- [in] Option index to get or set, must be one of the supported enum values.
opt_val -- [inout] Pointer to the option parameter.
opt_len -- [in] Length of the option parameter.
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STOPPED
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STARTED
-
esp_err_t esp_netif_dhcpc_start(esp_netif_t *esp_netif)
Start DHCP client (only if enabled in interface object)
Note
The default event handlers for the SYSTEM_EVENT_STA_CONNECTED and SYSTEM_EVENT_ETH_CONNECTED events call this function.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STARTED
ESP_ERR_ESP_NETIF_DHCPC_START_FAILED
-
esp_err_t esp_netif_dhcpc_stop(esp_netif_t *esp_netif)
Stop DHCP client (only if enabled in interface object)
Note
Calling action_netif_stop() will also stop the DHCP Client if it is running.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STOPPED
ESP_ERR_ESP_NETIF_IF_NOT_READY
-
esp_err_t esp_netif_dhcpc_get_status(esp_netif_t *esp_netif, esp_netif_dhcp_status_t *status)
Get DHCP client status.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
status -- [out] If successful, the status of DHCP client will be returned in this argument.
- Returns
ESP_OK
-
esp_err_t esp_netif_dhcps_get_status(esp_netif_t *esp_netif, esp_netif_dhcp_status_t *status)
Get DHCP Server status.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
status -- [out] If successful, the status of the DHCP server will be returned in this argument.
- Returns
ESP_OK
-
esp_err_t esp_netif_dhcps_start(esp_netif_t *esp_netif)
Start DHCP server (only if enabled in interface object)
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STARTED
-
esp_err_t esp_netif_dhcps_stop(esp_netif_t *esp_netif)
Stop DHCP server (only if enabled in interface object)
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STOPPED
ESP_ERR_ESP_NETIF_IF_NOT_READY
-
esp_err_t esp_netif_dhcps_get_clients_by_mac(esp_netif_t *esp_netif, int num, esp_netif_pair_mac_ip_t *mac_ip_pair)
Populate IP addresses of clients connected to DHCP server listed by their MAC addresses.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
num -- [in] Number of clients with specified MAC addresses in the array of pairs
mac_ip_pair -- [inout] Array of pairs of MAC and IP addresses (MAC are inputs, IP outputs)
- Returns
ESP_OK on success
ESP_ERR_ESP_NETIF_INVALID_PARAMS on invalid params
ESP_ERR_NOT_SUPPORTED if DHCP server not enabled
-
esp_err_t esp_netif_set_dns_info(esp_netif_t *esp_netif, esp_netif_dns_type_t type, esp_netif_dns_info_t *dns)
Set DNS Server information.
This function behaves differently if DHCP server or client is enabled
If DHCP client is enabled, main and backup DNS servers will be updated automatically from the DHCP lease if the relevant DHCP options are set. Fallback DNS Server is never updated from the DHCP lease and is designed to be set via this API. If DHCP client is disabled, all DNS server types can be set via this API only.
Note that LWIP stores DNS server information globally, not per interface, so the first parameter is unused in the default LWIP configuration. If CONFIG_ESP_NETIF_SET_DNS_PER_DEFAULT_NETIF=1 this API sets internal DNS server information per netif. It's also possible to set the global DNS server info by supplying esp_netif=NULL
If DHCP server is enabled, the Main DNS Server setting is used by the DHCP server to provide a DNS Server option to DHCP clients (Wi-Fi stations).
The default Main DNS server is typically the IP of the DHCP server itself.
This function can override it by setting server type ESP_NETIF_DNS_MAIN.
Other DNS Server types are not supported for the DHCP server.
To propagate the DNS info to client, please stop the DHCP server before using this API.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
type -- [in] Type of DNS Server to set: ESP_NETIF_DNS_MAIN, ESP_NETIF_DNS_BACKUP, ESP_NETIF_DNS_FALLBACK
dns -- [in] DNS Server address to set
- Returns
ESP_OK on success
ESP_ERR_ESP_NETIF_INVALID_PARAMS invalid params
-
esp_err_t esp_netif_get_dns_info(esp_netif_t *esp_netif, esp_netif_dns_type_t type, esp_netif_dns_info_t *dns)
Get DNS Server information.
Return the currently configured DNS Server address for the specified interface and Server type.
This may be result of a previous call to esp_netif_set_dns_info(). If the interface's DHCP client is enabled, the Main or Backup DNS Server may be set by the current DHCP lease.
Note that LWIP stores DNS server information globally, not per interface, so the first parameter is unused in the default LWIP configuration. If CONFIG_ESP_NETIF_SET_DNS_PER_DEFAULT_NETIF=1 this API returns internally saved DNS server information per netif. It's also possible to ask for the global DNS server info by supplying esp_netif=NULL
- Parameters
esp_netif -- [in] Handle to esp-netif instance
type -- [in] Type of DNS Server to get: ESP_NETIF_DNS_MAIN, ESP_NETIF_DNS_BACKUP, ESP_NETIF_DNS_FALLBACK
dns -- [out] DNS Server result is written here on success
- Returns
ESP_OK on success
ESP_ERR_ESP_NETIF_INVALID_PARAMS invalid params
-
esp_err_t esp_netif_create_ip6_linklocal(esp_netif_t *esp_netif)
Create interface link-local IPv6 address.
Cause the TCP/IP stack to create a link-local IPv6 address for the specified interface.
This function also registers a callback for the specified interface, so that if the link-local address becomes verified as the preferred address then a SYSTEM_EVENT_GOT_IP6 event will be sent.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
-
esp_err_t esp_netif_get_ip6_linklocal(esp_netif_t *esp_netif, esp_ip6_addr_t *if_ip6)
Get interface link-local IPv6 address.
If the specified interface is up and a preferred link-local IPv6 address has been created for the interface, return a copy of it.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
if_ip6 -- [out] IPv6 information will be returned in this argument if successful.
- Returns
ESP_OK
ESP_FAIL If interface is down, does not have a link-local IPv6 address, or the link-local IPv6 address is not a preferred address.
-
esp_err_t esp_netif_get_ip6_global(esp_netif_t *esp_netif, esp_ip6_addr_t *if_ip6)
Get interface global IPv6 address.
If the specified interface is up and a preferred global IPv6 address has been created for the interface, return a copy of it.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
if_ip6 -- [out] IPv6 information will be returned in this argument if successful.
- Returns
ESP_OK
ESP_FAIL If interface is down, does not have a global IPv6 address, or the global IPv6 address is not a preferred address.
-
int esp_netif_get_all_ip6(esp_netif_t *esp_netif, esp_ip6_addr_t if_ip6[])
Get all IPv6 addresses of the specified interface.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
if_ip6 -- [out] Array of IPv6 addresses will be copied to the argument
- Returns
number of returned IPv6 addresses
-
int esp_netif_get_all_preferred_ip6(esp_netif_t *esp_netif, esp_ip6_addr_t if_ip6[])
Get all preferred IPv6 addresses of the specified interface.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
if_ip6 -- [out] Array of IPv6 addresses will be copied to the argument
- Returns
number of returned IPv6 addresses
-
esp_err_t esp_netif_add_ip6_address(esp_netif_t *esp_netif, const esp_ip6_addr_t addr, bool preferred)
Cause the TCP/IP stack to add an IPv6 address to the interface.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
addr -- [in] The address to be added
preferred -- [in] The preferred status of the address
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_IP6_ADDR_FAILED
ESP_ERR_NO_MEM
-
esp_err_t esp_netif_remove_ip6_address(esp_netif_t *esp_netif, const esp_ip6_addr_t *addr)
Cause the TCP/IP stack to remove an IPv6 address from the interface.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
addr -- [in] The address to be removed
- Returns
ESP_OK
ESP_ERR_ESP_NETIF_INVALID_PARAMS
ESP_ERR_ESP_NETIF_IP6_ADDR_FAILED
ESP_ERR_NO_MEM
-
void esp_netif_set_ip4_addr(esp_ip4_addr_t *addr, uint8_t a, uint8_t b, uint8_t c, uint8_t d)
Sets IPv4 address to the specified octets.
- Parameters
addr -- [out] IP address to be set
a -- the first octet (127 for IP 127.0.0.1)
b --
c --
d --
-
char *esp_ip4addr_ntoa(const esp_ip4_addr_t *addr, char *buf, int buflen)
Converts numeric IP address into decimal dotted ASCII representation.
- Parameters
addr -- ip address in network order to convert
buf -- target buffer where the string is stored
buflen -- length of buf
- Returns
either pointer to buf which now holds the ASCII representation of addr or NULL if buf was too small
-
uint32_t esp_ip4addr_aton(const char *addr)
Ascii internet address interpretation routine The value returned is in network order.
- Parameters
addr -- IP address in ascii representation (e.g. "127.0.0.1")
- Returns
ip address in network order
-
esp_err_t esp_netif_str_to_ip4(const char *src, esp_ip4_addr_t *dst)
Converts Ascii internet IPv4 address into esp_ip4_addr_t.
- Parameters
src -- [in] IPv4 address in ascii representation (e.g. "127.0.0.1")
dst -- [out] Address of the target esp_ip4_addr_t structure to receive converted address
- Returns
ESP_OK on success
ESP_FAIL if conversion failed
ESP_ERR_INVALID_ARG if invalid parameter is passed into
-
esp_err_t esp_netif_str_to_ip6(const char *src, esp_ip6_addr_t *dst)
Converts Ascii internet IPv6 address into esp_ip4_addr_t Zeros in the IP address can be stripped or completely ommited: "2001:db8:85a3:0:0:0:2:1" or "2001:db8::2:1")
- Parameters
src -- [in] IPv6 address in ascii representation (e.g. ""2001:0db8:85a3:0000:0000:0000:0002:0001")
dst -- [out] Address of the target esp_ip6_addr_t structure to receive converted address
- Returns
ESP_OK on success
ESP_FAIL if conversion failed
ESP_ERR_INVALID_ARG if invalid parameter is passed into
-
esp_netif_iodriver_handle esp_netif_get_io_driver(esp_netif_t *esp_netif)
Gets media driver handle for this esp-netif instance.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
opaque pointer of related IO driver
-
esp_netif_t *esp_netif_get_handle_from_ifkey(const char *if_key)
Searches over a list of created objects to find an instance with supplied if key.
- Parameters
if_key -- Textual description of network interface
- Returns
Handle to esp-netif instance
-
esp_netif_flags_t esp_netif_get_flags(esp_netif_t *esp_netif)
Returns configured flags for this interface.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
Configuration flags
-
const char *esp_netif_get_ifkey(esp_netif_t *esp_netif)
Returns configured interface key for this esp-netif instance.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
Textual description of related interface
-
const char *esp_netif_get_desc(esp_netif_t *esp_netif)
Returns configured interface type for this esp-netif instance.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
Enumerated type of this interface, such as station, AP, ethernet
-
int esp_netif_get_route_prio(esp_netif_t *esp_netif)
Returns configured routing priority number.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
Integer representing the instance's route-prio, or -1 if invalid paramters
-
int32_t esp_netif_get_event_id(esp_netif_t *esp_netif, esp_netif_ip_event_type_t event_type)
Returns configured event for this esp-netif instance and supplied event type.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
event_type -- (either get or lost IP)
- Returns
specific event id which is configured to be raised if the interface lost or acquired IP address -1 if supplied event_type is not known
-
esp_netif_t *esp_netif_next(esp_netif_t *esp_netif)
Iterates over list of interfaces. Returns first netif if NULL given as parameter.
Note
This API doesn't lock the list, nor the TCPIP context, as this it's usually required to get atomic access between iteration steps rather that within a single iteration. Therefore it is recommended to iterate over the interfaces inside esp_netif_tcpip_exec()
Note
This API is deprecated. Please use esp_netif_next_unsafe() directly if all the system interfaces are under your control and you can safely iterate over them. Otherwise, iterate over interfaces using esp_netif_tcpip_exec(), or use esp_netif_find_if() to search in the list of netifs with defined predicate.
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
First netif from the list if supplied parameter is NULL, next one otherwise
-
esp_netif_t *esp_netif_next_unsafe(esp_netif_t *esp_netif)
Iterates over list of interfaces without list locking. Returns first netif if NULL given as parameter.
Used for bulk search loops within TCPIP context, e.g. using esp_netif_tcpip_exec(), or if we're sure that the iteration is safe from our application perspective (e.g. no interface is removed between iterations)
- Parameters
esp_netif -- [in] Handle to esp-netif instance
- Returns
First netif from the list if supplied parameter is NULL, next one otherwise
-
esp_netif_t *esp_netif_find_if(esp_netif_find_predicate_t fn, void *ctx)
Return a netif pointer for the first interface that meets criteria defined by the callback.
- Parameters
fn -- Predicate function returning true for the desired interface
ctx -- Context pointer passed to the predicate, typically a descriptor to compare with
- Returns
valid netif pointer if found, NULL if not
-
size_t esp_netif_get_nr_of_ifs(void)
Returns number of registered esp_netif objects.
- Returns
Number of esp_netifs
-
void esp_netif_netstack_buf_ref(void *netstack_buf)
increase the reference counter of net stack buffer
- Parameters
netstack_buf -- [in] the net stack buffer
-
void esp_netif_netstack_buf_free(void *netstack_buf)
free the netstack buffer
- Parameters
netstack_buf -- [in] the net stack buffer
-
esp_err_t esp_netif_tcpip_exec(esp_netif_callback_fn fn, void *ctx)
Utility to execute the supplied callback in TCP/IP context.
- Parameters
fn -- Pointer to the callback
ctx -- Parameter to the callback
- Returns
The error code (esp_err_t) returned by the callback
Type Definitions
-
typedef bool (*esp_netif_find_predicate_t)(esp_netif_t *netif, void *ctx)
Predicate callback for esp_netif_find_if() used to find interface which meets defined criteria.
-
typedef esp_err_t (*esp_netif_callback_fn)(void *ctx)
TCPIP thread safe callback used with esp_netif_tcpip_exec()
Header File
This header file can be included with:
#include "esp_netif_sntp.h"
This header file is a part of the API provided by the
esp_netif
component. To declare that your component depends onesp_netif
, add the following to your CMakeLists.txt:REQUIRES esp_netif
or
PRIV_REQUIRES esp_netif
Functions
-
esp_err_t esp_netif_sntp_init(const esp_sntp_config_t *config)
Initialize SNTP with supplied config struct.
- Parameters
config -- Config struct
- Returns
ESP_OK on success
-
esp_err_t esp_netif_sntp_start(void)
Start SNTP service if it wasn't started during init (config.start = false) or restart it if already started.
- Returns
ESP_OK on success
-
void esp_netif_sntp_deinit(void)
Deinitialize esp_netif SNTP module.
-
esp_err_t esp_netif_sntp_sync_wait(TickType_t tout)
Wait for time sync event.
- Parameters
tout -- Specified timeout in RTOS ticks
- Returns
ESP_TIMEOUT if sync event didn't came withing the timeout ESP_ERR_NOT_FINISHED if the sync event came, but we're in smooth update mode and still in progress (SNTP_SYNC_STATUS_IN_PROGRESS) ESP_OK if time sync'ed
-
esp_err_t esp_netif_sntp_reachability(unsigned int index, unsigned int *reachability)
Returns SNTP server's reachability shift register as described in RFC 5905.
- Parameters
index -- Index of the SERVER
reachability -- reachability shift register
- Returns
ESP_OK on success, ESP_ERR_INVALID_STATE if SNTP not initialized ESP_ERR_INVALID_ARG if invalid arguments
Structures
-
struct esp_sntp_config
SNTP configuration struct.
Public Members
-
bool smooth_sync
set to true if smooth sync required
-
bool server_from_dhcp
set to true to request NTP server config from DHCP
-
bool wait_for_sync
if true, we create a semaphore to signal time sync event
-
bool start
set to true to automatically start the SNTP service
-
esp_sntp_time_cb_t sync_cb
optionally sets callback function on time sync event
-
bool renew_servers_after_new_IP
this is used to refresh server list if NTP provided by DHCP (which cleans other pre-configured servers)
-
ip_event_t ip_event_to_renew
set the IP event id on which we refresh server list (if renew_servers_after_new_IP=true)
-
size_t index_of_first_server
refresh server list after this server (if renew_servers_after_new_IP=true)
-
size_t num_of_servers
number of preconfigured NTP servers
-
const char *servers[1]
list of servers
-
bool smooth_sync
Macros
-
ESP_SNTP_SERVER_LIST(...)
Utility macro for providing multiple servers in parentheses.
-
ESP_NETIF_SNTP_DEFAULT_CONFIG_MULTIPLE(servers_in_list, list_of_servers)
Default configuration to init SNTP with multiple servers.
- Parameters
servers_in_list -- Number of servers in the list
list_of_servers -- List of servers (use ESP_SNTP_SERVER_LIST(...))
-
ESP_NETIF_SNTP_DEFAULT_CONFIG(server)
Default configuration with a single server.
Type Definitions
-
typedef void (*esp_sntp_time_cb_t)(struct timeval *tv)
Time sync notification function.
-
typedef struct esp_sntp_config esp_sntp_config_t
SNTP configuration struct.
Header File
This header file can be included with:
#include "esp_netif_types.h"
This header file is a part of the API provided by the
esp_netif
component. To declare that your component depends onesp_netif
, add the following to your CMakeLists.txt:REQUIRES esp_netif
or
PRIV_REQUIRES esp_netif
Structures
-
struct esp_netif_dns_info_t
DNS server info.
Public Members
-
esp_ip_addr_t ip
IPV4 address of DNS server
-
esp_ip_addr_t ip
-
struct esp_netif_ip_info_t
Event structure for IP_EVENT_STA_GOT_IP, IP_EVENT_ETH_GOT_IP events
Public Members
-
esp_ip4_addr_t ip
Interface IPV4 address
-
esp_ip4_addr_t netmask
Interface IPV4 netmask
-
esp_ip4_addr_t gw
Interface IPV4 gateway address
-
esp_ip4_addr_t ip
-
struct esp_netif_ip6_info_t
IPV6 IP address information.
Public Members
-
esp_ip6_addr_t ip
Interface IPV6 address
-
esp_ip6_addr_t ip
-
struct ip_event_got_ip_t
Event structure for IP_EVENT_GOT_IP event.
Public Members
-
esp_netif_t *esp_netif
Pointer to corresponding esp-netif object
-
esp_netif_ip_info_t ip_info
IP address, netmask, gatway IP address
-
bool ip_changed
Whether the assigned IP has changed or not
-
esp_netif_t *esp_netif
-
struct ip_event_got_ip6_t
Event structure for IP_EVENT_GOT_IP6 event
Public Members
-
esp_netif_t *esp_netif
Pointer to corresponding esp-netif object
-
esp_netif_ip6_info_t ip6_info
IPv6 address of the interface
-
int ip_index
IPv6 address index
-
esp_netif_t *esp_netif
-
struct ip_event_add_ip6_t
Event structure for ADD_IP6 event
Public Members
-
esp_ip6_addr_t addr
The address to be added to the interface
-
bool preferred
The default preference of the address
-
esp_ip6_addr_t addr
-
struct ip_event_ap_staipassigned_t
Event structure for IP_EVENT_AP_STAIPASSIGNED event
Public Members
-
esp_netif_t *esp_netif
Pointer to the associated netif handle
-
esp_ip4_addr_t ip
IP address which was assigned to the station
-
uint8_t mac[6]
MAC address of the connected client
-
esp_netif_t *esp_netif
-
struct bridgeif_config
LwIP bridge configuration
-
struct esp_netif_inherent_config
ESP-netif inherent config parameters.
Public Members
-
esp_netif_flags_t flags
flags that define esp-netif behavior
-
uint8_t mac[6]
initial mac address for this interface
-
const esp_netif_ip_info_t *ip_info
initial ip address for this interface
-
uint32_t get_ip_event
event id to be raised when interface gets an IP
-
uint32_t lost_ip_event
event id to be raised when interface losts its IP
-
const char *if_key
string identifier of the interface
-
const char *if_desc
textual description of the interface
-
int route_prio
numeric priority of this interface to become a default routing if (if other netifs are up). A higher value of route_prio indicates a higher priority
-
bridgeif_config_t *bridge_info
LwIP bridge configuration
-
esp_netif_flags_t flags
-
struct esp_netif_driver_base_s
ESP-netif driver base handle.
Public Members
-
esp_err_t (*post_attach)(esp_netif_t *netif, esp_netif_iodriver_handle h)
post attach function pointer
-
esp_netif_t *netif
netif handle
-
esp_err_t (*post_attach)(esp_netif_t *netif, esp_netif_iodriver_handle h)
-
struct esp_netif_driver_ifconfig
Specific IO driver configuration.
Public Members
-
esp_netif_iodriver_handle handle
io-driver handle
-
esp_err_t (*transmit_wrap)(void *h, void *buffer, size_t len, void *netstack_buffer)
transmit wrap function pointer
-
void (*driver_free_rx_buffer)(void *h, void *buffer)
free rx buffer function pointer
-
esp_netif_iodriver_handle handle
-
struct esp_netif_config
Generic esp_netif configuration.
Public Members
-
const esp_netif_inherent_config_t *base
base config
-
const esp_netif_driver_ifconfig_t *driver
driver config
-
const esp_netif_netstack_config_t *stack
stack config
-
const esp_netif_inherent_config_t *base
-
struct esp_netif_pair_mac_ip_t
DHCP client's addr info (pair of MAC and IP address)
Macros
-
ESP_ERR_ESP_NETIF_BASE
Definition of ESP-NETIF based errors.
-
ESP_ERR_ESP_NETIF_INVALID_PARAMS
-
ESP_ERR_ESP_NETIF_IF_NOT_READY
-
ESP_ERR_ESP_NETIF_DHCPC_START_FAILED
-
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STARTED
-
ESP_ERR_ESP_NETIF_DHCP_ALREADY_STOPPED
-
ESP_ERR_ESP_NETIF_NO_MEM
-
ESP_ERR_ESP_NETIF_DHCP_NOT_STOPPED
-
ESP_ERR_ESP_NETIF_DRIVER_ATTACH_FAILED
-
ESP_ERR_ESP_NETIF_INIT_FAILED
-
ESP_ERR_ESP_NETIF_DNS_NOT_CONFIGURED
-
ESP_ERR_ESP_NETIF_MLD6_FAILED
-
ESP_ERR_ESP_NETIF_IP6_ADDR_FAILED
-
ESP_ERR_ESP_NETIF_DHCPS_START_FAILED
-
ESP_NETIF_BR_FLOOD
Definition of ESP-NETIF bridge controll.
-
ESP_NETIF_BR_DROP
-
ESP_NETIF_BR_FDW_CPU
Type Definitions
-
typedef struct esp_netif_obj esp_netif_t
-
typedef enum esp_netif_flags esp_netif_flags_t
-
typedef enum esp_netif_ip_event_type esp_netif_ip_event_type_t
-
typedef struct bridgeif_config bridgeif_config_t
LwIP bridge configuration
-
typedef struct esp_netif_inherent_config esp_netif_inherent_config_t
ESP-netif inherent config parameters.
-
typedef struct esp_netif_config esp_netif_config_t
-
typedef void *esp_netif_iodriver_handle
IO driver handle type.
-
typedef struct esp_netif_driver_base_s esp_netif_driver_base_t
ESP-netif driver base handle.
-
typedef struct esp_netif_driver_ifconfig esp_netif_driver_ifconfig_t
-
typedef struct esp_netif_netstack_config esp_netif_netstack_config_t
Specific L3 network stack configuration.
-
typedef esp_err_t (*esp_netif_receive_t)(esp_netif_t *esp_netif, void *buffer, size_t len, void *eb)
ESP-NETIF Receive function type.
Enumerations
-
enum esp_netif_dns_type_t
Type of DNS server.
Values:
-
enumerator ESP_NETIF_DNS_MAIN
DNS main server address
-
enumerator ESP_NETIF_DNS_BACKUP
DNS backup server address (Wi-Fi STA and Ethernet only)
-
enumerator ESP_NETIF_DNS_FALLBACK
DNS fallback server address (Wi-Fi STA and Ethernet only)
-
enumerator ESP_NETIF_DNS_MAX
-
enumerator ESP_NETIF_DNS_MAIN
-
enum esp_netif_dhcp_status_t
Status of DHCP client or DHCP server.
Values:
-
enumerator ESP_NETIF_DHCP_INIT
DHCP client/server is in initial state (not yet started)
-
enumerator ESP_NETIF_DHCP_STARTED
DHCP client/server has been started
-
enumerator ESP_NETIF_DHCP_STOPPED
DHCP client/server has been stopped
-
enumerator ESP_NETIF_DHCP_STATUS_MAX
-
enumerator ESP_NETIF_DHCP_INIT
-
enum esp_netif_dhcp_option_mode_t
Mode for DHCP client or DHCP server option functions.
Values:
-
enumerator ESP_NETIF_OP_START
-
enumerator ESP_NETIF_OP_SET
Set option
-
enumerator ESP_NETIF_OP_GET
Get option
-
enumerator ESP_NETIF_OP_MAX
-
enumerator ESP_NETIF_OP_START
-
enum esp_netif_dhcp_option_id_t
Supported options for DHCP client or DHCP server.
Values:
-
enumerator ESP_NETIF_SUBNET_MASK
Network mask
-
enumerator ESP_NETIF_DOMAIN_NAME_SERVER
Domain name server
-
enumerator ESP_NETIF_ROUTER_SOLICITATION_ADDRESS
Solicitation router address
-
enumerator ESP_NETIF_REQUESTED_IP_ADDRESS
Request specific IP address
-
enumerator ESP_NETIF_IP_ADDRESS_LEASE_TIME
Request IP address lease time
-
enumerator ESP_NETIF_IP_REQUEST_RETRY_TIME
Request IP address retry counter
-
enumerator ESP_NETIF_VENDOR_CLASS_IDENTIFIER
Vendor Class Identifier of a DHCP client
-
enumerator ESP_NETIF_VENDOR_SPECIFIC_INFO
Vendor Specific Information of a DHCP server
-
enumerator ESP_NETIF_SUBNET_MASK
-
enum ip_event_t
IP event declarations
Values:
-
enumerator IP_EVENT_STA_GOT_IP
station got IP from connected AP
-
enumerator IP_EVENT_STA_LOST_IP
station lost IP and the IP is reset to 0
-
enumerator IP_EVENT_AP_STAIPASSIGNED
soft-AP assign an IP to a connected station
-
enumerator IP_EVENT_GOT_IP6
station or ap or ethernet interface v6IP addr is preferred
-
enumerator IP_EVENT_ETH_GOT_IP
ethernet got IP from connected AP
-
enumerator IP_EVENT_ETH_LOST_IP
ethernet lost IP and the IP is reset to 0
-
enumerator IP_EVENT_PPP_GOT_IP
PPP interface got IP
-
enumerator IP_EVENT_PPP_LOST_IP
PPP interface lost IP
-
enumerator IP_EVENT_STA_GOT_IP
-
enum esp_netif_flags
Values:
-
enumerator ESP_NETIF_DHCP_CLIENT
-
enumerator ESP_NETIF_DHCP_SERVER
-
enumerator ESP_NETIF_FLAG_AUTOUP
-
enumerator ESP_NETIF_FLAG_GARP
-
enumerator ESP_NETIF_FLAG_EVENT_IP_MODIFIED
-
enumerator ESP_NETIF_FLAG_IS_PPP
-
enumerator ESP_NETIF_FLAG_IS_BRIDGE
-
enumerator ESP_NETIF_FLAG_MLDV6_REPORT
-
enumerator ESP_NETIF_DHCP_CLIENT
Header File
This header file can be included with:
#include "esp_netif_ip_addr.h"
This header file is a part of the API provided by the
esp_netif
component. To declare that your component depends onesp_netif
, add the following to your CMakeLists.txt:REQUIRES esp_netif
or
PRIV_REQUIRES esp_netif
Functions
-
esp_ip6_addr_type_t esp_netif_ip6_get_addr_type(esp_ip6_addr_t *ip6_addr)
Get the IPv6 address type.
- Parameters
ip6_addr -- [in] IPv6 type
- Returns
IPv6 type in form of enum esp_ip6_addr_type_t
-
static inline void esp_netif_ip_addr_copy(esp_ip_addr_t *dest, const esp_ip_addr_t *src)
Copy IP addresses.
- Parameters
dest -- [out] destination IP
src -- [in] source IP
Structures
-
struct esp_ip6_addr
IPv6 address.
-
struct _ip_addr
IP address.
Public Members
-
esp_ip6_addr_t ip6
IPv6 address type
-
esp_ip4_addr_t ip4
IPv4 address type
-
uint8_t type
ipaddress type
-
esp_ip6_addr_t ip6
Macros
-
esp_netif_htonl(x)
-
esp_netif_ip4_makeu32(a, b, c, d)
-
ESP_IP6_ADDR_BLOCK1(ip6addr)
-
ESP_IP6_ADDR_BLOCK2(ip6addr)
-
ESP_IP6_ADDR_BLOCK3(ip6addr)
-
ESP_IP6_ADDR_BLOCK4(ip6addr)
-
ESP_IP6_ADDR_BLOCK5(ip6addr)
-
ESP_IP6_ADDR_BLOCK6(ip6addr)
-
ESP_IP6_ADDR_BLOCK7(ip6addr)
-
ESP_IP6_ADDR_BLOCK8(ip6addr)
-
IPSTR
-
esp_ip4_addr_get_byte(ipaddr, idx)
-
esp_ip4_addr1(ipaddr)
-
esp_ip4_addr2(ipaddr)
-
esp_ip4_addr3(ipaddr)
-
esp_ip4_addr4(ipaddr)
-
esp_ip4_addr1_16(ipaddr)
-
esp_ip4_addr2_16(ipaddr)
-
esp_ip4_addr3_16(ipaddr)
-
esp_ip4_addr4_16(ipaddr)
-
IP2STR(ipaddr)
-
IPV6STR
-
IPV62STR(ipaddr)
-
ESP_IPADDR_TYPE_V4
-
ESP_IPADDR_TYPE_V6
-
ESP_IPADDR_TYPE_ANY
-
ESP_IP4TOUINT32(a, b, c, d)
-
ESP_IP4TOADDR(a, b, c, d)
-
ESP_IP4ADDR_INIT(a, b, c, d)
-
ESP_IP6ADDR_INIT(a, b, c, d)
-
IP4ADDR_STRLEN_MAX
-
ESP_IP_IS_ANY(addr)
Type Definitions
-
typedef struct esp_ip4_addr esp_ip4_addr_t
-
typedef struct esp_ip6_addr esp_ip6_addr_t
Enumerations
Header File
This header file can be included with:
#include "esp_vfs_l2tap.h"
This header file is a part of the API provided by the
esp_netif
component. To declare that your component depends onesp_netif
, add the following to your CMakeLists.txt:REQUIRES esp_netif
or
PRIV_REQUIRES esp_netif
Functions
-
esp_err_t esp_vfs_l2tap_intf_register(l2tap_vfs_config_t *config)
Add L2 TAP virtual filesystem driver.
This function must be called prior usage of ESP-NETIF L2 TAP Interface
- Parameters
config -- L2 TAP virtual filesystem driver configuration. Default base path /dev/net/tap is used when this paramenter is NULL.
- Returns
esp_err_t
ESP_OK on success
-
esp_err_t esp_vfs_l2tap_intf_unregister(const char *base_path)
Removes L2 TAP virtual filesystem driver.
- Parameters
base_path -- Base path to the L2 TAP virtual filesystem driver. Default path /dev/net/tap is used when this paramenter is NULL.
- Returns
esp_err_t
ESP_OK on success
-
esp_err_t esp_vfs_l2tap_eth_filter(l2tap_iodriver_handle driver_handle, void *buff, size_t *size)
Filters received Ethernet L2 frames into L2 TAP infrastructure.
- Parameters
driver_handle -- handle of driver at which the frame was received
buff -- received L2 frame
size -- input length of the L2 frame which is set to 0 when frame is filtered into L2 TAP
- Returns
esp_err_t
ESP_OK is always returned
Structures
Macros
-
L2TAP_VFS_DEFAULT_PATH
-
L2TAP_VFS_CONFIG_DEFAULT()
Type Definitions
-
typedef void *l2tap_iodriver_handle