:orphan: Station Class ------------- The number of features provided by ESP8266 in the station mode is far more extensive than covered in original `Arduino WiFi library `__. Therefore, instead of supplementing original documentation, we have decided to write a new one from scratch. Description of station class has been broken down into four parts. First discusses methods to establish connection to an access point. Second provides methods to manage connection like e.g. ``reconnect`` or ``isConnected``. Third covers properties to obtain information about connection like MAC or IP address. Finally the fourth section provides alternate methods to connect like e.g. Wi-Fi Protected Setup (WPS). Table of Contents ----------------- - `Start Here <#start-here>`__ - `begin <#begin>`__ - `config <#config>`__ - `Manage Connection <#manage-connection>`__ - `reconnect <#reconnect>`__ - `disconnect <#disconnect>`__ - `isConnected <#isconnected>`__ - `setAutoConnect <#setautoconnect>`__ - `getAutoConnect <#getautoconnect>`__ - `setAutoReconnect <#setautoreconnect>`__ - `waitForConnectResult <#waitforconnectresult>`__ - `Configuration <#configuration>`__ - `macAddress <#macAddress>`__ - `localIP <#localip>`__ - `subnetMask <#subnetmask>`__ - `gatewayIP <#gatewayip>`__ - `dnsIP <#dnsip>`__ - `hostname <#hostname>`__ - `status <#status>`__ - `SSID <#ssid>`__ - `psk <#psk>`__ - `BSSID <#bssid>`__ - `RSSI <#rssi>`__ - `Connect Different <#connect-different>`__ - `WPS <#wps>`__ - `Smart Config <#smart-config>`__ Points below provide description and code snippets how to use particular methods. For more code samples please refer to separate section with `examples `__ dedicated specifically to the Station Class. Start Here ~~~~~~~~~~ Switching the module to Station mode is done with ``begin`` function. Typical parameters passed to ``begin`` include SSID and password, so module can connect to specific Access Point. .. code:: cpp WiFi.begin(ssid, password) By default, ESP will attempt to reconnect to Wi-Fi network whenever it is disconnected. There is no need to handle this by separate code. A good way to simulate disconnection would be to reset the access point. ESP will report disconnection, and then try to reconnect automatically. begin ^^^^^ There are several versions (called `function overloads `__ in C++) of ``begin`` function. One was presented just above: ``WiFi.begin(ssid, password)``. Overloads provide flexibility in number or type of accepted parameters. The simplest overload of ``begin`` is as follows: .. code:: cpp WiFi.begin() Calling it will enable station mode and connect to the last used access point based on configuration saved in flash memory. Notes: - It is possible that calling ``begin`` will result in the module being in STA + softAP mode if the module was previously placed into AP mode. - If you notice strange behavior with DNS or other network functionality, check which mode your module is in (see ``WiFi.mode()`` in the `Generic Class Documentation `__). Below is the syntax of another overload of ``begin`` with the all possible parameters: .. code:: cpp WiFi.begin(ssid, password, channel, bssid, connect) Meaning of parameters is as follows: - ``ssid`` - a character string containing the SSID of Access Point we would like to connect to, may have up to 32 characters - ``password`` to the access point, a character string that should be minimum 8 characters long and not longer than 64 characters - ``channel`` of AP, if we like to operate using specific channel, otherwise this parameter may be omitted - ``bssid`` - mac address of AP, this parameter is also optional - ``connect`` - a ``boolean`` parameter that if set to ``false``, will instruct module just to save the other parameters without actually establishing connection to the access point config ^^^^^^ Disable `DHCP `__ client (Dynamic Host Configuration Protocol) and set the IP configuration of station interface to user defined arbitrary values. The interface will be a static IP configuration instead of values provided by DHCP. .. code:: cpp WiFi.config(local_ip, gateway, subnet, dns1, dns2) Function will return ``true`` if configuration change is applied successfully. If configuration can not be applied, because e.g. module is not in station or station + soft access point mode, then ``false`` will be returned. The following IP configuration may be provided: - ``local_ip`` - enter here IP address you would like to assign the ESP station's interface - ``gateway`` - should contain IP address of gateway (a router) to access external networks - ``subnet`` - this is a mask that defines the range of IP addresses of the local network - ``dns1``, ``dns2`` - optional parameters that define IP addresses of Domain Name Servers (DNS) that maintain a directory of domain names (like e.g. *www.google.co.uk*) and translate them for us to IP addresses *Example code:* .. code:: cpp #include const char* ssid = "********"; const char* password = "********"; IPAddress staticIP(192,168,1,22); IPAddress gateway(192,168,1,9); IPAddress subnet(255,255,255,0); void setup(void) { Serial.begin(115200); Serial.println(); Serial.printf("Connecting to %s\n", ssid); WiFi.config(staticIP, gateway, subnet); WiFi.begin(ssid, password); while (WiFi.status() != WL_CONNECTED) { delay(500); Serial.print("."); } Serial.println(); Serial.print("Connected, IP address: "); Serial.println(WiFi.localIP()); } void loop() {} *Example output:* :: Connecting to sensor-net . Connected, IP address: 192.168.1.22 Please note that station with static IP configuration usually connects to the network faster. In the above example it took about 500ms (one dot `.` displayed). This is because obtaining of IP configuration by DHCP client takes time and in this case this step is skipped. If you pass all three parameter as 0.0.0.0 (local_ip, gateway and subnet), it will re enable DHCP. You need to re-connect the device to get new IPs. Manage Connection ~~~~~~~~~~~~~~~~~ reconnect ^^^^^^^^^ Reconnect the station. This is done by disconnecting from the access point an then initiating connection back to the same AP. .. code:: cpp WiFi.reconnect() Notes: 1. Station should be already connected to an access point. If this is not the case, then function will return ``false`` not performing any action. 2. If ``true`` is returned it means that connection sequence has been successfully started. User should still check for connection status, waiting until ``WL_CONNECTED`` is reported: .. code:: cpp WiFi.reconnect(); while (WiFi.status() != WL_CONNECTED) { delay(500); Serial.print("."); } disconnect ^^^^^^^^^^ Sets currently configured SSID and password to ``null`` values and disconnects the station from an access point. .. code:: cpp WiFi.disconnect(wifioff) The ``wifioff`` is an optional ``boolean`` parameter. If set to ``true``, then the station mode will be turned off. isConnected ^^^^^^^^^^^ Returns ``true`` if Station is connected to an access point or ``false`` if not. .. code:: cpp WiFi.isConnected() setAutoConnect ^^^^^^^^^^^^^^ Configure module to automatically connect on power on to the last used access point. .. code:: cpp WiFi.setAutoConnect(autoConnect) The ``autoConnect`` is an optional parameter. If set to ``false`` then auto connection functionality up will be disabled. If omitted or set to ``true``, then auto connection will be enabled. getAutoConnect ^^^^^^^^^^^^^^ This is "companion" function to ``setAutoConnect()``. It returns ``true`` if module is configured to automatically connect to last used access point on power on. .. code:: cpp WiFi.getAutoConnect() If auto connection functionality is disabled, then function returns ``false``. setAutoReconnect ^^^^^^^^^^^^^^^^ Set whether module will attempt to reconnect to an access point in case it is disconnected. .. code:: cpp WiFi.setAutoReconnect(autoReconnect) If parameter ``autoReconnect`` is set to ``true``, then module will try to reestablish lost connection to the AP. If set to ``false`` then module will stay disconnected. Note: running ``setAutoReconnect(true)`` when module is already disconnected will not make it reconnect to the access point. Instead ``reconnect()`` should be used. waitForConnectResult ^^^^^^^^^^^^^^^^^^^^ Wait until module connects to the access point. This function is intended for module configured in station or station + soft access point mode. .. code:: cpp WiFi.waitForConnectResult() Function returns one of the following connection statuses: - ``WL_CONNECTED`` after successful connection is established - ``WL_NO_SSID_AVAIL`` in case configured SSID cannot be reached - ``WL_CONNECT_FAILED`` if connection failed - ``WL_CONNECT_WRONG_PASSWORD`` if password is incorrect - ``WL_IDLE_STATUS`` when Wi-Fi is in process of changing between statuses - ``WL_DISCONNECTED`` if module is not configured in station mode - ``-1`` on timeout Configuration ~~~~~~~~~~~~~ macAddress ^^^^^^^^^^ Get the MAC address of the ESP station's interface. .. code:: cpp WiFi.macAddress(mac) Function should be provided with ``mac`` that is a pointer to memory location (an ``uint8_t`` array the size of 6 elements) to save the mac address. The same pointer value is returned by the function itself. *Example code:* .. code:: cpp if (WiFi.status() == WL_CONNECTED) { uint8_t macAddr[6]; WiFi.macAddress(macAddr); Serial.printf("Connected, mac address: %02x:%02x:%02x:%02x:%02x:%02x\n", macAddr[0], macAddr[1], macAddr[2], macAddr[3], macAddr[4], macAddr[5]); } *Example output:* :: Mac address: 5C:CF:7F:08:11:17 If you do not feel comfortable with pointers, then there is optional version of this function available. Instead of the pointer, it returns a formatted ``String`` that contains the same mac address. .. code:: cpp WiFi.macAddress() *Example code:* .. code:: cpp if (WiFi.status() == WL_CONNECTED) { Serial.printf("Connected, mac address: %s\n", WiFi.macAddress().c_str()); } localIP ^^^^^^^ Function used to obtain IP address of ESP station's interface. .. code:: cpp WiFi.localIP() The type of returned value is `IPAddress `__. There is a couple of methods available to display this type of data. They are presented in examples below that cover description of ``subnetMask``, ``gatewayIP`` and ``dnsIP`` that return the IPAdress as well. *Example code:* .. code:: cpp if (WiFi.status() == WL_CONNECTED) { Serial.print("Connected, IP address: "); Serial.println(WiFi.localIP()); } *Example output:* :: Connected, IP address: 192.168.1.10 subnetMask ^^^^^^^^^^ Get the subnet mask of the station's interface. .. code:: cpp WiFi.subnetMask() Module should be connected to the access point to obtain the subnet mask. *Example code:* .. code:: cpp Serial.print("Subnet mask: "); Serial.println(WiFi.subnetMask()); *Example output:* :: Subnet mask: 255.255.255.0 gatewayIP ^^^^^^^^^ Get the IP address of the gateway. .. code:: cpp WiFi.gatewayIP() *Example code:* .. code:: cpp Serial.printf("Gataway IP: %s\n", WiFi.gatewayIP().toString().c_str()); *Example output:* :: Gataway IP: 192.168.1.9 dnsIP ^^^^^ Get the IP addresses of Domain Name Servers (DNS). .. code:: cpp WiFi.dnsIP(dns_no) With the input parameter ``dns_no`` we can specify which Domain Name Server's IP we need. This parameter is zero based and allowed values are none, 0 or 1. If no parameter is provided, then IP of DNS #1 is returned. *Example code:* .. code:: cpp Serial.print("DNS #1, #2 IP: "); WiFi.dnsIP().printTo(Serial); Serial.print(", "); WiFi.dnsIP(1).printTo(Serial); Serial.println(); *Example output:* :: DNS #1, #2 IP: 62.179.1.60, 62.179.1.61 hostname ^^^^^^^^ Get the DHCP hostname assigned to ESP station. .. code:: cpp WiFi.hostname() Function returns ``String`` type. Default hostname is in format ``ESP_24xMAC`` where 24xMAC are the last 24 bits of module's MAC address. The hostname may be changed using the following function: .. code:: cpp WiFi.hostname(aHostname) Input parameter ``aHostname`` may be a type of ``char*``, ``const char*`` or ``String``. Maximum length of assigned hostname is 32 characters. Function returns either ``true`` or ``false`` depending on result. For instance, if the limit of 32 characters is exceeded, function will return ``false`` without assigning the new hostname. *Example code:* .. code:: cpp Serial.printf("Default hostname: %s\n", WiFi.hostname().c_str()); WiFi.hostname("Station_Tester_02"); Serial.printf("New hostname: %s\n", WiFi.hostname().c_str()); *Example output:* :: Default hostname: ESP_081117 New hostname: Station_Tester_02 status ^^^^^^ Return the status of Wi-Fi connection. .. code:: cpp WiFi.status() Function returns one of the following connection statuses: - ``WL_CONNECTED`` after successful connection is established - ``WL_NO_SSID_AVAIL`` in case configured SSID cannot be reached - ``WL_CONNECT_FAILED`` if password is incorrect - ``WL_IDLE_STATUS`` when Wi-Fi is in process of changing between statuses - ``WL_DISCONNECTED`` if module is not configured in station mode Returned value is type of ``wl_status_t`` defined in `wl\_definitions.h `__ *Example code:* .. code:: cpp #include void setup(void) { Serial.begin(115200); Serial.printf("Connection status: %d\n", WiFi.status()); Serial.printf("Connecting to %s\n", ssid); WiFi.begin(ssid, password); Serial.printf("Connection status: %d\n", WiFi.status()); while (WiFi.status() != WL_CONNECTED) { delay(500); Serial.print("."); } Serial.printf("\nConnection status: %d\n", WiFi.status()); Serial.print("Connected, IP address: "); Serial.println(WiFi.localIP()); } void loop() {} *Example output:* :: Connection status: 6 Connecting to sensor-net Connection status: 6 ...... Connection status: 3 Connected, IP address: 192.168.1.10 Particular connection statuses 6 and 3 may be looked up in `wl\_definitions.h `__ as follows: :: 3 - WL_CONNECTED 6 - WL_DISCONNECTED Basing on this example, when running above code, module is initially disconnected from the network and returns connection status ``6 - WL_DISCONNECTED``. It is also disconnected immediately after running ``WiFi.begin(ssid, password)``. Then after about 3 seconds (basing on number of dots displayed every 500ms), it finally gets connected returning status ``3 - WL_CONNECTED``. SSID ^^^^ Return the name of Wi-Fi network, formally called `Service Set Identification (SSID) `__. .. code:: cpp WiFi.SSID() Returned value is of the ``String`` type. *Example code:* .. code:: cpp Serial.printf("SSID: %s\n", WiFi.SSID().c_str()); *Example output:* :: SSID: sensor-net psk ^^^ Return current pre shared key (password) associated with the Wi-Fi network. .. code:: cpp WiFi.psk() Function returns value of the ``String`` type. BSSID ^^^^^ Return the mac address of the access point to which the ESP module was directed to connect to. This address is formally called `Basic Service Set Identification (BSSID) `__. The returned pointer is what the user configured when calling begin() with a bssid argument. It does _not_ necessarily reflect the mac address of the access point to which the ESP module's station interface is currently connected to. .. code:: cpp WiFi.BSSID() The ``BSSID()`` function returns a pointer to the memory location (an ``uint8_t`` array with the size of 6 elements) where the BSSID is saved. Below is similar function, but returning BSSID but as a ``String`` type. .. code:: cpp WiFi.BSSIDstr() *Example code:* .. code:: cpp Serial.printf("BSSID: %s\n", WiFi.BSSIDstr().c_str()); *Example output:* :: BSSID: 00:1A:70:DE:C1:68 RSSI ^^^^ Return the signal strength of Wi-Fi network, that is formally called `Received Signal Strength Indication (RSSI) `__. .. code:: cpp WiFi.RSSI() Signal strength value is provided in dBm. The type of returned value is ``int32_t``. *Example code:* .. code:: cpp Serial.printf("RSSI: %d dBm\n", WiFi.RSSI()); *Example output:* :: RSSI: -68 dBm Connect Different ~~~~~~~~~~~~~~~~~ `ESP8266 SDK `__ provides alternate methods to connect ESP station to an access point. Out of them `esp8266 / Arduino `__ core implements `WPS <#wps>`__ and `Smart Config <#smart-config>`__ as described in more details below. WPS ^^^ The following ``beginWPSConfig`` function allows connecting to a network using `Wi-Fi Protected Setup (WPS) `__. Currently only `push-button configuration `__ (``WPS_TYPE_PBC`` mode) is supported (SDK 1.5.4). .. code:: cpp WiFi.beginWPSConfig() Depending on connection result function returns either ``true`` or ``false`` (``boolean`` type). *Example code:* .. code:: cpp #include void setup(void) { Serial.begin(115200); Serial.println(); Serial.printf("Wi-Fi mode set to WIFI_STA %s\n", WiFi.mode(WIFI_STA) ? "" : "Failed!"); Serial.print("Begin WPS (press WPS button on your router) ... "); Serial.println(WiFi.beginWPSConfig() ? "Success" : "Failed"); while (WiFi.status() != WL_CONNECTED) { delay(500); Serial.print("."); } Serial.println(); Serial.print("Connected, IP address: "); Serial.println(WiFi.localIP()); } void loop() {} *Example output:* :: Wi-Fi mode set to WIFI_STA Begin WPS (press WPS button on your router) ... Success ......... Connected, IP address: 192.168.1.102 Smart Config ^^^^^^^^^^^^ The Smart Config connection of an ESP module an access point is done by sniffing for special packets that contain SSID and password of desired AP. To do so the mobile device or computer should have functionality of broadcasting of encoded SSID and password. The following three functions are provided to implement Smart Config. Start smart configuration mode by sniffing for special packets that contain SSID and password of desired Access Point. Depending on result either ``true`` or ``false`` is returned. .. code:: cpp beginSmartConfig() Query Smart Config status, to decide when stop configuration. Function returns either ``true`` or ``false`` of ``boolean`` type. .. code:: cpp smartConfigDone() Stop smart config, free the buffer taken by ``beginSmartConfig()``. Depending on result function return either ``true`` or ``false`` of ``boolean`` type. .. code:: cpp stopSmartConfig() For additional details regarding Smart Config please refer to `ESP8266 API User Guide `__.