This project brings support for ESP8266 chip to the Arduino environment. ESP8266WiFi library bundled with this project has the same interface as the WiFi Shield library, making it easy to re-use existing code and libraries.
OS | Build status | Latest release |
---|---|---|
Linux | arduino-1.6.1-linux64.tar.xz | |
Windows | arduino-1.6.1-p1-windows.zip | |
OS X | arduino-1.6.1-macosx-java-latest-signed.zip |
$ git clone https://github.com/esp8266/Arduino.git
$ cd Arduino/build
$ ant dist
- Wifio
- Generic esp8266 modules (without auto-reset support)
pinMode
, digitalRead
, digitalWrite
work as usual.
Pin numbers correspond directly to the esp8266 GPIO pin numbers. To read GPIO2,
call digitalRead(2);
GPIO0-GPIO15 can be INPUT
, OUTPUT
, INPUT_PULLUP
, and OUTPUT_OPEN_DRAIN
.
GPIO16 can be INPUT
or OUTPUT
.
analogRead(0)
reads the value of the ADC channel connected to the TOUT pin.
Pin interrupts are supported through attachInterrupt
, detachInterrupt
functions.
Interrupts may be attached to any GPIO pin, except GPIO16. Standard Arduino interrupt
types are supported: CHANGE
, RISING
, FALLING
.
millis
and micros
return the number of milliseconds and microseconds elapsed after reset, respectively.
delay
pauses the sketch for a given number of milliseconds and allows WiFi and TCP/IP tasks to run.
delayMicroseconds
pauses for a given number of microseconds.
Remember that there is a lot of code that needs to run on the chip besides the sketch
when WiFi is connected. WiFi and TCP/IP libraries get a chance to handle any pending
events each time the loop()
function completes, OR when delay(...)
is called.
If you have a loop somewhere in your sketch that takes a lot of time (>50ms) without
calling delay()
, you might consider adding a call to delay function to keep the WiFi
stack running smoothly.
There is also a yield()
function which is equivalent to delay(0)
. The delayMicroseconds
function, on the other hand, does not yield to other tasks, so using it for delays
more than 20 milliseconds is not recommended.
Serial
object works much the same way as on a regular Arduino. Apart from hardware FIFO (128 bytes for TX and RX) HardwareSerial has additional 256-byte TX and RX buffers. Both transmit and receive is interrupt-driven. Write and read functions only block the sketch execution when the respective FIFO/buffers are full/empty.
Only 8n1 mode is supported right now.
By default the diagnostic output from WiFi libraries is disabled when you call Serial.begin
. To enable debug output again, call Serial.setDebugOutput(true);
This is mostly similar to WiFi shield library. Differences include:
WiFi.mode(m)
: set mode toWIFI_AP
,WIFI_STA
, orWIFI_AP_STA
.- call
WiFi.softAP(ssid)
to set up an open network - call
WiFi.softAP(ssid, passphrase)
to set up a WPA2-PSK network WiFi.macAddress(mac)
is for STA,WiFi.softAPmacAddress(mac)
is for AP.WiFi.localIP()
is for STA,WiFi.softAPIP()
is for AP.WiFi.RSSI()
doesn't workWiFi.printDiag(Serial);
will print out some diagnostic info
WiFiServer, WiFiClient, and WiFiUDP behave mostly the same way as with WiFi shield library. Four samples are provided for this library.
Library for calling functions repeatedly with a certain period. Two examples included.
This is a bit different from standard EEPROM class. You need to call EEPROM.begin(size)
before you start reading or writing, size being the number of bytes you want to use.
Size can be anywhere between 4 and 4096 bytes.
EEPROM.write
does not write to flash immediately, instead you must call EEPROM.commit()
whenever you wish to save changes to flash. EEPROM.end()
will also commit, and will
release the RAM copy of EEPROM contents.
Three examples included.
Only master mode works, and Wire.setClock
has not been verified to give exactly correct frequency.
Before using I2C, pins for SDA and SCL need to be set by calling
Wire.pins(int sda, int scl)
, i.e. Wire.pins(0, 2);
on ESP-01.
An initial SPI support for the HSPI interface (GPIO12-15) was implemented by Sermus. The implementation supports the entire Arduino SPI API including transactions, except setting phase and polarity as it's unclear how to set them in ESP8266 yet.
APIs related to deep sleep and watchdog timer are available in the ESP
object.
ESP.deepSleep(microseconds, mode)
will put the chip into deep sleep. mode
is one of WAKE_DEFAULT
, WAKE_RFCAL
, WAKE_NO_RFCAL
, WAKE_RF_DISABLED
.
ESP.wdtEnable()
, ESP.wdtDisable()
, and ESP.wdtFeed()
provide some control over the watchdog timer.
ESP.reset()
resets the CPU.
OneWire (from https://www.pjrc.com/teensy/td_libs_OneWire.html)
Library was adapted to work with ESP8266 by including register definitions into OneWire.h Note that if you have OneWire library in your Arduino/libraries folder, it will be used instead of the one that comes with the Arduino IDE (this one).
Allows the sketch to respond to multicast DNS queries for domain names like "foo.local". See attached example and library README file for details.
Libraries that don't rely on low-level access to AVR registers should work well. Here are a few libraries that were verified to work:
- aREST REST API handler library.
- PubSubClient MQTT library. Use this sample to get started.
- DHT11 - initialize DHT as follows:
DHT dht(DHTPIN, DHTTYPE, 15);
- DallasTemperature
Pick the correct serial port. You need to put ESP8266 into bootloader mode before uploading code (pull GPIO0 low and toggle power).
- analogWrite (PWM). ESP8266 has only one hardware PWM source. It is not yet clear how to use it with analogWrite API. Software PWM is also an option, but apparently it causes issues with WiFi connectivity.
- pulseIn
- I2C slave mode
- Serial modes other than 8n1
- WiFi.RSSI. SDK doesn't seem to have an API to get RSSI for the current network. So far the only way to obtain RSSI is to disconnect, perform a scan, and get the RSSI value from there.
- Upload sketches via WiFi. Conceptually and technically simple, but need to figure out how to provide the best UX for this feature.
- Samples for all the libraries
Forum: http://www.esp8266.com/arduino
Submit issues on Github: https://github.com/esp8266/Arduino/issues
Arduino IDE is based on Wiring and Processing. It is developed and maintained by the Arduino team. The IDE is licensed under GPL, and the core libraries are licensed under LGPL.
This build includes an xtensa gcc toolchain, which is also under GPL.
Espressif SDK included in this build is under Espressif Public License.
Esptool written by Christian Klippel is licensed under GPLv2, currently maintained by Ivan Grokhotkov: https://github.com/igrr/esptool-ck.
ESP8266 core support, ESP8266WiFi, Ticker, ESP8266WebServer libraries were written by Ivan Grokhotkov, [email protected].