f35aae366c
So they don't clash with other VFS implementations. |
||
|---|---|---|
| .. | ||
| modules | ||
| Makefile | ||
| README.md | ||
| README.ulp.md | ||
| esp32.custom_common.ld | ||
| esp32_ulp.c | ||
| espneopixel.c | ||
| esponewire.c | ||
| fatfs_port.c | ||
| gccollect.c | ||
| gccollect.h | ||
| help.c | ||
| machine_adc.c | ||
| machine_dac.c | ||
| machine_hw_spi.c | ||
| machine_pin.c | ||
| machine_pwm.c | ||
| machine_rtc.c | ||
| machine_rtc.h | ||
| machine_timer.c | ||
| machine_touchpad.c | ||
| machine_uart.c | ||
| machine_wdt.c | ||
| main.c | ||
| makeimg.py | ||
| memory.h | ||
| modesp.c | ||
| modesp.h | ||
| modesp32.c | ||
| modesp32.h | ||
| modmachine.c | ||
| modmachine.h | ||
| modnetwork.c | ||
| modnetwork.h | ||
| modsocket.c | ||
| moduhashlib.c | ||
| moduos.c | ||
| modutime.c | ||
| mpconfigport.h | ||
| mphalport.c | ||
| mphalport.h | ||
| mpthreadport.c | ||
| mpthreadport.h | ||
| network_lan.c | ||
| partitions.csv | ||
| qstrdefsport.h | ||
| sdkconfig.h | ||
| uart.c | ||
| uart.h | ||
README.md
MicroPython port to the ESP32
This is an experimental port of MicroPython to the Espressif ESP32 microcontroller. It uses the ESP-IDF framework and MicroPython runs as a task under FreeRTOS.
Supported features include:
- REPL (Python prompt) over UART0.
- 16k stack for the MicroPython task and 96k Python heap.
- Many of MicroPython's features are enabled: unicode, arbitrary-precision integers, single-precision floats, complex numbers, frozen bytecode, as well as many of the internal modules.
- Internal filesystem using the flash (currently 2M in size).
- The machine module with GPIO, UART, SPI, software I2C, ADC, DAC, PWM, TouchPad, WDT and Timer.
- The network module with WLAN (WiFi) support.
Development of this ESP32 port was sponsored in part by Microbric Pty Ltd.
Setting up the toolchain and ESP-IDF
There are two main components that are needed to build the firmware:
- the Xtensa cross-compiler that targets the CPU in the ESP32 (this is different to the compiler used by the ESP8266)
- the Espressif IDF (IoT development framework, aka SDK)
The ESP-IDF changes quickly and MicroPython only supports a certain version. The
git hash of this version can be found by running make without a configured
ESPIDF. Then you can fetch only the given esp-idf using the following command:
$ git clone https://github.com/espressif/esp-idf.git
$ git checkout <Current supported ESP-IDF commit hash>
$ git submodule update --init --recursive
The binary toolchain (binutils, gcc, etc.) can be installed using the following guides:
If you are on a Windows machine then the Windows Subsystem for Linux is the most efficient way to install the ESP32 toolchain and build the project. If you use WSL then follow the Linux guidelines for the ESP-IDF instead of the Windows ones.
The Espressif ESP-IDF instructions above only install pyserial for Python 2,
so if you're running Python 3 or a non-system Python you'll also need to
install pyserial (or esptool) so that the Makefile can flash the board
and set parameters:
$ pip install pyserial
Once everything is set up you should have a functioning toolchain with
prefix xtensa-esp32-elf- (or otherwise if you configured it differently)
as well as a copy of the ESP-IDF repository. You will need to update your PATH
environment variable to include the ESP32 toolchain. For example, you can issue
the following commands on (at least) Linux:
$ export PATH=$PATH:$HOME/esp/crosstool-NG/builds/xtensa-esp32-elf/bin
You can put this command in your .profile or .bash_login.
You then need to set the ESPIDF environment/makefile variable to point to
the root of the ESP-IDF repository. You can set the variable in your PATH,
or at the command line when calling make, or in your own custom makefile.
The last option is recommended as it allows you to easily configure other
variables for the build. In that case, create a new file in the esp32
directory called makefile and add the following lines to that file:
ESPIDF = <path to root of esp-idf repository>
#PORT = /dev/ttyUSB0
#FLASH_MODE = qio
#FLASH_SIZE = 4MB
#CROSS_COMPILE = xtensa-esp32-elf-
#CONFIG_SPIRAM_SUPPORT = 1
include Makefile
Be sure to enter the correct path to your local copy of the IDF repository
(and use $(HOME), not tilde, to reference your home directory).
If your filesystem is case-insensitive then you'll need to use GNUmakefile
instead of makefile.
If the Xtensa cross-compiler is not in your path you can use the
CROSS_COMPILE variable to set its location. Other options of interest
are PORT for the serial port of your esp32 module, and FLASH_MODE
(which may need to be dio for some modules)
and FLASH_SIZE. See the Makefile for further information.
Building the firmware
The MicroPython cross-compiler must be built to pre-compile some of the built-in scripts to bytecode. This can be done by (from the root of this repository):
$ make -C mpy-cross
The ESP32 port has a dependency on Berkeley DB, which is an external dependency (git submodule). You'll need to have git initialize that module using the commands:
$ git submodule init lib/berkeley-db-1.xx
$ git submodule update
Then to build MicroPython for the ESP32 run:
$ cd ports/esp32
$ make
This will produce binary firmware images in the build/ subdirectory
(three of them: bootloader.bin, partitions.bin and application.bin).
To flash the firmware you must have your ESP32 module in the bootloader
mode and connected to a serial port on your PC. Refer to the documentation
for your particular ESP32 module for how to do this. The serial port and
flash settings are set in the Makefile, and can be overridden in your
local makefile; see above for more details.
You will also need to have user permissions to access the /dev/ttyUSB0 device.
On Linux, you can enable this by adding your user to the dialout group,
and rebooting or logging out and in again.
$ sudo adduser <username> dialout
If you are installing MicroPython to your module for the first time, or after installing any other firmware, you should first erase the flash completely:
$ make erase
To flash the MicroPython firmware to your ESP32 use:
$ make deploy
This will use the esptool.py script (provided by ESP-IDF) to download the
binary images.
Getting a Python prompt
You can get a prompt via the serial port, via UART0, which is the same UART that is used for programming the firmware. The baudrate for the REPL is 115200 and you can use a command such as:
$ picocom -b 115200 /dev/ttyUSB0
Configuring the WiFi and using the board
The ESP32 port is designed to be (almost) equivalent to the ESP8266 in terms of the modules and user-facing API. There are some small differences, notably that the ESP32 does not automatically connect to the last access point when booting up. But for the most part the documentation and tutorials for the ESP8266 should apply to the ESP32 (at least for the components that are implemented).
See http://docs.micropython.org/en/latest/esp8266/esp8266/quickref.html for a quick reference, and http://docs.micropython.org/en/latest/esp8266/esp8266/tutorial/intro.html for a tutorial.
The following function can be used to connect to a WiFi access point (you can
either pass in your own SSID and password, or change the defaults so you can
quickly call wlan_connect() and it just works):
def wlan_connect(ssid='MYSSID', password='MYPASS'):
import network
wlan = network.WLAN(network.STA_IF)
if not wlan.active() or not wlan.isconnected():
wlan.active(True)
print('connecting to:', ssid)
wlan.connect(ssid, password)
while not wlan.isconnected():
pass
print('network config:', wlan.ifconfig())
Note that some boards require you to configure the WiFi antenna before using the WiFi. On Pycom boards like the LoPy and WiPy 2.0 you need to execute the following code to select the internal antenna (best to put this line in your boot.py file):
import machine
antenna = machine.Pin(16, machine.Pin.OUT, value=0)
Troubleshooting
- Continuous reboots after programming: Ensure FLASH_MODE is correct for your
board (e.g. ESP-WROOM-32 should be DIO). Then perform a
make clean, rebuild, redeploy.