6da41b5900
The goal here is to remove a slot (making way to turn make_new into a slot) as well as reduce code size by the ~40 references to mp_identity_getiter and mp_stream_unbuffered_iter. This introduces two new type flags: - MP_TYPE_FLAG_ITER_IS_ITERNEXT: This means that the "iter" slot in the type is "iternext", and should use the identity getiter. - MP_TYPE_FLAG_ITER_IS_CUSTOM: This means that the "iter" slot is a pointer to a mp_getiter_iternext_custom_t instance, which then defines both getiter and iternext. And a third flag that is the OR of both, MP_TYPE_FLAG_ITER_IS_STREAM: This means that the type should use the identity getiter, and mp_stream_unbuffered_iter as iternext. Finally, MP_TYPE_FLAG_ITER_IS_GETITER is defined as a no-op flag to give the default case where "iter" is "getiter". Signed-off-by: Jim Mussared <jim.mussared@gmail.com> |
||
---|---|---|
.. | ||
boards | ||
modules | ||
esp_init_data.c | ||
esp_mphal.c | ||
esp_mphal.h | ||
espapa102.c | ||
espapa102.h | ||
esppwm.c | ||
esppwm.h | ||
ets_alt_task.c | ||
ets_alt_task.h | ||
etshal.h | ||
fatfs_port.c | ||
gccollect.c | ||
gccollect.h | ||
gchelper.s | ||
help.c | ||
hspi_register.h | ||
hspi.c | ||
hspi.h | ||
lexerstr32.c | ||
machine_adc.c | ||
machine_bitstream.c | ||
machine_hspi.c | ||
machine_pin.c | ||
machine_pwm.c | ||
machine_rtc.c | ||
machine_uart.c | ||
machine_wdt.c | ||
main.c | ||
Makefile | ||
makeimg.py | ||
modesp.c | ||
modmachine.c | ||
modmachine.h | ||
modnetwork.c | ||
moduos.c | ||
modutime.c | ||
mpconfigport.h | ||
posix_helpers.c | ||
qstrdefsport.h | ||
README.md | ||
strtoll.c | ||
uart_register.h | ||
uart.c | ||
uart.h | ||
user_config.h | ||
xtirq.h |
MicroPython port to ESP8266
This is an experimental port of MicroPython for the WiFi modules based on Espressif ESP8266 chip.
WARNING: The port is experimental and many APIs are subject to change.
Supported features include:
- REPL (Python prompt) over UART0.
- Garbage collector, exceptions.
- Unicode support.
- Builtin modules: gc, array, collections, io, struct, sys, esp, network, many more.
- Arbitrary-precision long integers and 30-bit precision floats.
- WiFi support.
- Sockets using modlwip.
- GPIO and bit-banging I2C, SPI support.
- 1-Wire and WS2812 (aka Neopixel) protocols support.
- Internal filesystem using the flash.
- WebREPL over WiFi from a browser (clients at https://github.com/micropython/webrepl).
- Modules for HTTP, MQTT, many other formats and protocols via https://github.com/micropython/micropython-lib .
Documentation is available at http://docs.micropython.org/en/latest/esp8266/quickref.html.
Build instructions
You need the esp-open-sdk toolchain, which provides both the compiler and libraries.
There are two ways to do this:
- By running the toolchain in Docker (recommended).
- By installing a pre-built toolchain and adding it to your
$PATH
.
Regardless of which toolchain you use, the first step is to make sure required submodules are available:
$ make -C ports/esp8266 submodules
See the README in the repository root for more information about external dependencies.
Building with Docker
Once you have installed Docker, you can run all of the following build
commands inside the Docker container by prefixing them with docker run --rm -v $HOME:$HOME -u $UID -w $PWD larsks/esp-open-sdk ...command...
.
This will automatically download the Docker image provided by @larsks which
contains the full toolchain and SDK.
Then you need to compile the MicroPython cross-compiler (mpy-cross
). From
the root of this repository, run:
$ docker run --rm -v $HOME:$HOME -u $UID -w $PWD larsks/esp-open-sdk make -C mpy-cross
Note: The mpy-cross
binary will likely only work inside the Docker
container. This will not be a problem if you're only building ESP8266
firmware, but if you're also working on other ports then you will need to
recompile for your host when switching between ports. To avoid this, use
the local toolchain instead.
Then to compile the ESP8266 firmware:
$ cd ports/esp8266
$ docker run --rm -v $HOME:$HOME -u $UID -w $PWD larsks/esp-open-sdk make -j BOARD=GENERIC
This will produce binary images in the build-GENERIC/
subdirectory.
Substitute the board for whichever board you're using.
Building with a local toolchain
First download the pre-built toolchain (thanks to @jepler from Adafruit). You
will need to find somewhere to put it in your filesystem, e.g. ~/espressif
.
Create that directory first if necessary.
$ cd ~/espressif # Change as necessary
$ wget https://github.com/jepler/esp-open-sdk/releases/download/2018-06-10/xtensa-lx106-elf-standalone.tar.gz
$ tar zxvf xtensa-lx106-elf-standalone.tar.gz
$ rm xtensa-lx106-elf/bin/esptool.py # Use system version of esptool.py instead.
Then append this to your $PATH
variable so the compiler binaries can be
found:
$ export "PATH=$HOME/espressif/xtensa-lx106-elf/bin/:$PATH"
(You will need to do this each time you start a new terminal)
Then you need to compile the MicroPython cross-compiler (mpy-cross
). From
the root of this repository, run:
$ make -C mpy-cross
Then to compile the ESP8266 firmware:
$ cd ports/esp8266
$ make -j BOARD=GENERIC
This will produce binary images in the build-GENERIC/
subdirectory.
Substitute the board for whichever board you're using.
Installing MicroPython
To communicate with the board you will need to install esptool.py
. This can
be obtained from your system package manager or from PyPi via pip
.
If you install MicroPython to your module for the first time, or after installing any other firmware, you should erase flash completely:
$ esptool.py --port /dev/ttyXXX erase_flash
Erasing the flash is also useful as a troubleshooting measure, if a module doesn't behave as expected.
To flash MicroPython image to your ESP8266, use:
$ make deploy
(If using the Docker instructions above, do not run this command via Docker as it will need access to the serial port. Run it directly instead.)
This will use the esptool.py
script to download the images. You must have
your ESP module in the bootloader mode, and connected to a serial port on your PC.
The default serial port is /dev/ttyACM0
, flash mode is qio
and flash size is
detect
(auto-detect based on Flash ID).
To specify other values for esptool.py
, use, e.g.:
$ make PORT=/dev/ttyUSB0 FLASH_MODE=qio FLASH_SIZE=32m deploy
(note that flash size is in megabits)
If you want to flash manually using esptool.py
directly, the image produced is
build-GENERIC/firmware-combined.bin
, to be flashed at 0x00000.
The default board definition is the directory boards/GENERIC
.
For a custom configuration you can define your own board in the directory boards/
.
The BOARD
variable can be set on the make command line, for example:
$ make BOARD=GENERIC_512K
512KB FlashROM version
The normal build described above requires modules with at least 1MB of FlashROM
onboard. There's a special configuration for 512KB modules, which can be
built with make BOARD=GENERIC_512K
. This configuration is highly limited, lacks
filesystem support, WebREPL, and has many other features disabled. It's mostly
suitable for advanced users who are interested to fine-tune options to achieve a
required setup. If you are an end user, please consider using a module with at
least 1MB of FlashROM.
First start
Be sure to change ESP8266's WiFi access point password ASAP, see below.
Serial prompt
You can access the REPL (Python prompt) over UART (the same as used for programming).
- Baudrate: 115200
Run help()
for some basic information.
WiFi
Initially, the device configures itself as a WiFi access point (AP).
- ESSID: MicroPython-xxxxxx (x’s are replaced with part of the MAC address).
- Password: micropythoN (note the upper-case N).
- IP address of the board: 192.168.4.1.
- DHCP-server is activated.
- Please be sure to change the password to something non-guessable
immediately.
help()
gives information how.
WebREPL
Python prompt over WiFi, connecting through a browser.
- Hosted at http://micropython.org/webrepl.
- GitHub repository https://github.com/micropython/webrepl. Please follow the instructions there.
upip
The ESP8266 port comes with builtin upip
package manager, which can
be used to install additional modules (see the main README for more
information):
>>> import upip
>>> upip.install("micropython-pystone_lowmem")
[...]
>>> import pystone_lowmem
>>> pystone_lowmem.main()
Downloading and installing packages may requite a lot of free memory, if you get an error, retry immediately after the hard reset.
Documentation
More detailed documentation and instructions can be found at http://docs.micropython.org/en/latest/esp8266/ , which includes Quick Reference, Tutorial, General Information related to ESP8266 port, and to MicroPython in general.
Troubleshooting
While the port is in beta, it's known to be generally stable. If you experience strange bootloops, crashes, lockups, here's a list to check against:
- You didn't erase flash before programming MicroPython firmware.
- Firmware can be occasionally flashed incorrectly. Just retry. Recent esptool.py versions have --verify option.
- Power supply you use doesn't provide enough power for ESP8266 or isn't stable enough.
- A module/flash may be defective (not unheard of for cheap modules).
Please consult dedicated ESP8266 forums/resources for hardware-related problems.
Additional information may be available by the documentation links above.