Raspberry Pi Pico Emulator for the Wokwi Simulation Platform. It blinks, runs Arduino code, and even the MicroPython REPL!
If you are just looking to play around with the Raspberry Pi Pico Simulator, check out the Wokwi Simulator:
For more information, take a look at the wokwi-pi-pico docs and the Pi Pico MicroPython Guide.
If you want to develop your own application using the Raspberry Pi Pico simulator, the following examples may be helpful:
- Blink LEDs with RP2040js, from scratch - Press "Run" and patiently wait for the code to compile ;-)
You'd need to get hello_uart.hex by building it from the pico-examples repo, then copy it to the rp2040js root directory and run:
npm install
npm start
To run the MicroPython demo, first download RPI_PICO-20230426-v1.20.0.uf2, place it in the rp2040js root directory, then run:
npm install
npm run start:micropython
and enjoy the MicroPython REPL! Quit the REPL with Ctrl+X. A different MicroPython UF2 image can be loaded by supplying the --image option:
npm run start:micropython -- --image=my_image.uf2
A GDB server on port 3333 can be enabled by specifying the --gdb flag:
npm run start:micropython -- --gdb
For using the MicroPython demo code in tests, the --expect-text can come handy: it will look for the given text in the serial output and exit with code 0 if found, or 1 if not found. You can find an example in the MicroPython CI test.
With MicroPython, you can use the filesystem on the Pico. This becomes useful as more than one script file is used in your code. Just put a LittleFS formatted filesystem image called littlefs.img into the rp2040js root directory, and your main.py will be automatically started from there.
A simple way to create a suitable LittleFS image containing your script files is outlined in create_littlefs_image.py. So, using littlefs-python, you can do the following:
from littlefs import LittleFS
files = ['your.py', 'files.py', 'here.py', 'main.py']
output_image = 'output/littlefs.img' # symlinked/copied to rp2040js root directory
lfs = LittleFS(block_size=4096, block_count=352, prog_size=256)
for filename in files:
with open(filename, 'rb') as src_file, lfs.open(filename, 'w') as lfs_file:
lfs_file.write(src_file.read())
with open(output_image, 'wb') as fh:
fh.write(lfs.context.buffer)Other ways of creating LittleFS images can be found here or here.
Currently, the filesystem is not writeable, as the SSI peripheral required for flash writing is not implemented yet. If you're interested in hacking, see the discussion in #88 for a workaround.
To run the CircuitPython demo, you can follow the directions above for MicroPython, except download adafruit-circuitpython-raspberry_pi_pico-en_US-8.0.2.uf2 instead of the MicroPython UF2 file. Place it in the rp2040js root directory, then run:
npm install
npm run start:circuitpython
and start the CircuitPython REPL! The rest of the experience is the same as the MicroPython demo (Ctrl+X to exit, using the --image and
--gdb options, etc).
For CircuitPython, you can create a FAT12 filesystem in Linux using the truncate and mkfs.vfat utilities:
truncate fat12.img -s 1M # make the image file
mkfs.vfat -F12 -S512 fat12.img # create the FAT12 filesystemYou can then mount the filesystem image and add files to it:
mkdir fat12 # create the mounting folder if needed
sudo mount -o loop fat12.img fat12/ # mount the filesystem to the folder
sudo cp code.py fat12/ # copy code.py to the filesystem
sudo umount fat12/ # unmount the filesystemWhile CircuitPython does not typically use a writeable filesystem, note that this functionality is unavailable (see MicroPython filesystem support section for more details).
Released under the MIT licence. Copyright (c) 2021-2023, Uri Shaked.
