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wasp-os/README.md
2020-05-11 21:56:23 +01:00

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Watch Application System in Python

Introduction

Currently in its infancy wasp-os provides only a little more than a simple digital clock application for PineTime together with access to the MicroPython REPL for interactive testing and tweaking. However it keeps time well and has enough power saving functions implemented that it can survive for well over 72 hours between charges so even at this early stage it is functional as a wearable timepiece.

WASP includes a robust bootloader based on the Adafruit NRF52 Bootloader. It has been extended to make it robust for development on form-factor devices without a reset button, power switch, SWD debugger or UART. This allows us to confidently develop on sealed devices relying only on BLE for updates.

Videos

An M2 pre-release running on Pine64 PineTime
An M2 pre-release running on Pine64 PineTime

How to develop wasp-os python applications on a Pine64 PineTime
How to develop wasp-os python applications on a Pine64 PineTime

Developing for Pine64 PineTime using wasp-os and MicroPython
Developing for Pine64 PineTime using wasp-os and MicroPython

Documentation

WASP is has extensive documentation which includes a detailed Applicaiton Writer's Guide to help you get started coding for WASP as quickly as possible.

Building from a git clone

Get the code from https://github.com/daniel-thompson/wasp-os .

pip3 install --user click serial pyserial
make submodules
make softdevice
make -j `nproc` BOARD=pinetime all

Note: You will need a toolchain for the Arm Cortex-M4. wasp-os is developed and tested using the GNU-RM toolchain (9-2019-q4) from Arm.

Note #2: There are known problems with toolchains older than gcc-7.3 due to problems with link-time-optimization (which is enabled by default)

Installing

Note: If you have a new PineTime then it will have been delivered with flash protection enabled. You must disable the flash protection before trying to program it.

Use an SWD programmer to install bootloader.hex to the PineTime. This file is an Intel HEX file containing both the bootloader and the Nordic SoftDevice. Be careful to disconnect cleanly from the debug software since just pulling out the SWD cable will mean the nRF52 will still believe it is being debugged (and won't properly enter deep sleep modes).

To install using Android device:

  • Copy micropython.zip to your Android device and download nRF Connect for Android if you do not already have it.
  • In nRF Connect, choose settings and reduce the DFU packet count from 10 to 4.
  • Connect to PineDFU using nRFConnect, click the DFU button and send micropython.zip to the device.

To install using Linux and ota-dfu:

  • Look up the MAC address for your watch (try: sudo hcitool lescan).
  • Use ota-dfu to upload micropython.zip to the device. For example: tools/ota-dfu/dfu.py -z micropython.zip -a A0:B1:C2:D3:E3:F5 --legacy

At the end of this process your watch will show the time (03:00) together with a date and battery meter. When the watch goes into power saving mode you can use the side button to wake it again.

At this point you will also be able to use the Nordic UART Service to access the MicroPython REPL, although currently you must send ^C to interrupt the program that updates the watch display.

Just for fun try:

^C
import demo
demo.run()
# After watching the demo for a bit...
^C
wasp.app.draw(watch)
wasp.system.run()

To set the time and restart the main application:

^C
watch.rtc.set_localtime((yyyy, mm, dd, HH, MM, SS))
wasp.system.run()

Or just use:

./tools/wasptool --rtc

which can run these commands automatically.

As mentioned above there are many drivers and features still to be developed, see the TODO list for current status.

Screenshots

wasp-os digital clock app running on PineTime