cfa55b4ca1
mp_thread_begin_atomic_section() is expected to be recursive (i.e. for nested machine.disable_irq() calls, or if Python code calls disable_irq() and then the Python runtime calls mp_handle_pending() which also enters an atomic section to check the scheduler state). On rp2 when not using core1 the atomic sections are recursive. However when core1 was active (i.e. _thread) then there was a bug that caused the core to live-lock if an atomic section recursed. Adds a test case specifically for mutual exclusion and recursive atomic sections when using two threads. Without this fix the test immediately hangs on rp2. This work was funded through GitHub Sponsors. Signed-off-by: Angus Gratton <angus@redyak.com.au>
The RP2 port
This is a port of MicroPython to the Raspberry Pi RP2 series of microcontrollers. Currently supported features are:
- REPL over USB VCP, and optionally over UART (on GP0/GP1).
- Filesystem on the internal flash, using littlefs2.
- Support for native code generation and inline assembler.
timemodule with sleep, time and ticks functions.osmodule with VFS support.machinemodule with the following classes:Pin,ADC,PWM,I2C,SPI,SoftI2C,SoftSPI,Timer,UART,WDT.rp2module with programmable IO (PIO) support.
See the examples/rp2/ directory for some example code.
Building
The MicroPython cross-compiler must be built first, which will be used to pre-compile (freeze) built-in Python code. This cross-compiler is built and run on the host machine using:
$ make -C mpy-cross
This command should be executed from the root directory of this repository. All other commands below should be executed from the ports/rp2/ directory.
Building of the RP2 firmware is done entirely using CMake, although a simple Makefile is also provided as a convenience. To build the firmware run (from this directory):
$ make submodules
$ make clean
$ make
You can also build the standard CMake way. The final firmware is found in
the top-level of the CMake build directory (build by default) and is
called firmware.uf2.
If you are using a board other than a Raspberry Pi Pico, you should pass the board name to the build; e.g. for Raspberry Pi Pico W:
$ make BOARD=RPI_PICO_W submodules
$ make BOARD=RPI_PICO_W clean
$ make BOARD=RPI_PICO_W
Deploying firmware to the device
Firmware can be deployed to the device by putting it into bootloader mode
(hold down BOOTSEL while powering on or resetting) and then copying
firmware.uf2 to the USB mass storage device that appears.
If MicroPython is already installed then the bootloader can be entered by
executing import machine; machine.bootloader() at the REPL.
Sample code
The following samples can be easily run on the board by entering paste mode with Ctrl-E at the REPL, then cut-and-pasting the sample code to the REPL, then executing the code with Ctrl-D.
Blinky
This blinks the on-board LED on the Pico board at 1.25Hz, using a Timer object with a callback.
from machine import Pin, Timer
led = Pin(25, Pin.OUT)
tim = Timer()
def tick(timer):
global led
led.toggle()
tim.init(freq=2.5, mode=Timer.PERIODIC, callback=tick)
PIO blinky
This blinks the on-board LED on the Pico board at 1Hz, using a PIO peripheral and PIO assembler to directly toggle the LED at the required rate.
from machine import Pin
import rp2
@rp2.asm_pio(set_init=rp2.PIO.OUT_LOW)
def blink_1hz():
# Turn on the LED and delay, taking 1000 cycles.
set(pins, 1)
set(x, 31) [6]
label("delay_high")
nop() [29]
jmp(x_dec, "delay_high")
# Turn off the LED and delay, taking 1000 cycles.
set(pins, 0)
set(x, 31) [6]
label("delay_low")
nop() [29]
jmp(x_dec, "delay_low")
# Create StateMachine(0) with the blink_1hz program, outputting on Pin(25).
sm = rp2.StateMachine(0, blink_1hz, freq=2000, set_base=Pin(25))
sm.active(1)
See the examples/rp2/ directory for further example code.