Ham MMIO
Most microcontrollers access peripherals via memory-mapped IO. Let's try turning on an LED on our micro:bit:
#![no_main] #![no_std] extern crate panic_halt as _; mod interrupts; use core::mem::size_of; use cortex_m_rt::entry; /// GPIO port 0 peripheral address const GPIO_P0: usize = 0x5000_0000; // GPIO peripheral offsets const PIN_CNF: usize = 0x700; const OUTSET: usize = 0x508; const OUTCLR: usize = 0x50c; // PIN_CNF fields const DIR_OUTPUT: u32 = 0x1; const INPUT_DISCONNECT: u32 = 0x1 << 1; const PULL_DISABLED: u32 = 0x0 << 2; const DRIVE_S0S1: u32 = 0x0 << 8; const SENSE_DISABLED: u32 = 0x0 << 16; #[entry] fn main() -> ! { // Configure GPIO 0 pins 21 and 28 as push-pull outputs. let pin_cnf_21 = (GPIO_P0 + PIN_CNF + 21 * size_of::<u32>()) as *mut u32; let pin_cnf_28 = (GPIO_P0 + PIN_CNF + 28 * size_of::<u32>()) as *mut u32; // SAFETY: The pointers are to valid peripheral control registers, and no // aliases exist. unsafe { pin_cnf_21.write_volatile( DIR_OUTPUT | INPUT_DISCONNECT | PULL_DISABLED | DRIVE_S0S1 | SENSE_DISABLED, ); pin_cnf_28.write_volatile( DIR_OUTPUT | INPUT_DISCONNECT | PULL_DISABLED | DRIVE_S0S1 | SENSE_DISABLED, ); } // Set pin 28 low and pin 21 high to turn the LED on. let gpio0_outset = (GPIO_P0 + OUTSET) as *mut u32; let gpio0_outclr = (GPIO_P0 + OUTCLR) as *mut u32; // SAFETY: The pointers are to valid peripheral control registers, and no // aliases exist. unsafe { gpio0_outclr.write_volatile(1 << 28); gpio0_outset.write_volatile(1 << 21); } loop {} }
- GPIO 0 pin 21 is connected to the first column of the LED matrix, and pin 28 to the first row.
Run the example with:
cargo embed --bin mmio