//! Implementation module //! //! **File:** `board.rs` //! **Author:** Kevin Thomas //! **Date:** 2025 //! //! MIT License //! //! Copyright (c) 2025 Kevin Thomas //! //! Permission is hereby granted, free of charge, to any person obtaining a copy //! of this software and associated documentation files (the "Software"), to deal //! in the Software without restriction, including without limitation the rights //! to use, copy, modify, merge, publish, distribute, sublicense, and/or sell //! copies of the Software, and to permit persons to whom the Software is //! furnished to do so, subject to the following conditions: //! //! The above copyright notice and this permission notice shall be included in //! all copies or substantial portions of the Software. //! //! THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR //! IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, //! FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE //! AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER //! LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, //! OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE //! SOFTWARE. // I2C bus trait for device probing use embedded_hal::i2c::I2c; // Rate extension trait for .Hz() baud rate construction use fugit::RateExtU32; // Clock trait for accessing system clock frequency use hal::Clock; // GPIO pin types and function selectors use hal::gpio::{FunctionI2C, FunctionNull, FunctionUart, Pin, PullDown, PullNone, PullUp}; // UART configuration and peripheral types use hal::uart::{DataBits, Enabled, StopBits, UartConfig, UartPeripheral}; // Alias our HAL crate #[cfg(rp2350)] use rp235x_hal as hal; #[cfg(rp2040)] use rp2040_hal as hal; /// External crystal frequency in Hz (12 MHz). pub(crate) const XTAL_FREQ_HZ: u32 = 12_000_000u32; /// UART baud rate in bits per second. pub(crate) const UART_BAUD: u32 = 115_200; /// I2C bus speed in Hz (100 kHz standard mode). pub(crate) const I2C_BAUD: u32 = 100_000; /// Delay between scan cycles in milliseconds. pub(crate) const SCAN_DELAY_MS: u32 = 5_000; /// Type alias for the configured TX pin (GPIO 0, UART function, no pull). pub(crate) type TxPin = Pin; /// Type alias for the configured RX pin (GPIO 1, UART function, no pull). pub(crate) type RxPin = Pin; /// Type alias for the default TX pin state from `Pins::new()`. pub(crate) type TxPinDefault = Pin; /// Type alias for the default RX pin state from `Pins::new()`. pub(crate) type RxPinDefault = Pin; /// Type alias for the fully-enabled UART0 peripheral with TX/RX p. pub(crate) type EnabledUart = UartPeripheral; /// Initialise system clocks and PLLs from the external 12 MHz crystal. /// /// # Arguments /// /// * `xosc` - XOSC peripheral singleton. /// * `clocks` - CLOCKS peripheral singleton. /// * `pll_sys` - PLL_SYS peripheral singleton. /// * `pll_usb` - PLL_USB peripheral singleton. /// * `resets` - Mutable reference to the RESETS peripheral. /// * `watchdog` - Mutable reference to the watchdog timer. /// /// # Returns /// /// Configured clocks manager. /// /// # Panics /// /// Panics if clock initialisation fails. pub(crate) fn init_clocks( xosc: hal::pac::XOSC, clocks: hal::pac::CLOCKS, pll_sys: hal::pac::PLL_SYS, pll_usb: hal::pac::PLL_USB, resets: &mut hal::pac::RESETS, watchdog: &mut hal::Watchdog, ) -> hal::clocks::ClocksManager { hal::clocks::init_clocks_and_plls( XTAL_FREQ_HZ, xosc, clocks, pll_sys, pll_usb, resets, watchdog, ) .unwrap() } /// Unlock the GPIO bank and return the pin set. /// /// # Arguments /// /// * `io_bank0` - IO_BANK0 peripheral singleton. /// * `pads_bank0` - PADS_BANK0 peripheral singleton. /// * `sio` - SIO peripheral singleton. /// * `resets` - Mutable reference to the RESETS peripheral. /// /// # Returns /// /// GPIO pin set for the entire bank. pub(crate) fn init_pins( io_bank0: hal::pac::IO_BANK0, pads_bank0: hal::pac::PADS_BANK0, sio: hal::pac::SIO, resets: &mut hal::pac::RESETS, ) -> hal::gpio::Pins { let sio = hal::Sio::new(sio); hal::gpio::Pins::new(io_bank0, pads_bank0, sio.gpio_bank0, resets) } /// Initialise UART0 for serial output (stdio equivalent). /// /// # Arguments /// /// * `uart0` - PAC UART0 peripheral singleton. /// * `tx_pin` - GPIO pin to use as UART0 TX (GPIO 0). /// * `rx_pin` - GPIO pin to use as UART0 RX (GPIO 1). /// * `resets` - Mutable reference to the RESETS peripheral. /// * `clocks` - Reference to the initialised clock configuration. /// /// # Returns /// /// Enabled UART0 peripheral ready for blocking writes. /// /// # Panics /// /// Panics if the HAL cannot achieve the requested baud rate. pub(crate) fn init_uart( uart0: hal::pac::UART0, tx_pin: TxPinDefault, rx_pin: RxPinDefault, resets: &mut hal::pac::RESETS, clocks: &hal::clocks::ClocksManager, ) -> EnabledUart { let pins = ( tx_pin.reconfigure::(), rx_pin.reconfigure::(), ); let cfg = UartConfig::new(UART_BAUD.Hz(), DataBits::Eight, None, StopBits::One); UartPeripheral::new(uart0, pins, resets) .enable(cfg, clocks.peripheral_clock.freq()) .unwrap() } /// Create a blocking delay timer from the ARM SysTick peripheral. /// /// # Arguments /// /// * `clocks` - Reference to the initialised clock configuration. /// /// # Returns /// /// Blocking delay provider. /// /// # Panics /// /// Panics if the cortex-m core peripherals have already been taken. pub(crate) fn init_delay(clocks: &hal::clocks::ClocksManager) -> cortex_m::delay::Delay { let core = cortex_m::Peripherals::take().unwrap(); cortex_m::delay::Delay::new(core.SYST, clocks.system_clock.freq().to_Hz()) } /// Probe a 7-bit I2C address by attempting a 1-byte read. /// /// # Arguments /// /// * `i2c` - Mutable reference to the I2C bus. /// * `addr` - 7-bit I2C address to probe. /// /// # Returns /// /// `true` if a device acknowledged, `false` otherwise. pub(crate) fn probe_addr(i2c: &mut impl I2c, addr: u8) -> bool { let mut dummy = [0u8; 1]; i2c.read(addr, &mut dummy).is_ok() } /// Initialise all peripherals and run the I2C bus scanner demo. /// /// # Arguments /// /// * `pac` - PAC Peripherals singleton (consumed). pub(crate) fn run(mut pac: hal::pac::Peripherals) -> ! { let clocks = init_clocks(pac.XOSC, pac.CLOCKS, pac.PLL_SYS, pac.PLL_USB, &mut pac.RESETS, &mut hal::Watchdog::new(pac.WATCHDOG)); let p = init_pins(pac.IO_BANK0, pac.PADS_BANK0, pac.SIO, &mut pac.RESETS); let uart = init_uart(pac.UART0, p.gpio0, p.gpio1, &mut pac.RESETS, &clocks); let mut delay = init_delay(&clocks); let mut i2c = init_i2c(pac.I2C1, p.gpio2, p.gpio3, &mut pac.RESETS, &clocks); uart.write_full_blocking(b"I2C driver initialized: I2C1 @ 100000 Hz SDA=GPIO2 SCL=GPIO3\r\n"); scan_loop(&uart, &mut i2c, &mut delay) } /// Initialise I2C1 on SDA=GPIO2 / SCL=GPIO3. /// /// # Arguments /// /// * `i2c1` - PAC I2C1 peripheral singleton. /// * `sda` - Default GPIO 2 pin (will be reconfigured for I2C). /// * `scl` - Default GPIO 3 pin (will be reconfigured for I2C). /// * `resets` - Mutable reference to the RESETS peripheral. /// * `clocks` - Reference to the initialised clock configuration. /// /// # Returns /// /// Configured I2C1 bus controller. fn init_i2c( i2c1: hal::pac::I2C1, sda: Pin, scl: Pin, resets: &mut hal::pac::RESETS, clocks: &hal::clocks::ClocksManager, ) -> impl I2c { let sda = sda.reconfigure::(); let scl = scl.reconfigure::(); hal::I2C::i2c1(i2c1, sda, scl, I2C_BAUD.Hz(), resets, clocks.system_clock.freq()) } /// Run the I2C address scan loop forever. /// /// # Arguments /// /// * `uart` - Reference to the enabled UART peripheral for serial output. /// * `i2c` - Mutable reference to the I2C bus controller. /// * `delay` - Mutable reference to the blocking delay provider. fn scan_loop(uart: &EnabledUart, i2c: &mut impl I2c, delay: &mut cortex_m::delay::Delay) -> ! { let mut buf = [0u8; 80]; loop { let n = crate::i2c::format_scan_header(&mut buf); uart.write_full_blocking(&buf[..n]); scan_addresses(uart, i2c, &mut buf); delay.delay_ms(SCAN_DELAY_MS); } } /// Scan all 128 addresses and print the formatted result. /// /// # Arguments /// /// * `uart` - Reference to the enabled UART peripheral for serial output. /// * `i2c` - Mutable reference to the I2C bus controller. /// * `buf` - Scratch buffer for formatting output. fn scan_addresses(uart: &EnabledUart, i2c: &mut impl I2c, buf: &mut [u8; 80]) { for addr in 0u8..128 { let found = !crate::i2c::is_reserved(addr) && probe_addr(i2c, addr); let n = crate::i2c::format_scan_entry(buf, addr, found); uart.write_full_blocking(&buf[..n]); } }