#![no_std] #![no_main] #![feature(type_alias_impl_trait)] #[path = "../common.rs"] mod common; use defmt::*; use embassy_executor::Spawner; use embassy_rp::adc::{Adc, Channel, Config, InterruptHandler, Sample}; use embassy_rp::bind_interrupts; use embassy_rp::gpio::{Level, Output, Pull}; use {defmt_rtt as _, panic_probe as _}; bind_interrupts!(struct Irqs { ADC_IRQ_FIFO => InterruptHandler; }); #[embassy_executor::main] async fn main(_spawner: Spawner) { let mut p = embassy_rp::init(Default::default()); let _power_reg_pwm_mode = Output::new(p.PIN_23, Level::High); let _wifi_off = Output::new(p.PIN_25, Level::High); let mut adc = Adc::new(p.ADC, Irqs, Config::default()); { { let mut p = Channel::new_pin(&mut p.PIN_26, Pull::Down); defmt::assert!(adc.blocking_read(&mut p).unwrap() < 0b01_0000_0000); defmt::assert!(adc.read(&mut p).await.unwrap() < 0b01_0000_0000); } { let mut p = Channel::new_pin(&mut p.PIN_26, Pull::Up); defmt::assert!(adc.blocking_read(&mut p).unwrap() > 0b11_0000_0000); defmt::assert!(adc.read(&mut p).await.unwrap() > 0b11_0000_0000); } } // not bothering with async reads from now on { { let mut p = Channel::new_pin(&mut p.PIN_27, Pull::Down); defmt::assert!(adc.blocking_read(&mut p).unwrap() < 0b01_0000_0000); } { let mut p = Channel::new_pin(&mut p.PIN_27, Pull::Up); defmt::assert!(adc.blocking_read(&mut p).unwrap() > 0b11_0000_0000); } } { { let mut p = Channel::new_pin(&mut p.PIN_28, Pull::Down); defmt::assert!(adc.blocking_read(&mut p).unwrap() < 0b01_0000_0000); } { let mut p = Channel::new_pin(&mut p.PIN_28, Pull::Up); defmt::assert!(adc.blocking_read(&mut p).unwrap() > 0b11_0000_0000); } } { // gp29 is connected to vsys through a 200k/100k divider, // adding pulls should change the value let low = { let mut p = Channel::new_pin(&mut p.PIN_29, Pull::Down); adc.blocking_read(&mut p).unwrap() }; let none = { let mut p = Channel::new_pin(&mut p.PIN_29, Pull::None); adc.blocking_read(&mut p).unwrap() }; let up = { let mut p = Channel::new_pin(&mut p.PIN_29, Pull::Up); adc.blocking_read(&mut p).unwrap() }; defmt::assert!(low < none); defmt::assert!(none < up); } { let temp = convert_to_celsius( adc.read(&mut Channel::new_temp_sensor(&mut p.ADC_TEMP_SENSOR)) .await .unwrap(), ); defmt::assert!(temp > 0.0); defmt::assert!(temp < 60.0); } // run a bunch of conversions. we'll only check gp29 and the temp // sensor here for brevity, if those two work the rest will too. { // gp29 is connected to vsys through a 200k/100k divider, // adding pulls should change the value let mut low = [0u16; 16]; let mut none = [0u8; 16]; let mut up = [Sample::default(); 16]; adc.read_many( &mut Channel::new_pin(&mut p.PIN_29, Pull::Down), &mut low, &mut p.DMA_CH0, ) .await .unwrap(); adc.read_many( &mut Channel::new_pin(&mut p.PIN_29, Pull::None), &mut none, &mut p.DMA_CH0, ) .await .unwrap(); adc.read_many_raw(&mut Channel::new_pin(&mut p.PIN_29, Pull::Up), &mut up, &mut p.DMA_CH0) .await; defmt::assert!(low.iter().zip(none.iter()).all(|(l, n)| *l >> 4 < *n as u16)); defmt::assert!(up.iter().all(|s| s.good())); defmt::assert!(none.iter().zip(up.iter()).all(|(n, u)| (*n as u16) < u.value())); } { let mut temp = [0u16; 16]; adc.read_many( &mut Channel::new_temp_sensor(&mut p.ADC_TEMP_SENSOR), &mut temp, &mut p.DMA_CH0, ) .await .unwrap(); let temp = temp.map(convert_to_celsius); defmt::assert!(temp.iter().all(|t| *t > 0.0)); defmt::assert!(temp.iter().all(|t| *t < 60.0)); } info!("Test OK"); cortex_m::asm::bkpt(); } fn convert_to_celsius(raw_temp: u16) -> f32 { // According to chapter 4.9.5. Temperature Sensor in RP2040 datasheet 27.0 - (raw_temp as f32 * 3.3 / 4096.0 - 0.706) / 0.001721 as f32 }