#![no_std] #![no_main] #![feature(type_alias_impl_trait)] use defmt::{assert_eq, info, panic, unwrap}; use embassy_executor::Executor; use embassy_executor::_export::StaticCell; use embassy_rp::bind_interrupts; use embassy_rp::i2c::{self, Async, InterruptHandler}; use embassy_rp::multicore::{spawn_core1, Stack}; use embassy_rp::peripherals::{I2C0, I2C1}; use embedded_hal_1::i2c::Operation; use embedded_hal_async::i2c::I2c; use {defmt_rtt as _, panic_probe as _, panic_probe as _, panic_probe as _}; static mut CORE1_STACK: Stack<1024> = Stack::new(); static EXECUTOR0: StaticCell = StaticCell::new(); static EXECUTOR1: StaticCell = StaticCell::new(); use crate::i2c::AbortReason; bind_interrupts!(struct Irqs { I2C0_IRQ => InterruptHandler; I2C1_IRQ => InterruptHandler; }); const DEV_ADDR: u8 = 0x42; #[embassy_executor::task] async fn device_task(mut dev: i2c::I2cDevice<'static, I2C1>) -> ! { info!("Device start"); let mut count = 0xD0; loop { let mut buf = [0u8; 128]; match dev.listen(&mut buf).await { Ok(i2c::Command::GeneralCall(len)) => { assert_eq!(buf[..len], [0xCA, 0x11], "recieving the general call failed"); info!("General Call - OK"); } Ok(i2c::Command::Read) => { loop { //info!("Responding to read, count {}", count); let a = dev.respond_to_read(&[count]).await; //info!("x {}", a); match a { Ok(x) => match x { i2c::ReadStatus::Done => break, i2c::ReadStatus::NeedMoreBytes => count += 1, i2c::ReadStatus::LeftoverBytes(x) => { info!("tried to write {} extra bytes", x); break; } }, Err(e) => match e { embassy_rp::i2c::Error::Abort(AbortReason::Other(n)) => panic!("Other {:b}", n), _ => panic!("{}", e), }, } } count += 1; } Ok(i2c::Command::Write(len)) => match len { 1 => { assert_eq!(buf[..len], [0xAA], "recieving a single byte failed"); info!("Single Byte Write - OK") } 4 => { assert_eq!(buf[..len], [0xAA, 0xBB, 0xCC, 0xDD], "recieving 4 bytes failed"); info!("4 Byte Write - OK") } 32 => { assert_eq!( buf[..len], [ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31 ], "recieving 32 bytes failed" ); info!("32 Byte Write - OK") } _ => panic!("Invalid write length {}", len), }, Ok(i2c::Command::WriteRead(len)) => { info!("device recieved write read: {:x}", buf[..len]); match buf[0] { 0xC2 => { let resp_buff = [0xD1, 0xD2, 0xD3, 0xD4]; dev.respond_to_read(&resp_buff).await.unwrap(); } 0xC8 => { let mut resp_buff = [0u8; 32]; for i in 0..32 { resp_buff[i] = i as u8; } dev.respond_to_read(&resp_buff).await.unwrap(); } x => panic!("Invalid Write Read {:x}", x), } } Err(e) => match e { embassy_rp::i2c::Error::Abort(AbortReason::Other(n)) => panic!("Other {:b}", n), _ => panic!("{}", e), }, } } } #[embassy_executor::task] async fn controller_task(mut con: i2c::I2c<'static, I2C0, Async>) { info!("Device start"); { let buf = [0xCA, 0x11]; con.write(0u16, &buf).await.unwrap(); info!("Controler general call write"); embassy_futures::yield_now().await; } { let mut buf = [0u8]; con.read(DEV_ADDR, &mut buf).await.unwrap(); assert_eq!(buf, [0xD0], "single byte read failed"); info!("single byte read - OK"); embassy_futures::yield_now().await; } { let mut buf = [0u8; 4]; con.read(DEV_ADDR, &mut buf).await.unwrap(); assert_eq!(buf, [0xD1, 0xD2, 0xD3, 0xD4], "single byte read failed"); info!("4 byte read - OK"); embassy_futures::yield_now().await; } { let buf = [0xAA]; con.write(DEV_ADDR, &buf).await.unwrap(); info!("Controler single byte write"); embassy_futures::yield_now().await; } { let buf = [0xAA, 0xBB, 0xCC, 0xDD]; con.write(DEV_ADDR, &buf).await.unwrap(); info!("Controler 4 byte write"); embassy_futures::yield_now().await; } { let mut buf = [0u8; 32]; for i in 0..32 { buf[i] = i as u8; } con.write(DEV_ADDR, &buf).await.unwrap(); info!("Controler 32 byte write"); embassy_futures::yield_now().await; } { let mut buf = [0u8; 4]; let mut ops = [Operation::Write(&[0xC2]), Operation::Read(&mut buf)]; con.transaction(DEV_ADDR, &mut ops).await.unwrap(); assert_eq!(buf, [0xD1, 0xD2, 0xD3, 0xD4], "write_read failed"); info!("write_read - OK"); embassy_futures::yield_now().await; } { let mut buf = [0u8; 32]; let mut ops = [Operation::Write(&[0xC8]), Operation::Read(&mut buf)]; con.transaction(DEV_ADDR, &mut ops).await.unwrap(); assert_eq!( buf, [ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31 ], "write_read of 32 bytes failed" ); info!("large write_read - OK") } info!("Test OK"); cortex_m::asm::bkpt(); } #[cortex_m_rt::entry] fn main() -> ! { let p = embassy_rp::init(Default::default()); info!("Hello World!"); let d_sda = p.PIN_19; let d_scl = p.PIN_18; let mut config = i2c::DeviceConfig::default(); config.addr = DEV_ADDR as u16; let device = i2c::I2cDevice::new(p.I2C1, d_sda, d_scl, Irqs, config); spawn_core1(p.CORE1, unsafe { &mut CORE1_STACK }, move || { let executor1 = EXECUTOR1.init(Executor::new()); executor1.run(|spawner| unwrap!(spawner.spawn(device_task(device)))); }); let executor0 = EXECUTOR0.init(Executor::new()); let c_sda = p.PIN_21; let c_scl = p.PIN_20; let mut config = i2c::Config::default(); config.frequency = 5_000; let controller = i2c::I2c::new_async(p.I2C0, c_sda, c_scl, Irqs, config); executor0.run(|spawner| unwrap!(spawner.spawn(controller_task(controller)))); }