diff --git a/CHANGELOG.md b/CHANGELOG.md index d55c086..6191d73 100644 --- a/CHANGELOG.md +++ b/CHANGELOG.md @@ -20,6 +20,7 @@ and this project adheres to [Semantic Versioning](http://semver.org/). - PWM complementary output capability for TIM1 with new example to demonstrate - Implement interface for reading and writing to the internal flash memory and an example for demonstration. - PWM output on complementary channels only for single channel timers (TIM16 + TIM17) +- I2C slave added ### Fixed diff --git a/Cargo.toml b/Cargo.toml index 7d431fb..cee6e08 100644 --- a/Cargo.toml +++ b/Cargo.toml @@ -98,3 +98,7 @@ required-features = ["stm32f042", "rt"] [[example]] name = "usb_serial" required-features = ["rt", "stm32f042", "stm32-usbd"] + +[[example]] +name = "i2c_slave" +required-features = ["stm32f030x4", "rt"] diff --git a/examples/i2c_slave.rs b/examples/i2c_slave.rs new file mode 100644 index 0000000..0a51fd1 --- /dev/null +++ b/examples/i2c_slave.rs @@ -0,0 +1,89 @@ +#![no_main] +#![no_std] + +use crate::hal::{ + gpio::*, + pac::{interrupt, Interrupt, Peripherals}, +}; +use cortex_m_rt::entry; +use panic_halt as _; + +// use rtt_target::{rprintln, rtt_init_print}; +use stm32f0xx_hal::i2c_slave::{self, I2CSlave, State}; +use stm32f0xx_hal::{self as hal, prelude::*}; + +use core::cell::RefCell; +use cortex_m::{interrupt::Mutex, peripheral::Peripherals as c_m_Peripherals}; +type SCL = gpioa::PA9>; +type SDA = gpioa::PA10>; +type I2C = hal::pac::I2C1; +// Make I2C pin globally available +static GI2C: Mutex>>> = Mutex::new(RefCell::new(None)); + +#[interrupt] +fn I2C1() { + static mut I2C: Option> = None; + + let i2c = I2C.get_or_insert_with(|| { + cortex_m::interrupt::free(|cs| { + // Move I2C pin here, leaving a None in its place + GI2C.borrow(cs).replace(None).unwrap() + }) + }); + match i2c.interrupt() { + Ok(State::Buzy(_flag)) => { + // rprintln!("I2C is busy {:?}", _flag); + } + Ok(State::DataReceived(_reg)) => { + let _data = i2c.get_received_data(); + // rprintln!("Reg: {:?} Data: {:?}", _reg, _data); + } + Ok(State::DataRequested(_reg)) => { + // rprintln!("Data requested: {:?}", _reg); + if let Err(_e) = i2c.send_data(&[0x01, 0x02, 0x03]) { + // rprintln!("Error {:?}", _e); + } + } + Err(_e) => { + // rprintln!("Error {:?}", e); + } + } +} + +static I2C_ADDR: u8 = 0x52; +#[entry] +fn main() -> ! { + // rtt_init_print!(); + // rprintln!("Starting I2C Slave example..."); + if let (Some(mut p), Some(cp)) = (Peripherals::take(), c_m_Peripherals::take()) { + cortex_m::interrupt::free(move |cs| { + p.RCC.apb1enr.modify(|_, w| w.i2c1en().set_bit()); + let mut rcc = p + .RCC + .configure() + .sysclk(48.mhz()) + .pclk(24.mhz()) + .freeze(&mut p.FLASH); + let gpioa = p.GPIOA.split(&mut rcc); + + // Configure pins for I2C + let sda = gpioa.pa10.into_alternate_af4(cs); + let scl = gpioa.pa9.into_alternate_af4(cs); + let i2c = i2c_slave::I2CSlave::i2c1_slave(p.I2C1, (scl, sda), I2C_ADDR, &mut rcc); + *GI2C.borrow(cs).borrow_mut() = Some(i2c); + + // Enable I2C IRQ, set prio 1 and clear any pending IRQs + let mut nvic = cp.NVIC; + unsafe { + nvic.set_priority(Interrupt::I2C1, 1); + cortex_m::peripheral::NVIC::unmask(Interrupt::I2C1); + } + + cortex_m::peripheral::NVIC::unpend(Interrupt::I2C1); + }); + } + + loop { + continue; + } +} diff --git a/src/i2c_slave.rs b/src/i2c_slave.rs new file mode 100644 index 0000000..a2f3630 --- /dev/null +++ b/src/i2c_slave.rs @@ -0,0 +1,493 @@ +pub use crate::i2c; +use crate::i2c::{SclPin, SdaPin}; +use crate::rcc::Rcc; +use core::ops::Deref; +const BUFFER_SIZE: usize = 32; + +/// I2C slave state +/// DataRequested: Data requested by the master, 8bit register address attached +/// +/// DataReceived: Data received from the master, 8bit register address attached +/// +/// Buzy: I2C interrupt that is currently being handled +/// +#[derive(Copy, Clone, Debug)] +pub enum State { + DataRequested(u8), + DataReceived(u8), + Buzy(I2CInterrupt), +} + +#[derive(PartialEq, Copy, Clone, Debug)] +enum TransferState { + Idle, + Addr(Direction), + RegSet, + Receiving, + Transmitting, +} +/// I2C errors +#[derive(Debug, PartialEq)] +pub enum Error { + /// Overrun/Underrun + OVERRUN, + /// Not Acknowledge received + NACK, + /// Bus error + BUS, + /// Arbitration lost + ARBITRATION, + /// Timeout / t LOW error + TIMEOUT, + /// Packet error checking + PEC, + /// Unknown error + UNKNOWN, +} +impl Into for I2CInterrupt { + fn into(self) -> Error { + match self { + I2CInterrupt::Overrun => Error::OVERRUN, + I2CInterrupt::NotAcknowledgeReceived => Error::NACK, + I2CInterrupt::BusError => Error::BUS, + I2CInterrupt::ArbitrationLost => Error::ARBITRATION, + I2CInterrupt::Timeout => Error::TIMEOUT, + _ => Error::UNKNOWN, + } + } +} +/// I2C slave +/// # Example +/// ```rust +/// use cortex_m::{interrupt::Mutex, peripheral::Peripherals as c_m_Peripherals}; +/// if let (Some(mut p), Some(cp)) = (Peripherals::take(), c_m_Peripherals::take()) { +/// cortex_m::interrupt::free(move |cs| { +/// let gpioa = p.GPIOA.split(&mut rcc); +/// let sda = gpioa.pa10.into_alternate_af4(cs); +/// let scl = gpioa.pa9.into_alternate_af4(cs); +/// let i2c = i2c_slave::I2CSlave::i2c1_slave(p.I2C1, (scl, sda), I2C_ADDR, &mut rcc); +/// }); +/// } +/// +/// ``` +/// +pub struct I2CSlave { + i2c: I2C, + transfer_buffer: [u8; BUFFER_SIZE], + transfer_len: usize, + buffer_index: usize, + register: u8, + transfer_state: TransferState, + pins: (SCL, SDA), +} + +/// direction as specified in the datasheet +#[derive(PartialEq, Copy, Clone, Debug)] +pub enum Direction { + /// slave is receiver + Write, + /// slave is transmitter + Read, +} + +impl From for bool { + fn from(dir: Direction) -> Self { + Direction::Read == dir + } +} + +impl From for Direction { + fn from(raw: bool) -> Self { + if raw { + Direction::Read + } else { + Direction::Write + } + } +} + +macro_rules! i2c_slave { + ($($I2C:ident: ($i2c_slave:ident, $i2cXen:ident, $i2cXrst:ident, $apbenr:ident, $apbrstr:ident),)+) => { + $( + use crate::pac::$I2C; + impl I2CSlave<$I2C, SCLPIN, SDAPIN> { + pub fn $i2c_slave(i2c: $I2C, pins: (SCLPIN, SDAPIN), address: u8, rcc: &mut Rcc) -> Self + where + SCLPIN: SclPin<$I2C>, + SDAPIN: SdaPin<$I2C>, + { + // Enable clock for I2C + rcc.regs.$apbenr.modify(|_, w| w.$i2cXen().set_bit()); + + // Reset I2C + rcc.regs.$apbrstr.modify(|_, w| w.$i2cXrst().set_bit()); + rcc.regs.$apbrstr.modify(|_, w| w.$i2cXrst().clear_bit()); + I2CSlave { + i2c, + transfer_buffer: [0u8; BUFFER_SIZE], + transfer_len: 0, + buffer_index: 0, + register: 0, + transfer_state: TransferState::Idle, + pins + }.i2c_init(address) + } + } + )+ + } +} + +/// Enum representing the diffrent interuptt triggers from the STM32 reference manual: +/// The I2C slave interrupt request is generated when the following events occur: + +#[derive(PartialEq, Copy, Clone, Debug)] +pub enum I2CInterrupt { + /// • Receive buffer not empty (RXNE = 1) + ReceiveBufferNotEmpty, + /// • Transmit buffer interrupt status (TXIS = 1) + TXBufIntStatus, + /// • Stop detection (STOPF = 1) + StopDetection, + /// • Transfer complete reload (TCR = 1) + TransferCompleteReload, + /// • Transfer complete (TC = 1) + TransferComplete, + /// • Address matched with own address (ADDR = 1) + AddressMatch(Direction), + /// • Bus error (BERR = 1) + BusError, + /// • Arbitration lost (ARLO = 1) + ArbitrationLost, + /// • Overrun/Underrun (OVR = 1) + Overrun, + /// • Timeout / t LOW error (TIMEOUT = 1) + Timeout, + /// • SMBus alert (ALERT = 1) + SMBusAlert, + /// • Not Acknowledge received (NACKF = 1) + NotAcknowledgeReceived, +} +i2c_slave! { + I2C1: (i2c1_slave, i2c1en, i2c1rst, apb1enr, apb1rstr), +} + +#[cfg(any( + feature = "stm32f030x8", + feature = "stm32f030xc", + feature = "stm32f051", + feature = "stm32f058", + feature = "stm32f070xb", + feature = "stm32f071", + feature = "stm32f072", + feature = "stm32f078", + feature = "stm32f091", + feature = "stm32f098", +))] +i2c_slave! { + I2C2: (i2c2_slave, i2c2en, i2c2rst, apb1enr, apb1rstr), +} +// It's s needed for the impls, but rustc doesn't recognize that +#[allow(dead_code)] +type I2cRegisterBlock = crate::pac::i2c1::RegisterBlock; + +impl I2CSlave +where + I2C: Deref, +{ + /// Function to be called from the interrupt handler + /// Returns DataRequested, DataReceived, Buzy or an Error + /// + /// # Example + /// ```rust + /// #[interrupt] + /// fn I2C1() { + /// static mut I2C: Option> = None; + /// let i2c = I2C.get_or_insert_with(|| { + /// cortex_m::interrupt::free(|cs| { + /// // Move I2C pin here, leaving a None in its place + /// GI2C.borrow(cs).replace(None).unwrap() + /// }) + /// }); + /// match i2c.interrupt() { + /// Ok(State::Buzy(flag)) => { + /// rprintln!("I2C is busy {:?}", flag); + /// } + /// Ok(State::DataReceived(reg)) => { + /// let data = i2c.get_received_data(); + /// rprintln!("Reg: {:?} Data: {:?}", reg, data); + /// } + /// Ok(State::DataRequested(reg)) => { + /// rprintln!("Data requested: {:?}", reg); + /// if let Err(e) = i2c.send_data(&[0x01, 0x02, 0x03]) { + /// rprintln!("Error {:?}", e); + /// } + /// } + /// Err(e) => { + /// rprintln!("Error {:?}", e); + /// } + /// } + /// } + /// ``` + /// + pub fn interrupt(&mut self) -> Result { + let mut ret = Err(Error::UNKNOWN); + if let Some(interrupt_flag) = self.get_interrupt() { + use I2CInterrupt as I; + use TransferState as TS; + ret = match (interrupt_flag, self.transfer_state) { + (I::AddressMatch(dir), TS::Idle) => { + self.transfer_state = TS::Addr(dir); + self.clear_interrupt(interrupt_flag); + if dir == Direction::Read { + // enable TXIE to avoid deadlock when master is reading without setting register first + self.txie(true); + self.transfer_state = TS::Transmitting; + self.write(0xff); + } + Ok(State::Buzy(interrupt_flag)) + } + (I::NotAcknowledgeReceived, TS::Addr(Direction::Read) | TS::Transmitting) => { + self.transfer_state = TS::Addr(Direction::Read); + self.clear_interrupt(interrupt_flag); + self.reset_i2c(); + Ok(State::Buzy(interrupt_flag)) + } + (I::AddressMatch(Direction::Read), TS::RegSet) => { + self.transfer_state = TS::Transmitting; + self.txie(true); + self.flush_txdr(); + Ok(State::DataRequested(self.register)) + } + (I::ReceiveBufferNotEmpty, TS::Addr(Direction::Write)) => { + self.transfer_state = TS::RegSet; + self.register = self.read(); + Ok(State::Buzy(interrupt_flag)) + } + (I::ReceiveBufferNotEmpty, TS::RegSet | TS::Receiving) => { + if self.buffer_index >= BUFFER_SIZE - 1 { + self.transfer_state = TS::Idle; + let _ = self.read(); + self.clear_interrupt(interrupt_flag); + return Err(Error::OVERRUN); + } + self.transfer_state = TS::Receiving; + self.transfer_buffer[self.buffer_index] = self.read(); + self.buffer_index += 1; + if self.stopcf() { + self.transfer_state = TS::Idle; + self.clear_interrupt(I::StopDetection); + Ok(State::DataReceived(self.register)) + } else { + Ok(State::Buzy(interrupt_flag)) + } + } + (I::StopDetection, TS::Receiving) => { + self.transfer_state = TS::Idle; + self.clear_interrupt(I::StopDetection); + Ok(State::DataReceived(self.register)) + } + (I::StopDetection, TS::Transmitting | TS::Idle | TS::Addr(Direction::Read)) => { + self.transfer_state = TS::Idle; + self.txie(false); + self.clear_interrupt(I::StopDetection); + Ok(State::Buzy(interrupt_flag)) + } + (I::TXBufIntStatus, TS::Transmitting) => { + if self.buffer_index < self.transfer_len { + self.write(self.transfer_buffer[self.buffer_index]); + self.buffer_index += 1; + Ok(State::Buzy(interrupt_flag)) + } else { + self.write(0xff); // need to write to end the clock stretching + Ok(State::Buzy(interrupt_flag)) + } + } + _ => { + self.transfer_state = TS::Idle; + self.clear_interrupt(interrupt_flag); + self.write(0xff); + self.reset_i2c(); + Err(interrupt_flag.into()) + } + } + } + ret + } + + /// Send data to the I2C buffer and start the transmission + pub fn send_data(&mut self, buffer: &[u8]) -> Result<(), Error> { + if buffer.len() > BUFFER_SIZE { + return Err(Error::OVERRUN); + } + for (index, item) in buffer.iter().enumerate() { + self.transfer_buffer[index] = *item; + } + self.transfer_len = buffer.len(); + self.buffer_index = 0; + self.write(self.transfer_buffer[self.buffer_index]); + self.buffer_index += 1; + self.clear_interrupt(I2CInterrupt::AddressMatch(Direction::Read)); + Ok(()) + } + + /// Get the received data from the I2C peripheral + pub fn get_received_data(&mut self) -> &[u8] { + let data = &self.transfer_buffer[..self.buffer_index]; + self.buffer_index = 0; + self.transfer_len = 0; + data + } + + /// Release the I2C peripheral and pins + pub fn release(self) -> (I2C, (SCL, SDA)) { + (self.i2c, self.pins) + } + + fn i2c_init(self, address: u8) -> Self { + self.i2c.cr1.write(|w| { + w.nostretch() + .enabled() // enable clock stretching + .anfoff() + .enabled() // enable analog filter + .dnf() + .no_filter() // disable digital filter + .errie() + .enabled() // error interrupt enabled + .stopie() + .enabled() // stop interrupt enabled + .nackie() + .enabled() // nack interrupt enabled + .addrie() + .enabled() // address match interrupt enabled + .rxie() // rx interrupt enabled + .enabled() + .wupen() + .enabled() // wake up when address match + }); + self.txie(false); + self.i2c.oar1.write(|w| { + w.oa1en() + .enabled() + .oa1() + .bits((address as u16) << 1) + .oa1mode() + .bit7() + }); + + self.i2c.cr1.modify( + |_, w| w.pe().enabled(), // enable peripheral + ); + self + } + + fn clear_interrupt(&self, interrupt: I2CInterrupt) { + use I2CInterrupt as I; + match interrupt { + I::ReceiveBufferNotEmpty => { + // read from Recieve buffer RXDR + } + I::TXBufIntStatus => { + // write to Transmit buffer TXDR + } + I::StopDetection => { + self.i2c.icr.write(|w| w.stopcf().clear()); + } + I::TransferComplete | I::TransferCompleteReload => { + // Only in master mode, do nothing + } + I::AddressMatch(_dir) => { + self.i2c.icr.write(|w| w.addrcf().clear()); + } + I::BusError => { + self.i2c.icr.write(|w| w.berrcf().clear()); + } + I::ArbitrationLost => { + self.i2c.icr.write(|w| w.arlocf().clear()); + } + I::Overrun => { + self.i2c.icr.write(|w| w.ovrcf().clear()); + } + I::Timeout => { + self.i2c.icr.write(|w| w.timoutcf().clear()); + } + I::SMBusAlert => { + self.i2c.icr.write(|w| w.alertcf().clear()); + } + I::NotAcknowledgeReceived => { + self.i2c.icr.write(|w| w.nackcf().clear()); + } + } + } + fn stopcf(&self) -> bool { + self.i2c.isr.read().stopf().bit_is_set() + } + + // find what triggered the interrupt + fn get_interrupt(&self) -> Option { + let isr = self.i2c.isr.read(); + use I2CInterrupt as I; + if isr.rxne().bit_is_set() { + return Some(I::ReceiveBufferNotEmpty); + } + + if isr.tcr().bit_is_set() { + return Some(I::TransferCompleteReload); + } + if isr.tc().bit_is_set() { + return Some(I::TransferComplete); + } + if isr.addr().bit_is_set() { + return Some(I::AddressMatch(Direction::from(isr.dir().bit()))); + } + if isr.berr().bit_is_set() { + return Some(I::BusError); + } + if isr.arlo().bit_is_set() { + return Some(I::ArbitrationLost); + } + if isr.ovr().bit_is_set() { + return Some(I::Overrun); + } + if isr.timeout().bit_is_set() { + return Some(I::Timeout); + } + if isr.alert().bit_is_set() { + return Some(I::SMBusAlert); + } + if isr.nackf().bit_is_set() { + return Some(I::NotAcknowledgeReceived); + } + if isr.stopf().bit_is_set() { + return Some(I::StopDetection); + } + if isr.txis().bit_is_set() { + return Some(I::TXBufIntStatus); + } + None + } + + fn reset_i2c(&mut self) { + self.transfer_len = 0; + self.buffer_index = 0; + } + + fn flush_txdr(&mut self) { + self.i2c.isr.modify(|_, w| w.txe().set_bit()); + } + /// Read from the RXDR register + fn read(&self) -> u8 { + self.i2c.rxdr.read().bits() as u8 + } + + fn write(&self, value: u8) { + self.i2c.txdr.write(|w| w.txdata().bits(value)); + } + + /// Enable or disable the TX interrupt + + fn txie(&self, enable: bool) { + self.i2c + .cr1 + .modify(|_, w| w.txie().bit(enable).tcie().bit(enable)); + } +} diff --git a/src/lib.rs b/src/lib.rs index 623847c..fcc6219 100644 --- a/src/lib.rs +++ b/src/lib.rs @@ -47,6 +47,8 @@ pub mod gpio; #[cfg(feature = "device-selected")] pub mod i2c; #[cfg(feature = "device-selected")] +pub mod i2c_slave; +#[cfg(feature = "device-selected")] pub mod prelude; #[cfg(feature = "device-selected")] pub mod pwm;