Merge pull request #2351 from jewel-rs/feat/radio

[embassry_nrf]: add BLE Radio driver
This commit is contained in:
Ulf Lilleengen 2024-02-28 14:40:18 +00:00 committed by GitHub
commit b806800f23
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@ -173,6 +173,9 @@ embassy_hal_internal::peripherals! {
// I2S
I2S,
// Radio
RADIO,
}
impl_usb!(USBD, USBD, USBD);
@ -311,6 +314,8 @@ impl_saadc_input!(P0_31, ANALOG_INPUT7);
impl_i2s!(I2S, I2S, I2S);
impl_radio!(RADIO, RADIO, RADIO);
embassy_hal_internal::interrupt_mod!(
POWER_CLOCK,
RADIO,

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@ -45,6 +45,11 @@ pub mod buffered_uarte;
pub mod gpio;
#[cfg(feature = "gpiote")]
pub mod gpiote;
// TODO: tested on other chips
#[cfg(any(feature = "nrf52840"))]
pub mod radio;
#[cfg(any(feature = "nrf52832", feature = "nrf52833", feature = "nrf52840"))]
pub mod i2s;
pub mod nvmc;

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@ -0,0 +1,438 @@
//! Radio driver implementation focused on Bluetooth Low-Energy transmission.
use core::future::poll_fn;
use core::sync::atomic::{compiler_fence, Ordering};
use core::task::Poll;
use embassy_hal_internal::drop::OnDrop;
use embassy_hal_internal::{into_ref, PeripheralRef};
pub use pac::radio::mode::MODE_A as Mode;
use pac::radio::pcnf0::PLEN_A as PreambleLength;
use pac::radio::state::STATE_A as RadioState;
pub use pac::radio::txpower::TXPOWER_A as TxPower;
use crate::interrupt::typelevel::Interrupt;
use crate::radio::*;
use crate::util::slice_in_ram_or;
/// RADIO error.
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[non_exhaustive]
pub enum Error {
/// Buffer was too long.
BufferTooLong,
/// Buffer was to short.
BufferTooShort,
/// The buffer is not in data RAM. It is most likely in flash, and nRF's DMA cannot access flash.
BufferNotInRAM,
}
/// Radio driver.
pub struct Radio<'d, T: Instance> {
_p: PeripheralRef<'d, T>,
}
impl<'d, T: Instance> Radio<'d, T> {
/// Create a new radio driver.
pub fn new(
radio: impl Peripheral<P = T> + 'd,
_irq: impl interrupt::typelevel::Binding<T::Interrupt, InterruptHandler<T>> + 'd,
) -> Self {
into_ref!(radio);
let r = T::regs();
r.pcnf1.write(|w| unsafe {
// It is 0 bytes long in a standard BLE packet
w.statlen()
.bits(0)
// MaxLen configures the maximum packet payload plus add-on size in
// number of bytes that can be transmitted or received by the RADIO. This feature can be used to ensure
// that the RADIO does not overwrite, or read beyond, the RAM assigned to the packet payload. This means
// that if the packet payload length defined by PCNF1.STATLEN and the LENGTH field in the packet specifies a
// packet larger than MAXLEN, the payload will be truncated at MAXLEN
//
// To simplify the implementation, It is setted as the maximum value
// and the length of the packet is controlled only by the LENGTH field in the packet
.maxlen()
.bits(255)
// Configure the length of the address field in the packet
// The prefix after the address fields is always appended, so is always 1 byte less than the size of the address
// The base address is truncated from the least significant byte if the BALEN is less than 4
//
// BLE address is always 4 bytes long
.balen()
.bits(3) // 3 bytes base address (+ 1 prefix);
// Configure the endianess
// For BLE is always little endian (LSB first)
.endian()
.little()
// Data whitening is used to avoid long sequences of zeros or
// ones, e.g., 0b0000000 or 0b1111111, in the data bit stream.
// The whitener and de-whitener are defined the same way,
// using a 7-bit linear feedback shift register with the
// polynomial x7 + x4 + 1.
//
// In BLE Whitening shall be applied on the PDU and CRC of all
// Link Layer packets and is performed after the CRC generation
// in the transmitter. No other parts of the packets are whitened.
// De-whitening is performed before the CRC checking in the receiver
// Before whitening or de-whitening, the shift register should be
// initialized based on the channel index.
.whiteen()
.set_bit()
});
// Configure CRC
r.crccnf.write(|w| {
// In BLE the CRC shall be calculated on the PDU of all Link Layer
// packets (even if the packet is encrypted).
// It skips the address field
w.skipaddr()
.skip()
// In BLE 24-bit CRC = 3 bytes
.len()
.three()
});
// Ch map between 2400 MHZ .. 2500 MHz
// All modes use this range
r.frequency.write(|w| w.map().default());
// Configure shortcuts to simplify and speed up sending and receiving packets.
r.shorts.write(|w| {
// start transmission/recv immediately after ramp-up
// disable radio when transmission/recv is done
w.ready_start().enabled().end_disable().enabled()
});
// Enable NVIC interrupt
T::Interrupt::unpend();
unsafe { T::Interrupt::enable() };
Self { _p: radio }
}
fn state(&self) -> RadioState {
match T::regs().state.read().state().variant() {
Some(s) => s,
None => unreachable!(),
}
}
#[allow(dead_code)]
fn trace_state(&self) {
match self.state() {
RadioState::DISABLED => trace!("radio:state:DISABLED"),
RadioState::RX_RU => trace!("radio:state:RX_RU"),
RadioState::RX_IDLE => trace!("radio:state:RX_IDLE"),
RadioState::RX => trace!("radio:state:RX"),
RadioState::RX_DISABLE => trace!("radio:state:RX_DISABLE"),
RadioState::TX_RU => trace!("radio:state:TX_RU"),
RadioState::TX_IDLE => trace!("radio:state:TX_IDLE"),
RadioState::TX => trace!("radio:state:TX"),
RadioState::TX_DISABLE => trace!("radio:state:TX_DISABLE"),
}
}
/// Set the radio mode
///
/// The radio must be disabled before calling this function
pub fn set_mode(&mut self, mode: Mode) {
assert!(self.state() == RadioState::DISABLED);
let r = T::regs();
r.mode.write(|w| w.mode().variant(mode));
r.pcnf0.write(|w| {
w.plen().variant(match mode {
Mode::BLE_1MBIT => PreambleLength::_8BIT,
Mode::BLE_2MBIT => PreambleLength::_16BIT,
Mode::BLE_LR125KBIT | Mode::BLE_LR500KBIT => PreambleLength::LONG_RANGE,
_ => unimplemented!(),
})
});
}
/// Set the header size changing the S1's len field
///
/// The radio must be disabled before calling this function
pub fn set_header_expansion(&mut self, use_s1_field: bool) {
assert!(self.state() == RadioState::DISABLED);
let r = T::regs();
// s1 len in bits
let s1len: u8 = match use_s1_field {
false => 0,
true => 8,
};
r.pcnf0.write(|w| unsafe {
w
// Configure S0 to 1 byte length, this will represent the Data/Adv header flags
.s0len()
.set_bit()
// Configure the length (in bits) field to 1 byte length, this will represent the length of the payload
// and also be used to know how many bytes to read/write from/to the buffer
.lflen()
.bits(8)
// Configure the lengh (in bits) of bits in the S1 field. It could be used to represent the CTEInfo for data packages in BLE.
.s1len()
.bits(s1len)
});
}
/// Set initial data whitening value
/// Data whitening is used to avoid long sequences of zeros or ones, e.g., 0b0000000 or 0b1111111, in the data bit stream
/// On BLE the initial value is the channel index | 0x40
///
/// The radio must be disabled before calling this function
pub fn set_whitening_init(&mut self, whitening_init: u8) {
assert!(self.state() == RadioState::DISABLED);
let r = T::regs();
r.datawhiteiv.write(|w| unsafe { w.datawhiteiv().bits(whitening_init) });
}
/// Set the central frequency to be used
/// It should be in the range 2400..2500
///
/// [The radio must be disabled before calling this function](https://devzone.nordicsemi.com/f/nordic-q-a/15829/radio-frequency-change)
pub fn set_frequency(&mut self, frequency: u32) {
assert!(self.state() == RadioState::DISABLED);
assert!((2400..=2500).contains(&frequency));
let r = T::regs();
r.frequency
.write(|w| unsafe { w.frequency().bits((frequency - 2400) as u8) });
}
/// Set the acess address
/// This address is always constants for advertising
/// And a random value generate on each connection
/// It is used to filter the packages
///
/// The radio must be disabled before calling this function
pub fn set_access_address(&mut self, access_address: u32) {
assert!(self.state() == RadioState::DISABLED);
let r = T::regs();
// Configure logical address
// The byte ordering on air is always least significant byte first for the address
// So for the address 0xAA_BB_CC_DD, the address on air will be DD CC BB AA
// The package order is BASE, PREFIX so BASE=0xBB_CC_DD and PREFIX=0xAA
r.prefix0
.write(|w| unsafe { w.ap0().bits((access_address >> 24) as u8) });
// The base address is truncated from the least significant byte (because the BALEN is less than 4)
// So it shifts the address to the right
r.base0.write(|w| unsafe { w.bits(access_address << 8) });
// Don't match tx address
r.txaddress.write(|w| unsafe { w.txaddress().bits(0) });
// Match on logical address
// This config only filter the packets by the address,
// so only packages send to the previous address
// will finish the reception (TODO: check the explanation)
r.rxaddresses.write(|w| {
w.addr0()
.enabled()
.addr1()
.enabled()
.addr2()
.enabled()
.addr3()
.enabled()
.addr4()
.enabled()
});
}
/// Set the CRC polynomial
/// It only uses the 24 least significant bits
///
/// The radio must be disabled before calling this function
pub fn set_crc_poly(&mut self, crc_poly: u32) {
assert!(self.state() == RadioState::DISABLED);
let r = T::regs();
r.crcpoly.write(|w| unsafe {
// Configure the CRC polynomial
// Each term in the CRC polynomial is mapped to a bit in this
// register which index corresponds to the term's exponent.
// The least significant term/bit is hard-wired internally to
// 1, and bit number 0 of the register content is ignored by
// the hardware. The following example is for an 8 bit CRC
// polynomial: x8 + x7 + x3 + x2 + 1 = 1 1000 1101 .
w.crcpoly().bits(crc_poly & 0xFFFFFF)
});
}
/// Set the CRC init value
/// It only uses the 24 least significant bits
/// The CRC initial value varies depending of the PDU type
///
/// The radio must be disabled before calling this function
pub fn set_crc_init(&mut self, crc_init: u32) {
assert!(self.state() == RadioState::DISABLED);
let r = T::regs();
r.crcinit.write(|w| unsafe { w.crcinit().bits(crc_init & 0xFFFFFF) });
}
/// Set the radio tx power
///
/// The radio must be disabled before calling this function
pub fn set_tx_power(&mut self, tx_power: TxPower) {
assert!(self.state() == RadioState::DISABLED);
let r = T::regs();
r.txpower.write(|w| w.txpower().variant(tx_power));
}
/// Set buffer to read/write
///
/// This method is unsound. You should guarantee that the buffer will live
/// for the life time of the transmission or if the buffer will be modified.
/// Also if the buffer is smaller than the packet length, the radio will
/// read/write memory out of the buffer bounds.
fn set_buffer(&mut self, buffer: &[u8]) -> Result<(), Error> {
slice_in_ram_or(buffer, Error::BufferNotInRAM)?;
let r = T::regs();
// Here it consider that the length of the packet is
// correctly set in the buffer, otherwise it will send
// unowned regions of memory
let ptr = buffer.as_ptr();
// Configure the payload
r.packetptr.write(|w| unsafe { w.bits(ptr as u32) });
Ok(())
}
/// Send packet
/// If the length byte in the package is greater than the buffer length
/// the radio will read memory out of the buffer bounds
pub async fn transmit(&mut self, buffer: &[u8]) -> Result<(), Error> {
self.set_buffer(buffer)?;
let r = T::regs();
self.trigger_and_wait_end(move || {
// Initialize the transmission
// trace!("txen");
r.tasks_txen.write(|w| w.tasks_txen().set_bit());
})
.await;
Ok(())
}
/// Receive packet
/// If the length byte in the received package is greater than the buffer length
/// the radio will write memory out of the buffer bounds
pub async fn receive(&mut self, buffer: &mut [u8]) -> Result<(), Error> {
self.set_buffer(buffer)?;
let r = T::regs();
self.trigger_and_wait_end(move || {
// Initialize the transmission
// trace!("rxen");
r.tasks_rxen.write(|w| w.tasks_rxen().set_bit());
})
.await;
Ok(())
}
async fn trigger_and_wait_end(&mut self, trigger: impl FnOnce()) {
//self.trace_state();
let r = T::regs();
let s = T::state();
// If the Future is dropped before the end of the transmission
// it disable the interrupt and stop the transmission
// to keep the state consistent
let drop = OnDrop::new(|| {
trace!("radio drop: stopping");
r.intenclr.write(|w| w.end().clear());
r.events_end.reset();
r.tasks_stop.write(|w| w.tasks_stop().set_bit());
// The docs don't explicitly mention any event to acknowledge the stop task
while r.events_end.read().events_end().bit_is_clear() {}
trace!("radio drop: stopped");
});
// trace!("radio:enable interrupt");
// Clear some remnant side-effects (TODO: check if this is necessary)
r.events_end.reset();
// Enable interrupt
r.intenset.write(|w| w.end().set());
compiler_fence(Ordering::SeqCst);
// Trigger the transmission
trigger();
// self.trace_state();
// On poll check if interrupt happen
poll_fn(|cx| {
s.end_waker.register(cx.waker());
if r.events_end.read().events_end().bit_is_set() {
// trace!("radio:end");
return core::task::Poll::Ready(());
}
Poll::Pending
})
.await;
compiler_fence(Ordering::SeqCst);
r.events_disabled.reset(); // ACK
// Everthing ends fine, so it disable the drop
drop.defuse();
}
/// Disable the radio
fn disable(&mut self) {
let r = T::regs();
compiler_fence(Ordering::SeqCst);
// If it is already disabled, do nothing
if self.state() != RadioState::DISABLED {
trace!("radio:disable");
// Trigger the disable task
r.tasks_disable.write(|w| w.tasks_disable().set_bit());
// Wait until the radio is disabled
while r.events_disabled.read().events_disabled().bit_is_clear() {}
compiler_fence(Ordering::SeqCst);
// Acknowledge it
r.events_disabled.reset();
}
}
}
impl<'d, T: Instance> Drop for Radio<'d, T> {
fn drop(&mut self) {
self.disable();
}
}

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@ -0,0 +1,75 @@
//! Integrated 2.4 GHz Radio
//!
//! The 2.4 GHz radio transceiver is compatible with multiple radio standards
//! such as 1Mbps, 2Mbps and Long Range Bluetooth Low Energy.
#![macro_use]
/// Bluetooth Low Energy Radio driver.
pub mod ble;
use core::marker::PhantomData;
use crate::{interrupt, pac, Peripheral};
/// Interrupt handler
pub struct InterruptHandler<T: Instance> {
_phantom: PhantomData<T>,
}
impl<T: Instance> interrupt::typelevel::Handler<T::Interrupt> for InterruptHandler<T> {
unsafe fn on_interrupt() {
let r = T::regs();
let s = T::state();
if r.events_end.read().events_end().bit_is_set() {
s.end_waker.wake();
r.intenclr.write(|w| w.end().clear());
}
}
}
pub(crate) mod sealed {
use embassy_sync::waitqueue::AtomicWaker;
pub struct State {
/// end packet transmission or reception
pub end_waker: AtomicWaker,
}
impl State {
pub const fn new() -> Self {
Self {
end_waker: AtomicWaker::new(),
}
}
}
pub trait Instance {
fn regs() -> &'static crate::pac::radio::RegisterBlock;
fn state() -> &'static State;
}
}
macro_rules! impl_radio {
($type:ident, $pac_type:ident, $irq:ident) => {
impl crate::radio::sealed::Instance for peripherals::$type {
fn regs() -> &'static pac::radio::RegisterBlock {
unsafe { &*pac::$pac_type::ptr() }
}
fn state() -> &'static crate::radio::sealed::State {
static STATE: crate::radio::sealed::State = crate::radio::sealed::State::new();
&STATE
}
}
impl crate::radio::Instance for peripherals::$type {
type Interrupt = crate::interrupt::typelevel::$irq;
}
};
}
/// Radio peripheral instance.
pub trait Instance: Peripheral<P = Self> + sealed::Instance + 'static + Send {
/// Interrupt for this peripheral.
type Interrupt: interrupt::typelevel::Interrupt;
}