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embassy/embassy-nrf/src/lib.rs

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//! # Embassy nRF HAL
//!
//! HALs implement safe, idiomatic Rust APIs to use the hardware capabilities, so raw register manipulation is not needed.
//!
//! The Embassy nRF HAL targets the Nordic Semiconductor nRF family of hardware. The HAL implements both blocking and async APIs
//! for many peripherals. The benefit of using the async APIs is that the HAL takes care of waiting for peripherals to
//! complete operations in low power mod and handling interrupts, so that applications can focus on more important matters.
//!
//! ## EasyDMA considerations
//!
//! On nRF chips, peripherals can use the so called EasyDMA feature to offload the task of interacting
//! with peripherals. It takes care of sending/receiving data over a variety of bus protocols (TWI/I2C, UART, SPI).
//! However, EasyDMA requires the buffers used to transmit and receive data to reside in RAM. Unfortunately, Rust
//! slices will not always do so. The following example using the SPI peripheral shows a common situation where this might happen:
//!
//! ```no_run
//! // As we pass a slice to the function whose contents will not ever change,
//! // the compiler writes it into the flash and thus the pointer to it will
//! // reference static memory. Since EasyDMA requires slices to reside in RAM,
//! // this function call will fail.
//! let result = spim.write_from_ram(&[1, 2, 3]);
//! assert_eq!(result, Err(Error::DMABufferNotInDataMemory));
//!
//! // The data is still static and located in flash. However, since we are assigning
//! // it to a variable, the compiler will load it into memory. Passing a reference to the
//! // variable will yield a pointer that references dynamic memory, thus making EasyDMA happy.
//! // This function call succeeds.
//! let data = [1, 2, 3];
//! let result = spim.write_from_ram(&data);
//! assert!(result.is_ok());
//! ```
//!
//! Each peripheral struct which uses EasyDMA ([`Spim`](spim::Spim), [`Uarte`](uarte::Uarte), [`Twim`](twim::Twim)) has two variants of their mutating functions:
//! - Functions with the suffix (e.g. [`write_from_ram`](spim::Spim::write_from_ram), [`transfer_from_ram`](spim::Spim::transfer_from_ram)) will return an error if the passed slice does not reside in RAM.
//! - Functions without the suffix (e.g. [`write`](spim::Spim::write), [`transfer`](spim::Spim::transfer)) will check whether the data is in RAM and copy it into memory prior to transmission.
//!
//! Since copying incurs a overhead, you are given the option to choose from `_from_ram` variants which will
//! fail and notify you, or the more convenient versions without the suffix which are potentially a little bit
//! more inefficient. Be aware that this overhead is not only in terms of instruction count but also in terms of memory usage
//! as the methods without the suffix will be allocating a statically sized buffer (up to 512 bytes for the nRF52840).
//!
//! Note that the methods that read data like [`read`](spim::Spim::read) and [`transfer_in_place`](spim::Spim::transfer_in_place) do not have the corresponding `_from_ram` variants as
//! mutable slices always reside in RAM.
#![no_std]
#![cfg_attr(feature = "nightly", feature(generic_associated_types, type_alias_impl_trait))]
#[cfg(not(any(
feature = "nrf51",
feature = "nrf52805",
feature = "nrf52810",
feature = "nrf52811",
feature = "nrf52820",
feature = "nrf52832",
feature = "nrf52833",
feature = "nrf52840",
feature = "nrf5340-app-s",
feature = "nrf5340-app-ns",
feature = "nrf5340-net",
feature = "nrf9160-s",
feature = "nrf9160-ns",
)))]
compile_error!("No chip feature activated. You must activate exactly one of the following features: nrf52810, nrf52811, nrf52832, nrf52833, nrf52840");
// This mod MUST go first, so that the others see its macros.
pub(crate) mod fmt;
pub(crate) mod util;
#[cfg(feature = "_time-driver")]
mod time_driver;
#[cfg(feature = "nightly")]
pub mod buffered_uarte;
pub mod gpio;
#[cfg(feature = "gpiote")]
pub mod gpiote;
#[cfg(not(any(feature = "_nrf5340", feature = "_nrf9160")))]
pub mod nvmc;
pub mod ppi;
#[cfg(not(any(feature = "nrf52805", feature = "nrf52820", feature = "_nrf5340-net")))]
pub mod pwm;
#[cfg(not(any(feature = "nrf51", feature = "_nrf9160", feature = "_nrf5340")))]
pub mod qdec;
#[cfg(feature = "nrf52840")]
pub mod qspi;
#[cfg(not(any(feature = "_nrf5340", feature = "_nrf9160")))]
pub mod rng;
#[cfg(not(any(feature = "nrf52820", feature = "_nrf5340-net")))]
pub mod saadc;
pub mod spim;
#[cfg(not(any(feature = "_nrf5340", feature = "_nrf9160")))]
pub mod temp;
pub mod timer;
pub mod twim;
pub mod uarte;
#[cfg(any(
feature = "_nrf5340-app",
feature = "nrf52820",
feature = "nrf52833",
feature = "nrf52840"
))]
#[cfg(feature = "nightly")]
pub mod usb;
#[cfg(not(feature = "_nrf5340"))]
pub mod wdt;
// This mod MUST go last, so that it sees all the `impl_foo!` macros
#[cfg_attr(feature = "nrf52805", path = "chips/nrf52805.rs")]
#[cfg_attr(feature = "nrf52810", path = "chips/nrf52810.rs")]
#[cfg_attr(feature = "nrf52811", path = "chips/nrf52811.rs")]
#[cfg_attr(feature = "nrf52820", path = "chips/nrf52820.rs")]
#[cfg_attr(feature = "nrf52832", path = "chips/nrf52832.rs")]
#[cfg_attr(feature = "nrf52833", path = "chips/nrf52833.rs")]
#[cfg_attr(feature = "nrf52840", path = "chips/nrf52840.rs")]
#[cfg_attr(feature = "_nrf5340-app", path = "chips/nrf5340_app.rs")]
#[cfg_attr(feature = "_nrf5340-net", path = "chips/nrf5340_net.rs")]
#[cfg_attr(feature = "_nrf9160", path = "chips/nrf9160.rs")]
mod chip;
pub use chip::EASY_DMA_SIZE;
pub mod interrupt {
//! nRF interrupts for cortex-m devices.
pub use cortex_m::interrupt::{CriticalSection, Mutex};
pub use embassy_cortex_m::interrupt::*;
pub use crate::chip::irqs::*;
}
// Reexports
#[cfg(feature = "unstable-pac")]
pub use chip::pac;
#[cfg(not(feature = "unstable-pac"))]
pub(crate) use chip::pac;
pub use chip::{peripherals, Peripherals};
pub use embassy_cortex_m::executor;
pub use embassy_hal_common::{into_ref, Peripheral, PeripheralRef};
pub use embassy_macros::cortex_m_interrupt as interrupt;
pub mod config {
//! Configuration options used when initializing the HAL.
/// High frequency clock source.
pub enum HfclkSource {
/// Internal source
Internal,
/// External source from xtal.
ExternalXtal,
}
/// Low frequency clock source
pub enum LfclkSource {
/// Internal RC oscillator
InternalRC,
/// Synthesized from the high frequency clock source.
#[cfg(not(any(feature = "_nrf5340", feature = "_nrf9160")))]
Synthesized,
/// External source from xtal.
ExternalXtal,
/// External source from xtal with low swing applied.
#[cfg(not(any(feature = "_nrf5340", feature = "_nrf9160")))]
ExternalLowSwing,
/// External source from xtal with full swing applied.
#[cfg(not(any(feature = "_nrf5340", feature = "_nrf9160")))]
ExternalFullSwing,
}
/// Configuration for peripherals. Default configuration should work on any nRF chip.
#[non_exhaustive]
pub struct Config {
/// High frequency clock source.
pub hfclk_source: HfclkSource,
/// Low frequency clock source.
pub lfclk_source: LfclkSource,
/// GPIOTE interrupt priority. Should be lower priority than softdevice if used.
#[cfg(feature = "gpiote")]
pub gpiote_interrupt_priority: crate::interrupt::Priority,
/// Time driver interrupt priority. Should be lower priority than softdevice if used.
#[cfg(feature = "_time-driver")]
pub time_interrupt_priority: crate::interrupt::Priority,
}
impl Default for Config {
fn default() -> Self {
Self {
// There are hobby nrf52 boards out there without external XTALs...
// Default everything to internal so it Just Works. User can enable external
// xtals if they know they have them.
hfclk_source: HfclkSource::Internal,
lfclk_source: LfclkSource::InternalRC,
#[cfg(feature = "gpiote")]
gpiote_interrupt_priority: crate::interrupt::Priority::P0,
#[cfg(feature = "_time-driver")]
time_interrupt_priority: crate::interrupt::Priority::P0,
}
}
}
}
/// Initialize peripherals with the provided configuration. This should only be called once at startup.
pub fn init(config: config::Config) -> Peripherals {
// Do this first, so that it panics if user is calling `init` a second time
// before doing anything important.
let peripherals = Peripherals::take();
let r = unsafe { &*pac::CLOCK::ptr() };
// Start HFCLK.
match config.hfclk_source {
config::HfclkSource::Internal => {}
config::HfclkSource::ExternalXtal => {
// Datasheet says this is likely to take 0.36ms
r.events_hfclkstarted.write(|w| unsafe { w.bits(0) });
r.tasks_hfclkstart.write(|w| unsafe { w.bits(1) });
while r.events_hfclkstarted.read().bits() == 0 {}
}
}
// Configure LFCLK.
#[cfg(not(any(feature = "_nrf5340", feature = "_nrf9160")))]
match config.lfclk_source {
config::LfclkSource::InternalRC => r.lfclksrc.write(|w| w.src().rc()),
config::LfclkSource::Synthesized => r.lfclksrc.write(|w| w.src().synth()),
config::LfclkSource::ExternalXtal => r.lfclksrc.write(|w| w.src().xtal()),
config::LfclkSource::ExternalLowSwing => r.lfclksrc.write(|w| {
w.src().xtal();
w.external().enabled();
w.bypass().disabled();
w
}),
config::LfclkSource::ExternalFullSwing => r.lfclksrc.write(|w| {
w.src().xtal();
w.external().enabled();
w.bypass().enabled();
w
}),
}
#[cfg(feature = "_nrf9160")]
match config.lfclk_source {
config::LfclkSource::InternalRC => r.lfclksrc.write(|w| w.src().lfrc()),
config::LfclkSource::ExternalXtal => r.lfclksrc.write(|w| w.src().lfxo()),
}
// Start LFCLK.
// Datasheet says this could take 100us from synth source
// 600us from rc source, 0.25s from an external source.
r.events_lfclkstarted.write(|w| unsafe { w.bits(0) });
r.tasks_lfclkstart.write(|w| unsafe { w.bits(1) });
while r.events_lfclkstarted.read().bits() == 0 {}
// Init GPIOTE
#[cfg(feature = "gpiote")]
gpiote::init(config.gpiote_interrupt_priority);
// init RTC time driver
#[cfg(feature = "_time-driver")]
time_driver::init(config.time_interrupt_priority);
peripherals
}
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