#![cfg_attr(not(test), no_std)] #![allow(async_fn_in_trait)] //! ## Feature flags #![doc = document_features::document_features!(feature_label = r#"{feature}"#)] // This must go FIRST so that all the other modules see its macros. mod fmt; include!(concat!(env!("OUT_DIR"), "/_macros.rs")); // Utilities pub mod time; mod traits; // Always-present hardware pub mod dma; pub mod gpio; pub mod rcc; #[cfg(feature = "_time-driver")] mod time_driver; pub mod timer; // Sometimes-present hardware #[cfg(adc)] pub mod adc; #[cfg(can)] pub mod can; #[cfg(crc)] pub mod crc; #[cfg(dac)] pub mod dac; #[cfg(dcmi)] pub mod dcmi; #[cfg(eth)] pub mod eth; #[cfg(feature = "exti")] pub mod exti; pub mod flash; #[cfg(fmc)] pub mod fmc; #[cfg(hrtim)] pub mod hrtim; #[cfg(i2c)] pub mod i2c; #[cfg(all(spi_v1, rcc_f4))] pub mod i2s; #[cfg(stm32wb)] pub mod ipcc; #[cfg(feature = "low-power")] pub mod low_power; #[cfg(opamp)] pub mod opamp; #[cfg(quadspi)] pub mod qspi; #[cfg(rng)] pub mod rng; #[cfg(all(rtc, not(rtc_v1)))] pub mod rtc; #[cfg(sai)] pub mod sai; #[cfg(sdmmc)] pub mod sdmmc; #[cfg(spi)] pub mod spi; #[cfg(uid)] pub mod uid; #[cfg(usart)] pub mod usart; #[cfg(usb)] pub mod usb; #[cfg(otg)] pub mod usb_otg; #[cfg(iwdg)] pub mod wdg; // This must go last, so that it sees all the impl_foo! macros defined earlier. pub(crate) mod _generated { #![allow(dead_code)] #![allow(unused_imports)] #![allow(non_snake_case)] include!(concat!(env!("OUT_DIR"), "/_generated.rs")); } pub use crate::_generated::interrupt; /// Macro to bind interrupts to handlers. /// /// This defines the right interrupt handlers, and creates a unit struct (like `struct Irqs;`) /// and implements the right [`Binding`]s for it. You can pass this struct to drivers to /// prove at compile-time that the right interrupts have been bound. /// /// Example of how to bind one interrupt: /// /// ```rust,ignore /// use embassy_stm32::{bind_interrupts, usb_otg, peripherals}; /// /// bind_interrupts!(struct Irqs { /// OTG_FS => usb_otg::InterruptHandler; /// }); /// ``` /// /// Example of how to bind multiple interrupts, and multiple handlers to each interrupt, in a single macro invocation: /// /// ```rust,ignore /// use embassy_stm32::{bind_interrupts, i2c, peripherals}; /// /// bind_interrupts!(struct Irqs { /// I2C1 => i2c::EventInterruptHandler, i2c::ErrorInterruptHandler; /// I2C2_3 => i2c::EventInterruptHandler, i2c::ErrorInterruptHandler, /// i2c::EventInterruptHandler, i2c::ErrorInterruptHandler; /// }); /// ``` // developer note: this macro can't be in `embassy-hal-internal` due to the use of `$crate`. #[macro_export] macro_rules! bind_interrupts { ($vis:vis struct $name:ident { $($irq:ident => $($handler:ty),*;)* }) => { #[derive(Copy, Clone)] $vis struct $name; $( #[allow(non_snake_case)] #[no_mangle] unsafe extern "C" fn $irq() { $( <$handler as $crate::interrupt::typelevel::Handler<$crate::interrupt::typelevel::$irq>>::on_interrupt(); )* } $( unsafe impl $crate::interrupt::typelevel::Binding<$crate::interrupt::typelevel::$irq, $handler> for $name {} )* )* }; } // Reexports pub use _generated::{peripherals, Peripherals}; pub use embassy_hal_internal::{into_ref, Peripheral, PeripheralRef}; #[cfg(feature = "unstable-pac")] pub use stm32_metapac as pac; #[cfg(not(feature = "unstable-pac"))] pub(crate) use stm32_metapac as pac; use crate::interrupt::Priority; #[cfg(feature = "rt")] pub use crate::pac::NVIC_PRIO_BITS; use crate::rcc::sealed::RccPeripheral; #[non_exhaustive] pub struct Config { pub rcc: rcc::Config, #[cfg(dbgmcu)] pub enable_debug_during_sleep: bool, #[cfg(bdma)] pub bdma_interrupt_priority: Priority, #[cfg(dma)] pub dma_interrupt_priority: Priority, #[cfg(gpdma)] pub gpdma_interrupt_priority: Priority, } impl Default for Config { fn default() -> Self { Self { rcc: Default::default(), #[cfg(dbgmcu)] enable_debug_during_sleep: true, #[cfg(bdma)] bdma_interrupt_priority: Priority::P0, #[cfg(dma)] dma_interrupt_priority: Priority::P0, #[cfg(gpdma)] gpdma_interrupt_priority: Priority::P0, } } } /// Initialize embassy. pub fn init(config: Config) -> Peripherals { critical_section::with(|cs| { let p = Peripherals::take_with_cs(cs); #[cfg(dbgmcu)] if config.enable_debug_during_sleep { crate::pac::DBGMCU.cr().modify(|cr| { #[cfg(any(dbgmcu_f0, dbgmcu_c0, dbgmcu_g0, dbgmcu_u5, dbgmcu_wba))] { cr.set_dbg_stop(true); cr.set_dbg_standby(true); } #[cfg(any( dbgmcu_f1, dbgmcu_f2, dbgmcu_f3, dbgmcu_f4, dbgmcu_f7, dbgmcu_g4, dbgmcu_f7, dbgmcu_l0, dbgmcu_l1, dbgmcu_l4, dbgmcu_wb, dbgmcu_wl ))] { cr.set_dbg_sleep(true); cr.set_dbg_stop(true); cr.set_dbg_standby(true); } #[cfg(dbgmcu_h7)] { cr.set_d1dbgcken(true); cr.set_d3dbgcken(true); cr.set_dbgsleep_d1(true); cr.set_dbgstby_d1(true); cr.set_dbgstop_d1(true); } }); } #[cfg(not(any(stm32f1, stm32wb, stm32wl)))] peripherals::SYSCFG::enable_and_reset_with_cs(cs); #[cfg(not(any(stm32h5, stm32h7, stm32wb, stm32wl)))] peripherals::PWR::enable_and_reset_with_cs(cs); #[cfg(not(any(stm32f2, stm32f4, stm32f7, stm32l0, stm32h5, stm32h7)))] peripherals::FLASH::enable_and_reset_with_cs(cs); unsafe { #[cfg(feature = "_split-pins-enabled")] crate::pac::SYSCFG.pmcr().modify(|pmcr| { #[cfg(feature = "split-pa0")] pmcr.set_pa0so(true); #[cfg(feature = "split-pa1")] pmcr.set_pa1so(true); #[cfg(feature = "split-pc2")] pmcr.set_pc2so(true); #[cfg(feature = "split-pc3")] pmcr.set_pc3so(true); }); gpio::init(cs); dma::init( cs, #[cfg(bdma)] config.bdma_interrupt_priority, #[cfg(dma)] config.dma_interrupt_priority, #[cfg(gpdma)] config.gpdma_interrupt_priority, ); #[cfg(feature = "exti")] exti::init(cs); rcc::init(config.rcc); // must be after rcc init #[cfg(feature = "_time-driver")] time_driver::init(cs); #[cfg(feature = "low-power")] { crate::rcc::REFCOUNT_STOP2 = 0; crate::rcc::REFCOUNT_STOP1 = 0; } } p }) }