嵌入式 Rust:进阶篇
RTC 驱动程序
(返回练习)
main.rs:
#![no_main] #![no_std] mod exceptions; mod logger; mod pl011; mod pl031; use crate::pl031::Rtc; use arm_gic::gicv3::{IntId, Trigger}; use arm_gic::{irq_enable, wfi}; use chrono::{TimeZone, Utc}; use core::hint::spin_loop; use crate::pl011::Uart; use arm_gic::gicv3::GicV3; use core::panic::PanicInfo; use log::{error, info, trace, LevelFilter}; use smccc::psci::system_off; use smccc::Hvc; /// Base addresses of the GICv3. const GICD_BASE_ADDRESS: *mut u64 = 0x800_0000 as _; const GICR_BASE_ADDRESS: *mut u64 = 0x80A_0000 as _; /// Base address of the primary PL011 UART. const PL011_BASE_ADDRESS: *mut u32 = 0x900_0000 as _; /// Base address of the PL031 RTC. const PL031_BASE_ADDRESS: *mut u32 = 0x901_0000 as _; /// The IRQ used by the PL031 RTC. const PL031_IRQ: IntId = IntId::spi(2); #[no_mangle] extern "C" fn main(x0: u64, x1: u64, x2: u64, x3: u64) { // SAFETY: `PL011_BASE_ADDRESS` is the base address of a PL011 device, and // nothing else accesses that address range. let uart = unsafe { Uart::new(PL011_BASE_ADDRESS) }; logger::init(uart, LevelFilter::Trace).unwrap(); info!("main({:#x}, {:#x}, {:#x}, {:#x})", x0, x1, x2, x3); // SAFETY: `GICD_BASE_ADDRESS` and `GICR_BASE_ADDRESS` are the base // addresses of a GICv3 distributor and redistributor respectively, and // nothing else accesses those address ranges. let mut gic = unsafe { GicV3::new(GICD_BASE_ADDRESS, GICR_BASE_ADDRESS) }; gic.setup(); // SAFETY: `PL031_BASE_ADDRESS` is the base address of a PL031 device, and // nothing else accesses that address range. let mut rtc = unsafe { Rtc::new(PL031_BASE_ADDRESS) }; let timestamp = rtc.read(); let time = Utc.timestamp_opt(timestamp.into(), 0).unwrap(); info!("RTC: {time}"); GicV3::set_priority_mask(0xff); gic.set_interrupt_priority(PL031_IRQ, 0x80); gic.set_trigger(PL031_IRQ, Trigger::Level); irq_enable(); gic.enable_interrupt(PL031_IRQ, true); // Wait for 3 seconds, without interrupts. let target = timestamp + 3; rtc.set_match(target); info!("Waiting for {}", Utc.timestamp_opt(target.into(), 0).unwrap()); trace!( "matched={}, interrupt_pending={}", rtc.matched(), rtc.interrupt_pending() ); while !rtc.matched() { spin_loop(); } trace!( "matched={}, interrupt_pending={}", rtc.matched(), rtc.interrupt_pending() ); info!("Finished waiting"); // Wait another 3 seconds for an interrupt. let target = timestamp + 6; info!("Waiting for {}", Utc.timestamp_opt(target.into(), 0).unwrap()); rtc.set_match(target); rtc.clear_interrupt(); rtc.enable_interrupt(true); trace!( "matched={}, interrupt_pending={}", rtc.matched(), rtc.interrupt_pending() ); while !rtc.interrupt_pending() { wfi(); } trace!( "matched={}, interrupt_pending={}", rtc.matched(), rtc.interrupt_pending() ); info!("Finished waiting"); system_off::<Hvc>().unwrap(); } #[panic_handler] fn panic(info: &PanicInfo) -> ! { error!("{info}"); system_off::<Hvc>().unwrap(); loop {} }
pl031.rs:
#![allow(unused)] fn main() { use core::ptr::{addr_of, addr_of_mut}; #[repr(C, align(4))] struct Registers { /// Data register dr: u32, /// Match register mr: u32, /// Load register lr: u32, /// Control register cr: u8, _reserved0: [u8; 3], /// Interrupt Mask Set or Clear register imsc: u8, _reserved1: [u8; 3], /// Raw Interrupt Status ris: u8, _reserved2: [u8; 3], /// Masked Interrupt Status mis: u8, _reserved3: [u8; 3], /// Interrupt Clear Register icr: u8, _reserved4: [u8; 3], } /// Driver for a PL031 real-time clock. #[derive(Debug)] pub struct Rtc { registers: *mut Registers, } impl Rtc { /// Constructs a new instance of the RTC driver for a PL031 device at the /// given base address. /// /// # Safety /// /// The given base address must point to the MMIO control registers of a /// PL031 device, which must be mapped into the address space of the process /// as device memory and not have any other aliases. pub unsafe fn new(base_address: *mut u32) -> Self { Self { registers: base_address as *mut Registers } } /// Reads the current RTC value. pub fn read(&self) -> u32 { // SAFETY: We know that self.registers points to the control registers // of a PL031 device which is appropriately mapped. unsafe { addr_of!((*self.registers).dr).read_volatile() } } /// Writes a match value. When the RTC value matches this then an interrupt /// will be generated (if it is enabled). pub fn set_match(&mut self, value: u32) { // SAFETY: We know that self.registers points to the control registers // of a PL031 device which is appropriately mapped. unsafe { addr_of_mut!((*self.registers).mr).write_volatile(value) } } /// Returns whether the match register matches the RTC value, whether or not /// the interrupt is enabled. pub fn matched(&self) -> bool { // SAFETY: We know that self.registers points to the control registers // of a PL031 device which is appropriately mapped. let ris = unsafe { addr_of!((*self.registers).ris).read_volatile() }; (ris & 0x01) != 0 } /// Returns whether there is currently an interrupt pending. /// /// This should be true if and only if `matched` returns true and the /// interrupt is masked. pub fn interrupt_pending(&self) -> bool { // SAFETY: We know that self.registers points to the control registers // of a PL031 device which is appropriately mapped. let ris = unsafe { addr_of!((*self.registers).mis).read_volatile() }; (ris & 0x01) != 0 } /// Sets or clears the interrupt mask. /// /// When the mask is true the interrupt is enabled; when it is false the /// interrupt is disabled. pub fn enable_interrupt(&mut self, mask: bool) { let imsc = if mask { 0x01 } else { 0x00 }; // SAFETY: We know that self.registers points to the control registers // of a PL031 device which is appropriately mapped. unsafe { addr_of_mut!((*self.registers).imsc).write_volatile(imsc) } } /// Clears a pending interrupt, if any. pub fn clear_interrupt(&mut self) { // SAFETY: We know that self.registers points to the control registers // of a PL031 device which is appropriately mapped. unsafe { addr_of_mut!((*self.registers).icr).write_volatile(0x01) } } } // SAFETY: `Rtc` just contains a pointer to device memory, which can be // accessed from any context. unsafe impl Send for Rtc {} }