platform/src/timer.rs - sw/matcha - Git at Google

 //! Timer driver.

 use kernel::common::cells::OptionalCell;
 use kernel::common::registers::{register_bitfields, register_structs, ReadWrite, WriteOnly};
 use kernel::common::StaticRef;
 use kernel::hil::time;
 use kernel::hil::time::{Ticks, Ticks64, Time};
 use kernel::ReturnCode;

 const PRESCALE: u16 = ((crate::chip::CHIP_CPU_FREQ / 10_000) - 1) as u16; // 10Khz

 /// 10KHz `Frequency`
 #[derive(Debug)]
 pub struct Freq10KHz;
 impl time::Frequency for Freq10KHz {
     fn frequency() -> u32 {
         10_000
     }
 }

 register_structs! {
     pub TimerRegisters {
         (0x000 => ctrl: ReadWrite<u32, ctrl::Register>),

         (0x004 => _reserved),

         (0x100 => config: ReadWrite<u32, config::Register>),

         (0x104 => value_low: ReadWrite<u32>),
         (0x108 => value_high: ReadWrite<u32>),

         (0x10c => compare_low: ReadWrite<u32>),
         (0x110 => compare_high: ReadWrite<u32>),

         (0x114 => intr_enable: ReadWrite<u32, intr::Register>),
         (0x118 => intr_state: ReadWrite<u32, intr::Register>),
         (0x11c => intr_test: WriteOnly<u32, intr::Register>),
         (0x120 => @END),
     }
 }

 register_bitfields![u32,
     ctrl [
         enable OFFSET(0) NUMBITS(1) []
     ],
     config [
         prescale OFFSET(0) NUMBITS(12) [],
         step OFFSET(16) NUMBITS(8) []
     ],
     intr [
         timer0 OFFSET(0) NUMBITS(1) []
     ]
 ];

 pub struct RvTimer<'a> {
     registers: StaticRef<TimerRegisters>,
     alarm_client: OptionalCell<&'a dyn time::AlarmClient>,
     overflow_client: OptionalCell<&'a dyn time::OverflowClient>,
 }

 impl<'a> RvTimer<'a> {
     const fn new(base: StaticRef<TimerRegisters>) -> RvTimer<'a> {
         RvTimer {
             registers: base,
             alarm_client: OptionalCell::empty(),
             overflow_client: OptionalCell::empty(),
         }
     }

     pub fn setup(&self) {
         let regs = self.registers;
         // Set proper prescaler and the like
         regs.config
             .write(config::prescale.val(PRESCALE as u32) + config::step.val(1u32));
         regs.compare_high.set(0);
         regs.value_low.set(0xFFFF_0000);
         regs.intr_enable.write(intr::timer0::CLEAR);
         regs.ctrl.write(ctrl::enable::SET);
     }

     pub fn service_interrupt(&self) {
         let regs = self.registers;
         regs.intr_enable.write(intr::timer0::CLEAR);
         regs.intr_state.write(intr::timer0::SET);
         self.alarm_client.map(|client| {
             client.alarm();
         });
     }
 }

 impl time::Time for RvTimer<'_> {
     type Frequency = Freq10KHz;
     type Ticks = Ticks64;

     fn now(&self) -> Ticks64 {
         // RISC-V has a 64-bit counter but you can only read 32 bits
         // at once, which creates a race condition if the lower register
         // wraps between the reads. So the recommended approach is to read
         // low, read high, read low, and if the second low is lower, re-read
         // high. -pal 8/6/20
         let first_low: u32 = self.registers.value_low.get();
         let mut high: u32 = self.registers.value_high.get();
         let second_low: u32 = self.registers.value_low.get();
         if second_low < first_low {
             // Wraparound
             high = self.registers.value_high.get();
         }
         Ticks64::from(((high as u64) << 32) | second_low as u64)
     }
 }

 impl<'a> time::Counter<'a> for RvTimer<'a> {
     fn set_overflow_client(&'a self, client: &'a dyn time::OverflowClient) {
         self.overflow_client.set(client);
     }

     fn start(&self) -> ReturnCode {
         ReturnCode::SUCCESS
     }

     fn stop(&self) -> ReturnCode {
         // RISCV counter can't be stopped...
         ReturnCode::EBUSY
     }

     fn reset(&self) -> ReturnCode {
         // RISCV counter can't be reset
         ReturnCode::FAIL
     }

     fn is_running(&self) -> bool {
         true
     }
 }

 impl<'a> time::Alarm<'a> for RvTimer<'a> {
     fn set_alarm_client(&self, client: &'a dyn time::AlarmClient) {
         self.alarm_client.set(client);
     }

     fn set_alarm(&self, reference: Self::Ticks, dt: Self::Ticks) {
         // This does not handle the 64-bit wraparound case.
         // Because mtimer fires if the counter is >= the compare,
         // handling wraparound requires setting compare to the
         // maximum value, issuing a callback on the overflow client
         // if there is one, spinning until it wraps around to 0, then
         // setting the compare to the correct value.
         let regs = self.registers;
         let now = self.now();
         let mut expire = reference.wrapping_add(dt);

         if !now.within_range(reference, expire) {
             expire = now;
         }

         let val = expire.into_u64();
         let high = (val >> 32) as u32;
         let low = (val & 0xffffffff) as u32;

         // Recommended approach for setting the two compare registers
         // (RISC-V Privileged Architectures 3.1.15) -pal 8/6/20
         regs.compare_low.set(0xffffffff);
         regs.compare_high.set(high);
         regs.compare_low.set(low);
         //debug!("TIMER: set to {}", expire.into_u64());
         self.registers.intr_enable.write(intr::timer0::SET);
     }

     fn get_alarm(&self) -> Self::Ticks {
         let mut val: u64 = (self.registers.compare_high.get() as u64) << 32;
         val |= self.registers.compare_low.get() as u64;
         Ticks64::from(val)
     }

     fn disarm(&self) -> ReturnCode {
         // You clear the RISCV mtime interrupt by writing to the compare
         // registers. Since the only way to do so is to set a new alarm,
         // and this is also the only way to re-enable the interrupt, disabling
         // the interrupt is sufficient. Calling set_alarm will clear the
         // pending interrupt before re-enabling. -pal 8/6/20
         self.registers.intr_enable.write(intr::timer0::CLEAR);
         ReturnCode::SUCCESS
     }

     fn is_armed(&self) -> bool {
         self.registers.intr_enable.is_set(intr::timer0)
     }

     fn minimum_dt(&self) -> Self::Ticks {
         Self::Ticks::from(1 as u64)
     }
 }

 const TIMER_BASE: StaticRef<TimerRegisters> =
     unsafe { StaticRef::new(0x4010_0000 as *const TimerRegisters) };

 pub static mut TIMER: RvTimer = RvTimer::new(TIMER_BASE);
	//! Timer driver.

	use kernel::common::cells::OptionalCell;
	use kernel::common::registers::{register_bitfields, register_structs, ReadWrite, WriteOnly};
	use kernel::common::StaticRef;
	use kernel::hil::time;
	use kernel::hil::time::{Ticks, Ticks64, Time};
	use kernel::ReturnCode;

	const PRESCALE: u16 = ((crate::chip::CHIP_CPU_FREQ / 10_000) - 1) as u16; // 10Khz

	/// 10KHz `Frequency`
	#[derive(Debug)]
	pub struct Freq10KHz;
	impl time::Frequency for Freq10KHz {
	fn frequency() -> u32 {
	10_000
	}
	}

	register_structs! {
	pub TimerRegisters {
	(0x000 => ctrl: ReadWrite<u32, ctrl::Register>),

	(0x004 => _reserved),

	(0x100 => config: ReadWrite<u32, config::Register>),

	(0x104 => value_low: ReadWrite<u32>),
	(0x108 => value_high: ReadWrite<u32>),

	(0x10c => compare_low: ReadWrite<u32>),
	(0x110 => compare_high: ReadWrite<u32>),

	(0x114 => intr_enable: ReadWrite<u32, intr::Register>),
	(0x118 => intr_state: ReadWrite<u32, intr::Register>),
	(0x11c => intr_test: WriteOnly<u32, intr::Register>),
	(0x120 => @END),
	}
	}

	register_bitfields![u32,
	ctrl [
	enable OFFSET(0) NUMBITS(1) []
	],
	config [
	prescale OFFSET(0) NUMBITS(12) [],
	step OFFSET(16) NUMBITS(8) []
	],
	intr [
	timer0 OFFSET(0) NUMBITS(1) []
	]
	];

	pub struct RvTimer<'a> {
	registers: StaticRef<TimerRegisters>,
	alarm_client: OptionalCell<&'a dyn time::AlarmClient>,
	overflow_client: OptionalCell<&'a dyn time::OverflowClient>,
	}

	impl<'a> RvTimer<'a> {
	const fn new(base: StaticRef<TimerRegisters>) -> RvTimer<'a> {
	RvTimer {
	registers: base,
	alarm_client: OptionalCell::empty(),
	overflow_client: OptionalCell::empty(),
	}
	}

	pub fn setup(&self) {
	let regs = self.registers;
	// Set proper prescaler and the like
	regs.config
	.write(config::prescale.val(PRESCALE as u32) + config::step.val(1u32));
	regs.compare_high.set(0);
	regs.value_low.set(0xFFFF_0000);
	regs.intr_enable.write(intr::timer0::CLEAR);
	regs.ctrl.write(ctrl::enable::SET);
	}

	pub fn service_interrupt(&self) {
	let regs = self.registers;
	regs.intr_enable.write(intr::timer0::CLEAR);
	regs.intr_state.write(intr::timer0::SET);
	self.alarm_client.map(\|client\| {
	client.alarm();
	});
	}
	}

	impl time::Time for RvTimer<'_> {
	type Frequency = Freq10KHz;
	type Ticks = Ticks64;

	fn now(&self) -> Ticks64 {
	// RISC-V has a 64-bit counter but you can only read 32 bits
	// at once, which creates a race condition if the lower register
	// wraps between the reads. So the recommended approach is to read
	// low, read high, read low, and if the second low is lower, re-read
	// high. -pal 8/6/20
	let first_low: u32 = self.registers.value_low.get();
	let mut high: u32 = self.registers.value_high.get();
	let second_low: u32 = self.registers.value_low.get();
	if second_low < first_low {
	// Wraparound
	high = self.registers.value_high.get();
	}
	Ticks64::from(((high as u64) << 32) \| second_low as u64)
	}
	}

	impl<'a> time::Counter<'a> for RvTimer<'a> {
	fn set_overflow_client(&'a self, client: &'a dyn time::OverflowClient) {
	self.overflow_client.set(client);
	}

	fn start(&self) -> ReturnCode {
	ReturnCode::SUCCESS
	}

	fn stop(&self) -> ReturnCode {
	// RISCV counter can't be stopped...
	ReturnCode::EBUSY
	}

	fn reset(&self) -> ReturnCode {
	// RISCV counter can't be reset
	ReturnCode::FAIL
	}

	fn is_running(&self) -> bool {
	true
	}
	}

	impl<'a> time::Alarm<'a> for RvTimer<'a> {
	fn set_alarm_client(&self, client: &'a dyn time::AlarmClient) {
	self.alarm_client.set(client);
	}

	fn set_alarm(&self, reference: Self::Ticks, dt: Self::Ticks) {
	// This does not handle the 64-bit wraparound case.
	// Because mtimer fires if the counter is >= the compare,
	// handling wraparound requires setting compare to the
	// maximum value, issuing a callback on the overflow client
	// if there is one, spinning until it wraps around to 0, then
	// setting the compare to the correct value.
	let regs = self.registers;
	let now = self.now();
	let mut expire = reference.wrapping_add(dt);

	if !now.within_range(reference, expire) {
	expire = now;
	}

	let val = expire.into_u64();
	let high = (val >> 32) as u32;
	let low = (val & 0xffffffff) as u32;

	// Recommended approach for setting the two compare registers
	// (RISC-V Privileged Architectures 3.1.15) -pal 8/6/20
	regs.compare_low.set(0xffffffff);
	regs.compare_high.set(high);
	regs.compare_low.set(low);
	//debug!("TIMER: set to {}", expire.into_u64());
	self.registers.intr_enable.write(intr::timer0::SET);
	}

	fn get_alarm(&self) -> Self::Ticks {
	let mut val: u64 = (self.registers.compare_high.get() as u64) << 32;
	val \|= self.registers.compare_low.get() as u64;
	Ticks64::from(val)
	}

	fn disarm(&self) -> ReturnCode {
	// You clear the RISCV mtime interrupt by writing to the compare
	// registers. Since the only way to do so is to set a new alarm,
	// and this is also the only way to re-enable the interrupt, disabling
	// the interrupt is sufficient. Calling set_alarm will clear the
	// pending interrupt before re-enabling. -pal 8/6/20
	self.registers.intr_enable.write(intr::timer0::CLEAR);
	ReturnCode::SUCCESS
	}

	fn is_armed(&self) -> bool {
	self.registers.intr_enable.is_set(intr::timer0)
	}

	fn minimum_dt(&self) -> Self::Ticks {
	Self::Ticks::from(1 as u64)
	}
	}

	const TIMER_BASE: StaticRef<TimerRegisters> =
	unsafe { StaticRef::new(0x4010_0000 as *const TimerRegisters) };

	pub static mut TIMER: RvTimer = RvTimer::new(TIMER_BASE);