Refactor race condition free timer helper (#850)

* Implement half_period_counter in rtic-time * Rename compute_now to calculate_now, use it in stm32 and imxrt * Add more tests * Add some docs * Fix clippy warning, add imxrt timer to monotonics tests * Bump dependency version to make sure monotonics will build properly * Add changelog to rtic-monotonics * Add more docs * Add more docs * Finish documentation * Fix typos * Switch from atomic-polyfill to portable-atomic * Some more doc fixes * More doc fixes * Minor doc fix * Minor doc fix * Fix Atomics not existing * Fix example * Minor example improvement * Revert back to atomic-polyfill * Fix cargo.toml formatting * Remove atomic-polyfill * Attempt to fix unused macro warning * Remove atomics completely from half period counter * Minor doc fix * Doc fixes * Doc fixes * Remove obsolete comment * Fix ordering in monotonic initialization sequence
2024-11-23 12:12:50 +01:00 · 2023-12-04 15:53:02 +01:00 · 2023-12-04 15:53:02 +01:00 · c227a71d24
commit c227a71d24
parent 3de5f793f3
10 changed files with 350 additions and 49 deletions
--- a/rtic-monotonics/CHANGELOG.md
+++ b/rtic-monotonics/CHANGELOG.md
@ -11,6 +11,10 @@ For each category, *Added*, *Changed*, *Fixed* add new entries at the top!
 - **Soundness fix:** Monotonics did not wait long enough in `Duration` based delays.
 ### Changed
 - Bump `rtic-time`
 ## v1.3.0 - 2023-11-08
 ### Added
--- a/rtic-monotonics/Cargo.toml
+++ b/rtic-monotonics/Cargo.toml
@ -27,7 +27,7 @@ features = [
 rustdoc-flags = ["--cfg", "docsrs"]
 [dependencies]
-rtic-time = { version = "1.0.0", path = "../rtic-time" }
+rtic-time = { version = "1.1.0", path = "../rtic-time" }
 embedded-hal = { version = "1.0.0-rc.2" }
 embedded-hal-async = { version = "1.0.0-rc.2", optional = true }
 fugit = { version = "0.3.6" }
--- a/rtic-monotonics/src/imxrt.rs
+++ b/rtic-monotonics/src/imxrt.rs
@ -30,8 +30,9 @@
 //! ```
 use crate::{Monotonic, TimeoutError, TimerQueue};
-use atomic_polyfill::{compiler_fence, AtomicU32, Ordering};
+use atomic_polyfill::{AtomicU32, Ordering};
 pub use fugit::{self, ExtU64, ExtU64Ceil};
 use rtic_time::half_period_counter::calculate_now;
 use imxrt_ral as ral;
@ -73,29 +74,6 @@ macro_rules! create_imxrt_gpt2_token {
    }};
 }
 // Credits to the `time-driver` of `embassy-stm32`.
 //
 // Clock timekeeping works with something we call "periods", which are time intervals
 // of 2^31 ticks. The Clock counter value is 32 bits, so one "overflow cycle" is 2 periods.
 //
 // A `period` count is maintained in parallel to the Timer hardware `counter`, like this:
 // - `period` and `counter` start at 0
 // - `period` is incremented on overflow (at counter value 0)
 // - `period` is incremented "midway" between overflows (at counter value 0x8000_0000)
 //
 // Therefore, when `period` is even, counter is in 0..0x7FFF_FFFF. When odd, counter is in 0x8000_0000..0xFFFF_FFFF
 // This allows for now() to return the correct value even if it races an overflow.
 //
 // To get `now()`, `period` is read first, then `counter` is read. If the counter value matches
 // the expected range for the `period` parity, we're done. If it doesn't, this means that
 // a new period start has raced us between reading `period` and `counter`, so we assume the `counter` value
 // corresponds to the next period.
 //
 // `period` is a 32bit integer, so it overflows on 2^32 * 2^31 / 1_000_000 seconds of uptime, which is 292471 years.
 fn calc_now(period: u32, counter: u32) -> u64 {
    (u64::from(period) << 31) + u64::from(counter ^ ((period & 1) << 31))
 }
 macro_rules! make_timer {
    ($mono_name:ident, $timer:ident, $period:ident, $tq:ident$(, doc: ($($doc:tt)*))?) => {
        /// Timer implementing [`Monotonic`] which runs at 1 MHz.
@ -142,7 +120,7 @@ macro_rules! make_timer {
                );
                // Reset period
-                $period.store(0, Ordering::Relaxed);
+                $period.store(0, Ordering::SeqCst);
                // Prescaler
                ral::modify_reg!(ral::gpt, gpt, PR,
@ -231,12 +209,10 @@ macro_rules! make_timer {
            fn now() -> Self::Instant {
                let gpt = unsafe{ $timer::instance() };
-                // Important: period **must** be read first.
+                Self::Instant::from_ticks(calculate_now(
-                let period = $period.load(Ordering::Relaxed);
+                    $period.load(Ordering::Relaxed),
-                compiler_fence(Ordering::Acquire);
+                    || ral::read_reg!(ral::gpt, gpt, CNT)
-                let counter = ral::read_reg!(ral::gpt, gpt, CNT);
+                ))
                Self::Instant::from_ticks(calc_now(period, counter))
            }
            fn set_compare(instant: Self::Instant) {
--- a/rtic-monotonics/src/stm32.rs
+++ b/rtic-monotonics/src/stm32.rs
@ -35,8 +35,9 @@
 //! ```
 use crate::{Monotonic, TimeoutError, TimerQueue};
-use atomic_polyfill::{compiler_fence, AtomicU64, Ordering};
+use atomic_polyfill::{AtomicU64, Ordering};
 pub use fugit::{self, ExtU64, ExtU64Ceil};
 use rtic_time::half_period_counter::calculate_now;
 use stm32_metapac as pac;
 mod _generated {
@ -166,13 +167,14 @@ macro_rules! make_timer {
                // Since this is not the case, it should be cleared.
                $timer.sr().modify(|r| r.set_uif(false));
                $tq.initialize(Self {});
                $overflow.store(0, Ordering::SeqCst);
                // Start the counter.
                $timer.cr1().modify(|r| {
                    r.set_cen(true);
                });
                $tq.initialize(Self {});
                // SAFETY: We take full ownership of the peripheral and interrupt vector,
                // plus we are not using any external shared resources so we won't impact
                // basepri/source masking based critical sections.
@ -231,18 +233,10 @@ macro_rules! make_timer {
            const TICK_PERIOD: Self::Duration = Self::Duration::from_ticks(1);
            fn now() -> Self::Instant {
-                // Credits to the `time-driver` of `embassy-stm32`.
+                Self::Instant::from_ticks(calculate_now(
-                // For more info, see the `imxrt` driver.
+                    $overflow.load(Ordering::Relaxed),
-                fn calc_now(period: u64, counter: $bits) -> u64 {
+                    || $timer.cnt().read().cnt()
-                    (period << ($bits::BITS - 1)) + u64::from(counter ^ (((period & 1) as $bits) << ($bits::BITS - 1)))
+                ))
                }
                // Important: period **must** be read first.
                let period = $overflow.load(Ordering::Relaxed);
                compiler_fence(Ordering::Acquire);
                let counter = $timer.cnt().read().cnt();
                Self::Instant::from_ticks(calc_now(period, counter))
            }
            fn set_compare(instant: Self::Instant) {
--- a/rtic-time/CHANGELOG.md
+++ b/rtic-time/CHANGELOG.md
@ -9,7 +9,8 @@ For each category, *Added*, *Changed*, *Fixed* add new entries at the top!
 ### Added
- `should_dequeue` to the `Monotonic` trait to handle bugged timers
+- `half_period_counter` containing utilities for implementing a half-period-counter based monotonic.
 - `should_dequeue_check` to the `Monotonic` trait to handle bugged timers.
 ### Changed
--- a/rtic-time/Cargo.toml
+++ b/rtic-time/Cargo.toml
@ -1,6 +1,6 @@
 [package]
 name = "rtic-time"
-version = "1.0.0"
+version = "1.1.0"
 edition = "2021"
 authors = [
--- a/rtic-time/src/half_period_counter.rs
+++ b/rtic-time/src/half_period_counter.rs
@ -0,0 +1,229 @@
 //! Utility to implement a race condition free half-period based monotonic.
 //!
 //! # Background
 //!
 //! Monotonics are continuous and never wrap (in a reasonable amount of time), while
 //! the underlying hardware usually wraps frequently and has interrupts to indicate that
 //! a wrap happened.
 //!
 //! The biggest problem when implementing a monotonic from such hardware is that there exists
 //! a non-trivial race condition while reading data from the timer. Let's assume we increment
 //! a period counter every time an overflow interrupt happens.
 //! Which should we then read first when computing the current time? The period counter or
 //! the timer value?
 //! - When reading the timer value first, an overflow interrupt could happen before we read
 //!   the period counter, causing the calculated time to be much too high
 //! - When reading the period counter first, the timer value could overflow before we
 //!   read it, causing the calculated time to be much too low
 //!
 //! The reason this is non-trivil to solve is because even critical sections do not help
 //! much - the inherent problem here is that the timer value continues to change, and there
 //! is no way to read it together with the period counter in an atomic way.
 //!
 //! # Solution
 //!
 //! This module provides utilities to solve this problem in a reliable, race-condition free way.
 //! A second interrupt must be added at the half-period mark, which effectively converts the period counter
 //! to a half-period counter. This creates one bit of overlap between the
 //! timer value and the period counter, which makes it mathematically possible to solve the
 //! race condition.
 //!
 //! The following steps have to be fulfilled to make this reliable:
 //! - The period counter gets incremented twice per period; once when the timer overflow happens and once
 //!   at the half-period mark. For example, a 16-bit timer would require the period counter to be
 //!   incremented at the values `0x0000` and `0x8000`.
 //! - The timer value and the period counter must be in sync. After the overflow interrupt
 //!   was processed, the period counter must be even, and after the half-way interrupt was
 //!   processed, the period counter must be odd.
 //! - Both the overflow interrupt and the half-way interrupt must be processed within half a
 //!   timer period. This means those interrupts should be the highest priority in the
 //!   system - disabling them for more than half a period will cause the monotonic to misbehave.
 //!
 //! If those conditions are fulfilled, the [`calculate_now`] function will reliably
 //! return the correct time value.
 //!
 //! # Why does this work?
 //!
 //! It's complicated. In essence, this one bit of overlap gets used to make
 //! it irrelevant whether the period counter was already incremented or not.
 //! For example, during the second part of the timer period, it is irrelevant if the
 //! period counter is `2` (before the interrupt) or `3` (after the interrupt) - [`calculate_now`]
 //! will yield the same result. Then half a period later, in the first part of the next timer period,
 //! it is irrelevant if the period counter is `3` or `4` - they again will yield the same result.
 //!
 //! This means that as long as we read the period counter **before** the timer value, we will
 //! always get the correct result, given that the interrupts are not delayed by more than half a period.
 //!
 //! # Example
 //!
 //! This example takes a 16-bit timer and uses a 32-bit period counter
 //! to extend the timer to 47-bit. Note that one bit gets lost because
 //! this method requires the period counter to be increased twice per period.
 //!
 //! The resulting time value is returned as a `u64`.
 //!
 //! ```rust
 //! # fn timer_stop() {}
 //! # fn timer_reset() {}
 //! # fn timer_enable_overflow_interrupt() {}
 //! # fn timer_enable_compare_interrupt(_val: u16) {}
 //! # fn timer_start() {}
 //! # fn overflow_interrupt_happened() -> bool { false }
 //! # fn compare_interrupt_happened() -> bool { false }
 //! # fn clear_overflow_interrupt() {}
 //! # fn clear_compare_interrupt() {}
 //! # fn timer_get_value() -> u16 { 0 }
 //! use core::sync::atomic::{AtomicU32, Ordering};
 //!
 //! static HALF_PERIOD_COUNTER: AtomicU32 = AtomicU32::new(0);
 //!
 //! struct MyMonotonic;
 //!
 //! impl MyMonotonic {
 //!     fn init() {
 //!         timer_stop();
 //!         timer_reset();
 //!         HALF_PERIOD_COUNTER.store(0, Ordering::SeqCst);
 //!         timer_enable_overflow_interrupt();
 //!         timer_enable_compare_interrupt(0x8000);
 //!         // Both the period counter and the timer are reset
 //!         // to zero and the interrupts are enabled.
 //!         // This means the period counter and the timer value
 //!         // are in sync, so we can now enable the timer.
 //!         timer_start();
 //!     }
 //!
 //!     fn on_interrupt() {
 //!         if overflow_interrupt_happened() {
 //!             clear_overflow_interrupt();
 //!             HALF_PERIOD_COUNTER.fetch_add(1, Ordering::Relaxed);
 //!         }
 //!         if compare_interrupt_happened() {
 //!             clear_compare_interrupt();
 //!             HALF_PERIOD_COUNTER.fetch_add(1, Ordering::Relaxed);
 //!         }
 //!     }
 //!
 //!     fn now() -> u64 {
 //!         rtic_time::half_period_counter::calculate_now(
 //!             HALF_PERIOD_COUNTER.load(Ordering::Relaxed),
 //!             || timer_get_value(),
 //!         )
 //!     }
 //! }
 //! ```
 //!
 use core::sync::atomic::{compiler_fence, Ordering};
 /// The value of the timer's count register.
 pub trait TimerValue {
    /// Bit size of the timer. Does not need to be a multiple of `8`.
    const BITS: u32;
 }
 macro_rules! impl_timer_value {
    ($t:ty) => {
        impl TimerValue for $t {
            const BITS: u32 = Self::BITS;
        }
    };
 }
 impl_timer_value!(u8);
 impl_timer_value!(u16);
 impl_timer_value!(u32);
 impl_timer_value!(u64);
 /// Operations a type has to support
 /// in order to be used as the return value
 /// of [`calculate_now`].
 pub trait TimerOps: Copy {
    /// All bits set to `1`.
    const MAX: Self;
    /// The lowest bit set to `1`.
    const ONE: Self;
    /// The `^` operation.
    fn xor(self, other: Self) -> Self;
    /// The `&` operation.
    fn and(self, other: Self) -> Self;
    /// The `+` operation.
    fn add(self, other: Self) -> Self;
    /// The `<<` operation.
    fn left_shift(self, amount: u32) -> Self;
 }
 macro_rules! impl_timer_ops {
    ($t:ty) => {
        impl TimerOps for $t {
            const MAX: Self = Self::MAX;
            const ONE: Self = 1;
            #[inline]
            fn xor(self, other: Self) -> Self {
                self ^ other
            }
            #[inline]
            fn and(self, other: Self) -> Self {
                self & other
            }
            #[inline]
            fn add(self, other: Self) -> Self {
                self + other
            }
            #[inline]
            fn left_shift(self, amount: u32) -> Self {
                self << amount
            }
        }
    };
 }
 impl_timer_ops!(u16);
 impl_timer_ops!(u32);
 impl_timer_ops!(u64);
 impl_timer_ops!(u128);
 /// Calculates the current time from the half period counter and the timer value.
 ///
 /// # Arguments
 ///
 /// * `half_periods` - The period counter value. If read from an atomic, can use `Ordering::Relaxed`.
 /// * `timer_value` - A closure/function that when called produces the current timer value.
 pub fn calculate_now<P, T, F, O>(half_periods: P, timer_value: F) -> O
 where
    T: TimerValue,
    O: From<P> + From<T> + TimerOps,
    F: FnOnce() -> T,
 {
    // Important: half_period **must** be read first.
    // Otherwise we have another mathematical race condition.
    let half_periods = O::from(half_periods);
    compiler_fence(Ordering::Acquire);
    let timer_value = O::from(timer_value());
    // Credits to the `time-driver` of `embassy-stm32`.
    //
    // Given that our clock counter value is 32 bits.
    //
    // Clock timekeeping works with something we call "periods", which are time intervals
    // of 2^31 ticks. The Clock counter value is 32 bits, so one "overflow cycle" is 2 periods.
    //
    // A `period` count is maintained in parallel to the Timer hardware `counter`, like this:
    // - `period` and `counter` start at 0
    // - `period` is incremented on overflow (at counter value 0)
    // - `period` is incremented "midway" between overflows (at counter value 0x8000_0000)
    //
    // Therefore, when `period` is even, counter is in 0..0x7FFF_FFFF. When odd, counter is in 0x8000_0000..0xFFFF_FFFF
    // This allows for now() to return the correct value even if it races an overflow.
    //
    // To get `now()`, `period` is read first, then `counter` is read. If the counter value matches
    // the expected range for the `period` parity, we're done. If it doesn't, this means that
    // a new period start has raced us between reading `period` and `counter`, so we assume the `counter` value
    // corresponds to the next period.
    let upper_half = half_periods.left_shift(T::BITS - 1);
    let lower_half = O::ONE.left_shift(T::BITS - 1).and(upper_half);
    upper_half.add(lower_half.xor(timer_value))
 }
--- a/rtic-time/src/lib.rs
+++ b/rtic-time/src/lib.rs
@ -19,6 +19,7 @@ use linked_list::{Link, LinkedList};
 pub use monotonic::Monotonic;
 use rtic_common::dropper::OnDrop;
 pub mod half_period_counter;
 mod linked_list;
 mod monotonic;
--- a/rtic-time/tests/half_period_time_counter.rs
+++ b/rtic-time/tests/half_period_time_counter.rs
@ -0,0 +1,95 @@
 use rtic_time::half_period_counter::calculate_now;
 macro_rules! do_test_u8 {
    ($periods:literal, $counter:literal, $expected:literal) => {{
        let periods: u32 = $periods;
        let counter: u8 = $counter;
        let expected: u32 = $expected;
        let actual: u32 = calculate_now(periods, || counter);
        assert_eq!(
            actual, expected,
            "Expected: ({} | {}) => {}, got: {}",
            periods, counter, expected, actual
        );
    }};
 }
 macro_rules! do_test_u16 {
    ($periods:literal, $counter:literal, $expected:literal) => {{
        let periods: u16 = $periods;
        let counter: u16 = $counter;
        let expected: u32 = $expected;
        let actual: u32 = calculate_now(periods, || counter);
        assert_eq!(
            actual, expected,
            "Expected: ({} | {}) => {}, got: {}",
            periods, counter, expected, actual
        );
    }};
 }
 #[test]
 fn half_period_time_counter_u8() {
    do_test_u8!(0, 0, 0);
    do_test_u8!(0, 1, 1);
    do_test_u8!(0, 126, 126);
    do_test_u8!(1, 126, 382); // This is why it's important to load the periods before the counter
    do_test_u8!(0, 127, 127);
    do_test_u8!(1, 127, 383);
    do_test_u8!(0, 128, 128);
    do_test_u8!(1, 128, 128);
    do_test_u8!(0, 129, 129);
    do_test_u8!(1, 129, 129);
    do_test_u8!(1, 254, 254);
    do_test_u8!(2, 254, 510);
    do_test_u8!(1, 255, 255);
    do_test_u8!(2, 255, 511);
    do_test_u8!(1, 0, 256);
    do_test_u8!(2, 0, 256);
    do_test_u8!(1, 1, 257);
    do_test_u8!(2, 1, 257);
    do_test_u8!(2, 126, 382);
    do_test_u8!(3, 126, 638);
    do_test_u8!(2, 127, 383);
    do_test_u8!(3, 127, 639);
    do_test_u8!(2, 128, 384);
    do_test_u8!(3, 128, 384);
    do_test_u8!(2, 129, 385);
    do_test_u8!(3, 129, 385);
 }
 #[test]
 fn half_period_time_counter_u16() {
    do_test_u16!(0, 0, 0);
    do_test_u16!(0, 1, 1);
    do_test_u16!(0, 32766, 32766);
    do_test_u16!(1, 32766, 98302); // This is why it's important to load the periods before the counter
    do_test_u16!(0, 32767, 32767);
    do_test_u16!(1, 32767, 98303);
    do_test_u16!(0, 32768, 32768);
    do_test_u16!(1, 32768, 32768);
    do_test_u16!(0, 32769, 32769);
    do_test_u16!(1, 32769, 32769);
    do_test_u16!(1, 65534, 65534);
    do_test_u16!(2, 65534, 131070);
    do_test_u16!(1, 65535, 65535);
    do_test_u16!(2, 65535, 131071);
    do_test_u16!(1, 0, 65536);
    do_test_u16!(2, 0, 65536);
    do_test_u16!(1, 1, 65537);
    do_test_u16!(2, 1, 65537);
    do_test_u16!(2, 32766, 98302);
    do_test_u16!(3, 32766, 163838);
    do_test_u16!(2, 32767, 98303);
    do_test_u16!(3, 32767, 163839);
    do_test_u16!(2, 32768, 98304);
    do_test_u16!(3, 32768, 98304);
    do_test_u16!(2, 32769, 98305);
    do_test_u16!(3, 32769, 98305);
 }
--- a/xtask/src/argument_parsing.rs
+++ b/xtask/src/argument_parsing.rs
@ -79,6 +79,7 @@ impl Package {
                        "nrf5340-app,embedded-hal-async",
                        "nrf5340-net,embedded-hal-async",
                        "nrf9160,embedded-hal-async",
                        "imxrt_gpt1,imxrt-ral/imxrt1062,embedded-hal-async",
                    ][..]
                };