//! The [`Instant`] struct and its associated `impl`s. use core::borrow::Borrow; use core::cmp::{Ord, Ordering, PartialEq, PartialOrd}; use core::ops::{Add, Sub}; use core::time::Duration as StdDuration; use std::time::Instant as StdInstant; use crate::Duration; /// A measurement of a monotonically non-decreasing clock. Opaque and useful only with [`Duration`]. /// /// Instants are always guaranteed to be no less than any previously measured instant when created, /// and are often useful for tasks such as measuring benchmarks or timing how long an operation /// takes. /// /// Note, however, that instants are not guaranteed to be **steady**. In other words, each tick of /// the underlying clock may not be the same length (e.g. some seconds may be longer than others). /// An instant may jump forwards or experience time dilation (slow down or speed up), but it will /// never go backwards. /// /// Instants are opaque types that can only be compared to one another. There is no method to get /// "the number of seconds" from an instant. Instead, it only allows measuring the duration between /// two instants (or comparing two instants). /// /// This implementation allows for operations with signed [`Duration`]s, but is otherwise identical /// to [`std::time::Instant`]. #[repr(transparent)] #[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)] pub struct Instant(pub StdInstant); impl Instant { // region: delegation /// Returns an `Instant` corresponding to "now". /// /// ```rust /// # use time::Instant; /// println!("{:?}", Instant::now()); /// ``` pub fn now() -> Self { Self(StdInstant::now()) } /// Returns the amount of time elapsed since this instant was created. The duration will always /// be nonnegative if the instant is not synthetically created. /// /// ```rust /// # use time::{Instant, ext::{NumericalStdDuration, NumericalDuration}}; /// # use std::thread; /// let instant = Instant::now(); /// thread::sleep(1.std_milliseconds()); /// assert!(instant.elapsed() >= 1.milliseconds()); /// ``` pub fn elapsed(self) -> Duration { Self::now() - self } // endregion delegation // region: checked arithmetic /// Returns `Some(t)` where `t` is the time `self + duration` if `t` can be represented as /// `Instant` (which means it's inside the bounds of the underlying data structure), `None` /// otherwise. /// /// ```rust /// # use time::{Instant, ext::NumericalDuration}; /// let now = Instant::now(); /// assert_eq!(now.checked_add(5.seconds()), Some(now + 5.seconds())); /// assert_eq!(now.checked_add((-5).seconds()), Some(now + (-5).seconds())); /// ``` pub fn checked_add(self, duration: Duration) -> Option { if duration.is_zero() { Some(self) } else if duration.is_positive() { self.0.checked_add(duration.unsigned_abs()).map(Self) } else { debug_assert!(duration.is_negative()); self.0.checked_sub(duration.unsigned_abs()).map(Self) } } /// Returns `Some(t)` where `t` is the time `self - duration` if `t` can be represented as /// `Instant` (which means it's inside the bounds of the underlying data structure), `None` /// otherwise. /// /// ```rust /// # use time::{Instant, ext::NumericalDuration}; /// let now = Instant::now(); /// assert_eq!(now.checked_sub(5.seconds()), Some(now - 5.seconds())); /// assert_eq!(now.checked_sub((-5).seconds()), Some(now - (-5).seconds())); /// ``` pub fn checked_sub(self, duration: Duration) -> Option { if duration.is_zero() { Some(self) } else if duration.is_positive() { self.0.checked_sub(duration.unsigned_abs()).map(Self) } else { debug_assert!(duration.is_negative()); self.0.checked_add(duration.unsigned_abs()).map(Self) } } // endregion checked arithmetic /// Obtain the inner [`std::time::Instant`]. /// /// ```rust /// # use time::Instant; /// let now = Instant::now(); /// assert_eq!(now.into_inner(), now.0); /// ``` pub const fn into_inner(self) -> StdInstant { self.0 } } // region: trait impls impl From for Instant { fn from(instant: StdInstant) -> Self { Self(instant) } } impl From for StdInstant { fn from(instant: Instant) -> Self { instant.0 } } impl Sub for Instant { type Output = Duration; fn sub(self, other: Self) -> Self::Output { match self.0.cmp(&other.0) { Ordering::Equal => Duration::ZERO, Ordering::Greater => (self.0 - other.0) .try_into() .expect("overflow converting `std::time::Duration` to `time::Duration`"), Ordering::Less => -Duration::try_from(other.0 - self.0) .expect("overflow converting `std::time::Duration` to `time::Duration`"), } } } impl Sub for Instant { type Output = Duration; fn sub(self, other: StdInstant) -> Self::Output { self - Self(other) } } impl Sub for StdInstant { type Output = Duration; fn sub(self, other: Instant) -> Self::Output { Instant(self) - other } } impl Add for Instant { type Output = Self; fn add(self, duration: Duration) -> Self::Output { if duration.is_positive() { Self(self.0 + duration.unsigned_abs()) } else if duration.is_negative() { Self(self.0 - duration.unsigned_abs()) } else { debug_assert!(duration.is_zero()); self } } } impl Add for StdInstant { type Output = Self; fn add(self, duration: Duration) -> Self::Output { (Instant(self) + duration).0 } } impl Add for Instant { type Output = Self; fn add(self, duration: StdDuration) -> Self::Output { Self(self.0 + duration) } } impl_add_assign!(Instant: Duration, StdDuration); impl_add_assign!(StdInstant: Duration); impl Sub for Instant { type Output = Self; fn sub(self, duration: Duration) -> Self::Output { if duration.is_positive() { Self(self.0 - duration.unsigned_abs()) } else if duration.is_negative() { Self(self.0 + duration.unsigned_abs()) } else { debug_assert!(duration.is_zero()); self } } } impl Sub for StdInstant { type Output = Self; fn sub(self, duration: Duration) -> Self::Output { (Instant(self) - duration).0 } } impl Sub for Instant { type Output = Self; fn sub(self, duration: StdDuration) -> Self::Output { Self(self.0 - duration) } } impl_sub_assign!(Instant: Duration, StdDuration); impl_sub_assign!(StdInstant: Duration); impl PartialEq for Instant { fn eq(&self, rhs: &StdInstant) -> bool { self.0.eq(rhs) } } impl PartialEq for StdInstant { fn eq(&self, rhs: &Instant) -> bool { self.eq(&rhs.0) } } impl PartialOrd for Instant { fn partial_cmp(&self, rhs: &StdInstant) -> Option { self.0.partial_cmp(rhs) } } impl PartialOrd for StdInstant { fn partial_cmp(&self, rhs: &Instant) -> Option { self.partial_cmp(&rhs.0) } } impl AsRef for Instant { fn as_ref(&self) -> &StdInstant { &self.0 } } impl Borrow for Instant { fn borrow(&self) -> &StdInstant { &self.0 } } // endregion trait impls