linux-x86/1.37.0/src/stdlibs/src/libstd/sys/windows/time.rs - platform/prebuilts/rust - Git at Google

 use crate::cmp::Ordering;
 use crate::fmt;
 use crate::mem;
 use crate::sys::c;
 use crate::time::Duration;
 use crate::convert::TryInto;

 use core::hash::{Hash, Hasher};

 const NANOS_PER_SEC: u64 = 1_000_000_000;
 const INTERVALS_PER_SEC: u64 = NANOS_PER_SEC / 100;

 #[derive(Copy, Clone, Eq, PartialEq, Ord, PartialOrd, Debug, Hash)]
 pub struct Instant {
     // This duration is relative to an arbitrary microsecond epoch
     // from the winapi QueryPerformanceCounter function.
     t: Duration,
 }

 #[derive(Copy, Clone)]
 pub struct SystemTime {
     t: c::FILETIME,
 }

 const INTERVALS_TO_UNIX_EPOCH: u64 = 11_644_473_600 * INTERVALS_PER_SEC;

 pub const UNIX_EPOCH: SystemTime = SystemTime {
     t: c::FILETIME {
         dwLowDateTime: INTERVALS_TO_UNIX_EPOCH as u32,
         dwHighDateTime: (INTERVALS_TO_UNIX_EPOCH >> 32) as u32,
     },
 };

 impl Instant {
     pub fn now() -> Instant {
         // High precision timing on windows operates in "Performance Counter"
         // units, as returned by the WINAPI QueryPerformanceCounter function.
         // These relate to seconds by a factor of QueryPerformanceFrequency.
         // In order to keep unit conversions out of normal interval math, we
         // measure in QPC units and immediately convert to nanoseconds.
         perf_counter::PerformanceCounterInstant::now().into()
     }

     pub fn actually_monotonic() -> bool {
         false
     }

     pub const fn zero() -> Instant {
         Instant { t: Duration::from_secs(0) }
     }

     pub fn checked_sub_instant(&self, other: &Instant) -> Option<Duration> {
         // On windows there's a threshold below which we consider two timestamps
         // equivalent due to measurement error. For more details + doc link,
         // check the docs on epsilon.
         let epsilon =
             perf_counter::PerformanceCounterInstant::epsilon();
         if other.t > self.t && other.t - self.t <= epsilon {
             Some(Duration::new(0, 0))
         } else {
             self.t.checked_sub(other.t)
         }
     }

     pub fn checked_add_duration(&self, other: &Duration) -> Option<Instant> {
         Some(Instant {
             t: self.t.checked_add(*other)?
         })
     }

     pub fn checked_sub_duration(&self, other: &Duration) -> Option<Instant> {
         Some(Instant {
             t: self.t.checked_sub(*other)?
         })
     }
 }

 impl SystemTime {
     pub fn now() -> SystemTime {
         unsafe {
             let mut t: SystemTime = mem::zeroed();
             c::GetSystemTimeAsFileTime(&mut t.t);
             return t
         }
     }

     fn from_intervals(intervals: i64) -> SystemTime {
         SystemTime {
             t: c::FILETIME {
                 dwLowDateTime: intervals as c::DWORD,
                 dwHighDateTime: (intervals >> 32) as c::DWORD,
             }
         }
     }

     fn intervals(&self) -> i64 {
         (self.t.dwLowDateTime as i64) | ((self.t.dwHighDateTime as i64) << 32)
     }

     pub fn sub_time(&self, other: &SystemTime) -> Result<Duration, Duration> {
         let me = self.intervals();
         let other = other.intervals();
         if me >= other {
             Ok(intervals2dur((me - other) as u64))
         } else {
             Err(intervals2dur((other - me) as u64))
         }
     }

     pub fn checked_add_duration(&self, other: &Duration) -> Option<SystemTime> {
         let intervals = self.intervals().checked_add(checked_dur2intervals(other)?)?;
         Some(SystemTime::from_intervals(intervals))
     }

     pub fn checked_sub_duration(&self, other: &Duration) -> Option<SystemTime> {
         let intervals = self.intervals().checked_sub(checked_dur2intervals(other)?)?;
         Some(SystemTime::from_intervals(intervals))
     }
 }

 impl PartialEq for SystemTime {
     fn eq(&self, other: &SystemTime) -> bool {
         self.intervals() == other.intervals()
     }
 }

 impl Eq for SystemTime {}

 impl PartialOrd for SystemTime {
     fn partial_cmp(&self, other: &SystemTime) -> Option<Ordering> {
         Some(self.cmp(other))
     }
 }

 impl Ord for SystemTime {
     fn cmp(&self, other: &SystemTime) -> Ordering {
         self.intervals().cmp(&other.intervals())
     }
 }

 impl fmt::Debug for SystemTime {
     fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
         f.debug_struct("SystemTime")
          .field("intervals", &self.intervals())
          .finish()
     }
 }

 impl From<c::FILETIME> for SystemTime {
     fn from(t: c::FILETIME) -> SystemTime {
         SystemTime { t }
     }
 }

 impl Hash for SystemTime {
     fn hash<H : Hasher>(&self, state: &mut H) {
         self.intervals().hash(state)
     }
 }

 fn checked_dur2intervals(dur: &Duration) -> Option<i64> {
     dur.as_secs()
         .checked_mul(INTERVALS_PER_SEC)?
         .checked_add(dur.subsec_nanos() as u64 / 100)?
         .try_into()
         .ok()
 }

 fn intervals2dur(intervals: u64) -> Duration {
     Duration::new(intervals / INTERVALS_PER_SEC,
                   ((intervals % INTERVALS_PER_SEC) * 100) as u32)
 }

 mod perf_counter {
     use super::{NANOS_PER_SEC};
     use crate::sync::atomic::{AtomicUsize, Ordering::SeqCst};
     use crate::sys_common::mul_div_u64;
     use crate::sys::c;
     use crate::sys::cvt;
     use crate::time::Duration;

     pub struct PerformanceCounterInstant {
         ts: c::LARGE_INTEGER
     }
     impl PerformanceCounterInstant {
         pub fn now() -> Self {
             Self {
                 ts: query()
             }
         }

         // Per microsoft docs, the margin of error for cross-thread time comparisons
         // using QueryPerformanceCounter is 1 "tick" -- defined as 1/frequency().
         // Reference: https://docs.microsoft.com/en-us/windows/desktop/SysInfo
         //                   /acquiring-high-resolution-time-stamps
         pub fn epsilon() -> Duration {
             let epsilon = NANOS_PER_SEC / (frequency() as u64);
             Duration::from_nanos(epsilon)
         }
     }
     impl From<PerformanceCounterInstant> for super::Instant {
         fn from(other: PerformanceCounterInstant) -> Self {
             let freq = frequency() as u64;
             let instant_nsec = mul_div_u64(other.ts as u64, NANOS_PER_SEC, freq);
             Self {
                 t: Duration::from_nanos(instant_nsec)
             }
         }
     }

     fn frequency() -> c::LARGE_INTEGER {
         static mut FREQUENCY: c::LARGE_INTEGER = 0;
         static STATE: AtomicUsize = AtomicUsize::new(0);

         unsafe {
             // If a previous thread has filled in this global state, use that.
             if STATE.load(SeqCst) == 2 {
                 return FREQUENCY;
             }

             // ... otherwise learn for ourselves ...
             let mut frequency = 0;
             cvt(c::QueryPerformanceFrequency(&mut frequency)).unwrap();

             // ... and attempt to be the one thread that stores it globally for
             // all other threads
             if STATE.compare_exchange(0, 1, SeqCst, SeqCst).is_ok() {
                 FREQUENCY = frequency;
                 STATE.store(2, SeqCst);
             }
             return frequency;
         }
     }

     fn query() -> c::LARGE_INTEGER {
         let mut qpc_value: c::LARGE_INTEGER = 0;
         cvt(unsafe {
             c::QueryPerformanceCounter(&mut qpc_value)
         }).unwrap();
         qpc_value
     }
 }
	use crate::cmp::Ordering;
	use crate::fmt;
	use crate::mem;
	use crate::sys::c;
	use crate::time::Duration;
	use crate::convert::TryInto;

	use core::hash::{Hash, Hasher};

	const NANOS_PER_SEC: u64 = 1_000_000_000;
	const INTERVALS_PER_SEC: u64 = NANOS_PER_SEC / 100;

	#[derive(Copy, Clone, Eq, PartialEq, Ord, PartialOrd, Debug, Hash)]
	pub struct Instant {
	// This duration is relative to an arbitrary microsecond epoch
	// from the winapi QueryPerformanceCounter function.
	t: Duration,
	}

	#[derive(Copy, Clone)]
	pub struct SystemTime {
	t: c::FILETIME,
	}

	const INTERVALS_TO_UNIX_EPOCH: u64 = 11_644_473_600 * INTERVALS_PER_SEC;

	pub const UNIX_EPOCH: SystemTime = SystemTime {
	t: c::FILETIME {
	dwLowDateTime: INTERVALS_TO_UNIX_EPOCH as u32,
	dwHighDateTime: (INTERVALS_TO_UNIX_EPOCH >> 32) as u32,
	},
	};

	impl Instant {
	pub fn now() -> Instant {
	// High precision timing on windows operates in "Performance Counter"
	// units, as returned by the WINAPI QueryPerformanceCounter function.
	// These relate to seconds by a factor of QueryPerformanceFrequency.
	// In order to keep unit conversions out of normal interval math, we
	// measure in QPC units and immediately convert to nanoseconds.
	perf_counter::PerformanceCounterInstant::now().into()
	}

	pub fn actually_monotonic() -> bool {
	false
	}

	pub const fn zero() -> Instant {
	Instant { t: Duration::from_secs(0) }
	}

	pub fn checked_sub_instant(&self, other: &Instant) -> Option<Duration> {
	// On windows there's a threshold below which we consider two timestamps
	// equivalent due to measurement error. For more details + doc link,
	// check the docs on epsilon.
	let epsilon =
	perf_counter::PerformanceCounterInstant::epsilon();
	if other.t > self.t && other.t - self.t <= epsilon {
	Some(Duration::new(0, 0))
	} else {
	self.t.checked_sub(other.t)
	}
	}

	pub fn checked_add_duration(&self, other: &Duration) -> Option<Instant> {
	Some(Instant {
	t: self.t.checked_add(*other)?
	})
	}

	pub fn checked_sub_duration(&self, other: &Duration) -> Option<Instant> {
	Some(Instant {
	t: self.t.checked_sub(*other)?
	})
	}
	}

	impl SystemTime {
	pub fn now() -> SystemTime {
	unsafe {
	let mut t: SystemTime = mem::zeroed();
	c::GetSystemTimeAsFileTime(&mut t.t);
	return t
	}
	}

	fn from_intervals(intervals: i64) -> SystemTime {
	SystemTime {
	t: c::FILETIME {
	dwLowDateTime: intervals as c::DWORD,
	dwHighDateTime: (intervals >> 32) as c::DWORD,
	}
	}
	}

	fn intervals(&self) -> i64 {
	(self.t.dwLowDateTime as i64) \| ((self.t.dwHighDateTime as i64) << 32)
	}

	pub fn sub_time(&self, other: &SystemTime) -> Result<Duration, Duration> {
	let me = self.intervals();
	let other = other.intervals();
	if me >= other {
	Ok(intervals2dur((me - other) as u64))
	} else {
	Err(intervals2dur((other - me) as u64))
	}
	}

	pub fn checked_add_duration(&self, other: &Duration) -> Option<SystemTime> {
	let intervals = self.intervals().checked_add(checked_dur2intervals(other)?)?;
	Some(SystemTime::from_intervals(intervals))
	}

	pub fn checked_sub_duration(&self, other: &Duration) -> Option<SystemTime> {
	let intervals = self.intervals().checked_sub(checked_dur2intervals(other)?)?;
	Some(SystemTime::from_intervals(intervals))
	}
	}

	impl PartialEq for SystemTime {
	fn eq(&self, other: &SystemTime) -> bool {
	self.intervals() == other.intervals()
	}
	}

	impl Eq for SystemTime {}

	impl PartialOrd for SystemTime {
	fn partial_cmp(&self, other: &SystemTime) -> Option<Ordering> {
	Some(self.cmp(other))
	}
	}

	impl Ord for SystemTime {
	fn cmp(&self, other: &SystemTime) -> Ordering {
	self.intervals().cmp(&other.intervals())
	}
	}

	impl fmt::Debug for SystemTime {
	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
	f.debug_struct("SystemTime")
	.field("intervals", &self.intervals())
	.finish()
	}
	}

	impl From<c::FILETIME> for SystemTime {
	fn from(t: c::FILETIME) -> SystemTime {
	SystemTime { t }
	}
	}

	impl Hash for SystemTime {
	fn hash<H : Hasher>(&self, state: &mut H) {
	self.intervals().hash(state)
	}
	}

	fn checked_dur2intervals(dur: &Duration) -> Option<i64> {
	dur.as_secs()
	.checked_mul(INTERVALS_PER_SEC)?
	.checked_add(dur.subsec_nanos() as u64 / 100)?
	.try_into()
	.ok()
	}

	fn intervals2dur(intervals: u64) -> Duration {
	Duration::new(intervals / INTERVALS_PER_SEC,
	((intervals % INTERVALS_PER_SEC) * 100) as u32)
	}

	mod perf_counter {
	use super::{NANOS_PER_SEC};
	use crate::sync::atomic::{AtomicUsize, Ordering::SeqCst};
	use crate::sys_common::mul_div_u64;
	use crate::sys::c;
	use crate::sys::cvt;
	use crate::time::Duration;

	pub struct PerformanceCounterInstant {
	ts: c::LARGE_INTEGER
	}
	impl PerformanceCounterInstant {
	pub fn now() -> Self {
	Self {
	ts: query()
	}
	}

	// Per microsoft docs, the margin of error for cross-thread time comparisons
	// using QueryPerformanceCounter is 1 "tick" -- defined as 1/frequency().
	// Reference: https://docs.microsoft.com/en-us/windows/desktop/SysInfo
	// /acquiring-high-resolution-time-stamps
	pub fn epsilon() -> Duration {
	let epsilon = NANOS_PER_SEC / (frequency() as u64);
	Duration::from_nanos(epsilon)
	}
	}
	impl From<PerformanceCounterInstant> for super::Instant {
	fn from(other: PerformanceCounterInstant) -> Self {
	let freq = frequency() as u64;
	let instant_nsec = mul_div_u64(other.ts as u64, NANOS_PER_SEC, freq);
	Self {
	t: Duration::from_nanos(instant_nsec)
	}
	}
	}

	fn frequency() -> c::LARGE_INTEGER {
	static mut FREQUENCY: c::LARGE_INTEGER = 0;
	static STATE: AtomicUsize = AtomicUsize::new(0);

	unsafe {
	// If a previous thread has filled in this global state, use that.
	if STATE.load(SeqCst) == 2 {
	return FREQUENCY;
	}

	// ... otherwise learn for ourselves ...
	let mut frequency = 0;
	cvt(c::QueryPerformanceFrequency(&mut frequency)).unwrap();

	// ... and attempt to be the one thread that stores it globally for
	// all other threads
	if STATE.compare_exchange(0, 1, SeqCst, SeqCst).is_ok() {
	FREQUENCY = frequency;
	STATE.store(2, SeqCst);
	}
	return frequency;
	}
	}

	fn query() -> c::LARGE_INTEGER {
	let mut qpc_value: c::LARGE_INTEGER = 0;
	cvt(unsafe {
	c::QueryPerformanceCounter(&mut qpc_value)
	}).unwrap();
	qpc_value
	}
	}