vendor/tokio-1.26.0/src/util/rand.rs - toolchain/rustc - Git at Google

 use std::cell::Cell;

 cfg_rt! {
     use std::sync::Mutex;

     /// A deterministic generator for seeds (and other generators).
     ///
     /// Given the same initial seed, the generator will output the same sequence of seeds.
     ///
     /// Since the seed generator will be kept in a runtime handle, we need to wrap `FastRand`
     /// in a Mutex to make it thread safe. Different to the `FastRand` that we keep in a
     /// thread local store, the expectation is that seed generation will not need to happen
     /// very frequently, so the cost of the mutex should be minimal.
     #[derive(Debug)]
     pub(crate) struct RngSeedGenerator {
         /// Internal state for the seed generator. We keep it in a Mutex so that we can safely
         /// use it across multiple threads.
         state: Mutex<FastRand>,
     }

     impl RngSeedGenerator {
         /// Returns a new generator from the provided seed.
         pub(crate) fn new(seed: RngSeed) -> Self {
             Self {
                 state: Mutex::new(FastRand::new(seed)),
             }
         }

         /// Returns the next seed in the sequence.
         pub(crate) fn next_seed(&self) -> RngSeed {
             let rng = self
                 .state
                 .lock()
                 .expect("RNG seed generator is internally corrupt");

             let s = rng.fastrand();
             let r = rng.fastrand();

             RngSeed::from_pair(s, r)
         }

         /// Directly creates a generator using the next seed.
         pub(crate) fn next_generator(&self) -> Self {
             RngSeedGenerator::new(self.next_seed())
         }
     }
 }

 /// A seed for random number generation.
 ///
 /// In order to make certain functions within a runtime deterministic, a seed
 /// can be specified at the time of creation.
 #[allow(unreachable_pub)]
 #[derive(Clone, Debug)]
 pub struct RngSeed {
     s: u32,
     r: u32,
 }

 impl RngSeed {
     /// Creates a random seed using loom internally.
     pub(crate) fn new() -> Self {
         Self::from_u64(crate::loom::rand::seed())
     }

     cfg_unstable! {
         /// Generates a seed from the provided byte slice.
         ///
         /// # Example
         ///
         /// ```
         /// # use tokio::runtime::RngSeed;
         /// let seed = RngSeed::from_bytes(b"make me a seed");
         /// ```
         #[cfg(feature = "rt")]
         pub fn from_bytes(bytes: &[u8]) -> Self {
             use std::{collections::hash_map::DefaultHasher, hash::Hasher};

             let mut hasher = DefaultHasher::default();
             hasher.write(bytes);
             Self::from_u64(hasher.finish())
         }
     }

     fn from_u64(seed: u64) -> Self {
         let one = (seed >> 32) as u32;
         let mut two = seed as u32;

         if two == 0 {
             // This value cannot be zero
             two = 1;
         }

         Self::from_pair(one, two)
     }

     fn from_pair(s: u32, r: u32) -> Self {
         Self { s, r }
     }
 }
 /// Fast random number generate.
 ///
 /// Implement xorshift64+: 2 32-bit xorshift sequences added together.
 /// Shift triplet `[17,7,16]` was calculated as indicated in Marsaglia's
 /// Xorshift paper: <https://www.jstatsoft.org/article/view/v008i14/xorshift.pdf>
 /// This generator passes the SmallCrush suite, part of TestU01 framework:
 /// <http://simul.iro.umontreal.ca/testu01/tu01.html>
 #[derive(Debug)]
 pub(crate) struct FastRand {
     one: Cell<u32>,
     two: Cell<u32>,
 }

 impl FastRand {
     /// Initializes a new, thread-local, fast random number generator.
     pub(crate) fn new(seed: RngSeed) -> FastRand {
         FastRand {
             one: Cell::new(seed.s),
             two: Cell::new(seed.r),
         }
     }

     /// Replaces the state of the random number generator with the provided seed, returning
     /// the seed that represents the previous state of the random number generator.
     ///
     /// The random number generator will become equivalent to one created with
     /// the same seed.
     #[cfg(feature = "rt")]
     pub(crate) fn replace_seed(&self, seed: RngSeed) -> RngSeed {
         let old_seed = RngSeed::from_pair(self.one.get(), self.two.get());

         self.one.replace(seed.s);
         self.two.replace(seed.r);

         old_seed
     }

     #[cfg(any(
         feature = "macros",
         feature = "rt-multi-thread",
         all(feature = "sync", feature = "rt")
     ))]
     pub(crate) fn fastrand_n(&self, n: u32) -> u32 {
         // This is similar to fastrand() % n, but faster.
         // See https://lemire.me/blog/2016/06/27/a-fast-alternative-to-the-modulo-reduction/
         let mul = (self.fastrand() as u64).wrapping_mul(n as u64);
         (mul >> 32) as u32
     }

     fn fastrand(&self) -> u32 {
         let mut s1 = self.one.get();
         let s0 = self.two.get();

         s1 ^= s1 << 17;
         s1 = s1 ^ s0 ^ s1 >> 7 ^ s0 >> 16;

         self.one.set(s0);
         self.two.set(s1);

         s0.wrapping_add(s1)
     }
 }
	use std::cell::Cell;

	cfg_rt! {
	use std::sync::Mutex;

	/// A deterministic generator for seeds (and other generators).
	///
	/// Given the same initial seed, the generator will output the same sequence of seeds.
	///
	/// Since the seed generator will be kept in a runtime handle, we need to wrap `FastRand`
	/// in a Mutex to make it thread safe. Different to the `FastRand` that we keep in a
	/// thread local store, the expectation is that seed generation will not need to happen
	/// very frequently, so the cost of the mutex should be minimal.
	#[derive(Debug)]
	pub(crate) struct RngSeedGenerator {
	/// Internal state for the seed generator. We keep it in a Mutex so that we can safely
	/// use it across multiple threads.
	state: Mutex<FastRand>,
	}

	impl RngSeedGenerator {
	/// Returns a new generator from the provided seed.
	pub(crate) fn new(seed: RngSeed) -> Self {
	Self {
	state: Mutex::new(FastRand::new(seed)),
	}
	}

	/// Returns the next seed in the sequence.
	pub(crate) fn next_seed(&self) -> RngSeed {
	let rng = self
	.state
	.lock()
	.expect("RNG seed generator is internally corrupt");

	let s = rng.fastrand();
	let r = rng.fastrand();

	RngSeed::from_pair(s, r)
	}

	/// Directly creates a generator using the next seed.
	pub(crate) fn next_generator(&self) -> Self {
	RngSeedGenerator::new(self.next_seed())
	}
	}
	}

	/// A seed for random number generation.
	///
	/// In order to make certain functions within a runtime deterministic, a seed
	/// can be specified at the time of creation.
	#[allow(unreachable_pub)]
	#[derive(Clone, Debug)]
	pub struct RngSeed {
	s: u32,
	r: u32,
	}

	impl RngSeed {
	/// Creates a random seed using loom internally.
	pub(crate) fn new() -> Self {
	Self::from_u64(crate::loom::rand::seed())
	}

	cfg_unstable! {
	/// Generates a seed from the provided byte slice.
	///
	/// # Example
	///
	/// ```
	/// # use tokio::runtime::RngSeed;
	/// let seed = RngSeed::from_bytes(b"make me a seed");
	/// ```
	#[cfg(feature = "rt")]
	pub fn from_bytes(bytes: &[u8]) -> Self {
	use std::{collections::hash_map::DefaultHasher, hash::Hasher};

	let mut hasher = DefaultHasher::default();
	hasher.write(bytes);
	Self::from_u64(hasher.finish())
	}
	}

	fn from_u64(seed: u64) -> Self {
	let one = (seed >> 32) as u32;
	let mut two = seed as u32;

	if two == 0 {
	// This value cannot be zero
	two = 1;
	}

	Self::from_pair(one, two)
	}

	fn from_pair(s: u32, r: u32) -> Self {
	Self { s, r }
	}
	}
	/// Fast random number generate.
	///
	/// Implement xorshift64+: 2 32-bit xorshift sequences added together.
	/// Shift triplet `[17,7,16]` was calculated as indicated in Marsaglia's
	/// Xorshift paper: <https://www.jstatsoft.org/article/view/v008i14/xorshift.pdf>
	/// This generator passes the SmallCrush suite, part of TestU01 framework:
	/// <http://simul.iro.umontreal.ca/testu01/tu01.html>
	#[derive(Debug)]
	pub(crate) struct FastRand {
	one: Cell<u32>,
	two: Cell<u32>,
	}

	impl FastRand {
	/// Initializes a new, thread-local, fast random number generator.
	pub(crate) fn new(seed: RngSeed) -> FastRand {
	FastRand {
	one: Cell::new(seed.s),
	two: Cell::new(seed.r),
	}
	}

	/// Replaces the state of the random number generator with the provided seed, returning
	/// the seed that represents the previous state of the random number generator.
	///
	/// The random number generator will become equivalent to one created with
	/// the same seed.
	#[cfg(feature = "rt")]
	pub(crate) fn replace_seed(&self, seed: RngSeed) -> RngSeed {
	let old_seed = RngSeed::from_pair(self.one.get(), self.two.get());

	self.one.replace(seed.s);
	self.two.replace(seed.r);

	old_seed
	}

	#[cfg(any(
	feature = "macros",
	feature = "rt-multi-thread",
	all(feature = "sync", feature = "rt")
	))]
	pub(crate) fn fastrand_n(&self, n: u32) -> u32 {
	// This is similar to fastrand() % n, but faster.
	// See https://lemire.me/blog/2016/06/27/a-fast-alternative-to-the-modulo-reduction/
	let mul = (self.fastrand() as u64).wrapping_mul(n as u64);
	(mul >> 32) as u32
	}

	fn fastrand(&self) -> u32 {
	let mut s1 = self.one.get();
	let s0 = self.two.get();

	s1 ^= s1 << 17;
	s1 = s1 ^ s0 ^ s1 >> 7 ^ s0 >> 16;

	self.one.set(s0);
	self.two.set(s1);

	s0.wrapping_add(s1)
	}
	}