compiler/rustc_data_structures/src/fingerprint.rs - toolchain/rustc - Git at Google

 use crate::stable_hasher;
 use rustc_serialize::{Decodable, Decoder, Encodable, Encoder};
 use std::hash::{Hash, Hasher};

 #[cfg(test)]
 mod tests;

 #[derive(Eq, PartialEq, Ord, PartialOrd, Debug, Clone, Copy)]
 #[repr(C)]
 pub struct Fingerprint(u64, u64);

 impl Fingerprint {
     pub const ZERO: Fingerprint = Fingerprint(0, 0);

     #[inline]
     pub fn new(_0: u64, _1: u64) -> Fingerprint {
         Fingerprint(_0, _1)
     }

     #[inline]
     pub fn from_smaller_hash(hash: u64) -> Fingerprint {
         Fingerprint(hash, hash)
     }

     #[inline]
     pub fn to_smaller_hash(&self) -> u64 {
         // Even though both halves of the fingerprint are expected to be good
         // quality hash values, let's still combine the two values because the
         // Fingerprints in DefPathHash have the StableCrateId portion which is
         // the same for all DefPathHashes from the same crate. Combining the
         // two halves makes sure we get a good quality hash in such cases too.
         self.0.wrapping_mul(3).wrapping_add(self.1)
     }

     #[inline]
     pub fn as_value(&self) -> (u64, u64) {
         (self.0, self.1)
     }

     #[inline]
     pub fn combine(self, other: Fingerprint) -> Fingerprint {
         // See https://stackoverflow.com/a/27952689 on why this function is
         // implemented this way.
         Fingerprint(
             self.0.wrapping_mul(3).wrapping_add(other.0),
             self.1.wrapping_mul(3).wrapping_add(other.1),
         )
     }

     // Combines two hashes in an order independent way. Make sure this is what
     // you want.
     #[inline]
     pub fn combine_commutative(self, other: Fingerprint) -> Fingerprint {
         let a = u128::from(self.1) << 64 | u128::from(self.0);
         let b = u128::from(other.1) << 64 | u128::from(other.0);

         let c = a.wrapping_add(b);

         Fingerprint(c as u64, (c >> 64) as u64)
     }

     pub fn to_hex(&self) -> String {
         format!("{:x}{:x}", self.0, self.1)
     }

     #[inline]
     pub fn to_le_bytes(&self) -> [u8; 16] {
         // This seems to optimize to the same machine code as
         // `unsafe { mem::transmute(*k) }`. Well done, LLVM! :)
         let mut result = [0u8; 16];

         let first_half: &mut [u8; 8] = (&mut result[0..8]).try_into().unwrap();
         *first_half = self.0.to_le_bytes();

         let second_half: &mut [u8; 8] = (&mut result[8..16]).try_into().unwrap();
         *second_half = self.1.to_le_bytes();

         result
     }

     #[inline]
     pub fn from_le_bytes(bytes: [u8; 16]) -> Fingerprint {
         Fingerprint(
             u64::from_le_bytes(bytes[0..8].try_into().unwrap()),
             u64::from_le_bytes(bytes[8..16].try_into().unwrap()),
         )
     }
 }

 impl std::fmt::Display for Fingerprint {
     fn fmt(&self, formatter: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
         write!(formatter, "{:x}-{:x}", self.0, self.1)
     }
 }

 impl Hash for Fingerprint {
     #[inline]
     fn hash<H: Hasher>(&self, state: &mut H) {
         state.write_fingerprint(self);
     }
 }

 trait FingerprintHasher {
     fn write_fingerprint(&mut self, fingerprint: &Fingerprint);
 }

 impl<H: Hasher> FingerprintHasher for H {
     #[inline]
     default fn write_fingerprint(&mut self, fingerprint: &Fingerprint) {
         self.write_u64(fingerprint.0);
         self.write_u64(fingerprint.1);
     }
 }

 impl FingerprintHasher for crate::unhash::Unhasher {
     #[inline]
     fn write_fingerprint(&mut self, fingerprint: &Fingerprint) {
         // Even though both halves of the fingerprint are expected to be good
         // quality hash values, let's still combine the two values because the
         // Fingerprints in DefPathHash have the StableCrateId portion which is
         // the same for all DefPathHashes from the same crate. Combining the
         // two halves makes sure we get a good quality hash in such cases too.
         //
         // Since `Unhasher` is used only in the context of HashMaps, it is OK
         // to combine the two components in an order-independent way (which is
         // cheaper than the more robust Fingerprint::to_smaller_hash()). For
         // HashMaps we don't really care if Fingerprint(x,y) and
         // Fingerprint(y, x) result in the same hash value. Collision
         // probability will still be much better than with FxHash.
         self.write_u64(fingerprint.0.wrapping_add(fingerprint.1));
     }
 }

 impl stable_hasher::StableHasherResult for Fingerprint {
     #[inline]
     fn finish(hasher: stable_hasher::StableHasher) -> Self {
         let (_0, _1) = hasher.finalize();
         Fingerprint(_0, _1)
     }
 }

 impl_stable_traits_for_trivial_type!(Fingerprint);

 impl<E: Encoder> Encodable<E> for Fingerprint {
     #[inline]
     fn encode(&self, s: &mut E) {
         s.emit_raw_bytes(&self.to_le_bytes());
     }
 }

 impl<D: Decoder> Decodable<D> for Fingerprint {
     #[inline]
     fn decode(d: &mut D) -> Self {
         Fingerprint::from_le_bytes(d.read_raw_bytes(16).try_into().unwrap())
     }
 }

 // `PackedFingerprint` wraps a `Fingerprint`. Its purpose is to, on certain
 // architectures, behave like a `Fingerprint` without alignment requirements.
 // This behavior is only enabled on x86 and x86_64, where the impact of
 // unaligned accesses is tolerable in small doses.
 //
 // This may be preferable to use in large collections of structs containing
 // fingerprints, as it can reduce memory consumption by preventing the padding
 // that the more strictly-aligned `Fingerprint` can introduce. An application of
 // this is in the query dependency graph, which contains a large collection of
 // `DepNode`s. As of this writing, the size of a `DepNode` decreases by ~30%
 // (from 24 bytes to 17) by using the packed representation here, which
 // noticeably decreases total memory usage when compiling large crates.
 //
 // The wrapped `Fingerprint` is private to reduce the chance of a client
 // invoking undefined behavior by taking a reference to the packed field.
 #[cfg_attr(any(target_arch = "x86", target_arch = "x86_64"), repr(packed))]
 #[derive(Eq, PartialEq, Ord, PartialOrd, Debug, Clone, Copy, Hash)]
 pub struct PackedFingerprint(Fingerprint);

 impl std::fmt::Display for PackedFingerprint {
     #[inline]
     fn fmt(&self, formatter: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
         // Copy to avoid taking reference to packed field.
         let copy = self.0;
         copy.fmt(formatter)
     }
 }

 impl<E: Encoder> Encodable<E> for PackedFingerprint {
     #[inline]
     fn encode(&self, s: &mut E) {
         // Copy to avoid taking reference to packed field.
         let copy = self.0;
         copy.encode(s);
     }
 }

 impl<D: Decoder> Decodable<D> for PackedFingerprint {
     #[inline]
     fn decode(d: &mut D) -> Self {
         Self(Fingerprint::decode(d))
     }
 }

 impl From<Fingerprint> for PackedFingerprint {
     #[inline]
     fn from(f: Fingerprint) -> PackedFingerprint {
         PackedFingerprint(f)
     }
 }

 impl From<PackedFingerprint> for Fingerprint {
     #[inline]
     fn from(f: PackedFingerprint) -> Fingerprint {
         f.0
     }
 }
	use crate::stable_hasher;
	use rustc_serialize::{Decodable, Decoder, Encodable, Encoder};
	use std::hash::{Hash, Hasher};

	#[cfg(test)]
	mod tests;

	#[derive(Eq, PartialEq, Ord, PartialOrd, Debug, Clone, Copy)]
	#[repr(C)]
	pub struct Fingerprint(u64, u64);

	impl Fingerprint {
	pub const ZERO: Fingerprint = Fingerprint(0, 0);

	#[inline]
	pub fn new(_0: u64, _1: u64) -> Fingerprint {
	Fingerprint(_0, _1)
	}

	#[inline]
	pub fn from_smaller_hash(hash: u64) -> Fingerprint {
	Fingerprint(hash, hash)
	}

	#[inline]
	pub fn to_smaller_hash(&self) -> u64 {
	// Even though both halves of the fingerprint are expected to be good
	// quality hash values, let's still combine the two values because the
	// Fingerprints in DefPathHash have the StableCrateId portion which is
	// the same for all DefPathHashes from the same crate. Combining the
	// two halves makes sure we get a good quality hash in such cases too.
	self.0.wrapping_mul(3).wrapping_add(self.1)
	}

	#[inline]
	pub fn as_value(&self) -> (u64, u64) {
	(self.0, self.1)
	}

	#[inline]
	pub fn combine(self, other: Fingerprint) -> Fingerprint {
	// See https://stackoverflow.com/a/27952689 on why this function is
	// implemented this way.
	Fingerprint(
	self.0.wrapping_mul(3).wrapping_add(other.0),
	self.1.wrapping_mul(3).wrapping_add(other.1),
	)
	}

	// Combines two hashes in an order independent way. Make sure this is what
	// you want.
	#[inline]
	pub fn combine_commutative(self, other: Fingerprint) -> Fingerprint {
	let a = u128::from(self.1) << 64 \| u128::from(self.0);
	let b = u128::from(other.1) << 64 \| u128::from(other.0);

	let c = a.wrapping_add(b);

	Fingerprint(c as u64, (c >> 64) as u64)
	}

	pub fn to_hex(&self) -> String {
	format!("{:x}{:x}", self.0, self.1)
	}

	#[inline]
	pub fn to_le_bytes(&self) -> [u8; 16] {
	// This seems to optimize to the same machine code as
	// `unsafe { mem::transmute(*k) }`. Well done, LLVM! :)
	let mut result = [0u8; 16];

	let first_half: &mut [u8; 8] = (&mut result[0..8]).try_into().unwrap();
	*first_half = self.0.to_le_bytes();

	let second_half: &mut [u8; 8] = (&mut result[8..16]).try_into().unwrap();
	*second_half = self.1.to_le_bytes();

	result
	}

	#[inline]
	pub fn from_le_bytes(bytes: [u8; 16]) -> Fingerprint {
	Fingerprint(
	u64::from_le_bytes(bytes[0..8].try_into().unwrap()),
	u64::from_le_bytes(bytes[8..16].try_into().unwrap()),
	)
	}
	}

	impl std::fmt::Display for Fingerprint {
	fn fmt(&self, formatter: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
	write!(formatter, "{:x}-{:x}", self.0, self.1)
	}
	}

	impl Hash for Fingerprint {
	#[inline]
	fn hash<H: Hasher>(&self, state: &mut H) {
	state.write_fingerprint(self);
	}
	}

	trait FingerprintHasher {
	fn write_fingerprint(&mut self, fingerprint: &Fingerprint);
	}

	impl<H: Hasher> FingerprintHasher for H {
	#[inline]
	default fn write_fingerprint(&mut self, fingerprint: &Fingerprint) {
	self.write_u64(fingerprint.0);
	self.write_u64(fingerprint.1);
	}
	}

	impl FingerprintHasher for crate::unhash::Unhasher {
	#[inline]
	fn write_fingerprint(&mut self, fingerprint: &Fingerprint) {
	// Even though both halves of the fingerprint are expected to be good
	// quality hash values, let's still combine the two values because the
	// Fingerprints in DefPathHash have the StableCrateId portion which is
	// the same for all DefPathHashes from the same crate. Combining the
	// two halves makes sure we get a good quality hash in such cases too.
	//
	// Since `Unhasher` is used only in the context of HashMaps, it is OK
	// to combine the two components in an order-independent way (which is
	// cheaper than the more robust Fingerprint::to_smaller_hash()). For
	// HashMaps we don't really care if Fingerprint(x,y) and
	// Fingerprint(y, x) result in the same hash value. Collision
	// probability will still be much better than with FxHash.
	self.write_u64(fingerprint.0.wrapping_add(fingerprint.1));
	}
	}

	impl stable_hasher::StableHasherResult for Fingerprint {
	#[inline]
	fn finish(hasher: stable_hasher::StableHasher) -> Self {
	let (_0, _1) = hasher.finalize();
	Fingerprint(_0, _1)
	}
	}

	impl_stable_traits_for_trivial_type!(Fingerprint);

	impl<E: Encoder> Encodable<E> for Fingerprint {
	#[inline]
	fn encode(&self, s: &mut E) {
	s.emit_raw_bytes(&self.to_le_bytes());
	}
	}

	impl<D: Decoder> Decodable<D> for Fingerprint {
	#[inline]
	fn decode(d: &mut D) -> Self {
	Fingerprint::from_le_bytes(d.read_raw_bytes(16).try_into().unwrap())
	}
	}

	// `PackedFingerprint` wraps a `Fingerprint`. Its purpose is to, on certain
	// architectures, behave like a `Fingerprint` without alignment requirements.
	// This behavior is only enabled on x86 and x86_64, where the impact of
	// unaligned accesses is tolerable in small doses.
	//
	// This may be preferable to use in large collections of structs containing
	// fingerprints, as it can reduce memory consumption by preventing the padding
	// that the more strictly-aligned `Fingerprint` can introduce. An application of
	// this is in the query dependency graph, which contains a large collection of
	// `DepNode`s. As of this writing, the size of a `DepNode` decreases by ~30%
	// (from 24 bytes to 17) by using the packed representation here, which
	// noticeably decreases total memory usage when compiling large crates.
	//
	// The wrapped `Fingerprint` is private to reduce the chance of a client
	// invoking undefined behavior by taking a reference to the packed field.
	#[cfg_attr(any(target_arch = "x86", target_arch = "x86_64"), repr(packed))]
	#[derive(Eq, PartialEq, Ord, PartialOrd, Debug, Clone, Copy, Hash)]
	pub struct PackedFingerprint(Fingerprint);

	impl std::fmt::Display for PackedFingerprint {
	#[inline]
	fn fmt(&self, formatter: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
	// Copy to avoid taking reference to packed field.
	let copy = self.0;
	copy.fmt(formatter)
	}
	}

	impl<E: Encoder> Encodable<E> for PackedFingerprint {
	#[inline]
	fn encode(&self, s: &mut E) {
	// Copy to avoid taking reference to packed field.
	let copy = self.0;
	copy.encode(s);
	}
	}

	impl<D: Decoder> Decodable<D> for PackedFingerprint {
	#[inline]
	fn decode(d: &mut D) -> Self {
	Self(Fingerprint::decode(d))
	}
	}

	impl From<Fingerprint> for PackedFingerprint {
	#[inline]
	fn from(f: Fingerprint) -> PackedFingerprint {
	PackedFingerprint(f)
	}
	}

	impl From<PackedFingerprint> for Fingerprint {
	#[inline]
	fn from(f: PackedFingerprint) -> Fingerprint {
	f.0
	}
	}