linux-x86/1.74.1/lib/rustlib/src/rust/vendor/hashbrown/src/raw/bitmask.rs - platform/prebuilts/rust - Git at Google

 use super::imp::{
     BitMaskWord, NonZeroBitMaskWord, BITMASK_ITER_MASK, BITMASK_MASK, BITMASK_STRIDE,
 };

 /// A bit mask which contains the result of a `Match` operation on a `Group` and
 /// allows iterating through them.
 ///
 /// The bit mask is arranged so that low-order bits represent lower memory
 /// addresses for group match results.
 ///
 /// For implementation reasons, the bits in the set may be sparsely packed with
 /// groups of 8 bits representing one element. If any of these bits are non-zero
 /// then this element is considered to true in the mask. If this is the
 /// case, `BITMASK_STRIDE` will be 8 to indicate a divide-by-8 should be
 /// performed on counts/indices to normalize this difference. `BITMASK_MASK` is
 /// similarly a mask of all the actually-used bits.
 ///
 /// To iterate over a bit mask, it must be converted to a form where only 1 bit
 /// is set per element. This is done by applying `BITMASK_ITER_MASK` on the
 /// mask bits.
 #[derive(Copy, Clone)]
 pub(crate) struct BitMask(pub(crate) BitMaskWord);

 #[allow(clippy::use_self)]
 impl BitMask {
     /// Returns a new `BitMask` with all bits inverted.
     #[inline]
     #[must_use]
     #[allow(dead_code)]
     pub(crate) fn invert(self) -> Self {
         BitMask(self.0 ^ BITMASK_MASK)
     }

     /// Returns a new `BitMask` with the lowest bit removed.
     #[inline]
     #[must_use]
     fn remove_lowest_bit(self) -> Self {
         BitMask(self.0 & (self.0 - 1))
     }

     /// Returns whether the `BitMask` has at least one set bit.
     #[inline]
     pub(crate) fn any_bit_set(self) -> bool {
         self.0 != 0
     }

     /// Returns the first set bit in the `BitMask`, if there is one.
     #[inline]
     pub(crate) fn lowest_set_bit(self) -> Option<usize> {
         if let Some(nonzero) = NonZeroBitMaskWord::new(self.0) {
             Some(Self::nonzero_trailing_zeros(nonzero))
         } else {
             None
         }
     }

     /// Returns the number of trailing zeroes in the `BitMask`.
     #[inline]
     pub(crate) fn trailing_zeros(self) -> usize {
         // ARM doesn't have a trailing_zeroes instruction, and instead uses
         // reverse_bits (RBIT) + leading_zeroes (CLZ). However older ARM
         // versions (pre-ARMv7) don't have RBIT and need to emulate it
         // instead. Since we only have 1 bit set in each byte on ARM, we can
         // use swap_bytes (REV) + leading_zeroes instead.
         if cfg!(target_arch = "arm") && BITMASK_STRIDE % 8 == 0 {
             self.0.swap_bytes().leading_zeros() as usize / BITMASK_STRIDE
         } else {
             self.0.trailing_zeros() as usize / BITMASK_STRIDE
         }
     }

     /// Same as above but takes a `NonZeroBitMaskWord`.
     #[inline]
     fn nonzero_trailing_zeros(nonzero: NonZeroBitMaskWord) -> usize {
         if cfg!(target_arch = "arm") && BITMASK_STRIDE % 8 == 0 {
             // SAFETY: A byte-swapped non-zero value is still non-zero.
             let swapped = unsafe { NonZeroBitMaskWord::new_unchecked(nonzero.get().swap_bytes()) };
             swapped.leading_zeros() as usize / BITMASK_STRIDE
         } else {
             nonzero.trailing_zeros() as usize / BITMASK_STRIDE
         }
     }

     /// Returns the number of leading zeroes in the `BitMask`.
     #[inline]
     pub(crate) fn leading_zeros(self) -> usize {
         self.0.leading_zeros() as usize / BITMASK_STRIDE
     }
 }

 impl IntoIterator for BitMask {
     type Item = usize;
     type IntoIter = BitMaskIter;

     #[inline]
     fn into_iter(self) -> BitMaskIter {
         // A BitMask only requires each element (group of bits) to be non-zero.
         // However for iteration we need each element to only contain 1 bit.
         BitMaskIter(BitMask(self.0 & BITMASK_ITER_MASK))
     }
 }

 /// Iterator over the contents of a `BitMask`, returning the indices of set
 /// bits.
 #[derive(Copy, Clone)]
 pub(crate) struct BitMaskIter(pub(crate) BitMask);

 impl BitMaskIter {
     /// Flip the bit in the mask for the entry at the given index.
     ///
     /// Returns the bit's previous state.
     #[inline]
     #[allow(clippy::cast_ptr_alignment)]
     #[cfg(feature = "raw")]
     pub(crate) unsafe fn flip(&mut self, index: usize) -> bool {
         // NOTE: The + BITMASK_STRIDE - 1 is to set the high bit.
         let mask = 1 << (index * BITMASK_STRIDE + BITMASK_STRIDE - 1);
         self.0 .0 ^= mask;
         // The bit was set if the bit is now 0.
         self.0 .0 & mask == 0
     }
 }

 impl Iterator for BitMaskIter {
     type Item = usize;

     #[inline]
     fn next(&mut self) -> Option<usize> {
         let bit = self.0.lowest_set_bit()?;
         self.0 = self.0.remove_lowest_bit();
         Some(bit)
     }
 }
	use super::imp::{
	BitMaskWord, NonZeroBitMaskWord, BITMASK_ITER_MASK, BITMASK_MASK, BITMASK_STRIDE,
	};

	/// A bit mask which contains the result of a `Match` operation on a `Group` and
	/// allows iterating through them.
	///
	/// The bit mask is arranged so that low-order bits represent lower memory
	/// addresses for group match results.
	///
	/// For implementation reasons, the bits in the set may be sparsely packed with
	/// groups of 8 bits representing one element. If any of these bits are non-zero
	/// then this element is considered to true in the mask. If this is the
	/// case, `BITMASK_STRIDE` will be 8 to indicate a divide-by-8 should be
	/// performed on counts/indices to normalize this difference. `BITMASK_MASK` is
	/// similarly a mask of all the actually-used bits.
	///
	/// To iterate over a bit mask, it must be converted to a form where only 1 bit
	/// is set per element. This is done by applying `BITMASK_ITER_MASK` on the
	/// mask bits.
	#[derive(Copy, Clone)]
	pub(crate) struct BitMask(pub(crate) BitMaskWord);

	#[allow(clippy::use_self)]
	impl BitMask {
	/// Returns a new `BitMask` with all bits inverted.
	#[inline]
	#[must_use]
	#[allow(dead_code)]
	pub(crate) fn invert(self) -> Self {
	BitMask(self.0 ^ BITMASK_MASK)
	}

	/// Returns a new `BitMask` with the lowest bit removed.
	#[inline]
	#[must_use]
	fn remove_lowest_bit(self) -> Self {
	BitMask(self.0 & (self.0 - 1))
	}

	/// Returns whether the `BitMask` has at least one set bit.
	#[inline]
	pub(crate) fn any_bit_set(self) -> bool {
	self.0 != 0
	}

	/// Returns the first set bit in the `BitMask`, if there is one.
	#[inline]
	pub(crate) fn lowest_set_bit(self) -> Option<usize> {
	if let Some(nonzero) = NonZeroBitMaskWord::new(self.0) {
	Some(Self::nonzero_trailing_zeros(nonzero))
	} else {
	None
	}
	}

	/// Returns the number of trailing zeroes in the `BitMask`.
	#[inline]
	pub(crate) fn trailing_zeros(self) -> usize {
	// ARM doesn't have a trailing_zeroes instruction, and instead uses
	// reverse_bits (RBIT) + leading_zeroes (CLZ). However older ARM
	// versions (pre-ARMv7) don't have RBIT and need to emulate it
	// instead. Since we only have 1 bit set in each byte on ARM, we can
	// use swap_bytes (REV) + leading_zeroes instead.
	if cfg!(target_arch = "arm") && BITMASK_STRIDE % 8 == 0 {
	self.0.swap_bytes().leading_zeros() as usize / BITMASK_STRIDE
	} else {
	self.0.trailing_zeros() as usize / BITMASK_STRIDE
	}
	}

	/// Same as above but takes a `NonZeroBitMaskWord`.
	#[inline]
	fn nonzero_trailing_zeros(nonzero: NonZeroBitMaskWord) -> usize {
	if cfg!(target_arch = "arm") && BITMASK_STRIDE % 8 == 0 {
	// SAFETY: A byte-swapped non-zero value is still non-zero.
	let swapped = unsafe { NonZeroBitMaskWord::new_unchecked(nonzero.get().swap_bytes()) };
	swapped.leading_zeros() as usize / BITMASK_STRIDE
	} else {
	nonzero.trailing_zeros() as usize / BITMASK_STRIDE
	}
	}

	/// Returns the number of leading zeroes in the `BitMask`.
	#[inline]
	pub(crate) fn leading_zeros(self) -> usize {
	self.0.leading_zeros() as usize / BITMASK_STRIDE
	}
	}

	impl IntoIterator for BitMask {
	type Item = usize;
	type IntoIter = BitMaskIter;

	#[inline]
	fn into_iter(self) -> BitMaskIter {
	// A BitMask only requires each element (group of bits) to be non-zero.
	// However for iteration we need each element to only contain 1 bit.
	BitMaskIter(BitMask(self.0 & BITMASK_ITER_MASK))
	}
	}

	/// Iterator over the contents of a `BitMask`, returning the indices of set
	/// bits.
	#[derive(Copy, Clone)]
	pub(crate) struct BitMaskIter(pub(crate) BitMask);

	impl BitMaskIter {
	/// Flip the bit in the mask for the entry at the given index.
	///
	/// Returns the bit's previous state.
	#[inline]
	#[allow(clippy::cast_ptr_alignment)]
	#[cfg(feature = "raw")]
	pub(crate) unsafe fn flip(&mut self, index: usize) -> bool {
	// NOTE: The + BITMASK_STRIDE - 1 is to set the high bit.
	let mask = 1 << (index * BITMASK_STRIDE + BITMASK_STRIDE - 1);
	self.0 .0 ^= mask;
	// The bit was set if the bit is now 0.
	self.0 .0 & mask == 0
	}
	}

	impl Iterator for BitMaskIter {
	type Item = usize;

	#[inline]
	fn next(&mut self) -> Option<usize> {
	let bit = self.0.lowest_set_bit()?;
	self.0 = self.0.remove_lowest_bit();
	Some(bit)
	}
	}