//! Provides the abstraction of a bit field, which allows for bit-level update and retrieval //! operations. #![no_std] #[cfg(test)] mod tests; use core::ops::{Bound, Range, RangeBounds}; /// A generic trait which provides methods for extracting and setting specific bits or ranges of /// bits. pub trait BitField { /// The number of bits in this bit field. /// /// ```rust /// use bit_field::BitField; /// /// assert_eq!(u32::BIT_LENGTH, 32); /// assert_eq!(u64::BIT_LENGTH, 64); /// ``` const BIT_LENGTH: usize; /// Obtains the bit at the index `bit`; note that index 0 is the least significant bit, while /// index `length() - 1` is the most significant bit. /// /// ```rust /// use bit_field::BitField; /// /// let value: u32 = 0b110101; /// /// assert_eq!(value.get_bit(1), false); /// assert_eq!(value.get_bit(2), true); /// ``` /// /// ## Panics /// /// This method will panic if the bit index is out of bounds of the bit field. fn get_bit(&self, bit: usize) -> bool; /// Obtains the range of bits specified by `range`; note that index 0 is the least significant /// bit, while index `length() - 1` is the most significant bit. /// /// ```rust /// use bit_field::BitField; /// /// let value: u32 = 0b110101; /// /// assert_eq!(value.get_bits(0..3), 0b101); /// assert_eq!(value.get_bits(2..6), 0b1101); /// assert_eq!(value.get_bits(..), 0b110101); /// assert_eq!(value.get_bits(3..=3), value.get_bit(3) as u32); /// ``` /// /// ## Panics /// /// This method will panic if the start or end indexes of the range are out of bounds of the /// bit field. fn get_bits>(&self, range: T) -> Self; /// Sets the bit at the index `bit` to the value `value` (where true means a value of '1' and /// false means a value of '0'); note that index 0 is the least significant bit, while index /// `length() - 1` is the most significant bit. /// /// ```rust /// use bit_field::BitField; /// /// let mut value = 0u32; /// /// value.set_bit(1, true); /// assert_eq!(value, 2u32); /// /// value.set_bit(3, true); /// assert_eq!(value, 10u32); /// /// value.set_bit(1, false); /// assert_eq!(value, 8u32); /// ``` /// /// ## Panics /// /// This method will panic if the bit index is out of the bounds of the bit field. fn set_bit(&mut self, bit: usize, value: bool) -> &mut Self; /// Sets the range of bits defined by the range `range` to the lower bits of `value`; to be /// specific, if the range is N bits long, the N lower bits of `value` will be used; if any of /// the other bits in `value` are set to 1, this function will panic. /// /// ```rust /// use bit_field::BitField; /// /// let mut value = 0u32; /// /// value.set_bits(0..2, 0b11); /// assert_eq!(value, 0b11); /// /// value.set_bits(2..=3, 0b11); /// assert_eq!(value, 0b1111); /// /// value.set_bits(..4, 0b1010); /// assert_eq!(value, 0b1010); /// ``` /// /// ## Panics /// /// This method will panic if the range is out of bounds of the bit field, or if there are `1`s /// not in the lower N bits of `value`. fn set_bits>(&mut self, range: T, value: Self) -> &mut Self; } pub trait BitArray { /// Returns the length, eg number of bits, in this bit array. /// /// ```rust /// use bit_field::BitArray; /// /// assert_eq!([0u8, 4u8, 8u8].bit_length(), 24); /// assert_eq!([0u32, 5u32].bit_length(), 64); /// ``` fn bit_length(&self) -> usize; /// Obtains the bit at the index `bit`; note that index 0 is the least significant bit, while /// index `length() - 1` is the most significant bit. /// /// ```rust /// use bit_field::BitArray; /// /// let value: [u32; 1] = [0b110101]; /// /// assert_eq!(value.get_bit(1), false); /// assert_eq!(value.get_bit(2), true); /// ``` /// /// ## Panics /// /// This method will panic if the bit index is out of bounds of the bit array. fn get_bit(&self, bit: usize) -> bool; /// Obtains the range of bits specified by `range`; note that index 0 is the least significant /// bit, while index `length() - 1` is the most significant bit. /// /// ```rust /// use bit_field::BitArray; /// /// let value: [u32; 2] = [0b110101, 0b11]; /// /// assert_eq!(value.get_bits(0..3), 0b101); /// assert_eq!(value.get_bits(..6), 0b110101); /// assert_eq!(value.get_bits(31..33), 0b10); /// assert_eq!(value.get_bits(5..=32), 0b1_0000_0000_0000_0000_0000_0000_001); /// assert_eq!(value.get_bits(34..), 0); /// ``` /// /// ## Panics /// /// This method will panic if the start or end indexes of the range are out of bounds of the /// bit array, or if the range can't be contained by the bit field T. fn get_bits>(&self, range: U) -> T; /// Sets the bit at the index `bit` to the value `value` (where true means a value of '1' and /// false means a value of '0'); note that index 0 is the least significant bit, while index /// `length() - 1` is the most significant bit. /// /// ```rust /// use bit_field::BitArray; /// /// let mut value = [0u32]; /// /// value.set_bit(1, true); /// assert_eq!(value, [2u32]); /// /// value.set_bit(3, true); /// assert_eq!(value, [10u32]); /// /// value.set_bit(1, false); /// assert_eq!(value, [8u32]); /// ``` /// /// ## Panics /// /// This method will panic if the bit index is out of the bounds of the bit array. fn set_bit(&mut self, bit: usize, value: bool); /// Sets the range of bits defined by the range `range` to the lower bits of `value`; to be /// specific, if the range is N bits long, the N lower bits of `value` will be used; if any of /// the other bits in `value` are set to 1, this function will panic. /// /// ```rust /// use bit_field::BitArray; /// /// let mut value = [0u32, 0u32]; /// /// value.set_bits(0..2, 0b11); /// assert_eq!(value, [0b11, 0u32]); /// /// value.set_bits(31..35, 0b1010); /// assert_eq!(value, [0x0003, 0b101]); /// ``` /// /// ## Panics /// /// This method will panic if the range is out of bounds of the bit array, /// if the range can't be contained by the bit field T, or if there are `1`s /// not in the lower N bits of `value`. fn set_bits>(&mut self, range: U, value: T); } /// An internal macro used for implementing BitField on the standard integral types. macro_rules! bitfield_numeric_impl { ($($t:ty)*) => ($( impl BitField for $t { const BIT_LENGTH: usize = ::core::mem::size_of::() as usize * 8; #[track_caller] #[inline] fn get_bit(&self, bit: usize) -> bool { assert!(bit < Self::BIT_LENGTH); (*self & (1 << bit)) != 0 } #[track_caller] #[inline] fn get_bits>(&self, range: T) -> Self { let range = to_regular_range(&range, Self::BIT_LENGTH); assert!(range.start < Self::BIT_LENGTH); assert!(range.end <= Self::BIT_LENGTH); assert!(range.start < range.end); // shift away high bits let bits = *self << (Self::BIT_LENGTH - range.end) >> (Self::BIT_LENGTH - range.end); // shift away low bits bits >> range.start } #[track_caller] #[inline] fn set_bit(&mut self, bit: usize, value: bool) -> &mut Self { assert!(bit < Self::BIT_LENGTH); if value { *self |= 1 << bit; } else { *self &= !(1 << bit); } self } #[track_caller] #[inline] fn set_bits>(&mut self, range: T, value: Self) -> &mut Self { let range = to_regular_range(&range, Self::BIT_LENGTH); assert!(range.start < Self::BIT_LENGTH); assert!(range.end <= Self::BIT_LENGTH); assert!(range.start < range.end); assert!(value << (Self::BIT_LENGTH - (range.end - range.start)) >> (Self::BIT_LENGTH - (range.end - range.start)) == value, "value does not fit into bit range"); let bitmask: Self = !(!0 << (Self::BIT_LENGTH - range.end) >> (Self::BIT_LENGTH - range.end) >> range.start << range.start); // set bits *self = (*self & bitmask) | (value << range.start); self } } )*) } bitfield_numeric_impl! { u8 u16 u32 u64 u128 usize i8 i16 i32 i64 i128 isize } impl BitArray for [T] { #[inline] fn bit_length(&self) -> usize { self.len() * T::BIT_LENGTH } #[track_caller] #[inline] fn get_bit(&self, bit: usize) -> bool { let slice_index = bit / T::BIT_LENGTH; let bit_index = bit % T::BIT_LENGTH; self[slice_index].get_bit(bit_index) } #[track_caller] #[inline] fn get_bits>(&self, range: U) -> T { let range = to_regular_range(&range, self.bit_length()); assert!(range.len() <= T::BIT_LENGTH); let slice_start = range.start / T::BIT_LENGTH; let slice_end = range.end / T::BIT_LENGTH; let bit_start = range.start % T::BIT_LENGTH; let bit_end = range.end % T::BIT_LENGTH; let len = range.len(); assert!(slice_end - slice_start <= 1); if slice_start == slice_end { self[slice_start].get_bits(bit_start..bit_end) } else if bit_end == 0 { self[slice_start].get_bits(bit_start..T::BIT_LENGTH) } else { let mut ret = self[slice_start].get_bits(bit_start..T::BIT_LENGTH); ret.set_bits( (T::BIT_LENGTH - bit_start)..len, self[slice_end].get_bits(0..bit_end), ); ret } } #[track_caller] #[inline] fn set_bit(&mut self, bit: usize, value: bool) { let slice_index = bit / T::BIT_LENGTH; let bit_index = bit % T::BIT_LENGTH; self[slice_index].set_bit(bit_index, value); } #[track_caller] #[inline] fn set_bits>(&mut self, range: U, value: T) { let range = to_regular_range(&range, self.bit_length()); assert!(range.len() <= T::BIT_LENGTH); let slice_start = range.start / T::BIT_LENGTH; let slice_end = range.end / T::BIT_LENGTH; let bit_start = range.start % T::BIT_LENGTH; let bit_end = range.end % T::BIT_LENGTH; assert!(slice_end - slice_start <= 1); if slice_start == slice_end { self[slice_start].set_bits(bit_start..bit_end, value); } else if bit_end == 0 { self[slice_start].set_bits(bit_start..T::BIT_LENGTH, value); } else { self[slice_start].set_bits( bit_start..T::BIT_LENGTH, value.get_bits(0..T::BIT_LENGTH - bit_start), ); self[slice_end].set_bits( 0..bit_end, value.get_bits(T::BIT_LENGTH - bit_start..T::BIT_LENGTH), ); } } } fn to_regular_range>(generic_rage: &T, bit_length: usize) -> Range { let start = match generic_rage.start_bound() { Bound::Excluded(&value) => value + 1, Bound::Included(&value) => value, Bound::Unbounded => 0, }; let end = match generic_rage.end_bound() { Bound::Excluded(&value) => value, Bound::Included(&value) => value + 1, Bound::Unbounded => bit_length, }; start..end }