Crate bittle

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github crates.io docs.rs

Zero-cost bitsets over native Rust types.

The name bittle comes from bit and little. Small bitsets!


Usage

Add bittle as a dependency in your Cargo.toml:


[dependencies]
bittle = "0.5.6"

Guide

A bit is always identified by a u32 by its index, and the exact location for a bit in a primitive numbers is defined by its endianness, which is BigEndian by default.

BigEndian indexing grows from right to left, such as the following u8 literal:

0b0010_0010u8
    ^    ^- index 1
    '------ index 5

To interact with these bits we define the Bits, BitsMut, and BitsOwned traits. These traits are implemented for primitive types such as u32, [u32; 4], or &[u32]:

use bittle::Bits;

let array: [u32; 4] = [0, 1, 2, 3];
assert!(array.iter_ones().eq([32, 65, 96, 97]));

let n = 0b00000000_00000000_00000000_00010001u32;
assert!(n.iter_ones().eq([0, 4]));

let array_of_arrays: [[u8; 4]; 2] = [[16, 0, 0, 0], [0, 0, 1, 0]];
assert!(array_of_arrays.iter_ones().eq([4, 48]));

let mut vec: Vec<u32> = vec![0, 1, 2, 3];
assert!(vec.iter_ones().eq([32, 65, 96, 97]));

We also provide the set! macro, which is a zero-cost convenience method for constructing primitive forms of bit sets:

use bittle::Bits;

let array: [u32; 4] = bittle::set![32, 65, 96, 97];
assert!(array.iter_ones().eq([32, 65, 96, 97]));

let n: u32 = bittle::set![0, 4];
assert!(n.iter_ones().eq([0, 4]));

let array_of_arrays: [[u8; 4]; 2] = bittle::set![4, 48];
assert!(array_of_arrays.iter_ones().eq([4, 48]));

Since a vector is not a primitive bit set, it could instead make use of BitsMut directly:

use bittle::{Bits, BitsMut};

let mut vec: Vec<u32> = vec![0u32; 4];
vec.set_bit(32);
vec.set_bit(65);
vec.set_bit(96);
vec.set_bit(97);
assert!(vec.iter_ones().eq([32, 65, 96, 97]));
assert_eq!(vec, [0, 1, 2, 3]);

Due to how broadly these traits are implemented, we also try to avoid using names which are commonly used in other APIs, instead opt for bit-specific terminology such as:

  • Something like is_empty becomes all_zeros - since with bits you’re thinking about “ones and zeros”.
  • Testing if a bit is set is test_bit, or in general adding the *_bit suffix to operations over individual bits.
  • Clearing all bits becomes clear_bits, or in general adding the *_bits suffix when operating over all bits.
use bittle::{Bits, BitsMut};

let mut set = [0u16; 2];

set.set_bit(15);
assert!(set.test_bit(15));

set.union_assign(&bittle::set![31, 7]);
assert!(set.test_bit(31) && set.test_bit(7));

set.clear_bit(31);
assert!(!set.test_bit(31));

set.clear_bits();
assert!(set.all_zeros());

Some other interesting operations, such as Bits::join_ones are available, allowing bitsets to act like masks over other iterators:

use bittle::{Bits, BitsMut};

let elements = vec![10, 48, 101];
let mut m = 0u128;

m.set_bit(0);
assert!(m.join_ones(&elements).eq([&10]));
m.set_bit(2);
assert!(m.join_ones(&elements).eq([&10, &101]));

Modules

  • Bits associated types for primitive arrays.
  • Bits associated types for primitive numbers.
  • Prelude use to conveniently import all relevant bits-oriented traits.
  • Bits associated types for slices.

Macros

Structs

  • Big-endian indexing for bit sets.
  • Little-endian indexing for bit sets.
  • Convenience wrapper around bitsets providing the wrapped type with behaviors you’d expected out of a set-like container.

Traits

  • Bitset immutable operations.
  • Bitset mutable operations.
  • Bitset owned operations.
  • Trait governing endian-dependent operations for a primitive.

Type Definitions