Lib.rs

Parser implementations
#represented #hex #float #ieee-754 #representation #syntax #parse

hexfloat2

Parse and format IEEE754 floating point hexadecimal syntax

by Eric Seppanen

4 releases

0.1.3 Dec 2, 2023
0.1.2 Nov 30, 2023
0.1.1 Nov 30, 2023
0.1.0 Nov 30, 2023

#883 in Parser implementations

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Used in 4 crates (3 directly)

MIT license

29KB
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hexfloat2 supports hexadecimal f32/64 syntax.

IEEE754 defines a syntax for "hexadecimal-significand character sequences" that lets you write a precise representation of a floating point number.

For example:

  • 0x1.0p0 is just 1.0
  • 0x8.8p1 is 8.5 * 2^1, or 17.
  • 0x3.0p-12 is 3 * 2^-12, or 0.000732421875 in decimal.

Unlike decimal representations, "hexfloat" representations don't involve any rounding, so a format-then-parse round trip will always return exactly the same original value.

A formatted hexfloat will always appear in its "canonical" format, copying the exact bit representation as closely as possible. For example, the value 2^-20 will always be rendered as 0x1.0p-19.

The parser attempts to handle "non-canonical" representations. For example, these values will all be parsed as 2^-20:

  • 0x1.0p-20
  • 0x2.0p-21
  • 0x0.0008p-7

Some inputs won't parse: values with too many hex digits (e.g. 0x10000000000000000p20) will fail to parse because the parser is only willing to parse up to 16 hex digits. Values that are outside the range that can be represented in the underlying type (f32 or f64) will also fail to parse.

Values with excessive precision will have the trailing bits dropped. For example, 0x1.0000000000001p0 will be truncated to 1.0 when parsed into a HexFloat<f32> (but would fit in an f64).

"Subnormal" values can be successfully formatted and parsed; 0x0.000002p-127 can be parsed as an f32; anything smaller will be truncated to 0.

Examples

use hexfloat2::HexFloat32;

const EXPECTED: f32 = 1.0 / 1048576.0;

let x = "0x1.0p-20";
let fx: HexFloat32 = x.parse().unwrap();
assert_eq!(*fx, EXPECTED);

let y = "0x2.0p-21";
let fy: HexFloat32 = y.parse().unwrap();
assert_eq!(*fy, EXPECTED);

let z = "0x0.0008p-7";
let fz: HexFloat32 = z.parse().unwrap();
assert_eq!(*fz, EXPECTED);

let sz = format!("{fz}");
assert_eq!(sz, "0x1.000000p-20");

This crate provides newtype wrappers HexFloat<T>, aka HexFloat32 or HexFloat64, that implement Display and FromStr.

If you don't want to deal with the wrapper structs, you can also call hexfloat::parse::<T>() or hexfloat::format::<T>() instead.

No runtime deps