7.0 KiB
num_enum
Procedural macros to make inter-operation between primitives and enums easier. This crate is no_std compatible.
Turning an enum into a primitive
use num_enum::IntoPrimitive;
#[derive(IntoPrimitive)]
#[repr(u8)]
enum Number {
Zero,
One,
}
fn main() {
let zero: u8 = Number::Zero.into();
assert_eq!(zero, 0u8);
}
num_enum
's IntoPrimitive
is more type-safe than using as
, because as
will silently truncate - num_enum
only derives From
for exactly the discriminant type of the enum.
Attempting to turn a primitive into an enum with try_from
use num_enum::TryFromPrimitive;
use std::convert::TryFrom;
#[derive(Debug, Eq, PartialEq, TryFromPrimitive)]
#[repr(u8)]
enum Number {
Zero,
One,
}
fn main() {
let zero = Number::try_from(0u8);
assert_eq!(zero, Ok(Number::Zero));
let three = Number::try_from(3u8);
assert_eq!(
three.unwrap_err().to_string(),
"No discriminant in enum `Number` matches the value `3`",
);
}
Variant alternatives
Sometimes a single enum variant might be representable by multiple numeric values.
The #[num_enum(alternatives = [..])]
attribute allows you to define additional value alternatives for individual variants.
(The behavior of IntoPrimitive
is unaffected by this attribute, it will always return the canonical value.)
use num_enum::TryFromPrimitive;
use std::convert::TryFrom;
#[derive(Debug, Eq, PartialEq, TryFromPrimitive)]
#[repr(u8)]
enum Number {
Zero = 0,
#[num_enum(alternatives = [2])]
OneOrTwo = 1,
}
fn main() {
let zero = Number::try_from(0u8);
assert_eq!(zero, Ok(Number::Zero));
let one = Number::try_from(1u8);
assert_eq!(one, Ok(Number::OneOrTwo));
let two = Number::try_from(2u8);
assert_eq!(two, Ok(Number::OneOrTwo));
let three = Number::try_from(3u8);
assert_eq!(
three.unwrap_err().to_string(),
"No discriminant in enum `Number` matches the value `3`",
);
}
Range expressions are also supported for alternatives, but this requires enabling the complex-expressions
feature:
use num_enum::TryFromPrimitive;
use std::convert::TryFrom;
#[derive(Debug, Eq, PartialEq, TryFromPrimitive)]
#[repr(u8)]
enum Number {
Zero = 0,
#[num_enum(alternatives = [2..16])]
Some = 1,
#[num_enum(alternatives = [17, 18..=255])]
Many = 16,
}
fn main() {
let zero = Number::try_from(0u8);
assert_eq!(zero, Ok(Number::Zero));
let some = Number::try_from(15u8);
assert_eq!(some, Ok(Number::Some));
let many = Number::try_from(255u8);
assert_eq!(many, Ok(Number::Many));
}
Default variant
Sometimes it is desirable to have an Other
variant in an enum that acts as a kind of a wildcard matching all the value not yet covered by other variants.
The #[num_enum(default)]
attribute allows you to mark variant as the default.
(The behavior of IntoPrimitive
is unaffected by this attribute, it will always return the canonical value.)
use num_enum::TryFromPrimitive;
use std::convert::TryFrom;
#[derive(Debug, Eq, PartialEq, TryFromPrimitive)]
#[repr(u8)]
enum Number {
Zero = 0,
#[num_enum(default)]
NonZero = 1,
}
fn main() {
let zero = Number::try_from(0u8);
assert_eq!(zero, Ok(Number::Zero));
let one = Number::try_from(1u8);
assert_eq!(one, Ok(Number::NonZero));
let two = Number::try_from(2u8);
assert_eq!(two, Ok(Number::NonZero));
}
Safely turning a primitive into an exhaustive enum with from_primitive
If your enum has all possible primitive values covered, you can derive FromPrimitive
for it (which auto-implement stdlib's From
):
You can cover all possible values by:
- Having variants for every possible value
- Having a variant marked
#[num_enum(default)]
- Having a variant marked
#[num_enum(catch_all)]
- Having
#[num_enum(alternatives = [...])
s covering values not covered by a variant.
use num_enum::FromPrimitive;
#[derive(Debug, Eq, PartialEq, FromPrimitive)]
#[repr(u8)]
enum Number {
Zero,
#[num_enum(default)]
NonZero,
}
fn main() {
assert_eq!(
Number::Zero,
Number::from(0_u8),
);
assert_eq!(
Number::NonZero,
Number::from(1_u8),
);
}
Catch-all variant
Sometimes it is desirable to have an Other
variant which holds the otherwise un-matched value as a field.
The #[num_enum(catch_all)]
attribute allows you to mark at most one variant for this purpose. The variant it's applied to must be a tuple variant with exactly one field matching the repr
type.
use num_enum::FromPrimitive;
use std::convert::TryFrom;
#[derive(Debug, Eq, PartialEq, FromPrimitive)]
#[repr(u8)]
enum Number {
Zero = 0,
#[num_enum(catch_all)]
NonZero(u8),
}
fn main() {
let zero = Number::from(0u8);
assert_eq!(zero, Number::Zero);
let one = Number::from(1u8);
assert_eq!(one, Number::NonZero(1_u8));
let two = Number::from(2u8);
assert_eq!(two, Number::NonZero(2_u8));
}
As this is naturally exhaustive, this is only supported for FromPrimitive
, not also TryFromPrimitive
.
Unsafely turning a primitive into an enum with from_unchecked
If you're really certain a conversion will succeed (and have not made use of #[num_enum(default)]
or #[num_enum(alternatives = [..])]
for any of its variants), and want to avoid a small amount of overhead, you can use unsafe code to do this conversion.
Unless you have data showing that the match statement generated in the try_from
above is a bottleneck for you,
you should avoid doing this, as the unsafe code has potential to cause serious memory issues in your program.
use num_enum::UnsafeFromPrimitive;
#[derive(Debug, Eq, PartialEq, UnsafeFromPrimitive)]
#[repr(u8)]
enum Number {
Zero,
One,
}
fn main() {
assert_eq!(
unsafe { Number::from_unchecked(0_u8) },
Number::Zero,
);
assert_eq!(
unsafe { Number::from_unchecked(1_u8) },
Number::One,
);
}
unsafe fn undefined_behavior() {
let _ = Number::from_unchecked(2); // 2 is not a valid discriminant!
}
Optional features
Some enum values may be composed of complex expressions, for example:
enum Number {
Zero = (0, 1).0,
One = (0, 1).1,
}
To cut down on compile time, these are not supported by default, but if you enable the complex-expressions
feature of your dependency on num_enum
, these should start working.
License
num_enum may be used under your choice of the BSD 3-clause, Apache 2, or MIT license.