uom

Units of measurement is a crate that does automatic type-safe zero-cost dimensional analysis. You can create your own systems or use the pre-built International System of Units (SI) which is based on the International System of Quantities (ISQ) and includes numerous quantities (length, mass, time, ...) with conversion factors for even more numerous measurement units (meter, kilometer, foot, mile, ...). No more crashing your climate orbiter!

Usage

uom requires rustc 1.60.0 or later. Add this to your Cargo.toml:

[dependencies]
uom = "0.35.0"

and this to your crate root:

extern crate uom;

The simple example below shows how to use quantities and units as well as how uom stops invalid operations:

extern crate uom;

use uom::si::f32::*;
use uom::si::length::kilometer;
use uom::si::time::second;

fn main() {
    let length = Length::new::<kilometer>(5.0);
    let time = Time::new::<second>(15.0);
    let velocity/*: Velocity*/ = length / time;
    let _acceleration = calc_acceleration(velocity, time);
    //let error = length + time; // error[E0308]: mismatched types
}

fn calc_acceleration(velocity: Velocity, time: Time) -> Acceleration {
    velocity / time
}

See the examples directory for more advanced usage:

• si.rs -- Shows how to use the pre-built SI system.
• base.rs -- Shows how to create a set of Quantity type aliases for a different set of base units. See the Design section for implications of choosing different base units.
• mks.rs -- Shows how to create a custom system of quantities.
• unit.rs -- Shows how to add new units to existing quantities in the pre-build SI system.

Features

uom has multiple Cargo features for controlling available underlying storage types, the inclusion of the pre-built International System of Units (SI), support for Serde, and no_std functionality. The features are described below. f32, f64, std, and si are enabled by default. Features can be cherry-picked by using the --no-default-features and --features "..." flags when compiling uom or specifying features in Cargo.toml:

[dependencies]
uom = {
    version = "0.35.0",
    default-features = false,
    features = [
        "autoconvert", # automatic base unit conversion.
        "usize", "u8", "u16", "u32", "u64", "u128", # Unsigned integer storage types.
        "isize", "i8", "i16", "i32", "i64", "i128", # Signed integer storage types.
        "bigint", "biguint", # Arbitrary width integer storage types.
        "rational", "rational32", "rational64", "bigrational", # Integer ratio storage types.
        "complex32", "complex64", # Complex floating point storage types.
        "f32", "f64", # Floating point storage types.
        "si", "std", # Built-in SI system and std library support.
        "use_serde", # Serde support.
    ]
}

• autoconvert -- Feature to enable automatic conversion between base units in binary operators. Disabling the feature only allows for quantities with the same base units to directly interact. The feature exists to account for compiler limitations where zero-cost code is not generated for non-floating point underlying storage types.

• usize, u8, u16, u32, u64, u128, isize, i8, i16, i32, i64, i128, bigint, biguint, rational, rational32, rational64, bigrational, complex32, complex64, f32, f64 -- Features to enable underlying storage types. At least one of these features must be enabled. f32 and f64 are enabled by default. See the Design section for implications of choosing different underlying storage types.

• si -- Feature to include the pre-built International System of Units (SI). Enabled by default.

• std -- Feature to compile with standard library support. Disabling this feature compiles uom with no_std. Enabled by default.

• use_serde -- Feature to enable support for serialization and deserialization of quantities with the Serde crate. Disabled by default.

  Serde support for the big* and rational* underlying storage types requires manually enabling the serde feature for the num-rational and num-bigint crates. To do so, you can add one or both of the following lines to your Cargo.toml:

  num-rational = { version = "*", features = ["serde"] }
  num-bigint = { version = "*", features = ["serde"] }

Design

Rather than working with measurement units (meter, kilometer, foot, mile, ...) uom works with quantities (length, mass, time, ...). This simplifies usage because units are only involved at interface boundaries: the rest of your code only needs to be concerned about the quantities involved. This also makes operations on quantities (+, -, *, /, ...) have zero runtime cost over using the raw storage type (e.g. f32).

uom normalizes values to the base unit for the quantity. Alternative base units can be used by executing the macro defined for the system of quantities (ISQ! for the SI). uom supports usize, u8, u16, u32, u64, u128, isize, i8, i16, i32, i64, i128, bigint, biguint, rational, rational32, rational64, bigrational, complex32, complex64, f32, and f64 as the underlying storage type.

A consequence of normalizing values to the base unit is that some values may not be able to be represented or can't be precisely represented for floating point and rational underlying storage types. For example if the base unit of length is meter and the underlying storage type is i32 then values like 1 centimeter or 1.1 meter cannot be represented. 1 centimeter is normalized to 0.01 meter which can't be stored in an i32. uom only allows units to be used safely. Users of this library will still need to be aware of implementation details of the underlying storage type including limits and precision.

Contributing

Contributions are welcome from everyone. Submit a pull request, an issue, or just add comments to an existing item. The International Bureau of Weights and Measures is an international standards organization that publishes the SI Brochure. This document defines the SI and can be used as a comprehensive reference for changes to uom. Conversion factors for non-SI units can be found in NIST Special Publication 811.

Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as below, without any additional terms or conditions.

License

Licensed under either of

• Apache License, Version 2.0, (LICENSE-APACHE or https://www.apache.org/licenses/LICENSE-2.0)
• MIT license (LICENSE-MIT or https://opensource.org/licenses/MIT)

at your option.