Change Meter to Metre
This commit is contained in:
parent
44ff54160c
commit
fa40445683
@ -1,6 +1,6 @@
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[package]
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name = "units"
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version = "0.1.0"
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version = "0.2.0"
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edition = "2021"
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description = "Si units for typesafe calculations"
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license = "MIT or Apache-2.0"
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167
src/display.rs
167
src/display.rs
@ -1,19 +1,16 @@
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#[cfg(not(feature = "std"))]
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use core::fmt::{self, Display, Formatter};
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#[cfg(feature = "std")]
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use std::fmt::{self, Display, Formatter};
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use typenum::Integer;
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use crate::{
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types::{
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AmperePerMeter, AmperePerSquareMeter, Coulomb, CoulombPerCubicMeter, CoulombPerKilogram,
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CoulombPerSquareMeter, CubicMeterPerKilogram, Farad, FaradPerMeter, Gray, GrayPerSecond,
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Henry, HenryPerMeter, Herz, Joule, JoulePerKelvin, JoulePerKilogramKelvin, JoulePerMole,
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JoulePerMoleKelvin, Katal, KatalPerCubicMeter, KilogramPerCubicMeter,
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KilogramPerSquareMeter, Lux, MeterPerSecond, MeterPerSquareSecond, MolePerCubicMeter,
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Newton, NewtonPerMeter, Ohm, Pascal, PascalSecond, Siemens, Tesla, Volt, VoltPerMeter,
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Watt, WattPerMeterKelvin, WattPerSquareMeter, Weber,
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AmperePerMetre, AmperePerSquareMetre, Coulomb, CoulombPerCubicMetre, CoulombPerKilogram,
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CoulombPerSquareMetre, CubicMetrePerKilogram, Farad, FaradPerMetre, Gray, GrayPerSecond,
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Henry, HenryPerMetre, Herz, Joule, JoulePerKelvin, JoulePerKilogramKelvin, JoulePerMole,
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JoulePerMoleKelvin, Katal, KatalPerCubicMetre, KilogramPerCubicMetre,
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KilogramPerSquareMetre, Lux, MetrePerSecond, MetrePerSquareSecond, MolePerCubicMetre,
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Newton, NewtonPerMetre, Ohm, Pascal, PascalSecond, Siemens, Tesla, Volt, VoltPerMetre,
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Watt, WattPerMetreKelvin, WattPerSquareMetre, Weber,
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},
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SiUnit,
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};
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@ -53,11 +50,11 @@ macro_rules! display_special_unit_defmt {
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}
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#[cfg(feature = "defmt")]
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impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> defmt::Format
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for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
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impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> defmt::Format
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for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
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where
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Second: Integer,
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Meter: Integer,
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Metre: Integer,
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Kilogram: Integer,
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Ampere: Integer,
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Kelvin: Integer,
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@ -89,43 +86,43 @@ where
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);
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// derived units
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display_special_unit_defmt!(f, Self,
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("m/s", MeterPerSecond<T>),
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("m/s²", MeterPerSquareSecond<T>),
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("kg/m³", KilogramPerCubicMeter<T>),
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("kg/m²", KilogramPerSquareMeter<T>),
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("m³/kg", CubicMeterPerKilogram<T>),
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("A/m²", AmperePerSquareMeter<T>),
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("A/m", AmperePerMeter<T>),
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("mol/m³", MolePerCubicMeter<T>),
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("m/s", MetrePerSecond<T>),
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("m/s²", MetrePerSquareSecond<T>),
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("kg/m³", KilogramPerCubicMetre<T>),
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("kg/m²", KilogramPerSquareMetre<T>),
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("m³/kg", CubicMetrePerKilogram<T>),
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("A/m²", AmperePerSquareMetre<T>),
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("A/m", AmperePerMetre<T>),
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("mol/m³", MolePerCubicMetre<T>),
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);
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// derived units including special names
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display_special_unit_defmt!(f, Self,
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("Pa*s", PascalSecond<T>),
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("N/m", NewtonPerMeter<T>),
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("W/m²", WattPerSquareMeter<T>),
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("N/m", NewtonPerMetre<T>),
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("W/m²", WattPerSquareMetre<T>),
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("J/K", JoulePerKelvin<T>),
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("J/(kg*K)", JoulePerKilogramKelvin<T>),
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("W/(m*K)", WattPerMeterKelvin<T>),
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("V/m", VoltPerMeter<T>),
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("C/m³", CoulombPerCubicMeter<T>),
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("C/m²", CoulombPerSquareMeter<T>),
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("F/m", FaradPerMeter<T>),
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("H/m", HenryPerMeter<T>),
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("W/(m*K)", WattPerMetreKelvin<T>),
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("V/m", VoltPerMetre<T>),
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("C/m³", CoulombPerCubicMetre<T>),
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("C/m²", CoulombPerSquareMetre<T>),
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("F/m", FaradPerMetre<T>),
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("H/m", HenryPerMetre<T>),
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("J/mol", JoulePerMole<T>),
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("J/(mol*K)", JoulePerMoleKelvin<T>),
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("C/kg", CoulombPerKilogram<T>),
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("Gy/s", GrayPerSecond<T>),
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("kat/m³", KatalPerCubicMeter<T>),
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("kat/m³", KatalPerCubicMetre<T>),
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);
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// base units
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display_unit_defmt!(f, Second, "s", Meter, Kilogram, Ampere, Kelvin, Mole, Candela);
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display_unit_defmt!(f, Meter, "m", Second, Kilogram, Ampere, Kelvin, Mole, Candela);
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display_unit_defmt!(f, Kilogram, "kg", Second, Meter, Ampere, Kelvin, Mole, Candela);
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display_unit_defmt!(f, Ampere, "A", Second, Meter, Kilogram, Kelvin, Mole, Candela);
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display_unit_defmt!(f, Kelvin, "K", Second, Meter, Kilogram, Ampere, Mole, Candela);
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display_unit_defmt!(f, Mole, "mol", Second, Meter, Kilogram, Ampere, Kelvin, Candela);
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display_unit_defmt!(f, Candela, "cd", Second, Meter, Kilogram, Ampere, Kelvin, Mole);
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display_unit_defmt!(f, Second, "s", Metre, Kilogram, Ampere, Kelvin, Mole, Candela);
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display_unit_defmt!(f, Metre, "m", Second, Kilogram, Ampere, Kelvin, Mole, Candela);
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display_unit_defmt!(f, Kilogram, "kg", Second, Metre, Ampere, Kelvin, Mole, Candela);
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display_unit_defmt!(f, Ampere, "A", Second, Metre, Kilogram, Kelvin, Mole, Candela);
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display_unit_defmt!(f, Kelvin, "K", Second, Metre, Kilogram, Ampere, Mole, Candela);
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display_unit_defmt!(f, Mole, "mol", Second, Metre, Kilogram, Ampere, Kelvin, Candela);
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display_unit_defmt!(f, Candela, "cd", Second, Metre, Kilogram, Ampere, Kelvin, Mole);
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}
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}
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@ -160,11 +157,11 @@ macro_rules! display_special_unit {
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};
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}
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impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Display
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for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
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impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Display
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for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
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where
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Second: Integer,
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Meter: Integer,
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Metre: Integer,
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Kilogram: Integer,
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Ampere: Integer,
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Kelvin: Integer,
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@ -195,65 +192,67 @@ where
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);
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// derived units
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display_special_unit!(f, Self,
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("m/s", MeterPerSecond<T>),
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("m/s²", MeterPerSquareSecond<T>),
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("kg/m³", KilogramPerCubicMeter<T>),
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("kg/m²", KilogramPerSquareMeter<T>),
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("m³/kg", CubicMeterPerKilogram<T>),
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("A/m²", AmperePerSquareMeter<T>),
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("A/m", AmperePerMeter<T>),
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("mol/m³", MolePerCubicMeter<T>),
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("m/s", MetrePerSecond<T>),
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("m/s²", MetrePerSquareSecond<T>),
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("kg/m³", KilogramPerCubicMetre<T>),
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("kg/m²", KilogramPerSquareMetre<T>),
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("m³/kg", CubicMetrePerKilogram<T>),
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("A/m²", AmperePerSquareMetre<T>),
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("A/m", AmperePerMetre<T>),
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("mol/m³", MolePerCubicMetre<T>),
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);
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// derived units including special names
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display_special_unit!(f, Self,
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("Pa*s", PascalSecond<T>),
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("N/m", NewtonPerMeter<T>),
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("W/m²", WattPerSquareMeter<T>),
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("N/m", NewtonPerMetre<T>),
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("W/m²", WattPerSquareMetre<T>),
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("J/K", JoulePerKelvin<T>),
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("J/(kg*K)", JoulePerKilogramKelvin<T>),
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("W/(m*K)", WattPerMeterKelvin<T>),
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("V/m", VoltPerMeter<T>),
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("C/m³", CoulombPerCubicMeter<T>),
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("C/m²", CoulombPerSquareMeter<T>),
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("F/m", FaradPerMeter<T>),
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("H/m", HenryPerMeter<T>),
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("W/(m*K)", WattPerMetreKelvin<T>),
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("V/m", VoltPerMetre<T>),
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("C/m³", CoulombPerCubicMetre<T>),
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("C/m²", CoulombPerSquareMetre<T>),
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("F/m", FaradPerMetre<T>),
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("H/m", HenryPerMetre<T>),
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("J/mol", JoulePerMole<T>),
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("J/(mol*K)", JoulePerMoleKelvin<T>),
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("C/kg", CoulombPerKilogram<T>),
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("Gy/s", GrayPerSecond<T>),
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("kat/m³", KatalPerCubicMeter<T>),
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("kat/m³", KatalPerCubicMetre<T>),
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);
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// base units
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display_unit!(f, Second, "s", Meter, Kilogram, Ampere, Kelvin, Mole, Candela);
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display_unit!(f, Meter, "m", Second, Kilogram, Ampere, Kelvin, Mole, Candela);
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display_unit!(f, Kilogram, "kg", Second, Meter, Ampere, Kelvin, Mole, Candela);
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display_unit!(f, Ampere, "A", Second, Meter, Kilogram, Kelvin, Mole, Candela);
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display_unit!(f, Kelvin, "K", Second, Meter, Kilogram, Ampere, Mole, Candela);
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display_unit!(f, Mole, "mol", Second, Meter, Kilogram, Ampere, Kelvin, Candela);
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display_unit!(f, Candela, "cd", Second, Meter, Kilogram, Ampere, Kelvin, Mole);
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display_unit!(f, Second, "s", Metre, Kilogram, Ampere, Kelvin, Mole, Candela);
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display_unit!(f, Metre, "m", Second, Kilogram, Ampere, Kelvin, Mole, Candela);
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display_unit!(f, Kilogram, "kg", Second, Metre, Ampere, Kelvin, Mole, Candela);
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display_unit!(f, Ampere, "A", Second, Metre, Kilogram, Kelvin, Mole, Candela);
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display_unit!(f, Kelvin, "K", Second, Metre, Kilogram, Ampere, Mole, Candela);
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display_unit!(f, Mole, "mol", Second, Metre, Kilogram, Ampere, Kelvin, Candela);
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display_unit!(f, Candela, "cd", Second, Metre, Kilogram, Ampere, Kelvin, Mole);
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Ok(())
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}
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}
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#[cfg(test)]
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mod test {
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use crate::types::{Ampere, Candela, Kelvin, Kilogram, Meter, Mole, Second, Unit};
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use crate::types::{Ampere, Candela, Kelvin, Kilogram, Metre, Mole, Second, Unit};
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use super::*;
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#[test]
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#[cfg(feature = "std")]
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fn debug() {
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let m = Meter::new(2);
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let m = Metre::new(2);
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assert_eq!(format!("{m:?}"), "SiUnit { value: 2, _s: PhantomData<typenum::int::Z0>, _m: PhantomData<typenum::int::PInt<typenum::uint::UInt<typenum::uint::UTerm, typenum::bit::B1>>>, _kg: PhantomData<typenum::int::Z0>, _a: PhantomData<typenum::int::Z0>, _k: PhantomData<typenum::int::Z0>, _mol: PhantomData<typenum::int::Z0>, _cd: PhantomData<typenum::int::Z0> }".to_owned());
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}
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#[test]
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#[allow(clippy::cognitive_complexity)]
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#[cfg(feature = "std")]
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fn display() {
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let unit = Unit::new(2);
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let second = Second::new(2);
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let meter = Meter::new(2);
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let meter = Metre::new(2);
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let kilogram = Kilogram::new(2);
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let ampere = Ampere::new(2);
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let kelvin = Kelvin::new(2);
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@ -299,30 +298,30 @@ mod test {
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assert_eq!(Gray::new(2).to_string(), "2Gy|Sv");
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assert_eq!(Katal::new(2).to_string(), "2kat");
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assert_eq!(MeterPerSecond::new(2).to_string(), "2m/s");
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assert_eq!(MeterPerSquareSecond::new(2).to_string(), "2m/s²");
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assert_eq!(KilogramPerCubicMeter::new(2).to_string(), "2kg/m³");
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assert_eq!(KilogramPerSquareMeter::new(2).to_string(), "2kg/m²");
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assert_eq!(CubicMeterPerKilogram::new(2).to_string(), "2m³/kg");
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assert_eq!(AmperePerSquareMeter::new(2).to_string(), "2A/m²");
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assert_eq!(AmperePerMeter::new(2).to_string(), "2A/m");
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assert_eq!(MolePerCubicMeter::new(2).to_string(), "2mol/m³");
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assert_eq!(MetrePerSecond::new(2).to_string(), "2m/s");
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assert_eq!(MetrePerSquareSecond::new(2).to_string(), "2m/s²");
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assert_eq!(KilogramPerCubicMetre::new(2).to_string(), "2kg/m³");
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assert_eq!(KilogramPerSquareMetre::new(2).to_string(), "2kg/m²");
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assert_eq!(CubicMetrePerKilogram::new(2).to_string(), "2m³/kg");
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assert_eq!(AmperePerSquareMetre::new(2).to_string(), "2A/m²");
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assert_eq!(AmperePerMetre::new(2).to_string(), "2A/m");
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assert_eq!(MolePerCubicMetre::new(2).to_string(), "2mol/m³");
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assert_eq!(PascalSecond::new(2).to_string(), "2Pa*s");
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assert_eq!(NewtonPerMeter::new(2).to_string(), "2N/m");
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assert_eq!(WattPerSquareMeter::new(2).to_string(), "2W/m²");
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assert_eq!(NewtonPerMetre::new(2).to_string(), "2N/m");
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assert_eq!(WattPerSquareMetre::new(2).to_string(), "2W/m²");
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assert_eq!(JoulePerKelvin::new(2).to_string(), "2J/K");
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assert_eq!(JoulePerKilogramKelvin::new(2).to_string(), "2J/(kg*K)");
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assert_eq!(WattPerMeterKelvin::new(2).to_string(), "2W/(m*K)");
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assert_eq!(VoltPerMeter::new(2).to_string(), "2V/m");
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assert_eq!(CoulombPerCubicMeter::new(2).to_string(), "2C/m³");
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assert_eq!(CoulombPerSquareMeter::new(2).to_string(), "2C/m²");
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assert_eq!(FaradPerMeter::new(2).to_string(), "2F/m");
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assert_eq!(HenryPerMeter::new(2).to_string(), "2H/m");
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assert_eq!(WattPerMetreKelvin::new(2).to_string(), "2W/(m*K)");
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assert_eq!(VoltPerMetre::new(2).to_string(), "2V/m");
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assert_eq!(CoulombPerCubicMetre::new(2).to_string(), "2C/m³");
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assert_eq!(CoulombPerSquareMetre::new(2).to_string(), "2C/m²");
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assert_eq!(FaradPerMetre::new(2).to_string(), "2F/m");
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assert_eq!(HenryPerMetre::new(2).to_string(), "2H/m");
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assert_eq!(JoulePerMole::new(2).to_string(), "2J/mol");
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assert_eq!(JoulePerMoleKelvin::new(2).to_string(), "2J/(mol*K)");
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assert_eq!(CoulombPerKilogram::new(2).to_string(), "2C/kg");
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assert_eq!(GrayPerSecond::new(2).to_string(), "2Gy/s");
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assert_eq!(KatalPerCubicMeter::new(2).to_string(), "2kat/m³");
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assert_eq!(KatalPerCubicMetre::new(2).to_string(), "2kat/m³");
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}
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}
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255
src/lib.rs
255
src/lib.rs
@ -2,7 +2,6 @@
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mod display;
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pub mod types;
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#[cfg(not(feature = "std"))]
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use core::{
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marker::PhantomData,
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ops::{
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@ -10,24 +9,16 @@ use core::{
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SubAssign,
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},
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};
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#[cfg(feature = "std")]
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use std::{
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marker::PhantomData,
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ops::{
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Add, AddAssign, Deref, DerefMut, Div, DivAssign, Mul, MulAssign, Neg, Rem, RemAssign, Sub,
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SubAssign,
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},
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};
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use num_traits::{Num, One, Zero};
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use typenum::{int::Z0, op, Integer};
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use types::Unit;
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#[derive(Debug, PartialEq, Eq, PartialOrd, Ord, Clone, Copy)]
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pub struct SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
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pub struct SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
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where
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Second: Integer,
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Meter: Integer,
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Metre: Integer,
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Kilogram: Integer,
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Ampere: Integer,
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Kelvin: Integer,
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@ -36,7 +27,7 @@ where
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{
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value: T,
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_s: PhantomData<Second>,
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_m: PhantomData<Meter>,
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_m: PhantomData<Metre>,
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_kg: PhantomData<Kilogram>,
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_a: PhantomData<Ampere>,
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_k: PhantomData<Kelvin>,
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@ -44,11 +35,11 @@ where
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_cd: PhantomData<Candela>,
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}
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impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Deref
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for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
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impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Deref
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for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
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where
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Second: Integer,
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Meter: Integer,
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Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -62,11 +53,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> DerefMut
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> DerefMut
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -78,11 +69,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Neg
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Neg
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -90,18 +81,18 @@ where
|
||||
Candela: Integer,
|
||||
T: Neg,
|
||||
{
|
||||
type Output = SiUnit<T::Output, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>;
|
||||
type Output = SiUnit<T::Output, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>;
|
||||
|
||||
fn neg(self) -> Self::Output {
|
||||
Self::Output::new(-self.value)
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Zero
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Zero
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -118,11 +109,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> One
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> One
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer + Add<Output = Second>,
|
||||
Meter: Integer + Add<Output = Meter>,
|
||||
Metre: Integer + Add<Output = Metre>,
|
||||
Kilogram: Integer + Add<Output = Kilogram>,
|
||||
Ampere: Integer + Add<Output = Ampere>,
|
||||
Kelvin: Integer + Add<Output = Kelvin>,
|
||||
@ -130,7 +121,7 @@ where
|
||||
Candela: Integer + Add<Output = Candela>,
|
||||
T: One,
|
||||
<Second as Add>::Output: Integer,
|
||||
<Meter as Add>::Output: Integer,
|
||||
<Metre as Add>::Output: Integer,
|
||||
<Kilogram as Add>::Output: Integer,
|
||||
<Ampere as Add>::Output: Integer,
|
||||
<Kelvin as Add>::Output: Integer,
|
||||
@ -142,11 +133,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Num
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Num
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer + Add<Output = Second> + Sub<Output = Second> + PartialEq,
|
||||
Meter: Integer + Add<Output = Meter> + Sub<Output = Meter> + PartialEq,
|
||||
Metre: Integer + Add<Output = Metre> + Sub<Output = Metre> + PartialEq,
|
||||
Kilogram: Integer + Add<Output = Kilogram> + Sub<Output = Kilogram> + PartialEq,
|
||||
Ampere: Integer + Add<Output = Ampere> + Sub<Output = Ampere> + PartialEq,
|
||||
Kelvin: Integer + Add<Output = Kelvin> + Sub<Output = Kelvin> + PartialEq,
|
||||
@ -161,11 +152,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Add
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Add
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -173,18 +164,18 @@ where
|
||||
Candela: Integer,
|
||||
T: Add,
|
||||
{
|
||||
type Output = SiUnit<T::Output, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>;
|
||||
type Output = SiUnit<T::Output, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>;
|
||||
|
||||
fn add(self, rhs: Self) -> Self::Output {
|
||||
Self::Output::new(self.value + rhs.value)
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> AddAssign
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> AddAssign
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -197,11 +188,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Sub
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Sub
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -209,18 +200,18 @@ where
|
||||
Candela: Integer,
|
||||
T: Sub,
|
||||
{
|
||||
type Output = SiUnit<T::Output, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>;
|
||||
type Output = SiUnit<T::Output, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>;
|
||||
|
||||
fn sub(self, rhs: Self) -> Self::Output {
|
||||
Self::Output::new(self.value - rhs.value)
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> SubAssign
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> SubAssign
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -233,11 +224,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Mul<T>
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Mul<T>
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -252,11 +243,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> MulAssign<T>
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> MulAssign<T>
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -269,11 +260,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Div<T>
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Div<T>
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer + Sub<Z0>,
|
||||
Meter: Integer + Sub<Z0>,
|
||||
Metre: Integer + Sub<Z0>,
|
||||
Kilogram: Integer + Sub<Z0>,
|
||||
Ampere: Integer + Sub<Z0>,
|
||||
Kelvin: Integer + Sub<Z0>,
|
||||
@ -281,7 +272,7 @@ where
|
||||
Candela: Integer + Sub<Z0>,
|
||||
T: Div,
|
||||
<Second as Sub<Z0>>::Output: Integer,
|
||||
<Meter as Sub<Z0>>::Output: Integer,
|
||||
<Metre as Sub<Z0>>::Output: Integer,
|
||||
<Kilogram as Sub<Z0>>::Output: Integer,
|
||||
<Ampere as Sub<Z0>>::Output: Integer,
|
||||
<Kelvin as Sub<Z0>>::Output: Integer,
|
||||
@ -295,11 +286,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> DivAssign<T>
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> DivAssign<T>
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -312,11 +303,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> Rem<T>
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> Rem<T>
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer + Sub<Z0>,
|
||||
Meter: Integer + Sub<Z0>,
|
||||
Metre: Integer + Sub<Z0>,
|
||||
Kilogram: Integer + Sub<Z0>,
|
||||
Ampere: Integer + Sub<Z0>,
|
||||
Kelvin: Integer + Sub<Z0>,
|
||||
@ -324,7 +315,7 @@ where
|
||||
Candela: Integer + Sub<Z0>,
|
||||
T: Rem,
|
||||
<Second as Sub<Z0>>::Output: Integer,
|
||||
<Meter as Sub<Z0>>::Output: Integer,
|
||||
<Metre as Sub<Z0>>::Output: Integer,
|
||||
<Kilogram as Sub<Z0>>::Output: Integer,
|
||||
<Ampere as Sub<Z0>>::Output: Integer,
|
||||
<Kelvin as Sub<Z0>>::Output: Integer,
|
||||
@ -338,11 +329,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela> RemAssign<T>
|
||||
for SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela> RemAssign<T>
|
||||
for SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -355,11 +346,11 @@ where
|
||||
}
|
||||
}
|
||||
|
||||
impl<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
SiUnit<T, Second, Meter, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
impl<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
SiUnit<T, Second, Metre, Kilogram, Ampere, Kelvin, Mole, Candela>
|
||||
where
|
||||
Second: Integer,
|
||||
Meter: Integer,
|
||||
Metre: Integer,
|
||||
Kilogram: Integer,
|
||||
Ampere: Integer,
|
||||
Kelvin: Integer,
|
||||
@ -383,21 +374,21 @@ where
|
||||
impl<
|
||||
T,
|
||||
Second1,
|
||||
Meter1,
|
||||
Metre1,
|
||||
Kilogram1,
|
||||
Ampere1,
|
||||
Kelvin1,
|
||||
Mole1,
|
||||
Candela1,
|
||||
Second2,
|
||||
Meter2,
|
||||
Metre2,
|
||||
Kilogram2,
|
||||
Ampere2,
|
||||
Kelvin2,
|
||||
Mole2,
|
||||
Candela2,
|
||||
> Mul<SiUnit<T, Second1, Meter1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>>
|
||||
for SiUnit<T, Second2, Meter2, Kilogram2, Ampere2, Kelvin2, Mole2, Candela2>
|
||||
> Mul<SiUnit<T, Second1, Metre1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>>
|
||||
for SiUnit<T, Second2, Metre2, Kilogram2, Ampere2, Kelvin2, Mole2, Candela2>
|
||||
where
|
||||
Mole2: Integer,
|
||||
Candela2: Integer,
|
||||
@ -406,16 +397,16 @@ where
|
||||
Kelvin1: Integer + Add<Kelvin2>,
|
||||
Ampere1: Integer + Add<Ampere2>,
|
||||
Kilogram1: Integer + Add<Kilogram2>,
|
||||
Meter1: Integer + Add<Meter2>,
|
||||
Metre1: Integer + Add<Metre2>,
|
||||
Second1: Integer + Add<Second2>,
|
||||
Kelvin2: Integer,
|
||||
Ampere2: Integer,
|
||||
Kilogram2: Integer,
|
||||
Meter2: Integer,
|
||||
Metre2: Integer,
|
||||
Second2: Integer,
|
||||
T: Mul,
|
||||
Second1::Output: Integer,
|
||||
Meter1::Output: Integer,
|
||||
Metre1::Output: Integer,
|
||||
Kilogram1::Output: Integer,
|
||||
Ampere1::Output: Integer,
|
||||
Kelvin1::Output: Integer,
|
||||
@ -425,7 +416,7 @@ where
|
||||
type Output = SiUnit<
|
||||
T::Output,
|
||||
op!(Second1 + Second2),
|
||||
op!(Meter1 + Meter2),
|
||||
op!(Metre1 + Metre2),
|
||||
op!(Kilogram1 + Kilogram2),
|
||||
op!(Ampere1 + Ampere2),
|
||||
op!(Kelvin1 + Kelvin2),
|
||||
@ -435,7 +426,7 @@ where
|
||||
|
||||
fn mul(
|
||||
self,
|
||||
rhs: SiUnit<T, Second1, Meter1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>,
|
||||
rhs: SiUnit<T, Second1, Metre1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>,
|
||||
) -> Self::Output {
|
||||
Self::Output::new(self.value * rhs.value)
|
||||
}
|
||||
@ -444,31 +435,31 @@ where
|
||||
impl<
|
||||
T,
|
||||
Second1,
|
||||
Meter1,
|
||||
Metre1,
|
||||
Kilogram1,
|
||||
Ampere1,
|
||||
Kelvin1,
|
||||
Mole1,
|
||||
Candela1,
|
||||
Second2,
|
||||
Meter2,
|
||||
Metre2,
|
||||
Kilogram2,
|
||||
Ampere2,
|
||||
Kelvin2,
|
||||
Mole2,
|
||||
Candela2,
|
||||
> Div<SiUnit<T, Second1, Meter1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>>
|
||||
for SiUnit<T, Second2, Meter2, Kilogram2, Ampere2, Kelvin2, Mole2, Candela2>
|
||||
> Div<SiUnit<T, Second1, Metre1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>>
|
||||
for SiUnit<T, Second2, Metre2, Kilogram2, Ampere2, Kelvin2, Mole2, Candela2>
|
||||
where
|
||||
Second1: Integer,
|
||||
Meter1: Integer,
|
||||
Metre1: Integer,
|
||||
Kilogram1: Integer,
|
||||
Ampere1: Integer,
|
||||
Kelvin1: Integer,
|
||||
Mole1: Integer,
|
||||
Candela1: Integer,
|
||||
Second2: Integer + Sub<Second1>,
|
||||
Meter2: Integer + Sub<Meter1>,
|
||||
Metre2: Integer + Sub<Metre1>,
|
||||
Kilogram2: Integer + Sub<Kilogram1>,
|
||||
Ampere2: Integer + Sub<Ampere1>,
|
||||
Kelvin2: Integer + Sub<Kelvin1>,
|
||||
@ -476,7 +467,7 @@ where
|
||||
Candela2: Integer + Sub<Candela1>,
|
||||
T: Div,
|
||||
Second2::Output: Integer,
|
||||
Meter2::Output: Integer,
|
||||
Metre2::Output: Integer,
|
||||
Kilogram2::Output: Integer,
|
||||
Ampere2::Output: Integer,
|
||||
Kelvin2::Output: Integer,
|
||||
@ -486,7 +477,7 @@ where
|
||||
type Output = SiUnit<
|
||||
T::Output,
|
||||
op!(Second2 - Second1),
|
||||
op!(Meter2 - Meter1),
|
||||
op!(Metre2 - Metre1),
|
||||
op!(Kilogram2 - Kilogram1),
|
||||
op!(Ampere2 - Ampere1),
|
||||
op!(Kelvin2 - Kelvin1),
|
||||
@ -496,7 +487,7 @@ where
|
||||
|
||||
fn div(
|
||||
self,
|
||||
rhs: SiUnit<T, Second1, Meter1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>,
|
||||
rhs: SiUnit<T, Second1, Metre1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>,
|
||||
) -> Self::Output {
|
||||
Self::Output::new(self.value / rhs.value)
|
||||
}
|
||||
@ -505,31 +496,31 @@ where
|
||||
impl<
|
||||
T,
|
||||
Second1,
|
||||
Meter1,
|
||||
Metre1,
|
||||
Kilogram1,
|
||||
Ampere1,
|
||||
Kelvin1,
|
||||
Mole1,
|
||||
Candela1,
|
||||
Second2,
|
||||
Meter2,
|
||||
Metre2,
|
||||
Kilogram2,
|
||||
Ampere2,
|
||||
Kelvin2,
|
||||
Mole2,
|
||||
Candela2,
|
||||
> Rem<SiUnit<T, Second1, Meter1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>>
|
||||
for SiUnit<T, Second2, Meter2, Kilogram2, Ampere2, Kelvin2, Mole2, Candela2>
|
||||
> Rem<SiUnit<T, Second1, Metre1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>>
|
||||
for SiUnit<T, Second2, Metre2, Kilogram2, Ampere2, Kelvin2, Mole2, Candela2>
|
||||
where
|
||||
Second1: Integer,
|
||||
Meter1: Integer,
|
||||
Metre1: Integer,
|
||||
Kilogram1: Integer,
|
||||
Ampere1: Integer,
|
||||
Kelvin1: Integer,
|
||||
Mole1: Integer,
|
||||
Candela1: Integer,
|
||||
Second2: Integer + Sub<Second1>,
|
||||
Meter2: Integer + Sub<Meter1>,
|
||||
Metre2: Integer + Sub<Metre1>,
|
||||
Kilogram2: Integer + Sub<Kilogram1>,
|
||||
Ampere2: Integer + Sub<Ampere1>,
|
||||
Kelvin2: Integer + Sub<Kelvin1>,
|
||||
@ -537,7 +528,7 @@ where
|
||||
Candela2: Integer + Sub<Candela1>,
|
||||
T: Rem,
|
||||
Second2::Output: Integer,
|
||||
Meter2::Output: Integer,
|
||||
Metre2::Output: Integer,
|
||||
Kilogram2::Output: Integer,
|
||||
Ampere2::Output: Integer,
|
||||
Kelvin2::Output: Integer,
|
||||
@ -547,7 +538,7 @@ where
|
||||
type Output = SiUnit<
|
||||
T::Output,
|
||||
op!(Second2 - Second1),
|
||||
op!(Meter2 - Meter1),
|
||||
op!(Metre2 - Metre1),
|
||||
op!(Kilogram2 - Kilogram1),
|
||||
op!(Ampere2 - Ampere1),
|
||||
op!(Kelvin2 - Kelvin1),
|
||||
@ -557,7 +548,7 @@ where
|
||||
|
||||
fn rem(
|
||||
self,
|
||||
rhs: SiUnit<T, Second1, Meter1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>,
|
||||
rhs: SiUnit<T, Second1, Metre1, Kilogram1, Ampere1, Kelvin1, Mole1, Candela1>,
|
||||
) -> Self::Output {
|
||||
Self::Output::new(self.value % rhs.value)
|
||||
}
|
||||
@ -566,20 +557,20 @@ where
|
||||
#[cfg(test)]
|
||||
mod test {
|
||||
use super::types::{
|
||||
Ampere, Coulomb, CubicMeter, Meter, ReciprocalMeter, Second, SquareMeter, Unit, Volt, Watt,
|
||||
Ampere, Coulomb, CubicMetre, Metre, ReciprocalMetre, Second, SquareMetre, Unit, Volt, Watt,
|
||||
};
|
||||
use num_traits::{Num, One, Zero};
|
||||
|
||||
#[test]
|
||||
fn clone() {
|
||||
let m = Meter::new(2);
|
||||
let m = Metre::new(2);
|
||||
assert_eq!(m.clone(), m);
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn ord() {
|
||||
let a = Meter::new(2);
|
||||
let b = Meter::new(3);
|
||||
let a = Metre::new(2);
|
||||
let b = Metre::new(3);
|
||||
assert!(a < b);
|
||||
assert!(b > a);
|
||||
assert!(a == a);
|
||||
@ -590,27 +581,27 @@ mod test {
|
||||
|
||||
#[test]
|
||||
fn deref() {
|
||||
let m = Meter::new(2);
|
||||
let m = Metre::new(2);
|
||||
assert_eq!(*m, 2);
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn deref_mut() {
|
||||
let mut m = Meter::new(2);
|
||||
let mut m = Metre::new(2);
|
||||
*m = 3;
|
||||
assert_eq!(*m, 3);
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn neg() {
|
||||
let m = Meter::new(2);
|
||||
assert_eq!(-m, Meter::new(-2));
|
||||
let m = Metre::new(2);
|
||||
assert_eq!(-m, Metre::new(-2));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn zero() {
|
||||
let z = Meter::zero();
|
||||
assert_eq!(z, Meter::new(0));
|
||||
let z = Metre::zero();
|
||||
assert_eq!(z, Metre::new(0));
|
||||
assert!(z.is_zero());
|
||||
}
|
||||
|
||||
@ -627,89 +618,89 @@ mod test {
|
||||
|
||||
#[test]
|
||||
fn add() {
|
||||
let m = Meter::new(2);
|
||||
assert_eq!(m + m, Meter::new(4));
|
||||
assert_eq!(m + m + m, Meter::new(6));
|
||||
let m = Metre::new(2);
|
||||
assert_eq!(m + m, Metre::new(4));
|
||||
assert_eq!(m + m + m, Metre::new(6));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn add_assign() {
|
||||
let mut m = Meter::new(2);
|
||||
let mut m = Metre::new(2);
|
||||
m += m;
|
||||
assert_eq!(m, Meter::new(4));
|
||||
assert_eq!(m, Metre::new(4));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn sub() {
|
||||
let m = Meter::new(2);
|
||||
assert_eq!(m - m, Meter::new(0));
|
||||
assert_eq!(m - m - m, Meter::new(-2));
|
||||
let m = Metre::new(2);
|
||||
assert_eq!(m - m, Metre::new(0));
|
||||
assert_eq!(m - m - m, Metre::new(-2));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn sub_assign() {
|
||||
let mut m = Meter::new(2);
|
||||
let mut m = Metre::new(2);
|
||||
m -= m;
|
||||
assert_eq!(m, Meter::new(0));
|
||||
assert_eq!(m, Metre::new(0));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn mul() {
|
||||
let m = Meter::new(2);
|
||||
assert_eq!(m * m, SquareMeter::new(4));
|
||||
assert_eq!(m * m * m, CubicMeter::new(8));
|
||||
let m = Metre::new(2);
|
||||
assert_eq!(m * m, SquareMetre::new(4));
|
||||
assert_eq!(m * m * m, CubicMetre::new(8));
|
||||
let s = Second::new(1);
|
||||
let a = Ampere::new(2);
|
||||
assert_eq!(s * a, Coulomb::new(2));
|
||||
let v = Volt::new(2);
|
||||
assert_eq!(v * a, Watt::new(4));
|
||||
assert_eq!(m * 2, Meter::new(4));
|
||||
assert_eq!(m * 2, Metre::new(4));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn mul_assign() {
|
||||
let mut m = Meter::new(2);
|
||||
let mut m = Metre::new(2);
|
||||
m *= 2;
|
||||
assert_eq!(m, Meter::new(4));
|
||||
assert_eq!(m, Metre::new(4));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn div() {
|
||||
let m = Meter::new(2);
|
||||
let m = Metre::new(2);
|
||||
assert_eq!(m / m, Unit::new(1));
|
||||
assert_eq!(m / m / m, ReciprocalMeter::new(0));
|
||||
assert_eq!(m / m / m, ReciprocalMetre::new(0));
|
||||
let c = Coulomb::new(4);
|
||||
let a = Ampere::new(2);
|
||||
assert_eq!(c / a, Second::new(2));
|
||||
let w = Watt::new(2);
|
||||
assert_eq!(w / a, Volt::new(1));
|
||||
assert_eq!(m / 2, Meter::new(1));
|
||||
assert_eq!(m / 2, Metre::new(1));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn div_assign() {
|
||||
let mut m = Meter::new(2);
|
||||
let mut m = Metre::new(2);
|
||||
m /= 2;
|
||||
assert_eq!(m, Meter::new(1));
|
||||
assert_eq!(m, Metre::new(1));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn rem() {
|
||||
let m = Meter::new(2);
|
||||
let m = Metre::new(2);
|
||||
assert_eq!(m % m, Unit::new(0));
|
||||
assert_eq!(m / m % m, ReciprocalMeter::new(1));
|
||||
assert_eq!(m / m % m, ReciprocalMetre::new(1));
|
||||
let c = Coulomb::new(4);
|
||||
let a = Ampere::new(2);
|
||||
assert_eq!(c % a, Second::new(0));
|
||||
let w = Watt::new(2);
|
||||
assert_eq!(w % a, Volt::new(0));
|
||||
assert_eq!(m % 2, Meter::new(0));
|
||||
assert_eq!(m % 2, Metre::new(0));
|
||||
}
|
||||
|
||||
#[test]
|
||||
fn rem_assign() {
|
||||
let mut m = Meter::new(2);
|
||||
let mut m = Metre::new(2);
|
||||
m %= 2;
|
||||
assert_eq!(m, Meter::new(0));
|
||||
assert_eq!(m, Metre::new(0));
|
||||
}
|
||||
}
|
||||
|
50
src/types.rs
50
src/types.rs
@ -6,7 +6,7 @@ pub type Unit<T> = SiUnit<T, Z0, Z0, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// time
|
||||
pub type Second<T> = SiUnit<T, P1, Z0, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// length
|
||||
pub type Meter<T> = SiUnit<T, Z0, P1, Z0, Z0, Z0, Z0, Z0>;
|
||||
pub type Metre<T> = SiUnit<T, Z0, P1, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// mass
|
||||
pub type Kilogram<T> = SiUnit<T, Z0, Z0, P1, Z0, Z0, Z0, Z0>;
|
||||
/// electric current
|
||||
@ -64,43 +64,43 @@ pub type Katal<T> = SiUnit<T, N1, Z0, Z0, Z0, Z0, P1, Z0>;
|
||||
|
||||
// Derived units without special names
|
||||
/// area
|
||||
pub type SquareMeter<T> = SiUnit<T, Z0, P2, Z0, Z0, Z0, Z0, Z0>;
|
||||
pub type SquareMetre<T> = SiUnit<T, Z0, P2, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// volume
|
||||
pub type CubicMeter<T> = SiUnit<T, Z0, P3, Z0, Z0, Z0, Z0, Z0>;
|
||||
pub type CubicMetre<T> = SiUnit<T, Z0, P3, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// speed, velocity
|
||||
pub type MeterPerSecond<T> = SiUnit<T, N1, P1, Z0, Z0, Z0, Z0, Z0>;
|
||||
pub type MetrePerSecond<T> = SiUnit<T, N1, P1, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// acceleration
|
||||
pub type MeterPerSquareSecond<T> = SiUnit<T, N2, P1, Z0, Z0, Z0, Z0, Z0>;
|
||||
pub type MetrePerSquareSecond<T> = SiUnit<T, N2, P1, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// wavenumber, vergence
|
||||
pub type ReciprocalMeter<T> = SiUnit<T, Z0, N1, Z0, Z0, Z0, Z0, Z0>;
|
||||
pub type ReciprocalMetre<T> = SiUnit<T, Z0, N1, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// density, mass concentration
|
||||
pub type KilogramPerCubicMeter<T> = SiUnit<T, Z0, N3, P1, Z0, Z0, Z0, Z0>;
|
||||
pub type KilogramPerCubicMetre<T> = SiUnit<T, Z0, N3, P1, Z0, Z0, Z0, Z0>;
|
||||
/// surface density
|
||||
pub type KilogramPerSquareMeter<T> = SiUnit<T, Z0, N2, P1, Z0, Z0, Z0, Z0>;
|
||||
pub type KilogramPerSquareMetre<T> = SiUnit<T, Z0, N2, P1, Z0, Z0, Z0, Z0>;
|
||||
/// specific density
|
||||
pub type CubicMeterPerKilogram<T> = SiUnit<T, Z0, P3, N1, Z0, Z0, Z0, Z0>;
|
||||
pub type CubicMetrePerKilogram<T> = SiUnit<T, Z0, P3, N1, Z0, Z0, Z0, Z0>;
|
||||
/// current density
|
||||
pub type AmperePerSquareMeter<T> = SiUnit<T, Z0, N2, Z0, P1, Z0, Z0, Z0>;
|
||||
pub type AmperePerSquareMetre<T> = SiUnit<T, Z0, N2, Z0, P1, Z0, Z0, Z0>;
|
||||
/// magnetic field strength
|
||||
pub type AmperePerMeter<T> = SiUnit<T, Z0, N1, Z0, P1, Z0, Z0, Z0>;
|
||||
pub type AmperePerMetre<T> = SiUnit<T, Z0, N1, Z0, P1, Z0, Z0, Z0>;
|
||||
/// concentration
|
||||
pub type MolePerCubicMeter<T> = SiUnit<T, Z0, N3, Z0, Z0, Z0, P1, Z0>;
|
||||
pub type MolePerCubicMetre<T> = SiUnit<T, Z0, N3, Z0, Z0, Z0, P1, Z0>;
|
||||
/// luminance
|
||||
pub type CandelaPerSquareMeter<T> = SiUnit<T, Z0, N2, Z0, Z0, Z0, Z0, P1>;
|
||||
pub type CandelaPerSquareMetre<T> = SiUnit<T, Z0, N2, Z0, Z0, Z0, Z0, P1>;
|
||||
|
||||
// Derived units including special names
|
||||
/// dynamic viscosity
|
||||
pub type PascalSecond<T> = SiUnit<T, N1, N1, P1, Z0, Z0, Z0, Z0>;
|
||||
/// moment of force
|
||||
pub type NewtonMeter<T> = SiUnit<T, N2, P2, P1, Z0, Z0, Z0, Z0>;
|
||||
pub type NewtonMetre<T> = SiUnit<T, N2, P2, P1, Z0, Z0, Z0, Z0>;
|
||||
/// surface tension
|
||||
pub type NewtonPerMeter<T> = SiUnit<T, N2, Z0, P1, Z0, Z0, Z0, Z0>;
|
||||
pub type NewtonPerMetre<T> = SiUnit<T, N2, Z0, P1, Z0, Z0, Z0, Z0>;
|
||||
/// angular velocity, angular frequency
|
||||
pub type RadianPerSecond<T> = SiUnit<T, N1, Z0, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// angular acceleration
|
||||
pub type RadianPerSquareSecond<T> = SiUnit<T, N2, Z0, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// heat flux density, irradiance
|
||||
pub type WattPerSquareMeter<T> = SiUnit<T, N3, Z0, P1, Z0, Z0, Z0, Z0>;
|
||||
pub type WattPerSquareMetre<T> = SiUnit<T, N3, Z0, P1, Z0, Z0, Z0, Z0>;
|
||||
/// entropy, heat capacity
|
||||
pub type JoulePerKelvin<T> = SiUnit<T, N2, P2, P1, Z0, N1, Z0, Z0>;
|
||||
/// specific heat capacity, specific entropy
|
||||
@ -108,19 +108,19 @@ pub type JoulePerKilogramKelvin<T> = SiUnit<T, N2, P2, Z0, Z0, N1, Z0, Z0>;
|
||||
/// specific energy
|
||||
pub type JoulePerKilogram<T> = SiUnit<T, N2, P2, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// themal conductivity
|
||||
pub type WattPerMeterKelvin<T> = SiUnit<T, N3, P1, P1, Z0, N1, Z0, Z0>;
|
||||
pub type WattPerMetreKelvin<T> = SiUnit<T, N3, P1, P1, Z0, N1, Z0, Z0>;
|
||||
/// energy density
|
||||
pub type JoulePerCubicMeter<T> = SiUnit<T, N2, N1, P1, Z0, Z0, Z0, Z0>;
|
||||
pub type JoulePerCubicMetre<T> = SiUnit<T, N2, N1, P1, Z0, Z0, Z0, Z0>;
|
||||
/// electric field strength
|
||||
pub type VoltPerMeter<T> = SiUnit<T, N3, P1, P1, N1, Z0, Z0, Z0>;
|
||||
pub type VoltPerMetre<T> = SiUnit<T, N3, P1, P1, N1, Z0, Z0, Z0>;
|
||||
/// electric charge density
|
||||
pub type CoulombPerCubicMeter<T> = SiUnit<T, P1, N3, Z0, P1, Z0, Z0, Z0>;
|
||||
pub type CoulombPerCubicMetre<T> = SiUnit<T, P1, N3, Z0, P1, Z0, Z0, Z0>;
|
||||
/// surface charge density, electirc flusx density, electric displacement
|
||||
pub type CoulombPerSquareMeter<T> = SiUnit<T, P1, N2, Z0, P1, Z0, Z0, Z0>;
|
||||
pub type CoulombPerSquareMetre<T> = SiUnit<T, P1, N2, Z0, P1, Z0, Z0, Z0>;
|
||||
/// permittivity
|
||||
pub type FaradPerMeter<T> = SiUnit<T, P4, N3, N1, P2, Z0, Z0, Z0>;
|
||||
pub type FaradPerMetre<T> = SiUnit<T, P4, N3, N1, P2, Z0, Z0, Z0>;
|
||||
/// permeability
|
||||
pub type HenryPerMeter<T> = SiUnit<T, N2, P1, P1, N2, Z0, Z0, Z0>;
|
||||
pub type HenryPerMetre<T> = SiUnit<T, N2, P1, P1, N2, Z0, Z0, Z0>;
|
||||
/// molar energy
|
||||
pub type JoulePerMole<T> = SiUnit<T, N2, P2, P1, Z0, Z0, N1, Z0>;
|
||||
/// molar entropy, molar heat capacity
|
||||
@ -132,6 +132,6 @@ pub type GrayPerSecond<T> = SiUnit<T, N3, P2, Z0, Z0, Z0, Z0, Z0>;
|
||||
/// radiant intensity
|
||||
pub type WattPerSteradian<T> = SiUnit<T, N3, P2, P1, Z0, Z0, Z0, Z0>;
|
||||
/// radiance
|
||||
pub type WattPerSquareMeterSteradian<T> = SiUnit<T, N3, Z0, P1, Z0, Z0, Z0, Z0>;
|
||||
pub type WattPerSquareMetreSteradian<T> = SiUnit<T, N3, Z0, P1, Z0, Z0, Z0, Z0>;
|
||||
/// catalytic activity concentration
|
||||
pub type KatalPerCubicMeter<T> = SiUnit<T, N1, N3, Z0, Z0, Z0, P1, Z0>;
|
||||
pub type KatalPerCubicMetre<T> = SiUnit<T, N1, N3, Z0, Z0, Z0, P1, Z0>;
|
||||
|
Loading…
Reference in New Issue
Block a user