#JS-quantities
JS-quantities is originally a JavaScript port of Kevin Olbrich's library Ruby Units (http://github.com/olbrich/ruby-units).
The library aims to simplify the handling of units for scientific calculations involving quantities.
JS-quantities is defined as an UMD module and can be used with AMD, Node and within browsers.
Download latest release v1.5.0 or install it with Bower:
bower install js-quantities
Then include it:
<script src='quantities.js'></script>
When using Require.JS:
define(['quantities'], function(Qty) {
...
});
$ npm install js-quantities
$ node
> var Qty = require('js-quantities');
Instances of quantities are made by means of Qty()
method. Qty
can both be
used as a constructor (with new) or as a factory (without new):
qty = new Qty('23 ft'); // constructor
qty = Qty('23 ft'); // factory
Qty
constructor accepts strings, numbers and Qty
instances as
initializing values.
For the sake of simplicity, one will use the factory way below but using
new Qty()
is equivalent.
qty = Qty('1m'); // => 1 meter
qty = Qty('m'); // => 1 meter (scalar defaults to 1)
qty = Qty('1 N*m');
qty = Qty('1 N m'); // * is optional
qty = Qty('1 m/s');
qty = Qty('1 m^2/s^2');
qty = Qty('1 m^2 s^-2'); // negative powers
qty = Qty('1 m2 s-2'); // ^ is optional
qty = Qty('1 m^2 kg^2 J^2/s^2 A');
qty = Qty('1.5'); // unitless quantity
qty = Qty(1.5); // number as initializing value
qty = Qty('1 attoparsec/microfortnight');
qtyCopy = Qty(qty); // quantity could be copied when used as
// initializing value
Qty.parse
utility method is also provided to parse and create
quantities from strings. Unlike the constructor, it will return null
instead throwing an error when parsing an invalid quantity.
Qty.parse('1 m'); // => 1 meter
Qty.parse('foo') // => null
Qty.getKinds(); // => Array of names of every well-known kind of units
Qty.getUnits('currency'); // => [ 'dollar', 'cents' ]
// Or all alphabetically sorted
Qty.getUnits(); // => [ 'acre','Ah','ampere','AMU','angstrom']
Qty.getAliases('m'); // => [ 'm', 'meter', 'meters', 'metre', 'metres' ]
qty1.isCompatible(qty2); // => true or false
qty.kind(); // => 'length', 'area', etc...
qty.isUnitless(); // => true or false
qty.isBase(); // => true if quantity is represented with base units
qty.toBase(); // converts to SI units (10 cm => 0.1 m) (new instance)
qty.toFloat(); // returns scalar of unitless quantity
// (otherwise throws error)
qty.to('m'); // converts quantity to meter if compatible
// or throws an error (new instance)
qty1.to(qty2); // converts quantity to same unit of qty2 if compatible
// or throws an error (new instance)
qty.inverse(); // converts quantity to its inverse
// ('100 m/s' => '.01 s/m')
// Inverses can be used, but there is no special checking to
// rename the units
Qty('10ohm').inverse() // '.1/ohm'
// (not '.1S', although they are equivalent)
// however, the 'to' command will convert between inverses also
Qty('10ohm').to('S') // '.1S'
Qty.swiftConverter()
is a fast way to efficiently convert large array of
Number values. It configures a function accepting a value or an array of Number
values to convert.
var convert = Qty.swiftConverter('m/h', 'ft/s'); // Configures converter
// Converting single value
var converted = convert(2500); // => 2.278..
// Converting large array of values
var convertedSerie = convert([2500, 5000, ...]); // => [2.278.., 4.556.., ...]
The main drawback of this conversion method is that it does not take care of rounding issues.
qty1.eq(qty2); // => true if both quantities are equal (1m == 100cm => true)
qty1.same(qty2); // => true if both quantities are same (1m == 100cm => false)
qty1.lt(qty2); // => true if qty1 is stricty less than qty2
qty1.lte(qty2); // => true if qty1 is less than or equal to qty2
qty1.gt(qty2); // => true if qty1 is stricty greater than qty2
qty1.gte(qty2); // => true if qty1 is greater than or equal to qty2
qty1.compareTo(qty2); // => -1 if qty1 < qty2,
// => 0 if qty1 == qty2,
// => 1 if qty1 > qty2
- add(other): Add. other can be string or quantity. other should be unit compatible.
- sub(other): Substract. other can be string or quantity. other should be unit compatible.
- mul(other): Multiply. other can be string, number or quantity.
- div(other): Divide. other can be string, number or quantity.
Qty#toPrec(precision)
: returns the nearest multiple of quantity passed as
precision.
var qty = Qty('5.17 ft');
qty.toPrec('ft'); // => 5 ft
qty.toPrec('0.5 ft'); // => 5 ft
qty.toPrec('0.25 ft'); // => 5.25 ft
qty.toPrec('0.1 ft'); // => 5.2 ft
qty.toPrec('0.05 ft'); // => 5.15 ft
qty.toPrec('0.01 ft'); // => 5.17 ft
qty.toPrec('0.00001 ft'); // => 5.17 ft
qty.toPrec('2 ft'); // => 6 ft
qty.toPrec('2'); // => 6 ft
var qty = Qty('6.3782 m');
qty.toPrec('dm'); // => 6.4 m
qty.toPrec('cm'); // => 6.38 m
qty.toPrec('mm'); // => 6.378 m
qty.toPrec('5 cm'); // => 6.4 m
qty.toPrec('10 m'); // => 10 m
qty.toPrec(0.1); // => 6.3 m
var qty = Qty('1.146 MPa');
qty.toPrec('0.1 bar'); // => 1.15 MPa
Qty#toString
returns a string using the canonical form of the quantity (that
is it could be seamlessly reparsed by Qty
).
var qty = Qty('1.146 MPa');
qty.toString(); // => '1.146 MPa'
As a shorthand, units could be passed to Qty#toString
and is equivalent to
successively call Qty#to
then Qty#toString
.
var qty = Qty('1.146 MPa');
qty.toString('bar'); // => '11.46 bar'
qty.to('bar').toString(); // => '11.46 bar'
Qty#toString
could also be used with any method from Qty
to make some sort
of formatting. For instance, one could use Qty#toPrec
to fix the maximum
number of decimals:
var qty = Qty('1.146 MPa');
qty.toPrec(0.1).toString(); // => '1.1 MPa'
qty.to('bar').toPrec(0.1).toString(); // => '11.5 bar'
For advanced formatting needs as localization, specific rounding or any other
custom customization, quantities can be transformed into strings through
Qty#format
according to optional target units and formatter. If target units
are specified, the quantity is converted into them before formatting.
Such a string is not intended to be reparsed to construct a new instance of
Qty
(unlike output of Qty#toString
).
If no formatter is specified, quantities are formatted according to default
js-quantities' formatter and is equivalent to Qty#toString
.
var qty = Qty('1.1234 m');
qty.format(); // same units, default formatter => '1.234 m'
qty.format('cm'); // converted to 'cm', default formatter => '123.45 cm'
Qty#format
could delegates formatting to a custom formatter if required. A
formatter is a callback function accepting scalar and units as parameters and
returning a formatted string representing the quantity.
var configurableRoundingFormatter = function(maxDecimals) {
return function(scalar, units) {
var pow = Math.pow(10, maxDecimals);
var rounded = Math.round(scalar * pow) / pow;
return rounded + ' ' + units;
};
};
var qty = Qty('1.1234 m');
// same units, custom formatter => '1.12 m'
qty.format(configurableRoundingFormatter(2));
// convert to 'cm', custom formatter => '123.4 cm'
qty.format('cm', configurableRoundingFormatter(1));
Custom formatter can be configured globally by setting Qty.formatter
.
Qty.formatter = configurableRoundingFormatter(2);
var qty = Qty('1.1234 m');
qty.format(); // same units, current default formatter => '1.12 m'
Like ruby-units, JS-quantities makes a distinction between a temperature (which technically is a property) and degrees of temperature (which temperatures are measured in).
Temperature units (i.e., 'tempK') can be converted back and forth, and will take into account the differences in the zero points of the various scales. Differential temperature (e.g., '100 degC') units behave like most other units.
Qty('37 tempC').to('tempF') // => 98.6 tempF
JS-quantities will throw an error if you attempt to create a temperature unit that would fall below absolute zero.
Unit math on temperatures is fairly limited.
Qty('100 tempC').add('10 degC') // 110 tempC
Qty('100 tempC').sub('10 degC') // 90 tempC
Qty('100 tempC').add('50 tempC') // throws error
Qty('100 tempC').sub('50 tempC') // 50 degC
Qty('50 tempC').sub('100 tempC') // -50 degC
Qty('100 tempC').mul(scalar) // 100*scalar tempC
Qty('100 tempC').div(scalar) // 100/scalar tempC
Qty('100 tempC').mul(qty) // throws error
Qty('100 tempC').div(qty) // throws error
Qty('100 tempC*unit') // throws error
Qty('100 tempC/unit') // throws error
Qty('100 unit/tempC') // throws error
Qty('100 tempC').inverse() // throws error
Qty('100 tempC').to('degC') // => 100 degC
This conversion references the 0 point on the scale of the temperature unit
Qty('100 degC').to('tempC') // => -173.15 tempC
These conversions are always interpreted as being relative to absolute zero. Conversions are probably better done like this...
Qty('0 tempC').add('100 degC') // => 100 tempC
Every error thrown by JS-quantities is an instance of Qty.Error
.
try {
// code triggering an error inside JS-quantities
}
catch(e) {
if(e instanceof Qty.Error) {
// ...
}
else {
// ...
}
}
Tests are implemented with Jasmine (https://github.com/pivotal/jasmine). You could use both HTML and jasmine-node runners.
To execute specs through HTML runner, just open SpecRunner.html file in a browser to execute them.
To execute specs through node-jasmine, launch:
jasmine-node spec/
There is a small benchmarking HTML page to spot performance regression between currently checked-out quantities.js and any committed version. Just execute:
bundle exec rake bench
then open http://0.0.0.0:3000/bench
Checked-out version is benchmarked against HEAD by default but it could be changed by passing any commit SHA on the command line. Port (default 3000) is also configurable.
bundle exec rake bench COMMIT=e0c7fc468 PORT=5000
Feedback and contribution are welcomed.