One day Alan Eliasen read a fart joke and got so mad he invented a programming language. 20 years later Frink is one of the best special purpose languages for dealing with units.
âBut why do we need a language just for dealing with units?â Glad you asked!
Intro to Units
A unit is the physical property a number represents, like distance or time. We almost always are talking about SI units, or Système international. Thatâs things like meters, seconds, kilograms, along with prefixes like kilo- and mega-. One kilometer = 1000 meters, 1 centimeter = 1/100th of a meter.
Units can have exponents: m² is square meters, m³ is cubic meters, m * s-1 is speed. These form new physical properties, or dimensions. We can multiply and divide numbers with different dimensions but not add them. I can add 1 m + 1 m, but not 1 m + 1 kg. A unit-aware language needs to be able to track units and make sure that I donât add incompatible dimensions. It also should also make sure that I pass correct units into functions that depend on units. A pressure calculation would take an area and a force, not a frequency and an amperage.
Simple, right?
Nope
First of all, there are multiple different representations of units. Thereâs the SI system, which all sane, right-thinking nations use, and then thereâs the American system. Feet and meters are both distance. Is it okay to mix feet and meters? This is the bug that destroyed the Mars Climate Orbiter. But there are also valid uses cases where youâd want to mix them! When I cook, I use a mix of metric weights and American volumes, like 1 cup of water and 128 grams of flour. In the UK, beer is measured using pints but its alcohol by volume is measured in SI.
Different dimensions doesnât always mean the units are incompatible. Thereâs a nonstandard set of units called âGaussian unitsâ used in some niches of physics. In SI, capacitance is measured in Farads, which has dimensions A² sâ´ kg-1 mâ2. In Gaussian units, capacitance is measured in cm. If youâre explicit about what youâre doing you can add these seemingly-incompatible dimensions.
Dimensions arenât unique, and two incompatible physical quantities can have the same dimension. The canonical example is that energy and angular force are both measured in Newton-meters. There are also plenty of domain specific examples. As you enter a gravity well, the rate at which gravitational force changes has dimensions N/m. Surface tension is also measured in N/m.
What else?
- Whatâs 200° + 360°? It could be 200° or 560°, depending on we have a âcircular angleâ or a ârotational angleâ (like driving a screw in).
- Some quantities are unitless. Whatâs 20° + 1 radian? Theyâre both unitless quantities that have compatible dimensions. What about adding two ratios? What about adding a radian to a ratio?
- Units can have additional limitations. You can subtract timestamps from each other but not add them.
- Units can have different historical values. A foot is defined as exactly
0.3048 meters. Before 1959, though, it was 0.3048006 meters. This is means that all historical documents have a different measurement of foot. And there was a period of time where we used both definitions in different places!
- Uncertainties. If youâre working with physical measurements, all of your measurements will have some amount of uncertainty. What happens when you add two meters, plus or minus a centimeter?
If you want to learn more about how evil units are, check out Bill Kentâs Measurement Data Report.
Some solutions
Adding units of measure to a language is tricky. Itâs not just that there are many hard domain problems, thereâs also different tradeoffs in solutions. Do we want compile-time or runtime correctness? Should units be part of the type system or is there a better representation? How do we handle derived units? How do we handle generics? A good overview of the design challenges is here, which discusses some of the solutions proposed for Ada.
This page covers how various languages approach measurements. For the most part, they punt the question to preprocessors and libraries, limiting how much they can help you. The only mainstream language with built-in support for units of measure is F#. F# focuses on catching all errors at compile time. All conversions between units must be made explicit, so you canât accidentally add feet and meters. The price for this is flexibility: you canât add centimeters and meters, either.
// Mass, grams.
[<Measure>] type g
// Mass, kilograms.
[<Measure>] type kg
// Define conversion constants.
let gramsPerKilogram : float<g kg^-1> = 1000.0<g/kg>
// Define conversion functions.
let convertGramsToKilograms (x : float<g>) = x / gramsPerKilogram
Thatâs a good design choice for F#âs goals. It adds boilerplate but keeps your software from going haywire. This is appropriate for industrial software where a lot of people could be affected by a bug.
Itâs less appropriate for low-stakes, small scale work. Boilerplate makes it harder to use things interactively. If Iâm trying to find the Titanicâs weight in cups of rice I donât want to spend ten minutes writing unit conversions. For that, the most common tool is units, a GNU program for conversions:
You have: 12 ft + 3 in + 3|8 in
You want: ft
* 12.28125
/ 0.081424936
units is a fine piece of software, but itâs not a programming language. I want a language that has built-in dimensional analysis but doesnât need a lot of boilerplate. Something more powerful than units but not as strict as F#.
Frink
Thatâs where Frink comes in. In Frink, any number can be tagged with a unit. Frink will prevent you from adding incompatible units, same as F#.
> 1 meter
1 m (length)
> 1 meter + 2 kilograms
Error when adding: meter + 2 kilograms
Cause: Conformance Exception:
Cannot add units with different dimensions.
Dimension types:
m (length)
kg (mass)
The syntax is designed to look like ânaturalâ math, so a space counts as a multiplication. 1 meter is actually 1 * meter. This may seem like itâll cause some problems, but itâs actually kinda nice. It makes translating equations to Frink easier.
By using the -> operator, we can convert a value between two units. We can choose whether we include the name of unit in the conversion or not by putting it in quotes.
> 10 meters + 2 furlongs -> "feet"
2029212500/1499997 (approx. 1352.8110389554112) feet
Frink comes with a boatload of predefined units; itâs default units file is over 5,000 lines long.
//How do you measure, oh measure a year?
> 525600 minutes -> years
0.99933688171353600106
> 525600 minutes -> siderealyears
0.9992981356527034257
> 525600 minutes -> gaussianyears
0.99926355644744010579
> 525600 minutes -> calendaryear
1
You can also define new units at runtime in terms of other units.
> corn_on_sale := 0.25 USD
// If we had a living wage, how many ears/corn
// could you buy with one days labor?
> 15 USD/hour * 8 hours -> "corn_on_sale"
480. corn_on_sale
> 15 USD/hour -> "corn_on_sale/(8 hours)"
480.0 corn_on_sale/(8 hours)
Prefixes in Frink are just multipliers. I can write kilofeet and it automatically knows that means â1000 feetâ. Frink also knows common terms like half and square.
> square megapaces
5.80644e+11 m^2 (area)
You can break down conversions into multiple units.
> 1 kilometer -> ["kilofeet", "feet", "inches"]
3 kilofeet, 280 feet, 1280/127 (approx. 10.078740157480315) inches
> 1 kilometer -> ["kilofeet", "feet", "inches", 0]
3 kilofeet, 280 feet, 10 inches
Frink functions work as youâd expect, but you force parameters to conform to dimensions and preconditions.
> sphereVolume[radius is length] := 4/3 pi radius^3
> sphereVolume[2]
Error when calling function sphereVolume:
Constraint not met--value must have dimensions of length
Functions can also be the target of a conversion.
> HMS[1 day]
24 hours, 0 min, 0 sec
> (10 miles) / (3 mph) -> HMS
3 hours, 20 min, 0 sec
Affordances
Frink really shines in its affordances. It needs to be pleasant and reasonable if people are going to use it interactively. Frink does lots of small things to help with this. Some examples:
You can change the display units for a dimension.
> length :-> [feet, inches, 0]
// All lengths are now in feet and inches
> 1 meter
3, 3
// areas are unaffected
> 2 m * 2 m
4 m^2 (area)
You can globally set precisions and output formats.
> setPrecision[6]
> setEngineering[true]
140.5 million meters
140.500e+6 m (length)
You define entirely new dimensions and prefixes.
> population =!= person
> 2.7 megaperson / (5 square miles) -> (square feet) / person
Warning: reciprocal conversion
51.626666666666666665
By using ?str you can get a list of all the existing units which start with str. By using ?? it also gives you the value of the unit.
> ?foot
[acrefoot, arabicfoot, assyrianfoot, boardfoot, cordfoot, doricfoot, earlyromanfoot, foot, footballfield, footcandle, footlambert, frenchfoot, greekfoot, ionicfoot, irishfoot, lateromanfoot, northernfoot, olympicfoot, romanfoot, scotsfoot, sumerianfoot, timberfoot]
> ??foot
arabicfoot = 0.270256 m (length)
assyrianfoot = 0.27432 m (length)
boardfoot = 18435447/7812500000 (exactly 0.002359737216) m^3 (volume)
\\ it goes for a while
Thereâs special syntax for representing timestamps, which makes it easy to convert dates and times.
// Meeting is tomorrow, 3 PM Paris time, what's that in New York?
> # 3 PM Paris # + 1 day-> "New York"
AD 2020-07-10 AM 09:00:00.000 (Fri) Eastern Daylight Time
Some Use Cases
Eliasen loves cooking, so Frink has a lot of food measurements. A lot of baking recipes call for a volume of âsifted flourâ, but sifting is messy, annoying, and imprecise. We should measure them by mass instead:
> ?flour
[breadflour_scooped, breadflour_sifted, breadflour_spooned,
cakeflour_scooped, cakeflour_sifted, cakeflour_spooned,
flour_scooped, flour_sifted, flour_spooned]
> 2.5 cups flour_sifted -> grams
283.49523125
Letâs do something more complicated. Like Eliasen, I also love cooking. While I mostly make savory dishes, I also specialize in chocolatiering. Iâve always been a little curious about how many calories each of my chocolates are, so letâs try to figure that out using Frink.
For this example Iâll use the Chai tea recipe from the CIA book. Hereâs the list of ingredients:
| Ingredient |
amount (g) |
serving size |
Calories[^kcal] |
| Heavy Cream |
180 |
1 tablespoon |
50 |
| Milk Chocolate |
460 |
1.55 oz |
235 |
| Corn Syrup |
60 |
2 tbsp |
120 |
| Tea Blend |
10 g |
- |
- |
| Butter |
20 g |
14 grams |
100 |
I pulled the calories of each ingredient from its label, with the exception of the milk chocolate, as I buy that in bulk. Instead I found information online here. Not the same kind of milk chocolate, but itâll do for an estimate.
> specific_energy :-> "kcal/gram"
> energy :-> "kcal"
The :-> changes the default unit representation. Without it specific energy would be presented in base SI units, which would be joules per kilogram. Next I put all of the measurements into dictionaries. I didnât bother converting every measurement to SI units, as Frink can calculate the ratios for me.
kcg = new dict // kcal/gram
kcg@"hc" = 50 kcal / (tablespoon heavycream)
kcg@"cs" = 120 kcal / (2 tablespoon cornsyrup)
kcg@"butter" = 100 kcal / (14 grams)
kcg@"mc" = 235 kcal / (1.55 oz)
recipe = new dict //what actually goes in
recipe@"hc" = 180 grams
recipe@"cs" = 60 grams
recipe@"mc" = 460 grams
recipe@"butter" = 20 grams
ing = ["hc", "cs", "mc", "butter"]
total_cals = 0 kcal
for x = ing
total_cals = total_cals + recipe@x kcg@x
Depending on the shell, this is enough for somewhere between 80 and 100 chocolates. We can model this uncertainty with an interval:
made = new interval[100, 120]
Instead of having an exact number, we have an upper and lower bound on the number. All math done with the interval instead change the bounds.
> x = new interval[80, 100]
[80, 100]
// frink does interval math
> x + 2
[82, 102]
> x * 2
[160, 200]
> x - new interval[80, 100]
[-20, 20]
But thereâs more to a chocolate than its filling. Thereâs also the shell around it, which is going to have a different specific energy than the filling. To figure out how much shell there is per chocolate, I weighed 10 chocolates and took the average. That gave me 9 grams per chocolate. I know roughly how much of the filling there is per chocolate, based on how many chocolates I made from the filling. Subtracting the mass of the filling from the mass of the chocolate gives me the mass of the shell.
dictsum[d] := sum[map[{|x| x@1}, d]]
// grams per chocolate
gpc = new dict
gpc@"recipe" = dictsum[recipe] / made
gpc@"dc" = 9 grams - gpc@"recipe"
From then is a straightforward calculation to figure out how much calories both the shell and the filling have in total. And that gives me the total calories of the chocolate.
println[(total_cals / made) + kcg@"mc" * gpc@"dc"]
This tells me that each chocolate is 40-50 kcal, which is about what I expected.
If youâre interested in Frink, you can download it here. At the very least Iâd recommend checking out the default units file; itâs a hilarious and insightful introduction to just how weird units can be. Iâll leave you with some of his comments on candela:
I think the candela is a scam, and I am completely
opposed to it. Some good-for-nothing lighting âengineersâ
or psychologists probably got this perceptually-rigged
abomination into the whole otherwise scientific endeavor.
What an unbelievably useless and stupid unit. Is light
at 540.00000001 x 10^12 Hz (or any other frequency) zero
candela? Is this expected to be an impulse function at
this frequency? Oh, wait, the Heisenberg Uncertainty
Principle makes this impossible. No mention for
correction (ideally along the blackbody curve) for other
wavelengths? Damn you, 16th CGPM! Damn you all to hell!
Thanks to
Jubilee Young
for making the opening image. Composite images are from Sean Connery in Zardoz and Alan Eliasenâs homepage.
Comet C/2020 F3 NEOWISE Near Barcelona. | Photo by Albert Llop / NurPhoto via Getty Images
. If you canââ¬â¢t read this, try harder. Seriously. It looks like I havenââ¬â¢t written a lot, but I actually have. So here is the end now. Bye bye 
Hey look itââ¬â¢s a meatball
An artistic rendering of astronauts landing on the surface of the Moon again | Image: NASA
An artistic rendering of astronauts on the Moon, mining resources. | Image: NASA
