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https://github.com/purescript/purescript-partial

Utilities for working with partial functions
https://github.com/purescript/purescript-partial

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Utilities for working with partial functions

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# purescript-partial



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Utilities for working with partial functions.



## Installation



```

spago install partial

```



## Why have a Partial type class?



Every now and then, you will want to use _partial functions;_ that is,

functions which don't handle every possible case of their inputs. For example,

there is a function `fromJust :: ∀ a. Partial ⇒ Maybe a → a` in `Data.Maybe`,

which gives you the value inside a `Just` value, or throws an error if given

`Nothing`.



It's important that types tell the truth wherever possible, because this is a

large part of what allows us to understand PureScript code easily and refactor

it fearlessly. However, in certain contexts, you know that e.g. an `Either`

value is always going to be `Right`, but you can't prove that to the type

checker, and so you want an escape hatch so that you can write a function that

doesn't have to deal with the `Left` case. This is often the case when

performance is important, for instance.



Previously, partial functions have been indicated by putting the word "unsafe"

at the start of their names, or by putting them in an "Unsafe" module. For

instance, there was previously an `unsafeIndex` function in

`Data.Array.Unsafe`, and `fromJust` used to be in `Data.Maybe.Unsafe`. However,

this is not ideal, because the fact that these functions are partial, and

therefore unsafe if used carelessly, does not appear in the type. Consequently,

there is little to stop you from using it in an inappropriate manner by

accident.



The Partial type class allows us to put this information back into the types,

and thereby allows us to clearly demarcate which parts of your code are

responsible for making sure that unsafe functions are used in a safe manner.



## I just want to use a partial function, please



If you try to just use a partial function, you'll most likely get an error

about no instance being found for the `Partial` class. Take this program, for

instance:



```purescript

module Main where



import Prelude

import Data.Maybe (Maybe(..), fromJust)

import Effect (Effect)

import Effect.Console (logShow)



main :: Effect Unit

main = logShow (fromJust (Just 3))

```



Because `fromJust` is partial, and because the partiality hasn't been

explicitly handled, you'll get an error:



```

at src/Main.purs line 8, column 1 - line 8, column 56



  No type class instance was found for



    Prim.Partial

```



_Aside: Yes, this is not a fantastic error. It's going to get better soon._



The solution is usually to add an application of `unsafePartial` somewhere,

like this:



```purescript

module Main where



import Prelude

import Data.Maybe (Maybe(..), fromJust)

import Effect (Effect)

import Effect.Console (logShow)

import Partial.Unsafe (unsafePartial)



main :: Effect Unit

main = logShow (unsafePartial (fromJust (Just 3)))

```



## Where should I put unsafePartial?



The rule of thumb is to put `unsafePartial` at the level of your program such

that the types tell the truth, and the part of your program responsible for

making sure a use of a partial function is safe is also the part where the

`unsafePartial` is. This is perhaps best demonstrated with an example.



Imagine that we want to represent vectors in 3D with an array containing

exactly 3 values (perhaps we want to use them with some other API that expects

this representation, and we don't want to be converting back and forth all the

time). In this case, we would usually use a `newtype` and avoid exporting the

constructor:



```purescript

module Data.V3

  ( V3()

  , makeV3

  , runV3

  ) where



newtype V3 = V3 (Array Number)



makeV3 :: Number -> Number -> Number -> V3

makeV3 x y z = V3 [x, y, z]



runV3 :: V3 -> Array Number

runV3 (V3 v) = v

```



This way, all of the functions are safe; the code will guarantee that any `V3`

does contain exactly 3 values (although the type checker is not aware of this).



Now imagine we want to write a dot product function:



```purescript

dot :: V3 -> V3 -> Number

dot (V3 [x1, x2, x3]) (V3 [y1, y2, y3]) = x1*y1 + x2*y2 + x3*y3

```



We know this is ok, but the compiler disallows it:



```

A case expression could not be determined to cover all inputs.

The following additional cases are required to cover all inputs:



  (V3 _) _

  _      (V3 _)



Alternatively, add a Partial constraint to the type of the enclosing value.



in value declaration dot

```



In this case, we can use `unsafePartial` to explicitly say that we don't

actually need to worry about those other cases, and therefore we don't want to

propagate a `Partial` constraint; users of this `dot` function should not have

to worry about this partiality. For example:



```purescript

dot :: V3 -> V3 -> Number

dot x y = Partial.Unsafe.unsafePartial (go x y)

  where

  go :: Partial => V3 -> V3 -> Number

  go (V3 [x1, x2, x3]) (V3 [y1, y2, y3]) = x1*y1 + x2*y2 + x3*y3

  -- This second pattern can be omitted, but provides a better error message

  -- in case we do get an invalid argument at runtime.

  go _ _ = Partial.crash "Bad argument: expected exactly 3 elements."

```



The `unsafePartial` function comes from the `Partial.Unsafe` module, in the

`purescript-partial` package.



In this case, we could also use `Partial.Unsafe.unsafeCrashWith`:



```purescript

dot :: V3 -> V3 -> Number

dot (V3 [x1, x2, x3]) (V3 [y1, y2, y3]) = x1*y1 + x2*y2 + x3*y3

dot _ _ = unsafeCrashWith "Bad argument: expected exactly 3 elements."

```



Both implementations will behave in the same way.



In this case, we know our `dot` implementation is fine, and so users of it

should not have to worry about its partiality, so it makes sense to avoid

propagating the constraint. Now, we will see another case where a `Partial`

constraint _should_ be propagated.



Let us suppose we want a `foldr1` function, which works in a very similar way

to `foldr` on Lists, except that it doesn't require an initial value to be

passed, and instead requires that the list argument contains at least one

element.



We can implement it like this:



```purescript

foldr1 f (Cons x xs) = foldr f x xs

```



The compiler infers the correct type here, which is:



```purescript

foldr1 :: forall a. Partial => (a -> a -> a) -> List a -> a

```



Now imagine we want a version of `Data.Foldable.minimum` which returns an `a`

instead of a `Maybe a`, and is therefore partial. We can implement it in terms

of our new `foldr1` function:



```purescript

minimumP = foldr1 min

```



Again, the compiler infers the correct type:



```purescript

minimumP :: forall a. (Partial, Ord a) => List a -> a

```



Notice that the `Partial` constraint is automatically propagated to the

`minimumP` function because of the use of another partial function in its

definition, namely `foldr1`. In this case, this is what we want; we should

propagate the `Partial` constraint, because it is still the caller's

responsibility to make sure they supply a non-empty list.



So hopefully it is now clear why this partiality checking is implemented in

terms of a type class: it allows us to elegantly reuse existing machinery in

the type checker in order to check that a Partial constraint is either

explictly handled or propagated. This should help ensure that when you're

reading the code a few months later, it remains clear which part of the code is

responsible for ensuring that any assumed invariants which cannot be encoded in

the type system do hold.



## API Documentation



- API documentation is [published on Pursuit](http://pursuit.purescript.org/packages/purescript-partial).