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Brandon Rozek 2024-08-04 08:33:12 -07:00
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---
title: "Polymorphic Functions w/ Wildcard Matching in Lean 4"
date: 2024-08-04T07:21:07-07:00
draft: false
tags: []
math: false
medium_enabled: false
---
I was reading through the [Polymorphism](https://lean-lang.org/functional_programming_in_lean/getting-to-know/polymorphism.html) section in the Functional programming in Lean textbook and came across the following example:
```lean4
inductive Sign where
| pos
| neg
def posOrNegThree (s : Sign) : match s with | Sign.pos => Nat | Sign.neg => Int :=
match s with
| Sign.pos => (3 : Nat)
| Sign.neg => (-3 : Int)
```
The function `posOrNegThree` depending on the input, can either return an expression of type `Nat` or an expression of type `Int`. That's super neat!
What happens if we add a wildcard to the match?
For example, let's say we want a type based on the number of bits of precision specified. If we don't support the number of bits, we return the arbitrary precision `Nat` as our default.
```lean4
def UIntN (n: Nat) : Type := match n with
| 32 => UInt32
| 64 => UInt64
| _ => Nat
```
Now let's write a function that returns the zero element of our specified type:
```lean4
def u0 (x: Nat) : UIntN x := match x with
| 32 => (0: UInt32)
| 64 => (0: UInt64)
| _ => Nat.zero
```
This will result in the following error:
```lean4
type mismatch
Nat.zero
has type
: Type
but is expected to have type
UIntN x✝ : Type
```
I got stuck on this for a while, so I asked on the really helpful Lean Zulip and got a [great response](https://leanprover.zulipchat.com/#narrow/stream/113489-new-members/topic/.E2.9C.94.20Polymorphic.20Functions.20w.2F.20Wildcard.20Match.20Type)
```lean4
def u0 (x: Nat) : UIntN x := dite (x=32) (λ h ↦ by
subst h
exact (0 : UInt32)
) (dite (x = 64) (λ h ↦ by
intro h2
subst h
exact (0: UInt64)
)
(λ h ↦ by
intro h2
have : UIntN x = Nat := by
unfold UIntN
simp only
rw [this]
exact 0
))
```
Unfortunately this doesn't look pretty, but this was a massive clue in finding the prettier syntax to solve this problem!
```lean4
def u0 (x: Nat) : UIntN x :=
if h: x = 6 then by
subst h
exact (0: UInt32)
else if h2: x = 4 then by
subst h2
exact (0: UInt64)
else by
have : UIntN x = Nat := by
unfold UIntN
simp only
rw [this]
exact 0
```