# Cubical Agda: how do I prove two things not equal

How can I prove two things are not equal in Cubical Agda? (v2.6.1, Cubical repo version `acabbd9`)

Concretely, here are the integers as a higher inductive type:

``````{-# OPTIONS --safe --warning=error --cubical --without-K #-}

open import Cubical.Core.Everything
open import Cubical.Foundations.Prelude

module Integers where

data False : Set where

data ℕ : Set where
zero : ℕ
succ : ℕ → ℕ

{-# BUILTIN NATURAL ℕ #-}

data ℤ : Set where
pos : ℕ → ℤ
neg : ℕ → ℤ
congZero : pos 0 ≡ neg 0
``````

It's easy to show some rather odd equalities, because "equality" here actually means something which isn't quite what we're used to in the non-cubical world:

``````oddThing2 : pos 0 ≡ congZero i1
oddThing2 = congZero
``````

I found a rather nasty-looking proof that successors are nonzero at https://github.com/Saizan/cubical-demo/blob/b112c292ded61b02fa32a1b65cac77314a1e9698/examples/Cubical/Examples/CTT/Data/Nat.agda :

``````succNonzero : {a : ℕ} → succ a ≡ 0 → False
succNonzero {a} s = subst t s 0
where
t : ℕ → Set
t zero = False
t (succ i) = ℕ
``````

Is there a nicer proof? I can't pattern-match on the proof of `succ a ≡ 0` any more; in non-cubical Agda the proof would simply be `oneNotZero ()`, identifying the impossible pattern.

Then how can I prove the following (is it even true?)

``````posInjective : {a b : ℤ} → pos a ≡ pos b → a ≡ b
``````

It's probably clear that I'm a complete novice with Cubical; but I've used Agda a nontrivial amount in the past.

For `posInjective` you can actually do a much simpler proof,

``````fromPos : ℤ → ℕ
fromPos (pos n) = n
fromPos (neg _) = 0
fromPos (congZero i) = refl
``````

then `posInjective = cong fromPos`.

More generally one should do a so-called encode/decode proof (also called a NoConfusion proof), where one explicitly defines a relation on the datatype by recursion, and then proves it equivalent to path equality.

e.g. there's one such proof here about `List`

https://github.com/agda/cubical/blob/master/Cubical/Data/List/Properties.agda#L37

Injectivity and distinctness follow easily from the definition of `Cover`.

The possibility of this kind of proofs are actually the justification for the soundness of Agda's powerful pattern matching on inductive families. However HITs constructors in general are neither distinct nor injective, so Agda is conservative and doesn't use those properties for HITs at all.

• I feel like in an encode/decode proof I'm doing "basically the same work" as I would be doing without Cubical. I've effectively defined Z as a quotient with this higher inductive type, then you say I should define a decision procedure for Z, and show that this is equivalent to path equality. Without Cubical, I'd define the same quotient, define the same decision procedure, and show again that "decision procedure says Yes if and only if the numbers are equivalent under the quotient". Is the point that Cubical lets me deal more nicely with the quotient after this point (though not before)? Commented Apr 27, 2020 at 12:59
• Z of course is not where you're going to see a lot of payoff of HITs, as it's fairly simple to define the normal forms of the quotient, as in Agda's standard library. Commented Apr 29, 2020 at 7:59
• Also, to clarify: the encode/decode proof is not a decision procedure since you are proving equivalence to a relation which you do not need to prove decidable. The same technique applies to types without decidable equality. Commented Apr 29, 2020 at 8:07

Well, I have a very odd answer which I don't understand at all.

``````decr : ℤ → ℤ
decr (pos zero) = neg 1
decr (pos (succ x)) = pos x
decr (neg x) = neg (succ x)
decr (congZero i) = neg 1

-- "Given a proof that `pos (succ a) = pos (succ b)`, transport it back along `decr`."
posDecr : {a b : ℕ} → pos (succ a) ≡ pos (succ b) → pos a ≡ pos b
posDecr {a} {b} pr = cong decr pr

posInjective : {a b : ℕ} → pos a ≡ pos b → a ≡ b
posInjective {zero} {zero} x = refl
posInjective {zero} {succ b} x = subst t x (succ b)
where
t : ℤ → Set
t (pos zero) = ℕ
t (pos (succ x)) = zero ≡ succ b
t (neg x) = ℕ
t (congZero i) = ℕ
posInjective {succ a} {zero} x = subst t x (succ a)
where
t : ℤ → Set
t (pos zero) = succ a ≡ zero
t (pos (succ x)) = ℕ
t (neg x) = succ a ≡ zero
t (congZero i) = succ a ≡ zero
posInjective {succ a} {succ b} x = cong succ (posInjective (posDecr x))
``````