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I'm trying to representat mod-n counters as a cut of the interval [0, ..., n-1] into two parts:

data Counter : ℕ → Set where
  cut : (i j : ℕ) → Counter (suc (i + j))

Using this, defining the two crucial operations is straightforward (some proofs omitted for brevity):

_+1 : ∀ {n} → Counter n → Counter n
cut i zero    +1 = subst Counter {!!} (cut zero i)
cut i (suc j) +1 = subst Counter {!!} (cut (suc i) j)

_-1 : ∀ {n} → Counter n → Counter n
cut zero    j -1 = subst Counter {!!} (cut j zero)
cut (suc i) j -1 = subst Counter {!!} (cut i (suc j))

The problem comes when trying to prove that +1 and -1 are inverses. I keep running into situations where I need an eliminator for these substs introduced, i.e. something like

subst-elim : {A : Set} → {B : A → Set} → {x x′ : A} → {x=x′ : x ≡ x′} → {y : B x} → subst B x=x′ y ≡ y
subst-elim {A} {B} {x} {.x} {refl} = refl

but this turns out to be (somewhat) begging the question: it isn't accepted by the type checker, because subst B x=x' y : B x' and y : B x...

1 Answer 1

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you can state the type of your subst-elim if you use Relation.Binary.HeterogeneousEquality from the stdlib. However i'd probably just pattern match on the eventual proof of x ≡ x′ in a with or rewrite clause, so you don't have to make an explicit eliminator and so no typing problem.

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  • HeterogenousEquality feels like the right solution to this problem... However, I get a somewhat similar problem when trying to use that: I can't define something like Counter-cong : ∀ {n n′} {A : ℕ → Set} → (f : ∀{n} → Counter n → A n) → {k : Counter n} {k′ : Counter n′} → k ≅ k′ → f k ≅ f k′, because then I get the Refuse to solve heterogeneous constraint k : Counter n =?= k′ : Counter n′ error message...
    – Cactus
    Feb 15, 2012 at 15:30

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