Triangles #5
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{-# OPTIONS --safe --without-K #-}
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module Thinning.Triangle where
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open import Level
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open import Data.List.Base
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open import Relation.Binary.PropositionalEquality
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open import Thinning
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private
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variable
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a : Level
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A : Set a
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x : A
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xs ys zs : List A
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θ φ ψ : Thinning A xs ys
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-- Thinning triangles
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------------------------------------------------------------------------
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-- These are a sort of inductive view of "φ ∘ θ ≡ ψ" that's much easier to work
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-- with than a more direct definition. This helps a lot when working with slice
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-- categories!
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-- I choose the order of arguments to match composition order. The names are by
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-- the second argument, with "occlude" as another word that rhymes. Any aptitude
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-- is purely accidental.
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data Triangle (A : Set a) : Thinning A ys zs → Thinning A xs ys → Thinning A xs zs → Set a where
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end : Triangle A end end end
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include : Triangle A θ φ ψ → Triangle A (include {x = x} θ) (include φ) (include ψ)
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occlude : Triangle A θ φ ψ → Triangle A (exclude {x = x} θ) φ (exclude ψ)
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exclude : Triangle A θ φ ψ → Triangle A (include {x = x} θ) (exclude φ) (exclude ψ)
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-- We can construct a triangle by composition
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_⊚_ : (θ : Thinning A ys zs) (φ : Thinning A xs ys) → Triangle A θ φ (θ ∘ φ)
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end ⊚ end = end
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include θ ⊚ include φ = include (θ ⊚ φ)
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include θ ⊚ exclude φ = exclude (θ ⊚ φ)
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exclude θ ⊚ φ = occlude (θ ⊚ φ)
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-- We can deconstruct a triangle into a proof of equality to the composition
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untriangle : Triangle A θ φ ψ → θ ∘ φ ≡ ψ
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untriangle end = refl
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untriangle (include ▴) = cong include (untriangle ▴)
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untriangle (occlude ▴) = cong exclude (untriangle ▴)
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untriangle (exclude ▴) = cong exclude (untriangle ▴)
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