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Base.agda
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------------------------------------------------------------------------
-- The Agda standard library
--
-- Finite sets
------------------------------------------------------------------------
-- Note that elements of Fin n can be seen as natural numbers in the
-- set {m | m < n}. The notation "m" in comments below refers to this
-- natural number view.
{-# OPTIONS --cubical-compatible --safe #-}
module Data.Fin.Base where
open import Data.Bool.Base using (Bool; T)
open import Data.Nat.Base as ℕ using (ℕ; zero; suc)
open import Data.Product.Base as Product using (_×_; _,_; proj₁; proj₂)
open import Data.Sum.Base as Sum using (_⊎_; inj₁; inj₂; [_,_]′)
open import Function.Base using (id; _∘_; _on_; flip)
open import Level using (0ℓ)
open import Relation.Binary.Core
open import Relation.Binary.PropositionalEquality.Core using (_≡_; _≢_; refl; cong)
open import Relation.Binary.Indexed.Heterogeneous.Core using (IRel)
open import Relation.Nullary.Negation.Core using (contradiction)
private
variable
m n : ℕ
------------------------------------------------------------------------
-- Types
-- Fin n is a type with n elements.
data Fin : ℕ → Set where
zero : Fin (suc n)
suc : (i : Fin n) → Fin (suc n)
-- A conversion: toℕ "i" = i.
toℕ : Fin n → ℕ
toℕ zero = 0
toℕ (suc i) = suc (toℕ i)
-- A Fin-indexed variant of Fin.
Fin′ : Fin n → Set
Fin′ i = Fin (toℕ i)
------------------------------------------------------------------------
-- A cast that actually computes on constructors (as opposed to subst)
cast : .(m ≡ n) → Fin m → Fin n
cast {zero} {zero} eq k = k
cast {suc m} {suc n} eq zero = zero
cast {suc m} {suc n} eq (suc k) = suc (cast (cong ℕ.pred eq) k)
------------------------------------------------------------------------
-- Conversions
-- toℕ is defined above.
-- fromℕ n = "n".
fromℕ : (n : ℕ) → Fin (suc n)
fromℕ zero = zero
fromℕ (suc n) = suc (fromℕ n)
-- fromℕ< {m} _ = "m".
fromℕ< : .(m ℕ.< n) → Fin n
fromℕ< {zero} {suc _} _ = zero
fromℕ< {suc m} {suc _} m<n = suc (fromℕ< (ℕ.s<s⁻¹ m<n))
-- fromℕ<″ m _ = "m".
fromℕ<″ : ∀ m {n} → .(m ℕ.<″ n) → Fin n
fromℕ<″ zero {suc _} _ = zero
fromℕ<″ (suc m) {suc _} m<″n = suc (fromℕ<″ m (ℕ.s<″s⁻¹ m<″n))
-- canonical liftings of i:Fin m to larger index
-- injection on the left: "i" ↑ˡ n = "i" in Fin (m + n)
infixl 5 _↑ˡ_
_↑ˡ_ : ∀ {m} → Fin m → ∀ n → Fin (m ℕ.+ n)
zero ↑ˡ n = zero
(suc i) ↑ˡ n = suc (i ↑ˡ n)
-- injection on the right: n ↑ʳ "i" = "n + i" in Fin (n + m)
infixr 5 _↑ʳ_
_↑ʳ_ : ∀ {m} n → Fin m → Fin (n ℕ.+ m)
zero ↑ʳ i = i
(suc n) ↑ʳ i = suc (n ↑ʳ i)
-- reduce≥ "m + i" _ = "i".
reduce≥ : ∀ (i : Fin (m ℕ.+ n)) → .(m ℕ.≤ toℕ i) → Fin n
reduce≥ {zero} i _ = i
reduce≥ {suc _} (suc i) m≤i = reduce≥ i (ℕ.s≤s⁻¹ m≤i)
-- inject⋆ m "i" = "i".
inject : ∀ {i : Fin n} → Fin′ i → Fin n
inject {i = suc i} zero = zero
inject {i = suc i} (suc j) = suc (inject j)
inject! : ∀ {i : Fin (suc n)} → Fin′ i → Fin n
inject! {n = suc _} {i = suc _} zero = zero
inject! {n = suc _} {i = suc _} (suc j) = suc (inject! j)
inject₁ : Fin n → Fin (suc n)
inject₁ zero = zero
inject₁ (suc i) = suc (inject₁ i)
inject≤ : Fin m → .(m ℕ.≤ n) → Fin n
inject≤ {n = suc _} zero _ = zero
inject≤ {n = suc _} (suc i) m≤n = suc (inject≤ i (ℕ.s≤s⁻¹ m≤n))
-- lower₁ "i" _ = "i".
lower₁ : ∀ (i : Fin (suc n)) → n ≢ toℕ i → Fin n
lower₁ {zero} zero ne = contradiction refl ne
lower₁ {suc n} zero _ = zero
lower₁ {suc n} (suc i) ne = suc (lower₁ i (ne ∘ cong suc))
-- A strengthening injection into the minimal Fin fibre.
strengthen : ∀ (i : Fin n) → Fin′ (suc i)
strengthen zero = zero
strengthen (suc i) = suc (strengthen i)
-- splitAt m "i" = inj₁ "i" if i < m
-- inj₂ "i - m" if i ≥ m
-- This is dual to splitAt from Data.Vec.
splitAt : ∀ m {n} → Fin (m ℕ.+ n) → Fin m ⊎ Fin n
splitAt zero i = inj₂ i
splitAt (suc m) zero = inj₁ zero
splitAt (suc m) (suc i) = Sum.map suc id (splitAt m i)
-- inverse of above function
join : ∀ m n → Fin m ⊎ Fin n → Fin (m ℕ.+ n)
join m n = [ _↑ˡ n , m ↑ʳ_ ]′
-- quotRem k "i" = "i % k" , "i / k"
-- This is dual to group from Data.Vec.
quotRem : ∀ n → Fin (m ℕ.* n) → Fin n × Fin m
quotRem {suc m} n i with splitAt n i
... | inj₁ j = j , zero
... | inj₂ j = Product.map₂ suc (quotRem {m} n j)
-- a variant of quotRem the type of whose result matches the order of multiplication
remQuot : ∀ n → Fin (m ℕ.* n) → Fin m × Fin n
remQuot i = Product.swap ∘ quotRem i
quotient : ∀ n → Fin (m ℕ.* n) → Fin m
quotient n = proj₁ ∘ remQuot n
remainder : ∀ n → Fin (m ℕ.* n) → Fin n
remainder {m} n = proj₂ ∘ remQuot {m} n
-- inverse of remQuot
combine : Fin m → Fin n → Fin (m ℕ.* n)
combine {suc m} {n} zero j = j ↑ˡ (m ℕ.* n)
combine {suc m} {n} (suc i) j = n ↑ʳ (combine i j)
-- Next in progression after splitAt and remQuot
finToFun : Fin (m ℕ.^ n) → (Fin n → Fin m)
finToFun {m} {suc n} i zero = quotient (m ℕ.^ n) i
finToFun {m} {suc n} i (suc j) = finToFun (remainder {m} (m ℕ.^ n) i) j
-- inverse of above function
funToFin : (Fin m → Fin n) → Fin (n ℕ.^ m)
funToFin {zero} f = zero
funToFin {suc m} f = combine (f zero) (funToFin (f ∘ suc))
------------------------------------------------------------------------
-- Operations
-- Folds.
fold : ∀ {t} (T : ℕ → Set t) {m} →
(∀ {n} → T n → T (suc n)) →
(∀ {n} → T (suc n)) →
Fin m → T m
fold T f x zero = x
fold T f x (suc i) = f (fold T f x i)
fold′ : ∀ {n t} (T : Fin (suc n) → Set t) →
(∀ i → T (inject₁ i) → T (suc i)) →
T zero →
∀ i → T i
fold′ T f x zero = x
fold′ {n = suc n} T f x (suc i) =
f i (fold′ (T ∘ inject₁) (f ∘ inject₁) x i)
-- Lifts functions.
lift : ∀ k → (Fin m → Fin n) → Fin (k ℕ.+ m) → Fin (k ℕ.+ n)
lift zero f i = f i
lift (suc k) f zero = zero
lift (suc k) f (suc i) = suc (lift k f i)
-- "i" + "j" = "i + j".
infixl 6 _+_
_+_ : ∀ (i : Fin m) (j : Fin n) → Fin (toℕ i ℕ.+ n)
zero + j = j
suc i + j = suc (i + j)
-- "i" - "j" = "i ∸ j".
infixl 6 _-_
_-_ : ∀ (i : Fin n) (j : Fin′ (suc i)) → Fin (n ℕ.∸ toℕ j)
i - zero = i
suc i - suc j = i - j
-- m ℕ- "i" = "m ∸ i".
infixl 6 _ℕ-_
_ℕ-_ : (n : ℕ) (j : Fin (suc n)) → Fin (suc n ℕ.∸ toℕ j)
n ℕ- zero = fromℕ n
suc n ℕ- suc i = n ℕ- i
-- m ℕ-ℕ "i" = m ∸ i.
infixl 6 _ℕ-ℕ_
_ℕ-ℕ_ : (n : ℕ) → Fin (suc n) → ℕ
n ℕ-ℕ zero = n
suc n ℕ-ℕ suc i = n ℕ-ℕ i
-- pred "i" = "pred i".
pred : Fin n → Fin n
pred zero = zero
pred (suc i) = inject₁ i
-- opposite "i" = "n - i" (i.e. the additive inverse).
opposite : Fin n → Fin n
opposite {suc n} zero = fromℕ n
opposite {suc n} (suc i) = inject₁ (opposite i)
-- The function f(i,j) = if j>i then j-1 else j
-- This is a variant of the thick function from Conor
-- McBride's "First-order unification by structural recursion".
punchOut : ∀ {i j : Fin (suc n)} → i ≢ j → Fin n
punchOut {_} {zero} {zero} i≢j = contradiction refl i≢j
punchOut {_} {zero} {suc j} _ = j
punchOut {suc _} {suc i} {zero} _ = zero
punchOut {suc _} {suc i} {suc j} i≢j = suc (punchOut (i≢j ∘ cong suc))
-- The function f(i,j) = if j≥i then j+1 else j
punchIn : Fin (suc n) → Fin n → Fin (suc n)
punchIn zero j = suc j
punchIn (suc i) zero = zero
punchIn (suc i) (suc j) = suc (punchIn i j)
-- The function f(i,j) such that f(i,j) = if j≤i then j else j-1
pinch : Fin n → Fin (suc n) → Fin n
pinch {suc n} _ zero = zero
pinch {suc n} zero (suc j) = j
pinch {suc n} (suc i) (suc j) = suc (pinch i j)
------------------------------------------------------------------------
-- Order relations
infix 4 _≤_ _≥_ _<_ _>_
_≤_ : IRel Fin 0ℓ
i ≤ j = toℕ i ℕ.≤ toℕ j
_≥_ : IRel Fin 0ℓ
i ≥ j = toℕ i ℕ.≥ toℕ j
_<_ : IRel Fin 0ℓ
i < j = toℕ i ℕ.< toℕ j
_>_ : IRel Fin 0ℓ
i > j = toℕ i ℕ.> toℕ j
------------------------------------------------------------------------
-- An ordering view.
data Ordering {n : ℕ} : Fin n → Fin n → Set where
less : ∀ greatest (least : Fin′ greatest) →
Ordering (inject least) greatest
equal : ∀ i → Ordering i i
greater : ∀ greatest (least : Fin′ greatest) →
Ordering greatest (inject least)
compare : ∀ (i j : Fin n) → Ordering i j
compare zero zero = equal zero
compare zero (suc j) = less (suc j) zero
compare (suc i) zero = greater (suc i) zero
compare (suc i) (suc j) with compare i j
... | less greatest least = less (suc greatest) (suc least)
... | greater greatest least = greater (suc greatest) (suc least)
... | equal i = equal (suc i)
------------------------------------------------------------------------
-- DEPRECATED NAMES
------------------------------------------------------------------------
-- Please use the new names as continuing support for the old names is
-- not guaranteed.
-- Version 2.0
raise = _↑ʳ_
{-# WARNING_ON_USAGE raise
"Warning: raise was deprecated in v2.0.
Please use _↑ʳ_ instead."
#-}
inject+ : ∀ {m} n → Fin m → Fin (m ℕ.+ n)
inject+ n i = i ↑ˡ n
{-# WARNING_ON_USAGE inject+
"Warning: inject+ was deprecated in v2.0.
Please use _↑ˡ_ instead.
NB argument order has been flipped:
the left-hand argument is the Fin m
the right-hand is the Nat index increment."
#-}
data _≺_ : ℕ → ℕ → Set where
_≻toℕ_ : ∀ n (i : Fin n) → toℕ i ≺ n
{-# WARNING_ON_USAGE _≺_
"Warning: _≺_ was deprecated in v2.0.
Please use equivalent relation _<_ instead."
#-}
{-# WARNING_ON_USAGE _≻toℕ_
"Warning: _≻toℕ_ was deprecated in v2.0.
Please use toℕ<n from Data.Fin.Properties instead."
#-}