------------------------------------------------------------------------
-- The Agda standard library
--
-- Vectors, basic types and operations
------------------------------------------------------------------------
{-# OPTIONS --cubical-compatible --safe #-}
module Data.Vec.Base where
open import Data.Bool.Base using (Bool; true; false; if_then_else_)
open import Data.Nat.Base
open import Data.Fin.Base using (Fin; zero; suc)
open import Data.List.Base as List using (List)
open import Data.Product.Base as Product using (∃; ∃₂; _×_; _,_; proj₁; proj₂)
open import Data.These.Base as These using (These; this; that; these)
open import Function.Base using (const; _∘′_; id; _∘_; _$_)
open import Level using (Level)
open import Relation.Binary.PropositionalEquality.Core using (_≡_; refl; trans; cong)
open import Relation.Nullary.Decidable.Core using (does; T?)
open import Relation.Unary using (Pred; Decidable)
private
variable
a b c p : Level
A : Set a
B : Set b
C : Set c
m n : ℕ
------------------------------------------------------------------------
-- Types
infixr 5 _∷_
data Vec (A : Set a) : ℕ → Set a where
[] : Vec A zero
_∷_ : ∀ (x : A) (xs : Vec A n) → Vec A (suc n)
infix 4 _[_]=_
data _[_]=_ {A : Set a} : Vec A n → Fin n → A → Set a where
here : ∀ {x} {xs : Vec A n} → x ∷ xs [ zero ]= x
there : ∀ {i} {x y} {xs : Vec A n}
(xs[i]=x : xs [ i ]= x) → y ∷ xs [ suc i ]= x
------------------------------------------------------------------------
-- Basic operations
length : Vec A n → ℕ
length {n = n} _ = n
head : Vec A (1 + n) → A
head (x ∷ xs) = x
tail : Vec A (1 + n) → Vec A n
tail (x ∷ xs) = xs
lookup : Vec A n → Fin n → A
lookup (x ∷ xs) zero = x
lookup (x ∷ xs) (suc i) = lookup xs i
iterate : (A → A) → A → ∀ n → Vec A n
iterate s z zero = []
iterate s z (suc n) = z ∷ iterate s (s z) n
insertAt : Vec A n → Fin (suc n) → A → Vec A (suc n)
insertAt xs zero v = v ∷ xs
insertAt (x ∷ xs) (suc i) v = x ∷ insertAt xs i v
removeAt : Vec A (suc n) → Fin (suc n) → Vec A n
removeAt (x ∷ xs) zero = xs
removeAt (x ∷ xs@(_ ∷ _)) (suc i) = x ∷ removeAt xs i
updateAt : Vec A n → Fin n → (A → A) → Vec A n
updateAt (x ∷ xs) zero f = f x ∷ xs
updateAt (x ∷ xs) (suc i) f = x ∷ updateAt xs i f
-- xs [ i ]%= f modifies the i-th element of xs according to f
infixl 6 _[_]%=_ _[_]≔_
_[_]%=_ : Vec A n → Fin n → (A → A) → Vec A n
xs [ i ]%= f = updateAt xs i f
-- xs [ i ]≔ y overwrites the i-th element of xs with y
_[_]≔_ : Vec A n → Fin n → A → Vec A n
xs [ i ]≔ y = xs [ i ]%= const y
------------------------------------------------------------------------
-- Operations for transforming vectors
-- See README.Data.Vec.Relation.Binary.Equality.Cast for the reasoning
-- system of `cast`-ed equality.
cast : .(eq : m ≡ n) → Vec A m → Vec A n
cast {n = zero} eq [] = []
cast {n = suc _} eq (x ∷ xs) = x ∷ cast (cong pred eq) xs
map : (A → B) → Vec A n → Vec B n
map f [] = []
map f (x ∷ xs) = f x ∷ map f xs
-- Concatenation.
infixr 5 _++_
_++_ : Vec A m → Vec A n → Vec A (m + n)
[] ++ ys = ys
(x ∷ xs) ++ ys = x ∷ (xs ++ ys)
concat : Vec (Vec A m) n → Vec A (n * m)
concat [] = []
concat (xs ∷ xss) = xs ++ concat xss
-- Align, Restrict, and Zip.
alignWith : (These A B → C) → Vec A m → Vec B n → Vec C (m ⊔ n)
alignWith f [] bs = map (f ∘′ that) bs
alignWith f as@(_ ∷ _) [] = map (f ∘′ this) as
alignWith f (a ∷ as) (b ∷ bs) = f (these a b) ∷ alignWith f as bs
restrictWith : (A → B → C) → Vec A m → Vec B n → Vec C (m ⊓ n)
restrictWith f [] bs = []
restrictWith f (_ ∷ _) [] = []
restrictWith f (a ∷ as) (b ∷ bs) = f a b ∷ restrictWith f as bs
zipWith : (A → B → C) → Vec A n → Vec B n → Vec C n
zipWith f [] [] = []
zipWith f (x ∷ xs) (y ∷ ys) = f x y ∷ zipWith f xs ys
unzipWith : (A → B × C) → Vec A n → Vec B n × Vec C n
unzipWith f [] = [] , []
unzipWith f (a ∷ as) = Product.zip _∷_ _∷_ (f a) (unzipWith f as)
align : Vec A m → Vec B n → Vec (These A B) (m ⊔ n)
align = alignWith id
restrict : Vec A m → Vec B n → Vec (A × B) (m ⊓ n)
restrict = restrictWith _,_
zip : Vec A n → Vec B n → Vec (A × B) n
zip = zipWith _,_
unzip : Vec (A × B) n → Vec A n × Vec B n
unzip = unzipWith id
-- Interleaving.
infixr 5 _⋎_
_⋎_ : Vec A m → Vec A n → Vec A (m +⋎ n)
[] ⋎ ys = ys
(x ∷ xs) ⋎ ys = x ∷ (ys ⋎ xs)
-- Pointwise application
infixl 4 _⊛_
_⊛_ : Vec (A → B) n → Vec A n → Vec B n
[] ⊛ [] = []
(f ∷ fs) ⊛ (x ∷ xs) = f x ∷ (fs ⊛ xs)
-- Multiplication
module CartesianBind where
infixl 1 _>>=_
_>>=_ : Vec A m → (A → Vec B n) → Vec B (m * n)
xs >>= f = concat (map f xs)
infixl 4 _⊛*_
_⊛*_ : Vec (A → B) m → Vec A n → Vec B (m * n)
fs ⊛* xs = fs CartesianBind.>>= λ f → map f xs
allPairs : Vec A m → Vec B n → Vec (A × B) (m * n)
allPairs xs ys = map _,_ xs ⊛* ys
-- Diagonal
diagonal : Vec (Vec A n) n → Vec A n
diagonal [] = []
diagonal (xs ∷ xss) = head xs ∷ diagonal (map tail xss)
module DiagonalBind where
infixl 1 _>>=_
_>>=_ : Vec A n → (A → Vec B n) → Vec B n
xs >>= f = diagonal (map f xs)
------------------------------------------------------------------------
-- Operations for reducing vectors
-- Dependent folds
module _ (A : Set a) (B : ℕ → Set b) where
FoldrOp = ∀ {n} → A → B n → B (suc n)
FoldlOp = ∀ {n} → B n → A → B (suc n)
foldr : ∀ (B : ℕ → Set b) → FoldrOp A B → B zero → Vec A n → B n
foldr B _⊕_ e [] = e
foldr B _⊕_ e (x ∷ xs) = x ⊕ foldr B _⊕_ e xs
foldl : ∀ (B : ℕ → Set b) → FoldlOp A B → B zero → Vec A n → B n
foldl B _⊕_ e [] = e
foldl B _⊕_ e (x ∷ xs) = foldl (B ∘ suc) _⊕_ (e ⊕ x) xs
-- Non-dependent folds
foldr′ : (A → B → B) → B → Vec A n → B
foldr′ _⊕_ = foldr _ _⊕_
foldl′ : (B → A → B) → B → Vec A n → B
foldl′ _⊕_ = foldl _ _⊕_
-- Non-empty folds
foldr₁ : (A → A → A) → Vec A (suc n) → A
foldr₁ _⊕_ (x ∷ []) = x
foldr₁ _⊕_ (x ∷ y ∷ ys) = x ⊕ foldr₁ _⊕_ (y ∷ ys)
foldl₁ : (A → A → A) → Vec A (suc n) → A
foldl₁ _⊕_ (x ∷ xs) = foldl _ _⊕_ x xs
-- Special folds
sum : Vec ℕ n → ℕ
sum = foldr _ _+_ 0
count : ∀ {P : Pred A p} → Decidable P → Vec A n → ℕ
count P? [] = zero
count P? (x ∷ xs) = if does (P? x) then suc else id $ count P? xs
countᵇ : (A → Bool) → Vec A n → ℕ
countᵇ p = count (T? ∘ p)
------------------------------------------------------------------------
-- Operations for building vectors
[_] : A → Vec A 1
[ x ] = x ∷ []
replicate : (n : ℕ) → A → Vec A n
replicate zero x = []
replicate (suc n) x = x ∷ replicate n x
tabulate : (Fin n → A) → Vec A n
tabulate {n = zero} f = []
tabulate {n = suc n} f = f zero ∷ tabulate (f ∘ suc)
allFin : ∀ n → Vec (Fin n) n
allFin _ = tabulate id
------------------------------------------------------------------------
-- Operations for dividing vectors
splitAt : ∀ m {n} (xs : Vec A (m + n)) →
∃₂ λ (ys : Vec A m) (zs : Vec A n) → xs ≡ ys ++ zs
splitAt zero xs = [] , xs , refl
splitAt (suc m) (x ∷ xs) =
let ys , zs , eq = splitAt m xs in x ∷ ys , zs , cong (x ∷_) eq
take : ∀ m {n} → Vec A (m + n) → Vec A m
take m xs = proj₁ (splitAt m xs)
drop : ∀ m {n} → Vec A (m + n) → Vec A n
drop m xs = proj₁ (proj₂ (splitAt m xs))
group : ∀ n k (xs : Vec A (n * k)) →
∃ λ (xss : Vec (Vec A k) n) → xs ≡ concat xss
group zero k [] = ([] , refl)
group (suc n) k xs =
let ys , zs , eq-split = splitAt k xs in
let zss , eq-group = group n k zs in
(ys ∷ zss) , trans eq-split (cong (ys ++_) eq-group)
split : Vec A n → Vec A ⌈ n /2⌉ × Vec A ⌊ n /2⌋
split [] = ([] , [])
split (x ∷ []) = (x ∷ [] , [])
split (x ∷ y ∷ xs) = Product.map (x ∷_) (y ∷_) (split xs)
uncons : Vec A (suc n) → A × Vec A n
uncons (x ∷ xs) = x , xs
------------------------------------------------------------------------
-- Operations involving ≤
-- Take the first 'm' elements of a vector.
truncate : ∀ {m n} → m ≤ n → Vec A n → Vec A m
truncate {m = zero} _ _ = []
truncate (s≤s le) (x ∷ xs) = x ∷ (truncate le xs)
-- Pad out a vector with extra elements.
padRight : ∀ {m n} → m ≤ n → A → Vec A m → Vec A n
padRight z≤n a xs = replicate _ a
padRight (s≤s le) a (x ∷ xs) = x ∷ padRight le a xs
------------------------------------------------------------------------
-- Operations for converting between lists
toList : Vec A n → List A
toList [] = List.[]
toList (x ∷ xs) = List._∷_ x (toList xs)
fromList : (xs : List A) → Vec A (List.length xs)
fromList List.[] = []
fromList (List._∷_ x xs) = x ∷ fromList xs
------------------------------------------------------------------------
-- Operations for reversing vectors
-- snoc
infixl 5 _∷ʳ_
_∷ʳ_ : Vec A n → A → Vec A (suc n)
[] ∷ʳ y = [ y ]
(x ∷ xs) ∷ʳ y = x ∷ (xs ∷ʳ y)
-- vanilla reverse
reverse : Vec A n → Vec A n
reverse = foldl (Vec _) (λ rev x → x ∷ rev) []
-- reverse-append
infix 5 _ʳ++_
_ʳ++_ : Vec A m → Vec A n → Vec A (m + n)
xs ʳ++ ys = foldl (Vec _ ∘ (_+ _)) (λ rev x → x ∷ rev) ys xs
-- init and last
initLast : ∀ (xs : Vec A (1 + n)) → ∃₂ λ ys y → xs ≡ ys ∷ʳ y
initLast {n = zero} (x ∷ []) = [] , x , refl
initLast {n = suc n} (x ∷ xs) =
let ys , y , eq = initLast xs in
x ∷ ys , y , cong (x ∷_) eq
init : Vec A (1 + n) → Vec A n
init xs = proj₁ (initLast xs)
last : Vec A (1 + n) → A
last xs = proj₁ (proj₂ (initLast xs))
------------------------------------------------------------------------
-- Other operations
transpose : Vec (Vec A n) m → Vec (Vec A m) n
transpose {n = n} [] = replicate n []
transpose {n = n} (as ∷ ass) = ((replicate n _∷_) ⊛ as) ⊛ transpose ass
------------------------------------------------------------------------
-- DEPRECATED
------------------------------------------------------------------------
-- Please use the new names as continuing support for the old names is
-- not guaranteed.
-- Version 2.0
remove = removeAt
{-# WARNING_ON_USAGE remove
"Warning: remove was deprecated in v2.0.
Please use removeAt instead."
#-}
insert = insertAt
{-# WARNING_ON_USAGE insert
"Warning: insert was deprecated in v2.0.
Please use insertAt instead."
#-}