mirror of
https://github.com/idris-lang/Idris2.git
synced 2024-12-23 19:54:50 +03:00
811 lines
22 KiB
Idris
811 lines
22 KiB
Idris
module Data.Nat
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import public Control.Relation
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import public Control.Ord
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import public Control.Order
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import public Control.Function
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%default total
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export
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Uninhabited (Z = S n) where
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uninhabited Refl impossible
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export
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Uninhabited (S n = Z) where
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uninhabited Refl impossible
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export
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Uninhabited (a = b) => Uninhabited (S a = S b) where
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uninhabited Refl @{ab} = uninhabited @{ab} Refl
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public export
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isZero : Nat -> Bool
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isZero Z = True
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isZero (S n) = False
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public export
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isSucc : Nat -> Bool
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isSucc Z = False
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isSucc (S n) = True
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public export
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data IsSucc : (n : Nat) -> Type where
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ItIsSucc : IsSucc (S n)
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export
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Uninhabited (IsSucc Z) where
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uninhabited ItIsSucc impossible
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public export
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isItSucc : (n : Nat) -> Dec (IsSucc n)
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isItSucc Z = No absurd
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isItSucc (S n) = Yes ItIsSucc
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public export
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power : Nat -> Nat -> Nat
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power base Z = S Z
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power base (S exp) = base * (power base exp)
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public export
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hyper : Nat -> Nat -> Nat -> Nat
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hyper Z a b = S b
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hyper (S Z) a Z = a
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hyper (S(S Z)) a Z = Z
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hyper n a Z = S Z
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hyper (S pn) a (S pb) = hyper pn a (hyper (S pn) a pb)
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public export
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pred : Nat -> Nat
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pred Z = Z
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pred (S n) = n
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-- Comparisons
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export
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compareNatDiag : (k : Nat) -> compareNat k k === EQ
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compareNatDiag Z = Refl
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compareNatDiag (S k) = compareNatDiag k
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export
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compareNatFlip : (m, n : Nat) ->
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flip Prelude.compareNat m n === contra (compareNat m n)
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compareNatFlip 0 0 = Refl
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compareNatFlip 0 (S n) = Refl
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compareNatFlip (S m) 0 = Refl
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compareNatFlip (S m) (S n) = compareNatFlip m n
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public export
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data NotBothZero : (n, m : Nat) -> Type where
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LeftIsNotZero : NotBothZero (S n) m
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RightIsNotZero : NotBothZero n (S m)
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export
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Uninhabited (NotBothZero 0 0) where
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uninhabited LeftIsNotZero impossible
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uninhabited RightIsNotZero impossible
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public export
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data LTE : (n, m : Nat) -> Type where
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LTEZero : LTE Z right
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LTESucc : LTE left right -> LTE (S left) (S right)
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export
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Uninhabited (LTE (S n) Z) where
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uninhabited LTEZero impossible
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export
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Uninhabited (LTE m n) => Uninhabited (LTE (S m) (S n)) where
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uninhabited (LTESucc lte) = uninhabited lte
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public export
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Reflexive Nat LTE where
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reflexive {x = Z} = LTEZero
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reflexive {x = S _} = LTESucc $ reflexive
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public export
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Transitive Nat LTE where
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transitive LTEZero _ = LTEZero
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transitive (LTESucc xy) (LTESucc yz) =
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LTESucc $ transitive xy yz
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public export
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Antisymmetric Nat LTE where
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antisymmetric LTEZero LTEZero = Refl
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antisymmetric (LTESucc xy) (LTESucc yx) =
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cong S $ antisymmetric xy yx
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public export
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Connex Nat LTE where
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connex {x = Z} _ = Left LTEZero
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connex {y = Z} _ = Right LTEZero
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connex {x = S _} {y = S _} prf =
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case connex $ prf . (cong S) of
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Left jk => Left $ LTESucc jk
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Right kj => Right $ LTESucc kj
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public export
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Preorder Nat LTE where
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public export
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PartialOrder Nat LTE where
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public export
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LinearOrder Nat LTE where
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public export
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GTE : Nat -> Nat -> Type
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GTE left right = LTE right left
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public export
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LT : Nat -> Nat -> Type
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LT left right = LTE (S left) right
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namespace LT
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||| LT is defined in terms of LTE which makes it annoying to use.
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||| This convenient view of allows us to avoid having to constantly
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||| perform nested matches to obtain another LT subproof instead of
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||| an LTE one.
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public export
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data View : LT m n -> Type where
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LTZero : View (LTESucc LTEZero)
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LTSucc : (lt : m `LT` n) -> View (LTESucc lt)
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||| Deconstruct an LT proof into either a base case or a further *LT*
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export
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view : (lt : LT m n) -> View lt
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view (LTESucc LTEZero) = LTZero
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view (LTESucc lt@(LTESucc _)) = LTSucc lt
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||| A convenient alias for trivial LT proofs
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export
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ltZero : Z `LT` S m
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ltZero = LTESucc LTEZero
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public export
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GT : Nat -> Nat -> Type
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GT left right = LT right left
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export
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succNotLTEzero : Not (LTE (S m) Z)
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succNotLTEzero LTEZero impossible
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export
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fromLteSucc : LTE (S m) (S n) -> LTE m n
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fromLteSucc (LTESucc x) = x
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export
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succNotLTEpred : {x : Nat} -> Not $ LTE (S x) x
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succNotLTEpred {x = 0} prf = succNotLTEzero prf
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succNotLTEpred {x = S _} prf = succNotLTEpred $ fromLteSucc prf
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public export
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isLTE : (m, n : Nat) -> Dec (LTE m n)
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isLTE Z n = Yes LTEZero
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isLTE (S k) Z = No succNotLTEzero
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isLTE (S k) (S j)
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= case isLTE k j of
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No contra => No (contra . fromLteSucc)
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Yes prf => Yes (LTESucc prf)
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public export
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isGTE : (m, n : Nat) -> Dec (GTE m n)
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isGTE m n = isLTE n m
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public export
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isLT : (m, n : Nat) -> Dec (LT m n)
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isLT m n = isLTE (S m) n
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public export
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isGT : (m, n : Nat) -> Dec (GT m n)
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isGT m n = isLT n m
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export
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lteSuccRight : LTE n m -> LTE n (S m)
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lteSuccRight LTEZero = LTEZero
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lteSuccRight (LTESucc x) = LTESucc (lteSuccRight x)
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export
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lteSuccLeft : LTE (S n) m -> LTE n m
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lteSuccLeft (LTESucc x) = lteSuccRight x
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export
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lteAddRight : (n : Nat) -> LTE n (n + m)
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lteAddRight Z = LTEZero
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lteAddRight (S k) {m} = LTESucc (lteAddRight {m} k)
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export
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notLTEImpliesGT : {a, b : Nat} -> Not (a `LTE` b) -> a `GT` b
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notLTEImpliesGT {a = 0 } not_z_lte_b = absurd $ not_z_lte_b LTEZero
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notLTEImpliesGT {a = S a} {b = 0 } notLTE = LTESucc LTEZero
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notLTEImpliesGT {a = S a} {b = S k} notLTE = LTESucc (notLTEImpliesGT (notLTE . LTESucc))
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export
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LTEImpliesNotGT : a `LTE` b -> Not (a `GT` b)
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LTEImpliesNotGT LTEZero q = absurd q
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LTEImpliesNotGT (LTESucc p) (LTESucc q) = LTEImpliesNotGT p q
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export
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notLTImpliesGTE : {a, b : _} -> Not (LT a b) -> GTE a b
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notLTImpliesGTE notLT = fromLteSucc $ notLTEImpliesGT notLT
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export
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LTImpliesNotGTE : a `LT` b -> Not (a `GTE` b)
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LTImpliesNotGTE p q = LTEImpliesNotGT q p
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public export
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lte : Nat -> Nat -> Bool
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lte Z right = True
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lte left Z = False
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lte (S left) (S right) = lte left right
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public export
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gte : Nat -> Nat -> Bool
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gte left right = lte right left
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public export
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lt : Nat -> Nat -> Bool
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lt left right = lte (S left) right
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public export
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gt : Nat -> Nat -> Bool
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gt left right = lt right left
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export
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lteReflectsLTE : (k : Nat) -> (n : Nat) -> lte k n === True -> k `LTE` n
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lteReflectsLTE (S k) 0 _ impossible
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lteReflectsLTE 0 0 _ = LTEZero
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lteReflectsLTE 0 (S k) _ = LTEZero
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lteReflectsLTE (S k) (S j) prf = LTESucc (lteReflectsLTE k j prf)
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export
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gteReflectsGTE : (k : Nat) -> (n : Nat) -> gte k n === True -> k `GTE` n
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gteReflectsGTE k n prf = lteReflectsLTE n k prf
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export
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ltReflectsLT : (k : Nat) -> (n : Nat) -> lt k n === True -> k `LT` n
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ltReflectsLT k n prf = lteReflectsLTE (S k) n prf
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export
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gtReflectsGT : (k : Nat) -> (n : Nat) -> gt k n === True -> k `GT` n
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gtReflectsGT k n prf = ltReflectsLT n k prf
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public export
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minimum : Nat -> Nat -> Nat
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minimum Z m = Z
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minimum (S n) Z = Z
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minimum (S n) (S m) = S (minimum n m)
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public export
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maximum : Nat -> Nat -> Nat
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maximum Z m = m
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maximum (S n) Z = S n
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maximum (S n) (S m) = S (maximum n m)
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-- Proofs on S
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export
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eqSucc : (0 left, right : Nat) -> left = right -> S left = S right
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eqSucc _ _ Refl = Refl
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export
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Injective S where
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injective Refl = Refl
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||| A definition of non-zero with a better behaviour than `Not (x = Z)`
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||| This is amenable to proof search and `NonZero Z` is more readily
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||| detected as impossible by Idris
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public export
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data NonZero : Nat -> Type where
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SIsNonZero : NonZero (S x)
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export Uninhabited (NonZero Z) where uninhabited SIsNonZero impossible
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export
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SIsNotZ : Not (S x = Z)
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SIsNotZ = absurd
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||| Auxiliary function:
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||| mod' fuel a b = a `mod` (S b)
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||| assuming we have enough fuel
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public export
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mod' : Nat -> Nat -> Nat -> Nat
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mod' Z centre right = centre
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mod' (S fuel) centre right =
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if lte centre right then
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centre
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else
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mod' fuel (minus centre (S right)) right
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public export
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modNatNZ : Nat -> (y: Nat) -> (0 _ : NonZero y) -> Nat
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modNatNZ left Z p = void (absurd p)
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modNatNZ left (S right) _ = mod' left left right
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export partial
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modNat : Nat -> Nat -> Nat
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modNat left (S right) = modNatNZ left (S right) SIsNonZero
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||| Auxiliary function:
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||| div' fuel a b = a `div` (S b)
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||| assuming we have enough fuel
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public export
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div' : Nat -> Nat -> Nat -> Nat
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div' Z centre right = Z
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div' (S fuel) centre right =
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if lte centre right then
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Z
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else
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S (div' fuel (minus centre (S right)) right)
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-- 'public' to allow type-level division
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public export
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divNatNZ : Nat -> (y: Nat) -> (0 _ : NonZero y) -> Nat
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divNatNZ left (S right) _ = div' left left right
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export partial
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divNat : Nat -> Nat -> Nat
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divNat left (S right) = divNatNZ left (S right) SIsNonZero
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export
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covering
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divCeilNZ : Nat -> (y: Nat) -> (0 _ : NonZero y) -> Nat
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divCeilNZ x y p = case (modNatNZ x y p) of
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Z => divNatNZ x y p
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S _ => S (divNatNZ x y p)
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export partial
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divCeil : Nat -> Nat -> Nat
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divCeil x (S y) = divCeilNZ x (S y) SIsNonZero
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public export
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divmod' : Nat -> Nat -> Nat -> (Nat, Nat)
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divmod' Z centre right = (Z, centre)
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divmod' (S fuel) centre right =
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if lte centre right then
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(Z, centre)
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else
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let qr = divmod' fuel (minus centre (S right)) right
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in (S (fst qr), snd qr)
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public export
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divmodNatNZ : Nat -> (y: Nat) -> (0 _ : NonZero y) -> (Nat, Nat)
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divmodNatNZ left (S right) _ = divmod' left left right
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public export
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Integral Nat where
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div = divNat
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mod = modNat
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export
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covering
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gcd : (a: Nat) -> (b: Nat) -> {auto ok: NotBothZero a b} -> Nat
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gcd a Z = a
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gcd Z b = b
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gcd a (S b) = gcd (S b) (modNatNZ a (S b) SIsNonZero)
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export partial
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lcm : Nat -> Nat -> Nat
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lcm _ Z = Z
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lcm Z _ = Z
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lcm a (S b) = divNat (a * (S b)) (gcd a (S b))
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--------------------------------------------------------------------------------
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-- An informative comparison view
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--------------------------------------------------------------------------------
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public export
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data CmpNat : Nat -> Nat -> Type where
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CmpLT : (y : _) -> CmpNat x (x + S y)
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CmpEQ : CmpNat x x
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CmpGT : (x : _) -> CmpNat (y + S x) y
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export
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cmp : (x, y : Nat) -> CmpNat x y
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cmp Z Z = CmpEQ
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cmp Z (S k) = CmpLT _
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cmp (S k) Z = CmpGT _
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cmp (S x) (S y) with (cmp x y)
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cmp (S x) (S (x + (S k))) | CmpLT k = CmpLT k
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cmp (S x) (S x) | CmpEQ = CmpEQ
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cmp (S (y + (S k))) (S y) | CmpGT k = CmpGT k
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-- Proofs on +
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export
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plusZeroLeftNeutral : (right : Nat) -> 0 + right = right
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plusZeroLeftNeutral _ = Refl
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export
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plusZeroRightNeutral : (left : Nat) -> left + 0 = left
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plusZeroRightNeutral Z = Refl
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plusZeroRightNeutral (S n) = rewrite plusZeroRightNeutral n in Refl
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export
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plusSuccRightSucc : (left, right : Nat) -> S (left + right) = left + (S right)
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plusSuccRightSucc Z _ = Refl
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plusSuccRightSucc (S left) right = rewrite plusSuccRightSucc left right in Refl
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export
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plusCommutative : (left, right : Nat) -> left + right = right + left
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plusCommutative Z right = rewrite plusZeroRightNeutral right in Refl
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plusCommutative (S left) right =
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rewrite plusCommutative left right in
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rewrite plusSuccRightSucc right left in
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Refl
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export
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plusAssociative : (left, centre, right : Nat) ->
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left + (centre + right) = (left + centre) + right
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plusAssociative Z _ _ = Refl
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plusAssociative (S left) centre right =
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rewrite plusAssociative left centre right in Refl
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export
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plusConstantRight : (left, right, c : Nat) -> left = right ->
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left + c = right + c
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plusConstantRight _ _ _ Refl = Refl
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export
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plusConstantLeft : (left, right, c : Nat) -> left = right ->
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c + left = c + right
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plusConstantLeft _ _ _ Refl = Refl
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export
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plusOneSucc : (right : Nat) -> 1 + right = S right
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plusOneSucc _ = Refl
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export
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plusLeftCancel : (left, right, right' : Nat) ->
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left + right = left + right' -> right = right'
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plusLeftCancel Z _ _ p = p
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plusLeftCancel (S left) right right' p =
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plusLeftCancel left right right' $ injective p
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export
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plusRightCancel : (left, left', right : Nat) ->
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left + right = left' + right -> left = left'
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plusRightCancel left left' right p =
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plusLeftCancel right left left' $
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rewrite plusCommutative right left in
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rewrite plusCommutative right left' in
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p
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export
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plusLeftLeftRightZero : (left, right : Nat) ->
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left + right = left -> right = Z
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plusLeftLeftRightZero left right p =
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plusLeftCancel left right Z $
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rewrite plusZeroRightNeutral left in
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p
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export
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plusLteMonotoneRight : (p, q, r : Nat) -> q `LTE` r -> (q+p) `LTE` (r+p)
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plusLteMonotoneRight p Z r LTEZero = rewrite plusCommutative r p in
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lteAddRight p
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plusLteMonotoneRight p (S q) (S r) (LTESucc l) = LTESucc $ plusLteMonotoneRight p q r l
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export
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plusLteMonotoneLeft : (p, q, r : Nat) -> q `LTE` r -> (p + q) `LTE` (p + r)
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plusLteMonotoneLeft p q r p_lt_q
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= rewrite plusCommutative p q in
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rewrite plusCommutative p r in
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plusLteMonotoneRight p q r p_lt_q
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export
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plusLteMonotone : {m, n, p, q : Nat} -> m `LTE` n -> p `LTE` q ->
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(m + p) `LTE` (n + q)
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plusLteMonotone left right =
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transitive
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(plusLteMonotoneLeft m p q right)
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(plusLteMonotoneRight q m n left)
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zeroPlusLeftZero : (a,b : Nat) -> (0 = a + b) -> a = 0
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zeroPlusLeftZero 0 0 Refl = Refl
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zeroPlusLeftZero (S k) b _ impossible
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zeroPlusRightZero : (a,b : Nat) -> (0 = a + b) -> b = 0
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zeroPlusRightZero 0 0 Refl = Refl
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|
zeroPlusRightZero (S k) b _ impossible
|
|
|
|
-- Proofs on *
|
|
|
|
export
|
|
multZeroLeftZero : (right : Nat) -> Z * right = Z
|
|
multZeroLeftZero _ = Refl
|
|
|
|
export
|
|
multZeroRightZero : (left : Nat) -> left * Z = Z
|
|
multZeroRightZero Z = Refl
|
|
multZeroRightZero (S left) = multZeroRightZero left
|
|
|
|
export
|
|
multRightSuccPlus : (left, right : Nat) ->
|
|
left * (S right) = left + (left * right)
|
|
multRightSuccPlus Z _ = Refl
|
|
multRightSuccPlus (S left) right =
|
|
rewrite multRightSuccPlus left right in
|
|
rewrite plusAssociative left right (left * right) in
|
|
rewrite plusAssociative right left (left * right) in
|
|
rewrite plusCommutative right left in
|
|
Refl
|
|
|
|
export
|
|
multLeftSuccPlus : (left, right : Nat) ->
|
|
(S left) * right = right + (left * right)
|
|
multLeftSuccPlus _ _ = Refl
|
|
|
|
export
|
|
multCommutative : (left, right : Nat) -> left * right = right * left
|
|
multCommutative Z right = rewrite multZeroRightZero right in Refl
|
|
multCommutative (S left) right =
|
|
rewrite multCommutative left right in
|
|
rewrite multRightSuccPlus right left in
|
|
Refl
|
|
|
|
export
|
|
multDistributesOverPlusLeft : (left, centre, right : Nat) ->
|
|
(left + centre) * right = (left * right) + (centre * right)
|
|
multDistributesOverPlusLeft Z _ _ = Refl
|
|
multDistributesOverPlusLeft (S k) centre right =
|
|
rewrite multDistributesOverPlusLeft k centre right in
|
|
rewrite plusAssociative right (k * right) (centre * right) in
|
|
Refl
|
|
|
|
export
|
|
multDistributesOverPlusRight : (left, centre, right : Nat) ->
|
|
left * (centre + right) = (left * centre) + (left * right)
|
|
multDistributesOverPlusRight left centre right =
|
|
rewrite multCommutative left (centre + right) in
|
|
rewrite multCommutative left centre in
|
|
rewrite multCommutative left right in
|
|
multDistributesOverPlusLeft centre right left
|
|
|
|
export
|
|
multAssociative : (left, centre, right : Nat) ->
|
|
left * (centre * right) = (left * centre) * right
|
|
multAssociative Z _ _ = Refl
|
|
multAssociative (S left) centre right =
|
|
rewrite multAssociative left centre right in
|
|
rewrite multDistributesOverPlusLeft centre (mult left centre) right in
|
|
Refl
|
|
|
|
export
|
|
multOneLeftNeutral : (right : Nat) -> 1 * right = right
|
|
multOneLeftNeutral right = plusZeroRightNeutral right
|
|
|
|
export
|
|
multOneRightNeutral : (left : Nat) -> left * 1 = left
|
|
multOneRightNeutral left =
|
|
rewrite multCommutative left 1 in
|
|
multOneLeftNeutral left
|
|
|
|
-- Proofs on minus
|
|
|
|
export
|
|
minusSuccSucc : (left, right : Nat) ->
|
|
minus (S left) (S right) = minus left right
|
|
minusSuccSucc _ _ = Refl
|
|
|
|
export
|
|
minusZeroLeft : (right : Nat) -> minus 0 right = Z
|
|
minusZeroLeft _ = Refl
|
|
|
|
export
|
|
minusZeroRight : (left : Nat) -> minus left 0 = left
|
|
minusZeroRight Z = Refl
|
|
minusZeroRight (S _) = Refl
|
|
|
|
export
|
|
minusZeroN : (n : Nat) -> Z = minus n n
|
|
minusZeroN Z = Refl
|
|
minusZeroN (S n) = minusZeroN n
|
|
|
|
export
|
|
minusOneSuccN : (n : Nat) -> S Z = minus (S n) n
|
|
minusOneSuccN Z = Refl
|
|
minusOneSuccN (S n) = minusOneSuccN n
|
|
|
|
export
|
|
minusSuccOne : (n : Nat) -> minus (S n) 1 = n
|
|
minusSuccOne Z = Refl
|
|
minusSuccOne (S _) = Refl
|
|
|
|
export
|
|
minusPlusZero : (n, m : Nat) -> minus n (n + m) = Z
|
|
minusPlusZero Z _ = Refl
|
|
minusPlusZero (S n) m = minusPlusZero n m
|
|
|
|
export
|
|
minusPos : m `LT` n -> Z `LT` minus n m
|
|
minusPos lt = case view lt of
|
|
LTZero => ltZero
|
|
LTSucc lt => minusPos lt
|
|
|
|
export
|
|
minusLteMonotone : {p : Nat} -> m `LTE` n -> minus m p `LTE` minus n p
|
|
minusLteMonotone LTEZero = LTEZero
|
|
minusLteMonotone {p = Z} prf@(LTESucc _) = prf
|
|
minusLteMonotone {p = S p} (LTESucc lte) = minusLteMonotone lte
|
|
|
|
export
|
|
minusLtMonotone : m `LT` n -> p `LT` n -> minus m p `LT` minus n p
|
|
minusLtMonotone mltn pltn = case view pltn of
|
|
LTZero => rewrite minusZeroRight m in mltn
|
|
LTSucc pltn => case view mltn of
|
|
LTZero => minusPos pltn
|
|
LTSucc mltn => minusLtMonotone mltn pltn
|
|
|
|
public export
|
|
minusPlus : (m : Nat) -> minus (plus m n) m === n
|
|
minusPlus Z = irrelevantEq (minusZeroRight n)
|
|
minusPlus (S m) = minusPlus m
|
|
|
|
export
|
|
plusMinusLte : (n, m : Nat) -> LTE n m -> (minus m n) + n = m
|
|
plusMinusLte Z m _ = rewrite minusZeroRight m in
|
|
plusZeroRightNeutral m
|
|
plusMinusLte (S _) Z lte = absurd lte
|
|
plusMinusLte (S n) (S m) lte = rewrite sym $ plusSuccRightSucc (minus m n) n in
|
|
cong S $ plusMinusLte n m (fromLteSucc lte)
|
|
|
|
export
|
|
minusMinusMinusPlus : (left, centre, right : Nat) ->
|
|
minus (minus left centre) right = minus left (centre + right)
|
|
minusMinusMinusPlus Z Z _ = Refl
|
|
minusMinusMinusPlus (S _) Z _ = Refl
|
|
minusMinusMinusPlus Z (S _) _ = Refl
|
|
minusMinusMinusPlus (S left) (S centre) right =
|
|
rewrite minusMinusMinusPlus left centre right in Refl
|
|
|
|
export
|
|
plusMinusLeftCancel : (left, right : Nat) -> (right' : Nat) ->
|
|
minus (left + right) (left + right') = minus right right'
|
|
plusMinusLeftCancel Z _ _ = Refl
|
|
plusMinusLeftCancel (S left) right right' =
|
|
rewrite plusMinusLeftCancel left right right' in Refl
|
|
|
|
export
|
|
multDistributesOverMinusLeft : (left, centre, right : Nat) ->
|
|
(minus left centre) * right = minus (left * right) (centre * right)
|
|
multDistributesOverMinusLeft Z Z _ = Refl
|
|
multDistributesOverMinusLeft (S left) Z right =
|
|
rewrite minusZeroRight (right + (left * right)) in Refl
|
|
multDistributesOverMinusLeft Z (S _) _ = Refl
|
|
multDistributesOverMinusLeft (S left) (S centre) right =
|
|
rewrite multDistributesOverMinusLeft left centre right in
|
|
rewrite plusMinusLeftCancel right (left * right) (centre * right) in
|
|
Refl
|
|
|
|
export
|
|
multDistributesOverMinusRight : (left, centre, right : Nat) ->
|
|
left * (minus centre right) = minus (left * centre) (left * right)
|
|
multDistributesOverMinusRight left centre right =
|
|
rewrite multCommutative left (minus centre right) in
|
|
rewrite multDistributesOverMinusLeft centre right left in
|
|
rewrite multCommutative centre left in
|
|
rewrite multCommutative right left in
|
|
Refl
|
|
|
|
export
|
|
zeroMultEitherZero : (a,b : Nat) -> a*b = 0 -> Either (a = 0) (b = 0)
|
|
zeroMultEitherZero 0 b prf = Left Refl
|
|
zeroMultEitherZero (S a) b prf = Right $ zeroPlusLeftZero b (a * b) (sym prf)
|
|
|
|
-- power proofs
|
|
|
|
-- multPowerPowerPlus : (base, exp, exp' : Nat) ->
|
|
-- power base (exp + exp') = (power base exp) * (power base exp')
|
|
-- multPowerPowerPlus base Z exp' =
|
|
-- rewrite sym $ plusZeroRightNeutral (power base exp') in Refl
|
|
-- multPowerPowerPlus base (S exp) exp' =
|
|
-- rewrite multPowerPowerPlus base exp exp' in
|
|
-- rewrite sym $ multAssociative base (power base exp) (power base exp') in
|
|
-- Refl
|
|
|
|
--powerOneNeutral : (base : Nat) -> power base 1 = base
|
|
--powerOneNeutral base = rewrite multCommutative base 1 in multOneLeftNeutral base
|
|
--
|
|
--powerOneSuccOne : (exp : Nat) -> power 1 exp = 1
|
|
--powerOneSuccOne Z = Refl
|
|
--powerOneSuccOne (S exp) = rewrite powerOneSuccOne exp in Refl
|
|
--
|
|
--powerPowerMultPower : (base, exp, exp' : Nat) ->
|
|
-- power (power base exp) exp' = power base (exp * exp')
|
|
--powerPowerMultPower _ exp Z = rewrite multZeroRightZero exp in Refl
|
|
--powerPowerMultPower base exp (S exp') =
|
|
-- rewrite powerPowerMultPower base exp exp' in
|
|
-- rewrite multRightSuccPlus exp exp' in
|
|
-- rewrite sym $ multPowerPowerPlus base exp (exp * exp') in
|
|
-- Refl
|
|
|
|
-- minimum / maximum proofs
|
|
|
|
export
|
|
maximumAssociative : (l, c, r : Nat) ->
|
|
maximum l (maximum c r) = maximum (maximum l c) r
|
|
maximumAssociative Z _ _ = Refl
|
|
maximumAssociative (S _) Z _ = Refl
|
|
maximumAssociative (S _) (S _) Z = Refl
|
|
maximumAssociative (S k) (S j) (S i) = rewrite maximumAssociative k j i in Refl
|
|
|
|
export
|
|
maximumCommutative : (l, r : Nat) -> maximum l r = maximum r l
|
|
maximumCommutative Z Z = Refl
|
|
maximumCommutative Z (S _) = Refl
|
|
maximumCommutative (S _) Z = Refl
|
|
maximumCommutative (S k) (S j) = rewrite maximumCommutative k j in Refl
|
|
|
|
export
|
|
maximumIdempotent : (n : Nat) -> maximum n n = n
|
|
maximumIdempotent Z = Refl
|
|
maximumIdempotent (S k) = cong S $ maximumIdempotent k
|
|
|
|
export
|
|
minimumAssociative : (l, c, r : Nat) ->
|
|
minimum l (minimum c r) = minimum (minimum l c) r
|
|
minimumAssociative Z _ _ = Refl
|
|
minimumAssociative (S _) Z _ = Refl
|
|
minimumAssociative (S _) (S _) Z = Refl
|
|
minimumAssociative (S k) (S j) (S i) = rewrite minimumAssociative k j i in Refl
|
|
|
|
export
|
|
minimumCommutative : (l, r : Nat) -> minimum l r = minimum r l
|
|
minimumCommutative Z Z = Refl
|
|
minimumCommutative Z (S _) = Refl
|
|
minimumCommutative (S _) Z = Refl
|
|
minimumCommutative (S k) (S j) = rewrite minimumCommutative k j in Refl
|
|
|
|
export
|
|
minimumIdempotent : (n : Nat) -> minimum n n = n
|
|
minimumIdempotent Z = Refl
|
|
minimumIdempotent (S k) = cong S $ minimumIdempotent k
|
|
|
|
export
|
|
minimumZeroZeroLeft : (left : Nat) -> minimum left 0 = Z
|
|
minimumZeroZeroLeft left = rewrite minimumCommutative left 0 in Refl
|
|
|
|
export
|
|
minimumSuccSucc : (left, right : Nat) ->
|
|
minimum (S left) (S right) = S (minimum left right)
|
|
minimumSuccSucc _ _ = Refl
|
|
|
|
export
|
|
maximumZeroNLeft : (left : Nat) -> maximum left Z = left
|
|
maximumZeroNLeft left = rewrite maximumCommutative left Z in Refl
|
|
|
|
export
|
|
maximumSuccSucc : (left, right : Nat) ->
|
|
S (maximum left right) = maximum (S left) (S right)
|
|
maximumSuccSucc _ _ = Refl
|
|
|
|
export
|
|
sucMaxL : (l : Nat) -> maximum (S l) l = (S l)
|
|
sucMaxL Z = Refl
|
|
sucMaxL (S l) = cong S $ sucMaxL l
|
|
|
|
export
|
|
sucMaxR : (l : Nat) -> maximum l (S l) = (S l)
|
|
sucMaxR Z = Refl
|
|
sucMaxR (S l) = cong S $ sucMaxR l
|
|
|
|
export
|
|
sucMinL : (l : Nat) -> minimum (S l) l = l
|
|
sucMinL Z = Refl
|
|
sucMinL (S l) = cong S $ sucMinL l
|
|
|
|
export
|
|
sucMinR : (l : Nat) -> minimum l (S l) = l
|
|
sucMinR Z = Refl
|
|
sucMinR (S l) = cong S $ sucMinR l
|
|
|
|
-- Algebra -----------------------------
|
|
|
|
namespace Monoid
|
|
|
|
public export
|
|
[Maximum] Monoid Nat using Semigroup.Maximum where
|
|
neutral = 0
|