Idris2/libs/base/Data/Nat/Order.idr

||| Implementation of ordering relations for `Nat`ural numbers
module Data.Nat.Order

import Data.Nat
import Data.Fun
import Data.Rel
import Decidable.Decidable
import Decidable.Equality
import Decidable.Order

public export
total LTEIsTransitive : (m : Nat) -> (n : Nat) -> (o : Nat) ->
                           LTE m n -> LTE n o ->
                           LTE m o
LTEIsTransitive Z n o                 LTEZero                  nlteo   = LTEZero
LTEIsTransitive (S m) (S n) (S o) (LTESucc mlten)    (LTESucc nlteo)   = LTESucc (LTEIsTransitive m n o mlten nlteo)

public export
total LTEIsReflexive : (n : Nat) -> LTE n n
LTEIsReflexive Z      = LTEZero
LTEIsReflexive (S n)  = LTESucc (LTEIsReflexive n)

public export
implementation Preorder Nat LTE where
  transitive = LTEIsTransitive
  reflexive  = LTEIsReflexive

public export
total LTEIsAntisymmetric : (m : Nat) -> (n : Nat) ->
                              LTE m n -> LTE n m -> m = n
LTEIsAntisymmetric Z Z         LTEZero LTEZero = Refl
LTEIsAntisymmetric (S n) (S m) (LTESucc mLTEn) (LTESucc nLTEm) with (LTEIsAntisymmetric n m mLTEn nLTEm)
   LTEIsAntisymmetric (S n) (S n) (LTESucc mLTEn) (LTESucc nLTEm)    | Refl = Refl


public export
implementation Poset Nat LTE where
  antisymmetric = LTEIsAntisymmetric

public export
total zeroNeverGreater : {n : Nat} -> LTE (S n) Z -> Void
zeroNeverGreater {n} LTEZero     impossible
zeroNeverGreater {n} (LTESucc _) impossible

public export
total zeroAlwaysSmaller : {n : Nat} -> LTE Z n
zeroAlwaysSmaller = LTEZero

public export
total ltesuccinjective : {0 n : Nat} -> {0 m : Nat} -> (LTE n m -> Void) -> LTE (S n) (S m) -> Void
ltesuccinjective {n} {m} disprf (LTESucc nLTEm) = void (disprf nLTEm)
ltesuccinjective {n} {m} disprf LTEZero         impossible

public export
total decideLTE : (n : Nat) -> (m : Nat) -> Dec (LTE n m)
decideLTE    Z      y  = Yes LTEZero
decideLTE (S x)     Z  = No  zeroNeverGreater
decideLTE (S x)   (S y) with (decEq (S x) (S y))
  decideLTE (S x)   (S y) | Yes eq      = rewrite eq in Yes (reflexive (S y))
  decideLTE (S x)   (S y) | No _ with (decideLTE x y)
  decideLTE (S x)   (S y) | No _   | Yes nLTEm = Yes (LTESucc nLTEm)
  decideLTE (S x)   (S y) | No _   | No  nGTm  = No (ltesuccinjective nGTm)

public export
implementation Decidable 2 [Nat,Nat] LTE where
  decide = decideLTE

public export
total
lte : (m : Nat) -> (n : Nat) -> Dec (LTE m n)
lte m n = decide {ts = [Nat,Nat]} {p = LTE} m n

public export
total
shift : (m : Nat) -> (n : Nat) -> LTE m n -> LTE (S m) (S n)
shift m n mLTEn = LTESucc mLTEn

public export
implementation Ordered Nat LTE where
  order Z      n = Left LTEZero
  order m      Z = Right LTEZero
  order (S k) (S j) with (order {to=LTE} k j)
    order (S k) (S j) | Left  prf = Left  (shift k j prf)
    order (S k) (S j) | Right prf = Right (shift j k prf)
Port Decidable.Order from Idris1 (#543) 2020-08-19 00:26:56 +03:00			\|\|\| Implementation of ordering relations for `Nat`ural numbers
			`module Data.Nat.Order`

			`import Data.Nat`
			`import Data.Fun`
			`import Data.Rel`
			`import Decidable.Decidable`
			`import Decidable.Equality`
			`import Decidable.Order`

			`public export`
			`total LTEIsTransitive : (m : Nat) -> (n : Nat) -> (o : Nat) ->`
			`LTE m n -> LTE n o ->`
			`LTE m o`
			`LTEIsTransitive Z n o LTEZero nlteo = LTEZero`
			`LTEIsTransitive (S m) (S n) (S o) (LTESucc mlten) (LTESucc nlteo) = LTESucc (LTEIsTransitive m n o mlten nlteo)`

			`public export`
			`total LTEIsReflexive : (n : Nat) -> LTE n n`
			`LTEIsReflexive Z = LTEZero`
			`LTEIsReflexive (S n) = LTESucc (LTEIsReflexive n)`

			`public export`
			`implementation Preorder Nat LTE where`
			`transitive = LTEIsTransitive`
			`reflexive = LTEIsReflexive`

			`public export`
			`total LTEIsAntisymmetric : (m : Nat) -> (n : Nat) ->`
			`LTE m n -> LTE n m -> m = n`
			`LTEIsAntisymmetric Z Z LTEZero LTEZero = Refl`
			`LTEIsAntisymmetric (S n) (S m) (LTESucc mLTEn) (LTESucc nLTEm) with (LTEIsAntisymmetric n m mLTEn nLTEm)`
			`LTEIsAntisymmetric (S n) (S n) (LTESucc mLTEn) (LTESucc nLTEm) \| Refl = Refl`


			`public export`
			`implementation Poset Nat LTE where`
			`antisymmetric = LTEIsAntisymmetric`

			`public export`
			`total zeroNeverGreater : {n : Nat} -> LTE (S n) Z -> Void`
			`zeroNeverGreater {n} LTEZero impossible`
			`zeroNeverGreater {n} (LTESucc _) impossible`

			`public export`
			`total zeroAlwaysSmaller : {n : Nat} -> LTE Z n`
			`zeroAlwaysSmaller = LTEZero`

			`public export`
make constructor injectivity proofs use arguments at 0 multiplicity 2020-09-05 22:48:42 +03:00			`total ltesuccinjective : {0 n : Nat} -> {0 m : Nat} -> (LTE n m -> Void) -> LTE (S n) (S m) -> Void`
Port Decidable.Order from Idris1 (#543) 2020-08-19 00:26:56 +03:00			`ltesuccinjective {n} {m} disprf (LTESucc nLTEm) = void (disprf nLTEm)`
			`ltesuccinjective {n} {m} disprf LTEZero impossible`

			`public export`
			`total decideLTE : (n : Nat) -> (m : Nat) -> Dec (LTE n m)`
			`decideLTE Z y = Yes LTEZero`
			`decideLTE (S x) Z = No zeroNeverGreater`
			`decideLTE (S x) (S y) with (decEq (S x) (S y))`
			`decideLTE (S x) (S y) \| Yes eq = rewrite eq in Yes (reflexive (S y))`
			`decideLTE (S x) (S y) \| No _ with (decideLTE x y)`
			`decideLTE (S x) (S y) \| No _ \| Yes nLTEm = Yes (LTESucc nLTEm)`
			`decideLTE (S x) (S y) \| No _ \| No nGTm = No (ltesuccinjective nGTm)`

			`public export`
[ fix #657 ] RigCount for interface parameters (#808) 2020-12-11 14:58:26 +03:00			`implementation Decidable 2 [Nat,Nat] LTE where`
Port Decidable.Order from Idris1 (#543) 2020-08-19 00:26:56 +03:00			`decide = decideLTE`

			`public export`
			`total`
			`lte : (m : Nat) -> (n : Nat) -> Dec (LTE m n)`
			`lte m n = decide {ts = [Nat,Nat]} {p = LTE} m n`

			`public export`
			`total`
			`shift : (m : Nat) -> (n : Nat) -> LTE m n -> LTE (S m) (S n)`
			`shift m n mLTEn = LTESucc mLTEn`

			`public export`
			`implementation Ordered Nat LTE where`
			`order Z n = Left LTEZero`
			`order m Z = Right LTEZero`
			`order (S k) (S j) with (order {to=LTE} k j)`
			`order (S k) (S j) \| Left prf = Left (shift k j prf)`
			`order (S k) (S j) \| Right prf = Right (shift j k prf)`