mirror of
https://github.com/idris-lang/Idris2.git
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c88bf7af8d
This was taking too long, and adding too many things, because it was going too deep in the name of having everything accessible at the REPL and for the compiler. So, it's done a bit differently now, only chasing everything on a "full" load (i.e., final load at the REPL) This has some effects: + As systems get bigger, load time gets better (on my machine, checking Idris.Main now takes 52s from scratch, down from 76s) + You might find import errors that you didn't previously get, because things were being imported that shouldn't have been. The new way is correct! An unfortunate effect is that sometimes you end up getting "undefined name" errors even if you didn't explicitly use the name, because sometimes a module uses a name from another module in a type, which then gets exported, and eventually needs to be reduced. This mostly happens because there is a compile time check that should be done which I haven't implemented yet. That is, public export definitions should only be allowed to use names that are also public export. I'll get to this soon.
174 lines
5.1 KiB
Idris
174 lines
5.1 KiB
Idris
module Data.Fin
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import public Data.Maybe
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import Data.Nat
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import Decidable.Equality
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||| Numbers strictly less than some bound. The name comes from "finite sets".
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||| It's probably not a good idea to use `Fin` for arithmetic, and they will be
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||| exceedingly inefficient at run time.
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||| @ n the upper bound
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public export
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data Fin : (n : Nat) -> Type where
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FZ : Fin (S k)
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FS : Fin k -> Fin (S k)
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export
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implementation Uninhabited (Fin Z) where
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uninhabited FZ impossible
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uninhabited (FS f) impossible
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export
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FSInjective : (m : Fin k) -> (n : Fin k) -> FS m = FS n -> m = n
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FSInjective left _ Refl = Refl
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export
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implementation Eq (Fin n) where
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(==) FZ FZ = True
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(==) (FS k) (FS k') = k == k'
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(==) _ _ = False
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||| There are no elements of `Fin Z`
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export
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FinZAbsurd : Fin Z -> Void
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FinZAbsurd FZ impossible
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export
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FinZElim : Fin Z -> a
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FinZElim x = void (FinZAbsurd x)
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||| Convert a Fin to a Nat
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public export
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finToNat : Fin n -> Nat
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finToNat FZ = Z
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finToNat (FS k) = S (finToNat k)
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||| `finToNat` is injective
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export
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finToNatInjective : (fm : Fin k) -> (fn : Fin k) -> (finToNat fm) = (finToNat fn) -> fm = fn
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finToNatInjective (FS m) FZ Refl impossible
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finToNatInjective FZ (FS n) Refl impossible
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finToNatInjective (FS m) (FS n) prf =
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cong FS (finToNatInjective m n (succInjective (finToNat m) (finToNat n) prf))
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finToNatInjective FZ FZ Refl = Refl
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export
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implementation Cast (Fin n) Nat where
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cast x = finToNat x
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||| Convert a Fin to an Integer
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public export
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finToInteger : Fin n -> Integer
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finToInteger FZ = 0
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finToInteger (FS k) = 1 + finToInteger k
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export
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implementation Cast (Fin n) Integer where
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cast x = finToInteger x
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||| Weaken the bound on a Fin by 1
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public export
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weaken : Fin n -> Fin (S n)
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weaken FZ = FZ
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weaken (FS k) = FS (weaken k)
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||| Weaken the bound on a Fin by some amount
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public export
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weakenN : (n : Nat) -> Fin m -> Fin (m + n)
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weakenN n FZ = FZ
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weakenN n (FS f) = FS (weakenN n f)
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||| Attempt to tighten the bound on a Fin.
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||| Return `Left` if the bound could not be tightened, or `Right` if it could.
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export
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strengthen : {n : _} -> Fin (S n) -> Either (Fin (S n)) (Fin n)
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strengthen {n = S k} FZ = Right FZ
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strengthen {n = S k} (FS i) with (strengthen i)
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strengthen (FS i) | Left x = Left (FS x)
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strengthen (FS i) | Right x = Right (FS x)
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strengthen f = Left f
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||| Add some natural number to a Fin, extending the bound accordingly
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||| @ n the previous bound
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||| @ m the number to increase the Fin by
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public export
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shift : (m : Nat) -> Fin n -> Fin (m + n)
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shift Z f = f
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shift {n=n} (S m) f = FS {k = (m + n)} (shift m f)
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||| The largest element of some Fin type
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public export
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last : {n : _} -> Fin (S n)
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last {n=Z} = FZ
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last {n=S _} = FS last
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public export total
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FSinjective : {f : Fin n} -> {f' : Fin n} -> (FS f = FS f') -> f = f'
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FSinjective Refl = Refl
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export
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implementation Ord (Fin n) where
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compare FZ FZ = EQ
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compare FZ (FS _) = LT
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compare (FS _) FZ = GT
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compare (FS x) (FS y) = compare x y
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-- Construct a Fin from an integer literal which must fit in the given Fin
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public export
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natToFin : Nat -> (n : Nat) -> Maybe (Fin n)
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natToFin Z (S j) = Just FZ
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natToFin (S k) (S j)
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= case natToFin k j of
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Just k' => Just (FS k')
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Nothing => Nothing
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natToFin _ _ = Nothing
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||| Convert an `Integer` to a `Fin`, provided the integer is within bounds.
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||| @n The upper bound of the Fin
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public export
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integerToFin : Integer -> (n : Nat) -> Maybe (Fin n)
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integerToFin x Z = Nothing -- make sure 'n' is concrete, to save reduction!
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integerToFin x n = if x >= 0 then natToFin (fromInteger x) n else Nothing
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||| Allow overloading of Integer literals for Fin.
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||| @ x the Integer that the user typed
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||| @ prf an automatically-constructed proof that `x` is in bounds
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public export
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fromInteger : (x : Integer) -> {n : Nat} ->
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{auto prf : (IsJust (integerToFin x n))} ->
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Fin n
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fromInteger {n} x {prf} with (integerToFin x n)
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fromInteger {n} x {prf = ItIsJust} | Just y = y
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||| Convert an Integer to a Fin in the required bounds/
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||| This is essentially a composition of `mod` and `fromInteger`
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public export
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restrict : (n : Nat) -> Integer -> Fin (S n)
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restrict n val = let val' = assert_total (abs (mod val (cast (S n)))) in
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-- reasoning about primitives, so we need the
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-- 'believe_me'. It's fine because val' must be
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-- in the right range
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fromInteger {n = S n} val'
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{prf = believe_me {a=IsJust (Just val')} ItIsJust}
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--------------------------------------------------------------------------------
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-- DecEq
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--------------------------------------------------------------------------------
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export total
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FZNotFS : {f : Fin n} -> FZ {k = n} = FS f -> Void
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FZNotFS Refl impossible
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export
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implementation DecEq (Fin n) where
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decEq FZ FZ = Yes Refl
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decEq FZ (FS f) = No FZNotFS
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decEq (FS f) FZ = No $ negEqSym FZNotFS
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decEq (FS f) (FS f')
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= case decEq f f' of
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Yes p => Yes $ cong FS p
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No p => No $ \h => p $ FSinjective {f = f} {f' = f'} h
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