{-# LANGUAGE CPP #-}
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE DeriveDataTypeable #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE GADTs #-}
{-# LANGUAGE KindSignatures #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE TypeOperators #-}
{-# LANGUAGE UndecidableInstances #-}
#if MIN_VERSION_base(4,8,0)
{-# LANGUAGE Safe #-}
#else
{-# LANGUAGE Trustworthy #-}
#endif
module Data.Type.BinP (
SBinP (..),
sbinpToBinP,
sbinpToNatural,
SBinPI (..),
withSBinP,
reify,
reflect,
reflectToNum,
eqBinP,
induction,
Succ,
withSucc,
Plus,
ToGHC, FromGHC,
ToNat,
BinP1, BinP2, BinP3, BinP4, BinP5, BinP6, BinP7, BinP8, BinP9,
) where
import Data.BinP (BinP (..))
import Data.Nat (Nat (..))
import Data.Proxy (Proxy (..))
import Data.Typeable (Typeable)
import Numeric.Natural (Natural)
import qualified Data.Type.Nat as N
import qualified GHC.TypeLits as GHC
import TrustworthyCompat
data SBinP (b :: BinP) where
SBE :: SBinP 'BE
SB0 :: SBinPI b => SBinP ('B0 b)
SB1 :: SBinPI b => SBinP ('B1 b)
deriving (Typeable)
class SBinPI (b :: BinP) where sbinp :: SBinP b
instance SBinPI 'BE where sbinp :: SBinP 'BE
sbinp = SBinP 'BE
SBE
instance SBinPI b => SBinPI ('B0 b) where sbinp :: SBinP ('B0 b)
sbinp = SBinP ('B0 b)
forall (b :: BinP). SBinPI b => SBinP ('B0 b)
SB0
instance SBinPI b => SBinPI ('B1 b) where sbinp :: SBinP ('B1 b)
sbinp = SBinP ('B1 b)
forall (b :: BinP). SBinPI b => SBinP ('B1 b)
SB1
withSBinP :: SBinP b -> (SBinPI b => r) -> r
withSBinP :: SBinP b -> (SBinPI b => r) -> r
withSBinP SBinP b
SBE SBinPI b => r
k = r
SBinPI b => r
k
withSBinP SBinP b
SB0 SBinPI b => r
k = r
SBinPI b => r
k
withSBinP SBinP b
SB1 SBinPI b => r
k = r
SBinPI b => r
k
reify :: forall r. BinP -> (forall b. SBinPI b => Proxy b -> r) -> r
reify :: BinP -> (forall (b :: BinP). SBinPI b => Proxy @BinP b -> r) -> r
reify BinP
BE forall (b :: BinP). SBinPI b => Proxy @BinP b -> r
k = Proxy @BinP 'BE -> r
forall (b :: BinP). SBinPI b => Proxy @BinP b -> r
k (Proxy @BinP 'BE
forall k (t :: k). Proxy @k t
Proxy :: Proxy 'BE)
reify (B0 BinP
b) forall (b :: BinP). SBinPI b => Proxy @BinP b -> r
k = BinP -> (forall (b :: BinP). SBinPI b => Proxy @BinP b -> r) -> r
forall r.
BinP -> (forall (b :: BinP). SBinPI b => Proxy @BinP b -> r) -> r
reify BinP
b (\(Proxy @BinP b
_ :: Proxy b) -> Proxy @BinP ('B0 b) -> r
forall (b :: BinP). SBinPI b => Proxy @BinP b -> r
k (Proxy @BinP ('B0 b)
forall k (t :: k). Proxy @k t
Proxy :: Proxy ('B0 b)))
reify (B1 BinP
b) forall (b :: BinP). SBinPI b => Proxy @BinP b -> r
k = BinP -> (forall (b :: BinP). SBinPI b => Proxy @BinP b -> r) -> r
forall r.
BinP -> (forall (b :: BinP). SBinPI b => Proxy @BinP b -> r) -> r
reify BinP
b (\(Proxy @BinP b
_ :: Proxy b) -> Proxy @BinP ('B1 b) -> r
forall (b :: BinP). SBinPI b => Proxy @BinP b -> r
k (Proxy @BinP ('B1 b)
forall k (t :: k). Proxy @k t
Proxy :: Proxy ('B1 b)))
reflect :: forall b proxy. SBinPI b => proxy b -> BinP
reflect :: proxy b -> BinP
reflect proxy b
_ = KP BinP b -> BinP
forall a (b :: BinP). KP a b -> a
unKP (KP BinP 'BE
-> (forall (bb :: BinP).
SBinPI bb =>
KP BinP bb -> KP BinP ('B0 bb))
-> (forall (bb :: BinP).
SBinPI bb =>
KP BinP bb -> KP BinP ('B1 bb))
-> KP BinP b
forall (b :: BinP) (f :: BinP -> *).
SBinPI b =>
f 'BE
-> (forall (bb :: BinP). SBinPI bb => f bb -> f ('B0 bb))
-> (forall (bb :: BinP). SBinPI bb => f bb -> f ('B1 bb))
-> f b
induction (BinP -> KP BinP 'BE
forall a (b :: BinP). a -> KP a b
KP BinP
BE) ((BinP -> BinP) -> KP BinP bb -> KP BinP ('B0 bb)
forall a b (bn :: BinP) (bn' :: BinP).
(a -> b) -> KP a bn -> KP b bn'
mapKP BinP -> BinP
B0) ((BinP -> BinP) -> KP BinP bb -> KP BinP ('B1 bb)
forall a b (bn :: BinP) (bn' :: BinP).
(a -> b) -> KP a bn -> KP b bn'
mapKP BinP -> BinP
B1) :: KP BinP b)
reflectToNum :: forall b proxy a. (SBinPI b, Num a) => proxy b -> a
reflectToNum :: proxy b -> a
reflectToNum proxy b
_ = KP a b -> a
forall a (b :: BinP). KP a b -> a
unKP (KP a 'BE
-> (forall (bb :: BinP). SBinPI bb => KP a bb -> KP a ('B0 bb))
-> (forall (bb :: BinP). SBinPI bb => KP a bb -> KP a ('B1 bb))
-> KP a b
forall (b :: BinP) (f :: BinP -> *).
SBinPI b =>
f 'BE
-> (forall (bb :: BinP). SBinPI bb => f bb -> f ('B0 bb))
-> (forall (bb :: BinP). SBinPI bb => f bb -> f ('B1 bb))
-> f b
induction (a -> KP a 'BE
forall a (b :: BinP). a -> KP a b
KP a
1) ((a -> a) -> KP a bb -> KP a ('B0 bb)
forall a b (bn :: BinP) (bn' :: BinP).
(a -> b) -> KP a bn -> KP b bn'
mapKP (a
2a -> a -> a
forall a. Num a => a -> a -> a
*)) ((a -> a) -> KP a bb -> KP a ('B1 bb)
forall a b (bn :: BinP) (bn' :: BinP).
(a -> b) -> KP a bn -> KP b bn'
mapKP (\a
x -> a
2 a -> a -> a
forall a. Num a => a -> a -> a
* a
x a -> a -> a
forall a. Num a => a -> a -> a
+ a
1)) :: KP a b)
sbinpToBinP :: forall n. SBinP n -> BinP
sbinpToBinP :: SBinP n -> BinP
sbinpToBinP SBinP n
s = SBinP n -> (SBinPI n => BinP) -> BinP
forall (b :: BinP) r. SBinP b -> (SBinPI b => r) -> r
withSBinP SBinP n
s ((SBinPI n => BinP) -> BinP) -> (SBinPI n => BinP) -> BinP
forall a b. (a -> b) -> a -> b
$ Proxy @BinP n -> BinP
forall (b :: BinP) (proxy :: BinP -> *).
SBinPI b =>
proxy b -> BinP
reflect (Proxy @BinP n
forall k (t :: k). Proxy @k t
Proxy :: Proxy n)
sbinpToNatural :: forall n. SBinP n -> Natural
sbinpToNatural :: SBinP n -> Natural
sbinpToNatural SBinP n
s = SBinP n -> (SBinPI n => Natural) -> Natural
forall (b :: BinP) r. SBinP b -> (SBinPI b => r) -> r
withSBinP SBinP n
s ((SBinPI n => Natural) -> Natural)
-> (SBinPI n => Natural) -> Natural
forall a b. (a -> b) -> a -> b
$ KP Natural n -> Natural
forall a (b :: BinP). KP a b -> a
unKP (KP Natural 'BE
-> (forall (bb :: BinP).
SBinPI bb =>
KP Natural bb -> KP Natural ('B0 bb))
-> (forall (bb :: BinP).
SBinPI bb =>
KP Natural bb -> KP Natural ('B1 bb))
-> KP Natural n
forall (b :: BinP) (f :: BinP -> *).
SBinPI b =>
f 'BE
-> (forall (bb :: BinP). SBinPI bb => f bb -> f ('B0 bb))
-> (forall (bb :: BinP). SBinPI bb => f bb -> f ('B1 bb))
-> f b
induction
(Natural -> KP Natural 'BE
forall a (b :: BinP). a -> KP a b
KP Natural
1)
((Natural -> Natural) -> KP Natural bb -> KP Natural ('B0 bb)
forall a b (bn :: BinP) (bn' :: BinP).
(a -> b) -> KP a bn -> KP b bn'
mapKP (Natural
2 Natural -> Natural -> Natural
forall a. Num a => a -> a -> a
*))
((Natural -> Natural) -> KP Natural bb -> KP Natural ('B1 bb)
forall a b (bn :: BinP) (bn' :: BinP).
(a -> b) -> KP a bn -> KP b bn'
mapKP (\Natural
x -> Natural -> Natural
forall a. Enum a => a -> a
succ (Natural
2 Natural -> Natural -> Natural
forall a. Num a => a -> a -> a
* Natural
x))) :: KP Natural n)
eqBinP :: forall a b. (SBinPI a, SBinPI b) => Maybe (a :~: b)
eqBinP :: Maybe ((:~:) @BinP a b)
eqBinP = case (SBinP a
forall (b :: BinP). SBinPI b => SBinP b
sbinp :: SBinP a, SBinP b
forall (b :: BinP). SBinPI b => SBinP b
sbinp :: SBinP b) of
(SBinP a
SBE, SBinP b
SBE) -> (:~:) @BinP a a -> Maybe ((:~:) @BinP a a)
forall a. a -> Maybe a
Just (:~:) @BinP a a
forall k (a :: k). (:~:) @k a a
Refl
(SBinP a
SB0, SBinP b
SB0) -> Maybe ((:~:) @BinP a b)
forall (n :: BinP) (m :: BinP).
(SBinPI n, SBinPI m) =>
Maybe ((:~:) @BinP ('B0 n) ('B0 m))
recur where
recur :: forall n m. (SBinPI n, SBinPI m) => Maybe ('B0 n :~: 'B0 m)
recur :: Maybe ((:~:) @BinP ('B0 n) ('B0 m))
recur = do
(:~:) @BinP n m
Refl <- Maybe ((:~:) @BinP n m)
forall (a :: BinP) (b :: BinP).
(SBinPI a, SBinPI b) =>
Maybe ((:~:) @BinP a b)
eqBinP :: Maybe (n :~: m)
(:~:) @BinP ('B0 n) ('B0 n) -> Maybe ((:~:) @BinP ('B0 n) ('B0 n))
forall (m :: * -> *) a. Monad m => a -> m a
return (:~:) @BinP ('B0 n) ('B0 n)
forall k (a :: k). (:~:) @k a a
Refl
(SBinP a
SB1, SBinP b
SB1) -> Maybe ((:~:) @BinP a b)
forall (n :: BinP) (m :: BinP).
(SBinPI n, SBinPI m) =>
Maybe ((:~:) @BinP ('B1 n) ('B1 m))
recur where
recur :: forall n m. (SBinPI n, SBinPI m) => Maybe ('B1 n :~: 'B1 m)
recur :: Maybe ((:~:) @BinP ('B1 n) ('B1 m))
recur = do
(:~:) @BinP n m
Refl <- Maybe ((:~:) @BinP n m)
forall (a :: BinP) (b :: BinP).
(SBinPI a, SBinPI b) =>
Maybe ((:~:) @BinP a b)
eqBinP :: Maybe (n :~: m)
(:~:) @BinP ('B1 n) ('B1 n) -> Maybe ((:~:) @BinP ('B1 n) ('B1 n))
forall (m :: * -> *) a. Monad m => a -> m a
return (:~:) @BinP ('B1 n) ('B1 n)
forall k (a :: k). (:~:) @k a a
Refl
(SBinP a, SBinP b)
_ -> Maybe ((:~:) @BinP a b)
forall a. Maybe a
Nothing
instance TestEquality SBinP where
testEquality :: SBinP a -> SBinP b -> Maybe ((:~:) @BinP a b)
testEquality SBinP a
SBE SBinP b
SBE = (:~:) @BinP a a -> Maybe ((:~:) @BinP a a)
forall a. a -> Maybe a
Just (:~:) @BinP a a
forall k (a :: k). (:~:) @k a a
Refl
testEquality SBinP a
SB0 SBinP b
SB0 = Maybe ((:~:) @BinP a b)
forall (a :: BinP) (b :: BinP).
(SBinPI a, SBinPI b) =>
Maybe ((:~:) @BinP a b)
eqBinP
testEquality SBinP a
SB1 SBinP b
SB1 = Maybe ((:~:) @BinP a b)
forall (a :: BinP) (b :: BinP).
(SBinPI a, SBinPI b) =>
Maybe ((:~:) @BinP a b)
eqBinP
testEquality SBinP a
_ SBinP b
_ = Maybe ((:~:) @BinP a b)
forall a. Maybe a
Nothing
type family ToGHC (b :: BinP) :: GHC.Nat where
ToGHC 'BE = 1
ToGHC ('B0 b) = 2 GHC.* (ToGHC b)
ToGHC ('B1 b) = 1 GHC.+ 2 GHC.* (ToGHC b)
type family FromGHC (n :: GHC.Nat) :: BinP where
FromGHC n = FromGHC' (FromGHCMaybe n)
type family FromGHC' (b :: Maybe BinP) :: BinP where
FromGHC' ('Just b) = b
type family FromGHCMaybe (n :: GHC.Nat) :: Maybe BinP where
FromGHCMaybe n = FromGHCMaybe' (GhcDivMod2 n)
type family FromGHCMaybe' (p :: (GHC.Nat, Bool)) :: Maybe BinP where
FromGHCMaybe' '(0, 'False) = 'Nothing
FromGHCMaybe' '(0, 'True) = 'Just 'BE
FromGHCMaybe' '(n, 'False) = Mult2 (FromGHCMaybe n)
FromGHCMaybe' '(n, 'True) = 'Just (Mult2Plus1 (FromGHCMaybe n))
type family GhcDivMod2 (n :: GHC.Nat) :: (GHC.Nat, Bool) where
GhcDivMod2 0 = '(0, 'False)
GhcDivMod2 1 = '(0, 'True)
GhcDivMod2 n = GhcDivMod2' (GhcDivMod2 (n GHC.- 2))
type family GhcDivMod2' (p :: (GHC.Nat, Bool)) :: (GHC.Nat, Bool) where
GhcDivMod2' '(n, b) = '(1 GHC.+ n, b)
type family Mult2 (b :: Maybe BinP) :: Maybe BinP where
Mult2 'Nothing = 'Nothing
Mult2 ('Just n) = 'Just ('B0 n)
type family Mult2Plus1 (b :: Maybe BinP) :: BinP where
Mult2Plus1 'Nothing = 'BE
Mult2Plus1 ('Just n) = ('B1 n)
type family ToNat (b :: BinP) :: Nat where
ToNat 'BE = 'S 'Z
ToNat ('B0 b) = N.Mult2 (ToNat b)
ToNat ('B1 b) = 'S (N.Mult2 (ToNat b))
type family Succ (b :: BinP) :: BinP where
Succ 'BE = 'B0 'BE
Succ ('B0 n) = 'B1 n
Succ ('B1 n) = 'B0 (Succ n)
withSucc :: forall b r. SBinPI b => Proxy b -> (SBinPI (Succ b) => r) -> r
withSucc :: Proxy @BinP b -> (SBinPI (Succ b) => r) -> r
withSucc Proxy @BinP b
p SBinPI (Succ b) => r
k = case SBinP b
forall (b :: BinP). SBinPI b => SBinP b
sbinp :: SBinP b of
SBinP b
SBE -> r
SBinPI (Succ b) => r
k
SBinP b
SB0 -> r
SBinPI (Succ b) => r
k
SBinP b
SB1 -> Proxy @BinP ('B1 b) -> (SBinPI ('B0 (Succ b)) => r) -> r
forall (m :: BinP) s.
SBinPI m =>
Proxy @BinP ('B1 m) -> (SBinPI ('B0 (Succ m)) => s) -> s
recur Proxy @BinP b
Proxy @BinP ('B1 b)
p SBinPI ('B0 (Succ b)) => r
SBinPI (Succ b) => r
k
where
recur :: forall m s. SBinPI m => Proxy ('B1 m) -> (SBinPI ('B0 (Succ m)) => s) -> s
recur :: Proxy @BinP ('B1 m) -> (SBinPI ('B0 (Succ m)) => s) -> s
recur Proxy @BinP ('B1 m)
_ SBinPI ('B0 (Succ m)) => s
k' = Proxy @BinP m -> (SBinPI (Succ m) => s) -> s
forall (b :: BinP) r.
SBinPI b =>
Proxy @BinP b -> (SBinPI (Succ b) => r) -> r
withSucc (Proxy @BinP m
forall k (t :: k). Proxy @k t
Proxy :: Proxy m) SBinPI ('B0 (Succ m)) => s
SBinPI (Succ m) => s
k'
type family Plus (a :: BinP) (b :: BinP) :: BinP where
Plus 'BE b = Succ b
Plus a 'BE = Succ a
Plus ('B0 a) ('B0 b) = 'B0 (Plus a b)
Plus ('B1 a) ('B0 b) = 'B1 (Plus a b)
Plus ('B0 a) ('B1 b) = 'B1 (Plus a b)
Plus ('B1 a) ('B1 b) = 'B0 (Succ (Plus a b))
induction
:: forall b f. SBinPI b
=> f 'BE
-> (forall bb. SBinPI bb => f bb -> f ('B0 bb))
-> (forall bb. SBinPI bb => f bb -> f ('B1 bb))
-> f b
induction :: f 'BE
-> (forall (bb :: BinP). SBinPI bb => f bb -> f ('B0 bb))
-> (forall (bb :: BinP). SBinPI bb => f bb -> f ('B1 bb))
-> f b
induction f 'BE
e forall (bb :: BinP). SBinPI bb => f bb -> f ('B0 bb)
o forall (bb :: BinP). SBinPI bb => f bb -> f ('B1 bb)
i = f b
forall (bb :: BinP). SBinPI bb => f bb
go where
go :: forall bb. SBinPI bb => f bb
go :: f bb
go = case SBinP bb
forall (b :: BinP). SBinPI b => SBinP b
sbinp :: SBinP bb of
SBinP bb
SBE -> f bb
f 'BE
e
SBinP bb
SB0 -> f b -> f ('B0 b)
forall (bb :: BinP). SBinPI bb => f bb -> f ('B0 bb)
o f b
forall (bb :: BinP). SBinPI bb => f bb
go
SBinP bb
SB1 -> f b -> f ('B1 b)
forall (bb :: BinP). SBinPI bb => f bb -> f ('B1 bb)
i f b
forall (bb :: BinP). SBinPI bb => f bb
go
type BinP1 = 'BE
type BinP2 = 'B0 BinP1
type BinP3 = 'B1 BinP1
type BinP4 = 'B0 BinP2
type BinP5 = 'B1 BinP2
type BinP6 = 'B0 BinP3
type BinP7 = 'B1 BinP3
type BinP8 = 'B0 BinP4
type BinP9 = 'B1 BinP4
newtype KP a (b :: BinP) = KP a
unKP :: KP a b -> a
unKP :: KP a b -> a
unKP = KP a b -> a
coerce
mapKP :: (a -> b) -> KP a bn -> KP b bn'
mapKP :: (a -> b) -> KP a bn -> KP b bn'
mapKP = (a -> b) -> KP a bn -> KP b bn'
coerce