module Agda.Auto.CaseSplit where
import Data.IORef
import Data.Tuple (swap)
import Data.List (elemIndex)
import Data.Monoid ((<>), Sum(..))
import qualified Data.Set as Set
import qualified Data.IntMap as IntMap
import Control.Monad.State as St hiding (lift)
import Control.Monad.Reader as Rd hiding (lift)
import qualified Control.Monad.State as St
import Data.Function
import Agda.Syntax.Common (Hiding(..))
import Agda.Auto.NarrowingSearch
import Agda.Auto.Syntax
import Agda.Auto.SearchControl
import Agda.Auto.Typecheck
import Agda.Utils.Impossible
import Agda.Utils.Monad (or2M)
import Agda.Utils.List (last1)
abspatvarname :: String
abspatvarname :: String
abspatvarname = String
"\0absurdPattern"
costCaseSplitVeryHigh, costCaseSplitHigh, costCaseSplitLow, costAddVarDepth
:: Cost
costCaseSplitVeryHigh :: Cost
costCaseSplitVeryHigh = Cost
10000
costCaseSplitHigh :: Cost
costCaseSplitHigh = Cost
5000
costCaseSplitLow :: Cost
costCaseSplitLow = Cost
2000
costAddVarDepth :: Cost
costAddVarDepth = Cost
1000
data HI a = HI Hiding a
drophid :: [HI a] -> [a]
drophid :: forall a. [HI a] -> [a]
drophid = (HI a -> a) -> [HI a] -> [a]
forall a b. (a -> b) -> [a] -> [b]
map (\(HI Hiding
_ a
x) -> a
x)
type CSPat o = HI (CSPatI o)
type CSCtx o = [HI (MId, MExp o)]
data CSPatI o = CSPatConApp (ConstRef o) [CSPat o]
| CSPatVar Nat
| CSPatExp (MExp o)
| CSWith (MExp o)
| CSAbsurd
| CSOmittedArg
type Sol o = [(CSCtx o, [CSPat o], Maybe (MExp o))]
caseSplitSearch ::
forall o . IORef Int -> Int -> [ConstRef o] ->
Maybe (EqReasoningConsts o) -> Int -> Cost -> ConstRef o ->
CSCtx o -> MExp o -> [CSPat o] -> IO [Sol o]
caseSplitSearch :: forall o.
IORef Nat
-> Nat
-> [ConstRef o]
-> Maybe (EqReasoningConsts o)
-> Nat
-> Cost
-> ConstRef o
-> CSCtx o
-> MExp o
-> [CSPat o]
-> IO [Sol o]
caseSplitSearch IORef Nat
ticks Nat
nsolwanted [ConstRef o]
chints Maybe (EqReasoningConsts o)
meqr Nat
depthinterval Cost
depth ConstRef o
recdef CSCtx o
ctx MExp o
tt [CSPat o]
pats = do
let branchsearch :: Cost -> CSCtx o -> MExp o ->
([Nat], Nat, [Nat]) -> IO (Maybe (MExp o))
branchsearch :: Cost
-> CSCtx o -> MExp o -> ([Nat], Nat, [Nat]) -> IO (Maybe (MExp o))
branchsearch Cost
depth CSCtx o
ctx MExp o
tt ([Nat], Nat, [Nat])
termcheckenv = do
IORef Nat
nsol <- Nat -> IO (IORef Nat)
forall a. a -> IO (IORef a)
newIORef Nat
1
Metavar (Exp o) (RefInfo o)
m <- IO (Metavar (Exp o) (RefInfo o))
forall a blk. IO (Metavar a blk)
initMeta
IORef (Maybe (MExp o))
sol <- Maybe (MExp o) -> IO (IORef (Maybe (MExp o)))
forall a. a -> IO (IORef a)
newIORef Maybe (MExp o)
forall a. Maybe a
Nothing
let trm :: MExp o
trm = Metavar (Exp o) (RefInfo o) -> MExp o
forall a blk. Metavar a blk -> MM a blk
Meta Metavar (Exp o) (RefInfo o)
m
hsol :: IO ()
hsol = do MExp o
trm' <- MExp o -> IO (MExp o)
forall t. ExpandMetas t => t -> IO t
expandMetas MExp o
trm
IORef (Maybe (MExp o)) -> Maybe (MExp o) -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Maybe (MExp o))
sol (MExp o -> Maybe (MExp o)
forall a. a -> Maybe a
Just MExp o
trm')
initcon :: MetaEnv (PB (RefInfo o))
initcon = Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret
(Prop (RefInfo o) -> MetaEnv (PB (RefInfo o)))
-> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ MetaEnv (PB (RefInfo o))
-> MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o)
forall blk. MetaEnv (PB blk) -> MetaEnv (PB blk) -> Prop blk
Sidecondition
(([Nat], Nat, [Nat])
-> ConstRef o -> MExp o -> MetaEnv (PB (RefInfo o))
forall o.
([Nat], Nat, [Nat]) -> ConstRef o -> MExp o -> EE (MyPB o)
localTerminationSidecond ([Nat], Nat, [Nat])
termcheckenv ConstRef o
recdef MExp o
trm)
(MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o))
-> MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o)
forall a b. (a -> b) -> a -> b
$ (case Maybe (EqReasoningConsts o)
meqr of
Maybe (EqReasoningConsts o)
Nothing -> MetaEnv (PB (RefInfo o)) -> MetaEnv (PB (RefInfo o))
forall a. a -> a
id
Just EqReasoningConsts o
eqr -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret (Prop (RefInfo o) -> MetaEnv (PB (RefInfo o)))
-> (MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o))
-> MetaEnv (PB (RefInfo o))
-> MetaEnv (PB (RefInfo o))
forall b c a. (b -> c) -> (a -> b) -> a -> c
. MetaEnv (PB (RefInfo o))
-> MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o)
forall blk. MetaEnv (PB blk) -> MetaEnv (PB blk) -> Prop blk
Sidecondition (EqReasoningConsts o -> MExp o -> MetaEnv (PB (RefInfo o))
forall o. EqReasoningConsts o -> MExp o -> EE (MyPB o)
calcEqRState EqReasoningConsts o
eqr MExp o
trm)
) (MetaEnv (PB (RefInfo o)) -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o)) -> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ Bool -> Ctx o -> CExp o -> MExp o -> MetaEnv (PB (RefInfo o))
forall o. Bool -> Ctx o -> CExp o -> MExp o -> EE (MyPB o)
tcSearch Bool
False (((MId, MExp o) -> (MId, CExp o)) -> [(MId, MExp o)] -> Ctx o
forall a b. (a -> b) -> [a] -> [b]
map ((MExp o -> CExp o) -> (MId, MExp o) -> (MId, CExp o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap MExp o -> CExp o
forall o. MExp o -> CExp o
closify) (CSCtx o -> [(MId, MExp o)]
forall a. [HI a] -> [a]
drophid CSCtx o
ctx))
(MExp o -> CExp o
forall o. MExp o -> CExp o
closify MExp o
tt) MExp o
trm
ConstDef o
recdefd <- ConstRef o -> IO (ConstDef o)
forall a. IORef a -> IO a
readIORef ConstRef o
recdef
let env :: RefInfo o
env = RIEnv { rieHints :: [(ConstRef o, HintMode)]
rieHints = (ConstRef o
recdef, HintMode
HMRecCall) (ConstRef o, HintMode)
-> [(ConstRef o, HintMode)] -> [(ConstRef o, HintMode)]
forall a. a -> [a] -> [a]
: (ConstRef o -> (ConstRef o, HintMode))
-> [ConstRef o] -> [(ConstRef o, HintMode)]
forall a b. (a -> b) -> [a] -> [b]
map (, HintMode
HMNormal) [ConstRef o]
chints
, rieDefFreeVars :: Nat
rieDefFreeVars = ConstDef o -> Nat
forall o. ConstDef o -> Nat
cddeffreevars ConstDef o
recdefd
, rieEqReasoningConsts :: Maybe (EqReasoningConsts o)
rieEqReasoningConsts = Maybe (EqReasoningConsts o)
meqr
}
Bool
depreached <- IORef Nat
-> IORef Nat
-> IO ()
-> RefInfo o
-> MetaEnv (PB (RefInfo o))
-> Cost
-> Cost
-> IO Bool
forall blk.
IORef Nat
-> IORef Nat
-> IO ()
-> blk
-> MetaEnv (PB blk)
-> Cost
-> Cost
-> IO Bool
topSearch IORef Nat
ticks IORef Nat
nsol IO ()
hsol RefInfo o
env MetaEnv (PB (RefInfo o))
initcon Cost
depth (Cost
depth Cost -> Cost -> Cost
forall a. Num a => a -> a -> a
+ Cost
1)
IORef (Maybe (MExp o)) -> IO (Maybe (MExp o))
forall a. IORef a -> IO a
readIORef IORef (Maybe (MExp o))
sol
ctx' :: CSCtx o
ctx' = Nat -> CSCtx o -> CSCtx o
forall {b} {a}. Lift b => Nat -> [HI (a, b)] -> [HI (a, b)]
ff Nat
1 CSCtx o
ctx
ff :: Nat -> [HI (a, b)] -> [HI (a, b)]
ff Nat
_ [] = []
ff Nat
n (HI Hiding
hid (a
id, b
t) : [HI (a, b)]
ctx) = Hiding -> (a, b) -> HI (a, b)
forall a. Hiding -> a -> HI a
HI Hiding
hid (a
id, Nat -> b -> b
forall t. Lift t => Nat -> t -> t
lift Nat
n b
t) HI (a, b) -> [HI (a, b)] -> [HI (a, b)]
forall a. a -> [a] -> [a]
: Nat -> [HI (a, b)] -> [HI (a, b)]
ff (Nat
n Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) [HI (a, b)]
ctx
(Cost
-> CSCtx o -> MExp o -> ([Nat], Nat, [Nat]) -> IO (Maybe (MExp o)))
-> Nat
-> Cost
-> ConstRef o
-> CSCtx o
-> MExp o
-> [CSPat o]
-> IO [Sol o]
forall o.
(Cost
-> CSCtx o -> MExp o -> ([Nat], Nat, [Nat]) -> IO (Maybe (MExp o)))
-> Nat
-> Cost
-> ConstRef o
-> CSCtx o
-> MExp o
-> [CSPat o]
-> IO [Sol o]
caseSplitSearch' Cost
-> CSCtx o -> MExp o -> ([Nat], Nat, [Nat]) -> IO (Maybe (MExp o))
branchsearch Nat
depthinterval Cost
depth ConstRef o
recdef CSCtx o
ctx' MExp o
tt [CSPat o]
pats
caseSplitSearch' :: forall o .
(Cost -> CSCtx o -> MExp o -> ([Nat], Nat, [Nat]) -> IO (Maybe (MExp o))) ->
Int -> Cost -> ConstRef o -> CSCtx o -> MExp o -> [CSPat o] -> IO [Sol o]
caseSplitSearch' :: forall o.
(Cost
-> CSCtx o -> MExp o -> ([Nat], Nat, [Nat]) -> IO (Maybe (MExp o)))
-> Nat
-> Cost
-> ConstRef o
-> CSCtx o
-> MExp o
-> [CSPat o]
-> IO [Sol o]
caseSplitSearch' Cost
-> CSCtx o -> MExp o -> ([Nat], Nat, [Nat]) -> IO (Maybe (MExp o))
branchsearch Nat
depthinterval Cost
depth ConstRef o
recdef CSCtx o
ctx MExp o
tt [CSPat o]
pats = do
ConstDef o
recdefd <- ConstRef o -> IO (ConstDef o)
forall a. IORef a -> IO a
readIORef ConstRef o
recdef
Cost -> Nat -> CSCtx o -> MExp o -> [CSPat o] -> IO [Sol o]
rc Cost
depth (ConstDef o -> Nat
forall o. ConstDef o -> Nat
cddeffreevars ConstDef o
recdefd) CSCtx o
ctx MExp o
tt [CSPat o]
pats
where
rc :: Cost -> Int -> CSCtx o -> MExp o -> [CSPat o] -> IO [Sol o]
rc :: Cost -> Nat -> CSCtx o -> MExp o -> [CSPat o] -> IO [Sol o]
rc Cost
depth Nat
_ CSCtx o
_ MExp o
_ [CSPat o]
_ | Cost
depth Cost -> Cost -> Bool
forall a. Ord a => a -> a -> Bool
< Cost
0 = [Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return []
rc Cost
depth Nat
nscrutavoid CSCtx o
ctx MExp o
tt [CSPat o]
pats = do
[Nat]
mblkvar <- MExp o -> IO [Nat]
forall o. MExp o -> IO [Nat]
getblks MExp o
tt
[Nat] -> IO [Sol o]
fork
[Nat]
mblkvar
where
fork :: [Nat] -> IO [Sol o]
fork :: [Nat] -> IO [Sol o]
fork [Nat]
mblkvar = do
[Sol o]
sols1 <- IO [Sol o]
dobody
case [Sol o]
sols1 of
(Sol o
_:[Sol o]
_) -> [Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return [Sol o]
sols1
[] -> do
let r :: [Nat] -> IO [Sol o]
r :: [Nat] -> IO [Sol o]
r [] = [Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return []
r (Nat
v:[Nat]
vs) = do
[Sol o]
sols2 <- [Nat] -> Nat -> IO [Sol o]
splitvar [Nat]
mblkvar Nat
v
case [Sol o]
sols2 of
(Sol o
_:[Sol o]
_) -> [Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return [Sol o]
sols2
[] -> [Nat] -> IO [Sol o]
r [Nat]
vs
[Nat] -> IO [Sol o]
r [Nat
nv Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
x | Nat
x <- [Nat
0..Nat
nv]]
where nv :: Nat
nv = CSCtx o -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length CSCtx o
ctx Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
1
dobody :: IO [Sol o]
dobody :: IO [Sol o]
dobody = do
case [MExp o] -> Maybe [Nat]
forall o. [MExp o] -> Maybe [Nat]
findperm (((MId, MExp o) -> MExp o) -> [(MId, MExp o)] -> [MExp o]
forall a b. (a -> b) -> [a] -> [b]
map (MId, MExp o) -> MExp o
forall a b. (a, b) -> b
snd (CSCtx o -> [(MId, MExp o)]
forall a. [HI a] -> [a]
drophid CSCtx o
ctx)) of
Just [Nat]
perm -> do
let (CSCtx o
ctx', MExp o
tt', [CSPat o]
pats') = [Nat]
-> CSCtx o -> MExp o -> [CSPat o] -> (CSCtx o, MExp o, [CSPat o])
forall o.
[Nat]
-> CSCtx o -> MExp o -> [CSPat o] -> (CSCtx o, MExp o, [CSPat o])
applyperm [Nat]
perm CSCtx o
ctx MExp o
tt [CSPat o]
pats
Maybe (MExp o)
res <- Cost
-> CSCtx o -> MExp o -> ([Nat], Nat, [Nat]) -> IO (Maybe (MExp o))
branchsearch Cost
depth CSCtx o
ctx' MExp o
tt' ([CSPat o] -> ([Nat], Nat, [Nat])
forall o. [CSPat o] -> ([Nat], Nat, [Nat])
localTerminationEnv [CSPat o]
pats')
[Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return ([Sol o] -> IO [Sol o]) -> [Sol o] -> IO [Sol o]
forall a b. (a -> b) -> a -> b
$ case Maybe (MExp o)
res of
Just MExp o
trm -> [[(CSCtx o
ctx', [CSPat o]
pats', MExp o -> Maybe (MExp o)
forall a. a -> Maybe a
Just MExp o
trm)]]
Maybe (MExp o)
Nothing -> []
Maybe [Nat]
Nothing -> IO [Sol o]
forall a. HasCallStack => a
__IMPOSSIBLE__
splitvar :: [Nat] -> Nat -> IO [Sol o]
splitvar :: [Nat] -> Nat -> IO [Sol o]
splitvar [Nat]
mblkvar Nat
scrut = do
let scruttype :: MExp o
scruttype = CSCtx o -> Nat -> MExp o
forall o. CSCtx o -> Nat -> MExp o
infertypevar CSCtx o
ctx Nat
scrut
case Empty -> MExp o -> Exp o
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__ MExp o
scruttype of
App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Const ConstRef o
c) MArgList o
_ -> do
ConstDef o
cd <- ConstRef o -> IO (ConstDef o)
forall a. IORef a -> IO a
readIORef ConstRef o
c
case ConstDef o -> DeclCont o
forall o. ConstDef o -> DeclCont o
cdcont ConstDef o
cd of
Datatype [ConstRef o]
cons [ConstRef o]
_ -> do
[Sol o]
sols <- [ConstRef o] -> IO [Sol o]
dobranches [ConstRef o]
cons
[Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return ([Sol o] -> IO [Sol o]) -> [Sol o] -> IO [Sol o]
forall a b. (a -> b) -> a -> b
$ (Sol o -> Sol o) -> [Sol o] -> [Sol o]
forall a b. (a -> b) -> [a] -> [b]
map (\Sol o
sol -> case Sol o
sol of
[] ->
case [MExp o] -> Maybe [Nat]
forall o. [MExp o] -> Maybe [Nat]
findperm (((MId, MExp o) -> MExp o) -> [(MId, MExp o)] -> [MExp o]
forall a b. (a -> b) -> [a] -> [b]
map (MId, MExp o) -> MExp o
forall a b. (a, b) -> b
snd (CSCtx o -> [(MId, MExp o)]
forall a. [HI a] -> [a]
drophid CSCtx o
ctx)) of
Just [Nat]
perm ->
let HI Hiding
scrhid(MId
_, MExp o
scrt) = CSCtx o
ctx CSCtx o -> Nat -> HI (MId, MExp o)
forall a. [a] -> Nat -> a
!! Nat
scrut
ctx1 :: CSCtx o
ctx1 = Nat -> CSCtx o -> CSCtx o
forall a. Nat -> [a] -> [a]
take Nat
scrut CSCtx o
ctx CSCtx o -> CSCtx o -> CSCtx o
forall a. [a] -> [a] -> [a]
++ (Hiding -> (MId, MExp o) -> HI (MId, MExp o)
forall a. Hiding -> a -> HI a
HI Hiding
scrhid (String -> MId
Id String
abspatvarname, MExp o
scrt)) HI (MId, MExp o) -> CSCtx o -> CSCtx o
forall a. a -> [a] -> [a]
: Nat -> CSCtx o -> CSCtx o
forall a. Nat -> [a] -> [a]
drop (Nat
scrut Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) CSCtx o
ctx
(CSCtx o
ctx', MExp o
_, [CSPat o]
pats') = [Nat]
-> CSCtx o -> MExp o -> [CSPat o] -> (CSCtx o, MExp o, [CSPat o])
forall o.
[Nat]
-> CSCtx o -> MExp o -> [CSPat o] -> (CSCtx o, MExp o, [CSPat o])
applyperm [Nat]
perm CSCtx o
ctx1 MExp o
tt ([CSPat o]
pats)
in [(CSCtx o
ctx', [CSPat o]
pats', Maybe (MExp o)
forall a. Maybe a
Nothing)]
Maybe [Nat]
Nothing -> Sol o
forall a. HasCallStack => a
__IMPOSSIBLE__
Sol o
_ -> Sol o
sol
) [Sol o]
sols
where
dobranches :: [ConstRef o] -> IO [Sol o]
dobranches :: [ConstRef o] -> IO [Sol o]
dobranches [] = [Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return [[]]
dobranches (ConstRef o
con : [ConstRef o]
cons) = do
ConstDef o
cond <- ConstRef o -> IO (ConstDef o)
forall a. IORef a -> IO a
readIORef ConstRef o
con
let ff :: MExp o -> ([((Hiding, Nat), MId, MExp o)], MExp o)
ff MExp o
t = case Empty -> MExp o -> Exp o
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__ MExp o
t of
Pi Maybe (UId o)
_ Hiding
h Bool
_ MExp o
it (Abs MId
id MExp o
ot) ->
let ([((Hiding, Nat), MId, MExp o)]
xs, MExp o
inft) = MExp o -> ([((Hiding, Nat), MId, MExp o)], MExp o)
ff MExp o
ot
in (((Hiding
h, Nat
scrut Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ [((Hiding, Nat), MId, MExp o)] -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length [((Hiding, Nat), MId, MExp o)]
xs), MId
id, Nat -> MExp o -> MExp o
forall t. Lift t => Nat -> t -> t
lift (Nat
scrut Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ [((Hiding, Nat), MId, MExp o)] -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length [((Hiding, Nat), MId, MExp o)]
xs Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) MExp o
it) ((Hiding, Nat), MId, MExp o)
-> [((Hiding, Nat), MId, MExp o)] -> [((Hiding, Nat), MId, MExp o)]
forall a. a -> [a] -> [a]
: [((Hiding, Nat), MId, MExp o)]
xs, MExp o
inft)
Exp o
_ -> ([], Nat -> MExp o -> MExp o
forall t. Lift t => Nat -> t -> t
lift Nat
scrut MExp o
t)
([((Hiding, Nat), MId, MExp o)]
newvars, MExp o
inftype) = MExp o -> ([((Hiding, Nat), MId, MExp o)], MExp o)
ff (ConstDef o -> MExp o
forall o. ConstDef o -> MExp o
cdtype ConstDef o
cond)
constrapp :: MExp o
constrapp = Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o) -> Exp o -> MExp o
forall a b. (a -> b) -> a -> b
$ Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
forall a. Maybe a
Nothing (OKVal -> OKHandle (RefInfo o)
forall a blk. a -> MM a blk
NotM OKVal
OKVal) (ConstRef o -> Elr o
forall o. ConstRef o -> Elr o
Const ConstRef o
con) ((MArgList o -> ((Hiding, Nat), MId, MExp o) -> MArgList o)
-> MArgList o -> [((Hiding, Nat), MId, MExp o)] -> MArgList o
forall (t :: * -> *) b a.
Foldable t =>
(b -> a -> b) -> b -> t a -> b
foldl (\MArgList o
xs ((Hiding
h, Nat
v), MId
_, MExp o
_) -> ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM (ArgList o -> MArgList o) -> ArgList o -> MArgList o
forall a b. (a -> b) -> a -> b
$ Hiding -> MExp o -> MArgList o -> ArgList o
forall o. Hiding -> MExp o -> MArgList o -> ArgList o
ALCons Hiding
h (Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o) -> Exp o -> MExp o
forall a b. (a -> b) -> a -> b
$ Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
forall a. Maybe a
Nothing (OKVal -> OKHandle (RefInfo o)
forall a blk. a -> MM a blk
NotM OKVal
OKVal) (Nat -> Elr o
forall o. Nat -> Elr o
Var Nat
v) (ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM ArgList o
forall o. ArgList o
ALNil)) MArgList o
xs) (ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM ArgList o
forall o. ArgList o
ALNil) ([((Hiding, Nat), MId, MExp o)] -> [((Hiding, Nat), MId, MExp o)]
forall a. [a] -> [a]
reverse [((Hiding, Nat), MId, MExp o)]
newvars))
pconstrapp :: CSPatI o
pconstrapp = ConstRef o -> [CSPat o] -> CSPatI o
forall o. ConstRef o -> [CSPat o] -> CSPatI o
CSPatConApp ConstRef o
con ((((Hiding, Nat), MId, MExp o) -> CSPat o)
-> [((Hiding, Nat), MId, MExp o)] -> [CSPat o]
forall a b. (a -> b) -> [a] -> [b]
map (\((Hiding
hid, Nat
v), MId
_, MExp o
_) -> Hiding -> CSPatI o -> CSPat o
forall a. Hiding -> a -> HI a
HI Hiding
hid (Nat -> CSPatI o
forall o. Nat -> CSPatI o
CSPatVar Nat
v)) [((Hiding, Nat), MId, MExp o)]
newvars)
thesub :: MExp o -> MExp o
thesub = Nat
-> Nat -> MExp (ReplaceWith (MExp o) (MExp o)) -> MExp o -> MExp o
forall t u.
Replace t u =>
Nat -> Nat -> MExp (ReplaceWith t u) -> t -> u
replace Nat
scrut ([((Hiding, Nat), MId, MExp o)] -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length [((Hiding, Nat), MId, MExp o)]
newvars) MExp o
MExp (ReplaceWith (MExp o) (MExp o))
constrapp
Id String
newvarprefix = (MId, MExp o) -> MId
forall a b. (a, b) -> a
fst ((MId, MExp o) -> MId) -> (MId, MExp o) -> MId
forall a b. (a -> b) -> a -> b
$ (CSCtx o -> [(MId, MExp o)]
forall a. [HI a] -> [a]
drophid CSCtx o
ctx) [(MId, MExp o)] -> Nat -> (MId, MExp o)
forall a. [a] -> Nat -> a
!! Nat
scrut
ctx1 :: CSCtx o
ctx1 = (HI (MId, MExp o) -> HI (MId, MExp o)) -> CSCtx o -> CSCtx o
forall a b. (a -> b) -> [a] -> [b]
map (\(HI Hiding
hid (MId
id, MExp o
t)) -> Hiding -> (MId, MExp o) -> HI (MId, MExp o)
forall a. Hiding -> a -> HI a
HI Hiding
hid (MId
id, MExp o -> MExp o
thesub MExp o
t)) (Nat -> CSCtx o -> CSCtx o
forall a. Nat -> [a] -> [a]
take Nat
scrut CSCtx o
ctx) CSCtx o -> CSCtx o -> CSCtx o
forall a. [a] -> [a] -> [a]
++
CSCtx o -> CSCtx o
forall a. [a] -> [a]
reverse ((((Hiding, Nat), MId, MExp o) -> Integer -> HI (MId, MExp o))
-> [((Hiding, Nat), MId, MExp o)] -> [Integer] -> CSCtx o
forall a b c. (a -> b -> c) -> [a] -> [b] -> [c]
zipWith (\((Hiding
hid, Nat
_), MId
id, MExp o
t) Integer
i ->
Hiding -> (MId, MExp o) -> HI (MId, MExp o)
forall a. Hiding -> a -> HI a
HI Hiding
hid (String -> MId
Id (case MId
id of {MId
NoId -> String
newvarprefix; Id String
id -> String
id}), MExp o
t)
) [((Hiding, Nat), MId, MExp o)]
newvars [Integer
0..]) CSCtx o -> CSCtx o -> CSCtx o
forall a. [a] -> [a] -> [a]
++
(HI (MId, MExp o) -> HI (MId, MExp o)) -> CSCtx o -> CSCtx o
forall a b. (a -> b) -> [a] -> [b]
map (\(HI Hiding
hid (MId
id, MExp o
t)) -> Hiding -> (MId, MExp o) -> HI (MId, MExp o)
forall a. Hiding -> a -> HI a
HI Hiding
hid (MId
id, MExp o -> MExp o
thesub MExp o
t)) (Nat -> CSCtx o -> CSCtx o
forall a. Nat -> [a] -> [a]
drop (Nat
scrut Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) CSCtx o
ctx)
tt' :: MExp o
tt' = MExp o -> MExp o
thesub MExp o
tt
pats' :: [CSPat o]
pats' = (CSPat o -> CSPat o) -> [CSPat o] -> [CSPat o]
forall a b. (a -> b) -> [a] -> [b]
map (Nat -> Nat -> CSPatI o -> MExp o -> CSPat o -> CSPat o
forall o. Nat -> Nat -> CSPatI o -> MExp o -> CSPat o -> CSPat o
replacep Nat
scrut ([((Hiding, Nat), MId, MExp o)] -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length [((Hiding, Nat), MId, MExp o)]
newvars) CSPatI o
pconstrapp MExp o
constrapp) [CSPat o]
pats
scruttype' :: MExp o
scruttype' = MExp o -> MExp o
thesub MExp o
scruttype
case MExp o -> MExp o -> Maybe [(Nat, MExp o)]
forall o. MExp o -> MExp o -> Maybe [(Nat, MExp o)]
unifyexp MExp o
inftype MExp o
scruttype' of
Maybe [(Nat, MExp o)]
Nothing -> do
Bool
res <- Nat -> Nat -> MExp o -> MExp o -> IO Bool
forall t. Unify t => Nat -> Nat -> t -> t -> IO Bool
notequal Nat
scrut ([((Hiding, Nat), MId, MExp o)] -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length [((Hiding, Nat), MId, MExp o)]
newvars) MExp o
scruttype' MExp o
inftype
if Bool
res then
[ConstRef o] -> IO [Sol o]
dobranches [ConstRef o]
cons
else
[Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return []
Just [(Nat, MExp o)]
unif ->
do
let (CSCtx o
ctx2, MExp o
tt2, [CSPat o]
pats2) = CSCtx o
-> MExp o
-> [CSPat o]
-> [(Nat, MExp o)]
-> (CSCtx o, MExp o, [CSPat o])
forall o.
CSCtx o
-> MExp o
-> [CSPat o]
-> [(Nat, MExp o)]
-> (CSCtx o, MExp o, [CSPat o])
removevar CSCtx o
ctx1 MExp o
tt' [CSPat o]
pats' [(Nat, MExp o)]
unif
cost :: Cost
cost
| [Nat] -> Bool
forall (t :: * -> *) a. Foldable t => t a -> Bool
null [Nat]
mblkvar Bool -> Bool -> Bool
&& Nat
scrut Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
< CSCtx o -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length CSCtx o
ctx Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
nscrutavoid Bool -> Bool -> Bool
&& Bool
nothid
= Cost
costCaseSplitLow Cost -> Cost -> Cost
forall a. Num a => a -> a -> a
+
Cost
costAddVarDepth Cost -> Cost -> Cost
forall a. Num a => a -> a -> a
*
Nat -> Cost
Cost (Nat -> [CSPat o] -> Nat
forall o. Nat -> [CSPat o] -> Nat
depthofvar Nat
scrut [CSPat o]
pats)
| [Nat] -> Bool
forall (t :: * -> *) a. Foldable t => t a -> Bool
null [Nat]
mblkvar = Cost
costCaseSplitVeryHigh
| Nat
scrut Nat -> [Nat] -> Bool
forall (t :: * -> *) a. (Foldable t, Eq a) => a -> t a -> Bool
`elem` [Nat]
mblkvar = Cost
costCaseSplitLow
| Nat
scrut Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
< CSCtx o -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length CSCtx o
ctx Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
nscrutavoid Bool -> Bool -> Bool
&& Bool
nothid = Cost
costCaseSplitHigh
| Bool
otherwise = Cost
costCaseSplitVeryHigh
nothid :: Bool
nothid = let HI Hiding
hid (MId, MExp o)
_ = CSCtx o
ctx CSCtx o -> Nat -> HI (MId, MExp o)
forall a. [a] -> Nat -> a
!! Nat
scrut
in Hiding
hid Hiding -> Hiding -> Bool
forall a. Eq a => a -> a -> Bool
== Hiding
NotHidden
[Sol o]
sols <- Cost -> Nat -> CSCtx o -> MExp o -> [CSPat o] -> IO [Sol o]
rc (Cost
depth Cost -> Cost -> Cost
forall a. Num a => a -> a -> a
- Cost
cost) (CSCtx o -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length CSCtx o
ctx Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
1 Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
scrut) CSCtx o
ctx2 MExp o
tt2 [CSPat o]
pats2
case [Sol o]
sols of
[] -> [Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return []
[Sol o]
_ -> do
[Sol o]
sols2 <- [ConstRef o] -> IO [Sol o]
dobranches [ConstRef o]
cons
[Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return ([Sol o] -> IO [Sol o]) -> [Sol o] -> IO [Sol o]
forall a b. (a -> b) -> a -> b
$ (Sol o -> [Sol o]) -> [Sol o] -> [Sol o]
forall (t :: * -> *) a b. Foldable t => (a -> [b]) -> t a -> [b]
concatMap (\Sol o
sol -> (Sol o -> Sol o) -> [Sol o] -> [Sol o]
forall a b. (a -> b) -> [a] -> [b]
map (\Sol o
sol2 -> Sol o
sol Sol o -> Sol o -> Sol o
forall a. [a] -> [a] -> [a]
++ Sol o
sol2) [Sol o]
sols2) [Sol o]
sols
DeclCont o
_ -> [Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return []
Exp o
_ -> [Sol o] -> IO [Sol o]
forall (m :: * -> *) a. Monad m => a -> m a
return []
infertypevar :: CSCtx o -> Nat -> MExp o
infertypevar :: forall o. CSCtx o -> Nat -> MExp o
infertypevar CSCtx o
ctx Nat
v = (MId, MExp o) -> MExp o
forall a b. (a, b) -> b
snd ((MId, MExp o) -> MExp o) -> (MId, MExp o) -> MExp o
forall a b. (a -> b) -> a -> b
$ (CSCtx o -> [(MId, MExp o)]
forall a. [HI a] -> [a]
drophid CSCtx o
ctx) [(MId, MExp o)] -> Nat -> (MId, MExp o)
forall a. [a] -> Nat -> a
!! Nat
v
class Replace t u where
type ReplaceWith t u
replace' :: Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace :: Replace t u => Nat -> Nat -> MExp (ReplaceWith t u) -> t -> u
replace :: forall t u.
Replace t u =>
Nat -> Nat -> MExp (ReplaceWith t u) -> t -> u
replace Nat
sv Nat
nnew MExp (ReplaceWith t u)
e t
t = Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
0 MExp (ReplaceWith t u)
e t
t Reader (Nat, Nat) u -> (Nat, Nat) -> u
forall r a. Reader r a -> r -> a
`runReader` (Nat
sv, Nat
nnew)
instance Replace t u => Replace (Abs t) (Abs u) where
type ReplaceWith (Abs t) (Abs u) = ReplaceWith t u
replace' :: Nat
-> MExp (ReplaceWith (Abs t) (Abs u))
-> Abs t
-> Reader (Nat, Nat) (Abs u)
replace' Nat
n MExp (ReplaceWith (Abs t) (Abs u))
re (Abs MId
mid t
b) = MId -> u -> Abs u
forall a. MId -> a -> Abs a
Abs MId
mid (u -> Abs u)
-> ReaderT (Nat, Nat) Identity u -> Reader (Nat, Nat) (Abs u)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Nat -> MExp (ReplaceWith t u) -> t -> ReaderT (Nat, Nat) Identity u
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' (Nat
n Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) MExp (ReplaceWith t u)
MExp (ReplaceWith (Abs t) (Abs u))
re t
b
instance Replace (Exp o) (MExp o) where
type ReplaceWith (Exp o) (MExp o) = o
replace' :: Nat
-> MExp (ReplaceWith (Exp o) (MExp o))
-> Exp o
-> Reader (Nat, Nat) (MExp o)
replace' Nat
n MExp (ReplaceWith (Exp o) (MExp o))
re = \case
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok elr :: Elr o
elr@(Var Nat
v) MArgList o
args -> do
MArgList o
ih <- ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM (ArgList o -> MArgList o)
-> ReaderT (Nat, Nat) Identity (ArgList o)
-> ReaderT (Nat, Nat) Identity (MArgList o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Nat
-> MExp (ReplaceWith (MArgList o) (ArgList o))
-> MArgList o
-> ReaderT (Nat, Nat) Identity (ArgList o)
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith (MArgList o) (ArgList o))
MExp (ReplaceWith (Exp o) (MExp o))
re MArgList o
args
(Nat
sv, Nat
nnew) <- ReaderT (Nat, Nat) Identity (Nat, Nat)
forall r (m :: * -> *). MonadReader r m => m r
ask
MExp o -> Reader (Nat, Nat) (MExp o)
forall (m :: * -> *) a. Monad m => a -> m a
return (MExp o -> Reader (Nat, Nat) (MExp o))
-> MExp o -> Reader (Nat, Nat) (MExp o)
forall a b. (a -> b) -> a -> b
$
if Nat
v Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
>= Nat
n
then if Nat
v Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
n Nat -> Nat -> Bool
forall a. Eq a => a -> a -> Bool
== Nat
sv
then MExp o -> MArgList o -> MExp o
forall o. MExp o -> MArgList o -> MExp o
betareduce (Nat -> MExp o -> MExp o
forall t. Lift t => Nat -> t -> t
lift Nat
n MExp o
MExp (ReplaceWith (Exp o) (MExp o))
re) MArgList o
ih
else if Nat
v Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
n Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
> Nat
sv
then Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o) -> Exp o -> MExp o
forall a b. (a -> b) -> a -> b
$ Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok (Nat -> Elr o
forall o. Nat -> Elr o
Var (Nat
v Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
nnew Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
1)) MArgList o
ih
else Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o) -> Exp o -> MExp o
forall a b. (a -> b) -> a -> b
$ Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok Elr o
elr MArgList o
ih
else Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o) -> Exp o -> MExp o
forall a b. (a -> b) -> a -> b
$ Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok Elr o
elr MArgList o
ih
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok elr :: Elr o
elr@Const{} MArgList o
args ->
Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o) -> (ArgList o -> Exp o) -> ArgList o -> MExp o
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok Elr o
elr (MArgList o -> Exp o)
-> (ArgList o -> MArgList o) -> ArgList o -> Exp o
forall b c a. (b -> c) -> (a -> b) -> a -> c
. ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM (ArgList o -> MExp o)
-> ReaderT (Nat, Nat) Identity (ArgList o)
-> Reader (Nat, Nat) (MExp o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Nat
-> MExp (ReplaceWith (MArgList o) (ArgList o))
-> MArgList o
-> ReaderT (Nat, Nat) Identity (ArgList o)
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith (MArgList o) (ArgList o))
MExp (ReplaceWith (Exp o) (MExp o))
re MArgList o
args
Lam Hiding
hid Abs (MExp o)
b -> Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o)
-> (Abs (MExp o) -> Exp o) -> Abs (MExp o) -> MExp o
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Hiding -> Abs (MExp o) -> Exp o
forall o. Hiding -> Abs (MExp o) -> Exp o
Lam Hiding
hid (Abs (MExp o) -> MExp o)
-> ReaderT (Nat, Nat) Identity (Abs (MExp o))
-> Reader (Nat, Nat) (MExp o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Nat
-> MExp (ReplaceWith (Abs (MExp o)) (Abs (MExp o)))
-> Abs (MExp o)
-> ReaderT (Nat, Nat) Identity (Abs (MExp o))
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' (Nat
n Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) MExp (ReplaceWith (Exp o) (MExp o))
MExp (ReplaceWith (Abs (MExp o)) (Abs (MExp o)))
re Abs (MExp o)
b
Pi Maybe (UId o)
uid Hiding
hid Bool
possdep MExp o
it Abs (MExp o)
b ->
(Exp o -> MExp o)
-> ReaderT (Nat, Nat) Identity (Exp o)
-> Reader (Nat, Nat) (MExp o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (ReaderT (Nat, Nat) Identity (Exp o) -> Reader (Nat, Nat) (MExp o))
-> ReaderT (Nat, Nat) Identity (Exp o)
-> Reader (Nat, Nat) (MExp o)
forall a b. (a -> b) -> a -> b
$ Maybe (UId o) -> Hiding -> Bool -> MExp o -> Abs (MExp o) -> Exp o
forall o.
Maybe (UId o) -> Hiding -> Bool -> MExp o -> Abs (MExp o) -> Exp o
Pi Maybe (UId o)
uid Hiding
hid Bool
possdep (MExp o -> Abs (MExp o) -> Exp o)
-> Reader (Nat, Nat) (MExp o)
-> ReaderT (Nat, Nat) Identity (Abs (MExp o) -> Exp o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Nat
-> MExp (ReplaceWith (MExp o) (MExp o))
-> MExp o
-> Reader (Nat, Nat) (MExp o)
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith (MExp o) (MExp o))
MExp (ReplaceWith (Exp o) (MExp o))
re MExp o
it ReaderT (Nat, Nat) Identity (Abs (MExp o) -> Exp o)
-> ReaderT (Nat, Nat) Identity (Abs (MExp o))
-> ReaderT (Nat, Nat) Identity (Exp o)
forall (f :: * -> *) a b. Applicative f => f (a -> b) -> f a -> f b
<*> Nat
-> MExp (ReplaceWith (Abs (MExp o)) (Abs (MExp o)))
-> Abs (MExp o)
-> ReaderT (Nat, Nat) Identity (Abs (MExp o))
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith (Exp o) (MExp o))
MExp (ReplaceWith (Abs (MExp o)) (Abs (MExp o)))
re Abs (MExp o)
b
e :: Exp o
e@Sort{} -> MExp o -> Reader (Nat, Nat) (MExp o)
forall (m :: * -> *) a. Monad m => a -> m a
return (MExp o -> Reader (Nat, Nat) (MExp o))
-> MExp o -> Reader (Nat, Nat) (MExp o)
forall a b. (a -> b) -> a -> b
$ Exp o -> MExp o
forall a blk. a -> MM a blk
NotM Exp o
e
e :: Exp o
e@AbsurdLambda{} -> MExp o -> Reader (Nat, Nat) (MExp o)
forall (m :: * -> *) a. Monad m => a -> m a
return (MExp o -> Reader (Nat, Nat) (MExp o))
-> MExp o -> Reader (Nat, Nat) (MExp o)
forall a b. (a -> b) -> a -> b
$ Exp o -> MExp o
forall a blk. a -> MM a blk
NotM Exp o
e
instance Replace t u => Replace (MM t (RefInfo o)) u where
type ReplaceWith (MM t (RefInfo o)) u = ReplaceWith t u
replace' :: Nat
-> MExp (ReplaceWith (MM t (RefInfo o)) u)
-> MM t (RefInfo o)
-> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith (MM t (RefInfo o)) u)
re = Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith t u)
MExp (ReplaceWith (MM t (RefInfo o)) u)
re (t -> Reader (Nat, Nat) u)
-> (MM t (RefInfo o) -> t)
-> MM t (RefInfo o)
-> Reader (Nat, Nat) u
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Empty -> MM t (RefInfo o) -> t
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__
instance Replace (ArgList o) (ArgList o) where
type ReplaceWith (ArgList o) (ArgList o) = o
replace' :: Nat
-> MExp (ReplaceWith (ArgList o) (ArgList o))
-> ArgList o
-> Reader (Nat, Nat) (ArgList o)
replace' Nat
n MExp (ReplaceWith (ArgList o) (ArgList o))
re ArgList o
args = case ArgList o
args of
ArgList o
ALNil -> ArgList o -> Reader (Nat, Nat) (ArgList o)
forall (m :: * -> *) a. Monad m => a -> m a
return ArgList o
forall o. ArgList o
ALNil
ALCons Hiding
hid MExp o
a MArgList o
as ->
Hiding -> MExp o -> MArgList o -> ArgList o
forall o. Hiding -> MExp o -> MArgList o -> ArgList o
ALCons Hiding
hid (MExp o -> MArgList o -> ArgList o)
-> ReaderT (Nat, Nat) Identity (MExp o)
-> ReaderT (Nat, Nat) Identity (MArgList o -> ArgList o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Nat
-> MExp (ReplaceWith (MExp o) (MExp o))
-> MExp o
-> ReaderT (Nat, Nat) Identity (MExp o)
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith (MExp o) (MExp o))
MExp (ReplaceWith (ArgList o) (ArgList o))
re MExp o
a ReaderT (Nat, Nat) Identity (MArgList o -> ArgList o)
-> ReaderT (Nat, Nat) Identity (MArgList o)
-> Reader (Nat, Nat) (ArgList o)
forall (f :: * -> *) a b. Applicative f => f (a -> b) -> f a -> f b
<*> (ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM (ArgList o -> MArgList o)
-> Reader (Nat, Nat) (ArgList o)
-> ReaderT (Nat, Nat) Identity (MArgList o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Nat
-> MExp (ReplaceWith (MArgList o) (ArgList o))
-> MArgList o
-> Reader (Nat, Nat) (ArgList o)
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith (MArgList o) (ArgList o))
MExp (ReplaceWith (ArgList o) (ArgList o))
re MArgList o
as)
ALProj{} -> Reader (Nat, Nat) (ArgList o)
forall a. HasCallStack => a
__IMPOSSIBLE__
ALConPar MArgList o
as -> MArgList o -> ArgList o
forall o. MArgList o -> ArgList o
ALConPar (MArgList o -> ArgList o)
-> (ArgList o -> MArgList o) -> ArgList o -> ArgList o
forall b c a. (b -> c) -> (a -> b) -> a -> c
. ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM (ArgList o -> ArgList o)
-> Reader (Nat, Nat) (ArgList o) -> Reader (Nat, Nat) (ArgList o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> Nat
-> MExp (ReplaceWith (MArgList o) (ArgList o))
-> MArgList o
-> Reader (Nat, Nat) (ArgList o)
forall t u.
Replace t u =>
Nat -> MExp (ReplaceWith t u) -> t -> Reader (Nat, Nat) u
replace' Nat
n MExp (ReplaceWith (MArgList o) (ArgList o))
MExp (ReplaceWith (ArgList o) (ArgList o))
re MArgList o
as
betareduce :: MExp o -> MArgList o -> MExp o
betareduce :: forall o. MExp o -> MArgList o -> MExp o
betareduce MExp o
e MArgList o
args = case Empty -> MArgList o -> ArgList o
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__ MArgList o
args of
ArgList o
ALNil -> MExp o
e
ALCons Hiding
_ MExp o
a MArgList o
rargs -> case Empty -> MExp o -> Exp o
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__ MExp o
e of
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok Elr o
elr MArgList o
eargs -> Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o) -> Exp o -> MExp o
forall a b. (a -> b) -> a -> b
$ Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok Elr o
elr (MArgList o -> MArgList o -> MArgList o
forall o. MArgList o -> MArgList o -> MArgList o
concatargs MArgList o
eargs MArgList o
args)
Lam Hiding
_ (Abs MId
_ MExp o
b) -> MExp o -> MArgList o -> MExp o
forall o. MExp o -> MArgList o -> MExp o
betareduce (Nat
-> Nat -> MExp (ReplaceWith (MExp o) (MExp o)) -> MExp o -> MExp o
forall t u.
Replace t u =>
Nat -> Nat -> MExp (ReplaceWith t u) -> t -> u
replace Nat
0 Nat
0 MExp o
MExp (ReplaceWith (MExp o) (MExp o))
a MExp o
b) MArgList o
rargs
Exp o
_ -> MExp o
forall a. HasCallStack => a
__IMPOSSIBLE__
ALProj{} -> MExp o
forall a. HasCallStack => a
__IMPOSSIBLE__
ALConPar MArgList o
as -> MExp o
forall a. HasCallStack => a
__IMPOSSIBLE__
concatargs :: MArgList o -> MArgList o -> MArgList o
concatargs :: forall o. MArgList o -> MArgList o -> MArgList o
concatargs MArgList o
xs MArgList o
ys = case Empty -> MArgList o -> ArgList o
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__ MArgList o
xs of
ArgList o
ALNil -> MArgList o
ys
ALCons Hiding
hid MExp o
x MArgList o
xs -> ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM (ArgList o -> MArgList o) -> ArgList o -> MArgList o
forall a b. (a -> b) -> a -> b
$ Hiding -> MExp o -> MArgList o -> ArgList o
forall o. Hiding -> MExp o -> MArgList o -> ArgList o
ALCons Hiding
hid MExp o
x (MArgList o -> MArgList o -> MArgList o
forall o. MArgList o -> MArgList o -> MArgList o
concatargs MArgList o
xs MArgList o
ys)
ALProj{} -> MArgList o
forall a. HasCallStack => a
__IMPOSSIBLE__
ALConPar MArgList o
as -> ArgList o -> MArgList o
forall a blk. a -> MM a blk
NotM (ArgList o -> MArgList o) -> ArgList o -> MArgList o
forall a b. (a -> b) -> a -> b
$ MArgList o -> ArgList o
forall o. MArgList o -> ArgList o
ALConPar (MArgList o -> MArgList o -> MArgList o
forall o. MArgList o -> MArgList o -> MArgList o
concatargs MArgList o
xs MArgList o
ys)
replacep :: forall o. Nat -> Nat -> CSPatI o -> MExp o -> CSPat o -> CSPat o
replacep :: forall o. Nat -> Nat -> CSPatI o -> MExp o -> CSPat o -> CSPat o
replacep Nat
sv Nat
nnew CSPatI o
rp MExp o
re = CSPat o -> CSPat o
r
where
r :: CSPat o -> CSPat o
r :: CSPat o -> CSPat o
r (HI Hiding
hid (CSPatConApp ConstRef o
c [CSPat o]
ps)) = Hiding -> CSPatI o -> CSPat o
forall a. Hiding -> a -> HI a
HI Hiding
hid (ConstRef o -> [CSPat o] -> CSPatI o
forall o. ConstRef o -> [CSPat o] -> CSPatI o
CSPatConApp ConstRef o
c ((CSPat o -> CSPat o) -> [CSPat o] -> [CSPat o]
forall a b. (a -> b) -> [a] -> [b]
map CSPat o -> CSPat o
r [CSPat o]
ps))
r (HI Hiding
hid (CSPatVar Nat
v)) | Nat
v Nat -> Nat -> Bool
forall a. Eq a => a -> a -> Bool
== Nat
sv = Hiding -> CSPatI o -> CSPat o
forall a. Hiding -> a -> HI a
HI Hiding
hid CSPatI o
rp
| Nat
v Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
> Nat
sv = Hiding -> CSPatI o -> CSPat o
forall a. Hiding -> a -> HI a
HI Hiding
hid (Nat -> CSPatI o
forall o. Nat -> CSPatI o
CSPatVar (Nat
v Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
nnew Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
1))
| Bool
otherwise = Hiding -> CSPatI o -> CSPat o
forall a. Hiding -> a -> HI a
HI Hiding
hid (Nat -> CSPatI o
forall o. Nat -> CSPatI o
CSPatVar Nat
v)
r (HI Hiding
hid (CSPatExp MExp o
e)) = Hiding -> CSPatI o -> CSPat o
forall a. Hiding -> a -> HI a
HI Hiding
hid (MExp o -> CSPatI o
forall o. MExp o -> CSPatI o
CSPatExp (MExp o -> CSPatI o) -> MExp o -> CSPatI o
forall a b. (a -> b) -> a -> b
$ Nat
-> Nat -> MExp (ReplaceWith (MExp o) (MExp o)) -> MExp o -> MExp o
forall t u.
Replace t u =>
Nat -> Nat -> MExp (ReplaceWith t u) -> t -> u
replace Nat
sv Nat
nnew MExp o
MExp (ReplaceWith (MExp o) (MExp o))
re MExp o
e)
r p :: CSPat o
p@(HI Hiding
_ CSPatI o
CSOmittedArg) = CSPat o
p
r CSPat o
_ = CSPat o
forall a. HasCallStack => a
__IMPOSSIBLE__
type Assignments o = [(Nat, Exp o)]
class Unify t where
type UnifiesTo t
unify' :: t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
notequal' :: t -> t -> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
unify :: Unify t => t -> t -> Maybe (Assignments (UnifiesTo t))
unify :: forall t. Unify t => t -> t -> Maybe (Assignments (UnifiesTo t))
unify t
t t
u = t -> t -> StateT [(Nat, Exp (UnifiesTo t))] Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' t
t t
u StateT [(Nat, Exp (UnifiesTo t))] Maybe ()
-> [(Nat, Exp (UnifiesTo t))] -> Maybe [(Nat, Exp (UnifiesTo t))]
forall (m :: * -> *) s a. Monad m => StateT s m a -> s -> m s
`execStateT` []
notequal :: Unify t => Nat -> Nat -> t -> t -> IO Bool
notequal :: forall t. Unify t => Nat -> Nat -> t -> t -> IO Bool
notequal Nat
fstnew Nat
nbnew t
t1 t
t2 = t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' t
t1 t
t2 ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
-> (Nat, Nat) -> StateT (Assignments (UnifiesTo t)) IO Bool
forall r (m :: * -> *) a. ReaderT r m a -> r -> m a
`runReaderT` (Nat
fstnew, Nat
nbnew)
StateT (Assignments (UnifiesTo t)) IO Bool
-> Assignments (UnifiesTo t) -> IO Bool
forall (m :: * -> *) s a. Monad m => StateT s m a -> s -> m a
`evalStateT` []
instance (Unify t, o ~ UnifiesTo t) => Unify (MM t (RefInfo o)) where
type UnifiesTo (MM t (RefInfo o)) = o
unify' :: MM t (RefInfo o)
-> MM t (RefInfo o)
-> StateT (Assignments (UnifiesTo (MM t (RefInfo o)))) Maybe ()
unify' = t -> t -> StateT [(Nat, Exp o)] Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' (t -> t -> StateT [(Nat, Exp o)] Maybe ())
-> (MM t (RefInfo o) -> t)
-> MM t (RefInfo o)
-> MM t (RefInfo o)
-> StateT [(Nat, Exp o)] Maybe ()
forall b c a. (b -> b -> c) -> (a -> b) -> a -> a -> c
`on` Empty -> MM t (RefInfo o) -> t
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__
notequal' :: MM t (RefInfo o)
-> MM t (RefInfo o)
-> ReaderT
(Nat, Nat)
(StateT (Assignments (UnifiesTo (MM t (RefInfo o)))) IO)
Bool
notequal' = t -> t -> ReaderT (Nat, Nat) (StateT [(Nat, Exp o)] IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' (t -> t -> ReaderT (Nat, Nat) (StateT [(Nat, Exp o)] IO) Bool)
-> (MM t (RefInfo o) -> t)
-> MM t (RefInfo o)
-> MM t (RefInfo o)
-> ReaderT (Nat, Nat) (StateT [(Nat, Exp o)] IO) Bool
forall b c a. (b -> b -> c) -> (a -> b) -> a -> a -> c
`on` Empty -> MM t (RefInfo o) -> t
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__
unifyVar :: Nat -> Exp o -> StateT (Assignments o) Maybe ()
unifyVar :: forall o. Nat -> Exp o -> StateT (Assignments o) Maybe ()
unifyVar Nat
v Exp o
e = do
Assignments o
unif <- StateT (Assignments o) Maybe (Assignments o)
forall s (m :: * -> *). MonadState s m => m s
get
case Nat -> Assignments o -> Maybe (Exp o)
forall a b. Eq a => a -> [(a, b)] -> Maybe b
lookup Nat
v Assignments o
unif of
Maybe (Exp o)
Nothing -> (Assignments o -> Assignments o) -> StateT (Assignments o) Maybe ()
forall s (m :: * -> *). MonadState s m => (s -> s) -> m ()
modify ((Nat
v, Exp o
e) (Nat, Exp o) -> Assignments o -> Assignments o
forall a. a -> [a] -> [a]
:)
Just Exp o
e' -> Exp o -> Exp o -> StateT (Assignments (UnifiesTo (Exp o))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' Exp o
e Exp o
e'
instance Unify t => Unify (Abs t) where
type UnifiesTo (Abs t) = UnifiesTo t
unify' :: Abs t -> Abs t -> StateT (Assignments (UnifiesTo (Abs t))) Maybe ()
unify' (Abs MId
_ t
b1) (Abs MId
_ t
b2) = t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' t
b1 t
b2
notequal' :: Abs t
-> Abs t
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (Abs t))) IO) Bool
notequal' (Abs MId
_ t
b1) (Abs MId
_ t
b2) = t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' t
b1 t
b2
instance Unify (Exp o) where
type UnifiesTo (Exp o) = o
unify' :: Exp o -> Exp o -> StateT (Assignments (UnifiesTo (Exp o))) Maybe ()
unify' Exp o
e1 Exp o
e2 = case (Exp o
e1, Exp o
e2) of
(App Maybe (UId o)
_ OKHandle (RefInfo o)
_ Elr o
elr1 MArgList o
args1, App Maybe (UId o)
_ OKHandle (RefInfo o)
_ Elr o
elr2 MArgList o
args2) | Elr o
elr1 Elr o -> Elr o -> Bool
forall a. Eq a => a -> a -> Bool
== Elr o
elr2 -> MArgList o
-> MArgList o
-> StateT (Assignments (UnifiesTo (MArgList o))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' MArgList o
args1 MArgList o
args2
(Lam Hiding
hid1 Abs (MExp o)
b1, Lam Hiding
hid2 Abs (MExp o)
b2) | Hiding
hid1 Hiding -> Hiding -> Bool
forall a. Eq a => a -> a -> Bool
== Hiding
hid2 -> Abs (MExp o)
-> Abs (MExp o)
-> StateT (Assignments (UnifiesTo (Abs (MExp o)))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' Abs (MExp o)
b1 Abs (MExp o)
b2
(Pi Maybe (UId o)
_ Hiding
hid1 Bool
_ MExp o
a1 Abs (MExp o)
b1, Pi Maybe (UId o)
_ Hiding
hid2 Bool
_ MExp o
a2 Abs (MExp o)
b2) | Hiding
hid1 Hiding -> Hiding -> Bool
forall a. Eq a => a -> a -> Bool
== Hiding
hid2 -> MExp o
-> MExp o -> StateT (Assignments (UnifiesTo (MExp o))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' MExp o
a1 MExp o
a2
StateT (Assignments o) Maybe ()
-> StateT (Assignments o) Maybe ()
-> StateT (Assignments o) Maybe ()
forall (m :: * -> *) a b. Monad m => m a -> m b -> m b
>> Abs (MExp o)
-> Abs (MExp o)
-> StateT (Assignments (UnifiesTo (Abs (MExp o)))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' Abs (MExp o)
b1 Abs (MExp o)
b2
(Sort Sort
_, Sort Sort
_) -> () -> StateT (Assignments o) Maybe ()
forall (m :: * -> *) a. Monad m => a -> m a
return ()
(App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Var Nat
v) (NotM ArgList o
ALNil), Exp o
_)
| Nat
v Nat -> Set Nat -> Bool
forall a. Ord a => a -> Set a -> Bool
`Set.member` (Exp o -> Set Nat
forall t. FreeVars t => t -> Set Nat
freeVars Exp o
e2) -> Maybe () -> StateT (Assignments o) Maybe ()
forall (t :: (* -> *) -> * -> *) (m :: * -> *) a.
(MonadTrans t, Monad m) =>
m a -> t m a
St.lift Maybe ()
forall a. Maybe a
Nothing
(Exp o
_, App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Var Nat
v) (NotM ArgList o
ALNil))
| Nat
v Nat -> Set Nat -> Bool
forall a. Ord a => a -> Set a -> Bool
`Set.member` (Exp o -> Set Nat
forall t. FreeVars t => t -> Set Nat
freeVars Exp o
e1) -> Maybe () -> StateT (Assignments o) Maybe ()
forall (t :: (* -> *) -> * -> *) (m :: * -> *) a.
(MonadTrans t, Monad m) =>
m a -> t m a
St.lift Maybe ()
forall a. Maybe a
Nothing
(App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Var Nat
v) (NotM ArgList o
ALNil), Exp o
_) -> Nat -> Exp o -> StateT (Assignments o) Maybe ()
forall o. Nat -> Exp o -> StateT (Assignments o) Maybe ()
unifyVar Nat
v Exp o
e2
(Exp o
_, App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Var Nat
v) (NotM ArgList o
ALNil)) -> Nat -> Exp o -> StateT (Assignments o) Maybe ()
forall o. Nat -> Exp o -> StateT (Assignments o) Maybe ()
unifyVar Nat
v Exp o
e1
(Exp o, Exp o)
_ -> Maybe () -> StateT (Assignments o) Maybe ()
forall (t :: (* -> *) -> * -> *) (m :: * -> *) a.
(MonadTrans t, Monad m) =>
m a -> t m a
St.lift Maybe ()
forall a. Maybe a
Nothing
notequal' :: Exp o
-> Exp o
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (Exp o))) IO) Bool
notequal' Exp o
e1 Exp o
e2 = do
(Nat
fstnew, Nat
nbnew) <- ReaderT (Nat, Nat) (StateT (Assignments o) IO) (Nat, Nat)
forall r (m :: * -> *). MonadReader r m => m r
ask
Assignments o
unifier <- ReaderT (Nat, Nat) (StateT (Assignments o) IO) (Assignments o)
forall s (m :: * -> *). MonadState s m => m s
get
case (Exp o
e1, Exp o
e2) of
(App Maybe (UId o)
_ OKHandle (RefInfo o)
_ Elr o
elr1 MArgList o
es1, App Maybe (UId o)
_ OKHandle (RefInfo o)
_ Elr o
elr2 MArgList o
es2) | Elr o
elr1 Elr o -> Elr o -> Bool
forall a. Eq a => a -> a -> Bool
== Elr o
elr2 -> MArgList o
-> MArgList o
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (MArgList o))) IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' MArgList o
es1 MArgList o
es2
(Exp o
_, App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Var Nat
v2) (NotM ArgList o
ALNil))
| Nat
fstnew Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
<= Nat
v2 Bool -> Bool -> Bool
&& Nat
v2 Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
< Nat
fstnew Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
nbnew ->
case Nat -> Assignments o -> Maybe (Exp o)
forall a b. Eq a => a -> [(a, b)] -> Maybe b
lookup Nat
v2 Assignments o
unifier of
Maybe (Exp o)
Nothing -> (Assignments o -> Assignments o)
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) ()
forall s (m :: * -> *). MonadState s m => (s -> s) -> m ()
modify ((Nat
v2, Exp o
e1)(Nat, Exp o) -> Assignments o -> Assignments o
forall a. a -> [a] -> [a]
:) ReaderT (Nat, Nat) (StateT (Assignments o) IO) ()
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
forall (m :: * -> *) a b. Monad m => m a -> m b -> m b
>> Bool -> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
forall (m :: * -> *) a. Monad m => a -> m a
return Bool
False
Just Exp o
e2' -> Exp o
-> Exp o
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (Exp o))) IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' Exp o
e1 Exp o
e2'
(App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Const ConstRef o
c1) MArgList o
es1, App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Const ConstRef o
c2) MArgList o
es2) -> do
ConstDef o
cd1 <- IO (ConstDef o)
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) (ConstDef o)
forall (m :: * -> *) a. MonadIO m => IO a -> m a
liftIO (IO (ConstDef o)
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) (ConstDef o))
-> IO (ConstDef o)
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) (ConstDef o)
forall a b. (a -> b) -> a -> b
$ ConstRef o -> IO (ConstDef o)
forall a. IORef a -> IO a
readIORef ConstRef o
c1
ConstDef o
cd2 <- IO (ConstDef o)
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) (ConstDef o)
forall (m :: * -> *) a. MonadIO m => IO a -> m a
liftIO (IO (ConstDef o)
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) (ConstDef o))
-> IO (ConstDef o)
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) (ConstDef o)
forall a b. (a -> b) -> a -> b
$ ConstRef o -> IO (ConstDef o)
forall a. IORef a -> IO a
readIORef ConstRef o
c2
case (ConstDef o -> DeclCont o
forall o. ConstDef o -> DeclCont o
cdcont ConstDef o
cd1, ConstDef o -> DeclCont o
forall o. ConstDef o -> DeclCont o
cdcont ConstDef o
cd2) of
(Constructor{}, Constructor{}) -> if ConstRef o
c1 ConstRef o -> ConstRef o -> Bool
forall a. Eq a => a -> a -> Bool
== ConstRef o
c2 then MArgList o
-> MArgList o
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (MArgList o))) IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' MArgList o
es1 MArgList o
es2
else Bool -> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
forall (m :: * -> *) a. Monad m => a -> m a
return Bool
True
(DeclCont o, DeclCont o)
_ -> Bool -> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
forall (m :: * -> *) a. Monad m => a -> m a
return Bool
False
(Exp o, Exp o)
_ -> Bool -> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
forall (m :: * -> *) a. Monad m => a -> m a
return Bool
False
instance Unify (ArgList o) where
type UnifiesTo (ArgList o) = o
unify' :: ArgList o
-> ArgList o
-> StateT (Assignments (UnifiesTo (ArgList o))) Maybe ()
unify' ArgList o
args1 ArgList o
args2 = case (ArgList o
args1, ArgList o
args2) of
(ArgList o
ALNil, ArgList o
ALNil) -> () -> StateT (Assignments o) Maybe ()
forall (f :: * -> *) a. Applicative f => a -> f a
pure ()
(ALCons Hiding
hid1 MExp o
a1 MArgList o
as1, ALCons Hiding
hid2 MExp o
a2 MArgList o
as2) | Hiding
hid1 Hiding -> Hiding -> Bool
forall a. Eq a => a -> a -> Bool
== Hiding
hid2 -> MExp o
-> MExp o -> StateT (Assignments (UnifiesTo (MExp o))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' MExp o
a1 MExp o
a2
StateT (Assignments o) Maybe ()
-> StateT (Assignments o) Maybe ()
-> StateT (Assignments o) Maybe ()
forall (m :: * -> *) a b. Monad m => m a -> m b -> m b
>> MArgList o
-> MArgList o
-> StateT (Assignments (UnifiesTo (MArgList o))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' MArgList o
as1 MArgList o
as2
(ALConPar MArgList o
as1, ALCons Hiding
_ MExp o
_ MArgList o
as2) -> MArgList o
-> MArgList o
-> StateT (Assignments (UnifiesTo (MArgList o))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' MArgList o
as1 MArgList o
as2
(ALCons Hiding
_ MExp o
_ MArgList o
as1, ALConPar MArgList o
as2) -> MArgList o
-> MArgList o
-> StateT (Assignments (UnifiesTo (MArgList o))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' MArgList o
as1 MArgList o
as2
(ALConPar MArgList o
as1, ALConPar MArgList o
as2) -> MArgList o
-> MArgList o
-> StateT (Assignments (UnifiesTo (MArgList o))) Maybe ()
forall t.
Unify t =>
t -> t -> StateT (Assignments (UnifiesTo t)) Maybe ()
unify' MArgList o
as1 MArgList o
as2
(ArgList o, ArgList o)
_ -> Maybe () -> StateT (Assignments o) Maybe ()
forall (t :: (* -> *) -> * -> *) (m :: * -> *) a.
(MonadTrans t, Monad m) =>
m a -> t m a
St.lift Maybe ()
forall a. Maybe a
Nothing
notequal' :: ArgList o
-> ArgList o
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (ArgList o))) IO) Bool
notequal' ArgList o
args1 ArgList o
args2 = case (ArgList o
args1, ArgList o
args2) of
(ALCons Hiding
_ MExp o
e MArgList o
es, ALCons Hiding
_ MExp o
f MArgList o
fs) -> MExp o
-> MExp o
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (MExp o))) IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' MExp o
e MExp o
f ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
-> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
forall (m :: * -> *). Monad m => m Bool -> m Bool -> m Bool
`or2M` MArgList o
-> MArgList o
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (MArgList o))) IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' MArgList o
es MArgList o
fs
(ALConPar MArgList o
es1, ALConPar MArgList o
es2) -> MArgList o
-> MArgList o
-> ReaderT
(Nat, Nat) (StateT (Assignments (UnifiesTo (MArgList o))) IO) Bool
forall t.
Unify t =>
t
-> t
-> ReaderT (Nat, Nat) (StateT (Assignments (UnifiesTo t)) IO) Bool
notequal' MArgList o
es1 MArgList o
es2
(ArgList o, ArgList o)
_ -> Bool -> ReaderT (Nat, Nat) (StateT (Assignments o) IO) Bool
forall (m :: * -> *) a. Monad m => a -> m a
return Bool
False
unifyexp :: MExp o -> MExp o -> Maybe ([(Nat, MExp o)])
unifyexp :: forall o. MExp o -> MExp o -> Maybe [(Nat, MExp o)]
unifyexp MExp o
e1 MExp o
e2 = ((Nat, Exp o) -> (Nat, MExp o))
-> [(Nat, Exp o)] -> [(Nat, MExp o)]
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap (Exp o -> MExp o
forall a blk. a -> MM a blk
NotM (Exp o -> MExp o) -> (Nat, Exp o) -> (Nat, MExp o)
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$>) ([(Nat, Exp o)] -> [(Nat, MExp o)])
-> Maybe [(Nat, Exp o)] -> Maybe [(Nat, MExp o)]
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> MExp o -> MExp o -> Maybe (Assignments (UnifiesTo (MExp o)))
forall t. Unify t => t -> t -> Maybe (Assignments (UnifiesTo t))
unify MExp o
e1 MExp o
e2
class Lift t where
lift' :: Nat -> Nat -> t -> t
lift :: Lift t => Nat -> t -> t
lift :: forall t. Lift t => Nat -> t -> t
lift Nat
0 = t -> t
forall a. a -> a
id
lift Nat
n = Nat -> Nat -> t -> t
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
0
instance Lift t => Lift (Abs t) where
lift' :: Nat -> Nat -> Abs t -> Abs t
lift' Nat
n Nat
j (Abs MId
mid t
b) = MId -> t -> Abs t
forall a. MId -> a -> Abs a
Abs MId
mid (Nat -> Nat -> t -> t
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n (Nat
j Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) t
b)
instance Lift t => Lift (MM t r) where
lift' :: Nat -> Nat -> MM t r -> MM t r
lift' Nat
n Nat
j = t -> MM t r
forall a blk. a -> MM a blk
NotM (t -> MM t r) -> (MM t r -> t) -> MM t r -> MM t r
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Nat -> Nat -> t -> t
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j (t -> t) -> (MM t r -> t) -> MM t r -> t
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Empty -> MM t r -> t
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__
instance Lift (Exp o) where
lift' :: Nat -> Nat -> Exp o -> Exp o
lift' Nat
n Nat
j = \case
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok Elr o
elr MArgList o
args -> case Elr o
elr of
Var Nat
v | Nat
v Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
>= Nat
j -> Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok (Nat -> Elr o
forall o. Nat -> Elr o
Var (Nat
v Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
n)) (Nat -> Nat -> MArgList o -> MArgList o
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j MArgList o
args)
Elr o
_ -> Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
forall o.
Maybe (UId o)
-> OKHandle (RefInfo o) -> Elr o -> MArgList o -> Exp o
App Maybe (UId o)
uid OKHandle (RefInfo o)
ok Elr o
elr (Nat -> Nat -> MArgList o -> MArgList o
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j MArgList o
args)
Lam Hiding
hid Abs (MExp o)
b -> Hiding -> Abs (MExp o) -> Exp o
forall o. Hiding -> Abs (MExp o) -> Exp o
Lam Hiding
hid (Nat -> Nat -> Abs (MExp o) -> Abs (MExp o)
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j Abs (MExp o)
b)
Pi Maybe (UId o)
uid Hiding
hid Bool
possdep MExp o
it Abs (MExp o)
b -> Maybe (UId o) -> Hiding -> Bool -> MExp o -> Abs (MExp o) -> Exp o
forall o.
Maybe (UId o) -> Hiding -> Bool -> MExp o -> Abs (MExp o) -> Exp o
Pi Maybe (UId o)
uid Hiding
hid Bool
possdep (Nat -> Nat -> MExp o -> MExp o
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j MExp o
it) (Nat -> Nat -> Abs (MExp o) -> Abs (MExp o)
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j Abs (MExp o)
b)
e :: Exp o
e@Sort{} -> Exp o
e
e :: Exp o
e@AbsurdLambda{} -> Exp o
e
instance Lift (ArgList o) where
lift' :: Nat -> Nat -> ArgList o -> ArgList o
lift' Nat
n Nat
j ArgList o
args = case ArgList o
args of
ArgList o
ALNil -> ArgList o
forall o. ArgList o
ALNil
ALCons Hiding
hid MExp o
a MArgList o
as -> Hiding -> MExp o -> MArgList o -> ArgList o
forall o. Hiding -> MExp o -> MArgList o -> ArgList o
ALCons Hiding
hid (Nat -> Nat -> MExp o -> MExp o
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j MExp o
a) (Nat -> Nat -> MArgList o -> MArgList o
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j MArgList o
as)
ALProj{} -> ArgList o
forall a. HasCallStack => a
__IMPOSSIBLE__
ALConPar MArgList o
as -> MArgList o -> ArgList o
forall o. MArgList o -> ArgList o
ALConPar (Nat -> Nat -> MArgList o -> MArgList o
forall t. Lift t => Nat -> Nat -> t -> t
lift' Nat
n Nat
j MArgList o
as)
removevar :: CSCtx o -> MExp o -> [CSPat o] -> [(Nat, MExp o)] -> (CSCtx o, MExp o, [CSPat o])
removevar :: forall o.
CSCtx o
-> MExp o
-> [CSPat o]
-> [(Nat, MExp o)]
-> (CSCtx o, MExp o, [CSPat o])
removevar CSCtx o
ctx MExp o
tt [CSPat o]
pats [] = (CSCtx o
ctx, MExp o
tt, [CSPat o]
pats)
removevar CSCtx o
ctx MExp o
tt [CSPat o]
pats ((Nat
v, MExp o
e) : [(Nat, MExp o)]
unif) =
let
e2 :: MExp o
e2 = Nat
-> Nat -> MExp (ReplaceWith (MExp o) (MExp o)) -> MExp o -> MExp o
forall t u.
Replace t u =>
Nat -> Nat -> MExp (ReplaceWith t u) -> t -> u
replace Nat
v Nat
0 MExp (ReplaceWith (MExp o) (MExp o))
forall a. HasCallStack => a
__IMPOSSIBLE__ MExp o
e
thesub :: MExp o -> MExp o
thesub = Nat
-> Nat -> MExp (ReplaceWith (MExp o) (MExp o)) -> MExp o -> MExp o
forall t u.
Replace t u =>
Nat -> Nat -> MExp (ReplaceWith t u) -> t -> u
replace Nat
v Nat
0 MExp o
MExp (ReplaceWith (MExp o) (MExp o))
e2
ctx1 :: CSCtx o
ctx1 = (HI (MId, MExp o) -> HI (MId, MExp o)) -> CSCtx o -> CSCtx o
forall a b. (a -> b) -> [a] -> [b]
map (\(HI Hiding
hid (MId
id, MExp o
t)) -> Hiding -> (MId, MExp o) -> HI (MId, MExp o)
forall a. Hiding -> a -> HI a
HI Hiding
hid (MId
id, MExp o -> MExp o
thesub MExp o
t)) (Nat -> CSCtx o -> CSCtx o
forall a. Nat -> [a] -> [a]
take Nat
v CSCtx o
ctx) CSCtx o -> CSCtx o -> CSCtx o
forall a. [a] -> [a] -> [a]
++
(HI (MId, MExp o) -> HI (MId, MExp o)) -> CSCtx o -> CSCtx o
forall a b. (a -> b) -> [a] -> [b]
map (\(HI Hiding
hid (MId
id, MExp o
t)) -> Hiding -> (MId, MExp o) -> HI (MId, MExp o)
forall a. Hiding -> a -> HI a
HI Hiding
hid (MId
id, MExp o -> MExp o
thesub MExp o
t)) (Nat -> CSCtx o -> CSCtx o
forall a. Nat -> [a] -> [a]
drop (Nat
v Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) CSCtx o
ctx)
tt' :: MExp o
tt' = MExp o -> MExp o
thesub MExp o
tt
pats' :: [CSPat o]
pats' = (CSPat o -> CSPat o) -> [CSPat o] -> [CSPat o]
forall a b. (a -> b) -> [a] -> [b]
map (Nat -> Nat -> CSPatI o -> MExp o -> CSPat o -> CSPat o
forall o. Nat -> Nat -> CSPatI o -> MExp o -> CSPat o -> CSPat o
replacep Nat
v Nat
0 (MExp o -> CSPatI o
forall o. MExp o -> CSPatI o
CSPatExp MExp o
e2) MExp o
e2) [CSPat o]
pats
unif' :: [(Nat, MExp o)]
unif' = ((Nat, MExp o) -> (Nat, MExp o))
-> [(Nat, MExp o)] -> [(Nat, MExp o)]
forall a b. (a -> b) -> [a] -> [b]
map (\(Nat
uv, MExp o
ue) -> (if Nat
uv Nat -> Nat -> Bool
forall a. Ord a => a -> a -> Bool
> Nat
v then Nat
uv Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
1 else Nat
uv, MExp o -> MExp o
thesub MExp o
ue)) [(Nat, MExp o)]
unif
in
CSCtx o
-> MExp o
-> [CSPat o]
-> [(Nat, MExp o)]
-> (CSCtx o, MExp o, [CSPat o])
forall o.
CSCtx o
-> MExp o
-> [CSPat o]
-> [(Nat, MExp o)]
-> (CSCtx o, MExp o, [CSPat o])
removevar CSCtx o
ctx1 MExp o
tt' [CSPat o]
pats' [(Nat, MExp o)]
unif'
findperm :: [MExp o] -> Maybe [Nat]
findperm :: forall o. [MExp o] -> Maybe [Nat]
findperm [MExp o]
ts =
let
frees :: [[Nat]]
frees = (MExp o -> [Nat]) -> [MExp o] -> [[Nat]]
forall a b. (a -> b) -> [a] -> [b]
map MExp o -> [Nat]
forall t. FreeVars t => t -> [Nat]
freevars [MExp o]
ts
m :: IntMap Nat
m = [(Nat, Nat)] -> IntMap Nat
forall a. [(Nat, a)] -> IntMap a
IntMap.fromList ([(Nat, Nat)] -> IntMap Nat) -> [(Nat, Nat)] -> IntMap Nat
forall a b. (a -> b) -> a -> b
$
(Nat -> (Nat, Nat)) -> [Nat] -> [(Nat, Nat)]
forall a b. (a -> b) -> [a] -> [b]
map (\Nat
i -> (Nat
i, [[Nat]] -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length (([Nat] -> Bool) -> [[Nat]] -> [[Nat]]
forall a. (a -> Bool) -> [a] -> [a]
filter (Nat -> [Nat] -> Bool
forall (t :: * -> *) a. (Foldable t, Eq a) => a -> t a -> Bool
elem Nat
i) [[Nat]]
frees)))
[Nat
0..[MExp o] -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length [MExp o]
ts Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
1]
r :: IntMap Nat -> [Nat] -> Nat -> Maybe [Nat]
r IntMap Nat
_ [Nat]
perm Nat
0 = [Nat] -> Maybe [Nat]
forall a. a -> Maybe a
Just ([Nat] -> Maybe [Nat]) -> [Nat] -> Maybe [Nat]
forall a b. (a -> b) -> a -> b
$ [Nat] -> [Nat]
forall a. [a] -> [a]
reverse [Nat]
perm
r IntMap Nat
m [Nat]
perm Nat
n =
case Nat -> [(Nat, Nat)] -> Maybe Nat
forall a b. Eq a => a -> [(a, b)] -> Maybe b
lookup Nat
0 (((Nat, Nat) -> (Nat, Nat)) -> [(Nat, Nat)] -> [(Nat, Nat)]
forall a b. (a -> b) -> [a] -> [b]
map (Nat, Nat) -> (Nat, Nat)
forall a b. (a, b) -> (b, a)
swap (IntMap Nat -> [(Nat, Nat)]
forall a. IntMap a -> [(Nat, a)]
IntMap.toList IntMap Nat
m)) of
Maybe Nat
Nothing -> Maybe [Nat]
forall a. Maybe a
Nothing
Just Nat
i -> IntMap Nat -> [Nat] -> Nat -> Maybe [Nat]
r ((IntMap Nat -> Nat -> IntMap Nat)
-> IntMap Nat -> [Nat] -> IntMap Nat
forall (t :: * -> *) b a.
Foldable t =>
(b -> a -> b) -> b -> t a -> b
foldl ((Nat -> IntMap Nat -> IntMap Nat)
-> IntMap Nat -> Nat -> IntMap Nat
forall a b c. (a -> b -> c) -> b -> a -> c
flip ((Nat -> IntMap Nat -> IntMap Nat)
-> IntMap Nat -> Nat -> IntMap Nat)
-> (Nat -> IntMap Nat -> IntMap Nat)
-> IntMap Nat
-> Nat
-> IntMap Nat
forall a b. (a -> b) -> a -> b
$ (Nat -> Nat) -> Nat -> IntMap Nat -> IntMap Nat
forall a. (a -> a) -> Nat -> IntMap a -> IntMap a
IntMap.adjust (Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
subtract Nat
1))
(Nat -> Nat -> IntMap Nat -> IntMap Nat
forall a. Nat -> a -> IntMap a -> IntMap a
IntMap.insert Nat
i (-Nat
1) IntMap Nat
m)
([[Nat]]
frees [[Nat]] -> Nat -> [Nat]
forall a. [a] -> Nat -> a
!! Nat
i))
(Nat
i Nat -> [Nat] -> [Nat]
forall a. a -> [a] -> [a]
: [Nat]
perm) (Nat
n Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
1)
in IntMap Nat -> [Nat] -> Nat -> Maybe [Nat]
r IntMap Nat
m [] ([MExp o] -> Nat
forall (t :: * -> *) a. Foldable t => t a -> Nat
length [MExp o]
ts)
freevars :: FreeVars t => t -> [Nat]
freevars :: forall t. FreeVars t => t -> [Nat]
freevars = Set Nat -> [Nat]
forall a. Set a -> [a]
Set.toList (Set Nat -> [Nat]) -> (t -> Set Nat) -> t -> [Nat]
forall b c a. (b -> c) -> (a -> b) -> a -> c
. t -> Set Nat
forall t. FreeVars t => t -> Set Nat
freeVars
applyperm :: [Nat] -> CSCtx o -> MExp o -> [CSPat o] ->
(CSCtx o, MExp o, [CSPat o])
applyperm :: forall o.
[Nat]
-> CSCtx o -> MExp o -> [CSPat o] -> (CSCtx o, MExp o, [CSPat o])
applyperm [Nat]
perm CSCtx o
ctx MExp o
tt [CSPat o]
pats =
let ctx1 :: CSCtx o
ctx1 = (HI (MId, MExp o) -> HI (MId, MExp o)) -> CSCtx o -> CSCtx o
forall a b. (a -> b) -> [a] -> [b]
map (\(HI Hiding
hid (MId
id, MExp o
t)) -> Hiding -> (MId, MExp o) -> HI (MId, MExp o)
forall a. Hiding -> a -> HI a
HI Hiding
hid (MId
id, (Nat -> Nat) -> MExp o -> MExp o
forall t. Renaming t => (Nat -> Nat) -> t -> t
rename ([Nat] -> Nat -> Nat
ren [Nat]
perm) MExp o
t)) CSCtx o
ctx
ctx2 :: CSCtx o
ctx2 = (Nat -> HI (MId, MExp o)) -> [Nat] -> CSCtx o
forall a b. (a -> b) -> [a] -> [b]
map (\Nat
i -> CSCtx o
ctx1 CSCtx o -> Nat -> HI (MId, MExp o)
forall a. [a] -> Nat -> a
!! Nat
i) [Nat]
perm
ctx3 :: CSCtx o
ctx3 = CSCtx o -> CSCtx o
forall o. CSCtx o -> CSCtx o
seqctx CSCtx o
ctx2
tt' :: MExp o
tt' = (Nat -> Nat) -> MExp o -> MExp o
forall t. Renaming t => (Nat -> Nat) -> t -> t
rename ([Nat] -> Nat -> Nat
ren [Nat]
perm) MExp o
tt
pats' :: [CSPat o]
pats' = (CSPat o -> CSPat o) -> [CSPat o] -> [CSPat o]
forall a b. (a -> b) -> [a] -> [b]
map ((Nat -> Nat) -> CSPat o -> CSPat o
forall t. Renaming t => (Nat -> Nat) -> t -> t
rename ([Nat] -> Nat -> Nat
ren [Nat]
perm)) [CSPat o]
pats
in (CSCtx o
ctx3, MExp o
tt', [CSPat o]
pats')
ren :: [Nat] -> Nat -> Int
ren :: [Nat] -> Nat -> Nat
ren [Nat]
n Nat
i = let Just Nat
j = Nat -> [Nat] -> Maybe Nat
forall a. Eq a => a -> [a] -> Maybe Nat
elemIndex Nat
i [Nat]
n in Nat
j
instance Renaming t => Renaming (HI t) where
renameOffset :: Nat -> (Nat -> Nat) -> HI t -> HI t
renameOffset Nat
j Nat -> Nat
ren (HI Hiding
hid t
t) = Hiding -> t -> HI t
forall a. Hiding -> a -> HI a
HI Hiding
hid (t -> HI t) -> t -> HI t
forall a b. (a -> b) -> a -> b
$ Nat -> (Nat -> Nat) -> t -> t
forall t. Renaming t => Nat -> (Nat -> Nat) -> t -> t
renameOffset Nat
j Nat -> Nat
ren t
t
instance Renaming (CSPatI o) where
renameOffset :: Nat -> (Nat -> Nat) -> CSPatI o -> CSPatI o
renameOffset Nat
j Nat -> Nat
ren = \case
CSPatConApp ConstRef o
c [CSPat o]
pats -> ConstRef o -> [CSPat o] -> CSPatI o
forall o. ConstRef o -> [CSPat o] -> CSPatI o
CSPatConApp ConstRef o
c ([CSPat o] -> CSPatI o) -> [CSPat o] -> CSPatI o
forall a b. (a -> b) -> a -> b
$ (CSPat o -> CSPat o) -> [CSPat o] -> [CSPat o]
forall a b. (a -> b) -> [a] -> [b]
map (Nat -> (Nat -> Nat) -> CSPat o -> CSPat o
forall t. Renaming t => Nat -> (Nat -> Nat) -> t -> t
renameOffset Nat
j Nat -> Nat
ren) [CSPat o]
pats
CSPatVar Nat
i -> Nat -> CSPatI o
forall o. Nat -> CSPatI o
CSPatVar (Nat -> CSPatI o) -> Nat -> CSPatI o
forall a b. (a -> b) -> a -> b
$ Nat
j Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat -> Nat
ren Nat
i
CSPatExp MExp o
e -> MExp o -> CSPatI o
forall o. MExp o -> CSPatI o
CSPatExp (MExp o -> CSPatI o) -> MExp o -> CSPatI o
forall a b. (a -> b) -> a -> b
$ Nat -> (Nat -> Nat) -> MExp o -> MExp o
forall t. Renaming t => Nat -> (Nat -> Nat) -> t -> t
renameOffset Nat
j Nat -> Nat
ren MExp o
e
e :: CSPatI o
e@CSPatI o
CSOmittedArg -> CSPatI o
e
CSPatI o
_ -> CSPatI o
forall a. HasCallStack => a
__IMPOSSIBLE__
seqctx :: CSCtx o -> CSCtx o
seqctx :: forall o. CSCtx o -> CSCtx o
seqctx = Nat -> [HI (MId, MExp o)] -> [HI (MId, MExp o)]
forall {b} {a}. Lift b => Nat -> [HI (a, b)] -> [HI (a, b)]
r (-Nat
1)
where
r :: Nat -> [HI (a, b)] -> [HI (a, b)]
r Nat
_ [] = []
r Nat
n (HI Hiding
hid (a
id, b
t) : [HI (a, b)]
ctx) = Hiding -> (a, b) -> HI (a, b)
forall a. Hiding -> a -> HI a
HI Hiding
hid (a
id, Nat -> b -> b
forall t. Lift t => Nat -> t -> t
lift Nat
n b
t) HI (a, b) -> [HI (a, b)] -> [HI (a, b)]
forall a. a -> [a] -> [a]
: Nat -> [HI (a, b)] -> [HI (a, b)]
r (Nat
n Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
- Nat
1) [HI (a, b)]
ctx
depthofvar :: Nat -> [CSPat o] -> Nat
depthofvar :: forall o. Nat -> [CSPat o] -> Nat
depthofvar Nat
v [CSPat o]
pats =
let [Nat
depth] = (CSPatI o -> [Nat]) -> [CSPatI o] -> [Nat]
forall (t :: * -> *) a b. Foldable t => (a -> [b]) -> t a -> [b]
concatMap (Nat -> CSPatI o -> [Nat]
f Nat
0) ([CSPat o] -> [CSPatI o]
forall a. [HI a] -> [a]
drophid [CSPat o]
pats)
f :: Nat -> CSPatI o -> [Nat]
f Nat
d (CSPatConApp ConstRef o
_ [CSPat o]
pats) = (CSPatI o -> [Nat]) -> [CSPatI o] -> [Nat]
forall (t :: * -> *) a b. Foldable t => (a -> [b]) -> t a -> [b]
concatMap (Nat -> CSPatI o -> [Nat]
f (Nat
d Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1)) ([CSPat o] -> [CSPatI o]
forall a. [HI a] -> [a]
drophid [CSPat o]
pats)
f Nat
d (CSPatVar Nat
v') = [Nat
d | Nat
v Nat -> Nat -> Bool
forall a. Eq a => a -> a -> Bool
== Nat
v']
f Nat
_ CSPatI o
_ = []
in Nat
depth
class LocalTerminationEnv a where
sizeAndBoundVars :: a -> (Sum Nat, [Nat])
instance LocalTerminationEnv a => LocalTerminationEnv (HI a) where
sizeAndBoundVars :: HI a -> (Sum Nat, [Nat])
sizeAndBoundVars (HI Hiding
_ a
p) = a -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars a
p
instance LocalTerminationEnv (CSPatI o) where
sizeAndBoundVars :: CSPatI o -> (Sum Nat, [Nat])
sizeAndBoundVars = \case
CSPatConApp ConstRef o
_ [CSPat o]
ps -> (Sum Nat
1, []) (Sum Nat, [Nat]) -> (Sum Nat, [Nat]) -> (Sum Nat, [Nat])
forall a. Semigroup a => a -> a -> a
<> [CSPat o] -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars [CSPat o]
ps
CSPatVar Nat
n -> (Sum Nat
0, [Nat
n])
CSPatExp MExp o
e -> MExp o -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars MExp o
e
CSPatI o
_ -> (Sum Nat
0, [])
instance LocalTerminationEnv a => LocalTerminationEnv [a] where
sizeAndBoundVars :: [a] -> (Sum Nat, [Nat])
sizeAndBoundVars = (a -> (Sum Nat, [Nat])) -> [a] -> (Sum Nat, [Nat])
forall (t :: * -> *) m a.
(Foldable t, Monoid m) =>
(a -> m) -> t a -> m
foldMap a -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars
instance LocalTerminationEnv (MExp o) where
sizeAndBoundVars :: MExp o -> (Sum Nat, [Nat])
sizeAndBoundVars Meta{} = (Sum Nat
0, [])
sizeAndBoundVars (NotM Exp o
e) = case Exp o
e of
App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Var Nat
v) MArgList o
_ -> (Sum Nat
0, [Nat
v])
App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Const ConstRef o
_) MArgList o
args -> (Sum Nat
1, []) (Sum Nat, [Nat]) -> (Sum Nat, [Nat]) -> (Sum Nat, [Nat])
forall a. Semigroup a => a -> a -> a
<> MArgList o -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars MArgList o
args
Exp o
_ -> (Sum Nat
0, [])
instance (LocalTerminationEnv a, LocalTerminationEnv b) => LocalTerminationEnv (a, b) where
sizeAndBoundVars :: (a, b) -> (Sum Nat, [Nat])
sizeAndBoundVars (a
a, b
b) = a -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars a
a (Sum Nat, [Nat]) -> (Sum Nat, [Nat]) -> (Sum Nat, [Nat])
forall a. Semigroup a => a -> a -> a
<> b -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars b
b
instance LocalTerminationEnv (MArgList o) where
sizeAndBoundVars :: MArgList o -> (Sum Nat, [Nat])
sizeAndBoundVars MArgList o
as = case Empty -> MArgList o -> ArgList o
forall a b. Empty -> MM a b -> a
rm Empty
forall a. HasCallStack => a
__IMPOSSIBLE__ MArgList o
as of
ArgList o
ALNil -> (Sum Nat
0, [])
ALCons Hiding
_ MExp o
a MArgList o
as -> (MExp o, MArgList o) -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars (MExp o
a, MArgList o
as)
ALProj{} -> (Sum Nat, [Nat])
forall a. HasCallStack => a
__IMPOSSIBLE__
ALConPar MArgList o
as -> MArgList o -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars MArgList o
as
localTerminationEnv :: [CSPat o] -> ([Nat], Nat, [Nat])
localTerminationEnv :: forall o. [CSPat o] -> ([Nat], Nat, [Nat])
localTerminationEnv [CSPat o]
pats = ([Nat]
is, Sum Nat -> Nat
forall a. Sum a -> a
getSum Sum Nat
s, [Nat]
vs) where
([Nat]
is , Sum Nat
s , [Nat]
vs) = Nat -> [CSPat o] -> ([Nat], Sum Nat, [Nat])
forall o. Nat -> [CSPat o] -> ([Nat], Sum Nat, [Nat])
g Nat
0 [CSPat o]
pats
g :: Nat -> [CSPat o] -> ([Nat], Sum Nat, [Nat])
g :: forall o. Nat -> [CSPat o] -> ([Nat], Sum Nat, [Nat])
g Nat
_ [] = ([], Sum Nat
0, [])
g Nat
i (hp :: CSPat o
hp@(HI Hiding
_ CSPatI o
p) : [CSPat o]
ps) = case CSPatI o
p of
CSPatConApp{} -> let (Sum Nat
size, [Nat]
vars) = CSPat o -> (Sum Nat, [Nat])
forall a. LocalTerminationEnv a => a -> (Sum Nat, [Nat])
sizeAndBoundVars CSPat o
hp
in ([Nat
i], Sum Nat
size, [Nat]
vars) ([Nat], Sum Nat, [Nat])
-> ([Nat], Sum Nat, [Nat]) -> ([Nat], Sum Nat, [Nat])
forall a. Semigroup a => a -> a -> a
<> Nat -> [CSPat o] -> ([Nat], Sum Nat, [Nat])
forall o. Nat -> [CSPat o] -> ([Nat], Sum Nat, [Nat])
g (Nat
i Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) [CSPat o]
ps
CSPatI o
_ -> Nat -> [CSPat o] -> ([Nat], Sum Nat, [Nat])
forall o. Nat -> [CSPat o] -> ([Nat], Sum Nat, [Nat])
g (Nat
i Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) [CSPat o]
ps
localTerminationSidecond :: ([Nat], Nat, [Nat]) -> ConstRef o -> MExp o -> EE (MyPB o)
localTerminationSidecond :: forall o.
([Nat], Nat, [Nat]) -> ConstRef o -> MExp o -> EE (MyPB o)
localTerminationSidecond ([Nat]
is, Nat
size, [Nat]
vars) ConstRef o
reccallc MExp o
b =
MExp o -> MetaEnv (PB (RefInfo o))
ok MExp o
b
where
ok :: MExp o -> MetaEnv (PB (RefInfo o))
ok MExp o
e = BlkInfo (RefInfo o)
-> MExp o
-> (Exp o -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o))
forall a blk.
Refinable a blk =>
BlkInfo blk
-> MM a blk -> (a -> MetaEnv (PB blk)) -> MetaEnv (PB blk)
mmpcase (Bool
False, Prio
prioNo, Maybe (RefInfo o)
forall a. Maybe a
Nothing) MExp o
e ((Exp o -> MetaEnv (PB (RefInfo o))) -> MetaEnv (PB (RefInfo o)))
-> (Exp o -> MetaEnv (PB (RefInfo o))) -> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ \Exp o
e -> case Exp o
e of
App Maybe (UId o)
_ OKHandle (RefInfo o)
_ Elr o
elr MArgList o
args -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret (Prop (RefInfo o) -> MetaEnv (PB (RefInfo o)))
-> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ MetaEnv (PB (RefInfo o))
-> MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o)
forall blk. MetaEnv (PB blk) -> MetaEnv (PB blk) -> Prop blk
Sidecondition
(MArgList o -> MetaEnv (PB (RefInfo o))
oks MArgList o
args)
(case Elr o
elr of
Const ConstRef o
c | ConstRef o
c ConstRef o -> ConstRef o -> Bool
forall a. Eq a => a -> a -> Bool
== ConstRef o
reccallc -> if Nat
size Nat -> Nat -> Bool
forall a. Eq a => a -> a -> Bool
== Nat
0 then Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret (String -> Prop (RefInfo o)
forall blk. String -> Prop blk
Error String
"localTerminationSidecond: no size to decrement") else Nat -> Nat -> [Nat] -> MArgList o -> MetaEnv (PB (RefInfo o))
okcall Nat
0 Nat
size [Nat]
vars MArgList o
args
Elr o
_ -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret Prop (RefInfo o)
forall blk. Prop blk
OK
)
Lam Hiding
_ (Abs MId
_ MExp o
e) -> MExp o -> MetaEnv (PB (RefInfo o))
ok MExp o
e
Pi Maybe (UId o)
_ Hiding
_ Bool
_ MExp o
it (Abs MId
_ MExp o
ot) -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret (Prop (RefInfo o) -> MetaEnv (PB (RefInfo o)))
-> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ MetaEnv (PB (RefInfo o))
-> MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o)
forall blk. MetaEnv (PB blk) -> MetaEnv (PB blk) -> Prop blk
Sidecondition
(MExp o -> MetaEnv (PB (RefInfo o))
ok MExp o
it)
(MExp o -> MetaEnv (PB (RefInfo o))
ok MExp o
ot)
Sort{} -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret Prop (RefInfo o)
forall blk. Prop blk
OK
AbsurdLambda{} -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret Prop (RefInfo o)
forall blk. Prop blk
OK
oks :: MArgList o -> MetaEnv (PB (RefInfo o))
oks MArgList o
as = BlkInfo (RefInfo o)
-> MArgList o
-> (ArgList o -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o))
forall a blk.
Refinable a blk =>
BlkInfo blk
-> MM a blk -> (a -> MetaEnv (PB blk)) -> MetaEnv (PB blk)
mmpcase (Bool
False, Prio
prioNo, Maybe (RefInfo o)
forall a. Maybe a
Nothing) MArgList o
as ((ArgList o -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o)))
-> (ArgList o -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ \ArgList o
as -> case ArgList o
as of
ArgList o
ALNil -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret Prop (RefInfo o)
forall blk. Prop blk
OK
ALCons Hiding
_ MExp o
a MArgList o
as -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret (Prop (RefInfo o) -> MetaEnv (PB (RefInfo o)))
-> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ MetaEnv (PB (RefInfo o))
-> MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o)
forall blk. MetaEnv (PB blk) -> MetaEnv (PB blk) -> Prop blk
Sidecondition
(MExp o -> MetaEnv (PB (RefInfo o))
ok MExp o
a)
(MArgList o -> MetaEnv (PB (RefInfo o))
oks MArgList o
as)
ALProj MArgList o
eas MM (ConstRef o) (RefInfo o)
_ Hiding
_ MArgList o
as -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret (Prop (RefInfo o) -> MetaEnv (PB (RefInfo o)))
-> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ MetaEnv (PB (RefInfo o))
-> MetaEnv (PB (RefInfo o)) -> Prop (RefInfo o)
forall blk. MetaEnv (PB blk) -> MetaEnv (PB blk) -> Prop blk
Sidecondition (MArgList o -> MetaEnv (PB (RefInfo o))
oks MArgList o
eas) (MArgList o -> MetaEnv (PB (RefInfo o))
oks MArgList o
as)
ALConPar MArgList o
as -> MArgList o -> MetaEnv (PB (RefInfo o))
oks MArgList o
as
okcall :: Nat -> Nat -> [Nat] -> MArgList o -> MetaEnv (PB (RefInfo o))
okcall Nat
i Nat
size [Nat]
vars MArgList o
as = BlkInfo (RefInfo o)
-> MArgList o
-> (ArgList o -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o))
forall a blk.
Refinable a blk =>
BlkInfo blk
-> MM a blk -> (a -> MetaEnv (PB blk)) -> MetaEnv (PB blk)
mmpcase (Bool
False, Prio
prioNo, Maybe (RefInfo o)
forall a. Maybe a
Nothing) MArgList o
as ((ArgList o -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o)))
-> (ArgList o -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ \ArgList o
as -> case ArgList o
as of
ArgList o
ALNil -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret Prop (RefInfo o)
forall blk. Prop blk
OK
ALCons Hiding
_ MExp o
a MArgList o
as | Nat
i Nat -> [Nat] -> Bool
forall (t :: * -> *) a. (Foldable t, Eq a) => a -> t a -> Bool
`elem` [Nat]
is ->
Prio
-> Maybe (RefInfo o)
-> MetaEnv (MB (Maybe (Nat, [Nat])) (RefInfo o))
-> (Maybe (Nat, [Nat]) -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o))
forall blk a.
Prio
-> Maybe blk
-> MetaEnv (MB a blk)
-> (a -> MetaEnv (PB blk))
-> MetaEnv (PB blk)
mbpcase Prio
prioNo Maybe (RefInfo o)
forall a. Maybe a
Nothing (Nat
-> [Nat] -> MExp o -> MetaEnv (MB (Maybe (Nat, [Nat])) (RefInfo o))
forall {t} {o}.
(Eq t, Num t) =>
t
-> [Nat]
-> MM (Exp o) (RefInfo o)
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
he Nat
size [Nat]
vars MExp o
a) ((Maybe (Nat, [Nat]) -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o)))
-> (Maybe (Nat, [Nat]) -> MetaEnv (PB (RefInfo o)))
-> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ \Maybe (Nat, [Nat])
x -> case Maybe (Nat, [Nat])
x of
Maybe (Nat, [Nat])
Nothing -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret (Prop (RefInfo o) -> MetaEnv (PB (RefInfo o)))
-> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall a b. (a -> b) -> a -> b
$ String -> Prop (RefInfo o)
forall blk. String -> Prop blk
Error String
"localTerminationSidecond: reccall not ok"
Just (Nat
size', [Nat]
vars') -> Nat -> Nat -> [Nat] -> MArgList o -> MetaEnv (PB (RefInfo o))
okcall (Nat
i Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) Nat
size' [Nat]
vars' MArgList o
as
ALCons Hiding
_ MExp o
a MArgList o
as -> Nat -> Nat -> [Nat] -> MArgList o -> MetaEnv (PB (RefInfo o))
okcall (Nat
i Nat -> Nat -> Nat
forall a. Num a => a -> a -> a
+ Nat
1) Nat
size [Nat]
vars MArgList o
as
ALProj{} -> Prop (RefInfo o) -> MetaEnv (PB (RefInfo o))
forall blk. Prop blk -> MetaEnv (PB blk)
mpret Prop (RefInfo o)
forall blk. Prop blk
OK
ALConPar MArgList o
as -> MetaEnv (PB (RefInfo o))
forall a. HasCallStack => a
__IMPOSSIBLE__
he :: t
-> [Nat]
-> MM (Exp o) (RefInfo o)
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
he t
size [Nat]
vars MM (Exp o) (RefInfo o)
e = MM (Exp o) (RefInfo o)
-> (Exp o -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk b.
Refinable a blk =>
MM a blk -> (a -> MetaEnv (MB b blk)) -> MetaEnv (MB b blk)
mmcase MM (Exp o) (RefInfo o)
e ((Exp o -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> (Exp o -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a b. (a -> b) -> a -> b
$ \Exp o
e -> case Exp o
e of
App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Var Nat
v) MArgList o
_ ->
case Nat -> [Nat] -> Maybe [Nat]
forall {t}. Eq t => t -> [t] -> Maybe [t]
remove Nat
v [Nat]
vars of
Maybe [Nat]
Nothing -> Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk. a -> MetaEnv (MB a blk)
mbret Maybe (t, [Nat])
forall a. Maybe a
Nothing
Just [Nat]
vars' -> Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk. a -> MetaEnv (MB a blk)
mbret (Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a b. (a -> b) -> a -> b
$ (t, [Nat]) -> Maybe (t, [Nat])
forall a. a -> Maybe a
Just (t
size, [Nat]
vars')
App Maybe (UId o)
_ OKHandle (RefInfo o)
_ (Const ConstRef o
c) MArgList o
args -> do
ConstDef o
cd <- ConstRef o -> IO (ConstDef o)
forall a. IORef a -> IO a
readIORef ConstRef o
c
case ConstDef o -> DeclCont o
forall o. ConstDef o -> DeclCont o
cdcont ConstDef o
cd of
Constructor{} ->
if t
size t -> t -> Bool
forall a. Eq a => a -> a -> Bool
== t
1 then
Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk. a -> MetaEnv (MB a blk)
mbret Maybe (t, [Nat])
forall a. Maybe a
Nothing
else
t
-> [Nat]
-> MArgList o
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
hes (t
size t -> t -> t
forall a. Num a => a -> a -> a
- t
1) [Nat]
vars MArgList o
args
DeclCont o
_ -> Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk. a -> MetaEnv (MB a blk)
mbret Maybe (t, [Nat])
forall a. Maybe a
Nothing
Exp o
_ -> Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk. a -> MetaEnv (MB a blk)
mbret Maybe (t, [Nat])
forall a. Maybe a
Nothing
hes :: t
-> [Nat]
-> MArgList o
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
hes t
size [Nat]
vars MArgList o
as = MArgList o
-> (ArgList o -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk b.
Refinable a blk =>
MM a blk -> (a -> MetaEnv (MB b blk)) -> MetaEnv (MB b blk)
mmcase MArgList o
as ((ArgList o -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> (ArgList o -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a b. (a -> b) -> a -> b
$ \ArgList o
as -> case ArgList o
as of
ArgList o
ALNil -> Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk. a -> MetaEnv (MB a blk)
mbret (Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a b. (a -> b) -> a -> b
$ (t, [Nat]) -> Maybe (t, [Nat])
forall a. a -> Maybe a
Just (t
size, [Nat]
vars)
ALCons Hiding
_ MM (Exp o) (RefInfo o)
a MArgList o
as ->
MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
-> (Maybe (t, [Nat])
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk b.
MetaEnv (MB a blk)
-> (a -> MetaEnv (MB b blk)) -> MetaEnv (MB b blk)
mbcase (t
-> [Nat]
-> MM (Exp o) (RefInfo o)
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
he t
size [Nat]
vars MM (Exp o) (RefInfo o)
a) ((Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> (Maybe (t, [Nat])
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o)))
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a b. (a -> b) -> a -> b
$ \Maybe (t, [Nat])
x -> case Maybe (t, [Nat])
x of
Maybe (t, [Nat])
Nothing -> Maybe (t, [Nat]) -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a blk. a -> MetaEnv (MB a blk)
mbret Maybe (t, [Nat])
forall a. Maybe a
Nothing
Just (t
size', [Nat]
vars') -> t
-> [Nat]
-> MArgList o
-> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
hes t
size' [Nat]
vars' MArgList o
as
ALProj{} -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a. HasCallStack => a
__IMPOSSIBLE__
ALConPar MArgList o
as -> MetaEnv (MB (Maybe (t, [Nat])) (RefInfo o))
forall a. HasCallStack => a
__IMPOSSIBLE__
remove :: t -> [t] -> Maybe [t]
remove t
_ [] = Maybe [t]
forall a. Maybe a
Nothing
remove t
x (t
y : [t]
ys) | t
x t -> t -> Bool
forall a. Eq a => a -> a -> Bool
== t
y = [t] -> Maybe [t]
forall a. a -> Maybe a
Just [t]
ys
remove t
x (t
y : [t]
ys) = case t -> [t] -> Maybe [t]
remove t
x [t]
ys of {Maybe [t]
Nothing -> Maybe [t]
forall a. Maybe a
Nothing; Just [t]
ys' -> [t] -> Maybe [t]
forall a. a -> Maybe a
Just (t
y t -> [t] -> [t]
forall a. a -> [a] -> [a]
: [t]
ys')}
getblks :: MExp o -> IO [Nat]
getblks :: forall o. MExp o -> IO [Nat]
getblks MExp o
tt = do
NotB (HNExp o
hntt, HNNBlks o
blks) <- ICExp o -> EE (MB (HNExp o, HNNBlks o) (RefInfo o))
forall o. ICExp o -> EE (MyMB (HNExp o, HNNBlks o) o)
hnn_blks ([CAction o] -> MExp o -> ICExp o
forall a o. [CAction o] -> a -> Clos a o
Clos [] MExp o
tt)
case HNNBlks o -> Maybe Nat
forall {o} {o}. [WithSeenUIds (HNExp' o) o] -> Maybe Nat
f HNNBlks o
blks of
Just Nat
v -> [Nat] -> IO [Nat]
forall (m :: * -> *) a. Monad m => a -> m a
return [Nat
v]
Maybe Nat
Nothing -> case HNExp o -> HNExp' o
forall a o. WithSeenUIds a o -> a
rawValue HNExp o
hntt of
HNApp (Const ConstRef o
c) ICArgList o
args -> do
ConstDef o
cd <- ConstRef o -> IO (ConstDef o)
forall a. IORef a -> IO a
readIORef ConstRef o
c
case ConstDef o -> DeclCont o
forall o. ConstDef o -> DeclCont o
cdcont ConstDef o
cd of
Datatype{} -> [Nat] -> ICArgList o -> IO [Nat]
forall {o}. [Nat] -> ICArgList o -> IO [Nat]
g [] ICArgList o
args
DeclCont o
_ -> [Nat] -> IO [Nat]
forall (m :: * -> *) a. Monad m => a -> m a
return []
HNExp' o
_ -> [Nat] -> IO [Nat]
forall (m :: * -> *) a. Monad m => a -> m a
return []
where
f :: [WithSeenUIds (HNExp' o) o] -> Maybe Nat
f [WithSeenUIds (HNExp' o) o]
blks = case [WithSeenUIds (HNExp' o) o]
blks of
(WithSeenUIds (HNExp' o) o
b : [WithSeenUIds (HNExp' o) o]
bs) -> case WithSeenUIds (HNExp' o) o -> HNExp' o
forall a o. WithSeenUIds a o -> a
rawValue (WithSeenUIds (HNExp' o) o
-> [WithSeenUIds (HNExp' o) o] -> WithSeenUIds (HNExp' o) o
forall a. a -> [a] -> a
last1 WithSeenUIds (HNExp' o) o
b [WithSeenUIds (HNExp' o) o]
bs) of
HNApp (Var Nat
v) ICArgList o
_ -> Nat -> Maybe Nat
forall a. a -> Maybe a
Just Nat
v
HNExp' o
_ -> Maybe Nat
forall a. Maybe a
Nothing
[WithSeenUIds (HNExp' o) o]
_ -> Maybe Nat
forall a. Maybe a
Nothing
g :: [Nat] -> ICArgList o -> IO [Nat]
g [Nat]
vs ICArgList o
args = do
NotB HNArgList o
hnargs <- ICArgList o -> EE (MB (HNArgList o) (RefInfo o))
forall o. ICArgList o -> EE (MyMB (HNArgList o) o)
hnarglist ICArgList o
args
case HNArgList o
hnargs of
HNALCons Hiding
_ ICExp o
a ICArgList o
as -> do
NotB (HNExp o
_, HNNBlks o
blks) <- ICExp o -> EE (MB (HNExp o, HNNBlks o) (RefInfo o))
forall o. ICExp o -> EE (MyMB (HNExp o, HNNBlks o) o)
hnn_blks ICExp o
a
let vs' :: [Nat]
vs' = case HNNBlks o -> Maybe Nat
forall {o} {o}. [WithSeenUIds (HNExp' o) o] -> Maybe Nat
f HNNBlks o
blks of
Just Nat
v | Nat
v Nat -> [Nat] -> Bool
forall (t :: * -> *) a. (Foldable t, Eq a) => a -> t a -> Bool
`notElem` [Nat]
vs -> Nat
v Nat -> [Nat] -> [Nat]
forall a. a -> [a] -> [a]
: [Nat]
vs
Maybe Nat
_ -> [Nat]
vs
[Nat] -> ICArgList o -> IO [Nat]
g [Nat]
vs' ICArgList o
as
HNArgList o
_ -> [Nat] -> IO [Nat]
forall (m :: * -> *) a. Monad m => a -> m a
return [Nat]
vs