{-# LANGUAGE CPP #-}
{-# LANGUAGE LambdaCase #-}
{-# LANGUAGE OverloadedStrings #-}
{-# LANGUAGE RecordWildCards #-}
module Clash.Normalize.Util
( ConstantSpecInfo(..)
, isConstantArg
, shouldReduce
, alreadyInlined
, addNewInline
, specializeNorm
, isRecursiveBndr
, isClosed
, callGraph
, collectCallGraphUniques
, classifyFunction
, isCheapFunction
, isNonRecursiveGlobalVar
, constantSpecInfo
, normalizeTopLvlBndr
, rewriteExpr
, removedTm
, mkInlineTick
, substWithTyEq
, tvSubstWithTyEq
)
where
import Control.Lens ((&),(+~),(%=),(.=))
import qualified Control.Lens as Lens
import Data.Bifunctor (bimap)
import Data.Either (lefts)
import qualified Data.List as List
import qualified Data.List.Extra as List
import qualified Data.Map as Map
import qualified Data.HashMap.Strict as HashMapS
import qualified Data.HashSet as HashSet
import Data.Text (Text)
import qualified Data.Text as Text
#if MIN_VERSION_ghc(9,0,0)
import GHC.Builtin.Names (eqTyConKey)
import GHC.Types.Unique (getKey)
#else
import PrelNames (eqTyConKey)
import Unique (getKey)
#endif
import Clash.Annotations.Primitive (extractPrim)
import Clash.Core.FreeVars
(globalIds, hasLocalFreeVars, globalIdOccursIn)
import Clash.Core.Name (Name(nameOcc,nameUniq))
import Clash.Core.Pretty (showPpr)
import Clash.Core.Subst
(deShadowTerm, extendTvSubst, extendTvSubstList, mkSubst, substTm, substTy,
substId, extendIdSubst)
import Clash.Core.Term
import Clash.Core.TermInfo (isPolyFun, termType)
import Clash.Core.TyCon (TyConMap)
import Clash.Core.Type
(Type(LitTy, VarTy), LitTy(SymTy), TypeView (..), tyView, undefinedTy,
splitFunForallTy, splitTyConAppM, mkPolyFunTy)
import Clash.Core.Util
(isClockOrReset)
import Clash.Core.Var (Id, TyVar, Var (..), isGlobalId)
import Clash.Core.VarEnv
(VarEnv, emptyInScopeSet, emptyVarEnv, extendVarEnv, extendVarEnvWith,
lookupVarEnv, unionVarEnvWith, unitVarEnv, extendInScopeSetList)
import Clash.Debug (traceIf)
import Clash.Driver.Types (BindingMap, Binding(..), DebugLevel (..))
import {-# SOURCE #-} Clash.Normalize.Strategy (normalization)
import Clash.Normalize.Types
import Clash.Primitives.Util (constantArgs)
import Clash.Rewrite.Types
(RewriteMonad, TransformContext(..), bindings, curFun, dbgLevel, extra,
tcCache)
import Clash.Rewrite.Util
(runRewrite, specialise, mkTmBinderFor, mkDerivedName)
import Clash.Unique
import Clash.Util (SrcSpan, makeCachedU)
isConstantArg
:: Text
-> Int
-> RewriteMonad NormalizeState Bool
isConstantArg :: Text -> Int -> RewriteMonad NormalizeState Bool
isConstantArg Text
"Clash.Explicit.SimIO.mealyIO" Int
i = Bool -> RewriteMonad NormalizeState Bool
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (Int
i Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
2 Bool -> Bool -> Bool
|| Int
i Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
3)
isConstantArg Text
nm Int
i = do
Map Text (Set Int)
argMap <- Getting
(Map Text (Set Int))
(RewriteState NormalizeState)
(Map Text (Set Int))
-> RewriteMonad NormalizeState (Map Text (Set Int))
forall s (m :: Type -> Type) a.
MonadState s m =>
Getting a s a -> m a
Lens.use ((NormalizeState -> Const (Map Text (Set Int)) NormalizeState)
-> RewriteState NormalizeState
-> Const (Map Text (Set Int)) (RewriteState NormalizeState)
forall extra1 extra2.
Lens (RewriteState extra1) (RewriteState extra2) extra1 extra2
extra((NormalizeState -> Const (Map Text (Set Int)) NormalizeState)
-> RewriteState NormalizeState
-> Const (Map Text (Set Int)) (RewriteState NormalizeState))
-> ((Map Text (Set Int)
-> Const (Map Text (Set Int)) (Map Text (Set Int)))
-> NormalizeState -> Const (Map Text (Set Int)) NormalizeState)
-> Getting
(Map Text (Set Int))
(RewriteState NormalizeState)
(Map Text (Set Int))
forall b c a. (b -> c) -> (a -> b) -> a -> c
.(Map Text (Set Int)
-> Const (Map Text (Set Int)) (Map Text (Set Int)))
-> NormalizeState -> Const (Map Text (Set Int)) NormalizeState
Lens' NormalizeState (Map Text (Set Int))
primitiveArgs)
case Text -> Map Text (Set Int) -> Maybe (Set Int)
forall k a. Ord k => k -> Map k a -> Maybe a
Map.lookup Text
nm Map Text (Set Int)
argMap of
Maybe (Set Int)
Nothing -> do
CompiledPrimMap
prims <- Getting
CompiledPrimMap (RewriteState NormalizeState) CompiledPrimMap
-> RewriteMonad NormalizeState CompiledPrimMap
forall s (m :: Type -> Type) a.
MonadState s m =>
Getting a s a -> m a
Lens.use ((NormalizeState -> Const CompiledPrimMap NormalizeState)
-> RewriteState NormalizeState
-> Const CompiledPrimMap (RewriteState NormalizeState)
forall extra1 extra2.
Lens (RewriteState extra1) (RewriteState extra2) extra1 extra2
extra((NormalizeState -> Const CompiledPrimMap NormalizeState)
-> RewriteState NormalizeState
-> Const CompiledPrimMap (RewriteState NormalizeState))
-> ((CompiledPrimMap -> Const CompiledPrimMap CompiledPrimMap)
-> NormalizeState -> Const CompiledPrimMap NormalizeState)
-> Getting
CompiledPrimMap (RewriteState NormalizeState) CompiledPrimMap
forall b c a. (b -> c) -> (a -> b) -> a -> c
.(CompiledPrimMap -> Const CompiledPrimMap CompiledPrimMap)
-> NormalizeState -> Const CompiledPrimMap NormalizeState
Lens' NormalizeState CompiledPrimMap
primitives)
case PrimitiveGuard CompiledPrimitive -> Maybe CompiledPrimitive
forall a. PrimitiveGuard a -> Maybe a
extractPrim (PrimitiveGuard CompiledPrimitive -> Maybe CompiledPrimitive)
-> Maybe (PrimitiveGuard CompiledPrimitive)
-> Maybe CompiledPrimitive
forall (m :: Type -> Type) a b. Monad m => (a -> m b) -> m a -> m b
=<< Text -> CompiledPrimMap -> Maybe (PrimitiveGuard CompiledPrimitive)
forall k v. (Eq k, Hashable k) => k -> HashMap k v -> Maybe v
HashMapS.lookup Text
nm CompiledPrimMap
prims of
Maybe CompiledPrimitive
Nothing ->
Bool -> RewriteMonad NormalizeState Bool
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure Bool
False
Just CompiledPrimitive
p -> do
let m :: Set Int
m = Text -> CompiledPrimitive -> Set Int
constantArgs Text
nm CompiledPrimitive
p
((NormalizeState -> Identity NormalizeState)
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState)
forall extra1 extra2.
Lens (RewriteState extra1) (RewriteState extra2) extra1 extra2
extra((NormalizeState -> Identity NormalizeState)
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState))
-> ((Map Text (Set Int) -> Identity (Map Text (Set Int)))
-> NormalizeState -> Identity NormalizeState)
-> (Map Text (Set Int) -> Identity (Map Text (Set Int)))
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState)
forall b c a. (b -> c) -> (a -> b) -> a -> c
.(Map Text (Set Int) -> Identity (Map Text (Set Int)))
-> NormalizeState -> Identity NormalizeState
Lens' NormalizeState (Map Text (Set Int))
primitiveArgs) ((Map Text (Set Int) -> Identity (Map Text (Set Int)))
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState))
-> (Map Text (Set Int) -> Map Text (Set Int))
-> RewriteMonad NormalizeState ()
forall s (m :: Type -> Type) a b.
MonadState s m =>
ASetter s s a b -> (a -> b) -> m ()
Lens.%= Text -> Set Int -> Map Text (Set Int) -> Map Text (Set Int)
forall k a. Ord k => k -> a -> Map k a -> Map k a
Map.insert Text
nm Set Int
m
Bool -> RewriteMonad NormalizeState Bool
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (Int
i Int -> Set Int -> Bool
forall (t :: Type -> Type) a.
(Foldable t, Eq a) =>
a -> t a -> Bool
`elem` Set Int
m)
Just Set Int
m ->
Bool -> RewriteMonad NormalizeState Bool
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (Int
i Int -> Set Int -> Bool
forall (t :: Type -> Type) a.
(Foldable t, Eq a) =>
a -> t a -> Bool
`elem` Set Int
m)
shouldReduce
:: Context
-> RewriteMonad NormalizeState Bool
shouldReduce :: Context -> RewriteMonad NormalizeState Bool
shouldReduce = (CoreContext -> RewriteMonad NormalizeState Bool)
-> Context -> RewriteMonad NormalizeState Bool
forall (m :: Type -> Type) a.
Monad m =>
(a -> m Bool) -> [a] -> m Bool
List.anyM CoreContext -> RewriteMonad NormalizeState Bool
isConstantArg'
where
isConstantArg' :: CoreContext -> RewriteMonad NormalizeState Bool
isConstantArg' (AppArg (Just (Text
nm, Int
_, Int
i))) = Text -> Int -> RewriteMonad NormalizeState Bool
isConstantArg Text
nm Int
i
isConstantArg' CoreContext
_ = Bool -> RewriteMonad NormalizeState Bool
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure Bool
False
alreadyInlined
:: Id
-> Id
-> NormalizeMonad (Maybe Int)
alreadyInlined :: Id -> Id -> NormalizeMonad (Maybe Int)
alreadyInlined Id
f Id
cf = do
VarEnv (VarEnv Int)
inlinedHM <- Getting (VarEnv (VarEnv Int)) NormalizeState (VarEnv (VarEnv Int))
-> StateT NormalizeState Identity (VarEnv (VarEnv Int))
forall s (m :: Type -> Type) a.
MonadState s m =>
Getting a s a -> m a
Lens.use Getting (VarEnv (VarEnv Int)) NormalizeState (VarEnv (VarEnv Int))
Lens' NormalizeState (VarEnv (VarEnv Int))
inlineHistory
case Id -> VarEnv (VarEnv Int) -> Maybe (VarEnv Int)
forall b a. Var b -> VarEnv a -> Maybe a
lookupVarEnv Id
cf VarEnv (VarEnv Int)
inlinedHM of
Maybe (VarEnv Int)
Nothing -> Maybe Int -> NormalizeMonad (Maybe Int)
forall (m :: Type -> Type) a. Monad m => a -> m a
return Maybe Int
forall a. Maybe a
Nothing
Just VarEnv Int
inlined' -> Maybe Int -> NormalizeMonad (Maybe Int)
forall (m :: Type -> Type) a. Monad m => a -> m a
return (Id -> VarEnv Int -> Maybe Int
forall b a. Var b -> VarEnv a -> Maybe a
lookupVarEnv Id
f VarEnv Int
inlined')
addNewInline
:: Id
-> Id
-> NormalizeMonad ()
addNewInline :: Id -> Id -> NormalizeMonad ()
addNewInline Id
f Id
cf =
(VarEnv (VarEnv Int) -> Identity (VarEnv (VarEnv Int)))
-> NormalizeState -> Identity NormalizeState
Lens' NormalizeState (VarEnv (VarEnv Int))
inlineHistory ((VarEnv (VarEnv Int) -> Identity (VarEnv (VarEnv Int)))
-> NormalizeState -> Identity NormalizeState)
-> (VarEnv (VarEnv Int) -> VarEnv (VarEnv Int))
-> NormalizeMonad ()
forall s (m :: Type -> Type) a b.
MonadState s m =>
ASetter s s a b -> (a -> b) -> m ()
%= Id
-> VarEnv Int
-> (VarEnv Int -> VarEnv Int -> VarEnv Int)
-> VarEnv (VarEnv Int)
-> VarEnv (VarEnv Int)
forall b a. Var b -> a -> (a -> a -> a) -> VarEnv a -> VarEnv a
extendVarEnvWith
Id
cf
(Id -> Int -> VarEnv Int
forall b a. Var b -> a -> VarEnv a
unitVarEnv Id
f Int
1)
(\VarEnv Int
_ VarEnv Int
hm -> Id -> Int -> (Int -> Int -> Int) -> VarEnv Int -> VarEnv Int
forall b a. Var b -> a -> (a -> a -> a) -> VarEnv a -> VarEnv a
extendVarEnvWith Id
f Int
1 Int -> Int -> Int
forall a. Num a => a -> a -> a
(+) VarEnv Int
hm)
specializeNorm :: NormRewrite
specializeNorm :: NormRewrite
specializeNorm = Lens' NormalizeState (Map (Id, Int, Either Term Type) Id)
-> Lens' NormalizeState (VarEnv Int)
-> Lens' NormalizeState Int
-> NormRewrite
forall extra.
Lens' extra (Map (Id, Int, Either Term Type) Id)
-> Lens' extra (VarEnv Int) -> Lens' extra Int -> Rewrite extra
specialise Lens' NormalizeState (Map (Id, Int, Either Term Type) Id)
specialisationCache Lens' NormalizeState (VarEnv Int)
specialisationHistory Lens' NormalizeState Int
specialisationLimit
isClosed :: TyConMap
-> Term
-> Bool
isClosed :: TyConMap -> Term -> Bool
isClosed TyConMap
tcm = Bool -> Bool
not (Bool -> Bool) -> (Term -> Bool) -> Term -> Bool
forall b c a. (b -> c) -> (a -> b) -> a -> c
. TyConMap -> Term -> Bool
isPolyFun TyConMap
tcm
isNonRecursiveGlobalVar
:: Term
-> NormalizeSession Bool
isNonRecursiveGlobalVar :: Term -> RewriteMonad NormalizeState Bool
isNonRecursiveGlobalVar (Term -> (Term, [Either Term Type])
collectArgs -> (Var Id
i, [Either Term Type]
_args)) = do
let eIsGlobal :: Bool
eIsGlobal = Id -> Bool
forall a. Var a -> Bool
isGlobalId Id
i
Bool
eIsRec <- Id -> RewriteMonad NormalizeState Bool
isRecursiveBndr Id
i
Bool -> RewriteMonad NormalizeState Bool
forall (m :: Type -> Type) a. Monad m => a -> m a
return (Bool
eIsGlobal Bool -> Bool -> Bool
&& Bool -> Bool
not Bool
eIsRec)
isNonRecursiveGlobalVar Term
_ = Bool -> RewriteMonad NormalizeState Bool
forall (m :: Type -> Type) a. Monad m => a -> m a
return Bool
False
isRecursiveBndr
:: Id
-> NormalizeSession Bool
isRecursiveBndr :: Id -> RewriteMonad NormalizeState Bool
isRecursiveBndr Id
f = do
VarEnv Bool
cg <- Getting (VarEnv Bool) (RewriteState NormalizeState) (VarEnv Bool)
-> RewriteMonad NormalizeState (VarEnv Bool)
forall s (m :: Type -> Type) a.
MonadState s m =>
Getting a s a -> m a
Lens.use ((NormalizeState -> Const (VarEnv Bool) NormalizeState)
-> RewriteState NormalizeState
-> Const (VarEnv Bool) (RewriteState NormalizeState)
forall extra1 extra2.
Lens (RewriteState extra1) (RewriteState extra2) extra1 extra2
extra((NormalizeState -> Const (VarEnv Bool) NormalizeState)
-> RewriteState NormalizeState
-> Const (VarEnv Bool) (RewriteState NormalizeState))
-> ((VarEnv Bool -> Const (VarEnv Bool) (VarEnv Bool))
-> NormalizeState -> Const (VarEnv Bool) NormalizeState)
-> Getting
(VarEnv Bool) (RewriteState NormalizeState) (VarEnv Bool)
forall b c a. (b -> c) -> (a -> b) -> a -> c
.(VarEnv Bool -> Const (VarEnv Bool) (VarEnv Bool))
-> NormalizeState -> Const (VarEnv Bool) NormalizeState
Lens' NormalizeState (VarEnv Bool)
recursiveComponents)
case Id -> VarEnv Bool -> Maybe Bool
forall b a. Var b -> VarEnv a -> Maybe a
lookupVarEnv Id
f VarEnv Bool
cg of
Just Bool
isR -> Bool -> RewriteMonad NormalizeState Bool
forall (m :: Type -> Type) a. Monad m => a -> m a
return Bool
isR
Maybe Bool
Nothing -> do
Maybe (Binding Term)
fBodyM <- Id -> VarEnv (Binding Term) -> Maybe (Binding Term)
forall b a. Var b -> VarEnv a -> Maybe a
lookupVarEnv Id
f (VarEnv (Binding Term) -> Maybe (Binding Term))
-> RewriteMonad NormalizeState (VarEnv (Binding Term))
-> RewriteMonad NormalizeState (Maybe (Binding Term))
forall (f :: Type -> Type) a b. Functor f => (a -> b) -> f a -> f b
<$> Getting
(VarEnv (Binding Term))
(RewriteState NormalizeState)
(VarEnv (Binding Term))
-> RewriteMonad NormalizeState (VarEnv (Binding Term))
forall s (m :: Type -> Type) a.
MonadState s m =>
Getting a s a -> m a
Lens.use Getting
(VarEnv (Binding Term))
(RewriteState NormalizeState)
(VarEnv (Binding Term))
forall extra1. Lens' (RewriteState extra1) (VarEnv (Binding Term))
bindings
case Maybe (Binding Term)
fBodyM of
Maybe (Binding Term)
Nothing -> Bool -> RewriteMonad NormalizeState Bool
forall (m :: Type -> Type) a. Monad m => a -> m a
return Bool
False
Just Binding Term
b -> do
let isR :: Bool
isR = Id
f Id -> Term -> Bool
`globalIdOccursIn` Binding Term -> Term
forall a. Binding a -> a
bindingTerm Binding Term
b
((NormalizeState -> Identity NormalizeState)
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState)
forall extra1 extra2.
Lens (RewriteState extra1) (RewriteState extra2) extra1 extra2
extra((NormalizeState -> Identity NormalizeState)
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState))
-> ((VarEnv Bool -> Identity (VarEnv Bool))
-> NormalizeState -> Identity NormalizeState)
-> (VarEnv Bool -> Identity (VarEnv Bool))
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState)
forall b c a. (b -> c) -> (a -> b) -> a -> c
.(VarEnv Bool -> Identity (VarEnv Bool))
-> NormalizeState -> Identity NormalizeState
Lens' NormalizeState (VarEnv Bool)
recursiveComponents) ((VarEnv Bool -> Identity (VarEnv Bool))
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState))
-> (VarEnv Bool -> VarEnv Bool) -> RewriteMonad NormalizeState ()
forall s (m :: Type -> Type) a b.
MonadState s m =>
ASetter s s a b -> (a -> b) -> m ()
%= Id -> Bool -> VarEnv Bool -> VarEnv Bool
forall b a. Var b -> a -> VarEnv a -> VarEnv a
extendVarEnv Id
f Bool
isR
Bool -> RewriteMonad NormalizeState Bool
forall (m :: Type -> Type) a. Monad m => a -> m a
return Bool
isR
data ConstantSpecInfo =
ConstantSpecInfo
{ ConstantSpecInfo -> [(Id, Term)]
csrNewBindings :: [(Id, Term)]
, ConstantSpecInfo -> Term
csrNewTerm :: !Term
, ConstantSpecInfo -> Bool
csrFoundConstant :: !Bool
} deriving (Int -> ConstantSpecInfo -> ShowS
[ConstantSpecInfo] -> ShowS
ConstantSpecInfo -> String
(Int -> ConstantSpecInfo -> ShowS)
-> (ConstantSpecInfo -> String)
-> ([ConstantSpecInfo] -> ShowS)
-> Show ConstantSpecInfo
forall a.
(Int -> a -> ShowS) -> (a -> String) -> ([a] -> ShowS) -> Show a
showList :: [ConstantSpecInfo] -> ShowS
$cshowList :: [ConstantSpecInfo] -> ShowS
show :: ConstantSpecInfo -> String
$cshow :: ConstantSpecInfo -> String
showsPrec :: Int -> ConstantSpecInfo -> ShowS
$cshowsPrec :: Int -> ConstantSpecInfo -> ShowS
Show)
constantCsr :: Term -> ConstantSpecInfo
constantCsr :: Term -> ConstantSpecInfo
constantCsr Term
t = [(Id, Term)] -> Term -> Bool -> ConstantSpecInfo
ConstantSpecInfo [] Term
t Bool
True
bindCsr
:: TransformContext
-> Term
-> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr :: TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr ctx :: TransformContext
ctx@(TransformContext InScopeSet
is0 Context
_) Term
oldTerm = do
TyConMap
tcm <- Getting TyConMap RewriteEnv TyConMap
-> RewriteMonad NormalizeState TyConMap
forall s (m :: Type -> Type) a.
MonadReader s m =>
Getting a s a -> m a
Lens.view Getting TyConMap RewriteEnv TyConMap
Lens' RewriteEnv TyConMap
tcCache
Id
newId <- InScopeSet
-> TyConMap -> Name Term -> Term -> RewriteMonad NormalizeState Id
forall (m :: Type -> Type) a.
(MonadUnique m, MonadFail m) =>
InScopeSet -> TyConMap -> Name a -> Term -> m Id
mkTmBinderFor InScopeSet
is0 TyConMap
tcm (TransformContext -> Text -> Name Term
mkDerivedName TransformContext
ctx Text
"bindCsr") Term
oldTerm
ConstantSpecInfo -> RewriteMonad NormalizeState ConstantSpecInfo
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (ConstantSpecInfo :: [(Id, Term)] -> Term -> Bool -> ConstantSpecInfo
ConstantSpecInfo
{ csrNewBindings :: [(Id, Term)]
csrNewBindings = [(Id
newId, Term
oldTerm)]
, csrNewTerm :: Term
csrNewTerm = Id -> Term
Var Id
newId
, csrFoundConstant :: Bool
csrFoundConstant = Bool
False
})
mergeCsrs
:: TransformContext
-> [TickInfo]
-> Term
-> ([Either Term Type] -> Term)
-> [Either Term Type]
-> RewriteMonad NormalizeState ConstantSpecInfo
mergeCsrs :: TransformContext
-> [TickInfo]
-> Term
-> ([Either Term Type] -> Term)
-> [Either Term Type]
-> RewriteMonad NormalizeState ConstantSpecInfo
mergeCsrs TransformContext
ctx [TickInfo]
ticks Term
oldTerm [Either Term Type] -> Term
proposedTerm [Either Term Type]
subTerms = do
[Either ConstantSpecInfo Type]
subCsrs <- (TransformContext, [Either ConstantSpecInfo Type])
-> [Either ConstantSpecInfo Type]
forall a b. (a, b) -> b
snd ((TransformContext, [Either ConstantSpecInfo Type])
-> [Either ConstantSpecInfo Type])
-> RewriteMonad
NormalizeState (TransformContext, [Either ConstantSpecInfo Type])
-> RewriteMonad NormalizeState [Either ConstantSpecInfo Type]
forall (f :: Type -> Type) a b. Functor f => (a -> b) -> f a -> f b
<$> (TransformContext
-> Either Term Type
-> RewriteMonad
NormalizeState (TransformContext, Either ConstantSpecInfo Type))
-> TransformContext
-> [Either Term Type]
-> RewriteMonad
NormalizeState (TransformContext, [Either ConstantSpecInfo Type])
forall (m :: Type -> Type) acc x y.
Monad m =>
(acc -> x -> m (acc, y)) -> acc -> [x] -> m (acc, [y])
List.mapAccumLM TransformContext
-> Either Term Type
-> RewriteMonad
NormalizeState (TransformContext, Either ConstantSpecInfo Type)
constantSpecInfoFolder TransformContext
ctx [Either Term Type]
subTerms
let
anyArgsOrResultConstant :: Bool
anyArgsOrResultConstant =
[ConstantSpecInfo] -> Bool
forall (t :: Type -> Type) a. Foldable t => t a -> Bool
null ([Either ConstantSpecInfo Type] -> [ConstantSpecInfo]
forall a b. [Either a b] -> [a]
lefts [Either ConstantSpecInfo Type]
subCsrs) Bool -> Bool -> Bool
|| (ConstantSpecInfo -> Bool) -> [ConstantSpecInfo] -> Bool
forall (t :: Type -> Type) a.
Foldable t =>
(a -> Bool) -> t a -> Bool
any ConstantSpecInfo -> Bool
csrFoundConstant ([Either ConstantSpecInfo Type] -> [ConstantSpecInfo]
forall a b. [Either a b] -> [a]
lefts [Either ConstantSpecInfo Type]
subCsrs)
if Bool
anyArgsOrResultConstant then
let newTerm :: Term
newTerm = [Either Term Type] -> Term
proposedTerm ((ConstantSpecInfo -> Term)
-> (Type -> Type)
-> Either ConstantSpecInfo Type
-> Either Term Type
forall (p :: Type -> Type -> Type) a b c d.
Bifunctor p =>
(a -> b) -> (c -> d) -> p a c -> p b d
bimap ConstantSpecInfo -> Term
csrNewTerm Type -> Type
forall a. a -> a
id (Either ConstantSpecInfo Type -> Either Term Type)
-> [Either ConstantSpecInfo Type] -> [Either Term Type]
forall (f :: Type -> Type) a b. Functor f => (a -> b) -> f a -> f b
<$> [Either ConstantSpecInfo Type]
subCsrs) in
ConstantSpecInfo -> RewriteMonad NormalizeState ConstantSpecInfo
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (ConstantSpecInfo :: [(Id, Term)] -> Term -> Bool -> ConstantSpecInfo
ConstantSpecInfo
{ csrNewBindings :: [(Id, Term)]
csrNewBindings = (ConstantSpecInfo -> [(Id, Term)])
-> [ConstantSpecInfo] -> [(Id, Term)]
forall (t :: Type -> Type) a b.
Foldable t =>
(a -> [b]) -> t a -> [b]
concatMap ConstantSpecInfo -> [(Id, Term)]
csrNewBindings ([Either ConstantSpecInfo Type] -> [ConstantSpecInfo]
forall a b. [Either a b] -> [a]
lefts [Either ConstantSpecInfo Type]
subCsrs)
, csrNewTerm :: Term
csrNewTerm = Term -> [TickInfo] -> Term
mkTicks Term
newTerm [TickInfo]
ticks
, csrFoundConstant :: Bool
csrFoundConstant = Bool
True
})
else do
TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr TransformContext
ctx Term
oldTerm
where
constantSpecInfoFolder
:: TransformContext
-> Either Term Type
-> RewriteMonad NormalizeState (TransformContext, Either ConstantSpecInfo Type)
constantSpecInfoFolder :: TransformContext
-> Either Term Type
-> RewriteMonad
NormalizeState (TransformContext, Either ConstantSpecInfo Type)
constantSpecInfoFolder TransformContext
localCtx (Right Type
typ) =
(TransformContext, Either ConstantSpecInfo Type)
-> RewriteMonad
NormalizeState (TransformContext, Either ConstantSpecInfo Type)
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (TransformContext
localCtx, Type -> Either ConstantSpecInfo Type
forall a b. b -> Either a b
Right Type
typ)
constantSpecInfoFolder localCtx :: TransformContext
localCtx@(TransformContext InScopeSet
is0 Context
tfCtx) (Left Term
term) = do
ConstantSpecInfo
specInfo <- TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
constantSpecInfo TransformContext
localCtx Term
term
let newIds :: [Id]
newIds = ((Id, Term) -> Id) -> [(Id, Term)] -> [Id]
forall a b. (a -> b) -> [a] -> [b]
map (Id, Term) -> Id
forall a b. (a, b) -> a
fst (ConstantSpecInfo -> [(Id, Term)]
csrNewBindings ConstantSpecInfo
specInfo)
let is1 :: InScopeSet
is1 = InScopeSet -> [Id] -> InScopeSet
forall a. InScopeSet -> [Var a] -> InScopeSet
extendInScopeSetList InScopeSet
is0 [Id]
newIds
(TransformContext, Either ConstantSpecInfo Type)
-> RewriteMonad
NormalizeState (TransformContext, Either ConstantSpecInfo Type)
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (InScopeSet -> Context -> TransformContext
TransformContext InScopeSet
is1 Context
tfCtx, ConstantSpecInfo -> Either ConstantSpecInfo Type
forall a b. a -> Either a b
Left ConstantSpecInfo
specInfo)
constantSpecInfo
:: TransformContext
-> Term
-> RewriteMonad NormalizeState ConstantSpecInfo
constantSpecInfo :: TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
constantSpecInfo TransformContext
ctx Term
e = do
TyConMap
tcm <- Getting TyConMap RewriteEnv TyConMap
-> RewriteMonad NormalizeState TyConMap
forall s (m :: Type -> Type) a.
MonadReader s m =>
Getting a s a -> m a
Lens.view Getting TyConMap RewriteEnv TyConMap
Lens' RewriteEnv TyConMap
tcCache
if TyConMap -> Type -> Bool
isClockOrReset TyConMap
tcm (TyConMap -> Term -> Type
termType TyConMap
tcm Term
e) then
case Term -> (Term, [Either Term Type])
collectArgs Term
e of
(Prim PrimInfo
p, [Either Term Type]
_)
| PrimInfo -> Text
primName PrimInfo
p Text -> Text -> Bool
forall a. Eq a => a -> a -> Bool
== Text
"Clash.Transformations.removedArg" ->
ConstantSpecInfo -> RewriteMonad NormalizeState ConstantSpecInfo
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (Term -> ConstantSpecInfo
constantCsr Term
e)
(Term, [Either Term Type])
_ -> TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr TransformContext
ctx Term
e
else
case Term -> (Term, [Either Term Type], [TickInfo])
collectArgsTicks Term
e of
(dc :: Term
dc@(Data DataCon
_), [Either Term Type]
args, [TickInfo]
ticks) ->
TransformContext
-> [TickInfo]
-> Term
-> ([Either Term Type] -> Term)
-> [Either Term Type]
-> RewriteMonad NormalizeState ConstantSpecInfo
mergeCsrs TransformContext
ctx [TickInfo]
ticks Term
e (Term -> [Either Term Type] -> Term
mkApps Term
dc) [Either Term Type]
args
(prim :: Term
prim@(Prim PrimInfo
_), [Either Term Type]
args, [TickInfo]
ticks) -> do
ConstantSpecInfo
csr <- TransformContext
-> [TickInfo]
-> Term
-> ([Either Term Type] -> Term)
-> [Either Term Type]
-> RewriteMonad NormalizeState ConstantSpecInfo
mergeCsrs TransformContext
ctx [TickInfo]
ticks Term
e (Term -> [Either Term Type] -> Term
mkApps Term
prim) [Either Term Type]
args
if [(Id, Term)] -> Bool
forall (t :: Type -> Type) a. Foldable t => t a -> Bool
null (ConstantSpecInfo -> [(Id, Term)]
csrNewBindings ConstantSpecInfo
csr) then
ConstantSpecInfo -> RewriteMonad NormalizeState ConstantSpecInfo
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure ConstantSpecInfo
csr
else
TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr TransformContext
ctx Term
e
(Lam Id
_ Term
_, [Either Term Type]
_, [TickInfo]
_ticks) ->
if Term -> Bool
hasLocalFreeVars Term
e then
TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr TransformContext
ctx Term
e
else
ConstantSpecInfo -> RewriteMonad NormalizeState ConstantSpecInfo
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (Term -> ConstantSpecInfo
constantCsr Term
e)
(var :: Term
var@(Var Id
f), [Either Term Type]
args, [TickInfo]
ticks) -> do
(Id
curF, SrcSpan
_) <- Getting (Id, SrcSpan) (RewriteState NormalizeState) (Id, SrcSpan)
-> RewriteMonad NormalizeState (Id, SrcSpan)
forall s (m :: Type -> Type) a.
MonadState s m =>
Getting a s a -> m a
Lens.use Getting (Id, SrcSpan) (RewriteState NormalizeState) (Id, SrcSpan)
forall extra1. Lens' (RewriteState extra1) (Id, SrcSpan)
curFun
Bool
isNonRecGlobVar <- Term -> RewriteMonad NormalizeState Bool
isNonRecursiveGlobalVar Term
e
if Bool
isNonRecGlobVar Bool -> Bool -> Bool
&& Id
f Id -> Id -> Bool
forall a. Eq a => a -> a -> Bool
/= Id
curF then do
ConstantSpecInfo
csr <- TransformContext
-> [TickInfo]
-> Term
-> ([Either Term Type] -> Term)
-> [Either Term Type]
-> RewriteMonad NormalizeState ConstantSpecInfo
mergeCsrs TransformContext
ctx [TickInfo]
ticks Term
e (Term -> [Either Term Type] -> Term
mkApps Term
var) [Either Term Type]
args
if [(Id, Term)] -> Bool
forall (t :: Type -> Type) a. Foldable t => t a -> Bool
null (ConstantSpecInfo -> [(Id, Term)]
csrNewBindings ConstantSpecInfo
csr) then
ConstantSpecInfo -> RewriteMonad NormalizeState ConstantSpecInfo
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure ConstantSpecInfo
csr
else
TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr TransformContext
ctx Term
e
else
TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr TransformContext
ctx Term
e
(Literal Literal
_,[Either Term Type]
_, [TickInfo]
_ticks) ->
ConstantSpecInfo -> RewriteMonad NormalizeState ConstantSpecInfo
forall (f :: Type -> Type) a. Applicative f => a -> f a
pure (Term -> ConstantSpecInfo
constantCsr Term
e)
(Term, [Either Term Type], [TickInfo])
_ ->
TransformContext
-> Term -> RewriteMonad NormalizeState ConstantSpecInfo
bindCsr TransformContext
ctx Term
e
type CallGraph = VarEnv (VarEnv Word)
collectCallGraphUniques :: CallGraph -> HashSet.HashSet Unique
collectCallGraphUniques :: CallGraph -> HashSet Int
collectCallGraphUniques CallGraph
cg = [Int] -> HashSet Int
forall a. (Eq a, Hashable a) => [a] -> HashSet a
HashSet.fromList ([Int]
us0 [Int] -> [Int] -> [Int]
forall a. [a] -> [a] -> [a]
++ [Int]
us1)
where
us0 :: [Int]
us0 = CallGraph -> [Int]
forall a. UniqMap a -> [Int]
keysUniqMap CallGraph
cg
us1 :: [Int]
us1 = (UniqMap Word -> [Int]) -> [UniqMap Word] -> [Int]
forall (t :: Type -> Type) a b.
Foldable t =>
(a -> [b]) -> t a -> [b]
concatMap UniqMap Word -> [Int]
forall a. UniqMap a -> [Int]
keysUniqMap (CallGraph -> [UniqMap Word]
forall a. UniqMap a -> [a]
eltsUniqMap CallGraph
cg)
callGraph
:: BindingMap
-> Id
-> CallGraph
callGraph :: VarEnv (Binding Term) -> Id -> CallGraph
callGraph VarEnv (Binding Term)
bndrs Id
rt = CallGraph -> Int -> CallGraph
forall a. Num a => UniqMap (VarEnv a) -> Int -> UniqMap (VarEnv a)
go CallGraph
forall a. VarEnv a
emptyVarEnv (Id -> Int
forall a. Var a -> Int
varUniq Id
rt)
where
go :: UniqMap (VarEnv a) -> Int -> UniqMap (VarEnv a)
go UniqMap (VarEnv a)
cg Int
root
| Maybe (VarEnv a)
Nothing <- Int -> UniqMap (VarEnv a) -> Maybe (VarEnv a)
forall a b. Uniquable a => a -> UniqMap b -> Maybe b
lookupUniqMap Int
root UniqMap (VarEnv a)
cg
, Just Binding Term
rootTm <- Int -> VarEnv (Binding Term) -> Maybe (Binding Term)
forall a b. Uniquable a => a -> UniqMap b -> Maybe b
lookupUniqMap Int
root VarEnv (Binding Term)
bndrs =
let used :: VarEnv a
used = Fold Term Id
-> (VarEnv a -> VarEnv a -> VarEnv a)
-> VarEnv a
-> (Id -> VarEnv a)
-> Term
-> VarEnv a
forall s a r. Fold s a -> (r -> r -> r) -> r -> (a -> r) -> s -> r
Lens.foldMapByOf Fold Term Id
globalIds ((a -> a -> a) -> VarEnv a -> VarEnv a -> VarEnv a
forall a. (a -> a -> a) -> VarEnv a -> VarEnv a -> VarEnv a
unionVarEnvWith a -> a -> a
forall a. Num a => a -> a -> a
(+))
VarEnv a
forall a. VarEnv a
emptyVarEnv (Id -> a -> VarEnv a
forall a b. Uniquable a => a -> b -> UniqMap b
`unitUniqMap` a
1) (Binding Term -> Term
forall a. Binding a -> a
bindingTerm Binding Term
rootTm)
cg' :: UniqMap (VarEnv a)
cg' = Int -> VarEnv a -> UniqMap (VarEnv a) -> UniqMap (VarEnv a)
forall a b. Uniquable a => a -> b -> UniqMap b -> UniqMap b
extendUniqMap Int
root VarEnv a
used UniqMap (VarEnv a)
cg
in (UniqMap (VarEnv a) -> Int -> UniqMap (VarEnv a))
-> UniqMap (VarEnv a) -> [Int] -> UniqMap (VarEnv a)
forall (t :: Type -> Type) b a.
Foldable t =>
(b -> a -> b) -> b -> t a -> b
List.foldl' UniqMap (VarEnv a) -> Int -> UniqMap (VarEnv a)
go UniqMap (VarEnv a)
cg' (VarEnv a -> [Int]
forall a. UniqMap a -> [Int]
keysUniqMap VarEnv a
used)
go UniqMap (VarEnv a)
cg Int
_ = UniqMap (VarEnv a)
cg
classifyFunction
:: Term
-> TermClassification
classifyFunction :: Term -> TermClassification
classifyFunction = TermClassification -> Term -> TermClassification
go (Int -> Int -> Int -> TermClassification
TermClassification Int
0 Int
0 Int
0)
where
go :: TermClassification -> Term -> TermClassification
go !TermClassification
c (Lam Id
_ Term
e) = TermClassification -> Term -> TermClassification
go TermClassification
c Term
e
go !TermClassification
c (TyLam TyVar
_ Term
e) = TermClassification -> Term -> TermClassification
go TermClassification
c Term
e
go !TermClassification
c (Letrec [(Id, Term)]
bs Term
_) = (TermClassification -> Term -> TermClassification)
-> TermClassification -> [Term] -> TermClassification
forall (t :: Type -> Type) b a.
Foldable t =>
(b -> a -> b) -> b -> t a -> b
List.foldl' TermClassification -> Term -> TermClassification
go TermClassification
c (((Id, Term) -> Term) -> [(Id, Term)] -> [Term]
forall a b. (a -> b) -> [a] -> [b]
map (Id, Term) -> Term
forall a b. (a, b) -> b
snd [(Id, Term)]
bs)
go !TermClassification
c e :: Term
e@(App {}) = case (Term, [Either Term Type]) -> Term
forall a b. (a, b) -> a
fst (Term -> (Term, [Either Term Type])
collectArgs Term
e) of
Prim {} -> TermClassification
c TermClassification
-> (TermClassification -> TermClassification) -> TermClassification
forall a b. a -> (a -> b) -> b
& (Int -> Identity Int)
-> TermClassification -> Identity TermClassification
Lens' TermClassification Int
primitive ((Int -> Identity Int)
-> TermClassification -> Identity TermClassification)
-> Int -> TermClassification -> TermClassification
forall a s t. Num a => ASetter s t a a -> a -> s -> t
+~ Int
1
Var {} -> TermClassification
c TermClassification
-> (TermClassification -> TermClassification) -> TermClassification
forall a b. a -> (a -> b) -> b
& (Int -> Identity Int)
-> TermClassification -> Identity TermClassification
Lens' TermClassification Int
function ((Int -> Identity Int)
-> TermClassification -> Identity TermClassification)
-> Int -> TermClassification -> TermClassification
forall a s t. Num a => ASetter s t a a -> a -> s -> t
+~ Int
1
Term
_ -> TermClassification
c
go !TermClassification
c (Case Term
_ Type
_ [Alt]
alts) = case [Alt]
alts of
(Alt
_:Alt
_:[Alt]
_) -> TermClassification
c TermClassification
-> (TermClassification -> TermClassification) -> TermClassification
forall a b. a -> (a -> b) -> b
& (Int -> Identity Int)
-> TermClassification -> Identity TermClassification
Lens' TermClassification Int
selection ((Int -> Identity Int)
-> TermClassification -> Identity TermClassification)
-> Int -> TermClassification -> TermClassification
forall a s t. Num a => ASetter s t a a -> a -> s -> t
+~ Int
1
[Alt]
_ -> TermClassification
c
go !TermClassification
c (Tick TickInfo
_ Term
e) = TermClassification -> Term -> TermClassification
go TermClassification
c Term
e
go TermClassification
c Term
_ = TermClassification
c
isCheapFunction
:: Term
-> Bool
isCheapFunction :: Term -> Bool
isCheapFunction Term
tm = case Term -> TermClassification
classifyFunction Term
tm of
TermClassification {Int
_selection :: TermClassification -> Int
_primitive :: TermClassification -> Int
_function :: TermClassification -> Int
_selection :: Int
_primitive :: Int
_function :: Int
..}
| Int
_function Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
1 -> Int
_primitive Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
0 Bool -> Bool -> Bool
&& Int
_selection Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
0
| Int
_primitive Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
1 -> Int
_function Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
0 Bool -> Bool -> Bool
&& Int
_selection Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
0
| Int
_selection Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
1 -> Int
_function Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
0 Bool -> Bool -> Bool
&& Int
_primitive Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
0
| Bool
otherwise -> Bool
False
normalizeTopLvlBndr
:: Bool
-> Id
-> Binding Term
-> NormalizeSession (Binding Term)
normalizeTopLvlBndr :: Bool -> Id -> Binding Term -> NormalizeSession (Binding Term)
normalizeTopLvlBndr Bool
isTop Id
nm (Binding Id
nm' SrcSpan
sp InlineSpec
inl IsPrim
pr Term
tm) = Id
-> Lens' (RewriteState NormalizeState) (VarEnv (Binding Term))
-> NormalizeSession (Binding Term)
-> NormalizeSession (Binding Term)
forall s (m :: Type -> Type) k v.
(MonadState s m, Uniquable k) =>
k -> Lens' s (UniqMap v) -> m v -> m v
makeCachedU Id
nm ((NormalizeState -> f NormalizeState)
-> RewriteState NormalizeState -> f (RewriteState NormalizeState)
forall extra1 extra2.
Lens (RewriteState extra1) (RewriteState extra2) extra1 extra2
extra((NormalizeState -> f NormalizeState)
-> RewriteState NormalizeState -> f (RewriteState NormalizeState))
-> ((VarEnv (Binding Term) -> f (VarEnv (Binding Term)))
-> NormalizeState -> f NormalizeState)
-> (VarEnv (Binding Term) -> f (VarEnv (Binding Term)))
-> RewriteState NormalizeState
-> f (RewriteState NormalizeState)
forall b c a. (b -> c) -> (a -> b) -> a -> c
.(VarEnv (Binding Term) -> f (VarEnv (Binding Term)))
-> NormalizeState -> f NormalizeState
Lens' NormalizeState (VarEnv (Binding Term))
normalized) (NormalizeSession (Binding Term)
-> NormalizeSession (Binding Term))
-> NormalizeSession (Binding Term)
-> NormalizeSession (Binding Term)
forall a b. (a -> b) -> a -> b
$ do
TyConMap
tcm <- Getting TyConMap RewriteEnv TyConMap
-> RewriteMonad NormalizeState TyConMap
forall s (m :: Type -> Type) a.
MonadReader s m =>
Getting a s a -> m a
Lens.view Getting TyConMap RewriteEnv TyConMap
Lens' RewriteEnv TyConMap
tcCache
let nmS :: String
nmS = Name Term -> String
forall p. PrettyPrec p => p -> String
showPpr (Id -> Name Term
forall a. Var a -> Name a
varName Id
nm)
let tm1 :: Term
tm1 = HasCallStack => InScopeSet -> Term -> Term
InScopeSet -> Term -> Term
deShadowTerm InScopeSet
emptyInScopeSet Term
tm
tm2 :: Term
tm2 = if Bool
isTop then Term -> Term
substWithTyEq Term
tm1 else Term
tm1
(Id, SrcSpan)
old <- Getting (Id, SrcSpan) (RewriteState NormalizeState) (Id, SrcSpan)
-> RewriteMonad NormalizeState (Id, SrcSpan)
forall s (m :: Type -> Type) a.
MonadState s m =>
Getting a s a -> m a
Lens.use Getting (Id, SrcSpan) (RewriteState NormalizeState) (Id, SrcSpan)
forall extra1. Lens' (RewriteState extra1) (Id, SrcSpan)
curFun
Term
tm3 <- (String, NormRewrite)
-> (String, Term) -> (Id, SrcSpan) -> NormalizeSession Term
rewriteExpr (String
"normalization",NormRewrite
normalization) (String
nmS,Term
tm2) (Id
nm',SrcSpan
sp)
((Id, SrcSpan) -> Identity (Id, SrcSpan))
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState)
forall extra1. Lens' (RewriteState extra1) (Id, SrcSpan)
curFun (((Id, SrcSpan) -> Identity (Id, SrcSpan))
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState))
-> (Id, SrcSpan) -> RewriteMonad NormalizeState ()
forall s (m :: Type -> Type) a b.
MonadState s m =>
ASetter s s a b -> b -> m ()
.= (Id, SrcSpan)
old
let ty' :: Type
ty' = TyConMap -> Term -> Type
termType TyConMap
tcm Term
tm3
Binding Term -> NormalizeSession (Binding Term)
forall (m :: Type -> Type) a. Monad m => a -> m a
return (Id -> SrcSpan -> InlineSpec -> IsPrim -> Term -> Binding Term
forall a. Id -> SrcSpan -> InlineSpec -> IsPrim -> a -> Binding a
Binding Id
nm'{varType :: Type
varType = Type
ty'} SrcSpan
sp InlineSpec
inl IsPrim
pr Term
tm3)
substWithTyEq
:: Term
-> Term
substWithTyEq :: Term -> Term
substWithTyEq Term
e0 = [TyVar] -> Bool -> [Id] -> Term -> Term
go [] Bool
False [] Term
e0
where
go
:: [TyVar]
-> Bool
-> [Id]
-> Term
-> Term
go :: [TyVar] -> Bool -> [Id] -> Term -> Term
go [TyVar]
tvs Bool
changed [Id]
ids_ (TyLam TyVar
tv Term
e) = [TyVar] -> Bool -> [Id] -> Term -> Term
go (TyVar
tvTyVar -> [TyVar] -> [TyVar]
forall a. a -> [a] -> [a]
:[TyVar]
tvs) Bool
changed [Id]
ids_ Term
e
go [TyVar]
tvs Bool
changed [Id]
ids_ (Lam Id
v Term
e)
| TyConApp (TyConName -> Int
forall a. Name a -> Int
nameUniq -> Int
tcUniq) ([Type] -> Maybe (TyVar, Type)
tvFirst -> Just (TyVar
tv, Type
ty)) <- Type -> TypeView
tyView (Id -> Type
forall a. Var a -> Type
varType Id
v)
, Int
tcUniq Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Unique -> Int
getKey Unique
eqTyConKey
, TyVar
tv TyVar -> [TyVar] -> Bool
forall (t :: Type -> Type) a.
(Foldable t, Eq a) =>
a -> t a -> Bool
`elem` [TyVar]
tvs
= let
subst0 :: Subst
subst0 = Subst -> TyVar -> Type -> Subst
extendTvSubst (InScopeSet -> Subst
mkSubst InScopeSet
emptyInScopeSet) TyVar
tv Type
ty
subst1 :: Subst
subst1 = Subst -> Id -> Term -> Subst
extendIdSubst Subst
subst0 Id
v (Type -> Term
removedTm (Id -> Type
forall a. Var a -> Type
varType Id
v))
in [TyVar] -> Bool -> [Id] -> Term -> Term
go ([TyVar]
tvs [TyVar] -> [TyVar] -> [TyVar]
forall a. Eq a => [a] -> [a] -> [a]
List.\\ [TyVar
tv]) Bool
True (HasCallStack => Subst -> Id -> Id
Subst -> Id -> Id
substId Subst
subst0 Id
v Id -> [Id] -> [Id]
forall a. a -> [a] -> [a]
: [Id]
ids_) (HasCallStack => Doc () -> Subst -> Term -> Term
Doc () -> Subst -> Term -> Term
substTm Doc ()
"substWithTyEq e" Subst
subst1 Term
e)
| Bool
otherwise = [TyVar] -> Bool -> [Id] -> Term -> Term
go [TyVar]
tvs Bool
changed (Id
vId -> [Id] -> [Id]
forall a. a -> [a] -> [a]
:[Id]
ids_) Term
e
go [TyVar]
tvs Bool
True [Id]
ids_ Term
e =
let
e1 :: Term
e1 = (Term -> TyVar -> Term) -> Term -> [TyVar] -> Term
forall (t :: Type -> Type) b a.
Foldable t =>
(b -> a -> b) -> b -> t a -> b
List.foldl' ((TyVar -> Term -> Term) -> Term -> TyVar -> Term
forall a b c. (a -> b -> c) -> b -> a -> c
flip TyVar -> Term -> Term
TyLam) Term
e [TyVar]
tvs
e2 :: Term
e2 = (Term -> Id -> Term) -> Term -> [Id] -> Term
forall (t :: Type -> Type) b a.
Foldable t =>
(b -> a -> b) -> b -> t a -> b
List.foldl' ((Id -> Term -> Term) -> Term -> Id -> Term
forall a b c. (a -> b -> c) -> b -> a -> c
flip Id -> Term -> Term
Lam) Term
e1 [Id]
ids_
in Term
e2
go [TyVar]
_ Bool
False [Id]
_ Term
_ = Term
e0
tvFirst :: [Type] -> Maybe (TyVar, Type)
tvFirst :: [Type] -> Maybe (TyVar, Type)
tvFirst [Type
_, VarTy TyVar
tv, Type
ty] = (TyVar, Type) -> Maybe (TyVar, Type)
forall a. a -> Maybe a
Just (TyVar
tv, Type
ty)
tvFirst [Type
_, Type
ty, VarTy TyVar
tv] = (TyVar, Type) -> Maybe (TyVar, Type)
forall a. a -> Maybe a
Just (TyVar
tv, Type
ty)
tvFirst [Type]
_ = Maybe (TyVar, Type)
forall a. Maybe a
Nothing
tvSubstWithTyEq
:: Type
-> Type
tvSubstWithTyEq :: Type -> Type
tvSubstWithTyEq Type
ty0 = [(TyVar, Type)] -> [Either TyVar Type] -> Type
go [] [Either TyVar Type]
args0
where
([Either TyVar Type]
args0,Type
tyRes) = Type -> ([Either TyVar Type], Type)
splitFunForallTy Type
ty0
go :: [(TyVar,Type)] -> [Either TyVar Type] -> Type
go :: [(TyVar, Type)] -> [Either TyVar Type] -> Type
go [(TyVar, Type)]
eqs (Right Type
arg : [Either TyVar Type]
args)
| Just (TyConName
tc,[Type]
tcArgs) <- Type -> Maybe (TyConName, [Type])
splitTyConAppM Type
arg
, TyConName -> Int
forall a. Name a -> Int
nameUniq TyConName
tc Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Unique -> Int
getKey Unique
eqTyConKey
, Just (TyVar, Type)
eq <- [Type] -> Maybe (TyVar, Type)
tvFirst [Type]
tcArgs
= [(TyVar, Type)] -> [Either TyVar Type] -> Type
go ((TyVar, Type)
eq(TyVar, Type) -> [(TyVar, Type)] -> [(TyVar, Type)]
forall a. a -> [a] -> [a]
:[(TyVar, Type)]
eqs) [Either TyVar Type]
args
| Bool
otherwise = [(TyVar, Type)] -> [Either TyVar Type] -> Type
go [(TyVar, Type)]
eqs [Either TyVar Type]
args
go [(TyVar, Type)]
eqs (Left TyVar
_tv : [Either TyVar Type]
args)
= [(TyVar, Type)] -> [Either TyVar Type] -> Type
go [(TyVar, Type)]
eqs [Either TyVar Type]
args
go [] [] = Type
ty0
go [(TyVar, Type)]
eqs [] = HasCallStack => Subst -> Type -> Type
Subst -> Type -> Type
substTy Subst
subst Type
ty2
where
subst :: Subst
subst = Subst -> [(TyVar, Type)] -> Subst
extendTvSubstList (InScopeSet -> Subst
mkSubst InScopeSet
emptyInScopeSet) [(TyVar, Type)]
eqs
args2 :: [Either TyVar Type]
args2 = [Either TyVar Type]
args0 [Either TyVar Type] -> [Either TyVar Type] -> [Either TyVar Type]
forall a. Eq a => [a] -> [a] -> [a]
List.\\ (((TyVar, Type) -> Either TyVar Type)
-> [(TyVar, Type)] -> [Either TyVar Type]
forall a b. (a -> b) -> [a] -> [b]
map (TyVar -> Either TyVar Type
forall a b. a -> Either a b
Left (TyVar -> Either TyVar Type)
-> ((TyVar, Type) -> TyVar) -> (TyVar, Type) -> Either TyVar Type
forall b c a. (b -> c) -> (a -> b) -> a -> c
. (TyVar, Type) -> TyVar
forall a b. (a, b) -> a
fst) [(TyVar, Type)]
eqs)
ty2 :: Type
ty2 = Type -> [Either TyVar Type] -> Type
mkPolyFunTy Type
tyRes [Either TyVar Type]
args2
rewriteExpr :: (String,NormRewrite)
-> (String,Term)
-> (Id, SrcSpan)
-> NormalizeSession Term
rewriteExpr :: (String, NormRewrite)
-> (String, Term) -> (Id, SrcSpan) -> NormalizeSession Term
rewriteExpr (String
nrwS,NormRewrite
nrw) (String
bndrS,Term
expr) (Id
nm, SrcSpan
sp) = do
((Id, SrcSpan) -> Identity (Id, SrcSpan))
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState)
forall extra1. Lens' (RewriteState extra1) (Id, SrcSpan)
curFun (((Id, SrcSpan) -> Identity (Id, SrcSpan))
-> RewriteState NormalizeState
-> Identity (RewriteState NormalizeState))
-> (Id, SrcSpan) -> RewriteMonad NormalizeState ()
forall s (m :: Type -> Type) a b.
MonadState s m =>
ASetter s s a b -> b -> m ()
.= (Id
nm, SrcSpan
sp)
DebugLevel
lvl <- Getting DebugLevel RewriteEnv DebugLevel
-> RewriteMonad NormalizeState DebugLevel
forall s (m :: Type -> Type) a.
MonadReader s m =>
Getting a s a -> m a
Lens.view Getting DebugLevel RewriteEnv DebugLevel
Lens' RewriteEnv DebugLevel
dbgLevel
let before :: String
before = Term -> String
forall p. PrettyPrec p => p -> String
showPpr Term
expr
let expr' :: Term
expr' = Bool -> String -> Term -> Term
forall a. Bool -> String -> a -> a
traceIf (DebugLevel
lvl DebugLevel -> DebugLevel -> Bool
forall a. Ord a => a -> a -> Bool
>= DebugLevel
DebugFinal)
(String
bndrS String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
" before " String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
nrwS String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
":\n\n" String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
before String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
"\n")
Term
expr
Term
rewritten <- String
-> InScopeSet -> NormRewrite -> Term -> NormalizeSession Term
forall extra.
String
-> InScopeSet -> Rewrite extra -> Term -> RewriteMonad extra Term
runRewrite String
nrwS InScopeSet
emptyInScopeSet NormRewrite
nrw Term
expr'
let after :: String
after = Term -> String
forall p. PrettyPrec p => p -> String
showPpr Term
rewritten
Bool -> String -> NormalizeSession Term -> NormalizeSession Term
forall a. Bool -> String -> a -> a
traceIf (DebugLevel
lvl DebugLevel -> DebugLevel -> Bool
forall a. Ord a => a -> a -> Bool
>= DebugLevel
DebugFinal)
(String
bndrS String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
" after " String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
nrwS String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
":\n\n" String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
after String -> ShowS
forall a. [a] -> [a] -> [a]
++ String
"\n") (NormalizeSession Term -> NormalizeSession Term)
-> NormalizeSession Term -> NormalizeSession Term
forall a b. (a -> b) -> a -> b
$
Term -> NormalizeSession Term
forall (m :: Type -> Type) a. Monad m => a -> m a
return Term
rewritten
removedTm
:: Type
-> Term
removedTm :: Type -> Term
removedTm =
let removedNm :: Text
removedNm = Text
"Clash.Transformations.removedArg" in
Term -> Type -> Term
TyApp (PrimInfo -> Term
Prim (Text -> Type -> WorkInfo -> IsMultiPrim -> PrimInfo
PrimInfo Text
removedNm Type
undefinedTy WorkInfo
WorkNever IsMultiPrim
SingleResult))
mkInlineTick :: Id -> TickInfo
mkInlineTick :: Id -> TickInfo
mkInlineTick Id
n = NameMod -> Type -> TickInfo
NameMod NameMod
PrefixName (LitTy -> Type
LitTy (LitTy -> Type) -> (String -> LitTy) -> String -> Type
forall b c a. (b -> c) -> (a -> b) -> a -> c
. String -> LitTy
SymTy (String -> Type) -> String -> Type
forall a b. (a -> b) -> a -> b
$ Id -> String
forall a. Var a -> String
toStr Id
n)
where
toStr :: Var a -> String
toStr = Text -> String
Text.unpack (Text -> String) -> (Var a -> Text) -> Var a -> String
forall b c a. (b -> c) -> (a -> b) -> a -> c
. (Text, Text) -> Text
forall a b. (a, b) -> b
snd ((Text, Text) -> Text) -> (Var a -> (Text, Text)) -> Var a -> Text
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Text -> Text -> (Text, Text)
Text.breakOnEnd Text
"." (Text -> (Text, Text)) -> (Var a -> Text) -> Var a -> (Text, Text)
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Name a -> Text
forall a. Name a -> Text
nameOcc (Name a -> Text) -> (Var a -> Name a) -> Var a -> Text
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Var a -> Name a
forall a. Var a -> Name a
varName