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path: root/src/full/Agda/Syntax/Internal.hs
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{-# LANGUAGE CPP                        #-}
{-# LANGUAGE DeriveDataTypeable         #-}
{-# LANGUAGE DeriveFoldable             #-}
{-# LANGUAGE DeriveFunctor              #-}
{-# LANGUAGE DeriveTraversable          #-}
{-# LANGUAGE FlexibleInstances          #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE MultiParamTypeClasses      #-}
{-# LANGUAGE TemplateHaskell            #-}
{-# LANGUAGE TypeSynonymInstances       #-}

module Agda.Syntax.Internal
    ( module Agda.Syntax.Internal
    , module Agda.Syntax.Abstract.Name
    , module Agda.Utils.Pointer
    ) where

import Prelude hiding (foldr, mapM, null)

import Control.Arrow ((***))
import Control.Applicative
import Control.Monad.Identity hiding (mapM)
import Control.Monad.State hiding (mapM)
import Control.Parallel

import Data.Foldable
import Data.Function
import qualified Data.List as List
import Data.Maybe
import Data.Traversable
import Data.Typeable (Typeable)

import Agda.Syntax.Position
import Agda.Syntax.Common hiding (Arg, Dom, NamedArg, ArgInfo)
import qualified Agda.Syntax.Common as Common
import Agda.Syntax.Literal
import Agda.Syntax.Abstract.Name

import Agda.Utils.Empty
import Agda.Utils.Functor
import Agda.Utils.Geniplate
import Agda.Utils.List
import Agda.Utils.Null
import Agda.Utils.Permutation
import Agda.Utils.Pointer
import Agda.Utils.Size
import Agda.Utils.Pretty

#include "undefined.h"
import Agda.Utils.Impossible

type Color      = Term
type ArgInfo    = Common.ArgInfo Color
type Arg a      = Common.Arg Color a
type Dom a      = Common.Dom Color a
type NamedArg a = Common.NamedArg Color a

-- | Type of argument lists.
--
type Args       = [Arg Term]
type NamedArgs  = [NamedArg Term]

-- | Store the names of the record fields in the constructor.
--   This allows reduction of projection redexes outside of TCM.
--   For instance, during substitution and application.
data ConHead = ConHead
  { conName      :: QName     -- ^ The name of the constructor.
  , conInductive :: Induction -- ^ Record constructors can be coinductive.
  , conFields    :: [QName]   -- ^ The name of the record fields.
                              --   Empty list for data constructors.
                              --   'Arg' is not needed here since it
                              --   is stored in the constructor args.
  } deriving (Typeable)

instance Eq ConHead where
  (==) = (==) `on` conName

instance Ord ConHead where
  (<=) = (<=) `on` conName

instance Show ConHead where
  show (ConHead c i fs) = show c ++ "(" ++ show i ++ ")" ++ show fs

instance HasRange ConHead where
  getRange = getRange . conName

instance SetRange ConHead where
  setRange r = mapConName (setRange r)

class LensConName a where
  getConName :: a -> QName
  setConName :: QName -> a -> a
  setConName = mapConName . const
  mapConName :: (QName -> QName) -> a -> a
  mapConName f a = setConName (f (getConName a)) a

instance LensConName ConHead where
  getConName = conName
  setConName c con = con { conName = c }


-- | Raw values.
--
--   @Def@ is used for both defined and undefined constants.
--   Assume there is a type declaration and a definition for
--     every constant, even if the definition is an empty
--     list of clauses.
--
data Term = Var {-# UNPACK #-} !Int Elims -- ^ @x es@ neutral
          | Lam ArgInfo (Abs Term)        -- ^ Terms are beta normal. Relevance is ignored
          | ExtLam [Clause] Args          -- ^ Only used by unquote --> reify. Should never appear elsewhere.
          | Lit Literal
          | Def QName Elims               -- ^ @f es@, possibly a delta/iota-redex
          | Con ConHead Args              -- ^ @c vs@
          | Pi (Dom Type) (Abs Type)      -- ^ dependent or non-dependent function space
          | Sort Sort
          | Level Level
          | MetaV {-# UNPACK #-} !MetaId Elims
          | DontCare Term
            -- ^ Irrelevant stuff in relevant position, but created
            --   in an irrelevant context.  Basically, an internal
            --   version of the irrelevance axiom @.irrAx : .A -> A@.
          | Shared !(Ptr Term)
            -- ^ Explicit sharing
  deriving (Typeable, Show)

-- | Eliminations, subsuming applications and projections.
--
data Elim' a = Apply (Arg a) | Proj QName -- ^ name of a record projection
  deriving (Typeable, Show, Functor, Foldable, Traversable)

type Elim = Elim' Term
type Elims = [Elim]  -- ^ eliminations ordered left-to-right.

-- | Names in binders and arguments.
type ArgName = String

argNameToString :: ArgName -> String
argNameToString = id

stringToArgName :: String -> ArgName
stringToArgName = id

appendArgNames :: ArgName -> ArgName -> ArgName
appendArgNames = (++)

nameToArgName :: Name -> ArgName
nameToArgName = stringToArgName . prettyShow

-- | Binder.
--   'Abs': The bound variable might appear in the body.
--   'NoAbs' is pseudo-binder, it does not introduce a fresh variable,
--      similar to the @const@ of Haskell.
data Abs a = Abs   { absName :: ArgName, unAbs :: a }
               -- ^ The body has (at least) one free variable.
               --   Danger: 'unAbs' doesn't shift variables properly
           | NoAbs { absName :: ArgName, unAbs :: a }
  deriving (Typeable, Functor, Foldable, Traversable)

-- | Types are terms with a sort annotation.
--
data Type' a = El { getSort :: Sort, unEl :: a }
  deriving (Typeable, Show, Functor, Foldable, Traversable)

type Type = Type' Term

instance Decoration Type' where
  traverseF f (El s a) = El s <$> f a

-- | Sequence of types. An argument of the first type is bound in later types
--   and so on.
data Tele a = EmptyTel
            | ExtendTel a (Abs (Tele a))  -- ^ 'Abs' is never 'NoAbs'.
  deriving (Typeable, Show, Functor, Foldable, Traversable)

type Telescope = Tele (Dom Type)

instance Null (Tele a) where
  null EmptyTel    = True
  null ExtendTel{} = False
  empty = EmptyTel

mapAbsNamesM :: Applicative m => (ArgName -> m ArgName) -> Tele a -> m (Tele a)
mapAbsNamesM f EmptyTel                  = pure EmptyTel
mapAbsNamesM f (ExtendTel a (Abs x b))   = ExtendTel a <$> (Abs <$> f x <*> mapAbsNamesM f b)
mapAbsNamesM f (ExtendTel a (NoAbs x b)) = ExtendTel a <$> (NoAbs <$> f x <*> mapAbsNamesM f b)
  -- Ulf, 2013-11-06: Last case is really impossible but I'd rather find out we
  --                  violated that invariant somewhere other than here.

mapAbsNames :: (ArgName -> ArgName) -> Tele a -> Tele a
mapAbsNames f = runIdentity . mapAbsNamesM (Identity . f)

-- Ulf, 2013-11-06
-- The record parameter is named "" inside the record module so we can avoid
-- printing it (issue 208), but we don't want that to show up in the type of
-- the functions in the module (issue 892). This function is used on the record
-- module telescope before adding it to a type in
-- TypeChecking.Monad.Signature.addConstant (to handle functions defined in
-- record modules) and TypeChecking.Rules.Record.checkProjection (to handle
-- record projections).
replaceEmptyName :: ArgName -> Tele a -> Tele a
replaceEmptyName x = mapAbsNames $ \ y -> if null y then x else y

-- | Sorts.
--
data Sort = Type Level
          | Prop  -- ignore me
          | Inf
          | DLub Sort (Abs Sort)
            -- ^ if the free variable occurs in the second sort
            --   the whole thing should reduce to Inf, otherwise
            --   it's the normal Lub
  deriving (Typeable, Show)

-- | A level is a maximum expression of 0..n 'PlusLevel' expressions
--   each of which is a number or an atom plus a number.
--
--   The empty maximum is the canonical representation for level 0.
newtype Level = Max [PlusLevel]
  deriving (Show, Typeable)

data PlusLevel = ClosedLevel Integer
               | Plus Integer LevelAtom
  deriving (Show, Typeable)

data LevelAtom
  = MetaLevel MetaId Elims
  | BlockedLevel MetaId Term
  | NeutralLevel Term
  | UnreducedLevel Term
    -- ^ Introduced by 'instantiate', removed by 'reduce'.
  deriving (Show, Typeable)

-- | A meta variable identifier is just a natural number.
--
newtype MetaId = MetaId { metaId :: Nat }
    deriving (Eq, Ord, Num, Real, Enum, Integral, Typeable)

-- | Something where a meta variable may block reduction.
data Blocked t = Blocked MetaId t
               | NotBlocked t
    deriving (Typeable, Eq, Ord, Functor, Foldable, Traversable)

instance Applicative Blocked where
  pure = notBlocked
  Blocked x f  <*> e = Blocked x $ f (ignoreBlocking e)
  NotBlocked f <*> e = f <$> e


---------------------------------------------------------------------------
-- * Definitions
---------------------------------------------------------------------------

-- | A clause is a list of patterns and the clause body should @Bind@.
--
--  The telescope contains the types of the pattern variables and the
--  permutation is how to get from the order the variables occur in
--  the patterns to the order they occur in the telescope. The body
--  binds the variables in the order they appear in the patterns.
--
--  @clauseTel ~ permute clausePerm (patternVars clausPats)@
--
--  Terms in dot patterns are valid in the clause telescope.
--
--  For the purpose of the permutation and the body dot patterns count
--  as variables. TODO: Change this!
data Clause = Clause
    { clauseRange     :: Range
    , clauseTel       :: Telescope     -- ^ The types of the pattern variables.
    , clausePerm      :: Permutation
    , namedClausePats :: [NamedArg Pattern]
    , clauseBody      :: ClauseBody
    , clauseType      :: Maybe (Arg Type)
      -- ^ The type of the rhs under @clauseTel@.
      --   Used, e.g., by @TermCheck@.
      --   Can be 'Irrelevant' if we encountered an irrelevant projection
      --   pattern on the lhs.
    }
  deriving (Typeable, Show)

clausePats :: Clause -> [Arg Pattern]
clausePats = map (fmap namedThing) . namedClausePats

-- MOVED to Agda. Syntax.Internal.Patterns
-- -- | Translate the clause patterns to terms with free variables bound by the
-- --   clause telescope.
-- clauseArgs :: Clause -> Args
-- clauseArgs cl = evalState (argsToTerms $ namedClausePats cl) xs
--   where
--     perm = clausePerm cl
--     xs   = permute (invertP __IMPOSSIBLE__ perm) $ downFrom (size perm)
--
--     next = do x : xs <- get; put xs; return x
--
--     argsToTerms = traverse $ traverse $ patToTerm . namedThing
--     patToTerm p = case p of
--       VarP _      -> flip Var [] <$> next
--       DotP v      -> v <$ next   -- dot patterns count as variables
--       ConP c _ ps -> Con c <$> argsToTerms ps
--       LitP l      -> pure $ Lit l
--       ProjP{}     -> __IMPOSSIBLE__   -- TODO

data ClauseBodyF a = Body a
                   | Bind (Abs (ClauseBodyF a))
                   | NoBody    -- ^ for absurd clauses.
  deriving (Typeable, Show, Functor, Foldable, Traversable)

type ClauseBody = ClauseBodyF Term

instance HasRange Clause where
  getRange = clauseRange

-- | Pattern variables.
type PatVarName = ArgName

patVarNameToString :: PatVarName -> String
patVarNameToString = argNameToString

nameToPatVarName :: Name -> PatVarName
nameToPatVarName = nameToArgName

-- | Patterns are variables, constructors, or wildcards.
--   @QName@ is used in @ConP@ rather than @Name@ since
--     a constructor might come from a particular namespace.
--     This also meshes well with the fact that values (i.e.
--     the arguments we are matching with) use @QName@.
--
data Pattern' x
  = VarP x
    -- ^ @x@
  | DotP Term
    -- ^ @.t@
  | ConP ConHead ConPatternInfo [NamedArg (Pattern' x)]
    -- ^ @c ps@
    --   The subpatterns do not contain any projection copatterns.
  | LitP Literal
    -- ^ E.g. @5@, @"hello"@.
  | ProjP QName
    -- ^ Projection copattern.  Can only appear by itself.
  deriving (Typeable, Show, Functor, Foldable, Traversable)

type Pattern = Pattern' PatVarName
    -- ^ The @PatVarName@ is a name suggestion.


namedVarP :: PatVarName -> Named (Ranged PatVarName) Pattern
namedVarP x = Named named $ VarP x
  where named = if isUnderscore x then Nothing else Just $ unranged x

-- | The @ConPatternInfo@ states whether the constructor belongs to
--   a record type (@Just@) or data type (@Nothing@).
--   In the former case, the @Bool@ says whether the record pattern
--   orginates from the expansion of an implicit pattern.
--   The @Type@ is the type of the whole record pattern.
--   The scope used for the type is given by any outer scope
--   plus the clause's telescope ('clauseTel').
type ConPatternInfo = Maybe (Bool, Arg Type)

-- | Extract pattern variables in left-to-right order.
--   A 'DotP' is also treated as variable (see docu for 'Clause').
patternVars :: Arg Pattern -> [Arg (Either PatVarName Term)]
patternVars (Common.Arg i (VarP x)     ) = [Common.Arg i $ Left x]
patternVars (Common.Arg i (DotP t)     ) = [Common.Arg i $ Right t]
patternVars (Common.Arg i (ConP _ _ ps)) = List.concat $ map (patternVars . fmap namedThing) ps
patternVars (Common.Arg i (LitP l)     ) = []
patternVars (Common.Arg i ProjP{}      ) = []

-- | Does the pattern perform a match that could fail?
properlyMatching :: Pattern -> Bool
properlyMatching VarP{} = False
properlyMatching DotP{} = False
properlyMatching LitP{} = True
properlyMatching (ConP _ mt ps) = isNothing mt || -- not a record cons
  List.any (properlyMatching . namedArg) ps  -- or one of subpatterns is a proper m
properlyMatching ProjP{} = True

-----------------------------------------------------------------------------
-- * Explicit substitutions
-----------------------------------------------------------------------------

-- | Substitutions.

infixr 4 :#
data Substitution

  = IdS                     -- Γ ⊢ IdS : Γ

  | EmptyS                  -- Γ ⊢ EmptyS : ()

                            --      Γ ⊢ ρ : Δ
  | Wk !Int Substitution    -- -------------------
                            -- Γ, Ψ ⊢ Wk |Ψ| ρ : Δ

                            -- Γ ⊢ u : Aρ  Γ ⊢ ρ : Δ
  | Term :# Substitution    -- ---------------------
                            --   Γ ⊢ u :# ρ : Δ, A

    -- First argument is __IMPOSSIBLE__  --         Γ ⊢ ρ : Δ
  | Strengthen Empty Substitution        -- ---------------------------
                                         --   Γ ⊢ Strengthen ρ : Δ, A

                            --        Γ ⊢ ρ : Δ
  | Lift !Int Substitution  -- -------------------------
                            -- Γ, Ψρ ⊢ Lift |Ψ| ρ : Δ, Ψ
  deriving (Show)

---------------------------------------------------------------------------
-- * Absurd Lambda
---------------------------------------------------------------------------

-- | Absurd lambdas are internally represented as identity
--   with variable name "()".
absurdBody :: Abs Term
absurdBody = Abs absurdPatternName $ Var 0 []

isAbsurdBody :: Abs Term -> Bool
isAbsurdBody (Abs x (Var 0 [])) = isAbsurdPatternName x
isAbsurdBody _                  = False

absurdPatternName :: PatVarName
absurdPatternName = "()"

isAbsurdPatternName :: PatVarName -> Bool
isAbsurdPatternName x = x == absurdPatternName

---------------------------------------------------------------------------
-- * Pointers and Sharing
---------------------------------------------------------------------------

ignoreSharing :: Term -> Term
-- ignoreSharing (Shared p) = ignoreSharing $ derefPtr p
ignoreSharing v          = v

ignoreSharingType :: Type -> Type
-- ignoreSharingType (El s v) = El s (ignoreSharing v)
ignoreSharingType v = v

-- | Introduce sharing.
shared :: Term -> Term
-- shared v@Shared{}   = v
-- shared v@(Var _ []) = v
-- shared v            = Shared (newPtr v)
shared v = v

sharedType :: Type -> Type
-- sharedType (El s v) = El s (shared v)
sharedType v = v

-- | Typically m would be TCM and f would be Blocked.
updateSharedFM :: (Monad m, Applicative m, Traversable f) => (Term -> m (f Term)) -> Term -> m (f Term)
updateSharedFM f v0@(Shared p) = do
  fv <- f (derefPtr p)
  flip traverse fv $ \v ->
    case derefPtr (setPtr v p) of
      Var _ [] -> return v
      _        -> compressPointerChain v0 `pseq` return v0
updateSharedFM f v = f v

updateSharedM :: Monad m => (Term -> m Term) -> Term -> m Term
updateSharedM f v0@(Shared p) = do
  v <- f (derefPtr p)
  case derefPtr (setPtr v p) of
    Var _ [] -> return v
    _        -> compressPointerChain v0 `pseq` return v0
updateSharedM f v = f v

updateShared :: (Term -> Term) -> Term -> Term
updateShared f v0@(Shared p) =
  case derefPtr (setPtr (f $ derefPtr p) p) of
    v@(Var _ []) -> v
    _            -> compressPointerChain v0 `pseq` v0
updateShared f v = f v

pointerChain :: Term -> [Ptr Term]
pointerChain (Shared p) = p : pointerChain (derefPtr p)
pointerChain _          = []

-- Redirect all top-level pointers to point to the last pointer. So, after
-- compression there are at most two top-level indirections.
compressPointerChain :: Term -> Term
compressPointerChain v =
  case reverse $ pointerChain v of
    p:_:ps@(_:_) -> setPointers (Shared p) ps
    _            -> v
  where
    setPointers _ [] = v
    setPointers u (p : ps) =
      setPtr u p `seq` setPointers u ps

---------------------------------------------------------------------------
-- * Smart constructors
---------------------------------------------------------------------------

-- | An unapplied variable.
var :: Nat -> Term
var i | i >= 0    = Var i []
      | otherwise = __IMPOSSIBLE__

-- | Add 'DontCare' is it is not already a @DontCare@.
dontCare :: Term -> Term
dontCare v =
  case ignoreSharing v of
    DontCare{} -> v
    _          -> DontCare v

-- | A dummy type.
typeDontCare :: Type
typeDontCare = El Prop (Sort Prop)

-- | Top sort (Set\omega).
topSort :: Type
topSort = El Inf (Sort Inf)

prop :: Type
prop = sort Prop

sort :: Sort -> Type
sort s = El (sSuc s) $ Sort s

varSort :: Int -> Sort
varSort n = Type $ Max [Plus 0 $ NeutralLevel $ Var n []]

-- | Get the next higher sort.
sSuc :: Sort -> Sort
sSuc Prop            = mkType 1
sSuc Inf             = Inf
sSuc (DLub a b)      = DLub (sSuc a) (fmap sSuc b)
sSuc (Type l)        = Type $ levelSuc l

levelSuc :: Level -> Level
levelSuc (Max []) = Max [ClosedLevel 1]
levelSuc (Max as) = Max $ map inc as
  where inc (ClosedLevel n) = ClosedLevel (n + 1)
        inc (Plus n l)      = Plus (n + 1) l

mkType :: Integer -> Sort
mkType n = Type $ Max [ClosedLevel n | n > 0]

impossibleTerm :: String -> Int -> Term
impossibleTerm file line = Lit $ LitString noRange $ unlines
  [ "An internal error has occurred. Please report this as a bug."
  , "Location of the error: " ++ file ++ ":" ++ show line
  ]

class SgTel a where
  sgTel :: a -> Telescope

instance SgTel (ArgName, Dom Type) where
  sgTel (x, dom) = ExtendTel dom $ Abs x EmptyTel

instance SgTel (Dom (ArgName, Type)) where
  sgTel (Common.Dom ai (x, t)) = ExtendTel (Common.Dom ai t) $ Abs x EmptyTel

hackReifyToMeta :: Term
hackReifyToMeta = DontCare $ Lit $ LitInt noRange (-42)

isHackReifyToMeta :: Term -> Bool
isHackReifyToMeta (DontCare (Lit (LitInt r (-42)))) = r == noRange
isHackReifyToMeta _ = False

---------------------------------------------------------------------------
-- * Handling blocked terms.
---------------------------------------------------------------------------

blockingMeta :: Blocked t -> Maybe MetaId
blockingMeta (Blocked m _) = Just m
blockingMeta (NotBlocked _) = Nothing

blocked :: MetaId -> a -> Blocked a
blocked x = Blocked x

notBlocked :: a -> Blocked a
notBlocked = NotBlocked

ignoreBlocking :: Blocked a -> a
ignoreBlocking (Blocked _ x) = x
ignoreBlocking (NotBlocked x) = x

---------------------------------------------------------------------------
-- * Simple operations on terms and types.
---------------------------------------------------------------------------

-- | Removing a topmost 'DontCare' constructor.
stripDontCare :: Term -> Term
stripDontCare v = case ignoreSharing v of
  DontCare v -> v
  _          -> v

-- | Doesn't do any reduction.
arity :: Type -> Nat
arity t = case ignoreSharing $ unEl t of
  Pi  _ b -> 1 + arity (unAbs b)
  _       -> 0

-- | Suggest a name for the first argument of a function of the given type.
argName :: Type -> String
argName = argN . ignoreSharing . unEl
    where
        argN (Pi _ b)  = "." ++ argNameToString (absName b)
        argN _    = __IMPOSSIBLE__

-- | Pick the better name suggestion, i.e., the one that is not just underscore.
class Suggest a b where
  suggest :: a -> b -> String

instance Suggest String String where
  suggest "_" y = y
  suggest  x  _ = x

instance Suggest (Abs a) (Abs b) where
  suggest b1 b2 = suggest (absName b1) (absName b2)

---------------------------------------------------------------------------
-- * Eliminations.
---------------------------------------------------------------------------

-- | Convert top-level postfix projections into prefix projections.
unSpine :: Term -> Term
unSpine v =
  case hasElims v of
    Just (h, es) -> unSpine' h [] es
    Nothing      -> v
  where
    unSpine' :: (Elims -> Term) -> Elims -> Elims -> Term
    unSpine' h res es =
      case es of
        []                -> v
        e@(Apply a) : es' -> unSpine' h (e : res) es'
        Proj f      : es' -> unSpine' (Def f) [Apply (defaultArg v)] es'
      where v = h $ reverse res

-- | A view distinguishing the neutrals @Var@, @Def@, and @MetaV@ which
--   can be projected.
hasElims :: Term -> Maybe (Elims -> Term, Elims)
hasElims v =
  case ignoreSharing v of
    Var   i es -> Just (Var   i, es)
    Def   f es -> Just (Def   f, es)
    MetaV x es -> Just (MetaV x, es)
    Con{}      -> Nothing
    Lit{}      -> Nothing
    Lam{}      -> Nothing
    Pi{}       -> Nothing
    Sort{}     -> Nothing
    Level{}    -> Nothing
    DontCare{} -> Nothing
    ExtLam{}   -> Nothing
    Shared{}   -> __IMPOSSIBLE__

{- PROBABLY USELESS
getElims :: Term -> (Elims -> Term, Elims)
getElims v = maybe default id $ hasElims v
  where
    default = (\ [] -> v, [])
-}

-- | Drop 'Apply' constructor. (Unsafe!)
argFromElim :: Elim -> Arg Term
argFromElim (Apply u) = u
argFromElim Proj{}    = __IMPOSSIBLE__

-- | Drop 'Apply' constructor. (Safe)
isApplyElim :: Elim -> Maybe (Arg Term)
isApplyElim (Apply u) = Just u
isApplyElim Proj{}    = Nothing

-- | Drop 'Apply' constructors. (Safe)
allApplyElims :: Elims -> Maybe Args
allApplyElims = mapM isApplyElim

-- | Split at first non-'Apply'
splitApplyElims :: Elims -> (Args, Elims)
splitApplyElims (Apply u : es) = (u :) *** id $ splitApplyElims es
splitApplyElims es             = ([], es)

class IsProjElim e where
  isProjElim  :: e -> Maybe QName

instance IsProjElim Elim where
  isProjElim (Proj d) = Just d
  isProjElim Apply{}  = Nothing

-- | Discard @Proj f@ entries.
dropProjElims :: IsProjElim e => [e] -> [e]
dropProjElims = filter (isNothing . isProjElim)

-- | Discards @Proj f@ entries.
argsFromElims :: Elims -> Args
argsFromElims = map argFromElim . dropProjElims

{- NOTE: Elim' already contains Arg.

-- | Commute functors 'Arg' and 'Elim\''.
swapArgElim :: Common.Arg c (Elim' a) -> Elim' (Common.Arg c a)

swapArgElim (Common.Arg ai (Apply a)) = Apply (Common.Arg ai a)
swapArgElim (Common.Arg ai (Proj  d)) = Proj  d

-- IMPOSSIBLE TO DEFINE
swapElimArg :: Elim' (Common.Arg c a) -> Common.Arg c (Elim' a)
swapElimArg (Apply (Common.Arg ai a)) = Common.Arg ai (Apply a)
swapElimArg (Proj  d) = defaultArg (Proj  d)
-}

---------------------------------------------------------------------------
-- * Show instances.
---------------------------------------------------------------------------

instance Show a => Show (Abs a) where
  showsPrec p (Abs x a) = showParen (p > 0) $
    showString "Abs " . shows x . showString " " . showsPrec 10 a
  showsPrec p (NoAbs x a) = showParen (p > 0) $
    showString "NoAbs " . shows x . showString " " . showsPrec 10 a

instance Show MetaId where
    show (MetaId n) = "_" ++ show n

instance Show t => Show (Blocked t) where
  showsPrec p (Blocked m x) = showParen (p > 0) $
    showString "Blocked " . shows m . showString " " . showsPrec 10 x
  showsPrec p (NotBlocked x) = showsPrec p x

---------------------------------------------------------------------------
-- * Sized instances.
---------------------------------------------------------------------------

instance Sized Term where
  size v = case v of
    Var _ vs    -> 1 + Prelude.sum (map size vs)
    Def _ vs    -> 1 + Prelude.sum (map size vs)
    Con _ vs    -> 1 + Prelude.sum (map size vs)
    MetaV _ vs  -> 1 + Prelude.sum (map size vs)
    Level l     -> size l
    Lam _ f     -> 1 + size f
    Lit _       -> 1
    Pi a b      -> 1 + size a + size b
    Sort s      -> 1
    DontCare mv -> size mv
    Shared p    -> size (derefPtr p)
    ExtLam{}    -> __IMPOSSIBLE__

instance Sized Type where
  size = size . unEl

instance Sized Level where
  size (Max as) = 1 + Prelude.sum (map size as)

instance Sized PlusLevel where
  size (ClosedLevel _) = 1
  size (Plus _ a)      = size a

instance Sized LevelAtom where
  size (MetaLevel _   vs) = 1 + Prelude.sum (map size vs)
  size (BlockedLevel _ v) = size v
  size (NeutralLevel   v) = size v
  size (UnreducedLevel v) = size v

instance Sized (Tele a) where
  size  EmptyTel         = 0
  size (ExtendTel _ tel) = 1 + size tel

instance Sized a => Sized (Abs a) where
  size = size . unAbs

instance Sized a => Sized (Elim' a) where
  size (Apply v) = size v
  size  Proj{}   = 1

---------------------------------------------------------------------------
-- * KillRange instances.
---------------------------------------------------------------------------

instance KillRange ConHead where
  killRange (ConHead c i fs) = killRange3 ConHead c i fs

instance KillRange Term where
  killRange v = case v of
    Var i vs    -> killRange1 (Var i) vs
    Def c vs    -> killRange2 Def c vs
    Con c vs    -> killRange2 Con c vs
    MetaV m vs  -> killRange1 (MetaV m) vs
    Lam i f     -> killRange1 Lam i f
    Lit l       -> killRange1 Lit l
    Level l     -> killRange1 Level l
    Pi a b      -> killRange2 Pi a b
    Sort s      -> killRange1 Sort s
    DontCare mv -> killRange1 DontCare mv
    Shared p    -> Shared $ updatePtr killRange p
    ExtLam{}    -> __IMPOSSIBLE__

instance KillRange Level where
  killRange (Max as) = killRange1 Max as

instance KillRange PlusLevel where
  killRange l@ClosedLevel{} = l
  killRange (Plus n l) = killRange1 (Plus n) l

instance KillRange LevelAtom where
  killRange (MetaLevel n as)   = killRange1 (MetaLevel n) as
  killRange (BlockedLevel m v) = killRange1 (BlockedLevel m) v
  killRange (NeutralLevel v)   = killRange1 NeutralLevel v
  killRange (UnreducedLevel v) = killRange1 UnreducedLevel v

instance KillRange Type where
  killRange (El s v) = killRange2 El s v

instance KillRange Sort where
  killRange s = case s of
    Prop       -> Prop
    Inf        -> Inf
    Type a     -> killRange1 Type a
    DLub s1 s2 -> killRange2 DLub s1 s2

instance KillRange Pattern where
  killRange p =
    case p of
      VarP{}           -> p
      DotP v           -> killRange1 DotP v
      ConP con info ps -> killRange3 ConP con info ps
      LitP l           -> killRange1 LitP l
      ProjP q          -> killRange1 ProjP q

instance KillRange Permutation where
  killRange = id

instance KillRange Clause where
  killRange (Clause r tel perm ps body t) = killRange6 Clause r tel perm ps body t

instance KillRange a => KillRange (ClauseBodyF a) where
  killRange = fmap killRange

instance KillRange a => KillRange (Tele a) where
  killRange = fmap killRange

instance KillRange a => KillRange (Blocked a) where
  killRange = fmap killRange

instance KillRange a => KillRange (Abs a) where
  killRange = fmap killRange

instance KillRange a => KillRange (Elim' a) where
  killRange = fmap killRange

---------------------------------------------------------------------------
-- * UniverseBi instances.
---------------------------------------------------------------------------

instanceUniverseBiT' [] [t| (([Type], [Clause]), Pattern) |]
instanceUniverseBiT' [] [t| (Args, Pattern)               |]
instanceUniverseBiT' [] [t| (Elims, Pattern)              |] -- ?
instanceUniverseBiT' [] [t| (([Type], [Clause]), Term)    |]
instanceUniverseBiT' [] [t| (Args, Term)                  |]
instanceUniverseBiT' [] [t| (Elims, Term)                 |] -- ?
instanceUniverseBiT' [] [t| ([Term], Term)                |]

-----------------------------------------------------------------------------
-- * Simple pretty printing
-----------------------------------------------------------------------------

showTerm :: Term -> String
showTerm = show . pretty

instance Pretty Term where
  prettyPrec p v =
    case ignoreSharing v of
      Var x els -> text ("@" ++ show x) `pApp` els
      Lam _ b   ->
        mparens (p > 0) $
        sep [ text ("λ " ++ show (absName b) ++ " ->")
            , nest 2 $ pretty (unAbs b) ]
      Lit l                -> pretty l
      Def q els            -> text (show q) `pApp` els
      Con c vs             -> text (show $ conName c) `pApp` map Apply vs
      Pi a (NoAbs _ b)     -> mparens (p > 0) $
        sep [ prettyPrec 1 (unDom a) <+> text "->"
            , nest 2 $ pretty b ]
      Pi a b               -> mparens (p > 0) $
        sep [ pDom (domInfo a) (text (absName b) <+> text ":" <+> pretty (unDom a)) <+> text "->"
            , nest 2 $ pretty (unAbs b) ]
      Sort s      -> pretty s
      Level l     -> pretty l
      MetaV x els -> text (show x) `pApp` els
      DontCare v  -> pretty v
      Shared{}    -> __IMPOSSIBLE__
      ExtLam{}    -> __IMPOSSIBLE__
    where
      pApp d els = mparens (not (null els) && p > 9) $
                   d <+> fsep (map (prettyPrec 10) els)

      pDom i =
        case getHiding i of
          NotHidden -> parens
          Hidden    -> braces
          Instance  -> braces . braces

instance Pretty Level where
  prettyPrec p (Max as) =
    case as of
      []  -> prettyPrec p (ClosedLevel 0)
      [a] -> prettyPrec p a
      _   -> mparens (p > 9) $ List.foldr1 (\a b -> text "lub" <+> a <+> b) $ map (prettyPrec 10) as

instance Pretty PlusLevel where
  prettyPrec p l =
    case l of
      ClosedLevel n -> sucs p n $ \_ -> text "lzero"
      Plus n a      -> sucs p n $ \p -> prettyPrec p a
    where
      sucs p 0 d = d p
      sucs p n d = mparens (p > 9) $ text "lsuc" <+> sucs 10 (n - 1) d

instance Pretty LevelAtom where
  prettyPrec p a =
    case a of
      MetaLevel x els  -> prettyPrec p (MetaV x els)
      BlockedLevel _ v -> prettyPrec p v
      NeutralLevel v   -> prettyPrec p v
      UnreducedLevel v -> prettyPrec p v

instance Pretty Sort where
  prettyPrec p s =
    case s of
      Type (Max []) -> text "Set"
      Type (Max [ClosedLevel n]) -> text $ "Set" ++ show n
      Type l -> mparens (p > 9) $ text "Set" <+> prettyPrec 10 l
      Prop -> text "Prop"
      Inf -> text "Setω"
      DLub s b -> mparens (p > 9) $
        text "dlub" <+> prettyPrec 10 s
                    <+> parens (sep [ text ("λ " ++ show (absName b) ++ " ->")
                                    , nest 2 $ pretty (unAbs b) ])

instance Pretty Type where
  prettyPrec p (El _ a) = prettyPrec p a

instance Pretty Elim where
  prettyPrec p (Apply v) = prettyPrec p v
  prettyPrec _ (Proj x)  = text ("." ++ show x)

instance Pretty a => Pretty (Arg a) where
  prettyPrec p a =
    ($ unArg a) $
    case getHiding a of
      NotHidden -> prettyPrec p
      Hidden    -> braces . pretty
      Instance  -> braces . braces . pretty