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path: root/compiler/GHC/Hs/Expr.hs
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{-# LANGUAGE CPP                       #-}
{-# LANGUAGE ConstraintKinds           #-}
{-# LANGUAGE DataKinds                 #-}
{-# LANGUAGE DeriveDataTypeable        #-}
{-# LANGUAGE ExistentialQuantification #-}
{-# LANGUAGE FlexibleContexts          #-}
{-# LANGUAGE FlexibleInstances         #-}
{-# LANGUAGE LambdaCase                #-}
{-# LANGUAGE MultiParamTypeClasses     #-}
{-# LANGUAGE ScopedTypeVariables       #-}
{-# LANGUAGE StandaloneDeriving        #-}
{-# LANGUAGE TypeApplications          #-}
{-# LANGUAGE TypeFamilyDependencies    #-}
{-# LANGUAGE UndecidableInstances #-} -- Wrinkle in Note [Trees That Grow]
                                      -- in module Language.Haskell.Syntax.Extension

{-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-}
{-# OPTIONS_GHC -Wno-orphans #-} -- Outputable

{-
(c) The University of Glasgow 2006
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
-}

-- | Abstract Haskell syntax for expressions.
module GHC.Hs.Expr
  ( module Language.Haskell.Syntax.Expr
  , module GHC.Hs.Expr
  ) where

import Language.Haskell.Syntax.Expr

-- friends:
import GHC.Prelude

import GHC.Hs.Decls
import GHC.Hs.Pat
import GHC.Hs.Lit
import Language.Haskell.Syntax.Extension
import GHC.Hs.Extension
import GHC.Hs.Type
import GHC.Hs.Binds
import GHC.Parser.Annotation

-- others:
import GHC.Tc.Types.Evidence
import GHC.Core.DataCon (FieldLabelString)
import GHC.Types.Name
import GHC.Types.Name.Set
import GHC.Types.Basic
import GHC.Types.Fixity
import GHC.Types.SourceText
import GHC.Types.SrcLoc
import GHC.Types.Tickish (CoreTickish)
import GHC.Types.Var( InvisTVBinder )
import GHC.Core.ConLike
import GHC.Unit.Module (ModuleName)
import GHC.Utils.Misc
import GHC.Utils.Outputable
import GHC.Utils.Panic
import GHC.Utils.Panic.Plain
import GHC.Data.FastString
import GHC.Core.Type
import GHC.Builtin.Types (mkTupleStr)
import GHC.Tc.Utils.TcType (TcType)
import {-# SOURCE #-} GHC.Tc.Types (TcLclEnv)

-- libraries:
import Data.Data hiding (Fixity(..))
import qualified Data.Data as Data (Fixity(..))
import qualified Data.Kind
import Data.Maybe (isJust)
import Data.Foldable ( toList )

{- *********************************************************************
*                                                                      *
                Expressions proper
*                                                                      *
********************************************************************* -}

-- | Post-Type checking Expression
--
-- PostTcExpr is an evidence expression attached to the syntax tree by the
-- type checker (c.f. postTcType).
type PostTcExpr  = HsExpr GhcTc

-- | Post-Type checking Table
--
-- We use a PostTcTable where there are a bunch of pieces of evidence, more
-- than is convenient to keep individually.
type PostTcTable = [(Name, PostTcExpr)]

-------------------------

-- Defining SyntaxExpr in two stages allows for better type inference, because
-- we can declare SyntaxExprGhc to be injective (and closed). Without injectivity,
-- noSyntaxExpr would be ambiguous.
type instance SyntaxExpr (GhcPass p) = SyntaxExprGhc p

type family SyntaxExprGhc (p :: Pass) = (r :: Data.Kind.Type) | r -> p where
  SyntaxExprGhc 'Parsed      = NoExtField
  SyntaxExprGhc 'Renamed     = SyntaxExprRn
  SyntaxExprGhc 'Typechecked = SyntaxExprTc

-- | The function to use in rebindable syntax. See Note [NoSyntaxExpr].
data SyntaxExprRn = SyntaxExprRn (HsExpr GhcRn)
    -- Why is the payload not just a Name?
    -- See Note [Monad fail : Rebindable syntax, overloaded strings] in "GHC.Rename.Expr"
                  | NoSyntaxExprRn

-- | An expression with wrappers, used for rebindable syntax
--
-- This should desugar to
--
-- > syn_res_wrap $ syn_expr (syn_arg_wraps[0] arg0)
-- >                         (syn_arg_wraps[1] arg1) ...
--
-- where the actual arguments come from elsewhere in the AST.
data SyntaxExprTc = SyntaxExprTc { syn_expr      :: HsExpr GhcTc
                                 , syn_arg_wraps :: [HsWrapper]
                                 , syn_res_wrap  :: HsWrapper }
                  | NoSyntaxExprTc  -- See Note [NoSyntaxExpr]

-- | This is used for rebindable-syntax pieces that are too polymorphic
-- for tcSyntaxOp (trS_fmap and the mzip in ParStmt)
noExpr :: HsExpr (GhcPass p)
noExpr = HsLit noComments (HsString (SourceText  "noExpr") (fsLit "noExpr"))

noSyntaxExpr :: forall p. IsPass p => SyntaxExpr (GhcPass p)
                              -- Before renaming, and sometimes after
                              -- See Note [NoSyntaxExpr]
noSyntaxExpr = case ghcPass @p of
  GhcPs -> noExtField
  GhcRn -> NoSyntaxExprRn
  GhcTc -> NoSyntaxExprTc

-- | Make a 'SyntaxExpr GhcRn' from an expression
-- Used only in getMonadFailOp.
-- See Note [Monad fail : Rebindable syntax, overloaded strings] in "GHC.Rename.Expr"
mkSyntaxExpr :: HsExpr GhcRn -> SyntaxExprRn
mkSyntaxExpr = SyntaxExprRn

-- | Make a 'SyntaxExpr' from a 'Name' (the "rn" is because this is used in the
-- renamer).
mkRnSyntaxExpr :: Name -> SyntaxExprRn
mkRnSyntaxExpr name = SyntaxExprRn $ HsVar noExtField $ noLocA name

instance Outputable SyntaxExprRn where
  ppr (SyntaxExprRn expr) = ppr expr
  ppr NoSyntaxExprRn      = text "<no syntax expr>"

instance Outputable SyntaxExprTc where
  ppr (SyntaxExprTc { syn_expr      = expr
                    , syn_arg_wraps = arg_wraps
                    , syn_res_wrap  = res_wrap })
    = sdocOption sdocPrintExplicitCoercions $ \print_co ->
      getPprDebug $ \debug ->
      if debug || print_co
      then ppr expr <> braces (pprWithCommas ppr arg_wraps)
                    <> braces (ppr res_wrap)
      else ppr expr

  ppr NoSyntaxExprTc = text "<no syntax expr>"

-- | Extra data fields for a 'RecordUpd', added by the type checker
data RecordUpdTc = RecordUpdTc
      { rupd_cons :: [ConLike]
                -- Filled in by the type checker to the
                -- _non-empty_ list of DataCons that have
                -- all the upd'd fields

      , rupd_in_tys  :: [Type]  -- Argument types of *input* record type
      , rupd_out_tys :: [Type]  --             and  *output* record type
                -- For a data family, these are the type args of the
                -- /representation/ type constructor

      , rupd_wrap :: HsWrapper  -- See Note [Record Update HsWrapper]
      }

-- | HsWrap appears only in typechecker output
data HsWrap hs_syn = HsWrap HsWrapper      -- the wrapper
                            (hs_syn GhcTc) -- the thing that is wrapped

deriving instance (Data (hs_syn GhcTc), Typeable hs_syn) => Data (HsWrap hs_syn)

-- ---------------------------------------------------------------------

{-
Note [The life cycle of a TH quotation]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When desugaring a bracket (aka quotation), we want to produce Core
code that, when run, will produce the TH syntax tree for the quotation.
To that end, we want to desugar /renamed/ but not /typechecked/ code;
the latter is cluttered with the typechecker's elaboration that should
not appear in the TH syntax tree. So in (HsExpr GhcTc) tree, we must
have a (HsExpr GhcRn) for the quotation itself.

As such, when typechecking both typed and untyped brackets,
we keep a /renamed/ bracket in the extension field.

The HsBracketTc, the GhcTc ext field for both brackets, contains:
  - The renamed quote :: HsQuote GhcRn -- for the desugarer
  - [PendingTcSplice]
  - The type of the quote
  - Maybe QuoteWrapper

Note that (HsBracketTc) stores the untyped (HsQuote GhcRn) for both typed and
untyped brackets. They are treated uniformly by the desugarer, and we can
easily construct untyped brackets from typed ones (with ExpBr).

Typed quotes
~~~~~~~~~~~~
Here is the life cycle of a /typed/ quote [|| e ||], whose datacon is
  HsTypedBracket   (XTypedBracket p)   (LHsExpr p)

  In pass p   (XTypedBracket p)       (LHsExpr p)
  -------------------------------------------
  GhcPs   Annotations only            LHsExpr GhcPs
  GhcRn   Annotations only            LHsExpr GhcRn
  GhcTc   HsBracketTc                 LHsExpr GhcTc: unused!

Note that in the GhcTc tree, the second field (HsExpr GhcTc)
is entirely unused; the desugarer uses the (HsExpr GhcRn) from the
first field.

Untyped quotes
~~~~~~~~~~~~~~
Here is the life cycle of an /untyped/ quote, whose datacon is
   HsUntypedBracket (XUntypedBracket p) (HsQuote p)

Here HsQuote is a sum-type of expressions [| e |], patterns [| p |],
types [| t |] etc.

  In pass p   (XUntypedBracket p)          (HsQuote p)
  -------------------------------------------------------
  GhcPs   Annotations only                 HsQuote GhcPs
  GhcRn   Annotations, [PendingRnSplice]   HsQuote GhcRn
  GhcTc   HsBracketTc                      HsQuote GhcTc: unused!

The difficulty is: the typechecker does not typecheck the body of an
untyped quote, so how do we make a (HsQuote GhcTc) to put in the
second field?

Answer: we use the extension constructor of HsQuote, XQuote, and make
all the other constructors into DataConCantHappen.  That is, the only
non-bottom value of type (HsQuote GhcTc) is (XQuote noExtField). Hence
the instances
  type instance XExpBr GhcTc = DataConCantHappen
  ...etc...

See the related Note [How brackets and nested splices are handled] in GHC.Tc.Gen.Splice
-}

data HsBracketTc = HsBracketTc
  { brack_renamed_quote   :: (HsQuote GhcRn)      -- See Note [The life cycle of a TH quotation]
  , brack_ty              :: Type
  , brack_quote_wrapper   :: (Maybe QuoteWrapper) -- The wrapper to apply type and dictionary argument to the quote.
  , brack_pending_splices :: [PendingTcSplice]    -- Output of the type checker is the *original*
                                                  -- renamed expression, plus
                                                  -- _typechecked_ splices to be
                                                  -- pasted back in by the desugarer
  }

type instance XTypedBracket GhcPs = EpAnn [AddEpAnn]
type instance XTypedBracket GhcRn = NoExtField
type instance XTypedBracket GhcTc = HsBracketTc
type instance XUntypedBracket GhcPs = EpAnn [AddEpAnn]
type instance XUntypedBracket GhcRn = [PendingRnSplice] -- See Note [Pending Splices]
                                                        -- Output of the renamer is the *original* renamed expression,
                                                        -- plus _renamed_ splices to be type checked
type instance XUntypedBracket GhcTc = HsBracketTc

-- ---------------------------------------------------------------------

-- API Annotations types

data EpAnnHsCase = EpAnnHsCase
      { hsCaseAnnCase :: EpaLocation
      , hsCaseAnnOf   :: EpaLocation
      , hsCaseAnnsRest :: [AddEpAnn]
      } deriving Data

data EpAnnUnboundVar = EpAnnUnboundVar
     { hsUnboundBackquotes :: (EpaLocation, EpaLocation)
     , hsUnboundHole       :: EpaLocation
     } deriving Data

type instance XVar           (GhcPass _) = NoExtField

-- Record selectors at parse time are HsVar; they convert to HsRecSel
-- on renaming.
type instance XRecSel              GhcPs = DataConCantHappen
type instance XRecSel              GhcRn = NoExtField
type instance XRecSel              GhcTc = NoExtField

type instance XLam           (GhcPass _) = NoExtField

-- OverLabel not present in GhcTc pass; see GHC.Rename.Expr
-- Note [Handling overloaded and rebindable constructs]
type instance XOverLabel     GhcPs = EpAnnCO
type instance XOverLabel     GhcRn = EpAnnCO
type instance XOverLabel     GhcTc = DataConCantHappen

-- ---------------------------------------------------------------------

type instance XVar           (GhcPass _) = NoExtField

type instance XUnboundVar    GhcPs = EpAnn EpAnnUnboundVar
type instance XUnboundVar    GhcRn = NoExtField
type instance XUnboundVar    GhcTc = HoleExprRef
  -- We really don't need the whole HoleExprRef; just the IORef EvTerm
  -- would be enough. But then deriving a Data instance becomes impossible.
  -- Much, much easier just to define HoleExprRef with a Data instance and
  -- store the whole structure.

type instance XIPVar         GhcPs = EpAnnCO
type instance XIPVar         GhcRn = EpAnnCO
type instance XIPVar         GhcTc = DataConCantHappen
type instance XOverLitE      (GhcPass _) = EpAnnCO
type instance XLitE          (GhcPass _) = EpAnnCO

type instance XLam           (GhcPass _) = NoExtField

type instance XLamCase       (GhcPass _) = EpAnn [AddEpAnn]
type instance XApp           (GhcPass _) = EpAnnCO

type instance XAppTypeE      GhcPs = SrcSpan -- Where the `@` lives
type instance XAppTypeE      GhcRn = NoExtField
type instance XAppTypeE      GhcTc = Type

-- OpApp not present in GhcTc pass; see GHC.Rename.Expr
-- Note [Handling overloaded and rebindable constructs]
type instance XOpApp         GhcPs = EpAnn [AddEpAnn]
type instance XOpApp         GhcRn = Fixity
type instance XOpApp         GhcTc = DataConCantHappen

-- SectionL, SectionR not present in GhcTc pass; see GHC.Rename.Expr
-- Note [Handling overloaded and rebindable constructs]
type instance XSectionL      GhcPs = EpAnnCO
type instance XSectionR      GhcPs = EpAnnCO
type instance XSectionL      GhcRn = EpAnnCO
type instance XSectionR      GhcRn = EpAnnCO
type instance XSectionL      GhcTc = DataConCantHappen
type instance XSectionR      GhcTc = DataConCantHappen


type instance XNegApp        GhcPs = EpAnn [AddEpAnn]
type instance XNegApp        GhcRn = NoExtField
type instance XNegApp        GhcTc = NoExtField

type instance XPar           (GhcPass _) = EpAnnCO

type instance XExplicitTuple GhcPs = EpAnn [AddEpAnn]
type instance XExplicitTuple GhcRn = NoExtField
type instance XExplicitTuple GhcTc = NoExtField

type instance XExplicitSum   GhcPs = EpAnn AnnExplicitSum
type instance XExplicitSum   GhcRn = NoExtField
type instance XExplicitSum   GhcTc = [Type]

type instance XCase          GhcPs = EpAnn EpAnnHsCase
type instance XCase          GhcRn = NoExtField
type instance XCase          GhcTc = NoExtField

type instance XIf            GhcPs = EpAnn AnnsIf
type instance XIf            GhcRn = NoExtField
type instance XIf            GhcTc = NoExtField

type instance XMultiIf       GhcPs = EpAnn [AddEpAnn]
type instance XMultiIf       GhcRn = NoExtField
type instance XMultiIf       GhcTc = Type

type instance XLet           GhcPs = EpAnnCO
type instance XLet           GhcRn = NoExtField
type instance XLet           GhcTc = NoExtField

type instance XDo            GhcPs = EpAnn AnnList
type instance XDo            GhcRn = NoExtField
type instance XDo            GhcTc = Type

type instance XExplicitList  GhcPs = EpAnn AnnList
type instance XExplicitList  GhcRn = NoExtField
type instance XExplicitList  GhcTc = Type
-- GhcPs: ExplicitList includes all source-level
--   list literals, including overloaded ones
-- GhcRn and GhcTc: ExplicitList used only for list literals
--   that denote Haskell's built-in lists.  Overloaded lists
--   have been expanded away in the renamer
-- See Note [Handling overloaded and rebindable constructs]
-- in  GHC.Rename.Expr

type instance XRecordCon     GhcPs = EpAnn [AddEpAnn]
type instance XRecordCon     GhcRn = NoExtField
type instance XRecordCon     GhcTc = PostTcExpr   -- Instantiated constructor function

type instance XRecordUpd     GhcPs = EpAnn [AddEpAnn]
type instance XRecordUpd     GhcRn = NoExtField
type instance XRecordUpd     GhcTc = RecordUpdTc

type instance XGetField     GhcPs = EpAnnCO
type instance XGetField     GhcRn = NoExtField
type instance XGetField     GhcTc = DataConCantHappen
-- HsGetField is eliminated by the renamer. See [Handling overloaded
-- and rebindable constructs].

type instance XProjection     GhcPs = EpAnn AnnProjection
type instance XProjection     GhcRn = NoExtField
type instance XProjection     GhcTc = DataConCantHappen
-- HsProjection is eliminated by the renamer. See [Handling overloaded
-- and rebindable constructs].

type instance XExprWithTySig GhcPs = EpAnn [AddEpAnn]
type instance XExprWithTySig GhcRn = NoExtField
type instance XExprWithTySig GhcTc = NoExtField

type instance XArithSeq      GhcPs = EpAnn [AddEpAnn]
type instance XArithSeq      GhcRn = NoExtField
type instance XArithSeq      GhcTc = PostTcExpr

type instance XSpliceE       (GhcPass _) = EpAnnCO
type instance XProc          (GhcPass _) = EpAnn [AddEpAnn]

type instance XStatic        GhcPs = EpAnn [AddEpAnn]
type instance XStatic        GhcRn = NameSet
type instance XStatic        GhcTc = (NameSet, Type)
  -- Free variables and type of expression, this is stored for convenience as wiring in
  -- StaticPtr is a bit tricky (see #20150)

type instance XPragE         (GhcPass _) = NoExtField

type instance Anno [LocatedA ((StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (body (GhcPass pr)))))] = SrcSpanAnnL
type instance Anno (StmtLR GhcRn GhcRn (LocatedA (body GhcRn))) = SrcSpanAnnA

data AnnExplicitSum
  = AnnExplicitSum {
      aesOpen       :: EpaLocation,
      aesBarsBefore :: [EpaLocation],
      aesBarsAfter  :: [EpaLocation],
      aesClose      :: EpaLocation
      } deriving Data

data AnnFieldLabel
  = AnnFieldLabel {
      afDot :: Maybe EpaLocation
      } deriving Data

data AnnProjection
  = AnnProjection {
      apOpen  :: EpaLocation, -- ^ '('
      apClose :: EpaLocation  -- ^ ')'
      } deriving Data

data AnnsIf
  = AnnsIf {
      aiIf       :: EpaLocation,
      aiThen     :: EpaLocation,
      aiElse     :: EpaLocation,
      aiThenSemi :: Maybe EpaLocation,
      aiElseSemi :: Maybe EpaLocation
      } deriving Data

-- ---------------------------------------------------------------------

type instance XSCC           (GhcPass _) = EpAnn AnnPragma
type instance XXPragE        (GhcPass _) = DataConCantHappen

type instance XCDotFieldOcc (GhcPass _) = EpAnn AnnFieldLabel
type instance XXDotFieldOcc (GhcPass _) = DataConCantHappen

type instance XPresent         (GhcPass _) = EpAnn [AddEpAnn]

type instance XMissing         GhcPs = EpAnn EpaLocation
type instance XMissing         GhcRn = NoExtField
type instance XMissing         GhcTc = Scaled Type

type instance XXTupArg         (GhcPass _) = DataConCantHappen

tupArgPresent :: HsTupArg (GhcPass p) -> Bool
tupArgPresent (Present {}) = True
tupArgPresent (Missing {}) = False


{- *********************************************************************
*                                                                      *
            XXExpr: the extension constructor of HsExpr
*                                                                      *
********************************************************************* -}

type instance XXExpr GhcPs = DataConCantHappen
type instance XXExpr GhcRn = HsExpansion (HsExpr GhcRn) (HsExpr GhcRn)
type instance XXExpr GhcTc = XXExprGhcTc
-- HsExpansion: see Note [Rebindable syntax and HsExpansion] below


data XXExprGhcTc
  = WrapExpr        -- Type and evidence application and abstractions
      {-# UNPACK #-} !(HsWrap HsExpr)

  | ExpansionExpr   -- See Note [Rebindable syntax and HsExpansion] below
      {-# UNPACK #-} !(HsExpansion (HsExpr GhcRn) (HsExpr GhcTc))

  | ConLikeTc      -- Result of typechecking a data-con
                   -- See Note [Typechecking data constructors] in
                   --     GHC.Tc.Gen.Head
                   -- The two arguments describe how to eta-expand
                   -- the data constructor when desugaring
        ConLike [InvisTVBinder] [Scaled TcType]

  ---------------------------------------
  -- Haskell program coverage (Hpc) Support

  | HsTick
     CoreTickish
     (LHsExpr GhcTc)                    -- sub-expression

  | HsBinTick
     Int                                -- module-local tick number for True
     Int                                -- module-local tick number for False
     (LHsExpr GhcTc)                    -- sub-expression


{- *********************************************************************
*                                                                      *
            Pretty-printing expressions
*                                                                      *
********************************************************************* -}

instance (OutputableBndrId p) => Outputable (HsExpr (GhcPass p)) where
    ppr expr = pprExpr expr

-----------------------
-- pprExpr, pprLExpr, pprBinds call pprDeeper;
-- the underscore versions do not
pprLExpr :: (OutputableBndrId p) => LHsExpr (GhcPass p) -> SDoc
pprLExpr (L _ e) = pprExpr e

pprExpr :: (OutputableBndrId p) => HsExpr (GhcPass p) -> SDoc
pprExpr e | isAtomicHsExpr e || isQuietHsExpr e =            ppr_expr e
          | otherwise                           = pprDeeper (ppr_expr e)

isQuietHsExpr :: HsExpr id -> Bool
-- Parentheses do display something, but it gives little info and
-- if we go deeper when we go inside them then we get ugly things
-- like (...)
isQuietHsExpr (HsPar {})        = True
-- applications don't display anything themselves
isQuietHsExpr (HsApp {})        = True
isQuietHsExpr (HsAppType {})    = True
isQuietHsExpr (OpApp {})        = True
isQuietHsExpr _ = False

pprBinds :: (OutputableBndrId idL, OutputableBndrId idR)
         => HsLocalBindsLR (GhcPass idL) (GhcPass idR) -> SDoc
pprBinds b = pprDeeper (ppr b)

-----------------------
ppr_lexpr :: (OutputableBndrId p) => LHsExpr (GhcPass p) -> SDoc
ppr_lexpr e = ppr_expr (unLoc e)

ppr_expr :: forall p. (OutputableBndrId p)
         => HsExpr (GhcPass p) -> SDoc
ppr_expr (HsVar _ (L _ v))   = pprPrefixOcc v
ppr_expr (HsUnboundVar _ uv) = pprPrefixOcc uv
ppr_expr (HsRecSel _ f)      = pprPrefixOcc f
ppr_expr (HsIPVar _ v)       = ppr v
ppr_expr (HsOverLabel _ l)   = char '#' <> ppr l
ppr_expr (HsLit _ lit)       = ppr lit
ppr_expr (HsOverLit _ lit)   = ppr lit
ppr_expr (HsPar _ _ e _)     = parens (ppr_lexpr e)

ppr_expr (HsPragE _ prag e) = sep [ppr prag, ppr_lexpr e]

ppr_expr e@(HsApp {})        = ppr_apps e []
ppr_expr e@(HsAppType {})    = ppr_apps e []

ppr_expr (OpApp _ e1 op e2)
  | Just pp_op <- ppr_infix_expr (unLoc op)
  = pp_infixly pp_op
  | otherwise
  = pp_prefixly

  where
    pp_e1 = pprDebugParendExpr opPrec e1   -- In debug mode, add parens
    pp_e2 = pprDebugParendExpr opPrec e2   -- to make precedence clear

    pp_prefixly
      = hang (ppr op) 2 (sep [pp_e1, pp_e2])

    pp_infixly pp_op
      = hang pp_e1 2 (sep [pp_op, nest 2 pp_e2])

ppr_expr (NegApp _ e _) = char '-' <+> pprDebugParendExpr appPrec e

ppr_expr (SectionL _ expr op)
  | Just pp_op <- ppr_infix_expr (unLoc op)
  = pp_infixly pp_op
  | otherwise
  = pp_prefixly
  where
    pp_expr = pprDebugParendExpr opPrec expr

    pp_prefixly = hang (hsep [text " \\ x_ ->", ppr op])
                       4 (hsep [pp_expr, text "x_ )"])

    pp_infixly v = (sep [pp_expr, v])

ppr_expr (SectionR _ op expr)
  | Just pp_op <- ppr_infix_expr (unLoc op)
  = pp_infixly pp_op
  | otherwise
  = pp_prefixly
  where
    pp_expr = pprDebugParendExpr opPrec expr

    pp_prefixly = hang (hsep [text "( \\ x_ ->", ppr op, text "x_"])
                       4 (pp_expr <> rparen)

    pp_infixly v = sep [v, pp_expr]

ppr_expr (ExplicitTuple _ exprs boxity)
    -- Special-case unary boxed tuples so that they are pretty-printed as
    -- `Solo x`, not `(x)`
  | [Present _ expr] <- exprs
  , Boxed <- boxity
  = hsep [text (mkTupleStr Boxed 1), ppr expr]
  | otherwise
  = tupleParens (boxityTupleSort boxity) (fcat (ppr_tup_args exprs))
  where
    ppr_tup_args []               = []
    ppr_tup_args (Present _ e : es) = (ppr_lexpr e <> punc es) : ppr_tup_args es
    ppr_tup_args (Missing _   : es) = punc es : ppr_tup_args es

    punc (Present {} : _) = comma <> space
    punc (Missing {} : _) = comma
    punc (XTupArg {} : _) = comma <> space
    punc []               = empty

ppr_expr (ExplicitSum _ alt arity expr)
  = text "(#" <+> ppr_bars (alt - 1) <+> ppr expr <+> ppr_bars (arity - alt) <+> text "#)"
  where
    ppr_bars n = hsep (replicate n (char '|'))

ppr_expr (HsLam _ matches)
  = pprMatches matches

ppr_expr (HsLamCase _ matches)
  = sep [ sep [text "\\case"],
          nest 2 (pprMatches matches) ]

ppr_expr (HsCase _ expr matches@(MG { mg_alts = L _ alts }))
  = sep [ sep [text "case", nest 4 (ppr expr), text "of"],
          pp_alts ]
  where
    pp_alts | null alts = text "{}"
            | otherwise = nest 2 (pprMatches matches)

ppr_expr (HsIf _ e1 e2 e3)
  = sep [hsep [text "if", nest 2 (ppr e1), text "then"],
         nest 4 (ppr e2),
         text "else",
         nest 4 (ppr e3)]

ppr_expr (HsMultiIf _ alts)
  = hang (text "if") 3  (vcat (map ppr_alt alts))
  where ppr_alt (L _ (GRHS _ guards expr)) =
          hang vbar 2 (ppr_one one_alt)
          where
            ppr_one [] = panic "ppr_exp HsMultiIf"
            ppr_one (h:t) = hang h 2 (sep t)
            one_alt = [ interpp'SP guards
                      , text "->" <+> pprDeeper (ppr expr) ]
        ppr_alt (L _ (XGRHS x)) = ppr x

-- special case: let ... in let ...
ppr_expr (HsLet _ _ binds _ expr@(L _ (HsLet _ _ _ _ _)))
  = sep [hang (text "let") 2 (hsep [pprBinds binds, text "in"]),
         ppr_lexpr expr]

ppr_expr (HsLet _ _ binds _ expr)
  = sep [hang (text "let") 2 (pprBinds binds),
         hang (text "in")  2 (ppr expr)]

ppr_expr (HsDo _ do_or_list_comp (L _ stmts)) = pprDo do_or_list_comp stmts

ppr_expr (ExplicitList _ exprs)
  = brackets (pprDeeperList fsep (punctuate comma (map ppr_lexpr exprs)))

ppr_expr (RecordCon { rcon_con = con, rcon_flds = rbinds })
  = hang pp_con 2 (ppr rbinds)
  where
    -- con :: ConLikeP (GhcPass p)
    -- so we need case analysis to know to print it
    pp_con = case ghcPass @p of
               GhcPs -> ppr con
               GhcRn -> ppr con
               GhcTc -> ppr con

ppr_expr (RecordUpd { rupd_expr = L _ aexp, rupd_flds = flds })
  = case flds of
      Left rbinds -> hang (ppr aexp) 2 (braces (fsep (punctuate comma (map ppr rbinds))))
      Right pbinds -> hang (ppr aexp) 2 (braces (fsep (punctuate comma (map ppr pbinds))))

ppr_expr (HsGetField { gf_expr = L _ fexp, gf_field = field })
  = ppr fexp <> dot <> ppr field

ppr_expr (HsProjection { proj_flds = flds }) = parens (hcat (dot : (punctuate dot (map ppr $ toList flds))))

ppr_expr (ExprWithTySig _ expr sig)
  = hang (nest 2 (ppr_lexpr expr) <+> dcolon)
         4 (ppr sig)

ppr_expr (ArithSeq _ _ info) = brackets (ppr info)

ppr_expr (HsSpliceE _ s)         = pprSplice s

ppr_expr (HsTypedBracket b e)
  = case ghcPass @p of
    GhcPs -> thTyBrackets (ppr e)
    GhcRn -> thTyBrackets (ppr e)
    GhcTc | HsBracketTc _  _ty _wrap ps <- b ->
      thTyBrackets (ppr e) `ppr_with_pending_tc_splices` ps
ppr_expr (HsUntypedBracket b q)
  = case ghcPass @p of
    GhcPs -> ppr q
    GhcRn -> case b of
      [] -> ppr q
      ps -> ppr q $$ text "pending(rn)" <+> ppr ps
    GhcTc | HsBracketTc rnq  _ty _wrap ps <- b ->
      ppr rnq `ppr_with_pending_tc_splices` ps

ppr_expr (HsProc _ pat (L _ (HsCmdTop _ cmd)))
  = hsep [text "proc", ppr pat, text "->", ppr cmd]

ppr_expr (HsStatic _ e)
  = hsep [text "static", ppr e]

ppr_expr (XExpr x) = case ghcPass @p of
#if __GLASGOW_HASKELL__ < 811
  GhcPs -> ppr x
#endif
  GhcRn -> ppr x
  GhcTc -> ppr x

instance Outputable XXExprGhcTc where
  ppr (WrapExpr (HsWrap co_fn e))
    = pprHsWrapper co_fn (\_parens -> pprExpr e)

  ppr (ExpansionExpr e)
    = ppr e -- e is an HsExpansion, we print the original
            -- expression (LHsExpr GhcPs), not the
            -- desugared one (LHsExpr GhcTc).

  ppr (ConLikeTc con _ _) = pprPrefixOcc con
   -- Used in error messages generated by
   -- the pattern match overlap checker

  ppr (HsTick tickish exp) =
    pprTicks (ppr exp) $
      ppr tickish <+> ppr_lexpr exp

  ppr (HsBinTick tickIdTrue tickIdFalse exp) =
    pprTicks (ppr exp) $
      hcat [text "bintick<",
            ppr tickIdTrue,
            text ",",
            ppr tickIdFalse,
            text ">(",
            ppr exp, text ")"]

ppr_infix_expr :: forall p. (OutputableBndrId p) => HsExpr (GhcPass p) -> Maybe SDoc
ppr_infix_expr (HsVar _ (L _ v))    = Just (pprInfixOcc v)
ppr_infix_expr (HsRecSel _ f)       = Just (pprInfixOcc f)
ppr_infix_expr (HsUnboundVar _ occ) = Just (pprInfixOcc occ)
ppr_infix_expr (XExpr x)            = case ghcPass @p of
#if __GLASGOW_HASKELL__ < 901
                                        GhcPs -> Nothing
#endif
                                        GhcRn -> ppr_infix_expr_rn x
                                        GhcTc -> ppr_infix_expr_tc x
ppr_infix_expr _ = Nothing

ppr_infix_expr_rn :: HsExpansion (HsExpr GhcRn) (HsExpr GhcRn) -> Maybe SDoc
ppr_infix_expr_rn (HsExpanded a _) = ppr_infix_expr a

ppr_infix_expr_tc :: XXExprGhcTc -> Maybe SDoc
ppr_infix_expr_tc (WrapExpr (HsWrap _ e))          = ppr_infix_expr e
ppr_infix_expr_tc (ExpansionExpr (HsExpanded a _)) = ppr_infix_expr a
ppr_infix_expr_tc (ConLikeTc {})                   = Nothing
ppr_infix_expr_tc (HsTick {})                      = Nothing
ppr_infix_expr_tc (HsBinTick {})                   = Nothing

ppr_apps :: (OutputableBndrId p)
         => HsExpr (GhcPass p)
         -> [Either (LHsExpr (GhcPass p)) (LHsWcType (NoGhcTc (GhcPass p)))]
         -> SDoc
ppr_apps (HsApp _ (L _ fun) arg)        args
  = ppr_apps fun (Left arg : args)
ppr_apps (HsAppType _ (L _ fun) arg)    args
  = ppr_apps fun (Right arg : args)
ppr_apps fun args = hang (ppr_expr fun) 2 (fsep (map pp args))
  where
    pp (Left arg)                             = ppr arg
    -- pp (Right (LHsWcTypeX (HsWC { hswc_body = L _ arg })))
    --   = char '@' <> pprHsType arg
    pp (Right arg)
      = text "@" <> ppr arg


pprDebugParendExpr :: (OutputableBndrId p)
                   => PprPrec -> LHsExpr (GhcPass p) -> SDoc
pprDebugParendExpr p expr
  = getPprDebug $ \case
      True  -> pprParendLExpr p expr
      False -> pprLExpr         expr

pprParendLExpr :: (OutputableBndrId p)
               => PprPrec -> LHsExpr (GhcPass p) -> SDoc
pprParendLExpr p (L _ e) = pprParendExpr p e

pprParendExpr :: (OutputableBndrId p)
              => PprPrec -> HsExpr (GhcPass p) -> SDoc
pprParendExpr p expr
  | hsExprNeedsParens p expr = parens (pprExpr expr)
  | otherwise                = pprExpr expr
        -- Using pprLExpr makes sure that we go 'deeper'
        -- I think that is usually (always?) right

-- | @'hsExprNeedsParens' p e@ returns 'True' if the expression @e@ needs
-- parentheses under precedence @p@.
hsExprNeedsParens :: forall p. IsPass p => PprPrec -> HsExpr (GhcPass p) -> Bool
hsExprNeedsParens prec = go
  where
    go :: HsExpr (GhcPass p) -> Bool
    go (HsVar{})                      = False
    go (HsUnboundVar{})               = False
    go (HsIPVar{})                    = False
    go (HsOverLabel{})                = False
    go (HsLit _ l)                    = hsLitNeedsParens prec l
    go (HsOverLit _ ol)               = hsOverLitNeedsParens prec ol
    go (HsPar{})                      = False
    go (HsApp{})                      = prec >= appPrec
    go (HsAppType {})                 = prec >= appPrec
    go (OpApp{})                      = prec >= opPrec
    go (NegApp{})                     = prec > topPrec
    go (SectionL{})                   = True
    go (SectionR{})                   = True
    -- Special-case unary boxed tuple applications so that they are
    -- parenthesized as `Identity (Solo x)`, not `Identity Solo x` (#18612)
    -- See Note [One-tuples] in GHC.Builtin.Types
    go (ExplicitTuple _ [Present{}] Boxed)
                                      = prec >= appPrec
    go (ExplicitTuple{})              = False
    go (ExplicitSum{})                = False
    go (HsLam{})                      = prec > topPrec
    go (HsLamCase{})                  = prec > topPrec
    go (HsCase{})                     = prec > topPrec
    go (HsIf{})                       = prec > topPrec
    go (HsMultiIf{})                  = prec > topPrec
    go (HsLet{})                      = prec > topPrec
    go (HsDo _ sc _)
      | isDoComprehensionContext sc   = False
      | otherwise                     = prec > topPrec
    go (ExplicitList{})               = False
    go (RecordUpd{})                  = False
    go (ExprWithTySig{})              = prec >= sigPrec
    go (ArithSeq{})                   = False
    go (HsPragE{})                    = prec >= appPrec
    go (HsSpliceE{})                  = False
    go (HsTypedBracket{})             = False
    go (HsUntypedBracket{})           = False
    go (HsProc{})                     = prec > topPrec
    go (HsStatic{})                   = prec >= appPrec
    go (RecordCon{})                  = False
    go (HsRecSel{})                   = False
    go (HsProjection{})               = True
    go (HsGetField{})                 = False
    go (XExpr x) = case ghcPass @p of
                     GhcTc -> go_x_tc x
                     GhcRn -> go_x_rn x
#if __GLASGOW_HASKELL__ <= 900
                     GhcPs -> True
#endif

    go_x_tc :: XXExprGhcTc -> Bool
    go_x_tc (WrapExpr (HsWrap _ e))          = hsExprNeedsParens prec e
    go_x_tc (ExpansionExpr (HsExpanded a _)) = hsExprNeedsParens prec a
    go_x_tc (ConLikeTc {})                   = False
    go_x_tc (HsTick _ (L _ e))               = hsExprNeedsParens prec e
    go_x_tc (HsBinTick _ _ (L _ e))          = hsExprNeedsParens prec e

    go_x_rn :: HsExpansion (HsExpr GhcRn) (HsExpr GhcRn) -> Bool
    go_x_rn (HsExpanded a _) = hsExprNeedsParens prec a


-- | Parenthesize an expression without token information
gHsPar :: LHsExpr (GhcPass id) -> HsExpr (GhcPass id)
gHsPar e = HsPar noAnn noHsTok e noHsTok

-- | @'parenthesizeHsExpr' p e@ checks if @'hsExprNeedsParens' p e@ is true,
-- and if so, surrounds @e@ with an 'HsPar'. Otherwise, it simply returns @e@.
parenthesizeHsExpr :: IsPass p => PprPrec -> LHsExpr (GhcPass p) -> LHsExpr (GhcPass p)
parenthesizeHsExpr p le@(L loc e)
  | hsExprNeedsParens p e = L loc (gHsPar le)
  | otherwise             = le

stripParensLHsExpr :: LHsExpr (GhcPass p) -> LHsExpr (GhcPass p)
stripParensLHsExpr (L _ (HsPar _ _ e _)) = stripParensLHsExpr e
stripParensLHsExpr e = e

stripParensHsExpr :: HsExpr (GhcPass p) -> HsExpr (GhcPass p)
stripParensHsExpr (HsPar _ _ (L _ e) _) = stripParensHsExpr e
stripParensHsExpr e = e

isAtomicHsExpr :: forall p. IsPass p => HsExpr (GhcPass p) -> Bool
-- True of a single token
isAtomicHsExpr (HsVar {})        = True
isAtomicHsExpr (HsLit {})        = True
isAtomicHsExpr (HsOverLit {})    = True
isAtomicHsExpr (HsIPVar {})      = True
isAtomicHsExpr (HsOverLabel {})  = True
isAtomicHsExpr (HsUnboundVar {}) = True
isAtomicHsExpr (HsRecSel{})      = True
isAtomicHsExpr (XExpr x)
  | GhcTc <- ghcPass @p          = go_x_tc x
  | GhcRn <- ghcPass @p          = go_x_rn x
  where
    go_x_tc (WrapExpr      (HsWrap _ e))     = isAtomicHsExpr e
    go_x_tc (ExpansionExpr (HsExpanded a _)) = isAtomicHsExpr a
    go_x_tc (ConLikeTc {})                   = True
    go_x_tc (HsTick {}) = False
    go_x_tc (HsBinTick {}) = False

    go_x_rn (HsExpanded a _) = isAtomicHsExpr a

isAtomicHsExpr _ = False

instance Outputable (HsPragE (GhcPass p)) where
  ppr (HsPragSCC _ st (StringLiteral stl lbl _)) =
    pprWithSourceText st (text "{-# SCC")
     -- no doublequotes if stl empty, for the case where the SCC was written
     -- without quotes.
    <+> pprWithSourceText stl (ftext lbl) <+> text "#-}"


{- *********************************************************************
*                                                                      *
             HsExpansion and rebindable syntax
*                                                                      *
********************************************************************* -}

{- Note [Rebindable syntax and HsExpansion]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We implement rebindable syntax (RS) support by performing a desugaring
in the renamer. We transform GhcPs expressions and patterns affected by
RS into the appropriate desugared form, but **annotated with the original
expression/pattern**.

Let us consider a piece of code like:

    {-# LANGUAGE RebindableSyntax #-}
    ifThenElse :: Char -> () -> () -> ()
    ifThenElse _ _ _ = ()
    x = if 'a' then () else True

The parsed AST for the RHS of x would look something like (slightly simplified):

    L locif (HsIf (L loca 'a') (L loctrue ()) (L locfalse True))

Upon seeing such an AST with RS on, we could transform it into a
mere function call, as per the RS rules, equivalent to the
following function application:

    ifThenElse 'a' () True

which doesn't typecheck. But GHC would report an error about
not being able to match the third argument's type (Bool) with the
expected type: (), in the expression _as desugared_, i.e in
the aforementioned function application. But the user never
wrote a function application! This would be pretty bad.

To remedy this, instead of transforming the original HsIf
node into mere applications of 'ifThenElse', we keep the
original 'if' expression around too, using the TTG
XExpr extension point to allow GHC to construct an
'HsExpansion' value that will keep track of the original
expression in its first field, and the desugared one in the
second field. The resulting renamed AST would look like:

    L locif (XExpr
      (HsExpanded
        (HsIf (L loca 'a')
              (L loctrue ())
              (L locfalse True)
        )
        (App (L generatedSrcSpan
                (App (L generatedSrcSpan
                        (App (L generatedSrcSpan (Var ifThenElse))
                             (L loca 'a')
                        )
                     )
                     (L loctrue ())
                )
             )
             (L locfalse True)
        )
      )
    )

When comes the time to typecheck the program, we end up calling
tcMonoExpr on the AST above. If this expression gives rise to
a type error, then it will appear in a context line and GHC
will pretty-print it using the 'Outputable (HsExpansion a b)'
instance defined below, which *only prints the original
expression*. This is the gist of the idea, but is not quite
enough to recover the error messages that we had with the
SyntaxExpr-based, typechecking/desugaring-to-core time
implementation of rebindable syntax. The key idea is to decorate
some elements of the desugared expression so as to be able to
give them a special treatment when typechecking the desugared
expression, to print a different context line or skip one
altogether.

Whenever we 'setSrcSpan' a 'generatedSrcSpan', we update a field in
TcLclEnv called 'tcl_in_gen_code', setting it to True, which indicates that we
entered generated code, i.e code fabricated by the compiler when rebinding some
syntax. If someone tries to push some error context line while that field is set
to True, the pushing won't actually happen and the context line is just dropped.
Once we 'setSrcSpan' a real span (for an expression that was in the original
source code), we set 'tcl_in_gen_code' back to False, indicating that we
"emerged from the generated code tunnel", and that the expressions we will be
processing are relevant to report in context lines again.

You might wonder why TcLclEnv has both
   tcl_loc         :: RealSrcSpan
   tcl_in_gen_code :: Bool
Could we not store a Maybe RealSrcSpan? The problem is that we still
generate constraints when processing generated code, and a CtLoc must
contain a RealSrcSpan -- otherwise, error messages might appear
without source locations. So tcl_loc keeps the RealSrcSpan of the last
location spotted that wasn't generated; it's as good as we're going to
get in generated code. Once we get to sub-trees that are not
generated, then we update the RealSrcSpan appropriately, and set the
tcl_in_gen_code Bool to False.

---

An overview of the constructs that are desugared in this way is laid out in
Note [Handling overloaded and rebindable constructs] in GHC.Rename.Expr.

A general recipe to follow this approach for new constructs could go as follows:

- Remove any GhcRn-time SyntaxExpr extensions to the relevant constructor for your
  construct, in HsExpr or related syntax data types.
- At renaming-time:
    - take your original node of interest (HsIf above)
    - rename its subexpressions/subpatterns (condition and true/false
      branches above)
    - construct the suitable "rebound"-and-renamed result (ifThenElse call
      above), where the 'SrcSpan' attached to any _fabricated node_ (the
      HsVar/HsApp nodes, above) is set to 'generatedSrcSpan'
    - take both the original node and that rebound-and-renamed result and wrap
      them into an expansion construct:
        for expressions, XExpr (HsExpanded <original node> <desugared>)
        for patterns, XPat (HsPatExpanded <original node> <desugared>)
 - At typechecking-time:
    - remove any logic that was previously dealing with your rebindable
      construct, typically involving [tc]SyntaxOp, SyntaxExpr and friends.
    - the XExpr (HsExpanded ... ...) case in tcExpr already makes sure that we
      typecheck the desugared expression while reporting the original one in
      errors
-}

{- Note [Overview of record dot syntax]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This is the note that explains all the moving parts for record dot
syntax.

The language extensions @OverloadedRecordDot@ and
@OverloadedRecordUpdate@ (providing "record dot syntax") are
implemented using the techniques of Note [Rebindable syntax and
HsExpansion].

When OverloadedRecordDot is enabled:
- Field selection expressions
  - e.g. foo.bar.baz
  - Have abstract syntax HsGetField
  - After renaming are XExpr (HsExpanded (HsGetField ...) (getField @"..."...)) expressions
- Field selector expressions e.g. (.x.y)
  - Have abstract syntax HsProjection
  - After renaming are XExpr (HsExpanded (HsProjection ...) ((getField @"...") . (getField @"...") . ...) expressions

When OverloadedRecordUpdate is enabled:
- Record update expressions
  - e.g. a{foo.bar=1, quux="corge", baz}
  - Have abstract syntax RecordUpd
    - With rupd_flds containting a Right
    - See Note [RecordDotSyntax field updates] (in Language.Haskell.Syntax.Expr)
  - After renaming are XExpr (HsExpanded (RecordUpd ...) (setField@"..." ...) expressions
    - Note that this is true for all record updates even for those that do not involve '.'

When OverloadedRecordDot is enabled and RebindableSyntax is not
enabled the name 'getField' is resolved to GHC.Records.getField. When
OverloadedRecordDot is enabled and RebindableSyntax is enabled the
name 'getField' is whatever in-scope name that is.

When OverloadedRecordUpd is enabled and RebindableSyntax is not
enabled it is an error for now (temporary while we wait on native
setField support; see
https://gitlab.haskell.org/ghc/ghc/-/issues/16232). When
OverloadedRecordUpd is enabled and RebindableSyntax is enabled the
names 'getField' and 'setField' are whatever in-scope names they are.
-}

-- See Note [Rebindable syntax and HsExpansion] just above.
data HsExpansion orig expanded
  = HsExpanded orig expanded
  deriving Data

-- | Just print the original expression (the @a@).
instance (Outputable a, Outputable b) => Outputable (HsExpansion a b) where
  ppr (HsExpanded orig expanded)
    = ifPprDebug (vcat [ppr orig, braces (text "Expansion:" <+> ppr expanded)])
                 (ppr orig)


{-
************************************************************************
*                                                                      *
\subsection{Commands (in arrow abstractions)}
*                                                                      *
************************************************************************
-}

type instance XCmdArrApp  GhcPs = EpAnn AddEpAnn
type instance XCmdArrApp  GhcRn = NoExtField
type instance XCmdArrApp  GhcTc = Type

type instance XCmdArrForm GhcPs = EpAnn AnnList
type instance XCmdArrForm GhcRn = NoExtField
type instance XCmdArrForm GhcTc = NoExtField

type instance XCmdApp     (GhcPass _) = EpAnnCO
type instance XCmdLam     (GhcPass _) = NoExtField
type instance XCmdPar     (GhcPass _) = EpAnnCO

type instance XCmdCase    GhcPs = EpAnn EpAnnHsCase
type instance XCmdCase    GhcRn = NoExtField
type instance XCmdCase    GhcTc = NoExtField

type instance XCmdLamCase (GhcPass _) = EpAnn [AddEpAnn]

type instance XCmdIf      GhcPs = EpAnn AnnsIf
type instance XCmdIf      GhcRn = NoExtField
type instance XCmdIf      GhcTc = NoExtField

type instance XCmdLet     GhcPs = EpAnnCO
type instance XCmdLet     GhcRn = NoExtField
type instance XCmdLet     GhcTc = NoExtField

type instance XCmdDo      GhcPs = EpAnn AnnList
type instance XCmdDo      GhcRn = NoExtField
type instance XCmdDo      GhcTc = Type

type instance XCmdWrap    (GhcPass _) = NoExtField

type instance XXCmd       GhcPs = DataConCantHappen
type instance XXCmd       GhcRn = DataConCantHappen
type instance XXCmd       GhcTc = HsWrap HsCmd

type instance Anno [LocatedA (StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (HsCmd (GhcPass pr))))]
  = SrcSpanAnnL

    -- If   cmd :: arg1 --> res
    --      wrap :: arg1 "->" arg2
    -- Then (XCmd (HsWrap wrap cmd)) :: arg2 --> res

data CmdTopTc
  = CmdTopTc Type    -- Nested tuple of inputs on the command's stack
             Type    -- return type of the command
             (CmdSyntaxTable GhcTc) -- See Note [CmdSyntaxTable]

type instance XCmdTop  GhcPs = NoExtField
type instance XCmdTop  GhcRn = CmdSyntaxTable GhcRn -- See Note [CmdSyntaxTable]
type instance XCmdTop  GhcTc = CmdTopTc

type instance XXCmdTop (GhcPass _) = DataConCantHappen

instance (OutputableBndrId p) => Outputable (HsCmd (GhcPass p)) where
    ppr cmd = pprCmd cmd

-----------------------
-- pprCmd and pprLCmd call pprDeeper;
-- the underscore versions do not
pprLCmd :: (OutputableBndrId p) => LHsCmd (GhcPass p) -> SDoc
pprLCmd (L _ c) = pprCmd c

pprCmd :: (OutputableBndrId p) => HsCmd (GhcPass p) -> SDoc
pprCmd c | isQuietHsCmd c =            ppr_cmd c
         | otherwise      = pprDeeper (ppr_cmd c)

isQuietHsCmd :: HsCmd id -> Bool
-- Parentheses do display something, but it gives little info and
-- if we go deeper when we go inside them then we get ugly things
-- like (...)
isQuietHsCmd (HsCmdPar {}) = True
-- applications don't display anything themselves
isQuietHsCmd (HsCmdApp {}) = True
isQuietHsCmd _ = False

-----------------------
ppr_lcmd :: (OutputableBndrId p) => LHsCmd (GhcPass p) -> SDoc
ppr_lcmd c = ppr_cmd (unLoc c)

ppr_cmd :: forall p. (OutputableBndrId p
                     ) => HsCmd (GhcPass p) -> SDoc
ppr_cmd (HsCmdPar _ _ c _) = parens (ppr_lcmd c)

ppr_cmd (HsCmdApp _ c e)
  = let (fun, args) = collect_args c [e] in
    hang (ppr_lcmd fun) 2 (sep (map ppr args))
  where
    collect_args (L _ (HsCmdApp _ fun arg)) args = collect_args fun (arg:args)
    collect_args fun args = (fun, args)

ppr_cmd (HsCmdLam _ matches)
  = pprMatches matches

ppr_cmd (HsCmdCase _ expr matches)
  = sep [ sep [text "case", nest 4 (ppr expr), text "of"],
          nest 2 (pprMatches matches) ]

ppr_cmd (HsCmdLamCase _ matches)
  = sep [ text "\\case", nest 2 (pprMatches matches) ]

ppr_cmd (HsCmdIf _ _ e ct ce)
  = sep [hsep [text "if", nest 2 (ppr e), text "then"],
         nest 4 (ppr ct),
         text "else",
         nest 4 (ppr ce)]

-- special case: let ... in let ...
ppr_cmd (HsCmdLet _ _ binds _ cmd@(L _ (HsCmdLet {})))
  = sep [hang (text "let") 2 (hsep [pprBinds binds, text "in"]),
         ppr_lcmd cmd]

ppr_cmd (HsCmdLet _ _ binds _ cmd)
  = sep [hang (text "let") 2 (pprBinds binds),
         hang (text "in")  2 (ppr cmd)]

ppr_cmd (HsCmdDo _ (L _ stmts))  = pprArrowExpr stmts

ppr_cmd (HsCmdArrApp _ arrow arg HsFirstOrderApp True)
  = hsep [ppr_lexpr arrow, larrowt, ppr_lexpr arg]
ppr_cmd (HsCmdArrApp _ arrow arg HsFirstOrderApp False)
  = hsep [ppr_lexpr arg, arrowt, ppr_lexpr arrow]
ppr_cmd (HsCmdArrApp _ arrow arg HsHigherOrderApp True)
  = hsep [ppr_lexpr arrow, larrowtt, ppr_lexpr arg]
ppr_cmd (HsCmdArrApp _ arrow arg HsHigherOrderApp False)
  = hsep [ppr_lexpr arg, arrowtt, ppr_lexpr arrow]

ppr_cmd (HsCmdArrForm _ (L _ op) ps_fix rn_fix args)
  | HsVar _ (L _ v) <- op
  = ppr_cmd_infix v
  | GhcTc <- ghcPass @p
  , XExpr (ConLikeTc c _ _) <- op
  = ppr_cmd_infix (conLikeName c)
  | otherwise
  = fall_through
  where
    fall_through = hang (text "(|" <+> ppr_expr op)
                      4 (sep (map (pprCmdArg.unLoc) args) <+> text "|)")

    ppr_cmd_infix :: OutputableBndr v => v -> SDoc
    ppr_cmd_infix v
      | [arg1, arg2] <- args
      , isJust rn_fix || ps_fix == Infix
      = hang (pprCmdArg (unLoc arg1))
           4 (sep [ pprInfixOcc v, pprCmdArg (unLoc arg2)])
      | otherwise
      = fall_through

ppr_cmd (XCmd x) = case ghcPass @p of
#if __GLASGOW_HASKELL__ < 811
  GhcPs -> ppr x
  GhcRn -> ppr x
#endif
  GhcTc -> case x of
    HsWrap w cmd -> pprHsWrapper w (\_ -> parens (ppr_cmd cmd))

pprCmdArg :: (OutputableBndrId p) => HsCmdTop (GhcPass p) -> SDoc
pprCmdArg (HsCmdTop _ cmd)
  = ppr_lcmd cmd

instance (OutputableBndrId p) => Outputable (HsCmdTop (GhcPass p)) where
    ppr = pprCmdArg

{-
************************************************************************
*                                                                      *
\subsection{@Match@, @GRHSs@, and @GRHS@ datatypes}
*                                                                      *
************************************************************************
-}

type instance XMG         GhcPs b = NoExtField
type instance XMG         GhcRn b = NoExtField
type instance XMG         GhcTc b = MatchGroupTc

type instance XXMatchGroup (GhcPass _) b = DataConCantHappen

type instance XCMatch (GhcPass _) b = EpAnn [AddEpAnn]
type instance XXMatch (GhcPass _) b = DataConCantHappen

instance (OutputableBndrId pr, Outputable body)
            => Outputable (Match (GhcPass pr) body) where
  ppr = pprMatch

isEmptyMatchGroup :: MatchGroup (GhcPass p) body -> Bool
isEmptyMatchGroup (MG { mg_alts = ms }) = null $ unLoc ms

-- | Is there only one RHS in this list of matches?
isSingletonMatchGroup :: [LMatch (GhcPass p) body] -> Bool
isSingletonMatchGroup matches
  | [L _ match] <- matches
  , Match { m_grhss = GRHSs { grhssGRHSs = [_] } } <- match
  = True
  | otherwise
  = False

matchGroupArity :: MatchGroup (GhcPass id) body -> Arity
-- Precondition: MatchGroup is non-empty
-- This is called before type checking, when mg_arg_tys is not set
matchGroupArity (MG { mg_alts = alts })
  | L _ (alt1:_) <- alts = length (hsLMatchPats alt1)
  | otherwise        = panic "matchGroupArity"

hsLMatchPats :: LMatch (GhcPass id) body -> [LPat (GhcPass id)]
hsLMatchPats (L _ (Match { m_pats = pats })) = pats

-- We keep the type checker happy by providing EpAnnComments.  They
-- can only be used if they follow a `where` keyword with no binds,
-- but in that case the comment is attached to the following parsed
-- item. So this can never be used in practice.
type instance XCGRHSs (GhcPass _) _ = EpAnnComments

type instance XXGRHSs (GhcPass _) _ = DataConCantHappen

data GrhsAnn
  = GrhsAnn {
      ga_vbar :: Maybe EpaLocation, -- TODO:AZ do we need this?
      ga_sep  :: AddEpAnn -- ^ Match separator location
      } deriving (Data)

type instance XCGRHS (GhcPass _) _ = EpAnn GrhsAnn
                                   -- Location of matchSeparator
                                   -- TODO:AZ does this belong on the GRHS, or GRHSs?

type instance XXGRHS (GhcPass _) b = DataConCantHappen

pprMatches :: (OutputableBndrId idR, Outputable body)
           => MatchGroup (GhcPass idR) body -> SDoc
pprMatches MG { mg_alts = matches }
    = vcat (map pprMatch (map unLoc (unLoc matches)))
      -- Don't print the type; it's only a place-holder before typechecking

-- Exported to GHC.Hs.Binds, which can't see the defn of HsMatchContext
pprFunBind :: (OutputableBndrId idR)
           => MatchGroup (GhcPass idR) (LHsExpr (GhcPass idR)) -> SDoc
pprFunBind matches = pprMatches matches

-- Exported to GHC.Hs.Binds, which can't see the defn of HsMatchContext
pprPatBind :: forall bndr p . (OutputableBndrId bndr,
                               OutputableBndrId p)
           => LPat (GhcPass bndr) -> GRHSs (GhcPass p) (LHsExpr (GhcPass p)) -> SDoc
pprPatBind pat grhss
 = sep [ppr pat,
       nest 2 (pprGRHSs (PatBindRhs :: HsMatchContext (GhcPass p)) grhss)]

pprMatch :: (OutputableBndrId idR, Outputable body)
         => Match (GhcPass idR) body -> SDoc
pprMatch (Match { m_pats = pats, m_ctxt = ctxt, m_grhss = grhss })
  = sep [ sep (herald : map (nest 2 . pprParendLPat appPrec) other_pats)
        , nest 2 (pprGRHSs ctxt grhss) ]
  where
    (herald, other_pats)
        = case ctxt of
            FunRhs {mc_fun=L _ fun, mc_fixity=fixity, mc_strictness=strictness}
                | SrcStrict <- strictness
                -> assert (null pats)     -- A strict variable binding
                   (char '!'<>pprPrefixOcc fun, pats)

                | Prefix <- fixity
                -> (pprPrefixOcc fun, pats) -- f x y z = e
                                            -- Not pprBndr; the AbsBinds will
                                            -- have printed the signature
                | otherwise
                -> case pats of
                     (p1:p2:rest)
                        | null rest -> (pp_infix, [])           -- x &&& y = e
                        | otherwise -> (parens pp_infix, rest)  -- (x &&& y) z = e
                        where
                          pp_infix = pprParendLPat opPrec p1
                                     <+> pprInfixOcc fun
                                     <+> pprParendLPat opPrec p2
                     _ -> pprPanic "pprMatch" (ppr ctxt $$ ppr pats)

            LambdaExpr -> (char '\\', pats)

            ArrowMatchCtxt KappaExpr -> (char '\\', pats)

            ArrowMatchCtxt ProcExpr -> (text "proc", pats)

            _ -> case pats of
                   []    -> (empty, [])
                   [pat] -> (ppr pat, [])  -- No parens around the single pat in a case
                   _     -> pprPanic "pprMatch" (ppr ctxt $$ ppr pats)

pprGRHSs :: (OutputableBndrId idR, Outputable body)
         => HsMatchContext passL -> GRHSs (GhcPass idR) body -> SDoc
pprGRHSs ctxt (GRHSs _ grhss binds)
  = vcat (map (pprGRHS ctxt . unLoc) grhss)
  -- Print the "where" even if the contents of the binds is empty. Only
  -- EmptyLocalBinds means no "where" keyword
 $$ ppUnless (eqEmptyLocalBinds binds)
      (text "where" $$ nest 4 (pprBinds binds))

pprGRHS :: (OutputableBndrId idR, Outputable body)
        => HsMatchContext passL -> GRHS (GhcPass idR) body -> SDoc
pprGRHS ctxt (GRHS _ [] body)
 =  pp_rhs ctxt body

pprGRHS ctxt (GRHS _ guards body)
 = sep [vbar <+> interpp'SP guards, pp_rhs ctxt body]

pp_rhs :: Outputable body => HsMatchContext passL -> body -> SDoc
pp_rhs ctxt rhs = matchSeparator ctxt <+> pprDeeper (ppr rhs)

instance Outputable GrhsAnn where
  ppr (GrhsAnn v s) = text "GrhsAnn" <+> ppr v <+> ppr s

{-
************************************************************************
*                                                                      *
\subsection{Do stmts and list comprehensions}
*                                                                      *
************************************************************************
-}

-- Extra fields available post typechecking for RecStmt.
data RecStmtTc =
  RecStmtTc
     { recS_bind_ty :: Type       -- S in (>>=) :: Q -> (R -> S) -> T
     , recS_later_rets :: [PostTcExpr] -- (only used in the arrow version)
     , recS_rec_rets :: [PostTcExpr] -- These expressions correspond 1-to-1
                                  -- with recS_later_ids and recS_rec_ids,
                                  -- and are the expressions that should be
                                  -- returned by the recursion.
                                  -- They may not quite be the Ids themselves,
                                  -- because the Id may be *polymorphic*, but
                                  -- the returned thing has to be *monomorphic*,
                                  -- so they may be type applications

      , recS_ret_ty :: Type        -- The type of
                                   -- do { stmts; return (a,b,c) }
                                   -- With rebindable syntax the type might not
                                   -- be quite as simple as (m (tya, tyb, tyc)).
      }


type instance XLastStmt        (GhcPass _) (GhcPass _) b = NoExtField

type instance XBindStmt        (GhcPass _) GhcPs b = EpAnn [AddEpAnn]
type instance XBindStmt        (GhcPass _) GhcRn b = XBindStmtRn
type instance XBindStmt        (GhcPass _) GhcTc b = XBindStmtTc

data XBindStmtRn = XBindStmtRn
  { xbsrn_bindOp :: SyntaxExpr GhcRn
  , xbsrn_failOp :: FailOperator GhcRn
  }

data XBindStmtTc = XBindStmtTc
  { xbstc_bindOp :: SyntaxExpr GhcTc
  , xbstc_boundResultType :: Type -- If (>>=) :: Q -> (R -> S) -> T, this is S
  , xbstc_boundResultMult :: Mult -- If (>>=) :: Q -> (R -> S) -> T, this is S
  , xbstc_failOp :: FailOperator GhcTc
  }

type instance XApplicativeStmt (GhcPass _) GhcPs b = NoExtField
type instance XApplicativeStmt (GhcPass _) GhcRn b = NoExtField
type instance XApplicativeStmt (GhcPass _) GhcTc b = Type

type instance XBodyStmt        (GhcPass _) GhcPs b = NoExtField
type instance XBodyStmt        (GhcPass _) GhcRn b = NoExtField
type instance XBodyStmt        (GhcPass _) GhcTc b = Type

type instance XLetStmt         (GhcPass _) (GhcPass _) b = EpAnn [AddEpAnn]

type instance XParStmt         (GhcPass _) GhcPs b = NoExtField
type instance XParStmt         (GhcPass _) GhcRn b = NoExtField
type instance XParStmt         (GhcPass _) GhcTc b = Type

type instance XTransStmt       (GhcPass _) GhcPs b = EpAnn [AddEpAnn]
type instance XTransStmt       (GhcPass _) GhcRn b = NoExtField
type instance XTransStmt       (GhcPass _) GhcTc b = Type

type instance XRecStmt         (GhcPass _) GhcPs b = EpAnn AnnList
type instance XRecStmt         (GhcPass _) GhcRn b = NoExtField
type instance XRecStmt         (GhcPass _) GhcTc b = RecStmtTc

type instance XXStmtLR         (GhcPass _) (GhcPass _) b = DataConCantHappen

type instance XParStmtBlock  (GhcPass pL) (GhcPass pR) = NoExtField
type instance XXParStmtBlock (GhcPass pL) (GhcPass pR) = DataConCantHappen

type instance XApplicativeArgOne GhcPs = NoExtField
type instance XApplicativeArgOne GhcRn = FailOperator GhcRn
type instance XApplicativeArgOne GhcTc = FailOperator GhcTc

type instance XApplicativeArgMany (GhcPass _) = NoExtField
type instance XXApplicativeArg    (GhcPass _) = DataConCantHappen

instance (Outputable (StmtLR (GhcPass idL) (GhcPass idL) (LHsExpr (GhcPass idL))),
          Outputable (XXParStmtBlock (GhcPass idL) (GhcPass idR)))
        => Outputable (ParStmtBlock (GhcPass idL) (GhcPass idR)) where
  ppr (ParStmtBlock _ stmts _ _) = interpp'SP stmts

instance (OutputableBndrId pl, OutputableBndrId pr,
                 Anno (StmtLR (GhcPass pl) (GhcPass pr) body) ~ SrcSpanAnnA,
          Outputable body)
         => Outputable (StmtLR (GhcPass pl) (GhcPass pr) body) where
    ppr stmt = pprStmt stmt

pprStmt :: forall idL idR body . (OutputableBndrId idL,
                                  OutputableBndrId idR,
                 Anno (StmtLR (GhcPass idL) (GhcPass idR) body) ~ SrcSpanAnnA,
                                  Outputable body)
        => (StmtLR (GhcPass idL) (GhcPass idR) body) -> SDoc
pprStmt (LastStmt _ expr m_dollar_stripped _)
  = whenPprDebug (text "[last]") <+>
      (case m_dollar_stripped of
        Just True -> text "return $"
        Just False -> text "return"
        Nothing -> empty) <+>
      ppr expr
pprStmt (BindStmt _ pat expr)  = pprBindStmt pat expr
pprStmt (LetStmt _ binds)      = hsep [text "let", pprBinds binds]
pprStmt (BodyStmt _ expr _ _)  = ppr expr
pprStmt (ParStmt _ stmtss _ _) = sep (punctuate (text " | ") (map ppr stmtss))

pprStmt (TransStmt { trS_stmts = stmts, trS_by = by
                   , trS_using = using, trS_form = form })
  = sep $ punctuate comma (map ppr stmts ++ [pprTransStmt by using form])

pprStmt (RecStmt { recS_stmts = segment, recS_rec_ids = rec_ids
                 , recS_later_ids = later_ids })
  = text "rec" <+>
    vcat [ ppr_do_stmts (unLoc segment)
         , whenPprDebug (vcat [ text "rec_ids=" <> ppr rec_ids
                            , text "later_ids=" <> ppr later_ids])]

pprStmt (ApplicativeStmt _ args mb_join)
  = getPprStyle $ \style ->
      if userStyle style
         then pp_for_user
         else pp_debug
  where
  -- make all the Applicative stuff invisible in error messages by
  -- flattening the whole ApplicativeStmt nest back to a sequence
  -- of statements.
   pp_for_user = vcat $ concatMap flattenArg args

   -- ppr directly rather than transforming here, because we need to
   -- inject a "return" which is hard when we're polymorphic in the id
   -- type.
   flattenStmt :: ExprLStmt (GhcPass idL) -> [SDoc]
   flattenStmt (L _ (ApplicativeStmt _ args _)) = concatMap flattenArg args
   flattenStmt stmt = [ppr stmt]

   flattenArg :: forall a . (a, ApplicativeArg (GhcPass idL)) -> [SDoc]
   flattenArg (_, ApplicativeArgOne _ pat expr isBody)
     | isBody =  [ppr expr] -- See Note [Applicative BodyStmt]
     | otherwise = [pprBindStmt pat expr]
   flattenArg (_, ApplicativeArgMany _ stmts _ _ _) =
     concatMap flattenStmt stmts

   pp_debug =
     let
         ap_expr = sep (punctuate (text " |") (map pp_arg args))
     in
       whenPprDebug (if isJust mb_join then text "[join]" else empty) <+>
       (if lengthAtLeast args 2 then parens else id) ap_expr

   pp_arg :: (a, ApplicativeArg (GhcPass idL)) -> SDoc
   pp_arg (_, applicativeArg) = ppr applicativeArg

pprBindStmt :: (Outputable pat, Outputable expr) => pat -> expr -> SDoc
pprBindStmt pat expr = hsep [ppr pat, larrow, ppr expr]

instance (OutputableBndrId idL)
      => Outputable (ApplicativeArg (GhcPass idL)) where
  ppr = pprArg

pprArg :: forall idL . (OutputableBndrId idL) => ApplicativeArg (GhcPass idL) -> SDoc
pprArg (ApplicativeArgOne _ pat expr isBody)
  | isBody = ppr expr -- See Note [Applicative BodyStmt]
  | otherwise = pprBindStmt pat expr
pprArg (ApplicativeArgMany _ stmts return pat ctxt) =
     ppr pat <+>
     text "<-" <+>
     pprDo ctxt (stmts ++
                   [noLocA (LastStmt noExtField (noLocA return) Nothing noSyntaxExpr)])

pprTransformStmt :: (OutputableBndrId p)
                 => [IdP (GhcPass p)] -> LHsExpr (GhcPass p)
                 -> Maybe (LHsExpr (GhcPass p)) -> SDoc
pprTransformStmt bndrs using by
  = sep [ text "then" <+> whenPprDebug (braces (ppr bndrs))
        , nest 2 (ppr using)
        , nest 2 (pprBy by)]

pprTransStmt :: Outputable body => Maybe body -> body -> TransForm -> SDoc
pprTransStmt by using ThenForm
  = sep [ text "then", nest 2 (ppr using), nest 2 (pprBy by)]
pprTransStmt by using GroupForm
  = sep [ text "then group", nest 2 (pprBy by), nest 2 (text "using" <+> ppr using)]

pprBy :: Outputable body => Maybe body -> SDoc
pprBy Nothing  = empty
pprBy (Just e) = text "by" <+> ppr e

pprDo :: (OutputableBndrId p, Outputable body,
                 Anno (StmtLR (GhcPass p) (GhcPass p) body) ~ SrcSpanAnnA
         )
      => HsDoFlavour -> [LStmt (GhcPass p) body] -> SDoc
pprDo (DoExpr m)    stmts =
  ppr_module_name_prefix m <> text "do"  <+> ppr_do_stmts stmts
pprDo GhciStmtCtxt  stmts = text "do"  <+> ppr_do_stmts stmts
pprDo (MDoExpr m)   stmts =
  ppr_module_name_prefix m <> text "mdo"  <+> ppr_do_stmts stmts
pprDo ListComp      stmts = brackets    $ pprComp stmts
pprDo MonadComp     stmts = brackets    $ pprComp stmts

pprArrowExpr :: (OutputableBndrId p, Outputable body,
                 Anno (StmtLR (GhcPass p) (GhcPass p) body) ~ SrcSpanAnnA
         )
      => [LStmt (GhcPass p) body] -> SDoc
pprArrowExpr stmts = text "do"  <+> ppr_do_stmts stmts

ppr_module_name_prefix :: Maybe ModuleName -> SDoc
ppr_module_name_prefix = \case
  Nothing -> empty
  Just module_name -> ppr module_name <> char '.'

ppr_do_stmts :: (OutputableBndrId idL, OutputableBndrId idR,
                 Anno (StmtLR (GhcPass idL) (GhcPass idR) body) ~ SrcSpanAnnA,
                 Outputable body)
             => [LStmtLR (GhcPass idL) (GhcPass idR) body] -> SDoc
-- Print a bunch of do stmts
ppr_do_stmts stmts = pprDeeperList vcat (map ppr stmts)

pprComp :: (OutputableBndrId p, Outputable body,
                 Anno (StmtLR (GhcPass p) (GhcPass p) body) ~ SrcSpanAnnA)
        => [LStmt (GhcPass p) body] -> SDoc
pprComp quals     -- Prints:  body | qual1, ..., qualn
  | Just (initStmts, L _ (LastStmt _ body _ _)) <- snocView quals
  = if null initStmts
       -- If there are no statements in a list comprehension besides the last
       -- one, we simply treat it like a normal list. This does arise
       -- occasionally in code that GHC generates, e.g., in implementations of
       -- 'range' for derived 'Ix' instances for product datatypes with exactly
       -- one constructor (e.g., see #12583).
       then ppr body
       else hang (ppr body <+> vbar) 2 (pprQuals initStmts)
  | otherwise
  = pprPanic "pprComp" (pprQuals quals)

pprQuals :: (OutputableBndrId p, Outputable body,
                 Anno (StmtLR (GhcPass p) (GhcPass p) body) ~ SrcSpanAnnA)
         => [LStmt (GhcPass p) body] -> SDoc
-- Show list comprehension qualifiers separated by commas
pprQuals quals = interpp'SP quals

{-
************************************************************************
*                                                                      *
                Template Haskell quotation brackets
*                                                                      *
************************************************************************
-}

newtype HsSplicedT = HsSplicedT DelayedSplice deriving (Data)

type instance XTypedSplice   (GhcPass _) = EpAnn [AddEpAnn]
type instance XUntypedSplice (GhcPass _) = EpAnn [AddEpAnn]
type instance XQuasiQuote    (GhcPass _) = NoExtField
type instance XSpliced       (GhcPass _) = NoExtField
type instance XXSplice       GhcPs       = DataConCantHappen
type instance XXSplice       GhcRn       = DataConCantHappen
type instance XXSplice       GhcTc       = HsSplicedT

-- See Note [Running typed splices in the zonker]
-- These are the arguments that are passed to `GHC.Tc.Gen.Splice.runTopSplice`
data DelayedSplice =
  DelayedSplice
    TcLclEnv          -- The local environment to run the splice in
    (LHsExpr GhcRn)   -- The original renamed expression
    TcType            -- The result type of running the splice, unzonked
    (LHsExpr GhcTc)   -- The typechecked expression to run and splice in the result

-- A Data instance which ignores the argument of 'DelayedSplice'.
instance Data DelayedSplice where
  gunfold _ _ _ = panic "DelayedSplice"
  toConstr  a   = mkConstr (dataTypeOf a) "DelayedSplice" [] Data.Prefix
  dataTypeOf a  = mkDataType "HsExpr.DelayedSplice" [toConstr a]

-- See Note [Pending Splices]
type SplicePointName = Name

-- | Pending Renamer Splice
data PendingRnSplice
  = PendingRnSplice UntypedSpliceFlavour SplicePointName (LHsExpr GhcRn)

-- | Pending Type-checker Splice
data PendingTcSplice
  = PendingTcSplice SplicePointName (LHsExpr GhcTc)

{-
Note [Pending Splices]
~~~~~~~~~~~~~~~~~~~~~~
When we rename an untyped bracket, we name and lift out all the nested
splices, so that when the typechecker hits the bracket, it can
typecheck those nested splices without having to walk over the untyped
bracket code.  So for example
    [| f $(g x) |]
looks like

    HsUntypedBracket _ (HsApp (HsVar "f") (HsSpliceE _ (HsUntypedSplice sn (g x)))

which the renamer rewrites to

    HsUntypedBracket
        [PendingRnSplice UntypedExpSplice sn (g x)]
        (HsApp (HsVar f) (HsSpliceE _ (HsUntypedSplice sn (g x)))

* The 'sn' is the Name of the splice point, the SplicePointName

* The PendingRnExpSplice gives the splice that splice-point name maps to;
  and the typechecker can now conveniently find these sub-expressions

* Note that a nested splice, such as the `$(g x)` now appears twice:
  - In the PendingRnSplice: this is the version that will later be typechecked
  - In the HsSpliceE in the body of the bracket. This copy is used only for pretty printing.

There are four varieties of pending splices generated by the renamer,
distinguished by their UntypedSpliceFlavour

 * Pending expression splices (UntypedExpSplice), e.g.,
       [|$(f x) + 2|]

   UntypedExpSplice is also used for
     * quasi-quotes, where the pending expression expands to
          $(quoter "...blah...")
       (see GHC.Rename.Splice.makePending, HsQuasiQuote case)

     * cross-stage lifting, where the pending expression expands to
          $(lift x)
       (see GHC.Rename.Splice.checkCrossStageLifting)

 * Pending pattern splices (UntypedPatSplice), e.g.,
       [| \$(f x) -> x |]

 * Pending type splices (UntypedTypeSplice), e.g.,
       [| f :: $(g x) |]

 * Pending declaration (UntypedDeclSplice), e.g.,
       [| let $(f x) in ... |]

There is a fifth variety of pending splice, which is generated by the type
checker:

  * Pending *typed* expression splices, (PendingTcSplice), e.g.,
        [||1 + $$(f 2)||]
-}

instance OutputableBndrId p
       => Outputable (HsSplicedThing (GhcPass p)) where
  ppr (HsSplicedExpr e) = ppr_expr e
  ppr (HsSplicedTy   t) = ppr t
  ppr (HsSplicedPat  p) = ppr p

instance (OutputableBndrId p) => Outputable (HsSplice (GhcPass p)) where
  ppr s = pprSplice s

pprPendingSplice :: (OutputableBndrId p)
                 => SplicePointName -> LHsExpr (GhcPass p) -> SDoc
pprPendingSplice n e = angleBrackets (ppr n <> comma <+> ppr (stripParensLHsExpr e))

pprSpliceDecl ::  (OutputableBndrId p)
          => HsSplice (GhcPass p) -> SpliceExplicitFlag -> SDoc
pprSpliceDecl e@HsQuasiQuote{} _ = pprSplice e
pprSpliceDecl e ExplicitSplice   = text "$" <> ppr_splice_decl e
pprSpliceDecl e ImplicitSplice   = ppr_splice_decl e

ppr_splice_decl :: (OutputableBndrId p)
                => HsSplice (GhcPass p) -> SDoc
ppr_splice_decl (HsUntypedSplice _ _ n e) = ppr_splice empty n e empty
ppr_splice_decl e = pprSplice e

pprSplice :: forall p. (OutputableBndrId p) => HsSplice (GhcPass p) -> SDoc
pprSplice (HsTypedSplice _ DollarSplice n e)
  = ppr_splice (text "$$") n e empty
pprSplice (HsTypedSplice _ BareSplice _ _ )
  = panic "Bare typed splice"  -- impossible
pprSplice (HsUntypedSplice _ DollarSplice n e)
  = ppr_splice (text "$")  n e empty
pprSplice (HsUntypedSplice _ BareSplice n e)
  = ppr_splice empty  n e empty
pprSplice (HsQuasiQuote _ n q _ s)      = ppr_quasi n q s
pprSplice (HsSpliced _ _ thing)         = ppr thing
pprSplice (XSplice x)                   = case ghcPass @p of
#if __GLASGOW_HASKELL__ < 811
                                            GhcPs -> dataConCantHappen x
                                            GhcRn -> dataConCantHappen x
#endif
                                            GhcTc -> case x of
                                                       HsSplicedT _ -> text "Unevaluated typed splice"

ppr_quasi :: OutputableBndr p => p -> p -> FastString -> SDoc
ppr_quasi n quoter quote = whenPprDebug (brackets (ppr n)) <>
                           char '[' <> ppr quoter <> vbar <>
                           ppr quote <> text "|]"

ppr_splice :: (OutputableBndrId p)
           => SDoc -> (IdP (GhcPass p)) -> LHsExpr (GhcPass p) -> SDoc -> SDoc
ppr_splice herald n e trail
    = herald <> whenPprDebug (brackets (ppr n)) <> ppr e <> trail


type instance XExpBr  GhcPs       = NoExtField
type instance XPatBr  GhcPs       = NoExtField
type instance XDecBrL GhcPs       = NoExtField
type instance XDecBrG GhcPs       = NoExtField
type instance XTypBr  GhcPs       = NoExtField
type instance XVarBr  GhcPs       = NoExtField
type instance XXQuote GhcPs       = DataConCantHappen

type instance XExpBr  GhcRn       = NoExtField
type instance XPatBr  GhcRn       = NoExtField
type instance XDecBrL GhcRn       = NoExtField
type instance XDecBrG GhcRn       = NoExtField
type instance XTypBr  GhcRn       = NoExtField
type instance XVarBr  GhcRn       = NoExtField
type instance XXQuote GhcRn       = DataConCantHappen

-- See Note [The life cycle of a TH quotation]
type instance XExpBr  GhcTc       = DataConCantHappen
type instance XPatBr  GhcTc       = DataConCantHappen
type instance XDecBrL GhcTc       = DataConCantHappen
type instance XDecBrG GhcTc       = DataConCantHappen
type instance XTypBr  GhcTc       = DataConCantHappen
type instance XVarBr  GhcTc       = DataConCantHappen
type instance XXQuote GhcTc       = NoExtField

instance OutputableBndrId p
          => Outputable (HsQuote (GhcPass p)) where
  ppr = pprHsQuote
    where
      pprHsQuote :: forall p. (OutputableBndrId p)
                   => HsQuote (GhcPass p) -> SDoc
      pprHsQuote (ExpBr _ e)   = thBrackets empty (ppr e)
      pprHsQuote (PatBr _ p)   = thBrackets (char 'p') (ppr p)
      pprHsQuote (DecBrG _ gp) = thBrackets (char 'd') (ppr gp)
      pprHsQuote (DecBrL _ ds) = thBrackets (char 'd') (vcat (map ppr ds))
      pprHsQuote (TypBr _ t)   = thBrackets (char 't') (ppr t)
      pprHsQuote (VarBr _ True n)
        = char '\'' <> pprPrefixOcc (unLoc n)
      pprHsQuote (VarBr _ False n)
        = text "''" <> pprPrefixOcc (unLoc n)
      pprHsQuote (XQuote b)  = case ghcPass @p of
#if __GLASGOW_HASKELL__ <= 900
          GhcPs -> dataConCantHappen b
          GhcRn -> dataConCantHappen b
#endif
          GhcTc -> pprPanic "pprHsQuote: `HsQuote GhcTc` shouldn't exist" (ppr b)
                   -- See Note [The life cycle of a TH quotation]

thBrackets :: SDoc -> SDoc -> SDoc
thBrackets pp_kind pp_body = char '[' <> pp_kind <> vbar <+>
                             pp_body <+> text "|]"

thTyBrackets :: SDoc -> SDoc
thTyBrackets pp_body = text "[||" <+> pp_body <+> text "||]"

instance Outputable PendingRnSplice where
  ppr (PendingRnSplice _ n e) = pprPendingSplice n e

instance Outputable PendingTcSplice where
  ppr (PendingTcSplice n e) = pprPendingSplice n e

ppr_with_pending_tc_splices :: SDoc -> [PendingTcSplice] -> SDoc
ppr_with_pending_tc_splices x [] = x
ppr_with_pending_tc_splices x ps = x $$ text "pending(tc)" <+> ppr ps

{-
************************************************************************
*                                                                      *
\subsection{Enumerations and list comprehensions}
*                                                                      *
************************************************************************
-}

instance OutputableBndrId p
         => Outputable (ArithSeqInfo (GhcPass p)) where
    ppr (From e1)             = hcat [ppr e1, pp_dotdot]
    ppr (FromThen e1 e2)      = hcat [ppr e1, comma, space, ppr e2, pp_dotdot]
    ppr (FromTo e1 e3)        = hcat [ppr e1, pp_dotdot, ppr e3]
    ppr (FromThenTo e1 e2 e3)
      = hcat [ppr e1, comma, space, ppr e2, pp_dotdot, ppr e3]

pp_dotdot :: SDoc
pp_dotdot = text " .. "

{-
************************************************************************
*                                                                      *
\subsection{HsMatchCtxt}
*                                                                      *
************************************************************************
-}

instance OutputableBndrId p => Outputable (HsMatchContext (GhcPass p)) where
  ppr m@(FunRhs{})          = text "FunRhs" <+> ppr (mc_fun m) <+> ppr (mc_fixity m)
  ppr LambdaExpr            = text "LambdaExpr"
  ppr CaseAlt               = text "CaseAlt"
  ppr IfAlt                 = text "IfAlt"
  ppr (ArrowMatchCtxt c)    = text "ArrowMatchCtxt" <+> ppr c
  ppr PatBindRhs            = text "PatBindRhs"
  ppr PatBindGuards         = text "PatBindGuards"
  ppr RecUpd                = text "RecUpd"
  ppr (StmtCtxt _)          = text "StmtCtxt _"
  ppr ThPatSplice           = text "ThPatSplice"
  ppr ThPatQuote            = text "ThPatQuote"
  ppr PatSyn                = text "PatSyn"

instance Outputable HsArrowMatchContext where
  ppr ProcExpr     = text "ProcExpr"
  ppr ArrowCaseAlt = text "ArrowCaseAlt"
  ppr KappaExpr    = text "KappaExpr"

-----------------

instance OutputableBndrId p
      => Outputable (HsStmtContext (GhcPass p)) where
    ppr = pprStmtContext

-- Used to generate the string for a *runtime* error message
matchContextErrString :: OutputableBndrId p
                      => HsMatchContext (GhcPass p) -> SDoc
matchContextErrString (FunRhs{mc_fun=L _ fun})   = text "function" <+> ppr fun
matchContextErrString CaseAlt                    = text "case"
matchContextErrString IfAlt                      = text "multi-way if"
matchContextErrString PatBindRhs                 = text "pattern binding"
matchContextErrString PatBindGuards              = text "pattern binding guards"
matchContextErrString RecUpd                     = text "record update"
matchContextErrString LambdaExpr                 = text "lambda"
matchContextErrString (ArrowMatchCtxt c)         = matchArrowContextErrString c
matchContextErrString ThPatSplice                = panic "matchContextErrString"  -- Not used at runtime
matchContextErrString ThPatQuote                 = panic "matchContextErrString"  -- Not used at runtime
matchContextErrString PatSyn                     = panic "matchContextErrString"  -- Not used at runtime
matchContextErrString (StmtCtxt (ParStmtCtxt c))   = matchContextErrString (StmtCtxt c)
matchContextErrString (StmtCtxt (TransStmtCtxt c)) = matchContextErrString (StmtCtxt c)
matchContextErrString (StmtCtxt (PatGuard _))      = text "pattern guard"
matchContextErrString (StmtCtxt (ArrowExpr))       = text "'do' block"
matchContextErrString (StmtCtxt (HsDoStmt flavour)) = matchDoContextErrString flavour

matchArrowContextErrString :: HsArrowMatchContext -> SDoc
matchArrowContextErrString ProcExpr     = text "proc"
matchArrowContextErrString ArrowCaseAlt = text "case"
matchArrowContextErrString KappaExpr    = text "kappa"

matchDoContextErrString :: HsDoFlavour -> SDoc
matchDoContextErrString GhciStmtCtxt = text "interactive GHCi command"
matchDoContextErrString (DoExpr m)   = prependQualified m (text "'do' block")
matchDoContextErrString (MDoExpr m)  = prependQualified m (text "'mdo' block")
matchDoContextErrString ListComp     = text "list comprehension"
matchDoContextErrString MonadComp    = text "monad comprehension"

pprMatchInCtxt :: (OutputableBndrId idR, Outputable body)
               => Match (GhcPass idR) body -> SDoc
pprMatchInCtxt match  = hang (text "In" <+> pprMatchContext (m_ctxt match)
                                        <> colon)
                             4 (pprMatch match)

pprStmtInCtxt :: (OutputableBndrId idL,
                  OutputableBndrId idR,
                  OutputableBndrId ctx,
                  Outputable body,
                 Anno (StmtLR (GhcPass idL) (GhcPass idR) body) ~ SrcSpanAnnA)
              => HsStmtContext (GhcPass ctx)
              -> StmtLR (GhcPass idL) (GhcPass idR) body
              -> SDoc
pprStmtInCtxt ctxt (LastStmt _ e _ _)
  | isComprehensionContext ctxt      -- For [ e | .. ], do not mutter about "stmts"
  = hang (text "In the expression:") 2 (ppr e)

pprStmtInCtxt ctxt stmt
  = hang (text "In a stmt of" <+> pprAStmtContext ctxt <> colon)
       2 (ppr_stmt stmt)
  where
    -- For Group and Transform Stmts, don't print the nested stmts!
    ppr_stmt (TransStmt { trS_by = by, trS_using = using
                        , trS_form = form }) = pprTransStmt by using form
    ppr_stmt stmt = pprStmt stmt

{-
************************************************************************
*                                                                      *
\subsection{Anno instances}
*                                                                      *
************************************************************************
-}

type instance Anno (HsExpr (GhcPass p)) = SrcSpanAnnA
type instance Anno [LocatedA ((StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (HsExpr (GhcPass pr)))))] = SrcSpanAnnL
type instance Anno [LocatedA ((StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (HsCmd (GhcPass pr)))))] = SrcSpanAnnL

type instance Anno (HsCmd (GhcPass p)) = SrcSpanAnnA

type instance Anno [LocatedA (StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (HsCmd (GhcPass pr))))]
  = SrcSpanAnnL
type instance Anno (HsCmdTop (GhcPass p)) = SrcAnn NoEpAnns
type instance Anno [LocatedA (Match (GhcPass p) (LocatedA (HsExpr (GhcPass p))))] = SrcSpanAnnL
type instance Anno [LocatedA (Match (GhcPass p) (LocatedA (HsCmd  (GhcPass p))))] = SrcSpanAnnL
type instance Anno (Match (GhcPass p) (LocatedA (HsExpr (GhcPass p)))) = SrcSpanAnnA
type instance Anno (Match (GhcPass p) (LocatedA (HsCmd  (GhcPass p)))) = SrcSpanAnnA
type instance Anno (GRHS (GhcPass p) (LocatedA (HsExpr (GhcPass p)))) = SrcAnn NoEpAnns
type instance Anno (GRHS (GhcPass p) (LocatedA (HsCmd  (GhcPass p)))) = SrcAnn NoEpAnns
type instance Anno (StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (HsExpr (GhcPass pr)))) = SrcSpanAnnA
type instance Anno (StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (HsCmd  (GhcPass pr)))) = SrcSpanAnnA

type instance Anno (HsSplice (GhcPass p)) = SrcSpanAnnA

type instance Anno [LocatedA (StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (HsExpr (GhcPass pr))))] = SrcSpanAnnL
type instance Anno [LocatedA (StmtLR (GhcPass pl) (GhcPass pr) (LocatedA (HsCmd  (GhcPass pr))))] = SrcSpanAnnL

type instance Anno (FieldLabelStrings (GhcPass p)) = SrcAnn NoEpAnns
type instance Anno (FieldLabelString) = SrcAnn NoEpAnns
type instance Anno (DotFieldOcc (GhcPass p)) = SrcAnn NoEpAnns

instance (Anno a ~ SrcSpanAnn' (EpAnn an))
   => WrapXRec (GhcPass p) a where
  wrapXRec = noLocA