{-# OPTIONS_GHC -w #-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE MagicHash #-}
{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE TypeSynonymInstances #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE PatternGuards #-}
{-# LANGUAGE NoStrictData #-}
{-# LANGUAGE UnboxedTuples #-}
{-# LANGUAGE PartialTypeSignatures #-}
#if __GLASGOW_HASKELL__ >= 710
{-# LANGUAGE PartialTypeSignatures #-}
#endif
{-# OPTIONS_GHC -fno-warn-incomplete-patterns -fno-warn-overlapping-patterns #-}
{-# LANGUAGE PatternSynonyms #-}
module Lam.Par
( happyError
, myLexer
, pExp
) where
import Prelude
import qualified Lam.Abs
import Lam.Lex
import qualified Data.Function as Happy_Prelude
import qualified Data.Bool as Happy_Prelude
import qualified Data.Function as Happy_Prelude
import qualified Data.Maybe as Happy_Prelude
import qualified Data.Int as Happy_Prelude
import qualified Data.String as Happy_Prelude
import qualified Data.List as Happy_Prelude
import qualified Control.Monad as Happy_Prelude
import qualified Text.Show as Happy_Prelude
import qualified GHC.Num as Happy_Prelude
import qualified GHC.Err as Happy_Prelude
import qualified Data.Array as Happy_Data_Array
import qualified Data.Bits as Bits
import qualified GHC.Exts as Happy_GHC_Exts
import Control.Applicative(Applicative(..))
import Control.Monad (ap)
-- parser produced by Happy Version 2.1.2
newtype HappyAbsSyn = HappyAbsSyn HappyAny
#if __GLASGOW_HASKELL__ >= 607
type HappyAny = Happy_GHC_Exts.Any
#else
type HappyAny = forall a . a
#endif
newtype HappyWrap5 = HappyWrap5 (Lam.Abs.Ident)
happyIn5 :: (Lam.Abs.Ident) -> (HappyAbsSyn )
happyIn5 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap5 x)
{-# INLINE happyIn5 #-}
happyOut5 :: (HappyAbsSyn ) -> HappyWrap5
happyOut5 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut5 #-}
newtype HappyWrap6 = HappyWrap6 (Lam.Abs.Lambda)
happyIn6 :: (Lam.Abs.Lambda) -> (HappyAbsSyn )
happyIn6 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap6 x)
{-# INLINE happyIn6 #-}
happyOut6 :: (HappyAbsSyn ) -> HappyWrap6
happyOut6 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut6 #-}
newtype HappyWrap7 = HappyWrap7 (Lam.Abs.Arrow)
happyIn7 :: (Lam.Abs.Arrow) -> (HappyAbsSyn )
happyIn7 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap7 x)
{-# INLINE happyIn7 #-}
happyOut7 :: (HappyAbsSyn ) -> HappyWrap7
happyOut7 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut7 #-}
newtype HappyWrap8 = HappyWrap8 (Lam.Abs.Exp)
happyIn8 :: (Lam.Abs.Exp) -> (HappyAbsSyn )
happyIn8 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap8 x)
{-# INLINE happyIn8 #-}
happyOut8 :: (HappyAbsSyn ) -> HappyWrap8
happyOut8 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut8 #-}
newtype HappyWrap9 = HappyWrap9 (Lam.Abs.Exp)
happyIn9 :: (Lam.Abs.Exp) -> (HappyAbsSyn )
happyIn9 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap9 x)
{-# INLINE happyIn9 #-}
happyOut9 :: (HappyAbsSyn ) -> HappyWrap9
happyOut9 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut9 #-}
newtype HappyWrap10 = HappyWrap10 (Lam.Abs.Exp)
happyIn10 :: (Lam.Abs.Exp) -> (HappyAbsSyn )
happyIn10 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap10 x)
{-# INLINE happyIn10 #-}
happyOut10 :: (HappyAbsSyn ) -> HappyWrap10
happyOut10 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut10 #-}
newtype HappyWrap11 = HappyWrap11 (Lam.Abs.Exp)
happyIn11 :: (Lam.Abs.Exp) -> (HappyAbsSyn )
happyIn11 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap11 x)
{-# INLINE happyIn11 #-}
happyOut11 :: (HappyAbsSyn ) -> HappyWrap11
happyOut11 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut11 #-}
newtype HappyWrap12 = HappyWrap12 (Lam.Abs.Ty)
happyIn12 :: (Lam.Abs.Ty) -> (HappyAbsSyn )
happyIn12 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap12 x)
{-# INLINE happyIn12 #-}
happyOut12 :: (HappyAbsSyn ) -> HappyWrap12
happyOut12 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut12 #-}
newtype HappyWrap13 = HappyWrap13 (Lam.Abs.Ty)
happyIn13 :: (Lam.Abs.Ty) -> (HappyAbsSyn )
happyIn13 x = Happy_GHC_Exts.unsafeCoerce# (HappyWrap13 x)
{-# INLINE happyIn13 #-}
happyOut13 :: (HappyAbsSyn ) -> HappyWrap13
happyOut13 x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOut13 #-}
happyInTok :: (Token) -> (HappyAbsSyn )
happyInTok x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyInTok #-}
happyOutTok :: (HappyAbsSyn ) -> (Token)
happyOutTok x = Happy_GHC_Exts.unsafeCoerce# x
{-# INLINE happyOutTok #-}
{-# NOINLINE happyTokenStrings #-}
happyTokenStrings = ["'('","')'","L_Ident","L_Lambda","L_Arrow","%eof"]
happyActOffsets :: HappyAddr
happyActOffsets = HappyA# "\x14\x00\x00\x00\xff\xff\xff\xff\x00\x00\x00\x00\x00\x00\x00\x00\xff\xff\xff\xff\x00\x00\x00\x00\x19\x00\x00\x00\x03\x00\x00\x00\x00\x00\x00\x00\x14\x00\x00\x00\x00\x00\x00\x00\x0e\x00\x00\x00\x00\x00\x00\x00\x16\x00\x00\x00\x14\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"#
happyGotoOffsets :: HappyAddr
happyGotoOffsets = HappyA# "\x01\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x1e\x00\x00\x00\x00\x00\x00\x00\x17\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x08\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x1d\x00\x00\x00\x0f\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"#
happyDefActions :: HappyAddr
happyDefActions = HappyA# "\x00\x00\x00\x00\x00\x00\x00\x00\xfe\xff\xff\xff\xfb\xff\xff\xff\x00\x00\x00\x00\xf8\xff\xff\xff\xf5\xff\xff\xff\x00\x00\x00\x00\xf6\xff\xff\xff\x00\x00\x00\x00\xfd\xff\xff\xff\x00\x00\x00\x00\xf9\xff\xff\xff\x00\x00\x00\x00\x00\x00\x00\x00\xfc\xff\xff\xff\xfa\xff\xff\xff\xf7\xff\xff\xff"#
happyCheck :: HappyAddr
happyCheck = HappyA# "\xff\xff\xff\xff\x00\x00\x00\x00\x01\x00\x00\x00\x04\x00\x00\x00\x03\x00\x00\x00\x04\x00\x00\x00\x05\x00\x00\x00\x06\x00\x00\x00\x00\x00\x00\x00\x01\x00\x00\x00\x07\x00\x00\x00\x03\x00\x00\x00\x04\x00\x00\x00\x05\x00\x00\x00\x06\x00\x00\x00\x00\x00\x00\x00\x01\x00\x00\x00\x03\x00\x00\x00\x03\x00\x00\x00\x04\x00\x00\x00\x05\x00\x00\x00\x06\x00\x00\x00\x02\x00\x00\x00\x00\x00\x00\x00\x04\x00\x00\x00\x05\x00\x00\x00\x03\x00\x00\x00\x02\x00\x00\x00\x06\x00\x00\x00\x04\x00\x00\x00\x00\x00\x00\x00\x02\x00\x00\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff"#
happyTable :: HappyAddr
happyTable = HappyA# "\x00\x00\x00\x00\x03\x00\x00\x00\x04\x00\x00\x00\x03\x00\x00\x00\x05\x00\x00\x00\x06\x00\x00\x00\x07\x00\x00\x00\x08\x00\x00\x00\x03\x00\x00\x00\x04\x00\x00\x00\xff\xff\xff\xff\x05\x00\x00\x00\x06\x00\x00\x00\x0b\x00\x00\x00\x08\x00\x00\x00\x03\x00\x00\x00\x04\x00\x00\x00\x11\x00\x00\x00\x05\x00\x00\x00\x06\x00\x00\x00\x11\x00\x00\x00\x08\x00\x00\x00\x0a\x00\x00\x00\x03\x00\x00\x00\x03\x00\x00\x00\x0b\x00\x00\x00\x0c\x00\x00\x00\x0a\x00\x00\x00\x10\x00\x00\x00\x03\x00\x00\x00\x0d\x00\x00\x00\x0e\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"#
happyReduceArr = Happy_Data_Array.array (1, 14) [
(1 , happyReduce_1),
(2 , happyReduce_2),
(3 , happyReduce_3),
(4 , happyReduce_4),
(5 , happyReduce_5),
(6 , happyReduce_6),
(7 , happyReduce_7),
(8 , happyReduce_8),
(9 , happyReduce_9),
(10 , happyReduce_10),
(11 , happyReduce_11),
(12 , happyReduce_12),
(13 , happyReduce_13),
(14 , happyReduce_14)
]
happyRuleArr :: HappyAddr
happyRuleArr = HappyA# "\x00\x00\x00\x00\x01\x00\x00\x00\x01\x00\x00\x00\x01\x00\x00\x00\x02\x00\x00\x00\x01\x00\x00\x00\x03\x00\x00\x00\x01\x00\x00\x00\x03\x00\x00\x00\x03\x00\x00\x00\x04\x00\x00\x00\x02\x00\x00\x00\x04\x00\x00\x00\x01\x00\x00\x00\x05\x00\x00\x00\x04\x00\x00\x00\x05\x00\x00\x00\x01\x00\x00\x00\x06\x00\x00\x00\x01\x00\x00\x00\x07\x00\x00\x00\x01\x00\x00\x00\x07\x00\x00\x00\x03\x00\x00\x00\x08\x00\x00\x00\x03\x00\x00\x00\x08\x00\x00\x00\x01\x00\x00\x00"#
happyCatchStates :: [Happy_Prelude.Int]
happyCatchStates = []
happy_n_terms = 8 :: Happy_Prelude.Int
happy_n_nonterms = 9 :: Happy_Prelude.Int
happy_n_starts = 1 :: Happy_Prelude.Int
happyReduce_1 = happySpecReduce_1 0# happyReduction_1
happyReduction_1 happy_x_1
= case happyOutTok happy_x_1 of { (PT _ (TV happy_var_1)) ->
happyIn5
(Lam.Abs.Ident happy_var_1
)}
happyReduce_2 = happySpecReduce_1 1# happyReduction_2
happyReduction_2 happy_x_1
= case happyOutTok happy_x_1 of { (PT _ (T_Lambda happy_var_1)) ->
happyIn6
(Lam.Abs.Lambda happy_var_1
)}
happyReduce_3 = happySpecReduce_1 2# happyReduction_3
happyReduction_3 happy_x_1
= case happyOutTok happy_x_1 of { (PT _ (T_Arrow happy_var_1)) ->
happyIn7
(Lam.Abs.Arrow happy_var_1
)}
happyReduce_4 = happySpecReduce_1 3# happyReduction_4
happyReduction_4 happy_x_1
= case happyOut5 happy_x_1 of { (HappyWrap5 happy_var_1) ->
happyIn8
(Lam.Abs.EId happy_var_1
)}
happyReduce_5 = happySpecReduce_3 3# happyReduction_5
happyReduction_5 happy_x_3
happy_x_2
happy_x_1
= case happyOut10 happy_x_2 of { (HappyWrap10 happy_var_2) ->
happyIn8
(happy_var_2
)}
happyReduce_6 = happySpecReduce_2 4# happyReduction_6
happyReduction_6 happy_x_2
happy_x_1
= case happyOut9 happy_x_1 of { (HappyWrap9 happy_var_1) ->
case happyOut8 happy_x_2 of { (HappyWrap8 happy_var_2) ->
happyIn9
(Lam.Abs.EApp happy_var_1 happy_var_2
)}}
happyReduce_7 = happySpecReduce_1 4# happyReduction_7
happyReduction_7 happy_x_1
= case happyOut8 happy_x_1 of { (HappyWrap8 happy_var_1) ->
happyIn9
(happy_var_1
)}
happyReduce_8 = happyReduce 4# 5# happyReduction_8
happyReduction_8 (happy_x_4 `HappyStk`
happy_x_3 `HappyStk`
happy_x_2 `HappyStk`
happy_x_1 `HappyStk`
happyRest)
= case happyOut6 happy_x_1 of { (HappyWrap6 happy_var_1) ->
case happyOut5 happy_x_2 of { (HappyWrap5 happy_var_2) ->
case happyOut7 happy_x_3 of { (HappyWrap7 happy_var_3) ->
case happyOut10 happy_x_4 of { (HappyWrap10 happy_var_4) ->
happyIn10
(Lam.Abs.EAbs happy_var_1 happy_var_2 happy_var_3 happy_var_4
) `HappyStk` happyRest}}}}
happyReduce_9 = happySpecReduce_1 5# happyReduction_9
happyReduction_9 happy_x_1
= case happyOut11 happy_x_1 of { (HappyWrap11 happy_var_1) ->
happyIn10
(happy_var_1
)}
happyReduce_10 = happySpecReduce_1 6# happyReduction_10
happyReduction_10 happy_x_1
= case happyOut9 happy_x_1 of { (HappyWrap9 happy_var_1) ->
happyIn11
(happy_var_1
)}
happyReduce_11 = happySpecReduce_1 7# happyReduction_11
happyReduction_11 happy_x_1
= case happyOut5 happy_x_1 of { (HappyWrap5 happy_var_1) ->
happyIn12
(Lam.Abs.TId happy_var_1
)}
happyReduce_12 = happySpecReduce_3 7# happyReduction_12
happyReduction_12 happy_x_3
happy_x_2
happy_x_1
= case happyOut13 happy_x_2 of { (HappyWrap13 happy_var_2) ->
happyIn12
(happy_var_2
)}
happyReduce_13 = happySpecReduce_3 8# happyReduction_13
happyReduction_13 happy_x_3
happy_x_2
happy_x_1
= case happyOut12 happy_x_1 of { (HappyWrap12 happy_var_1) ->
case happyOut7 happy_x_2 of { (HappyWrap7 happy_var_2) ->
case happyOut13 happy_x_3 of { (HappyWrap13 happy_var_3) ->
happyIn13
(Lam.Abs.TArr happy_var_1 happy_var_2 happy_var_3
)}}}
happyReduce_14 = happySpecReduce_1 8# happyReduction_14
happyReduction_14 happy_x_1
= case happyOut12 happy_x_1 of { (HappyWrap12 happy_var_1) ->
happyIn13
(happy_var_1
)}
happyTerminalToTok term = case term of {
PT _ (TS _ 1) -> 2#;
PT _ (TS _ 2) -> 3#;
PT _ (TV happy_dollar_dollar) -> 4#;
PT _ (T_Lambda happy_dollar_dollar) -> 5#;
PT _ (T_Arrow happy_dollar_dollar) -> 6#;
_ -> -1#;
}
{-# NOINLINE happyTerminalToTok #-}
happyLex kend _kmore [] = kend notHappyAtAll []
happyLex _kend kmore (tk:tks) = kmore (happyTerminalToTok tk) tk tks
{-# INLINE happyLex #-}
happyNewToken action sts stk = happyLex (\tk -> happyDoAction 7# notHappyAtAll action sts stk) (\i tk -> happyDoAction i tk action sts stk)
happyReport 7# tk explist resume tks = happyReport' tks explist resume
happyReport _ tk explist resume tks = happyReport' (tk:tks) explist (\tks -> resume (Happy_Prelude.tail tks))
happyThen :: () => (Err a) -> (a -> (Err b)) -> (Err b)
happyThen = ((>>=))
happyReturn :: () => a -> (Err a)
happyReturn = (return)
happyThen1 m k tks = ((>>=)) m (\a -> k a tks)
happyFmap1 f m tks = happyThen (m tks) (\a -> happyReturn (f a))
happyReturn1 :: () => a -> b -> (Err a)
happyReturn1 = \a tks -> (return) a
happyReport' :: () => [(Token)] -> [Happy_Prelude.String] -> ([(Token)] -> (Err a)) -> (Err a)
happyReport' = (\tokens expected resume -> happyError tokens)
happyAbort :: () => [(Token)] -> (Err a)
happyAbort = Happy_Prelude.error "Called abort handler in non-resumptive parser"
pExp tks = happySomeParser where
happySomeParser = happyThen (happyParse 0# tks) (\x -> happyReturn (let {(HappyWrap10 x') = happyOut10 x} in x'))
happySeq = happyDontSeq
type Err = Either String
happyError :: [Token] -> Err a
happyError ts = Left $
"syntax error at " ++ tokenPos ts ++
case ts of
[] -> []
[Err _] -> " due to lexer error"
t:_ -> " before `" ++ (prToken t) ++ "'"
myLexer :: String -> [Token]
myLexer = tokens
#define HAPPY_COERCE 1
-- $Id: GenericTemplate.hs,v 1.26 2005/01/14 14:47:22 simonmar Exp $
#if !defined(__GLASGOW_HASKELL__)
# error This code isn't being built with GHC.
#endif
-- Get WORDS_BIGENDIAN (if defined)
#include "MachDeps.h"
-- Do not remove this comment. Required to fix CPP parsing when using GCC and a clang-compiled alex.
#define LT(n,m) ((Happy_GHC_Exts.tagToEnum# (n Happy_GHC_Exts.<# m)) :: Happy_Prelude.Bool)
#define GTE(n,m) ((Happy_GHC_Exts.tagToEnum# (n Happy_GHC_Exts.>=# m)) :: Happy_Prelude.Bool)
#define EQ(n,m) ((Happy_GHC_Exts.tagToEnum# (n Happy_GHC_Exts.==# m)) :: Happy_Prelude.Bool)
#define PLUS(n,m) (n Happy_GHC_Exts.+# m)
#define MINUS(n,m) (n Happy_GHC_Exts.-# m)
#define TIMES(n,m) (n Happy_GHC_Exts.*# m)
#define NEGATE(n) (Happy_GHC_Exts.negateInt# (n))
type Happy_Int = Happy_GHC_Exts.Int#
data Happy_IntList = HappyCons Happy_Int Happy_IntList
#define INVALID_TOK -1#
#define ERROR_TOK 0#
#define CATCH_TOK 1#
#if defined(HAPPY_COERCE)
# define GET_ERROR_TOKEN(x) (case Happy_GHC_Exts.unsafeCoerce# x of { (Happy_GHC_Exts.I# i) -> i })
# define MK_ERROR_TOKEN(i) (Happy_GHC_Exts.unsafeCoerce# (Happy_GHC_Exts.I# i))
# define MK_TOKEN(x) (happyInTok (x))
#else
# define GET_ERROR_TOKEN(x) (case x of { HappyErrorToken (Happy_GHC_Exts.I# i) -> i })
# define MK_ERROR_TOKEN(i) (HappyErrorToken (Happy_GHC_Exts.I# i))
# define MK_TOKEN(x) (HappyTerminal (x))
#endif
#if defined(HAPPY_DEBUG)
# define DEBUG_TRACE(s) (happyTrace (s)) Happy_Prelude.$
happyTrace string expr = Happy_System_IO_Unsafe.unsafePerformIO Happy_Prelude.$ do
Happy_System_IO.hPutStr Happy_System_IO.stderr string
Happy_Prelude.return expr
#else
# define DEBUG_TRACE(s) {- nothing -}
#endif
infixr 9 `HappyStk`
data HappyStk a = HappyStk a (HappyStk a)
-----------------------------------------------------------------------------
-- starting the parse
happyParse start_state = happyNewToken start_state notHappyAtAll notHappyAtAll
-----------------------------------------------------------------------------
-- Accepting the parse
-- If the current token is ERROR_TOK, it means we've just accepted a partial
-- parse (a %partial parser). We must ignore the saved token on the top of
-- the stack in this case.
happyAccept ERROR_TOK tk st sts (_ `HappyStk` ans `HappyStk` _) =
happyReturn1 ans
happyAccept j tk st sts (HappyStk ans _) =
(happyTcHack j (happyTcHack st)) (happyReturn1 ans)
-----------------------------------------------------------------------------
-- Arrays only: do the next action
happyDoAction i tk st =
DEBUG_TRACE("state: " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# st) Happy_Prelude.++
",\ttoken: " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# i) Happy_Prelude.++
",\taction: ")
case happyDecodeAction (happyNextAction i st) of
HappyFail -> DEBUG_TRACE("failing.\n")
happyFail i tk st
HappyAccept -> DEBUG_TRACE("accept.\n")
happyAccept i tk st
HappyReduce rule -> DEBUG_TRACE("reduce (rule " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# rule) Happy_Prelude.++ ")")
(happyReduceArr Happy_Data_Array.! (Happy_GHC_Exts.I# rule)) i tk st
HappyShift new_state -> DEBUG_TRACE("shift, enter state " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# new_state) Happy_Prelude.++ "\n")
happyShift new_state i tk st
{-# INLINE happyNextAction #-}
happyNextAction i st = case happyIndexActionTable i st of
Happy_Prelude.Just (Happy_GHC_Exts.I# act) -> act
Happy_Prelude.Nothing -> happyIndexOffAddr happyDefActions st
{-# INLINE happyIndexActionTable #-}
happyIndexActionTable i st
| GTE(i, 0#), GTE(off, 0#), EQ(happyIndexOffAddr happyCheck off, i)
-- i >= 0: Guard against INVALID_TOK (do the default action, which ultimately errors)
-- off >= 0: Otherwise it's a default action
-- equality check: Ensure that the entry in the compressed array is owned by st
= Happy_Prelude.Just (Happy_GHC_Exts.I# (happyIndexOffAddr happyTable off))
| Happy_Prelude.otherwise
= Happy_Prelude.Nothing
where
off = PLUS(happyIndexOffAddr happyActOffsets st, i)
data HappyAction
= HappyFail
| HappyAccept
| HappyReduce Happy_Int -- rule number
| HappyShift Happy_Int -- new state
deriving Happy_Prelude.Show
{-# INLINE happyDecodeAction #-}
happyDecodeAction :: Happy_Int -> HappyAction
happyDecodeAction 0# = HappyFail
happyDecodeAction -1# = HappyAccept
happyDecodeAction action | LT(action, 0#) = HappyReduce NEGATE(PLUS(action, 1#))
| Happy_Prelude.otherwise = HappyShift MINUS(action, 1#)
{-# INLINE happyIndexGotoTable #-}
happyIndexGotoTable nt st = happyIndexOffAddr happyTable off
where
off = PLUS(happyIndexOffAddr happyGotoOffsets st, nt)
{-# INLINE happyIndexOffAddr #-}
happyIndexOffAddr :: HappyAddr -> Happy_Int -> Happy_Int
happyIndexOffAddr (HappyA# arr) off =
#if __GLASGOW_HASKELL__ >= 901
Happy_GHC_Exts.int32ToInt# -- qualified import because it doesn't exist on older GHC's
#endif
#ifdef WORDS_BIGENDIAN
-- The CI of `alex` tests this code path
(Happy_GHC_Exts.word32ToInt32# (Happy_GHC_Exts.wordToWord32# (Happy_GHC_Exts.byteSwap32# (Happy_GHC_Exts.word32ToWord# (Happy_GHC_Exts.int32ToWord32#
#endif
(Happy_GHC_Exts.indexInt32OffAddr# arr off)
#ifdef WORDS_BIGENDIAN
)))))
#endif
happyIndexRuleArr :: Happy_Int -> (# Happy_Int, Happy_Int #)
happyIndexRuleArr r = (# nt, len #)
where
!(Happy_GHC_Exts.I# n_starts) = happy_n_starts
offs = TIMES(MINUS(r,n_starts),2#)
nt = happyIndexOffAddr happyRuleArr offs
len = happyIndexOffAddr happyRuleArr PLUS(offs,1#)
data HappyAddr = HappyA# Happy_GHC_Exts.Addr#
-----------------------------------------------------------------------------
-- Shifting a token
happyShift new_state ERROR_TOK tk st sts stk@(x `HappyStk` _) =
-- See "Error Fixup" below
let i = GET_ERROR_TOKEN(x) in
DEBUG_TRACE("shifting the error token")
happyDoAction i tk new_state (HappyCons st sts) stk
happyShift new_state i tk st sts stk =
happyNewToken new_state (HappyCons st sts) (MK_TOKEN(tk) `HappyStk` stk)
-- happyReduce is specialised for the common cases.
happySpecReduce_0 nt fn j tk st sts stk
= happySeq fn (happyGoto nt j tk st (HappyCons st sts) (fn `HappyStk` stk))
happySpecReduce_1 nt fn j tk old_st sts@(HappyCons st _) (v1 `HappyStk` stk')
= let r = fn v1 in
happyTcHack old_st (happySeq r (happyGoto nt j tk st sts (r `HappyStk` stk')))
happySpecReduce_2 nt fn j tk old_st
(HappyCons _ sts@(HappyCons st _))
(v1 `HappyStk` v2 `HappyStk` stk')
= let r = fn v1 v2 in
happyTcHack old_st (happySeq r (happyGoto nt j tk st sts (r `HappyStk` stk')))
happySpecReduce_3 nt fn j tk old_st
(HappyCons _ (HappyCons _ sts@(HappyCons st _)))
(v1 `HappyStk` v2 `HappyStk` v3 `HappyStk` stk')
= let r = fn v1 v2 v3 in
happyTcHack old_st (happySeq r (happyGoto nt j tk st sts (r `HappyStk` stk')))
happyReduce k nt fn j tk st sts stk
= case happyDrop MINUS(k,(1# :: Happy_Int)) sts of
sts1@(HappyCons st1 _) ->
let r = fn stk in -- it doesn't hurt to always seq here...
st `happyTcHack` happyDoSeq r (happyGoto nt j tk st1 sts1 r)
happyMonadReduce k nt fn j tk st sts stk =
case happyDrop k (HappyCons st sts) of
sts1@(HappyCons st1 _) ->
let drop_stk = happyDropStk k stk in
j `happyTcHack` happyThen1 (fn stk tk)
(\r -> happyGoto nt j tk st1 sts1 (r `HappyStk` drop_stk))
happyMonad2Reduce k nt fn j tk st sts stk =
case happyDrop k (HappyCons st sts) of
sts1@(HappyCons st1 _) ->
let drop_stk = happyDropStk k stk
off = happyIndexOffAddr happyGotoOffsets st1
off_i = PLUS(off, nt)
new_state = happyIndexOffAddr happyTable off_i
in
j `happyTcHack` happyThen1 (fn stk tk)
(\r -> happyNewToken new_state sts1 (r `HappyStk` drop_stk))
happyDrop 0# l = l
happyDrop n (HappyCons _ t) = happyDrop MINUS(n,(1# :: Happy_Int)) t
happyDropStk 0# l = l
happyDropStk n (x `HappyStk` xs) = happyDropStk MINUS(n,(1#::Happy_Int)) xs
-----------------------------------------------------------------------------
-- Moving to a new state after a reduction
happyGoto nt j tk st =
DEBUG_TRACE(", goto state " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# new_state) Happy_Prelude.++ "\n")
happyDoAction j tk new_state
where new_state = happyIndexGotoTable nt st
{- Note [Error recovery]
~~~~~~~~~~~~~~~~~~~~~~~~
When there is no applicable action for the current lookahead token `tk`,
happy enters error recovery mode. Depending on whether the grammar file
declares the two action form `%error { abort } { report }` for
Resumptive Error Handling,
it works in one (not resumptive) or two phases (resumptive):
1. Fixup mode:
Try to see if there is an action for the error token ERROR_TOK. If there
is, do *not* emit an error and pretend instead that an `error` token was
inserted.
When there is no ERROR_TOK action, report an error.
In non-resumptive error handling, calling the single error handler
(e.g. `happyError`) will throw an exception and abort the parser.
However, in resumptive error handling we enter *error resumption mode*.
2. Error resumption mode:
After reporting the error (with `report`), happy will attempt to find
a good state stack to resume parsing in.
For each candidate stack, it discards input until one of the candidates
resumes (i.e. shifts the current input).
If no candidate resumes before the end of input, resumption failed and
calls the `abort` function, to much the same effect as in non-resumptive
error handling.
Candidate stacks are declared by the grammar author using the special
`catch` terminal and called "catch frames".
This mechanism is described in detail in Note [happyResume].
The `catch` resumption mechanism (2) is what usually is associated with
`error` in `bison` or `menhir`. Since `error` is used for the Fixup mechanism
(1) above, we call the corresponding token `catch`.
Furthermore, in constrast to `bison`, our implementation of `catch`
non-deterministically considers multiple catch frames on the stack for
resumption (See Note [Multiple catch frames]).
Note [happyResume]
~~~~~~~~~~~~~~~~~~
`happyResume` implements the resumption mechanism from Note [Error recovery].
It is best understood by example. Consider
Exp :: { String }
Exp : '1' { "1" }
| catch { "catch" }
| Exp '+' Exp %shift { $1 Happy_Prelude.++ " + " Happy_Prelude.++ $3 } -- %shift: associate 1 + 1 + 1 to the right
| '(' Exp ')' { "(" Happy_Prelude.++ $2 Happy_Prelude.++ ")" }
The idea of the use of `catch` here is that upon encountering a parse error
during expression parsing, we can gracefully degrade using the `catch` rule,
still producing a partial syntax tree and keep on parsing to find further
syntax errors.
Let's trace the parser state for input 11+1, which will error out after shifting 1.
After shifting, we have the following item stack (growing downwards and omitting
transitive closure items):
State 0: %start_parseExp -> . Exp
State 5: Exp -> '1' .
(Stack as a list of state numbers: [5,0].)
As Note [Error recovery] describes, we will first try Fixup mode.
That fails because no production can shift the `error` token.
Next we try Error resumption mode. This works as follows:
1. Pop off the item stack until we find an item that can shift the `catch`
token. (Implemented in `pop_items`.)
* State 5 cannot shift catch. Pop.
* State 0 can shift catch, which would transition into
State 4: Exp -> catch .
So record the *stack* `[4,0]` after doing the shift transition.
We call this a *catch frame*, where the top is a *catch state*,
corresponding to an item in which we just shifted a `catch` token.
There can be multiple such catch stacks, see Note [Multiple catch frames].
2. Discard tokens from the input until the lookahead can be shifted in one
of the catch stacks. (Implemented in `discard_input_until_exp` and
`some_catch_state_shifts`.)
* We cannot shift the current lookahead '1' in state 4, so we discard
* We *can* shift the next lookahead '+' in state 4, but only after
reducing, which pops State 4 and goes to State 3:
State 3: %start_parseExp -> Exp .
Exp -> Exp . '+' Exp
Here we can shift '+'.
As you can see, to implement this machinery we need to simulate
the operation of the LALR automaton, especially reduction
(`happySimulateReduce`).
Note [Multiple catch frames]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
For fewer spurious error messages, it can be beneficial to trace multiple catch
items. Consider
Exp : '1'
| catch
| Exp '+' Exp %shift
| '(' Exp ')'
Let's trace the parser state for input (;+1, which will error out after shifting (.
After shifting, we have the following item stack (growing downwards):
State 0: %start_parseExp -> . Exp
State 6: Exp -> '(' . Exp ')'
Upon error, we want to find items in the stack which can shift a catch token.
Note that both State 0 and State 6 can shift a catch token, transitioning into
State 4: Exp -> catch .
Hence we record the catch frames `[4,6,0]` and `[4,0]` for possible resumption.
Which catch frame do we pick for resumption?
Note that resuming catch frame `[4,0]` will parse as "catch+1", whereas
resuming the innermost frame `[4,6,0]` corresponds to parsing "(catch+1".
The latter would keep discarding input until the closing ')' is found.
So we will discard + and 1, leading to a spurious syntax error at the end of
input, aborting the parse and never producing a partial syntax tree. Bad!
It is far preferable to resume with catch frame `[4,0]`, where we can resume
successfully on input +, so that is what we do.
In general, we pick the catch frame for resumption that discards the least
amount of input for a successful shift, preferring the topmost such catch frame.
-}
-- happyFail :: Happy_Int -> Token -> Happy_Int -> _
-- This function triggers Note [Error recovery].
-- If the current token is ERROR_TOK, phase (1) has failed and we might try
-- phase (2).
happyFail ERROR_TOK = happyFixupFailed
happyFail i = happyTryFixup i
-- Enter Error Fixup (see Note [Error recovery]):
-- generate an error token, save the old token and carry on.
-- When a `happyShift` accepts the error token, we will pop off the error token
-- to resume parsing with the current lookahead `i`.
happyTryFixup i tk action sts stk =
DEBUG_TRACE("entering `error` fixup.\n")
happyDoAction ERROR_TOK tk action sts (MK_ERROR_TOKEN(i) `HappyStk` stk)
-- NB: `happyShift` will simply pop the error token and carry on with
-- `tk`. Hence we don't change `tk` in the call here
-- See Note [Error recovery], phase (2).
-- Enter resumption mode after reporting the error by calling `happyResume`.
happyFixupFailed tk st sts (x `HappyStk` stk) =
let i = GET_ERROR_TOKEN(x) in
DEBUG_TRACE("`error` fixup failed.\n")
let resume = happyResume i tk st sts stk
expected = happyExpectedTokens st sts in
happyReport i tk expected resume
-- happyResume :: Happy_Int -> Token -> Happy_Int -> _
-- See Note [happyResume]
happyResume i tk st sts stk = pop_items [] st sts stk
where
!(Happy_GHC_Exts.I# n_starts) = happy_n_starts -- this is to test whether we have a start token
!(Happy_GHC_Exts.I# eof_i) = happy_n_terms Happy_Prelude.- 1 -- this is the token number of the EOF token
happy_list_to_list :: Happy_IntList -> [Happy_Prelude.Int]
happy_list_to_list (HappyCons st sts)
| LT(st, n_starts)
= [(Happy_GHC_Exts.I# st)]
| Happy_Prelude.otherwise
= (Happy_GHC_Exts.I# st) : happy_list_to_list sts
-- See (1) of Note [happyResume]
pop_items catch_frames st sts stk
| LT(st, n_starts)
= DEBUG_TRACE("reached start state " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# st) Happy_Prelude.++ ", ")
if Happy_Prelude.null catch_frames_new
then DEBUG_TRACE("no resumption.\n")
happyAbort
else DEBUG_TRACE("now discard input, trying to anchor in states " Happy_Prelude.++ Happy_Prelude.show (Happy_Prelude.map (happy_list_to_list . Happy_Prelude.fst) (Happy_Prelude.reverse catch_frames_new)) Happy_Prelude.++ ".\n")
discard_input_until_exp i tk (Happy_Prelude.reverse catch_frames_new)
| (HappyCons st1 sts1) <- sts, _ `HappyStk` stk1 <- stk
= pop_items catch_frames_new st1 sts1 stk1
where
!catch_frames_new
| HappyShift new_state <- happyDecodeAction (happyNextAction CATCH_TOK st)
, DEBUG_TRACE("can shift catch token in state " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# st) Happy_Prelude.++ ", into state " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# new_state) Happy_Prelude.++ "\n")
Happy_Prelude.null (Happy_Prelude.filter (\(HappyCons _ (HappyCons h _),_) -> EQ(st,h)) catch_frames)
= (HappyCons new_state (HappyCons st sts), MK_ERROR_TOKEN(i) `HappyStk` stk):catch_frames -- MK_ERROR_TOKEN(i) is just some dummy that should not be accessed by user code
| Happy_Prelude.otherwise
= DEBUG_TRACE("already shifted or can't shift catch in " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# st) Happy_Prelude.++ "\n")
catch_frames
-- See (2) of Note [happyResume]
discard_input_until_exp i tk catch_frames
| Happy_Prelude.Just (HappyCons st (HappyCons catch_st sts), catch_frame) <- some_catch_state_shifts i catch_frames
= DEBUG_TRACE("found expected token in state " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# st) Happy_Prelude.++ " after shifting from " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# catch_st) Happy_Prelude.++ ": " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# i) Happy_Prelude.++ "\n")
happyDoAction i tk st (HappyCons catch_st sts) catch_frame
| EQ(i,eof_i) -- is i EOF?
= DEBUG_TRACE("reached EOF, cannot resume. abort parse :(\n")
happyAbort
| Happy_Prelude.otherwise
= DEBUG_TRACE("discard token " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# i) Happy_Prelude.++ "\n")
happyLex (\eof_tk -> discard_input_until_exp eof_i eof_tk catch_frames) -- eof
(\i tk -> discard_input_until_exp i tk catch_frames) -- not eof
some_catch_state_shifts _ [] = DEBUG_TRACE("no catch state could shift.\n") Happy_Prelude.Nothing
some_catch_state_shifts i catch_frames@(((HappyCons st sts),_):_) = try_head i st sts catch_frames
where
try_head i st sts catch_frames = -- PRECONDITION: head catch_frames = (HappyCons st sts)
DEBUG_TRACE("trying token " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# i) Happy_Prelude.++ " in state " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# st) Happy_Prelude.++ ": ")
case happyDecodeAction (happyNextAction i st) of
HappyFail -> DEBUG_TRACE("fail.\n") some_catch_state_shifts i (Happy_Prelude.tail catch_frames)
HappyAccept -> DEBUG_TRACE("accept.\n") Happy_Prelude.Just (Happy_Prelude.head catch_frames)
HappyShift _ -> DEBUG_TRACE("shift.\n") Happy_Prelude.Just (Happy_Prelude.head catch_frames)
HappyReduce r -> case happySimulateReduce r st sts of
(HappyCons st1 sts1) -> try_head i st1 sts1 catch_frames
happySimulateReduce r st sts =
DEBUG_TRACE("simulate reduction of rule " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# r) Happy_Prelude.++ ", ")
let (# nt, len #) = happyIndexRuleArr r in
DEBUG_TRACE("nt " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# nt) Happy_Prelude.++ ", len: " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# len) Happy_Prelude.++ ", new_st ")
let !(sts1@(HappyCons st1 _)) = happyDrop len (HappyCons st sts)
new_st = happyIndexGotoTable nt st1 in
DEBUG_TRACE(Happy_Prelude.show (Happy_GHC_Exts.I# new_st) Happy_Prelude.++ ".\n")
(HappyCons new_st sts1)
happyTokenToString :: Happy_Prelude.Int -> Happy_Prelude.String
happyTokenToString i = happyTokenStrings Happy_Prelude.!! (i Happy_Prelude.- 2) -- 2: errorTok, catchTok
happyExpectedTokens :: Happy_Int -> Happy_IntList -> [Happy_Prelude.String]
-- Upon a parse error, we want to suggest tokens that are expected in that
-- situation. This function computes such tokens.
-- It works by examining the top of the state stack.
-- For every token number that does a shift transition, record that token number.
-- For every token number that does a reduce transition, simulate that reduction
-- on the state state stack and repeat.
-- The recorded token numbers are then formatted with 'happyTokenToString' and
-- returned.
happyExpectedTokens st sts =
DEBUG_TRACE("constructing expected tokens.\n")
Happy_Prelude.map happyTokenToString (search_shifts st sts [])
where
search_shifts st sts shifts = Happy_Prelude.foldr (add_action st sts) shifts (distinct_actions st)
add_action st sts (Happy_GHC_Exts.I# i, Happy_GHC_Exts.I# act) shifts =
DEBUG_TRACE("found action in state " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# st) Happy_Prelude.++ ", input " Happy_Prelude.++ Happy_Prelude.show (Happy_GHC_Exts.I# i) Happy_Prelude.++ ", " Happy_Prelude.++ Happy_Prelude.show (happyDecodeAction act) Happy_Prelude.++ "\n")
case happyDecodeAction act of
HappyFail -> shifts
HappyAccept -> shifts -- This would always be %eof or error... Not helpful
HappyShift _ -> Happy_Prelude.insert (Happy_GHC_Exts.I# i) shifts
HappyReduce r -> case happySimulateReduce r st sts of
(HappyCons st1 sts1) -> search_shifts st1 sts1 shifts
distinct_actions st
-- The (token number, action) pairs of all actions in the given state
= ((-1), (Happy_GHC_Exts.I# (happyIndexOffAddr happyDefActions st)))
: [ (i, act) | i <- [begin_i..happy_n_terms], act <- get_act row_off i ]
where
row_off = happyIndexOffAddr happyActOffsets st
begin_i = 2 -- +2: errorTok,catchTok
get_act off (Happy_GHC_Exts.I# i) -- happyIndexActionTable with cached row offset
| let off_i = PLUS(off,i)
, GTE(off_i,0#)
, EQ(happyIndexOffAddr happyCheck off_i,i)
= [(Happy_GHC_Exts.I# (happyIndexOffAddr happyTable off_i))]
| Happy_Prelude.otherwise
= []
-- Internal happy errors:
notHappyAtAll :: a
notHappyAtAll = Happy_Prelude.error "Internal Happy parser panic. This is not supposed to happen! Please open a bug report at https://github.com/haskell/happy/issues.\n"
-----------------------------------------------------------------------------
-- Hack to get the typechecker to accept our action functions
happyTcHack :: Happy_Int -> a -> a
happyTcHack x y = y
{-# INLINE happyTcHack #-}
-----------------------------------------------------------------------------
-- Seq-ing. If the --strict flag is given, then Happy emits
-- happySeq = happyDoSeq
-- otherwise it emits
-- happySeq = happyDontSeq
happyDoSeq, happyDontSeq :: a -> b -> b
happyDoSeq a b = a `Happy_GHC_Exts.seq` b
happyDontSeq a b = b
-----------------------------------------------------------------------------
-- Don't inline any functions from the template. GHC has a nasty habit
-- of deciding to inline happyGoto everywhere, which increases the size of
-- the generated parser quite a bit.
{-# NOINLINE happyDoAction #-}
{-# NOINLINE happyTable #-}
{-# NOINLINE happyCheck #-}
{-# NOINLINE happyActOffsets #-}
{-# NOINLINE happyGotoOffsets #-}
{-# NOINLINE happyDefActions #-}
{-# NOINLINE happyShift #-}
{-# NOINLINE happySpecReduce_0 #-}
{-# NOINLINE happySpecReduce_1 #-}
{-# NOINLINE happySpecReduce_2 #-}
{-# NOINLINE happySpecReduce_3 #-}
{-# NOINLINE happyReduce #-}
{-# NOINLINE happyMonadReduce #-}
{-# NOINLINE happyGoto #-}
{-# NOINLINE happyFail #-}
-- end of Happy Template.