-- -*- Mode: Haskell; -*- -- -- QuickCheck tests for Megaparsec's lexer. -- -- Copyright © 2015 Megaparsec contributors -- -- Redistribution and use in source and binary forms, with or without -- modification, are permitted provided that the following conditions are -- met: -- -- * Redistributions of source code must retain the above copyright notice, -- this list of conditions and the following disclaimer. -- -- * Redistributions in binary form must reproduce the above copyright -- notice, this list of conditions and the following disclaimer in the -- documentation and/or other materials provided with the distribution. -- -- This software is provided by the copyright holders "as is" and any -- express or implied warranties, including, but not limited to, the implied -- warranties of merchantability and fitness for a particular purpose are -- disclaimed. In no event shall the copyright holders be liable for any -- direct, indirect, incidental, special, exemplary, or consequential -- damages (including, but not limited to, procurement of substitute goods -- or services; loss of use, data, or profits; or business interruption) -- however caused and on any theory of liability, whether in contract, -- strict liability, or tort (including negligence or otherwise) arising in -- any way out of the use of this software, even if advised of the -- possibility of such damage. module Lexer (tests) where import Control.Applicative (empty) import Control.Monad (void) #if MIN_VERSION_base(4,7,0) import Data.Bool (bool) #endif import Data.Char ( readLitChar , showLitChar , isDigit , isAlphaNum , isSpace , toLower ) import Data.List (findIndices, isInfixOf, find) import Data.Maybe (listToMaybe, maybeToList, isNothing, fromJust) import Numeric (showInt, showHex, showOct, showSigned) import Test.Framework import Test.Framework.Providers.QuickCheck2 (testProperty) import Test.QuickCheck import Text.Megaparsec.Error import Text.Megaparsec.Lexer import Text.Megaparsec.Pos import Text.Megaparsec.Prim import Text.Megaparsec.String import qualified Text.Megaparsec.Char as C import Util #if !MIN_VERSION_base(4,8,0) import Control.Applicative ((<$>), (<*), (<*>)) #endif #if !MIN_VERSION_base(4,7,0) bool :: a -> a -> Bool -> a bool f _ False = f bool _ t True = t #endif tests :: Test tests = testGroup "Lexer" [ testProperty "space combinator" prop_space , testProperty "symbol combinator" prop_symbol , testProperty "symbol' combinator" prop_symbol' , testProperty "indentGuard combinator" prop_indentGuard , testProperty "charLiteral" prop_charLiteral , testProperty "integer" prop_integer , testProperty "decimal" prop_decimal , testProperty "hexadecimal" prop_hexadecimal , testProperty "octal" prop_octal , testProperty "float 0" prop_float_0 , testProperty "float 1" prop_float_1 , testProperty "number" prop_number , testProperty "signed" prop_signed ] newtype WhiteSpace = WhiteSpace { getWhiteSpace :: String } deriving (Show, Eq) instance Arbitrary WhiteSpace where arbitrary = WhiteSpace . concat <$> listOf whiteUnit newtype Symbol = Symbol { getSymbol :: String } deriving (Show, Eq) instance Arbitrary Symbol where arbitrary = Symbol <$> ((++) <$> symbolName <*> whiteChars) whiteUnit :: Gen String whiteUnit = oneof [whiteChars, whiteLine, whiteBlock] whiteChars :: Gen String whiteChars = listOf $ elements "\t\n " whiteLine :: Gen String whiteLine = commentOut <$> arbitrary `suchThat` goodEnough where commentOut x = "//" ++ x ++ "\n" goodEnough x = '\n' `notElem` x whiteBlock :: Gen String whiteBlock = commentOut <$> arbitrary `suchThat` goodEnough where commentOut x = "/*" ++ x ++ "*/" goodEnough x = not $ "*/" `isInfixOf` x symbolName :: Gen String symbolName = listOf $ arbitrary `suchThat` isAlphaNum sc :: Parser () sc = space (void C.spaceChar) l b where l = skipLineComment "//" b = skipBlockComment "/*" "*/" sc' :: Parser () sc' = space (void $ C.oneOf " \t") empty empty prop_space :: WhiteSpace -> Property prop_space w = checkParser p r s where p = sc r = Right () s = getWhiteSpace w prop_symbol :: Symbol -> Maybe Char -> Property prop_symbol = parseSymbol (symbol sc) id prop_symbol' :: Symbol -> Maybe Char -> Property prop_symbol' = parseSymbol (symbol' sc) (fmap toLower) parseSymbol :: (String -> Parser String) -> (String -> String) -> Symbol -> Maybe Char -> Property parseSymbol p' f s' t = checkParser p r s where p = p' (f g) r | g == s || isSpace (last s) = Right g | otherwise = posErr (length s - 1) s [uneCh (last s), exEof] g = takeWhile (not . isSpace) s s = getSymbol s' ++ maybeToList t newtype IndLine = IndLine { getIndLine :: String } deriving (Show, Eq) instance Arbitrary IndLine where arbitrary = IndLine . concat <$> sequence [spc, sym, spc, eol] where spc = listOf (elements " \t") sym = return "xxx" eol = return "\n" prop_indentGuard :: IndLine -> IndLine -> IndLine -> Property prop_indentGuard l0 l1 l2 = checkParser p r s where p = ip (> 1) >>= \x -> sp >> ip (== x) >> sp >> ip (> x) >> sp ip = indentGuard sc' sp = void $ symbol sc' "xxx" <* C.eol r | f' l0 <= 1 = posErr 0 s msg' | f' l1 /= f' l0 = posErr (f l1 + g [l0]) s msg' | f' l2 <= f' l0 = posErr (f l2 + g [l0, l1]) s msg' | otherwise = Right () msg' = [msg "incorrect indentation"] f = length . takeWhile isSpace . getIndLine f' x = sourceColumn $ updatePosString defaultTabWidth (initialPos "") $ take (f x) (getIndLine x) g xs = sum $ length . getIndLine <$> xs s = concat $ getIndLine <$> [l0, l1, l2] prop_charLiteral :: String -> Bool -> Property prop_charLiteral t i = checkParser charLiteral r s where b = listToMaybe $ readLitChar s (h, g) = fromJust b r | isNothing b = posErr 0 s $ exSpec "literal character" : [ if null s then uneEof else uneCh (head s) ] | null g = Right h | otherwise = posErr l s [uneCh (head g), exEof] l = length s - length g s = if null t || i then t else showLitChar (head t) (tail t) prop_integer :: NonNegative Integer -> Int -> Property prop_integer n' i = checkParser integer r s where (r, s) = quasiCorrupted n' i showInt "integer" prop_decimal :: NonNegative Integer -> Int -> Property prop_decimal n' i = checkParser decimal r s where (r, s) = quasiCorrupted n' i showInt "decimal integer" prop_hexadecimal :: NonNegative Integer -> Int -> Property prop_hexadecimal n' i = checkParser hexadecimal r s where (r, s) = quasiCorrupted n' i showHex "hexadecimal integer" prop_octal :: NonNegative Integer -> Int -> Property prop_octal n' i = checkParser octal r s where (r, s) = quasiCorrupted n' i showOct "octal integer" prop_float_0 :: NonNegative Double -> Property prop_float_0 n' = checkParser float r s where n = getNonNegative n' r = Right n s = show n prop_float_1 :: Maybe (NonNegative Integer) -> Property prop_float_1 n' = checkParser float r s where r | isNothing n' = posErr 0 s [uneEof, exSpec "float"] | otherwise = posErr (length s) s [ uneEof, exCh '.', exCh 'E' , exCh 'e', exSpec "digit" ] s = maybe "" (show . getNonNegative) n' prop_number :: Either (NonNegative Integer) (NonNegative Double) -> Integer -> Property prop_number n' i = checkParser number r s where r | null s = posErr 0 s [uneEof, exSpec "number"] | otherwise = Right $ case n' of Left x -> Left $ getNonNegative x Right x -> Right $ getNonNegative x s = if i < 5 then "" else either (show . getNonNegative) (show . getNonNegative) n' prop_signed :: Integer -> Int -> Bool -> Property prop_signed n i plus = checkParser p r s where p = signed (hidden C.space) integer r | i > length z = Right n | otherwise = posErr i s $ uneCh '?' : (if i <= 0 then [exCh '+', exCh '-'] else []) ++ [exSpec $ bool "rest of integer" "integer" $ isNothing . find isDigit $ take i s] ++ [exEof | i > head (findIndices isDigit s)] z = let bar = showSigned showInt 0 n "" in if n < 0 || plus then bar else '+' : bar s = if i <= length z then take i z ++ "?" ++ drop i z else z quasiCorrupted :: NonNegative Integer -> Int -> (Integer -> String -> String) -> String -> (Either ParseError Integer, String) quasiCorrupted n' i shower l = (r, s) where n = getNonNegative n' r | i > length z = Right n | otherwise = posErr i s $ uneCh '?' : [ exEof | i > 0 ] ++ [if i <= 0 || null l then exSpec l else exSpec $ "rest of " ++ l] z = shower n "" s = if i <= length z then take i z ++ "?" ++ drop i z else z