megaparsec/tests/Prim.hs

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-- -*- Mode: Haskell; -*-
--
-- QuickCheck tests for Megaparsec's primitive parser combinators.
--
-- 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.
{-# OPTIONS -fno-warn-orphans #-}
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module Prim (tests) where
import Control.Applicative
import Control.Monad (guard)
import Data.Bool (bool)
import Data.Char (isLetter)
import Data.Foldable (asum)
import Data.List (isPrefixOf)
import Data.Maybe (maybeToList)
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import Test.Framework
import Test.Framework.Providers.QuickCheck2 (testProperty)
import Test.QuickCheck
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import Text.Megaparsec.Char
import Text.Megaparsec.Pos
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import Text.Megaparsec.Prim
import Text.Megaparsec.String
import Pos ()
import Util
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tests :: Test
tests = testGroup "Primitive parser combinators"
[ testProperty "ParsecT functor" prop_functor
, testProperty "ParsecT applicative (<*>)" prop_applicative_0
, testProperty "ParsecT applicative (*>)" prop_applicative_1
, testProperty "ParsecT applicative (<*)" prop_applicative_2
, testProperty "ParsecT alternative empty and (<|>)" prop_alternative_0
, testProperty "ParsecT alternative (<|>)" prop_alternative_1
, testProperty "ParsecT alternative (<|>) pos" prop_alternative_2
, testProperty "ParsecT alternative (<|>) hints" prop_alternative_3
, testProperty "ParsecT alternative many" prop_alternative_4
, testProperty "ParsecT alternative some" prop_alternative_5
, testProperty "ParsecT alternative optional" prop_alternative_6
, testProperty "ParsecT monad return" prop_monad_0
, testProperty "ParsecT monad (>>)" prop_monad_1
, testProperty "ParsecT monad (>>=)" prop_monad_2
, testProperty "ParsecT monad fail" prop_monad_3
, testProperty "combinator unexpected" prop_unexpected
, testProperty "combinator label" prop_label
, testProperty "combinator hidden" prop_hidden
, testProperty "combinator try" prop_try
, testProperty "combinator lookAhead" prop_lookAhead_0
, testProperty "combinator lookAhead hints" prop_lookAhead_1
, testProperty "combinator lookAhead messages" prop_lookAhead_2
, testProperty "combinator notFollowedBy" prop_notFollowedBy_0
, testProperty "combinator notFollowedBy twice" prop_notFollowedBy_1
, testProperty "combinator notFollowedBy eof" prop_notFollowedBy_2
, testProperty "combinator token" prop_token
, testProperty "combinator tokens" prop_tokens
, testProperty "parser state position" prop_state_pos
, testProperty "parser state input" prop_state_input
, testProperty "parser state general" prop_state
, testProperty "user state set and get" prop_user_state
, testProperty "user state backtracking" prop_user_backtrack ]
instance Arbitrary u => Arbitrary (State String u) where
arbitrary = State <$> arbitrary <*> arbitrary <*> arbitrary
-- Functor instance
prop_functor :: Integer -> Integer -> Property
prop_functor n m =
((+ m) <$> return n) /=\ n + m .&&. ((* n) <$> return m) /=\ n * m
-- Applicative instance
prop_applicative_0 :: Integer -> Integer -> Property
prop_applicative_0 n m = ((+) <$> pure n <*> pure m) /=\ n + m
prop_applicative_1 :: Integer -> Integer -> Property
prop_applicative_1 n m = (pure n *> pure m) /=\ m
prop_applicative_2 :: Integer -> Integer -> Property
prop_applicative_2 n m = (pure n <* pure m) /=\ n
-- Alternative instance
prop_alternative_0 :: Integer -> Property
prop_alternative_0 n = (empty <|> return n) /=\ n
prop_alternative_1 :: String -> String -> Property
prop_alternative_1 s0 s1
| s0 == s1 = checkParser p (Right s0) s1
| null s0 = checkParser p (posErr 0 s1 [uneCh (head s1), exEof]) s1
| s0 `isPrefixOf` s1 =
checkParser p (posErr s0l s1 [uneCh (s1 !! s0l), exEof]) s1
| otherwise = checkParser p (Right s0) s0 .&&. checkParser p (Right s1) s1
where p = try (string s0) <|> string s1
s0l = length s0
prop_alternative_2 :: Char -> Char -> Char -> Bool -> Property
prop_alternative_2 a b c l = checkParser p r s
where p = char a <|> (char b >> char a)
r | l = Right a
| a == b = posErr 1 s [uneCh c, exEof]
| a == c = Right a
| otherwise = posErr 1 s [uneCh c, exCh a]
s = if l then [a] else [b,c]
prop_alternative_3 :: Property
prop_alternative_3 = checkParser p r s
where p = asum [empty, try (string ">>>"), empty, return "foo"] <?> "bar"
p' = bsum [empty, try (string ">>>"), empty, return "foo"] <?> "bar"
bsum = foldl (<|>) empty
r = simpleParse p' s
s = ">>"
prop_alternative_4 :: NonNegative Int -> NonNegative Int -> NonNegative Int ->
Property
prop_alternative_4 a' b' c' = checkParser p r s
where [a,b,c] = getNonNegative <$> [a',b',c']
p = (++) <$> many (char 'a') <*> many (char 'b')
r | null s = Right s
| c > 0 = posErr (a + b) s $ [uneCh 'c', exCh 'b', exEof]
++ [exCh 'a' | b == 0]
| otherwise = Right s
s = abcRow a b c
prop_alternative_5 :: NonNegative Int -> NonNegative Int -> NonNegative Int ->
Property
prop_alternative_5 a' b' c' = checkParser p r s
where [a,b,c] = getNonNegative <$> [a',b',c']
p = (++) <$> some (char 'a') <*> some (char 'b')
r | null s = posErr 0 s [uneEof, exCh 'a']
| a == 0 = posErr 0 s [uneCh (head s), exCh 'a']
| b == 0 = posErr a s $ [exCh 'a', exCh 'b'] ++
if c > 0 then [uneCh 'c'] else [uneEof]
| c > 0 = posErr (a + b) s [uneCh 'c', exCh 'b', exEof]
| otherwise = Right s
s = abcRow a b c
prop_alternative_6 :: Bool -> Bool -> Bool -> Property
prop_alternative_6 a b c = checkParser p r s
where p = f <$> optional (char 'a') <*> optional (char 'b')
f x y = maybe "" (:[]) x ++ maybe "" (:[]) y
r | c = posErr ab s $ [uneCh 'c', exEof] ++
[exCh 'a' | not a && not b] ++ [exCh 'b' | not b]
| otherwise = Right s
s = abcRow' a b c
ab = fromEnum a + fromEnum b
-- Monad instance
prop_monad_0 :: Integer -> Property
prop_monad_0 n = checkParser (return n) (Right n) ""
prop_monad_1 :: Char -> Char -> Maybe Char -> Property
prop_monad_1 a b c = checkParser p r s
where p = char a >> char b
r = simpleParse (char a *> char b) s
s = a : b : maybeToList c
prop_monad_2 :: Char -> Char -> Maybe Char -> Property
prop_monad_2 a b c = checkParser p r s
where p = char a >>= \x -> char b >> return x
r = simpleParse (char a <* char b) s
s = a : b : maybeToList c
prop_monad_3 :: String -> Property
prop_monad_3 m = checkParser p r s
where p = fail m :: Parser ()
r | null m = posErr 0 s []
| otherwise = posErr 0 s [msg m]
s = ""
-- TODO MonadReader instance
-- TODO MonadState instance
-- Primitive combinators
prop_unexpected :: String -> Property
prop_unexpected m = checkParser p r s
where p = unexpected m :: Parser ()
r | null m = posErr 0 s []
| otherwise = posErr 0 s [uneSpec m]
s = ""
prop_label :: NonNegative Int -> NonNegative Int -> NonNegative Int ->
String -> Property
prop_label a' b' c' l = checkParser p r s
where [a,b,c] = getNonNegative <$> [a',b',c']
p = (++) <$> many (char 'a') <*> (many (char 'b') <?> l)
r | null s = Right s
| c > 0 = posErr (a + b) s $ [uneCh 'c', exSpec l, exEof]
++ [exCh 'a' | b == 0]
| otherwise = Right s
s = abcRow a b c
prop_hidden :: NonNegative Int -> NonNegative Int -> NonNegative Int ->
Property
prop_hidden a' b' c' = checkParser p r s
where [a,b,c] = getNonNegative <$> [a',b',c']
p = (++) <$> many (char 'a') <*> hidden (many (char 'b'))
r | null s = Right s
| c > 0 = posErr (a + b) s $ [uneCh 'c', exEof]
++ [exCh 'a' | b == 0]
| otherwise = Right s
s = abcRow a b c
prop_try :: String -> String -> String -> Property
prop_try pre s1' s2' = checkParser p r s
where s1 = pre ++ s1'
s2 = pre ++ s2'
p = try (string s1) <|> string s2
r | s == s1 || s == s2 = Right s
| otherwise = posErr 0 s $ bool [uneStr pre] [uneEof] (null s)
++ [uneStr pre, exStr s1, exStr s2]
s = pre
prop_lookAhead_0 :: Bool -> Bool -> Bool -> Property
prop_lookAhead_0 a b c = checkParser p r s
where p = do
l <- lookAhead (oneOf "ab" <?> "label")
guard (l == h)
char 'a'
h = head s
r | null s = posErr 0 s [uneEof, exSpec "label"]
| s == "a" = Right 'a'
| h == 'b' = posErr 0 s [uneCh 'b', exCh 'a']
| h == 'c' = posErr 0 s [uneCh 'c', exSpec "label"]
| otherwise = posErr 1 s [uneCh (s !! 1), exEof]
s = abcRow' a b c
prop_lookAhead_1 :: String -> Property
prop_lookAhead_1 s = checkParser p r s
where p = lookAhead (some letterChar) >> fail "failed" :: Parser ()
h = head s
r | null s = posErr 0 s [uneEof, exSpec "letter"]
| isLetter h = posErr 0 s [msg "failed"]
| otherwise = posErr 0 s [uneCh h, exSpec "letter"]
prop_lookAhead_2 :: Bool -> Bool -> Bool -> Property
prop_lookAhead_2 a b c = checkParser p r s
where p = lookAhead (some (char 'a')) >> char 'b'
r | null s = posErr 0 s [uneEof, exCh 'a']
| a = posErr 0 s [uneCh 'a', exCh 'b']
| otherwise = posErr 0 s [uneCh (head s), exCh 'a']
s = abcRow' a b c
prop_notFollowedBy_0 :: NonNegative Int -> NonNegative Int -> NonNegative Int ->
Property
prop_notFollowedBy_0 a' b' c' = checkParser p r s
where [a,b,c] = getNonNegative <$> [a',b',c']
p = many (char 'a') <* notFollowedBy (char 'b') <* many (char 'c')
r | b > 0 = posErr a s [uneCh 'b', exCh 'a']
| otherwise = Right (replicate a 'a')
s = abcRow a b c
prop_notFollowedBy_1 :: NonNegative Int -> NonNegative Int -> NonNegative Int ->
Property
prop_notFollowedBy_1 a' b' c' = checkParser p r s
where [a,b,c] = getNonNegative <$> [a',b',c']
p = many (char 'a') <* f (char 'c') <* many (char 'c')
f = notFollowedBy . notFollowedBy -- = 'lookAhead' in this case
r | b == 0 && c > 0 = Right (replicate a 'a')
| b > 0 = posErr a s [uneCh 'b', exCh 'a']
| otherwise = posErr a s [uneEof, exCh 'a']
s = abcRow a b c
prop_notFollowedBy_2 :: NonNegative Int -> NonNegative Int -> NonNegative Int ->
Property
prop_notFollowedBy_2 a' b' c' = checkParser p r s
where [a,b,c] = getNonNegative <$> [a',b',c']
p = many (char 'a') <* notFollowedBy eof <* many anyChar
r | b > 0 || c > 0 = Right (replicate a 'a')
| otherwise = posErr a s [uneEof, exCh 'a']
s = abcRow a b c
-- We omit tests for 'eof' here because it's used virtually everywhere, it's
-- already thoroughly tested.
prop_token :: String -> Property
prop_token s = checkParser p r s
where p = token nextPos testChar
nextPos pos x _ = updatePosChar pos x
testChar x = if isLetter x then Just x else Nothing
h = head s
r | null s = posErr 0 s [uneEof]
| isLetter h && length s == 1 = Right (head s)
| isLetter h && length s > 1 = posErr 1 s [uneCh (s !! 1), exEof]
| otherwise = posErr 0 s [uneCh h]
prop_tokens :: String -> String -> Property
prop_tokens a = checkString p a (showToken a)
where p = tokens updatePosString a
-- Parser state combinators
prop_state_pos :: SourcePos -> Property
prop_state_pos pos = p /=\ pos
where p = setPosition pos >> getPosition
prop_state_input :: String -> Property
prop_state_input s = p /=\ s
where p = do
st0 <- getInput
guard (null st0)
setInput s
result <- string s
st1 <- getInput
guard (null st1)
return result
prop_state :: State String Integer -> State String Integer -> Property
prop_state s1 s2 = runParser p 0 "" "" === Right (f s2 s1)
where f (State s1' pos u1) (State s2' _ u2) =
State (max s1' s2' ) pos (u1 + u2)
p = do
st <- getParserState
guard (st == State "" (initialPos "") 0)
setParserState s1
updateParserState (f s2)
getParserState
-- User state combinators
prop_user_state :: Integer -> Integer -> Property
prop_user_state n m = runParser p 0 "" "" === Right (n + m)
where p = setState n >> modifyState (+ m) >> getState
prop_user_backtrack :: Integer -> Integer -> Property
prop_user_backtrack n m = runParser p 0 "" "" === Right n
where p = setState n >> lookAhead (setState m >> eof) >> getState