flatparse-0.3.4.0: test/Test.hs
{-# LANGUAGE ScopedTypeVariables #-}
module Main where
import Data.ByteString (ByteString)
import qualified Data.ByteString as B
import qualified Data.Char
import FlatParse.Basic
import Test.HUnit
import Test.Hspec
import Test.Hspec.QuickCheck
import Test.QuickCheck hiding ( (.&.) )
import Data.Word
import Data.Int
import Data.Bits
import Test.QuickCheck.Instances.ByteString()
main :: IO ()
main = hspec $ do
basicSpec
-- | The spec for FlatParse.Basic.
basicSpec :: SpecWith ()
basicSpec = describe "FlatParse.Basic" $ do
describe "Errors and failures" $ do
describe "empty" $
it "always fails" $ empty `shouldParseFail` ""
describe "err" $
it "throws an error" $ err "nope" `shouldParseErr` ""
describe "lookahead" $
it "restores state" $ do
let p = lookahead $(string "fun") *> $(string "function")
p `shouldParse` "function"
describe "fails" $ do
it "expects child to fail" $ fails empty `shouldParse` ""
it "fails when child succeeds" $ fails (pure ()) `shouldParseFail` ""
it "propagates errors" $ fails (err "nope") `shouldParseErr` ""
describe "try" $
it "turns error into failure" $ try (err "nope") `shouldParseFail` ""
describe "optional" $ do
it "can succeed" $ optional (pure ()) `shouldParseWith` ("", Just ())
it "can succeed when argument missing" $
optional empty `shouldParseWith` ("", Nothing)
it "propagates errors" $ optional (err "nope") `shouldParseErr` ""
describe "optional_" $ do
it "can succeed" $ optional (pure ()) `shouldParse` ""
it "can succeed when argument missing" $ optional empty `shouldParse` ""
it "propagates errors" $ optional (err "nope") `shouldParseErr` ""
describe "optioned" $ do
let opt p = optioned p (pure . reverse) (pure "bar")
it "handles success" $ opt (pure "foo") `shouldParseWith` ("", "oof")
it "handles failure" $ opt empty `shouldParseWith` ("", "bar")
it "handles error" $ opt (err "nope") `shouldParseErr` ""
describe "cut" $ do
it "turns failure into error" $ empty `cut` "nope" `shouldParseErr` ""
it "leaves success alone" $ pure () `cut` "nope" `shouldParse` ""
it "propagates error" $
err "inner" `cut` "outer" `shouldParseErrWith` ("", "inner")
describe "cutting" $ do
it "turns failure into error" $
cutting empty "nope" (++) `shouldParseErrWith` ("", "nope")
it "leaves success alone" $ do
cutting (pure ()) "nope" (++) `shouldParse` ""
it "combines errors" $
cutting (err "!!!") "nope" (++) `shouldParseErrWith` ("", "!!!nope")
describe "Basic lexing and parsing" $ do
describe "eof" $ do
it "succeeds at end of file" $ eof `shouldParse` ""
it "fails with more input" $ eof `shouldParseFail` "more"
describe "char" $ do
it "succeeds on that char" $ $(char 'a') `shouldParse` "a"
it "succeeds on multibyte char" $ $(char 'ȩ') `shouldParse` packUTF8 "ȩ"
it "fails on the wrong char" $ $(char 'a') `shouldParseFail` "b"
it "fails at end of file" $ $(char 'a') `shouldParseFail` ""
describe "byte" $ do
it "succeeds on that byte" $ byte 0x61 `shouldParse` "\x61"
it "succeeds on high bytes" $ byte 0xfe `shouldParse` "\xfe"
it "fails on the wrong byte" $ byte 0x61 `shouldParseFail` "\x62"
it "fails on end of file" $ byte 0x61 `shouldParseFail` ""
describe "bytes" $ do
it "succeeds on those bytes" $
$(bytes [1, 2, 3, 4]) `shouldParse` "\x01\x02\x03\x04"
it "succeeds on high bytes" $
$(bytes [0xf1, 0xf2, 0xf3, 0xf4]) `shouldParse` "\xf1\xf2\xf3\xf4"
it "fails on wrong bytes" $
$(bytes [1, 2, 5, 4]) `shouldParseFail` "\x01\x02\x03\x04"
it "fails when out of space" $
$(bytes [1, 2, 3, 4]) `shouldParseFail` "\x01\x02\x03"
describe "string" $ do
it "succeeds on the right string" $ $(string "foo") `shouldParse` "foo"
it "succeeds with multibyte chars" $
$(string "foȩ") `shouldParse` packUTF8 "foȩ"
it "fails on the wrong string" $ $(string "foo") `shouldParseFail` "bar"
it "fails when out of space" $ $(string "foo") `shouldParseFail` "fo"
describe "switch" $ do
it "parses simple words" $
$( switch
[|
case _ of
"foo" -> pure 1
"bar" -> pure 2
|]
)
`shouldParseWith` ("foo", 1)
it "matches the default" $
$( switch
[|
case _ of
"foo" -> pure 1
"bar" -> pure 2
_ -> pure 0
|]
)
`shouldParsePartialWith` ("fez", 0)
it "fails with no default" $
$( switch
[|
case _ of
"foo" -> pure 1
"bar" -> pure 2
|]
)
`shouldParseFail` "fez"
it "prefers longest match" $
$( switch
[|
case _ of
"foo" -> pure 1
"foobar" -> pure 2
|]
)
`shouldParseWith` ("foobar", 2)
it "doesn't reproduce bug #12" $
$( switch
[|
case _ of
"Eac" -> pure ()
"EAc" -> pure ()
"E" -> pure ()
|]
)
`shouldParse` "E"
describe "switchWithPost" $ do
it "applies post after match" $
$( switchWithPost
(Just [|$(string "bar")|])
[|
case _ of
"foo" -> pure ()
|]
)
`shouldParse` "foobar"
it "doesn't apply post after default" $
$( switchWithPost
(Just [|$(string "bar")|])
[|
case _ of
"foo" -> pure ()
_ -> pure ()
|]
)
`shouldParse` ""
it "requires the post must match" $
$( switchWithPost
(Just [|$(string "bar")|])
[|
case _ of
"foo" -> pure ()
|]
)
`shouldParseFail` "foo"
describe "rawSwitchWithPost" $ do
it "parses simple words" $
$( rawSwitchWithPost
Nothing
[ ("foo", [|pure 1|]),
("bar", [|pure 2|])
]
Nothing
)
`shouldParseWith` ("foo", 1)
it "matches the default" $
$( rawSwitchWithPost
Nothing
[ ("foo", [|pure 1|]),
("bar", [|pure 2|])
]
(Just [|pure 0|])
)
`shouldParsePartialWith` ("fez", 0)
it "fails with no default" $
$( rawSwitchWithPost
Nothing
[ ("foo", [|pure 1|]),
("bar", [|pure 2|])
]
Nothing
)
`shouldParseFail` "fez"
it "prefers longest match" $
$( rawSwitchWithPost
Nothing
[ ("foo", [|pure 1|]),
("foobar", [|pure 2|])
]
Nothing
)
`shouldParseWith` ("foobar", 2)
it "applies post after match" $
$( rawSwitchWithPost
(Just [|$(string "bar")|])
[("foo", [|pure ()|])]
Nothing
)
`shouldParse` "foobar"
it "doesn't apply post after default" $
$( rawSwitchWithPost
(Just [|$(string "bar")|])
[("foo", [|pure ()|])]
(Just [|pure ()|])
)
`shouldParse` ""
it "requires the post must match" $
$( rawSwitchWithPost
(Just [|$(string "bar")|])
[("foo", [|pure ()|])]
Nothing
)
`shouldParseFail` "foo"
describe "satisfy" $ do
it "succeeds on the right char" $
satisfy (== 'a') `shouldParseWith` ("a", 'a')
it "succeeds on multi-byte chars" $ do
let chars = "$¢€𐍈" :: [Char]
sequence_
[ if a == b
then satisfy (== a) `shouldParseWith` (packUTF8 (pure b), b)
else satisfy (== a) `shouldParseFail` packUTF8 (pure b)
| a <- chars,
b <- chars
]
it "fails on the wrong char" $
satisfy (== 'a') `shouldParseFail` "b"
it "fails at end of file" $
satisfy (== 'a') `shouldParseFail` ""
describe "satisfyASCII" $ do
it "succeeds on the right char" $
satisfyASCII (== 'a') `shouldParseWith` ("a", 'a')
it "fails on the wrong char" $
satisfyASCII (== 'a') `shouldParseFail` "b"
it "fails on the wrong multi-byte char" $
-- The specification for satisfyASCII requires that the predicate
-- return False for non-ASCII characters, but multi-byte chars are
-- still allowed in the input.
satisfyASCII (== 'a') `shouldParseFail` packUTF8 "ȩ"
it "fails at end of file" $
satisfyASCII (== 'a') `shouldParseFail` ""
describe "satisfyASCII_" $ do
it "succeeds on the right char" $
satisfyASCII_ (== 'a') `shouldParseWith` ("a", ())
it "fails on the wrong char" $
satisfyASCII_ (== 'a') `shouldParseFail` "b"
it "fails on the wrong multi-byte char" $
satisfyASCII_ (== 'a') `shouldParseFail` packUTF8 "ȩ"
it "fails at end of file" $
satisfyASCII_ (== 'a') `shouldParseFail` ""
describe "fusedSatisfy" $ do
it "correctly routes chars based on length" $ do
fusedSatisfy (== '$') (const False) (const False) (const False)
`shouldParse` packUTF8 "$"
fusedSatisfy (const False) (== '¢') (const False) (const False)
`shouldParse` packUTF8 "¢"
fusedSatisfy (const False) (const False) (== '€') (const False)
`shouldParse` packUTF8 "€"
fusedSatisfy (const False) (const False) (const False) (== '𐍈')
`shouldParse` packUTF8 "𐍈"
it "fails on empty input" $
fusedSatisfy (const True) (const True) (const True) (const True)
`shouldParseFail` ""
describe "anyWord8" $ do
it "reads a byte" $ anyWord8 `shouldParseWith` ("\xef", 0xef)
it "fails on empty input" $ anyWord8 `shouldParseFail` ""
describe "anyWord16" $ do
-- Byte order is unspecified, so just assert that it succeeds.
it "succeeds" $ anyWord16 `shouldParse` "\xef\xbe"
it "fails on empty input" $ anyWord16 `shouldParseFail` ""
it "fails on insufficient input" $ anyWord16 `shouldParseFail` "\xff"
describe "anyWord32" $ do
-- Byte order is unspecified, so just assert that it succeeds.
it "succeeds" $ anyWord32 `shouldParse` "\xef\xbe\xae\x7e"
it "fails on empty input" $ anyWord32 `shouldParseFail` ""
it "fails on insufficient input" $
anyWord32 `shouldParseFail` "\xff\xff\xff"
describe "anyWord" $ do
-- This combinator is inherently non-portable, but we know a Word is at
-- least some bytes.
it "fails on empty input" $ anyWord `shouldParseFail` ""
describe "anyChar" $ do
it "reads 1-byte char" $ anyChar `shouldParseWith` (packUTF8 "$", '$')
it "reads 2-byte char" $ anyChar `shouldParseWith` (packUTF8 "¢", '¢')
it "reads 3-byte char" $ anyChar `shouldParseWith` (packUTF8 "€", '€')
it "reads 4-byte char" $ anyChar `shouldParseWith` (packUTF8 "𐍈", '𐍈')
it "fails on empty input" $ anyChar `shouldParseFail` ""
describe "anyChar_" $ do
it "reads 1-byte char" $ anyChar_ `shouldParseWith` (packUTF8 "$", ())
it "reads 2-byte char" $ anyChar_ `shouldParseWith` (packUTF8 "¢", ())
it "reads 3-byte char" $ anyChar_ `shouldParseWith` (packUTF8 "€", ())
it "reads 4-byte char" $ anyChar_ `shouldParseWith` (packUTF8 "𐍈", ())
it "fails on empty input" $ anyChar_ `shouldParseFail` ""
describe "anyCharASCII" $ do
it "reads ASCII char" $ anyCharASCII `shouldParseWith` (packUTF8 "$", '$')
it "fails on non-ASCII char" $ anyCharASCII `shouldParseFail` packUTF8 "¢"
it "fails on empty input" $ anyCharASCII `shouldParseFail` ""
describe "anyCharASCII_" $ do
it "reads ASCII char" $ anyCharASCII_ `shouldParseWith` (packUTF8 "$", ())
it "fails on non-ASCII char" $
anyCharASCII_ `shouldParseFail` packUTF8 "¢"
it "fails on empty input" $ anyCharASCII_ `shouldParseFail` ""
describe "isDigit" $ do
it "agrees with Data.Char" $
property $
\c -> isDigit c === Data.Char.isDigit c
describe "isLatinLetter" $ do
it "agrees with Data.Char" $
property $
\c ->
isLatinLetter c
=== (Data.Char.isAsciiUpper c || Data.Char.isAsciiLower c)
describe "readInt" $ do
it "round-trips on non-negative Ints" $
property $
\(NonNegative i) -> readInt `shouldParseWith` (packUTF8 (show i), i)
it "fails on non-integers" $ readInt `shouldParseFail` "foo"
it "fails on negative integers" $ readInt `shouldParseFail` "-5"
it "fails on empty input" $ readInt `shouldParseFail` ""
describe "readInteger" $ do
it "round-trips on non-negative Integers" $
property $
\(NonNegative i) ->
readInteger `shouldParseWith` (packUTF8 (show i), i)
it "fails on non-integers" $ readInteger `shouldParseFail` "foo"
it "fails on negative integers" $ readInteger `shouldParseFail` "-5"
it "fails on empty input" $ readInteger `shouldParseFail` ""
describe "Explicit-endianness machine integers" $ do
describe "Unsigned" $ do
prop "parses Word8s" $ do
\(w :: Word8) -> anyWord8 `shouldParseWith` (w8AsByteString w, w)
prop "parses Word16s (LE)" $ do
\(w :: Word16) -> anyWord16le `shouldParseWith` (w16leAsByteString w, w)
prop "parses Word16s (BE)" $ do
\(w :: Word16) -> anyWord16be `shouldParseWith` (B.reverse (w16leAsByteString w), w)
prop "parses Word32s (LE)" $ do
\(w :: Word32) -> anyWord32le `shouldParseWith` (w32leAsByteString w, w)
prop "parses Word32s (BE)" $ do
\(w :: Word32) -> anyWord32be `shouldParseWith` (B.reverse (w32leAsByteString w), w)
prop "parses Word64s (LE)" $ do
\(w :: Word64) -> anyWord64le `shouldParseWith` (w64leAsByteString w, w)
prop "parses Word64s (BE)" $ do
\(w :: Word64) -> anyWord64be `shouldParseWith` (B.reverse (w64leAsByteString w), w)
describe "Signed" $ do
prop "parses Int8s" $ do
\(i :: Int8) -> anyInt8 `shouldParseWith` (w8AsByteString i, i)
prop "parses Int16s (LE)" $ do
\(i :: Int16) -> anyInt16le `shouldParseWith` (w16leAsByteString i, i)
prop "parses Int16s (BE)" $ do
\(i :: Int16) -> anyInt16be `shouldParseWith` (B.reverse (w16leAsByteString i), i)
prop "parses Int32s (LE)" $ do
\(i :: Int32) -> anyInt32le `shouldParseWith` (w32leAsByteString i, i)
prop "parses Int32s (BE)" $ do
\(i :: Int32) -> anyInt32be `shouldParseWith` (B.reverse (w32leAsByteString i), i)
prop "parses Int64s (LE)" $ do
\(i :: Int64) -> anyInt64le `shouldParseWith` (w64leAsByteString i, i)
prop "parses Int64s (BE)" $ do
\(i :: Int64) -> anyInt64be `shouldParseWith` (B.reverse (w64leAsByteString i), i)
describe "Combinators" $ do
describe "Functor instance" $ do
it "fmaps over the result" $
((+ 2) <$> readInt) `shouldParseWith` ("2", 4)
describe "Applicative instance" $ do
it "combines using <*>" $
((+) <$> readInt <* $(string "+") <*> readInt)
`shouldParseWith` ("2+3", 5)
describe "Monad instance" $ do
it "combines with a do block" $ do
let parser = do
i <- readInt
$(string "+")
j <- readInt
pure (i + j)
parser `shouldParseWith` ("2+3", 5)
describe "(<|>)" $ do
it "chooses first option on success" $
(("A" <$ $(string "foo")) <|> ("B" <$ $(string "foo")))
`shouldParseWith` ("foo", "A")
it "chooses second option when first fails" $
(("A" <$ $(string "bar")) <|> ("B" <$ $(string "foo")))
`shouldParseWith` ("foo", "B")
describe "branch" $ do
it "chooses the first branch on success" $
branch (pure ()) (pure "A") (pure "B") `shouldParseWith` ("", "A")
it "does not backtrack from first branch" $
branch (pure ()) empty (pure "B") `shouldParseFail` ""
it "chooses the second branch on failure" $
branch empty (pure "A") (pure "B") `shouldParseWith` ("", "B")
describe "chainl" $ do
it "parses a chain of numbers" $
chainl (+) readInt ($(char '+') *> readInt)
`shouldParseWith` ("1+2+3", 6)
it "allows the right chain to be empty" $
chainl (+) readInt ($(char '+') *> readInt)
`shouldParseWith` ("1", 1)
it "requires at least the leftmost parser to match" $
chainl (+) readInt ($(char '+') *> readInt)
`shouldParseFail` ""
describe "chainr" $ do
it "parses a chain of numbers" $
chainr (+) (readInt <* $(char '+')) readInt
`shouldParseWith` ("1+2+3", 6)
it "allows the left chain to be empty" $
chainr (+) (readInt <* $(char '+')) readInt
`shouldParseWith` ("1", 1)
it "requires at least the rightmost parser to match" $
chainr (+) (readInt <* $(char '+')) readInt
`shouldParseFail` ""
describe "many" $ do
it "parses many chars" $
many (satisfy isLatinLetter) `shouldParseWith` ("abc", "abc")
it "accepts empty input" $
many (satisfy isLatinLetter) `shouldParseWith` ("", "")
it "is greedy" $
(many (satisfy isDigit) *> satisfy isDigit) `shouldParseFail` "123"
describe "many_" $ do
it "parses many chars" $
many_ (satisfy isLatinLetter) `shouldParseWith` ("abc", ())
it "accepts empty input" $
many_ (satisfy isLatinLetter) `shouldParseWith` ("", ())
it "is greedy" $
(many_ (satisfy isDigit) *> satisfy isDigit) `shouldParseFail` "123"
describe "some" $ do
it "parses some chars" $
some (satisfy isLatinLetter) `shouldParseWith` ("abc", "abc")
it "rejects empty input" $
some (satisfy isLatinLetter) `shouldParseFail` ""
it "is greedy" $
(some (satisfy isDigit) *> satisfy isDigit) `shouldParseFail` "123"
describe "some_" $ do
it "parses some chars" $
some_ (satisfy isLatinLetter) `shouldParseWith` ("abc", ())
it "rejects empty input" $
some_ (satisfy isLatinLetter) `shouldParseFail` ""
it "is greedy" $
(some_ (satisfy isDigit) *> satisfy isDigit) `shouldParseFail` "123"
describe "notFollowedBy" $ do
it "succeeds when it should" $
readInt `notFollowedBy` $(char '.') `shouldParsePartial` "123+5"
it "fails when first parser doesn't match" $
readInt `notFollowedBy` $(char '.') `shouldParseFail` "a"
it "fails when followed by the wrong thing" $
readInt `notFollowedBy` $(char '.') `shouldParseFail` "123.0"
describe "isolate" $ do
prop "isolate takeRestBs is identity" $ do
\(bs :: ByteString) ->
isolate (B.length bs) takeRestBs `shouldParseWith` (bs, bs)
prop "isolate takeBs length is identity" $ do
\(bs :: ByteString) ->
isolate (B.length bs) (takeBs (B.length bs)) `shouldParseWith` (bs, bs)
describe "Positions and spans" $ do
describe "Pos Ord instance" $ do
pure ()
describe "getPos" $ do
pure ()
describe "setPos" $ do
pure ()
describe "endPos" $ do
pure ()
describe "spanOf" $ do
pure ()
describe "spanned" $ do
pure ()
describe "byteStringOf" $ do
pure ()
describe "byteStringed" $ do
pure ()
describe "inSpan" $ do
pure ()
describe "Positions and span conversions" $ do
describe "validPos" $ do
pure ()
describe "posLineCols" $ do
pure ()
describe "unsafeSpanToByteString" $ do
pure ()
describe "unsafeSlice" $ do
pure ()
describe "mkPos" $ do
pure ()
describe "lines" $ do
pure ()
describe "Getting the rest of the input as a String" $ do
describe "takeLine" $ do
pure ()
describe "traceLine" $ do
pure ()
describe "takeRest" $ do
pure ()
describe "traceRest" $ do
pure ()
describe "String conversions" $ do
describe "packUTF8" $ do
pure ()
describe "unpackUTF8" $ do
pure ()
--------------------------------------------------------------------------------
w8AsByteString :: (Bits w, Num w, Integral w) => w -> ByteString
w8AsByteString w = B.pack [b1]
where
b1 = fromIntegral $ w .&. 0x00FF
w16leAsByteString :: (Bits w, Num w, Integral w) => w -> ByteString
w16leAsByteString w = B.pack [b1, b2]
where
b1 = fromIntegral $ w .&. 0x00FF
b2 = fromIntegral $ (w .&. 0xFF00) `shiftR` 8
w32leAsByteString :: (Bits w, Num w, Integral w) => w -> ByteString
w32leAsByteString w = B.pack [b1, b2, b3, b4]
where
b1 = fromIntegral $ w .&. 0x000000FF
b2 = fromIntegral $ (w .&. 0x0000FF00) `shiftR` 8
b3 = fromIntegral $ (w .&. 0x00FF0000) `shiftR` 16
b4 = fromIntegral $ (w .&. 0xFF000000) `shiftR` 24
w64leAsByteString :: (Bits w, Num w, Integral w) => w -> ByteString
w64leAsByteString w = B.pack [b1, b2, b3, b4, b5, b6, b7, b8]
where
b1 = fromIntegral $ w .&. 0x00000000000000FF
b2 = fromIntegral $ (w .&. 0x000000000000FF00) `shiftR` 8
b3 = fromIntegral $ (w .&. 0x0000000000FF0000) `shiftR` 16
b4 = fromIntegral $ (w .&. 0x00000000FF000000) `shiftR` 24
b5 = fromIntegral $ (w .&. 0x000000FF00000000) `shiftR` 32
b6 = fromIntegral $ (w .&. 0x0000FF0000000000) `shiftR` 40
b7 = fromIntegral $ (w .&. 0x00FF000000000000) `shiftR` 48
b8 = fromIntegral $ (w .&. 0xFF00000000000000) `shiftR` 56
--------------------------------------------------------------------------------
-- Some combinators that make it easier to assert the results of a parser.
-- | The parser should parse this string, consuming it entirely, and succeed.
shouldParse :: Show e => Parser e a -> ByteString -> Expectation
p `shouldParse` s = case runParser p s of
OK _ "" -> pure ()
OK _ lo -> assertFailure $ "Unexpected leftover: " ++ show lo
Fail -> assertFailure "Parse failed unexpectedly"
Err e -> assertFailure $ "Parse threw unexpected error: " ++ show e
-- | The parser should parse this string, possibly with leftovers, and succeed.
shouldParsePartial :: Show e => Parser e a -> ByteString -> Expectation
p `shouldParsePartial` s = case runParser p s of
OK _ lo -> pure ()
Fail -> assertFailure "Parse failed unexpectedly"
Err e -> assertFailure $ "Parse threw unexpected error: " ++ show e
-- | The parser should parse this string, consuming it entirely, and succeed
-- yielding the matching value.
shouldParseWith ::
(Show a, Eq a, Show e) => Parser e a -> (ByteString, a) -> Expectation
p `shouldParseWith` (s, r) = case runParser p s of
OK r' "" -> r' `shouldBe` r
OK _ lo -> assertFailure $ "Unexpected leftover: " ++ show lo
Fail -> assertFailure "Parse failed unexpectedly"
Err e -> assertFailure $ "Parse threw unexpected error: " ++ show e
-- | The parser should parse this string, possibly with leftovers, and succeed
-- yielding the matching value.
shouldParsePartialWith ::
(Show a, Eq a, Show e) => Parser e a -> (ByteString, a) -> Expectation
p `shouldParsePartialWith` (s, r) = case runParser p s of
OK r' lo -> r' `shouldBe` r
Fail -> assertFailure "Parse failed unexpectedly"
Err e -> assertFailure $ "Parse threw unexpected error: " ++ show e
-- | The parser should fail when given this string.
shouldParseFail :: Show e => Parser e a -> ByteString -> Expectation
p `shouldParseFail` s = case runParser p s of
Fail -> pure ()
OK _ _ -> assertFailure "Parse succeeded unexpectedly"
Err e -> assertFailure $ "Parse threw unexpected error: " ++ show e
-- | The parser should throw an error when given this string.
shouldParseErr :: Parser e a -> ByteString -> Expectation
p `shouldParseErr` s = case runParser p s of
Err e -> pure ()
Fail -> assertFailure "Parse failed unexpectedly"
OK _ _ -> assertFailure "Parse succeeded unexpectedly"
-- | The parser should throw an error when given this string, and the error
-- should be the one given.
shouldParseErrWith ::
(Show e, Eq e) => Parser e a -> (ByteString, e) -> Expectation
p `shouldParseErrWith` (s, e) = case runParser p s of
Err e' -> e' `shouldBe` e
Fail -> assertFailure "Parse failed unexpectedly"
OK _ _ -> assertFailure "Parse succeeded unexpectedly"