module Dhall.Parser (
exprFromText
, exprAndHeaderFromText
, expr, exprA
, Src(..)
, ParseError(..)
, Parser(..)
) where
import Control.Applicative (Alternative(..), liftA2, optional)
import Control.Exception (Exception)
import Control.Monad (MonadPlus)
import Data.ByteString (ByteString)
import Data.Functor (void)
import Data.Map (Map)
import Data.Monoid ((<>))
import Data.Sequence (ViewL(..))
import Data.String (IsString(..))
import Data.Text.Buildable (Buildable(..))
import Data.Text.Lazy (Text)
import Data.Text.Lazy.Builder (Builder)
import Data.Typeable (Typeable)
import Dhall.Core
import Numeric.Natural (Natural)
import Prelude hiding (const, pi)
import Text.PrettyPrint.ANSI.Leijen (Doc)
import Text.Parser.Combinators (choice, try, (<?>))
import Text.Parser.Token (TokenParsing(..))
import Text.Trifecta
(CharParsing, DeltaParsing, MarkParsing, Parsing, Result(..))
import Text.Trifecta.Delta (Delta)
import qualified Control.Monad
import qualified Data.ByteString.Base16.Lazy
import qualified Data.Char
import qualified Data.HashSet
import qualified Data.Map
import qualified Data.ByteString.Lazy
import qualified Data.Sequence
import qualified Data.Text
import qualified Data.Text.Encoding
import qualified Data.Text.Lazy
import qualified Data.Text.Lazy.Builder
import qualified Data.Text.Lazy.Encoding
import qualified Data.Vector
import qualified Filesystem.Path.CurrentOS
import qualified Text.Parser.Char
import qualified Text.Parser.Combinators
import qualified Text.Parser.Token
import qualified Text.Parser.Token.Style
import qualified Text.PrettyPrint.ANSI.Leijen
import qualified Text.Trifecta
data Src = Src Delta Delta ByteString deriving (Eq, Show)
instance Buildable Src where
build (Src begin _ bytes) =
build text <> "\n"
<> "\n"
<> build (show (Text.PrettyPrint.ANSI.Leijen.pretty begin))
<> "\n"
where
bytes' = Data.ByteString.Lazy.fromStrict bytes
text = Data.Text.Lazy.strip (Data.Text.Lazy.Encoding.decodeUtf8 bytes')
newtype Parser a = Parser { unParser :: Text.Trifecta.Parser a }
deriving
( Functor
, Applicative
, Monad
, Alternative
, MonadPlus
, Parsing
, CharParsing
, DeltaParsing
, MarkParsing Delta
)
instance Monoid a => Monoid (Parser a) where
mempty = pure mempty
mappend = liftA2 mappend
instance IsString a => IsString (Parser a) where
fromString x = fmap fromString (Text.Parser.Char.string x)
instance TokenParsing Parser where
someSpace =
Text.Parser.Token.Style.buildSomeSpaceParser
(Parser someSpace)
Text.Parser.Token.Style.haskellCommentStyle
nesting (Parser m) = Parser (nesting m)
semi = Parser semi
highlight h (Parser m) = Parser (highlight h m)
noted :: Parser (Expr Src a) -> Parser (Expr Src a)
noted parser = do
before <- Text.Trifecta.position
(e, bytes) <- Text.Trifecta.slicedWith (,) parser
after <- Text.Trifecta.position
return (Note (Src before after bytes) e)
count :: Monoid a => Int -> Parser a -> Parser a
count n parser = mconcat (replicate n parser)
range :: Monoid a => Int -> Int -> Parser a -> Parser a
range minimumBound maximumMatches parser =
count minimumBound parser <> loop maximumMatches
where
loop 0 = mempty
loop n = (parser <> loop (n 1)) <|> mempty
option :: (Alternative f, Monoid a) => f a -> f a
option p = p <|> pure mempty
star :: (Alternative f, Monoid a) => f a -> f a
star p = plus p <|> pure mempty
plus :: (Alternative f, Monoid a) => f a -> f a
plus p = mappend <$> p <*> star p
satisfy :: (Char -> Bool) -> Parser Builder
satisfy predicate =
fmap Data.Text.Lazy.Builder.singleton (Text.Parser.Char.satisfy predicate)
blockComment :: Parser ()
blockComment = do
_ <- Text.Parser.Char.text "{-"
blockCommentContinue
blockCommentChunk :: Parser ()
blockCommentChunk =
choice
[ blockComment
, character
, endOfLine
]
where
character = void (Text.Parser.Char.satisfy predicate)
where
predicate c = '\x20' <= c && c <= '\x10FFFF' || c == '\n' || c == '\t'
endOfLine = void (Text.Parser.Char.text "\r\n")
blockCommentContinue :: Parser ()
blockCommentContinue = endOfComment <|> continue
where
endOfComment = void (Text.Parser.Char.text "-}")
continue = do
blockCommentChunk
blockCommentContinue
lineComment :: Parser ()
lineComment = do
_ <- Text.Parser.Char.text "--"
Text.Parser.Combinators.skipMany notEndOfLine
endOfLine
return ()
where
endOfLine =
void (Text.Parser.Char.char '\n' )
<|> void (Text.Parser.Char.text "\r\n")
notEndOfLine = void (Text.Parser.Char.satisfy predicate)
where
predicate c = ('\x20' <= c && c <= '\x10FFFF') || c == '\t'
whitespaceChunk :: Parser ()
whitespaceChunk =
choice
[ void (Text.Parser.Char.satisfy predicate)
, void (Text.Parser.Char.text "\r\n")
, lineComment
, blockComment
] <?> "whitespace"
where
predicate c = c == ' ' || c == '\t' || c == '\n'
whitespace :: Parser ()
whitespace = Text.Parser.Combinators.skipMany whitespaceChunk
alpha :: Char -> Bool
alpha c = ('\x41' <= c && c <= '\x5A') || ('\x61' <= c && c <= '\x7A')
digit :: Char -> Bool
digit c = '\x30' <= c && c <= '\x39'
hexdig :: Char -> Bool
hexdig c =
('0' <= c && c <= '9')
|| ('A' <= c && c <= 'F')
|| ('a' <= c && c <= 'f')
hexNumber :: Parser Int
hexNumber = choice [ hexDigit, hexUpper, hexLower ]
where
hexDigit = do
c <- Text.Parser.Char.satisfy predicate
return (Data.Char.ord c Data.Char.ord '0')
where
predicate c = '0' <= c && c <= '9'
hexUpper = do
c <- Text.Parser.Char.satisfy predicate
return (10 + Data.Char.ord c Data.Char.ord 'A')
where
predicate c = 'A' <= c && c <= 'F'
hexLower = do
c <- Text.Parser.Char.satisfy predicate
return (10 + Data.Char.ord c Data.Char.ord 'a')
where
predicate c = 'a' <= c && c <= 'f'
simpleLabel :: Parser Text
simpleLabel = try (do
c <- Text.Parser.Char.satisfy headCharacter
cs <- many (Text.Parser.Char.satisfy tailCharacter)
let string = c:cs
let text = Data.Text.Lazy.pack string
Control.Monad.guard (not (Data.HashSet.member text reservedIdentifiers))
return text )
where
headCharacter c = alpha c || c == '_'
tailCharacter c = alpha c || digit c || c == '_' || c == '-' || c == '/'
backtickLabel :: Parser Text
backtickLabel = do
_ <- Text.Parser.Char.char '`'
t <- some (Text.Parser.Char.satisfy predicate)
_ <- Text.Parser.Char.char '`'
return (Data.Text.Lazy.pack t)
where
predicate c = alpha c || digit c || elem c ("-/_:." :: String)
label :: Parser Text
label = (do
t <- backtickLabel <|> simpleLabel
whitespace
return t ) <?> "label"
doubleQuotedChunk :: Parser a -> Parser (Chunks Src a)
doubleQuotedChunk embedded =
choice
[ interpolation
, unescapedCharacter
, escapedCharacter
]
where
interpolation = do
_ <- Text.Parser.Char.text "${"
e <- expression embedded
_ <- Text.Parser.Char.char '}'
return (Chunks [(mempty, e)] mempty)
unescapedCharacter = do
c <- Text.Parser.Char.satisfy predicate
return (Chunks [] (Data.Text.Lazy.Builder.singleton c))
where
predicate c =
('\x20' <= c && c <= '\x21' )
|| ('\x23' <= c && c <= '\x5B' )
|| ('\x5D' <= c && c <= '\x10FFFF')
escapedCharacter = do
_ <- Text.Parser.Char.char '\\'
c <- choice
[ quotationMark
, dollarSign
, backSlash
, forwardSlash
, backSpace
, formFeed
, lineFeed
, carriageReturn
, tab
, unicode
]
return (Chunks [] (Data.Text.Lazy.Builder.singleton c))
where
quotationMark = Text.Parser.Char.char '"'
dollarSign = Text.Parser.Char.char '$'
backSlash = Text.Parser.Char.char '\\'
forwardSlash = Text.Parser.Char.char '/'
backSpace = do _ <- Text.Parser.Char.char 'b'; return '\b'
formFeed = do _ <- Text.Parser.Char.char 'f'; return '\f'
lineFeed = do _ <- Text.Parser.Char.char 'n'; return '\n'
carriageReturn = do _ <- Text.Parser.Char.char 'r'; return '\r'
tab = do _ <- Text.Parser.Char.char 't'; return '\t'
unicode = do
_ <- Text.Parser.Char.char 'u';
n0 <- hexNumber
n1 <- hexNumber
n2 <- hexNumber
n3 <- hexNumber
let n = ((n0 * 16 + n1) * 16 + n2) * 16 + n3
return (Data.Char.chr n)
doubleQuotedLiteral :: Parser a -> Parser (Chunks Src a)
doubleQuotedLiteral embedded = do
_ <- Text.Parser.Char.char '"'
chunks <- many (doubleQuotedChunk embedded)
_ <- Text.Parser.Char.char '"'
return (mconcat chunks)
buildChunks :: Chunks s a -> Builder
buildChunks (Chunks a b) = foldMap buildChunk a <> escapeText b
where
buildChunk (c, _) = escapeText c <> "${x}"
dedent :: Chunks Src a -> Chunks Src a
dedent chunks0 = process chunks0
where
builder0 = buildChunks chunks0
text0 = Data.Text.Lazy.Builder.toLazyText builder0
lines0 = Data.Text.Lazy.lines text0
isEmpty = Data.Text.Lazy.all Data.Char.isSpace
nonEmptyLines = filter (not . isEmpty) lines0
indentLength line =
Data.Text.Lazy.length (Data.Text.Lazy.takeWhile Data.Char.isSpace line)
shortestIndent = case nonEmptyLines of
[] -> 0
_ -> minimum (map indentLength nonEmptyLines)
trimBegin =
build
. Data.Text.Lazy.intercalate "\n"
. map (Data.Text.Lazy.drop shortestIndent)
. Data.Text.Lazy.splitOn "\n"
. Data.Text.Lazy.Builder.toLazyText
trimContinue builder = build (Data.Text.Lazy.intercalate "\n" lines_)
where
text = Data.Text.Lazy.Builder.toLazyText builder
lines_ = case Data.Text.Lazy.splitOn "\n" text of
[] -> []
l:ls -> l:map (Data.Text.Lazy.drop shortestIndent) ls
process (Chunks ((x0, y0):xys) z) =
Chunks ((trimBegin x0, y0):xys') (trimContinue z)
where
xys' = [ (trimContinue x, y) | (x, y) <- xys ]
process (Chunks [] z) =
Chunks [] (trimBegin z)
singleQuoteContinue :: Parser a -> Parser (Chunks Src a)
singleQuoteContinue embedded =
choice
[ escapeSingleQuotes
, interpolation
, escapeInterpolation
, endLiteral
, unescapedCharacter
, tab
, endOfLine
]
where
escapeSingleQuotes = do
_ <- "'''" :: Parser Builder
b <- singleQuoteContinue embedded
return ("''" <> b)
interpolation = do
_ <- Text.Parser.Char.text "${"
a <- expression embedded
_ <- Text.Parser.Char.char '}'
b <- singleQuoteContinue embedded
return (Chunks [(mempty, a)] mempty <> b)
escapeInterpolation = do
_ <- Text.Parser.Char.text "''${"
b <- singleQuoteContinue embedded
return ("${" <> b)
endLiteral = do
_ <- Text.Parser.Char.text "''"
return mempty
unescapedCharacter = do
a <- satisfy predicate
b <- singleQuoteContinue embedded
return (Chunks [] a <> b)
where
predicate c = '\x20' <= c && c <= '\x10FFFF'
endOfLine = do
a <- "\n" <|> "\r\n"
b <- singleQuoteContinue embedded
return (Chunks [] a <> b)
tab = do
_ <- Text.Parser.Char.char '\t'
b <- singleQuoteContinue embedded
return ("\t" <> b)
singleQuoteLiteral :: Parser a -> Parser (Chunks Src a)
singleQuoteLiteral embedded = do
_ <- Text.Parser.Char.text "''"
_ <- optional endOfLine
a <- singleQuoteContinue embedded
return (dedent a)
where
endOfLine =
void (Text.Parser.Char.char '\n' )
<|> void (Text.Parser.Char.text "\r\n")
textLiteral :: Parser a -> Parser (Expr Src a)
textLiteral embedded = (do
literal <- doubleQuotedLiteral embedded <|> singleQuoteLiteral embedded
whitespace
return (TextLit literal) ) <?> "text literal"
reserved :: Data.Text.Text -> Parser ()
reserved x = do _ <- Text.Parser.Char.text x; whitespace
_if :: Parser ()
_if = reserved "if"
_then :: Parser ()
_then = reserved "then"
_else :: Parser ()
_else = reserved "else"
_let :: Parser ()
_let = reserved "let"
_in :: Parser ()
_in = reserved "in"
_as :: Parser ()
_as = reserved "as"
_using :: Parser ()
_using = reserved "using"
_merge :: Parser ()
_merge = reserved "merge"
_constructors :: Parser ()
_constructors = reserved "constructors"
_NaturalFold :: Parser ()
_NaturalFold = reserved "Natural/fold"
_NaturalBuild :: Parser ()
_NaturalBuild = reserved "Natural/build"
_NaturalIsZero :: Parser ()
_NaturalIsZero = reserved "Natural/isZero"
_NaturalEven :: Parser ()
_NaturalEven = reserved "Natural/even"
_NaturalOdd :: Parser ()
_NaturalOdd = reserved "Natural/odd"
_NaturalToInteger :: Parser ()
_NaturalToInteger = reserved "Natural/toInteger"
_NaturalShow :: Parser ()
_NaturalShow = reserved "Natural/show"
_IntegerShow :: Parser ()
_IntegerShow = reserved "Integer/show"
_DoubleShow :: Parser ()
_DoubleShow = reserved "Double/show"
_ListBuild :: Parser ()
_ListBuild = reserved "List/build"
_ListFold :: Parser ()
_ListFold = reserved "List/fold"
_ListLength :: Parser ()
_ListLength = reserved "List/length"
_ListHead :: Parser ()
_ListHead = reserved "List/head"
_ListLast :: Parser ()
_ListLast = reserved "List/last"
_ListIndexed :: Parser ()
_ListIndexed = reserved "List/indexed"
_ListReverse :: Parser ()
_ListReverse = reserved "List/reverse"
_OptionalFold :: Parser ()
_OptionalFold = reserved "Optional/fold"
_OptionalBuild :: Parser ()
_OptionalBuild = reserved "Optional/build"
_Bool :: Parser ()
_Bool = reserved "Bool"
_Optional :: Parser ()
_Optional = reserved "Optional"
_Natural :: Parser ()
_Natural = reserved "Natural"
_Integer :: Parser ()
_Integer = reserved "Integer"
_Double :: Parser ()
_Double = reserved "Double"
_Text :: Parser ()
_Text = reserved "Text"
_List :: Parser ()
_List = reserved "List"
_True :: Parser ()
_True = reserved "True"
_False :: Parser ()
_False = reserved "False"
_Type :: Parser ()
_Type = reserved "Type"
_Kind :: Parser ()
_Kind = reserved "Kind"
_equal :: Parser ()
_equal = reserved "="
_or :: Parser ()
_or = reserved "||"
_plus :: Parser ()
_plus = reserved "+"
_textAppend :: Parser ()
_textAppend = reserved "++"
_listAppend :: Parser ()
_listAppend = reserved "#"
_and :: Parser ()
_and = reserved "&&"
_times :: Parser ()
_times = reserved "*"
_doubleEqual :: Parser ()
_doubleEqual = reserved "=="
_notEqual :: Parser ()
_notEqual = reserved "!="
_dot :: Parser ()
_dot = reserved "."
_openBrace :: Parser ()
_openBrace = reserved "{"
_closeBrace :: Parser ()
_closeBrace = reserved "}"
_openBracket :: Parser ()
_openBracket = reserved "["
_closeBracket :: Parser ()
_closeBracket = reserved "]"
_openAngle :: Parser ()
_openAngle = reserved "<"
_closeAngle :: Parser ()
_closeAngle = reserved ">"
_bar :: Parser ()
_bar = reserved "|"
_comma :: Parser ()
_comma = reserved ","
_openParens :: Parser ()
_openParens = reserved "("
_closeParens :: Parser ()
_closeParens = reserved ")"
_colon :: Parser ()
_colon = reserved ":"
_at :: Parser ()
_at = reserved "@"
_combine :: Parser ()
_combine = do
void (Text.Parser.Char.char '∧' <?> "\"∧\"") <|> void (Text.Parser.Char.text "/\\")
whitespace
_prefer :: Parser ()
_prefer = do
void (Text.Parser.Char.char '⫽' <?> "\"⫽\"") <|> void (Text.Parser.Char.text "//")
whitespace
_lambda :: Parser ()
_lambda = do
_ <- Text.Parser.Char.satisfy predicate
whitespace
where
predicate 'λ' = True
predicate '\\' = True
predicate _ = False
_forall :: Parser ()
_forall = do
void (Text.Parser.Char.char '∀' <?> "\"∀\"") <|> void (Text.Parser.Char.text "forall")
whitespace
_arrow :: Parser ()
_arrow = do
void (Text.Parser.Char.char '→' <?> "\"→\"") <|> void (Text.Parser.Char.text "->")
whitespace
doubleLiteral :: Parser Double
doubleLiteral = (do
sign <- fmap (\_ -> negate) (Text.Parser.Char.char '-')
<|> pure id
a <- Text.Parser.Token.double
return (sign a) ) <?> "double literal"
integerLiteral :: Parser Integer
integerLiteral = Text.Parser.Token.integer <?> "integer literal"
naturalLiteral :: Parser Natural
naturalLiteral = (do
_ <- Text.Parser.Char.char '+'
a <- Text.Parser.Token.natural
return (fromIntegral a) ) <?> "natural literal"
identifier :: Parser Var
identifier = do
x <- label
let indexed = do
_ <- Text.Parser.Char.char '@'
Text.Parser.Token.natural
n <- indexed <|> pure 0
return (V x n)
headPathCharacter :: Char -> Bool
headPathCharacter c =
('\x21' <= c && c <= '\x27')
|| ('\x2A' <= c && c <= '\x2B')
|| ('\x2D' <= c && c <= '\x2E')
|| ('\x30' <= c && c <= '\x3B')
|| c == '\x3D'
|| ('\x3F' <= c && c <= '\x5A')
|| ('\x5E' <= c && c <= '\x7A')
|| c == '\x7C'
|| c == '\x7E'
pathCharacter :: Char -> Bool
pathCharacter c =
headPathCharacter c
|| c == '\\'
|| c == '/'
fileRaw :: Parser PathType
fileRaw =
choice
[ try absolutePath
, relativePath
, parentPath
, homePath
]
where
absolutePath = do
_ <- Text.Parser.Char.char '/'
a <- Text.Parser.Char.satisfy headPathCharacter
bs <- many (Text.Parser.Char.satisfy pathCharacter)
let string = '/':a:bs
return (File Homeless (Filesystem.Path.CurrentOS.decodeString string))
relativePath = do
_ <- Text.Parser.Char.text "./"
as <- many (Text.Parser.Char.satisfy pathCharacter)
let string = "./" <> as
return (File Homeless (Filesystem.Path.CurrentOS.decodeString string))
parentPath = do
_ <- Text.Parser.Char.text "../"
as <- many (Text.Parser.Char.satisfy pathCharacter)
let string = "../" <> as
return (File Homeless (Filesystem.Path.CurrentOS.decodeString string))
homePath = do
_ <- Text.Parser.Char.text "~/"
as <- many (Text.Parser.Char.satisfy pathCharacter)
return (File Home (Filesystem.Path.CurrentOS.decodeString as))
file :: Parser PathType
file = do
a <- fileRaw
whitespace
return a
scheme :: Parser Builder
scheme = "http" <> option "s"
httpRaw :: Parser Builder
httpRaw =
scheme
<> "://"
<> authority
<> pathAbempty
<> option ("?" <> query)
<> option ("#" <> fragment)
authority :: Parser Builder
authority = option (try (userinfo <> "@")) <> host <> option (":" <> port)
userinfo :: Parser Builder
userinfo = star (satisfy predicate <|> pctEncoded)
where
predicate c = unreserved c || subDelims c || c == ':'
host :: Parser Builder
host = choice [ ipLiteral, ipV4Address, regName ]
port :: Parser Builder
port = star (satisfy digit)
ipLiteral :: Parser Builder
ipLiteral = "[" <> (ipV6Address <|> ipVFuture) <> "]"
ipVFuture :: Parser Builder
ipVFuture = "v" <> plus (satisfy hexdig) <> "." <> plus (satisfy predicate)
where
predicate c = unreserved c || subDelims c || c == ':'
ipV6Address :: Parser Builder
ipV6Address =
choice
[ try alternative0
, try alternative1
, try alternative2
, try alternative3
, try alternative4
, try alternative5
, try alternative6
, try alternative7
, alternative8
]
where
alternative0 = count 6 (h16 <> ":") <> ls32
alternative1 = "::" <> count 5 (h16 <> ":") <> ls32
alternative2 = option h16 <> "::" <> count 4 (h16 <> ":") <> ls32
alternative3 =
option (range 0 1 (h16 <> ":") <> h16)
<> "::"
<> count 3 (h16 <> ":")
<> ls32
alternative4 =
option (range 0 2 (h16 <> ":") <> h16)
<> "::"
<> count 2 (h16 <> ":")
<> ls32
alternative5 =
option (range 0 3 (h16 <> ":") <> h16) <> "::" <> h16 <> ":" <> ls32
alternative6 =
option (range 0 4 (h16 <> ":") <> h16) <> "::" <> ls32
alternative7 =
option (range 0 5 (h16 <> ":") <> h16) <> "::" <> h16
alternative8 =
option (range 0 6 (h16 <> ":") <> h16) <> "::"
h16 :: Parser Builder
h16 = range 1 3 (satisfy hexdig)
ls32 :: Parser Builder
ls32 = (h16 <> ":" <> h16) <|> ipV4Address
ipV4Address :: Parser Builder
ipV4Address = decOctet <> "." <> decOctet <> "." <> decOctet <> "." <> decOctet
decOctet :: Parser Builder
decOctet =
choice
[ try alternative4
, try alternative3
, try alternative2
, try alternative1
, alternative0
]
where
alternative0 = satisfy digit
alternative1 = satisfy predicate <> satisfy digit
where
predicate c = '\x31' <= c && c <= '\x39'
alternative2 = "1" <> count 2 (satisfy digit)
alternative3 = "2" <> satisfy predicate <> satisfy digit
where
predicate c = '\x30' <= c && c <= '\x34'
alternative4 = "25" <> satisfy predicate
where
predicate c = '\x30' <= c && c <= '\x35'
regName :: Parser Builder
regName = star (satisfy predicate <|> pctEncoded)
where
predicate c = unreserved c || subDelims c
pathAbempty :: Parser Builder
pathAbempty = star ("/" <> segment)
segment :: Parser Builder
segment = star pchar
pchar :: Parser Builder
pchar = satisfy predicate <|> pctEncoded
where
predicate c = unreserved c || subDelims c || c == ':' || c == '@'
query :: Parser Builder
query = star (pchar <|> satisfy predicate)
where
predicate c = c == '/' || c == '?'
fragment :: Parser Builder
fragment = star (pchar <|> satisfy predicate)
where
predicate c = c == '/' || c == '?'
pctEncoded :: Parser Builder
pctEncoded = "%" <> count 2 (satisfy hexdig)
unreserved :: Char -> Bool
unreserved c =
alpha c || digit c || c == '-' || c == '.' || c == '_' || c == '~'
subDelims :: Char -> Bool
subDelims c = c `elem` ("!$&'()*+,;=" :: String)
http :: Parser PathType
http = do
a <- httpRaw
whitespace
b <- optional (do
_using
pathHashed_ )
return (URL (Data.Text.Lazy.Builder.toLazyText a) b)
env :: Parser PathType
env = do
_ <- Text.Parser.Char.text "env:"
a <- (alternative0 <|> alternative1)
whitespace
return (Env a)
where
alternative0 = do
a <- bashEnvironmentVariable
return (Data.Text.Lazy.Builder.toLazyText a)
alternative1 = do
_ <- Text.Parser.Char.char '"'
a <- posixEnvironmentVariable
_ <- Text.Parser.Char.char '"'
return (Data.Text.Lazy.Builder.toLazyText a)
bashEnvironmentVariable :: Parser Builder
bashEnvironmentVariable = satisfy predicate0 <> star (satisfy predicate1)
where
predicate0 c = alpha c || c == '_'
predicate1 c = alpha c || digit c || c == '_'
posixEnvironmentVariable :: Parser Builder
posixEnvironmentVariable = plus posixEnvironmentVariableCharacter
posixEnvironmentVariableCharacter :: Parser Builder
posixEnvironmentVariableCharacter =
("\\" <> satisfy predicate0) <|> satisfy predicate1
where
predicate0 c = c `elem` ("\"\\abfnrtv" :: String)
predicate1 c =
('\x20' <= c && c <= '\x21')
|| ('\x23' <= c && c <= '\x3C')
|| ('\x3E' <= c && c <= '\x5B')
|| ('\x5D' <= c && c <= '\x7E')
expression :: Parser a -> Parser (Expr Src a)
expression embedded =
( noted
( choice
[ alternative0
, alternative1
, alternative2
, alternative3
, alternative4
]
)
<|> alternative5
) <?> "expression"
where
alternative0 = do
_lambda
_openParens
a <- label
_colon
b <- expression embedded
_closeParens
_arrow
c <- expression embedded
return (Lam a b c)
alternative1 = do
_if
a <- expression embedded
_then
b <- expression embedded
_else
c <- expression embedded
return (BoolIf a b c)
alternative2 = do
_let
a <- label
b <- optional (do
_colon
expression embedded )
_equal
c <- expression embedded
_in
d <- expression embedded
return (Let a b c d)
alternative3 = do
_forall
_openParens
a <- label
_colon
b <- expression embedded
_closeParens
_arrow
c <- expression embedded
return (Pi a b c)
alternative4 = do
a <- try (do a <- operatorExpression embedded; _arrow; return a)
b <- expression embedded
return (Pi "_" a b)
alternative5 = annotatedExpression embedded
annotatedExpression :: Parser a -> Parser (Expr Src a)
annotatedExpression embedded =
noted
( choice
[ alternative0
, try alternative1
, alternative2
]
)
where
alternative0 = do
_merge
a <- selectorExpression embedded
b <- selectorExpression embedded
c <- optional (do
_colon
applicationExpression embedded )
return (Merge a b c)
alternative1 = (do
_openBracket
(emptyCollection embedded <|> nonEmptyOptional embedded) )
<?> "list literal"
alternative2 = do
a <- operatorExpression embedded
b <- optional (do _colon; expression embedded)
case b of
Nothing -> return a
Just c -> return (Annot a c)
emptyCollection :: Parser a -> Parser (Expr Src a)
emptyCollection embedded = do
_closeBracket
_colon
a <- alternative0 <|> alternative1
b <- selectorExpression embedded
return (a b empty)
where
alternative0 = do
_List
return (\a b -> ListLit (Just a) b)
alternative1 = do
_Optional
return OptionalLit
nonEmptyOptional :: Parser a -> Parser (Expr Src a)
nonEmptyOptional embedded = do
a <- expression embedded
_closeBracket
_colon
_Optional
b <- selectorExpression embedded
return (OptionalLit b (pure a))
operatorExpression :: Parser a -> Parser (Expr Src a)
operatorExpression = orExpression
makeOperatorExpression
:: (Parser a -> Parser (Expr Src a))
-> Parser ()
-> (Expr Src a -> Expr Src a -> Expr Src a)
-> Parser a
-> Parser (Expr Src a)
makeOperatorExpression subExpression operatorParser operator embedded =
noted (do
a <- subExpression embedded
b <- many (do operatorParser; subExpression embedded)
return (foldr1 operator (a:b)) )
orExpression :: Parser a -> Parser (Expr Src a)
orExpression =
makeOperatorExpression plusExpression _or BoolOr
plusExpression :: Parser a -> Parser (Expr Src a)
plusExpression =
makeOperatorExpression textAppendExpression _plus NaturalPlus
textAppendExpression :: Parser a -> Parser (Expr Src a)
textAppendExpression =
makeOperatorExpression listAppendExpression _textAppend TextAppend
listAppendExpression :: Parser a -> Parser (Expr Src a)
listAppendExpression =
makeOperatorExpression andExpression _listAppend ListAppend
andExpression :: Parser a -> Parser (Expr Src a)
andExpression =
makeOperatorExpression combineExpression _and BoolAnd
combineExpression :: Parser a -> Parser (Expr Src a)
combineExpression =
makeOperatorExpression preferExpression _combine Combine
preferExpression :: Parser a -> Parser (Expr Src a)
preferExpression =
makeOperatorExpression timesExpression _prefer Prefer
timesExpression :: Parser a -> Parser (Expr Src a)
timesExpression =
makeOperatorExpression equalExpression _times NaturalTimes
equalExpression :: Parser a -> Parser (Expr Src a)
equalExpression =
makeOperatorExpression notEqualExpression _doubleEqual BoolEQ
notEqualExpression :: Parser a -> Parser (Expr Src a)
notEqualExpression =
makeOperatorExpression applicationExpression _notEqual BoolNE
applicationExpression :: Parser a -> Parser (Expr Src a)
applicationExpression embedded = do
f <- (do _constructors; return Constructors) <|> return id
a <- noted (selectorExpression embedded)
b <- many (noted (selectorExpression embedded))
return (foldl app (f a) b)
where
app nL@(Note (Src before _ bytesL) _) nR@(Note (Src _ after bytesR) _) =
Note (Src before after (bytesL <> bytesR)) (App nL nR)
app nL nR =
App nL nR
selectorExpression :: Parser a -> Parser (Expr Src a)
selectorExpression embedded = noted (do
a <- primitiveExpression embedded
b <- many (try (do _dot; label))
return (foldl Field a b) )
primitiveExpression :: Parser a -> Parser (Expr Src a)
primitiveExpression embedded =
noted
( choice
[ alternative00
, alternative01
, alternative02
, alternative03
, alternative04
, alternative05
, alternative06
, alternative07
, choice
[ alternative08
, alternative09
, alternative10
, alternative11
, alternative12
, alternative13
, alternative14
, alternative15
, alternative16
, alternative17
, alternative18
, alternative19
, alternative20
, alternative21
, alternative22
, alternative23
, alternative24
, alternative25
, alternative26
, alternative27
, alternative28
, alternative29
, alternative30
, alternative31
, alternative32
, alternative33
, alternative34
, alternative35
, alternative36
] <?> "built-in expression"
, alternative37
]
)
<|> alternative38
where
alternative00 = do
a <- try doubleLiteral
return (DoubleLit a)
alternative01 = do
a <- try naturalLiteral
return (NaturalLit a)
alternative02 = do
a <- try integerLiteral
return (IntegerLit a)
alternative03 = textLiteral embedded
alternative04 = (do
_openBrace
a <- recordTypeOrLiteral embedded
_closeBrace
return a ) <?> "record type or literal"
alternative05 = (do
_openAngle
a <- unionTypeOrLiteral embedded
_closeAngle
return a ) <?> "union type or literal"
alternative06 = nonEmptyListLiteral embedded
alternative07 = do
a <- embedded
return (Embed a)
alternative08 = do
_NaturalFold
return NaturalFold
alternative09 = do
_NaturalBuild
return NaturalBuild
alternative10 = do
_NaturalIsZero
return NaturalIsZero
alternative11 = do
_NaturalEven
return NaturalEven
alternative12 = do
_NaturalOdd
return NaturalOdd
alternative13 = do
_NaturalToInteger
return NaturalToInteger
alternative14 = do
_NaturalShow
return NaturalShow
alternative15 = do
_IntegerShow
return IntegerShow
alternative16 = do
_DoubleShow
return DoubleShow
alternative17 = do
_ListBuild
return ListBuild
alternative18 = do
_ListFold
return ListFold
alternative19 = do
_ListLength
return ListLength
alternative20 = do
_ListHead
return ListHead
alternative21 = do
_ListLast
return ListLast
alternative22 = do
_ListIndexed
return ListIndexed
alternative23 = do
_ListReverse
return ListReverse
alternative24 = do
_OptionalFold
return OptionalFold
alternative25 = do
_OptionalBuild
return OptionalBuild
alternative26 = do
_Bool
return Bool
alternative27 = do
_Optional
return Optional
alternative28 = do
_Natural
return Natural
alternative29 = do
_Integer
return Integer
alternative30 = do
_Double
return Double
alternative31 = do
_Text
return Text
alternative32 = do
_List
return List
alternative33 = do
_True
return (BoolLit True)
alternative34 = do
_False
return (BoolLit False)
alternative35 = do
_Type
return (Const Type)
alternative36 = do
_Kind
return (Const Kind)
alternative37 = do
a <- identifier
return (Var a)
alternative38 = do
_openParens
a <- expression embedded
_closeParens
return a
recordTypeOrLiteral :: Parser a -> Parser (Expr Src a)
recordTypeOrLiteral embedded =
choice
[ alternative0
, alternative1
, alternative2
]
where
alternative0 = do
_equal
return (RecordLit Data.Map.empty)
alternative1 = nonEmptyRecordTypeOrLiteral embedded
alternative2 = return (Record Data.Map.empty)
nonEmptyRecordTypeOrLiteral :: Parser a -> Parser (Expr Src a)
nonEmptyRecordTypeOrLiteral embedded = do
a <- label
let nonEmptyRecordType = do
_colon
b <- expression embedded
e <- many (do
_comma
c <- label
_colon
d <- expression embedded
return (c, d) )
return (Record (Data.Map.fromList ((a, b):e)))
let nonEmptyRecordLiteral = do
_equal
b <- expression embedded
e <- many (do
_comma
c <- label
_equal
d <- expression embedded
return (c, d) )
return (RecordLit (Data.Map.fromList ((a, b):e)))
nonEmptyRecordType <|> nonEmptyRecordLiteral
unionTypeOrLiteral :: Parser a -> Parser (Expr Src a)
unionTypeOrLiteral embedded =
nonEmptyUnionTypeOrLiteral embedded <|> return (Union Data.Map.empty)
nonEmptyUnionTypeOrLiteral :: Parser a -> Parser (Expr Src a)
nonEmptyUnionTypeOrLiteral embedded = do
(f, kvs) <- loop
m <- toMap kvs
return (f m)
where
loop = do
a <- label
let alternative0 = do
_equal
b <- expression embedded
kvs <- many (do
_bar
c <- label
_colon
d <- expression embedded
return (c, d) )
return (UnionLit a b, kvs)
let alternative1 = do
_colon
b <- expression embedded
let alternative2 = do
_bar
(f, kvs) <- loop
return (f, (a, b):kvs)
let alternative3 = return (Union, [(a, b)])
alternative2 <|> alternative3
alternative0 <|> alternative1
nonEmptyListLiteral :: Parser a -> Parser (Expr Src a)
nonEmptyListLiteral embedded = (do
_openBracket
a <- expression embedded
b <- many (do _comma; expression embedded)
_closeBracket
return (ListLit Nothing (Data.Vector.fromList (a:b))) ) <?> "list literal"
completeExpression :: Parser a -> Parser (Expr Src a)
completeExpression embedded = do
whitespace
expression embedded
toMap :: [(Text, a)] -> Parser (Map Text a)
toMap kvs = do
let adapt (k, v) = (k, pure v)
let m = Data.Map.fromListWith (<|>) (fmap adapt kvs)
let action k vs = case Data.Sequence.viewl vs of
EmptyL -> empty
v :< vs' ->
if null vs'
then pure v
else
Text.Parser.Combinators.unexpected
("duplicate field: " ++ Data.Text.Lazy.unpack k)
Data.Map.traverseWithKey action m
expr :: Parser (Expr Src Path)
expr = exprA import_
exprA :: Parser a -> Parser (Expr Src a)
exprA = completeExpression
pathType_ :: Parser PathType
pathType_ = choice [ file, http, env ]
pathHashed_ :: Parser PathHashed
pathHashed_ = do
pathType <- pathType_
hash <- optional pathHash_
return (PathHashed {..})
where
pathHash_ = do
_ <- Text.Parser.Char.text "sha256:"
builder <- count 64 (satisfy hexdig <?> "hex digit")
whitespace
let lazyText = Data.Text.Lazy.Builder.toLazyText builder
let lazyBytes = Data.Text.Lazy.Encoding.encodeUtf8 lazyText
let (hash, suffix) = Data.ByteString.Base16.Lazy.decode lazyBytes
if Data.ByteString.Lazy.null suffix
then return (Data.ByteString.Lazy.toStrict hash)
else fail "Invalid sha256 hash"
import_ :: Parser Path
import_ = (do
pathHashed <- pathHashed_
pathMode <- alternative <|> pure Code
return (Path {..}) ) <?> "import"
where
alternative = do
_as
_Text
return RawText
newtype ParseError = ParseError Doc deriving (Typeable)
instance Show ParseError where
show (ParseError doc) =
"\n\ESC[1;31mError\ESC[0m: Invalid input\n\n" <> show doc
instance Exception ParseError
exprFromText :: Delta -> Text -> Either ParseError (Expr Src Path)
exprFromText delta text = fmap snd (exprAndHeaderFromText delta text)
exprAndHeaderFromText
:: Delta
-> Text
-> Either ParseError (Text, Expr Src Path)
exprAndHeaderFromText delta text = case result of
Failure errInfo -> Left (ParseError (Text.Trifecta._errDoc errInfo))
Success (bytes, r) -> case Data.Text.Encoding.decodeUtf8' bytes of
Left errInfo -> Left (ParseError (fromString (show errInfo)))
Right txt -> do
let stripped = Data.Text.dropWhileEnd (/= '\n') txt
let lazyText = Data.Text.Lazy.fromStrict stripped
Right (lazyText, r)
where
string = Data.Text.Lazy.unpack text
parser = unParser (do
bytes <- Text.Trifecta.slicedWith (\_ x -> x) whitespace
r <- expr
Text.Parser.Combinators.eof
return (bytes, r) )
result = Text.Trifecta.parseString parser delta string