{-# LANGUAGE OverloadedStrings, TypeSynonymInstances, FlexibleInstances, CPP #-}
{-# LANGUAGE LambdaCase #-}
{-# OPTIONS_GHC -Wall -fno-warn-orphans -fno-warn-unused-do-bind #-}
module Sound.Tidal.ParseBP where
import Control.Applicative ((<$>), (<*>), pure)
import qualified Control.Exception as E
import Data.Colour
import Data.Colour.Names
import Data.Functor.Identity (Identity)
import Data.Maybe
import Data.Ratio
import Data.Typeable (Typeable)
import GHC.Exts ( IsString(..) )
import Text.Parsec.Error
import Text.ParserCombinators.Parsec
import Text.ParserCombinators.Parsec.Language ( haskellDef )
import qualified Text.ParserCombinators.Parsec.Token as P
import qualified Text.Parsec.Prim
import Sound.Tidal.Pattern
import Sound.Tidal.UI
import Sound.Tidal.Core
import Sound.Tidal.Chords (chordTable)
data TidalParseError = TidalParseError {parsecError :: ParseError,
code :: String
}
deriving (Eq, Typeable)
instance E.Exception TidalParseError
instance Show TidalParseError where
show err = "Syntax error in sequence:\n \"" ++ code err ++ "\"\n " ++ pointer ++ " " ++ message
where pointer = replicate (sourceColumn $ errorPos perr) ' ' ++ "^"
message = showErrorMessages "or" "unknown parse error" "expecting" "unexpected" "end of input" $ errorMessages perr
perr = parsecError err
type MyParser = Text.Parsec.Prim.Parsec String Int
data TPat a = TPat_Atom (Maybe ((Int, Int), (Int, Int))) a
| TPat_Fast (TPat Time) (TPat a)
| TPat_Slow (TPat Time) (TPat a)
| TPat_DegradeBy Int Double (TPat a)
| TPat_CycleChoose Int [TPat a]
| TPat_Euclid (TPat Int) (TPat Int) (TPat Int) (TPat a)
| TPat_Stack [TPat a]
| TPat_Polyrhythm (Maybe (TPat Rational)) [TPat a]
| TPat_Seq [TPat a]
| TPat_Silence
| TPat_Foot
| TPat_Elongate Rational (TPat a)
| TPat_Repeat Int (TPat a)
| TPat_EnumFromTo (TPat a) (TPat a)
deriving (Show)
toPat :: (Parseable a, Enumerable a) => TPat a -> Pattern a
toPat = \case
TPat_Atom (Just loc) x -> setContext (Context [loc]) $ pure x
TPat_Atom Nothing x -> pure x
TPat_Fast t x -> fast (toPat t) $ toPat x
TPat_Slow t x -> slow (toPat t) $ toPat x
TPat_DegradeBy seed amt x -> _degradeByUsing (rotL (0.0001 * (fromIntegral seed)) rand) amt $ toPat x
TPat_CycleChoose seed xs -> unwrap $ segment 1 $ chooseBy (rotL (0.0001 * (fromIntegral seed)) rand) $ map toPat xs
TPat_Euclid n k s thing ->
doEuclid (toPat n) (toPat k) (toPat s) (toPat thing)
TPat_Stack xs -> stack $ map toPat xs
TPat_Silence -> silence
TPat_EnumFromTo a b -> unwrap $ fromTo <$> toPat a <*> toPat b
TPat_Foot -> error "Can't happen, feet are pre-processed."
TPat_Polyrhythm mSteprate ps -> stack $ map adjust_speed pats
where adjust_speed (sz, pat) = fast ((/sz) <$> steprate) pat
pats = map resolve_tpat ps
steprate :: Pattern Rational
steprate = fromMaybe base_first (toPat <$> mSteprate)
base_first | null pats = pure 0
| otherwise = pure $ fst $ head pats
TPat_Seq xs -> snd $ resolve_seq xs
_ -> silence
resolve_tpat :: (Enumerable a, Parseable a) => TPat a -> (Rational, Pattern a)
resolve_tpat (TPat_Seq xs) = resolve_seq xs
resolve_tpat a = (1, toPat a)
resolve_seq :: (Enumerable a, Parseable a) => [TPat a] -> (Rational, Pattern a)
resolve_seq xs = (total_size, timeCat sized_pats)
where sized_pats = map (toPat <$>) $ resolve_size xs
total_size = sum $ map fst sized_pats
resolve_size :: [TPat a] -> [(Rational, TPat a)]
resolve_size [] = []
resolve_size ((TPat_Elongate r p):ps) = (r, p):(resolve_size ps)
resolve_size ((TPat_Repeat n p):ps) = replicate n (1,p) ++ (resolve_size ps)
resolve_size (p:ps) = (1,p):(resolve_size ps)
parseBP :: (Enumerable a, Parseable a) => String -> Either ParseError (Pattern a)
parseBP s = toPat <$> parseTPat s
parseBP_E :: (Enumerable a, Parseable a) => String -> Pattern a
parseBP_E s = toE parsed
where
parsed = parseTPat s
toE (Left e) = E.throw $ TidalParseError {parsecError = e, code = s}
toE (Right tp) = toPat tp
parseTPat :: Parseable a => String -> Either ParseError (TPat a)
parseTPat = parseRhythm tPatParser
class Parseable a where
tPatParser :: MyParser (TPat a)
doEuclid :: Pattern Int -> Pattern Int -> Pattern Int -> Pattern a -> Pattern a
class Enumerable a where
fromTo :: a -> a -> Pattern a
fromThenTo :: a -> a -> a -> Pattern a
instance Parseable Double where
tPatParser = pDouble
doEuclid = euclidOff
instance Enumerable Double where
fromTo = enumFromTo'
fromThenTo = enumFromThenTo'
instance Parseable String where
tPatParser = pVocable
doEuclid = euclidOff
instance Enumerable String where
fromTo a b = fastFromList [a,b]
fromThenTo a b c = fastFromList [a,b,c]
instance Parseable Bool where
tPatParser = pBool
doEuclid = euclidOffBool
instance Enumerable Bool where
fromTo a b = fastFromList [a,b]
fromThenTo a b c = fastFromList [a,b,c]
instance Parseable Int where
tPatParser = pIntegral
doEuclid = euclidOff
instance Enumerable Int where
fromTo = enumFromTo'
fromThenTo = enumFromThenTo'
instance Parseable Integer where
tPatParser = pIntegral
doEuclid = euclidOff
instance Enumerable Integer where
fromTo = enumFromTo'
fromThenTo = enumFromThenTo'
instance Parseable Rational where
tPatParser = pRational
doEuclid = euclidOff
instance Enumerable Rational where
fromTo = enumFromTo'
fromThenTo = enumFromThenTo'
enumFromTo' :: (Ord a, Enum a) => a -> a -> Pattern a
enumFromTo' a b | a > b = fastFromList $ reverse $ enumFromTo b a
| otherwise = fastFromList $ enumFromTo a b
enumFromThenTo'
:: (Ord a, Enum a, Num a) => a -> a -> a -> Pattern a
enumFromThenTo' a b c | a > c = fastFromList $ reverse $ enumFromThenTo c (c + (a-b)) a
| otherwise = fastFromList $ enumFromThenTo a b c
type ColourD = Colour Double
instance Parseable ColourD where
tPatParser = pColour
doEuclid = euclidOff
instance Enumerable ColourD where
fromTo a b = fastFromList [a,b]
fromThenTo a b c = fastFromList [a,b,c]
instance (Enumerable a, Parseable a) => IsString (Pattern a) where
fromString = parseBP_E
lexer :: P.GenTokenParser String u Data.Functor.Identity.Identity
lexer = P.makeTokenParser haskellDef
braces, brackets, parens, angles:: MyParser a -> MyParser a
braces = P.braces lexer
brackets = P.brackets lexer
parens = P.parens lexer
angles = P.angles lexer
symbol :: String -> MyParser String
symbol = P.symbol lexer
natural, integer, decimal :: MyParser Integer
natural = P.natural lexer
integer = P.integer lexer
decimal = P.integer lexer
float :: MyParser Double
float = P.float lexer
naturalOrFloat :: MyParser (Either Integer Double)
naturalOrFloat = P.naturalOrFloat lexer
data Sign = Positive | Negative
applySign :: Num a => Sign -> a -> a
applySign Positive = id
applySign Negative = negate
sign :: MyParser Sign
sign = do char '-'
return Negative
<|> do char '+'
return Positive
<|> return Positive
intOrFloat :: MyParser Double
intOrFloat = do s <- sign
num <- naturalOrFloat
return (case num of
Right x -> applySign s x
Left x -> fromIntegral $ applySign s x
)
parseRhythm :: Parseable a => MyParser (TPat a) -> String -> Either ParseError (TPat a)
parseRhythm f = runParser (pSequence f') (0 :: Int) ""
where f' = do f
<|> do symbol "~" <?> "rest"
return TPat_Silence
pSequence :: Parseable a => MyParser (TPat a) -> GenParser Char Int (TPat a)
pSequence f = do spaces
s <- many $ do a <- pPart f
spaces
do try $ symbol ".."
b <- pPart f
return $ TPat_EnumFromTo a b
<|> do rs <- many1 $ do oneOf "@_"
r <- ((subtract 1) <$> pRatio) <|> return 1
spaces
return $ r
return $ TPat_Elongate (1 + sum rs) a
<|> do es <- many1 $ do char '!'
n <- (((subtract 1) . read) <$> many1 digit) <|> return 1
spaces
return n
return $ TPat_Repeat (1 + sum es) a
<|> return a
<|> do symbol "."
return TPat_Foot
return $ resolve_feet s
where resolve_feet ps | length ss > 1 = TPat_Seq $ map TPat_Seq ss
| otherwise = TPat_Seq ps
where ss = splitFeet ps
splitFeet :: [TPat t] -> [[TPat t]]
splitFeet [] = []
splitFeet pats = foot : splitFeet pats'
where (foot, pats') = takeFoot pats
takeFoot [] = ([], [])
takeFoot (TPat_Foot:pats'') = ([], pats'')
takeFoot (pat:pats'') = (\(a,b) -> (pat:a,b)) $ takeFoot pats''
pSingle :: MyParser (TPat a) -> MyParser (TPat a)
pSingle f = f >>= pRand >>= pMult
pPart :: Parseable a => MyParser (TPat a) -> MyParser (TPat a)
pPart f = do pt <- (pSingle f <|> pPolyIn f <|> pPolyOut f) >>= pE >>= pRand
spaces
return pt
newSeed :: MyParser Int
newSeed = do seed <- Text.Parsec.Prim.getState
Text.Parsec.Prim.modifyState (+1)
return seed
pPolyIn :: Parseable a => MyParser (TPat a) -> MyParser (TPat a)
pPolyIn f = do x <- brackets $ do s <- pSequence f <?> "sequence"
stackTail s <|> chooseTail s <|> return s
pMult x
where stackTail s = do symbol ","
ss <- pSequence f `sepBy` symbol ","
spaces
return $ TPat_Stack (s:ss)
chooseTail s = do symbol "|"
ss <- pSequence f `sepBy` symbol "|"
spaces
seed <- newSeed
return $ TPat_CycleChoose seed (s:ss)
pPolyOut :: Parseable a => MyParser (TPat a) -> MyParser (TPat a)
pPolyOut f = do ss <- braces (pSequence f `sepBy` symbol ",")
spaces
base <- do char '%'
r <- pSequence pRational <?> "rational number"
return $ Just r
<|> return Nothing
pMult $ TPat_Polyrhythm base ss
<|>
do ss <- angles (pSequence f `sepBy` symbol ",")
spaces
pMult $ TPat_Polyrhythm (Just $ TPat_Atom Nothing 1) ss
pString :: MyParser String
pString = do c <- (letter <|> oneOf "0123456789") <?> "charnum"
cs <- many (letter <|> oneOf "0123456789:.-_") <?> "string"
return (c:cs)
wrapPos :: MyParser (TPat a) -> MyParser (TPat a)
wrapPos p = do b <- getPosition
tpat <- p
e <- getPosition
let addPos (TPat_Atom _ v') =
TPat_Atom (Just ((sourceColumn b, sourceLine b), (sourceColumn e, sourceLine e))) v'
addPos x = x
return $ addPos tpat
pVocable :: MyParser (TPat String)
pVocable = wrapPos $ (TPat_Atom Nothing) <$> pString
pDouble :: MyParser (TPat Double)
pDouble = wrapPos $ do f <- choice [intOrFloat, parseNote] <?> "float"
do c <- parseChord
return $ TPat_Stack $ map ((TPat_Atom Nothing) . (+f)) c
<|> return (TPat_Atom Nothing f)
<|>
do c <- parseChord
return $ TPat_Stack $ map (TPat_Atom Nothing) c
pBool :: MyParser (TPat Bool)
pBool = wrapPos $ do oneOf "t1"
return $ TPat_Atom Nothing True
<|>
do oneOf "f0"
return $ TPat_Atom Nothing False
parseIntNote :: Integral i => MyParser i
parseIntNote = do s <- sign
i <- choice [integer, parseNote]
return $ applySign s $ fromIntegral i
parseInt :: MyParser Int
parseInt = do s <- sign
i <- integer
return $ applySign s $ fromIntegral i
pIntegral :: Integral a => MyParser (TPat a)
pIntegral = wrapPos $ do i <- parseIntNote
do c <- parseChord
return $ TPat_Stack $ map ((TPat_Atom Nothing) . (+i)) c
<|> return (TPat_Atom Nothing i)
<|>
do c <- parseChord
return $ TPat_Stack $ map (TPat_Atom Nothing) c
parseChord :: (Enum a, Num a) => MyParser [a]
parseChord = do char '\''
name <- many1 $ letter <|> digit
let chord = fromMaybe [0] $ lookup name chordTable
do char '\''
notFollowedBy space <?> "chord range or 'i'"
let n = length chord
i <- option n (fromIntegral <$> integer)
j <- length <$> many (char 'i')
let chord' = take i $ drop j $ concatMap (\x -> map (+ x) chord) [0,12..]
return chord'
<|> return chord
parseNote :: Num a => MyParser a
parseNote = do n <- notenum
modifiers <- many noteModifier
octave <- option 5 natural
let n' = foldr (+) n modifiers
return $ fromIntegral $ n' + ((octave-5)*12)
where
notenum :: MyParser Integer
notenum = choice [char 'c' >> return 0,
char 'd' >> return 2,
char 'e' >> return 4,
char 'f' >> return 5,
char 'g' >> return 7,
char 'a' >> return 9,
char 'b' >> return 11
]
noteModifier :: MyParser Integer
noteModifier = choice [char 's' >> return 1,
char 'f' >> return (-1),
char 'n' >> return 0
]
fromNote :: Num a => Pattern String -> Pattern a
fromNote pat = either (const 0) id . runParser parseNote 0 "" <$> pat
pColour :: MyParser (TPat ColourD)
pColour = wrapPos $ do name <- many1 letter <?> "colour name"
colour <- readColourName name <?> "known colour"
return $ TPat_Atom Nothing colour
pMult :: TPat a -> MyParser (TPat a)
pMult thing = do char '*'
spaces
r <- pRational <|> pPolyIn pRational <|> pPolyOut pRational
return $ TPat_Fast r thing
<|>
do char '/'
spaces
r <- pRational <|> pPolyIn pRational <|> pPolyOut pRational
return $ TPat_Slow r thing
<|>
return thing
pRand :: TPat a -> MyParser (TPat a)
pRand thing = do char '?'
r <- float <|> return 0.5
spaces
seed <- newSeed
return $ TPat_DegradeBy seed r thing
<|> return thing
pE :: TPat a -> MyParser (TPat a)
pE thing = do (n,k,s) <- parens pair
pure $ TPat_Euclid n k s thing
<|> return thing
where pair :: MyParser (TPat Int, TPat Int, TPat Int)
pair = do a <- pSequence pIntegral
spaces
symbol ","
spaces
b <- pSequence pIntegral
c <- do symbol ","
spaces
pSequence pIntegral
<|> return (TPat_Atom Nothing 0)
return (a, b, c)
pRatio :: MyParser Rational
pRatio = do s <- sign
n <- read <$> many1 digit
result <- do char '%'
d <- decimal
return (n%d)
<|>
do char '.'
frac <- many1 digit
return (toRational ((read $ show n ++ "." ++ frac) :: Double))
<|>
return (n%1)
c <- (ratioChar <|> return 1)
return $ applySign s (result * c)
<|> ratioChar
where ratioChar = do char 'h'
return $ 1%2
<|> do char 'q'
return $ 1%4
<|> do char 'e'
return $ 1%8
<|> do char 's'
return $ 1%16
<|> do char 't'
return $ 1%3
<|> do char 'f'
return $ 1%5
pRational :: MyParser (TPat Rational)
pRational = wrapPos $ (TPat_Atom Nothing) <$> pRatio