{-# LANGUAGE DeriveDataTypeable, FlexibleInstances, TypeSynonymInstances #-} {-# LANGUAGE DeriveFunctor #-} {-# OPTIONS_GHC -fno-warn-orphans #-} module Sound.Tidal.Pattern where import Prelude hiding ((<*), (*>)) import Control.Applicative (liftA2) --import Data.Bifunctor (Bifunctor(..)) import Data.Data (Data) -- toConstr import Data.List (delete, findIndex, sort) import qualified Data.Map.Strict as Map import Data.Maybe (isJust, fromJust, catMaybes, mapMaybe) import Data.Typeable (Typeable) import Control.DeepSeq (NFData(rnf)) import Data.Word (Word8) ------------------------------------------------------------------------ -- * Types -- | Time is rational type Time = Rational -- | The 'sam' (start of cycle) for the given time value sam :: Time -> Time sam = fromIntegral . (floor :: Time -> Int) -- | Turns a number into a (rational) time value. An alias for 'toRational'. toTime :: Real a => a -> Rational toTime = toRational -- | The end point of the current cycle (and starting point of the next cycle) nextSam :: Time -> Time nextSam = (1+) . sam -- | The position of a time value relative to the start of its cycle. cyclePos :: Time -> Time cyclePos t = t - sam t -- | An arc of time, with a start time (or onset) and a stop time (or offset) data ArcF a = Arc { start :: a , stop :: a } deriving (Eq, Ord, Functor, Show) type Arc = ArcF Time instance NFData a => NFData (ArcF a) where rnf (Arc s e) = rnf s `seq` rnf e instance Num a => Num (ArcF a) where negate = fmap negate (+) = liftA2 (+) (*) = liftA2 (*) fromInteger = pure . fromInteger abs = fmap abs signum = fmap signum instance (Fractional a) => Fractional (ArcF a) where recip = fmap recip fromRational = pure . fromRational sect :: Arc -> Arc -> Arc sect (Arc s e) (Arc s' e') = Arc (max s s') (min e e') -- | convex hull union hull :: Arc -> Arc -> Arc hull (Arc s e) (Arc s' e') = Arc (min s s') (max e e') -- | @subArc i j@ is the timespan that is the intersection of @i@ and @j@. -- intersection -- The definition is a bit fiddly as results might be zero-width, but -- not at the end of an non-zero-width arc - e.g. (0,1) and (1,2) do -- not intersect, but (1,1) (1,1) does. subArc :: Arc -> Arc -> Maybe Arc subArc a@(Arc s e) b@(Arc s' e') | and [s'' == e'', s'' == e, s < e] = Nothing | and [s'' == e'', s'' == e', s' < e'] = Nothing | s'' <= e'' = Just (Arc s'' e'') | otherwise = Nothing where (Arc s'' e'') = sect a b subMaybeArc :: Maybe Arc -> Maybe Arc -> Maybe (Maybe Arc) subMaybeArc (Just a) (Just b) = do sa <- subArc a b return $ Just sa subMaybeArc _ _ = Just Nothing instance Applicative ArcF where pure t = Arc t t (<*>) (Arc sf ef) (Arc sx ex) = Arc (sf sx) (ef ex) -- | The arc of the whole cycle that the given time value falls within timeToCycleArc :: Time -> Arc timeToCycleArc t = Arc (sam t) (sam t + 1) -- | Shifts an arc to the equivalent one that starts during cycle zero cycleArc :: Arc -> Arc cycleArc (Arc s e) = Arc (cyclePos s) (cyclePos s + (e-s)) -- | A list of cycle numbers which are included in the given arc cyclesInArc :: Integral a => Arc -> [a] cyclesInArc (Arc s e) | s > e = [] | s == e = [floor s] | otherwise = [floor s .. ceiling e-1] -- | A list of arcs of the whole cycles which are included in the given arc cycleArcsInArc :: Arc -> [Arc] cycleArcsInArc = map (timeToCycleArc . (toTime :: Int -> Time)) . cyclesInArc -- | Splits the given 'Arc' into a list of 'Arc's, at cycle boundaries. arcCycles :: Arc -> [Arc] arcCycles (Arc s e) | s >= e = [] | sam s == sam e = [Arc s e] | otherwise = Arc s (nextSam s) : arcCycles (Arc (nextSam s) e) -- | Like arcCycles, but returns zero-width arcs arcCyclesZW :: Arc -> [Arc] arcCyclesZW (Arc s e) | s == e = [Arc s e] | otherwise = arcCycles (Arc s e) -- | Similar to 'fmap' but time is relative to the cycle (i.e. the -- sam of the start of the arc) mapCycle :: (Time -> Time) -> Arc -> Arc mapCycle f (Arc s e) = Arc (sam' + f (s - sam')) (sam' + f (e - sam')) where sam' = sam s -- | @isIn a t@ is @True@ if @t@ is inside -- the arc represented by @a@. isIn :: Arc -> Time -> Bool isIn (Arc s e) t = t >= s && t < e data Context = Context {contextPosition :: [((Int, Int), (Int, Int))]} deriving (Eq, Ord) instance NFData Context where rnf (Context c) = rnf c combineContexts :: [Context] -> Context combineContexts = Context . concatMap contextPosition setContext :: Context -> Pattern a -> Pattern a setContext c pat = withEvents (map (\e -> e {context = c})) pat withContext :: (Context -> Context) -> Pattern a -> Pattern a withContext f pat = withEvents (map (\e -> e {context = f $ context e})) pat deltaContext :: Int -> Int -> Pattern a -> Pattern a deltaContext column line pat = withEvents (map (\e -> e {context = f $ context e})) pat where f :: Context -> Context f (Context xs) = Context $ map (\((bx,by), (ex,ey)) -> ((bx+column,by+line), (ex+column,ey+line))) xs -- | An event is a value that's active during a timespan. If a whole -- is present, the part should be equal to or fit inside it. data EventF a b = Event { context :: Context , whole :: Maybe a , part :: a , value :: b } deriving (Eq, Ord, Functor) type Event a = EventF (ArcF Time) a instance (NFData a, NFData b) => NFData (EventF a b) where rnf (Event c w p v) = rnf c `seq` rnf w `seq` rnf p `seq` rnf v {-instance Bifunctor EventF where bimap f g (Event w p e) = Event (f w) (f p) (g e) -} isAnalog :: Event a -> Bool isAnalog (Event {whole = Nothing}) = True isAnalog _ = False isDigital :: Event a -> Bool isDigital = not . isAnalog -- | `True` if an `Event`'s starts is within given `Arc` onsetIn :: Arc -> Event a -> Bool onsetIn a e = isIn a (wholeStart e) -- | Compares two lists of events, attempting to combine fragmented events in the process -- for a 'truer' compare compareDefrag :: (Ord a) => [Event a] -> [Event a] -> Bool compareDefrag as bs = sort (defragParts as) == sort (defragParts bs) -- | Returns a list of events, with any adjacent parts of the same whole combined defragParts :: Eq a => [Event a] -> [Event a] defragParts [] = [] defragParts [e] = [e] defragParts (e:es) | isJust i = defraged : defragParts (delete e' es) | otherwise = e : defragParts es where i = findIndex (isAdjacent e) es e' = es !! fromJust i defraged = Event (context e) (whole e) u (value e) u = hull (part e) (part e') -- | Returns 'True' if the two given events are adjacent parts of the same whole isAdjacent :: Eq a => Event a -> Event a -> Bool isAdjacent e e' = (whole e == whole e') && (value e == value e') && ((stop (part e) == start (part e')) || (stop (part e') == start (part e)) ) wholeOrPart :: Event a -> Arc wholeOrPart (Event {whole = Just a}) = a wholeOrPart e = part e -- | Get the onset of an event's 'whole' wholeStart :: Event a -> Time wholeStart = start . wholeOrPart -- | Get the offset of an event's 'whole' wholeStop :: Event a -> Time wholeStop = stop . wholeOrPart -- | Get the onset of an event's 'whole' eventPartStart :: Event a -> Time eventPartStart = start . part -- | Get the offset of an event's 'part' eventPartStop :: Event a -> Time eventPartStop = stop . part -- | Get the timespan of an event's 'part' eventPart :: Event a -> Arc eventPart = part eventValue :: Event a -> a eventValue = value eventHasOnset :: Event a -> Bool eventHasOnset e | isAnalog e = False | otherwise = start (fromJust $ whole e) == start (part e) -- TODO - Is this used anywhere? Just tests, it seems -- TODO - support 'context' field toEvent :: (((Time, Time), (Time, Time)), a) -> Event a toEvent (((ws, we), (ps, pe)), v) = Event (Context []) (Just $ Arc ws we) (Arc ps pe) v -- | an Arc and some named control values data State = State {arc :: Arc, controls :: StateMap } -- | A function that represents events taking place over time type Query a = (State -> [Event a]) -- | A datatype that's basically a query data Pattern a = Pattern {query :: Query a} data Value = VS { svalue :: String } | VF { fvalue :: Double } | VR { rvalue :: Rational } | VI { ivalue :: Int } | VB { bvalue :: Bool } | VX { xvalue :: [Word8] } -- Used for OSC 'blobs' deriving (Typeable,Data) class Valuable a where toValue :: a -> Value instance NFData Value where rnf (VS s) = rnf s rnf (VF f) = rnf f rnf (VR r) = rnf r rnf (VI i) = rnf i rnf (VB b) = rnf b rnf (VX xs) = rnf xs instance Valuable String where toValue = VS instance Valuable Double where toValue a = VF a instance Valuable Rational where toValue a = VR a instance Valuable Int where toValue a = VI a instance Valuable Bool where toValue a = VB a instance Valuable [Word8] where toValue a = VX a instance Eq Value where (VS x) == (VS y) = x == y (VB x) == (VB y) = x == y (VF x) == (VF y) = x == y (VI x) == (VI y) = x == y (VR x) == (VR y) = x == y (VX x) == (VX y) = x == y (VF x) == (VI y) = x == (fromIntegral y) (VI y) == (VF x) = x == (fromIntegral y) (VF x) == (VR y) = (toRational x) == y (VR y) == (VF x) = (toRational x) == y (VI x) == (VR y) = (toRational x) == y (VR y) == (VI x) = (toRational x) == y _ == _ = False instance Ord Value where compare (VS x) (VS y) = compare x y compare (VB x) (VB y) = compare x y compare (VF x) (VF y) = compare x y compare (VI x) (VI y) = compare x y compare (VR x) (VR y) = compare x y compare (VX x) (VX y) = compare x y compare (VS _) _ = LT compare _ (VS _) = GT compare (VB _) _ = LT compare _ (VB _) = GT compare (VX _) _ = LT compare _ (VX _) = GT compare (VF x) (VI y) = compare x (fromIntegral y) compare (VI x) (VF y) = compare (fromIntegral x) y compare (VR x) (VI y) = compare x (fromIntegral y) compare (VI x) (VR y) = compare (fromIntegral x) y compare (VF x) (VR y) = compare x (fromRational y) compare (VR x) (VF y) = compare (fromRational x) y type StateMap = Map.Map String (Pattern Value) type ControlMap = Map.Map String Value type ControlPattern = Pattern ControlMap ------------------------------------------------------------------------ -- * Instances instance NFData a => NFData (Pattern a) where rnf (Pattern q) = rnf $ \s -> q s instance Functor Pattern where -- | apply a function to all the values in a pattern fmap f p = p {query = fmap (fmap f) . query p} applyPatToPat :: (Maybe Arc -> Maybe Arc -> Maybe (Maybe Arc)) -> Pattern (a -> b) -> Pattern a -> Pattern b applyPatToPat combineWholes pf px = Pattern q where q st = catMaybes $ concatMap match $ query pf st where match (ef@(Event (Context c) _ fPart f)) = map (\ex@(Event (Context c') _ xPart x) -> do whole' <- combineWholes (whole ef) (whole ex) part' <- subArc fPart xPart return (Event (Context $ c ++ c') whole' part' (f x)) ) (query px $ st {arc = (wholeOrPart ef)}) instance Applicative Pattern where -- | Repeat the given value once per cycle, forever pure v = Pattern $ \(State a _) -> map (\a' -> Event (Context []) (Just a') (sect a a') v) $ cycleArcsInArc a (<*>) = applyPatToPatBoth applyPatToPatBoth :: Pattern (a -> b) -> Pattern a -> Pattern b applyPatToPatBoth pf px = Pattern q where q st = catMaybes $ (concatMap match $ query pf st) ++ (concatMap matchX $ query (filterAnalog px) st) where -- match analog events from pf with all events from px match ef@(Event _ Nothing fPart _) = map (withFX ef) (query px $ st {arc = fPart}) -- analog -- match digital events from pf with digital events from px match ef@(Event _ (Just fWhole) _ _) = map (withFX ef) (query (filterDigital px) $ st {arc = fWhole}) -- digital -- match analog events from px (constrained above) with digital events from px matchX ex@(Event _ Nothing fPart _) = map (\ef -> withFX ef ex) (query (filterDigital pf) $ st {arc = fPart}) -- digital matchX _ = error "can't happen" withFX ef ex = do whole' <- subMaybeArc (whole ef) (whole ex) part' <- subArc (part ef) (part ex) return (Event (combineContexts [context ef, context ex]) whole' part' (value ef $ value ex)) applyPatToPatLeft :: Pattern (a -> b) -> Pattern a -> Pattern b applyPatToPatLeft pf px = Pattern q where q st = catMaybes $ (concatMap match $ query pf st) where match ef = map (withFX ef) (query px $ st {arc = wholeOrPart ef}) withFX ef ex = do let whole' = whole ef part' <- subArc (part ef) (part ex) return (Event (combineContexts [context ef, context ex]) whole' part' (value ef $ value ex)) applyPatToPatRight :: Pattern (a -> b) -> Pattern a -> Pattern b applyPatToPatRight pf px = Pattern q where q st = catMaybes $ (concatMap match $ query px st) where match ex = map (\ef -> withFX ef ex) (query pf $ st {arc = wholeOrPart ex}) withFX ef ex = do let whole' = whole ex part' <- subArc (part ef) (part ex) return (Event (combineContexts [context ef, context ex]) whole' part' (value ef $ value ex)) -- | Like <*>, but the 'wholes' come from the left (<*) :: Pattern (a -> b) -> Pattern a -> Pattern b (<*) = applyPatToPatLeft -- | Like <*>, but the 'wholes' come from the right (*>) :: Pattern (a -> b) -> Pattern a -> Pattern b (*>) = applyPatToPatRight infixl 4 <*, *> instance Monad Pattern where return = pure p >>= f = unwrap (f <$> p) -- | Turns a pattern of patterns into a single pattern. -- (this is actually 'join') -- -- 1/ For query 'arc', get the events from the outer pattern @pp@ -- 2/ Query the inner pattern using the 'part' of the outer -- 3/ For each inner event, set the whole and part to be the intersection -- of the outer whole and part, respectively -- 4/ Concatenate all the events together (discarding wholes/parts that didn't intersect) -- -- TODO - what if a continuous pattern contains a discrete one, or vice-versa? unwrap :: Pattern (Pattern a) -> Pattern a unwrap pp = pp {query = q} where q st = concatMap (\(Event c w p v) -> mapMaybe (munge c w p) $ query v st {arc = p}) (query pp st) munge oc ow op (Event ic iw ip v') = do w' <- subMaybeArc ow iw p' <- subArc op ip return (Event (combineContexts [ic, oc]) w' p' v') -- | Turns a pattern of patterns into a single pattern. Like @unwrap@, -- but structure only comes from the inner pattern. innerJoin :: Pattern (Pattern a) -> Pattern a innerJoin pp = pp {query = q} where q st = concatMap (\(Event oc _ op v) -> mapMaybe (munge oc) $ query v st {arc = op} ) (query pp st) where munge oc (Event ic iw ip v) = do p <- subArc (arc st) ip p' <- subArc p (arc st) return (Event (combineContexts [ic, oc]) iw p' v) -- | Turns a pattern of patterns into a single pattern. Like @unwrap@, -- but structure only comes from the outer pattern. outerJoin :: Pattern (Pattern a) -> Pattern a outerJoin pp = pp {query = q} where q st = concatMap (\e -> mapMaybe (munge (context e) (whole e) (part e)) $ query (value e) st {arc = pure (start $ wholeOrPart e)} ) (query pp st) where munge oc ow op (Event ic _ _ v') = do p' <- subArc (arc st) op return (Event (combineContexts [oc, ic]) ow p' v') -- | Like @unwrap@, but cycles of the inner patterns are compressed to fit the -- timespan of the outer whole (or the original query if it's a continuous pattern?) -- TODO - what if a continuous pattern contains a discrete one, or vice-versa? squeezeJoin :: Pattern (Pattern a) -> Pattern a squeezeJoin pp = pp {query = q} where q st = concatMap (\e@(Event c w p v) -> mapMaybe (munge c w p) $ query (compressArc (cycleArc $ wholeOrPart e) v) st {arc = p} ) (query pp st) munge oContext oWhole oPart (Event iContext iWhole iPart v) = do w' <- subMaybeArc oWhole iWhole p' <- subArc oPart iPart return (Event (combineContexts [iContext, oContext]) w' p' v) noOv :: String -> a noOv meth = error $ meth ++ ": not supported for patterns" class TolerantEq a where (~==) :: a -> a -> Bool instance TolerantEq Value where (VS a) ~== (VS b) = a == b (VI a) ~== (VI b) = a == b (VR a) ~== (VR b) = a == b (VF a) ~== (VF b) = abs (a - b) < 0.000001 _ ~== _ = False instance TolerantEq ControlMap where a ~== b = Map.differenceWith (\a' b' -> if a' ~== b' then Nothing else Just a') a b == Map.empty instance TolerantEq (Event ControlMap) where (Event _ w p x) ~== (Event _ w' p' x') = w == w' && p == p' && x ~== x' instance TolerantEq a => TolerantEq [a] where as ~== bs = (length as == length bs) && all (uncurry (~==)) (zip as bs) instance Eq (Pattern a) where (==) = noOv "(==)" instance Ord a => Ord (Pattern a) where min = liftA2 min max = liftA2 max compare = noOv "compare" (<=) = noOv "(<=)" instance Num a => Num (Pattern a) where negate = fmap negate (+) = liftA2 (+) (*) = liftA2 (*) fromInteger = pure . fromInteger abs = fmap abs signum = fmap signum instance Enum a => Enum (Pattern a) where succ = fmap succ pred = fmap pred toEnum = pure . toEnum fromEnum = noOv "fromEnum" enumFrom = noOv "enumFrom" enumFromThen = noOv "enumFromThen" enumFromTo = noOv "enumFromTo" enumFromThenTo = noOv "enumFromThenTo" instance (Num a, Ord a) => Real (Pattern a) where toRational = noOv "toRational" instance (Integral a) => Integral (Pattern a) where quot = liftA2 quot rem = liftA2 rem div = liftA2 div mod = liftA2 mod toInteger = noOv "toInteger" x `quotRem` y = (x `quot` y, x `rem` y) x `divMod` y = (x `div` y, x `mod` y) instance (Fractional a) => Fractional (Pattern a) where recip = fmap recip fromRational = pure . fromRational instance (Floating a) => Floating (Pattern a) where pi = pure pi sqrt = fmap sqrt exp = fmap exp log = fmap log sin = fmap sin cos = fmap cos asin = fmap asin atan = fmap atan acos = fmap acos sinh = fmap sinh cosh = fmap cosh asinh = fmap asinh atanh = fmap atanh acosh = fmap acosh instance (RealFrac a) => RealFrac (Pattern a) where properFraction = noOv "properFraction" truncate = noOv "truncate" round = noOv "round" ceiling = noOv "ceiling" floor = noOv "floor" instance (RealFloat a) => RealFloat (Pattern a) where floatRadix = noOv "floatRadix" floatDigits = noOv "floatDigits" floatRange = noOv "floatRange" decodeFloat = noOv "decodeFloat" encodeFloat = ((.).(.)) pure encodeFloat exponent = noOv "exponent" significand = noOv "significand" scaleFloat n = fmap (scaleFloat n) isNaN = noOv "isNaN" isInfinite = noOv "isInfinite" isDenormalized = noOv "isDenormalized" isNegativeZero = noOv "isNegativeZero" isIEEE = noOv "isIEEE" atan2 = liftA2 atan2 instance Num ControlMap where negate = (applyFIS negate negate id <$>) (+) = Map.unionWith (fNum2 (+) (+)) (*) = Map.unionWith (fNum2 (*) (*)) fromInteger i = Map.singleton "n" $ VI $ fromInteger i signum = (applyFIS signum signum id <$>) abs = (applyFIS abs abs id <$>) instance Fractional ControlMap where recip = fmap (applyFIS recip id id) fromRational = Map.singleton "speed" . VF . fromRational ------------------------------------------------------------------------ -- * Internal functions empty :: Pattern a empty = Pattern {query = const []} queryArc :: Pattern a -> Arc -> [Event a] queryArc p a = query p $ State a Map.empty -- | Splits queries that span cycles. For example `query p (0.5, 1.5)` would be -- turned into two queries, `(0.5,1)` and `(1,1.5)`, and the results -- combined. Being able to assume queries don't span cycles often -- makes transformations easier to specify. splitQueries :: Pattern a -> Pattern a splitQueries p = p {query = \st -> concatMap (\a -> query p st {arc = a}) $ arcCyclesZW (arc st)} -- | Apply a function to the arcs/timespans (both whole and parts) of the result withResultArc :: (Arc -> Arc) -> Pattern a -> Pattern a withResultArc f pat = pat { query = map (\(Event c w p e) -> Event c (f <$> w) (f p) e) . query pat} -- | Apply a function to the time (both start and end of the timespans -- of both whole and parts) of the result withResultTime :: (Time -> Time) -> Pattern a -> Pattern a withResultTime f = withResultArc (\(Arc s e) -> Arc (f s) (f e)) -- | Apply a function to the timespan of the query withQueryArc :: (Arc -> Arc) -> Pattern a -> Pattern a withQueryArc f p = p {query = query p . (\(State a m) -> State (f a) m)} -- | Apply a function to the time (both start and end) of the query withQueryTime :: (Time -> Time) -> Pattern a -> Pattern a withQueryTime f = withQueryArc (\(Arc s e) -> Arc (f s) (f e)) -- | @withEvent f p@ returns a new @Pattern@ with each event mapped over -- function @f@. withEvent :: (Event a -> Event b) -> Pattern a -> Pattern b withEvent f p = p {query = map f . query p} -- | @withEvent f p@ returns a new @Pattern@ with f applied to the resulting list of events for each query -- function @f@. withEvents :: ([Event a] -> [Event b]) -> Pattern a -> Pattern b withEvents f p = p {query = f . query p} -- | @withPart f p@ returns a new @Pattern@ with function @f@ applied -- to the part. withPart :: (Arc -> Arc) -> Pattern a -> Pattern a withPart f = withEvent (\(Event c w p v) -> Event c w (f p) v) -- | Apply one of three functions to a Value, depending on its type applyFIS :: (Double -> Double) -> (Int -> Int) -> (String -> String) -> Value -> Value applyFIS f _ _ (VF f') = VF $ f f' applyFIS _ f _ (VI i ) = VI $ f i applyFIS _ _ f (VS s ) = VS $ f s applyFIS _ _ _ v = v -- | Apply one of two functions to a Value, depending on its type (int -- or float; strings and rationals are ignored) fNum2 :: (Int -> Int -> Int) -> (Double -> Double -> Double) -> Value -> Value -> Value fNum2 fInt _ (VI a) (VI b) = VI $ fInt a b fNum2 _ fFloat (VF a) (VF b) = VF $ fFloat a b fNum2 _ fFloat (VI a) (VF b) = VF $ fFloat (fromIntegral a) b fNum2 _ fFloat (VF a) (VI b) = VF $ fFloat a (fromIntegral b) fNum2 _ _ x _ = x getI :: Value -> Maybe Int getI (VI i) = Just i getI (VR x) = Just $ floor x getI (VF x) = Just $ floor x getI _ = Nothing getF :: Value -> Maybe Double getF (VF f) = Just f getF (VR x) = Just $ fromRational x getF (VI x) = Just $ fromIntegral x getF _ = Nothing getS :: Value -> Maybe String getS (VS s) = Just s getS _ = Nothing getB :: Value -> Maybe Bool getB (VB b) = Just b getB _ = Nothing getR :: Value -> Maybe Rational getR (VR r) = Just r getR (VF x) = Just $ toRational x getR (VI x) = Just $ toRational x getR _ = Nothing getBlob :: Value -> Maybe [Word8] getBlob (VX xs) = Just xs getBlob _ = Nothing compressArc :: Arc -> Pattern a -> Pattern a compressArc (Arc s e) p | s > e = empty | s > 1 || e > 1 = empty | s < 0 || e < 0 = empty | otherwise = s `rotR` _fastGap (1/(e-s)) p compressArcTo :: Arc -> Pattern a -> Pattern a compressArcTo (Arc s e) = compressArc (Arc (cyclePos s) (e - sam s)) _fastGap :: Time -> Pattern a -> Pattern a _fastGap 0 _ = empty _fastGap r p = splitQueries $ withResultArc (\(Arc s e) -> Arc (sam s + ((s - sam s)/r')) (sam s + ((e - sam s)/r')) ) $ p {query = f} where r' = max r 1 -- zero width queries of the next sam should return zero in this case.. f st@(State a _) | start a' == nextSam (start a) = [] | otherwise = query p st {arc = a'} where mungeQuery t = sam t + min 1 (r' * cyclePos t) a' = (\(Arc s e) -> Arc (mungeQuery s) (mungeQuery e)) a -- | Shifts a pattern back in time by the given amount, expressed in cycles rotL :: Time -> Pattern a -> Pattern a rotL t p = withResultTime (subtract t) $ withQueryTime (+ t) p -- | Shifts a pattern forward in time by the given amount, expressed in cycles rotR :: Time -> Pattern a -> Pattern a rotR t = rotL (negate t) -- ** Event filters -- | Remove events from patterns that to not meet the given test filterValues :: (a -> Bool) -> Pattern a -> Pattern a filterValues f p = p {query = filter (f . value) . query p} -- | Turns a pattern of 'Maybe' values into a pattern of values, -- dropping the events of 'Nothing'. filterJust :: Pattern (Maybe a) -> Pattern a filterJust p = fromJust <$> filterValues isJust p -- formerly known as playWhen filterWhen :: (Time -> Bool) -> Pattern a -> Pattern a filterWhen test p = p {query = filter (test . wholeStart) . query p} filterOnsets :: Pattern a -> Pattern a filterOnsets p = p {query = filter (\e -> eventPartStart e == wholeStart e) . query (filterDigital p)} filterEvents :: (Event a -> Bool) -> Pattern a -> Pattern a filterEvents f p = p {query = filter f . query p} filterDigital :: Pattern a -> Pattern a filterDigital = filterEvents isDigital filterAnalog :: Pattern a -> Pattern a filterAnalog = filterEvents isAnalog playFor :: Time -> Time -> Pattern a -> Pattern a playFor s e = filterWhen (\t -> (t >= s) && (t < e)) -- ** Temporal parameter helpers tParam :: (t1 -> t2 -> Pattern a) -> Pattern t1 -> t2 -> Pattern a tParam f tv p = innerJoin $ (`f` p) <$> tv tParam2 :: (a -> b -> c -> Pattern d) -> Pattern a -> Pattern b -> c -> Pattern d tParam2 f a b p = innerJoin $ (\x y -> f x y p) <$> a <*> b tParam3 :: (a -> b -> c -> Pattern d -> Pattern e) -> (Pattern a -> Pattern b -> Pattern c -> Pattern d -> Pattern e) tParam3 f a b c p = innerJoin $ (\x y z -> f x y z p) <$> a <*> b <*> c tParamSqueeze :: (a -> Pattern b -> Pattern c) -> (Pattern a -> Pattern b -> Pattern c) tParamSqueeze f tv p = squeezeJoin $ (`f` p) <$> tv -- | Mark values in the first pattern which match with at least one -- value in the second pattern. matchManyToOne :: (b -> a -> Bool) -> Pattern a -> Pattern b -> Pattern (Bool, b) matchManyToOne f pa pb = pa {query = q} where q st = map match $ query pb st where match (ex@(Event xContext xWhole xPart x)) = Event (combineContexts $ xContext:(map context as')) xWhole xPart (any (f x) (map value $ as'), x) where as' = as $ start $ wholeOrPart ex as s = query pa $ fQuery s fQuery s = st {arc = Arc s s}