tidal 1.9.4 → 1.9.5
raw patch · 15 files changed
+3818/−2483 lines, 15 filesdep ~criteriondep ~networkdep ~randomnew-uploader
Dependency ranges changed: criterion, network, random, tidal-link
Files
- CHANGELOG.md +21/−1
- src/Sound/Tidal/Chords.hs +59/−7
- src/Sound/Tidal/Control.hs +236/−121
- src/Sound/Tidal/Core.hs +222/−46
- src/Sound/Tidal/Params.hs +183/−18
- src/Sound/Tidal/Pattern.hs +106/−21
- src/Sound/Tidal/Safe/Boot.hs +42/−0
- src/Sound/Tidal/Scales.hs +79/−16
- src/Sound/Tidal/Stream.hs +21/−10
- src/Sound/Tidal/StreamTypes.hs +3/−0
- src/Sound/Tidal/Tempo.hs +6/−0
- src/Sound/Tidal/Time.hs +5/−5
- src/Sound/Tidal/UI.hs +2827/−2230
- src/Sound/Tidal/Version.hs +1/−1
- tidal.cabal +7/−7
CHANGELOG.md view
@@ -1,5 +1,25 @@ # TidalCycles log of changes +## 1.9.5 - Sashiko++## What's Changed+* avoid loading stream module in other modules, so hint wont crash by @polymorphicengine in https://github.com/tidalcycles/Tidal/pull/1019+* change streamGetnow to factor in the processAhead and also destroy the sessionstate by @polymorphicengine in https://github.com/tidalcycles/Tidal/pull/1025+* fix minor7sharp9 chord (the 9th wasn't sharp) by @cleary in https://github.com/tidalcycles/Tidal/pull/1036+* add metatune param, now against 1.9-dev by @ahihi in https://github.com/tidalcycles/Tidal/pull/1046+* Build fixes for Tidal 1.9 by @mindofmatthew in https://github.com/tidalcycles/Tidal/pull/1052+* Update link 1.9 dev by @yaxu in https://github.com/tidalcycles/Tidal/pull/1058+* More build fixes by @mindofmatthew in https://github.com/tidalcycles/Tidal/pull/1062+* Consolidate site docs into source docs, and some docs editing by @trespaul in https://github.com/tidalcycles/Tidal/pull/1070+* Fix negative numbers not working for boolean euclids by @geikha in https://github.com/tidalcycles/Tidal/pull/1063++## New Contributors+* @ahihi made their first contribution in https://github.com/tidalcycles/Tidal/pull/1046+* @trespaul made their first contribution in https://github.com/tidalcycles/Tidal/pull/1070+* @geikha made their first contribution in https://github.com/tidalcycles/Tidal/pull/1063++**Full Changelog**: https://github.com/tidalcycles/Tidal/compare/v1.9.4...v1.9.5+ ## 1.9.4 - Stitch ### What's Changed@@ -17,7 +37,7 @@ **Full Changelog**: https://github.com/tidalcycles/Tidal/compare/v1.9.3...v1.9.4 -### 1.9.3 - Kolam+## 1.9.3 - Kolam ### What's Changed * fix for squeezejoin by @yaxu in https://github.com/tidalcycles/Tidal/pull/950
src/Sound/Tidal/Chords.hs view
@@ -22,7 +22,10 @@ import Sound.Tidal.Pattern --- major chords+-- * Chord definitions++-- ** Major chords+ major :: Num a => [a] major = [0,4,7] aug :: Num a => [a]@@ -45,7 +48,9 @@ major13 = [0,4,7,11,14,21] add13 :: Num a => [a] add13 = [0,4,7,21]--- dominant chords++-- ** Dominant chords+ dom7 :: Num a => [a] dom7 = [0,4,7,10] dom9 :: Num a => [a]@@ -66,7 +71,9 @@ eleven = [0,4,7,10,14,17] thirteen :: Num a => [a] thirteen = [0,4,7,10,14,17,21]--- minor chords++-- ** Minor chords+ minor :: Num a => [a] minor = [0,3,7] diminished :: Num a => [a]@@ -86,7 +93,7 @@ minor7flat9 :: Num a => [a] minor7flat9 = [0,3,7,10,13] minor7sharp9 :: Num a => [a]-minor7sharp9 = [0,3,7,10,14]+minor7sharp9 = [0,3,7,10,15] diminished7 :: Num a => [a] diminished7 = [0,3,6,9] minor9 :: Num a => [a]@@ -97,7 +104,9 @@ minor13 = [0,3,7,10,14,17,21] minorMajor7 :: Num a => [a] minorMajor7 = [0,3,7,11]--- other chords++-- ** Other chords+ one :: Num a => [a] one = [0] five :: Num a => [a]@@ -112,7 +121,9 @@ sevenSus4 = [0,5,7,10] nineSus4 :: Num a => [a] nineSus4 = [0,5,7,10,14]--- questionable chords++-- ** Questionable chords+ sevenFlat10 :: Num a => [a] sevenFlat10 = [0,4,7,10,15] nineSharp5 :: Num a => [a]@@ -128,6 +139,8 @@ minor11sharp :: Num a => [a] minor11sharp = [0,3,7,10,14,18] +-- * Chord functions+ -- | @chordate cs m n@ selects the @n@th "chord" (a chord is a list of Ints) -- from a list of chords @cs@ and transposes it by @m@ -- chordate :: Num b => [[b]] -> b -> Int -> [b]@@ -140,6 +153,22 @@ -- enchord :: Num a => [[a]] -> Pattern a -> Pattern Int -> Pattern a -- enchord chords pn pc = flatpat $ (chordate chords) <$> pn <*> pc +{-|+ The @chordTable@ function outputs a list of all available chords and their+ corresponding notes. For example, its first entry is @("major",[0,4,7])@ which+ means that a major triad is formed by the root (0), the major third (4 semitones+ above the root), and the perfect fifth (7 semitones above the root).++ As the list is big, you can use the function 'chordL'.++ If you know the notes from a chord, but can’t find the name of it, you can use this Haskell code to do a reverse look up into the table:++ > filter (\(_,x)->x==[0,4,7,10]) chordTable++ This will output @[("dom7",[0,4,7,10])]@++ (You’ll need to run @import Sound.Tidal.Chords@ before using this function.)+-} chordTable :: Num a => [(String, [a])] chordTable = [("major", major), ("maj", major),@@ -273,9 +302,31 @@ ("m11s", minor11sharp) ] +-- | Look up a specific chord: @chordL "minor7"@ returns @(0>1)|[0,3,7,10]@. chordL :: Num a => Pattern String -> Pattern [a] chordL p = (\name -> fromMaybe [] $ lookup name chordTable) <$> p +{-|+Outputs all the available chords:++@+major maj M aug plus sharp5 six 6 sixNine six9 sixby9 6by9 major7 maj7+major9 maj9 add9 major11 maj11 add11 major13 maj13 add13 dom7 dom9 dom11+dom13 sevenFlat5 7f5 sevenSharp5 7s5 sevenFlat9 7f9 nine eleven 11 thirteen 13+minor min m diminished dim minorSharp5 msharp5 mS5 minor6 min6 m6 minorSixNine+minor69 min69 minSixNine m69 mSixNine m6by9 minor7flat5 minor7f5 min7flat5+min7f5 m7flat5 m7f5 minor7 min7 m7 minor7sharp5 minor7s5 min7sharp5 min7s5+m7sharp5 m7s5 minor7flat9 minor7f9 min7flat9 min7f9 m7flat9 m7f9 minor7sharp9+minor7s9 min7sharp9 min7s9 m7sharp9 m7s9 diminished7 dim7 minor9 min9 m9+minor11 min11 m11 minor13 min13 m13 minorMajor7 minMaj7 mmaj7 one 1 five 5+sus2 sus4 sevenSus2 7sus2 sevenSus4 7sus4 nineSus4 ninesus4 9sus4 sevenFlat10+7f10 nineSharp5 9sharp5 9s5 minor9sharp5 minor9s5 min9sharp5 min9s5 m9sharp5+m9s5 sevenSharp5flat9 7s5f9 minor7sharp5flat9 m7sharp5flat9 elevenSharp 11s+minor11sharp m11sharp m11s+@++(You’ll need to run @import Sound.Tidal.Chords@ before using this function.)+-} chordList :: String chordList = unwords $ map fst (chordTable :: [(String, [Int])]) @@ -317,6 +368,7 @@ let ch = map (+ n) (fromMaybe [0] $ lookup name chordTable) applyModifierPatSeq f (return ch) modsP --- | turns a given pattern of some Num type, a pattern of chord names and a list of patterns of modifiers into a chord pattern+-- | Turns a given pattern of some 'Num' type, a pattern of chord names, and a+-- list of patterns of modifiers into a chord pattern chord :: (Num a, Enum a) => Pattern a -> Pattern String -> [Pattern [Modifier]] -> Pattern a chord = chordToPatSeq id
src/Sound/Tidal/Control.hs view
@@ -29,20 +29,19 @@ import Sound.Tidal.Pattern import Sound.Tidal.Core-import Sound.Tidal.Stream (patternTimeID)+import Sound.Tidal.StreamTypes (patternTimeID) import Sound.Tidal.UI import qualified Sound.Tidal.Params as P import Sound.Tidal.Utils -{- | `spin` will "spin" a layer up a pattern the given number of times,-with each successive layer offset in time by an additional `1/n` of a-cycle, and panned by an additional `1/n`. The result is a pattern that-seems to spin around. This function works best on multichannel-systems.+{- | `spin` will "spin" and layer up a pattern the given number of times,+with each successive layer offset in time by an additional @1/n@ of a cycle,+and panned by an additional @1/n@. The result is a pattern that seems to spin+around. This function work well on multichannel systems. -@-d1 $ slow 3 $ spin 4 $ sound "drum*3 tabla:4 [arpy:2 ~ arpy] [can:2 can:3]"-@+> d1 $ slow 3+> $ spin 4+> $ sound "drum*3 tabla:4 [arpy:2 ~ arpy] [can:2 can:3]" -} spin :: Pattern Int -> ControlPattern -> ControlPattern spin = tParam _spin@@ -57,23 +56,36 @@ -{- | `chop` granualizes every sample in place as it is played, turning a pattern of samples into a pattern of sample parts. Use an integer value to specify how many granules each sample is chopped into:+{- | `chop` granularises every sample in place as it is played, turning a+ pattern of samples into a pattern of sample parts. Can be used to explore+ granular synthesis. -@-d1 $ chop 16 $ sound "arpy arp feel*4 arpy*4"-@+ Use an integer value to specify how many granules each sample is chopped into: -Different values of `chop` can yield very different results, depending-on the samples used:+ > d1 $ chop 16 $ sound "arpy arp feel*4 arpy*4" + Different values of @chop@ can yield very different results, depending on the+ samples used: -@-d1 $ chop 16 $ sound (samples "arpy*8" (run 16))-d1 $ chop 32 $ sound (samples "arpy*8" (run 16))-d1 $ chop 256 $ sound "bd*4 [sn cp] [hh future]*2 [cp feel]"-@--}+ > d1 $ chop 16 $ sound (samples "arpy*8" (run 16))+ > d1 $ chop 32 $ sound (samples "arpy*8" (run 16))+ > d1 $ chop 256 $ sound "bd*4 [sn cp] [hh future]*2 [cp feel]" + You can also use @chop@ (or 'striate') with very long samples to cut them into short+ chunks and pattern those chunks. The following cuts a sample into 32 parts, and+ plays it over 8 cycles:++ > d1 $ loopAt 8 $ chop 32 $ sound "bev"++ The 'loopAt' takes care of changing the speed of sample playback so that the+ sample fits in the given number of cycles perfectly. As a result, in the above+ the granules line up perfectly, so you can’t really hear that the sample has+ been cut into bits. Again, this becomes more apparent when you do further+ manipulations of the pattern, for example 'rev' to reverse the order of the cut+ up bits:++ > d1 $ loopAt 8 $ rev $ chop 32 $ sound "bev"+-} chop :: Pattern Int -> ControlPattern -> ControlPattern chop = tParam _chop @@ -118,28 +130,25 @@ -} -{- | Striate is a kind of granulator, for example:+{-| Striate is a kind of granulator, cutting samples into bits in a similar to+chop, but the resulting bits are organised differently. For example: -@-d1 $ striate 3 $ sound "ho ho:2 ho:3 hc"-@+> d1 $ striate 3 $ sound "ho ho:2 ho:3 hc" -This plays the loop the given number of times, but triggering-progressive portions of each sample. So in this case it plays the loop-three times, the first time playing the first third of each sample,-then the second time playing the second third of each sample, etc..-With the highhat samples in the above example it sounds a bit like-reverb, but it isn't really.+This plays the loop the given number of times, but triggers progressive portions+of each sample. So in this case it plays the loop three times, the first+time playing the first third of each sample, then the second time playing the+second third of each sample, and lastly playing the last third of each sample.+Replacing @striate@ with 'chop' above, one can hear that the ''chop' version+plays the bits from each chopped-up sample in turn, while @striate@ "interlaces"+the cut up bits of samples together. -You can also use striate with very long samples, to cut it into short-chunks and pattern those chunks. This is where things get towards-granular synthesis. The following cuts a sample into 128 parts, plays-it over 8 cycles and manipulates those parts by reversing and rotating-the loops.+You can also use @striate@ with very long samples, to cut them into short+chunks and pattern those chunks. This is where things get towards granular+synthesis. The following cuts a sample into 128 parts, plays it over 8 cycles+and manipulates those parts by reversing and rotating the loops: -@-d1 $ slow 8 $ striate 128 $ sound "bev"-@+> d1 $ slow 8 $ striate 128 $ sound "bev" -} striate :: Pattern Int -> ControlPattern -> ControlPattern@@ -157,20 +166,19 @@ {-|-The `striateBy` function is a variant of `striate` with an extra-parameter, which specifies the length of each part. The `striateBy`+The @striateBy@ function is a variant of `striate` with an extra+parameter which specifies the length of each part. The @striateBy@ function still scans across the sample over a single cycle, but if each bit is longer, it creates a sort of stuttering effect. For-example the following will cut the bev sample into 32 parts, but each+example the following will cut the @bev@ sample into 32 parts, but each will be 1/16th of a sample long: -@-d1 $ slow 32 $ striateBy 32 (1/16) $ sound "bev"-@+> d1 $ slow 32 $ striateBy 32 (1/16) $ sound "bev" -Note that `striate` uses the `begin` and `end` parameters-internally. This means that if you're using `striate` (or `striateBy`)-you probably shouldn't also specify `begin` or `end`. -}+Note that `striate` and @striateBy@ use the `begin` and `end` parameters+internally. This means that you probably shouldn't also specify `begin` or+`end`.+-} striateBy :: Pattern Int -> Pattern Double -> ControlPattern -> ControlPattern striateBy = tParam2 _striateBy @@ -188,10 +196,9 @@ but every other grain is silent. Use an integer value to specify how many granules each sample is chopped into: -@-d1 $ gap 8 $ sound "jvbass"-d1 $ gap 16 $ sound "[jvbass drum:4]"-@-}+> d1 $ gap 8 $ sound "jvbass"+> d1 $ gap 16 $ sound "[jvbass drum:4]"+-} gap :: Pattern Int -> ControlPattern -> ControlPattern gap = tParam _gap@@ -200,28 +207,56 @@ _gap n p = _fast (toRational n) (cat [pure 1, silence]) |>| _chop n p {- |-`weave` applies a function smoothly over an array of different patterns. It uses an `OscPattern` to-apply the function at different levels to each pattern, creating a weaving effect.+ @weave@ applies one control pattern to a list of other control patterns, with+ a successive time offset. It uses an `OscPattern` to apply the function at+ different levels to each pattern, creating a weaving effect. For example: -@-d1 $ weave 3 (shape $ sine1) [sound "bd [sn drum:2*2] bd*2 [sn drum:1]", sound "arpy*8 ~"]-@+ > d1 $ weave 16 (pan sine)+ > [ sound "bd sn cp"+ > , sound "casio casio:1"+ > , sound "[jvbass*2 jvbass:2]/2"+ > , sound "hc*4"+ > ]++ In the above, the @pan sine@ control pattern is slowed down by the given+ number of cycles, in particular 16, and applied to all of the given sound+ patterns. What makes this interesting is that the @pan@ control pattern is+ successively offset for each of the given sound patterns; because the @pan@ is+ closed down by 16 cycles, and there are four patterns, they are ‘spread out’,+ i.e. with a gap of four cycles. For this reason, the four patterns seem to+ chase after each other around the stereo field. Try listening on headphones to+ hear this more clearly.++ You can even have it the other way round, and have the effect parameters chasing+ after each other around a sound parameter, like this:++ > d1 $ weave 16 (sound "arpy" >| n (run 8))+ > [ vowel "a e i"+ > , vowel "i [i o] o u"+ > , vowel "[e o]/3 [i o u]/2"+ > , speed "1 2 3"+ > ] -} weave :: Time -> ControlPattern -> [ControlPattern] -> ControlPattern weave t p ps = weave' t p (map (#) ps) -{- | `weaveWith` is similar in that it blends functions at the same time at different amounts over a pattern:+{-|+ @weaveWith@ is similar to the above, but weaves with a list of functions, rather+ than a list of controls. For example: -@-d1 $ weaveWith 3 (sound "bd [sn drum:2*2] bd*2 [sn drum:1]") [density 2, (# speed "0.5"), chop 16]-@+ > d1 $ weaveWith 3 (sound "bd [sn drum:2*2] bd*2 [sn drum:1]")+ > [ fast 2+ > , (# speed "0.5")+ > , chop 16+ > ] -} weaveWith :: Time -> Pattern a -> [Pattern a -> Pattern a] -> Pattern a weaveWith t p fs | l == 0 = silence | otherwise = _slow t $ stack $ zipWith (\ i f -> (fromIntegral i % l) `rotL` _fast t (f (_slow t p))) [0 :: Int ..] fs where l = fromIntegral $ length fs +-- | An old alias for 'weaveWith'. weave' :: Time -> Pattern a -> [Pattern a -> Pattern a] -> Pattern a weave' = weaveWith @@ -234,9 +269,7 @@ Example: -@-d1 $ interlace (sound "bd sn kurt") (every 3 rev $ sound "bd sn:2")-@+> d1 $ interlace (sound "bd sn kurt") (every 3 rev $ sound "bd sn:2") -} interlace :: ControlPattern -> ControlPattern -> ControlPattern interlace a b = weave 16 (P.shape (sine * 0.9)) [a, b]@@ -245,9 +278,7 @@ {- | Just like `striate`, but also loops each sample chunk a number of times specified in the second argument. The primed version is just like `striateBy`, where the loop count is the third argument. For example: -@-d1 $ striateL' 3 0.125 4 $ sound "feel sn:2"-@+> d1 $ striateL' 3 0.125 4 $ sound "feel sn:2" Like `striate`, these use the `begin` and `end` parameters internally, as well as the `loop` parameter for these versions. -}@@ -267,6 +298,21 @@ -} +{-| @slice@ is similar to 'chop' and 'striate', in that it’s used to slice+ samples up into bits. The difference is that it allows you to rearrange those+ bits as a pattern.++ > d1 $ slice 8 "7 6 5 4 3 2 1 0"+ > $ sound "breaks165"+ > # legato 1++ The above slices the sample into eight bits, and then plays them backwards,+ equivalent of applying rev $ chop 8. Here’s a more complex example:++ > d1 $ slice 8 "[<0*8 0*2> 3*4 2 4] [4 .. 7]"+ > $ sound "breaks165"+ > # legato 1+-} slice :: Pattern Int -> Pattern Int -> ControlPattern -> ControlPattern slice pN pI p = P.begin b # P.end e # p where b = div' <$> pI <* pN@@ -279,6 +325,16 @@ # P.begin (pure $ fromIntegral i / fromIntegral n) # P.end (pure $ fromIntegral (i+1) / fromIntegral n) +{-|+ @randslice@ chops the sample into the given number of pieces and then plays back+ a random one each cycle:++ > d1 $ randslice 32 $ sound "bev"++ Use 'fast' to get more than one per cycle:++ > d1 $ fast 4 $ randslice 32 $ sound "bev"+-} randslice :: Pattern Int -> ControlPattern -> ControlPattern randslice = tParam $ \n p -> innerJoin $ (\i -> _slice n i p) <$> _irand n @@ -290,56 +346,80 @@ where d = sz / fromRational (wholeStop ev - wholeStart ev) sz = 1/fromIntegral bits +{-|+ @splice@ is similar to 'slice', but the slices are automatically pitched up or down+ to fit their ‘slot’.++ > d1 $ splice 8 "[<0*8 0*2> 3*4 2 4] [4 .. 7]" $ sound "breaks165"+-} splice :: Pattern Int -> Pattern Int -> ControlPattern -> Pattern (Map.Map String Value) splice bitpat ipat pat = innerJoin $ (\bits -> _splice bits ipat pat) <$> bitpat -{- |-`loopAt` makes a sample fit the given number of cycles. Internally, it-works by setting the `unit` parameter to "c", changing the playback-speed of the sample with the `speed` parameter, and setting setting-the `density` of the pattern to match.+{-|+ @loopAt@ makes a sample fit the given number of cycles. Internally, it+ works by setting the `unit` parameter to @"c"@, changing the playback+ speed of the sample with the `speed` parameter, and setting setting+ the `density` of the pattern to match. -@-d1 $ loopAt 4 $ sound "breaks125"-d1 $ juxBy 0.6 (|* speed "2") $ slowspread (loopAt) [4,6,2,3] $ chop 12 $ sound "fm:14"-@+ > d1 $ loopAt 4 $ sound "breaks125"++ It’s a good idea to use this in conjuction with 'chop', so the break is chopped+ into pieces and you don’t have to wait for the whole sample to start/stop.++ > d1 $ loopAt 4 $ chop 32 $ sound "breaks125"++ Like all Tidal functions, you can mess about with this considerably. The below+ example shows how you can supply a pattern of cycle counts to @loopAt@:++ > d1 $ juxBy 0.6 (|* speed "2")+ > $ slowspread (loopAt) [4,6,2,3]+ > $ chop 12+ > $ sound "fm:14" -} loopAt :: Pattern Time -> ControlPattern -> ControlPattern loopAt n p = slow n p |* P.speed (fromRational <$> (1/n)) # P.unit (pure "c") +{-|+ @hurry@ is similiar to 'fast' in that it speeds up a pattern, but it also+ increases the speed control by the same factor. So, if you’re triggering+ samples, the sound gets higher in pitch. For example:++ > d1 $ every 2 (hurry 2) $ sound "bd sn:2 ~ cp"+-} hurry :: Pattern Rational -> ControlPattern -> ControlPattern hurry !x = (|* P.speed (fromRational <$> x)) . fast x -{- | Smash is a combination of `spread` and `striate` - it cuts the samples+{- | @smash@ is a combination of `spread` and `striate` — it cuts the samples into the given number of bits, and then cuts between playing the loop-at different speeds according to the values in the list.--So this:+at different speeds according to the values in the list. So this: -@-d1 $ smash 3 [2,3,4] $ sound "ho ho:2 ho:3 hc"-@+> d1 $ smash 3 [2,3,4] $ sound "ho ho:2 ho:3 hc" -Is a bit like this:+is a bit like this: -@-d1 $ spread (slow) [2,3,4] $ striate 3 $ sound "ho ho:2 ho:3 hc"-@+> d1 $ spread (slow) [2,3,4] $ striate 3 $ sound "ho ho:2 ho:3 hc" This is quite dancehall: -@-d1 $ (spread' slow "1%4 2 1 3" $ spread (striate) [2,3,4,1] $ sound-"sn:2 sid:3 cp sid:4")- # speed "[1 2 1 1]/2"-@+> d1 $ ( spread' slow "1%4 2 1 3"+> $ spread (striate) [2,3,4,1]+> $ sound "sn:2 sid:3 cp sid:4"+> )+> # speed "[1 2 1 1]/2" -} smash :: Pattern Int -> [Pattern Time] -> ControlPattern -> Pattern ValueMap smash n xs p = slowcat $ map (`slow` p') xs where p' = striate n p -{- | an altenative form to `smash` is `smash'` which will use `chop` instead of `striate`.+{- | An altenative form of `smash`, which uses `chop` instead of `striate`.++ Compare the following variations:++ > d1 $ smash 6 [2,3,4] $ sound "ho ho:2 ho:3 hc"+ > d1 $ smash' 6 [2,3,4] $ sound "ho ho:2 ho:3 hc"+ > d1 $ smash 12 [2,3,4] $ s "bev*4"+ > d1 $ smash' 12 [2,3,4] $ s "bev*4" -} smash' :: Int -> [Pattern Time] -> ControlPattern -> ControlPattern smash' n xs p = slowcat $ map (`slow` p') xs@@ -347,19 +427,18 @@ {- | Applies a type of delay to a pattern.- It has three parameters, which could be called depth, time and feedback.+ It has three parameters, which could be called @depth@, @time@ and @feedback@.+ @depth@ is and integer, and @time@ and @feedback@ are floating point numbers. This adds a bit of echo:- @- d1 $ echo 4 0.2 0.5 $ sound "bd sn"- @ + > d1 $ echo 4 0.2 0.5 $ sound "bd sn"+ The above results in 4 echos, each one 50% quieter than the last, with 1/5th of a cycle between them. It is possible to reverse the echo:- @- d1 $ echo 4 (-0.2) 0.5 $ sound "bd sn"- @++ > d1 $ echo 4 (-0.2) 0.5 $ sound "bd sn" -} echo :: Pattern Integer -> Pattern Rational -> Pattern Double -> ControlPattern -> ControlPattern echo = tParam3 _echo@@ -368,13 +447,19 @@ _echo count time feedback p = _echoWith count time (|* P.gain (pure $ feedback)) p {- |- Allows to apply a function for each step and overlays the result delayed by the given time.+ @echoWith@ is similar to 'echo', but instead of just decreasing volume to+ produce echoes, @echoWith@ applies a function each step and overlays the+ result delayed by the given time. - @- d1 $ echoWith 2 "1%3" (# vowel "{a e i o u}%2") $ sound "bd sn"- @+ > d1 $ echoWith 2 "1%3" (# vowel "{a e i o u}%2") $ sound "bd sn" - In this case there are two _overlays_ delayed by 1/3 of a cycle, where each has the @vowel@ filter applied.+ In this case there are two _overlays_ delayed by 1/3 of a cycle, where each+ has the 'vowel' filter applied.++ > d1 $ echoWith 4 (1/6) (|* speed "1.5") $ sound "arpy arpy:2"++ In the above, three versions are put on top, with each step getting higher in+ pitch as @|* speed "1.5"@ is successively applied. -} echoWith :: Pattern Int -> Pattern Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a echoWith n t f p = innerJoin $ (\a b -> _echoWith a b f p) <$> n <* t@@ -422,22 +507,23 @@ -- | (Alias @__qt__@) Quantise trigger. Aligns the start of the pattern -- with the next cycle boundary. For example, this pattern will fade in -- starting with the next cycle after the pattern is evaluated:--- --- @--- d1 $ qtrigger $ s "hh(5, 8)" # amp envL--- @--- +--+-- > d1 $ qtrigger $ s "hh(5, 8)" # amp envL+-- -- Note that the pattern will start playing immediately. The /start/ of the -- pattern aligns with the next cycle boundary, but events will play before -- if the pattern has events at negative timestamps (which most loops do). -- These events can be filtered out, for example:--- --- @--- d1 $ qtrigger $ filterWhen (>= 0) $ s "hh(5, 8)"--- @+--+-- > d1 $ qtrigger $ filterWhen (>= 0) $ s "hh(5, 8)"+--+-- Alternatively, you can use 'wait' to achieve the same result:+--+-- > wait 1 1 $ s "bd hh hh hh" qtrigger :: Pattern a -> Pattern a qtrigger = ctrigger +-- | Alias for 'qtrigger'. qt :: Pattern a -> Pattern a qt = qtrigger @@ -456,20 +542,49 @@ ftrigger :: Pattern a -> Pattern a ftrigger = triggerWith $ (fromIntegral :: Int -> Rational) . floor --- | (Alias @__mt__@) Mod trigger. Aligns the start of a pattern to the--- next cycle boundary where the cycle is evenly divisible by a given--- number. 'qtrigger' is equivalent to @mtrigger 1@.+{- | (Alias @__mt__@) Mod trigger. Aligns the start of a pattern to the+ next cycle boundary where the cycle is evenly divisible by a given+ number. 'qtrigger' is equivalent to @mtrigger 1@.++ In the following example, when activating the @d1@ pattern, it will start at the+ same time as the next clap, even if it has to wait for 3 cycles. Once activated,+ the @arpy@ sound will play on every cycle, just like any other pattern:++ > do+ > resetCycles+ > d2 $ every 4 (# s "clap") $ s "bd"++ > d1 $ mtrigger 4 $ filterWhen (>=0) $ s "arpy"+-} mtrigger :: Int -> Pattern a -> Pattern a mtrigger n = triggerWith $ fromIntegral . nextMod where nextMod t = n * ceiling (t / (fromIntegral n)) +-- | Alias for 'mtrigger'. mt :: Int -> Pattern a -> Pattern a mt = mtrigger --- | This aligns the start of a pattern to some value relative to the--- time the pattern is evaluated. The provided function maps the evaluation--- time (on the global cycle clock) to a new time, and then @triggerWith@--- aligns the pattern's start to the time that's returned.+{- | This aligns the start of a pattern to some value relative to the+ time the pattern is evaluated. The provided function maps the evaluation+ time (on the global cycle clock) to a new time, and then @triggerWith@+ aligns the pattern's start to the time that's returned.++ This is a more flexible triggering function. In fact, all the other trigger+ functions are defined based on @triggerWith@. For example, 'trigger' is just+ @triggerWith id@.++ In the next example, use @d1@ as a metronome, and play with different values+ (from 0 to 1) on the @const@ expression. You’ll notice how the @clap@ is+ displaced from the beginning of each cycle to the end, as the number increases:++ > d1 $ s "bd hh!3"+ >+ > d2 $ triggerWith (const 0.1) $ s "clap"++ This last example is equivalent to this:++ > d2 $ rotR 0.1 $ s "clap"+-} triggerWith :: (Time -> Time) -> Pattern a -> Pattern a triggerWith f pat = pat {query = q} where q st = query (rotR (offset st) pat) st
src/Sound/Tidal/Core.hs view
@@ -29,7 +29,13 @@ -- ** Elemental patterns --- | Takes a function from time to values, and turns it into a 'Pattern'.+{-| Takes a function of time to values, and turns it into a 'Pattern'.+ Useful for creating continuous patterns such as 'sine' or 'perlin'.++ For example, 'saw' is defined as++ > saw = sig $ \t -> mod' (fromRational t) 1+-} sig :: (Time -> a) -> Pattern a sig f = Pattern q where q (State (Arc s e) _)@@ -50,13 +56,13 @@ -- | @cosine@ - unipolar cosine wave. A pattern of continuous values -- following a cosine with frequency of one cycle, and amplitude from--- 0 to 1. Equivalent to `0.25 ~> sine`.+-- 0 to 1. Equivalent to @0.25 ~> sine@. cosine :: Fractional a => Pattern a cosine = 0.25 `rotR` sine -- | @cosine2@ - bipolar cosine wave. A pattern of continuous values -- following a cosine with frequency of one cycle, and amplitude from--- -1 to 1. Equivalent to `0.25 ~> sine2`.+-- -1 to 1. Equivalent to @0.25 ~> sine2@. cosine2 :: Fractional a => Pattern a cosine2 = 0.25 `rotR` sine2 @@ -230,11 +236,21 @@ -- ** Constructing patterns --- | Turns a list of values into a pattern, playing one of them per cycle.+{-| Turns a list of values into a pattern, playing one of them per cycle.+ The following are equivalent:++ > d1 $ n (fromList [0, 1, 2]) # s "superpiano"+ > d1 $ n "<0 1 2>" # s "superpiano"+-} fromList :: [a] -> Pattern a fromList = cat . map pure --- | Turns a list of values into a pattern, playing all of them per cycle.+{-| Turns a list of values into a pattern, playing /all/ of them per cycle.+ The following are equivalent:++ > d1 $ n (fastFromList [0, 1, 2]) # s "superpiano"+ > d1 $ n "[0 1 2]" # s "superpiano"+-} fastFromList :: [a] -> Pattern a fastFromList = fastcat . map pure @@ -245,19 +261,32 @@ -- | 'fromMaybes; is similar to 'fromList', but allows values to -- be optional using the 'Maybe' type, so that 'Nothing' results in -- gaps in the pattern.+-- The following are equivalent:+-- > d1 $ n (fromMaybes [Just 0, Nothing, Just 2]) # s "superpiano"+-- > d1 $ n "0 ~ 2" # s "superpiano" fromMaybes :: [Maybe a] -> Pattern a fromMaybes = fastcat . map f where f Nothing = silence f (Just x) = pure x --- | A pattern of whole numbers from 0 to the given number, in a single cycle.+{-| A pattern of whole numbers from 0 to the given number, in a single cycle.+ Can be used used to @run@ through a folder of samples in order:++ > d1 $ n (run 8) # sound "amencutup"++ The first parameter to run can be given as a pattern:++ > d1 $ n (run "<4 8 4 6>") # sound "amencutup"+-} run :: (Enum a, Num a) => Pattern a -> Pattern a run = (>>= _run) _run :: (Enum a, Num a) => a -> Pattern a _run n = fastFromList [0 .. n-1] --- | From @1@ for the first cycle, successively adds a number until it gets up to @n@+-- | Similar to 'run', but starts from @1@ for the first cycle, successively+-- adds a number until it gets up to @n@.+-- > d1 $ n (scan 8) # sound "amencutup" scan :: (Enum a, Num a) => Pattern a -> Pattern a scan = (>>= _scan) @@ -267,11 +296,20 @@ -- ** Combining patterns -- | Alternate between cycles of the two given patterns+-- > d1 $ append (sound "bd*2 sn") (sound "arpy jvbass*2") append :: Pattern a -> Pattern a -> Pattern a append a b = cat [a,b] --- | Like 'append', but for a list of patterns. Interlaces them, playing the first cycle from each--- in turn, then the second cycle from each, and so on.+{- |+ Like 'append', but for a list of patterns. Interlaces them, playing the+ first cycle from each in turn, then the second cycle from each, and so on. It+ concatenates a list of patterns into a new pattern; each pattern in the list+ will maintain its original duration. For example:++ > d1 $ cat [sound "bd*2 sn", sound "arpy jvbass*2"]+ > d1 $ cat [sound "bd*2 sn", sound "arpy jvbass*2", sound "drum*2"]+ > d1 $ cat [sound "bd*2 sn", sound "jvbass*3", sound "drum*2", sound "ht mt"]+-} cat :: [Pattern a] -> Pattern a cat [] = silence cat ps = Pattern q@@ -296,14 +334,20 @@ slowappend = append -- | Like 'append', but twice as fast+-- > d1 $ fastAppend (sound "bd*2 sn") (sound "arpy jvbass*2") fastAppend :: Pattern a -> Pattern a -> Pattern a fastAppend a b = _fast 2 $ append a b fastappend :: Pattern a -> Pattern a -> Pattern a fastappend = fastAppend --- | The same as 'cat', but speeds up the result by the number of--- patterns there are, so the cycles from each are squashed to fit a--- single cycle.+{-| The same as 'cat', but speeds up the result by the number of+ patterns there are, so the cycles from each are squashed to fit a+ single cycle.++ > d1 $ fastcat [sound "bd*2 sn", sound "arpy jvbass*2"]+ > d1 $ fastcat [sound "bd*2 sn", sound "arpy jvbass*2", sound "drum*2"]+ > d1 $ fastcat [sound "bd*2 sn", sound "jvbass*3", sound "drum*2", sound "ht mt"]+-} fastCat :: [Pattern a] -> Pattern a fastCat ps = _fast (toTime $ length ps) $ cat ps @@ -311,7 +355,21 @@ fastcat :: [Pattern a] -> Pattern a fastcat = fastCat --- | Similar to @fastCat@, but each pattern is given a relative duration+{- | Similar to @fastCat@, but each pattern is given a relative duration.+ You provide proportionate sizes of the patterns to each other for when they’re+ concatenated into one cycle. The larger the value in the list, the larger+ relative size the pattern takes in the final loop. If all values are equal+ then this is equivalent to fastcat (e.g. the following two code fragments are+ equivalent).++ > d1 $ fastcat [s "bd*4", s "hh27*8", s "superpiano" # n 0]++ > d1 $ timeCat [ (1, s "bd*4")+ > , (1, s "hh27*8")+ > , (1, s "superpiano" # n 0)+ > ]++-} timeCat :: [(Time, Pattern a)] -> Pattern a timeCat tps = stack $ map (\(s,e,p) -> compressArc (Arc (s/total) (e/total)) p) $ arrange 0 tps where total = sum $ map fst tps@@ -323,13 +381,42 @@ timecat :: [(Time, Pattern a)] -> Pattern a timecat = timeCat --- | 'overlay' combines two 'Pattern's into a new pattern, so that--- their events are combined over time. +{- | @overlay@ combines two 'Pattern's into a new pattern, so that their events+are combined over time. For example, the following two lines are equivalent:++> d1 $ sound (overlay "bd sn:2" "cp*3")+> d1 $ sound "[bd sn:2, cp*3]"++@overlay@ is equal to '<>',++> (<>) :: Semigroup a => a -> a -> a++which can thus be used as an infix operator equivalent of 'overlay':++> d1 $ sound ("bd sn:2" <> "cp*3")+-} overlay :: Pattern a -> Pattern a -> Pattern a overlay = (<>) --- | 'stack' combines a list of 'Pattern's into a new pattern, so that--- their events are combined over time.+{- | 'stack' combines a list of 'Pattern's into a new pattern, so that their+events are combined over time, i.e., all of the patterns in the list are played+simultaneously.++> d1 $ stack [+> sound "bd bd*2",+> sound "hh*2 [sn cp] cp future*4",+> sound "arpy" +| n "0 .. 15"+> ]++This is particularly useful if you want to apply a function or synth control+pattern to multiple patterns at once:++> d1 $ whenmod 5 3 (striate 3) $ stack [+> sound "bd bd*2",+> sound "hh*2 [sn cp] cp future*4",+> sound "arpy" +| n "0 .. 15"+> ] # speed "[[1 0.8], [1.5 2]*2]/3"+-} stack :: [Pattern a] -> Pattern a stack = foldr overlay silence @@ -343,8 +430,28 @@ (~>) :: Pattern Time -> Pattern a -> Pattern a (~>) = tParam rotR --- | Slow down a pattern by the factors in the given time pattern, 'squeezing'--- the pattern to fit the slot given in the time pattern+{-| Slow down a pattern by the factors in the given time pattern, "squeezing"+ the pattern to fit the slot given in the time pattern. It is the slow analogue+ to 'fastSqueeze'.++ If the time pattern only has a single value in a cycle, @slowSqueeze@ becomes equivalent to slow. These are equivalent:++ > d1 $ slow "<2 4>" $ s "bd*8"+ > d1 $ slowSqueeze "<2 4>" $ s "bd*8"++ When the time pattern has multiple values, however, the behavior is a little+ different. Instead, a slowed version of the pattern will be made for each value+ in the time pattern, and they’re all combined together in a cycle according to+ the structure of the time pattern. For example, these are equivalent:++ > d1 $ slowSqueeze "2 4 8 16" $ s "bd*8"+ > d1 $ s "bd*4 bd*2 bd bd/2"++ as are these:++ > d1 $ slowSqueeze "2 4 [8 16]" $ s "bd*8"+ > d1 $ s "bd*4 bd*2 [bd bd/2]"+-} slowSqueeze :: Pattern Time -> Pattern a -> Pattern a slowSqueeze = tParamSqueeze _slow @@ -353,17 +460,18 @@ sparsity = slow {- | Plays a portion of a pattern, specified by a time arc (start and end time).-The new resulting pattern is played over the time period of the original pattern:+ The new resulting pattern is played over the time period of the original pattern. -@-d1 $ zoom (0.25, 0.75) $ sound "bd*2 hh*3 [sn bd]*2 drum"-@+ > d1 $ zoom (0.25, 0.75) $ sound "bd*2 hh*3 [sn bd]*2 drum" -In the pattern above, `zoom` is used with an arc from 25% to 75%. It is equivalent to this pattern:+ In the pattern above, @zoom@ is used with an arc from 25% to 75%. It is+ equivalent to: -@-d1 $ sound "hh*3 [sn bd]*2"-@+ > d1 $ sound "hh*3 [sn bd]*2"++ Here’s an example of it being used with a conditional:++ > d1 $ every 4 (zoom (0.25, 0.75)) $ sound "bd*2 hh*3 [sn bd]*2 drum" -} zoom :: (Time, Time) -> Pattern a -> Pattern a zoom (s,e) = zoomArc (Arc s e)@@ -373,10 +481,12 @@ withResultArc (mapCycle ((/d) . subtract s)) $ withQueryArc (mapCycle ((+s) . (*d))) p where d = e-s --- | @fastGap@ is similar to 'fast' but maintains its cyclic--- alignment. For example, @fastGap 2 p@ would squash the events in--- pattern @p@ into the first half of each cycle (and the second--- halves would be empty). The factor should be at least 1+{-| @fastGap@ is similar to 'fast' but maintains its cyclic alignment, i.e.,+ rather than playing the pattern multiple times, it instead leaves a gap in+ the remaining space of the cycle. For example, @fastGap 2 p@ would squash the+ events in pattern @p@ into the first half of each cycle (and the second halves+ would be empty). The factor should be at least 1.+-} fastGap :: Pattern Time -> Pattern a -> Pattern a fastGap = tParam _fastGap @@ -384,6 +494,24 @@ densityGap :: Pattern Time -> Pattern a -> Pattern a densityGap = fastGap +{-|+ @compress@ takes a pattern and squeezes it within the specified time span (i.e.+ the ‘arc’). The new resulting pattern is a sped up version of the original.++ > d1 $ compress (1/4, 3/4) $ s "[bd sn]!"++ In the above example, the pattern will play in an arc spanning from 25% to 75%+ of the duration of a cycle. It is equivalent to:++ > d1 $ s "~ [bd sn]! ~"++ Another example, where all events are different:++ > d1 $ compress (1/4, 3/4) $ n (run 4) # s "arpy"++ It differs from 'zoom' in that it preserves the original pattern but it speeds+ up its events so to match with the new time period.+-} compress :: (Time,Time) -> Pattern a -> Pattern a compress (s,e) = compressArc (Arc s e) @@ -403,8 +531,24 @@ -- | Functions which work on other functions (higher order functions) --- | @every n f p@ applies the function @f@ to @p@, but only affects--- every @n@ cycles.+{- | @every n f p@ applies the function @f@ to @p@, but only affects+ every @n@ cycles.++ It takes three inputs: how often the function should be applied (e.g. 3 to+ apply it every 3 cycles), the function to be applied, and the pattern you are+ applying it to. For example: to reverse a pattern every three cycles (and for+ the other two play it normally)++ > d1 $ every 3 rev $ n "0 1 [~ 2] 3" # sound "arpy"++ Note that if the function you’re applying requires additional parameters+ itself (such as fast 2 to make a pattern twice as fast), then you’ll need to+ wrap it in parenthesis, like so:++ > d1 $ every 3 (fast 2) $ n "0 1 [~ 2] 3" # sound "arpy"++ Otherwise, the every function will think it is being passed too many parameters.+-} every :: Pattern Int -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a every tp f p = innerJoin $ (\t -> _every t f p) <$> tp @@ -412,30 +556,55 @@ _every 0 _ p = p _every n f p = when ((== 0) . (`mod` n)) f p --- | @every n o f'@ is like @every n f@ with an offset of @o@ cycles+{-| @every' n o f p@ is like @every n f p@ but with an offset of @o@ cycles.++ For example, @every' 3 0 (fast 2)@ will speed up the cycle on cycles 0,3,6,…+ whereas @every' 3 1 (fast 2)@ will transform the pattern on cycles 1,4,7,….++ With this in mind, setting the second argument of @every'@ to 0 gives the+ equivalent every function. For example, every 3 is equivalent to every' 3 0.++ The @every@ functions can be used to silence a full cycle or part of a cycle+ by using silent or mask "~". Mask provides additional flexibility to turn on/off+ individual steps.++ > d1 $ every 3 silent $ n "2 9 11 2" # s "hh27"+ > d1 $ every 3 (mask "~") $ n "2 9 10 2" # s "hh27"+ > d1 $ every 3 (mask "0 0 0 0") $ n "2 9 11 2" # s "hh27"+-} every' :: Pattern Int -> Pattern Int -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a every' np op f p = do { n <- np; o <- op; _every' n o f p } _every' :: Int -> Int -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a _every' n o = when ((== o) . (`mod` n)) --- | @foldEvery ns f p@ applies the function @f@ to @p@, and is applied for--- each cycle in @ns@.+{- | @foldEvery ns f p@ applies the function @f@ to @p@, and is applied for+ each cycle in @ns@.++ It is similar to chaining multiple @every@ functions together. It transforms+ a pattern with a function, once per any of the given number of cycles. If a+ particular cycle is the start of more than one of the given cycle periods, then+ it it applied more than once.++ > d1 $ foldEvery [5,3] (|+ n 1) $ s "moog" # legato 1++ The first moog samples are tuned to C2, C3 and C4. Note how on cycles that are+ multiples of 3 or 5 the pitch is an octave higher, and on multiples of 15 the+ pitch is two octaves higher, as the transformation is applied twice.+-} foldEvery :: [Int] -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a foldEvery ns f p = foldr (`_every` f) p ns {-|-Only `when` the given test function returns `True` the given pattern-transformation is applied. The test function will be called with the-current cycle as a number.+The given pattern transformation is applied only @when@ the given test function+returns @True@. The test function will be called with the current cycle as+a number. -@-d1 $ when ((elem '4').show)- (striate 4)- $ sound "hh hc"-@+> d1 $ when (elem '4' . show)+> (striate 4)+> $ sound "hh hc" -The above will only apply `striate 4` to the pattern if the current+The above will only apply @striate 4@ to the pattern if the current cycle number contains the number 4. So the fourth cycle will be striated and the fourteenth and so on. Expect lots of striates after cycle number 399.@@ -445,7 +614,14 @@ where apply st | test (floor $ start $ arc st) = query (f p) st | otherwise = query p st --- | Like 'when', but works on continuous time values rather than cycle numbers.+{- | Like 'when', but works on continuous time values rather than cycle numbers.+ The following will apply @# speed 2@ only when the remainder of the current+ @Time@ divided by 2 is less than 0.5:++ > d1 $ whenT ((< 0.5) . (flip Data.Fixed.mod' 2))+ > (# speed 2)+ > $ sound "hh(4,8) hc(3,8)"+-} whenT :: (Time -> Bool) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a whenT test f p = splitQueries $ p {query = apply} where apply st | test (start $ arc st) = query (f p) st
src/Sound/Tidal/Params.hs view
@@ -31,7 +31,7 @@ import Data.Word (Word8) import Data.Fixed (mod') --- | group multiple params into one+-- | Group multiple params into one. grp :: [String -> ValueMap] -> Pattern String -> ControlPattern grp [] _ = empty grp fs p = splitby <$> p@@ -50,7 +50,7 @@ mS :: String -> String -> ValueMap mS name v = Map.singleton name (VS v) --- | Param makers+-- * Param makers pF :: String -> Pattern Double -> ControlPattern pF name = fmap (Map.singleton name . VF)@@ -119,7 +119,7 @@ pStateListS :: String -> String -> [String] -> ControlPattern pStateListS name sName = pStateList name sName . map VS --- | Grouped params+-- * Grouped params sound :: Pattern String -> ControlPattern sound = grp [mS "s", mF "n"]@@ -139,6 +139,13 @@ nrpnv :: Pattern Int -> ControlPattern nrpnv = pI "val" +{-| @grain'@ is a shortcut to join a @begin@ and @end@++ These are equivalent:++ > d1 $ slow 2 $ s "bev" # grain' "0.2:0.3" # legato 1+ > d1 $ slow 2 $ s "bev" # begin 0.2 # end 0.3 # legato 1+-} grain' :: Pattern String -> ControlPattern grain' = grp [mF "begin", mF "end"] @@ -212,11 +219,23 @@ drumN "os" = 87 drumN _ = 0 --- Generated params+-- * Generated params --- | a pattern of numbers that speed up (or slow down) samples while they play.+{- | A pattern of numbers that speed up (or slow down) samples while they play.++ In the following example, the sound starts at the original pitch and gets+ higher as it plays:++ > d1 $ s "arpy" # accelerate 2++ You can use a negative number to make the sound get lower. In this example, a+ different acceleration is applied to each played note using state values:++ > d1 $ arp "up" $ note "c'maj'4" # s "arpy" # accelerateTake "susan" [0.2,1,-1]+-} accelerate :: Pattern Double -> ControlPattern accelerate = pF "accelerate"+ accelerateTake :: String -> [Double] -> ControlPattern accelerateTake name xs = pStateListF "accelerate" name xs accelerateCount :: String -> ControlPattern@@ -227,7 +246,11 @@ acceleratebus :: Pattern Int -> Pattern Double -> ControlPattern acceleratebus _ _ = error $ "Control parameter 'accelerate' can't be sent to a bus." --- | like @gain@, but linear.+{-| Controls the amplitude (volume) of the sound. Like 'gain', but linear.+ Default value is 0.4.++ > d1 $ s "arpy" # amp "<0.4 0.8 0.2>"+-} amp :: Pattern Double -> ControlPattern amp = pF "amp" ampTake :: String -> [Double] -> ControlPattern@@ -295,7 +318,16 @@ bandqrecv :: Pattern Int -> ControlPattern bandqrecv busid = pI "^bandq" busid --- | a pattern of numbers from 0 to 1. Skips the beginning of each sample, e.g. `0.25` to cut off the first quarter from each sample.+{- | @begin@ receives a pattern of numbers from 0 to 1 and skips the beginning+of each sample by the indicated proportion. I.e., 0 would play the sample from+the start, 1 would skip the whole sample, and 0.25 would cut off the first+quarter.++In this example, the first 3 @ade@ samples are played on every cycle, but the+start point from which they are played changes on each cycle:++> d1 $ n "0 1 2" # s "ade" # begin "<0 0.25 0.5 0.75>" # legato 1+-} begin :: Pattern Double -> ControlPattern begin = pF "begin" beginTake :: String -> [Double] -> ControlPattern@@ -660,7 +692,13 @@ controlbus :: Pattern Int -> Pattern Double -> ControlPattern controlbus _ _ = error $ "Control parameter 'control' can't be sent to a bus." --- | +{-| A control pattern; 'setcps' is the standalone function.++ Patterns don’t (yet) have independent tempos though, if you change it on one+ pattern, it changes on all of them.++ > p "cpsfun" $ s "bd sd(3,8)" # cps (slow 8 $ 0.5 + saw)+-} cps :: Pattern Double -> ControlPattern cps = pF "cps" cpsTake :: String -> [Double] -> ControlPattern@@ -913,7 +951,14 @@ durrecv :: Pattern Int -> ControlPattern durrecv busid = pI "^dur" busid --- | the same as `begin`, but cuts the end off samples, shortening them; e.g. `0.75` to cut off the last quarter of each sample.+{- | Similar to `begin`, but cuts the end off samples, shortening them; e.g.+ 0.75 to cut off the last quarter of each sample.++ > d1 $ s "bev" >| begin 0.5 >| end "[0.65 0.55]"++ The example above will play the sample two times for cycle, but the second time+ will play a shorter segment than the first time, creating a kind of canon effect.+-} end :: Pattern Double -> ControlPattern end = pF "end" endTake :: String -> [Double] -> ControlPattern@@ -1098,7 +1143,24 @@ fshiftphaserecv :: Pattern Int -> ControlPattern fshiftphaserecv busid = pI "^fshiftphase" busid --- | a pattern of numbers that specify volume. Values less than 1 make the sound quieter. Values greater than 1 make the sound louder. For the linear equivalent, see @amp@.+{- | Used to control the amplitude (volume) of the sound. Values less than 1+make the sound quieter and values greater than 1 make the sound louder.++@gain@ uses a power function, so the volume change around 1 is subtle, but it+gets more noticeable as it increases or decreases. Typical values for @gain@ are+between 0 and 1.5.++For the linear equivalent, see 'amp'.++> d1 $ s "arpy" # gain 0.8++This plays the first arpy sample at a quieter level than the default.++> d1 $ s "ab*16" # gain (range 0.8 1.3 $ sine)++This plays a hihat sound, 16 times per cycle, with a @gain@ moving from 0.8 to 1.3+following a sine wave.+-} gain :: Pattern Double -> ControlPattern gain = pF "gain" gainTake :: String -> [Double] -> ControlPattern@@ -1630,6 +1692,21 @@ lsnarerecv :: Pattern Int -> ControlPattern lsnarerecv busid = pI "^lsnare" busid +-- | A pattern of numbers. Specifies whether the pitch of played samples should be tuned relative to their pitch metadata, if it exists. When set to 1, pitch metadata is applied. When set to 0, pitch metadata is ignored.+metatune :: Pattern Double -> ControlPattern+metatune = pF "metatune"+metatuneTake :: String -> [Double] -> ControlPattern+metatuneTake name xs = pStateListF "metatune" name xs+metatuneCount :: String -> ControlPattern+metatuneCount name = pStateF "metatune" name (maybe 0 (+1))+metatuneCountTo :: String -> Pattern Double -> Pattern ValueMap+metatuneCountTo name ipat = innerJoin $ (\i -> pStateF "metatune" name (maybe 0 ((`mod'` i) . (+1)))) <$> ipat++metatunebus :: Pattern Int -> Pattern Double -> ControlPattern+metatunebus busid pat = (pF "metatune" pat) # (pI "^metatune" busid)+metatunerecv :: Pattern Int -> ControlPattern+metatunerecv busid = pI "^metatune" busid+ -- | midibend :: Pattern Double -> ControlPattern midibend = pF "midibend"@@ -1862,7 +1939,7 @@ ophatdecayrecv :: Pattern Int -> ControlPattern ophatdecayrecv busid = pI "^ophatdecay" busid --- | a pattern of numbers. An `orbit` is a global parameter context for patterns. Patterns with the same orbit will share hardware output bus offset and global effects, e.g. reverb and delay. The maximum number of orbits is specified in the superdirt startup, numbers higher than maximum will wrap around.+-- | a pattern of numbers. An "orbit" is a global parameter context for patterns. Patterns with the same orbit will share hardware output bus offset and global effects, e.g. reverb and delay. The maximum number of orbits is specified in the superdirt startup, numbers higher than maximum will wrap around. orbit :: Pattern Int -> ControlPattern orbit = pI "orbit" orbitTake :: String -> [Double] -> ControlPattern@@ -2111,7 +2188,7 @@ progNumbus :: Pattern Int -> Pattern Double -> ControlPattern progNumbus _ _ = error $ "Control parameter 'progNum' can't be sent to a bus." --- | used in SuperDirt softsynths as a control rate or 'speed'+-- | used in SuperDirt softsynths as a control rate or "speed" rate :: Pattern Double -> ControlPattern rate = pF "rate" rateTake :: String -> [Double] -> ControlPattern@@ -2647,7 +2724,20 @@ songPtrbus :: Pattern Int -> Pattern Double -> ControlPattern songPtrbus _ _ = error $ "Control parameter 'songPtr' can't be sent to a bus." --- | a pattern of numbers which changes the speed of sample playback, i.e. a cheap way of changing pitch. Negative values will play the sample backwards!+{-|+ A pattern of numbers which changes the speed of sample playback which also+ changes pitch. Negative values will play the sample backwards.++ > d1 $ slow 5 $ s "sax:5" # legato 1 # speed 0.5++ This will play the @sax:5@ sample at half its rate. As a result, the sample will+ last twice the normal time, and will be pitched a whole octave lower. This is+ equivalent to @d1 $ slow 5 $ s "sax:5" # legato 1 |- note 12@.++ > d1 $ fast 2 $ s "breaks125:1" # cps (125/60/4) # speed (-2)++ In the above example, the break (which lasts for exactly one bar at 125 BPM), will be played backwards, and at double speed (so, we use @fast 2@ to fill the whole cycle).+-} speed :: Pattern Double -> ControlPattern speed = pF "speed" speedTake :: String -> [Double] -> ControlPattern@@ -2720,7 +2810,22 @@ stuttertimerecv :: Pattern Int -> ControlPattern stuttertimerecv busid = pI "^stuttertime" busid --- | +{-|+ A pattern of numbers that indicates the total duration of sample playback in seconds.++ This @sustain@ refers to the whole playback duration and is not to be confused with the sustain level of a typical ADSR envelope.++ > d1 $ fast 2 $ s "breaks125:1" # cps (120/60/4) # sustain 1++ At 120 BPM, a cycle lasts for two seconds. In the above example, we cut the+ sample so it plays just for one second, and repeat this part two times, so we+ fill the whole cycle. Note that sample pitch isn’t modified.++ > d1 $ s "breaks125:2!3" # cps (120/60/4) # sustain "0.4 0.2 0.4" # begin "0 0 0.4"++ Here, we take advantage that sustain receives a pattern to build a different+ break from the original sample.+-} sustain :: Pattern Double -> ControlPattern sustain = pF "sustain" sustainTake :: String -> [Double] -> ControlPattern@@ -2748,9 +2853,25 @@ sustainpedalrecv :: Pattern Int -> ControlPattern sustainpedalrecv busid = pI "^sustainpedal" busid --- | time stretch amount+{- |+ @timescale@ is the main function used to activate time-stretching, and usually+ the only one you need. It receives a single parameter which is the stretching+ rate to apply.++ You can use any positive number as the ratio, but the particular method used is+ designed for ratios greater than 1, and work reasonably well for values between+ 0.1 and 3.++ > d1 $ slow 2 $ s "breaks152" # legato 1 # timescale (152/130) # cps (130/60/4)++ In the example above, we set tempo at 130 beats per minute. But we want to play+ one of the @breaks152@ samples, which are, as indicated, at 152 BPM. So, the+ ratio we want is 152 over 130. This will slow down the sample to fit in our 130+ BPM tempo.+-} timescale :: Pattern Double -> ControlPattern timescale = pF "timescale"+ timescaleTake :: String -> [Double] -> ControlPattern timescaleTake name xs = pStateListF "timescale" name xs timescaleCount :: String -> ControlPattern@@ -2761,9 +2882,39 @@ timescalebus :: Pattern Int -> Pattern Double -> ControlPattern timescalebus _ _ = error $ "Control parameter 'timescale' can't be sent to a bus." --- | time stretch window size+{- | Time stretch window size.++The algorithm used to time-stretch a sample divides a sample in many little parts, modifies them, and puts them all together again. It uses one particular parameter, called @windowSize@, which is the length of each sample part.++The @windowSize@ value is automatically calculated, but can be changed with @timescalewin@. The @windowSize@ value is multiplied by the number provided.++@timescalewin@ can be used to improve the quality of time-stretching for some samples, or simply as an effect.++Consider the following two examples. In the first one, @timescalewin 0.01@ makes+the window size a lot smaller, and the extreme chopping of the sample causes+a rougher sound. In the second one, @timescalewin 10@ makes the chunks a lot+bigger. The method used overlaps the treated chunks when recomposing the sample,+and, with the bigger window size, this overlap is noticeable and causes a kind+of delay effect.++> d1 $ slow 2+> $ s "breaks152"+> # legato 1+> # timescale (152/130)+> # timescalewin 0.01+> # cps (130/60/4)++> d1 $ slow 2+> $ s "breaks152"+> # legato 1+> # timescale (152/130)+> # timescalewin 10+> # cps (130/60/4)++-} timescalewin :: Pattern Double -> ControlPattern timescalewin = pF "timescalewin"+ timescalewinTake :: String -> [Double] -> ControlPattern timescalewinTake name xs = pStateListF "timescalewin" name xs timescalewinCount :: String -> ControlPattern@@ -2887,7 +3038,21 @@ uidbus :: Pattern Int -> Pattern Double -> ControlPattern uidbus _ _ = error $ "Control parameter 'uid' can't be sent to a bus." --- | used in conjunction with `speed`, accepts values of "r" (rate, default behavior), "c" (cycles), or "s" (seconds). Using `unit "c"` means `speed` will be interpreted in units of cycles, e.g. `speed "1"` means samples will be stretched to fill a cycle. Using `unit "s"` means the playback speed will be adjusted so that the duration is the number of seconds specified by `speed`.+{- |+ Used in conjunction with `speed`. It accepts values of @r@ (rate, default+ behavior), @c@ (cycles), or @s@ (seconds). Using @unit "c"@ means `speed`+ will be interpreted in units of cycles, e.g. @speed "1"@ means samples will be+ stretched to fill a cycle. Using @unit "s"@ means the playback speed will be+ adjusted so that the duration is the number of seconds specified by `speed`.++ In the following example, @speed 2@ means that samples will be stretched to fill+ half a cycle:++ > d1 $ stack [+ > s "sax:5" # legato 1 # speed 2 # unit "c",+ > s "bd*2"+ > ]+-} unit :: Pattern String -> ControlPattern unit = pS "unit" unitTake :: String -> [Double] -> ControlPattern@@ -3010,7 +3175,7 @@ --- aliases+-- * Aliases voi :: Pattern Double -> ControlPattern voi = voice
src/Sound/Tidal/Pattern.hs view
@@ -74,40 +74,40 @@ v) $ cycleArcsInArc a - -- | In each of `a <*> b`, `a <* b` and `a *> b`+ -- | In each of @a <*> b@, @a <* b@ and @a *> b@ -- (using the definitions from this module, not the Prelude), -- the time structure of the result- -- depends on the structures of both `a` and `b`.- -- They all result in `Event`s with identical `part`s and `value`s.- -- However, their `whole`s are different.+ -- depends on the structures of both @a@ and @b@.+ -- They all result in @Event@s with identical @part@s and @value@s.+ -- However, their @whole@s are different. --- -- For instance, `listToPat [(+1), (+2)] <*> "0 10 100"`- -- gives the following 4-`Event` cycle:+ -- For instance, @listToPat [(+1), (+2)] <*> "0 10 100"@+ -- gives the following 4-@Event@ cycle: -- > (0>⅓)|1 -- > (⅓>½)|11 -- > (½>⅔)|12 -- > (⅔>1)|102- -- If we use `<*` instead, we get this:+ -- If we use @<*@ instead, we get this: -- > (0>⅓)-½|1 -- > 0-(⅓>½)|11 -- > (½>⅔)-1|12 -- > ½-(⅔>1)|102- -- And if we use `*>`, we get this:+ -- And if we use @*>@, we get this: -- > (0>⅓)|1 -- > (⅓>½)-⅔|11 -- > ⅓-(½>⅔)|12 -- > (⅔>1)|102 (<*>) = applyPatToPatBoth --- | Like <*>, but the 'wholes' come from the left+-- | Like @<*>@, but the "wholes" come from the left (<*) :: Pattern (a -> b) -> Pattern a -> Pattern b (<*) = applyPatToPatLeft --- | Like <*>, but the 'wholes' come from the right+-- | Like @<*>@, but the "wholes" come from the right (*>) :: Pattern (a -> b) -> Pattern a -> Pattern b (*>) = applyPatToPatRight --- | Like <*>, but the 'wholes' come from the left+-- | Like @<*>@, but the "wholes" come from the left (<<*) :: Pattern (a -> b) -> Pattern a -> Pattern b (<<*) = applyPatToPatSqueeze @@ -162,9 +162,11 @@ applyPatToPatSqueeze pf px = squeezeJoin $ (\f -> f <$> px) <$> pf -- * Monad and friends-+--+-- $monadAndFriends+-- -- Note there are four ways of joining - the default 'unwrap' used by @>>=@, as well--- as innerJoin, innerJoin and squeezeJoin.+-- as @innerJoin@, @innerJoin@ and @squeezeJoin@. instance Monad Pattern where return = pure@@ -504,12 +506,56 @@ focusArc (Arc s e) p = (cyclePos s) `rotR` (_fast (1/(e-s)) p) --- | Speed up a pattern by the given time pattern+{-| Speed up a pattern by the given time pattern.++For example, the following will play the sound pattern @"bd sn kurt"@ twice as+fast (i.e., so it repeats twice per cycle), and the vowel pattern three times+as fast:++> d1 $ sound (fast 2 "bd sn kurt")+> # fast 3 (vowel "a e o")++The first parameter can be patterned to, for example, play the pattern at twice+the speed for the first half of each cycle and then four times the speed for the+second half:++> d1 $ fast "2 4" $ sound "bd sn kurt cp"+-} fast :: Pattern Time -> Pattern a -> Pattern a fast = tParam _fast --- | Slow down a pattern by the factors in the given time pattern, 'squeezing'--- the pattern to fit the slot given in the time pattern+{-| @fastSqueeze@ speeds up a pattern by a time pattern given as input,+ squeezing the resulting pattern inside one cycle and playing the original+ pattern at every repetition.++ To better understand how it works, compare it with 'fast':++ >>> print $ fast "1 2" $ s "bd sn"+ (0>½)|s: "bd"+ (½>¾)|s: "bd"+ (¾>1)|s: "sn"++ This will give @bd@ played in the first half cycle, and @bd sn@ in the second+ half. On the other hand, using fastSqueeze;++ >>> print $ fastSqueeze "1 2" $ s "bd sn"+ (0>¼)|s: "bd"+ (¼>½)|s: "sn"+ (½>⅝)|s: "bd"+ (⅝>¾)|s: "sn"+ (¾>⅞)|s: "bd"+ (⅞>1)|s: "sn"++ The original pattern will play in the first half, and two repetitions of the+ original pattern will play in the second half. That is, every repetition+ contains the whole pattern.++ If the time pattern has a single value, it becomes equivalent to 'fast':++ > d1 $ fastSqueeze 2 $ s "bd sn"+ > d1 $ fast 2 $ s "bd sn"+ > d1 $ s "[bd sn]*2"+-} fastSqueeze :: Pattern Time -> Pattern a -> Pattern a fastSqueeze = tParamSqueeze _fast @@ -522,7 +568,15 @@ | rate < 0 = rev $ _fast (negate rate) pat | otherwise = withResultTime (/ rate) $ withQueryTime (* rate) pat --- | Slow down a pattern by the given time pattern+{-| Slow down a pattern by the given time pattern.++ For example, the following will play the sound pattern @"bd sn kurt"@ twice as+ slow (i.e., so it repeats once every two cycles), and the vowel pattern three+ times as slow:++ > d1 $ sound (slow 2 "bd sn kurt")+ > # slow 3 (vowel "a e o")+-} slow :: Pattern Time -> Pattern a -> Pattern a slow = tParam _slow _slow :: Time -> Pattern a -> Pattern a@@ -542,16 +596,47 @@ 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+{-| Shifts a pattern back in time by the given amount, expressed in cycles.++ This will skip to the fourth cycle:++ > do+ > resetCycles+ > d1 $ rotL 4 $ seqP+ > [ (0, 12, sound "bd bd*2")+ > , (4, 12, sound "hh*2 [sn cp] cp future*4")+ > , (8, 12, sound (samples "arpy*8" (run 16)))+ > ]++ Useful when building and testing out longer sequences.+-} 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+{-| Shifts a pattern forward in time by the given amount, expressed in cycles.+ Opposite of 'rotL'.+-} rotR :: Time -> Pattern a -> Pattern a rotR t = rotL (negate t) --- | @rev p@ returns @p@ with the event positions in each cycle--- reversed (or mirrored).+{- | @rev p@ returns @p@ with the event positions in each cycle reversed (or+ mirrored).++ For example rev @"1 [~ 2] ~ 3"@ is equivalent to rev @"3 ~ [2 ~] 1"@.++ Note that @rev@ reverses on a cycle-by-cycle basis. This means that @rev (slow+ 2 "1 2 3 4")@ would actually result in @(slow 2 "2 1 4 3")@. This is because the+ @slow 2@ makes the repeating pattern last two cycles, each of which is reversed+ independently.++ In practice rev is generally used with conditionals, for example with every:++ > d1 $ every 3 rev $ n "0 1 [~ 2] 3" # sound "arpy"++ or 'jux':++ > d1 $ jux rev $ n (iter 4 "0 1 [~ 2] 3") # sound "arpy"+-} rev :: Pattern a -> Pattern a rev p = splitQueries $ p {
src/Sound/Tidal/Safe/Boot.hs view
@@ -42,8 +42,50 @@ asap = once nudgeAll = streamNudgeAll all = streamAll++{-|+ Resets the cycle count back to 0.+ Useful to make sure a pattern or set of patterns start from the beginning:++ > do+ > resetCycles+ > d1 $ s "bd hh hh hh"+ > d2 $ s "ade" # cut 1++ Cycle count affects all patterns, so if there are any active, all of them will immediately jump to the beginning.+ @resetCycles@ is also userful in multi-user Tidal.++ Also see 'setCycle', 'getnow'.+-} resetCycles = streamResetCycles++{-|+ Adjusts the number of cycles per second, i.e., tempo.+ Accepts integers, decimals, and fractions.++ The default number of cycles per second is 0.5625, equivalent to 135\/60\/4, i.e.,+ 135 beats per minute if there are 4 beats per cycle.++ Representing cycles per second using fractions has the advantage of being more+ human-readable and more closely aligned with how tempo is commonly represented+ in music as beats per minute (bpm). For example, techno has a typical range of+ 120-140 bpm and house has a range of 115-130 bpm. To set the tempo in Tidal to+ fast house, e.g.,: @setcps (130\/60\/4)@.++ The following sound the same:++ > setcps (130/60/4)+ > d1 $ n "1" # s "kick kick kick kick"++ and++ > setcps (130/60/1)+ > d1 $ n "1" # s "kick"+-} setcps = asap . cps++-- * Transitions+ xfade i = transition True (Sound.Tidal.Transition.xfadeIn 4) i xfadeIn i t = transition True (Sound.Tidal.Transition.xfadeIn t) i histpan i t = transition True (Sound.Tidal.Transition.histpan t) i
src/Sound/Tidal/Scales.hs view
@@ -23,21 +23,24 @@ import Sound.Tidal.Pattern import Sound.Tidal.Utils --- five notes scales+-- * Scale definitions++-- ** Five notes scales minPent :: Fractional a => [a] minPent = [0,3,5,7,10] majPent :: Fractional a => [a] majPent = [0,2,4,7,9] --- another mode of major pentatonic+-- | Another mode of major pentatonic ritusen :: Fractional a => [a] ritusen = [0,2,5,7,9] --- another mode of major pentatonic+-- | Another mode of major pentatonic egyptian :: Fractional a => [a] egyptian = [0,2,5,7,10] ---+-- *** Other scales+ kumai :: Fractional a => [a] kumai = [0,2,3,7,9] hirajoshi :: Fractional a => [a]@@ -51,13 +54,14 @@ pelog :: Fractional a => [a] pelog = [0,1,3,7,8] ---+-- *** More scales+ prometheus :: Fractional a => [a] prometheus = [0,2,4,6,11] scriabin :: Fractional a => [a] scriabin = [0,1,4,7,9] --- han chinese pentatonic scales+-- *** Han Chinese pentatonic scales gong :: Fractional a => [a] gong = [0,2,4,7,9] shang :: Fractional a => [a]@@ -69,7 +73,7 @@ yu :: Fractional a => [a] yu = [0,3,5,7,10] --- 6 note scales+-- ** 6 note scales whole' :: Fractional a => [a] whole' = [0,2,4,6,8,10] augmented :: Fractional a => [a]@@ -77,7 +81,7 @@ augmented2 :: Fractional a => [a] augmented2 = [0,1,4,5,8,9] --- hexatonic modes with no tritone+-- *** Hexatonic modes with no tritone hexMajor7 :: Fractional a => [a] hexMajor7 = [0,2,4,7,9,11] hexDorian :: Fractional a => [a]@@ -91,7 +95,7 @@ hexAeolian :: Fractional a => [a] hexAeolian = [0,3,5,7,8,10] --- 7 note scales+-- ** 7 note scales major :: Fractional a => [a] major = [0,2,4,5,7,9,11] ionian :: Fractional a => [a]@@ -125,7 +129,7 @@ hindu :: Fractional a => [a] hindu = melodicMajor --- raga modes+-- *** Raga modes todi :: Fractional a => [a] todi = [0,1,3,6,7,8,11] purvi :: Fractional a => [a]@@ -137,7 +141,7 @@ ahirbhairav :: Fractional a => [a] ahirbhairav = [0,1,4,5,7,9,10] ---+-- *** More modes superLocrian :: Fractional a => [a] superLocrian = [0,1,3,4,6,8,10] romanianMinor :: Fractional a => [a]@@ -151,7 +155,7 @@ spanish :: Fractional a => [a] spanish = [0,1,4,5,7,8,10] --- modes of whole tones with added note ->+-- *** Modes of whole tones with added note -> leadingWhole :: Fractional a => [a] leadingWhole = [0,2,4,6,8,10,11] lydianMinor :: Fractional a => [a]@@ -161,13 +165,13 @@ locrianMajor :: Fractional a => [a] locrianMajor = [0,2,4,5,6,8,10] --- 8 note scales+-- ** 8 note scales diminished :: Fractional a => [a] diminished = [0,1,3,4,6,7,9,10] diminished2 :: Fractional a => [a] diminished2 = [0,2,3,5,6,8,9,11] --- modes of limited transposition+-- ** Modes of limited transposition messiaen1 :: Fractional a => [a] messiaen1 = whole' messiaen2 :: Fractional a => [a]@@ -183,7 +187,7 @@ messiaen7 :: Fractional a => [a] messiaen7 = [0, 1, 2, 3, 5, 6, 7, 8, 9, 11] --- Arabic maqams taken from SuperCollider's Scale.sc+-- ** Arabic maqams taken from SuperCollider's Scale.sc bayati :: Fractional a => [a] bayati = [0, 1.5, 3, 5, 7, 8, 10] hijaz :: Fractional a => [a]@@ -197,22 +201,81 @@ saba :: Fractional a => [a] saba = [0, 1.5, 3, 4, 6, 8, 10] --- 12 note scales+-- ** 12 note scales chromatic :: Fractional a => [a] chromatic = [0,1,2,3,4,5,6,7,8,9,10,11] +{-|+ Interprets a pattern of note numbers into a particular named scale. For example:++ > d1+ > $ jux rev+ > $ chunk 4 (fast 2 . (|- n 12))+ > $ off 0.25 (|+ 7)+ > $ struct (iter 4 "t(5,8)")+ > $ n (scale "ritusen" "0 .. 7")+ > # sound "superpiano"+-} scale :: Fractional a => Pattern String -> Pattern Int -> Pattern a scale = getScale scaleTable +{-|+ Build a scale function, with additional scales if you wish. For example:++ > let myscale =+ > getScale+ > ( scaleTable +++ > [ ("techno", [0,2,3,5,7,8,10])+ > , ("broken", [0,1,4,7,8,10])+ > ]+ > )++ The above takes the standard 'scaleTable' as a starting point and adds two custom scales to it. You’ll be able to use the new function in place of the normal one:++ > d1 $ n (myscale "techno" "0 1 2 3 4 5 6 7") # sound "superpiano"+-} getScale :: Fractional a => [(String, [a])] -> Pattern String -> Pattern Int -> Pattern a getScale table sp p = (\n scaleName -> noteInScale (fromMaybe [0] $ lookup scaleName table) n) <$> p <* sp where octave s x = x `div` length s noteInScale s x = (s !!! x) + fromIntegral (12 * octave s x) +{-|+ Outputs this list of all the available scales:++@+minPent majPent ritusen egyptian kumai hirajoshi iwato chinese indian pelog+prometheus scriabin gong shang jiao zhi yu whole wholetone augmented augmented2+hexMajor7 hexDorian hexPhrygian hexSus hexMajor6 hexAeolian major ionian dorian+phrygian lydian mixolydian aeolian minor locrian harmonicMinor harmonicMajor+melodicMinor melodicMinorDesc melodicMajor bartok hindu todi purvi marva bhairav+ahirbhairav superLocrian romanianMinor hungarianMinor neapolitanMinor enigmatic+spanish leadingWhole lydianMinor neapolitanMajor locrianMajor diminished+octatonic diminished2 octatonic2 messiaen1 messiaen2 messiaen3 messiaen4+messiaen5 messiaen6 messiaen7 chromatic bayati hijaz sikah rast saba iraq+@+-} scaleList :: String scaleList = unwords $ map fst (scaleTable :: [(String, [Rational])]) +{-|+ Outputs a list of all available scales and their corresponding notes. For+ example, its first entry is @("minPent",[0,3,5,7,10]@) which means that+ a minor pentatonic scale is formed by the root (0), the minor third (3 semitones+ above the root), the perfect fourth (5 semitones above the root), etc.++ As the list is big, you can use the Haskell function lookup to look up a+ specific scale: @lookup "phrygian" scaleTable@. This will output+ @Just [0.0,1.0,3.0,5.0,7.0,8.0,10.0]@.++ You can also do a reverse lookup into the scale table. For example:++ > filter ( \(_, x) -> take 3 x == [0,2,4] ) scaleTable++ The above example will output all scales of which the first three notes are+ the root, the major second (2 semitones above the fundamental), and the major+ third (4 semitones above the root).+-} scaleTable :: Fractional a => [(String, [a])] scaleTable = [("minPent", minPent), ("majPent", majPent),
src/Sound/Tidal/Stream.hs view
@@ -200,7 +200,7 @@ -- Spawns a thread within Tempo that acts as the clock -- Spawns a thread that listens to and acts on OSC control messages startStream :: Config -> [(Target, [OSC])] -> IO Stream-startStream config oscmap +startStream config oscmap = do sMapMV <- newMVar Map.empty pMapMV <- newMVar Map.empty bussesMV <- newMVar []@@ -219,7 +219,7 @@ u <- O.udp_socket (\sock sockaddr -> do N.setSocketOption sock N.Broadcast broadcast N.connect sock sockaddr ) (oAddress target) (oPort target)- return $ Cx {cxUDP = u, cxAddr = remote_addr, cxBusAddr = remote_bus_addr, cxTarget = target, cxOSCs = os} + return $ Cx {cxUDP = u, cxAddr = remote_addr, cxBusAddr = remote_bus_addr, cxTarget = target, cxOSCs = os} ) oscmap let bpm = (coerce defaultCps) * 60 * (cBeatsPerCycle config) abletonLink <- Link.create bpm@@ -249,7 +249,7 @@ sendHandshakes :: Stream -> IO () sendHandshakes stream = mapM_ sendHandshake $ filter (oHandshake . cxTarget) (sCxs stream) where sendHandshake cx = if (isJust $ sListen stream)- then + then do -- send it _from_ the udp socket we're listening to, so the -- replies go back there sendO False (sListen stream) cx $ O.Message "/dirt/handshake" []@@ -290,7 +290,7 @@ toDatum (VB False) = O.int32 (0 :: Int) toDatum (VX xs) = O.Blob $ O.blob_pack xs toDatum _ = error "toDatum: unhandled value"- + toData :: OSC -> Event ValueMap -> Maybe [O.Datum] toData (OSC {args = ArgList as}) e = fmap (fmap (toDatum)) $ sequence $ map (\(n,v) -> Map.lookup n (value e) <|> v) as toData (OSC {args = Named rqrd}) e@@ -362,7 +362,7 @@ -- If there is already cps in the event, the union will preserve that. let extra = Map.fromList [("cps", (VF (coerce $! peCps pe))), ("delta", VF (T.addMicrosToOsc (peDelta pe) 0)),- ("cycle", VF (fromRational (peCycle pe))) + ("cycle", VF (fromRational (peCycle pe))) ] addExtra = Map.union playmap' extra ts = (peOnWholeOrPartOsc pe) + nudge -- + latency@@ -399,8 +399,6 @@ ident = fromMaybe "unknown" $ Map.lookup "_id_" (value $ peEvent pe) >>= getS ts = (peOnWholeOrPartOsc pe) + nudge -- + latency -patternTimeID :: String-patternTimeID = "_t_pattern" -- Used for Tempo callback updatePattern :: Stream -> ID -> Time -> ControlPattern -> IO ()@@ -431,7 +429,7 @@ onPart <- (T.timeAtBeat ops) partStartBeat when (eventHasOnset e) (do let cps' = Map.lookup "cps" (value e) >>= getF- maybe (return ()) (\newCps -> (T.setTempo ops) ((T.cyclesToBeat ops) (newCps * 60)) on) $ coerce cps' + maybe (return ()) (\newCps -> (T.setTempo ops) ((T.cyclesToBeat ops) (newCps * 60)) on) $ coerce cps' ) off <- (T.timeAtBeat ops) offBeat bpm <- (T.getTempo ops)@@ -491,7 +489,7 @@ -- If an exception occurs during sending, -- this functions prints a warning and continues, because -- the likely reason is that the backend (supercollider) isn't running.--- +-- -- If any exception occurs before or outside sending -- (e.g., while querying the pattern, while computing a message), -- this function prints a warning and resets the current pattern@@ -691,7 +689,7 @@ -- Only report the first time.. when (null prev) $ verbose c $ "Connected to SuperDirt." return ()- where + where bufferIndices [] = [] bufferIndices (x:xs') | x == (O.AsciiString $ O.ascii "&controlBusIndices") = catMaybes $ takeWhile isJust $ map O.datum_integral xs' | otherwise = bufferIndices xs'@@ -745,6 +743,7 @@ let config = sConfig s ss <- Link.createAndCaptureAppSessionState (sLink s) bpm <- Link.getTempo ss+ Link.destroySessionState ss return $! coerce $ bpm / (cBeatsPerCycle config) / 60 streamGetnow :: Stream -> IO Double@@ -753,4 +752,16 @@ ss <- Link.createAndCaptureAppSessionState (sLink s) now <- Link.clock (sLink s) beat <- Link.beatAtTime ss now (cQuantum config)+ Link.destroySessionState ss return $! coerce $ beat / (cBeatsPerCycle config)++getProcessAhead :: Stream -> Link.Micros+getProcessAhead str = round $ (cProcessAhead $ sConfig str) * 100000++streamGetAhead :: Stream -> IO Double+streamGetAhead str = do+ ss <- Link.createAndCaptureAppSessionState (sLink str)+ now <- Link.clock (sLink str)+ beat <- Link.beatAtTime ss (now + (getProcessAhead str)) (cQuantum $! sConfig str)+ Link.destroySessionState ss+ return $ coerce $! beat / (cBeatsPerCycle $! sConfig str)
src/Sound/Tidal/StreamTypes.hs view
@@ -19,3 +19,6 @@ tickNudge :: Double } deriving Show++patternTimeID :: String+patternTimeID = "_t_pattern"
src/Sound/Tidal/Tempo.hs view
@@ -76,6 +76,12 @@ cyclesToBeat :: CDouble -> CDouble } +{-|+ Start cycles from the given cycle number.++ > setCycle 5+ > d1 $ n "6 2 0 8" # s "east"+-} setCycle :: P.Time -> MVar [TempoAction] -> IO () setCycle cyc actionsMV = modifyMVar_ actionsMV (\actions -> return $ SetCycle cyc : actions)
src/Sound/Tidal/Time.hs view
@@ -36,7 +36,7 @@ recip = fmap recip fromRational = pure . fromRational --- Utility functions - Time+-- * Utility functions - Time -- | The @sam@ (start of cycle) for the given time value. -- Cycles have duration 1, so every integer Time value divides two cycles.@@ -59,7 +59,7 @@ cyclePos :: Time -> Time cyclePos t = t - sam t --- Utility functions - Arc+-- * Utility functions - Arc -- | convex hull union hull :: Arc -> Arc -> Arc@@ -109,9 +109,9 @@ -- Thus, for instance, @cyclesInArc (Arc 0 1.5) == [0,1]@.) -- -- Edge cases:--- > cyclesInArc $ Arc 0 1.0001 == [0,1]--- > cyclesInArc $ Arc 0 1 == [0] -- the endpoint is excluded--- > cyclesInArc $ Arc 1 1 == [1] -- unless the Arc has duration 0+-- > cyclesInArc $ Arc 0 1.0001 == [0,1]+-- > cyclesInArc $ Arc 0 1 == [0] -- the endpoint is excluded+-- > cyclesInArc $ Arc 1 1 == [1] -- unless the Arc has duration 0 -- -- PITFALL: Don't be fooled by the name. The output cycles -- are not necessarily completely contained in the input @Arc@,
src/Sound/Tidal/UI.hs view
@@ -64,2236 +64,2833 @@ This is an efficient algorithm suitable for use in tight loops and used to implement the below functions, which are used to implement 'rand'. -See George Marsaglia (2003). ["Xorshift RNGs"](@https://www.jstatsoft.org/article/view/v008i14@),-in Journal of Statistical Software, pages 8–14.---}-xorwise :: Int -> Int-xorwise x =- let a = xor (shiftL x 13) x- b = xor (shiftR a 17) a- in xor (shiftL b 5) b---- stretch 300 cycles over the range of [0,2**29 == 536870912) then apply the xorshift algorithm-timeToIntSeed :: RealFrac a => a -> Int-timeToIntSeed = xorwise . truncate . (* 536870912) . snd . (properFraction :: (RealFrac a => a -> (Int,a))) . (/ 300)--intSeedToRand :: Fractional a => Int -> a-intSeedToRand = (/ 536870912) . realToFrac . (`mod` 536870912)--timeToRand :: (RealFrac a, Fractional b) => a -> b-timeToRand = intSeedToRand . timeToIntSeed--timeToRands :: (RealFrac a, Fractional b) => a -> Int -> [b]-timeToRands t n = timeToRands' (timeToIntSeed t) n--timeToRands' :: Fractional a => Int -> Int -> [a]-timeToRands' seed n- | n <= 0 = []- | otherwise = (intSeedToRand seed) : (timeToRands' (xorwise seed) (n-1))--{-|--`rand` generates a continuous pattern of (pseudo-)random numbers between @0@ and @1@.--@-sound "bd*8" # pan rand-@--pans bass drums randomly, and--@-sound "sn sn ~ sn" # gain rand-@--makes the snares randomly loud and quiet.--Numbers coming from this pattern are \'seeded\' by time. So if you reset time-(using 'resetCycles', 'setCycle', or 'cps') the random pattern will emit the-exact same _random_ numbers again.--In cases where you need two different random patterns, you can shift-one of them around to change the time from which the _random_ pattern-is read, note the difference:--@-jux (# gain rand) $ sound "sn sn ~ sn" # gain rand-@--and with the juxed version shifted backwards for 1024 cycles:--@-jux (# ((1024 <~) $ gain rand)) $ sound "sn sn ~ sn" # gain rand-@--}-rand :: Fractional a => Pattern a-rand = Pattern (\(State a@(Arc s e) _) -> [Event (Context []) Nothing a (realToFrac $ (timeToRand ((e + s)/2) :: Double))])---- | Boolean rand - a continuous stream of true\/false values, with a 50\/50 chance.-brand :: Pattern Bool-brand = _brandBy 0.5---- | Boolean rand with probability as input, e.g. @brandBy 0.25@ produces trues 25% of the time.-brandBy :: Pattern Double -> Pattern Bool-brandBy probpat = innerJoin $ (\prob -> _brandBy prob) <$> probpat--_brandBy :: Double -> Pattern Bool-_brandBy prob = fmap (< prob) rand--{- | Just like `rand` but for whole numbers, @irand n@ generates a pattern of (pseudo-) random whole numbers between @0@ to @n-1@ inclusive. Notably used to pick a random-samples from a folder:--@-d1 $ segment 4 $ n (irand 5) # sound "drum"-@--}-irand :: Num a => Pattern Int -> Pattern a-irand = (>>= _irand)--_irand :: Num a => Int -> Pattern a-_irand i = fromIntegral . (floor :: Double -> Int) . (* fromIntegral i) <$> rand--{- | 1D Perlin (smooth) noise, works like rand but smoothly moves between random-values each cycle. `perlinWith` takes a pattern as the RNG's "input" instead-of automatically using the cycle count.-@-d1 $ s "arpy*32" # cutoff (perlinWith (saw * 4) * 2000)-@-will generate a smooth random pattern for the cutoff frequency which will-repeat every cycle (because the saw does)-The `perlin` function uses the cycle count as input and can be used much like @rand@.--}-perlinWith :: Fractional a => Pattern Double -> Pattern a-perlinWith p = fmap realToFrac $ (interp) <$> (p-pa) <*> (timeToRand <$> pa) <*> (timeToRand <$> pb) where- pa = (fromIntegral :: Int -> Double) . floor <$> p- pb = (fromIntegral :: Int -> Double) . (+1) . floor <$> p- interp x a b = a + smootherStep x * (b-a)- smootherStep x = 6.0 * x**5 - 15.0 * x**4 + 10.0 * x**3---- | As 'perlin' with a suitable choice of input pattern (@'sig' 'fromRational'@).-perlin :: Fractional a => Pattern a-perlin = perlinWith (sig fromRational)--{-| `perlin2With` is Perlin noise with a 2-dimensional input. This can be-useful for more control over how the randomness repeats (or doesn't).--@-d1- $ s "[supersaw:-12*32]"- # lpf (rangex 60 5000 $ perlin2With (cosine*2) (sine*2))- # lpq 0.3-@-will generate a smooth random cutoff pattern that repeats every cycle without-any reversals or discontinuities (because the 2D path is a circle).-`perlin2` only needs one input because it uses the cycle count as the-second input.--}-perlin2With :: Pattern Double -> Pattern Double -> Pattern Double-perlin2With x y = (/2) . (+1) $ interp2 <$> xfrac <*> yfrac <*> dota <*> dotb <*> dotc <*> dotd where- fl = fmap ((fromIntegral :: Int -> Double) . floor)- ce = fmap ((fromIntegral :: Int -> Double) . (+1) . floor)- xfrac = x - fl x- yfrac = y - fl y- randAngle a b = 2 * pi * timeToRand (a + 0.0001 * b)- pcos x' y' = cos $ randAngle <$> x' <*> y'- psin x' y' = sin $ randAngle <$> x' <*> y'- dota = pcos (fl x) (fl y) * xfrac + psin (fl x) (fl y) * yfrac- dotb = pcos (ce x) (fl y) * (xfrac - 1) + psin (ce x) (fl y) * yfrac- dotc = pcos (fl x) (ce y) * xfrac + psin (fl x) (ce y) * (yfrac - 1)- dotd = pcos (ce x) (ce y) * (xfrac - 1) + psin (ce x) (ce y) * (yfrac - 1)- interp2 x' y' a b c d = (1.0 - s x') * (1.0 - s y') * a + s x' * (1.0 - s y') * b- + (1.0 - s x') * s y' * c + s x' * s y' * d- s x' = 6.0 * x'**5 - 15.0 * x'**4 + 10.0 * x'**3---- | As 'perlin2' with a suitable choice of input pattern (@'sig' 'fromRational'@).-perlin2 :: Pattern Double -> Pattern Double-perlin2 = perlin2With (sig fromRational)--{- | Randomly picks an element from the given list--@-sound "superpiano(3,8)" # note (choose ["a", "e", "g", "c"])-@--plays a melody randomly choosing one of the four notes \"a\", \"e\", \"g\", \"c\".--}-choose :: [a] -> Pattern a-choose = chooseBy rand---{- | Given a pattern of doubles, 'chooseBy' normalizes them so that each-corresponds to an index in the provided list. The returned pattern-contains the corresponding elements in the list.--@'choose' = chooseBy 'rand'@--}-chooseBy :: Pattern Double -> [a] -> Pattern a-chooseBy _ [] = silence-chooseBy f xs = (xs !!!) . floor <$> range 0 (fromIntegral $ length xs) f--{- | Like @choose@, but works on an a list of tuples of values and weights--@-sound "superpiano(3,8)" # note (wchoose [("a",1), ("e",0.5), ("g",2), ("c",1)])-@--In the above example, the "a" and "c" notes are twice as likely to-play as the "e" note, and half as likely to play as the "g" note.---}-wchoose :: [(a,Double)] -> Pattern a-wchoose = wchooseBy rand--{- | Given a pattern of probabilities and an list of @(value, weight)@ pairs,-'wchooseBy' creates a @'Pattern' value@ by choosing values based on those-probabilities and, weighted appropriately by the weights in the list of pairs.--@'wchoose' = wchooseBy 'rand'@---}-wchooseBy :: Pattern Double -> [(a,Double)] -> Pattern a-wchooseBy pat pairs = match <$> pat- where- match r = values !! head (findIndices (> (r*total)) cweights)- cweights = scanl1 (+) (map snd pairs)- values = map fst pairs- total = sum $ map snd pairs---- | @randcat ps@: does a @slowcat@ on the list of patterns @ps@ but--- randomises the order in which they are played.-randcat :: [Pattern a] -> Pattern a-randcat ps = spread' rotL (_segment 1 $ (% 1) . fromIntegral <$> (_irand (length ps) :: Pattern Int)) (slowcat ps)---- | As 'randcat', but allowing weighted choice.-wrandcat :: [(Pattern a, Double)] -> Pattern a-wrandcat ps = unwrap $ wchooseBy (segment 1 rand) ps--{- | `degrade` randomly removes events from a pattern 50% of the time:--@-d1 $ slow 2 $ degrade $ sound "[[[feel:5*8,feel*3] feel:3*8], feel*4]"- # accelerate "-6"- # speed "2"-@--The shorthand syntax for `degrade` is a question mark: `?`. Using `?`-will allow you to randomly remove events from a portion of a pattern:--@-d1 $ slow 2 $ sound "bd ~ sn bd ~ bd? [sn bd?] ~"-@--You can also use `?` to randomly remove events from entire sub-patterns:--@-d1 $ slow 2 $ sound "[[[feel:5*8,feel*3] feel:3*8]?, feel*4]"-@--}-degrade :: Pattern a -> Pattern a-degrade = _degradeBy 0.5--{- |-Similar to `degrade`, `degradeBy` allows you to control the percentage of events that-are removed. For example, to remove events 90% of the time:--@-d1 $ slow 2 $ degradeBy 0.9 $ sound "[[[feel:5*8,feel*3] feel:3*8], feel*4]"- # accelerate "-6"- # speed "2"-@--You can also invoke this behavior in the shorthand notation by specifying a percentage, as a-number between 0 and 1, after the question mark:--@-d1 $ s "bd hh?0.8 bd hh?0.4"-@--}-degradeBy :: Pattern Double -> Pattern a -> Pattern a-degradeBy = tParam _degradeBy--_degradeBy :: Double -> Pattern a -> Pattern a-_degradeBy = _degradeByUsing rand---- Useful for manipulating random stream, e.g. to change 'seed'-_degradeByUsing :: Pattern Double -> Double -> Pattern a -> Pattern a-_degradeByUsing prand x p = fmap fst $ filterValues ((> x) . snd) $ (,) <$> p <* prand--{-|-As 'degradeBy', but the pattern of probabilities represents the chances to retain rather-than remove the corresponding element.--}-unDegradeBy :: Pattern Double -> Pattern a -> Pattern a-unDegradeBy = tParam _unDegradeBy--_unDegradeBy :: Double -> Pattern a -> Pattern a-_unDegradeBy x p = fmap fst $ filterValues ((<= x) . snd) $ (,) <$> p <* rand--degradeOverBy :: Int -> Pattern Double -> Pattern a -> Pattern a-degradeOverBy i tx p = unwrap $ (\x -> fmap fst $ filterValues ((> x) . snd) $ (,) <$> p <* fastRepeatCycles i rand) <$> slow (fromIntegral i) tx---{- | Use @sometimesBy@ to apply a given function "sometimes". For example, the-following code results in @density 2@ being applied about 25% of the time:--@-d1 $ sometimesBy 0.25 (density 2) $ sound "bd*8"-@--There are some aliases as well:--@-'sometimes' = sometimesBy 0.5-'often' = sometimesBy 0.75-'rarely' = sometimesBy 0.25-'almostNever' = sometimesBy 0.1-'almostAlways' = sometimesBy 0.9-@--}-sometimesBy :: Pattern Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-sometimesBy x f pat = overlay (degradeBy x pat) (f $ unDegradeBy x pat)--{- | As 'sometimesBy', but applies the given transformation to the pattern in its entirety-before filtering its actual appearances. Less efficient than 'sometimesBy' but may-be useful when the passed pattern transformation depends on properties of the-pattern before probabilities are taken into account.--@-'sometimes'' = sometimesBy' 0.5-'often'' = sometimesBy' 0.75-'rarely'' = sometimesBy' 0.25-'almostNever'' = sometimesBy' 0.1-'almostAlways'' = sometimesBy' 0.9-@--}-sometimesBy' :: Pattern Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-sometimesBy' x f pat = overlay (degradeBy x pat) (unDegradeBy x $ f pat)---- | @sometimes@ is an alias for @sometimesBy 0.5@.-sometimes :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-sometimes = sometimesBy 0.5--sometimes' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-sometimes' = sometimesBy' 0.5---- | @often@ is an alias for @sometimesBy 0.75@.-often :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-often = sometimesBy 0.75--often' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-often' = sometimesBy' 0.75---- | @rarely@ is an alias for @sometimesBy 0.25@.-rarely :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-rarely = sometimesBy 0.25--rarely' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-rarely' = sometimesBy' 0.25---- | @almostNever@ is an alias for @sometimesBy 0.1@.-almostNever :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-almostNever = sometimesBy 0.1--almostNever' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-almostNever' = sometimesBy 0.1---- | @almostAlways@ is an alias for @sometimesBy 0.9@.-almostAlways :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-almostAlways = sometimesBy 0.9--almostAlways' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-almostAlways' = sometimesBy' 0.9--{-|-Never apply a transformation, returning the pattern unmodified.--@never = flip const@--}--never :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-never = flip const--{-|-Apply the transformation to the pattern unconditionally.--@always = id@--}-always :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-always = id--{- | @someCyclesBy@ is a cycle-by-cycle version of @'sometimesBy'@.--@someCycles = someCyclesBy 0.5@--}-someCyclesBy :: Pattern Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-someCyclesBy pd f pat = innerJoin $ (\d -> _someCyclesBy d f pat) <$> pd--_someCyclesBy :: Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-_someCyclesBy x = when test- where test c = timeToRand (fromIntegral c :: Double) < x--somecyclesBy :: Pattern Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-somecyclesBy = someCyclesBy---- | @someCycles = someCyclesBy 0.5@-someCycles :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-someCycles = someCyclesBy 0.5--somecycles :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-somecycles = someCycles---- ** Pattern transformations--{- |-Pattern transformations are functions generally of type @'Pattern' a -> 'Pattern' a@.-This means they take a pattern of any type and return a pattern of that type.---This transformation makes a pattern sound a bit like a breakbeat.--Example:--@-d1 $ sound (brak "bd sn kurt")-@--}-brak :: Pattern a -> Pattern a-brak = when ((== 1) . (`mod` 2)) (((1%4) `rotR`) . (\x -> fastcat [x, silence]))--{- | Divides a pattern into a given number of subdivisions, plays the subdivisions-in order, but increments the starting subdivision each cycle. The pattern-wraps to the first subdivision after the last subdivision is played.--Example:--@-d1 $ iter 4 $ sound "bd hh sn cp"-@--This will produce the following over four cycles:--@-bd hh sn cp-hh sn cp bd-sn cp bd hh-cp bd hh sn-@--There is also `iter'`, which shifts the pattern in the opposite direction.---}-iter :: Pattern Int -> Pattern c -> Pattern c-iter = tParam _iter--_iter :: Int -> Pattern a -> Pattern a-_iter n p = slowcat $ map (\i -> (fromIntegral i % fromIntegral n) `rotL` p) [0 .. (n-1)]---- | @iter'@ is the same as @iter@, but decrements the starting--- subdivision instead of incrementing it.-iter' :: Pattern Int -> Pattern c -> Pattern c-iter' = tParam _iter'--_iter' :: Int -> Pattern a -> Pattern a-_iter' n p = slowcat $ map (\i -> (fromIntegral i % fromIntegral n) `rotR` p) [0 .. (n-1)]---- | @palindrome p@ applies @rev@ to @p@ every other cycle, so that--- the pattern alternates between forwards and backwards.-palindrome :: Pattern a -> Pattern a-palindrome p = slowAppend p (rev p)---- | Degrades a pattern over the given time.-fadeOut :: Time -> Pattern a -> Pattern a-fadeOut dur p = innerJoin $ (`_degradeBy` p) <$> _slow dur envL---- | Alternate version to @fadeOut@ where you can provide the time from which the fade starts-fadeOutFrom :: Time -> Time -> Pattern a -> Pattern a-fadeOutFrom from dur p = innerJoin $ (`_degradeBy` p) <$> (from `rotR` _slow dur envL)---- | ’Undegrades’ a pattern over the given time.-fadeIn :: Time -> Pattern a -> Pattern a-fadeIn dur p = innerJoin $ (`_degradeBy` p) <$> _slow dur envLR---- | Alternate version to @fadeIn@ where you can provide the time from--- which the fade in starts-fadeInFrom :: Time -> Time -> Pattern a -> Pattern a-fadeInFrom from dur p = innerJoin $ (`_degradeBy` p) <$> (from `rotR` _slow dur envLR)--{- | The 'spread' function allows you to take a pattern transformation-which takes a parameter, such as `slow`, and provide several-parameters which are switched between. In other words it 'spreads' a-function across several values.--Taking a simple high hat loop as an example:--@-d1 $ sound "ho ho:2 ho:3 hc"-@--We can slow it down by different amounts, such as by a half:--@-d1 $ slow 2 $ sound "ho ho:2 ho:3 hc"-@--Or by four thirds (i.e. speeding it up by a third; @4%3@ means four over-three):--@-d1 $ slow (4%3) $ sound "ho ho:2 ho:3 hc"-@--But if we use `spread`, we can make a pattern which alternates between-the two speeds:--@-d1 $ spread slow [2,4%3] $ sound "ho ho:2 ho:3 hc"-@--Note that if you pass @($)@ as the function to spread values over, you-can put functions as the list of values. ('spreadf' is an alias for @spread ($)@.)-For example:--@-d1 $ spread ($) [density 2, rev, slow 2, striate 3, (# speed "0.8")]- $ sound "[bd*2 [~ bd]] [sn future]*2 cp jvbass*4"-@--Above, the pattern will have these transforms applied to it, one at a time, per cycle:--* cycle 1: @density 2@ - pattern will increase in speed-* cycle 2: @rev@ - pattern will be reversed-* cycle 3: @slow 2@ - pattern will decrease in speed-* cycle 4: @striate 3@ - pattern will be granualized-* cycle 5: @(# speed "0.8")@ - pattern samples will be played back more slowly--After @(# speed "0.8")@, the transforms will repeat and start at @density 2@ again.--}-spread :: (a -> t -> Pattern b) -> [a] -> t -> Pattern b-spread f xs p = slowcat $ map (`f` p) xs---- | An alias for 'spread' consistent with 'fastspread'.-slowspread :: (a -> t -> Pattern b) -> [a] -> t -> Pattern b-slowspread = spread--{- | @fastspread@ works the same as `spread`, but the result is squashed into a single cycle. If you gave four values to @spread@, then the result would seem to speed up by a factor of four. Compare these two:--@- d1 $ spread chop [4,64,32,16] $ sound "ho ho:2 ho:3 hc"-- d1 $ fastspread chop [4,64,32,16] $ sound "ho ho:2 ho:3 hc"-@--There is also `slowspread`, which is an alias of @spread@.--}-fastspread :: (a -> t -> Pattern b) -> [a] -> t -> Pattern b-fastspread f xs p = fastcat $ map (`f` p) xs--{- | There's a version of this function, `spread'` (pronounced "spread prime"), which takes a /pattern/ of parameters, instead of a list:--@-d1 $ spread' slow "2 4%3" $ sound "ho ho:2 ho:3 hc"-@--This is quite a messy area of Tidal—due to a slight difference of-implementation this sounds completely different! One advantage of-using `spread'` though is that you can provide polyphonic parameters, e.g.:--@-d1 $ spread' slow "[2 4%3, 3]" $ sound "ho ho:2 ho:3 hc"-@--}-spread' :: Monad m => (a -> b -> m c) -> m a -> b -> m c-spread' f vpat pat = vpat >>= \v -> f v pat--{- | @spreadChoose f xs p@ is similar to `slowspread` but picks values from-`xs` at random, rather than cycling through them in order.--}-spreadChoose :: (t -> t1 -> Pattern b) -> [t] -> t1 -> Pattern b-spreadChoose f vs p = do v <- _segment 1 (choose vs)- f v p---- | A shorter alias for 'spreadChoose'.-spreadr :: (t -> t1 -> Pattern b) -> [t] -> t1 -> Pattern b-spreadr = spreadChoose--{-| Decide whether to apply one or another function depending on the result of a test function that is passed the current cycle as a number.--@-d1 $ ifp ((== 0).(flip mod 2))- (striate 4)- (# coarse "24 48") $- sound "hh hc"-@--This will apply @'striate' 4@ for every _even_ cycle and apply @# coarse "24 48"@ for every _odd_.--Detail: As you can see the test function is arbitrary and does not rely on anything tidal specific. In fact it uses only plain haskell functionality, that is: it calculates the modulo of 2 of the current cycle which is either 0 (for even cycles) or 1. It then compares this value against 0 and returns the result, which is either `True` or `False`. This is what the `ifp` signature's first part signifies `(Int -> Bool)`, a function that takes a whole number and returns either `True` or `False`.--}-ifp :: (Int -> Bool) -> (Pattern a -> Pattern a) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-ifp test f1 f2 p = splitQueries $ p {query = q}- where q a | test (floor $ start $ arc a) = query (f1 p) a- | otherwise = query (f2 p) a---- | @wedge t p p'@ combines patterns @p@ and @p'@ by squashing the--- @p@ into the portion of each cycle given by @t@, and @p'@ into the--- remainer of each cycle.-wedge :: Pattern Time -> Pattern a -> Pattern a -> Pattern a-wedge pt pa pb = innerJoin $ (\t -> _wedge t pa pb) <$> pt--_wedge :: Time -> Pattern a -> Pattern a -> Pattern a-_wedge 0 _ p' = p'-_wedge 1 p _ = p-_wedge t p p' = overlay (_fastGap (1/t) p) (t `rotR` _fastGap (1/(1-t)) p')---{- | @whenmod@ has a similar form and behavior to `every`, but requires an-additional number. Applies the function to the pattern, when the-remainder of the current loop number divided by the first parameter,-is greater or equal than the second parameter.--For example the following makes every other block of four loops twice-as dense:--@-d1 $ whenmod 8 4 (density 2) (sound "bd sn kurt")-@--}-whenmod :: Pattern Time -> Pattern Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-whenmod a b f pat = innerJoin $ (\a' b' -> _whenmod a' b' f pat) <$> a <*> b--_whenmod :: Time -> Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-_whenmod a b = whenT (\t -> ((t `mod'` a) >= b ))---{- |-@-superimpose f p = stack [p, f p]-@--`superimpose` plays a modified version of a pattern at the same time as the original pattern,-resulting in two patterns being played at the same time.--@-d1 $ superimpose (density 2) $ sound "bd sn [cp ht] hh"-d1 $ superimpose ((# speed "2") . (0.125 <~)) $ sound "bd sn cp hh"-@---}-superimpose :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a-superimpose f p = stack [p, f p]--{- | @trunc@ truncates a pattern so that only a fraction of the pattern is played.-The following example plays only the first quarter of the pattern:--@-d1 $ trunc 0.25 $ sound "bd sn*2 cp hh*4 arpy bd*2 cp bd*2"-@--}-trunc :: Pattern Time -> Pattern a -> Pattern a-trunc = tParam _trunc--_trunc :: Time -> Pattern a -> Pattern a-_trunc t = compress (0, t) . zoomArc (Arc 0 t)--{- | @linger@ is similar to `trunc` but the truncated part of the pattern loops until the end of the cycle.--@-d1 $ linger 0.25 $ sound "bd sn*2 cp hh*4 arpy bd*2 cp bd*2"-@--If you give it a negative number, it will linger on the last part of-the pattern, instead of the start of it. E.g. to linger on the last-quarter:--@-d1 $ linger (-0.25) $ sound "bd sn*2 cp hh*4 arpy bd*2 cp bd*2"-@--}-linger :: Pattern Time -> Pattern a -> Pattern a-linger = tParam _linger--_linger :: Time -> Pattern a -> Pattern a-_linger n p | n < 0 = _fast (1/n) $ zoomArc (Arc (1 + n) 1) p- | otherwise = _fast (1/n) $ zoomArc (Arc 0 n) p--{- |-Use `within` to apply a function to only a part of a pattern. For example, to-apply `density 2` to only the first half of a pattern:--@-d1 $ within (0, 0.5) (density 2) $ sound "bd*2 sn lt mt hh hh hh hh"-@--Or, to apply `(# speed "0.5") to only the last quarter of a pattern:--@-d1 $ within (0.75, 1) (# speed "0.5") $ sound "bd*2 sn lt mt hh hh hh hh"-@--}-within :: (Time, Time) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-within (s, e) f p = stack [filterWhen (\t -> cyclePos t >= s && cyclePos t < e) $ f p,- filterWhen (\t -> not $ cyclePos t >= s && cyclePos t < e) p- ]--withinArc :: Arc -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-withinArc (Arc s e) = within (s, e)--{- |-For many cases, @within'@ will function exactly as within.-The difference between the two occurs when applying functions that change the timing of notes such as 'fast' or '<~'.-within first applies the function to all notes in the cycle, then keeps the results in the specified interval, and then combines it with the old cycle (an "apply split combine" paradigm).-within' first keeps notes in the specified interval, then applies the function to these notes, and then combines it with the old cycle (a "split apply combine" paradigm).---For example, whereas using the standard version of within--@-d1 $ within (0, 0.25) (fast 2) $ sound "bd hh cp sd"-@--sounds like:--@-d1 $ sound "[bd hh] hh cp sd"-@--using this alternative version, within'--@-d1 $ within' (0, 0.25) (fast 2) $ sound "bd hh cp sd"-@--sounds like:--@-d1 $ sound "[bd bd] hh cp sd"-@---}-within' :: (Time, Time) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-within' a@(s, e) f p =- stack [ filterWhen (\t -> cyclePos t >= s && cyclePos t < e) $ compress a $ f $ zoom a p- , filterWhen (\t -> not $ cyclePos t >= s && cyclePos t < e) p- ]--{-|-Reverse the part of the pattern sliced out by the @(start, end)@ pair.--@revArc a = within a rev@--}-revArc :: (Time, Time) -> Pattern a -> Pattern a-revArc a = within a rev--{- | You can use the @euclid@ function to apply a Euclidean algorithm over a-complex pattern, although the structure of that pattern will be lost:--@-d1 $ euclid 3 8 $ sound "bd*2 [sn cp]"-@--In the above, three sounds are picked from the pattern on the right according-to the structure given by the @euclid 3 8@. It ends up picking two @bd@ sounds, a-@cp@ and missing the @sn@ entirely.--A negative first argument provides the inverse of the euclidean pattern.--These types of sequences use "Bjorklund's algorithm", which wasn't made for-music but for an application in nuclear physics, which is exciting. More-exciting still is that it is very similar in structure to the one of the first-known algorithms written in Euclid's book of elements in 300 BC. You can read-more about this in the paper-[The Euclidean Algorithm Generates Traditional Musical Rhythms](http://cgm.cs.mcgill.ca/~godfried/publications/banff.pdf)-by Toussaint. Some examples from this paper are included below,-including rotation as a third parameter in some cases (see 'euclidOff').--@-- (2,5) : A thirteenth century Persian rhythm called Khafif-e-ramal.-- (3,4) : The archetypal pattern of the Cumbia from Colombia, as well as a Calypso rhythm from Trinidad.-- (3,5,2) : Another thirteenth century Persian rhythm by the name of Khafif-e-ramal, as well as a Rumanian folk-dance rhythm.-- (3,7) : A Ruchenitza rhythm used in a Bulgarian folk-dance.-- (3,8) : The Cuban tresillo pattern.-- (4,7) : Another Ruchenitza Bulgarian folk-dance rhythm.-- (4,9) : The Aksak rhythm of Turkey.-- (4,11) : The metric pattern used by Frank Zappa in his piece titled Outside Now.-- (5,6) : Yields the York-Samai pattern, a popular Arab rhythm.-- (5,7) : The Nawakhat pattern, another popular Arab rhythm.-- (5,8) : The Cuban cinquillo pattern.-- (5,9) : A popular Arab rhythm called Agsag-Samai.-- (5,11) : The metric pattern used by Moussorgsky in Pictures at an Exhibition.-- (5,12) : The Venda clapping pattern of a South African children’s song.-- (5,16) : The Bossa-Nova rhythm necklace of Brazil.-- (7,8) : A typical rhythm played on the Bendir (frame drum).-- (7,12) : A common West African bell pattern.-- (7,16,14) : A Samba rhythm necklace from Brazil.-- (9,16) : A rhythm necklace used in the Central African Republic.-- (11,24,14) : A rhythm necklace of the Aka Pygmies of Central Africa.-- (13,24,5) : Another rhythm necklace of the Aka Pygmies of the upper Sangha.-@--There was once a shorter alias @e@ for this function. It has been removed, but you-may see references to it in older Tidal code.--}-euclid :: Pattern Int -> Pattern Int -> Pattern a -> Pattern a-euclid = tParam2 _euclid--_euclid :: Int -> Int -> Pattern a -> Pattern a-_euclid n k a | n >= 0 = fastcat $ fmap (bool silence a) $ bjorklund (n,k)- | otherwise = fastcat $ fmap (bool a silence) $ bjorklund (-n,k)--{- |--@euclidFull n k pa pb@ stacks @'euclid' n k pa@ with @'euclidInv' n k pb@. For example,-to implement the traditional flamenco rhythm, you could use hard claps for the former-and soft claps for the latter:--@d1 $ euclidFull 3 7 "realclaps" ("realclaps" # gain 0.8)@---}-euclidFull :: Pattern Int -> Pattern Int -> Pattern a -> Pattern a -> Pattern a-euclidFull n k pa pb = stack [ euclid n k pa, euclidInv n k pb ]---- | Less expressive than 'euclid' due to its constrained types, but may be more efficient.-_euclidBool :: Int -> Int -> Pattern Bool -- TODO: add 'euclidBool'?-_euclidBool n k = fastFromList $ bjorklund (n,k)--_euclid' :: Int -> Int -> Pattern a -> Pattern a-_euclid' n k p = fastcat $ map (\x -> if x then p else silence) (bjorklund (n,k))--{- |--As 'euclid', but taking a third rotational parameter corresponding to the onset-at which to start the rhythm.---}-euclidOff :: Pattern Int -> Pattern Int -> Pattern Int -> Pattern a -> Pattern a-euclidOff = tParam3 _euclidOff---- | A shorter alias for 'euclidOff'.-eoff :: Pattern Int -> Pattern Int -> Pattern Int -> Pattern a -> Pattern a-eoff = euclidOff--_euclidOff :: Int -> Int -> Int -> Pattern a -> Pattern a-_euclidOff _ 0 _ _ = silence-_euclidOff n k s p = (rotL $ fromIntegral s%fromIntegral k) (_euclid n k p)---- | As 'euclidOff', but specialized to 'Bool'. May be more efficient than 'euclidOff'.-euclidOffBool :: Pattern Int -> Pattern Int -> Pattern Int -> Pattern Bool -> Pattern Bool-euclidOffBool = tParam3 _euclidOffBool--_euclidOffBool :: Int -> Int -> Int -> Pattern Bool -> Pattern Bool-_euclidOffBool _ 0 _ _ = silence-_euclidOffBool n k s p = ((fromIntegral s % fromIntegral k) `rotL`) ((\a b -> if b then a else not a) <$> _euclidBool n k <*> p)--distrib :: [Pattern Int] -> Pattern a -> Pattern a-distrib ps p = do p' <- sequence ps- _distrib p' p--_distrib :: [Int] -> Pattern a -> Pattern a-_distrib xs p = boolsToPat (foldr distrib' (replicate (last xs) True) (reverse $ layers xs)) p- where- distrib' :: [Bool] -> [Bool] -> [Bool]- distrib' [] _ = []- distrib' (_:a) [] = False : distrib' a []- distrib' (True:a) (x:b) = x : distrib' a b- distrib' (False:a) b = False : distrib' a b- layers = map bjorklund . (zip<*>tail)- boolsToPat a b' = flip const <$> filterValues (== True) (fastFromList a) <* b'--{- | `euclidInv` fills in the blanks left by `euclid`.--Whereas @euclid 3 8 "x"@ produces @"x ~ ~ x ~ ~ x ~"@, @euclidInv 3 8 "x"@ produces @"~ x x ~ x x ~ x"@.--}-euclidInv :: Pattern Int -> Pattern Int -> Pattern a -> Pattern a-euclidInv = tParam2 _euclidInv--_euclidInv :: Int -> Int -> Pattern a -> Pattern a-_euclidInv n k a = _euclid (-n) k a--index :: Real b => b -> Pattern b -> Pattern c -> Pattern c-index sz indexpat pat =- spread' (zoom' $ toRational sz) (toRational . (*(1-sz)) <$> indexpat) pat- where- zoom' tSz s = zoomArc (Arc s (s+tSz))--{---- | @prrw f rot (blen, vlen) beatPattern valuePattern@: pattern rotate/replace.-prrw :: (a -> b -> c) -> Int -> (Time, Time) -> Pattern a -> Pattern b -> Pattern c-prrw f rot (blen, vlen) beatPattern valuePattern =- let- ecompare (_,e1,_) (_,e2,_) = compare (fst e1) (fst e2)- beats = sortBy ecompare $ arc beatPattern (0, blen)- values = fmap thd' . sortBy ecompare $ arc valuePattern (0, vlen)- cycles = blen * (fromIntegral $ lcm (length beats) (length values) `div` (length beats))- in- _slow cycles $ stack $ zipWith- (\( _, (start, end), v') v -> (start `rotR`) $ densityGap (1 / (end - start)) $ pure (f v' v))- (sortBy ecompare $ arc (_fast cycles $ beatPattern) (0, blen))- (drop (rot `mod` length values) $ cycle values)---- | @prr rot (blen, vlen) beatPattern valuePattern@: pattern rotate/replace.-prr :: Int -> (Time, Time) -> Pattern String -> Pattern b -> Pattern b-prr = prrw $ flip const--{-|-@preplace (blen, plen) beats values@ combines the timing of @beats@ with the values-of @values@. Other ways of saying this are:-* sequential convolution-* @values@ quantized to @beats@.--Examples:--@-d1 $ sound $ preplace (1,1) "x [~ x] x x" "bd sn"-d1 $ sound $ preplace (1,1) "x(3,8)" "bd sn"-d1 $ sound $ "x(3,8)" <~> "bd sn"-d1 $ sound "[jvbass jvbass:5]*3" |+| (shape $ "1 1 1 1 1" <~> "0.2 0.9")-@--It is assumed the pattern fits into a single cycle. This works well with-pattern literals, but not always with patterns defined elsewhere. In those cases-use @preplace@ and provide desired pattern lengths:-@-let p = slow 2 $ "x x x"--d1 $ sound $ preplace (2,1) p "bd sn"-@--}-preplace :: (Time, Time) -> Pattern String -> Pattern b -> Pattern b-preplace = preplaceWith $ flip const---- | @prep@ is an alias for preplace.-prep :: (Time, Time) -> Pattern String -> Pattern b -> Pattern b-prep = preplace--preplace1 :: Pattern String -> Pattern b -> Pattern b-preplace1 = preplace (1, 1)--preplaceWith :: (a -> b -> c) -> (Time, Time) -> Pattern a -> Pattern b -> Pattern c-preplaceWith f (blen, plen) = prrw f 0 (blen, plen)--prw :: (a -> b -> c) -> (Time, Time) -> Pattern a -> Pattern b -> Pattern c-prw = preplaceWith--preplaceWith1 :: (a -> b -> c) -> Pattern a -> Pattern b -> Pattern c-preplaceWith1 f = prrw f 0 (1, 1)--prw1 :: (a -> b -> c) -> Pattern a -> Pattern b -> Pattern c-prw1 = preplaceWith1--(<~>) :: Pattern String -> Pattern b -> Pattern b-(<~>) = preplace (1, 1)---- | @protate len rot p@ rotates pattern @p@ by @rot@ beats to the left.--- @len@: length of the pattern, in cycles.--- Example: @d1 $ every 4 (protate 2 (-1)) $ slow 2 $ sound "bd hh hh hh"@-protate :: Time -> Int -> Pattern a -> Pattern a-protate len rot p = prrw (flip const) rot (len, len) p p--prot :: Time -> Int -> Pattern a -> Pattern a-prot = protate--prot1 :: Int -> Pattern a -> Pattern a-prot1 = protate 1--{-| The @<<~@ operator rotates a unit pattern to the left, similar to @<~@,-but by events rather than linear time. The timing of the pattern remains constant:--@-d1 $ (1 <<~) $ sound "bd ~ sn hh"--- will become-d1 $ sound "sn ~ hh bd"-@ -}--(<<~) :: Int -> Pattern a -> Pattern a-(<<~) = protate 1---- | @~>>@ is like @<<~@ but for shifting to the right.-(~>>) :: Int -> Pattern a -> Pattern a-(~>>) = (<<~) . (0-)---- | @pequal cycles p1 p2@: quickly test if @p1@ and @p2@ are the same.-pequal :: Ord a => Time -> Pattern a -> Pattern a -> Bool-pequal cycles p1 p2 = (sort $ arc p1 (0, cycles)) == (sort $ arc p2 (0, cycles))--}---- | @rot n p@ rotates the values in a pattern @p@ by @n@ beats to the left.--- Example: @d1 $ every 4 (rot 2) $ slow 2 $ sound "bd hh hh hh"@-rot :: Ord a => Pattern Int -> Pattern a -> Pattern a-rot = tParam _rot---- | Calculates a whole cycle, rotates it, then constrains events to the original query arc.-_rot :: Ord a => Int -> Pattern a -> Pattern a-_rot i pat = splitQueries $ pat {query = \st -> f st (query pat (st {arc = wholeCycle (arc st)}))}- where -- TODO maybe events with the same arc (part+whole) should be- -- grouped together in the rotation?- f st es = constrainEvents (arc st) $ shiftValues $ sort $ defragParts es- shiftValues es | i >= 0 =- zipWith (\e s -> e {value = s}) es- (drop i $ cycle $ map value es)- | otherwise =- zipWith (\e s -> e{value = s}) es- (drop (length es - abs i) $ cycle $ map value es)- wholeCycle (Arc s _) = Arc (sam s) (nextSam s)- constrainEvents :: Arc -> [Event a] -> [Event a]- constrainEvents a es = mapMaybe (constrainEvent a) es- constrainEvent :: Arc -> Event a -> Maybe (Event a)- constrainEvent a e =- do- p' <- subArc (part e) a- return e {part = p'}---- | @segment n p@: ’samples’ the pattern @p@ at a rate of @n@--- events per cycle. Useful for turning a continuous pattern into a--- discrete one.-segment :: Pattern Time -> Pattern a -> Pattern a-segment = tParam _segment--_segment :: Time -> Pattern a -> Pattern a-_segment n p = _fast n (pure id) <* p---- | @discretise@: the old (deprecated) name for 'segment'-discretise :: Pattern Time -> Pattern a -> Pattern a-discretise = segment---- @fromNote p@: converts a pattern of human-readable pitch names--- into pitch numbers. For example, @"cs2"@ will be parsed as C Sharp--- in the 2nd octave with the result of @11@, and @"b-3"@ as--- @-25@. Pitches can be decorated using:------ * s = Sharp, a half-step above (@"gs-1"@)--- * f = Flat, a half-step below (@"gf-1"@)--- * n = Natural, no decoration (@"g-1" and "gn-1"@ are equivalent)--- * ss = Double sharp, a whole step above (@"gss-1"@)--- * ff = Double flat, a whole step below (@"gff-1"@)------ Note that TidalCycles now assumes that middle C is represented by--- the value 0, rather than the previous value of 60. This function--- is similar to previously available functions @tom@ and @toMIDI@,--- but the default octave is now 0 rather than 5.-{---definition moved to Parse.hs ..--toMIDI :: Pattern String -> Pattern Int-toMIDI p = fromJust <$> (filterValues (isJust) (noteLookup <$> p))- where- noteLookup :: String -> Maybe Int- noteLookup [] = Nothing- noteLookup s | not (last s `elem` ['0' .. '9']) = noteLookup (s ++ "0")- | not (isLetter (s !! 1)) = noteLookup((head s):'n':(tail s))- | otherwise = parse s- parse x = (\a b c -> a+b+c) <$> pc x <*> sym x <*> Just(12*digitToInt (last x))- pc x = lookup (head x) [('c',0),('d',2),('e',4),('f',5),('g',7),('a',9),('b',11)]- sym x = lookup (init (tail x)) [("s",1),("f",-1),("n",0),("ss",2),("ff",-2)]--}---- @tom p@: Alias for @toMIDI@.--- tom = toMIDI---{- | The `fit` function takes a pattern of integer numbers, which are used to select values from the given list. What makes this a bit strange is that only a given number of values are selected each cycle. For example:--@-d1 $ sound (fit 3 ["bd", "sn", "arpy", "arpy:1", "casio"] "0 [~ 1] 2 1")-@--The above fits three samples into the pattern, i.e. for the first cycle this will be `"bd"`, `"sn"` and `"arpy"`, giving the result `"bd [~ sn] arpy sn"` (note that we start counting at zero, so that `0` picks the first value). The following cycle the *next* three values in the list will be picked, i.e. `"arpy:1"`, `"casio"` and `"bd"`, giving the pattern `"arpy:1 [~ casio] bd casio"` (note that the list wraps round here).---}-fit :: Pattern Int -> [a] -> Pattern Int -> Pattern a-fit pint xs p = (tParam func) pint (xs,p)- where func i (xs',p') = _fit i xs' p'--_fit :: Int -> [a] -> Pattern Int -> Pattern a-_fit perCycle xs p = (xs !!!) <$> (p {query = map (\e -> fmap (+ pos e) e) . query p})- where pos e = perCycle * floor (start $ part e)---permstep :: RealFrac b => Int -> [a] -> Pattern b -> Pattern a-permstep nSteps things p = unwrap $ (\n -> fastFromList $ concatMap (\x -> replicate (fst x) (snd x)) $ zip (ps !! floor (n * fromIntegral (length ps - 1))) things) <$> _segment 1 p- where ps = permsort (length things) nSteps- deviance avg xs = sum $ map (abs . (avg-) . fromIntegral) xs- permsort n total = map fst $ sortOn snd $ map (\x -> (x,deviance (fromIntegral total / (fromIntegral n :: Double)) x)) $ perms n total- perms 0 _ = []- perms 1 n = [[n]]- perms n total = concatMap (\x -> map (x:) $ perms (n-1) (total-x)) [1 .. (total-(n-1))]---- | @struct a b@: structures pattern @b@ in terms of the pattern of--- boolean values @a@. Only @True@ values in the boolean pattern are--- used.-struct :: Pattern Bool -> Pattern a -> Pattern a-struct ps pv = filterJust $ (\a b -> if a then Just b else Nothing ) <$> ps <* pv---- | @substruct a b@: similar to @struct@, but each event in pattern @a@ gets replaced with pattern @b@, compressed to fit the timespan of the event.-substruct :: Pattern Bool -> Pattern b -> Pattern b-substruct s p = p {query = f}- where f st =- concatMap ((\a' -> queryArc (compressArcTo a' p) a') . wholeOrPart) $ filter value $ query s st--randArcs :: Int -> Pattern [Arc]-randArcs n =- do rs <- mapM (\x -> pure (toRational x / toRational n) <~ choose [1 :: Int,2,3]) [0 .. (n-1)]- let rats = map toRational rs- total = sum rats- pairs = pairUp $ accumulate $ map (/total) rats- return pairs- where pairUp [] = []- pairUp xs = Arc 0 (head xs) : pairUp' xs- pairUp' [] = []- pairUp' [_] = []- pairUp' [a, _] = [Arc a 1]- pairUp' (a:b:xs) = Arc a b: pairUp' (b:xs)----- TODO - what does this do? Something for @stripe@ ..-randStruct :: Int -> Pattern Int-randStruct n = splitQueries $ Pattern {query = f}- where f st = map (\(a,b,c) -> Event (Context []) (Just a) (fromJust b) c) $ filter (\(_,x,_) -> isJust x) as- where as = map (\(i, Arc s' e') ->- (Arc (s' + sam s) (e' + sam s),- subArc (Arc s e) (Arc (s' + sam s) (e' + sam s)), i)) $- enumerate $ value $ head $- queryArc (randArcs n) (Arc (sam s) (nextSam s))- (Arc s e) = arc st---- TODO - what does this do?-substruct' :: Pattern Int -> Pattern a -> Pattern a-substruct' s p = p {query = \st -> concatMap (f st) (query s st)}- where f st (Event c (Just a') _ i) = map (\e -> e {context = combineContexts [c, context e]}) $ queryArc (compressArcTo a' (inside (pure $ 1/toRational(length (queryArc s (Arc (sam (start $ arc st)) (nextSam (start $ arc st)))))) (rotR (toRational i)) p)) a'- -- Ignore analog events (ones without wholes)- f _ _ = []---- | @stripe n p@: repeats pattern @p@, @n@ times per cycle. So--- similar to @fast@, but with random durations. The repetitions will--- be continguous (touching, but not overlapping) and the durations--- will add up to a single cycle. @n@ can be supplied as a pattern of--- integers.-stripe :: Pattern Int -> Pattern a -> Pattern a-stripe = tParam _stripe--_stripe :: Int -> Pattern a -> Pattern a-_stripe = substruct' . randStruct---- | @slowstripe n p@ is the same as @stripe@, but the result is also--- @n@ times slower, so that the mean average duration of the stripes--- is exactly one cycle, and every @n@th stripe starts on a cycle--- boundary (in Indian classical terms, the /sam/).-slowstripe :: Pattern Int -> Pattern a -> Pattern a-slowstripe n = slow (toRational <$> n) . stripe n---- Lindenmayer patterns, these go well with the step sequencer--- general rule parser (strings map to strings)-parseLMRule :: String -> [(String,String)]-parseLMRule s = map (splitOn ':') commaSplit- where splitOn sep str = splitAt (fromJust $ elemIndex sep str)- $ filter (/= sep) str- commaSplit = map T.unpack $ T.splitOn (T.pack ",") $ T.pack s---- specific parser for step sequencer (chars map to string)--- ruleset in form "a:b,b:ab"-parseLMRule' :: String -> [(Char, String)]-parseLMRule' str = map fixer $ parseLMRule str- where fixer (c,r) = (head c, r)--{- | Returns the `n`th iteration of a [Lindenmayer System](https://en.wikipedia.org/wiki/L-system) with given start sequence.--An example--@-lindenmayer 1 "a:b,b:ab" "ab" -> "bab"-@--}-lindenmayer :: Int -> String -> String -> String-lindenmayer _ _ [] = []-lindenmayer 1 r (c:cs) = fromMaybe [c] (lookup c $ parseLMRule' r)- ++ lindenmayer 1 r cs-lindenmayer n r s = iterate (lindenmayer 1 r) s !! n--{- | @lindenmayerI@ converts the resulting string into a a list of integers-with @fromIntegral@ applied (so they can be used seamlessly where floats or-rationals are required) -}-lindenmayerI :: Num b => Int -> String -> String -> [b]-lindenmayerI n r s = fmap (fromIntegral . digitToInt) $ lindenmayer n r s--{- | @runMarkov n tmat xi seed@ generates a Markov chain (as a list) of length @n@-using the transition matrix @tmat@ starting from initial state @xi@, starting-with random numbers generated from @seed@-Each entry in the chain is the index of state (starting from zero).-Each row of the matrix will be automatically normalized. For example:-@-runMarkov 8 [[2,3], [1,3]] 0 0-@-will produce a two-state chain 8 steps long, from initial state @0@, where the-transition probability from state 0->0 is 2/5, 0->1 is 3/5, 1->0 is 1/4, and-1->1 is 3/4. -}-runMarkov :: Int -> [[Double]] -> Int -> Time -> [Int]-runMarkov n tp xi seed = reverse $ (iterate (markovStep $ renorm) [xi])!! (n-1) where- markovStep tp' xs = (fromJust $ findIndex (r <=) $ scanl1 (+) (tp'!!(head xs))) : xs where- r = timeToRand $ seed + (fromIntegral . length) xs / fromIntegral n- renorm = [ map (/ sum x) x | x <- tp ]--{- @markovPat n xi tp@ generates a one-cycle pattern of @n@ steps in a Markov-chain starting from state @xi@ with transition matrix @tp@. Each row of the-transition matrix is automatically normalized. For example:-@-tidal> markovPat 8 1 [[3,5,2], [4,4,2], [0,1,0]]--(0>⅛)|1-(⅛>¼)|2-(¼>⅜)|1-(⅜>½)|1-(½>⅝)|2-(⅝>¾)|1-(¾>⅞)|1-(⅞>1)|0-@ -}-markovPat :: Pattern Int -> Pattern Int -> [[Double]] -> Pattern Int-markovPat = tParam2 _markovPat--_markovPat :: Int -> Int -> [[Double]] -> Pattern Int-_markovPat n xi tp = splitQueries $ Pattern (\(State a@(Arc s _) _) ->- queryArc (listToPat $ runMarkov n tp xi (sam s)) a)--{-|-Removes events from second pattern that don't start during an event from first.--Consider this, kind of messy rhythm without any rests.--@-d1 $ sound (slowcat ["sn*8", "[cp*4 bd*4, hc*5]"]) # n (run 8)-@--If we apply a mask to it--@-d1 $ s (mask ("1 1 1 ~ 1 1 ~ 1" :: Pattern Bool)- (slowcat ["sn*8", "[cp*4 bd*4, bass*5]"] ))- # n (run 8)-@--Due to the use of `slowcat` here, the same mask is first applied to `"sn*8"` and in the next cycle to `"[cp*4 bd*4, hc*5]".--You could achieve the same effect by adding rests within the `slowcat` patterns, but mask allows you to do this more easily. It kind of keeps the rhythmic structure and you can change the used samples independently, e.g.--@-d1 $ s (mask ("1 ~ 1 ~ 1 1 ~ 1")- (slowcat ["can*8", "[cp*4 sn*4, jvbass*16]"] ))- # n (run 8)-@--}-mask :: Pattern Bool -> Pattern a -> Pattern a-mask b p = const <$> p <* (filterValues id b)---- | TODO: refactor towards union-enclosingArc :: [Arc] -> Arc-enclosingArc [] = Arc 0 1-enclosingArc as = Arc (minimum (map start as)) (maximum (map stop as))--stretch :: Pattern a -> Pattern a--- TODO - should that be whole or part?-stretch p = splitQueries $ p {query = q}- where q st = query (zoomArc (cycleArc $ enclosingArc $ map wholeOrPart $ query p (st {arc = Arc (sam s) (nextSam s)})) p) st- where s = start $ arc st--{- | `fit'` is a generalization of `fit`, where the list is instead constructed by using another integer pattern to slice up a given pattern. The first argument is the number of cycles of that latter pattern to use when slicing. It's easier to understand this with a few examples:--@-d1 $ sound (fit' 1 2 "0 1" "1 0" "bd sn")-@--So what does this do? The first `1` just tells it to slice up a single cycle of `"bd sn"`. The `2` tells it to select two values each cycle, just like the first argument to `fit`. The next pattern `"0 1"` is the "from" pattern which tells it how to slice, which in this case means `"0"` maps to `"bd"`, and `"1"` maps to `"sn"`. The next pattern `"1 0"` is the "to" pattern, which tells it how to rearrange those slices. So the final result is the pattern `"sn bd"`.--A more useful example might be something like--@-d1 $ fit' 1 4 (run 4) "[0 3*2 2 1 0 3*2 2 [1*8 ~]]/2" $ chop 4 $ (sound "breaks152" # unit "c")-@--which uses `chop` to break a single sample into individual pieces, which `fit'` then puts into a list (using the `run 4` pattern) and reassembles according to the complicated integer pattern.---}-fit' :: Pattern Time -> Int -> Pattern Int -> Pattern Int -> Pattern a -> Pattern a-fit' cyc n from to p = squeezeJoin $ _fit n mapMasks to- where mapMasks = [stretch $ mask (const True <$> filterValues (== i) from') p'- | i <- [0..n-1]]- p' = density cyc p- from' = density cyc from--{-|- Treats the given pattern @p@ as having @n@ chunks, and applies the function @f@ to one of those sections per cycle.- Running:- - from left to right if chunk number is positive- - from right to left if chunk number is negative-- @- d1 $ chunk 4 (fast 4) $ sound "cp sn arpy [mt lt]"- @--}-chunk :: Pattern Int -> (Pattern b -> Pattern b) -> Pattern b -> Pattern b-chunk npat f p = innerJoin $ (\n -> _chunk n f p) <$> npat--_chunk :: Integral a => a -> (Pattern b -> Pattern b) -> Pattern b -> Pattern b-_chunk n f p | n >= 0 = cat [withinArc (Arc (i % fromIntegral n) ((i+1) % fromIntegral n)) f p | i <- [0 .. fromIntegral n - 1]]- | otherwise = do i <- _slow (toRational (-n)) $ rev $ run (fromIntegral (-n))- withinArc (Arc (i % fromIntegral (-n)) ((i+1) % fromIntegral (-n))) f p---- | DEPRECATED, use 'chunk' with negative numbers instead-chunk' :: Integral a1 => Pattern a1 -> (Pattern a2 -> Pattern a2) -> Pattern a2 -> Pattern a2-chunk' npat f p = innerJoin $ (\n -> _chunk' n f p) <$> npat---- | DEPRECATED, use '_chunk' with negative numbers instead-_chunk' :: Integral a => a -> (Pattern b -> Pattern b) -> Pattern b -> Pattern b-_chunk' n f p = _chunk (-n) f p--{-|-@inside@ carries out an operation /inside/ a cycle.-For example, while @rev "0 1 2 3 4 5 6 7"@ is the same as @"7 6 5 4 3 2 1 0"@,-@inside 2 rev "0 1 2 3 4 5 6 7"@ gives @"3 2 1 0 7 6 5 4"@.--}-inside :: Pattern Time -> (Pattern a1 -> Pattern a) -> Pattern a1 -> Pattern a-inside np f p = innerJoin $ (\n -> _inside n f p) <$> np--_inside :: Time -> (Pattern a1 -> Pattern a) -> Pattern a1 -> Pattern a-_inside n f p = _fast n $ f (_slow n p)--{-|-@outside@ is the inverse of the 'inside' function. @outside@ applies its function /outside/ the cycle.-Say you have a pattern that takes 4 cycles to repeat and apply the rev function:--@-d1 $ rev $ cat [s "bd bd sn",s "sn sn bd", s"lt lt sd", s "sd sd bd"]-@--The above generates:--@-d1 $ rev $ cat [s "sn bd bd",s "bd sn sn", s "sd lt lt", s "bd sd sd"]-@--However if you apply @outside@:--@-d1 $ outside 4 (rev) $ cat [s "bd bd sn",s "sn sn bd", s"lt lt sd", s "sd sd bd"]-@--The result is:--@-d1 $ rev $ cat [s "bd sd sd", s "sd lt lt", s "sn sn bd", s "bd bd sn"]-@---}-outside :: Pattern Time -> (Pattern a1 -> Pattern a) -> Pattern a1 -> Pattern a-outside np f p = innerJoin $ (\n -> _outside n f p) <$> np--_outside :: Time -> (Pattern a1 -> Pattern a) -> Pattern a1 -> Pattern a-_outside n = _inside (1/n)--loopFirst :: Pattern a -> Pattern a-loopFirst p = splitQueries $ p {query = f}- where f st = map- (\(Event c w p' v) ->- Event c (plus <$> w) (plus p') v) $- query p (st {arc = minus $ arc st})- where minus = fmap (subtract (sam s))- plus = fmap (+ sam s)- s = start $ arc st--timeLoop :: Pattern Time -> Pattern a -> Pattern a-timeLoop n = outside n loopFirst--seqPLoop :: [(Time, Time, Pattern a)] -> Pattern a-seqPLoop ps = timeLoop (pure $ maxT - minT) $ minT `rotL` seqP ps- where minT = minimum $ map (\(x,_,_) -> x) ps- maxT = maximum $ map (\(_,x,_) -> x) ps--{-|-@toScale@ lets you turn a pattern of notes within a scale (expressed as a-list) to note numbers.--For example: @toScale [0, 4, 7] "0 1 2 3"@ will turn-into the pattern @"0 4 7 12"@.--This function assumes your scale fits within an-octave; if that's not true, use 'toScale''.--@toScale = toScale' 12@--}-toScale :: Num a => [a] -> Pattern Int -> Pattern a-toScale = toScale' 12--{- | As 'toScale', though allowing scales of arbitrary size.--An example: @toScale' 24 [0,4,7,10,14,17] (run 8)@ turns into @"0 4 7 10 14 17 24 28"@.--}-toScale' :: Num a => Int -> [a] -> Pattern Int -> Pattern a-toScale' _ [] = const silence-toScale' o s = fmap noteInScale- where octave x = x `div` length s- noteInScale x = (s !!! x) + fromIntegral (o * octave x)---{- | `swingBy x n` divides a cycle into `n` slices and delays the notes in-the second half of each slice by `x` fraction of a slice.--}-swingBy :: Pattern Time -> Pattern Time -> Pattern a -> Pattern a-swingBy x n = inside n (withinArc (Arc 0.5 1) (x ~>))--{-|-As 'swingBy', with the cycle division set to ⅓.--}-swing :: Pattern Time -> Pattern a -> Pattern a-swing = swingBy (pure $ 1%3)--{- | `cycleChoose` is like `choose` but only picks a new item from the list-once each cycle -}-cycleChoose :: [a] -> Pattern a-cycleChoose = segment 1 . choose--{- | Internal function used by shuffle and scramble -}-_rearrangeWith :: Pattern Int -> Int -> Pattern a -> Pattern a-_rearrangeWith ipat n pat = innerJoin $ (\i -> _fast nT $ _repeatCycles n $ pats !! i) <$> ipat- where- pats = map (\i -> zoom (fromIntegral i / nT, fromIntegral (i+1) / nT) pat) [0 .. (n-1)]- nT :: Time- nT = fromIntegral n--{- | @shuffle n p@ evenly divides one cycle of the pattern @p@ into @n@ parts,-and returns a random permutation of the parts each cycle. For example,-@shuffle 3 "a b c"@ could return @"a b c"@, @"a c b"@, @"b a c"@, @"b c a"@,-@"c a b"@, or @"c b a"@. But it will **never** return @"a a a"@, because that-is not a permutation of the parts.--}-shuffle :: Pattern Int -> Pattern a -> Pattern a-shuffle = tParam _shuffle--_shuffle :: Int -> Pattern a -> Pattern a-_shuffle n = _rearrangeWith (randrun n) n--{- | @scramble n p@ is like 'shuffle' but randomly selects from the parts-of @p@ instead of making permutations.-For example, @scramble 3 "a b c"@ will randomly select 3 parts from-@"a"@ @"b"@ and @"c"@, possibly repeating a single part.--}-scramble :: Pattern Int -> Pattern a -> Pattern a-scramble = tParam _scramble--_scramble :: Int -> Pattern a -> Pattern a-_scramble n = _rearrangeWith (_segment (fromIntegral n) $ _irand n) n--{-|-@randrun n@ generates a pattern of random integers less than @n@.--The following plays random notes in an octave:--@-d1 $ s "superhammond!12" # n (fromIntegral <$> randrun 13)-@---}-randrun :: Int -> Pattern Int-randrun 0 = silence-randrun n' =- splitQueries $ Pattern (\(State a@(Arc s _) _) -> events a $ sam s)- where events a seed = mapMaybe toEv $ zip arcs shuffled- where shuffled = map snd $ sortOn fst $ zip rs [0 .. (n'-1)]- rs = timeToRands seed n' :: [Double]- arcs = zipWith Arc fractions (tail fractions)- fractions = map (+ (sam $ start a)) [0, 1 / fromIntegral n' .. 1]- toEv (a',v) = do a'' <- subArc a a'- return $ Event (Context []) (Just a') a'' v---- ** Composing patterns--{- | The function @seqP@ allows you to define when-a sound within a list starts and ends. The code below contains three-separate patterns in a `stack`, but each has different start times-(zero cycles, eight cycles, and sixteen cycles, respectively). All-patterns stop after 128 cycles:--@-d1 $ seqP [- (0, 128, sound "bd bd*2"),- (8, 128, sound "hh*2 [sn cp] cp future*4"),- (16, 128, sound (samples "arpy*8" (run 16)))-]-@--}-seqP :: [(Time, Time, Pattern a)] -> Pattern a-seqP ps = stack $ map (\(s, e, p) -> playFor s e (sam s `rotR` p)) ps--{-|-The @ur@ function is designed for longer form composition, by allowing you to-create ’patterns of patterns’ in a repeating loop. It takes four parameters:-how long the loop will take, a pattern giving the structure of the composition,-a lookup table for named patterns to feed into that structure, and a second-lookup table for named transformations\/effects.--The /ur-/ prefix [comes from German](https://en.wiktionary.org/wiki/ur-#German) and-means /proto-/ or /original/. For a mnemonic device, think of this function as-assembling a set of original patterns (ur-patterns) into a larger, newer whole.--Lets say you had three patterns (called @a@, @b@ and @c@), and that you wanted-to play them four cycles each, over twelve cycles in total. Here is one way to-do it:--@-let pats =- [- ("a", stack [n "c4 c5 g4 f4 f5 g4 e5 g4" # s "superpiano" # gain "0.7",- n "[c3,g4,c4]" # s "superpiano"# gain "0.7"- ]- ),- ("b", stack [n "d4 c5 g4 f4 f5 g4 e5 g4" # s "superpiano" # gain "0.7",- n "[d3,a4,d4]" # s "superpiano"# gain "0.7"- ]- ),- ("c", stack [n "f4 c5 g4 f4 f5 g4 e5 g4" # s "superpiano" # gain "0.7",- n "[f4,c5,f4]" # s "superpiano"# gain "0.7"- ]- )- ]-in-d1 $ ur 12 "a b c" pats []-@---}-ur :: Time -> Pattern String -> [(String, Pattern a)] -> [(String, Pattern a -> Pattern a)] -> Pattern a-ur t outer_p ps fs = _slow t $ unwrap $ adjust <$> timedValues (getPat . split <$> outer_p)- where split = wordsBy (==':')- getPat (s:xs) = (match s, transform xs)- -- TODO - check this really can't happen..- getPat _ = error "can't happen?"- match s = fromMaybe silence $ lookup s ps'- ps' = map (fmap (_fast t)) ps- adjust (a, (p, f)) = f a p- transform (x:_) a = transform' x a- transform _ _ = id- transform' str (Arc s e) p = s `rotR` inside (pure $ 1/(e-s)) (matchF str) p- matchF str = fromMaybe id $ lookup str fs- timedValues = withEvent (\(Event c (Just a) a' v) -> Event c (Just a) a' (a,v)) . filterDigital---- | A simpler version of 'ur' that just provides name-value bindings that are reflected in the provided pattern.-inhabit :: [(String, Pattern a)] -> Pattern String -> Pattern a-inhabit ps p = squeezeJoin $ (\s -> fromMaybe silence $ lookup s ps) <$> p--{- | @spaceOut xs p@ repeats a 'Pattern' @p@ at different durations given by the list of time values in @xs@. -}-spaceOut :: [Time] -> Pattern a -> Pattern a-spaceOut xs p = _slow (toRational $ sum xs) $ stack $ map (`compressArc` p) spaceArcs- where markOut :: Time -> [Time] -> [Arc]- markOut _ [] = []- markOut offset (x:xs') = Arc offset (offset+x):markOut (offset+x) xs'- spaceArcs = map (\(Arc a b) -> Arc (a/s) (b/s)) $ markOut 0 xs- s = sum xs---- | @flatpat@ takes a 'Pattern' of lists and pulls the list elements as--- separate 'Event's.-flatpat :: Pattern [a] -> Pattern a-flatpat p = p {query = concatMap (\(Event c b b' xs) -> map (Event c b b') xs) . query p}---- | @layer@ takes a list of 'Pattern'-returning functions and a seed element,--- stacking the result of applying the seed element to each function in the list.-layer :: [a -> Pattern b] -> a -> Pattern b-layer fs p = stack $ map ($ p) fs---- | @arpeggiate@ finds events that share the same timespan, and spreads--- them out during that timespan, so for example @arpeggiate "[bd,sn]"@--- gets turned into @"bd sn"@. Useful for creating arpeggios/broken chords.-arpeggiate :: Pattern a -> Pattern a-arpeggiate = arpWith id---- | Shorthand alias for arpeggiate-arpg :: Pattern a -> Pattern a-arpg = arpeggiate--arpWith :: ([EventF (ArcF Time) a] -> [EventF (ArcF Time) b]) -> Pattern a -> Pattern b-arpWith f p = withEvents munge p- where munge es = concatMap (spreadOut . f) (groupBy (\a b -> whole a == whole b) $ sortOn whole es)- spreadOut xs = mapMaybe (\(n, x) -> shiftIt n (length xs) x) $ enumerate xs- shiftIt n d (Event c (Just (Arc s e)) a' v) =- do- a'' <- subArc (Arc newS newE) a'- return (Event c (Just $ Arc newS newE) a'' v)- where newS = s + (dur * fromIntegral n)- newE = newS + dur- dur = (e - s) / fromIntegral d- -- TODO ignoring analog events.. Should we just leave them as-is?- shiftIt _ _ _ = Nothing---{-| The @arp@ function takes an additional pattern of arpeggiate modes. For example:--@-d1 $ sound "superpiano" # n (arp "<up down diverge>" "<a'm9'8 e'7sus4'8>")-@--The different arpeggiate modes are:-@-up down updown downup up&down down&up converge-diverge disconverge pinkyup pinkyupdown-thumbup thumbupdown--@--}-arp :: Pattern String -> Pattern a -> Pattern a-arp = tParam _arp--_arp :: String -> Pattern a -> Pattern a-_arp name p = arpWith f p- where f = fromMaybe id $ lookup name arps- arps :: [(String, [a] -> [a])]- arps = [("up", id),- ("down", reverse),- ("updown", \x -> init x ++ init (reverse x)),- ("downup", \x -> init (reverse x) ++ init x),- ("up&down", \x -> x ++ reverse x),- ("down&up", \x -> reverse x ++ x),- ("converge", converge),- ("diverge", reverse . converge),- ("disconverge", \x -> converge x ++ tail (reverse $ converge x)),- ("pinkyup", pinkyup),- ("pinkyupdown", \x -> init (pinkyup x) ++ init (reverse $ pinkyup x)),- ("thumbup", thumbup),- ("thumbupdown", \x -> init (thumbup x) ++ init (reverse $ thumbup x))- ]- converge [] = []- converge (x:xs) = x : converge' xs- converge' [] = []- converge' xs = last xs : converge (init xs)- pinkyup xs = concatMap (:[pinky]) $ init xs- where pinky = last xs- thumbup xs = concatMap (\x -> [thumb,x]) $ tail xs- where thumb = head xs--{- | `rolled` plays each note of a chord quickly in order, as opposed to simultaneously; to give a chord a harp-like effect.-This will played from the lowest note to the highest note of the chord:-@-rolled $ n "c'maj'4" # s "superpiano"-@--@rolled = rolledBy (1/4)@--}-rolled :: Pattern a -> Pattern a-rolled = rolledBy (1/4)--{--As 'rolled', but allowing you to specify the length of the roll. The value in the passed pattern-is the divisor of the cycle length. A negative value will play the arpeggio in reverse order.--@-rolledBy "<1 -0.5 0.25 -0.125>" $ note "c'maj9" # s "superpiano"-@--}-rolledBy :: Pattern (Ratio Integer) -> Pattern a -> Pattern a-rolledBy pt = tParam rolledWith (segment 1 $ pt)--rolledWith :: Ratio Integer -> Pattern a -> Pattern a-rolledWith t = withEvents aux- where aux es = concatMap (steppityIn) (groupBy (\a b -> whole a == whole b) $ ((isRev t) es))- isRev b = (\x -> if x > 0 then id else reverse ) b- steppityIn xs = mapMaybe (\(n, ev) -> (timeguard n xs ev t)) $ enumerate xs- timeguard _ _ ev 0 = return ev- timeguard n xs ev _ = (shiftIt n (length xs) ev)- shiftIt n d (Event c (Just (Arc s e)) a' v) = do- a'' <- subArc (Arc newS e) a'- return (Event c (Just $ Arc newS e) a'' v)- where newS = s + (dur * fromIntegral n)- dur = ((e - s)) / ((1/ (abs t))*fromIntegral d)- shiftIt _ _ ev = return ev--{- TODO !---- | @fill@ 'fills in' gaps in one pattern with events from another. For example @fill "bd" "cp ~ cp"@ would result in the equivalent of `"~ bd ~"`. This only finds gaps in a resulting pattern, in other words @"[bd ~, sn]"@ doesn't contain any gaps (because @sn@ covers it all), and @"bd ~ ~ sn"@ only contains a single gap that bridges two steps.-fill :: Pattern a -> Pattern a -> Pattern a-fill p' p = struct (splitQueries $ p {query = q}) p'- where- q st = removeTolerance (s,e) $ invert (s-tolerance, e+tolerance) $ query p (st {arc = (s-tolerance, e+tolerance)})- where (s,e) = arc st- invert (s,e) es = map arcToEvent $ foldr remove [(s,e)] (map part es)- remove (s,e) xs = concatMap (remove' (s, e)) xs- remove' (s,e) (s',e') | s > s' && e < e' = [(s',s),(e,e')] -- inside- | s > s' && s < e' = [(s',s)] -- cut off right- | e > s' && e < e' = [(e,e')] -- cut off left- | s <= s' && e >= e' = [] -- swallow- | otherwise = [(s',e')] -- miss- arcToEvent a = ((a,a),"x")- removeTolerance (s,e) es = concatMap (expand) $ map (withPart f) es- where f a = concatMap (remove' (e,e+tolerance)) $ remove' (s-tolerance,s) a- expand ((a,xs),c) = map (\x -> ((a,x),c)) xs- tolerance = 0.01--}---- | @ply n@ repeats each event @n@ times within its arc.-ply :: Pattern Rational -> Pattern a -> Pattern a-ply = tParam _ply--_ply :: Rational -> Pattern a -> Pattern a-_ply n pat = squeezeJoin $ (_fast n . pure) <$> pat---- | As 'ply', but applies a function each time. The applications are compounded.-plyWith :: (Ord t, Num t) => Pattern t -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-plyWith np f p = innerJoin $ (\n -> _plyWith n f p) <$> np--_plyWith :: (Ord t, Num t) => t -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-_plyWith numPat f p = arpeggiate $ compound numPat- where compound n | n <= 1 = p- | otherwise = overlay p (f $ compound $ n-1)---- | Syncopates a rhythm, shifting each event halfway into its arc (aka timespan), e.g. @"a b [c d] e"@ becomes the equivalent of @"[~ a] [~ b] [[~ c] [~ d]] [~ e]"@-press :: Pattern a -> Pattern a-press = _pressBy 0.5---- | Like @press@, but allows you to specify the amount in which each event is shifted. @pressBy 0.5@ is the same as @press@, while @pressBy (1/3)@ shifts each event by a third of its arc.-pressBy :: Pattern Time -> Pattern a -> Pattern a-pressBy = tParam _pressBy--_pressBy :: Time -> Pattern a -> Pattern a-_pressBy r pat = squeezeJoin $ (compressTo (r,1) . pure) <$> pat---- | Uses the first (binary) pattern to switch between the following--- two patterns. The resulting structure comes from the source patterns, not the--- binary pattern. See also @stitch@.-sew :: Pattern Bool -> Pattern a -> Pattern a -> Pattern a-sew pb a b = overlay (mask pb a) (mask (inv pb) b)---- | Uses the first (binary) pattern to switch between the following--- two patterns. The resulting structure comes from the binary--- pattern, not the source patterns. See also @sew@.-stitch :: Pattern Bool -> Pattern a -> Pattern a -> Pattern a-stitch pb a b = overlay (struct pb a) (struct (inv pb) b)---- | A binary pattern is used to conditionally apply a function to a--- source pattern. The function is applied when a @True@ value is--- active, and the pattern is let through unchanged when a @False@--- value is active. No events are let through where no binary values--- are active.-while :: Pattern Bool -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-while b f pat = sew b (f pat) pat--{-|-@stutter n t pat@ repeats each event in @pat@ @n@ times, separated by @t@ time (in fractions of a cycle).-It is like 'Sound.Tidal.Control.echo' that doesn't reduce the volume, or 'ply' if you controlled the timing.--@-d1 $ stutter 4 (1/16) $ s "bd cp"-@--is functionally equivalent to-@-d1 $ stut 4 1 (1/16) $ s "bd cp"-@--}-stutter :: Integral i => i -> Time -> Pattern a -> Pattern a-stutter n t p = stack $ map (\i -> (t * fromIntegral i) `rotR` p) [0 .. (n-1)]--{- | The `jux` function creates strange stereo effects, by applying a-function to a pattern, but only in the right-hand channel. For-example, the following reverses the pattern on the righthand side:--@-d1 $ slow 32 $ jux (rev) $ striateBy 32 (1/16) $ sound "bev"-@--When passing pattern transforms to functions like [jux](#jux) and [every](#every),-it's possible to chain multiple transforms together with `.`, for-example this both reverses and halves the playback speed of the-pattern in the righthand channel:--@-d1 $ slow 32 $ jux ((# speed "0.5") . rev) $ striateBy 32 (1/16) $ sound "bev"-@--}-jux- :: (Pattern ValueMap -> Pattern ValueMap)- -> Pattern ValueMap -> Pattern ValueMap-jux = juxBy 1-juxcut- :: (Pattern ValueMap -> Pattern ValueMap)- -> Pattern ValueMap -> Pattern ValueMap-juxcut f p = stack [p # P.pan (pure 0) # P.cut (pure (-1)),- f $ p # P.pan (pure 1) # P.cut (pure (-2))- ]--juxcut' :: [t -> Pattern ValueMap] -> t -> Pattern ValueMap-juxcut' fs p = stack $ map (\n -> ((fs !! n) p |+ P.cut (pure $ 1-n)) # P.pan (pure $ fromIntegral n / fromIntegral l)) [0 .. l-1]- where l = length fs--{- | In addition to `jux`, `jux'` allows using a list of pattern transform. resulting patterns from each transformation will be spread via pan from left to right.--For example:--@-d1 $ jux' [iter 4, chop 16, id, rev, palindrome] $ sound "bd sn"-@--will put `iter 4` of the pattern to the far left and `palindrome` to the far right. In the center the original pattern will play and mid left mid right the chopped and the reversed version will appear.--One could also write:--@-d1 $ stack [- iter 4 $ sound "bd sn" # pan "0",- chop 16 $ sound "bd sn" # pan "0.25",- sound "bd sn" # pan "0.5",- rev $ sound "bd sn" # pan "0.75",- palindrome $ sound "bd sn" # pan "1",- ]-@---}-jux' :: [t -> Pattern ValueMap] -> t -> Pattern ValueMap-jux' fs p = stack $ map (\n -> (fs !! n) p |+ P.pan (pure $ fromIntegral n / fromIntegral l)) [0 .. l-1]- where l = length fs---- | Multichannel variant of `jux`, _not sure what it does_-jux4- :: (Pattern ValueMap -> Pattern ValueMap)- -> Pattern ValueMap -> Pattern ValueMap-jux4 f p = stack [p # P.pan (pure (5/8)), f $ p # P.pan (pure (1/8))]--{- |-With `jux`, the original and effected versions of the pattern are-panned hard left and right (i.e., panned at 0 and 1). This can be a-bit much, especially when listening on headphones. The variant `juxBy`-has an additional parameter, which brings the channel closer to the-centre. For example:--@-d1 $ juxBy 0.5 (density 2) $ sound "bd sn:1"-@--In the above, the two versions of the pattern would be panned at 0.25-and 0.75, rather than 0 and 1.--}-juxBy- :: Pattern Double- -> (Pattern ValueMap -> Pattern ValueMap)- -> Pattern ValueMap- -> Pattern ValueMap-juxBy n f p = stack [p |+ P.pan 0.5 |- P.pan (n/2), f $ p |+ P.pan 0.5 |+ P.pan (n/2)]--{- |-Given a sample's directory name and number, this generates a string-suitable to pass to 'Data.String.fromString' to create a 'Pattern String'.-'samples' is a 'Pattern'-compatible interface to this function.--@pick name n = name ++ ":" ++ show n@--}-pick :: String -> Int -> String-pick name n = name ++ ":" ++ show n--{- |-Given a pattern of sample directory names and a of pattern indices-create a pattern of strings corresponding to the sample at each-name-index pair.--An example:-@samples "jvbass [~ latibro] [jvbass [latibro jvbass]]" ((1%2) `rotL` slow 6 "[1 6 8 7 3]")@--The type signature is more general here, but you can consider this-to be a function of type @Pattern String -> Pattern Int -> Pattern String.--@samples = liftA2 pick@--}-samples :: Applicative f => f String -> f Int -> f String-samples p p' = pick <$> p <*> p'--{- |-Equivalent to 'samples', though the sample specifier pattern-(the @f Int@) will be evaluated first. Not a large difference-in the majority of cases.--}-samples' :: Applicative f => f String -> f Int -> f String-samples' p p' = flip pick <$> p' <*> p--{--scrumple :: Time -> Pattern a -> Pattern a -> Pattern a-scrumple o p p' = p'' -- overlay p (o `rotR` p'')- where p'' = Pattern $ \a -> concatMap- (\((s,d), vs) -> map (\x -> ((s,d),- snd x- )- )- (arc p' (s,s))- ) (arc p a)--}--{-- As 'spread', but specialized so that the list contains functions returning patterns.--@spreadf = 'spread' ($)@--}-spreadf :: [a -> Pattern b] -> a -> Pattern b-spreadf = spread ($)--stackwith :: Unionable a => Pattern a -> [Pattern a] -> Pattern a-stackwith p ps | null ps = silence- | otherwise = stack $ map (\(i, p') -> p' # ((fromIntegral i % l) `rotL` p)) (zip [0::Int ..] ps)- where l = fromIntegral $ length ps--{--cross f p p' = Pattern $ \t -> concat [filter flt $ arc p t,- filter (not . flt) $ arc p' t- ]-] where flt = f . cyclePos . fst . fst--}--{- | `range` will take a pattern which goes from 0 to 1 (like `sine`), and range it to a different range - between the first and second arguments. In the below example, `range 1 1.5` shifts the range of `sine1` from 0 - 1 to 1 - 1.5.--@-d1 $ jux (iter 4) $ sound "arpy arpy:2*2"- |+ speed (slow 4 $ range 1 1.5 sine1)-@--}-range :: Num a => Pattern a -> Pattern a -> Pattern a -> Pattern a-range fromP toP p = (\from to v -> ((v * (to-from)) + from)) <$> fromP *> toP *> p--_range :: (Functor f, Num b) => b -> b -> f b -> f b-_range from to p = (+ from) . (* (to-from)) <$> p--{- | `rangex` is an exponential version of `range`, good for using with-frequencies. Do *not* use negative numbers or zero as arguments! -}-rangex :: (Functor f, Floating b) => b -> b -> f b -> f b-rangex from to p = exp <$> _range (log from) (log to) p--off :: Pattern Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-off tp f p = innerJoin $ (\tv -> _off tv f p) <$> tp--_off :: Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-_off t f p = superimpose (f . (t `rotR`)) p--offadd :: Num a => Pattern Time -> Pattern a -> Pattern a -> Pattern a-offadd tp pn p = off tp (+pn) p---- | Step sequencing-step :: String -> String -> Pattern String-step s cs = fastcat $ map f cs- where f c | c == 'x' = pure s- | isDigit c = pure $ s ++ ":" ++ [c]- | otherwise = silence--steps :: [(String, String)] -> Pattern String-steps = stack . map (uncurry step)---- | like `step`, but allows you to specify an array of strings to use for 0,1,2...-step' :: [String] -> String -> Pattern String-step' ss cs = fastcat $ map f cs- where f c | c == 'x' = pure $ head ss- | isDigit c = pure $ ss !! digitToInt c- | otherwise = silence----- | Deprecated backwards-compatible alias for 'ghostWith'.-ghost'' :: Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-ghost'' = ghostWith---- | Like 'ghost'', but a user-supplied function describes how to alter the pattern.-ghostWith :: Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-ghostWith a f p = superimpose (((a*2.5) `rotR`) . f) $ superimpose (((a*1.5) `rotR`) . f) p--{--@ghost' t pat@ Adds quieter, pitch-shifted, copies of an event @t@ cycles after events in @pat@, emulating ghost notes that are common in drumming patterns.--}-ghost' :: Time -> Pattern ValueMap -> Pattern ValueMap-ghost' a p = ghostWith a ((|*| P.gain (pure 0.7)) . (|> P.end (pure 0.2)) . (|*| P.speed (pure 1.25))) p--{-| As 'ghost', but with the copies set to appear one-eighth of a cycle afterwards.--@ghost = ghost' 0.125@--}-ghost :: Pattern ValueMap -> Pattern ValueMap-ghost = ghost' 0.125--{- | A more literal weaving than the `weave` function. Given @tabby threads p1 p@,- parameters representing the threads per cycle and the patterns to weave, and- this function will weave them together using a plain (aka ’tabby’) weave,- with a simple over/under structure- -}-tabby :: Int -> Pattern a -> Pattern a -> Pattern a-tabby nInt p p' = stack [maskedWarp,- maskedWeft- ]- where- n = fromIntegral nInt- weft = concatMap (const [[0..n-1], reverse [0..n-1]]) [0 .. (n `div` 2) - 1]- warp = transpose weft- thread xs p'' = _slow (n%1) $ fastcat $ map (\i -> zoomArc (Arc (i%n) ((i+1)%n)) p'') (concat xs)- weftP = thread weft p'- warpP = thread warp p- maskedWeft = mask (every 2 rev $ _fast (n % 2) $ fastCat [silence, pure True]) weftP- maskedWarp = mask (every 2 rev $ _fast (n % 2) $ fastCat [pure True, silence]) warpP---- | chooses between a list of patterns, using a pattern of floats (from 0-1)-select :: Pattern Double -> [Pattern a] -> Pattern a-select = tParam _select--_select :: Double -> [Pattern a] -> Pattern a-_select f ps = ps !! floor (max 0 (min 1 f) * fromIntegral (length ps - 1))---- | chooses between a list of functions, using a pattern of floats (from 0-1)-selectF :: Pattern Double -> [Pattern a -> Pattern a] -> Pattern a -> Pattern a-selectF pf ps p = innerJoin $ (\f -> _selectF f ps p) <$> pf--_selectF :: Double -> [Pattern a -> Pattern a] -> Pattern a -> Pattern a-_selectF f ps p = (ps !! floor (max 0 (min 0.999999 f) * fromIntegral (length ps))) p---- | chooses between a list of functions, using a pattern of integers-pickF :: Pattern Int -> [Pattern a -> Pattern a] -> Pattern a -> Pattern a-pickF pInt fs pat = innerJoin $ (\i -> _pickF i fs pat) <$> pInt--_pickF :: Int -> [Pattern a -> Pattern a] -> Pattern a -> Pattern a-_pickF i fs p = (fs !!! i) p---- | @contrast p f f' p'@ splits the control pattern @p'@ in two, applying--- the function @f@ to one and @f'@ to the other. This depends on--- whether events in it contains values matching with those in @p@.--- For example in @contrast (# crush 3) (# vowel "a") (n "1") $ n "0 1" # s "bd sn" # speed 3@,--- the first event will have the vowel effect applied and the second--- will have the crush applied.-contrast :: (ControlPattern -> ControlPattern) -> (ControlPattern -> ControlPattern)- -> ControlPattern -> ControlPattern -> ControlPattern-contrast = contrastBy (==)--contrastBy :: (a -> Value -> Bool)- -> (ControlPattern -> Pattern b)- -> (ControlPattern -> Pattern b)- -> Pattern (Map.Map String a)- -> Pattern (Map.Map String Value)- -> Pattern b-contrastBy comp f f' p p' = overlay (f matched) (f' unmatched)- where matches = matchManyToOne (flip $ Map.isSubmapOfBy comp) p p'- matched :: ControlPattern- matched = filterJust $ (\(t, a) -> if t then Just a else Nothing) <$> matches- unmatched :: ControlPattern- unmatched = filterJust $ (\(t, a) -> if not t then Just a else Nothing) <$> matches--contrastRange- :: (ControlPattern -> Pattern a)- -> (ControlPattern -> Pattern a)- -> Pattern (Map.Map String (Value, Value))- -> ControlPattern- -> Pattern a-contrastRange = contrastBy f- where f (VI s, VI e) (VI v) = v >= s && v <= e- f (VF s, VF e) (VF v) = v >= s && v <= e- f (VN s, VN e) (VN v) = v >= s && v <= e- f (VS s, VS e) (VS v) = v == s && v == e- f _ _ = False---- | Like @contrast@, but one function is given, and applied to events with matching controls.-fix :: (ControlPattern -> ControlPattern) -> ControlPattern -> ControlPattern -> ControlPattern-fix f = contrast f id---- | Like @contrast@, but one function is given, and applied to events--- with controls which don't match.-unfix :: (ControlPattern -> ControlPattern) -> ControlPattern -> ControlPattern -> ControlPattern-unfix = contrast id--fixRange :: (ControlPattern -> Pattern ValueMap)- -> Pattern (Map.Map String (Value, Value))- -> ControlPattern- -> ControlPattern-fixRange f = contrastRange f id--unfixRange :: (ControlPattern -> Pattern ValueMap)- -> Pattern (Map.Map String (Value, Value))- -> ControlPattern- -> ControlPattern-unfixRange = contrastRange id---- | Limits values in a Pattern (or other Functor) to n equally spaced--- divisions of 1.-quantise :: (Functor f, RealFrac b) => b -> f b -> f b-quantise n = fmap ((/n) . (fromIntegral :: RealFrac b => Int -> b) . round . (*n))---- | As 'quantise', but uses 'Prelude.floor' to calculate divisions.-qfloor :: (Functor f, RealFrac b) => b -> f b -> f b-qfloor n = fmap ((/n) . (fromIntegral :: RealFrac b => Int -> b) . floor . (*n))---- | As 'quantise', but uses 'Prelude.ceiling' to calculate divisions.-qceiling :: (Functor f, RealFrac b) => b -> f b -> f b-qceiling n = fmap ((/n) . (fromIntegral :: RealFrac b => Int -> b) . ceiling . (*n))---- | An alias for 'quantise'.-qround :: (Functor f, RealFrac b) => b -> f b -> f b-qround = quantise---- | Inverts all the values in a boolean pattern-inv :: Functor f => f Bool -> f Bool-inv = (not <$>)---- | Serialises a pattern so there's only one event playing at any one--- time, making it /monophonic/. Events which start/end earlier are given priority.-mono :: Pattern a -> Pattern a-mono p = Pattern $ \(State a cm) -> flatten $ query p (State a cm) where- flatten :: [Event a] -> [Event a]- flatten = mapMaybe constrainPart . truncateOverlaps . sortOn whole- truncateOverlaps [] = []- truncateOverlaps (e:es) = e : truncateOverlaps (mapMaybe (snip e) es)- -- TODO - decide what to do about analog events..- snip a b | start (wholeOrPart b) >= stop (wholeOrPart a) = Just b- | stop (wholeOrPart b) <= stop (wholeOrPart a) = Nothing- | otherwise = Just b {whole = Just $ Arc (stop $ wholeOrPart a) (stop $ wholeOrPart b)}- constrainPart :: Event a -> Maybe (Event a)- constrainPart e = do a <- subArc (wholeOrPart e) (part e)- return $ e {part = a}--{-|-@smooth@ receives a pattern of numbers and linearly goes from one to the next, passing through all of them. As time is cycle-based, after reaching the last number in the pattern, it will smoothly go to the first one again.--@- d1 $ sound "bd*4" # pan (slow 4 $ smooth "0 1 0.5 1")-@--This sound will pan gradually from left to right, then to the center, then to the right again, and finally comes back to the left.---}---- serialize the given pattern--- find the middle of the query's arc and use that to query the serialized pattern. We should get either no events or a single event back--- if we don't get any events, return nothing--- if we get an event, get the stop of its arc, and use that to query the serialized pattern, to see if there's an adjoining event--- if there isn't, return the event as-is.--- if there is, check where we are in the 'whole' of the event, and use that to tween between the values of the event and the next event--- smooth :: Pattern Double -> Pattern Double---- TODO - test this with analog events-smooth :: Fractional a => Pattern a -> Pattern a-smooth p = Pattern $ \st@(State a cm) -> tween st a $ query monoP (State (midArc a) cm)- where- midArc a = Arc (mid (start a, stop a)) (mid (start a, stop a))- tween _ _ [] = []- tween st queryA (e:_) = maybe [e {whole = Just queryA, part = queryA}] (tween' queryA) (nextV st)- where aStop = Arc (wholeStop e) (wholeStop e)- nextEs st' = query monoP (st' {arc = aStop})- nextV st' | null (nextEs st') = Nothing- | otherwise = Just $ value (head (nextEs st'))- tween' queryA' v =- [ Event- { context = context e,- whole = Just queryA'- , part = queryA'- , value = value e + ((v - value e) * pc)}- ]- pc | delta' (wholeOrPart e) == 0 = 0- | otherwise = fromRational $ (eventPartStart e - wholeStart e) / delta' (wholeOrPart e)- delta' a = stop a - start a- monoP = mono p---- | Looks up values from a list of tuples, in order to swap values in the given pattern-swap :: Eq a => [(a, b)] -> Pattern a -> Pattern b-swap things p = filterJust $ (`lookup` things) <$> p--{-|- @snowball@ takes a function that can combine patterns (like '+'),- a function that transforms a pattern (like 'slow'),- a depth, and a starting pattern,- it will then transform the pattern and combine it with the last transformation until the depth is reached.- This is like putting an effect (like a filter) in the feedback of a delay line; each echo is more affected.-- @d1 $ note (scale "hexDorian" $ snowball 8 (+) (slow 2 . rev) "0 ~ . -1 . 5 3 4 . ~ -2") # s "gtr"@--}-snowball :: Int -> (Pattern a -> Pattern a -> Pattern a) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-snowball depth combinationFunction f pattern = cat $ take depth $ scanl combinationFunction pattern $ drop 1 $ iterate f pattern--{- @soak@ |- applies a function to a pattern and cats the resulting pattern,- then continues applying the function until the depth is reached- this can be used to create a pattern that wanders away from- the original pattern by continually adding random numbers- d1 $ note (scale "hexDorian" mutateBy (+ (range -1 1 $ irand 2)) 8 $ "0 1 . 2 3 4") # s "gtr"--}-soak :: Int -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a-soak depth f pattern = cat $ take depth $ iterate f pattern---- | @construct n p@ breaks @p@ into pieces and then reassembles them--- so that it fits into @n@ steps.-deconstruct :: Int -> Pattern String -> String-deconstruct n p = intercalate " " $ map showStep $ toList p- where- showStep :: [String] -> String- showStep [] = "~"- showStep [x] = x- showStep xs = "[" ++ (intercalate ", " xs) ++ "]"- toList :: Pattern a -> [[a]]- toList pat = map (\(s,e) -> map value $ queryArc (_segment n' pat) (Arc s e)) arcs- where breaks = [0, (1/n') ..]- arcs = zip (take n breaks) (drop 1 breaks)- n' = fromIntegral n--{- | @bite n ipat pat@ slices a pattern @pat@ into @n@ pieces, then uses the- @ipat@ pattern of integers to index into those slices. So @bite 4 "0 2*2" (run- 8)@ is the same as @"[0 1] [4 5]*2"@.--}-bite :: Pattern Int -> Pattern Int -> Pattern a -> Pattern a-bite npat ipat pat = innerJoin $ (\n -> _bite n ipat pat) <$> npat--_bite :: Int -> Pattern Int -> Pattern a -> Pattern a-_bite n ipat pat = squeezeJoin $ zoompat <$> ipat- where zoompat i = zoom (i'/(fromIntegral n), (i'+1)/(fromIntegral n)) pat- where i' = fromIntegral $ i `mod` n--{- | @squeeze@ uses a pattern of integers to index into a list of patterns.--}-squeeze :: Pattern Int -> [Pattern a] -> Pattern a-squeeze _ [] = silence-squeeze ipat pats = squeezeJoin $ (pats !!!) <$> ipat--squeezeJoinUp :: Pattern (ControlPattern) -> ControlPattern-squeezeJoinUp pp = pp {query = q}- where q st = concatMap (f st) (query (filterDigital pp) st)- f st (Event c (Just w) p v) =- mapMaybe (munge c w p) $ query (compressArc (cycleArc w) (v |* P.speed (pure $ fromRational $ 1/(stop w - start w)))) st {arc = p}- -- already ignoring analog events, but for completeness..- f _ _ = []- munge co oWhole oPart (Event ci (Just iWhole) iPart v) =- do w' <- subArc oWhole iWhole- p' <- subArc oPart iPart- return (Event (combineContexts [ci,co]) (Just w') p' v)- munge _ _ _ _ = Nothing--_chew :: Int -> Pattern Int -> ControlPattern -> ControlPattern-_chew n ipat pat = (squeezeJoinUp $ zoompat <$> ipat) |/ P.speed (pure $ fromIntegral n)- where zoompat i = zoom (i'/(fromIntegral n), (i'+1)/(fromIntegral n)) (pat)- where i' = fromIntegral $ i `mod` n--{-|-@chew@ works the same as 'bite', but speeds up\/slows down playback of sounds as well as squeezing/contracting the slices of the provided pattern.--}---- TODO maybe _chew could pattern the first parameter directly..-chew :: Pattern Int -> Pattern Int -> ControlPattern -> ControlPattern-chew npat ipat pat = innerJoin $ (\n -> _chew n ipat pat) <$> npat--__binary :: Data.Bits.Bits b => Int -> b -> [Bool]-__binary n num = map (testBit num) $ reverse [0 .. n-1]--_binary :: Data.Bits.Bits b => Int -> b -> Pattern Bool-_binary n num = listToPat $ __binary n num--_binaryN :: Int -> Pattern Int -> Pattern Bool-_binaryN n p = squeezeJoin $ _binary n <$> p--binaryN :: Pattern Int -> Pattern Int -> Pattern Bool-binaryN n p = tParam _binaryN n p--binary :: Pattern Int -> Pattern Bool-binary = binaryN 8--ascii :: Pattern String -> Pattern Bool-ascii p = squeezeJoin $ (listToPat . concatMap (__binary 8 . ord)) <$> p---- | Given a start point and a duration (both specified in cycles), this--- generates a control pattern that makes a sound begin at the start--- point and last the duration.------ @grain s d = 'Sound.Tidal.Params.begin' s # 'Sound.Tidal.Params.end' (s+d)@-grain :: Pattern Double -> Pattern Double -> ControlPattern-grain s w = P.begin b # P.end e- where b = s- e = s + w---- | For specifying a boolean pattern according to a list of offsets--- (aka inter-onset intervals). For example `necklace 12 [4,2]` is+See George Marsaglia (2003). ["Xorshift RNGs"](https://www.jstatsoft.org/article/view/v008i14),+in Journal of Statistical Software, pages 8–14.++-}+xorwise :: Int -> Int+xorwise x =+ let a = xor (shiftL x 13) x+ b = xor (shiftR a 17) a+ in xor (shiftL b 5) b++-- stretch 300 cycles over the range of [0,2**29 == 536870912) then apply the xorshift algorithm+timeToIntSeed :: RealFrac a => a -> Int+timeToIntSeed = xorwise . truncate . (* 536870912) . snd . (properFraction :: (RealFrac a => a -> (Int,a))) . (/ 300)++intSeedToRand :: Fractional a => Int -> a+intSeedToRand = (/ 536870912) . realToFrac . (`mod` 536870912)++timeToRand :: (RealFrac a, Fractional b) => a -> b+timeToRand = intSeedToRand . timeToIntSeed++timeToRands :: (RealFrac a, Fractional b) => a -> Int -> [b]+timeToRands t n = timeToRands' (timeToIntSeed t) n++timeToRands' :: Fractional a => Int -> Int -> [a]+timeToRands' seed n+ | n <= 0 = []+ | otherwise = (intSeedToRand seed) : (timeToRands' (xorwise seed) (n-1))++{-|++@rand@ is an oscillator that generates a continuous pattern of (pseudo-)random+numbers between 0 and 1.++For example, to randomly pan around the stereo field:++> d1 $ sound "bd*8" # pan rand++Or to enjoy a randomised speed from 0.5 to 1.5, add 0.5 to it:++> d1 $ sound "arpy*4" # speed (rand + 0.5)++To make the snares randomly loud and quiet:++> sound "sn sn ~ sn" # gain rand++Numbers coming from this pattern are \'seeded\' by time. So if you reset time+(using 'resetCycles', 'setCycle', or 'cps') the random pattern will emit the+exact same _random_ numbers again.++In cases where you need two different random patterns, you can shift+one of them around to change the time from which the _random_ pattern+is read, note the difference:++> jux (# gain rand) $ sound "sn sn ~ sn" # gain rand++and with the juxed version shifted backwards for 1024 cycles:++> jux (# ((1024 <~) $ gain rand)) $ sound "sn sn ~ sn" # gain rand+-}+rand :: Fractional a => Pattern a+rand = Pattern (\(State a@(Arc s e) _) -> [Event (Context []) Nothing a (realToFrac $ (timeToRand ((e + s)/2) :: Double))])++-- | Boolean rand - a continuous stream of true\/false values, with a 50\/50 chance.+brand :: Pattern Bool+brand = _brandBy 0.5++-- | Boolean rand with probability as input, e.g. @brandBy 0.25@ produces trues 25% of the time.+brandBy :: Pattern Double -> Pattern Bool+brandBy probpat = innerJoin $ (\prob -> _brandBy prob) <$> probpat++_brandBy :: Double -> Pattern Bool+_brandBy prob = fmap (< prob) rand++{- | Just like `rand` but for whole numbers, @irand n@ generates a pattern of (pseudo-) random whole numbers between @0@ to @n-1@ inclusive. Notably used to pick a random+samples from a folder:++@+d1 $ segment 4 $ n (irand 5) # sound "drum"+@+-}+irand :: Num a => Pattern Int -> Pattern a+irand = (>>= _irand)++_irand :: Num a => Int -> Pattern a+_irand i = fromIntegral . (floor :: Double -> Int) . (* fromIntegral i) <$> rand++{- | 1D Perlin (smooth) noise, works like 'rand' but smoothly moves between random+values each cycle. @perlinWith@ takes a pattern as the random number generator's+"input" instead of automatically using the cycle count.++> d1 $ s "arpy*32" # cutoff (perlinWith (saw * 4) * 2000)++will generate a smooth random pattern for the cutoff frequency which will+repeat every cycle (because the saw does).++The `perlin` function uses the cycle count as input and can be used much like @rand@.+-}+perlinWith :: Fractional a => Pattern Double -> Pattern a+perlinWith p = fmap realToFrac $ (interp) <$> (p-pa) <*> (timeToRand <$> pa) <*> (timeToRand <$> pb) where+ pa = (fromIntegral :: Int -> Double) . floor <$> p+ pb = (fromIntegral :: Int -> Double) . (+1) . floor <$> p+ interp x a b = a + smootherStep x * (b-a)+ smootherStep x = 6.0 * x**5 - 15.0 * x**4 + 10.0 * x**3++{- | As 'perlin' with a suitable choice of input pattern (@'sig' 'fromRational'@).++ The @perlin@ function produces a new random value to move to every cycle. If+ you want a new random value to be generated more or less frequently, you can use+ fast or slow, respectively:++ > d1 $ sound "bd*32" # speed (fast 4 $ perlin + 0.5)+ > d1 $ sound "bd*32" # speed (slow 4 $ perlin + 0.5)+-}+perlin :: Fractional a => Pattern a+perlin = perlinWith (sig fromRational)++{-| @perlin2With@ is Perlin noise with a 2-dimensional input. This can be+useful for more control over how the randomness repeats (or doesn't).++@+d1+ $ s "[supersaw:-12*32]"+ # lpf (rangex 60 5000 $ perlin2With (cosine*2) (sine*2))+ # lpq 0.3+@++The above will generate a smooth random cutoff pattern that repeats every cycle+without any reversals or discontinuities (because the 2D path is a circle).++See also: `perlin2`, which only needs one input because it uses the cycle count+as the second input.+-}+perlin2With :: Pattern Double -> Pattern Double -> Pattern Double+perlin2With x y = (/2) . (+1) $ interp2 <$> xfrac <*> yfrac <*> dota <*> dotb <*> dotc <*> dotd where+ fl = fmap ((fromIntegral :: Int -> Double) . floor)+ ce = fmap ((fromIntegral :: Int -> Double) . (+1) . floor)+ xfrac = x - fl x+ yfrac = y - fl y+ randAngle a b = 2 * pi * timeToRand (a + 0.0001 * b)+ pcos x' y' = cos $ randAngle <$> x' <*> y'+ psin x' y' = sin $ randAngle <$> x' <*> y'+ dota = pcos (fl x) (fl y) * xfrac + psin (fl x) (fl y) * yfrac+ dotb = pcos (ce x) (fl y) * (xfrac - 1) + psin (ce x) (fl y) * yfrac+ dotc = pcos (fl x) (ce y) * xfrac + psin (fl x) (ce y) * (yfrac - 1)+ dotd = pcos (ce x) (ce y) * (xfrac - 1) + psin (ce x) (ce y) * (yfrac - 1)+ interp2 x' y' a b c d = (1.0 - s x') * (1.0 - s y') * a + s x' * (1.0 - s y') * b+ + (1.0 - s x') * s y' * c + s x' * s y' * d+ s x' = 6.0 * x'**5 - 15.0 * x'**4 + 10.0 * x'**3++-- | As 'perlin2' with a suitable choice of input pattern (@'sig' 'fromRational'@).+perlin2 :: Pattern Double -> Pattern Double+perlin2 = perlin2With (sig fromRational)++{- | Randomly picks an element from the given list.++@+sound "superpiano(3,8)" # note (choose ["a", "e", "g", "c"])+@++plays a melody randomly choosing one of the four notes \"a\", \"e\", \"g\", \"c\".++As with all continuous patterns, you have to be careful to give them structure; in this case choose gives you an infinitely detailed stream of random choices.++> choose = 'chooseBy' 'rand'+-}+choose :: [a] -> Pattern a+choose = chooseBy rand+++{- | Given a pattern of doubles, @chooseBy@ normalizes them so that each+corresponds to an index in the provided list. The returned pattern+contains the corresponding elements in the list.++It is like choose, but instead of selecting elements of the list randomly, it+uses the given pattern to select elements.++@'choose' = chooseBy 'rand'@++The following results in the pattern @"a b c"@:++> chooseBy "0 0.25 0.5" ["a","b","c","d"]+-}+chooseBy :: Pattern Double -> [a] -> Pattern a+chooseBy _ [] = silence+chooseBy f xs = (xs !!!) . floor <$> range 0 (fromIntegral $ length xs) f++{- | Like @choose@, but works on an a list of tuples of values and weights++@+sound "superpiano(3,8)" # note (wchoose [("a",1), ("e",0.5), ("g",2), ("c",1)])+@++In the above example, the "a" and "c" notes are twice as likely to+play as the "e" note, and half as likely to play as the "g" note.++> wchoose = 'wchooseBy' 'rand'+-}+wchoose :: [(a,Double)] -> Pattern a+wchoose = wchooseBy rand++{- | Given a pattern of probabilities and a list of @(value, weight)@ pairs,+@wchooseBy@ creates a @'Pattern' value@ by choosing values based on those+probabilities and weighted appropriately by the weights in the list of pairs.+-}+wchooseBy :: Pattern Double -> [(a,Double)] -> Pattern a+wchooseBy pat pairs = match <$> pat+ where+ match r = values !! head (findIndices (> (r*total)) cweights)+ cweights = scanl1 (+) (map snd pairs)+ values = map fst pairs+ total = sum $ map snd pairs++{-| @randcat ps@: does a @slowcat@ on the list of patterns @ps@ but+ randomises the order in which they are played.++ > d1 $ sound (randcat ["bd*2 sn", "jvbass*3", "drum*2", "ht mt"])+-}+randcat :: [Pattern a] -> Pattern a+randcat ps = spread' rotL (_segment 1 $ (% 1) . fromIntegral <$> (_irand (length ps) :: Pattern Int)) (slowcat ps)++{-| As 'randcat', but allowing weighted choice.++ In the following, the first pattern is the most likely and will play about half the time, and the last pattern is the less likely, with only a 10% probability.++ > d1 $ sound+ > $ wrandcat+ > [ ("bd*2 sn", 5), ("jvbass*3", 2), ("drum*2", 2), ("ht mt", 1) ]+-}+wrandcat :: [(Pattern a, Double)] -> Pattern a+wrandcat ps = unwrap $ wchooseBy (segment 1 rand) ps++{- | @degrade@ randomly removes events from a pattern 50% of the time:++> d1 $ slow 2 $ degrade $ sound "[[[feel:5*8,feel*3] feel:3*8], feel*4]"+> # accelerate "-6"+> # speed "2"++The shorthand syntax for @degrade@ is a question mark: @?@. Using @?@+will allow you to randomly remove events from a portion of a pattern:++> d1 $ slow 2 $ sound "bd ~ sn bd ~ bd? [sn bd?] ~"++You can also use @?@ to randomly remove events from entire sub-patterns:++> d1 $ slow 2 $ sound "[[[feel:5*8,feel*3] feel:3*8]?, feel*4]"+-}+degrade :: Pattern a -> Pattern a+degrade = _degradeBy 0.5++{- |+Similar to `degrade`, @degradeBy@ allows you to control the percentage of events that+are removed. For example, to remove events 90% of the time:++@+d1 $ slow 2 $ degradeBy 0.9 $ sound "[[[feel:5*8,feel*3] feel:3*8], feel*4]"+ # accelerate "-6"+ # speed "2"+@++You can also invoke this behavior in the shorthand notation by specifying a percentage, as a+number between 0 and 1, after the question mark:++@+d1 $ s "bd hh?0.8 bd hh?0.4"+@+-}+degradeBy :: Pattern Double -> Pattern a -> Pattern a+degradeBy = tParam _degradeBy++_degradeBy :: Double -> Pattern a -> Pattern a+_degradeBy = _degradeByUsing rand++-- Useful for manipulating random stream, e.g. to change 'seed'+_degradeByUsing :: Pattern Double -> Double -> Pattern a -> Pattern a+_degradeByUsing prand x p = fmap fst $ filterValues ((> x) . snd) $ (,) <$> p <* prand++{-|+As 'degradeBy', but the pattern of probabilities represents the chances to retain rather+than remove the corresponding element.+-}+unDegradeBy :: Pattern Double -> Pattern a -> Pattern a+unDegradeBy = tParam _unDegradeBy++_unDegradeBy :: Double -> Pattern a -> Pattern a+_unDegradeBy x p = fmap fst $ filterValues ((<= x) . snd) $ (,) <$> p <* rand++degradeOverBy :: Int -> Pattern Double -> Pattern a -> Pattern a+degradeOverBy i tx p = unwrap $ (\x -> fmap fst $ filterValues ((> x) . snd) $ (,) <$> p <* fastRepeatCycles i rand) <$> slow (fromIntegral i) tx+++{- | Use @sometimesBy@ to apply a given function "sometimes". For example, the+following code results in @density 2@ being applied about 25% of the time:++@+d1 $ sometimesBy 0.25 (density 2) $ sound "bd*8"+@++There are some aliases as well:++@+'sometimes' = sometimesBy 0.5+'often' = sometimesBy 0.75+'rarely' = sometimesBy 0.25+'almostNever' = sometimesBy 0.1+'almostAlways' = sometimesBy 0.9+@+-}+sometimesBy :: Pattern Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+sometimesBy x f pat = overlay (degradeBy x pat) (f $ unDegradeBy x pat)++{- | As 'sometimesBy', but applies the given transformation to the pattern in its entirety+before filtering its actual appearances. Less efficient than 'sometimesBy' but may+be useful when the passed pattern transformation depends on properties of the+pattern before probabilities are taken into account.++@+'sometimes'' = sometimesBy' 0.5+'often'' = sometimesBy' 0.75+'rarely'' = sometimesBy' 0.25+'almostNever'' = sometimesBy' 0.1+'almostAlways'' = sometimesBy' 0.9+@+-}+sometimesBy' :: Pattern Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+sometimesBy' x f pat = overlay (degradeBy x pat) (unDegradeBy x $ f pat)++-- | @sometimes@ is an alias for @'sometimesBy' 0.5@.+sometimes :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+sometimes = sometimesBy 0.5++-- | @sometimes'@ is an alias for @'sometimesBy'' 0.5@.+sometimes' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+sometimes' = sometimesBy' 0.5++-- | @often@ is an alias for @'sometimesBy' 0.75@.+often :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+often = sometimesBy 0.75++-- | @often'@ is an alias for @'sometimesBy'' 0.75@.+often' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+often' = sometimesBy' 0.75++-- | @rarely@ is an alias for @'sometimesBy' 0.25@.+rarely :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+rarely = sometimesBy 0.25++-- | @rarely'@ is an alias for @'sometimesBy'' 0.25@.+rarely' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+rarely' = sometimesBy' 0.25++-- | @almostNever@ is an alias for @'sometimesBy' 0.1@.+almostNever :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+almostNever = sometimesBy 0.1++-- | @almostNever'@ is an alias for @'sometimesBy'' 0.1@.+almostNever' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+almostNever' = sometimesBy 0.1++-- | @almostAlways@ is an alias for @'sometimesBy' 0.9@.+almostAlways :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+almostAlways = sometimesBy 0.9++-- | @almostAlways'@ is an alias for @'sometimesBy'' 0.9@.+almostAlways' :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+almostAlways' = sometimesBy' 0.9++{-|+Never apply a transformation, returning the pattern unmodified.++@never = flip const@+-}++never :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+never = flip const++{-|+Apply the transformation to the pattern unconditionally.++@always = id@+-}+always :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+always = id++{- | @someCyclesBy@ is a cycle-by-cycle version of @'sometimesBy'@.++ For example the following will either distort all of the events in a cycle, or+ none of them:++ > d1 $ someCyclesBy 0.5 (# crush 2) $ n "0 1 [~ 2] 3" # sound "arpy"+-}+someCyclesBy :: Pattern Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+someCyclesBy pd f pat = innerJoin $ (\d -> _someCyclesBy d f pat) <$> pd++_someCyclesBy :: Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+_someCyclesBy x = when test+ where test c = timeToRand (fromIntegral c :: Double) < x++-- | Alias of 'someCyclesBy'.+somecyclesBy :: Pattern Double -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+somecyclesBy = someCyclesBy++-- | @someCycles = 'someCyclesBy' 0.5@+someCycles :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+someCycles = someCyclesBy 0.5++-- | Alias of 'someCycles'.+somecycles :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+somecycles = someCycles++-- ** Pattern transformations+--+-- $patternTransformations+--+-- Pattern transformations are functions generally of type+-- @'Pattern' a -> 'Pattern' a@. This means they take a pattern of any type+-- and return a pattern of that type.++{-|+@brak@ makes a pattern sound a bit like a breakbeat. It does this by, every+other cycle, squashing the pattern to fit half a cycle, and offsetting it by a+quarter of a cycle.++@+d1 $ sound (brak "bd sn kurt")+d1 $ brak $ sound "[feel feel:3, hc:3 hc:2 hc:4 ho:1]"+@+-}+brak :: Pattern a -> Pattern a+brak = when ((== 1) . (`mod` 2)) (((1%4) `rotR`) . (\x -> fastcat [x, silence]))++{- | Divides a pattern into a given number of subdivisions, plays the subdivisions+in order, but increments the starting subdivision each cycle. The pattern+wraps to the first subdivision after the last subdivision is played.++Example:++@+d1 $ iter 4 $ sound "bd hh sn cp"+@++This will produce the following over four cycles:++@+bd hh sn cp+hh sn cp bd+sn cp bd hh+cp bd hh sn+@++There is also `iter'`, which shifts the pattern in the opposite direction.++-}+iter :: Pattern Int -> Pattern c -> Pattern c+iter = tParam _iter++_iter :: Int -> Pattern a -> Pattern a+_iter n p = slowcat $ map (\i -> (fromIntegral i % fromIntegral n) `rotL` p) [0 .. (n-1)]++{- | @iter'@ is the same as @iter@, but decrements the starting+subdivision instead of incrementing it. For example,++@+d1 $ iter' 4 $ sound "bd hh sn cp"+@++produces++@+bd hh sn cp+cp bd hh sn+sn cp bd hh+hh sn cp bd+@+-}+iter' :: Pattern Int -> Pattern c -> Pattern c+iter' = tParam _iter'++_iter' :: Int -> Pattern a -> Pattern a+_iter' n p = slowcat $ map (\i -> (fromIntegral i % fromIntegral n) `rotR` p) [0 .. (n-1)]++{- | @palindrome p@ applies @rev@ to @p@ every other cycle, so that the pattern+alternates between forwards and backwards. For example, these are equivalent:++@+d1 $ palindrome $ sound "arpy:0 arpy:1 arpy:2 arpy:3"+d1 $ slow 2 $ sound "arpy:0 arpy:1 arpy:2 arpy:3 arpy:3 arpy:2 arpy:1 arpy:0"+d1 $ every 2 rev $ sound "arpy:0 arpy:1 arpy:2 arpy:3"+@+-}+palindrome :: Pattern a -> Pattern a+palindrome p = slowAppend p (rev p)++-- | Degrades a pattern over the given time.+fadeOut :: Time -> Pattern a -> Pattern a+fadeOut dur p = innerJoin $ (`_degradeBy` p) <$> _slow dur envL++-- | Alternate version to @fadeOut@ where you can provide the time from which the fade starts+fadeOutFrom :: Time -> Time -> Pattern a -> Pattern a+fadeOutFrom from dur p = innerJoin $ (`_degradeBy` p) <$> (from `rotR` _slow dur envL)++-- | ’Undegrades’ a pattern over the given time.+fadeIn :: Time -> Pattern a -> Pattern a+fadeIn dur p = innerJoin $ (`_degradeBy` p) <$> _slow dur envLR++-- | Alternate version to @fadeIn@ where you can provide the time from+-- which the fade in starts+fadeInFrom :: Time -> Time -> Pattern a -> Pattern a+fadeInFrom from dur p = innerJoin $ (`_degradeBy` p) <$> (from `rotR` _slow dur envLR)++{- | The 'spread' function allows you to take a pattern transformation+which takes a parameter, such as `slow`, and provide several+parameters which are switched between. In other words it "spreads" a+function across several values.++Taking a simple high hat loop as an example:++> d1 $ sound "ho ho:2 ho:3 hc"++We can slow it down by different amounts, such as by a half:++> d1 $ slow 2 $ sound "ho ho:2 ho:3 hc"++Or by four thirds (i.e. speeding it up by a third; @4%3@ means four over+three):++> d1 $ slow (4%3) $ sound "ho ho:2 ho:3 hc"++But if we use `spread`, we can make a pattern which alternates between+the two speeds:++> d1 $ spread slow [2,4%3] $ sound "ho ho:2 ho:3 hc"++Note that if you pass @($)@ as the function to spread values over, you+can put functions as the list of values. ('spreadf' is an alias for @spread ($)@.)+For example:++> d1 $ spread ($) [density 2, rev, slow 2, striate 3, (# speed "0.8")]+> $ sound "[bd*2 [~ bd]] [sn future]*2 cp jvbass*4"++Above, the pattern will have these transforms applied to it, one at a time, per cycle:++* cycle 1: @density 2@ - pattern will increase in speed+* cycle 2: @rev@ - pattern will be reversed+* cycle 3: @slow 2@ - pattern will decrease in speed+* cycle 4: @striate 3@ - pattern will be granualized+* cycle 5: @(# speed "0.8")@ - pattern samples will be played back more slowly++After @(# speed "0.8")@, the transforms will repeat and start at @density 2@ again.+-}+spread :: (a -> t -> Pattern b) -> [a] -> t -> Pattern b+spread f xs p = slowcat $ map (`f` p) xs++-- | An alias for 'spread' consistent with 'fastspread'.+slowspread :: (a -> t -> Pattern b) -> [a] -> t -> Pattern b+slowspread = spread++{- | @fastspread@ works the same as `spread`, but the result is squashed into a single cycle. If you gave four values to @spread@, then the result would seem to speed up by a factor of four. Compare these two:++> d1 $ spread chop [4,64,32,16] $ sound "ho ho:2 ho:3 hc"+> d1 $ fastspread chop [4,64,32,16] $ sound "ho ho:2 ho:3 hc"++There is also `slowspread`, which is an alias of @spread@.+-}+fastspread :: (a -> t -> Pattern b) -> [a] -> t -> Pattern b+fastspread f xs p = fastcat $ map (`f` p) xs++{- | There's a version of this function, `spread'` (pronounced "spread prime"), which takes a /pattern/ of parameters, instead of a list:++> d1 $ spread' slow "2 4%3" $ sound "ho ho:2 ho:3 hc"++This is quite a messy area of Tidal—due to a slight difference of+implementation this sounds completely different! One advantage of+using `spread'` though is that you can provide polyphonic parameters, e.g.:++> d1 $ spread' slow "[2 4%3, 3]" $ sound "ho ho:2 ho:3 hc"+-}+spread' :: Monad m => (a -> b -> m c) -> m a -> b -> m c+spread' f vpat pat = vpat >>= \v -> f v pat++{- | @spreadChoose f xs p@ is similar to `slowspread` but picks values from+@xs@ at random, rather than cycling through them in order.++> d1 $ spreadChoose ($) [gap 4, striate 4] $ sound "ho ho:2 ho:3 hc"+-}+spreadChoose :: (t -> t1 -> Pattern b) -> [t] -> t1 -> Pattern b+spreadChoose f vs p = do v <- _segment 1 (choose vs)+ f v p++-- | A shorter alias for 'spreadChoose'.+spreadr :: (t -> t1 -> Pattern b) -> [t] -> t1 -> Pattern b+spreadr = spreadChoose++{-| Decide whether to apply one or another function depending on the result of a test function, which is passed the current cycle as a number.++@+d1 $ ifp ((== 0) . flip mod 2)+ (striate 4)+ (# coarse "24 48")+ $ sound "hh hc"+@++This will apply @'striate' 4@ for every /even/ cycle and apply @# coarse "24 48"@ for every /odd/.++Detail: As you can see the test function is arbitrary and does not rely on+anything Tidal specific. In fact it uses only plain Haskell functionality, that+is: it calculates the modulo of 2 of the current cycle which is either 0 (for+even cycles) or 1. It then compares this value against 0 and returns the result,+which is either @True@ or @False@. This is what the @ifp@ signature's first part+signifies: @(Int -> Bool)@, a function that takes a whole number and returns+either @True@ or @False@.+-}+ifp :: (Int -> Bool) -> (Pattern a -> Pattern a) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+ifp test f1 f2 p = splitQueries $ p {query = q}+ where q a | test (floor $ start $ arc a) = query (f1 p) a+ | otherwise = query (f2 p) a++-- | @wedge t p p'@ combines patterns @p@ and @p'@ by squashing the+-- @p@ into the portion of each cycle given by @t@, and @p'@ into the+-- remainer of each cycle.+-- > d1 $ wedge (1/4) (sound "bd*2 arpy*3 cp sn*2") (sound "odx [feel future]*2 hh hh")+wedge :: Pattern Time -> Pattern a -> Pattern a -> Pattern a+wedge pt pa pb = innerJoin $ (\t -> _wedge t pa pb) <$> pt++_wedge :: Time -> Pattern a -> Pattern a -> Pattern a+_wedge 0 _ p' = p'+_wedge 1 p _ = p+_wedge t p p' = overlay (_fastGap (1/t) p) (t `rotR` _fastGap (1/(1-t)) p')+++{- | @whenmod@ has a similar form and behavior to `every`, but requires an+additional number. It applies the function to the pattern when the+remainder of the current loop number divided by the first parameter+is greater or equal than the second parameter.++For example, the following makes every other block of four loops twice+as dense:++> d1 $ whenmod 8 4 (density 2) (sound "bd sn kurt")+-}+whenmod :: Pattern Time -> Pattern Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+whenmod a b f pat = innerJoin $ (\a' b' -> _whenmod a' b' f pat) <$> a <*> b++_whenmod :: Time -> Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+_whenmod a b = whenT (\t -> ((t `mod'` a) >= b ))+++{- |+> superimpose f p = stack [p, f p]++@superimpose@ plays a modified version of a pattern at the same time as the+original pattern, resulting in two patterns being played at the same time. The+following are equivalent:++> d1 $ superimpose (fast 2) $ sound "bd sn [cp ht] hh"+> d1 $ stack [sound "bd sn [cp ht] hh",+> fast 2 $ sound "bd sn [cp ht] hh"+> ]++More examples:++> d1 $ superimpose (density 2) $ sound "bd sn [cp ht] hh"+> d1 $ superimpose ((# speed "2") . (0.125 <~)) $ sound "bd sn cp hh"++-}+superimpose :: (Pattern a -> Pattern a) -> Pattern a -> Pattern a+superimpose f p = stack [p, f p]++{- | @trunc@ truncates a pattern so that only a fraction of the pattern is played.+The following example plays only the first quarter of the pattern:++> d1 $ trunc 0.25 $ sound "bd sn*2 cp hh*4 arpy bd*2 cp bd*2"++You can also pattern the first parameter, for example to cycle through three values, one per cycle:++> d1 $ trunc "<0.75 0.25 1>" $ sound "bd sn:2 [mt rs] hc"+-}+trunc :: Pattern Time -> Pattern a -> Pattern a+trunc = tParam _trunc++_trunc :: Time -> Pattern a -> Pattern a+_trunc t = compress (0, t) . zoomArc (Arc 0 t)++{- | @linger@ is similar to `trunc`, in that it truncates a pattern so that+only the first fraction of the pattern is played, but the truncated part of the+pattern loops to fill the remainder of the cycle.++> d1 $ linger 0.25 $ sound "bd sn*2 cp hh*4 arpy bd*2 cp bd*2"++For example this repeats the first quarter, so you only hear a single repeating note:++> d1 $ linger 0.25 $ n "0 2 [3 4] 2" # sound "arpy"++or slightly more interesting, applied only every fourth cycle:++> d1 $ every 4 (linger 0.25) $ n "0 2 [3 4] 2" # sound "arpy"++or to a chopped-up sample:++> d1 $ every 2 (linger 0.25) $ loopAt 2 $ chop 8 $ sound "breaks125"++You can also pattern the first parameter, for example to cycle through three+values, one per cycle:++> d1 $ linger "<0.75 0.25 1>" $ sound "bd sn:2 [mt rs] hc"+> d1 $ linger "<0.25 0.5 1>" $ loopAt 2 $ chop 8 $ sound "breaks125"++If you give it a negative number, it will linger on the last part of+the pattern, instead of the start of it. E.g. to linger on the last+quarter:++> d1 $ linger (-0.25) $ sound "bd sn*2 cp hh*4 arpy bd*2 cp bd*2"+-}+linger :: Pattern Time -> Pattern a -> Pattern a+linger = tParam _linger++_linger :: Time -> Pattern a -> Pattern a+_linger n p | n < 0 = _fast (1/n) $ zoomArc (Arc (1 + n) 1) p+ | otherwise = _fast (1/n) $ zoomArc (Arc 0 n) p++{- |+Use @within@ to apply a function to only a part of a pattern. It takes two+arguments: a start time and an end time, specified as floats between 0 and 1,+which are applied to the relevant pattern. Note that the second argument must be+greater than the first for the function to have any effect.++For example, to apply @'fast' 2@ to only the first half of a pattern:++> d1 $ within (0, 0.5) (fast 2) $ sound "bd*2 sn lt mt hh hh hh hh"++Or, to apply @(# 'speed' "0.5")@ to only the last quarter of a pattern:++> d1 $ within (0.75, 1) (# speed "0.5") $ sound "bd*2 sn lt mt hh hh hh hh"+-}+within :: (Time, Time) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+within (s, e) f p = stack [filterWhen (\t -> cyclePos t >= s && cyclePos t < e) $ f p,+ filterWhen (\t -> not $ cyclePos t >= s && cyclePos t < e) p+ ]++withinArc :: Arc -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+withinArc (Arc s e) = within (s, e)++{- |+For many cases, @within'@ will function exactly as within.+The difference between the two occurs when applying functions that change the timing of notes such as 'fast' or '<~'.+within first applies the function to all notes in the cycle, then keeps the results in the specified interval, and then combines it with the old cycle (an "apply split combine" paradigm).+within' first keeps notes in the specified interval, then applies the function to these notes, and then combines it with the old cycle (a "split apply combine" paradigm).++For example, whereas using the standard version of within++> d1 $ within (0, 0.25) (fast 2) $ sound "bd hh cp sd"++sounds like:++> d1 $ sound "[bd hh] hh cp sd"++using this alternative version, within'++> d1 $ within' (0, 0.25) (fast 2) $ sound "bd hh cp sd"++sounds like:++> d1 $ sound "[bd bd] hh cp sd"++-}+within' :: (Time, Time) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+within' a@(s, e) f p =+ stack [ filterWhen (\t -> cyclePos t >= s && cyclePos t < e) $ compress a $ f $ zoom a p+ , filterWhen (\t -> not $ cyclePos t >= s && cyclePos t < e) p+ ]++{-|+Reverse the part of the pattern sliced out by the @(start, end)@ pair.++@revArc a = within a rev@+-}+revArc :: (Time, Time) -> Pattern a -> Pattern a+revArc a = within a rev++{- | You can use the @euclid@ function to apply a Euclidean algorithm over a+complex pattern, although the structure of that pattern will be lost:++> d1 $ euclid 3 8 $ sound "bd*2 [sn cp]"++In the above, three sounds are picked from the pattern on the right according+to the structure given by the @euclid 3 8@. It ends up picking two @bd@ sounds, a+@cp@ and missing the @sn@ entirely.++A negative first argument provides the inverse of the euclidean pattern.++These types of sequences use "Bjorklund's algorithm", which wasn't made for+music but for an application in nuclear physics, which is exciting. More+exciting still is that it is very similar in structure to the one of the first+known algorithms written in Euclid's book of elements in 300 BC. You can read+more about this in the paper+[The Euclidean Algorithm Generates Traditional Musical Rhythms](http://cgm.cs.mcgill.ca/~godfried/publications/banff.pdf)+by Toussaint. Some examples from this paper are included below,+including rotation as a third parameter in some cases (see 'euclidOff').+++------------+-----------------------------------------------------------------++| Pattern | Example |++============+=================================================================++| (2,5) | A thirteenth century Persian rhythm called Khafif-e-ramal. |++------------+-----------------------------------------------------------------++| (3,4) | The archetypal pattern of the Cumbia from Colombia, as well as |+| | a Calypso rhythm from Trinidad. |++------------+-----------------------------------------------------------------++| (3,5,2) | Another thirteenth century Persian rhythm by the name of |+| | Khafif-e-ramal, as well as a Rumanian folk-dance rhythm. |++------------+-----------------------------------------------------------------++| (3,7) | A Ruchenitza rhythm used in a Bulgarian folk-dance. |++------------+-----------------------------------------------------------------++| (3,8) | The Cuban tresillo pattern. |++------------+-----------------------------------------------------------------++| (4,7) | Another Ruchenitza Bulgarian folk-dance rhythm. |++------------+-----------------------------------------------------------------++| (4,9) | The Aksak rhythm of Turkey. |++------------+-----------------------------------------------------------------++| (4,11) | The metric pattern used by Frank Zappa in his piece titled |+| | Outside Now. |++------------+-----------------------------------------------------------------++| (5,6) | Yields the York-Samai pattern, a popular Arab rhythm. |++------------+-----------------------------------------------------------------++| (5,7) | The Nawakhat pattern, another popular Arab rhythm. |++------------+-----------------------------------------------------------------++| (5,8) | The Cuban cinquillo pattern. |++------------+-----------------------------------------------------------------++| (5,9) | A popular Arab rhythm called Agsag-Samai. |++------------+-----------------------------------------------------------------++| (5,11) | The metric pattern used by Moussorgsky in |+| | Pictures at an Exhibition. |++------------+-----------------------------------------------------------------++| (5,12) | The Venda clapping pattern of a South African children’s song. |++------------+-----------------------------------------------------------------++| (5,16) | The Bossa-Nova rhythm necklace of Brazil. |++------------+-----------------------------------------------------------------++| (7,8) | A typical rhythm played on the Bendir (frame drum). |++------------+-----------------------------------------------------------------++| (7,12) | A common West African bell pattern. |++------------+-----------------------------------------------------------------++| (7,16,14) | A Samba rhythm necklace from Brazil. |++------------+-----------------------------------------------------------------++| (9,16) | A rhythm necklace used in the Central African Republic. |++------------+-----------------------------------------------------------------++| (11,24,14) | A rhythm necklace of the Aka Pygmies of Central Africa. |++------------+-----------------------------------------------------------------++| (13,24,5) | Another rhythm necklace of the Aka Pygmies of the upper Sangha. |++------------+-----------------------------------------------------------------+++There was once a shorter alias @e@ for this function. It has been removed, but you+may see references to it in older Tidal code.+-}+euclid :: Pattern Int -> Pattern Int -> Pattern a -> Pattern a+euclid = tParam2 _euclid++_euclid :: Int -> Int -> Pattern a -> Pattern a+_euclid n k a | n >= 0 = fastcat $ fmap (bool silence a) $ bjorklund (n,k)+ | otherwise = fastcat $ fmap (bool a silence) $ bjorklund (-n,k)++{- |++@euclidFull n k pa pb@ stacks @'euclid' n k pa@ with @'euclidInv' n k pb@. That+is, it plays one pattern on the euclidean rhythm and a different pattern on+the off-beat.++For example, to implement the traditional flamenco rhythm, you could use hard+claps for the former and soft claps for the latter:++> d1 $ euclidFull 3 7 "realclaps" ("realclaps" # gain 0.8)++-}+euclidFull :: Pattern Int -> Pattern Int -> Pattern a -> Pattern a -> Pattern a+euclidFull n k pa pb = stack [ euclid n k pa, euclidInv n k pb ]++-- | Less expressive than 'euclid' due to its constrained types, but may be more efficient.+_euclidBool :: Int -> Int -> Pattern Bool -- TODO: add 'euclidBool'?+_euclidBool n k | n >= 0 = fastFromList $ bjorklund (n,k)+ | otherwise = fastFromList $ fmap (not) $ bjorklund (-n,k)++_euclid' :: Int -> Int -> Pattern a -> Pattern a+_euclid' n k p = fastcat $ map (\x -> if x then p else silence) (bjorklund (n,k))++{- |+As 'euclid', but taking a third rotational parameter corresponding to the onset+at which to start the rhythm.+-}+euclidOff :: Pattern Int -> Pattern Int -> Pattern Int -> Pattern a -> Pattern a+euclidOff = tParam3 _euclidOff++-- | A shorter alias for 'euclidOff'.+eoff :: Pattern Int -> Pattern Int -> Pattern Int -> Pattern a -> Pattern a+eoff = euclidOff++_euclidOff :: Int -> Int -> Int -> Pattern a -> Pattern a+_euclidOff _ 0 _ _ = silence+_euclidOff n k s p = (rotL $ fromIntegral s%fromIntegral k) (_euclid n k p)++-- | As 'euclidOff', but specialized to 'Bool'. May be more efficient than 'euclidOff'.+euclidOffBool :: Pattern Int -> Pattern Int -> Pattern Int -> Pattern Bool -> Pattern Bool+euclidOffBool = tParam3 _euclidOffBool++_euclidOffBool :: Int -> Int -> Int -> Pattern Bool -> Pattern Bool+_euclidOffBool _ 0 _ _ = silence+_euclidOffBool n k s p = ((fromIntegral s % fromIntegral k) `rotL`) ((\a b -> if b then a else not a) <$> _euclidBool n k <*> p)++distrib :: [Pattern Int] -> Pattern a -> Pattern a+distrib ps p = do p' <- sequence ps+ _distrib p' p++_distrib :: [Int] -> Pattern a -> Pattern a+_distrib xs p = boolsToPat (foldr distrib' (replicate (last xs) True) (reverse $ layers xs)) p+ where+ distrib' :: [Bool] -> [Bool] -> [Bool]+ distrib' [] _ = []+ distrib' (_:a) [] = False : distrib' a []+ distrib' (True:a) (x:b) = x : distrib' a b+ distrib' (False:a) b = False : distrib' a b+ layers = map bjorklund . (zip<*>tail)+ boolsToPat a b' = flip const <$> filterValues (== True) (fastFromList a) <* b'++{-| @euclidInv@ fills in the blanks left by `euclid`, i.e., it inverts the+pattern.++For example, whereas @euclid 3 8 "x"@ produces++> "x ~ ~ x ~ ~ x ~"++@euclidInv 3 8 "x"@ produces++> "~ x x ~ x x ~ x"++As another example, in++> d1 $ stack [ euclid 5 8 $ s "bd"+> , euclidInv 5 8 $ s "hh27"+> ]++the hi-hat event fires on every one of the eight even beats that the bass drum+does not.+-}+euclidInv :: Pattern Int -> Pattern Int -> Pattern a -> Pattern a+euclidInv = tParam2 _euclidInv++_euclidInv :: Int -> Int -> Pattern a -> Pattern a+_euclidInv n k a = _euclid (-n) k a++index :: Real b => b -> Pattern b -> Pattern c -> Pattern c+index sz indexpat pat =+ spread' (zoom' $ toRational sz) (toRational . (*(1-sz)) <$> indexpat) pat+ where+ zoom' tSz s = zoomArc (Arc s (s+tSz))++{-+-- | @prrw f rot (blen, vlen) beatPattern valuePattern@: pattern rotate/replace.+prrw :: (a -> b -> c) -> Int -> (Time, Time) -> Pattern a -> Pattern b -> Pattern c+prrw f rot (blen, vlen) beatPattern valuePattern =+ let+ ecompare (_,e1,_) (_,e2,_) = compare (fst e1) (fst e2)+ beats = sortBy ecompare $ arc beatPattern (0, blen)+ values = fmap thd' . sortBy ecompare $ arc valuePattern (0, vlen)+ cycles = blen * (fromIntegral $ lcm (length beats) (length values) `div` (length beats))+ in+ _slow cycles $ stack $ zipWith+ (\( _, (start, end), v') v -> (start `rotR`) $ densityGap (1 / (end - start)) $ pure (f v' v))+ (sortBy ecompare $ arc (_fast cycles $ beatPattern) (0, blen))+ (drop (rot `mod` length values) $ cycle values)++-- | @prr rot (blen, vlen) beatPattern valuePattern@: pattern rotate/replace.+prr :: Int -> (Time, Time) -> Pattern String -> Pattern b -> Pattern b+prr = prrw $ flip const++{-|+@preplace (blen, plen) beats values@ combines the timing of @beats@ with the values+of @values@. Other ways of saying this are:+* sequential convolution+* @values@ quantized to @beats@.++Examples:++@+d1 $ sound $ preplace (1,1) "x [~ x] x x" "bd sn"+d1 $ sound $ preplace (1,1) "x(3,8)" "bd sn"+d1 $ sound $ "x(3,8)" <~> "bd sn"+d1 $ sound "[jvbass jvbass:5]*3" |+| (shape $ "1 1 1 1 1" <~> "0.2 0.9")+@++It is assumed the pattern fits into a single cycle. This works well with+pattern literals, but not always with patterns defined elsewhere. In those cases+use @preplace@ and provide desired pattern lengths:+@+let p = slow 2 $ "x x x"++d1 $ sound $ preplace (2,1) p "bd sn"+@+-}+preplace :: (Time, Time) -> Pattern String -> Pattern b -> Pattern b+preplace = preplaceWith $ flip const++-- | @prep@ is an alias for preplace.+prep :: (Time, Time) -> Pattern String -> Pattern b -> Pattern b+prep = preplace++preplace1 :: Pattern String -> Pattern b -> Pattern b+preplace1 = preplace (1, 1)++preplaceWith :: (a -> b -> c) -> (Time, Time) -> Pattern a -> Pattern b -> Pattern c+preplaceWith f (blen, plen) = prrw f 0 (blen, plen)++prw :: (a -> b -> c) -> (Time, Time) -> Pattern a -> Pattern b -> Pattern c+prw = preplaceWith++preplaceWith1 :: (a -> b -> c) -> Pattern a -> Pattern b -> Pattern c+preplaceWith1 f = prrw f 0 (1, 1)++prw1 :: (a -> b -> c) -> Pattern a -> Pattern b -> Pattern c+prw1 = preplaceWith1++(<~>) :: Pattern String -> Pattern b -> Pattern b+(<~>) = preplace (1, 1)++-- | @protate len rot p@ rotates pattern @p@ by @rot@ beats to the left.+-- @len@: length of the pattern, in cycles.+-- Example: @d1 $ every 4 (protate 2 (-1)) $ slow 2 $ sound "bd hh hh hh"@+protate :: Time -> Int -> Pattern a -> Pattern a+protate len rot p = prrw (flip const) rot (len, len) p p++prot :: Time -> Int -> Pattern a -> Pattern a+prot = protate++prot1 :: Int -> Pattern a -> Pattern a+prot1 = protate 1++{-| The @<<~@ operator rotates a unit pattern to the left, similar to @<~@,+but by events rather than linear time. The timing of the pattern remains constant:++@+d1 $ (1 <<~) $ sound "bd ~ sn hh"+-- will become+d1 $ sound "sn ~ hh bd"+@ -}++(<<~) :: Int -> Pattern a -> Pattern a+(<<~) = protate 1++-- | @~>>@ is like @<<~@ but for shifting to the right.+(~>>) :: Int -> Pattern a -> Pattern a+(~>>) = (<<~) . (0-)++-- | @pequal cycles p1 p2@: quickly test if @p1@ and @p2@ are the same.+pequal :: Ord a => Time -> Pattern a -> Pattern a -> Bool+pequal cycles p1 p2 = (sort $ arc p1 (0, cycles)) == (sort $ arc p2 (0, cycles))+-}++{- | @rot n p@ "rotates" the values in a pattern @p@ by @n@ beats to the left,+preserving its structure. For example, in the following, each value will shift+to its neighbour's position one step to the left, so that @b@ takes the place of+@a@, @a@ of @c@, and @c@ of @b@:++> rot 1 "a ~ b c"++The result is equivalent of:++> "b ~ c a"++The first parameter is the number of steps, and may be given as a pattern. For example, in++> d1 $ rot "<0 0 1 3>" $ n "0 ~ 1 2 0 2 ~ 3*2" # sound "drum"++the pattern will not be rotated for the first two cycles, but will rotate it+by one the third cycle, and by three the fourth cycle.++Additional example:++> d1 $ every 4 (rot 2) $ slow 2 $ sound "bd hh hh hh"+-}+rot :: Ord a => Pattern Int -> Pattern a -> Pattern a+rot = tParam _rot++-- | Calculates a whole cycle, rotates it, then constrains events to the original query arc.+_rot :: Ord a => Int -> Pattern a -> Pattern a+_rot i pat = splitQueries $ pat {query = \st -> f st (query pat (st {arc = wholeCycle (arc st)}))}+ where -- TODO maybe events with the same arc (part+whole) should be+ -- grouped together in the rotation?+ f st es = constrainEvents (arc st) $ shiftValues $ sort $ defragParts es+ shiftValues es | i >= 0 =+ zipWith (\e s -> e {value = s}) es+ (drop i $ cycle $ map value es)+ | otherwise =+ zipWith (\e s -> e{value = s}) es+ (drop (length es - abs i) $ cycle $ map value es)+ wholeCycle (Arc s _) = Arc (sam s) (nextSam s)+ constrainEvents :: Arc -> [Event a] -> [Event a]+ constrainEvents a es = mapMaybe (constrainEvent a) es+ constrainEvent :: Arc -> Event a -> Maybe (Event a)+ constrainEvent a e =+ do+ p' <- subArc (part e) a+ return e {part = p'}++{-| @segment n p@ ’samples’ the pattern @p@ at a rate of @n@ events per cycle.+Useful for turning a continuous pattern into a discrete one.++In the following example, the pattern originates from the shape of a sine+wave, a continuous pattern. Without @segment@, the samples will get triggered+at an undefined frequency which may be very high.++> d1 $ n (slow 2 $ segment 16 $ range 0 32 $ sine) # sound "amencutup"+-}+segment :: Pattern Time -> Pattern a -> Pattern a+segment = tParam _segment++_segment :: Time -> Pattern a -> Pattern a+_segment n p = _fast n (pure id) <* p++-- | @discretise@: the old (deprecated) name for 'segment'+discretise :: Pattern Time -> Pattern a -> Pattern a+discretise = segment++-- @fromNote p@: converts a pattern of human-readable pitch names+-- into pitch numbers. For example, @"cs2"@ will be parsed as C Sharp+-- in the 2nd octave with the result of @11@, and @"b-3"@ as+-- @-25@. Pitches can be decorated using:+--+-- * s = Sharp, a half-step above (@"gs-1"@)+-- * f = Flat, a half-step below (@"gf-1"@)+-- * n = Natural, no decoration (@"g-1" and "gn-1"@ are equivalent)+-- * ss = Double sharp, a whole step above (@"gss-1"@)+-- * ff = Double flat, a whole step below (@"gff-1"@)+--+-- Note that TidalCycles now assumes that middle C is represented by+-- the value 0, rather than the previous value of 60. This function+-- is similar to previously available functions @tom@ and @toMIDI@,+-- but the default octave is now 0 rather than 5.+{-++definition moved to Parse.hs ..++toMIDI :: Pattern String -> Pattern Int+toMIDI p = fromJust <$> (filterValues (isJust) (noteLookup <$> p))+ where+ noteLookup :: String -> Maybe Int+ noteLookup [] = Nothing+ noteLookup s | not (last s `elem` ['0' .. '9']) = noteLookup (s ++ "0")+ | not (isLetter (s !! 1)) = noteLookup((head s):'n':(tail s))+ | otherwise = parse s+ parse x = (\a b c -> a+b+c) <$> pc x <*> sym x <*> Just(12*digitToInt (last x))+ pc x = lookup (head x) [('c',0),('d',2),('e',4),('f',5),('g',7),('a',9),('b',11)]+ sym x = lookup (init (tail x)) [("s",1),("f",-1),("n",0),("ss",2),("ff",-2)]+-}++-- @tom p@: Alias for @toMIDI@.+-- tom = toMIDI+++{- | The `fit` function takes a pattern of integer numbers, which are used to select values from the given list. What makes this a bit strange is that only a given number of values are selected each cycle. For example:++> d1 $ sound (fit 3 ["bd", "sn", "arpy", "arpy:1", "casio"] "0 [~ 1] 2 1")++The above fits three samples into the pattern, i.e. for the first cycle this+will be @"bd"@, @"sn"@ and @"arpy"@, giving the result @"bd [~ sn] arpy sn"@+(note that we start counting at zero, so that 0 picks the first value). The+following cycle the /next/ three values in the list will be picked, i.e.+@"arpy:1"@, @"casio"@ and @"bd"@, giving the pattern+@"arpy:1 [~ casio] bd casio"@ (note that the list wraps round here).++-}+fit :: Pattern Int -> [a] -> Pattern Int -> Pattern a+fit pint xs p = (tParam func) pint (xs,p)+ where func i (xs',p') = _fit i xs' p'++_fit :: Int -> [a] -> Pattern Int -> Pattern a+_fit perCycle xs p = (xs !!!) <$> (p {query = map (\e -> fmap (+ pos e) e) . query p})+ where pos e = perCycle * floor (start $ part e)+++permstep :: RealFrac b => Int -> [a] -> Pattern b -> Pattern a+permstep nSteps things p = unwrap $ (\n -> fastFromList $ concatMap (\x -> replicate (fst x) (snd x)) $ zip (ps !! floor (n * fromIntegral (length ps - 1))) things) <$> _segment 1 p+ where ps = permsort (length things) nSteps+ deviance avg xs = sum $ map (abs . (avg-) . fromIntegral) xs+ permsort n total = map fst $ sortOn snd $ map (\x -> (x,deviance (fromIntegral total / (fromIntegral n :: Double)) x)) $ perms n total+ perms 0 _ = []+ perms 1 n = [[n]]+ perms n total = concatMap (\x -> map (x:) $ perms (n-1) (total-x)) [1 .. (total-(n-1))]++{-|+ @struct a b@ structures pattern @b@ in terms of the pattern of boolean+ values @a@. Only @True@ values in the boolean pattern are used.++ The following are equivalent:++ > d1 $ struct ("t ~ t*2 ~") $ sound "cp"+ > d1 $ sound "cp ~ cp*2 ~"++ The structure comes from a boolean pattern, i.e. a binary pattern containing+ true or false values. Above we only used true values, denoted by @t@. It’s also+ possible to include false values with @f@, which @struct@ will simply treat as+ silence. For example, this would have the same outcome as the above:++ > d1 $ struct ("t f t*2 f") $ sound "cp"++ These true / false binary patterns become useful when you conditionally+ manipulate them, for example, ‘inverting’ the values using 'every' and 'inv':++ > d1 $ struct (every 3 inv "t f t*2 f") $ sound "cp"++ In the above, the boolean values will be ‘inverted’ every third cycle, so that+ the structure comes from the @f@s rather than @t@. Note that euclidean patterns+ also create true/false values, for example:++ > d1 $ struct (every 3 inv "t(3,8)") $ sound "cp"++ In the above, the euclidean pattern creates @"t f t f t f f t"@ which gets+ inverted to @"f t f t f t t f"@ every third cycle. Note that if you prefer you+ can use 1 and 0 instead of @t@ and @f@.+-}+struct :: Pattern Bool -> Pattern a -> Pattern a+struct ps pv = filterJust $ (\a b -> if a then Just b else Nothing ) <$> ps <* pv++-- | @substruct a b@: similar to @struct@, but each event in pattern @a@ gets replaced with pattern @b@, compressed to fit the timespan of the event.+substruct :: Pattern Bool -> Pattern b -> Pattern b+substruct s p = p {query = f}+ where f st =+ concatMap ((\a' -> queryArc (compressArcTo a' p) a') . wholeOrPart) $ filter value $ query s st++randArcs :: Int -> Pattern [Arc]+randArcs n =+ do rs <- mapM (\x -> pure (toRational x / toRational n) <~ choose [1 :: Int,2,3]) [0 .. (n-1)]+ let rats = map toRational rs+ total = sum rats+ pairs = pairUp $ accumulate $ map (/total) rats+ return pairs+ where pairUp [] = []+ pairUp xs = Arc 0 (head xs) : pairUp' xs+ pairUp' [] = []+ pairUp' [_] = []+ pairUp' [a, _] = [Arc a 1]+ pairUp' (a:b:xs) = Arc a b: pairUp' (b:xs)+++-- TODO - what does this do? Something for @stripe@ ..+randStruct :: Int -> Pattern Int+randStruct n = splitQueries $ Pattern {query = f}+ where f st = map (\(a,b,c) -> Event (Context []) (Just a) (fromJust b) c) $ filter (\(_,x,_) -> isJust x) as+ where as = map (\(i, Arc s' e') ->+ (Arc (s' + sam s) (e' + sam s),+ subArc (Arc s e) (Arc (s' + sam s) (e' + sam s)), i)) $+ enumerate $ value $ head $+ queryArc (randArcs n) (Arc (sam s) (nextSam s))+ (Arc s e) = arc st++-- TODO - what does this do?+substruct' :: Pattern Int -> Pattern a -> Pattern a+substruct' s p = p {query = \st -> concatMap (f st) (query s st)}+ where f st (Event c (Just a') _ i) = map (\e -> e {context = combineContexts [c, context e]}) $ queryArc (compressArcTo a' (inside (pure $ 1/toRational(length (queryArc s (Arc (sam (start $ arc st)) (nextSam (start $ arc st)))))) (rotR (toRational i)) p)) a'+ -- Ignore analog events (ones without wholes)+ f _ _ = []++{- | @stripe n p@: repeats pattern @p@ @n@ times per cycle, i.e., the first+parameter gives the number of cycles to operate over. So, it is similar to+@fast@, but with random durations. For example @stripe 2@ will repeat a pattern+twice, over two cycles++In the following example, the start of every third repetition of the @d1@+pattern will match with the clap on the @d2@ pattern.++> d1 $ stripe 3 $ sound "bd sd ~ [mt ht]"+> d2 $ sound "cp"++The repetitions will be contiguous (touching, but not overlapping) and the+durations will add up to a single cycle. @n@ can be supplied as a pattern of+integers.+-}+stripe :: Pattern Int -> Pattern a -> Pattern a+stripe = tParam _stripe++_stripe :: Int -> Pattern a -> Pattern a+_stripe = substruct' . randStruct++-- | @slowstripe n p@ is the same as @stripe@, but the result is also+-- @n@ times slower, so that the mean average duration of the stripes+-- is exactly one cycle, and every @n@th stripe starts on a cycle+-- boundary (in Indian classical terms, the /sam/).+slowstripe :: Pattern Int -> Pattern a -> Pattern a+slowstripe n = slow (toRational <$> n) . stripe n++-- Lindenmayer patterns, these go well with the step sequencer+-- general rule parser (strings map to strings)+parseLMRule :: String -> [(String,String)]+parseLMRule s = map (splitOn ':') commaSplit+ where splitOn sep str = splitAt (fromJust $ elemIndex sep str)+ $ filter (/= sep) str+ commaSplit = map T.unpack $ T.splitOn (T.pack ",") $ T.pack s++-- specific parser for step sequencer (chars map to string)+-- ruleset in form "a:b,b:ab"+parseLMRule' :: String -> [(Char, String)]+parseLMRule' str = map fixer $ parseLMRule str+ where fixer (c,r) = (head c, r)++{- | Returns the @n@th iteration of a+ [Lindenmayer System](https://en.wikipedia.org/wiki/L-system)+ with given start sequence.++ It takes an integer @b@, a Lindenmayer system rule set, and an initiating+ string as input in order to generate an L-system tree string of @b@ iterations.+ It can be used in conjunction with a step function to convert the generated+ string into a playable pattern. For example,++ > d1 $ slow 16+ > $ sound+ > $ step' ["feel:0", "sn:1", "bd:0"]+ > ( take 512+ > $ lindenmayer 5 "0:1~~~,1:0~~~2~~~~~0~~~2~,2:2~1~,~:~~1~" "0"+ > )++ generates an L-system with initiating string @"0"@ and maps it onto a list+ of samples.++ Complex L-system trees with many rules and iterations can sometimes result in unwieldy strings. Using @take n@ to only use the first @n@ elements of the string, along with a 'slow' function, can make the generated values more manageable.++-}+lindenmayer :: Int -> String -> String -> String+lindenmayer _ _ [] = []+lindenmayer 1 r (c:cs) = fromMaybe [c] (lookup c $ parseLMRule' r)+ ++ lindenmayer 1 r cs+lindenmayer n r s = iterate (lindenmayer 1 r) s !! n++{- | @lindenmayerI@ converts the resulting string into a a list of integers+with @fromIntegral@ applied (so they can be used seamlessly where floats or+rationals are required) -}+lindenmayerI :: Num b => Int -> String -> String -> [b]+lindenmayerI n r s = fmap (fromIntegral . digitToInt) $ lindenmayer n r s++{- | @runMarkov n tmat xi seed@ generates a Markov chain (as a list) of length @n@+using the transition matrix @tmat@ starting from initial state @xi@, starting+with random numbers generated from @seed@+Each entry in the chain is the index of state (starting from zero).+Each row of the matrix will be automatically normalized. For example:+@+runMarkov 8 [[2,3], [1,3]] 0 0+@+will produce a two-state chain 8 steps long, from initial state @0@, where the+transition probability from state 0->0 is 2/5, 0->1 is 3/5, 1->0 is 1/4, and+1->1 is 3/4. -}+runMarkov :: Int -> [[Double]] -> Int -> Time -> [Int]+runMarkov n tp xi seed = reverse $ (iterate (markovStep $ renorm) [xi])!! (n-1) where+ markovStep tp' xs = (fromJust $ findIndex (r <=) $ scanl1 (+) (tp'!!(head xs))) : xs where+ r = timeToRand $ seed + (fromIntegral . length) xs / fromIntegral n+ renorm = [ map (/ sum x) x | x <- tp ]++{- | @markovPat n xi tp@ generates a one-cycle pattern of @n@ steps in a Markov+chain starting from state @xi@ with transition matrix @tp@. Each row of the+transition matrix is automatically normalized. For example:++>>> markovPat 8 1 [[3,5,2], [4,4,2], [0,1,0]]+(0>⅛)|1+(⅛>¼)|2+(¼>⅜)|1+(⅜>½)|1+(½>⅝)|2+(⅝>¾)|1+(¾>⅞)|1+(⅞>1)|0+-}+markovPat :: Pattern Int -> Pattern Int -> [[Double]] -> Pattern Int+markovPat = tParam2 _markovPat++_markovPat :: Int -> Int -> [[Double]] -> Pattern Int+_markovPat n xi tp = splitQueries $ Pattern (\(State a@(Arc s _) _) ->+ queryArc (listToPat $ runMarkov n tp xi (sam s)) a)++{-|+@mask@ takes a boolean pattern and ‘masks’ another pattern with it. That is,+events are only carried over if they match within a ‘true’ event in the binary+pattern, i.e., it removes events from the second pattern that don't start during+an event from the first.++For example, consider this kind of messy rhythm without any rests.++> d1 $ sound (slowcat ["sn*8", "[cp*4 bd*4, hc*5]"]) # n (run 8)++If we apply a mask to it++@+d1 $ s ( mask ("1 1 1 ~ 1 1 ~ 1" :: Pattern Bool)+ ( slowcat ["sn*8", "[cp*4 bd*4, bass*5]"] )+ )+ # n (run 8)+@++Due to the use of `slowcat` here, the same mask is first applied to @"sn*8"@ and+in the next cycle to @"[cp*4 bd*4, hc*5]"@.++You could achieve the same effect by adding rests within the `slowcat` patterns,+but mask allows you to do this more easily. It kind of keeps the rhythmic+structure and you can change the used samples independently, e.g.,++@+d1 $ s ( mask ("1 ~ 1 ~ 1 1 ~ 1")+ ( slowcat ["can*8", "[cp*4 sn*4, jvbass*16]"] )+ )+ # n (run 8)+@+-}+mask :: Pattern Bool -> Pattern a -> Pattern a+mask b p = const <$> p <* (filterValues id b)++-- TODO: refactor towards union+enclosingArc :: [Arc] -> Arc+enclosingArc [] = Arc 0 1+enclosingArc as = Arc (minimum (map start as)) (maximum (map stop as))++{-|+ @stretch@ takes a pattern, and if there’s silences at the start or end of the+ current cycle, it will zoom in to avoid them. The following are equivalent:++ > d1 $ note (stretch "~ 0 1 5 8*4 ~") # s "superpiano"+ > d1 $ note "0 1 5 8*4" # s "superpiano"++ You can pattern silences on the extremes of a cycle to make changes to the rhythm:++ > d1 $ note (stretch "~ <0 ~> 1 5 8*4 ~") # s "superpiano"+-}+stretch :: Pattern a -> Pattern a+-- TODO - should that be whole or part?+stretch p = splitQueries $ p {query = q}+ where q st = query (zoomArc (cycleArc $ enclosingArc $ map wholeOrPart $ query p (st {arc = Arc (sam s) (nextSam s)})) p) st+ where s = start $ arc st++{- | @fit'@ is a generalization of `fit`, where the list is instead constructed+by using another integer pattern to slice up a given pattern. The first argument+is the number of cycles of that latter pattern to use when slicing. It's easier+to understand this with a few examples:++> d1 $ sound (fit' 1 2 "0 1" "1 0" "bd sn")++So what does this do? The first @1@ just tells it to slice up a single cycle of+@"bd sn"@. The @2@ tells it to select two values each cycle, just like the first+argument to @fit@. The next pattern @"0 1"@ is the "from" pattern which tells+it how to slice, which in this case means @"0"@ maps to @"bd"@, and @"1"@ maps+to @"sn"@. The next pattern @"1 0"@ is the "to" pattern, which tells it how to+rearrange those slices. So the final result is the pattern @"sn bd"@.++A more useful example might be something like++> d1 $ fit' 1 4 (run 4) "[0 3*2 2 1 0 3*2 2 [1*8 ~]]/2"+> $ chop 4+> $ (sound "breaks152" # unit "c")++which uses @chop@ to break a single sample into individual pieces, which @fit'@ then puts into a list (using the @run 4@ pattern) and reassembles according to the complicated integer pattern.+-}+fit' :: Pattern Time -> Int -> Pattern Int -> Pattern Int -> Pattern a -> Pattern a+fit' cyc n from to p = squeezeJoin $ _fit n mapMasks to+ where mapMasks = [stretch $ mask (const True <$> filterValues (== i) from') p'+ | i <- [0..n-1]]+ p' = density cyc p+ from' = density cyc from++{-|+ Treats the given pattern @p@ as having @n@ chunks, and applies the function @f@ to one of those sections per cycle.+ Running:+ - from left to right if chunk number is positive+ - from right to left if chunk number is negative++ > d1 $ chunk 4 (fast 4) $ sound "cp sn arpy [mt lt]"++ The following:++ > d1 $ chunk 4 (# speed 2) $ sound "bd hh sn cp"++ applies @(# speed 2)@ to the uppercased part of the cycle below:++ > BD hh sn cp+ > bd HH sn cp+ > bd hh SN cp+ > bd hh sn CP+-}+chunk :: Pattern Int -> (Pattern b -> Pattern b) -> Pattern b -> Pattern b+chunk npat f p = innerJoin $ (\n -> _chunk n f p) <$> npat++_chunk :: Integral a => a -> (Pattern b -> Pattern b) -> Pattern b -> Pattern b+_chunk n f p | n >= 0 = cat [withinArc (Arc (i % fromIntegral n) ((i+1) % fromIntegral n)) f p | i <- [0 .. fromIntegral n - 1]]+ | otherwise = do i <- _slow (toRational (-n)) $ rev $ run (fromIntegral (-n))+ withinArc (Arc (i % fromIntegral (-n)) ((i+1) % fromIntegral (-n))) f p++-- | DEPRECATED, use 'chunk' with negative numbers instead+chunk' :: Integral a1 => Pattern a1 -> (Pattern a2 -> Pattern a2) -> Pattern a2 -> Pattern a2+chunk' npat f p = innerJoin $ (\n -> _chunk' n f p) <$> npat++-- | DEPRECATED, use '_chunk' with negative numbers instead+_chunk' :: Integral a => a -> (Pattern b -> Pattern b) -> Pattern b -> Pattern b+_chunk' n f p = _chunk (-n) f p++{-|+@inside@ carries out an operation /inside/ a cycle.+For example, while @rev "0 1 2 3 4 5 6 7"@ is the same as @"7 6 5 4 3 2 1 0"@,+@inside 2 rev "0 1 2 3 4 5 6 7"@ gives @"3 2 1 0 7 6 5 4"@.++What this function is really doing is ‘slowing down’ the pattern by a given+factor, applying the given function to it, and then ‘speeding it up’ by the same+factor. In other words, this:++> inside 2 rev "0 1 2 3 4 5 6 7"++Is doing this:++> fast 2 $ rev $ slow 2 "0 1 2 3 4 5 6 7"++so rather than whole cycles, each half of a cycle is reversed.+-}+inside :: Pattern Time -> (Pattern a1 -> Pattern a) -> Pattern a1 -> Pattern a+inside np f p = innerJoin $ (\n -> _inside n f p) <$> np++_inside :: Time -> (Pattern a1 -> Pattern a) -> Pattern a1 -> Pattern a+_inside n f p = _fast n $ f (_slow n p)++{-|+@outside@ is the inverse of the 'inside' function. @outside@ applies its function /outside/ the cycle.+Say you have a pattern that takes 4 cycles to repeat and apply the rev function:++> d1 $ rev $ cat [s "bd bd sn",s "sn sn bd", s"lt lt sd", s "sd sd bd"]++The above generates:++> d1 $ rev $ cat [s "sn bd bd",s "bd sn sn", s "sd lt lt", s "bd sd sd"]++However if you apply @outside@:++> d1 $ outside 4 (rev) $ cat [s "bd bd sn",s "sn sn bd", s"lt lt sd", s "sd sd bd"]++The result is:++> d1 $ rev $ cat [s "bd sd sd", s "sd lt lt", s "sn sn bd", s "bd bd sn"]++Notice that the whole idea has been reversed. What this function is really doing+is ‘speeding up’ the pattern by a given factor, applying the given function to+it, and then ‘slowing it down’ by the same factor. In other words, this:++> d1 $ slow 4 $ rev $ fast 4+> $ cat [s "bd bd sn",s "sn sn bd", s"lt lt sd", s "sd sd bd"]++This compresses the idea into a single cycle before rev operates and then slows it back to the original speed.+-}+outside :: Pattern Time -> (Pattern a1 -> Pattern a) -> Pattern a1 -> Pattern a+outside np f p = innerJoin $ (\n -> _outside n f p) <$> np++_outside :: Time -> (Pattern a1 -> Pattern a) -> Pattern a1 -> Pattern a+_outside n = _inside (1/n)++{-|+ Takes a pattern and loops only the first cycle of the pattern. For example, the following code will only play the bass drum sample:++ > d1 $ loopFirst $ s "<<bd*4 ht*8> cp*4>"++ This function combines with 'sometimes' to insert events from the first cycle randomly into subsequent cycles of the pattern:++ > d1 $ sometimes loopFirst $ s "<<bd*4 ht*8> cp*4>"+-}+loopFirst :: Pattern a -> Pattern a+loopFirst p = splitQueries $ p {query = f}+ where f st = map+ (\(Event c w p' v) ->+ Event c (plus <$> w) (plus p') v) $+ query p (st {arc = minus $ arc st})+ where minus = fmap (subtract (sam s))+ plus = fmap (+ sam s)+ s = start $ arc st++timeLoop :: Pattern Time -> Pattern a -> Pattern a+timeLoop n = outside n loopFirst++{-|+ @seqPLoop@ will keep looping the sequence when it gets to the end:++ > d1 $ qtrigger $ seqPLoop+ > [ (0, 12, sound "bd bd*2")+ > , (4, 12, sound "hh*2 [sn cp] cp future*4")+ > , (8, 12, sound (samples "arpy*8" (run 16)))+ > ]+-}+seqPLoop :: [(Time, Time, Pattern a)] -> Pattern a+seqPLoop ps = timeLoop (pure $ maxT - minT) $ minT `rotL` seqP ps+ where minT = minimum $ map (\(x,_,_) -> x) ps+ maxT = maximum $ map (\(_,x,_) -> x) ps++{-|+@toScale@ lets you turn a pattern of notes within a scale (expressed as a+list) to note numbers.++For example:++> toScale [0, 4, 7] "0 1 2 3"++will turn into the pattern @"0 4 7 12"@.++@toScale@ is handy for quickly applying a scale without naming it:++> d1 $ n (toScale [0,2,3,5,7,8,10] "0 1 2 3 4 5 6 7") # sound "superpiano"++This function assumes your scale fits within an octave; if that's not true,+use 'toScale''.++@toScale = toScale' 12@+-}+toScale :: Num a => [a] -> Pattern Int -> Pattern a+toScale = toScale' 12++{- | As 'toScale', though allowing scales of arbitrary size.++An example: @toScale' 24 [0,4,7,10,14,17] (run 8)@ turns into @"0 4 7 10 14 17 24 28"@.+-}+toScale' :: Num a => Int -> [a] -> Pattern Int -> Pattern a+toScale' _ [] = const silence+toScale' o s = fmap noteInScale+ where octave x = x `div` length s+ noteInScale x = (s !!! x) + fromIntegral (o * octave x)+++{- | @swingBy x n@ divides a cycle into @n@ slices and delays the notes in the+ second half of each slice by @x@ fraction of a slice. So if @x@ is 0 it does+ nothing, 0.5 delays for half the note duration, and 1 will wrap around to+ doing nothing again. The end result is a shuffle or swing-like rhythm. For+ example, the following will delay every other @"hh"@ 1/3 of the way to the+ next @"hh"@:++ > d1 $ swingBy (1/3) 4 $ sound "hh*8"+-}+swingBy :: Pattern Time -> Pattern Time -> Pattern a -> Pattern a+swingBy x n = inside n (withinArc (Arc 0.5 1) (x ~>))++{-|+As 'swingBy', with the cycle division set to ⅓.+-}+swing :: Pattern Time -> Pattern a -> Pattern a+swing = swingBy (pure $ 1%3)++{- | @cycleChoose@ is like `choose` but only picks a new item from the list+ once each cycle.++ > d1 $ sound "drum ~ drum drum" # n (cycleChoose [0,2,3])+-}+cycleChoose :: [a] -> Pattern a+cycleChoose = segment 1 . choose++{- | Internal function used by shuffle and scramble -}+_rearrangeWith :: Pattern Int -> Int -> Pattern a -> Pattern a+_rearrangeWith ipat n pat = innerJoin $ (\i -> _fast nT $ _repeatCycles n $ pats !! i) <$> ipat+ where+ pats = map (\i -> zoom (fromIntegral i / nT, fromIntegral (i+1) / nT) pat) [0 .. (n-1)]+ nT :: Time+ nT = fromIntegral n++{- | @shuffle n p@ evenly divides one cycle of the pattern @p@ into @n@ parts,+and returns a random permutation of the parts each cycle. For example,+@shuffle 3 "a b c"@ could return @"a b c"@, @"a c b"@, @"b a c"@, @"b c a"@,+@"c a b"@, or @"c b a"@. But it will /never/ return @"a a a"@, because that+is not a permutation of the parts.++This could also be called “sampling without replacement”.+-}+shuffle :: Pattern Int -> Pattern a -> Pattern a+shuffle = tParam _shuffle++_shuffle :: Int -> Pattern a -> Pattern a+_shuffle n = _rearrangeWith (randrun n) n++{- | @scramble n p@ is like 'shuffle' but randomly selects from the parts+of @p@ instead of making permutations.+For example, @scramble 3 "a b c"@ will randomly select 3 parts from+@"a"@ @"b"@ and @"c"@, possibly repeating a single part.++This could also be called “sampling with replacement”.+-}+scramble :: Pattern Int -> Pattern a -> Pattern a+scramble = tParam _scramble++_scramble :: Int -> Pattern a -> Pattern a+_scramble n = _rearrangeWith (_segment (fromIntegral n) $ _irand n) n++{-|+@randrun n@ generates a pattern of random integers less than @n@.++The following plays random notes in an octave:++@+d1 $ s "superhammond!12" # n (fromIntegral <$> randrun 13)+@++-}+randrun :: Int -> Pattern Int+randrun 0 = silence+randrun n' =+ splitQueries $ Pattern (\(State a@(Arc s _) _) -> events a $ sam s)+ where events a seed = mapMaybe toEv $ zip arcs shuffled+ where shuffled = map snd $ sortOn fst $ zip rs [0 .. (n'-1)]+ rs = timeToRands seed n' :: [Double]+ arcs = zipWith Arc fractions (tail fractions)+ fractions = map (+ (sam $ start a)) [0, 1 / fromIntegral n' .. 1]+ toEv (a',v) = do a'' <- subArc a a'+ return $ Event (Context []) (Just a') a'' v++-- ** Composing patterns++{- | The function @seqP@ allows you to define when+a sound within a list starts and ends. The code below contains three+separate patterns in a `stack`, but each has different start times+(zero cycles, eight cycles, and sixteen cycles, respectively). All+patterns stop after 128 cycles:++@+d1 $ seqP [+ (0, 128, sound "bd bd*2"),+ (8, 128, sound "hh*2 [sn cp] cp future*4"),+ (16, 128, sound (samples "arpy*8" (run 16)))+]+@+-}+seqP :: [(Time, Time, Pattern a)] -> Pattern a+seqP ps = stack $ map (\(s, e, p) -> playFor s e (sam s `rotR` p)) ps++{-|+The @ur@ function is designed for longer form composition, by allowing you to+create ‘patterns of patterns’ in a repeating loop. It takes four parameters:+how long the loop will take, a pattern giving the structure of the composition,+a lookup table for named patterns to feed into that structure, and a second+lookup table for named transformations\/effects.++The /ur-/ prefix [comes from German](https://en.wiktionary.org/wiki/ur-#German) and+means /proto-/ or /original/. For a mnemonic device, think of this function as+assembling a set of original patterns (ur-patterns) into a larger, newer whole.++Lets say you had three patterns (called @a@, @b@ and @c@), and that you wanted+to play them four cycles each, over twelve cycles in total. Here is one way to+do it:++@+let pats =+ [ ( "a", stack [ n "c4 c5 g4 f4 f5 g4 e5 g4" # s "superpiano" # gain "0.7"+ , n "[c3,g4,c4]" # s "superpiano"# gain "0.7"+ ]+ )+ , ( "b", stack [ n "d4 c5 g4 f4 f5 g4 e5 g4" # s "superpiano" # gain "0.7"+ , n "[d3,a4,d4]" # s "superpiano"# gain "0.7"+ ]+ )+ , ( "c", stack [ n "f4 c5 g4 f4 f5 g4 e5 g4" # s "superpiano" # gain "0.7"+ , n "[f4,c5,f4]" # s "superpiano"# gain "0.7"+ ]+ )+ ]+in+d1 $ ur 12 "a b c" pats []+@++In the above, the fourth parameter is given as an empty list, but that is where+you can put another lookup table, of functions rather than patterns this time.+For example:++@+let+ pats = ...+ fx = [ ("reverb", ( # (room 0.8 # sz 0.99 # orbit 1)))+ , ("faster", fast 2)+ ]+in+d1 $ ur 12 "a b:reverb c:faster" pats fx+@++In this example, @b@ has the function applied that’s named as reverb, while @c@+is made to go faster. It’s also possible to schedule multiple patterns at once,+like in the following:++@+let pats = [ ("drums", s "drum cp*2")+ , ("melody", s "arpy:2 arpy:3 arpy:5")+ , ("craziness", s "cp:4*8" # speed ( sine + 0.5 ))+ ]+ fx = [("higher", ( # speed 2))]+in+d1 $ ur 8 "[drums, melody] [drums,craziness,melody] melody:higher" pats fx+@+-}+ur :: Time -> Pattern String -> [(String, Pattern a)] -> [(String, Pattern a -> Pattern a)] -> Pattern a+ur t outer_p ps fs = _slow t $ unwrap $ adjust <$> timedValues (getPat . split <$> outer_p)+ where split = wordsBy (==':')+ getPat (s:xs) = (match s, transform xs)+ -- TODO - check this really can't happen..+ getPat _ = error "can't happen?"+ match s = fromMaybe silence $ lookup s ps'+ ps' = map (fmap (_fast t)) ps+ adjust (a, (p, f)) = f a p+ transform (x:_) a = transform' x a+ transform _ _ = id+ transform' str (Arc s e) p = s `rotR` inside (pure $ 1/(e-s)) (matchF str) p+ matchF str = fromMaybe id $ lookup str fs+ timedValues = withEvent (\(Event c (Just a) a' v) -> Event c (Just a) a' (a,v)) . filterDigital++{- | A simpler version of 'ur' that just provides name-value bindings that are+ reflected in the provided pattern.++ @inhabit@ allows you to link patterns to some @String@, or in other words,+ to give patterns a name and then call them from within another pattern of+ @String@s.++ For example, we can make our own bassdrum, hi-hat and snaredrum kit:++ > do+ > let drum = inhabit [ ("bd", s "sine" |- accelerate 1.5)+ > , ("hh", s "alphabet:7" # begin 0.7 # hpf 7000)+ > , ("sd", s "invaders:3" # speed 12)+ > ]+ > d1 $ drum "[bd*8?, [~hh]*4, sd(6,16)]"++ @inhabit@ can be very useful when using MIDI controlled drum machines, since you+ can give understandable drum names to patterns of notes.+-}+inhabit :: [(String, Pattern a)] -> Pattern String -> Pattern a+inhabit ps p = squeezeJoin $ (\s -> fromMaybe silence $ lookup s ps) <$> p++{- | @spaceOut xs p@ repeats a 'Pattern' @p@ at different durations given by the list of time values in @xs@. -}+spaceOut :: [Time] -> Pattern a -> Pattern a+spaceOut xs p = _slow (toRational $ sum xs) $ stack $ map (`compressArc` p) spaceArcs+ where markOut :: Time -> [Time] -> [Arc]+ markOut _ [] = []+ markOut offset (x:xs') = Arc offset (offset+x):markOut (offset+x) xs'+ spaceArcs = map (\(Arc a b) -> Arc (a/s) (b/s)) $ markOut 0 xs+ s = sum xs++{-| @flatpat@ takes a 'Pattern' of lists and pulls the list elements as+ separate 'Event's. For example, the following code uses @flatpat@ in combination with @listToPat@ to create an alternating pattern of chords:++ > d1 $ n (flatpat $ listToPat [[0,4,7],[(-12),(-8),(-5)]])+ > # s "superpiano" # sustain 2++ This code is equivalent to:++ > d1 $ n ("[0,4,7] [-12,-8,-5]") # s "superpiano" # sustain 2+-}+flatpat :: Pattern [a] -> Pattern a+flatpat p = p {query = concatMap (\(Event c b b' xs) -> map (Event c b b') xs) . query p}++{- | @layer@ takes a list of 'Pattern'-returning functions and a seed element,+stacking the result of applying the seed element to each function in the list.++It allows you to layer up multiple functions on one pattern. For example, the following+will play two versions of the pattern at the same time, one reversed and one at twice+the speed:++> d1 $ layer [rev, fast 2] $ sound "arpy [~ arpy:4]"++The original version of the pattern can be included by using the @id@ function:++> d1 $ layer [id, rev, fast 2] $ sound "arpy [~ arpy:4]"+-}+layer :: [a -> Pattern b] -> a -> Pattern b+layer fs p = stack $ map ($ p) fs++-- | @arpeggiate@ finds events that share the same timespan, and spreads+-- them out during that timespan, so for example @arpeggiate "[bd,sn]"@+-- gets turned into @"bd sn"@. Useful for creating arpeggios/broken chords.+arpeggiate :: Pattern a -> Pattern a+arpeggiate = arpWith id++-- | Shorthand alias for arpeggiate+arpg :: Pattern a -> Pattern a+arpg = arpeggiate++arpWith :: ([EventF (ArcF Time) a] -> [EventF (ArcF Time) b]) -> Pattern a -> Pattern b+arpWith f p = withEvents munge p+ where munge es = concatMap (spreadOut . f) (groupBy (\a b -> whole a == whole b) $ sortOn whole es)+ spreadOut xs = mapMaybe (\(n, x) -> shiftIt n (length xs) x) $ enumerate xs+ shiftIt n d (Event c (Just (Arc s e)) a' v) =+ do+ a'' <- subArc (Arc newS newE) a'+ return (Event c (Just $ Arc newS newE) a'' v)+ where newS = s + (dur * fromIntegral n)+ newE = newS + dur+ dur = (e - s) / fromIntegral d+ -- TODO ignoring analog events.. Should we just leave them as-is?+ shiftIt _ _ _ = Nothing+++{-| The @arp@ function takes an additional pattern of arpeggiate modes. For example:++@+d1 $ sound "superpiano" # n (arp "<up down diverge>" "<a'm9'8 e'7sus4'8>")+@++The different arpeggiate modes are:+@+up down updown downup up&down down&up converge+diverge disconverge pinkyup pinkyupdown+thumbup thumbupdown+@+-}+arp :: Pattern String -> Pattern a -> Pattern a+arp = tParam _arp++_arp :: String -> Pattern a -> Pattern a+_arp name p = arpWith f p+ where f = fromMaybe id $ lookup name arps+ arps :: [(String, [a] -> [a])]+ arps = [("up", id),+ ("down", reverse),+ ("updown", \x -> init x ++ init (reverse x)),+ ("downup", \x -> init (reverse x) ++ init x),+ ("up&down", \x -> x ++ reverse x),+ ("down&up", \x -> reverse x ++ x),+ ("converge", converge),+ ("diverge", reverse . converge),+ ("disconverge", \x -> converge x ++ tail (reverse $ converge x)),+ ("pinkyup", pinkyup),+ ("pinkyupdown", \x -> init (pinkyup x) ++ init (reverse $ pinkyup x)),+ ("thumbup", thumbup),+ ("thumbupdown", \x -> init (thumbup x) ++ init (reverse $ thumbup x))+ ]+ converge [] = []+ converge (x:xs) = x : converge' xs+ converge' [] = []+ converge' xs = last xs : converge (init xs)+ pinkyup xs = concatMap (:[pinky]) $ init xs+ where pinky = last xs+ thumbup xs = concatMap (\x -> [thumb,x]) $ tail xs+ where thumb = head xs++{- | @rolled@ plays each note of a chord quickly in order, as opposed to+simultaneously; to give a chord a harp-like or strum effect.++Notes are played low to high, and are evenly distributed within (1/4) of the chord event length, as opposed to arp/arpeggiate that spread the notes over the whole event.++@+rolled $ n "c'maj'4" # s "superpiano"+@++@rolled = rolledBy (1/4)@+-}+rolled :: Pattern a -> Pattern a+rolled = rolledBy (1/4)++{-+As 'rolled', but allows you to specify the length of the roll, i.e., the+fraction of the event that the notes will be spread over. The value in the+passed pattern is the divisor of the cycle length. A negative value will play+the arpeggio in reverse order.++@+rolledBy "<1 -0.5 0.25 -0.125>" $ note "c'maj9" # s "superpiano"+@+-}+rolledBy :: Pattern (Ratio Integer) -> Pattern a -> Pattern a+rolledBy pt = tParam rolledWith (segment 1 $ pt)++rolledWith :: Ratio Integer -> Pattern a -> Pattern a+rolledWith t = withEvents aux+ where aux es = concatMap (steppityIn) (groupBy (\a b -> whole a == whole b) $ ((isRev t) es))+ isRev b = (\x -> if x > 0 then id else reverse ) b+ steppityIn xs = mapMaybe (\(n, ev) -> (timeguard n xs ev t)) $ enumerate xs+ timeguard _ _ ev 0 = return ev+ timeguard n xs ev _ = (shiftIt n (length xs) ev)+ shiftIt n d (Event c (Just (Arc s e)) a' v) = do+ a'' <- subArc (Arc newS e) a'+ return (Event c (Just $ Arc newS e) a'' v)+ where newS = s + (dur * fromIntegral n)+ dur = ((e - s)) / ((1/ (abs t))*fromIntegral d)+ shiftIt _ _ ev = return ev++{- TODO !++-- | @fill@ 'fills in' gaps in one pattern with events from another. For example @fill "bd" "cp ~ cp"@ would result in the equivalent of `"~ bd ~"`. This only finds gaps in a resulting pattern, in other words @"[bd ~, sn]"@ doesn't contain any gaps (because @sn@ covers it all), and @"bd ~ ~ sn"@ only contains a single gap that bridges two steps.+fill :: Pattern a -> Pattern a -> Pattern a+fill p' p = struct (splitQueries $ p {query = q}) p'+ where+ q st = removeTolerance (s,e) $ invert (s-tolerance, e+tolerance) $ query p (st {arc = (s-tolerance, e+tolerance)})+ where (s,e) = arc st+ invert (s,e) es = map arcToEvent $ foldr remove [(s,e)] (map part es)+ remove (s,e) xs = concatMap (remove' (s, e)) xs+ remove' (s,e) (s',e') | s > s' && e < e' = [(s',s),(e,e')] -- inside+ | s > s' && s < e' = [(s',s)] -- cut off right+ | e > s' && e < e' = [(e,e')] -- cut off left+ | s <= s' && e >= e' = [] -- swallow+ | otherwise = [(s',e')] -- miss+ arcToEvent a = ((a,a),"x")+ removeTolerance (s,e) es = concatMap (expand) $ map (withPart f) es+ where f a = concatMap (remove' (e,e+tolerance)) $ remove' (s-tolerance,s) a+ expand ((a,xs),c) = map (\x -> ((a,x),c)) xs+ tolerance = 0.01+-}++{- | @ply n@ repeats each event @n@ times within its arc.++For example, the following are equivalent:++@+d1 $ ply 3 $ s "bd ~ sn cp"+d1 $ s "[bd bd bd] ~ [sn sn sn] [cp cp cp]"+@++The first parameter may be given as a pattern, so that the following are equivalent:++@+d1 $ ply "2 3" $ s "bd ~ sn cp"+d1 $ s "[bd bd] ~ [sn sn sn] [cp cp cp]"+@++Here is an example of it being used conditionally:++@+d1 $ every 3 (ply 4) $ s "bd ~ sn cp"+@+-}+ply :: Pattern Rational -> Pattern a -> Pattern a+ply = tParam _ply++_ply :: Rational -> Pattern a -> Pattern a+_ply n pat = squeezeJoin $ (_fast n . pure) <$> pat++-- | As 'ply', but applies a function each time. The applications are compounded.+plyWith :: (Ord t, Num t) => Pattern t -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+plyWith np f p = innerJoin $ (\n -> _plyWith n f p) <$> np++_plyWith :: (Ord t, Num t) => t -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+_plyWith numPat f p = arpeggiate $ compound numPat+ where compound n | n <= 1 = p+ | otherwise = overlay p (f $ compound $ n-1)++{-| Syncopates a rhythm, shifting (delaying) each event halfway into its arc+ (timespan).++ In mini-notation terms, it basically turns every instance of a into @[~ a]@,+ e.g., @"a b [c d] e"@ becomes the equivalent of+ @"[~ a] [~ b] [[~ c] [~ d]] [~ e]"@.+ Every beat then becomes an offbeat, and so the overall effect is to+ syncopate a pattern.++ In the following example, you can hear that the piano chords play between the+ snare and the bass drum. In 4/4 time, they are playing in the 2 and a half,+ and 4 and a half beats:++ > do+ > resetCycles+ > d1 $ stack [+ > press $ n "~ c'maj ~ c'maj" # s "superpiano" # gain 0.9 # pan 0.6,+ > s "[bd,clap sd bd sd]" # pan 0.4+ > ] # cps (90/60/4)++ In the next example, the C major chord plays before the G major. As the slot+ that occupies the C chord is that of one eighth note, it is displaced by press+ only a sixteenth note:++ > do+ > resetCycles+ > d1 $ stack [+ > press $ n "~ [c'maj ~] ~ ~" # s "superpiano" # gain 0.9 # pan 0.6,+ > press $ n "~ g'maj ~ ~" # s "superpiano" # gain 0.9 # pan 0.4,+ > s "[bd,clap sd bd sd]"+ > ] # cps (90/60/4)+-}+press :: Pattern a -> Pattern a+press = _pressBy 0.5++{-| Like @press@, but allows you to specify the amount in which each event is+ shifted as a float from 0 to 1 (exclusive).++ @pressBy 0.5@ is the same as @press@, while @pressBy (1/3)@ shifts each event+ by a third of its arc.++ You can pattern the displacement to create interesting rhythmic effects:++ > d1 $ stack [+ > s "bd sd bd sd",+ > pressBy "<0 0.5>" $ s "co:2*4"+ > ]++ > d1 $ stack [+ > s "[bd,co sd bd sd]",+ > pressBy "<0 0.25 0.5 0.75>" $ s "cp"+ > ]+-}+pressBy :: Pattern Time -> Pattern a -> Pattern a+pressBy = tParam _pressBy++_pressBy :: Time -> Pattern a -> Pattern a+_pressBy r pat = squeezeJoin $ (compressTo (r,1) . pure) <$> pat++{-+ Uses the first (binary) pattern to switch between the following+ two patterns. The resulting structure comes from the source patterns, not the+ binary pattern. See also `stitch`.++ The following will play the first pattern for the first half of a cycle, and+ the second pattern for the other half; it combines two patterns of strings and+ passes the result to the sound function:++ > d1 $ sound (sew "t f" "bd*8" "cp*8")++ It’s possible to sew together two control patterns:++ > d1 $ sew "t <f t> <f [f t] t>"+ > (n "0 .. 15" # s "future")+ > (s "cp:3*16" # speed saw + 1.2)++ You can also use Euclidean rhythm syntax in the boolean sequence:++ > d1 $ sew "t(11,16)"+ > (n "0 .. 15" # s "future")+ > (s "cp:3*16" # speed sine + 1.5)+-}+sew :: Pattern Bool -> Pattern a -> Pattern a -> Pattern a+sew pb a b = overlay (mask pb a) (mask (inv pb) b)++{-| Uses the first (binary) pattern to switch between the following+ two patterns. The resulting structure comes from the binary+ pattern, not the source patterns. (In 'sew', by contrast, the resulting structure comes from the source patterns.)++ The following uses a euclidean pattern to control CC0:++ > d1 $ ccv (stitch "t(7,16)" 127 0) # ccn 0 # "midi"+-}+stitch :: Pattern Bool -> Pattern a -> Pattern a -> Pattern a+stitch pb a b = overlay (struct pb a) (struct (inv pb) b)++-- | A binary pattern is used to conditionally apply a function to a+-- source pattern. The function is applied when a @True@ value is+-- active, and the pattern is let through unchanged when a @False@+-- value is active. No events are let through where no binary values+-- are active.+while :: Pattern Bool -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+while b f pat = sew b (f pat) pat++{-|+@stutter n t pat@ repeats each event in @pat@ @n@ times, separated by @t@ time (in fractions of a cycle).+It is like 'Sound.Tidal.Control.echo' that doesn't reduce the volume, or 'ply' if you controlled the timing.++> d1 $ stutter 4 (1/16) $ s "bd cp"++is functionally equivalent to++> d1 $ stut 4 1 (1/16) $ s "bd cp"+-}+stutter :: Integral i => i -> Time -> Pattern a -> Pattern a+stutter n t p = stack $ map (\i -> (t * fromIntegral i) `rotR` p) [0 .. (n-1)]++{- | The @jux@ function creates strange stereo effects by applying a+ function to a pattern, but only in the right-hand channel. For+ example, the following reverses the pattern on the righthand side:++ > d1 $ slow 32 $ jux (rev) $ striateBy 32 (1/16) $ sound "bev"++ When passing pattern transforms to functions like @jux@ and 'every',+ it's possible to chain multiple transforms together with `.` (function+ composition). For example this both reverses and halves the playback speed of+ the pattern in the righthand channel:++ > d1 $ slow 32 $ jux ((# speed "0.5") . rev) $ striateBy 32 (1/16) $ sound "bev"+-}+jux+ :: (Pattern ValueMap -> Pattern ValueMap)+ -> Pattern ValueMap -> Pattern ValueMap+jux = juxBy 1+juxcut+ :: (Pattern ValueMap -> Pattern ValueMap)+ -> Pattern ValueMap -> Pattern ValueMap+juxcut f p = stack [p # P.pan (pure 0) # P.cut (pure (-1)),+ f $ p # P.pan (pure 1) # P.cut (pure (-2))+ ]++juxcut' :: [t -> Pattern ValueMap] -> t -> Pattern ValueMap+juxcut' fs p = stack $ map (\n -> ((fs !! n) p |+ P.cut (pure $ 1-n)) # P.pan (pure $ fromIntegral n / fromIntegral l)) [0 .. l-1]+ where l = length fs++{- | In addition to `jux`, `jux'` allows using a list of pattern+ transformations. Resulting patterns from each transformation will be spread via+ pan from left to right.++ For example, the following will put @iter 4@ of the pattern to the far left+ and `palindrome` to the far right. In the center, the original pattern will+ play and the chopped and the reversed version will appear mid left and mid+ right respectively.++ > d1 $ jux' [iter 4, chop 16, id, rev, palindrome] $ sound "bd sn"++One could also write:++@+d1 $ stack+ [ iter 4 $ sound "bd sn" # pan "0"+ , chop 16 $ sound "bd sn" # pan "0.25"+ , sound "bd sn" # pan "0.5"+ , rev $ sound "bd sn" # pan "0.75"+ , palindrome $ sound "bd sn" # pan "1"+ ]+@++-}+jux' :: [t -> Pattern ValueMap] -> t -> Pattern ValueMap+jux' fs p = stack $ map (\n -> (fs !! n) p |+ P.pan (pure $ fromIntegral n / fromIntegral l)) [0 .. l-1]+ where l = length fs++-- | Multichannel variant of `jux`, /not sure what it does/+jux4+ :: (Pattern ValueMap -> Pattern ValueMap)+ -> Pattern ValueMap -> Pattern ValueMap+jux4 f p = stack [p # P.pan (pure (5/8)), f $ p # P.pan (pure (1/8))]++{- |+With `jux`, the original and effected versions of the pattern are+panned hard left and right (i.e., panned at 0 and 1). This can be a+bit much, especially when listening on headphones. The variant @juxBy@+has an additional parameter, which brings the channel closer to the+centre. For example:++> d1 $ juxBy 0.5 (fast 2) $ sound "bd sn:1"++In the above, the two versions of the pattern would be panned at 0.25+and 0.75, rather than 0 and 1.+-}+juxBy+ :: Pattern Double+ -> (Pattern ValueMap -> Pattern ValueMap)+ -> Pattern ValueMap+ -> Pattern ValueMap+juxBy n f p = stack [p |+ P.pan 0.5 |- P.pan (n/2), f $ p |+ P.pan 0.5 |+ P.pan (n/2)]++{- |+Given a sample's directory name and number, this generates a string+suitable to pass to 'Data.String.fromString' to create a 'Pattern String'.+'samples' is a 'Pattern'-compatible interface to this function.++@pick name n = name ++ ":" ++ show n@+-}+pick :: String -> Int -> String+pick name n = name ++ ":" ++ show n++{- |+Given a pattern of sample directory names and a of pattern indices+create a pattern of strings corresponding to the sample at each+name-index pair.++An example:++> samples "jvbass [~ latibro] [jvbass [latibro jvbass]]"+> ((1%2) `rotL` slow 6 "[1 6 8 7 3]")++The type signature is more general here, but you can consider this+to be a function of type @Pattern String -> Pattern Int -> Pattern String@.++@samples = liftA2 pick@+-}+samples :: Applicative f => f String -> f Int -> f String+samples p p' = pick <$> p <*> p'++{- |+Equivalent to 'samples', though the sample specifier pattern+(the @f Int@) will be evaluated first. Not a large difference+in the majority of cases.+-}+samples' :: Applicative f => f String -> f Int -> f String+samples' p p' = flip pick <$> p' <*> p++{-+scrumple :: Time -> Pattern a -> Pattern a -> Pattern a+scrumple o p p' = p'' -- overlay p (o `rotR` p'')+ where p'' = Pattern $ \a -> concatMap+ (\((s,d), vs) -> map (\x -> ((s,d),+ snd x+ )+ )+ (arc p' (s,s))+ ) (arc p a)+-}++{-+ As 'spread', but specialized so that the list contains functions returning patterns.++@spreadf = 'spread' ($)@+-}+spreadf :: [a -> Pattern b] -> a -> Pattern b+spreadf = spread ($)++stackwith :: Unionable a => Pattern a -> [Pattern a] -> Pattern a+stackwith p ps | null ps = silence+ | otherwise = stack $ map (\(i, p') -> p' # ((fromIntegral i % l) `rotL` p)) (zip [0::Int ..] ps)+ where l = fromIntegral $ length ps++{-+cross f p p' = Pattern $ \t -> concat [filter flt $ arc p t,+ filter (not . flt) $ arc p' t+ ]+] where flt = f . cyclePos . fst . fst+-}++{- | `range` will take a pattern which goes from 0 to 1 (like `sine`), and range it to a different range - between the first and second arguments. In the below example, `range 1 1.5` shifts the range of `sine1` from 0 - 1 to 1 - 1.5.++> d1 $ jux (iter 4) $ sound "arpy arpy:2*2"+> |+ speed (slow 4 $ range 1 1.5 sine1)++The above is equivalent to:++> d1 $ jux (iter 4) $ sound "arpy arpy:2*2"+> |+ speed (slow 4 $ sine1 * 0.5 + 1)+-}+range :: Num a => Pattern a -> Pattern a -> Pattern a -> Pattern a+range fromP toP p = (\from to v -> ((v * (to-from)) + from)) <$> fromP *> toP *> p++_range :: (Functor f, Num b) => b -> b -> f b -> f b+_range from to p = (+ from) . (* (to-from)) <$> p++{- | `rangex` is an exponential version of `range`, good for using with+frequencies. For example, @range 20 2000 "0.5"@ will give @1010@ - halfway+between @20@ and @2000@. But @rangex 20 2000 0.5@ will give @200@ - halfway+between on a logarithmic scale. This usually sounds better if you’re using the+numbers as pitch frequencies. Since rangex uses logarithms, don’t try to scale+things to zero or less.+-}+rangex :: (Functor f, Floating b) => b -> b -> f b -> f b+rangex from to p = exp <$> _range (log from) (log to) p++{-|+ @off@ is similar to 'superimpose', in that it applies a function to a pattern+ and layers up the results on top of the original pattern. The difference+ is that @off@ takes an extra pattern being a time (in cycles) to shift the+ transformed version of the pattern by.++ The following plays a pattern on top of itself, but offset by an eighth of a+ cycle, with a distorting bitcrush effect applied:++ > d1 $ off 0.125 (# crush 2) $ sound "bd [~ sn:2] mt lt*2"++ The following makes arpeggios by adding offset patterns that are shifted up+ the scale:++ > d1 $ slow 2+ > $ n (off 0.25 (+12)+ > $ off 0.125 (+7)+ > $ slow 2 "c(3,8) a(3,8,2) f(3,8) e(3,8,4)")+ > # sound "superpiano"+-}+off :: Pattern Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+off tp f p = innerJoin $ (\tv -> _off tv f p) <$> tp++_off :: Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+_off t f p = superimpose (f . (t `rotR`)) p++offadd :: Num a => Pattern Time -> Pattern a -> Pattern a -> Pattern a+offadd tp pn p = off tp (+pn) p++{- |+ @step@ acts as a kind of simple step-sequencer using strings. For example,+ @step "sn" "x x 12"@ is equivalent to the pattern of strings given by @"sn ~+ sn ~ sn:1 sn:2 ~"@. @step@ substitutes the given string for each @x@, for each number+ it substitutes the string followed by a colon and the number, and for everything+ else it puts in a rest.++ In other words, @step@ generates a pattern of strings in exactly the syntax you’d want for selecting samples and that can be fed directly into the 's' function.++ > d1 $ s (step "sn" "x x 12 ")+-}+step :: String -> String -> Pattern String+step s cs = fastcat $ map f cs+ where f c | c == 'x' = pure s+ | isDigit c = pure $ s ++ ":" ++ [c]+ | otherwise = silence++{- | @steps@ is like @step@ but it takes a list of pairs, like step would, and+ it plays them all simultaneously.++ > d1 $ s (steps [("cp","x x x x x x"),("bd", "xxxx")])+-}+steps :: [(String, String)] -> Pattern String+steps = stack . map (uncurry step)++{- | like `step`, but allows you to specify an array of strings to use for @0,1,2...@+ For example,++ > d1 $ s (step' ["superpiano","supermandolin"] "0 1 000 1")+ > # sustain 4 # n 0++ is equivalent to++ > d1 $ s "superpiano ~ supermandolin ~ superpiano!3 ~ supermandolin"+ > # sustain 4 # n 0+-}+step' :: [String] -> String -> Pattern String+step' ss cs = fastcat $ map f cs+ where f c | c == 'x' = pure $ head ss+ | isDigit c = pure $ ss !! digitToInt c+ | otherwise = silence+++-- | Deprecated backwards-compatible alias for 'ghostWith'.+ghost'' :: Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+ghost'' = ghostWith++{-| Like 'ghost'', but a user-supplied function describes how to alter the pattern.++ In this example, ghost notes are applied to the snare hit, but these notes will+ be louder, not quieter, and the sample will have its beginning slightly cut:++ > d1 $ slow 2+ > $ ghostWith (1/16) ((|*| gain 1.1) . (|> begin 0.05))+ > $ sound "sn"++-}+ghostWith :: Time -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+ghostWith a f p = superimpose (((a*2.5) `rotR`) . f) $ superimpose (((a*1.5) `rotR`) . f) p++{-+@ghost' t pat@ Adds quieter, pitch-shifted, copies of an event @t@ cycles after events in @pat@, emulating ghost notes that are common in drumming patterns.++The following creates a kick snare pattern with ghost notes applied to the snare hit:++> d1 $ stack [ ghost' 0.125 $ sound "~ sn", sound "bd*2 [~ bd]" ]+-}+ghost' :: Time -> Pattern ValueMap -> Pattern ValueMap+ghost' a p = ghostWith a ((|*| P.gain (pure 0.7)) . (|> P.end (pure 0.2)) . (|*| P.speed (pure 1.25))) p++{-| As 'ghost'', but with the copies set to appear one-eighth of a cycle afterwards.++@ghost = ghost' 0.125@++The following creates a kick snare pattern with ghost notes applied to the snare hit:++> d1 $ stack [ ghost $ sound "~ sn", sound "bd*2 [~ bd]" ]+-}+ghost :: Pattern ValueMap -> Pattern ValueMap+ghost = ghost' 0.125++{- | A more literal weaving than the `weave` function. Given @tabby threads p1 p@,+ parameters representing the threads per cycle and the patterns to weave, and+ this function will weave them together using a plain (aka ’tabby’) weave,+ with a simple over/under structure+ -}+tabby :: Int -> Pattern a -> Pattern a -> Pattern a+tabby nInt p p' = stack [maskedWarp,+ maskedWeft+ ]+ where+ n = fromIntegral nInt+ weft = concatMap (const [[0..n-1], reverse [0..n-1]]) [0 .. (n `div` 2) - 1]+ warp = transpose weft+ thread xs p'' = _slow (n%1) $ fastcat $ map (\i -> zoomArc (Arc (i%n) ((i+1)%n)) p'') (concat xs)+ weftP = thread weft p'+ warpP = thread warp p+ maskedWeft = mask (every 2 rev $ _fast (n % 2) $ fastCat [silence, pure True]) weftP+ maskedWarp = mask (every 2 rev $ _fast (n % 2) $ fastCat [pure True, silence]) warpP++-- | Chooses from a list of patterns, using a pattern of floats (from 0 to 1).+select :: Pattern Double -> [Pattern a] -> Pattern a+select = tParam _select++_select :: Double -> [Pattern a] -> Pattern a+_select f ps = ps !! floor (max 0 (min 1 f) * fromIntegral (length ps - 1))++-- | Chooses from a list of functions, using a pattern of floats (from 0 to 1).+selectF :: Pattern Double -> [Pattern a -> Pattern a] -> Pattern a -> Pattern a+selectF pf ps p = innerJoin $ (\f -> _selectF f ps p) <$> pf++_selectF :: Double -> [Pattern a -> Pattern a] -> Pattern a -> Pattern a+_selectF f ps p = (ps !! floor (max 0 (min 0.999999 f) * fromIntegral (length ps))) p++-- | Chooses from a list of functions, using a pattern of integers.+pickF :: Pattern Int -> [Pattern a -> Pattern a] -> Pattern a -> Pattern a+pickF pInt fs pat = innerJoin $ (\i -> _pickF i fs pat) <$> pInt++_pickF :: Int -> [Pattern a -> Pattern a] -> Pattern a -> Pattern a+_pickF i fs p = (fs !!! i) p++{- | @contrast f f' p p'@ splits the control pattern @p'@ in two, applying+ the function @f@ to one and @f'@ to the other. This depends on+ whether events in @p'@ contain values matching with those in @p@.+ For example, in++ > contrast (# crush 3) (# vowel "a") (n "1") $ n "0 1" # s "bd sn" # speed 3++ the first event will have the vowel effect applied and the second will have+ the crush applied.++ @contrast@ is like an if-else-statement over patterns. For @contrast t f p@+ you can think of @t@ as the true branch, @f@ as the false branch, and @p@ as+ the test.++ You can use any control pattern as a test of equality, e.g., @n "<0 1>", speed+ "0.5"@, or things like that. This lets you choose specific properties of the+ pattern you’re transforming for testing, like in the following example,++ > d1 $ contrast (|+ n 12) (|- n 12) (n "c") $ n (run 4) # s "superpiano"++ where every note that isn’t middle-c will be shifted down an octave but+ middle-c will be shifted up to c5.++ Since the test given to contrast is also a pattern, you can do things like have+ it alternate between options:++ > d1 $ contrast (|+ n 12) (|- n 12) (s "<superpiano superchip>")+ > $ s "superpiano superchip" # n 0++ If you listen to this you’ll hear that which instrument is shifted up and which+ instrument is shifted down alternates between cycles.+-}+contrast :: (ControlPattern -> ControlPattern) -> (ControlPattern -> ControlPattern)+ -> ControlPattern -> ControlPattern -> ControlPattern+contrast = contrastBy (==)++{-|+ @contrastBy@ is contrastBy is the general version of 'contrast', in which you can specify an abritrary boolean function that will be used to compare the control patterns.++ > d2 $ contrastBy (>=) (|+ n 12) (|- n 12) (n "2") $ n "0 1 2 [3 4]" # s "superpiano"+-}+contrastBy :: (a -> Value -> Bool)+ -> (ControlPattern -> Pattern b)+ -> (ControlPattern -> Pattern b)+ -> Pattern (Map.Map String a)+ -> Pattern (Map.Map String Value)+ -> Pattern b+contrastBy comp f f' p p' = overlay (f matched) (f' unmatched)+ where matches = matchManyToOne (flip $ Map.isSubmapOfBy comp) p p'+ matched :: ControlPattern+ matched = filterJust $ (\(t, a) -> if t then Just a else Nothing) <$> matches+ unmatched :: ControlPattern+ unmatched = filterJust $ (\(t, a) -> if not t then Just a else Nothing) <$> matches++contrastRange+ :: (ControlPattern -> Pattern a)+ -> (ControlPattern -> Pattern a)+ -> Pattern (Map.Map String (Value, Value))+ -> ControlPattern+ -> Pattern a+contrastRange = contrastBy f+ where f (VI s, VI e) (VI v) = v >= s && v <= e+ f (VF s, VF e) (VF v) = v >= s && v <= e+ f (VN s, VN e) (VN v) = v >= s && v <= e+ f (VS s, VS e) (VS v) = v == s && v == e+ f _ _ = False++{- |+ The @fix@ function applies another function to matching events in a pattern of+ controls. @fix@ is 'contrast' where the false-branching function is set to the+ identity 'id'. It is like 'contrast', but one function is given and applied to+ events with matching controls.++ For example, the following only adds the 'crush' control when the @n@ control+ is set to either 1 or 4:++ > d1 $ slow 2+ > $ fix (# crush 3) (n "[1,4]")+ > $ n "0 1 2 3 4 5 6"+ > # sound "arpy"++ You can be quite specific; for example, the following applies the function+ @'hurry' 2@ to sample 1 of the drum sample set, and leaves the rest as they are:++ > fix (hurry 2) (s "drum" # n "1")+-}+fix :: (ControlPattern -> ControlPattern) -> ControlPattern -> ControlPattern -> ControlPattern+fix f = contrast f id++-- | Like 'contrast', but one function is given, and applied to events with+-- controls which don't match. @unfix@ is 'fix' but only applies when the+-- testing pattern is /not/ a match.+unfix :: (ControlPattern -> ControlPattern) -> ControlPattern -> ControlPattern -> ControlPattern+unfix = contrast id++{-|+ The @fixRange@ function isn’t very user-friendly at the moment, but you can+ create a @fix@ variant with a range condition. Any value of a 'ControlPattern'+ wich matches the values will apply the passed function.++ > d1 $ ( fixRange ( (# distort 1) . (# gain 0.8) )+ > ( pure $ Map.singleton "note" ((VN 0, VN 7)) )+ > )+ > $ s "superpiano"+ > <| note "1 12 7 11"+-}+fixRange :: (ControlPattern -> Pattern ValueMap)+ -> Pattern (Map.Map String (Value, Value))+ -> ControlPattern+ -> ControlPattern+fixRange f = contrastRange f id++unfixRange :: (ControlPattern -> Pattern ValueMap)+ -> Pattern (Map.Map String (Value, Value))+ -> ControlPattern+ -> ControlPattern+unfixRange = contrastRange id++{- | @quantise@ limits values in a Pattern (or other Functor) to @n@ equally spaced+divisions of 1.++It is useful for rounding a collection of numbers to some particular base+fraction. For example,++> quantise 5 [0, 1.3 ,2.6,3.2,4.7,5]++It will round all the values to the nearest @(1/5)=0.2@ and thus will output+the list @[0.0,1.2,2.6,3.2,4.8,5.0]@. You can use this function to force a+continuous pattern like sine into specific values. In the following example:++> d1 $ s "superchip*8" # n (quantise 1 $ range (-10) (10) $ slow 8 $ cosine)+> # release (quantise 5 $ slow 8 $ sine + 0.1)++all the releases selected be rounded to the nearest @0.1@ and the notes selected+to the nearest @1@.++@quantise@ with fractional inputs does the consistent thing: @quantise 0.5@+rounds values to the nearest @2@, @quantise 0.25@ rounds the nearest @4@, etc.+-}+quantise :: (Functor f, RealFrac b) => b -> f b -> f b+quantise n = fmap ((/n) . (fromIntegral :: RealFrac b => Int -> b) . round . (*n))++-- | As 'quantise', but uses 'Prelude.floor' to calculate divisions.+qfloor :: (Functor f, RealFrac b) => b -> f b -> f b+qfloor n = fmap ((/n) . (fromIntegral :: RealFrac b => Int -> b) . floor . (*n))++-- | As 'quantise', but uses 'Prelude.ceiling' to calculate divisions.+qceiling :: (Functor f, RealFrac b) => b -> f b -> f b+qceiling n = fmap ((/n) . (fromIntegral :: RealFrac b => Int -> b) . ceiling . (*n))++-- | An alias for 'quantise'.+qround :: (Functor f, RealFrac b) => b -> f b -> f b+qround = quantise++-- | Inverts all the values in a boolean pattern+inv :: Functor f => f Bool -> f Bool+inv = (not <$>)++-- | Serialises a pattern so there's only one event playing at any one+-- time, making it /monophonic/. Events which start/end earlier are given priority.+mono :: Pattern a -> Pattern a+mono p = Pattern $ \(State a cm) -> flatten $ query p (State a cm) where+ flatten :: [Event a] -> [Event a]+ flatten = mapMaybe constrainPart . truncateOverlaps . sortOn whole+ truncateOverlaps [] = []+ truncateOverlaps (e:es) = e : truncateOverlaps (mapMaybe (snip e) es)+ -- TODO - decide what to do about analog events..+ snip a b | start (wholeOrPart b) >= stop (wholeOrPart a) = Just b+ | stop (wholeOrPart b) <= stop (wholeOrPart a) = Nothing+ | otherwise = Just b {whole = Just $ Arc (stop $ wholeOrPart a) (stop $ wholeOrPart b)}+ constrainPart :: Event a -> Maybe (Event a)+ constrainPart e = do a <- subArc (wholeOrPart e) (part e)+ return $ e {part = a}++{-|+@smooth@ receives a pattern of numbers and linearly goes from one to the next, passing through all of them. As time is cycle-based, after reaching the last number in the pattern, it will smoothly go to the first one again.++> d1 $ sound "bd*4" # pan (slow 4 $ smooth "0 1 0.5 1")++This sound will pan gradually from left to right, then to the center, then to the right again, and finally comes back to the left.+-}++-- serialize the given pattern+-- find the middle of the query's arc and use that to query the serialized pattern. We should get either no events or a single event back+-- if we don't get any events, return nothing+-- if we get an event, get the stop of its arc, and use that to query the serialized pattern, to see if there's an adjoining event+-- if there isn't, return the event as-is.+-- if there is, check where we are in the 'whole' of the event, and use that to tween between the values of the event and the next event+-- smooth :: Pattern Double -> Pattern Double++-- TODO - test this with analog events+smooth :: Fractional a => Pattern a -> Pattern a+smooth p = Pattern $ \st@(State a cm) -> tween st a $ query monoP (State (midArc a) cm)+ where+ midArc a = Arc (mid (start a, stop a)) (mid (start a, stop a))+ tween _ _ [] = []+ tween st queryA (e:_) = maybe [e {whole = Just queryA, part = queryA}] (tween' queryA) (nextV st)+ where aStop = Arc (wholeStop e) (wholeStop e)+ nextEs st' = query monoP (st' {arc = aStop})+ nextV st' | null (nextEs st') = Nothing+ | otherwise = Just $ value (head (nextEs st'))+ tween' queryA' v =+ [ Event+ { context = context e,+ whole = Just queryA'+ , part = queryA'+ , value = value e + ((v - value e) * pc)}+ ]+ pc | delta' (wholeOrPart e) == 0 = 0+ | otherwise = fromRational $ (eventPartStart e - wholeStart e) / delta' (wholeOrPart e)+ delta' a = stop a - start a+ monoP = mono p++-- | Looks up values from a list of tuples, in order to swap values in the given pattern+swap :: Eq a => [(a, b)] -> Pattern a -> Pattern b+swap things p = filterJust $ (`lookup` things) <$> p++{-|+ @snowball@ takes a function that can combine patterns (like '+'),+ a function that transforms a pattern (like 'slow'),+ a depth, and a starting pattern,+ it will then transform the pattern and combine it with the last transformation until the depth is reached.+ This is like putting an effect (like a filter) in the feedback of a delay line; each echo is more affected.++ > d1 $ note ( scale "hexDorian"+ > $ snowball 8 (+) (slow 2 . rev) "0 ~ . -1 . 5 3 4 . ~ -2"+ > )+ > # s "gtr"+-}+snowball :: Int -> (Pattern a -> Pattern a -> Pattern a) -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+snowball depth combinationFunction f pattern = cat $ take depth $ scanl combinationFunction pattern $ drop 1 $ iterate f pattern++{- |+ Applies a function to a pattern and cats the resulting pattern, then continues+ applying the function until the depth is reached this can be used to create+ a pattern that wanders away from the original pattern by continually adding+ random numbers.++ > d1 $ note ( scale "hexDorian" mutateBy (+ (range -1 1 $ irand 2)) 8+ > $ "0 1 . 2 3 4"+ > )+ > # s "gtr"+-}+soak :: Int -> (Pattern a -> Pattern a) -> Pattern a -> Pattern a+soak depth f pattern = cat $ take depth $ iterate f pattern++-- | @construct n p@ breaks @p@ into pieces and then reassembles them+-- so that it fits into @n@ steps.+deconstruct :: Int -> Pattern String -> String+deconstruct n p = intercalate " " $ map showStep $ toList p+ where+ showStep :: [String] -> String+ showStep [] = "~"+ showStep [x] = x+ showStep xs = "[" ++ (intercalate ", " xs) ++ "]"+ toList :: Pattern a -> [[a]]+ toList pat = map (\(s,e) -> map value $ queryArc (_segment n' pat) (Arc s e)) arcs+ where breaks = [0, (1/n') ..]+ arcs = zip (take n breaks) (drop 1 breaks)+ n' = fromIntegral n++{- | @bite n ipat pat@ slices a pattern @pat@ into @n@ pieces, then uses the+ @ipat@ pattern of integers to index into those slices. So @bite 4 "0 2*2" (run+ 8)@ is the same as @"[0 1] [4 5]*2"@.++ I.e., it allows you to slice each cycle into a given number of equal sized+ bits, and then pattern those bits by number. It’s similar to @slice@, but is+ for slicing up patterns, rather than samples. The following slices the pattern+ into four bits, and then plays those bits in turn:++ > d1 $ bite 4 "0 1 2 3" $ n "0 .. 7" # sound "arpy"++ Of course that doesn’t actually change anything, but then you can reorder those bits:++ > d1 $ bite 4 "2 0 1 3" $ n "0 .. 7" # sound "arpy"++ The slices bits of pattern will be squeezed or contracted to fit:++ > d1 $ bite 4 "2 [0 3] 1*4 1" $ n "0 .. 7" # sound "arpy"+-}+bite :: Pattern Int -> Pattern Int -> Pattern a -> Pattern a+bite npat ipat pat = innerJoin $ (\n -> _bite n ipat pat) <$> npat++_bite :: Int -> Pattern Int -> Pattern a -> Pattern a+_bite n ipat pat = squeezeJoin $ zoompat <$> ipat+ where zoompat i = zoom (i'/(fromIntegral n), (i'+1)/(fromIntegral n)) pat+ where i' = fromIntegral $ i `mod` n++-- | Chooses from a list of patterns, using a pattern of integers.+squeeze :: Pattern Int -> [Pattern a] -> Pattern a+squeeze _ [] = silence+squeeze ipat pats = squeezeJoin $ (pats !!!) <$> ipat++squeezeJoinUp :: Pattern (ControlPattern) -> ControlPattern+squeezeJoinUp pp = pp {query = q}+ where q st = concatMap (f st) (query (filterDigital pp) st)+ f st (Event c (Just w) p v) =+ mapMaybe (munge c w p) $ query (compressArc (cycleArc w) (v |* P.speed (pure $ fromRational $ 1/(stop w - start w)))) st {arc = p}+ -- already ignoring analog events, but for completeness..+ f _ _ = []+ munge co oWhole oPart (Event ci (Just iWhole) iPart v) =+ do w' <- subArc oWhole iWhole+ p' <- subArc oPart iPart+ return (Event (combineContexts [ci,co]) (Just w') p' v)+ munge _ _ _ _ = Nothing++_chew :: Int -> Pattern Int -> ControlPattern -> ControlPattern+_chew n ipat pat = (squeezeJoinUp $ zoompat <$> ipat) |/ P.speed (pure $ fromIntegral n)+ where zoompat i = zoom (i'/(fromIntegral n), (i'+1)/(fromIntegral n)) (pat)+ where i' = fromIntegral $ i `mod` n++{-|+ @chew@ works the same as 'bite', but speeds up\/slows down playback of sounds as+ well as squeezing\/contracting the slices of the provided pattern. Compare:++ > d1 $ 'bite' 4 "0 1*2 2*2 [~ 3]" $ n "0 .. 7" # sound "drum"+ > d1 $ chew 4 "0 1*2 2*2 [~ 3]" $ n "0 .. 7" # sound "drum"+-}++-- TODO maybe _chew could pattern the first parameter directly..+chew :: Pattern Int -> Pattern Int -> ControlPattern -> ControlPattern+chew npat ipat pat = innerJoin $ (\n -> _chew n ipat pat) <$> npat++__binary :: Data.Bits.Bits b => Int -> b -> [Bool]+__binary n num = map (testBit num) $ reverse [0 .. n-1]++_binary :: Data.Bits.Bits b => Int -> b -> Pattern Bool+_binary n num = listToPat $ __binary n num++_binaryN :: Int -> Pattern Int -> Pattern Bool+_binaryN n p = squeezeJoin $ _binary n <$> p++binaryN :: Pattern Int -> Pattern Int -> Pattern Bool+binaryN n p = tParam _binaryN n p++binary :: Pattern Int -> Pattern Bool+binary = binaryN 8++ascii :: Pattern String -> Pattern Bool+ascii p = squeezeJoin $ (listToPat . concatMap (__binary 8 . ord)) <$> p++{- | Given a start point and a duration (both specified in cycles), this+ generates a control pattern that makes a sound begin at the start+ point and last the duration.++ The following are equivalent:++ > d1 $ slow 2 $ s "bev" # grain 0.2 0.1 # legato 1+ > d1 $ slow 2 $ s "bev" # begin 0.2 # end 0.3 # legato 1++ @grain@ is defined as:++ > grain s d = 'Sound.Tidal.Params.begin' s # 'Sound.Tidal.Params.end' (s+d)+-}+grain :: Pattern Double -> Pattern Double -> ControlPattern+grain s w = P.begin b # P.end e+ where b = s+ e = s + w++-- | For specifying a boolean pattern according to a list of offsets+-- (aka inter-onset intervals). For example @necklace 12 [4,2]@ is -- the same as "t f f f t f t f f f t f". That is, 12 steps per cycle, -- with true values alternating between every 4 and every 2 steps. necklace :: Rational -> [Int] -> Pattern Bool
src/Sound/Tidal/Version.hs view
@@ -21,7 +21,7 @@ -} tidal_version :: String-tidal_version = "1.9.4"+tidal_version = "1.9.5" tidal_status :: IO () tidal_status = tidal_status_string >>= putStrLn
tidal.cabal view
@@ -1,7 +1,7 @@ cabal-version: 2.0 name: tidal-version: 1.9.4+version: 1.9.5 synopsis: Pattern language for improvised music description: Tidal is a domain specific language for live coding patterns. homepage: http://tidalcycles.org/@@ -53,21 +53,21 @@ Paths_tidal Build-depends: base >=4.8 && <5- , containers < 0.7+ , containers < 0.8 , colour < 2.4 , hosc >= 0.20 && < 0.21- , text < 2.1+ , text < 2.2 , parsec >= 3.1.12 && < 3.2 , network < 3.2 , transformers >= 0.5 && < 0.7- , bytestring < 0.12+ , bytestring < 0.13 , clock < 0.9 , deepseq >= 1.1.0.0- , primitive < 0.9+ , primitive < 0.10 , random < 1.3 , exceptions < 0.11 , mtl >= 2.2- , tidal-link == 1.0.1+ , tidal-link == 1.0.3 test-suite tests type: exitcode-stdio-1.0@@ -116,7 +116,7 @@ Tidal.Inputs build-depends: base == 4.*- , criterion+ , criterion >= 1.6.3.0 , tidal ghc-options: -Wall