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-- region V1: 6 op, too complex
do
-- sets the amount of operator 'op' in the superfm output mix
-- (1 <= op <= 6)
-- fmamp :: Int -> Pattern Double -> ControlPattern
let fmamp op = pF ("amp" ++ show op)
-- sets the ratio for operator 'op'.
-- the frequency is note * ratio + detune Hz
-- (1 <= op <= 6)
-- fmratio :: Int -> Pattern Double -> ControlPattern
let fmratio op = pF ("ratio" ++ show op)
-- set the detune for operator 'op'
-- fmdetune :: Int -> Pattern Double -> ControlPattern
let fmdetune op = pF ("detune" ++ show op)
-- set the modulation of oerator opa by operator opb
-- if opa == opb, then the modulation amount is multiplied by the
-- 'feedback' parameter
-- fmmod :: Int -> Int -> Pattern Double -> ControlPattern
let fmmod opa opb = pF ("mod" ++ show opa ++ show opb)
-- feedback
-- fmfeedback :: Pattern Double -> ControlPattern
let fmfeedback = pF "feedback"
-- Envelope definition: each operator has an envelop with 4 steps
-- fmeglevel :: Int -> Int -> Pattern Double -> ControlPattern
let fmeglevel op step = pF ("eglevel" ++ show op ++ show step)
-- Envelope definition: sets the rate at which the envelope moves
-- between steps. Low numbers are slow, high numbers are fast.
-- fmegrate :: Int -> Int -> Pattern Double -> ControlPattern
let fmegrate op step = pF ("egrate" ++ show op ++ show step)
let fmparam function (x:xs) = foldr (#) (function 1 x) (zipWith function [2..] xs)
let fmamps = fmparam fmamp
let fmratios = fmparam fmratio
let fmdetunes = fmparam fmdetune
let envrate op = fmparam (fmegrate op)
let envlevel op = fmparam (fmeglevel op)
d1
$ s "superfm"
|+| note (scale "aeolian" (
-- arp "pinkyup" "[0,4,7,12] [0,5,7,9]"
"[0,4,6]"
+ "[0(<3 3 <3 1> <5 [5 3]>>,8)]*2"
+ "0 2"
- 7
))
# gain (range 0 1.8 "^77")
# fmfeedback (range 0 2 "^78")
# fmamps ["^15", "^16", "^17", "^18", "^19", "^20"]
# fmratios ["^31", "^32", "^33", "^34", "^35", "^36"]
# fmdetunes ["^51", "^52", "^53", "^54", "^55", "^56"]
# fmmod 1 1 1
# fmmod 1 2 0
# fmmod 2 3 0
# fmmod 3 4 0
# fmmod 4 5 0
# fmmod 5 6 0
# envlevel 1 [1, 0.5, 0, 0, 0, 0]
# envrate 1 [10, 0.1, 0.1, 1, 0, 0]
# envlevel 2 [1, 0, 0, 0, 0, 0]
# envrate 2 [1, 0.3, 0.7, 1, 0, 0]
# envlevel 3 [1, 0.2, 0, 1, 0, 0]
# envrate 3 [10, 0.5, 0.4, 1, 0, 0]
# lpf 1000
# room 0.3
-- endregion V1
-- region V2 minimaliste
do
-- sets the amount of operator 'op' in the superfm output mix
-- (1 <= op <= 6)
-- fmamp :: Int -> Pattern Double -> ControlPattern
let fmamp op = pF ("amp" ++ show op)
-- sets the ratio for operator 'op'.
-- the frequency is note * ratio + detune Hz
-- (1 <= op <= 6)
-- fmratio :: Int -> Pattern Double -> ControlPattern
let fmratio op = pF ("ratio" ++ show op)
-- set the detune for operator 'op'
-- fmdetune :: Int -> Pattern Double -> ControlPattern
let fmdetune op = pF ("detune" ++ show op)
-- set the modulation of oerator opa by operator opb
-- if opa == opb, then the modulation amount is multiplied by the
-- 'feedback' parameter
-- fmmod :: Int -> Int -> Pattern Double -> ControlPattern
let fmmod opa opb = pF ("mod" ++ show opa ++ show opb)
-- feedback
-- fmfeedback :: Pattern Double -> ControlPattern
let fmfeedback = pF "feedback"
-- Envelope definition: each operator has an envelop with 4 steps
-- fmeglevel :: Int -> Int -> Pattern Double -> ControlPattern
let fmeglevel op step = pF ("eglevel" ++ show op ++ show step)
-- Envelope definition: sets the rate at which the envelope moves
-- between steps. Low numbers are slow, high numbers are fast.
-- fmegrate :: Int -> Int -> Pattern Double -> ControlPattern
let fmegrate op step = pF ("egrate" ++ show op ++ show step)
let fmparam function (x:xs) = foldr (#) (function 1 x) (zipWith function [2..] xs)
let fmamps = fmparam fmamp
let fmratios = fmparam fmratio
let fmdetunes = fmparam fmdetune
let envrate op = fmparam (fmegrate op)
let envlevel op = fmparam (fmeglevel op)
-- Params
let lfodepth = pF "lfodepth"
let lfofreq = pF "lfofreq"
-- Nova
let novaOn ch pat = someCyclesBy ch pat
let novaOff ch pat = someCyclesBy (1 - ch) (pat)
d1 $ "jazz*<2!16 4!16>" # lpf 2000 # gain (1 - (0.5 * (1 - "^77")))
d2
$ novaOn "^42" (off "q" ((# room 0.2) . (|* gain 0.8)))
$ novaOn "^43" (degradeBy "0 1!5 0.5 0.25")
$ novaOn "^41" rev
$ s "superfm"
|+| note (scale "aeolian" (
-- arp "pinkyup" "[0,4,7,12] [0,5,7,9]"
"<[1 2] [2 <3 [3 4]>]>"
+ "[0,6,10]"
+ "[0(<3 3 <3 1> <5 [5 3]>>,8)]*2"
+ "0 2"
- 7
))
# gain (range 0 1 "^77")
# fmfeedback (range 0 400 "^78")
# lfofreq (range 500 1000 "^79")
# lfodepth (range 0 1 "^80")
-- # fmamps ["^15", "^17", "^19"]
# fmratios [range 0 100 "^31", range 0 100 "^33", range 0 100 "^35"]
-- # fmdetunes ["^32", "^53", "^55"]
# fmmod 1 1 (range 0 4 "^16")
# fmmod 1 2 (range 0 4 "^32")
# fmmod 1 3 (range 0 4 "^52")
# fmmod 2 1 "^18"
# fmmod 2 2 "^34"
# fmmod 2 3 "^54"
# fmmod 3 1 "^20"
# fmmod 3 2 "^36"
# fmmod 3 3 "^56"
# fmmod 3 4 1
# fmmod 4 5 1
# fmmod 5 6 1
# envlevel 1 [1, perlin, perlin, 0, 0, 0]
# envrate 1 [perlin, 1, 1, 0, 0, 0]
# envlevel 2 [1, 1, 1, 0, 0, 0]
# envrate 2 [1, 0, 1, 0, 0, 0]
# envlevel 3 [1, 0, 1, slow 4 sine, slow 8 cosine, 1]
# envrate 3 [1, fast 4 sine, 1, 1, 1, 1]
# envlevel 4 [1, 1, 1, 1, 1, 1]
# envrate 4 [1, 1, 1, 1, 1, 1]
# envlevel 5 [1, 1, 1, 1, 1, 1]
# envrate 5 [1, 1, 1, 1, 1, 1]
-- # envlevel 6 [1, 1, 1, 1, 1, 1]
-- # envrate 6 [1, 1, 1, 1, 1, 1]
-- endregion V2