{-# LANGUAGE NoImplicitPrelude #-} {- | Copyright : (c) Henning Thielemann 2006 License : GPL Maintainer : synthesizer@henning-thielemann.de Stability : provisional Portability : requires multi-parameter type classes Tone generators -} module Synthesizer.State.Oscillator where import qualified Synthesizer.Causal.Oscillator as Osci import qualified Synthesizer.Basic.WaveSmoothed as WaveSmooth import qualified Synthesizer.Basic.Wave as Wave import qualified Synthesizer.Basic.Phase as Phase import qualified Synthesizer.Causal.Process as Causal import qualified Synthesizer.State.Signal as Sig import qualified Synthesizer.Generic.Signal as SigG import qualified Synthesizer.Interpolation as Interpolation import qualified Algebra.Transcendental as Trans import qualified Algebra.RealField as RealField -- import qualified Prelude as P -- import NumericPrelude -- import PreludeBase {- * Oscillators with arbitrary but constant waveforms -} {-# INLINE static #-} {- | Oscillator with constant frequency. It causes aliasing effects for sharp waveforms and high frequencies. -} static :: (RealField.C a) => Wave.T a b -> (Phase.T a -> a -> Sig.T b) static wave phase freq = Sig.map (Wave.apply wave) (Osci.freqToPhases phase freq) {-# INLINE staticAntiAlias #-} {- | Oscillator with constant frequency that suppresses aliasing effects using waveforms with controllable smoothness. -} staticAntiAlias :: (RealField.C a) => WaveSmooth.T a b -> (Phase.T a -> a -> Sig.T b) staticAntiAlias wave phase freq = Sig.map (WaveSmooth.apply wave freq) (Osci.freqToPhases phase freq) {-# INLINE phaseMod #-} {- | oscillator with modulated phase -} phaseMod :: (RealField.C a) => Wave.T a b -> a -> Sig.T a -> Sig.T b phaseMod wave freq = Causal.apply (Osci.phaseMod wave freq) {-# INLINE shapeMod #-} {- | oscillator with modulated shape -} shapeMod :: (RealField.C a) => (c -> Wave.T a b) -> Phase.T a -> a -> Sig.T c -> Sig.T b shapeMod wave phase freq = Causal.apply (Osci.shapeMod wave phase freq) {-# INLINE freqMod #-} {- | oscillator with modulated frequency -} freqMod :: (RealField.C a) => Wave.T a b -> Phase.T a -> Sig.T a -> Sig.T b freqMod wave phase = Causal.apply (Osci.freqMod wave phase) {-# INLINE freqModAntiAlias #-} {- | oscillator with modulated frequency -} freqModAntiAlias :: (RealField.C a) => WaveSmooth.T a b -> Phase.T a -> Sig.T a -> Sig.T b freqModAntiAlias wave phase = Causal.apply (Osci.freqModAntiAlias wave phase) {-# INLINE phaseFreqMod #-} {- | oscillator with both phase and frequency modulation -} phaseFreqMod :: (RealField.C a) => Wave.T a b -> Sig.T a -> Sig.T a -> Sig.T b phaseFreqMod wave = Causal.apply2 (Osci.phaseFreqMod wave) {-# INLINE shapeFreqMod #-} {- | oscillator with both shape and frequency modulation -} shapeFreqMod :: (RealField.C a) => (c -> Wave.T a b) -> Phase.T a -> Sig.T c -> Sig.T a -> Sig.T b shapeFreqMod wave phase = Causal.apply2 (Osci.shapeFreqMod wave phase) {- | oscillator with a sampled waveform with constant frequency This essentially an interpolation with cyclic padding. -} {-# INLINE staticSample #-} staticSample :: RealField.C a => Interpolation.T a b -> Sig.T b -> Phase.T a -> a -> Sig.T b staticSample ip wave phase freq = Causal.apply (Osci.freqModSample ip wave phase) (Sig.repeat freq) {- | oscillator with a sampled waveform with modulated frequency Should behave homogenously for different types of interpolation. -} {-# INLINE freqModSample #-} freqModSample :: RealField.C a => Interpolation.T a b -> Sig.T b -> Phase.T a -> Sig.T a -> Sig.T b freqModSample ip wave phase = Causal.apply (Osci.freqModSample ip wave phase) {-# INLINE shapeFreqModSample #-} shapeFreqModSample :: (RealField.C c, RealField.C a) => Interpolation.T c (Wave.T a b) -> Sig.T (Wave.T a b) -> c -> Phase.T a -> Sig.T c -> Sig.T a -> Sig.T b shapeFreqModSample ip waves shape0 phase = Causal.apply2 (Osci.shapeFreqModSample ip waves shape0 phase) {-# INLINE shapeFreqModFromSampledTone #-} shapeFreqModFromSampledTone :: (RealField.C a, SigG.Transform sig b) => Interpolation.T a b -> Interpolation.T a b -> a -> sig b -> a -> Phase.T a -> Sig.T a -> Sig.T a -> Sig.T b shapeFreqModFromSampledTone ipLeap ipStep period sampledTone shape0 phase = Causal.apply2 (Osci.shapeFreqModFromSampledTone ipLeap ipStep period sampledTone shape0 phase) {-# INLINE shapePhaseFreqModFromSampledTone #-} shapePhaseFreqModFromSampledTone :: (RealField.C a, SigG.Transform sig b) => Interpolation.T a b -> Interpolation.T a b -> a -> sig b -> a -> Phase.T a -> Sig.T a -> Sig.T a -> Sig.T a -> Sig.T b shapePhaseFreqModFromSampledTone ipLeap ipStep period sampledTone shape0 phase = Causal.apply3 (Osci.shapePhaseFreqModFromSampledTone ipLeap ipStep period sampledTone shape0 phase) {- * Oscillators with specific waveforms -} {-# INLINE staticSine #-} {- | sine oscillator with static frequency -} staticSine :: (Trans.C a, RealField.C a) => Phase.T a -> a -> Sig.T a staticSine = static Wave.sine {-# INLINE freqModSine #-} {- | sine oscillator with modulated frequency -} freqModSine :: (Trans.C a, RealField.C a) => Phase.T a -> Sig.T a -> Sig.T a freqModSine = freqMod Wave.sine {-# INLINE phaseModSine #-} {- | sine oscillator with modulated phase, useful for FM synthesis -} phaseModSine :: (Trans.C a, RealField.C a) => a -> Sig.T a -> Sig.T a phaseModSine = phaseMod Wave.sine {-# INLINE staticSaw #-} {- | saw tooth oscillator with modulated frequency -} staticSaw :: RealField.C a => Phase.T a -> a -> Sig.T a staticSaw = static Wave.saw {-# INLINE freqModSaw #-} {- | saw tooth oscillator with modulated frequency -} freqModSaw :: RealField.C a => Phase.T a -> Sig.T a -> Sig.T a freqModSaw = freqMod Wave.saw