Merge branch 'master' of https://github.com/calf-studio-gear/calf

[calf.git] / src / calf / modules_synths.h

/* Calf DSP Library
 * Audio modules - synthesizers
 *
 * Copyright (C) 2001-2007 Krzysztof Foltman
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2 of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General
 * Public License along with this program; if not, write to the
 * Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, 
 * Boston, MA 02111-1307, USA.
 */
#ifndef __CALF_MODULES_SYNTHS_H
#define __CALF_MODULES_SYNTHS_H

#include "biquad.h"
#include "onepole.h"
#include "audio_fx.h"
#include "inertia.h"
#include "osc.h"
#include "synth.h"
#include "envelope.h"
#include "modmatrix.h"
#include "metadata.h"
#include "giface.h"

namespace calf_plugins {

#define MONOSYNTH_WAVE_BITS 12
    
/// Monosynth-in-making. Parameters may change at any point, so don't make songs with it!
/// It lacks inertia for parameters, even for those that really need it.
class monosynth_audio_module: public audio_module<monosynth_metadata>, public line_graph_iface, public mod_matrix_impl
{
public:
    uint32_t srate, crate;
    static dsp::waveform_family<MONOSYNTH_WAVE_BITS> *waves;
    dsp::waveform_oscillator<MONOSYNTH_WAVE_BITS> osc1, osc2, detosc;
    dsp::triangle_lfo lfo1, lfo2;
    dsp::simple_oscillator unison_osc;
    dsp::biquad_d1_lerp filter, filter2;
    /// The step code is producing non-zero values
    bool running;
    /// This is the last non-zero buffer (set on calculate_step after fadeout is complete, the next calculate_step will zero running)
    bool stopping;
    /// A key is kept pressed
    bool gate;
    /// All notes off fadeout
    bool force_fadeout;
    /// Last triggered note
    int last_key;
    
    /// Output buffers, used to ensure updates are done every step_size regardless of process buffer size
    float buffer[step_size], buffer2[step_size];
    /// Read position within the buffers, on each '0' the buffers are being filled with new data by calculate_step
    uint32_t output_pos;
    /// Waveform number - OSC1
    int wave1;
    /// Waveform number - OSC2
    int wave2;
    /// Last used waveform number - OSC1
    int prev_wave1;
    /// Last used waveform number - OSC2
    int prev_wave2;
    /// Filter type
    int filter_type;
    /// Filter type on the last calculate_step
    int last_filter_type;
    float freq, start_freq, target_freq, cutoff, fgain, fgain_delta, separation;
    float detune, xpose1, xpose2, xfade, ampctl, fltctl;
    float odcr, porta_time, lfo_bend;
    /// Modulation wheel position (0.f-1.f)
    float modwheel_value;
    /// Delay counter for LFOs
    float lfo_clock;
    /// Last value of phase shift for pulse width emulation for OSC1
    int32_t last_pwshift1;
    /// Last value of phase shift for pulse width emulation for OSC2
    int32_t last_pwshift2;
    /// Last value of stretch for osc sync emulation for OSC1
    int32_t last_stretch1;
    /// Next note to play on the next calculate_step
    int queue_note_on;
    /// Whether the queued note has been already released
    bool queue_note_on_and_off;
    /// Velocity of the next note to play
    float queue_vel;
    /// Integer value for modwheel (0-16383, read from CC1 - MSBs and CC33 - LSBs)
    int modwheel_value_int;
    /// Legato mode (bitmask)
    int legato;
    /// Envelope Generators
    dsp::adsr envelope1, envelope2;
    dsp::keystack stack;
    /// Smoothing for master volume
    dsp::gain_smoothing master;
    /// Fadeout for buffer 1
    dsp::fadeout fadeout;
    /// Fadeout for buffer 2
    dsp::fadeout fadeout2;
    /// Smoothed cutoff value
    dsp::inertia<dsp::exponential_ramp> inertia_cutoff;
    /// Smoothed pitch bend value
    dsp::inertia<dsp::exponential_ramp> inertia_pitchbend;
    /// Smoothed channel pressure value
    dsp::inertia<dsp::linear_ramp> inertia_pressure;
    /// Rows of the modulation matrix
    dsp::modulation_entry mod_matrix_data[mod_matrix_slots];
    /// Currently used velocity
    float velocity;
    /// Last value of oscillator mix ratio
    float last_xfade;
    /// Last value of unison amount
    float last_unison;
    /// Current calculated mod matrix outputs
    float moddest[moddest_count];
     
    monosynth_audio_module();    
    void set_sample_rate(uint32_t sr);
    void delayed_note_on();
    /// Release a note (physically), called from note-off handler or when note-off has been scheduled after note-on (very short queued note)
    void end_note();
    /// Handle MIDI Note On message (does not immediately trigger a note, as it must start on
    /// boundary of step_size samples).
    void note_on(int channel, int note, int vel);
    /// Handle MIDI Note Off message
    void note_off(int channel, int note, int vel);
    /// Handle MIDI Channel Pressure
    void channel_pressure(int channel, int value);
    /// Handle pitch bend message.
    inline void pitch_bend(int /*channel*/, int value)
    {
        inertia_pitchbend.set_inertia(pow(2.0, (value * *params[par_pwhlrange]) / (1200.0 * 8192.0)));
    }
    /// Update oscillator frequency based on base frequency, detune amount, pitch bend scaling factor and sample rate.
    void set_frequency();
    /// Handle control change messages.
    void control_change(int channel, int controller, int value);
    /// Update variables from control ports.
    void params_changed();
    void activate();
    void deactivate();
    void post_instantiate(uint32_t)
    {
        precalculate_waves(progress_report);
    }
    /// Set waveform addresses for oscillators
    void lookup_waveforms();
    /// Run oscillators
    void calculate_buffer_oscs(float lfo);
    /// Run two filters in series to produce mono output samples.
    void calculate_buffer_ser();
    /// Run one filter to produce mono output samples.
    void calculate_buffer_single();
    /// Run two filters (one per channel) to produce stereo output samples.
    void calculate_buffer_stereo();
    /// Retrieve filter graph (which is 'live' so it cannot be generated by get_static_graph), or fall back to get_static_graph.
    bool get_graph(int index, int subindex, int phase, float *data, int points, cairo_iface *context, int *mode) const;
    bool get_layers(int index, int generation, unsigned int &layers) const { layers = LG_REALTIME_GRAPH; return true; }
    /// @retval true if the filter 1 is to be used for the left channel and filter 2 for the right channel
    /// No CV inputs for now
    bool is_cv(int param_no) const { return false; }
    /// Practically all the stuff here is noisy
    bool is_noisy(int param_no) const { return param_no != par_cutoff; }
    /// Main processing function
    uint32_t process(uint32_t offset, uint32_t nsamples, uint32_t inputs_mask, uint32_t outputs_mask);
    /// Send all configure variables set within a plugin to given destination (which may be limited to only those that plugin understands)
    virtual void send_configures(send_configure_iface *sci) { return mod_matrix_impl::send_configures(sci); }
    virtual char *configure(const char *key, const char *value) { return mod_matrix_impl::configure(key, value); }
private:
    void reset();
    float get_lfo(dsp::triangle_lfo &lfo, int param);
    /// Apply anti-click'n'pop fadeout (used at the end of the sound)
    void apply_fadeout();
    /// Calculate control signals and produce step_size samples of output.
    void calculate_step();
    /// @retval false if filters are to be connected in series and sent (mono) to both channels    
    inline bool is_stereo_filter() const
    {
        return filter_type == flt_2lp12 || filter_type == flt_2bp6;
    }
    static void precalculate_waves(progress_report_iface *reporter);
};

};

#if ENABLE_EXPERIMENTAL
    
#include "wavetable.h"

#endif

#endif