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lmms/plugins/monstro/Monstro.cpp
Levin Oehlmann f742710758 Macro cleanup (#6095) 
Summary:

* `NULL` -> `nullptr`
* `gui` -> Function `getGUI()`
* `pluginFactory` -> Function `getPluginFactory()`
* `assert` (redefinition) -> using `NDEBUG` instead, which standard `assert` respects.
* `powf` (C stdlib symbol clash) -> removed and all expansions replaced with calls to `std::pow`.
* `exp10` (nonstandard function symbol clash) -> removed and all expansions replaced with calls to `std::pow`.
* `PATH_DEV_DSP` -> File-scope QString of identical name and value.
* `VST_SNC_SHM_KEY_FILE` -> constexpr char* with identical name and value.
* `MM_ALLOC` and `MM_FREE` -> Functions with identical name and implementation.
* `INVAL`, `OUTVAL`, etc. for automation nodes -> Functions with identical names and implementations.
* BandLimitedWave.h: All integer constant macros replaced with constexpr ints of same name and value.
* `FAST_RAND_MAX` -> constexpr int of same name and value.
* `QSTR_TO_STDSTR` -> Function with identical name and equivalent implementation.
* `CCONST` -> constexpr function template with identical name and implementation.
* `F_OPEN_UTF8` -> Function with identical name and equivalent implementation.
* `LADSPA_PATH_SEPARATOR` -> constexpr char with identical name and value.
* `UI_CTRL_KEY` -> constexpr char* with identical name and value.
* `ALIGN_SIZE` -> Renamed to `LMMS_ALIGN_SIZE` and converted from a macro to a constexpr size_t.
* `JACK_MIDI_BUFFER_MAX` -> constexpr size_t with identical name and value.
* versioninfo.h: `PLATFORM`, `MACHINE` and `COMPILER_VERSION` -> prefixed with `LMMS_BUILDCONF_` and converted from macros to constexpr char* literals.
* Header guard _OSCILLOSCOPE -> renamed to OSCILLOSCOPE_H
* Header guard _TIME_DISPLAY_WIDGET -> renamed to TIME_DISPLAY_WIDGET_H
* C-style typecasts in DrumSynth.cpp have been replaced with `static_cast`.
* constexpr numerical constants are initialized with assignment notation instead of curly brace intializers.
* In portsmf, `Alg_seq::operator[]` will throw an exception instead of returning null if the operator index is out of range.

Additionally, in many places, global constants that were declared as `const T foo = bar;` were changed from const to constexpr, leaving them const and making them potentially evaluable at compile time.

Some macros that only appeared in single source files and were unused in those files have been removed entirely.
2021-09-30 18:01:27 +02:00

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/*
* Monstro.cpp - a monstrous semi-modular 3-osc synth with modulation matrix
*
* Copyright (c) 2014 Vesa Kivimäki <contact/dot/diizy/at/nbl/dot/fi>
*
* This file is part of LMMS - https://lmms.io
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU 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
* General Public License for more details.
*
* You should have received a copy of the GNU General Public
* License along with this program (see COPYING); if not, write to the
* Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
* Boston, MA 02110-1301 USA.
*
*/
#include <QDomElement>
#include "Monstro.h"
#include "Engine.h"
#include "InstrumentTrack.h"
#include "gui_templates.h"
#include "ToolTip.h"
#include "Song.h"
#include "lmms_math.h"
#include "interpolation.h"
#include "embed.h"
#include "plugin_export.h"
extern "C"
{
Plugin::Descriptor PLUGIN_EXPORT monstro_plugin_descriptor =
{
STRINGIFY( PLUGIN_NAME ),
"Monstro",
QT_TRANSLATE_NOOP( "PluginBrowser",
"Monstrous 3-oscillator synth with modulation matrix" ),
"Vesa Kivimäki <contact/dot/diizy/at/nbl/dot/fi>",
0x0100,
Plugin::Instrument,
new PluginPixmapLoader( "logo" ),
nullptr,
nullptr,
} ;
}
MonstroSynth::MonstroSynth( MonstroInstrument * _i, NotePlayHandle * _nph ) :
m_parent( _i ),
m_nph( _nph )
{
m_osc1l_phase = 0.0f;
m_osc1r_phase = 0.0f;
m_osc2l_phase = 0.0f;
m_osc2r_phase = 0.0f;
m_osc3l_phase = 0.0f;
m_osc3r_phase = 0.0f;
m_ph2l_last = 0.0f;
m_ph2r_last = 0.0f;
m_ph3l_last = 0.0f;
m_ph3r_last = 0.0f;
m_env_phase[0] = 0.0f;
m_env_phase[1] = 0.0f;
m_lfo_phase[0] = 0.0f;
m_lfo_phase[1] = 0.0f;
m_lfo_next[0] = Oscillator::noiseSample( 0.0f );
m_lfo_next[1] = Oscillator::noiseSample( 0.0f );
m_osc1l_last = 0.0f;
m_osc1r_last = 0.0f;
m_l_last = 0.0f;
m_r_last = 0.0f;
m_invert2l = false;
m_invert2r = false;
m_invert3l = false;
m_invert3r = false;
m_counter2l = 0;
m_counter2r = 0;
m_counter3l = 0;
m_counter3r = 0;
m_lfo[0].resize( m_parent->m_fpp );
m_lfo[1].resize( m_parent->m_fpp );
m_env[0].resize( m_parent->m_fpp );
m_env[1].resize( m_parent->m_fpp );
}
MonstroSynth::~MonstroSynth()
{
}
void MonstroSynth::renderOutput( fpp_t _frames, sampleFrame * _buf )
{
float modtmp; // temp variable for freq modulation
// macros for modulating with env/lfos
#define modulatefreq( car, mod ) \
modtmp = 0.0f; \
if( mod##_e1 != 0.0f ) modtmp += m_env[0][f] * mod##_e1; \
if( mod##_e2 != 0.0f ) modtmp += m_env[1][f] * mod##_e2; \
if( mod##_l1 != 0.0f ) modtmp += m_lfo[0][f] * mod##_l1; \
if( mod##_l2 != 0.0f ) modtmp += m_lfo[1][f] * mod##_l2; \
car = qBound( MIN_FREQ, car * powf( 2.0f, modtmp ), MAX_FREQ );
#define modulateabs( car, mod ) \
if( mod##_e1 != 0.0f ) car += m_env[0][f] * mod##_e1; \
if( mod##_e2 != 0.0f ) car += m_env[1][f] * mod##_e2; \
if( mod##_l1 != 0.0f ) car += m_lfo[0][f] * mod##_l1; \
if( mod##_l2 != 0.0f ) car += m_lfo[1][f] * mod##_l2;
#define modulatephs( car, mod ) \
if( mod##_e1 != 0.0f ) car += m_env[0][f] * mod##_e1; \
if( mod##_e2 != 0.0f ) car += m_env[1][f] * mod##_e2; \
if( mod##_l1 != 0.0f ) car += m_lfo[0][f] * mod##_l1; \
if( mod##_l2 != 0.0f ) car += m_lfo[1][f] * mod##_l2;
#define modulatevol( car, mod ) \
if( mod##_e1 > 0.0f ) car *= ( 1.0f - mod##_e1 + mod##_e1 * m_env[0][f] ); \
if( mod##_e1 < 0.0f ) car *= ( 1.0f + mod##_e1 * m_env[0][f] ); \
if( mod##_e2 > 0.0f ) car *= ( 1.0f - mod##_e2 + mod##_e2 * m_env[1][f] ); \
if( mod##_e2 < 0.0f ) car *= ( 1.0f + mod##_e2 * m_env[1][f] ); \
if( mod##_l1 != 0.0f ) car *= ( 1.0f + mod##_l1 * m_lfo[0][f] ); \
if( mod##_l2 != 0.0f ) car *= ( 1.0f + mod##_l2 * m_lfo[1][f] ); \
car = qBound( -MODCLIP, car, MODCLIP );
////////////////////
// //
// MODULATORS //
// //
////////////////////
// LFO phase offsets
const float lfo1_po = m_parent->m_lfo1Phs.value() / 360.0f;
const float lfo2_po = m_parent->m_lfo2Phs.value() / 360.0f;
// remove cruft from phase counters to prevent overflow, add phase offset
m_lfo_phase[0] = absFraction( m_lfo_phase[0] + lfo1_po );
m_lfo_phase[1] = absFraction( m_lfo_phase[1] + lfo2_po );
// LFO rates and increment
m_lfo_rate[0] = ( m_parent->m_lfo1Rate.value() * 0.001f * m_parent->m_samplerate );
m_lfo_rate[1] = ( m_parent->m_lfo2Rate.value() * 0.001f * m_parent->m_samplerate );
m_lfo_inc[0] = 1.0f / m_lfo_rate[0];
m_lfo_inc[1] = 1.0f / m_lfo_rate[1];
m_env_sus[0] = m_parent-> m_env1Sus.value();
m_env_sus[1] = m_parent-> m_env2Sus.value();
m_lfovalue[0] = m_parent->m_lfo1Wave.value();
m_lfovalue[1] = m_parent->m_lfo2Wave.value();
m_lfoatt[0] = m_parent->m_lfo1_att;
m_lfoatt[1] = m_parent->m_lfo2_att;
m_env_pre[0] = m_parent->m_env1_pre;
m_env_att[0] = m_parent->m_env1_att;
m_env_hold[0] = m_parent->m_env1_hold;
m_env_dec[0] = m_parent->m_env1_dec;
m_env_rel[0] = m_parent->m_env1_rel;
m_env_pre[1] = m_parent->m_env2_pre;
m_env_att[1] = m_parent->m_env2_att;
m_env_hold[1] = m_parent->m_env2_hold;
m_env_dec[1] = m_parent->m_env2_dec;
m_env_rel[1] = m_parent->m_env2_rel;
// get updated osc1 values
// get pulse width
const float pw = ( m_parent->m_osc1Pw.value() * 0.01f );
const float o1pw_e1 = ( m_parent->m_pw1env1.value() );
const float o1pw_e2 = ( m_parent->m_pw1env2.value() );
const float o1pw_l1 = ( m_parent->m_pw1lfo1.value() * 0.5f );
const float o1pw_l2 = ( m_parent->m_pw1lfo2.value() * 0.5f );
const bool o1pw_mod = o1pw_e1 != 0.0f || o1pw_e2 != 0.0f || o1pw_l1 != 0.0f || o1pw_l2 != 0.0f;
// get phases
const float o1lpo = m_parent->m_osc1l_po;
const float o1rpo = m_parent->m_osc1r_po;
const float o1p_e1 = ( m_parent->m_phs1env1.value() );
const float o1p_e2 = ( m_parent->m_phs1env2.value() );
const float o1p_l1 = ( m_parent->m_phs1lfo1.value() * 0.5f );
const float o1p_l2 = ( m_parent->m_phs1lfo2.value() * 0.5f );
const bool o1p_mod = o1p_e1 != 0.0f || o1p_e2 != 0.0f || o1p_l1 != 0.0f || o1p_l2 != 0.0f;
// get pitch
const float o1lfb = ( m_parent->m_osc1l_freq * m_nph->frequency() );
const float o1rfb = ( m_parent->m_osc1r_freq * m_nph->frequency() );
const float o1f_e1 = ( m_parent->m_pit1env1.value() * 2.0f );
const float o1f_e2 = ( m_parent->m_pit1env2.value() * 2.0f );
const float o1f_l1 = ( m_parent->m_pit1lfo1.value() );
const float o1f_l2 = ( m_parent->m_pit1lfo2.value() );
const bool o1f_mod = o1f_e1 != 0.0f || o1f_e2 != 0.0f || o1f_l1 != 0.0f || o1f_l2 != 0.0f;
// get volumes
const float o1lv = m_parent->m_osc1l_vol;
const float o1rv = m_parent->m_osc1r_vol;
const float o1v_e1 = ( m_parent->m_vol1env1.value() );
const float o1v_e2 = ( m_parent->m_vol1env2.value() );
const float o1v_l1 = ( m_parent->m_vol1lfo1.value() );
const float o1v_l2 = ( m_parent->m_vol1lfo2.value() );
const bool o1v_mod = o1v_e1 != 0.0f || o1v_e2 != 0.0f || o1v_l1 != 0.0f || o1v_l2 != 0.0f;
// update osc2
// get waveform
const int o2w = m_parent->m_osc2Wave.value();
// get phases
const float o2lpo = m_parent->m_osc2l_po;
const float o2rpo = m_parent->m_osc2r_po;
const float o2p_e1 = ( m_parent->m_phs2env1.value() );
const float o2p_e2 = ( m_parent->m_phs2env2.value() );
const float o2p_l1 = ( m_parent->m_phs2lfo1.value() * 0.5f );
const float o2p_l2 = ( m_parent->m_phs2lfo2.value() * 0.5f );
const bool o2p_mod = o2p_e1 != 0.0f || o2p_e2 != 0.0f || o2p_l1 != 0.0f || o2p_l2 != 0.0f;
// get pitch
const float o2lfb = ( m_parent->m_osc2l_freq * m_nph->frequency() );
const float o2rfb = ( m_parent->m_osc2r_freq * m_nph->frequency() );
const float o2f_e1 = ( m_parent->m_pit2env1.value() * 2.0f );
const float o2f_e2 = ( m_parent->m_pit2env2.value() * 2.0f );
const float o2f_l1 = ( m_parent->m_pit2lfo1.value() );
const float o2f_l2 = ( m_parent->m_pit2lfo2.value() );
const bool o2f_mod = o2f_e1 != 0.0f || o2f_e2 != 0.0f || o2f_l1 != 0.0f || o2f_l2 != 0.0f;
// get volumes
const float o2lv = m_parent->m_osc2l_vol;
const float o2rv = m_parent->m_osc2r_vol;
const float o2v_e1 = ( m_parent->m_vol2env1.value() );
const float o2v_e2 = ( m_parent->m_vol2env2.value() );
const float o2v_l1 = ( m_parent->m_vol2lfo1.value() );
const float o2v_l2 = ( m_parent->m_vol2lfo2.value() );
const bool o2v_mod = o2v_e1 != 0.0f || o2v_e2 != 0.0f || o2v_l1 != 0.0f || o2v_l2 != 0.0f;
// update osc3
// get waveforms
const int o3w1 = m_parent->m_osc3Wave1.value();
const int o3w2 = m_parent->m_osc3Wave2.value();
// get phases
const float o3lpo = m_parent->m_osc3l_po;
const float o3rpo = m_parent->m_osc3r_po;
const float o3p_e1 = ( m_parent->m_phs3env1.value() );
const float o3p_e2 = ( m_parent->m_phs3env2.value() );
const float o3p_l1 = ( m_parent->m_phs3lfo1.value() * 0.5f );
const float o3p_l2 = ( m_parent->m_phs3lfo2.value() * 0.5f );
const bool o3p_mod = o3p_e1 != 0.0f || o3p_e2 != 0.0f || o3p_l1 != 0.0f || o3p_l2 != 0.0f;
// get pitch modulators
const float o3fb = ( m_parent->m_osc3_freq * m_nph->frequency() );
const float o3f_e1 = ( m_parent->m_pit3env1.value() * 2.0f );
const float o3f_e2 = ( m_parent->m_pit3env2.value() * 2.0f );
const float o3f_l1 = ( m_parent->m_pit3lfo1.value() );
const float o3f_l2 = ( m_parent->m_pit3lfo2.value() );
const bool o3f_mod = o3f_e1 != 0.0f || o3f_e2 != 0.0f || o3f_l1 != 0.0f || o3f_l2 != 0.0f;
// get volumes
const float o3lv = m_parent->m_osc3l_vol;
const float o3rv = m_parent->m_osc3r_vol;
const float o3v_e1 = ( m_parent->m_vol3env1.value() );
const float o3v_e2 = ( m_parent->m_vol3env2.value() );
const float o3v_l1 = ( m_parent->m_vol3lfo1.value() );
const float o3v_l2 = ( m_parent->m_vol3lfo2.value() );
const bool o3v_mod = o3v_e1 != 0.0f || o3v_e2 != 0.0f || o3v_l1 != 0.0f || o3v_l2 != 0.0f;
// get sub
const float o3sub = ( m_parent->m_osc3Sub.value() + 100.0f ) / 200.0f;
const float o3s_e1 = ( m_parent->m_sub3env1.value() );
const float o3s_e2 = ( m_parent->m_sub3env2.value() );
const float o3s_l1 = ( m_parent->m_sub3lfo1.value() * 0.5f );
const float o3s_l2 = ( m_parent->m_sub3lfo2.value() * 0.5f );
const bool o3s_mod = o3s_e1 != 0.0f || o3s_e2 != 0.0f || o3s_l1 != 0.0f || o3s_l2 != 0.0f;
//o2-o3 modulation
const int omod = m_parent->m_o23Mod.value();
// sync information
const bool o1ssr = m_parent->m_osc1SSR.value();
const bool o1ssf = m_parent->m_osc1SSF.value();
const bool o2sync = m_parent->m_osc2SyncH.value();
const bool o3sync = m_parent->m_osc3SyncH.value();
const bool o2syncr = m_parent->m_osc2SyncR.value();
const bool o3syncr = m_parent->m_osc3SyncR.value();
///////////////////////////
// //
// start buffer loop //
// //
///////////////////////////
// declare working variables for for loop
// phase manipulation vars - these can be reused by all oscs
float leftph;
float rightph;
float pd_l;
float pd_r;
float len_l;
float len_r;
// osc1 vars
float o1l_f;
float o1r_f;
float o1l_p = m_osc1l_phase + o1lpo; // we add phase offset here so we don't have to do it every frame
float o1r_p = m_osc1r_phase + o1rpo; // then subtract it again after loop...
float o1_pw;
// osc2 vars
float o2l_f;
float o2r_f;
float o2l_p = m_osc2l_phase + o2lpo;
float o2r_p = m_osc2r_phase + o2rpo;
// osc3 vars
float o3l_f;
float o3r_f;
float o3l_p = m_osc3l_phase + o3lpo;
float o3r_p = m_osc3r_phase + o3rpo;
float sub;
// render modulators: envelopes, lfos
updateModulators( m_env[0].data(), m_env[1].data(), m_lfo[0].data(), m_lfo[1].data(), _frames );
// begin for loop
for( f_cnt_t f = 0; f < _frames; ++f )
{
/* // debug code
if( f % 10 == 0 ) {
qDebug( "env1 %f -- env1 phase %f", m_env1_buf[f], m_env1_phase );
qDebug( "env1 pre %f att %f dec %f rel %f ", m_parent->m_env1_pre, m_parent->m_env1_att,
m_parent->m_env1_dec, m_parent->m_env1_rel );
}*/
/////////////////////////////
// //
// OSC 1 //
// //
/////////////////////////////
// calc and mod frequencies
o1l_f = o1lfb;
o1r_f = o1rfb;
if( o1f_mod )
{
modulatefreq( o1l_f, o1f )
modulatefreq( o1r_f, o1f )
}
// calc and modulate pulse
o1_pw = pw;
if( o1pw_mod )
{
modulateabs( o1_pw, o1pw )
o1_pw = qBound( PW_MIN, o1_pw, PW_MAX );
}
// calc and modulate phase
leftph = o1l_p;
rightph = o1r_p;
if( o1p_mod )
{
modulatephs( leftph, o1p )
modulatephs( rightph, o1p )
}
// pulse wave osc
sample_t O1L = ( absFraction( leftph ) < o1_pw ) ? 1.0f : -1.0f;
sample_t O1R = ( absFraction( rightph ) < o1_pw ) ? 1.0f : -1.0f;
// check for rise/fall, and sync if appropriate
// sync on rise
if( o1ssr )
{
// hard sync
if( o2sync )
{
if( O1L > m_osc1l_last ) { o2l_p = o2lpo; m_counter2l = m_parent->m_counterMax; }
if( O1R > m_osc1r_last ) { o2r_p = o2rpo; m_counter2r = m_parent->m_counterMax; }
}
if( o3sync )
{
if( O1L > m_osc1l_last ) { o3l_p = o3lpo; m_counter3l = m_parent->m_counterMax; }
if( O1R > m_osc1r_last ) { o3r_p = o3rpo; m_counter3r = m_parent->m_counterMax; }
}
// reverse sync
if( o2syncr )
{
if( O1L > m_osc1l_last ) { m_invert2l = !m_invert2l; m_counter2l = m_parent->m_counterMax; }
if( O1R > m_osc1r_last ) { m_invert2r = !m_invert2r; m_counter2r = m_parent->m_counterMax; }
}
if( o3syncr )
{
if( O1L > m_osc1l_last ) { m_invert3l = !m_invert3l; m_counter3l = m_parent->m_counterMax; }
if( O1R > m_osc1r_last ) { m_invert3r = !m_invert3r; m_counter3r = m_parent->m_counterMax; }
}
}
// sync on fall
if( o1ssf )
{
// hard sync
if( o2sync )
{
if( O1L < m_osc1l_last ) { o2l_p = o2lpo; m_counter2l = m_parent->m_counterMax; }
if( O1R < m_osc1r_last ) { o2r_p = o2rpo; m_counter2r = m_parent->m_counterMax; }
}
if( o3sync )
{
if( O1L < m_osc1l_last ) { o3l_p = o3lpo; m_counter3l = m_parent->m_counterMax; }
if( O1R < m_osc1r_last ) { o3r_p = o3rpo; m_counter3r = m_parent->m_counterMax; }
}
// reverse sync
if( o2syncr )
{
if( O1L < m_osc1l_last ) { m_invert2l = !m_invert2l; m_counter2l = m_parent->m_counterMax; }
if( O1R < m_osc1r_last ) { m_invert2r = !m_invert2r; m_counter2r = m_parent->m_counterMax; }
}
if( o3syncr )
{
if( O1L < m_osc1l_last ) { m_invert3l = !m_invert3l; m_counter3l = m_parent->m_counterMax; }
if( O1R < m_osc1r_last ) { m_invert3r = !m_invert3r; m_counter3r = m_parent->m_counterMax; }
}
}
// update last before signal is touched
// also do a very simple amp delta cap
const sample_t tmpl = m_osc1l_last;
const sample_t tmpr = m_osc1r_last;
m_osc1l_last = O1L;
m_osc1r_last = O1R;
if( tmpl != O1L ) O1L = 0.0f;
if( tmpr != O1R ) O1R = 0.0f;
// modulate volume
O1L *= o1lv;
O1R *= o1rv;
if( o1v_mod )
{
modulatevol( O1L, o1v )
modulatevol( O1R, o1v )
}
// update osc1 phase working variable
o1l_p += 1.0f / ( static_cast<float>( m_parent->m_samplerate ) / o1l_f );
o1r_p += 1.0f / ( static_cast<float>( m_parent->m_samplerate ) / o1r_f );
/////////////////////////////
// //
// OSC 2 //
// //
/////////////////////////////
// calc and mod frequencies
o2l_f = o2lfb;
o2r_f = o2rfb;
if( o2f_mod )
{
modulatefreq( o2l_f, o2f )
modulatefreq( o2r_f, o2f )
}
// calc and modulate phase
leftph = o2l_p;
rightph = o2r_p;
if( o2p_mod )
{
modulatephs( leftph, o2p )
modulatephs( rightph, o2p )
}
leftph = absFraction( leftph );
rightph = absFraction( rightph );
// phase delta
pd_l = qAbs( leftph - m_ph2l_last );
if( pd_l > 0.5 ) pd_l = 1.0 - pd_l;
pd_r = qAbs( rightph - m_ph2r_last );
if( pd_r > 0.5 ) pd_r = 1.0 - pd_r;
// multi-wave DC Oscillator
len_l = BandLimitedWave::pdToLen( pd_l );
len_r = BandLimitedWave::pdToLen( pd_r );
if( m_counter2l > 0 ) { len_l /= m_counter2l; m_counter2l--; }
if( m_counter2r > 0 ) { len_r /= m_counter2r; m_counter2r--; }
sample_t O2L = oscillate( o2w, leftph, len_l );
sample_t O2R = oscillate( o2w, rightph, len_r );
// modulate volume
O2L *= o2lv;
O2R *= o2rv;
if( o2v_mod )
{
modulatevol( O2L, o2v )
modulatevol( O2R, o2v )
}
// reverse sync - invert waveforms when needed
if( m_invert2l ) O2L *= -1.0;
if( m_invert2r ) O2R *= -1.0;
// update osc2 phases
m_ph2l_last = leftph;
m_ph2r_last = rightph;
o2l_p += 1.0f / ( static_cast<float>( m_parent->m_samplerate ) / o2l_f );
o2r_p += 1.0f / ( static_cast<float>( m_parent->m_samplerate ) / o2r_f );
/////////////////////////////
// //
// OSC 3 //
// //
/////////////////////////////
// calc and mod frequencies
o3l_f = o3fb;
o3r_f = o3fb;
if( o3f_mod )
{
modulatefreq( o3l_f, o3f )
modulatefreq( o3r_f, o3f )
}
// calc and modulate phase
leftph = o3l_p;
rightph = o3r_p;
if( o3p_mod )
{
modulatephs( leftph, o3p )
modulatephs( rightph, o3p )
}
// o2 modulation?
if( omod == MOD_PM )
{
leftph += O2L * 0.5f;
rightph += O2R * 0.5f;
}
leftph = absFraction( leftph );
rightph = absFraction( rightph );
// phase delta
pd_l = qAbs( leftph - m_ph3l_last );
if( pd_l > 0.5 ) pd_l = 1.0 - pd_l;
pd_r = qAbs( rightph - m_ph3r_last );
if( pd_r > 0.5 ) pd_r = 1.0 - pd_r;
// multi-wave DC Oscillator
len_l = BandLimitedWave::pdToLen( pd_l );
len_r = BandLimitedWave::pdToLen( pd_r );
if( m_counter3l > 0 ) { len_l /= m_counter3l; m_counter3l--; }
if( m_counter3r > 0 ) { len_r /= m_counter3r; m_counter3r--; }
// sub-osc 1
sample_t O3AL = oscillate( o3w1, leftph, len_l );
sample_t O3AR = oscillate( o3w1, rightph, len_r );
// multi-wave DC Oscillator, sub-osc 2
sample_t O3BL = oscillate( o3w2, leftph, len_l );
sample_t O3BR = oscillate( o3w2, rightph, len_r );
// calc and modulate sub
sub = o3sub;
if( o3s_mod )
{
modulateabs( sub, o3s )
sub = qBound( 0.0f, sub, 1.0f );
}
sample_t O3L = linearInterpolate( O3AL, O3BL, sub );
sample_t O3R = linearInterpolate( O3AR, O3BR, sub );
// modulate volume
O3L *= o3lv;
O3R *= o3rv;
if( o3v_mod )
{
modulatevol( O3L, o3v )
modulatevol( O3R, o3v )
}
// o2 modulation?
if( omod == MOD_AM )
{
O3L = qBound( -MODCLIP, O3L * qMax( 0.0f, 1.0f + O2L ), MODCLIP );
O3R = qBound( -MODCLIP, O3R * qMax( 0.0f, 1.0f + O2R ), MODCLIP );
}
// reverse sync - invert waveforms when needed
if( m_invert3l ) O3L *= -1.0;
if( m_invert3r ) O3R *= -1.0;
// update osc3 phases
m_ph3l_last = leftph;
m_ph3r_last = rightph;
len_l = 1.0f / ( static_cast<float>( m_parent->m_samplerate ) / o3l_f );
len_r = 1.0f / ( static_cast<float>( m_parent->m_samplerate ) / o3r_f );
// handle FM as PM
if( omod == MOD_FM )
{
len_l += O2L * m_parent->m_fmCorrection;
len_r += O2R * m_parent->m_fmCorrection;
}
o3l_p += len_l;
o3r_p += len_r;
// integrator - very simple filter
sample_t L = O1L + O3L + ( omod == MOD_MIX ? O2L : 0.0f );
sample_t R = O1R + O3R + ( omod == MOD_MIX ? O2R : 0.0f );
_buf[f][0] = linearInterpolate( L, m_l_last, m_parent->m_integrator );
_buf[f][1] = linearInterpolate( R, m_r_last, m_parent->m_integrator );
m_l_last = L;
m_r_last = R;
}
// update phases
m_osc1l_phase = absFraction( o1l_p - o1lpo );
m_osc1r_phase = absFraction( o1r_p - o1rpo );
m_osc2l_phase = absFraction( o2l_p - o2lpo );
m_osc2r_phase = absFraction( o2r_p - o2rpo );
m_osc3l_phase = absFraction( o3l_p - o3lpo );
m_osc3r_phase = absFraction( o3r_p - o3rpo );
m_lfo_phase[0] = absFraction( m_lfo_phase[0] - lfo1_po );
m_lfo_phase[1] = absFraction( m_lfo_phase[1] - lfo2_po );
}
inline void MonstroSynth::updateModulators( float * env1, float * env2, float * lfo1, float * lfo2, int frames )
{
// frames played before
const f_cnt_t tfp = m_nph->totalFramesPlayed();
float * lfo [2];
float * env [2];
lfo[0] = lfo1;
lfo[1] = lfo2;
env[0] = env1;
env[1] = env2;
for( int i = 0; i < 2; ++i )
{
switch( m_lfovalue[i] )
{
case WAVE_SINE:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = Oscillator::sinSample( m_lfo_phase[i] );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_TRI:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = Oscillator::triangleSample( m_lfo_phase[i] );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_SAW:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = Oscillator::sawSample( m_lfo_phase[i] );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_RAMP:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = Oscillator::sawSample( m_lfo_phase[i] ) * -1.0f;
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_SQR:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = Oscillator::squareSample( m_lfo_phase[i] );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_SQRSOFT:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = oscillate( WAVE_SQRSOFT, m_lfo_phase[i], 0 );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_MOOG:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = Oscillator::moogSawSample( m_lfo_phase[i] );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_SINABS:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = oscillate( WAVE_SINABS, m_lfo_phase[i], 0 );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_EXP:
for( f_cnt_t f = 0; f < frames; ++f )
{
lfo[i][f] = Oscillator::expSample( m_lfo_phase[i] );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_RANDOM:
for( f_cnt_t f = 0; f < frames; ++f )
{
if( ( tfp + f ) % static_cast<int>( m_lfo_rate[i] ) == 0 ) m_lfo_last[i] = Oscillator::noiseSample( 0.0f );
lfo[i][f] = m_lfo_last[i];
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
case WAVE_RANDOM_SMOOTH:
for( f_cnt_t f = 0; f < frames; ++f )
{
const f_cnt_t tm = ( tfp + f ) % static_cast<int>( m_lfo_rate[i] );
if( tm == 0 )
{
m_lfo_last[i] = m_lfo_next[i];
m_lfo_next[i] = Oscillator::noiseSample( 0.0f );
}
lfo[i][f] = cosinusInterpolate( m_lfo_last[i], m_lfo_next[i], static_cast<float>( tm ) / m_lfo_rate[i] );
m_lfo_phase[i] += m_lfo_inc[i];
}
break;
}
// attack
for( f_cnt_t f = 0; f < frames; ++f )
{
if( tfp + f < m_lfoatt[i] ) lfo[i][f] *= ( static_cast<sample_t>( tfp ) / m_lfoatt[i] );
}
/////////////////////////////////////////////
// //
// //
// envelopes //
// //
// //
/////////////////////////////////////////////
for( f_cnt_t f = 0; f < frames; ++f )
{
if( m_env_phase[i] < 4.0f && m_nph->isReleased() && f >= m_nph->framesBeforeRelease() )
{
if( m_env_phase[i] < 1.0f ) m_env_phase[i] = 5.0f;
else if( m_env_phase[i] < 2.0f ) m_env_phase[i] = 5.0f - fraction( m_env_phase[i] );
else if( m_env_phase[i] < 3.0f ) m_env_phase[i] = 4.0f;
else m_env_phase[i] = 4.0f + fraction( m_env_phase[i] );
}
// process envelope
if( m_env_phase[i] < 1.0f ) // pre-delay phase
{
env[i][f] = 0.0f;
m_env_phase[i] = qMin( 1.0f, m_env_phase[i] + m_env_pre[i] );
}
else if( m_env_phase[i] < 2.0f ) // attack phase
{
env[i][f] = calcSlope( i, fraction( m_env_phase[i] ) );
m_env_phase[i] = qMin( 2.0f, m_env_phase[i] + m_env_att[i] );
}
else if( m_env_phase[i] < 3.0f ) // hold phase
{
env[i][f] = 1.0f;
m_env_phase[i] = qMin( 3.0f, m_env_phase[i] + m_env_hold[i] );
}
else if( m_env_phase[i] < 4.0f ) // decay phase
{
const sample_t s = calcSlope( i, 1.0f - fraction( m_env_phase[i] ) );
if( s <= m_env_sus[i] )
{
env[i][f] = m_env_sus[i];
}
else
{
env[i][f] = s;
m_env_phase[i] = qMin( 4.0f - m_env_sus[i], m_env_phase[i] + m_env_dec[i] );
if( m_env_phase[i] == 4.0f ) m_env_phase[i] = 5.0f; // jump over release if sustain is zero - fix for clicking
}
}
else if( m_env_phase[i] < 5.0f ) // release phase
{
env[i][f] = calcSlope( i, 1.0f - fraction( m_env_phase[i] ) );
m_env_phase[i] += m_env_rel[i];
}
else env[i][f] = 0.0f;
}
}
}
inline sample_t MonstroSynth::calcSlope( int slope, sample_t s )
{
if( m_parent->m_slope[slope] == 1.0f ) return s;
if( s == 0.0f ) return s;
return fastPow( s, m_parent->m_slope[slope] );
}
MonstroInstrument::MonstroInstrument( InstrumentTrack * _instrument_track ) :
Instrument( _instrument_track, &monstro_plugin_descriptor ),
m_osc1Vol( 33.0, 0.0, 200.0, 0.1, this, tr( "Osc 1 volume" ) ),
m_osc1Pan( 0.0, -100.0, 100.0, 0.1, this, tr( "Osc 1 panning" ) ),
m_osc1Crs( 0.0, -24.0, 24.0, 1.0, this, tr( "Osc 1 coarse detune" ) ),
m_osc1Ftl( 0.0, -100.0, 100.0, 1.0, this, tr( "Osc 1 fine detune left" ) ),
m_osc1Ftr( 0.0, -100.0, 100.0, 1.0, this, tr( "Osc 1 fine detune right" ) ),
m_osc1Spo( 0.0, -180.0, 180.0, 0.1, this, tr( "Osc 1 stereo phase offset" ) ),
m_osc1Pw( 50.0, PW_MIN, PW_MAX, 0.01, this, tr( "Osc 1 pulse width" ) ),
m_osc1SSR( false, this, tr( "Osc 1 sync send on rise" ) ),
m_osc1SSF( false, this, tr( "Osc 1 sync send on fall" ) ),
m_osc2Vol( 33.0, 0.0, 200.0, 0.1, this, tr( "Osc 2 volume" ) ),
m_osc2Pan( 0.0, -100.0, 100.0, 0.1, this, tr( "Osc 2 panning" ) ),
m_osc2Crs( 0.0, -24.0, 24.0, 1.0, this, tr( "Osc 2 coarse detune" ) ),
m_osc2Ftl( 0.0, -100.0, 100.0, 1.0, this, tr( "Osc 2 fine detune left" ) ),
m_osc2Ftr( 0.0, -100.0, 100.0, 1.0, this, tr( "Osc 2 fine detune right" ) ),
m_osc2Spo( 0.0, -180.0, 180.0, 0.1, this, tr( "Osc 2 stereo phase offset" ) ),
m_osc2Wave( this, tr( "Osc 2 waveform" ) ),
m_osc2SyncH( false, this, tr( "Osc 2 sync hard" ) ),
m_osc2SyncR( false, this, tr( "Osc 2 sync reverse" ) ),
m_osc3Vol( 33.0, 0.0, 200.0, 0.1, this, tr( "Osc 3 volume" ) ),
m_osc3Pan( 0.0, -100.0, 100.0, 0.1, this, tr( "Osc 3 panning" ) ),
m_osc3Crs( 0.0, -24.0, 24.0, 1.0, this, tr( "Osc 3 coarse detune" ) ),
m_osc3Spo( 0.0, -180.0, 180.0, 0.1, this, tr( "Osc 3 Stereo phase offset" ) ),
m_osc3Sub( 0.0, -100.0, 100.0, 0.1, this, tr( "Osc 3 sub-oscillator mix" ) ),
m_osc3Wave1( this, tr( "Osc 3 waveform 1" ) ),
m_osc3Wave2( this, tr( "Osc 3 waveform 2" ) ),
m_osc3SyncH( false, this, tr( "Osc 3 sync hard" ) ),
m_osc3SyncR( false, this, tr( "Osc 3 Sync reverse" ) ),
m_lfo1Wave( this, tr( "LFO 1 waveform" ) ),
m_lfo1Att( 0.0f, 0.0f, 2000.0f, 1.0f, 2000.0f, this, tr( "LFO 1 attack" ) ),
m_lfo1Rate( 1.0f, 0.1, 10000.0, 0.1, 10000.0f, this, tr( "LFO 1 rate" ) ),
m_lfo1Phs( 0.0, -180.0, 180.0, 0.1, this, tr( "LFO 1 phase" ) ),
m_lfo2Wave( this, tr( "LFO 2 waveform" ) ),
m_lfo2Att( 0.0f, 0.0f, 2000.0f, 1.0f, 2000.0f, this, tr( "LFO 2 attack" ) ),
m_lfo2Rate( 1.0f, 0.1, 10000.0, 0.1, 10000.0f, this, tr( "LFO 2 rate" ) ),
m_lfo2Phs( 0.0, -180.0, 180.0, 0.1, this, tr( "LFO 2 phase" ) ),
m_env1Pre( 0.0f, 0.0f, 2000.0f, 1.0f, 2000.0f, this, tr( "Env 1 pre-delay" ) ),
m_env1Att( 0.0f, 0.0f, 2000.0f, 1.0f, 2000.0f, this, tr( "Env 1 attack" ) ),
m_env1Hold( 0.0f, 0.0f, 4000.0f, 1.0f, 4000.0f, this, tr( "Env 1 hold" ) ),
m_env1Dec( 0.0f, 0.0f, 4000.0f, 1.0f, 4000.0f, this, tr( "Env 1 decay" ) ),
m_env1Sus( 1.0f, 0.0f, 1.0f, 0.001f, this, tr( "Env 1 sustain" ) ),
m_env1Rel( 0.0f, 0.0f, 4000.0f, 1.0f, 4000.0f, this, tr( "Env 1 release" ) ),
m_env1Slope( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Env 1 slope" ) ),
m_env2Pre( 0.0f, 0.0f, 2000.0f, 1.0f, 2000.0f, this, tr( "Env 2 pre-delay" ) ),
m_env2Att( 0.0f, 0.0f, 2000.0f, 1.0f, 2000.0f, this, tr( "Env 2 attack" ) ),
m_env2Hold( 0.0f, 0.0f, 4000.0f, 1.0f, 4000.0f, this, tr( "Env 2 hold" ) ),
m_env2Dec( 0.0f, 0.0f, 4000.0f, 1.0f, 4000.0f, this, tr( "Env 2 decay" ) ),
m_env2Sus( 1.0f, 0.0f, 1.0f, 0.001f, this, tr( "Env 2 sustain" ) ),
m_env2Rel( 0.0f, 0.0f, 4000.0f, 1.0f, 4000.0f, this, tr( "Env 2 release" ) ),
m_env2Slope( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Env 2 slope" ) ),
m_o23Mod( 0, 0, NUM_MODS - 1, this, tr( "Osc 2+3 modulation" ) ),
m_selectedView( 0, 0, 1, this, tr( "Selected view" ) ),
m_vol1env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Vol env 1" ) ),
m_vol1env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Vol env 2" ) ),
m_vol1lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Vol LFO 1" ) ),
m_vol1lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Vol LFO 2" ) ),
m_vol2env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Vol env 1" ) ),
m_vol2env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Vol env 2" ) ),
m_vol2lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Vol LFO 1" ) ),
m_vol2lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Vol LFO 2" ) ),
m_vol3env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Vol env 1" ) ),
m_vol3env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Vol env 2" ) ),
m_vol3lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Vol LFO 1" ) ),
m_vol3lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Vol LFO 2" ) ),
m_phs1env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Phs env 1" ) ),
m_phs1env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Phs env 2" ) ),
m_phs1lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Phs LFO 1" ) ),
m_phs1lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Phs LFO 2" ) ),
m_phs2env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Phs env 1" ) ),
m_phs2env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Phs env 2" ) ),
m_phs2lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Phs LFO 1" ) ),
m_phs2lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Phs LFO 2" ) ),
m_phs3env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Phs env 1" ) ),
m_phs3env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Phs env 2" ) ),
m_phs3lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Phs LFO 1" ) ),
m_phs3lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Phs LFO 2" ) ),
m_pit1env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Pit env 1" ) ),
m_pit1env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Pit env 2" ) ),
m_pit1lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Pit LFO 1" ) ),
m_pit1lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - Pit LFO 2" ) ),
m_pit2env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Pit env 1" ) ),
m_pit2env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Pit env 2" ) ),
m_pit2lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Pit LFO 1" ) ),
m_pit2lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 2 - Pit LFO 2" ) ),
m_pit3env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Pit env 1" ) ),
m_pit3env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Pit env 2" ) ),
m_pit3lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Pit LFO 1" ) ),
m_pit3lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Pit LFO 2" ) ),
m_pw1env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - PW env 1" ) ),
m_pw1env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - PW env 2" ) ),
m_pw1lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - PW LFO 1" ) ),
m_pw1lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 1 - PW LFO 2" ) ),
m_sub3env1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Sub env 1" ) ),
m_sub3env2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Sub env 2" ) ),
m_sub3lfo1( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Sub LFO 1" ) ),
m_sub3lfo2( 0.0f, -1.0f, 1.0f, 0.001f, this, tr( "Osc 3 - Sub LFO 2" ) )
{
// setup waveboxes
setwavemodel( m_osc2Wave )
setwavemodel( m_osc3Wave1 )
setwavemodel( m_osc3Wave2 )
setlfowavemodel( m_lfo1Wave )
setlfowavemodel( m_lfo2Wave )
// make connections:
// updateVolumes
connect( &m_osc1Vol, SIGNAL( dataChanged() ), this, SLOT( updateVolume1() ), Qt::DirectConnection );
connect( &m_osc1Pan, SIGNAL( dataChanged() ), this, SLOT( updateVolume1() ), Qt::DirectConnection );
connect( &m_osc2Vol, SIGNAL( dataChanged() ), this, SLOT( updateVolume2() ), Qt::DirectConnection );
connect( &m_osc2Pan, SIGNAL( dataChanged() ), this, SLOT( updateVolume2() ), Qt::DirectConnection );
connect( &m_osc3Vol, SIGNAL( dataChanged() ), this, SLOT( updateVolume3() ), Qt::DirectConnection );
connect( &m_osc3Pan, SIGNAL( dataChanged() ), this, SLOT( updateVolume3() ), Qt::DirectConnection );
// updateFreq
connect( &m_osc1Crs, SIGNAL( dataChanged() ), this, SLOT( updateFreq1() ), Qt::DirectConnection );
connect( &m_osc2Crs, SIGNAL( dataChanged() ), this, SLOT( updateFreq2() ), Qt::DirectConnection );
connect( &m_osc3Crs, SIGNAL( dataChanged() ), this, SLOT( updateFreq3() ), Qt::DirectConnection );
connect( &m_osc1Ftl, SIGNAL( dataChanged() ), this, SLOT( updateFreq1() ), Qt::DirectConnection );
connect( &m_osc2Ftl, SIGNAL( dataChanged() ), this, SLOT( updateFreq2() ), Qt::DirectConnection );
connect( &m_osc1Ftr, SIGNAL( dataChanged() ), this, SLOT( updateFreq1() ), Qt::DirectConnection );
connect( &m_osc2Ftr, SIGNAL( dataChanged() ), this, SLOT( updateFreq2() ), Qt::DirectConnection );
// updatePO
connect( &m_osc1Spo, SIGNAL( dataChanged() ), this, SLOT( updatePO1() ), Qt::DirectConnection );
connect( &m_osc2Spo, SIGNAL( dataChanged() ), this, SLOT( updatePO2() ), Qt::DirectConnection );
connect( &m_osc3Spo, SIGNAL( dataChanged() ), this, SLOT( updatePO3() ), Qt::DirectConnection );
// updateEnvelope1
connect( &m_env1Pre, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope1() ), Qt::DirectConnection );
connect( &m_env1Att, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope1() ), Qt::DirectConnection );
connect( &m_env1Hold, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope1() ), Qt::DirectConnection );
connect( &m_env1Dec, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope1() ), Qt::DirectConnection );
connect( &m_env1Rel, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope1() ), Qt::DirectConnection );
connect( &m_env1Slope, SIGNAL( dataChanged() ), this, SLOT( updateSlope1() ), Qt::DirectConnection );
// updateEnvelope2
connect( &m_env2Pre, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope2() ), Qt::DirectConnection );
connect( &m_env2Att, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope2() ), Qt::DirectConnection );
connect( &m_env2Hold, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope2() ), Qt::DirectConnection );
connect( &m_env2Dec, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope2() ), Qt::DirectConnection );
connect( &m_env2Rel, SIGNAL( dataChanged() ), this, SLOT( updateEnvelope2() ), Qt::DirectConnection );
connect( &m_env2Slope, SIGNAL( dataChanged() ), this, SLOT( updateSlope2() ), Qt::DirectConnection );
// updateLFOAtts
connect( &m_lfo1Att, SIGNAL( dataChanged() ), this, SLOT( updateLFOAtts() ), Qt::DirectConnection );
connect( &m_lfo2Att, SIGNAL( dataChanged() ), this, SLOT( updateLFOAtts() ), Qt::DirectConnection );
// updateSampleRate
connect( Engine::audioEngine(), SIGNAL( sampleRateChanged() ), this, SLOT( updateSamplerate() ) );
m_fpp = Engine::audioEngine()->framesPerPeriod();
updateSamplerate();
updateVolume1();
updateVolume2();
updateVolume3();
updateFreq1();
updateFreq2();
updateFreq3();
updatePO1();
updatePO2();
updatePO3();
updateSlope1();
updateSlope2();
}
MonstroInstrument::~MonstroInstrument()
{
}
void MonstroInstrument::playNote( NotePlayHandle * _n,
sampleFrame * _working_buffer )
{
const fpp_t frames = _n->framesLeftForCurrentPeriod();
const f_cnt_t offset = _n->noteOffset();
if ( _n->totalFramesPlayed() == 0 || _n->m_pluginData == nullptr )
{
_n->m_pluginData = new MonstroSynth( this, _n );
}
MonstroSynth * ms = static_cast<MonstroSynth *>( _n->m_pluginData );
ms->renderOutput( frames, _working_buffer + offset );
//applyRelease( _working_buffer, _n ); // we have our own release
instrumentTrack()->processAudioBuffer( _working_buffer, frames + offset, _n );
}
void MonstroInstrument::deleteNotePluginData( NotePlayHandle * _n )
{
delete static_cast<MonstroSynth *>( _n->m_pluginData );
}
void MonstroInstrument::saveSettings( QDomDocument & _doc,
QDomElement & _this )
{
m_osc1Vol.saveSettings( _doc, _this, "o1vol" );
m_osc1Pan.saveSettings( _doc, _this, "o1pan" );
m_osc1Crs.saveSettings( _doc, _this, "o1crs" );
m_osc1Ftl.saveSettings( _doc, _this, "o1ftl" );
m_osc1Ftr.saveSettings( _doc, _this, "o1ftr" );
m_osc1Spo.saveSettings( _doc, _this, "o1spo" );
m_osc1Pw.saveSettings( _doc, _this, "o1pw" );
m_osc1SSR.saveSettings( _doc, _this, "o1ssr" );
m_osc1SSF.saveSettings( _doc, _this, "o1ssf" );
m_osc2Vol.saveSettings( _doc, _this, "o2vol" );
m_osc2Pan.saveSettings( _doc, _this, "o2pan" );
m_osc2Crs.saveSettings( _doc, _this, "o2crs" );
m_osc2Ftl.saveSettings( _doc, _this, "o2ftl" );
m_osc2Ftr.saveSettings( _doc, _this, "o2ftr" );
m_osc2Spo.saveSettings( _doc, _this, "o2spo" );
m_osc2Wave.saveSettings( _doc, _this, "o2wav" );
m_osc2SyncH.saveSettings( _doc, _this, "o2syn" );
m_osc2SyncR.saveSettings( _doc, _this, "o2synr" );
m_osc3Vol.saveSettings( _doc, _this, "o3vol" );
m_osc3Pan.saveSettings( _doc, _this, "o3pan" );
m_osc3Crs.saveSettings( _doc, _this, "o3crs" );
m_osc3Spo.saveSettings( _doc, _this, "o3spo" );
m_osc3Sub.saveSettings( _doc, _this, "o3sub" );
m_osc3Wave1.saveSettings( _doc, _this, "o3wav1" );
m_osc3Wave2.saveSettings( _doc, _this, "o3wav2" );
m_osc3SyncH.saveSettings( _doc, _this, "o3syn" );
m_osc3SyncR.saveSettings( _doc, _this, "o3synr" );
m_lfo1Wave.saveSettings( _doc, _this, "l1wav" );
m_lfo1Att.saveSettings( _doc, _this, "l1att" );
m_lfo1Rate.saveSettings( _doc, _this, "l1rat" );
m_lfo1Phs.saveSettings( _doc, _this, "l1phs" );
m_lfo2Wave.saveSettings( _doc, _this, "l2wav" );
m_lfo2Att.saveSettings( _doc, _this, "l2att" );
m_lfo2Rate.saveSettings( _doc, _this, "l2rat" );
m_lfo2Phs.saveSettings( _doc, _this, "l2phs" );
m_env1Pre.saveSettings( _doc, _this, "e1pre" );
m_env1Att.saveSettings( _doc, _this, "e1att" );
m_env1Hold.saveSettings( _doc, _this, "e1hol" );
m_env1Dec.saveSettings( _doc, _this, "e1dec" );
m_env1Sus.saveSettings( _doc, _this, "e1sus" );
m_env1Rel.saveSettings( _doc, _this, "e1rel" );
m_env1Slope.saveSettings( _doc, _this, "e1slo" );
m_env2Pre.saveSettings( _doc, _this, "e2pre" );
m_env2Att.saveSettings( _doc, _this, "e2att" );
m_env2Hold.saveSettings( _doc, _this, "e2hol" );
m_env2Dec.saveSettings( _doc, _this, "e2dec" );
m_env2Sus.saveSettings( _doc, _this, "e2sus" );
m_env2Rel.saveSettings( _doc, _this, "e2rel" );
m_env2Slope.saveSettings( _doc, _this, "e2slo" );
m_o23Mod.saveSettings( _doc, _this, "o23mo" );
m_vol1env1.saveSettings( _doc, _this, "v1e1" );
m_vol1env2.saveSettings( _doc, _this, "v1e2" );
m_vol1lfo1.saveSettings( _doc, _this, "v1l1" );
m_vol1lfo2.saveSettings( _doc, _this, "v1l2" );
m_vol2env1.saveSettings( _doc, _this, "v2e1" );
m_vol2env2.saveSettings( _doc, _this, "v2e2" );
m_vol2lfo1.saveSettings( _doc, _this, "v2l1" );
m_vol2lfo2.saveSettings( _doc, _this, "v2l2" );
m_vol3env1.saveSettings( _doc, _this, "v3e1" );
m_vol3env2.saveSettings( _doc, _this, "v3e2" );
m_vol3lfo1.saveSettings( _doc, _this, "v3l1" );
m_vol3lfo2.saveSettings( _doc, _this, "v3l2" );
m_phs1env1.saveSettings( _doc, _this, "p1e1" );
m_phs1env2.saveSettings( _doc, _this, "p1e2" );
m_phs1lfo1.saveSettings( _doc, _this, "p1l1" );
m_phs1lfo2.saveSettings( _doc, _this, "p1l2" );
m_phs2env1.saveSettings( _doc, _this, "p2e1" );
m_phs2env2.saveSettings( _doc, _this, "p2e2" );
m_phs2lfo1.saveSettings( _doc, _this, "p2l1" );
m_phs2lfo2.saveSettings( _doc, _this, "p2l2" );
m_phs3env1.saveSettings( _doc, _this, "p3e1" );
m_phs3env2.saveSettings( _doc, _this, "p3e2" );
m_phs3lfo1.saveSettings( _doc, _this, "p3l1" );
m_phs3lfo2.saveSettings( _doc, _this, "p3l2" );
m_pit1env1.saveSettings( _doc, _this, "f1e1" );
m_pit1env2.saveSettings( _doc, _this, "f1e2" );
m_pit1lfo1.saveSettings( _doc, _this, "f1l1" );
m_pit1lfo2.saveSettings( _doc, _this, "f1l2" );
m_pit2env1.saveSettings( _doc, _this, "f2e1" );
m_pit2env2.saveSettings( _doc, _this, "f2e2" );
m_pit2lfo1.saveSettings( _doc, _this, "f2l1" );
m_pit2lfo2.saveSettings( _doc, _this, "f2l2" );
m_pit3env1.saveSettings( _doc, _this, "f3e1" );
m_pit3env2.saveSettings( _doc, _this, "f3e2" );
m_pit3lfo1.saveSettings( _doc, _this, "f3l1" );
m_pit3lfo2.saveSettings( _doc, _this, "f3l2" );
m_pw1env1.saveSettings( _doc, _this, "w1e1" );
m_pw1env2.saveSettings( _doc, _this, "w1e2" );
m_pw1lfo1.saveSettings( _doc, _this, "w1l1" );
m_pw1lfo2.saveSettings( _doc, _this, "w1l2" );
m_sub3env1.saveSettings( _doc, _this, "s3e1" );
m_sub3env2.saveSettings( _doc, _this, "s3e2" );
m_sub3lfo1.saveSettings( _doc, _this, "s3l1" );
m_sub3lfo2.saveSettings( _doc, _this, "s3l2" );
}
void MonstroInstrument::loadSettings( const QDomElement & _this )
{
m_osc1Vol.loadSettings( _this, "o1vol" );
m_osc1Pan.loadSettings( _this, "o1pan" );
m_osc1Crs.loadSettings( _this, "o1crs" );
m_osc1Ftl.loadSettings( _this, "o1ftl" );
m_osc1Ftr.loadSettings( _this, "o1ftr" );
m_osc1Spo.loadSettings( _this, "o1spo" );
m_osc1Pw.loadSettings( _this, "o1pw" );
m_osc1SSR.loadSettings( _this, "o1ssr" );
m_osc1SSF.loadSettings( _this, "o1ssf" );
m_osc2Vol.loadSettings( _this, "o2vol" );
m_osc2Pan.loadSettings( _this, "o2pan" );
m_osc2Crs.loadSettings( _this, "o2crs" );
m_osc2Ftl.loadSettings( _this, "o2ftl" );
m_osc2Ftr.loadSettings( _this, "o2ftr" );
m_osc2Spo.loadSettings( _this, "o2spo" );
m_osc2Wave.loadSettings( _this, "o2wav" );
m_osc2SyncH.loadSettings( _this, "o2syn" );
m_osc2SyncR.loadSettings( _this, "o2synr" );
m_osc3Vol.loadSettings( _this, "o3vol" );
m_osc3Pan.loadSettings( _this, "o3pan" );
m_osc3Crs.loadSettings( _this, "o3crs" );
m_osc3Spo.loadSettings( _this, "o3spo" );
m_osc3Sub.loadSettings( _this, "o3sub" );
m_osc3Wave1.loadSettings( _this, "o3wav1" );
m_osc3Wave2.loadSettings( _this, "o3wav2" );
m_osc3SyncH.loadSettings( _this, "o3syn" );
m_osc3SyncR.loadSettings( _this, "o3synr" );
m_lfo1Wave.loadSettings( _this, "l1wav" );
m_lfo1Att.loadSettings( _this, "l1att" );
m_lfo1Rate.loadSettings( _this, "l1rat" );
m_lfo1Phs.loadSettings( _this, "l1phs" );
m_lfo2Wave.loadSettings( _this, "l2wav" );
m_lfo2Att.loadSettings( _this, "l2att" );
m_lfo2Rate.loadSettings( _this, "l2rat" );
m_lfo2Phs.loadSettings( _this, "l2phs" );
m_env1Pre.loadSettings( _this, "e1pre" );
m_env1Att.loadSettings( _this, "e1att" );
m_env1Hold.loadSettings( _this, "e1hol" );
m_env1Dec.loadSettings( _this, "e1dec" );
m_env1Sus.loadSettings( _this, "e1sus" );
m_env1Rel.loadSettings( _this, "e1rel" );
m_env1Slope.loadSettings( _this, "e1slo" );
m_env2Pre.loadSettings( _this, "e2pre" );
m_env2Att.loadSettings( _this, "e2att" );
m_env2Hold.loadSettings( _this, "e2hol" );
m_env2Dec.loadSettings( _this, "e2dec" );
m_env2Sus.loadSettings( _this, "e2sus" );
m_env2Rel.loadSettings( _this, "e2rel" );
m_env2Slope.loadSettings( _this, "e2slo" );
m_o23Mod.loadSettings( _this, "o23mo" );
m_vol1env1.loadSettings( _this, "v1e1" );
m_vol1env2.loadSettings( _this, "v1e2" );
m_vol1lfo1.loadSettings( _this, "v1l1" );
m_vol1lfo2.loadSettings( _this, "v1l2" );
m_vol2env1.loadSettings( _this, "v2e1" );
m_vol2env2.loadSettings( _this, "v2e2" );
m_vol2lfo1.loadSettings( _this, "v2l1" );
m_vol2lfo2.loadSettings( _this, "v2l2" );
m_vol3env1.loadSettings( _this, "v3e1" );
m_vol3env2.loadSettings( _this, "v3e2" );
m_vol3lfo1.loadSettings( _this, "v3l1" );
m_vol3lfo2.loadSettings( _this, "v3l2" );
m_phs1env1.loadSettings( _this, "p1e1" );
m_phs1env2.loadSettings( _this, "p1e2" );
m_phs1lfo1.loadSettings( _this, "p1l1" );
m_phs1lfo2.loadSettings( _this, "p1l2" );
m_phs2env1.loadSettings( _this, "p2e1" );
m_phs2env2.loadSettings( _this, "p2e2" );
m_phs2lfo1.loadSettings( _this, "p2l1" );
m_phs2lfo2.loadSettings( _this, "p2l2" );
m_phs3env1.loadSettings( _this, "p3e1" );
m_phs3env2.loadSettings( _this, "p3e2" );
m_phs3lfo1.loadSettings( _this, "p3l1" );
m_phs3lfo2.loadSettings( _this, "p3l2" );
m_pit1env1.loadSettings( _this, "f1e1" );
m_pit1env2.loadSettings( _this, "f1e2" );
m_pit1lfo1.loadSettings( _this, "f1l1" );
m_pit1lfo2.loadSettings( _this, "f1l2" );
m_pit2env1.loadSettings( _this, "f2e1" );
m_pit2env2.loadSettings( _this, "f2e2" );
m_pit2lfo1.loadSettings( _this, "f2l1" );
m_pit2lfo2.loadSettings( _this, "f2l2" );
m_pit3env1.loadSettings( _this, "f3e1" );
m_pit3env2.loadSettings( _this, "f3e2" );
m_pit3lfo1.loadSettings( _this, "f3l1" );
m_pit3lfo2.loadSettings( _this, "f3l2" );
m_pw1env1.loadSettings( _this, "w1e1" );
m_pw1env2.loadSettings( _this, "w1e2" );
m_pw1lfo1.loadSettings( _this, "w1l1" );
m_pw1lfo2.loadSettings( _this, "w1l2" );
m_sub3env1.loadSettings( _this, "s3e1" );
m_sub3env2.loadSettings( _this, "s3e2" );
m_sub3lfo1.loadSettings( _this, "s3l1" );
m_sub3lfo2.loadSettings( _this, "s3l2" );
}
QString MonstroInstrument::nodeName() const
{
return monstro_plugin_descriptor.name;
}
f_cnt_t MonstroInstrument::desiredReleaseFrames() const
{
return qMax( 64, qMax( m_env1_relF, m_env2_relF ) );
}
PluginView * MonstroInstrument::instantiateView( QWidget * _parent )
{
return( new MonstroView( this, _parent ) );
}
void MonstroInstrument::updateVolume1()
{
m_osc1l_vol = leftCh( m_osc1Vol.value(), m_osc1Pan.value() );
m_osc1r_vol = rightCh( m_osc1Vol.value(), m_osc1Pan.value() );
}
void MonstroInstrument::updateVolume2()
{
m_osc2l_vol = leftCh( m_osc2Vol.value(), m_osc2Pan.value() );
m_osc2r_vol = rightCh( m_osc2Vol.value(), m_osc2Pan.value() );
}
void MonstroInstrument::updateVolume3()
{
m_osc3l_vol = leftCh( m_osc3Vol.value(), m_osc3Pan.value() );
m_osc3r_vol = rightCh( m_osc3Vol.value(), m_osc3Pan.value() );
}
void MonstroInstrument::updateFreq1()
{
m_osc1l_freq = powf( 2.0f, m_osc1Crs.value() / 12.0f ) *
powf( 2.0f, m_osc1Ftl.value() / 1200.0f );
m_osc1r_freq = powf( 2.0f, m_osc1Crs.value() / 12.0f ) *
powf( 2.0f, m_osc1Ftr.value() / 1200.0f );
}
void MonstroInstrument::updateFreq2()
{
m_osc2l_freq = powf( 2.0f, m_osc2Crs.value() / 12.0f ) *
powf( 2.0f, m_osc2Ftl.value() / 1200.0f );
m_osc2r_freq = powf( 2.0f, m_osc2Crs.value() / 12.0f ) *
powf( 2.0f, m_osc2Ftr.value() / 1200.0f );
}
void MonstroInstrument::updateFreq3()
{
m_osc3_freq = powf( 2.0f, m_osc3Crs.value() / 12.0f );
}
void MonstroInstrument::updatePO1()
{
m_osc1l_po = m_osc1Spo.value() / 720.0f;
m_osc1r_po = ( m_osc1Spo.value() * -1.0 ) / 720.0f;
}
void MonstroInstrument::updatePO2()
{
m_osc2l_po = m_osc2Spo.value() / 720.0f;
m_osc2r_po = ( m_osc2Spo.value() * -1.0 ) / 720.0f;
}
void MonstroInstrument::updatePO3()
{
m_osc3l_po = m_osc3Spo.value() / 720.0f;
m_osc3r_po = ( m_osc3Spo.value() * -1.0 ) / 720.0f;
}
void MonstroInstrument::updateEnvelope1()
{
if( m_env1Pre.value() == 0.0f ) m_env1_pre = 1.0;
else m_env1_pre = 1.0f / ( m_env1Pre.value() / 1000.0f ) / m_samplerate;
if( m_env1Att.value() == 0.0f ) m_env1_att = 1.0;
else m_env1_att = 1.0f / ( m_env1Att.value() / 1000.0f ) / m_samplerate;
if( m_env1Hold.value() == 0.0f ) m_env1_hold = 1.0;
else m_env1_hold = 1.0f / ( m_env1Hold.value() / 1000.0f ) / m_samplerate;
if( m_env1Dec.value() == 0.0f ) m_env1_dec = 1.0;
else m_env1_dec = 1.0f / ( m_env1Dec.value() / 1000.0f ) / m_samplerate;
if( m_env1Rel.value() == 0.0f ) m_env1_rel = 1.0;
else m_env1_rel = 1.0f / ( m_env1Rel.value() / 1000.0f ) / m_samplerate;
m_env1_len = ( m_env1Pre.value() + m_env1Att.value() + m_env1Hold.value() + m_env1Dec.value() ) * m_samplerate / 1000.0f;
m_env1_relF = m_env1Rel.value() * m_samplerate / 1000.0f;
}
void MonstroInstrument::updateEnvelope2()
{
if( m_env2Pre.value() == 0.0f ) m_env2_pre = 1.0;
else m_env2_pre = 1.0f / ( m_env2Pre.value() / 1000.0f ) / m_samplerate;
if( m_env2Att.value() == 0.0f ) m_env2_att = 1.0;
else m_env2_att = 1.0f / ( m_env2Att.value() / 1000.0f ) / m_samplerate;
if( m_env2Hold.value() == 0.0f ) m_env2_hold = 1.0;
else m_env2_hold = 1.0f / ( m_env2Hold.value() / 1000.0f ) / m_samplerate;
if( m_env2Dec.value() == 0.0f ) m_env2_dec = 1.0;
else m_env2_dec = 1.0f / ( m_env2Dec.value() / 1000.0f ) / m_samplerate;
if( m_env2Rel.value() == 0.0f ) m_env2_rel = 1.0;
else m_env2_rel = 1.0f / ( m_env2Rel.value() / 1000.0f ) / m_samplerate;
m_env2_len = ( m_env2Pre.value() + m_env2Att.value() + m_env2Hold.value() + m_env2Dec.value() ) * m_samplerate / 1000.0f;
m_env2_relF = m_env2Rel.value() * m_samplerate / 1000.0f;
}
void MonstroInstrument::updateLFOAtts()
{
m_lfo1_att = m_lfo1Att.value() * m_samplerate / 1000.0f;
m_lfo2_att = m_lfo2Att.value() * m_samplerate / 1000.0f;
}
void MonstroInstrument::updateSamplerate()
{
m_samplerate = Engine::audioEngine()->processingSampleRate();
m_integrator = 0.5f - ( 0.5f - INTEGRATOR ) * 44100.0f / m_samplerate;
m_fmCorrection = 44100.f / m_samplerate * FM_AMOUNT;
m_counterMax = ( m_samplerate * 5 ) / 44100;
updateEnvelope1();
updateEnvelope2();
updateLFOAtts();
}
void MonstroInstrument::updateSlope1()
{
const float slope = m_env1Slope.value();
m_slope[0] = std::pow(10.f, slope * -1.0f );
}
void MonstroInstrument::updateSlope2()
{
const float slope = m_env2Slope.value();
m_slope[1] = std::pow(10.f, slope * -1.0f );
}
MonstroView::MonstroView( Instrument * _instrument,
QWidget * _parent ) :
InstrumentViewFixedSize( _instrument, _parent )
{
m_operatorsView = setupOperatorsView( this );
setWidgetBackground( m_operatorsView, "artwork_op" );
m_operatorsView->show();
m_operatorsView->move( 0, 0 );
m_matrixView = setupMatrixView( this );
setWidgetBackground( m_matrixView, "artwork_mat" );
m_matrixView->hide();
m_matrixView->move( 0, 0 );
// "tab buttons"
PixmapButton * m_opViewButton = new PixmapButton( this, nullptr );
m_opViewButton -> move( 0,0 );
m_opViewButton -> setActiveGraphic( PLUGIN_NAME::getIconPixmap( "opview_active" ) );
m_opViewButton -> setInactiveGraphic( PLUGIN_NAME::getIconPixmap( "opview_inactive" ) );
ToolTip::add( m_opViewButton, tr( "Operators view" ) );
PixmapButton * m_matViewButton = new PixmapButton( this, nullptr );
m_matViewButton -> move( 125,0 );
m_matViewButton -> setActiveGraphic( PLUGIN_NAME::getIconPixmap( "matview_active" ) );
m_matViewButton -> setInactiveGraphic( PLUGIN_NAME::getIconPixmap( "matview_inactive" ) );
ToolTip::add( m_matViewButton, tr( "Matrix view" ) );
m_selectedViewGroup = new automatableButtonGroup( this );
m_selectedViewGroup -> addButton( m_opViewButton );
m_selectedViewGroup -> addButton( m_matViewButton );
connect( m_opViewButton, SIGNAL( clicked() ), this, SLOT( updateLayout() ) );
connect( m_matViewButton, SIGNAL( clicked() ), this, SLOT( updateLayout() ) );
}
MonstroView::~MonstroView()
{
}
void MonstroView::updateLayout()
{
switch( m_selectedViewGroup->model()->value() )
{
case OPVIEW:
m_operatorsView->show();
m_matrixView->hide();
break;
case MATVIEW:
m_operatorsView->hide();
m_matrixView->show();
break;
}
}
void MonstroView::modelChanged()
{
MonstroInstrument * m = castModel<MonstroInstrument>();
m_osc1VolKnob-> setModel( &m-> m_osc1Vol );
m_osc1PanKnob-> setModel( &m-> m_osc1Pan );
m_osc1CrsKnob-> setModel( &m-> m_osc1Crs );
m_osc1FtlKnob-> setModel( &m-> m_osc1Ftl );
m_osc1FtrKnob-> setModel( &m-> m_osc1Ftr );
m_osc1SpoKnob-> setModel( &m-> m_osc1Spo );
m_osc1PwKnob-> setModel( &m-> m_osc1Pw );
m_osc1SSRButton-> setModel( &m-> m_osc1SSR );
m_osc1SSFButton-> setModel( &m-> m_osc1SSF );
m_osc2VolKnob-> setModel( &m-> m_osc2Vol );
m_osc2PanKnob-> setModel( &m-> m_osc2Pan );
m_osc2CrsKnob-> setModel( &m-> m_osc2Crs );
m_osc2FtlKnob-> setModel( &m-> m_osc2Ftl );
m_osc2FtrKnob-> setModel( &m-> m_osc2Ftr );
m_osc2SpoKnob-> setModel( &m-> m_osc2Spo );
m_osc2WaveBox-> setModel( &m-> m_osc2Wave );
m_osc2SyncHButton-> setModel( &m-> m_osc2SyncH );
m_osc2SyncRButton-> setModel( &m-> m_osc2SyncR );
m_osc3VolKnob-> setModel( &m-> m_osc3Vol );
m_osc3PanKnob-> setModel( &m-> m_osc3Pan );
m_osc3CrsKnob-> setModel( &m-> m_osc3Crs );
m_osc3SpoKnob-> setModel( &m-> m_osc3Spo );
m_osc3SubKnob-> setModel( &m-> m_osc3Sub );
m_osc3Wave1Box-> setModel( &m-> m_osc3Wave1 );
m_osc3Wave2Box-> setModel( &m-> m_osc3Wave2 );
m_osc3SyncHButton-> setModel( &m-> m_osc3SyncH );
m_osc3SyncRButton-> setModel( &m-> m_osc3SyncR );
m_lfo1WaveBox-> setModel( &m-> m_lfo1Wave );
m_lfo1AttKnob-> setModel( &m-> m_lfo1Att );
m_lfo1RateKnob-> setModel( &m-> m_lfo1Rate );
m_lfo1PhsKnob-> setModel( &m-> m_lfo1Phs );
m_lfo2WaveBox-> setModel( &m-> m_lfo2Wave );
m_lfo2AttKnob-> setModel( &m-> m_lfo2Att );
m_lfo2RateKnob-> setModel( &m-> m_lfo2Rate );
m_lfo2PhsKnob-> setModel( &m-> m_lfo2Phs );
m_env1PreKnob-> setModel( &m-> m_env1Pre );
m_env1AttKnob-> setModel( &m-> m_env1Att );
m_env1HoldKnob-> setModel( &m-> m_env1Hold );
m_env1DecKnob-> setModel( &m-> m_env1Dec );
m_env1SusKnob-> setModel( &m-> m_env1Sus );
m_env1RelKnob-> setModel( &m-> m_env1Rel );
m_env1SlopeKnob-> setModel( &m-> m_env1Slope );
m_env2PreKnob-> setModel( &m-> m_env2Pre );
m_env2AttKnob-> setModel( &m-> m_env2Att );
m_env2HoldKnob-> setModel( &m-> m_env2Hold );
m_env2DecKnob-> setModel( &m-> m_env2Dec );
m_env2SusKnob-> setModel( &m-> m_env2Sus );
m_env2RelKnob-> setModel( &m-> m_env2Rel );
m_env2SlopeKnob-> setModel( &m-> m_env2Slope );
m_o23ModGroup-> setModel( &m-> m_o23Mod );
m_selectedViewGroup-> setModel( &m-> m_selectedView );
m_vol1env1Knob-> setModel( &m-> m_vol1env1 );
m_vol1env2Knob-> setModel( &m-> m_vol1env2 );
m_vol1lfo1Knob-> setModel( &m-> m_vol1lfo1 );
m_vol1lfo2Knob-> setModel( &m-> m_vol1lfo2 );
m_vol2env1Knob-> setModel( &m-> m_vol2env1 );
m_vol2env2Knob-> setModel( &m-> m_vol2env2 );
m_vol2lfo1Knob-> setModel( &m-> m_vol2lfo1 );
m_vol2lfo2Knob-> setModel( &m-> m_vol2lfo2 );
m_vol3env1Knob-> setModel( &m-> m_vol3env1 );
m_vol3env2Knob-> setModel( &m-> m_vol3env2 );
m_vol3lfo1Knob-> setModel( &m-> m_vol3lfo1 );
m_vol3lfo2Knob-> setModel( &m-> m_vol3lfo2 );
m_phs1env1Knob-> setModel( &m-> m_phs1env1 );
m_phs1env2Knob-> setModel( &m-> m_phs1env2 );
m_phs1lfo1Knob-> setModel( &m-> m_phs1lfo1 );
m_phs1lfo2Knob-> setModel( &m-> m_phs1lfo2 );
m_phs2env1Knob-> setModel( &m-> m_phs2env1 );
m_phs2env2Knob-> setModel( &m-> m_phs2env2 );
m_phs2lfo1Knob-> setModel( &m-> m_phs2lfo1 );
m_phs2lfo2Knob-> setModel( &m-> m_phs2lfo2 );
m_phs3env1Knob-> setModel( &m-> m_phs3env1 );
m_phs3env2Knob-> setModel( &m-> m_phs3env2 );
m_phs3lfo1Knob-> setModel( &m-> m_phs3lfo1 );
m_phs3lfo2Knob-> setModel( &m-> m_phs3lfo2 );
m_pit1env1Knob-> setModel( &m-> m_pit1env1 );
m_pit1env2Knob-> setModel( &m-> m_pit1env2 );
m_pit1lfo1Knob-> setModel( &m-> m_pit1lfo1 );
m_pit1lfo2Knob-> setModel( &m-> m_pit1lfo2 );
m_pit2env1Knob-> setModel( &m-> m_pit2env1 );
m_pit2env2Knob-> setModel( &m-> m_pit2env2 );
m_pit2lfo1Knob-> setModel( &m-> m_pit2lfo1 );
m_pit2lfo2Knob-> setModel( &m-> m_pit2lfo2 );
m_pit3env1Knob-> setModel( &m-> m_pit3env1 );
m_pit3env2Knob-> setModel( &m-> m_pit3env2 );
m_pit3lfo1Knob-> setModel( &m-> m_pit3lfo1 );
m_pit3lfo2Knob-> setModel( &m-> m_pit3lfo2 );
m_pw1env1Knob-> setModel( &m-> m_pw1env1 );
m_pw1env2Knob-> setModel( &m-> m_pw1env2 );
m_pw1lfo1Knob-> setModel( &m-> m_pw1lfo1 );
m_pw1lfo2Knob-> setModel( &m-> m_pw1lfo2 );
m_sub3env1Knob-> setModel( &m-> m_sub3env1 );
m_sub3env2Knob-> setModel( &m-> m_sub3env2 );
m_sub3lfo1Knob-> setModel( &m-> m_sub3lfo1 );
m_sub3lfo2Knob-> setModel( &m-> m_sub3lfo2 );
}
void MonstroView::setWidgetBackground( QWidget * _widget, const QString & _pic )
{
_widget->setAutoFillBackground( true );
QPalette pal;
pal.setBrush( _widget->backgroundRole(),
PLUGIN_NAME::getIconPixmap( _pic.toLatin1().constData() ) );
_widget->setPalette( pal );
}
QWidget * MonstroView::setupOperatorsView( QWidget * _parent )
{
// operators view
QWidget * view = new QWidget( _parent );
view-> setFixedSize( 250, 250 );
makeknob( m_osc1VolKnob, KNOBCOL1, O1ROW, tr( "Volume" ), "%", "osc1Knob" )
makeknob( m_osc1PanKnob, KNOBCOL2, O1ROW, tr( "Panning" ), "", "osc1Knob" )
makeknob( m_osc1CrsKnob, KNOBCOL3, O1ROW, tr( "Coarse detune" ), tr( " semitones" ), "osc1Knob" )
makeknob( m_osc1FtlKnob, KNOBCOL4, O1ROW, tr( "Fine tune left" ), tr( " cents" ), "osc1Knob" )
makeknob( m_osc1FtrKnob, KNOBCOL5, O1ROW, tr( "Fine tune right" ), tr( " cents" ), "osc1Knob" )
makeknob( m_osc1SpoKnob, KNOBCOL6, O1ROW, tr( "Stereo phase offset" ), tr( " deg" ), "osc1Knob" )
makeknob( m_osc1PwKnob, KNOBCOL7, O1ROW, tr( "Pulse width" ), "%", "osc1Knob" )
m_osc1VolKnob -> setVolumeKnob( true );
maketinyled( m_osc1SSRButton, 230, 34, tr( "Send sync on pulse rise" ) )
maketinyled( m_osc1SSFButton, 230, 44, tr( "Send sync on pulse fall" ) )
makeknob( m_osc2VolKnob, KNOBCOL1, O2ROW, tr( "Volume" ), "%", "osc2Knob" )
makeknob( m_osc2PanKnob, KNOBCOL2, O2ROW, tr( "Panning" ), "", "osc2Knob" )
makeknob( m_osc2CrsKnob, KNOBCOL3, O2ROW, tr( "Coarse detune" ), tr( " semitones" ), "osc2Knob" )
makeknob( m_osc2FtlKnob, KNOBCOL4, O2ROW, tr( "Fine tune left" ), tr( " cents" ), "osc2Knob" )
makeknob( m_osc2FtrKnob, KNOBCOL5, O2ROW, tr( "Fine tune right" ), tr( " cents" ), "osc2Knob" )
makeknob( m_osc2SpoKnob, KNOBCOL6, O2ROW, tr( "Stereo phase offset" ), tr( " deg" ), "osc2Knob" )
m_osc2VolKnob -> setVolumeKnob( true );
m_osc2WaveBox = new ComboBox( view );
m_osc2WaveBox -> setGeometry( 204, O2ROW + 7, 42, ComboBox::DEFAULT_HEIGHT );
m_osc2WaveBox->setFont( pointSize<8>( m_osc2WaveBox->font() ) );
maketinyled( m_osc2SyncHButton, 212, O2ROW - 3, tr( "Hard sync oscillator 2" ) )
maketinyled( m_osc2SyncRButton, 191, O2ROW - 3, tr( "Reverse sync oscillator 2" ) )
makeknob( m_osc3VolKnob, KNOBCOL1, O3ROW, tr( "Volume" ), "%", "osc3Knob" )
makeknob( m_osc3PanKnob, KNOBCOL2, O3ROW, tr( "Panning" ), "", "osc3Knob" )
makeknob( m_osc3CrsKnob, KNOBCOL3, O3ROW, tr( "Coarse detune" ), tr( " semitones" ), "osc3Knob" )
makeknob( m_osc3SpoKnob, KNOBCOL4, O3ROW, tr( "Stereo phase offset" ), tr( " deg" ), "osc3Knob" )
makeknob( m_osc3SubKnob, KNOBCOL5, O3ROW, tr( "Sub-osc mix" ), "", "osc3Knob" )
m_osc3VolKnob -> setVolumeKnob( true );
m_osc3Wave1Box = new ComboBox( view );
m_osc3Wave1Box -> setGeometry( 160, O3ROW + 7, 42, ComboBox::DEFAULT_HEIGHT );
m_osc3Wave1Box->setFont( pointSize<8>( m_osc3Wave1Box->font() ) );
m_osc3Wave2Box = new ComboBox( view );
m_osc3Wave2Box -> setGeometry( 204, O3ROW + 7, 42, ComboBox::DEFAULT_HEIGHT );
m_osc3Wave2Box->setFont( pointSize<8>( m_osc3Wave2Box->font() ) );
maketinyled( m_osc3SyncHButton, 212, O3ROW - 3, tr( "Hard sync oscillator 3" ) )
maketinyled( m_osc3SyncRButton, 191, O3ROW - 3, tr( "Reverse sync oscillator 3" ) )
m_lfo1WaveBox = new ComboBox( view );
m_lfo1WaveBox -> setGeometry( 2, LFOROW + 7, 42, ComboBox::DEFAULT_HEIGHT );
m_lfo1WaveBox->setFont( pointSize<8>( m_lfo1WaveBox->font() ) );
maketsknob( m_lfo1AttKnob, LFOCOL1, LFOROW, tr( "Attack" ), " ms", "lfoKnob" )
maketsknob( m_lfo1RateKnob, LFOCOL2, LFOROW, tr( "Rate" ), " ms", "lfoKnob" )
makeknob( m_lfo1PhsKnob, LFOCOL3, LFOROW, tr( "Phase" ), tr( " deg" ), "lfoKnob" )
m_lfo2WaveBox = new ComboBox( view );
m_lfo2WaveBox -> setGeometry( 127, LFOROW + 7, 42, ComboBox::DEFAULT_HEIGHT );
m_lfo2WaveBox->setFont( pointSize<8>( m_lfo2WaveBox->font() ) );
maketsknob( m_lfo2AttKnob, LFOCOL4, LFOROW, tr( "Attack" ), " ms", "lfoKnob" )
maketsknob( m_lfo2RateKnob, LFOCOL5, LFOROW, tr( "Rate" ), " ms", "lfoKnob" )
makeknob( m_lfo2PhsKnob, LFOCOL6, LFOROW, tr( "Phase" ), tr( " deg" ), "lfoKnob" )
maketsknob( m_env1PreKnob, KNOBCOL1, E1ROW, tr( "Pre-delay" ), " ms", "envKnob" )
maketsknob( m_env1AttKnob, KNOBCOL2, E1ROW, tr( "Attack" ), " ms", "envKnob" )
maketsknob( m_env1HoldKnob, KNOBCOL3, E1ROW, tr( "Hold" ), " ms", "envKnob" )
maketsknob( m_env1DecKnob, KNOBCOL4, E1ROW, tr( "Decay" ), " ms", "envKnob" )
makeknob( m_env1SusKnob, KNOBCOL5, E1ROW, tr( "Sustain" ), "", "envKnob" )
maketsknob( m_env1RelKnob, KNOBCOL6, E1ROW, tr( "Release" ), " ms", "envKnob" )
makeknob( m_env1SlopeKnob, KNOBCOL7, E1ROW, tr( "Slope" ), "", "envKnob" )
maketsknob( m_env2PreKnob, KNOBCOL1, E2ROW, tr( "Pre-delay" ), " ms", "envKnob" )
maketsknob( m_env2AttKnob, KNOBCOL2, E2ROW, tr( "Attack" ), " ms", "envKnob" )
maketsknob( m_env2HoldKnob, KNOBCOL3, E2ROW, tr( "Hold" ), " ms", "envKnob" )
maketsknob( m_env2DecKnob, KNOBCOL4, E2ROW, tr( "Decay" ), " ms", "envKnob" )
makeknob( m_env2SusKnob, KNOBCOL5, E2ROW, tr( "Sustain" ), "", "envKnob" )
maketsknob( m_env2RelKnob, KNOBCOL6, E2ROW, tr( "Release" ), " ms", "envKnob" )
makeknob( m_env2SlopeKnob, KNOBCOL7, E2ROW, tr( "Slope" ), "", "envKnob" )
// mod selector
PixmapButton * m_mixButton = new PixmapButton( view, nullptr );
m_mixButton -> move( 225, 185 );
m_mixButton -> setActiveGraphic( PLUGIN_NAME::getIconPixmap( "mix_active" ) );
m_mixButton -> setInactiveGraphic( PLUGIN_NAME::getIconPixmap( "mix_inactive" ) );
ToolTip::add( m_mixButton, tr( "Mix osc 2 with osc 3" ) );
PixmapButton * m_amButton = new PixmapButton( view, nullptr );
m_amButton -> move( 225, 185 + 15 );
m_amButton -> setActiveGraphic( PLUGIN_NAME::getIconPixmap( "am_active" ) );
m_amButton -> setInactiveGraphic( PLUGIN_NAME::getIconPixmap( "am_inactive" ) );
ToolTip::add( m_amButton, tr( "Modulate amplitude of osc 3 by osc 2" ) );
PixmapButton * m_fmButton = new PixmapButton( view, nullptr );
m_fmButton -> move( 225, 185 + 15*2 );
m_fmButton -> setActiveGraphic( PLUGIN_NAME::getIconPixmap( "fm_active" ) );
m_fmButton -> setInactiveGraphic( PLUGIN_NAME::getIconPixmap( "fm_inactive" ) );
ToolTip::add( m_fmButton, tr( "Modulate frequency of osc 3 by osc 2" ) );
PixmapButton * m_pmButton = new PixmapButton( view, nullptr );
m_pmButton -> move( 225, 185 + 15*3 );
m_pmButton -> setActiveGraphic( PLUGIN_NAME::getIconPixmap( "pm_active" ) );
m_pmButton -> setInactiveGraphic( PLUGIN_NAME::getIconPixmap( "pm_inactive" ) );
ToolTip::add( m_pmButton, tr( "Modulate phase of osc 3 by osc 2" ) );
m_o23ModGroup = new automatableButtonGroup( view );
m_o23ModGroup-> addButton( m_mixButton );
m_o23ModGroup-> addButton( m_amButton );
m_o23ModGroup-> addButton( m_fmButton );
m_o23ModGroup-> addButton( m_pmButton );
return( view );
}
QWidget * MonstroView::setupMatrixView( QWidget * _parent )
{
// matrix view
QWidget * view = new QWidget( _parent );
view-> setFixedSize( 250, 250 );
makeknob( m_vol1env1Knob, MATCOL1, MATROW1, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol1env2Knob, MATCOL2, MATROW1, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol1lfo1Knob, MATCOL3, MATROW1, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol1lfo2Knob, MATCOL4, MATROW1, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol2env1Knob, MATCOL1, MATROW3, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol2env2Knob, MATCOL2, MATROW3, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol2lfo1Knob, MATCOL3, MATROW3, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol2lfo2Knob, MATCOL4, MATROW3, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol3env1Knob, MATCOL1, MATROW5, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol3env2Knob, MATCOL2, MATROW5, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol3lfo1Knob, MATCOL3, MATROW5, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_vol3lfo2Knob, MATCOL4, MATROW5, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs1env1Knob, MATCOL1, MATROW2, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs1env2Knob, MATCOL2, MATROW2, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs1lfo1Knob, MATCOL3, MATROW2, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs1lfo2Knob, MATCOL4, MATROW2, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs2env1Knob, MATCOL1, MATROW4, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs2env2Knob, MATCOL2, MATROW4, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs2lfo1Knob, MATCOL3, MATROW4, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs2lfo2Knob, MATCOL4, MATROW4, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs3env1Knob, MATCOL1, MATROW6, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs3env2Knob, MATCOL2, MATROW6, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs3lfo1Knob, MATCOL3, MATROW6, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_phs3lfo2Knob, MATCOL4, MATROW6, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit1env1Knob, MATCOL5, MATROW1, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit1env2Knob, MATCOL6, MATROW1, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit1lfo1Knob, MATCOL7, MATROW1, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit1lfo2Knob, MATCOL8, MATROW1, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit2env1Knob, MATCOL5, MATROW3, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit2env2Knob, MATCOL6, MATROW3, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit2lfo1Knob, MATCOL7, MATROW3, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit2lfo2Knob, MATCOL8, MATROW3, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit3env1Knob, MATCOL5, MATROW5, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit3env2Knob, MATCOL6, MATROW5, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit3lfo1Knob, MATCOL7, MATROW5, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pit3lfo2Knob, MATCOL8, MATROW5, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pw1env1Knob, MATCOL5, MATROW2, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pw1env2Knob, MATCOL6, MATROW2, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pw1lfo1Knob, MATCOL7, MATROW2, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_pw1lfo2Knob, MATCOL8, MATROW2, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_sub3env1Knob, MATCOL5, MATROW6, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_sub3env2Knob, MATCOL6, MATROW6, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_sub3lfo1Knob, MATCOL7, MATROW6, tr( "Modulation amount" ), "", "matrixKnob" )
makeknob( m_sub3lfo2Knob, MATCOL8, MATROW6, tr( "Modulation amount" ), "", "matrixKnob" )
return( view );
}
extern "C"
{
// necessary for getting instance out of shared lib
PLUGIN_EXPORT Plugin * lmms_plugin_main( Model *m, void * )
{
return new MonstroInstrument( static_cast<InstrumentTrack *>( m ) );
}
}
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