/// <summary>
/// Makes scale data
/// </summary>
/// <param name="_composition"></param>
/// <returns></returns>
public ScaleNote GenerateScale(Composition _composition)
{
// scale data
ScaleNote _scaleNote = new ScaleNote();
// 1.1. make scale
_scaleNote.MakeScale(_composition.Setting.Scale, _composition.Setting.ScaleNote, _composition.Setting.ChordHeight);
return(_scaleNote);
}
List <List <Note> > GetMellToneList(MellTone _mellTone, Form _form, ScaleNote _scale)
{
// avoid notes
List <List <Note> > _avoid = new List <List <Note> >();
// tension notes
List <List <Note> > _tension = new List <List <Note> >();
// chord tone notes
List <List <Note> > _tone = new List <List <Note> >();
int _lastNoteBuffer;
int _thirdNoteBuffer;
// 1. prepare usable note list
for (int _count = 0; _count < _form.Chord.FullChord.Count; _count++)
{
_avoid.Add(new List <Note>());
_tension.Add(new List <Note>());
_tone.Add(new List <Note>());
}
// copy chord as pure
List <List <Note> > _chordBuffer = new List <List <Note> >();
List <Note> _subBuffer = new List <Note>();
foreach (List <Note> _iterChord in _form.Chord.FullChord)
{
foreach (Note _iterNote in _iterChord)
{
_subBuffer.Add(GetPureNote(_iterNote));
}
_chordBuffer.Add(CopyNoteList(_subBuffer));
_subBuffer.Clear();
}
// 2. make avoid, tension and chord tone note list
for (int _iterChord = 0; _iterChord < _chordBuffer.Count; _iterChord++)
{
for (int _iterNote = 0; _iterNote < _chordBuffer[_iterChord].Count; _iterNote++)
{
// chord tone
_tone[_iterChord].Add(GetPureNote(_chordBuffer[_iterChord][_iterNote]));
// check if there is 3 avoid or tension notes
if (_tone[_iterChord].Count == _chordBuffer[_iterChord].Count)
{
break;
}
// last note in the chord
_lastNoteBuffer = ((int)_chordBuffer[_iterChord][_chordBuffer[_iterChord].Count - 1] % 12);
// 해당 코드에서 n번째 3도 위 음의 인덱스(스케일에서의 인덱스)
_thirdNoteBuffer = (_scale.Notes.IndexOf((Note)_lastNoteBuffer) + (3 * (_iterNote + 1))) % 7;
// avoid
if ((int)_scale.Notes[_thirdNoteBuffer] - _lastNoteBuffer == 1)
{
_avoid[_iterChord].Add(_scale.Notes[_thirdNoteBuffer]);
}
// tension
else
{
_tension[_iterChord].Add(_scale.Notes[_thirdNoteBuffer]);
}
}
}
switch (_mellTone)
{
case (MellTone.Tone):
return(_tone);
case (MellTone.Tension):
return(_tension);
case (MellTone.Avoid):
return(_avoid);
}
return(_tone);
}
/// <summary>
/// Extends mellodies, rhythm in the form
/// </summary>
/// <param name="_origin"></param>
/// <param name="_scale"></param>
/// <returns></returns>
Form VariateExtend(Form _origin, ScaleNote _scale, int _baseOctave)
{
Form _result = new Form();
// avoid notes
List <List <Note> > _avoid;
// tension notes
List <List <Note> > _tension;
// chord tone notes
List <List <Note> > _tone;
// deep copy the form
_result.Copy(_origin);
// 1. make mellody tone list
_avoid = GetMellToneList(MellTone.Avoid, _origin, _scale);
_tension = GetMellToneList(MellTone.Tension, _origin, _scale);
_tone = GetMellToneList(MellTone.Tone, _origin, _scale);
int _octaveBuffer = 0;
// 2.1. specific tension list making
for (int _iter = 0; _iter < _tension.Count; _iter++)
{
_octaveBuffer = 0;
for (int _itt = 0; _itt < _tension[_iter].Count; _itt++)
{
if (_itt != _tension[_iter].Count - 1 && _tension[_iter][_itt] > _tension[_iter][_itt + 1])
{
_tension[_iter][_itt] = GetOctaveNote(_tension[_iter][_itt], _baseOctave + _octaveBuffer);
_octaveBuffer++;
continue;
}
_tension[_iter][_itt] = GetOctaveNote(_tension[_iter][_itt], _baseOctave + _octaveBuffer);
}
}
// 2.2. specific tone list making
for (int _iter = 0; _iter < _tone.Count; _iter++)
{
_octaveBuffer = 0;
for (int _itt = 0; _itt < _tone[_iter].Count; _itt++)
{
if (_itt != _tone[_iter].Count - 1 && _tone[_iter][_itt] > _tone[_iter][_itt + 1])
{
_tone[_iter][_itt] = GetOctaveNote(_tone[_iter][_itt], _baseOctave + _octaveBuffer);
_octaveBuffer++;
continue;
}
_tone[_iter][_itt] = GetOctaveNote(_tone[_iter][_itt], _baseOctave + _octaveBuffer);
}
}
// count buffer
int _countBuffer = 0;
// random buffer
int _ranBuffer;
// 2. variate
for (int _iter = 0; _iter < _origin.Rhythm.NoteTime.Count; _iter++)
{
// check the item index
if (_origin.Rhythm.NoteTime[_iter] != 1)
{
_ranBuffer = random.Next() % 10;
_result.Rhythm.NoteTime[_iter] /= 2;
_result.Rhythm.NoteTime.Insert(_iter, _origin.Rhythm.NoteTime[_iter] / 2);
// tension : 30 %
if (_ranBuffer <= 2)
{
_result.Mellody.FullMellody.Insert(_iter,
_tension[_countBuffer / 8][random.Next() % _tension[_countBuffer / 8].Count]);
}
// chord tone : 70%
else
{
_result.Mellody.FullMellody.Insert(_iter,
_tone[_countBuffer / 8][random.Next() % _tone[_countBuffer / 8].Count]);
}
}
_countBuffer += _origin.Rhythm.NoteTime[_iter];
}
return(_result);
}
/// <summary>
/// Variate tail randomly
/// </summary>
/// <param name="_origin"></param>
/// <param name="_scale"></param>
/// <returns></returns>
Form VariateTail(Form _origin, ScaleNote _scale, int _baseOctave)
{
Form _result = new Form();
// avoid notes
List <List <Note> > _avoid;
// tension notes
List <List <Note> > _tension;
// chord tone notes
List <List <Note> > _tone;
// deep copy the form
_result.Copy(_origin);
// 1. make mellody tone list
_avoid = GetMellToneList(MellTone.Avoid, _origin, _scale);
_tension = GetMellToneList(MellTone.Tension, _origin, _scale);
_tone = GetMellToneList(MellTone.Tone, _origin, _scale);
int _octaveBuffer = 0;
// 2.1. specific tension list making
for (int _iter = 0; _iter < _tension.Count; _iter++)
{
_octaveBuffer = 0;
for (int _itt = 0; _itt < _tension[_iter].Count; _itt++)
{
if (_itt != _tension[_iter].Count - 1 && _tension[_iter][_itt] > _tension[_iter][_itt + 1])
{
_tension[_iter][_itt] = GetOctaveNote(_tension[_iter][_itt], _baseOctave + _octaveBuffer);
_octaveBuffer++;
continue;
}
_tension[_iter][_itt] = GetOctaveNote(_tension[_iter][_itt], _baseOctave + _octaveBuffer);
}
}
// 2.2. specific tone list making
for (int _iter = 0; _iter < _tone.Count; _iter++)
{
_octaveBuffer = 0;
for (int _itt = 0; _itt < _tone[_iter].Count; _itt++)
{
if (_itt != _tone[_iter].Count - 1 && _tone[_iter][_itt] > _tone[_iter][_itt + 1])
{
_tone[_iter][_itt] = GetOctaveNote(_tone[_iter][_itt], _baseOctave + _octaveBuffer);
_octaveBuffer++;
continue;
}
_tone[_iter][_itt] = GetOctaveNote(_tone[_iter][_itt], _baseOctave + _octaveBuffer);
}
}
// count buffer
int _countBuffer = 0;
// random buffer
int _ranBuffer;
// tail buffer
int _tailBuffer = 0;
// index buffer
int _indexBuffer = 0;
// 1. calculate full time
foreach (int _iter in _origin.Rhythm.NoteTime)
{
_tailBuffer += _iter;
}
// 75% of value
_tailBuffer = _tailBuffer - (_tailBuffer / 4);
// 2. variate
for (int _iter = 0; _iter < _origin.Rhythm.NoteTime.Count; _iter++)
{
// check the item time value
if (_countBuffer > _tailBuffer)
{
_indexBuffer = _iter;
break;
}
_countBuffer += _origin.Rhythm.NoteTime[_iter];
}
// reset mellodies
_result.Mellody.FullMellody.Clear();
// refresh count buffer
_countBuffer = 0;
// 3. make new mellody notes
for (int _iter = 0; _iter < _origin.Rhythm.NoteTime.Count; _iter++)
{
// check index : first 75% notes to be same / last 25% notes to be new
if (_iter < _indexBuffer)
{
_result.Mellody.FullMellody.Add(_origin.Mellody.FullMellody[_iter]);
}
else
{
_ranBuffer = random.Next() % 10;
// tension : 20 %
if (_ranBuffer < 0)
{
_result.Mellody.FullMellody.Add(_tension[_countBuffer / 8][random.Next() % _tension[_countBuffer / 8].Count]);
}
// chord tone : 70%
else
{
_result.Mellody.FullMellody.Add(_tone[_countBuffer / 8][random.Next() % _tone[_countBuffer / 8].Count]);
}
}
_countBuffer += _origin.Rhythm.NoteTime[_iter];
}
return(_result);
}
