OPL/py/oplparse.py

import sys
import json

REG_SCOPE = {
    0x00: 'Chip',
    0x20: '0x20',
    0x30: '0x20',
    0x40: '0x40',
    0x50: '0x40',
    0x60: 'Attack/decay',
    0x70: 'Attack/decay',
    0x80: 'Sustain/release',
    0x90: 'Sustain/release',
    0xA0: 'Frequency (L)',
    0xB0: 'Key on/off/Frequency(H)',
    0xE0: 'Wave select', 
    0xF0: 'Wave select',
}

# Map register ranges to channel + operator
OPERATOR_MAP = {
    0x00: (1, 1),
    0x01: (2, 1),
    0x02: (3, 1),
    0x03: (1, 2),
    0x04: (2, 2),
    0x05: (3, 2),
    0x08: (4, 1),
    0x09: (5, 1),
    0x0a: (6, 1),
    0x0b: (4, 2),
    0x0c: (4, 2),
    0x0d: (6, 2),
    0x10: (7, 1),
    0x11: (8, 1),
    0x12: (9, 1),
    0x13: (7, 2),
    0x14: (8, 2),
    0x15: (9, 2),
}
OSC_MAP = {1: 'mod', 2: 'car'}

def reg_to_chan_and_op(reg):
    # from REGOP in opl driver
    #return ( ( reg >> 3) & 0x20 ) | ( reg & 0x1f ) 
    chan, op = OPERATOR_MAP.get(reg % 32, (-1, 1))
    print 'ch%02d.%s: ' % (chan, OSC_MAP[op]),
    return chan, op

def interpret_00(reg, val, ev):
    regs = {1:'TEST', 2:'Timer 1', 3:'Timer 2', 4:'Timer Ctrl', 8:'CSM/keysplit'}
    print '%02X (%s)' % (reg, regs.get(reg, '??')),

def interpret_20(reg, val, ev):
    ch, op = reg_to_chan_and_op(reg)
    ev[2]['ch'] = ch
    bitfields = {7: 'tre', 6: 'vib', 5: 'sus', 4:'ksr'}
    bf = val & 0xf0
    opts = []
    for b, opt in bitfields.iteritems():
        optset = 'X' if (bf & (0x1 << b)) else '-'
        opts.append('%s:%s' % (opt, optset))
        ev[op-1][opt]=optset
    fm_mult = val & 0x0f
    mults = {0:0.5, 11:10, 13:12, 14:15}
    fm_mult = mults.get(fm_mult, fm_mult)
    opts.append('fm_mult:x%d' % (fm_mult))
    ev[op-1]['fm_mult'] = fm_mult
    print '; '.join(opts) ,

def _db_atten_to_factor(atten_db):
    return (10 ** -(atten_db / 10))

def interpret_40(reg, val, ev):
    ch, op = reg_to_chan_and_op(reg)
    ev[2]['ch'] = ch
    bit_db = {5:24, 4:12, 3:6, 2:3, 1:1.5, 0:0.75}
    oct_db = {0:0, 0x40:1.5, 0x80:3, 0xC0:6}
    lvl = 0.0
    for b, db in bit_db.iteritems():
        if (val & (0x1 << b)):
            lvl += db
    db_oct = oct_db[val & 0xC0]
    oct_scale = '-%d dB/8ve' % db_oct
    factor = _db_atten_to_factor(lvl)
    ev[op-1]['db'] = lvl
    ev[op-1]['db_oct'] = db_oct
    ev[op-1]['scale'] = factor
    print '%.2f dB; (x%.4f) %s' % (lvl, factor, oct_scale) ,  

def interpret_60(reg, val, ev):
    ch, op = reg_to_chan_and_op(reg)
    ev[2]['ch'] = ch
    a = val >> 4
    d = val & 0x0f
    ev[op-1]['a'] = a
    ev[op-1]['d'] = d
    print 'Att: 0x%1x; Dec: 0x%1x' % (a, d) ,
    
def interpret_80(reg, val, ev):
    ch, op = reg_to_chan_and_op(reg)
    ev[2]['ch'] = ch
    s = val >> 4
    r = val & 0x0f
    ev[op-1]['s'] = s
    ev[op-1]['r'] = r    
    print 'Sus: 0x%1x; Rel: 0x%1x' % (s, r) ,
    
def interpret_A0(reg, val, ev):
    global freq_lsb
    freq_lsb = val
    chan = 1 + reg % 0xA0
    print 'ch%02d:      Freq-LSB=%02X' % (chan, val) , 
    
def interpret_B0(reg, val, ev):
    global freq_lsb
    try:
        freq_lsb
    except NameError:
        freq_lsb = 0
    oct = (val >> 2) & 0x7
    fnum = ((val & 0x3) << 8) + freq_lsb
    chan = 1 + reg % 0xB0
    key = 'ON' if (1 << 5) & val else 'off'
    frq = _fnum_to_hz(fnum, oct)
    ev[1]['frq'] = frq
    ev[2]['key'] = key
    ev[2]['ch'] = chan
    #ev[0]['gate'] = key
    print 'ch%02d:      Key-%s; f0x%03X oct:%d (%.4f Hz)' % (chan, key, fnum, oct, frq) ,

'''
A0-A8: Frequency Number:

   Determines the pitch of the note. Highest bits of F-Number are stored
   in the register below.


B0-B8: Key On / Block Number / F-Number(hi bits):

   bit 5:    KEY-ON. When 1, channel output is enabled.
   bits 2-4: Block Number. Roughly determines the octave.
   bits 0-1: Frequency Number. 2 highest bits of the above register.

	     The following formula is used to determine F-Number and Block:

		F-Number = Music Frequency * 2^(20-Block) / 49716 Hz
'''

def _fnum_to_hz(fnum, octave):
    return (49716.0 * fnum) / (2 ** (21 - octave))
   
def interpret_BD(reg, val, ev):
    print '* BD' ,

def interpret_C0(reg, val, ev):
    alg = 'ADD' if val & 0x1 else 'MODULATE'
    feedback = (val >> 1) & 0xc
    ev[2]['alg'] = alg
    ev[2]['feedback'] = feedback
    print 'feedback: %d  algo: %s' % (feedback, alg) ,

def interpret_E0(reg, val, ev):
    ch, op = reg_to_chan_and_op(reg)
    ev[2]['ch'] = ch
    waves = {0: 'SIN', 1: 'HALFSIN', 2: 'ABSSIN', 3: 'QUARTSIN'}
    wav = waves[val & 0x3]
    ev[op-1]['wav'] = wav
    print wav ,

def interpret_write(ts, reg, val, ev):
    print '%10d : ' % ts,
    if reg >= 0x01 and reg <= 0x08:
        interpret_00(reg, val, ev)
    elif reg >= 0x20 and reg <= 0x35:
        interpret_20(reg, val, ev)
    elif reg >= 0x40 and reg <= 0x55:
        interpret_40(reg, val, ev)
    elif reg >= 0x60 and reg <= 0x75:
        interpret_60(reg, val, ev)
    elif reg >= 0x80 and reg <= 0x95:
        interpret_80(reg, val, ev)
    elif reg >= 0xA0 and reg <= 0xA8:
        interpret_A0(reg, val, ev)
    elif reg >= 0xB0 and reg <= 0xB8:
        interpret_B0(reg, val, ev)        
    elif reg == 0xBD:
        interpret_BD(reg, val, ev)
    elif reg >= 0xC0 and reg <= 0xC8:
        interpret_C0(reg, val, ev)
    elif reg >= 0xE0 and reg <= 0xF5:
        interpret_E0(reg, val, ev)
    else:
        print '?????', 
    print
        
    #scope = REG_SCOPE.get(reg & 0xF0, '??')
    #chan, operator = reg_to_chan_and_op(reg)
    #aprint '%10f : %02d.%1d : %02x : %20s' % (float(ts)/1000, chan, operator, val, scope)

def parse_opldump(stream):
    events = dict()
    t0 = tp = False
    line = stream.readline()
    while len(line) >= 1:
        ts, opl2, op = line.split(':')
        if 'OPL2' == opl2:
            ts = int(ts)
            if not t0:
                t0 = ts
            ts -= t0
            reg, val = op.split('=')
            reg = int(reg, 16)
            val = int(val, 16)
            try:
                ev = events[ts]
            except KeyError:
                ev = [dict(), dict(), dict()]
                events[ts] = ev            
            interpret_write(ts, reg, val, ev)
        line = stream.readline() 
    return events

def get_javascript_for(event):
    mod = event[0]
    car = event[1]
    anc = event[2]
    indent = 8*' '
    lines = []
    if 'ch' in anc:
        lines.append('var ch = opl2.channels[%d];\n' % (anc['ch'] - 1))
    if 'fm_mult' in car:
        lines.append('ch.setModulatorMultiplier(%d); ch.setCarrierMultiplier(%d);\n' % (mod['fm_mult'], car['fm_mult']))
    if 'scale' in car:
        lines.append('ch.setModulatorAttenuation(%f); ch.setCarrierAttenuation(%f);\n' % (mod['scale'], car['scale']))
    if 'a' in mod:
        lines.append('ch.setEnvParams(ch.modEnv, 1/%d, 1/%d, 1/%d, 1/%d);\n' % (mod['a'], mod['d'], mod['s']+1, mod['r']))
    if 'a' in car:
        lines.append('ch.setEnvParams(ch.carEnv, 1/%d, 1/%d, 1/%d, 1/%d);\n' % (car['a'], car['d'], car['s']+1, car['r']))
    if 'wav' in car:
        lines.append('ch.setCarrierWaveform(ch.%s); ch.setModulatorWaveform(ch.%s);\n' % (car['wav'], mod['wav']))
    if 'key' in anc:
        if 'ON' == anc['key'].upper():
            lines.append('ch.noteOn(%f);\n' % car['frq'])
        elif 'OFF' == anc['key'].upper():
            lines.append('ch.noteOff();\n')
    return indent + indent.join(lines)
        
    
def find_unique_instruments(events):
    instruments = dict()
    ilist = list()
    timestamps = events.keys()
    timestamps.sort()
    for t in timestamps:
        ev = events[t]
        try:     # get rid of fields which don't define uniqueness
            del ev[2]['key']
            del ev[2]['ch']
            del ev[1]['frq']
        except KeyError:
            pass
        instr_json = json.dumps(ev, indent=2)
        if instr_json not in instruments:
            instruments[instr_json] = t
            ilist.append(instr_json)
    return ilist, instruments

def print_instrument(json_i, ts):
    print
    print '@ %10d:' % ts
    try:
        d = json.loads(json_i)
        print 'Waveforms: %10s%10s' % (d[0]['wav'], d[1]['wav'])
        print 'Freq mult: %9dx%9dx' % (d[0]['fm_mult'], d[1]['fm_mult'])
        print 'Levels:    %7d dB%7d dB' % (-d[0]['db'], -d[1]['db'])
        envs = (d[0]['a'], d[0]['d'], d[0]['s'], d[0]['r'], d[1]['a'], d[1]['d'], d[1]['s'], d[1]['r'])
        print 'Envelopes:    %1x %1x %1x %1x    %1x %1x %1x %1x' % envs
    except KeyError:
        print 'incomplete instrument?'

# Conversions mapping to VST floating point values
W2F = {'SIN':0, 'HALFSIN':.33, 'ABSSIN':.66, 'QUARTSIN':1}
def m2f(mult):
    if mult < 1:  # half frq
        return 0
    else:
        return float(mult)/15.0

def a2f(att_db):
    a = float(att_db)/0.75
    return a/63.0

def b2f(bool_param):
    if 'X' == bool_param:
        return 1.0
    else:
        return 0.0
D2F = {0:0.0,1.5:0.33,3.0:0.66,6.0:1.0}

def e2f(env_val):
    return float(env_val)/15.0

def output_instrument_vst_program(json_i, ts):
    try:
        d = json.loads(json_i)
        m=d[0]; c=d[1]
        lines = [
            '    const float i_params_%d[] = {' % ts,
            '        %.6ff, %.6ff,  // waveforms' % (W2F[c['wav']], W2F[m['wav']]),
            '        %.6ff, %.6ff,  // frq multipliers' % (m2f(c['fm_mult']), m2f(m['fm_mult'])),
            '        %.6ff, %.6ff,  // attenuation' %     (a2f(c['db']), a2f(m['db'])),
            '        %.1ff, %.1ff, %.1ff, %.1ff,  // tre / vib / sus / ks' % tuple([b2f(c[x]) for x in ['tre', 'vib', 'sus', 'ksr']]),
            '        %.1ff, %.1ff, %.1ff, %.1ff,  // tre / vib / sus / ks' % tuple([b2f(m[x]) for x in ['tre', 'vib', 'sus', 'ksr']]),
            '        %.6ff, %.6ff,  // KSR/8ve' % (D2F[c['db_oct']], D2F[m['db_oct']]),
            '        %.6ff,            // algorithm' % (1.0 if 'ADD'==d[2]['alg'] else 0.0),
            '        %.6ff,            // feedback' % (float(d[2]['feedback'])/7.0),
            '        %.1ff, %.1ff, %.1ff, %.1ff,  // adsr' % tuple([e2f(c[x]) for x in ['a', 'd', 's', 'r']]),
            '        %.1ff, %.1ff, %.1ff, %.1ff,  // adsr' % tuple([e2f(m[x]) for x in ['a', 'd', 's', 'r']]),
            '    };',
            '    std::vector<float> v_i_params_%d (i_params_%d, i_params_%d + sizeof(i_params_%d) / sizeof(float));' % (ts,ts,ts,ts),
            '    programs["Instr %d"] = std::vector<float>(v_i_params_%d);' % (ts, ts),
        ]
        print
        print '\n'.join(lines)
    except KeyError:
        pass
        #print
        #print '// incomplete instrument..'

def main(argv):
    events = parse_opldump(sys.stdin)
    ilist, instruments = find_unique_instruments(events)
    for i in ilist:
        output_instrument_vst_program(i, instruments[i])
        #print i, instruments[i]
        #print_instrument(i, instruments[i])

if '__main__' == __name__:
    main(sys.argv)
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`import sys`
			`import json`

			`REG_SCOPE = {`
			`0x00: 'Chip',`
			`0x20: '0x20',`
			`0x30: '0x20',`
			`0x40: '0x40',`
			`0x50: '0x40',`
			`0x60: 'Attack/decay',`
			`0x70: 'Attack/decay',`
			`0x80: 'Sustain/release',`
			`0x90: 'Sustain/release',`
			`0xA0: 'Frequency (L)',`
			`0xB0: 'Key on/off/Frequency(H)',`
			`0xE0: 'Wave select',`
			`0xF0: 'Wave select',`
			`}`

			`# Map register ranges to channel + operator`
			`OPERATOR_MAP = {`
			`0x00: (1, 1),`
			`0x01: (2, 1),`
			`0x02: (3, 1),`
			`0x03: (1, 2),`
			`0x04: (2, 2),`
			`0x05: (3, 2),`
			`0x08: (4, 1),`
			`0x09: (5, 1),`
			`0x0a: (6, 1),`
			`0x0b: (4, 2),`
			`0x0c: (4, 2),`
			`0x0d: (6, 2),`
			`0x10: (7, 1),`
			`0x11: (8, 1),`
			`0x12: (9, 1),`
			`0x13: (7, 2),`
			`0x14: (8, 2),`
			`0x15: (9, 2),`
			`}`
			`OSC_MAP = {1: 'mod', 2: 'car'}`

			`def reg_to_chan_and_op(reg):`
			`# from REGOP in opl driver`
			`#return ( ( reg >> 3) & 0x20 ) \| ( reg & 0x1f )`
			`chan, op = OPERATOR_MAP.get(reg % 32, (-1, 1))`
			`print 'ch%02d.%s: ' % (chan, OSC_MAP[op]),`
			`return chan, op`

			`def interpret_00(reg, val, ev):`
			`regs = {1:'TEST', 2:'Timer 1', 3:'Timer 2', 4:'Timer Ctrl', 8:'CSM/keysplit'}`
			`print '%02X (%s)' % (reg, regs.get(reg, '??')),`

			`def interpret_20(reg, val, ev):`
			`ch, op = reg_to_chan_and_op(reg)`
			`ev[2]['ch'] = ch`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`bitfields = {7: 'tre', 6: 'vib', 5: 'sus', 4:'ksr'}`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`bf = val & 0xf0`
			`opts = []`
			`for b, opt in bitfields.iteritems():`
			`optset = 'X' if (bf & (0x1 << b)) else '-'`
			`opts.append('%s:%s' % (opt, optset))`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`ev[op-1][opt]=optset`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`fm_mult = val & 0x0f`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`mults = {0:0.5, 11:10, 13:12, 14:15}`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`fm_mult = mults.get(fm_mult, fm_mult)`
			`opts.append('fm_mult:x%d' % (fm_mult))`
			`ev[op-1]['fm_mult'] = fm_mult`
			`print '; '.join(opts) ,`

			`def _db_atten_to_factor(atten_db):`
			`return (10 ** -(atten_db / 10))`

			`def interpret_40(reg, val, ev):`
			`ch, op = reg_to_chan_and_op(reg)`
			`ev[2]['ch'] = ch`
			`bit_db = {5:24, 4:12, 3:6, 2:3, 1:1.5, 0:0.75}`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`oct_db = {0:0, 0x40:1.5, 0x80:3, 0xC0:6}`
			`lvl = 0.0`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`for b, db in bit_db.iteritems():`
			`if (val & (0x1 << b)):`
			`lvl += db`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`db_oct = oct_db[val & 0xC0]`
			`oct_scale = '-%d dB/8ve' % db_oct`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`factor = _db_atten_to_factor(lvl)`
			`ev[op-1]['db'] = lvl`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`ev[op-1]['db_oct'] = db_oct`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`ev[op-1]['scale'] = factor`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`print '%.2f dB; (x%.4f) %s' % (lvl, factor, oct_scale) ,`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00
			`def interpret_60(reg, val, ev):`
			`ch, op = reg_to_chan_and_op(reg)`
			`ev[2]['ch'] = ch`
			`a = val >> 4`
			`d = val & 0x0f`
			`ev[op-1]['a'] = a`
			`ev[op-1]['d'] = d`
			`print 'Att: 0x%1x; Dec: 0x%1x' % (a, d) ,`

			`def interpret_80(reg, val, ev):`
			`ch, op = reg_to_chan_and_op(reg)`
			`ev[2]['ch'] = ch`
			`s = val >> 4`
			`r = val & 0x0f`
			`ev[op-1]['s'] = s`
			`ev[op-1]['r'] = r`
			`print 'Sus: 0x%1x; Rel: 0x%1x' % (s, r) ,`

			`def interpret_A0(reg, val, ev):`
			`global freq_lsb`
			`freq_lsb = val`
			`chan = 1 + reg % 0xA0`
			`print 'ch%02d: Freq-LSB=%02X' % (chan, val) ,`

			`def interpret_B0(reg, val, ev):`
			`global freq_lsb`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`try:`
			`freq_lsb`
			`except NameError:`
			`freq_lsb = 0`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`oct = (val >> 2) & 0x7`
			`fnum = ((val & 0x3) << 8) + freq_lsb`
			`chan = 1 + reg % 0xB0`
			`key = 'ON' if (1 << 5) & val else 'off'`
			`frq = _fnum_to_hz(fnum, oct)`
			`ev[1]['frq'] = frq`
			`ev[2]['key'] = key`
			`ev[2]['ch'] = chan`
			`#ev[0]['gate'] = key`
			`print 'ch%02d: Key-%s; f0x%03X oct:%d (%.4f Hz)' % (chan, key, fnum, oct, frq) ,`

			`'''`
			`A0-A8: Frequency Number:`

			`Determines the pitch of the note. Highest bits of F-Number are stored`
			`in the register below.`


			`B0-B8: Key On / Block Number / F-Number(hi bits):`

			`bit 5: KEY-ON. When 1, channel output is enabled.`
			`bits 2-4: Block Number. Roughly determines the octave.`
			`bits 0-1: Frequency Number. 2 highest bits of the above register.`

			`The following formula is used to determine F-Number and Block:`

			`F-Number = Music Frequency * 2^(20-Block) / 49716 Hz`
			`'''`

			`def _fnum_to_hz(fnum, octave):`
			`return (49716.0 * fnum) / (2 ** (21 - octave))`

			`def interpret_BD(reg, val, ev):`
			`print '* BD' ,`

			`def interpret_C0(reg, val, ev):`
			`alg = 'ADD' if val & 0x1 else 'MODULATE'`
			`feedback = (val >> 1) & 0xc`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`ev[2]['alg'] = alg`
			`ev[2]['feedback'] = feedback`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`print 'feedback: %d algo: %s' % (feedback, alg) ,`

			`def interpret_E0(reg, val, ev):`
			`ch, op = reg_to_chan_and_op(reg)`
			`ev[2]['ch'] = ch`
			`waves = {0: 'SIN', 1: 'HALFSIN', 2: 'ABSSIN', 3: 'QUARTSIN'}`
			`wav = waves[val & 0x3]`
			`ev[op-1]['wav'] = wav`
			`print wav ,`

			`def interpret_write(ts, reg, val, ev):`
			`print '%10d : ' % ts,`
			`if reg >= 0x01 and reg <= 0x08:`
			`interpret_00(reg, val, ev)`
			`elif reg >= 0x20 and reg <= 0x35:`
			`interpret_20(reg, val, ev)`
			`elif reg >= 0x40 and reg <= 0x55:`
			`interpret_40(reg, val, ev)`
			`elif reg >= 0x60 and reg <= 0x75:`
			`interpret_60(reg, val, ev)`
			`elif reg >= 0x80 and reg <= 0x95:`
			`interpret_80(reg, val, ev)`
			`elif reg >= 0xA0 and reg <= 0xA8:`
			`interpret_A0(reg, val, ev)`
			`elif reg >= 0xB0 and reg <= 0xB8:`
			`interpret_B0(reg, val, ev)`
			`elif reg == 0xBD:`
			`interpret_BD(reg, val, ev)`
			`elif reg >= 0xC0 and reg <= 0xC8:`
			`interpret_C0(reg, val, ev)`
			`elif reg >= 0xE0 and reg <= 0xF5:`
			`interpret_E0(reg, val, ev)`
			`else:`
			`print '?????',`
			`print`

			`#scope = REG_SCOPE.get(reg & 0xF0, '??')`
			`#chan, operator = reg_to_chan_and_op(reg)`
			`#aprint '%10f : %02d.%1d : %02x : %20s' % (float(ts)/1000, chan, operator, val, scope)`

			`def parse_opldump(stream):`
			`events = dict()`
			`t0 = tp = False`
			`line = stream.readline()`
			`while len(line) >= 1:`
			`ts, opl2, op = line.split(':')`
			`if 'OPL2' == opl2:`
			`ts = int(ts)`
			`if not t0:`
			`t0 = ts`
			`ts -= t0`
			`reg, val = op.split('=')`
			`reg = int(reg, 16)`
			`val = int(val, 16)`
			`try:`
			`ev = events[ts]`
			`except KeyError:`
			`ev = [dict(), dict(), dict()]`
			`events[ts] = ev`
			`interpret_write(ts, reg, val, ev)`
			`line = stream.readline()`
			`return events`

			`def get_javascript_for(event):`
			`mod = event[0]`
			`car = event[1]`
			`anc = event[2]`
			`indent = 8*' '`
			`lines = []`
			`if 'ch' in anc:`
			`lines.append('var ch = opl2.channels[%d];\n' % (anc['ch'] - 1))`
			`if 'fm_mult' in car:`
			`lines.append('ch.setModulatorMultiplier(%d); ch.setCarrierMultiplier(%d);\n' % (mod['fm_mult'], car['fm_mult']))`
			`if 'scale' in car:`
			`lines.append('ch.setModulatorAttenuation(%f); ch.setCarrierAttenuation(%f);\n' % (mod['scale'], car['scale']))`
			`if 'a' in mod:`
			`lines.append('ch.setEnvParams(ch.modEnv, 1/%d, 1/%d, 1/%d, 1/%d);\n' % (mod['a'], mod['d'], mod['s']+1, mod['r']))`
			`if 'a' in car:`
			`lines.append('ch.setEnvParams(ch.carEnv, 1/%d, 1/%d, 1/%d, 1/%d);\n' % (car['a'], car['d'], car['s']+1, car['r']))`
			`if 'wav' in car:`
			`lines.append('ch.setCarrierWaveform(ch.%s); ch.setModulatorWaveform(ch.%s);\n' % (car['wav'], mod['wav']))`
			`if 'key' in anc:`
			`if 'ON' == anc['key'].upper():`
			`lines.append('ch.noteOn(%f);\n' % car['frq'])`
			`elif 'OFF' == anc['key'].upper():`
			`lines.append('ch.noteOff();\n')`
			`return indent + indent.join(lines)`


Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`def find_unique_instruments(events):`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`instruments = dict()`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`ilist = list()`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`timestamps = events.keys()`
			`timestamps.sort()`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`for t in timestamps:`
			`ev = events[t]`
			`try: # get rid of fields which don't define uniqueness`
			`del ev[2]['key']`
			`del ev[2]['ch']`
			`del ev[1]['frq']`
			`except KeyError:`
			`pass`
			`instr_json = json.dumps(ev, indent=2)`
			`if instr_json not in instruments:`
			`instruments[instr_json] = t`
			`ilist.append(instr_json)`
			`return ilist, instruments`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00
			`def print_instrument(json_i, ts):`
			`print`
			`print '@ %10d:' % ts`
			`try:`
			`d = json.loads(json_i)`
			`print 'Waveforms: %10s%10s' % (d[0]['wav'], d[1]['wav'])`
			`print 'Freq mult: %9dx%9dx' % (d[0]['fm_mult'], d[1]['fm_mult'])`
			`print 'Levels: %7d dB%7d dB' % (-d[0]['db'], -d[1]['db'])`
			`envs = (d[0]['a'], d[0]['d'], d[0]['s'], d[0]['r'], d[1]['a'], d[1]['d'], d[1]['s'], d[1]['r'])`
			`print 'Envelopes: %1x %1x %1x %1x %1x %1x %1x %1x' % envs`
			`except KeyError:`
			`print 'incomplete instrument?'`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00
			`# Conversions mapping to VST floating point values`
			`W2F = {'SIN':0, 'HALFSIN':.33, 'ABSSIN':.66, 'QUARTSIN':1}`
			`def m2f(mult):`
			`if mult < 1: # half frq`
			`return 0`
			`else:`
			`return float(mult)/15.0`

			`def a2f(att_db):`
			`a = float(att_db)/0.75`
			`return a/63.0`

			`def b2f(bool_param):`
			`if 'X' == bool_param:`
			`return 1.0`
			`else:`
			`return 0.0`
			`D2F = {0:0.0,1.5:0.33,3.0:0.66,6.0:1.0}`

			`def e2f(env_val):`
			`return float(env_val)/15.0`

			`def output_instrument_vst_program(json_i, ts):`
			`try:`
			`d = json.loads(json_i)`
			`m=d[0]; c=d[1]`
Improve instrument ripper C++ output and add some instruments from Dune 2. 2013-09-14 16:47:55 +00:00			`lines = [`
			`' const float i_params_%d[] = {' % ts,`
			`' %.6ff, %.6ff, // waveforms' % (W2F[c['wav']], W2F[m['wav']]),`
			`' %.6ff, %.6ff, // frq multipliers' % (m2f(c['fm_mult']), m2f(m['fm_mult'])),`
			`' %.6ff, %.6ff, // attenuation' % (a2f(c['db']), a2f(m['db'])),`
			`' %.1ff, %.1ff, %.1ff, %.1ff, // tre / vib / sus / ks' % tuple([b2f(c[x]) for x in ['tre', 'vib', 'sus', 'ksr']]),`
			`' %.1ff, %.1ff, %.1ff, %.1ff, // tre / vib / sus / ks' % tuple([b2f(m[x]) for x in ['tre', 'vib', 'sus', 'ksr']]),`
			`' %.6ff, %.6ff, // KSR/8ve' % (D2F[c['db_oct']], D2F[m['db_oct']]),`
			`' %.6ff, // algorithm' % (1.0 if 'ADD'==d[2]['alg'] else 0.0),`
			`' %.6ff, // feedback' % (float(d[2]['feedback'])/7.0),`
			`' %.1ff, %.1ff, %.1ff, %.1ff, // adsr' % tuple([e2f(c[x]) for x in ['a', 'd', 's', 'r']]),`
			`' %.1ff, %.1ff, %.1ff, %.1ff, // adsr' % tuple([e2f(m[x]) for x in ['a', 'd', 's', 'r']]),`
			`' };',`
			`' std::vector<float> v_i_params_%d (i_params_%d, i_params_%d + sizeof(i_params_%d) / sizeof(float));' % (ts,ts,ts,ts),`
			`' programs["Instr %d"] = std::vector<float>(v_i_params_%d);' % (ts, ts),`
			`]`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`print`
Improve instrument ripper C++ output and add some instruments from Dune 2. 2013-09-14 16:47:55 +00:00			`print '\n'.join(lines)`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`except KeyError:`
Improve instrument ripper C++ output and add some instruments from Dune 2. 2013-09-14 16:47:55 +00:00			`pass`
			`#print`
			`#print '// incomplete instrument..'`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00			`def main(argv):`
			`events = parse_opldump(sys.stdin)`
Fix bugs in parsing script, output C++ code for instrument programs extracted. 2013-09-14 16:07:21 +00:00			`ilist, instruments = find_unique_instruments(events)`
			`for i in ilist:`
			`output_instrument_vst_program(i, instruments[i])`
			`#print i, instruments[i]`
			`#print_instrument(i, instruments[i])`
Add raw OPL output parser script. 2013-09-13 18:04:31 +00:00
			`if '__main__' == __name__:`
			`main(sys.argv)`