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r'''#=================================================================================================================== | |
# | |
# MIDI to Colab AUdio Python Module | |
# | |
# Converts any MIDI file to raw audio which is compatible | |
# with Google Colab or HUgging Face Gradio | |
# | |
# Version 1.0 | |
# | |
# Includes full source code of MIDI, pyfluidsynth, and midi_synthesizer Python modules | |
# | |
# Original source code for all modules was retrieved on 10/23/2023 | |
# | |
# Project Los Angeles | |
# Tegridy Code 2023 | |
# | |
#=================================================================================================================== | |
# | |
# Critical dependencies | |
# | |
# pip install numpy | |
# sudo apt install fluidsynth | |
# | |
#=================================================================================================================== | |
# | |
# Example usage: | |
# | |
# from midi_to_colab_audio import midi_to_colab_audio | |
# from IPython.display import display, Audio | |
# | |
# raw_audio = midi_to_colab_audio('/content/input.mid') | |
# | |
# display(Audio(raw_audio, rate=16000, normalize=False)) | |
# | |
#=================================================================================================================== | |
#! /usr/bin/python3 | |
# unsupported 20091104 ... | |
# ['set_sequence_number', dtime, sequence] | |
# ['raw_data', dtime, raw] | |
# 20150914 jimbo1qaz MIDI.py str/bytes bug report | |
# I found a MIDI file which had Shift-JIS titles. When midi.py decodes it as | |
# latin-1, it produces a string which cannot even be accessed without raising | |
# a UnicodeDecodeError. Maybe, when converting raw byte strings from MIDI, | |
# you should keep them as bytes, not improperly decode them. However, this | |
# would change the API. (ie: text = a "string" ? of 0 or more bytes). It | |
# could break compatiblity, but there's not much else you can do to fix the bug | |
# https://en.wikipedia.org/wiki/Shift_JIS | |
This module offers functions: concatenate_scores(), grep(), | |
merge_scores(), mix_scores(), midi2opus(), midi2score(), opus2midi(), | |
opus2score(), play_score(), score2midi(), score2opus(), score2stats(), | |
score_type(), segment(), timeshift() and to_millisecs(), | |
where "midi" means the MIDI-file bytes (as can be put in a .mid file, | |
or piped into aplaymidi), and "opus" and "score" are list-structures | |
as inspired by Sean Burke's MIDI-Perl CPAN module. | |
Warning: Version 6.4 is not necessarily backward-compatible with | |
previous versions, in that text-data is now bytes, not strings. | |
This reflects the fact that many MIDI files have text data in | |
encodings other that ISO-8859-1, for example in Shift-JIS. | |
Download MIDI.py from http://www.pjb.com.au/midi/free/MIDI.py | |
and put it in your PYTHONPATH. MIDI.py depends on Python3. | |
There is also a call-compatible translation into Lua of this | |
module: see http://www.pjb.com.au/comp/lua/MIDI.html | |
Backup web site: https://peterbillam.gitlab.io/miditools/ | |
The "opus" is a direct translation of the midi-file-events, where | |
the times are delta-times, in ticks, since the previous event. | |
The "score" is more human-centric; it uses absolute times, and | |
combines the separate note_on and note_off events into one "note" | |
event, with a duration: | |
['note', start_time, duration, channel, note, velocity] # in a "score" | |
EVENTS (in an "opus" structure) | |
['note_off', dtime, channel, note, velocity] # in an "opus" | |
['note_on', dtime, channel, note, velocity] # in an "opus" | |
['key_after_touch', dtime, channel, note, velocity] | |
['control_change', dtime, channel, controller(0-127), value(0-127)] | |
['patch_change', dtime, channel, patch] | |
['channel_after_touch', dtime, channel, velocity] | |
['pitch_wheel_change', dtime, channel, pitch_wheel] | |
['text_event', dtime, text] | |
['copyright_text_event', dtime, text] | |
['track_name', dtime, text] | |
['instrument_name', dtime, text] | |
['lyric', dtime, text] | |
['marker', dtime, text] | |
['cue_point', dtime, text] | |
['text_event_08', dtime, text] | |
['text_event_09', dtime, text] | |
['text_event_0a', dtime, text] | |
['text_event_0b', dtime, text] | |
['text_event_0c', dtime, text] | |
['text_event_0d', dtime, text] | |
['text_event_0e', dtime, text] | |
['text_event_0f', dtime, text] | |
['end_track', dtime] | |
['set_tempo', dtime, tempo] | |
['smpte_offset', dtime, hr, mn, se, fr, ff] | |
['time_signature', dtime, nn, dd, cc, bb] | |
['key_signature', dtime, sf, mi] | |
['sequencer_specific', dtime, raw] | |
['raw_meta_event', dtime, command(0-255), raw] | |
['sysex_f0', dtime, raw] | |
['sysex_f7', dtime, raw] | |
['song_position', dtime, song_pos] | |
['song_select', dtime, song_number] | |
['tune_request', dtime] | |
DATA TYPES | |
channel = a value 0 to 15 | |
controller = 0 to 127 (see http://www.pjb.com.au/muscript/gm.html#cc ) | |
dtime = time measured in "ticks", 0 to 268435455 | |
velocity = a value 0 (soft) to 127 (loud) | |
note = a value 0 to 127 (middle-C is 60) | |
patch = 0 to 127 (see http://www.pjb.com.au/muscript/gm.html ) | |
pitch_wheel = a value -8192 to 8191 (0x1FFF) | |
raw = bytes, of length 0 or more (for sysex events see below) | |
sequence_number = a value 0 to 65,535 (0xFFFF) | |
song_pos = a value 0 to 16,383 (0x3FFF) | |
song_number = a value 0 to 127 | |
tempo = microseconds per crochet (quarter-note), 0 to 16777215 | |
text = bytes, of length 0 or more | |
ticks = the number of ticks per crochet (quarter-note) | |
In sysex_f0 events, the raw data must not start with a \xF0 byte, | |
since this gets added automatically; | |
but it must end with an explicit \xF7 byte! | |
In the very unlikely case that you ever need to split sysex data | |
into one sysex_f0 followed by one or more sysex_f7s, then only the | |
last of those sysex_f7 events must end with the explicit \xF7 byte | |
(again, the raw data of individual sysex_f7 events must not start | |
with any \xF7 byte, since this gets added automatically). | |
Since version 6.4, text data is in bytes, not in a ISO-8859-1 string. | |
GOING THROUGH A SCORE WITHIN A PYTHON PROGRAM | |
channels = {2,3,5,8,13} | |
itrack = 1 # skip 1st element which is ticks | |
while itrack < len(score): | |
for event in score[itrack]: | |
if event[0] == 'note': # for example, | |
pass # do something to all notes | |
# or, to work on events in only particular channels... | |
channel_index = MIDI.Event2channelindex.get(event[0], False) | |
if channel_index and (event[channel_index] in channels): | |
pass # do something to channels 2,3,5,8 and 13 | |
itrack += 1 | |
''' | |
import sys, struct, copy | |
# sys.stdout = os.fdopen(sys.stdout.fileno(), 'wb') | |
Version = '6.7' | |
VersionDate = '20201120' | |
# 20201120 6.7 call to bytest() removed, and protect _unshift_ber_int | |
# 20160702 6.6 to_millisecs() now handles set_tempo across multiple Tracks | |
# 20150921 6.5 segment restores controllers as well as patch and tempo | |
# 20150914 6.4 text data is bytes or bytearray, not ISO-8859-1 strings | |
# 20150628 6.3 absent any set_tempo, default is 120bpm (see MIDI file spec 1.1) | |
# 20150101 6.2 all text events can be 8-bit; let user get the right encoding | |
# 20141231 6.1 fix _some_text_event; sequencer_specific data can be 8-bit | |
# 20141230 6.0 synth_specific data can be 8-bit | |
# 20120504 5.9 add the contents of mid_opus_tracks() | |
# 20120208 5.8 fix num_notes_by_channel() ; should be a dict | |
# 20120129 5.7 _encode handles empty tracks; score2stats num_notes_by_channel | |
# 20111111 5.6 fix patch 45 and 46 in Number2patch, should be Harp | |
# 20110129 5.5 add mix_opus_tracks() and event2alsaseq() | |
# 20110126 5.4 "previous message repeated N times" to save space on stderr | |
# 20110125 5.2 opus2score terminates unended notes at the end of the track | |
# 20110124 5.1 the warnings in midi2opus display track_num | |
# 21110122 5.0 if garbage, midi2opus returns the opus so far | |
# 21110119 4.9 non-ascii chars stripped out of the text_events | |
# 21110110 4.8 note_on with velocity=0 treated as a note-off | |
# 21110108 4.6 unknown F-series event correctly eats just one byte | |
# 21011010 4.2 segment() uses start_time, end_time named params | |
# 21011005 4.1 timeshift() must not pad the set_tempo command | |
# 21011003 4.0 pitch2note_event must be chapitch2note_event | |
# 21010918 3.9 set_sequence_number supported, FWIW | |
# 20100913 3.7 many small bugfixes; passes all tests | |
# 20100910 3.6 concatenate_scores enforce ticks=1000, just like merge_scores | |
# 20100908 3.5 minor bugs fixed in score2stats | |
# 20091104 3.4 tune_request now supported | |
# 20091104 3.3 fixed bug in decoding song_position and song_select | |
# 20091104 3.2 unsupported: set_sequence_number tune_request raw_data | |
# 20091101 3.1 document how to traverse a score within Python | |
# 20091021 3.0 fixed bug in score2stats detecting GM-mode = 0 | |
# 20091020 2.9 score2stats reports GM-mode and bank msb,lsb events | |
# 20091019 2.8 in merge_scores, channel 9 must remain channel 9 (in GM) | |
# 20091018 2.7 handles empty tracks gracefully | |
# 20091015 2.6 grep() selects channels | |
# 20091010 2.5 merge_scores reassigns channels to avoid conflicts | |
# 20091010 2.4 fixed bug in to_millisecs which now only does opusses | |
# 20091010 2.3 score2stats returns channels & patch_changes, by_track & total | |
# 20091010 2.2 score2stats() returns also pitches and percussion dicts | |
# 20091010 2.1 bugs: >= not > in segment, to notice patch_change at time 0 | |
# 20091010 2.0 bugs: spurious pop(0) ( in _decode sysex | |
# 20091008 1.9 bugs: ISO decoding in sysex; str( not int( in note-off warning | |
# 20091008 1.8 add concatenate_scores() | |
# 20091006 1.7 score2stats() measures nticks and ticks_per_quarter | |
# 20091004 1.6 first mix_scores() and merge_scores() | |
# 20090424 1.5 timeshift() bugfix: earliest only sees events after from_time | |
# 20090330 1.4 timeshift() has also a from_time argument | |
# 20090322 1.3 timeshift() has also a start_time argument | |
# 20090319 1.2 add segment() and timeshift() | |
# 20090301 1.1 add to_millisecs() | |
_previous_warning = '' # 5.4 | |
_previous_times = 0 # 5.4 | |
#------------------------------- Encoding stuff -------------------------- | |
def opus2midi(opus=[]): | |
r'''The argument is a list: the first item in the list is the "ticks" | |
parameter, the others are the tracks. Each track is a list | |
of midi-events, and each event is itself a list; see above. | |
opus2midi() returns a bytestring of the MIDI, which can then be | |
written either to a file opened in binary mode (mode='wb'), | |
or to stdout by means of: sys.stdout.buffer.write() | |
my_opus = [ | |
96, | |
[ # track 0: | |
['patch_change', 0, 1, 8], # and these are the events... | |
['note_on', 5, 1, 25, 96], | |
['note_off', 96, 1, 25, 0], | |
['note_on', 0, 1, 29, 96], | |
['note_off', 96, 1, 29, 0], | |
], # end of track 0 | |
] | |
my_midi = opus2midi(my_opus) | |
sys.stdout.buffer.write(my_midi) | |
''' | |
if len(opus) < 2: | |
opus=[1000, [],] | |
tracks = copy.deepcopy(opus) | |
ticks = int(tracks.pop(0)) | |
ntracks = len(tracks) | |
if ntracks == 1: | |
format = 0 | |
else: | |
format = 1 | |
my_midi = b"MThd\x00\x00\x00\x06"+struct.pack('>HHH',format,ntracks,ticks) | |
for track in tracks: | |
events = _encode(track) | |
my_midi += b'MTrk' + struct.pack('>I',len(events)) + events | |
_clean_up_warnings() | |
return my_midi | |
def score2opus(score=None): | |
r''' | |
The argument is a list: the first item in the list is the "ticks" | |
parameter, the others are the tracks. Each track is a list | |
of score-events, and each event is itself a list. A score-event | |
is similar to an opus-event (see above), except that in a score: | |
1) the times are expressed as an absolute number of ticks | |
from the track's start time | |
2) the pairs of 'note_on' and 'note_off' events in an "opus" | |
are abstracted into a single 'note' event in a "score": | |
['note', start_time, duration, channel, pitch, velocity] | |
score2opus() returns a list specifying the equivalent "opus". | |
my_score = [ | |
96, | |
[ # track 0: | |
['patch_change', 0, 1, 8], | |
['note', 5, 96, 1, 25, 96], | |
['note', 101, 96, 1, 29, 96] | |
], # end of track 0 | |
] | |
my_opus = score2opus(my_score) | |
''' | |
if len(score) < 2: | |
score=[1000, [],] | |
tracks = copy.deepcopy(score) | |
ticks = int(tracks.pop(0)) | |
opus_tracks = [] | |
for scoretrack in tracks: | |
time2events = dict([]) | |
for scoreevent in scoretrack: | |
if scoreevent[0] == 'note': | |
note_on_event = ['note_on',scoreevent[1], | |
scoreevent[3],scoreevent[4],scoreevent[5]] | |
note_off_event = ['note_off',scoreevent[1]+scoreevent[2], | |
scoreevent[3],scoreevent[4],scoreevent[5]] | |
if time2events.get(note_on_event[1]): | |
time2events[note_on_event[1]].append(note_on_event) | |
else: | |
time2events[note_on_event[1]] = [note_on_event,] | |
if time2events.get(note_off_event[1]): | |
time2events[note_off_event[1]].append(note_off_event) | |
else: | |
time2events[note_off_event[1]] = [note_off_event,] | |
continue | |
if time2events.get(scoreevent[1]): | |
time2events[scoreevent[1]].append(scoreevent) | |
else: | |
time2events[scoreevent[1]] = [scoreevent,] | |
sorted_times = [] # list of keys | |
for k in time2events.keys(): | |
sorted_times.append(k) | |
sorted_times.sort() | |
sorted_events = [] # once-flattened list of values sorted by key | |
for time in sorted_times: | |
sorted_events.extend(time2events[time]) | |
abs_time = 0 | |
for event in sorted_events: # convert abs times => delta times | |
delta_time = event[1] - abs_time | |
abs_time = event[1] | |
event[1] = delta_time | |
opus_tracks.append(sorted_events) | |
opus_tracks.insert(0,ticks) | |
_clean_up_warnings() | |
return opus_tracks | |
def score2midi(score=None): | |
r''' | |
Translates a "score" into MIDI, using score2opus() then opus2midi() | |
''' | |
return opus2midi(score2opus(score)) | |
#--------------------------- Decoding stuff ------------------------ | |
def midi2opus(midi=b''): | |
r'''Translates MIDI into a "opus". For a description of the | |
"opus" format, see opus2midi() | |
''' | |
my_midi=bytearray(midi) | |
if len(my_midi) < 4: | |
_clean_up_warnings() | |
return [1000,[],] | |
id = bytes(my_midi[0:4]) | |
if id != b'MThd': | |
_warn("midi2opus: midi starts with "+str(id)+" instead of 'MThd'") | |
_clean_up_warnings() | |
return [1000,[],] | |
[length, format, tracks_expected, ticks] = struct.unpack( | |
'>IHHH', bytes(my_midi[4:14])) | |
if length != 6: | |
_warn("midi2opus: midi header length was "+str(length)+" instead of 6") | |
_clean_up_warnings() | |
return [1000,[],] | |
my_opus = [ticks,] | |
my_midi = my_midi[14:] | |
track_num = 1 # 5.1 | |
while len(my_midi) >= 8: | |
track_type = bytes(my_midi[0:4]) | |
if track_type != b'MTrk': | |
_warn('midi2opus: Warning: track #'+str(track_num)+' type is '+str(track_type)+" instead of b'MTrk'") | |
[track_length] = struct.unpack('>I', my_midi[4:8]) | |
my_midi = my_midi[8:] | |
if track_length > len(my_midi): | |
_warn('midi2opus: track #'+str(track_num)+' length '+str(track_length)+' is too large') | |
_clean_up_warnings() | |
return my_opus # 5.0 | |
my_midi_track = my_midi[0:track_length] | |
my_track = _decode(my_midi_track) | |
my_opus.append(my_track) | |
my_midi = my_midi[track_length:] | |
track_num += 1 # 5.1 | |
_clean_up_warnings() | |
return my_opus | |
def opus2score(opus=[]): | |
r'''For a description of the "opus" and "score" formats, | |
see opus2midi() and score2opus(). | |
''' | |
if len(opus) < 2: | |
_clean_up_warnings() | |
return [1000,[],] | |
tracks = copy.deepcopy(opus) # couple of slices probably quicker... | |
ticks = int(tracks.pop(0)) | |
score = [ticks,] | |
for opus_track in tracks: | |
ticks_so_far = 0 | |
score_track = [] | |
chapitch2note_on_events = dict([]) # 4.0 | |
for opus_event in opus_track: | |
ticks_so_far += opus_event[1] | |
if opus_event[0] == 'note_off' or (opus_event[0] == 'note_on' and opus_event[4] == 0): # 4.8 | |
cha = opus_event[2] | |
pitch = opus_event[3] | |
key = cha*128 + pitch | |
if chapitch2note_on_events.get(key): | |
new_event = chapitch2note_on_events[key].pop(0) | |
new_event[2] = ticks_so_far - new_event[1] | |
score_track.append(new_event) | |
elif pitch > 127: | |
pass #_warn('opus2score: note_off with no note_on, bad pitch='+str(pitch)) | |
else: | |
pass #_warn('opus2score: note_off with no note_on cha='+str(cha)+' pitch='+str(pitch)) | |
elif opus_event[0] == 'note_on': | |
cha = opus_event[2] | |
pitch = opus_event[3] | |
key = cha*128 + pitch | |
new_event = ['note',ticks_so_far,0,cha,pitch, opus_event[4]] | |
if chapitch2note_on_events.get(key): | |
chapitch2note_on_events[key].append(new_event) | |
else: | |
chapitch2note_on_events[key] = [new_event,] | |
else: | |
opus_event[1] = ticks_so_far | |
score_track.append(opus_event) | |
# check for unterminated notes (Oisín) -- 5.2 | |
for chapitch in chapitch2note_on_events: | |
note_on_events = chapitch2note_on_events[chapitch] | |
for new_e in note_on_events: | |
new_e[2] = ticks_so_far - new_e[1] | |
score_track.append(new_e) | |
pass #_warn("opus2score: note_on with no note_off cha="+str(new_e[3])+' pitch='+str(new_e[4])+'; adding note_off at end') | |
score.append(score_track) | |
_clean_up_warnings() | |
return score | |
def midi2score(midi=b''): | |
r''' | |
Translates MIDI into a "score", using midi2opus() then opus2score() | |
''' | |
return opus2score(midi2opus(midi)) | |
def midi2ms_score(midi=b''): | |
r''' | |
Translates MIDI into a "score" with one beat per second and one | |
tick per millisecond, using midi2opus() then to_millisecs() | |
then opus2score() | |
''' | |
return opus2score(to_millisecs(midi2opus(midi))) | |
#------------------------ Other Transformations --------------------- | |
def to_millisecs(old_opus=None): | |
r'''Recallibrates all the times in an "opus" to use one beat | |
per second and one tick per millisecond. This makes it | |
hard to retrieve any information about beats or barlines, | |
but it does make it easy to mix different scores together. | |
''' | |
if old_opus == None: | |
return [1000,[],] | |
try: | |
old_tpq = int(old_opus[0]) | |
except IndexError: # 5.0 | |
_warn('to_millisecs: the opus '+str(type(old_opus))+' has no elements') | |
return [1000,[],] | |
new_opus = [1000,] | |
# 6.7 first go through building a table of set_tempos by absolute-tick | |
ticks2tempo = {} | |
itrack = 1 | |
while itrack < len(old_opus): | |
ticks_so_far = 0 | |
for old_event in old_opus[itrack]: | |
if old_event[0] == 'note': | |
raise TypeError('to_millisecs needs an opus, not a score') | |
ticks_so_far += old_event[1] | |
if old_event[0] == 'set_tempo': | |
ticks2tempo[ticks_so_far] = old_event[2] | |
itrack += 1 | |
# then get the sorted-array of their keys | |
tempo_ticks = [] # list of keys | |
for k in ticks2tempo.keys(): | |
tempo_ticks.append(k) | |
tempo_ticks.sort() | |
# then go through converting to millisec, testing if the next | |
# set_tempo lies before the next track-event, and using it if so. | |
itrack = 1 | |
while itrack < len(old_opus): | |
ms_per_old_tick = 500.0 / old_tpq # float: will round later 6.3 | |
i_tempo_ticks = 0 | |
ticks_so_far = 0 | |
ms_so_far = 0.0 | |
previous_ms_so_far = 0.0 | |
new_track = [['set_tempo',0,1000000],] # new "crochet" is 1 sec | |
for old_event in old_opus[itrack]: | |
# detect if ticks2tempo has something before this event | |
# 20160702 if ticks2tempo is at the same time, leave it | |
event_delta_ticks = old_event[1] | |
if (i_tempo_ticks < len(tempo_ticks) and | |
tempo_ticks[i_tempo_ticks] < (ticks_so_far + old_event[1])): | |
delta_ticks = tempo_ticks[i_tempo_ticks] - ticks_so_far | |
ms_so_far += (ms_per_old_tick * delta_ticks) | |
ticks_so_far = tempo_ticks[i_tempo_ticks] | |
ms_per_old_tick = ticks2tempo[ticks_so_far] / (1000.0*old_tpq) | |
i_tempo_ticks += 1 | |
event_delta_ticks -= delta_ticks | |
new_event = copy.deepcopy(old_event) # now handle the new event | |
ms_so_far += (ms_per_old_tick * old_event[1]) | |
new_event[1] = round(ms_so_far - previous_ms_so_far) | |
if old_event[0] != 'set_tempo': | |
previous_ms_so_far = ms_so_far | |
new_track.append(new_event) | |
ticks_so_far += event_delta_ticks | |
new_opus.append(new_track) | |
itrack += 1 | |
_clean_up_warnings() | |
return new_opus | |
def event2alsaseq(event=None): # 5.5 | |
r'''Converts an event into the format needed by the alsaseq module, | |
http://pp.com.mx/python/alsaseq | |
The type of track (opus or score) is autodetected. | |
''' | |
pass | |
def grep(score=None, channels=None): | |
r'''Returns a "score" containing only the channels specified | |
''' | |
if score == None: | |
return [1000,[],] | |
ticks = score[0] | |
new_score = [ticks,] | |
if channels == None: | |
return new_score | |
channels = set(channels) | |
global Event2channelindex | |
itrack = 1 | |
while itrack < len(score): | |
new_score.append([]) | |
for event in score[itrack]: | |
channel_index = Event2channelindex.get(event[0], False) | |
if channel_index: | |
if event[channel_index] in channels: | |
new_score[itrack].append(event) | |
else: | |
new_score[itrack].append(event) | |
itrack += 1 | |
return new_score | |
def play_score(score=None): | |
r'''Converts the "score" to midi, and feeds it into 'aplaymidi -' | |
''' | |
if score == None: | |
return | |
import subprocess | |
pipe = subprocess.Popen(['aplaymidi','-'], stdin=subprocess.PIPE) | |
if score_type(score) == 'opus': | |
pipe.stdin.write(opus2midi(score)) | |
else: | |
pipe.stdin.write(score2midi(score)) | |
pipe.stdin.close() | |
def timeshift(score=None, shift=None, start_time=None, from_time=0, tracks={0,1,2,3,4,5,6,7,8,10,12,13,14,15}): | |
r'''Returns a "score" shifted in time by "shift" ticks, or shifted | |
so that the first event starts at "start_time" ticks. | |
If "from_time" is specified, only those events in the score | |
that begin after it are shifted. If "start_time" is less than | |
"from_time" (or "shift" is negative), then the intermediate | |
notes are deleted, though patch-change events are preserved. | |
If "tracks" are specified, then only those tracks get shifted. | |
"tracks" can be a list, tuple or set; it gets converted to set | |
internally. | |
It is deprecated to specify both "shift" and "start_time". | |
If this does happen, timeshift() will print a warning to | |
stderr and ignore the "shift" argument. | |
If "shift" is negative and sufficiently large that it would | |
leave some event with a negative tick-value, then the score | |
is shifted so that the first event occurs at time 0. This | |
also occurs if "start_time" is negative, and is also the | |
default if neither "shift" nor "start_time" are specified. | |
''' | |
#_warn('tracks='+str(tracks)) | |
if score == None or len(score) < 2: | |
return [1000, [],] | |
new_score = [score[0],] | |
my_type = score_type(score) | |
if my_type == '': | |
return new_score | |
if my_type == 'opus': | |
_warn("timeshift: opus format is not supported\n") | |
# _clean_up_scores() 6.2; doesn't exist! what was it supposed to do? | |
return new_score | |
if not (shift == None) and not (start_time == None): | |
_warn("timeshift: shift and start_time specified: ignoring shift\n") | |
shift = None | |
if shift == None: | |
if (start_time == None) or (start_time < 0): | |
start_time = 0 | |
# shift = start_time - from_time | |
i = 1 # ignore first element (ticks) | |
tracks = set(tracks) # defend against tuples and lists | |
earliest = 1000000000 | |
if not (start_time == None) or shift < 0: # first find the earliest event | |
while i < len(score): | |
if len(tracks) and not ((i-1) in tracks): | |
i += 1 | |
continue | |
for event in score[i]: | |
if event[1] < from_time: | |
continue # just inspect the to_be_shifted events | |
if event[1] < earliest: | |
earliest = event[1] | |
i += 1 | |
if earliest > 999999999: | |
earliest = 0 | |
if shift == None: | |
shift = start_time - earliest | |
elif (earliest + shift) < 0: | |
start_time = 0 | |
shift = 0 - earliest | |
i = 1 # ignore first element (ticks) | |
while i < len(score): | |
if len(tracks) == 0 or not ((i-1) in tracks): # 3.8 | |
new_score.append(score[i]) | |
i += 1 | |
continue | |
new_track = [] | |
for event in score[i]: | |
new_event = list(event) | |
#if new_event[1] == 0 and shift > 0 and new_event[0] != 'note': | |
# pass | |
#elif new_event[1] >= from_time: | |
if new_event[1] >= from_time: | |
# 4.1 must not rightshift set_tempo | |
if new_event[0] != 'set_tempo' or shift<0: | |
new_event[1] += shift | |
elif (shift < 0) and (new_event[1] >= (from_time+shift)): | |
continue | |
new_track.append(new_event) | |
if len(new_track) > 0: | |
new_score.append(new_track) | |
i += 1 | |
_clean_up_warnings() | |
return new_score | |
def segment(score=None, start_time=None, end_time=None, start=0, end=100000000, | |
tracks={0,1,2,3,4,5,6,7,8,10,11,12,13,14,15}): | |
r'''Returns a "score" which is a segment of the one supplied | |
as the argument, beginning at "start_time" ticks and ending | |
at "end_time" ticks (or at the end if "end_time" is not supplied). | |
If the set "tracks" is specified, only those tracks will | |
be returned. | |
''' | |
if score == None or len(score) < 2: | |
return [1000, [],] | |
if start_time == None: # as of 4.2 start_time is recommended | |
start_time = start # start is legacy usage | |
if end_time == None: # likewise | |
end_time = end | |
new_score = [score[0],] | |
my_type = score_type(score) | |
if my_type == '': | |
return new_score | |
if my_type == 'opus': | |
# more difficult (disconnecting note_on's from their note_off's)... | |
_warn("segment: opus format is not supported\n") | |
_clean_up_warnings() | |
return new_score | |
i = 1 # ignore first element (ticks); we count in ticks anyway | |
tracks = set(tracks) # defend against tuples and lists | |
while i < len(score): | |
if len(tracks) and not ((i-1) in tracks): | |
i += 1 | |
continue | |
new_track = [] | |
channel2cc_num = {} # most recent controller change before start | |
channel2cc_val = {} | |
channel2cc_time = {} | |
channel2patch_num = {} # keep most recent patch change before start | |
channel2patch_time = {} | |
set_tempo_num = 500000 # most recent tempo change before start 6.3 | |
set_tempo_time = 0 | |
earliest_note_time = end_time | |
for event in score[i]: | |
if event[0] == 'control_change': # 6.5 | |
cc_time = channel2cc_time.get(event[2]) or 0 | |
if (event[1] <= start_time) and (event[1] >= cc_time): | |
channel2cc_num[event[2]] = event[3] | |
channel2cc_val[event[2]] = event[4] | |
channel2cc_time[event[2]] = event[1] | |
elif event[0] == 'patch_change': | |
patch_time = channel2patch_time.get(event[2]) or 0 | |
if (event[1]<=start_time) and (event[1] >= patch_time): # 2.0 | |
channel2patch_num[event[2]] = event[3] | |
channel2patch_time[event[2]] = event[1] | |
elif event[0] == 'set_tempo': | |
if (event[1]<=start_time) and (event[1]>=set_tempo_time): #6.4 | |
set_tempo_num = event[2] | |
set_tempo_time = event[1] | |
if (event[1] >= start_time) and (event[1] <= end_time): | |
new_track.append(event) | |
if (event[0] == 'note') and (event[1] < earliest_note_time): | |
earliest_note_time = event[1] | |
if len(new_track) > 0: | |
new_track.append(['set_tempo', start_time, set_tempo_num]) | |
for c in channel2patch_num: | |
new_track.append(['patch_change',start_time,c,channel2patch_num[c]],) | |
for c in channel2cc_num: # 6.5 | |
new_track.append(['control_change',start_time,c,channel2cc_num[c],channel2cc_val[c]]) | |
new_score.append(new_track) | |
i += 1 | |
_clean_up_warnings() | |
return new_score | |
def score_type(opus_or_score=None): | |
r'''Returns a string, either 'opus' or 'score' or '' | |
''' | |
if opus_or_score == None or str(type(opus_or_score)).find('list')<0 or len(opus_or_score) < 2: | |
return '' | |
i = 1 # ignore first element | |
while i < len(opus_or_score): | |
for event in opus_or_score[i]: | |
if event[0] == 'note': | |
return 'score' | |
elif event[0] == 'note_on': | |
return 'opus' | |
i += 1 | |
return '' | |
def concatenate_scores(scores): | |
r'''Concatenates a list of scores into one score. | |
If the scores differ in their "ticks" parameter, | |
they will all get converted to millisecond-tick format. | |
''' | |
# the deepcopys are needed if the input_score's are refs to the same obj | |
# e.g. if invoked by midisox's repeat() | |
input_scores = _consistentise_ticks(scores) # 3.7 | |
output_score = copy.deepcopy(input_scores[0]) | |
for input_score in input_scores[1:]: | |
output_stats = score2stats(output_score) | |
delta_ticks = output_stats['nticks'] | |
itrack = 1 | |
while itrack < len(input_score): | |
if itrack >= len(output_score): # new output track if doesn't exist | |
output_score.append([]) | |
for event in input_score[itrack]: | |
output_score[itrack].append(copy.deepcopy(event)) | |
output_score[itrack][-1][1] += delta_ticks | |
itrack += 1 | |
return output_score | |
def merge_scores(scores): | |
r'''Merges a list of scores into one score. A merged score comprises | |
all of the tracks from all of the input scores; un-merging is possible | |
by selecting just some of the tracks. If the scores differ in their | |
"ticks" parameter, they will all get converted to millisecond-tick | |
format. merge_scores attempts to resolve channel-conflicts, | |
but there are of course only 15 available channels... | |
''' | |
input_scores = _consistentise_ticks(scores) # 3.6 | |
output_score = [1000] | |
channels_so_far = set() | |
all_channels = {0,1,2,3,4,5,6,7,8,10,11,12,13,14,15} | |
global Event2channelindex | |
for input_score in input_scores: | |
new_channels = set(score2stats(input_score).get('channels_total', [])) | |
new_channels.discard(9) # 2.8 cha9 must remain cha9 (in GM) | |
for channel in channels_so_far & new_channels: | |
# consistently choose lowest avaiable, to ease testing | |
free_channels = list(all_channels - (channels_so_far|new_channels)) | |
if len(free_channels) > 0: | |
free_channels.sort() | |
free_channel = free_channels[0] | |
else: | |
free_channel = None | |
break | |
itrack = 1 | |
while itrack < len(input_score): | |
for input_event in input_score[itrack]: | |
channel_index=Event2channelindex.get(input_event[0],False) | |
if channel_index and input_event[channel_index]==channel: | |
input_event[channel_index] = free_channel | |
itrack += 1 | |
channels_so_far.add(free_channel) | |
channels_so_far |= new_channels | |
output_score.extend(input_score[1:]) | |
return output_score | |
def _ticks(event): | |
return event[1] | |
def mix_opus_tracks(input_tracks): # 5.5 | |
r'''Mixes an array of tracks into one track. A mixed track | |
cannot be un-mixed. It is assumed that the tracks share the same | |
ticks parameter and the same tempo. | |
Mixing score-tracks is trivial (just insert all events into one array). | |
Mixing opus-tracks is only slightly harder, but it's common enough | |
that a dedicated function is useful. | |
''' | |
output_score = [1000, []] | |
for input_track in input_tracks: # 5.8 | |
input_score = opus2score([1000, input_track]) | |
for event in input_score[1]: | |
output_score[1].append(event) | |
output_score[1].sort(key=_ticks) | |
output_opus = score2opus(output_score) | |
return output_opus[1] | |
def mix_scores(scores): | |
r'''Mixes a list of scores into one one-track score. | |
A mixed score cannot be un-mixed. Hopefully the scores | |
have no undesirable channel-conflicts between them. | |
If the scores differ in their "ticks" parameter, | |
they will all get converted to millisecond-tick format. | |
''' | |
input_scores = _consistentise_ticks(scores) # 3.6 | |
output_score = [1000, []] | |
for input_score in input_scores: | |
for input_track in input_score[1:]: | |
output_score[1].extend(input_track) | |
return output_score | |
def score2stats(opus_or_score=None): | |
r'''Returns a dict of some basic stats about the score, like | |
bank_select (list of tuples (msb,lsb)), | |
channels_by_track (list of lists), channels_total (set), | |
general_midi_mode (list), | |
ntracks, nticks, patch_changes_by_track (list of dicts), | |
num_notes_by_channel (list of numbers), | |
patch_changes_total (set), | |
percussion (dict histogram of channel 9 events), | |
pitches (dict histogram of pitches on channels other than 9), | |
pitch_range_by_track (list, by track, of two-member-tuples), | |
pitch_range_sum (sum over tracks of the pitch_ranges), | |
''' | |
bank_select_msb = -1 | |
bank_select_lsb = -1 | |
bank_select = [] | |
channels_by_track = [] | |
channels_total = set([]) | |
general_midi_mode = [] | |
num_notes_by_channel = dict([]) | |
patches_used_by_track = [] | |
patches_used_total = set([]) | |
patch_changes_by_track = [] | |
patch_changes_total = set([]) | |
percussion = dict([]) # histogram of channel 9 "pitches" | |
pitches = dict([]) # histogram of pitch-occurrences channels 0-8,10-15 | |
pitch_range_sum = 0 # u pitch-ranges of each track | |
pitch_range_by_track = [] | |
is_a_score = True | |
if opus_or_score == None: | |
return {'bank_select':[], 'channels_by_track':[], 'channels_total':[], | |
'general_midi_mode':[], 'ntracks':0, 'nticks':0, | |
'num_notes_by_channel':dict([]), | |
'patch_changes_by_track':[], 'patch_changes_total':[], | |
'percussion':{}, 'pitches':{}, 'pitch_range_by_track':[], | |
'ticks_per_quarter':0, 'pitch_range_sum':0} | |
ticks_per_quarter = opus_or_score[0] | |
i = 1 # ignore first element, which is ticks | |
nticks = 0 | |
while i < len(opus_or_score): | |
highest_pitch = 0 | |
lowest_pitch = 128 | |
channels_this_track = set([]) | |
patch_changes_this_track = dict({}) | |
for event in opus_or_score[i]: | |
if event[0] == 'note': | |
num_notes_by_channel[event[3]] = num_notes_by_channel.get(event[3],0) + 1 | |
if event[3] == 9: | |
percussion[event[4]] = percussion.get(event[4],0) + 1 | |
else: | |
pitches[event[4]] = pitches.get(event[4],0) + 1 | |
if event[4] > highest_pitch: | |
highest_pitch = event[4] | |
if event[4] < lowest_pitch: | |
lowest_pitch = event[4] | |
channels_this_track.add(event[3]) | |
channels_total.add(event[3]) | |
finish_time = event[1] + event[2] | |
if finish_time > nticks: | |
nticks = finish_time | |
elif event[0] == 'note_off' or (event[0] == 'note_on' and event[4] == 0): # 4.8 | |
finish_time = event[1] | |
if finish_time > nticks: | |
nticks = finish_time | |
elif event[0] == 'note_on': | |
is_a_score = False | |
num_notes_by_channel[event[2]] = num_notes_by_channel.get(event[2],0) + 1 | |
if event[2] == 9: | |
percussion[event[3]] = percussion.get(event[3],0) + 1 | |
else: | |
pitches[event[3]] = pitches.get(event[3],0) + 1 | |
if event[3] > highest_pitch: | |
highest_pitch = event[3] | |
if event[3] < lowest_pitch: | |
lowest_pitch = event[3] | |
channels_this_track.add(event[2]) | |
channels_total.add(event[2]) | |
elif event[0] == 'patch_change': | |
patch_changes_this_track[event[2]] = event[3] | |
patch_changes_total.add(event[3]) | |
elif event[0] == 'control_change': | |
if event[3] == 0: # bank select MSB | |
bank_select_msb = event[4] | |
elif event[3] == 32: # bank select LSB | |
bank_select_lsb = event[4] | |
if bank_select_msb >= 0 and bank_select_lsb >= 0: | |
bank_select.append((bank_select_msb,bank_select_lsb)) | |
bank_select_msb = -1 | |
bank_select_lsb = -1 | |
elif event[0] == 'sysex_f0': | |
if _sysex2midimode.get(event[2], -1) >= 0: | |
general_midi_mode.append(_sysex2midimode.get(event[2])) | |
if is_a_score: | |
if event[1] > nticks: | |
nticks = event[1] | |
else: | |
nticks += event[1] | |
if lowest_pitch == 128: | |
lowest_pitch = 0 | |
channels_by_track.append(channels_this_track) | |
patch_changes_by_track.append(patch_changes_this_track) | |
pitch_range_by_track.append((lowest_pitch,highest_pitch)) | |
pitch_range_sum += (highest_pitch-lowest_pitch) | |
i += 1 | |
return {'bank_select':bank_select, | |
'channels_by_track':channels_by_track, | |
'channels_total':channels_total, | |
'general_midi_mode':general_midi_mode, | |
'ntracks':len(opus_or_score)-1, | |
'nticks':nticks, | |
'num_notes_by_channel':num_notes_by_channel, | |
'patch_changes_by_track':patch_changes_by_track, | |
'patch_changes_total':patch_changes_total, | |
'percussion':percussion, | |
'pitches':pitches, | |
'pitch_range_by_track':pitch_range_by_track, | |
'pitch_range_sum':pitch_range_sum, | |
'ticks_per_quarter':ticks_per_quarter} | |
#----------------------------- Event stuff -------------------------- | |
_sysex2midimode = { | |
"\x7E\x7F\x09\x01\xF7": 1, | |
"\x7E\x7F\x09\x02\xF7": 0, | |
"\x7E\x7F\x09\x03\xF7": 2, | |
} | |
# Some public-access tuples: | |
MIDI_events = tuple('''note_off note_on key_after_touch | |
control_change patch_change channel_after_touch | |
pitch_wheel_change'''.split()) | |
Text_events = tuple('''text_event copyright_text_event | |
track_name instrument_name lyric marker cue_point text_event_08 | |
text_event_09 text_event_0a text_event_0b text_event_0c | |
text_event_0d text_event_0e text_event_0f'''.split()) | |
Nontext_meta_events = tuple('''end_track set_tempo | |
smpte_offset time_signature key_signature sequencer_specific | |
raw_meta_event sysex_f0 sysex_f7 song_position song_select | |
tune_request'''.split()) | |
# unsupported: raw_data | |
# Actually, 'tune_request' is is F-series event, not strictly a meta-event... | |
Meta_events = Text_events + Nontext_meta_events | |
All_events = MIDI_events + Meta_events | |
# And three dictionaries: | |
Number2patch = { # General MIDI patch numbers: | |
0:'Acoustic Grand', | |
1:'Bright Acoustic', | |
2:'Electric Grand', | |
3:'Honky-Tonk', | |
4:'Electric Piano 1', | |
5:'Electric Piano 2', | |
6:'Harpsichord', | |
7:'Clav', | |
8:'Celesta', | |
9:'Glockenspiel', | |
10:'Music Box', | |
11:'Vibraphone', | |
12:'Marimba', | |
13:'Xylophone', | |
14:'Tubular Bells', | |
15:'Dulcimer', | |
16:'Drawbar Organ', | |
17:'Percussive Organ', | |
18:'Rock Organ', | |
19:'Church Organ', | |
20:'Reed Organ', | |
21:'Accordion', | |
22:'Harmonica', | |
23:'Tango Accordion', | |
24:'Acoustic Guitar(nylon)', | |
25:'Acoustic Guitar(steel)', | |
26:'Electric Guitar(jazz)', | |
27:'Electric Guitar(clean)', | |
28:'Electric Guitar(muted)', | |
29:'Overdriven Guitar', | |
30:'Distortion Guitar', | |
31:'Guitar Harmonics', | |
32:'Acoustic Bass', | |
33:'Electric Bass(finger)', | |
34:'Electric Bass(pick)', | |
35:'Fretless Bass', | |
36:'Slap Bass 1', | |
37:'Slap Bass 2', | |
38:'Synth Bass 1', | |
39:'Synth Bass 2', | |
40:'Violin', | |
41:'Viola', | |
42:'Cello', | |
43:'Contrabass', | |
44:'Tremolo Strings', | |
45:'Pizzicato Strings', | |
46:'Orchestral Harp', | |
47:'Timpani', | |
48:'String Ensemble 1', | |
49:'String Ensemble 2', | |
50:'SynthStrings 1', | |
51:'SynthStrings 2', | |
52:'Choir Aahs', | |
53:'Voice Oohs', | |
54:'Synth Voice', | |
55:'Orchestra Hit', | |
56:'Trumpet', | |
57:'Trombone', | |
58:'Tuba', | |
59:'Muted Trumpet', | |
60:'French Horn', | |
61:'Brass Section', | |
62:'SynthBrass 1', | |
63:'SynthBrass 2', | |
64:'Soprano Sax', | |
65:'Alto Sax', | |
66:'Tenor Sax', | |
67:'Baritone Sax', | |
68:'Oboe', | |
69:'English Horn', | |
70:'Bassoon', | |
71:'Clarinet', | |
72:'Piccolo', | |
73:'Flute', | |
74:'Recorder', | |
75:'Pan Flute', | |
76:'Blown Bottle', | |
77:'Skakuhachi', | |
78:'Whistle', | |
79:'Ocarina', | |
80:'Lead 1 (square)', | |
81:'Lead 2 (sawtooth)', | |
82:'Lead 3 (calliope)', | |
83:'Lead 4 (chiff)', | |
84:'Lead 5 (charang)', | |
85:'Lead 6 (voice)', | |
86:'Lead 7 (fifths)', | |
87:'Lead 8 (bass+lead)', | |
88:'Pad 1 (new age)', | |
89:'Pad 2 (warm)', | |
90:'Pad 3 (polysynth)', | |
91:'Pad 4 (choir)', | |
92:'Pad 5 (bowed)', | |
93:'Pad 6 (metallic)', | |
94:'Pad 7 (halo)', | |
95:'Pad 8 (sweep)', | |
96:'FX 1 (rain)', | |
97:'FX 2 (soundtrack)', | |
98:'FX 3 (crystal)', | |
99:'FX 4 (atmosphere)', | |
100:'FX 5 (brightness)', | |
101:'FX 6 (goblins)', | |
102:'FX 7 (echoes)', | |
103:'FX 8 (sci-fi)', | |
104:'Sitar', | |
105:'Banjo', | |
106:'Shamisen', | |
107:'Koto', | |
108:'Kalimba', | |
109:'Bagpipe', | |
110:'Fiddle', | |
111:'Shanai', | |
112:'Tinkle Bell', | |
113:'Agogo', | |
114:'Steel Drums', | |
115:'Woodblock', | |
116:'Taiko Drum', | |
117:'Melodic Tom', | |
118:'Synth Drum', | |
119:'Reverse Cymbal', | |
120:'Guitar Fret Noise', | |
121:'Breath Noise', | |
122:'Seashore', | |
123:'Bird Tweet', | |
124:'Telephone Ring', | |
125:'Helicopter', | |
126:'Applause', | |
127:'Gunshot', | |
} | |
Notenum2percussion = { # General MIDI Percussion (on Channel 9): | |
35:'Acoustic Bass Drum', | |
36:'Bass Drum 1', | |
37:'Side Stick', | |
38:'Acoustic Snare', | |
39:'Hand Clap', | |
40:'Electric Snare', | |
41:'Low Floor Tom', | |
42:'Closed Hi-Hat', | |
43:'High Floor Tom', | |
44:'Pedal Hi-Hat', | |
45:'Low Tom', | |
46:'Open Hi-Hat', | |
47:'Low-Mid Tom', | |
48:'Hi-Mid Tom', | |
49:'Crash Cymbal 1', | |
50:'High Tom', | |
51:'Ride Cymbal 1', | |
52:'Chinese Cymbal', | |
53:'Ride Bell', | |
54:'Tambourine', | |
55:'Splash Cymbal', | |
56:'Cowbell', | |
57:'Crash Cymbal 2', | |
58:'Vibraslap', | |
59:'Ride Cymbal 2', | |
60:'Hi Bongo', | |
61:'Low Bongo', | |
62:'Mute Hi Conga', | |
63:'Open Hi Conga', | |
64:'Low Conga', | |
65:'High Timbale', | |
66:'Low Timbale', | |
67:'High Agogo', | |
68:'Low Agogo', | |
69:'Cabasa', | |
70:'Maracas', | |
71:'Short Whistle', | |
72:'Long Whistle', | |
73:'Short Guiro', | |
74:'Long Guiro', | |
75:'Claves', | |
76:'Hi Wood Block', | |
77:'Low Wood Block', | |
78:'Mute Cuica', | |
79:'Open Cuica', | |
80:'Mute Triangle', | |
81:'Open Triangle', | |
} | |
Event2channelindex = { 'note':3, 'note_off':2, 'note_on':2, | |
'key_after_touch':2, 'control_change':2, 'patch_change':2, | |
'channel_after_touch':2, 'pitch_wheel_change':2 | |
} | |
################################################################ | |
# The code below this line is full of frightening things, all to | |
# do with the actual encoding and decoding of binary MIDI data. | |
def _twobytes2int(byte_a): | |
r'''decode a 16 bit quantity from two bytes,''' | |
return (byte_a[1] | (byte_a[0] << 8)) | |
def _int2twobytes(int_16bit): | |
r'''encode a 16 bit quantity into two bytes,''' | |
return bytes([(int_16bit>>8) & 0xFF, int_16bit & 0xFF]) | |
def _read_14_bit(byte_a): | |
r'''decode a 14 bit quantity from two bytes,''' | |
return (byte_a[0] | (byte_a[1] << 7)) | |
def _write_14_bit(int_14bit): | |
r'''encode a 14 bit quantity into two bytes,''' | |
return bytes([int_14bit & 0x7F, (int_14bit>>7) & 0x7F]) | |
def _ber_compressed_int(integer): | |
r'''BER compressed integer (not an ASN.1 BER, see perlpacktut for | |
details). Its bytes represent an unsigned integer in base 128, | |
most significant digit first, with as few digits as possible. | |
Bit eight (the high bit) is set on each byte except the last. | |
''' | |
ber = bytearray(b'') | |
seven_bits = 0x7F & integer | |
ber.insert(0, seven_bits) # XXX surely should convert to a char ? | |
integer >>= 7 | |
while integer > 0: | |
seven_bits = 0x7F & integer | |
ber.insert(0, 0x80|seven_bits) # XXX surely should convert to a char ? | |
integer >>= 7 | |
return ber | |
def _unshift_ber_int(ba): | |
r'''Given a bytearray, returns a tuple of (the ber-integer at the | |
start, and the remainder of the bytearray). | |
''' | |
if not len(ba): # 6.7 | |
_warn('_unshift_ber_int: no integer found') | |
return ((0, b"")) | |
byte = ba.pop(0) | |
integer = 0 | |
while True: | |
integer += (byte & 0x7F) | |
if not (byte & 0x80): | |
return ((integer, ba)) | |
if not len(ba): | |
_warn('_unshift_ber_int: no end-of-integer found') | |
return ((0, ba)) | |
byte = ba.pop(0) | |
integer <<= 7 | |
def _clean_up_warnings(): # 5.4 | |
# Call this before returning from any publicly callable function | |
# whenever there's a possibility that a warning might have been printed | |
# by the function, or by any private functions it might have called. | |
global _previous_times | |
global _previous_warning | |
if _previous_times > 1: | |
# E:1176, 0: invalid syntax (<string>, line 1176) (syntax-error) ??? | |
# print(' previous message repeated '+str(_previous_times)+' times', file=sys.stderr) | |
# 6.7 | |
sys.stderr.write(' previous message repeated {0} times\n'.format(_previous_times)) | |
elif _previous_times > 0: | |
sys.stderr.write(' previous message repeated\n') | |
_previous_times = 0 | |
_previous_warning = '' | |
def _warn(s=''): | |
global _previous_times | |
global _previous_warning | |
if s == _previous_warning: # 5.4 | |
_previous_times = _previous_times + 1 | |
else: | |
_clean_up_warnings() | |
sys.stderr.write(str(s)+"\n") | |
_previous_warning = s | |
def _some_text_event(which_kind=0x01, text=b'some_text'): | |
if str(type(text)).find("'str'") >= 0: # 6.4 test for back-compatibility | |
data = bytes(text, encoding='ISO-8859-1') | |
else: | |
data = bytes(text) | |
return b'\xFF'+bytes((which_kind,))+_ber_compressed_int(len(data))+data | |
def _consistentise_ticks(scores): # 3.6 | |
# used by mix_scores, merge_scores, concatenate_scores | |
if len(scores) == 1: | |
return copy.deepcopy(scores) | |
are_consistent = True | |
ticks = scores[0][0] | |
iscore = 1 | |
while iscore < len(scores): | |
if scores[iscore][0] != ticks: | |
are_consistent = False | |
break | |
iscore += 1 | |
if are_consistent: | |
return copy.deepcopy(scores) | |
new_scores = [] | |
iscore = 0 | |
while iscore < len(scores): | |
score = scores[iscore] | |
new_scores.append(opus2score(to_millisecs(score2opus(score)))) | |
iscore += 1 | |
return new_scores | |
########################################################################### | |
def _decode(trackdata=b'', exclude=None, include=None, | |
event_callback=None, exclusive_event_callback=None, no_eot_magic=False): | |
r'''Decodes MIDI track data into an opus-style list of events. | |
The options: | |
'exclude' is a list of event types which will be ignored SHOULD BE A SET | |
'include' (and no exclude), makes exclude a list | |
of all possible events, /minus/ what include specifies | |
'event_callback' is a coderef | |
'exclusive_event_callback' is a coderef | |
''' | |
trackdata = bytearray(trackdata) | |
if exclude == None: | |
exclude = [] | |
if include == None: | |
include = [] | |
if include and not exclude: | |
exclude = All_events | |
include = set(include) | |
exclude = set(exclude) | |
# Pointer = 0; not used here; we eat through the bytearray instead. | |
event_code = -1; # used for running status | |
event_count = 0; | |
events = [] | |
while(len(trackdata)): | |
# loop while there's anything to analyze ... | |
eot = False # When True, the event registrar aborts this loop | |
event_count += 1 | |
E = [] | |
# E for events - we'll feed it to the event registrar at the end. | |
# Slice off the delta time code, and analyze it | |
[time, remainder] = _unshift_ber_int(trackdata) | |
# Now let's see what we can make of the command | |
first_byte = trackdata.pop(0) & 0xFF | |
if (first_byte < 0xF0): # It's a MIDI event | |
if (first_byte & 0x80): | |
event_code = first_byte | |
else: | |
# It wants running status; use last event_code value | |
trackdata.insert(0, first_byte) | |
if (event_code == -1): | |
_warn("Running status not set; Aborting track.") | |
return [] | |
command = event_code & 0xF0 | |
channel = event_code & 0x0F | |
if (command == 0xF6): # 0-byte argument | |
pass | |
elif (command == 0xC0 or command == 0xD0): # 1-byte argument | |
parameter = trackdata.pop(0) # could be B | |
else: # 2-byte argument could be BB or 14-bit | |
parameter = (trackdata.pop(0), trackdata.pop(0)) | |
################################################################# | |
# MIDI events | |
if (command == 0x80): | |
if 'note_off' in exclude: | |
continue | |
E = ['note_off', time, channel, parameter[0], parameter[1]] | |
elif (command == 0x90): | |
if 'note_on' in exclude: | |
continue | |
E = ['note_on', time, channel, parameter[0], parameter[1]] | |
elif (command == 0xA0): | |
if 'key_after_touch' in exclude: | |
continue | |
E = ['key_after_touch',time,channel,parameter[0],parameter[1]] | |
elif (command == 0xB0): | |
if 'control_change' in exclude: | |
continue | |
E = ['control_change',time,channel,parameter[0],parameter[1]] | |
elif (command == 0xC0): | |
if 'patch_change' in exclude: | |
continue | |
E = ['patch_change', time, channel, parameter] | |
elif (command == 0xD0): | |
if 'channel_after_touch' in exclude: | |
continue | |
E = ['channel_after_touch', time, channel, parameter] | |
elif (command == 0xE0): | |
if 'pitch_wheel_change' in exclude: | |
continue | |
E = ['pitch_wheel_change', time, channel, | |
_read_14_bit(parameter)-0x2000] | |
else: | |
_warn("Shouldn't get here; command="+hex(command)) | |
elif (first_byte == 0xFF): # It's a Meta-Event! ################## | |
#[command, length, remainder] = | |
# unpack("xCwa*", substr(trackdata, $Pointer, 6)); | |
#Pointer += 6 - len(remainder); | |
# # Move past JUST the length-encoded. | |
command = trackdata.pop(0) & 0xFF | |
[length, trackdata] = _unshift_ber_int(trackdata) | |
if (command == 0x00): | |
if (length == 2): | |
E = ['set_sequence_number',time,_twobytes2int(trackdata)] | |
else: | |
_warn('set_sequence_number: length must be 2, not '+str(length)) | |
E = ['set_sequence_number', time, 0] | |
elif command >= 0x01 and command <= 0x0f: # Text events | |
# 6.2 take it in bytes; let the user get the right encoding. | |
# text_str = trackdata[0:length].decode('ascii','ignore') | |
# text_str = trackdata[0:length].decode('ISO-8859-1') | |
# 6.4 take it in bytes; let the user get the right encoding. | |
text_data = bytes(trackdata[0:length]) # 6.4 | |
# Defined text events | |
if (command == 0x01): | |
E = ['text_event', time, text_data] | |
elif (command == 0x02): | |
E = ['copyright_text_event', time, text_data] | |
elif (command == 0x03): | |
E = ['track_name', time, text_data] | |
elif (command == 0x04): | |
E = ['instrument_name', time, text_data] | |
elif (command == 0x05): | |
E = ['lyric', time, text_data] | |
elif (command == 0x06): | |
E = ['marker', time, text_data] | |
elif (command == 0x07): | |
E = ['cue_point', time, text_data] | |
# Reserved but apparently unassigned text events | |
elif (command == 0x08): | |
E = ['text_event_08', time, text_data] | |
elif (command == 0x09): | |
E = ['text_event_09', time, text_data] | |
elif (command == 0x0a): | |
E = ['text_event_0a', time, text_data] | |
elif (command == 0x0b): | |
E = ['text_event_0b', time, text_data] | |
elif (command == 0x0c): | |
E = ['text_event_0c', time, text_data] | |
elif (command == 0x0d): | |
E = ['text_event_0d', time, text_data] | |
elif (command == 0x0e): | |
E = ['text_event_0e', time, text_data] | |
elif (command == 0x0f): | |
E = ['text_event_0f', time, text_data] | |
# Now the sticky events ------------------------------------- | |
elif (command == 0x2F): | |
E = ['end_track', time] | |
# The code for handling this, oddly, comes LATER, | |
# in the event registrar. | |
elif (command == 0x51): # DTime, Microseconds/Crochet | |
if length != 3: | |
_warn('set_tempo event, but length='+str(length)) | |
E = ['set_tempo', time, | |
struct.unpack(">I", b'\x00'+trackdata[0:3])[0]] | |
elif (command == 0x54): | |
if length != 5: # DTime, HR, MN, SE, FR, FF | |
_warn('smpte_offset event, but length='+str(length)) | |
E = ['smpte_offset',time] + list(struct.unpack(">BBBBB",trackdata[0:5])) | |
elif (command == 0x58): | |
if length != 4: # DTime, NN, DD, CC, BB | |
_warn('time_signature event, but length='+str(length)) | |
E = ['time_signature', time]+list(trackdata[0:4]) | |
elif (command == 0x59): | |
if length != 2: # DTime, SF(signed), MI | |
_warn('key_signature event, but length='+str(length)) | |
E = ['key_signature',time] + list(struct.unpack(">bB",trackdata[0:2])) | |
elif (command == 0x7F): # 6.4 | |
E = ['sequencer_specific',time, bytes(trackdata[0:length])] | |
else: | |
E = ['raw_meta_event', time, command, | |
bytes(trackdata[0:length])] # 6.0 | |
#"[uninterpretable meta-event command of length length]" | |
# DTime, Command, Binary Data | |
# It's uninterpretable; record it as raw_data. | |
# Pointer += length; # Now move Pointer | |
trackdata = trackdata[length:] | |
###################################################################### | |
elif (first_byte == 0xF0 or first_byte == 0xF7): | |
# Note that sysexes in MIDI /files/ are different than sysexes | |
# in MIDI transmissions!! The vast majority of system exclusive | |
# messages will just use the F0 format. For instance, the | |
# transmitted message F0 43 12 00 07 F7 would be stored in a | |
# MIDI file as F0 05 43 12 00 07 F7. As mentioned above, it is | |
# required to include the F7 at the end so that the reader of the | |
# MIDI file knows that it has read the entire message. (But the F7 | |
# is omitted if this is a non-final block in a multiblock sysex; | |
# but the F7 (if there) is counted in the message's declared | |
# length, so we don't have to think about it anyway.) | |
#command = trackdata.pop(0) | |
[length, trackdata] = _unshift_ber_int(trackdata) | |
if first_byte == 0xF0: | |
# 20091008 added ISO-8859-1 to get an 8-bit str | |
# 6.4 return bytes instead | |
E = ['sysex_f0', time, bytes(trackdata[0:length])] | |
else: | |
E = ['sysex_f7', time, bytes(trackdata[0:length])] | |
trackdata = trackdata[length:] | |
###################################################################### | |
# Now, the MIDI file spec says: | |
# <track data> = <MTrk event>+ | |
# <MTrk event> = <delta-time> <event> | |
# <event> = <MIDI event> | <sysex event> | <meta-event> | |
# I know that, on the wire, <MIDI event> can include note_on, | |
# note_off, and all the other 8x to Ex events, AND Fx events | |
# other than F0, F7, and FF -- namely, <song position msg>, | |
# <song select msg>, and <tune request>. | |
# | |
# Whether these can occur in MIDI files is not clear specified | |
# from the MIDI file spec. So, I'm going to assume that | |
# they CAN, in practice, occur. I don't know whether it's | |
# proper for you to actually emit these into a MIDI file. | |
elif (first_byte == 0xF2): # DTime, Beats | |
# <song position msg> ::= F2 <data pair> | |
E = ['song_position', time, _read_14_bit(trackdata[:2])] | |
trackdata = trackdata[2:] | |
elif (first_byte == 0xF3): # <song select msg> ::= F3 <data singlet> | |
# E = ['song_select', time, struct.unpack('>B',trackdata.pop(0))[0]] | |
E = ['song_select', time, trackdata[0]] | |
trackdata = trackdata[1:] | |
# DTime, Thing (what?! song number? whatever ...) | |
elif (first_byte == 0xF6): # DTime | |
E = ['tune_request', time] | |
# What would a tune request be doing in a MIDI /file/? | |
######################################################### | |
# ADD MORE META-EVENTS HERE. TODO: | |
# f1 -- MTC Quarter Frame Message. One data byte follows | |
# the Status; it's the time code value, from 0 to 127. | |
# f8 -- MIDI clock. no data. | |
# fa -- MIDI start. no data. | |
# fb -- MIDI continue. no data. | |
# fc -- MIDI stop. no data. | |
# fe -- Active sense. no data. | |
# f4 f5 f9 fd -- unallocated | |
r''' | |
elif (first_byte > 0xF0) { # Some unknown kinda F-series event #### | |
# Here we only produce a one-byte piece of raw data. | |
# But the encoder for 'raw_data' accepts any length of it. | |
E = [ 'raw_data', | |
time, substr(trackdata,Pointer,1) ] | |
# DTime and the Data (in this case, the one Event-byte) | |
++Pointer; # itself | |
''' | |
elif first_byte > 0xF0: # Some unknown F-series event | |
# Here we only produce a one-byte piece of raw data. | |
# E = ['raw_data', time, bytest(trackdata[0])] # 6.4 | |
E = ['raw_data', time, trackdata[0]] # 6.4 6.7 | |
trackdata = trackdata[1:] | |
else: # Fallthru. | |
_warn("Aborting track. Command-byte first_byte="+hex(first_byte)) | |
break | |
# End of the big if-group | |
###################################################################### | |
# THE EVENT REGISTRAR... | |
if E and (E[0] == 'end_track'): | |
# This is the code for exceptional handling of the EOT event. | |
eot = True | |
if not no_eot_magic: | |
if E[1] > 0: # a null text-event to carry the delta-time | |
E = ['text_event', E[1], ''] | |
else: | |
E = [] # EOT with a delta-time of 0; ignore it. | |
if E and not (E[0] in exclude): | |
#if ( $exclusive_event_callback ): | |
# &{ $exclusive_event_callback }( @E ); | |
#else: | |
# &{ $event_callback }( @E ) if $event_callback; | |
events.append(E) | |
if eot: | |
break | |
# End of the big "Event" while-block | |
return events | |
########################################################################### | |
def _encode(events_lol, unknown_callback=None, never_add_eot=False, | |
no_eot_magic=False, no_running_status=False): | |
# encode an event structure, presumably for writing to a file | |
# Calling format: | |
# $data_r = MIDI::Event::encode( \@event_lol, { options } ); | |
# Takes a REFERENCE to an event structure (a LoL) | |
# Returns an (unblessed) REFERENCE to track data. | |
# If you want to use this to encode a /single/ event, | |
# you still have to do it as a reference to an event structure (a LoL) | |
# that just happens to have just one event. I.e., | |
# encode( [ $event ] ) or encode( [ [ 'note_on', 100, 5, 42, 64] ] ) | |
# If you're doing this, consider the never_add_eot track option, as in | |
# print MIDI ${ encode( [ $event], { 'never_add_eot' => 1} ) }; | |
data = [] # what I'll store the chunks of byte-data in | |
# This is so my end_track magic won't corrupt the original | |
events = copy.deepcopy(events_lol) | |
if not never_add_eot: | |
# One way or another, tack on an 'end_track' | |
if events: | |
last = events[-1] | |
if not (last[0] == 'end_track'): # no end_track already | |
if (last[0] == 'text_event' and len(last[2]) == 0): | |
# 0-length text event at track-end. | |
if no_eot_magic: | |
# Exceptional case: don't mess with track-final | |
# 0-length text_events; just peg on an end_track | |
events.append(['end_track', 0]) | |
else: | |
# NORMAL CASE: replace with an end_track, leaving DTime | |
last[0] = 'end_track' | |
else: | |
# last event was neither 0-length text_event nor end_track | |
events.append(['end_track', 0]) | |
else: # an eventless track! | |
events = [['end_track', 0],] | |
# maybe_running_status = not no_running_status # unused? 4.7 | |
last_status = -1 | |
for event_r in (events): | |
E = copy.deepcopy(event_r) | |
# otherwise the shifting'd corrupt the original | |
if not E: | |
continue | |
event = E.pop(0) | |
if not len(event): | |
continue | |
dtime = int(E.pop(0)) | |
# print('event='+str(event)+' dtime='+str(dtime)) | |
event_data = '' | |
if ( # MIDI events -- eligible for running status | |
event == 'note_on' | |
or event == 'note_off' | |
or event == 'control_change' | |
or event == 'key_after_touch' | |
or event == 'patch_change' | |
or event == 'channel_after_touch' | |
or event == 'pitch_wheel_change' ): | |
# This block is where we spend most of the time. Gotta be tight. | |
if (event == 'note_off'): | |
status = 0x80 | (int(E[0]) & 0x0F) | |
parameters = struct.pack('>BB', int(E[1])&0x7F, int(E[2])&0x7F) | |
elif (event == 'note_on'): | |
status = 0x90 | (int(E[0]) & 0x0F) | |
parameters = struct.pack('>BB', int(E[1])&0x7F, int(E[2])&0x7F) | |
elif (event == 'key_after_touch'): | |
status = 0xA0 | (int(E[0]) & 0x0F) | |
parameters = struct.pack('>BB', int(E[1])&0x7F, int(E[2])&0x7F) | |
elif (event == 'control_change'): | |
status = 0xB0 | (int(E[0]) & 0x0F) | |
parameters = struct.pack('>BB', int(E[1])&0xFF, int(E[2])&0xFF) | |
elif (event == 'patch_change'): | |
status = 0xC0 | (int(E[0]) & 0x0F) | |
parameters = struct.pack('>B', int(E[1]) & 0xFF) | |
elif (event == 'channel_after_touch'): | |
status = 0xD0 | (int(E[0]) & 0x0F) | |
parameters = struct.pack('>B', int(E[1]) & 0xFF) | |
elif (event == 'pitch_wheel_change'): | |
status = 0xE0 | (int(E[0]) & 0x0F) | |
parameters = _write_14_bit(int(E[1]) + 0x2000) | |
else: | |
_warn("BADASS FREAKOUT ERROR 31415!") | |
# And now the encoding | |
# w = BER compressed integer (not ASN.1 BER, see perlpacktut for | |
# details). Its bytes represent an unsigned integer in base 128, | |
# most significant digit first, with as few digits as possible. | |
# Bit eight (the high bit) is set on each byte except the last. | |
data.append(_ber_compressed_int(dtime)) | |
if (status != last_status) or no_running_status: | |
data.append(struct.pack('>B', status)) | |
data.append(parameters) | |
last_status = status | |
continue | |
else: | |
# Not a MIDI event. | |
# All the code in this block could be more efficient, | |
# but this is not where the code needs to be tight. | |
# print "zaz $event\n"; | |
last_status = -1 | |
if event == 'raw_meta_event': | |
event_data = _some_text_event(int(E[0]), E[1]) | |
elif (event == 'set_sequence_number'): # 3.9 | |
event_data = b'\xFF\x00\x02'+_int2twobytes(E[0]) | |
# Text meta-events... | |
# a case for a dict, I think (pjb) ... | |
elif (event == 'text_event'): | |
event_data = _some_text_event(0x01, E[0]) | |
elif (event == 'copyright_text_event'): | |
event_data = _some_text_event(0x02, E[0]) | |
elif (event == 'track_name'): | |
event_data = _some_text_event(0x03, E[0]) | |
elif (event == 'instrument_name'): | |
event_data = _some_text_event(0x04, E[0]) | |
elif (event == 'lyric'): | |
event_data = _some_text_event(0x05, E[0]) | |
elif (event == 'marker'): | |
event_data = _some_text_event(0x06, E[0]) | |
elif (event == 'cue_point'): | |
event_data = _some_text_event(0x07, E[0]) | |
elif (event == 'text_event_08'): | |
event_data = _some_text_event(0x08, E[0]) | |
elif (event == 'text_event_09'): | |
event_data = _some_text_event(0x09, E[0]) | |
elif (event == 'text_event_0a'): | |
event_data = _some_text_event(0x0A, E[0]) | |
elif (event == 'text_event_0b'): | |
event_data = _some_text_event(0x0B, E[0]) | |
elif (event == 'text_event_0c'): | |
event_data = _some_text_event(0x0C, E[0]) | |
elif (event == 'text_event_0d'): | |
event_data = _some_text_event(0x0D, E[0]) | |
elif (event == 'text_event_0e'): | |
event_data = _some_text_event(0x0E, E[0]) | |
elif (event == 'text_event_0f'): | |
event_data = _some_text_event(0x0F, E[0]) | |
# End of text meta-events | |
elif (event == 'end_track'): | |
event_data = b"\xFF\x2F\x00" | |
elif (event == 'set_tempo'): | |
#event_data = struct.pack(">BBwa*", 0xFF, 0x51, 3, | |
# substr( struct.pack('>I', E[0]), 1, 3)) | |
event_data = b'\xFF\x51\x03'+struct.pack('>I',E[0])[1:] | |
elif (event == 'smpte_offset'): | |
# event_data = struct.pack(">BBwBBBBB", 0xFF, 0x54, 5, E[0:5] ) | |
event_data = struct.pack(">BBBbBBBB", 0xFF,0x54,0x05,E[0],E[1],E[2],E[3],E[4]) | |
elif (event == 'time_signature'): | |
# event_data = struct.pack(">BBwBBBB", 0xFF, 0x58, 4, E[0:4] ) | |
event_data = struct.pack(">BBBbBBB", 0xFF, 0x58, 0x04, E[0],E[1],E[2],E[3]) | |
elif (event == 'key_signature'): | |
event_data = struct.pack(">BBBbB", 0xFF, 0x59, 0x02, E[0],E[1]) | |
elif (event == 'sequencer_specific'): | |
# event_data = struct.pack(">BBwa*", 0xFF,0x7F, len(E[0]), E[0]) | |
event_data = _some_text_event(0x7F, E[0]) | |
# End of Meta-events | |
# Other Things... | |
elif (event == 'sysex_f0'): | |
#event_data = struct.pack(">Bwa*", 0xF0, len(E[0]), E[0]) | |
#B=bitstring w=BER-compressed-integer a=null-padded-ascii-str | |
event_data = bytearray(b'\xF0')+_ber_compressed_int(len(E[0]))+bytearray(E[0]) | |
elif (event == 'sysex_f7'): | |
#event_data = struct.pack(">Bwa*", 0xF7, len(E[0]), E[0]) | |
event_data = bytearray(b'\xF7')+_ber_compressed_int(len(E[0]))+bytearray(E[0]) | |
elif (event == 'song_position'): | |
event_data = b"\xF2" + _write_14_bit( E[0] ) | |
elif (event == 'song_select'): | |
event_data = struct.pack('>BB', 0xF3, E[0] ) | |
elif (event == 'tune_request'): | |
event_data = b"\xF6" | |
elif (event == 'raw_data'): | |
_warn("_encode: raw_data event not supported") | |
# event_data = E[0] | |
continue | |
# End of Other Stuff | |
else: | |
# The Big Fallthru | |
if unknown_callback: | |
# push(@data, &{ $unknown_callback }( @$event_r )) | |
pass | |
else: | |
_warn("Unknown event: "+str(event)) | |
# To surpress complaint here, just set | |
# 'unknown_callback' => sub { return () } | |
continue | |
#print "Event $event encoded part 2\n" | |
if str(type(event_data)).find("'str'") >= 0: | |
event_data = bytearray(event_data.encode('Latin1', 'ignore')) | |
if len(event_data): # how could $event_data be empty | |
# data.append(struct.pack('>wa*', dtime, event_data)) | |
# print(' event_data='+str(event_data)) | |
data.append(_ber_compressed_int(dtime)+event_data) | |
return b''.join(data) | |
#=============================================================================== | |
""" | |
================================================================================ | |
pyFluidSynth | |
Python bindings for FluidSynth | |
Copyright 2008, Nathan Whitehead <nwhitehe@gmail.com> | |
Released under the LGPL | |
This module contains python bindings for FluidSynth. FluidSynth is a | |
software synthesizer for generating music. It works like a MIDI | |
synthesizer. You load patches, set parameters, then send NOTEON and | |
NOTEOFF events to play notes. Instruments are defined in SoundFonts, | |
generally files with the extension SF2. FluidSynth can either be used | |
to play audio itself, or you can call a function that returns chunks | |
of audio data and output the data to the soundcard yourself. | |
FluidSynth works on all major platforms, so pyFluidSynth should also. | |
================================================================================ | |
""" | |
from ctypes import * | |
from ctypes.util import find_library | |
import os | |
# A short circuited or expression to find the FluidSynth library | |
# (mostly needed for Windows distributions of libfluidsynth supplied with QSynth) | |
# DLL search method changed in Python 3.8 | |
# https://docs.python.org/3/library/os.html#os.add_dll_directory | |
if hasattr(os, 'add_dll_directory'): | |
os.add_dll_directory(os.getcwd()) | |
lib = find_library('fluidsynth') or \ | |
find_library('libfluidsynth') or \ | |
find_library('libfluidsynth-3') or \ | |
find_library('libfluidsynth-2') or \ | |
find_library('libfluidsynth-1') | |
if lib is None: | |
raise ImportError("Couldn't find the FluidSynth library.") | |
# Dynamically link the FluidSynth library | |
# Architecture (32-/64-bit) must match your Python version | |
_fl = CDLL(lib) | |
# Helper function for declaring function prototypes | |
def cfunc(name, result, *args): | |
"""Build and apply a ctypes prototype complete with parameter flags""" | |
if hasattr(_fl, name): | |
atypes = [] | |
aflags = [] | |
for arg in args: | |
atypes.append(arg[1]) | |
aflags.append((arg[2], arg[0]) + arg[3:]) | |
return CFUNCTYPE(result, *atypes)((name, _fl), tuple(aflags)) | |
else: # Handle Fluidsynth 1.x, 2.x, etc. API differences | |
return None | |
# Bump this up when changing the interface for users | |
api_version = '1.3.1' | |
# Function prototypes for C versions of functions | |
FLUID_OK = 0 | |
FLUID_FAILED = -1 | |
fluid_version = cfunc('fluid_version', c_void_p, | |
('major', POINTER(c_int), 1), | |
('minor', POINTER(c_int), 1), | |
('micro', POINTER(c_int), 1)) | |
majver = c_int() | |
fluid_version(majver, c_int(), c_int()) | |
if majver.value > 1: | |
FLUIDSETTING_EXISTS = FLUID_OK | |
else: | |
FLUIDSETTING_EXISTS = 1 | |
# fluid settings | |
new_fluid_settings = cfunc('new_fluid_settings', c_void_p) | |
fluid_settings_setstr = cfunc('fluid_settings_setstr', c_int, | |
('settings', c_void_p, 1), | |
('name', c_char_p, 1), | |
('str', c_char_p, 1)) | |
fluid_settings_setnum = cfunc('fluid_settings_setnum', c_int, | |
('settings', c_void_p, 1), | |
('name', c_char_p, 1), | |
('val', c_double, 1)) | |
fluid_settings_setint = cfunc('fluid_settings_setint', c_int, | |
('settings', c_void_p, 1), | |
('name', c_char_p, 1), | |
('val', c_int, 1)) | |
fluid_settings_copystr = cfunc('fluid_settings_copystr', c_int, | |
('settings', c_void_p, 1), | |
('name', c_char_p, 1), | |
('str', c_char_p, 1), | |
('len', c_int, 1)) | |
fluid_settings_getnum = cfunc('fluid_settings_getnum', c_int, | |
('settings', c_void_p, 1), | |
('name', c_char_p, 1), | |
('val', POINTER(c_double), 1)) | |
fluid_settings_getint = cfunc('fluid_settings_getint', c_int, | |
('settings', c_void_p, 1), | |
('name', c_char_p, 1), | |
('val', POINTER(c_int), 1)) | |
delete_fluid_settings = cfunc('delete_fluid_settings', None, | |
('settings', c_void_p, 1)) | |
fluid_synth_activate_key_tuning = cfunc('fluid_synth_activate_key_tuning', c_int, | |
('synth', c_void_p, 1), | |
('bank', c_int, 1), | |
('prog', c_int, 1), | |
('name', c_char_p, 1), | |
('pitch', POINTER(c_double), 1), | |
('apply', c_int, 1)) | |
fluid_synth_activate_tuning = cfunc('fluid_synth_activate_tuning', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('bank', c_int, 1), | |
('prog', c_int, 1), | |
('apply', c_int, 1)) | |
fluid_synth_deactivate_tuning = cfunc('fluid_synth_deactivate_tuning', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('apply', c_int, 1)) | |
fluid_synth_tuning_dump = cfunc('fluid_synth_tuning_dump', c_int, | |
('synth', c_void_p, 1), | |
('bank', c_int, 1), | |
('prog', c_int, 1), | |
('name', c_char_p, 1), | |
('length', c_int, 1), | |
('pitch', POINTER(c_double), 1)) | |
# fluid synth | |
new_fluid_synth = cfunc('new_fluid_synth', c_void_p, | |
('settings', c_void_p, 1)) | |
delete_fluid_synth = cfunc('delete_fluid_synth', None, | |
('synth', c_void_p, 1)) | |
fluid_synth_sfload = cfunc('fluid_synth_sfload', c_int, | |
('synth', c_void_p, 1), | |
('filename', c_char_p, 1), | |
('update_midi_presets', c_int, 1)) | |
fluid_synth_sfunload = cfunc('fluid_synth_sfunload', c_int, | |
('synth', c_void_p, 1), | |
('sfid', c_int, 1), | |
('update_midi_presets', c_int, 1)) | |
fluid_synth_program_select = cfunc('fluid_synth_program_select', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('sfid', c_int, 1), | |
('bank', c_int, 1), | |
('preset', c_int, 1)) | |
fluid_synth_noteon = cfunc('fluid_synth_noteon', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('key', c_int, 1), | |
('vel', c_int, 1)) | |
fluid_synth_noteoff = cfunc('fluid_synth_noteoff', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('key', c_int, 1)) | |
fluid_synth_pitch_bend = cfunc('fluid_synth_pitch_bend', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('val', c_int, 1)) | |
fluid_synth_cc = cfunc('fluid_synth_cc', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('ctrl', c_int, 1), | |
('val', c_int, 1)) | |
fluid_synth_get_cc = cfunc('fluid_synth_get_cc', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('num', c_int, 1), | |
('pval', POINTER(c_int), 1)) | |
fluid_synth_program_change = cfunc('fluid_synth_program_change', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('prg', c_int, 1)) | |
fluid_synth_unset_program = cfunc('fluid_synth_unset_program', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1)) | |
fluid_synth_get_program = cfunc('fluid_synth_get_program', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('sfont_id', POINTER(c_int), 1), | |
('bank_num', POINTER(c_int), 1), | |
('preset_num', POINTER(c_int), 1)) | |
fluid_synth_bank_select = cfunc('fluid_synth_bank_select', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('bank', c_int, 1)) | |
fluid_synth_sfont_select = cfunc('fluid_synth_sfont_select', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('sfid', c_int, 1)) | |
fluid_synth_program_reset = cfunc('fluid_synth_program_reset', c_int, | |
('synth', c_void_p, 1)) | |
fluid_synth_system_reset = cfunc('fluid_synth_system_reset', c_int, | |
('synth', c_void_p, 1)) | |
fluid_synth_write_s16 = cfunc('fluid_synth_write_s16', c_void_p, | |
('synth', c_void_p, 1), | |
('len', c_int, 1), | |
('lbuf', c_void_p, 1), | |
('loff', c_int, 1), | |
('lincr', c_int, 1), | |
('rbuf', c_void_p, 1), | |
('roff', c_int, 1), | |
('rincr', c_int, 1)) | |
fluid_synth_all_notes_off = cfunc('fluid_synth_all_notes_off', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1)) | |
fluid_synth_all_sounds_off = cfunc('fluid_synth_all_sounds_off', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1)) | |
class fluid_synth_channel_info_t(Structure): | |
_fields_ = [ | |
('assigned', c_int), | |
('sfont_id', c_int), | |
('bank', c_int), | |
('program', c_int), | |
('name', c_char*32), | |
('reserved', c_char*32)] | |
fluid_synth_get_channel_info = cfunc('fluid_synth_get_channel_info', c_int, | |
('synth', c_void_p, 1), | |
('chan', c_int, 1), | |
('info', POINTER(fluid_synth_channel_info_t), 1)) | |
fluid_synth_set_reverb_full = cfunc('fluid_synth_set_reverb_full', c_int, | |
('synth', c_void_p, 1), | |
('set', c_int, 1), | |
('roomsize', c_double, 1), | |
('damping', c_double, 1), | |
('width', c_double, 1), | |
('level', c_double, 1)) | |
fluid_synth_set_chorus_full = cfunc('fluid_synth_set_chorus_full', c_int, | |
('synth', c_void_p, 1), | |
('set', c_int, 1), | |
('nr', c_int, 1), | |
('level', c_double, 1), | |
('speed', c_double, 1), | |
('depth_ms', c_double, 1), | |
('type', c_int, 1)) | |
fluid_synth_set_reverb = cfunc('fluid_synth_set_reverb', c_int, | |
('synth', c_void_p, 1), | |
('roomsize', c_double, 1), | |
('damping', c_double, 1), | |
('width', c_double, 1), | |
('level', c_double, 1)) | |
fluid_synth_set_chorus = cfunc('fluid_synth_set_chorus', c_int, | |
('synth', c_void_p, 1), | |
('nr', c_int, 1), | |
('level', c_double, 1), | |
('speed', c_double, 1), | |
('depth_ms', c_double, 1), | |
('type', c_int, 1)) | |
fluid_synth_set_reverb_roomsize = cfunc('fluid_synth_set_reverb_roomsize', c_int, | |
('synth', c_void_p, 1), | |
('roomsize', c_double, 1)) | |
fluid_synth_set_reverb_damp = cfunc('fluid_synth_set_reverb_damp', c_int, | |
('synth', c_void_p, 1), | |
('damping', c_double, 1)) | |
fluid_synth_set_reverb_level = cfunc('fluid_synth_set_reverb_level', c_int, | |
('synth', c_void_p, 1), | |
('level', c_double, 1)) | |
fluid_synth_set_reverb_width = cfunc('fluid_synth_set_reverb_width', c_int, | |
('synth', c_void_p, 1), | |
('width', c_double, 1)) | |
fluid_synth_set_chorus_nr = cfunc('fluid_synth_set_chorus_nr', c_int, | |
('synth', c_void_p, 1), | |
('nr', c_int, 1)) | |
fluid_synth_set_chorus_level = cfunc('fluid_synth_set_chorus_level', c_int, | |
('synth', c_void_p, 1), | |
('level', c_double, 1)) | |
fluid_synth_set_chorus_type = cfunc('fluid_synth_set_chorus_type', c_int, | |
('synth', c_void_p, 1), | |
('type', c_int, 1)) | |
fluid_synth_get_reverb_roomsize = cfunc('fluid_synth_get_reverb_roomsize', c_double, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_reverb_damp = cfunc('fluid_synth_get_reverb_damp', c_double, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_reverb_level = cfunc('fluid_synth_get_reverb_level', c_double, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_reverb_width = cfunc('fluid_synth_get_reverb_width', c_double, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_chorus_nr = cfunc('fluid_synth_get_chorus_nr', c_int, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_chorus_level = cfunc('fluid_synth_get_chorus_level', c_double, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_chorus_speed_Hz = cfunc('fluid_synth_get_chorus_speed_Hz', c_double, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_chorus_depth_ms = cfunc('fluid_synth_get_chorus_depth_ms', c_double, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_chorus_type = cfunc('fluid_synth_get_chorus_type', c_int, | |
('synth', c_void_p, 1)) | |
fluid_synth_set_midi_router = cfunc('fluid_synth_set_midi_router', None, | |
('synth', c_void_p, 1), | |
('router', c_void_p, 1)) | |
fluid_synth_handle_midi_event = cfunc('fluid_synth_handle_midi_event', c_int, | |
('data', c_void_p, 1), | |
('event', c_void_p, 1)) | |
# fluid sequencer | |
new_fluid_sequencer2 = cfunc('new_fluid_sequencer2', c_void_p, | |
('use_system_timer', c_int, 1)) | |
fluid_sequencer_process = cfunc('fluid_sequencer_process', None, | |
('seq', c_void_p, 1), | |
('msec', c_uint, 1)) | |
fluid_sequencer_register_fluidsynth = cfunc('fluid_sequencer_register_fluidsynth', c_short, | |
('seq', c_void_p, 1), | |
('synth', c_void_p, 1)) | |
fluid_sequencer_register_client = cfunc('fluid_sequencer_register_client', c_short, | |
('seq', c_void_p, 1), | |
('name', c_char_p, 1), | |
('callback', CFUNCTYPE(None, c_uint, c_void_p, c_void_p, c_void_p), 1), | |
('data', c_void_p, 1)) | |
fluid_sequencer_get_tick = cfunc('fluid_sequencer_get_tick', c_uint, | |
('seq', c_void_p, 1)) | |
fluid_sequencer_set_time_scale = cfunc('fluid_sequencer_set_time_scale', None, | |
('seq', c_void_p, 1), | |
('scale', c_double, 1)) | |
fluid_sequencer_get_time_scale = cfunc('fluid_sequencer_get_time_scale', c_double, | |
('seq', c_void_p, 1)) | |
fluid_sequencer_send_at = cfunc('fluid_sequencer_send_at', c_int, | |
('seq', c_void_p, 1), | |
('evt', c_void_p, 1), | |
('time', c_uint, 1), | |
('absolute', c_int, 1)) | |
delete_fluid_sequencer = cfunc('delete_fluid_sequencer', None, | |
('seq', c_void_p, 1)) | |
# fluid event | |
new_fluid_event = cfunc('new_fluid_event', c_void_p) | |
fluid_event_set_source = cfunc('fluid_event_set_source', None, | |
('evt', c_void_p, 1), | |
('src', c_void_p, 1)) | |
fluid_event_set_dest = cfunc('fluid_event_set_dest', None, | |
('evt', c_void_p, 1), | |
('dest', c_void_p, 1)) | |
fluid_event_timer = cfunc('fluid_event_timer', None, | |
('evt', c_void_p, 1), | |
('data', c_void_p, 1)) | |
fluid_event_note = cfunc('fluid_event_note', None, | |
('evt', c_void_p, 1), | |
('channel', c_int, 1), | |
('key', c_short, 1), | |
('vel', c_short, 1), | |
('duration', c_uint, 1)) | |
fluid_event_noteon = cfunc('fluid_event_noteon', None, | |
('evt', c_void_p, 1), | |
('channel', c_int, 1), | |
('key', c_short, 1), | |
('vel', c_short, 1)) | |
fluid_event_noteoff = cfunc('fluid_event_noteoff', None, | |
('evt', c_void_p, 1), | |
('channel', c_int, 1), | |
('key', c_short, 1)) | |
delete_fluid_event = cfunc('delete_fluid_event', None, | |
('evt', c_void_p, 1)) | |
fluid_midi_event_get_channel = cfunc('fluid_midi_event_get_channel', c_int, | |
('evt', c_void_p, 1)) | |
fluid_midi_event_get_control = cfunc('fluid_midi_event_get_control', c_int, | |
('evt', c_void_p, 1)) | |
fluid_midi_event_get_program = cfunc('fluid_midi_event_get_program', c_int, | |
('evt', c_void_p, 1)) | |
fluid_midi_event_get_key = cfunc('fluid_midi_event_get_key', c_int, | |
('evt', c_void_p, 1)) | |
fluid_midi_event_get_type = cfunc('fluid_midi_event_get_type', c_int, | |
('evt', c_void_p, 1)) | |
fluid_midi_event_get_value = cfunc('fluid_midi_event_get_value', c_int, | |
('evt', c_void_p, 1)) | |
fluid_midi_event_get_velocity = cfunc('fluid_midi_event_get_velocity', c_int, | |
('evt', c_void_p, 1)) | |
# fluid_player_status returned by fluid_player_get_status() | |
FLUID_PLAYER_READY = 0 | |
FLUID_PLAYER_PLAYING = 1 | |
FLUID_PLAYER_STOPPING = 2 | |
FLUID_PLAYER_DONE = 3 | |
# tempo_type used by fluid_player_set_tempo() | |
FLUID_PLAYER_TEMPO_INTERNAL = 0 | |
FLUID_PLAYER_TEMPO_EXTERNAL_BPM = 1 | |
FLUID_PLAYER_TEMPO_EXTERNAL_MIDI = 2 | |
new_fluid_player = cfunc('new_fluid_player', c_void_p, | |
('synth', c_void_p, 1)) | |
delete_fluid_player = cfunc('delete_fluid_player', None, | |
('player', c_void_p, 1)) | |
fluid_player_add = cfunc('fluid_player_add', c_int, | |
('player', c_void_p, 1), | |
('filename', c_char_p, 1)) | |
fluid_player_get_status = cfunc('fluid_player_get_status', c_int, | |
('player', c_void_p, 1)) | |
fluid_player_join = cfunc('fluid_player_join', c_int, | |
('player', c_void_p, 1)) | |
fluid_player_play = cfunc('fluid_player_play', c_int, | |
('player', c_void_p, 1)) | |
fluid_player_set_playback_callback = cfunc('fluid_player_set_playback_callback', c_int, | |
('player', c_void_p, 1), | |
('handler', CFUNCTYPE(c_int, c_void_p, c_void_p), 1), | |
('event_handler_data', c_void_p, 1)) | |
fluid_player_set_tempo = cfunc('fluid_player_set_tempo', c_int, | |
('player', c_void_p, 1), | |
('tempo_type', c_int, 1), | |
('tempo', c_double, 1)) | |
fluid_player_seek = cfunc('fluid_player_seek', c_int, | |
('player', c_void_p, 1), | |
('ticks', c_int, 1)) | |
fluid_player_stop = cfunc('fluid_player_stop', c_int, | |
('player', c_void_p, 1)) | |
# fluid audio driver | |
new_fluid_audio_driver = cfunc('new_fluid_audio_driver', c_void_p, | |
('settings', c_void_p, 1), | |
('synth', c_void_p, 1)) | |
delete_fluid_audio_driver = cfunc('delete_fluid_audio_driver', None, | |
('driver', c_void_p, 1)) | |
# fluid midi driver | |
new_fluid_midi_driver = cfunc('new_fluid_midi_driver', c_void_p, | |
('settings', c_void_p, 1), | |
('handler', CFUNCTYPE(c_int, c_void_p, c_void_p), 1), | |
('event_handler_data', c_void_p, 1)) | |
# fluid midi router rule | |
class fluid_midi_router_t(Structure): | |
_fields_ = [ | |
('synth', c_void_p), | |
('rules_mutex', c_void_p), | |
('rules', c_void_p*6), | |
('free_rules', c_void_p), | |
('event_handler', c_void_p), | |
('event_handler_data', c_void_p), | |
('nr_midi_channels', c_int), | |
('cmd_rule', c_void_p), | |
('cmd_rule_type', POINTER(c_int))] | |
delete_fluid_midi_router_rule = cfunc('delete_fluid_midi_router_rule', c_int, | |
('rule', c_void_p, 1)) | |
new_fluid_midi_router_rule = cfunc('new_fluid_midi_router_rule', c_void_p) | |
fluid_midi_router_rule_set_chan = cfunc('fluid_midi_router_rule_set_chan', None, | |
('rule', c_void_p, 1), | |
('min', c_int, 1), | |
('max', c_int, 1), | |
('mul', c_float, 1), | |
('add', c_int, 1)) | |
fluid_midi_router_rule_set_param1 = cfunc('fluid_midi_router_rule_set_param1', None, | |
('rule', c_void_p, 1), | |
('min', c_int, 1), | |
('max', c_int, 1), | |
('mul', c_float, 1), | |
('add', c_int, 1)) | |
fluid_midi_router_rule_set_param2 = cfunc('fluid_midi_router_rule_set_param2', None, | |
('rule', c_void_p, 1), | |
('min', c_int, 1), | |
('max', c_int, 1), | |
('mul', c_float, 1), | |
('add', c_int, 1)) | |
# fluid midi router | |
new_fluid_midi_router = cfunc('new_fluid_midi_router', POINTER(fluid_midi_router_t), | |
('settings', c_void_p, 1), | |
('handler', CFUNCTYPE(c_int, c_void_p, c_void_p), 1), | |
('event_handler_data', c_void_p, 1)) | |
fluid_midi_router_handle_midi_event = cfunc('fluid_midi_router_handle_midi_event', c_int, | |
('data', c_void_p, 1), | |
('event', c_void_p, 1)) | |
fluid_midi_router_clear_rules = cfunc('fluid_midi_router_clear_rules', c_int, | |
('router', POINTER(fluid_midi_router_t), 1)) | |
fluid_midi_router_set_default_rules = cfunc('fluid_midi_router_set_default_rules', c_int, | |
('router', POINTER(fluid_midi_router_t), 1)) | |
fluid_midi_router_add_rule = cfunc('fluid_midi_router_add_rule', c_int, | |
('router', POINTER(fluid_midi_router_t), 1), | |
('rule', c_void_p, 1), | |
('type', c_int, 1)) | |
# fluidsynth 2.x | |
new_fluid_cmd_handler=cfunc('new_fluid_cmd_handler', c_void_p, | |
('synth', c_void_p, 1), | |
('router', c_void_p, 1)) | |
fluid_synth_get_sfont_by_id = cfunc('fluid_synth_get_sfont_by_id', c_void_p, | |
('synth', c_void_p, 1), | |
('id', c_int, 1)) | |
fluid_sfont_get_preset = cfunc('fluid_sfont_get_preset', c_void_p, | |
('sfont', c_void_p, 1), | |
('banknum', c_int, 1), | |
('prenum', c_int, 1)) | |
fluid_preset_get_name = cfunc('fluid_preset_get_name', c_char_p, | |
('preset', c_void_p, 1)) | |
fluid_synth_set_reverb = cfunc('fluid_synth_set_reverb', c_int, | |
('synth', c_void_p, 1), | |
('roomsize', c_double, 1), | |
('damping', c_double, 1), | |
('width', c_double, 1), | |
('level', c_double, 1)) | |
fluid_synth_set_chorus = cfunc('fluid_synth_set_chorus', c_int, | |
('synth', c_void_p, 1), | |
('nr', c_int, 1), | |
('level', c_double, 1), | |
('speed', c_double, 1), | |
('depth_ms', c_double, 1), | |
('type', c_int, 1)) | |
fluid_synth_get_chorus_speed = cfunc('fluid_synth_get_chorus_speed', c_double, | |
('synth', c_void_p, 1)) | |
fluid_synth_get_chorus_depth = cfunc('fluid_synth_get_chorus_depth', c_double, | |
('synth', c_void_p, 1)) | |
def fluid_synth_write_s16_stereo(synth, len): | |
"""Return generated samples in stereo 16-bit format | |
Return value is a Numpy array of samples. | |
""" | |
import numpy | |
buf = create_string_buffer(len * 4) | |
fluid_synth_write_s16(synth, len, buf, 0, 2, buf, 1, 2) | |
return numpy.frombuffer(buf[:], dtype=numpy.int16) | |
# Object-oriented interface, simplifies access to functions | |
class Synth: | |
"""Synth represents a FluidSynth synthesizer""" | |
def __init__(self, gain=0.2, samplerate=44100, channels=256, **kwargs): | |
"""Create new synthesizer object to control sound generation | |
Optional keyword arguments: | |
gain : scale factor for audio output, default is 0.2 | |
lower values are quieter, allow more simultaneous notes | |
samplerate : output samplerate in Hz, default is 44100 Hz | |
added capability for passing arbitrary fluid settings using args | |
""" | |
self.settings = new_fluid_settings() | |
self.setting('synth.gain', gain) | |
self.setting('synth.sample-rate', float(samplerate)) | |
self.setting('synth.midi-channels', channels) | |
for opt,val in kwargs.items(): | |
self.setting(opt, val) | |
self.synth = new_fluid_synth(self.settings) | |
self.audio_driver = None | |
self.midi_driver = None | |
self.router = None | |
def setting(self, opt, val): | |
"""change an arbitrary synth setting, type-smart""" | |
if isinstance(val, (str, bytes)): | |
fluid_settings_setstr(self.settings, opt.encode(), val.encode()) | |
elif isinstance(val, int): | |
fluid_settings_setint(self.settings, opt.encode(), val) | |
elif isinstance(val, float): | |
fluid_settings_setnum(self.settings, opt.encode(), c_double(val)) | |
def get_setting(self, opt): | |
"""get current value of an arbitrary synth setting""" | |
val = c_int() | |
if fluid_settings_getint(self.settings, opt.encode(), byref(val)) == FLUIDSETTING_EXISTS: | |
return val.value | |
strval = create_string_buffer(32) | |
if fluid_settings_copystr(self.settings, opt.encode(), strval, 32) == FLUIDSETTING_EXISTS: | |
return strval.value.decode() | |
num = c_double() | |
if fluid_settings_getnum(self.settings, opt.encode(), byref(num)) == FLUIDSETTING_EXISTS: | |
return round(num.value, 6) | |
return None | |
def start(self, driver=None, device=None, midi_driver=None, midi_router=None): | |
"""Start audio output driver in separate background thread | |
Call this function any time after creating the Synth object. | |
If you don't call this function, use get_samples() to generate | |
samples. | |
Optional keyword argument: | |
driver : which audio driver to use for output | |
device : the device to use for audio output | |
midi_driver : the midi driver to use for communicating with midi devices | |
see http://www.fluidsynth.org/api/fluidsettings.xml for allowed values and defaults by platform | |
""" | |
driver = driver or self.get_setting('audio.driver') | |
device = device or self.get_setting('audio.%s.device' % driver) | |
midi_driver = midi_driver or self.get_setting('midi.driver') | |
self.setting('audio.driver', driver) | |
self.setting('audio.%s.device' % driver, device) | |
self.audio_driver = new_fluid_audio_driver(self.settings, self.synth) | |
self.setting('midi.driver', midi_driver) | |
self.router = new_fluid_midi_router(self.settings, fluid_synth_handle_midi_event, self.synth) | |
if new_fluid_cmd_handler: | |
new_fluid_cmd_handler(self.synth, self.router) | |
else: | |
fluid_synth_set_midi_router(self.synth, self.router) | |
if midi_router == None: ## Use fluidsynth to create a MIDI event handler | |
self.midi_driver = new_fluid_midi_driver(self.settings, fluid_midi_router_handle_midi_event, self.router) | |
self.custom_router_callback = None | |
else: ## Supply an external MIDI event handler | |
self.custom_router_callback = CFUNCTYPE(c_int, c_void_p, c_void_p)(midi_router) | |
self.midi_driver = new_fluid_midi_driver(self.settings, self.custom_router_callback, self.router) | |
return FLUID_OK | |
def delete(self): | |
if self.audio_driver: | |
delete_fluid_audio_driver(self.audio_driver) | |
delete_fluid_synth(self.synth) | |
delete_fluid_settings(self.settings) | |
def sfload(self, filename, update_midi_preset=0): | |
"""Load SoundFont and return its ID""" | |
return fluid_synth_sfload(self.synth, filename.encode(), update_midi_preset) | |
def sfunload(self, sfid, update_midi_preset=0): | |
"""Unload a SoundFont and free memory it used""" | |
return fluid_synth_sfunload(self.synth, sfid, update_midi_preset) | |
def program_select(self, chan, sfid, bank, preset): | |
"""Select a program""" | |
return fluid_synth_program_select(self.synth, chan, sfid, bank, preset) | |
def program_unset(self, chan): | |
"""Set the preset of a MIDI channel to an unassigned state""" | |
return fluid_synth_unset_program(self.synth, chan) | |
def channel_info(self, chan): | |
"""get soundfont, bank, prog, preset name of channel""" | |
if fluid_synth_get_channel_info is not None: | |
info=fluid_synth_channel_info_t() | |
fluid_synth_get_channel_info(self.synth, chan, byref(info)) | |
return (info.sfont_id, info.bank, info.program, info.name) | |
else: | |
(sfontid, banknum, presetnum) = self.program_info(chan) | |
presetname = self.sfpreset_name(sfontid, banknum, presetnum) | |
return (sfontid, banknum, presetnum, presetname) | |
def program_info(self, chan): | |
"""get active soundfont, bank, prog on a channel""" | |
if fluid_synth_get_program is not None: | |
sfontid=c_int() | |
banknum=c_int() | |
presetnum=c_int() | |
fluid_synth_get_program(self.synth, chan, byref(sfontid), byref(banknum), byref(presetnum)) | |
return (sfontid.value, banknum.value, presetnum.value) | |
else: | |
(sfontid, banknum, prognum, presetname) = self.channel_info(chan) | |
return (sfontid, banknum, prognum) | |
def sfpreset_name(self, sfid, bank, prenum): | |
"""Return name of a soundfont preset""" | |
if fluid_synth_get_sfont_by_id is not None: | |
sfont=fluid_synth_get_sfont_by_id(self.synth, sfid) | |
preset=fluid_sfont_get_preset(sfont, bank, prenum) | |
if not preset: | |
return None | |
return fluid_preset_get_name(preset).decode('ascii') | |
else: | |
(sfontid, banknum, presetnum, presetname) = self.channel_info(chan) | |
return presetname | |
def router_clear(self): | |
if self.router is not None: | |
fluid_midi_router_clear_rules(self.router) | |
def router_default(self): | |
if self.router is not None: | |
fluid_midi_router_set_default_rules(self.router) | |
def router_begin(self, type): | |
"""types are [note|cc|prog|pbend|cpress|kpress]""" | |
if self.router is not None: | |
if type=='note': | |
self.router.cmd_rule_type=0 | |
elif type=='cc': | |
self.router.cmd_rule_type=1 | |
elif type=='prog': | |
self.router.cmd_rule_type=2 | |
elif type=='pbend': | |
self.router.cmd_rule_type=3 | |
elif type=='cpress': | |
self.router.cmd_rule_type=4 | |
elif type=='kpress': | |
self.router.cmd_rule_type=5 | |
if 'self.router.cmd_rule' in globals(): | |
delete_fluid_midi_router_rule(self.router.cmd_rule) | |
self.router.cmd_rule = new_fluid_midi_router_rule() | |
def router_end(self): | |
if self.router is not None: | |
if self.router.cmd_rule is None: | |
return | |
if fluid_midi_router_add_rule(self.router, self.router.cmd_rule, self.router.cmd_rule_type)<0: | |
delete_fluid_midi_router_rule(self.router.cmd_rule) | |
self.router.cmd_rule=None | |
def router_chan(self, min, max, mul, add): | |
if self.router is not None: | |
fluid_midi_router_rule_set_chan(self.router.cmd_rule, min, max, mul, add) | |
def router_par1(self, min, max, mul, add): | |
if self.router is not None: | |
fluid_midi_router_rule_set_param1(self.router.cmd_rule, min, max, mul, add) | |
def router_par2(self, min, max, mul, add): | |
if self.router is not None: | |
fluid_midi_router_rule_set_param2(self.router.cmd_rule, min, max, mul, add) | |
def set_reverb(self, roomsize=-1.0, damping=-1.0, width=-1.0, level=-1.0): | |
""" | |
roomsize Reverb room size value (0.0-1.0) | |
damping Reverb damping value (0.0-1.0) | |
width Reverb width value (0.0-100.0) | |
level Reverb level value (0.0-1.0) | |
""" | |
if fluid_synth_set_reverb is not None: | |
return fluid_synth_set_reverb(self.synth, roomsize, damping, width, level) | |
else: | |
set=0 | |
if roomsize>=0: | |
set+=0b0001 | |
if damping>=0: | |
set+=0b0010 | |
if width>=0: | |
set+=0b0100 | |
if level>=0: | |
set+=0b1000 | |
return fluid_synth_set_reverb_full(self.synth, set, roomsize, damping, width, level) | |
def set_chorus(self, nr=-1, level=-1.0, speed=-1.0, depth=-1.0, type=-1): | |
""" | |
nr Chorus voice count (0-99, CPU time consumption proportional to this value) | |
level Chorus level (0.0-10.0) | |
speed Chorus speed in Hz (0.29-5.0) | |
depth_ms Chorus depth (max value depends on synth sample rate, 0.0-21.0 is safe for sample rate values up to 96KHz) | |
type Chorus waveform type (0=sine, 1=triangle) | |
""" | |
if fluid_synth_set_chorus is not None: | |
return fluid_synth_set_chorus(self.synth, nr, level, speed, depth, type) | |
else: | |
set=0 | |
if nr>=0: | |
set+=0b00001 | |
if level>=0: | |
set+=0b00010 | |
if speed>=0: | |
set+=0b00100 | |
if depth>=0: | |
set+=0b01000 | |
if type>=0: | |
set+=0b10000 | |
return fluid_synth_set_chorus_full(self.synth, set, nr, level, speed, depth, type) | |
def set_reverb_roomsize(self, roomsize): | |
if fluid_synth_set_reverb_roomsize is not None: | |
return fluid_synth_set_reverb_roomsize(self.synth, roomsize) | |
else: | |
return self.set_reverb(roomsize=roomsize) | |
def set_reverb_damp(self, damping): | |
if fluid_synth_set_reverb_damp is not None: | |
return fluid_synth_set_reverb_damp(self.synth, damping) | |
else: | |
return self.set_reverb(damping=damping) | |
def set_reverb_level(self, level): | |
if fluid_synth_set_reverb_level is not None: | |
return fluid_synth_set_reverb_level(self.synth, level) | |
else: | |
return self.set_reverb(level=level) | |
def set_reverb_width(self, width): | |
if fluid_synth_set_reverb_width is not None: | |
return fluid_synth_set_reverb_width(self.synth, width) | |
else: | |
return self.set_reverb(width=width) | |
def set_chorus_nr(self, nr): | |
if fluid_synth_set_chorus_nr is not None: | |
return fluid_synth_set_chorus_nr(self.synth, nr) | |
else: | |
return self.set_chorus(nr=nr) | |
def set_chorus_level(self, level): | |
if fluid_synth_set_chorus_level is not None: | |
return fluid_synth_set_chorus_level(self.synth, level) | |
else: | |
return self.set_chorus(leve=level) | |
def set_chorus_speed(self, speed): | |
if fluid_synth_set_chorus_speed is not None: | |
return fluid_synth_set_chorus_speed(self.synth, speed) | |
else: | |
return self.set_chorus(speed=speed) | |
def set_chorus_depth(self, depth): | |
if fluid_synth_set_chorus_depth is not None: | |
return fluid_synth_set_chorus_depth(self.synth, depth) | |
else: | |
return self.set_chorus(depth=depth) | |
def set_chorus_type(self, type): | |
if fluid_synth_set_chorus_type is not None: | |
return fluid_synth_set_chorus_type(self.synth, type) | |
else: | |
return self.set_chorus(type=type) | |
def get_reverb_roomsize(self): | |
return fluid_synth_get_reverb_roomsize(self.synth) | |
def get_reverb_damp(self): | |
return fluid_synth_get_reverb_damp(self.synth) | |
def get_reverb_level(self): | |
return fluid_synth_get_reverb_level(self.synth) | |
def get_reverb_width(self): | |
return fluid_synth_get_reverb_width(self.synth) | |
def get_chorus_nr(self): | |
return fluid_synth_get_chorus_nr(self.synth) | |
def get_chorus_level(self): | |
return fluid_synth_get_reverb_level(self.synth) | |
def get_chorus_speed(self): | |
if fluid_synth_get_chorus_speed is not None: | |
return fluid_synth_get_chorus_speed(self.synth) | |
else: | |
return fluid_synth_get_chorus_speed_Hz(self.synth) | |
def get_chorus_depth(self): | |
if fluid_synth_get_chorus_depth is not None: | |
return fluid_synth_get_chorus_depth(self.synth) | |
else: | |
return fluid_synth_get_chorus_depth_ms(self.synth) | |
def get_chorus_type(self): | |
return fluid_synth_get_chorus_type(self.synth) | |
def noteon(self, chan, key, vel): | |
"""Play a note""" | |
if key < 0 or key > 127: | |
return False | |
if chan < 0: | |
return False | |
if vel < 0 or vel > 127: | |
return False | |
return fluid_synth_noteon(self.synth, chan, key, vel) | |
def noteoff(self, chan, key): | |
"""Stop a note""" | |
if key < 0 or key > 127: | |
return False | |
if chan < 0: | |
return False | |
return fluid_synth_noteoff(self.synth, chan, key) | |
def pitch_bend(self, chan, val): | |
"""Adjust pitch of a playing channel by small amounts | |
A pitch bend value of 0 is no pitch change from default. | |
A value of -2048 is 1 semitone down. | |
A value of 2048 is 1 semitone up. | |
Maximum values are -8192 to +8192 (transposing by 4 semitones). | |
""" | |
return fluid_synth_pitch_bend(self.synth, chan, val + 8192) | |
def cc(self, chan, ctrl, val): | |
"""Send control change value | |
The controls that are recognized are dependent on the | |
SoundFont. Values are always 0 to 127. Typical controls | |
include: | |
1 : vibrato | |
7 : volume | |
10 : pan (left to right) | |
11 : expression (soft to loud) | |
64 : sustain | |
91 : reverb | |
93 : chorus | |
""" | |
return fluid_synth_cc(self.synth, chan, ctrl, val) | |
def get_cc(self, chan, num): | |
i=c_int() | |
fluid_synth_get_cc(self.synth, chan, num, byref(i)) | |
return i.value | |
def program_change(self, chan, prg): | |
"""Change the program""" | |
return fluid_synth_program_change(self.synth, chan, prg) | |
def bank_select(self, chan, bank): | |
"""Choose a bank""" | |
return fluid_synth_bank_select(self.synth, chan, bank) | |
def all_notes_off(self, chan): | |
"""Turn off all notes on a channel (release all keys)""" | |
return fluid_synth_all_notes_off(self.synth, chan) | |
def all_sounds_off(self, chan): | |
"""Turn off all sounds on a channel (equivalent to mute)""" | |
return fluid_synth_all_sounds_off(self.synth, chan) | |
def sfont_select(self, chan, sfid): | |
"""Choose a SoundFont""" | |
return fluid_synth_sfont_select(self.synth, chan, sfid) | |
def program_reset(self): | |
"""Reset the programs on all channels""" | |
return fluid_synth_program_reset(self.synth) | |
def system_reset(self): | |
"""Stop all notes and reset all programs""" | |
return fluid_synth_system_reset(self.synth) | |
def get_samples(self, len=1024): | |
"""Generate audio samples | |
The return value will be a NumPy array containing the given | |
length of audio samples. If the synth is set to stereo output | |
(the default) the array will be size 2 * len. | |
""" | |
return fluid_synth_write_s16_stereo(self.synth, len) | |
def tuning_dump(self, bank, prog, pitch): | |
return fluid_synth_tuning_dump(self.synth, bank, prog, name.encode(), length(name), pitch) | |
def midi_event_get_type(self, event): | |
return fluid_midi_event_get_type(event) | |
def midi_event_get_velocity(self, event): | |
return fluid_midi_event_get_velocity(event) | |
def midi_event_get_key(self, event): | |
return fluid_midi_event_get_key(event) | |
def midi_event_get_channel(self, event): | |
return fluid_midi_event_get_channel(event) | |
def midi_event_get_control(self, event): | |
return fluid_midi_event_get_control(event) | |
def midi_event_get_program(self, event): | |
return fluid_midi_event_get_program(event) | |
def midi_event_get_value(self, event): | |
return fluid_midi_event_get_value(event) | |
def play_midi_file(self, filename): | |
self.player = new_fluid_player(self.synth) | |
if self.player == None: return FLUID_FAILED | |
if self.custom_router_callback != None: | |
fluid_player_set_playback_callback(self.player, self.custom_router_callback, self.synth) | |
status = fluid_player_add(self.player, filename.encode()) | |
if status == FLUID_FAILED: return status | |
status = fluid_player_play(self.player) | |
return status | |
def play_midi_stop(self): | |
status = fluid_player_stop(self.player) | |
if status == FLUID_FAILED: return status | |
status = fluid_player_seek(self.player, 0) | |
delete_fluid_player(self.player) | |
return status | |
def player_set_tempo(self, tempo_type, tempo): | |
return fluid_player_set_tempo(self.player, tempo_type, tempo) | |
class Sequencer: | |
def __init__(self, time_scale=1000, use_system_timer=True): | |
"""Create new sequencer object to control and schedule timing of midi events | |
Optional keyword arguments: | |
time_scale: ticks per second, defaults to 1000 | |
use_system_timer: whether the sequencer should advance by itself | |
""" | |
self.client_callbacks = [] | |
self.sequencer = new_fluid_sequencer2(use_system_timer) | |
fluid_sequencer_set_time_scale(self.sequencer, time_scale) | |
def register_fluidsynth(self, synth): | |
response = fluid_sequencer_register_fluidsynth(self.sequencer, synth.synth) | |
if response == FLUID_FAILED: | |
raise Error("Registering fluid synth failed") | |
return response | |
def register_client(self, name, callback, data=None): | |
c_callback = CFUNCTYPE(None, c_uint, c_void_p, c_void_p, c_void_p)(callback) | |
response = fluid_sequencer_register_client(self.sequencer, name.encode(), c_callback, data) | |
if response == FLUID_FAILED: | |
raise Error("Registering client failed") | |
# store in a list to prevent garbage collection | |
self.client_callbacks.append(c_callback) | |
return response | |
def note(self, time, channel, key, velocity, duration, source=-1, dest=-1, absolute=True): | |
evt = self._create_event(source, dest) | |
fluid_event_note(evt, channel, key, velocity, duration) | |
self._schedule_event(evt, time, absolute) | |
delete_fluid_event(evt) | |
def note_on(self, time, channel, key, velocity=127, source=-1, dest=-1, absolute=True): | |
evt = self._create_event(source, dest) | |
fluid_event_noteon(evt, channel, key, velocity) | |
self._schedule_event(evt, time, absolute) | |
delete_fluid_event(evt) | |
def note_off(self, time, channel, key, source=-1, dest=-1, absolute=True): | |
evt = self._create_event(source, dest) | |
fluid_event_noteoff(evt, channel, key) | |
self._schedule_event(evt, time, absolute) | |
delete_fluid_event(evt) | |
def timer(self, time, data=None, source=-1, dest=-1, absolute=True): | |
evt = self._create_event(source, dest) | |
fluid_event_timer(evt, data) | |
self._schedule_event(evt, time, absolute) | |
delete_fluid_event(evt) | |
def _create_event(self, source=-1, dest=-1): | |
evt = new_fluid_event() | |
fluid_event_set_source(evt, source) | |
fluid_event_set_dest(evt, dest) | |
return evt | |
def _schedule_event(self, evt, time, absolute=True): | |
response = fluid_sequencer_send_at(self.sequencer, evt, time, absolute) | |
if response == FLUID_FAILED: | |
raise Error("Scheduling event failed") | |
def get_tick(self): | |
return fluid_sequencer_get_tick(self.sequencer) | |
def process(self, msec): | |
fluid_sequencer_process(self.sequencer, msec) | |
def delete(self): | |
delete_fluid_sequencer(self.sequencer) | |
def raw_audio_string(data): | |
"""Return a string of bytes to send to soundcard | |
Input is a numpy array of samples. Default output format | |
is 16-bit signed (other formats not currently supported). | |
""" | |
import numpy | |
return (data.astype(numpy.int16)).tostring() | |
#=============================================================================== | |
import numpy as np | |
import wave | |
def midi_opus_to_colab_audio(midi_opus, | |
soundfont_path='/usr/share/sounds/sf2/FluidR3_GM.sf2', | |
sample_rate=16000, # 44100 | |
volume_scale=10, | |
trim_silence=True, | |
silence_threshold=0.1, | |
output_for_gradio=False, | |
write_audio_to_WAV='' | |
): | |
def normalize_volume(matrix, factor=10): | |
norm = np.linalg.norm(matrix) | |
matrix = matrix/norm # normalized matrix | |
mult_matrix = matrix * factor | |
final_matrix = np.clip(mult_matrix, -1.0, 1.0) | |
return final_matrix | |
if midi_opus[1]: | |
ticks_per_beat = midi_opus[0] | |
event_list = [] | |
for track_idx, track in enumerate(midi_opus[1:]): | |
abs_t = 0 | |
for event in track: | |
abs_t += event[1] | |
event_new = [*event] | |
event_new[1] = abs_t | |
event_list.append(event_new) | |
event_list = sorted(event_list, key=lambda e: e[1]) | |
tempo = int((60 / 120) * 10 ** 6) # default 120 bpm | |
ss = np.empty((0, 2), dtype=np.int16) | |
fl = Synth(samplerate=float(sample_rate)) | |
sfid = fl.sfload(soundfont_path) | |
last_t = 0 | |
for c in range(16): | |
fl.program_select(c, sfid, 128 if c == 9 else 0, 0) | |
for event in event_list: | |
name = event[0] | |
sample_len = int(((event[1] / ticks_per_beat) * tempo / (10 ** 6)) * sample_rate) | |
sample_len -= int(((last_t / ticks_per_beat) * tempo / (10 ** 6)) * sample_rate) | |
last_t = event[1] | |
if sample_len > 0: | |
sample = fl.get_samples(sample_len).reshape(sample_len, 2) | |
ss = np.concatenate([ss, sample]) | |
if name == "set_tempo": | |
tempo = event[2] | |
elif name == "patch_change": | |
c, p = event[2:4] | |
fl.program_select(c, sfid, 128 if c == 9 else 0, p) | |
elif name == "control_change": | |
c, cc, v = event[2:5] | |
fl.cc(c, cc, v) | |
elif name == "note_on" and event[3] > 0: | |
c, p, v = event[2:5] | |
fl.noteon(c, p, v) | |
elif name == "note_off" or (name == "note_on" and event[3] == 0): | |
c, p = event[2:4] | |
fl.noteoff(c, p) | |
fl.delete() | |
if ss.shape[0] > 0: | |
max_val = np.abs(ss).max() | |
if max_val != 0: | |
ss = (ss / max_val) * np.iinfo(np.int16).max | |
ss = ss.astype(np.int16) | |
if trim_silence: | |
threshold = np.std(np.abs(ss)) * silence_threshold | |
exceeded_thresh = np.abs(ss) > threshold | |
if np.any(exceeded_thresh): | |
last_idx = np.where(exceeded_thresh)[0][-1] | |
ss = ss[:last_idx+1] | |
if output_for_gradio: | |
return ss | |
ss = ss.swapaxes(1, 0) | |
raw_audio = normalize_volume(ss, volume_scale) | |
if write_audio_to_WAV != '': | |
r_audio = raw_audio.T | |
r_audio = np.int16(r_audio / np.max(np.abs(r_audio)) * 32767) | |
with wave.open(write_audio_to_WAV, 'w') as wf: | |
wf.setframerate(sample_rate) | |
wf.setsampwidth(2) | |
wf.setnchannels(r_audio.shape[1]) | |
wf.writeframes(r_audio) | |
return raw_audio | |
else: | |
return None | |
def midi_to_colab_audio(midi_file, | |
soundfont_path='/usr/share/sounds/sf2/FluidR3_GM.sf2', | |
sample_rate=16000, # 44100 | |
volume_scale=10, | |
trim_silence=True, | |
silence_threshold=0.1, | |
output_for_gradio=False, | |
write_audio_to_WAV=False | |
): | |
''' | |
Returns raw audio to pass to IPython.disaply.Audio func | |
Example usage: | |
from IPython.display import Audio | |
display(Audio(raw_audio, rate=16000, normalize=False)) | |
''' | |
def normalize_volume(matrix, factor=10): | |
norm = np.linalg.norm(matrix) | |
matrix = matrix/norm # normalized matrix | |
mult_matrix = matrix * factor | |
final_matrix = np.clip(mult_matrix, -1.0, 1.0) | |
return final_matrix | |
midi_opus = midi2opus(open(midi_file, 'rb').read()) | |
if midi_opus[1]: | |
ticks_per_beat = midi_opus[0] | |
event_list = [] | |
for track_idx, track in enumerate(midi_opus[1:]): | |
abs_t = 0 | |
for event in track: | |
abs_t += event[1] | |
event_new = [*event] | |
event_new[1] = abs_t | |
event_list.append(event_new) | |
event_list = sorted(event_list, key=lambda e: e[1]) | |
tempo = int((60 / 120) * 10 ** 6) # default 120 bpm | |
ss = np.empty((0, 2), dtype=np.int16) | |
fl = Synth(samplerate=float(sample_rate)) | |
sfid = fl.sfload(soundfont_path) | |
last_t = 0 | |
for c in range(16): | |
fl.program_select(c, sfid, 128 if c == 9 else 0, 0) | |
for event in event_list: | |
name = event[0] | |
sample_len = int(((event[1] / ticks_per_beat) * tempo / (10 ** 6)) * sample_rate) | |
sample_len -= int(((last_t / ticks_per_beat) * tempo / (10 ** 6)) * sample_rate) | |
last_t = event[1] | |
if sample_len > 0: | |
sample = fl.get_samples(sample_len).reshape(sample_len, 2) | |
ss = np.concatenate([ss, sample]) | |
if name == "set_tempo": | |
tempo = event[2] | |
elif name == "patch_change": | |
c, p = event[2:4] | |
fl.program_select(c, sfid, 128 if c == 9 else 0, p) | |
elif name == "control_change": | |
c, cc, v = event[2:5] | |
fl.cc(c, cc, v) | |
elif name == "note_on" and event[3] > 0: | |
c, p, v = event[2:5] | |
fl.noteon(c, p, v) | |
elif name == "note_off" or (name == "note_on" and event[3] == 0): | |
c, p = event[2:4] | |
fl.noteoff(c, p) | |
fl.delete() | |
if ss.shape[0] > 0: | |
max_val = np.abs(ss).max() | |
if max_val != 0: | |
ss = (ss / max_val) * np.iinfo(np.int16).max | |
ss = ss.astype(np.int16) | |
if trim_silence: | |
threshold = np.std(np.abs(ss)) * silence_threshold | |
exceeded_thresh = np.abs(ss) > threshold | |
if np.any(exceeded_thresh): | |
last_idx = np.where(exceeded_thresh)[0][-1] | |
ss = ss[:last_idx+1] | |
if output_for_gradio: | |
return ss | |
ss = ss.swapaxes(1, 0) | |
raw_audio = normalize_volume(ss, volume_scale) | |
if write_audio_to_WAV: | |
filename = midi_file.split('.')[-2] + '.wav' | |
r_audio = raw_audio.T | |
r_audio = np.int16(r_audio / np.max(np.abs(r_audio)) * 32767) | |
with wave.open(filename, 'w') as wf: | |
wf.setframerate(sample_rate) | |
wf.setsampwidth(2) | |
wf.setnchannels(r_audio.shape[1]) | |
wf.writeframes(r_audio) | |
return raw_audio | |
else: | |
return None | |
#=================================================================================================================== |