Projekt_AI-Automatyczny_saper/venv/Lib/site-packages/pygame/midi.py

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"""pygame.midi
pygame module for interacting with midi input and output.
The midi module can send output to midi devices, and get input
from midi devices. It can also list midi devices on the system.
Including real midi devices, and virtual ones.
It uses the portmidi library. Is portable to which ever platforms
portmidi supports (currently windows, OSX, and linux).
This uses pyportmidi for now, but may use its own bindings at some
point in the future. The pyportmidi bindings are included with pygame.
New in pygame 1.9.0.
"""
# TODO: finish writing tests.
# - likely as interactive tests... so you'd need to plug in
# a midi device.
# TODO: create a background thread version for input threads.
# - that can automatically inject input into the event queue
# once the input object is running. Like joysticks.
# In Python 2.7 pygame.math is imported instead of the built-in math module.
# This import from future allows the built-in math module to be imported.
from __future__ import absolute_import
import math
import atexit
import pygame
import pygame.locals
import pygame.pypm as _pypm
# For backward compatibility.
MIDIIN = pygame.locals.MIDIIN
MIDIOUT = pygame.locals.MIDIOUT
__all__ = [
"Input",
"MIDIIN",
"MIDIOUT",
"MidiException",
"Output",
"get_count",
"get_default_input_id",
"get_default_output_id",
"get_device_info",
"init",
"midis2events",
"quit",
"get_init",
"time",
"frequency_to_midi",
"midi_to_frequency",
"midi_to_ansi_note",
]
__theclasses__ = ["Input", "Output"]
def _module_init(state=None):
# this is a sneaky dodge to store module level state in a non-public
# function. Helps us dodge using globals.
if state is not None:
_module_init.value = state
return state
try:
_module_init.value
except AttributeError:
return False
else:
return _module_init.value
def init():
"""initialize the midi module
pygame.midi.init(): return None
Call the initialisation function before using the midi module.
It is safe to call this more than once.
"""
if not _module_init():
_pypm.Initialize()
_module_init(True)
atexit.register(quit)
def quit(): # pylint: disable=redefined-builtin
"""uninitialize the midi module
pygame.midi.quit(): return None
Called automatically atexit if you don't call it.
It is safe to call this function more than once.
"""
if _module_init():
# TODO: find all Input and Output classes and close them first?
_pypm.Terminate()
_module_init(False)
def get_init():
"""returns True if the midi module is currently initialized
pygame.midi.get_init(): return bool
Returns True if the pygame.midi module is currently initialized.
New in pygame 1.9.5.
"""
return _module_init()
def _check_init():
if not _module_init():
raise RuntimeError("pygame.midi not initialised.")
def get_count():
"""gets the number of devices.
pygame.midi.get_count(): return num_devices
Device ids range from 0 to get_count() -1
"""
_check_init()
return _pypm.CountDevices()
def get_default_input_id():
"""gets default input device number
pygame.midi.get_default_input_id(): return default_id
Return the default device ID or -1 if there are no devices.
The result can be passed to the Input()/Output() class.
On the PC, the user can specify a default device by
setting an environment variable. For example, to use device #1.
set PM_RECOMMENDED_INPUT_DEVICE=1
The user should first determine the available device ID by using
the supplied application "testin" or "testout".
In general, the registry is a better place for this kind of info,
and with USB devices that can come and go, using integers is not
very reliable for device identification. Under Windows, if
PM_RECOMMENDED_OUTPUT_DEVICE (or PM_RECOMMENDED_INPUT_DEVICE) is
*NOT* found in the environment, then the default device is obtained
by looking for a string in the registry under:
HKEY_LOCAL_MACHINE/SOFTWARE/PortMidi/Recommended_Input_Device
and HKEY_LOCAL_MACHINE/SOFTWARE/PortMidi/Recommended_Output_Device
for a string. The number of the first device with a substring that
matches the string exactly is returned. For example, if the string
in the registry is "USB", and device 1 is named
"In USB MidiSport 1x1", then that will be the default
input because it contains the string "USB".
In addition to the name, get_device_info() returns "interf", which
is the interface name. (The "interface" is the underlying software
system or API used by PortMidi to access devices. Examples are
MMSystem, DirectX (not implemented), ALSA, OSS (not implemented), etc.)
At present, the only Win32 interface is "MMSystem", the only Linux
interface is "ALSA", and the only Max OS X interface is "CoreMIDI".
To specify both the interface and the device name in the registry,
separate the two with a comma and a space, e.g.:
MMSystem, In USB MidiSport 1x1
In this case, the string before the comma must be a substring of
the "interf" string, and the string after the space must be a
substring of the "name" name string in order to match the device.
Note: in the current release, the default is simply the first device
(the input or output device with the lowest PmDeviceID).
"""
_check_init()
return _pypm.GetDefaultInputDeviceID()
def get_default_output_id():
"""gets default output device number
pygame.midi.get_default_output_id(): return default_id
Return the default device ID or -1 if there are no devices.
The result can be passed to the Input()/Output() class.
On the PC, the user can specify a default device by
setting an environment variable. For example, to use device #1.
set PM_RECOMMENDED_OUTPUT_DEVICE=1
The user should first determine the available device ID by using
the supplied application "testin" or "testout".
In general, the registry is a better place for this kind of info,
and with USB devices that can come and go, using integers is not
very reliable for device identification. Under Windows, if
PM_RECOMMENDED_OUTPUT_DEVICE (or PM_RECOMMENDED_INPUT_DEVICE) is
*NOT* found in the environment, then the default device is obtained
by looking for a string in the registry under:
HKEY_LOCAL_MACHINE/SOFTWARE/PortMidi/Recommended_Input_Device
and HKEY_LOCAL_MACHINE/SOFTWARE/PortMidi/Recommended_Output_Device
for a string. The number of the first device with a substring that
matches the string exactly is returned. For example, if the string
in the registry is "USB", and device 1 is named
"In USB MidiSport 1x1", then that will be the default
input because it contains the string "USB".
In addition to the name, get_device_info() returns "interf", which
is the interface name. (The "interface" is the underlying software
system or API used by PortMidi to access devices. Examples are
MMSystem, DirectX (not implemented), ALSA, OSS (not implemented), etc.)
At present, the only Win32 interface is "MMSystem", the only Linux
interface is "ALSA", and the only Max OS X interface is "CoreMIDI".
To specify both the interface and the device name in the registry,
separate the two with a comma and a space, e.g.:
MMSystem, In USB MidiSport 1x1
In this case, the string before the comma must be a substring of
the "interf" string, and the string after the space must be a
substring of the "name" name string in order to match the device.
Note: in the current release, the default is simply the first device
(the input or output device with the lowest PmDeviceID).
"""
_check_init()
return _pypm.GetDefaultOutputDeviceID()
def get_device_info(an_id):
""" returns information about a midi device
pygame.midi.get_device_info(an_id): return (interf, name,
input, output,
opened)
interf - a text string describing the device interface, eg 'ALSA'.
name - a text string for the name of the device, eg 'Midi Through Port-0'
input - 0, or 1 if the device is an input device.
output - 0, or 1 if the device is an output device.
opened - 0, or 1 if the device is opened.
If the id is out of range, the function returns None.
"""
_check_init()
return _pypm.GetDeviceInfo(an_id)
class Input(object):
"""Input is used to get midi input from midi devices.
Input(device_id)
Input(device_id, buffer_size)
buffer_size - the number of input events to be buffered waiting to
be read using Input.read()
"""
def __init__(self, device_id, buffer_size=4096):
"""
The buffer_size specifies the number of input events to be buffered
waiting to be read using Input.read().
"""
_check_init()
if device_id == -1:
raise MidiException("Device id is -1, not a valid output id. "
"-1 usually means there were no default "
"Output devices.")
try:
result = get_device_info(device_id)
except TypeError:
raise TypeError("an integer is required")
except OverflowError:
raise OverflowError("long int too large to convert to int")
# and now some nasty looking error checking, to provide nice error
# messages to the kind, lovely, midi using people of wherever.
if result:
_, _, is_input, is_output, _ = result
if is_input:
try:
self._input = _pypm.Input(device_id, buffer_size)
except TypeError:
raise TypeError("an integer is required")
self.device_id = device_id
elif is_output:
raise MidiException(
"Device id given is not a valid"
" input id, it is an output id.")
else:
raise MidiException("Device id given is not a valid input id.")
else:
raise MidiException("Device id invalid, out of range.")
def _check_open(self):
if self._input is None:
raise MidiException("midi not open.")
def close(self):
""" closes a midi stream, flushing any pending buffers.
Input.close(): return None
PortMidi attempts to close open streams when the application
exits -- this is particularly difficult under Windows.
"""
_check_init()
if self._input is not None:
self._input.Close()
self._input = None
def read(self, num_events):
"""reads num_events midi events from the buffer.
Input.read(num_events): return midi_event_list
Reads from the Input buffer and gives back midi events.
[[[status,data1,data2,data3],timestamp],
[[status,data1,data2,data3],timestamp],...]
"""
_check_init()
self._check_open()
return self._input.Read(num_events)
def poll(self):
"""returns true if there's data, or false if not.
Input.poll(): return Bool
raises a MidiException on error.
"""
_check_init()
self._check_open()
result = self._input.Poll()
if result == _pypm.TRUE:
return True
if result == _pypm.FALSE:
return False
err_text = _pypm.GetErrorText(result)
raise MidiException((result, err_text))
class Output(object):
"""Output is used to send midi to an output device
Output(device_id)
Output(device_id, latency = 0)
Output(device_id, buffer_size = 4096)
Output(device_id, latency, buffer_size)
The buffer_size specifies the number of output events to be
buffered waiting for output. (In some cases -- see below --
PortMidi does not buffer output at all and merely passes data
to a lower-level API, in which case buffersize is ignored.)
latency is the delay in milliseconds applied to timestamps to determine
when the output should actually occur. (If latency is < 0, 0 is
assumed.)
If latency is zero, timestamps are ignored and all output is delivered
immediately. If latency is greater than zero, output is delayed until
the message timestamp plus the latency. (NOTE: time is measured
relative to the time source indicated by time_proc. Timestamps are
absolute, not relative delays or offsets.) In some cases, PortMidi
can obtain better timing than your application by passing timestamps
along to the device driver or hardware. Latency may also help you
to synchronize midi data to audio data by matching midi latency to
the audio buffer latency.
"""
def __init__(self, device_id, latency=0, buffer_size=256):
"""Output(device_id)
Output(device_id, latency = 0)
Output(device_id, buffer_size = 4096)
Output(device_id, latency, buffer_size)
The buffer_size specifies the number of output events to be
buffered waiting for output. (In some cases -- see below --
PortMidi does not buffer output at all and merely passes data
to a lower-level API, in which case buffersize is ignored.)
latency is the delay in milliseconds applied to timestamps to determine
when the output should actually occur. (If latency is < 0, 0 is
assumed.)
If latency is zero, timestamps are ignored and all output is delivered
immediately. If latency is greater than zero, output is delayed until
the message timestamp plus the latency. (NOTE: time is measured
relative to the time source indicated by time_proc. Timestamps are
absolute, not relative delays or offsets.) In some cases, PortMidi
can obtain better timing than your application by passing timestamps
along to the device driver or hardware. Latency may also help you
to synchronize midi data to audio data by matching midi latency to
the audio buffer latency.
"""
_check_init()
self._aborted = 0
if device_id == -1:
raise MidiException("Device id is -1, not a valid output id."
" -1 usually means there were no default "
"Output devices.")
try:
result = get_device_info(device_id)
except TypeError:
raise TypeError("an integer is required")
except OverflowError:
raise OverflowError("long int too large to convert to int")
# and now some nasty looking error checking, to provide nice error
# messages to the kind, lovely, midi using people of wherever.
if result:
_, _, is_input, is_output, _ = result
if is_output:
try:
self._output = _pypm.Output(device_id, latency,
buffer_size)
except TypeError:
raise TypeError("an integer is required")
self.device_id = device_id
elif is_input:
raise MidiException("Device id given is not a valid output "
"id, it is an input id.")
else:
raise MidiException("Device id given is not a"
" valid output id.")
else:
raise MidiException("Device id invalid, out of range.")
def _check_open(self):
if self._output is None:
raise MidiException("midi not open.")
if self._aborted:
raise MidiException("midi aborted.")
def close(self):
""" closes a midi stream, flushing any pending buffers.
Output.close(): return None
PortMidi attempts to close open streams when the application
exits -- this is particularly difficult under Windows.
"""
_check_init()
if self._output is not None:
self._output.Close()
self._output = None
def abort(self):
"""terminates outgoing messages immediately
Output.abort(): return None
The caller should immediately close the output port;
this call may result in transmission of a partial midi message.
There is no abort for Midi input because the user can simply
ignore messages in the buffer and close an input device at
any time.
"""
_check_init()
if self._output:
self._output.Abort()
self._aborted = 1
def write(self, data):
"""writes a list of midi data to the Output
Output.write(data)
writes series of MIDI information in the form of a list:
write([[[status <,data1><,data2><,data3>],timestamp],
[[status <,data1><,data2><,data3>],timestamp],...])
<data> fields are optional
example: choose program change 1 at time 20000 and
send note 65 with velocity 100 500 ms later.
write([[[0xc0,0,0],20000],[[0x90,60,100],20500]])
notes:
1. timestamps will be ignored if latency = 0.
2. To get a note to play immediately, send MIDI info with
timestamp read from function Time.
3. understanding optional data fields:
write([[[0xc0,0,0],20000]]) is equivalent to
write([[[0xc0],20000]])
Can send up to 1024 elements in your data list, otherwise an
IndexError exception is raised.
"""
_check_init()
self._check_open()
self._output.Write(data)
def write_short(self, status, data1=0, data2=0):
"""write_short(status <, data1><, data2>)
Output.write_short(status)
Output.write_short(status, data1 = 0, data2 = 0)
output MIDI information of 3 bytes or less.
data fields are optional
status byte could be:
0xc0 = program change
0x90 = note on
etc.
data bytes are optional and assumed 0 if omitted
example: note 65 on with velocity 100
write_short(0x90,65,100)
"""
_check_init()
self._check_open()
self._output.WriteShort(status, data1, data2)
def write_sys_ex(self, when, msg):
"""writes a timestamped system-exclusive midi message.
Output.write_sys_ex(when, msg)
msg - can be a *list* or a *string*
when - a timestamp in miliseconds
example:
(assuming o is an onput MIDI stream)
o.write_sys_ex(0,'\\xF0\\x7D\\x10\\x11\\x12\\x13\\xF7')
is equivalent to
o.write_sys_ex(pygame.midi.time(),
[0xF0,0x7D,0x10,0x11,0x12,0x13,0xF7])
"""
_check_init()
self._check_open()
self._output.WriteSysEx(when, msg)
def note_on(self, note, velocity, channel=0):
"""turns a midi note on. Note must be off.
Output.note_on(note, velocity, channel=0)
note is an integer from 0 to 127
velocity is an integer from 0 to 127
channel is an integer from 0 to 15
Turn a note on in the output stream. The note must already
be off for this to work correctly.
"""
if not 0 <= channel <= 15:
raise ValueError("Channel not between 0 and 15.")
self.write_short(0x90 + channel, note, velocity)
def note_off(self, note, velocity=0, channel=0):
"""turns a midi note off. Note must be on.
Output.note_off(note, velocity=0, channel=0)
note is an integer from 0 to 127
velocity is an integer from 0 to 127 (release velocity)
channel is an integer from 0 to 15
Turn a note off in the output stream. The note must already
be on for this to work correctly.
"""
if not 0 <= channel <= 15:
raise ValueError("Channel not between 0 and 15.")
self.write_short(0x80 + channel, note, velocity)
def set_instrument(self, instrument_id, channel=0):
"""select an instrument for a channel, with a value between 0 and 127
Output.set_instrument(instrument_id, channel=0)
Also called "patch change" or "program change".
"""
if not 0 <= instrument_id <= 127:
raise ValueError("Undefined instrument id: %d" % instrument_id)
if not 0 <= channel <= 15:
raise ValueError("Channel not between 0 and 15.")
self.write_short(0xc0 + channel, instrument_id)
def pitch_bend(self, value=0, channel=0):
"""modify the pitch of a channel.
Output.pitch_bend(value=0, channel=0)
Adjust the pitch of a channel. The value is a signed integer
from -8192 to +8191. For example, 0 means "no change", +4096 is
typically a semitone higher, and -8192 is 1 whole tone lower (though
the musical range corresponding to the pitch bend range can also be
changed in some synthesizers).
If no value is given, the pitch bend is returned to "no change".
"""
if not 0 <= channel <= 15:
raise ValueError("Channel not between 0 and 15.")
if not -8192 <= value <= 8191:
raise ValueError("Pitch bend value must be between "
"-8192 and +8191, not %d." % value)
# "The 14 bit value of the pitch bend is defined so that a value of
# 0x2000 is the center corresponding to the normal pitch of the note
# (no pitch change)." so value=0 should send 0x2000
value = value + 0x2000
lsb = value & 0x7f # keep least 7 bits
msb = value >> 7
self.write_short(0xe0 + channel, lsb, msb)
# MIDI commands
#
# 0x80 Note Off (note_off)
# 0x90 Note On (note_on)
# 0xA0 Aftertouch
# 0xB0 Continuous controller
# 0xC0 Patch change (set_instrument?)
# 0xD0 Channel Pressure
# 0xE0 Pitch bend
# 0xF0 (non-musical commands)
def time():
"""returns the current time in ms of the PortMidi timer
pygame.midi.time(): return time
The time is reset to 0, when the module is inited.
"""
_check_init()
return _pypm.Time()
def midis2events(midis, device_id):
"""converts midi events to pygame events
pygame.midi.midis2events(midis, device_id): return [Event, ...]
Takes a sequence of midi events and returns list of pygame events.
"""
evs = []
for midi in midis:
((status, data1, data2, data3), timestamp) = midi
event = pygame.event.Event(MIDIIN,
status=status,
data1=data1,
data2=data2,
data3=data3,
timestamp=timestamp,
vice_id=device_id)
evs.append(event)
return evs
class MidiException(Exception):
"""exception that pygame.midi functions and classes can raise
MidiException(errno)
"""
def __init__(self, value):
super(MidiException, self).__init__(value)
self.parameter = value
def __str__(self):
return repr(self.parameter)
def frequency_to_midi(frequency):
""" converts a frequency into a MIDI note.
Rounds to the closest midi note.
::Examples::
>>> frequency_to_midi(27.5)
21
>>> frequency_to_midi(36.7)
26
>>> frequency_to_midi(4186.0)
108
"""
return int(
round(
69 + (
12 * math.log(frequency / 440.0)
) / math.log(2)
)
)
def midi_to_frequency(midi_note):
""" Converts a midi note to a frequency.
::Examples::
>>> midi_to_frequency(21)
27.5
>>> midi_to_frequency(26)
36.7
>>> midi_to_frequency(108)
4186.0
"""
return round(440.0 * 2 ** ((midi_note - 69) * (1. / 12.)), 1)
def midi_to_ansi_note(midi_note):
""" returns the Ansi Note name for a midi number.
::Examples::
>>> midi_to_ansi_note(21)
'A0'
>>> midi_to_ansi_note(102)
'F#7'
>>> midi_to_ansi_note(108)
'C8'
"""
notes = ['A', 'A#', 'B', 'C', 'C#', 'D', 'D#', 'E', 'F', 'F#', 'G', 'G#']
num_notes = 12
note_name = notes[int(((midi_note - 21) % num_notes))]
note_number = (midi_note - 12) // num_notes
return '%s%s' % (note_name, note_number)