I've seen the recording tutorial on the PyAudio website for recording a fixed length recording, but I was wondering how I could do the same with a non-fixed recording? Bascially, I want to create buttons to start and end the recording but I haven't found anything on the matter. Any ideas, and I am not looking for an alternative library?
3 Answers
Best is to use the non-blocking way of recording, i.e. you provide a callback function that gets called from the moment you start the stream and keeps getting called for every block/buffer that gets processed until you stop the stream.
In that callback function you check for a boolean for example, and when it is true you write the incoming buffer to a datastructure, when it is false you ignore the incoming buffer. This boolean can be set from clicking a button for example.
EDIT: look at the example of wire audio: http://people.csail.mit.edu/hubert/pyaudio/#wire-callback-example The stream is opened with an argument
stream_callback=my_callback
Where my_callback is a regular function declared as
def my_callback(in_data, frame_count, time_info, status)
This function will be called every time a new buffer is available. in_data
contains the input, which you want to record. In this example, in_data
just gets returned in a tuple together with pyaudio.paContinue
. Which means that the incoming buffer from the input device is put/copied back into the output buffer sent the the output device (its the same device, so its actually routing input to output aka wire). See the api docs for a bit more explanation: http://people.csail.mit.edu/hubert/pyaudio/docs/#pyaudio.PyAudio.open
So in this function you can do something like (this is an extract from some code I've written, which is not complete: I use some functions not depicted. Also I play a sinewave on one channel and noise on the other in 24bit format.):
record_on = False
playback_on = False
recorded_frames = queue.Queue()
def callback_play_sine(in_data, frame_count, time_info, status):
if record_on:
global recorded_frames
recorded_frames.put(in_data)
if playback_on:
left_channel_data = mysine.next_block(frame_count) * MAX_INT24 * gain
right_channel_data = ((np.random.rand(frame_count) * 2) - 1) * MAX_INT24 * gain
data = interleave_channels(max_nr_of_channels, (left_output_channel, left_channel_data), (right_output_channel, right_channel_data))
data = convert_int32_to_24bit_bytestream(data)
else:
data = np.zeros(frame_count*max_nr_of_channels).tostring()
if stop_callback:
callback_flag = pyaudio.paComplete
else:
callback_flag = pyaudio.paContinue
return data, callback_flag
You can then set record_on
and playback_on
to True
or False
from another part of your code while the stream is open/running, causing recording and playback to start or stop independently without interrupting the stream.
I copy the in_data
in a (threadsafe) queue
, which is used by another thread to write to disk there, else the queue will get big after a while.
BTW: pyaudio is based on portaudio, which has much more documentation and helpful tips. For example (http://portaudio.com/docs/v19-doxydocs/writing_a_callback.html): the callback function has to finish before a new buffer is presented, else buffers will be lost. So writing to a file inside the callback function usually not a good idea. (though writing to a file gets buffered and I don't know if it blocks when its written to disk eventually)
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I'm not following you. Can you explain this method further? Commented Feb 9, 2015 at 19:53
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I'm not familiar with C or C++. Can you actually explain some Python? Commented Feb 9, 2015 at 20:01
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As far as I know not really. You could use the non-callback (blocking) version, but then you have to put it in a separate thread if you don't want the rest of the code to freeze up, which is probably more complicated. Also the callback version is the standard way to interact with a realtime IO device. The IO device causes an interrupt in the operating system/driver which triggers some function to get called (callback), the blocking way of working is just a convenience built on top of this for the simplest of cases. Commented Feb 9, 2015 at 21:11
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1That's what I'm using to simulate button presses. See below. Commented Feb 9, 2015 at 21:17
import pyaudio
import wave
import pygame, sys
from pygame.locals import *
pygame.init()
scr = pygame.display.set_mode((640, 480))
recording = True
CHUNK = 1024
FORMAT = pyaudio.paInt16
CHANNELS = 2
RATE = 44100
RECORD_SECONDS = 5
WAVE_OUTPUT_FILENAME = "output.wav"
p = pyaudio.PyAudio()
stream = p.open(format=FORMAT,
channels=CHANNELS,
rate=RATE,
input=True,
frames_per_buffer=CHUNK)
print("* recording")
frames = []
while True:
if recording:
data = stream.read(CHUNK)
frames.append(data)
for event in pygame.event.get():
if event.type == KEYDOWN and recording:
print("* done recording")
stream.stop_stream()
stream.close()
p.terminate()
wf = wave.open(WAVE_OUTPUT_FILENAME, 'wb')
wf.setnchannels(CHANNELS)
wf.setsampwidth(p.get_sample_size(FORMAT))
wf.setframerate(RATE)
wf.writeframes(b''.join(frames))
wf.close()
recording = False
if event.type == QUIT:
pygame.quit(); sys.exit()
This is what I came up with when compiling it to an exe. Passing arguments to the
exeparser = argparse.ArgumentParser()
parser.add_argument('-t', dest='time', action='store')
args = parser.parse_args()
time = int(args.time)