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I need to analyze sound written in a .wav file. For that I need to transform this file into set of numbers (arrays, for example). I think I need to use the wave package. However, I do not know how exactly it works. For example I did the following:

import wave
w = wave.open('/usr/share/sounds/ekiga/voicemail.wav', 'r')
for i in range(w.getnframes()):
    frame = w.readframes(i)
    print frame

As a result of this code I expected to see sound pressure as function of time. In contrast I see a lot of strange, mysterious symbols (which are not hexadecimal numbers). Can anybody, pleas, help me with that?

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It's really confusing when someone else with my name posts a question that I am asking, but I have no memory of doing so myself :) – Roman May 25 '15 at 7:50
What on earth are hexagonal numbers? – glglgl Sep 17 '15 at 12:20
up vote 32 down vote accepted

Per the sources, scipy.io.wavfile.read(somefile) returns a tuple of two items: the first is the sampling rate in samples per second, the second is a numpy array with all the data read from the file. Looks pretty easy to use!

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You can combine this with command line conversion tools to open other formats. – endolith Dec 31 '10 at 2:31
It seriously lacks the number of channels though. How are you supposed to work with audio without knowing the number of channels? – bastibe Mar 2 '11 at 10:58
throwns some weird struct unpacking errors on my computer. I think it's using struct.unpack('<i',data) instead of the struct.unpack('<h',data) nak used below. – Alex S Jul 2 '13 at 9:16
Does this library work? I run into a number of problems: scipy.io.wavfile.read('/usr/lib/python2.7/dist-packages/pygame/examples/data/hou‌​se_lo.wav') -> No data. scipy.io.wavfile.read('/usr/lib/python2.7/dist-packages/pygame/examples/data/sec‌​osmic_lo.wav') -> ZeroDivisionError: integer division or modulo by zero – Finn Årup Nielsen Sep 26 '13 at 13:07
it seems that it doesn't work for 24bits file ! – Basj Nov 13 '13 at 20:09

I did some research this evening and figured this out:

import wave, struct

waveFile = wave.open('sine.wav', 'r')

length = waveFile.getnframes()
for i in range(0,length):
    waveData = waveFile.readframes(1)
    data = struct.unpack("<h", waveData)

Hopefully this snippet helps someone. Details: using the struct module, you can take the wave frames (which are in 2s complementary binary between -32768; 0x8000 and 32767; 0x7FFF) This reads a MONO, 16-BIT, WAVE file. I found this webpage quite useful in formulating this.

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how to handle 24bits stereo files ? – Basj Nov 13 '13 at 20:10
this gives me the error: "struct.error: unpack requires a string argument of length 2" – Coder404 Oct 14 '14 at 16:05
If you run this piece of code with a very big audio file. Your computer will be die to due the memory need by this program. Need to process audio file by block for big audio file – ArthurLambert Apr 28 '15 at 12:48
@Coder404 You probably have a stereo wave file, or a different bit depth. – jmilloy Jun 18 '15 at 1:49
For those who, like me, are wondering what is 2s complementary binary, see here stackoverflow.com/questions/1049722/what-is-2s-complement – Dennis Golomazov Sep 28 '15 at 12:32

You can accomplish this using the scikits.audiolab module. It requires NumPy and SciPy to function, and also libsndfile.

Note, I was only able to get it to work on Ubunutu and not on OSX.

from scikits.audiolab import wavread

filename = "testfile.wav"

data, sample_frequency,encoding = wavread(filename)

Now you have the wav data

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I have found 4 module to read wave audio file: scikits.audiolab, scipy.io.wavfile, wave, and numpy.

Warning: the data are not always the same in function of the method you use. For example:

from scikits import audiolab
from scipy.io import wavfile
from sys import argv
for filetest in argv[1:]:
    [x, fs, nbBits] = audiolab.wavread(filePath)
    print '\nReading with scikits.audiolab.wavread: ', x

Reading with scikits.audiolab.wavread: [ 0. 0. 0. ..., -0.00097656 -0.00079346 -0.00097656]

    [fs, x] = wavfile.read(filetest)
    print '\nReading with scipy.io.wavfile.read: ', x

Reading with scipy.io.wavfile.read: [ 0 0 0 ..., -32 -26 -32]

Therefore, you need to convert the data of scipy, wave and numpy according to the number of bit of encoding. Audiolab return a signal between -1 and 1 (as matab does).

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IMHO, the easiest way to get audio data from a sound file into a NumPy array is PySoundFile:

import soundfile as sf
data, fs = sf.read('/usr/share/sounds/ekiga/voicemail.wav')

This also supports 24-bit files out of the box.

There are many sound file libraries available, I've written an overview where you can see a few pros and cons. It also features a page explaining how to read a 24-bit wav file with the wave module.

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If you want to procces an audio block by block, some of the given solutions are quite awful in the sense that they imply loading the whole audio into memory producing many cache misses and slowing down your program. python-wavefile provides some pythonic constructs to do NumPy block-by-block processing using efficient and transparent block management by means of generators. Other pythonic niceties are context manager for files, metadata as properties... and if you want the whole file interface, because you are developing a quick prototype and you don't care about efficency, the whole file interface is still there.

A simple example of processing would be:

import sys
from wavefile import WaveReader, WaveWriter

with WaveReader(sys.argv[1]) as r :
    with WaveWriter(
            ) as w :

        # Just to set the metadata
        w.metadata.title = r.metadata.title + " II"
        w.metadata.artist = r.metadata.artist

        # This is the prodessing loop
        for data in r.read_iter(size=512) :
            data[1] *= .8     # lower volume on the second channel

The example reuses the same block to read the whole file, even in the case of the last block that usually is less than the required size. In this case you get an slice of the block. So trust the returned block length instead of using a hardcoded 512 size for any further processing.

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If you're going to perform transfers on the waveform data then perhaps you should use SciPy, specifically scipy.io.wavfile.

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OK. I just installed the SciPy but I cannot find any example of the usage of scipy.io.wavfile. – Roman Jan 13 '10 at 22:25
Nothing like the interactive interpreter for figuring out how things work! Be ambitious! – Ignacio Vazquez-Abrams Jan 13 '10 at 22:44

if its just two files and the sample rate is significantly high, you could just interleave them.

from scipy.io import wavfile
rate1,dat1 = wavfile.read(File1)
rate2,dat2 = wavfile.read(File2)

if len(dat2) > len(dat1):#swap shortest
    temp = dat2
    dat2 = dat1
    dat1 = temp

output = dat1
for i in range(len(dat2)/2): output[i*2]=dat2[i*2]

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I needed to read a 1-channel 24-bit WAV file. The post above by Nak was very useful. However, as mentioned above by basj 24-bit is not straightforward. I finally got it working using the following snippet:

from scipy.io import wavfile
TheFile = 'example24bit1channelFile.wav'
[fs, x] = wavfile.read(TheFile)

# convert the loaded data into a 24bit signal

nx = len(x)
ny = nx/3*4    # four 3-byte samples are contained in three int32 words

y = np.zeros((ny,), dtype=np.int32)    # initialise array

# build the data left aligned in order to keep the sign bit operational.
# result will be factor 256 too high

y[0:ny:4] = ((x[0:nx:3] & 0x000000FF) << 8) | \
  ((x[0:nx:3] & 0x0000FF00) << 8) | ((x[0:nx:3] & 0x00FF0000) << 8)
y[1:ny:4] = ((x[0:nx:3] & 0xFF000000) >> 16) | \
  ((x[1:nx:3] & 0x000000FF) << 16) | ((x[1:nx:3] & 0x0000FF00) << 16)
y[2:ny:4] = ((x[1:nx:3] & 0x00FF0000) >> 8) | \
  ((x[1:nx:3] & 0xFF000000) >> 8) | ((x[2:nx:3] & 0x000000FF) << 24)
y[3:ny:4] = (x[2:nx:3] & 0x0000FF00) | \
  (x[2:nx:3] & 0x00FF0000) | (x[2:nx:3] & 0xFF000000)

y = y/256   # correct for building 24 bit data left aligned in 32bit words

Some additional scaling is required if you need results between -1 and +1. Maybe some of you out there might find this useful

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