I'm a musician and I'm writing a python script that reads a .wav file, uses the fast fourier transform to turn it into a bunch of sine waves, then tunes those sine waves to their nearest harmonic frequency. If all of that sounded like gibberish then that's fine, my question can be answered without any music knowledge.

When I run my script on a fairly long .wav file it takes several hours to process the following section of the script:

```
filtered_data_fft = np.zeros(data_fft.size)
for f in data_fft:
if f > 1:
valid_frequency = (np.abs(valid_frequencies - i)).argmin()
filtered_data_fft[valid_frequency] += data_fft[i]
i += 1
```

Both of the arrays that end with fft are arrays where the index corresponds to a frequency, and the valid_frequencies array is a list of frequencies that correspond to said indices. I originally didn't use numpy arrays for everything and it took so long to run that I couldn't get a short sound file to process in a reasonable time, but with numpy it's a lot faster. Can anyone think of a way to make it even faster than this? I'll put the full script below.

Also, there are two known warnings about casting complex values to real ones which discards the complex number, but I don't think they're a problem. The FFT returns an array of tuples where the first value is a frequency and the second one is a complex number that represents something I don't quite understand, but according to the page I followed to learn this it's not important. Here's where I learned this stuff: https://pythonforengineers.com/audio-and-digital-signal-processingdsp-in-python/

Admittedly I don't fully understand a lot of the DSP stuff I'm doing here, so let me know if I'm horribly wrong about something! I'm just trying to make an interesting way to turn noise into music for a project I'm working on.

Here's the audio sample I'm testing with: https://my.mixtape.moe/iltlos.wav (rename it to missile.wav)

And here's the full script (updated to be correct):

```
import struct
import wave
import numpy as np
import matplotlib.pyplot as plt
# import data from wave
wav_file = wave.open("missile.wav", 'r')
num_samples = wav_file.getnframes()
sampling_rate = wav_file.getframerate() / 2
data = wav_file.readframes(num_samples)
wav_file.close()
data = struct.unpack('{n}h'.format(n=num_samples), data)
data = np.array(data)
# fast fourier transform makes an array of the frequencies of sine waves that comprise the sound
data_fft = np.fft.rfft(data)
# generate list of ratios that can be used for tuning (not octave reduced)
MAX_HARMONIC = 5
valid_ratios = []
for i in range(1, MAX_HARMONIC + 1):
for j in range(1, MAX_HARMONIC + 1):
if i % 2 != 0 and j % 2 != 0:
valid_ratios.append(i/float(j))
valid_ratios.append(j/float(i))
# remove dupes
valid_ratios = list(set(valid_ratios))
# find all the frequencies with the valid ratios
valid_frequencies = []
multiple = 2
while(multiple < num_samples / 2):
multiple *= 2
for ratio in valid_ratios:
frequency = ratio * multiple
if frequency < num_samples / 2:
valid_frequencies.append(frequency)
# remove dupes and sort and turn into a numpy array
valid_frequencies = np.sort(np.array(list(set(valid_frequencies))))
# bin the data_fft into the nearest valid frequency
valid_frequencies = valid_frequencies.astype(int)
boundaries = np.concatenate([[0], np.round(np.sqrt(0.25 + valid_frequencies[:-1] * valid_frequencies[1:])).astype(int)])
select = np.abs(data_fft) > 1
filtered_data_fft = np.zeros_like(data_fft)
filtered_data_fft[valid_frequencies] = np.add.reduceat(np.where(select, data_fft, 0), boundaries)
# do the inverse fourier transform to get a sound wave back
recovered_signal = np.fft.irfft(filtered_data_fft)
# write sound wave to wave file
comptype="NONE"
compname="not compressed"
nchannels=1
sampwidth=2
wav_file=wave.open("missile_output.wav", 'w')
wav_file.setparams((nchannels, sampwidth, int(sampling_rate), num_samples, comptype, compname))
for s in recovered_signal:
wav_file.writeframes(struct.pack('h', s))
wav_file.close()
```