# Audio Processing C++ - FFT

I'm probably going to ask this incorrectly and make myself look very stupid but here goes:

I'm trying to do some audio manipulate and processing on a .wav file. Now, I am able to read all of the data (including the header) but need the data to be in frequency, and, in order to this I need to use an FFT.

I searched the internet high and low and found one, and the example was taken out of the "Numerical Recipes in C" book, however, I amended it to use vectors instead of arrays. Ok so here's the problem:

I have been given (as an example to use) a series of numbers and a sampling rate:

``````X = {50, 206, -100, -65, -50, -6, 100, -135}
``````

Sampling Rate : 8000 Number of Samples: 8

``````  0Hz     A=0       D=1.57079633
1000Hz     A=50      D=1.57079633
2000HZ     A=100     D=0
3000HZ     A=100     D=0
4000HZ     A=0       D=3.14159265
``````

The code that I re-wrote compiles, however, when trying to input these numbers into the equation (function) I get a Segmentation fault.. Is there something wrong with my code, or is the sampling rate too high? (The algorithm doesn't segment when using a much, much smaller sampling rate). Here is the code:

``````#include <iostream>
#include <math.h>
#include <vector>
using namespace std;

#define SWAP(a,b) tempr=(a);(a)=(b);(b)=tempr;
#define pi 3.14159

void ComplexFFT(vector<float> &realData, vector<float> &actualData, unsigned long sample_num, unsigned int sample_rate, int sign)
{
unsigned long n, mmax, m, j, istep, i;
double wtemp,wr,wpr,wpi,wi,theta,tempr,tempi;

// CHECK TO SEE IF VECTOR IS EMPTY;

actualData.resize(2*sample_rate, 0);

for(n=0; (n < sample_rate); n++)
{
if(n < sample_num)
{
actualData[2*n] = realData[n];
}else{
actualData[2*n] = 0;
actualData[2*n+1] = 0;
}
}

// Binary Inversion
n = sample_rate << 1;
j = 0;

for(i=0; (i< n /2); i+=2)
{
if(j > i)
{
SWAP(actualData[j], actualData[i]);
SWAP(actualData[j+1], actualData[i+1]);
if((j/2)<(n/4))
{
SWAP(actualData[(n-(i+2))], actualData[(n-(j+2))]);
SWAP(actualData[(n-(i+2))+1], actualData[(n-(j+2))+1]);
}
}
m = n >> 1;
while (m >= 2 && j >= m) {
j -= m;
m >>= 1;
}
j += m;
}
mmax=2;

while(n > mmax) {

istep = mmax << 1;
theta = sign * (2*pi/mmax);
wtemp = sin(0.5*theta);
wpr = -2.0*wtemp*wtemp;
wpi = sin(theta);
wr = 1.0;
wi = 0.0;

for(m=1; (m < mmax); m+=2) {
for(i=m; (i <= n); i += istep)
{
j = i*mmax;
tempr = wr*actualData[j-1]-wi*actualData[j];
tempi = wr*actualData[j]+wi*actualData[j-1];

actualData[j-1] = actualData[i-1] - tempr;
actualData[j] = actualData[i]-tempi;
actualData[i-1] += tempr;
actualData[i] += tempi;
}
wr = (wtemp=wr)*wpr-wi*wpi+wr;
wi = wi*wpr+wtemp*wpi+wi;
}
mmax = istep;
}

// determine if the fundamental frequency
int fundemental_frequency = 0;
for(i=2; (i <= sample_rate); i+=2)
{
if((pow(actualData[i], 2)+pow(actualData[i+1], 2)) > pow(actualData[fundemental_frequency], 2)+pow(actualData[fundemental_frequency+1], 2)) {
fundemental_frequency = i;
}

}
}
int main(int argc, char *argv[]) {

vector<float> numbers;
vector<float> realNumbers;

numbers.push_back(50);
numbers.push_back(206);
numbers.push_back(-100);
numbers.push_back(-65);
numbers.push_back(-50);
numbers.push_back(-6);
numbers.push_back(100);
numbers.push_back(-135);

ComplexFFT(numbers, realNumbers, 8, 8000, 0);

for(int i=0; (i < realNumbers.size()); i++)
{
cout << realNumbers[i] << "\n";
}
}
``````

The other thing, (I know this sounds stupid) but I don't really know what is expected of the "int sign" That is being passed through the ComplexFFT function, this is where I could be going wrong.

Does anyone have any suggestions or solutions to this problem?

Thank you :)

• Have you tried debugging to find out what line is causing a segfault? Also, you should really use `std::swap`, that `SWAP` macro is very brittle. – Gordon Bailey Aug 7 '12 at 17:53
• Hello, currently I cannot debug the solution :(! I was thinking about testing this data using MatLab and see what results I come up with – Phorce Aug 7 '12 at 17:56
• Why can you not debug it? Does it compile? – Gordon Bailey Aug 7 '12 at 17:57
• Have you considered using FFTW (fftw.org) rather than trying to roll your own? – andand Aug 7 '12 at 18:09
• @andand I have to write my own :( – Phorce Aug 7 '12 at 18:13

I think the problem lies in errors in how you translated the algorithm.

• Did you mean to initialize `j` to `1` rather than `0`?

• `for(i = 0; (i < n/2); i += 2)` should probably be `for (i = 1; i < n; i += 2)`.

• Your `SWAP`s should probably be

``````SWAP(actualData[j - 1], actualData[i - 1]);
SWAP(actualData[j], actualData[i]);
``````
• What are the following `SWAP`s for? I don't think they're needed.

``````if((j/2)<(n/4))
{
SWAP(actualData[(n-(i+2))], actualData[(n-(j+2))]);
SWAP(actualData[(n-(i+2))+1], actualData[(n-(j+2))+1]);
}
``````
• The `j >= m` in `while (m >= 2 && j >= m)` should probably be `j > m` if you intended to do bit reversal.

• In the code implementing the Danielson-Lanczos section, are you sure `j = i*mmax;` was not supposed to be an addition, i.e. `j = i + mmax;`?

Apart from that, there are a lot of things you can do to simplify your code.

Using your `SWAP` macro should be discouraged when you can just use `std::swap`... I was going to suggest `std::swap_ranges`, but then I realized you only need to swap the real parts, since your data is all reals (your time-series imaginary parts are all `0`):

``````std::swap(actualData[j - 1], actualData[i - 1]);
``````

You can simplify the entire thing using `std::complex`, too.

• Heyy thank you for your reply :)! I did what you said, and, it now allows me to have sample_rate at 8000, only thing is, I don't think the results are right, but, the inputs I'm using are from a completely different algorithm to one I'm using.. Is there a way to check my answers, without using pen and paper? Thank you again – Phorce Aug 7 '12 at 19:07
• @user1582478 there are other tools which will implement discrete Fourier transforms. See for example this online Java applet that I found from a Google search :p – oldrinb Aug 7 '12 at 19:16
• @user1582478 I found another flaw in your implementation and corrected an error in my `std::copy` example. :-) – oldrinb Aug 7 '12 at 19:37
• Thanks for the reply. It seems to work :)! Well, for small numbers.. You don't happen to know what "sample_rate" does? – Phorce Aug 7 '12 at 19:41
• @user1582478 actually I think `sample_rate` is the number of real time series samples to compute the DFT for, while `sample_num` is the number of actually provided samples in `realData`. The discrepancy between the two is filled in with `0`. – oldrinb Aug 7 '12 at 19:56

I reckon its down to the re-sizing of your vector.

One possibility: Maybe re-sizing will create temp objects on the stack before moving them back to heap i think.

• But if I don't re-size the vector "actualData" it will cause it to segment even with a small sample rate... Thanks for your reply though – Phorce Aug 7 '12 at 18:13
• Try reserve instead, maybe more efficient (You know the size you will need). – Science_Fiction Aug 7 '12 at 18:21

The FFT in Numerical Recipes in C uses the Cooley-Tukey Algorithm, so in answer to your question at the end, the `int sign` being passed allows the same routine to be used to compute both the forward (`sign=-1`) and inverse (`sign=1`) FFT. This seems to be consistent with the way you are using `sign` when you define `theta = sign * (2*pi/mmax)`.