Executing fft using vDSP_fft_zrip on N point data gives you N/2 point PACKED split complex where in index 0, the real part shows the DC amount (index 0 of fft) and the imaginary part shows Nyquist amount (index N of fft).
for more details: https://developer.apple.com/library/ios/documentation/Performance/Conceptual/vDSP_Programming_Guide/UsingFourierTransforms/UsingFourierTransforms.html#//apple_ref/doc/uid/TP40005147-CH3-SW1

One trick you can use vDSP_zvmags and get the correct result is like this:

```
const int LOG2_N = 10 ; // (say N=1024)
const int N = 1 << LOG2_N ;
FFTSetup fftSetup;
DSPSplitComplex tempSplitComplex;
x = new float[N] ; // N point data you can put your data
X = new float[N/2+1] ; // magnitude of fft of signal from index 0 (dc) to N/2 (Nyquist)
tempSplitComplex.realp = new float[N/2];
tempSplitComplex.imagp = new float[N/2];
fftSetup = vDSP_create_fftsetup(LOG_N, kFFTRadix2);
vDSP_ctoz((DSPComplex *) x, 2, &tempSplitComplex, 1, N/2 ) ;
// perform fft
vDSP_fft_zrip(fftSetup, &tempSplitComplex, 1, LOG_N, kFFTDirection_Forward) ;
// calculating square of magnitude for each value
vDSP_zvmags(&tempSplitComplex, 1, X, 1, N/2);
// after this line X[0] is incorrect and X[N] is not calculated,
// but others are correct, so we need to fix those two (X[0], and X[N])
// DC and Nyquist ffts' imaginary parts are zero,
// so Nyquist fft is stored in imaginary part of DC fft
X[0] = tempSplitComplex.realp[0] * tempSplitComplex.realp[0]; // DC squared
X[N/2] = tempSplitComplex.imagp[0] * tempSplitComplex.imagp[0]; // Nyquist squared
```