I'm trying to implement NumPy's `rfft2()`

, the **RFFT** function that supports arrays with 2-dimensions, by performing 1D RFFT on each row and then performing 1D RFFT again on each column of the previous result.

This approach works well to implement a **2D FFT** function, as discussed previously on this post, but it doesn't seem to work for **2D RFFT**.

Here's a script that implements a custom 2D FFT function that this follows this idea using the 1D version of NumPy's FFT as basis and later compares its result to the actual 2D version from NumPy:

```
import cmath
import numpy as np
import math
def my_fft2d(matrix):
fft_rows = [np.fft.fft(row) for row in matrix]
return np.transpose([np.fft.fft(row) for row in np.transpose(fft_rows)])
# initialize test data
img = np.array([[0,0,0,0], [0,1,0,0], [0,0,0,0], [0,0,0,0]])
print('img shape=', img.shape)
# perform custom FFT2D and print result
custom_result = my_fft2d(img)
print('\ncustom_result shape=', custom_result.shape)
for row in custom_result:
print(', '.join(['%.3f + %.3fi' % (x.real, x.imag) for x in row]))
# perform numpy FFT2D and print result
numpy_result = np.fft.fft2(img)
print('\nnumpy_result shape=', numpy_result.shape)
for row in numpy_result:
print(', '.join(['%.3f + %.3fi' % (x.real, x.imag) for x in row]))
# compare results
print('\nAre the results equivalent to NumPy?', np.allclose(custom_result, custom_result))
print('ASSERT(assert_array_almost_equal):', np.testing.assert_array_almost_equal(custom_result, custom_result))
```

**Output**:

```
img shape= (4, 4)
custom_result shape= (4, 4)
1.000 + 0.000i, 0.000 + -1.000i, -1.000 + 0.000i, 0.000 + 1.000i
0.000 + -1.000i, -1.000 + 0.000i, 0.000 + 1.000i, 1.000 + 0.000i
-1.000 + 0.000i, 0.000 + 1.000i, 1.000 + 0.000i, 0.000 + -1.000i
0.000 + 1.000i, 1.000 + 0.000i, 0.000 + -1.000i, -1.000 + 0.000i
numpy_result shape= (4, 4)
1.000 + 0.000i, 0.000 + -1.000i, -1.000 + 0.000i, 0.000 + 1.000i
0.000 + -1.000i, -1.000 + 0.000i, 0.000 + 1.000i, 1.000 + 0.000i
-1.000 + 0.000i, 0.000 + 1.000i, 1.000 + 0.000i, 0.000 + -1.000i
0.000 + 1.000i, 1.000 + 0.000i, 0.000 + -1.000i, -1.000 + 0.000i
Are the results equivalent to NumPy? True
ASSERT(assert_array_almost_equal): None
```

The output of the script shows that `my_fft2d()`

implementation is compatible with `np.fft.fft2()`

.

However, when the same logic is applied to implement the RFFT version of the transform, the resulting array has a different shape, as the script below demonstrates:

```
def my_rfft2d(matrix):
fft_rows = [np.fft.rfft(row) for row in matrix]
return np.transpose([np.fft.rfft(row) for row in np.transpose(fft_rows)])
# initialize test data
img = np.array([[0,0,0,0], [0,1,0,0], [0,0,0,0], [0,0,0,0]])
print('img shape=', img.shape)
# perform custom FFT2D and print result
custom_result = my_rfft2d(img)
print('\ncustom_result shape=', custom_result.shape)
for row in custom_result:
print(', '.join(['%.3f + %.3fi' % (x.real, x.imag) for x in row]))
# perform numpy FFT2D and print results
numpy_result = np.fft.rfft2(img)
print('\nnumpy_result shape=', numpy_result.shape)
for row in numpy_result:
print(', '.join(['%.3f + %.3fi' % (x.real, x.imag) for x in row]))
```

**Output**:

```
img shape= (4, 4)
C:\Users\username\AppData\Roaming\Python\Python37\site-packages\numpy\fft\_pocketfft.py:77: ComplexWarning: Casting complex values to real discards the imaginary part
r = pfi.execute(a, is_real, is_forward, fct)
custom_result shape= (3, 3)
1.000 + 0.000i, 0.000 + 0.000i, -1.000 + 0.000i
0.000 + -1.000i, 0.000 + 0.000i, 0.000 + 1.000i
-1.000 + 0.000i, 0.000 + 0.000i, 1.000 + 0.000i
numpy_result shape= (4, 3)
1.000 + 0.000i, 0.000 + -1.000i, -1.000 + 0.000i
0.000 + -1.000i, -1.000 + 0.000i, 0.000 + 1.000i
-1.000 + 0.000i, 0.000 + 1.000i, 1.000 + 0.000i
0.000 + 1.000i, 1.000 + 0.000i, 0.000 + -1.000i
```

As you can see, there are two problems in the output:

- a warning from numpy complains about something I'm not totally sure how to fix;
- the custom implementation of 2D RFFT returns a result that has less rows than the one returned by
`np.fft.rfft2()`

;

**How can I fix this problem and make my_rfft2d() compatible with np.fft.rfft2()?**