New and improved version which handles arbitrary strides in the input and output arrays.
By default this one is now not-in-place and creates a new array.
It mimics the Numpy FFT routines except that it has a different normalisation.

```
''' Wrapper to MKL FFT routines '''
import numpy as _np
import ctypes as _ctypes
mkl = _ctypes.cdll.LoadLibrary("mk2_rt.dll")
_DFTI_COMPLEX = _ctypes.c_int(32)
_DFTI_DOUBLE = _ctypes.c_int(36)
_DFTI_PLACEMENT = _ctypes.c_int(11)
_DFTI_NOT_INPLACE = _ctypes.c_int(44)
_DFTI_INPUT_STRIDES = _ctypes.c_int(12)
_DFTI_OUTPUT_STRIDES = _ctypes.c_int(13)
def fft2(a, out=None):
'''
Forward two-dimensional double-precision complex-complex FFT.
Uses the Intel MKL libraries distributed with Enthought Python.
Normalisation is different from Numpy!
By default, allocates new memory like 'a' for output data.
Returns the array containing output data.
'''
assert a.dtype == _np.complex128
assert len(a.shape) == 2
inplace = False
if out is a:
inplace = True
elif out is not None:
assert out.dtype == _np.complex128
assert a.shape == out.shape
assert not _np.may_share_memory(a, out)
else:
out = _np.empty_like(a)
Desc_Handle = _ctypes.c_void_p(0)
dims = (_ctypes.c_int*2)(*a.shape)
mkl.DftiCreateDescriptor(_ctypes.byref(Desc_Handle), _DFTI_DOUBLE, _DFTI_COMPLEX, _ctypes.c_int(2), dims )
#Set input strides if necessary
if not a.flags['C_CONTIGUOUS']:
in_strides = (_ctypes.c_int*3)(0, a.strides[0]/16, a.strides[1]/16)
mkl.DftiSetValue(Desc_Handle, _DFTI_INPUT_STRIDES, _ctypes.byref(in_strides))
if inplace:
#Inplace FFT
mkl.DftiCommitDescriptor(Desc_Handle)
mkl.DftiComputeForward(Desc_Handle, a.ctypes.data_as(_ctypes.c_void_p) )
else:
#Not-inplace FFT
mkl.DftiSetValue(Desc_Handle, _DFTI_PLACEMENT, _DFTI_NOT_INPLACE)
#Set output strides if necessary
if not out.flags['C_CONTIGUOUS']:
out_strides = (_ctypes.c_int*3)(0, out.strides[0]/16, out.strides[1]/16)
mkl.DftiSetValue(Desc_Handle, _DFTI_OUTPUT_STRIDES, _ctypes.byref(out_strides))
mkl.DftiCommitDescriptor(Desc_Handle)
mkl.DftiComputeForward(Desc_Handle, a.ctypes.data_as(_ctypes.c_void_p), out.ctypes.data_as(_ctypes.c_void_p) )
mkl.DftiFreeDescriptor(_ctypes.byref(Desc_Handle))
return out
def ifft2(a, out=None):
'''
Backward two-dimensional double-precision complex-complex FFT.
Uses the Intel MKL libraries distributed with Enthought Python.
Normalisation is different from Numpy!
By default, allocates new memory like 'a' for output data.
Returns the array containing output data.
'''
assert a.dtype == _np.complex128
assert len(a.shape) == 2
inplace = False
if out is a:
inplace = True
elif out is not None:
assert out.dtype == _np.complex128
assert a.shape == out.shape
assert not _np.may_share_memory(a, out)
else:
out = _np.empty_like(a)
Desc_Handle = _ctypes.c_void_p(0)
dims = (_ctypes.c_int*2)(*a.shape)
mkl.DftiCreateDescriptor(_ctypes.byref(Desc_Handle), _DFTI_DOUBLE, _DFTI_COMPLEX, _ctypes.c_int(2), dims )
#Set input strides if necessary
if not a.flags['C_CONTIGUOUS']:
in_strides = (_ctypes.c_int*3)(0, a.strides[0]/16, a.strides[1]/16)
mkl.DftiSetValue(Desc_Handle, _DFTI_INPUT_STRIDES, _ctypes.byref(in_strides))
if inplace:
#Inplace FFT
mkl.DftiCommitDescriptor(Desc_Handle)
mkl.DftiComputeBackward(Desc_Handle, a.ctypes.data_as(_ctypes.c_void_p) )
else:
#Not-inplace FFT
mkl.DftiSetValue(Desc_Handle, _DFTI_PLACEMENT, _DFTI_NOT_INPLACE)
#Set output strides if necessary
if not out.flags['C_CONTIGUOUS']:
out_strides = (_ctypes.c_int*3)(0, out.strides[0]/16, out.strides[1]/16)
mkl.DftiSetValue(Desc_Handle, _DFTI_OUTPUT_STRIDES, _ctypes.byref(out_strides))
mkl.DftiCommitDescriptor(Desc_Handle)
mkl.DftiComputeBackward(Desc_Handle, a.ctypes.data_as(_ctypes.c_void_p), out.ctypes.data_as(_ctypes.c_void_p) )
mkl.DftiFreeDescriptor(_ctypes.byref(Desc_Handle))
return out
```