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I have made some Numpy C-extensions before with great help from this site, but as far as I can see the returned parameters are all fixed length.

Is there any way to have a Numpy C-extension return a variable length numpy array instead?

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what do you refer to as a "variable length numpy array"? As far as I know, numpy arrays cannot be resized once their size is set. –  albertov Jan 7 '11 at 14:04
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1 Answer

You may find it easier to make numpy extensions in Cython using the Numpy C-API which simplifies the process as it allows you to mix python and c objects. In that case there is little difficult about making a variable length array, you can simply specify an array with an arbitrary shape.

The Cython numpy tutorial is probably the best source on this topic.

For example, here is a function I recently wrote:

import numpy as np
cimport numpy as np
cimport cython

dtype = np.double
ctypedef double dtype_t

np.import_ufunc()
np.import_array()

def ewma(a, d, axis):
    #Calculates the exponentially weighted moving average of array a along axis using the parameter d.
    cdef void *args[1]

    cdef double weight[1]
    weight[0] = <double>np.exp(-d)


    args[0] = &weight[0]

    return apply_along_axis(&ewma_func, np.array(a, dtype = float), np.double, np.double, False, &(args[0]), <int>axis)

cdef void ewma_func(int n, void* aData,int astride, void* oData, int ostride, void** args):
    #Exponentially weighted moving average calculation function 

    cdef double avg = 0.0
    cdef double weight = (<double*>(args[0]))[0]
    cdef int i = 0

    for i in range(n): 

        avg = (<double*>((<char*>aData) + i * astride))[0]*weight + avg * (1.0 - weight) 


        (<double*>((<char*>oData) + i * ostride))[0] = avg  

ctypedef void (*func_1d)(int, void*, int, void*, int, void **)

cdef apply_along_axis(func_1d function, a, adtype, odtype, reduce,  void** args, int axis):
    #generic function for applying a cython function along a particular dimension

    oshape = list(a.shape)

    if reduce :
        oshape[axis] = 1

    out = np.empty(oshape, odtype)

    cdef np.flatiter ita, ito

    ita = np.PyArray_IterAllButAxis(a,   &axis)
    ito = np.PyArray_IterAllButAxis(out, &axis)

    cdef int axis_length = a.shape[axis]
    cdef int a_axis_stride = a.strides[axis]
    cdef int o_axis_stride = out.strides[axis]

    if reduce: 
        o_axis_stride = 0

    while np.PyArray_ITER_NOTDONE(ita):

        function(axis_length, np.PyArray_ITER_DATA (ita), a_axis_stride, np.PyArray_ITER_DATA (ito), o_axis_stride, args)

        np.PyArray_ITER_NEXT(ita)
        np.PyArray_ITER_NEXT(ito)

    if reduce:  
        oshape.pop(axis)
        out.shape = oshape

    return out  

If this doesn't suit you, there is a function for making a new empty array with arbitrary shape (link).

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