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I would like to create numpy.ndarray objects that hold complex integer values in them. NumPy does have complex support built-in, but for floating-point formats (float and double) only; I can create an ndarray with dtype='cfloat', for example, but there is no analogous dtype='cint16'. I would like to be able to create arrays that hold complex values represented using either 8- or 16-bit integers.

I found this mailing list post from 2007 where someone inquired about such support. The only workaround they recommended involved defining a new dtype that holds pairs of integers. This seems to represent each array element as a tuple of 2 values, but it's not clear what other work would need to be done in order to make the resulting datatype work seamlessly with arithmetic functions.

I also considered another approach based on registration of user-defined types with NumPy. I don't have a problem with going to the C API to set this up if it will work well. However, the documentation for the type descriptor strucure seems to suggest that the type's kind field only supports signed/unsigned integer, floating-point, and complex floating-point numeric types. It's not clear that I would be able to get anywhere trying to define a complex integer type.

Any recommendations on an approach that may work?

Edit: One more thing; whatever scheme I select must be amenable to wrapping of existing complex integer buffers without performing a copy. That is, I would like to be able to use PyArray_SimpleNewFromData() to expose the buffer to Python without having to make a copy of the buffer first. The buffer would be in interleaved real/imaginary format already, and would either be an array of int8_t or int16_t.

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    This is pretty - non-standard. How do you define division for this type? for example, what do you expect if you do (2+1j)/(3+0j)? Do you expect it to give you a complex result or (0+0j)? – mgilson Dec 13 '12 at 16:02
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    Out of curiosity, when in signal processing are complex integers used? I can't think of examples off the top of my head. – acjay Dec 13 '12 at 17:57
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    This is silly. Just do the work with floating point arithmetic, and assume all floating point values along the way. Then you won't face a type conversion (since you expect floats). I've written many digital signal processing modules for work in NumPy and even when working with things that specifically depend on Gaussian integer properties (root locus work or some special Laplace transforms for example), this type conversion has never been an issue. Not from a performance (speed, round-off) perspective nor a math perspective. – ely Jan 16 '13 at 20:51
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    @EMS: I fully understand the disadvantages of using integers for complex arithmetic. However, your argument isn't very constructive to this problem; suffice it to say that I have a requirement to sometimes interface with complex data that is formatted as integers. – Jason R Jan 29 '13 at 13:12
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    Just to add to the discussion, I too have a requirement for complex integers. It's basically for modelling fixed point implementations of algorithms. This most certainly is not rare. That said, in my case it can be worked around using floating point complex values with suitable rounding (since I'm only dealing with multiplication). – Henry Gomersall Jul 16 '14 at 17:27
10

I also deal with lots of complex integer data, generally basebanded data. I use

dtype = np.dtype([('re', np.int16), ('im', np.int16)])

It's not perfect, but it adequately describes the data. I use it for loading into memory without doubling the size of the data. It also has the advantage of being able to load and store transparently with HDF5.

DATATYPE  H5T_COMPOUND {
    H5T_STD_I16LE "re";
    H5T_STD_I16LE "im";
}

Using it is straightforward, just different.

x = np.zeros((3,3),dtype)
x[0,0]['re'] = 1
x[0,0]['im'] = 2
x
>> array([[(1, 2), (0, 0), (0, 0)],
>>        [(0, 0), (0, 0), (0, 0)],
>>        [(0, 0), (0, 0), (0, 0)]], 
>>  dtype=[('re', '<i2'), ('im', '<i2')])

To do math with it, I convert to a native complex float type. The obvious approach doesn't work, but it's also not that hard.

y = x.astype(np.complex64) # doesn't work, only gets the real part
y = x['re'] + 1.j*x['im']  # works, but slow and big
y = x.view(np.int16).astype(np.float32).view(np.complex64)
y
>> array([[ 1.+2.j,  0.+0.j,  0.+0.j],
>>        [ 0.+0.j,  0.+0.j,  0.+0.j],
>>        [ 0.+0.j,  0.+0.j,  0.+0.j]], dtype=complex64)

This last conversion approach inspired by https://stackoverflow.com/a/5658446/1784179

  • I convert my array f (which looks like that: array([(127, -128), (127, 127)], dtype=[('I', 'i1'), ('Q', 'i1')])) like that: f_complex = [np.complex(*x) for x in f]. Its still not a complex integer, but I think a more elegant solution to convert from int to complex float. – Stefan D. Dec 1 '15 at 18:48
  • @StefanD. I expected your method to be slower, but I was shocked to measure >10000x slower on 1M points. It also only works for 1D (instead of any array), and f_complex is a list, not an array. – Greg Allen Jan 8 '16 at 23:22
  • Your method doesn't seem to work with vectorized np operations.. – Jay Shin Mar 17 '18 at 21:25
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Python and hence Numpy does support complex numbers, if you want complex integers, just use np.round or ignore the decimal part.

e.g.

import numpy as np
#Create 100 complex numbers in a 1D array
a=100*np.random.sample(100)+(100*np.random.sample(100)*1j)
#Reshape to a 2D array
np.round(a)
a.reshape(10,10)

#Get the real and imag parts of a couple x/y points as integers
print int(a[1:2].real)
print int(a[3:4].imag)
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    The OP wants complex integers. – Vladimir F Feb 7 '13 at 13:51
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    That's what I was trying to say, use complex and treat as an integer. – Jason Morgan Feb 7 '13 at 13:57
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    This works for many applications. I suspect those down voting don't understand the problem. – Henry Gomersall Jul 17 '14 at 7:39

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