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`

.

`(2+1j)/(3+0j)`

? Do you expect it to give you a complex result or`(0+0j)`

? – mgilson Dec 13 '12 at 16:02requirementto sometimes interface with complex data that is formatted as integers. – Jason R Jan 29 '13 at 13:12notrare. 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