Function common_precision takes two numpy arrays, say x and y. I want to make sure that they are in the same and the highest precision. It seems that relational comparison of dtypes does something to what I want, but:

  1. I don't know what it actually compares
  2. It thinks that numpy.int64 < numpy.float16, which I'm not sure if I agree

    def common_precision(x, y):
        if x.dtype > y.dtype:
           y = y.astype(x.dtype)
           x = x.astype(y.dtype)
        return (x, y)

Edited: Thanks to kennytm's answer I found that NumPy's find_common_type does exactly what I wanted.

    def common_precision(self, x, y):        
        dtype = np.find_common_type([x.dtype, y.dtype], [])
        if x.dtype != dtype: x = x.astype(dtype)
        if y.dtype != dtype: y = y.astype(dtype)       
        return x, y

x.dtype > y.dtype means y.dtype can be casted to x.dtype (&& x.dtype != y.type), so:

>>> numpy.dtype('i8') < numpy.dtype('f2')
>>> numpy.dtype('i8') > numpy.dtype('f2')

float16 and int64 are simply incompatible. You could extract some information like:

>>> numpy.dtype('f2').kind
>>> numpy.dtype('f2').itemsize
>>> numpy.dtype('i8').kind
>>> numpy.dtype('i8').itemsize

and determine your comparison scheme based on this.

  • This did not entirely solve my question, but your answer and your link got me on the correct path. Thanks! – Dawid Laszuk Feb 10 '17 at 20:48

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