This is a conscious design decision by the `numpy`

authors. When deciding on the resulting type, only the types of the operands are considered, not their actual values. And for the operation you perform, there is a risk of having a result outside the valid range, e.g. if you subtract a very large `uint64`

number, the result would not fit in an `int64`

. The safe selection is thus to convert to `float64`

, which certainly will fit the result (possibly with reduced precision, though).

Compare with an example of `x = np.int32(2) - np.uint32(1)`

. This can always be safely represented as an `int64`

, therefore that type is chosen. The same would be true for `x = np.int64(2) - np.uint32(1)`

. This will also yield an `int64`

.

The alternative would be to follow e.g. the *c* rules, which would cast everything to `uint64`

. But that could, of course, lead to very strange results with over/underflows.

If you want to know ahead of time what type you will end up with, look into `np.result_type()`

, `np.can_cast()`

, and `np.promote_types()`

. Reading about this in the docs might also help you understand the issue a bit better.