I'm looking at a third-party lib that has the following if-test:

if isinstance(xx_, numpy.ndarray) and xx_.dtype is numpy.float64 and xx_.flags.contiguous:
    xx_[:] = ctypes.cast(xx_.ctypes._as_parameter_,ctypes.POINTER(ctypes.c_double))

It appears that xx_.dtype is numpy.float64 always fails:

>>> xx_ = numpy.zeros(8, dtype=numpy.float64)
>>> xx_.dtype is numpy.float64


What is the correct way to test that the dtype of a numpy array is float64 ?

  • 1
    First, why do you have both numpy and np in the same script? Is there any chance they're different copies of the module? (Try numpy is np to see…) – abarnert Nov 14 '14 at 2:17
  • 1
    typo - fixed now. That later example is just to demonstrate a test showing the comparison always fails, it's not part of the third-party lib – Zero Nov 14 '14 at 2:18
  • As, then I didn't really need to prove the same thing in my answer that you already knew, and could have made it shorter. Oh well. :) – abarnert Nov 14 '14 at 2:28
  • If it's not too much trouble, could you edit you answer to provide the correct way to do the test? I think I'll edit my question to make that more the focus, as doing the test correctly will be of more interest to anyone looking at this question in the future. – Zero Nov 14 '14 at 2:36
  • I'm not 100% sure what the right test is. It's probably ==, but, without knowing why it's checking, it may not be. I'll try to write the answer to convey that. – abarnert Nov 14 '14 at 2:58

This is a bug in the lib.

dtype objects can be constructed dynamically. And NumPy does so all the time. There's no guarantee anywhere that they're interned, so constructing a dtype that already exists will give you the same one.

On top of that, np.float64 isn't actually a dtype; it's a… I don't know what these types are called, but the types used to construct scalar objects out of array bytes, which are usually found in the type attribute of a dtype, so I'm going to call it a dtype.type. (Note that np.float64 subclasses both NumPy's numeric tower types and Python's numeric tower ABCs, while np.dtype of course doesn't.)

Normally, you can use these interchangeably; when you use a dtype.type—or, for that matter, a native Python numeric type—where a dtype was expected, a dtype is constructed on the fly (which, again, is not guaranteed to be interned), but of course that doesn't mean they're identical:

>>> np.float64 == np.dtype(np.float64) == np.dtype('float64') 
>>> np.float64 == np.dtype(np.float64).type

The dtype.type usually will be identical if you're using builtin types:

>>> np.float64 is np.dtype(np.float64).type

But two dtypes are often not:

>>> np.dtype(np.float64) is np.dtype('float64')

But again, none of that is guaranteed. (Also, note that np.float64 and float use the exact same storage, but are separate types. And of course you can also make a dtype('f8'), which is guaranteed to work the same as dtype(np.float64), but that doesn't mean 'f8' is, or even ==, np.float64.)

So, it's possible that constructing an array by explicitly passing np.float64 as its dtype argument will mean you get back the same instance when you check the dtype.type attribute, but that isn't guaranteed. And if you pass np.dtype('float64'), or you ask NumPy to infer it from the data, or you pass a dtype string for it to parse like 'f8', etc., it's even less likely to match. More importantly, you definitely not get np.float64 back as the dtype itself.

So, how should it be fixed?

Well, the docs define what it means for two dtypes to be equal, and that's a useful thing, and I think it's probably the useful thing you're looking for here. So, just replace the is with ==:

if isinstance(xx_, numpy.ndarray) and xx_.dtype == numpy.float64 and xx_.flags.contiguous:

However, to some extent I'm only guessing that's what you're looking for. (The fact that it's checking the contiguous flag implies that it's probably going to go right into the internal storage… but then why isn't it checking C vs. Fortran order, or byte order, or anything else?)



x = np.zeros(8, dtype=np.float64)
print x.dtype is np.dtype(np.float64))    

is tests for the identity of 2 objects, whether they have the same id(). It is used for example to test is None, but can give errors when testing for integers or strings. But in this case, there's a further problem, x.dtype and np.float64 are not the same class.

isinstance(x.dtype, np.dtype)  # True
isinstance(np.float64, np.dtype) # False

x.dtype.__class__  # numpy.dtype
np.float64.__class__ # type

np.float64 is actually a function. np.float64() produces 0.0. x.dtype() produces an error. (correction np.float64 is a class.)

In my interactive tests:

x.dtype is np.dtype(np.float64)

returns True. But I don't know if that's universally the case, or just the result of some sort of local caching. The dtype documentation mentions a dtype attribute:

dtype.num A unique number for each of the 21 different built-in types.

Both dtypes give 12 for this num.

x.dtype == np.float64

tests True.

Also, using type works:

x.dtype.type is np.float64  # True

When I import ctypes and do the cast (with your xx_) I get an error:

ValueError: setting an array element with a sequence.

I don't know enough of ctypes to understand what it is trying to do. It looks like it is doing a type conversion of the data pointer of xx_, xx_.ctypes._as_parameter_ is the same number as xx_.__array_interface__['data'][0].

In the numpy test code I find these dtype tests:

issubclass(arr.dtype.type, (nt.integer, nt.bool_)
assert_(dat.dtype.type is np.float64)
assert_equal(A.dtype.type, np.unicode_)
assert_equal(r['col1'].dtype.kind, 'i')

numpy documentation also talks about

np.issubdtype(x.dtype, np.float64)
np.issubsctype(x, np.float64)

both of which use issubclass.

Further tracing of the c code suggests that x.dtype == np.float64 is evaluated as:

x.dtype.num == np.dtype(np.float64).num

That is, the scalar type is converted to a dtype, and the .num attributes compared. The code is in scalarapi.c, descriptor.c, multiarraymodule.c of numpy / core / src / multiarray

  • There's some useful information here. It's true that a dtype has a type, which is the class used to construct scalars of the type, and not the same as the dtype itself, and that float64 is the latter, not the former. On the other hand, it's not true that float64 is actually a function (the fact that its type is type proves that). And you can generally use a dtype.type wherever you can use a dtype; doing so just constructs a new dtype object on the fly. Note that dtype('float64') == dtype(float64) == float64. And I think the last one is key to what the OP cares about here. – abarnert Nov 14 '14 at 20:06
  • OK, `np.float64' isn't a function. Would callable class be more accurate? – hpaulj Nov 14 '14 at 21:37
  • Well, all classes are callable. I don't understand what contrast you're aiming for there. – abarnert Nov 14 '14 at 22:09
  • You're right. I was thinking of class objects being callable, which isn't the case here. I'm trying to pin down the difference between a type like float64 and a dtype. Do you know where the __eq__ for dtype is defined (or its equivalent in c code)? – hpaulj Nov 15 '14 at 0:11
  • For the first half, the difference is that a float64 is a numeric type. I don't know what the right term for those is, but it's similar to the builtin float (in fact, nearly interchangeable with it; IIRC, it's just a subclass that also inherits from the NumPy numeric tower types) or int. The same way you can construct np.dtype(float), you can construct np.dtype(float64). And the same way you can just pass float anywhere a dtype is expected, you can pass float64. – abarnert Nov 15 '14 at 0:14

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