Can you please help understand what are the main differences (if any) between the native int type and the numpy.int32 or numpy.int64 types?
3 Answers
There are several major differences. The first is that python integers are flexiblesized (at least in python 3.x). This means they can grow to accommodate any number of any size (within memory constraints, of course). The numpy integers, on the other hand, are fixedsized. This means there is a maximum value they can hold. This is defined by the number of bytes in the integer (int32
vs. int64
), with more bytes holding larger numbers, as well as whether the number is signed or unsigned (int32
vs. uint32
), with unsigned being able to hold larger numbers but not able to hold negative number.
So, you might ask, why use the fixedsized integers? The reason is that modern processors have builtin tools for doing math on fixedsize integers, so calculations on those are much, much, much faster. In fact, python uses fixedsized integers behindthescenes when the number is small enough, only switching to the slower, flexiblesized integers when the number gets too large.
Another advantage of fixedsized values is that they can be placed into consistentlysized adjacent memory blocks of the same type. This is the format that numpy arrays use to store data. The libraries that numpy relies on are able to do extremely fast computations on data in this format, in fact modern CPUs have builtin features for accelerating this sort of computation. With the variablesized python integers, this sort of computation is impossible because there is no way to say how big the blocks should be and no consistentcy in the data format.
That being said, numpy is actually able to make arrays of python integers. But rather than arrays containing the values, instead they are arrays containing references to other pieces of memory holding the actual python integers. This cannot be accelerated in the same way, so even if all the python integers fit within the fixed integer size, it still won't be accelerated.
None of this is the case with Python 2. In Python 2, Python integers are fixed integers and thus can be directly translated into numpy integers. For variablelength integers, Python 2 had the long
type. But this was confusing and it was decided this confusion wasn't worth the performance gains, especially when people who need performance would be using numpy or something like it anyway.
Another way to look at the differences is to ask what methods do the 2 kinds of objects have.
In Ipython I can use tab complete to look at methods:
In [1277]: x=123; y=np.int32(123)
int
methods and attributes:
In [1278]: x.<tab>
x.bit_length x.denominator x.imag x.numerator x.to_bytes
x.conjugate x.from_bytes x.real
int
'operators'
In [1278]: x.__<tab>
x.__abs__ x.__init__ x.__rlshift__
x.__add__ x.__int__ x.__rmod__
x.__and__ x.__invert__ x.__rmul__
x.__bool__ x.__le__ x.__ror__
...
x.__gt__ x.__reduce_ex__ x.__xor__
x.__hash__ x.__repr__
x.__index__ x.__rfloordiv__
np.int32
methods and attributes (or properties). Some of the same, but a lot more, basically all the ndarray
ones:
In [1278]: y.<tab>
y.T y.denominator y.ndim y.size
y.all y.diagonal y.newbyteorder y.sort
y.any y.dtype y.nonzero y.squeeze
...
y.cumsum y.min y.setflags
y.data y.nbytes y.shape
the y.__
methods look a lot like the int
ones. They can do the same math.
In [1278]: y.__<tab>
y.__abs__ y.__getitem__ y.__reduce_ex__
y.__add__ y.__gt__ y.__repr__
...
y.__format__ y.__rand__ y.__subclasshook__
y.__ge__ y.__rdivmod__ y.__truediv__
y.__getattribute__ y.__reduce__ y.__xor__
y
is in many ways the same as a 0d array. Not identical, but close.
In [1281]: z=np.array(123,dtype=np.int32)
np.int32
is what I get when I index an array of that type:
In [1300]: A=np.array([0,123,3])
In [1301]: A[1]
Out[1301]: 123
In [1302]: type(A[1])
Out[1302]: numpy.int32
I have to use item
to remove all of the numpy
wrapping.
In [1303]: type(A[1].item())
Out[1303]: int
As a numpy
user, an np.int32
is an int
with a numpy
wrapper. Or conversely a single element of an ndarray
. Usually I don't pay attention as to whether A[0]
is giving me the 'native' int
or the numpy equivalent. In contrast to some new users, I rarely use np.int32(123)
; I would use np.array(123)
instead.
A = np.array([1,123,0], np.int32)
does not contain 3 np.int32
objects. Rather its data buffer is 3*4=12 bytes long. It's the array overhead that interprets it as 3 ints in a 1d. And view
shows me the same databuffer with different interpretations:
In [1307]: A.view(np.int16)
Out[1307]: array([ 1, 0, 123, 0, 0, 0], dtype=int16)
In [1310]: A.view('S4')
Out[1310]: array([b'\x01', b'{', b''], dtype='S4')
It's only when I index a single element that I get a np.int32
object.
The list L=[1, 123, 0]
is different; it's a list of pointers  pointers to int
objects else where in memory. Similarly for a dtype=object array.
I think that the biggest difference is that the numpy types are compatible with their C counterparts. For one thing, this means that numpy ints can overflow...
>>> np.int32(2**32)
0
This is why you can create an array of integers and specify the datatype as np.int32
for example. Numpy will then allocate an array that is large enough to hold the specified number of 32 bit integers and then when you need the values, it'll convert the Cintegers to np.int32
(which is very quick). The benefits of being able to convert back and forth from np.int32
and a Cint also include huge memory savings. Python objects are generally pretty big:
>>> sys.getsizeof(1)
24
A np.int32
isn't any smaller:
>>> sys.getsizeof(np.int32(1))
28
but remember, most of the time when we're working with numpy arrays, we're only working with the C integers which only take 4 bytes (instead of 24). We only need to work with the np.int32
when dealing with scalar values from an array.

2

4I think that 24 is the overhead of virtually any python object. 28 is because we needed to construct a python object and stick a cinteger in it  I think (though I could be wrong  I'm not a numpy dev or anything). When you pack a whole lot of cintegers into a numpy array however, you only need 1 python object for all of those integers.– mgilsonJan 9, 2019 at 18:26