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I am a bit struggled with so many int data types in cython.

np.int, np.int_, np.int_t, int

I guess int in pure python is equivalent to np.int_, then where does np.int come from? I cannot find the document from numpy? Also, why does np.int_ exist given we do already have int?

In cython, I guess int becomes a C type when used as cdef int or ndarray[int], and when used as int() it stays as the python caster?

Is np.int_ equivalent to long in C? so cdef long is the identical to cdef np.int_?

Under what circumstances should I use np.int_t instead of np.int? e.g. cdef np.int_t, ndarray[np.int_t] ...

Can someone briefly explain how the wrong use of those types would affect the performance of compiled cython code?

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3 Answers 3

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It's a bit complicated because the names have different meanings depending on the context.

int

  1. In Python

    The int is normally just a Python type, it's of arbitrary precision, meaning that you can store any conceivable integer inside it (as long as you have enough memory).

    >>> int(10**50)
    100000000000000000000000000000000000000000000000000
    
  2. However, when you use it as dtype for a NumPy array it will be interpreted as np.int_ 1. Which is not of arbitrary precision, it will have the same size as C's long:

    >>> np.array(10**50, dtype=int)
    OverflowError: Python int too large to convert to C long
    

    That also means the following two are equivalent:

    np.array([1,2,3], dtype=int)
    np.array([1,2,3], dtype=np.int_)
    
  3. As Cython type identifier it has another meaning, here it stands for the type int. It's of limited precision (typically 32bits). You can use it as Cython type, for example when defining variables with cdef:

    cdef int value = 100    # variable
    cdef int[:] arr = ...   # memoryview
    

    As return value or argument value for cdef or cpdef functions:

    cdef int my_function(int argument1, int argument2):
        # ...
    

    As "generic" for ndarray:

    cimport numpy as cnp
    cdef cnp.ndarray[int, ndim=1] val = ...
    

    For type casting:

    avalue = <int>(another_value)
    

    And probably many more.

  4. In Cython but as Python type. You can still call int and you'll get a "Python int" (of arbitrary precision), or use it for isinstance or as dtype argument for np.array. Here the context is important, so converting to a Python int is different from converting to a C int:

    cdef object val = int(10)  # Python int
    cdef int val = <int>(10)   # C int
    

np.int

Actually this is very easy. It's just an alias for int:

>>> int is np.int
True

So everything from above applies to np.int as well. However you can't use it as a type-identifier except when you use it on the cimported package. In that case it represents the Python integer type.

cimport numpy as cnp

cpdef func(cnp.int obj):
    return obj

This will expect obj to be a Python integer not a NumPy type:

>>> func(np.int_(10))
TypeError: Argument 'obj' has incorrect type (expected int, got numpy.int32)
>>> func(10)
10

My advise regarding np.int: Avoid it whenever possible. In Python code it's equivalent to int and in Cython code it's also equivalent to Pythons int but if used as type-identifier it will probably confuse you and everyone who reads the code! It certainly confused me...

np.int_

Actually it only has one meaning: It's a Python type that represents a scalar NumPy type. You use it like Pythons int:

>>> np.int_(10)        # looks like a normal Python integer
10
>>> type(np.int_(10))  # but isn't (output may vary depending on your system!)
numpy.int32

Or you use it to specify the dtype, for example with np.array:

>>> np.array([1,2,3], dtype=np.int_)
array([1, 2, 3])

But you cannot use it as type-identifier in Cython.

cnp.int_t

It's the type-identifier version for np.int_. That means you can't use it as dtype argument. But you can use it as type for cdef declarations:

cimport numpy as cnp
import numpy as np

cdef cnp.int_t[:] arr = np.array([1,2,3], dtype=np.int_)
     |---TYPE---|                         |---DTYPE---|

This example (hopefully) shows that the type-identifier with the trailing _t actually represents the type of an array using the dtype without the trailing t. You can't interchange them in Cython code!

Notes

There are several more numeric types in NumPy I'll include a list containing the NumPy dtype and Cython type-identifier and the C type identifier that could also be used in Cython here. But it's basically taken from the NumPy documentation and the Cython NumPy pxd file:

NumPy dtype          Numpy Cython type         C Cython type identifier

np.bool_             None                      None
np.int_              cnp.int_t                 long
np.intc              None                      int       
np.intp              cnp.intp_t                ssize_t
np.int8              cnp.int8_t                signed char
np.int16             cnp.int16_t               signed short
np.int32             cnp.int32_t               signed int
np.int64             cnp.int64_t               signed long long
np.uint8             cnp.uint8_t               unsigned char
np.uint16            cnp.uint16_t              unsigned short
np.uint32            cnp.uint32_t              unsigned int
np.uint64            cnp.uint64_t              unsigned long
np.float_            cnp.float64_t             double
np.float32           cnp.float32_t             float
np.float64           cnp.float64_t             double
np.complex_          cnp.complex128_t          double complex
np.complex64         cnp.complex64_t           float complex
np.complex128        cnp.complex128_t          double complex

Actually there are Cython types for np.bool_: cnp.npy_bool and bint but both they can't be used for NumPy arrays currently. For scalars cnp.npy_bool will just be an unsigned integer while bint will be a boolean. Not sure what's going on there...


1 Taken From the NumPy documentation "Data type objects"

Built-in Python types

Several python types are equivalent to a corresponding array scalar when used to generate a dtype object:

int           np.int_
bool          np.bool_
float         np.float_
complex       np.cfloat
bytes         np.bytes_
str           np.bytes_ (Python2) or np.unicode_ (Python3)
unicode       np.unicode_
buffer        np.void
(all others)  np.object_
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  • 3
    Thanks a lot for this very thorough overview!
    – Axel
    Commented Aug 21, 2018 at 7:39
  • What about np.integer? Commented Jun 8, 2022 at 16:13
  • @HebertoMayorquin it's an abstract base class that exists to check (using isinstance or issubclass) if you have any integer dtype (comparably to collections.abc.Hashable and similar). Since it's not a "real" dtype and it's (as far as I know) not specially implemented in Cython it's not really relevant for this question. But feel free to ask a new question if you want to know something specific.
    – MSeifert
    Commented Jun 8, 2022 at 16:37
  • @MSeifert thanks, that was it. I guess that the fact that the dtypes have similar names to the abstract classes for the objects confused me. This came from here: stackoverflow.com/questions/72549583/… Commented Jun 8, 2022 at 16:59
  • The matched C type is platform dependent so that chart is very misleading.
    – Zak
    Commented Dec 13, 2022 at 3:08
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np.int_ is the default integer type (as defined in the NumPy docs), on a 64bit system this would be a C long. np.intc is the default C int either int32 or int64. np.int is an alias to the built-in int function

>>> np.int(2.4)
2
>>> np.int is int  # object id equality
True

The cython datatypes should reflect C datatypes, so cdef int a is a C int and so on.

As for np.int_t that is the Cython compile time equivalent of the NumPy np.int_ datatype, np.int64_t is the Cython compile time equivalent of np.int64

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    np.intc is practically always 32 bits. I've never seen a C environment where int is 64 bits.
    – Fred Foo
    Commented Feb 18, 2014 at 12:39
  • Can I always use np.int_t instead of np.int_ under cython cdef, or vice vesa?
    – colinfang
    Commented Feb 18, 2014 at 13:21
  • You can't use when instantiating numpy arrays np.zeros(5, 5, dtype=np.int_t) will throw an error where as np.zeros(5, 5, dtype=np.int_) won't. You can use it to declare the type of the array though np.ndarray[np.int_t] a = ... and since it's a compile time thing you'll get early warnings anyway.
    – Matti Lyra
    Commented Feb 18, 2014 at 13:49
  • Then, can I always use np.int_ instead of np.int_t? Do I suffer any speed loss?
    – colinfang
    Commented Feb 18, 2014 at 23:44
  • correct me if im wrong, but speed loss should be negligible. The only difference would be that np.int_ may (or may not) take more than 4 bytes, while np.int_t is guaranteed 4 bytes.
    – richizy
    Commented Feb 20, 2014 at 7:33
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This is a clarification on difference between int and np.int_t in Cython code, which are not the same:

np.int_t maps to long and not to int in Cython code.

That means:

  • On 64bit Windows (i.e. compiled with MSVC), int is 4 bytes but also long (and thus np.int_t).
  • On 64bit Linux (i.e. compiled with gcc), int is 4 bytes but long (and thus np.int_t) is 8 bytes!

An np.int-numpy-array would map to np.int_t[:]-memory view in Cython, which is correct because the following code:

import numpy as np

a = np.zeros(1, np.int_)  # or np.zeros(1, np.int)
print(a.itemsize)

would yield 4 (size of long in bytes on Windows) on Windows and 8 on Linux.

Often it makes sense to specify exactly how big the values are, e.g. by using np.int32 and np.int64 which would map to np.int32_t and np.int64_t in Cython and have the same size on all platforms.

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