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

`int`

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
```

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_)
```

As Cython type identifier it has another meaning, here it stands for the c 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.

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 `cimport`

ed 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_
```