Python CTypes Tutorial

Python ctypes is a python built-in library that invokes exported functions from native compiled libraries. Learn More about it here.

Note: Since this library handles compiled code, it is relatively OS dependent.

ctypes arrays

As any good C programmer knows, a single value won’t get you that far. What will really get us going are arrays!

c_int * 16

This is not an actual array, but it’s pretty darn close! We created a class that denotes an array of 16 ints.

Now all we need to do is to initialize it:

arr = (c_int * 16)(*range(16))
<main.c_long_Array_16 object at 0xbaddcafe>

Now arr is an actual array that contains the numbers from 0 to 15.

They can be accessed just like any list:

arr[5] = 20

And just like any other ctypes object, it also has a size and a location:

64 # sizeof(c_int) * 16
hex(addressof(arr)) ‘0xc000l0ff’

Wrapping functions for ctypes

In some cases, a C function accepts a function pointer. As avid ctypes users, we would like to use those functions, and even pass python function as arguments.

Let’s define a function:

def max(x, y):
return x if x >= y else y

Now, that function takes two arguments and returns a result of the same type. For the sake of the example, let’s assume that type is an int.

Like we did on the array example, we can define an object that denotes that prototype:

CFUNCTYPE(c_int, c_int, c_int)

That prototype denotes a function that returns an c_int (the first argument), and accepts two c_int arguments (the other arguments).

Now let’s wrap the function:

CFUNCTYPE(c_int, c_int, c_int)(max)

Function prototypes have on more usage: They can wrap ctypes function (like libc.ntohl) and verify that the correct arguments are used when invoking the function.

libc.ntohl() # garbage in - garbage out
CFUNCTYPE(c_int, c_int)(libc.ntohl)() Traceback (most recent call last):
File "", line 1, in
TypeError: this function takes at least 1 argument (0 given)

Section 189.3: Basic usage

Let’s say we want to use libc’s ntohl function.

First, we must load

from ctypes import *
libc = cdll.LoadLibrary('')

Then, we get the function object:

ntohl = libc.ntohl
<_FuncPtr object at 0xbaadf00d>

And now, we can simply invoke the function:

ntohl(0x6C) 1811939328
hex(_) '0x6c000000'

Which does exactly what we expect it to do.

Common pitfalls

Failing to load a file

The first possible error is failing to load the library. In that case an OSError is usually raised.

This is either because the file doesn’t exists (or can’t be found by the OS):

cdll.LoadLibrary(“”) Traceback (most recent call last): File “”, line 1, in – Python® Notes for Professionals 719

File "/usr/lib/python3.5/ctypes/", line 425, in LoadLibrary return self._dlltype(name)
File "/usr/lib/python3.5/ctypes/", line 347, in init self._handle = _dlopen(self._name, mode)
OSError: cannot open shared object file: No such file or directory

As you can see, the error is clear and pretty indicative.

The second reason is that the file is found, but is not of the correct format.

cdll.LoadLibrary("") Traceback (most recent call last): File "", line 1, in
File "/usr/lib/python3.5/ctypes/", line 425, in LoadLibrary return self._dlltype(name)
File "/usr/lib/python3.5/ctypes/", line 347, in init self._handle = _dlopen(self._name, mode)
OSError: /usr/lib/i386-linux-gnu/ invalid ELF header

In this case, the file is a script file and not a .so file. This might also happen when trying to open a .dll file on a Linux machine or a 64bit file on a 32bit python interpreter. As you can see, in this case the error is a bit more vague, and requires some digging around.

Failing to access a function

Assuming we successfully loaded the .so file, we then need to access our function like we’ve done on the first example.

When a non-existing function is used, an AttributeError is raised:
Traceback (most recent call last):
File "", line 1, in
File "/usr/lib/python3.5/ctypes/", line 360, in getattr func = self.getitem(name)
File "/usr/lib/python3.5/ctypes/", line 365, in getitem func = self._FuncPtr((name_or_ordinal, self))
AttributeError: /lib/i386-linux-gnu/ undefined symbol: foo

Python ctypes: Basic ctypes object

The most basic object is an int:

obj = ctypes.c_int(12)

Now, obj refers to a chunk of memory containing the value 12.

That value can be accessed directly, and even modified:

obj.value = 13

Since obj refers to a chunk of memory, we can also find out its size and location:

hex(addressof(obj)) '0xdeadbeef'

Python ctypes: Complex usage

Let’s combine all of the examples above into one complex scenario: using libc’s lfind function.

For more details about the function, read the man page. I urge you to read it before going on.

First, we’ll define the proper prototypes:

compar_proto = CFUNCTYPE(c_int, POINTER(c_int), POINTER(c_int))
lfind_proto = CFUNCTYPE(c_void_p, c_void_p, c_void_p, POINTER(c_uint), c_uint, compar_proto)

Then, let’s create the variables:

key = c_int(12)
arr = (c_int * 16)(*range(16))
nmemb = c_uint(16)

And now we define the comparison function:

def compar(x, y):
return x.contents.value - y.contents.value

Notice that x, and y are POINTER(c_int), so we need to dereference them and take their values in order to actually compare the value stored in the memory.

Now we can combine everything together:

lfind = lfind_proto(libc.lfind)
ptr = lfind(byref(key), byref(arr), byref(nmemb), sizeof(c_int), compar_proto(compar))

ptr is the returned void pointer. If key wasn’t found in arr, the value would be None, but in this case we got a valid value.

Now we can convert it and access the value:

cast(ptr, POINTER(c_int)).contents c_long(12)

Also, we can see that ptr points to the correct value inside arr:

addressof(arr) + 12 * sizeof(c_int) == ptr

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