# Emulate uint32_t in Python?

I was trying to port a function from C to Python and to make it easy to debug, I'd prefer it performed the same CPU word-size limited operations so I could compare the intermediate results. In other words, I'd like something like:

``````a = UnsignedBoundedInt(32, 399999)
b = UnsignedBoundedInt(32, 399999)
print(a*b) # prints 1085410049 (159999200001 % 2**32)
``````

What's the best way to achieve this so that all operations (including bitwise shifts) would work as in C?

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You can try using `ctypes.uint_32` to bound the results for you:

``````>>> import ctypes
>>> print ctypes.c_uint32(399999 * 399999).value
1085410049
``````

Alternatively you can use numpy's data types:

``````>>> import numpy as np
>>> a = np.uint32(399999)
>>> b = np.uint32(399999)
>>> a * b
__main__:1: RuntimeWarning: overflow encountered in uint_scalars
1085410049
``````
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v1 -= ((v0 << 4 ^ v0 >> 5) + v0) ^ (sum + k[sum>>11 & 3]) TypeError: unsupported operand type(s) for <<: 'c_uint' and 'int' –  d33tah Oct 7 at 19:47
And: >>> type(numpy.uint32(3) << 4) <type 'numpy.int64'> –  d33tah Oct 7 at 19:54
TypeError: unsupported operand type(s) for <<: 'c_uint' and 'c_uint' –  d33tah Oct 7 at 19:57
So, looks like it's not exactly the best solution. –  d33tah Oct 7 at 19:57
@d33tah You forgot about the `.value` in the `ctypes` case. Besides, you should put this "clipping operation" one level towards the outside. That is, if you have `clip_u32 = lambda val: ctypes.c_uint32(val).value`, you could do `v1 -= clip_u32((v0 << 4 ^ v0 >> 5) + v0) ^ clip_u32(sum + k[sum>>11 & 3])`. –  glglgl Oct 7 at 20:36
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Here's an interesting solution, though it only works under Python 2:

``````class U32:
"""Emulates 32-bit unsigned int known from C programming language."""

def __init__(self, num=0, base=None):
"""Creates the U32 object.

Args:
num: the integer/string to use as the initial state
base: the base of the integer use if the num given was a string
"""
if base is None:
self.int_ = int(num) % 2**32
else:
self.int_ = int(num, base) % 2**32

def __coerce__(self, ignored):
return None

def __str__(self):
return "<U32 instance at 0x%x, int=%d>" % (id(self), self.int_)

def __getattr__(self, attribute_name):
print("getattr called, attribute_name=%s" % attribute_name)
# you might want to take a look here:
# http://stackoverflow.com/q/19611001/1091116
r = getattr(self.int_, attribute_name)
if callable(r):  # return a wrapper if integer's function was requested
def f(*args, **kwargs):
if args and isinstance(args[0], U32):
args = (args[0].int_, ) + args[1:]
ret = r(*args, **kwargs)
if ret is NotImplemented:
return ret
if attribute_name in ['__str__', '__repr__', '__index__']:
return ret
ret %= 2**32
return U32(ret)
return f
return r

print(U32(4) / 2)
print(4 / U32(2))
print(U32(4) / U32(2))
``````

For Python 3 compatibility, have a look here.

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