# Is there a faster way to convert an arbitrary large integer to a big endian sequence of bytes?

I have this Python code to do this:

``````from struct import pack as _pack

if lnum < 0:
raise RangeError("Cannot use packl to convert a negative integer "
"to a string.")
count = 0
l = []
while lnum > 0:
l.append(lnum & 0xffffffffffffffffL)
count += 1
lnum >>= 64
if count <= 0:
lens = 8 * count % pad
l.append('>' + 'x' * pad + 'Q' * count)
l.reverse()
return _pack(*l)
else:
l.append('>' + 'Q' * count)
l.reverse()
s = _pack(*l).lstrip('\0')
lens = len(s)
if (lens % pad) != 0:
else:
return s
``````

This takes approximately 174 usec to convert `2**9700 - 1` to a string of bytes on my machine. If I'm willing to use the Python 2.7 and Python 3.x specific `bit_length` method, I can shorten that to 159 usecs by pre-allocating the `l` array to be the exact right size at the very beginning and using `l[something] =` syntax instead of `l.append`.

Is there anything I can do that will make this faster? This will be used to convert large prime numbers used in cryptography as well as some (but not many) smaller numbers.

Edit

This is currently the fastest option in Python < 3.2, it takes about half the time either direction as the accepted answer:

``````def packl(lnum, padmultiple=1):
"""Packs the lnum (which must be convertable to a long) into a
byte string 0 padded to a multiple of padmultiple bytes in size. 0
means no padding whatsoever, so that packing 0 result in an empty
string.  The resulting byte string is the big-endian two's
complement representation of the passed in long."""

if lnum == 0:
elif lnum < 0:
raise ValueError("Can only convert non-negative numbers.")
s = hex(lnum)[2:]
s = s.rstrip('L')
if len(s) & 1:
s = '0' + s
s = binascii.unhexlify(s)
if filled_so_far != 0:
s = b'\0' * (padmultiple - filled_so_far) + s
return s

def unpackl(bytestr):
"""Treats a byte string as a sequence of base 256 digits
representing an unsigned integer in big-endian format and converts
that representation into a Python integer."""

return int(binascii.hexlify(bytestr), 16) if len(bytestr) > 0 else 0
``````

In Python 3.2 the `int` class has `to_bytes` and `from_bytes` functions that can accomplish this much more quickly that the method given above.

-
What does `pad` do? A docstring would be handy to understand the usage. –  Scott Griffiths Dec 5 '10 at 10:33
@Scott As far as I can tell, the output is zero-padded at the front to the next multiple-of-pad number of bytes. –  Karl Knechtel Dec 5 '10 at 10:42
Reagrdelss of eing a localy used variable, you shoul avoid using a variable name sucha s "l" - it looks too much like "1" on most fonts to keep readability. –  jsbueno Dec 5 '10 at 13:12
@Karl Knechtel - That's precisely right. I wanted to use this in situations where I wanted to dump it into a slot that was exactly 64 bits long, or 128 bits long or something like that. –  Omnifarious Dec 5 '10 at 16:56
@Scott Griffiths - You're right, it does need a docstring. embarrassed look –  Omnifarious Dec 5 '10 at 16:57

For completeness and for future readers of this question:

Starting in Python 3.2, there are functions `int.from_bytes()` and `int.to_bytes()` that perform the conversion between `bytes` and `int` objects in chosable byte order.

-
Thanks! I'm wondering though if the endian flags will slow it down or not. We'll see. –  Omnifarious Jun 22 '11 at 0:15
Even with the endian flag, it still takes 1/3rd the time (or less) of the fastest method I'd found so far. –  Omnifarious Jun 22 '11 at 5:37

Here is a solution calling the Python/C API via `ctypes`. Currently, it uses NumPy, but if NumPy is not an option, it could be done purely with `ctypes`.

``````import numpy
import ctypes
PyLong_AsByteArray = ctypes.pythonapi._PyLong_AsByteArray
PyLong_AsByteArray.argtypes = [ctypes.py_object,
numpy.ctypeslib.ndpointer(numpy.uint8),
ctypes.c_size_t,
ctypes.c_int,
ctypes.c_int]

def packl_ctypes_numpy(lnum):
a = numpy.zeros(lnum.bit_length()//8 + 1, dtype=numpy.uint8)
PyLong_AsByteArray(lnum, a, a.size, 0, 1)
return a
``````

On my machine, this is 15 times faster than your approach.

Edit: Here is the same code using `ctypes` only and returning a string instead of a NumPy array:

``````import ctypes
PyLong_AsByteArray = ctypes.pythonapi._PyLong_AsByteArray
PyLong_AsByteArray.argtypes = [ctypes.py_object,
ctypes.c_char_p,
ctypes.c_size_t,
ctypes.c_int,
ctypes.c_int]

def packl_ctypes(lnum):
a = ctypes.create_string_buffer(lnum.bit_length()//8 + 1)
PyLong_AsByteArray(lnum, a, len(a), 0, 1)
return a.raw
``````

This is another two times faster, totalling to a speed-up factor of 30 on my machine.

-
Won't that use the system native endianness though? –  Karl Knechtel Dec 5 '10 at 11:47
@Karl: No, it won't. The fourth parameter to `PyLong_AsByteArray()` indicates which endianness to use: `0` means big endian, anything else means little endian. –  Sven Marnach Dec 5 '10 at 11:52
Awesome. Now I wish this were exposed directly... :/ –  Karl Knechtel Dec 5 '10 at 12:13
Has this API changed much over different versions of Python? –  Omnifarious Dec 5 '10 at 16:58
And, of course, you cheated just a little. :-) You do not support padding. But that's a very small detail. –  Omnifarious Dec 5 '10 at 17:25

I suppose you really should just be using numpy, which I'm sure has something or other built in for this. It might also be faster to hack around with the `array` module. But I'll take a stab at it anyway.

IMX, creating a generator and using a list comprehension and/or built-in summation is faster than a loop that appends to a list, because the appending can be done internally. Oh, and 'lstrip' on a large string has got to be costly.

Also, some style points: special cases aren't special enough; and you appear not to have gotten the memo about the new `x if y else z` construct. :) Although we don't need it anyway. ;)

``````from struct import pack as _pack

Q_size = 64
Q_bitmask = (1L << Q_size) - 1L

while a_long:
a_long >>= Q_size

if lnum < 0:
raise RangeError("Cannot use packl to convert a negative integer "
"to a string.")
# Pack the first one separately so we can lstrip nicely.
first = _pack('>Q', qs[0]).lstrip('\x00')
rest = _pack('>%sQ' % len(qs) - 1, *qs[1:])
count = len(first) + len(rest)
# A little math trick that depends on Python's behaviour of modulus
# for negative numbers - but it's well-defined and documented
return '\x00' * (-count % pad) + first + rest
``````
-
Have you tested this against the original code? –  Omnifarious Dec 5 '10 at 17:37
I shouldn't have voted you up. Your code has numerous errors. –  Omnifarious Dec 5 '10 at 17:45

Just wanted to post a follow-up to Sven's answer (which works great). The opposite operation - going from arbitrarily long bytes object to Python Integer object requires the following (because there is no PyLong_FromByteArray() C API function that I can find):

``````import binascii

def unpack_bytes(stringbytes):
#binascii.hexlify will be obsolete in python3 soon
#They will add a .tohex() method to bytes class
#Issue 3532 bugs.python.org
return int(binascii.hexlify(stringbytes), 16)
``````
-
There is in fact a `_PyLong_FromByteArray` function (at least in Python 2.7 and Python 3). I'm using it. But your method would probably be pretty fast too. –  Omnifarious Feb 12 '11 at 4:54
This is, in fact, faster than calling _PyLong_FromByteArray using ctypes. How bizarre. Even better, I don't have to check if the input is a `memoryview` because hexlify handles those, and I don't have to convert to an `int` in Python 2.7 in order to make the value into a straight `int` if it's small enough to not need to be a `long`. –  Omnifarious Feb 12 '11 at 15:03
Also, using `hex(lnum)' and `binascii.unhexlify` (with a little extra glue) is also faster than the ctypes option. –  Omnifarious Feb 12 '11 at 15:37
Weird. I looked through the Python 3.1.x C API reference and couldn't find PyLong_FromByteArray(). –  bk0 Feb 14 '11 at 20:02