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Python is more strongly typed than other scripting languages. For example, in Perl:

perl -E '$c=5; $d="6"; say $c+$d'   #prints 11

But in Python:

>>> c="6"
>>> d=5
>>> print c+d
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: cannot concatenate 'str' and 'int' objects

Perl will inspect a string and convert to a number, and the + - / * ** operators work as you expect with a number. PHP is similar.

Python uses + to concatenate strings so the the attempted operation of c+d fails because c is a string, d an int. Python has stronger sense of numeric types than does Perl. OK -- I can deal with that.

But consider:

>>> from sys import maxint
>>> type(maxint)
<type 'int'>
>>> print maxint
9223372036854775807
>>> type(maxint+2)
<type 'long'>
>>> print maxint+2
9223372036854775809
>>> type((maxint+2)+maxint)
<type 'long'>
>>> print ((maxint+2)+maxint)
18446744073709551616

Now Python will autopromote from an int, which in this case is a 64 bit long (OS X, python 2.6.1) to a python long int which is of arbitrary precision. Even though the types are not the same, they are similar and Python allows the usual numeric operators to be used. Usually this is helpful. It is helpful with smoothing the differences between 32 bit and 64 bit for example.

The conversion from int to long is one way:

>>> type((maxint+2)-2)
<type 'long'>

Once the conversion is made, all operations on that variable are now done in arbitrary precision. The arbitrary precision operations are orders of magnitude slower than the native int operations. On a script I am working on, I would have some execution be snappy and other that extended into hours because of this. Consider:

>>> print maxint**maxint        # execution so long it is essentially a crash

So my question: Is there a way to defeat or not allow the auto-promotion of a Python int to a Python long?

Edit, follow-up:

I received several comments in the form of 'why on earth would you want to have C style overflow behavior?' The issue was that this particular piece of code worked OK on 32 bits in C and Perl (with use int) with C's overflow behavior. There was a failed attempt to port this code to Python. Python's different overflow behavior turn out to be (part) of the problem. The code has many of those different idioms (C, Perl, some python) mixed in (and those comments mixed in), so it was challenging.

Essentially, the image analysis being done is a disc based high-pass filter to perform similar image comparison. Part of the high-pass filter has an integer-based multiplication of two large polynomials. The overflow was essentially a "don't - care, it's big..." kind of logic so the result was as intended with a C-based overflow. So the use of Horner's rule with O(n2) time was a waste since the larger polynomials would just be "big" -- a rough-justice form of carot-top's saturation arithmetic.

Changing the loop-based polynomial multiplication to a form of FFT is probably significantly faster. FFT runs in close to linear time vs O(n2) for Horner's rule polynomial multiply. Going from disc based to in-memory will also speed this up. The images are not terribly big, but the original code was written at a time when they were considered "huge!!!" The code owner is not quite ready to trash his beloved code, so we'll see. The 'right answer' for him probably is just keep Perl or C if he wants that code.

Thanks for the answers. I did not know about Python's decimal module, and that seemed to be closest to what I was asking -- even though there are other issues to be solved in this case!

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1  
maxint**maxint is a number with >>750 decimals, i hope you're not really suprised it takes a while. Also what is supposed to happen when a number does not fit into 32 bit? –  Jochen Ritzel Dec 6 '10 at 1:29
1  
You're saying basic mathematically operations is making your application run hours longer it otherwise would? That sounds like your error, not python's –  Falmarri Dec 6 '10 at 1:38
1  
Also, what should happen instead of autopromotion? Segfault? Sounds like you should keep your numbers below sys.maxint... –  Falmarri Dec 6 '10 at 1:39
2  
Raising OverflowError is perfectly reasonable alternative behavior to converting to a long, though there's no mechanism in the language to do this (eg. there's probably no sane to do it for just your code and not libraries, which means it'd break things). –  Glenn Maynard Dec 6 '10 at 2:43
    
@Glenn Maynard: That is really the answer I was looking for. Is there a 'pythonic' way that me as a newby could not see or Google that change the default behavior of an int. Numpy is probably closest, but lots of code to change to get there. –  dawg Dec 6 '10 at 7:13

6 Answers 6

up vote 3 down vote accepted

So you want to throw out the One True Way and go retro on overflows. Silly you.

There is no good upside to the C / C++ / C# / Java style of overflow. It does not reliably raise an error condition. For C and C99 it is "undefined behavior" in ANSI and POSIX (C++ mandates modulo return) and it is a known security risk. Why do you want this?

The Python method of seamlessly overflowing to a long is the better way. I believe this is the same behavior being adapted by Perl 6.

You can use the Decimal module to get more finite overflows:

>>> from decimal import *
>>> from sys import maxint
>>> getcontext()
Context(prec=28, rounding=ROUND_HALF_EVEN, Emin=-999999999, Emax=999999999, capitals=1,
flags=[], traps=[DivisionByZero, Overflow, InvalidOperation])

>>> d=Decimal(maxint)
>>> d
Decimal('9223372036854775807')
>>> e=Decimal(maxint)
>>> f=d**e
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
  File "/System/Library/Frameworks/Python.framework/Versions/2.6/lib/python2.6/decimal.py", line 2225, in __pow__
    ans = ans._fix(context)
  File "/System/Library/Frameworks/Python.framework/Versions/2.6/lib/python2.6/decimal.py", line 1589, in _fix
    return context._raise_error(Overflow, 'above Emax', self._sign)
  File "/System/Library/Frameworks/Python.framework/Versions/2.6/lib/python2.6/decimal.py", line 3680, in _raise_error
    raise error(explanation)
decimal.Overflow: above Emax

You can set your precision and boundary conditions with Decimal classes and the overflow is nearly immediate. You can set what you trap for. You can set your max and min. Really -- How does it get better than this? (I don't know about relative speed to be honest, but I suspect it is faster than numby but slower than native ints obviously...)

For your specific issue of image processing, this sounds like a natural application to consider some form of saturation arithmetic. You also might consider, if you are having overflows on 32 arithmetic, check operands along the way on obvious cases: pow, **, *. You might consider overloaded operators and check for the conditions you don't want.

If Decimal, saturation, or overloaded operators don't work -- you can write an extension. Heaven help you if you want to throw out the Python way of overflow to go retro...

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If you want arithmetic overflows to overflow within e.g. 32 bits, you could use e.g. numpy.uint32.

That gives you a warning when an overflow occurs.

>>> import numpy
>>> numpy.uint32(2**32-3) + numpy.uint32(5)
Warning: overflow encountered in ulong_scalars
2

I tested its speed though:

>\python26\python.exe -m timeit "2**16 + 2**2"
1000000 loops, best of 3: 0.118 usec per loop

>\python26\python.exe -m timeit "2**67 + 2**65"
1000000 loops, best of 3: 0.234 usec per loop

>\python26\python.exe -m timeit -s "import numpy; numpy.seterr('ignore')" "numpy.uint32(2)**numpy.uint32(67) + numpy.uint32(2)**numpy.uint32(65)"
10000 loops, best of 3: 34.7 usec per loop

It's not looking good for speed.

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1  
it will be much slower than usual integer arithmetic, as numpy's overhead for per/item handling is quite significant –  David Cournapeau Dec 6 '10 at 10:27
2  
You called the constructor four times in each loop, which is going to be madly expensive. Instead, you should cache the uint32 objects themselves. –  nneonneo Oct 13 '12 at 15:41

Int vs long is an historical legacy - in python 3, every int is a "long". If your script speed is limited by int computation, it is likely that you are doing it wrong.

To give you a proper answer, we need more information on what are you trying to do.

share|improve this answer
    
It is hard to say "exactly" what I am doing because about 75% is code cut and paste. I am mostly a Perl guy and learning Python as I go. I do know enough python to see WHY it is randomly slowing down; these are 32 bit image signatures and 99.99% are with 2^32. 0.01% are unbelievable slow which I have traced to a 32 bit overflow from an image signature. My first inclination was (Surprise!!!) to rewrite the offending code in C or Perl, but I thought I would give this notion a try.... –  dawg Dec 6 '10 at 6:59
    
Can you give us the code which computes those signature ? –  David Cournapeau Dec 6 '10 at 7:16
    
It is 4000 lines and copyrighted to my client..... –  dawg Dec 6 '10 at 7:24
1  
@drewk: No thanks, I'd rather take my arbitrary precision. –  Falmarri Dec 6 '10 at 21:27
1  
@Falmarri: More is good... all is better. I don't think it is a matter of either / or. I just wanted a failure mode that happened immediately rather than a failure mode that never happens. Both modes are failures in the case of a large overflow. It would be nice to be able to set or choose the behavior desired. The Decimal module has it (but it is kinda slow...`) As a default, Pythons behavior for ints / longs is fine and logical. As the only possible way -- I prefer choices. –  dawg Dec 8 '10 at 19:51

You can force your values to return to normal ints if you include an num = int(num) occasionally in your algorithm. If the value is long but fits in a native int, it will demote down to int. If the value doesn't fit in a native int, it will remain a long.

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Well, if you don't care about accuracy you could all of your math ops modulo maxint.

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Evaluating (maxint**maxint) % maxint is still going to be just as slow. –  Glenn Maynard Dec 6 '10 at 2:44
1  
@Glenn Maynard: pow(maxint, maxint, maxint) is much faster. –  J.F. Sebastian Dec 6 '10 at 6:19

I don't know if it would be faster, neccesarily, but you could use numpy arrays of one element instead of ints.

If the specific calculation you are concerned about is integer exponentiation, then there are some inferences we can draw:

def smart_pow(mantissa, exponent, limit=int(math.ceil(math.log(sys.maxint)/math.log(2)))):
    if mantissa in (0, 1):
        return mantissa
    if exponent > limit:
        if mantissa == -1: 
            return -1 if exponent&1 else 1
        if mantissa > 1:
            return sys.maxint
        else: 
            return (-1-sys.maxint) if exponent&1 else sys.maxint
    else: # this *might* overflow, but at least it won't take long
        return mantissa ** exponent
share|improve this answer
1  
it will much much slower - numpy's speed is coming from handling a lot of items from the same type altogether. The overhead per item is quite significant, especially compared to one int. Also, numpy won't necessarily warn you if you overflow your integers. –  David Cournapeau Dec 6 '10 at 3:58
1  
I don't know of too many ways to reliably or portably getting overflow information after the fact even in C. If you want this, you probably need to write code that explicitly checks for calculations that will overflow such as if (MAX_INT - b) < a, or access overflow status flags in assembly language. –  SingleNegationElimination Dec 6 '10 at 5:00
    
Please see Integer Security for numerous ways to this in C. –  dawg Dec 6 '10 at 7:34
    
I must be missing something, I don't see any way in that paper that shows how to portably detect integer overflows after they have occured. There are many ways (similar to the examples I've provided) it shows how to detect that an overflow will occur, and it also shows some x86 assembly that provides access to the hardware condition registers that do detect the error. Thank you for providing support for my answer. –  SingleNegationElimination Dec 6 '10 at 8:27
    
@@TokenMacGuy: I think you thought I was disagreeing with you. I was agreeing with the posted link. Rereading my comment, I guess that was not too clear! ;-) –  dawg Dec 6 '10 at 15:32

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