# XOR swap algorithm in python?

I tried to implement XOR swap in python.

``````x,y= 10,20

x,y,x = x^y,x^y,x^y

print('%s , %s'%(x,y))
``````

OUTPUT:

``````30 , 30
``````

I am not new to python but I am unable to explain this output. It should have been `20,10`.

What is going on under the hood?

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Python doesn't modify int's in place when you do this, so even doing it in 3 steps doesn't avoid using extra temporary storage as you may expect. –  gnibbler Mar 16 '10 at 5:56
Do you mean xor-sort is not possible in python without using any extra storage? –  Pratik Deoghare Mar 16 '10 at 6:36
@Matthew Flaschen Thanks! –  Pratik Deoghare Mar 16 '10 at 7:42
Shouldn't it be XOR swap instead of sort? –  MAK Mar 16 '10 at 10:20

First, a tuple is created consisting of `x^y`, `x^y` and `x^y`. Then the tuple is unpacked into `x`, `y`, and `x`, causing both to be bound to the result of `x^y`.

Save yourself the headache and do it the Pythonic way:

``````x, y = y, x
``````
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what is happening under the hood for `x, y = y, x`? –  Anirban Nag Nov 8 '13 at 18:55
@tintinmj: This. –  Ignacio Vazquez-Abrams Nov 8 '13 at 19:58

While it's definitely best, as other answers say, to just `x, y = y, x`, if you're allergic to creating and unpacking tuples you can do it with successive x-oring... it just has to be successive, not simultaneous as you're doing!

``````>>> x = 1234
>>> y = 3421
>>> x ^= y
>>> y ^= x
>>> x ^= y
>>> print x
3421
>>> print y
1234
``````

The key to the xor-swap trick is three successive xors, i.e. one after the other -- the three separate `^=` statements, in this snippet. Of course, it makes no practical sense, but, if you're really keen on it, it does work, in Python like anywhere else;-).

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@Matthew: XOR swap doesn't know what an object is. Alex's code simulates what happens in registers. Use `reg = [10, 20]` and operate on `reg[0]` and `reg[1]` if that makes you feel better :-) –  John Machin Mar 16 '10 at 5:57
@Matthew, in Python every integer operation may "create a new object" -- or may not do so: it's entirely up to the implementation because it's strictly a performance issue (no effect whatsoever on semantics!), the application code cannot control it. For example, small ints may be cached (so no new object is actually created for ints < some threshold, entirely up to the Python implementation), memory of an existing object may be reused if the implementation can prove the last reference to it is being dropped, etc. Your assurance of creation is misplaced (more...) –  Alex Martelli Mar 16 '10 at 14:50
@Matthew, to respond to your sea-lawyering in detail: "without using extra space for a temporary variable" -- there's no extra VARIABLE used here (there may be extra OBJECTS -- which are not variable but immutable -- but definitely no variables, so we're OK!-). And: if an object is a "region of data storage in the execution environment", then a Python object isn't an object any more as soon as the last ref to it drops, because this means it isn't in the execution environment -- it's dead bits available to the underlying implementation below the environment to use (or not) as it pleases. –  Alex Martelli Mar 16 '10 at 14:55
@Matthew, usability of identifiers has nothing to do with the compiler's ability to make objects accessible: e.g. an implementation can decide that `__x` is visible in any scope and returns a pointer allowing access to said objects ("reserved to the implementation for any use" per 17.4.3.2.1 in C++ std (2003), 7.1.3 per C std (1999), so that use is fine) so those objects are perfectly allowed to "in the execution environment", contra your assertions. Similarly, a CPU (seen as an implementation of its machine language) can allocate xtra objects "in the execution environment", quite lawfully. –  Alex Martelli Mar 17 '10 at 1:22
And the point of all this is that your "proof" that Python can't do XOR swaps (because a given implementation might allocate extra objects if the values are 1234 and 3421 -- although it wouldn't if the values are 10 and 20, as per the OP's question, e.g. in CPython since many releases) is totally bogus: the "might allocate extra objects" (in execution environment) depends on the implementation (of Python, of C, of any machine language) and thus obviously cannot be used to "deduce" anything at all, contra your silly claims. –  Alex Martelli Mar 17 '10 at 1:26

You need to transcribe the "algorithm" line for line.

``````>>> x, y = 10, 20
>>> x = x ^ y; print x, y
30 20
>>> y = x ^ y; print x, y
30 10
>>> x = x ^ y; print x, y
20 10
>>>
``````

You need to read the remainder of the Wikipedia article, which explains that correct implementation blocks parallel operations, and that the whole idea is pretty much useless (on modern computer architectures, at least).

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+1 for the `whole idea is pretty much useless`. unless for learning purpose, this kind of trick gives a headache to anyone reading the code. –  Adrien Plisson Mar 16 '10 at 7:58

The XOR swap algorithm only makes sense when you have two pointers to mutable objects. a and b are two references to immutable ints.

EDIT (moving from comments as requested, and expanding):

Python integers are immutable. So every time you "modify" one using XOR, new storage will be allocated (or reused, e.g. for interning). This is fundamentally different from (e.g. C), where swap changes the value without allocating new memory. Put another way, XOR swap does not create new objects in either the C99 sense ("region of data storage in the execution environment, the contents of which can represent values") or the Python sense. As noted here, a true XOR swap can "exchange the values of the variables a and b without using extra space for a temporary variable."

Or empirically:

``````>>> x = 3
>>> y = 5
>>> print "x: ", x, ", id(x): ", id(x), "y: ", y, ", id(y): ", id(y)
x:  3 , id(x):  137452872 y:  5 , id(y):  137452848
>>> x ^= y
>>> print "x: ", x, ", id(x): ", id(x), "y: ", y, ", id(y): ", id(y)
x:  6 , id(x):  137452836 y:  5 , id(y):  137452848
>>> y ^= x
>>> print "x: ", x, ", id(x): ", id(x), "y: ", y, ", id(y): ", id(y)
x:  6 , id(x):  137452836 y:  3 , id(y):  137452872
>>> x ^= y
>>> print "x: ", x, ", id(x): ", id(x), "y: ", y, ", id(y): ", id(y)
x:  5 , id(x):  137452848 y:  3 , id(y):  137452872
``````

In this case, we see that the interpreter (2.6.4) seems to be interning the integers, so x ends up with the memory address y originally had. But the main point is that the swap requires at least one allocation (137452836), and x and y don't retain the same memory address throughout.

In C:

``````int x = 3;
int y = 5;
printf("x: %d, &x: %p, y: %d, &y: %p\n", x, &x, y, &y);
x ^= y;
printf("x: %d, &x: %p, y: %d, &y: %p\n", x, &x, y, &y);
y ^= x;
printf("x: %d, &x: %p, y: %d, &y: %p\n", x, &x, y, &y);
x ^= y;
printf("x: %d, &x: %p, y: %d, &y: %p\n", x, &x, y, &y);
``````

gives:

``````x: 3, &x: 0xbfd433ec, y: 5, &y: 0xbfd433e8
x: 6, &x: 0xbfd433ec, y: 5, &y: 0xbfd433e8
x: 6, &x: 0xbfd433ec, y: 3, &y: 0xbfd433e8
x: 5, &x: 0xbfd433ec, y: 3, &y: 0xbfd433e8
``````

This is a real XOR swap, so x and y always maintain the same memory locations and there is no temporary.

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@Matthew, as my answer shows, it makes just as much sense (i.e. not much) with references to immutable ints as it would with pointers to mutable objects. It's temporal succession vs simultaneous evaluation that's really the crux of the matter! –  Alex Martelli Mar 16 '10 at 5:48
I think we're confusing the purpose of this implementation of the swap procedure with the XOR algorithm itself. You might choose the XOR implementation when you don't want to use extra storage, but doing it for that reason that absolutely requires mutable data. So if using XOR creates new values, even if it can be shown to work correctly - as in your answer, Alex - there's little point because you could just use the new value for a temporary instead. –  Kylotan Mar 16 '10 at 10:55
The math works, but the underlying goal of a space-efficient swap is not satisfied. –  Mike Graham Mar 16 '10 at 15:58

You can do this swap easily using the following:

```x, y = 10, 20
x, y = y, x
print((x,y))
```

As for the behavior you're seeing, I'm pretty sure that's because the entire RHS is evaluated and then assigned to the LHS at the same time, and `x^y` is always 30 in that case.

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