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I was told that += can have different effects than the standard notation of i = i +. Is there a case in which i += 1 would be different from i = i + 1?

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+= acts like extend() in case of lists. – Ashwini Chaudhary Mar 13 '13 at 3:38
@AshwiniChaudhary That's a pretty subtle distinction, considering that i=[1,2,3];i=i+[4,5,6];i==[1,2,3,4,5,6] is True. Many developers may not notice that id(i) changes for one operation, but not the other. – kojiro Mar 13 '13 at 12:22
@kojiro -- While it's a subtle distinction, I think it is an important one. – mgilson Mar 13 '13 at 16:44
@mgilson it is important, and so I felt it needed an explanation. :) – kojiro Mar 13 '13 at 18:55
Related question regarding differences between the two in Java: stackoverflow.com/a/7456548/245966 – jakub.g Mar 19 '13 at 19:38
up vote 249 down vote accepted

This depends entirely on the object i.

+= calls the __iadd__ method (if it exists -- falling back on __add__ if it doesn't exist) whereas + calls the __add__ method1.

From an API perspective, __iadd__ is supposed to be used for modifying mutable objects in place (returning the object which was mutated) whereas __add__ should return a new instance of something. For immutable objects, both methods return a new instance, but __iadd__ will put the new instance in the current namespace with the same name that the old instance had. This is why

i = 1
i += 1

seems to increment i. In reality, you get a new integer and assign it "on top of" i -- losing one reference to the old integer. In this case, i += 1 is exactly the same as i = i + 1. But, with most mutable objects, it's a different story:

As a concrete example:

a = [1, 2, 3]
b = a
b += [1, 2, 3]
print a  #[1, 2, 3, 1, 2, 3]
print b  #[1, 2, 3, 1, 2, 3]

compared to:

a = [1, 2, 3]
b = a
b = b + [1, 2, 3]
print a #[1, 2, 3]
print b #[1, 2, 3, 1, 2, 3]

notice how in the first example, since b and a reference the same object, when I use += on b, it actually changes b (and a sees that change too -- After all, it's referencing the same list). In the second case however, when I do b = b + [1, 2, 3], this takes the list that b is referencing and concatenates it with a new list [1, 2, 3]. It then stores the concatenated list in the current namespace as b -- With no regard for what b was the line before.

1In the expression x + y, if x.__add__ isn't implemented or if x.__add__(y) returns NotImplemented and x and y have different types, then x + y tries to call y.__radd__(x). So, in the case where you have

foo_instance += bar_instance

if Foo doesn't implement __add__ or __iadd__ then the result here is the same as

foo_instance = bar_instance.__radd__(bar_instance,foo_instance)

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Well, += calls __iadd__ if it exists, and falls back to adding and rebinding otherwise. That's why i = 1; i += 1 works even though there's no int.__iadd__. But other than that minor nit, great explanations. – abarnert Mar 13 '13 at 3:31
@abarnert -- I always assumed that int.__iadd__ just called __add__. I'm glad to have learned something new today :). – mgilson Mar 13 '13 at 3:34
@abarnert -- I suppose maybe to be complete, x + y calls y.__radd__(x) if x.__add__ doesn't exist (or returns NotImplemented and x and y are of different types) – mgilson Mar 13 '13 at 13:59
If you really want to be completist, you'd have to mention that the "if it exists" bit goes through the usual getattr mechanisms, except for some quirks with classic classes, and for types implemented in the C API it instead looks for either nb_inplace_add or sq_inplace_concat, and those C API functions have stricter requirements than the Python dunder methods, and… But I don't think that's relevant to the answer. The main distinction is that += tries to do an in-place add before falling back to acting like +, which I think you've already explained. – abarnert Mar 13 '13 at 18:51
Yeah, I suppose you're right ... Although I could just fall back on the stance that the C API isn't part of python. It's part of Cpython :-P – mgilson Mar 13 '13 at 19:49

Under the covers, i += 1 does something like this:

    i = i.__iadd__(1)
except AttributeError:
    i = i.__add__(1)

While i = i + 1 does something like this:

i = i.__add__(1)

This is a slight oversimplification, but you get the idea: Python gives types a way to handle += specially, by creating an __iadd__ method as well as an __add__.

The intention is that mutable types, like list, will mutate themselves in __iadd__ (and then return self, unless you're doing something very tricky), while immutable types, like int, will just not implement it.

For example:

>>> l1 = []
>>> l2 = l1
>>> l1 += [3]
>>> l2

Because l2 is the same object as l1, and you mutated l1, you also mutated l2.


>>> l1 = []
>>> l2 = l1
>>> l1 = l1 + [3]
>>> l2

Here, you didn't mutate l1; instead, you created a new list, l1 + [3], and rebound the name l1 to point at it, leaving l2 pointing at the original list.

(In the += version, you were also rebinding l1, it's just that in that case you were rebinding it to the same list it was already bound to, so you can usually ignore that part.)

share|improve this answer
does __iadd__ actually call __add__ in the event of an AttributeError? – mgilson Mar 13 '13 at 3:31
Well, i.__iadd__ doesn't call __add__; it's i += 1 that calls __add__. – abarnert Mar 13 '13 at 3:32
The first attempt is actually i = i.__iadd__(1) - iadd can modify the object in place, but doesn't have to, and so is expected to return the result in either case. – lvc Mar 13 '13 at 3:33
s/l\([12]\)/L\\1/g – John La Rooy Mar 13 '13 at 3:39
Whoever downvoted a months-old answer, care to explain why? – abarnert May 16 '13 at 20:18

Here is an example that directly compares “i += x” with “i = i + x”:

def foo(x):
  x = x + [42]

def bar(x):
  x += [42]

c = [27]
foo(c); # c is not changed
bar(c); # c is changed to [27, 42]
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If you're just dealing with literals, then i += 1 has the same behavior as i = i + 1.

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Do you feel that the existing answers do not clarify that fact enough? This seems like an unneeded answer given the expansive answer given by mgilson. – Guvante Mar 13 '13 at 16:21
Yes, because none of the existing answers simply addressed the actual question, they went into all sorts of directions, while I interpreted the question to be a simpler one involving literals. – Jon Harbour Mar 13 '13 at 20:17
In Python, the term "literal" has two different meanings, probably neither of which is what you're thinking of. There's literal tokens (which don't include None, -1 or 'a' 'b'), or literal structures (which include list/tuple/dict displays). At the level of literal structures, i += [1] doesn't have the same behavior as i = i + [1], even though it's dealing with a list display literal. – abarnert Mar 14 '13 at 18:20
More importantly, the whole thing is a red herring. i obviously isn't a literal, and neither is the whole expression. And i += 1 doesn't have the same behavior as i = i + 1 if i is an instance of a class that defines __iadd__, even though 1 is a literal. In the same way, if i is, say, an int, i += a has the same behavior as i = i + a, even though a is not a literal. So, "literal" has nothing to do with any correct answer. – abarnert Mar 14 '13 at 18:22
@JonHarbour: Given that the OP accepted mgilson's answer, and that (so far) 91+26 people think the two "over-thought" answers are good, do you think it might be possible that you read the OP's intentions wrong? – abarnert Mar 14 '13 at 21:07

In simple words, you have two cases:

i = i + 1

This creates a new variable i using the value of previous i and increments it by one and stores it in some other memory location.

i += 1

This doesn't create a new variable but rather it increments the variable i at the same memory location. This is much more efficient than the previous one.

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