715

I notice that a pre-increment/decrement operator can be applied on a variable (like ++count). It compiles, but it does not actually change the value of the variable!

What is the behavior of the pre-increment/decrement operators (++/--) in Python?

Why does Python deviate from the behavior of these operators seen in C/C++?

  • 15
    Python is not C or C++. Different design decisions went into making the language. In particular, Python deliberately does not define assignment operators that can be used in an arbitrary expression; rather, there are assignment statements and augmented assignment statements. See reference below. – Ned Deily Sep 28 '09 at 8:22
  • 8
    What made you think python had ++ and -- operators? – u0b34a0f6ae Sep 28 '09 at 9:09
  • 19
    Kaizer: Coming from C/C++, I write ++count and it compiles in Python. So, I thought the language has the operators. – Ashwin Nanjappa Sep 28 '09 at 9:47
  • 3
    @Fox You're assuming a level of planning and organisation not in evidence – Basic May 15 '15 at 15:09
  • 2
    @mehaase ++ and -- don't exist in c "as syntactic sugar for pointer arithmetic", they exist because many processors have automatic increment and decrement memory access mechanisms (in general pointer indexing, stack indexing) as part of their native instruction set. For instance, in 6809 assembler: sta x++ ...the atomic instruction that results stores the a accumulator where x is pointing, then increments x by the size of the accumulator. This is done because it is faster than pointer arithmetic, because it is very common, and because it's easy to understand. Both pre- and -post. – fyngyrz Oct 28 '16 at 13:16
934

++ is not an operator. It is two + operators. The + operator is the identity operator, which does nothing. (Clarification: the + and - unary operators only work on numbers, but I presume that you wouldn't expect a hypothetical ++ operator to work on strings.)

++count

Parses as

+(+count)

Which translates to

count

You have to use the slightly longer += operator to do what you want to do:

count += 1

I suspect the ++ and -- operators were left out for consistency and simplicity. I don't know the exact argument Guido van Rossum gave for the decision, but I can imagine a few arguments:

  • Simpler parsing. Technically, parsing ++count is ambiguous, as it could be +, +, count (two unary + operators) just as easily as it could be ++, count (one unary ++ operator). It's not a significant syntactic ambiguity, but it does exist.
  • Simpler language. ++ is nothing more than a synonym for += 1. It was a shorthand invented because C compilers were stupid and didn't know how to optimize a += 1 into the inc instruction most computers have. In this day of optimizing compilers and bytecode interpreted languages, adding operators to a language to allow programmers to optimize their code is usually frowned upon, especially in a language like Python that is designed to be consistent and readable.
  • Confusing side-effects. One common newbie error in languages with ++ operators is mixing up the differences (both in precedence and in return value) between the pre- and post-increment/decrement operators, and Python likes to eliminate language "gotcha"-s. The precedence issues of pre-/post-increment in C are pretty hairy, and incredibly easy to mess up.
  • 13
    "The + operator is the "identity" operator, which does nothing." Only for numeric types; for other type it is an error by default. – newacct Sep 28 '09 at 7:47
  • 43
    Also, be aware that, in Python, += and friends are not operators that can be used in expressions. Rather, in Python they are defined as part of an "augmented assignment statement". This is consistent with the language design decision in Python to not allow assignment ("=") as an operator within arbitrary expressions, unlike what one can do in C. See docs.python.org/reference/… – Ned Deily Sep 28 '09 at 8:06
  • 15
    The unary + operator has a use. For decimal.Decimal objects, it rounds to current precision. – u0b34a0f6ae Sep 28 '09 at 9:10
  • 20
    I'm betting on parser simplification. Note an item in PEP 3099, "Things that will Not Change in Python 3000": "The parser won't be more complex than LL(1). Simple is better than complex. This idea extends to the parser. Restricting Python's grammar to an LL(1) parser is a blessing, not a curse. It puts us in handcuffs that prevent us from going overboard and ending up with funky grammar rules like some other dynamic languages that will go unnamed, such as Perl." I don't see how to disambiguate + + and ++ without breaking LL(1). – Mike DeSimone Oct 14 '10 at 19:42
  • 6
    It's not correct to say that ++ is nothing more than a synonym for += 1. There are pre-increment and post-increment variants of ++ so it is clearly not the same thing. I agree with the rest of your points, though. – PhilHibbs May 17 '17 at 8:59
376

When you want to increment or decrement, you typically want to do that on an integer. Like so:

b++

But in Python, integers are immutable. That is you can't change them. This is because the integer objects can be used under several names. Try this:

>>> b = 5
>>> a = 5
>>> id(a)
162334512
>>> id(b)
162334512
>>> a is b
True

a and b above are actually the same object. If you incremented a, you would also increment b. That's not what you want. So you have to reassign. Like this:

b = b + 1

Or simpler:

b += 1

Which will reassign b to b+1. That is not an increment operator, because it does not increment b, it reassigns it.

In short: Python behaves differently here, because it is not C, and is not a low level wrapper around machine code, but a high-level dynamic language, where increments don't make sense, and also are not as necessary as in C, where you use them every time you have a loop, for example.

  • 64
    That example is wrong (and you're probably confusing immutability with identity) - they have the same id due to some vm optimization that uses the same objects for numbers till 255 (or something like that). Eg (bigger numbers): >>> a = 1231231231231 >>> b = 1231231231231 >>> id(a), id(b) (32171144, 32171168) – ionelmc Jan 11 '10 at 1:00
  • 51
    The immutability claim is spurious. Conceptually, i++ would mean to assign i + 1 to the variable i. i = 5; i++ means to assign 6 to i, not modify the int object pointed to by i. That is, it does not mean to increment the value of 5! – Mechanical snail Sep 20 '11 at 4:19
  • 3
    @Mechanical snail: In which case it would not be increment operators at all. And then the += operator is clearer, more explicit, more flexible and does the same thing anyway. – Lennart Regebro Sep 20 '11 at 5:35
  • 6
    @LennartRegebro: In C++ and Java, i++ only operates on lvalues. If it were intended to increment the object pointed to by i, this restriction would be unnecessary. – Mechanical snail Sep 20 '11 at 7:18
  • 3
    @LennartRegebro - Yes; I see now that my confusion is just over the definition of "increment". I have it in my head that the definition of "increment" is tied to the equality semantics of the language, meaning any function f with no side effects can be called "increment" if f(x) == x + 1, always holds for all numeric values x. Other people clearly don't see it that way, which I will keep in mind in the future. +1 for a thought-provoking answer in any case. P.S. - Clojure's increment operator is even more explicit than ++: it is (inc value). – charleslparker Jan 31 '13 at 20:48
49

While the others answers are correct in so far as they show what a mere + usually does (namely, leave the number as it is, if it is one), they are incomplete in so far as they don't explain what happens.

To be exact, +x evaluates to x.__pos__() and ++x to x.__pos__().__pos__().

I could imagine a VERY weird class structure (Children, don't do this at home!) like this:

class ValueKeeper(object):
    def __init__(self, value): self.value = value
    def __str__(self): return str(self.value)

class A(ValueKeeper):
    def __pos__(self):
        print 'called A.__pos__'
        return B(self.value - 3)

class B(ValueKeeper):
    def __pos__(self):
        print 'called B.__pos__'
        return A(self.value + 19)

x = A(430)
print x, type(x)
print +x, type(+x)
print ++x, type(++x)
print +++x, type(+++x)
10

In Python, a distinction between expressions and statements is rigidly enforced, in contrast to languages such as Common Lisp, Scheme, or Ruby.

Wikipedia

So by introducing such operators, you would break the expression/statement split.

For the same reason you can't write

if x = 0:
  y = 1

as you can in some other languages where such distinction is not preserved.

10

Python does not have these operators, but if you really need them you can write a function having the same functionality.

def PreIncrement(name, local={}):
    #Equivalent to ++name
    if name in local:
        local[name]+=1
        return local[name]
    globals()[name]+=1
    return globals()[name]

def PostIncrement(name, local={}):
    #Equivalent to name++
    if name in local:
        local[name]+=1
        return local[name]-1
    globals()[name]+=1
    return globals()[name]-1

Usage:

x = 1
y = PreIncrement('x') #y and x are both 2
a = 1
b = PostIncrement('a') #b is 1 and a is 2

Inside a function you have to add locals() as a second argument if you want to change local variable, otherwise it will try to change global.

x = 1
def test():
    x = 10
    y = PreIncrement('x') #y will be 2, local x will be still 10 and global x will be changed to 2
    z = PreIncrement('x', locals()) #z will be 11, local x will be 11 and global x will be unaltered
test()

Also with these functions you can do:

x = 1
print(PreIncrement('x'))   #print(x+=1) is illegal!

But in my opinion following approach is much clearer:

x = 1
x+=1
print(x)

Decrement operators:

def PreDecrement(name, local={}):
    #Equivalent to --name
    if name in local:
        local[name]-=1
        return local[name]
    globals()[name]-=1
    return globals()[name]

def PostDecrement(name, local={}):
    #Equivalent to name--
    if name in local:
        local[name]-=1
        return local[name]+1
    globals()[name]-=1
    return globals()[name]+1

I used these functions in my module translating javascript to python.

  • Note: while great, these helper methods will not work if your locals exist on class function stack frame. i.e - calling them from within a class method def will not work - the 'locals()' dict is a snapshot, and does not update the stack frame. – Adam Jun 14 at 5:49
4

Yeah, I missed ++ and -- functionality as well. A few million lines of c code engrained that kind of thinking in my old head, and rather than fight it... Here's a class I cobbled up that implements:

pre- and post-increment, pre- and post-decrement, addition,
subtraction, multiplication, division, results assignable
as integer, printable, settable.

Here 'tis:

class counter(object):
    def __init__(self,v=0):
        self.set(v)

    def preinc(self):
        self.v += 1
        return self.v
    def predec(self):
        self.v -= 1
        return self.v

    def postinc(self):
        self.v += 1
        return self.v - 1
    def postdec(self):
        self.v -= 1
        return self.v + 1

    def __add__(self,addend):
        return self.v + addend
    def __sub__(self,subtrahend):
        return self.v - subtrahend
    def __mul__(self,multiplier):
        return self.v * multiplier
    def __div__(self,divisor):
        return self.v / divisor

    def __getitem__(self):
        return self.v

    def __str__(self):
        return str(self.v)

    def set(self,v):
        if type(v) != int:
            v = 0
        self.v = v

You might use it like this:

c = counter()                          # defaults to zero
for listItem in myList:                # imaginary task
     doSomething(c.postinc(),listItem) # passes c, but becomes c+1

...already having c, you could do this...

c.set(11)
while c.predec() > 0:
    print c

....or just...

d = counter(11)
while d.predec() > 0:
    print d

...and for (re-)assignment into integer...

c = counter(100)
d = c + 223 # assignment as integer
c = c + 223 # re-assignment as integer
print type(c),c # <type 'int'> 323

...while this will maintain c as type counter:

c = counter(100)
c.set(c + 223)
print type(c),c # <class '__main__.counter'> 323

EDIT:

And then there's this bit of unexpected (and thoroughly unwanted) behavior,

c = counter(42)
s = '%s: %d' % ('Expecting 42',c) # but getting non-numeric exception
print s

...because inside that tuple, getitem() isn't what used, instead a reference to the object is passed to the formatting function. Sigh. So:

c = counter(42)
s = '%s: %d' % ('Expecting 42',c.v) # and getting 42.
print s

...or, more verbosely, and explicitly what we actually wanted to happen, although counter-indicated in actual form by the verbosity (use c.v instead)...

c = counter(42)
s = '%s: %d' % ('Expecting 42',c.__getitem__()) # and getting 42.
print s
2

TL;DR

Python does not have unary increment/decrement operators (--/++). Instead, to increment a value, use

a += 1

More detail and gotchas

But be careful here. If you're coming from C, even this is different in python. Python doesn't have "variables" in the sense that C does, instead python uses names and objects, and in python ints are immutable.

so lets say you do

a = 1

What this means in python is: create an object of type int having value 1 and bind the name a to it. The object is an instance of int having value 1, and the name a refers to it. The name a and the object to which it refers are distinct.

Now lets say you do

a += 1

Since ints are immutable, what happens here is as follows:

  1. look up the object that a refers to (it is an int with id 0x559239eeb380)
  2. look up the value of object 0x559239eeb380 (it is 1)
  3. add 1 to that value (1 + 1 = 2)
  4. create a new int object with value 2 (it has object id 0x559239eeb3a0)
  5. rebind the name a to this new object
  6. Now a refers to object 0x559239eeb3a0 and the original object (0x559239eeb380) is no longer refered to by the name a. If there aren't any other names refering to the original object it will be garbage collected later.

Give it a try yourself:

a = 1
print(hex(id(a)))
a += 1
print(hex(id(a)))

protected by Community Jul 24 '16 at 1:53

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