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I am trying to find the rationale behind having the re- and post- versions of the increment and decrement operators overloadable separately.
In my mind, and in every implementation I have ever seen of these operators for any type of class, these are the same operator (=do the same thing) and just differ in when it is called.
It would seem much more logical to me that the designers of C++ would have had one ++ operator, and the compiler would call it as needed, either before or after reading the value (or, more likely, at the previous or next sequence point, which I think is equivalent)

So, the question is: Does anyone have an example of a case/class where these might not be implemented the same? Or does anyone know/guess the rationale behind this design choice?


For those that prefer to look at code than read text in a question, here is the summary:

For what type T (a user defined class representing anything you want) would it make sense for the following 2 lines to not have the same side effects:

T v;

v++;
++v;

EDIT
To quote @Simple's comment below, which I hope clarifys the question:

Why post-increment (overloading) is in the language if the compiler can just do a copy itself and do the pre-increment


EDIT 2
Since the question is apparently unclear to many, here is another explanation:

Consider the following two lines:

b = a++;
b = ++a;

If it was one operator (for the sake of argument, I will call the operator +a+), the first line would be translated by the compiler into

b = a;
+a+;

and the second into

+a+;
b = a;
share|improve this question
4  
Considering that they kinda do do two different things even when they do the same thing... – cHao Nov 5 '13 at 15:55
1  
I don't know why do you say the are the same, the implementations are usually different – Karoly Horvath Nov 5 '13 at 15:56
1  
How about T x=v++; and T x=++v;? – Beta Nov 5 '13 at 15:57
4  
Post-increment can always be implemented in terms of pre-increment. He's asking why post-increment (overloading) is in the language if the compiler can just do a copy itself and do the pre-increment. – Simple Nov 5 '13 at 16:02
3  
The question can be expanded to: why can't all of the relational operators just be implemented in terms of operator<; why can't operator!= just be implemented in terms of operator==; why can't all of the arithmetical operators be implemented in terms of operator@=, etc. The answer is, really, just because someone/some people thought it would be a good idea if these could do different things back in 1998. – Simple Nov 5 '13 at 16:15

Pre increment increments the variable before the rest of the statement so for example

x = 2;
y = ++x;

y == 3;
x == 3;

Whereas post increment does the increment after the rest of the statement,

x = 2;
y = x++;

y == 2;
x == 3;

Pre increment is slightly faster so it should be preferred. Something to note is that when both operators are used in one statement the behaviour is undefined, so something like

x = 5;
x = x++ + ++x;

will give different results in different languages.

share|improve this answer
    
I know this. The question is why are these 2 operators, and not 1 operator that is called at different points – baruch Nov 5 '13 at 15:57
    
for performance reasons – Karoly Horvath Nov 5 '13 at 15:59
    
Psh. The compiler could easily optimize away the difference if there weren't two separate operators. (In fact, it'd be the one responsible for making x++ work properly rather than trusting that the code did so.) The question is why there are two separate operators -- that is, where would it make sense to have them do anything besides get the value before or after assignment. – cHao Nov 5 '13 at 16:05
    
It should be noted that virtually all modern compilers will optimize away the temporary if you use post-fix instead of prefix (e.g. when writing a for-loop), so the performance issue is no longer an issue. – Zac Howland Nov 5 '13 at 16:49

How would you implement a generic version of post-increment ?

I guess: T operator++(int) { T tmp(*this); ++*this; return tmp; }

What if my type is non-copiable, or expensive to copy ?

Well, I'd would prefer:

Proxy operator++(int) { return Proxy(++*this, 1); }

And then have things like:

bool operator==(Proxy const& left, T const& right) {
    return left.value - 1 == right.value;
}

Why post-increment (overloading) is in the language if the compiler can just do a copy itself and do the pre-increment ?

Because your assumption that the compiler can do the copy is erroneous, and even when it holds might be too costly.

share|improve this answer

This distinction becomes important in iterators over complex types. The expression

*it++

gives me the object the iterator currently points to, and increments the iterator. If the data would normally not be kept in memory after the iterator advances, returning the previous object becomes difficult. There are two approaches to this:

  1. keep a copy in the postincrement
  2. advance after delay

The former method still has to return something that behaves like an iterator (at least with regard to operator* and operator->, but cannot be a pointer because it also has to keep ownership of the copy of the object, so a proxy is returned:

struct iterator {
    value_type value;

    struct proxy {
        value_type value;
        value_type &operator*() { return value; }
        value_type *operator->() { return &value; }
    };

    value_type &operator*() { return value; }
    value_type *operator->() { return &value; }
    iterator &operator++(); // actual increment code
    proxy operator++(int) { proxy ret = { value }; ++*this; return ret; }
};

If creating a copy is expensive as well and should be avoided, you can also delay the increment:

struct iterator {
    value_type value;
    bool needs_increment;

    value_type &operator*() { if(needs_increment) ++*this; return value; }
    value_type *operator->() { if(needs_increment) ++*this; return &value; }
    iterator &operator++(); // actual increment code, resets needs_increment
    value_type *operator++(int) { needs_increment = true; return &value; }
};
share|improve this answer
    
Finally, an actual answer. – cHao Nov 7 '13 at 1:33

Because of the separate semantics of these operators for built-in types. The value of the expression differs between pre and post increment/decrement, even though both change the operand.

int a = 1;
(a++) == 1;
a = 1;
(++a) == 2;

Allowing to overload them separately permits creating similar semantics for the return value.

share|improve this answer
    
This doesn't answer the question. I know this. But this could still be achieved if they were one operator, by calling it either before or after the instruction that uses it. – baruch Nov 5 '13 at 15:58
    
@baruch, what do you mean by "calling it either before or after the instruction that uses it"? – StoryTeller Nov 5 '13 at 16:00
    
If it was one operator (for the sake of argument, I will call the operator +a+), your first line would be translated by the compiler into a==1; +a+; and the second into +a+; a==2; – baruch Nov 5 '13 at 16:03
1  
@baruch they're not one operator, so you're going to be waiting awhile. The question in general-comment is more interesting anyway. I.e. Why can't the compiler generate proper temp-value post-increment using pre-increment implementation, thereby allowing you to have only a operator++() (assuming you don't provide your own post-increment override). If that is the real question its an interesting one, otherwise this is getting lame fast. – WhozCraig Nov 5 '13 at 16:14
1  
@baruch and my comment regarding this is likely the reason, but I've not taken the time to look it up. I'm guessing (dangerous to do with the standard) that post-increment is in no way defined by the standard as an equivalency to pre-increment (or vice versa) precisely because they're two different operators. it would be like defining operator -(val) as equivalent to operator +(-val). The standard goes to great lengths to define operators independently for maximum flexibility and directly conclusive implementations. (again, just a stab at it, but its would seem reasonable). – WhozCraig Nov 5 '13 at 16:22

I think that the problem is related to the order of evaluation of (sub)expressions and the time of applying of side effects. For example in C# the order of evaluation of (sub)expressions is deterministic and side effects are applied at once. For example consider the following C# code

int x = 0;
int y = x++ + ++x;

This code has defined behaviour in C#. So you can implement only one increment operator and the compiler will use it the appropriate way.

C++ has no such a possibility. The order of evaluation of (sub)expressions is unspecified and side effects are not applied at once.

share|improve this answer

Look at the following example

int i = 5;
int x = i++;
cout << i << " " << x;

This will print

6 5

int i = 5;
int x = ++i;
cout << i << " " << x;

This will print

6 6

So what can we infer?
In post-fix, the value of i is assigned to x first and then i is incremented
In pre-fix, the value of i is incremented first and then assigned to x

share|improve this answer
1  
The precedence of post-fix > precedence of assignment operator > precedence of pre-fix <-- that is not accurate. – Zac Howland Nov 5 '13 at 16:43
    
@ZacHowland Yeah I was wrong. Thanks! – gldraphael Nov 5 '13 at 17:03

Perhaps something in a threaded environment that implements lazily? For ++a you want it to block until it has updated a so you get the updated value back, but for a++ you just send the signal and get on with things.

share|improve this answer

They are two separate operators because they do two different (albeit related) things.

Pre-increment/decrement will increment/decrement the variable and return the new value.

int i = 0;
int j = ++i; // j is now 1

Post-increment/decrement will increment/decrement the variable and return the old value.

int i = 0;
int j = i++; // j is now 0

In general, the implementation of these operators looks like this (for some type T):

T& T::operator++() // prefix overload
{
    *this = *this + 1;
    return *this;
}

T T::operator++(int) // postfix overload
{
    T prev = *this;
    ++(*this); // call prefix overload
    return prev;
}

As you can see, the prefix overload does not need an extra copy of the type, while the postfix version does.

As the bulk of the comments center around the question of why this is the case:

The short answer is: Because the C standard says so (and C++ inherited it from C).

The longer answer is:

++a and a++ are simply shorthand notation for calling specific functions. ++a (for a given type T) maps to either T& T::operator++() or T& operator++(T&) and a++ maps to either T T::operator++(int) or T operator(T&, int). As with all operators, you (as the programmer) can define them to do anything you want with respect to your corresponding type (Note: it is generally considered bad practice to overload an operator to do something strange, but the standard does not stop you from doing so). In general, if you are defining a type (e.g. an iterator), you would make it match the behavior of a built in type (e.g. a pointer) by providing a similar interface (i.e. overloading the proper operators). However, you could decide that you want operator++() to perform the quadratic formula and operator++(int) to take a Fourier Transform. As they are 2 separate functions, that is allowed. If the compiler was allowed to infer operator++(int) based on the on premise that it would be defined in terms of operator++(), they would be tied together.

Operators in C++ are nothing more than shorthand notation for function calls. While it is common to implement several operators in terms of others, it is not required by the standard, and thus the compiler cannot make such an assumption. If it were required by the standard, then there would be a lot of assumed behavior to keep track of.

Additionally, the behavior of ++a and a++ is a carry-over from C. There is a lot of code that exists that utilizes the behavior of one or the other, and changing that in the C++ standard would break compatibility with C (unless you also made the change in the C standard). As there is a lot of existing code that utilizes the behavior of these operators, you would be potentially making a large breaking change.

While it is quite common to implement post-increment in terms of pre-increment, you really should think of these two functions as different functions (much the same way you think of operator== vs operator!=, operator<, operator>, etc. Just because something is common does not mean the standard will, or even should, make it a requirement.

share|improve this answer
    
But when does it make sense for x++ to be a separate operator, if pretty much every sane post-increment overload is basically the same as the one you have here? Why couldn't the compiler have been made to generate code that does exactly what you've done with your postfix overload? To, say, turn T i; T j = i++; into T i; T j = i; ++i; ? At that point even the performance difference between ++i and i++ could go away until you assigned the result somewhere. – cHao Nov 5 '13 at 16:36
    
The compiler knows nothing about the purpose of your class; it only knows what you tell it. There are times where you do not want a post-increment and want everything to be done with pre-increment only (or vice versa). Having the compiler make assumptions about things is how you end up with unpredictable code. – Zac Howland Nov 5 '13 at 16:42
    
The purpose of your class shouldn't really involve enforcing syntax. But if you wanted to outlaw post-increment, all you'd have to do is make the class not copy-assignable or copy-constructible. If you allow either one, people already have a trivial workaround anyway for your refusal to allow post-increment, and the lack of an operator for it appears as an oversight rather than a design decision. – cHao Nov 5 '13 at 16:48
    
Making a class non-copyable has a lot of other side effects. If you were, for example, writing an iterator class and only wanted to allow pre-increment, then making the entire class non-copyable just to do that would make your entire iterator class unusable. You are confusing the syntax with what it actually is: an interface. ++a is shorthand for a call to operator++() while a++ is shorthand for a call to operator++(int). They are 2 separate functions. – Zac Howland Nov 5 '13 at 16:55
    
The whole point (and in fact the very title of the question!) is, why are they two separate functions? When does it not make sense for them to do the same thing, with the only difference being whether the old value or the new one is returned (a difference which could have been handled by the compiler)? You haven't really answered that; you're going on about outlawing syntax, but ignore the changes that would be required to make such an arbitrary decision useful, when those changes would themselves prevent post-increment from working anyway. – cHao Nov 5 '13 at 17:02

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