I am a bit confused about the differences between

Type  operator +  (const Type &type);
Type &operator += (const Type &type);


friend Type  operator +  (const Type &type1, const Type &type2);
friend Type &operator += (const Type &type1, const Type &type2);

which way is preferred, what do they look like and when should either be used?

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    Note that the two examples you present are not the same. In the first examples, the left operand cannot be const-qualified; in the second examples it can. To allow the first examples to take a const-qualified left operand, you need to qualify the member function, e.g. T operator+(const T& t) const;. – James McNellis Jan 11 '11 at 0:28
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    More or less a duplicate: stackoverflow.com/questions/4622330/… – Charles Salvia Jan 11 '11 at 1:09
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    The friend keyword has no direct relation to the issue and can only add to the confusion. There's absolutely no requirement for a standalone operator to be declared as a friend. Even though you one can often hear this approach referred to as "declaring operator as a friend", the reference to friendship in this context is a confusing misnomer. – AnT Jan 11 '11 at 1:38
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    @AndreyT: although occasionally you do see a non-member operator overload as friend not because of anything to do with access control, but simply because that's the way to put the definition of a non-member function inside a class definition. So in that situation the two issues are related. – Steve Jessop Jan 11 '11 at 2:32
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    @James: to be specific, in both cases operator+ should take const for its first operand, and operator+= definitely shouldn't. – Steve Jessop Jan 11 '11 at 2:33

The first form of the operators is what you would define inside class Type.

The second form of the operators is what you would define as free-standing functions in the same namespace as class Type.

It's a very good idea to define free-standing functions because then the operands to those can take part in implicit conversions.


Assume this class:

class Type {
    Type(int foo) { }

    // Added the const qualifier as an update: see end of answer
    Type operator + (const Type& type) const { return *this; }

You could then write:

Type a = Type(1) + Type(2); // OK
Type b = Type(1) + 2; // Also OK: conversion of int(2) to Type

But you could NOT write:

Type c = 1 + Type(2); // DOES NOT COMPILE

Having operator+ as a free function allows the last case as well.

What the second form of the operator does wrong though is that it performs the addition by directly tweaking the private members of its operands (I 'm assuming that, otherwise it would not need to be a friend). It should not be doing that: instead, the operators should also be defined inside the class and the free-standing functions should call them.

To see how that would turn out, let's ask for the services of a guru: http://www.gotw.ca/gotw/004.htm. Scroll at the very end to see how to implement the free-standing functions.


As James McNellis calls out in his comment, the two forms given also have another difference: the left-hand-side is not const-qualified in the first version. Since the operands of operator+ should really not be modified as part of the addition, it's a very very good idea to const-qualify them all the time. The class Type in my example now does this, where initially it did not.


The best way to deal with operators + and += is:

  1. Define operator+= as T& T::operator+=(const T&); inside your class. This is where the addition would be implemented.
  2. Define operator+ as T T::operator+(const T&) const; inside your class. This operator would be implemented in terms of the previous one.
  3. Provide a free function T operator+(const T&, const T&); outside the class, but inside the same namespace. This function would call the member operator+ to do the work.

You can omit step 2 and have the free function call T::operator+= directly, but as a matter of personal preference I 'd want to keep all of the addition logic inside the class.

  • The operator isn't necessarily "tweaking" anything; sometimes there's just data that you don't want to provide an accessor for, but that matters to the operation. – cHao Jan 11 '11 at 0:14
  • I usually define the modifying operation (i.e. +=) inside the class, then define operator + as a free function in terms of +=. Create a copy of arg1, then return tmp += arg2. This lets you define the addition in one place. This method is detailed in one of Meyer's Effective C++ books. – Daniel Gallagher Jan 11 '11 at 0:31
  • @cHao: Since you don't want to provide access to the data, force all interested parties to call through your own method (this would be the first form of operator+). This is what I 'm saying. – Jon Jan 11 '11 at 0:32
  • @Daniel Gallagher: This is the way to go, I fully agree. If you take a look at the Herb Sutter link, that's how it's done there as well. – Jon Jan 11 '11 at 0:33
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    @Jon: the best way: T& T::operator+=(T const&); and T operator+(T lhs, T const& rhs) { return lhs += rhs; } --> your step 2. is spurious, your signature is off in step 3. (compiler can optimize the copy in function signature better, especially with the upcoming move semantics) – Matthieu M. Jan 11 '11 at 7:29

The proper way to implement operators, with respect to C++03 and C++0x (NRVO and move-semantics), is:

struct foo
    // mutates left-operand => member-function
    foo& operator+=(const foo& other)
        x += other.x;

        return *this;

    int x;

// non-mutating => non-member function
foo operator+(foo first, // parameter as value, move-construct (or elide)
                const foo& second) 
    first += second; // implement in terms of mutating operator

    return first; // NRVO (or move-construct)

Note it's tempting to combine the above into:

foo operator+(foo first, const foo& second) 
    return first += second;

But sometimes (in my testing) the compiler doesn't enable NRVO (or move semantics) because it can't be certain (until it inlines the mutating operator) that first += second is the same as first. Simpler and safer is to split it up.

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    +1 for a good answer, but recommending something based on the quirks of your compiler's optimiser (without even saying which compiler(s)) is a bit short-sighted ;-P – Tony Delroy Jan 11 '11 at 1:16
  • @GMan: FYI, it's not very tempting. – Steve Jessop Jan 11 '11 at 2:39
  • @Steve: I do consider it tempting :) @GMan: Would you happen to know (without an inlined += and +) what a = a + b would give ? I don't understand how NRVO could kick in here, since if += were to throw, then a is supposedly unmodified. – Matthieu M. Jan 11 '11 at 7:34
  • @Tony: Sorry, was MSVC. @Matt: Hm, good point. My tests were actually with move-constructing and I just assumed (I think now incorrectly) NRVO would follow the same criteria. – GManNickG Jan 11 '11 at 7:41
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    @Matthieu: NRVO is a copy constructor elision, not a copy assignment operator elision. AFAIK, the caller can't provide an existing object as the target for the return value, it has to be an object being constructed. In cases where the caller can't make use of NRVO, it just provides a temporary and assigns from that, doesn't it? – Steve Jessop Jan 11 '11 at 13:27

The friend specifier is used when the thing being declared isn't a member of the class, but needs access to the private members of the class's instances in order to do its job.

If your operator will be defined in the class itself, use the first way; if it'll be a standalone function, use the second.

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