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The title says it all.

The first case f(const X&) is the good old fashioned const reference parameter.

However, when taking a mutable reference parameter, why not always use X&&? This way client code can use temps or regular lvalues, rather than f() dictating usage.

EDIT: Sloppiness on my part, sorry. I meant, given fc(const X&) and fm(X&&), do we need fm(X&)?

EDIT: Example: I use stateless decorators to pass as parameters:

class Base64Writer: public Writer {
public:
  Base64Writer(Writer& w): w_(w) {}
private:
  virtual void doWrite() override;
  Writer& w_;
}

void func(Writer&& w) { w.doWrite(); }

// to be called as
Writer wr = ...;
func(Base64Writer(wr));
share|improve this question
    
What if you don't want temporaries passed? Like after an implicit conversion. –  Bo Persson Jan 19 '13 at 9:25
    
@Bo, why should the implementation dictate usage? Is it not the caller's prerogative what to pass? –  Benito Ciaro Jan 19 '13 at 9:27
    
The reason for not allowing temporaries with f(X&) was that the users were surprised by the bugs it caused. Using f(X&&) instead would surely bring those bugs back. –  Bo Persson Jan 19 '13 at 9:30
    
I prefer minimalist interfaces and expect the users to know what they are doing. –  Benito Ciaro Jan 19 '13 at 9:42

3 Answers 3

up vote 2 down vote accepted
  • If you mean to ask : is it logical to have all three overloads at the same time?

    In most cases, it would be a bad idea. as the semantic of the overloaded functions contradict each other. One promises that it will not modify the argument, the other doesn't make any such promise (it tacitly says it will modify the argument!). The user of such overloaded functions will be confused that differs only by const.

    It makes sense to have these overloads at the same time:

    void process(std::vector<int> const&);
    void process(std::vector<int> &&);
    

    But a third one, in addition to the above two, doesn't make much sense to me:

    void process(std::vector<int> &); //contradicts the first overload
    

    It only adds confusion and makes code harder to read. If you want this semantic, choose a different name for the function!

  • If you mean to ask : which one should you have (though not necessarily all at the same time)?

    I would say, it depends on the semantic. If the parameter behaves as input and/or output parameter, then f(X&) makes sense. If the parameter is only input parameter, then f(X const&) makes sense, in this case you can additionally define f(X&&) also, to gain performance advantage!

share|improve this answer
    
Sorry, I wasn't clear. I edited my question. –  Benito Ciaro Jan 19 '13 at 9:25
    
@BenitoCiaro: Updated my answer. –  Nawaz Jan 19 '13 at 9:32
    
Yes, but my question is why do I need to define fm(X&) if I have already defined fm(X&&) –  Benito Ciaro Jan 19 '13 at 9:44
    
@BenitoCiaro: though that is not clear in your question, but then my answer also answers that. You don't need to define f(X&), when you already have f(X&&); in most cases it adds confusion. –  Nawaz Jan 19 '13 at 9:46
    
I was hoping to go beyond "most cases" to see if X& is ever needed. All it does is restrict the caller's options which I don't believe is the library's job to dictate such things to the caller. –  Benito Ciaro Jan 19 '13 at 10:52

Absolutely!

For example, you need it whenever you're manipulating a container passed as an argument.

In fact, you might need all three -- compare these, for example:

vector<int> append_if_not_ends_with(vector<int> const &original, int x)
{
    vector<int> v(original);
    if (v.empty() || v.back() != x)
    { v.push_back(x); }
    return v;
}

vector<int> &append_if_not_ends_with(vector<int> &v, int x)
{
    if (v.empty() || v.back() != x)
    { v.push_back(x); }
    return v;
}

vector<int> append_if_not_ends_with(vector<int> &&original, int x)
{
    vector<int> v(std::move(original));
    if (v.empty() || v.back() != x)
    { v.push_back(x); }
    return v;
}

If you have all 3 overloads, then you can avoid copying the contents of the vector when you don't need to.

vector<int> v1;
vector<int> const &v2 =
    foo ? append_if_not_ends_with(v1) :
    bar ? append_if_not_ends_with(static_cast<vector<int> const &>(v1)) :
          append_if_not_ends_with(vector<int>());
share|improve this answer
    
Why would you need BOTH? std::vector<int> const& or std::vector<int> &? –  Nawaz Jan 19 '13 at 9:22
    
@Nawaz: I'm confused, when did I say we would necessarily need both? –  Mehrdad Jan 19 '13 at 9:23
    
So you mean it is logical to have an overloaded function vector<int> const & append_if_not_ends_with(vector<int> const &v, int x) ? –  Nawaz Jan 19 '13 at 9:23
    
Read the question. –  Nawaz Jan 19 '13 at 9:24
1  
@BenitoCiaro: Could you provide an example of what you mean? I'm having trouble seeing how that would avoid copying. –  Mehrdad Jan 19 '13 at 9:53

I am surprised that nobody pointed out that you can actually pass by value, and that this practice in c++11 is actually the right thing to do whenever you think that you need f(X&&).

Imo:

  • Use f(const X &) if you need just to read from the element.
  • Use f(X) if you need to take the ownership of the object passed. The caller of your function can just do f( std::move(something)) or f(something) when appropriate.
  • Use f(X&) if you need to modify the passed object.
share|improve this answer
    
The question is about pass-by-reference, not pass-by-value. The two are completely different and are NOT interchangeable. –  Benito Ciaro Jan 20 '13 at 4:08
    
@BenitoCiaro Actually I see really few cases in which you would need f(X&&) when you can have f(X), unless your moving constructor is really expensive. See also this question stackoverflow.com/questions/7592630/… –  sbabbi Jan 20 '13 at 11:45

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