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struct Person {
   string name;

Person* p = ...

Assume that no operators are overloaded.

Which is more efficient (if any) ?

(*p).name vs. p->name

Somewhere in the back of my head I hear some bells ringing, that the * dereference operator may create a temporary copy of an object; is this true?

The background of this question are cases like this:

Person& Person::someFunction(){
    return *this;

and I began to wonder, if changing the result to Person* and the last line to simply return this would make any difference (in performance)?

share|improve this question
At this point you should much more worry about readability, and since -> is the more common syntactic sugar, (*i).m is frowned upon in many places. Only if any profiling shows that there might be a problem related to this you should start worrying about its efficiency. – PlasmaHH May 3 '13 at 9:22
I'd expect the compiler to produce exactly the same result. You can answer this yourself, compile both codes to assembler and check the produced code. – bluehallu May 3 '13 at 9:22
I asked this question because of the background I described - many basic operators usually return a reference to self, and I see very often them returning *this; – Kalamar Obliwy May 3 '13 at 9:23
*p is an l-value (you can do *p = something;). How could this create a temporary object? – Angew May 3 '13 at 9:25
@KalamarObliwy There is no such possibility. The built-in pointer dereference operator * returns an l-value designating the object pointed to (you can think of it as a reference to it). – Angew May 3 '13 at 9:29
up vote 8 down vote accepted

When you return a reference, that's exactly the same as passing back a pointer, pointer semantics excluded.
You pass back a sizeof(void*) element, not a sizeof(yourClass).

So when you do that:

Person& Person::someFunction(){
    return *this;

You return a reference, and that reference has the same intrinsic size than a pointer, so there's no runtime difference.

Same goes for your use of (*i).name, but in that case you create an l-value, which has then the same semantics as a reference (see also here)

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This is a good point about the size of return. Can you explain, what does *p do just by itself then? The result of it is a Person& or Person, or const Person&? – Kalamar Obliwy May 3 '13 at 9:29
You get an l-value, which references the object's address, if I read stackoverflow.com/questions/11347111/… correctly and according to wikipedia: en.wikipedia.org/wiki/Value_(computer_science) – Gui13 May 3 '13 at 9:33
Interesting reads in the links, thank you :) – Kalamar Obliwy May 3 '13 at 9:35

There's no difference. Even the standard says the two are equivalent, and if there's any compiler out there that doesn't generate the same binary for both versions, it's a bad one.

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The same for built-in types and user-defined?? – Kalamar Obliwy May 3 '13 at 9:22
@KalamarObliwy assuming no operator overloading, yes. – Luchian Grigore May 3 '13 at 9:22
And for the standard smart pointers (std::unique_ptr, std::shared_ptr), the overloaded operators still behave the same. – MSalters May 3 '13 at 13:00

Yes, it's much harder to read and type, so you are much better off using the x->y than (*x).y - but other than typing efficiency, there is absolutely no difference. The compiler still needs to read the value of x and then add the offset to y, whether you use one form or the other [assuming there are no funny objects/classes involved that override the operator-> and operator* respectively, of course]

There is definitely no extra object created when (*x) is referenced. The value of the pointer is loaded into a register in the processor [1]. That's it.

Returning a reference is typically more efficient, as it returns a pointer (in disguise) to the object, rather than making a copy of the object. For objects that are bigger than the size of a pointer, this is typically a win.

[1] Yes, we can have a C++ compiler for a processor that doesn't have registers. I know of at least one processor from Rank-Xerox that I saw in about 1984, which doesn't have registers, it was a dedicated LiSP processor, and it just has a stack for LiSP objects... But they are far from common in todays world. If someone working on a processor that doesn't have registers, please don't downvote my answer simply because I don't cover that option. I'm trying to keep the answer simple.

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-1 for not considering processors without r... oh, wait. :) – Michael Kjörling May 3 '13 at 14:37

Any good compiler will produce the same results. You can answer this yourself, compile both codes to assembler and check the produced code.

share|improve this answer
ideone.com/Ovj7ao – BoBTFish May 3 '13 at 9:33
@BoBTFish voodoo – Luchian Grigore May 3 '13 at 9:45

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