I just finished listening to the Software Engineering radio podcast interview with Scott Meyers regarding C++0x. Most of the new features made sense to me, and I am actually excited about C++0x now, with the exception of one. I still don't get move semantics... What is it exactly?
I find it easiest to understand move semantics with example code. Let's start with a very simple string class which only holds a pointer to a heap-allocated block of memory:
Since we chose to manage the memory ourselves, we need to follow the rule of three. I am going to defer writing the assignment operator and only implement the destructor and the copy constructor for now:
The copy constructor defines what it means to copy string objects. The parameter
Now comes the key insight into move semantics. Note that only in the first line where we copy
The arguments in lines 2 and 3 are not lvalues, but rvalues, because the underlying string objects have no names, so the client has no way to inspect them again at a later point in time.
rvalues denote temporary objects which are destroyed at the next semicolon (to be more precise: at the end of the full-expression that lexically contains the rvalue). This is important because during the initialization of
C++0x introduces a new mechanism called "rvalue reference" which, among other things, allows us to detect rvalue arguments via function overloading. All we have to do is write a constructor with an rvalue reference parameter. Inside that constructor we can do anything we want with the source, as long as we leave it in some valid state:
What have we done here? Instead of deeply copying the heap data, we have just copied the pointer and then set the original pointer to null. In effect, we have "stolen" the data that originally belonged to the source string. Again, the key insight is that under no circumstance could the client detect that the source had been modified. Since we don't really do a copy here, we call this constructor a "move constructor". Its job is to move resources from one object to another instead of copying them.
Congratulations, you now understand the basics of move semantics! Let's continue by implementing the assignment operator. If you're unfamiliar with the copy and swap idiom, learn it and come back, because it's an awesome C++ idiom related to exception safety.
Huh, that's it? "Where's the rvalue reference?" you might ask. "We don't need it here!" is my answer :)
Note that we pass the parameter
So if you say
But if you say
To summarize, the copy constructor makes a deep copy, because the source must remain untouched. The move constructor, on the other hand, can just copy the pointer and then set the pointer in the source to null. It is okay to "nullify" the source object in this manner, because the client has no way of inspecting the object again.
I hope this example got the main point across. There is a lot more to rvalue references and move semantics which I intentionally left out to keep it simple. If you want more details please see my supplementary answer.
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It's like copy semantics, but instead of having to duplicate all of the data you get to steal the data from the object being "moved" from.
First of all, sorry for my english.
In easy (practical) terms:
To copy an object means copies of its statics members and calls to the
However, to move an object (I repeat, in a practical point of view) implies only to copy the pointers to dynamic objects, and not to create new ones.
But, is that not dangerous? Of course, you could destruct twice a dynamic object (segmentation fault). So, to avoid that, you should "invalidate" the source pointers to avoid destructing them twice:
Ok, but if I move an object, the source object becomes useless, not? Of course, but in certains situations that's very useful. The most evident one is when I call a function with an anonymous object (temporal, rvalue object, ..., you can call it with different names):
In that situation, an anonymous object is created, next copied to the function parameter, and after deleted. So, here it is better to move the object, because you don't need the anonymous object and you can save time an memory.
Here it begins the concept of rvalue reference. That exists in C++11 only to detect if the received object is anonymous or not. I thing you do already know that but, an lvalue is an assignable entity (the left part of the
In this case, when an object of type
It is important to remember that static objects are always copied. There's no ways to "move" a static object (object in stack and not in heap). So, the distinction "move"/ "copy" when an object has no dynamic members (directly or indirectly) is irrelevant.
If your object is complex and the destructor has other secondary effects, like calling to a library's function, calling to other global functions or whatever it is, perhaps is better to signal a movement with a flag:
So, your code is shorter (you don't need to do a
Other typical question: difference between
And what is perfect forwarding?: it is important to say that a "rvalue reference" is a reference to a named object in the "caller's scope". But in the actual scope, a rvalue reference is a name to an object, so, it acts as a named object. If you pass a rvalue reference to another function, you are passing a named object, so, the object isn't received like a temporal object.
With this line,
Is that perfect forwarding? Not, but we are very close. Perfect forwarding is only useful to work with templates, with the purpose to say: if I need to pass an object to another function, I want that if I receive a named object, the object is passed as a named object, and when not, I want to pass it like a unnamed object:
That's the signature of a prototipical function that uses perfect forwarding, implemented in C++11 by means of
Move semantics is based on rvalue references.
In the above code, with old compilers the result of
My first answer was an extremely simplified introduction to move semantics, and many details were left out on purpose to keep it simple. However, there is a lot more to move semantics, and I thought it was time for a second answer to fill the gaps. The first answer is already quite old, and it did not feel right to simply replace it with a completely different text. I think it still serves well as a first introduction. But if you want to dig deeper, read on :)
Stephan T. Lavavej took the time provide valuable feedback. Thank you very much, Stephan!
Move semantics allows an object, under certain conditions, to take ownership of some other object's external resources. This is important in two ways:
What is a move?
The C++98 standard library offers a smart pointer with unique ownership semantics called
The unusual thing about
Note how the initialization of
The copy constructor of
Dangerous and harmless moves
The dangerous thing about
Note how both examples follow the same syntactic pattern:
And yet, one of them invokes undefined behavior, whereas the other one does not. So what is the difference between the expressions
Obviously, there must be some profound difference between the expression
Moving from lvalues such as
Note that the letters
We now understand that moving from lvalues is potentially dangerous, but moving from rvalues is harmless. If C++ had language support to distinguish lvalue arguments from rvalue arguments, we could either completely forbid moving from lvalues, or at least make moving from lvalues explicit at call site, so that we no longer move by accident.
C++11's answer to this problem is rvalue references. An rvalue reference is a new kind of reference that only binds to rvalues, and the syntax is
If we throw
In practice, you can forget about
Rvalue references went through several versions. Since version 2.1, an rvalue reference
In the above example,
A useful example of a function with an
The constructor takes ownership of the object, and the destructor deletes it:
Now comes the interesting part, the move constructor:
This move constructor does exactly what the
The second line fails to compile, because
Move assignment operators
The last missing piece is the move assignment operator. Its job is to release the old resource and acquire the new resource from its argument:
Note how this implementation of the move assignment operator duplicates logic of both the destructor and the move constructor. Are you familiar with the copy-and-swap idiom? It can also be applied to move semantics as the move-and-swap idiom:
Moving from lvalues
Sometimes, we want to move from lvalues. That is, sometimes we want the compiler to treat an lvalue as if it were an rvalue, so it can invoke the move constructor, even though it could be potentially unsafe.
For this purpose, C++11 offers a standard library function template called
Here is how you explicitly move from an lvalue:
Note that after the third line,
Note that even though
Both prvalues and xvalues are rvalues. Xvalues and lvalues are both glvalues (Generalized lvalues). The relationships are easier to grasp with a diagram:
Note that only xvalues are really new; the rest is just due to renaming and grouping.
Moving out of functions
So far, we have seen movement into local variables, and into function parameters. But moving is also possible in the opposite direction. If a function returns by value, some object at call site (probably a local variable or a temporary, but could be any kind of object) is initialized with the expression after the
Perhaps surprisingly, automatic objects (local variables that are not declared as
How come the move constructor accepts the lvalue
Note that in both factory functions, the return type is a value, not an rvalue reference. Rvalue references are still references, and as always, you should never return a reference to an automatic object; the caller would end up with a dangling reference if you tricked the compiler into accepting your code, like this:
Moving into members
Sooner or later, you are going to write code like this:
Basically, the compiler will complain that
The solution is to manually enable the move:
You could argue that
You can also pass
Special member functions
C++98 implicitly declares three special member functions on demand, that is, when they are needed somewhere: the copy constructor, the copy assignment operator and the destructor.
Rvalue references went through several versions. Since version 3.0, C++11 declares two additional special member functions on demand: the move constructor and the move assignment operator. Note that neither VC10 nor VC11 conform to version 3.0 yet, so you will have to implement them yourself.
These two new special member functions are only implicitly declared if none of the special member functions are declared manually. Also, if you declare your own move constructor or move assignment operator, neither the copy constructor nor the copy assignment operator will be declared implicitly.
What do these rules mean in practice?
Note that the copy assignment operator and the move assignment operator can be fused into a single, unified assignment operator, taking its argument by value:
This way, the number of special member functions to implement drops from five to four. There is a tradeoff between exception-safety and efficiency here, but I am not an expert on this issue.
Consider the following function template:
You might expect
If the argument is an rvalue of type
If you want to constrain a function template to rvalues, you can combine SFINAE with type traits:
Implementation of move
Now that you understand reference collapsing, here is how
As you can see,
Note that returning by rvalue reference is fine in this example, because
I found Eli Bendersky's blog article about lvalues and rvalues in C and C++ pretty informative. He also mentions rvalue references in C++11 and introduces them with small examples.
Move semantics is about transferring resources rather than copying them when nobody needs the source value anymore.
In C++03, objects are often copied, only to be destroyed or assigned-over before any code uses the value again. For example, when you return by value from a function—unless RVO kicks in—the value you're returning is copied to the caller's stack frame, and then it goes out of scope and is destroyed. This is just one of many examples: see pass-by-value when the source object is a temporary, algorithms like
When such copy/destroy pairs are expensive, it's typically because the object owns some heavyweight resource. For example,
If you are really interested in a good, in-depth explanation of move semantics, I'd highly recommend reading the original paper on them, "A Proposal to Add Move Semantics Support to the C++ Language."
It's very accessible and easy to read and it makes an excellent case for the benefits that they offer. There are other more recent and up to date papers about move semantics available on the WG21 website, but this one is probably the most straightforward since it approaches things from a top-level view and doesn't get very much into the gritty language details.
You know what a copy semantics means right? it means you have types which are copyable, for user-defined types you define this either buy explicitly writing a copy constructor & assignment operator or the compiler generates them implicitly. This will do a copy.
Move semantics is basically a user-defined type with constructor that takes an r-value reference (new type of reference using && (yes two ampersands)) which is non-const, this is called a move constructor, same goes for assignment operator. So what does a move constructor do, well instead of copying memory from it's source argument it 'moves' memory from the source to the destination.
When would you want to do that? well std::vector is an example, say you created a temporary std::vector and you return it from a function say:
You're going to have overhead from the copy constructor when the function returns, if (and it will in C++0x) std::vector has a move constructor instead of copying it can just set it's pointers and 'move' dynamically allocated memory to the new instance. It's kind of like transfer-of-ownership semantics with std::auto_ptr.
Suppose you have a function that returns a substantial object:
When you write code like this:
then an ordinary C++ compiler will create a temporary object for the result of
This is especially important if (like perhaps the
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