Move Semantics in C++
Published at 2023-05-30
Last update over 365 days ago
Licensed under CC BY-NC-SA 4.0
cpp
move-semantics
r-value-reference
special-member-functions
programming-language
This is a note for Lecture 13, CS106L, Spring 2023.
DEFINITION
L-VALUE
l-value can appear on the left or right of an =
.
For example, here x
is an l-value:
int x = 3;
int y = x;
- l-values have names
- l-values are not temporary
- l-values live until the end of the scope
R-VALUE
r-value can ONLY appear on the right of an =
For example, here 3
is an r-value:
int x = 3;
int y = x;
- r-values don’t have names
- r-values are temporary
- r-values live until the end of the line
EXAMPLES
int x = 3; // 3 is an r-value
int *ptr = 0x02248837; // 0x02248837 is an r-value
vector<int> v1{1, 2, 3}; // {1, 2, 3} is an r-value, v1 is an l-value
auto v4 = v1 + v2; // v1 + v2 is an r-value
size_t size = v.size(); // v.size() is an r-value
v1[1] = 4 * i; // 4 * i is an r-value, v1[1] is an l-value
ptr = &x; // &x is an r-value
v1[2] = *ptr; // *ptr is an l-value
MyClass obj; // obj is an l-value
x = obj.public_member_variable; // obj.public_member_variable is l-value
MOVE SEMANTICS
In our generic vector
class, we have a vector copy assignment operator like this:
template <typename T>
vector<T>& vector<T>::operator=(const vector<T>& other) {
if (&other == this) return *this;
_size = other._size;
_capacity = other._capacity;
delete[] _elems;
_elems = new T[other._capacity];
std::copy(other._elems, other._elems + other._size, _elems);
return *this;
}
Aside: std::copy
is a generic copy function used to copy a range of elements from one container to another.
And in the code fragment below:
int main() {
vector<int> vec;
vec = make_me_a_vec(123);
}
vec
is created using the default constructormake_me_a_vec
creates a vector using the default constructorvec
is reassigned to a copy of that return value using copy assignment- copy assignment creates a new array and copies the contents of the old one
- The original return value’s lifetime ends and it calls its destructor
vec
’s lifetime ends and it calls its destructor
Here is a problem: make_me_a_vec(123)
is an r-value, and in vector<T>::operator=(const vector<T>& other)
, other
should be an l-value (referenced using &). Can r-values be bound to const &
?
The answer is Yes.
Another problem is that, we creates a vector, copies its content to another and deleted it. Can we do better?
We can use move assignment like this:
template <typename T>
vector<T>& vector<T>::operator=(const vector<T>& other) {
if (&other == this) return *this;
_size = other._size;
_capacity = other._capacity;
_elems = other._elems; // we don't copy in this version
return *this;
}
But what about this?
int main() {
vector<string> vec1 = {"hello", "world"};
vector<string> vec2;
vec2 = vec1;
vec1.push_back("Sure hope vec2 doesn't see this!");
} // BAD!
A problem occurs here!We need both a copy assignment AND a move assignment.
How do we know when to use move assignment and when to use copy assignment?
When the item on the right of the = is an r-value we should use move assignment.
Why? r-values are always about to die, so we can steal their resources.
int main() {
vector<int> vec;
vec = make_me_a_vec(123); // using move assignment
}
int main() {
vector<string> vec1 = {"hello", "world"};
vector<string> vec2;
vec2 = vec1; // using copy assignment
vec1.push_back("Sure hope vec2 doesn't see this!");
} // and vec2 never saw a thing
And now the question is: how to make two different assignment operator?
Answer: Overload vector::operator=
!
Introducing… the r-value reference using &&
R-VALUE REFERENCE
By using r-value reference, we can do this:
int main() {
int x = 1;
change(x); // this will call version 2
change(7); // this will call version 1
}
void change(int&& num) {...} // version 1 takes r-values
void change(int& num) {...} // version 2 takes l-values
// num is a reference to int
So, we should keep our copy assignment:
vector<T>& operator=(const vector<T>& other) {
if (&other == this) return *this;
_size = other._size;
_capacity = other._capacity;
// must **copy** entire array
delete[] _elems;
_elems = new T[other._capacity];
std::copy(other._elems, other._elems + other.size, _elems);
return *this;
}
And overload vector::operator=
(move assignment) like this:
vector<T>& operator=(vector<T>&& other) {
if (&other == this) return *this;
_size = other._size;
_capacity = other._capacity;
// we can **steal** the array
delete[] _elems;
_elems = other._elems;
return *this;
}
But actually, we still copy _size
and _capacity
, etc.
Introducing…std::move
!
std::move
std::move(x)
doesn’t do anything except cast x as an r-value- It is a way to force C++ to choose the
&&
version of a function
int main() {
int x = 1;
change(x); // this will call version 2
change(std::move(x)); // this will call version 1
}
void change(int&& num) {...} // version 1 takes r-values
void change(int& num) {...} // version 2 takes l-values
We can modify our move assignment like this:
vector<T>& operator=(vector<T>&& other) {
if (&other == this) return *this;
_size = std::move(other._size); // force move assignment
_capacity = std::move(other._capacity); // force move assignment
// we can **steal** the array
delete[] _elems;
_elems = std::move(other._elems); // force move assignment
return *this;
}
This works!
int main() {
vector<int> vec;
vec = make_me_a_vec(123); // this will use move assignment
vector<string> vec1 = {"hello", "world"};
vector<string> vec2;
vec2 = vec1; // this will use copy assignment
vec1.push_back("Sure hope vec2 doesn't see this!");
}
However, what if we wanted to declare and initialize a vec on the same line?
int main() {
vector<int> vec;
vec = make_me_a_vec(123); // this will use move assignment
vector<string> vec1 = {"hello", "world"};
vector<string> vec2 = vec1; // this will use copy constructor
vec1.push_back("Sure hope vec2 doesn't see this!");
}
Similarly, vector<string> vec1 = {"hello", "world"};
will use move constructor.
vector<T>(vector<T>&& other) {
if (&other == this) return *this;
_size = std::move(other._size);
_capacity = std::move(other._capacity);
// we can steal the array
delete[] _elems;
_elems = std::move(other._elems);
return *this;
}
Where else should we use std::move
?
Rule of Thumb: Wherever we take in a
const &
parameter in a class member function and assign it to something else in our function (TO BE CONTINUED)
For example:
// copy push_back
void push_back(const T& element) {
elems[_size++] = element;
// this is copy assignment
}
// move push_back
void push_back(T&& element) {
elems[_size++] = std::move(element);
// this forces T's move assignment
}
Be careful with std::move
int main() {
vector<string> vec1 = {"hello", "world"};
vector<string> vec2 = std::move(vec1);
vec1.push_back("Sure hope vec2 doesn't see this!"); // WRONG
}
Rule of Thumb: Wherever we take in a
const &
parameter in a class member function and assign it to something else in our function Don’t usestd::move
outside of class definitions, never use it in application code!
TLDR
-
If your class has copy constructor and copy assignment defined, you should also define a move constructor and move assignment
-
Define these by overloading your copy constructor and assignment to be defined for
Type&& other
as well asType& other
-
Use
std::move
to force the use of other types’ move assignments and constructors -
All
std::move(x)
does is castx
as an r-value -
By wary of
std::move(x)
in main function code!
PHILOSOPHY about SMFs
The 6 Special Member Functions
- Default constructor: Initializes an object to a default state
- Copy constructor: Creates a new object by copying an existing object
- Move constructor: Creates a new object by moving the resources of an existing object
- Copy Assignment Operator: Assigns the contents of one object to another object
- Move Assignment Operator: Moves the resources of one object to another object
- Destructor: Frees any dynamically allocated resources owned by an object when it is destroyed
Some Philosophy about SMFs
There are three guiding rules:
Rule of Zero
- If you can avoid defining default operations, do
- Why? It’s the simplest and gives the cleanest semantic
- Example: Since
std::map
andstd::string
have all the special functions, no further work is needed.
Class Named_map {
public:
// ...no default operations declared
private:
std::string name;
std::map<int, int> rep;
};
Named_map nm; // default construct
Named_map nm2{nm}; // copy construct
Rule of Three
- If you need to implement a custom destructor, you almost certainly need to define a copy constructor and copy assignment operator
- Why? You are probably managing your own memory somehow, so the shallow copies provided by the default operations won’t work correctly
Rule of Five
- If you define custom copy constructor/assignment operator, you should define move constructor/assignment operator as well
- Why? This is about efficiency rather than correctness. It’s inefficient to make extra copies (although it’s “correct”)