References differ from pointers in that there are things you cannot do to a reference and have it be defined behavior.
You cannot take the address of a reference, but only what is referred to. You cannot modify a reference once it is created.
A T&
and a T*const
(note that const
applies to the pointer, not the pointed-to, there) are relatively similar. Taking the address of an actual const
value and modifying it is undefined behavior, as is modifying (any storage that it uses directly) a reference.
Now, in practice, you can get a the storage of a reference:
struct foo {
int& x;
};
sizeof(foo)
will almost certainly equal sizeof(int*)
. But the compiler is free to neglect the possibility that someone directly accessing the bytes of foo
could actually change the value referred to. This permits the compiler to read the reference "pointer" implementation once, and then never read it again. If we had struct foo{ int* x; }
the compiler would have to prove each time it did a *f.x
that the pointer value had not changed.
If you had struct foo{ int*const x; }
is again starts behaving reference-like in its immutability (modifying something that was declared const
is UB).
A trick that I'm not aware of any compiler writers using is to compress reference-capture in a lambda.
If you have a lambda that captures data by reference, instead of capturing each value via a pointer, it could capture only the stack frame pointer. The offsets to each local variable are compile-time constants off the stack frame pointer.
The exception is references captured by reference, which under a defect report to C++ must remain valid even if the reference variable goes out of scope. So those have to be captured by pseudo-pointer.
For a concrete example (if a toy one):
void part( std::vector<int>& v, int left, int right ) {
std::function<bool(int)> op = [&](int y){return y<left && y>right;};
std::partition( begin(v), end(v), op );
}
the lambda above could capture only the stack frame pointer, and know where left
and right
are relative to it, reducing it size, instead of capturing two int
s by (basically pointer) reference.
Here we have references implied by [&]
whose existence is eliminated easier than if they where pointers captured by value:
void part( std::vector<int>& v, int left, int right ) {
int* pleft=&left;
int* pright=&right;
std::function<bool(int)> op = [=](int y){return y<*pleft && y>*pright;};
std::partition( begin(v), end(v), op );
}
There are a few other differences between references and pointers.
A reference can extend the lifetime of a temporary.
This is used heavily in for(:)
loops. Both the definition of the for(:)
loop relies on reference lifetime extension to avoid needless copies, and users of for(:)
loops can use auto&&
to automatically deduce the lightest weight way to wrap the iterated objects.
struct big { int data[1<<10]; };
std::array<big, 100> arr;
arr get_arr();
for (auto&& b : get_arr()) {
}
here reference lifetime extension carefully prevents needless copies from ever occuring. If we change make_arr
to return a arr const&
it continues to work without any copies. If we change get_arr
to return a container that returns big
elements by-value (say, an input iterator range), again no needless copies are done.
This is in a sense syntactic sugar, but it allows the same construct to be optimal in many cases without having to micro-optimize based on how things are returned or iterated over.
Similarly, forwarding references allow data to be treated as a const, non-const, lvalue or rvalue intelligently. Temporaries are marked as temporaries, data that users have no further need for is marked as temporary, data that will persist is marked as being an lvalue reference.
The advantage references have over non-references here is that you can form a rvalue reference to a temporary, and you cannot form a pointer to that temporary without passing it through an rvalue reference-to-lvalue reference conversion.
a call-by-pointer involves a copy anyway, and that seems to be true about a call-by-reference as well. The underlying mechanism appears to be the same