The call to
v.insert is calling a member function of the container. The member function knows how the container is implemented, so it can do things that a more generic algorithm can't do. In particular, when inserting a range of values designated by random-access iterators into a vector, the implementation knows how many elements are being added, so it can resize the internal storage once and then just copy the elements.
The call to
std::copy with an insert-iterator, on the other hand, has to call
insert for each element. It can't preallocate, because
std::copy works with sequences, not containers; it doesn't know how to adjust the size of the container. So for large insertions into a vector the internal storage gets resized each time the vector is full and a new insertion is needed. The overhead of that reallocation is amortized constant time, but the constant is much larger than the constant when only one resizing is done.
With the call to
reserve (which I overlooked, thanks, @ChrisDrew), the overhead of reallocating is not as significant. But the implementation of
insert knows how many values are being copied, and it knows that those values are contiguous in memory (because the iterator is a pointer), and it knows that the values are trivially copyable, so it will use
std::memcpy to blast the bits in all at once. With
std::copy, none of that applies; the back inserter has to check whether a reallocation is necessary, and that code can't be optimized out, so you end up with a loop that copies an element at a time, checking for the end of the allocated space for each element. That's much more expensive than a plain
In general, the more the algorithm knows about the internals of the data structure that it's accessing, the faster it can be. STL algorithms are generic, and the cost of that genericity can be more overhead than a that of a container-specific algorithm.