The claim that
unique_ptr performs as well as a raw pointer after optimization mostly applies only to the basic operations on a single pointer, such as creation, dereferencing, assignment of a single pointer and deletion. Those operations are defined simply enough that an optimizing compiler can usually make the required transformations such that the resulting code is equivalent (or nearly so) in performance to the raw version0.
One place this falls apart is especially higher level language-based optimizations on array-based containers such as
std::vector, as you have noted with your test. These containers usually use source level optimizations which depend on type traits to determine at compile time if a type can safely be copied using a byte-wise copy such as
memcpy, and delegate to such a method if so, or otherwise fall back to an element-wise copy loop.
To be safely copyable with
memcpy an object must be trivially copyable. Now
std::unique_ptr is not trivially copyable since indeed it fails several of the requirements such as having only trivial or deleted copy and move constructors. The exact mechanism depends on the standard library involved, but in general a quality
std::vector implementation will end up calling a specialized form of something like
std::uninitialized_copy for trivially-copyable types that just delegates to
The typical implementation details are quite tortured, but for
libstc++ (used by
gcc) you can see the high-level divergence in
template<typename _InputIterator, typename _ForwardIterator>
uninitialized_copy(_InputIterator __first, _InputIterator __last,
__uninit_copy(__first, __last, __result);
From there you can take my word that many of the
std::vector "movement" methods end up here, and that
__uninitialized_copy<true>::__uinit_copy(...) ultimately calls
memmove while the
<false> version doesn't - or you can trace through the code yourself (but you already saw the result in your benchmark).
Ultimately then, you end up with a several loops that perform the required copy steps for non-trivial objects, such as calling the move constructor of the destination object, and subsequently calling the destructor of all the source objects. These are separate loops and even modern compilers will pretty much not be able to reason about something like "OK, in the first loop I moved all the destination objects so their
ptr member will be null, so the second loop is a no-op". Finally, to equal the speed of raw pointers, not only would compilers need to optimize across these two loops, they would need to have a transformation which recognizes that the whole thing can be replaced by
So one answer to your question is that compilers just aren't smart enough to do this optimization, but it's largely because the "raw" version has a lot of compile-time help to skip the need for this optimization entirely.
As mentioned the existing
vector implementations implement a resize-type operation in two separate loops (in addition to non-loop work such as allocating the new storage and freeing the old storage):
- Copying the source objects into the newly allocated destination array (conceptually using something like placement new calling the move constructor).
- Destroying the source objects in the old region.
Conceptually you could imagine an alternative way: doing this all in one loop, copying each element and them immediately destroying it. It possible that a compiler could even notice that the two loops iterate over the same set of values and fuse the two loops into one. [Apparently], howevever, (https://gcc.gnu.org/ml/gcc/2015-04/msg00291.html)
gcc doesn't do any loop fusion today, and nor do
icc if you believe this test.
So then we are left trying to put the loops together explicitly at the source level.
Now the two-loop implementation helps preserve the exception safety contract of the operation by not destroying any source objects until we know the construction part of the copy has completed, but it also helps to optimize the copy and destruction when we have trivially-copyable and trivially-destructible objects, respectively. In particular, with simple-traits based selection we can replace the copy with a
memmove and the destruction loop can be elided entirely3.
So the two-loop approach helps when those optimizations apply, but it actually hurts in the general case of objects which are neither trivially copyable or destructible. It means you need two passes over the objects and you lose the opportunity to optimize and eliminate code between the copy of the object and it's subsequent destruction. In the
unique_ptr case you lose the ability for the compiler to propagate the knowledge that the source
unique_ptr will have a
ptr member and hence skip the
if (ptr) delete ptr check entirely4.
Now one might ask whether we could apply the same type-traits compile-time optimization to the
unique_ptr case. For example, one might look at the trivially copyable requirements and see that they are perhaps too strict for the common move operations in
std::vector. Sure, a
unique_ptr is evidently not trivially copyable since a bit-wise copy would leave both the source and destination object owing the same pointer (and result in double-deletion), but it seems that it should be bit-wise movable: if you move a
unique_ptr from one area of memory to another, such that you no longer consider the source as a live object (and hence won't call its destructor) it should "just work", for the typical
Unfortunately, no such "trivial move" concept exists, although you could try to roll your own. There seems to be an open debate about whether this is UB or not for objects that can be byte-wise copied and do not depend on their constructor or destructor behavior in the move scenario.
You could always implement your own trivially movable concept, which would be something like (a) the object has a trivial move constructor and (b) when used as the source argument of the move constructor the object is left in a state where it's destructor has no effect. Note that such a definition is currently mostly useless, since "trivial move constructor" (basically element-wise copy and nothing else) is not consistent with any modification of the source object. So for example, a trivial move constructor cannot set the
ptr member of the source
unique_ptr to zero. So you'd need to jump though some more hoops such as introducing the concept of a destructive move operation which leaves the source object destroyed, rather than in a valid-but-unspecified state.
You can find some more detailed discussion of this "trivially movable" on this thread on the ISO C++ usenet discussion group. In the particular, in the linked reply, the exact issue of vectors of
unique_ptr is addressed:
It turns out many smart pointers (unique_ptr and shared_ptr included)
fall into all three of those categories and by applying them you can
have vectors of smart pointers with essentially zero overhead over raw
pointers even in non-optimized debug builds.
See also the relocator proposal.
0 Although the non-vector examples at the end of your question show that this isn't always the case. Here it is due to possible aliasing as zneak explains in his answer. Raw pointers will avoid many of these aliasing issues since they lack the indirection that
unique_ptr has (e.g, you pass a raw pointer by value, rather than a structure with a pointer by reference) and can often omit the
if (ptr) delete ptr check entirely.
2 This is actually harder than you might think, because
memmove, for example, has subtly different semantics than an object copy loop, when the source and destination overlap. Of course the high level type traits code that works for raw points knows (by contract) that there is no overlap, or the behavior of
memmove is consistent even if there is overlap, but proving the same thing at some later arbitrary optimization pass may be much harder.
3 It is important to note that these optimizations are more or less independent. For example, many objects are trivially destructible that at are not trivially copyable.
4 Although in my test neither
clang were able to suppress the check, even with
__restrict__ applied, apparently due to insufficiently powerful aliasing analysis, or perhaps because
std::move strips the "restrict" qualifier somehow.