P0137 introduces the function template std::launder and makes many, many changes to the standard in the sections concerning unions, lifetime, and pointers.

What is the problem this paper is solving? What are the changes to the language that I have to be aware of? And what are we laundering?

  • 2
    Are you asking about the paper itself or about std::launder? std::launder is used to "obtain a pointer to an object created in storage occupied by an existing object of the same type, even if it has const or reference members." – txtechhelp Sep 8 '16 at 4:25
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    useful link on the subject. Also this question stackoverflow.com/questions/27003727/… – Paul Rooney Sep 8 '16 at 4:30
  • This has now been released in VC2017 in version 15.7.0 – Damian May 8 at 0:47
up vote 174 down vote accepted

std::launder is aptly named, though only if you know what it's for. It performs memory laundering.

Consider the example in the paper:

struct X { const int n; };
union U { X x; float f; };

U u = {{ 1 }};

That statement performs aggregate initialization, initializing the first member of U with {1}.

Because n is a const variable, the compiler is free to assume that u.x.n shall always be 1.

So what' happens if we do this:

X *p = new (&u.x) X {2};

Because X is trivial, we need not destroy the old object before creating a new one in its place, so this is perfectly legal code. The new object will have its n member be 2.

So tell me... what will u.x.n return?

The obvious answer will be 2. But that's wrong, because the compiler is allowed to assume that a truly const variable (not merely a const&, but an object variable declared const) will never change. But we just changed it.

[basic.life]/8 spells out the circumstances when it is OK to access the newly created object through variables/pointers/references to the old one. And having a const member is one of the disqualifying factors.

So... how can we talk about u.x.n properly?

We have to launder our memory:

assert(*std::launder(&u.x.n) == 2); //Will be true.

Money laundering is used to prevent people from tracing where you got your money from. Memory laundering is used to prevent the compiler from tracing where you got your object from, thus forcing it to avoid any optimizations that may no longer apply.

Another of the disqualifying factors is if you change the type of the object. std::launder can help here too:

aligned_storage<sizeof(int), alignof(int)>::type data;
new(&data) int;
int *p = std::launder(reinterpret_cast<int*>(&data));

[basic.life]/8 tells us that, if you allocate a new object in the storage of the old one, you cannot access the new object through pointers to the old. launder allows us to side-step that.

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    So is my tl;dr correct: "laundering is basically for non-UB type punning"? – druckermanly Sep 8 '16 at 5:16
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    Could you explain why this is true? "Because n is a const variable, the compiler is free to assume that u.x.n shall always be 1." Where in the standard does it say that? I ask because the very problem you pointed out would seem to imply to me that it is false in the first place. It should only be true under the as-if rule, which fails here. What am I missing? – Mehrdad Sep 8 '16 at 8:39
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    How much can we sidestep that aliasing rule? Like template <class T, class U> T* alias_cast(U* ptr) { return std::launder(reinterpret_cast<T*>(ptr)); } How UB is that? – Barry Sep 8 '16 at 13:49
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    @Barry Very; if there's no objects of type T located at the address ptr represents, then you break launder's precondition, so there's no point talking about the outcome. – T.C. Sep 8 '16 at 17:52
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    @NicolBolas One can only hope supercat does as much lobbying of the Committees as they do endlessly demanding answers from fellow third-party language users on SO. Besides, a good optimising compiler will optimise your correct solution of memcpy into an in-place reinterpretation on supported (i.e. lax alignment) platforms anyway. – underscore_d Sep 12 '16 at 8:59

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