I just watched Stephan T. Lavavej talk at CppCon 2018 on "Class Template Argument Deduction", where at some point he incidentally says:

In C++ type information almost never flows backwards ... I had to say "almost" because there's one or two cases, possibly more but very few.

Despite trying to figure out which cases he might be referring to, I couldn't come up with anything. Hence the question:

In which cases the C++17 standard mandates that type information propagate backwards?

  • pattern matching partial specialization and destructuring assignments. – v.oddou Nov 13 at 5:11
up vote 77 down vote accepted

Here is at least one case:

struct foo {
  template<class T>
  operator T() const {
    std::cout << sizeof(T) << "\n";
    return {};

if you do foo f; int x = f; double y = f;, type information will flow "backwards" to figure out what T is in operator T.

You can use this in a more advanced way:

template<class T>
struct tag_t {using type=T;};

template<class F>
struct deduce_return_t {
  F f;
  template<class T>
  operator T()&&{ return std::forward<F>(f)(tag_t<T>{}); }
template<class F>

auto construct_from( Args&&... args ) {
  return deduce_return_t{ [&](auto ret){
    using R=typename decltype(ret)::type;
    return R{ std::forward<Args>(args)... };

so now I can do

std::vector<int> v = construct_from( 1, 2, 3 );

and it works.

Of course, why not just do {1,2,3}? Well, {1,2,3} isn't an expression.

std::vector<std::vector<int>> v;
v.emplace_back( construct_from(1,2,3) );

which, admittedly, require a bit more wizardry: Live example. (I have to make the deduce return do a SFINAE check of F, then make the F be SFINAE friendly, and I have to block std::initializer_list in deduce_return_t operator T.)

  • Very interesting answer, and I learned a new trick so thank you very much! I had to add a template deduction guideline to make your example compile, but other than that it works like a charm! – Massimiliano Nov 12 at 22:28
  • 5
    The && qualifier on the operator T() is a great touch; it helps avoid the poor interaction with auto by causing a compilation error if auto is misused here. – Justin Nov 12 at 22:42
  • 1
    That's very impressive, could you point me to some reference/talk to the idea in the example? or maybe it's original :) ... – liliscent Nov 12 at 23:59
  • 3
    @lili Which idea? I count 5: Using operator T to deduce return types? Using tags to pass the deduced type to a lambda? Using conversion operators to roll-your-own placement object construction? Connecting all 4? – Yakk - Adam Nevraumont Nov 13 at 0:13
  • 1
    @lili Tha "more advanced way" example is, as I said, just 4 or so ideas glued together. I did the gluing on the fly for this post, but I certainly have seen many pairs or even triplets of those used together. It is a bunch of reasonably obscure techniques (as tootsie complains), but nothing novel. – Yakk - Adam Nevraumont Nov 13 at 2:26

Stephan T. Lavavej explained the case he was talking about in a tweet:

The case I was thinking of is where you can take the address of an overloaded/templated function and if it’s being used to initialize a variable of a specific type, that will disambiguate which one you want. (There’s a list of what disambiguates.)

we can see examples of this from cppreference page on Address of overloaded function, I have excepted a few below:

int f(int) { return 1; } 
int f(double) { return 2; }   

void g( int(&f1)(int), int(*f2)(double) ) {}

int main(){
    g(f, f); // selects int f(int) for the 1st argument
             // and int f(double) for the second

     auto foo = []() -> int (*)(int) {
        return f; // selects int f(int)

    auto p = static_cast<int(*)(int)>(f); // selects int f(int)

Michael Park adds:

It's not limited to initializing a concrete type, either. It could also infer just from the number of arguments

and provides this live example:

void overload(int, int) {}
void overload(int, int, int) {}

template <typename T1, typename T2,
          typename A1, typename A2>
void f(void (*)(T1, T2), A1&&, A2&&) {}

template <typename T1, typename T2, typename T3,
          typename A1, typename A2, typename A3>
void f(void (*)(T1, T2, T3), A1&&, A2&&, A3&&) {}

int main () {
  f(&overload, 1, 2);

which I elaborate a little more here.

  • 4
    We could also describe this as: cases where the type of an expression depends on the context? – M.M Nov 12 at 23:56

I believe in static casting of overloaded functions the flow goes the opposite direction as in usual overload resolution. So one of those is backwards, I guess.

  • 6
    I believe this is correct. And it is when you pass a function name to a function pointer type; type information flows from the context of the expression (the type you are assigning to/constructing/etc) backwards into the name of the function to determine which overload is chosen. – Yakk - Adam Nevraumont Nov 12 at 22:08

Your Answer

By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.