We consider the goal of creating two different types, using the exact same syntax. This can be easily done with lambdas:

auto x = []{};
auto y = []{};
static_assert(!std::is_same_v<decltype(x), decltype(y)>);

But instead of using lambdas, we are looking for another, more elegant syntax. Here are some tests. We start by defining some tools:

#include <iostream>
#include <type_traits>
#define macro object<decltype([]{})>
#define singleton object<decltype([]{})>

constexpr auto function() noexcept
    return []{};

template <class T = decltype([]{})>
constexpr auto defaulted(T arg = {}) noexcept
    return arg;

template <class T = decltype([]{})>
struct object
    constexpr object() noexcept {}

template <class T>
struct ctad
    template <class... Args>
    constexpr ctad(const Args&...) noexcept {}

template <class... Args>
ctad(const Args&...) -> ctad<decltype([]{})>;

and the following variables:

// Lambdas
constexpr auto x0 = []{};
constexpr auto y0 = []{};
constexpr bool ok0 = !std::is_same_v<decltype(x0), decltype(y0)>;

// Function
constexpr auto x1 = function();
constexpr auto y1 = function();
constexpr bool ok1 = !std::is_same_v<decltype(x1), decltype(y1)>;

// Defaulted
constexpr auto x2 = defaulted();
constexpr auto y2 = defaulted();
constexpr bool ok2 = !std::is_same_v<decltype(x2), decltype(y2)>;

// Object
constexpr auto x3 = object();
constexpr auto y3 = object();
constexpr bool ok3 = !std::is_same_v<decltype(x3), decltype(y3)>;

// Ctad
constexpr auto x4 = ctad();
constexpr auto y4 = ctad();
constexpr bool ok4 = !std::is_same_v<decltype(x4), decltype(y4)>;

// Macro
constexpr auto x5 = macro();
constexpr auto y5 = macro();
constexpr bool ok5 = !std::is_same_v<decltype(x5), decltype(y5)>;

// Singleton
constexpr singleton x6;
constexpr singleton y6;
constexpr bool ok6 = !std::is_same_v<decltype(x6), decltype(y6)>;

and the following test:

int main(int argc, char* argv[])
    // Assertions
    static_assert(ok0); // lambdas
    //static_assert(ok1); // function
    static_assert(ok2); // defaulted function
    static_assert(ok3); // defaulted class
    //static_assert(ok4); // CTAD
    static_assert(ok5); // macro
    static_assert(ok6); // singleton (macro also)

    // Display
    std::cout << ok1 << std::endl;
    std::cout << ok2 << std::endl;
    std::cout << ok3 << std::endl;
    std::cout << ok4 << std::endl;
    std::cout << ok5 << std::endl;
    std::cout << ok6 << std::endl;

    // Return
    return 0;

this is compiled with the current trunk version of GCC, with options -std=c++2a. See result here in compiler explorer.

The fact that ok0, ok5 and ok6 work are not really a surprise. However, the fact that ok2 and ok3 are true while ok4 is not is very surprising to me.

  • Could someone provide an explanation of the rules that make ok3 true but ok4 false?
  • Is it really how it should work, or this is a compiler bug concerning an experimental feature (lambdas in unevaluated contexts)? (reference to the standard or to C++ proposals are very welcomed)

Note: I really hope this is a feature and not a bug, but just because it makes some crazy ideas implementable

  • 17
    Tosses upvote and runs away – Quentin Apr 2 at 13:01
  • 2
    As far as I know, this is how it is intended. Default arguments are applied in the context of the caller; therefore each call site has a different lambda an thus a different type. ctad has no default argument. The single Landa definition is same. I'd be curious whether it is the same when the template arguments differ. – eerorika Apr 2 at 13:10
  • 6
    eel.is/c++draft/temp.arg#8 almost gives you an answer for ok2/ok3, for CTAD, there is a single definition of the constructor, so a single instantiation of the decltype([]{}). – Holt Apr 2 at 13:12
  • 3
    hmmm... almost look like another way to do compile time stateful programming – Guillaume Racicot Apr 2 at 13:26
  • 5
    I believe you're in violation of eel.is/c++draft/temp.res#8.5, but I'm not sure. – Rakete1111 Apr 2 at 14:15

for ok2 function parameter type (T) depends on specified template parameter. for ok3 ctor is not a template.

for ok4 both deductions depend on same parameter type list (which is empty in this case) and due to that deduction occurs only once. template instantiation and deduction are different things. while for same parameter type list deduction occurs only once, instantiation occurs for all usages.

look this code (https://godbolt.org/z/ph1Wk2). if parameters are different for deduction, seperate deductions occur.

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  • 1
    Since the question is tagged language-lawyer, could you give some references to the standard. Maybe a quote on "deduction occurs only once"? – HolyBlackCat 2 days ago

If we compile with clang :

error: lambda expression in an unevaluated operand
template <class T = decltype([]{})>

More read here : Why are lambda expressions not allowed in an unevaluated operands but allowed in the unevaluated portions of constant expressions?

So, even I am not a language layer, I would say : it's not (valid) C++

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