I want to write a C++ class with such a definition:

template <typename T, std::size_t A = 0>
struct Counter {
    static constexpr inline std::size_t valueOfA = A;

    T value;

I want to have a member function addOne(), such that it consumes itself, e.g. Counter<0> and returns itself but of a type where its type parameter is the sum of 1 and its previous type argument, e.g. Counter<1>. Simply put, Counter<1> Counter<0>.addOne().

addOne() should also consume itself such that all variables referencing to Counter<A> should not be valid variables after addOne() is called.


The compiler error I got this:

x86-64 clang 15.0.0
x86-64 clang 15.0.0
<Compilation failed>

# For more information see the output window
x86-64 clang 15.0.0 - 1285ms
<source>:32:16: error: no viable conversion from returned value of type 'Counter<[...], 0>' to function return type 'Counter<[...], 0UL + 1 aka 1>'
        return *this;

EDIT: Some have asked for 1. a minimal reproducible example and 2. a reason for wanting to do something like that.

  1. Minimal Reproducible Example (in fact, I am giving the full concrete example)
#include <iostream>
#include <tuple>
#include <type_traits>
#include <utility>

template <std::size_t A>
struct AddOne {
    static constexpr inline std::size_t value = A + 1;

template <std::size_t A, std::size_t B>
struct IsALesserThanB : std::integral_constant<bool, A < B> {};

template <typename T, std::size_t MEC, std::size_t EC = 0>
class Secret {
    T value;

    template <std::size_t NewEC=AddOne<EC>::value>
    constexpr inline Secret(
        Secret<T, MEC, EC>&& this_secret) {
        T value_ = std::move(this_secret.value);
        return Secret {
            .value = value_,


    Secret(T initialValue) : value(std::move(initialValue)) {}

    template <
        typename Closure,
        typename = std::enable_if_t<std::conjunction_v<
            std::is_invocable<Closure, const T&>, IsALesserThanB<EC, MEC>>>>
    [[nodiscard]] constexpr inline std::tuple<
        std::invoke_result_t<Closure, const T&>, Secret<T, MEC, EC + 1>>
    exposeSecret(Closure closure) const noexcept {
        Secret<T, MEC, EC + 1> new_secret{std::move(*this)};
        return {closure(value), new_secret};

int main() {
    Secret<double, 3, 2> secretString{std::move(69.69)};

    auto length =
        secretString.exposeSecret([](const double& s) { return "69"; });

    std::cout << std::get<0>(length) << std::endl;

    return 0;
  1. The Reason I want to create a type Secret<T, MEC, EC> in C++, such that whenever expose_secret() is called more than MEC times, it can no longer be called and the program cannot compile.

expose_secret() should also consume Secret<T, MEC, EC> (MEC: maximum exposed count, EC: exposed count) with each invocation of expose_secret() with std::move.

  • 1
    Please include a minimal reproducible example inline in your question! Dec 2, 2023 at 15:51
  • Suppose you got your example to compile - what output do you expect from it? Since you print counter.valueOfA before and after, it appears you expect it to change - but it can't possibly change, it's constexpr. Dec 2, 2023 at 16:11
  • I find this whole idea bizarre. What's the point of it? Dec 2, 2023 at 16:24
  • returns itself but of a type where its type parameter is the sum of 1 ... -- you cannot change the type of an oject at runtime. You ca only construct a new object of a different type.
    – chrysante
    Dec 2, 2023 at 16:33
  • 1
    @PaulSanders, updated my post with a more concrete example and an explanation of why I am doing this.
    – Jim
    Dec 2, 2023 at 16:51

1 Answer 1


Well, stripping this down to the bare essentials, the solution is easy enough:

#include <iostream>

template <std::size_t A = 0>
struct Counter {

    auto AddOne ()
        static_assert (A < 100, "A is >= 100");
        assert (valid);
        valid = false;
        return Counter <A + 1> { };

    bool valid = true;

int main ()
    Counter c0;
    auto c1 = c0.AddOne ();             // static_assert ok here

    Counter <100> c100;
    auto c101 = c100.AddOne ();         // static_assert fails here

But I don't see this as being particularly useful, because each time AddOne() is called, it returns an object with a new type, so you can't keep track of how many times AddOne() has been called using just a single object.

If you drop the requirement for a compile-time check, this problem can be avoided.

  • Hi @paul, thank you for your response. Would you mind showing if Counter holds an inner value then how would you go about moving that inner value from Counter<A> to Counter<A+1>?
    – Jim
    Dec 3, 2023 at 2:55
  • I would copy it (in AddOne), to the object that is about to be returned. No need to move it, unless it is a type that defines a move assignment operator, in which case moving it would be more efficient than copying. Dec 3, 2023 at 19:33

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