I am fairly new to meta programming and I am trying to create a factory singleton that creates cloneable objects. To this end I have the following code which I have also shared in live coliru

The thing I am trying to achieve (and it is not included in the code in the coliru link) is to constrain the factory to only allow its typename T to ICloneable interfaces.

This ICloneable interface is defined as follows:

template <typename T>
class ICloneable {
    virtual std::unique_ptr<T> clone() const = 0;

The code to instantiate the factory is shown below.

The closest answer that I can see is factory of templated class. I was thinking that something along the lines of type traits would be helpful - like std::is_same_v - but I have no experience with these meta programming techniques.

int main()
    auto protoType = std::make_unique<Widget>(1,2);
    const auto gpFactory = Factory<Widget>::getInstance();
    gpFactory->registerType(std::move(protoType), 32u);
    auto cloned = gpFactory->getClone(32u);
    std::cout << *cloned;
    return 0;

closed as off-topic by Barry, Yakk - Adam Nevraumont, Ulrich Eckhardt, L. F., Don'tDownVote Jun 13 at 11:35

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  • "Questions seeking debugging help ("why isn't this code working?") must include the desired behavior, a specific problem or error and the shortest code necessary to reproduce it in the question itself. Questions without a clear problem statement are not useful to other readers. See: How to create a Minimal, Reproducible Example." – Barry, Yakk - Adam Nevraumont, Ulrich Eckhardt, L. F., Don'tDownVote
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  • 1
    For the first error I think you need to remove const here: const auto& gFactory = Factory<Widget>::getInstance(); you are modifying gFactory with gFactory.registerType(protoType, 32u). – drescherjm Jun 12 at 19:06
  • 2
    Please provide a minimal reproducible example, with all the relevant code in the question. – Barry Jun 12 at 19:14
  • 1
    You should really fix all the unrelated compile errors (e.g. trying to copy a unique_ptr instead of moving it) before posting a question. I was going to write an answer, but with that many unrelated errors I can't even work on the problem you want to fix. – Pezo Jun 12 at 19:23
  • Thanks I just fixed the compilation issues and reworked the question to focus on the meta-programming aspects – johnco3 Jun 12 at 19:39

The first problem is gFactory is a const&. registerType is a non-const method.

auto& gFactory = Factory<Widget>::getInstance();

to fix that.

gFactory.registerType(protoType, 32u);

registerType is expecting a unique_ptr<Widget>. You are passing in a unique_ptr<Widget>, but you are trying to copy it.

You cannot copy a unique_ptr.

gFactory.registerType(std::move(protoType), 32u);

Next, a missing argument and similar problem here:

  const auto& [iter, inserted] = mFactoryRegInfo.try_emplace(rkey, std::move(protoType));

and you discard a nodiscard argument in main.

Live example.

Requiring ICloneable<T> is actually considered an anti-pattern in generic code.

template<class T, class C=std::unique_ptr<T>>
struct can_clone:std::false_type{};

template<class T>
struct can_clone<T, decltype( std::declval<T const&>().clone() )>:std::true_type {};

template <typename T,
  std::enable_if_t< can_clone<T>{}, bool > = true
class Factory final {
    //! Thread safe singleton pattern
    static Factory& getInstance() {
        static std::unique_ptr<Factory> pInstance = std::make_unique<Factory>(token{0});
        return *pInstance;

    //! Registers a new cloneable type in the factory.
    [[nodiscard]] bool registerType(std::unique_ptr<T> protoType, const uint32_t rkey) {
        // Critical Section
        std::lock_guard<std::mutex> lock(MutexGuard);
        const auto& [iter, inserted] = mFactoryRegInfo.try_emplace(rkey, std::move(protoType));
        return inserted;

    //! Factory function - returns newly cloned unique_ptr<T>.
    [[nodiscard]] std::unique_ptr<T> getClone(const uint32_t rkey) const {
        // Critical Section
        std::lock_guard<std::mutex> lock(MutexGuard);
        const auto& iter = mFactoryRegInfo.find(rkey);
        if (iter != mFactoryRegInfo.end()) {
            return iter->second->clone();
        return nullptr;

    //! C.67: A polymorphic class should suppress copying.
    Factory(const Factory&) = delete;
    Factory(Factory&&) noexcept = delete;
    Factory& operator=(const Factory&) = delete;
    Factory& operator=(Factory&&) noexcept = delete;

    //! Defaulted destructor.
    ~Factory() = default;
    //! Singleton private constructor.
    Factory() = default;
    struct token { explicit token(int){} };
    explicit Factory(token):Factory() {}

    // UUID (uint32_t) to T mapping
    std::map<uint32_t, std::unique_ptr<T>> mFactoryRegInfo{};

    mutable std::mutex MutexGuard;

this simply requires T have a T::clone() const method that supports returns unique_ptr<T>.

An improvement would be to require that it return a type convertible to unique_ptr<T>.

Also note I cleaned up your singleton code. As a note, you shouldn't mix singleton code with functional code; there can be plenty of reasons to have more than one Factory<Bob> in the same code base, from unit testing to wanting document-specific object factories.

Singleton, if needed, can be implemented as a separate bit of template metaprogramming.

This will save your life when you realize that singleton lifetime gets insanely more complex when you mix dynamic library loading in.

Live example.

  • Thanks! I think I was fixing the code in the background after a const hint from @drescherjm - the question has been edited to focus on the real problem of meta programming now – johnco3 Jun 12 at 19:41
  • This doesn't answer the original question though, how to constrain the Factory template parameter to types implementing ICloneable. – Pezo Jun 12 at 19:41
  • I agree - that is what I just commented – johnco3 Jun 12 at 19:43
  • @Pezo The question was edited as I was answering it. – Yakk - Adam Nevraumont Jun 12 at 19:57
  • @Yakk-AdamNevraumont yikes - your second example is a bit of black magic. I'm running down many rabbit holes trying to understand it. I'm not sure what the whole token thing is about (looks like a way of using unique ptr for the factory instance), and I am curious as to how to implemented the singleton via meta-programming as you indicated. – johnco3 Jun 12 at 20:59

You can use a static assertion like this inside Factory to make sure T implements ICloneable<T>:

static_assert(std::is_convertible<T*, ICloneable<T>*>::value, "T must implement ICloneable<T>");

Live example

Note that although there is the std::is_base_of trait, std::is_convertible is indeed the right type trait to use in this case. To quote cppreference:

std::is_base_of<A, B>::value is true even if A is a private, protected, or ambiguous base class of B. In many situations, std::is_convertible<B*, A*> is the more appropriate test.

  • that works thanks, why the pointer semantics in the 'std::is_convertible'? It also works with 'std::is_convertible<T, ICloneable<T>>::value' – johnco3 Jun 12 at 19:58
  • 1
    Because you do polymorphism by pointer or reference. Didn't work for me without the pointer... – Pezo Jun 12 at 20:04
  • I stand corrected! I missed an error when I removed the pointers – johnco3 Jun 12 at 20:10
  • actually, I think std::is_base_of might be a better choice as it exploits the 'is a' relationship in which case the pointer trick is not necessary. coliru.stacked-crooked.com/a/534fd9a282bf2740 – johnco3 Jun 13 at 1:24
  • No it's not, I extended my answer accordingly (at least in the case of your original question). For checking that you passed the right template argument to ICloneable I'm not quite sure, it may be more appropriate there. – Pezo Jun 13 at 5:43

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