I created this class so I could have a value of any type which is either fixed or recalculated everytime it's used:

template<typename T>
class Value {
    bool fixed;
    union {
        T value;
        std::function<T()> get;
    Value(const T& value) : fixed(true), value(value) {}
    Value(const std::function<T()>& get) : fixed(false), get(get) {}
    Value(const T *pointer) : Value([pointer]() { return *pointer; }) {}
    ~Value() {}
    operator T() { return fixed ? value : get(); }

All the following expressions seem to work fine:

Value<double> a = 2.2;
double b = 1.;
double c = a;
Value<double> d = &b;
Value<int> e = Value<int>([]() { return 1.; });

But when I try to do:

Value<double> f = []() { return 1.; };

a compilation error is triggered:

error: conversion from 'main()::<lambda()>' to non-scalar type 'Value<double>' requested

You can try this example here.

Why does assigning work for T and not std::function<T()> and how can I make it so it does?

Note: I'm aware of this answer but I didn't become clear to me how to fix the issue without having to explicitly call the constructor like I did for Value<double> e.

  • @SilvioMayolo Just added a link to the platform I'm testing this on. Dec 7, 2020 at 17:14
  • in your godbolt link the line reads Value<int> e = Value<int>([]() { return 1; }); while the one here Value<double> e = Value<int>([]() { return 1.; }); is an error Dec 7, 2020 at 17:16
  • @largest_prime_is_463035818 Should be fixed. I converted everything to doubles to simplify the question but forgot to change it on godbolt. Dec 7, 2020 at 17:19
  • you could write auto f = Value<int>([]() { return 1; }); If you are worried about spelling out the type twice. Its basically the same, and works ;) Dec 7, 2020 at 17:20
  • I'd suggest replacing the innards of this class with std::variant. Also, for the first two constructors, since Value wants to "takes ownership of" (i.e. saves) the argument, you should make the arguments by-value (no reference qualifier) and std::move them into the data members. That way, the caller controls whether to copy or to move, instead of you forcing a copy.
    – HTNW
    Dec 7, 2020 at 17:26

2 Answers 2


Why does assigning work for T and not std::function<T()> and how can I make it so it does?

Your code does not use assignment, but copy initialization and

In addition, the implicit conversion in copy-initialization must produce T directly from the initializer, while, e.g. direct-initialization expects an implicit conversion from the initializer to an argument of T's constructor.

So to make it work you have to make your ctor to accept lambda directly (this is simplified example):

template<typename T>
class Value {
    std::function<T()> get;    
    template<class Y>
    Value(Y lambda ) : get( std::move( lambda ) )  {}

live code You probably want to add restriction using std::enable_if or concept if C++20 is allowed to this ctor as well as in this form this constructor would try to accept everithing other overloads would not and may produce cryptic errrors. And according to this enable_if template param is lambda (with particular signature) it could be as simple as

template<class Y, typename = decltype(std::declval<Y&>()())>
Value(Y lambda ) : get( std::move( lambda ) )  {}

which supports C++14. Here is yet another live example where you can see that this constructor is not used for initializer of type int:

 Value<double> d2 = 123;

prog.cpp:9:5: note: candidate template ignored: substitution failure [with Y = int]: called object type 'int' is not a function or function pointer Value(Y lambda ) : get( std::move( lambda ) ) {}


A lambda is not a std::function. That means when you do

Value<double> f = []() { return 1.; };

you need to convert []() { return 1.; } into a std::function, which is a user defined conversion, and then you need to convert that std::function into a Value<double>, which is another user defined conversion. That's two user defined conversion when you are only ever allowed up to one such conversion. This is why the code fails to compile.

  • You can get around it by using the other constructor syntax Value<double> f { []() { return 1.; } };, which counts as an explicit constructor call and therefore not an extra conversion. Dec 7, 2020 at 17:19
  • Can I make it work by modifying the class though? Dec 7, 2020 at 17:20
  • @SilvioMayolo Yes, with that you have one user defined conversion from the lambda type to a std::function, and then that std::function object is used for the direct initialization. Dec 7, 2020 at 17:20
  • @cabralpinto You can. You would need to add a template constructor to Value that takes any type of callable. That would let you take the lambda as is, and then you'd be okay. Dec 7, 2020 at 17:21
  • Is it possible you can edit your answer to show those changes? I'm quite new to C++ and am still trying to figure out templates. Dec 7, 2020 at 17:23

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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