I'm writing a function which I want to accept a distribution as a parameter. Let's say the following:

using namespace std;

random_device rd;
mt19937 gen(rd());

void print_random(uniform_real_distribution<>& d) {
    cout << d(gen);

Now is there a way to generalise this code, in a short way, in C++ such that it would accept all distributions and distributions only (otherwise the compiler should complain)? Edit: To clarify, the solution should also be able to accept only a subset of all distributions (which would have to be pre-specified).

I would for example accept the ability to define a type as a collection of allowed types but it would be even better if there is already a type which has this property for distributions.

  • If you accept all distributions, you would have to ensure that the type is valid for the distribution, otherwise it's undefined behavior.
    – user3920237
    Dec 15, 2014 at 11:40
  • 1
    @remyabel What type? I thought all distributions can use a standard generator like mt19937.
    – Chris Drew
    Dec 15, 2014 at 12:10
  • What is your definition of "distributions only". In my mind anything that satisfies the implicit interface of a distribution is a distribution.
    – Chris Drew
    Dec 15, 2014 at 12:12
  • @ChrisDrew I added that because I do not want to accept non-distribution types, if you accept all types you also accept distributions but that's not what I want. It would be fine if it accepts only types which satisfy the implicit interface of a distribution, e.g. something which accepts a random number generator and outputs a number.
    – Haffi112
    Dec 15, 2014 at 13:12

3 Answers 3


There is no such traits in standard library. You can just write something like

template<typename T>
struct is_distribution : public std::false_type {};

and specialize for each type, that is distribution

template<typename T>
struct is_distribution<std::uniform_int_distribution<T> > :
public std::true_type {};

Then just

template<typename Distr>
typename std::enable_if<is_distribution<Distr>::value>::type 
print_random(Distr& d)
    cout << d(gen);

Also, you can use something like concepts-lite (but with decltypes, since there is no this feature now), it can not work in some cases. In standard there are rules, that should any distribution follow (n3376 118).

template<typename D>
constexpr auto is_distribution(D& d) ->
decltype(std::declval<typename D::result_type>(),
std::declval<typename D::param_type>(),
d.reset(), d.param(), d.param(std::declval<typename D::param_type>()), true);

template<typename D>
auto print_random(D& d) -> decltype(is_distribution(d), void())

If you want just check that type is callable with some generator and execution of this call returns result_type you can just simplify function

template<typename D>
auto is_distribution(D& d) ->
decltype(std::is_same<typename D::result_type,

all this things will be much simple, when concepts-lite will be available in standard.

  • except it would be d(gen) :-) Dec 15, 2014 at 11:43
  • Ok, thanks, this is very useful but rather ugly :( I would prefer a shorter/clearer way of achieving this.
    – Haffi112
    Dec 15, 2014 at 11:44
  • 5
    @Haffi112 Yeah, C++ really isn't about being short and clear. Dec 15, 2014 at 13:54

I would just do:

template<typename Distribution>
void print_random(Distribution& d) {
    cout << d(gen);

Anything that doesn't satisfy the implicit interface for a distribution will not compile. i.e it must have an operator() that takes a generator as a parameter and returns a value.

  • This solution is more concise but it does not solve the problem of defining a type as a subset of allowed types.
    – Haffi112
    Dec 15, 2014 at 13:21
  • 1
    Sorry, I must have misunderstood you question. You stated you want it to accept "all distributions". Do you want it to only accept some distributions?
    – Chris Drew
    Dec 15, 2014 at 13:28
  • The code above is just an example of a use case. And yes, if you only want to accept some distributions this solution would not cover it.
    – Haffi112
    Dec 15, 2014 at 13:40
  • Regarding accepting all distributions this code covers that case but it does not cover the "only distributions" case because it also compiles all types which accept a generator and return a value (and they are not necessarily distributions).
    – Haffi112
    Dec 15, 2014 at 13:47
  • 1
    @Haffi112 name one thing that takes a generator, returns a value, and is not a distribution. Dec 15, 2014 at 13:55

First, some boilerplate to give us a SFINAE friendly invoke type test:

namespace invoke_details {
  template<class Sig,class=void> struct invoke {};
  template<class F, class...Args> struct invoke<
    void( decltype( std::declval<F>(Args...) ) )
  > {
    using type=decltype( std::declval<F>(Args...) );
template<class Sig> using invoke=typename invoke_details::invoke<Sig>::type;

now invoke< Foo(int, int) > is the type you get when you take a variable of type Foo and invoke it with two ints, and it evaluates in a SFINAE friendly manner.

This is basically a SFINAE friendly std::result_of.

Next, some more pretty stuff. result_type and param_type save on typing elsewhere:

template<class T>
using result_type = typename T::result_type;
template<class T>
using param_type = typename T::param_type;

details::has_property< X, T > will take a template X and apply T. If this succeeds, it is true_type, otherwise false_type:

namespace details {
  template<template<class>class X, class T, class=void>
  struct has_property : std::false_type {};
  template<template<class>class X, class T>
  struct has_property<X,T,void(X<T>)> : std::true_type {};

This gives us has_result_type etc in a pretty way:

template<class T>
using has_result_type = details::has_property< result_type, T >;
template<class T>
using has_param_type = details::has_property< param_type, T >;
template<class Sig>
using can_invoke = details::has_property< invoke, Sig >;
template<class T>
using can_twist_invoke = can_invoke< T(std::mt19937) >;

I think the simplicity of these declarations is worth the earlier boilerplate.

Now, a bit of boolean metaprogramming:

template<bool...> struct all_of : std::true_type {};
template<bool b0, bool... bs> struct all_of : std::integral_constant< bool, b0 && all_of<bs...>{} > {};

template<class T, template<class>class... Tests>
using passes_tests = all_of< Tests<T>{}... >;

And we get our one line pretty is_distribution:

template<class T>
using is_distribution = passes_tests< T, has_result_type, has_param_type, can_twist_invoke >;

This does not yet cover .param or .reset.

This style leads to more code, but the "nasty" stuff gets hidden away in details namespaces. Someone who sees is_distribution can look at the definition and see self-documented what it means. Only after drilling down will they see the messier implementation details.

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