Can someone please explain to me why C++, at least to my knowledge, doesn't implement a strongly typed ellipsis function, something to the effect of:

void foo(double ...) {
 // Do Something

Meaning that, in plain speak: 'The user can pass a variable number of terms to the foo function, however, all of the terms must be doubles'

  • 3
    I would guess that variadic functions were added to C with the sole purpose of supporting the printf family of functions, which must be type-unsafe. The format-string I/O concept itself was probably just taken from C's predecessors like BCPL (see en.wikipedia.org/wiki/BCPL). In modern C++, there is no need to introduce type-safe variadic functions, because we have superior language constructs anyway, especially since C++11. Unfortunately I have no references for my guesses. It would be interesting to ask this question to Bjarne Stroustrup himself. – Christian Hackl Aug 28 '15 at 12:37
  • 1
    You can do void foo(double *) and call it by foo((double[]){1,2,3,4,5}). Need GNU C++ extension. – user3528438 Aug 28 '15 at 12:50
  • 7
    @ChristianHackl: There's no fundamental reason why the printf family must be type-unsafe. C could have declared that the implementation first pushes a "type token" on the call stack so the vararg mechanism can check that the right type of value is on the stack. That would have slowed down correct code, and C historically had a strong preference of fast above safe. – MSalters Aug 28 '15 at 13:05
  • 1
    @MSalters: OTOH, that still would not make it type-safe at compile time. – Christian Hackl Aug 28 '15 at 13:08
  • 2
    @user3528438 template<class T> using id = T; void foo(double*); foo(id<double[]>{1,2,3,4}); works fine w/o extensions. – dyp Aug 28 '15 at 18:08

Historically, the ellipsis syntax ... comes from C.

This complicated beast was used to power printf-like functions and is to be used with va_list, va_start etc...

As you noted, it is not typesafe; but then C is far from being typesafe, what with its implicit conversions from and to void* for any pointer types, its implicit truncation of integrals/floating point values, etc...

Because C++ was to be as close as possible as a superset of C, it inherited the ellipsis from C.

Since its inception, C++ practices evolved, and there has been a strong push toward stronger typing.

In C++11, this culminated in:

  • initializer lists, a short-hand syntax for a variable number of values of a given type: foo({1, 2, 3, 4, 5})
  • variadic templates, which are a beast of their own and allow writing a type-safe printf for example

Variadic templates actually reuse the ellipsis ... in their syntax, to denote packs of types or values and as an unpack operator:

void print(std::ostream&) {}

template <typename T, typename... Args>
void print(std::ostream& out, T const& t, Args const&... args) {
    print(out << t, args...); // recursive, unless there are no args left
                              // (in that case, it calls the first overload
                              // instead of recursing.)

Note the 3 different uses of ...:

  • typename... to declare a variadic type
  • Args const&... to declare a pack of arguments
  • args... to unpack the pack in an expression
  • The call to print doesn't make much sense. Where do the args go ? – Quentin Aug 28 '15 at 15:03
  • 5
    @Quentin: Variadic functions often work (today) with recursion, so you call print with 4 arguments, which calls print with 3 arguments, which calls print with 2 arguments, which calls print with 1 argument => this is the base case (non-variadic function) and the recursion stops. – Matthieu M. Aug 28 '15 at 15:19
  • I'm blind, didn't see that they were two overload of print. Makes way more sense now :p – Quentin Aug 28 '15 at 15:23

There is

 void foo(std::initializer_list<double> values);
 // foo( {1.5, 3.14, 2.7} );

which is very close to that.

You could also use variadic templates but it gets more discursive. As for the actual reason I would say the effort to bring in that new syntax isn't probably worth it: how do you access the single elements? How do you know when to stop? What makes it better than, say, std::initializer_list?

C++ does have something even closer to that: non-type parameter packs.

template < non-type ... values>

like in

template <int ... Ints>
void foo()
     for (int i : {Ints...} )
         // do something with i

but the type of the non-type template parameter (uhm) has some restrictions: it cannot be double, for example.

  • 5
    and the value of the non-type template parameter(s) have restrictions -- they have to be compile-time constant expressions. – Ben Voigt Aug 28 '15 at 20:31

It is already possible with variadic templates and SFINAE :

template <bool...> struct bool_pack;
template <bool... v>
using all_true = std::is_same<bool_pack<true, v...>, bool_pack<v..., true>>;

template <class... Doubles, class = std::enable_if_t<
    all_true<std::is_convertible<Doubles, double>{}...>{}
void foo(Doubles... args) {}

Thanks to Columbo for the nice all_true trick. You will also be able to use a fold expression in C++17.

As later and upcoming standards are focusing on terser syntax (terse for-loops, implicit function templates...) it is very possible that your proposed syntax ends up in the Standard one day ;)

  • I can't get it to work: error C2783: 'void foo(Doubles...)': could not deduce template argument for '<unnamed-symbol>' – Simon Kraemer Aug 28 '15 at 14:37
  • @SimonKraemer IIRC SFINAE is all kinds of broken on MSVC, but sadly I don't have experience in finding workarounds... – Quentin Aug 28 '15 at 14:51
  • Even in VS2015? Ok.... In the meantime I build a "workaround" myself: stackoverflow.com/a/32273936/4181011 – Simon Kraemer Aug 28 '15 at 14:55
  • @RyanHaining haha, yeah, C++ often starts with the most complete possible syntax, then adds shorthands for recurrent patterns. If you look at a C++03 iterator for-loop, it's pretty bulky too. – Quentin Aug 29 '15 at 11:49

For why specifically such a thing wasn't proposed (or was proposed and rejected), I do not know. Such a thing would certainly be useful, but would add more complexity to the language. As Quentin demonstrates, there is already proposes a C++11 way of achieving such a thing with templates.

When Concepts gets added to the standard, we'll have another, more concise way:

template <Convertible<double>... Args>
void foo(Args... doubles);


template <typename... Args>
    requires Convertible<Args, double>()...
void foo(Args... doubles);

or, as @dyp points out:

void foo(Convertible<double>... doubles);    

Personally, between the current solution and the ones that we will get with Concepts, I feel that's an adequate solution to the problem. Especially since the last one is basically what you'd originally asked for anyway.

  • 1
    Or simply void foo(Convertible<double>... doubles); (which I had to look up, but is guaranteed to work by N4377; the reason probably being that any function with a placeholder in the parameter-decl-clause is equivalent to / defined as a function template) – dyp Aug 28 '15 at 18:05
  • @dyp Personally I'm not a fan of that usage as now we're hiding that this is a function template. Although I look forward to all the rep I will get by answering SO questions about it :) – Barry Aug 28 '15 at 18:12
  • Oh we can make it entirely clear that this is a template by using the pretty AllConvertibleToDouble{...T} void foo(T... t); -- I just can't get gcc to accept AllConvertible<double>{...T} void foo(T... t); unfortunately :( -- hmm now I want to define a concept named Template – dyp Aug 28 '15 at 18:56
  • @dyp AllConvertible<double>{...T} is invalid syntax: a template-introduction needs a qualified-concept-name before the {. AllConvertible<double> is a partial-concept-id. – Casey Sep 15 '15 at 22:50
  • Also, FWIW, Convertible is likely going to be named ConvertibleTo in accordance with LWG guidance during the July Ranges TS telecon. (Unless, obviously, the committee changes the name again ;) – Casey Sep 15 '15 at 22:52

The way to achieve (sort of) what you suggest is to use variadic templates

template<typename... Arguments>
void foo(Arguments... parameters);

however you can pass any type in the parameter pack now. What you propose has never been implemented, maybe it could be a great addition to the language, or it could just be too difficult to implement as things stand. You could always try to write a proposal and submit it to isocpp.org

  • It's not too difficult to implement. It's in fact easier than variadic templates. However, the paper should (A) include a rationale why this is needed, and thus why std::initializer_list<double> won't do, and probably (B) explain how sizeof... works for double.... Bonus points for (C) actual proposed wording for the Standard. – MSalters Aug 28 '15 at 12:54
template<typename T, typename... Arguments>
struct are_same;

template <typename T, typename A1, typename... Args>
struct are_same<T, A1, Args...>{    static const bool value = std::is_same<T, A1>::value && are_same<T, Args...>::value;};

template <typename T>
struct are_same<T>{static const bool value = true;};

template<typename T, typename... Arguments>
using requires_same = std::enable_if_t<are_same<T, Arguments...>::value>;

template <typename... Arguments, typename = requires_same<double, Arguments...>>
void foo(Arguments ... parameters)

Based on Matthew's answer:

void foo () {}

template <typename... Rest>
void foo (double arg, Rest... rest)
    /* do something with arg */

If the code using foo compiles, you know all the arguments are convertible to double.


Because you can use

void foo(std::vector<T> values);
  • ...which is type-safe but only allows a single type... and is not very "natural" to call, either. – DevSolar Aug 28 '15 at 12:43
  • I seriously doubt this is the reason. Plus, it is not the same kind of thing at all. – juanchopanza Aug 28 '15 at 12:44
  • @juan, please elaborate. The OP wanted an analogue of a function with a variable amount of arguments, with all the arguments being of a single type (that is clearly stated). Now, what do we have here, compared to that? A variable amount of unnamed arguments? Check. Being able to count the arguments actually passed, and get their values? Check. Of course, this is not the reason, however, I think that a function that takes a vector of T fully meets the OPs requirement of The user can pass a variable number of terms to the foo function, however, all of the terms must be of type T – SingerOfTheFall Aug 28 '15 at 12:49
  • @SingerOfTheFall: To me, it sounds more like the OP wants some historical references or other theoretical background on why there is no built-in language support for such a feature. – Christian Hackl Aug 28 '15 at 13:03
  • @MSalters: Well, it sure feels very different to me than foo(0.4, 0.3, 0.2);. But feelings are irrational anyway :) – Christian Hackl Aug 28 '15 at 13:09

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.