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How can I write a function that accepts a variable number of arguments? Is this possible, how?

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13  
At this time with C++11 the answers for this question would greatly differ –  K-ballo Jan 8 '13 at 20:07
    
@K-ballo I added C++11 examples as well since a recent question asked this same thing recently and I felt this needed one in order to justify closing it stackoverflow.com/questions/16337459/… –  Shafik Yaghmour May 3 '13 at 13:46
    
Added pre C++11 options to my answer as well, so it now should cover most of the choices available. –  Shafik Yaghmour Dec 2 '13 at 18:32

11 Answers 11

up vote 49 down vote accepted

You probably shouldn't, and you can probably do what you want to do in a safer and simpler way. Technically to use variable number of arguments in C you include stdarg.h. From that you'll get the va_list type as well as three functions that operate on it called va_start(), va_arg() and va_end().

#include<stdarg.h>

int maxof(int n_args, ...)
{
    va_list ap;
    va_start(ap, n_args);
    int max = va_arg(ap, int);
    for(int i = 2; i <= n_args; i++) {
        int a = va_arg(ap, int);
        if(a > max) max = a;
    }
    va_end(ap);
    return max;
}

If you ask me, this is a mess. It looks bad, it's unsafe, and it's full of technical details that have nothing to do with what you're conceptually trying to achieve. Instead, consider using overloading or inheritance/polymorphism, builder pattern (as in operator<<() in streams) or default arguments etc. These are all safer: the compiler gets to know more about what you're trying to do so there are more occasions it can stop you before you blow your leg off.

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5  
Presumably, you cannot pass references to a varargs function because the compiler wouldn't know when to pass by value and when by reference, and because the underlying C macros would not necessarily know what to do with references -- there are already restrictions on what you can pass into a C function with variable arguments because of things like promotion rules. –  Jonathan Leffler Nov 1 '09 at 19:24
    
@Jonathan: That doesn't really matter. The problem is quite solvable in theory, so ISO WG21 can just say: "This is the spec, now you make it work.". There's no good reason why the C++ compiler makers would have to restrict themselves to C macros. For instance, a trivial solution would be to push RTTI information on the stack before each vararg argument. But as wilhemtell correctly explains, even if the compiler could, you'd still have that nasty interface. –  MSalters Nov 2 '09 at 10:28
2  
is it necessary to provide atleast one argument before the ... syntax? –  Lazer Jun 23 '10 at 9:54
3  
@Lazer it is not a language or library requirement, but the standard library doesn't give you means to tell the length of the list. You need the caller to give you this information or else somehow figure it out yourself. In the case of printf(), for example, the function parses the string argument for special tokens to figure out how many extra arguments it should expect in the variable argument list. –  wilhelmtell Jun 23 '10 at 21:33
3  
you should probably use <cstdarg> in C++ instead of <stdarg.h> –  newacct Jan 8 '13 at 21:05

In C++11 you have two new options, as the Variadic functions reference page in the Alternatives section states:

  • Variadic templates can also be used to create functions that take variable number of arguments. They are often the better choice because they do not impose restrictions on the types of the arguments, do not perform integral and floating-point promotions, and are type safe. (since C++11)
  • If all variable arguments share a common type, a std::initializer_list provides a convenient mechanism (albeit with a different syntax) for accessing variable arguments.

Below is an example showing both alternatives (see it live):

#include <iostream>
#include <string>
#include <initializer_list>

template <typename T>
void func(T t) 
{
    std::cout << t << std::endl ;
}

template<typename T, typename... Args>
void func(T t, Args... args) // recursive variadic function
{
    std::cout << t <<std::endl ;

    func(args...) ;
}

template <class T>
void func2( std::initializer_list<T> list )
{
    for( auto elem : list )
    {
        std::cout << elem << std::endl ;
    }
}

int main()
{
    std::string
        str1( "Hello" ),
        str2( "world" );

    func(1,2.5,'a',str1);

    func2( {10, 20, 30, 40 }) ;
    func2( {str1, str2 } ) ;
} 

If you are using gcc or clang we can use the PRETTY_FUNCTION magic variable to also display the type signature of the function which can be helpful in understanding what is going on. For example using:

std::cout << __PRETTY_FUNCTION__ << ": " << t <<std::endl ;

would results int following for variadic functions in the example (see it live):

void func(T, Args...) [T = int, Args = <double, char, std::basic_string<char>>]: 1
void func(T, Args...) [T = double, Args = <char, std::basic_string<char>>]: 2.5
void func(T, Args...) [T = char, Args = <std::basic_string<char>>]: a
void func(T) [T = std::basic_string<char>]: Hello

Update Pre C++11

Pre C++11 the alternative for std::initializer_list would be std::vector or one of the other standard containers:

#include <iostream>
#include <string>
#include <vector>

template <class T>
void func1( std::vector<T> vec )
{
    for( typename std::vector<T>::iterator iter = vec.begin();  iter != vec.end(); ++iter )
    {
        std::cout << *iter << std::endl ;
    }
}

int main()
{
    int arr1[] = {10, 20, 30, 40} ;
    std::string arr2[] = { "hello", "world" } ; 
    std::vector<int> v1( arr1, arr1+4 ) ;
    std::vector<std::string> v2( arr2, arr2+2 ) ;

    func1( v1 ) ;
    func1( v2 ) ;
}

and the alternative for variadic templates would be variadic functions although they are not type-safe and in general error prone and can be unsafe to use but the only other potential alternative would be to use default arguments, although that has limited use. The example below is a modified version of the sample code in the linked reference:

#include <iostream>
#include <string>
#include <cstdarg>

void simple_printf(const char *fmt, ...)
{
    va_list args;
    va_start(args, fmt);

    while (*fmt != '\0') {
        if (*fmt == 'd') {
            int i = va_arg(args, int);
            std::cout << i << '\n';
        } else if (*fmt == 's') {
            char * s = va_arg(args, char*);
            std::cout << s << '\n';
        }
        ++fmt;
    }

    va_end(args);
}


int main()
{
    std::string
        str1( "Hello" ),
        str2( "world" );

    simple_printf("dddd", 10, 20, 30, 40 );
    simple_printf("ss", str1.c_str(), str2.c_str() ); 

    return 0 ;
} 

Using variadic functions also comes with restrictions in the arguments you can pass which is detailed in the draft C++ standard in section 5.2.2 Function call paragraph 7:

When there is no parameter for a given argument, the argument is passed in such a way that the receiving function can obtain the value of the argument by invoking va_arg (18.7). The lvalue-to-rvalue (4.1), array-to-pointer (4.2), and function-to-pointer (4.3) standard conversions are performed on the argument expression. After these conversions, if the argument does not have arithmetic, enumeration, pointer, pointer to member, or class type, the program is ill-formed. If the argument has a non-POD class type (clause 9), the behavior is undefined. [...]

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C-style variadic functions are supported in C++.

However, most C++ libraries use an alternative idiom e.g. whereas the 'c' printf function takes variable arguments the c++ cout object uses << overloading which addresses type safety and ADTs (perhaps at the cost of implementation simplicity).

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Apart from varargs or overloading, you could consider to aggregate your arguments in a std::vector or other containers (std::map for example). Something like this:

template <typename T> void f(std::vector<T> const&);
std::vector<int> my_args;
my_args.push_back(1);
my_args.push_back(2);
f(my_args);

In this way you would gain type safety and the logical meaning of these variadic arguments would be apparent.

Surely this approach can have performance issues but you should not worry about them unless you are sure that you cannot pay the price. It is a sort of a a "Pythonic" approach to c++ ...

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2  
Cleaner would be to not enforce vectors. Instead use a template argument specifying the STL-styled collection then iterate through it using the argument's begin and end methods. This way you can use std::vector<T>, c++11's std::array<T, N>, std::initializer_list<T> or even make your own collection. –  Jens Åkerblom Mar 29 '13 at 11:26
    
@JensÅkerblom I agree but this is the kind of choice that should be analyzed for the issue at hand, to avoid over engineering. Since this is a matter of API signature, it is important to understand the tradeoff between maximum flexibility and clarity of intent/usability/maintanability etc. –  Francesco Mar 30 '13 at 14:18

The only way is through the use of C style variable arguments, as described here. Note that this is not a recommended practice, as it's not typesafe and error-prone.

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By error prone I assume you mean potentially very very dangerous? Especially when working with untrusted input. –  Kevin Loney Nov 1 '09 at 18:32
    
Yes, but because of the type safety issues. Think all of the possible issues that regular printf has: format strings not matching passed arguments, and such. printf uses the same technique, BTW. –  Dave Van den Eynde Nov 1 '09 at 18:34

In C++11 there is a way to do variable argument templates which lead to a really elegant and type safe way to have variable argument functions. Bjarne himself gives a nice example of printf using variable argument templates in the C++11FAQ.

Personally, I consider this so elegant that I wouldn't even bother with a variable argument function in C++ until that compiler has support for C++11 variable argument templates.

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Please, note that using variadic templates is not without trade-offs you need to generate code for each instance. –  Shafik Yaghmour Apr 22 at 20:23

There is no standard C++ way to do this without resorting to C-style varargs (...).

There are of course default arguments that sort of "look" like variable number of arguments depending on the context:

void myfunc( int i = 0, int j = 1, int k = 2 );

// other code...

myfunc();
myfunc( 2 );
myfunc( 2, 1 );
myfunc( 2, 1, 0 );

All four function calls call myfunc with varying number of arguments. If none are given, the default arguments are used. Note however, that you can only omit trailing arguments. There is no way, for example to omit i and give only j.

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As others have said, C-style varargs. But you can also do something similar with default arguments.

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If you know the range of number of arguments that will be provided, you can always use some function overloading, like

f(int a)
    {int res=a; return res;}
f(int a, int b)
    {int res=a+b; return res;}

and so on...

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It's possible you want overloading or default parameters - define the same function with defaulted parameters:

void doStuff( int a, double termstator = 1.0, bool useFlag = true )
{
   // stuff
}

void doStuff( double std_termstator )
{
   // assume the user always wants '1' for the a param
   return doStuff( 1, std_termstator );
}

This will allow you to call the method with one of four different calls:

doStuff( 1 );
doStuff( 2, 2.5 );
doStuff( 1, 1.0, false );
doStuff( 6.72 );

... or you could be looking for the v_args calling conventions from C.

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We could also use an initializer_list if all arguments are const and of the same type

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