40

I have a template function with varargs template arguments, like this

template<typename Args...>
void ascendingPrint(Args... args) { /* ... */ }

And I want to write

template<typename Args...>
void descendingPrint(Args... args) {
  /* implementation using ascendingPrint()? */
}

How do I reverse the order of the parameter-pack args before passing it along, i.e. in pseudo-code:

template<typename Args...>
void descendingPrint(Args... args) {
  ascendingPrint( reverse(args) );
}
5
  • This one could be useful!
    – Carsten
    Apr 9, 2013 at 14:23
  • @Aschratt I saw that, I think the question title there is misleading.
    – towi
    Apr 9, 2013 at 14:24
  • 1
    Expanding into a tuple and generating indices in reverse order would be a relatively easy way, although that induces an overhead for constructing the tuple.
    – Xeo
    Apr 9, 2013 at 14:24
  • @towi: Sorry you did not find an solution there, but I thought the example could fit your requirement: typename Mapped_scope_deep<T0, T1, T2, T3>::type needs to be written as typename Mapped_scope_deep<T3, T2, T1, T0>::type
    – Carsten
    Apr 9, 2013 at 14:25
  • @Xeo Good idea, like reverse tuple in c++.
    – towi
    Apr 9, 2013 at 14:26

6 Answers 6

29

Overall approach and usage


The overal approach consists in packing the arguments into an std::tuple of references, exploiting the perfect forwarding machinery of std::forward_as_tuple().

This means that, at run-time, you should incur in very small overhead and no unnecessary copy/move operations. Also, the framework does not use recursion (apart from compile-time recursion, which is unavoidable for generating indices), so no risk of run-time overhead even in case the compiler would not manage to inline the recursive function calls (which is unlikely anyway, so this is more of an academic argument).

Moreover, this solution is general, in that you can use it as a header-only library to invoke your functions with reversed arguments and with minimum effort: descending_print() should be just a minimal thin wrapper around ascending_print().

Here is how it should look like:

MAKE_REVERT_CALLABLE(ascending_print)

template<typename... Args>
void descending_print(Args&&... args)
{
    revert_call(REVERT_ADAPTER(ascending_print), std::forward<Args>(args)...);
} 

What follows is a presentation of the implementation.


First step: reverting a type sequence


Here is a simple way to revert a type sequence:

#include <tuple>
#include <type_traits>

template<typename, typename>
struct append_to_type_seq { };

template<typename T, typename... Ts>
struct append_to_type_seq<T, std::tuple<Ts...>>
{
    using type = std::tuple<Ts..., T>;
};

template<typename... Ts>
struct revert_type_seq
{
    using type = std::tuple<>;
};

template<typename T, typename... Ts>
struct revert_type_seq<T, Ts...>
{
    using type = typename append_to_type_seq<
        T,
        typename revert_type_seq<Ts...>::type
        >::type;
};

A small test program:

int main()
{
    static_assert(
        std::is_same<
            revert_type_seq<char, int, bool>::type,
            std::tuple<bool, int, char>
            >::value,
        "Error"
        );
}

And a live example.


Second step: reverting a tuple


The next step consists in reverting a tuple. Given the usual indices trick machinery:

template <int... Is>
struct index_list { };

namespace detail
{
    template <int MIN, int N, int... Is>
    struct range_builder;

    template <int MIN, int... Is>
    struct range_builder<MIN, MIN, Is...>
    {
        typedef index_list<Is...> type;
    };

    template <int MIN, int N, int... Is>
    struct range_builder : public range_builder<MIN, N - 1, N - 1, Is...>
    { };
}

template<int MIN, int MAX>
using index_range = typename detail::range_builder<MIN, MAX>::type;

Together with the functions defined above, a tuple can easily be reverted this way:

template<typename... Args, int... Is>
typename revert_type_seq<Args...>::type
revert_tuple(std::tuple<Args...> t, index_list<Is...>)
{
    using reverted_tuple = typename revert_type_seq<Args...>::type;

    // Forwarding machinery that handles both lvalues and rvalues...
    auto rt = std::forward_as_tuple(
            std::forward<
                typename std::conditional<
                    std::is_lvalue_reference<
                        typename std::tuple_element<Is, reverted_tuple>::type
                        >::value,
                    typename std::tuple_element<Is, reverted_tuple>::type,
                    typename std::remove_reference<
                        typename std::tuple_element<Is, reverted_tuple>::type
                        >::type
                    >::type
                >(std::get<sizeof...(Args) - Is - 1>(t))...
        );

    return rt;
}

template<typename... Args>
typename revert_type_seq<Args...>::type
revert_tuple(std::tuple<Args...> t)
{
    return revert_tuple(t, index_range<0, sizeof...(Args)>());
}

Here is a simple test program:

#include <iostream>

int main()
{
    std::tuple<int, int, char> t(42, 1729, 'c');
    auto rt = revert_tuple(t);

    std::cout << std::get<0>(rt) << " "; // Prints c
    std::cout << std::get<1>(rt) << " "; // Prints 1729
    std::cout << std::get<2>(rt) << " "; // Prints 42
}

Here is a live example.


Third step: reverting a function's arguments


The final step consists in unpacking the tuple when calling our target function. Here is another generic utility to save us a couple of lines:

template<typename... Args>
typename revert_type_seq<Args...>::type
make_revert(Args&&... args)
{
    auto t = std::forward_as_tuple(std::forward<Args>(args)...);
    return revert_tuple(t);
}

The above function creates a tuple whose elements are the arguments provided, but in reverse order. We are not ready to define our target:

template<typename T>
void ascending_print(T&& t)
{
    std::cout << std::forward<T>(t) << " ";
}

template<typename T, typename... Args>
void ascending_print(T&& t, Args&&... args)
{
    ascending_print(std::forward<T>(t));
    ascending_print(std::forward<Args>(args)...);
}

The above function(s) prints all the arguments provided. And here is how we could write descending_print():

template<typename T, int... Is>
void call_ascending_print(T&& t, index_list<Is...>)
{
    ascending_print(std::get<Is>(std::forward<T>(t))...);
}

template<typename... Args>
void descending_print(Args&&... args) {
    call_ascending_print(make_revert(std::forward<Args>(args)...),
         index_range<0, sizeof...(Args)>());
}

A simple test case again:

int main()
{
    ascending_print(42, 3.14, "Hello, World!");
    std::cout << std::endl;
    descending_print(42, 3.14, "Hello, World!");
}

And of course a live example.


Final step: simplification


The above solution may be non-trivial to understand, but it can be made trivial to use, and quite flexible. Given a couple of generic functions:

template<typename F, typename... Args, int... Is>
void revert_call(F&& f, index_list<Is...>, Args&&... args)
{
    auto rt = make_revert(std::forward<Args>(args)...);
    f(std::get<Is>(rt)...);
}

template<typename F, typename... Args>
void revert_call(F&& f, Args&&... args)
{
    revert_call(f, index_range<0, sizeof...(Args)>(), 
                std::forward<Args>(args)...);
}

And a couple of macro definitions (I couldn't find a way to create an overload set for a function template, sorry):

#define MAKE_REVERT_CALLABLE(func) \
    struct revert_caller_ ## func \
    { \
        template<typename... Args> void operator () (Args&&... args) \
        { func(std::forward<Args>(args)...); } \
    };

#define REVERT_ADAPTER(func) \
    revert_caller_ ## func()

It becomes really easy to adapt any function for being called with arguments in reverse order:

MAKE_REVERT_CALLABLE(ascending_print)

template<typename... Args>
void descending_print(Args&&... args)
{
    revert_call(REVERT_ADAPTER(ascending_print), std::forward<Args>(args)...);
}

int main()
{
    ascending_print(42, 3.14, "Hello, World!");
    std::cout << std::endl;
    descending_print(42, 3.14, "Hello, World!");
}

To conclude, as usual, a live example.

18
  • 1
    "I couldn't find a way to create an overload set for a function template" -- Well, my dear friend, have this! Hopefully in C++14, anyways. :)
    – Xeo
    Apr 9, 2013 at 17:03
  • @Xeo: I really hope we will have it!
    – Andy Prowl
    Apr 9, 2013 at 17:06
  • While I do like your goal to keep the implementation of descending_print simple without much boilerplate code in it, have to look into the other solutions if this complexity is really necessary. Although, I like the MAKE_REVERT_CALLABLE-idea, which I would have never thought of, (except it being a macro, smile) I need to understand why it is required.
    – towi
    Apr 10, 2013 at 7:28
  • @towi: The macro is necessary because there is no way (yet!) to pass the name of a function template (in this case, ascending_print()) as an argument to revert_call(), because the name of a function template denotes a whole overload set. Note, that if ascending_print() were not a template or an overloaded function, the macro would not be needed.
    – Andy Prowl
    Apr 10, 2013 at 7:34
  • @AndyProwl Yes, I understood the macro-necessity, and I looked up N3617. The way through "make revert callable" is what eludes me. I figure, that compared to the other solutions, your solution uses perfect forwarding and should therefore be a bit more efficient in the general case? What do you think of @Alex revert/apply?
    – towi
    Apr 10, 2013 at 7:42
24

I think instead of reversing the arguments, you can reverse your logic! For example reverse the operations on arguments.

template <typename T>
void ascendingPrint(const T& x)
{
    cout << x << " ";
}

template<typename T, typename ... Args>
void ascendingPrint(const T& t, Args... args)
{
    ascendingPrint(t);                   // First print `t`
    ascendingPrint(args...);             // Then print others `args...`
}

template <typename T>
void descendingPrint(const T& x)
{
    cout << x << " ";
}

template<typename T, typename ... Args>
void descendingPrint(const T& t, Args... args)
{
    descendingPrint(args...);            // First print others `args...`
    descendingPrint(t);                  // Then print `t`
}

and then

int main()
{
    ascendingPrint(1, 2, 3, 4);
    cout << endl;
    descendingPrint(1, 2, 3, 4);
}

Output

1 2 3 4 
4 3 2 1 
5
  • 1
    I like this...it's far easier to read. :) I worry a little bit about the recursion, though. Is there something promising the template will expand to something iterative, or at least tail-recursive?
    – cHao
    Apr 9, 2013 at 14:59
  • 1
    @cHao - Why, how many arguments do you really have? Hundreds?
    – Bo Persson
    Apr 9, 2013 at 15:26
  • @BoPersson: I'm more wondering about the potential explosion of templates. Each instance of the template causes instantiation of a version for a subset of its args. If the compiler doesn't promise to inline, passing a dozen args may create a dozen different functions. Or is that not really an issue?
    – cHao
    Apr 9, 2013 at 16:09
  • 1
    I like it, too. I am a wee bit concerned about code duplication. Although, it should be straight forward in almost all situations to reverse the implementation, it introduces non-trivial duplication.
    – towi
    Apr 10, 2013 at 7:30
  • 3
    +1 for reminding everyone, that generalization is not always the best choice :-)
    – towi
    Apr 11, 2013 at 7:55
16

Here's the simple approach I mentioned in the comments: Generating indices in reverse and unpacking a tuple with that.

// reversed indices...
template<unsigned... Is> struct seq{ using type = seq; };

template<unsigned I, unsigned... Is>
struct rgen_seq : rgen_seq<I-1, Is..., I-1>{};

template<unsigned... Is>
struct rgen_seq<0, Is...> : seq<Is...>{};

#include <tuple>

namespace aux{
template<class Tup, unsigned... Is>
void descending_print(Tup&& t, seq<Is...>)
{
    ascending_print(std::get<Is>(std::forward<Tup>(t))...);
}
} // aux::

template<class... Args>
void descending_print(Args&&... args)
{
    auto t = std::forward_as_tuple(std::forward<Args>(args)...);
    aux::descending_print(t, rgen_seq<sizeof...(Args)>{});
}

Live example.

2
  • 1
    Beautiful, and you are promoted by AndyProwl. I give you a +1, too -- but I have to admit I needed his explanations to fully appreciate your code.
    – towi
    Apr 10, 2013 at 8:19
  • @towi: Maybe this helps?
    – Xeo
    Apr 10, 2013 at 8:35
14

Here is a recursive implementation of a specialized revert<>:

// forward decl
template<class ...Tn>
struct revert;

// recursion anchor
template<>
struct revert<>
{
    template<class ...Un>
    static void apply(Un const&... un)
    {
        ascendingPrint(un...);
    }
};

// recursion
template<class T, class ...Tn>
struct revert<T, Tn...> 
{
    template<class ...Un>
    static void apply(T const& t, Tn const&... tn, Un const&... un)
    {
        // bubble 1st parameter backwards
        revert<Tn...>::apply(tn..., t, un...);
    }
};

// using recursive function
template<class A, class ...An>
void descendingPrint(A const& a, An const&... an)
{
    revert<An...>::apply(an..., a);
}

It works with gcc-4.6/7/8 and clang and is probably standard compliant -- the only difficult part being the call of revert<Tn...>::apply(tn..., t, un...).

It has drawbacks though (as recursion often has), that it generates a lot of template-instantiations of the target function (code bloat) and does not use perfect forwarding, which may be an issue (but maybe could be improved to use it).

5
  • Beautiful, and looking like a literal translation of Haskell to TMP /smile/. out This looks simple enough. Why do you say "works with gcc 4.8"? Don't you think its Std? I can't see why it weren't. Are you worried about the multiple parameter-packs of apply? As far as I remember function-templates can have more then one parameter-pack -- only class-templates can not. Leaves apply(tn..., t, un...) and the question if the compiler can unroll all the arguments correctly. "Proven by example" (gcc) it seems it should, but does the Standard say so, too?
    – towi
    Apr 10, 2013 at 7:37
  • 2
    @towi Thanks! I think this is std C++, but gcc 4.8 was the only compiler I have tested. Here is a slightly modified version. Works with gcc 4.6/7/8 and clang, but not with the Intel compiler.
    – Alex
    Apr 10, 2013 at 8:17
  • 2
    I accepted your answer in favor of the non-recursive ones because I do like recursion myself and this version is the easiest for me to understand.But it was a difficult choice: I urge the readers of this to read the other answers too, of AndyPowl and Xeo, (and maybe the comments) -- they may have benefits you need. And M-M has a point too, if you do not need a general solution.
    – towi
    Apr 11, 2013 at 7:54
  • I think it is worth to mention it here that we always force inlining in such recursion situations, which yield in significant performance gain, even with light optimization. Jan 20, 2019 at 4:59
  • I know this is nitpicking but "revert" has a different meaning than "reverse". I mention because I think it's probably a hypercorrection; you probably thought that technically "revert" is the verb form of "reverse". But "reverse" is correct as a verb (actually that's how it's most often used). May 10, 2020 at 11:50
5

This can be done using C++17 fold expression and a little trick for right-to-left order execution.

#include <iostream>

template< typename T> void print(T&& val) { std::cout << val; }

template< typename ... Types > void descendingPrint(Types&&... vals) {
    int tmps = 0;
    ((print(vals), tmps) = ...);
}

int main() {
    descendingPrint(1, ' ', 2, ' ', 3);
    return 0;
}
1
  • Very clever and concise way of forcing the expanded pack to respect different order of evaluation. Shame that we have to use such tricks, but well, said tricks are not that bad.
    – Fureeish
    Dec 3, 2022 at 12:47
3

My solution supports perfect forwarding and does not involve a recursion:

#include <iostream>
#include <utility>
#include <tuple>

#include <cstdlib>

template< typename ...types >
void
ascendingPrint(types &&... _values)
{
    (std::cout << ... << std::forward< types >(_values)) << std::endl;
}

template< typename ...types, std::size_t ...indices >
void
descendingPrintHelper(std::tuple< types... > const & refs, std::index_sequence< indices... >)
{
    constexpr std::size_t back_index = sizeof...(indices) - 1;
    return ascendingPrint(std::forward< std::tuple_element_t< back_index - indices, std::tuple< types... > > >(std::get< back_index - indices >(refs))...);
}

template< typename ...types >
void
descendingPrint(types &&... _values)
{
    auto const refs = std::forward_as_tuple(std::forward< types >(_values)...);
    return descendingPrintHelper(refs, std::make_index_sequence< sizeof...(types) >{});
}

int
main()
{
    ascendingPrint(1, ' ', 2, ' ', 3);
    descendingPrint(1, ' ', 2, ' ', 3);
    return EXIT_SUCCESS;
}

Live example (or even simplier).

Also modern compilers can perfectly optimize out all the unnecessary stuff: https://godbolt.org/g/01Qf6w

5
  • 1
    It should be noted that fold expressions are a C++1z feature, and the indices facilities are C++14. The former can be emulated in C++11, the latter can be implemented in C++11.
    – dyp
    Jun 25, 2015 at 9:48
  • @dyp Also there is constant evaluation for non-type template arguments feature involved, but I don't know whether it C++11/4/z or not. Jun 25, 2015 at 10:15
  • What do you mean with constant evaluation for non-type template arguments? Even C++03 allows using constant expressions as non-type template arguments.
    – dyp
    Jun 25, 2015 at 10:32
  • @dyp open-std.org/jtc1/sc22/wg21/docs/papers/2014/n4268.html Maybe I am wrong. Jun 25, 2015 at 10:44
  • 1
    Ah, note it says for all non-type template arguments. My earlier statement was too general; constant expressions are allowed since C++03 for non-type template arguments of integral/enumeration type. Up to and including C++14, there are restrictions on non-type template arguments of e.g. pointer type. See stackoverflow.com/q/15885399
    – dyp
    Jun 25, 2015 at 11:37

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

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