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So I'm trying to figure out how this works: C++11: I can go from multiple args to tuple, but can I go from tuple to multiple args?

The piece of black magic I do not understand is this code fragment:


it's the expression inside f that I don't understand.

I understand that the expression somehow unpacks/expands what's inside t into a list of arguments. But could someone care to explain how this is done? When I look at the definition of std::get (http://en.cppreference.com/w/cpp/utility/tuple/get), I don't see how N fits in...? As far as I can tell, N is a sequence of integers.

Based on what I can observe, I'm assuming that expressions in the form E<X>... where X is the sequence of types X1. X2, ... Xn, the expression will be expanded as E<X1>, E<X2> ... E<Xn>. Is this how it works?

Edit: In this case N is not a sequence of types, but integers. But I'm guessing this language construct applies to both types and values.

share|improve this question
Yes, yes, yes, and yes. It basically expands to get<0>(t), get<1>(t), get<2>(t), ..., get<N>(t) – Xeo Sep 24 '13 at 21:23
BIG FAT WARNING: Never ever use std::forward or std::move within argument pack expansion - a value (here the tuple t) is only allowed to be moved once. It might work here because std::get<N> does not actually move, but the above is in itself an anti-pattern one should be able to spot and then fix! – Daniel Frey Sep 24 '13 at 21:29
@Daniel: std::forward here is perfectly fine, since it extracts only the tuple-elements and thus only moves them. If you know what you're doing, I don't see the problem and I don't think it's an anti-pattern quite like you make it out to be. – Xeo Sep 24 '13 at 21:34
@DanielFrey I don't think it's UB. [tuple.elem]/3 specifies the effects of get(tuple<Types...>&& t) as equivalent to return std::forward<typename tuple_element<I, tuple<Types...> >::type&&>(get<I>(t));. So the tuple isn't actually moved, only the contained element forwarded. (forward itself is specified as a static_cast) – dyp Sep 24 '13 at 21:59
Everyone, repeat the mantra: "std::move doesn't move and std::forward<> doesn't forward" :) – sehe Sep 24 '13 at 22:21
up vote 5 down vote accepted

I think that @Xeo's comment summed it up well. From 14.5.3 of the C++11 standard:

A pack expansion consists of a pattern and an ellipsis, the instantiation of which produces zero or more instantiations of the pattern in a list.

In your case, by the time you finish with the recursive template instantiation and end up in the partial specialization, you have


...where N is parameter pack of four ints (0, 1, 2, and 3). From the standardese above, the pattern here is


The application of the ... ellipsis to the above pattern causes it to be expanded into four instantiations in list form, i.e.

f(std::get<0>(t), std::get<1>(t), std::get<2>(t), std::get<3>(t));
share|improve this answer

The fundamental ingredient to expanding the std::tuple<T...> is actually omitted from the code: you need to obtain a a second parameter back: in addition to the list of types of the std::tuple<...> you need a parameter pack with indices 0, 1, ..., n. Once you have these two parameters packs, you can expand them in tandem:

template <typename F, typename... T, int... N>
void call_impl(F&& fun, std::tuple<T...>&& t) {

The real magic lies in conjuring up the second parameter pack when you just have a std::tuple<T...>. It takes a bit of template programming. Here is an approach to create the list of indices:

template <int... Indices> struct indices;
template <> struct indices<-1> { typedef indices<> type; };
template <int... Indices>
struct indices<0, Indices...>
    typedef indices<0, Indices...> type;
template <int Index, int... Indices>
struct indices<Index, Indices...>
    typedef typename indices<Index - 1, Index, Indices...>::type type;

template <typename T>
typename indices<std::tuple_size<T>::value - 1>::type const*
    return 0;

So, if you have a function template, let's call it call() which takes a function object and a std::tuple<T...> with the arguments to the function. An easy approach is to rewrite the call_impl() mentioned above to deal with deducing the indices:

template <typename F, typename Tuple, int... N>
void call_impl(F&& fun, Tuple&& t, indices<Indices...> const*)

template <typename F, typename Tuple>
void call(F&& fun, Tuple&& t)
    call_imle(std::forward<F>(fun), std::forward<Tuple>(t), make_indices<Tuple>());

What this code doesn't really extend is the correct use of std::forward<...>() with the various std::tuple<...> elements when calling the function. Just using std::forward<Tuple>(t) does not work because it possibly moves the entire std::tuple<...> rather than moving the elements. I think something like a suitable element-wise move of a std::tuple<...> can be done but I haven't done it, yet.

share|improve this answer
Is there a special reason for 0 instead of nullptr in make_indices? (And a reason for const* instead of by-value, using return {};?) – dyp Sep 24 '13 at 23:29
@DyP: nullptr vs. 0: I just haven't changed to use nullptr. The index list could also be used directly but I don't think it matters. – Dietmar Kühl Sep 24 '13 at 23:37
I don't see how it could move the entire tuple. The standard says that it only moves the specified element on an rvalue argument to std::get, no? – Xeo Sep 24 '13 at 23:56
surely the pack is 0,1,2,...,n-1 not ...,n. Second, why return a nullptr pointer-to-indexes instead of an actual (stateless) indexes instance? – Yakk Sep 25 '13 at 2:06

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