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How can I iterate over a tuple (using C++11)? I tried the following:
for(int i=0; i<std::tuple_size<T...>::value; ++i)
std::get<i>(my_tuple).do_sth();
but this doesn't work:
Error 1: sorry, unimplemented: cannot expand ‘Listener ...’ into a fixed-length argument list.
Error 2: i cannot appear in a constant expression.
So, how do I correctly iterate over the elements of a tuple?
I have an answer based on Iterating over a Tuple:
#include <tuple>
#include <utility>
#include <iostream>
template<std::size_t I = 0, typename... Tp>
inline typename std::enable_if<I == sizeof...(Tp), void>::type
print(std::tuple<Tp...>& t)
{ }
template<std::size_t I = 0, typename... Tp>
inline typename std::enable_if<I < sizeof...(Tp), void>::type
print(std::tuple<Tp...>& t)
{
std::cout << std::get<I>(t) << std::endl;
print<I + 1, Tp...>(t);
}
int
main()
{
typedef std::tuple<int, float, double> T;
T t = std::make_tuple(2, 3.14159F, 2345.678);
print(t);
}
The usual idea is to use compile time recursion. In fact, this idea is used to make a printf that is type safe as noted in the original tuple papers.
This can be easily generalized into a for_each for tuples:
#include <tuple>
#include <utility>
template<std::size_t I = 0, typename FuncT, typename... Tp>
inline typename std::enable_if<I == sizeof...(Tp), void>::type
for_each(std::tuple<Tp...> &, FuncT) // Unused arguments are given no names.
{ }
template<std::size_t I = 0, typename FuncT, typename... Tp>
inline typename std::enable_if<I < sizeof...(Tp), void>::type
for_each(std::tuple<Tp...>& t, FuncT f)
{
f(std::get<I>(t));
for_each<I + 1, FuncT, Tp...>(t, f);
}
Though this then requires some effort to have FuncT represent something with the appropriate overloads for every type the tuple might contain. This works best if you know all the tuple elements will share a common base class or something similar.
In C++17, you can use std::apply with fold expression:
std::apply([](auto&&... args) {((/* args.dosomething() */), ...);}, the_tuple);
A complete example for printing a tuple:
#include <tuple>
#include <iostream>
int main()
{
std::tuple t{42, 'a', 4.2}; // Another C++17 feature: class template argument deduction
std::apply([](auto&&... args) {((std::cout << args << '\n'), ...);}, t);
}
[Online Example on Coliru]
This solution solves the issue of evaluation order in M. Alaggan's answer.
C++ is introducing expansion statements for this purpose. They were originally on track for C++20 but narrowly missed the cut due to a lack of time for language wording review (see here and here).
The currently agreed syntax (see the links above) is:
{
auto tup = std::make_tuple(0, 'a', 3.14);
template for (auto elem : tup)
std::cout << elem << std::endl;
}
Boost.Fusion is a possibility:
Untested example:
struct DoSomething
{
template<typename T>
void operator()(T& t) const
{
t.do_sth();
}
};
tuple<....> t = ...;
boost::fusion::for_each(t, DoSomething());
In C++17 you can do this:
std::apply([](auto ...x){std::make_tuple(x.do_something()...);} , the_tuple);
This already works in Clang++ 3.9, using std::experimental::apply.
A more simple, intuitive and compiler-friendly way of doing this in C++17, using if constexpr:
// prints every element of a tuple
template<size_t I = 0, typename... Tp>
void print(std::tuple<Tp...>& t) {
std::cout << std::get<I>(t) << " ";
// do things
if constexpr(I+1 != sizeof...(Tp))
print<I+1>(t);
}
This is compile-time recursion, similar to the one presented by #emsr. But this doesn't use SFINAE so (I think) it is more compiler-friendly.
Use Boost.Hana and generic lambdas:
#include <tuple>
#include <iostream>
#include <boost/hana.hpp>
#include <boost/hana/ext/std/tuple.hpp>
struct Foo1 {
int foo() const { return 42; }
};
struct Foo2 {
int bar = 0;
int foo() { bar = 24; return bar; }
};
int main() {
using namespace std;
using boost::hana::for_each;
Foo1 foo1;
Foo2 foo2;
for_each(tie(foo1, foo2), [](auto &foo) {
cout << foo.foo() << endl;
});
cout << "foo2.bar after mutation: " << foo2.bar << endl;
}
http://coliru.stacked-crooked.com/a/27b3691f55caf271
Here's an easy C++17 way of iterating over tuple items with just standard library:
#include <tuple> // std::tuple
#include <functional> // std::invoke
template <
size_t Index = 0, // start iteration at 0 index
typename TTuple, // the tuple type
size_t Size =
std::tuple_size_v<
std::remove_reference_t<TTuple>>, // tuple size
typename TCallable, // the callable to be invoked for each tuple item
typename... TArgs // other arguments to be passed to the callable
>
void for_each(TTuple&& tuple, TCallable&& callable, TArgs&&... args)
{
if constexpr (Index < Size)
{
std::invoke(callable, args..., std::get<Index>(tuple));
if constexpr (Index + 1 < Size)
for_each<Index + 1>(
std::forward<TTuple>(tuple),
std::forward<TCallable>(callable),
std::forward<TArgs>(args)...);
}
}
Example:
#include <iostream>
int main()
{
std::tuple<int, char> items{1, 'a'};
for_each(items, [](const auto& item) {
std::cout << item << "\n";
});
}
Output:
1
a
This can be extended to conditionally break the loop in case the callable returns a value (but still work with callables that do not return a bool assignable value, e.g. void):
#include <tuple> // std::tuple
#include <functional> // std::invoke
template <
size_t Index = 0, // start iteration at 0 index
typename TTuple, // the tuple type
size_t Size =
std::tuple_size_v<
std::remove_reference_t<TTuple>>, // tuple size
typename TCallable, // the callable to bo invoked for each tuple item
typename... TArgs // other arguments to be passed to the callable
>
void for_each(TTuple&& tuple, TCallable&& callable, TArgs&&... args)
{
if constexpr (Index < Size)
{
if constexpr (std::is_assignable_v<bool&, std::invoke_result_t<TCallable&&, TArgs&&..., decltype(std::get<Index>(tuple))>>)
{
if (!std::invoke(callable, args..., std::get<Index>(tuple)))
return;
}
else
{
std::invoke(callable, args..., std::get<Index>(tuple));
}
if constexpr (Index + 1 < Size)
for_each<Index + 1>(
std::forward<TTuple>(tuple),
std::forward<TCallable>(callable),
std::forward<TArgs>(args)...);
}
}
Example:
#include <iostream>
int main()
{
std::tuple<int, char> items{ 1, 'a' };
for_each(items, [](const auto& item) {
std::cout << item << "\n";
});
std::cout << "---\n";
for_each(items, [](const auto& item) {
std::cout << item << "\n";
return false;
});
}
Output:
1
a
---
1
You need to use template metaprogramming, here shown with Boost.Tuple:
#include <boost/tuple/tuple.hpp>
#include <iostream>
template <typename T_Tuple, size_t size>
struct print_tuple_helper {
static std::ostream & print( std::ostream & s, const T_Tuple & t ) {
return print_tuple_helper<T_Tuple,size-1>::print( s, t ) << boost::get<size-1>( t );
}
};
template <typename T_Tuple>
struct print_tuple_helper<T_Tuple,0> {
static std::ostream & print( std::ostream & s, const T_Tuple & ) {
return s;
}
};
template <typename T_Tuple>
std::ostream & print_tuple( std::ostream & s, const T_Tuple & t ) {
return print_tuple_helper<T_Tuple,boost::tuples::length<T_Tuple>::value>::print( s, t );
}
int main() {
const boost::tuple<int,char,float,char,double> t( 0, ' ', 2.5f, '\n', 3.1416 );
print_tuple( std::cout, t );
return 0;
}
In C++0x, you can write print_tuple() as a variadic template function instead.
First define some index helpers:
template <size_t ...I>
struct index_sequence {};
template <size_t N, size_t ...I>
struct make_index_sequence : public make_index_sequence<N - 1, N - 1, I...> {};
template <size_t ...I>
struct make_index_sequence<0, I...> : public index_sequence<I...> {};
With your function you would like to apply on each tuple element:
template <typename T>
/* ... */ foo(T t) { /* ... */ }
you can write:
template<typename ...T, size_t ...I>
/* ... */ do_foo_helper(std::tuple<T...> &ts, index_sequence<I...>) {
std::tie(foo(std::get<I>(ts)) ...);
}
template <typename ...T>
/* ... */ do_foo(std::tuple<T...> &ts) {
return do_foo_helper(ts, make_index_sequence<sizeof...(T)>());
}
Or if foo returns void, use
std::tie((foo(std::get<I>(ts)), 1) ... );
Note: On C++14 make_index_sequence is already defined (http://en.cppreference.com/w/cpp/utility/integer_sequence).
If you do need a left-to-right evaluation order, consider something like this:
template <typename T, typename ...R>
void do_foo_iter(T t, R ...r) {
foo(t);
do_foo(r...);
}
void do_foo_iter() {}
template<typename ...T, size_t ...I>
void do_foo_helper(std::tuple<T...> &ts, index_sequence<I...>) {
do_foo_iter(std::get<I>(ts) ...);
}
template <typename ...T>
void do_foo(std::tuple<T...> &ts) {
do_foo_helper(ts, make_index_sequence<sizeof...(T)>());
}
If you want to use std::tuple and you have C++ compiler which supports variadic templates, try code bellow (tested with g++4.5). This should be the answer to your question.
#include <tuple>
// ------------- UTILITY---------------
template<int...> struct index_tuple{};
template<int I, typename IndexTuple, typename... Types>
struct make_indexes_impl;
template<int I, int... Indexes, typename T, typename ... Types>
struct make_indexes_impl<I, index_tuple<Indexes...>, T, Types...>
{
typedef typename make_indexes_impl<I + 1, index_tuple<Indexes..., I>, Types...>::type type;
};
template<int I, int... Indexes>
struct make_indexes_impl<I, index_tuple<Indexes...> >
{
typedef index_tuple<Indexes...> type;
};
template<typename ... Types>
struct make_indexes : make_indexes_impl<0, index_tuple<>, Types...>
{};
// ----------- FOR EACH -----------------
template<typename Func, typename Last>
void for_each_impl(Func&& f, Last&& last)
{
f(last);
}
template<typename Func, typename First, typename ... Rest>
void for_each_impl(Func&& f, First&& first, Rest&&...rest)
{
f(first);
for_each_impl( std::forward<Func>(f), rest...);
}
template<typename Func, int ... Indexes, typename ... Args>
void for_each_helper( Func&& f, index_tuple<Indexes...>, std::tuple<Args...>&& tup)
{
for_each_impl( std::forward<Func>(f), std::forward<Args>(std::get<Indexes>(tup))...);
}
template<typename Func, typename ... Args>
void for_each( std::tuple<Args...>& tup, Func&& f)
{
for_each_helper(std::forward<Func>(f),
typename make_indexes<Args...>::type(),
std::forward<std::tuple<Args...>>(tup) );
}
template<typename Func, typename ... Args>
void for_each( std::tuple<Args...>&& tup, Func&& f)
{
for_each_helper(std::forward<Func>(f),
typename make_indexes<Args...>::type(),
std::forward<std::tuple<Args...>>(tup) );
}
boost::fusion is another option, but it requires its own tuple type: boost::fusion::tuple. Lets better stick to the standard! Here is a test:
#include <iostream>
// ---------- FUNCTOR ----------
struct Functor
{
template<typename T>
void operator()(T& t) const { std::cout << t << std::endl; }
};
int main()
{
for_each( std::make_tuple(2, 0.6, 'c'), Functor() );
return 0;
}
the power of variadic templates!
In MSVC STL there's a _For_each_tuple_element function (not documented):
#include <tuple>
// ...
std::tuple<int, char, float> values{};
std::_For_each_tuple_element(values, [](auto&& value)
{
// process 'value'
});
Another option would be to implement iterators for tuples. This has the advantage that you can use a variety of algorithms provided by the standard library and range-based for loops. An elegant approach to this is explained here https://foonathan.net/2017/03/tuple-iterator/. The basic idea is to turn tuples into a range with begin() and end() methods to provide iterators. The iterator itself returns a std::variant<...> which can then be visited using std::visit.
Here some examples:
auto t = std::tuple{ 1, 2.f, 3.0 };
auto r = to_range(t);
for(auto v : r)
{
std::visit(unwrap([](auto& x)
{
x = 1;
}), v);
}
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(unwrap([](auto& x)
{
x = 0;
}), v);
});
std::accumulate(begin(r), end(r), 0.0, [](auto acc, auto v)
{
return acc + std::visit(unwrap([](auto& x)
{
return static_cast<double>(x);
}), v);
});
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(unwrap([](const auto& x)
{
std::cout << x << std::endl;
}), v);
});
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(overload(
[](int x) { std::cout << "int" << std::endl; },
[](float x) { std::cout << "float" << std::endl; },
[](double x) { std::cout << "double" << std::endl; }), v);
});
My implementation (which is heavily based on the explanations in the link above):
#ifndef TUPLE_RANGE_H
#define TUPLE_RANGE_H
#include <utility>
#include <functional>
#include <variant>
#include <type_traits>
template<typename Accessor>
class tuple_iterator
{
public:
tuple_iterator(Accessor acc, const int idx)
: acc_(acc), index_(idx)
{
}
tuple_iterator operator++()
{
++index_;
return *this;
}
template<typename T>
bool operator ==(tuple_iterator<T> other)
{
return index_ == other.index();
}
template<typename T>
bool operator !=(tuple_iterator<T> other)
{
return index_ != other.index();
}
auto operator*() { return std::invoke(acc_, index_); }
[[nodiscard]] int index() const { return index_; }
private:
const Accessor acc_;
int index_;
};
template<bool IsConst, typename...Ts>
struct tuple_access
{
using tuple_type = std::tuple<Ts...>;
using tuple_ref = std::conditional_t<IsConst, const tuple_type&, tuple_type&>;
template<typename T>
using element_ref = std::conditional_t<IsConst,
std::reference_wrapper<const T>,
std::reference_wrapper<T>>;
using variant_type = std::variant<element_ref<Ts>...>;
using function_type = variant_type(*)(tuple_ref);
using table_type = std::array<function_type, sizeof...(Ts)>;
private:
template<size_t Index>
static constexpr function_type create_accessor()
{
return { [](tuple_ref t) -> variant_type
{
if constexpr (IsConst)
return std::cref(std::get<Index>(t));
else
return std::ref(std::get<Index>(t));
} };
}
template<size_t...Is>
static constexpr table_type create_table(std::index_sequence<Is...>)
{
return { create_accessor<Is>()... };
}
public:
static constexpr auto table = create_table(std::make_index_sequence<sizeof...(Ts)>{});
};
template<bool IsConst, typename...Ts>
class tuple_range
{
public:
using tuple_access_type = tuple_access<IsConst, Ts...>;
using tuple_ref = typename tuple_access_type::tuple_ref;
static constexpr auto tuple_size = sizeof...(Ts);
explicit tuple_range(tuple_ref tuple)
: tuple_(tuple)
{
}
[[nodiscard]] auto begin() const
{
return tuple_iterator{ create_accessor(), 0 };
}
[[nodiscard]] auto end() const
{
return tuple_iterator{ create_accessor(), tuple_size };
}
private:
tuple_ref tuple_;
auto create_accessor() const
{
return [this](int idx)
{
return std::invoke(tuple_access_type::table[idx], tuple_);
};
}
};
template<bool IsConst, typename...Ts>
auto begin(const tuple_range<IsConst, Ts...>& r)
{
return r.begin();
}
template<bool IsConst, typename...Ts>
auto end(const tuple_range<IsConst, Ts...>& r)
{
return r.end();
}
template <class ... Fs>
struct overload : Fs... {
explicit overload(Fs&&... fs) : Fs{ fs }... {}
using Fs::operator()...;
template<class T>
auto operator()(std::reference_wrapper<T> ref)
{
return (*this)(ref.get());
}
template<class T>
auto operator()(std::reference_wrapper<const T> ref)
{
return (*this)(ref.get());
}
};
template <class F>
struct unwrap : overload<F>
{
explicit unwrap(F&& f) : overload<F>{ std::forward<F>(f) } {}
using overload<F>::operator();
};
template<typename...Ts>
auto to_range(std::tuple<Ts...>& t)
{
return tuple_range<false, Ts...>{t};
}
template<typename...Ts>
auto to_range(const std::tuple<Ts...>& t)
{
return tuple_range<true, Ts...>{t};
}
#endif
Read-only access is also supported by passing a const std::tuple<>& to to_range().
Others have mentioned some well-designed third-party libraries that you may turn to. However, if you are using C++ without those third-party libraries, the following code may help.
namespace detail {
template <class Tuple, std::size_t I, class = void>
struct for_each_in_tuple_helper {
template <class UnaryFunction>
static void apply(Tuple&& tp, UnaryFunction& f) {
f(std::get<I>(std::forward<Tuple>(tp)));
for_each_in_tuple_helper<Tuple, I + 1u>::apply(std::forward<Tuple>(tp), f);
}
};
template <class Tuple, std::size_t I>
struct for_each_in_tuple_helper<Tuple, I, typename std::enable_if<
I == std::tuple_size<typename std::decay<Tuple>::type>::value>::type> {
template <class UnaryFunction>
static void apply(Tuple&&, UnaryFunction&) {}
};
} // namespace detail
template <class Tuple, class UnaryFunction>
UnaryFunction for_each_in_tuple(Tuple&& tp, UnaryFunction f) {
detail::for_each_in_tuple_helper<Tuple, 0u>
::apply(std::forward<Tuple>(tp), f);
return std::move(f);
}
Note: The code compiles with any compiler supporing C++11, and it keeps consistency with design of the standard library:
The tuple need not be std::tuple, and instead may be anything that supports std::get and std::tuple_size; in particular, std::array and std::pair may be used;
The tuple may be a reference type or cv-qualified;
It has similar behavior as std::for_each, and returns the input UnaryFunction;
For C++14 (or laster version) users, typename std::enable_if<T>::type and typename std::decay<T>::type could be replaced with their simplified version, std::enable_if_t<T> and std::decay_t<T>;
For C++17 (or laster version) users, std::tuple_size<T>::value could be replaced with its simplified version, std::tuple_size_v<T>.
For C++20 (or laster version) users, the SFINAE feature could be implemented with the Concepts.
Using constexpr and if constexpr(C++17) this is fairly simple and straight forward:
template <std::size_t I = 0, typename ... Ts>
void print(std::tuple<Ts...> tup) {
if constexpr (I == sizeof...(Ts)) {
return;
} else {
std::cout << std::get<I>(tup) << ' ';
print<I+1>(tup);
}
}
I might have missed this train, but this will be here for future reference.
Here's my construct based on this answer and on this gist:
#include <tuple>
#include <utility>
template<std::size_t N>
struct tuple_functor
{
template<typename T, typename F>
static void run(std::size_t i, T&& t, F&& f)
{
const std::size_t I = (N - 1);
switch(i)
{
case I:
std::forward<F>(f)(std::get<I>(std::forward<T>(t)));
break;
default:
tuple_functor<I>::run(i, std::forward<T>(t), std::forward<F>(f));
}
}
};
template<>
struct tuple_functor<0>
{
template<typename T, typename F>
static void run(std::size_t, T, F){}
};
You then use it as follow:
template<typename... T>
void logger(std::string format, T... args) //behaves like C#'s String.Format()
{
auto tp = std::forward_as_tuple(args...);
auto fc = [](const auto& t){std::cout << t;};
/* ... */
std::size_t some_index = ...
tuple_functor<sizeof...(T)>::run(some_index, tp, fc);
/* ... */
}
There could be room for improvements.
As per OP's code, it would become this:
const std::size_t num = sizeof...(T);
auto my_tuple = std::forward_as_tuple(t...);
auto do_sth = [](const auto& elem){/* ... */};
for(int i = 0; i < num; ++i)
tuple_functor<num>::run(i, my_tuple, do_sth);
Of all the answers I've seen here, here and here, I liked #sigidagi's way of iterating best. Unfortunately, his answer is very verbose which in my opinion obscures the inherent clarity.
This is my version of his solution which is more concise and works with std::tuple, std::pair and std::array.
template<typename UnaryFunction>
void invoke_with_arg(UnaryFunction)
{}
/**
* Invoke the unary function with each of the arguments in turn.
*/
template<typename UnaryFunction, typename Arg0, typename... Args>
void invoke_with_arg(UnaryFunction f, Arg0&& a0, Args&&... as)
{
f(std::forward<Arg0>(a0));
invoke_with_arg(std::move(f), std::forward<Args>(as)...);
}
template<typename Tuple, typename UnaryFunction, std::size_t... Indices>
void for_each_helper(Tuple&& t, UnaryFunction f, std::index_sequence<Indices...>)
{
using std::get;
invoke_with_arg(std::move(f), get<Indices>(std::forward<Tuple>(t))...);
}
/**
* Invoke the unary function for each of the elements of the tuple.
*/
template<typename Tuple, typename UnaryFunction>
void for_each(Tuple&& t, UnaryFunction f)
{
using size = std::tuple_size<typename std::remove_reference<Tuple>::type>;
for_each_helper(
std::forward<Tuple>(t),
std::move(f),
std::make_index_sequence<size::value>()
);
}
Demo: coliru
C++14's std::make_index_sequence can be implemented for C++11.
Expanding on #Stypox answer, we can make their solution more generic (C++17 onward). By adding a callable function argument:
template<size_t I = 0, typename... Tp, typename F>
void for_each_apply(std::tuple<Tp...>& t, F &&f) {
f(std::get<I>(t));
if constexpr(I+1 != sizeof...(Tp)) {
for_each_apply<I+1>(t, std::forward<F>(f));
}
}
Then, we need a strategy to visit each type.
Let start with some helpers (first two taken from cppreference):
template<class... Ts> struct overloaded : Ts... { using Ts::operator()...; };
template<class... Ts> overloaded(Ts...) -> overloaded<Ts...>;
template<class ... Ts> struct variant_ref { using type = std::variant<std::reference_wrapper<Ts>...>; };
variant_ref is used to allow tuples' state to be modified.
Usage:
std::tuple<Foo, Bar, Foo> tuples;
for_each_apply(tuples,
[](variant_ref<Foo, Bar>::type &&v) {
std::visit(overloaded {
[](Foo &arg) { arg.foo(); },
[](Bar const &arg) { arg.bar(); },
}, v);
});
Result:
Foo0
Bar
Foo0
Foo1
Bar
Foo1
For completeness, here are my Bar & Foo:
struct Foo {
void foo() {std::cout << "Foo" << i++ << std::endl;}
int i = 0;
};
struct Bar {
void bar() const {std::cout << "Bar" << std::endl;}
};
I have stumbled on the same problem for iterating over a tuple of function objects, so here is one more solution:
#include <tuple>
#include <iostream>
// Function objects
class A
{
public:
inline void operator()() const { std::cout << "A\n"; };
};
class B
{
public:
inline void operator()() const { std::cout << "B\n"; };
};
class C
{
public:
inline void operator()() const { std::cout << "C\n"; };
};
class D
{
public:
inline void operator()() const { std::cout << "D\n"; };
};
// Call iterator using recursion.
template<typename Fobjects, int N = 0>
struct call_functors
{
static void apply(Fobjects const& funcs)
{
std::get<N>(funcs)();
// Choose either the stopper or descend further,
// depending if N + 1 < size of the tuple.
using caller = std::conditional_t
<
N + 1 < std::tuple_size_v<Fobjects>,
call_functors<Fobjects, N + 1>,
call_functors<Fobjects, -1>
>;
caller::apply(funcs);
}
};
// Stopper.
template<typename Fobjects>
struct call_functors<Fobjects, -1>
{
static void apply(Fobjects const& funcs)
{
}
};
// Call dispatch function.
template<typename Fobjects>
void call(Fobjects const& funcs)
{
call_functors<Fobjects>::apply(funcs);
};
using namespace std;
int main()
{
using Tuple = tuple<A,B,C,D>;
Tuple functors = {A{}, B{}, C{}, D{}};
call(functors);
return 0;
}
Output:
A
B
C
D
There're many great answers, but for some reason most of them don't consider returning the results of applying f to our tuple...
or did I overlook it? Anyway, here's yet another way you can do that:
Doing Foreach with style (debatable)
auto t = std::make_tuple(1, "two", 3.f);
t | foreach([](auto v){ std::cout << v << " "; });
And returning from that:
auto t = std::make_tuple(1, "two", 3.f);
auto sizes = t | foreach([](auto v) {
return sizeof(v);
});
sizes | foreach([](auto v) {
std::cout << v;
});
Implementation (pretty simple one)
Edit: it gets a little messier.
I won't include some metaprogramming boilerplate here, for it will definitely make things less readable and besides, I believe those have already been answered somewhere on stackoverflow.
In case you're feeling lazy, feel free to peek into my github repo for implementation of both
#include <utility>
// Optional includes, if you don't want to implement it by hand or google it
// you can find it in the repo (link below)
#include "typesystem/typelist.hpp"
// used to check if all return types are void,
// making it a special case
// (and, alas, not using constexpr-if
// for the sake of being compatible with C++14...)
template <bool Cond, typename T, typename F>
using select = typename std::conditional<Cond, T, F>::type;
template <typename F>
struct elementwise_apply {
F f;
};
template <typename F>
constexpr auto foreach(F && f) -> elementwise_apply<F> { return {std::forward<F>(f)}; }
template <typename R>
struct tuple_map {
template <typename F, typename T, size_t... Is>
static constexpr decltype(auto) impl(std::index_sequence<Is...>, F && f, T&& tuple) {
return R{ std::forward<F>(f)( std::get<Is>(tuple) )... };
}
};
template<>
struct tuple_map<void> {
template <typename F, typename T, size_t... Is>
static constexpr void impl(std::index_sequence<Is...>, F && f, T&& tuple) {
[[maybe_unused]] std::initializer_list<int> _ {((void)std::forward<F>(f)( std::get<Is>(tuple) ), 0)... };
}
};
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> & t, fmap<F> && op) {
constexpr bool all_void = core::Types<decltype( std::move(op).f(std::declval<Ts&>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, t);
}
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> const& t, fmap<F> && op) {
constexpr bool all_void = check if all "decltype( std::move(op).f(std::declval<Ts>()) )..." types are void, since then it's a special case
// e.g. core::Types<decltype( std::move(op).f(std::declval<Ts>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts const&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, t);
}
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> && t, fmap<F> && op) {
constexpr bool all_void = core::Types<decltype( std::move(op).f(std::declval<Ts&&>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts&&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, std::move(t));
}
Yeah, that would be much nicer if we were to use C++17
This is also an example of std::moving object's members, for which I'll better refer to this nice brief article
P.S. If you're stuck checking if all "decltype( std::move(op).f(std::declval()) )..." types are void
you can find some metaprogramming library, or, if those libraries seem too hard to grasp (which some of them may be due to some crazy metaprogramming tricks), you know where to look
template <typename F, typename T>
static constexpr size_t
foreach_in_tuple(std::tuple<T> & tuple, F && do_, size_t index_ = 0)
{
do_(tuple, index_);
return index_;
}
template <typename F, typename T, typename U, typename... Types>
static constexpr size_t
foreach_in_tuple(std::tuple<T,U,Types...> & tuple, F && do_, size_t index_ = 0)
{
if(!do_(tuple, index_))
return index_;
auto & next_tuple = reinterpret_cast<std::tuple<U,Types...> &>(tuple);
return foreach_in_tuple(next_tuple, std::forward<F>(do_), index_+1);
}
int main()
{
using namespace std;
auto tup = make_tuple(1, 2.3f, 'G', "hello");
foreach_in_tuple(tup, [](auto & tuple, size_t i)
{
auto & value = std::get<0>(tuple);
std::cout << i << " " << value << std::endl;
// if(i >= 2) return false; // break;
return true; // continue
});
}
Here is a solution based on std::interger_sequence.
As I don't know if my_tuple is constructed from std::make_tuple<T>(T &&...) in your code. It's essential for how to construct std::integer_sequence in the solution below.
(1) if your already have a my_tuple outside your function(not using template<typename ...T>), You can use
[](auto my_tuple)
{
[&my_tuple]<typename N, N... n>(std::integer_sequence<N, n...> int_seq)
{
((std::cout << std::get<n>(my_tuple) << '\n'), ...);
}(std::make_index_sequence<std::tuple_size_v<decltype(my_tuple)>>{});
}(std::make_tuple());
(2) if your havn't constructed my_tuple in your function and want to handle your T ...arguments
[]<typename ...T>(T... args)
{
[&args...]<typename N, N... n>(std::integer_sequence<N, n...> int_seq)
{
((std::cout << std::get<n>(std::forward_as_tuple(args...)) << '\n'), ...);
}(std::index_sequence_for<T...>{});
}();
boost's tuple provides helper functions get_head() and get_tail() so your helper functions may look like this:
inline void call_do_sth(const null_type&) {};
template <class H, class T>
inline void call_do_sth(cons<H, T>& x) { x.get_head().do_sth(); call_do_sth(x.get_tail()); }
as described in here http://www.boost.org/doc/libs/1_34_0/libs/tuple/doc/tuple_advanced_interface.html
with std::tuple it should be similar.
Actually, unfortunately std::tuple does not seem to provide such interface, so methods suggested before should work, or you would need to switch to boost::tuple which has other benefits (like io operators already provided). Though there is downside of boost::tuple with gcc - it does not accept variadic templates yet, but that may be already fixed as I do not have latest version of boost installed on my machine.
How can I iterate over a tuple (using C++11)? I tried the following:
for(int i=0; i<std::tuple_size<T...>::value; ++i)
std::get<i>(my_tuple).do_sth();
but this doesn't work:
Error 1: sorry, unimplemented: cannot expand ‘Listener ...’ into a fixed-length argument list.
Error 2: i cannot appear in a constant expression.
So, how do I correctly iterate over the elements of a tuple?
I have an answer based on Iterating over a Tuple:
#include <tuple>
#include <utility>
#include <iostream>
template<std::size_t I = 0, typename... Tp>
inline typename std::enable_if<I == sizeof...(Tp), void>::type
print(std::tuple<Tp...>& t)
{ }
template<std::size_t I = 0, typename... Tp>
inline typename std::enable_if<I < sizeof...(Tp), void>::type
print(std::tuple<Tp...>& t)
{
std::cout << std::get<I>(t) << std::endl;
print<I + 1, Tp...>(t);
}
int
main()
{
typedef std::tuple<int, float, double> T;
T t = std::make_tuple(2, 3.14159F, 2345.678);
print(t);
}
The usual idea is to use compile time recursion. In fact, this idea is used to make a printf that is type safe as noted in the original tuple papers.
This can be easily generalized into a for_each for tuples:
#include <tuple>
#include <utility>
template<std::size_t I = 0, typename FuncT, typename... Tp>
inline typename std::enable_if<I == sizeof...(Tp), void>::type
for_each(std::tuple<Tp...> &, FuncT) // Unused arguments are given no names.
{ }
template<std::size_t I = 0, typename FuncT, typename... Tp>
inline typename std::enable_if<I < sizeof...(Tp), void>::type
for_each(std::tuple<Tp...>& t, FuncT f)
{
f(std::get<I>(t));
for_each<I + 1, FuncT, Tp...>(t, f);
}
Though this then requires some effort to have FuncT represent something with the appropriate overloads for every type the tuple might contain. This works best if you know all the tuple elements will share a common base class or something similar.
In C++17, you can use std::apply with fold expression:
std::apply([](auto&&... args) {((/* args.dosomething() */), ...);}, the_tuple);
A complete example for printing a tuple:
#include <tuple>
#include <iostream>
int main()
{
std::tuple t{42, 'a', 4.2}; // Another C++17 feature: class template argument deduction
std::apply([](auto&&... args) {((std::cout << args << '\n'), ...);}, t);
}
[Online Example on Coliru]
This solution solves the issue of evaluation order in M. Alaggan's answer.
C++ is introducing expansion statements for this purpose. They were originally on track for C++20 but narrowly missed the cut due to a lack of time for language wording review (see here and here).
The currently agreed syntax (see the links above) is:
{
auto tup = std::make_tuple(0, 'a', 3.14);
template for (auto elem : tup)
std::cout << elem << std::endl;
}
Boost.Fusion is a possibility:
Untested example:
struct DoSomething
{
template<typename T>
void operator()(T& t) const
{
t.do_sth();
}
};
tuple<....> t = ...;
boost::fusion::for_each(t, DoSomething());
In C++17 you can do this:
std::apply([](auto ...x){std::make_tuple(x.do_something()...);} , the_tuple);
This already works in Clang++ 3.9, using std::experimental::apply.
A more simple, intuitive and compiler-friendly way of doing this in C++17, using if constexpr:
// prints every element of a tuple
template<size_t I = 0, typename... Tp>
void print(std::tuple<Tp...>& t) {
std::cout << std::get<I>(t) << " ";
// do things
if constexpr(I+1 != sizeof...(Tp))
print<I+1>(t);
}
This is compile-time recursion, similar to the one presented by #emsr. But this doesn't use SFINAE so (I think) it is more compiler-friendly.
Use Boost.Hana and generic lambdas:
#include <tuple>
#include <iostream>
#include <boost/hana.hpp>
#include <boost/hana/ext/std/tuple.hpp>
struct Foo1 {
int foo() const { return 42; }
};
struct Foo2 {
int bar = 0;
int foo() { bar = 24; return bar; }
};
int main() {
using namespace std;
using boost::hana::for_each;
Foo1 foo1;
Foo2 foo2;
for_each(tie(foo1, foo2), [](auto &foo) {
cout << foo.foo() << endl;
});
cout << "foo2.bar after mutation: " << foo2.bar << endl;
}
http://coliru.stacked-crooked.com/a/27b3691f55caf271
Here's an easy C++17 way of iterating over tuple items with just standard library:
#include <tuple> // std::tuple
#include <functional> // std::invoke
template <
size_t Index = 0, // start iteration at 0 index
typename TTuple, // the tuple type
size_t Size =
std::tuple_size_v<
std::remove_reference_t<TTuple>>, // tuple size
typename TCallable, // the callable to be invoked for each tuple item
typename... TArgs // other arguments to be passed to the callable
>
void for_each(TTuple&& tuple, TCallable&& callable, TArgs&&... args)
{
if constexpr (Index < Size)
{
std::invoke(callable, args..., std::get<Index>(tuple));
if constexpr (Index + 1 < Size)
for_each<Index + 1>(
std::forward<TTuple>(tuple),
std::forward<TCallable>(callable),
std::forward<TArgs>(args)...);
}
}
Example:
#include <iostream>
int main()
{
std::tuple<int, char> items{1, 'a'};
for_each(items, [](const auto& item) {
std::cout << item << "\n";
});
}
Output:
1
a
This can be extended to conditionally break the loop in case the callable returns a value (but still work with callables that do not return a bool assignable value, e.g. void):
#include <tuple> // std::tuple
#include <functional> // std::invoke
template <
size_t Index = 0, // start iteration at 0 index
typename TTuple, // the tuple type
size_t Size =
std::tuple_size_v<
std::remove_reference_t<TTuple>>, // tuple size
typename TCallable, // the callable to bo invoked for each tuple item
typename... TArgs // other arguments to be passed to the callable
>
void for_each(TTuple&& tuple, TCallable&& callable, TArgs&&... args)
{
if constexpr (Index < Size)
{
if constexpr (std::is_assignable_v<bool&, std::invoke_result_t<TCallable&&, TArgs&&..., decltype(std::get<Index>(tuple))>>)
{
if (!std::invoke(callable, args..., std::get<Index>(tuple)))
return;
}
else
{
std::invoke(callable, args..., std::get<Index>(tuple));
}
if constexpr (Index + 1 < Size)
for_each<Index + 1>(
std::forward<TTuple>(tuple),
std::forward<TCallable>(callable),
std::forward<TArgs>(args)...);
}
}
Example:
#include <iostream>
int main()
{
std::tuple<int, char> items{ 1, 'a' };
for_each(items, [](const auto& item) {
std::cout << item << "\n";
});
std::cout << "---\n";
for_each(items, [](const auto& item) {
std::cout << item << "\n";
return false;
});
}
Output:
1
a
---
1
You need to use template metaprogramming, here shown with Boost.Tuple:
#include <boost/tuple/tuple.hpp>
#include <iostream>
template <typename T_Tuple, size_t size>
struct print_tuple_helper {
static std::ostream & print( std::ostream & s, const T_Tuple & t ) {
return print_tuple_helper<T_Tuple,size-1>::print( s, t ) << boost::get<size-1>( t );
}
};
template <typename T_Tuple>
struct print_tuple_helper<T_Tuple,0> {
static std::ostream & print( std::ostream & s, const T_Tuple & ) {
return s;
}
};
template <typename T_Tuple>
std::ostream & print_tuple( std::ostream & s, const T_Tuple & t ) {
return print_tuple_helper<T_Tuple,boost::tuples::length<T_Tuple>::value>::print( s, t );
}
int main() {
const boost::tuple<int,char,float,char,double> t( 0, ' ', 2.5f, '\n', 3.1416 );
print_tuple( std::cout, t );
return 0;
}
In C++0x, you can write print_tuple() as a variadic template function instead.
First define some index helpers:
template <size_t ...I>
struct index_sequence {};
template <size_t N, size_t ...I>
struct make_index_sequence : public make_index_sequence<N - 1, N - 1, I...> {};
template <size_t ...I>
struct make_index_sequence<0, I...> : public index_sequence<I...> {};
With your function you would like to apply on each tuple element:
template <typename T>
/* ... */ foo(T t) { /* ... */ }
you can write:
template<typename ...T, size_t ...I>
/* ... */ do_foo_helper(std::tuple<T...> &ts, index_sequence<I...>) {
std::tie(foo(std::get<I>(ts)) ...);
}
template <typename ...T>
/* ... */ do_foo(std::tuple<T...> &ts) {
return do_foo_helper(ts, make_index_sequence<sizeof...(T)>());
}
Or if foo returns void, use
std::tie((foo(std::get<I>(ts)), 1) ... );
Note: On C++14 make_index_sequence is already defined (http://en.cppreference.com/w/cpp/utility/integer_sequence).
If you do need a left-to-right evaluation order, consider something like this:
template <typename T, typename ...R>
void do_foo_iter(T t, R ...r) {
foo(t);
do_foo(r...);
}
void do_foo_iter() {}
template<typename ...T, size_t ...I>
void do_foo_helper(std::tuple<T...> &ts, index_sequence<I...>) {
do_foo_iter(std::get<I>(ts) ...);
}
template <typename ...T>
void do_foo(std::tuple<T...> &ts) {
do_foo_helper(ts, make_index_sequence<sizeof...(T)>());
}
If you want to use std::tuple and you have C++ compiler which supports variadic templates, try code bellow (tested with g++4.5). This should be the answer to your question.
#include <tuple>
// ------------- UTILITY---------------
template<int...> struct index_tuple{};
template<int I, typename IndexTuple, typename... Types>
struct make_indexes_impl;
template<int I, int... Indexes, typename T, typename ... Types>
struct make_indexes_impl<I, index_tuple<Indexes...>, T, Types...>
{
typedef typename make_indexes_impl<I + 1, index_tuple<Indexes..., I>, Types...>::type type;
};
template<int I, int... Indexes>
struct make_indexes_impl<I, index_tuple<Indexes...> >
{
typedef index_tuple<Indexes...> type;
};
template<typename ... Types>
struct make_indexes : make_indexes_impl<0, index_tuple<>, Types...>
{};
// ----------- FOR EACH -----------------
template<typename Func, typename Last>
void for_each_impl(Func&& f, Last&& last)
{
f(last);
}
template<typename Func, typename First, typename ... Rest>
void for_each_impl(Func&& f, First&& first, Rest&&...rest)
{
f(first);
for_each_impl( std::forward<Func>(f), rest...);
}
template<typename Func, int ... Indexes, typename ... Args>
void for_each_helper( Func&& f, index_tuple<Indexes...>, std::tuple<Args...>&& tup)
{
for_each_impl( std::forward<Func>(f), std::forward<Args>(std::get<Indexes>(tup))...);
}
template<typename Func, typename ... Args>
void for_each( std::tuple<Args...>& tup, Func&& f)
{
for_each_helper(std::forward<Func>(f),
typename make_indexes<Args...>::type(),
std::forward<std::tuple<Args...>>(tup) );
}
template<typename Func, typename ... Args>
void for_each( std::tuple<Args...>&& tup, Func&& f)
{
for_each_helper(std::forward<Func>(f),
typename make_indexes<Args...>::type(),
std::forward<std::tuple<Args...>>(tup) );
}
boost::fusion is another option, but it requires its own tuple type: boost::fusion::tuple. Lets better stick to the standard! Here is a test:
#include <iostream>
// ---------- FUNCTOR ----------
struct Functor
{
template<typename T>
void operator()(T& t) const { std::cout << t << std::endl; }
};
int main()
{
for_each( std::make_tuple(2, 0.6, 'c'), Functor() );
return 0;
}
the power of variadic templates!
In MSVC STL there's a _For_each_tuple_element function (not documented):
#include <tuple>
// ...
std::tuple<int, char, float> values{};
std::_For_each_tuple_element(values, [](auto&& value)
{
// process 'value'
});
Another option would be to implement iterators for tuples. This has the advantage that you can use a variety of algorithms provided by the standard library and range-based for loops. An elegant approach to this is explained here https://foonathan.net/2017/03/tuple-iterator/. The basic idea is to turn tuples into a range with begin() and end() methods to provide iterators. The iterator itself returns a std::variant<...> which can then be visited using std::visit.
Here some examples:
auto t = std::tuple{ 1, 2.f, 3.0 };
auto r = to_range(t);
for(auto v : r)
{
std::visit(unwrap([](auto& x)
{
x = 1;
}), v);
}
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(unwrap([](auto& x)
{
x = 0;
}), v);
});
std::accumulate(begin(r), end(r), 0.0, [](auto acc, auto v)
{
return acc + std::visit(unwrap([](auto& x)
{
return static_cast<double>(x);
}), v);
});
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(unwrap([](const auto& x)
{
std::cout << x << std::endl;
}), v);
});
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(overload(
[](int x) { std::cout << "int" << std::endl; },
[](float x) { std::cout << "float" << std::endl; },
[](double x) { std::cout << "double" << std::endl; }), v);
});
My implementation (which is heavily based on the explanations in the link above):
#ifndef TUPLE_RANGE_H
#define TUPLE_RANGE_H
#include <utility>
#include <functional>
#include <variant>
#include <type_traits>
template<typename Accessor>
class tuple_iterator
{
public:
tuple_iterator(Accessor acc, const int idx)
: acc_(acc), index_(idx)
{
}
tuple_iterator operator++()
{
++index_;
return *this;
}
template<typename T>
bool operator ==(tuple_iterator<T> other)
{
return index_ == other.index();
}
template<typename T>
bool operator !=(tuple_iterator<T> other)
{
return index_ != other.index();
}
auto operator*() { return std::invoke(acc_, index_); }
[[nodiscard]] int index() const { return index_; }
private:
const Accessor acc_;
int index_;
};
template<bool IsConst, typename...Ts>
struct tuple_access
{
using tuple_type = std::tuple<Ts...>;
using tuple_ref = std::conditional_t<IsConst, const tuple_type&, tuple_type&>;
template<typename T>
using element_ref = std::conditional_t<IsConst,
std::reference_wrapper<const T>,
std::reference_wrapper<T>>;
using variant_type = std::variant<element_ref<Ts>...>;
using function_type = variant_type(*)(tuple_ref);
using table_type = std::array<function_type, sizeof...(Ts)>;
private:
template<size_t Index>
static constexpr function_type create_accessor()
{
return { [](tuple_ref t) -> variant_type
{
if constexpr (IsConst)
return std::cref(std::get<Index>(t));
else
return std::ref(std::get<Index>(t));
} };
}
template<size_t...Is>
static constexpr table_type create_table(std::index_sequence<Is...>)
{
return { create_accessor<Is>()... };
}
public:
static constexpr auto table = create_table(std::make_index_sequence<sizeof...(Ts)>{});
};
template<bool IsConst, typename...Ts>
class tuple_range
{
public:
using tuple_access_type = tuple_access<IsConst, Ts...>;
using tuple_ref = typename tuple_access_type::tuple_ref;
static constexpr auto tuple_size = sizeof...(Ts);
explicit tuple_range(tuple_ref tuple)
: tuple_(tuple)
{
}
[[nodiscard]] auto begin() const
{
return tuple_iterator{ create_accessor(), 0 };
}
[[nodiscard]] auto end() const
{
return tuple_iterator{ create_accessor(), tuple_size };
}
private:
tuple_ref tuple_;
auto create_accessor() const
{
return [this](int idx)
{
return std::invoke(tuple_access_type::table[idx], tuple_);
};
}
};
template<bool IsConst, typename...Ts>
auto begin(const tuple_range<IsConst, Ts...>& r)
{
return r.begin();
}
template<bool IsConst, typename...Ts>
auto end(const tuple_range<IsConst, Ts...>& r)
{
return r.end();
}
template <class ... Fs>
struct overload : Fs... {
explicit overload(Fs&&... fs) : Fs{ fs }... {}
using Fs::operator()...;
template<class T>
auto operator()(std::reference_wrapper<T> ref)
{
return (*this)(ref.get());
}
template<class T>
auto operator()(std::reference_wrapper<const T> ref)
{
return (*this)(ref.get());
}
};
template <class F>
struct unwrap : overload<F>
{
explicit unwrap(F&& f) : overload<F>{ std::forward<F>(f) } {}
using overload<F>::operator();
};
template<typename...Ts>
auto to_range(std::tuple<Ts...>& t)
{
return tuple_range<false, Ts...>{t};
}
template<typename...Ts>
auto to_range(const std::tuple<Ts...>& t)
{
return tuple_range<true, Ts...>{t};
}
#endif
Read-only access is also supported by passing a const std::tuple<>& to to_range().
Others have mentioned some well-designed third-party libraries that you may turn to. However, if you are using C++ without those third-party libraries, the following code may help.
namespace detail {
template <class Tuple, std::size_t I, class = void>
struct for_each_in_tuple_helper {
template <class UnaryFunction>
static void apply(Tuple&& tp, UnaryFunction& f) {
f(std::get<I>(std::forward<Tuple>(tp)));
for_each_in_tuple_helper<Tuple, I + 1u>::apply(std::forward<Tuple>(tp), f);
}
};
template <class Tuple, std::size_t I>
struct for_each_in_tuple_helper<Tuple, I, typename std::enable_if<
I == std::tuple_size<typename std::decay<Tuple>::type>::value>::type> {
template <class UnaryFunction>
static void apply(Tuple&&, UnaryFunction&) {}
};
} // namespace detail
template <class Tuple, class UnaryFunction>
UnaryFunction for_each_in_tuple(Tuple&& tp, UnaryFunction f) {
detail::for_each_in_tuple_helper<Tuple, 0u>
::apply(std::forward<Tuple>(tp), f);
return std::move(f);
}
Note: The code compiles with any compiler supporing C++11, and it keeps consistency with design of the standard library:
The tuple need not be std::tuple, and instead may be anything that supports std::get and std::tuple_size; in particular, std::array and std::pair may be used;
The tuple may be a reference type or cv-qualified;
It has similar behavior as std::for_each, and returns the input UnaryFunction;
For C++14 (or laster version) users, typename std::enable_if<T>::type and typename std::decay<T>::type could be replaced with their simplified version, std::enable_if_t<T> and std::decay_t<T>;
For C++17 (or laster version) users, std::tuple_size<T>::value could be replaced with its simplified version, std::tuple_size_v<T>.
For C++20 (or laster version) users, the SFINAE feature could be implemented with the Concepts.
Using constexpr and if constexpr(C++17) this is fairly simple and straight forward:
template <std::size_t I = 0, typename ... Ts>
void print(std::tuple<Ts...> tup) {
if constexpr (I == sizeof...(Ts)) {
return;
} else {
std::cout << std::get<I>(tup) << ' ';
print<I+1>(tup);
}
}
I might have missed this train, but this will be here for future reference.
Here's my construct based on this answer and on this gist:
#include <tuple>
#include <utility>
template<std::size_t N>
struct tuple_functor
{
template<typename T, typename F>
static void run(std::size_t i, T&& t, F&& f)
{
const std::size_t I = (N - 1);
switch(i)
{
case I:
std::forward<F>(f)(std::get<I>(std::forward<T>(t)));
break;
default:
tuple_functor<I>::run(i, std::forward<T>(t), std::forward<F>(f));
}
}
};
template<>
struct tuple_functor<0>
{
template<typename T, typename F>
static void run(std::size_t, T, F){}
};
You then use it as follow:
template<typename... T>
void logger(std::string format, T... args) //behaves like C#'s String.Format()
{
auto tp = std::forward_as_tuple(args...);
auto fc = [](const auto& t){std::cout << t;};
/* ... */
std::size_t some_index = ...
tuple_functor<sizeof...(T)>::run(some_index, tp, fc);
/* ... */
}
There could be room for improvements.
As per OP's code, it would become this:
const std::size_t num = sizeof...(T);
auto my_tuple = std::forward_as_tuple(t...);
auto do_sth = [](const auto& elem){/* ... */};
for(int i = 0; i < num; ++i)
tuple_functor<num>::run(i, my_tuple, do_sth);
Of all the answers I've seen here, here and here, I liked #sigidagi's way of iterating best. Unfortunately, his answer is very verbose which in my opinion obscures the inherent clarity.
This is my version of his solution which is more concise and works with std::tuple, std::pair and std::array.
template<typename UnaryFunction>
void invoke_with_arg(UnaryFunction)
{}
/**
* Invoke the unary function with each of the arguments in turn.
*/
template<typename UnaryFunction, typename Arg0, typename... Args>
void invoke_with_arg(UnaryFunction f, Arg0&& a0, Args&&... as)
{
f(std::forward<Arg0>(a0));
invoke_with_arg(std::move(f), std::forward<Args>(as)...);
}
template<typename Tuple, typename UnaryFunction, std::size_t... Indices>
void for_each_helper(Tuple&& t, UnaryFunction f, std::index_sequence<Indices...>)
{
using std::get;
invoke_with_arg(std::move(f), get<Indices>(std::forward<Tuple>(t))...);
}
/**
* Invoke the unary function for each of the elements of the tuple.
*/
template<typename Tuple, typename UnaryFunction>
void for_each(Tuple&& t, UnaryFunction f)
{
using size = std::tuple_size<typename std::remove_reference<Tuple>::type>;
for_each_helper(
std::forward<Tuple>(t),
std::move(f),
std::make_index_sequence<size::value>()
);
}
Demo: coliru
C++14's std::make_index_sequence can be implemented for C++11.
Expanding on #Stypox answer, we can make their solution more generic (C++17 onward). By adding a callable function argument:
template<size_t I = 0, typename... Tp, typename F>
void for_each_apply(std::tuple<Tp...>& t, F &&f) {
f(std::get<I>(t));
if constexpr(I+1 != sizeof...(Tp)) {
for_each_apply<I+1>(t, std::forward<F>(f));
}
}
Then, we need a strategy to visit each type.
Let start with some helpers (first two taken from cppreference):
template<class... Ts> struct overloaded : Ts... { using Ts::operator()...; };
template<class... Ts> overloaded(Ts...) -> overloaded<Ts...>;
template<class ... Ts> struct variant_ref { using type = std::variant<std::reference_wrapper<Ts>...>; };
variant_ref is used to allow tuples' state to be modified.
Usage:
std::tuple<Foo, Bar, Foo> tuples;
for_each_apply(tuples,
[](variant_ref<Foo, Bar>::type &&v) {
std::visit(overloaded {
[](Foo &arg) { arg.foo(); },
[](Bar const &arg) { arg.bar(); },
}, v);
});
Result:
Foo0
Bar
Foo0
Foo1
Bar
Foo1
For completeness, here are my Bar & Foo:
struct Foo {
void foo() {std::cout << "Foo" << i++ << std::endl;}
int i = 0;
};
struct Bar {
void bar() const {std::cout << "Bar" << std::endl;}
};
I have stumbled on the same problem for iterating over a tuple of function objects, so here is one more solution:
#include <tuple>
#include <iostream>
// Function objects
class A
{
public:
inline void operator()() const { std::cout << "A\n"; };
};
class B
{
public:
inline void operator()() const { std::cout << "B\n"; };
};
class C
{
public:
inline void operator()() const { std::cout << "C\n"; };
};
class D
{
public:
inline void operator()() const { std::cout << "D\n"; };
};
// Call iterator using recursion.
template<typename Fobjects, int N = 0>
struct call_functors
{
static void apply(Fobjects const& funcs)
{
std::get<N>(funcs)();
// Choose either the stopper or descend further,
// depending if N + 1 < size of the tuple.
using caller = std::conditional_t
<
N + 1 < std::tuple_size_v<Fobjects>,
call_functors<Fobjects, N + 1>,
call_functors<Fobjects, -1>
>;
caller::apply(funcs);
}
};
// Stopper.
template<typename Fobjects>
struct call_functors<Fobjects, -1>
{
static void apply(Fobjects const& funcs)
{
}
};
// Call dispatch function.
template<typename Fobjects>
void call(Fobjects const& funcs)
{
call_functors<Fobjects>::apply(funcs);
};
using namespace std;
int main()
{
using Tuple = tuple<A,B,C,D>;
Tuple functors = {A{}, B{}, C{}, D{}};
call(functors);
return 0;
}
Output:
A
B
C
D
There're many great answers, but for some reason most of them don't consider returning the results of applying f to our tuple...
or did I overlook it? Anyway, here's yet another way you can do that:
Doing Foreach with style (debatable)
auto t = std::make_tuple(1, "two", 3.f);
t | foreach([](auto v){ std::cout << v << " "; });
And returning from that:
auto t = std::make_tuple(1, "two", 3.f);
auto sizes = t | foreach([](auto v) {
return sizeof(v);
});
sizes | foreach([](auto v) {
std::cout << v;
});
Implementation (pretty simple one)
Edit: it gets a little messier.
I won't include some metaprogramming boilerplate here, for it will definitely make things less readable and besides, I believe those have already been answered somewhere on stackoverflow.
In case you're feeling lazy, feel free to peek into my github repo for implementation of both
#include <utility>
// Optional includes, if you don't want to implement it by hand or google it
// you can find it in the repo (link below)
#include "typesystem/typelist.hpp"
// used to check if all return types are void,
// making it a special case
// (and, alas, not using constexpr-if
// for the sake of being compatible with C++14...)
template <bool Cond, typename T, typename F>
using select = typename std::conditional<Cond, T, F>::type;
template <typename F>
struct elementwise_apply {
F f;
};
template <typename F>
constexpr auto foreach(F && f) -> elementwise_apply<F> { return {std::forward<F>(f)}; }
template <typename R>
struct tuple_map {
template <typename F, typename T, size_t... Is>
static constexpr decltype(auto) impl(std::index_sequence<Is...>, F && f, T&& tuple) {
return R{ std::forward<F>(f)( std::get<Is>(tuple) )... };
}
};
template<>
struct tuple_map<void> {
template <typename F, typename T, size_t... Is>
static constexpr void impl(std::index_sequence<Is...>, F && f, T&& tuple) {
[[maybe_unused]] std::initializer_list<int> _ {((void)std::forward<F>(f)( std::get<Is>(tuple) ), 0)... };
}
};
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> & t, fmap<F> && op) {
constexpr bool all_void = core::Types<decltype( std::move(op).f(std::declval<Ts&>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, t);
}
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> const& t, fmap<F> && op) {
constexpr bool all_void = check if all "decltype( std::move(op).f(std::declval<Ts>()) )..." types are void, since then it's a special case
// e.g. core::Types<decltype( std::move(op).f(std::declval<Ts>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts const&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, t);
}
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> && t, fmap<F> && op) {
constexpr bool all_void = core::Types<decltype( std::move(op).f(std::declval<Ts&&>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts&&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, std::move(t));
}
Yeah, that would be much nicer if we were to use C++17
This is also an example of std::moving object's members, for which I'll better refer to this nice brief article
P.S. If you're stuck checking if all "decltype( std::move(op).f(std::declval()) )..." types are void
you can find some metaprogramming library, or, if those libraries seem too hard to grasp (which some of them may be due to some crazy metaprogramming tricks), you know where to look
template <typename F, typename T>
static constexpr size_t
foreach_in_tuple(std::tuple<T> & tuple, F && do_, size_t index_ = 0)
{
do_(tuple, index_);
return index_;
}
template <typename F, typename T, typename U, typename... Types>
static constexpr size_t
foreach_in_tuple(std::tuple<T,U,Types...> & tuple, F && do_, size_t index_ = 0)
{
if(!do_(tuple, index_))
return index_;
auto & next_tuple = reinterpret_cast<std::tuple<U,Types...> &>(tuple);
return foreach_in_tuple(next_tuple, std::forward<F>(do_), index_+1);
}
int main()
{
using namespace std;
auto tup = make_tuple(1, 2.3f, 'G', "hello");
foreach_in_tuple(tup, [](auto & tuple, size_t i)
{
auto & value = std::get<0>(tuple);
std::cout << i << " " << value << std::endl;
// if(i >= 2) return false; // break;
return true; // continue
});
}
Here is a solution based on std::interger_sequence.
As I don't know if my_tuple is constructed from std::make_tuple<T>(T &&...) in your code. It's essential for how to construct std::integer_sequence in the solution below.
(1) if your already have a my_tuple outside your function(not using template<typename ...T>), You can use
[](auto my_tuple)
{
[&my_tuple]<typename N, N... n>(std::integer_sequence<N, n...> int_seq)
{
((std::cout << std::get<n>(my_tuple) << '\n'), ...);
}(std::make_index_sequence<std::tuple_size_v<decltype(my_tuple)>>{});
}(std::make_tuple());
(2) if your havn't constructed my_tuple in your function and want to handle your T ...arguments
[]<typename ...T>(T... args)
{
[&args...]<typename N, N... n>(std::integer_sequence<N, n...> int_seq)
{
((std::cout << std::get<n>(std::forward_as_tuple(args...)) << '\n'), ...);
}(std::index_sequence_for<T...>{});
}();
boost's tuple provides helper functions get_head() and get_tail() so your helper functions may look like this:
inline void call_do_sth(const null_type&) {};
template <class H, class T>
inline void call_do_sth(cons<H, T>& x) { x.get_head().do_sth(); call_do_sth(x.get_tail()); }
as described in here http://www.boost.org/doc/libs/1_34_0/libs/tuple/doc/tuple_advanced_interface.html
with std::tuple it should be similar.
Actually, unfortunately std::tuple does not seem to provide such interface, so methods suggested before should work, or you would need to switch to boost::tuple which has other benefits (like io operators already provided). Though there is downside of boost::tuple with gcc - it does not accept variadic templates yet, but that may be already fixed as I do not have latest version of boost installed on my machine.
Let me please consider the following synthetic example:
inline int fun2(int x) {
return x;
}
inline int fun2(double x) {
return 0;
}
inline int fun2(float x) {
return -1;
}
int fun(const std::tuple<int,double,float>& t, std::size_t i) {
switch(i) {
case 0: return fun2(std::get<0>(t));
case 1: return fun2(std::get<1>(t));
case 2: return fun2(std::get<2>(t));
}
}
The question is how should I expand this to the general case
template<class... Args> int fun(const std::tuple<Args...>& t, std::size_t i) {
// ?
}
Guaranteeing that
fun2 can be inlined into fun
search complexity not worse than O(log(i)) (for large i).
It is known that optimizer usually uses lookup jump table or compile-time binary search tree when large enough switch expanded. So, I would like to keep this property affecting performance for large number of items.
Update #3: I remeasured performance with uniform random index value:
1 10 20 100
#TartanLlama
gcc ~0 42.9235 44.7900 46.5233
clang 10.2046 38.7656 40.4316 41.7557
#chris-beck
gcc ~0 37.564 51.3653 81.552
clang ~0 38.0361 51.6968 83.7704
naive tail recursion
gcc 3.0798 40.6061 48.6744 118.171
clang 11.5907 40.6197 42.8172 137.066
manual switch statement
gcc 41.7236
clang 7.3768
Update #2: It seems that clang is able to inline functions in #TartanLlama solution whereas gcc always generates function call.
Ok, I rewrote my answer. This gives a different approach to what TartanLlama and also what I suggested before. This meets your complexity requirement and doesn't use function pointers so everything is inlineable.
Edit: Much thanks to Yakk for pointing out a quite significant optimization (for the compile-time template recursion depth required) in comments
Basically I make a binary tree of the types / function handlers using templates, and implement the binary search manually.
It might be possible to do this more cleanly using either mpl or boost::fusion, but this implementation is self-contained anyways.
It definitely meets your requirements, that the functions are inlineable and runtime look up is O(log n) in the number of types in the tuple.
Here's the complete listing:
#include <cassert>
#include <cstdint>
#include <tuple>
#include <iostream>
using std::size_t;
// Basic typelist object
template<typename... TL>
struct TypeList{
static const int size = sizeof...(TL);
};
// Metafunction Concat: Concatenate two typelists
template<typename L, typename R>
struct Concat;
template<typename... TL, typename... TR>
struct Concat <TypeList<TL...>, TypeList<TR...>> {
typedef TypeList<TL..., TR...> type;
};
template<typename L, typename R>
using Concat_t = typename Concat<L,R>::type;
// Metafunction First: Get first type from a typelist
template<typename T>
struct First;
template<typename T, typename... TL>
struct First <TypeList<T, TL...>> {
typedef T type;
};
template<typename T>
using First_t = typename First<T>::type;
// Metafunction Split: Split a typelist at a particular index
template<int i, typename TL>
struct Split;
template<int k, typename... TL>
struct Split<k, TypeList<TL...>> {
private:
typedef Split<k/2, TypeList<TL...>> FirstSplit;
typedef Split<k-k/2, typename FirstSplit::R> SecondSplit;
public:
typedef Concat_t<typename FirstSplit::L, typename SecondSplit::L> L;
typedef typename SecondSplit::R R;
};
template<typename T, typename... TL>
struct Split<0, TypeList<T, TL...>> {
typedef TypeList<> L;
typedef TypeList<T, TL...> R;
};
template<typename T, typename... TL>
struct Split<1, TypeList<T, TL...>> {
typedef TypeList<T> L;
typedef TypeList<TL...> R;
};
template<int k>
struct Split<k, TypeList<>> {
typedef TypeList<> L;
typedef TypeList<> R;
};
// Metafunction Subdivide: Split a typelist into two roughly equal typelists
template<typename TL>
struct Subdivide : Split<TL::size / 2, TL> {};
// Metafunction MakeTree: Make a tree from a typelist
template<typename T>
struct MakeTree;
/*
template<>
struct MakeTree<TypeList<>> {
typedef TypeList<> L;
typedef TypeList<> R;
static const int size = 0;
};*/
template<typename T>
struct MakeTree<TypeList<T>> {
typedef TypeList<> L;
typedef TypeList<T> R;
static const int size = R::size;
};
template<typename T1, typename T2, typename... TL>
struct MakeTree<TypeList<T1, T2, TL...>> {
private:
typedef TypeList<T1, T2, TL...> MyList;
typedef Subdivide<MyList> MySubdivide;
public:
typedef MakeTree<typename MySubdivide::L> L;
typedef MakeTree<typename MySubdivide::R> R;
static const int size = L::size + R::size;
};
// Typehandler: What our lists will be made of
template<typename T>
struct type_handler_helper {
typedef int result_type;
typedef T input_type;
typedef result_type (*func_ptr_type)(const input_type &);
};
template<typename T, typename type_handler_helper<T>::func_ptr_type me>
struct type_handler {
typedef type_handler_helper<T> base;
typedef typename base::func_ptr_type func_ptr_type;
typedef typename base::result_type result_type;
typedef typename base::input_type input_type;
static constexpr func_ptr_type my_func = me;
static result_type apply(const input_type & t) {
return me(t);
}
};
// Binary search implementation
template <typename T, bool b = (T::L::size != 0)>
struct apply_helper;
template <typename T>
struct apply_helper<T, false> {
template<typename V>
static int apply(const V & v, size_t index) {
assert(index == 0);
return First_t<typename T::R>::apply(v);
}
};
template <typename T>
struct apply_helper<T, true> {
template<typename V>
static int apply(const V & v, size_t index) {
if( index >= T::L::size ) {
return apply_helper<typename T::R>::apply(v, index - T::L::size);
} else {
return apply_helper<typename T::L>::apply(v, index);
}
}
};
// Original functions
inline int fun2(int x) {
return x;
}
inline int fun2(double x) {
return 0;
}
inline int fun2(float x) {
return -1;
}
// Adapted functions
typedef std::tuple<int, double, float> tup;
inline int g0(const tup & t) { return fun2(std::get<0>(t)); }
inline int g1(const tup & t) { return fun2(std::get<1>(t)); }
inline int g2(const tup & t) { return fun2(std::get<2>(t)); }
// Registry
typedef TypeList<
type_handler<tup, &g0>,
type_handler<tup, &g1>,
type_handler<tup, &g2>
> registry;
typedef MakeTree<registry> jump_table;
int apply(const tup & t, size_t index) {
return apply_helper<jump_table>::apply(t, index);
}
// Demo
int main() {
{
tup t{5, 1.5, 15.5f};
std::cout << apply(t, 0) << std::endl;
std::cout << apply(t, 1) << std::endl;
std::cout << apply(t, 2) << std::endl;
}
{
tup t{10, 1.5, 15.5f};
std::cout << apply(t, 0) << std::endl;
std::cout << apply(t, 1) << std::endl;
std::cout << apply(t, 2) << std::endl;
}
{
tup t{15, 1.5, 15.5f};
std::cout << apply(t, 0) << std::endl;
std::cout << apply(t, 1) << std::endl;
std::cout << apply(t, 2) << std::endl;
}
{
tup t{20, 1.5, 15.5f};
std::cout << apply(t, 0) << std::endl;
std::cout << apply(t, 1) << std::endl;
std::cout << apply(t, 2) << std::endl;
}
}
Live on Coliru:
http://coliru.stacked-crooked.com/a/3cfbd4d9ebd3bb3a
If you make fun2 into a class with overloaded operator():
struct fun2 {
inline int operator()(int x) {
return x;
}
inline int operator()(double x) {
return 0;
}
inline int operator()(float x) {
return -1;
}
};
then we can modify dyp's answer from here to work for us.
Note that this would look a lot neater in C++14, as we could have all the return types deduced and use std::index_sequence.
//call the function with the tuple element at the given index
template<class Ret, int N, class T, class Func>
auto apply_one(T&& p, Func func) -> Ret
{
return func( std::get<N>(std::forward<T>(p)) );
}
//call with runtime index
template<class Ret, class T, class Func, int... Is>
auto apply(T&& p, int index, Func func, seq<Is...>) -> Ret
{
using FT = Ret(T&&, Func);
//build up a constexpr array of function pointers to index
static constexpr FT* arr[] = { &apply_one<Ret, Is, T&&, Func>... };
//call the function pointer at the specified index
return arr[index](std::forward<T>(p), func);
}
//tag dispatcher
template<class Ret, class T, class Func>
auto apply(T&& p, int index, Func func) -> Ret
{
return apply<Ret>(std::forward<T>(p), index, func,
gen_seq<std::tuple_size<typename std::decay<T>::type>::value>{});
}
We then call apply and pass the return type as a template argument (you could deduce this using decltype or C++14):
auto t = std::make_tuple(1,1.0,1.0f);
std::cout << apply<int>(t, 0, fun2{}) << std::endl;
std::cout << apply<int>(t, 1, fun2{}) << std::endl;
std::cout << apply<int>(t, 2, fun2{}) << std::endl;
Live Demo
I'm not sure if this will completely fulfil your requirements due to the use of function pointers, but compilers can optimize this kind of thing pretty aggressively. The searching will be O(1) as the pointer array is just built once then indexed directly, which is pretty good. I'd try this out, measure, and see if it'll work for you.
How can I iterate over a tuple (using C++11)? I tried the following:
for(int i=0; i<std::tuple_size<T...>::value; ++i)
std::get<i>(my_tuple).do_sth();
but this doesn't work:
Error 1: sorry, unimplemented: cannot expand ‘Listener ...’ into a fixed-length argument list.
Error 2: i cannot appear in a constant expression.
So, how do I correctly iterate over the elements of a tuple?
I have an answer based on Iterating over a Tuple:
#include <tuple>
#include <utility>
#include <iostream>
template<std::size_t I = 0, typename... Tp>
inline typename std::enable_if<I == sizeof...(Tp), void>::type
print(std::tuple<Tp...>& t)
{ }
template<std::size_t I = 0, typename... Tp>
inline typename std::enable_if<I < sizeof...(Tp), void>::type
print(std::tuple<Tp...>& t)
{
std::cout << std::get<I>(t) << std::endl;
print<I + 1, Tp...>(t);
}
int
main()
{
typedef std::tuple<int, float, double> T;
T t = std::make_tuple(2, 3.14159F, 2345.678);
print(t);
}
The usual idea is to use compile time recursion. In fact, this idea is used to make a printf that is type safe as noted in the original tuple papers.
This can be easily generalized into a for_each for tuples:
#include <tuple>
#include <utility>
template<std::size_t I = 0, typename FuncT, typename... Tp>
inline typename std::enable_if<I == sizeof...(Tp), void>::type
for_each(std::tuple<Tp...> &, FuncT) // Unused arguments are given no names.
{ }
template<std::size_t I = 0, typename FuncT, typename... Tp>
inline typename std::enable_if<I < sizeof...(Tp), void>::type
for_each(std::tuple<Tp...>& t, FuncT f)
{
f(std::get<I>(t));
for_each<I + 1, FuncT, Tp...>(t, f);
}
Though this then requires some effort to have FuncT represent something with the appropriate overloads for every type the tuple might contain. This works best if you know all the tuple elements will share a common base class or something similar.
In C++17, you can use std::apply with fold expression:
std::apply([](auto&&... args) {((/* args.dosomething() */), ...);}, the_tuple);
A complete example for printing a tuple:
#include <tuple>
#include <iostream>
int main()
{
std::tuple t{42, 'a', 4.2}; // Another C++17 feature: class template argument deduction
std::apply([](auto&&... args) {((std::cout << args << '\n'), ...);}, t);
}
[Online Example on Coliru]
This solution solves the issue of evaluation order in M. Alaggan's answer.
C++ is introducing expansion statements for this purpose. They were originally on track for C++20 but narrowly missed the cut due to a lack of time for language wording review (see here and here).
The currently agreed syntax (see the links above) is:
{
auto tup = std::make_tuple(0, 'a', 3.14);
template for (auto elem : tup)
std::cout << elem << std::endl;
}
Boost.Fusion is a possibility:
Untested example:
struct DoSomething
{
template<typename T>
void operator()(T& t) const
{
t.do_sth();
}
};
tuple<....> t = ...;
boost::fusion::for_each(t, DoSomething());
In C++17 you can do this:
std::apply([](auto ...x){std::make_tuple(x.do_something()...);} , the_tuple);
This already works in Clang++ 3.9, using std::experimental::apply.
A more simple, intuitive and compiler-friendly way of doing this in C++17, using if constexpr:
// prints every element of a tuple
template<size_t I = 0, typename... Tp>
void print(std::tuple<Tp...>& t) {
std::cout << std::get<I>(t) << " ";
// do things
if constexpr(I+1 != sizeof...(Tp))
print<I+1>(t);
}
This is compile-time recursion, similar to the one presented by #emsr. But this doesn't use SFINAE so (I think) it is more compiler-friendly.
Use Boost.Hana and generic lambdas:
#include <tuple>
#include <iostream>
#include <boost/hana.hpp>
#include <boost/hana/ext/std/tuple.hpp>
struct Foo1 {
int foo() const { return 42; }
};
struct Foo2 {
int bar = 0;
int foo() { bar = 24; return bar; }
};
int main() {
using namespace std;
using boost::hana::for_each;
Foo1 foo1;
Foo2 foo2;
for_each(tie(foo1, foo2), [](auto &foo) {
cout << foo.foo() << endl;
});
cout << "foo2.bar after mutation: " << foo2.bar << endl;
}
http://coliru.stacked-crooked.com/a/27b3691f55caf271
Here's an easy C++17 way of iterating over tuple items with just standard library:
#include <tuple> // std::tuple
#include <functional> // std::invoke
template <
size_t Index = 0, // start iteration at 0 index
typename TTuple, // the tuple type
size_t Size =
std::tuple_size_v<
std::remove_reference_t<TTuple>>, // tuple size
typename TCallable, // the callable to be invoked for each tuple item
typename... TArgs // other arguments to be passed to the callable
>
void for_each(TTuple&& tuple, TCallable&& callable, TArgs&&... args)
{
if constexpr (Index < Size)
{
std::invoke(callable, args..., std::get<Index>(tuple));
if constexpr (Index + 1 < Size)
for_each<Index + 1>(
std::forward<TTuple>(tuple),
std::forward<TCallable>(callable),
std::forward<TArgs>(args)...);
}
}
Example:
#include <iostream>
int main()
{
std::tuple<int, char> items{1, 'a'};
for_each(items, [](const auto& item) {
std::cout << item << "\n";
});
}
Output:
1
a
This can be extended to conditionally break the loop in case the callable returns a value (but still work with callables that do not return a bool assignable value, e.g. void):
#include <tuple> // std::tuple
#include <functional> // std::invoke
template <
size_t Index = 0, // start iteration at 0 index
typename TTuple, // the tuple type
size_t Size =
std::tuple_size_v<
std::remove_reference_t<TTuple>>, // tuple size
typename TCallable, // the callable to bo invoked for each tuple item
typename... TArgs // other arguments to be passed to the callable
>
void for_each(TTuple&& tuple, TCallable&& callable, TArgs&&... args)
{
if constexpr (Index < Size)
{
if constexpr (std::is_assignable_v<bool&, std::invoke_result_t<TCallable&&, TArgs&&..., decltype(std::get<Index>(tuple))>>)
{
if (!std::invoke(callable, args..., std::get<Index>(tuple)))
return;
}
else
{
std::invoke(callable, args..., std::get<Index>(tuple));
}
if constexpr (Index + 1 < Size)
for_each<Index + 1>(
std::forward<TTuple>(tuple),
std::forward<TCallable>(callable),
std::forward<TArgs>(args)...);
}
}
Example:
#include <iostream>
int main()
{
std::tuple<int, char> items{ 1, 'a' };
for_each(items, [](const auto& item) {
std::cout << item << "\n";
});
std::cout << "---\n";
for_each(items, [](const auto& item) {
std::cout << item << "\n";
return false;
});
}
Output:
1
a
---
1
You need to use template metaprogramming, here shown with Boost.Tuple:
#include <boost/tuple/tuple.hpp>
#include <iostream>
template <typename T_Tuple, size_t size>
struct print_tuple_helper {
static std::ostream & print( std::ostream & s, const T_Tuple & t ) {
return print_tuple_helper<T_Tuple,size-1>::print( s, t ) << boost::get<size-1>( t );
}
};
template <typename T_Tuple>
struct print_tuple_helper<T_Tuple,0> {
static std::ostream & print( std::ostream & s, const T_Tuple & ) {
return s;
}
};
template <typename T_Tuple>
std::ostream & print_tuple( std::ostream & s, const T_Tuple & t ) {
return print_tuple_helper<T_Tuple,boost::tuples::length<T_Tuple>::value>::print( s, t );
}
int main() {
const boost::tuple<int,char,float,char,double> t( 0, ' ', 2.5f, '\n', 3.1416 );
print_tuple( std::cout, t );
return 0;
}
In C++0x, you can write print_tuple() as a variadic template function instead.
First define some index helpers:
template <size_t ...I>
struct index_sequence {};
template <size_t N, size_t ...I>
struct make_index_sequence : public make_index_sequence<N - 1, N - 1, I...> {};
template <size_t ...I>
struct make_index_sequence<0, I...> : public index_sequence<I...> {};
With your function you would like to apply on each tuple element:
template <typename T>
/* ... */ foo(T t) { /* ... */ }
you can write:
template<typename ...T, size_t ...I>
/* ... */ do_foo_helper(std::tuple<T...> &ts, index_sequence<I...>) {
std::tie(foo(std::get<I>(ts)) ...);
}
template <typename ...T>
/* ... */ do_foo(std::tuple<T...> &ts) {
return do_foo_helper(ts, make_index_sequence<sizeof...(T)>());
}
Or if foo returns void, use
std::tie((foo(std::get<I>(ts)), 1) ... );
Note: On C++14 make_index_sequence is already defined (http://en.cppreference.com/w/cpp/utility/integer_sequence).
If you do need a left-to-right evaluation order, consider something like this:
template <typename T, typename ...R>
void do_foo_iter(T t, R ...r) {
foo(t);
do_foo(r...);
}
void do_foo_iter() {}
template<typename ...T, size_t ...I>
void do_foo_helper(std::tuple<T...> &ts, index_sequence<I...>) {
do_foo_iter(std::get<I>(ts) ...);
}
template <typename ...T>
void do_foo(std::tuple<T...> &ts) {
do_foo_helper(ts, make_index_sequence<sizeof...(T)>());
}
If you want to use std::tuple and you have C++ compiler which supports variadic templates, try code bellow (tested with g++4.5). This should be the answer to your question.
#include <tuple>
// ------------- UTILITY---------------
template<int...> struct index_tuple{};
template<int I, typename IndexTuple, typename... Types>
struct make_indexes_impl;
template<int I, int... Indexes, typename T, typename ... Types>
struct make_indexes_impl<I, index_tuple<Indexes...>, T, Types...>
{
typedef typename make_indexes_impl<I + 1, index_tuple<Indexes..., I>, Types...>::type type;
};
template<int I, int... Indexes>
struct make_indexes_impl<I, index_tuple<Indexes...> >
{
typedef index_tuple<Indexes...> type;
};
template<typename ... Types>
struct make_indexes : make_indexes_impl<0, index_tuple<>, Types...>
{};
// ----------- FOR EACH -----------------
template<typename Func, typename Last>
void for_each_impl(Func&& f, Last&& last)
{
f(last);
}
template<typename Func, typename First, typename ... Rest>
void for_each_impl(Func&& f, First&& first, Rest&&...rest)
{
f(first);
for_each_impl( std::forward<Func>(f), rest...);
}
template<typename Func, int ... Indexes, typename ... Args>
void for_each_helper( Func&& f, index_tuple<Indexes...>, std::tuple<Args...>&& tup)
{
for_each_impl( std::forward<Func>(f), std::forward<Args>(std::get<Indexes>(tup))...);
}
template<typename Func, typename ... Args>
void for_each( std::tuple<Args...>& tup, Func&& f)
{
for_each_helper(std::forward<Func>(f),
typename make_indexes<Args...>::type(),
std::forward<std::tuple<Args...>>(tup) );
}
template<typename Func, typename ... Args>
void for_each( std::tuple<Args...>&& tup, Func&& f)
{
for_each_helper(std::forward<Func>(f),
typename make_indexes<Args...>::type(),
std::forward<std::tuple<Args...>>(tup) );
}
boost::fusion is another option, but it requires its own tuple type: boost::fusion::tuple. Lets better stick to the standard! Here is a test:
#include <iostream>
// ---------- FUNCTOR ----------
struct Functor
{
template<typename T>
void operator()(T& t) const { std::cout << t << std::endl; }
};
int main()
{
for_each( std::make_tuple(2, 0.6, 'c'), Functor() );
return 0;
}
the power of variadic templates!
In MSVC STL there's a _For_each_tuple_element function (not documented):
#include <tuple>
// ...
std::tuple<int, char, float> values{};
std::_For_each_tuple_element(values, [](auto&& value)
{
// process 'value'
});
Another option would be to implement iterators for tuples. This has the advantage that you can use a variety of algorithms provided by the standard library and range-based for loops. An elegant approach to this is explained here https://foonathan.net/2017/03/tuple-iterator/. The basic idea is to turn tuples into a range with begin() and end() methods to provide iterators. The iterator itself returns a std::variant<...> which can then be visited using std::visit.
Here some examples:
auto t = std::tuple{ 1, 2.f, 3.0 };
auto r = to_range(t);
for(auto v : r)
{
std::visit(unwrap([](auto& x)
{
x = 1;
}), v);
}
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(unwrap([](auto& x)
{
x = 0;
}), v);
});
std::accumulate(begin(r), end(r), 0.0, [](auto acc, auto v)
{
return acc + std::visit(unwrap([](auto& x)
{
return static_cast<double>(x);
}), v);
});
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(unwrap([](const auto& x)
{
std::cout << x << std::endl;
}), v);
});
std::for_each(begin(r), end(r), [](auto v)
{
std::visit(overload(
[](int x) { std::cout << "int" << std::endl; },
[](float x) { std::cout << "float" << std::endl; },
[](double x) { std::cout << "double" << std::endl; }), v);
});
My implementation (which is heavily based on the explanations in the link above):
#ifndef TUPLE_RANGE_H
#define TUPLE_RANGE_H
#include <utility>
#include <functional>
#include <variant>
#include <type_traits>
template<typename Accessor>
class tuple_iterator
{
public:
tuple_iterator(Accessor acc, const int idx)
: acc_(acc), index_(idx)
{
}
tuple_iterator operator++()
{
++index_;
return *this;
}
template<typename T>
bool operator ==(tuple_iterator<T> other)
{
return index_ == other.index();
}
template<typename T>
bool operator !=(tuple_iterator<T> other)
{
return index_ != other.index();
}
auto operator*() { return std::invoke(acc_, index_); }
[[nodiscard]] int index() const { return index_; }
private:
const Accessor acc_;
int index_;
};
template<bool IsConst, typename...Ts>
struct tuple_access
{
using tuple_type = std::tuple<Ts...>;
using tuple_ref = std::conditional_t<IsConst, const tuple_type&, tuple_type&>;
template<typename T>
using element_ref = std::conditional_t<IsConst,
std::reference_wrapper<const T>,
std::reference_wrapper<T>>;
using variant_type = std::variant<element_ref<Ts>...>;
using function_type = variant_type(*)(tuple_ref);
using table_type = std::array<function_type, sizeof...(Ts)>;
private:
template<size_t Index>
static constexpr function_type create_accessor()
{
return { [](tuple_ref t) -> variant_type
{
if constexpr (IsConst)
return std::cref(std::get<Index>(t));
else
return std::ref(std::get<Index>(t));
} };
}
template<size_t...Is>
static constexpr table_type create_table(std::index_sequence<Is...>)
{
return { create_accessor<Is>()... };
}
public:
static constexpr auto table = create_table(std::make_index_sequence<sizeof...(Ts)>{});
};
template<bool IsConst, typename...Ts>
class tuple_range
{
public:
using tuple_access_type = tuple_access<IsConst, Ts...>;
using tuple_ref = typename tuple_access_type::tuple_ref;
static constexpr auto tuple_size = sizeof...(Ts);
explicit tuple_range(tuple_ref tuple)
: tuple_(tuple)
{
}
[[nodiscard]] auto begin() const
{
return tuple_iterator{ create_accessor(), 0 };
}
[[nodiscard]] auto end() const
{
return tuple_iterator{ create_accessor(), tuple_size };
}
private:
tuple_ref tuple_;
auto create_accessor() const
{
return [this](int idx)
{
return std::invoke(tuple_access_type::table[idx], tuple_);
};
}
};
template<bool IsConst, typename...Ts>
auto begin(const tuple_range<IsConst, Ts...>& r)
{
return r.begin();
}
template<bool IsConst, typename...Ts>
auto end(const tuple_range<IsConst, Ts...>& r)
{
return r.end();
}
template <class ... Fs>
struct overload : Fs... {
explicit overload(Fs&&... fs) : Fs{ fs }... {}
using Fs::operator()...;
template<class T>
auto operator()(std::reference_wrapper<T> ref)
{
return (*this)(ref.get());
}
template<class T>
auto operator()(std::reference_wrapper<const T> ref)
{
return (*this)(ref.get());
}
};
template <class F>
struct unwrap : overload<F>
{
explicit unwrap(F&& f) : overload<F>{ std::forward<F>(f) } {}
using overload<F>::operator();
};
template<typename...Ts>
auto to_range(std::tuple<Ts...>& t)
{
return tuple_range<false, Ts...>{t};
}
template<typename...Ts>
auto to_range(const std::tuple<Ts...>& t)
{
return tuple_range<true, Ts...>{t};
}
#endif
Read-only access is also supported by passing a const std::tuple<>& to to_range().
Others have mentioned some well-designed third-party libraries that you may turn to. However, if you are using C++ without those third-party libraries, the following code may help.
namespace detail {
template <class Tuple, std::size_t I, class = void>
struct for_each_in_tuple_helper {
template <class UnaryFunction>
static void apply(Tuple&& tp, UnaryFunction& f) {
f(std::get<I>(std::forward<Tuple>(tp)));
for_each_in_tuple_helper<Tuple, I + 1u>::apply(std::forward<Tuple>(tp), f);
}
};
template <class Tuple, std::size_t I>
struct for_each_in_tuple_helper<Tuple, I, typename std::enable_if<
I == std::tuple_size<typename std::decay<Tuple>::type>::value>::type> {
template <class UnaryFunction>
static void apply(Tuple&&, UnaryFunction&) {}
};
} // namespace detail
template <class Tuple, class UnaryFunction>
UnaryFunction for_each_in_tuple(Tuple&& tp, UnaryFunction f) {
detail::for_each_in_tuple_helper<Tuple, 0u>
::apply(std::forward<Tuple>(tp), f);
return std::move(f);
}
Note: The code compiles with any compiler supporing C++11, and it keeps consistency with design of the standard library:
The tuple need not be std::tuple, and instead may be anything that supports std::get and std::tuple_size; in particular, std::array and std::pair may be used;
The tuple may be a reference type or cv-qualified;
It has similar behavior as std::for_each, and returns the input UnaryFunction;
For C++14 (or laster version) users, typename std::enable_if<T>::type and typename std::decay<T>::type could be replaced with their simplified version, std::enable_if_t<T> and std::decay_t<T>;
For C++17 (or laster version) users, std::tuple_size<T>::value could be replaced with its simplified version, std::tuple_size_v<T>.
For C++20 (or laster version) users, the SFINAE feature could be implemented with the Concepts.
Using constexpr and if constexpr(C++17) this is fairly simple and straight forward:
template <std::size_t I = 0, typename ... Ts>
void print(std::tuple<Ts...> tup) {
if constexpr (I == sizeof...(Ts)) {
return;
} else {
std::cout << std::get<I>(tup) << ' ';
print<I+1>(tup);
}
}
I might have missed this train, but this will be here for future reference.
Here's my construct based on this answer and on this gist:
#include <tuple>
#include <utility>
template<std::size_t N>
struct tuple_functor
{
template<typename T, typename F>
static void run(std::size_t i, T&& t, F&& f)
{
const std::size_t I = (N - 1);
switch(i)
{
case I:
std::forward<F>(f)(std::get<I>(std::forward<T>(t)));
break;
default:
tuple_functor<I>::run(i, std::forward<T>(t), std::forward<F>(f));
}
}
};
template<>
struct tuple_functor<0>
{
template<typename T, typename F>
static void run(std::size_t, T, F){}
};
You then use it as follow:
template<typename... T>
void logger(std::string format, T... args) //behaves like C#'s String.Format()
{
auto tp = std::forward_as_tuple(args...);
auto fc = [](const auto& t){std::cout << t;};
/* ... */
std::size_t some_index = ...
tuple_functor<sizeof...(T)>::run(some_index, tp, fc);
/* ... */
}
There could be room for improvements.
As per OP's code, it would become this:
const std::size_t num = sizeof...(T);
auto my_tuple = std::forward_as_tuple(t...);
auto do_sth = [](const auto& elem){/* ... */};
for(int i = 0; i < num; ++i)
tuple_functor<num>::run(i, my_tuple, do_sth);
Of all the answers I've seen here, here and here, I liked #sigidagi's way of iterating best. Unfortunately, his answer is very verbose which in my opinion obscures the inherent clarity.
This is my version of his solution which is more concise and works with std::tuple, std::pair and std::array.
template<typename UnaryFunction>
void invoke_with_arg(UnaryFunction)
{}
/**
* Invoke the unary function with each of the arguments in turn.
*/
template<typename UnaryFunction, typename Arg0, typename... Args>
void invoke_with_arg(UnaryFunction f, Arg0&& a0, Args&&... as)
{
f(std::forward<Arg0>(a0));
invoke_with_arg(std::move(f), std::forward<Args>(as)...);
}
template<typename Tuple, typename UnaryFunction, std::size_t... Indices>
void for_each_helper(Tuple&& t, UnaryFunction f, std::index_sequence<Indices...>)
{
using std::get;
invoke_with_arg(std::move(f), get<Indices>(std::forward<Tuple>(t))...);
}
/**
* Invoke the unary function for each of the elements of the tuple.
*/
template<typename Tuple, typename UnaryFunction>
void for_each(Tuple&& t, UnaryFunction f)
{
using size = std::tuple_size<typename std::remove_reference<Tuple>::type>;
for_each_helper(
std::forward<Tuple>(t),
std::move(f),
std::make_index_sequence<size::value>()
);
}
Demo: coliru
C++14's std::make_index_sequence can be implemented for C++11.
Expanding on #Stypox answer, we can make their solution more generic (C++17 onward). By adding a callable function argument:
template<size_t I = 0, typename... Tp, typename F>
void for_each_apply(std::tuple<Tp...>& t, F &&f) {
f(std::get<I>(t));
if constexpr(I+1 != sizeof...(Tp)) {
for_each_apply<I+1>(t, std::forward<F>(f));
}
}
Then, we need a strategy to visit each type.
Let start with some helpers (first two taken from cppreference):
template<class... Ts> struct overloaded : Ts... { using Ts::operator()...; };
template<class... Ts> overloaded(Ts...) -> overloaded<Ts...>;
template<class ... Ts> struct variant_ref { using type = std::variant<std::reference_wrapper<Ts>...>; };
variant_ref is used to allow tuples' state to be modified.
Usage:
std::tuple<Foo, Bar, Foo> tuples;
for_each_apply(tuples,
[](variant_ref<Foo, Bar>::type &&v) {
std::visit(overloaded {
[](Foo &arg) { arg.foo(); },
[](Bar const &arg) { arg.bar(); },
}, v);
});
Result:
Foo0
Bar
Foo0
Foo1
Bar
Foo1
For completeness, here are my Bar & Foo:
struct Foo {
void foo() {std::cout << "Foo" << i++ << std::endl;}
int i = 0;
};
struct Bar {
void bar() const {std::cout << "Bar" << std::endl;}
};
I have stumbled on the same problem for iterating over a tuple of function objects, so here is one more solution:
#include <tuple>
#include <iostream>
// Function objects
class A
{
public:
inline void operator()() const { std::cout << "A\n"; };
};
class B
{
public:
inline void operator()() const { std::cout << "B\n"; };
};
class C
{
public:
inline void operator()() const { std::cout << "C\n"; };
};
class D
{
public:
inline void operator()() const { std::cout << "D\n"; };
};
// Call iterator using recursion.
template<typename Fobjects, int N = 0>
struct call_functors
{
static void apply(Fobjects const& funcs)
{
std::get<N>(funcs)();
// Choose either the stopper or descend further,
// depending if N + 1 < size of the tuple.
using caller = std::conditional_t
<
N + 1 < std::tuple_size_v<Fobjects>,
call_functors<Fobjects, N + 1>,
call_functors<Fobjects, -1>
>;
caller::apply(funcs);
}
};
// Stopper.
template<typename Fobjects>
struct call_functors<Fobjects, -1>
{
static void apply(Fobjects const& funcs)
{
}
};
// Call dispatch function.
template<typename Fobjects>
void call(Fobjects const& funcs)
{
call_functors<Fobjects>::apply(funcs);
};
using namespace std;
int main()
{
using Tuple = tuple<A,B,C,D>;
Tuple functors = {A{}, B{}, C{}, D{}};
call(functors);
return 0;
}
Output:
A
B
C
D
There're many great answers, but for some reason most of them don't consider returning the results of applying f to our tuple...
or did I overlook it? Anyway, here's yet another way you can do that:
Doing Foreach with style (debatable)
auto t = std::make_tuple(1, "two", 3.f);
t | foreach([](auto v){ std::cout << v << " "; });
And returning from that:
auto t = std::make_tuple(1, "two", 3.f);
auto sizes = t | foreach([](auto v) {
return sizeof(v);
});
sizes | foreach([](auto v) {
std::cout << v;
});
Implementation (pretty simple one)
Edit: it gets a little messier.
I won't include some metaprogramming boilerplate here, for it will definitely make things less readable and besides, I believe those have already been answered somewhere on stackoverflow.
In case you're feeling lazy, feel free to peek into my github repo for implementation of both
#include <utility>
// Optional includes, if you don't want to implement it by hand or google it
// you can find it in the repo (link below)
#include "typesystem/typelist.hpp"
// used to check if all return types are void,
// making it a special case
// (and, alas, not using constexpr-if
// for the sake of being compatible with C++14...)
template <bool Cond, typename T, typename F>
using select = typename std::conditional<Cond, T, F>::type;
template <typename F>
struct elementwise_apply {
F f;
};
template <typename F>
constexpr auto foreach(F && f) -> elementwise_apply<F> { return {std::forward<F>(f)}; }
template <typename R>
struct tuple_map {
template <typename F, typename T, size_t... Is>
static constexpr decltype(auto) impl(std::index_sequence<Is...>, F && f, T&& tuple) {
return R{ std::forward<F>(f)( std::get<Is>(tuple) )... };
}
};
template<>
struct tuple_map<void> {
template <typename F, typename T, size_t... Is>
static constexpr void impl(std::index_sequence<Is...>, F && f, T&& tuple) {
[[maybe_unused]] std::initializer_list<int> _ {((void)std::forward<F>(f)( std::get<Is>(tuple) ), 0)... };
}
};
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> & t, fmap<F> && op) {
constexpr bool all_void = core::Types<decltype( std::move(op).f(std::declval<Ts&>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, t);
}
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> const& t, fmap<F> && op) {
constexpr bool all_void = check if all "decltype( std::move(op).f(std::declval<Ts>()) )..." types are void, since then it's a special case
// e.g. core::Types<decltype( std::move(op).f(std::declval<Ts>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts const&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, t);
}
template <typename F, typename... Ts>
constexpr decltype(auto) operator| (std::tuple<Ts...> && t, fmap<F> && op) {
constexpr bool all_void = core::Types<decltype( std::move(op).f(std::declval<Ts&&>()) )...>.all( core::is_void );
using R = meta::select<all_void, void, std::tuple<decltype(std::move(op).f(std::declval<Ts&&>()))...>>;
return tuple_map<R>::impl(std::make_index_sequence<sizeof...(Ts)>{}, std::move(op).f, std::move(t));
}
Yeah, that would be much nicer if we were to use C++17
This is also an example of std::moving object's members, for which I'll better refer to this nice brief article
P.S. If you're stuck checking if all "decltype( std::move(op).f(std::declval()) )..." types are void
you can find some metaprogramming library, or, if those libraries seem too hard to grasp (which some of them may be due to some crazy metaprogramming tricks), you know where to look
template <typename F, typename T>
static constexpr size_t
foreach_in_tuple(std::tuple<T> & tuple, F && do_, size_t index_ = 0)
{
do_(tuple, index_);
return index_;
}
template <typename F, typename T, typename U, typename... Types>
static constexpr size_t
foreach_in_tuple(std::tuple<T,U,Types...> & tuple, F && do_, size_t index_ = 0)
{
if(!do_(tuple, index_))
return index_;
auto & next_tuple = reinterpret_cast<std::tuple<U,Types...> &>(tuple);
return foreach_in_tuple(next_tuple, std::forward<F>(do_), index_+1);
}
int main()
{
using namespace std;
auto tup = make_tuple(1, 2.3f, 'G', "hello");
foreach_in_tuple(tup, [](auto & tuple, size_t i)
{
auto & value = std::get<0>(tuple);
std::cout << i << " " << value << std::endl;
// if(i >= 2) return false; // break;
return true; // continue
});
}
Here is a solution based on std::interger_sequence.
As I don't know if my_tuple is constructed from std::make_tuple<T>(T &&...) in your code. It's essential for how to construct std::integer_sequence in the solution below.
(1) if your already have a my_tuple outside your function(not using template<typename ...T>), You can use
[](auto my_tuple)
{
[&my_tuple]<typename N, N... n>(std::integer_sequence<N, n...> int_seq)
{
((std::cout << std::get<n>(my_tuple) << '\n'), ...);
}(std::make_index_sequence<std::tuple_size_v<decltype(my_tuple)>>{});
}(std::make_tuple());
(2) if your havn't constructed my_tuple in your function and want to handle your T ...arguments
[]<typename ...T>(T... args)
{
[&args...]<typename N, N... n>(std::integer_sequence<N, n...> int_seq)
{
((std::cout << std::get<n>(std::forward_as_tuple(args...)) << '\n'), ...);
}(std::index_sequence_for<T...>{});
}();
boost's tuple provides helper functions get_head() and get_tail() so your helper functions may look like this:
inline void call_do_sth(const null_type&) {};
template <class H, class T>
inline void call_do_sth(cons<H, T>& x) { x.get_head().do_sth(); call_do_sth(x.get_tail()); }
as described in here http://www.boost.org/doc/libs/1_34_0/libs/tuple/doc/tuple_advanced_interface.html
with std::tuple it should be similar.
Actually, unfortunately std::tuple does not seem to provide such interface, so methods suggested before should work, or you would need to switch to boost::tuple which has other benefits (like io operators already provided). Though there is downside of boost::tuple with gcc - it does not accept variadic templates yet, but that may be already fixed as I do not have latest version of boost installed on my machine.
I have function at designed to access std::tuple element by index specified in runtime
template<std::size_t _Index = 0, typename _Tuple, typename _Function>
inline typename std::enable_if<_Index == std::tuple_size<_Tuple>::value, void>::type
for_each(_Tuple &, _Function)
{}
template<std::size_t _Index = 0, typename _Tuple, typename _Function>
inline typename std::enable_if < _Index < std::tuple_size<_Tuple>::value, void>::type
for_each(_Tuple &t, _Function f)
{
f(std::get<_Index>(t));
for_each<_Index + 1, _Tuple, _Function>(t, f);
}
namespace detail { namespace at {
template < typename _Function >
struct helper
{
inline helper(size_t index_, _Function f_) : index(index_), f(f_), count(0) {}
template < typename _Arg >
void operator()(_Arg &arg_) const
{
if(index == count++)
f(arg_);
}
const size_t index;
mutable size_t count;
_Function f;
};
}} // end of namespace detail
template < typename _Tuple, typename _Function >
void at(_Tuple &t, size_t index_, _Function f)
{
if(std::tuple_size<_Tuple> ::value <= index_)
throw std::out_of_range("");
for_each(t, detail::at::helper<_Function>(index_, f));
}
It has linear complexity. How can i achive O(1) complexity?
Assuming you pass something similar to a generic lambda, i.e. a function object with an overloaded function call operator:
#include <iostream>
struct Func
{
template<class T>
void operator()(T p)
{
std::cout << __PRETTY_FUNCTION__ << " : " << p << "\n";
}
};
The you can build an array of function pointers:
#include <tuple>
template<int... Is> struct seq {};
template<int N, int... Is> struct gen_seq : gen_seq<N-1, N-1, Is...> {};
template<int... Is> struct gen_seq<0, Is...> : seq<Is...> {};
template<int N, class T, class F>
void apply_one(T& p, F func)
{
func( std::get<N>(p) );
}
template<class T, class F, int... Is>
void apply(T& p, int index, F func, seq<Is...>)
{
using FT = void(T&, F);
static constexpr FT* arr[] = { &apply_one<Is, T, F>... };
arr[index](p, func);
}
template<class T, class F>
void apply(T& p, int index, F func)
{
apply(p, index, func, gen_seq<std::tuple_size<T>::value>{});
}
Usage example:
int main()
{
std::tuple<int, double, char, double> t{1, 2.3, 4, 5.6};
for(int i = 0; i < 4; ++i) apply(t, i, Func{});
}
clang++ also accepts an expansion applied to a pattern that contains a lambda expression:
static FT* arr[] = { [](T& p, F func){ func(std::get<Is>(p)); }... };
(although I've to admit that looks really weird)
g++4.8.1 rejects this.