基本逻辑思考
首先是实现 function,这个比较简单,重载 operator() 就好,这里只实现对函数指针的包装
其次是实现 tuple,这个会比较绕,通过模板取第一个参数,然后用剩下的参数继续生成 tuple并继承,是一种递归的思想
有了 tuple 就要有 get(),这个就更比较绕了,首先是需要类似的方式实现获得 tuple 的值类型与元组类型,然后通过强制类型转换,获取对应的层级的 value
接下来是 bind,首先要解决的就是如何保存创建时的参数列表,这里就用到 tuple 来保存了
奇技淫巧还是运行函数时取相应的元组的对应位置的值,还是类似的方式,通过特化模板,公式是 <n, indexs...> => <n - 1, n - 1, indexs...>,比如 3 最后会生成 0 0 1 2 那么抛弃第一个,并用来展开元组,传递给函数指针
最重要的来了,就是如何实现 placeholders,简单来说就是在上一步的 operator() 增加传入参数,并制造成元组 r_args,然后带进一个 _unwrap_tuple 类,这里会重载 operator[] 根据传入数据结构,如果是 _placeholders<index> 那么取 r_args 相应的 index 位置,否则会直接 return
代码
不多说,还是直接放代码,仅作为参考,有写的不好的地方轻喷
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/* * Author: SpringHack - springhack@live.cn * Last modified: 2020-02-19 10:16:17 * Filename: main.cpp * Description: Created by SpringHack using vim automatically. */ #include <iostream> namespace dosk { // begin namespace dosk // function template < typename ... T> class function; template < typename Result, typename ... Args> class function<Result(Args...)> { private : Result (*function_)(Args...); public : typedef Result return_type; function() = default ; function(Result (*fn)(Args...)) : function_(fn) {}; Result operator()(Args... a) { return function_(a...); } function& operator=(Result (*fn)(Args...)) { function_ = fn; return * this ; } }; // tuple template < typename ... T> class tuple; template < typename HEAD, typename ... LIST> class tuple<HEAD, LIST...> : public tuple<LIST...> { public : HEAD value; tuple(HEAD head, LIST... list) : tuple<LIST...>(list...), value(head) {}; }; template <> class tuple<> {}; // tuple get template < int index, typename ... T> class _tuple_type; template < int index, typename HEAD, typename ... LIST> class _tuple_type<index, tuple<HEAD, LIST...>> { public : typedef typename _tuple_type<index - 1, tuple<LIST...>>::value_type value_type; typedef typename _tuple_type<index - 1, tuple<LIST...>>::tuple_type tuple_type; }; template < typename HEAD, typename ... LIST> class _tuple_type<0, tuple<HEAD, LIST...>> { public : typedef HEAD value_type; typedef tuple<HEAD, LIST...> tuple_type; }; template < int index, typename HEAD, typename ... LIST> typename _tuple_type<index, tuple<HEAD, LIST...>>::value_type get(tuple<HEAD, LIST...> t) { typedef typename _tuple_type<index, tuple<HEAD, LIST...>>::value_type value_type; typedef typename _tuple_type<index, tuple<HEAD, LIST...>>::tuple_type tuple_type; value_type rv = ((tuple_type)t).value; return rv; } // bind template < size_t ...> class _tuple_index {}; template < size_t n, size_t ... indexs> class _make_indexs : public _make_indexs<n - 1, n - 1, indexs...> {}; template < size_t ... indexs> class _make_indexs<0, indexs...> { public : typedef _tuple_index<indexs...> index_type; }; namespace placeholders { template < size_t index> class _placeholders {}; _placeholders<0> _1; _placeholders<1> _2; _placeholders<2> _3; _placeholders<3> _4; _placeholders<4> _5; _placeholders<5> _6; _placeholders<6> _7; _placeholders<7> _8; _placeholders<8> _9; _placeholders<9> _10; template < typename ... RArgs> class _unwrap_tuple { public : tuple<RArgs...> r_args; _unwrap_tuple(tuple<RArgs...> r_args) : r_args(r_args) {}; template < typename R> R operator[](R r) { return r; } template < size_t index> auto operator[](placeholders::_placeholders<index>) { return get<index>(r_args); } }; }; template < typename Func, typename ... Args> class bind_t { public : typedef typename _make_indexs< sizeof ...(Args)>::index_type _indexs; typedef typename Func::return_type return_type; Func func; tuple<Args...> args; bind_t(Func func, Args... args): func(func), args(args...) {} template < typename ... RArgs> return_type operator()(RArgs&&... _r_args) { tuple<RArgs...> r_args = tuple<RArgs...>(_r_args...); return run(_indexs(), r_args); } template < size_t ... Idx, typename ... RArgs> return_type run(_tuple_index<Idx...>, tuple<RArgs...> r_args) { return func(unwrap_args<Idx>(r_args)...); } template < size_t index, typename ... RArgs> auto unwrap_args(tuple<RArgs...> r_args) { placeholders::_unwrap_tuple<RArgs...> _u_a(r_args); auto _m_a = get<index>(args); return _u_a[_m_a]; } }; template < typename Func, typename ... Args> bind_t<Func, Args...> bind(Func& func, Args&&... args) { return bind_t<Func, Args...>(func, args...); } }; // end namespace dosk // Test code std::string test_func( int a, const char * b) { return std::to_string(a) + std::string(b); } std::string test_bind_args( int a, int b, int c, int d, int e) { return std::to_string(a) + std::to_string(b) + std::to_string(c) + std::to_string(d) + std::to_string(e); } int main() { // Test tuple dosk::tuple< int , const char *> t(123, "456" ); std::cout << dosk::get<0>(t) << dosk::get<1>(t) << std::endl; // Test function dosk::function<std::string( int , const char *)> closure_1 = test_func; std::cout << closure_1(123, "456" ) << std::endl; // Test bind dosk::function<std::string( int , int , int , int , int )> closure_2 = test_bind_args; auto binder = dosk::bind(closure_2, 1, dosk::placeholders::_2, 3, dosk::placeholders::_1, 5); std::cout << binder(4, 2, 0) << std::endl; return 0; } |
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原文链接:https://www.dosk.win/2020/02/19/fake-stl-bind-tuple-function/