Pointer-to-Member Operators: .* and ->*

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转载 最新推荐文章于 2024-05-02 20:07:46 发布 · 1.6k 阅读 · 0
文章标签:

#function #pointers #class #access #object #types

本文详细介绍了C++中指针到成员操作符的使用方法,包括如何通过指针调用成员函数和访问成员变量,通过实例代码展示了操作过程。 
expression .* expression 
expression –>* expression

The pointer-to-member operators, .* and –>*, return the value of a specific class member for the object specified on the left side of the expression.  The right side must specify a member of the class.  The following example shows how to use these operators:

Copy 
// expre_Expressions_with_Pointer_Member_Operators.cpp
// compile with: /EHsc
#include <iostream>

using namespace std;

class Testpm {
public:
   void m_func1() { cout << "m_func1\n"; }
   int m_num;
};

// Define derived types pmfn and pmd.
// These types are pointers to members m_func1() and
// m_num, respectively.
void (Testpm::*pmfn)() = &Testpm::m_func1;
int Testpm::*pmd = &Testpm::m_num;

int main() {
   Testpm ATestpm;
   Testpm *pTestpm = new Testpm;

// Access the member function
   (ATestpm.*pmfn)();
   (pTestpm->*pmfn)();   // Parentheses required since * binds
                        // less tightly than the function call.

// Access the member data
   ATestpm.*pmd = 1;
   pTestpm->*pmd = 2;

   cout  << ATestpm.*pmd << endl
         << pTestpm->*pmd << endl;
   delete pTestpm;
}

Output

Copy 
m_func1
m_func1
1
2

In the preceding example, a pointer to a member, pmfn, is used to invoke the member function m_func1. Another pointer to a member, pmd, is used to access the m_num member.

The binary operator .* combines its first operand, which must be an object of class type, with its second operand, which must be a pointer-to-member type.

The binary operator –>* combines its first operand, which must be a pointer to an object of class type, with its second operand, which must be a pointer-to-member type.

In an expression containing the .* operator, the first operand must be of the class type of, and be accessible to, the pointer to member specified in the second operand or of an accessible type unambiguously derived from and accessible to that class.

In an expression containing the –>* operator, the first operand must be of the type "pointer to the class type" of the type specified in the second operand, or it must be of a type unambiguously derived from that class.

Consider the following classes and program fragment:

Copy 
// expre_Expressions_with_Pointer_Member_Operators2.cpp
// C2440 expected
class BaseClass {
public:
   BaseClass(); // Base class constructor.
   void Func1();
};

// Declare a pointer to member function Func1.
void (BaseClass::*pmfnFunc1)() = &BaseClass::Func1;

class Derived : public BaseClass {
public:
   Derived();  // Derived class constructor.
   void Func2();
};

// Declare a pointer to member function Func2.
void (Derived::*pmfnFunc2)() = &Derived::Func2;

int main() {
   BaseClass ABase;
   Derived ADerived;

   (ABase.*pmfnFunc1)();   // OK: defined for BaseClass.
   (ABase.*pmfnFunc2)();   // Error: cannot use base class to
                           // access pointers to members of
                           // derived classes. 

   (ADerived.*pmfnFunc1)();   // OK: Derived is unambiguously
                              // derived from BaseClass. 
   (ADerived.*pmfnFunc2)();   // OK: defined for Derived.
}

The result of the .* or –>* pointer-to-member operators is an object or function of the type specified in the declaration of the pointer to member. So, in the preceding example, the result of the expression ADerived.*pmfnFunc1() is a pointer to a function that returns void. This result is an l-value if the second operand is an l-value.

NoteNote

If the result of one of the pointer-to-member operators is a function, then the result can be used only as an operand to the function call operator.

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此代码报错如下,如何修改?// Functor implementations -*- C++ -*- // Copyright (C) 2001-2014 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 3, or (at your option) // any later version. // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // Under Section 7 of GPL version 3, you are granted additional // permissions described in the GCC Runtime Library Exception, version // 3.1, as published by the Free Software Foundation. // You should have received a copy of the GNU General Public License and // a copy of the GCC Runtime Library Exception along with this program; // see the files COPYING3 and COPYING.RUNTIME respectively. If not, see // <http://www.gnu.org/licenses/>. /* * * Copyright (c) 1994 * Hewlett-Packard Company * * Permission to use, copy, modify, distribute and sell this software * and its documentation for any purpose is hereby granted without fee, * provided that the above copyright notice appear in all copies and * that both that copyright notice and this permission notice appear * in supporting documentation. Hewlett-Packard Company makes no * representations about the suitability of this software for any * purpose. 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It is provided "as is" without express or implied warranty. */ /** @file bits/stl_function.h * This is an internal header file, included by other library headers. * Do not attempt to use it directly. @headername{functional} */ #ifndef _STL_FUNCTION_H #define _STL_FUNCTION_H 1 #if __cplusplus > 201103L #include <bits/move.h> #endif namespace std _GLIBCXX_VISIBILITY(default) { _GLIBCXX_BEGIN_NAMESPACE_VERSION // 20.3.1 base classes /** @defgroup functors Function Objects * @ingroup utilities * * Function objects, or @e functors, are objects with an @c operator() * defined and accessible. They can be passed as arguments to algorithm * templates and used in place of a function pointer. Not only is the * resulting expressiveness of the library increased, but the generated * code can be more efficient than what you might write by hand. When we * refer to @a functors, then, generally we include function pointers in * the description as well. * * Often, functors are only created as temporaries passed to algorithm * calls, rather than being created as named variables. * * Two examples taken from the standard itself follow. To perform a * by-element addition of two vectors @c a and @c b containing @c double, * and put the result in @c a, use * \code * transform (a.begin(), a.end(), b.begin(), a.begin(), plus<double>()); * \endcode * To negate every element in @c a, use * \code * transform(a.begin(), a.end(), a.begin(), negate<double>()); * \endcode * The addition and negation functions will be inlined directly. * * The standard functors are derived from structs named @c unary_function * and @c binary_function. These two classes contain nothing but typedefs, * to aid in generic (template) programming. If you write your own * functors, you might consider doing the same. * * @{ */ /** * This is one of the @link functors functor base classes@endlink. */ template<typename _Arg, typename _Result> struct unary_function { /// @c argument_type is the type of the argument typedef _Arg argument_type; /// @c result_type is the return type typedef _Result result_type; }; /** * This is one of the @link functors functor base classes@endlink. */ template<typename _Arg1, typename _Arg2, typename _Result> struct binary_function { /// @c first_argument_type is the type of the first argument typedef _Arg1 first_argument_type; /// @c second_argument_type is the type of the second argument typedef _Arg2 second_argument_type; /// @c result_type is the return type typedef _Result result_type; }; /** @} */ // 20.3.2 arithmetic /** @defgroup arithmetic_functors Arithmetic Classes * @ingroup functors * * Because basic math often needs to be done during an algorithm, * the library provides functors for those operations. See the * documentation for @link functors the base classes@endlink * for examples of their use. * * @{ */ #if __cplusplus > 201103L struct __is_transparent; // undefined template<typename _Tp = void> struct plus; template<typename _Tp = void> struct minus; template<typename _Tp = void> struct multiplies; template<typename _Tp = void> struct divides; template<typename _Tp = void> struct modulus; template<typename _Tp = void> struct negate; #endif /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct plus : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x + __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct minus : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x - __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct multiplies : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x * __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct divides : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x / __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct modulus : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x % __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct negate : public unary_function<_Tp, _Tp> { _Tp operator()(const _Tp& __x) const { return -__x; } }; #if __cplusplus > 201103L #define __cpp_lib_transparent_operators 201210 //#define __cpp_lib_generic_associative_lookup 201304 template<> struct plus<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) + std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) + std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) + std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct minus<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) - std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) - std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) - std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct multiplies<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) * std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) * std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) * std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct divides<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) / std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) / std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) / std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct modulus<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) % std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) % std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) % std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct negate<void> { template <typename _Tp> auto operator()(_Tp&& __t) const noexcept(noexcept(-std::forward<_Tp>(__t))) -> decltype(-std::forward<_Tp>(__t)) { return -std::forward<_Tp>(__t); } typedef __is_transparent is_transparent; }; #endif /** @} */ // 20.3.3 comparisons /** @defgroup comparison_functors Comparison Classes * @ingroup functors * * The library provides six wrapper functors for all the basic comparisons * in C++, like @c <. * * @{ */ #if __cplusplus > 201103L template<typename _Tp = void> struct equal_to; template<typename _Tp = void> struct not_equal_to; template<typename _Tp = void> struct greater; template<typename _Tp = void> struct less; template<typename _Tp = void> struct greater_equal; template<typename _Tp = void> struct less_equal; #endif /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct equal_to : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x == __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct not_equal_to : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x != __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct greater : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x > __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct less : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x < __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct greater_equal : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x >= __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct less_equal : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x <= __y; } }; #if __cplusplus > 201103L /// One of the @link comparison_functors comparison functors@endlink. template<> struct equal_to<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) == std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) == std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) == std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct not_equal_to<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) != std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) != std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) != std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct greater<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) > std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) > std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) > std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct less<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) < std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) < std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) < std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct greater_equal<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) >= std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) >= std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) >= std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct less_equal<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) <= std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) <= std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) <= std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; #endif /** @} */ // 20.3.4 logical operations /** @defgroup logical_functors Boolean Operations Classes * @ingroup functors * * Here are wrapper functors for Boolean operations: @c &&, @c ||, * and @c !. * * @{ */ #if __cplusplus > 201103L template<typename _Tp = void> struct logical_and; template<typename _Tp = void> struct logical_or; template<typename _Tp = void> struct logical_not; #endif /// One of the @link logical_functors Boolean operations functors@endlink. template<typename _Tp> struct logical_and : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x && __y; } }; /// One of the @link logical_functors Boolean operations functors@endlink. template<typename _Tp> struct logical_or : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x || __y; } }; /// One of the @link logical_functors Boolean operations functors@endlink. template<typename _Tp> struct logical_not : public unary_function<_Tp, bool> { bool operator()(const _Tp& __x) const { return !__x; } }; #if __cplusplus > 201103L /// One of the @link logical_functors Boolean operations functors@endlink. template<> struct logical_and<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) && std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) && std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) && std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link logical_functors Boolean operations functors@endlink. template<> struct logical_or<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) || std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) || std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) || std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link logical_functors Boolean operations functors@endlink. template<> struct logical_not<void> { template <typename _Tp> auto operator()(_Tp&& __t) const noexcept(noexcept(!std::forward<_Tp>(__t))) -> decltype(!std::forward<_Tp>(__t)) { return !std::forward<_Tp>(__t); } typedef __is_transparent is_transparent; }; #endif /** @} */ #if __cplusplus > 201103L template<typename _Tp = void> struct bit_and; template<typename _Tp = void> struct bit_or; template<typename _Tp = void> struct bit_xor; template<typename _Tp = void> struct bit_not; #endif // _GLIBCXX_RESOLVE_LIB_DEFECTS // DR 660. Missing Bitwise Operations. template<typename _Tp> struct bit_and : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x & __y; } }; template<typename _Tp> struct bit_or : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x | __y; } }; template<typename _Tp> struct bit_xor : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x ^ __y; } }; template<typename _Tp> struct bit_not : public unary_function<_Tp, _Tp> { _Tp operator()(const _Tp& __x) const { return ~__x; } }; #if __cplusplus > 201103L template <> struct bit_and<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) & std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) & std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) & std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; template <> struct bit_or<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) | std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) | std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) | std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; template <> struct bit_xor<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) ^ std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) ^ std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) ^ std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; template <> struct bit_not<void> { template <typename _Tp> auto operator()(_Tp&& __t) const noexcept(noexcept(~std::forward<_Tp>(__t))) -> decltype(~std::forward<_Tp>(__t)) { return ~std::forward<_Tp>(__t); } typedef __is_transparent is_transparent; }; #endif // 20.3.5 negators /** @defgroup negators Negators * @ingroup functors * * The functions @c not1 and @c not2 each take a predicate functor * and return an instance of @c unary_negate or * @c binary_negate, respectively. These classes are functors whose * @c operator() performs the stored predicate function and then returns * the negation of the result. * * For example, given a vector of integers and a trivial predicate, * \code * struct IntGreaterThanThree * : public std::unary_function<int, bool> * { * bool operator() (int x) { return x > 3; } * }; * * std::find_if (v.begin(), v.end(), not1(IntGreaterThanThree())); * \endcode * The call to @c find_if will locate the first index (i) of @c v for which * <code>!(v[i] > 3)</code> is true. * * The not1/unary_negate combination works on predicates taking a single * argument. The not2/binary_negate combination works on predicates which * take two arguments. * * @{ */ /// One of the @link negators negation functors@endlink. template<typename _Predicate> class unary_negate : public unary_function<typename _Predicate::argument_type, bool> { protected: _Predicate _M_pred; public: explicit unary_negate(const _Predicate& __x) : _M_pred(__x) { } bool operator()(const typename _Predicate::argument_type& __x) const { return !_M_pred(__x); } }; /// One of the @link negators negation functors@endlink. template<typename _Predicate> inline unary_negate<_Predicate> not1(const _Predicate& __pred) { return unary_negate<_Predicate>(__pred); } /// One of the @link negators negation functors@endlink. template<typename _Predicate> class binary_negate : public binary_function<typename _Predicate::first_argument_type, typename _Predicate::second_argument_type, bool> { protected: _Predicate _M_pred; public: explicit binary_negate(const _Predicate& __x) : _M_pred(__x) { } bool operator()(const typename _Predicate::first_argument_type& __x, const typename _Predicate::second_argument_type& __y) const { return !_M_pred(__x, __y); } }; /// One of the @link negators negation functors@endlink. template<typename _Predicate> inline binary_negate<_Predicate> not2(const _Predicate& __pred) { return binary_negate<_Predicate>(__pred); } /** @} */ // 20.3.7 adaptors pointers functions /** @defgroup pointer_adaptors Adaptors for pointers to functions * @ingroup functors * * The advantage of function objects over pointers to functions is that * the objects in the standard library declare nested typedefs describing * their argument and result types with uniform names (e.g., @c result_type * from the base classes @c unary_function and @c binary_function). * Sometimes those typedefs are required, not just optional. * * Adaptors are provided to turn pointers to unary (single-argument) and * binary (double-argument) functions into function objects. The * long-winded functor @c pointer_to_unary_function is constructed with a * function pointer @c f, and its @c operator() called with argument @c x * returns @c f(x). The functor @c pointer_to_binary_function does the same * thing, but with a double-argument @c f and @c operator(). * * The function @c ptr_fun takes a pointer-to-function @c f and constructs * an instance of the appropriate functor. * * @{ */ /// One of the @link pointer_adaptors adaptors for function pointers@endlink. template<typename _Arg, typename _Result> class pointer_to_unary_function : public unary_function<_Arg, _Result> { protected: _Result (*_M_ptr)(_Arg); public: pointer_to_unary_function() { } explicit pointer_to_unary_function(_Result (*__x)(_Arg)) : _M_ptr(__x) { } _Result operator()(_Arg __x) const { return _M_ptr(__x); } }; /// One of the @link pointer_adaptors adaptors for function pointers@endlink. template<typename _Arg, typename _Result> inline pointer_to_unary_function<_Arg, _Result> ptr_fun(_Result (*__x)(_Arg)) { return pointer_to_unary_function<_Arg, _Result>(__x); } /// One of the @link pointer_adaptors adaptors for function pointers@endlink. template<typename _Arg1, typename _Arg2, typename _Result> class pointer_to_binary_function : public binary_function<_Arg1, _Arg2, _Result> { protected: _Result (*_M_ptr)(_Arg1, _Arg2); public: pointer_to_binary_function() { } explicit pointer_to_binary_function(_Result (*__x)(_Arg1, _Arg2)) : _M_ptr(__x) { } _Result operator()(_Arg1 __x, _Arg2 __y) const { return _M_ptr(__x, __y); } }; /// One of the @link pointer_adaptors adaptors for function pointers@endlink. template<typename _Arg1, typename _Arg2, typename _Result> inline pointer_to_binary_function<_Arg1, _Arg2, _Result> ptr_fun(_Result (*__x)(_Arg1, _Arg2)) { return pointer_to_binary_function<_Arg1, _Arg2, _Result>(__x); } /** @} */ template<typename _Tp> struct _Identity : public unary_function<_Tp,_Tp> { _Tp& operator()(_Tp& __x) const { return __x; } const _Tp& operator()(const _Tp& __x) const { return __x; } }; template<typename _Pair> struct _Select1st : public unary_function<_Pair, typename _Pair::first_type> { typename _Pair::first_type& operator()(_Pair& __x) const { return __x.first; } const typename _Pair::first_type& operator()(const _Pair& __x) const { return __x.first; } #if __cplusplus >= 201103L template<typename _Pair2> typename _Pair2::first_type& operator()(_Pair2& __x) const { return __x.first; } template<typename _Pair2> const typename _Pair2::first_type& operator()(const _Pair2& __x) const { return __x.first; } #endif }; template<typename _Pair> struct _Select2nd : public unary_function<_Pair, typename _Pair::second_type> { typename _Pair::second_type& operator()(_Pair& __x) const { return __x.second; } const typename _Pair::second_type& operator()(const _Pair& __x) const { return __x.second; } }; // 20.3.8 adaptors pointers members /** @defgroup memory_adaptors Adaptors for pointers to members * @ingroup functors * * There are a total of 8 = 2^3 function objects in this family. * (1) Member functions taking no arguments vs member functions taking * one argument. * (2) Call through pointer vs call through reference. * (3) Const vs non-const member function. * * All of this complexity is in the function objects themselves. You can * ignore it by using the helper function mem_fun and mem_fun_ref, * which create whichever type of adaptor is appropriate. * * @{ */ /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp> class mem_fun_t : public unary_function<_Tp*, _Ret> { public: explicit mem_fun_t(_Ret (_Tp::*__pf)()) : _M_f(__pf) { } _Ret operator()(_Tp* __p) const { return (__p->*_M_f)(); } private: _Ret (_Tp::*_M_f)(); }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp> class const_mem_fun_t : public unary_function<const _Tp*, _Ret> { public: explicit const_mem_fun_t(_Ret (_Tp::*__pf)() const) : _M_f(__pf) { } _Ret operator()(const _Tp* __p) const { return (__p->*_M_f)(); } private: _Ret (_Tp::*_M_f)() const; }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp> class mem_fun_ref_t : public unary_function<_Tp, _Ret> { public: explicit mem_fun_ref_t(_Ret (_Tp::*__pf)()) : _M_f(__pf) { } _Ret operator()(_Tp& __r) const { return (__r.*_M_f)(); } private: _Ret (_Tp::*_M_f)(); }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp> class const_mem_fun_ref_t : public unary_function<_Tp, _Ret> { public: explicit const_mem_fun_ref_t(_Ret (_Tp::*__pf)() const) : _M_f(__pf) { } _Ret operator()(const _Tp& __r) const { return (__r.*_M_f)(); } private: _Ret (_Tp::*_M_f)() const; }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp, typename _Arg> class mem_fun1_t : public binary_function<_Tp*, _Arg, _Ret> { public: explicit mem_fun1_t(_Ret (_Tp::*__pf)(_Arg)) : _M_f(__pf) { } _Ret operator()(_Tp* __p, _Arg __x) const { return (__p->*_M_f)(__x); } private: _Ret (_Tp::*_M_f)(_Arg); }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp, typename _Arg> class const_mem_fun1_t : public binary_function<const _Tp*, _Arg, _Ret> { public: explicit const_mem_fun1_t(_Ret (_Tp::*__pf)(_Arg) const) : _M_f(__pf) { } _Ret operator()(const _Tp* __p, _Arg __x) const { return (__p->*_M_f)(__x); } private: _Ret (_Tp::*_M_f)(_Arg) const; }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp, typename _Arg> class mem_fun1_ref_t : public binary_function<_Tp, _Arg, _Ret> { public: explicit mem_fun1_ref_t(_Ret (_Tp::*__pf)(_Arg)) : _M_f(__pf) { } _Ret operator()(_Tp& __r, _Arg __x) const { return (__r.*_M_f)(__x); } private: _Ret (_Tp::*_M_f)(_Arg); }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp, typename _Arg> class const_mem_fun1_ref_t : public binary_function<_Tp, _Arg, _Ret> { public: explicit const_mem_fun1_ref_t(_Ret (_Tp::*__pf)(_Arg) const) : _M_f(__pf) { } _Ret operator()(const _Tp& __r, _Arg __x) const { return (__r.*_M_f)(__x); } private: _Ret (_Tp::*_M_f)(_Arg) const; }; // Mem_fun adaptor helper functions. There are only two: // mem_fun and mem_fun_ref. template<typename _Ret, typename _Tp> inline mem_fun_t<_Ret, _Tp> mem_fun(_Ret (_Tp::*__f)()) { return mem_fun_t<_Ret, _Tp>(__f); } template<typename _Ret, typename _Tp> inline const_mem_fun_t<_Ret, _Tp> mem_fun(_Ret (_Tp::*__f)() const) { return const_mem_fun_t<_Ret, _Tp>(__f); } template<typename _Ret, typename _Tp> inline mem_fun_ref_t<_Ret, _Tp> mem_fun_ref(_Ret (_Tp::*__f)()) { return mem_fun_ref_t<_Ret, _Tp>(__f); } template<typename _Ret, typename _Tp> inline const_mem_fun_ref_t<_Ret, _Tp> mem_fun_ref(_Ret (_Tp::*__f)() const) { return const_mem_fun_ref_t<_Ret, _Tp>(__f); } template<typename _Ret, typename _Tp, typename _Arg> inline mem_fun1_t<_Ret, _Tp, _Arg> mem_fun(_Ret (_Tp::*__f)(_Arg)) { return mem_fun1_t<_Ret, _Tp, _Arg>(__f); } template<typename _Ret, typename _Tp, typename _Arg> inline const_mem_fun1_t<_Ret, _Tp, _Arg> mem_fun(_Ret (_Tp::*__f)(_Arg) const) { return const_mem_fun1_t<_Ret, _Tp, _Arg>(__f); } template<typename _Ret, typename _Tp, typename _Arg> inline mem_fun1_ref_t<_Ret, _Tp, _Arg> mem_fun_ref(_Ret (_Tp::*__f)(_Arg)) { return mem_fun1_ref_t<_Ret, _Tp, _Arg>(__f); } template<typename _Ret, typename _Tp, typename _Arg> inline const_mem_fun1_ref_t<_Ret, _Tp, _Arg> mem_fun_ref(_Ret (_Tp::*__f)(_Arg) const) { return const_mem_fun1_ref_t<_Ret, _Tp, _Arg>(__f); } /** @} */ _GLIBCXX_END_NAMESPACE_VERSION } // namespace #if (__cplusplus < 201103L) || _GLIBCXX_USE_DEPRECATED # include <backward/binders.h> #endif #endif /* _STL_FUNCTION_H */
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cin >> n >> k; vector<int> nums(n); for (int i = 0; i ; ++i) { cin >> nums[i]; } vector<int> maxValues = maxSlidingWindow(nums, k); vector<int> minValues = minSlidingWindow(nums, k); for ...
报错如下,如何修改》// Functor implementations -*- C++ -*- // Copyright (C) 2001-2014 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 3, or (at your option) // any later version. // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // Under Section 7 of GPL version 3, you are granted additional // permissions described in the GCC Runtime Library Exception, version // 3.1, as published by the Free Software Foundation. // You should have received a copy of the GNU General Public License and // a copy of the GCC Runtime Library Exception along with this program; // see the files COPYING3 and COPYING.RUNTIME respectively. If not, see // <http://www.gnu.org/licenses/>. /* * * Copyright (c) 1994 * Hewlett-Packard Company * * Permission to use, copy, modify, distribute and sell this software * and its documentation for any purpose is hereby granted without fee, * provided that the above copyright notice appear in all copies and * that both that copyright notice and this permission notice appear * in supporting documentation. Hewlett-Packard Company makes no * representations about the suitability of this software for any * purpose. It is provided "as is" without express or implied warranty. * * * Copyright (c) 1996-1998 * Silicon Graphics Computer Systems, Inc. * * Permission to use, copy, modify, distribute and sell this software * and its documentation for any purpose is hereby granted without fee, * provided that the above copyright notice appear in all copies and * that both that copyright notice and this permission notice appear * in supporting documentation. Silicon Graphics makes no * representations about the suitability of this software for any * purpose. It is provided "as is" without express or implied warranty. */ /** @file bits/stl_function.h * This is an internal header file, included by other library headers. * Do not attempt to use it directly. @headername{functional} */ #ifndef _STL_FUNCTION_H #define _STL_FUNCTION_H 1 #if __cplusplus > 201103L #include <bits/move.h> #endif namespace std _GLIBCXX_VISIBILITY(default) { _GLIBCXX_BEGIN_NAMESPACE_VERSION // 20.3.1 base classes /** @defgroup functors Function Objects * @ingroup utilities * * Function objects, or @e functors, are objects with an @c operator() * defined and accessible. They can be passed as arguments to algorithm * templates and used in place of a function pointer. Not only is the * resulting expressiveness of the library increased, but the generated * code can be more efficient than what you might write by hand. When we * refer to @a functors, then, generally we include function pointers in * the description as well. * * Often, functors are only created as temporaries passed to algorithm * calls, rather than being created as named variables. * * Two examples taken from the standard itself follow. To perform a * by-element addition of two vectors @c a and @c b containing @c double, * and put the result in @c a, use * \code * transform (a.begin(), a.end(), b.begin(), a.begin(), plus<double>()); * \endcode * To negate every element in @c a, use * \code * transform(a.begin(), a.end(), a.begin(), negate<double>()); * \endcode * The addition and negation functions will be inlined directly. * * The standard functors are derived from structs named @c unary_function * and @c binary_function. These two classes contain nothing but typedefs, * to aid in generic (template) programming. If you write your own * functors, you might consider doing the same. * * @{ */ /** * This is one of the @link functors functor base classes@endlink. */ template<typename _Arg, typename _Result> struct unary_function { /// @c argument_type is the type of the argument typedef _Arg argument_type; /// @c result_type is the return type typedef _Result result_type; }; /** * This is one of the @link functors functor base classes@endlink. */ template<typename _Arg1, typename _Arg2, typename _Result> struct binary_function { /// @c first_argument_type is the type of the first argument typedef _Arg1 first_argument_type; /// @c second_argument_type is the type of the second argument typedef _Arg2 second_argument_type; /// @c result_type is the return type typedef _Result result_type; }; /** @} */ // 20.3.2 arithmetic /** @defgroup arithmetic_functors Arithmetic Classes * @ingroup functors * * Because basic math often needs to be done during an algorithm, * the library provides functors for those operations. See the * documentation for @link functors the base classes@endlink * for examples of their use. * * @{ */ #if __cplusplus > 201103L struct __is_transparent; // undefined template<typename _Tp = void> struct plus; template<typename _Tp = void> struct minus; template<typename _Tp = void> struct multiplies; template<typename _Tp = void> struct divides; template<typename _Tp = void> struct modulus; template<typename _Tp = void> struct negate; #endif /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct plus : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x + __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct minus : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x - __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct multiplies : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x * __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct divides : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x / __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct modulus : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x % __y; } }; /// One of the @link arithmetic_functors math functors@endlink. template<typename _Tp> struct negate : public unary_function<_Tp, _Tp> { _Tp operator()(const _Tp& __x) const { return -__x; } }; #if __cplusplus > 201103L #define __cpp_lib_transparent_operators 201210 //#define __cpp_lib_generic_associative_lookup 201304 template<> struct plus<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) + std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) + std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) + std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct minus<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) - std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) - std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) - std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct multiplies<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) * std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) * std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) * std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct divides<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) / std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) / std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) / std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct modulus<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) % std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) % std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) % std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link arithmetic_functors math functors@endlink. template<> struct negate<void> { template <typename _Tp> auto operator()(_Tp&& __t) const noexcept(noexcept(-std::forward<_Tp>(__t))) -> decltype(-std::forward<_Tp>(__t)) { return -std::forward<_Tp>(__t); } typedef __is_transparent is_transparent; }; #endif /** @} */ // 20.3.3 comparisons /** @defgroup comparison_functors Comparison Classes * @ingroup functors * * The library provides six wrapper functors for all the basic comparisons * in C++, like @c <. * * @{ */ #if __cplusplus > 201103L template<typename _Tp = void> struct equal_to; template<typename _Tp = void> struct not_equal_to; template<typename _Tp = void> struct greater; template<typename _Tp = void> struct less; template<typename _Tp = void> struct greater_equal; template<typename _Tp = void> struct less_equal; #endif /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct equal_to : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x == __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct not_equal_to : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x != __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct greater : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x > __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct less : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x < __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct greater_equal : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x >= __y; } }; /// One of the @link comparison_functors comparison functors@endlink. template<typename _Tp> struct less_equal : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x <= __y; } }; #if __cplusplus > 201103L /// One of the @link comparison_functors comparison functors@endlink. template<> struct equal_to<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) == std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) == std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) == std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct not_equal_to<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) != std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) != std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) != std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct greater<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) > std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) > std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) > std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct less<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) < std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) < std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) < std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct greater_equal<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) >= std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) >= std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) >= std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link comparison_functors comparison functors@endlink. template<> struct less_equal<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) <= std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) <= std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) <= std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; #endif /** @} */ // 20.3.4 logical operations /** @defgroup logical_functors Boolean Operations Classes * @ingroup functors * * Here are wrapper functors for Boolean operations: @c &&, @c ||, * and @c !. * * @{ */ #if __cplusplus > 201103L template<typename _Tp = void> struct logical_and; template<typename _Tp = void> struct logical_or; template<typename _Tp = void> struct logical_not; #endif /// One of the @link logical_functors Boolean operations functors@endlink. template<typename _Tp> struct logical_and : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x && __y; } }; /// One of the @link logical_functors Boolean operations functors@endlink. template<typename _Tp> struct logical_or : public binary_function<_Tp, _Tp, bool> { bool operator()(const _Tp& __x, const _Tp& __y) const { return __x || __y; } }; /// One of the @link logical_functors Boolean operations functors@endlink. template<typename _Tp> struct logical_not : public unary_function<_Tp, bool> { bool operator()(const _Tp& __x) const { return !__x; } }; #if __cplusplus > 201103L /// One of the @link logical_functors Boolean operations functors@endlink. template<> struct logical_and<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) && std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) && std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) && std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link logical_functors Boolean operations functors@endlink. template<> struct logical_or<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) || std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) || std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) || std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; /// One of the @link logical_functors Boolean operations functors@endlink. template<> struct logical_not<void> { template <typename _Tp> auto operator()(_Tp&& __t) const noexcept(noexcept(!std::forward<_Tp>(__t))) -> decltype(!std::forward<_Tp>(__t)) { return !std::forward<_Tp>(__t); } typedef __is_transparent is_transparent; }; #endif /** @} */ #if __cplusplus > 201103L template<typename _Tp = void> struct bit_and; template<typename _Tp = void> struct bit_or; template<typename _Tp = void> struct bit_xor; template<typename _Tp = void> struct bit_not; #endif // _GLIBCXX_RESOLVE_LIB_DEFECTS // DR 660. Missing Bitwise Operations. template<typename _Tp> struct bit_and : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x & __y; } }; template<typename _Tp> struct bit_or : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x | __y; } }; template<typename _Tp> struct bit_xor : public binary_function<_Tp, _Tp, _Tp> { _Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x ^ __y; } }; template<typename _Tp> struct bit_not : public unary_function<_Tp, _Tp> { _Tp operator()(const _Tp& __x) const { return ~__x; } }; #if __cplusplus > 201103L template <> struct bit_and<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) & std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) & std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) & std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; template <> struct bit_or<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) | std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) | std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) | std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; template <> struct bit_xor<void> { template <typename _Tp, typename _Up> auto operator()(_Tp&& __t, _Up&& __u) const noexcept(noexcept(std::forward<_Tp>(__t) ^ std::forward<_Up>(__u))) -> decltype(std::forward<_Tp>(__t) ^ std::forward<_Up>(__u)) { return std::forward<_Tp>(__t) ^ std::forward<_Up>(__u); } typedef __is_transparent is_transparent; }; template <> struct bit_not<void> { template <typename _Tp> auto operator()(_Tp&& __t) const noexcept(noexcept(~std::forward<_Tp>(__t))) -> decltype(~std::forward<_Tp>(__t)) { return ~std::forward<_Tp>(__t); } typedef __is_transparent is_transparent; }; #endif // 20.3.5 negators /** @defgroup negators Negators * @ingroup functors * * The functions @c not1 and @c not2 each take a predicate functor * and return an instance of @c unary_negate or * @c binary_negate, respectively. These classes are functors whose * @c operator() performs the stored predicate function and then returns * the negation of the result. * * For example, given a vector of integers and a trivial predicate, * \code * struct IntGreaterThanThree * : public std::unary_function<int, bool> * { * bool operator() (int x) { return x > 3; } * }; * * std::find_if (v.begin(), v.end(), not1(IntGreaterThanThree())); * \endcode * The call to @c find_if will locate the first index (i) of @c v for which * <code>!(v[i] > 3)</code> is true. * * The not1/unary_negate combination works on predicates taking a single * argument. The not2/binary_negate combination works on predicates which * take two arguments. * * @{ */ /// One of the @link negators negation functors@endlink. template<typename _Predicate> class unary_negate : public unary_function<typename _Predicate::argument_type, bool> { protected: _Predicate _M_pred; public: explicit unary_negate(const _Predicate& __x) : _M_pred(__x) { } bool operator()(const typename _Predicate::argument_type& __x) const { return !_M_pred(__x); } }; /// One of the @link negators negation functors@endlink. template<typename _Predicate> inline unary_negate<_Predicate> not1(const _Predicate& __pred) { return unary_negate<_Predicate>(__pred); } /// One of the @link negators negation functors@endlink. template<typename _Predicate> class binary_negate : public binary_function<typename _Predicate::first_argument_type, typename _Predicate::second_argument_type, bool> { protected: _Predicate _M_pred; public: explicit binary_negate(const _Predicate& __x) : _M_pred(__x) { } bool operator()(const typename _Predicate::first_argument_type& __x, const typename _Predicate::second_argument_type& __y) const { return !_M_pred(__x, __y); } }; /// One of the @link negators negation functors@endlink. template<typename _Predicate> inline binary_negate<_Predicate> not2(const _Predicate& __pred) { return binary_negate<_Predicate>(__pred); } /** @} */ // 20.3.7 adaptors pointers functions /** @defgroup pointer_adaptors Adaptors for pointers to functions * @ingroup functors * * The advantage of function objects over pointers to functions is that * the objects in the standard library declare nested typedefs describing * their argument and result types with uniform names (e.g., @c result_type * from the base classes @c unary_function and @c binary_function). * Sometimes those typedefs are required, not just optional. * * Adaptors are provided to turn pointers to unary (single-argument) and * binary (double-argument) functions into function objects. The * long-winded functor @c pointer_to_unary_function is constructed with a * function pointer @c f, and its @c operator() called with argument @c x * returns @c f(x). The functor @c pointer_to_binary_function does the same * thing, but with a double-argument @c f and @c operator(). * * The function @c ptr_fun takes a pointer-to-function @c f and constructs * an instance of the appropriate functor. * * @{ */ /// One of the @link pointer_adaptors adaptors for function pointers@endlink. template<typename _Arg, typename _Result> class pointer_to_unary_function : public unary_function<_Arg, _Result> { protected: _Result (*_M_ptr)(_Arg); public: pointer_to_unary_function() { } explicit pointer_to_unary_function(_Result (*__x)(_Arg)) : _M_ptr(__x) { } _Result operator()(_Arg __x) const { return _M_ptr(__x); } }; /// One of the @link pointer_adaptors adaptors for function pointers@endlink. template<typename _Arg, typename _Result> inline pointer_to_unary_function<_Arg, _Result> ptr_fun(_Result (*__x)(_Arg)) { return pointer_to_unary_function<_Arg, _Result>(__x); } /// One of the @link pointer_adaptors adaptors for function pointers@endlink. template<typename _Arg1, typename _Arg2, typename _Result> class pointer_to_binary_function : public binary_function<_Arg1, _Arg2, _Result> { protected: _Result (*_M_ptr)(_Arg1, _Arg2); public: pointer_to_binary_function() { } explicit pointer_to_binary_function(_Result (*__x)(_Arg1, _Arg2)) : _M_ptr(__x) { } _Result operator()(_Arg1 __x, _Arg2 __y) const { return _M_ptr(__x, __y); } }; /// One of the @link pointer_adaptors adaptors for function pointers@endlink. template<typename _Arg1, typename _Arg2, typename _Result> inline pointer_to_binary_function<_Arg1, _Arg2, _Result> ptr_fun(_Result (*__x)(_Arg1, _Arg2)) { return pointer_to_binary_function<_Arg1, _Arg2, _Result>(__x); } /** @} */ template<typename _Tp> struct _Identity : public unary_function<_Tp,_Tp> { _Tp& operator()(_Tp& __x) const { return __x; } const _Tp& operator()(const _Tp& __x) const { return __x; } }; template<typename _Pair> struct _Select1st : public unary_function<_Pair, typename _Pair::first_type> { typename _Pair::first_type& operator()(_Pair& __x) const { return __x.first; } const typename _Pair::first_type& operator()(const _Pair& __x) const { return __x.first; } #if __cplusplus >= 201103L template<typename _Pair2> typename _Pair2::first_type& operator()(_Pair2& __x) const { return __x.first; } template<typename _Pair2> const typename _Pair2::first_type& operator()(const _Pair2& __x) const { return __x.first; } #endif }; template<typename _Pair> struct _Select2nd : public unary_function<_Pair, typename _Pair::second_type> { typename _Pair::second_type& operator()(_Pair& __x) const { return __x.second; } const typename _Pair::second_type& operator()(const _Pair& __x) const { return __x.second; } }; // 20.3.8 adaptors pointers members /** @defgroup memory_adaptors Adaptors for pointers to members * @ingroup functors * * There are a total of 8 = 2^3 function objects in this family. * (1) Member functions taking no arguments vs member functions taking * one argument. * (2) Call through pointer vs call through reference. * (3) Const vs non-const member function. * * All of this complexity is in the function objects themselves. You can * ignore it by using the helper function mem_fun and mem_fun_ref, * which create whichever type of adaptor is appropriate. * * @{ */ /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp> class mem_fun_t : public unary_function<_Tp*, _Ret> { public: explicit mem_fun_t(_Ret (_Tp::*__pf)()) : _M_f(__pf) { } _Ret operator()(_Tp* __p) const { return (__p->*_M_f)(); } private: _Ret (_Tp::*_M_f)(); }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp> class const_mem_fun_t : public unary_function<const _Tp*, _Ret> { public: explicit const_mem_fun_t(_Ret (_Tp::*__pf)() const) : _M_f(__pf) { } _Ret operator()(const _Tp* __p) const { return (__p->*_M_f)(); } private: _Ret (_Tp::*_M_f)() const; }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp> class mem_fun_ref_t : public unary_function<_Tp, _Ret> { public: explicit mem_fun_ref_t(_Ret (_Tp::*__pf)()) : _M_f(__pf) { } _Ret operator()(_Tp& __r) const { return (__r.*_M_f)(); } private: _Ret (_Tp::*_M_f)(); }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp> class const_mem_fun_ref_t : public unary_function<_Tp, _Ret> { public: explicit const_mem_fun_ref_t(_Ret (_Tp::*__pf)() const) : _M_f(__pf) { } _Ret operator()(const _Tp& __r) const { return (__r.*_M_f)(); } private: _Ret (_Tp::*_M_f)() const; }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp, typename _Arg> class mem_fun1_t : public binary_function<_Tp*, _Arg, _Ret> { public: explicit mem_fun1_t(_Ret (_Tp::*__pf)(_Arg)) : _M_f(__pf) { } _Ret operator()(_Tp* __p, _Arg __x) const { return (__p->*_M_f)(__x); } private: _Ret (_Tp::*_M_f)(_Arg); }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp, typename _Arg> class const_mem_fun1_t : public binary_function<const _Tp*, _Arg, _Ret> { public: explicit const_mem_fun1_t(_Ret (_Tp::*__pf)(_Arg) const) : _M_f(__pf) { } _Ret operator()(const _Tp* __p, _Arg __x) const { return (__p->*_M_f)(__x); } private: _Ret (_Tp::*_M_f)(_Arg) const; }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp, typename _Arg> class mem_fun1_ref_t : public binary_function<_Tp, _Arg, _Ret> { public: explicit mem_fun1_ref_t(_Ret (_Tp::*__pf)(_Arg)) : _M_f(__pf) { } _Ret operator()(_Tp& __r, _Arg __x) const { return (__r.*_M_f)(__x); } private: _Ret (_Tp::*_M_f)(_Arg); }; /// One of the @link memory_adaptors adaptors for member /// pointers@endlink. template<typename _Ret, typename _Tp, typename _Arg> class const_mem_fun1_ref_t : public binary_function<_Tp, _Arg, _Ret> { public: explicit const_mem_fun1_ref_t(_Ret (_Tp::*__pf)(_Arg) const) : _M_f(__pf) { } _Ret operator()(const _Tp& __r, _Arg __x) const { return (__r.*_M_f)(__x); } private: _Ret (_Tp::*_M_f)(_Arg) const; }; // Mem_fun adaptor helper functions. There are only two: // mem_fun and mem_fun_ref. template<typename _Ret, typename _Tp> inline mem_fun_t<_Ret, _Tp> mem_fun(_Ret (_Tp::*__f)()) { return mem_fun_t<_Ret, _Tp>(__f); } template<typename _Ret, typename _Tp> inline const_mem_fun_t<_Ret, _Tp> mem_fun(_Ret (_Tp::*__f)() const) { return const_mem_fun_t<_Ret, _Tp>(__f); } template<typename _Ret, typename _Tp> inline mem_fun_ref_t<_Ret, _Tp> mem_fun_ref(_Ret (_Tp::*__f)()) { return mem_fun_ref_t<_Ret, _Tp>(__f); } template<typename _Ret, typename _Tp> inline const_mem_fun_ref_t<_Ret, _Tp> mem_fun_ref(_Ret (_Tp::*__f)() const) { return const_mem_fun_ref_t<_Ret, _Tp>(__f); } template<typename _Ret, typename _Tp, typename _Arg> inline mem_fun1_t<_Ret, _Tp, _Arg> mem_fun(_Ret (_Tp::*__f)(_Arg)) { return mem_fun1_t<_Ret, _Tp, _Arg>(__f); } template<typename _Ret, typename _Tp, typename _Arg> inline const_mem_fun1_t<_Ret, _Tp, _Arg> mem_fun(_Ret (_Tp::*__f)(_Arg) const) { return const_mem_fun1_t<_Ret, _Tp, _Arg>(__f); } template<typename _Ret, typename _Tp, typename _Arg> inline mem_fun1_ref_t<_Ret, _Tp, _Arg> mem_fun_ref(_Ret (_Tp::*__f)(_Arg)) { return mem_fun1_ref_t<_Ret, _Tp, _Arg>(__f); } template<typename _Ret, typename _Tp, typename _Arg> inline const_mem_fun1_ref_t<_Ret, _Tp, _Arg> mem_fun_ref(_Ret (_Tp::*__f)(_Arg) const) { return const_mem_fun1_ref_t<_Ret, _Tp, _Arg>(__f); } /** @} */ _GLIBCXX_END_NAMESPACE_VERSION } // namespace #if (__cplusplus < 201103L) || _GLIBCXX_USE_DEPRECATED # include <backward/binders.h> #endif #endif /* _STL_FUNCTION_H */
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C++ 中的“&”、“*”、“.”、“->”、“:”和“::”运算符介绍
ERROR: Requested omegaconf==2.0.5 from file:///E:/tools/omegaconf-2.0.5-py3-none-any.whl has invalid metadata: .* suffix can only be used with `==` or `!=` operators PyYAML (>=5.1.*)
07-25
在尝试安装 `omegaconf==2.0.5` 时遇到的错误 `ERROR: Requested omegaconf==2.0.5 has invalid metadata: .* suffix can only be used with == or != operators PyYAML >=5.1.*` 是由于 `omegaconf` 的依赖项 `PyYAML` 的版本规范不符合 `pip` 的解析规则所导致的。具体来说,该版本的 `omegaconf` 指定了 `PyYAML>=5.1.*`,而 `pip` 从 24.1 版本开始不再支持在版本比较中使用通配符(如 `*`)[^2]。 ### 错误原因分析 该错误的核心问题是 `omegaconf==2.0.5` 的依赖声明中使用了非标准的依赖版本规范 `PyYAML>=5.1.*`,而新版 `pip` 对依赖解析更加严格,不再支持这种格式。这种格式在过去可能被允许,但在 `pip` 更新后会导致元数据解析失败。 ### 解决方案 #### 方法一:使用旧版本 `pip` 一种直接的解决方案是回退到 `pip` 版本低于 24.1 的环境,以避免对非标准依赖的严格检查。 ```bash pip install pip==23.3.2 ``` 然后尝试安装 `omegaconf==2.0.5`: ```bash pip install omegaconf==2.0.5 ``` #### 方法二:手动指定兼容的 `PyYAML` 版本 可以尝试在安装 `omegaconf` 之前先安装一个兼容的 `PyYAML` 版本,例如 `PyYAML==5.3.1`,这样可以绕过依赖解析问题: ```bash pip install PyYAML==5.3.1 pip install omegaconf==2.0.5 ``` #### 方法三:升级 `omegaconf` 推荐的做法是升级到更新的版本(如 `omegaconf>=2.1.0`),因为这些版本已经修复了依赖声明的问题[^1]。如果项目对 `omegaconf==2.0.5` 没有强依赖,建议使用更新版本: ```bash pip install omegaconf --upgrade ``` #### 方法四:使用虚拟环境隔离依赖 为避免全局环境的污染,可以使用 `conda` 或 `venv` 创建独立的虚拟环境,并在其中尝试上述安装方式: ```bash # 使用 conda 创建虚拟环境 conda create -n omegaconf_fix python=3.8 conda activate omegaconf_fix # 或者使用 venv 创建虚拟环境 python -m venv omegaconf_env source omegaconf_env/bin/activate # Linux/macOS omegaconf_env\Scripts\activate # Windows ``` 然后在该环境中尝试上述安装策略。 ### 总结 该错误源于 `omegaconf==2.0.5` 的依赖描述与新版 `pip` 的不兼容。解决方法包括回退 `pip` 版本、手动安装兼容的 `PyYAML`、升级 `omegaconf`,或在虚拟环境中进行隔离安装。推荐优先考虑升级 `omegaconf` 或使用虚拟环境以保持依赖的清晰和可控。 ---
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