x86_64-unknown-linux-gnu/include/c++/4.5.3/bits/atomic_0.h - toolchains/kvm - Git at Google

 // -*- C++ -*- header.

 // Copyright (C) 2008, 2009, 2010, 2011
 // 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/>.

 /** @file bits/atomic_0.h
  *  This is an internal header file, included by other library headers.
  *  You should not attempt to use it directly.
  */

 #ifndef _GLIBCXX_ATOMIC_0_H
 #define _GLIBCXX_ATOMIC_0_H 1

 #pragma GCC system_header

 // _GLIBCXX_BEGIN_NAMESPACE(std)

   // 0 == __atomic0 == Never lock-free
 namespace __atomic0
 {
   struct atomic_flag;

   // Implementation specific defines.
 #define _ATOMIC_LOAD_(__a, __x)						   \
   ({__typeof__ _ATOMIC_MEMBER_* __p = &_ATOMIC_MEMBER_;	   		   \
     __atomic_flag_base* __g = __atomic_flag_for_address(__p);	  	   \
     __atomic_flag_wait_explicit(__g, __x);				   \
     __typeof__ _ATOMIC_MEMBER_ __r = *__p;				   \
     atomic_flag_clear_explicit(__g, __x);		       		   \
     __r; })

 #define _ATOMIC_STORE_(__a, __n, __x)					   \
   ({__typeof__ _ATOMIC_MEMBER_* __p = &_ATOMIC_MEMBER_;	   		   \
     __typeof__(__n) __w = (__n);			       		   \
     __atomic_flag_base* __g = __atomic_flag_for_address(__p);	  	   \
     __atomic_flag_wait_explicit(__g, __x);				   \
     *__p = __w;								   \
     atomic_flag_clear_explicit(__g, __x);		       		   \
     __w; })

 #define _ATOMIC_MODIFY_(__a, __o, __n, __x)				   \
   ({__typeof__ _ATOMIC_MEMBER_* __p = &_ATOMIC_MEMBER_;	   		   \
     __typeof__(__n) __w = (__n);			       		   \
     __atomic_flag_base* __g = __atomic_flag_for_address(__p);	  	   \
     __atomic_flag_wait_explicit(__g, __x);				   \
     __typeof__ _ATOMIC_MEMBER_ __r = *__p;				   \
     *__p __o __w;					       		   \
     atomic_flag_clear_explicit(__g, __x);		       		   \
     __r; })

 #define _ATOMIC_CMPEXCHNG_(__a, __e, __n, __x)				   \
   ({__typeof__ _ATOMIC_MEMBER_* __p = &_ATOMIC_MEMBER_;	   		   \
     __typeof__(__e) __q = (__e);			       		   \
     __typeof__(__n) __w = (__n);			       		   \
     bool __r;						       		   \
     __atomic_flag_base* __g = __atomic_flag_for_address(__p);	   	   \
     __atomic_flag_wait_explicit(__g, __x);				   \
     __typeof__ _ATOMIC_MEMBER_ __t__ = *__p;		       		   \
     if (__t__ == *__q) { *__p = __w; __r = true; }			   \
     else { *__q = __t__; __r = false; }		       			   \
     atomic_flag_clear_explicit(__g, __x);		       		   \
     __r; })

   /// atomic_flag
   struct atomic_flag : public __atomic_flag_base
   {
     atomic_flag() = default;
     ~atomic_flag() = default;
     atomic_flag(const atomic_flag&) = delete;
     atomic_flag& operator=(const atomic_flag&) volatile = delete;

     // Conversion to ATOMIC_FLAG_INIT.
     atomic_flag(bool __i): __atomic_flag_base({ __i }) { }

     bool
     test_and_set(memory_order __m = memory_order_seq_cst);

     void
     clear(memory_order __m = memory_order_seq_cst);
   };

   /// 29.4.2, address types
   struct atomic_address
   {
   private:
     void* _M_i;

   public:
     atomic_address() = default;
     ~atomic_address() = default;
     atomic_address(const atomic_address&) = delete;
     atomic_address& operator=(const atomic_address&) volatile = delete;

     atomic_address(void* __v) { _M_i = __v; }

     bool
     is_lock_free() const
     { return false; }

     void
     store(void* __v, memory_order __m = memory_order_seq_cst)
     {
       __glibcxx_assert(__m != memory_order_acquire);
       __glibcxx_assert(__m != memory_order_acq_rel);
       __glibcxx_assert(__m != memory_order_consume);
       _ATOMIC_STORE_(this, __v, __m);
     }

     void*
     load(memory_order __m = memory_order_seq_cst) const
     {
       __glibcxx_assert(__m != memory_order_release);
       __glibcxx_assert(__m != memory_order_acq_rel);
       return _ATOMIC_LOAD_(this, __m);
     }

     void*
     exchange(void* __v, memory_order __m = memory_order_seq_cst)
     { return _ATOMIC_MODIFY_(this, =, __v, __m); }

     bool
     compare_exchange_weak(void*& __v1, void* __v2, memory_order __m1,
 			  memory_order __m2)
     {
       __glibcxx_assert(__m2 != memory_order_release);
       __glibcxx_assert(__m2 != memory_order_acq_rel);
       __glibcxx_assert(__m2 <= __m1);
       return _ATOMIC_CMPEXCHNG_(this, &__v1, __v2, __m1);
     }

     bool
     compare_exchange_weak(void*& __v1, void* __v2,
 			  memory_order __m = memory_order_seq_cst)
     {
       return compare_exchange_weak(__v1, __v2, __m,
 				   __calculate_memory_order(__m));
     }

     bool
     compare_exchange_strong(void*& __v1, void* __v2, memory_order __m1,
 			    memory_order __m2)
     {
       __glibcxx_assert(__m2 != memory_order_release);
       __glibcxx_assert(__m2 != memory_order_acq_rel);
       __glibcxx_assert(__m2 <= __m1);
       return _ATOMIC_CMPEXCHNG_(this, &__v1, __v2, __m1);
     }

     bool
     compare_exchange_strong(void*& __v1, void* __v2,
 			  memory_order __m = memory_order_seq_cst)
     {
       return compare_exchange_strong(__v1, __v2, __m,
 				     __calculate_memory_order(__m));
     }

     void*
     fetch_add(ptrdiff_t __d, memory_order __m = memory_order_seq_cst)
     {
       void** __p = &(_M_i);
       __atomic_flag_base* __g = __atomic_flag_for_address(__p);
       __atomic_flag_wait_explicit(__g, __m);
       void* __r = *__p;
       *__p = (void*)((char*)(*__p) + __d);
       atomic_flag_clear_explicit(__g, __m);
       return __r;
     }

     void*
     fetch_sub(ptrdiff_t __d, memory_order __m = memory_order_seq_cst)
     {
       void** __p = &(_M_i);
       __atomic_flag_base* __g = __atomic_flag_for_address(__p);
       __atomic_flag_wait_explicit(__g, __m);
       void* __r = *__p;
       *__p = (void*)((char*)(*__p) - __d);
       atomic_flag_clear_explicit(__g, __m);
       return __r;
     }

     operator void*() const
     { return load(); }

     void*
     operator=(void* __v)
     {
       store(__v);
       return __v;
     }

     void*
     operator+=(ptrdiff_t __d)
     { return fetch_add(__d) + __d; }

     void*
     operator-=(ptrdiff_t __d)
     { return fetch_sub(__d) - __d; }
   };


   // 29.3.1 atomic integral types
   // For each of the integral types, define atomic_[integral type] struct
   //
   // atomic_bool     bool
   // atomic_char     char
   // atomic_schar    signed char
   // atomic_uchar    unsigned char
   // atomic_short    short
   // atomic_ushort   unsigned short
   // atomic_int      int
   // atomic_uint     unsigned int
   // atomic_long     long
   // atomic_ulong    unsigned long
   // atomic_llong    long long
   // atomic_ullong   unsigned long long
   // atomic_char16_t char16_t
   // atomic_char32_t char32_t
   // atomic_wchar_t  wchar_t

   // Base type.
   // NB: Assuming _ITp is an integral scalar type that is 1, 2, 4, or 8 bytes,
   // since that is what GCC built-in functions for atomic memory access work on.
   template<typename _ITp>
     struct __atomic_base
     {
     private:
       typedef _ITp 	__integral_type;

       __integral_type 	_M_i;

     public:
       __atomic_base() = default;
       ~__atomic_base() = default;
       __atomic_base(const __atomic_base&) = delete;
       __atomic_base& operator=(const __atomic_base&) volatile = delete;

       // Requires __integral_type convertible to _M_base._M_i.
       __atomic_base(__integral_type __i) { _M_i = __i; }

       operator __integral_type() const
       { return load(); }

       __integral_type
       operator=(__integral_type __i)
       {
 	store(__i);
 	return __i;
       }

       __integral_type
       operator++(int)
       { return fetch_add(1); }

       __integral_type
       operator--(int)
       { return fetch_sub(1); }

       __integral_type
       operator++()
       { return fetch_add(1) + 1; }

       __integral_type
       operator--()
       { return fetch_sub(1) - 1; }

       __integral_type
       operator+=(__integral_type __i)
       { return fetch_add(__i) + __i; }

       __integral_type
       operator-=(__integral_type __i)
       { return fetch_sub(__i) - __i; }

       __integral_type
       operator&=(__integral_type __i)
       { return fetch_and(__i) & __i; }

       __integral_type
       operator|=(__integral_type __i)
       { return fetch_or(__i) | __i; }

       __integral_type
       operator^=(__integral_type __i)
       { return fetch_xor(__i) ^ __i; }

       bool
       is_lock_free() const
       { return false; }

       void
       store(__integral_type __i, memory_order __m = memory_order_seq_cst)
       {
 	__glibcxx_assert(__m != memory_order_acquire);
 	__glibcxx_assert(__m != memory_order_acq_rel);
 	__glibcxx_assert(__m != memory_order_consume);
 	_ATOMIC_STORE_(this, __i, __m);
       }

       __integral_type
       load(memory_order __m = memory_order_seq_cst) const
       {
 	__glibcxx_assert(__m != memory_order_release);
 	__glibcxx_assert(__m != memory_order_acq_rel);
 	return _ATOMIC_LOAD_(this, __m);
       }

       __integral_type
       exchange(__integral_type __i, memory_order __m = memory_order_seq_cst)
       { return _ATOMIC_MODIFY_(this, =, __i, __m); }

       bool
       compare_exchange_weak(__integral_type& __i1, __integral_type __i2,
 			    memory_order __m1, memory_order __m2)
       {
 	__glibcxx_assert(__m2 != memory_order_release);
 	__glibcxx_assert(__m2 != memory_order_acq_rel);
 	__glibcxx_assert(__m2 <= __m1);
 	return _ATOMIC_CMPEXCHNG_(this, &__i1, __i2, __m1);
       }

       bool
       compare_exchange_weak(__integral_type& __i1, __integral_type __i2,
 			    memory_order __m = memory_order_seq_cst)
       {
 	return compare_exchange_weak(__i1, __i2, __m,
 				     __calculate_memory_order(__m));
       }

       bool
       compare_exchange_strong(__integral_type& __i1, __integral_type __i2,
 			      memory_order __m1, memory_order __m2)
       {
 	__glibcxx_assert(__m2 != memory_order_release);
 	__glibcxx_assert(__m2 != memory_order_acq_rel);
 	__glibcxx_assert(__m2 <= __m1);
 	return _ATOMIC_CMPEXCHNG_(this, &__i1, __i2, __m1);
       }

       bool
       compare_exchange_strong(__integral_type& __i1, __integral_type __i2,
 			      memory_order __m = memory_order_seq_cst)
       {
 	return compare_exchange_strong(__i1, __i2, __m,
 				       __calculate_memory_order(__m));
       }

       __integral_type
       fetch_add(__integral_type __i, memory_order __m = memory_order_seq_cst)
       { return _ATOMIC_MODIFY_(this, +=, __i, __m); }

       __integral_type
       fetch_sub(__integral_type __i, memory_order __m = memory_order_seq_cst)
       { return _ATOMIC_MODIFY_(this, -=, __i, __m); }

       __integral_type
       fetch_and(__integral_type __i, memory_order __m = memory_order_seq_cst)
       { return _ATOMIC_MODIFY_(this, &=, __i, __m); }

       __integral_type
       fetch_or(__integral_type __i, memory_order __m = memory_order_seq_cst)
       { return _ATOMIC_MODIFY_(this, |=, __i, __m); }

       __integral_type
       fetch_xor(__integral_type __i, memory_order __m = memory_order_seq_cst)
       { return _ATOMIC_MODIFY_(this, ^=, __i, __m); }
     };


   /// atomic_bool
   // NB: No operators or fetch-operations for this type.
   struct atomic_bool
   {
   private:
     __atomic_base<bool>	_M_base;

   public:
     atomic_bool() = default;
     ~atomic_bool() = default;
     atomic_bool(const atomic_bool&) = delete;
     atomic_bool& operator=(const atomic_bool&) volatile = delete;

     atomic_bool(bool __i) : _M_base(__i) { }

     bool
     operator=(bool __i)
     { return _M_base.operator=(__i); }

     operator bool() const
     { return _M_base.load(); }

     bool
     is_lock_free() const
     { return _M_base.is_lock_free(); }

     void
     store(bool __i, memory_order __m = memory_order_seq_cst)
     { _M_base.store(__i, __m); }

     bool
     load(memory_order __m = memory_order_seq_cst) const
     { return _M_base.load(__m); }

     bool
     exchange(bool __i, memory_order __m = memory_order_seq_cst)
     { return _M_base.exchange(__i, __m); }

     bool
     compare_exchange_weak(bool& __i1, bool __i2, memory_order __m1,
 			  memory_order __m2)
     { return _M_base.compare_exchange_weak(__i1, __i2, __m1, __m2); }

     bool
     compare_exchange_weak(bool& __i1, bool __i2,
 			  memory_order __m = memory_order_seq_cst)
     { return _M_base.compare_exchange_weak(__i1, __i2, __m); }

     bool
     compare_exchange_strong(bool& __i1, bool __i2, memory_order __m1,
 			    memory_order __m2)
     { return _M_base.compare_exchange_strong(__i1, __i2, __m1, __m2); }


     bool
     compare_exchange_strong(bool& __i1, bool __i2,
 			    memory_order __m = memory_order_seq_cst)
     { return _M_base.compare_exchange_strong(__i1, __i2, __m); }
   };

 #undef _ATOMIC_LOAD_
 #undef _ATOMIC_STORE_
 #undef _ATOMIC_MODIFY_
 #undef _ATOMIC_CMPEXCHNG_
 } // namespace __atomic0

 // _GLIBCXX_END_NAMESPACE

 #endif
	// -- C++ -- header.

	// Copyright (C) 2008, 2009, 2010, 2011
	// 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/>.

	/** @file bits/atomic_0.h
	* This is an internal header file, included by other library headers.
	* You should not attempt to use it directly.
	*/

	#ifndef _GLIBCXX_ATOMIC_0_H
	#define _GLIBCXX_ATOMIC_0_H 1

	#pragma GCC system_header

	// _GLIBCXX_BEGIN_NAMESPACE(std)

	// 0 == __atomic0 == Never lock-free
	namespace __atomic0
	{
	struct atomic_flag;

	// Implementation specific defines.
	#define _ATOMIC_LOAD_(__a, __x) \
	({__typeof__ _ATOMIC_MEMBER_* __p = &_ATOMIC_MEMBER_; \
	__atomic_flag_base* __g = __atomic_flag_for_address(__p); \
	__atomic_flag_wait_explicit(__g, __x); \
	__typeof__ _ATOMIC_MEMBER_ __r = *__p; \
	atomic_flag_clear_explicit(__g, __x); \
	__r; })

	#define _ATOMIC_STORE_(__a, __n, __x) \
	({__typeof__ _ATOMIC_MEMBER_* __p = &_ATOMIC_MEMBER_; \
	__typeof__(__n) __w = (__n); \
	__atomic_flag_base* __g = __atomic_flag_for_address(__p); \
	__atomic_flag_wait_explicit(__g, __x); \
	*__p = __w; \
	atomic_flag_clear_explicit(__g, __x); \
	__w; })

	#define _ATOMIC_MODIFY_(__a, __o, __n, __x) \
	({__typeof__ _ATOMIC_MEMBER_* __p = &_ATOMIC_MEMBER_; \
	__typeof__(__n) __w = (__n); \
	__atomic_flag_base* __g = __atomic_flag_for_address(__p); \
	__atomic_flag_wait_explicit(__g, __x); \
	__typeof__ _ATOMIC_MEMBER_ __r = *__p; \
	*__p __o __w; \
	atomic_flag_clear_explicit(__g, __x); \
	__r; })

	#define _ATOMIC_CMPEXCHNG_(__a, __e, __n, __x) \
	({__typeof__ _ATOMIC_MEMBER_* __p = &_ATOMIC_MEMBER_; \
	__typeof__(__e) __q = (__e); \
	__typeof__(__n) __w = (__n); \
	bool __r; \
	__atomic_flag_base* __g = __atomic_flag_for_address(__p); \
	__atomic_flag_wait_explicit(__g, __x); \
	__typeof__ _ATOMIC_MEMBER_ __t__ = *__p; \
	if (__t__ == __q) { __p = __w; __r = true; } \
	else { *__q = __t__; __r = false; } \
	atomic_flag_clear_explicit(__g, __x); \
	__r; })

	/// atomic_flag
	struct atomic_flag : public __atomic_flag_base
	{
	atomic_flag() = default;
	~atomic_flag() = default;
	atomic_flag(const atomic_flag&) = delete;
	atomic_flag& operator=(const atomic_flag&) volatile = delete;

	// Conversion to ATOMIC_FLAG_INIT.
	atomic_flag(bool __i): __atomic_flag_base({ __i }) { }

	bool
	test_and_set(memory_order __m = memory_order_seq_cst);

	void
	clear(memory_order __m = memory_order_seq_cst);
	};

	/// 29.4.2, address types
	struct atomic_address
	{
	private:
	void* _M_i;

	public:
	atomic_address() = default;
	~atomic_address() = default;
	atomic_address(const atomic_address&) = delete;
	atomic_address& operator=(const atomic_address&) volatile = delete;

	atomic_address(void* __v) { _M_i = __v; }

	bool
	is_lock_free() const
	{ return false; }

	void
	store(void* __v, memory_order __m = memory_order_seq_cst)
	{
	__glibcxx_assert(__m != memory_order_acquire);
	__glibcxx_assert(__m != memory_order_acq_rel);
	__glibcxx_assert(__m != memory_order_consume);
	_ATOMIC_STORE_(this, __v, __m);
	}

	void*
	load(memory_order __m = memory_order_seq_cst) const
	{
	__glibcxx_assert(__m != memory_order_release);
	__glibcxx_assert(__m != memory_order_acq_rel);
	return _ATOMIC_LOAD_(this, __m);
	}

	void*
	exchange(void* __v, memory_order __m = memory_order_seq_cst)
	{ return _ATOMIC_MODIFY_(this, =, __v, __m); }

	bool
	compare_exchange_weak(void& __v1, void __v2, memory_order __m1,
	memory_order __m2)
	{
	__glibcxx_assert(__m2 != memory_order_release);
	__glibcxx_assert(__m2 != memory_order_acq_rel);
	__glibcxx_assert(__m2 <= __m1);
	return _ATOMIC_CMPEXCHNG_(this, &__v1, __v2, __m1);
	}

	bool
	compare_exchange_weak(void& __v1, void __v2,
	memory_order __m = memory_order_seq_cst)
	{
	return compare_exchange_weak(__v1, __v2, __m,
	__calculate_memory_order(__m));
	}

	bool
	compare_exchange_strong(void& __v1, void __v2, memory_order __m1,
	memory_order __m2)
	{
	__glibcxx_assert(__m2 != memory_order_release);
	__glibcxx_assert(__m2 != memory_order_acq_rel);
	__glibcxx_assert(__m2 <= __m1);
	return _ATOMIC_CMPEXCHNG_(this, &__v1, __v2, __m1);
	}

	bool
	compare_exchange_strong(void& __v1, void __v2,
	memory_order __m = memory_order_seq_cst)
	{
	return compare_exchange_strong(__v1, __v2, __m,
	__calculate_memory_order(__m));
	}

	void*
	fetch_add(ptrdiff_t __d, memory_order __m = memory_order_seq_cst)
	{
	void** __p = &(_M_i);
	__atomic_flag_base* __g = __atomic_flag_for_address(__p);
	__atomic_flag_wait_explicit(__g, __m);
	void* __r = *__p;
	__p = (void)((char)(__p) + __d);
	atomic_flag_clear_explicit(__g, __m);
	return __r;
	}

	void*
	fetch_sub(ptrdiff_t __d, memory_order __m = memory_order_seq_cst)
	{
	void** __p = &(_M_i);
	__atomic_flag_base* __g = __atomic_flag_for_address(__p);
	__atomic_flag_wait_explicit(__g, __m);
	void* __r = *__p;
	__p = (void)((char)(__p) - __d);
	atomic_flag_clear_explicit(__g, __m);
	return __r;
	}

	operator void*() const
	{ return load(); }

	void*
	operator=(void* __v)
	{
	store(__v);
	return __v;
	}

	void*
	operator+=(ptrdiff_t __d)
	{ return fetch_add(__d) + __d; }

	void*
	operator-=(ptrdiff_t __d)
	{ return fetch_sub(__d) - __d; }
	};


	// 29.3.1 atomic integral types
	// For each of the integral types, define atomic_[integral type] struct
	//
	// atomic_bool bool
	// atomic_char char
	// atomic_schar signed char
	// atomic_uchar unsigned char
	// atomic_short short
	// atomic_ushort unsigned short
	// atomic_int int
	// atomic_uint unsigned int
	// atomic_long long
	// atomic_ulong unsigned long
	// atomic_llong long long
	// atomic_ullong unsigned long long
	// atomic_char16_t char16_t
	// atomic_char32_t char32_t
	// atomic_wchar_t wchar_t

	// Base type.
	// NB: Assuming _ITp is an integral scalar type that is 1, 2, 4, or 8 bytes,
	// since that is what GCC built-in functions for atomic memory access work on.
	template<typename _ITp>
	struct __atomic_base
	{
	private:
	typedef _ITp __integral_type;

	__integral_type _M_i;

	public:
	__atomic_base() = default;
	~__atomic_base() = default;
	__atomic_base(const __atomic_base&) = delete;
	__atomic_base& operator=(const __atomic_base&) volatile = delete;

	// Requires __integral_type convertible to _M_base._M_i.
	__atomic_base(__integral_type __i) { _M_i = __i; }

	operator __integral_type() const
	{ return load(); }

	__integral_type
	operator=(__integral_type __i)
	{
	store(__i);
	return __i;
	}

	__integral_type
	operator++(int)
	{ return fetch_add(1); }

	__integral_type
	operator--(int)
	{ return fetch_sub(1); }

	__integral_type
	operator++()
	{ return fetch_add(1) + 1; }

	__integral_type
	operator--()
	{ return fetch_sub(1) - 1; }

	__integral_type
	operator+=(__integral_type __i)
	{ return fetch_add(__i) + __i; }

	__integral_type
	operator-=(__integral_type __i)
	{ return fetch_sub(__i) - __i; }

	__integral_type
	operator&=(__integral_type __i)
	{ return fetch_and(__i) & __i; }

	__integral_type
	operator\|=(__integral_type __i)
	{ return fetch_or(__i) \| __i; }

	__integral_type
	operator^=(__integral_type __i)
	{ return fetch_xor(__i) ^ __i; }

	bool
	is_lock_free() const
	{ return false; }

	void
	store(__integral_type __i, memory_order __m = memory_order_seq_cst)
	{
	__glibcxx_assert(__m != memory_order_acquire);
	__glibcxx_assert(__m != memory_order_acq_rel);
	__glibcxx_assert(__m != memory_order_consume);
	_ATOMIC_STORE_(this, __i, __m);
	}

	__integral_type
	load(memory_order __m = memory_order_seq_cst) const
	{
	__glibcxx_assert(__m != memory_order_release);
	__glibcxx_assert(__m != memory_order_acq_rel);
	return _ATOMIC_LOAD_(this, __m);
	}

	__integral_type
	exchange(__integral_type __i, memory_order __m = memory_order_seq_cst)
	{ return _ATOMIC_MODIFY_(this, =, __i, __m); }

	bool
	compare_exchange_weak(__integral_type& __i1, __integral_type __i2,
	memory_order __m1, memory_order __m2)
	{
	__glibcxx_assert(__m2 != memory_order_release);
	__glibcxx_assert(__m2 != memory_order_acq_rel);
	__glibcxx_assert(__m2 <= __m1);
	return _ATOMIC_CMPEXCHNG_(this, &__i1, __i2, __m1);
	}

	bool
	compare_exchange_weak(__integral_type& __i1, __integral_type __i2,
	memory_order __m = memory_order_seq_cst)
	{
	return compare_exchange_weak(__i1, __i2, __m,
	__calculate_memory_order(__m));
	}

	bool
	compare_exchange_strong(__integral_type& __i1, __integral_type __i2,
	memory_order __m1, memory_order __m2)
	{
	__glibcxx_assert(__m2 != memory_order_release);
	__glibcxx_assert(__m2 != memory_order_acq_rel);
	__glibcxx_assert(__m2 <= __m1);
	return _ATOMIC_CMPEXCHNG_(this, &__i1, __i2, __m1);
	}

	bool
	compare_exchange_strong(__integral_type& __i1, __integral_type __i2,
	memory_order __m = memory_order_seq_cst)
	{
	return compare_exchange_strong(__i1, __i2, __m,
	__calculate_memory_order(__m));
	}

	__integral_type
	fetch_add(__integral_type __i, memory_order __m = memory_order_seq_cst)
	{ return _ATOMIC_MODIFY_(this, +=, __i, __m); }

	__integral_type
	fetch_sub(__integral_type __i, memory_order __m = memory_order_seq_cst)
	{ return _ATOMIC_MODIFY_(this, -=, __i, __m); }

	__integral_type
	fetch_and(__integral_type __i, memory_order __m = memory_order_seq_cst)
	{ return _ATOMIC_MODIFY_(this, &=, __i, __m); }

	__integral_type
	fetch_or(__integral_type __i, memory_order __m = memory_order_seq_cst)
	{ return _ATOMIC_MODIFY_(this, \|=, __i, __m); }

	__integral_type
	fetch_xor(__integral_type __i, memory_order __m = memory_order_seq_cst)
	{ return _ATOMIC_MODIFY_(this, ^=, __i, __m); }
	};


	/// atomic_bool
	// NB: No operators or fetch-operations for this type.
	struct atomic_bool
	{
	private:
	__atomic_base<bool> _M_base;

	public:
	atomic_bool() = default;
	~atomic_bool() = default;
	atomic_bool(const atomic_bool&) = delete;
	atomic_bool& operator=(const atomic_bool&) volatile = delete;

	atomic_bool(bool __i) : _M_base(__i) { }

	bool
	operator=(bool __i)
	{ return _M_base.operator=(__i); }

	operator bool() const
	{ return _M_base.load(); }

	bool
	is_lock_free() const
	{ return _M_base.is_lock_free(); }

	void
	store(bool __i, memory_order __m = memory_order_seq_cst)
	{ _M_base.store(__i, __m); }

	bool
	load(memory_order __m = memory_order_seq_cst) const
	{ return _M_base.load(__m); }

	bool
	exchange(bool __i, memory_order __m = memory_order_seq_cst)
	{ return _M_base.exchange(__i, __m); }

	bool
	compare_exchange_weak(bool& __i1, bool __i2, memory_order __m1,
	memory_order __m2)
	{ return _M_base.compare_exchange_weak(__i1, __i2, __m1, __m2); }

	bool
	compare_exchange_weak(bool& __i1, bool __i2,
	memory_order __m = memory_order_seq_cst)
	{ return _M_base.compare_exchange_weak(__i1, __i2, __m); }

	bool
	compare_exchange_strong(bool& __i1, bool __i2, memory_order __m1,
	memory_order __m2)
	{ return _M_base.compare_exchange_strong(__i1, __i2, __m1, __m2); }


	bool
	compare_exchange_strong(bool& __i1, bool __i2,
	memory_order __m = memory_order_seq_cst)
	{ return _M_base.compare_exchange_strong(__i1, __i2, __m); }
	};

	#undef _ATOMIC_LOAD_
	#undef _ATOMIC_STORE_
	#undef _ATOMIC_MODIFY_
	#undef _ATOMIC_CMPEXCHNG_
	} // namespace __atomic0

	// _GLIBCXX_END_NAMESPACE

	#endif