third_party/llvm-project/libcxx/src/memory.cpp - cobalt - Git at Google

 //===------------------------ memory.cpp ----------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "memory"
 #ifndef _LIBCPP_HAS_NO_THREADS
 #include "mutex"
 #include "thread"
 #endif
 #include "include/atomic_support.h"

 _LIBCPP_BEGIN_NAMESPACE_STD

 const allocator_arg_t allocator_arg = allocator_arg_t();

 bad_weak_ptr::~bad_weak_ptr() _NOEXCEPT {}

 const char*
 bad_weak_ptr::what() const _NOEXCEPT
 {
     return "bad_weak_ptr";
 }

 __shared_count::~__shared_count()
 {
 }

 __shared_weak_count::~__shared_weak_count()
 {
 }

 #if defined(_LIBCPP_DEPRECATED_ABI_LEGACY_LIBRARY_DEFINITIONS_FOR_INLINE_FUNCTIONS)
 void
 __shared_count::__add_shared() _NOEXCEPT
 {
     __libcpp_atomic_refcount_increment(__shared_owners_);
 }

 bool
 __shared_count::__release_shared() _NOEXCEPT
 {
     if (__libcpp_atomic_refcount_decrement(__shared_owners_) == -1)
     {
         __on_zero_shared();
         return true;
     }
     return false;
 }

 void
 __shared_weak_count::__add_shared() _NOEXCEPT
 {
     __shared_count::__add_shared();
 }

 void
 __shared_weak_count::__add_weak() _NOEXCEPT
 {
     __libcpp_atomic_refcount_increment(__shared_weak_owners_);
 }

 void
 __shared_weak_count::__release_shared() _NOEXCEPT
 {
     if (__shared_count::__release_shared())
         __release_weak();
 }

 #endif // _LIBCPP_DEPRECATED_ABI_LEGACY_LIBRARY_DEFINITIONS_FOR_INLINE_FUNCTIONS

 void
 __shared_weak_count::__release_weak() _NOEXCEPT
 {
     // NOTE: The acquire load here is an optimization of the very
     // common case where a shared pointer is being destructed while
     // having no other contended references.
     //
     // BENEFIT: We avoid expensive atomic stores like XADD and STREX
     // in a common case.  Those instructions are slow and do nasty
     // things to caches.
     //
     // IS THIS SAFE?  Yes.  During weak destruction, if we see that we
     // are the last reference, we know that no-one else is accessing
     // us. If someone were accessing us, then they would be doing so
     // while the last shared / weak_ptr was being destructed, and
     // that's undefined anyway.
     //
     // If we see anything other than a 0, then we have possible
     // contention, and need to use an atomicrmw primitive.
     // The same arguments don't apply for increment, where it is legal
     // (though inadvisable) to share shared_ptr references between
     // threads, and have them all get copied at once.  The argument
     // also doesn't apply for __release_shared, because an outstanding
     // weak_ptr::lock() could read / modify the shared count.
     if (__libcpp_atomic_load(&__shared_weak_owners_, _AO_Acquire) == 0)
     {
         // no need to do this store, because we are about
         // to destroy everything.
         //__libcpp_atomic_store(&__shared_weak_owners_, -1, _AO_Release);
         __on_zero_shared_weak();
     }
     else if (__libcpp_atomic_refcount_decrement(__shared_weak_owners_) == -1)
         __on_zero_shared_weak();
 }

 __shared_weak_count*
 __shared_weak_count::lock() _NOEXCEPT
 {
     long object_owners = __libcpp_atomic_load(&__shared_owners_);
     while (object_owners != -1)
     {
         if (__libcpp_atomic_compare_exchange(&__shared_owners_,
                                              &object_owners,
                                              object_owners+1))
             return this;
     }
     return nullptr;
 }

 #if !defined(_LIBCPP_NO_RTTI) || !defined(_LIBCPP_BUILD_STATIC)

 const void*
 __shared_weak_count::__get_deleter(const type_info&) const _NOEXCEPT
 {
     return nullptr;
 }

 #endif  // _LIBCPP_NO_RTTI

 #if !defined(_LIBCPP_HAS_NO_ATOMIC_HEADER)

 _LIBCPP_SAFE_STATIC static const std::size_t __sp_mut_count = 16;
 _LIBCPP_SAFE_STATIC static __libcpp_mutex_t mut_back[__sp_mut_count] =
 {
     _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER,
     _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER,
     _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER,
     _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER
 };

 _LIBCPP_CONSTEXPR __sp_mut::__sp_mut(void* p) _NOEXCEPT
    : __lx(p)
 {
 }

 void
 __sp_mut::lock() _NOEXCEPT
 {
     auto m = static_cast<__libcpp_mutex_t*>(__lx);
     unsigned count = 0;
     while (!__libcpp_mutex_trylock(m))
     {
         if (++count > 16)
         {
             __libcpp_mutex_lock(m);
             break;
         }
         this_thread::yield();
     }
 }

 void
 __sp_mut::unlock() _NOEXCEPT
 {
     __libcpp_mutex_unlock(static_cast<__libcpp_mutex_t*>(__lx));
 }

 __sp_mut&
 __get_sp_mut(const void* p)
 {
     static __sp_mut muts[__sp_mut_count]
     {
         &mut_back[ 0], &mut_back[ 1], &mut_back[ 2], &mut_back[ 3],
         &mut_back[ 4], &mut_back[ 5], &mut_back[ 6], &mut_back[ 7],
         &mut_back[ 8], &mut_back[ 9], &mut_back[10], &mut_back[11],
         &mut_back[12], &mut_back[13], &mut_back[14], &mut_back[15]
     };
     return muts[hash<const void*>()(p) & (__sp_mut_count-1)];
 }

 #endif // !defined(_LIBCPP_HAS_NO_ATOMIC_HEADER)

 void
 declare_reachable(void*)
 {
 }

 void
 declare_no_pointers(char*, size_t)
 {
 }

 void
 undeclare_no_pointers(char*, size_t)
 {
 }

 #if !defined(_LIBCPP_ABI_POINTER_SAFETY_ENUM_TYPE)
 pointer_safety get_pointer_safety() _NOEXCEPT
 {
     return pointer_safety::relaxed;
 }
 #endif

 void*
 __undeclare_reachable(void* p)
 {
     return p;
 }

 void*
 align(size_t alignment, size_t size, void*& ptr, size_t& space)
 {
     void* r = nullptr;
     if (size <= space)
     {
         char* p1 = static_cast<char*>(ptr);
         char* p2 = reinterpret_cast<char*>(reinterpret_cast<size_t>(p1 + (alignment - 1)) & -alignment);
         size_t d = static_cast<size_t>(p2 - p1);
         if (d <= space - size)
         {
             r = p2;
             ptr = r;
             space -= d;
         }
     }
     return r;
 }

 _LIBCPP_END_NAMESPACE_STD
	//===------------------------ memory.cpp ----------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "memory"
	#ifndef _LIBCPP_HAS_NO_THREADS
	#include "mutex"
	#include "thread"
	#endif
	#include "include/atomic_support.h"

	_LIBCPP_BEGIN_NAMESPACE_STD

	const allocator_arg_t allocator_arg = allocator_arg_t();

	bad_weak_ptr::~bad_weak_ptr() _NOEXCEPT {}

	const char*
	bad_weak_ptr::what() const _NOEXCEPT
	{
	return "bad_weak_ptr";
	}

	__shared_count::~__shared_count()
	{
	}

	__shared_weak_count::~__shared_weak_count()
	{
	}

	#if defined(_LIBCPP_DEPRECATED_ABI_LEGACY_LIBRARY_DEFINITIONS_FOR_INLINE_FUNCTIONS)
	void
	__shared_count::__add_shared() _NOEXCEPT
	{
	__libcpp_atomic_refcount_increment(__shared_owners_);
	}

	bool
	__shared_count::__release_shared() _NOEXCEPT
	{
	if (__libcpp_atomic_refcount_decrement(__shared_owners_) == -1)
	{
	__on_zero_shared();
	return true;
	}
	return false;
	}

	void
	__shared_weak_count::__add_shared() _NOEXCEPT
	{
	__shared_count::__add_shared();
	}

	void
	__shared_weak_count::__add_weak() _NOEXCEPT
	{
	__libcpp_atomic_refcount_increment(__shared_weak_owners_);
	}

	void
	__shared_weak_count::__release_shared() _NOEXCEPT
	{
	if (__shared_count::__release_shared())
	__release_weak();
	}

	#endif // _LIBCPP_DEPRECATED_ABI_LEGACY_LIBRARY_DEFINITIONS_FOR_INLINE_FUNCTIONS

	void
	__shared_weak_count::__release_weak() _NOEXCEPT
	{
	// NOTE: The acquire load here is an optimization of the very
	// common case where a shared pointer is being destructed while
	// having no other contended references.
	//
	// BENEFIT: We avoid expensive atomic stores like XADD and STREX
	// in a common case. Those instructions are slow and do nasty
	// things to caches.
	//
	// IS THIS SAFE? Yes. During weak destruction, if we see that we
	// are the last reference, we know that no-one else is accessing
	// us. If someone were accessing us, then they would be doing so
	// while the last shared / weak_ptr was being destructed, and
	// that's undefined anyway.
	//
	// If we see anything other than a 0, then we have possible
	// contention, and need to use an atomicrmw primitive.
	// The same arguments don't apply for increment, where it is legal
	// (though inadvisable) to share shared_ptr references between
	// threads, and have them all get copied at once. The argument
	// also doesn't apply for __release_shared, because an outstanding
	// weak_ptr::lock() could read / modify the shared count.
	if (__libcpp_atomic_load(&__shared_weak_owners_, _AO_Acquire) == 0)
	{
	// no need to do this store, because we are about
	// to destroy everything.
	//__libcpp_atomic_store(&__shared_weak_owners_, -1, _AO_Release);
	__on_zero_shared_weak();
	}
	else if (__libcpp_atomic_refcount_decrement(__shared_weak_owners_) == -1)
	__on_zero_shared_weak();
	}

	__shared_weak_count*
	__shared_weak_count::lock() _NOEXCEPT
	{
	long object_owners = __libcpp_atomic_load(&__shared_owners_);
	while (object_owners != -1)
	{
	if (__libcpp_atomic_compare_exchange(&__shared_owners_,
	&object_owners,
	object_owners+1))
	return this;
	}
	return nullptr;
	}

	#if !defined(_LIBCPP_NO_RTTI) \|\| !defined(_LIBCPP_BUILD_STATIC)

	const void*
	__shared_weak_count::__get_deleter(const type_info&) const _NOEXCEPT
	{
	return nullptr;
	}

	#endif // _LIBCPP_NO_RTTI

	#if !defined(_LIBCPP_HAS_NO_ATOMIC_HEADER)

	_LIBCPP_SAFE_STATIC static const std::size_t __sp_mut_count = 16;
	_LIBCPP_SAFE_STATIC static __libcpp_mutex_t mut_back[__sp_mut_count] =
	{
	_LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER,
	_LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER,
	_LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER,
	_LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER, _LIBCPP_MUTEX_INITIALIZER
	};

	_LIBCPP_CONSTEXPR __sp_mut::__sp_mut(void* p) _NOEXCEPT
	: __lx(p)
	{
	}

	void
	__sp_mut::lock() _NOEXCEPT
	{
	auto m = static_cast<__libcpp_mutex_t*>(__lx);
	unsigned count = 0;
	while (!__libcpp_mutex_trylock(m))
	{
	if (++count > 16)
	{
	__libcpp_mutex_lock(m);
	break;
	}
	this_thread::yield();
	}
	}

	void
	__sp_mut::unlock() _NOEXCEPT
	{
	__libcpp_mutex_unlock(static_cast<__libcpp_mutex_t*>(__lx));
	}

	__sp_mut&
	__get_sp_mut(const void* p)
	{
	static __sp_mut muts[__sp_mut_count]
	{
	&mut_back[ 0], &mut_back[ 1], &mut_back[ 2], &mut_back[ 3],
	&mut_back[ 4], &mut_back[ 5], &mut_back[ 6], &mut_back[ 7],
	&mut_back[ 8], &mut_back[ 9], &mut_back[10], &mut_back[11],
	&mut_back[12], &mut_back[13], &mut_back[14], &mut_back[15]
	};
	return muts[hash<const void*>()(p) & (__sp_mut_count-1)];
	}

	#endif // !defined(_LIBCPP_HAS_NO_ATOMIC_HEADER)

	void
	declare_reachable(void*)
	{
	}

	void
	declare_no_pointers(char*, size_t)
	{
	}

	void
	undeclare_no_pointers(char*, size_t)
	{
	}

	#if !defined(_LIBCPP_ABI_POINTER_SAFETY_ENUM_TYPE)
	pointer_safety get_pointer_safety() _NOEXCEPT
	{
	return pointer_safety::relaxed;
	}
	#endif

	void*
	__undeclare_reachable(void* p)
	{
	return p;
	}

	void*
	align(size_t alignment, size_t size, void*& ptr, size_t& space)
	{
	void* r = nullptr;
	if (size <= space)
	{
	char* p1 = static_cast<char*>(ptr);
	char* p2 = reinterpret_cast<char*>(reinterpret_cast<size_t>(p1 + (alignment - 1)) & -alignment);
	size_t d = static_cast<size_t>(p2 - p1);
	if (d <= space - size)
	{
	r = p2;
	ptr = r;
	space -= d;
	}
	}
	return r;
	}

	_LIBCPP_END_NAMESPACE_STD