//===------------------------ 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. // //===----------------------------------------------------------------------===// #define _LIBCPP_BUILDING_MEMORY #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()(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(ptr); char* p2 = reinterpret_cast(reinterpret_cast(p1 + (alignment - 1)) & -alignment); size_t d = static_cast(p2 - p1); if (d <= space - size) { r = p2; ptr = r; space -= d; } } return r; } _LIBCPP_END_NAMESPACE_STD