#pragma once #include "ExtendedAtomicTypes.h" UNITY_PLATFORM_BEGIN_NAMESPACE; enum memory_order_relaxed_t { memory_order_relaxed = 0 }; enum memory_order_acquire_t { memory_order_acquire = 2, memory_order_consume = memory_order_acquire }; enum memory_order_release_t { memory_order_release = 3 }; enum memory_order_acq_rel_t { memory_order_acq_rel = 4 }; enum memory_order_seq_cst_t { memory_order_seq_cst = 5 }; /* Available atomic functions: // non-explicit versions, use sequential consistency semantic by default // atomic load atomic_word atomic_load (const volatile atomic_word* p); // atomic store void atomic_store (volatile atomic_word* p, atomic_word val); // atomic exchange, returns previous value atomic_word atomic_exchange (volatile atomic_word* p, atomic_word val); // atomic compare exchange (strong), returns if the operation succeeded and update *oldval with the previous value bool atomic_compare_exchange (volatile atomic_word* p, atomic_word* oldval, atomic_word newval); // atomic fetch then add, returns previous value atomic_word atomic_fetch_add (volatile atomic_word *p, atomic_word val); // atomic fetch then sub, returns previous value atomic_word atomic_fetch_sub (volatile atomic_word *p, atomic_word val); // explicit versions // memory fence with semantic void atomic_thread_fence (memory_order_t mo); // atomic load with semantic atomic_word atomic_load_explicit (const volatile atomic_word* p, memory_order_t mo); // atomic store with semantic void atomic_store_explicit (volatile atomic_word* p, atomic_word v, memory_order_t mo); // atomic exchange with semantic, returns previous value atomic_word atomic_exchange_explicit (volatile atomic_word* p, atomic_word v, memory_order_t mo); // on RISC platforms with LoadLinked-StoreConditional available: // atomic_compare_exchange_weak_explicit: can fail spuriously even if *p == *oldval // uses memory barrier when it succeeds, otherwize // returns the state of the operation and updates *oldval with the previous value bool atomic_compare_exchange_weak_explicit (volatile atomic_word* p, atomic_word *oldval, atomic_word newval, memory_order_t success, memory_order_t failure); // atomic_compare_exchange_strong_explicit: can loop and only returns false if *p != *oldval // uses memory barrier when it succeeds, otherwise // returns the state of the operation and updates *oldval with the previous value bool atomic_compare_exchange_strong_explicit (volatile atomic_word* p, atomic_word *oldval, atomic_word newval, memory_order_t success, memory_order_t failure); // atomic fetch then add with semantic, returns previous value int atomic_fetch_add_explicit (volatile int* p, int val, memory_order_t mo); atomic_word atomic_fetch_add_explicit (volatile atomic_word* p, atomic_word val, memory_order_t mo); // atomic fetch then sub with semantic, returns previous value int atomic_fetch_sub_explicit (volatile int* p, int val, memory_order_t mo); atomic_word atomic_fetch_sub_explicit (volatile atomic_word* p, atomic_word val, memory_order_t mo); // extensions to the C++0x11 standard: // atomic increment with relaxed semantic void atomic_retain (volatile int *p); // atomic decrement with acquire/release semantic, returns true if resulting value is zero, false otherwize bool atomic_release (volatile int *p); // on platforms with double word compare exchange (ABA safe atomic pointers): // atomic load atomic_word2 atomic_load_explicit (const volatile atomic_word2* p, memory_order_t mo); // atomic store void atomic_store_explicit (volatile atomic_word2* p, atomic_word2 v, memory_order_t mo); // atomic exchange atomic_word atomic_exchange_explicit (volatile atomic_word2* p, atomic_word2 newval, memory_order_t mo); // atomic compare exchange bool atomic_compare_exchange_strong_explicit (volatile atomic_word2* p, atomic_word2* oldval, atomic_word2 newval, memory_order_t success, memory_order_t failure); */ #if IL2CPP_TARGET_HAS_EXTENDED_ATOMICS # include "os/ExtendedAtomicOps.h" #elif UNITY_ATOMIC_USE_GCC_ATOMICS || UNITY_ATOMIC_USE_CLANG_ATOMICS # include "ExtendedAtomicOps-clang-gcc.h" #elif defined(__x86_64__) || defined(_M_X64) # include "ExtendedAtomicOps-x86-64.h" # define UNITY_ATOMIC_INT_OVERLOAD #elif defined(__x86__) || defined(__i386__) || defined(_M_IX86) # include "ExtendedAtomicOps-x86.h" #elif (defined(__arm64__) || defined(__aarch64__)) && (defined(__clang__) || defined(__GNUC__)) # include "ExtendedAtomicOps-arm64.h" # define UNITY_ATOMIC_INT_OVERLOAD #elif defined(_M_ARM) || (defined(__arm__) && (defined(__ARM_ARCH_7__) || defined(__ARM_ARCH_7A__) || defined(__ARM_ARCH_7R__) || defined(__ARM_ARCH_7M__) || defined(__ARM_ARCH_7S__)) && (!UNITY_STV_API) && (defined(__clang__) || defined(__GNUC__))) # include "ExtendedAtomicOps-arm.h" #elif PLATFORM_WIIU # include "ExtendedAtomicOps-ppc.h" #elif PLATFORM_PSVITA # include "PlatformExtendedAtomicOps.h" #elif (defined(__ppc64__) || defined(_ARCH_PPC64)) && (defined(__clang__) || defined(__GNUC__)) # include "ExtendedAtomicOps-ppc64.h" # define UNITY_ATOMIC_INT_OVERLOAD //#elif defined (__ppc__) && (defined (__clang__) || defined (__GNUC__)) //# include "Runtime/Threads/ExtendedAtomicOps-ppc.h" #else #define UNITY_NO_ATOMIC_OPS static inline atomic_word atomic_load_explicit(const volatile atomic_word* p, memory_order_relaxed_t) { return *p; } static inline void atomic_store_explicit(volatile atomic_word* p, atomic_word v, memory_order_relaxed_t) { *p = v; } #endif #ifndef UNITY_NO_ATOMIC_OPS // non-explicit versions, use sequential consistency semantic static inline void atomic_thread_fence() { atomic_thread_fence(memory_order_seq_cst); } static inline atomic_word atomic_load(const volatile atomic_word* p) { return atomic_load_explicit(p, memory_order_seq_cst); } static inline void atomic_store(volatile atomic_word* p, atomic_word val) { atomic_store_explicit(p, val, memory_order_seq_cst); } static inline atomic_word atomic_exchange(volatile atomic_word* p, atomic_word val) { return atomic_exchange_explicit(p, val, memory_order_seq_cst); } static inline bool atomic_compare_exchange(volatile atomic_word* p, atomic_word* oldval, atomic_word newval) { return atomic_compare_exchange_strong_explicit(p, oldval, newval, memory_order_seq_cst, memory_order_seq_cst); } static inline atomic_word atomic_fetch_add(volatile atomic_word *p, atomic_word val) { return atomic_fetch_add_explicit(p, val, memory_order_seq_cst); } static inline atomic_word atomic_fetch_sub(volatile atomic_word *p, atomic_word val) { return atomic_fetch_sub_explicit(p, val, memory_order_seq_cst); } #if defined(UNITY_ATOMIC_INT_OVERLOAD) static inline int atomic_load(const volatile int* p) { return atomic_load_explicit(p, memory_order_seq_cst); } static inline void atomic_store(volatile int* p, int val) { atomic_store_explicit(p, val, memory_order_seq_cst); } static inline int atomic_fetch_add(volatile int *p, int val) { return static_cast(atomic_fetch_add_explicit(p, val, memory_order_seq_cst)); } static inline int atomic_fetch_sub(volatile int *p, int val) { return static_cast(atomic_fetch_sub_explicit(p, val, memory_order_seq_cst)); } #endif #endif UNITY_PLATFORM_END_NAMESPACE;