/* * Copyright (C) Igor Sysoev * Copyright (C) NGINX, Inc. */ #ifndef _NXT_ATOMIC_H_INCLUDED_ #define _NXT_ATOMIC_H_INCLUDED_ /* * nxt_atomic_try_lock() must set an acquire barrier on lock. * nxt_atomic_xchg() must set an acquire barrier. * nxt_atomic_release() must set a release barrier. */ #if (NXT_HAVE_GCC_ATOMIC) /* GCC 4.1 builtin atomic operations */ typedef intptr_t nxt_atomic_int_t; typedef uintptr_t nxt_atomic_uint_t; typedef volatile nxt_atomic_uint_t nxt_atomic_t; /* * __sync_bool_compare_and_swap() is a full barrier. * __sync_lock_test_and_set() is an acquire barrier. * __sync_lock_release() is a release barrier. */ #define nxt_atomic_cmp_set(lock, cmp, set) \ __sync_bool_compare_and_swap(lock, cmp, set) #define nxt_atomic_xchg(lock, set) \ __sync_lock_test_and_set(lock, set) #define nxt_atomic_fetch_add(value, add) \ __sync_fetch_and_add(value, add) #define nxt_atomic_try_lock(lock) \ nxt_atomic_cmp_set(lock, 0, 1) #define nxt_atomic_release(lock) \ __sync_lock_release(lock) #define nxt_atomic_or_fetch(ptr, val) \ __sync_or_and_fetch(ptr, val) #define nxt_atomic_and_fetch(ptr, val) \ __sync_and_and_fetch(ptr, val) #if (__i386__ || __i386 || __amd64__ || __amd64) #define nxt_cpu_pause() \ __asm__ ("pause") #else #define nxt_cpu_pause() #endif #elif (NXT_HAVE_SOLARIS_ATOMIC) /* Solaris 10 */ #include typedef long nxt_atomic_int_t; typedef ulong_t nxt_atomic_uint_t; typedef volatile nxt_atomic_uint_t nxt_atomic_t; #define nxt_atomic_cmp_set(lock, cmp, set) \ (atomic_cas_ulong(lock, cmp, set) == (ulong_t) cmp) #define nxt_atomic_xchg(lock, set) \ atomic_add_swap(lock, set) #define nxt_atomic_fetch_add(value, add) \ (atomic_add_long_nv(value, add) - add) #define nxt_atomic_or_fetch(ptr, val) \ atomic_or_ulong_nv(ptr, val) #define nxt_atomic_and_fetch(ptr, val) \ atomic_and_ulong_nv(ptr, val) /* * Solaris uses SPARC Total Store Order model. In this model: * 1) Each atomic load-store instruction behaves as if it were followed by * #LoadLoad, #LoadStore, and #StoreStore barriers. * 2) Each load instruction behaves as if it were followed by * #LoadLoad and #LoadStore barriers. * 3) Each store instruction behaves as if it were followed by * #StoreStore barrier. * * In X86_64 atomic instructions set a full barrier and usual instructions * set implicit #LoadLoad, #LoadStore, and #StoreStore barriers. * * An acquire barrier requires at least #LoadLoad and #LoadStore barriers * and they are provided by atomic load-store instruction. * * A release barrier requires at least #LoadStore and #StoreStore barriers, * so a lock release does not require an explicit barrier: all load * instructions in critical section is followed by implicit #LoadStore * barrier and all store instructions are followed by implicit #StoreStore * barrier. */ #define nxt_atomic_try_lock(lock) \ nxt_atomic_cmp_set(lock, 0, 1) #define nxt_atomic_release(lock) \ *lock = 0; /* * The "rep; nop" is used instead of "pause" to omit the "[ PAUSE ]" hardware * capability added by linker since Solaris ld.so.1 does not know about it: * * ld.so.1: ...: fatal: hardware capability unsupported: 0x2000 [ PAUSE ] */ #if (__i386__ || __i386 || __amd64__ || __amd64) #define nxt_cpu_pause() \ __asm__ ("rep; nop") #else #define nxt_cpu_pause() #endif /* elif (NXT_HAVE_MACOSX_ATOMIC) */ /* * The atomic(3) interface has been introduced in MacOS 10.4 (Tiger) and * extended in 10.5 (Leopard). However its support is omitted because: * * 1) the interface is still incomplete: * *) there are OSAtomicAdd32Barrier() and OSAtomicAdd64Barrier() * but no OSAtomicAddLongBarrier(); * *) there is no interface for XCHG operation. * * 2) the interface is tuned for non-SMP systems due to omission of the * LOCK prefix on single CPU system but nowadays MacOSX systems are at * least dual core. Thus these indirect calls just add overhead as * compared with inlined atomic operations which are supported by GCC * and Clang in modern MacOSX systems. */ #elif (NXT_HAVE_XLC_ATOMIC) /* XL C/C++ V8.0 for AIX */ #if (NXT_64BIT) typedef long nxt_atomic_int_t; typedef unsigned long nxt_atomic_uint_t; typedef volatile nxt_atomic_int_t nxt_atomic_t; nxt_inline nxt_bool_t nxt_atomic_cmp_set(nxt_atomic_t *lock, nxt_atomic_int_t cmp, nxt_atomic_int_t set) { nxt_atomic_int_t old; old = cmp; return __compare_and_swaplp(lock, &old, set); } #define nxt_atomic_xchg(lock, set) \ __fetch_and_swaplp(lock, set) #define nxt_atomic_fetch_add(value, add) \ __fetch_and_addlp(value, add) #else /* NXT_32BIT */ typedef int nxt_atomic_int_t; typedef unsigned int nxt_atomic_uint_t; typedef volatile nxt_atomic_int_t nxt_atomic_t; nxt_inline nxt_bool_t nxt_atomic_cmp_set(nxt_atomic_t *lock, nxt_atomic_int_t cmp, nxt_atomic_int_t set) { nxt_atomic_int_t old; old = cmp; return __compare_and_swap(lock, &old, set); } #define nxt_atomic_xchg(lock, set) \ __fetch_and_swap(lock, set) #define nxt_atomic_fetch_add(value, add) \ __fetch_and_add(value, add) #endif /* NXT_32BIT*/ /* * __lwsync() is a "lwsync" instruction that sets #LoadLoad, #LoadStore, * and #StoreStore barrier. * * __compare_and_swap() is a pair of "ldarx" and "stdcx" instructions. * A "lwsync" does not set #StoreLoad barrier so it can not be used after * this pair since a next load inside critical section can be performed * after the "ldarx" instruction but before the "stdcx" instruction. * However, this next load instruction will load correct data because * otherwise the "ldarx/stdcx" pair will fail and this data will be * discarded. Nevertheless, the "isync" instruction is used for sure. * * A full barrier can be set with __sync(), a "sync" instruction, but there * is also a faster __isync(), an "isync" instruction. This instruction is * not a memory barrier but an instruction barrier. An "isync" instruction * causes the processor to complete execution of all previous instructions * and then to discard instructions (which may have begun execution) following * the "isync". After the "isync" is executed, the following instructions * then begin execution. The "isync" is used to ensure that the loads * following entry into a critical section are not performed (because of * aggressive out-of-order or speculative execution in the processor) until * the lock is granted. */ nxt_inline nxt_bool_t nxt_atomic_try_lock(nxt_atomic_t *lock) { if (nxt_atomic_cmp_set(lock, 0, 1)) { __isync(); return 1; } return 0; } #define nxt_atomic_release(lock) \ do { __lwsync(); *lock = 0; } while (0) #define nxt_cpu_pause() #endif /* NXT_HAVE_XLC_ATOMIC */ #endif /* _NXT_ATOMIC_H_INCLUDED_ */