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Code Editor : atomic.h
#ifndef RUBY_ATOMIC_H /*-*-C++-*-vi:se ft=cpp:*/ #define RUBY_ATOMIC_H /** * @file * @author Ruby developers <ruby-core@ruby-lang.org> * @copyright This file is a part of the programming language Ruby. * Permission is hereby granted, to either redistribute and/or * modify this file, provided that the conditions mentioned in the * file COPYING are met. Consult the file for details. * @warning Symbols prefixed with either `RBIMPL` or `rbimpl` are * implementation details. Don't take them as canon. They could * rapidly appear then vanish. The name (path) of this header file * is also an implementation detail. Do not expect it to persist * at the place it is now. Developers are free to move it anywhere * anytime at will. * @note To ruby-core: remember that this header can be possibly * recursively included from extension libraries written in C++. * Do not expect for instance `__VA_ARGS__` is always available. * We assume C99 for ruby itself but we don't assume languages of * extension libraries. They could be written in C++98. * @brief Atomic operations * * Basically, if we could assume either C11 or C++11, these macros are just * redundant. Sadly we cannot. We have to do them ourselves. */ #include "ruby/internal/config.h" #ifdef STDC_HEADERS # include <stddef.h> /* size_t */ #endif #ifdef HAVE_SYS_TYPES_H # include <sys/types.h> /* ssize_t */ #endif #if RBIMPL_COMPILER_SINCE(MSVC, 13, 0, 0) # pragma intrinsic(_InterlockedOr) #elif defined(__sun) && defined(HAVE_ATOMIC_H) # include <atomic.h> #endif #include "ruby/assert.h" #include "ruby/backward/2/limits.h" #include "ruby/internal/attr/artificial.h" #include "ruby/internal/attr/noalias.h" #include "ruby/internal/attr/nonnull.h" #include "ruby/internal/compiler_since.h" #include "ruby/internal/cast.h" #include "ruby/internal/value.h" #include "ruby/internal/static_assert.h" #include "ruby/internal/stdbool.h" /* * Asserts that your environment supports more than one atomic types. These * days systems tend to have such property (C11 was a standard of decades ago, * right?) but we still support older ones. */ #if defined(__DOXYGEN__) || defined(HAVE_GCC_ATOMIC_BUILTINS) || defined(HAVE_GCC_SYNC_BUILTINS) # define RUBY_ATOMIC_GENERIC_MACRO 1 #endif /** * Type that is eligible for atomic operations. Depending on your host * platform you might have more than one such type, but we choose one of them * anyways. */ #if defined(__DOXYGEN__) using rb_atomic_t = std::atomic<unsigned>; #elif defined(HAVE_GCC_ATOMIC_BUILTINS) typedef unsigned int rb_atomic_t; #elif defined(HAVE_GCC_SYNC_BUILTINS) typedef unsigned int rb_atomic_t; #elif defined(_WIN32) typedef LONG rb_atomic_t; #elif defined(__sun) && defined(HAVE_ATOMIC_H) typedef unsigned int rb_atomic_t; #else # error No atomic operation found #endif /** * Atomically replaces the value pointed by `var` with the result of addition * of `val` to the old value of `var`. * * @param var A variable of ::rb_atomic_t. * @param val Value to add. * @return What was stored in `var` before the addition. * @post `var` holds `var + val`. */ #define RUBY_ATOMIC_FETCH_ADD(var, val) rbimpl_atomic_fetch_add(&(var), (val)) /** * Atomically replaces the value pointed by `var` with the result of * subtraction of `val` to the old value of `var`. * * @param var A variable of ::rb_atomic_t. * @param val Value to subtract. * @return What was stored in `var` before the subtraction. * @post `var` holds `var - val`. */ #define RUBY_ATOMIC_FETCH_SUB(var, val) rbimpl_atomic_fetch_sub(&(var), (val)) /** * Atomically replaces the value pointed by `var` with the result of * bitwise OR between `val` and the old value of `var`. * * @param var A variable of ::rb_atomic_t. * @param val Value to mix. * @return void * @post `var` holds `var | val`. * @note For portability, this macro can return void. */ #define RUBY_ATOMIC_OR(var, val) rbimpl_atomic_or(&(var), (val)) /** * Atomically replaces the value pointed by `var` with `val`. This is just an * assignment, but you can additionally know the previous value. * * @param var A variable of ::rb_atomic_t. * @param val Value to set. * @return What was stored in `var` before the assignment. * @post `var` holds `val`. */ #define RUBY_ATOMIC_EXCHANGE(var, val) rbimpl_atomic_exchange(&(var), (val)) /** * Atomic compare-and-swap. This stores `val` to `var` if and only if the * assignment changes the value of `var` from `oldval` to `newval`. You can * detect whether the assignment happened or not using the return value. * * @param var A variable of ::rb_atomic_t. * @param oldval Expected value of `var` before the assignment. * @param newval What you want to store at `var`. * @retval oldval Successful assignment (`var` is now `newval`). * @retval otherwise Something else is at `var`; not updated. */ #define RUBY_ATOMIC_CAS(var, oldval, newval) \ rbimpl_atomic_cas(&(var), (oldval), (newval)) /** * Atomic load. This loads `var` with an atomic intrinsic and returns * its value. * * @param var A variable of ::rb_atomic_t * @return What was stored in `var`j */ #define RUBY_ATOMIC_LOAD(var) rbimpl_atomic_load(&(var)) /** * Identical to #RUBY_ATOMIC_EXCHANGE, except for the return type. * * @param var A variable of ::rb_atomic_t. * @param val Value to set. * @return void * @post `var` holds `val`. */ #define RUBY_ATOMIC_SET(var, val) rbimpl_atomic_set(&(var), (val)) /** * Identical to #RUBY_ATOMIC_FETCH_ADD, except for the return type. * * @param var A variable of ::rb_atomic_t. * @param val Value to add. * @return void * @post `var` holds `var + val`. */ #define RUBY_ATOMIC_ADD(var, val) rbimpl_atomic_add(&(var), (val)) /** * Identical to #RUBY_ATOMIC_FETCH_SUB, except for the return type. * * @param var A variable of ::rb_atomic_t. * @param val Value to subtract. * @return void * @post `var` holds `var - val`. */ #define RUBY_ATOMIC_SUB(var, val) rbimpl_atomic_sub(&(var), (val)) /** * Atomically increments the value pointed by `var`. * * @param var A variable of ::rb_atomic_t. * @return void * @post `var` holds `var + 1`. */ #define RUBY_ATOMIC_INC(var) rbimpl_atomic_inc(&(var)) /** * Atomically decrements the value pointed by `var`. * * @param var A variable of ::rb_atomic_t. * @return void * @post `var` holds `var - 1`. */ #define RUBY_ATOMIC_DEC(var) rbimpl_atomic_dec(&(var)) /** * Identical to #RUBY_ATOMIC_INC, except it expects its argument is `size_t`. * There are cases where ::rb_atomic_t is 32bit while `size_t` is 64bit. This * should be used for size related operations to support such platforms. * * @param var A variable of `size_t`. * @return void * @post `var` holds `var + 1`. */ #define RUBY_ATOMIC_SIZE_INC(var) rbimpl_atomic_size_inc(&(var)) /** * Identical to #RUBY_ATOMIC_DEC, except it expects its argument is `size_t`. * There are cases where ::rb_atomic_t is 32bit while `size_t` is 64bit. This * should be used for size related operations to support such platforms. * * @param var A variable of `size_t`. * @return void * @post `var` holds `var - 1`. */ #define RUBY_ATOMIC_SIZE_DEC(var) rbimpl_atomic_size_dec(&(var)) /** * Identical to #RUBY_ATOMIC_EXCHANGE, except it expects its arguments are * `size_t`. There are cases where ::rb_atomic_t is 32bit while `size_t` is * 64bit. This should be used for size related operations to support such * platforms. * * @param var A variable of `size_t`. * @param val Value to set. * @return What was stored in `var` before the assignment. * @post `var` holds `val`. */ #define RUBY_ATOMIC_SIZE_EXCHANGE(var, val) \ rbimpl_atomic_size_exchange(&(var), (val)) /** * Identical to #RUBY_ATOMIC_CAS, except it expects its arguments are `size_t`. * There are cases where ::rb_atomic_t is 32bit while `size_t` is 64bit. This * should be used for size related operations to support such platforms. * * @param var A variable of `size_t`. * @param oldval Expected value of `var` before the assignment. * @param newval What you want to store at `var`. * @retval oldval Successful assignment (`var` is now `newval`). * @retval otherwise Something else is at `var`; not updated. */ #define RUBY_ATOMIC_SIZE_CAS(var, oldval, newval) \ rbimpl_atomic_size_cas(&(var), (oldval), (newval)) /** * Identical to #RUBY_ATOMIC_ADD, except it expects its arguments are `size_t`. * There are cases where ::rb_atomic_t is 32bit while `size_t` is 64bit. This * should be used for size related operations to support such platforms. * * @param var A variable of `size_t`. * @param val Value to add. * @return void * @post `var` holds `var + val`. */ #define RUBY_ATOMIC_SIZE_ADD(var, val) rbimpl_atomic_size_add(&(var), (val)) /** * Identical to #RUBY_ATOMIC_SUB, except it expects its arguments are `size_t`. * There are cases where ::rb_atomic_t is 32bit while `size_t` is 64bit. This * should be used for size related operations to support such platforms. * * @param var A variable of `size_t`. * @param val Value to subtract. * @return void * @post `var` holds `var - val`. */ #define RUBY_ATOMIC_SIZE_SUB(var, val) rbimpl_atomic_size_sub(&(var), (val)) /** * Identical to #RUBY_ATOMIC_EXCHANGE, except it expects its arguments are * `void*`. There are cases where ::rb_atomic_t is 32bit while `void*` is * 64bit. This should be used for pointer related operations to support such * platforms. * * @param var A variable of `void *`. * @param val Value to set. * @return What was stored in `var` before the assignment. * @post `var` holds `val`. * * @internal * * :FIXME: this `(void*)` cast is evil! However `void*` is incompatible with * some pointers, most notably function pointers. */ #define RUBY_ATOMIC_PTR_EXCHANGE(var, val) \ RBIMPL_CAST(rbimpl_atomic_ptr_exchange((void **)&(var), (void *)val)) /** * Identical to #RUBY_ATOMIC_LOAD, except it expects its arguments are `void*`. * There are cases where ::rb_atomic_t is 32bit while `void*` is 64bit. This * should be used for size related operations to support such platforms. * * @param var A variable of `void*` * @return The value of `var` (without tearing) */ #define RUBY_ATOMIC_PTR_LOAD(var) \ RBIMPL_CAST(rbimpl_atomic_ptr_load((void **)&var)) /** * Identical to #RUBY_ATOMIC_CAS, except it expects its arguments are `void*`. * There are cases where ::rb_atomic_t is 32bit while `void*` is 64bit. This * should be used for size related operations to support such platforms. * * @param var A variable of `void*`. * @param oldval Expected value of `var` before the assignment. * @param newval What you want to store at `var`. * @retval oldval Successful assignment (`var` is now `newval`). * @retval otherwise Something else is at `var`; not updated. */ #define RUBY_ATOMIC_PTR_CAS(var, oldval, newval) \ RBIMPL_CAST(rbimpl_atomic_ptr_cas((void **)&(var), (oldval), (newval))) /** * Identical to #RUBY_ATOMIC_EXCHANGE, except it expects its arguments are * ::VALUE. There are cases where ::rb_atomic_t is 32bit while ::VALUE is * 64bit. This should be used for pointer related operations to support such * platforms. * * @param var A variable of ::VALUE. * @param val Value to set. * @return What was stored in `var` before the assignment. * @post `var` holds `val`. */ #define RUBY_ATOMIC_VALUE_EXCHANGE(var, val) \ rbimpl_atomic_value_exchange(&(var), (val)) /** * Identical to #RUBY_ATOMIC_CAS, except it expects its arguments are ::VALUE. * There are cases where ::rb_atomic_t is 32bit while ::VALUE is 64bit. This * should be used for size related operations to support such platforms. * * @param var A variable of `void*`. * @param oldval Expected value of `var` before the assignment. * @param newval What you want to store at `var`. * @retval oldval Successful assignment (`var` is now `newval`). * @retval otherwise Something else is at `var`; not updated. */ #define RUBY_ATOMIC_VALUE_CAS(var, oldval, newval) \ rbimpl_atomic_value_cas(&(var), (oldval), (newval)) /** @cond INTERNAL_MACRO */ RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline rb_atomic_t rbimpl_atomic_fetch_add(volatile rb_atomic_t *ptr, rb_atomic_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) return __atomic_fetch_add(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) return __sync_fetch_and_add(ptr, val); #elif defined(_WIN32) return InterlockedExchangeAdd(ptr, val); #elif defined(__sun) && defined(HAVE_ATOMIC_H) /* * `atomic_add_int_nv` takes its second argument as `int`! Meanwhile our * `rb_atomic_t` is unsigned. We cannot pass `val` as-is. We have to * manually check integer overflow. */ RBIMPL_ASSERT_OR_ASSUME(val <= INT_MAX); return atomic_add_int_nv(ptr, val) - val; #else # error Unsupported platform. #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_add(volatile rb_atomic_t *ptr, rb_atomic_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) /* * GCC on amd64 is smart enough to detect this `__atomic_add_fetch`'s * return value is not used, then compiles it into single `LOCK ADD` * instruction. */ __atomic_add_fetch(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) __sync_add_and_fetch(ptr, val); #elif defined(_WIN32) /* * `InterlockedExchangeAdd` is `LOCK XADD`. It seems there also is * `_InterlockedAdd` intrinsic in ARM Windows but not for x86? Sticking to * `InterlockedExchangeAdd` for better portability. */ InterlockedExchangeAdd(ptr, val); #elif defined(__sun) && defined(HAVE_ATOMIC_H) /* Ditto for `atomic_add_int_nv`. */ RBIMPL_ASSERT_OR_ASSUME(val <= INT_MAX); atomic_add_int(ptr, val); #else # error Unsupported platform. #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_size_add(volatile size_t *ptr, size_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) __atomic_add_fetch(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) __sync_add_and_fetch(ptr, val); #elif defined(_WIN32) && defined(_M_AMD64) /* Ditto for `InterlockeExchangedAdd`. */ InterlockedExchangeAdd64(ptr, val); #elif defined(__sun) && defined(HAVE_ATOMIC_H) && (defined(_LP64) || defined(_I32LPx)) /* Ditto for `atomic_add_int_nv`. */ RBIMPL_ASSERT_OR_ASSUME(val <= LONG_MAX); atomic_add_long(ptr, val); #else RBIMPL_STATIC_ASSERT(size_of_rb_atomic_t, sizeof *ptr == sizeof(rb_atomic_t)); volatile rb_atomic_t *const tmp = RBIMPL_CAST((volatile rb_atomic_t *)ptr); rbimpl_atomic_add(tmp, val); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_inc(volatile rb_atomic_t *ptr) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) || defined(HAVE_GCC_SYNC_BUILTINS) rbimpl_atomic_add(ptr, 1); #elif defined(_WIN32) InterlockedIncrement(ptr); #elif defined(__sun) && defined(HAVE_ATOMIC_H) atomic_inc_uint(ptr); #else rbimpl_atomic_add(ptr, 1); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_size_inc(volatile size_t *ptr) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) || defined(HAVE_GCC_SYNC_BUILTINS) rbimpl_atomic_size_add(ptr, 1); #elif defined(_WIN32) && defined(_M_AMD64) InterlockedIncrement64(ptr); #elif defined(__sun) && defined(HAVE_ATOMIC_H) && (defined(_LP64) || defined(_I32LPx)) atomic_inc_ulong(ptr); #else rbimpl_atomic_size_add(ptr, 1); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline rb_atomic_t rbimpl_atomic_fetch_sub(volatile rb_atomic_t *ptr, rb_atomic_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) return __atomic_fetch_sub(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) return __sync_fetch_and_sub(ptr, val); #elif defined(_WIN32) /* rb_atomic_t is signed here! Safe to do `-val`. */ return InterlockedExchangeAdd(ptr, -val); #elif defined(__sun) && defined(HAVE_ATOMIC_H) /* Ditto for `rbimpl_atomic_fetch_add`. */ const signed neg = -1; RBIMPL_ASSERT_OR_ASSUME(val <= INT_MAX); return atomic_add_int_nv(ptr, neg * val) + val; #else # error Unsupported platform. #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_sub(volatile rb_atomic_t *ptr, rb_atomic_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) __atomic_sub_fetch(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) __sync_sub_and_fetch(ptr, val); #elif defined(_WIN32) InterlockedExchangeAdd(ptr, -val); #elif defined(__sun) && defined(HAVE_ATOMIC_H) const signed neg = -1; RBIMPL_ASSERT_OR_ASSUME(val <= INT_MAX); atomic_add_int(ptr, neg * val); #else # error Unsupported platform. #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_size_sub(volatile size_t *ptr, size_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) __atomic_sub_fetch(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) __sync_sub_and_fetch(ptr, val); #elif defined(_WIN32) && defined(_M_AMD64) const ssize_t neg = -1; InterlockedExchangeAdd64(ptr, neg * val); #elif defined(__sun) && defined(HAVE_ATOMIC_H) && (defined(_LP64) || defined(_I32LPx)) const signed neg = -1; RBIMPL_ASSERT_OR_ASSUME(val <= LONG_MAX); atomic_add_long(ptr, neg * val); #else RBIMPL_STATIC_ASSERT(size_of_rb_atomic_t, sizeof *ptr == sizeof(rb_atomic_t)); volatile rb_atomic_t *const tmp = RBIMPL_CAST((volatile rb_atomic_t *)ptr); rbimpl_atomic_sub(tmp, val); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_dec(volatile rb_atomic_t *ptr) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) || defined(HAVE_GCC_SYNC_BUILTINS) rbimpl_atomic_sub(ptr, 1); #elif defined(_WIN32) InterlockedDecrement(ptr); #elif defined(__sun) && defined(HAVE_ATOMIC_H) atomic_dec_uint(ptr); #else rbimpl_atomic_sub(ptr, 1); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_size_dec(volatile size_t *ptr) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) || defined(HAVE_GCC_SYNC_BUILTINS) rbimpl_atomic_size_sub(ptr, 1); #elif defined(_WIN32) && defined(_M_AMD64) InterlockedDecrement64(ptr); #elif defined(__sun) && defined(HAVE_ATOMIC_H) && (defined(_LP64) || defined(_I32LPx)) atomic_dec_ulong(ptr); #else rbimpl_atomic_size_sub(ptr, 1); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_or(volatile rb_atomic_t *ptr, rb_atomic_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) __atomic_or_fetch(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) __sync_or_and_fetch(ptr, val); #elif RBIMPL_COMPILER_SINCE(MSVC, 13, 0, 0) _InterlockedOr(ptr, val); #elif defined(_WIN32) && defined(__GNUC__) /* This was for old MinGW. Maybe not needed any longer? */ __asm__( "lock\n\t" "orl\t%1, %0" : "=m"(ptr) : "Ir"(val)); #elif defined(_WIN32) && defined(_M_IX86) __asm mov eax, ptr; __asm mov ecx, val; __asm lock or [eax], ecx; #elif defined(__sun) && defined(HAVE_ATOMIC_H) atomic_or_uint(ptr, val); #else # error Unsupported platform. #endif } /* Nobody uses this but for theoretical backwards compatibility... */ #if RBIMPL_COMPILER_BEFORE(MSVC, 13, 0, 0) static inline rb_atomic_t rb_w32_atomic_or(volatile rb_atomic_t *var, rb_atomic_t val) { return rbimpl_atomic_or(var, val); } #endif RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline rb_atomic_t rbimpl_atomic_exchange(volatile rb_atomic_t *ptr, rb_atomic_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) return __atomic_exchange_n(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) return __sync_lock_test_and_set(ptr, val); #elif defined(_WIN32) return InterlockedExchange(ptr, val); #elif defined(__sun) && defined(HAVE_ATOMIC_H) return atomic_swap_uint(ptr, val); #else # error Unsupported platform. #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline size_t rbimpl_atomic_size_exchange(volatile size_t *ptr, size_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) return __atomic_exchange_n(ptr, val, __ATOMIC_SEQ_CST); #elif defined(HAVE_GCC_SYNC_BUILTINS) return __sync_lock_test_and_set(ptr, val); #elif defined(_WIN32) && defined(_M_AMD64) return InterlockedExchange64(ptr, val); #elif defined(__sun) && defined(HAVE_ATOMIC_H) && (defined(_LP64) || defined(_I32LPx)) return atomic_swap_ulong(ptr, val); #else RBIMPL_STATIC_ASSERT(size_of_size_t, sizeof *ptr == sizeof(rb_atomic_t)); volatile rb_atomic_t *const tmp = RBIMPL_CAST((volatile rb_atomic_t *)ptr); const rb_atomic_t ret = rbimpl_atomic_exchange(tmp, val); return RBIMPL_CAST((size_t)ret); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void * rbimpl_atomic_ptr_exchange(void *volatile *ptr, const void *val) { #if 0 #elif defined(InterlockedExchangePointer) /* const_cast */ PVOID *pptr = RBIMPL_CAST((PVOID *)ptr); PVOID pval = RBIMPL_CAST((PVOID)val); return InterlockedExchangePointer(pptr, pval); #elif defined(__sun) && defined(HAVE_ATOMIC_H) return atomic_swap_ptr(ptr, RBIMPL_CAST((void *)val)); #else RBIMPL_STATIC_ASSERT(sizeof_voidp, sizeof *ptr == sizeof(size_t)); const size_t sval = RBIMPL_CAST((size_t)val); volatile size_t *const sptr = RBIMPL_CAST((volatile size_t *)ptr); const size_t sret = rbimpl_atomic_size_exchange(sptr, sval); return RBIMPL_CAST((void *)sret); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline VALUE rbimpl_atomic_value_exchange(volatile VALUE *ptr, VALUE val) { RBIMPL_STATIC_ASSERT(sizeof_value, sizeof *ptr == sizeof(size_t)); const size_t sval = RBIMPL_CAST((size_t)val); volatile size_t *const sptr = RBIMPL_CAST((volatile size_t *)ptr); const size_t sret = rbimpl_atomic_size_exchange(sptr, sval); return RBIMPL_CAST((VALUE)sret); } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline rb_atomic_t rbimpl_atomic_load(volatile rb_atomic_t *ptr) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) return __atomic_load_n(ptr, __ATOMIC_SEQ_CST); #else return rbimpl_atomic_fetch_add(ptr, 0); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void rbimpl_atomic_set(volatile rb_atomic_t *ptr, rb_atomic_t val) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) __atomic_store_n(ptr, val, __ATOMIC_SEQ_CST); #else /* Maybe std::atomic<rb_atomic_t>::store can be faster? */ rbimpl_atomic_exchange(ptr, val); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline rb_atomic_t rbimpl_atomic_cas(volatile rb_atomic_t *ptr, rb_atomic_t oldval, rb_atomic_t newval) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) __atomic_compare_exchange_n( ptr, &oldval, newval, 0, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST); return oldval; #elif defined(HAVE_GCC_SYNC_BUILTINS) return __sync_val_compare_and_swap(ptr, oldval, newval); #elif RBIMPL_COMPILER_SINCE(MSVC, 13, 0, 0) return InterlockedCompareExchange(ptr, newval, oldval); #elif defined(_WIN32) PVOID *pptr = RBIMPL_CAST((PVOID *)ptr); PVOID pold = RBIMPL_CAST((PVOID)oldval); PVOID pnew = RBIMPL_CAST((PVOID)newval); PVOID pret = InterlockedCompareExchange(pptr, pnew, pold); return RBIMPL_CAST((rb_atomic_t)pret); #elif defined(__sun) && defined(HAVE_ATOMIC_H) return atomic_cas_uint(ptr, oldval, newval); #else # error Unsupported platform. #endif } /* Nobody uses this but for theoretical backwards compatibility... */ #if RBIMPL_COMPILER_BEFORE(MSVC, 13, 0, 0) static inline rb_atomic_t rb_w32_atomic_cas(volatile rb_atomic_t *var, rb_atomic_t oldval, rb_atomic_t newval) { return rbimpl_atomic_cas(var, oldval, newval); } #endif RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline size_t rbimpl_atomic_size_cas(volatile size_t *ptr, size_t oldval, size_t newval) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) __atomic_compare_exchange_n( ptr, &oldval, newval, 0, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST); return oldval; #elif defined(HAVE_GCC_SYNC_BUILTINS) return __sync_val_compare_and_swap(ptr, oldval, newval); #elif defined(_WIN32) && defined(_M_AMD64) return InterlockedCompareExchange64(ptr, newval, oldval); #elif defined(__sun) && defined(HAVE_ATOMIC_H) && (defined(_LP64) || defined(_I32LPx)) return atomic_cas_ulong(ptr, oldval, newval); #else RBIMPL_STATIC_ASSERT(size_of_size_t, sizeof *ptr == sizeof(rb_atomic_t)); volatile rb_atomic_t *tmp = RBIMPL_CAST((volatile rb_atomic_t *)ptr); return rbimpl_atomic_cas(tmp, oldval, newval); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void * rbimpl_atomic_ptr_cas(void **ptr, const void *oldval, const void *newval) { #if 0 #elif defined(InterlockedExchangePointer) /* ... Can we say that InterlockedCompareExchangePtr surly exists when * InterlockedExchangePointer is defined? Seems so but...?*/ PVOID *pptr = RBIMPL_CAST((PVOID *)ptr); PVOID pold = RBIMPL_CAST((PVOID)oldval); PVOID pnew = RBIMPL_CAST((PVOID)newval); return InterlockedCompareExchangePointer(pptr, pnew, pold); #elif defined(__sun) && defined(HAVE_ATOMIC_H) void *pold = RBIMPL_CAST((void *)oldval); void *pnew = RBIMPL_CAST((void *)newval); return atomic_cas_ptr(ptr, pold, pnew); #else RBIMPL_STATIC_ASSERT(sizeof_voidp, sizeof *ptr == sizeof(size_t)); const size_t snew = RBIMPL_CAST((size_t)newval); const size_t sold = RBIMPL_CAST((size_t)oldval); volatile size_t *const sptr = RBIMPL_CAST((volatile size_t *)ptr); const size_t sret = rbimpl_atomic_size_cas(sptr, sold, snew); return RBIMPL_CAST((void *)sret); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline void * rbimpl_atomic_ptr_load(void **ptr) { #if 0 #elif defined(HAVE_GCC_ATOMIC_BUILTINS) return __atomic_load_n(ptr, __ATOMIC_SEQ_CST); #else void *val = *ptr; return rbimpl_atomic_ptr_cas(ptr, val, val); #endif } RBIMPL_ATTR_ARTIFICIAL() RBIMPL_ATTR_NOALIAS() RBIMPL_ATTR_NONNULL((1)) static inline VALUE rbimpl_atomic_value_cas(volatile VALUE *ptr, VALUE oldval, VALUE newval) { RBIMPL_STATIC_ASSERT(sizeof_value, sizeof *ptr == sizeof(size_t)); const size_t snew = RBIMPL_CAST((size_t)newval); const size_t sold = RBIMPL_CAST((size_t)oldval); volatile size_t *const sptr = RBIMPL_CAST((volatile size_t *)ptr); const size_t sret = rbimpl_atomic_size_cas(sptr, sold, snew); return RBIMPL_CAST((VALUE)sret); } /** @endcond */ #endif /* RUBY_ATOMIC_H */
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