include/qemu/atomic.h - third_party/qemu - Git at Google

 /*
  * Simple interface for atomic operations.
  *
  * Copyright (C) 2013 Red Hat, Inc.
  *
  * Author: Paolo Bonzini <pbonzini@redhat.com>
  *
  * This work is licensed under the terms of the GNU GPL, version 2 or later.
  * See the COPYING file in the top-level directory.
  *
  * See docs/devel/atomics.rst for discussion about the guarantees each
  * atomic primitive is meant to provide.
  */

 #ifndef QEMU_ATOMIC_H
 #define QEMU_ATOMIC_H

 /* Compiler barrier */
 #define barrier()   ({ asm volatile("" ::: "memory"); (void)0; })

 /* The variable that receives the old value of an atomically-accessed
  * variable must be non-qualified, because atomic builtins return values
  * through a pointer-type argument as in __atomic_load(&var, &old, MODEL).
  *
  * This macro has to handle types smaller than int manually, because of
  * implicit promotion.  int and larger types, as well as pointers, can be
  * converted to a non-qualified type just by applying a binary operator.
  */
 #define typeof_strip_qual(expr)                                                    \
   typeof(                                                                          \
     __builtin_choose_expr(                                                         \
       __builtin_types_compatible_p(typeof(expr), bool) ||                          \
         __builtin_types_compatible_p(typeof(expr), const bool) ||                  \
         __builtin_types_compatible_p(typeof(expr), volatile bool) ||               \
         __builtin_types_compatible_p(typeof(expr), const volatile bool),           \
         (bool)1,                                                                   \
     __builtin_choose_expr(                                                         \
       __builtin_types_compatible_p(typeof(expr), signed char) ||                   \
         __builtin_types_compatible_p(typeof(expr), const signed char) ||           \
         __builtin_types_compatible_p(typeof(expr), volatile signed char) ||        \
         __builtin_types_compatible_p(typeof(expr), const volatile signed char),    \
         (signed char)1,                                                            \
     __builtin_choose_expr(                                                         \
       __builtin_types_compatible_p(typeof(expr), unsigned char) ||                 \
         __builtin_types_compatible_p(typeof(expr), const unsigned char) ||         \
         __builtin_types_compatible_p(typeof(expr), volatile unsigned char) ||      \
         __builtin_types_compatible_p(typeof(expr), const volatile unsigned char),  \
         (unsigned char)1,                                                          \
     __builtin_choose_expr(                                                         \
       __builtin_types_compatible_p(typeof(expr), signed short) ||                  \
         __builtin_types_compatible_p(typeof(expr), const signed short) ||          \
         __builtin_types_compatible_p(typeof(expr), volatile signed short) ||       \
         __builtin_types_compatible_p(typeof(expr), const volatile signed short),   \
         (signed short)1,                                                           \
     __builtin_choose_expr(                                                         \
       __builtin_types_compatible_p(typeof(expr), unsigned short) ||                \
         __builtin_types_compatible_p(typeof(expr), const unsigned short) ||        \
         __builtin_types_compatible_p(typeof(expr), volatile unsigned short) ||     \
         __builtin_types_compatible_p(typeof(expr), const volatile unsigned short), \
         (unsigned short)1,                                                         \
       (expr)+0))))))

 #ifndef __ATOMIC_RELAXED
 #error "Expecting C11 atomic ops"
 #endif

 /* Manual memory barriers
  *
  *__atomic_thread_fence does not include a compiler barrier; instead,
  * the barrier is part of __atomic_load/__atomic_store's "volatile-like"
  * semantics. If smp_wmb() is a no-op, absence of the barrier means that
  * the compiler is free to reorder stores on each side of the barrier.
  * Add one here, and similarly in smp_rmb() and smp_read_barrier_depends().
  */

 #define smp_mb()                     ({ barrier(); __atomic_thread_fence(__ATOMIC_SEQ_CST); })
 #define smp_mb_release()             ({ barrier(); __atomic_thread_fence(__ATOMIC_RELEASE); })
 #define smp_mb_acquire()             ({ barrier(); __atomic_thread_fence(__ATOMIC_ACQUIRE); })

 /* Most compilers currently treat consume and acquire the same, but really
  * no processors except Alpha need a barrier here.  Leave it in if
  * using Thread Sanitizer to avoid warnings, otherwise optimize it away.
  */
 #if defined(__SANITIZE_THREAD__)
 #define smp_read_barrier_depends()   ({ barrier(); __atomic_thread_fence(__ATOMIC_CONSUME); })
 #elif defined(__alpha__)
 #define smp_read_barrier_depends()   asm volatile("mb":::"memory")
 #else
 #define smp_read_barrier_depends()   barrier()
 #endif

 /*
  * A signal barrier forces all pending local memory ops to be observed before
  * a SIGSEGV is delivered to the *same* thread.  In practice this is exactly
  * the same as barrier(), but since we have the correct builtin, use it.
  */
 #define signal_barrier()    __atomic_signal_fence(__ATOMIC_SEQ_CST)

 /* Sanity check that the size of an atomic operation isn't "overly large".
  * Despite the fact that e.g. i686 has 64-bit atomic operations, we do not
  * want to use them because we ought not need them, and this lets us do a
  * bit of sanity checking that other 32-bit hosts might build.
  *
  * That said, we have a problem on 64-bit ILP32 hosts in that in order to
  * sync with TCG_OVERSIZED_GUEST, this must match TCG_TARGET_REG_BITS.
  * We'd prefer not want to pull in everything else TCG related, so handle
  * those few cases by hand.
  *
  * Note that x32 is fully detected with __x86_64__ + _ILP32, and that for
  * Sparc we always force the use of sparcv9 in configure. MIPS n32 (ILP32) &
  * n64 (LP64) ABIs are both detected using __mips64.
  */
 #if defined(__x86_64__) || defined(__sparc__) || defined(__mips64)
 # define ATOMIC_REG_SIZE  8
 #else
 # define ATOMIC_REG_SIZE  sizeof(void *)
 #endif

 /* Weak atomic operations prevent the compiler moving other
  * loads/stores past the atomic operation load/store. However there is
  * no explicit memory barrier for the processor.
  *
  * The C11 memory model says that variables that are accessed from
  * different threads should at least be done with __ATOMIC_RELAXED
  * primitives or the result is undefined. Generally this has little to
  * no effect on the generated code but not using the atomic primitives
  * will get flagged by sanitizers as a violation.
  */
 #define qatomic_read__nocheck(ptr) \
     __atomic_load_n(ptr, __ATOMIC_RELAXED)

 #define qatomic_read(ptr)                              \
     ({                                                 \
     QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
     qatomic_read__nocheck(ptr);                        \
     })

 #define qatomic_set__nocheck(ptr, i) \
     __atomic_store_n(ptr, i, __ATOMIC_RELAXED)

 #define qatomic_set(ptr, i)  do {                      \
     QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
     qatomic_set__nocheck(ptr, i);                      \
 } while(0)

 /* See above: most compilers currently treat consume and acquire the
  * same, but this slows down qatomic_rcu_read unnecessarily.
  */
 #ifdef __SANITIZE_THREAD__
 #define qatomic_rcu_read__nocheck(ptr, valptr)           \
     __atomic_load(ptr, valptr, __ATOMIC_CONSUME);
 #else
 #define qatomic_rcu_read__nocheck(ptr, valptr)           \
     __atomic_load(ptr, valptr, __ATOMIC_RELAXED);        \
     smp_read_barrier_depends();
 #endif

 #define qatomic_rcu_read(ptr)                          \
     ({                                                 \
     QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
     typeof_strip_qual(*ptr) _val;                      \
     qatomic_rcu_read__nocheck(ptr, &_val);             \
     _val;                                              \
     })

 #define qatomic_rcu_set(ptr, i) do {                   \
     QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
     __atomic_store_n(ptr, i, __ATOMIC_RELEASE);        \
 } while(0)

 #define qatomic_load_acquire(ptr)                       \
     ({                                                  \
     QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE);  \
     typeof_strip_qual(*ptr) _val;                       \
     __atomic_load(ptr, &_val, __ATOMIC_ACQUIRE);        \
     _val;                                               \
     })

 #define qatomic_store_release(ptr, i)  do {             \
     QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE);  \
     __atomic_store_n(ptr, i, __ATOMIC_RELEASE);         \
 } while(0)


 /* All the remaining operations are fully sequentially consistent */

 #define qatomic_xchg__nocheck(ptr, i)    ({                 \
     __atomic_exchange_n(ptr, (i), __ATOMIC_SEQ_CST);        \
 })

 #define qatomic_xchg(ptr, i)    ({                          \
     QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE);      \
     qatomic_xchg__nocheck(ptr, i);                          \
 })

 /* Returns the eventual value, failed or not */
 #define qatomic_cmpxchg__nocheck(ptr, old, new)    ({                   \
     typeof_strip_qual(*ptr) _old = (old);                               \
     (void)__atomic_compare_exchange_n(ptr, &_old, new, false,           \
                               __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST);      \
     _old;                                                               \
 })

 #define qatomic_cmpxchg(ptr, old, new)    ({                            \
     QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE);                  \
     qatomic_cmpxchg__nocheck(ptr, old, new);                            \
 })

 /* Provide shorter names for GCC atomic builtins, return old value */
 #define qatomic_fetch_inc(ptr)  __atomic_fetch_add(ptr, 1, __ATOMIC_SEQ_CST)
 #define qatomic_fetch_dec(ptr)  __atomic_fetch_sub(ptr, 1, __ATOMIC_SEQ_CST)

 #define qatomic_fetch_add(ptr, n) __atomic_fetch_add(ptr, n, __ATOMIC_SEQ_CST)
 #define qatomic_fetch_sub(ptr, n) __atomic_fetch_sub(ptr, n, __ATOMIC_SEQ_CST)
 #define qatomic_fetch_and(ptr, n) __atomic_fetch_and(ptr, n, __ATOMIC_SEQ_CST)
 #define qatomic_fetch_or(ptr, n)  __atomic_fetch_or(ptr, n, __ATOMIC_SEQ_CST)
 #define qatomic_fetch_xor(ptr, n) __atomic_fetch_xor(ptr, n, __ATOMIC_SEQ_CST)

 #define qatomic_inc_fetch(ptr)    __atomic_add_fetch(ptr, 1, __ATOMIC_SEQ_CST)
 #define qatomic_dec_fetch(ptr)    __atomic_sub_fetch(ptr, 1, __ATOMIC_SEQ_CST)
 #define qatomic_add_fetch(ptr, n) __atomic_add_fetch(ptr, n, __ATOMIC_SEQ_CST)
 #define qatomic_sub_fetch(ptr, n) __atomic_sub_fetch(ptr, n, __ATOMIC_SEQ_CST)
 #define qatomic_and_fetch(ptr, n) __atomic_and_fetch(ptr, n, __ATOMIC_SEQ_CST)
 #define qatomic_or_fetch(ptr, n)  __atomic_or_fetch(ptr, n, __ATOMIC_SEQ_CST)
 #define qatomic_xor_fetch(ptr, n) __atomic_xor_fetch(ptr, n, __ATOMIC_SEQ_CST)

 /* And even shorter names that return void.  */
 #define qatomic_inc(ptr) \
     ((void) __atomic_fetch_add(ptr, 1, __ATOMIC_SEQ_CST))
 #define qatomic_dec(ptr) \
     ((void) __atomic_fetch_sub(ptr, 1, __ATOMIC_SEQ_CST))
 #define qatomic_add(ptr, n) \
     ((void) __atomic_fetch_add(ptr, n, __ATOMIC_SEQ_CST))
 #define qatomic_sub(ptr, n) \
     ((void) __atomic_fetch_sub(ptr, n, __ATOMIC_SEQ_CST))
 #define qatomic_and(ptr, n) \
     ((void) __atomic_fetch_and(ptr, n, __ATOMIC_SEQ_CST))
 #define qatomic_or(ptr, n) \
     ((void) __atomic_fetch_or(ptr, n, __ATOMIC_SEQ_CST))
 #define qatomic_xor(ptr, n) \
     ((void) __atomic_fetch_xor(ptr, n, __ATOMIC_SEQ_CST))

 #define smp_wmb()   smp_mb_release()
 #define smp_rmb()   smp_mb_acquire()

 /* qatomic_mb_read/set semantics map Java volatile variables. They are
  * less expensive on some platforms (notably POWER) than fully
  * sequentially consistent operations.
  *
  * As long as they are used as paired operations they are safe to
  * use. See docs/devel/atomics.rst for more discussion.
  */

 #define qatomic_mb_read(ptr)                             \
     qatomic_load_acquire(ptr)

 #if !defined(__SANITIZE_THREAD__) && \
     (defined(__i386__) || defined(__x86_64__) || defined(__s390x__))
 /* This is more efficient than a store plus a fence.  */
 # define qatomic_mb_set(ptr, i)  ((void)qatomic_xchg(ptr, i))
 #else
 # define qatomic_mb_set(ptr, i) \
    ({ qatomic_store_release(ptr, i); smp_mb(); })
 #endif

 #define qatomic_fetch_inc_nonzero(ptr) ({                               \
     typeof_strip_qual(*ptr) _oldn = qatomic_read(ptr);                  \
     while (_oldn && qatomic_cmpxchg(ptr, _oldn, _oldn + 1) != _oldn) {  \
         _oldn = qatomic_read(ptr);                                      \
     }                                                                   \
     _oldn;                                                              \
 })

 /*
  * Abstractions to access atomically (i.e. "once") i64/u64 variables.
  *
  * The i386 abi is odd in that by default members are only aligned to
  * 4 bytes, which means that 8-byte types can wind up mis-aligned.
  * Clang will then warn about this, and emit a call into libatomic.
  *
  * Use of these types in structures when they will be used with atomic
  * operations can avoid this.
  */
 typedef int64_t aligned_int64_t __attribute__((aligned(8)));
 typedef uint64_t aligned_uint64_t __attribute__((aligned(8)));

 #ifdef CONFIG_ATOMIC64
 /* Use __nocheck because sizeof(void *) might be < sizeof(u64) */
 #define qatomic_read_i64(P) \
     _Generic(*(P), int64_t: qatomic_read__nocheck(P))
 #define qatomic_read_u64(P) \
     _Generic(*(P), uint64_t: qatomic_read__nocheck(P))
 #define qatomic_set_i64(P, V) \
     _Generic(*(P), int64_t: qatomic_set__nocheck(P, V))
 #define qatomic_set_u64(P, V) \
     _Generic(*(P), uint64_t: qatomic_set__nocheck(P, V))

 static inline void qatomic64_init(void)
 {
 }
 #else /* !CONFIG_ATOMIC64 */
 int64_t  qatomic_read_i64(const int64_t *ptr);
 uint64_t qatomic_read_u64(const uint64_t *ptr);
 void qatomic_set_i64(int64_t *ptr, int64_t val);
 void qatomic_set_u64(uint64_t *ptr, uint64_t val);
 void qatomic64_init(void);
 #endif /* !CONFIG_ATOMIC64 */

 #endif /* QEMU_ATOMIC_H */
	/*
	* Simple interface for atomic operations.
	*
	* Copyright (C) 2013 Red Hat, Inc.
	*
	* Author: Paolo Bonzini <pbonzini@redhat.com>
	*
	* This work is licensed under the terms of the GNU GPL, version 2 or later.
	* See the COPYING file in the top-level directory.
	*
	* See docs/devel/atomics.rst for discussion about the guarantees each
	* atomic primitive is meant to provide.
	*/

	#ifndef QEMU_ATOMIC_H
	#define QEMU_ATOMIC_H

	/* Compiler barrier */
	#define barrier() ({ asm volatile("" ::: "memory"); (void)0; })

	/* The variable that receives the old value of an atomically-accessed
	* variable must be non-qualified, because atomic builtins return values
	* through a pointer-type argument as in __atomic_load(&var, &old, MODEL).
	*
	* This macro has to handle types smaller than int manually, because of
	* implicit promotion. int and larger types, as well as pointers, can be
	* converted to a non-qualified type just by applying a binary operator.
	*/
	#define typeof_strip_qual(expr) \
	typeof( \
	__builtin_choose_expr( \
	__builtin_types_compatible_p(typeof(expr), bool) \|\| \
	__builtin_types_compatible_p(typeof(expr), const bool) \|\| \
	__builtin_types_compatible_p(typeof(expr), volatile bool) \|\| \
	__builtin_types_compatible_p(typeof(expr), const volatile bool), \
	(bool)1, \
	__builtin_choose_expr( \
	__builtin_types_compatible_p(typeof(expr), signed char) \|\| \
	__builtin_types_compatible_p(typeof(expr), const signed char) \|\| \
	__builtin_types_compatible_p(typeof(expr), volatile signed char) \|\| \
	__builtin_types_compatible_p(typeof(expr), const volatile signed char), \
	(signed char)1, \
	__builtin_choose_expr( \
	__builtin_types_compatible_p(typeof(expr), unsigned char) \|\| \
	__builtin_types_compatible_p(typeof(expr), const unsigned char) \|\| \
	__builtin_types_compatible_p(typeof(expr), volatile unsigned char) \|\| \
	__builtin_types_compatible_p(typeof(expr), const volatile unsigned char), \
	(unsigned char)1, \
	__builtin_choose_expr( \
	__builtin_types_compatible_p(typeof(expr), signed short) \|\| \
	__builtin_types_compatible_p(typeof(expr), const signed short) \|\| \
	__builtin_types_compatible_p(typeof(expr), volatile signed short) \|\| \
	__builtin_types_compatible_p(typeof(expr), const volatile signed short), \
	(signed short)1, \
	__builtin_choose_expr( \
	__builtin_types_compatible_p(typeof(expr), unsigned short) \|\| \
	__builtin_types_compatible_p(typeof(expr), const unsigned short) \|\| \
	__builtin_types_compatible_p(typeof(expr), volatile unsigned short) \|\| \
	__builtin_types_compatible_p(typeof(expr), const volatile unsigned short), \
	(unsigned short)1, \
	(expr)+0))))))

	#ifndef __ATOMIC_RELAXED
	#error "Expecting C11 atomic ops"
	#endif

	/* Manual memory barriers
	*
	*__atomic_thread_fence does not include a compiler barrier; instead,
	* the barrier is part of __atomic_load/__atomic_store's "volatile-like"
	* semantics. If smp_wmb() is a no-op, absence of the barrier means that
	* the compiler is free to reorder stores on each side of the barrier.
	* Add one here, and similarly in smp_rmb() and smp_read_barrier_depends().
	*/

	#define smp_mb() ({ barrier(); __atomic_thread_fence(__ATOMIC_SEQ_CST); })
	#define smp_mb_release() ({ barrier(); __atomic_thread_fence(__ATOMIC_RELEASE); })
	#define smp_mb_acquire() ({ barrier(); __atomic_thread_fence(__ATOMIC_ACQUIRE); })

	/* Most compilers currently treat consume and acquire the same, but really
	* no processors except Alpha need a barrier here. Leave it in if
	* using Thread Sanitizer to avoid warnings, otherwise optimize it away.
	*/
	#if defined(__SANITIZE_THREAD__)
	#define smp_read_barrier_depends() ({ barrier(); __atomic_thread_fence(__ATOMIC_CONSUME); })
	#elif defined(__alpha__)
	#define smp_read_barrier_depends() asm volatile("mb":::"memory")
	#else
	#define smp_read_barrier_depends() barrier()
	#endif

	/*
	* A signal barrier forces all pending local memory ops to be observed before
	* a SIGSEGV is delivered to the same thread. In practice this is exactly
	* the same as barrier(), but since we have the correct builtin, use it.
	*/
	#define signal_barrier() __atomic_signal_fence(__ATOMIC_SEQ_CST)

	/* Sanity check that the size of an atomic operation isn't "overly large".
	* Despite the fact that e.g. i686 has 64-bit atomic operations, we do not
	* want to use them because we ought not need them, and this lets us do a
	* bit of sanity checking that other 32-bit hosts might build.
	*
	* That said, we have a problem on 64-bit ILP32 hosts in that in order to
	* sync with TCG_OVERSIZED_GUEST, this must match TCG_TARGET_REG_BITS.
	* We'd prefer not want to pull in everything else TCG related, so handle
	* those few cases by hand.
	*
	* Note that x32 is fully detected with __x86_64__ + _ILP32, and that for
	* Sparc we always force the use of sparcv9 in configure. MIPS n32 (ILP32) &
	* n64 (LP64) ABIs are both detected using __mips64.
	*/
	#if defined(__x86_64__) \|\| defined(__sparc__) \|\| defined(__mips64)
	# define ATOMIC_REG_SIZE 8
	#else
	# define ATOMIC_REG_SIZE sizeof(void *)
	#endif

	/* Weak atomic operations prevent the compiler moving other
	* loads/stores past the atomic operation load/store. However there is
	* no explicit memory barrier for the processor.
	*
	* The C11 memory model says that variables that are accessed from
	* different threads should at least be done with __ATOMIC_RELAXED
	* primitives or the result is undefined. Generally this has little to
	* no effect on the generated code but not using the atomic primitives
	* will get flagged by sanitizers as a violation.
	*/
	#define qatomic_read__nocheck(ptr) \
	__atomic_load_n(ptr, __ATOMIC_RELAXED)

	#define qatomic_read(ptr) \
	({ \
	QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
	qatomic_read__nocheck(ptr); \
	})

	#define qatomic_set__nocheck(ptr, i) \
	__atomic_store_n(ptr, i, __ATOMIC_RELAXED)

	#define qatomic_set(ptr, i) do { \
	QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
	qatomic_set__nocheck(ptr, i); \
	} while(0)

	/* See above: most compilers currently treat consume and acquire the
	* same, but this slows down qatomic_rcu_read unnecessarily.
	*/
	#ifdef __SANITIZE_THREAD__
	#define qatomic_rcu_read__nocheck(ptr, valptr) \
	__atomic_load(ptr, valptr, __ATOMIC_CONSUME);
	#else
	#define qatomic_rcu_read__nocheck(ptr, valptr) \
	__atomic_load(ptr, valptr, __ATOMIC_RELAXED); \
	smp_read_barrier_depends();
	#endif

	#define qatomic_rcu_read(ptr) \
	({ \
	QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
	typeof_strip_qual(*ptr) _val; \
	qatomic_rcu_read__nocheck(ptr, &_val); \
	_val; \
	})

	#define qatomic_rcu_set(ptr, i) do { \
	QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
	__atomic_store_n(ptr, i, __ATOMIC_RELEASE); \
	} while(0)

	#define qatomic_load_acquire(ptr) \
	({ \
	QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
	typeof_strip_qual(*ptr) _val; \
	__atomic_load(ptr, &_val, __ATOMIC_ACQUIRE); \
	_val; \
	})

	#define qatomic_store_release(ptr, i) do { \
	QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
	__atomic_store_n(ptr, i, __ATOMIC_RELEASE); \
	} while(0)


	/* All the remaining operations are fully sequentially consistent */

	#define qatomic_xchg__nocheck(ptr, i) ({ \
	__atomic_exchange_n(ptr, (i), __ATOMIC_SEQ_CST); \
	})

	#define qatomic_xchg(ptr, i) ({ \
	QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
	qatomic_xchg__nocheck(ptr, i); \
	})

	/* Returns the eventual value, failed or not */
	#define qatomic_cmpxchg__nocheck(ptr, old, new) ({ \
	typeof_strip_qual(*ptr) _old = (old); \
	(void)__atomic_compare_exchange_n(ptr, &_old, new, false, \
	__ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST); \
	_old; \
	})

	#define qatomic_cmpxchg(ptr, old, new) ({ \
	QEMU_BUILD_BUG_ON(sizeof(*ptr) > ATOMIC_REG_SIZE); \
	qatomic_cmpxchg__nocheck(ptr, old, new); \
	})

	/* Provide shorter names for GCC atomic builtins, return old value */
	#define qatomic_fetch_inc(ptr) __atomic_fetch_add(ptr, 1, __ATOMIC_SEQ_CST)
	#define qatomic_fetch_dec(ptr) __atomic_fetch_sub(ptr, 1, __ATOMIC_SEQ_CST)

	#define qatomic_fetch_add(ptr, n) __atomic_fetch_add(ptr, n, __ATOMIC_SEQ_CST)
	#define qatomic_fetch_sub(ptr, n) __atomic_fetch_sub(ptr, n, __ATOMIC_SEQ_CST)
	#define qatomic_fetch_and(ptr, n) __atomic_fetch_and(ptr, n, __ATOMIC_SEQ_CST)
	#define qatomic_fetch_or(ptr, n) __atomic_fetch_or(ptr, n, __ATOMIC_SEQ_CST)
	#define qatomic_fetch_xor(ptr, n) __atomic_fetch_xor(ptr, n, __ATOMIC_SEQ_CST)

	#define qatomic_inc_fetch(ptr) __atomic_add_fetch(ptr, 1, __ATOMIC_SEQ_CST)
	#define qatomic_dec_fetch(ptr) __atomic_sub_fetch(ptr, 1, __ATOMIC_SEQ_CST)
	#define qatomic_add_fetch(ptr, n) __atomic_add_fetch(ptr, n, __ATOMIC_SEQ_CST)
	#define qatomic_sub_fetch(ptr, n) __atomic_sub_fetch(ptr, n, __ATOMIC_SEQ_CST)
	#define qatomic_and_fetch(ptr, n) __atomic_and_fetch(ptr, n, __ATOMIC_SEQ_CST)
	#define qatomic_or_fetch(ptr, n) __atomic_or_fetch(ptr, n, __ATOMIC_SEQ_CST)
	#define qatomic_xor_fetch(ptr, n) __atomic_xor_fetch(ptr, n, __ATOMIC_SEQ_CST)

	/* And even shorter names that return void. */
	#define qatomic_inc(ptr) \
	((void) __atomic_fetch_add(ptr, 1, __ATOMIC_SEQ_CST))
	#define qatomic_dec(ptr) \
	((void) __atomic_fetch_sub(ptr, 1, __ATOMIC_SEQ_CST))
	#define qatomic_add(ptr, n) \
	((void) __atomic_fetch_add(ptr, n, __ATOMIC_SEQ_CST))
	#define qatomic_sub(ptr, n) \
	((void) __atomic_fetch_sub(ptr, n, __ATOMIC_SEQ_CST))
	#define qatomic_and(ptr, n) \
	((void) __atomic_fetch_and(ptr, n, __ATOMIC_SEQ_CST))
	#define qatomic_or(ptr, n) \
	((void) __atomic_fetch_or(ptr, n, __ATOMIC_SEQ_CST))
	#define qatomic_xor(ptr, n) \
	((void) __atomic_fetch_xor(ptr, n, __ATOMIC_SEQ_CST))

	#define smp_wmb() smp_mb_release()
	#define smp_rmb() smp_mb_acquire()

	/* qatomic_mb_read/set semantics map Java volatile variables. They are
	* less expensive on some platforms (notably POWER) than fully
	* sequentially consistent operations.
	*
	* As long as they are used as paired operations they are safe to
	* use. See docs/devel/atomics.rst for more discussion.
	*/

	#define qatomic_mb_read(ptr) \
	qatomic_load_acquire(ptr)

	#if !defined(__SANITIZE_THREAD__) && \
	(defined(__i386__) \|\| defined(__x86_64__) \|\| defined(__s390x__))
	/* This is more efficient than a store plus a fence. */
	# define qatomic_mb_set(ptr, i) ((void)qatomic_xchg(ptr, i))
	#else
	# define qatomic_mb_set(ptr, i) \
	({ qatomic_store_release(ptr, i); smp_mb(); })
	#endif

	#define qatomic_fetch_inc_nonzero(ptr) ({ \
	typeof_strip_qual(*ptr) _oldn = qatomic_read(ptr); \
	while (_oldn && qatomic_cmpxchg(ptr, _oldn, _oldn + 1) != _oldn) { \
	_oldn = qatomic_read(ptr); \
	} \
	_oldn; \
	})

	/*
	* Abstractions to access atomically (i.e. "once") i64/u64 variables.
	*
	* The i386 abi is odd in that by default members are only aligned to
	* 4 bytes, which means that 8-byte types can wind up mis-aligned.
	* Clang will then warn about this, and emit a call into libatomic.
	*
	* Use of these types in structures when they will be used with atomic
	* operations can avoid this.
	*/
	typedef int64_t aligned_int64_t __attribute__((aligned(8)));
	typedef uint64_t aligned_uint64_t __attribute__((aligned(8)));

	#ifdef CONFIG_ATOMIC64
	/* Use __nocheck because sizeof(void ) might be < sizeof(u64) /
	#define qatomic_read_i64(P) \
	_Generic(*(P), int64_t: qatomic_read__nocheck(P))
	#define qatomic_read_u64(P) \
	_Generic(*(P), uint64_t: qatomic_read__nocheck(P))
	#define qatomic_set_i64(P, V) \
	_Generic(*(P), int64_t: qatomic_set__nocheck(P, V))
	#define qatomic_set_u64(P, V) \
	_Generic(*(P), uint64_t: qatomic_set__nocheck(P, V))

	static inline void qatomic64_init(void)
	{
	}
	#else /* !CONFIG_ATOMIC64 */
	int64_t qatomic_read_i64(const int64_t *ptr);
	uint64_t qatomic_read_u64(const uint64_t *ptr);
	void qatomic_set_i64(int64_t *ptr, int64_t val);
	void qatomic_set_u64(uint64_t *ptr, uint64_t val);
	void qatomic64_init(void);
	#endif /* !CONFIG_ATOMIC64 */

	#endif /* QEMU_ATOMIC_H */