freebsd-nq/sys/i386/include/atomic.h
Andriy Gapon db8bee42ce i386: hide more of atomic 64-bit definitions under _KERNEL
At the moment i386 does not provide 64-bit atomic operations in
userland.  Exposing some atomic_*_64 defines can cause unnecessary
confusion.

Discussed with:	kib
MFC after:	2 weeks
2019-10-08 10:50:16 +00:00

962 lines
27 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 1998 Doug Rabson
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $FreeBSD$
*/
#ifndef _MACHINE_ATOMIC_H_
#define _MACHINE_ATOMIC_H_
#ifndef _SYS_CDEFS_H_
#error this file needs sys/cdefs.h as a prerequisite
#endif
#include <sys/atomic_common.h>
#ifdef _KERNEL
#include <machine/md_var.h>
#include <machine/specialreg.h>
#endif
#ifndef __OFFSETOF_MONITORBUF
/*
* __OFFSETOF_MONITORBUF == __pcpu_offset(pc_monitorbuf).
*
* The open-coded number is used instead of the symbolic expression to
* avoid a dependency on sys/pcpu.h in machine/atomic.h consumers.
* An assertion in i386/vm_machdep.c ensures that the value is correct.
*/
#define __OFFSETOF_MONITORBUF 0x80
static __inline void
__mbk(void)
{
__asm __volatile("lock; addl $0,%%fs:%0"
: "+m" (*(u_int *)__OFFSETOF_MONITORBUF) : : "memory", "cc");
}
static __inline void
__mbu(void)
{
__asm __volatile("lock; addl $0,(%%esp)" : : : "memory", "cc");
}
#endif
/*
* Various simple operations on memory, each of which is atomic in the
* presence of interrupts and multiple processors.
*
* atomic_set_char(P, V) (*(u_char *)(P) |= (V))
* atomic_clear_char(P, V) (*(u_char *)(P) &= ~(V))
* atomic_add_char(P, V) (*(u_char *)(P) += (V))
* atomic_subtract_char(P, V) (*(u_char *)(P) -= (V))
*
* atomic_set_short(P, V) (*(u_short *)(P) |= (V))
* atomic_clear_short(P, V) (*(u_short *)(P) &= ~(V))
* atomic_add_short(P, V) (*(u_short *)(P) += (V))
* atomic_subtract_short(P, V) (*(u_short *)(P) -= (V))
*
* atomic_set_int(P, V) (*(u_int *)(P) |= (V))
* atomic_clear_int(P, V) (*(u_int *)(P) &= ~(V))
* atomic_add_int(P, V) (*(u_int *)(P) += (V))
* atomic_subtract_int(P, V) (*(u_int *)(P) -= (V))
* atomic_swap_int(P, V) (return (*(u_int *)(P)); *(u_int *)(P) = (V);)
* atomic_readandclear_int(P) (return (*(u_int *)(P)); *(u_int *)(P) = 0;)
*
* atomic_set_long(P, V) (*(u_long *)(P) |= (V))
* atomic_clear_long(P, V) (*(u_long *)(P) &= ~(V))
* atomic_add_long(P, V) (*(u_long *)(P) += (V))
* atomic_subtract_long(P, V) (*(u_long *)(P) -= (V))
* atomic_swap_long(P, V) (return (*(u_long *)(P)); *(u_long *)(P) = (V);)
* atomic_readandclear_long(P) (return (*(u_long *)(P)); *(u_long *)(P) = 0;)
*/
/*
* The above functions are expanded inline in the statically-linked
* kernel. Lock prefixes are generated if an SMP kernel is being
* built.
*
* Kernel modules call real functions which are built into the kernel.
* This allows kernel modules to be portable between UP and SMP systems.
*/
#if !defined(__GNUCLIKE_ASM)
#define ATOMIC_ASM(NAME, TYPE, OP, CONS, V) \
void atomic_##NAME##_##TYPE(volatile u_##TYPE *p, u_##TYPE v); \
void atomic_##NAME##_barr_##TYPE(volatile u_##TYPE *p, u_##TYPE v)
int atomic_cmpset_char(volatile u_char *dst, u_char expect, u_char src);
int atomic_cmpset_short(volatile u_short *dst, u_short expect, u_short src);
int atomic_cmpset_int(volatile u_int *dst, u_int expect, u_int src);
int atomic_fcmpset_char(volatile u_char *dst, u_char *expect, u_char src);
int atomic_fcmpset_short(volatile u_short *dst, u_short *expect,
u_short src);
int atomic_fcmpset_int(volatile u_int *dst, u_int *expect, u_int src);
u_int atomic_fetchadd_int(volatile u_int *p, u_int v);
int atomic_testandset_int(volatile u_int *p, u_int v);
int atomic_testandclear_int(volatile u_int *p, u_int v);
void atomic_thread_fence_acq(void);
void atomic_thread_fence_acq_rel(void);
void atomic_thread_fence_rel(void);
void atomic_thread_fence_seq_cst(void);
#define ATOMIC_LOAD(TYPE) \
u_##TYPE atomic_load_acq_##TYPE(volatile u_##TYPE *p)
#define ATOMIC_STORE(TYPE) \
void atomic_store_rel_##TYPE(volatile u_##TYPE *p, u_##TYPE v)
int atomic_cmpset_64(volatile uint64_t *, uint64_t, uint64_t);
int atomic_fcmpset_64(volatile uint64_t *, uint64_t *, uint64_t);
uint64_t atomic_load_acq_64(volatile uint64_t *);
void atomic_store_rel_64(volatile uint64_t *, uint64_t);
uint64_t atomic_swap_64(volatile uint64_t *, uint64_t);
uint64_t atomic_fetchadd_64(volatile uint64_t *, uint64_t);
void atomic_add_64(volatile uint64_t *, uint64_t);
void atomic_subtract_64(volatile uint64_t *, uint64_t);
#else /* !KLD_MODULE && __GNUCLIKE_ASM */
/*
* For userland, always use lock prefixes so that the binaries will run
* on both SMP and !SMP systems.
*/
#if defined(SMP) || !defined(_KERNEL) || defined(KLD_MODULE)
#define MPLOCKED "lock ; "
#else
#define MPLOCKED
#endif
/*
* The assembly is volatilized to avoid code chunk removal by the compiler.
* GCC aggressively reorders operations and memory clobbering is necessary
* in order to avoid that for memory barriers.
*/
#define ATOMIC_ASM(NAME, TYPE, OP, CONS, V) \
static __inline void \
atomic_##NAME##_##TYPE(volatile u_##TYPE *p, u_##TYPE v)\
{ \
__asm __volatile(MPLOCKED OP \
: "+m" (*p) \
: CONS (V) \
: "cc"); \
} \
\
static __inline void \
atomic_##NAME##_barr_##TYPE(volatile u_##TYPE *p, u_##TYPE v)\
{ \
__asm __volatile(MPLOCKED OP \
: "+m" (*p) \
: CONS (V) \
: "memory", "cc"); \
} \
struct __hack
/*
* Atomic compare and set, used by the mutex functions.
*
* cmpset:
* if (*dst == expect)
* *dst = src
*
* fcmpset:
* if (*dst == *expect)
* *dst = src
* else
* *expect = *dst
*
* Returns 0 on failure, non-zero on success.
*/
#define ATOMIC_CMPSET(TYPE, CONS) \
static __inline int \
atomic_cmpset_##TYPE(volatile u_##TYPE *dst, u_##TYPE expect, u_##TYPE src) \
{ \
u_char res; \
\
__asm __volatile( \
" " MPLOCKED " " \
" cmpxchg %3,%1 ; " \
" sete %0 ; " \
"# atomic_cmpset_" #TYPE " " \
: "=q" (res), /* 0 */ \
"+m" (*dst), /* 1 */ \
"+a" (expect) /* 2 */ \
: CONS (src) /* 3 */ \
: "memory", "cc"); \
return (res); \
} \
\
static __inline int \
atomic_fcmpset_##TYPE(volatile u_##TYPE *dst, u_##TYPE *expect, u_##TYPE src) \
{ \
u_char res; \
\
__asm __volatile( \
" " MPLOCKED " " \
" cmpxchg %3,%1 ; " \
" sete %0 ; " \
"# atomic_fcmpset_" #TYPE " " \
: "=q" (res), /* 0 */ \
"+m" (*dst), /* 1 */ \
"+a" (*expect) /* 2 */ \
: CONS (src) /* 3 */ \
: "memory", "cc"); \
return (res); \
}
ATOMIC_CMPSET(char, "q");
ATOMIC_CMPSET(short, "r");
ATOMIC_CMPSET(int, "r");
/*
* Atomically add the value of v to the integer pointed to by p and return
* the previous value of *p.
*/
static __inline u_int
atomic_fetchadd_int(volatile u_int *p, u_int v)
{
__asm __volatile(
" " MPLOCKED " "
" xaddl %0,%1 ; "
"# atomic_fetchadd_int"
: "+r" (v), /* 0 */
"+m" (*p) /* 1 */
: : "cc");
return (v);
}
static __inline int
atomic_testandset_int(volatile u_int *p, u_int v)
{
u_char res;
__asm __volatile(
" " MPLOCKED " "
" btsl %2,%1 ; "
" setc %0 ; "
"# atomic_testandset_int"
: "=q" (res), /* 0 */
"+m" (*p) /* 1 */
: "Ir" (v & 0x1f) /* 2 */
: "cc");
return (res);
}
static __inline int
atomic_testandclear_int(volatile u_int *p, u_int v)
{
u_char res;
__asm __volatile(
" " MPLOCKED " "
" btrl %2,%1 ; "
" setc %0 ; "
"# atomic_testandclear_int"
: "=q" (res), /* 0 */
"+m" (*p) /* 1 */
: "Ir" (v & 0x1f) /* 2 */
: "cc");
return (res);
}
/*
* We assume that a = b will do atomic loads and stores. Due to the
* IA32 memory model, a simple store guarantees release semantics.
*
* However, a load may pass a store if they are performed on distinct
* addresses, so we need Store/Load barrier for sequentially
* consistent fences in SMP kernels. We use "lock addl $0,mem" for a
* Store/Load barrier, as recommended by the AMD Software Optimization
* Guide, and not mfence. In the kernel, we use a private per-cpu
* cache line for "mem", to avoid introducing false data
* dependencies. In user space, we use the word at the top of the
* stack.
*
* For UP kernels, however, the memory of the single processor is
* always consistent, so we only need to stop the compiler from
* reordering accesses in a way that violates the semantics of acquire
* and release.
*/
#if defined(_KERNEL)
#if defined(SMP) || defined(KLD_MODULE)
#define __storeload_barrier() __mbk()
#else /* _KERNEL && UP */
#define __storeload_barrier() __compiler_membar()
#endif /* SMP */
#else /* !_KERNEL */
#define __storeload_barrier() __mbu()
#endif /* _KERNEL*/
#define ATOMIC_LOAD(TYPE) \
static __inline u_##TYPE \
atomic_load_acq_##TYPE(volatile u_##TYPE *p) \
{ \
u_##TYPE res; \
\
res = *p; \
__compiler_membar(); \
return (res); \
} \
struct __hack
#define ATOMIC_STORE(TYPE) \
static __inline void \
atomic_store_rel_##TYPE(volatile u_##TYPE *p, u_##TYPE v) \
{ \
\
__compiler_membar(); \
*p = v; \
} \
struct __hack
static __inline void
atomic_thread_fence_acq(void)
{
__compiler_membar();
}
static __inline void
atomic_thread_fence_rel(void)
{
__compiler_membar();
}
static __inline void
atomic_thread_fence_acq_rel(void)
{
__compiler_membar();
}
static __inline void
atomic_thread_fence_seq_cst(void)
{
__storeload_barrier();
}
#ifdef _KERNEL
#ifdef WANT_FUNCTIONS
int atomic_cmpset_64_i386(volatile uint64_t *, uint64_t, uint64_t);
int atomic_cmpset_64_i586(volatile uint64_t *, uint64_t, uint64_t);
uint64_t atomic_load_acq_64_i386(volatile uint64_t *);
uint64_t atomic_load_acq_64_i586(volatile uint64_t *);
void atomic_store_rel_64_i386(volatile uint64_t *, uint64_t);
void atomic_store_rel_64_i586(volatile uint64_t *, uint64_t);
uint64_t atomic_swap_64_i386(volatile uint64_t *, uint64_t);
uint64_t atomic_swap_64_i586(volatile uint64_t *, uint64_t);
#endif
/* I486 does not support SMP or CMPXCHG8B. */
static __inline int
atomic_cmpset_64_i386(volatile uint64_t *dst, uint64_t expect, uint64_t src)
{
volatile uint32_t *p;
u_char res;
p = (volatile uint32_t *)dst;
__asm __volatile(
" pushfl ; "
" cli ; "
" xorl %1,%%eax ; "
" xorl %2,%%edx ; "
" orl %%edx,%%eax ; "
" jne 1f ; "
" movl %4,%1 ; "
" movl %5,%2 ; "
"1: "
" sete %3 ; "
" popfl"
: "+A" (expect), /* 0 */
"+m" (*p), /* 1 */
"+m" (*(p + 1)), /* 2 */
"=q" (res) /* 3 */
: "r" ((uint32_t)src), /* 4 */
"r" ((uint32_t)(src >> 32)) /* 5 */
: "memory", "cc");
return (res);
}
static __inline int
atomic_fcmpset_64_i386(volatile uint64_t *dst, uint64_t *expect, uint64_t src)
{
if (atomic_cmpset_64_i386(dst, *expect, src)) {
return (1);
} else {
*expect = *dst;
return (0);
}
}
static __inline uint64_t
atomic_load_acq_64_i386(volatile uint64_t *p)
{
volatile uint32_t *q;
uint64_t res;
q = (volatile uint32_t *)p;
__asm __volatile(
" pushfl ; "
" cli ; "
" movl %1,%%eax ; "
" movl %2,%%edx ; "
" popfl"
: "=&A" (res) /* 0 */
: "m" (*q), /* 1 */
"m" (*(q + 1)) /* 2 */
: "memory");
return (res);
}
static __inline void
atomic_store_rel_64_i386(volatile uint64_t *p, uint64_t v)
{
volatile uint32_t *q;
q = (volatile uint32_t *)p;
__asm __volatile(
" pushfl ; "
" cli ; "
" movl %%eax,%0 ; "
" movl %%edx,%1 ; "
" popfl"
: "=m" (*q), /* 0 */
"=m" (*(q + 1)) /* 1 */
: "A" (v) /* 2 */
: "memory");
}
static __inline uint64_t
atomic_swap_64_i386(volatile uint64_t *p, uint64_t v)
{
volatile uint32_t *q;
uint64_t res;
q = (volatile uint32_t *)p;
__asm __volatile(
" pushfl ; "
" cli ; "
" movl %1,%%eax ; "
" movl %2,%%edx ; "
" movl %4,%2 ; "
" movl %3,%1 ; "
" popfl"
: "=&A" (res), /* 0 */
"+m" (*q), /* 1 */
"+m" (*(q + 1)) /* 2 */
: "r" ((uint32_t)v), /* 3 */
"r" ((uint32_t)(v >> 32))); /* 4 */
return (res);
}
static __inline int
atomic_cmpset_64_i586(volatile uint64_t *dst, uint64_t expect, uint64_t src)
{
u_char res;
__asm __volatile(
" " MPLOCKED " "
" cmpxchg8b %1 ; "
" sete %0"
: "=q" (res), /* 0 */
"+m" (*dst), /* 1 */
"+A" (expect) /* 2 */
: "b" ((uint32_t)src), /* 3 */
"c" ((uint32_t)(src >> 32)) /* 4 */
: "memory", "cc");
return (res);
}
static __inline int
atomic_fcmpset_64_i586(volatile uint64_t *dst, uint64_t *expect, uint64_t src)
{
u_char res;
__asm __volatile(
" " MPLOCKED " "
" cmpxchg8b %1 ; "
" sete %0"
: "=q" (res), /* 0 */
"+m" (*dst), /* 1 */
"+A" (*expect) /* 2 */
: "b" ((uint32_t)src), /* 3 */
"c" ((uint32_t)(src >> 32)) /* 4 */
: "memory", "cc");
return (res);
}
static __inline uint64_t
atomic_load_acq_64_i586(volatile uint64_t *p)
{
uint64_t res;
__asm __volatile(
" movl %%ebx,%%eax ; "
" movl %%ecx,%%edx ; "
" " MPLOCKED " "
" cmpxchg8b %1"
: "=&A" (res), /* 0 */
"+m" (*p) /* 1 */
: : "memory", "cc");
return (res);
}
static __inline void
atomic_store_rel_64_i586(volatile uint64_t *p, uint64_t v)
{
__asm __volatile(
" movl %%eax,%%ebx ; "
" movl %%edx,%%ecx ; "
"1: "
" " MPLOCKED " "
" cmpxchg8b %0 ; "
" jne 1b"
: "+m" (*p), /* 0 */
"+A" (v) /* 1 */
: : "ebx", "ecx", "memory", "cc");
}
static __inline uint64_t
atomic_swap_64_i586(volatile uint64_t *p, uint64_t v)
{
__asm __volatile(
" movl %%eax,%%ebx ; "
" movl %%edx,%%ecx ; "
"1: "
" " MPLOCKED " "
" cmpxchg8b %0 ; "
" jne 1b"
: "+m" (*p), /* 0 */
"+A" (v) /* 1 */
: : "ebx", "ecx", "memory", "cc");
return (v);
}
static __inline int
atomic_cmpset_64(volatile uint64_t *dst, uint64_t expect, uint64_t src)
{
if ((cpu_feature & CPUID_CX8) == 0)
return (atomic_cmpset_64_i386(dst, expect, src));
else
return (atomic_cmpset_64_i586(dst, expect, src));
}
static __inline int
atomic_fcmpset_64(volatile uint64_t *dst, uint64_t *expect, uint64_t src)
{
if ((cpu_feature & CPUID_CX8) == 0)
return (atomic_fcmpset_64_i386(dst, expect, src));
else
return (atomic_fcmpset_64_i586(dst, expect, src));
}
static __inline uint64_t
atomic_load_acq_64(volatile uint64_t *p)
{
if ((cpu_feature & CPUID_CX8) == 0)
return (atomic_load_acq_64_i386(p));
else
return (atomic_load_acq_64_i586(p));
}
static __inline void
atomic_store_rel_64(volatile uint64_t *p, uint64_t v)
{
if ((cpu_feature & CPUID_CX8) == 0)
atomic_store_rel_64_i386(p, v);
else
atomic_store_rel_64_i586(p, v);
}
static __inline uint64_t
atomic_swap_64(volatile uint64_t *p, uint64_t v)
{
if ((cpu_feature & CPUID_CX8) == 0)
return (atomic_swap_64_i386(p, v));
else
return (atomic_swap_64_i586(p, v));
}
static __inline uint64_t
atomic_fetchadd_64(volatile uint64_t *p, uint64_t v)
{
for (;;) {
uint64_t t = *p;
if (atomic_cmpset_64(p, t, t + v))
return (t);
}
}
static __inline void
atomic_add_64(volatile uint64_t *p, uint64_t v)
{
uint64_t t;
for (;;) {
t = *p;
if (atomic_cmpset_64(p, t, t + v))
break;
}
}
static __inline void
atomic_subtract_64(volatile uint64_t *p, uint64_t v)
{
uint64_t t;
for (;;) {
t = *p;
if (atomic_cmpset_64(p, t, t - v))
break;
}
}
#endif /* _KERNEL */
#endif /* KLD_MODULE || !__GNUCLIKE_ASM */
ATOMIC_ASM(set, char, "orb %b1,%0", "iq", v);
ATOMIC_ASM(clear, char, "andb %b1,%0", "iq", ~v);
ATOMIC_ASM(add, char, "addb %b1,%0", "iq", v);
ATOMIC_ASM(subtract, char, "subb %b1,%0", "iq", v);
ATOMIC_ASM(set, short, "orw %w1,%0", "ir", v);
ATOMIC_ASM(clear, short, "andw %w1,%0", "ir", ~v);
ATOMIC_ASM(add, short, "addw %w1,%0", "ir", v);
ATOMIC_ASM(subtract, short, "subw %w1,%0", "ir", v);
ATOMIC_ASM(set, int, "orl %1,%0", "ir", v);
ATOMIC_ASM(clear, int, "andl %1,%0", "ir", ~v);
ATOMIC_ASM(add, int, "addl %1,%0", "ir", v);
ATOMIC_ASM(subtract, int, "subl %1,%0", "ir", v);
ATOMIC_ASM(set, long, "orl %1,%0", "ir", v);
ATOMIC_ASM(clear, long, "andl %1,%0", "ir", ~v);
ATOMIC_ASM(add, long, "addl %1,%0", "ir", v);
ATOMIC_ASM(subtract, long, "subl %1,%0", "ir", v);
#define ATOMIC_LOADSTORE(TYPE) \
ATOMIC_LOAD(TYPE); \
ATOMIC_STORE(TYPE)
ATOMIC_LOADSTORE(char);
ATOMIC_LOADSTORE(short);
ATOMIC_LOADSTORE(int);
ATOMIC_LOADSTORE(long);
#undef ATOMIC_ASM
#undef ATOMIC_LOAD
#undef ATOMIC_STORE
#undef ATOMIC_LOADSTORE
#ifndef WANT_FUNCTIONS
static __inline int
atomic_cmpset_long(volatile u_long *dst, u_long expect, u_long src)
{
return (atomic_cmpset_int((volatile u_int *)dst, (u_int)expect,
(u_int)src));
}
static __inline int
atomic_fcmpset_long(volatile u_long *dst, u_long *expect, u_long src)
{
return (atomic_fcmpset_int((volatile u_int *)dst, (u_int *)expect,
(u_int)src));
}
static __inline u_long
atomic_fetchadd_long(volatile u_long *p, u_long v)
{
return (atomic_fetchadd_int((volatile u_int *)p, (u_int)v));
}
static __inline int
atomic_testandset_long(volatile u_long *p, u_int v)
{
return (atomic_testandset_int((volatile u_int *)p, v));
}
static __inline int
atomic_testandclear_long(volatile u_long *p, u_int v)
{
return (atomic_testandclear_int((volatile u_int *)p, v));
}
/* Read the current value and store a new value in the destination. */
#ifdef __GNUCLIKE_ASM
static __inline u_int
atomic_swap_int(volatile u_int *p, u_int v)
{
__asm __volatile(
" xchgl %1,%0 ; "
"# atomic_swap_int"
: "+r" (v), /* 0 */
"+m" (*p)); /* 1 */
return (v);
}
static __inline u_long
atomic_swap_long(volatile u_long *p, u_long v)
{
return (atomic_swap_int((volatile u_int *)p, (u_int)v));
}
#else /* !__GNUCLIKE_ASM */
u_int atomic_swap_int(volatile u_int *p, u_int v);
u_long atomic_swap_long(volatile u_long *p, u_long v);
#endif /* __GNUCLIKE_ASM */
#define atomic_set_acq_char atomic_set_barr_char
#define atomic_set_rel_char atomic_set_barr_char
#define atomic_clear_acq_char atomic_clear_barr_char
#define atomic_clear_rel_char atomic_clear_barr_char
#define atomic_add_acq_char atomic_add_barr_char
#define atomic_add_rel_char atomic_add_barr_char
#define atomic_subtract_acq_char atomic_subtract_barr_char
#define atomic_subtract_rel_char atomic_subtract_barr_char
#define atomic_cmpset_acq_char atomic_cmpset_char
#define atomic_cmpset_rel_char atomic_cmpset_char
#define atomic_fcmpset_acq_char atomic_fcmpset_char
#define atomic_fcmpset_rel_char atomic_fcmpset_char
#define atomic_set_acq_short atomic_set_barr_short
#define atomic_set_rel_short atomic_set_barr_short
#define atomic_clear_acq_short atomic_clear_barr_short
#define atomic_clear_rel_short atomic_clear_barr_short
#define atomic_add_acq_short atomic_add_barr_short
#define atomic_add_rel_short atomic_add_barr_short
#define atomic_subtract_acq_short atomic_subtract_barr_short
#define atomic_subtract_rel_short atomic_subtract_barr_short
#define atomic_cmpset_acq_short atomic_cmpset_short
#define atomic_cmpset_rel_short atomic_cmpset_short
#define atomic_fcmpset_acq_short atomic_fcmpset_short
#define atomic_fcmpset_rel_short atomic_fcmpset_short
#define atomic_set_acq_int atomic_set_barr_int
#define atomic_set_rel_int atomic_set_barr_int
#define atomic_clear_acq_int atomic_clear_barr_int
#define atomic_clear_rel_int atomic_clear_barr_int
#define atomic_add_acq_int atomic_add_barr_int
#define atomic_add_rel_int atomic_add_barr_int
#define atomic_subtract_acq_int atomic_subtract_barr_int
#define atomic_subtract_rel_int atomic_subtract_barr_int
#define atomic_cmpset_acq_int atomic_cmpset_int
#define atomic_cmpset_rel_int atomic_cmpset_int
#define atomic_fcmpset_acq_int atomic_fcmpset_int
#define atomic_fcmpset_rel_int atomic_fcmpset_int
#define atomic_set_acq_long atomic_set_barr_long
#define atomic_set_rel_long atomic_set_barr_long
#define atomic_clear_acq_long atomic_clear_barr_long
#define atomic_clear_rel_long atomic_clear_barr_long
#define atomic_add_acq_long atomic_add_barr_long
#define atomic_add_rel_long atomic_add_barr_long
#define atomic_subtract_acq_long atomic_subtract_barr_long
#define atomic_subtract_rel_long atomic_subtract_barr_long
#define atomic_cmpset_acq_long atomic_cmpset_long
#define atomic_cmpset_rel_long atomic_cmpset_long
#define atomic_fcmpset_acq_long atomic_fcmpset_long
#define atomic_fcmpset_rel_long atomic_fcmpset_long
#define atomic_readandclear_int(p) atomic_swap_int(p, 0)
#define atomic_readandclear_long(p) atomic_swap_long(p, 0)
/* Operations on 8-bit bytes. */
#define atomic_set_8 atomic_set_char
#define atomic_set_acq_8 atomic_set_acq_char
#define atomic_set_rel_8 atomic_set_rel_char
#define atomic_clear_8 atomic_clear_char
#define atomic_clear_acq_8 atomic_clear_acq_char
#define atomic_clear_rel_8 atomic_clear_rel_char
#define atomic_add_8 atomic_add_char
#define atomic_add_acq_8 atomic_add_acq_char
#define atomic_add_rel_8 atomic_add_rel_char
#define atomic_subtract_8 atomic_subtract_char
#define atomic_subtract_acq_8 atomic_subtract_acq_char
#define atomic_subtract_rel_8 atomic_subtract_rel_char
#define atomic_load_acq_8 atomic_load_acq_char
#define atomic_store_rel_8 atomic_store_rel_char
#define atomic_cmpset_8 atomic_cmpset_char
#define atomic_cmpset_acq_8 atomic_cmpset_acq_char
#define atomic_cmpset_rel_8 atomic_cmpset_rel_char
#define atomic_fcmpset_8 atomic_fcmpset_char
#define atomic_fcmpset_acq_8 atomic_fcmpset_acq_char
#define atomic_fcmpset_rel_8 atomic_fcmpset_rel_char
/* Operations on 16-bit words. */
#define atomic_set_16 atomic_set_short
#define atomic_set_acq_16 atomic_set_acq_short
#define atomic_set_rel_16 atomic_set_rel_short
#define atomic_clear_16 atomic_clear_short
#define atomic_clear_acq_16 atomic_clear_acq_short
#define atomic_clear_rel_16 atomic_clear_rel_short
#define atomic_add_16 atomic_add_short
#define atomic_add_acq_16 atomic_add_acq_short
#define atomic_add_rel_16 atomic_add_rel_short
#define atomic_subtract_16 atomic_subtract_short
#define atomic_subtract_acq_16 atomic_subtract_acq_short
#define atomic_subtract_rel_16 atomic_subtract_rel_short
#define atomic_load_acq_16 atomic_load_acq_short
#define atomic_store_rel_16 atomic_store_rel_short
#define atomic_cmpset_16 atomic_cmpset_short
#define atomic_cmpset_acq_16 atomic_cmpset_acq_short
#define atomic_cmpset_rel_16 atomic_cmpset_rel_short
#define atomic_fcmpset_16 atomic_fcmpset_short
#define atomic_fcmpset_acq_16 atomic_fcmpset_acq_short
#define atomic_fcmpset_rel_16 atomic_fcmpset_rel_short
/* Operations on 32-bit double words. */
#define atomic_set_32 atomic_set_int
#define atomic_set_acq_32 atomic_set_acq_int
#define atomic_set_rel_32 atomic_set_rel_int
#define atomic_clear_32 atomic_clear_int
#define atomic_clear_acq_32 atomic_clear_acq_int
#define atomic_clear_rel_32 atomic_clear_rel_int
#define atomic_add_32 atomic_add_int
#define atomic_add_acq_32 atomic_add_acq_int
#define atomic_add_rel_32 atomic_add_rel_int
#define atomic_subtract_32 atomic_subtract_int
#define atomic_subtract_acq_32 atomic_subtract_acq_int
#define atomic_subtract_rel_32 atomic_subtract_rel_int
#define atomic_load_acq_32 atomic_load_acq_int
#define atomic_store_rel_32 atomic_store_rel_int
#define atomic_cmpset_32 atomic_cmpset_int
#define atomic_cmpset_acq_32 atomic_cmpset_acq_int
#define atomic_cmpset_rel_32 atomic_cmpset_rel_int
#define atomic_fcmpset_32 atomic_fcmpset_int
#define atomic_fcmpset_acq_32 atomic_fcmpset_acq_int
#define atomic_fcmpset_rel_32 atomic_fcmpset_rel_int
#define atomic_swap_32 atomic_swap_int
#define atomic_readandclear_32 atomic_readandclear_int
#define atomic_fetchadd_32 atomic_fetchadd_int
#define atomic_testandset_32 atomic_testandset_int
#define atomic_testandclear_32 atomic_testandclear_int
#ifdef _KERNEL
/* Operations on 64-bit quad words. */
#define atomic_cmpset_acq_64 atomic_cmpset_64
#define atomic_cmpset_rel_64 atomic_cmpset_64
#define atomic_fcmpset_acq_64 atomic_fcmpset_64
#define atomic_fcmpset_rel_64 atomic_fcmpset_64
#define atomic_fetchadd_acq_64 atomic_fetchadd_64
#define atomic_fetchadd_rel_64 atomic_fetchadd_64
#define atomic_add_acq_64 atomic_add_64
#define atomic_add_rel_64 atomic_add_64
#define atomic_subtract_acq_64 atomic_subtract_64
#define atomic_subtract_rel_64 atomic_subtract_64
#define atomic_load_64 atomic_load_acq_64
#define atomic_store_64 atomic_store_rel_64
#endif
/* Operations on pointers. */
#define atomic_set_ptr(p, v) \
atomic_set_int((volatile u_int *)(p), (u_int)(v))
#define atomic_set_acq_ptr(p, v) \
atomic_set_acq_int((volatile u_int *)(p), (u_int)(v))
#define atomic_set_rel_ptr(p, v) \
atomic_set_rel_int((volatile u_int *)(p), (u_int)(v))
#define atomic_clear_ptr(p, v) \
atomic_clear_int((volatile u_int *)(p), (u_int)(v))
#define atomic_clear_acq_ptr(p, v) \
atomic_clear_acq_int((volatile u_int *)(p), (u_int)(v))
#define atomic_clear_rel_ptr(p, v) \
atomic_clear_rel_int((volatile u_int *)(p), (u_int)(v))
#define atomic_add_ptr(p, v) \
atomic_add_int((volatile u_int *)(p), (u_int)(v))
#define atomic_add_acq_ptr(p, v) \
atomic_add_acq_int((volatile u_int *)(p), (u_int)(v))
#define atomic_add_rel_ptr(p, v) \
atomic_add_rel_int((volatile u_int *)(p), (u_int)(v))
#define atomic_subtract_ptr(p, v) \
atomic_subtract_int((volatile u_int *)(p), (u_int)(v))
#define atomic_subtract_acq_ptr(p, v) \
atomic_subtract_acq_int((volatile u_int *)(p), (u_int)(v))
#define atomic_subtract_rel_ptr(p, v) \
atomic_subtract_rel_int((volatile u_int *)(p), (u_int)(v))
#define atomic_load_acq_ptr(p) \
atomic_load_acq_int((volatile u_int *)(p))
#define atomic_store_rel_ptr(p, v) \
atomic_store_rel_int((volatile u_int *)(p), (v))
#define atomic_cmpset_ptr(dst, old, new) \
atomic_cmpset_int((volatile u_int *)(dst), (u_int)(old), (u_int)(new))
#define atomic_cmpset_acq_ptr(dst, old, new) \
atomic_cmpset_acq_int((volatile u_int *)(dst), (u_int)(old), \
(u_int)(new))
#define atomic_cmpset_rel_ptr(dst, old, new) \
atomic_cmpset_rel_int((volatile u_int *)(dst), (u_int)(old), \
(u_int)(new))
#define atomic_fcmpset_ptr(dst, old, new) \
atomic_fcmpset_int((volatile u_int *)(dst), (u_int *)(old), (u_int)(new))
#define atomic_fcmpset_acq_ptr(dst, old, new) \
atomic_fcmpset_acq_int((volatile u_int *)(dst), (u_int *)(old), \
(u_int)(new))
#define atomic_fcmpset_rel_ptr(dst, old, new) \
atomic_fcmpset_rel_int((volatile u_int *)(dst), (u_int *)(old), \
(u_int)(new))
#define atomic_swap_ptr(p, v) \
atomic_swap_int((volatile u_int *)(p), (u_int)(v))
#define atomic_readandclear_ptr(p) \
atomic_readandclear_int((volatile u_int *)(p))
#endif /* !WANT_FUNCTIONS */
#if defined(_KERNEL)
#define mb() __mbk()
#define wmb() __mbk()
#define rmb() __mbk()
#else
#define mb() __mbu()
#define wmb() __mbu()
#define rmb() __mbu()
#endif
#endif /* !_MACHINE_ATOMIC_H_ */