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nginx / nginx / e31e90b3e10ca2afafccae9a57910133d93b2d37 / . / src / os / unix / ngx_atomic.h
blob: d90cf6691eb7bd1985f4fd42205751c641de2048 [file] [log] [blame]
/*
* Copyright (C) Igor Sysoev
*/
#ifndef _NGX_ATOMIC_H_INCLUDED_
#define _NGX_ATOMIC_H_INCLUDED_
#include <ngx_config.h>
#include <ngx_core.h>
#if ( __i386__ )
#define NGX_HAVE_ATOMIC_OPS 1
typedef int32_t ngx_atomic_int_t;
typedef uint32_t ngx_atomic_uint_t;
typedef volatile ngx_atomic_uint_t ngx_atomic_t;
#define NGX_ATOMIC_T_LEN sizeof("-2147483648") - 1
#if (NGX_SMP)
#define NGX_SMP_LOCK "lock;"
#else
#define NGX_SMP_LOCK
#endif
/*
* the "=q" is any of the %eax, %ebx, %ecx, or %edx registers.
* the '"0" (1)' parameter preloads 1 into %0.
* the "cc" means that flags were changed.
*
* "xadd r, [m]":
*
* temp = [m];
* [m] += r;
* r = temp;
*/
static ngx_inline ngx_atomic_uint_t
ngx_atomic_inc(ngx_atomic_t *value)
{
ngx_atomic_uint_t old;
__asm__ volatile (
NGX_SMP_LOCK
" xaddl %0, %2; "
" incl %0; "
: "=q" (old) : "0" (1), "m" (*value) : "cc", "memory");
return old;
}
static ngx_inline ngx_atomic_uint_t
ngx_atomic_dec(ngx_atomic_t *value)
{
ngx_atomic_uint_t old;
__asm__ volatile (
NGX_SMP_LOCK
" xaddl %0, %2; "
" decl %0; "
: "=q" (old) : "0" (-1), "m" (*value) : "cc", "memory");
return old;
}
/*
* the "q" is any of the %eax, %ebx, %ecx, or %edx registers.
* the "=a" and "a" are the %eax register. Although we can return result
* in any register, we use %eax because it is used in cmpxchg anyway.
*
* "cmpxchg r, [m]":
*
* if (eax == [m]) {
* zf = 1;
* [m] = r;
* } else {
* zf = 0;
* eax = [m];
* }
*/
static ngx_inline ngx_atomic_uint_t
ngx_atomic_cmp_set(ngx_atomic_t *lock, ngx_atomic_uint_t old,
ngx_atomic_uint_t set)
{
ngx_atomic_uint_t res;
__asm__ volatile (
NGX_SMP_LOCK
" cmpxchgl %3, %1; "
" setz %b0; "
" movzbl %b0, %0; "
: "=a" (res) : "m" (*lock), "a" (old), "q" (set) : "cc", "memory");
return res;
}
#elif ( __amd64__ )
#define NGX_HAVE_ATOMIC_OPS 1
typedef int64_t ngx_atomic_int_t;
typedef uint64_t ngx_atomic_uint_t;
typedef volatile ngx_atomic_uint_t ngx_atomic_t;
#define NGX_ATOMIC_T_LEN sizeof("-9223372036854775808") - 1
#if (NGX_SMP)
#define NGX_SMP_LOCK "lock;"
#else
#define NGX_SMP_LOCK
#endif
static ngx_inline ngx_atomic_uint_t
ngx_atomic_inc(ngx_atomic_t *value)
{
ngx_atomic_uint_t old;
__asm__ volatile (
NGX_SMP_LOCK
" xaddq %0, %2; "
" incq %0; "
: "=r" (old) : "0" (1), "m" (*value) : "cc", "memory");
return old;
}
/* the '"0" (-1LL)' parameter preloads -1 into the 64-bit %0 register */
static ngx_inline ngx_atomic_uint_t
ngx_atomic_dec(ngx_atomic_t *value)
{
ngx_atomic_uint_t old;
__asm__ volatile (
NGX_SMP_LOCK
" xaddq %0, %2; "
" decq %0; "
: "=r" (old) : "0" (-1LL), "m" (*value) : "cc", "memory");
return old;
}
/* the "=a" and "a" are the %rax register. */
static ngx_inline ngx_atomic_uint_t
ngx_atomic_cmp_set(ngx_atomic_t *lock, ngx_atomic_uint_t old,
ngx_atomic_uint_t set)
{
ngx_atomic_uint_t res;
__asm__ volatile (
NGX_SMP_LOCK
" cmpxchgq %3, %1; "
" setz %b0; "
" movzbq %b0, %0; "
: "=a" (res) : "m" (*lock), "a" (old), "r" (set) : "cc", "memory");
return res;
}
#elif ( __sparc__ )
#define NGX_HAVE_ATOMIC_OPS 1
#if (NGX_PTR_SIZE == 8)
typedef int64_t ngx_atomic_int_t;
typedef uint64_t ngx_atomic_uint_t;
#define NGX_ATOMIC_T_LEN sizeof("-9223372036854775808") - 1
#define NGX_CASXA "casxa"
#else
typedef int32_t ngx_atomic_int_t;
typedef uint32_t ngx_atomic_uint_t;
#define NGX_ATOMIC_T_LEN sizeof("-2147483648") - 1
#define NGX_CASXA "casa"
#endif
typedef volatile ngx_atomic_uint_t ngx_atomic_t;
/*
* the "+r" means the general register used for both input and output.
*
* "casa [r1] 0x80, r2, r0" and
* "casxa [r1] 0x80, r2, r0" do the following:
*
* if ([r1] == r2) {
* swap(r0, [r1]);
* } else {
* r0 = [r1];
* }
*
* so "r0 == r2" means that the operation was successfull.
*/
static ngx_inline ngx_atomic_uint_t
ngx_atomic_inc(ngx_atomic_t *value)
{
ngx_atomic_uint_t old, new, res;
old = *value;
for ( ;; ) {
new = old + 1;
res = new;
__asm__ volatile (
NGX_CASXA " [%1] 0x80, %2, %0"
: "+r" (res) : "r" (value), "r" (old) : "memory");
if (res == old) {
return new;
}
old = res;
}
}
static ngx_inline ngx_atomic_uint_t
ngx_atomic_dec(ngx_atomic_t *value)
{
ngx_atomic_uint_t old, new, res;
old = *value;
for ( ;; ) {
new = old - 1;
res = new;
__asm__ volatile (
NGX_CASXA " [%1] 0x80, %2, %0"
: "+r" (res) : "r" (value), "r" (old) : "memory");
if (res == old) {
return new;
}
old = res;
}
}
static ngx_inline ngx_atomic_uint_t
ngx_atomic_cmp_set(ngx_atomic_t *lock, ngx_atomic_uint_t old,
ngx_atomic_uint_t set)
{
__asm__ volatile (
NGX_CASXA " [%1] 0x80, %2, %0"
: "+r" (set) : "r" (lock), "r" (old) : "memory");
return (set == old);
}
#elif ( __ppc__ )
#define NGX_HAVE_ATOMIC_OPS 1
#if (NGX_PTR_SIZE == 8)
typedef int64_t ngx_atomic_int_t;
typedef uint64_t ngx_atomic_uint_t;
#define NGX_ATOMIC_T_LEN sizeof("-9223372036854775808") - 1
#else
typedef int32_t ngx_atomic_int_t;
typedef uint32_t ngx_atomic_uint_t;
#define NGX_ATOMIC_T_LEN sizeof("-2147483648") - 1
#endif
typedef volatile ngx_atomic_uint_t ngx_atomic_t;
/*
* the ppc assembler treats ";" as comment, so we have to use "\n".
* the minus in "bne-" is a hint for the branch prediction unit that
* this branch is unlikely to be taken.
*
* the "=&r" means that no input registers can be used.
* the "=&b" means that the base registers can be used only, i.e. any register
* except r0. the r0 register can not be used in "addi r0, r0, 1".
* the "1b" means the nearest backward label "1" and the "1f" means
* the nearest forward label "1".
*/
static ngx_inline ngx_atomic_uint_t
ngx_atomic_inc(ngx_atomic_t *value)
{
ngx_atomic_uint_t res;
__asm__ volatile (
"1: lwarx %0, 0, %1 \n" /* load from [value] into "res" */
/* and store reservation */
" addi %0, %0, 1 \n" /* add "1" to "res" */
" stwcx. %0, 0, %1 \n" /* store "res" into [value] if reservation */
/* is not cleared */
" bne- 1b \n" /* try again if reservation was cleared */
: "=&b" (res) : "r" (value) : "cc", "memory");
return res;
}
static ngx_inline ngx_atomic_uint_t
ngx_atomic_dec(ngx_atomic_t *value)
{
ngx_atomic_uint_t res;
__asm__ volatile (
"1: lwarx %0, 0, %1 \n" /* load from [value] into "res" */
/* and store reservation */
" addi %0, %0, -1 \n" /* sub "1" from "res" */
" stwcx. %0, 0, %1 \n" /* store "res" into [value] if reservation */
/* is not cleared */
" bne- 1b \n" /* try again if reservation was cleared */
: "=&b" (res) : "r" (value) : "cc", "memory");
return res;
}
static ngx_inline ngx_atomic_uint_t
ngx_atomic_cmp_set(ngx_atomic_t *lock, ngx_atomic_uint_t old,
ngx_atomic_uint_t set)
{
ngx_atomic_uint_t res, temp;
__asm__ volatile (
" li %0, 0 \n" /* preset "0" to "res" */
" lwarx %1, 0, %2 \n" /* load from [lock] into "temp" */
/* and store reservation */
" cmpw %1, %3 \n" /* compare "temp" and "old" */
" bne- 1f \n" /* not equal */
" stwcx. %4, 0, %2 \n" /* store "set" into [lock] if reservation */
/* is not cleared */
" bne- 1f \n" /* the reservation was cleared */
" li %0, 1 \n" /* set "1" to "res" */
"1: \n"
: "=&r" (res), "=&r" (temp)
: "r" (lock), "r" (old), "r" (set)
: "cc", "memory");
return res;
}
#else
#define NGX_HAVE_ATOMIC_OPS 0
typedef int32_t ngx_atomic_int_t;
typedef uint32_t ngx_atomic_uint_t;
typedef volatile ngx_atomic_uint_t ngx_atomic_t;
#define NGX_ATOMIC_T_LEN sizeof("-2147483648") - 1
#define ngx_atomic_inc(x) ++(*(x))
#define ngx_atomic_dec(x) --(*(x))
static ngx_inline ngx_atomic_uint_t
ngx_atomic_cmp_set(ngx_atomic_t *lock, ngx_atomic_uint_t old,
ngx_atomic_uint_t set)
{
*lock = set;
return 1;
}
#endif
void ngx_spinlock(ngx_atomic_t *lock, ngx_uint_t spin);
#define ngx_trylock(lock) (*(lock) == 0 && ngx_atomic_cmp_set(lock, 0, 1))
#define ngx_unlock(lock) *(lock) = 0
#endif /* _NGX_ATOMIC_H_INCLUDED_ */