0
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1
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2 /*
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3 * Copyright (C) Igor Sysoev
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4 */
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5
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6
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7 #include <ngx_config.h>
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8 #include <ngx_core.h>
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9
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10 /*
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11 * The threads implementation uses the rfork(RFPROC|RFTHREAD|RFMEM) syscall
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12 * to create threads. All threads use the stacks of the same size mmap()ed
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13 * below the main stack. Thus the current thread id is determinated via
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14 * the stack pointer value.
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15 *
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16 * The mutex implementation uses the ngx_atomic_cmp_set() operation
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17 * to acquire a mutex and the SysV semaphore to wait on a mutex and to wake up
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18 * the waiting threads. The light mutex does not use semaphore, so after
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19 * spinning in the lock the thread calls sched_yield(). However the light
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20 * mutecies are intended to be used with the "trylock" operation only.
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21 * The SysV semop() is a cheap syscall, particularly if it has little sembuf's
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22 * and does not use SEM_UNDO.
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23 *
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10
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24 * The condition variable implementation uses the signal #64.
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25 * The signal handler is SIG_IGN so the kill() is a cheap syscall.
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26 * The thread waits a signal in kevent(). The use of the EVFILT_SIGNAL
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27 * is safe since FreeBSD 4.10-STABLE.
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0
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28 *
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29 * This threads implementation currently works on i386 (486+) and amd64
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30 * platforms only.
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31 */
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32
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33
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34 char *ngx_freebsd_kern_usrstack;
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35 size_t ngx_thread_stack_size;
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36
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37
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38 static size_t rz_size;
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39 static size_t usable_stack_size;
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40 static char *last_stack;
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41
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42 static ngx_uint_t nthreads;
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43 static ngx_uint_t max_threads;
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44
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45 static ngx_uint_t nkeys;
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46 static ngx_tid_t *tids; /* the threads tids array */
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47 void **ngx_tls; /* the threads tls's array */
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48
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49 /* the thread-safe libc errno */
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50
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51 static int errno0; /* the main thread's errno */
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52 static int *errnos; /* the threads errno's array */
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53
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54 int *__error()
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55 {
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56 int tid;
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57
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58 tid = ngx_gettid();
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59
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60 return tid ? &errnos[tid - 1] : &errno0;
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61 }
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62
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63
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64 /*
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65 * __isthreaded enables the spinlocks in some libc functions, i.e. in malloc()
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66 * and some other places. Nevertheless we protect our malloc()/free() calls
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67 * by own mutex that is more efficient than the spinlock.
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68 *
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69 * _spinlock() is a weak referenced stub in src/lib/libc/gen/_spinlock_stub.c
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70 * that does nothing.
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71 */
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72
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73 extern int __isthreaded;
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74
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75 void _spinlock(ngx_atomic_t *lock)
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76 {
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77 ngx_int_t tries;
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78
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79 tries = 0;
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80
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81 for ( ;; ) {
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82
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83 if (*lock) {
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84 if (ngx_ncpu > 1 && tries++ < 1000) {
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85 continue;
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86 }
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87
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88 sched_yield();
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89 tries = 0;
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90
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91 } else {
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92 if (ngx_atomic_cmp_set(lock, 0, 1)) {
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93 return;
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94 }
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95 }
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96 }
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97 }
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98
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99
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100 /*
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101 * Before FreeBSD 5.1 _spinunlock() is a simple #define in
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102 * src/lib/libc/include/spinlock.h that zeroes lock.
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103 *
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104 * Since FreeBSD 5.1 _spinunlock() is a weak referenced stub in
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105 * src/lib/libc/gen/_spinlock_stub.c that does nothing.
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106 */
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107
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108 #ifndef _spinunlock
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109
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110 void _spinunlock(ngx_atomic_t *lock)
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111 {
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112 *lock = 0;
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113 }
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114
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115 #endif
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116
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117
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10
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118 ngx_err_t ngx_create_thread(ngx_tid_t *tid, void* (*func)(void *arg), void *arg,
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119 ngx_log_t *log)
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0
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120 {
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10
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121 ngx_pid_t id;
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122 ngx_err_t err;
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123 char *stack, *stack_top;
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0
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124
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125 if (nthreads >= max_threads) {
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126 ngx_log_error(NGX_LOG_CRIT, log, 0,
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10
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127 "no more than %ui threads can be created", max_threads);
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0
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128 return NGX_ERROR;
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129 }
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130
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131 last_stack -= ngx_thread_stack_size;
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132
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133 stack = mmap(last_stack, usable_stack_size, PROT_READ|PROT_WRITE,
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134 MAP_STACK, -1, 0);
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135
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136 if (stack == MAP_FAILED) {
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137 ngx_log_error(NGX_LOG_ALERT, log, ngx_errno,
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10
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138 "mmap(%p:%uz, MAP_STACK) thread stack failed",
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0
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139 last_stack, usable_stack_size);
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140 return NGX_ERROR;
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141 }
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142
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143 if (stack != last_stack) {
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10
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144 ngx_log_error(NGX_LOG_ALERT, log, 0,
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145 "stack %p address was changed to %p", last_stack, stack);
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146 return NGX_ERROR;
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0
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147 }
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148
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149 stack_top = stack + usable_stack_size;
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150
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151 ngx_log_debug2(NGX_LOG_DEBUG_CORE, log, 0,
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10
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152 "thread stack: %p-%p", stack, stack_top);
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0
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153
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154 ngx_set_errno(0);
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155
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156 id = rfork_thread(RFPROC|RFTHREAD|RFMEM, stack_top,
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157 (ngx_rfork_thread_func_pt) func, arg);
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158
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159 err = ngx_errno;
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160
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161 if (id == -1) {
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162 ngx_log_error(NGX_LOG_ALERT, log, err, "rfork() failed");
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163
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164 } else {
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165 *tid = id;
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166 nthreads = (ngx_freebsd_kern_usrstack - stack_top)
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167 / ngx_thread_stack_size;
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168 tids[nthreads] = id;
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169
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10
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170 ngx_log_debug1(NGX_LOG_DEBUG_CORE, log, 0, "rfork()ed thread: %P", id);
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0
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171 }
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172
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173 return err;
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174 }
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175
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176
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177 ngx_int_t ngx_init_threads(int n, size_t size, ngx_cycle_t *cycle)
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178 {
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179 char *red_zone, *zone;
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180 size_t len;
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181 ngx_int_t i;
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182 struct sigaction sa;
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183
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184 max_threads = n + 1;
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185
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186 for (i = 0; i < n; i++) {
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187 ngx_memzero(&sa, sizeof(struct sigaction));
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188 sa.sa_handler = SIG_IGN;
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189 sigemptyset(&sa.sa_mask);
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190 if (sigaction(NGX_CV_SIGNAL, &sa, NULL) == -1) {
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191 ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
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192 "sigaction(%d, SIG_IGN) failed", NGX_CV_SIGNAL);
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193 return NGX_ERROR;
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194 }
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195 }
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196
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197 len = sizeof(ngx_freebsd_kern_usrstack);
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198 if (sysctlbyname("kern.usrstack", &ngx_freebsd_kern_usrstack, &len,
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199 NULL, 0) == -1)
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200 {
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201 ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
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202 "sysctlbyname(kern.usrstack) failed");
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203 return NGX_ERROR;
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204 }
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205
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206 /* the main thread stack red zone */
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207 rz_size = ngx_pagesize;
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208 red_zone = ngx_freebsd_kern_usrstack - (size + rz_size);
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209
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210 ngx_log_debug2(NGX_LOG_DEBUG_CORE, cycle->log, 0,
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10
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211 "usrstack: %p red zone: %p",
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0
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212 ngx_freebsd_kern_usrstack, red_zone);
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213
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214 zone = mmap(red_zone, rz_size, PROT_NONE, MAP_ANON, -1, 0);
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215 if (zone == MAP_FAILED) {
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216 ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
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10
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217 "mmap(%p:%uz, PROT_NONE, MAP_ANON) red zone failed",
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0
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218 red_zone, rz_size);
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219 return NGX_ERROR;
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220 }
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221
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222 if (zone != red_zone) {
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223 ngx_log_error(NGX_LOG_ALERT, cycle->log, 0,
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10
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224 "red zone %p address was changed to %p", red_zone, zone);
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225 return NGX_ERROR;
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0
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226 }
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227
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10
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228 /* create the thread errno' array */
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0
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229
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50
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230 errnos = ngx_calloc(n * sizeof(int), cycle->log);
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231 if (errnos == NULL) {
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0
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232 return NGX_ERROR;
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233 }
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234
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10
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235 /* create the thread tids array */
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0
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236
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50
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237 tids = ngx_calloc((n + 1) * sizeof(ngx_tid_t), cycle->log);
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238 if (tids == NULL) {
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0
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239 return NGX_ERROR;
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240 }
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241
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242 tids[0] = ngx_pid;
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243
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10
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244 /* create the thread tls' array */
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0
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245
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246 ngx_tls = ngx_calloc(NGX_THREAD_KEYS_MAX * (n + 1) * sizeof(void *),
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247 cycle->log);
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248 if (ngx_tls == NULL) {
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249 return NGX_ERROR;
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250 }
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251
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252 nthreads = 1;
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253
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254 last_stack = zone + rz_size;
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255 usable_stack_size = size;
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256 ngx_thread_stack_size = size + rz_size;
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257
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258 /* allow the spinlock in libc malloc() */
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259 __isthreaded = 1;
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260
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261 ngx_threaded = 1;
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262
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263 return NGX_OK;
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264 }
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265
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266
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267 ngx_tid_t ngx_thread_self()
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268 {
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50
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269 ngx_int_t tid;
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0
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270
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271 tid = ngx_gettid();
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272
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273 if (tids == NULL) {
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274 return ngx_pid;
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275 }
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276
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277 return tids[tid];
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278 }
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279
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280
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10
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281 ngx_err_t ngx_thread_key_create(ngx_tls_key_t *key)
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0
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282 {
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283 if (nkeys >= NGX_THREAD_KEYS_MAX) {
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284 return NGX_ENOMEM;
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285 }
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286
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287 *key = nkeys++;
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288
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289 return 0;
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290 }
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291
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292
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10
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293 ngx_err_t ngx_thread_set_tls(ngx_tls_key_t key, void *value)
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0
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294 {
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295 if (key >= NGX_THREAD_KEYS_MAX) {
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296 return NGX_EINVAL;
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297 }
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298
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299 ngx_tls[key * NGX_THREAD_KEYS_MAX + ngx_gettid()] = value;
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300 return 0;
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301 }
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302
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303
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10
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304 ngx_mutex_t *ngx_mutex_init(ngx_log_t *log, ngx_uint_t flags)
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0
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305 {
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306 ngx_mutex_t *m;
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307 union semun op;
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308
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50
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309 m = ngx_alloc(sizeof(ngx_mutex_t), log);
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310 if (m == NULL) {
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0
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311 return NULL;
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312 }
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313
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314 m->lock = 0;
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315 m->log = log;
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316
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317 if (flags & NGX_MUTEX_LIGHT) {
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318 m->semid = -1;
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319 return m;
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320 }
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321
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322 m->semid = semget(IPC_PRIVATE, 1, SEM_R|SEM_A);
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323 if (m->semid == -1) {
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324 ngx_log_error(NGX_LOG_ALERT, log, ngx_errno, "semget() failed");
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325 return NULL;
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326 }
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327
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328 op.val = 0;
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329
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330 if (semctl(m->semid, 0, SETVAL, op) == -1) {
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331 ngx_log_error(NGX_LOG_ALERT, log, ngx_errno, "semctl(SETVAL) failed");
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332
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333 if (semctl(m->semid, 0, IPC_RMID) == -1) {
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334 ngx_log_error(NGX_LOG_ALERT, log, ngx_errno,
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335 "semctl(IPC_RMID) failed");
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336 }
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337
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338 return NULL;
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339 }
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340
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341 return m;
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342 }
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343
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344
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345 void ngx_mutex_destroy(ngx_mutex_t *m)
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346 {
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347 if (semctl(m->semid, 0, IPC_RMID) == -1) {
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348 ngx_log_error(NGX_LOG_ALERT, m->log, ngx_errno,
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349 "semctl(IPC_RMID) failed");
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350 }
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351
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352 ngx_free((void *) m);
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353 }
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354
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355
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356 ngx_int_t ngx_mutex_dolock(ngx_mutex_t *m, ngx_int_t try)
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357 {
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50
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358 uint32_t lock, old;
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0
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359 ngx_uint_t tries;
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360 struct sembuf op;
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361
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362 if (!ngx_threaded) {
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363 return NGX_OK;
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364 }
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365
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366 #if (NGX_DEBUG)
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367 if (try) {
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368 ngx_log_debug2(NGX_LOG_DEBUG_MUTEX, m->log, 0,
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10
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369 "try lock mutex %p lock:%XD", m, m->lock);
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0
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370 } else {
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371 ngx_log_debug2(NGX_LOG_DEBUG_MUTEX, m->log, 0,
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10
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372 "lock mutex %p lock:%XD", m, m->lock);
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0
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373 }
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374 #endif
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375
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376 old = m->lock;
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377 tries = 0;
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378
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379 for ( ;; ) {
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380 if (old & NGX_MUTEX_LOCK_BUSY) {
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381
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382 if (try) {
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383 return NGX_AGAIN;
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384 }
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385
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18
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386 if (ngx_ncpu > 1 && tries++ < 1000) {
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0
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387
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388 /* the spinlock is used only on the SMP system */
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389
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390 old = m->lock;
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391 continue;
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392 }
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393
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394 if (m->semid == -1) {
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395 sched_yield();
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396
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397 tries = 0;
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398 old = m->lock;
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399 continue;
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400 }
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401
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402 ngx_log_debug2(NGX_LOG_DEBUG_MUTEX, m->log, 0,
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10
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403 "mutex %p lock:%XD", m, m->lock);
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0
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404
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405 /*
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406 * The mutex is locked so we increase a number
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407 * of the threads that are waiting on the mutex
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408 */
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409
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410 lock = old + 1;
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411
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412 if ((lock & ~NGX_MUTEX_LOCK_BUSY) > nthreads) {
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413 ngx_log_error(NGX_LOG_ALERT, m->log, ngx_errno,
|
10
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414 "%D threads wait for mutex %p, "
|
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415 "while only %ui threads are available",
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0
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416 lock & ~NGX_MUTEX_LOCK_BUSY, m, nthreads);
|
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417 return NGX_ERROR;
|
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418 }
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419
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420 if (ngx_atomic_cmp_set(&m->lock, old, lock)) {
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421
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422 ngx_log_debug2(NGX_LOG_DEBUG_MUTEX, m->log, 0,
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10
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423 "wait mutex %p lock:%XD", m, m->lock);
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0
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424
|
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425 /*
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426 * The number of the waiting threads has been increased
|
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427 * and we would wait on the SysV semaphore.
|
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428 * A semaphore should wake up us more efficiently than
|
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429 * a simple sched_yield() or usleep().
|
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430 */
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431
|
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432 op.sem_num = 0;
|
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433 op.sem_op = -1;
|
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434 op.sem_flg = 0;
|
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435
|
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436 if (semop(m->semid, &op, 1) == -1) {
|
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437 ngx_log_error(NGX_LOG_ALERT, m->log, ngx_errno,
|
10
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438 "semop() failed while waiting on mutex %p", m);
|
0
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439 return NGX_ERROR;
|
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440 }
|
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441
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442 ngx_log_debug2(NGX_LOG_DEBUG_MUTEX, m->log, 0,
|
10
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443 "mutex waked up %p lock:%XD", m, m->lock);
|
0
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444
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445 tries = 0;
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446 old = m->lock;
|
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447 continue;
|
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448 }
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449
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450 old = m->lock;
|
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451
|
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452 } else {
|
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453 lock = old | NGX_MUTEX_LOCK_BUSY;
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454
|
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455 if (ngx_atomic_cmp_set(&m->lock, old, lock)) {
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456
|
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457 /* we locked the mutex */
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458
|
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459 break;
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460 }
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461
|
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462 old = m->lock;
|
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463 }
|
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464
|
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465 if (tries++ > 1000) {
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466
|
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467 ngx_log_debug1(NGX_LOG_DEBUG_MUTEX, m->log, 0,
|
10
|
468 "mutex %p is contested", m);
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0
|
469
|
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470 /* the mutex is probably contested so we are giving up now */
|
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471
|
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472 sched_yield();
|
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473
|
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474 tries = 0;
|
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475 old = m->lock;
|
|
476 }
|
|
477 }
|
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478
|
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479 ngx_log_debug2(NGX_LOG_DEBUG_MUTEX, m->log, 0,
|
10
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480 "mutex %p is locked, lock:%XD", m, m->lock);
|
0
|
481
|
|
482 return NGX_OK;
|
|
483 }
|
|
484
|
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485
|
|
486 ngx_int_t ngx_mutex_unlock(ngx_mutex_t *m)
|
|
487 {
|
50
|
488 uint32_t lock, old;
|
0
|
489 struct sembuf op;
|
|
490
|
|
491 if (!ngx_threaded) {
|
|
492 return NGX_OK;
|
|
493 }
|
|
494
|
|
495 old = m->lock;
|
|
496
|
|
497 if (!(old & NGX_MUTEX_LOCK_BUSY)) {
|
|
498 ngx_log_error(NGX_LOG_ALERT, m->log, 0,
|
10
|
499 "trying to unlock the free mutex %p", m);
|
0
|
500 return NGX_ERROR;
|
|
501 }
|
|
502
|
|
503 /* free the mutex */
|
|
504
|
|
505 #if 0
|
|
506 ngx_log_debug2(NGX_LOG_DEBUG_MUTEX, m->log, 0,
|
10
|
507 "unlock mutex %p lock:%XD", m, old);
|
0
|
508 #endif
|
|
509
|
|
510 for ( ;; ) {
|
|
511 lock = old & ~NGX_MUTEX_LOCK_BUSY;
|
|
512
|
|
513 if (ngx_atomic_cmp_set(&m->lock, old, lock)) {
|
|
514 break;
|
|
515 }
|
|
516
|
|
517 old = m->lock;
|
|
518 }
|
|
519
|
|
520 if (m->semid == -1) {
|
|
521 ngx_log_debug1(NGX_LOG_DEBUG_MUTEX, m->log, 0,
|
10
|
522 "mutex %p is unlocked", m);
|
0
|
523
|
|
524 return NGX_OK;
|
|
525 }
|
|
526
|
|
527 /* check whether we need to wake up a waiting thread */
|
|
528
|
|
529 old = m->lock;
|
|
530
|
|
531 for ( ;; ) {
|
|
532 if (old & NGX_MUTEX_LOCK_BUSY) {
|
|
533
|
|
534 /* the mutex is just locked by another thread */
|
|
535
|
|
536 break;
|
|
537 }
|
|
538
|
|
539 if (old == 0) {
|
|
540 break;
|
|
541 }
|
|
542
|
|
543 /* there are the waiting threads */
|
|
544
|
|
545 lock = old - 1;
|
|
546
|
|
547 if (ngx_atomic_cmp_set(&m->lock, old, lock)) {
|
|
548
|
|
549 /* wake up the thread that waits on semaphore */
|
|
550
|
|
551 ngx_log_debug1(NGX_LOG_DEBUG_MUTEX, m->log, 0,
|
10
|
552 "wake up mutex %p", m);
|
0
|
553
|
|
554 op.sem_num = 0;
|
|
555 op.sem_op = 1;
|
|
556 op.sem_flg = 0;
|
|
557
|
|
558 if (semop(m->semid, &op, 1) == -1) {
|
|
559 ngx_log_error(NGX_LOG_ALERT, m->log, ngx_errno,
|
10
|
560 "semop() failed while waking up on mutex %p", m);
|
0
|
561 return NGX_ERROR;
|
|
562 }
|
|
563
|
|
564 break;
|
|
565 }
|
|
566
|
|
567 old = m->lock;
|
|
568 }
|
|
569
|
|
570 ngx_log_debug1(NGX_LOG_DEBUG_MUTEX, m->log, 0,
|
10
|
571 "mutex %p is unlocked", m);
|
0
|
572
|
|
573 return NGX_OK;
|
|
574 }
|
|
575
|
|
576
|
|
577 ngx_cond_t *ngx_cond_init(ngx_log_t *log)
|
|
578 {
|
|
579 ngx_cond_t *cv;
|
|
580
|
50
|
581 cv = ngx_alloc(sizeof(ngx_cond_t), log);
|
|
582 if (cv == NULL) {
|
0
|
583 return NULL;
|
|
584 }
|
|
585
|
|
586 cv->signo = NGX_CV_SIGNAL;
|
18
|
587 cv->tid = -1;
|
0
|
588 cv->log = log;
|
|
589 cv->kq = -1;
|
|
590
|
|
591 return cv;
|
|
592 }
|
|
593
|
|
594
|
|
595 void ngx_cond_destroy(ngx_cond_t *cv)
|
|
596 {
|
|
597 if (close(cv->kq) == -1) {
|
|
598 ngx_log_error(NGX_LOG_ALERT, cv->log, ngx_errno,
|
|
599 "kqueue close() failed");
|
|
600 }
|
|
601
|
|
602 ngx_free(cv);
|
|
603 }
|
|
604
|
|
605
|
|
606 ngx_int_t ngx_cond_wait(ngx_cond_t *cv, ngx_mutex_t *m)
|
|
607 {
|
|
608 int n;
|
|
609 ngx_err_t err;
|
|
610 struct kevent kev;
|
|
611 struct timespec ts;
|
|
612
|
|
613 if (cv->kq == -1) {
|
|
614
|
|
615 /*
|
|
616 * We have to add the EVFILT_SIGNAL filter in the rfork()ed thread.
|
|
617 * Otherwise the thread would not get a signal event.
|
|
618 *
|
|
619 * However, we have not to open the kqueue in the thread,
|
|
620 * it is simply handy do it together.
|
|
621 */
|
|
622
|
|
623 cv->kq = kqueue();
|
|
624 if (cv->kq == -1) {
|
|
625 ngx_log_error(NGX_LOG_ALERT, cv->log, ngx_errno, "kqueue() failed");
|
|
626 return NGX_ERROR;
|
|
627 }
|
|
628
|
|
629 ngx_log_debug2(NGX_LOG_DEBUG_CORE, cv->log, 0,
|
|
630 "cv kq:%d signo:%d", cv->kq, cv->signo);
|
|
631
|
|
632 kev.ident = cv->signo;
|
|
633 kev.filter = EVFILT_SIGNAL;
|
|
634 kev.flags = EV_ADD;
|
|
635 kev.fflags = 0;
|
|
636 kev.data = 0;
|
|
637 kev.udata = NULL;
|
|
638
|
|
639 ts.tv_sec = 0;
|
|
640 ts.tv_nsec = 0;
|
|
641
|
|
642 if (kevent(cv->kq, &kev, 1, NULL, 0, &ts) == -1) {
|
|
643 ngx_log_error(NGX_LOG_ALERT, cv->log, ngx_errno, "kevent() failed");
|
|
644 return NGX_ERROR;
|
|
645 }
|
18
|
646
|
|
647 cv->tid = ngx_thread_self();
|
0
|
648 }
|
|
649
|
|
650 if (ngx_mutex_unlock(m) == NGX_ERROR) {
|
|
651 return NGX_ERROR;
|
|
652 }
|
|
653
|
|
654 ngx_log_debug3(NGX_LOG_DEBUG_CORE, cv->log, 0,
|
10
|
655 "cv %p wait, kq:%d, signo:%d", cv, cv->kq, cv->signo);
|
0
|
656
|
|
657 for ( ;; ) {
|
|
658 n = kevent(cv->kq, NULL, 0, &kev, 1, NULL);
|
|
659
|
|
660 ngx_log_debug2(NGX_LOG_DEBUG_CORE, cv->log, 0,
|
10
|
661 "cv %p kevent: %d", cv, n);
|
0
|
662
|
|
663 if (n == -1) {
|
|
664 err = ngx_errno;
|
|
665 ngx_log_error((err == NGX_EINTR) ? NGX_LOG_INFO : NGX_LOG_ALERT,
|
|
666 cv->log, ngx_errno,
|
10
|
667 "kevent() failed while waiting condition variable %p",
|
|
668 cv);
|
0
|
669
|
|
670 if (err == NGX_EINTR) {
|
|
671 break;
|
|
672 }
|
|
673
|
|
674 return NGX_ERROR;
|
|
675 }
|
|
676
|
|
677 if (n == 0) {
|
|
678 ngx_log_error(NGX_LOG_ALERT, cv->log, 0,
|
|
679 "kevent() returned no events "
|
10
|
680 "while waiting condition variable %p",
|
0
|
681 cv);
|
|
682 continue;
|
|
683 }
|
|
684
|
|
685 if (kev.filter != EVFILT_SIGNAL) {
|
|
686 ngx_log_error(NGX_LOG_ALERT, cv->log, 0,
|
|
687 "kevent() returned unexpected events: %d "
|
10
|
688 "while waiting condition variable %p",
|
0
|
689 kev.filter, cv);
|
|
690 continue;
|
|
691 }
|
|
692
|
|
693 if (kev.ident != (uintptr_t) cv->signo) {
|
|
694 ngx_log_error(NGX_LOG_ALERT, cv->log, 0,
|
|
695 "kevent() returned unexpected signal: %d ",
|
10
|
696 "while waiting condition variable %p",
|
0
|
697 kev.ident, cv);
|
|
698 continue;
|
|
699 }
|
|
700
|
|
701 break;
|
|
702 }
|
|
703
|
10
|
704 ngx_log_debug1(NGX_LOG_DEBUG_CORE, cv->log, 0, "cv %p is waked up", cv);
|
0
|
705
|
|
706 if (ngx_mutex_lock(m) == NGX_ERROR) {
|
|
707 return NGX_ERROR;
|
|
708 }
|
|
709
|
|
710 return NGX_OK;
|
|
711 }
|
|
712
|
|
713
|
|
714 ngx_int_t ngx_cond_signal(ngx_cond_t *cv)
|
|
715 {
|
|
716 ngx_err_t err;
|
|
717
|
|
718 ngx_log_debug3(NGX_LOG_DEBUG_CORE, cv->log, 0,
|
10
|
719 "cv %p to signal %P %d",
|
0
|
720 cv, cv->tid, cv->signo);
|
|
721
|
18
|
722 if (cv->tid == -1) {
|
|
723 return NGX_OK;
|
|
724 }
|
|
725
|
0
|
726 if (kill(cv->tid, cv->signo) == -1) {
|
|
727
|
|
728 err = ngx_errno;
|
|
729
|
|
730 ngx_log_error(NGX_LOG_ALERT, cv->log, err,
|
10
|
731 "kill() failed while signaling condition variable %p", cv);
|
0
|
732
|
|
733 if (err == NGX_ESRCH) {
|
|
734 cv->tid = -1;
|
|
735 }
|
|
736
|
|
737 return NGX_ERROR;
|
|
738 }
|
|
739
|
10
|
740 ngx_log_debug1(NGX_LOG_DEBUG_CORE, cv->log, 0, "cv %p is signaled", cv);
|
0
|
741
|
|
742 return NGX_OK;
|
|
743 }
|