Mercurial > hg > nginx
view src/stream/ngx_stream.c @ 6755:e2f13011343e stable-1.10
HTTP/2: fixed the "http request count is zero" alert.
When the stream is terminated the HEADERS frame can still wait in the output
queue. This frame can't be removed and must be sent to the client anyway,
since HTTP/2 uses stateful compression for headers. So in order to postpone
closing and freeing memory of such stream the special close stream handler
is set to the write event. After the HEADERS frame is sent the write event
is called and the stream will be finally closed.
Some events like receiving a RST_STREAM can trigger the read handler of such
stream in closing state and cause unexpected processing that can result in
another attempt to finalize the request. To prevent it the read handler is
now set to ngx_http_empty_handler.
Thanks to Amazon.
| author | Valentin Bartenev <vbart@nginx.com> |
|---|---|
| date | Thu, 16 Jun 2016 20:55:11 +0300 |
| parents | 8f038068f4bc |
| children | c90cf79d0e1d |
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/* * Copyright (C) Roman Arutyunyan * Copyright (C) Nginx, Inc. */ #include <ngx_config.h> #include <ngx_core.h> #include <ngx_event.h> #include <ngx_stream.h> static char *ngx_stream_block(ngx_conf_t *cf, ngx_command_t *cmd, void *conf); static ngx_int_t ngx_stream_add_ports(ngx_conf_t *cf, ngx_array_t *ports, ngx_stream_listen_t *listen); static char *ngx_stream_optimize_servers(ngx_conf_t *cf, ngx_array_t *ports); static ngx_int_t ngx_stream_add_addrs(ngx_conf_t *cf, ngx_stream_port_t *stport, ngx_stream_conf_addr_t *addr); #if (NGX_HAVE_INET6) static ngx_int_t ngx_stream_add_addrs6(ngx_conf_t *cf, ngx_stream_port_t *stport, ngx_stream_conf_addr_t *addr); #endif static ngx_int_t ngx_stream_cmp_conf_addrs(const void *one, const void *two); ngx_uint_t ngx_stream_max_module; static ngx_command_t ngx_stream_commands[] = { { ngx_string("stream"), NGX_MAIN_CONF|NGX_CONF_BLOCK|NGX_CONF_NOARGS, ngx_stream_block, 0, 0, NULL }, ngx_null_command }; static ngx_core_module_t ngx_stream_module_ctx = { ngx_string("stream"), NULL, NULL }; ngx_module_t ngx_stream_module = { NGX_MODULE_V1, &ngx_stream_module_ctx, /* module context */ ngx_stream_commands, /* module directives */ NGX_CORE_MODULE, /* module type */ NULL, /* init master */ NULL, /* init module */ NULL, /* init process */ NULL, /* init thread */ NULL, /* exit thread */ NULL, /* exit process */ NULL, /* exit master */ NGX_MODULE_V1_PADDING }; static char * ngx_stream_block(ngx_conf_t *cf, ngx_command_t *cmd, void *conf) { char *rv; ngx_uint_t i, m, mi, s; ngx_conf_t pcf; ngx_array_t ports; ngx_stream_listen_t *listen; ngx_stream_module_t *module; ngx_stream_conf_ctx_t *ctx; ngx_stream_core_srv_conf_t **cscfp; ngx_stream_core_main_conf_t *cmcf; if (*(ngx_stream_conf_ctx_t **) conf) { return "is duplicate"; } /* the main stream context */ ctx = ngx_pcalloc(cf->pool, sizeof(ngx_stream_conf_ctx_t)); if (ctx == NULL) { return NGX_CONF_ERROR; } *(ngx_stream_conf_ctx_t **) conf = ctx; /* count the number of the stream modules and set up their indices */ ngx_stream_max_module = ngx_count_modules(cf->cycle, NGX_STREAM_MODULE); /* the stream main_conf context, it's the same in the all stream contexts */ ctx->main_conf = ngx_pcalloc(cf->pool, sizeof(void *) * ngx_stream_max_module); if (ctx->main_conf == NULL) { return NGX_CONF_ERROR; } /* * the stream null srv_conf context, it is used to merge * the server{}s' srv_conf's */ ctx->srv_conf = ngx_pcalloc(cf->pool, sizeof(void *) * ngx_stream_max_module); if (ctx->srv_conf == NULL) { return NGX_CONF_ERROR; } /* * create the main_conf's and the null srv_conf's of the all stream modules */ for (m = 0; cf->cycle->modules[m]; m++) { if (cf->cycle->modules[m]->type != NGX_STREAM_MODULE) { continue; } module = cf->cycle->modules[m]->ctx; mi = cf->cycle->modules[m]->ctx_index; if (module->create_main_conf) { ctx->main_conf[mi] = module->create_main_conf(cf); if (ctx->main_conf[mi] == NULL) { return NGX_CONF_ERROR; } } if (module->create_srv_conf) { ctx->srv_conf[mi] = module->create_srv_conf(cf); if (ctx->srv_conf[mi] == NULL) { return NGX_CONF_ERROR; } } } /* parse inside the stream{} block */ pcf = *cf; cf->ctx = ctx; cf->module_type = NGX_STREAM_MODULE; cf->cmd_type = NGX_STREAM_MAIN_CONF; rv = ngx_conf_parse(cf, NULL); if (rv != NGX_CONF_OK) { *cf = pcf; return rv; } /* init stream{} main_conf's, merge the server{}s' srv_conf's */ cmcf = ctx->main_conf[ngx_stream_core_module.ctx_index]; cscfp = cmcf->servers.elts; for (m = 0; cf->cycle->modules[m]; m++) { if (cf->cycle->modules[m]->type != NGX_STREAM_MODULE) { continue; } module = cf->cycle->modules[m]->ctx; mi = cf->cycle->modules[m]->ctx_index; /* init stream{} main_conf's */ cf->ctx = ctx; if (module->init_main_conf) { rv = module->init_main_conf(cf, ctx->main_conf[mi]); if (rv != NGX_CONF_OK) { *cf = pcf; return rv; } } for (s = 0; s < cmcf->servers.nelts; s++) { /* merge the server{}s' srv_conf's */ cf->ctx = cscfp[s]->ctx; if (module->merge_srv_conf) { rv = module->merge_srv_conf(cf, ctx->srv_conf[mi], cscfp[s]->ctx->srv_conf[mi]); if (rv != NGX_CONF_OK) { *cf = pcf; return rv; } } } } for (m = 0; cf->cycle->modules[m]; m++) { if (cf->cycle->modules[m]->type != NGX_STREAM_MODULE) { continue; } module = cf->cycle->modules[m]->ctx; if (module->postconfiguration) { if (module->postconfiguration(cf) != NGX_OK) { return NGX_CONF_ERROR; } } } *cf = pcf; if (ngx_array_init(&ports, cf->temp_pool, 4, sizeof(ngx_stream_conf_port_t)) != NGX_OK) { return NGX_CONF_ERROR; } listen = cmcf->listen.elts; for (i = 0; i < cmcf->listen.nelts; i++) { if (ngx_stream_add_ports(cf, &ports, &listen[i]) != NGX_OK) { return NGX_CONF_ERROR; } } return ngx_stream_optimize_servers(cf, &ports); } static ngx_int_t ngx_stream_add_ports(ngx_conf_t *cf, ngx_array_t *ports, ngx_stream_listen_t *listen) { in_port_t p; ngx_uint_t i; struct sockaddr *sa; struct sockaddr_in *sin; ngx_stream_conf_port_t *port; ngx_stream_conf_addr_t *addr; #if (NGX_HAVE_INET6) struct sockaddr_in6 *sin6; #endif sa = &listen->u.sockaddr; switch (sa->sa_family) { #if (NGX_HAVE_INET6) case AF_INET6: sin6 = &listen->u.sockaddr_in6; p = sin6->sin6_port; break; #endif #if (NGX_HAVE_UNIX_DOMAIN) case AF_UNIX: p = 0; break; #endif default: /* AF_INET */ sin = &listen->u.sockaddr_in; p = sin->sin_port; break; } port = ports->elts; for (i = 0; i < ports->nelts; i++) { if (p == port[i].port && listen->type == port[i].type && sa->sa_family == port[i].family) { /* a port is already in the port list */ port = &port[i]; goto found; } } /* add a port to the port list */ port = ngx_array_push(ports); if (port == NULL) { return NGX_ERROR; } port->family = sa->sa_family; port->type = listen->type; port->port = p; if (ngx_array_init(&port->addrs, cf->temp_pool, 2, sizeof(ngx_stream_conf_addr_t)) != NGX_OK) { return NGX_ERROR; } found: addr = ngx_array_push(&port->addrs); if (addr == NULL) { return NGX_ERROR; } addr->opt = *listen; return NGX_OK; } static char * ngx_stream_optimize_servers(ngx_conf_t *cf, ngx_array_t *ports) { ngx_uint_t i, p, last, bind_wildcard; ngx_listening_t *ls; ngx_stream_port_t *stport; ngx_stream_conf_port_t *port; ngx_stream_conf_addr_t *addr; ngx_stream_core_srv_conf_t *cscf; port = ports->elts; for (p = 0; p < ports->nelts; p++) { ngx_sort(port[p].addrs.elts, (size_t) port[p].addrs.nelts, sizeof(ngx_stream_conf_addr_t), ngx_stream_cmp_conf_addrs); addr = port[p].addrs.elts; last = port[p].addrs.nelts; /* * if there is the binding to the "*:port" then we need to bind() * to the "*:port" only and ignore the other bindings */ if (addr[last - 1].opt.wildcard) { addr[last - 1].opt.bind = 1; bind_wildcard = 1; } else { bind_wildcard = 0; } i = 0; while (i < last) { if (bind_wildcard && !addr[i].opt.bind) { i++; continue; } ls = ngx_create_listening(cf, &addr[i].opt.u.sockaddr, addr[i].opt.socklen); if (ls == NULL) { return NGX_CONF_ERROR; } ls->addr_ntop = 1; ls->handler = ngx_stream_init_connection; ls->pool_size = 256; ls->type = addr[i].opt.type; cscf = addr->opt.ctx->srv_conf[ngx_stream_core_module.ctx_index]; ls->logp = cscf->error_log; ls->log.data = &ls->addr_text; ls->log.handler = ngx_accept_log_error; ls->backlog = addr[i].opt.backlog; ls->wildcard = addr[i].opt.wildcard; ls->keepalive = addr[i].opt.so_keepalive; #if (NGX_HAVE_KEEPALIVE_TUNABLE) ls->keepidle = addr[i].opt.tcp_keepidle; ls->keepintvl = addr[i].opt.tcp_keepintvl; ls->keepcnt = addr[i].opt.tcp_keepcnt; #endif #if (NGX_HAVE_INET6 && defined IPV6_V6ONLY) ls->ipv6only = addr[i].opt.ipv6only; #endif #if (NGX_HAVE_REUSEPORT) ls->reuseport = addr[i].opt.reuseport; #endif stport = ngx_palloc(cf->pool, sizeof(ngx_stream_port_t)); if (stport == NULL) { return NGX_CONF_ERROR; } ls->servers = stport; stport->naddrs = i + 1; switch (ls->sockaddr->sa_family) { #if (NGX_HAVE_INET6) case AF_INET6: if (ngx_stream_add_addrs6(cf, stport, addr) != NGX_OK) { return NGX_CONF_ERROR; } break; #endif default: /* AF_INET */ if (ngx_stream_add_addrs(cf, stport, addr) != NGX_OK) { return NGX_CONF_ERROR; } break; } if (ngx_clone_listening(cf, ls) != NGX_OK) { return NGX_CONF_ERROR; } addr++; last--; } } return NGX_CONF_OK; } static ngx_int_t ngx_stream_add_addrs(ngx_conf_t *cf, ngx_stream_port_t *stport, ngx_stream_conf_addr_t *addr) { u_char *p; size_t len; ngx_uint_t i; struct sockaddr_in *sin; ngx_stream_in_addr_t *addrs; u_char buf[NGX_SOCKADDR_STRLEN]; stport->addrs = ngx_pcalloc(cf->pool, stport->naddrs * sizeof(ngx_stream_in_addr_t)); if (stport->addrs == NULL) { return NGX_ERROR; } addrs = stport->addrs; for (i = 0; i < stport->naddrs; i++) { sin = &addr[i].opt.u.sockaddr_in; addrs[i].addr = sin->sin_addr.s_addr; addrs[i].conf.ctx = addr[i].opt.ctx; #if (NGX_STREAM_SSL) addrs[i].conf.ssl = addr[i].opt.ssl; #endif len = ngx_sock_ntop(&addr[i].opt.u.sockaddr, addr[i].opt.socklen, buf, NGX_SOCKADDR_STRLEN, 1); p = ngx_pnalloc(cf->pool, len); if (p == NULL) { return NGX_ERROR; } ngx_memcpy(p, buf, len); addrs[i].conf.addr_text.len = len; addrs[i].conf.addr_text.data = p; } return NGX_OK; } #if (NGX_HAVE_INET6) static ngx_int_t ngx_stream_add_addrs6(ngx_conf_t *cf, ngx_stream_port_t *stport, ngx_stream_conf_addr_t *addr) { u_char *p; size_t len; ngx_uint_t i; struct sockaddr_in6 *sin6; ngx_stream_in6_addr_t *addrs6; u_char buf[NGX_SOCKADDR_STRLEN]; stport->addrs = ngx_pcalloc(cf->pool, stport->naddrs * sizeof(ngx_stream_in6_addr_t)); if (stport->addrs == NULL) { return NGX_ERROR; } addrs6 = stport->addrs; for (i = 0; i < stport->naddrs; i++) { sin6 = &addr[i].opt.u.sockaddr_in6; addrs6[i].addr6 = sin6->sin6_addr; addrs6[i].conf.ctx = addr[i].opt.ctx; #if (NGX_STREAM_SSL) addrs6[i].conf.ssl = addr[i].opt.ssl; #endif len = ngx_sock_ntop(&addr[i].opt.u.sockaddr, addr[i].opt.socklen, buf, NGX_SOCKADDR_STRLEN, 1); p = ngx_pnalloc(cf->pool, len); if (p == NULL) { return NGX_ERROR; } ngx_memcpy(p, buf, len); addrs6[i].conf.addr_text.len = len; addrs6[i].conf.addr_text.data = p; } return NGX_OK; } #endif static ngx_int_t ngx_stream_cmp_conf_addrs(const void *one, const void *two) { ngx_stream_conf_addr_t *first, *second; first = (ngx_stream_conf_addr_t *) one; second = (ngx_stream_conf_addr_t *) two; if (first->opt.wildcard) { /* a wildcard must be the last resort, shift it to the end */ return 1; } if (second->opt.wildcard) { /* a wildcard must be the last resort, shift it to the end */ return -1; } if (first->opt.bind && !second->opt.bind) { /* shift explicit bind()ed addresses to the start */ return -1; } if (!first->opt.bind && second->opt.bind) { /* shift explicit bind()ed addresses to the start */ return 1; } /* do not sort by default */ return 0; }