转载自 详解proxy_pass、upstream与resolver
应用场景
这里列举几个应用场景,下文会针对这几个场景并结合代码进行分析。
(1)proxy_pass + upstream
upstream foo.example.com {
server 127.0.0.1:8001;
}
server {
listen 80;
server_name localhost;
location /foo {
proxy_pass http://foo.example.com;
}
}
访问http://localhost/foo,proxy模块会将请求转发到127.0.0.1的8001端口上。
(2)只有proxy_pass,没有upstream与resolver
server {
listen 80;
server_name localhost;
location /foo {
proxy_pass http://foo.example.com;
}
}
实际上是隐式创建了upstream,upstream名字就是foo.example.com。upstream模块利用本机设置的DNS服务器(或/etc/hosts),将foo.example.com解析成IP,访问http://localhost/foo,proxy模块会将请求转发到解析后的IP上。
如果本机未设置DNS服务器,或者DNS服务器无法解析域名,则nginx启动时会报类似如下错误:
nginx: [emerg] host not found in upstream "foo.example.com" in /path/nginx/conf/nginx.conf:110
(3)proxy_pass + resolver(变量设置域名)
server {
listen 80;
server_name localhost;
resolver 114.114.114.114;
location /foo {
set $foo foo.example.com;
proxy_pass http://$foo;
}
}
访问http://localhost/foo,nginx会动态利用resolver设置的DNS服务器(本机设置的DNS服务器或/etc/hosts无效),将域名解析成IP,proxy模块会将请求转发到解析后的IP上。
(4)proxy_pass + upstream(显式) + resolver(变量设置域名)
upstream foo.example.com {
server 127.0.0.1:8001;
}
server {
listen 80;
server_name localhost;
resolver 114.114.114.114;
location /foo {
set $foo foo.example.com;
proxy_pass http://$foo;
}
}
访问http://localhost/foo时,upstream模块会优先查找是否有定义upstream后端服务器,如果有定义则直接利用,不再走DNS解析。所以proxy模块会将请求转发到127.0.0.1的8001端口上。
(5)proxy_pass + upstream(隐式) + resolver(变量设置域名)
server {
listen 80;
server_name localhost;
resolver 114.114.114.114;
location /foo {
set $foo foo.example.com;
proxy_pass http://$foo;
}
location /foo2 {
proxy_pass http://foo.example.com;
}
}
location /foo2实际上是隐式定义了upstream foo.example.com,并由本地DNS服务器进行了域名解析,访问http://localhost/foo时,upstream模块会优先查找upstream,即隐式定义的foo.example.com,proxy模块会将请求转发到解析后的IP上。
(6)proxy_pass + resolver(不用变量设置域名)
server {
listen 80;
server_name localhost;
resolver 114.114.114.114;
location /foo {
proxy_pass http://foo.example.com;
}
}
不使用变量设置域名,则resolver的设置不起作用,此时相当于场景2,只有proxy_pass的场景。
(7)proxy_pass + upstream + resolver(不用变量设置域名)
upstream foo.example.com {
server 127.0.0.1:8001;
}
server {
listen 80;
server_name localhost;
resolver 114.114.114.114;
location /foo {
proxy_pass http://foo.example.com;
}
}
不使用变量设置域名,则resolver的设置不起作用,此时相当于场景1 proxy_pass + upstream。
(8)proxy_pass 直接指定IP加端口号
server {
listen 80;
server_name localhost;
location /foo {
proxy_pass http://127.0.0.1:8001/;
}
}
实际上是隐式创建了upstream,proxy_pass会将请求转发到127.0.0.1的8001端口上。
主要代码
解析proxy_pass指令的代码:
static char *
ngx_http_proxy_pass(ngx_conf_t *cf, ngx_command_t *cmd, void *conf)
{
ngx_http_proxy_loc_conf_t *plcf = conf;
size_t add;
u_short port;
ngx_str_t *value, *url;
ngx_url_t u;
ngx_uint_t n;
ngx_http_core_loc_conf_t *clcf;
ngx_http_script_compile_t sc;
if (plcf->upstream.upstream || plcf->proxy_lengths) {
return "is duplicate";
}
clcf = ngx_http_conf_get_module_loc_conf(cf, ngx_http_core_module);
clcf->handler = ngx_http_proxy_handler;
if (clcf->name.data[clcf->name.len - 1] == '/') {
clcf->auto_redirect = 1;
}
value = cf->args->elts;
url = &value[1];
/* 查找指令中$符号的位置,判断是否使用了变量 */
n = ngx_http_script_variables_count(url);
if (n) {
/* 使用变量设置域名 */
ngx_memzero(&sc, sizeof(ngx_http_script_compile_t));
sc.cf = cf;
sc.source = url;
sc.lengths = &plcf->proxy_lengths;
sc.values = &plcf->proxy_values;
sc.variables = n;
sc.complete_lengths = 1;
sc.complete_values = 1;
if (ngx_http_script_compile(&sc) != NGX_OK) {
return NGX_CONF_ERROR;
}
#if (NGX_HTTP_SSL)
plcf->ssl = 1;
#endif
return NGX_CONF_OK;
}
if (ngx_strncasecmp(url->data, (u_char *) "http://", 7) == 0) {
add = 7;
port = 80;
} else if (ngx_strncasecmp(url->data, (u_char *) "https://", 8) == 0) {
#if (NGX_HTTP_SSL)
plcf->ssl = 1;
add = 8;
port = 443;
#else
ngx_conf_log_error(NGX_LOG_EMERG, cf, 0,
"https protocol requires SSL support");
return NGX_CONF_ERROR;
#endif
} else {
ngx_conf_log_error(NGX_LOG_EMERG, cf, 0, "invalid URL prefix");
return NGX_CONF_ERROR;
}
ngx_memzero(&u, sizeof(ngx_url_t));
u.url.len = url->len - add;
u.url.data = url->data + add;
u.default_port = port;
u.uri_part = 1;
u.no_resolve = 1;
plcf->upstream.upstream = ngx_http_upstream_add(cf, &u, 0);
if (plcf->upstream.upstream == NULL) {
return NGX_CONF_ERROR;
}
plcf->vars.schema.len = add;
plcf->vars.schema.data = url->data;
plcf->vars.key_start = plcf->vars.schema;
ngx_http_proxy_set_vars(&u, &plcf->vars);
plcf->location = clcf->name;
if (clcf->named
#if (NGX_PCRE)
|| clcf->regex
#endif
|| clcf->noname)
{
if (plcf->vars.uri.len) {
ngx_conf_log_error(NGX_LOG_EMERG, cf, 0,
"\"proxy_pass\" cannot have URI part in "
"location given by regular expression, "
"or inside named location, "
"or inside \"if\" statement, "
"or inside \"limit_except\" block");
return NGX_CONF_ERROR;
}
plcf->location.len = 0;
}
plcf->url = *url;
return NGX_CONF_OK;
}
upstream定义的后端服务器的处理逻辑,包括显式定义的和隐式定义的。隐式定义,即proxy_pass指定的后端服务器的地址没有显式用upstream定义,nginx内部会定义一个。
ngx_int_t
ngx_http_upstream_init_round_robin(ngx_conf_t *cf,
ngx_http_upstream_srv_conf_t *us)
{
ngx_url_t u;
ngx_uint_t i, j, n, w;
ngx_http_upstream_server_t *server;
ngx_http_upstream_rr_peer_t *peer, **peerp;
ngx_http_upstream_rr_peers_t *peers, *backup;
us->peer.init = ngx_http_upstream_init_round_robin_peer;
/*
* 使用upstream指令显式定义upstream
* 或者proxy_pass直接指定IP的场景
*/
if (us->servers) {
server = us->servers->elts;
n = 0;
w = 0;
for (i = 0; i < us->servers->nelts; i++) {
if (server[i].backup) {
continue;
}
n += server[i].naddrs;
w += server[i].naddrs * server[i].weight;
}
if (n == 0) {
ngx_log_error(NGX_LOG_EMERG, cf->log, 0,
"no servers in upstream \"%V\" in %s:%ui",
&us->host, us->file_name, us->line);
return NGX_ERROR;
}
peers = ngx_pcalloc(cf->pool, sizeof(ngx_http_upstream_rr_peers_t));
if (peers == NULL) {
return NGX_ERROR;
}
peer = ngx_pcalloc(cf->pool, sizeof(ngx_http_upstream_rr_peer_t) * n);
if (peer == NULL) {
return NGX_ERROR;
}
peers->single = (n == 1);
peers->number = n;
peers->weighted = (w != n);
peers->total_weight = w;
peers->name = &us->host;
n = 0;
peerp = &peers->peer;
for (i = 0; i < us->servers->nelts; i++) {
/* 设置sockaddr、weight、max_fails、fail_timeout等属性 */
}
us->peer.data = peers;
/* 处理backup servers相关逻辑 */
return NGX_OK;
}
/* 未使用upstream指令,使用proxy_pass隐式定义upstream */
/* an upstream implicitly defined by proxy_pass, etc. */
if (us->port == 0) {
ngx_log_error(NGX_LOG_EMERG, cf->log, 0,
"no port in upstream \"%V\" in %s:%ui",
&us->host, us->file_name, us->line);
return NGX_ERROR;
}
ngx_memzero(&u, sizeof(ngx_url_t));
u.host = us->host;
u.port = us->port;
if (ngx_inet_resolve_host(cf->pool, &u) != NGX_OK) {
if (u.err) {
ngx_log_error(NGX_LOG_EMERG, cf->log, 0,
"%s in upstream \"%V\" in %s:%ui",
u.err, &us->host, us->file_name, us->line);
}
return NGX_ERROR;
}
n = u.naddrs;
peers = ngx_pcalloc(cf->pool, sizeof(ngx_http_upstream_rr_peers_t));
if (peers == NULL) {
return NGX_ERROR;
}
peer = ngx_pcalloc(cf->pool, sizeof(ngx_http_upstream_rr_peer_t) * n);
if (peer == NULL) {
return NGX_ERROR;
}
peers->single = (n == 1);
peers->number = n;
peers->weighted = 0;
peers->total_weight = n;
peers->name = &us->host;
peerp = &peers->peer;
for (i = 0; i < u.naddrs; i++) {
/* 设置sockaddr、weight、max_fails、fail_timeout等属性 */
}
us->peer.data = peers;
/* implicitly defined upstream has no backup servers */
return NGX_OK;
}
upstream模块初始化请求时的逻辑:
static void
ngx_http_upstream_init_request(ngx_http_request_t *r)
{
ngx_str_t *host;
ngx_uint_t i;
ngx_resolver_ctx_t *ctx, temp;
ngx_http_cleanup_t *cln;
ngx_http_upstream_t *u;
ngx_http_core_loc_conf_t *clcf;
ngx_http_upstream_srv_conf_t *uscf, **uscfp;
ngx_http_upstream_main_conf_t *umcf;
if (r->aio) {
return;
}
u = r->upstream;
/* NGX_HTTP_CACHE 等其他处理 */
cln->handler = ngx_http_upstream_cleanup;
cln->data = r;
u->cleanup = &cln->handler;
if (u->resolved == NULL) {
/* 如果没有使用resolver设置DNS,直接取upstream的设置 */
uscf = u->conf->upstream;
} else {
#if (NGX_HTTP_SSL)
u->ssl_name = u->resolved->host;
#endif
host = &u->resolved->host;
if (u->resolved->sockaddr) {
if (u->resolved->port == 0
&& u->resolved->sockaddr->sa_family != AF_UNIX)
{
ngx_log_error(NGX_LOG_ERR, r->connection->log, 0,
"no port in upstream \"%V\"", host);
ngx_http_upstream_finalize_request(r, u,
NGX_HTTP_INTERNAL_SERVER_ERROR);
return;
}
if (ngx_http_upstream_create_round_robin_peer(r, u->resolved)
!= NGX_OK)
{
ngx_http_upstream_finalize_request(r, u,
NGX_HTTP_INTERNAL_SERVER_ERROR);
return;
}
ngx_http_upstream_connect(r, u);
return;
}
umcf = ngx_http_get_module_main_conf(r, ngx_http_upstream_module);
uscfp = umcf->upstreams.elts;
/* 在显式/隐式定义的upstream中查找 */
for (i = 0; i < umcf->upstreams.nelts; i++) {
uscf = uscfp[i];
if (uscf->host.len == host->len
&& ((uscf->port == 0 && u->resolved->no_port)
|| uscf->port == u->resolved->port)
&& ngx_strncasecmp(uscf->host.data, host->data, host->len) == 0)
{
goto found;
}
}
if (u->resolved->port == 0) {
ngx_log_error(NGX_LOG_ERR, r->connection->log, 0,
"no port in upstream \"%V\"", host);
ngx_http_upstream_finalize_request(r, u,
NGX_HTTP_INTERNAL_SERVER_ERROR);
return;
}
temp.name = *host;
ctx = ngx_resolve_start(clcf->resolver, &temp);
if (ctx == NULL) {
ngx_http_upstream_finalize_request(r, u,
NGX_HTTP_INTERNAL_SERVER_ERROR);
return;
}
if (ctx == NGX_NO_RESOLVER) {
ngx_log_error(NGX_LOG_ERR, r->connection->log, 0,
"no resolver defined to resolve %V", host);
ngx_http_upstream_finalize_request(r, u, NGX_HTTP_BAD_GATEWAY);
return;
}
ctx->name = *host;
ctx->handler = ngx_http_upstream_resolve_handler;
ctx->data = r;
ctx->timeout = clcf->resolver_timeout;
u->resolved->ctx = ctx;
if (ngx_resolve_name(ctx) != NGX_OK) {
u->resolved->ctx = NULL;
ngx_http_upstream_finalize_request(r, u,
NGX_HTTP_INTERNAL_SERVER_ERROR);
return;
}
return;
}
found:
if (uscf == NULL) {
ngx_log_error(NGX_LOG_ALERT, r->connection->log, 0,
"no upstream configuration");
ngx_http_upstream_finalize_request(r, u,
NGX_HTTP_INTERNAL_SERVER_ERROR);
return;
}
#if (NGX_HTTP_SSL)
u->ssl_name = uscf->host;
#endif
if (uscf->peer.init(r, uscf) != NGX_OK) {
ngx_http_upstream_finalize_request(r, u,
NGX_HTTP_INTERNAL_SERVER_ERROR);
return;
}
u->peer.start_time = ngx_current_msec;
if (u->conf->next_upstream_tries
&& u->peer.tries > u->conf->next_upstream_tries)
{
u->peer.tries = u->conf->next_upstream_tries;
}
ngx_http_upstream_connect(r, u);
}
详细分析
场景1
解析proxy_pass的函数ngx_http_proxy_pass中,没有找到$符号(即,变量设置域名),走ngx_http_proxy_pass后半部分的处理逻辑。ngx_http_upstream_init_round_robin初始化upstream时,走显式定义upstream的逻辑。proxy_pass转发请求初始化时,ngx_http_upstream_init_request中直接使用upstream中的后端server建立连接。
场景2
ngx_http_upstream_init_round_robin初始化upstream时,走隐式定义upstream的逻辑,会调用ngx_inet_resolve_host对proxy_pass中的域名进行解析,设置upstream。proxy_pass转发请求初始化时,ngx_http_upstream_init_request中直接使用upstream中的设置,也就是利用本地设置的DNS服务器解析出的IP,建立连接。
场景3
解析proxy_pass指令时,找到了$符号,设置ngx_http_script_compile_t,并利用ngx_http_script_compile进行编译,不走后半部分逻辑。配置文件没有显式/隐式定义upstream,所以不会调用ngx_http_upstream_init_round_robin方法。proxy_pass转发请求初始化时,ngx_http_upstream_init_request中发现没有显式也没有隐式定义的upstream,随后调用ngx_resolve_start,对域名进行解析,之后将请求转发过去。
场景4
解析proxy_pass指令时,找到了$符号,设置ngx_http_script_compile_t,并利用ngx_http_script_compile进行编译,不走后半部分逻辑。显式调用了upstream,所以调用ngx_http_upstream_init_round_robin方法中的显式upstream的处理逻辑。proxy_pass转发请求初始化时,ngx_http_upstream_init_request中优先查找upstream,如果找到了,直接将请求转发到upstream中的后端server上。如果upstream中没有找到,则对域名进行解析,然后将请求转发到解析后的IP上。
场景5
基本与场景4相同,不同之处在于调用ngx_http_upstream_init_round_robin方法时,走隐式upstream部分的处理逻辑。
场景6
与场景2相同。
场景7
与场景1相同。
场景8
实际上是隐式创建了upstream,但是因为proxy_pass中指定了IP和端口号,所以ngx_http_upstream_init_round_robin初始化upstream时,us->servers不为空,所以走该函数的上半部分逻辑。与场景1有些类似。
