/* Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. * The ASF licenses this file to You under the Apache License, Version 2.0 * (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* Utility routines for Apache proxy */ #include "mod_proxy.h" #include "ap_mpm.h" #include "scoreboard.h" #include "apr_version.h" #include "apr_strings.h" #include "apr_hash.h" #include "proxy_util.h" #include "ajp.h" #include "scgi.h" #include "mod_http2.h" /* for http2_get_num_workers() */ #if APR_HAVE_UNISTD_H #include /* for getpid() */ #endif #if APR_HAVE_SYS_UN_H #include #endif #if (APR_MAJOR_VERSION < 2) #include "apr_support.h" /* for apr_wait_for_io_or_timeout() */ #endif APLOG_USE_MODULE(proxy); /* * Opaque structure containing target server info when * using a forward proxy. * Up to now only used in combination with HTTP CONNECT. */ typedef struct { int use_http_connect; /* Use SSL Tunneling via HTTP CONNECT */ const char *target_host; /* Target hostname */ apr_port_t target_port; /* Target port */ const char *proxy_auth; /* Proxy authorization */ } forward_info; /* Global balancer counter */ int PROXY_DECLARE_DATA proxy_lb_workers = 0; static int lb_workers_limit = 0; const apr_strmatch_pattern PROXY_DECLARE_DATA *ap_proxy_strmatch_path; const apr_strmatch_pattern PROXY_DECLARE_DATA *ap_proxy_strmatch_domain; extern apr_global_mutex_t *proxy_mutex; static int proxy_match_ipaddr(struct dirconn_entry *This, request_rec *r); static int proxy_match_domainname(struct dirconn_entry *This, request_rec *r); static int proxy_match_hostname(struct dirconn_entry *This, request_rec *r); static int proxy_match_word(struct dirconn_entry *This, request_rec *r); static int ap_proxy_retry_worker(const char *proxy_function, proxy_worker *worker, server_rec *s); static proxy_worker *proxy_balancer_get_best_worker(proxy_balancer *balancer, request_rec *r, proxy_is_best_callback_fn_t *is_best, void *baton); APR_IMPLEMENT_OPTIONAL_HOOK_RUN_ALL(proxy, PROXY, int, create_req, (request_rec *r, request_rec *pr), (r, pr), OK, DECLINED) PROXY_DECLARE(apr_status_t) ap_proxy_strncpy(char *dst, const char *src, apr_size_t dlen) { char *thenil; apr_size_t thelen; /* special case handling */ if (!dlen) { /* XXX: APR_ENOSPACE would be better */ return APR_EGENERAL; } if (!src) { *dst = '\0'; return APR_SUCCESS; } thenil = apr_cpystrn(dst, src, dlen); thelen = thenil - dst; if (src[thelen] == '\0') { return APR_SUCCESS; } return APR_EGENERAL; } /* already called in the knowledge that the characters are hex digits */ PROXY_DECLARE(int) ap_proxy_hex2c(const char *x) { int i; #if !APR_CHARSET_EBCDIC int ch = x[0]; if (apr_isdigit(ch)) { i = ch - '0'; } else if (apr_isupper(ch)) { i = ch - ('A' - 10); } else { i = ch - ('a' - 10); } i <<= 4; ch = x[1]; if (apr_isdigit(ch)) { i += ch - '0'; } else if (apr_isupper(ch)) { i += ch - ('A' - 10); } else { i += ch - ('a' - 10); } return i; #else /*APR_CHARSET_EBCDIC*/ /* * we assume that the hex value refers to an ASCII character * so convert to EBCDIC so that it makes sense locally; * * example: * * client specifies %20 in URL to refer to a space char; * at this point we're called with EBCDIC "20"; after turning * EBCDIC "20" into binary 0x20, we then need to assume that 0x20 * represents an ASCII char and convert 0x20 to EBCDIC, yielding * 0x40 */ char buf[1]; if (1 == sscanf(x, "%2x", &i)) { buf[0] = i & 0xFF; ap_xlate_proto_from_ascii(buf, 1); return buf[0]; } else { return 0; } #endif /*APR_CHARSET_EBCDIC*/ } PROXY_DECLARE(void) ap_proxy_c2hex(int ch, char *x) { #if !APR_CHARSET_EBCDIC int i; x[0] = '%'; i = (ch & 0xF0) >> 4; if (i >= 10) { x[1] = ('A' - 10) + i; } else { x[1] = '0' + i; } i = ch & 0x0F; if (i >= 10) { x[2] = ('A' - 10) + i; } else { x[2] = '0' + i; } #else /*APR_CHARSET_EBCDIC*/ static const char ntoa[] = { "0123456789ABCDEF" }; char buf[1]; ch &= 0xFF; buf[0] = ch; ap_xlate_proto_to_ascii(buf, 1); x[0] = '%'; x[1] = ntoa[(buf[0] >> 4) & 0x0F]; x[2] = ntoa[buf[0] & 0x0F]; x[3] = '\0'; #endif /*APR_CHARSET_EBCDIC*/ } /* * canonicalise a URL-encoded string */ /* * Convert a URL-encoded string to canonical form. * It decodes characters which need not be encoded, * and encodes those which must be encoded, and does not touch * those which must not be touched. */ PROXY_DECLARE(char *)ap_proxy_canonenc(apr_pool_t *p, const char *x, int len, enum enctype t, int forcedec, int proxyreq) { int i, j, ch; char *y; char *allowed; /* characters which should not be encoded */ char *reserved; /* characters which much not be en/de-coded */ /* * N.B. in addition to :@&=, this allows ';' in an http path * and '?' in an ftp path -- this may be revised * * Also, it makes a '+' character in a search string reserved, as * it may be form-encoded. (Although RFC 1738 doesn't allow this - * it only permits ; / ? : @ = & as reserved chars.) */ if (t == enc_path) { allowed = "~$-_.+!*'(),;:@&="; } else if (t == enc_search) { allowed = "$-_.!*'(),;:@&="; } else if (t == enc_user) { allowed = "$-_.+!*'(),;@&="; } else if (t == enc_fpath) { allowed = "$-_.+!*'(),?:@&="; } else { /* if (t == enc_parm) */ allowed = "$-_.+!*'(),?/:@&="; } if (t == enc_path) { reserved = "/"; } else if (t == enc_search) { reserved = "+"; } else { reserved = ""; } y = apr_palloc(p, 3 * len + 1); for (i = 0, j = 0; i < len; i++, j++) { /* always handle '/' first */ ch = x[i]; if (strchr(reserved, ch)) { y[j] = ch; continue; } /* * decode it if not already done. do not decode reverse proxied URLs * unless specifically forced */ if ((forcedec || (proxyreq && proxyreq != PROXYREQ_REVERSE)) && ch == '%') { if (!apr_isxdigit(x[i + 1]) || !apr_isxdigit(x[i + 2])) { return NULL; } ch = ap_proxy_hex2c(&x[i + 1]); i += 2; if (ch != 0 && strchr(reserved, ch)) { /* keep it encoded */ ap_proxy_c2hex(ch, &y[j]); j += 2; continue; } } /* recode it, if necessary */ if (!apr_isalnum(ch) && !strchr(allowed, ch)) { ap_proxy_c2hex(ch, &y[j]); j += 2; } else { y[j] = ch; } } y[j] = '\0'; return y; } /* * Parses network-location. * urlp on input the URL; on output the path, after the leading / * user NULL if no user/password permitted * password holder for password * host holder for host * port port number; only set if one is supplied. * * Returns an error string. */ PROXY_DECLARE(char *) ap_proxy_canon_netloc(apr_pool_t *p, char **const urlp, char **userp, char **passwordp, char **hostp, apr_port_t *port) { char *addr, *scope_id, *strp, *host, *url = *urlp; char *user = NULL, *password = NULL; apr_port_t tmp_port; apr_status_t rv; if (url[0] != '/' || url[1] != '/') { return "Malformed URL"; } host = url + 2; url = strchr(host, '/'); if (url == NULL) { url = ""; } else { *(url++) = '\0'; /* skip separating '/' */ } /* find _last_ '@' since it might occur in user/password part */ strp = strrchr(host, '@'); if (strp != NULL) { *strp = '\0'; user = host; host = strp + 1; /* find password */ strp = strchr(user, ':'); if (strp != NULL) { *strp = '\0'; password = ap_proxy_canonenc(p, strp + 1, strlen(strp + 1), enc_user, 1, 0); if (password == NULL) { return "Bad %-escape in URL (password)"; } } user = ap_proxy_canonenc(p, user, strlen(user), enc_user, 1, 0); if (user == NULL) { return "Bad %-escape in URL (username)"; } } if (userp != NULL) { *userp = user; } if (passwordp != NULL) { *passwordp = password; } /* * Parse the host string to separate host portion from optional port. * Perform range checking on port. */ rv = apr_parse_addr_port(&addr, &scope_id, &tmp_port, host, p); if (rv != APR_SUCCESS || addr == NULL || scope_id != NULL) { return "Invalid host/port"; } if (tmp_port != 0) { /* only update caller's port if port was specified */ *port = tmp_port; } ap_str_tolower(addr); /* DNS names are case-insensitive */ *urlp = url; *hostp = addr; return NULL; } PROXY_DECLARE(int) ap_proxyerror(request_rec *r, int statuscode, const char *message) { apr_table_setn(r->notes, "error-notes", apr_pstrcat(r->pool, "The proxy server could not handle the request

" "Reason: ", ap_escape_html(r->pool, message), "

", NULL)); /* Allow "error-notes" string to be printed by ap_send_error_response() */ apr_table_setn(r->notes, "verbose-error-to", "*"); r->status_line = apr_psprintf(r->pool, "%3.3u Proxy Error", statuscode); ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, APLOGNO(00898) "%s returned by %s", message, r->uri); return statuscode; } static const char * proxy_get_host_of_request(request_rec *r) { char *url, *user = NULL, *password = NULL, *err, *host = NULL; apr_port_t port; if (r->hostname != NULL) { return r->hostname; } /* Set url to the first char after "scheme://" */ if ((url = strchr(r->uri, ':')) == NULL || url[1] != '/' || url[2] != '/') { return NULL; } url = apr_pstrdup(r->pool, &url[1]); /* make it point to "//", which is what proxy_canon_netloc expects */ err = ap_proxy_canon_netloc(r->pool, &url, &user, &password, &host, &port); if (err != NULL) { ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, APLOGNO(00899) "%s", err); } r->hostname = host; return host; /* ought to return the port, too */ } /* Return TRUE if addr represents an IP address (or an IP network address) */ PROXY_DECLARE(int) ap_proxy_is_ipaddr(struct dirconn_entry *This, apr_pool_t *p) { const char *addr = This->name; long ip_addr[4]; int i, quads; long bits; /* * if the address is given with an explicit netmask, use that * Due to a deficiency in apr_inet_addr(), it is impossible to parse * "partial" addresses (with less than 4 quads) correctly, i.e. * 192.168.123 is parsed as 192.168.0.123, which is not what I want. * I therefore have to parse the IP address manually: * if (proxy_readmask(This->name, &This->addr.s_addr, &This->mask.s_addr) == 0) * addr and mask were set by proxy_readmask() * return 1; */ /* * Parse IP addr manually, optionally allowing * abbreviated net addresses like 192.168. */ /* Iterate over up to 4 (dotted) quads. */ for (quads = 0; quads < 4 && *addr != '\0'; ++quads) { char *tmp; if (*addr == '/' && quads > 0) { /* netmask starts here. */ break; } if (!apr_isdigit(*addr)) { return 0; /* no digit at start of quad */ } ip_addr[quads] = strtol(addr, &tmp, 0); if (tmp == addr) { /* expected a digit, found something else */ return 0; } if (ip_addr[quads] < 0 || ip_addr[quads] > 255) { /* invalid octet */ return 0; } addr = tmp; if (*addr == '.' && quads != 3) { ++addr; /* after the 4th quad, a dot would be illegal */ } } for (This->addr.s_addr = 0, i = 0; i < quads; ++i) { This->addr.s_addr |= htonl(ip_addr[i] << (24 - 8 * i)); } if (addr[0] == '/' && apr_isdigit(addr[1])) { /* net mask follows: */ char *tmp; ++addr; bits = strtol(addr, &tmp, 0); if (tmp == addr) { /* expected a digit, found something else */ return 0; } addr = tmp; if (bits < 0 || bits > 32) { /* netmask must be between 0 and 32 */ return 0; } } else { /* * Determine (i.e., "guess") netmask by counting the * number of trailing .0's; reduce #quads appropriately * (so that 192.168.0.0 is equivalent to 192.168.) */ while (quads > 0 && ip_addr[quads - 1] == 0) { --quads; } /* "IP Address should be given in dotted-quad form, optionally followed by a netmask (e.g., 192.168.111.0/24)"; */ if (quads < 1) { return 0; } /* every zero-byte counts as 8 zero-bits */ bits = 8 * quads; if (bits != 32) { /* no warning for fully qualified IP address */ ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00900) "Warning: NetMask not supplied with IP-Addr; guessing: %s/%ld", inet_ntoa(This->addr), bits); } } This->mask.s_addr = htonl(APR_INADDR_NONE << (32 - bits)); if (*addr == '\0' && (This->addr.s_addr & ~This->mask.s_addr) != 0) { ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00901) "Warning: NetMask and IP-Addr disagree in %s/%ld", inet_ntoa(This->addr), bits); This->addr.s_addr &= This->mask.s_addr; ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00902) " Set to %s/%ld", inet_ntoa(This->addr), bits); } if (*addr == '\0') { This->matcher = proxy_match_ipaddr; return 1; } else { return (*addr == '\0'); /* okay iff we've parsed the whole string */ } } /* Return TRUE if addr represents an IP address (or an IP network address) */ static int proxy_match_ipaddr(struct dirconn_entry *This, request_rec *r) { int i, ip_addr[4]; struct in_addr addr, *ip; const char *host = proxy_get_host_of_request(r); if (host == NULL) { /* oops! */ return 0; } memset(&addr, '\0', sizeof addr); memset(ip_addr, '\0', sizeof ip_addr); if (4 == sscanf(host, "%d.%d.%d.%d", &ip_addr[0], &ip_addr[1], &ip_addr[2], &ip_addr[3])) { for (addr.s_addr = 0, i = 0; i < 4; ++i) { /* ap_proxy_is_ipaddr() already confirmed that we have * a valid octet in ip_addr[i] */ addr.s_addr |= htonl(ip_addr[i] << (24 - 8 * i)); } if (This->addr.s_addr == (addr.s_addr & This->mask.s_addr)) { #if DEBUGGING ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00903) "1)IP-Match: %s[%s] <-> ", host, inet_ntoa(addr)); ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00904) "%s/", inet_ntoa(This->addr)); ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00905) "%s", inet_ntoa(This->mask)); #endif return 1; } #if DEBUGGING else { ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00906) "1)IP-NoMatch: %s[%s] <-> ", host, inet_ntoa(addr)); ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00907) "%s/", inet_ntoa(This->addr)); ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00908) "%s", inet_ntoa(This->mask)); } #endif } else { struct apr_sockaddr_t *reqaddr; if (apr_sockaddr_info_get(&reqaddr, host, APR_UNSPEC, 0, 0, r->pool) != APR_SUCCESS) { #if DEBUGGING ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00909) "2)IP-NoMatch: hostname=%s msg=Host not found", host); #endif return 0; } /* Try to deal with multiple IP addr's for a host */ /* FIXME: This needs to be able to deal with IPv6 */ while (reqaddr) { ip = (struct in_addr *) reqaddr->ipaddr_ptr; if (This->addr.s_addr == (ip->s_addr & This->mask.s_addr)) { #if DEBUGGING ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00910) "3)IP-Match: %s[%s] <-> ", host, inet_ntoa(*ip)); ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00911) "%s/", inet_ntoa(This->addr)); ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00912) "%s", inet_ntoa(This->mask)); #endif return 1; } #if DEBUGGING else { ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00913) "3)IP-NoMatch: %s[%s] <-> ", host, inet_ntoa(*ip)); ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00914) "%s/", inet_ntoa(This->addr)); ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00915) "%s", inet_ntoa(This->mask)); } #endif reqaddr = reqaddr->next; } } return 0; } /* Return TRUE if addr represents a domain name */ PROXY_DECLARE(int) ap_proxy_is_domainname(struct dirconn_entry *This, apr_pool_t *p) { char *addr = This->name; int i; /* Domain name must start with a '.' */ if (addr[0] != '.') { return 0; } /* rfc1035 says DNS names must consist of "[-a-zA-Z0-9]" and '.' */ for (i = 0; apr_isalnum(addr[i]) || addr[i] == '-' || addr[i] == '.'; ++i) { continue; } #if 0 if (addr[i] == ':') { ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(03234) "@@@@ handle optional port in proxy_is_domainname()"); /* @@@@ handle optional port */ } #endif if (addr[i] != '\0') { return 0; } /* Strip trailing dots */ for (i = strlen(addr) - 1; i > 0 && addr[i] == '.'; --i) { addr[i] = '\0'; } This->matcher = proxy_match_domainname; return 1; } /* Return TRUE if host "host" is in domain "domain" */ static int proxy_match_domainname(struct dirconn_entry *This, request_rec *r) { const char *host = proxy_get_host_of_request(r); int d_len = strlen(This->name), h_len; if (host == NULL) { /* some error was logged already */ return 0; } h_len = strlen(host); /* @@@ do this within the setup? */ /* Ignore trailing dots in domain comparison: */ while (d_len > 0 && This->name[d_len - 1] == '.') { --d_len; } while (h_len > 0 && host[h_len - 1] == '.') { --h_len; } return h_len > d_len && strncasecmp(&host[h_len - d_len], This->name, d_len) == 0; } /* Return TRUE if host represents a host name */ PROXY_DECLARE(int) ap_proxy_is_hostname(struct dirconn_entry *This, apr_pool_t *p) { struct apr_sockaddr_t *addr; char *host = This->name; int i; /* Host names must not start with a '.' */ if (host[0] == '.') { return 0; } /* rfc1035 says DNS names must consist of "[-a-zA-Z0-9]" and '.' */ for (i = 0; apr_isalnum(host[i]) || host[i] == '-' || host[i] == '.'; ++i); if (host[i] != '\0' || apr_sockaddr_info_get(&addr, host, APR_UNSPEC, 0, 0, p) != APR_SUCCESS) { return 0; } This->hostaddr = addr; /* Strip trailing dots */ for (i = strlen(host) - 1; i > 0 && host[i] == '.'; --i) { host[i] = '\0'; } This->matcher = proxy_match_hostname; return 1; } /* Return TRUE if host "host" is equal to host2 "host2" */ static int proxy_match_hostname(struct dirconn_entry *This, request_rec *r) { char *host = This->name; const char *host2 = proxy_get_host_of_request(r); int h2_len; int h1_len; if (host == NULL || host2 == NULL) { return 0; /* oops! */ } h2_len = strlen(host2); h1_len = strlen(host); #if 0 struct apr_sockaddr_t *addr = *This->hostaddr; /* Try to deal with multiple IP addr's for a host */ while (addr) { if (addr->ipaddr_ptr == ? ? ? ? ? ? ? ? ? ? ? ? ?) return 1; addr = addr->next; } #endif /* Ignore trailing dots in host2 comparison: */ while (h2_len > 0 && host2[h2_len - 1] == '.') { --h2_len; } while (h1_len > 0 && host[h1_len - 1] == '.') { --h1_len; } return h1_len == h2_len && strncasecmp(host, host2, h1_len) == 0; } /* Return TRUE if addr is to be matched as a word */ PROXY_DECLARE(int) ap_proxy_is_word(struct dirconn_entry *This, apr_pool_t *p) { This->matcher = proxy_match_word; return 1; } /* Return TRUE if string "str2" occurs literally in "str1" */ static int proxy_match_word(struct dirconn_entry *This, request_rec *r) { const char *host = proxy_get_host_of_request(r); return host != NULL && ap_strstr_c(host, This->name) != NULL; } /* Backwards-compatible interface. */ PROXY_DECLARE(int) ap_proxy_checkproxyblock(request_rec *r, proxy_server_conf *conf, apr_sockaddr_t *uri_addr) { return ap_proxy_checkproxyblock2(r, conf, uri_addr->hostname, uri_addr); } #define MAX_IP_STR_LEN (46) PROXY_DECLARE(int) ap_proxy_checkproxyblock2(request_rec *r, proxy_server_conf *conf, const char *hostname, apr_sockaddr_t *addr) { int j; /* XXX FIXME: conf->noproxies->elts is part of an opaque structure */ for (j = 0; j < conf->noproxies->nelts; j++) { struct noproxy_entry *npent = (struct noproxy_entry *) conf->noproxies->elts; struct apr_sockaddr_t *conf_addr; ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "checking remote machine [%s] against [%s]", hostname, npent[j].name); if (ap_strstr_c(hostname, npent[j].name) || npent[j].name[0] == '*') { ap_log_rerror(APLOG_MARK, APLOG_WARNING, 0, r, APLOGNO(00916) "connect to remote machine %s blocked: name %s " "matched", hostname, npent[j].name); return HTTP_FORBIDDEN; } /* No IP address checks if no IP address was passed in, * i.e. the forward address proxy case, where this server does * not resolve the hostname. */ if (!addr) continue; for (conf_addr = npent[j].addr; conf_addr; conf_addr = conf_addr->next) { char caddr[MAX_IP_STR_LEN], uaddr[MAX_IP_STR_LEN]; apr_sockaddr_t *uri_addr; if (apr_sockaddr_ip_getbuf(caddr, sizeof caddr, conf_addr)) continue; for (uri_addr = addr; uri_addr; uri_addr = uri_addr->next) { if (apr_sockaddr_ip_getbuf(uaddr, sizeof uaddr, uri_addr)) continue; ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "ProxyBlock comparing %s and %s", caddr, uaddr); if (!strcmp(caddr, uaddr)) { ap_log_rerror(APLOG_MARK, APLOG_WARNING, 0, r, APLOGNO(00917) "connect to remote machine %s blocked: " "IP %s matched", hostname, caddr); return HTTP_FORBIDDEN; } } } } return OK; } /* set up the minimal filter set */ PROXY_DECLARE(int) ap_proxy_pre_http_request(conn_rec *c, request_rec *r) { ap_add_input_filter("HTTP_IN", NULL, r, c); return OK; } PROXY_DECLARE(const char *) ap_proxy_location_reverse_map(request_rec *r, proxy_dir_conf *conf, const char *url) { proxy_req_conf *rconf; struct proxy_alias *ent; int i, l1, l1_orig, l2; char *u; /* * XXX FIXME: Make sure this handled the ambiguous case of the : * after the hostname * XXX FIXME: Ensure the /uri component is a case sensitive match */ if (r->proxyreq != PROXYREQ_REVERSE) { return url; } l1_orig = strlen(url); if (conf->interpolate_env == 1) { rconf = ap_get_module_config(r->request_config, &proxy_module); ent = (struct proxy_alias *)rconf->raliases->elts; } else { ent = (struct proxy_alias *)conf->raliases->elts; } for (i = 0; i < conf->raliases->nelts; i++) { proxy_server_conf *sconf = (proxy_server_conf *) ap_get_module_config(r->server->module_config, &proxy_module); proxy_balancer *balancer; const char *real = ent[i].real; /* Restore the url length, if it had been changed by the code below */ l1 = l1_orig; /* * First check if mapping against a balancer and see * if we have such a entity. If so, then we need to * find the particulars of the actual worker which may * or may not be the right one... basically, we need * to find which member actually handled this request. */ if (ap_proxy_valid_balancer_name((char *)real, 0) && (balancer = ap_proxy_get_balancer(r->pool, sconf, real, 1))) { int n, l3 = 0; proxy_worker **worker = (proxy_worker **)balancer->workers->elts; const char *urlpart = ap_strchr_c(real + sizeof(BALANCER_PREFIX) - 1, '/'); if (urlpart) { if (!urlpart[1]) urlpart = NULL; else l3 = strlen(urlpart); } /* The balancer comparison is a bit trickier. Given the context * BalancerMember balancer://alias http://example.com/foo * ProxyPassReverse /bash balancer://alias/bar * translate url http://example.com/foo/bar/that to /bash/that */ for (n = 0; n < balancer->workers->nelts; n++) { l2 = strlen((*worker)->s->name_ex); if (urlpart) { /* urlpart (l3) assuredly starts with its own '/' */ if ((*worker)->s->name_ex[l2 - 1] == '/') --l2; if (l1 >= l2 + l3 && strncasecmp((*worker)->s->name_ex, url, l2) == 0 && strncmp(urlpart, url + l2, l3) == 0) { u = apr_pstrcat(r->pool, ent[i].fake, &url[l2 + l3], NULL); return ap_is_url(u) ? u : ap_construct_url(r->pool, u, r); } } else if (l1 >= l2 && strncasecmp((*worker)->s->name_ex, url, l2) == 0) { /* edge case where fake is just "/"... avoid double slash */ if ((ent[i].fake[0] == '/') && (ent[i].fake[1] == 0) && (url[l2] == '/')) { u = apr_pstrdup(r->pool, &url[l2]); } else { u = apr_pstrcat(r->pool, ent[i].fake, &url[l2], NULL); } return ap_is_url(u) ? u : ap_construct_url(r->pool, u, r); } worker++; } } else { const char *part = url; l2 = strlen(real); if (real[0] == '/') { part = ap_strstr_c(url, "://"); if (part) { part = ap_strchr_c(part+3, '/'); if (part) { l1 = strlen(part); } else { part = url; } } else { part = url; } } if (l2 > 0 && l1 >= l2 && strncasecmp(real, part, l2) == 0) { u = apr_pstrcat(r->pool, ent[i].fake, &part[l2], NULL); return ap_is_url(u) ? u : ap_construct_url(r->pool, u, r); } } } return url; } /* * Cookies are a bit trickier to match: we've got two substrings to worry * about, and we can't just find them with strstr 'cos of case. Regexp * matching would be an easy fix, but for better consistency with all the * other matches we'll refrain and use apr_strmatch to find path=/domain= * and stick to plain strings for the config values. */ PROXY_DECLARE(const char *) ap_proxy_cookie_reverse_map(request_rec *r, proxy_dir_conf *conf, const char *str) { proxy_req_conf *rconf = ap_get_module_config(r->request_config, &proxy_module); struct proxy_alias *ent; apr_size_t len = strlen(str); const char *newpath = NULL; const char *newdomain = NULL; const char *pathp; const char *domainp; const char *pathe = NULL; const char *domaine = NULL; apr_size_t l1, l2, poffs = 0, doffs = 0; int i; int ddiff = 0; int pdiff = 0; char *tmpstr, *tmpstr_orig, *token, *last, *ret; if (r->proxyreq != PROXYREQ_REVERSE) { return str; } /* * Find the match and replacement, but save replacing until we've done * both path and domain so we know the new strlen */ tmpstr_orig = tmpstr = apr_pstrdup(r->pool, str); while ((token = apr_strtok(tmpstr, ";", &last))) { /* skip leading spaces */ while (apr_isspace(*token)) { ++token; } if (ap_cstr_casecmpn("path=", token, 5) == 0) { pathp = token + 5; poffs = pathp - tmpstr_orig; l1 = strlen(pathp); pathe = str + poffs + l1; if (conf->interpolate_env == 1) { ent = (struct proxy_alias *)rconf->cookie_paths->elts; } else { ent = (struct proxy_alias *)conf->cookie_paths->elts; } for (i = 0; i < conf->cookie_paths->nelts; i++) { l2 = strlen(ent[i].fake); if (l1 >= l2 && strncmp(ent[i].fake, pathp, l2) == 0) { newpath = ent[i].real; pdiff = strlen(newpath) - l1; break; } } } else if (ap_cstr_casecmpn("domain=", token, 7) == 0) { domainp = token + 7; doffs = domainp - tmpstr_orig; l1 = strlen(domainp); domaine = str + doffs + l1; if (conf->interpolate_env == 1) { ent = (struct proxy_alias *)rconf->cookie_domains->elts; } else { ent = (struct proxy_alias *)conf->cookie_domains->elts; } for (i = 0; i < conf->cookie_domains->nelts; i++) { l2 = strlen(ent[i].fake); if (l1 >= l2 && strncasecmp(ent[i].fake, domainp, l2) == 0) { newdomain = ent[i].real; ddiff = strlen(newdomain) - l1; break; } } } /* Iterate the remaining tokens using apr_strtok(NULL, ...) */ tmpstr = NULL; } if (newpath) { ret = apr_palloc(r->pool, len + pdiff + ddiff + 1); l1 = strlen(newpath); if (newdomain) { l2 = strlen(newdomain); if (doffs > poffs) { memcpy(ret, str, poffs); memcpy(ret + poffs, newpath, l1); memcpy(ret + poffs + l1, pathe, str + doffs - pathe); memcpy(ret + doffs + pdiff, newdomain, l2); strcpy(ret + doffs + pdiff + l2, domaine); } else { memcpy(ret, str, doffs) ; memcpy(ret + doffs, newdomain, l2); memcpy(ret + doffs + l2, domaine, str + poffs - domaine); memcpy(ret + poffs + ddiff, newpath, l1); strcpy(ret + poffs + ddiff + l1, pathe); } } else { memcpy(ret, str, poffs); memcpy(ret + poffs, newpath, l1); strcpy(ret + poffs + l1, pathe); } } else if (newdomain) { ret = apr_palloc(r->pool, len + ddiff + 1); l2 = strlen(newdomain); memcpy(ret, str, doffs); memcpy(ret + doffs, newdomain, l2); strcpy(ret + doffs + l2, domaine); } else { ret = (char *)str; /* no change */ } return ret; } /* * BALANCER related... */ /* * verifies that the balancer name conforms to standards. */ PROXY_DECLARE(int) ap_proxy_valid_balancer_name(char *name, int i) { if (!i) i = sizeof(BALANCER_PREFIX)-1; return (!ap_cstr_casecmpn(name, BALANCER_PREFIX, i)); } PROXY_DECLARE(proxy_balancer *) ap_proxy_get_balancer(apr_pool_t *p, proxy_server_conf *conf, const char *url, int care) { proxy_balancer *balancer; char *c, *uri = apr_pstrdup(p, url); int i; proxy_hashes hash; c = strchr(uri, ':'); if (c == NULL || c[1] != '/' || c[2] != '/' || c[3] == '\0') { return NULL; } /* remove path from uri */ if ((c = strchr(c + 3, '/'))) { *c = '\0'; } ap_str_tolower(uri); hash.def = ap_proxy_hashfunc(uri, PROXY_HASHFUNC_DEFAULT); hash.fnv = ap_proxy_hashfunc(uri, PROXY_HASHFUNC_FNV); balancer = (proxy_balancer *)conf->balancers->elts; for (i = 0; i < conf->balancers->nelts; i++) { if (balancer->hash.def == hash.def && balancer->hash.fnv == hash.fnv) { if (!care || !balancer->s->inactive) { return balancer; } } balancer++; } return NULL; } PROXY_DECLARE(char *) ap_proxy_update_balancer(apr_pool_t *p, proxy_balancer *balancer, const char *url) { apr_uri_t puri; if (!url) { return NULL; } if (apr_uri_parse(p, url, &puri) != APR_SUCCESS) { return apr_psprintf(p, "unable to parse: %s", url); } if (puri.path && PROXY_STRNCPY(balancer->s->vpath, puri.path) != APR_SUCCESS) { return apr_psprintf(p, "balancer %s front-end virtual-path (%s) too long", balancer->s->name, puri.path); } if (puri.hostname && PROXY_STRNCPY(balancer->s->vhost, puri.hostname) != APR_SUCCESS) { return apr_psprintf(p, "balancer %s front-end vhost name (%s) too long", balancer->s->name, puri.hostname); } return NULL; } #define PROXY_UNSET_NONCE '\n' PROXY_DECLARE(char *) ap_proxy_define_balancer(apr_pool_t *p, proxy_balancer **balancer, proxy_server_conf *conf, const char *url, const char *alias, int do_malloc) { proxy_balancer_method *lbmethod; proxy_balancer_shared *bshared; char *c, *q, *uri = apr_pstrdup(p, url); const char *sname; /* We should never get here without a valid BALANCER_PREFIX... */ c = strchr(uri, ':'); if (c == NULL || c[1] != '/' || c[2] != '/' || c[3] == '\0') return apr_psprintf(p, "Bad syntax for a balancer name (%s)", uri); /* remove path from uri */ if ((q = strchr(c + 3, '/'))) *q = '\0'; ap_str_tolower(uri); *balancer = apr_array_push(conf->balancers); memset(*balancer, 0, sizeof(proxy_balancer)); /* * NOTE: The default method is byrequests - if it doesn't * exist, that's OK at this time. We check when we share and sync */ lbmethod = ap_lookup_provider(PROXY_LBMETHOD, "byrequests", "0"); (*balancer)->lbmethod = lbmethod; (*balancer)->workers = apr_array_make(p, 5, sizeof(proxy_worker *)); #if APR_HAS_THREADS (*balancer)->gmutex = NULL; (*balancer)->tmutex = NULL; #endif if (do_malloc) bshared = ap_malloc(sizeof(proxy_balancer_shared)); else bshared = apr_palloc(p, sizeof(proxy_balancer_shared)); memset(bshared, 0, sizeof(proxy_balancer_shared)); bshared->was_malloced = (do_malloc != 0); PROXY_STRNCPY(bshared->lbpname, "byrequests"); if (PROXY_STRNCPY(bshared->name, uri) != APR_SUCCESS) { if (do_malloc) free(bshared); return apr_psprintf(p, "balancer name (%s) too long", uri); } (*balancer)->lbmethod_set = 1; /* * We do the below for verification. The real sname will be * done post_config */ ap_pstr2_alnum(p, bshared->name + sizeof(BALANCER_PREFIX) - 1, &sname); sname = apr_pstrcat(p, conf->id, "_", sname, NULL); if (PROXY_STRNCPY(bshared->sname, sname) != APR_SUCCESS) { if (do_malloc) free(bshared); return apr_psprintf(p, "balancer safe-name (%s) too long", sname); } bshared->hash.def = ap_proxy_hashfunc(bshared->name, PROXY_HASHFUNC_DEFAULT); bshared->hash.fnv = ap_proxy_hashfunc(bshared->name, PROXY_HASHFUNC_FNV); (*balancer)->hash = bshared->hash; bshared->forcerecovery = 1; bshared->sticky_separator = '.'; *bshared->nonce = PROXY_UNSET_NONCE; /* impossible valid input */ (*balancer)->s = bshared; (*balancer)->sconf = conf; return ap_proxy_update_balancer(p, *balancer, alias); } /* * Create an already defined balancer and free up memory. */ PROXY_DECLARE(apr_status_t) ap_proxy_share_balancer(proxy_balancer *balancer, proxy_balancer_shared *shm, int i) { apr_status_t rv = APR_SUCCESS; proxy_balancer_method *lbmethod; char *action = "copying"; if (!shm || !balancer->s) return APR_EINVAL; if ((balancer->s->hash.def != shm->hash.def) || (balancer->s->hash.fnv != shm->hash.fnv)) { memcpy(shm, balancer->s, sizeof(proxy_balancer_shared)); if (balancer->s->was_malloced) free(balancer->s); } else { action = "re-using"; } balancer->s = shm; balancer->s->index = i; ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, ap_server_conf, APLOGNO(02337) "%s shm[%d] (0x%pp) for %s", action, i, (void *)shm, balancer->s->name); /* the below should always succeed */ lbmethod = ap_lookup_provider(PROXY_LBMETHOD, balancer->s->lbpname, "0"); if (lbmethod) { balancer->lbmethod = lbmethod; balancer->lbmethod_set = 1; } else { ap_log_error(APLOG_MARK, APLOG_CRIT, 0, ap_server_conf, APLOGNO(02432) "Cannot find LB Method: %s", balancer->s->lbpname); return APR_EINVAL; } if (*balancer->s->nonce == PROXY_UNSET_NONCE) { char nonce[APR_UUID_FORMATTED_LENGTH + 1]; apr_uuid_t uuid; /* Generate a pseudo-UUID from the PRNG to use as a nonce for * the lifetime of the process. uuid.data is a char array so * this is an adequate substitute for apr_uuid_get(). */ ap_random_insecure_bytes(uuid.data, sizeof uuid.data); apr_uuid_format(nonce, &uuid); rv = PROXY_STRNCPY(balancer->s->nonce, nonce); } return rv; } PROXY_DECLARE(apr_status_t) ap_proxy_initialize_balancer(proxy_balancer *balancer, server_rec *s, apr_pool_t *p) { #if APR_HAS_THREADS apr_status_t rv = APR_SUCCESS; #endif ap_slotmem_provider_t *storage = balancer->storage; apr_size_t size; unsigned int num; if (!storage) { ap_log_error(APLOG_MARK, APLOG_CRIT, 0, s, APLOGNO(00918) "no provider for %s", balancer->s->name); return APR_EGENERAL; } /* * for each balancer we need to init the global * mutex and then attach to the shared worker shm */ if (!balancer->gmutex) { ap_log_error(APLOG_MARK, APLOG_CRIT, 0, s, APLOGNO(00919) "no mutex %s", balancer->s->name); return APR_EGENERAL; } /* Re-open the mutex for the child. */ rv = apr_global_mutex_child_init(&(balancer->gmutex), apr_global_mutex_lockfile(balancer->gmutex), p); if (rv != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_CRIT, rv, s, APLOGNO(00920) "Failed to reopen mutex %s in child", balancer->s->name); return rv; } /* now attach */ storage->attach(&(balancer->wslot), balancer->s->sname, &size, &num, p); if (!balancer->wslot) { ap_log_error(APLOG_MARK, APLOG_CRIT, 0, s, APLOGNO(00921) "slotmem_attach failed"); return APR_EGENERAL; } if (balancer->lbmethod && balancer->lbmethod->reset) balancer->lbmethod->reset(balancer, s); #if APR_HAS_THREADS if (balancer->tmutex == NULL) { rv = apr_thread_mutex_create(&(balancer->tmutex), APR_THREAD_MUTEX_DEFAULT, p); if (rv != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_CRIT, 0, s, APLOGNO(00922) "can not create balancer thread mutex"); return rv; } } #endif return APR_SUCCESS; } static proxy_worker *proxy_balancer_get_best_worker(proxy_balancer *balancer, request_rec *r, proxy_is_best_callback_fn_t *is_best, void *baton) { int i = 0; int cur_lbset = 0; int max_lbset = 0; int unusable_workers = 0; apr_pool_t *tpool = NULL; apr_array_header_t *spares = NULL; apr_array_header_t *standbys = NULL; proxy_worker *worker = NULL; proxy_worker *best_worker = NULL; ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, r->server, APLOGNO(10122) "proxy: Entering %s for BALANCER (%s)", balancer->lbmethod->name, balancer->s->name); apr_pool_create(&tpool, r->pool); apr_pool_tag(tpool, "proxy_lb_best"); spares = apr_array_make(tpool, 1, sizeof(proxy_worker*)); standbys = apr_array_make(tpool, 1, sizeof(proxy_worker*)); /* Process lbsets in order, only replacing unusable workers in a given lbset * with available spares from the same lbset. Hot standbys will be used as a * last resort when all other workers and spares are unavailable. */ for (cur_lbset = 0; !best_worker && (cur_lbset <= max_lbset); cur_lbset++) { unusable_workers = 0; apr_array_clear(spares); apr_array_clear(standbys); for (i = 0; i < balancer->workers->nelts; i++) { worker = APR_ARRAY_IDX(balancer->workers, i, proxy_worker *); if (worker->s->lbset > max_lbset) { max_lbset = worker->s->lbset; } if (worker->s->lbset != cur_lbset) { continue; } /* A draining worker that is neither a spare nor a standby should be * considered unusable to be replaced by spares. */ if (PROXY_WORKER_IS_DRAINING(worker)) { if (!PROXY_WORKER_IS_SPARE(worker) && !PROXY_WORKER_IS_STANDBY(worker)) { unusable_workers++; } continue; } /* If the worker is in error state run retry on that worker. It will * be marked as operational if the retry timeout is elapsed. The * worker might still be unusable, but we try anyway. */ if (!PROXY_WORKER_IS_USABLE(worker)) { ap_proxy_retry_worker("BALANCER", worker, r->server); } if (PROXY_WORKER_IS_SPARE(worker)) { if (PROXY_WORKER_IS_USABLE(worker)) { APR_ARRAY_PUSH(spares, proxy_worker *) = worker; } } else if (PROXY_WORKER_IS_STANDBY(worker)) { if (PROXY_WORKER_IS_USABLE(worker)) { APR_ARRAY_PUSH(standbys, proxy_worker *) = worker; } } else if (PROXY_WORKER_IS_USABLE(worker)) { if (is_best(worker, best_worker, baton)) { best_worker = worker; } } else { unusable_workers++; } } /* Check if any spares are best. */ for (i = 0; (i < spares->nelts) && (i < unusable_workers); i++) { worker = APR_ARRAY_IDX(spares, i, proxy_worker *); if (is_best(worker, best_worker, baton)) { best_worker = worker; } } /* If no workers are available, use the standbys. */ if (!best_worker) { for (i = 0; i < standbys->nelts; i++) { worker = APR_ARRAY_IDX(standbys, i, proxy_worker *); if (is_best(worker, best_worker, baton)) { best_worker = worker; } } } } apr_pool_destroy(tpool); if (best_worker) { ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, r->server, APLOGNO(10123) "proxy: %s selected worker \"%s\" : busy %" APR_SIZE_T_FMT " : lbstatus %d", balancer->lbmethod->name, best_worker->s->name_ex, best_worker->s->busy, best_worker->s->lbstatus); } return best_worker; } PROXY_DECLARE(proxy_worker *) ap_proxy_balancer_get_best_worker(proxy_balancer *balancer, request_rec *r, proxy_is_best_callback_fn_t *is_best, void *baton) { return proxy_balancer_get_best_worker(balancer, r, is_best, baton); } /* * CONNECTION related... */ static void socket_cleanup(proxy_conn_rec *conn) { conn->sock = NULL; conn->tmp_bb = NULL; conn->connection = NULL; conn->ssl_hostname = NULL; apr_pool_clear(conn->scpool); } static apr_status_t conn_pool_cleanup(void *theworker) { ((proxy_worker *)theworker)->cp = NULL; return APR_SUCCESS; } static void init_conn_pool(apr_pool_t *p, proxy_worker *worker) { apr_pool_t *pool; apr_pool_t *dns_pool; proxy_conn_pool *cp; /* * Create a connection pool's subpool. * This pool is used for connection recycling. * Once the worker is added it is never removed but * it can be disabled. */ apr_pool_create(&pool, p); apr_pool_tag(pool, "proxy_worker_cp"); /* * Create a subpool of the connection pool for worker * scoped DNS resolutions. This is needed to avoid race * conditions in using the connection pool by multiple * threads during ramp up. */ apr_pool_create(&dns_pool, pool); apr_pool_tag(dns_pool, "proxy_worker_dns"); /* * Alloc from the same pool as worker. * proxy_conn_pool is permanently attached to the worker. */ cp = (proxy_conn_pool *)apr_pcalloc(p, sizeof(proxy_conn_pool)); cp->pool = pool; cp->dns_pool = dns_pool; worker->cp = cp; apr_pool_pre_cleanup_register(p, worker, conn_pool_cleanup); } PROXY_DECLARE(int) ap_proxy_connection_reusable(proxy_conn_rec *conn) { proxy_worker *worker = conn->worker; return ! (conn->close || !worker->s->is_address_reusable || worker->s->disablereuse); } static apr_status_t connection_cleanup(void *theconn) { proxy_conn_rec *conn = (proxy_conn_rec *)theconn; proxy_worker *worker = conn->worker; if (conn->r) { apr_pool_destroy(conn->r->pool); conn->r = NULL; } /* Sanity check: Did we already return the pooled connection? */ if (conn->inreslist) { ap_log_perror(APLOG_MARK, APLOG_ERR, 0, conn->pool, APLOGNO(00923) "Pooled connection 0x%pp for worker %s has been" " already returned to the connection pool.", conn, ap_proxy_worker_name(conn->pool, worker)); return APR_SUCCESS; } /* determine if the connection need to be closed */ if (!worker->s->is_address_reusable || worker->s->disablereuse) { apr_pool_t *p = conn->pool; apr_pool_clear(p); conn = apr_pcalloc(p, sizeof(proxy_conn_rec)); conn->pool = p; conn->worker = worker; apr_pool_create(&(conn->scpool), p); apr_pool_tag(conn->scpool, "proxy_conn_scpool"); } else if (conn->close || (conn->connection && conn->connection->keepalive == AP_CONN_CLOSE)) { socket_cleanup(conn); conn->close = 0; } else if (conn->is_ssl) { /* Unbind/reset the SSL connection dir config (sslconn->dc) from * r->per_dir_config, r will likely get destroyed before this proxy * conn is reused. */ ap_proxy_ssl_engine(conn->connection, worker->section_config, 1); } if (worker->s->hmax && worker->cp->res) { conn->inreslist = 1; apr_reslist_release(worker->cp->res, (void *)conn); } else { worker->cp->conn = conn; } /* Always return the SUCCESS */ return APR_SUCCESS; } /* DEPRECATED */ PROXY_DECLARE(apr_status_t) ap_proxy_ssl_connection_cleanup(proxy_conn_rec *conn, request_rec *r) { apr_status_t rv; /* * If we have an existing SSL connection it might be possible that the * server sent some SSL message we have not read so far (e.g. an SSL * shutdown message if the server closed the keepalive connection while * the connection was held unused in our pool). * So ensure that if present (=> APR_NONBLOCK_READ) it is read and * processed. We don't expect any data to be in the returned brigade. */ if (conn->sock && conn->connection) { rv = ap_get_brigade(conn->connection->input_filters, conn->tmp_bb, AP_MODE_READBYTES, APR_NONBLOCK_READ, HUGE_STRING_LEN); if (!APR_BRIGADE_EMPTY(conn->tmp_bb)) { apr_off_t len; rv = apr_brigade_length(conn->tmp_bb, 0, &len); ap_log_rerror(APLOG_MARK, APLOG_TRACE3, rv, r, "SSL cleanup brigade contained %" APR_OFF_T_FMT " bytes of data.", len); apr_brigade_cleanup(conn->tmp_bb); } if ((rv != APR_SUCCESS) && !APR_STATUS_IS_EAGAIN(rv)) { socket_cleanup(conn); } } return APR_SUCCESS; } /* reslist constructor */ static apr_status_t connection_constructor(void **resource, void *params, apr_pool_t *pool) { apr_pool_t *ctx; apr_pool_t *scpool; proxy_conn_rec *conn; proxy_worker *worker = (proxy_worker *)params; /* * Create the subpool for each connection * This keeps the memory consumption constant * when disconnecting from backend. */ apr_pool_create(&ctx, pool); apr_pool_tag(ctx, "proxy_conn_pool"); /* * Create another subpool that manages the data for the * socket and the connection member of the proxy_conn_rec struct as we * destroy this data more frequently than other data in the proxy_conn_rec * struct like hostname and addr (at least in the case where we have * keepalive connections that timed out). */ apr_pool_create(&scpool, ctx); apr_pool_tag(scpool, "proxy_conn_scpool"); conn = apr_pcalloc(ctx, sizeof(proxy_conn_rec)); conn->pool = ctx; conn->scpool = scpool; conn->worker = worker; conn->inreslist = 1; *resource = conn; return APR_SUCCESS; } /* reslist destructor */ static apr_status_t connection_destructor(void *resource, void *params, apr_pool_t *pool) { proxy_worker *worker = params; /* Destroy the pool only if not called from reslist_destroy */ if (worker->cp) { proxy_conn_rec *conn = resource; apr_pool_destroy(conn->pool); } return APR_SUCCESS; } /* * WORKER related... */ PROXY_DECLARE(char *) ap_proxy_worker_name(apr_pool_t *p, proxy_worker *worker) { if (!(*worker->s->uds_path) || !p) { /* just in case */ return worker->s->name_ex; } return apr_pstrcat(p, "unix:", worker->s->uds_path, "|", worker->s->name_ex, NULL); } PROXY_DECLARE(int) ap_proxy_worker_can_upgrade(apr_pool_t *p, const proxy_worker *worker, const char *upgrade, const char *dflt) { /* Find in worker->s->upgrade list (if any) */ const char *worker_upgrade = worker->s->upgrade; if (*worker_upgrade) { return (strcmp(worker_upgrade, "*") == 0 || ap_cstr_casecmp(worker_upgrade, upgrade) == 0 || ap_find_token(p, worker_upgrade, upgrade)); } /* Compare to the provided default (if any) */ return (dflt && ap_cstr_casecmp(dflt, upgrade) == 0); } /* * Taken from ap_strcmp_match() : * Match = 0, NoMatch = 1, Abort = -1, Inval = -2 * Based loosely on sections of wildmat.c by Rich Salz * Hmmm... shouldn't this really go component by component? * * Adds handling of the "\" => "" unescaping. */ static int ap_proxy_strcmp_ematch(const char *str, const char *expected) { apr_size_t x, y; for (x = 0, y = 0; expected[y]; ++y, ++x) { if (expected[y] == '$' && apr_isdigit(expected[y + 1])) { do { y += 2; } while (expected[y] == '$' && apr_isdigit(expected[y + 1])); if (!expected[y]) return 0; while (str[x]) { int ret; if ((ret = ap_proxy_strcmp_ematch(&str[x++], &expected[y])) != 1) return ret; } return -1; } else if (!str[x]) { return -1; } else if (expected[y] == '\\' && !expected[++y]) { /* NUL is an invalid char! */ return -2; } if (str[x] != expected[y]) return 1; } /* We got all the way through the worker path without a difference */ return 0; } PROXY_DECLARE(proxy_worker *) ap_proxy_get_worker_ex(apr_pool_t *p, proxy_balancer *balancer, proxy_server_conf *conf, const char *url, unsigned int mask) { proxy_worker *worker; proxy_worker *max_worker = NULL; int max_match = 0; int url_length; int min_match; int worker_name_length; const char *c; char *url_copy; int i; if (!url) { return NULL; } if (!(mask & AP_PROXY_WORKER_NO_UDS)) { url = ap_proxy_de_socketfy(p, url); if (!url) { return NULL; } } c = ap_strchr_c(url, ':'); if (c == NULL || c[1] != '/' || c[2] != '/' || c[3] == '\0') { return NULL; } url_length = strlen(url); url_copy = apr_pstrmemdup(p, url, url_length); /* Default to lookup for both _PREFIX and _MATCH workers */ if (!(mask & (AP_PROXY_WORKER_IS_PREFIX | AP_PROXY_WORKER_IS_MATCH))) { mask |= AP_PROXY_WORKER_IS_PREFIX | AP_PROXY_WORKER_IS_MATCH; } /* * We need to find the start of the path and * therefore we know the length of the scheme://hostname/ * part to we can force-lowercase everything up to * the start of the path. */ c = ap_strchr_c(c+3, '/'); if (c) { char *pathstart; pathstart = url_copy + (c - url); *pathstart = '\0'; ap_str_tolower(url_copy); min_match = strlen(url_copy); *pathstart = '/'; } else { ap_str_tolower(url_copy); min_match = strlen(url_copy); } /* * Do a "longest match" on the worker name to find the worker that * fits best to the URL, but keep in mind that we must have at least * a minimum matching of length min_match such that * scheme://hostname[:port] matches between worker and url. */ if (balancer) { proxy_worker **workers = (proxy_worker **)balancer->workers->elts; for (i = 0; i < balancer->workers->nelts; i++, workers++) { worker = *workers; if ( ((worker_name_length = strlen(worker->s->name_ex)) <= url_length) && (worker_name_length >= min_match) && (worker_name_length > max_match) && (worker->s->is_name_matchable || ((mask & AP_PROXY_WORKER_IS_PREFIX) && strncmp(url_copy, worker->s->name_ex, worker_name_length) == 0)) && (!worker->s->is_name_matchable || ((mask & AP_PROXY_WORKER_IS_MATCH) && ap_proxy_strcmp_ematch(url_copy, worker->s->name_ex) == 0)) ) { max_worker = worker; max_match = worker_name_length; } } } else { worker = (proxy_worker *)conf->workers->elts; for (i = 0; i < conf->workers->nelts; i++, worker++) { if ( ((worker_name_length = strlen(worker->s->name_ex)) <= url_length) && (worker_name_length >= min_match) && (worker_name_length > max_match) && (worker->s->is_name_matchable || ((mask & AP_PROXY_WORKER_IS_PREFIX) && strncmp(url_copy, worker->s->name_ex, worker_name_length) == 0)) && (!worker->s->is_name_matchable || ((mask & AP_PROXY_WORKER_IS_MATCH) && ap_proxy_strcmp_ematch(url_copy, worker->s->name_ex) == 0)) ) { max_worker = worker; max_match = worker_name_length; } } } return max_worker; } PROXY_DECLARE(proxy_worker *) ap_proxy_get_worker(apr_pool_t *p, proxy_balancer *balancer, proxy_server_conf *conf, const char *url) { return ap_proxy_get_worker_ex(p, balancer, conf, url, 0); } /* * To create a worker from scratch first we define the * specifics of the worker; this is all local data. * We then allocate space for it if data needs to be * shared. This allows for dynamic addition during * config and runtime. */ PROXY_DECLARE(char *) ap_proxy_define_worker_ex(apr_pool_t *p, proxy_worker **worker, proxy_balancer *balancer, proxy_server_conf *conf, const char *url, unsigned int mask) { apr_status_t rv; proxy_worker_shared *wshared; const char *ptr = NULL, *sockpath = NULL, *pdollars = NULL; apr_port_t port_of_scheme; apr_uri_t uri; /* * Look to see if we are using UDS: * require format: unix:/path/foo/bar.sock|http://ignored/path2/ * This results in talking http to the socket at /path/foo/bar.sock */ if (!ap_cstr_casecmpn(url, "unix:", 5) && (ptr = ap_strchr_c(url + 5, '|'))) { rv = apr_uri_parse(p, apr_pstrmemdup(p, url, ptr - url), &uri); if (rv == APR_SUCCESS) { sockpath = ap_runtime_dir_relative(p, uri.path);; ptr++; /* so we get the scheme for the uds */ } else { ptr = url; } } else { ptr = url; } if (mask & AP_PROXY_WORKER_IS_MATCH) { /* apr_uri_parse() will accept the '$' sign anywhere in the URL but * in the :port part, and we don't want scheme://host:port$1$2/path * to fail (e.g. "ProxyPassMatch ^/(a|b)(/.*)? http://host:port$2"). * So we trim all the $n from the :port and prepend them in uri.path * afterward for apr_uri_unparse() to restore the original URL below. */ #define IS_REF(x) (x[0] == '$' && apr_isdigit(x[1])) const char *pos = ap_strstr_c(ptr, "://"); if (pos) { pos += 3; while (*pos && *pos != ':' && *pos != '/') { pos++; } if (*pos == ':') { pos++; while (*pos && !IS_REF(pos) && *pos != '/') { pos++; } if (IS_REF(pos)) { struct iovec vec[2]; const char *path = pos + 2; while (*path && *path != '/') { path++; } pdollars = apr_pstrmemdup(p, pos, path - pos); vec[0].iov_base = (void *)ptr; vec[0].iov_len = pos - ptr; vec[1].iov_base = (void *)path; vec[1].iov_len = strlen(path); ptr = apr_pstrcatv(p, vec, 2, NULL); } } } #undef IS_REF } /* Normalize the url (worker name) */ rv = apr_uri_parse(p, ptr, &uri); if (rv != APR_SUCCESS) { return apr_pstrcat(p, "Unable to parse URL: ", url, NULL); } if (!uri.scheme) { return apr_pstrcat(p, "URL must be absolute!: ", url, NULL); } if (!uri.hostname) { if (sockpath) { /* allow for unix:/path|http: */ uri.hostname = "localhost"; } else { return apr_pstrcat(p, "URL must be absolute!: ", url, NULL); } } else { ap_str_tolower(uri.hostname); } ap_str_tolower(uri.scheme); port_of_scheme = ap_proxy_port_of_scheme(uri.scheme); if (uri.port && uri.port == port_of_scheme) { uri.port = 0; } if (pdollars) { /* Restore/prepend pdollars into the path. */ uri.path = apr_pstrcat(p, pdollars, uri.path, NULL); } ptr = apr_uri_unparse(p, &uri, APR_URI_UNP_REVEALPASSWORD); /* * Workers can be associated w/ balancers or on their * own; ie: the generic reverse-proxy or a worker * in a simple ProxyPass statement. eg: * * ProxyPass / http://www.example.com * * in which case the worker goes in the conf slot. */ if (balancer) { proxy_worker **runtime; /* recall that we get a ptr to the ptr here */ runtime = apr_array_push(balancer->workers); *worker = *runtime = apr_palloc(p, sizeof(proxy_worker)); /* right to left baby */ /* we've updated the list of workers associated with * this balancer *locally* */ balancer->wupdated = apr_time_now(); } else if (conf) { *worker = apr_array_push(conf->workers); } else { /* we need to allocate space here */ *worker = apr_palloc(p, sizeof(proxy_worker)); } memset(*worker, 0, sizeof(proxy_worker)); /* right here we just want to tuck away the worker info. * if called during config, we don't have shm setup yet, * so just note the info for later. */ if (mask & AP_PROXY_WORKER_IS_MALLOCED) wshared = ap_malloc(sizeof(proxy_worker_shared)); /* will be freed ap_proxy_share_worker */ else wshared = apr_palloc(p, sizeof(proxy_worker_shared)); memset(wshared, 0, sizeof(proxy_worker_shared)); if (PROXY_STRNCPY(wshared->name_ex, ptr) != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_ERR, 0, ap_server_conf, APLOGNO(10366) "Alert! worker name (%s) too long; truncated to: %s", ptr, wshared->name_ex); } if (PROXY_STRNCPY(wshared->name, ptr) != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_INFO, 0, ap_server_conf, APLOGNO(010118) "worker name (%s) too long; truncated for legacy modules that do not use " "proxy_worker_shared->name_ex: %s", ptr, wshared->name); } if (PROXY_STRNCPY(wshared->scheme, uri.scheme) != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_ERR, 0, ap_server_conf, APLOGNO(010117) "Alert! worker scheme (%s) too long; truncated to: %s", uri.scheme, wshared->scheme); } if (PROXY_STRNCPY(wshared->hostname_ex, uri.hostname) != APR_SUCCESS) { return apr_psprintf(p, "worker hostname (%s) too long", uri.hostname); } if (PROXY_STRNCPY(wshared->hostname, uri.hostname) != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_INFO, 0, ap_server_conf, APLOGNO(010118) "worker hostname (%s) too long; truncated for legacy modules that do not use " "proxy_worker_shared->hostname_ex: %s", uri.hostname, wshared->hostname); } wshared->port = (uri.port) ? uri.port : port_of_scheme; wshared->flush_packets = flush_off; wshared->flush_wait = PROXY_FLUSH_WAIT; wshared->is_address_reusable = 1; wshared->lbfactor = 100; wshared->passes = 1; wshared->fails = 1; wshared->interval = apr_time_from_sec(HCHECK_WATHCHDOG_DEFAULT_INTERVAL); wshared->smax = -1; wshared->hash.def = ap_proxy_hashfunc(wshared->name_ex, PROXY_HASHFUNC_DEFAULT); wshared->hash.fnv = ap_proxy_hashfunc(wshared->name_ex, PROXY_HASHFUNC_FNV); wshared->was_malloced = (mask & AP_PROXY_WORKER_IS_MALLOCED) != 0; wshared->is_name_matchable = 0; if (sockpath) { if (PROXY_STRNCPY(wshared->uds_path, sockpath) != APR_SUCCESS) { return apr_psprintf(p, "worker uds path (%s) too long", sockpath); } } else { *wshared->uds_path = '\0'; } if (!balancer) { wshared->status |= PROXY_WORKER_IGNORE_ERRORS; } (*worker)->hash = wshared->hash; (*worker)->context = NULL; (*worker)->cp = NULL; (*worker)->balancer = balancer; (*worker)->s = wshared; if (mask & AP_PROXY_WORKER_IS_MATCH) { (*worker)->s->is_name_matchable = 1; if (ap_strchr_c((*worker)->s->name_ex, '$')) { /* Before AP_PROXY_WORKER_IS_MATCH (< 2.4.47), a regex worker * with dollar substitution was never matched against the actual * URL thus the request fell through the generic worker. To avoid * dns and connection reuse compat issues, let's disable connection * reuse by default, it can still be overwritten by an explicit * enablereuse=on. */ (*worker)->s->disablereuse = 1; } } return NULL; } PROXY_DECLARE(char *) ap_proxy_define_worker(apr_pool_t *p, proxy_worker **worker, proxy_balancer *balancer, proxy_server_conf *conf, const char *url, int do_malloc) { return ap_proxy_define_worker_ex(p, worker, balancer, conf, url, AP_PROXY_WORKER_IS_PREFIX | (do_malloc ? AP_PROXY_WORKER_IS_MALLOCED : 0)); } /* DEPRECATED */ PROXY_DECLARE(char *) ap_proxy_define_match_worker(apr_pool_t *p, proxy_worker **worker, proxy_balancer *balancer, proxy_server_conf *conf, const char *url, int do_malloc) { return ap_proxy_define_worker_ex(p, worker, balancer, conf, url, AP_PROXY_WORKER_IS_MATCH | (do_malloc ? AP_PROXY_WORKER_IS_MALLOCED : 0)); } /* * Create an already defined worker and free up memory */ PROXY_DECLARE(apr_status_t) ap_proxy_share_worker(proxy_worker *worker, proxy_worker_shared *shm, int i) { char *action = "copying"; if (!shm || !worker->s) return APR_EINVAL; if ((worker->s->hash.def != shm->hash.def) || (worker->s->hash.fnv != shm->hash.fnv)) { memcpy(shm, worker->s, sizeof(proxy_worker_shared)); if (worker->s->was_malloced) free(worker->s); /* was malloced in ap_proxy_define_worker */ } else { action = "re-using"; } worker->s = shm; worker->s->index = i; if (APLOGdebug(ap_server_conf)) { apr_pool_t *pool; apr_pool_create(&pool, ap_server_conf->process->pool); apr_pool_tag(pool, "proxy_worker_name"); ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, ap_server_conf, APLOGNO(02338) "%s shm[%d] (0x%pp) for worker: %s", action, i, (void *)shm, ap_proxy_worker_name(pool, worker)); if (pool) { apr_pool_destroy(pool); } } return APR_SUCCESS; } PROXY_DECLARE(apr_status_t) ap_proxy_initialize_worker(proxy_worker *worker, server_rec *s, apr_pool_t *p) { APR_OPTIONAL_FN_TYPE(http2_get_num_workers) *get_h2_num_workers; apr_status_t rv = APR_SUCCESS; int max_threads, minw, maxw; if (worker->s->status & PROXY_WORKER_INITIALIZED) { /* The worker is already initialized */ ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00924) "worker %s shared already initialized", ap_proxy_worker_name(p, worker)); } else { ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00925) "initializing worker %s shared", ap_proxy_worker_name(p, worker)); /* Set default parameters */ if (!worker->s->retry_set) { worker->s->retry = apr_time_from_sec(PROXY_WORKER_DEFAULT_RETRY); } /* By default address is reusable unless DisableReuse is set */ if (worker->s->disablereuse) { worker->s->is_address_reusable = 0; } else { worker->s->is_address_reusable = 1; } /* * When mod_http2 is loaded we might have more threads since it has * its own pool of processing threads. */ ap_mpm_query(AP_MPMQ_MAX_THREADS, &max_threads); get_h2_num_workers = APR_RETRIEVE_OPTIONAL_FN(http2_get_num_workers); if (get_h2_num_workers) { get_h2_num_workers(s, &minw, &maxw); /* So now the max is: * max_threads-1 threads for HTTP/1 each requiring one connection * + one thread for HTTP/2 requiring maxw connections */ max_threads = max_threads - 1 + maxw; } if (max_threads > 1) { /* Default hmax is max_threads to scale with the load and never * wait for an idle connection to proceed. */ if (worker->s->hmax == 0) { worker->s->hmax = max_threads; } if (worker->s->smax == -1 || worker->s->smax > worker->s->hmax) { worker->s->smax = worker->s->hmax; } /* Set min to be lower than smax */ if (worker->s->min > worker->s->smax) { worker->s->min = worker->s->smax; } } else { /* This will suppress the apr_reslist creation */ worker->s->min = worker->s->smax = worker->s->hmax = 0; } } /* What if local is init'ed and shm isn't?? Even possible? */ if (worker->local_status & PROXY_WORKER_INITIALIZED) { ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00926) "worker %s local already initialized", ap_proxy_worker_name(p, worker)); } else { apr_global_mutex_lock(proxy_mutex); /* Check again after we got the lock if we are still uninitialized */ if (!(AP_VOLATILIZE_T(unsigned int, worker->local_status) & PROXY_WORKER_INITIALIZED)) { ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00927) "initializing worker %s local", ap_proxy_worker_name(p, worker)); /* Now init local worker data */ #if APR_HAS_THREADS if (worker->tmutex == NULL) { rv = apr_thread_mutex_create(&(worker->tmutex), APR_THREAD_MUTEX_DEFAULT, p); if (rv != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(00928) "can not create worker thread mutex"); apr_global_mutex_unlock(proxy_mutex); return rv; } } #endif if (worker->cp == NULL) init_conn_pool(p, worker); if (worker->cp == NULL) { ap_log_error(APLOG_MARK, APLOG_ERR, 0, s, APLOGNO(00929) "can not create connection pool"); apr_global_mutex_unlock(proxy_mutex); return APR_EGENERAL; } if (worker->s->hmax) { rv = apr_reslist_create(&(worker->cp->res), worker->s->min, worker->s->smax, worker->s->hmax, worker->s->ttl, connection_constructor, connection_destructor, worker, worker->cp->pool); ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00930) "initialized pool in child %" APR_PID_T_FMT " for (%s:%d) min=%d max=%d smax=%d", getpid(), worker->s->hostname_ex, (int)worker->s->port, worker->s->min, worker->s->hmax, worker->s->smax); /* Set the acquire timeout */ if (rv == APR_SUCCESS && worker->s->acquire_set) { apr_reslist_timeout_set(worker->cp->res, worker->s->acquire); } } else { void *conn; rv = connection_constructor(&conn, worker, worker->cp->pool); worker->cp->conn = conn; ap_log_error(APLOG_MARK, APLOG_DEBUG, rv, s, APLOGNO(00931) "initialized single connection worker in child %" APR_PID_T_FMT " for (%s:%d)", getpid(), worker->s->hostname_ex, (int)worker->s->port); } if (rv == APR_SUCCESS) { worker->local_status |= (PROXY_WORKER_INITIALIZED); } } apr_global_mutex_unlock(proxy_mutex); } if (rv == APR_SUCCESS) { worker->s->status |= (PROXY_WORKER_INITIALIZED); } return rv; } static int ap_proxy_retry_worker(const char *proxy_function, proxy_worker *worker, server_rec *s) { if (worker->s->status & PROXY_WORKER_IN_ERROR) { if (PROXY_WORKER_IS(worker, PROXY_WORKER_STOPPED)) { ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(3305) "%s: Won't retry worker (%s:%d): stopped", proxy_function, worker->s->hostname_ex, (int)worker->s->port); return DECLINED; } if ((worker->s->status & PROXY_WORKER_IGNORE_ERRORS) || apr_time_now() > worker->s->error_time + worker->s->retry) { ++worker->s->retries; worker->s->status &= ~PROXY_WORKER_IN_ERROR; ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00932) "%s: worker for (%s:%d) has been marked for retry", proxy_function, worker->s->hostname_ex, (int)worker->s->port); return OK; } else { ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00933) "%s: too soon to retry worker for (%s:%d)", proxy_function, worker->s->hostname_ex, (int)worker->s->port); return DECLINED; } } else { return OK; } } /* * In the case of the reverse proxy, we need to see if we * were passed a UDS url (eg: from mod_proxy) and adjust uds_path * as required. */ static int fix_uds_filename(request_rec *r, char **url) { char *uds_url = r->filename + 6, *origin_url; if (!strncmp(r->filename, "proxy:", 6) && !ap_cstr_casecmpn(uds_url, "unix:", 5) && (origin_url = ap_strchr(uds_url + 5, '|'))) { char *uds_path = NULL; apr_size_t url_len; apr_uri_t urisock; apr_status_t rv; *origin_url = '\0'; rv = apr_uri_parse(r->pool, uds_url, &urisock); *origin_url++ = '|'; if (rv == APR_SUCCESS && urisock.path && (!urisock.hostname || !urisock.hostname[0])) { uds_path = ap_runtime_dir_relative(r->pool, urisock.path); } if (!uds_path) { ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, APLOGNO(10292) "Invalid proxy UDS filename (%s)", r->filename); return 0; } apr_table_setn(r->notes, "uds_path", uds_path); /* Remove the UDS path from *url and r->filename */ url_len = strlen(origin_url); *url = apr_pstrmemdup(r->pool, origin_url, url_len); memcpy(uds_url, *url, url_len + 1); ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "*: rewrite of url due to UDS(%s): %s (%s)", uds_path, *url, r->filename); } return 1; } PROXY_DECLARE(int) ap_proxy_pre_request(proxy_worker **worker, proxy_balancer **balancer, request_rec *r, proxy_server_conf *conf, char **url) { int access_status; access_status = proxy_run_pre_request(worker, balancer, r, conf, url); if (access_status == DECLINED && *balancer == NULL) { const int forward = (r->proxyreq == PROXYREQ_PROXY); *worker = ap_proxy_get_worker_ex(r->pool, NULL, conf, *url, forward ? AP_PROXY_WORKER_NO_UDS : 0); if (*worker) { ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "%s: found worker %s for %s", (*worker)->s->scheme, (*worker)->s->name_ex, *url); if (!forward && !fix_uds_filename(r, url)) { return HTTP_INTERNAL_SERVER_ERROR; } access_status = OK; } else if (forward) { if (conf->forward) { ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "*: found forward proxy worker for %s", *url); *worker = conf->forward; access_status = OK; /* * The forward worker does not keep connections alive, so * ensure that mod_proxy_http does the correct thing * regarding the Connection header in the request. */ apr_table_setn(r->subprocess_env, "proxy-nokeepalive", "1"); } } else if (r->proxyreq == PROXYREQ_REVERSE) { if (conf->reverse) { ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "*: using default reverse proxy worker for %s " "(no keepalive)", *url); *worker = conf->reverse; access_status = OK; /* * The reverse worker does not keep connections alive, so * ensure that mod_proxy_http does the correct thing * regarding the Connection header in the request. */ apr_table_setn(r->subprocess_env, "proxy-nokeepalive", "1"); if (!fix_uds_filename(r, url)) { return HTTP_INTERNAL_SERVER_ERROR; } } } } else if (access_status == DECLINED && *balancer != NULL) { /* All the workers are busy */ ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, APLOGNO(00934) "all workers are busy. Unable to serve %s", *url); access_status = HTTP_SERVICE_UNAVAILABLE; } return access_status; } PROXY_DECLARE(int) ap_proxy_post_request(proxy_worker *worker, proxy_balancer *balancer, request_rec *r, proxy_server_conf *conf) { int access_status = OK; if (balancer) { access_status = proxy_run_post_request(worker, balancer, r, conf); if (access_status == DECLINED) { access_status = OK; /* no post_request handler available */ /* TODO: recycle direct worker */ } } return access_status; } /* DEPRECATED */ PROXY_DECLARE(int) ap_proxy_connect_to_backend(apr_socket_t **newsock, const char *proxy_function, apr_sockaddr_t *backend_addr, const char *backend_name, proxy_server_conf *conf, request_rec *r) { apr_status_t rv; int connected = 0; int loglevel; while (backend_addr && !connected) { if ((rv = apr_socket_create(newsock, backend_addr->family, SOCK_STREAM, 0, r->pool)) != APR_SUCCESS) { loglevel = backend_addr->next ? APLOG_DEBUG : APLOG_ERR; ap_log_rerror(APLOG_MARK, loglevel, rv, r, APLOGNO(00935) "%s: error creating fam %d socket for target %s", proxy_function, backend_addr->family, backend_name); /* * this could be an IPv6 address from the DNS but the * local machine won't give us an IPv6 socket; hopefully the * DNS returned an additional address to try */ backend_addr = backend_addr->next; continue; } if (conf->recv_buffer_size > 0 && (rv = apr_socket_opt_set(*newsock, APR_SO_RCVBUF, conf->recv_buffer_size))) { ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, APLOGNO(00936) "apr_socket_opt_set(SO_RCVBUF): Failed to set " "ProxyReceiveBufferSize, using default"); } rv = apr_socket_opt_set(*newsock, APR_TCP_NODELAY, 1); if (rv != APR_SUCCESS && rv != APR_ENOTIMPL) { ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, APLOGNO(00937) "apr_socket_opt_set(APR_TCP_NODELAY): " "Failed to set"); } /* Set a timeout on the socket */ if (conf->timeout_set) { apr_socket_timeout_set(*newsock, conf->timeout); } else { apr_socket_timeout_set(*newsock, r->server->timeout); } ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "%s: fam %d socket created to connect to %s", proxy_function, backend_addr->family, backend_name); if (conf->source_address) { apr_sockaddr_t *local_addr; /* Make a copy since apr_socket_bind() could change * conf->source_address, which we don't want. */ local_addr = apr_pmemdup(r->pool, conf->source_address, sizeof(apr_sockaddr_t)); local_addr->pool = r->pool; rv = apr_socket_bind(*newsock, local_addr); if (rv != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, APLOGNO(00938) "%s: failed to bind socket to local address", proxy_function); } } /* make the connection out of the socket */ rv = apr_socket_connect(*newsock, backend_addr); /* if an error occurred, loop round and try again */ if (rv != APR_SUCCESS) { apr_socket_close(*newsock); loglevel = backend_addr->next ? APLOG_DEBUG : APLOG_ERR; ap_log_rerror(APLOG_MARK, loglevel, rv, r, APLOGNO(00939) "%s: attempt to connect to %pI (%s) failed", proxy_function, backend_addr, backend_name); backend_addr = backend_addr->next; continue; } connected = 1; } return connected ? 0 : 1; } PROXY_DECLARE(int) ap_proxy_acquire_connection(const char *proxy_function, proxy_conn_rec **conn, proxy_worker *worker, server_rec *s) { apr_status_t rv; if (!PROXY_WORKER_IS_USABLE(worker)) { /* Retry the worker */ ap_proxy_retry_worker(proxy_function, worker, s); if (!PROXY_WORKER_IS_USABLE(worker)) { ap_log_error(APLOG_MARK, APLOG_ERR, 0, s, APLOGNO(00940) "%s: disabled connection for (%s:%d)", proxy_function, worker->s->hostname_ex, (int)worker->s->port); return HTTP_SERVICE_UNAVAILABLE; } } if (worker->s->hmax && worker->cp->res) { rv = apr_reslist_acquire(worker->cp->res, (void **)conn); } else { /* create the new connection if the previous was destroyed */ if (!worker->cp->conn) { rv = connection_constructor((void **)conn, worker, worker->cp->pool); } else { *conn = worker->cp->conn; worker->cp->conn = NULL; rv = APR_SUCCESS; } } if (rv != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(00941) "%s: failed to acquire connection for (%s:%d)", proxy_function, worker->s->hostname_ex, (int)worker->s->port); return HTTP_SERVICE_UNAVAILABLE; } ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00942) "%s: has acquired connection for (%s:%d)", proxy_function, worker->s->hostname_ex, (int)worker->s->port); (*conn)->worker = worker; (*conn)->close = 0; (*conn)->inreslist = 0; return OK; } PROXY_DECLARE(int) ap_proxy_release_connection(const char *proxy_function, proxy_conn_rec *conn, server_rec *s) { ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00943) "%s: has released connection for (%s:%d)", proxy_function, conn->worker->s->hostname_ex, (int)conn->worker->s->port); connection_cleanup(conn); return OK; } PROXY_DECLARE(int) ap_proxy_determine_connection(apr_pool_t *p, request_rec *r, proxy_server_conf *conf, proxy_worker *worker, proxy_conn_rec *conn, apr_uri_t *uri, char **url, const char *proxyname, apr_port_t proxyport, char *server_portstr, int server_portstr_size) { int server_port; apr_status_t err = APR_SUCCESS; #if APR_HAS_THREADS apr_status_t uerr = APR_SUCCESS; #endif const char *uds_path; /* * Break up the URL to determine the host to connect to */ /* we break the URL into host, port, uri */ if (APR_SUCCESS != apr_uri_parse(p, *url, uri)) { return ap_proxyerror(r, HTTP_BAD_REQUEST, apr_pstrcat(p,"URI cannot be parsed: ", *url, NULL)); } if (!uri->port) { uri->port = ap_proxy_port_of_scheme(uri->scheme); } ap_log_rerror(APLOG_MARK, APLOG_DEBUG, 0, r, APLOGNO(00944) "connecting %s to %s:%d", *url, uri->hostname, uri->port); /* * allocate these out of the specified connection pool * The scheme handler decides if this is permanent or * short living pool. */ /* Unless we are connecting the backend via a (forward Proxy)Remote, we * have to use the original form of the URI (non absolute), but this is * also the case via a remote proxy using the CONNECT method since the * original request (and URI) is to be embedded in the body. */ if (!proxyname || conn->is_ssl) { *url = apr_pstrcat(p, uri->path, uri->query ? "?" : "", uri->query ? uri->query : "", uri->fragment ? "#" : "", uri->fragment ? uri->fragment : "", NULL); } /* * Figure out if our passed in proxy_conn_rec has a usable * address cached. * * TODO: Handle this much better... * * XXX: If generic workers are ever address-reusable, we need * to check host and port on the conn and be careful about * spilling the cached addr from the worker. */ uds_path = (*worker->s->uds_path ? worker->s->uds_path : apr_table_get(r->notes, "uds_path")); if (uds_path) { if (conn->uds_path == NULL) { /* use (*conn)->pool instead of worker->cp->pool to match lifetime */ conn->uds_path = apr_pstrdup(conn->pool, uds_path); } if (conn->uds_path) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, 0, r, APLOGNO(02545) "%s: has determined UDS as %s", uri->scheme, conn->uds_path); } else { /* should never happen */ ap_log_rerror(APLOG_MARK, APLOG_DEBUG, 0, r, APLOGNO(02546) "%s: cannot determine UDS (%s)", uri->scheme, uds_path); } /* * In UDS cases, some structs are NULL. Protect from de-refs * and provide info for logging at the same time. */ if (!conn->addr) { apr_sockaddr_t *sa; apr_sockaddr_info_get(&sa, NULL, APR_UNSPEC, 0, 0, conn->pool); conn->addr = sa; } conn->hostname = "httpd-UDS"; conn->port = 0; } else { int will_reuse = worker->s->is_address_reusable && !worker->s->disablereuse; if (!conn->hostname || !will_reuse) { if (proxyname) { conn->hostname = apr_pstrdup(conn->pool, proxyname); conn->port = proxyport; /* * If we have a forward proxy and the protocol is HTTPS, * then we need to prepend a HTTP CONNECT request before * sending our actual HTTPS requests. * Save our real backend data for using it later during HTTP CONNECT. */ if (conn->is_ssl) { const char *proxy_auth; forward_info *forward = apr_pcalloc(conn->pool, sizeof(forward_info)); conn->forward = forward; forward->use_http_connect = 1; forward->target_host = apr_pstrdup(conn->pool, uri->hostname); forward->target_port = uri->port; /* Do we want to pass Proxy-Authorization along? * If we haven't used it, then YES * If we have used it then MAYBE: RFC2616 says we MAY propagate it. * So let's make it configurable by env. * The logic here is the same used in mod_proxy_http. */ proxy_auth = apr_table_get(r->headers_in, "Proxy-Authorization"); if (proxy_auth != NULL && proxy_auth[0] != '\0' && r->user == NULL && /* we haven't yet authenticated */ apr_table_get(r->subprocess_env, "Proxy-Chain-Auth")) { forward->proxy_auth = apr_pstrdup(conn->pool, proxy_auth); } } } else { conn->hostname = apr_pstrdup(conn->pool, uri->hostname); conn->port = uri->port; } if (!will_reuse) { /* * Only do a lookup if we should not reuse the backend address. * Otherwise we will look it up once for the worker. */ err = apr_sockaddr_info_get(&(conn->addr), conn->hostname, APR_UNSPEC, conn->port, 0, conn->pool); } socket_cleanup(conn); conn->close = 0; } if (will_reuse) { /* * Looking up the backend address for the worker only makes sense if * we can reuse the address. */ if (!worker->cp->addr) { #if APR_HAS_THREADS if ((err = PROXY_THREAD_LOCK(worker)) != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, err, r, APLOGNO(00945) "lock"); return HTTP_INTERNAL_SERVER_ERROR; } #endif /* * Recheck addr after we got the lock. This may have changed * while waiting for the lock. */ if (!AP_VOLATILIZE_T(apr_sockaddr_t *, worker->cp->addr)) { apr_sockaddr_t *addr; /* * Worker can have the single constant backend address. * The single DNS lookup is used once per worker. * If dynamic change is needed then set the addr to NULL * inside dynamic config to force the lookup. */ err = apr_sockaddr_info_get(&addr, conn->hostname, APR_UNSPEC, conn->port, 0, worker->cp->dns_pool); worker->cp->addr = addr; } conn->addr = worker->cp->addr; #if APR_HAS_THREADS if ((uerr = PROXY_THREAD_UNLOCK(worker)) != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, uerr, r, APLOGNO(00946) "unlock"); } #endif } else { conn->addr = worker->cp->addr; } } } /* Close a possible existing socket if we are told to do so */ if (conn->close) { socket_cleanup(conn); conn->close = 0; } if (err != APR_SUCCESS) { return ap_proxyerror(r, HTTP_BAD_GATEWAY, apr_pstrcat(p, "DNS lookup failure for: ", conn->hostname, NULL)); } /* Get the server port for the Via headers */ server_port = ap_get_server_port(r); AP_DEBUG_ASSERT(server_portstr_size > 0); if (ap_is_default_port(server_port, r)) { server_portstr[0] = '\0'; } else { apr_snprintf(server_portstr, server_portstr_size, ":%d", server_port); } /* check if ProxyBlock directive on this host */ if (OK != ap_proxy_checkproxyblock2(r, conf, uri->hostname, proxyname ? NULL : conn->addr)) { return ap_proxyerror(r, HTTP_FORBIDDEN, "Connect to remote machine blocked"); } /* * When SSL is configured, determine the hostname (SNI) for the request * and save it in conn->ssl_hostname. Close any reused connection whose * SNI differs. */ if (conn->is_ssl) { proxy_dir_conf *dconf; const char *ssl_hostname; /* * In the case of ProxyPreserveHost on use the hostname of * the request if present otherwise use the one from the * backend request URI. */ dconf = ap_get_module_config(r->per_dir_config, &proxy_module); if (dconf->preserve_host) { ssl_hostname = r->hostname; } else if (conn->forward && ((forward_info *)(conn->forward))->use_http_connect) { ssl_hostname = ((forward_info *)conn->forward)->target_host; } else { ssl_hostname = conn->hostname; } /* * Close if a SNI is in use but this request requires no or * a different one, or no SNI is in use but one is required. */ if ((conn->ssl_hostname && (!ssl_hostname || strcasecmp(conn->ssl_hostname, ssl_hostname) != 0)) || (!conn->ssl_hostname && ssl_hostname && conn->sock)) { socket_cleanup(conn); } if (conn->ssl_hostname == NULL) { conn->ssl_hostname = apr_pstrdup(conn->scpool, ssl_hostname); } } ap_log_rerror(APLOG_MARK, APLOG_DEBUG, 0, r, APLOGNO(00947) "connected %s to %s:%d", *url, conn->hostname, conn->port); return OK; } #define USE_ALTERNATE_IS_CONNECTED 1 #if !defined(APR_MSG_PEEK) && defined(MSG_PEEK) #define APR_MSG_PEEK MSG_PEEK #endif #if USE_ALTERNATE_IS_CONNECTED && defined(APR_MSG_PEEK) PROXY_DECLARE(int) ap_proxy_is_socket_connected(apr_socket_t *socket) { apr_pollfd_t pfds[1]; apr_status_t status; apr_int32_t nfds; pfds[0].reqevents = APR_POLLIN; pfds[0].desc_type = APR_POLL_SOCKET; pfds[0].desc.s = socket; do { status = apr_poll(&pfds[0], 1, &nfds, 0); } while (APR_STATUS_IS_EINTR(status)); if (status == APR_SUCCESS && nfds == 1 && pfds[0].rtnevents == APR_POLLIN) { apr_sockaddr_t unused; apr_size_t len = 1; char buf[1]; /* The socket might be closed in which case * the poll will return POLLIN. * If there is no data available the socket * is closed. */ status = apr_socket_recvfrom(&unused, socket, APR_MSG_PEEK, &buf[0], &len); if (status == APR_SUCCESS && len) return 1; else return 0; } else if (APR_STATUS_IS_EAGAIN(status) || APR_STATUS_IS_TIMEUP(status)) { return 1; } return 0; } #else PROXY_DECLARE(int) ap_proxy_is_socket_connected(apr_socket_t *sock) { apr_size_t buffer_len = 1; char test_buffer[1]; apr_status_t socket_status; apr_interval_time_t current_timeout; /* save timeout */ apr_socket_timeout_get(sock, ¤t_timeout); /* set no timeout */ apr_socket_timeout_set(sock, 0); socket_status = apr_socket_recv(sock, test_buffer, &buffer_len); /* put back old timeout */ apr_socket_timeout_set(sock, current_timeout); if (APR_STATUS_IS_EOF(socket_status) || APR_STATUS_IS_ECONNRESET(socket_status)) { return 0; } else { return 1; } } #endif /* USE_ALTERNATE_IS_CONNECTED */ /* * Send a HTTP CONNECT request to a forward proxy. * The proxy is given by "backend", the target server * is contained in the "forward" member of "backend". */ static apr_status_t send_http_connect(proxy_conn_rec *backend, server_rec *s) { int status; apr_size_t nbytes; apr_size_t left; int complete = 0; char buffer[HUGE_STRING_LEN]; char drain_buffer[HUGE_STRING_LEN]; forward_info *forward = (forward_info *)backend->forward; int len = 0; ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00948) "CONNECT: sending the CONNECT request for %s:%d " "to the remote proxy %pI (%s)", forward->target_host, forward->target_port, backend->addr, backend->hostname); /* Create the CONNECT request */ nbytes = apr_snprintf(buffer, sizeof(buffer), "CONNECT %s:%d HTTP/1.0" CRLF, forward->target_host, forward->target_port); /* Add proxy authorization from the initial request if necessary */ if (forward->proxy_auth != NULL) { nbytes += apr_snprintf(buffer + nbytes, sizeof(buffer) - nbytes, "Proxy-Authorization: %s" CRLF, forward->proxy_auth); } /* Set a reasonable agent and send everything */ nbytes += apr_snprintf(buffer + nbytes, sizeof(buffer) - nbytes, "Proxy-agent: %s" CRLF CRLF, ap_get_server_banner()); ap_xlate_proto_to_ascii(buffer, nbytes); apr_socket_send(backend->sock, buffer, &nbytes); /* Receive the whole CONNECT response */ left = sizeof(buffer) - 1; /* Read until we find the end of the headers or run out of buffer */ do { nbytes = left; status = apr_socket_recv(backend->sock, buffer + len, &nbytes); len += nbytes; left -= nbytes; buffer[len] = '\0'; if (strstr(buffer + len - nbytes, CRLF_ASCII CRLF_ASCII) != NULL) { ap_xlate_proto_from_ascii(buffer, len); complete = 1; break; } } while (status == APR_SUCCESS && left > 0); /* Drain what's left */ if (!complete) { nbytes = sizeof(drain_buffer) - 1; while (status == APR_SUCCESS && nbytes) { status = apr_socket_recv(backend->sock, drain_buffer, &nbytes); drain_buffer[nbytes] = '\0'; nbytes = sizeof(drain_buffer) - 1; if (strstr(drain_buffer, CRLF_ASCII CRLF_ASCII) != NULL) { break; } } } /* Check for HTTP_OK response status */ if (status == APR_SUCCESS) { unsigned int major, minor; /* Only scan for three character status code */ char code_str[4]; ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00949) "send_http_connect: response from the forward proxy: %s", buffer); /* Extract the returned code */ if (sscanf(buffer, "HTTP/%u.%u %3s", &major, &minor, code_str) == 3) { status = atoi(code_str); if (status == HTTP_OK) { status = APR_SUCCESS; } else { ap_log_error(APLOG_MARK, APLOG_ERR, 0, s, APLOGNO(00950) "send_http_connect: the forward proxy returned code is '%s'", code_str); status = APR_INCOMPLETE; } } } return(status); } /* TODO: In APR 2.x: Extend apr_sockaddr_t to possibly be a path !!! */ PROXY_DECLARE(apr_status_t) ap_proxy_connect_uds(apr_socket_t *sock, const char *uds_path, apr_pool_t *p) { #if APR_HAVE_SYS_UN_H apr_status_t rv; apr_os_sock_t rawsock; apr_interval_time_t t; struct sockaddr_un *sa; apr_socklen_t addrlen, pathlen; rv = apr_os_sock_get(&rawsock, sock); if (rv != APR_SUCCESS) { return rv; } rv = apr_socket_timeout_get(sock, &t); if (rv != APR_SUCCESS) { return rv; } pathlen = strlen(uds_path); /* copy the UDS path (including NUL) to the sockaddr_un */ addrlen = APR_OFFSETOF(struct sockaddr_un, sun_path) + pathlen; sa = (struct sockaddr_un *)apr_palloc(p, addrlen + 1); memcpy(sa->sun_path, uds_path, pathlen + 1); sa->sun_family = AF_UNIX; do { rv = connect(rawsock, (struct sockaddr*)sa, addrlen); } while (rv == -1 && (rv = errno) == EINTR); if (rv && rv != EISCONN) { if ((rv == EINPROGRESS || rv == EALREADY) && (t > 0)) { #if APR_MAJOR_VERSION < 2 rv = apr_wait_for_io_or_timeout(NULL, sock, 0); #else rv = apr_socket_wait(sock, APR_WAIT_WRITE); #endif } if (rv != APR_SUCCESS) { return rv; } } return APR_SUCCESS; #else return APR_ENOTIMPL; #endif } PROXY_DECLARE(apr_status_t) ap_proxy_check_connection(const char *scheme, proxy_conn_rec *conn, server_rec *server, unsigned max_blank_lines, int flags) { apr_status_t rv = APR_SUCCESS; proxy_worker *worker = conn->worker; if (!PROXY_WORKER_IS_USABLE(worker)) { /* * The worker is in error likely done by a different thread / process * e.g. for a timeout or bad status. We should respect this and should * not continue with a connection via this worker even if we got one. */ rv = APR_EINVAL; } else if (conn->connection) { /* We have a conn_rec, check the full filter stack for things like * SSL alert/shutdown, filters aside data... */ rv = ap_check_pipeline(conn->connection, conn->tmp_bb, max_blank_lines); apr_brigade_cleanup(conn->tmp_bb); if (rv == APR_SUCCESS) { /* Some data available, the caller might not want them. */ if (flags & PROXY_CHECK_CONN_EMPTY) { rv = APR_ENOTEMPTY; } } else if (APR_STATUS_IS_EAGAIN(rv)) { /* Filter chain is OK and empty, yet we can't determine from * ap_check_pipeline (actually ap_core_input_filter) whether * an empty non-blocking read is EAGAIN or EOF on the socket * side (it's always SUCCESS), so check it explicitly here. */ if (ap_proxy_is_socket_connected(conn->sock)) { rv = APR_SUCCESS; } else { rv = APR_EPIPE; } } } else if (conn->sock) { /* For modules working with sockets directly, check it. */ if (!ap_proxy_is_socket_connected(conn->sock)) { rv = APR_EPIPE; } } else { rv = APR_ENOSOCKET; } if (rv == APR_SUCCESS) { if (APLOGtrace2(server)) { apr_sockaddr_t *local_addr = NULL; apr_socket_addr_get(&local_addr, APR_LOCAL, conn->sock); ap_log_error(APLOG_MARK, APLOG_TRACE2, 0, server, "%s: reusing backend connection %pI<>%pI", scheme, local_addr, conn->addr); } } else if (conn->sock) { /* This clears conn->scpool (and associated data), so backup and * restore any ssl_hostname for this connection set earlier by * ap_proxy_determine_connection(). */ char ssl_hostname[PROXY_WORKER_RFC1035_NAME_SIZE]; if (rv == APR_EINVAL || !conn->ssl_hostname || PROXY_STRNCPY(ssl_hostname, conn->ssl_hostname)) { ssl_hostname[0] = '\0'; } socket_cleanup(conn); if (rv != APR_ENOTEMPTY) { ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, server, APLOGNO(00951) "%s: backend socket is disconnected.", scheme); } else { ap_log_error(APLOG_MARK, APLOG_INFO, 0, server, APLOGNO(03408) "%s: reusable backend connection is not empty: " "forcibly closed", scheme); } if (ssl_hostname[0]) { conn->ssl_hostname = apr_pstrdup(conn->scpool, ssl_hostname); } } return rv; } PROXY_DECLARE(int) ap_proxy_connect_backend(const char *proxy_function, proxy_conn_rec *conn, proxy_worker *worker, server_rec *s) { apr_status_t rv; int loglevel; apr_sockaddr_t *backend_addr = conn->addr; /* the local address to use for the outgoing connection */ apr_sockaddr_t *local_addr; apr_socket_t *newsock; void *sconf = s->module_config; proxy_server_conf *conf = (proxy_server_conf *) ap_get_module_config(sconf, &proxy_module); rv = ap_proxy_check_connection(proxy_function, conn, s, 0, 0); if (rv == APR_EINVAL) { return DECLINED; } while (rv != APR_SUCCESS && (backend_addr || conn->uds_path)) { #if APR_HAVE_SYS_UN_H if (conn->uds_path) { rv = apr_socket_create(&newsock, AF_UNIX, SOCK_STREAM, 0, conn->scpool); if (rv != APR_SUCCESS) { loglevel = APLOG_ERR; ap_log_error(APLOG_MARK, loglevel, rv, s, APLOGNO(02453) "%s: error creating Unix domain socket for " "target %s:%d", proxy_function, worker->s->hostname_ex, (int)worker->s->port); break; } conn->connection = NULL; rv = ap_proxy_connect_uds(newsock, conn->uds_path, conn->scpool); if (rv != APR_SUCCESS) { apr_socket_close(newsock); ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(02454) "%s: attempt to connect to Unix domain socket " "%s (%s:%d) failed", proxy_function, conn->uds_path, worker->s->hostname_ex, (int)worker->s->port); break; } ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(02823) "%s: connection established with Unix domain socket " "%s (%s:%d)", proxy_function, conn->uds_path, worker->s->hostname_ex, (int)worker->s->port); } else #endif { if ((rv = apr_socket_create(&newsock, backend_addr->family, SOCK_STREAM, APR_PROTO_TCP, conn->scpool)) != APR_SUCCESS) { loglevel = backend_addr->next ? APLOG_DEBUG : APLOG_ERR; ap_log_error(APLOG_MARK, loglevel, rv, s, APLOGNO(00952) "%s: error creating fam %d socket for " "target %s:%d", proxy_function, backend_addr->family, worker->s->hostname_ex, (int)worker->s->port); /* * this could be an IPv6 address from the DNS but the * local machine won't give us an IPv6 socket; hopefully the * DNS returned an additional address to try */ backend_addr = backend_addr->next; continue; } conn->connection = NULL; if (worker->s->recv_buffer_size > 0 && (rv = apr_socket_opt_set(newsock, APR_SO_RCVBUF, worker->s->recv_buffer_size))) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(00953) "apr_socket_opt_set(SO_RCVBUF): Failed to set " "ProxyReceiveBufferSize, using default"); } rv = apr_socket_opt_set(newsock, APR_TCP_NODELAY, 1); if (rv != APR_SUCCESS && rv != APR_ENOTIMPL) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(00954) "apr_socket_opt_set(APR_TCP_NODELAY): " "Failed to set"); } /* Set a timeout for connecting to the backend on the socket */ if (worker->s->conn_timeout_set) { apr_socket_timeout_set(newsock, worker->s->conn_timeout); } else if (worker->s->timeout_set) { apr_socket_timeout_set(newsock, worker->s->timeout); } else if (conf->timeout_set) { apr_socket_timeout_set(newsock, conf->timeout); } else { apr_socket_timeout_set(newsock, s->timeout); } /* Set a keepalive option */ if (worker->s->keepalive) { if ((rv = apr_socket_opt_set(newsock, APR_SO_KEEPALIVE, 1)) != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(00955) "apr_socket_opt_set(SO_KEEPALIVE): Failed to set" " Keepalive"); } } ap_log_error(APLOG_MARK, APLOG_TRACE2, 0, s, "%s: fam %d socket created to connect to %s:%d", proxy_function, backend_addr->family, worker->s->hostname_ex, (int)worker->s->port); if (conf->source_address_set) { local_addr = apr_pmemdup(conn->scpool, conf->source_address, sizeof(apr_sockaddr_t)); local_addr->pool = conn->scpool; rv = apr_socket_bind(newsock, local_addr); if (rv != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, s, APLOGNO(00956) "%s: failed to bind socket to local address", proxy_function); } } /* make the connection out of the socket */ rv = apr_socket_connect(newsock, backend_addr); /* if an error occurred, loop round and try again */ if (rv != APR_SUCCESS) { apr_socket_close(newsock); loglevel = backend_addr->next ? APLOG_DEBUG : APLOG_ERR; ap_log_error(APLOG_MARK, loglevel, rv, s, APLOGNO(00957) "%s: attempt to connect to %pI (%s:%d) failed", proxy_function, backend_addr, worker->s->hostname_ex, (int)worker->s->port); backend_addr = backend_addr->next; continue; } ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(02824) "%s: connection established with %pI (%s:%d)", proxy_function, backend_addr, worker->s->hostname_ex, (int)worker->s->port); } /* Set a timeout on the socket */ if (worker->s->timeout_set) { apr_socket_timeout_set(newsock, worker->s->timeout); } else if (conf->timeout_set) { apr_socket_timeout_set(newsock, conf->timeout); } else { apr_socket_timeout_set(newsock, s->timeout); } conn->sock = newsock; if (!conn->uds_path && conn->forward) { forward_info *forward = (forward_info *)conn->forward; /* * For HTTP CONNECT we need to prepend CONNECT request before * sending our actual HTTPS requests. */ if (forward->use_http_connect) { rv = send_http_connect(conn, s); /* If an error occurred, loop round and try again */ if (rv != APR_SUCCESS) { conn->sock = NULL; apr_socket_close(newsock); loglevel = backend_addr->next ? APLOG_DEBUG : APLOG_ERR; ap_log_error(APLOG_MARK, loglevel, rv, s, APLOGNO(00958) "%s: attempt to connect to %s:%d " "via http CONNECT through %pI (%s:%d) failed", proxy_function, forward->target_host, forward->target_port, backend_addr, worker->s->hostname_ex, (int)worker->s->port); backend_addr = backend_addr->next; continue; } } } } if (PROXY_WORKER_IS_USABLE(worker)) { /* * Put the entire worker to error state if * the PROXY_WORKER_IGNORE_ERRORS flag is not set. * Although some connections may be alive * no further connections to the worker could be made */ if (rv != APR_SUCCESS) { if (!(worker->s->status & PROXY_WORKER_IGNORE_ERRORS)) { worker->s->error_time = apr_time_now(); worker->s->status |= PROXY_WORKER_IN_ERROR; ap_log_error(APLOG_MARK, APLOG_ERR, 0, s, APLOGNO(00959) "ap_proxy_connect_backend disabling worker for (%s:%d) for %" APR_TIME_T_FMT "s", worker->s->hostname_ex, (int)worker->s->port, apr_time_sec(worker->s->retry)); } } else { if (worker->s->retries) { /* * A worker came back. So here is where we need to * either reset all params to initial conditions or * apply some sort of aging */ } worker->s->error_time = 0; worker->s->retries = 0; } } else { /* * The worker is in error likely done by a different thread / process * e.g. for a timeout or bad status. We should respect this and should * not continue with a connection via this worker even if we got one. */ if (rv == APR_SUCCESS) { socket_cleanup(conn); } rv = APR_EINVAL; } return rv == APR_SUCCESS ? OK : DECLINED; } static apr_status_t connection_shutdown(void *theconn) { proxy_conn_rec *conn = (proxy_conn_rec *)theconn; conn_rec *c = conn->connection; if (c) { if (!c->aborted) { apr_interval_time_t saved_timeout = 0; apr_socket_timeout_get(conn->sock, &saved_timeout); if (saved_timeout) { apr_socket_timeout_set(conn->sock, 0); } (void)ap_shutdown_conn(c, 0); c->aborted = 1; if (saved_timeout) { apr_socket_timeout_set(conn->sock, saved_timeout); } } ap_log_cerror(APLOG_MARK, APLOG_DEBUG, 0, c, APLOGNO(02642) "proxy: connection shutdown"); } return APR_SUCCESS; } static int proxy_connection_create(const char *proxy_function, proxy_conn_rec *conn, request_rec *r, server_rec *s) { ap_conf_vector_t *per_dir_config = (r) ? r->per_dir_config : conn->worker->section_config; apr_sockaddr_t *backend_addr = conn->addr; int rc; apr_interval_time_t current_timeout; apr_bucket_alloc_t *bucket_alloc; if (conn->connection) { if (conn->is_ssl) { /* on reuse, reinit the SSL connection dir config with the current * r->per_dir_config, the previous one was reset on release. */ ap_proxy_ssl_engine(conn->connection, per_dir_config, 1); } return OK; } bucket_alloc = apr_bucket_alloc_create(conn->scpool); conn->tmp_bb = apr_brigade_create(conn->scpool, bucket_alloc); /* * The socket is now open, create a new backend server connection */ conn->connection = ap_run_create_connection(conn->scpool, s, conn->sock, 0, NULL, bucket_alloc); if (!conn->connection) { /* * the peer reset the connection already; ap_run_create_connection() * closed the socket */ ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00960) "%s: an error occurred creating a " "new connection to %pI (%s)", proxy_function, backend_addr, conn->hostname); /* XXX: Will be closed when proxy_conn is closed */ socket_cleanup(conn); return HTTP_INTERNAL_SERVER_ERROR; } /* For ssl connection to backend */ if (conn->is_ssl) { if (!ap_proxy_ssl_engine(conn->connection, per_dir_config, 1)) { ap_log_error(APLOG_MARK, APLOG_ERR, 0, s, APLOGNO(00961) "%s: failed to enable ssl support " "for %pI (%s)", proxy_function, backend_addr, conn->hostname); return HTTP_INTERNAL_SERVER_ERROR; } if (conn->ssl_hostname) { /* Set a note on the connection about what CN is requested, * such that mod_ssl can check if it is requested to do so. */ ap_log_cerror(APLOG_MARK, APLOG_TRACE1, 0, conn->connection, "%s: set SNI to %s for (%s)", proxy_function, conn->ssl_hostname, conn->hostname); apr_table_setn(conn->connection->notes, "proxy-request-hostname", conn->ssl_hostname); } } else { /* TODO: See if this will break FTP */ ap_proxy_ssl_engine(conn->connection, per_dir_config, 0); } ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00962) "%s: connection complete to %pI (%s)", proxy_function, backend_addr, conn->hostname); /* * save the timeout of the socket because core_pre_connection * will set it to base_server->timeout * (core TimeOut directive). */ apr_socket_timeout_get(conn->sock, ¤t_timeout); /* set up the connection filters */ rc = ap_run_pre_connection(conn->connection, conn->sock); if (rc != OK && rc != DONE) { conn->connection->aborted = 1; ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(00963) "%s: pre_connection setup failed (%d)", proxy_function, rc); return rc; } apr_socket_timeout_set(conn->sock, current_timeout); /* Shutdown the connection before closing it (eg. SSL connections * need to be close-notify-ed). */ apr_pool_pre_cleanup_register(conn->scpool, conn, connection_shutdown); return OK; } PROXY_DECLARE(int) ap_proxy_connection_create_ex(const char *proxy_function, proxy_conn_rec *conn, request_rec *r) { return proxy_connection_create(proxy_function, conn, r, r->server); } PROXY_DECLARE(int) ap_proxy_connection_create(const char *proxy_function, proxy_conn_rec *conn, conn_rec *c, server_rec *s) { (void) c; /* unused */ return proxy_connection_create(proxy_function, conn, NULL, s); } int ap_proxy_lb_workers(void) { /* * Since we can't resize the scoreboard when reconfiguring, we * have to impose a limit on the number of workers, we are * able to reconfigure to. */ if (!lb_workers_limit) lb_workers_limit = proxy_lb_workers + PROXY_DYNAMIC_BALANCER_LIMIT; return lb_workers_limit; } static APR_INLINE int error_code_overridden(const int *elts, int nelts, int code) { int min = 0; int max = nelts - 1; AP_DEBUG_ASSERT(max >= 0); while (min < max) { int mid = (min + max) / 2; int val = elts[mid]; if (val < code) { min = mid + 1; } else if (val > code) { max = mid - 1; } else { return 1; } } return elts[min] == code; } PROXY_DECLARE(int) ap_proxy_should_override(proxy_dir_conf *conf, int code) { if (!conf->error_override) return 0; if (apr_is_empty_array(conf->error_override_codes)) return ap_is_HTTP_ERROR(code); /* Since error_override_codes is sorted, apply binary search. */ return error_code_overridden((int *)conf->error_override_codes->elts, conf->error_override_codes->nelts, code); } PROXY_DECLARE(void) ap_proxy_backend_broke(request_rec *r, apr_bucket_brigade *brigade) { apr_bucket *e; conn_rec *c = r->connection; r->no_cache = 1; /* * If this is a subrequest, then prevent also caching of the main * request. */ if (r->main) r->main->no_cache = 1; e = ap_bucket_error_create(HTTP_BAD_GATEWAY, NULL, c->pool, c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(brigade, e); e = apr_bucket_eos_create(c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(brigade, e); } /* * Provide a string hashing function for the proxy. * We offer 2 methods: one is the APR model but we * also provide our own, based on either FNV or SDBM. * The reason is in case we want to use both to ensure no * collisions. */ PROXY_DECLARE(unsigned int) ap_proxy_hashfunc(const char *str, proxy_hash_t method) { if (method == PROXY_HASHFUNC_APR) { apr_ssize_t slen = strlen(str); return apr_hashfunc_default(str, &slen); } else if (method == PROXY_HASHFUNC_FNV) { /* FNV model */ unsigned int hash; const unsigned int fnv_prime = 0x811C9DC5; for (hash = 0; *str; str++) { hash *= fnv_prime; hash ^= (*str); } return hash; } else { /* method == PROXY_HASHFUNC_DEFAULT */ /* SDBM model */ unsigned int hash; for (hash = 0; *str; str++) { hash = (*str) + (hash << 6) + (hash << 16) - hash; } return hash; } } PROXY_DECLARE(apr_status_t) ap_proxy_set_wstatus(char c, int set, proxy_worker *w) { unsigned int *status = &w->s->status; char flag = toupper(c); proxy_wstat_t *pwt = proxy_wstat_tbl; while (pwt->bit) { if (flag == pwt->flag) { if (set) *status |= pwt->bit; else *status &= ~(pwt->bit); return APR_SUCCESS; } pwt++; } return APR_EINVAL; } PROXY_DECLARE(char *) ap_proxy_parse_wstatus(apr_pool_t *p, proxy_worker *w) { char *ret = ""; unsigned int status = w->s->status; proxy_wstat_t *pwt = proxy_wstat_tbl; while (pwt->bit) { if (status & pwt->bit) ret = apr_pstrcat(p, ret, pwt->name, NULL); pwt++; } if (!*ret) { ret = "??? "; } if (PROXY_WORKER_IS_USABLE(w)) ret = apr_pstrcat(p, ret, "Ok ", NULL); return ret; } PROXY_DECLARE(apr_status_t) ap_proxy_sync_balancer(proxy_balancer *b, server_rec *s, proxy_server_conf *conf) { proxy_worker **workers; int i; int index; proxy_worker_shared *shm; proxy_balancer_method *lbmethod; ap_slotmem_provider_t *storage = b->storage; if (b->s->wupdated <= b->wupdated) return APR_SUCCESS; /* balancer sync */ lbmethod = ap_lookup_provider(PROXY_LBMETHOD, b->s->lbpname, "0"); if (lbmethod) { b->lbmethod = lbmethod; } else { ap_log_error(APLOG_MARK, APLOG_CRIT, 0, s, APLOGNO(02433) "Cannot find LB Method: %s", b->s->lbpname); return APR_EINVAL; } /* worker sync */ /* * Look thru the list of workers in shm * and see which one(s) we are lacking... * again, the cast to unsigned int is safe * since our upper limit is always max_workers * which is int. */ for (index = 0; index < b->max_workers; index++) { int found; apr_status_t rv; if ((rv = storage->dptr(b->wslot, (unsigned int)index, (void *)&shm)) != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_EMERG, rv, s, APLOGNO(00965) "worker slotmem_dptr failed"); return APR_EGENERAL; } /* account for possible "holes" in the slotmem * (eg: slots 0-2 are used, but 3 isn't, but 4-5 is) */ if (!shm->hash.def || !shm->hash.fnv) continue; found = 0; workers = (proxy_worker **)b->workers->elts; for (i = 0; i < b->workers->nelts; i++, workers++) { proxy_worker *worker = *workers; if (worker->hash.def == shm->hash.def && worker->hash.fnv == shm->hash.fnv) { found = 1; ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(02402) "re-grabbing shm[%d] (0x%pp) for worker: %s", i, (void *)shm, ap_proxy_worker_name(conf->pool, worker)); break; } } if (!found) { proxy_worker **runtime; /* XXX: a thread mutex is maybe enough here */ apr_global_mutex_lock(proxy_mutex); runtime = apr_array_push(b->workers); *runtime = apr_pcalloc(conf->pool, sizeof(proxy_worker)); apr_global_mutex_unlock(proxy_mutex); (*runtime)->hash = shm->hash; (*runtime)->balancer = b; (*runtime)->s = shm; rv = ap_proxy_initialize_worker(*runtime, s, conf->pool); if (rv != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_EMERG, rv, s, APLOGNO(00966) "Cannot init worker"); return rv; } ap_log_error(APLOG_MARK, APLOG_DEBUG, 0, s, APLOGNO(02403) "grabbing shm[%d] (0x%pp) for worker: %s", i, (void *)shm, (*runtime)->s->name_ex); } } if (b->s->need_reset) { if (b->lbmethod && b->lbmethod->reset) b->lbmethod->reset(b, s); b->s->need_reset = 0; } b->wupdated = b->s->wupdated; return APR_SUCCESS; } PROXY_DECLARE(proxy_worker_shared *) ap_proxy_find_workershm(ap_slotmem_provider_t *storage, ap_slotmem_instance_t *slot, proxy_worker *worker, unsigned int *index) { proxy_worker_shared *shm; unsigned int i, limit; limit = storage->num_slots(slot); for (i = 0; i < limit; i++) { if (storage->dptr(slot, i, (void *)&shm) != APR_SUCCESS) { return NULL; } if ((worker->s->hash.def == shm->hash.def) && (worker->s->hash.fnv == shm->hash.fnv)) { *index = i; return shm; } } return NULL; } PROXY_DECLARE(proxy_balancer_shared *) ap_proxy_find_balancershm(ap_slotmem_provider_t *storage, ap_slotmem_instance_t *slot, proxy_balancer *balancer, unsigned int *index) { proxy_balancer_shared *shm; unsigned int i, limit; limit = storage->num_slots(slot); for (i = 0; i < limit; i++) { if (storage->dptr(slot, i, (void *)&shm) != APR_SUCCESS) { return NULL; } if ((balancer->s->hash.def == shm->hash.def) && (balancer->s->hash.fnv == shm->hash.fnv)) { *index = i; return shm; } } return NULL; } typedef struct header_connection { apr_pool_t *pool; apr_array_header_t *array; const char *first; unsigned int closed:1; } header_connection; static int find_conn_headers(void *data, const char *key, const char *val) { header_connection *x = data; const char *name; do { while (*val == ',' || *val == ';') { val++; } name = ap_get_token(x->pool, &val, 0); if (!strcasecmp(name, "close")) { x->closed = 1; } if (!x->first) { x->first = name; } else { const char **elt; if (!x->array) { x->array = apr_array_make(x->pool, 4, sizeof(char *)); } elt = apr_array_push(x->array); *elt = name; } } while (*val); return 1; } /** * Remove all headers referred to by the Connection header. */ static int ap_proxy_clear_connection(request_rec *r, apr_table_t *headers) { const char **name; header_connection x; x.pool = r->pool; x.array = NULL; x.first = NULL; x.closed = 0; apr_table_unset(headers, "Proxy-Connection"); apr_table_do(find_conn_headers, &x, headers, "Connection", NULL); if (x.first) { /* fast path - no memory allocated for one header */ apr_table_unset(headers, "Connection"); apr_table_unset(headers, x.first); } if (x.array) { /* two or more headers */ while ((name = apr_array_pop(x.array))) { apr_table_unset(headers, *name); } } return x.closed; } PROXY_DECLARE(int) ap_proxy_create_hdrbrgd(apr_pool_t *p, apr_bucket_brigade *header_brigade, request_rec *r, proxy_conn_rec *p_conn, proxy_worker *worker, proxy_server_conf *conf, apr_uri_t *uri, char *url, char *server_portstr, char **old_cl_val, char **old_te_val) { int rc = OK; conn_rec *c = r->connection; int counter; char *buf; apr_table_t *saved_headers_in = r->headers_in; const char *saved_host = apr_table_get(saved_headers_in, "Host"); const apr_array_header_t *headers_in_array; const apr_table_entry_t *headers_in; apr_bucket *e; int force10 = 0, do_100_continue = 0; conn_rec *origin = p_conn->connection; const char *host, *val; proxy_dir_conf *dconf = ap_get_module_config(r->per_dir_config, &proxy_module); /* * HTTP "Ping" test? Easiest is 100-Continue. However: * To be compliant, we only use 100-Continue for requests with bodies. * We also make sure we won't be talking HTTP/1.0 as well. */ if (apr_table_get(r->subprocess_env, "force-proxy-request-1.0")) { force10 = 1; } else if (apr_table_get(r->notes, "proxy-100-continue") || PROXY_SHOULD_PING_100_CONTINUE(worker, r)) { do_100_continue = 1; } if (force10 || apr_table_get(r->subprocess_env, "proxy-nokeepalive")) { if (origin) { origin->keepalive = AP_CONN_CLOSE; } p_conn->close = 1; } if (force10) { buf = apr_pstrcat(p, r->method, " ", url, " HTTP/1.0" CRLF, NULL); } else { buf = apr_pstrcat(p, r->method, " ", url, " HTTP/1.1" CRLF, NULL); } ap_xlate_proto_to_ascii(buf, strlen(buf)); e = apr_bucket_pool_create(buf, strlen(buf), p, c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(header_brigade, e); /* * Make a copy on r->headers_in for the request we make to the backend, * modify the copy in place according to our configuration and connection * handling, use it to fill in the forwarded headers' brigade, and finally * restore the saved/original ones in r->headers_in. * * Note: We need to take r->pool for apr_table_copy as the key / value * pairs in r->headers_in have been created out of r->pool and * p might be (and actually is) a longer living pool. * This would trigger the bad pool ancestry abort in apr_table_copy if * apr is compiled with APR_POOL_DEBUG. * * icing: if p indeed lives longer than r->pool, we should allocate * all new header values from r->pool as well and avoid leakage. */ r->headers_in = apr_table_copy(r->pool, saved_headers_in); /* Return the original Transfer-Encoding and/or Content-Length values * then drop the headers, they must be set by the proxy handler based * on the actual body being forwarded. */ if ((*old_te_val = (char *)apr_table_get(r->headers_in, "Transfer-Encoding"))) { apr_table_unset(r->headers_in, "Transfer-Encoding"); } if ((*old_cl_val = (char *)apr_table_get(r->headers_in, "Content-Length"))) { apr_table_unset(r->headers_in, "Content-Length"); } /* Clear out hop-by-hop request headers not to forward */ if (ap_proxy_clear_connection(r, r->headers_in) < 0) { rc = HTTP_BAD_REQUEST; goto cleanup; } /* RFC2616 13.5.1 says we should strip these */ apr_table_unset(r->headers_in, "Keep-Alive"); apr_table_unset(r->headers_in, "Upgrade"); apr_table_unset(r->headers_in, "Trailer"); apr_table_unset(r->headers_in, "TE"); /* Compute Host header */ if (dconf->preserve_host == 0) { if (ap_strchr_c(uri->hostname, ':')) { /* if literal IPv6 address */ if (uri->port_str && uri->port != DEFAULT_HTTP_PORT) { host = apr_pstrcat(r->pool, "[", uri->hostname, "]:", uri->port_str, NULL); } else { host = apr_pstrcat(r->pool, "[", uri->hostname, "]", NULL); } } else { if (uri->port_str && uri->port != DEFAULT_HTTP_PORT) { host = apr_pstrcat(r->pool, uri->hostname, ":", uri->port_str, NULL); } else { host = uri->hostname; } } apr_table_setn(r->headers_in, "Host", host); } else { /* don't want to use r->hostname as the incoming header might have a * port attached, let's use the original header. */ host = saved_host; if (!host) { host = r->server->server_hostname; ap_log_rerror(APLOG_MARK, APLOG_WARNING, 0, r, APLOGNO(01092) "no HTTP 0.9 request (with no host line) " "on incoming request and preserve host set " "forcing hostname to be %s for uri %s", host, r->uri); apr_table_setn(r->headers_in, "Host", host); } } /* handle Via */ if (conf->viaopt == via_block) { /* Block all outgoing Via: headers */ apr_table_unset(r->headers_in, "Via"); } else if (conf->viaopt != via_off) { const char *server_name = ap_get_server_name(r); /* If USE_CANONICAL_NAME_OFF was configured for the proxy virtual host, * then the server name returned by ap_get_server_name() is the * origin server name (which does make too much sense with Via: headers) * so we use the proxy vhost's name instead. */ if (server_name == r->hostname) server_name = r->server->server_hostname; /* Create a "Via:" request header entry and merge it */ /* Generate outgoing Via: header with/without server comment: */ apr_table_mergen(r->headers_in, "Via", (conf->viaopt == via_full) ? apr_psprintf(p, "%d.%d %s%s (%s)", HTTP_VERSION_MAJOR(r->proto_num), HTTP_VERSION_MINOR(r->proto_num), server_name, server_portstr, AP_SERVER_BASEVERSION) : apr_psprintf(p, "%d.%d %s%s", HTTP_VERSION_MAJOR(r->proto_num), HTTP_VERSION_MINOR(r->proto_num), server_name, server_portstr) ); } /* Use HTTP/1.1 100-Continue as quick "HTTP ping" test * to backend */ if (do_100_continue) { /* Add the Expect header if not already there. */ if (!(val = apr_table_get(r->headers_in, "Expect")) || (ap_cstr_casecmp(val, "100-Continue") != 0 /* fast path */ && !ap_find_token(r->pool, val, "100-Continue"))) { apr_table_mergen(r->headers_in, "Expect", "100-Continue"); } } else { /* XXX: we should strip the 100-continue token only from the * Expect header, but are there others actually used anywhere? */ apr_table_unset(r->headers_in, "Expect"); } /* X-Forwarded-*: handling * * XXX Privacy Note: * ----------------- * * These request headers are only really useful when the mod_proxy * is used in a reverse proxy configuration, so that useful info * about the client can be passed through the reverse proxy and on * to the backend server, which may require the information to * function properly. * * In a forward proxy situation, these options are a potential * privacy violation, as information about clients behind the proxy * are revealed to arbitrary servers out there on the internet. * * The HTTP/1.1 Via: header is designed for passing client * information through proxies to a server, and should be used in * a forward proxy configuration instead of X-Forwarded-*. See the * ProxyVia option for details. */ if (dconf->add_forwarded_headers) { if (PROXYREQ_REVERSE == r->proxyreq) { /* Add X-Forwarded-For: so that the upstream has a chance to * determine, where the original request came from. */ apr_table_mergen(r->headers_in, "X-Forwarded-For", r->useragent_ip); /* Add X-Forwarded-Host: so that upstream knows what the * original request hostname was. */ if (saved_host) { apr_table_mergen(r->headers_in, "X-Forwarded-Host", saved_host); } /* Add X-Forwarded-Server: so that upstream knows what the * name of this proxy server is (if there are more than one) * XXX: This duplicates Via: - do we strictly need it? */ apr_table_mergen(r->headers_in, "X-Forwarded-Server", r->server->server_hostname); } } /* Do we want to strip Proxy-Authorization ? * If we haven't used it, then NO * If we have used it then MAYBE: RFC2616 says we MAY propagate it. * So let's make it configurable by env. */ if (r->user != NULL /* we've authenticated */ && !apr_table_get(r->subprocess_env, "Proxy-Chain-Auth")) { apr_table_unset(r->headers_in, "Proxy-Authorization"); } /* for sub-requests, ignore freshness/expiry headers */ if (r->main) { apr_table_unset(r->headers_in, "If-Match"); apr_table_unset(r->headers_in, "If-Modified-Since"); apr_table_unset(r->headers_in, "If-Range"); apr_table_unset(r->headers_in, "If-Unmodified-Since"); apr_table_unset(r->headers_in, "If-None-Match"); } /* run hook to fixup the request we are about to send */ proxy_run_fixups(r); /* We used to send `Host: ` always first, so let's keep it that * way. No telling which legacy backend is relying on this. * If proxy_run_fixups() changed the value, use it (though removal * is ignored). */ val = apr_table_get(r->headers_in, "Host"); if (val) { apr_table_unset(r->headers_in, "Host"); host = val; } buf = apr_pstrcat(p, "Host: ", host, CRLF, NULL); ap_xlate_proto_to_ascii(buf, strlen(buf)); e = apr_bucket_pool_create(buf, strlen(buf), p, c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(header_brigade, e); /* Append the (remaining) headers to the brigade */ headers_in_array = apr_table_elts(r->headers_in); headers_in = (const apr_table_entry_t *) headers_in_array->elts; for (counter = 0; counter < headers_in_array->nelts; counter++) { if (headers_in[counter].key == NULL || headers_in[counter].val == NULL) { continue; } buf = apr_pstrcat(p, headers_in[counter].key, ": ", headers_in[counter].val, CRLF, NULL); ap_xlate_proto_to_ascii(buf, strlen(buf)); e = apr_bucket_pool_create(buf, strlen(buf), p, c->bucket_alloc); APR_BRIGADE_INSERT_TAIL(header_brigade, e); } cleanup: r->headers_in = saved_headers_in; return rc; } PROXY_DECLARE(int) ap_proxy_prefetch_input(request_rec *r, proxy_conn_rec *backend, apr_bucket_brigade *input_brigade, apr_read_type_e block, apr_off_t *bytes_read, apr_off_t max_read) { apr_pool_t *p = r->pool; conn_rec *c = r->connection; apr_bucket_brigade *temp_brigade; apr_status_t status; apr_off_t bytes; *bytes_read = 0; if (max_read < APR_BUCKET_BUFF_SIZE) { max_read = APR_BUCKET_BUFF_SIZE; } /* Prefetch max_read bytes * * This helps us avoid any election of C-L v.s. T-E * request bodies, since we are willing to keep in * memory this much data, in any case. This gives * us an instant C-L election if the body is of some * reasonable size. */ temp_brigade = apr_brigade_create(p, input_brigade->bucket_alloc); /* Account for saved input, if any. */ apr_brigade_length(input_brigade, 0, bytes_read); /* Ensure we don't hit a wall where we have a buffer too small for * ap_get_brigade's filters to fetch us another bucket, surrender * once we hit 80 bytes (an arbitrary value) less than max_read. */ while (*bytes_read < max_read - 80 && (APR_BRIGADE_EMPTY(input_brigade) || !APR_BUCKET_IS_EOS(APR_BRIGADE_LAST(input_brigade)))) { status = ap_get_brigade(r->input_filters, temp_brigade, AP_MODE_READBYTES, block, max_read - *bytes_read); /* ap_get_brigade may return success with an empty brigade * for a non-blocking read which would block */ if (block == APR_NONBLOCK_READ && ((status == APR_SUCCESS && APR_BRIGADE_EMPTY(temp_brigade)) || APR_STATUS_IS_EAGAIN(status))) { break; } if (status != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, status, r, APLOGNO(01095) "prefetch request body failed to %pI (%s)" " from %s (%s)", backend->addr, backend->hostname ? backend->hostname : "", c->client_ip, c->remote_host ? c->remote_host : ""); return ap_map_http_request_error(status, HTTP_BAD_REQUEST); } apr_brigade_length(temp_brigade, 1, &bytes); *bytes_read += bytes; /* * Save temp_brigade in input_brigade. (At least) in the SSL case * temp_brigade contains transient buckets whose data would get * overwritten during the next call of ap_get_brigade in the loop. * ap_save_brigade ensures these buckets to be set aside. * Calling ap_save_brigade with NULL as filter is OK, because * input_brigade already has been created and does not need to get * created by ap_save_brigade. */ status = ap_save_brigade(NULL, &input_brigade, &temp_brigade, p); if (status != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, status, r, APLOGNO(01096) "processing prefetched request body failed" " to %pI (%s) from %s (%s)", backend->addr, backend->hostname ? backend->hostname : "", c->client_ip, c->remote_host ? c->remote_host : ""); return HTTP_INTERNAL_SERVER_ERROR; } } return OK; } PROXY_DECLARE(int) ap_proxy_read_input(request_rec *r, proxy_conn_rec *backend, apr_bucket_brigade *bb, apr_off_t max_read) { apr_bucket_alloc_t *bucket_alloc = bb->bucket_alloc; apr_read_type_e block = (backend->connection) ? APR_NONBLOCK_READ : APR_BLOCK_READ; apr_status_t status; int rv; for (;;) { apr_brigade_cleanup(bb); status = ap_get_brigade(r->input_filters, bb, AP_MODE_READBYTES, block, max_read); if (block == APR_BLOCK_READ || (!(status == APR_SUCCESS && APR_BRIGADE_EMPTY(bb)) && !APR_STATUS_IS_EAGAIN(status))) { break; } /* Flush and retry (blocking) */ apr_brigade_cleanup(bb); rv = ap_proxy_pass_brigade(bucket_alloc, r, backend, backend->connection, bb, 1); if (rv != OK) { return rv; } block = APR_BLOCK_READ; } if (status != APR_SUCCESS) { conn_rec *c = r->connection; ap_log_rerror(APLOG_MARK, APLOG_ERR, status, r, APLOGNO(02608) "read request body failed to %pI (%s)" " from %s (%s)", backend->addr, backend->hostname ? backend->hostname : "", c->client_ip, c->remote_host ? c->remote_host : ""); return ap_map_http_request_error(status, HTTP_BAD_REQUEST); } return OK; } PROXY_DECLARE(int) ap_proxy_spool_input(request_rec *r, proxy_conn_rec *backend, apr_bucket_brigade *input_brigade, apr_off_t *bytes_spooled, apr_off_t max_mem_spool) { apr_pool_t *p = r->pool; int seen_eos = 0, rv = OK; apr_status_t status = APR_SUCCESS; apr_bucket_alloc_t *bucket_alloc = input_brigade->bucket_alloc; apr_bucket_brigade *body_brigade; apr_bucket *e; apr_off_t bytes, fsize = 0; apr_file_t *tmpfile = NULL; *bytes_spooled = 0; body_brigade = apr_brigade_create(p, bucket_alloc); do { if (APR_BRIGADE_EMPTY(input_brigade)) { rv = ap_proxy_read_input(r, backend, input_brigade, HUGE_STRING_LEN); if (rv != OK) { return rv; } } /* If this brigade contains EOS, either stop or remove it. */ if (APR_BUCKET_IS_EOS(APR_BRIGADE_LAST(input_brigade))) { seen_eos = 1; } apr_brigade_length(input_brigade, 1, &bytes); if (*bytes_spooled + bytes > max_mem_spool) { /* can't spool any more in memory; write latest brigade to disk */ if (tmpfile == NULL) { const char *temp_dir; char *template; status = apr_temp_dir_get(&temp_dir, p); if (status != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, status, r, APLOGNO(01089) "search for temporary directory failed"); return HTTP_INTERNAL_SERVER_ERROR; } apr_filepath_merge(&template, temp_dir, "modproxy.tmp.XXXXXX", APR_FILEPATH_NATIVE, p); status = apr_file_mktemp(&tmpfile, template, 0, p); if (status != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, status, r, APLOGNO(01090) "creation of temporary file in directory " "%s failed", temp_dir); return HTTP_INTERNAL_SERVER_ERROR; } } for (e = APR_BRIGADE_FIRST(input_brigade); e != APR_BRIGADE_SENTINEL(input_brigade); e = APR_BUCKET_NEXT(e)) { const char *data; apr_size_t bytes_read, bytes_written; apr_bucket_read(e, &data, &bytes_read, APR_BLOCK_READ); status = apr_file_write_full(tmpfile, data, bytes_read, &bytes_written); if (status != APR_SUCCESS) { const char *tmpfile_name; if (apr_file_name_get(&tmpfile_name, tmpfile) != APR_SUCCESS) { tmpfile_name = "(unknown)"; } ap_log_rerror(APLOG_MARK, APLOG_ERR, status, r, APLOGNO(01091) "write to temporary file %s failed", tmpfile_name); return HTTP_INTERNAL_SERVER_ERROR; } AP_DEBUG_ASSERT(bytes_read == bytes_written); fsize += bytes_written; } apr_brigade_cleanup(input_brigade); } else { /* * Save input_brigade in body_brigade. (At least) in the SSL case * input_brigade contains transient buckets whose data would get * overwritten during the next call of ap_get_brigade in the loop. * ap_save_brigade ensures these buckets to be set aside. * Calling ap_save_brigade with NULL as filter is OK, because * body_brigade already has been created and does not need to get * created by ap_save_brigade. */ status = ap_save_brigade(NULL, &body_brigade, &input_brigade, p); if (status != APR_SUCCESS) { return HTTP_INTERNAL_SERVER_ERROR; } } *bytes_spooled += bytes; } while (!seen_eos); APR_BRIGADE_CONCAT(input_brigade, body_brigade); if (tmpfile) { apr_brigade_insert_file(input_brigade, tmpfile, 0, fsize, p); } if (apr_table_get(r->subprocess_env, "proxy-sendextracrlf")) { e = apr_bucket_immortal_create(CRLF_ASCII, 2, bucket_alloc); APR_BRIGADE_INSERT_TAIL(input_brigade, e); } if (tmpfile) { /* We dropped metadata buckets when spooling to tmpfile, * terminate with EOS to allow for flushing in a one go. */ e = apr_bucket_eos_create(bucket_alloc); APR_BRIGADE_INSERT_TAIL(input_brigade, e); } return OK; } PROXY_DECLARE(int) ap_proxy_pass_brigade(apr_bucket_alloc_t *bucket_alloc, request_rec *r, proxy_conn_rec *p_conn, conn_rec *origin, apr_bucket_brigade *bb, int flush) { apr_status_t status; apr_off_t transferred; if (flush) { apr_bucket *e = apr_bucket_flush_create(bucket_alloc); APR_BRIGADE_INSERT_TAIL(bb, e); } apr_brigade_length(bb, 0, &transferred); if (transferred != -1) p_conn->worker->s->transferred += transferred; status = ap_pass_brigade(origin->output_filters, bb); /* Cleanup the brigade now to avoid buckets lifetime * issues in case of error returned below. */ apr_brigade_cleanup(bb); if (status != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, status, r, APLOGNO(01084) "pass request body failed to %pI (%s)", p_conn->addr, p_conn->hostname); if (origin->aborted) { const char *ssl_note; if (((ssl_note = apr_table_get(origin->notes, "SSL_connect_rv")) != NULL) && (strcmp(ssl_note, "err") == 0)) { return ap_proxyerror(r, HTTP_INTERNAL_SERVER_ERROR, "Error during SSL Handshake with" " remote server"); } return APR_STATUS_IS_TIMEUP(status) ? HTTP_GATEWAY_TIME_OUT : HTTP_BAD_GATEWAY; } else { return HTTP_BAD_REQUEST; } } return OK; } /* Fill in unknown schemes from apr_uri_port_of_scheme() */ typedef struct proxy_schemes_t { const char *name; apr_port_t default_port; } proxy_schemes_t ; static proxy_schemes_t pschemes[] = { {"fcgi", 8000}, {"ajp", AJP13_DEF_PORT}, {"scgi", SCGI_DEF_PORT}, {"h2c", DEFAULT_HTTP_PORT}, {"h2", DEFAULT_HTTPS_PORT}, {"ws", DEFAULT_HTTP_PORT}, {"wss", DEFAULT_HTTPS_PORT}, { NULL, 0xFFFF } /* unknown port */ }; PROXY_DECLARE(apr_port_t) ap_proxy_port_of_scheme(const char *scheme) { if (scheme) { apr_port_t port; if ((port = apr_uri_port_of_scheme(scheme)) != 0) { return port; } else { proxy_schemes_t *pscheme; for (pscheme = pschemes; pscheme->name != NULL; ++pscheme) { if (ap_cstr_casecmp(scheme, pscheme->name) == 0) { return pscheme->default_port; } } } } return 0; } static APR_INLINE int ap_filter_should_yield(ap_filter_t *f) { return f->c->data_in_output_filters; } static APR_INLINE int ap_filter_output_pending(conn_rec *c) { ap_filter_t *f = c->output_filters; while (f->next) { f = f->next; } if (f->frec->filter_func.out_func(f, NULL)) { return AP_FILTER_ERROR; } return c->data_in_output_filters ? OK : DECLINED; } PROXY_DECLARE(apr_status_t) ap_proxy_buckets_lifetime_transform(request_rec *r, apr_bucket_brigade *from, apr_bucket_brigade *to) { apr_bucket *e; apr_bucket *new; const char *data; apr_size_t bytes; apr_status_t rv = APR_SUCCESS; apr_bucket_alloc_t *bucket_alloc = to->bucket_alloc; apr_brigade_cleanup(to); for (e = APR_BRIGADE_FIRST(from); e != APR_BRIGADE_SENTINEL(from); e = APR_BUCKET_NEXT(e)) { if (!APR_BUCKET_IS_METADATA(e)) { apr_bucket_read(e, &data, &bytes, APR_BLOCK_READ); new = apr_bucket_transient_create(data, bytes, bucket_alloc); APR_BRIGADE_INSERT_TAIL(to, new); } else if (APR_BUCKET_IS_FLUSH(e)) { new = apr_bucket_flush_create(bucket_alloc); APR_BRIGADE_INSERT_TAIL(to, new); } else if (APR_BUCKET_IS_EOS(e)) { new = apr_bucket_eos_create(bucket_alloc); APR_BRIGADE_INSERT_TAIL(to, new); } else { ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, APLOGNO(03304) "Unhandled bucket type of type %s in" " ap_proxy_buckets_lifetime_transform", e->type->name); rv = APR_EGENERAL; } } return rv; } /* An arbitrary large value to address pathological case where we keep * reading from one side only, without scheduling the other direction for * too long. This can happen with large MTU and small read buffers, like * micro-benchmarking huge files bidirectional transfer with client, proxy * and backend on localhost for instance. Though we could just ignore the * case and let the sender stop by itself at some point when/if it needs to * receive data, or the receiver stop when/if it needs to send... */ #define PROXY_TRANSFER_MAX_READS 10000 PROXY_DECLARE(apr_status_t) ap_proxy_transfer_between_connections( request_rec *r, conn_rec *c_i, conn_rec *c_o, apr_bucket_brigade *bb_i, apr_bucket_brigade *bb_o, const char *name, int *sent, apr_off_t bsize, int flags) { apr_status_t rv; int flush_each = 0; unsigned int num_reads = 0; #ifdef DEBUGGING apr_off_t len; #endif /* * Compat: since FLUSH_EACH is default (and zero) for legacy reasons, we * pretend it's no FLUSH_AFTER nor YIELD_PENDING flags, the latter because * flushing would defeat the purpose of checking for pending data (hence * determine whether or not the output chain/stack is full for stopping). */ if (!(flags & (AP_PROXY_TRANSFER_FLUSH_AFTER | AP_PROXY_TRANSFER_YIELD_PENDING))) { flush_each = 1; } for (;;) { apr_brigade_cleanup(bb_i); rv = ap_get_brigade(c_i->input_filters, bb_i, AP_MODE_READBYTES, APR_NONBLOCK_READ, bsize); if (rv != APR_SUCCESS) { if (!APR_STATUS_IS_EAGAIN(rv) && !APR_STATUS_IS_EOF(rv)) { ap_log_rerror(APLOG_MARK, APLOG_DEBUG, rv, r, APLOGNO(03308) "ap_proxy_transfer_between_connections: " "error on %s - ap_get_brigade", name); if (rv == APR_INCOMPLETE) { /* Don't return APR_INCOMPLETE, it'd mean "should yield" * for the caller, while it means "incomplete body" here * from ap_http_filter(), which is an error. */ rv = APR_EGENERAL; } } break; } if (c_o->aborted) { apr_brigade_cleanup(bb_i); flags &= ~AP_PROXY_TRANSFER_FLUSH_AFTER; rv = APR_EPIPE; break; } if (APR_BRIGADE_EMPTY(bb_i)) { break; } #ifdef DEBUGGING len = -1; apr_brigade_length(bb_i, 0, &len); ap_log_rerror(APLOG_MARK, APLOG_DEBUG, 0, r, APLOGNO(03306) "ap_proxy_transfer_between_connections: " "read %" APR_OFF_T_FMT " bytes from %s", len, name); #endif if (sent) { *sent = 1; } ap_proxy_buckets_lifetime_transform(r, bb_i, bb_o); if (flush_each) { apr_bucket *b; /* * Do not use ap_fflush here since this would cause the flush * bucket to be sent in a separate brigade afterwards which * causes some filters to set aside the buckets from the first * brigade and process them when FLUSH arrives in the second * brigade. As set asides of our transformed buckets involve * memory copying we try to avoid this. If we have the flush * bucket in the first brigade they directly process the * buckets without setting them aside. */ b = apr_bucket_flush_create(bb_o->bucket_alloc); APR_BRIGADE_INSERT_TAIL(bb_o, b); } rv = ap_pass_brigade(c_o->output_filters, bb_o); apr_brigade_cleanup(bb_o); if (rv != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, APLOGNO(03307) "ap_proxy_transfer_between_connections: " "error on %s - ap_pass_brigade", name); flags &= ~AP_PROXY_TRANSFER_FLUSH_AFTER; break; } /* Yield if the output filters stack is full? This is to avoid * blocking and give the caller a chance to POLLOUT async. */ if ((flags & AP_PROXY_TRANSFER_YIELD_PENDING) && ap_filter_should_yield(c_o->output_filters)) { int rc = ap_filter_output_pending(c_o); if (rc == OK) { ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "ap_proxy_transfer_between_connections: " "yield (output pending)"); rv = APR_INCOMPLETE; break; } if (rc != DECLINED) { rv = AP_FILTER_ERROR; break; } } /* Yield if we keep hold of the thread for too long? This gives * the caller a chance to schedule the other direction too. */ if ((flags & AP_PROXY_TRANSFER_YIELD_MAX_READS) && ++num_reads > PROXY_TRANSFER_MAX_READS) { ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, "ap_proxy_transfer_between_connections: " "yield (max reads)"); rv = APR_SUCCESS; break; } } if (flags & AP_PROXY_TRANSFER_FLUSH_AFTER) { ap_fflush(c_o->output_filters, bb_o); apr_brigade_cleanup(bb_o); } apr_brigade_cleanup(bb_i); ap_log_rerror(APLOG_MARK, APLOG_TRACE2, rv, r, "ap_proxy_transfer_between_connections complete (%s %pI)", (c_i == r->connection) ? "to" : "from", (c_i == r->connection) ? c_o->client_addr : c_i->client_addr); if (APR_STATUS_IS_EAGAIN(rv)) { rv = APR_SUCCESS; } return rv; } struct proxy_tunnel_conn { /* the other side of the tunnel */ struct proxy_tunnel_conn *other; conn_rec *c; const char *name; apr_pollfd_t *pfd; apr_bucket_brigade *bb; unsigned int down_in:1, down_out:1; }; PROXY_DECLARE(apr_status_t) ap_proxy_tunnel_create(proxy_tunnel_rec **ptunnel, request_rec *r, conn_rec *c_o, const char *scheme) { apr_status_t rv; conn_rec *c_i = r->connection; apr_interval_time_t timeout = -1; proxy_tunnel_rec *tunnel; *ptunnel = NULL; tunnel = apr_pcalloc(r->pool, sizeof(*tunnel)); rv = apr_pollset_create(&tunnel->pollset, 2, r->pool, APR_POLLSET_NOCOPY); if (rv != APR_SUCCESS) { return rv; } tunnel->r = r; tunnel->scheme = apr_pstrdup(r->pool, scheme); tunnel->client = apr_pcalloc(r->pool, sizeof(struct proxy_tunnel_conn)); tunnel->origin = apr_pcalloc(r->pool, sizeof(struct proxy_tunnel_conn)); tunnel->pfds = apr_array_make(r->pool, 2, sizeof(apr_pollfd_t)); tunnel->read_buf_size = ap_get_read_buf_size(r); tunnel->client->other = tunnel->origin; tunnel->origin->other = tunnel->client; tunnel->timeout = -1; tunnel->client->c = c_i; tunnel->client->name = "client"; tunnel->client->bb = apr_brigade_create(c_i->pool, c_i->bucket_alloc); tunnel->client->pfd = &APR_ARRAY_PUSH(tunnel->pfds, apr_pollfd_t); tunnel->client->pfd->p = r->pool; tunnel->client->pfd->desc_type = APR_POLL_SOCKET; tunnel->client->pfd->desc.s = ap_get_conn_socket(c_i); tunnel->client->pfd->client_data = tunnel->client; tunnel->origin->c = c_o; tunnel->origin->name = "origin"; tunnel->origin->bb = apr_brigade_create(c_o->pool, c_o->bucket_alloc); tunnel->origin->pfd = &APR_ARRAY_PUSH(tunnel->pfds, apr_pollfd_t); tunnel->origin->pfd->p = r->pool; tunnel->origin->pfd->desc_type = APR_POLL_SOCKET; tunnel->origin->pfd->desc.s = ap_get_conn_socket(c_o); tunnel->origin->pfd->client_data = tunnel->origin; /* Defaults to the biggest timeout of both connections */ apr_socket_timeout_get(tunnel->client->pfd->desc.s, &timeout); apr_socket_timeout_get(tunnel->origin->pfd->desc.s, &tunnel->timeout); if (timeout >= 0 && (tunnel->timeout < 0 || tunnel->timeout < timeout)) { tunnel->timeout = timeout; } /* We should be nonblocking from now on the sockets */ apr_socket_opt_set(tunnel->client->pfd->desc.s, APR_SO_NONBLOCK, 1); apr_socket_opt_set(tunnel->origin->pfd->desc.s, APR_SO_NONBLOCK, 1); /* No coalescing filters */ ap_remove_output_filter_byhandle(c_i->output_filters, "SSL/TLS Coalescing Filter"); ap_remove_output_filter_byhandle(c_o->output_filters, "SSL/TLS Coalescing Filter"); /* Bidirectional non-HTTP stream will confuse mod_reqtimeoout */ ap_remove_input_filter_byhandle(c_i->input_filters, "reqtimeout"); /* The input/output filter stacks should contain connection filters only */ r->input_filters = r->proto_input_filters = c_i->input_filters; r->output_filters = r->proto_output_filters = c_i->output_filters; /* Won't be reused after tunneling */ c_i->keepalive = AP_CONN_CLOSE; c_o->keepalive = AP_CONN_CLOSE; /* Disable half-close forwarding for this request? */ if (apr_table_get(r->subprocess_env, "proxy-nohalfclose")) { tunnel->nohalfclose = 1; } /* Start with POLLOUT and let ap_proxy_tunnel_run() schedule both * directions when there are no output data pending (anymore). */ tunnel->client->pfd->reqevents = APR_POLLOUT | APR_POLLERR; tunnel->origin->pfd->reqevents = APR_POLLOUT | APR_POLLERR; if ((rv = apr_pollset_add(tunnel->pollset, tunnel->client->pfd)) || (rv = apr_pollset_add(tunnel->pollset, tunnel->origin->pfd))) { return rv; } *ptunnel = tunnel; return APR_SUCCESS; } static void add_pollset(apr_pollset_t *pollset, apr_pollfd_t *pfd, apr_int16_t events) { apr_status_t rv; AP_DEBUG_ASSERT((pfd->reqevents & events) == 0); if (pfd->reqevents) { rv = apr_pollset_remove(pollset, pfd); if (rv != APR_SUCCESS) { AP_DEBUG_ASSERT(1); } } if (events & APR_POLLIN) { events |= APR_POLLHUP; } pfd->reqevents |= events | APR_POLLERR; rv = apr_pollset_add(pollset, pfd); if (rv != APR_SUCCESS) { AP_DEBUG_ASSERT(1); } } static void del_pollset(apr_pollset_t *pollset, apr_pollfd_t *pfd, apr_int16_t events) { apr_status_t rv; AP_DEBUG_ASSERT((pfd->reqevents & events) != 0); rv = apr_pollset_remove(pollset, pfd); if (rv != APR_SUCCESS) { AP_DEBUG_ASSERT(0); return; } if (events & APR_POLLIN) { events |= APR_POLLHUP; } if (pfd->reqevents & ~(events | APR_POLLERR)) { pfd->reqevents &= ~events; rv = apr_pollset_add(pollset, pfd); if (rv != APR_SUCCESS) { AP_DEBUG_ASSERT(0); return; } } else { pfd->reqevents = 0; } } static int proxy_tunnel_forward(proxy_tunnel_rec *tunnel, struct proxy_tunnel_conn *in) { struct proxy_tunnel_conn *out = in->other; apr_status_t rv; int sent = 0; ap_log_rerror(APLOG_MARK, APLOG_TRACE8, 0, tunnel->r, "proxy: %s: %s input ready", tunnel->scheme, in->name); rv = ap_proxy_transfer_between_connections(tunnel->r, in->c, out->c, in->bb, out->bb, in->name, &sent, tunnel->read_buf_size, AP_PROXY_TRANSFER_YIELD_PENDING | AP_PROXY_TRANSFER_YIELD_MAX_READS); if (sent && out == tunnel->client) { tunnel->replied = 1; } if (rv != APR_SUCCESS) { if (APR_STATUS_IS_INCOMPLETE(rv)) { /* Pause POLLIN while waiting for POLLOUT on the other * side, hence avoid filling the output filters even * more to avoid blocking there. */ ap_log_rerror(APLOG_MARK, APLOG_TRACE5, 0, tunnel->r, "proxy: %s: %s wait writable", tunnel->scheme, out->name); } else if (APR_STATUS_IS_EOF(rv)) { /* Stop POLLIN and wait for POLLOUT (flush) on the * other side to shut it down. */ ap_log_rerror(APLOG_MARK, APLOG_TRACE3, 0, tunnel->r, "proxy: %s: %s read shutdown", tunnel->scheme, in->name); if (tunnel->nohalfclose) { /* No half-close forwarding, we are done both ways as * soon as one side shuts down. */ return DONE; } in->down_in = 1; } else { /* Real failure, bail out */ return HTTP_INTERNAL_SERVER_ERROR; } del_pollset(tunnel->pollset, in->pfd, APR_POLLIN); add_pollset(tunnel->pollset, out->pfd, APR_POLLOUT); } return OK; } PROXY_DECLARE(int) ap_proxy_tunnel_run(proxy_tunnel_rec *tunnel) { int status = OK, rc; request_rec *r = tunnel->r; apr_pollset_t *pollset = tunnel->pollset; struct proxy_tunnel_conn *client = tunnel->client, *origin = tunnel->origin; apr_interval_time_t timeout = tunnel->timeout >= 0 ? tunnel->timeout : -1; const char *scheme = tunnel->scheme; apr_status_t rv; ap_log_rerror(APLOG_MARK, APLOG_TRACE1, 0, r, APLOGNO(10212) "proxy: %s: tunnel running (timeout %lf)", scheme, timeout >= 0 ? (double)timeout / APR_USEC_PER_SEC : (double)-1.0); /* Loop until both directions of the connection are closed, * or a failure occurs. */ do { const apr_pollfd_t *results; apr_int32_t nresults, i; ap_log_rerror(APLOG_MARK, APLOG_TRACE8, 0, r, "proxy: %s: polling (client=%hx, origin=%hx)", scheme, client->pfd->reqevents, origin->pfd->reqevents); do { rv = apr_pollset_poll(pollset, timeout, &nresults, &results); } while (APR_STATUS_IS_EINTR(rv)); if (rv != APR_SUCCESS) { if (APR_STATUS_IS_TIMEUP(rv)) { ap_log_rerror(APLOG_MARK, APLOG_TRACE2, 0, r, APLOGNO(10213) "proxy: %s: polling timed out " "(client=%hx, origin=%hx)", scheme, client->pfd->reqevents, origin->pfd->reqevents); status = HTTP_GATEWAY_TIME_OUT; } else { ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, APLOGNO(10214) "proxy: %s: polling failed", scheme); status = HTTP_INTERNAL_SERVER_ERROR; } goto done; } ap_log_rerror(APLOG_MARK, APLOG_TRACE8, 0, r, APLOGNO(10215) "proxy: %s: woken up, %i result(s)", scheme, nresults); for (i = 0; i < nresults; i++) { const apr_pollfd_t *pfd = &results[i]; struct proxy_tunnel_conn *tc = pfd->client_data; ap_log_rerror(APLOG_MARK, APLOG_TRACE8, 0, r, "proxy: %s: #%i: %s: %hx/%hx", scheme, i, tc->name, pfd->rtnevents, tc->pfd->reqevents); /* sanity check */ if (pfd->desc.s != client->pfd->desc.s && pfd->desc.s != origin->pfd->desc.s) { ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, APLOGNO(10222) "proxy: %s: unknown socket in pollset", scheme); status = HTTP_INTERNAL_SERVER_ERROR; goto done; } if (!(pfd->rtnevents & (APR_POLLIN | APR_POLLOUT | APR_POLLHUP | APR_POLLERR))) { /* this catches POLLNVAL etc.. */ ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, APLOGNO(10220) "proxy: %s: polling events error (%x)", scheme, pfd->rtnevents); status = HTTP_INTERNAL_SERVER_ERROR; goto done; } /* We want to write if we asked for POLLOUT and got: * - POLLOUT: the socket is ready for write; * - !POLLIN: the socket is in error state (POLLERR) so we let * the user know by failing the write and log, OR the socket * is shutdown for read already (POLLHUP) so we have to * shutdown for write. */ if ((tc->pfd->reqevents & APR_POLLOUT) && ((pfd->rtnevents & APR_POLLOUT) || !(tc->pfd->reqevents & APR_POLLIN) || !(pfd->rtnevents & (APR_POLLIN | APR_POLLHUP)))) { struct proxy_tunnel_conn *out = tc, *in = tc->other; ap_log_rerror(APLOG_MARK, APLOG_TRACE8, 0, r, "proxy: %s: %s output ready", scheme, out->name); rc = ap_filter_output_pending(out->c); if (rc == OK) { /* Keep polling out (only) */ continue; } if (rc != DECLINED) { /* Real failure, bail out */ ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, APLOGNO(10221) "proxy: %s: %s flushing failed (%i)", scheme, out->name, rc); status = rc; goto done; } /* No more pending data. If the other side is not readable * anymore it's time to shutdown for write (this direction * is over). Otherwise back to normal business. */ del_pollset(pollset, out->pfd, APR_POLLOUT); if (in->down_in) { ap_log_rerror(APLOG_MARK, APLOG_TRACE3, 0, r, "proxy: %s: %s write shutdown", scheme, out->name); apr_socket_shutdown(out->pfd->desc.s, 1); out->down_out = 1; } else { ap_log_rerror(APLOG_MARK, APLOG_TRACE5, 0, r, "proxy: %s: %s resume writable", scheme, out->name); add_pollset(pollset, in->pfd, APR_POLLIN); /* Flush any pending input data now, we don't know when * the next POLLIN will trigger and retaining data might * deadlock the underlying protocol. We don't check for * pending data first with ap_filter_input_pending() since * the read from proxy_tunnel_forward() is nonblocking * anyway and returning OK if there's no data. */ rc = proxy_tunnel_forward(tunnel, in); if (rc != OK) { status = rc; goto done; } } } /* We want to read if we asked for POLLIN|HUP and got: * - POLLIN|HUP: the socket is ready for read or EOF (POLLHUP); * - !POLLOUT: the socket is in error state (POLLERR) so we let * the user know by failing the read and log. */ if ((tc->pfd->reqevents & APR_POLLIN) && ((pfd->rtnevents & (APR_POLLIN | APR_POLLHUP)) || !(pfd->rtnevents & APR_POLLOUT))) { rc = proxy_tunnel_forward(tunnel, tc); if (rc != OK) { status = rc; goto done; } } } } while (!client->down_out || !origin->down_out); done: ap_log_rerror(APLOG_MARK, APLOG_TRACE1, 0, r, APLOGNO(10223) "proxy: %s: tunneling returns (%i)", scheme, status); if (status == DONE) { status = OK; } return status; } PROXY_DECLARE (const char *) ap_proxy_show_hcmethod(hcmethod_t method) { proxy_hcmethods_t *m = proxy_hcmethods; for (; m->name; m++) { if (m->method == method) { return m->name; } } return "???"; } void proxy_util_register_hooks(apr_pool_t *p) { APR_REGISTER_OPTIONAL_FN(ap_proxy_retry_worker); APR_REGISTER_OPTIONAL_FN(ap_proxy_clear_connection); APR_REGISTER_OPTIONAL_FN(proxy_balancer_get_best_worker); }