/********************************************************************* * * File : $Source: /cvsroot/ijbswa/current/gateway.c,v $ * * Purpose : Contains functions to connect to a server, possibly * using a "forwarder" (i.e. HTTP proxy and/or a SOCKS4 * or SOCKS5 proxy). * * Copyright : Written by and Copyright (C) 2001-2020 the * Privoxy team. https://www.privoxy.org/ * * Based on the Internet Junkbuster originally written * by and Copyright (C) 1997 Anonymous Coders and * Junkbusters Corporation. http://www.junkbusters.com * * This program is free software; you can redistribute it * and/or modify it under the terms of the GNU General * Public License as published by the Free Software * Foundation; either version 2 of the License, or (at * your option) any later version. * * This program is distributed in the hope that it will * be useful, but WITHOUT ANY WARRANTY; without even the * implied warranty of MERCHANTABILITY or FITNESS FOR A * PARTICULAR PURPOSE. See the GNU General Public * License for more details. * * The GNU General Public License should be included with * this file. If not, you can view it at * http://www.gnu.org/copyleft/gpl.html * or write to the Free Software Foundation, Inc., 59 * Temple Place - Suite 330, Boston, MA 02111-1307, USA. * *********************************************************************/ #include "config.h" #include #include #ifndef _WIN32 #include #endif #include #include #include "assert.h" #ifdef _WIN32 #include #endif /* def _WIN32 */ #ifdef __BEOS__ #include #endif /* def __BEOS__ */ #include "project.h" #include "jcc.h" #include "errlog.h" #include "jbsockets.h" #include "gateway.h" #include "miscutil.h" #include "list.h" #include "parsers.h" #ifdef FEATURE_CONNECTION_KEEP_ALIVE #ifdef HAVE_POLL #ifdef __GLIBC__ #include #else #include #endif /* def __GLIBC__ */ #endif /* HAVE_POLL */ #endif /* def FEATURE_CONNECTION_KEEP_ALIVE */ static jb_socket socks4_connect(const struct forward_spec *fwd, const char *target_host, int target_port, struct client_state *csp); static jb_socket socks5_connect(const struct forward_spec *fwd, const char *target_host, int target_port, struct client_state *csp); enum { SOCKS4_REQUEST_GRANTED = 90, SOCKS4_REQUEST_REJECT = 91, SOCKS4_REQUEST_IDENT_FAILED = 92, SOCKS4_REQUEST_IDENT_CONFLICT = 93 }; enum { SOCKS5_REQUEST_GRANTED = 0, SOCKS5_REQUEST_FAILED = 1, SOCKS5_REQUEST_DENIED = 2, SOCKS5_REQUEST_NETWORK_UNREACHABLE = 3, SOCKS5_REQUEST_HOST_UNREACHABLE = 4, SOCKS5_REQUEST_CONNECTION_REFUSED = 5, SOCKS5_REQUEST_TTL_EXPIRED = 6, SOCKS5_REQUEST_PROTOCOL_ERROR = 7, SOCKS5_REQUEST_BAD_ADDRESS_TYPE = 8 }; /* structure of a socks client operation */ struct socks_op { unsigned char vn; /* socks version number */ unsigned char cd; /* command code */ unsigned char dstport[2]; /* destination port */ unsigned char dstip[4]; /* destination address */ char userid; /* first byte of userid */ char padding[3]; /* make sure sizeof(struct socks_op) is endian-independent. */ /* more bytes of the userid follow, terminated by a NULL */ }; /* structure of a socks server reply */ struct socks_reply { unsigned char vn; /* socks version number */ unsigned char cd; /* command code */ unsigned char dstport[2]; /* destination port */ unsigned char dstip[4]; /* destination address */ }; static const char socks_userid[] = "anonymous"; #ifdef FEATURE_CONNECTION_SHARING #ifndef FEATURE_CONNECTION_KEEP_ALIVE #error Using FEATURE_CONNECTION_SHARING without FEATURE_CONNECTION_KEEP_ALIVE is impossible #endif #define MAX_REUSABLE_CONNECTIONS 100 static struct reusable_connection reusable_connection[MAX_REUSABLE_CONNECTIONS]; static int mark_connection_unused(const struct reusable_connection *connection); /********************************************************************* * * Function : initialize_reusable_connections * * Description : Initializes the reusable_connection structures. * Must be called with connection_reuse_mutex locked. * * Parameters : N/A * * Returns : void * *********************************************************************/ extern void initialize_reusable_connections(void) { unsigned int slot = 0; #if !defined(HAVE_POLL) && !defined(_WIN32) log_error(LOG_LEVEL_INFO, "Detecting already dead connections might not work " "correctly on your platform. In case of problems, " "unset the keep-alive-timeout option."); #endif for (slot = 0; slot < SZ(reusable_connection); slot++) { mark_connection_closed(&reusable_connection[slot]); } log_error(LOG_LEVEL_CONNECT, "Initialized %d socket slots.", slot); } /********************************************************************* * * Function : remember_connection * * Description : Remembers a server connection for reuse later on. * * Parameters : * 1 : connection = The server connection to remember. * * Returns : void * *********************************************************************/ void remember_connection(const struct reusable_connection *connection) { unsigned int slot = 0; int free_slot_found = FALSE; assert(NULL != connection); assert(connection->sfd != JB_INVALID_SOCKET); if (mark_connection_unused(connection)) { return; } privoxy_mutex_lock(&connection_reuse_mutex); /* Find free socket slot. */ for (slot = 0; slot < SZ(reusable_connection); slot++) { if (reusable_connection[slot].sfd == JB_INVALID_SOCKET) { assert(reusable_connection[slot].in_use == 0); log_error(LOG_LEVEL_CONNECT, "Remembering socket %d for %s:%d in slot %d.", connection->sfd, connection->host, connection->port, slot); free_slot_found = TRUE; break; } } if (!free_slot_found) { log_error(LOG_LEVEL_CONNECT, "No free slots found to remember socket for %s:%d. Last slot %d.", connection->host, connection->port, slot); privoxy_mutex_unlock(&connection_reuse_mutex); close_socket(connection->sfd); return; } assert(slot < SZ(reusable_connection)); assert(NULL != connection->host); reusable_connection[slot].host = strdup_or_die(connection->host); reusable_connection[slot].sfd = connection->sfd; reusable_connection[slot].port = connection->port; reusable_connection[slot].in_use = 0; reusable_connection[slot].timestamp = connection->timestamp; reusable_connection[slot].request_sent = connection->request_sent; reusable_connection[slot].response_received = connection->response_received; reusable_connection[slot].keep_alive_timeout = connection->keep_alive_timeout; reusable_connection[slot].requests_sent_total = connection->requests_sent_total; assert(reusable_connection[slot].gateway_host == NULL); assert(reusable_connection[slot].gateway_port == 0); assert(reusable_connection[slot].auth_username == NULL); assert(reusable_connection[slot].auth_password == NULL); assert(reusable_connection[slot].forwarder_type == SOCKS_NONE); assert(reusable_connection[slot].forward_host == NULL); assert(reusable_connection[slot].forward_port == 0); reusable_connection[slot].forwarder_type = connection->forwarder_type; if (NULL != connection->gateway_host) { reusable_connection[slot].gateway_host = strdup_or_die(connection->gateway_host); } else { reusable_connection[slot].gateway_host = NULL; } reusable_connection[slot].gateway_port = connection->gateway_port; if (NULL != connection->auth_username) { reusable_connection[slot].auth_username = strdup_or_die(connection->auth_username); } else { reusable_connection[slot].auth_username = NULL; } if (NULL != connection->auth_password) { reusable_connection[slot].auth_password = strdup_or_die(connection->auth_password); } else { reusable_connection[slot].auth_password = NULL; } if (NULL != connection->forward_host) { reusable_connection[slot].forward_host = strdup_or_die(connection->forward_host); } else { reusable_connection[slot].forward_host = NULL; } reusable_connection[slot].forward_port = connection->forward_port; privoxy_mutex_unlock(&connection_reuse_mutex); } #endif /* def FEATURE_CONNECTION_SHARING */ /********************************************************************* * * Function : mark_connection_closed * * Description : Marks a reused connection closed. * * Parameters : * 1 : closed_connection = The connection to mark as closed. * * Returns : void * *********************************************************************/ void mark_connection_closed(struct reusable_connection *closed_connection) { closed_connection->in_use = FALSE; closed_connection->sfd = JB_INVALID_SOCKET; freez(closed_connection->host); closed_connection->port = 0; closed_connection->timestamp = 0; closed_connection->request_sent = 0; closed_connection->response_received = 0; closed_connection->keep_alive_timeout = 0; closed_connection->requests_sent_total = 0; closed_connection->forwarder_type = SOCKS_NONE; freez(closed_connection->gateway_host); closed_connection->gateway_port = 0; freez(closed_connection->auth_username); freez(closed_connection->auth_password); freez(closed_connection->forward_host); closed_connection->forward_port = 0; } #ifdef FEATURE_CONNECTION_SHARING /********************************************************************* * * Function : forget_connection * * Description : Removes a previously remembered connection from * the list of reusable connections. * * Parameters : * 1 : sfd = The socket belonging to the connection in question. * * Returns : void * *********************************************************************/ void forget_connection(jb_socket sfd) { unsigned int slot = 0; assert(sfd != JB_INVALID_SOCKET); privoxy_mutex_lock(&connection_reuse_mutex); for (slot = 0; slot < SZ(reusable_connection); slot++) { if (reusable_connection[slot].sfd == sfd) { assert(reusable_connection[slot].in_use); log_error(LOG_LEVEL_CONNECT, "Forgetting socket %d for %s:%d in slot %d.", sfd, reusable_connection[slot].host, reusable_connection[slot].port, slot); mark_connection_closed(&reusable_connection[slot]); break; } } privoxy_mutex_unlock(&connection_reuse_mutex); } #endif /* def FEATURE_CONNECTION_SHARING */ #ifdef FEATURE_CONNECTION_KEEP_ALIVE /********************************************************************* * * Function : string_or_none * * Description : Returns a given string or "none" if a NULL pointer * is given. * Helper function for connection_destination_matches(). * * Parameters : * 1 : string = The string to check. * * Returns : The string if non-NULL, "none" otherwise. * *********************************************************************/ static const char *string_or_none(const char *string) { return(string != NULL ? string : "none"); } /********************************************************************* * * Function : connection_detail_matches * * Description : Helper function for connection_destination_matches(). * Compares strings which can be NULL. * * Parameters : * 1 : connection_detail = The connection detail to compare. * 2 : fowarder_detail = The forwarder detail to compare. * * Returns : TRUE for yes, FALSE otherwise. * *********************************************************************/ static int connection_detail_matches(const char *connection_detail, const char *forwarder_detail) { if (connection_detail == NULL && forwarder_detail == NULL) { /* Both details are unset. */ return TRUE; } if ((connection_detail == NULL && forwarder_detail != NULL) || (connection_detail != NULL && forwarder_detail == NULL)) { /* Only one detail isn't set. */ return FALSE; } /* Both details are set, but do they match? */ return(!strcmpic(connection_detail, forwarder_detail)); } /********************************************************************* * * Function : connection_destination_matches * * Description : Determines whether a remembered connection can * be reused. That is, whether the destination and * the forwarding settings match. * * Parameters : * 1 : connection = The connection to check. * 2 : http = The destination for the connection. * 3 : fwd = The forwarder settings. * * Returns : TRUE for yes, FALSE otherwise. * *********************************************************************/ int connection_destination_matches(const struct reusable_connection *connection, const struct http_request *http, const struct forward_spec *fwd) { if ((connection->forwarder_type != fwd->type) || (connection->gateway_port != fwd->gateway_port) || (connection->forward_port != fwd->forward_port) || (connection->port != http->port)) { return FALSE; } if (!connection_detail_matches(connection->gateway_host, fwd->gateway_host)) { log_error(LOG_LEVEL_CONNECT, "Gateway mismatch. Previous gateway: %s. Current gateway: %s", string_or_none(connection->gateway_host), string_or_none(fwd->gateway_host)); return FALSE; } if (!connection_detail_matches(connection->auth_username, fwd->auth_username)) { log_error(LOG_LEVEL_CONNECT, "Socks user name mismatch. " "Previous user name: %s. Current user name: %s", string_or_none(connection->auth_username), string_or_none(fwd->auth_username)); return FALSE; } if (!connection_detail_matches(connection->auth_password, fwd->auth_password)) { log_error(LOG_LEVEL_CONNECT, "Socks user name mismatch. " "Previous password: %s. Current password: %s", string_or_none(connection->auth_password), string_or_none(fwd->auth_password)); return FALSE; } if (!connection_detail_matches(connection->forward_host, fwd->forward_host)) { log_error(LOG_LEVEL_CONNECT, "Forwarding proxy mismatch. Previous proxy: %s. Current proxy: %s", string_or_none(connection->forward_host), string_or_none(fwd->forward_host)); return FALSE; } return (!strcmpic(connection->host, http->host)); } #endif /* def FEATURE_CONNECTION_KEEP_ALIVE */ #ifdef FEATURE_CONNECTION_SHARING /********************************************************************* * * Function : close_unusable_connections * * Description : Closes remembered connections that have timed * out or have been closed on the other side. * * Parameters : none * * Returns : Number of connections that are still alive. * *********************************************************************/ int close_unusable_connections(void) { unsigned int slot = 0; int connections_alive = 0; privoxy_mutex_lock(&connection_reuse_mutex); for (slot = 0; slot < SZ(reusable_connection); slot++) { if (!reusable_connection[slot].in_use && (JB_INVALID_SOCKET != reusable_connection[slot].sfd)) { time_t time_open = time(NULL) - reusable_connection[slot].timestamp; time_t latency = (reusable_connection[slot].response_received - reusable_connection[slot].request_sent) / 2; if (reusable_connection[slot].keep_alive_timeout < time_open + latency) { log_error(LOG_LEVEL_CONNECT, "The connection to %s:%d in slot %d timed out. " "Closing socket %d. Timeout is: %d. Assumed latency: %ld.", reusable_connection[slot].host, reusable_connection[slot].port, slot, reusable_connection[slot].sfd, reusable_connection[slot].keep_alive_timeout, latency); close_socket(reusable_connection[slot].sfd); mark_connection_closed(&reusable_connection[slot]); } else if (!socket_is_still_alive(reusable_connection[slot].sfd)) { log_error(LOG_LEVEL_CONNECT, "The connection to %s:%d in slot %d is no longer usable. " "Closing socket %d.", reusable_connection[slot].host, reusable_connection[slot].port, slot, reusable_connection[slot].sfd); close_socket(reusable_connection[slot].sfd); mark_connection_closed(&reusable_connection[slot]); } else { connections_alive++; } } } privoxy_mutex_unlock(&connection_reuse_mutex); return connections_alive; } /********************************************************************* * * Function : get_reusable_connection * * Description : Returns an open socket to a previously remembered * open connection (if there is one). * * Parameters : * 1 : http = The destination for the connection. * 2 : fwd = The forwarder settings. * * Returns : JB_INVALID_SOCKET => No reusable connection found, * otherwise a usable socket. * *********************************************************************/ static jb_socket get_reusable_connection(const struct http_request *http, const struct forward_spec *fwd) { jb_socket sfd = JB_INVALID_SOCKET; unsigned int slot = 0; close_unusable_connections(); privoxy_mutex_lock(&connection_reuse_mutex); for (slot = 0; slot < SZ(reusable_connection); slot++) { if (!reusable_connection[slot].in_use && (JB_INVALID_SOCKET != reusable_connection[slot].sfd)) { if (connection_destination_matches(&reusable_connection[slot], http, fwd)) { reusable_connection[slot].in_use = TRUE; sfd = reusable_connection[slot].sfd; log_error(LOG_LEVEL_CONNECT, "Found reusable socket %d for %s:%d in slot %d. Timestamp made %ld " "seconds ago. Timeout: %d. Latency: %d. Requests served: %d", sfd, reusable_connection[slot].host, reusable_connection[slot].port, slot, time(NULL) - reusable_connection[slot].timestamp, reusable_connection[slot].keep_alive_timeout, (int)(reusable_connection[slot].response_received - reusable_connection[slot].request_sent), reusable_connection[slot].requests_sent_total); break; } } } privoxy_mutex_unlock(&connection_reuse_mutex); return sfd; } /********************************************************************* * * Function : mark_connection_unused * * Description : Gives a remembered connection free for reuse. * * Parameters : * 1 : connection = The connection in question. * * Returns : TRUE => Socket found and marked as unused. * FALSE => Socket not found. * *********************************************************************/ static int mark_connection_unused(const struct reusable_connection *connection) { unsigned int slot = 0; int socket_found = FALSE; assert(connection->sfd != JB_INVALID_SOCKET); privoxy_mutex_lock(&connection_reuse_mutex); for (slot = 0; slot < SZ(reusable_connection); slot++) { if (reusable_connection[slot].sfd == connection->sfd) { assert(reusable_connection[slot].in_use); socket_found = TRUE; log_error(LOG_LEVEL_CONNECT, "Marking open socket %d for %s:%d in slot %d as unused.", connection->sfd, reusable_connection[slot].host, reusable_connection[slot].port, slot); reusable_connection[slot].in_use = 0; reusable_connection[slot].timestamp = connection->timestamp; break; } } privoxy_mutex_unlock(&connection_reuse_mutex); return socket_found; } #endif /* def FEATURE_CONNECTION_SHARING */ /********************************************************************* * * Function : forwarded_connect * * Description : Connect to a specified web server, possibly via * a HTTP proxy and/or a SOCKS proxy. * * Parameters : * 1 : fwd = the proxies to use when connecting. * 2 : http = the http request and apropos headers * 3 : csp = Current client state (buffers, headers, etc...) * * Returns : JB_INVALID_SOCKET => failure, else it is the socket file descriptor. * *********************************************************************/ jb_socket forwarded_connect(const struct forward_spec *fwd, struct http_request *http, struct client_state *csp) { const char *dest_host; int dest_port; jb_socket sfd = JB_INVALID_SOCKET; #ifdef FEATURE_CONNECTION_SHARING if ((csp->config->feature_flags & RUNTIME_FEATURE_CONNECTION_SHARING) && !(csp->flags & CSP_FLAG_SERVER_SOCKET_TAINTED)) { sfd = get_reusable_connection(http, fwd); if (JB_INVALID_SOCKET != sfd) { return sfd; } } #endif /* def FEATURE_CONNECTION_SHARING */ /* Figure out if we need to connect to the web server or a HTTP proxy. */ if (fwd->forward_host) { /* HTTP proxy */ dest_host = fwd->forward_host; dest_port = fwd->forward_port; } else { /* Web server */ dest_host = http->host; dest_port = http->port; } /* Connect, maybe using a SOCKS proxy */ switch (fwd->type) { case SOCKS_NONE: case FORWARD_WEBSERVER: sfd = connect_to(dest_host, dest_port, csp); break; case SOCKS_4: case SOCKS_4A: sfd = socks4_connect(fwd, dest_host, dest_port, csp); break; case SOCKS_5: case SOCKS_5T: sfd = socks5_connect(fwd, dest_host, dest_port, csp); break; default: /* Should never get here */ log_error(LOG_LEVEL_FATAL, "Internal error in forwarded_connect(). Bad proxy type: %d", fwd->type); } if (JB_INVALID_SOCKET != sfd) { log_error(LOG_LEVEL_CONNECT, "Created new connection to %s:%d on socket %d.", http->host, http->port, sfd); } return sfd; } #ifdef FUZZ /********************************************************************* * * Function : socks_fuzz * * Description : Wrapper around socks[45]_connect() used for fuzzing. * * Parameters : * 1 : csp = Current client state (buffers, headers, etc...) * * Returns : JB_ERR_OK or JB_ERR_PARSE * *********************************************************************/ extern jb_err socks_fuzz(struct client_state *csp) { jb_socket socket; static struct forward_spec fwd; char target_host[] = "fuzz.example.org"; int target_port = 12345; fwd.gateway_host = strdup_or_die("fuzz.example.org"); fwd.gateway_port = 12345; fwd.type = SOCKS_4A; socket = socks4_connect(&fwd, target_host, target_port, csp); if (JB_INVALID_SOCKET != socket) { fwd.type = SOCKS_5; socket = socks5_connect(&fwd, target_host, target_port, csp); } if (JB_INVALID_SOCKET == socket) { log_error(LOG_LEVEL_ERROR, "%s", csp->error_message); return JB_ERR_PARSE; } log_error(LOG_LEVEL_INFO, "Input looks like an acceptable socks response"); return JB_ERR_OK; } #endif /********************************************************************* * * Function : socks4_connect * * Description : Connect to the SOCKS server, and connect through * it to the specified server. This handles * all the SOCKS negotiation, and returns a file * descriptor for a socket which can be treated as a * normal (non-SOCKS) socket. * * Logged error messages are saved to csp->error_message * and later reused by error_response() for the CGI * message. strdup allocation failures are handled there. * * Parameters : * 1 : fwd = Specifies the SOCKS proxy to use. * 2 : target_host = The final server to connect to. * 3 : target_port = The final port to connect to. * 4 : csp = Current client state (buffers, headers, etc...) * * Returns : JB_INVALID_SOCKET => failure, else a socket file descriptor. * *********************************************************************/ static jb_socket socks4_connect(const struct forward_spec *fwd, const char *target_host, int target_port, struct client_state *csp) { unsigned long web_server_addr; char buf[BUFFER_SIZE]; struct socks_op *c = (struct socks_op *)buf; struct socks_reply *s = (struct socks_reply *)buf; size_t n; size_t csiz; jb_socket sfd; int err = 0; char *errstr = NULL; if ((fwd->gateway_host == NULL) || (*fwd->gateway_host == '\0')) { /* XXX: Shouldn't the config file parser prevent this? */ errstr = "NULL gateway host specified."; err = 1; } if (fwd->gateway_port <= 0) { errstr = "invalid gateway port specified."; err = 1; } if (err) { log_error(LOG_LEVEL_CONNECT, "socks4_connect: %s", errstr); csp->error_message = strdup(errstr); errno = EINVAL; return(JB_INVALID_SOCKET); } /* build a socks request for connection to the web server */ strlcpy(&(c->userid), socks_userid, sizeof(buf) - sizeof(struct socks_op)); csiz = sizeof(*c) + sizeof(socks_userid) - sizeof(c->userid) - sizeof(c->padding); switch (fwd->type) { case SOCKS_4: web_server_addr = resolve_hostname_to_ip(target_host); if (web_server_addr == INADDR_NONE) { errstr = "could not resolve target host"; log_error(LOG_LEVEL_CONNECT, "socks4_connect: %s %s", errstr, target_host); err = 1; } else { web_server_addr = htonl(web_server_addr); } break; case SOCKS_4A: web_server_addr = 0x00000001; n = csiz + strlen(target_host) + 1; if (n > sizeof(buf)) { errno = EINVAL; errstr = "buffer cbuf too small."; log_error(LOG_LEVEL_CONNECT, "socks4_connect: %s", errstr); err = 1; } else { strlcpy(buf + csiz, target_host, sizeof(buf) - sizeof(struct socks_op) - csiz); /* * What we forward to the socks4a server should have the * size of socks_op, plus the length of the userid plus * its \0 byte (which we don't have to add because the * first byte of the userid is counted twice as it's also * part of sock_op) minus the padding bytes (which are part * of the userid as well), plus the length of the target_host * (which is stored csiz bytes after the beginning of the buffer), * plus another \0 byte. */ assert(n == sizeof(struct socks_op) + strlen(&(c->userid)) - sizeof(c->padding) + strlen(buf + csiz) + 1); csiz = n; } break; default: /* Should never get here */ log_error(LOG_LEVEL_FATAL, "socks4_connect: SOCKS4 impossible internal error - bad SOCKS type."); /* Not reached */ return(JB_INVALID_SOCKET); } if (err) { csp->error_message = strdup(errstr); return(JB_INVALID_SOCKET); } c->vn = 4; c->cd = 1; c->dstport[0] = (unsigned char)((target_port >> 8 ) & 0xff); c->dstport[1] = (unsigned char)((target_port ) & 0xff); c->dstip[0] = (unsigned char)((web_server_addr >> 24) & 0xff); c->dstip[1] = (unsigned char)((web_server_addr >> 16) & 0xff); c->dstip[2] = (unsigned char)((web_server_addr >> 8) & 0xff); c->dstip[3] = (unsigned char)((web_server_addr ) & 0xff); #ifdef FUZZ sfd = 0; #else /* pass the request to the socks server */ sfd = connect_to(fwd->gateway_host, fwd->gateway_port, csp); if (sfd == JB_INVALID_SOCKET) { /* The error an its reason have already been logged by connect_to() */ return(JB_INVALID_SOCKET); } else if (write_socket(sfd, (char *)c, csiz)) { errstr = "SOCKS4 negotiation write failed."; log_error(LOG_LEVEL_CONNECT, "socks4_connect: %s", errstr); err = 1; close_socket(sfd); } else if (!data_is_available(sfd, csp->config->socket_timeout)) { if (socket_is_still_alive(sfd)) { errstr = "SOCKS4 negotiation timed out"; } else { errstr = "SOCKS4 negotiation got aborted by the server"; } log_error(LOG_LEVEL_CONNECT, "socks4_connect: %s", errstr); err = 1; close_socket(sfd); } else #endif if (read_socket(sfd, buf, sizeof(buf)) != sizeof(*s)) { errstr = "SOCKS4 negotiation read failed."; log_error(LOG_LEVEL_CONNECT, "socks4_connect: %s", errstr); err = 1; close_socket(sfd); } if (err) { csp->error_message = strdup(errstr); return(JB_INVALID_SOCKET); } switch (s->cd) { case SOCKS4_REQUEST_GRANTED: return(sfd); case SOCKS4_REQUEST_REJECT: errstr = "SOCKS request rejected or failed."; errno = EINVAL; break; case SOCKS4_REQUEST_IDENT_FAILED: errstr = "SOCKS request rejected because " "SOCKS server cannot connect to identd on the client."; errno = EACCES; break; case SOCKS4_REQUEST_IDENT_CONFLICT: errstr = "SOCKS request rejected because " "the client program and identd report " "different user-ids."; errno = EACCES; break; default: errno = ENOENT; snprintf(buf, sizeof(buf), "SOCKS request rejected for reason code %d.", s->cd); errstr = buf; } log_error(LOG_LEVEL_CONNECT, "socks4_connect: %s", errstr); csp->error_message = strdup(errstr); close_socket(sfd); return(JB_INVALID_SOCKET); } /********************************************************************* * * Function : translate_socks5_error * * Description : Translates a SOCKS errors to a string. * * Parameters : * 1 : socks_error = The error code to translate. * * Returns : The string translation. * *********************************************************************/ static const char *translate_socks5_error(int socks_error) { switch (socks_error) { /* XXX: these should be more descriptive */ case SOCKS5_REQUEST_FAILED: return "SOCKS5 request failed"; case SOCKS5_REQUEST_DENIED: return "SOCKS5 request denied"; case SOCKS5_REQUEST_NETWORK_UNREACHABLE: return "SOCKS5 network unreachable"; case SOCKS5_REQUEST_HOST_UNREACHABLE: return "SOCKS5 destination host unreachable"; case SOCKS5_REQUEST_CONNECTION_REFUSED: return "SOCKS5 connection refused"; case SOCKS5_REQUEST_TTL_EXPIRED: return "SOCKS5 TTL expired"; case SOCKS5_REQUEST_PROTOCOL_ERROR: return "SOCKS5 client protocol error"; case SOCKS5_REQUEST_BAD_ADDRESS_TYPE: return "SOCKS5 domain names unsupported"; case SOCKS5_REQUEST_GRANTED: return "everything's peachy"; default: return "SOCKS5 negotiation protocol error"; } } /********************************************************************* * * Function : socks5_connect * * Description : Connect to the SOCKS server, and connect through * it to the specified server. This handles * all the SOCKS negotiation, and returns a file * descriptor for a socket which can be treated as a * normal (non-SOCKS) socket. * * Parameters : * 1 : fwd = Specifies the SOCKS proxy to use. * 2 : target_host = The final server to connect to. * 3 : target_port = The final port to connect to. * 4 : csp = Current client state (buffers, headers, etc...) * * Returns : JB_INVALID_SOCKET => failure, else a socket file descriptor. * *********************************************************************/ static jb_socket socks5_connect(const struct forward_spec *fwd, const char *target_host, int target_port, struct client_state *csp) { #define SIZE_SOCKS5_REPLY_IPV4 10 #define SIZE_SOCKS5_REPLY_IPV6 22 #define SOCKS5_REPLY_DIFFERENCE (SIZE_SOCKS5_REPLY_IPV6 - SIZE_SOCKS5_REPLY_IPV4) int err = 0; char cbuf[300]; char sbuf[SIZE_SOCKS5_REPLY_IPV6]; size_t client_pos = 0; int server_size = 0; size_t hostlen = 0; jb_socket sfd; const char *errstr = NULL; assert(fwd->gateway_host); if ((fwd->gateway_host == NULL) || (*fwd->gateway_host == '\0')) { errstr = "NULL gateway host specified"; err = 1; } if (fwd->gateway_port <= 0) { /* * XXX: currently this can't happen because in * case of invalid gateway ports we use the defaults. * Of course we really shouldn't do that. */ errstr = "invalid gateway port specified"; err = 1; } hostlen = strlen(target_host); if (hostlen > (size_t)255) { errstr = "target host name is longer than 255 characters"; err = 1; } if ((fwd->type != SOCKS_5) && (fwd->type != SOCKS_5T)) { /* Should never get here */ log_error(LOG_LEVEL_FATAL, "SOCKS5 impossible internal error - bad SOCKS type"); err = 1; } if (err) { errno = EINVAL; assert(errstr != NULL); log_error(LOG_LEVEL_CONNECT, "socks5_connect: %s", errstr); csp->error_message = strdup(errstr); return(JB_INVALID_SOCKET); } #ifdef FUZZ sfd = 0; if (!err && read_socket(sfd, sbuf, 2) != 2) #else /* pass the request to the socks server */ sfd = connect_to(fwd->gateway_host, fwd->gateway_port, csp); if (sfd == JB_INVALID_SOCKET) { errstr = "socks5 server unreachable"; log_error(LOG_LEVEL_CONNECT, "socks5_connect: %s", errstr); /* Free the generic error message provided by connect_to() */ freez(csp->error_message); csp->error_message = strdup(errstr); return(JB_INVALID_SOCKET); } client_pos = 0; cbuf[client_pos++] = '\x05'; /* Version */ if (fwd->auth_username && fwd->auth_password) { cbuf[client_pos++] = '\x02'; /* Two authentication methods supported */ cbuf[client_pos++] = '\x02'; /* Username/password */ } else { cbuf[client_pos++] = '\x01'; /* One authentication method supported */ } cbuf[client_pos++] = '\x00'; /* The no authentication authentication method */ if (write_socket(sfd, cbuf, client_pos)) { errstr = "SOCKS5 negotiation write failed"; csp->error_message = strdup(errstr); log_error(LOG_LEVEL_CONNECT, "%s", errstr); close_socket(sfd); return(JB_INVALID_SOCKET); } if (!data_is_available(sfd, csp->config->socket_timeout)) { if (socket_is_still_alive(sfd)) { errstr = "SOCKS5 negotiation timed out"; } else { errstr = "SOCKS5 negotiation got aborted by the server"; } err = 1; } if (!err && read_socket(sfd, sbuf, sizeof(sbuf)) != 2) #endif { errstr = "SOCKS5 negotiation read failed"; err = 1; } if (!err && (sbuf[0] != '\x05')) { errstr = "SOCKS5 negotiation protocol version error"; err = 1; } if (!err && (sbuf[1] == '\xff')) { errstr = "SOCKS5 authentication required"; err = 1; } if (!err && (sbuf[1] == '\x02')) { if (fwd->auth_username && fwd->auth_password) { /* check cbuf overflow */ size_t auth_len = strlen(fwd->auth_username) + strlen(fwd->auth_password) + 3; if (auth_len > sizeof(cbuf)) { errstr = "SOCKS5 username and/or password too long"; err = 1; } } else { errstr = "SOCKS5 server requested authentication while " "no credentials are configured"; err = 1; } if (!err) { client_pos = 0; cbuf[client_pos++] = '\x01'; /* Version */ cbuf[client_pos++] = (char)strlen(fwd->auth_username); memcpy(cbuf + client_pos, fwd->auth_username, strlen(fwd->auth_username)); client_pos += strlen(fwd->auth_username); cbuf[client_pos++] = (char)strlen(fwd->auth_password); memcpy(cbuf + client_pos, fwd->auth_password, strlen(fwd->auth_password)); client_pos += strlen(fwd->auth_password); if (write_socket(sfd, cbuf, client_pos)) { errstr = "SOCKS5 negotiation auth write failed"; csp->error_message = strdup(errstr); log_error(LOG_LEVEL_CONNECT, "%s", errstr); close_socket(sfd); return(JB_INVALID_SOCKET); } if (read_socket(sfd, sbuf, sizeof(sbuf)) != 2) { errstr = "SOCKS5 negotiation auth read failed"; err = 1; } } if (!err && (sbuf[1] != '\x00')) { errstr = "SOCKS5 authentication failed"; err = 1; } } else if (!err && (sbuf[1] != '\x00')) { errstr = "SOCKS5 negotiation protocol error"; err = 1; } if (err) { assert(errstr != NULL); log_error(LOG_LEVEL_CONNECT, "socks5_connect: %s", errstr); csp->error_message = strdup(errstr); close_socket(sfd); errno = EINVAL; return(JB_INVALID_SOCKET); } client_pos = 0; cbuf[client_pos++] = '\x05'; /* Version */ cbuf[client_pos++] = '\x01'; /* TCP connect */ cbuf[client_pos++] = '\x00'; /* Reserved, must be 0x00 */ cbuf[client_pos++] = '\x03'; /* Address is domain name */ cbuf[client_pos++] = (char)(hostlen & 0xffu); assert(sizeof(cbuf) - client_pos > (size_t)255); /* Using strncpy because we really want the nul byte padding. */ strncpy(cbuf + client_pos, target_host, sizeof(cbuf) - client_pos - 1); client_pos += (hostlen & 0xffu); cbuf[client_pos++] = (char)((target_port >> 8) & 0xff); cbuf[client_pos++] = (char)((target_port ) & 0xff); #ifndef FUZZ if (write_socket(sfd, cbuf, client_pos)) { errstr = "SOCKS5 negotiation write failed"; csp->error_message = strdup(errstr); log_error(LOG_LEVEL_CONNECT, "%s", errstr); close_socket(sfd); errno = EINVAL; return(JB_INVALID_SOCKET); } /* * Optimistically send the HTTP request with the initial * SOCKS request if the user enabled the use of Tor extensions, * the CONNECT method isn't being used (in which case the client * doesn't send data until it gets our 200 response) and the * client request has actually been completely read already. */ if ((fwd->type == SOCKS_5T) && (csp->http->ssl == 0) && (csp->flags & CSP_FLAG_CLIENT_REQUEST_COMPLETELY_READ)) { char *client_headers = list_to_text(csp->headers); size_t header_length; if (client_headers == NULL) { log_error(LOG_LEVEL_FATAL, "Out of memory rebuilding client headers"); } list_remove_all(csp->headers); header_length= strlen(client_headers); log_error(LOG_LEVEL_CONNECT, "Optimistically sending %lu bytes of client headers intended for %s", header_length, csp->http->hostport); if (write_socket(sfd, client_headers, header_length)) { log_error(LOG_LEVEL_CONNECT, "optimistically writing header to: %s failed: %E", csp->http->hostport); freez(client_headers); return(JB_INVALID_SOCKET); } freez(client_headers); if (csp->expected_client_content_length != 0) { unsigned long long buffered_request_bytes = (unsigned long long)(csp->client_iob->eod - csp->client_iob->cur); log_error(LOG_LEVEL_CONNECT, "Optimistically sending %llu bytes of client body. Expected %llu", csp->expected_client_content_length, buffered_request_bytes); assert(csp->expected_client_content_length == buffered_request_bytes); if (write_socket(sfd, csp->client_iob->cur, buffered_request_bytes)) { log_error(LOG_LEVEL_CONNECT, "optimistically writing %llu bytes of client body to: %s failed: %E", buffered_request_bytes, csp->http->hostport); return(JB_INVALID_SOCKET); } clear_iob(csp->client_iob); } } #endif server_size = read_socket(sfd, sbuf, SIZE_SOCKS5_REPLY_IPV4); if (server_size != SIZE_SOCKS5_REPLY_IPV4) { errstr = "SOCKS5 negotiation read failed"; } else { if (sbuf[0] != '\x05') { errstr = "SOCKS5 negotiation protocol version error"; } else if (sbuf[2] != '\x00') { errstr = "SOCKS5 negotiation protocol error"; } else if (sbuf[1] != SOCKS5_REQUEST_GRANTED) { errstr = translate_socks5_error(sbuf[1]); } else { if (sbuf[3] == '\x04') { /* * The address field contains an IPv6 address * which means we didn't get the whole reply * yet. Read and discard the rest of it to make * sure it isn't treated as HTTP data later on. */ server_size = read_socket(sfd, sbuf, SOCKS5_REPLY_DIFFERENCE); if (server_size != SOCKS5_REPLY_DIFFERENCE) { errstr = "SOCKS5 negotiation read failed (IPv6 address)"; } } else if (sbuf[3] != '\x01') { errstr = "SOCKS5 reply contains unsupported address type"; } if (errstr == NULL) { return(sfd); } } } assert(errstr != NULL); csp->error_message = strdup(errstr); log_error(LOG_LEVEL_CONNECT, "socks5_connect: %s", errstr); close_socket(sfd); errno = EINVAL; return(JB_INVALID_SOCKET); } /* Local Variables: tab-width: 3 end: */