/* Copyright 2001,2002,2003 Roger Dingledine, Matej Pfajfar. */ /* See LICENSE for licensing information */ /* $Id$ */ #include "or.h" extern or_options_t options; /* command-line and config-file options */ static void circuit_free_cpath(crypt_path_t *cpath); static void circuit_free_cpath_node(crypt_path_t *victim); static aci_t get_unique_aci_by_addr_port(uint32_t addr, uint16_t port, int aci_type); unsigned long stats_n_relay_cells_relayed = 0; unsigned long stats_n_relay_cells_delivered = 0; /********* START VARIABLES **********/ static circuit_t *global_circuitlist=NULL; char *circuit_state_to_string[] = { "receiving the onion", /* 0 */ "waiting to process create", /* 1 */ "connecting to firsthop", /* 2 */ "open" /* 3 */ }; /********* END VARIABLES ************/ void circuit_add(circuit_t *circ) { if(!global_circuitlist) { /* first one */ global_circuitlist = circ; circ->next = NULL; } else { circ->next = global_circuitlist; global_circuitlist = circ; } } void circuit_remove(circuit_t *circ) { circuit_t *tmpcirc; assert(circ && global_circuitlist); if(global_circuitlist == circ) { global_circuitlist = global_circuitlist->next; return; } for(tmpcirc = global_circuitlist;tmpcirc->next;tmpcirc = tmpcirc->next) { if(tmpcirc->next == circ) { tmpcirc->next = circ->next; return; } } } circuit_t *circuit_new(aci_t p_aci, connection_t *p_conn) { circuit_t *circ; circ = (circuit_t *)tor_malloc(sizeof(circuit_t)); memset(circ,0,sizeof(circuit_t)); /* zero it out */ circ->timestamp_created = time(NULL); circ->p_aci = p_aci; circ->p_conn = p_conn; circ->state = CIRCUIT_STATE_ONIONSKIN_PENDING; /* ACIs */ circ->p_aci = p_aci; /* circ->n_aci remains 0 because we haven't identified the next hop yet */ circ->package_window = CIRCWINDOW_START; circ->deliver_window = CIRCWINDOW_START; circuit_add(circ); return circ; } void circuit_free(circuit_t *circ) { if (circ->n_crypto) crypto_free_cipher_env(circ->n_crypto); if (circ->p_crypto) crypto_free_cipher_env(circ->p_crypto); circuit_free_cpath(circ->cpath); free(circ); } static void circuit_free_cpath(crypt_path_t *cpath) { crypt_path_t *victim, *head=cpath; if(!cpath) return; /* it's a doubly linked list, so we have to notice when we've * gone through it once. */ while(cpath->next && cpath->next != head) { victim = cpath; cpath = victim->next; circuit_free_cpath_node(victim); } circuit_free_cpath_node(cpath); } static void circuit_free_cpath_node(crypt_path_t *victim) { if(victim->f_crypto) crypto_free_cipher_env(victim->f_crypto); if(victim->b_crypto) crypto_free_cipher_env(victim->b_crypto); if(victim->handshake_state) crypto_dh_free(victim->handshake_state); free(victim); } /* return 0 if can't get a unique aci. */ static aci_t get_unique_aci_by_addr_port(uint32_t addr, uint16_t port, int aci_type) { aci_t test_aci; connection_t *conn; uint16_t high_bit; high_bit = (aci_type == ACI_TYPE_HIGHER) ? 1<<15 : 0; conn = connection_exact_get_by_addr_port(addr,port); /* XXX race condition: if conn is marked_for_close it won't be noticed */ if (!conn) return (1|high_bit); /* No connection exists; conflict is impossible. */ do { /* Sequentially iterate over test_aci=1...1<<15-1 until we find an * aci such that (high_bit|test_aci) is not already used. */ /* XXX Will loop forever if all aci's in our range are used. * This matters because it's an external DoS vulnerability. */ test_aci = conn->next_aci++; if (test_aci == 0 || test_aci >= 1<<15) { test_aci = 1; conn->next_aci = 2; } test_aci |= high_bit; } while(circuit_get_by_aci_conn(test_aci, conn)); return test_aci; } circuit_t *circuit_enumerate_by_naddr_nport(circuit_t *circ, uint32_t naddr, uint16_t nport) { if(!circ) /* use circ if it's defined, else start from the beginning */ circ = global_circuitlist; else circ = circ->next; for( ; circ; circ = circ->next) { if(circ->n_addr == naddr && circ->n_port == nport) return circ; } return NULL; } circuit_t *circuit_get_by_aci_conn(aci_t aci, connection_t *conn) { circuit_t *circ; connection_t *tmpconn; for(circ=global_circuitlist;circ;circ = circ->next) { if(circ->p_aci == aci) { if(circ->p_conn == conn) return circ; for(tmpconn = circ->p_streams; tmpconn; tmpconn = tmpconn->next_stream) { if(tmpconn == conn) return circ; } } if(circ->n_aci == aci) { if(circ->n_conn == conn) return circ; for(tmpconn = circ->n_streams; tmpconn; tmpconn = tmpconn->next_stream) { if(tmpconn == conn) return circ; } } } return NULL; } circuit_t *circuit_get_by_conn(connection_t *conn) { circuit_t *circ; connection_t *tmpconn; for(circ=global_circuitlist;circ;circ = circ->next) { if(circ->p_conn == conn) return circ; if(circ->n_conn == conn) return circ; for(tmpconn = circ->p_streams; tmpconn; tmpconn=tmpconn->next_stream) if(tmpconn == conn) return circ; for(tmpconn = circ->n_streams; tmpconn; tmpconn=tmpconn->next_stream) if(tmpconn == conn) return circ; } return NULL; } circuit_t *circuit_get_newest_open(void) { circuit_t *circ, *bestcirc=NULL; for(circ=global_circuitlist;circ;circ = circ->next) { if(circ->cpath && circ->state == CIRCUIT_STATE_OPEN && circ->n_conn && (!bestcirc || bestcirc->timestamp_created < circ->timestamp_created)) { log_fn(LOG_DEBUG,"Choosing circuit %s:%d:%d.", circ->n_conn->address, circ->n_port, circ->n_aci); assert(circ->n_aci); bestcirc = circ; } } return bestcirc; } int circuit_deliver_relay_cell(cell_t *cell, circuit_t *circ, int cell_direction, crypt_path_t *layer_hint) { connection_t *conn=NULL; char recognized=0; char buf[256]; assert(cell && circ); assert(cell_direction == CELL_DIRECTION_OUT || cell_direction == CELL_DIRECTION_IN); buf[0] = cell->length; memcpy(buf+1, cell->payload, CELL_PAYLOAD_SIZE); log_fn(LOG_DEBUG,"direction %d, streamid %d before crypt.", cell_direction, *(int*)(cell->payload+1)); if(relay_crypt(circ, buf, 1+CELL_PAYLOAD_SIZE, cell_direction, &layer_hint, &recognized, &conn) < 0) { log_fn(LOG_WARN,"relay crypt failed. Dropping connection."); return -1; } cell->length = buf[0]; memcpy(cell->payload, buf+1, CELL_PAYLOAD_SIZE); if(recognized) { if(cell_direction == CELL_DIRECTION_OUT) { ++stats_n_relay_cells_delivered; log_fn(LOG_DEBUG,"Sending to exit."); return connection_edge_process_relay_cell(cell, circ, conn, EDGE_EXIT, NULL); } if(cell_direction == CELL_DIRECTION_IN) { ++stats_n_relay_cells_delivered; log_fn(LOG_DEBUG,"Sending to AP."); return connection_edge_process_relay_cell(cell, circ, conn, EDGE_AP, layer_hint); } } ++stats_n_relay_cells_relayed; /* not recognized. pass it on. */ if(cell_direction == CELL_DIRECTION_OUT) conn = circ->n_conn; else conn = circ->p_conn; if(!conn) { //|| !connection_speaks_cells(conn)) { log_fn(LOG_INFO,"Didn't recognize cell (%d), but circ stops here! Dropping.", *(int *)(cell->payload+1)); return 0; } log_fn(LOG_DEBUG,"Passing on unrecognized cell."); connection_or_write_cell_to_buf(cell, conn); return 0; } int relay_crypt(circuit_t *circ, char *in, int inlen, char cell_direction, crypt_path_t **layer_hint, char *recognized, connection_t **conn) { crypt_path_t *thishop; char out[256]; assert(circ && in && recognized && conn); assert(inlen < 256); if(cell_direction == CELL_DIRECTION_IN) { if(circ->cpath) { /* we're at the beginning of the circuit. We'll want to do layered crypts. */ thishop = circ->cpath; if(thishop->state != CPATH_STATE_OPEN) { log_fn(LOG_WARN,"Relay cell before first created cell?"); return -1; } do { /* Remember: cpath is in forward order, that is, first hop first. */ assert(thishop); log_fn(LOG_DEBUG,"before decrypt: %d",*(int*)(in+2)); /* decrypt */ if(crypto_cipher_decrypt(thishop->b_crypto, in, inlen, out)) { log_fn(LOG_WARN,"Error performing onion decryption: %s", crypto_perror()); return -1; } memcpy(in,out,inlen); log_fn(LOG_DEBUG,"after decrypt: %d",*(int*)(in+2)); if( (*recognized = relay_check_recognized(circ, cell_direction, in+2, conn))) { *layer_hint = thishop; return 0; } thishop = thishop->next; } while(thishop != circ->cpath && thishop->state == CPATH_STATE_OPEN); log_fn(LOG_INFO,"in-cell at OP not recognized. Dropping."); return 0; } else { /* we're in the middle. Just one crypt. */ log_fn(LOG_DEBUG,"before encrypt: %d",*(int*)(in+2)); if(crypto_cipher_encrypt(circ->p_crypto, in, inlen, out)) { log_fn(LOG_WARN,"Onion encryption failed for ACI %u: %s", circ->p_aci, crypto_perror()); return -1; } memcpy(in,out,inlen); log_fn(LOG_DEBUG,"after encrypt: %d",*(int*)(in+2)); log_fn(LOG_DEBUG,"Skipping recognized check, because we're not the OP."); /* don't check for recognized. only the OP can recognize a stream on the way back. */ } } else if(cell_direction == CELL_DIRECTION_OUT) { if(circ->cpath) { /* we're at the beginning of the circuit. We'll want to do layered crypts. */ thishop = *layer_hint; /* we already know which layer, from when we package_raw_inbuf'ed */ /* moving from last to first hop */ do { assert(thishop); log_fn(LOG_DEBUG,"before encrypt: %d",*(int*)(in+2)); if(crypto_cipher_encrypt(thishop->f_crypto, in, inlen, out)) { log_fn(LOG_WARN,"Error performing encryption: %s", crypto_perror()); return -1; } memcpy(in,out,inlen); log_fn(LOG_DEBUG,"after encrypt: %d",*(int*)(in+2)); thishop = thishop->prev; } while(thishop != circ->cpath->prev); } else { /* we're in the middle. Just one crypt. */ if(crypto_cipher_decrypt(circ->n_crypto,in, inlen, out)) { log_fn(LOG_WARN,"Decryption failed for ACI %u: %s", circ->n_aci, crypto_perror()); return -1; } memcpy(in,out,inlen); if( (*recognized = relay_check_recognized(circ, cell_direction, in+2, conn))) return 0; } } else { log_fn(LOG_ERR,"unknown cell direction %d.", cell_direction); assert(0); } return 0; } int relay_check_recognized(circuit_t *circ, int cell_direction, char *stream, connection_t **conn) { /* FIXME can optimize by passing thishop in */ connection_t *tmpconn; if(!memcmp(stream,ZERO_STREAM,STREAM_ID_SIZE)) { log_fn(LOG_DEBUG,"It's the zero stream. Recognized."); return 1; /* the zero stream is always recognized */ } log_fn(LOG_DEBUG,"not the zero stream."); if(cell_direction == CELL_DIRECTION_OUT) tmpconn = circ->n_streams; else tmpconn = circ->p_streams; if(!tmpconn) { log_fn(LOG_DEBUG,"No conns. Not recognized."); return 0; } for( ; tmpconn; tmpconn=tmpconn->next_stream) { if(!memcmp(stream,tmpconn->stream_id, STREAM_ID_SIZE)) { log_fn(LOG_DEBUG,"recognized stream %d.", *(int*)stream); *conn = tmpconn; return 1; } log_fn(LOG_DEBUG,"considered stream %d, not it.",*(int*)tmpconn->stream_id); } log_fn(LOG_DEBUG,"Didn't recognize on this iteration of decryption."); return 0; } void circuit_resume_edge_reading(circuit_t *circ, int edge_type, crypt_path_t *layer_hint) { connection_t *conn; assert(edge_type == EDGE_EXIT || edge_type == EDGE_AP); log_fn(LOG_DEBUG,"resuming"); if(edge_type == EDGE_EXIT) conn = circ->n_streams; else conn = circ->p_streams; for( ; conn; conn=conn->next_stream) { if((edge_type == EDGE_EXIT && conn->package_window > 0) || (edge_type == EDGE_AP && conn->package_window > 0 && conn->cpath_layer == layer_hint)) { connection_start_reading(conn); connection_edge_package_raw_inbuf(conn); /* handle whatever might still be on the inbuf */ /* If the circuit won't accept any more data, return without looking * at any more of the streams. Any connections that should be stopped * have already been stopped by connection_edge_package_raw_inbuf. */ if(circuit_consider_stop_edge_reading(circ, edge_type, layer_hint)) return; } } } /* returns 1 if the window is empty, else 0. If it's empty, tell edge conns to stop reading. */ int circuit_consider_stop_edge_reading(circuit_t *circ, int edge_type, crypt_path_t *layer_hint) { connection_t *conn = NULL; assert(edge_type == EDGE_EXIT || edge_type == EDGE_AP); assert(edge_type == EDGE_EXIT || layer_hint); log_fn(LOG_DEBUG,"considering"); if(edge_type == EDGE_EXIT && circ->package_window <= 0) conn = circ->n_streams; else if(edge_type == EDGE_AP && layer_hint->package_window <= 0) conn = circ->p_streams; else return 0; for( ; conn; conn=conn->next_stream) if(!layer_hint || conn->cpath_layer == layer_hint) connection_stop_reading(conn); log_fn(LOG_DEBUG,"yes. stopped."); return 1; } int circuit_consider_sending_sendme(circuit_t *circ, int edge_type, crypt_path_t *layer_hint) { cell_t cell; assert(circ); memset(&cell, 0, sizeof(cell_t)); cell.command = CELL_RELAY; SET_CELL_RELAY_COMMAND(cell, RELAY_COMMAND_SENDME); SET_CELL_STREAM_ID(cell, ZERO_STREAM); cell.length = RELAY_HEADER_SIZE; if(edge_type == EDGE_AP) { /* i'm the AP */ cell.aci = circ->n_aci; while(layer_hint->deliver_window < CIRCWINDOW_START-CIRCWINDOW_INCREMENT) { log_fn(LOG_DEBUG,"deliver_window %d, Queueing sendme forward.", layer_hint->deliver_window); layer_hint->deliver_window += CIRCWINDOW_INCREMENT; if(circuit_deliver_relay_cell(&cell, circ, CELL_DIRECTION_OUT, layer_hint) < 0) { return -1; } } } else if(edge_type == EDGE_EXIT) { /* i'm the exit */ cell.aci = circ->p_aci; while(circ->deliver_window < CIRCWINDOW_START-CIRCWINDOW_INCREMENT) { log_fn(LOG_DEBUG,"deliver_window %d, Queueing sendme back.", circ->deliver_window); circ->deliver_window += CIRCWINDOW_INCREMENT; if(circuit_deliver_relay_cell(&cell, circ, CELL_DIRECTION_IN, layer_hint) < 0) { return -1; } } } return 0; } void circuit_close(circuit_t *circ) { connection_t *conn; circuit_t *youngest=NULL; assert(circ); if(options.APPort) { youngest = circuit_get_newest_open(); log_fn(LOG_DEBUG,"youngest %d, circ %d.",(int)youngest, (int)circ); } circuit_remove(circ); if(circ->n_conn) connection_send_destroy(circ->n_aci, circ->n_conn); for(conn=circ->n_streams; conn; conn=conn->next_stream) { connection_send_destroy(circ->n_aci, conn); } if(circ->p_conn) connection_send_destroy(circ->n_aci, circ->p_conn); for(conn=circ->p_streams; conn; conn=conn->next_stream) { connection_send_destroy(circ->p_aci, conn); } if(options.APPort && youngest == circ) { /* check this after we've sent the destroys, to reduce races */ /* our current circuit just died. Launch another one pronto. */ log_fn(LOG_INFO,"Youngest circuit dying. Launching a replacement."); circuit_launch_new(1); } circuit_free(circ); } void circuit_about_to_close_connection(connection_t *conn) { /* send destroys for all circuits using conn */ /* currently, we assume it's too late to flush conn's buf here. * down the road, maybe we'll consider that eof doesn't mean can't-write */ circuit_t *circ; connection_t *prevconn; if(!connection_speaks_cells(conn)) { /* it's an edge conn. need to remove it from the linked list of * conn's for this circuit. Send an 'end' relay command. * But don't kill the circuit. */ circ = circuit_get_by_conn(conn); if(!circ) return; if(conn == circ->p_streams) { circ->p_streams = conn->next_stream; goto send_end; } if(conn == circ->n_streams) { circ->n_streams = conn->next_stream; goto send_end; } for(prevconn = circ->p_streams; prevconn && prevconn->next_stream && prevconn->next_stream != conn; prevconn = prevconn->next_stream) ; if(prevconn && prevconn->next_stream) { prevconn->next_stream = conn->next_stream; goto send_end; } for(prevconn = circ->n_streams; prevconn && prevconn->next_stream && prevconn->next_stream != conn; prevconn = prevconn->next_stream) ; if(prevconn && prevconn->next_stream) { prevconn->next_stream = conn->next_stream; goto send_end; } log_fn(LOG_ERR,"edge conn not in circuit's list?"); assert(0); /* should never get here */ send_end: connection_edge_send_command(conn, circ, RELAY_COMMAND_END, NULL, 0, conn->cpath_layer); return; } /* this connection speaks cells. We must close all the circuits on it. */ while((circ = circuit_get_by_conn(conn))) { if(circ->n_conn == conn) /* it's closing in front of us */ circ->n_conn = NULL; if(circ->p_conn == conn) /* it's closing behind us */ circ->p_conn = NULL; circuit_close(circ); } } /* FIXME this now leaves some out */ void circuit_dump_by_conn(connection_t *conn) { circuit_t *circ; connection_t *tmpconn; for(circ=global_circuitlist;circ;circ = circ->next) { if(circ->p_conn == conn) printf("Conn %d has App-ward circuit: aci %d (other side %d), state %d (%s)\n", conn->poll_index, circ->p_aci, circ->n_aci, circ->state, circuit_state_to_string[circ->state]); for(tmpconn=circ->p_streams; tmpconn; tmpconn=tmpconn->next_stream) { if(tmpconn == conn) { printf("Conn %d has App-ward circuit: aci %d (other side %d), state %d (%s)\n", conn->poll_index, circ->p_aci, circ->n_aci, circ->state, circuit_state_to_string[circ->state]); } } if(circ->n_conn == conn) printf("Conn %d has Exit-ward circuit: aci %d (other side %d), state %d (%s)\n", conn->poll_index, circ->n_aci, circ->p_aci, circ->state, circuit_state_to_string[circ->state]); for(tmpconn=circ->n_streams; tmpconn; tmpconn=tmpconn->next_stream) { if(tmpconn == conn) { printf("Conn %d has Exit-ward circuit: aci %d (other side %d), state %d (%s)\n", conn->poll_index, circ->n_aci, circ->p_aci, circ->state, circuit_state_to_string[circ->state]); } } } } void circuit_expire_unused_circuits(void) { circuit_t *circ, *tmpcirc; circuit_t *youngest; youngest = circuit_get_newest_open(); circ = global_circuitlist; while(circ) { tmpcirc = circ; circ = circ->next; if(tmpcirc != youngest && !tmpcirc->p_conn && !tmpcirc->p_streams) { log_fn(LOG_DEBUG,"Closing n_aci %d",tmpcirc->n_aci); circuit_close(tmpcirc); } } } /* failure_status code: negative means reset failures to 0. Other values mean * add that value to the current number of failures, then if we don't have too * many failures on record, try to make a new circuit. */ void circuit_launch_new(int failure_status) { static int failures=0; if(!options.APPort) /* we're not an application proxy. no need for circuits. */ return; if(failure_status == -1) { /* I was called because a circuit succeeded */ failures = 0; return; } failures += failure_status; retry_circuit: if(failures > 5) { log_fn(LOG_INFO,"Giving up for now, %d failures.", failures); return; } if(circuit_establish_circuit() < 0) { failures++; goto retry_circuit; } failures = 0; return; } int circuit_establish_circuit(void) { routerinfo_t *firsthop; connection_t *n_conn; circuit_t *circ; circ = circuit_new(0, NULL); /* sets circ->p_aci and circ->p_conn */ circ->state = CIRCUIT_STATE_OR_WAIT; circ->cpath = onion_generate_cpath(&firsthop); if(!circ->cpath) { log_fn(LOG_INFO,"Generating cpath failed."); circuit_close(circ); return -1; } /* now see if we're already connected to the first OR in 'route' */ log_fn(LOG_DEBUG,"Looking for firsthop '%s:%u'", firsthop->address,firsthop->or_port); n_conn = connection_twin_get_by_addr_port(firsthop->addr,firsthop->or_port); if(!n_conn || n_conn->state != OR_CONN_STATE_OPEN) { /* not currently connected */ circ->n_addr = firsthop->addr; circ->n_port = firsthop->or_port; if(options.OnionRouter) { /* we would be connected if he were up. but he's not. */ log_fn(LOG_INFO,"Route's firsthop isn't connected."); circuit_close(circ); return -1; } if(!n_conn) { /* launch the connection */ n_conn = connection_or_connect(firsthop); if(!n_conn) { /* connect failed, forget the whole thing */ log_fn(LOG_INFO,"connect to firsthop failed. Closing."); circuit_close(circ); return -1; } } log_fn(LOG_DEBUG,"connecting in progress (or finished). Good."); return 0; /* return success. The onion/circuit/etc will be taken care of automatically * (may already have been) whenever n_conn reaches OR_CONN_STATE_OPEN. */ } else { /* it (or a twin) is already open. use it. */ circ->n_addr = n_conn->addr; circ->n_port = n_conn->port; circ->n_conn = n_conn; log_fn(LOG_DEBUG,"Conn open. Delivering first onion skin."); if(circuit_send_next_onion_skin(circ) < 0) { log_fn(LOG_INFO,"circuit_send_next_onion_skin failed."); circuit_close(circ); return -1; } } return 0; } /* find circuits that are waiting on me, if any, and get them to send the onion */ void circuit_n_conn_open(connection_t *or_conn) { circuit_t *circ; log_fn(LOG_DEBUG,"Starting."); circ = circuit_enumerate_by_naddr_nport(NULL, or_conn->addr, or_conn->port); for(;;) { if(!circ) return; log_fn(LOG_DEBUG,"Found circ, sending onion skin."); circ->n_conn = or_conn; if(circuit_send_next_onion_skin(circ) < 0) { log_fn(LOG_INFO,"send_next_onion_skin failed; circuit marked for closing."); circuit_close(circ); return; /* FIXME will want to try the other circuits too? */ } circ = circuit_enumerate_by_naddr_nport(circ, or_conn->addr, or_conn->port); } } int circuit_send_next_onion_skin(circuit_t *circ) { cell_t cell; crypt_path_t *hop; routerinfo_t *router; assert(circ && circ->cpath); if(circ->cpath->state == CPATH_STATE_CLOSED) { log_fn(LOG_DEBUG,"First skin; sending create cell."); circ->n_aci = get_unique_aci_by_addr_port(circ->n_addr, circ->n_port, ACI_TYPE_BOTH); memset(&cell, 0, sizeof(cell_t)); cell.command = CELL_CREATE; cell.aci = circ->n_aci; cell.length = DH_ONIONSKIN_LEN; if(onion_skin_create(circ->n_conn->onion_pkey, &(circ->cpath->handshake_state), cell.payload) < 0) { log_fn(LOG_WARN,"onion_skin_create (first hop) failed."); return -1; } connection_or_write_cell_to_buf(&cell, circ->n_conn); circ->cpath->state = CPATH_STATE_AWAITING_KEYS; circ->state = CIRCUIT_STATE_BUILDING; log_fn(LOG_DEBUG,"first skin; finished sending create cell."); } else { assert(circ->cpath->state == CPATH_STATE_OPEN); assert(circ->state == CIRCUIT_STATE_BUILDING); log_fn(LOG_DEBUG,"starting to send subsequent skin."); for(hop=circ->cpath->next; hop != circ->cpath && hop->state == CPATH_STATE_OPEN; hop=hop->next) ; if(hop == circ->cpath) { /* done building the circuit. whew. */ circ->state = CIRCUIT_STATE_OPEN; log_fn(LOG_INFO,"circuit built!"); return 0; } router = router_get_by_addr_port(hop->addr,hop->port); if(!router) { log_fn(LOG_WARN,"couldn't lookup router %d:%d",hop->addr,hop->port); return -1; } memset(&cell, 0, sizeof(cell_t)); cell.command = CELL_RELAY; cell.aci = circ->n_aci; SET_CELL_RELAY_COMMAND(cell, RELAY_COMMAND_EXTEND); SET_CELL_STREAM_ID(cell, ZERO_STREAM); cell.length = RELAY_HEADER_SIZE + 6 + DH_ONIONSKIN_LEN; *(uint32_t*)(cell.payload+RELAY_HEADER_SIZE) = htonl(hop->addr); *(uint16_t*)(cell.payload+RELAY_HEADER_SIZE+4) = htons(hop->port); if(onion_skin_create(router->onion_pkey, &(hop->handshake_state), cell.payload+RELAY_HEADER_SIZE+6) < 0) { log_fn(LOG_WARN,"onion_skin_create failed."); return -1; } log_fn(LOG_DEBUG,"Sending extend relay cell."); /* send it to hop->prev, because it will transfer it to a create cell and then send to hop */ if(circuit_deliver_relay_cell(&cell, circ, CELL_DIRECTION_OUT, hop->prev) < 0) { log_fn(LOG_WARN,"failed to deliver extend cell. Closing."); return -1; } hop->state = CPATH_STATE_AWAITING_KEYS; } return 0; } /* take the 'extend' cell, pull out addr/port plus the onion skin. Make * sure we're connected to the next hop, and pass it the onion skin in * a create cell. */ int circuit_extend(cell_t *cell, circuit_t *circ) { connection_t *n_conn; aci_t aci_type; cell_t newcell; if(circ->n_conn) { log_fn(LOG_WARN,"n_conn already set. Bug/attack. Closing."); return -1; } circ->n_addr = ntohl(*(uint32_t*)(cell->payload+RELAY_HEADER_SIZE)); circ->n_port = ntohs(*(uint16_t*)(cell->payload+RELAY_HEADER_SIZE+4)); n_conn = connection_twin_get_by_addr_port(circ->n_addr,circ->n_port); if(!n_conn || n_conn->type != CONN_TYPE_OR) { /* i've disabled making connections through OPs, but it's definitely * possible here. I'm not sure if it would be a bug or a feature. -RD */ /* note also that this will close circuits where the onion has the same * router twice in a row in the path. i think that's ok. -RD */ struct in_addr in; in.s_addr = htonl(circ->n_addr); log_fn(LOG_DEBUG,"Next router (%s:%d) not connected. Closing.", inet_ntoa(in), circ->n_port); /* XXX later we should fail more gracefully here, like with a 'truncated' */ return -1; } circ->n_addr = n_conn->addr; /* these are different if we found a twin instead */ circ->n_port = n_conn->port; circ->n_conn = n_conn; log_fn(LOG_DEBUG,"n_conn is %s:%u",n_conn->address,n_conn->port); aci_type = decide_aci_type(options.Nickname, n_conn->nickname); log_fn(LOG_DEBUG,"aci_type = %u.",aci_type); circ->n_aci = get_unique_aci_by_addr_port(circ->n_addr, circ->n_port, aci_type); if(!circ->n_aci) { log_fn(LOG_WARN,"failed to get unique aci."); return -1; } log_fn(LOG_DEBUG,"Chosen ACI %u.",circ->n_aci); memset(&newcell, 0, sizeof(cell_t)); newcell.command = CELL_CREATE; newcell.aci = circ->n_aci; newcell.length = DH_ONIONSKIN_LEN; memcpy(newcell.payload, cell->payload+RELAY_HEADER_SIZE+6, DH_ONIONSKIN_LEN); connection_or_write_cell_to_buf(&newcell, circ->n_conn); return 0; } int circuit_finish_handshake(circuit_t *circ, char *reply) { unsigned char iv[16]; unsigned char keys[32]; crypt_path_t *hop; memset(iv, 0, 16); assert(circ->cpath); if(circ->cpath->state == CPATH_STATE_AWAITING_KEYS) hop = circ->cpath; else { for(hop=circ->cpath->next; hop != circ->cpath && hop->state == CPATH_STATE_OPEN; hop=hop->next) ; if(hop == circ->cpath) { /* got an extended when we're all done? */ log_fn(LOG_WARN,"got extended when circ already built? Closing."); return -1; } } assert(hop->state == CPATH_STATE_AWAITING_KEYS); if(onion_skin_client_handshake(hop->handshake_state, reply, keys, 32) < 0) { log_fn(LOG_WARN,"onion_skin_client_handshake failed."); return -1; } crypto_dh_free(hop->handshake_state); /* don't need it anymore */ hop->handshake_state = NULL; log_fn(LOG_DEBUG,"hop %d init cipher forward %d, backward %d.", (uint32_t)hop, *(uint32_t*)keys, *(uint32_t*)(keys+16)); if (!(hop->f_crypto = crypto_create_init_cipher(CIRCUIT_CIPHER,keys,iv,1))) { log(LOG_WARN,"forward cipher initialization failed."); return -1; } if (!(hop->b_crypto = crypto_create_init_cipher(CIRCUIT_CIPHER,keys+16,iv,0))) { log(LOG_WARN,"backward cipher initialization failed."); return -1; } hop->state = CPATH_STATE_OPEN; log_fn(LOG_INFO,"finished"); return 0; } int circuit_truncated(circuit_t *circ, crypt_path_t *layer) { crypt_path_t *victim; connection_t *stream; assert(circ); assert(layer); while(layer->next != circ->cpath) { /* we need to clear out layer->next */ victim = layer->next; log_fn(LOG_DEBUG, "Killing a layer of the cpath."); for(stream = circ->p_streams; stream; stream=stream->next_stream) { if(stream->cpath_layer == victim) { log_fn(LOG_INFO, "Marking stream %d for close.", *(int*)stream->stream_id); /*ENDCLOSE*/ stream->marked_for_close = 1; } } layer->next = victim->next; circuit_free_cpath_node(victim); } log_fn(LOG_INFO, "finished"); return 0; } void assert_cpath_layer_ok(const crypt_path_t *cp) { assert(cp->f_crypto); assert(cp->b_crypto); assert(cp->addr); assert(cp->port); switch(cp->state) { case CPATH_STATE_CLOSED: case CPATH_STATE_OPEN: assert(!cp->handshake_state); break; case CPATH_STATE_AWAITING_KEYS: assert(cp->handshake_state); break; default: assert(0); } assert(cp->package_window >= 0); assert(cp->deliver_window >= 0); } void assert_cpath_ok(const crypt_path_t *cp) { while(cp->prev) cp = cp->prev; while(cp->next) { assert_cpath_layer_ok(cp); /* layers must be in sequence of: "open* awaiting? closed*" */ if (cp->prev) { if (cp->prev->state == CPATH_STATE_OPEN) { assert(cp->state == CPATH_STATE_CLOSED || cp->state == CPATH_STATE_AWAITING_KEYS); } else { assert(cp->state == CPATH_STATE_CLOSED); } } cp = cp->next; } } void assert_circuit_ok(const circuit_t *c) { connection_t *conn; assert(c->n_addr); assert(c->n_port); assert(c->n_conn); assert(c->n_conn->type == CONN_TYPE_OR); if (c->p_conn) assert(c->p_conn->type == CONN_TYPE_OR); for (conn = c->p_streams; conn; conn = conn->next_stream) assert(c->p_conn->type == CONN_TYPE_EXIT); for (conn = c->n_streams; conn; conn = conn->next_stream) assert(conn->type == CONN_TYPE_EXIT); assert(c->deliver_window >= 0); assert(c->package_window >= 0); if (c->state == CIRCUIT_STATE_OPEN) { if (c->cpath) { assert(!c->n_crypto); assert(!c->p_crypto); } else { assert(c->n_crypto); assert(c->p_crypto); } } if (c->cpath) { assert_cpath_ok(c->cpath); } } /* Local Variables: mode:c indent-tabs-mode:nil c-basic-offset:2 End: */