/* Copyright 2001 Matej Pfajfar. * Copyright (c) 2001-2004, Roger Dingledine. * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson. * Copyright (c) 2007-2012, The Tor Project, Inc. */ /* See LICENSE for licensing information */ /** * \file circuitlist.c * \brief Manage the global circuit list. **/ #include "or.h" #include "channel.h" #include "circuitbuild.h" #include "circuitlist.h" #include "circuituse.h" #include "connection.h" #include "config.h" #include "connection_edge.h" #include "connection_or.h" #include "control.h" #include "networkstatus.h" #include "nodelist.h" #include "onion.h" #include "relay.h" #include "rendclient.h" #include "rendcommon.h" #include "rephist.h" #include "routerlist.h" #include "routerset.h" #include "ht.h" /********* START VARIABLES **********/ /** A global list of all circuits at this hop. */ circuit_t *global_circuitlist=NULL; /** A list of all the circuits in CIRCUIT_STATE_CHAN_WAIT. */ static smartlist_t *circuits_pending_chans = NULL; static void circuit_free(circuit_t *circ); static void circuit_free_cpath(crypt_path_t *cpath); static void circuit_free_cpath_node(crypt_path_t *victim); static void cpath_ref_decref(crypt_path_reference_t *cpath_ref); /********* END VARIABLES ************/ /** A map from channel and circuit ID to circuit. (Lookup performance is * very important here, since we need to do it every time a cell arrives.) */ typedef struct chan_circid_circuit_map_t { HT_ENTRY(chan_circid_circuit_map_t) node; channel_t *chan; circid_t circ_id; circuit_t *circuit; } chan_circid_circuit_map_t; /** Helper for hash tables: compare the channel and circuit ID for a and * b, and return less than, equal to, or greater than zero appropriately. */ static INLINE int chan_circid_entries_eq_(chan_circid_circuit_map_t *a, chan_circid_circuit_map_t *b) { return a->chan == b->chan && a->circ_id == b->circ_id; } /** Helper: return a hash based on circuit ID and the pointer value of * chan in a. */ static INLINE unsigned int chan_circid_entry_hash_(chan_circid_circuit_map_t *a) { return (((unsigned)a->circ_id)<<8) ^ (unsigned)(uintptr_t)(a->chan); } /** Map from [chan,circid] to circuit. */ static HT_HEAD(chan_circid_map, chan_circid_circuit_map_t) chan_circid_map = HT_INITIALIZER(); HT_PROTOTYPE(chan_circid_map, chan_circid_circuit_map_t, node, chan_circid_entry_hash_, chan_circid_entries_eq_) HT_GENERATE(chan_circid_map, chan_circid_circuit_map_t, node, chan_circid_entry_hash_, chan_circid_entries_eq_, 0.6, malloc, realloc, free) /** The most recently returned entry from circuit_get_by_circid_chan; * used to improve performance when many cells arrive in a row from the * same circuit. */ chan_circid_circuit_map_t *_last_circid_chan_ent = NULL; /** Implementation helper for circuit_set_{p,n}_circid_channel: A circuit ID * and/or channel for circ has just changed from old_chan, old_id * to chan, id. Adjust the chan,circid map as appropriate, removing * the old entry (if any) and adding a new one. */ static void circuit_set_circid_chan_helper(circuit_t *circ, int direction, circid_t id, channel_t *chan) { chan_circid_circuit_map_t search; chan_circid_circuit_map_t *found; channel_t *old_chan, **chan_ptr; circid_t old_id, *circid_ptr; int make_active, attached = 0; if (direction == CELL_DIRECTION_OUT) { chan_ptr = &circ->n_chan; circid_ptr = &circ->n_circ_id; make_active = circ->n_chan_cells.n > 0; } else { or_circuit_t *c = TO_OR_CIRCUIT(circ); chan_ptr = &c->p_chan; circid_ptr = &c->p_circ_id; make_active = c->p_chan_cells.n > 0; } old_chan = *chan_ptr; old_id = *circid_ptr; if (id == old_id && chan == old_chan) return; if (_last_circid_chan_ent && ((old_id == _last_circid_chan_ent->circ_id && old_chan == _last_circid_chan_ent->chan) || (id == _last_circid_chan_ent->circ_id && chan == _last_circid_chan_ent->chan))) { _last_circid_chan_ent = NULL; } if (old_chan) { /* * If we're changing channels or ID and had an old channel and a non * zero old ID and weren't marked for close (i.e., we should have been * attached), detach the circuit. ID changes require this because * circuitmux hashes on (channel_id, circuit_id). */ if (old_id != 0 && (old_chan != chan || old_id != id) && !(circ->marked_for_close)) { tor_assert(old_chan->cmux); circuitmux_detach_circuit(old_chan->cmux, circ); } /* we may need to remove it from the conn-circid map */ search.circ_id = old_id; search.chan = old_chan; found = HT_REMOVE(chan_circid_map, &chan_circid_map, &search); if (found) { tor_free(found); if (direction == CELL_DIRECTION_OUT) { /* One fewer circuits use old_chan as n_chan */ --(old_chan->num_n_circuits); } else { /* One fewer circuits use old_chan as p_chan */ --(old_chan->num_p_circuits); } } } /* Change the values only after we have possibly made the circuit inactive * on the previous chan. */ *chan_ptr = chan; *circid_ptr = id; if (chan == NULL) return; /* now add the new one to the conn-circid map */ search.circ_id = id; search.chan = chan; found = HT_FIND(chan_circid_map, &chan_circid_map, &search); if (found) { found->circuit = circ; } else { found = tor_malloc_zero(sizeof(chan_circid_circuit_map_t)); found->circ_id = id; found->chan = chan; found->circuit = circ; HT_INSERT(chan_circid_map, &chan_circid_map, found); } /* * Attach to the circuitmux if we're changing channels or IDs and * have a new channel and ID to use and the circuit is not marked for * close. */ if (chan && id != 0 && (old_chan != chan || old_id != id) && !(circ->marked_for_close)) { tor_assert(chan->cmux); circuitmux_attach_circuit(chan->cmux, circ, direction); attached = 1; } /* * This is a no-op if we have no cells, but if we do it marks us active to * the circuitmux */ if (make_active && attached) update_circuit_on_cmux(circ, direction); /* Adjust circuit counts on new channel */ if (direction == CELL_DIRECTION_OUT) { ++chan->num_n_circuits; } else { ++chan->num_p_circuits; } } /** Set the p_conn field of a circuit circ, along * with the corresponding circuit ID, and add the circuit as appropriate * to the (chan,id)-\>circuit map. */ void circuit_set_p_circid_chan(or_circuit_t *circ, circid_t id, channel_t *chan) { circuit_set_circid_chan_helper(TO_CIRCUIT(circ), CELL_DIRECTION_IN, id, chan); if (chan) tor_assert(bool_eq(circ->p_chan_cells.n, circ->next_active_on_p_chan)); } /** Set the n_conn field of a circuit circ, along * with the corresponding circuit ID, and add the circuit as appropriate * to the (chan,id)-\>circuit map. */ void circuit_set_n_circid_chan(circuit_t *circ, circid_t id, channel_t *chan) { circuit_set_circid_chan_helper(circ, CELL_DIRECTION_OUT, id, chan); if (chan) tor_assert(bool_eq(circ->n_chan_cells.n, circ->next_active_on_n_chan)); } /** Change the state of circ to state, adding it to or removing * it from lists as appropriate. */ void circuit_set_state(circuit_t *circ, uint8_t state) { tor_assert(circ); if (state == circ->state) return; if (!circuits_pending_chans) circuits_pending_chans = smartlist_new(); if (circ->state == CIRCUIT_STATE_CHAN_WAIT) { /* remove from waiting-circuit list. */ smartlist_remove(circuits_pending_chans, circ); } if (state == CIRCUIT_STATE_CHAN_WAIT) { /* add to waiting-circuit list. */ smartlist_add(circuits_pending_chans, circ); } if (state == CIRCUIT_STATE_OPEN) tor_assert(!circ->n_chan_onionskin); circ->state = state; } /** Add circ to the global list of circuits. This is called only from * within circuit_new. */ static 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; } } /** Append to out all circuits in state CHAN_WAIT waiting for * the given connection. */ void circuit_get_all_pending_on_channel(smartlist_t *out, channel_t *chan) { tor_assert(out); tor_assert(chan); if (!circuits_pending_chans) return; SMARTLIST_FOREACH_BEGIN(circuits_pending_chans, circuit_t *, circ) { if (circ->marked_for_close) continue; if (!circ->n_hop) continue; tor_assert(circ->state == CIRCUIT_STATE_CHAN_WAIT); if (tor_digest_is_zero(circ->n_hop->identity_digest)) { /* Look at addr/port. This is an unkeyed connection. */ if (!channel_matches_extend_info(chan, circ->n_hop)) continue; } else { /* We expected a key. See if it's the right one. */ if (tor_memneq(chan->identity_digest, circ->n_hop->identity_digest, DIGEST_LEN)) continue; } smartlist_add(out, circ); } SMARTLIST_FOREACH_END(circ); } /** Return the number of circuits in state CHAN_WAIT, waiting for the given * channel. */ int circuit_count_pending_on_channel(channel_t *chan) { int cnt; smartlist_t *sl = smartlist_new(); tor_assert(chan); circuit_get_all_pending_on_channel(sl, chan); cnt = smartlist_len(sl); smartlist_free(sl); log_debug(LD_CIRC,"or_conn to %s at %s, %d pending circs", chan->nickname ? chan->nickname : "NULL", channel_get_canonical_remote_descr(chan), cnt); return cnt; } /** Detach from the global circuit list, and deallocate, all * circuits that have been marked for close. */ void circuit_close_all_marked(void) { circuit_t *tmp,*m; while (global_circuitlist && global_circuitlist->marked_for_close) { tmp = global_circuitlist->next; circuit_free(global_circuitlist); global_circuitlist = tmp; } tmp = global_circuitlist; while (tmp && tmp->next) { if (tmp->next->marked_for_close) { m = tmp->next->next; circuit_free(tmp->next); tmp->next = m; /* Need to check new tmp->next; don't advance tmp. */ } else { /* Advance tmp. */ tmp = tmp->next; } } } /** Return the head of the global linked list of circuits. */ circuit_t * circuit_get_global_list_(void) { return global_circuitlist; } /** Function to make circ-\>state human-readable */ const char * circuit_state_to_string(int state) { static char buf[64]; switch (state) { case CIRCUIT_STATE_BUILDING: return "doing handshakes"; case CIRCUIT_STATE_ONIONSKIN_PENDING: return "processing the onion"; case CIRCUIT_STATE_CHAN_WAIT: return "connecting to server"; case CIRCUIT_STATE_OPEN: return "open"; default: log_warn(LD_BUG, "Unknown circuit state %d", state); tor_snprintf(buf, sizeof(buf), "unknown state [%d]", state); return buf; } } /** Map a circuit purpose to a string suitable to be displayed to a * controller. */ const char * circuit_purpose_to_controller_string(uint8_t purpose) { static char buf[32]; switch (purpose) { case CIRCUIT_PURPOSE_OR: case CIRCUIT_PURPOSE_INTRO_POINT: case CIRCUIT_PURPOSE_REND_POINT_WAITING: case CIRCUIT_PURPOSE_REND_ESTABLISHED: return "SERVER"; /* A controller should never see these, actually. */ case CIRCUIT_PURPOSE_C_GENERAL: return "GENERAL"; case CIRCUIT_PURPOSE_C_INTRODUCING: case CIRCUIT_PURPOSE_C_INTRODUCE_ACK_WAIT: case CIRCUIT_PURPOSE_C_INTRODUCE_ACKED: return "HS_CLIENT_INTRO"; case CIRCUIT_PURPOSE_C_ESTABLISH_REND: case CIRCUIT_PURPOSE_C_REND_READY: case CIRCUIT_PURPOSE_C_REND_READY_INTRO_ACKED: case CIRCUIT_PURPOSE_C_REND_JOINED: return "HS_CLIENT_REND"; case CIRCUIT_PURPOSE_S_ESTABLISH_INTRO: case CIRCUIT_PURPOSE_S_INTRO: return "HS_SERVICE_INTRO"; case CIRCUIT_PURPOSE_S_CONNECT_REND: case CIRCUIT_PURPOSE_S_REND_JOINED: return "HS_SERVICE_REND"; case CIRCUIT_PURPOSE_TESTING: return "TESTING"; case CIRCUIT_PURPOSE_C_MEASURE_TIMEOUT: return "MEASURE_TIMEOUT"; case CIRCUIT_PURPOSE_CONTROLLER: return "CONTROLLER"; default: tor_snprintf(buf, sizeof(buf), "UNKNOWN_%d", (int)purpose); return buf; } } /** Return a string specifying the state of the hidden-service circuit * purpose purpose, or NULL if purpose is not a * hidden-service-related circuit purpose. */ const char * circuit_purpose_to_controller_hs_state_string(uint8_t purpose) { switch (purpose) { default: log_fn(LOG_WARN, LD_BUG, "Unrecognized circuit purpose: %d", (int)purpose); tor_fragile_assert(); /* fall through */ case CIRCUIT_PURPOSE_OR: case CIRCUIT_PURPOSE_C_GENERAL: case CIRCUIT_PURPOSE_C_MEASURE_TIMEOUT: case CIRCUIT_PURPOSE_TESTING: case CIRCUIT_PURPOSE_CONTROLLER: return NULL; case CIRCUIT_PURPOSE_INTRO_POINT: return "OR_HSSI_ESTABLISHED"; case CIRCUIT_PURPOSE_REND_POINT_WAITING: return "OR_HSCR_ESTABLISHED"; case CIRCUIT_PURPOSE_REND_ESTABLISHED: return "OR_HS_R_JOINED"; case CIRCUIT_PURPOSE_C_INTRODUCING: return "HSCI_CONNECTING"; case CIRCUIT_PURPOSE_C_INTRODUCE_ACK_WAIT: return "HSCI_INTRO_SENT"; case CIRCUIT_PURPOSE_C_INTRODUCE_ACKED: return "HSCI_DONE"; case CIRCUIT_PURPOSE_C_ESTABLISH_REND: return "HSCR_CONNECTING"; case CIRCUIT_PURPOSE_C_REND_READY: return "HSCR_ESTABLISHED_IDLE"; case CIRCUIT_PURPOSE_C_REND_READY_INTRO_ACKED: return "HSCR_ESTABLISHED_WAITING"; case CIRCUIT_PURPOSE_C_REND_JOINED: return "HSCR_JOINED"; case CIRCUIT_PURPOSE_S_ESTABLISH_INTRO: return "HSSI_CONNECTING"; case CIRCUIT_PURPOSE_S_INTRO: return "HSSI_ESTABLISHED"; case CIRCUIT_PURPOSE_S_CONNECT_REND: return "HSSR_CONNECTING"; case CIRCUIT_PURPOSE_S_REND_JOINED: return "HSSR_JOINED"; } } /** Return a human-readable string for the circuit purpose purpose. */ const char * circuit_purpose_to_string(uint8_t purpose) { static char buf[32]; switch (purpose) { case CIRCUIT_PURPOSE_OR: return "Circuit at relay"; case CIRCUIT_PURPOSE_INTRO_POINT: return "Acting as intro point"; case CIRCUIT_PURPOSE_REND_POINT_WAITING: return "Acting as rendevous (pending)"; case CIRCUIT_PURPOSE_REND_ESTABLISHED: return "Acting as rendevous (established)"; case CIRCUIT_PURPOSE_C_GENERAL: return "General-purpose client"; case CIRCUIT_PURPOSE_C_INTRODUCING: return "Hidden service client: Connecting to intro point"; case CIRCUIT_PURPOSE_C_INTRODUCE_ACK_WAIT: return "Hidden service client: Waiting for ack from intro point"; case CIRCUIT_PURPOSE_C_INTRODUCE_ACKED: return "Hidden service client: Received ack from intro point"; case CIRCUIT_PURPOSE_C_ESTABLISH_REND: return "Hidden service client: Establishing rendezvous point"; case CIRCUIT_PURPOSE_C_REND_READY: return "Hidden service client: Pending rendezvous point"; case CIRCUIT_PURPOSE_C_REND_READY_INTRO_ACKED: return "Hidden service client: Pending rendezvous point (ack received)"; case CIRCUIT_PURPOSE_C_REND_JOINED: return "Hidden service client: Active rendezvous point"; case CIRCUIT_PURPOSE_C_MEASURE_TIMEOUT: return "Measuring circuit timeout"; case CIRCUIT_PURPOSE_S_ESTABLISH_INTRO: return "Hidden service: Establishing introduction point"; case CIRCUIT_PURPOSE_S_INTRO: return "Hidden service: Introduction point"; case CIRCUIT_PURPOSE_S_CONNECT_REND: return "Hidden service: Connecting to rendezvous point"; case CIRCUIT_PURPOSE_S_REND_JOINED: return "Hidden service: Active rendezvous point"; case CIRCUIT_PURPOSE_TESTING: return "Testing circuit"; case CIRCUIT_PURPOSE_CONTROLLER: return "Circuit made by controller"; default: tor_snprintf(buf, sizeof(buf), "UNKNOWN_%d", (int)purpose); return buf; } } /** Pick a reasonable package_window to start out for our circuits. * Originally this was hard-coded at 1000, but now the consensus votes * on the answer. See proposal 168. */ int32_t circuit_initial_package_window(void) { int32_t num = networkstatus_get_param(NULL, "circwindow", CIRCWINDOW_START, CIRCWINDOW_START_MIN, CIRCWINDOW_START_MAX); /* If the consensus tells us a negative number, we'd assert. */ if (num < 0) num = CIRCWINDOW_START; return num; } /** Initialize the common elements in a circuit_t, and add it to the global * list. */ static void init_circuit_base(circuit_t *circ) { tor_gettimeofday(&circ->timestamp_created); circ->package_window = circuit_initial_package_window(); circ->deliver_window = CIRCWINDOW_START; circuit_add(circ); } /** Allocate space for a new circuit, initializing with p_circ_id * and p_conn. Add it to the global circuit list. */ origin_circuit_t * origin_circuit_new(void) { origin_circuit_t *circ; /* never zero, since a global ID of 0 is treated specially by the * controller */ static uint32_t n_circuits_allocated = 1; circ = tor_malloc_zero(sizeof(origin_circuit_t)); circ->base_.magic = ORIGIN_CIRCUIT_MAGIC; circ->next_stream_id = crypto_rand_int(1<<16); circ->global_identifier = n_circuits_allocated++; circ->remaining_relay_early_cells = MAX_RELAY_EARLY_CELLS_PER_CIRCUIT; circ->remaining_relay_early_cells -= crypto_rand_int(2); init_circuit_base(TO_CIRCUIT(circ)); circ_times.last_circ_at = approx_time(); return circ; } /** Allocate a new or_circuit_t, connected to p_conn as * p_circ_id. If p_conn is NULL, the circuit is unattached. */ or_circuit_t * or_circuit_new(circid_t p_circ_id, channel_t *p_chan) { /* CircIDs */ or_circuit_t *circ; circ = tor_malloc_zero(sizeof(or_circuit_t)); circ->base_.magic = OR_CIRCUIT_MAGIC; if (p_chan) circuit_set_p_circid_chan(circ, p_circ_id, p_chan); circ->remaining_relay_early_cells = MAX_RELAY_EARLY_CELLS_PER_CIRCUIT; init_circuit_base(TO_CIRCUIT(circ)); return circ; } /** Deallocate space associated with circ. */ static void circuit_free(circuit_t *circ) { void *mem; size_t memlen; if (!circ) return; if (CIRCUIT_IS_ORIGIN(circ)) { origin_circuit_t *ocirc = TO_ORIGIN_CIRCUIT(circ); mem = ocirc; memlen = sizeof(origin_circuit_t); tor_assert(circ->magic == ORIGIN_CIRCUIT_MAGIC); if (ocirc->build_state) { extend_info_free(ocirc->build_state->chosen_exit); circuit_free_cpath_node(ocirc->build_state->pending_final_cpath); cpath_ref_decref(ocirc->build_state->service_pending_final_cpath_ref); } tor_free(ocirc->build_state); circuit_free_cpath(ocirc->cpath); crypto_pk_free(ocirc->intro_key); rend_data_free(ocirc->rend_data); tor_free(ocirc->dest_address); if (ocirc->socks_username) { memset(ocirc->socks_username, 0x12, ocirc->socks_username_len); tor_free(ocirc->socks_username); } if (ocirc->socks_password) { memset(ocirc->socks_password, 0x06, ocirc->socks_password_len); tor_free(ocirc->socks_password); } } else { or_circuit_t *ocirc = TO_OR_CIRCUIT(circ); /* Remember cell statistics for this circuit before deallocating. */ if (get_options()->CellStatistics) rep_hist_buffer_stats_add_circ(circ, time(NULL)); mem = ocirc; memlen = sizeof(or_circuit_t); tor_assert(circ->magic == OR_CIRCUIT_MAGIC); crypto_cipher_free(ocirc->p_crypto); crypto_digest_free(ocirc->p_digest); crypto_cipher_free(ocirc->n_crypto); crypto_digest_free(ocirc->n_digest); if (ocirc->rend_splice) { or_circuit_t *other = ocirc->rend_splice; tor_assert(other->base_.magic == OR_CIRCUIT_MAGIC); other->rend_splice = NULL; } /* remove from map. */ circuit_set_p_circid_chan(ocirc, 0, NULL); /* Clear cell queue _after_ removing it from the map. Otherwise our * "active" checks will be violated. */ cell_queue_clear(ô->p_chan_cells); } extend_info_free(circ->n_hop); tor_free(circ->n_chan_onionskin); /* Remove from map. */ circuit_set_n_circid_chan(circ, 0, NULL); /* Clear cell queue _after_ removing it from the map. Otherwise our * "active" checks will be violated. */ cell_queue_clear(&circ->n_chan_cells); memset(mem, 0xAA, memlen); /* poison memory */ tor_free(mem); } /** Deallocate space associated with the linked list cpath. */ 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); } /** Release all storage held by circuits. */ void circuit_free_all(void) { circuit_t *next; while (global_circuitlist) { next = global_circuitlist->next; if (! CIRCUIT_IS_ORIGIN(global_circuitlist)) { or_circuit_t *or_circ = TO_OR_CIRCUIT(global_circuitlist); while (or_circ->resolving_streams) { edge_connection_t *next_conn; next_conn = or_circ->resolving_streams->next_stream; connection_free(TO_CONN(or_circ->resolving_streams)); or_circ->resolving_streams = next_conn; } } circuit_free(global_circuitlist); global_circuitlist = next; } smartlist_free(circuits_pending_chans); circuits_pending_chans = NULL; HT_CLEAR(chan_circid_map, &chan_circid_map); } /** Deallocate space associated with the cpath node victim. */ static void circuit_free_cpath_node(crypt_path_t *victim) { if (!victim) return; crypto_cipher_free(victim->f_crypto); crypto_cipher_free(victim->b_crypto); crypto_digest_free(victim->f_digest); crypto_digest_free(victim->b_digest); crypto_dh_free(victim->dh_handshake_state); extend_info_free(victim->extend_info); memset(victim, 0xBB, sizeof(crypt_path_t)); /* poison memory */ tor_free(victim); } /** Release a crypt_path_reference_t*, which may be NULL. */ static void cpath_ref_decref(crypt_path_reference_t *cpath_ref) { if (cpath_ref != NULL) { if (--(cpath_ref->refcount) == 0) { circuit_free_cpath_node(cpath_ref->cpath); tor_free(cpath_ref); } } } /** A helper function for circuit_dump_by_conn() below. Log a bunch * of information about circuit circ. */ static void circuit_dump_conn_details(int severity, circuit_t *circ, int conn_array_index, const char *type, int this_circid, int other_circid) { log(severity, LD_CIRC, "Conn %d has %s circuit: circID %d (other side %d), " "state %d (%s), born %ld:", conn_array_index, type, this_circid, other_circid, circ->state, circuit_state_to_string(circ->state), (long)circ->timestamp_created.tv_sec); if (CIRCUIT_IS_ORIGIN(circ)) { /* circ starts at this node */ circuit_log_path(severity, LD_CIRC, TO_ORIGIN_CIRCUIT(circ)); } } /** Log, at severity severity, information about each circuit * that is connected to conn. */ void circuit_dump_by_conn(connection_t *conn, int severity) { circuit_t *circ; edge_connection_t *tmpconn; for (circ = global_circuitlist; circ; circ = circ->next) { circid_t n_circ_id = circ->n_circ_id, p_circ_id = 0; if (circ->marked_for_close) { continue; } if (!CIRCUIT_IS_ORIGIN(circ)) { p_circ_id = TO_OR_CIRCUIT(circ)->p_circ_id; } if (CIRCUIT_IS_ORIGIN(circ)) { for (tmpconn=TO_ORIGIN_CIRCUIT(circ)->p_streams; tmpconn; tmpconn=tmpconn->next_stream) { if (TO_CONN(tmpconn) == conn) { circuit_dump_conn_details(severity, circ, conn->conn_array_index, "App-ward", p_circ_id, n_circ_id); } } } if (! CIRCUIT_IS_ORIGIN(circ)) { for (tmpconn=TO_OR_CIRCUIT(circ)->n_streams; tmpconn; tmpconn=tmpconn->next_stream) { if (TO_CONN(tmpconn) == conn) { circuit_dump_conn_details(severity, circ, conn->conn_array_index, "Exit-ward", n_circ_id, p_circ_id); } } } } } /** A helper function for circuit_dump_by_chan() below. Log a bunch * of information about circuit circ. */ static void circuit_dump_chan_details(int severity, circuit_t *circ, channel_t *chan, const char *type, int this_circid, int other_circid) { log(severity, LD_CIRC, "Conn %p has %s circuit: circID %d (other side %d), " "state %d (%s), born %ld:", chan, type, this_circid, other_circid, circ->state, circuit_state_to_string(circ->state), (long)circ->timestamp_created.tv_sec); if (CIRCUIT_IS_ORIGIN(circ)) { /* circ starts at this node */ circuit_log_path(severity, LD_CIRC, TO_ORIGIN_CIRCUIT(circ)); } } /** Log, at severity severity, information about each circuit * that is connected to chan. */ void circuit_dump_by_chan(channel_t *chan, int severity) { circuit_t *circ; tor_assert(chan); for (circ = global_circuitlist; circ; circ = circ->next) { circid_t n_circ_id = circ->n_circ_id, p_circ_id = 0; if (circ->marked_for_close) { continue; } if (!CIRCUIT_IS_ORIGIN(circ)) { p_circ_id = TO_OR_CIRCUIT(circ)->p_circ_id; } if (! CIRCUIT_IS_ORIGIN(circ) && TO_OR_CIRCUIT(circ)->p_chan && TO_OR_CIRCUIT(circ)->p_chan == chan) { circuit_dump_chan_details(severity, circ, chan, "App-ward", p_circ_id, n_circ_id); } if (circ->n_chan && circ->n_chan == chan) { circuit_dump_chan_details(severity, circ, chan, "Exit-ward", n_circ_id, p_circ_id); } if (!circ->n_chan && circ->n_hop && channel_matches_extend_info(chan, circ->n_hop) && tor_memeq(chan->identity_digest, circ->n_hop->identity_digest, DIGEST_LEN)) { circuit_dump_chan_details(severity, circ, chan, (circ->state == CIRCUIT_STATE_OPEN && !CIRCUIT_IS_ORIGIN(circ)) ? "Endpoint" : "Pending", n_circ_id, p_circ_id); } } } /** Return the circuit whose global ID is id, or NULL if no * such circuit exists. */ origin_circuit_t * circuit_get_by_global_id(uint32_t id) { circuit_t *circ; for (circ=global_circuitlist;circ;circ = circ->next) { if (CIRCUIT_IS_ORIGIN(circ) && TO_ORIGIN_CIRCUIT(circ)->global_identifier == id) { if (circ->marked_for_close) return NULL; else return TO_ORIGIN_CIRCUIT(circ); } } return NULL; } /** Return a circ such that: * - circ-\>n_circ_id or circ-\>p_circ_id is equal to circ_id, and * - circ is attached to chan, either as p_chan or n_chan. * Return NULL if no such circuit exists. */ static INLINE circuit_t * circuit_get_by_circid_channel_impl(circid_t circ_id, channel_t *chan) { chan_circid_circuit_map_t search; chan_circid_circuit_map_t *found; if (_last_circid_chan_ent && circ_id == _last_circid_chan_ent->circ_id && chan == _last_circid_chan_ent->chan) { found = _last_circid_chan_ent; } else { search.circ_id = circ_id; search.chan = chan; found = HT_FIND(chan_circid_map, &chan_circid_map, &search); _last_circid_chan_ent = found; } if (found && found->circuit) { log_debug(LD_CIRC, "circuit_get_by_circid_channel_impl() returning circuit %p for" " circ_id %d, channel ID " U64_FORMAT " (%p)", found->circuit, circ_id, U64_PRINTF_ARG(chan->global_identifier), chan); return found->circuit; } log_debug(LD_CIRC, "circuit_get_by_circid_channel_impl() found nothing for" " circ_id %d, channel ID " U64_FORMAT " (%p)", circ_id, U64_PRINTF_ARG(chan->global_identifier), chan); return NULL; /* The rest of this checks for bugs. Disabled by default. */ /* We comment it out because coverity complains otherwise. { circuit_t *circ; for (circ=global_circuitlist;circ;circ = circ->next) { if (! CIRCUIT_IS_ORIGIN(circ)) { or_circuit_t *or_circ = TO_OR_CIRCUIT(circ); if (or_circ->p_chan == chan && or_circ->p_circ_id == circ_id) { log_warn(LD_BUG, "circuit matches p_chan, but not in hash table (Bug!)"); return circ; } } if (circ->n_chan == chan && circ->n_circ_id == circ_id) { log_warn(LD_BUG, "circuit matches n_chan, but not in hash table (Bug!)"); return circ; } } return NULL; } */ } /** Return a circ such that: * - circ-\>n_circ_id or circ-\>p_circ_id is equal to circ_id, and * - circ is attached to chan, either as p_chan or n_chan. * - circ is not marked for close. * Return NULL if no such circuit exists. */ circuit_t * circuit_get_by_circid_channel(circid_t circ_id, channel_t *chan) { circuit_t *circ = circuit_get_by_circid_channel_impl(circ_id, chan); if (!circ || circ->marked_for_close) return NULL; else return circ; } /** Return a circ such that: * - circ-\>n_circ_id or circ-\>p_circ_id is equal to circ_id, and * - circ is attached to chan, either as p_chan or n_chan. * Return NULL if no such circuit exists. */ circuit_t * circuit_get_by_circid_channel_even_if_marked(circid_t circ_id, channel_t *chan) { return circuit_get_by_circid_channel_impl(circ_id, chan); } /** Return true iff the circuit ID circ_id is currently used by a * circuit, marked or not, on chan. */ int circuit_id_in_use_on_channel(circid_t circ_id, channel_t *chan) { return circuit_get_by_circid_channel_impl(circ_id, chan) != NULL; } /** Return the circuit that a given edge connection is using. */ circuit_t * circuit_get_by_edge_conn(edge_connection_t *conn) { circuit_t *circ; circ = conn->on_circuit; tor_assert(!circ || (CIRCUIT_IS_ORIGIN(circ) ? circ->magic == ORIGIN_CIRCUIT_MAGIC : circ->magic == OR_CIRCUIT_MAGIC)); return circ; } /** For each circuit that has chan as n_chan or p_chan, unlink the * circuit from the chan,circid map, and mark it for close if it hasn't * been marked already. */ void circuit_unlink_all_from_channel(channel_t *chan, int reason) { circuit_t *circ; channel_unlink_all_circuits(chan); for (circ = global_circuitlist; circ; circ = circ->next) { int mark = 0; if (circ->n_chan == chan) { circuit_set_n_circid_chan(circ, 0, NULL); mark = 1; } if (! CIRCUIT_IS_ORIGIN(circ)) { or_circuit_t *or_circ = TO_OR_CIRCUIT(circ); if (or_circ->p_chan == chan) { circuit_set_p_circid_chan(or_circ, 0, NULL); mark = 1; } } if (mark && !circ->marked_for_close) circuit_mark_for_close(circ, reason); } } /** Return a circ such that * - circ-\>rend_data-\>onion_address is equal to * rend_data-\>onion_address, * - circ-\>rend_data-\>rend_cookie is equal to * rend_data-\>rend_cookie, and * - circ-\>purpose is equal to CIRCUIT_PURPOSE_C_REND_READY. * * Return NULL if no such circuit exists. */ origin_circuit_t * circuit_get_ready_rend_circ_by_rend_data(const rend_data_t *rend_data) { circuit_t *circ; for (circ = global_circuitlist; circ; circ = circ->next) { if (!circ->marked_for_close && circ->purpose == CIRCUIT_PURPOSE_C_REND_READY) { origin_circuit_t *ocirc = TO_ORIGIN_CIRCUIT(circ); if (ocirc->rend_data && !rend_cmp_service_ids(rend_data->onion_address, ocirc->rend_data->onion_address) && tor_memeq(ocirc->rend_data->rend_cookie, rend_data->rend_cookie, REND_COOKIE_LEN)) return ocirc; } } return NULL; } /** Return the first circuit originating here in global_circuitlist after * start whose purpose is purpose, and where * digest (if set) matches the rend_pk_digest field. Return NULL if no * circuit is found. If start is NULL, begin at the start of the list. */ origin_circuit_t * circuit_get_next_by_pk_and_purpose(origin_circuit_t *start, const char *digest, uint8_t purpose) { circuit_t *circ; tor_assert(CIRCUIT_PURPOSE_IS_ORIGIN(purpose)); if (start == NULL) circ = global_circuitlist; else circ = TO_CIRCUIT(start)->next; for ( ; circ; circ = circ->next) { if (circ->marked_for_close) continue; if (circ->purpose != purpose) continue; if (!digest) return TO_ORIGIN_CIRCUIT(circ); else if (TO_ORIGIN_CIRCUIT(circ)->rend_data && tor_memeq(TO_ORIGIN_CIRCUIT(circ)->rend_data->rend_pk_digest, digest, DIGEST_LEN)) return TO_ORIGIN_CIRCUIT(circ); } return NULL; } /** Return the first OR circuit in the global list whose purpose is * purpose, and whose rend_token is the len-byte * token. */ static or_circuit_t * circuit_get_by_rend_token_and_purpose(uint8_t purpose, const char *token, size_t len) { circuit_t *circ; for (circ = global_circuitlist; circ; circ = circ->next) { if (! circ->marked_for_close && circ->purpose == purpose && tor_memeq(TO_OR_CIRCUIT(circ)->rend_token, token, len)) return TO_OR_CIRCUIT(circ); } return NULL; } /** Return the circuit waiting for a rendezvous with the provided cookie. * Return NULL if no such circuit is found. */ or_circuit_t * circuit_get_rendezvous(const char *cookie) { return circuit_get_by_rend_token_and_purpose( CIRCUIT_PURPOSE_REND_POINT_WAITING, cookie, REND_COOKIE_LEN); } /** Return the circuit waiting for intro cells of the given digest. * Return NULL if no such circuit is found. */ or_circuit_t * circuit_get_intro_point(const char *digest) { return circuit_get_by_rend_token_and_purpose( CIRCUIT_PURPOSE_INTRO_POINT, digest, DIGEST_LEN); } /** Return a circuit that is open, is CIRCUIT_PURPOSE_C_GENERAL, * has a timestamp_dirty value of 0, has flags matching the CIRCLAUNCH_* * flags in flags, and if info is defined, does not already use info * as any of its hops; or NULL if no circuit fits this description. * * The purpose argument (currently ignored) refers to the purpose of * the circuit we want to create, not the purpose of the circuit we want to * cannibalize. * * If !CIRCLAUNCH_NEED_UPTIME, prefer returning non-uptime circuits. */ origin_circuit_t * circuit_find_to_cannibalize(uint8_t purpose, extend_info_t *info, int flags) { circuit_t *circ_; origin_circuit_t *best=NULL; int need_uptime = (flags & CIRCLAUNCH_NEED_UPTIME) != 0; int need_capacity = (flags & CIRCLAUNCH_NEED_CAPACITY) != 0; int internal = (flags & CIRCLAUNCH_IS_INTERNAL) != 0; const or_options_t *options = get_options(); /* Make sure we're not trying to create a onehop circ by * cannibalization. */ tor_assert(!(flags & CIRCLAUNCH_ONEHOP_TUNNEL)); log_debug(LD_CIRC, "Hunting for a circ to cannibalize: purpose %d, uptime %d, " "capacity %d, internal %d", purpose, need_uptime, need_capacity, internal); for (circ_=global_circuitlist; circ_; circ_ = circ_->next) { if (CIRCUIT_IS_ORIGIN(circ_) && circ_->state == CIRCUIT_STATE_OPEN && !circ_->marked_for_close && circ_->purpose == CIRCUIT_PURPOSE_C_GENERAL && !circ_->timestamp_dirty) { origin_circuit_t *circ = TO_ORIGIN_CIRCUIT(circ_); if ((!need_uptime || circ->build_state->need_uptime) && (!need_capacity || circ->build_state->need_capacity) && (internal == circ->build_state->is_internal) && circ->remaining_relay_early_cells && circ->build_state->desired_path_len == DEFAULT_ROUTE_LEN && !circ->build_state->onehop_tunnel && !circ->isolation_values_set) { if (info) { /* need to make sure we don't duplicate hops */ crypt_path_t *hop = circ->cpath; const node_t *ri1 = node_get_by_id(info->identity_digest); do { const node_t *ri2; if (tor_memeq(hop->extend_info->identity_digest, info->identity_digest, DIGEST_LEN)) goto next; if (ri1 && (ri2 = node_get_by_id(hop->extend_info->identity_digest)) && nodes_in_same_family(ri1, ri2)) goto next; hop=hop->next; } while (hop!=circ->cpath); } if (options->ExcludeNodes) { /* Make sure no existing nodes in the circuit are excluded for * general use. (This may be possible if StrictNodes is 0, and we * thought we needed to use an otherwise excluded node for, say, a * directory operation.) */ crypt_path_t *hop = circ->cpath; do { if (routerset_contains_extendinfo(options->ExcludeNodes, hop->extend_info)) goto next; hop = hop->next; } while (hop != circ->cpath); } if (!best || (best->build_state->need_uptime && !need_uptime)) best = circ; next: ; } } } return best; } /** Return the number of hops in circuit's path. */ int circuit_get_cpath_len(origin_circuit_t *circ) { int n = 0; if (circ && circ->cpath) { crypt_path_t *cpath, *cpath_next = NULL; for (cpath = circ->cpath; cpath_next != circ->cpath; cpath = cpath_next) { cpath_next = cpath->next; ++n; } } return n; } /** Return the hopnumth hop in circ->cpath, or NULL if there * aren't that many hops in the list. */ crypt_path_t * circuit_get_cpath_hop(origin_circuit_t *circ, int hopnum) { if (circ && circ->cpath && hopnum > 0) { crypt_path_t *cpath, *cpath_next = NULL; for (cpath = circ->cpath; cpath_next != circ->cpath; cpath = cpath_next) { cpath_next = cpath->next; if (--hopnum <= 0) return cpath; } } return NULL; } /** Go through the circuitlist; mark-for-close each circuit that starts * at us but has not yet been used. */ void circuit_mark_all_unused_circs(void) { circuit_t *circ; for (circ=global_circuitlist; circ; circ = circ->next) { if (CIRCUIT_IS_ORIGIN(circ) && !circ->marked_for_close && !circ->timestamp_dirty) circuit_mark_for_close(circ, END_CIRC_REASON_FINISHED); } } /** Go through the circuitlist; for each circuit that starts at us * and is dirty, frob its timestamp_dirty so we won't use it for any * new streams. * * This is useful for letting the user change pseudonyms, so new * streams will not be linkable to old streams. */ /* XXX024 this is a bad name for what this function does */ void circuit_expire_all_dirty_circs(void) { circuit_t *circ; const or_options_t *options = get_options(); for (circ=global_circuitlist; circ; circ = circ->next) { if (CIRCUIT_IS_ORIGIN(circ) && !circ->marked_for_close && circ->timestamp_dirty) /* XXXX024 This is a screwed-up way to say "This is too dirty * for new circuits. */ circ->timestamp_dirty -= options->MaxCircuitDirtiness; } } /** Mark circ to be closed next time we call * circuit_close_all_marked(). Do any cleanup needed: * - If state is onionskin_pending, remove circ from the onion_pending * list. * - If circ isn't open yet: call circuit_build_failed() if we're * the origin, and in either case call circuit_rep_hist_note_result() * to note stats. * - If purpose is C_INTRODUCE_ACK_WAIT, report the intro point * failure we just had to the hidden service client module. * - If purpose is C_INTRODUCING and reason isn't TIMEOUT, * report to the hidden service client module that the intro point * we just tried may be unreachable. * - Send appropriate destroys and edge_destroys for conns and * streams attached to circ. * - If circ->rend_splice is set (we are the midpoint of a joined * rendezvous stream), then mark the other circuit to close as well. */ void circuit_mark_for_close_(circuit_t *circ, int reason, int line, const char *file) { int orig_reason = reason; /* Passed to the controller */ assert_circuit_ok(circ); tor_assert(line); tor_assert(file); if (circ->marked_for_close) { log(LOG_WARN,LD_BUG, "Duplicate call to circuit_mark_for_close at %s:%d" " (first at %s:%d)", file, line, circ->marked_for_close_file, circ->marked_for_close); return; } if (reason == END_CIRC_AT_ORIGIN) { if (!CIRCUIT_IS_ORIGIN(circ)) { log_warn(LD_BUG, "Specified 'at-origin' non-reason for ending circuit, " "but circuit was not at origin. (called %s:%d, purpose=%d)", file, line, circ->purpose); } reason = END_CIRC_REASON_NONE; } if (CIRCUIT_IS_ORIGIN(circ)) { /* We don't send reasons when closing circuits at the origin. */ reason = END_CIRC_REASON_NONE; } if (reason & END_CIRC_REASON_FLAG_REMOTE) reason &= ~END_CIRC_REASON_FLAG_REMOTE; if (reason < END_CIRC_REASON_MIN_ || reason > END_CIRC_REASON_MAX_) { if (!(orig_reason & END_CIRC_REASON_FLAG_REMOTE)) log_warn(LD_BUG, "Reason %d out of range at %s:%d", reason, file, line); reason = END_CIRC_REASON_NONE; } if (circ->state == CIRCUIT_STATE_ONIONSKIN_PENDING) { onion_pending_remove(TO_OR_CIRCUIT(circ)); } /* If the circuit ever became OPEN, we sent it to the reputation history * module then. If it isn't OPEN, we send it there now to remember which * links worked and which didn't. */ if (circ->state != CIRCUIT_STATE_OPEN) { if (CIRCUIT_IS_ORIGIN(circ)) { origin_circuit_t *ocirc = TO_ORIGIN_CIRCUIT(circ); circuit_build_failed(ocirc); /* take actions if necessary */ circuit_rep_hist_note_result(ocirc); } } if (circ->state == CIRCUIT_STATE_CHAN_WAIT) { if (circuits_pending_chans) smartlist_remove(circuits_pending_chans, circ); } if (CIRCUIT_IS_ORIGIN(circ)) { control_event_circuit_status(TO_ORIGIN_CIRCUIT(circ), (circ->state == CIRCUIT_STATE_OPEN)?CIRC_EVENT_CLOSED:CIRC_EVENT_FAILED, orig_reason); } if (circ->purpose == CIRCUIT_PURPOSE_C_INTRODUCE_ACK_WAIT) { origin_circuit_t *ocirc = TO_ORIGIN_CIRCUIT(circ); int timed_out = (reason == END_CIRC_REASON_TIMEOUT); tor_assert(circ->state == CIRCUIT_STATE_OPEN); tor_assert(ocirc->build_state->chosen_exit); tor_assert(ocirc->rend_data); /* treat this like getting a nack from it */ log_info(LD_REND, "Failed intro circ %s to %s (awaiting ack). %s", safe_str_client(ocirc->rend_data->onion_address), safe_str_client(build_state_get_exit_nickname(ocirc->build_state)), timed_out ? "Recording timeout." : "Removing from descriptor."); rend_client_report_intro_point_failure(ocirc->build_state->chosen_exit, ocirc->rend_data, timed_out ? INTRO_POINT_FAILURE_TIMEOUT : INTRO_POINT_FAILURE_GENERIC); } else if (circ->purpose == CIRCUIT_PURPOSE_C_INTRODUCING && reason != END_CIRC_REASON_TIMEOUT) { origin_circuit_t *ocirc = TO_ORIGIN_CIRCUIT(circ); if (ocirc->build_state->chosen_exit && ocirc->rend_data) { log_info(LD_REND, "Failed intro circ %s to %s " "(building circuit to intro point). " "Marking intro point as possibly unreachable.", safe_str_client(ocirc->rend_data->onion_address), safe_str_client(build_state_get_exit_nickname(ocirc->build_state))); rend_client_report_intro_point_failure(ocirc->build_state->chosen_exit, ocirc->rend_data, INTRO_POINT_FAILURE_UNREACHABLE); } } if (circ->n_chan) { circuit_clear_cell_queue(circ, circ->n_chan); channel_send_destroy(circ->n_circ_id, circ->n_chan, reason); circuitmux_detach_circuit(circ->n_chan->cmux, circ); } if (! CIRCUIT_IS_ORIGIN(circ)) { or_circuit_t *or_circ = TO_OR_CIRCUIT(circ); edge_connection_t *conn; for (conn=or_circ->n_streams; conn; conn=conn->next_stream) connection_edge_destroy(or_circ->p_circ_id, conn); or_circ->n_streams = NULL; while (or_circ->resolving_streams) { conn = or_circ->resolving_streams; or_circ->resolving_streams = conn->next_stream; if (!conn->base_.marked_for_close) { /* The client will see a DESTROY, and infer that the connections * are closing because the circuit is getting torn down. No need * to send an end cell. */ conn->edge_has_sent_end = 1; conn->end_reason = END_STREAM_REASON_DESTROY; conn->end_reason |= END_STREAM_REASON_FLAG_ALREADY_SENT_CLOSED; connection_mark_for_close(TO_CONN(conn)); } conn->on_circuit = NULL; } if (or_circ->p_chan) { circuit_clear_cell_queue(circ, or_circ->p_chan); channel_send_destroy(or_circ->p_circ_id, or_circ->p_chan, reason); circuitmux_detach_circuit(or_circ->p_chan->cmux, circ); } } else { origin_circuit_t *ocirc = TO_ORIGIN_CIRCUIT(circ); edge_connection_t *conn; for (conn=ocirc->p_streams; conn; conn=conn->next_stream) connection_edge_destroy(circ->n_circ_id, conn); ocirc->p_streams = NULL; } circ->marked_for_close = line; circ->marked_for_close_file = file; if (!CIRCUIT_IS_ORIGIN(circ)) { or_circuit_t *or_circ = TO_OR_CIRCUIT(circ); if (or_circ->rend_splice) { if (!or_circ->rend_splice->base_.marked_for_close) { /* do this after marking this circuit, to avoid infinite recursion. */ circuit_mark_for_close(TO_CIRCUIT(or_circ->rend_splice), reason); } or_circ->rend_splice = NULL; } } } /** Verify that cpath layer cp has all of its invariants * correct. Trigger an assert if anything is invalid. */ void assert_cpath_layer_ok(const crypt_path_t *cp) { // tor_assert(cp->addr); /* these are zero for rendezvous extra-hops */ // tor_assert(cp->port); tor_assert(cp); tor_assert(cp->magic == CRYPT_PATH_MAGIC); switch (cp->state) { case CPATH_STATE_OPEN: tor_assert(cp->f_crypto); tor_assert(cp->b_crypto); /* fall through */ case CPATH_STATE_CLOSED: tor_assert(!cp->dh_handshake_state); break; case CPATH_STATE_AWAITING_KEYS: /* tor_assert(cp->dh_handshake_state); */ break; default: log_fn(LOG_ERR, LD_BUG, "Unexpected state %d", cp->state); tor_assert(0); } tor_assert(cp->package_window >= 0); tor_assert(cp->deliver_window >= 0); } /** Verify that cpath cp has all of its invariants * correct. Trigger an assert if anything is invalid. */ static void assert_cpath_ok(const crypt_path_t *cp) { const crypt_path_t *start = cp; do { assert_cpath_layer_ok(cp); /* layers must be in sequence of: "open* awaiting? closed*" */ if (cp != start) { if (cp->state == CPATH_STATE_AWAITING_KEYS) { tor_assert(cp->prev->state == CPATH_STATE_OPEN); } else if (cp->state == CPATH_STATE_OPEN) { tor_assert(cp->prev->state == CPATH_STATE_OPEN); } } cp = cp->next; tor_assert(cp); } while (cp != start); } /** Verify that circuit c has all of its invariants * correct. Trigger an assert if anything is invalid. */ void assert_circuit_ok(const circuit_t *c) { edge_connection_t *conn; const or_circuit_t *or_circ = NULL; const origin_circuit_t *origin_circ = NULL; tor_assert(c); tor_assert(c->magic == ORIGIN_CIRCUIT_MAGIC || c->magic == OR_CIRCUIT_MAGIC); tor_assert(c->purpose >= CIRCUIT_PURPOSE_MIN_ && c->purpose <= CIRCUIT_PURPOSE_MAX_); { /* Having a separate variable for this pleases GCC 4.2 in ways I hope I * never understand. -NM. */ circuit_t *nonconst_circ = (circuit_t*) c; if (CIRCUIT_IS_ORIGIN(c)) origin_circ = TO_ORIGIN_CIRCUIT(nonconst_circ); else or_circ = TO_OR_CIRCUIT(nonconst_circ); } if (c->n_chan) { tor_assert(!c->n_hop); if (c->n_circ_id) { /* We use the _impl variant here to make sure we don't fail on marked * circuits, which would not be returned by the regular function. */ circuit_t *c2 = circuit_get_by_circid_channel_impl(c->n_circ_id, c->n_chan); tor_assert(c == c2); } } if (or_circ && or_circ->p_chan) { if (or_circ->p_circ_id) { /* ibid */ circuit_t *c2 = circuit_get_by_circid_channel_impl(or_circ->p_circ_id, or_circ->p_chan); tor_assert(c == c2); } } if (or_circ) for (conn = or_circ->n_streams; conn; conn = conn->next_stream) tor_assert(conn->base_.type == CONN_TYPE_EXIT); tor_assert(c->deliver_window >= 0); tor_assert(c->package_window >= 0); if (c->state == CIRCUIT_STATE_OPEN) { tor_assert(!c->n_chan_onionskin); if (or_circ) { tor_assert(or_circ->n_crypto); tor_assert(or_circ->p_crypto); tor_assert(or_circ->n_digest); tor_assert(or_circ->p_digest); } } if (c->state == CIRCUIT_STATE_CHAN_WAIT && !c->marked_for_close) { tor_assert(circuits_pending_chans && smartlist_isin(circuits_pending_chans, c)); } else { tor_assert(!circuits_pending_chans || !smartlist_isin(circuits_pending_chans, c)); } if (origin_circ && origin_circ->cpath) { assert_cpath_ok(origin_circ->cpath); } if (c->purpose == CIRCUIT_PURPOSE_REND_ESTABLISHED) { tor_assert(or_circ); if (!c->marked_for_close) { tor_assert(or_circ->rend_splice); tor_assert(or_circ->rend_splice->rend_splice == or_circ); } tor_assert(or_circ->rend_splice != or_circ); } else { tor_assert(!or_circ || !or_circ->rend_splice); } }