/* Copyright (c) 2016-2019, The Tor Project, Inc. */ /* See LICENSE for licensing information */ /** * \file shared_random_state.c * * \brief Functions and data structures for the state of the random protocol * as defined in proposal #250. **/ #define SHARED_RANDOM_STATE_PRIVATE #include "core/or/or.h" #include "app/config/config.h" #include "app/config/confparse.h" #include "lib/crypt_ops/crypto_util.h" #include "feature/dirauth/dirvote.h" #include "feature/nodelist/networkstatus.h" #include "feature/relay/router.h" #include "feature/dirauth/shared_random.h" #include "feature/hs_common/shared_random_client.h" #include "feature/dirauth/shared_random_state.h" #include "feature/dircommon/voting_schedule.h" #include "lib/encoding/confline.h" #include "lib/version/torversion.h" #include "app/config/or_state_st.h" /* Default filename of the shared random state on disk. */ static const char default_fname[] = "sr-state"; /* String representation of a protocol phase. */ static const char *phase_str[] = { "unknown", "commit", "reveal" }; /* Our shared random protocol state. There is only one possible state per * protocol run so this is the global state which is reset at every run once * the shared random value has been computed. */ static sr_state_t *sr_state = NULL; /* Representation of our persistent state on disk. The sr_state above * contains the data parsed from this state. When we save to disk, we * translate the sr_state to this sr_disk_state. */ static sr_disk_state_t *sr_disk_state = NULL; /* Disk state file keys. */ static const char dstate_commit_key[] = "Commit"; static const char dstate_prev_srv_key[] = "SharedRandPreviousValue"; static const char dstate_cur_srv_key[] = "SharedRandCurrentValue"; /** dummy instance of sr_disk_state_t, used for type-checking its * members with CONF_CHECK_VAR_TYPE. */ DUMMY_TYPECHECK_INSTANCE(sr_disk_state_t); #define VAR(varname,conftype,member,initvalue) \ CONFIG_VAR_ETYPE(sr_disk_state_t, varname, conftype, member, 0, initvalue) #define V(member,conftype,initvalue) \ VAR(#member, conftype, member, initvalue) /* Our persistent state magic number. */ #define SR_DISK_STATE_MAGIC 0x98AB1254 static int disk_state_validate_cb(void *old_state, void *state, void *default_state, int from_setconf, char **msg); static void disk_state_free_cb(const config_mgr_t *mgr, void *); /* Array of variables that are saved to disk as a persistent state. */ static const config_var_t state_vars[] = { V(Version, POSINT, "0"), V(TorVersion, STRING, NULL), V(ValidAfter, ISOTIME, NULL), V(ValidUntil, ISOTIME, NULL), V(Commit, LINELIST, NULL), V(SharedRandValues, LINELIST_V, NULL), VAR("SharedRandPreviousValue",LINELIST_S, SharedRandValues, NULL), VAR("SharedRandCurrentValue", LINELIST_S, SharedRandValues, NULL), END_OF_CONFIG_VARS }; /* "Extra" variable in the state that receives lines we can't parse. This * lets us preserve options from versions of Tor newer than us. */ static const struct_member_t state_extra_var = { .name = "__extra", .type = CONFIG_TYPE_LINELIST, .offset = offsetof(sr_disk_state_t, ExtraLines), }; /* Configuration format of sr_disk_state_t. */ static const config_format_t state_format = { sizeof(sr_disk_state_t), { "sr_disk_state_t", SR_DISK_STATE_MAGIC, offsetof(sr_disk_state_t, magic_), }, NULL, NULL, state_vars, disk_state_validate_cb, disk_state_free_cb, &state_extra_var, }; /* Global configuration manager for the shared-random state file */ static config_mgr_t *shared_random_state_mgr = NULL; /** Return the configuration manager for the shared-random state file. */ static const config_mgr_t * get_srs_mgr(void) { if (PREDICT_UNLIKELY(shared_random_state_mgr == NULL)) { shared_random_state_mgr = config_mgr_new(&state_format); config_mgr_freeze(shared_random_state_mgr); } return shared_random_state_mgr; } static void state_query_del_(sr_state_object_t obj_type, void *data); /* Return a string representation of a protocol phase. */ STATIC const char * get_phase_str(sr_phase_t phase) { const char *the_string = NULL; switch (phase) { case SR_PHASE_COMMIT: case SR_PHASE_REVEAL: the_string = phase_str[phase]; break; default: /* Unknown phase shouldn't be possible. */ tor_assert(0); } return the_string; } /* Return the time we should expire the state file created at now. * We expire the state file in the beginning of the next protocol run. */ STATIC time_t get_state_valid_until_time(time_t now) { int total_rounds = SHARED_RANDOM_N_ROUNDS * SHARED_RANDOM_N_PHASES; int current_round, voting_interval, rounds_left; time_t valid_until, beginning_of_current_round; voting_interval = get_voting_interval(); /* Find the time the current round started. */ beginning_of_current_round = get_start_time_of_current_round(); /* Find how many rounds are left till the end of the protocol run */ current_round = (now / voting_interval) % total_rounds; rounds_left = total_rounds - current_round; /* To find the valid-until time now, take the start time of the current * round and add to it the time it takes for the leftover rounds to * complete. */ valid_until = beginning_of_current_round + (rounds_left * voting_interval); { /* Logging */ char tbuf[ISO_TIME_LEN + 1]; format_iso_time(tbuf, valid_until); log_debug(LD_DIR, "SR: Valid until time for state set to %s.", tbuf); } return valid_until; } /* Given the consensus 'valid-after' time, return the protocol phase we should * be in. */ STATIC sr_phase_t get_sr_protocol_phase(time_t valid_after) { /* Shared random protocol has two phases, commit and reveal. */ int total_periods = SHARED_RANDOM_N_ROUNDS * SHARED_RANDOM_N_PHASES; int current_slot; /* Split time into slots of size 'voting_interval'. See which slot we are * currently into, and find which phase it corresponds to. */ current_slot = (valid_after / get_voting_interval()) % total_periods; if (current_slot < SHARED_RANDOM_N_ROUNDS) { return SR_PHASE_COMMIT; } else { return SR_PHASE_REVEAL; } } /* Add the given commit to state. It MUST be a valid commit * and there shouldn't be a commit from the same authority in the state * already else verification hasn't been done prior. This takes ownership of * the commit once in our state. */ static void commit_add_to_state(sr_commit_t *commit, sr_state_t *state) { sr_commit_t *saved_commit; tor_assert(commit); tor_assert(state); saved_commit = digestmap_set(state->commits, commit->rsa_identity, commit); if (saved_commit != NULL) { /* This means we already have that commit in our state so adding twice * the same commit is either a code flow error, a corrupted disk state * or some new unknown issue. */ log_warn(LD_DIR, "SR: Commit from %s exists in our state while " "adding it: '%s'", sr_commit_get_rsa_fpr(commit), commit->encoded_commit); sr_commit_free(saved_commit); } } /* Helper: deallocate a commit object. (Used with digestmap_free(), which * requires a function pointer whose argument is void *). */ static void commit_free_(void *p) { sr_commit_free_(p); } #define state_free(val) \ FREE_AND_NULL(sr_state_t, state_free_, (val)) /* Free a state that was allocated with state_new(). */ static void state_free_(sr_state_t *state) { if (state == NULL) { return; } tor_free(state->fname); digestmap_free(state->commits, commit_free_); tor_free(state->current_srv); tor_free(state->previous_srv); tor_free(state); } /* Allocate an sr_state_t object and returns it. If no fname, the * default file name is used. This function does NOT initialize the state * timestamp, phase or shared random value. NULL is never returned. */ static sr_state_t * state_new(const char *fname, time_t now) { sr_state_t *new_state = tor_malloc_zero(sizeof(*new_state)); /* If file name is not provided, use default. */ if (fname == NULL) { fname = default_fname; } new_state->fname = tor_strdup(fname); new_state->version = SR_PROTO_VERSION; new_state->commits = digestmap_new(); new_state->phase = get_sr_protocol_phase(now); new_state->valid_until = get_state_valid_until_time(now); return new_state; } /* Set our global state pointer with the one given. */ static void state_set(sr_state_t *state) { tor_assert(state); if (sr_state != NULL) { state_free(sr_state); } sr_state = state; } #define disk_state_free(val) \ FREE_AND_NULL(sr_disk_state_t, disk_state_free_, (val)) /* Free an allocated disk state. */ static void disk_state_free_(sr_disk_state_t *state) { if (state == NULL) { return; } config_free(get_srs_mgr(), state); } /* Allocate a new disk state, initialize it and return it. */ static sr_disk_state_t * disk_state_new(time_t now) { sr_disk_state_t *new_state = tor_malloc_zero(sizeof(*new_state)); new_state->magic_ = SR_DISK_STATE_MAGIC; new_state->Version = SR_PROTO_VERSION; new_state->TorVersion = tor_strdup(get_version()); new_state->ValidUntil = get_state_valid_until_time(now); new_state->ValidAfter = now; /* Init config format. */ config_init(get_srs_mgr(), new_state); return new_state; } /* Set our global disk state with the given state. */ static void disk_state_set(sr_disk_state_t *state) { tor_assert(state); if (sr_disk_state != NULL) { disk_state_free(sr_disk_state); } sr_disk_state = state; } /* Return -1 if the disk state is invalid (something in there that we can't or * shouldn't use). Return 0 if everything checks out. */ static int disk_state_validate(const sr_disk_state_t *state) { time_t now; tor_assert(state); /* Do we support the protocol version in the state or is it 0 meaning * Version wasn't found in the state file or bad anyway ? */ if (state->Version == 0 || state->Version > SR_PROTO_VERSION) { goto invalid; } /* If the valid until time is before now, we shouldn't use that state. */ now = time(NULL); if (state->ValidUntil < now) { log_info(LD_DIR, "SR: Disk state has expired. Ignoring it."); goto invalid; } /* Make sure we don't have a valid after time that is earlier than a valid * until time which would make things not work well. */ if (state->ValidAfter >= state->ValidUntil) { log_info(LD_DIR, "SR: Disk state valid after/until times are invalid."); goto invalid; } return 0; invalid: return -1; } /* Validate the disk state (NOP for now). */ static int disk_state_validate_cb(void *old_state, void *state, void *default_state, int from_setconf, char **msg) { /* We don't use these; only options do. */ (void) from_setconf; (void) default_state; (void) old_state; /* This is called by config_dump which is just before we are about to * write it to disk. At that point, our global memory state has been * copied to the disk state so it's fair to assume it's trustable. */ (void) state; (void) msg; return 0; } static void disk_state_free_cb(const config_mgr_t *mgr, void *state) { (void)mgr; disk_state_free_(state); } /* Parse the Commit line(s) in the disk state and translate them to the * the memory state. Return 0 on success else -1 on error. */ static int disk_state_parse_commits(sr_state_t *state, const sr_disk_state_t *disk_state) { config_line_t *line; smartlist_t *args = NULL; tor_assert(state); tor_assert(disk_state); for (line = disk_state->Commit; line; line = line->next) { sr_commit_t *commit = NULL; /* Extra safety. */ if (strcasecmp(line->key, dstate_commit_key) || line->value == NULL) { /* Ignore any lines that are not commits. */ tor_fragile_assert(); continue; } args = smartlist_new(); smartlist_split_string(args, line->value, " ", SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); if (smartlist_len(args) < 3) { log_warn(LD_BUG, "SR: Too few arguments in Commit Line: %s", escaped(line->value)); goto error; } commit = sr_parse_commit(args); if (commit == NULL) { /* Ignore badly formed commit. It could also be a authority * fingerprint that we don't know about so it shouldn't be used. */ smartlist_free(args); continue; } /* We consider parseable commit from our disk state to be valid because * they need to be in the first place to get in there. */ commit->valid = 1; /* Add commit to our state pointer. */ commit_add_to_state(commit, state); SMARTLIST_FOREACH(args, char *, cp, tor_free(cp)); smartlist_free(args); } return 0; error: SMARTLIST_FOREACH(args, char *, cp, tor_free(cp)); smartlist_free(args); return -1; } /* Parse a share random value line from the disk state and save it to dst * which is an allocated srv object. Return 0 on success else -1. */ static int disk_state_parse_srv(const char *value, sr_srv_t *dst) { int ret = -1; smartlist_t *args; sr_srv_t *srv; tor_assert(value); tor_assert(dst); args = smartlist_new(); smartlist_split_string(args, value, " ", SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); if (smartlist_len(args) < 2) { log_warn(LD_BUG, "SR: Too few arguments in shared random value. " "Line: %s", escaped(value)); goto error; } srv = sr_parse_srv(args); if (srv == NULL) { goto error; } dst->num_reveals = srv->num_reveals; memcpy(dst->value, srv->value, sizeof(dst->value)); tor_free(srv); ret = 0; error: SMARTLIST_FOREACH(args, char *, s, tor_free(s)); smartlist_free(args); return ret; } /* Parse both SharedRandCurrentValue and SharedRandPreviousValue line from * the state. Return 0 on success else -1. */ static int disk_state_parse_sr_values(sr_state_t *state, const sr_disk_state_t *disk_state) { /* Only one value per type (current or previous) is allowed so we keep * track of it with these flag. */ unsigned int seen_previous = 0, seen_current = 0; config_line_t *line; sr_srv_t *srv = NULL; tor_assert(state); tor_assert(disk_state); for (line = disk_state->SharedRandValues; line; line = line->next) { if (line->value == NULL) { continue; } srv = tor_malloc_zero(sizeof(*srv)); if (disk_state_parse_srv(line->value, srv) < 0) { log_warn(LD_BUG, "SR: Broken current SRV line in state %s", escaped(line->value)); goto bad; } if (!strcasecmp(line->key, dstate_prev_srv_key)) { if (seen_previous) { log_warn(LD_DIR, "SR: Second previous SRV value seen. Bad state"); goto bad; } state->previous_srv = srv; seen_previous = 1; } else if (!strcasecmp(line->key, dstate_cur_srv_key)) { if (seen_current) { log_warn(LD_DIR, "SR: Second current SRV value seen. Bad state"); goto bad; } state->current_srv = srv; seen_current = 1; } else { /* Unknown key. Ignoring. */ tor_free(srv); } } return 0; bad: tor_free(srv); return -1; } /* Parse the given disk state and set a newly allocated state. On success, * return that state else NULL. */ static sr_state_t * disk_state_parse(const sr_disk_state_t *new_disk_state) { sr_state_t *new_state = state_new(default_fname, time(NULL)); tor_assert(new_disk_state); new_state->version = new_disk_state->Version; new_state->valid_until = new_disk_state->ValidUntil; new_state->valid_after = new_disk_state->ValidAfter; /* Set our current phase according to the valid-after time in our disk * state. The disk state we are parsing contains everything for the phase * starting at valid_after so make sure our phase reflects that. */ new_state->phase = get_sr_protocol_phase(new_state->valid_after); /* Parse the shared random values. */ if (disk_state_parse_sr_values(new_state, new_disk_state) < 0) { goto error; } /* Parse the commits. */ if (disk_state_parse_commits(new_state, new_disk_state) < 0) { goto error; } /* Great! This new state contains everything we had on disk. */ return new_state; error: state_free(new_state); return NULL; } /* From a valid commit object and an allocated config line, set the line's * value to the state string representation of a commit. */ static void disk_state_put_commit_line(const sr_commit_t *commit, config_line_t *line) { char *reveal_str = NULL; tor_assert(commit); tor_assert(line); if (!fast_mem_is_zero(commit->encoded_reveal, sizeof(commit->encoded_reveal))) { /* Add extra whitespace so we can format the line correctly. */ tor_asprintf(&reveal_str, " %s", commit->encoded_reveal); } tor_asprintf(&line->value, "%u %s %s %s%s", SR_PROTO_VERSION, crypto_digest_algorithm_get_name(commit->alg), sr_commit_get_rsa_fpr(commit), commit->encoded_commit, reveal_str != NULL ? reveal_str : ""); if (reveal_str != NULL) { memwipe(reveal_str, 0, strlen(reveal_str)); tor_free(reveal_str); } } /* From a valid srv object and an allocated config line, set the line's * value to the state string representation of a shared random value. */ static void disk_state_put_srv_line(const sr_srv_t *srv, config_line_t *line) { char encoded[SR_SRV_VALUE_BASE64_LEN + 1]; tor_assert(line); /* No SRV value thus don't add the line. This is possible since we might * not have a current or previous SRV value in our state. */ if (srv == NULL) { return; } sr_srv_encode(encoded, sizeof(encoded), srv); tor_asprintf(&line->value, "%" PRIu64 " %s", srv->num_reveals, encoded); } /* Reset disk state that is free allocated memory and zeroed the object. */ static void disk_state_reset(void) { /* Free allocated memory */ config_free_lines(sr_disk_state->Commit); config_free_lines(sr_disk_state->SharedRandValues); config_free_lines(sr_disk_state->ExtraLines); tor_free(sr_disk_state->TorVersion); /* Clean up the struct */ memset(sr_disk_state, 0, sizeof(*sr_disk_state)); /* Reset it with useful data */ sr_disk_state->magic_ = SR_DISK_STATE_MAGIC; sr_disk_state->TorVersion = tor_strdup(get_version()); } /* Update our disk state based on our global SR state. */ static void disk_state_update(void) { config_line_t **next, *line; if (BUG(!sr_disk_state)) return; if (BUG(!sr_state)) return; /* Reset current disk state. */ disk_state_reset(); /* First, update elements that we don't need to do a construction. */ sr_disk_state->Version = sr_state->version; sr_disk_state->ValidUntil = sr_state->valid_until; sr_disk_state->ValidAfter = sr_state->valid_after; /* Shared random values. */ next = &sr_disk_state->SharedRandValues; if (sr_state->previous_srv != NULL) { *next = line = tor_malloc_zero(sizeof(config_line_t)); line->key = tor_strdup(dstate_prev_srv_key); disk_state_put_srv_line(sr_state->previous_srv, line); /* Go to the next shared random value. */ next = &(line->next); } if (sr_state->current_srv != NULL) { *next = line = tor_malloc_zero(sizeof(*line)); line->key = tor_strdup(dstate_cur_srv_key); disk_state_put_srv_line(sr_state->current_srv, line); } /* Parse the commits and construct config line(s). */ next = &sr_disk_state->Commit; DIGESTMAP_FOREACH(sr_state->commits, key, sr_commit_t *, commit) { *next = line = tor_malloc_zero(sizeof(*line)); line->key = tor_strdup(dstate_commit_key); disk_state_put_commit_line(commit, line); next = &(line->next); } DIGESTMAP_FOREACH_END; } /* Load state from disk and put it into our disk state. If the state passes * validation, our global state will be updated with it. Return 0 on * success. On error, -EINVAL is returned if the state on disk did contained * something malformed or is unreadable. -ENOENT is returned indicating that * the state file is either empty of non existing. */ static int disk_state_load_from_disk(void) { int ret; char *fname; fname = get_datadir_fname(default_fname); ret = disk_state_load_from_disk_impl(fname); tor_free(fname); return ret; } /* Helper for disk_state_load_from_disk(). */ STATIC int disk_state_load_from_disk_impl(const char *fname) { int ret; char *content = NULL; sr_state_t *parsed_state = NULL; sr_disk_state_t *disk_state = NULL; /* Read content of file so we can parse it. */ if ((content = read_file_to_str(fname, 0, NULL)) == NULL) { log_warn(LD_FS, "SR: Unable to read SR state file %s", escaped(fname)); ret = -errno; goto error; } { config_line_t *lines = NULL; char *errmsg = NULL; /* Every error in this code path will return EINVAL. */ ret = -EINVAL; if (config_get_lines(content, &lines, 0) < 0) { config_free_lines(lines); goto error; } disk_state = disk_state_new(time(NULL)); config_assign(get_srs_mgr(), disk_state, lines, 0, &errmsg); config_free_lines(lines); if (errmsg) { log_warn(LD_DIR, "SR: Reading state error: %s", errmsg); tor_free(errmsg); goto error; } } /* So far so good, we've loaded our state file into our disk state. Let's * validate it and then parse it. */ if (disk_state_validate(disk_state) < 0) { ret = -EINVAL; goto error; } parsed_state = disk_state_parse(disk_state); if (parsed_state == NULL) { ret = -EINVAL; goto error; } state_set(parsed_state); disk_state_set(disk_state); tor_free(content); log_info(LD_DIR, "SR: State loaded successfully from file %s", fname); return 0; error: disk_state_free(disk_state); tor_free(content); return ret; } /* Save the disk state to disk but before that update it from the current * state so we always have the latest. Return 0 on success else -1. */ static int disk_state_save_to_disk(void) { int ret; char *state, *content = NULL, *fname = NULL; char tbuf[ISO_TIME_LEN + 1]; time_t now = time(NULL); /* If we didn't have the opportunity to setup an internal disk state, * don't bother saving something to disk. */ if (sr_disk_state == NULL) { ret = 0; goto done; } /* Make sure that our disk state is up to date with our memory state * before saving it to disk. */ disk_state_update(); state = config_dump(get_srs_mgr(), NULL, sr_disk_state, 0, 0); format_local_iso_time(tbuf, now); tor_asprintf(&content, "# Tor shared random state file last generated on %s " "local time\n" "# Other times below are in UTC\n" "# Please *do not* edit this file.\n\n%s", tbuf, state); tor_free(state); fname = get_datadir_fname(default_fname); if (write_str_to_file(fname, content, 0) < 0) { log_warn(LD_FS, "SR: Unable to write SR state to file %s", fname); ret = -1; goto done; } ret = 0; log_debug(LD_DIR, "SR: Saved state to file %s", fname); done: tor_free(fname); tor_free(content); return ret; } /* Reset our state to prepare for a new protocol run. Once this returns, all * commits in the state will be removed and freed. */ STATIC void reset_state_for_new_protocol_run(time_t valid_after) { if (BUG(!sr_state)) return; /* Keep counters in track */ sr_state->n_reveal_rounds = 0; sr_state->n_commit_rounds = 0; sr_state->n_protocol_runs++; /* Reset valid-until */ sr_state->valid_until = get_state_valid_until_time(valid_after); sr_state->valid_after = valid_after; /* We are in a new protocol run so cleanup commits. */ sr_state_delete_commits(); } /* This is the first round of the new protocol run starting at * valid_after. Do the necessary housekeeping. */ STATIC void new_protocol_run(time_t valid_after) { sr_commit_t *our_commitment = NULL; /* Only compute the srv at the end of the reveal phase. */ if (sr_state->phase == SR_PHASE_REVEAL) { /* We are about to compute a new shared random value that will be set in * our state as the current value so rotate values. */ state_rotate_srv(); /* Compute the shared randomness value of the day. */ sr_compute_srv(); } /* Prepare for the new protocol run by reseting the state */ reset_state_for_new_protocol_run(valid_after); /* Do some logging */ log_info(LD_DIR, "SR: Protocol run #%" PRIu64 " starting!", sr_state->n_protocol_runs); /* Generate fresh commitments for this protocol run */ our_commitment = sr_generate_our_commit(valid_after, get_my_v3_authority_cert()); if (our_commitment) { /* Add our commitment to our state. In case we are unable to create one * (highly unlikely), we won't vote for this protocol run since our * commitment won't be in our state. */ sr_state_add_commit(our_commitment); } } /* Return 1 iff the next_phase is a phase transition from the current * phase that is it's different. */ STATIC int is_phase_transition(sr_phase_t next_phase) { return sr_state->phase != next_phase; } /* Helper function: return a commit using the RSA fingerprint of the * authority or NULL if no such commit is known. */ static sr_commit_t * state_query_get_commit(const char *rsa_fpr) { tor_assert(rsa_fpr); return digestmap_get(sr_state->commits, rsa_fpr); } /* Helper function: This handles the GET state action using an * obj_type and data needed for the action. */ static void * state_query_get_(sr_state_object_t obj_type, const void *data) { if (BUG(!sr_state)) return NULL; void *obj = NULL; switch (obj_type) { case SR_STATE_OBJ_COMMIT: { obj = state_query_get_commit(data); break; } case SR_STATE_OBJ_COMMITS: obj = sr_state->commits; break; case SR_STATE_OBJ_CURSRV: obj = sr_state->current_srv; break; case SR_STATE_OBJ_PREVSRV: obj = sr_state->previous_srv; break; case SR_STATE_OBJ_PHASE: obj = &sr_state->phase; break; case SR_STATE_OBJ_VALID_AFTER: default: tor_assert(0); } return obj; } /* Helper function: This handles the PUT state action using an * obj_type and data needed for the action. * PUT frees the previous data before replacing it, if needed. */ static void state_query_put_(sr_state_object_t obj_type, void *data) { if (BUG(!sr_state)) return; switch (obj_type) { case SR_STATE_OBJ_COMMIT: { sr_commit_t *commit = data; tor_assert(commit); /* commit_add_to_state() frees the old commit, if there is one */ commit_add_to_state(commit, sr_state); break; } case SR_STATE_OBJ_CURSRV: /* Check if the new pointer is the same as the old one: if it is, it's * probably a bug. The caller may have confused current and previous, * or they may have forgotten to sr_srv_dup(). * Putting NULL multiple times is allowed. */ if (!BUG(data && sr_state->current_srv == (sr_srv_t *) data)) { /* We own the old SRV, so we need to free it. */ state_query_del_(SR_STATE_OBJ_CURSRV, NULL); sr_state->current_srv = (sr_srv_t *) data; } break; case SR_STATE_OBJ_PREVSRV: /* Check if the new pointer is the same as the old one: if it is, it's * probably a bug. The caller may have confused current and previous, * or they may have forgotten to sr_srv_dup(). * Putting NULL multiple times is allowed. */ if (!BUG(data && sr_state->previous_srv == (sr_srv_t *) data)) { /* We own the old SRV, so we need to free it. */ state_query_del_(SR_STATE_OBJ_PREVSRV, NULL); sr_state->previous_srv = (sr_srv_t *) data; } break; case SR_STATE_OBJ_VALID_AFTER: sr_state->valid_after = *((time_t *) data); break; /* It's not allowed to change the phase nor the full commitments map from * the state. The phase is decided during a strict process post voting and * the commits should be put individually. */ case SR_STATE_OBJ_PHASE: case SR_STATE_OBJ_COMMITS: default: tor_assert(0); } } /* Helper function: This handles the DEL_ALL state action using an * obj_type and data needed for the action. */ static void state_query_del_all_(sr_state_object_t obj_type) { if (BUG(!sr_state)) return; switch (obj_type) { case SR_STATE_OBJ_COMMIT: { /* We are in a new protocol run so cleanup commitments. */ DIGESTMAP_FOREACH_MODIFY(sr_state->commits, key, sr_commit_t *, c) { sr_commit_free(c); MAP_DEL_CURRENT(key); } DIGESTMAP_FOREACH_END; break; } /* The following objects are _NOT_ supposed to be removed. */ case SR_STATE_OBJ_CURSRV: case SR_STATE_OBJ_PREVSRV: case SR_STATE_OBJ_PHASE: case SR_STATE_OBJ_COMMITS: case SR_STATE_OBJ_VALID_AFTER: default: tor_assert(0); } } /* Helper function: This handles the DEL state action using an * obj_type and data needed for the action. */ static void state_query_del_(sr_state_object_t obj_type, void *data) { (void) data; if (BUG(!sr_state)) return; switch (obj_type) { case SR_STATE_OBJ_PREVSRV: tor_free(sr_state->previous_srv); break; case SR_STATE_OBJ_CURSRV: tor_free(sr_state->current_srv); break; case SR_STATE_OBJ_COMMIT: case SR_STATE_OBJ_COMMITS: case SR_STATE_OBJ_PHASE: case SR_STATE_OBJ_VALID_AFTER: default: tor_assert(0); } } /* Query state using an action for an object type obj_type. * The data pointer needs to point to an object that the action needs * to use and if anything is required to be returned, it is stored in * out. * * This mechanism exists so we have one single point where we synchronized * our memory state with our disk state for every actions that changes it. * We then trigger a write on disk immediately. * * This should be the only entry point to our memory state. It's used by all * our state accessors and should be in the future. */ static void state_query(sr_state_action_t action, sr_state_object_t obj_type, void *data, void **out) { switch (action) { case SR_STATE_ACTION_GET: *out = state_query_get_(obj_type, data); break; case SR_STATE_ACTION_PUT: state_query_put_(obj_type, data); break; case SR_STATE_ACTION_DEL: state_query_del_(obj_type, data); break; case SR_STATE_ACTION_DEL_ALL: state_query_del_all_(obj_type); break; case SR_STATE_ACTION_SAVE: /* Only trigger a disk state save. */ break; default: tor_assert(0); } /* If the action actually changes the state, immediately save it to disk. * The following will sync the state -> disk state and then save it. */ if (action != SR_STATE_ACTION_GET) { disk_state_save_to_disk(); } } /* Delete the current SRV value from the state freeing it and the value is set * to NULL meaning empty. */ STATIC void state_del_current_srv(void) { state_query(SR_STATE_ACTION_DEL, SR_STATE_OBJ_CURSRV, NULL, NULL); } /* Delete the previous SRV value from the state freeing it and the value is * set to NULL meaning empty. */ STATIC void state_del_previous_srv(void) { state_query(SR_STATE_ACTION_DEL, SR_STATE_OBJ_PREVSRV, NULL, NULL); } /* Rotate SRV value by setting the previous SRV to the current SRV, and * clearing the current SRV. */ STATIC void state_rotate_srv(void) { /* First delete previous SRV from the state. Object will be freed. */ state_del_previous_srv(); /* Set previous SRV to a copy of the current one. */ sr_state_set_previous_srv(sr_srv_dup(sr_state_get_current_srv())); /* Free and NULL the current srv. */ sr_state_set_current_srv(NULL); } /* Set valid after time in the our state. */ void sr_state_set_valid_after(time_t valid_after) { state_query(SR_STATE_ACTION_PUT, SR_STATE_OBJ_VALID_AFTER, (void *) &valid_after, NULL); } /* Return the phase we are currently in according to our state. */ sr_phase_t sr_state_get_phase(void) { void *ptr; state_query(SR_STATE_ACTION_GET, SR_STATE_OBJ_PHASE, NULL, &ptr); return *(sr_phase_t *) ptr; } /* Return the previous SRV value from our state. Value CAN be NULL. * The state object owns the SRV, so the calling code should not free the SRV. * Use sr_srv_dup() if you want to keep a copy of the SRV. */ const sr_srv_t * sr_state_get_previous_srv(void) { const sr_srv_t *srv; state_query(SR_STATE_ACTION_GET, SR_STATE_OBJ_PREVSRV, NULL, (void *) &srv); return srv; } /* Set the current SRV value from our state. Value CAN be NULL. The srv * object ownership is transferred to the state object. */ void sr_state_set_previous_srv(const sr_srv_t *srv) { state_query(SR_STATE_ACTION_PUT, SR_STATE_OBJ_PREVSRV, (void *) srv, NULL); } /* Return the current SRV value from our state. Value CAN be NULL. * The state object owns the SRV, so the calling code should not free the SRV. * Use sr_srv_dup() if you want to keep a copy of the SRV. */ const sr_srv_t * sr_state_get_current_srv(void) { const sr_srv_t *srv; state_query(SR_STATE_ACTION_GET, SR_STATE_OBJ_CURSRV, NULL, (void *) &srv); return srv; } /* Set the current SRV value from our state. Value CAN be NULL. The srv * object ownership is transferred to the state object. */ void sr_state_set_current_srv(const sr_srv_t *srv) { state_query(SR_STATE_ACTION_PUT, SR_STATE_OBJ_CURSRV, (void *) srv, NULL); } /* Clean all the SRVs in our state. */ void sr_state_clean_srvs(void) { /* Remove SRVs from state. They will be set to NULL as "empty". */ state_del_previous_srv(); state_del_current_srv(); } /* Return a pointer to the commits map from our state. CANNOT be NULL. */ digestmap_t * sr_state_get_commits(void) { digestmap_t *commits; state_query(SR_STATE_ACTION_GET, SR_STATE_OBJ_COMMITS, NULL, (void *) &commits); tor_assert(commits); return commits; } /* Update the current SR state as needed for the upcoming voting round at * valid_after. */ void sr_state_update(time_t valid_after) { sr_phase_t next_phase; if (BUG(!sr_state)) return; /* Don't call this function twice in the same voting period. */ if (valid_after <= sr_state->valid_after) { log_info(LD_DIR, "SR: Asked to update state twice. Ignoring."); return; } /* Get phase of upcoming round. */ next_phase = get_sr_protocol_phase(valid_after); /* If we are transitioning to a new protocol phase, prepare the stage. */ if (is_phase_transition(next_phase)) { if (next_phase == SR_PHASE_COMMIT) { /* Going into commit phase means we are starting a new protocol run. */ new_protocol_run(valid_after); } /* Set the new phase for this round */ sr_state->phase = next_phase; } else if (sr_state->phase == SR_PHASE_COMMIT && digestmap_size(sr_state->commits) == 0) { /* We are _NOT_ in a transition phase so if we are in the commit phase * and have no commit, generate one. Chances are that we are booting up * so let's have a commit in our state for the next voting period. */ sr_commit_t *our_commit = sr_generate_our_commit(valid_after, get_my_v3_authority_cert()); if (our_commit) { /* Add our commitment to our state. In case we are unable to create one * (highly unlikely), we won't vote for this protocol run since our * commitment won't be in our state. */ sr_state_add_commit(our_commit); } } sr_state_set_valid_after(valid_after); /* Count the current round */ if (sr_state->phase == SR_PHASE_COMMIT) { /* invariant check: we've not entered reveal phase yet */ if (BUG(sr_state->n_reveal_rounds != 0)) return; sr_state->n_commit_rounds++; } else { sr_state->n_reveal_rounds++; } { /* Debugging. */ char tbuf[ISO_TIME_LEN + 1]; format_iso_time(tbuf, valid_after); log_info(LD_DIR, "SR: State prepared for upcoming voting period (%s). " "Upcoming phase is %s (counters: %d commit & %d reveal rounds).", tbuf, get_phase_str(sr_state->phase), sr_state->n_commit_rounds, sr_state->n_reveal_rounds); } } /* Return commit object from the given authority digest rsa_identity. * Return NULL if not found. */ sr_commit_t * sr_state_get_commit(const char *rsa_identity) { sr_commit_t *commit; tor_assert(rsa_identity); state_query(SR_STATE_ACTION_GET, SR_STATE_OBJ_COMMIT, (void *) rsa_identity, (void *) &commit); return commit; } /* Add commit to the permanent state. The commit object ownership is * transferred to the state so the caller MUST not free it. */ void sr_state_add_commit(sr_commit_t *commit) { tor_assert(commit); /* Put the commit to the global state. */ state_query(SR_STATE_ACTION_PUT, SR_STATE_OBJ_COMMIT, (void *) commit, NULL); log_debug(LD_DIR, "SR: Commit from %s has been added to our state.", sr_commit_get_rsa_fpr(commit)); } /* Remove all commits from our state. */ void sr_state_delete_commits(void) { state_query(SR_STATE_ACTION_DEL_ALL, SR_STATE_OBJ_COMMIT, NULL, NULL); } /* Copy the reveal information from commit into saved_commit. * This saved_commit MUST come from our current SR state. Once modified, * the disk state is updated. */ void sr_state_copy_reveal_info(sr_commit_t *saved_commit, const sr_commit_t *commit) { tor_assert(saved_commit); tor_assert(commit); saved_commit->reveal_ts = commit->reveal_ts; memcpy(saved_commit->random_number, commit->random_number, sizeof(saved_commit->random_number)); strlcpy(saved_commit->encoded_reveal, commit->encoded_reveal, sizeof(saved_commit->encoded_reveal)); state_query(SR_STATE_ACTION_SAVE, 0, NULL, NULL); log_debug(LD_DIR, "SR: Reveal value learned %s (for commit %s) from %s", saved_commit->encoded_reveal, saved_commit->encoded_commit, sr_commit_get_rsa_fpr(saved_commit)); } /* Set the fresh SRV flag from our state. This doesn't need to trigger a * disk state synchronization so we directly change the state. */ void sr_state_set_fresh_srv(void) { sr_state->is_srv_fresh = 1; } /* Unset the fresh SRV flag from our state. This doesn't need to trigger a * disk state synchronization so we directly change the state. */ void sr_state_unset_fresh_srv(void) { sr_state->is_srv_fresh = 0; } /* Return the value of the fresh SRV flag. */ unsigned int sr_state_srv_is_fresh(void) { return sr_state->is_srv_fresh; } /* Cleanup and free our disk and memory state. */ void sr_state_free_all(void) { state_free(sr_state); disk_state_free(sr_disk_state); /* Nullify our global state. */ sr_state = NULL; sr_disk_state = NULL; config_mgr_free(shared_random_state_mgr); } /* Save our current state in memory to disk. */ void sr_state_save(void) { /* Query a SAVE action on our current state so it's synced and saved. */ state_query(SR_STATE_ACTION_SAVE, 0, NULL, NULL); } /* Return 1 iff the state has been initialized that is it exists in memory. * Return 0 otherwise. */ int sr_state_is_initialized(void) { return sr_state == NULL ? 0 : 1; } /* Initialize the disk and memory state. * * If save_to_disk is set to 1, the state is immediately saved to disk after * creation else it's not thus only kept in memory. * If read_from_disk is set to 1, we try to load the state from the disk and * if not found, a new state is created. * * Return 0 on success else a negative value on error. */ int sr_state_init(int save_to_disk, int read_from_disk) { int ret = -ENOENT; time_t now = time(NULL); /* We shouldn't have those assigned. */ tor_assert(sr_disk_state == NULL); tor_assert(sr_state == NULL); /* First, try to load the state from disk. */ if (read_from_disk) { ret = disk_state_load_from_disk(); } if (ret < 0) { switch (-ret) { case EINVAL: /* We have a state on disk but it contains something we couldn't parse * or an invalid entry in the state file. Let's remove it since it's * obviously unusable and replace it by an new fresh state below. */ case ENOENT: { /* No state on disk so allocate our states for the first time. */ sr_state_t *new_state = state_new(default_fname, now); sr_disk_state_t *new_disk_state = disk_state_new(now); state_set(new_state); /* It's important to set our disk state pointer since the save call * below uses it to synchronized it with our memory state. */ disk_state_set(new_disk_state); /* No entry, let's save our new state to disk. */ if (save_to_disk && disk_state_save_to_disk() < 0) { goto error; } break; } default: /* Big problem. Not possible. */ tor_assert(0); } } /* We have a state in memory, let's make sure it's updated for the current * and next voting round. */ { time_t valid_after = voting_schedule_get_next_valid_after_time(); sr_state_update(valid_after); } return 0; error: return -1; } #ifdef TOR_UNIT_TESTS /* Set the current phase of the protocol. Used only by unit tests. */ void set_sr_phase(sr_phase_t phase) { if (BUG(!sr_state)) return; sr_state->phase = phase; } /* Get the SR state. Used only by unit tests */ sr_state_t * get_sr_state(void) { return sr_state; } #endif /* defined(TOR_UNIT_TESTS) */