/* SPDX-License-Identifier: GPL-3.0-or-later * Copyright © 2016-2018 The TokTok team. * Copyright © 2013 Tox project. */ /** * Implementation of the announce part of docs/Prevent_Tracking.txt */ #include "onion_announce.h" #include #include #include #include "DHT.h" #include "LAN_discovery.h" #include "ccompat.h" #include "mono_time.h" #include "shared_key_cache.h" #include "util.h" #define PING_ID_TIMEOUT ONION_ANNOUNCE_TIMEOUT #define ANNOUNCE_REQUEST_MIN_SIZE_RECV (ONION_ANNOUNCE_REQUEST_MIN_SIZE + ONION_RETURN_3) #define ANNOUNCE_REQUEST_MAX_SIZE_RECV (ONION_ANNOUNCE_REQUEST_MAX_SIZE + ONION_RETURN_3) /* TODO(Jfreegman): DEPRECATE */ #define ANNOUNCE_REQUEST_SIZE_RECV (ONION_ANNOUNCE_REQUEST_SIZE + ONION_RETURN_3) #define DATA_REQUEST_MIN_SIZE ONION_DATA_REQUEST_MIN_SIZE #define DATA_REQUEST_MIN_SIZE_RECV (DATA_REQUEST_MIN_SIZE + ONION_RETURN_3) #define ONION_MINIMAL_SIZE (ONION_PING_ID_SIZE + CRYPTO_PUBLIC_KEY_SIZE * 2 + ONION_ANNOUNCE_SENDBACK_DATA_LENGTH) /* Settings for the shared key cache */ #define MAX_KEYS_PER_SLOT 4 #define KEYS_TIMEOUT 600 static_assert(ONION_PING_ID_SIZE == CRYPTO_PUBLIC_KEY_SIZE, "announce response packets assume that ONION_PING_ID_SIZE is equal to CRYPTO_PUBLIC_KEY_SIZE"); typedef struct Onion_Announce_Entry { uint8_t public_key[CRYPTO_PUBLIC_KEY_SIZE]; IP_Port ret_ip_port; uint8_t ret[ONION_RETURN_3]; uint8_t data_public_key[CRYPTO_PUBLIC_KEY_SIZE]; uint64_t announce_time; } Onion_Announce_Entry; struct Onion_Announce { const Logger *log; const Mono_Time *mono_time; const Random *rng; DHT *dht; Networking_Core *net; Onion_Announce_Entry entries[ONION_ANNOUNCE_MAX_ENTRIES]; uint8_t hmac_key[CRYPTO_HMAC_KEY_SIZE]; Shared_Key_Cache *shared_keys_recv; uint16_t extra_data_max_size; pack_extra_data_cb *extra_data_callback; void *extra_data_object; }; void onion_announce_extra_data_callback(Onion_Announce *onion_a, uint16_t extra_data_max_size, pack_extra_data_cb *extra_data_callback, void *extra_data_object) { onion_a->extra_data_max_size = extra_data_max_size; onion_a->extra_data_callback = extra_data_callback; onion_a->extra_data_object = extra_data_object; } uint8_t *onion_announce_entry_public_key(Onion_Announce *onion_a, uint32_t entry) { return onion_a->entries[entry].public_key; } void onion_announce_entry_set_time(Onion_Announce *onion_a, uint32_t entry, uint64_t announce_time) { onion_a->entries[entry].announce_time = announce_time; } /** @brief Create an onion announce request packet in packet of max_packet_length. * * Recommended value for max_packet_length is ONION_ANNOUNCE_REQUEST_MIN_SIZE. * * dest_client_id is the public key of the node the packet will be sent to. * public_key and secret_key is the kepair which will be used to encrypt the request. * ping_id is the ping id that will be sent in the request. * client_id is the client id of the node we are searching for. * data_public_key is the public key we want others to encrypt their data packets with. * sendback_data is the data of ONION_ANNOUNCE_SENDBACK_DATA_LENGTH length that we expect to * receive back in the response. * * return -1 on failure. * return packet length on success. */ int create_announce_request(const Random *rng, uint8_t *packet, uint16_t max_packet_length, const uint8_t *dest_client_id, const uint8_t *public_key, const uint8_t *secret_key, const uint8_t *ping_id, const uint8_t *client_id, const uint8_t *data_public_key, uint64_t sendback_data) { if (max_packet_length < ONION_ANNOUNCE_REQUEST_MIN_SIZE) { return -1; } uint8_t plain[ONION_PING_ID_SIZE + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_PUBLIC_KEY_SIZE + ONION_ANNOUNCE_SENDBACK_DATA_LENGTH]; memcpy(plain, ping_id, ONION_PING_ID_SIZE); memcpy(plain + ONION_PING_ID_SIZE, client_id, CRYPTO_PUBLIC_KEY_SIZE); memcpy(plain + ONION_PING_ID_SIZE + CRYPTO_PUBLIC_KEY_SIZE, data_public_key, CRYPTO_PUBLIC_KEY_SIZE); memcpy(plain + ONION_PING_ID_SIZE + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_PUBLIC_KEY_SIZE, &sendback_data, sizeof(sendback_data)); packet[0] = NET_PACKET_ANNOUNCE_REQUEST_OLD; random_nonce(rng, packet + 1); const int len = encrypt_data(dest_client_id, secret_key, packet + 1, plain, sizeof(plain), packet + 1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE); if ((uint32_t)len + 1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE != ONION_ANNOUNCE_REQUEST_MIN_SIZE) { return -1; } memcpy(packet + 1 + CRYPTO_NONCE_SIZE, public_key, CRYPTO_PUBLIC_KEY_SIZE); return ONION_ANNOUNCE_REQUEST_MIN_SIZE; } /** @brief Create an onion data request packet in packet of max_packet_length. * * Recommended value for max_packet_length is ONION_ANNOUNCE_REQUEST_SIZE. * * public_key is the real public key of the node which we want to send the data of length length to. * encrypt_public_key is the public key used to encrypt the data packet. * * nonce is the nonce to encrypt this packet with * * return -1 on failure. * return 0 on success. */ int create_data_request(const Random *rng, uint8_t *packet, uint16_t max_packet_length, const uint8_t *public_key, const uint8_t *encrypt_public_key, const uint8_t *nonce, const uint8_t *data, uint16_t length) { if (DATA_REQUEST_MIN_SIZE + length > max_packet_length) { return -1; } if (DATA_REQUEST_MIN_SIZE + length > ONION_MAX_DATA_SIZE) { return -1; } packet[0] = NET_PACKET_ONION_DATA_REQUEST; memcpy(packet + 1, public_key, CRYPTO_PUBLIC_KEY_SIZE); memcpy(packet + 1 + CRYPTO_PUBLIC_KEY_SIZE, nonce, CRYPTO_NONCE_SIZE); uint8_t random_public_key[CRYPTO_PUBLIC_KEY_SIZE]; uint8_t random_secret_key[CRYPTO_SECRET_KEY_SIZE]; crypto_new_keypair(rng, random_public_key, random_secret_key); memcpy(packet + 1 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_NONCE_SIZE, random_public_key, CRYPTO_PUBLIC_KEY_SIZE); const int len = encrypt_data(encrypt_public_key, random_secret_key, packet + 1 + CRYPTO_PUBLIC_KEY_SIZE, data, length, packet + 1 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE); if (1 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE + len != DATA_REQUEST_MIN_SIZE + length) { return -1; } return DATA_REQUEST_MIN_SIZE + length; } /** @brief Create and send an onion announce request packet. * * path is the path the request will take before it is sent to dest. * * public_key and secret_key is the kepair which will be used to encrypt the request. * ping_id is the ping id that will be sent in the request. * client_id is the client id of the node we are searching for. * data_public_key is the public key we want others to encrypt their data packets with. * sendback_data is the data of ONION_ANNOUNCE_SENDBACK_DATA_LENGTH length that we expect to * receive back in the response. * * return -1 on failure. * return 0 on success. */ int send_announce_request(const Networking_Core *net, const Random *rng, const Onion_Path *path, const Node_format *dest, const uint8_t *public_key, const uint8_t *secret_key, const uint8_t *ping_id, const uint8_t *client_id, const uint8_t *data_public_key, uint64_t sendback_data) { uint8_t request[ONION_ANNOUNCE_REQUEST_MIN_SIZE]; int len = create_announce_request(rng, request, sizeof(request), dest->public_key, public_key, secret_key, ping_id, client_id, data_public_key, sendback_data); if (len != sizeof(request)) { return -1; } uint8_t packet[ONION_MAX_PACKET_SIZE]; len = create_onion_packet(rng, packet, sizeof(packet), path, &dest->ip_port, request, sizeof(request)); if (len == -1) { return -1; } if (sendpacket(net, &path->ip_port1, packet, len) != len) { return -1; } return 0; } /** @brief Create and send an onion data request packet. * * path is the path the request will take before it is sent to dest. * (if dest knows the person with the public_key they should * send the packet to that person in the form of a response) * * public_key is the real public key of the node which we want to send the data of length length to. * encrypt_public_key is the public key used to encrypt the data packet. * * nonce is the nonce to encrypt this packet with * * The maximum length of data is MAX_DATA_REQUEST_SIZE. * * return -1 on failure. * return 0 on success. */ int send_data_request(const Networking_Core *net, const Random *rng, const Onion_Path *path, const IP_Port *dest, const uint8_t *public_key, const uint8_t *encrypt_public_key, const uint8_t *nonce, const uint8_t *data, uint16_t length) { uint8_t request[ONION_MAX_DATA_SIZE]; int len = create_data_request(rng, request, sizeof(request), public_key, encrypt_public_key, nonce, data, length); if (len == -1) { return -1; } uint8_t packet[ONION_MAX_PACKET_SIZE]; len = create_onion_packet(rng, packet, sizeof(packet), path, dest, request, len); if (len == -1) { return -1; } if (sendpacket(net, &path->ip_port1, packet, len) != len) { return -1; } return 0; } /** @brief check if public key is in entries list * * return -1 if no * return position in list if yes */ non_null() static int in_entries(const Onion_Announce *onion_a, const uint8_t *public_key) { for (unsigned int i = 0; i < ONION_ANNOUNCE_MAX_ENTRIES; ++i) { if (!mono_time_is_timeout(onion_a->mono_time, onion_a->entries[i].announce_time, ONION_ANNOUNCE_TIMEOUT) && pk_equal(onion_a->entries[i].public_key, public_key)) { return i; } } return -1; } typedef struct Cmp_Data { const Mono_Time *mono_time; const uint8_t *base_public_key; Onion_Announce_Entry entry; } Cmp_Data; non_null() static int cmp_entry(const void *a, const void *b) { const Cmp_Data *cmp1 = (const Cmp_Data *)a; const Cmp_Data *cmp2 = (const Cmp_Data *)b; const Onion_Announce_Entry entry1 = cmp1->entry; const Onion_Announce_Entry entry2 = cmp2->entry; const uint8_t *cmp_public_key = cmp1->base_public_key; const bool t1 = mono_time_is_timeout(cmp1->mono_time, entry1.announce_time, ONION_ANNOUNCE_TIMEOUT); const bool t2 = mono_time_is_timeout(cmp1->mono_time, entry2.announce_time, ONION_ANNOUNCE_TIMEOUT); if (t1 && t2) { return 0; } if (t1) { return -1; } if (t2) { return 1; } const int closest = id_closest(cmp_public_key, entry1.public_key, entry2.public_key); if (closest == 1) { return 1; } if (closest == 2) { return -1; } return 0; } non_null() static void sort_onion_announce_list(Onion_Announce_Entry *list, unsigned int length, const Mono_Time *mono_time, const uint8_t *comp_public_key) { // Pass comp_public_key to qsort with each Client_data entry, so the // comparison function can use it as the base of comparison. Cmp_Data *cmp_list = (Cmp_Data *)calloc(length, sizeof(Cmp_Data)); if (cmp_list == nullptr) { return; } for (uint32_t i = 0; i < length; ++i) { cmp_list[i].mono_time = mono_time; cmp_list[i].base_public_key = comp_public_key; cmp_list[i].entry = list[i]; } qsort(cmp_list, length, sizeof(Cmp_Data), cmp_entry); for (uint32_t i = 0; i < length; ++i) { list[i] = cmp_list[i].entry; } free(cmp_list); } /** @brief add entry to entries list * * return -1 if failure * return position if added */ non_null() static int add_to_entries(Onion_Announce *onion_a, const IP_Port *ret_ip_port, const uint8_t *public_key, const uint8_t *data_public_key, const uint8_t *ret) { int pos = in_entries(onion_a, public_key); if (pos == -1) { for (unsigned i = 0; i < ONION_ANNOUNCE_MAX_ENTRIES; ++i) { if (mono_time_is_timeout(onion_a->mono_time, onion_a->entries[i].announce_time, ONION_ANNOUNCE_TIMEOUT)) { pos = i; } } } if (pos == -1) { if (id_closest(dht_get_self_public_key(onion_a->dht), public_key, onion_a->entries[0].public_key) == 1) { pos = 0; } } if (pos == -1) { return -1; } memcpy(onion_a->entries[pos].public_key, public_key, CRYPTO_PUBLIC_KEY_SIZE); onion_a->entries[pos].ret_ip_port = *ret_ip_port; memcpy(onion_a->entries[pos].ret, ret, ONION_RETURN_3); memcpy(onion_a->entries[pos].data_public_key, data_public_key, CRYPTO_PUBLIC_KEY_SIZE); onion_a->entries[pos].announce_time = mono_time_get(onion_a->mono_time); sort_onion_announce_list(onion_a->entries, ONION_ANNOUNCE_MAX_ENTRIES, onion_a->mono_time, dht_get_self_public_key(onion_a->dht)); return in_entries(onion_a, public_key); } non_null() static void make_announce_payload_helper(const Onion_Announce *onion_a, const uint8_t *ping_id, uint8_t *response, int index, const uint8_t *packet_public_key, const uint8_t *data_public_key) { if (index < 0) { response[0] = 0; memcpy(response + 1, ping_id, ONION_PING_ID_SIZE); return; } if (pk_equal(onion_a->entries[index].public_key, packet_public_key)) { if (!pk_equal(onion_a->entries[index].data_public_key, data_public_key)) { response[0] = 0; memcpy(response + 1, ping_id, ONION_PING_ID_SIZE); } else { response[0] = 2; memcpy(response + 1, ping_id, ONION_PING_ID_SIZE); } } else { response[0] = 1; memcpy(response + 1, onion_a->entries[index].data_public_key, CRYPTO_PUBLIC_KEY_SIZE); } } /** @brief Handle an onion announce request, possibly with extra data for group chats. * * @param onion_a The announce object. * @param source Requester IP/Port. * @param packet Encrypted incoming packet. * @param length Length of incoming packet. * @param response_packet_id Packet ID to use for the onion announce response. * @param plain_size Expected size of the decrypted packet. This function returns an error if the * actual decrypted size is not exactly equal to this number. * @param want_node_count If true, the packed nodes in the response are preceded by the number of * nodes sent in the packet. This is necessary if you want to send extra data after the nodes. * @param max_extra_size Amount of memory to allocate in the outgoing packet to be filled by the * extra data callback. * @param pack_extra_data_callback Callback that may write extra data into the packet. * * @retval 1 on failure. * @retval 0 on success. */ non_null(1, 2, 3) nullable(9) static int handle_announce_request_common( Onion_Announce *onion_a, const IP_Port *source, const uint8_t *packet, uint16_t length, uint8_t response_packet_id, uint16_t plain_size, bool want_node_count, uint16_t max_extra_size, pack_extra_data_cb *pack_extra_data_callback) { const uint8_t *packet_public_key = packet + 1 + CRYPTO_NONCE_SIZE; const uint8_t *shared_key = shared_key_cache_lookup(onion_a->shared_keys_recv, packet_public_key); if (shared_key == nullptr) { /* Error looking up/deriving the shared key */ return 1; } uint8_t *plain = (uint8_t *)malloc(plain_size); if (plain == nullptr) { return 1; } const int decrypted_len = decrypt_data_symmetric(shared_key, packet + 1, packet + 1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE, plain_size + CRYPTO_MAC_SIZE, plain); if ((uint32_t)decrypted_len != plain_size) { free(plain); return 1; } const uint16_t ping_id_data_len = CRYPTO_PUBLIC_KEY_SIZE + sizeof(*source); uint8_t ping_id_data[CRYPTO_PUBLIC_KEY_SIZE + sizeof(*source)]; memcpy(ping_id_data, packet_public_key, CRYPTO_PUBLIC_KEY_SIZE); memcpy(ping_id_data + CRYPTO_PUBLIC_KEY_SIZE, source, sizeof(*source)); const uint8_t *data_public_key = plain + ONION_PING_ID_SIZE + CRYPTO_PUBLIC_KEY_SIZE; int index; if (check_timed_auth(onion_a->mono_time, PING_ID_TIMEOUT, onion_a->hmac_key, ping_id_data, ping_id_data_len, plain)) { index = add_to_entries(onion_a, source, packet_public_key, data_public_key, packet + (length - ONION_RETURN_3)); } else { index = in_entries(onion_a, plain + ONION_PING_ID_SIZE); } /* Respond with a announce response packet */ Node_format nodes_list[MAX_SENT_NODES]; const unsigned int num_nodes = get_close_nodes(onion_a->dht, plain + ONION_PING_ID_SIZE, nodes_list, net_family_unspec(), ip_is_lan(&source->ip), false); assert(num_nodes <= UINT8_MAX); uint8_t nonce[CRYPTO_NONCE_SIZE]; random_nonce(onion_a->rng, nonce); const uint16_t nodes_offset = 1 + ONION_PING_ID_SIZE + (want_node_count ? 1 : 0); const uint16_t response_size = nodes_offset + MAX_SENT_NODES * PACKED_NODE_SIZE_IP6 + max_extra_size; uint8_t *response = (uint8_t *)malloc(response_size); if (response == nullptr) { free(plain); return 1; } uint8_t ping_id[TIMED_AUTH_SIZE]; generate_timed_auth(onion_a->mono_time, PING_ID_TIMEOUT, onion_a->hmac_key, ping_id_data, ping_id_data_len, ping_id); make_announce_payload_helper(onion_a, ping_id, response, index, packet_public_key, data_public_key); int nodes_length = 0; if (num_nodes != 0) { nodes_length = pack_nodes(onion_a->log, response + nodes_offset, sizeof(nodes_list), nodes_list, (uint16_t)num_nodes); if (nodes_length <= 0) { LOGGER_WARNING(onion_a->log, "Failed to pack nodes"); free(response); free(plain); return 1; } } uint16_t offset = nodes_offset + nodes_length; if (want_node_count) { response[1 + ONION_PING_ID_SIZE] = (uint8_t)num_nodes; } const int extra_size = pack_extra_data_callback == nullptr ? 0 : pack_extra_data_callback(onion_a->extra_data_object, onion_a->log, onion_a->mono_time, num_nodes, plain + ONION_MINIMAL_SIZE, length - ANNOUNCE_REQUEST_MIN_SIZE_RECV, response, response_size, offset); if (extra_size == -1) { free(response); free(plain); return 1; } offset += extra_size; uint8_t data[ONION_ANNOUNCE_RESPONSE_MAX_SIZE]; const int len = encrypt_data_symmetric(shared_key, nonce, response, offset, data + 1 + ONION_ANNOUNCE_SENDBACK_DATA_LENGTH + CRYPTO_NONCE_SIZE); if (len != offset + CRYPTO_MAC_SIZE) { LOGGER_ERROR(onion_a->log, "Failed to encrypt announce response"); free(response); free(plain); return 1; } data[0] = response_packet_id; memcpy(data + 1, plain + ONION_PING_ID_SIZE + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_PUBLIC_KEY_SIZE, ONION_ANNOUNCE_SENDBACK_DATA_LENGTH); memcpy(data + 1 + ONION_ANNOUNCE_SENDBACK_DATA_LENGTH, nonce, CRYPTO_NONCE_SIZE); if (send_onion_response(onion_a->net, source, data, 1 + ONION_ANNOUNCE_SENDBACK_DATA_LENGTH + CRYPTO_NONCE_SIZE + len, packet + (length - ONION_RETURN_3)) == -1) { free(response); free(plain); return 1; } free(response); free(plain); return 0; } non_null() static int handle_gca_announce_request(Onion_Announce *onion_a, const IP_Port *source, const uint8_t *packet, uint16_t length) { if (length > ANNOUNCE_REQUEST_MAX_SIZE_RECV || length <= ANNOUNCE_REQUEST_MIN_SIZE_RECV) { return 1; } if (onion_a->extra_data_callback == nullptr) { return 1; } return handle_announce_request_common(onion_a, source, packet, length, NET_PACKET_ANNOUNCE_RESPONSE, ONION_MINIMAL_SIZE + length - ANNOUNCE_REQUEST_MIN_SIZE_RECV, true, onion_a->extra_data_max_size, onion_a->extra_data_callback); } non_null(1, 2, 3) nullable(5) static int handle_announce_request(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { Onion_Announce *onion_a = (Onion_Announce *)object; if (length != ANNOUNCE_REQUEST_MIN_SIZE_RECV) { return handle_gca_announce_request(onion_a, source, packet, length); } return handle_announce_request_common(onion_a, source, packet, length, NET_PACKET_ANNOUNCE_RESPONSE, ONION_PING_ID_SIZE + CRYPTO_PUBLIC_KEY_SIZE * 2 + ONION_ANNOUNCE_SENDBACK_DATA_LENGTH, true, 0, nullptr); } /* TODO(Jfreegman): DEPRECATE */ non_null(1, 2, 3) nullable(5) static int handle_announce_request_old(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { Onion_Announce *onion_a = (Onion_Announce *)object; if (length != ANNOUNCE_REQUEST_SIZE_RECV) { return 1; } return handle_announce_request_common(onion_a, source, packet, length, NET_PACKET_ANNOUNCE_RESPONSE_OLD, ONION_PING_ID_SIZE + CRYPTO_PUBLIC_KEY_SIZE * 2 + ONION_ANNOUNCE_SENDBACK_DATA_LENGTH, false, 0, nullptr); } non_null() static int handle_data_request(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { const Onion_Announce *onion_a = (const Onion_Announce *)object; if (length <= DATA_REQUEST_MIN_SIZE_RECV) { return 1; } if (length > ONION_MAX_PACKET_SIZE) { return 1; } const int index = in_entries(onion_a, packet + 1); if (index == -1) { return 1; } VLA(uint8_t, data, length - (CRYPTO_PUBLIC_KEY_SIZE + ONION_RETURN_3)); data[0] = NET_PACKET_ONION_DATA_RESPONSE; memcpy(data + 1, packet + 1 + CRYPTO_PUBLIC_KEY_SIZE, length - (1 + CRYPTO_PUBLIC_KEY_SIZE + ONION_RETURN_3)); if (send_onion_response(onion_a->net, &onion_a->entries[index].ret_ip_port, data, SIZEOF_VLA(data), onion_a->entries[index].ret) == -1) { return 1; } return 0; } Onion_Announce *new_onion_announce(const Logger *log, const Random *rng, const Mono_Time *mono_time, DHT *dht) { if (dht == nullptr) { return nullptr; } Onion_Announce *onion_a = (Onion_Announce *)calloc(1, sizeof(Onion_Announce)); if (onion_a == nullptr) { return nullptr; } onion_a->log = log; onion_a->rng = rng; onion_a->mono_time = mono_time; onion_a->dht = dht; onion_a->net = dht_get_net(dht); onion_a->extra_data_max_size = 0; onion_a->extra_data_callback = nullptr; onion_a->extra_data_object = nullptr; new_hmac_key(rng, onion_a->hmac_key); onion_a->shared_keys_recv = shared_key_cache_new(mono_time, dht_get_self_secret_key(dht), KEYS_TIMEOUT, MAX_KEYS_PER_SLOT); if (onion_a->shared_keys_recv == nullptr) { kill_onion_announce(onion_a); return nullptr; } networking_registerhandler(onion_a->net, NET_PACKET_ANNOUNCE_REQUEST, &handle_announce_request, onion_a); networking_registerhandler(onion_a->net, NET_PACKET_ANNOUNCE_REQUEST_OLD, &handle_announce_request_old, onion_a); networking_registerhandler(onion_a->net, NET_PACKET_ONION_DATA_REQUEST, &handle_data_request, onion_a); return onion_a; } void kill_onion_announce(Onion_Announce *onion_a) { if (onion_a == nullptr) { return; } networking_registerhandler(onion_a->net, NET_PACKET_ANNOUNCE_REQUEST, nullptr, nullptr); networking_registerhandler(onion_a->net, NET_PACKET_ANNOUNCE_REQUEST_OLD, nullptr, nullptr); networking_registerhandler(onion_a->net, NET_PACKET_ONION_DATA_REQUEST, nullptr, nullptr); crypto_memzero(onion_a->hmac_key, CRYPTO_HMAC_KEY_SIZE); shared_key_cache_free(onion_a->shared_keys_recv); free(onion_a); }