/* SPDX-License-Identifier: GPL-3.0-or-later * Copyright © 2016-2018 The TokTok team. * Copyright © 2013 Tox project. */ /** * Implementation of the onion part of docs/Prevent_Tracking.txt */ #include "onion.h" #include #include #include "DHT.h" #include "attributes.h" #include "ccompat.h" #include "crypto_core.h" #include "logger.h" #include "mem.h" #include "mono_time.h" #include "network.h" #include "shared_key_cache.h" #include "util.h" #define RETURN_1 ONION_RETURN_1 #define RETURN_2 ONION_RETURN_2 #define RETURN_3 ONION_RETURN_3 #define SEND_BASE ONION_SEND_BASE #define SEND_3 ONION_SEND_3 #define SEND_2 ONION_SEND_2 #define SEND_1 ONION_SEND_1 #define KEY_REFRESH_INTERVAL (2 * 60 * 60) // Settings for the shared key cache #define MAX_KEYS_PER_SLOT 4 #define KEYS_TIMEOUT 600 /** Change symmetric keys every 2 hours to make paths expire eventually. */ non_null() static void change_symmetric_key(Onion *onion) { if (mono_time_is_timeout(onion->mono_time, onion->timestamp, KEY_REFRESH_INTERVAL)) { new_symmetric_key(onion->rng, onion->secret_symmetric_key); onion->timestamp = mono_time_get(onion->mono_time); } } /** packing and unpacking functions */ non_null() static void ip_pack_to_bytes(uint8_t *data, const IP *source) { data[0] = source->family.value; if (net_family_is_ipv4(source->family) || net_family_is_tox_tcp_ipv4(source->family)) { memzero(data + 1, SIZE_IP6); memcpy(data + 1, source->ip.v4.uint8, SIZE_IP4); } else { memcpy(data + 1, source->ip.v6.uint8, SIZE_IP6); } } /** return 0 on success, -1 on failure. */ non_null() static int ip_unpack_from_bytes(IP *target, const uint8_t *data, unsigned int data_size, bool disable_family_check) { if (data_size < (1 + SIZE_IP6)) { return -1; } // TODO(iphydf): Validate input. target->family.value = data[0]; if (net_family_is_ipv4(target->family) || net_family_is_tox_tcp_ipv4(target->family)) { memcpy(target->ip.v4.uint8, data + 1, SIZE_IP4); } else { memcpy(target->ip.v6.uint8, data + 1, SIZE_IP6); } const bool valid = disable_family_check || net_family_is_ipv4(target->family) || net_family_is_ipv6(target->family); return valid ? 0 : -1; } non_null() static void ipport_pack(uint8_t *data, const IP_Port *source) { ip_pack_to_bytes(data, &source->ip); memcpy(data + SIZE_IP, &source->port, SIZE_PORT); } /** return 0 on success, -1 on failure. */ non_null() static int ipport_unpack(IP_Port *target, const uint8_t *data, unsigned int data_size, bool disable_family_check) { if (data_size < (SIZE_IP + SIZE_PORT)) { return -1; } if (ip_unpack_from_bytes(&target->ip, data, data_size, disable_family_check) == -1) { return -1; } memcpy(&target->port, data + SIZE_IP, SIZE_PORT); return 0; } /** @brief Create a new onion path. * * Create a new onion path out of nodes (nodes is a list of ONION_PATH_LENGTH nodes) * * new_path must be an empty memory location of at least Onion_Path size. * * return -1 on failure. * return 0 on success. */ int create_onion_path(const Random *rng, const DHT *dht, Onion_Path *new_path, const Node_format *nodes) { if (new_path == nullptr || nodes == nullptr) { return -1; } encrypt_precompute(nodes[0].public_key, dht_get_self_secret_key(dht), new_path->shared_key1); memcpy(new_path->public_key1, dht_get_self_public_key(dht), CRYPTO_PUBLIC_KEY_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); encrypt_precompute(nodes[1].public_key, random_secret_key, new_path->shared_key2); memcpy(new_path->public_key2, random_public_key, CRYPTO_PUBLIC_KEY_SIZE); crypto_new_keypair(rng, random_public_key, random_secret_key); encrypt_precompute(nodes[2].public_key, random_secret_key, new_path->shared_key3); memcpy(new_path->public_key3, random_public_key, CRYPTO_PUBLIC_KEY_SIZE); crypto_memzero(random_secret_key, sizeof(random_secret_key)); new_path->ip_port1 = nodes[0].ip_port; new_path->ip_port2 = nodes[1].ip_port; new_path->ip_port3 = nodes[2].ip_port; memcpy(new_path->node_public_key1, nodes[0].public_key, CRYPTO_PUBLIC_KEY_SIZE); memcpy(new_path->node_public_key2, nodes[1].public_key, CRYPTO_PUBLIC_KEY_SIZE); memcpy(new_path->node_public_key3, nodes[2].public_key, CRYPTO_PUBLIC_KEY_SIZE); return 0; } /** @brief Dump nodes in onion path to nodes of length num_nodes. * * return -1 on failure. * return 0 on success. */ int onion_path_to_nodes(Node_format *nodes, unsigned int num_nodes, const Onion_Path *path) { if (num_nodes < ONION_PATH_LENGTH) { return -1; } nodes[0].ip_port = path->ip_port1; nodes[1].ip_port = path->ip_port2; nodes[2].ip_port = path->ip_port3; memcpy(nodes[0].public_key, path->node_public_key1, CRYPTO_PUBLIC_KEY_SIZE); memcpy(nodes[1].public_key, path->node_public_key2, CRYPTO_PUBLIC_KEY_SIZE); memcpy(nodes[2].public_key, path->node_public_key3, CRYPTO_PUBLIC_KEY_SIZE); return 0; } /** @brief Create a onion packet. * * Use Onion_Path path to create packet for data of length to dest. * Maximum length of data is ONION_MAX_DATA_SIZE. * packet should be at least ONION_MAX_PACKET_SIZE big. * * return -1 on failure. * return length of created packet on success. */ int create_onion_packet(const Random *rng, uint8_t *packet, uint16_t max_packet_length, const Onion_Path *path, const IP_Port *dest, const uint8_t *data, uint16_t length) { if (1 + length + SEND_1 > max_packet_length || length == 0) { return -1; } const uint16_t step1_size = SIZE_IPPORT + length; VLA(uint8_t, step1, step1_size); ipport_pack(step1, dest); memcpy(step1 + SIZE_IPPORT, data, length); uint8_t nonce[CRYPTO_NONCE_SIZE]; random_nonce(rng, nonce); const uint16_t step2_size = SIZE_IPPORT + SEND_BASE + length; VLA(uint8_t, step2, step2_size); ipport_pack(step2, &path->ip_port3); memcpy(step2 + SIZE_IPPORT, path->public_key3, CRYPTO_PUBLIC_KEY_SIZE); int len = encrypt_data_symmetric(path->shared_key3, nonce, step1, step1_size, step2 + SIZE_IPPORT + CRYPTO_PUBLIC_KEY_SIZE); if (len != SIZE_IPPORT + length + CRYPTO_MAC_SIZE) { return -1; } const uint16_t step3_size = SIZE_IPPORT + SEND_BASE * 2 + length; VLA(uint8_t, step3, step3_size); ipport_pack(step3, &path->ip_port2); memcpy(step3 + SIZE_IPPORT, path->public_key2, CRYPTO_PUBLIC_KEY_SIZE); len = encrypt_data_symmetric(path->shared_key2, nonce, step2, step2_size, step3 + SIZE_IPPORT + CRYPTO_PUBLIC_KEY_SIZE); if (len != SIZE_IPPORT + SEND_BASE + length + CRYPTO_MAC_SIZE) { return -1; } packet[0] = NET_PACKET_ONION_SEND_INITIAL; memcpy(packet + 1, nonce, CRYPTO_NONCE_SIZE); memcpy(packet + 1 + CRYPTO_NONCE_SIZE, path->public_key1, CRYPTO_PUBLIC_KEY_SIZE); len = encrypt_data_symmetric(path->shared_key1, nonce, step3, step3_size, packet + 1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE); if (len != SIZE_IPPORT + SEND_BASE * 2 + length + CRYPTO_MAC_SIZE) { return -1; } return 1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE + len; } /** @brief Create a onion packet to be sent over tcp. * * Use Onion_Path path to create packet for data of length to dest. * Maximum length of data is ONION_MAX_DATA_SIZE. * packet should be at least ONION_MAX_PACKET_SIZE big. * * return -1 on failure. * return length of created packet on success. */ int create_onion_packet_tcp(const Random *rng, uint8_t *packet, uint16_t max_packet_length, const Onion_Path *path, const IP_Port *dest, const uint8_t *data, uint16_t length) { if (CRYPTO_NONCE_SIZE + SIZE_IPPORT + SEND_BASE * 2 + length > max_packet_length || length == 0) { return -1; } const uint16_t step1_size = SIZE_IPPORT + length; VLA(uint8_t, step1, step1_size); ipport_pack(step1, dest); memcpy(step1 + SIZE_IPPORT, data, length); uint8_t nonce[CRYPTO_NONCE_SIZE]; random_nonce(rng, nonce); const uint16_t step2_size = SIZE_IPPORT + SEND_BASE + length; VLA(uint8_t, step2, step2_size); ipport_pack(step2, &path->ip_port3); memcpy(step2 + SIZE_IPPORT, path->public_key3, CRYPTO_PUBLIC_KEY_SIZE); int len = encrypt_data_symmetric(path->shared_key3, nonce, step1, step1_size, step2 + SIZE_IPPORT + CRYPTO_PUBLIC_KEY_SIZE); if (len != SIZE_IPPORT + length + CRYPTO_MAC_SIZE) { return -1; } ipport_pack(packet + CRYPTO_NONCE_SIZE, &path->ip_port2); memcpy(packet + CRYPTO_NONCE_SIZE + SIZE_IPPORT, path->public_key2, CRYPTO_PUBLIC_KEY_SIZE); len = encrypt_data_symmetric(path->shared_key2, nonce, step2, step2_size, packet + CRYPTO_NONCE_SIZE + SIZE_IPPORT + CRYPTO_PUBLIC_KEY_SIZE); if (len != SIZE_IPPORT + SEND_BASE + length + CRYPTO_MAC_SIZE) { return -1; } memcpy(packet, nonce, CRYPTO_NONCE_SIZE); return CRYPTO_NONCE_SIZE + SIZE_IPPORT + CRYPTO_PUBLIC_KEY_SIZE + len; } /** @brief Create and send a onion response sent initially to dest with. * Maximum length of data is ONION_RESPONSE_MAX_DATA_SIZE. * * return -1 on failure. * return 0 on success. */ int send_onion_response(const Logger *log, Networking_Core *net, const IP_Port *dest, const uint8_t *data, uint16_t length, const uint8_t *ret) { if (length > ONION_RESPONSE_MAX_DATA_SIZE || length == 0) { return -1; } const uint16_t packet_size = 1 + RETURN_3 + length; VLA(uint8_t, packet, packet_size); packet[0] = NET_PACKET_ONION_RECV_3; memcpy(packet + 1, ret, RETURN_3); memcpy(packet + 1 + RETURN_3, data, length); if ((uint16_t)sendpacket(net, dest, packet, packet_size) != packet_size) { return -1; } Ip_Ntoa ip_str; LOGGER_TRACE(log, "forwarded onion RECV_3 to %s:%d (%02x in %02x, %d bytes)", net_ip_ntoa(&dest->ip, &ip_str), net_ntohs(dest->port), data[0], packet[0], packet_size); return 0; } non_null() static int handle_send_initial(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { Onion *onion = (Onion *)object; if (length > ONION_MAX_PACKET_SIZE) { LOGGER_TRACE(onion->log, "invalid initial onion packet length: %u (max: %u)", length, ONION_MAX_PACKET_SIZE); return 1; } if (length <= 1 + SEND_1) { LOGGER_TRACE(onion->log, "initial onion packet cannot contain SEND_1 packet: %u <= %u", length, 1 + SEND_1); return 1; } change_symmetric_key(onion); const int nonce_start = 1; const int public_key_start = nonce_start + CRYPTO_NONCE_SIZE; const int ciphertext_start = public_key_start + CRYPTO_PUBLIC_KEY_SIZE; const int ciphertext_length = length - ciphertext_start; const int plaintext_length = ciphertext_length - CRYPTO_MAC_SIZE; uint8_t plain[ONION_MAX_PACKET_SIZE]; const uint8_t *public_key = &packet[public_key_start]; const uint8_t *shared_key = shared_key_cache_lookup(onion->shared_keys_1, public_key); if (shared_key == nullptr) { /* Error looking up/deriving the shared key */ LOGGER_TRACE(onion->log, "shared onion key lookup failed for pk %02x%02x...", public_key[0], public_key[1]); return 1; } const int len = decrypt_data_symmetric( shared_key, &packet[nonce_start], &packet[ciphertext_start], ciphertext_length, plain); if (len != plaintext_length) { LOGGER_TRACE(onion->log, "decrypt failed: %d != %d", len, plaintext_length); return 1; } return onion_send_1(onion, plain, len, source, packet + 1); } int onion_send_1(const Onion *onion, const uint8_t *plain, uint16_t len, const IP_Port *source, const uint8_t *nonce) { const uint16_t max_len = ONION_MAX_PACKET_SIZE + SIZE_IPPORT - (1 + CRYPTO_NONCE_SIZE + ONION_RETURN_1); if (len > max_len) { LOGGER_TRACE(onion->log, "invalid SEND_1 length: %d > %d", len, max_len); return 1; } if (len <= SIZE_IPPORT + SEND_BASE * 2) { return 1; } IP_Port send_to; if (ipport_unpack(&send_to, plain, len, false) == -1) { return 1; } uint8_t ip_port[SIZE_IPPORT]; ipport_pack(ip_port, source); uint8_t data[ONION_MAX_PACKET_SIZE] = {0}; data[0] = NET_PACKET_ONION_SEND_1; memcpy(data + 1, nonce, CRYPTO_NONCE_SIZE); memcpy(data + 1 + CRYPTO_NONCE_SIZE, plain + SIZE_IPPORT, len - SIZE_IPPORT); uint16_t data_len = 1 + CRYPTO_NONCE_SIZE + (len - SIZE_IPPORT); uint8_t *ret_part = data + data_len; random_nonce(onion->rng, ret_part); len = encrypt_data_symmetric(onion->secret_symmetric_key, ret_part, ip_port, SIZE_IPPORT, ret_part + CRYPTO_NONCE_SIZE); if (len != SIZE_IPPORT + CRYPTO_MAC_SIZE) { return 1; } data_len += CRYPTO_NONCE_SIZE + len; if ((uint32_t)sendpacket(onion->net, &send_to, data, data_len) != data_len) { return 1; } Ip_Ntoa ip_str; LOGGER_TRACE(onion->log, "forwarded onion packet to %s:%d, level 1 (%02x in %02x, %d bytes)", net_ip_ntoa(&send_to.ip, &ip_str), net_ntohs(send_to.port), plain[0], data[0], data_len); return 0; } non_null() static int handle_send_1(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { Onion *onion = (Onion *)object; if (length > ONION_MAX_PACKET_SIZE) { return 1; } if (length <= 1 + SEND_2) { return 1; } change_symmetric_key(onion); uint8_t plain[ONION_MAX_PACKET_SIZE]; const uint8_t *public_key = packet + 1 + CRYPTO_NONCE_SIZE; const uint8_t *shared_key = shared_key_cache_lookup(onion->shared_keys_2, public_key); if (shared_key == nullptr) { /* Error looking up/deriving the shared key */ return 1; } int len = decrypt_data_symmetric(shared_key, packet + 1, packet + 1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE, length - (1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE + RETURN_1), plain); if (len != length - (1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE + RETURN_1 + CRYPTO_MAC_SIZE)) { return 1; } IP_Port send_to; if (ipport_unpack(&send_to, plain, len, false) == -1) { return 1; } uint8_t data[ONION_MAX_PACKET_SIZE] = {0}; data[0] = NET_PACKET_ONION_SEND_2; memcpy(data + 1, packet + 1, CRYPTO_NONCE_SIZE); memcpy(data + 1 + CRYPTO_NONCE_SIZE, plain + SIZE_IPPORT, len - SIZE_IPPORT); uint16_t data_len = 1 + CRYPTO_NONCE_SIZE + (len - SIZE_IPPORT); uint8_t *ret_part = data + data_len; random_nonce(onion->rng, ret_part); uint8_t ret_data[RETURN_1 + SIZE_IPPORT]; ipport_pack(ret_data, source); memcpy(ret_data + SIZE_IPPORT, packet + (length - RETURN_1), RETURN_1); len = encrypt_data_symmetric(onion->secret_symmetric_key, ret_part, ret_data, sizeof(ret_data), ret_part + CRYPTO_NONCE_SIZE); if (len != RETURN_2 - CRYPTO_NONCE_SIZE) { return 1; } data_len += CRYPTO_NONCE_SIZE + len; if ((uint32_t)sendpacket(onion->net, &send_to, data, data_len) != data_len) { return 1; } Ip_Ntoa ip_str; LOGGER_TRACE(onion->log, "forwarded onion packet to %s:%d, level 2 (%02x in %02x, %d bytes)", net_ip_ntoa(&send_to.ip, &ip_str), net_ntohs(send_to.port), packet[0], data[0], data_len); return 0; } non_null() static int handle_send_2(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { Onion *onion = (Onion *)object; if (length > ONION_MAX_PACKET_SIZE) { return 1; } if (length <= 1 + SEND_3) { return 1; } change_symmetric_key(onion); uint8_t plain[ONION_MAX_PACKET_SIZE]; const uint8_t *public_key = packet + 1 + CRYPTO_NONCE_SIZE; const uint8_t *shared_key = shared_key_cache_lookup(onion->shared_keys_3, public_key); if (shared_key == nullptr) { /* Error looking up/deriving the shared key */ return 1; } int len = decrypt_data_symmetric(shared_key, packet + 1, packet + 1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE, length - (1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE + RETURN_2), plain); if (len != length - (1 + CRYPTO_NONCE_SIZE + CRYPTO_PUBLIC_KEY_SIZE + RETURN_2 + CRYPTO_MAC_SIZE)) { return 1; } assert(len > SIZE_IPPORT); const uint8_t packet_id = plain[SIZE_IPPORT]; if (packet_id != NET_PACKET_ANNOUNCE_REQUEST && packet_id != NET_PACKET_ANNOUNCE_REQUEST_OLD && packet_id != NET_PACKET_ONION_DATA_REQUEST) { return 1; } IP_Port send_to; if (ipport_unpack(&send_to, plain, len, false) == -1) { return 1; } uint8_t data[ONION_MAX_PACKET_SIZE] = {0}; memcpy(data, plain + SIZE_IPPORT, len - SIZE_IPPORT); uint16_t data_len = len - SIZE_IPPORT; uint8_t *ret_part = data + (len - SIZE_IPPORT); random_nonce(onion->rng, ret_part); uint8_t ret_data[RETURN_2 + SIZE_IPPORT]; ipport_pack(ret_data, source); memcpy(ret_data + SIZE_IPPORT, packet + (length - RETURN_2), RETURN_2); len = encrypt_data_symmetric(onion->secret_symmetric_key, ret_part, ret_data, sizeof(ret_data), ret_part + CRYPTO_NONCE_SIZE); if (len != RETURN_3 - CRYPTO_NONCE_SIZE) { return 1; } data_len += RETURN_3; if ((uint32_t)sendpacket(onion->net, &send_to, data, data_len) != data_len) { return 1; } Ip_Ntoa ip_str; LOGGER_TRACE(onion->log, "forwarded onion packet to %s:%d, level 3 (%02x in %02x, %d bytes)", net_ip_ntoa(&send_to.ip, &ip_str), net_ntohs(send_to.port), packet[0], data[0], data_len); return 0; } non_null() static int handle_recv_3(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { Onion *onion = (Onion *)object; if (length > ONION_MAX_PACKET_SIZE) { return 1; } if (length <= 1 + RETURN_3) { return 1; } const uint8_t packet_id = packet[1 + RETURN_3]; if (packet_id != NET_PACKET_ANNOUNCE_RESPONSE && packet_id != NET_PACKET_ANNOUNCE_RESPONSE_OLD && packet_id != NET_PACKET_ONION_DATA_RESPONSE) { return 1; } change_symmetric_key(onion); uint8_t plain[SIZE_IPPORT + RETURN_2]; const int len = decrypt_data_symmetric(onion->secret_symmetric_key, packet + 1, packet + 1 + CRYPTO_NONCE_SIZE, SIZE_IPPORT + RETURN_2 + CRYPTO_MAC_SIZE, plain); if ((uint32_t)len != sizeof(plain)) { return 1; } IP_Port send_to; if (ipport_unpack(&send_to, plain, len, false) == -1) { LOGGER_DEBUG(onion->log, "failed to unpack IP/Port"); return 1; } uint8_t data[ONION_MAX_PACKET_SIZE] = {0}; data[0] = NET_PACKET_ONION_RECV_2; memcpy(data + 1, plain + SIZE_IPPORT, RETURN_2); memcpy(data + 1 + RETURN_2, packet + 1 + RETURN_3, length - (1 + RETURN_3)); const uint16_t data_len = 1 + RETURN_2 + (length - (1 + RETURN_3)); if ((uint32_t)sendpacket(onion->net, &send_to, data, data_len) != data_len) { return 1; } Ip_Ntoa ip_str; LOGGER_TRACE(onion->log, "forwarded onion RECV_2 to %s:%d (%02x in %02x, %d bytes)", net_ip_ntoa(&send_to.ip, &ip_str), net_ntohs(send_to.port), packet[0], data[0], data_len); return 0; } non_null() static int handle_recv_2(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { Onion *onion = (Onion *)object; if (length > ONION_MAX_PACKET_SIZE) { return 1; } if (length <= 1 + RETURN_2) { return 1; } const uint8_t packet_id = packet[1 + RETURN_2]; if (packet_id != NET_PACKET_ANNOUNCE_RESPONSE && packet_id != NET_PACKET_ANNOUNCE_RESPONSE_OLD && packet_id != NET_PACKET_ONION_DATA_RESPONSE) { return 1; } change_symmetric_key(onion); uint8_t plain[SIZE_IPPORT + RETURN_1]; const int len = decrypt_data_symmetric(onion->secret_symmetric_key, packet + 1, packet + 1 + CRYPTO_NONCE_SIZE, SIZE_IPPORT + RETURN_1 + CRYPTO_MAC_SIZE, plain); if ((uint32_t)len != sizeof(plain)) { return 1; } IP_Port send_to; if (ipport_unpack(&send_to, plain, len, false) == -1) { return 1; } uint8_t data[ONION_MAX_PACKET_SIZE] = {0}; data[0] = NET_PACKET_ONION_RECV_1; memcpy(data + 1, plain + SIZE_IPPORT, RETURN_1); memcpy(data + 1 + RETURN_1, packet + 1 + RETURN_2, length - (1 + RETURN_2)); const uint16_t data_len = 1 + RETURN_1 + (length - (1 + RETURN_2)); if ((uint32_t)sendpacket(onion->net, &send_to, data, data_len) != data_len) { return 1; } Ip_Ntoa ip_str; LOGGER_TRACE(onion->log, "forwarded onion RECV_1 to %s:%d (%02x in %02x, %d bytes)", net_ip_ntoa(&send_to.ip, &ip_str), net_ntohs(send_to.port), packet[0], data[0], data_len); return 0; } non_null() static int handle_recv_1(void *object, const IP_Port *source, const uint8_t *packet, uint16_t length, void *userdata) { Onion *onion = (Onion *)object; if (length > ONION_MAX_PACKET_SIZE) { return 1; } if (length <= 1 + RETURN_1) { return 1; } const uint8_t packet_id = packet[1 + RETURN_1]; if (packet_id != NET_PACKET_ANNOUNCE_RESPONSE && packet_id != NET_PACKET_ANNOUNCE_RESPONSE_OLD && packet_id != NET_PACKET_ONION_DATA_RESPONSE) { return 1; } change_symmetric_key(onion); uint8_t plain[SIZE_IPPORT]; const int len = decrypt_data_symmetric(onion->secret_symmetric_key, packet + 1, packet + 1 + CRYPTO_NONCE_SIZE, SIZE_IPPORT + CRYPTO_MAC_SIZE, plain); if ((uint32_t)len != SIZE_IPPORT) { return 1; } IP_Port send_to; if (ipport_unpack(&send_to, plain, len, true) == -1) { LOGGER_DEBUG(onion->log, "failed to unpack IP/Port"); return 1; } const uint16_t data_len = length - (1 + RETURN_1); if (onion->recv_1_function != nullptr && !net_family_is_ipv4(send_to.ip.family) && !net_family_is_ipv6(send_to.ip.family)) { return onion->recv_1_function(onion->callback_object, &send_to, packet + (1 + RETURN_1), data_len); } if ((uint32_t)sendpacket(onion->net, &send_to, packet + (1 + RETURN_1), data_len) != data_len) { return 1; } return 0; } void set_callback_handle_recv_1(Onion *onion, onion_recv_1_cb *function, void *object) { onion->recv_1_function = function; onion->callback_object = object; } Onion *new_onion(const Logger *log, const Memory *mem, const Mono_Time *mono_time, const Random *rng, DHT *dht) { if (dht == nullptr) { return nullptr; } Onion *onion = (Onion *)mem_alloc(mem, sizeof(Onion)); if (onion == nullptr) { return nullptr; } onion->log = log; onion->dht = dht; onion->net = dht_get_net(dht); onion->mono_time = mono_time; onion->rng = rng; onion->mem = mem; new_symmetric_key(rng, onion->secret_symmetric_key); onion->timestamp = mono_time_get(onion->mono_time); const uint8_t *secret_key = dht_get_self_secret_key(dht); onion->shared_keys_1 = shared_key_cache_new(log, mono_time, mem, secret_key, KEYS_TIMEOUT, MAX_KEYS_PER_SLOT); onion->shared_keys_2 = shared_key_cache_new(log, mono_time, mem, secret_key, KEYS_TIMEOUT, MAX_KEYS_PER_SLOT); onion->shared_keys_3 = shared_key_cache_new(log, mono_time, mem, secret_key, KEYS_TIMEOUT, MAX_KEYS_PER_SLOT); if (onion->shared_keys_1 == nullptr || onion->shared_keys_2 == nullptr || onion->shared_keys_3 == nullptr) { // cppcheck-suppress mismatchAllocDealloc kill_onion(onion); return nullptr; } networking_registerhandler(onion->net, NET_PACKET_ONION_SEND_INITIAL, &handle_send_initial, onion); networking_registerhandler(onion->net, NET_PACKET_ONION_SEND_1, &handle_send_1, onion); networking_registerhandler(onion->net, NET_PACKET_ONION_SEND_2, &handle_send_2, onion); networking_registerhandler(onion->net, NET_PACKET_ONION_RECV_3, &handle_recv_3, onion); networking_registerhandler(onion->net, NET_PACKET_ONION_RECV_2, &handle_recv_2, onion); networking_registerhandler(onion->net, NET_PACKET_ONION_RECV_1, &handle_recv_1, onion); return onion; } void kill_onion(Onion *onion) { if (onion == nullptr) { return; } networking_registerhandler(onion->net, NET_PACKET_ONION_SEND_INITIAL, nullptr, nullptr); networking_registerhandler(onion->net, NET_PACKET_ONION_SEND_1, nullptr, nullptr); networking_registerhandler(onion->net, NET_PACKET_ONION_SEND_2, nullptr, nullptr); networking_registerhandler(onion->net, NET_PACKET_ONION_RECV_3, nullptr, nullptr); networking_registerhandler(onion->net, NET_PACKET_ONION_RECV_2, nullptr, nullptr); networking_registerhandler(onion->net, NET_PACKET_ONION_RECV_1, nullptr, nullptr); crypto_memzero(onion->secret_symmetric_key, sizeof(onion->secret_symmetric_key)); shared_key_cache_free(onion->shared_keys_1); shared_key_cache_free(onion->shared_keys_2); shared_key_cache_free(onion->shared_keys_3); mem_delete(onion->mem, onion); }