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261d2e53b7
tomato/toxcore/onion.c
Green Sky 261d2e53b7 Squashed 'external/toxcore/c-toxcore/' changes from 55752a2e2ef..11ab1d2a723 
11ab1d2a723 fix: reduce memory usage in group chats by 75% Significantly reduced the memory usage of groups since all message slots are preallocated for every peer for send and receive buffers of buffer size (hundreds of MiB peak when save contained alot of peers to try to connect to)
4f09f4e147c chore: Fix tsan build by moving it to GitHub CI.
6460c25c9e0 refactor: Use `merge_sort` instead of `qsort` for sorting.
c660bbe8c95 test: Fix crypto_test to initialise its plain text buffer.
0204db6184b cleanup: Fix layering check warnings.
df2211e1548 refactor: Use tox memory allocator for temporary buffers in crypto.
ac812871a2e feat: implement the last 2 missing network struct functions and make use of them
29d1043be0b test: friend request test now tests min/max message sizes
93aafd78c1f fix: friend requests with very long messages are no longer dropped
819aa2b2618 feat: Add option to disable DNS lookups in toxcore.
0ac23cee035 fix: windows use of REUSEADDR
7d2811d302d chore(ci): make bazel server shutdown faster
1dc399ba20d chore: Use vcpkg instead of conan in the MSVC build.
14d823165d9 chore: Migrate to conan 2.
bdd17c16787 cleanup: Allocate logger using tox memory allocator.
b396c061515 chore(deps): bump third_party/cmp from `2ac6bca` to `52bfcfa`
2e94da60d09 feat(net): add missing connect to network struct
41fb1839c7b chore: Add check to ensure version numbers agree.
934a8301113 chore: Release 0.2.20
3acef4bf044 fix: Add missing free in dht_get_nodes_response event.

git-subtree-dir: external/toxcore/c-toxcore
git-subtree-split: 11ab1d2a7232eee19b51ce126ccce267d6578903
2024-12-19 16:27:40 +01:00

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/* 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 <assert.h>
#include <string.h>
#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 Memory *mem, 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(mem, 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(mem, 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(mem, 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 Memory *mem, 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(mem, 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(mem, 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, const 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(
onion->mem, 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->mem, 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(onion->mem, 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->mem, 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(onion->mem, 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->mem, 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->mem, 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->mem, 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->mem, 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);
}
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