toxcore/auto_tests/TCP_test.c
iphydf 5c2600d87b
Add new Circle CI configuration.
This one has ASAN enabled, unlike Travis.
2018-06-24 19:51:34 +00:00

838 lines
32 KiB
C

#ifndef _XOPEN_SOURCE
#define _XOPEN_SOURCE 600
#endif
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include "check_compat.h"
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <sys/types.h>
#include <time.h>
#include "../toxcore/TCP_client.h"
#include "../toxcore/TCP_server.h"
#include "../toxcore/crypto_core.h"
#include "../toxcore/util.h"
#include "helpers.h"
#define NUM_PORTS 3
#ifndef USE_IPV6
#define USE_IPV6 1
#endif
#if !USE_IPV6
#define net_family_ipv6 net_family_ipv4
#endif
static inline IP get_loopback()
{
IP ip;
#if USE_IPV6
ip.family = net_family_ipv6;
ip.ip.v6 = get_ip6_loopback();
#else
ip.family = net_family_ipv4;
ip.ip.v4 = get_ip4_loopback();
#endif
return ip;
}
static uint16_t ports[NUM_PORTS] = {13215, 33445, 25643};
START_TEST(test_basic)
{
// Attempt to create a new TCP_Server instance.
uint8_t self_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t self_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Server *tcp_s = new_TCP_server(USE_IPV6, NUM_PORTS, ports, self_secret_key, nullptr);
ck_assert_msg(tcp_s != nullptr, "Failed to create a TCP relay server.");
ck_assert_msg(tcp_server_listen_count(tcp_s) == NUM_PORTS,
"Failed to bind a TCP relay server to all %d attempted ports.", NUM_PORTS);
Socket sock = {0};
// Check all opened ports for connectivity.
for (uint8_t i = 0; i < NUM_PORTS; i++) {
sock = net_socket(net_family_ipv6, TOX_SOCK_STREAM, TOX_PROTO_TCP);
IP_Port ip_port_loopback;
ip_port_loopback.ip = get_loopback();
ip_port_loopback.port = net_htons(ports[i]);
int ret = net_connect(sock, ip_port_loopback);
ck_assert_msg(ret == 0, "Failed to connect to created TCP relay server on port %d.", ports[i]);
// Leave open one connection for the next test.
if (i + 1 < NUM_PORTS) {
kill_sock(sock);
}
}
// Key creation.
uint8_t f_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t f_secret_key[CRYPTO_SECRET_KEY_SIZE];
uint8_t f_nonce[CRYPTO_NONCE_SIZE];
crypto_new_keypair(f_public_key, f_secret_key);
random_nonce(f_nonce);
// Generation of the initial handshake.
uint8_t t_secret_key[CRYPTO_SECRET_KEY_SIZE];
uint8_t handshake_plain[TCP_HANDSHAKE_PLAIN_SIZE];
crypto_new_keypair(handshake_plain, t_secret_key);
memcpy(handshake_plain + CRYPTO_PUBLIC_KEY_SIZE, f_nonce, CRYPTO_NONCE_SIZE);
uint8_t handshake[TCP_CLIENT_HANDSHAKE_SIZE];
memcpy(handshake, f_public_key, CRYPTO_PUBLIC_KEY_SIZE);
random_nonce(handshake + CRYPTO_PUBLIC_KEY_SIZE);
// Encrypting handshake
int ret = encrypt_data(self_public_key, f_secret_key, handshake + CRYPTO_PUBLIC_KEY_SIZE, handshake_plain,
TCP_HANDSHAKE_PLAIN_SIZE, handshake + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_NONCE_SIZE);
ck_assert_msg(ret == TCP_CLIENT_HANDSHAKE_SIZE - (CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_NONCE_SIZE),
"encrypt_data() call failed.");
// Sending the handshake
ck_assert_msg(net_send(sock, handshake, TCP_CLIENT_HANDSHAKE_SIZE - 1) == TCP_CLIENT_HANDSHAKE_SIZE - 1,
"An attempt to send the initial handshake minus last byte failed.");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
ck_assert_msg(net_send(sock, handshake + (TCP_CLIENT_HANDSHAKE_SIZE - 1), 1) == 1,
"The attempt to send the last byte of handshake failed.");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
// Receiving server response and decrypting it
uint8_t response[TCP_SERVER_HANDSHAKE_SIZE];
uint8_t response_plain[TCP_HANDSHAKE_PLAIN_SIZE];
ck_assert_msg(net_recv(sock, response, TCP_SERVER_HANDSHAKE_SIZE) == TCP_SERVER_HANDSHAKE_SIZE,
"Could/did not receive a server response to the initial handshake.");
ret = decrypt_data(self_public_key, f_secret_key, response, response + CRYPTO_NONCE_SIZE,
TCP_SERVER_HANDSHAKE_SIZE - CRYPTO_NONCE_SIZE, response_plain);
ck_assert_msg(ret == TCP_HANDSHAKE_PLAIN_SIZE, "Failed to decrypt handshake response.");
uint8_t f_nonce_r[CRYPTO_NONCE_SIZE];
uint8_t f_shared_key[CRYPTO_SHARED_KEY_SIZE];
encrypt_precompute(response_plain, t_secret_key, f_shared_key);
memcpy(f_nonce_r, response_plain + CRYPTO_SHARED_KEY_SIZE, CRYPTO_NONCE_SIZE);
// Building a request
uint8_t r_req_p[1 + CRYPTO_PUBLIC_KEY_SIZE] = {0};
memcpy(r_req_p + 1, f_public_key, CRYPTO_PUBLIC_KEY_SIZE);
uint8_t r_req[2 + 1 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_MAC_SIZE];
uint16_t size = 1 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_MAC_SIZE;
size = net_htons(size);
encrypt_data_symmetric(f_shared_key, f_nonce, r_req_p, 1 + CRYPTO_PUBLIC_KEY_SIZE, r_req + 2);
increment_nonce(f_nonce);
memcpy(r_req, &size, 2);
// Sending the request at random intervals in random pieces.
for (uint32_t i = 0; i < sizeof(r_req);) {
uint8_t msg_length = rand() % 5 + 1; // msg_length = 1 to 5
if (i + msg_length >= sizeof(r_req)) {
msg_length = sizeof(r_req) - i;
}
ck_assert_msg(net_send(sock, r_req + i, msg_length) == msg_length,
"Failed to send request after completing the handshake.");
i += msg_length;
c_sleep(50);
do_TCP_server(tcp_s);
}
// Receiving the second response and verifying its validity
uint8_t packet_resp[4096];
int recv_data_len = net_recv(sock, packet_resp, 2 + 2 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_MAC_SIZE);
ck_assert_msg(recv_data_len == 2 + 2 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_MAC_SIZE,
"Failed to receive server response to request. %u", recv_data_len);
memcpy(&size, packet_resp, 2);
ck_assert_msg(net_ntohs(size) == 2 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_MAC_SIZE,
"Wrong packet size for request response.");
uint8_t packet_resp_plain[4096];
ret = decrypt_data_symmetric(f_shared_key, f_nonce_r, packet_resp + 2, recv_data_len - 2, packet_resp_plain);
ck_assert_msg(ret != -1, "Failed to decrypt the TCP server's response.");
increment_nonce(f_nonce_r);
ck_assert_msg(packet_resp_plain[0] == 1, "Server sent the wrong packet id: %u", packet_resp_plain[0]);
ck_assert_msg(packet_resp_plain[1] == 0, "Server did not refuse the connection.");
ck_assert_msg(public_key_cmp(packet_resp_plain + 2, f_public_key) == 0, "Server sent the wrong public key.");
// Closing connections.
kill_sock(sock);
kill_TCP_server(tcp_s);
}
END_TEST
struct sec_TCP_con {
Socket sock;
uint8_t public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t recv_nonce[CRYPTO_NONCE_SIZE];
uint8_t sent_nonce[CRYPTO_NONCE_SIZE];
uint8_t shared_key[CRYPTO_SHARED_KEY_SIZE];
};
static struct sec_TCP_con *new_TCP_con(TCP_Server *tcp_s)
{
struct sec_TCP_con *sec_c = (struct sec_TCP_con *)malloc(sizeof(struct sec_TCP_con));
Socket sock = net_socket(net_family_ipv6, TOX_SOCK_STREAM, TOX_PROTO_TCP);
IP_Port ip_port_loopback;
ip_port_loopback.ip = get_loopback();
ip_port_loopback.port = net_htons(ports[random_u32() % NUM_PORTS]);
int ret = net_connect(sock, ip_port_loopback);
ck_assert_msg(ret == 0, "Failed to connect to the test TCP relay server.");
uint8_t f_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(sec_c->public_key, f_secret_key);
random_nonce(sec_c->sent_nonce);
uint8_t t_secret_key[CRYPTO_SECRET_KEY_SIZE];
uint8_t handshake_plain[TCP_HANDSHAKE_PLAIN_SIZE];
crypto_new_keypair(handshake_plain, t_secret_key);
memcpy(handshake_plain + CRYPTO_PUBLIC_KEY_SIZE, sec_c->sent_nonce, CRYPTO_NONCE_SIZE);
uint8_t handshake[TCP_CLIENT_HANDSHAKE_SIZE];
memcpy(handshake, sec_c->public_key, CRYPTO_PUBLIC_KEY_SIZE);
random_nonce(handshake + CRYPTO_PUBLIC_KEY_SIZE);
ret = encrypt_data(tcp_server_public_key(tcp_s), f_secret_key, handshake + CRYPTO_PUBLIC_KEY_SIZE, handshake_plain,
TCP_HANDSHAKE_PLAIN_SIZE, handshake + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_NONCE_SIZE);
ck_assert_msg(ret == TCP_CLIENT_HANDSHAKE_SIZE - (CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_NONCE_SIZE),
"Failed to encrypt the outgoing handshake.");
ck_assert_msg(net_send(sock, handshake, TCP_CLIENT_HANDSHAKE_SIZE - 1) == TCP_CLIENT_HANDSHAKE_SIZE - 1,
"Failed to send the first portion of the handshake to the TCP relay server.");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
ck_assert_msg(net_send(sock, handshake + (TCP_CLIENT_HANDSHAKE_SIZE - 1), 1) == 1,
"Failed to send last byte of handshake.");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
uint8_t response[TCP_SERVER_HANDSHAKE_SIZE];
uint8_t response_plain[TCP_HANDSHAKE_PLAIN_SIZE];
ck_assert_msg(net_recv(sock, response, TCP_SERVER_HANDSHAKE_SIZE) == TCP_SERVER_HANDSHAKE_SIZE,
"Failed to receive server handshake response.");
ret = decrypt_data(tcp_server_public_key(tcp_s), f_secret_key, response, response + CRYPTO_NONCE_SIZE,
TCP_SERVER_HANDSHAKE_SIZE - CRYPTO_NONCE_SIZE, response_plain);
ck_assert_msg(ret == TCP_HANDSHAKE_PLAIN_SIZE, "Failed to decrypt server handshake response.");
encrypt_precompute(response_plain, t_secret_key, sec_c->shared_key);
memcpy(sec_c->recv_nonce, response_plain + CRYPTO_SHARED_KEY_SIZE, CRYPTO_NONCE_SIZE);
sec_c->sock = sock;
return sec_c;
}
static void kill_TCP_con(struct sec_TCP_con *con)
{
kill_sock(con->sock);
free(con);
}
static int write_packet_TCP_secure_connection(struct sec_TCP_con *con, uint8_t *data, uint16_t length)
{
VLA(uint8_t, packet, sizeof(uint16_t) + length + CRYPTO_MAC_SIZE);
uint16_t c_length = net_htons(length + CRYPTO_MAC_SIZE);
memcpy(packet, &c_length, sizeof(uint16_t));
int len = encrypt_data_symmetric(con->shared_key, con->sent_nonce, data, length, packet + sizeof(uint16_t));
if ((unsigned int)len != (SIZEOF_VLA(packet) - sizeof(uint16_t))) {
return -1;
}
increment_nonce(con->sent_nonce);
ck_assert_msg(net_send(con->sock, packet, SIZEOF_VLA(packet)) == SIZEOF_VLA(packet), "Failed to send a packet");
return 0;
}
static int read_packet_sec_TCP(struct sec_TCP_con *con, uint8_t *data, uint16_t length)
{
int rlen = net_recv(con->sock, data, length);
ck_assert_msg(rlen == length, "Did not receive packet of correct length. Wanted %i, instead got %i", length, rlen);
rlen = decrypt_data_symmetric(con->shared_key, con->recv_nonce, data + 2, length - 2, data);
ck_assert_msg(rlen != -1, "Failed to decrypt a received packet from the Relay server.");
increment_nonce(con->recv_nonce);
return rlen;
}
START_TEST(test_some)
{
uint8_t self_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t self_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Server *tcp_s = new_TCP_server(USE_IPV6, NUM_PORTS, ports, self_secret_key, nullptr);
ck_assert_msg(tcp_s != nullptr, "Failed to create TCP relay server");
ck_assert_msg(tcp_server_listen_count(tcp_s) == NUM_PORTS, "Failed to bind to all ports");
struct sec_TCP_con *con1 = new_TCP_con(tcp_s);
struct sec_TCP_con *con2 = new_TCP_con(tcp_s);
struct sec_TCP_con *con3 = new_TCP_con(tcp_s);
uint8_t requ_p[1 + CRYPTO_PUBLIC_KEY_SIZE];
requ_p[0] = 0;
// Sending wrong public keys to test server response.
memcpy(requ_p + 1, con3->public_key, CRYPTO_PUBLIC_KEY_SIZE);
write_packet_TCP_secure_connection(con1, requ_p, sizeof(requ_p));
memcpy(requ_p + 1, con1->public_key, CRYPTO_PUBLIC_KEY_SIZE);
write_packet_TCP_secure_connection(con3, requ_p, sizeof(requ_p));
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
// Testing response from connection 1
uint8_t data[2048];
int len = read_packet_sec_TCP(con1, data, 2 + 1 + 1 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_MAC_SIZE);
ck_assert_msg(len == 1 + 1 + CRYPTO_PUBLIC_KEY_SIZE, "Wrong response packet length of %d.", len);
ck_assert_msg(data[0] == 1, "Wrong response packet id of %d.", data[0]);
ck_assert_msg(data[1] == 16, "Server didn't refuse connection using wrong public key.");
ck_assert_msg(public_key_cmp(data + 2, con3->public_key) == 0, "Key in response packet wrong.");
// Connection 3
len = read_packet_sec_TCP(con3, data, 2 + 1 + 1 + CRYPTO_PUBLIC_KEY_SIZE + CRYPTO_MAC_SIZE);
ck_assert_msg(len == 1 + 1 + CRYPTO_PUBLIC_KEY_SIZE, "Wrong response packet length of %d.", len);
ck_assert_msg(data[0] == 1, "Wrong response packet id of %d.", data[0]);
ck_assert_msg(data[1] == 16, "Server didn't refuse connection using wrong public key.");
ck_assert_msg(public_key_cmp(data + 2, con1->public_key) == 0, "Key in response packet wrong.");
uint8_t test_packet[512] = {16, 17, 16, 86, 99, 127, 255, 189, 78}; //What is this packet????
write_packet_TCP_secure_connection(con3, test_packet, sizeof(test_packet));
write_packet_TCP_secure_connection(con3, test_packet, sizeof(test_packet));
write_packet_TCP_secure_connection(con3, test_packet, sizeof(test_packet));
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
len = read_packet_sec_TCP(con1, data, 2 + 2 + CRYPTO_MAC_SIZE);
ck_assert_msg(len == 2, "wrong len %d", len);
ck_assert_msg(data[0] == 2, "wrong packet id %u", data[0]);
ck_assert_msg(data[1] == 16, "wrong peer id %u", data[1]);
len = read_packet_sec_TCP(con3, data, 2 + 2 + CRYPTO_MAC_SIZE);
ck_assert_msg(len == 2, "wrong len %d", len);
ck_assert_msg(data[0] == 2, "wrong packet id %u", data[0]);
ck_assert_msg(data[1] == 16, "wrong peer id %u", data[1]);
len = read_packet_sec_TCP(con1, data, 2 + sizeof(test_packet) + CRYPTO_MAC_SIZE);
ck_assert_msg(len == sizeof(test_packet), "wrong len %d", len);
ck_assert_msg(memcmp(data, test_packet, sizeof(test_packet)) == 0, "packet is wrong %u %u %u %u", data[0], data[1],
data[sizeof(test_packet) - 2], data[sizeof(test_packet) - 1]);
len = read_packet_sec_TCP(con1, data, 2 + sizeof(test_packet) + CRYPTO_MAC_SIZE);
ck_assert_msg(len == sizeof(test_packet), "wrong len %d", len);
ck_assert_msg(memcmp(data, test_packet, sizeof(test_packet)) == 0, "packet is wrong %u %u %u %u", data[0], data[1],
data[sizeof(test_packet) - 2], data[sizeof(test_packet) - 1]);
len = read_packet_sec_TCP(con1, data, 2 + sizeof(test_packet) + CRYPTO_MAC_SIZE);
ck_assert_msg(len == sizeof(test_packet), "wrong len %d", len);
ck_assert_msg(memcmp(data, test_packet, sizeof(test_packet)) == 0, "packet is wrong %u %u %u %u", data[0], data[1],
data[sizeof(test_packet) - 2], data[sizeof(test_packet) - 1]);
write_packet_TCP_secure_connection(con1, test_packet, sizeof(test_packet));
write_packet_TCP_secure_connection(con1, test_packet, sizeof(test_packet));
write_packet_TCP_secure_connection(con1, test_packet, sizeof(test_packet));
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
len = read_packet_sec_TCP(con3, data, 2 + sizeof(test_packet) + CRYPTO_MAC_SIZE);
ck_assert_msg(len == sizeof(test_packet), "wrong len %d", len);
ck_assert_msg(memcmp(data, test_packet, sizeof(test_packet)) == 0, "packet is wrong %u %u %u %u", data[0], data[1],
data[sizeof(test_packet) - 2], data[sizeof(test_packet) - 1]);
len = read_packet_sec_TCP(con3, data, 2 + sizeof(test_packet) + CRYPTO_MAC_SIZE);
ck_assert_msg(len == sizeof(test_packet), "wrong len %d", len);
ck_assert_msg(memcmp(data, test_packet, sizeof(test_packet)) == 0, "packet is wrong %u %u %u %u", data[0], data[1],
data[sizeof(test_packet) - 2], data[sizeof(test_packet) - 1]);
len = read_packet_sec_TCP(con3, data, 2 + sizeof(test_packet) + CRYPTO_MAC_SIZE);
ck_assert_msg(len == sizeof(test_packet), "wrong len %d", len);
ck_assert_msg(memcmp(data, test_packet, sizeof(test_packet)) == 0, "packet is wrong %u %u %u %u", data[0], data[1],
data[sizeof(test_packet) - 2], data[sizeof(test_packet) - 1]);
uint8_t ping_packet[1 + sizeof(uint64_t)] = {4, 8, 6, 9, 67};
write_packet_TCP_secure_connection(con1, ping_packet, sizeof(ping_packet));
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
len = read_packet_sec_TCP(con1, data, 2 + sizeof(ping_packet) + CRYPTO_MAC_SIZE);
ck_assert_msg(len == sizeof(ping_packet), "wrong len %d", len);
ck_assert_msg(data[0] == 5, "wrong packet id %u", data[0]);
ck_assert_msg(memcmp(ping_packet + 1, data + 1, sizeof(uint64_t)) == 0, "wrong packet data");
// Kill off the connections
kill_TCP_server(tcp_s);
kill_TCP_con(con1);
kill_TCP_con(con2);
kill_TCP_con(con3);
}
END_TEST
static int response_callback_good;
static uint8_t response_callback_connection_id;
static uint8_t response_callback_public_key[CRYPTO_PUBLIC_KEY_SIZE];
static int response_callback(void *object, uint8_t connection_id, const uint8_t *public_key)
{
if (set_tcp_connection_number((TCP_Client_Connection *)((char *)object - 2), connection_id, 7) != 0) {
return 1;
}
response_callback_connection_id = connection_id;
memcpy(response_callback_public_key, public_key, CRYPTO_PUBLIC_KEY_SIZE);
response_callback_good++;
return 0;
}
static int status_callback_good;
static uint8_t status_callback_connection_id;
static uint8_t status_callback_status;
static int status_callback(void *object, uint32_t number, uint8_t connection_id, uint8_t status)
{
if (object != (void *)2) {
return 1;
}
if (number != 7) {
return 1;
}
status_callback_connection_id = connection_id;
status_callback_status = status;
status_callback_good++;
return 0;
}
static int data_callback_good;
static int data_callback(void *object, uint32_t number, uint8_t connection_id, const uint8_t *data, uint16_t length,
void *userdata)
{
if (object != (void *)3) {
return 1;
}
if (number != 7) {
return 1;
}
if (length != 5) {
return 1;
}
if (data[0] == 1 && data[1] == 2 && data[2] == 3 && data[3] == 4 && data[4] == 5) {
data_callback_good++;
return 0;
}
return 1;
}
static int oob_data_callback_good;
static uint8_t oob_pubkey[CRYPTO_PUBLIC_KEY_SIZE];
static int oob_data_callback(void *object, const uint8_t *public_key, const uint8_t *data, uint16_t length,
void *userdata)
{
if (object != (void *)4) {
return 1;
}
if (length != 5) {
return 1;
}
if (public_key_cmp(public_key, oob_pubkey) != 0) {
return 1;
}
if (data[0] == 1 && data[1] == 2 && data[2] == 3 && data[3] == 4 && data[4] == 5) {
oob_data_callback_good++;
return 0;
}
return 1;
}
START_TEST(test_client)
{
unix_time_update();
uint8_t self_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t self_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Server *tcp_s = new_TCP_server(USE_IPV6, NUM_PORTS, ports, self_secret_key, nullptr);
ck_assert_msg(tcp_s != nullptr, "Failed to create TCP relay server");
ck_assert_msg(tcp_server_listen_count(tcp_s) == NUM_PORTS, "Failed to bind to all ports");
uint8_t f_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t f_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(f_public_key, f_secret_key);
IP_Port ip_port_tcp_s;
ip_port_tcp_s.port = net_htons(ports[random_u32() % NUM_PORTS]);
ip_port_tcp_s.ip = get_loopback();
TCP_Client_Connection *conn = new_TCP_connection(ip_port_tcp_s, self_public_key, f_public_key, f_secret_key, nullptr);
c_sleep(50);
do_TCP_connection(conn, nullptr);
ck_assert_msg(tcp_con_status(conn) == TCP_CLIENT_UNCONFIRMED, "Wrong status. Expected: %u, is: %u",
TCP_CLIENT_UNCONFIRMED, tcp_con_status(conn));
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_TCP_connection(conn, nullptr);
ck_assert_msg(tcp_con_status(conn) == TCP_CLIENT_CONFIRMED, "Wrong status. Expected: %u, is: %u", TCP_CLIENT_CONFIRMED,
tcp_con_status(conn));
c_sleep(500);
do_TCP_connection(conn, nullptr);
ck_assert_msg(tcp_con_status(conn) == TCP_CLIENT_CONFIRMED, "Wrong status. Expected: %u, is: %u", TCP_CLIENT_CONFIRMED,
tcp_con_status(conn));
c_sleep(500);
do_TCP_connection(conn, nullptr);
ck_assert_msg(tcp_con_status(conn) == TCP_CLIENT_CONFIRMED, "Wrong status. Expected: %u, is: %u", TCP_CLIENT_CONFIRMED,
tcp_con_status(conn));
do_TCP_server(tcp_s);
c_sleep(50);
ck_assert_msg(tcp_con_status(conn) == TCP_CLIENT_CONFIRMED, "Wrong status. Expected: %u, is: %u", TCP_CLIENT_CONFIRMED,
tcp_con_status(conn));
uint8_t f2_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t f2_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(f2_public_key, f2_secret_key);
ip_port_tcp_s.port = net_htons(ports[random_u32() % NUM_PORTS]);
TCP_Client_Connection *conn2 = new_TCP_connection(
ip_port_tcp_s, self_public_key, f2_public_key, f2_secret_key, nullptr);
routing_response_handler(conn, response_callback, (char *)conn + 2);
routing_status_handler(conn, status_callback, (void *)2);
routing_data_handler(conn, data_callback, (void *)3);
oob_data_handler(conn, oob_data_callback, (void *)4);
oob_data_callback_good = response_callback_good = status_callback_good = data_callback_good = 0;
c_sleep(50);
do_TCP_connection(conn, nullptr);
do_TCP_connection(conn2, nullptr);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_TCP_connection(conn, nullptr);
do_TCP_connection(conn2, nullptr);
c_sleep(50);
uint8_t data[5] = {1, 2, 3, 4, 5};
memcpy(oob_pubkey, f2_public_key, CRYPTO_PUBLIC_KEY_SIZE);
send_oob_packet(conn2, f_public_key, data, 5);
send_routing_request(conn, f2_public_key);
send_routing_request(conn2, f_public_key);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_TCP_connection(conn, nullptr);
do_TCP_connection(conn2, nullptr);
ck_assert_msg(oob_data_callback_good == 1, "oob callback not called");
ck_assert_msg(response_callback_good == 1, "response callback not called");
ck_assert_msg(public_key_cmp(response_callback_public_key, f2_public_key) == 0, "wrong public key");
ck_assert_msg(status_callback_good == 1, "status callback not called");
ck_assert_msg(status_callback_status == 2, "wrong status");
ck_assert_msg(status_callback_connection_id == response_callback_connection_id, "connection ids not equal");
c_sleep(50);
do_TCP_server(tcp_s);
ck_assert_msg(send_data(conn2, 0, data, 5) == 1, "send data failed");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_TCP_connection(conn, nullptr);
do_TCP_connection(conn2, nullptr);
ck_assert_msg(data_callback_good == 1, "data callback not called");
status_callback_good = 0;
send_disconnect_request(conn2, 0);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_TCP_connection(conn, nullptr);
do_TCP_connection(conn2, nullptr);
ck_assert_msg(status_callback_good == 1, "status callback not called");
ck_assert_msg(status_callback_status == 1, "wrong status");
kill_TCP_server(tcp_s);
kill_TCP_connection(conn);
kill_TCP_connection(conn2);
}
END_TEST
START_TEST(test_client_invalid)
{
unix_time_update();
uint8_t self_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t self_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(self_public_key, self_secret_key);
uint8_t f_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t f_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(f_public_key, f_secret_key);
IP_Port ip_port_tcp_s;
ip_port_tcp_s.port = net_htons(ports[random_u32() % NUM_PORTS]);
ip_port_tcp_s.ip = get_loopback();
TCP_Client_Connection *conn = new_TCP_connection(ip_port_tcp_s, self_public_key, f_public_key, f_secret_key, nullptr);
c_sleep(50);
do_TCP_connection(conn, nullptr);
ck_assert_msg(tcp_con_status(conn) == TCP_CLIENT_CONNECTING, "Wrong status. Expected: %u, is: %u",
TCP_CLIENT_CONNECTING, tcp_con_status(conn));
c_sleep(5000);
do_TCP_connection(conn, nullptr);
ck_assert_msg(tcp_con_status(conn) == TCP_CLIENT_CONNECTING, "Wrong status. Expected: %u, is: %u",
TCP_CLIENT_CONNECTING, tcp_con_status(conn));
c_sleep(6000);
do_TCP_connection(conn, nullptr);
ck_assert_msg(tcp_con_status(conn) == TCP_CLIENT_DISCONNECTED, "Wrong status. Expected: %u, is: %u",
TCP_CLIENT_DISCONNECTED, tcp_con_status(conn));
kill_TCP_connection(conn);
}
END_TEST
#include "../toxcore/TCP_connection.h"
static bool tcp_data_callback_called;
static int tcp_data_callback(void *object, int id, const uint8_t *data, uint16_t length, void *userdata)
{
if (object != (void *)120397) {
return -1;
}
if (id != 123) {
return -1;
}
if (length != 6) {
return -1;
}
if (memcmp(data, "Gentoo", length) != 0) {
return -1;
}
tcp_data_callback_called = 1;
return 0;
}
START_TEST(test_tcp_connection)
{
tcp_data_callback_called = 0;
unix_time_update();
uint8_t self_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t self_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Server *tcp_s = new_TCP_server(USE_IPV6, NUM_PORTS, ports, self_secret_key, nullptr);
ck_assert_msg(public_key_cmp(tcp_server_public_key(tcp_s), self_public_key) == 0, "Wrong public key");
TCP_Proxy_Info proxy_info;
proxy_info.proxy_type = TCP_PROXY_NONE;
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Connections *tc_1 = new_tcp_connections(self_secret_key, &proxy_info);
ck_assert_msg(public_key_cmp(tcp_connections_public_key(tc_1), self_public_key) == 0, "Wrong public key");
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Connections *tc_2 = new_tcp_connections(self_secret_key, &proxy_info);
ck_assert_msg(public_key_cmp(tcp_connections_public_key(tc_2), self_public_key) == 0, "Wrong public key");
IP_Port ip_port_tcp_s;
ip_port_tcp_s.port = net_htons(ports[random_u32() % NUM_PORTS]);
ip_port_tcp_s.ip = get_loopback();
int connection = new_tcp_connection_to(tc_1, tcp_connections_public_key(tc_2), 123);
ck_assert_msg(connection == 0, "Connection id wrong");
ck_assert_msg(add_tcp_relay_connection(tc_1, connection, ip_port_tcp_s, tcp_server_public_key(tcp_s)) == 0,
"Could not add tcp relay to connection\n");
ip_port_tcp_s.port = net_htons(ports[random_u32() % NUM_PORTS]);
connection = new_tcp_connection_to(tc_2, tcp_connections_public_key(tc_1), 123);
ck_assert_msg(connection == 0, "Connection id wrong");
ck_assert_msg(add_tcp_relay_connection(tc_2, connection, ip_port_tcp_s, tcp_server_public_key(tcp_s)) == 0,
"Could not add tcp relay to connection\n");
ck_assert_msg(new_tcp_connection_to(tc_2, tcp_connections_public_key(tc_1), 123) == -1,
"Managed to readd same connection\n");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
int ret = send_packet_tcp_connection(tc_1, 0, (const uint8_t *)"Gentoo", 6);
ck_assert_msg(ret == 0, "could not send packet.");
set_packet_tcp_connection_callback(tc_2, &tcp_data_callback, (void *) 120397);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
ck_assert_msg(tcp_data_callback_called, "could not recv packet.");
ck_assert_msg(tcp_connection_to_online_tcp_relays(tc_1, 0) == 1, "Wrong number of connected relays");
ck_assert_msg(kill_tcp_connection_to(tc_1, 0) == 0, "could not kill connection to\n");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
ck_assert_msg(send_packet_tcp_connection(tc_1, 0, (const uint8_t *)"Gentoo", 6) == -1, "could send packet.");
ck_assert_msg(kill_tcp_connection_to(tc_2, 0) == 0, "could not kill connection to\n");
kill_TCP_server(tcp_s);
kill_tcp_connections(tc_1);
kill_tcp_connections(tc_2);
}
END_TEST
static bool tcp_oobdata_callback_called;
static int tcp_oobdata_callback(void *object, const uint8_t *public_key, unsigned int id, const uint8_t *data,
uint16_t length, void *userdata)
{
TCP_Connections *tcp_c = (TCP_Connections *)object;
if (length != 6) {
return -1;
}
if (memcmp(data, "Gentoo", length) != 0) {
return -1;
}
if (tcp_send_oob_packet(tcp_c, id, public_key, data, length) == 0) {
tcp_oobdata_callback_called = 1;
}
return 0;
}
START_TEST(test_tcp_connection2)
{
tcp_oobdata_callback_called = 0;
tcp_data_callback_called = 0;
unix_time_update();
uint8_t self_public_key[CRYPTO_PUBLIC_KEY_SIZE];
uint8_t self_secret_key[CRYPTO_SECRET_KEY_SIZE];
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Server *tcp_s = new_TCP_server(USE_IPV6, NUM_PORTS, ports, self_secret_key, nullptr);
ck_assert_msg(public_key_cmp(tcp_server_public_key(tcp_s), self_public_key) == 0, "Wrong public key");
TCP_Proxy_Info proxy_info;
proxy_info.proxy_type = TCP_PROXY_NONE;
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Connections *tc_1 = new_tcp_connections(self_secret_key, &proxy_info);
ck_assert_msg(public_key_cmp(tcp_connections_public_key(tc_1), self_public_key) == 0, "Wrong public key");
crypto_new_keypair(self_public_key, self_secret_key);
TCP_Connections *tc_2 = new_tcp_connections(self_secret_key, &proxy_info);
ck_assert_msg(public_key_cmp(tcp_connections_public_key(tc_2), self_public_key) == 0, "Wrong public key");
IP_Port ip_port_tcp_s;
ip_port_tcp_s.port = net_htons(ports[random_u32() % NUM_PORTS]);
ip_port_tcp_s.ip = get_loopback();
int connection = new_tcp_connection_to(tc_1, tcp_connections_public_key(tc_2), 123);
ck_assert_msg(connection == 0, "Connection id wrong");
ck_assert_msg(add_tcp_relay_connection(tc_1, connection, ip_port_tcp_s, tcp_server_public_key(tcp_s)) == 0,
"Could not add tcp relay to connection\n");
ck_assert_msg(add_tcp_relay_global(tc_2, ip_port_tcp_s, tcp_server_public_key(tcp_s)) == 0,
"Could not add global relay");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
int ret = send_packet_tcp_connection(tc_1, 0, (const uint8_t *)"Gentoo", 6);
ck_assert_msg(ret == 0, "could not send packet.");
set_oob_packet_tcp_connection_callback(tc_2, &tcp_oobdata_callback, tc_2);
set_packet_tcp_connection_callback(tc_1, &tcp_data_callback, (void *) 120397);
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
ck_assert_msg(tcp_oobdata_callback_called, "could not recv packet.");
c_sleep(50);
do_TCP_server(tcp_s);
c_sleep(50);
do_tcp_connections(tc_1, nullptr);
do_tcp_connections(tc_2, nullptr);
ck_assert_msg(tcp_data_callback_called, "could not recv packet.");
ck_assert_msg(kill_tcp_connection_to(tc_1, 0) == 0, "could not kill connection to\n");
kill_TCP_server(tcp_s);
kill_tcp_connections(tc_1);
kill_tcp_connections(tc_2);
}
END_TEST
static Suite *TCP_suite(void)
{
Suite *s = suite_create("TCP");
DEFTESTCASE_SLOW(basic, 5);
DEFTESTCASE_SLOW(some, 10);
DEFTESTCASE_SLOW(client, 10);
DEFTESTCASE_SLOW(client_invalid, 15);
DEFTESTCASE_SLOW(tcp_connection, 20);
DEFTESTCASE_SLOW(tcp_connection2, 20);
return s;
}
int main(void)
{
setvbuf(stdout, nullptr, _IONBF, 0);
srand((unsigned int) time(nullptr));
Suite *TCP = TCP_suite();
SRunner *test_runner = srunner_create(TCP);
int number_failed = 0;
srunner_run_all(test_runner, CK_NORMAL);
number_failed = srunner_ntests_failed(test_runner);
srunner_free(test_runner);
return number_failed;
}