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tor-android/external/badvpn_dns/client/client.c

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/**
* @file client.c
* @author Ambroz Bizjak <ambrop7@gmail.com>
*
* @section LICENSE
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the author nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <limits.h>
#include <protocol/msgproto.h>
#include <protocol/addr.h>
#include <protocol/dataproto.h>
#include <misc/version.h>
#include <misc/debug.h>
#include <misc/offset.h>
#include <misc/byteorder.h>
#include <misc/nsskey.h>
#include <misc/loglevel.h>
#include <misc/loggers_string.h>
#include <misc/string_begins_with.h>
#include <misc/open_standard_streams.h>
#include <structure/LinkedList1.h>
#include <base/DebugObject.h>
#include <base/BLog.h>
#include <security/BSecurity.h>
#include <security/BRandom.h>
#include <system/BSignal.h>
#include <system/BTime.h>
#include <system/BNetwork.h>
#include <nspr_support/DummyPRFileDesc.h>
#include <nspr_support/BSSLConnection.h>
#include <server_connection/ServerConnection.h>
#include <tuntap/BTap.h>
#include <threadwork/BThreadWork.h>
#ifndef BADVPN_USE_WINAPI
#include <base/BLog_syslog.h>
#endif
#include <client/client.h>
#include <generated/blog_channel_client.h>
#define TRANSPORT_MODE_UDP 0
#define TRANSPORT_MODE_TCP 1
#define LOGGER_STDOUT 1
#define LOGGER_SYSLOG 2
// command-line options
struct ext_addr_option {
char *addr;
char *scope;
};
struct bind_addr_option {
char *addr;
int num_ports;
int num_ext_addrs;
struct ext_addr_option ext_addrs[MAX_EXT_ADDRS];
};
struct {
int help;
int version;
int logger;
#ifndef BADVPN_USE_WINAPI
char *logger_syslog_facility;
char *logger_syslog_ident;
#endif
int loglevel;
int loglevels[BLOG_NUM_CHANNELS];
int threads;
int use_threads_for_ssl_handshake;
int use_threads_for_ssl_data;
int ssl;
char *nssdb;
char *client_cert_name;
char *server_name;
char *server_addr;
char *tapdev;
int num_scopes;
char *scopes[MAX_SCOPES];
int num_bind_addrs;
struct bind_addr_option bind_addrs[MAX_BIND_ADDRS];
int transport_mode;
int encryption_mode;
int hash_mode;
int otp_mode;
int otp_num;
int otp_num_warn;
int fragmentation_latency;
int peer_ssl;
int peer_tcp_socket_sndbuf;
int send_buffer_size;
int send_buffer_relay_size;
int max_macs;
int max_groups;
int igmp_group_membership_interval;
int igmp_last_member_query_time;
int allow_peer_talk_without_ssl;
int max_peers;
} options;
// bind addresses
struct ext_addr {
int server_reported_port;
BAddr addr; // if server_reported_port>=0, defined only after hello received
char scope[64];
};
struct bind_addr {
BAddr addr;
int num_ports;
int num_ext_addrs;
struct ext_addr ext_addrs[MAX_EXT_ADDRS];
};
int num_bind_addrs;
struct bind_addr bind_addrs[MAX_BIND_ADDRS];
// TCP listeners
PasswordListener listeners[MAX_BIND_ADDRS];
// SPProto parameters (UDP only)
struct spproto_security_params sp_params;
// server address we connect to
BAddr server_addr;
// server name to use for SSL
char server_name[256];
// reactor
BReactor ss;
// thread work dispatcher
BThreadWorkDispatcher twd;
// client certificate if using SSL
CERTCertificate *client_cert;
// client private key if using SSL
SECKEYPrivateKey *client_key;
// device
BTap device;
int device_mtu;
// DataProtoSource for device input (reading)
DataProtoSource device_dpsource;
// DPReceiveDevice for device output (writing)
DPReceiveDevice device_output_dprd;
// data communication MTU
int data_mtu;
// peers list
LinkedList1 peers;
int num_peers;
// frame decider
FrameDecider frame_decider;
// peers that can be user as relays
LinkedList1 relays;
// peers than need a relay
LinkedList1 waiting_relay_peers;
// server connection
ServerConnection server;
// my ID, defined only after server_ready
peerid_t my_id;
// fair queue for sending peer messages to the server
PacketPassFairQueue server_queue;
// whether server is ready
int server_ready;
// dying server flow
struct server_flow *dying_server_flow;
// stops event processing, causing the program to exit
static void terminate (void);
// prints program name and version to standard output
static void print_help (const char *name);
// prints program name and version to standard output
static void print_version (void);
// parses the command line
static int parse_arguments (int argc, char *argv[]);
// processes certain command line options
static int process_arguments (void);
static int ssl_flags (void);
// handler for program termination request
static void signal_handler (void *unused);
// adds a new peer
static void peer_add (peerid_t id, int flags, const uint8_t *cert, int cert_len);
// removes a peer
static void peer_remove (struct peer_data *peer, int exiting);
// appends the peer log prefix to the logger
static void peer_logfunc (struct peer_data *peer);
// passes a message to the logger, prepending it info about the peer
static void peer_log (struct peer_data *peer, int level, const char *fmt, ...);
// see if we are the master relative to this peer
static int peer_am_master (struct peer_data *peer);
// frees PeerChat, disconnecting it from the server flow
static void peer_free_chat (struct peer_data *peer);
// initializes the link
static int peer_init_link (struct peer_data *peer);
// frees link resources
static void peer_free_link (struct peer_data *peer);
// frees link, relaying, waiting relaying
static void peer_cleanup_connections (struct peer_data *peer);
// registers the peer as a relay provider
static void peer_enable_relay_provider (struct peer_data *peer);
// unregisters the peer as a relay provider
static void peer_disable_relay_provider (struct peer_data *peer);
// install relaying for a peer
static void peer_install_relaying (struct peer_data *peer, struct peer_data *relay);
// uninstall relaying for a peer
static void peer_free_relaying (struct peer_data *peer);
// handle a peer that needs a relay
static void peer_need_relay (struct peer_data *peer);
// inserts the peer into the need relay list
static void peer_register_need_relay (struct peer_data *peer);
// removes the peer from the need relay list
static void peer_unregister_need_relay (struct peer_data *peer);
// handle a link setup failure
static void peer_reset (struct peer_data *peer);
// fees chat and sends resetpeer
static void peer_resetpeer (struct peer_data *peer);
// chat handlers
static void peer_chat_handler_error (struct peer_data *peer);
static void peer_chat_handler_message (struct peer_data *peer, uint8_t *data, int data_len);
// handlers for different message types
static void peer_msg_youconnect (struct peer_data *peer, uint8_t *data, int data_len);
static void peer_msg_cannotconnect (struct peer_data *peer, uint8_t *data, int data_len);
static void peer_msg_cannotbind (struct peer_data *peer, uint8_t *data, int data_len);
static void peer_msg_seed (struct peer_data *peer, uint8_t *data, int data_len);
static void peer_msg_confirmseed (struct peer_data *peer, uint8_t *data, int data_len);
static void peer_msg_youretry (struct peer_data *peer, uint8_t *data, int data_len);
// handler from DatagramPeerIO when we should generate a new OTP send seed
static void peer_udp_pio_handler_seed_warning (struct peer_data *peer);
// handler from DatagramPeerIO when a new OTP seed can be recognized once it was provided to it
static void peer_udp_pio_handler_seed_ready (struct peer_data *peer);
// handler from DatagramPeerIO when an error occurs on the connection
static void peer_udp_pio_handler_error (struct peer_data *peer);
// handler from StreamPeerIO when an error occurs on the connection
static void peer_tcp_pio_handler_error (struct peer_data *peer);
// peer retry timer handler. The timer is used only on the master side,
// wither when we detect an error, or the peer reports an error.
static void peer_reset_timer_handler (struct peer_data *peer);
// start binding, according to the protocol
static void peer_start_binding (struct peer_data *peer);
// tries binding on one address, according to the protocol
static void peer_bind (struct peer_data *peer);
static void peer_bind_one_address (struct peer_data *peer, int addr_index, int *cont);
static void peer_connect (struct peer_data *peer, BAddr addr, uint8_t *encryption_key, uint64_t password);
static int peer_start_msg (struct peer_data *peer, void **data, int type, int len);
static void peer_end_msg (struct peer_data *peer);
// sends a message with no payload to the peer
static void peer_send_simple (struct peer_data *peer, int msgid);
static void peer_send_conectinfo (struct peer_data *peer, int addr_index, int port_adjust, uint8_t *enckey, uint64_t pass);
static void peer_send_confirmseed (struct peer_data *peer, uint16_t seed_id);
// handler for peer DataProto up state changes
static void peer_dataproto_handler (struct peer_data *peer, int up);
// looks for a peer with the given ID
static struct peer_data * find_peer_by_id (peerid_t id);
// device error handler
static void device_error_handler (void *unused);
// DataProtoSource handler for packets from the device
static void device_dpsource_handler (void *unused, const uint8_t *frame, int frame_len);
// assign relays to clients waiting for them
static void assign_relays (void);
// checks if the given address scope is known (i.e. we can connect to an address in it)
static char * address_scope_known (uint8_t *name, int name_len);
// handlers for server messages
static void server_handler_error (void *user);
static void server_handler_ready (void *user, peerid_t param_my_id, uint32_t ext_ip);
static void server_handler_newclient (void *user, peerid_t peer_id, int flags, const uint8_t *cert, int cert_len);
static void server_handler_endclient (void *user, peerid_t peer_id);
static void server_handler_message (void *user, peerid_t peer_id, uint8_t *data, int data_len);
// jobs
static void peer_job_send_seed (struct peer_data *peer);
static void peer_job_init (struct peer_data *peer);
// server flows
static struct server_flow * server_flow_init (void);
static void server_flow_free (struct server_flow *flow);
static void server_flow_die (struct server_flow *flow);
static void server_flow_qflow_handler_busy (struct server_flow *flow);
static void server_flow_connect (struct server_flow *flow, PacketRecvInterface *input);
static void server_flow_disconnect (struct server_flow *flow);
int main (int argc, char *argv[])
{
if (argc <= 0) {
return 1;
}
// open standard streams
open_standard_streams();
// parse command-line arguments
if (!parse_arguments(argc, argv)) {
fprintf(stderr, "Failed to parse arguments\n");
print_help(argv[0]);
goto fail0;
}
// handle --help and --version
if (options.help) {
print_version();
print_help(argv[0]);
return 0;
}
if (options.version) {
print_version();
return 0;
}
// initialize logger
switch (options.logger) {
case LOGGER_STDOUT:
BLog_InitStdout();
break;
#ifndef BADVPN_USE_WINAPI
case LOGGER_SYSLOG:
if (!BLog_InitSyslog(options.logger_syslog_ident, options.logger_syslog_facility)) {
fprintf(stderr, "Failed to initialize syslog logger\n");
goto fail0;
}
break;
#endif
default:
ASSERT(0);
}
// configure logger channels
for (int i = 0; i < BLOG_NUM_CHANNELS; i++) {
if (options.loglevels[i] >= 0) {
BLog_SetChannelLoglevel(i, options.loglevels[i]);
}
else if (options.loglevel >= 0) {
BLog_SetChannelLoglevel(i, options.loglevel);
}
}
BLog(BLOG_NOTICE, "initializing "GLOBAL_PRODUCT_NAME" "PROGRAM_NAME" "GLOBAL_VERSION);
if (options.ssl) {
// init NSPR
PR_Init(PR_USER_THREAD, PR_PRIORITY_NORMAL, 0);
// register local NSPR file types
if (!DummyPRFileDesc_GlobalInit()) {
BLog(BLOG_ERROR, "DummyPRFileDesc_GlobalInit failed");
goto fail01;
}
if (!BSSLConnection_GlobalInit()) {
BLog(BLOG_ERROR, "BSSLConnection_GlobalInit failed");
goto fail01;
}
// init NSS
if (NSS_Init(options.nssdb) != SECSuccess) {
BLog(BLOG_ERROR, "NSS_Init failed (%d)", (int)PR_GetError());
goto fail01;
}
// set cipher policy
if (NSS_SetDomesticPolicy() != SECSuccess) {
BLog(BLOG_ERROR, "NSS_SetDomesticPolicy failed (%d)", (int)PR_GetError());
goto fail02;
}
// init server cache
if (SSL_ConfigServerSessionIDCache(0, 0, 0, NULL) != SECSuccess) {
BLog(BLOG_ERROR, "SSL_ConfigServerSessionIDCache failed (%d)", (int)PR_GetError());
goto fail02;
}
// open server certificate and private key
if (!open_nss_cert_and_key(options.client_cert_name, &client_cert, &client_key)) {
BLog(BLOG_ERROR, "Cannot open certificate and key");
goto fail03;
}
}
// initialize network
if (!BNetwork_GlobalInit()) {
BLog(BLOG_ERROR, "BNetwork_GlobalInit failed");
goto fail1;
}
// init time
BTime_Init();
// process arguments
if (!process_arguments()) {
BLog(BLOG_ERROR, "Failed to process arguments");
goto fail1;
}
// init reactor
if (!BReactor_Init(&ss)) {
BLog(BLOG_ERROR, "BReactor_Init failed");
goto fail1;
}
// setup signal handler
if (!BSignal_Init(&ss, signal_handler, NULL)) {
BLog(BLOG_ERROR, "BSignal_Init failed");
goto fail2;
}
// init thread work dispatcher
if (!BThreadWorkDispatcher_Init(&twd, &ss, options.threads)) {
BLog(BLOG_ERROR, "BThreadWorkDispatcher_Init failed");
goto fail3;
}
// init BSecurity
if (BThreadWorkDispatcher_UsingThreads(&twd)) {
if (!BSecurity_GlobalInitThreadSafe()) {
BLog(BLOG_ERROR, "BSecurity_GlobalInitThreadSafe failed");
goto fail4;
}
}
// init listeners
int num_listeners = 0;
if (options.transport_mode == TRANSPORT_MODE_TCP) {
while (num_listeners < num_bind_addrs) {
struct bind_addr *addr = &bind_addrs[num_listeners];
if (!PasswordListener_Init(&listeners[num_listeners], &ss, &twd, addr->addr, TCP_MAX_PASSWORD_LISTENER_CLIENTS, options.peer_ssl, ssl_flags(), client_cert, client_key)) {
BLog(BLOG_ERROR, "PasswordListener_Init failed");
goto fail8;
}
num_listeners++;
}
}
// init device
if (!BTap_Init(&device, &ss, options.tapdev, device_error_handler, NULL, 0)) {
BLog(BLOG_ERROR, "BTap_Init failed");
goto fail8;
}
// remember device MTU
device_mtu = BTap_GetMTU(&device);
BLog(BLOG_INFO, "device MTU is %d", device_mtu);
// calculate data MTU
if (device_mtu > INT_MAX - DATAPROTO_MAX_OVERHEAD) {
BLog(BLOG_ERROR, "Device MTU is too large");
goto fail9;
}
data_mtu = DATAPROTO_MAX_OVERHEAD + device_mtu;
// init device input
if (!DataProtoSource_Init(&device_dpsource, BTap_GetOutput(&device), device_dpsource_handler, NULL, &ss)) {
BLog(BLOG_ERROR, "DataProtoSource_Init failed");
goto fail9;
}
// init device output
if (!DPReceiveDevice_Init(&device_output_dprd, device_mtu, (DPReceiveDevice_output_func)BTap_Send, &device, &ss, options.send_buffer_relay_size, PEER_RELAY_FLOW_INACTIVITY_TIME)) {
BLog(BLOG_ERROR, "DPReceiveDevice_Init failed");
goto fail10;
}
// init peers list
LinkedList1_Init(&peers);
num_peers = 0;
// init frame decider
FrameDecider_Init(&frame_decider, options.max_macs, options.max_groups, options.igmp_group_membership_interval, options.igmp_last_member_query_time, &ss);
// init relays list
LinkedList1_Init(&relays);
// init need relay list
LinkedList1_Init(&waiting_relay_peers);
// start connecting to server
if (!ServerConnection_Init(&server, &ss, &twd, server_addr, SC_KEEPALIVE_INTERVAL, SERVER_BUFFER_MIN_PACKETS, options.ssl, ssl_flags(), client_cert, client_key, server_name, NULL,
server_handler_error, server_handler_ready, server_handler_newclient, server_handler_endclient, server_handler_message
)) {
BLog(BLOG_ERROR, "ServerConnection_Init failed");
goto fail11;
}
// set server not ready
server_ready = 0;
// set no dying flow
dying_server_flow = NULL;
// enter event loop
BLog(BLOG_NOTICE, "entering event loop");
BReactor_Exec(&ss);
if (server_ready) {
// allow freeing server queue flows
PacketPassFairQueue_PrepareFree(&server_queue);
// make ServerConnection stop using buffers from peers before they are freed
ServerConnection_ReleaseBuffers(&server);
}
// free peers
LinkedList1Node *node;
while (node = LinkedList1_GetFirst(&peers)) {
struct peer_data *peer = UPPER_OBJECT(node, struct peer_data, list_node);
peer_remove(peer, 1);
}
// free dying server flow
if (dying_server_flow) {
server_flow_free(dying_server_flow);
}
if (server_ready) {
PacketPassFairQueue_Free(&server_queue);
}
ServerConnection_Free(&server);
fail11:
FrameDecider_Free(&frame_decider);
DPReceiveDevice_Free(&device_output_dprd);
fail10:
DataProtoSource_Free(&device_dpsource);
fail9:
BTap_Free(&device);
fail8:
if (options.transport_mode == TRANSPORT_MODE_TCP) {
while (num_listeners-- > 0) {
PasswordListener_Free(&listeners[num_listeners]);
}
}
if (BThreadWorkDispatcher_UsingThreads(&twd)) {
BSecurity_GlobalFreeThreadSafe();
}
fail4:
// NOTE: BThreadWorkDispatcher must be freed before NSPR and stuff
BThreadWorkDispatcher_Free(&twd);
fail3:
BSignal_Finish();
fail2:
BReactor_Free(&ss);
fail1:
if (options.ssl) {
CERT_DestroyCertificate(client_cert);
SECKEY_DestroyPrivateKey(client_key);
fail03:
ASSERT_FORCE(SSL_ShutdownServerSessionIDCache() == SECSuccess)
fail02:
SSL_ClearSessionCache();
ASSERT_FORCE(NSS_Shutdown() == SECSuccess)
fail01:
ASSERT_FORCE(PR_Cleanup() == PR_SUCCESS)
PL_ArenaFinish();
}
BLog(BLOG_NOTICE, "exiting");
BLog_Free();
fail0:
// finish objects
DebugObjectGlobal_Finish();
return 1;
}
void terminate (void)
{
BLog(BLOG_NOTICE, "tearing down");
// exit event loop
BReactor_Quit(&ss, 0);
}
void print_help (const char *name)
{
printf(
"Usage:\n"
" %s\n"
" [--help]\n"
" [--version]\n"
" [--logger <"LOGGERS_STRING">]\n"
#ifndef BADVPN_USE_WINAPI
" (logger=syslog?\n"
" [--syslog-facility <string>]\n"
" [--syslog-ident <string>]\n"
" )\n"
#endif
" [--loglevel <0-5/none/error/warning/notice/info/debug>]\n"
" [--channel-loglevel <channel-name> <0-5/none/error/warning/notice/info/debug>] ...\n"
" [--threads <integer>]\n"
" [--use-threads-for-ssl-handshake]\n"
" [--use-threads-for-ssl-data]\n"
" [--ssl --nssdb <string> --client-cert-name <string>]\n"
" [--server-name <string>]\n"
" --server-addr <addr>\n"
" [--tapdev <name>]\n"
" [--scope <scope_name>] ...\n"
" [\n"
" --bind-addr <addr>\n"
" (transport-mode=udp? --num-ports <num>)\n"
" [--ext-addr <addr / {server_reported}:port> <scope_name>] ...\n"
" ] ...\n"
" --transport-mode <udp/tcp>\n"
" (transport-mode=udp?\n"
" --encryption-mode <blowfish/aes/none>\n"
" --hash-mode <md5/sha1/none>\n"
" [--otp <blowfish/aes> <num> <num-warn>]\n"
" [--fragmentation-latency <milliseconds>]\n"
" )\n"
" (transport-mode=tcp?\n"
" (ssl? [--peer-ssl])\n"
" [--peer-tcp-socket-sndbuf <bytes / 0>]\n"
" )\n"
" [--send-buffer-size <num-packets>]\n"
" [--send-buffer-relay-size <num-packets>]\n"
" [--max-macs <num>]\n"
" [--max-groups <num>]\n"
" [--igmp-group-membership-interval <ms>]\n"
" [--igmp-last-member-query-time <ms>]\n"
" [--allow-peer-talk-without-ssl]\n"
" [--max-peers <number>]\n"
"Address format is a.b.c.d:port (IPv4) or [addr]:port (IPv6).\n",
name
);
}
void print_version (void)
{
printf(GLOBAL_PRODUCT_NAME" "PROGRAM_NAME" "GLOBAL_VERSION"\n"GLOBAL_COPYRIGHT_NOTICE"\n");
}
int parse_arguments (int argc, char *argv[])
{
if (argc <= 0) {
return 0;
}
options.help = 0;
options.version = 0;
options.logger = LOGGER_STDOUT;
#ifndef BADVPN_USE_WINAPI
options.logger_syslog_facility = "daemon";
options.logger_syslog_ident = argv[0];
#endif
options.loglevel = -1;
for (int i = 0; i < BLOG_NUM_CHANNELS; i++) {
options.loglevels[i] = -1;
}
options.threads = 0;
options.use_threads_for_ssl_handshake = 0;
options.use_threads_for_ssl_data = 0;
options.ssl = 0;
options.nssdb = NULL;
options.client_cert_name = NULL;
options.server_name = NULL;
options.server_addr = NULL;
options.tapdev = NULL;
options.num_scopes = 0;
options.num_bind_addrs = 0;
options.transport_mode = -1;
options.encryption_mode = -1;
options.hash_mode = -1;
options.otp_mode = SPPROTO_OTP_MODE_NONE;
options.fragmentation_latency = PEER_DEFAULT_UDP_FRAGMENTATION_LATENCY;
options.peer_ssl = 0;
options.peer_tcp_socket_sndbuf = -1;
options.send_buffer_size = PEER_DEFAULT_SEND_BUFFER_SIZE;
options.send_buffer_relay_size = PEER_DEFAULT_SEND_BUFFER_RELAY_SIZE;
options.max_macs = PEER_DEFAULT_MAX_MACS;
options.max_groups = PEER_DEFAULT_MAX_GROUPS;
options.igmp_group_membership_interval = DEFAULT_IGMP_GROUP_MEMBERSHIP_INTERVAL;
options.igmp_last_member_query_time = DEFAULT_IGMP_LAST_MEMBER_QUERY_TIME;
options.allow_peer_talk_without_ssl = 0;
options.max_peers = DEFAULT_MAX_PEERS;
int have_fragmentation_latency = 0;
int i;
for (i = 1; i < argc; i++) {
char *arg = argv[i];
if (!strcmp(arg, "--help")) {
options.help = 1;
}
else if (!strcmp(arg, "--version")) {
options.version = 1;
}
else if (!strcmp(arg, "--logger")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
char *arg2 = argv[i + 1];
if (!strcmp(arg2, "stdout")) {
options.logger = LOGGER_STDOUT;
}
#ifndef BADVPN_USE_WINAPI
else if (!strcmp(arg2, "syslog")) {
options.logger = LOGGER_SYSLOG;
}
#endif
else {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
#ifndef BADVPN_USE_WINAPI
else if (!strcmp(arg, "--syslog-facility")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.logger_syslog_facility = argv[i + 1];
i++;
}
else if (!strcmp(arg, "--syslog-ident")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.logger_syslog_ident = argv[i + 1];
i++;
}
#endif
else if (!strcmp(arg, "--loglevel")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.loglevel = parse_loglevel(argv[i + 1])) < 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--channel-loglevel")) {
if (2 >= argc - i) {
fprintf(stderr, "%s: requires two arguments\n", arg);
return 0;
}
int channel = BLogGlobal_GetChannelByName(argv[i + 1]);
if (channel < 0) {
fprintf(stderr, "%s: wrong channel argument\n", arg);
return 0;
}
int loglevel = parse_loglevel(argv[i + 2]);
if (loglevel < 0) {
fprintf(stderr, "%s: wrong loglevel argument\n", arg);
return 0;
}
options.loglevels[channel] = loglevel;
i += 2;
}
else if (!strcmp(arg, "--threads")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.threads = atoi(argv[i + 1]);
i++;
}
else if (!strcmp(arg, "--use-threads-for-ssl-handshake")) {
options.use_threads_for_ssl_handshake = 1;
}
else if (!strcmp(arg, "--use-threads-for-ssl-data")) {
options.use_threads_for_ssl_data = 1;
}
else if (!strcmp(arg, "--ssl")) {
options.ssl = 1;
}
else if (!strcmp(arg, "--nssdb")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.nssdb = argv[i + 1];
i++;
}
else if (!strcmp(arg, "--client-cert-name")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.client_cert_name = argv[i + 1];
i++;
}
else if (!strcmp(arg, "--server-name")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.server_name = argv[i + 1];
i++;
}
else if (!strcmp(arg, "--server-addr")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.server_addr = argv[i + 1];
i++;
}
else if (!strcmp(arg, "--tapdev")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.tapdev = argv[i + 1];
i++;
}
else if (!strcmp(arg, "--scope")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if (options.num_scopes == MAX_SCOPES) {
fprintf(stderr, "%s: too many\n", arg);
return 0;
}
options.scopes[options.num_scopes] = argv[i + 1];
options.num_scopes++;
i++;
}
else if (!strcmp(arg, "--bind-addr")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if (options.num_bind_addrs == MAX_BIND_ADDRS) {
fprintf(stderr, "%s: too many\n", arg);
return 0;
}
struct bind_addr_option *addr = &options.bind_addrs[options.num_bind_addrs];
addr->addr = argv[i + 1];
addr->num_ports = -1;
addr->num_ext_addrs = 0;
options.num_bind_addrs++;
i++;
}
else if (!strcmp(arg, "--num-ports")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if (options.num_bind_addrs == 0) {
fprintf(stderr, "%s: must folow --bind-addr\n", arg);
return 0;
}
struct bind_addr_option *addr = &options.bind_addrs[options.num_bind_addrs - 1];
if ((addr->num_ports = atoi(argv[i + 1])) < 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--ext-addr")) {
if (2 >= argc - i) {
fprintf(stderr, "%s: requires two arguments\n", arg);
return 0;
}
if (options.num_bind_addrs == 0) {
fprintf(stderr, "%s: must folow --bind-addr\n", arg);
return 0;
}
struct bind_addr_option *addr = &options.bind_addrs[options.num_bind_addrs - 1];
if (addr->num_ext_addrs == MAX_EXT_ADDRS) {
fprintf(stderr, "%s: too many\n", arg);
return 0;
}
struct ext_addr_option *eaddr = &addr->ext_addrs[addr->num_ext_addrs];
eaddr->addr = argv[i + 1];
eaddr->scope = argv[i + 2];
addr->num_ext_addrs++;
i += 2;
}
else if (!strcmp(arg, "--transport-mode")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
char *arg2 = argv[i + 1];
if (!strcmp(arg2, "udp")) {
options.transport_mode = TRANSPORT_MODE_UDP;
}
else if (!strcmp(arg2, "tcp")) {
options.transport_mode = TRANSPORT_MODE_TCP;
}
else {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--encryption-mode")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
char *arg2 = argv[i + 1];
if (!strcmp(arg2, "none")) {
options.encryption_mode = SPPROTO_ENCRYPTION_MODE_NONE;
}
else if (!strcmp(arg2, "blowfish")) {
options.encryption_mode = BENCRYPTION_CIPHER_BLOWFISH;
}
else if (!strcmp(arg2, "aes")) {
options.encryption_mode = BENCRYPTION_CIPHER_AES;
}
else {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--hash-mode")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
char *arg2 = argv[i + 1];
if (!strcmp(arg2, "none")) {
options.hash_mode = SPPROTO_HASH_MODE_NONE;
}
else if (!strcmp(arg2, "md5")) {
options.hash_mode = BHASH_TYPE_MD5;
}
else if (!strcmp(arg2, "sha1")) {
options.hash_mode = BHASH_TYPE_SHA1;
}
else {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--otp")) {
if (3 >= argc - i) {
fprintf(stderr, "%s: requires three arguments\n", arg);
return 0;
}
char *otp_mode = argv[i + 1];
char *otp_num = argv[i + 2];
char *otp_num_warn = argv[i + 3];
if (!strcmp(otp_mode, "blowfish")) {
options.otp_mode = BENCRYPTION_CIPHER_BLOWFISH;
}
else if (!strcmp(otp_mode, "aes")) {
options.otp_mode = BENCRYPTION_CIPHER_AES;
}
else {
fprintf(stderr, "%s: wrong mode\n", arg);
return 0;
}
if ((options.otp_num = atoi(otp_num)) <= 0) {
fprintf(stderr, "%s: wrong num\n", arg);
return 0;
}
options.otp_num_warn = atoi(otp_num_warn);
if (options.otp_num_warn <= 0 || options.otp_num_warn > options.otp_num) {
fprintf(stderr, "%s: wrong num warn\n", arg);
return 0;
}
i += 3;
}
else if (!strcmp(arg, "--fragmentation-latency")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
options.fragmentation_latency = atoi(argv[i + 1]);
have_fragmentation_latency = 1;
i++;
}
else if (!strcmp(arg, "--peer-ssl")) {
options.peer_ssl = 1;
}
else if (!strcmp(arg, "--peer-tcp-socket-sndbuf")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.peer_tcp_socket_sndbuf = atoi(argv[i + 1])) < 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--send-buffer-size")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.send_buffer_size = atoi(argv[i + 1])) <= 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--send-buffer-relay-size")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.send_buffer_relay_size = atoi(argv[i + 1])) <= 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--max-macs")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.max_macs = atoi(argv[i + 1])) <= 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--max-groups")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.max_groups = atoi(argv[i + 1])) <= 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--igmp-group-membership-interval")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.igmp_group_membership_interval = atoi(argv[i + 1])) <= 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--igmp-last-member-query-time")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.igmp_last_member_query_time = atoi(argv[i + 1])) <= 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--max-peers")) {
if (1 >= argc - i) {
fprintf(stderr, "%s: requires an argument\n", arg);
return 0;
}
if ((options.max_peers = atoi(argv[i + 1])) <= 0) {
fprintf(stderr, "%s: wrong argument\n", arg);
return 0;
}
i++;
}
else if (!strcmp(arg, "--allow-peer-talk-without-ssl")) {
options.allow_peer_talk_without_ssl = 1;
}
else {
fprintf(stderr, "unknown option: %s\n", arg);
return 0;
}
}
if (options.help || options.version) {
return 1;
}
if (options.ssl != !!options.nssdb) {
fprintf(stderr, "False: --ssl <=> --nssdb\n");
return 0;
}
if (options.ssl != !!options.client_cert_name) {
fprintf(stderr, "False: --ssl <=> --client-cert-name\n");
return 0;
}
if (!options.server_addr) {
fprintf(stderr, "False: --server-addr\n");
return 0;
}
if (options.transport_mode < 0) {
fprintf(stderr, "False: --transport-mode\n");
return 0;
}
if ((options.transport_mode == TRANSPORT_MODE_UDP) != (options.encryption_mode >= 0)) {
fprintf(stderr, "False: UDP <=> --encryption-mode\n");
return 0;
}
if ((options.transport_mode == TRANSPORT_MODE_UDP) != (options.hash_mode >= 0)) {
fprintf(stderr, "False: UDP <=> --hash-mode\n");
return 0;
}
if (!(!(options.otp_mode != SPPROTO_OTP_MODE_NONE) || (options.transport_mode == TRANSPORT_MODE_UDP))) {
fprintf(stderr, "False: --otp => UDP\n");
return 0;
}
if (!(!have_fragmentation_latency || (options.transport_mode == TRANSPORT_MODE_UDP))) {
fprintf(stderr, "False: --fragmentation-latency => UDP\n");
return 0;
}
if (!(!options.peer_ssl || (options.ssl && options.transport_mode == TRANSPORT_MODE_TCP))) {
fprintf(stderr, "False: --peer-ssl => (--ssl && TCP)\n");
return 0;
}
if (!(!(options.peer_tcp_socket_sndbuf >= 0) || options.transport_mode == TRANSPORT_MODE_TCP)) {
fprintf(stderr, "False: --peer-tcp-socket-sndbuf => TCP\n");
return 0;
}
return 1;
}
int process_arguments (void)
{
// resolve server address
ASSERT(options.server_addr)
if (!BAddr_Parse(&server_addr, options.server_addr, server_name, sizeof(server_name))) {
BLog(BLOG_ERROR, "server addr: BAddr_Parse failed");
return 0;
}
// override server name if requested
if (options.server_name) {
if (strlen(options.server_name) >= sizeof(server_name)) {
BLog(BLOG_ERROR, "server name: too long");
return 0;
}
strcpy(server_name, options.server_name);
}
// resolve bind addresses and external addresses
num_bind_addrs = 0;
for (int i = 0; i < options.num_bind_addrs; i++) {
struct bind_addr_option *addr = &options.bind_addrs[i];
struct bind_addr *out = &bind_addrs[num_bind_addrs];
// read addr
if (!BAddr_Parse(&out->addr, addr->addr, NULL, 0)) {
BLog(BLOG_ERROR, "bind addr: BAddr_Parse failed");
return 0;
}
// read num ports
if (options.transport_mode == TRANSPORT_MODE_UDP) {
if (addr->num_ports < 0) {
BLog(BLOG_ERROR, "bind addr: num ports missing");
return 0;
}
out->num_ports = addr->num_ports;
}
else if (addr->num_ports >= 0) {
BLog(BLOG_ERROR, "bind addr: num ports given, but not using UDP");
return 0;
}
// read ext addrs
out->num_ext_addrs = 0;
for (int j = 0; j < addr->num_ext_addrs; j++) {
struct ext_addr_option *eaddr = &addr->ext_addrs[j];
struct ext_addr *eout = &out->ext_addrs[out->num_ext_addrs];
// read addr
if (string_begins_with(eaddr->addr, "{server_reported}:")) {
char *colon = strstr(eaddr->addr, ":");
if ((eout->server_reported_port = atoi(colon + 1)) < 0) {
BLog(BLOG_ERROR, "ext addr: wrong port");
return 0;
}
} else {
eout->server_reported_port = -1;
if (!BAddr_Parse(&eout->addr, eaddr->addr, NULL, 0)) {
BLog(BLOG_ERROR, "ext addr: BAddr_Parse failed");
return 0;
}
if (!addr_supported(eout->addr)) {
BLog(BLOG_ERROR, "ext addr: addr_supported failed");
return 0;
}
}
// read scope
if (strlen(eaddr->scope) >= sizeof(eout->scope)) {
BLog(BLOG_ERROR, "ext addr: too long");
return 0;
}
strcpy(eout->scope, eaddr->scope);
out->num_ext_addrs++;
}
num_bind_addrs++;
}
// initialize SPProto parameters
if (options.transport_mode == TRANSPORT_MODE_UDP) {
sp_params.encryption_mode = options.encryption_mode;
sp_params.hash_mode = options.hash_mode;
sp_params.otp_mode = options.otp_mode;
if (options.otp_mode > 0) {
sp_params.otp_num = options.otp_num;
}
}
return 1;
}
int ssl_flags (void)
{
int flags = 0;
if (options.use_threads_for_ssl_handshake) {
flags |= BSSLCONNECTION_FLAG_THREADWORK_HANDSHAKE;
}
if (options.use_threads_for_ssl_data) {
flags |= BSSLCONNECTION_FLAG_THREADWORK_IO;
}
return flags;
}
void signal_handler (void *unused)
{
BLog(BLOG_NOTICE, "termination requested");
terminate();
}
void peer_add (peerid_t id, int flags, const uint8_t *cert, int cert_len)
{
ASSERT(server_ready)
ASSERT(num_peers < options.max_peers)
ASSERT(!find_peer_by_id(id))
ASSERT(id != my_id)
ASSERT(cert_len >= 0)
ASSERT(cert_len <= SCID_NEWCLIENT_MAX_CERT_LEN)
// allocate structure
struct peer_data *peer = (struct peer_data *)malloc(sizeof(*peer));
if (!peer) {
BLog(BLOG_ERROR, "peer %d: failed to allocate memory", (int)id);
goto fail0;
}
// remember id
peer->id = id;
// remember flags
peer->flags = flags;
// set no common name
peer->common_name = NULL;
if (options.ssl) {
// remember certificate
memcpy(peer->cert, cert, cert_len);
peer->cert_len = cert_len;
// make sure that CERT_DecodeCertFromPackage will interpretet the input as raw DER and not base64,
// in which case following workaroud wouldn't help
if (!(cert_len > 0 && (cert[0] & 0x1f) == 0x10)) {
peer_log(peer, BLOG_ERROR, "certificate does not look like DER");
goto fail1;
}
// copy the certificate and append it a good load of zero bytes,
// hopefully preventing the crappy CERT_DecodeCertFromPackage from crashing
// by reading past the of its input
uint8_t *certbuf = (uint8_t *)malloc(cert_len + 100);
if (!certbuf) {
peer_log(peer, BLOG_ERROR, "malloc failed");
goto fail1;
}
memcpy(certbuf, cert, cert_len);
memset(certbuf + cert_len, 0, 100);
// decode certificate, so we can extract the common name
CERTCertificate *nsscert = CERT_DecodeCertFromPackage((char *)certbuf, cert_len);
if (!nsscert) {
peer_log(peer, BLOG_ERROR, "CERT_DecodeCertFromPackage failed (%d)", PORT_GetError());
free(certbuf);
goto fail1;
}
free(certbuf);
// remember common name
if (!(peer->common_name = CERT_GetCommonName(&nsscert->subject))) {
peer_log(peer, BLOG_ERROR, "CERT_GetCommonName failed");
CERT_DestroyCertificate(nsscert);
goto fail1;
}
CERT_DestroyCertificate(nsscert);
}
// init and set init job (must be before initing server flow so we can send)
BPending_Init(&peer->job_init, BReactor_PendingGroup(&ss), (BPending_handler)peer_job_init, peer);
BPending_Set(&peer->job_init);
// init server flow
if (!(peer->server_flow = server_flow_init())) {
peer_log(peer, BLOG_ERROR, "server_flow_init failed");
goto fail2;
}
if ((peer->flags & SCID_NEWCLIENT_FLAG_SSL) && !options.ssl) {
peer_log(peer, BLOG_ERROR, "peer requires talking with SSL, but we're not using SSL!?");
goto fail3;
}
if (options.ssl && !(peer->flags & SCID_NEWCLIENT_FLAG_SSL) && !options.allow_peer_talk_without_ssl) {
peer_log(peer, BLOG_ERROR, "peer requires talking without SSL, but we don't allow that");
goto fail3;
}
// choose chat SSL mode
int chat_ssl_mode = PEERCHAT_SSL_NONE;
if ((peer->flags & SCID_NEWCLIENT_FLAG_SSL)) {
chat_ssl_mode = (peer_am_master(peer) ? PEERCHAT_SSL_SERVER : PEERCHAT_SSL_CLIENT);
}
// init chat
if (!PeerChat_Init(&peer->chat, peer->id, chat_ssl_mode, ssl_flags(), client_cert, client_key, peer->cert, peer->cert_len, BReactor_PendingGroup(&ss), &twd, peer,
(BLog_logfunc)peer_logfunc,
(PeerChat_handler_error)peer_chat_handler_error,
(PeerChat_handler_message)peer_chat_handler_message
)) {
peer_log(peer, BLOG_ERROR, "PeerChat_Init failed");
goto fail3;
}
// set no message
peer->chat_send_msg_len = -1;
// connect server flow to chat
server_flow_connect(peer->server_flow, PeerChat_GetSendOutput(&peer->chat));
// set have chat
peer->have_chat = 1;
// set have no resetpeer
peer->have_resetpeer = 0;
// init local flow
if (!DataProtoFlow_Init(&peer->local_dpflow, &device_dpsource, my_id, peer->id, options.send_buffer_size, -1, NULL, NULL)) {
peer_log(peer, BLOG_ERROR, "DataProtoFlow_Init failed");
goto fail4;
}
// init frame decider peer
if (!FrameDeciderPeer_Init(&peer->decider_peer, &frame_decider, peer, (BLog_logfunc)peer_logfunc)) {
peer_log(peer, BLOG_ERROR, "FrameDeciderPeer_Init failed");
goto fail5;
}
// init receive peer
DPReceivePeer_Init(&peer->receive_peer, &device_output_dprd, peer->id, &peer->decider_peer, !!(peer->flags & SCID_NEWCLIENT_FLAG_RELAY_CLIENT));
// have no link
peer->have_link = 0;
// have no relaying
peer->relaying_peer = NULL;
// not waiting for relay
peer->waiting_relay = 0;
// init reset timer
BTimer_Init(&peer->reset_timer, PEER_RETRY_TIME, (BTimer_handler)peer_reset_timer_handler, peer);
// is not relay server
peer->is_relay = 0;
// init binding
peer->binding = 0;
// add to peers list
LinkedList1_Append(&peers, &peer->list_node);
num_peers++;
switch (chat_ssl_mode) {
case PEERCHAT_SSL_NONE:
peer_log(peer, BLOG_INFO, "initialized; talking to peer in plaintext mode");
break;
case PEERCHAT_SSL_CLIENT:
peer_log(peer, BLOG_INFO, "initialized; talking to peer in SSL client mode");
break;
case PEERCHAT_SSL_SERVER:
peer_log(peer, BLOG_INFO, "initialized; talking to peer in SSL server mode");
break;
}
return;
fail5:
DataProtoFlow_Free(&peer->local_dpflow);
fail4:
server_flow_disconnect(peer->server_flow);
PeerChat_Free(&peer->chat);
fail3:
server_flow_free(peer->server_flow);
fail2:
BPending_Free(&peer->job_init);
if (peer->common_name) {
PORT_Free(peer->common_name);
}
fail1:
free(peer);
fail0:
return;
}
void peer_remove (struct peer_data *peer, int exiting)
{
peer_log(peer, BLOG_INFO, "removing");
// cleanup connections
peer_cleanup_connections(peer);
ASSERT(!peer->have_link)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->waiting_relay)
ASSERT(!peer->is_relay)
// remove from peers list
LinkedList1_Remove(&peers, &peer->list_node);
num_peers--;
// free reset timer
BReactor_RemoveTimer(&ss, &peer->reset_timer);
// free receive peer
DPReceivePeer_Free(&peer->receive_peer);
// free frame decider
FrameDeciderPeer_Free(&peer->decider_peer);
// free local flow
DataProtoFlow_Free(&peer->local_dpflow);
// free chat
if (peer->have_chat) {
peer_free_chat(peer);
}
// free resetpeer
if (peer->have_resetpeer) {
// disconnect resetpeer source from server flow
server_flow_disconnect(peer->server_flow);
// free resetpeer source
SinglePacketSource_Free(&peer->resetpeer_source);
}
// free/die server flow
if (exiting || !PacketPassFairQueueFlow_IsBusy(&peer->server_flow->qflow)) {
server_flow_free(peer->server_flow);
} else {
server_flow_die(peer->server_flow);
}
// free jobs
BPending_Free(&peer->job_init);
// free common name
if (peer->common_name) {
PORT_Free(peer->common_name);
}
// free peer structure
free(peer);
}
void peer_logfunc (struct peer_data *peer)
{
BLog_Append("peer %d", (int)peer->id);
if (peer->common_name) {
BLog_Append(" (%s)", peer->common_name);
}
BLog_Append(": ");
}
void peer_log (struct peer_data *peer, int level, const char *fmt, ...)
{
va_list vl;
va_start(vl, fmt);
BLog_LogViaFuncVarArg((BLog_logfunc)peer_logfunc, peer, BLOG_CURRENT_CHANNEL, level, fmt, vl);
va_end(vl);
}
int peer_am_master (struct peer_data *peer)
{
return (my_id > peer->id);
}
void peer_free_chat (struct peer_data *peer)
{
ASSERT(peer->have_chat)
// disconnect chat from server flow
server_flow_disconnect(peer->server_flow);
// free chat
PeerChat_Free(&peer->chat);
// set have no chat
peer->have_chat = 0;
}
int peer_init_link (struct peer_data *peer)
{
ASSERT(!peer->have_link)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->waiting_relay)
ASSERT(!peer->is_relay)
// init receive receiver
DPReceiveReceiver_Init(&peer->receive_receiver, &peer->receive_peer);
PacketPassInterface *recv_if = DPReceiveReceiver_GetInput(&peer->receive_receiver);
// init transport-specific link objects
PacketPassInterface *link_if;
if (options.transport_mode == TRANSPORT_MODE_UDP) {
// init DatagramPeerIO
if (!DatagramPeerIO_Init(
&peer->pio.udp.pio, &ss, data_mtu, CLIENT_UDP_MTU, sp_params,
options.fragmentation_latency, PEER_UDP_ASSEMBLER_NUM_FRAMES, recv_if,
options.otp_num_warn, &twd, peer,
(BLog_logfunc)peer_logfunc,
(DatagramPeerIO_handler_error)peer_udp_pio_handler_error,
(DatagramPeerIO_handler_otp_warning)peer_udp_pio_handler_seed_warning,
(DatagramPeerIO_handler_otp_ready)peer_udp_pio_handler_seed_ready
)) {
peer_log(peer, BLOG_ERROR, "DatagramPeerIO_Init failed");
goto fail1;
}
if (SPPROTO_HAVE_OTP(sp_params)) {
// init send seed state
peer->pio.udp.sendseed_nextid = 0;
peer->pio.udp.sendseed_sent = 0;
// init send seed job
BPending_Init(&peer->pio.udp.job_send_seed, BReactor_PendingGroup(&ss), (BPending_handler)peer_job_send_seed, peer);
}
link_if = DatagramPeerIO_GetSendInput(&peer->pio.udp.pio);
} else {
// init StreamPeerIO
if (!StreamPeerIO_Init(
&peer->pio.tcp.pio, &ss, &twd, options.peer_ssl, ssl_flags(),
(options.peer_ssl ? peer->cert : NULL),
(options.peer_ssl ? peer->cert_len : -1),
data_mtu,
(options.peer_tcp_socket_sndbuf >= 0 ? options.peer_tcp_socket_sndbuf : PEER_DEFAULT_TCP_SOCKET_SNDBUF),
recv_if,
(BLog_logfunc)peer_logfunc,
(StreamPeerIO_handler_error)peer_tcp_pio_handler_error, peer
)) {
peer_log(peer, BLOG_ERROR, "StreamPeerIO_Init failed");
goto fail1;
}
link_if = StreamPeerIO_GetSendInput(&peer->pio.tcp.pio);
}
// init sending
if (!DataProtoSink_Init(&peer->send_dp, &ss, link_if, PEER_KEEPALIVE_INTERVAL, PEER_KEEPALIVE_RECEIVE_TIMER, (DataProtoSink_handler)peer_dataproto_handler, peer)) {
peer_log(peer, BLOG_ERROR, "DataProto_Init failed");
goto fail2;
}
// attach local flow to our DataProtoSink
DataProtoFlow_Attach(&peer->local_dpflow, &peer->send_dp);
// attach receive peer to our DataProtoSink
DPReceivePeer_AttachSink(&peer->receive_peer, &peer->send_dp);
// set have link
peer->have_link = 1;
return 1;
fail2:
if (options.transport_mode == TRANSPORT_MODE_UDP) {
if (SPPROTO_HAVE_OTP(sp_params)) {
BPending_Free(&peer->pio.udp.job_send_seed);
}
DatagramPeerIO_Free(&peer->pio.udp.pio);
} else {
StreamPeerIO_Free(&peer->pio.tcp.pio);
}
fail1:
DPReceiveReceiver_Free(&peer->receive_receiver);
return 0;
}
void peer_free_link (struct peer_data *peer)
{
ASSERT(peer->have_link)
ASSERT(!peer->is_relay)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->waiting_relay)
// detach receive peer from our DataProtoSink
DPReceivePeer_DetachSink(&peer->receive_peer);
// detach local flow from our DataProtoSink
DataProtoFlow_Detach(&peer->local_dpflow);
// free sending
DataProtoSink_Free(&peer->send_dp);
// free transport-specific link objects
if (options.transport_mode == TRANSPORT_MODE_UDP) {
if (SPPROTO_HAVE_OTP(sp_params)) {
BPending_Free(&peer->pio.udp.job_send_seed);
}
DatagramPeerIO_Free(&peer->pio.udp.pio);
} else {
StreamPeerIO_Free(&peer->pio.tcp.pio);
}
// free receive receiver
DPReceiveReceiver_Free(&peer->receive_receiver);
// set have no link
peer->have_link = 0;
}
void peer_cleanup_connections (struct peer_data *peer)
{
if (peer->have_link) {
if (peer->is_relay) {
peer_disable_relay_provider(peer);
}
peer_free_link(peer);
}
else if (peer->relaying_peer) {
peer_free_relaying(peer);
}
else if (peer->waiting_relay) {
peer_unregister_need_relay(peer);
}
ASSERT(!peer->have_link)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->waiting_relay)
ASSERT(!peer->is_relay)
}
void peer_enable_relay_provider (struct peer_data *peer)
{
ASSERT(peer->have_link)
ASSERT(!peer->is_relay)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->waiting_relay)
// add to relays list
LinkedList1_Append(&relays, &peer->relay_list_node);
// init users list
LinkedList1_Init(&peer->relay_users);
// set is relay
peer->is_relay = 1;
// assign relays
assign_relays();
}
void peer_disable_relay_provider (struct peer_data *peer)
{
ASSERT(peer->is_relay)
ASSERT(peer->have_link)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->waiting_relay)
// disconnect relay users
LinkedList1Node *list_node;
while (list_node = LinkedList1_GetFirst(&peer->relay_users)) {
struct peer_data *relay_user = UPPER_OBJECT(list_node, struct peer_data, relaying_list_node);
ASSERT(relay_user->relaying_peer == peer)
// disconnect relay user
peer_free_relaying(relay_user);
// add it to need relay list
peer_register_need_relay(relay_user);
}
// remove from relays list
LinkedList1_Remove(&relays, &peer->relay_list_node);
// set is not relay
peer->is_relay = 0;
// assign relays
assign_relays();
}
void peer_install_relaying (struct peer_data *peer, struct peer_data *relay)
{
ASSERT(!peer->relaying_peer)
ASSERT(!peer->have_link)
ASSERT(!peer->waiting_relay)
ASSERT(relay->is_relay)
ASSERT(!peer->is_relay)
ASSERT(relay->have_link)
peer_log(peer, BLOG_INFO, "installing relaying through %d", (int)relay->id);
// add to relay's users list
LinkedList1_Append(&relay->relay_users, &peer->relaying_list_node);
// attach local flow to relay
DataProtoFlow_Attach(&peer->local_dpflow, &relay->send_dp);
// set relaying
peer->relaying_peer = relay;
}
void peer_free_relaying (struct peer_data *peer)
{
ASSERT(peer->relaying_peer)
ASSERT(!peer->have_link)
ASSERT(!peer->waiting_relay)
struct peer_data *relay = peer->relaying_peer;
ASSERT(relay->is_relay)
ASSERT(relay->have_link)
peer_log(peer, BLOG_INFO, "uninstalling relaying through %d", (int)relay->id);
// detach local flow from relay
DataProtoFlow_Detach(&peer->local_dpflow);
// remove from relay's users list
LinkedList1_Remove(&relay->relay_users, &peer->relaying_list_node);
// set not relaying
peer->relaying_peer = NULL;
}
void peer_need_relay (struct peer_data *peer)
{
ASSERT(!peer->is_relay)
if (peer->waiting_relay) {
// already waiting for relay, do nothing
return;
}
if (peer->have_link) {
peer_free_link(peer);
}
else if (peer->relaying_peer) {
peer_free_relaying(peer);
}
// register the peer as needing a relay
peer_register_need_relay(peer);
// assign relays
assign_relays();
}
void peer_register_need_relay (struct peer_data *peer)
{
ASSERT(!peer->waiting_relay)
ASSERT(!peer->have_link)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->is_relay)
// add to need relay list
LinkedList1_Append(&waiting_relay_peers, &peer->waiting_relay_list_node);
// set waiting relay
peer->waiting_relay = 1;
}
void peer_unregister_need_relay (struct peer_data *peer)
{
ASSERT(peer->waiting_relay)
ASSERT(!peer->have_link)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->is_relay)
// remove from need relay list
LinkedList1_Remove(&waiting_relay_peers, &peer->waiting_relay_list_node);
// set not waiting relay
peer->waiting_relay = 0;
}
void peer_reset (struct peer_data *peer)
{
peer_log(peer, BLOG_NOTICE, "resetting");
// cleanup connections
peer_cleanup_connections(peer);
if (peer_am_master(peer)) {
// if we're the master, schedule retry
BReactor_SetTimer(&ss, &peer->reset_timer);
} else {
// if we're the slave, report to master
peer_send_simple(peer, MSGID_YOURETRY);
}
}
void peer_resetpeer (struct peer_data *peer)
{
ASSERT(peer->have_chat)
ASSERT(!peer->have_resetpeer)
// free chat
peer_free_chat(peer);
// build resetpeer packet
struct packetproto_header pp_header;
struct sc_header sc_header;
struct sc_client_resetpeer sc_resetpeer;
pp_header.len = htol16(sizeof(struct sc_header) + sizeof(struct sc_client_resetpeer));
sc_header.type = htol8(SCID_RESETPEER);
sc_resetpeer.clientid = htol16(peer->id);
memcpy(peer->resetpeer_packet, &pp_header, sizeof(pp_header));
memcpy(peer->resetpeer_packet + sizeof(pp_header), &sc_header, sizeof(sc_header));
memcpy(peer->resetpeer_packet + sizeof(pp_header) + sizeof(sc_header), &sc_resetpeer, sizeof(sc_resetpeer));
// init resetpeer sourse
SinglePacketSource_Init(&peer->resetpeer_source, peer->resetpeer_packet, sizeof(peer->resetpeer_packet), BReactor_PendingGroup(&ss));
// connect server flow to resetpeer source
server_flow_connect(peer->server_flow, SinglePacketSource_GetOutput(&peer->resetpeer_source));
// set have resetpeer
peer->have_resetpeer = 1;
}
void peer_chat_handler_error (struct peer_data *peer)
{
ASSERT(peer->have_chat)
ASSERT(!peer->have_resetpeer)
peer_log(peer, BLOG_ERROR, "chat error, sending resetpeer");
peer_resetpeer(peer);
}
void peer_chat_handler_message (struct peer_data *peer, uint8_t *data, int data_len)
{
ASSERT(peer->have_chat)
ASSERT(data_len >= 0)
ASSERT(data_len <= SC_MAX_MSGLEN)
// parse message
msgParser parser;
if (!msgParser_Init(&parser, data, data_len)) {
peer_log(peer, BLOG_NOTICE, "msg: failed to parse");
return;
}
// read message
uint16_t type = 0; // to remove warning
ASSERT_EXECUTE(msgParser_Gettype(&parser, &type))
uint8_t *payload = NULL; // to remove warning
int payload_len = 0; // to remove warning
ASSERT_EXECUTE(msgParser_Getpayload(&parser, &payload, &payload_len))
// dispatch according to message type
switch (type) {
case MSGID_YOUCONNECT:
peer_msg_youconnect(peer, payload, payload_len);
return;
case MSGID_CANNOTCONNECT:
peer_msg_cannotconnect(peer, payload, payload_len);
return;
case MSGID_CANNOTBIND:
peer_msg_cannotbind(peer, payload, payload_len);
return;
case MSGID_YOURETRY:
peer_msg_youretry(peer, payload, payload_len);
return;
case MSGID_SEED:
peer_msg_seed(peer, payload, payload_len);
return;
case MSGID_CONFIRMSEED:
peer_msg_confirmseed(peer, payload, payload_len);
return;
default:
BLog(BLOG_NOTICE, "msg: unknown type");
return;
}
}
void peer_msg_youconnect (struct peer_data *peer, uint8_t *data, int data_len)
{
// init parser
msg_youconnectParser parser;
if (!msg_youconnectParser_Init(&parser, data, data_len)) {
peer_log(peer, BLOG_WARNING, "msg_youconnect: failed to parse");
return;
}
// try addresses
BAddr addr;
while (1) {
// get address message
uint8_t *addrmsg_data;
int addrmsg_len;
if (!msg_youconnectParser_Getaddr(&parser, &addrmsg_data, &addrmsg_len)) {
peer_log(peer, BLOG_NOTICE, "msg_youconnect: no usable addresses");
peer_send_simple(peer, MSGID_CANNOTCONNECT);
return;
}
// parse address message
msg_youconnect_addrParser aparser;
if (!msg_youconnect_addrParser_Init(&aparser, addrmsg_data, addrmsg_len)) {
peer_log(peer, BLOG_WARNING, "msg_youconnect: failed to parse address message");
return;
}
// check if the address scope is known
uint8_t *name_data = NULL; // to remove warning
int name_len = 0; // to remove warning
ASSERT_EXECUTE(msg_youconnect_addrParser_Getname(&aparser, &name_data, &name_len))
char *name;
if (!(name = address_scope_known(name_data, name_len))) {
continue;
}
// read address
uint8_t *addr_data = NULL; // to remove warning
int addr_len = 0; // to remove warning
ASSERT_EXECUTE(msg_youconnect_addrParser_Getaddr(&aparser, &addr_data, &addr_len))
if (!addr_read(addr_data, addr_len, &addr)) {
peer_log(peer, BLOG_WARNING, "msg_youconnect: failed to read address");
continue;
}
peer_log(peer, BLOG_NOTICE, "msg_youconnect: using address in scope '%s'", name);
break;
}
// discard further addresses
msg_youconnectParser_Forwardaddr(&parser);
uint8_t *key = NULL;
uint64_t password = 0;
// read additonal parameters
if (options.transport_mode == TRANSPORT_MODE_UDP) {
if (SPPROTO_HAVE_ENCRYPTION(sp_params)) {
int key_len;
if (!msg_youconnectParser_Getkey(&parser, &key, &key_len)) {
peer_log(peer, BLOG_WARNING, "msg_youconnect: no key");
return;
}
if (key_len != BEncryption_cipher_key_size(sp_params.encryption_mode)) {
peer_log(peer, BLOG_WARNING, "msg_youconnect: wrong key size");
return;
}
}
} else {
if (!msg_youconnectParser_Getpassword(&parser, &password)) {
peer_log(peer, BLOG_WARNING, "msg_youconnect: no password");
return;
}
}
if (!msg_youconnectParser_GotEverything(&parser)) {
peer_log(peer, BLOG_WARNING, "msg_youconnect: stray data");
return;
}
peer_log(peer, BLOG_INFO, "connecting");
peer_connect(peer, addr, key, password);
}
void peer_msg_cannotconnect (struct peer_data *peer, uint8_t *data, int data_len)
{
if (data_len != 0) {
peer_log(peer, BLOG_WARNING, "msg_cannotconnect: invalid length");
return;
}
if (!peer->binding) {
peer_log(peer, BLOG_WARNING, "msg_cannotconnect: not binding");
return;
}
peer_log(peer, BLOG_INFO, "peer could not connect");
// continue trying bind addresses
peer_bind(peer);
return;
}
void peer_msg_cannotbind (struct peer_data *peer, uint8_t *data, int data_len)
{
if (data_len != 0) {
peer_log(peer, BLOG_WARNING, "msg_cannotbind: invalid length");
return;
}
peer_log(peer, BLOG_INFO, "peer cannot bind");
if (!peer_am_master(peer)) {
peer_start_binding(peer);
} else {
if (!peer->is_relay) {
peer_need_relay(peer);
}
}
}
void peer_msg_seed (struct peer_data *peer, uint8_t *data, int data_len)
{
msg_seedParser parser;
if (!msg_seedParser_Init(&parser, data, data_len)) {
peer_log(peer, BLOG_WARNING, "msg_seed: failed to parse");
return;
}
// read message
uint16_t seed_id = 0; // to remove warning
ASSERT_EXECUTE(msg_seedParser_Getseed_id(&parser, &seed_id))
uint8_t *key = NULL; // to remove warning
int key_len = 0; // to remove warning
ASSERT_EXECUTE(msg_seedParser_Getkey(&parser, &key, &key_len))
uint8_t *iv = NULL; // to remove warning
int iv_len = 0; // to remove warning
ASSERT_EXECUTE(msg_seedParser_Getiv(&parser, &iv, &iv_len))
if (options.transport_mode != TRANSPORT_MODE_UDP) {
peer_log(peer, BLOG_WARNING, "msg_seed: not in UDP mode");
return;
}
if (!SPPROTO_HAVE_OTP(sp_params)) {
peer_log(peer, BLOG_WARNING, "msg_seed: OTPs disabled");
return;
}
if (key_len != BEncryption_cipher_key_size(sp_params.otp_mode)) {
peer_log(peer, BLOG_WARNING, "msg_seed: wrong key length");
return;
}
if (iv_len != BEncryption_cipher_block_size(sp_params.otp_mode)) {
peer_log(peer, BLOG_WARNING, "msg_seed: wrong IV length");
return;
}
if (!peer->have_link) {
peer_log(peer, BLOG_WARNING, "msg_seed: have no link");
return;
}
peer_log(peer, BLOG_DEBUG, "received OTP receive seed");
// add receive seed
DatagramPeerIO_AddOTPRecvSeed(&peer->pio.udp.pio, seed_id, key, iv);
// remember seed ID so we can confirm it from peer_udp_pio_handler_seed_ready
peer->pio.udp.pending_recvseed_id = seed_id;
}
void peer_msg_confirmseed (struct peer_data *peer, uint8_t *data, int data_len)
{
msg_confirmseedParser parser;
if (!msg_confirmseedParser_Init(&parser, data, data_len)) {
peer_log(peer, BLOG_WARNING, "msg_confirmseed: failed to parse");
return;
}
// read message
uint16_t seed_id = 0; // to remove warning
ASSERT_EXECUTE(msg_confirmseedParser_Getseed_id(&parser, &seed_id))
if (options.transport_mode != TRANSPORT_MODE_UDP) {
peer_log(peer, BLOG_WARNING, "msg_confirmseed: not in UDP mode");
return;
}
if (!SPPROTO_HAVE_OTP(sp_params)) {
peer_log(peer, BLOG_WARNING, "msg_confirmseed: OTPs disabled");
return;
}
if (!peer->have_link) {
peer_log(peer, BLOG_WARNING, "msg_confirmseed: have no link");
return;
}
if (!peer->pio.udp.sendseed_sent) {
peer_log(peer, BLOG_WARNING, "msg_confirmseed: no seed has been sent");
return;
}
if (seed_id != peer->pio.udp.sendseed_sent_id) {
peer_log(peer, BLOG_WARNING, "msg_confirmseed: invalid seed: expecting %d, received %d", (int)peer->pio.udp.sendseed_sent_id, (int)seed_id);
return;
}
peer_log(peer, BLOG_DEBUG, "OTP send seed confirmed");
// no longer waiting for confirmation
peer->pio.udp.sendseed_sent = 0;
// start using the seed
DatagramPeerIO_SetOTPSendSeed(&peer->pio.udp.pio, peer->pio.udp.sendseed_sent_id, peer->pio.udp.sendseed_sent_key, peer->pio.udp.sendseed_sent_iv);
}
void peer_msg_youretry (struct peer_data *peer, uint8_t *data, int data_len)
{
if (data_len != 0) {
peer_log(peer, BLOG_WARNING, "msg_youretry: invalid length");
return;
}
if (!peer_am_master(peer)) {
peer_log(peer, BLOG_WARNING, "msg_youretry: we are not master");
return;
}
peer_log(peer, BLOG_NOTICE, "requests reset");
peer_reset(peer);
}
void peer_udp_pio_handler_seed_warning (struct peer_data *peer)
{
ASSERT(options.transport_mode == TRANSPORT_MODE_UDP)
ASSERT(SPPROTO_HAVE_OTP(sp_params))
ASSERT(peer->have_link)
// generate and send a new seed
if (!peer->pio.udp.sendseed_sent) {
BPending_Set(&peer->pio.udp.job_send_seed);
}
}
void peer_udp_pio_handler_seed_ready (struct peer_data *peer)
{
ASSERT(options.transport_mode == TRANSPORT_MODE_UDP)
ASSERT(SPPROTO_HAVE_OTP(sp_params))
ASSERT(peer->have_link)
// send confirmation
peer_send_confirmseed(peer, peer->pio.udp.pending_recvseed_id);
}
void peer_udp_pio_handler_error (struct peer_data *peer)
{
ASSERT(options.transport_mode == TRANSPORT_MODE_UDP)
ASSERT(peer->have_link)
peer_log(peer, BLOG_NOTICE, "UDP connection failed");
peer_reset(peer);
return;
}
void peer_tcp_pio_handler_error (struct peer_data *peer)
{
ASSERT(options.transport_mode == TRANSPORT_MODE_TCP)
ASSERT(peer->have_link)
peer_log(peer, BLOG_NOTICE, "TCP connection failed");
peer_reset(peer);
return;
}
void peer_reset_timer_handler (struct peer_data *peer)
{
ASSERT(peer_am_master(peer))
BLog(BLOG_NOTICE, "retry timer expired");
// start setup process
peer_start_binding(peer);
}
void peer_start_binding (struct peer_data *peer)
{
peer->binding = 1;
peer->binding_addrpos = 0;
peer_bind(peer);
}
void peer_bind (struct peer_data *peer)
{
ASSERT(peer->binding)
ASSERT(peer->binding_addrpos >= 0)
ASSERT(peer->binding_addrpos <= num_bind_addrs)
while (peer->binding_addrpos < num_bind_addrs) {
// if there are no external addresses, skip bind address
if (bind_addrs[peer->binding_addrpos].num_ext_addrs == 0) {
peer->binding_addrpos++;
continue;
}
// try to bind
int cont;
peer_bind_one_address(peer, peer->binding_addrpos, &cont);
// increment address counter
peer->binding_addrpos++;
if (!cont) {
return;
}
}
peer_log(peer, BLOG_NOTICE, "no more addresses to bind to");
// no longer binding
peer->binding = 0;
// tell the peer we failed to bind
peer_send_simple(peer, MSGID_CANNOTBIND);
// if we are the slave, setup relaying
if (!peer_am_master(peer)) {
if (!peer->is_relay) {
peer_need_relay(peer);
}
}
}
void peer_bind_one_address (struct peer_data *peer, int addr_index, int *cont)
{
ASSERT(addr_index >= 0)
ASSERT(addr_index < num_bind_addrs)
ASSERT(bind_addrs[addr_index].num_ext_addrs > 0)
// get a fresh link
peer_cleanup_connections(peer);
if (!peer_init_link(peer)) {
peer_log(peer, BLOG_ERROR, "cannot get link");
*cont = 0;
peer_reset(peer);
return;
}
if (options.transport_mode == TRANSPORT_MODE_UDP) {
// get addr
struct bind_addr *addr = &bind_addrs[addr_index];
// try binding to all ports in the range
int port_add;
for (port_add = 0; port_add < addr->num_ports; port_add++) {
BAddr tryaddr = addr->addr;
BAddr_SetPort(&tryaddr, hton16(ntoh16(BAddr_GetPort(&tryaddr)) + port_add));
if (DatagramPeerIO_Bind(&peer->pio.udp.pio, tryaddr)) {
break;
}
}
if (port_add == addr->num_ports) {
BLog(BLOG_NOTICE, "failed to bind to any port");
*cont = 1;
return;
}
uint8_t key[BENCRYPTION_MAX_KEY_SIZE];
// generate and set encryption key
if (SPPROTO_HAVE_ENCRYPTION(sp_params)) {
BRandom_randomize(key, BEncryption_cipher_key_size(sp_params.encryption_mode));
DatagramPeerIO_SetEncryptionKey(&peer->pio.udp.pio, key);
}
// schedule sending OTP seed
if (SPPROTO_HAVE_OTP(sp_params)) {
BPending_Set(&peer->pio.udp.job_send_seed);
}
// send connectinfo
peer_send_conectinfo(peer, addr_index, port_add, key, 0);
} else {
// order StreamPeerIO to listen
uint64_t pass;
StreamPeerIO_Listen(&peer->pio.tcp.pio, &listeners[addr_index], &pass);
// send connectinfo
peer_send_conectinfo(peer, addr_index, 0, NULL, pass);
}
peer_log(peer, BLOG_NOTICE, "bound to address number %d", addr_index);
*cont = 0;
}
void peer_connect (struct peer_data *peer, BAddr addr, uint8_t* encryption_key, uint64_t password)
{
// get a fresh link
peer_cleanup_connections(peer);
if (!peer_init_link(peer)) {
peer_log(peer, BLOG_ERROR, "cannot get link");
peer_reset(peer);
return;
}
if (options.transport_mode == TRANSPORT_MODE_UDP) {
// order DatagramPeerIO to connect
if (!DatagramPeerIO_Connect(&peer->pio.udp.pio, addr)) {
peer_log(peer, BLOG_NOTICE, "DatagramPeerIO_Connect failed");
peer_reset(peer);
return;
}
// set encryption key
if (SPPROTO_HAVE_ENCRYPTION(sp_params)) {
DatagramPeerIO_SetEncryptionKey(&peer->pio.udp.pio, encryption_key);
}
// generate and send a send seed
if (SPPROTO_HAVE_OTP(sp_params)) {
BPending_Set(&peer->pio.udp.job_send_seed);
}
} else {
// order StreamPeerIO to connect
if (!StreamPeerIO_Connect(&peer->pio.tcp.pio, addr, password, client_cert, client_key)) {
peer_log(peer, BLOG_NOTICE, "StreamPeerIO_Connect failed");
peer_reset(peer);
return;
}
}
}
static int peer_start_msg (struct peer_data *peer, void **data, int type, int len)
{
ASSERT(len >= 0)
ASSERT(len <= MSG_MAX_PAYLOAD)
ASSERT(!(len > 0) || data)
ASSERT(peer->chat_send_msg_len == -1)
// make sure we have chat
if (!peer->have_chat) {
peer_log(peer, BLOG_ERROR, "cannot send message, chat is down");
return 0;
}
#ifdef SIMULATE_PEER_OUT_OF_BUFFER
uint8_t x;
BRandom_randomize(&x, sizeof(x));
if (x < SIMULATE_PEER_OUT_OF_BUFFER) {
peer_log(peer, BLOG_ERROR, "simulating out of buffer, sending resetpeer");
peer_resetpeer(peer);
return 0;
}
#endif
// obtain buffer location
uint8_t *packet;
if (!PeerChat_StartMessage(&peer->chat, &packet)) {
peer_log(peer, BLOG_ERROR, "cannot send message, out of buffer, sending resetpeer");
peer_resetpeer(peer);
return 0;
}
// write fields
msgWriter writer;
msgWriter_Init(&writer, packet);
msgWriter_Addtype(&writer, type);
uint8_t *payload_dst = msgWriter_Addpayload(&writer, len);
msgWriter_Finish(&writer);
// set have message
peer->chat_send_msg_len = len;
if (data) {
*data = payload_dst;
}
return 1;
}
static void peer_end_msg (struct peer_data *peer)
{
ASSERT(peer->chat_send_msg_len >= 0)
ASSERT(peer->have_chat)
// submit packet to buffer
PeerChat_EndMessage(&peer->chat, msg_SIZEtype + msg_SIZEpayload(peer->chat_send_msg_len));
// set no message
peer->chat_send_msg_len = -1;
}
void peer_send_simple (struct peer_data *peer, int msgid)
{
if (!peer_start_msg(peer, NULL, msgid, 0)) {
return;
}
peer_end_msg(peer);
}
void peer_send_conectinfo (struct peer_data *peer, int addr_index, int port_adjust, uint8_t *enckey, uint64_t pass)
{
ASSERT(addr_index >= 0)
ASSERT(addr_index < num_bind_addrs)
ASSERT(bind_addrs[addr_index].num_ext_addrs > 0)
// get address
struct bind_addr *bind_addr = &bind_addrs[addr_index];
// remember encryption key size
int key_size = 0; // to remove warning
if (options.transport_mode == TRANSPORT_MODE_UDP && SPPROTO_HAVE_ENCRYPTION(sp_params)) {
key_size = BEncryption_cipher_key_size(sp_params.encryption_mode);
}
// calculate message length ..
int msg_len = 0;
// addresses
for (int i = 0; i < bind_addr->num_ext_addrs; i++) {
int addrmsg_len =
msg_youconnect_addr_SIZEname(strlen(bind_addr->ext_addrs[i].scope)) +
msg_youconnect_addr_SIZEaddr(addr_size(bind_addr->ext_addrs[i].addr));
msg_len += msg_youconnect_SIZEaddr(addrmsg_len);
}
// encryption key
if (options.transport_mode == TRANSPORT_MODE_UDP && SPPROTO_HAVE_ENCRYPTION(sp_params)) {
msg_len += msg_youconnect_SIZEkey(key_size);
}
// password
if (options.transport_mode == TRANSPORT_MODE_TCP) {
msg_len += msg_youconnect_SIZEpassword;
}
// check if it's too big (because of the addresses)
if (msg_len > MSG_MAX_PAYLOAD) {
BLog(BLOG_ERROR, "cannot send too big youconnect message");
return;
}
// start message
uint8_t *msg;
if (!peer_start_msg(peer, (void **)&msg, MSGID_YOUCONNECT, msg_len)) {
return;
}
// init writer
msg_youconnectWriter writer;
msg_youconnectWriter_Init(&writer, msg);
// write addresses
for (int i = 0; i < bind_addr->num_ext_addrs; i++) {
int name_len = strlen(bind_addr->ext_addrs[i].scope);
int addr_len = addr_size(bind_addr->ext_addrs[i].addr);
// get a pointer for writing the address
int addrmsg_len =
msg_youconnect_addr_SIZEname(name_len) +
msg_youconnect_addr_SIZEaddr(addr_len);
uint8_t *addrmsg_dst = msg_youconnectWriter_Addaddr(&writer, addrmsg_len);
// init address writer
msg_youconnect_addrWriter awriter;
msg_youconnect_addrWriter_Init(&awriter, addrmsg_dst);
// write scope
uint8_t *name_dst = msg_youconnect_addrWriter_Addname(&awriter, name_len);
memcpy(name_dst, bind_addr->ext_addrs[i].scope, name_len);
// write address with adjusted port
BAddr addr = bind_addr->ext_addrs[i].addr;
BAddr_SetPort(&addr, hton16(ntoh16(BAddr_GetPort(&addr)) + port_adjust));
uint8_t *addr_dst = msg_youconnect_addrWriter_Addaddr(&awriter, addr_len);
addr_write(addr_dst, addr);
// finish address writer
msg_youconnect_addrWriter_Finish(&awriter);
}
// write encryption key
if (options.transport_mode == TRANSPORT_MODE_UDP && SPPROTO_HAVE_ENCRYPTION(sp_params)) {
uint8_t *key_dst = msg_youconnectWriter_Addkey(&writer, key_size);
memcpy(key_dst, enckey, key_size);
}
// write password
if (options.transport_mode == TRANSPORT_MODE_TCP) {
msg_youconnectWriter_Addpassword(&writer, pass);
}
// finish writer
msg_youconnectWriter_Finish(&writer);
// end message
peer_end_msg(peer);
}
void peer_send_confirmseed (struct peer_data *peer, uint16_t seed_id)
{
ASSERT(options.transport_mode == TRANSPORT_MODE_UDP)
ASSERT(SPPROTO_HAVE_OTP(sp_params))
// send confirmation
int msg_len = msg_confirmseed_SIZEseed_id;
uint8_t *msg;
if (!peer_start_msg(peer, (void **)&msg, MSGID_CONFIRMSEED, msg_len)) {
return;
}
msg_confirmseedWriter writer;
msg_confirmseedWriter_Init(&writer, msg);
msg_confirmseedWriter_Addseed_id(&writer, seed_id);
msg_confirmseedWriter_Finish(&writer);
peer_end_msg(peer);
}
void peer_dataproto_handler (struct peer_data *peer, int up)
{
ASSERT(peer->have_link)
if (up) {
peer_log(peer, BLOG_INFO, "up");
// if it can be a relay provided, enable it
if ((peer->flags & SCID_NEWCLIENT_FLAG_RELAY_SERVER) && !peer->is_relay) {
peer_enable_relay_provider(peer);
}
} else {
peer_log(peer, BLOG_INFO, "down");
// if it is a relay provider, disable it
if (peer->is_relay) {
peer_disable_relay_provider(peer);
}
}
}
struct peer_data * find_peer_by_id (peerid_t id)
{
for (LinkedList1Node *node = LinkedList1_GetFirst(&peers); node; node = LinkedList1Node_Next(node)) {
struct peer_data *peer = UPPER_OBJECT(node, struct peer_data, list_node);
if (peer->id == id) {
return peer;
}
}
return NULL;
}
void device_error_handler (void *unused)
{
BLog(BLOG_ERROR, "device error");
terminate();
}
void device_dpsource_handler (void *unused, const uint8_t *frame, int frame_len)
{
ASSERT(frame_len >= 0)
ASSERT(frame_len <= device_mtu)
// give frame to decider
FrameDecider_AnalyzeAndDecide(&frame_decider, frame, frame_len);
// forward frame to peers
FrameDeciderPeer *decider_peer = FrameDecider_NextDestination(&frame_decider);
while (decider_peer) {
FrameDeciderPeer *next = FrameDecider_NextDestination(&frame_decider);
struct peer_data *peer = UPPER_OBJECT(decider_peer, struct peer_data, decider_peer);
DataProtoFlow_Route(&peer->local_dpflow, !!next);
decider_peer = next;
}
}
void assign_relays (void)
{
LinkedList1Node *list_node;
while (list_node = LinkedList1_GetFirst(&waiting_relay_peers)) {
struct peer_data *peer = UPPER_OBJECT(list_node, struct peer_data, waiting_relay_list_node);
ASSERT(peer->waiting_relay)
ASSERT(!peer->relaying_peer)
ASSERT(!peer->have_link)
// get a relay
LinkedList1Node *list_node2 = LinkedList1_GetFirst(&relays);
if (!list_node2) {
BLog(BLOG_NOTICE, "no relays");
return;
}
struct peer_data *relay = UPPER_OBJECT(list_node2, struct peer_data, relay_list_node);
ASSERT(relay->is_relay)
// no longer waiting for relay
peer_unregister_need_relay(peer);
// install the relay
peer_install_relaying(peer, relay);
}
}
char * address_scope_known (uint8_t *name, int name_len)
{
ASSERT(name_len >= 0)
for (int i = 0; i < options.num_scopes; i++) {
if (name_len == strlen(options.scopes[i]) && !memcmp(name, options.scopes[i], name_len)) {
return options.scopes[i];
}
}
return NULL;
}
void server_handler_error (void *user)
{
BLog(BLOG_ERROR, "server connection failed, exiting");
terminate();
}
void server_handler_ready (void *user, peerid_t param_my_id, uint32_t ext_ip)
{
ASSERT(!server_ready)
// remember our ID
my_id = param_my_id;
// store server reported addresses
for (int i = 0; i < num_bind_addrs; i++) {
struct bind_addr *addr = &bind_addrs[i];
for (int j = 0; j < addr->num_ext_addrs; j++) {
struct ext_addr *eaddr = &addr->ext_addrs[j];
if (eaddr->server_reported_port >= 0) {
if (ext_ip == 0) {
BLog(BLOG_ERROR, "server did not provide our address");
terminate();
return;
}
BAddr_InitIPv4(&eaddr->addr, ext_ip, hton16(eaddr->server_reported_port));
char str[BADDR_MAX_PRINT_LEN];
BAddr_Print(&eaddr->addr, str);
BLog(BLOG_INFO, "external address (%d,%d): server reported %s", i, j, str);
}
}
}
// give receive device the ID
DPReceiveDevice_SetPeerID(&device_output_dprd, my_id);
// init server queue
if (!PacketPassFairQueue_Init(&server_queue, ServerConnection_GetSendInterface(&server), BReactor_PendingGroup(&ss), 0, 1)) {
BLog(BLOG_ERROR, "PacketPassFairQueue_Init failed");
terminate();
return;
}
// set server ready
server_ready = 1;
BLog(BLOG_INFO, "server: ready, my ID is %d", (int)my_id);
}
void server_handler_newclient (void *user, peerid_t peer_id, int flags, const uint8_t *cert, int cert_len)
{
ASSERT(server_ready)
ASSERT(cert_len >= 0)
ASSERT(cert_len <= SCID_NEWCLIENT_MAX_CERT_LEN)
// check if the peer already exists
if (find_peer_by_id(peer_id)) {
BLog(BLOG_WARNING, "server: newclient: peer already known");
return;
}
// make sure it's not the same ID as us
if (peer_id == my_id) {
BLog(BLOG_WARNING, "server: newclient: peer has our ID");
return;
}
// check if there is spece for the peer
if (num_peers >= options.max_peers) {
BLog(BLOG_WARNING, "server: newclient: no space for new peer (maximum number reached)");
return;
}
if (!options.ssl && cert_len > 0) {
BLog(BLOG_WARNING, "server: newclient: certificate supplied, but not using TLS");
return;
}
peer_add(peer_id, flags, cert, cert_len);
}
void server_handler_endclient (void *user, peerid_t peer_id)
{
ASSERT(server_ready)
// find peer
struct peer_data *peer = find_peer_by_id(peer_id);
if (!peer) {
BLog(BLOG_WARNING, "server: endclient: peer %d not known", (int)peer_id);
return;
}
// remove peer
peer_remove(peer, 0);
}
void server_handler_message (void *user, peerid_t peer_id, uint8_t *data, int data_len)
{
ASSERT(server_ready)
ASSERT(data_len >= 0)
ASSERT(data_len <= SC_MAX_MSGLEN)
// find peer
struct peer_data *peer = find_peer_by_id(peer_id);
if (!peer) {
BLog(BLOG_WARNING, "server: message: peer not known");
return;
}
// make sure we have chat
if (!peer->have_chat) {
peer_log(peer, BLOG_ERROR, "cannot process message, chat is down");
return;
}
// pass message to chat
PeerChat_InputReceived(&peer->chat, data, data_len);
}
void peer_job_send_seed (struct peer_data *peer)
{
ASSERT(options.transport_mode == TRANSPORT_MODE_UDP)
ASSERT(SPPROTO_HAVE_OTP(sp_params))
ASSERT(peer->have_link)
ASSERT(!peer->pio.udp.sendseed_sent)
peer_log(peer, BLOG_DEBUG, "sending OTP send seed");
int key_len = BEncryption_cipher_key_size(sp_params.otp_mode);
int iv_len = BEncryption_cipher_block_size(sp_params.otp_mode);
// generate seed
peer->pio.udp.sendseed_sent_id = peer->pio.udp.sendseed_nextid;
BRandom_randomize(peer->pio.udp.sendseed_sent_key, key_len);
BRandom_randomize(peer->pio.udp.sendseed_sent_iv, iv_len);
// set as sent, increment next seed ID
peer->pio.udp.sendseed_sent = 1;
peer->pio.udp.sendseed_nextid++;
// send seed to the peer
int msg_len = msg_seed_SIZEseed_id + msg_seed_SIZEkey(key_len) + msg_seed_SIZEiv(iv_len);
if (msg_len > MSG_MAX_PAYLOAD) {
peer_log(peer, BLOG_ERROR, "OTP send seed message too big");
return;
}
uint8_t *msg;
if (!peer_start_msg(peer, (void **)&msg, MSGID_SEED, msg_len)) {
return;
}
msg_seedWriter writer;
msg_seedWriter_Init(&writer, msg);
msg_seedWriter_Addseed_id(&writer, peer->pio.udp.sendseed_sent_id);
uint8_t *key_dst = msg_seedWriter_Addkey(&writer, key_len);
memcpy(key_dst, peer->pio.udp.sendseed_sent_key, key_len);
uint8_t *iv_dst = msg_seedWriter_Addiv(&writer, iv_len);
memcpy(iv_dst, peer->pio.udp.sendseed_sent_iv, iv_len);
msg_seedWriter_Finish(&writer);
peer_end_msg(peer);
}
void peer_job_init (struct peer_data *peer)
{
// start setup process
if (peer_am_master(peer)) {
peer_start_binding(peer);
}
}
struct server_flow * server_flow_init (void)
{
ASSERT(server_ready)
// allocate structure
struct server_flow *flow = (struct server_flow *)malloc(sizeof(*flow));
if (!flow) {
BLog(BLOG_ERROR, "malloc failed");
goto fail0;
}
// init queue flow
PacketPassFairQueueFlow_Init(&flow->qflow, &server_queue);
// init connector
PacketRecvConnector_Init(&flow->connector, sizeof(struct packetproto_header) + SC_MAX_ENC, BReactor_PendingGroup(&ss));
// init encoder buffer
if (!SinglePacketBuffer_Init(&flow->encoder_buffer, PacketRecvConnector_GetOutput(&flow->connector), PacketPassFairQueueFlow_GetInput(&flow->qflow), BReactor_PendingGroup(&ss))) {
BLog(BLOG_ERROR, "SinglePacketBuffer_Init failed");
goto fail1;
}
// set not connected
flow->connected = 0;
return flow;
fail1:
PacketRecvConnector_Free(&flow->connector);
PacketPassFairQueueFlow_Free(&flow->qflow);
free(flow);
fail0:
return NULL;
}
void server_flow_free (struct server_flow *flow)
{
PacketPassFairQueueFlow_AssertFree(&flow->qflow);
ASSERT(!flow->connected)
// remove dying flow reference
if (flow == dying_server_flow) {
dying_server_flow = NULL;
}
// free encoder buffer
SinglePacketBuffer_Free(&flow->encoder_buffer);
// free connector
PacketRecvConnector_Free(&flow->connector);
// free queue flow
PacketPassFairQueueFlow_Free(&flow->qflow);
// free structure
free(flow);
}
void server_flow_die (struct server_flow *flow)
{
ASSERT(PacketPassFairQueueFlow_IsBusy(&flow->qflow))
ASSERT(!flow->connected)
ASSERT(!dying_server_flow)
// request notification when flow is done
PacketPassFairQueueFlow_SetBusyHandler(&flow->qflow, (PacketPassFairQueue_handler_busy)server_flow_qflow_handler_busy, flow);
// set dying flow
dying_server_flow = flow;
}
void server_flow_qflow_handler_busy (struct server_flow *flow)
{
ASSERT(flow == dying_server_flow)
ASSERT(!flow->connected)
PacketPassFairQueueFlow_AssertFree(&flow->qflow);
// finally free flow
server_flow_free(flow);
}
void server_flow_connect (struct server_flow *flow, PacketRecvInterface *input)
{
ASSERT(!flow->connected)
ASSERT(flow != dying_server_flow)
// connect input
PacketRecvConnector_ConnectInput(&flow->connector, input);
// set connected
flow->connected = 1;
}
void server_flow_disconnect (struct server_flow *flow)
{
ASSERT(flow->connected)
ASSERT(flow != dying_server_flow)
// disconnect input
PacketRecvConnector_DisconnectInput(&flow->connector);
// set not connected
flow->connected = 0;
}
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