int chdir_for_file(char const *dir, bool is_filename)
{
char *redir;
if (is_filename) {
redir = tempstr_printf("%s", dir);
char *last_slash = redir;
for (char *c = redir; *c; c++) if (*c == '/') last_slash = c;
*last_slash = '\0';
} else {
redir = (char *)dir;
}
SLOG(LOG_DEBUG, "chdir into '%s'", redir);
if (redir[0] == '\0') return 0;
if (0 != chdir(redir)) {
SLOG(LOG_ERR, "Cannot chdir(%s) : %s", redir, strerror(errno));
return -1;
}
return 0;
}
static enum proto_parse_status tns_parse_login_property(struct sql_proto_info *info, struct cursor *cursor)
{
SLOG(LOG_DEBUG, "Parsing tns login property");
// We are only interested in response
if (info->is_query) return PROTO_OK;
if (info->msg_type != SQL_UNKNOWN && info->msg_type != SQL_STARTUP) return PROTO_PARSE_ERR;
// Drop Server version
DROP_FIX(cursor, 3);
// Drop Server version text
uint8_t marker = 0x00;
enum proto_parse_status status = cursor_drop_until(cursor, &marker, sizeof(marker));
if (status != PROTO_OK) return status;
// Drop Null byte
DROP_FIX(cursor, 1);
CHECK(2);
uint16_t charset = cursor_read_u16le(cursor);
SLOG(LOG_DEBUG, "Found a charset of 0x%02x", charset);
switch (charset) {
case 0x01:
case 0x02:
case 0x1f:
case 0xb2:
sql_set_encoding(info, SQL_ENCODING_LATIN1);
break;
case 0x366:
case 0x367:
case 0x369:
sql_set_encoding(info, SQL_ENCODING_UTF8);
break;
default:
SLOG(LOG_DEBUG, "Unknown charset");
break;
}
// We don't care of the rest...
cursor_drop(cursor, cursor->cap_len);
return PROTO_OK;
}
static gid_t get_gid(const char * const group)
{
assert(group);
gid_t gid = getgid(); // default one
struct group *g = getgrnam(group);
if (NULL == g)
SLOG(LOG_ERR, "getgrnam: can't get the uid of '%s'", group);
else
gid = g->gr_gid;
return gid;
}
static int netbios_parser_ctor(struct netbios_parser *netbios_parser, struct proto *proto)
{
SLOG(LOG_DEBUG, "Constructing netbios_parser@%p", netbios_parser);
assert(proto == proto_netbios);
if (0 != parser_ctor(&netbios_parser->parser, proto)) return -1;
netbios_parser->msg_parser = NULL;
timeval_reset(&netbios_parser->first_packet_tv[0]);
timeval_reset(&netbios_parser->first_packet_tv[1]);
if (0 != streambuf_ctor(&netbios_parser->sbuf, netbios_sbuf_parse, 30000, NULL)) {
parser_dtor(&netbios_parser->parser);
return -1;
}
return 0;
}
ssize_t file_size(char const *file_name)
{
int fd = file_open(file_name, O_RDONLY);
if (fd < 0) return -1;
off_t sz = lseek(fd, 0, SEEK_END);
if (sz == (off_t)-1) {
SLOG(LOG_ERR, "Cannot lseek at end of '%s' : %s", file_name, strerror(errno));
return -1;
}
file_close(fd);
return sz;
}
static enum proto_parse_status rtp_parse(struct parser *parser, struct proto_layer *parent, unsigned way, uint8_t const *packet, size_t cap_len, size_t wire_len, struct timeval const *now, proto_okfn_t *okfn)
{
SLOG(LOG_DEBUG, "Starting RTP analysis");
/* Parse */
struct rtp_header *rtph = (struct rtp_header *)packet;
if (wire_len < sizeof(*rtph)) return PROTO_PARSE_ERR;
if (cap_len < sizeof(*rtph)) return PROTO_TOO_SHORT;
SLOG(LOG_DEBUG, "RTP header, version=%u, CSRC_count=%u, payload_type=%u",
rtph->version, rtph->csrc_count, rtph->payload_type);
size_t head_len = sizeof(*rtph) + rtph->csrc_count * 4;
if (wire_len < head_len) return PROTO_PARSE_ERR;
if (cap_len < head_len) return PROTO_TOO_SHORT;
struct rtp_proto_info info;
rtp_proto_info_ctor(&info, rtph, head_len, wire_len - head_len);
struct proto_layer layer;
proto_layer_ctor(&layer, parent, parser, &info.info);
return proto_parse(NULL, &layer, way, NULL, 0, 0, now, okfn);
}
static int
log_x25_facilities (int fd, int coc, char *caption)
{
FACILITY_DB f;
if (ioctl (fd, X25_RD_FACILITY, (char *) &f) == NOTOK) {
SLOG (compat_log, LLOG_EXCEPTIONS, "failed", ("X25_RD_FACILITY"));
return NOTOK;
}
print_x25_facilities (f, coc, caption);
return OK;
}
void on_unload(void)
{
SLOG(LOG_INFO, "Duplicogram unloading");
term_fini();
hook_subscriber_dtor(&dup_hook, &dup_subscription);
hook_subscriber_dtor(&proto_cap->hook, &cap_subscription);
cli_unregister(duplicogram_opts);
//mutex_dtor(&dup_lock); no since we can have some callbacks called even after we unsubscribed (in another thread)
ext_param_bucket_width_fini();
log_category_duplicogram_fini();
}
int ip_addr_ctor_from_str_any(struct ip_addr *ip, char const *str)
{
if (1 == inet_pton(AF_INET, str, &ip->u.v4)) {
ip->family = AF_INET;
return 0;
}
if (1 == inet_pton(AF_INET6, str, &ip->u.v6)) {
ip->family = AF_INET6;
return 0;
}
SLOG(LOG_WARNING, "Cannot convert string to IP address: %s", strerror(errno));
return -1;
}
/* CRelationMgr::Insert()和CRelationMgr::Remove()时调用,
用于添加网关上下线记录。
*/
bool CClientInfo::AddOnoffRecord(const char * name, char * add, int onoff)
{
char sql_line_exist[NORMAL_XG_BUF_LEN];
int sql_len_exist = _snprintf_s(sql_line_exist, NORMAL_XG_BUF_LEN-1, _TRUNCATE,
"SELECT COUNT(*) FROM %s WHERE serial='%s'", m_onoff_record_table, name);
sql_line_exist[sql_len_exist] = '\0';
SLOG(4)("AddOnoffRecord = %s", sql_line_exist);
MYSQL_RES * existresults = BeginQuery(sql_line_exist);
if (NULL == existresults)
{
return FALSE;
}
int recordnum = strtoul(*mysql_fetch_row(existresults), NULL, 0);
EndQuery(existresults);
if( recordnum == 120) // 如果已有的该网关上下线记录等于120条
{
SLOG(4)("此处应当删除前21条记录");
DelOnoffRecord(name);
}
InsertOnoffRecord(name, add, onoff);
return TRUE;
}
static enum proto_parse_status rtp_parse(struct parser *parser, struct proto_info *parent, unsigned way, uint8_t const *packet, size_t cap_len, size_t wire_len, struct timeval const *now, size_t tot_cap_len, uint8_t const *tot_packet)
{
SLOG(LOG_DEBUG, "Starting RTP analysis");
/* Parse */
struct rtp_hdr *rtph = (struct rtp_hdr *)packet;
if (wire_len < sizeof(*rtph)) return PROTO_PARSE_ERR;
if (cap_len < sizeof(*rtph)) return PROTO_TOO_SHORT;
unsigned const version = READ_U8(&rtph->flags0) >> 6U;
unsigned const csrc_count = READ_U8(&rtph->flags0) & F0_CSRC_COUNT_MASK;
unsigned const payload_type = READ_U8(&rtph->flags1) & F1_PLD_TYPE_MASK;
SLOG(LOG_DEBUG, "RTP header, version=%u, CSRC_count=%u, payload_type=%u", version, csrc_count, payload_type);
size_t head_len = sizeof(*rtph) + csrc_count * 4;
if (wire_len < head_len) return PROTO_PARSE_ERR;
if (cap_len < head_len) return PROTO_TOO_SHORT;
struct rtp_proto_info info;
rtp_proto_info_ctor(&info, parser, parent, rtph, head_len, wire_len - head_len);
return proto_parse(NULL, &info.info, way, NULL, 0, 0, now, tot_cap_len, tot_packet);
}
static int ftw_copy_link(const struct FTW *p,
const char *spath,
const struct stat *sstp,
int exists)
{
int len;
char llink[PATH_MAX];
if ((len = readlink(spath, llink, sizeof(llink) - 1)) == -1) {
SLOG("readlink: %s: %s", spath, strerror(errno));
return (1);
}
llink[len] = '\0';
if (exists && unlink(to.p_path)) {
SLOG("unlink: %s: %s", to.p_path, strerror(errno));
return (1);
}
if (symlink(llink, to.p_path)) {
SLOG("symlink: %s: %s", llink, strerror(errno));
return (1);
}
return (pflag ? setfile(sstp, -1) : 0);
}
static Eina_Bool __tts_notify_utt_completed(void *data)
{
tts_h tts = (tts_h)data;
tts_client_s* client = tts_client_get(tts);
/* check handle */
if (NULL == client) {
SLOG(LOG_WARN, TAG_TTSC, "[WARNING] Fail to notify utt completed : A handle is not valid");
return EINA_FALSE;
}
if (NULL != client->utt_completeted_cb) {
SLOG(LOG_DEBUG, TAG_TTSC, "Call callback function of utterance completed \n");
tts_client_use_callback(client);
client->utt_completeted_cb(client->tts, client->utt_id, client->utt_completed_user_data);
tts_client_not_use_callback(client);
} else {
SLOG(LOG_WARN, TAG_TTSC, "No registered callback function of utterance completed \n");
}
return EINA_FALSE;
}
static Eina_Bool __tts_notify_state_changed(void *data)
{
tts_h tts = (tts_h)data;
tts_client_s* client = tts_client_get(tts);
/* check handle */
if (NULL == client) {
SLOG(LOG_WARN, TAG_TTSC, "Fail to notify error : A handle is not valid");
return EINA_FALSE;
}
if (NULL != client->state_changed_cb) {
tts_client_use_callback(client);
client->state_changed_cb(client->tts, client->before_state, client->current_state, client->state_changed_user_data);
tts_client_not_use_callback(client);
SLOG(LOG_DEBUG, TAG_TTSC, "State changed callback is called");
} else {
SLOG(LOG_WARN, TAG_TTSC, "[WARNING] State changed callback is null");
}
return EINA_FALSE;
}
static Eina_Bool __tts_notify_error(void *data)
{
tts_h tts = (tts_h)data;
tts_client_s* client = tts_client_get(tts);
/* check handle */
if (NULL == client) {
SLOG(LOG_WARN, TAG_TTSC, "Fail to notify error : A handle is not valid");
return EINA_FALSE;
}
if (NULL != client->error_cb) {
SLOG(LOG_DEBUG, TAG_TTSC, "Call callback function of error");
tts_client_use_callback(client);
client->error_cb(client->tts, client->utt_id, client->reason, client->error_user_data );
tts_client_not_use_callback(client);
} else {
SLOG(LOG_WARN, TAG_TTSC, "No registered callback function of error \n");
}
return EINA_FALSE;
}
void CSocket::socketSystemDestroy()
{
// errorOut("debuglog.txt", ":: Destroying socket system...");
#if defined(_WIN32) || defined(_WIN64)
int intTimeCheck = 0;
while (intTimeCheck++ < 3)
{
if (WSACleanup() == SOCKET_ERROR)
SLOG("[CSocket::socketSystemDestroy] WSACleanup() returned error: %s\n", errorMessage(identifyError()));
sleep(1000);
}
#endif
}
int ttsd_server_initialize(int pid, int uid)
{
if (false == g_is_engine) {
if (0 != ttsd_engine_agent_initialize_current_engine()) {
SLOG(LOG_WARN, TAG_TTSD, "[Server WARNING] No Engine !!! " );
g_is_engine = false;
return TTSD_ERROR_ENGINE_NOT_FOUND;
} else {
g_is_engine = true;
}
}
if (-1 != ttsd_data_is_client(uid)) {
SLOG(LOG_ERROR, TAG_TTSD, "[Server ERROR] Uid has already been registered ");
return TTSD_ERROR_INVALID_PARAMETER;
}
if (0 == ttsd_data_get_client_count()) {
if (0 != ttsd_engine_agent_load_current_engine()) {
SLOG(LOG_ERROR, TAG_TTSD, "[Server ERROR] Fail to load current engine ");
return TTSD_ERROR_OPERATION_FAILED;
}
}
if (0 != ttsd_data_new_client(pid, uid)) {
SLOG(LOG_ERROR, TAG_TTSD, "[Server ERROR] Fail to add client info ");
return TTSD_ERROR_OPERATION_FAILED;
}
if (0 != ttsd_player_create_instance(uid)) {
SLOG(LOG_ERROR, TAG_TTSD, "[Server ERROR] Fail to create player ");
return TTSD_ERROR_OPERATION_FAILED;
}
return TTSD_ERROR_NONE;
}
static int callid_2_sdp_ctor(struct callid_2_sdp *c2s, char const *call_id, struct timeval const *now)
{
SLOG(LOG_DEBUG, "Construct callid_2_sdp@%p for callid '%s'", c2s, call_id);
c2s->sdp_parser = proto_sdp->ops->parser_new(proto_sdp);
if (! c2s->sdp_parser) return -1;
memset(c2s->call_id, 0, sizeof c2s->call_id); // because it's used as a hash key
snprintf(c2s->call_id, sizeof(c2s->call_id), "%s", call_id);
c2s->last_used = *now;
mutex_lock(&callids_2_sdps_mutex);
callids_2_sdps_timeout(now);
HASH_INSERT(&callids_2_sdps, c2s, &c2s->call_id, entry);
TAILQ_INSERT_TAIL(&callids_2_sdps_used, c2s, used_entry);
mutex_unlock(&callids_2_sdps_mutex);
return 0;
}
int tts_get_max_text_count(tts_h tts, int* count)
{
if (NULL == tts || NULL == count) {
SLOG(LOG_ERROR, TAG_TTSC, "[ERROR] Get max text count : Input parameter is null");
return TTS_ERROR_INVALID_PARAMETER;
}
tts_client_s* client = tts_client_get(tts);
if (NULL == client) {
SLOG(LOG_ERROR, TAG_TTSC, "[ERROR] Get max text count : A handle is not valid");
return TTS_ERROR_INVALID_PARAMETER;
}
if (TTS_STATE_READY != client->current_state) {
SLOG(LOG_ERROR, TAG_TTSC, "[ERROR] Get max text count : Current state is NOT 'READY'.");
return TTS_ERROR_INVALID_STATE;
}
*count = MAX_TEXT_COUNT;
SLOG(LOG_DEBUG, TAG_TTSC, "[Suceess] Get max text count");
return TTS_ERROR_NONE;
}
void ip_addr_deserialize(struct ip_addr *addr, uint8_t const **buf)
{
unsigned version = deserialize_1(buf);
if (version == 4) {
addr->family = AF_INET;
addr->u.v4.s_addr = deserialize_4(buf);
} else if (version == 6) {
addr->family = AF_INET6;
deserialize_n(buf, &addr->u.v6, sizeof(addr->u.v6));
} else {
SLOG(LOG_ERR, "Cannot deserialize ip_addr of version %u", version);
addr->family = AF_INET; // run forest, run!
addr->u.v4.s_addr = 0U;
}
}
static void __my_sig_child(int signo, siginfo_t *info, void *data)
{
int status;
pid_t child_pid, child_pgid;
child_pgid = getpgid(info->si_pid);
SLOG(LOG_DEBUG, TAG_TTSC, "Signal handler: dead pid = %d, pgid = %d\n", info->si_pid, child_pgid);
while (0 < (child_pid = waitpid(-1, &status, WNOHANG))) {
if(child_pid == child_pgid)
killpg(child_pgid, SIGKILL);
}
return;
}
static int tds_parser_ctor(struct tds_parser *tds_parser, struct proto *proto)
{
SLOG(LOG_DEBUG, "Constructing tds_parser@%p", tds_parser);
assert(proto == proto_tds);
if (0 != parser_ctor(&tds_parser->parser, proto)) return -1;
tds_parser->msg_parser = NULL;
tds_parser->had_gap = false;
tds_parser->data_left = 0;
tds_parser->channels[0] = 0;
tds_parser->channels[1] = 0;
tds_parser->pkt_number = 1;
if (0 != streambuf_ctor(&tds_parser->sbuf, tds_sbuf_parse, 30000, NULL)) return -1;
return 0;
}
void*
CD_RunHTTPd (CDHTTPd* self)
{
self->event.handle = evhttp_bind_socket_with_handle(self->event.httpd,
self->server->config->cache.httpd.connection.bind.ipv4,
self->server->config->cache.httpd.connection.port);
SLOG(self->server, LOG_NOTICE, "Started HTTPd at http://%s:%d",
self->server->config->cache.httpd.connection.bind.ipv4,
self->server->config->cache.httpd.connection.port);
event_base_dispatch(self->event.base);
return NULL;
}
int
start_x25_client (struct NSAPaddr *local, int priv)
{
int sd;
if ((sd = socket (AF_X25, SOCK_STREAM, 0)) == NOTOK) {
SLOG (compat_log, LLOG_EXCEPTIONS, "failed", ("socket"));
return NOTOK;
}
#ifdef AEF_NSAP
if (local && local -> na_stack == NA_NSAP) {
FACILITY f;
f.type = T_CALLING_AEF;
if (nsap2if (local, &f.f_calling_aef) == NOTOK ||
ioctl (sd, X25_SET_FACILITY, &f) == NOTOK) {
SLOG (compat_log, LLOG_EXCEPTIONS, "failed", ("set calling AEF"));
close_x25_socket (sd);
return NOTOK;
}
}
#endif
return sd;
}
static enum proto_parse_status parse_rpc_call(struct cursor *cursor, struct rpc_proto_info *info)
{
CHECK(28);
info->u.call_msg.rpc_version = cursor_read_u32n(cursor);
if (info->u.call_msg.rpc_version != 2) {
SLOG(LOG_DEBUG, "Rpc version should be 2, got %"PRIu32, info->u.call_msg.rpc_version);
return PROTO_PARSE_ERR;
}
info->u.call_msg.program = cursor_read_u32n(cursor);
info->u.call_msg.program_version = cursor_read_u32n(cursor);
info->u.call_msg.procedure = cursor_read_u32n(cursor);
RPC_CHECK_AUTH(credential);
RPC_CHECK_AUTH(auth);
return PROTO_OK;
}
// Decode the flow in src into flow. We already checked there are enough bytes to read in src.
static int nf_flow_decode(struct nf_flow *flow, struct nf_msg const *head, void const *src)
{
struct nf_flow_ll const *flow_ll = src; // FIXME: won't work if not properly aligned
CONV_IP(flow, addr[0]); CONV_IP(flow, addr[1]); CONV_IP(flow, next_hop);
CONV_16(flow, port[0]); CONV_16(flow, port[1]);
CONV_16(flow, in_iface); CONV_16(flow, out_iface);
CONV_32(flow, packets); CONV_32(flow, bytes);
CONV_8(flow, tcp_flags); CONV_8(flow, ip_proto); CONV_8(flow, ip_tos);
CONV_16(flow, as[0]); CONV_16(flow, as[1]);
CONV_8(flow, mask[0]); CONV_8(flow, mask[1]);
/* The first/last fields of the netflow are the uptime at the first/last pkt of the flow.
* We find a timestamp more interesting, so we get it from sysuptime and localtime of the header.
* But this imply trusting the netflow header localtime. */
SLOG(LOG_DEBUG, "Decoding a flow which sys_uptime=%"PRIu32", now=%s, first=%u, last=%u",
head->sys_uptime, timeval_2_str(&head->ts), ntohl(flow_ll->first), ntohl(flow_ll->last));
flow->first = head->ts;
timeval_sub_usec(&flow->first, (int64_t)(head->sys_uptime - ntohl(flow_ll->first)) * 1000);
flow->last = head->ts;
timeval_sub_usec(&flow->last, (int64_t)(head->sys_uptime - ntohl(flow_ll->last)) * 1000);
SLOG(LOG_DEBUG, "...yielding: %s->%s", timeval_2_str(&flow->first), timeval_2_str(&flow->last));
return 0;
}
int ttsd_server_pause(int uid, int* utt_id)
{
app_state_e state;
if (0 > ttsd_data_get_client_state(uid, &state)) {
SLOG(LOG_ERROR, TAG_TTSD, "[Server ERROR] ttsd_server_pause : uid is not valid ");
return TTSD_ERROR_INVALID_PARAMETER;
}
if (APP_STATE_PLAYING != state) {
SLOG(LOG_WARN, TAG_TTSD, "[Server WARNING] Current state is not 'play' ");
return TTSD_ERROR_INVALID_STATE;
}
int ret = 0;
ret = ttsd_player_pause(uid);
if (0 != ret) {
SLOG(LOG_ERROR, TAG_TTSD, "[Server ERROR] fail player_pause() : ret(%d)", ret);
return TTSD_ERROR_OPERATION_FAILED;
}
ttsd_data_set_client_state(uid, APP_STATE_PAUSED);
return TTSD_ERROR_NONE;
}
int
join_x25_client (int fd, struct NSAPaddr *remote)
{
CONN_DB sbuf;
CONN_DB *sock = &sbuf;
int len = sizeof *sock;
int nfd;
#ifdef AEF_NSAP
FACILITY f;
#endif
if ((nfd = accept (fd, (struct sockaddr *) sock, &len)) == NOTOK) {
if (compat_log -> ll_events & LLOG_EXCEPTIONS)
log_cause_and_diag(fd); /* Sun's documentation throwns
no light as to whether, or
not this will result in any
useful information */
}
#ifdef DEBUG
else if (compat_log -> ll_events & LLOG_DEBUG)
log_x25_facilities(fd, CALLED, "Effective Called");
#endif
if (nfd < 0) return nfd;
/* May also need to send call accept packet if using
* FAST_ACPT_CLR, or X25_CALL_ACPT_APPROVAL
* there was a SUNLINK bug in this area
*
* May as well try it -- if it fails, so what ??
*/
if (ioctl(nfd,X25_SEND_CALL_ACPT, NULLCP) < 0)
SLOG (compat_log, LLOG_EXCEPTIONS, "failed", ("X25_SEND_CALL_ACPT"));
#ifdef AEF_NONE /* sunnet 7.0 or > */
/*
* For sunnet 7.0 - see if we have a real nsap and use that.
*/
f.type = T_CALLING_AEF;
if (ioctl (nfd, X25_GET_FACILITY, &f) == NOTOK ||
if2nsap (&f.f_calling_aef, remote) == NOTOK)
#endif
remote = if2gen (remote, sock, ADDR_REMOTE);
return nfd;
}
int streambuf_ctor(struct streambuf *sbuf, parse_fun *parse, size_t max_size, struct mutex_pool *pool)
{
SLOG(LOG_DEBUG, "Constructing a streambuf@%p of max size %zu", sbuf, max_size);
sbuf->parse = parse;
sbuf->max_size = max_size;
sbuf->mutex = mutex_pool_anyone(pool ? pool : &streambuf_locks);
for (unsigned d = 0; d < 2; d++) {
sbuf->dir[d].buffer = NULL;
sbuf->dir[d].buffer_size = 0;
sbuf->dir[d].restart_offset = 0;
}
return 0;
}
static bool check_fixed_query(struct cursor *cursor, uint8_t current,
uint8_t next, struct query_candidate *candidate)
{
if (is_print(current) && is_print(next)) {
for (unsigned i = 0; i < candidate->num_candidate_size; ++i) {
uint64_t size = candidate->candidate_sizes[i];
if (is_query_valid(cursor, size, 0)) {
candidate->query_size = candidate->candidate_sizes[i];
SLOG(LOG_DEBUG, " Found a fixed query string of size %u", candidate->query_size);
candidate->is_chunked = false;
return true;
}
}
}
return false;
}
