static int handle_state_initial(struct npool *nsp, struct nevent *nse, void *udata) {
struct proxy_chain_context *px_ctx = nse->iod->px_ctx;
struct sockaddr_storage *ss;
size_t sslen;
unsigned short port;
struct proxy_node *next;
int timeout;
px_ctx->px_state = PROXY_STATE_HTTP_TCP_CONNECTED;
next = proxy_ctx_node_next(px_ctx);
if (next) {
ss = &next->ss;
sslen = next->sslen;
port = next->port;
} else {
ss = &px_ctx->target_ss;
sslen = px_ctx->target_sslen;
port = px_ctx->target_port;
}
timeout = TIMEVAL_MSEC_SUBTRACT(nse->timeout, nsock_tod);
nsock_printf(nsp, (nsock_iod)nse->iod, nsock_proxy_ev_dispatch,
timeout, udata, "CONNECT %s:%d HTTP/1.1\r\n\r\n",
inet_ntop_ez(ss, sslen), (int)port);
nsock_readlines(nsp, (nsock_iod)nse->iod, nsock_proxy_ev_dispatch,
timeout, udata, 1);
return 0;
}
static int _base_save_state(struct base *base)
{
struct timeval tv0, tv1;
gettimeofday(&tv0, NULL);
struct swriter *swriter = swriter_new(base->index_dir, STATE_FILENAME);
if (swriter == NULL) {
log_error(base->db, "Unable to write snapshot. %s", "");
return -1;
}
struct _save_ctx ctx = {swriter, logs_newest(base->logs)};
int r = logs_iterate(base->logs, _save_callback, &ctx);
if (r != 0) {
swriter_free(swriter, 0);
log_error(base->db, "Unable to write snapshot. %s", "");
return -1;
}
r = swriter_free(swriter, 1);
if (r == 0) {
gettimeofday(&tv1, NULL);
log_info(base->db, "Snapshot saved in %lu ms.",
TIMEVAL_MSEC_SUBTRACT(tv1, tv0));
} else {
log_error(base->db, "Unable to save snapshot.%s", "");
}
return r;
}
/* Here is the all important looping function that tells the event engine to
* start up and begin processing events. It will continue until all events have
* been delivered (including new ones started from event handlers), or the
* msec_timeout is reached, or a major error has occurred. Use -1 if you don't
* want to set a maximum time for it to run. A timeout of 0 will return after 1
* non-blocking loop. The nsock loop can be restarted again after it returns.
* For example you could do a series of 15 second runs, allowing you to do other
* stuff between them */
enum nsock_loopstatus nsock_loop(nsock_pool nsp, int msec_timeout) {
mspool *ms = (mspool *)nsp;
struct timeval loop_timeout;
int msecs_left;
unsigned long loopnum = 0;
enum nsock_loopstatus quitstatus = NSOCK_LOOP_ERROR;
gettimeofday(&nsock_tod, NULL);
if (msec_timeout < -1) {
ms->errnum = EINVAL;
return NSOCK_LOOP_ERROR;
}
TIMEVAL_MSEC_ADD(loop_timeout, nsock_tod, msec_timeout);
msecs_left = msec_timeout;
if (ms->tracelevel > 2) {
if (msec_timeout >= 0)
nsock_trace(ms, "nsock_loop() started (timeout=%dms). %d events pending",
msec_timeout, ms->events_pending);
else
nsock_trace(ms, "nsock_loop() started (no timeout). %d events pending",
ms->events_pending);
}
while (1) {
if (ms->quit) {
/* We've been asked to quit the loop through nsock_loop_quit. */
ms->quit = 0;
quitstatus = NSOCK_LOOP_QUIT;
break;
}
if (ms->events_pending == 0) {
/* if no events at all are pending, then none can be created until
* we quit nsock_loop() -- so we do that now. */
quitstatus = NSOCK_LOOP_NOEVENTS;
break;
}
if (msec_timeout >= 0) {
msecs_left = MAX(0, TIMEVAL_MSEC_SUBTRACT(loop_timeout, nsock_tod));
if (msecs_left == 0 && loopnum > 0) {
quitstatus = NSOCK_LOOP_TIMEOUT;
break;
}
}
if (ms->engine->loop(ms, msecs_left) == -1) {
quitstatus = NSOCK_LOOP_ERROR;
break;
}
gettimeofday(&nsock_tod, NULL); /* we do this at end because there is one
* at beginning of function */
loopnum++;
}
return quitstatus;
}
void nsock_trace(mspool *ms, char *fmt, ...) {
va_list ap;
int elapsed_time_ms;
assert(ms->tracefile != NULL);
elapsed_time_ms = TIMEVAL_MSEC_SUBTRACT(nsock_tod, ms->tracebasetime);
va_start(ap, fmt);
fflush(ms->tracefile);
fprintf(ms->tracefile, "NSOCK (%.4fs) ", elapsed_time_ms / 1000.0);
vfprintf(ms->tracefile, fmt, ap);
fprintf(ms->tracefile, "\n");
va_end(ap);
}
static void _ydb_close(struct ydb *ydb, int msg)
{
struct timeval tv0, tv1;
gettimeofday(&tv0, NULL);
base_free(ydb->base);
gettimeofday(&tv1, NULL);
if (msg) {
log_info(ydb->db, "Closing YDB database (took %lu ms)",
TIMEVAL_MSEC_SUBTRACT(tv1, tv0));
}
db_free(ydb->db);
free(ydb);
}
int log_iterate_sorted(struct log *log, uint64_t prefetch_size,
log_iterate_callback callback, void *userdata)
{
struct timeval tv0, tv1;
gettimeofday(&tv0, NULL);
struct hashdir *shd = hashdir_dup_sorted(log->hashdir);
gettimeofday(&tv1, NULL);
log_info(log->db, "Sorting index in log %llx took %5li ms.",
(unsigned long long)log->log_number,
TIMEVAL_MSEC_SUBTRACT(tv1, tv0));
int hpos_max = hashdir_size(shd);
int last_hpos = 1;
int r = 0;
int i;
for (i=1; i < hpos_max; i++) {
if (i == last_hpos) {
last_hpos = _iterate_prefetch(log, shd,
last_hpos, prefetch_size);
}
struct hashdir_item hi = hashdir_get(shd, i);
struct keyvalue kv;
char *buf = malloc(hi.size);
r = reader_read(log->reader, hi.offset, buf, hi.size, &kv);
if (r) {
free(buf);
break;
}
r = callback(userdata,
kv.key, kv.key_sz,
kv.value, kv.value_sz);
free(buf);
if (r) {
break;
}
}
hashdir_free(shd);
return r;
}
struct ydb *ydb_open(const char *directory, struct ydb_options *options)
{
struct db *db = db_new(directory);
if (db == NULL) {
return NULL;
}
struct base *base = base_new(db, db_log_dir(db), db_index_dir(db),
options);
if (base == NULL) {
db_free(db);
return NULL;
}
log_info(db, "Opening YDB database \"%s\" by pid=%i.",
directory, getpid());
linux_check_overcommit(db);
struct ydb *ydb = malloc(sizeof(struct ydb));
ydb->db = db;
ydb->base = base;
struct timeval tv0, tv1;
gettimeofday(&tv0, NULL);
int r = base_load(ydb->base);
if (r != 0) {
_ydb_close(ydb, 0);
return NULL;
}
base_print_stats(ydb->base);
gettimeofday(&tv1, NULL);
log_info(db, "YDB loaded %llu items in %.3f seconds.",
(unsigned long long)base->used_size.count,
(float)TIMEVAL_MSEC_SUBTRACT(tv1, tv0) / 1000.);
return ydb;
}
void process_event(struct npool *nsp, gh_list_t *evlist, struct nevent *nse, int ev) {
int match_r = 0, match_w = 0;
#if HAVE_OPENSSL
int desire_r = 0, desire_w = 0;
#endif
nsock_log_debug_all("Processing event %lu (timeout in %ldms, done=%d)",
nse->id,
(long)TIMEVAL_MSEC_SUBTRACT(nse->timeout, nsock_tod),
nse->event_done);
if (!nse->event_done) {
switch (nse->type) {
case NSE_TYPE_CONNECT:
case NSE_TYPE_CONNECT_SSL:
if (ev != EV_NONE)
handle_connect_result(nsp, nse, NSE_STATUS_SUCCESS);
if (event_timedout(nse))
handle_connect_result(nsp, nse, NSE_STATUS_TIMEOUT);
break;
case NSE_TYPE_READ:
match_r = ev & EV_READ;
match_w = ev & EV_WRITE;
#if HAVE_OPENSSL
desire_r = nse->sslinfo.ssl_desire == SSL_ERROR_WANT_READ;
desire_w = nse->sslinfo.ssl_desire == SSL_ERROR_WANT_WRITE;
if (nse->iod->ssl && ((desire_r && match_r) || (desire_w && match_w)))
handle_read_result(nsp, nse, NSE_STATUS_SUCCESS);
else
#endif
if (!nse->iod->ssl && match_r)
handle_read_result(nsp, nse, NSE_STATUS_SUCCESS);
if (event_timedout(nse))
handle_read_result(nsp, nse, NSE_STATUS_TIMEOUT);
break;
case NSE_TYPE_WRITE:
match_r = ev & EV_READ;
match_w = ev & EV_WRITE;
#if HAVE_OPENSSL
desire_r = nse->sslinfo.ssl_desire == SSL_ERROR_WANT_READ;
desire_w = nse->sslinfo.ssl_desire == SSL_ERROR_WANT_WRITE;
if (nse->iod->ssl && ((desire_r && match_r) || (desire_w && match_w)))
handle_write_result(nsp, nse, NSE_STATUS_SUCCESS);
else
#endif
if (!nse->iod->ssl && match_w)
handle_write_result(nsp, nse, NSE_STATUS_SUCCESS);
if (event_timedout(nse))
handle_write_result(nsp, nse, NSE_STATUS_TIMEOUT);
break;
case NSE_TYPE_TIMER:
if (event_timedout(nse))
handle_timer_result(nsp, nse, NSE_STATUS_SUCCESS);
break;
#if HAVE_PCAP
case NSE_TYPE_PCAP_READ:{
nsock_log_debug_all("PCAP iterating %lu", nse->id);
if (ev & EV_READ) {
/* buffer empty? check it! */
if (fs_length(&(nse->iobuf)) == 0)
do_actual_pcap_read(nse);
}
/* if already received something */
if (fs_length(&(nse->iobuf)) > 0)
handle_pcap_read_result(nsp, nse, NSE_STATUS_SUCCESS);
if (event_timedout(nse))
handle_pcap_read_result(nsp, nse, NSE_STATUS_TIMEOUT);
#if PCAP_BSD_SELECT_HACK
/* If event occurred, and we're in BSD_HACK mode, then this event was added
* to two queues. read_event and pcap_read_event
* Of course we should destroy it only once.
* I assume we're now in read_event, so just unlink this event from
* pcap_read_event */
if (((mspcap *)nse->iod->pcap)->pcap_desc >= 0
&& nse->event_done
&& evlist == &nsp->read_events) {
/* event is done, list is read_events and we're in BSD_HACK mode.
* So unlink event from pcap_read_events */
update_first_events(nse);
gh_list_remove(&nsp->pcap_read_events, &nse->nodeq_pcap);
nsock_log_debug_all("PCAP NSE #%lu: Removing event from PCAP_READ_EVENTS",
nse->id);
}
if (((mspcap *)nse->iod->pcap)->pcap_desc >= 0
&& nse->event_done
&& evlist == &nsp->pcap_read_events) {
update_first_events(nse);
gh_list_remove(&nsp->read_events, &nse->nodeq_io);
nsock_log_debug_all("PCAP NSE #%lu: Removing event from READ_EVENTS",
nse->id);
}
#endif
break;
}
#endif
default:
fatal("Event has unknown type (%d)", nse->type);
}
}
if (nse->event_done) {
/* Security sanity check: don't return a functional SSL iod without
* setting an SSL data structure. */
if (nse->type == NSE_TYPE_CONNECT_SSL && nse->status == NSE_STATUS_SUCCESS)
assert(nse->iod->ssl != NULL);
nsock_log_debug_all("NSE #%lu: Sending event", nse->id);
/* WooHoo! The event is ready to be sent */
event_dispatch_and_delete(nsp, nse, 1);
}
}
/* Adds an event to the appropriate nsp event list, handles housekeeping such as
* adjusting the descriptor select/poll lists, registering the timeout value,
* etc. */
void nsock_pool_add_event(struct npool *nsp, struct nevent *nse) {
nsock_log_debug("NSE #%lu: Adding event (timeout in %ldms)",
nse->id,
(long)TIMEVAL_MSEC_SUBTRACT(nse->timeout, nsock_tod));
nsp->events_pending++;
if (!nse->event_done && nse->timeout.tv_sec) {
/* This event is expirable, add it to the queue */
gh_heap_push(&nsp->expirables, &nse->expire);
}
/* Now we do the event type specific actions */
switch (nse->type) {
case NSE_TYPE_CONNECT:
case NSE_TYPE_CONNECT_SSL:
if (!nse->event_done) {
assert(nse->iod->sd >= 0);
socket_count_read_inc(nse->iod);
socket_count_write_inc(nse->iod);
update_events(nse->iod, nsp, EV_READ|EV_WRITE|EV_EXCEPT, EV_NONE);
}
iod_add_event(nse->iod, nse);
break;
case NSE_TYPE_READ:
if (!nse->event_done) {
assert(nse->iod->sd >= 0);
socket_count_read_inc(nse->iod);
update_events(nse->iod, nsp, EV_READ, EV_NONE);
#if HAVE_OPENSSL
if (nse->iod->ssl)
nse->sslinfo.ssl_desire = SSL_ERROR_WANT_READ;
#endif
}
iod_add_event(nse->iod, nse);
break;
case NSE_TYPE_WRITE:
if (!nse->event_done) {
assert(nse->iod->sd >= 0);
socket_count_write_inc(nse->iod);
update_events(nse->iod, nsp, EV_WRITE, EV_NONE);
#if HAVE_OPENSSL
if (nse->iod->ssl)
nse->sslinfo.ssl_desire = SSL_ERROR_WANT_WRITE;
#endif
}
iod_add_event(nse->iod, nse);
break;
case NSE_TYPE_TIMER:
/* nothing to do */
break;
#if HAVE_PCAP
case NSE_TYPE_PCAP_READ: {
mspcap *mp = (mspcap *)nse->iod->pcap;
assert(mp);
if (mp->pcap_desc >= 0) { /* pcap descriptor present */
if (!nse->event_done) {
socket_count_readpcap_inc(nse->iod);
update_events(nse->iod, nsp, EV_READ, EV_NONE);
}
nsock_log_debug_all("PCAP NSE #%lu: Adding event to READ_EVENTS", nse->id);
#if PCAP_BSD_SELECT_HACK
/* when using BSD hack we must do pcap_next() after select().
* Let's insert this pcap to bot queues, to selectable and nonselectable.
* This will result in doing pcap_next_ex() just before select() */
nsock_log_debug_all("PCAP NSE #%lu: Adding event to PCAP_READ_EVENTS", nse->id);
#endif
} else {
/* pcap isn't selectable. Add it to pcap-specific queue. */
nsock_log_debug_all("PCAP NSE #%lu: Adding event to PCAP_READ_EVENTS", nse->id);
}
iod_add_event(nse->iod, nse);
break;
}
#endif
default:
fatal("Unknown nsock event type (%d)", nse->type);
}
/* It can happen that the event already completed. In which case we can
* already deliver it, even though we're probably not inside nsock_loop(). */
if (nse->event_done) {
event_dispatch_and_delete(nsp, nse, 1);
update_first_events(nse);
nevent_unref(nsp, nse);
}
}
int kqueue_loop(mspool *nsp, int msec_timeout) {
int results_left = 0;
int event_msecs; /* msecs before an event goes off */
int combined_msecs;
struct timespec ts, *ts_p;
int sock_err = 0;
struct kqueue_engine_info *kinfo = (struct kqueue_engine_info *)nsp->engine_data;
assert(msec_timeout >= -1);
if (nsp->events_pending == 0)
return 0; /* No need to wait on 0 events ... */
if (gh_list_count(&nsp->active_iods) > kinfo->evlen) {
kinfo->evlen = gh_list_count(&nsp->active_iods) * 2;
kinfo->events = (struct kevent *)safe_realloc(kinfo->events, kinfo->evlen * sizeof(struct kevent));
}
do {
msevent *nse;
nsock_log_debug_all(nsp, "wait for events");
nse = next_expirable_event(nsp);
if (!nse)
event_msecs = -1; /* None of the events specified a timeout */
else
event_msecs = MAX(0, TIMEVAL_MSEC_SUBTRACT(nse->timeout, nsock_tod));
#if HAVE_PCAP
#ifndef PCAP_CAN_DO_SELECT
/* Force a low timeout when capturing packets on systems where
* the pcap descriptor is not select()able. */
if (gh_list_count(&nsp->pcap_read_events) > 0)
if (event_msecs > PCAP_POLL_INTERVAL)
event_msecs = PCAP_POLL_INTERVAL;
#endif
#endif
/* We cast to unsigned because we want -1 to be very high (since it means no
* timeout) */
combined_msecs = MIN((unsigned)event_msecs, (unsigned)msec_timeout);
/* Set up the timeval pointer we will give to kevent() */
memset(&ts, 0, sizeof(struct timespec));
if (combined_msecs >= 0) {
ts.tv_sec = combined_msecs / 1000;
ts.tv_nsec = (combined_msecs % 1000) * 1000000L;
ts_p = &ts;
} else {
ts_p = NULL;
}
#if HAVE_PCAP
#ifndef PCAP_CAN_DO_SELECT
/* do non-blocking read on pcap devices that doesn't support select()
* If there is anything read, just leave this loop. */
if (pcap_read_on_nonselect(nsp)) {
/* okay, something was read. */
} else
#endif
#endif
{
results_left = kevent(kinfo->kqfd, NULL, 0, kinfo->events, kinfo->evlen, ts_p);
if (results_left == -1)
sock_err = socket_errno();
}
gettimeofday(&nsock_tod, NULL); /* Due to kevent delay */
} while (results_left == -1 && sock_err == EINTR); /* repeat only if signal occurred */
if (results_left == -1 && sock_err != EINTR) {
nsock_log_error(nsp, "nsock_loop error %d: %s", sock_err, socket_strerror(sock_err));
nsp->errnum = sock_err;
return -1;
}
iterate_through_event_lists(nsp, results_left);
return 1;
}
int ncat_connect(void)
{
nsock_pool mypool;
int rc;
/* Unless explicitely asked not to do so, ncat uses the
* fallback nsock engine to maximize compatibility between
* operating systems and the different use cases.
*/
if (!o.nsock_engine)
nsock_set_default_engine("select");
/* Create an nsock pool */
if ((mypool = nsp_new(NULL)) == NULL)
bye("Failed to create nsock_pool.");
if (o.debug >= 6)
nsock_set_loglevel(mypool, NSOCK_LOG_DBG_ALL);
else if (o.debug >= 3)
nsock_set_loglevel(mypool, NSOCK_LOG_DBG);
else if (o.debug >= 1)
nsock_set_loglevel(mypool, NSOCK_LOG_INFO);
else
nsock_set_loglevel(mypool, NSOCK_LOG_ERROR);
/* Allow connections to broadcast addresses. */
nsp_setbroadcast(mypool, 1);
#ifdef HAVE_OPENSSL
set_ssl_ctx_options((SSL_CTX *) nsp_ssl_init(mypool));
#endif
if (httpconnect.storage.ss_family == AF_UNSPEC
&& socksconnect.storage.ss_family == AF_UNSPEC) {
/* A non-proxy connection. Create an iod for a new socket. */
cs.sock_nsi = nsi_new(mypool, NULL);
if (cs.sock_nsi == NULL)
bye("Failed to create nsock_iod.");
if (nsi_set_hostname(cs.sock_nsi, o.target) == -1)
bye("Failed to set hostname on iod.");
#if HAVE_SYS_UN_H
/* For DGRAM UNIX socket we have to use source socket */
if (o.af == AF_UNIX && o.udp)
{
if (srcaddr.storage.ss_family != AF_UNIX) {
char *tmp_name = NULL;
/* If no source socket was specified, we have to create temporary one. */
if ((tmp_name = tempnam(NULL, "ncat.")) == NULL)
bye("Failed to create name for temporary DGRAM source Unix domain socket (tempnam).");
srcaddr.un.sun_family = AF_UNIX;
strncpy(srcaddr.un.sun_path, tmp_name, sizeof(srcaddr.un.sun_path));
free (tmp_name);
}
nsi_set_localaddr(cs.sock_nsi, &srcaddr.storage, SUN_LEN((struct sockaddr_un *)&srcaddr.storage));
if (o.verbose)
loguser("[%s] used as source DGRAM Unix domain socket.\n", srcaddr.un.sun_path);
}
else
#endif
if (srcaddr.storage.ss_family != AF_UNSPEC)
nsi_set_localaddr(cs.sock_nsi, &srcaddr.storage, sizeof(srcaddr.storage));
if (o.numsrcrtes) {
unsigned char *ipopts = NULL;
size_t ipoptslen = 0;
if (o.af != AF_INET)
bye("Sorry, -g can only currently be used with IPv4.");
ipopts = buildsrcrte(targetss.in.sin_addr, o.srcrtes, o.numsrcrtes, o.srcrteptr, &ipoptslen);
nsi_set_ipoptions(cs.sock_nsi, ipopts, ipoptslen);
free(ipopts); /* Nsock has its own copy */
}
#if HAVE_SYS_UN_H
if (o.af == AF_UNIX) {
if (o.udp) {
nsock_connect_unixsock_datagram(mypool, cs.sock_nsi, connect_handler, NULL,
&targetss.sockaddr,
SUN_LEN((struct sockaddr_un *)&targetss.sockaddr));
} else {
nsock_connect_unixsock_stream(mypool, cs.sock_nsi, connect_handler, o.conntimeout,
NULL, &targetss.sockaddr,
SUN_LEN((struct sockaddr_un *)&targetss.sockaddr));
}
} else
#endif
if (o.udp) {
nsock_connect_udp(mypool, cs.sock_nsi, connect_handler,
NULL, &targetss.sockaddr, targetsslen,
inet_port(&targetss));
}
#ifdef HAVE_OPENSSL
else if (o.sctp && o.ssl) {
nsock_connect_ssl(mypool, cs.sock_nsi, connect_handler,
o.conntimeout, NULL,
&targetss.sockaddr, targetsslen,
IPPROTO_SCTP, inet_port(&targetss),
NULL);
}
#endif
else if (o.sctp) {
nsock_connect_sctp(mypool, cs.sock_nsi, connect_handler,
o.conntimeout, NULL,
&targetss.sockaddr, targetsslen,
inet_port(&targetss));
}
#ifdef HAVE_OPENSSL
else if (o.ssl) {
nsock_connect_ssl(mypool, cs.sock_nsi, connect_handler,
o.conntimeout, NULL,
&targetss.sockaddr, targetsslen,
IPPROTO_TCP, inet_port(&targetss),
NULL);
}
#endif
else {
nsock_connect_tcp(mypool, cs.sock_nsi, connect_handler,
o.conntimeout, NULL,
&targetss.sockaddr, targetsslen,
inet_port(&targetss));
}
} else {
/* A proxy connection. */
static int connect_socket;
int len;
char *line;
size_t n;
if (httpconnect.storage.ss_family != AF_UNSPEC) {
connect_socket = do_proxy_http();
if (connect_socket == -1)
return 1;
} else if (socksconnect.storage.ss_family != AF_UNSPEC) {
struct socket_buffer stateful_buf;
struct socks4_data socks4msg;
char socksbuf[8];
connect_socket = do_connect(SOCK_STREAM);
if (connect_socket == -1) {
loguser("Proxy connection failed: %s.\n", socket_strerror(socket_errno()));
return 1;
}
socket_buffer_init(&stateful_buf, connect_socket);
if (o.verbose) {
loguser("Connected to proxy %s:%hu\n", inet_socktop(&targetss),
inet_port(&targetss));
}
/* Fill the socks4_data struct */
zmem(&socks4msg, sizeof(socks4msg));
socks4msg.version = SOCKS4_VERSION;
socks4msg.type = SOCKS_CONNECT;
socks4msg.port = socksconnect.in.sin_port;
socks4msg.address = socksconnect.in.sin_addr.s_addr;
if (o.proxy_auth)
Strncpy(socks4msg.username, (char *) o.proxy_auth, sizeof(socks4msg.username));
len = 8 + strlen(socks4msg.username) + 1;
if (send(connect_socket, (char *) &socks4msg, len, 0) < 0) {
loguser("Error sending proxy request: %s.\n", socket_strerror(socket_errno()));
return 1;
}
/* The size of the socks4 response is 8 bytes. So read exactly
8 bytes from the buffer */
if (socket_buffer_readcount(&stateful_buf, socksbuf, 8) < 0) {
loguser("Error: short reponse from proxy.\n");
return 1;
}
if (socksbuf[1] != 90) {
loguser("Proxy connection failed.\n");
return 1;
}
/* Clear out whatever is left in the socket buffer which may be
already sent by proxy server along with http response headers. */
line = socket_buffer_remainder(&stateful_buf, &n);
/* Write the leftover data to stdout. */
Write(STDOUT_FILENO, line, n);
}
/* Once the proxy negotiation is done, Nsock takes control of the
socket. */
cs.sock_nsi = nsi_new2(mypool, connect_socket, NULL);
/* Create IOD for nsp->stdin */
if ((cs.stdin_nsi = nsi_new2(mypool, 0, NULL)) == NULL)
bye("Failed to create stdin nsiod.");
post_connect(mypool, cs.sock_nsi);
}
/* connect */
rc = nsock_loop(mypool, -1);
if (o.verbose) {
struct timeval end_time;
double time;
gettimeofday(&end_time, NULL);
time = TIMEVAL_MSEC_SUBTRACT(end_time, start_time) / 1000.0;
loguser("%lu bytes sent, %lu bytes received in %.2f seconds.\n",
nsi_get_write_count(cs.sock_nsi),
nsi_get_read_count(cs.sock_nsi), time);
}
#if HAVE_SYS_UN_H
if (o.af == AF_UNIX && o.udp) {
if (o.verbose)
loguser("Deleting source DGRAM Unix domain socket. [%s]\n", srcaddr.un.sun_path);
unlink(srcaddr.un.sun_path);
}
#endif
nsp_delete(mypool);
return rc == NSOCK_LOOP_ERROR ? 1 : 0;
}
int select_loop(mspool *nsp, int msec_timeout) {
int results_left = 0;
int event_msecs; /* msecs before an event goes off */
int combined_msecs;
int sock_err = 0;
struct timeval select_tv;
struct timeval *select_tv_p;
struct select_engine_info *sinfo = (struct select_engine_info *)nsp->engine_data;
assert(msec_timeout >= -1);
if (nsp->events_pending == 0)
return 0; /* No need to wait on 0 events ... */
do {
nsock_log_debug_all(nsp, "wait for events");
if (nsp->next_ev.tv_sec == 0)
event_msecs = -1; /* None of the events specified a timeout */
else
event_msecs = MAX(0, TIMEVAL_MSEC_SUBTRACT(nsp->next_ev, nsock_tod));
#if HAVE_PCAP
#ifndef PCAP_CAN_DO_SELECT
/* Force a low timeout when capturing packets on systems where
* the pcap descriptor is not select()able. */
if (GH_LIST_COUNT(&nsp->pcap_read_events))
if (event_msecs > PCAP_POLL_INTERVAL)
event_msecs = PCAP_POLL_INTERVAL;
#endif
#endif
/* We cast to unsigned because we want -1 to be very high (since it means no
* timeout) */
combined_msecs = MIN((unsigned)event_msecs, (unsigned)msec_timeout);
/* Set up the timeval pointer we will give to select() */
memset(&select_tv, 0, sizeof(select_tv));
if (combined_msecs > 0) {
select_tv.tv_sec = combined_msecs / 1000;
select_tv.tv_usec = (combined_msecs % 1000) * 1000;
select_tv_p = &select_tv;
} else if (combined_msecs == 0) {
/* we want the tv_sec and tv_usec to be zero but they already are from bzero */
select_tv_p = &select_tv;
} else {
assert(combined_msecs == -1);
select_tv_p = NULL;
}
#if HAVE_PCAP
#ifndef PCAP_CAN_DO_SELECT
/* do non-blocking read on pcap devices that doesn't support select()
* If there is anything read, just leave this loop. */
if (pcap_read_on_nonselect(nsp)) {
/* okay, something was read. */
} else
#endif
#endif
{
/* Set up the descriptors for select */
sinfo->fds_results_r = sinfo->fds_master_r;
sinfo->fds_results_w = sinfo->fds_master_w;
sinfo->fds_results_x = sinfo->fds_master_x;
results_left = fselect(sinfo->max_sd + 1, &sinfo->fds_results_r,
&sinfo->fds_results_w, &sinfo->fds_results_x, select_tv_p);
if (results_left == -1)
sock_err = socket_errno();
}
gettimeofday(&nsock_tod, NULL); /* Due to select delay */
} while (results_left == -1 && sock_err == EINTR); /* repeat only if signal occurred */
if (results_left == -1 && sock_err != EINTR) {
nsock_log_error(nsp, "nsock_loop error %d: %s", sock_err, socket_strerror(sock_err));
nsp->errnum = sock_err;
return -1;
}
iterate_through_event_lists(nsp);
return 1;
}
int poll_loop(struct npool *nsp, int msec_timeout) {
int results_left = 0;
int event_msecs; /* msecs before an event goes off */
int combined_msecs;
int sock_err = 0;
struct poll_engine_info *pinfo = (struct poll_engine_info *)nsp->engine_data;
assert(msec_timeout >= -1);
if (nsp->events_pending == 0)
return 0; /* No need to wait on 0 events ... */
do {
struct nevent *nse;
nsock_log_debug_all(nsp, "wait for events");
nse = next_expirable_event(nsp);
if (!nse)
event_msecs = -1; /* None of the events specified a timeout */
else
event_msecs = MAX(0, TIMEVAL_MSEC_SUBTRACT(nse->timeout, nsock_tod));
#if HAVE_PCAP
#ifndef PCAP_CAN_DO_SELECT
/* Force a low timeout when capturing packets on systems where
* the pcap descriptor is not select()able. */
if (gh_list_count(&nsp->pcap_read_events) > 0)
if (event_msecs > PCAP_POLL_INTERVAL)
event_msecs = PCAP_POLL_INTERVAL;
#endif
#endif
/* We cast to unsigned because we want -1 to be very high (since it means no
* timeout) */
combined_msecs = MIN((unsigned)event_msecs, (unsigned)msec_timeout);
#if HAVE_PCAP
#ifndef PCAP_CAN_DO_SELECT
/* do non-blocking read on pcap devices that doesn't support select()
* If there is anything read, just leave this loop. */
if (pcap_read_on_nonselect(nsp)) {
/* okay, something was read. */
} else
#endif
#endif
{
results_left = Poll(pinfo->events, pinfo->max_fd + 1, combined_msecs);
if (results_left == -1)
sock_err = socket_errno();
}
gettimeofday(&nsock_tod, NULL); /* Due to poll delay */
} while (results_left == -1 && sock_err == EINTR); /* repeat only if signal occurred */
if (results_left == -1 && sock_err != EINTR) {
nsock_log_error(nsp, "nsock_loop error %d: %s", sock_err, socket_strerror(sock_err));
nsp->errnum = sock_err;
return -1;
}
iterate_through_event_lists(nsp);
return 1;
}
int epoll_loop(mspool *nsp, int msec_timeout) {
int results_left = 0;
int event_msecs; /* msecs before an event goes off */
int combined_msecs;
int sock_err = 0;
struct epoll_engine_info *einfo = (struct epoll_engine_info *)nsp->engine_data;
assert(msec_timeout >= -1);
if (nsp->events_pending == 0)
return 0; /* No need to wait on 0 events ... */
if (GH_LIST_COUNT(&nsp->active_iods) > einfo->evlen) {
einfo->evlen = GH_LIST_COUNT(&nsp->active_iods) * 2;
einfo->events = (struct epoll_event *)safe_realloc(einfo->events, einfo->evlen * sizeof(struct epoll_event));
}
do {
if (nsp->tracelevel > 6)
nsock_trace(nsp, "wait_for_events");
if (nsp->next_ev.tv_sec == 0)
event_msecs = -1; /* None of the events specified a timeout */
else
event_msecs = MAX(0, TIMEVAL_MSEC_SUBTRACT(nsp->next_ev, nsock_tod));
#if HAVE_PCAP
#ifndef PCAP_CAN_DO_SELECT
/* Force a low timeout when capturing packets on systems where
* the pcap descriptor is not select()able. */
if (GH_LIST_COUNT(&nsp->pcap_read_events) > 0)
if (event_msecs > PCAP_POLL_INTERVAL)
event_msecs = PCAP_POLL_INTERVAL;
#endif
#endif
/* We cast to unsigned because we want -1 to be very high (since it means no
* timeout) */
combined_msecs = MIN((unsigned)event_msecs, (unsigned)msec_timeout);
#if HAVE_PCAP
#ifndef PCAP_CAN_DO_SELECT
/* do non-blocking read on pcap devices that doesn't support select()
* If there is anything read, just leave this loop. */
if (pcap_read_on_nonselect(nsp)) {
/* okay, something was read. */
} else
#endif
#endif
{
if (einfo->evlen)
results_left = epoll_wait(einfo->epfd, einfo->events, einfo->evlen, combined_msecs);
else
results_left = 0;
if (results_left == -1)
sock_err = socket_errno();
}
gettimeofday(&nsock_tod, NULL); /* Due to epoll delay */
} while (results_left == -1 && sock_err == EINTR); /* repeat only if signal occurred */
if (results_left == -1 && sock_err != EINTR) {
nsock_trace(nsp, "nsock_loop error %d: %s", sock_err, socket_strerror(sock_err));
nsp->errnum = sock_err;
return -1;
}
iterate_through_event_lists(nsp, results_left);
return 1;
}