| blob | 56156c0321938e7b126903ec776222bf3076c73f |
1 /* Copyright (c) 2001 Matej Pfajfar.
2 * Copyright (c) 2001-2004, Roger Dingledine.
3 * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
4 * Copyright (c) 2007-2021, The Tor Project, Inc. */
5 /* See LICENSE for licensing information */
7 /**
8 * \file relay.c
9 * \brief Handle relay cell encryption/decryption, plus packaging and
10 * receiving from circuits, plus queuing on circuits.
11 *
12 * This is a core modules that makes Tor work. It's responsible for
13 * dealing with RELAY cells (the ones that travel more than one hop along a
14 * circuit), by:
15 * <ul>
16 * <li>constructing relays cells,
17 * <li>encrypting relay cells,
18 * <li>decrypting relay cells,
19 * <li>demultiplexing relay cells as they arrive on a connection,
20 * <li>queueing relay cells for retransmission,
21 * <li>or handling relay cells that are for us to receive (as an exit or a
22 * client).
23 * </ul>
24 *
25 * RELAY cells are generated throughout the code at the client or relay side,
26 * using relay_send_command_from_edge() or one of the functions like
27 * connection_edge_send_command() that calls it. Of particular interest is
28 * connection_edge_package_raw_inbuf(), which takes information that has
29 * arrived on an edge connection socket, and packages it as a RELAY_DATA cell
30 * -- this is how information is actually sent across the Tor network. The
31 * cryptography for these functions is handled deep in
32 * circuit_package_relay_cell(), which either adds a single layer of
33 * encryption (if we're an exit), or multiple layers (if we're the origin of
34 * the circuit). After construction and encryption, the RELAY cells are
35 * passed to append_cell_to_circuit_queue(), which queues them for
36 * transmission and tells the circuitmux (see circuitmux.c) that the circuit
37 * is waiting to send something.
38 *
39 * Incoming RELAY cells arrive at circuit_receive_relay_cell(), called from
40 * command.c. There they are decrypted and, if they are for us, are passed to
41 * connection_edge_process_relay_cell(). If they're not for us, they're
42 * re-queued for retransmission again with append_cell_to_circuit_queue().
43 *
44 * The connection_edge_process_relay_cell() function handles all the different
45 * types of relay cells, launching requests or transmitting data as needed.
46 **/
48 #define RELAY_PRIVATE
107 cell_direction_t cell_direction,
131 /** Stats: how many relay cells have originated at this hop, or have
132 * been relayed onward (not recognized at this hop)?
133 */
135 /** Stats: how many relay cells have been delivered to streams at this
136 * hop?
137 */
139 /** Stats: how many circuits have we closed due to the cell queue limit being
140 * reached (see append_cell_to_circuit_queue()) */
144 /**
145 * Update channel usage state based on the type of relay cell and
146 * circuit properties.
147 *
148 * This is needed to determine if a client channel is being
149 * used for application traffic, and if a relay channel is being
150 * used for multihop circuits and application traffic. The decision
151 * to pad in channelpadding.c depends upon this info (as well as
152 * consensus parameters) to decide what channels to pad.
153 */
154 static void
156 {
158 /*
159 * The client state was first set much earlier in
160 * circuit_send_next_onion_skin(), so we can start padding as early as
161 * possible.
162 *
163 * However, if padding turns out to be expensive, we may want to not do
164 * it until actual application traffic starts flowing (which is controlled
165 * via consensus param nf_pad_before_usage).
166 *
167 * So: If we're an origin circuit and we've created a full length circuit,
168 * then any CELL_RELAY cell means application data. Increase the usage
169 * state of the channel to indicate this.
170 *
171 * We want to wait for CELL_RELAY specifically here, so we know that
172 * the channel was definitely being used for data and not for extends.
173 * By default, we pad as soon as a channel has been used for *any*
174 * circuits, so this state is irrelevant to the padding decision in
175 * the default case. However, if padding turns out to be expensive,
176 * we would like the ability to avoid padding until we're absolutely
177 * sure that a channel is used for enough application data to be worth
178 * padding.
179 *
180 * (So it does not matter that CELL_RELAY_EARLY can actually contain
181 * application data. This is only a load reducing option and that edge
182 * case does not matter if we're desperately trying to reduce overhead
183 * anyway. See also consensus parameter nf_pad_before_usage).
184 */
191 }
193 /* If we're a relay circuit, the question is more complicated. Basically:
194 * we only want to pad connections that carry multihop (anonymous)
195 * circuits.
196 *
197 * We assume we're more than one hop if either the previous hop
198 * is not a client, or if the previous hop is a client and there's
199 * a next hop. Then, circuit traffic starts at RELAY_EARLY, and
200 * user application traffic starts when we see RELAY cells.
201 */
212 }
215 }
216 }
217 }
218 }
220 /** Receive a relay cell:
221 * - Crypt it (encrypt if headed toward the origin or if we <b>are</b> the
222 * origin; decrypt if we're headed toward the exit).
223 * - Check if recognized (if exitward).
224 * - If recognized and the digest checks out, then find if there's a stream
225 * that the cell is intended for, and deliver it to the right
226 * connection_edge.
227 * - If not recognized, then we need to relay it: append it to the appropriate
228 * cell_queue on <b>circ</b>.
229 *
230 * Return -<b>reason</b> on failure.
231 */
232 int
234 cell_direction_t cell_direction)
235 {
253 }
260 /* Recognized cell, the cell digest has been updated, we'll record it for
261 * the SENDME if need be. */
267 }
269 /* We need to drop this cell no matter what to avoid code that expects
270 * a certain purpose (such as the hidserv code). */
272 }
281 "connection_edge_process_relay_cell (away from origin) "
284 }
285 }
290 layer_hint);
292 /* If a client is trying to connect to unknown hidden service port,
293 * END_CIRC_AT_ORIGIN is sent back so we can then close the circuit.
294 * Do not log warn as this is an expected behavior for a service. */
298 }
300 }
301 }
303 }
305 /* not recognized. inform circpad and pass it on. */
317 /* If we see unrecognized cells on path bias testing circs,
318 * it's bad mojo. Those circuits need to die.
319 * XXX: Shouldn't they always die? */
325 }
326 }
329 // XXXX Can this splice stuff be done more cleanly?
342 /* XXXX Do this here, or just return -1? */
345 }
347 }
349 /* Should be impossible at this point. */
351 }
356 "Didn't recognize a cell, but circ stops here! Closing circuit. "
358 }
360 }
365 * we might kill the circ before we relay
366 * the cells. */
370 }
372 }
374 /** Package a relay cell from an edge:
375 * - Encrypt it to the right layer
376 * - Append it to the appropriate cell_queue on <b>circ</b>.
377 *
378 * Return 1 if the cell was successfully sent as in queued on the circuit.
379 * Return 0 if the cell needs to be dropped as in ignored.
380 * Return -1 on error for which the circuit should be marked for close. */
383 cell_direction_t cell_direction,
386 {
390 /* Circuit is marked; send nothing. */
392 }
398 " Dropping. Circuit is in state %s (%d), and is "
406 }
409 }
415 }
419 /* Update circ written totals for control port */
422 CELL_PAYLOAD_SIZE);
426 /* We should never package an _incoming_ cell from the circuit
427 * origin; that means we messed up somewhere. */
431 }
435 }
440 }
442 /** If cell's stream_id matches the stream_id of any conn that's
443 * attached to circ, return that conn, else return NULL.
444 */
448 {
450 relay_header_t rh;
457 /* IN or OUT cells could have come from either direction, now
458 * that we allow rendezvous *to* an OP.
459 */
468 }
469 }
479 }
480 }
487 }
488 }
489 }
491 }
493 /** Pack the relay_header_t host-order structure <b>src</b> into
494 * network-order in the buffer <b>dest</b>. See tor-spec.txt for details
495 * about the wire format.
496 */
497 void
499 {
505 }
507 /** Unpack the network-order buffer <b>src</b> into a host-order
508 * relay_header_t structure <b>dest</b>.
509 */
510 void
512 {
518 }
520 /** Convert the relay <b>command</b> into a human-readable string. */
523 {
561 }
562 }
564 /** When padding a cell with randomness, leave this many zeros after the
565 * payload. */
566 #define CELL_PADDING_GAP 4
568 /** Return the offset where the padding should start. The <b>data_len</b> is
569 * the relay payload length expected to be put in the cell. It can not be
570 * bigger than RELAY_PAYLOAD_SIZE else this function assert().
571 *
572 * Value will always be smaller than CELL_PAYLOAD_SIZE because this offset is
573 * for the entire cell length not just the data payload length. Zero is
574 * returned if there is no room for padding.
575 *
576 * This function always skips the first 4 bytes after the payload because
577 * having some unused zero bytes has saved us a lot of times in the past. */
579 STATIC size_t
581 {
582 /* This is never supposed to happen but in case it does, stop right away
583 * because if tor is tricked somehow into not adding random bytes to the
584 * payload with this function returning 0 for a bad data_len, the entire
585 * authenticated SENDME design can be bypassed leading to bad denial of
586 * service attacks. */
589 /* If the offset is larger than the cell payload size, we return an offset
590 * of zero indicating that no padding needs to be added. */
594 }
596 }
598 /* Add random bytes to the unused portion of the payload, to foil attacks
599 * where the other side can predict all of the bytes in the payload and thus
600 * compute the authenticated SENDME cells without seeing the traffic. See
601 * proposal 289. */
602 static void
604 {
611 /* We can't add padding so we are done. */
613 }
615 /* Remember here that the cell_payload is the length of the header and
616 * payload size so we offset it using the full length of the cell. */
620 }
622 /** Make a relay cell out of <b>relay_command</b> and <b>payload</b>, and send
623 * it onto the open circuit <b>circ</b>. <b>stream_id</b> is the ID on
624 * <b>circ</b> for the stream that's sending the relay cell, or 0 if it's a
625 * control cell. <b>cpath_layer</b> is NULL for OR->OP cells, or the
626 * destination hop for OP->OR cells.
627 *
628 * If you can't send the cell, mark the circuit for close and return -1. Else
629 * return 0.
630 */
636 {
637 cell_t cell;
638 relay_header_t rh;
639 cell_direction_t cell_direction;
642 /* If conflux is enabled, decide which leg to send on, and use that */
645 relay_command);
653 /* Conflux circuits always send multiplexed relay commands to
654 * to the last hop. (Non-multiplexed commands go on their
655 * original circuit and hop). */
657 }
658 }
660 /* XXXX NM Split this function into a separate versions per circuit type? */
675 }
686 /* Add random padding to the cell if we can. */
692 /* Tell circpad we're sending a relay cell */
695 /* If we are sending an END cell and this circuit is used for a tunneled
696 * directory request, advance its state. */
699 DIRREQ_END_CELL_SENT);
702 /* if we're using relaybandwidthrate, this conn wants priority */
704 }
712 /* If we've got any relay_early cells left and (we're sending
713 * an extend cell or we're not talking to the first hop), use
714 * one of them. Don't worry about the conn protocol version:
715 * append_cell_to_circuit_queue will fix it up. */
717 /* If we're out of relay early cells, tell circpad */
722 /* Memorize the command that is sent as RELAY_EARLY cell; helps debug
723 * task 878. */
728 /* If no RELAY_EARLY cells can be sent over this circuit, log which
729 * commands have been sent as RELAY_EARLY cells before; helps debug
730 * task 878. */
739 "but we have run out of RELAY_EARLY cells on that circuit. "
743 }
745 /* Let's assume we're well-behaved: Anything that we decide to send is
746 * valid, delivered data. */
748 }
752 lineno);
757 /* This means we should drop the cell or that the circuit was already
758 * marked for close. At this point in time, we do NOT close the circuit if
759 * the cell is dropped. It is not the case with arti where each circuit
760 * protocol violation will lead to closing the circuit. */
762 }
764 /* At this point, we are certain that the cell was queued on the circuit and
765 * thus will be sent on the wire. */
769 }
771 /* If applicable, note the cell digest for the SENDME version 1 purpose if
772 * we need to. This call needs to be after the circuit_package_relay_cell()
773 * because the cell digest is set within that function. */
777 /* Handle the circuit-level SENDME package window. */
779 /* Package window has gone under 0. Protocol issue. */
784 }
785 }
788 }
790 /** Make a relay cell out of <b>relay_command</b> and <b>payload</b>, and
791 * send it onto the open circuit <b>circ</b>. <b>fromconn</b> is the stream
792 * that's sending the relay cell, or NULL if it's a control cell.
793 * <b>cpath_layer</b> is NULL for OR->OP cells, or the destination hop
794 * for OP->OR cells.
795 *
796 * If you can't send the cell, mark the circuit for close and
797 * return -1. Else return 0.
798 */
799 int
803 {
804 /* XXXX NM Split this function into a separate versions per circuit type? */
817 }
823 END_STREAM_REASON_INTERNAL);
829 }
831 }
834 /* The circuit has been marked, but not freed yet. When it's freed, it
835 * will mark this connection for close. */
837 }
839 #ifdef MEASUREMENTS_21206
840 /* Keep track of the number of RELAY_DATA cells sent for directory
841 * connections. */
846 }
852 }
854 /** How many times will I retry a stream that fails due to DNS
855 * resolve failure or misc error?
856 */
857 #define MAX_RESOLVE_FAILURES 3
859 /** Return 1 if reason is something that you should retry if you
860 * get the end cell before you've connected; else return 0. */
861 static int
863 {
870 }
872 /** Called when we receive an END cell on a stream that isn't open yet,
873 * from the client side.
874 * Arguments are as for connection_edge_process_relay_cell().
875 */
876 static int
880 {
890 /* Both of these reasons could mean a failed tag
891 * hit the exit and it complained. Do not probe.
892 * Fail the circuit. */
896 /* We can't infer success or failure, since older Tors report
897 * ENETUNREACH as END_STREAM_REASON_INTERNAL. */
899 /* Path bias: If we get a valid reason code from the exit,
900 * it wasn't due to tagging.
901 *
902 * We rely on recognized+digest being strong enough to make
903 * tags unlikely to allow us to get tagged, yet 'recognized'
904 * reason codes here. */
906 }
907 }
909 /* This end cell is now valid. */
914 }
919 /* avoid retry if rend */
929 tor_addr_t addr;
944 }
950 }
957 "Got an EXITPOLICY failure on a connection with a "
961 }
968 }
974 {
981 }
982 }
983 }
984 /* check if the exit *ought* to have allowed it */
987 conn,
988 exitrouter,
993 /* stop wanting a specific exit */
995 /* A non-zero chosen_exit_retries can happen if we set a
996 * TrackHostExits for this address under a port that the exit
997 * relay allows, but then try the same address with a different
998 * port that it doesn't allow to exit. We shouldn't unregister
999 * the mapping, since it is probably still wanted on the
1000 * original port. But now we give away to the exit relay that
1001 * we probably have a TrackHostExits on it. So be it. */
1004 }
1007 /* else, conn will get closed below */
1009 }
1013 /* Else fall through: expire this circuit, clear the
1014 * chosen_exit_name field, and try again. */
1015 FALLTHROUGH;
1022 /* We haven't retried too many times; reattach the connection. */
1024 /* Mark this circuit "unusable for new streams". */
1028 /* stop wanting a specific exit */
1031 }
1034 /* else, conn will get closed below */
1037 "Have tried resolving or connecting to address '%s' "
1040 MAX_RESOLVE_FAILURES);
1041 /* clear the failures, so it will have a full try next time */
1043 }
1049 }
1051 /* stop wanting a specific exit */
1054 }
1057 /* else, will close below */
1061 }
1067 /* need to test because of detach_retriable */
1071 }
1073 /** Called when we have gotten an END_REASON_EXITPOLICY failure on <b>circ</b>
1074 * for <b>conn</b>, while attempting to connect via <b>node</b>. If the node
1075 * told us which address it rejected, then <b>addr</b> is that address;
1076 * otherwise it is AF_UNSPEC.
1077 *
1078 * If we are sure the node should have allowed this address, mark the node as
1079 * having a reject *:* exit policy. Otherwise, mark the circuit as unusable
1080 * for this particular address.
1081 **/
1082 static void
1087 {
1092 tor_addr_t tmp;
1099 }
1103 "Exitrouter %s seems to be more restrictive than its exit "
1107 }
1108 }
1112 }
1114 /** Helper: change the socks_request->address field on conn to the
1115 * dotted-quad representation of <b>new_addr</b>,
1116 * and send an appropriate REMAP event. */
1117 static void
1119 {
1124 REMAP_STREAM_SOURCE_EXIT);
1125 }
1127 /** Extract the contents of a connected cell in <b>cell</b>, whose relay
1128 * header has already been parsed into <b>rh</b>. On success, set
1129 * <b>addr_out</b> to the address we're connected to, and <b>ttl_out</b> to
1130 * the ttl of that address, in seconds, and return 0. On failure, return
1131 * -1.
1132 *
1133 * Note that the resulting address can be UNSPEC if the connected cell had no
1134 * address (as for a stream to an union service or a tunneled directory
1135 * connection), and that the ttl can be absent (in which case <b>ttl_out</b>
1136 * is set to -1). */
1137 STATIC int
1140 {
1152 /* If bytes is 0, this is maybe a v6 address. Otherwise it's a v4 address */
1154 /* v4 address */
1160 }
1170 }
1172 }
1174 /** Drop all storage held by <b>addr</b>. */
1175 STATIC void
1177 {
1182 }
1184 /** Parse a resolved cell in <b>cell</b>, with parsed header in <b>rh</b>.
1185 * Return -1 on parse error. On success, add one or more newly allocated
1186 * address_ttl_t to <b>addresses_out</b>; set *<b>errcode_out</b> to
1187 * one of 0, RESOLVED_TYPE_ERROR, or RESOLVED_TYPE_ERROR_TRANSIENT, and
1188 * return 0. */
1189 STATIC int
1192 {
1224 }
1228 }
1247 }
1257 /* Ignore the error contents */
1261 }
1264 }
1267 /* Report an error only if there were no results. */
1269 }
1276 err:
1277 /* On parse error, don't report any results */
1281 }
1283 /** Helper for connection_edge_process_resolved_cell: given an error code,
1284 * an entry_connection, and a list of address_ttl_t *, report the best answer
1285 * to the entry_connection. */
1286 static void
1290 {
1296 /* If it's an error code, that's easy. */
1303 }
1305 /* Get the first answer of each type. */
1310 }
1314 }
1318 }
1319 }
1322 /* Now figure out which type we wanted to deliver. */
1326 RESOLVED_TYPE_HOSTNAME,
1333 }
1335 }
1341 }
1343 /* Now convert it to the ugly old interface */
1348 }
1356 }
1358 /** Handle a RELAY_COMMAND_RESOLVED cell that we received on a non-open AP
1359 * stream. */
1360 STATIC int
1364 {
1373 }
1382 }
1393 }
1399 RESOLVED_TYPE_ERROR_TRANSIENT,
1402 END_STREAM_REASON_TORPROTOCOL);
1404 }
1405 }
1407 /* This is valid data at this point. Count it */
1411 }
1414 errcode,
1415 resolved_addresses);
1418 END_STREAM_REASON_DONE |
1419 END_STREAM_REASON_FLAG_ALREADY_SOCKS_REPLIED);
1421 done:
1426 }
1428 /** An incoming relay cell has arrived from circuit <b>circ</b> to
1429 * stream <b>conn</b>.
1430 *
1431 * The arguments here are the same as in
1432 * connection_edge_process_relay_cell() below; this function is called
1433 * from there when <b>conn</b> is defined and not in an open state.
1434 */
1435 static int
1439 {
1445 layer_hint);
1447 /* we just got an 'end', don't need to send one */
1450 END_STREAM_REASON_FLAG_REMOTE;
1453 }
1454 }
1458 tor_addr_t addr;
1466 }
1480 }
1482 /* The family is not UNSPEC: so we were given an address in the
1483 * connected cell. (This is normal, except for BEGINDIR and onion
1484 * service streams.) */
1493 END_STREAM_REASON_TORPROTOCOL);
1495 }
1500 "Got a connected cell to %s with unsupported address family."
1504 END_STREAM_REASON_TORPROTOCOL);
1506 }
1513 }
1515 /* don't send a socks reply to transparent conns */
1519 }
1521 /* Was it a linked dir conn? If so, a dir request just started to
1522 * fetch something; this could be a bootstrap status milestone. */
1542 }
1543 }
1544 /* This is definitely a success, so forget about any pending data we
1545 * had sent. */
1549 }
1551 /* This is valid data at this point. Count it */
1554 /* handle anything that might have queued */
1556 /* (We already sent an end cell if possible) */
1559 }
1561 }
1565 }
1572 // connection_edge_end(conn, END_STREAM_REASON_TORPROTOCOL);
1573 // connection_mark_for_close(conn);
1574 // return -1;
1575 }
1577 /** Process a SENDME cell that arrived on <b>circ</b>. If it is a stream level
1578 * cell, it is destined for the given <b>conn</b>. If it is a circuit level
1579 * cell, it is destined for the <b>layer_hint</b>. The <b>domain</b> is the
1580 * logging domain that should be used.
1581 *
1582 * Return 0 if everything went well or a negative value representing a circuit
1583 * end reason on error for which the caller is responsible for closing it. */
1584 static int
1588 {
1594 /* Circuit level SENDME cell. */
1600 }
1601 /* Resume reading on any streams now that we've processed a valid
1602 * SENDME cell that updated our package window. */
1604 /* We are done, the rest of the code is for the stream level. */
1606 }
1608 /* No connection, might be half edge state. We are done if so. */
1618 }
1619 }
1624 }
1626 /* Stream level SENDME cell. */
1627 // TODO: Turn this off for cc_alg=1,2,3; use XON/XOFF instead
1630 /* Means we need to close the circuit with reason ret. */
1632 }
1634 /* We've now processed properly a SENDME cell, all windows have been
1635 * properly updated, we'll read on the edge connection to see if we can
1636 * get data out towards the end point (Exit or client) since we are now
1637 * allowed to deliver more cells. */
1640 /* Still waiting for queue to flush; don't touch conn */
1642 }
1644 /* handle whatever might still be on the inbuf */
1646 /* (We already sent an end cell if possible) */
1649 }
1651 }
1653 /** A helper for connection_edge_process_relay_cell(): Actually handles the
1654 * cell that we received on the connection.
1655 *
1656 * The arguments are the same as in the parent function
1657 * connection_edge_process_relay_cell(), plus the relay header <b>rh</b> as
1658 * unpacked by the parent function, and <b>optimistic_data</b> as set by the
1659 * parent function.
1660 */
1661 STATIC int
1665 {
1671 /* First pass the cell to the circuit padding subsystem, in case it's a
1672 * padding cell or circuit that should be handled there. */
1676 }
1678 /* Now handle all the other commands */
1698 }
1702 "Relay begin request to Hidden Service "
1705 }
1710 }
1713 /* Assign this circuit and its app-ward OR connection a unique ID,
1714 * so that we can measure download times. The local edge and dir
1715 * connection will be assigned the same ID when they are created
1716 * and linked. */
1720 }
1736 "data cell on circ %u valid on half-closed "
1738 }
1739 }
1744 }
1746 /* Update our stream-level deliver window that we just received a DATA
1747 * cell. Going below 0 means we have a protocol level error so the
1748 * stream and circuit are closed. */
1754 }
1755 /* Total all valid application bytes delivered */
1758 }
1760 /* For onion service connection, update the metrics. */
1765 }
1771 #ifdef MEASUREMENTS_21206
1772 /* Count number of RELAY_DATA cells received on a linked directory
1773 * connection. */
1778 }
1782 /* Only send a SENDME if we're not getting optimistic data; otherwise
1783 * a SENDME could arrive before the CONNECTED.
1784 */
1786 }
1797 }
1798 }
1800 }
1805 }
1806 }
1816 }
1817 }
1819 }
1824 }
1825 }
1839 "end cell (%s) on circ %u valid on half-closed "
1844 }
1845 }
1849 }
1850 /* XXX add to this log_fn the exit node's nickname? */
1862 }
1863 /* We just *got* an end; no reason to send one. */
1868 /* only mark it if not already marked. it's possible to
1869 * get the 'end' right around when the client hangs up on us. */
1872 /* Total all valid application bytes delivered */
1875 }
1876 }
1881 total_n_extend++;
1886 }
1889 #define EARLY_WARNING_INTERVAL 3600
1903 }
1908 }
1910 }
1912 }
1919 }
1921 {
1922 extended_cell_t extended_cell;
1929 }
1934 * here. */
1935 }
1936 }
1940 }
1941 /* Total all valid bytes delivered. */
1944 }
1951 }
1959 }
1965 trunc_reason);
1967 }
1969 {
1974 }
1981 }
1983 /* Count the truncated as valid, for completeness. The
1984 * circuit is being torn down anyway, though. */
1988 }
1997 }
2005 "connected cell on circ %u valid on half-closed "
2008 }
2009 }
2012 "'connected' received on circid %u for streamid %d, "
2032 }
2039 }
2048 "resolved cell on circ %u valid on half-closed "
2051 }
2052 }
2070 }
2072 "Received unknown relay command %d. Perhaps the other side is using "
2076 }
2078 /** An incoming relay cell has arrived on circuit <b>circ</b>. If
2079 * <b>conn</b> is NULL this is a control cell, else <b>cell</b> is
2080 * destined for <b>conn</b>.
2081 *
2082 * If <b>layer_hint</b> is defined, then we're the origin of the
2083 * circuit, and it specifies the hop that packaged <b>cell</b>.
2084 *
2085 * Return -reason if you want to warn and tear down the circuit, else 0.
2086 */
2087 STATIC int
2091 {
2093 relay_header_t rh;
2100 // log_fn(LOG_DEBUG,"command %d stream %d", rh.command, rh.stream_id);
2101 num_seen++;
2109 }
2123 ;
2124 }
2125 }
2127 /* Regardless of conflux or not, we always decide to send a SENDME
2128 * for RELAY_DATA immediately
2129 */
2131 /* Update our circuit-level deliver window that we received a DATA cell.
2132 * If the deliver window goes below 0, we end the circuit and stream due
2133 * to a protocol failure. */
2139 }
2141 /* Consider sending a circuit-level SENDME cell. */
2144 /* Continue on to process the data cell via conflux or not */
2145 }
2147 /* Conflux handling: If conflux is disabled, or the relay command is not
2148 * multiplexed across circuits, then process it immediately.
2149 *
2150 * Otherwise, we need to process the relay cell against our conflux
2151 * queues, and if doing so results in ordered cells to deliver, we
2152 * dequeue and process those in-order until there are no more.
2153 */
2158 // If conflux says this cell is in-order, then begin processing
2159 // cells from queue until there are none. Otherwise, we do nothing
2160 // until further cells arrive.
2165 /* First, process this cell */
2169 }
2171 /* Now, check queue for more */
2175 layer_hint);
2179 /* Negative return value is a fatal error. Return early and tear down
2180 * circuit */
2183 }
2185 }
2186 }
2187 }
2190 }
2192 /**
2193 * Helper function to process a relay cell that is in the proper order
2194 * for processing right now. */
2195 static int
2200 {
2202 * that's in the EXIT_CONN_STATE_RESOLVING
2203 * or EXIT_CONN_STATE_CONNECTING states. */
2205 /* Tell circpad that we've received a recognized cell */
2208 /* either conn is NULL, in which case we've got a control cell, or else
2209 * conn points to the recognized stream. */
2215 /* Allow DATA cells to be delivered to an exit node in state
2216 * EXIT_CONN_STATE_CONNECTING or EXIT_CONN_STATE_RESOLVING.
2217 * This speeds up HTTP, for example. */
2225 }
2226 }
2230 }
2232 /** How many relay_data cells have we built, ever? */
2234 /** How many bytes of data have we put in relay_data cells have we built,
2235 * ever? This would be RELAY_PAYLOAD_SIZE*stats_n_data_cells_packaged if
2236 * every relay cell we ever sent were completely full of data. */
2238 /** How many relay_data cells have we received, ever? */
2240 /** How many bytes of data have we received relay_data cells, ever? This would
2241 * be RELAY_PAYLOAD_SIZE*stats_n_data_cells_packaged if every relay cell we
2242 * ever received were completely full of data. */
2245 /**
2246 * Called when initializing a circuit, or when we have reached the end of the
2247 * window in which we need to send some randomness so that incoming sendme
2248 * cells will be unpredictable. Resets the flags and picks a new window.
2249 */
2250 void
2252 {
2254 // XXX: do we need to change this check for congestion control?
2257 }
2259 /**
2260 * Any relay data payload containing fewer than this many real bytes is
2261 * considered to have enough randomness to.
2262 **/
2263 #define RELAY_PAYLOAD_LENGTH_FOR_RANDOM_SENDMES \
2264 (RELAY_PAYLOAD_SIZE - CELL_PADDING_GAP - 16)
2266 /**
2267 * Helper. Return the number of bytes that should be put into a cell from a
2268 * given edge connection on which <b>n_available</b> bytes are available.
2269 */
2270 STATIC size_t
2274 {
2278 /* Do we need to force this payload to have space for randomness? */
2283 /* At most how much would we like to send in this cell? */
2289 }
2291 /* Decide how many bytes we will actually put into this cell. */
2298 else
2300 }
2302 /* If we reach this point, we will be definitely sending the cell. */
2306 /* This cell will have enough randomness in the padding to make a future
2307 * sendme cell unpredictable. */
2309 }
2312 /* Either this cell, or some previous cell, had enough padding to
2313 * ensure sendme unpredictability. */
2315 /* Pick a new interval in which we need to send randomness. */
2317 }
2322 }
2324 /** If <b>conn</b> has an entire relay payload of bytes on its inbuf (or
2325 * <b>package_partial</b> is true), and the appropriate package windows aren't
2326 * empty, grab a cell and send it down the circuit.
2327 *
2328 * If *<b>max_cells</b> is given, package no more than max_cells. Decrement
2329 * *<b>max_cells</b> by the number of cells packaged.
2330 *
2331 * Return -1 (and send a RELAY_COMMAND_END cell if necessary) if conn should
2332 * be marked for close, else return 0.
2333 */
2334 int
2337 {
2346 entry_conn &&
2358 }
2363 repeat_connection_edge_package_raw_inbuf:
2370 }
2380 }
2391 }
2394 }
2401 /* If we reach this point, we will definitely be packaging bytes into
2402 * a cell. */
2408 /* XXXX We could be more efficient here by sometimes packing
2409 * previously-sent optimistic data in the same cell with data
2410 * from the inbuf. */
2415 }
2418 }
2425 /* This is new optimistic data; remember it in case we need to detach and
2426 retry */
2430 }
2432 /* Send a data cell. This handles the circuit package window. */
2435 /* circuit got marked for close, don't continue, don't need to mark conn */
2437 }
2439 /* Handle the stream-level SENDME package window. */
2445 }
2452 }
2454 /* handle more if there's more, or return 0 if there isn't */
2456 }
2458 /** The circuit <b>circ</b> has received a circuit-level sendme
2459 * (on hop <b>layer_hint</b>, if we're the OP). Go through all the
2460 * attached streams and let them resume reading and packaging, if
2461 * their stream windows allow it.
2462 */
2463 static void
2465 {
2469 }
2471 /* If we have a conflux negotiated, and it still can't send on
2472 * any circuit, then do not resume sending. */
2477 }
2484 else
2487 }
2489 /** A helper function for circuit_resume_edge_reading() above.
2490 * The arguments are the same, except that <b>conn</b> is the head
2491 * of a linked list of edge streams that should each be considered.
2492 */
2493 static int
2497 {
2507 /* Don't bother to try to do the rest of this if there are no connections
2508 * to resume. */
2510 }
2512 /* Once we used to start listening on the streams in the order they
2513 * appeared in the linked list. That leads to starvation on the
2514 * streams that appeared later on the list, since the first streams
2515 * would always get to read first. Instead, we just pick a random
2516 * stream on the list, and enable reading for streams starting at that
2517 * point (and wrapping around as if the list were circular). It would
2518 * probably be better to actually remember which streams we've
2519 * serviced in the past, but this is simple and effective. */
2521 /* Select a stream uniformly at random from the linked list. We
2522 * don't need cryptographic randomness here. */
2523 {
2526 num_streams++;
2530 }
2531 /* Invariant: chosen_stream has been chosen uniformly at random from
2532 * among the first num_streams streams on first_conn.
2533 *
2534 * (Note that we iterate over every stream on the circuit, so that after
2535 * we've considered the first stream, we've chosen it with P=1; and
2536 * after we consider the second stream, we've switched to it with P=1/2
2537 * and stayed with the first stream with P=1/2; and after we've
2538 * considered the third stream, we've switched to it with P=1/3 and
2539 * remained with one of the first two streams with P=(2/3), giving each
2540 * one P=(1/2)(2/3) )=(1/3).) */
2541 }
2542 }
2544 /* Count how many non-marked streams there are that have anything on
2545 * their inbuf, and enable reading on all of the connections. */
2547 /* Activate reading starting from the chosen stream */
2549 /* Start reading for the streams starting from here */
2556 }
2560 }
2561 }
2562 /* Go back and do the ones we skipped, circular-style */
2570 }
2574 }
2575 }
2580 again:
2582 /* If we're using conflux, the circuit we decide to send on may change
2583 * after we're sending. Get it again, and re-check package windows
2584 * for it */
2591 /* Get the destination layer hint for this circuit */
2593 }
2595 /* How many cells do we have space for? It will be the minimum of
2596 * the number needed to exhaust the package window, and the minimum
2597 * needed to fill the cell queue. */
2604 }
2613 /* Iterate over all connections. Package up to cells_per_conn cells on
2614 * each. Update packaged_this_round with the total number of cells
2615 * packaged, and n_streams_left with the number that still have data to
2616 * package.
2617 */
2623 /* handle whatever might still be on the inbuf */
2626 /* Note how many we packaged */
2630 /* Problem while packaging. (We already sent an end cell if
2631 * possible) */
2634 }
2636 /* If there's still data to read, we'll be coming back to this stream. */
2640 /* If the circuit won't accept any more data, return without looking
2641 * at any more of the streams. Any connections that should be stopped
2642 * have already been stopped by connection_edge_package_raw_inbuf. */
2645 /* XXXX should we also stop immediately if we fill up the cell queue?
2646 * Probably. */
2647 }
2648 }
2650 /* If we made progress, and we are willing to package more, and there are
2651 * any streams left that want to package stuff... try again!
2652 */
2654 n_streams_left) {
2657 }
2660 }
2662 /** Check if the package window for <b>circ</b> is empty (at
2663 * hop <b>layer_hint</b> if it's defined).
2664 *
2665 * If yes, tell edge streams to stop reading and return 1.
2666 * Else return 0.
2667 */
2668 static int
2670 {
2683 }
2685 }
2686 /* else, layer hint is defined, use it */
2695 }
2697 }
2699 }
2701 /** The total number of cells we have allocated. */
2704 /** Release storage held by <b>cell</b>. */
2707 {
2710 }
2712 /** Allocate and return a new packed_cell_t. */
2713 STATIC packed_cell_t *
2715 {
2718 }
2720 /** Return a packed cell used outside by channel_t lower layer */
2721 void
2723 {
2727 }
2729 /** Log current statistics for cell pool allocation at log level
2730 * <b>severity</b>. */
2731 void
2733 {
2741 }
2746 }
2748 /** Allocate a new copy of packed <b>cell</b>. */
2751 {
2755 }
2757 /** Append <b>cell</b> to the end of <b>queue</b>. */
2758 void
2760 {
2763 }
2765 /** Append a newly allocated copy of <b>cell</b> to the end of the
2766 * <b>exitward</b> (or app-ward) <b>queue</b> of <b>circ</b>. If
2767 * <b>use_stats</b> is true, record statistics about the cell.
2768 */
2769 void
2773 {
2782 }
2784 /** Initialize <b>queue</b> as an empty cell queue. */
2785 void
2787 {
2790 }
2792 /** Remove and free every cell in <b>queue</b>. */
2793 void
2795 {
2800 }
2803 }
2805 /** Extract and return the cell at the head of <b>queue</b>; return NULL if
2806 * <b>queue</b> is empty. */
2807 STATIC packed_cell_t *
2809 {
2816 }
2818 /** Initialize <b>queue</b> as an empty cell queue. */
2819 void
2821 {
2824 }
2826 /** Remove and free every cell in <b>queue</b>. */
2827 void
2829 {
2834 }
2837 }
2839 /** Extract and return the cell at the head of <b>queue</b>; return NULL if
2840 * <b>queue</b> is empty. */
2841 STATIC destroy_cell_t *
2843 {
2850 }
2852 /** Append a destroy cell for <b>circid</b> to <b>queue</b>. */
2853 void
2855 circid_t circid,
2857 {
2861 /* Not yet used, but will be required for OOM handling. */
2866 }
2868 /** Convert a destroy_cell_t to a newly allocated cell_t. Frees its input. */
2871 {
2873 cell_t cell;
2882 }
2884 /** Return the total number of bytes used for each packed_cell in a queue.
2885 * Approximate. */
2886 size_t
2888 {
2890 }
2892 /* DOCDOC */
2893 size_t
2895 {
2897 }
2899 /** How long after we've been low on memory should we try to conserve it? */
2900 #define MEMORY_PRESSURE_INTERVAL (30*60)
2902 /** The time at which we were last low on memory. */
2905 /** Statistics on how many bytes were removed by the OOM per type. */
2911 /** Check whether we've got too much space used for cells. If so,
2912 * call the OOM handler and return 1. Otherwise, return 0. */
2913 STATIC int
2915 {
2934 /* Note this overload down */
2937 /* If we're spending over 20% of the memory limit on hidden service
2938 * descriptors, free them until we're down to 10%. Do the same for geoip
2939 * client cache. */
2946 }
2949 geoip_client_cache_total -
2954 }
2961 }
2962 /* Like onion service above, try to go down to 10% if we are above 20% */
2969 }
2973 }
2974 }
2976 }
2978 /** Return true if we've been under memory pressure in the last
2979 * MEMORY_PRESSURE_INTERVAL seconds. */
2980 int
2982 {
2985 }
2987 /**
2988 * Update the number of cells available on the circuit's n_chan or p_chan's
2989 * circuit mux.
2990 */
2991 void
2994 {
3001 /* Okay, get the channel */
3007 }
3012 /* Now get the cmux */
3015 /* Cmux sanity check */
3020 }
3023 /* Update the number of cells we have for the circuit mux */
3028 }
3029 }
3031 /** Remove all circuits from the cmux on <b>chan</b>.
3032 *
3033 * If <b>circuits_out</b> is non-NULL, add all detached circuits to
3034 * <b>circuits_out</b>.
3035 **/
3036 void
3038 {
3045 }
3047 /**
3048 * Called when a circuit becomes blocked or unblocked due to the channel
3049 * cell queue.
3050 *
3051 * Block (if <b>block</b> is true) or unblock (if <b>block</b> is false)
3052 * every edge connection that is using <b>circ</b> to write to <b>chan</b>,
3053 * and start or stop reading as appropriate.
3054 */
3055 static void
3057 {
3067 }
3070 }
3072 /**
3073 * Helper function to block or unblock streams in a stream list.
3074 *
3075 * If <b>stream_id</b> is 0, apply the <b>block</b> state to all streams
3076 * in the stream list. If it is non-zero, only apply to that specific stream.
3077 */
3078 static void
3081 {
3082 /* If we have a conflux object, we need to examine its status before
3083 * blocking and unblocking streams. */
3088 /* Don't actually block streams, since conflux can send*/
3091 /* Don't actually unblock streams, since conflux still can't send */
3093 }
3094 }
3103 /* This connection should not start or stop reading. */
3105 }
3111 /* Is this right? */
3114 }
3115 }
3116 }
3118 /** Extract the command from a packed cell. */
3119 uint8_t
3121 {
3126 }
3127 }
3129 /** Extract the circuit ID from a packed cell. */
3130 circid_t
3132 {
3137 }
3138 }
3140 /** Pull as many cells as possible (but no more than <b>max</b>) from the
3141 * queue of the first active circuit on <b>chan</b>, and write them to
3142 * <b>chan</b>->outbuf. Return the number of cells written. Advance
3143 * the active circuit pointer to the next active circuit in the ring. */
3146 {
3156 /* Get the cmux */
3161 /* Main loop: pick a circuit, send a cell, update the cmux */
3166 /* this code is duplicated from some of the logic below. Ugly! XXXX */
3167 /* If we are given a destroy_queue here, then it is required to be
3168 * nonempty... */
3171 /* ...and pop() will always yield a cell from a nonempty queue. */
3173 /* frees dcell */
3175 /* Send the DESTROY cell. It is very unlikely that this fails but just
3176 * in case, get rid of the channel. */
3178 /* The cell has been freed. */
3181 }
3182 /* Update the cmux destroy counter */
3187 }
3188 /* If it returns NULL, no cells left to send */
3199 }
3201 /* Circuitmux told us this was active, so it should have cells.
3202 *
3203 * Note: In terms of logic and coherence, this should never happen but the
3204 * cmux dragon is powerful. Reason is that when the OOM is triggered, when
3205 * cleaning up circuits, we mark them for close and then clear their cell
3206 * queues. And so, we can have a circuit considered active by the cmux
3207 * dragon but without cells. The cmux subsystem is only notified of this
3208 * when the circuit is freed which leaves a tiny window between close and
3209 * free to end up here.
3210 *
3211 * We are accepting this as an "ok" race else the changes are likely non
3212 * trivial to make the mark for close to set the num cells to 0 and change
3213 * the free functions to detach the circuit conditionally without creating
3214 * a chain effect of madness.
3215 *
3216 * The lesson here is arti will prevail and leave the cmux dragon alone. */
3222 }
3226 /*
3227 * Get just one cell here; once we've sent it, that can change the circuit
3228 * selection, so we have to loop around for another even if this circuit
3229 * has more than one.
3230 */
3233 /* Calculate the exact time that this cell has spent in the queue. */
3245 }
3260 }
3261 }
3263 /* If we just flushed our queue and this circuit is used for a
3264 * tunneled directory request, possibly advance its state. */
3267 DIRREQ_TUNNELED,
3268 DIRREQ_CIRC_QUEUE_FLUSHED);
3270 /* Now send the cell. It is very unlikely that this fails but just in
3271 * case, get rid of the channel. */
3273 /* The cell has been freed at this point. */
3276 }
3279 /*
3280 * Don't packed_cell_free_unchecked(cell) here because the channel will
3281 * do so when it gets out of the channel queue (probably already did, in
3282 * which case that was an immediate double-free bug).
3283 */
3285 /* Update the counter */
3288 /*
3289 * Now update the cmux; tell it we've just sent a cell, and how many
3290 * we have left.
3291 */
3297 /* Is the cell queue low enough to unblock all the streams that are waiting
3298 * to write to this circuit? */
3302 /* If n_flushed < max still, loop around and pick another circuit */
3303 }
3305 /* Okay, we're done sending now */
3307 }
3309 /* Minimum value is the maximum circuit window size.
3310 *
3311 * This value is set to a lower bound we believe is reasonable with congestion
3312 * control and basic network running parameters.
3313 *
3314 * SENDME cells makes it that we can control how many cells can be inflight on
3315 * a circuit from end to end. This logic makes it that on any circuit cell
3316 * queue, we have a maximum of cells possible.
3317 *
3318 * Because the Tor protocol allows for a client to exit at any hop in a
3319 * circuit and a circuit can be of a maximum of 8 hops, so in theory the
3320 * normal worst case will be the circuit window start value times the maximum
3321 * number of hops (8). Having more cells then that means something is wrong.
3322 *
3323 * However, because padding cells aren't counted in the package window, we set
3324 * the maximum size to a reasonably large size for which we expect that we'll
3325 * never reach in theory. And if we ever do because of future changes, we'll
3326 * be able to control it with a consensus parameter.
3327 *
3328 * XXX: Unfortunately, END cells aren't accounted for in the circuit window
3329 * which means that for instance if a client opens 8001 streams, the 8001
3330 * following END cells will queue up in the circuit which will get closed if
3331 * the max limit is 8000. Which is sad because it is allowed by the Tor
3332 * protocol. But, we need an upper bound on circuit queue in order to avoid
3333 * DoS memory pressure so the default size is a middle ground between not
3334 * having any limit and having a very restricted one. This is why we can also
3335 * control it through a consensus parameter. */
3336 #define RELAY_CIRC_CELL_QUEUE_SIZE_MIN 50
3337 /* We can't have a consensus parameter above this value. */
3338 #define RELAY_CIRC_CELL_QUEUE_SIZE_MAX INT32_MAX
3339 /* Default value is set to a large value so we can handle padding cells
3340 * properly which aren't accounted for in the SENDME window. Default is 2500
3341 * allowed cells in the queue resulting in ~1MB. */
3342 #define RELAY_CIRC_CELL_QUEUE_SIZE_DEFAULT \
3343 (50 * RELAY_CIRC_CELL_QUEUE_SIZE_MIN)
3345 /* The maximum number of cells a circuit queue can contain. This is updated at
3346 * every new consensus and controlled by a parameter. */
3348 RELAY_CIRC_CELL_QUEUE_SIZE_DEFAULT;
3349 /** Maximum number of cell on an outbound circuit queue. This is updated at
3350 * every new consensus and controlled by a parameter. This default is incorrect
3351 * and won't be used at all except in unit tests. */
3353 RELAY_CIRC_CELL_QUEUE_SIZE_DEFAULT;
3355 /** Return consensus parameter "circ_max_cell_queue_size". The given ns can be
3356 * NULL. */
3357 static uint32_t
3359 {
3361 RELAY_CIRC_CELL_QUEUE_SIZE_DEFAULT,
3362 RELAY_CIRC_CELL_QUEUE_SIZE_MIN,
3363 RELAY_CIRC_CELL_QUEUE_SIZE_MAX);
3364 }
3366 /** Return consensus parameter "circ_max_cell_queue_size_out". The given ns can
3367 * be NULL. */
3368 static uint32_t
3370 {
3373 RELAY_CIRC_CELL_QUEUE_SIZE_MIN,
3374 RELAY_CIRC_CELL_QUEUE_SIZE_MAX);
3375 }
3377 /* Called when the consensus has changed. At this stage, the global consensus
3378 * object has NOT been updated. It is called from
3379 * notify_before_networkstatus_changes(). */
3380 void
3382 {
3385 /* Update the circuit max cell queue size from the consensus. */
3386 max_circuit_cell_queue_size =
3388 max_circuit_cell_queue_size_out =
3390 }
3392 /** Add <b>cell</b> to the queue of <b>circ</b> writing to <b>chan</b>
3393 * transmitting in <b>direction</b>.
3394 *
3395 * The given <b>cell</b> is copied onto the circuit queue so the caller must
3396 * cleanup the memory.
3397 *
3398 * This function is part of the fast path.
3399 *
3400 * Return 1 if the cell was successfully sent.
3401 * Return 0 if the cell can not be sent. The caller MUST NOT close the circuit.
3402 * Return -1 indicating an error and that the caller should mark the circuit
3403 * for close. */
3404 int
3407 streamid_t fromstream)
3408 {
3417 }
3432 }
3435 /* This DoS defense only applies at the Guard as in the p_chan is likely
3436 * a client IP attacking the network. */
3438 stats_n_circ_max_cell_outq_reached++;
3440 }
3443 "%s circuit has %d cells in its queue, maximum allowed is %d. "
3446 max_queue_size);
3447 stats_n_circ_max_cell_reached++;
3449 }
3451 /* Very important that we copy to the circuit queue because all calls to
3452 * this function use the stack for the cell memory. */
3456 /* Check and run the OOM if needed. */
3458 /* We ran the OOM handler which might have closed this circuit. */
3461 }
3462 }
3464 /* If we have too many cells on the circuit, note that it should
3465 * be blocked from new cells. */
3470 /* This edge connection is apparently not blocked; this can happen for
3471 * new streams on a blocked circuit, for their CONNECTED response.
3472 * block it now, unless we have conflux. */
3474 }
3478 /* This was the first cell added to the queue. We just made this
3479 * circuit active. */
3481 }
3483 /* New way: mark this as having waiting cells for the scheduler */
3486 }
3488 /** Append an encoded value of <b>addr</b> to <b>payload_out</b>, which must
3489 * have at least 18 bytes of free space. The encoding is, as specified in
3490 * tor-spec.txt:
3491 * RESOLVED_TYPE_IPV4 or RESOLVED_TYPE_IPV6 [1 byte]
3492 * LENGTH [1 byte]
3493 * ADDRESS [length bytes]
3494 * Return the number of bytes added, or -1 on error */
3495 int
3497 {
3514 }
3515 }
3517 /** Given <b>payload_len</b> bytes at <b>payload</b>, starting with an address
3518 * encoded as by append_address_to_payload(), try to decode the address into
3519 * *<b>addr_out</b>. Return the next byte in the payload after the address on
3520 * success, or NULL on failure. */
3524 {
3544 }
3546 }
3548 /** Remove all the cells queued on <b>circ</b> for <b>chan</b>. */
3549 void
3551 {
3553 cell_direction_t direction;
3563 }
3565 /* Clear the queue */
3568 /* Update the cell counter in the cmux */
3571 }
3573 /** Return 1 if we shouldn't restart reading on this circuit, even if
3574 * we get a SENDME. Else return 0.
3575 */
3576 static int
3578 {
3583 }
3584 }