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367 lines
14 KiB
C
367 lines
14 KiB
C
/*
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Serval Distributed Numbering Architecture (DNA)
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Copyright (C) 2010 Paul Gardner-Stephen
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License
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as published by the Free Software Foundation; either version 2
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of the License, or (at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*/
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#include "serval.h"
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#include "strbuf.h"
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struct sockaddr_in loopback = {
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.sin_family=0,
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.sin_port=0,
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.sin_addr.s_addr=0x0100007f
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};
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int packetOkOverlay(struct overlay_interface *interface,unsigned char *packet, size_t len,
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unsigned char *transaction_id,int recvttl,
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struct sockaddr *recvaddr, size_t recvaddrlen, int parseP)
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{
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/*
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This function decodes overlay packets which have been assembled for delivery overy IP networks.
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IP based wireless networks have a high, but limited rate of packets that can be sent. In order
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to increase throughput of small payloads, we ammend many payloads together and have used a scheme
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to compress common network identifiers.
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A different network type may have very different constraints on the number and size of packets,
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and may need a different encoding scheme to use the bandwidth efficiently.
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The current structure of an overlay packet is as follows;
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Fixed header [0x4F, 0x10]
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Version [0x00, 0x01]
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Each frame within the packet has the following fields:
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Frame type (8-24bits)
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TTL (8bits)
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Remaining frame size (RFS) (see overlay_payload.c or overlay_buffer.c for explanation of format)
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Next hop (variable length due to address abbreviation)
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Destination (variable length due to address abbreviation)
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Source (variable length due to address abbreviation)
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Payload (length = RFS- len(frame type) - len(next hop)
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This structure is intended to allow relaying nodes to quickly ignore frames that are
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not addressed to them as either the next hop or final destination.
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The RFS field uses additional bytes to encode the length of longer frames.
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This provides us with a slight space saving for the common case of short frames.
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The frame payload itself can be enciphered with the final destination's public key, so
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that it is not possible for the relaying 3rd parties to observe the content.
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Naturally some information will leak simply based on the size, periodicity and other
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characteristics of the traffic, and some 3rd parties may be malevolent, so noone should
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assume that this provides complete security.
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It would be possible to design a super-paranoid mode where onion routing is used with
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concentric shells of encryption so that each hop can only work out the next node to send it
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to. However, that would result in rather large frames, which may well betray more information
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than the super-paranoid mode would hide.
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Note also that it is possible to dispatch frames on a local link which are addressed to
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broadcast, but are enciphered. In that situation only the intended recipient can
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decode the frame, but at the cost of having all nodes on the local link having to decrypt
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frame. Of course the nodes may elect to not decrypt such anonymous frames.
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Such frames could even be flooded throughout part of the mesh by having the TTL>1, and
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optionally with an anonymous source address to provide some plausible deniability for both
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sending and reception if combined with a randomly selected TTL to give the impression of
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the source having received the frame from elsewhere.
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*/
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int ofs;
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overlay_frame f;
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bzero(&f,sizeof(overlay_frame));
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if (recvaddr->sa_family==AF_INET){
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f.recvaddr=recvaddr;
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if (debug&DEBUG_OVERLAYFRAMES)
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DEBUG("Received overlay packet");
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} else {
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if (interface->fileP) {
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/* dummy interface, so tell to use 0.0.0.0 */
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f.recvaddr=(struct sockaddr *)&loopback;
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} else
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/* some other sort of interface, so we can't offer any help here */
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f.recvaddr=NULL;
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}
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overlay_abbreviate_unset_current_sender();
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// TODO put sender of packet and sequence number in envelope header
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// Then we can quickly drop reflected broadcast packets
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// currently we see annoying errors as we attempt to parse each payload
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// plus with a sequence number we can detect dropped packets and nack them for retransmission
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/* Skip magic bytes and version */
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for(ofs=4;ofs<len;)
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{
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/* Get normal form of packet type and modifiers */
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f.type=packet[ofs]&OF_TYPE_BITS;
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f.modifiers=packet[ofs]&OF_MODIFIER_BITS;
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switch(packet[ofs]&OF_TYPE_BITS)
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{
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case OF_TYPE_EXTENDED20:
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/* Eat the next two bytes and then skip over this reserved frame type */
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f.type=OF_TYPE_FLAG_E20|(packet[ofs]&OF_MODIFIER_BITS)|(packet[ofs+2]<<12)|(packet[ofs+1]<<4);
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f.modifiers=0;
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ofs+=3;
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break;
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case OF_TYPE_EXTENDED12:
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/* Eat the next byte and then skip over this reserved frame type */
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f.type=OF_TYPE_FLAG_E12|(packet[ofs]&OF_MODIFIER_BITS)|(packet[ofs+1]<<4);
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f.modifiers=0;
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ofs+=2;
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break;
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default:
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/* No extra bytes to deal with here */
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ofs++;
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break;
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}
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/* Get time to live */
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f.ttl=packet[ofs++];
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/* Decode length of remainder of frame */
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f.rfs=rfs_decode(packet,&ofs);
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if (debug&DEBUG_PACKETFORMATS) DEBUGF("f.rfs=%d, ofs=%d", f.rfs, ofs);
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if (!f.rfs) {
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/* Zero length -- assume we fell off the end of the packet */
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break;
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}
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int payloadStart = ofs;
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int nextPayload = ofs+f.rfs;
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if (nextPayload > len){
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WHYF("Payload length %d is too long for the remaining packet buffer %d", f.rfs, len - ofs);
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break;
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}
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/* Always attempt to resolve all of the addresses in a packet, or we could fail to understand an important payload
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eg, peer sends two payloads travelling in opposite directions;
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[Next, Dest, Sender] forwarding a payload we just send, so Sender == Me
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[Next, Dest, Sender] delivering a payload to us so Next == Me
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But Next would be encoded as OA_CODE_PREVIOUS, so we must parse all three addresses,
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even if Next is obviously not intended for us
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*/
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/* Now extract the next hop address */
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int alen=0;
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int nexthop_address_status=overlay_abbreviate_expand_address(packet,&ofs,f.nexthop,&alen);
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if (ofs>nextPayload){
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WARN("Next hop address didn't fit in payload");
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break;
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}
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alen=0;
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int destination_address_status=overlay_abbreviate_expand_address(packet,&ofs,f.destination,&alen);
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if (ofs>nextPayload){
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WARN("Destination address didn't fit in payload");
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break;
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}
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alen=0;
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int source_address_status=overlay_abbreviate_expand_address(packet,&ofs,f.source,&alen);
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if (ofs>nextPayload){
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WARN("Source address didn't fit in payload");
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break;
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}
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// TODO respond with OA_PLEASEEXPLAIN's?
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if (debug&DEBUG_OVERLAYFRAMES) {
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DEBUGF("Type=0x%02x", f.type);
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strbuf b = strbuf_alloca(1024);
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strbuf_sprintf(b, "Next Hop for this frame is (resolve code=%d): ", nexthop_address_status);
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if (nexthop_address_status==OA_RESOLVED)
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strbuf_sprintf(b, "%s", alloca_tohex_sid(f.nexthop));
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else
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strbuf_puts(b, "???");
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DEBUG(strbuf_str(b));
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strbuf_reset(b);
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strbuf_sprintf(b, "Destination for this frame is (resolve code=%d): ", destination_address_status);
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if (destination_address_status==OA_RESOLVED)
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strbuf_sprintf(b, "%s", alloca_tohex_sid(f.destination));
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else
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strbuf_puts(b, "???");
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DEBUG(strbuf_str(b));
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strbuf_reset(b);
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strbuf_sprintf(b, "Source for this frame is (resolve code=%d): ", source_address_status);
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if (source_address_status==OA_RESOLVED)
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strbuf_sprintf(b, "%s", alloca_tohex_sid(f.source));
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else
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strbuf_puts(b, "???");
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DEBUG(strbuf_str(b));
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}
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if (f.nexthop[0]==0 || f.destination[0]==0 || f.source[0]==0){
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WHY("Addresses expanded incorrectly");
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dump("Addresses expanded incorrectly", &packet[payloadStart], ofs - payloadStart);
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break;
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}
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if (nexthop_address_status!=OA_RESOLVED
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|| destination_address_status!=OA_RESOLVED
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|| source_address_status!=OA_RESOLVED){
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WARN("Unable to resolve all payload addresses");
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// we have to stop now as we can't be certain about the destination of any other payloads in this packet.
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break;
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}
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/* not that noteworthy, as when listening to a broadcast socket
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you hear everything you send. */
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if (overlay_address_is_local(f.source)){
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// skip the remainder of any packet that we know we sent
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// TODO add our id to the header
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if (f.type==OF_TYPE_SELFANNOUNCE)
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break;
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}else{
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// TODO refactor all packet parsing to only allocate additional memory for the payload
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// if it needs to be queued for forwarding.
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f.payload = ob_static(&packet[ofs], nextPayload - ofs);
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ob_setlength(f.payload, nextPayload - ofs);
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/* Finally process the frame */
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overlay_frame_process(interface,&f);
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ob_free(f.payload);
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}
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/* Jump to the next payload offset */
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ofs = nextPayload;
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}
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if (0) INFOF("Finished processing overlay packet");
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return 0;
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}
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int overlay_add_selfannouncement(int interface,overlay_buffer *b)
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{
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/* Pull the first record from the HLR database and turn it into a
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self-announcment. These are shorter than regular Subscriber Observation
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Notices (SON) because they are just single-hop announcments of presence.
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Do we really need to push the whole SID (32 bytes), or will just, say,
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8 do so that we use a prefix of the SID which is still very hard to forge?
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A hearer of a self-announcement who has not previously seen the sender might
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like to get some authentication to prevent naughty people from spoofing routes.
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We can do this by having ourselves, the sender, keep track of the last few frames
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we have sent, so that we can be asked to sign them. Actually, we won't sign them,
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as that is too slow/energy intensive, but we could use a D-H exchange with the neighbour,
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performed once to get a shared secret that can be used to feed a stream cipher to
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produce some sort of verification.
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XXX - But this functionality really needs to move up a level to whole frame composition.
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*/
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unsigned char *sid=overlay_get_my_sid();
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long long now = overlay_gettime_ms();
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/* Header byte */
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if (ob_append_byte(b, OF_TYPE_SELFANNOUNCE))
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return WHY("Could not add self-announcement header");
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static int ticks_per_full_address = -1;
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if (ticks_per_full_address == -1) {
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ticks_per_full_address = confValueGetInt64Range("mdp.selfannounce.ticks_per_full_address", 4LL, 1LL, 1000000LL);
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INFOF("ticks_per_full_address = %d", ticks_per_full_address);
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}
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int send_prefix = ++overlay_interfaces[interface].ticks_since_sent_full_address < ticks_per_full_address;
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if (!send_prefix)
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overlay_interfaces[interface].ticks_since_sent_full_address = 0;
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/* A TTL for this frame.
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XXX - BATMAN uses various TTLs, but I think that it may just be better to have all TTL=1,
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and have the onward nodes selectively choose which nodes to on-announce. If we prioritise
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newly arrived nodes somewhat (or at least reserve some slots for them), then we can still
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get the good news travels fast property of BATMAN, but without having to flood in the formal
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sense. */
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if (ob_append_byte(b,1))
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return WHY("Could not add TTL to self-announcement");
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/* Add space for Remaining Frame Size field. This will always be a single byte
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for self-announcments as they are always <256 bytes. */
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if (ob_append_rfs(b,1+8+1+(send_prefix?(1+7):SID_SIZE)+4+4+1))
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return WHY("Could not add RFS for self-announcement frame");
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/* Add next-hop address. Always link-local broadcast for self-announcements */
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if (ob_append_byte(b,OA_CODE_BROADCAST))
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return WHY("Could not add self-announcement header");
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/* BPI for broadcast */
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{
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int i;
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for(i=0;i<8;i++)
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if (ob_append_byte(b,random()&0xff))
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return WHYF("Could not add next-hop address byte %d", i);
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}
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/* Add final destination. Always broadcast for self-announcments.
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As we have just referenced the broadcast address, we can encode it in a single byte */
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if (ob_append_byte(b, OA_CODE_PREVIOUS))
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return WHY("Could not add self-announcement header");
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/* Add our SID to the announcement as sender
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We can likely get away with abbreviating our own address much of the time, since these
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frames will be sent on a regular basis. However, we can only abbreviate using a prefix,
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not any of the fancier methods. Indeed, if we tried to use the standard abbreviation
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functions they would notice that we are attaching an address which is ourself, and send
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a uselessly short address. So instead we will use a simple scheme where we will send our
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address in full an arbitrary 1 in 4 times.
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*/
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if (send_prefix) {
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if (ob_append_byte(b, OA_CODE_PREFIX7)) return WHY("Could not add address format code.");
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if (ob_append_bytes(b,sid,7)) return WHY("Could not append SID prefix to self-announcement");
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}
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else {
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if (ob_append_bytes(b,sid,SID_SIZE)) return WHY("Could not append SID to self-announcement");
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}
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/* Make note that this is the most recent address we have set */
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overlay_abbreviate_set_most_recent_address(sid);
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/* And the sender for any other addresses in this packet */
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overlay_abbreviate_set_current_sender(sid);
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/* Sequence number range. Based on one tick per milli-second. */
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if (ob_append_int(b,overlay_interfaces[interface].last_tick_ms))
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return WHY("Could not add low sequence number to self-announcement");
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if (ob_append_int(b,now))
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return WHY("Could not add high sequence number to self-announcement");
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overlay_interfaces[interface].last_tick_ms=now;
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if (debug&DEBUG_OVERLAYINTERFACES)
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DEBUGF("last tick seq# = %lld", overlay_interfaces[interface].last_tick_ms);
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/* A byte that indicates which interface we are sending over */
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if (ob_append_byte(b,interface))
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return WHY("Could not add interface number to self-announcement");
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ob_patch_rfs(b, COMPUTE_RFS_LENGTH);
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return 0;
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}
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