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https://github.com/servalproject/serval-dna.git
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e20cfdb59d
POLLOUT seems to get stuck once triggered.
422 lines
13 KiB
C
422 lines
13 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 "conf.h"
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#include "str.h"
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#include "strbuf.h"
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#include "overlay_buffer.h"
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#include "overlay_packet.h"
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struct sockaddr_in loopback;
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unsigned char magic_header[]={0x00, 0x01};
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#define PACKET_UNICAST (1<<0)
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#define PACKET_INTERFACE (1<<1)
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#define PACKET_SEQ (1<<2)
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int overlay_packet_init_header(struct decode_context *context, struct overlay_buffer *buff,
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struct subscriber *destination,
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char unicast, char interface, char seq){
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if (ob_append_bytes(buff,magic_header,sizeof magic_header))
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return -1;
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if (overlay_address_append(context, buff, my_subscriber))
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return -1;
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context->sender = my_subscriber;
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int flags=0;
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if (unicast)
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flags |= PACKET_UNICAST;
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if (interface)
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flags |= PACKET_INTERFACE;
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if (seq)
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flags |= PACKET_SEQ;
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ob_append_byte(buff,flags);
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if (flags & PACKET_INTERFACE)
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ob_append_byte(buff,interface);
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if (flags & PACKET_SEQ)
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ob_append_byte(buff,seq);
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return 0;
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}
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// a frame destined for one of our local addresses, or broadcast, has arrived. Process it.
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int process_incoming_frame(time_ms_t now, struct overlay_interface *interface, struct overlay_frame *f, struct decode_context *context){
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IN();
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int id = (interface - overlay_interfaces);
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switch(f->type)
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{
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case OF_TYPE_SELFANNOUNCE_ACK:
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if (config.debug.overlayframes)
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DEBUG("Processing OF_TYPE_SELFANNOUNCE_ACK");
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overlay_route_saw_selfannounce_ack(f,now);
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break;
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case OF_TYPE_NODEANNOUNCE:
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if (config.debug.overlayframes)
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DEBUG("Processing OF_TYPE_NODEANNOUNCE");
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overlay_route_saw_advertisements(id,f,context,now);
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break;
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// data frames
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case OF_TYPE_RHIZOME_ADVERT:
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if (config.debug.overlayframes)
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DEBUG("Processing OF_TYPE_RHIZOME_ADVERT");
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overlay_rhizome_saw_advertisements(id,f,now);
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break;
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case OF_TYPE_DATA:
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case OF_TYPE_DATA_VOICE:
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if (config.debug.overlayframes)
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DEBUG("Processing OF_TYPE_DATA");
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overlay_saw_mdp_containing_frame(f,now);
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break;
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case OF_TYPE_PLEASEEXPLAIN:
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if (config.debug.overlayframes)
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DEBUG("Processing OF_TYPE_PLEASEEXPLAIN");
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process_explain(f);
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break;
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default:
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RETURN(WHYF("Support for f->type=0x%x not implemented",f->type));
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}
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RETURN(0);
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}
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// duplicate the frame and queue it
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int overlay_forward_payload(struct overlay_frame *f){
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IN();
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if (f->ttl<=0)
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RETURN(0);
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if (config.debug.overlayframes)
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DEBUGF("Forwarding payload for %s, ttl=%d",
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(f->destination?alloca_tohex_sid(f->destination->sid):"broadcast"),
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f->ttl);
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/* Queue frame for dispatch.
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Don't forget to put packet in the correct queue based on type.
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(e.g., mesh management, voice, video, ordinary or opportunistic).
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But the really important bit is to clone the frame, since the
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structure we are looking at here must be left as is and returned
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to the caller to do as they please */
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struct overlay_frame *qf=op_dup(f);
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if (!qf)
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RETURN(WHY("Could not clone frame for queuing"));
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if (overlay_payload_enqueue(qf)) {
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op_free(qf);
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RETURN(WHY("failed to enqueue forwarded payload"));
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}
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RETURN(0);
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}
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int packetOkOverlay(struct overlay_interface *interface,unsigned char *packet, size_t len,
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int recvttl, struct sockaddr *recvaddr, size_t recvaddrlen)
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{
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IN();
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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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if (recvaddr&&recvaddr->sa_family!=AF_INET)
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RETURN(WHYF("Unexpected protocol family %d",recvaddr->sa_family));
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struct overlay_frame f;
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struct decode_context context;
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bzero(&context, sizeof context);
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bzero(&f,sizeof f);
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time_ms_t now = gettime_ms();
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struct overlay_buffer *b = ob_static(packet, len);
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ob_limitsize(b, len);
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if (ob_get(b)!=magic_header[0] || ob_get(b)!=magic_header[1]){
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ob_free(b);
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RETURN(WHY("Packet type not recognised."));
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}
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context.interface = f.interface = interface;
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f.recvaddr = *((struct sockaddr_in *)recvaddr);
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if (config.debug.overlayframes)
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DEBUG("Received overlay packet");
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if (overlay_address_parse(&context, b, &context.sender)){
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WHY("Unable to parse sender");
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}
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int packet_flags = ob_get(b);
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int sender_interface = 0;
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if (packet_flags & PACKET_INTERFACE)
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sender_interface = ob_get(b);
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if (packet_flags & PACKET_SEQ)
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ob_get(b); // sequence number, not implemented yet
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if (context.sender){
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if (context.sender->reachable==REACHABLE_SELF){
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ob_free(b);
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RETURN(0);
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}
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context.sender->last_rx = now;
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// TODO probe unicast links when we detect an address change.
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// if this is a dummy announcement for a node that isn't in our routing table
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if (context.sender->reachable == REACHABLE_NONE) {
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context.sender->interface = interface;
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context.sender->address = f.recvaddr;
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context.sender->last_probe = 0;
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// assume for the moment, that we can reply with the same packet type
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if (packet_flags&PACKET_UNICAST){
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set_reachable(context.sender, REACHABLE_UNICAST|REACHABLE_ASSUMED);
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}else{
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set_reachable(context.sender, REACHABLE_BROADCAST|REACHABLE_ASSUMED);
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}
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}
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/* Note the probe payload must be queued before any SID/SAS request so we can force the packet to have a full sid */
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if (context.sender->last_probe==0 || now - context.sender->last_probe > 5000)
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overlay_send_probe(context.sender, f.recvaddr, interface, OQ_MESH_MANAGEMENT);
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if ((!(packet_flags&PACKET_UNICAST)) && context.sender->last_acked + interface->tick_ms <= now){
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overlay_route_ack_selfannounce(interface,
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context.sender->last_acked>now - 3*interface->tick_ms?context.sender->last_acked:now,
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now,sender_interface,context.sender);
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context.sender->last_acked = now;
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}
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}
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if (packet_flags & PACKET_UNICAST)
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context.addr=f.recvaddr;
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else
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context.addr=interface->broadcast_address;
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while(b->position < b->sizeLimit){
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context.invalid_addresses=0;
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struct subscriber *nexthop=NULL;
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bzero(f.broadcast_id.id, BROADCAST_LEN);
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int process=1;
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int forward=1;
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int flags = ob_get(b);
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if (flags<0){
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WHY("Unable to parse payload flags");
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break;
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}
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if (flags & PAYLOAD_FLAG_SENDER_SAME){
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if (!context.sender)
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context.invalid_addresses=1;
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f.source = context.sender;
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}else{
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if (overlay_address_parse(&context, b, &f.source)){
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WHY("Unable to parse payload source");
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break;
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}
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if (!f.source || f.source->reachable==REACHABLE_SELF)
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process=forward=0;
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}
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if (flags & PAYLOAD_FLAG_TO_BROADCAST){
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if (!(flags & PAYLOAD_FLAG_ONE_HOP)){
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if (overlay_broadcast_parse(b, &f.broadcast_id)){
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WHY("Unable to parse payload broadcast id");
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break;
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}
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if (overlay_broadcast_drop_check(&f.broadcast_id)){
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process=forward=0;
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if (config.debug.overlayframes)
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DEBUGF("Ignoring duplicate broadcast (%s)", alloca_tohex(f.broadcast_id.id, BROADCAST_LEN));
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}
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}
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f.destination=NULL;
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}else{
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if (overlay_address_parse(&context, b, &f.destination)){
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WHY("Unable to parse payload destination");
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break;
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}
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if (!f.destination || f.destination->reachable!=REACHABLE_SELF){
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process=0;
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}
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if (!(flags & PAYLOAD_FLAG_ONE_HOP)){
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if (overlay_address_parse(&context, b, &nexthop)){
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WHY("Unable to parse payload nexthop");
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break;
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}
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if (!nexthop || nexthop->reachable!=REACHABLE_SELF){
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forward=0;
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}
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}
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}
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if (flags & PAYLOAD_FLAG_ONE_HOP){
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f.ttl=1;
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}else{
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int ttl_qos = ob_get(b);
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if (ttl_qos<0){
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WHY("Unable to parse ttl/qos");
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break;
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}
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f.ttl = ttl_qos & 0x1F;
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f.queue = (ttl_qos >> 5) & 3;
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}
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f.ttl--;
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if (f.ttl<=0)
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forward=0;
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if (flags & PAYLOAD_FLAG_LEGACY_TYPE){
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f.type=ob_get(b);
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if (f.type<0){
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WHY("Unable to parse payload type");
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break;
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}
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}else
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f.type=OF_TYPE_DATA;
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f.modifiers=flags;
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// TODO allow for one byte length
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unsigned int payload_len = ob_get_ui16(b);
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if (payload_len > ob_remaining(b)){
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WHYF("Unable to parse payload length (%d)", payload_len);
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break;
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}
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int next_payload = ob_position(b) + payload_len;
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if (f.source)
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f.source->last_rx = now;
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// if we can't understand one of the addresses, skip processing the payload
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if (context.invalid_addresses){
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if (config.debug.overlayframes)
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DEBUG("Skipping payload due to unknown addresses");
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goto next;
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}
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if (config.debug.overlayframes){
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DEBUGF("Received payload type %x, len %d", f.type, next_payload - b->position);
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DEBUGF("Payload from %s", alloca_tohex_sid(f.source->sid));
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DEBUGF("Payload to %s", (f.destination?alloca_tohex_sid(f.destination->sid):"broadcast"));
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if (!is_all_matching(f.broadcast_id.id, BROADCAST_LEN, 0))
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DEBUGF("Broadcast id %s", alloca_tohex(f.broadcast_id.id, BROADCAST_LEN));
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if (nexthop)
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DEBUGF("Next hop %s", alloca_tohex_sid(nexthop->sid));
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}
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if (!process && !forward)
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goto next;
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f.payload = ob_slice(b, b->position, payload_len);
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if (!f.payload){
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WHY("Payload length is longer than remaining packet size");
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break;
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}
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// mark the entire payload as having valid data
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ob_limitsize(f.payload, payload_len);
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// forward payloads that are for someone else or everyone
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if (forward){
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overlay_forward_payload(&f);
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}
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// process payloads that are for me or everyone
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if (process){
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process_incoming_frame(now, interface, &f, &context);
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}
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next:
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if (f.payload){
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ob_free(f.payload);
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f.payload=NULL;
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}
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b->position=next_payload;
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}
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send_please_explain(&context, my_subscriber, context.sender);
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ob_free(b);
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RETURN(0);
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}
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