serval-dna/overlay_interface.c
Andrew Bettison 2c87039307 Replace overlay_render_sid() with alloca_tohex_sid()
To eliminate timebomb bugs caused by rotor wraparound
2012-07-03 17:59:30 +09:30

1054 lines
34 KiB
C

/*
Serval Distributed Numbering Architecture (DNA)
Copyright (C) 2010 Paul Gardner-Stephen
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
#include <assert.h>
#include <time.h>
#include "serval.h"
#include "strbuf.h"
#ifdef HAVE_IFADDRS_H
#include <ifaddrs.h>
#endif
int overlay_ready=0;
int overlay_interface_count=0;
overlay_interface overlay_interfaces[OVERLAY_MAX_INTERFACES];
int overlay_last_interface_number=-1;
struct interface_rules {
char *namespec;
unsigned long long speed_in_bits;
int port;
char type;
char excludeP;
struct interface_rules *next;
};
struct interface_rules *interface_filter=NULL;
struct profile_total interface_poll_stats;
struct profile_total dummy_poll_stats;
unsigned int overlay_sequence_number=0;
long long overlay_next_tick();
/* Return milliseconds since server started. First call will always return zero.
Must use long long, not time_t, as time_t can be 32bits, which is too small for
milli-seconds since 1970. */
long long overlay_sequence_start_time = 0;
long long overlay_gettime_ms()
{
long long now;
if (!overlay_sequence_start_time) {
overlay_sequence_start_time = gettime_ms();
now = 0;
} else
now= gettime_ms()-overlay_sequence_start_time;
return now;
}
int overlay_update_sequence_number()
{
long long now=overlay_gettime_ms();
overlay_sequence_number=now&0xffffffff;
return 0;
}
int overlay_interface_type(char *s)
{
if (!strcasecmp(s,"ethernet")) return OVERLAY_INTERFACE_ETHERNET;
if (!strcasecmp(s,"wifi")) return OVERLAY_INTERFACE_WIFI;
if (!strcasecmp(s,"other")) return OVERLAY_INTERFACE_UNKNOWN;
if (!strcasecmp(s,"catear")) return OVERLAY_INTERFACE_PACKETRADIO;
return WHY("Invalid interface type -- consider using 'wifi','ethernet' or 'other'");
}
int overlay_interface_arg(char *arg)
{
/* Parse an interface argument, of the form:
<+|->[interfacename][=type]
+interface tells DNA to sit on that interface
-interface tells DNA to not sit on that interface
+/- without an interface tells DNA to sit on all interfaces.
The first match rules, so -en0+ tells DNA to use all interfaces, excepting en0
The optional =type specifier tells DNA how to handle the interface in terms of
bandwidth:distance relationship for calculating tick times etc.
The special type =custom allows full specification:
XXX - Settle the custom specification now that we have changed the interface
management.
*/
char sign[80]="+";
char interface_name[80]="";
char speed[80]="1m";
char typestring[80]="wifi";
int port=PORT_DNA;
int type=OVERLAY_INTERFACE_UNKNOWN;
int n=0;
/* Too long */
if (strlen(arg)>79) return WHY("interface specification was >79 characters");
struct interface_rules *r=calloc(sizeof(struct interface_rules),1);
if (!r) return WHY("calloc(struct interface rules),1) failed");
if (sscanf(arg,"%[+-]%n%[^=:,]%n=%[^:]%n:%d%n:%[^:]%n",
sign,&n,interface_name,&n,typestring,&n,&port,&n,speed,&n)>=1)
{
if (n<strlen(arg)) { free(r); return WHY("Extra junk at end of interface specification"); }
if (strlen(sign)>1) { free(r); return WHY("Sign must be + or -"); }
switch(sign[0])
{
case '+': break;
case '-': r->excludeP=1; break;
default:
free(r);
return WHY("Invalid interface list item: Must begin with + or -");
}
long long speed_in_bits=parse_quantity(speed);
if (speed_in_bits<=1) {
free(r);
return WHY("Interfaces must be capable of at least 1 bit per second");
}
if (n<strlen(arg)) return WHY("Extra stuff at end of interface specification");
type=overlay_interface_type(typestring);
if (type<0) { free(r); return WHY("Invalid interface type in specification"); }
/* Okay, register the interface preference */
r->namespec=strdup(interface_name);
r->speed_in_bits=speed_in_bits;
r->port=port;
r->type=type;
r->next=interface_filter;
interface_filter=r;
return 0;
}
else { free(r); return WHY("Bad interface specification"); }
}
int overlay_interface_args(const char *arg)
{
/* Parse series of comma-separated interface definitions from a single argument
*/
int i=0;
char interface[80];
int len=0;
for(i=0;arg[i];i++)
{
if (arg[i]==','||arg[i]=='\n') {
interface[len]=0;
if (overlay_interface_arg(interface)) return WHY("Could not add interface");
len=0;
} else {
if (len<79) {
interface[len++]=arg[i];
interface[len]=0;
} else
return WHY("Interface definition is too long (each must be <80 characters)");
}
}
if (len) if (overlay_interface_arg(interface)) return WHY("Could not add final interface");
return 0;
}
int
overlay_interface_init_socket(int interface, struct sockaddr_in src_addr, struct sockaddr_in broadcast) {
char srctxt[INET_ADDRSTRLEN];
#define I(X) overlay_interfaces[interface].X
I(broadcast_address) = broadcast;
I(fileP) = 0;
I(alarm.poll.fd) = socket(PF_INET,SOCK_DGRAM,0);
if (I(alarm.poll.fd) < 0) {
WHY_perror("socket");
WHYF("Could not create UDP socket for interface: %s",strerror(errno));
goto error;
} else
INFOF("interface #%d fd=%d",interface, I(alarm.poll.fd));
int reuseP = 1;
if (setsockopt(I(alarm.poll.fd), SOL_SOCKET, SO_REUSEADDR, &reuseP, sizeof(reuseP)) < 0) {
WHY_perror("setsockopt(SO_REUSEADR)");
goto error;
}
#ifdef SO_REUSEPORT
if (setsockopt(I(alarm.poll.fd), SOL_SOCKET, SO_REUSEPORT, &reuseP, sizeof(reuseP)) < 0) {
WHY_perror("setsockopt(SO_REUSEPORT)");
goto error;
}
#endif
int broadcastP = 1;
if (setsockopt(I(alarm.poll.fd), SOL_SOCKET, SO_BROADCAST, &broadcastP, sizeof(broadcastP)) < 0) {
WHY_perror("setsockopt");
goto error;
}
/* Automatically close socket on calls to exec().
This makes life easier when we restart with an exec after receiving
a bad signal. */
fcntl(I(alarm.poll.fd), F_SETFL, fcntl(I(alarm.poll.fd), F_GETFL, NULL) | O_CLOEXEC);
/* @PGS/20120615
Use the broadcast address, so that we can reliably receive broadcast
traffic on all platforms. BUT on OSX we really need a non-broadcast socket
to send from, because you cannot send from a broadcast socket on OSX it seems.
*/
broadcast.sin_family = AF_INET;
broadcast.sin_port = htons(I(port));
if (bind(I(alarm.poll.fd), (struct sockaddr *)&broadcast, sizeof(broadcast))) {
WHY_perror("bind");
WHY("MP HLR server could not bind to requested UDP port (bind() failed)");
goto error;
}
assert(inet_ntop(AF_INET, (const void *)&broadcast.sin_addr, srctxt, INET_ADDRSTRLEN) != NULL);
if (debug & (DEBUG_PACKETRX | DEBUG_IO)) DEBUGF("Bound to %s:%d", srctxt, ntohs(broadcast.sin_port));
I(alarm.poll.events)=POLLIN;
I(alarm.function) = overlay_interface_poll;
interface_poll_stats.name="overlay_interface_poll";
I(alarm.stats)=&interface_poll_stats;
watch(&I(alarm));
return 0;
error:
close(I(alarm.poll.fd));
I(alarm.poll.fd)=-1;
return -1;
#undef I
}
int overlay_interface_init(char *name,struct sockaddr_in src_addr,struct sockaddr_in broadcast,
int speed_in_bits,int port,int type)
{
/* Too many interfaces */
if (overlay_interface_count>=OVERLAY_MAX_INTERFACES) return WHY("Too many interfaces -- Increase OVERLAY_MAX_INTERFACES");
#define I(X) overlay_interfaces[overlay_interface_count].X
strcpy(I(name),name);
/* Pick a reasonable default MTU.
This will ultimately get tuned by the bandwidth and other properties of the interface */
I(mtu)=1200;
I(observed)=1;
I(bits_per_second)=speed_in_bits;
I(port)=port;
I(type)=type;
I(last_tick_ms)=0;
I(alarm.poll.fd)=0;
switch (type) {
case OVERLAY_INTERFACE_PACKETRADIO:
I(tick_ms) = confValueGetInt64Range("mdp.packetradio.tick_ms", 15000LL, 1LL, 3600000LL);
break;
case OVERLAY_INTERFACE_ETHERNET:
I(tick_ms) = confValueGetInt64Range("mdp.ethernet.tick_ms", 500LL, 1LL, 3600000LL);
break;
case OVERLAY_INTERFACE_WIFI:
I(tick_ms) = confValueGetInt64Range("mdp.wifi.tick_ms", 500LL, 1LL, 3600000LL);
break;
case OVERLAY_INTERFACE_UNKNOWN:
I(tick_ms) = confValueGetInt64Range("mdp.unknown.tick_ms", 500LL, 1LL, 3600000LL);
break;
default:
return WHYF("Unsupported interface type %d", type);
}
if (name[0]=='>') {
I(fileP)=1;
char dummyfile[1024];
if (name[1]=='/') {
/* Absolute path */
snprintf(dummyfile,1024,"%s",&name[1]);
} else
/* Relative to instance path */
if (!FORM_SERVAL_INSTANCE_PATH(dummyfile, &name[1]))
return WHY("could not form dummy interfance name");
if ((I(alarm.poll.fd) = open(dummyfile,O_APPEND|O_RDWR)) < 1) {
return WHY("could not open dummy interface file for append");
}
/* Seek to end of file as initial reading point */
I(offset)=lseek(I(alarm.poll.fd),0,SEEK_END); /* socket gets reused to hold file offset */
/* XXX later add pretend location information so that we can decide which "packets" to receive
based on closeness */
// schedule an alarm for this interface
I(alarm.function)=overlay_dummy_poll;
I(alarm.alarm)=overlay_gettime_ms()+10;
dummy_poll_stats.name="overlay_dummy_poll";
I(alarm.stats)=&dummy_poll_stats;
schedule(&I(alarm));
} else {
if (overlay_interface_init_socket(overlay_interface_count,src_addr,broadcast))
return WHY("overlay_interface_init_socket() failed");
}
overlay_interface_count++;
#undef I
return 0;
}
void overlay_interface_poll(struct sched_ent *alarm)
{
struct overlay_interface *interface = (overlay_interface *)alarm;
int plen=0;
unsigned char packet[16384];
struct sockaddr src_addr;
socklen_t addrlen = sizeof(src_addr);
/* Read only one UDP packet per call to share resources more fairly, and also
enable stats to accurately count packets received */
int recvttl=1;
plen = recvwithttl(alarm->poll.fd,packet, sizeof(packet), &recvttl, &src_addr, &addrlen);
if (plen != -1) {
/* We have a frame from this interface */
if (debug&DEBUG_PACKETRX)
serval_packetvisualise(open_logging(),"Read from real interface", packet,plen);
if (debug&DEBUG_OVERLAYINTERFACES) DEBUGF("Received %d bytes on interface %s",plen,interface->name);
if (packetOk(interface,packet,plen,NULL,recvttl,&src_addr,addrlen,1)) {
WHY("Malformed packet");
serval_packetvisualise(open_logging(), "Malformed packet", packet,plen);
}
}
}
void overlay_dummy_poll(struct sched_ent *alarm)
{
overlay_interface *interface = (overlay_interface *)alarm;
/* Grab packets, unpackage and dispatch frames to consumers */
/* XXX Okay, so how are we managing out-of-process consumers?
They need some way to register their interest in listening to a port.
*/
unsigned char packet[16384];
int plen=0;
struct sockaddr src_addr;
size_t addrlen = sizeof(src_addr);
unsigned char transaction_id[8];
/* Read from dummy interface file */
long long length=lseek(alarm->poll.fd,0,SEEK_END);
if (interface->offset>=length)
{
if (debug&DEBUG_OVERLAYINTERFACES)
DEBUGF("At end of input on dummy interface %s", interface->name);
}
else
{
lseek(alarm->poll.fd,interface->offset,SEEK_SET);
if (debug&DEBUG_OVERLAYINTERFACES)
DEBUGF("Read interface %s (size=%lld) at offset=%d",interface->name, length, interface->offset);
ssize_t nread = read(alarm->poll.fd,&packet[0],2048);
if (nread == -1)
WHY_perror("read");
else {
interface->offset += nread;
if (nread == 2048) {
plen = packet[110]+(packet[111]<<8);
if (plen > nread - 128)
plen = -1;
if (debug&DEBUG_PACKETRX)
serval_packetvisualise(open_logging(), "Read from dummy interface", &packet[128], plen);
bzero(&transaction_id[0],8);
bzero(&src_addr,sizeof(src_addr));
if (plen >= 4) {
if (packet[0] == 0x01 && packet[1] == 0 && packet[2] == 0 && packet[3] == 0) {
if (packetOk(interface,&packet[128],plen,transaction_id, -1 /* fake TTL */, &src_addr,addrlen,1) == -1)
WARN("Unsupported packet from dummy interface");
} else {
WARNF("Unsupported packet version from dummy interface: %02x %02x %02x %02x", packet[0], packet[1], packet[2], packet[3]);
}
} else {
WARNF("Invalid packet from dummy interface: plen=%lld", (long long) plen);
}
}
else
WARNF("Read %lld bytes from dummy interface", nread);
}
}
alarm->alarm = overlay_gettime_ms()+10;
schedule(alarm);
return ;
}
int overlay_tx_messages()
{
/* Check out the various queues, and add payloads to a new frame and send it out. */
/* XXX We may want to throttle the maximum packets/sec or KB/sec */
/* How are we going to pick and choose things from the various priority queues?
We could simply pick the top item from each queue in round-robin until the
frame is filled. That would be a start. We could certainly get more intelligent
and stuff lots of little frames from a high priority queue in if that makes sense,
especially if they look like getting delayed a bit. Perhaps we just reserve the first
n bytes for the first queue, the first n+k bytes for the first two queues and so on?
*/
/* XXX Go through queue and separate into per-interface queues? */
return WHY("not implemented");
}
int overlay_broadcast_ensemble(int interface_number,
struct sockaddr_in *recipientaddr /* NULL == broadcast */,
unsigned char *bytes,int len)
{
struct sockaddr_in s;
if (debug&DEBUG_PACKETTX)
{
DEBUGF("Sending this packet via interface #%d",interface_number);
serval_packetvisualise(open_logging(),NULL,bytes,len);
}
overlay_interface *interface = &overlay_interfaces[interface_number];
memset(&s, '\0', sizeof(struct sockaddr_in));
if (recipientaddr) {
bcopy(recipientaddr,&s,sizeof(struct sockaddr_in));
}
else {
s = interface->broadcast_address;
s.sin_family = AF_INET;
if (debug&DEBUG_PACKETTX) DEBUGF("Port=%d",interface->port);
s.sin_port = htons(interface->port);
}
if (interface->fileP)
{
char buf[2048];
bzero(&buf[0],128);
/* Version information */
buf[0]=1; buf[1]=0;
buf[2]=0; buf[3]=0;
/* PID of creator */
buf[4]=getpid()&0xff; buf[5]=getpid()>>8;
/* TODO make a structure for all this stuff */
/* bytes 4-5 = half-power beam height (uint16) */
/* bytes 6-7 = half-power beam width (uint16) */
/* bytes 8-11 = range in metres, centre beam (uint32) */
/* bytes 16-47 = sender */
/* bytes 48-79 = next hop */
/* bytes 80-83 = latitude (uint32) */
/* bytes 84-87 = longitude (uint32) */
/* bytes 88-89 = X/Z direction (uint16) */
/* bytes 90-91 = Y direction (uint16) */
/* bytes 92-93 = speed in metres per second (uint16) */
/* bytes 94-97 = TX frequency in Hz, uncorrected for doppler (which must be done at the receiving end to take into account
relative motion) */
/* bytes 98-109 = coding method (use for doppler response etc) null terminated string */
/* bytes 110-111 = length of packet body in bytes */
/* bytes 112-127 reserved for future use */
if (len>2048-128) {
WARN("Truncating long packet to fit within 1920 byte limit for dummy interface");
len=2048-128;
}
/* Record length of packet */
buf[110]=len&0xff;
buf[111]=(len>>8)&0xff;
bzero(&buf[128+len],2048-(128+len));
bcopy(bytes,&buf[128],len);
/* This lseek() is unneccessary because the dummy file is opened in O_APPEND mode. It's
only purpose is to find out the offset to print in the DEBUG statement. It is vulnerable
to a race condition with other processes appending to the same file. */
off_t fsize = lseek(interface->alarm.poll.fd, (off_t) 0, SEEK_END);
if (fsize == -1)
return WHY_perror("lseek");
interface->offset = fsize;
if (debug&DEBUG_OVERLAYINTERFACES)
DEBUGF("Write to interface %s at offset=%d", interface->name, interface->offset);
ssize_t nwrite = write(interface->alarm.poll.fd, buf, 2048);
if (nwrite == -1)
return WHY_perror("write");
interface->offset += nwrite;
if (nwrite != 2048)
return WHYF("only wrote %lld of %lld bytes", nwrite, 2048);
return 0;
}
else
{
if(sendto(interface->alarm.poll.fd,
bytes, len, 0, (struct sockaddr *)&s, sizeof(struct sockaddr_in)) != len)
return WHY_perror("sendto(c)");
return 0;
}
}
/* This function is called to return old non-overlay requests back out the
interface they came in. */
int overlay_sendto(struct sockaddr_in *recipientaddr,unsigned char *bytes,int len)
{
if (debug&DEBUG_PACKETTX) DEBUGF("Sending %d bytes",len);
if (overlay_broadcast_ensemble(overlay_last_interface_number,recipientaddr,bytes,len) == -1)
return -1;
return len;
}
/* Register the interface, or update the existing interface registration */
int
overlay_interface_register(char *name,
struct sockaddr_in local,
struct sockaddr_in broadcast) {
struct interface_rules *r, *me;
int i;
/* See if the interface is listed in the filter */
me = NULL;
r = interface_filter;
while(r) {
if (!strcasecmp(name, r->namespec))
me = r;
r = r->next;
}
if (me == NULL || me->excludeP) {
if (debug & DEBUG_OVERLAYINTERFACES)
DEBUGF("Interface %s is not interesting.",name);
return 0;
}
/* Search in the exist list of interfaces */
for(i = 0; i < overlay_interface_count; i++)
if (!strcasecmp(overlay_interfaces[i].name, name))
break;
if (i < overlay_interface_count) {
/* We already know about this interface, so just update it. */
/* Check if the broadcast address is the same
TODO: This only applies on Linux because only there can you bind to the bcast addr
DOC 20120608
*/
if ((overlay_interfaces[i].broadcast_address.sin_addr.s_addr & 0xffffffff)
== (broadcast.sin_addr.s_addr & 0xffffffff)) {
/* Same address, mark it as being seen */
overlay_interfaces[i].observed = 1;
return 0;
} else {
if (0) {
/* Interface has changed.
TODO: We should register each address we understand in a list and check them.
DOC 20120608 */
INFOF("Interface changed %08llx.%08llx vs %08llx.%08llx",
/* overlay_interfaces[i].local_address.sin_addr.s_addr */0,
overlay_interfaces[i].broadcast_address.sin_addr.s_addr,
local.sin_addr.s_addr,
broadcast.sin_addr.s_addr);
unwatch(&overlay_interfaces[i].alarm);
close(overlay_interfaces[i].alarm.poll.fd);
overlay_interfaces[i].alarm.poll.fd = -1;
if (overlay_interface_init_socket(i, local, broadcast))
INFOF("Could not reinitialise changed interface %s", name);
}
}
} else {
/* New interface, so register it */
if (overlay_interface_init(name,local, broadcast, me->speed_in_bits, me->port, me->type))
WHYF("Could not initialise newly seen interface %s", name);
else
if (debug & DEBUG_OVERLAYINTERFACES) DEBUGF("Registered interface %s", name);
}
return 0;
}
void overlay_interface_discover(struct sched_ent *alarm){
int no_route, i;
struct interface_rules *r;
struct sockaddr_in dummyaddr;
/* Mark all interfaces as not observed, so that we know if we need to cull any */
for(i = 0; i < overlay_interface_count; i++)
overlay_interfaces[i].observed = 0;
/* Check through for any virtual dummy interfaces */
for (r = interface_filter; r != NULL; r = r->next) {
if (r->namespec[0] != '>')
continue;
for(i = 0; i < overlay_interface_count; i++)
if (!strcasecmp(overlay_interfaces[i].name,r->namespec))
break;
if (i < overlay_interface_count)
/* We already know about this interface, so just update it */
overlay_interfaces[i].observed = 1;
else {
/* New interface, so register it */
if (overlay_interface_init(r->namespec,dummyaddr,dummyaddr,
1000000,PORT_DNA,OVERLAY_INTERFACE_WIFI)) {
if (debug & DEBUG_OVERLAYINTERFACES) DEBUGF("Could not initialise newly seen interface %s", r->namespec);
}
else
if (debug & DEBUG_OVERLAYINTERFACES) DEBUGF("Registered interface %s",r->namespec);
}
}
/* Look for real interfaces */
no_route = 1;
#ifdef HAVE_IFADDRS_H
if (no_route != 0)
no_route = doifaddrs();
#endif
#ifdef SIOCGIFCONF
if (no_route != 0)
no_route = lsif();
#endif
#ifdef linux
if (no_route != 0)
no_route = scrapeProcNetRoute();
#endif
if (no_route != 0) {
FATAL("Unable to get any interface information");
}
alarm->alarm = overlay_gettime_ms()+5000;
schedule(alarm);
return;
}
int overlay_stuff_packet_from_queue(int i,overlay_buffer *e,int q,long long now,overlay_frame *pax[],int *frame_pax,int frame_max_pax)
{
if (0) DEBUGF("Stuffing from queue #%d on interface #%d",q,i);
overlay_frame **p=&overlay_tx[q].first;
if (0) DEBUGF("A p=%p, *p=%p, queue=%d",p,*p,q);
while(p&&(*p))
{
if (0) DEBUGF("B p=%p, *p=%p, queue=%d",p,*p,q);
/* Throw away any stale frames */
overlay_frame *pp;
if (p) pp=*p;
if (!pp) break;
if (0) DEBUGF("now=%lld, *p=%p, q=%d, overlay_tx[q]=%p",
now,*p,q,&overlay_tx[q]);
if (0) overlay_queue_dump(&overlay_tx[q]);
if (now>((*p)->enqueued_at+overlay_tx[q].latencyTarget)) {
/* Stale, so remove from queue. */
/* Get pointer to stale entry */
overlay_frame *stale=*p;
if (0)
DEBUGF("Removing stale frame at %p (now=%lld, expiry=%lld)",
stale,
now,((*p)->enqueued_at+overlay_tx[q].latencyTarget));
if (0) DEBUGF("now=%lld, *p=%p, q=%d, overlay_tx[q]=%p",
now,*p,q,&overlay_tx[q]);
/* Make ->next pointer that points to the stale node skip the stale node */
if (0) DEBUGF("p=%p, stale=%p, stale->next=%p",p,stale,stale->next);
*p=stale->next;
/* If there is an entry after the stale now, make it's prev point to the
node before the stale node */
if (*p) (*p)->prev=stale->prev;
if (overlay_tx[q].first==stale) overlay_tx[q].first=stale->next;
if (overlay_tx[q].last==stale) overlay_tx[q].last=stale->prev;
op_free(stale);
overlay_tx[q].length--;
}
else
{
/* We keep trying to queue frames in case they will fit, as not all
frames are of equal size. This means that lower bit-rate codecs will
get higher priority, which is probably not all bad. The only hard
limit is the maximum number of payloads we allow in a frame, which is
set so high as to be irrelevant, even on loopback or gigabit ethernet
interface */
/* Filter for those which should be sent via this interface.
To do that we need to know the nexthop, and the best route to the
next hop. */
int dontSend=1;
/* See if this interface has the best path to this node */
if (!(*p)->isBroadcast) {
unsigned char nexthop[SID_SIZE];
int len=0;
int next_hop_interface=-1;
int r=overlay_get_nexthop((*p)->destination,nexthop,&len,
&next_hop_interface);
if (!r) {
if (next_hop_interface==i) {
if (0) DEBUGF("unicast pax %p",*p);
dontSend=0; } else {
if (0)
DEBUGF("Packet should go via interface #%d, but I am interface #%d",next_hop_interface,i);
}
} else {
DEBUG("bummer, I couldn't find an open route to that node");
DEBUGF("sid=%s", alloca_tohex_sid((*p)->destination));
}
} else if (!(*p)->broadcast_sent_via[i])
{
/* Broadcast frames are easy to work out if they go via this interface,
just make sure that they haven't been previously sent via this
interface. We then have some magic that only dequeues broadcast packets
once they have been sent via all open interfaces (or gone stale) */
dontSend=0;
(*p)->broadcast_sent_via[i]=1;
if (0) DEBUGF("broadcast pax %p",*p);
}
if (dontSend==0) {
/* Try sending by this queue */
if (*frame_pax>=frame_max_pax) break;
if (!overlay_frame_package_fmt1(*p,e))
{
/* Add payload to list of payloads we are sending with this frame so that we can dequeue them
if we send them. */
if (0) {
DEBUGF(" paxed#%d %p%s",*frame_pax,*p,
(*p)->isBroadcast?"(broadcast)":"");
dump("payload of pax",(*p)->payload->bytes,(*p)->payload->length);
}
pax[(*frame_pax)++]=*p;
}
}
}
if (0) DEBUGF("C p=%p, *p=%p, queue=%d",p,*p,q);
if (*p)
/* Consider next in queue */
p=&(*p)->next;
if (0) DEBUGF("D p=%p, *p=%p, queue=%d",p,p?*p:NULL,q);
}
if (0) DEBUG("returning from stuffing");
return 0;
}
int overlay_queue_dump(overlay_txqueue *q)
{
strbuf b = strbuf_alloca(8192);
struct overlay_frame *f;
strbuf_sprintf(b,"overlay_txqueue @ 0x%p\n",q);
strbuf_sprintf(b," length=%d\n",q->length);
strbuf_sprintf(b," maxLenght=%d\n",q->maxLength);
strbuf_sprintf(b," latencyTarget=%d milli-seconds\n",q->latencyTarget);
strbuf_sprintf(b," first=%p\n",q->first);
f=q->first;
while(f) {
strbuf_sprintf(b," %p: ->next=%p, ->prev=%p ->dequeue=%d\n",
f,f->next,f->prev,f->dequeue);
if (f==f->next) {
strbuf_sprintf(b," LOOP!\n"); break;
}
f=f->next;
}
strbuf_sprintf(b," last=%p\n",q->last);
f=q->last;
while(f) {
strbuf_sprintf(b," %p: ->next=%p, ->prev=%p\n",
f,f->next,f->prev);
if (f==f->prev) {
strbuf_sprintf(b," LOOP!\n"); break;
}
f=f->prev;
}
DEBUG(strbuf_str(b));
return 0;
}
int overlay_tick_interface(int i, long long now)
{
int frame_pax=0;
overlay_buffer *e=NULL;
#define MAX_FRAME_PAX 1024
overlay_frame *pax[MAX_FRAME_PAX];
if (overlay_interfaces[i].bits_per_second<1) {
/* An interface with no speed budget is for listening only, so doesn't get ticked */
return 0;
}
if (debug&DEBUG_OVERLAYINTERFACES) DEBUGF("Ticking interface #%d",i);
/* Get a buffer ready, and limit it's size appropriately.
XXX size limit should be reduced from MTU.
XXX we should also take account of the volume of data likely to be in the TX buffer. */
e=ob_new(overlay_interfaces[i].mtu);
if (!e) return WHY("ob_new() failed");
ob_limitsize(e,overlay_interfaces[i].mtu/4);
/* 0. Setup Serval Mesh frame header. We do not use an explicit length field for these, as the various
component payloads are all self-authenticating, or at least that is the theory. */
unsigned char bytes[]={/* Magic */ 'O',0x10,
/* Version */ 0x00,0x01};
if (ob_append_bytes(e,bytes,4)) {
ob_free(e);
return WHY("ob_append_bytes() refused to append magic bytes.");
}
/* 1. Send announcement about ourselves, including one SID that we host if we host more than one SID
(the first SID we host becomes our own identity, saving a little bit of data here).
*/
overlay_add_selfannouncement(i,e);
/* 2. Add any queued high-priority isochronous data (i.e. voice) to the frame. */
overlay_stuff_packet_from_queue(i,e,OQ_ISOCHRONOUS_VOICE,now,pax,&frame_pax,MAX_FRAME_PAX);
ob_limitsize(e,overlay_interfaces[i].mtu/2);
/* 3. Add some mesh reachability reports (unlike BATMAN we announce reachability to peers progressively).
Give priority to newly observed nodes so that good news travels quickly to help roaming.
XXX - Don't forget about PONGing reachability reports to allow use of monodirectional links.
*/
overlay_stuff_packet_from_queue(i,e,OQ_MESH_MANAGEMENT,now,pax,&frame_pax,MAX_FRAME_PAX);
/* We previously limited manifest space to 3/4 of MTU, but that causes problems for
MeshMS journal manifests, at least until we move to a compact binary format.
So for now, allow allow rest of packet to get used */
#warning reduce to <= mtu*3/4 once we have compacty binary canonical manifest format
ob_limitsize(e,overlay_interfaces[i].mtu*4/4);
/* Add advertisements for ROUTES not Rhizome bundles.
Rhizome bundle advertisements are lower priority */
overlay_route_add_advertisements(e);
ob_limitsize(e,overlay_interfaces[i].mtu);
/* 4. XXX Add lower-priority queued data */
overlay_stuff_packet_from_queue(i,e,OQ_ISOCHRONOUS_VIDEO,now,pax,&frame_pax,MAX_FRAME_PAX);
overlay_stuff_packet_from_queue(i,e,OQ_ORDINARY,now,pax,&frame_pax,MAX_FRAME_PAX);
overlay_stuff_packet_from_queue(i,e,OQ_OPPORTUNISTIC,now,pax,&frame_pax,MAX_FRAME_PAX);
/* 5. XXX Fill the packet up to a suitable size with anything that seems a good idea */
if (rhizome_enabled())
overlay_rhizome_add_advertisements(i,e);
if (debug&DEBUG_PACKETCONSTRUCTION)
dump("assembled packet",&e->bytes[0],e->length);
/* Now send the frame. This takes the form of a special DNA packet with a different
service code, which we setup earlier. */
if (debug&DEBUG_OVERLAYINTERFACES)
DEBUGF("Sending %d byte tick packet",e->length);
if (overlay_broadcast_ensemble(i,NULL,e->bytes,e->length) != -1)
{
overlay_update_sequence_number();
if (debug&DEBUG_OVERLAYINTERFACES)
DEBUGF("Successfully transmitted tick frame #%lld on interface #%d (%d bytes)",
(long long)overlay_sequence_number,i,e->length);
/* De-queue the passengers who were aboard.
One round of marking, and then one round of culling from the queue. */
int j,q;
/* Mark frames that can be dequeued */
for(j=0;j<frame_pax;j++)
{
overlay_frame *p=pax[j];
if (0)
DEBUGF("dequeue %p ?%s",p,p->isBroadcast?" (broadcast)":" (unicast)");
if (!p->isBroadcast)
{
if (0) DEBUG("yes");
p->dequeue=1;
}
else {
int i;
int workLeft=0;
for(i=0;i<OVERLAY_MAX_INTERFACES;i++)
{
if (overlay_interfaces[i].observed>0)
if (!p->broadcast_sent_via[i])
{
workLeft=1;
break;
}
}
if (!workLeft) p->dequeue=1;
}
}
/* Visit queues and dequeue all that we can */
for(q=0;q<OQ_MAX;q++)
{
overlay_frame **p=&overlay_tx[q].first;
overlay_frame *t;
while(p&&(*p))
{
if ((*p)->dequeue) {
{
if (debug&DEBUG_QUEUES)
DEBUGF("dequeuing %s* -> %s* NOW (queue length=%d)",
overlay_render_sid_prefix((*p)->source,7),
overlay_render_sid_prefix((*p)->destination,7),
overlay_tx[q].length);
t=*p;
*p=t->next;
if (overlay_tx[q].last==t) overlay_tx[q].last=t->prev;
if (overlay_tx[q].first==t) overlay_tx[q].first=t->next;
if (t->prev) t->prev->next=t->next;
if (t->next) t->next->prev=t->prev;
if (debug&DEBUG_QUEUES)
{
DEBUGF("** dequeued pax @ %p",t);
overlay_queue_dump(&overlay_tx[q]);
}
if (op_free(t)) {
overlay_queue_dump(&overlay_tx[q]);
WHY("op_free() failed");
if (debug&DEBUG_QUEUES) exit(WHY("Queue structures corrupt"));
}
overlay_tx[q].length--;
}
} else {
/* only skip ahead if we haven't dequeued something */
if (!(*p)) break;
p=&(*p)->next;
}
}
}
if (e) ob_free(e); e=NULL;
return 0;
}
else {
if (e) ob_free(e); e=NULL;
return WHY("overlay_broadcast_ensemble() failed");
}
}
void overlay_check_ticks(struct sched_ent *alarm) {
/* Check if any interface(s) are due for a tick */
int i;
long long now = overlay_gettime_ms();
/* Now check if the next tick time for the interfaces is no later than that time.
If so, trigger a tick on the interface. */
if (debug & DEBUG_OVERLAYINTERFACES) DEBUGF("Examining %d interfaces.",overlay_interface_count);
for(i = 0; i < overlay_interface_count; i++) {
/* Only tick live interfaces */
if (overlay_interfaces[i].observed > 0) {
if (debug & DEBUG_VERBOSE_IO) DEBUGF("Interface %s ticks every %dms, last at %lld.",
overlay_interfaces[i].name,
overlay_interfaces[i].tick_ms,
overlay_interfaces[i].last_tick_ms);
if (now >= overlay_interfaces[i].last_tick_ms + overlay_interfaces[i].tick_ms) {
/* This interface is due for a tick */
overlay_tick_interface(i, now);
overlay_interfaces[i].last_tick_ms = now;
}
} else
if (debug & DEBUG_VERBOSE_IO) DEBUGF("Interface %s is awol.", overlay_interfaces[i].name);
}
/* Update interval until next tick */
alarm->alarm = overlay_next_tick();
schedule(alarm);
return;
}
long long overlay_next_tick()
{
/* By default only tick once per day */
long long now=overlay_gettime_ms();
long long nexttick=86400*1000;
int i;
if (debug&DEBUG_VERBOSE_IO) DEBUGF("Tick-check on %d interfaces at %lldms",overlay_interface_count,now);
for(i=0;i<overlay_interface_count;i++)
if (overlay_interfaces[i].observed>0)
{
long long thistick=
overlay_interfaces[i].tick_ms
-(now-overlay_interfaces[i].last_tick_ms);
if (0)
DEBUGF("Interface %s ticks every %dms, last at T-%lldms, next needed in %lldms",
overlay_interfaces[i].name,
overlay_interfaces[i].tick_ms,now-overlay_interfaces[i].last_tick_ms,
thistick);
if (thistick<0) thistick=0;
if (thistick<nexttick) nexttick=thistick;
if (0) WHYF("nexttick is now %lldms",nexttick);
}
if (0) WHYF("Next tick required in %lldms",nexttick);
return now + nexttick;
}
long long parse_quantity(char *q)
{
int m;
char units[80];
if (strlen(q)>=80) return WHY("quantity string >=80 characters");
if (sscanf(q,"%d%s",&m,units)==2)
{
if (units[1]) return WHY("Units should be single character");
switch(units[0])
{
case 'k': return m*1000LL;
case 'K': return m*1024LL;
case 'm': return m*1000LL*1000LL;
case 'M': return m*1024LL*1024LL;
case 'g': return m*1000LL*1000LL*1000LL;
case 'G': return m*1024LL*1024LL*1024LL;
default:
return WHY("Illegal unit: should be k,K,m,M,g, or G.");
}
}
if (sscanf(q,"%d",&m)==1)
{
return m;
}
else
{
return WHY("Could not parse quantity");
}
}