/* 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 #include #include "serval.h" #include "strbuf.h" #include "overlay_buffer.h" #include "overlay_packet.h" #ifdef HAVE_IFADDRS_H #include #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; struct sched_ent sock_any; struct sockaddr_in sock_any_addr; struct profile_total sock_any_stats; struct outgoing_packet{ overlay_interface *interface; int i; struct sockaddr_in dest; struct overlay_buffer *buffer; }; struct sched_ent next_packet; struct profile_total send_packet; static int overlay_tick_interface(int i, time_ms_t now); static void overlay_interface_poll(struct sched_ent *alarm); static void logServalPacket(int level, struct __sourceloc where, const char *message, const unsigned char *packet, size_t len); static long long parse_quantity(char *q); unsigned char magic_header[]={/* Magic */ 'O',0x10, /* Version */ 0x00,0x01}; static 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 (n1) { 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 (nnamespec=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; } static void overlay_interface_close(overlay_interface *interface){ if (interface->fileP){ INFOF("Interface %s is down", interface->name); }else{ INFOF("Interface %s addr %s is down", interface->name, inet_ntoa(interface->broadcast_address.sin_addr)); } unschedule(&interface->alarm); unwatch(&interface->alarm); close(interface->alarm.poll.fd); interface->alarm.poll.fd=-1; interface->state=INTERFACE_STATE_DOWN; } // create a socket with options common to all our UDP sockets static int overlay_bind_socket(const struct sockaddr *addr, size_t addr_size, char *interface_name){ int fd; int reuseP = 1; int broadcastP = 1; fd = socket(PF_INET,SOCK_DGRAM,0); if (fd < 0) { WHY_perror("Error creating socket"); return -1; } if (setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, &reuseP, sizeof(reuseP)) < 0) { WHY_perror("setsockopt(SO_REUSEADR)"); goto error; } #ifdef SO_REUSEPORT if (setsockopt(fd, SOL_SOCKET, SO_REUSEPORT, &reuseP, sizeof(reuseP)) < 0) { WHY_perror("setsockopt(SO_REUSEPORT)"); goto error; } #endif if (setsockopt(fd, SOL_SOCKET, SO_BROADCAST, &broadcastP, sizeof(broadcastP)) < 0) { WHY_perror("setsockopt(SO_BROADCAST)"); 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(fd, F_SETFL, fcntl(fd, F_GETFL, NULL) | O_CLOEXEC); #ifdef SO_BINDTODEVICE /* Limit incoming and outgoing packets to this interface, no matter what the routing table says. This should allow for a device with multiple interfaces on the same subnet. Don't abort if this fails, I believe it requires root, just log it. */ if (interface_name && setsockopt(fd, SOL_SOCKET, SO_BINDTODEVICE, interface_name, strlen(interface_name)+1) < 0) { WHY_perror("setsockopt(SO_BINDTODEVICE)"); } #endif if (bind(fd, addr, addr_size)) { WHY_perror("Bind failed"); goto error; } return fd; error: close(fd); return -1; } overlay_interface * overlay_interface_find(struct in_addr addr){ int i; for (i=0;ipoll.revents & POLLIN) { int plen=0; int recvttl=1; unsigned char packet[16384]; overlay_interface *interface=NULL; 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 */ plen = recvwithttl(alarm->poll.fd, packet, sizeof(packet), &recvttl, &src_addr, &addrlen); if (plen == -1) { WHY_perror("recvwithttl(c)"); unwatch(alarm); close(alarm->poll.fd); return; } struct in_addr src = ((struct sockaddr_in *)&src_addr)->sin_addr; /* Try to identify the real interface that the packet arrived on */ interface = overlay_interface_find(src); /* Drop the packet if we don't find a match */ if (!interface){ if (debug&DEBUG_OVERLAYINTERFACES) DEBUGF("Could not find matching interface for packet received from %s", inet_ntoa(src)); return; } /* We have a frame from this interface */ if (debug&DEBUG_PACKETRX) DEBUG_packet_visualise("Read from real interface", packet,plen); if (debug&DEBUG_OVERLAYINTERFACES) DEBUGF("Received %d bytes on interface INADDR_ANY",plen); if (packetOk(interface,packet,plen,NULL,recvttl,&src_addr,addrlen,1)) { WHY("Malformed packet"); } } if (alarm->poll.revents & (POLLHUP | POLLERR)) { INFO("Closing broadcast socket due to error"); unwatch(alarm); close(alarm->poll.fd); alarm->poll.fd=-1; } } // bind a socket to INADDR_ANY:port // for now, we don't have a graceful close for this interface but it should go away when the process dies static int overlay_interface_init_any(int port){ struct sockaddr_in addr; if (sock_any.poll.fd>0){ // Check the port number matches assert(sock_any_addr.sin_port == htons(port)); return 0; } addr.sin_family = AF_INET; addr.sin_port = htons(port); addr.sin_addr.s_addr = INADDR_ANY; sock_any.poll.fd = overlay_bind_socket((const struct sockaddr *)&addr, sizeof(addr), NULL); if (sock_any.poll.fd<0) return -1; sock_any_addr = addr; sock_any.poll.events=POLLIN; sock_any.function = overlay_interface_read_any; sock_any_stats.name="overlay_interface_read_any"; sock_any.stats=&sock_any_stats; watch(&sock_any); return 0; } static int overlay_interface_init_socket(int interface_index) { overlay_interface *const interface = &overlay_interfaces[interface_index]; interface->fileP = 0; #ifdef __APPLE__ /* On OSX and probably windows you can't bind to a broadcast address. */ const struct sockaddr *addr = (const struct sockaddr *)&interface->address; /* On osx, UDP sockets bound to a specific interface can send broadcast packets just fine, but can't receive broadcast packets So we need a socket bound to INADDR_ANY for receiving them. */ overlay_interface_init_any(interface->port); #else /* Bind to the broadcast address, so that we can reliably receive broadcast traffic on linux platforms. */ const struct sockaddr *addr = (const struct sockaddr *)&interface->broadcast_address; #endif interface->alarm.poll.fd = overlay_bind_socket(addr, sizeof(interface->broadcast_address), interface->name); if (interface->alarm.poll.fd<0){ interface->state=INTERFACE_STATE_DOWN; return -1; } if (debug & (DEBUG_PACKETRX | DEBUG_IO)){ char srctxt[INET_ADDRSTRLEN]; if (inet_ntop(AF_INET, (const void *)&interface->broadcast_address.sin_addr, srctxt, INET_ADDRSTRLEN)) DEBUGF("Bound to %s:%d", srctxt, ntohs(interface->broadcast_address.sin_port)); } interface->alarm.poll.events=POLLIN; interface->alarm.function = overlay_interface_poll; interface_poll_stats.name="overlay_interface_poll"; interface->alarm.stats=&interface_poll_stats; watch(&interface->alarm); if (interface->tick_ms>0){ // run the first tick asap interface->alarm.alarm=gettime_ms(); interface->alarm.deadline=interface->alarm.alarm+10; schedule(&interface->alarm); } interface->state=INTERFACE_STATE_UP; INFOF("Interface %s addr %s, is up",interface->name, inet_ntoa(interface->broadcast_address.sin_addr)); return 0; } static int overlay_interface_init(char *name, struct in_addr src_addr, struct in_addr netmask, struct in_addr 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"); overlay_interface *const interface = &overlay_interfaces[overlay_interface_count]; strcpy(interface->name,name); /* Pick a reasonable default MTU. This will ultimately get tuned by the bandwidth and other properties of the interface */ interface->mtu=1200; interface->state=INTERFACE_STATE_DOWN; interface->bits_per_second=speed_in_bits; interface->port=port; interface->type=type; interface->last_tick_ms= -1; // not ticked yet interface->alarm.poll.fd=0; // how often do we announce ourselves on this interface? switch (type) { case OVERLAY_INTERFACE_PACKETRADIO: interface->tick_ms = confValueGetInt64Range("mdp.packetradio.tick_ms", 15000LL, 1LL, 3600000LL); break; case OVERLAY_INTERFACE_ETHERNET: interface->tick_ms = confValueGetInt64Range("mdp.ethernet.tick_ms", 500LL, 1LL, 3600000LL); break; case OVERLAY_INTERFACE_WIFI: interface->tick_ms = confValueGetInt64Range("mdp.wifi.tick_ms", 500LL, 1LL, 3600000LL); break; case OVERLAY_INTERFACE_UNKNOWN: interface->tick_ms = confValueGetInt64Range("mdp.unknown.tick_ms", 500LL, 1LL, 3600000LL); break; default: return WHYF("Unsupported interface type %d", type); } // allow for a per interface override of tick interval { char option_name[64]; snprintf(option_name, sizeof(option_name), "mdp.%s.tick_ms", name); interface->tick_ms = confValueGetInt64Range(option_name, interface->tick_ms, 1LL, 3600000LL); } // disable announcements and other broadcasts if tick_ms=0. if (interface->tick_ms>0) interface->send_broadcasts=1; else interface->send_broadcasts=0; if (name[0]=='>') { interface->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 ((interface->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 */ interface->recv_offset = lseek(interface->alarm.poll.fd,0,SEEK_END); /* XXX later add pretend location information so that we can decide which "packets" to receive based on closeness */ // schedule an alarm for this interface interface->alarm.function=overlay_dummy_poll; interface->alarm.alarm=gettime_ms()+10; interface->alarm.deadline=interface->alarm.alarm; dummy_poll_stats.name="overlay_dummy_poll"; interface->alarm.stats=&dummy_poll_stats; schedule(&interface->alarm); interface->state=INTERFACE_STATE_UP; INFOF("Dummy interface %s is up",interface->name); } else { interface->netmask = netmask; interface->address.sin_addr = src_addr; interface->address.sin_family = AF_INET; interface->address.sin_port = htons(interface->port); interface->broadcast_address.sin_addr = broadcast; interface->broadcast_address.sin_family = AF_INET; interface->broadcast_address.sin_port = htons(interface->port); if (overlay_interface_init_socket(overlay_interface_count)) return WHY("overlay_interface_init_socket() failed"); } overlay_interface_count++; return 0; } static void overlay_interface_poll(struct sched_ent *alarm) { struct overlay_interface *interface = (overlay_interface *)alarm; if (alarm->poll.revents==0){ if (interface->state==INTERFACE_STATE_UP && interface->tick_ms>0){ // tick the interface time_ms_t now = gettime_ms(); int i = (interface - overlay_interfaces); overlay_tick_interface(i, now); alarm->alarm=now+interface->tick_ms; alarm->deadline=alarm->alarm+interface->tick_ms/2; schedule(alarm); } return; } if (alarm->poll.revents & POLLIN) { 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) { WHY_perror("recvwithttl(c)"); overlay_interface_close(interface); return; } /* We have a frame from this interface */ if (debug&DEBUG_PACKETRX) DEBUG_packet_visualise("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"); // Do we really want to attempt to parse it again? //DEBUG_packet_visualise("Malformed packet", packet,plen); } } if (alarm->poll.revents & (POLLHUP | POLLERR)) { overlay_interface_close(interface); } } 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[2048]; int plen=0; struct sockaddr src_addr; size_t addrlen = sizeof(src_addr); unsigned char transaction_id[8]; time_ms_t now = gettime_ms(); if (interface->tick_ms>0 && (interface->last_tick_ms == -1 || now >= interface->last_tick_ms + interface->tick_ms)) { // tick the interface int i = (interface - overlay_interfaces); overlay_tick_interface(i, now); } /* Read from dummy interface file */ long long length=lseek(alarm->poll.fd,0,SEEK_END); if (interface->recv_offset >= length) { /* if there's no input, while we want to check for more soon, we need to allow all other low priority alarms to fire first, otherwise we'll dominate the scheduler without accomplishing anything */ alarm->alarm = gettime_ms() + 20; if (interface->last_tick_ms != -1 && alarm->alarm > interface->last_tick_ms + interface->tick_ms) alarm->alarm = interface->last_tick_ms + interface->tick_ms; alarm->deadline = alarm->alarm + 10000; } else { if (lseek(alarm->poll.fd,interface->recv_offset,SEEK_SET) == -1) WHY_perror("lseek"); else { if (debug&DEBUG_OVERLAYINTERFACES) DEBUGF("Read interface %s (size=%lld) at offset=%d",interface->name, length, interface->recv_offset); ssize_t nread = read(alarm->poll.fd, packet, sizeof packet); if (nread == -1) WHY_perror("read"); else { interface->recv_offset += nread; if (nread == sizeof packet) { plen = packet[110] + (packet[111] << 8); if (plen > nread - 128) plen = -1; if (debug&DEBUG_PACKETRX) DEBUG_packet_visualise("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); } } /* keep reading new packets as fast as possible, but don't prevent other high priority alarms */ alarm->alarm = gettime_ms(); alarm->deadline = alarm->alarm + 200; } schedule(alarm); return ; } static int overlay_broadcast_ensemble(int interface_number, struct sockaddr_in *recipientaddr, unsigned char *bytes,int len) { if (debug&DEBUG_PACKETTX) { DEBUGF("Sending this packet via interface #%d",interface_number); DEBUG_packet_visualise(NULL,bytes,len); } overlay_interface *interface = &overlay_interfaces[interface_number]; if (interface->state!=INTERFACE_STATE_UP){ return WHYF("Cannot send to interface %s as it is down", interface->name); } 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"); if (debug&DEBUG_OVERLAYINTERFACES) DEBUGF("Write to interface %s at offset=%d", interface->name, fsize); ssize_t nwrite = write(interface->alarm.poll.fd, buf, 2048); if (nwrite == -1) return WHY_perror("write"); 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 *)recipientaddr, sizeof(struct sockaddr_in)) != len){ WHY_perror("sendto(c)"); overlay_interface_close(interface); return -1; } 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 in_addr addr, struct in_addr mask) { struct interface_rules *r, *me; int i; struct in_addr broadcast = {.s_addr = addr.s_addr | ~mask.s_addr}; if (debug & DEBUG_OVERLAYINTERFACES) { // note, inet_ntop doesn't seem to behave on android DEBUGF("%s address: %s", name, inet_ntoa(addr)); DEBUGF("%s broadcast address: %s", name, inet_ntoa(broadcast)); } /* 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; } int found_interface= -1; /* Search in the exist list of interfaces */ for(i = 0; i < overlay_interface_count; i++){ int broadcast_match = 0; int name_match =0; if ((overlay_interfaces[i].broadcast_address.sin_addr.s_addr & 0xffffffff) == (broadcast.s_addr & 0xffffffff)){ broadcast_match = 1; } name_match = !strcasecmp(overlay_interfaces[i].name, name); // if we find an exact match we can stop searching if (name_match && broadcast_match){ // mark this interface as still alive if (overlay_interfaces[i].state==INTERFACE_STATE_DETECTING) overlay_interfaces[i].state=INTERFACE_STATE_UP; // try to bring the interface back up again even if the address has changed if (overlay_interfaces[i].state==INTERFACE_STATE_DOWN){ overlay_interfaces[i].address.sin_addr = addr; overlay_interface_init_socket(i); } // we already know about this interface, and it's up so stop looking immediately return 0; } // remember this slot to bring the interface back up again, even if the address has changed if (name_match && overlay_interfaces[i].state==INTERFACE_STATE_DOWN) found_interface=i; } if (found_interface>=0){ // try to reactivate the existing interface overlay_interfaces[i].address.sin_addr = addr; overlay_interfaces[i].broadcast_address.sin_addr = broadcast; overlay_interfaces[i].netmask = mask; return overlay_interface_init_socket(i); } /* New interface, so register it */ if (overlay_interface_init(name, addr, mask, broadcast, me->speed_in_bits, me->port, me->type)) return 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 i; struct interface_rules *r; struct in_addr dummyaddr; int detect_real_interfaces = 0; /* Mark all UP interfaces as DETECTING, so we can tell which interfaces are new, and which are dead */ for (i = 0; i < overlay_interface_count; i++) if (overlay_interfaces[i].state==INTERFACE_STATE_UP) overlay_interfaces[i].state=INTERFACE_STATE_DETECTING; /* Check through for any virtual dummy interfaces */ for (r = interface_filter; r != NULL; r = r->next) { if (r->namespec[0] != '>'){ detect_real_interfaces = 1; continue; } for (i = 0; i < overlay_interface_count; i++) if (!strcasecmp(overlay_interfaces[i].name,r->namespec)){ if (overlay_interfaces[i].state==INTERFACE_STATE_DETECTING) overlay_interfaces[i].state=INTERFACE_STATE_UP; break; } if (i >= overlay_interface_count){ /* New interface, so register it */ overlay_interface_init(r->namespec,dummyaddr,dummyaddr,dummyaddr,1000000,PORT_DNA,OVERLAY_INTERFACE_WIFI); } } /* Look for real interfaces */ if (detect_real_interfaces){ int 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"); } } // detect if any interfaces have gone away and need to be closed for(i = 0; i < overlay_interface_count; i++) if (overlay_interfaces[i].state==INTERFACE_STATE_DETECTING) overlay_interface_close(&overlay_interfaces[i]); alarm->alarm = gettime_ms()+5000; alarm->deadline = alarm->alarm + 10000; schedule(alarm); return; } /* remove and free a payload from the queue */ static struct overlay_frame * overlay_queue_remove(overlay_txqueue *queue, struct overlay_frame *frame){ struct overlay_frame *prev = frame->prev; struct overlay_frame *next = frame->next; if (prev) prev->next = next; else if(frame == queue->first) queue->first = next; if (next) next->prev = prev; else if(frame == queue->last) queue->last = prev; queue->length--; op_free(frame); return next; } /* XXX: unused */ static 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\n", f,f->next,f->prev); 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; } static void overlay_init_packet(struct outgoing_packet *packet, overlay_interface *interface, struct sockaddr_in addr){ packet->interface = interface; packet->i = (interface - overlay_interfaces); packet->dest=addr; packet->buffer=ob_new(); ob_limitsize(packet->buffer, packet->interface->mtu); ob_append_bytes(packet->buffer,magic_header,4); overlay_address_clear(); } // update the alarm time and return 1 if changed static int overlay_calc_queue_time(overlay_txqueue *queue, struct overlay_frame *frame){ int ret=0; time_ms_t send_time; // ignore packet if the destination is currently unreachable if (frame->destination && frame->destination->reachable==REACHABLE_NONE) return 0; // when is the next packet from this queue due? send_time=queue->first->enqueued_at + queue->transmit_delay; if (next_packet.alarm==0 || send_time < next_packet.alarm){ next_packet.alarm=send_time; ret = 1; } // how long can we wait if the server is busy? send_time += queue->grace_period; if (next_packet.deadline==0 || send_time < next_packet.deadline){ next_packet.deadline=send_time; ret = 1; } if (!next_packet.function){ next_packet.function=overlay_send_packet; send_packet.name="overlay_send_packet"; next_packet.stats=&send_packet; } return ret; } static void overlay_stuff_packet(struct outgoing_packet *packet, overlay_txqueue *queue, time_ms_t now){ struct overlay_frame *frame = queue->first; // TODO stop when the packet is nearly full? while(frame){ if (frame->enqueued_at + queue->latencyTarget < now){ DEBUGF("Dropping frame type %x for %s due to expiry timeout", frame->type, frame->destination?alloca_tohex_sid(frame->destination->sid):"All"); frame = overlay_queue_remove(queue, frame); continue; } /* Note, once we queue a broadcast packet we are committed to sending it out every interface, even if we hear it from somewhere else in the mean time */ if (frame->destination && frame->destination->reachable==REACHABLE_NONE) goto skip; struct subscriber *next_hop = frame->destination; if (next_hop){ switch(next_hop->reachable){ case REACHABLE_INDIRECT: next_hop=next_hop->next_hop; // make sure the routing table is consistent if (next_hop->reachable!=REACHABLE_DIRECT) goto skip; // fall through case REACHABLE_DIRECT: frame->sendBroadcast=0; break; case REACHABLE_BROADCAST: if (!frame->sendBroadcast){ frame->sendBroadcast=1; overlay_broadcast_generate_address(&frame->broadcast_id); int i; for(i=0;ibroadcast_sent_via[i]=0; } break; } } if (!packet->buffer){ // use the interface of the first payload we find if (frame->sendBroadcast){ // find an interface that we haven't broadcast on yet int i; for(i=0;ibroadcast_sent_via[i]){ overlay_init_packet(packet, &overlay_interfaces[i], overlay_interfaces[i].broadcast_address); break; } } if (!packet->buffer){ // oh dear, why is this broadcast still in the queue? frame = overlay_queue_remove(queue, frame); continue; } }else{ overlay_init_packet(packet, next_hop->interface, next_hop->address); } }else{ // make sure this payload can be sent via this interface if (frame->sendBroadcast){ if (frame->broadcast_sent_via[packet->i]){ goto skip; } }else if(packet->interface != next_hop->interface || packet->dest.sin_addr.s_addr != next_hop->address.sin_addr.s_addr){ goto skip; } } if (debug&DEBUG_OVERLAYFRAMES){ DEBUGF("Sending payload type %x len %d for %s via %s", frame->type, frame->payload->position, frame->destination?alloca_tohex_sid(frame->destination->sid):"All", frame->sendBroadcast?alloca_tohex(frame->broadcast_id.id, BROADCAST_LEN):alloca_tohex_sid(next_hop->sid)); } if (overlay_frame_append_payload(frame, next_hop, packet->buffer)) // payload was not queued goto skip; // mark the payload as sent int keep_payload = 0; if (frame->sendBroadcast){ int i; frame->broadcast_sent_via[packet->i]=1; // check if there is still a broadcast to be sent for(i=0;ibroadcast_sent_via[i]){ keep_payload=1; break; } } } if (!keep_payload){ frame = overlay_queue_remove(queue, frame); continue; } skip: // if we can't send the payload now, check when we should try overlay_calc_queue_time(queue, frame); frame = frame->next; } } // fill a packet from our outgoing queues and send it static int overlay_fill_send_packet(struct outgoing_packet *packet, time_ms_t now) { int i; IN(); // while we're looking at queues, work out when to schedule another packet unschedule(&next_packet); next_packet.alarm=0; next_packet.deadline=0; for (i=0;ibuffer){ // send the packet if (packet->buffer->position>=HEADERFIELDS_LEN){ // stuff rhizome announcements at the last moment if (rhizome_enabled() && rhizome_http_server_running()){ overlay_rhizome_add_advertisements(packet->i,packet->buffer); } if (debug&DEBUG_PACKETCONSTRUCTION) dump("assembled packet",&packet->buffer->bytes[0],packet->buffer->position); if (debug&DEBUG_OVERLAYINTERFACES) DEBUGF("Sending %d byte packet",packet->buffer->position); overlay_broadcast_ensemble(packet->i, &packet->dest, packet->buffer->bytes, packet->buffer->position); } ob_free(packet->buffer); overlay_address_clear(); RETURN(1); } RETURN(0); } // when the queue timer elapses, send a packet void overlay_send_packet(struct sched_ent *alarm){ struct outgoing_packet packet; bzero(&packet, sizeof(struct outgoing_packet)); overlay_fill_send_packet(&packet, gettime_ms()); } // update time for next alarm and reschedule void overlay_update_queue_schedule(overlay_txqueue *queue, struct overlay_frame *frame){ if (overlay_calc_queue_time(queue, frame)){ unschedule(&next_packet); schedule(&next_packet); } } static int overlay_tick_interface(int i, time_ms_t now) { struct outgoing_packet packet; IN(); /* An interface with no speed budget is for listening only, so doesn't get ticked */ if (overlay_interfaces[i].bits_per_second<1 || overlay_interfaces[i].state!=INTERFACE_STATE_UP) { RETURN(0); } // initialise the packet buffer bzero(&packet, sizeof(struct outgoing_packet)); overlay_init_packet(&packet, &overlay_interfaces[i], overlay_interfaces[i].broadcast_address); if (debug&DEBUG_OVERLAYINTERFACES) DEBUGF("Ticking interface #%d",i); /* 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). */ if (overlay_add_selfannouncement(i,packet.buffer) == -1) return WHY("tick failed"); /* Add advertisements for ROUTES */ overlay_route_add_advertisements(packet.buffer); /* Stuff more payloads from queues and send it */ overlay_fill_send_packet(&packet, now); RETURN(0); } static 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"); } } static void logServalPacket(int level, struct __sourceloc where, const char *message, const unsigned char *packet, size_t len) { struct mallocbuf mb = STRUCT_MALLOCBUF_NULL; if (serval_packetvisualise(XPRINTF_MALLOCBUF(&mb), message, packet, len) == -1) WHY("serval_packetvisualise() failed"); else if (mb.buffer == NULL) WHYF("serval_packetvisualise() output buffer missing, message=%s packet=%p len=%lu", alloca_toprint(-1, message, strlen(message)), packet, len); else logString(level, where, mb.buffer); if (mb.buffer) free(mb.buffer); }