/* 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. */ /* Smart-flooding of broadcast information is also a requirement. The long addresses help here, as we can make any address that begins with the first 192 bits all ones be broadcast, and use the remaining 64 bits as a "broadcast packet identifier" (BPI). Nodes can remember recently seen BPIs and not forward broadcast frames that have been seen recently. This should get us smart flooding of the majority of a mesh (with some node mobility issues being a factor). We could refine this later, but it will do for now, especially since for things like number resolution we are happy to send repeat requests. */ #include "serval.h" #include "str.h" #include "overlay_address.h" #include "overlay_buffer.h" #include "overlay_packet.h" #include #define MAX_BPIS 1024 #define BPI_MASK 0x3ff static struct broadcast bpilist[MAX_BPIS]; // each node has 16 slots based on the next 4 bits of a subscriber id // each slot either points to another tree node or a struct subscriber. struct tree_node{ // bit flags for the type of object each element points to int is_tree; union{ struct tree_node *tree_nodes[16]; struct subscriber *subscribers[16]; }; }; static struct tree_node root; static struct subscriber *previous=NULL; static struct subscriber *sender=NULL; static struct broadcast *previous_broadcast=NULL; struct subscriber *my_subscriber=NULL; static unsigned char get_nibble(const unsigned char *sid, int pos){ unsigned char byte = sid[pos>>1]; if (!(pos&1)) byte=byte>>4; return byte&0xF; } // find a subscriber struct from a whole or abbreviated subscriber id // TODO find abreviated sid's struct subscriber *find_subscriber(const unsigned char *sid, int len, int create){ struct tree_node *ptr = &root; int pos=0; if (len!=SID_SIZE) create =0; do{ unsigned char nibble = get_nibble(sid, pos++); if (ptr->is_tree & (1<tree_nodes[nibble]; }else if(!ptr->subscribers[nibble]){ // subscriber is not yet known if (create){ struct subscriber *ret=(struct subscriber *)malloc(sizeof(struct subscriber)); memset(ret,0,sizeof(struct subscriber)); ptr->subscribers[nibble]=ret; bcopy(sid, ret->sid, SID_SIZE); ret->abbreviate_len=pos; // always send the full sid on first use ret->send_full=1; // always send my full sid when we hear about someone new if (my_subscriber) my_subscriber->send_full = 1; } return ptr->subscribers[nibble]; }else{ // there's a subscriber in this slot, does it match the rest of the sid we've been given? struct subscriber *ret = ptr->subscribers[nibble]; if (memcmp(ret->sid,sid,len)==0){ return ret; } // if we need to insert this subscriber, we have to make a new tree node first if (!create) return NULL; // create a new tree node and move the existing subscriber into it struct tree_node *new=(struct tree_node *)malloc(sizeof(struct tree_node)); memset(new,0,sizeof(struct tree_node)); ptr->tree_nodes[nibble]=new; ptr->is_tree |= (1<sid,pos); ptr->subscribers[nibble]=ret; ret->abbreviate_len=pos+1; // then go around the loop again to compare the next nibble against the sid until we find an empty slot. } }while(pos < len*2); // abbreviation is not unique return NULL; } /* Walk the subscriber tree, calling the callback function for each subscriber. if start is a valid pointer, the first entry returned will be after this subscriber if the callback returns non-zero, the process will stop. */ static int walk_tree(struct tree_node *node, int pos, unsigned char *start, int start_len, unsigned char *end, int end_len, int(*callback)(struct subscriber *, void *), void *context){ int i=0, e=16; if (start && pos < start_len*2){ i=get_nibble(start,pos); } if (end && pos < end_len*2){ e=get_nibble(end,pos) +1; } for (;iis_tree & (1<tree_nodes[i], pos+1, start, start_len, end, end_len, callback, context)) return 1; }else if(node->subscribers[i]){ if (callback(node->subscribers[i], context)) return 1; } // stop comparing the start sid after looking at the first branch of the tree start=NULL; } return 0; } /* walk the tree, starting at start inclusive, calling the supplied callback function */ void enum_subscribers(struct subscriber *start, int(*callback)(struct subscriber *, void *), void *context){ walk_tree(&root, 0, start->sid, SID_SIZE, NULL, 0, callback, context); } // quick test to make sure the specified route is valid. int subscriber_is_reachable(struct subscriber *subscriber){ if (!subscriber) return REACHABLE_NONE; int ret = subscriber->reachable; if (ret==REACHABLE_INDIRECT){ if (!subscriber->next_hop) ret = REACHABLE_NONE; // avoid infinite recursion... else if (subscriber->next_hop->reachable!=REACHABLE_DIRECT && subscriber->next_hop->reachable!=REACHABLE_UNICAST) ret = REACHABLE_NONE; else{ int r = subscriber_is_reachable(subscriber->next_hop); if (r!=REACHABLE_DIRECT && r!= REACHABLE_UNICAST) ret = REACHABLE_NONE; } } if (ret==REACHABLE_DIRECT || ret==REACHABLE_UNICAST){ // make sure the interface is still up if (!subscriber->interface) ret=REACHABLE_NONE; else if (subscriber->interface->state!=INTERFACE_STATE_UP) ret=REACHABLE_NONE; } // after all of that, should we use a default route? if (ret==REACHABLE_NONE && directory_service && subscriber!=directory_service && subscriber_is_reachable(directory_service)!=REACHABLE_NONE){ ret = REACHABLE_DEFAULT_ROUTE; } return ret; } int set_reachable(struct subscriber *subscriber, int reachable){ if (subscriber->reachable==reachable) return 0; int old_value=subscriber->reachable; subscriber->reachable=reachable; // These log messages are for use in tests. Changing them may break test scripts. if (debug&DEBUG_OVERLAYROUTING) { switch (reachable) { case REACHABLE_NONE: DEBUGF("NOT REACHABLE sid=%s", alloca_tohex_sid(subscriber->sid)); break; case REACHABLE_SELF: break; case REACHABLE_DIRECT: DEBUGF("REACHABLE DIRECTLY sid=%s", alloca_tohex_sid(subscriber->sid)); break; case REACHABLE_INDIRECT: DEBUGF("REACHABLE INDIRECTLY sid=%s", alloca_tohex_sid(subscriber->sid)); break; case REACHABLE_UNICAST: DEBUGF("REACHABLE VIA UNICAST sid=%s", alloca_tohex_sid(subscriber->sid)); break; case REACHABLE_BROADCAST: DEBUGF("REACHABLE VIA BROADCAST sid=%s", alloca_tohex_sid(subscriber->sid)); break; } } /* Pre-emptively send a sas request */ if (!subscriber->sas_valid && reachable!=REACHABLE_SELF && reachable!=REACHABLE_NONE && reachable!=REACHABLE_BROADCAST) keyring_send_sas_request(subscriber); // Hacky layering violation... send our identity to a directory service if (subscriber==directory_service && (old_value==REACHABLE_NONE||old_value==REACHABLE_BROADCAST) && (reachable!=REACHABLE_NONE&&reachable!=REACHABLE_BROADCAST) ) directory_registration(); return 0; } // mark the subscriber as reachable via reply unicast packet int reachable_unicast(struct subscriber *subscriber, overlay_interface *interface, struct in_addr addr, int port){ if (subscriber->reachable!=REACHABLE_NONE && subscriber->reachable!=REACHABLE_UNICAST) return WHYF("Subscriber %s is already reachable", alloca_tohex_sid(subscriber->sid)); if (subscriber->node) return WHYF("Subscriber %s is already known for overlay routing", alloca_tohex_sid(subscriber->sid)); subscriber->interface = interface; subscriber->address.sin_family = AF_INET; subscriber->address.sin_addr = addr; subscriber->address.sin_port = htons(port); set_reachable(subscriber, REACHABLE_UNICAST); return 0; } // load a unicast address from configuration, replace with database?? int load_subscriber_address(struct subscriber *subscriber){ char buff[80]; const char *sid_hex = alloca_tohex_sid(subscriber->sid); snprintf(buff, sizeof(buff), "%s.interface", sid_hex); const char *interface_name = confValueGet(buff, NULL); // no unicast configuration? just return. if (!interface_name) return 1; snprintf(buff, sizeof(buff), "%s.address", sid_hex); const char *address = confValueGet(buff, NULL); if (!address) return 1; snprintf(buff, sizeof(buff), "%s.port", sid_hex); int port = confValueGetInt64Range(buff, PORT_DNA, 1, 65535); overlay_interface *interface = overlay_interface_find_name(interface_name); if (!interface){ WARNF("Interface %s is not UP", interface_name); return -1; } struct in_addr addr; if (!inet_aton(address, &addr)){ return WHYF("%s doesn't look like an IP address", address); } return reachable_unicast(subscriber, interface, addr, port); } // generate a new random broadcast address int overlay_broadcast_generate_address(struct broadcast *addr) { int i; for(i=0;iid[i]=random()&0xff; return 0; } // test if the broadcast address has been seen int overlay_broadcast_drop_check(struct broadcast *addr) { /* Hash the BPI and see if we have seen it recently. If so, drop the frame. The occassional failure to supress a broadcast frame is not something we are going to worry about just yet. For byzantine robustness it is however required. */ int bpi_index=0; int i; for(i=0;i>13)&0x7); bpi_index^=addr->id[i]; } bpi_index&=BPI_MASK; if (memcmp(bpilist[bpi_index].id, addr->id, BROADCAST_LEN)){ if (debug&DEBUG_BROADCASTS) DEBUGF("BPI %s is new", alloca_tohex(addr->id, BROADCAST_LEN)); bcopy(addr->id, bpilist[bpi_index].id, BROADCAST_LEN); return 0; /* don't drop */ }else{ if (debug&DEBUG_BROADCASTS) DEBUGF("BPI %s is a duplicate", alloca_tohex(addr->id, BROADCAST_LEN)); return 1; /* drop frame because we have seen this BPI recently */ } } int overlay_broadcast_append(struct overlay_buffer *b, struct broadcast *broadcast) { if (ob_append_byte(b, OA_CODE_BROADCAST)) return -1; if (ob_append_bytes(b, broadcast->id, BROADCAST_LEN)) return -1; previous=NULL; return 0; } // append an appropriate abbreviation into the address int overlay_address_append(struct overlay_buffer *b, struct subscriber *subscriber) { if (subscriber==sender){ ob_append_byte(b, OA_CODE_SELF); }else if(subscriber==previous){ ob_append_byte(b, OA_CODE_PREVIOUS); }else if(subscriber->send_full || subscriber->abbreviate_len >= 20){ subscriber->send_full=0; ob_append_bytes(b, subscriber->sid, SID_SIZE); }else if(subscriber->abbreviate_len <= 4){ ob_append_byte(b, OA_CODE_PREFIX3); ob_append_bytes(b, subscriber->sid, 3); }else if(subscriber->abbreviate_len <= 12){ ob_append_byte(b, OA_CODE_PREFIX7); ob_append_bytes(b, subscriber->sid, 7); }else{ ob_append_byte(b, OA_CODE_PREFIX11); ob_append_bytes(b, subscriber->sid, 11); } previous = subscriber; return 0; } int overlay_address_append_self(overlay_interface *interface, struct overlay_buffer *b){ static int ticks_per_full_address = -1; if (ticks_per_full_address == -1) { ticks_per_full_address = confValueGetInt64Range("mdp.selfannounce.ticks_per_full_address", 4LL, 1LL, 1000000LL); INFOF("ticks_per_full_address = %d", ticks_per_full_address); } if (!my_subscriber) return WHY("I don't know who I am yet"); if (++interface->ticks_since_sent_full_address > ticks_per_full_address){ interface->ticks_since_sent_full_address = 0; my_subscriber->send_full=1; } if (overlay_address_append(b, my_subscriber)) return WHY("Could not append my sid"); return 0; } static int add_explain_response(struct subscriber *subscriber, void *context){ struct decode_context *response = context; if (!response->please_explain){ response->please_explain = calloc(sizeof(struct overlay_frame),1); response->please_explain->payload=ob_new(); ob_limitsize(response->please_explain->payload, 1024); } // if one of our identities is unknown, // the header of our next payload must include our full sid. if (subscriber->reachable==REACHABLE_SELF) subscriber->send_full = 1; // add the whole subscriber id to the payload, stop if we run out of space DEBUGF("Adding full sid by way of explanation %s", alloca_tohex_sid(subscriber->sid)); if (ob_append_bytes(response->please_explain->payload, subscriber->sid, SID_SIZE)) return 1; return 0; } int find_subscr_buffer(struct decode_context *context, struct overlay_buffer *b, int code, int len, int create, struct subscriber **subscriber){ unsigned char *id = ob_get_bytes_ptr(b, len); if (!id) return WHY("Not enough space in buffer to parse address"); if (!subscriber){ WARN("Could not resolve address, no buffer supplied"); context->invalid_addresses=1; return 0; } *subscriber=find_subscriber(id, len, create); if (!*subscriber){ context->invalid_addresses=1; // generate a please explain in the passed in context // add the abbreviation you told me about if (!context->please_explain){ context->please_explain = calloc(sizeof(struct overlay_frame),1); context->please_explain->payload=ob_new(); ob_limitsize(context->please_explain->payload, MDP_MTU); } // And I'll tell you about any subscribers I know that match this abbreviation, // so you don't try to use an abbreviation that's too short in future. walk_tree(&root, 0, id, len, id, len, add_explain_response, context); INFOF("Asking for explanation of %s", alloca_tohex(id, len)); if (code>=0) ob_append_byte(context->please_explain->payload, code); ob_append_bytes(context->please_explain->payload, id, len); }else{ previous=*subscriber; previous_broadcast=NULL; } return 0; } // returns 0 = success, -1 = fatal parsing error, 1 = unable to identify address int overlay_address_parse(struct decode_context *context, struct overlay_buffer *b, struct broadcast *broadcast, struct subscriber **subscriber) { int code = ob_getbyte(b,b->position); if (code<0) return -1; switch(code){ case OA_CODE_BROADCAST: b->position++; if (subscriber) *subscriber=NULL; if (!broadcast){ context->invalid_addresses=1; }else{ ob_get_bytes(b, broadcast->id, BROADCAST_LEN); } previous_broadcast=broadcast; previous=NULL; return 0; case OA_CODE_SELF: b->position++; if (!subscriber){ WARN("Could not resolve address, no buffer supplied"); context->invalid_addresses=1; }else if (!sender){ INFO("Could not resolve address, sender has not been set"); context->invalid_addresses=1; }else{ *subscriber=sender; previous=sender; } return 0; case OA_CODE_PREVIOUS: b->position++; // previous may be null, if the previous address was a broadcast. // In this case we want the subscriber to be null as well and not report an error, if (!subscriber){ WARN("Could not resolve address, no buffer supplied"); context->invalid_addresses=1; }else if (previous){ *subscriber=previous; }else if (previous_broadcast){ *subscriber=NULL; // not an error if broadcast is NULL, as the previous OA_CODE_BROADCAST address must have been valid. if (broadcast) bcopy(previous_broadcast->id, broadcast->id, BROADCAST_LEN); }else{ INFO("Unable to decode previous address"); context->invalid_addresses=1; } return 0; case OA_CODE_PREFIX3: b->position++; return find_subscr_buffer(context, b, code, 3,0,subscriber); case OA_CODE_PREFIX7: b->position++; return find_subscr_buffer(context, b, code, 7,0,subscriber); case OA_CODE_PREFIX11: b->position++; return find_subscr_buffer(context, b, code, 11,0,subscriber); } // we must assume that we wont be able to understand the rest of the packet if (code<=0x0f || context->abbreviations_only) return WHYF("Unsupported abbreviation code %d", code); return find_subscr_buffer(context, b, -1, SID_SIZE,1,subscriber); } // once we've finished parsing a packet, complete and send a please explain if required. int send_please_explain(struct decode_context *context, struct subscriber *source, struct subscriber *destination){ if (!context->please_explain) return 0; context->please_explain->type = OF_TYPE_PLEASEEXPLAIN; if (source) context->please_explain->source = source; else context->please_explain->source = my_subscriber; if (destination){ context->please_explain->destination = destination; context->please_explain->ttl=64; }else{ context->please_explain->ttl=2;// how will this work with olsr?? overlay_broadcast_generate_address(&context->please_explain->broadcast_id); } DEBUGF("Queued please explain"); context->please_explain->queue=OQ_MESH_MANAGEMENT; if (!overlay_payload_enqueue(context->please_explain)) return 0; op_free(context->please_explain); return 0; } // process an incoming request for explanation of subscriber abbreviations int process_explain(struct overlay_frame *frame){ struct overlay_buffer *b=frame->payload; struct decode_context context={ .please_explain=NULL, }; while(b->position < b->sizeLimit){ int code = ob_getbyte(b,b->position); int len=SID_SIZE; switch(code){ case OA_CODE_PREFIX3: len=3; b->position++; break; case OA_CODE_PREFIX7: len=7; b->position++; break; case OA_CODE_PREFIX11: len=11; b->position++; break; } if (len==SID_SIZE && code<=0x0f) return WHYF("Unsupported abbreviation code %d", code); unsigned char *sid = ob_get_bytes_ptr(b, len); if (len==SID_SIZE){ // This message is also used to inform people of previously unknown subscribers // make sure we know this one find_subscriber(sid,len,1); INFOF("Now know about %s", alloca_tohex(sid, len)); }else{ // reply to the sender with all subscribers that match this abbreviation INFOF("Sending responses for %s", alloca_tohex(sid, len)); walk_tree(&root, 0, sid, len, sid, len, add_explain_response, &context); } } send_please_explain(&context, frame->destination, frame->source); return 0; } void overlay_address_clear(void){ sender=NULL; previous=NULL; previous_broadcast=NULL; } void overlay_address_set_sender(struct subscriber *subscriber){ sender = subscriber; }