/*---------------------------------------------------------------------------*/
PROCESS_THREAD(udp_server_process, ev, data)
{
uip_ipaddr_t ipaddr;
struct uip_ds6_addr *root_if;
PROCESS_BEGIN();
PROCESS_PAUSE();
SENSORS_ACTIVATE(button_sensor);
PRINTF("UDP server started\n");
#if UIP_CONF_ROUTER
uip_ip6addr(&ipaddr, 0xaaaa, 0, 0, 0, 0, 0, 0, 1);
/* uip_ds6_set_addr_iid(&ipaddr, &uip_lladdr); */
uip_ds6_addr_add(&ipaddr, 0, ADDR_MANUAL);
root_if = uip_ds6_addr_lookup(&ipaddr);
if(root_if != NULL) {
rpl_dag_t *dag;
rpl_set_root((uip_ip6addr_t *)&ipaddr);
dag = rpl_get_dag(RPL_ANY_INSTANCE);
uip_ip6addr(&ipaddr, 0xaaaa, 0, 0, 0, 0, 0, 0, 0);
rpl_set_prefix(dag, &ipaddr, 64);
PRINTF("created a new RPL dag\n");
} else {
PRINTF("failed to create a new RPL DAG\n");
}
#endif /* UIP_CONF_ROUTER */
print_local_addresses();
/* The data sink runs with a 100% duty cycle in order to ensure high
packet reception rates. */
NETSTACK_RDC.off(1);
server_conn = udp_new(NULL, UIP_HTONS(UDP_CLIENT_PORT), NULL);
udp_bind(server_conn, UIP_HTONS(UDP_SERVER_PORT));
PRINTF("Created a server connection with remote address ");
PRINT6ADDR(&server_conn->ripaddr);
PRINTF(" local/remote port %u/%u\n", UIP_HTONS(server_conn->lport),
UIP_HTONS(server_conn->rport));
while(1) {
PROCESS_YIELD();
if(ev == tcpip_event) {
tcpip_handler();
} else if (ev == sensors_event && data == &button_sensor) {
PRINTF("Initiaing global repair\n");
rpl_repair_dag(rpl_get_dag(RPL_ANY_INSTANCE));
}
}
PROCESS_END();
}
void
rpl_ipv6_neighbor_callback(uip_ds6_nbr_t *nbr)
{
rpl_dag_t *dag;
rpl_parent_t *p;
/* This only handles one DODAG - if multiple we need to check all */
dag = rpl_get_dag(RPL_ANY_INSTANCE);
if(dag == NULL) {
return;
}
/* if this is our default route then clean the dag->def_route state */
if(dag->def_route != NULL &&
uip_ipaddr_cmp(&dag->def_route->ipaddr, &nbr->ipaddr)) {
dag->def_route = NULL;
}
if(!nbr->isused) {
PRINTF("RPL: Removing neighbor ");
PRINT6ADDR(&nbr->ipaddr);
PRINTF("\n");
p = rpl_find_parent(dag, &nbr->ipaddr);
if(p != NULL) {
p->rank = INFINITE_RANK;
/* Trigger DAG rank recalculation. */
p->updated = 1;
}
}
}
void
rpl_recalculate_ranks(void)
{
rpl_dag_t *dag;
rpl_parent_t *p;
/*
* We recalculate ranks when we receive feedback from the system rather
* than RPL protocol messages. This periodical recalculation is called
* from a timer in order to keep the stack depth reasonably low.
*/
dag = rpl_get_dag(RPL_ANY_INSTANCE);
if(dag != NULL) {
for(p = list_head(dag->parents); p != NULL; p = p->next) {
if(p->updated) {
p->updated = 0;
rpl_process_parent_event(dag, p);
/*
* Stop calculating here because the parent list may have changed.
* If more ranks need to be recalculated, it will be taken care of
* in subsequent calls to this functions.
*/
break;
}
}
}
}
rpl_dag_t *
rpl_set_root(uip_ipaddr_t *dag_id)
{
rpl_dag_t *dag;
int version;
version = -1;
dag = rpl_get_dag(RPL_DEFAULT_INSTANCE);
if(dag != NULL) {
PRINTF("RPL: Dropping a joined DAG when setting this node as root");
version = dag->version;
rpl_free_dag(dag);
}
dag = rpl_alloc_dag(RPL_DEFAULT_INSTANCE);
if(dag == NULL) {
PRINTF("RPL: Failed to allocate a DAG\n");
return NULL;
}
dag->joined = 1;
dag->version = version + 1;
dag->grounded = RPL_GROUNDED;
dag->mop = RPL_MOP_DEFAULT;
dag->of = &RPL_OF;
dag->preferred_parent = NULL;
dag->dtsn_out = 1; /* Trigger DAOs from the beginning. */
memcpy(&dag->dag_id, dag_id, sizeof(dag->dag_id));
dag->dio_intdoubl = DEFAULT_DIO_INTERVAL_DOUBLINGS;
dag->dio_intmin = DEFAULT_DIO_INTERVAL_MIN;
dag->dio_redundancy = DEFAULT_DIO_REDUNDANCY;
dag->max_rankinc = DEFAULT_MAX_RANKINC;
dag->min_hoprankinc = DEFAULT_MIN_HOPRANKINC;
dag->default_lifetime = RPL_DEFAULT_LIFETIME;
dag->lifetime_unit = RPL_DEFAULT_LIFETIME_UNIT;
dag->rank = ROOT_RANK(dag);
dag->of->update_metric_container(dag);
PRINTF("RPL: Node set to be a DAG root with DAG ID ");
PRINT6ADDR(&dag->dag_id);
PRINTF("\n");
ANNOTATE("#A root=%u\n",dag->dag_id.u8[sizeof(dag->dag_id) - 1]);
rpl_reset_dio_timer(dag, 1);
return dag;
}
/*---------------------------------------------------------------------------*/
PROCESS_THREAD(border_router_process, ev, data)
{
static struct etimer et;
rpl_dag_t *dag;
PROCESS_BEGIN();
prefix_set = 0;
PROCESS_PAUSE();
#if WEBSERVER
process_start(&webserver_nogui_process, NULL);
#endif
//SENSORS_ACTIVATE(button_sensor);
PRINTF("RPL-Border router started\n");
/* Request prefix until it has been received */
while(!prefix_set) {
etimer_set(&et, CLOCK_SECOND);
request_prefix();
PROCESS_WAIT_EVENT_UNTIL(etimer_expired(&et));
}
dag = rpl_set_root((uip_ip6addr_t *)dag_id);
if(dag != NULL) {
rpl_set_prefix(dag, &prefix, 64);
PRINTF("created a new RPL dag\n");
}
#if DEBUG || 1
print_local_addresses();
#endif
/* The border router runs with a 100% duty cycle in order to ensure high
packet reception rates. */
NETSTACK_MAC.off(1);
static struct etimer t;
etimer_set(&t, 10*CLOCK_SECOND);
while(1) {
PROCESS_YIELD();
//if (ev == sensors_event && data == &button_sensor) {
if (etimer_expired(&t)) {
PRINTF("Initiating global repair\n");
rpl_repair_dag(rpl_get_dag(RPL_ANY_INSTANCE));
etimer_reset(&t);
}
}
PROCESS_END();
}
static void
handle_periodic_timer(void *ptr)
{
rpl_purge_routes();
rpl_recalculate_ranks();
/* handle DIS */
#ifdef RPL_DIS_SEND
next_dis++;
if(rpl_get_dag(RPL_ANY_INSTANCE) == NULL && next_dis >= RPL_DIS_INTERVAL) {
next_dis = 0;
dis_output(NULL);
}
#endif
ctimer_reset(&periodic_timer);
}
static void
rpl_link_neighbor_callback(const rimeaddr_t *addr, int known, int etx)
{
uip_ipaddr_t ipaddr;
rpl_dag_t *dag;
rpl_parent_t *parent;
uip_ip6addr(&ipaddr, 0xfe80, 0, 0, 0, 0, 0, 0, 0);
uip_ds6_set_addr_iid(&ipaddr, (uip_lladdr_t *)addr);
PRINTF("RPL: Neighbor ");
PRINT6ADDR(&ipaddr);
PRINTF(" is %sknown. ETX = %u\n", known ? "" : "no longer ", NEIGHBOR_INFO_FIX2ETX(etx));
dag = rpl_get_dag(RPL_DEFAULT_INSTANCE);
if(dag == NULL) {
return;
}
parent = rpl_find_parent(dag, &ipaddr);
if(parent == NULL) {
if(!known) {
PRINTF("RPL: Deleting routes installed by DAOs received from ");
PRINT6ADDR(&ipaddr);
PRINTF("\n");
uip_ds6_route_rm_by_nexthop(&ipaddr);
}
return;
}
/* Trigger DAG rank recalculation. */
parent->updated = 1;
parent->link_metric = etx;
if(dag->of->parent_state_callback != NULL) {
dag->of->parent_state_callback(parent, known, etx);
}
if(!known) {
PRINTF("RPL: Removing parent ");
PRINT6ADDR(&parent->addr);
PRINTF(" because of bad connectivity (ETX %d)\n", etx);
parent->rank = INFINITE_RANK;
}
}
/*---------------------------------------------------------------------------*/
static void
create_rpl_dag(uip_ipaddr_t *ipaddr)
{
struct uip_ds6_addr *root_if;
root_if = uip_ds6_addr_lookup(ipaddr);
if(root_if != NULL) {
rpl_dag_t *dag;
uip_ipaddr_t prefix;
rpl_set_root(ipaddr);
dag = rpl_get_dag(RPL_ANY_INSTANCE);
uip_ip6addr(&prefix, 0xaaaa, 0, 0, 0, 0, 0, 0, 0);
rpl_set_prefix(dag, &prefix, 64);
PRINTF("created a new RPL dag\n");
} else {
PRINTF("failed to create a new RPL DAG\n");
}
}
void
collect_common_net_print(void)
{
rpl_dag_t *dag;
int i;
dag = rpl_get_dag(RPL_ANY_INSTANCE);
if(dag->preferred_parent != NULL) {
PRINTF("Preferred parent: ");
PRINT6ADDR(&dag->preferred_parent->addr);
PRINTF("\n");
}
PRINTF("Route entries:\n");
for(i = 0; i < UIP_DS6_ROUTE_NB; i++) {
if(uip_ds6_routing_table[i].isused) {
PRINT6ADDR(&uip_ds6_routing_table[i].ipaddr);
PRINTF("\n");
}
}
PRINTF("---\n");
}
void
rpl_process_dio(uip_ipaddr_t *from, rpl_dio_t *dio)
{
rpl_dag_t *dag;
rpl_parent_t *p;
if(dio->mop != RPL_MOP_DEFAULT) {
PRINTF("RPL: Ignoring a DIO with an unsupported MOP: %d\n", dio->mop);
return;
}
// LVD 24/03/2011
instanceID = dio->instance_id;
dag = rpl_get_dag(dio->instance_id);
if(dag == NULL) {
/* Join the first possible DAG of this RPL instance. */
if(dio->rank != INFINITE_RANK) {
join_dag(from, dio);
} else {
PRINTF("RPL: Ignoring DIO from node with infinite rank: ");
PRINT6ADDR(from);
PRINTF("\n");
}
return;
}
if(memcmp(&dag->dag_id, &dio->dag_id, sizeof(dag->dag_id))) {
PRINTF("RPL: Ignoring DIO for another DAG within our instance\n");
return;
}
if(dio->version > dag->version) {
if(dag->rank == ROOT_RANK(dag)) {
PRINTF("RPL: Root received inconsistent DIO version number\n");
dag->version = dio->version + 1;
rpl_reset_dio_timer(dag, 1);
} else {
global_repair(from, dag, dio);
}
return;
} else if(dio->version < dag->version) {
/* Inconsistency detected - someone is still on old version */
PRINTF("RPL: old version received => inconsistency detected\n");
rpl_reset_dio_timer(dag, 1);
return;
}
if(dio->rank == INFINITE_RANK) {
rpl_reset_dio_timer(dag, 1);
} else if(dio->rank < ROOT_RANK(dag)) {
PRINTF("RPL: Ignoring DIO with too low rank: %u\n",
(unsigned)dio->rank);
return;
}
if(dag->rank == ROOT_RANK(dag)) {
if(dio->rank != INFINITE_RANK) {
dag->dio_counter++;
}
return;
}
/*
* At this point, we know that this DIO pertains to a DAG that
* we are already part of. We consider the sender of the DIO to be
* a candidate parent, and let rpl_process_parent_event decide
* whether to keep it in the set.
*/
p = rpl_find_parent(dag, from);
if(p == NULL) {
if(RPL_PARENT_COUNT(dag) == RPL_MAX_PARENTS) {
/* Make room for a new parent. */
remove_worst_parent(dag, dio->rank);
}
/* Add the DIO sender as a candidate parent. */
p = rpl_add_parent(dag, dio, from);
if(p == NULL) {
PRINTF("RPL: Failed to add a new parent (");
PRINT6ADDR(from);
PRINTF(")\n");
return;
}
PRINTF("RPL: New candidate parent with rank %u: ", (unsigned)p->rank);
PRINT6ADDR(from);
PRINTF("\n");
} else if(DAG_RANK(p->rank, dag) == DAG_RANK(dio->rank, dag)) {
PRINTF("RPL: Received consistent DIO\n");
dag->dio_counter++;
}
/* We have allocated a candidate parent; process the DIO further. */
memcpy(&p->mc, &dio->mc, sizeof(p->mc));
p->rank = dio->rank;
if(rpl_process_parent_event(dag, p) == 0) {
/* The candidate parent no longer exists. */
return;
}
if(should_send_dao(dag, dio, p)) {
rpl_schedule_dao(dag);
}
p->dtsn = dio->dtsn;
}
/*---------------------------------------------------------------------------*/
void
collect_common_send(void)
{
static uint8_t seqno;
struct {
uint8_t seqno;
uint8_t for_alignment;
struct collect_view_data_msg msg;
} msg;
/* struct collect_neighbor *n; */
uint16_t parent_etx;
uint16_t rtmetric;
uint16_t num_neighbors;
uint16_t beacon_interval;
rpl_parent_t *preferred_parent;
rimeaddr_t parent;
rpl_dag_t *dag;
if(client_conn == NULL) {
/* Not setup yet */
return;
}
memset(&msg, 0, sizeof(msg));
seqno++;
if(seqno == 0) {
/* Wrap to 128 to identify restarts */
seqno = 128;
}
msg.seqno = seqno;
rimeaddr_copy(&parent, &rimeaddr_null);
parent_etx = 0;
dag = rpl_get_dag(RPL_DEFAULT_INSTANCE);
if(dag != NULL) {
preferred_parent = dag->preferred_parent;
if(preferred_parent != NULL) {
uip_ds6_nbr_t *nbr;
nbr = uip_ds6_nbr_lookup(&preferred_parent->addr);
if(nbr != NULL) {
/* Use parts of the IPv6 address as the parent address, in reversed byte order. */
parent.u8[RIMEADDR_SIZE - 1] = nbr->ipaddr.u8[sizeof(uip_ipaddr_t) - 2];
parent.u8[RIMEADDR_SIZE - 2] = nbr->ipaddr.u8[sizeof(uip_ipaddr_t) - 1];
parent_etx = neighbor_info_get_metric((rimeaddr_t *) &nbr->lladdr) / 2;
}
}
rtmetric = dag->rank;
beacon_interval = (uint16_t) ((2L << dag->dio_intcurrent) / 1000);
num_neighbors = RPL_PARENT_COUNT(dag);
} else {
rtmetric = 0;
beacon_interval = 0;
num_neighbors = 0;
}
/* num_neighbors = collect_neighbor_list_num(&tc.neighbor_list); */
collect_view_construct_message(&msg.msg, &parent,
parent_etx, rtmetric,
num_neighbors, beacon_interval);
uip_udp_packet_sendto(client_conn, &msg, sizeof(msg),
&server_ipaddr, UIP_HTONS(UDP_SERVER_PORT));
}
