void handle_synchro_timeout(socket_internal_t *current_socket)
{
msg_t send;
if (thread_getstatus(current_socket->recv_pid) == STATUS_RECEIVE_BLOCKED) {
timex_t now;
vtimer_now(&now);
if ((current_socket->socket_values.tcp_control.no_of_retries == 0) &&
(timex_uint64(timex_sub(now, current_socket->socket_values.tcp_control.last_packet_time)) > TCP_SYN_INITIAL_TIMEOUT)) {
current_socket->socket_values.tcp_control.no_of_retries++;
net_msg_send(&send, current_socket->recv_pid, 0, TCP_RETRY);
}
else if ((current_socket->socket_values.tcp_control.no_of_retries > 0) &&
(timex_uint64(timex_sub(now, current_socket->socket_values.tcp_control.last_packet_time)) >
(current_socket->socket_values.tcp_control.no_of_retries *
TCP_SYN_TIMEOUT + TCP_SYN_INITIAL_TIMEOUT))) {
current_socket->socket_values.tcp_control.no_of_retries++;
if (current_socket->socket_values.tcp_control.no_of_retries >
TCP_MAX_SYN_RETRIES) {
net_msg_send(&send, current_socket->recv_pid, 0, TCP_TIMEOUT);
}
else {
net_msg_send(&send, current_socket->recv_pid, 0, TCP_RETRY);
}
}
}
}
/**
* Function executed by NHDP thread receiving messages in an endless loop
*/
static void *_nhdp_runner(void *arg)
{
nhdp_if_entry_t *if_entry;
msg_t msg_rcvd, msg_queue[NHDP_MSG_QUEUE_SIZE];
(void)arg;
msg_init_queue(msg_queue, NHDP_MSG_QUEUE_SIZE);
while (1) {
msg_receive(&msg_rcvd);
switch (msg_rcvd.type) {
case HELLO_TIMER:
mutex_lock(&send_rcv_mutex);
if_entry = msg_rcvd.content.ptr;
nhdp_writer_send_hello(if_entry);
/* TODO: Add jitter */
/* Schedule next sending */
xtimer_set_msg64(&if_entry->if_timer,
timex_uint64(if_entry->hello_interval),
&msg_rcvd, thread_getpid());
mutex_unlock(&send_rcv_mutex);
break;
#if (NHDP_METRIC_NEEDS_TIMER)
case NHDP_METRIC_TIMER:
mutex_lock(&send_rcv_mutex);
/* Process necessary metric computations */
iib_process_metric_refresh();
/* Schedule next sending */
metric_msg.type = NHDP_METRIC_TIMER;
metric_msg.content.ptr = NULL;
xtimer_set_msg64(&metric_timer, timex_uint64(metric_interval),
metric_msg, thread_getpid());
mutex_unlock(&send_rcv_mutex);
break;
#endif
default:
break;
}
}
return 0;
}
void handle_established(socket_internal_t *current_socket)
{
msg_t send;
double current_timeout = current_socket->socket_values.tcp_control.rto;
if (current_timeout < SECOND) {
current_timeout = SECOND;
}
uint8_t i;
if ((current_socket->socket_values.tcp_control.send_nxt >
current_socket->socket_values.tcp_control.send_una) &&
(thread_getstatus(current_socket->send_pid) == STATUS_RECEIVE_BLOCKED)) {
for (i = 0; i < current_socket->socket_values.tcp_control.no_of_retries;
i++) {
current_timeout *= 2;
}
timex_t now;
vtimer_now(&now);
if (current_timeout > TCP_ACK_MAX_TIMEOUT) {
net_msg_send(&send, current_socket->send_pid, 0, TCP_TIMEOUT);
}
else if (timex_uint64(timex_sub(now, current_socket->socket_values.tcp_control.last_packet_time)) >
current_timeout) {
current_socket->socket_values.tcp_control.no_of_retries++;
net_msg_send(&send, current_socket->send_pid, 0, TCP_RETRY);
}
}
}
/* router-only functions from net/gnrc/sixlowpan/nd.h */
void gnrc_sixlowpan_nd_opt_abr_handle(kernel_pid_t iface, ndp_rtr_adv_t *rtr_adv, int sicmpv6_size,
sixlowpan_nd_opt_abr_t *abr_opt)
{
uint16_t opt_offset = 0;
uint8_t *buf = (uint8_t *)(rtr_adv + 1);
gnrc_sixlowpan_nd_router_abr_t *abr;
timex_t t = { 0, 0 };
if (_is_me(&abr_opt->braddr)) {
return;
}
/* validity and version was checked in previously called
* gnrc_sixlowpan_nd_router_abr_older() */
abr = _get_abr(&abr_opt->braddr);
if (abr == NULL) {
return;
}
abr->ltime = byteorder_ntohs(abr_opt->ltime);
if (abr->ltime == 0) {
abr->ltime = GNRC_SIXLOWPAN_ND_BORDER_ROUTER_DEFAULT_LTIME;
return;
}
sicmpv6_size -= sizeof(ndp_rtr_adv_t);
while (sicmpv6_size > 0) {
ndp_opt_t *opt = (ndp_opt_t *)(buf + opt_offset);
switch (opt->type) {
case NDP_OPT_PI:
_add_prefix(iface, abr, (ndp_opt_pi_t *)opt);
case NDP_OPT_6CTX:
_add_ctx(abr, (sixlowpan_nd_opt_6ctx_t *)opt);
default:
break;
}
opt_offset += (opt->len * 8);
sicmpv6_size -= (opt->len * 8);
}
abr->version = (uint32_t)byteorder_ntohs(abr_opt->vlow);
abr->version |= ((uint32_t)byteorder_ntohs(abr_opt->vhigh)) << 16;
abr->addr.u64[0] = abr_opt->braddr.u64[0];
abr->addr.u64[1] = abr_opt->braddr.u64[1];
memset(abr->ctxs, 0, sizeof(abr->ctxs));
abr->prfs = NULL;
t.seconds = abr->ltime * 60;
xtimer_remove(&abr->ltimer);
abr->ltimer_msg.type = GNRC_SIXLOWPAN_ND_MSG_ABR_TIMEOUT;
abr->ltimer_msg.content.ptr = (char *) abr;
xtimer_set_msg(&abr->ltimer, (uint32_t) timex_uint64(t), &abr->ltimer_msg, gnrc_ipv6_pid);
}
static void add_seq_entry(uint8_t src, uint8_t id)
{
/* Remove all entries with given source to avoid short time overflow
* of one bit counter (of the source node). So a valid packet would get
* lost (especially important in constant RX mode). */
int i;
for (i = 0; i < MAX_SEQ_BUFFER_SIZE; i++) {
if (seq_buffer[i].source == src) {
seq_buffer[i].source = 0; /* Reset */
}
}
/* Add new entry */
seq_buffer[seq_buffer_pos].source = src;
seq_buffer[seq_buffer_pos].identification = id;
timex_t now;
vtimer_now(&now);
seq_buffer[seq_buffer_pos].m_ticks = timex_uint64(now);
/* Store 16 bit sequence number of layer 0 for speedup */
last_seq_num = src;
last_seq_num <<= 8;
last_seq_num += id;
seq_buffer_pos++;
if (seq_buffer_pos == MAX_SEQ_BUFFER_SIZE) {
seq_buffer_pos = 0;
}
}
gnrc_ipv6_nc_t *gnrc_ipv6_nc_still_reachable(const ipv6_addr_t *ipv6_addr)
{
gnrc_ipv6_nc_t *entry = gnrc_ipv6_nc_get(KERNEL_PID_UNDEF, ipv6_addr);
if (entry == NULL) {
DEBUG("ipv6_nc: No entry found for %s\n",
ipv6_addr_to_str(addr_str, ipv6_addr, sizeof(addr_str)));
return NULL;
}
if ((gnrc_ipv6_nc_get_state(entry) != GNRC_IPV6_NC_STATE_INCOMPLETE) &&
(gnrc_ipv6_nc_get_state(entry) != GNRC_IPV6_NC_STATE_UNMANAGED)) {
#if defined(MODULE_GNRC_IPV6_NETIF) && defined(MODULE_VTIMER) && defined(MODULE_GNRC_IPV6)
gnrc_ipv6_netif_t *iface = gnrc_ipv6_netif_get(entry->iface);
timex_t t = iface->reach_time;
gnrc_ndp_internal_reset_nbr_sol_timer(entry, (uint32_t) timex_uint64(t),
GNRC_NDP_MSG_NC_STATE_TIMEOUT, gnrc_ipv6_pid);
#endif
DEBUG("ipv6_nc: Marking entry %s as reachable\n",
ipv6_addr_to_str(addr_str, ipv6_addr, sizeof(addr_str)));
entry->flags &= ~(GNRC_IPV6_NC_STATE_MASK >> GNRC_IPV6_NC_STATE_POS);
entry->flags |= (GNRC_IPV6_NC_STATE_REACHABLE >> GNRC_IPV6_NC_STATE_POS);
}
static void calc_rtt(void)
{
timex_t rtt = timex_sub(end, start);
rtt_sum = timex_add(rtt_sum, rtt);
l2_ping_stats.last_rtt = rtt;
l2_ping_stats.avg_rtt = timex_from_uint64(timex_uint64(rtt_sum) / l2_ping_stats.pong_count);
if (timex_cmp(rtt, l2_ping_stats.max_rtt) > 0) {
l2_ping_stats.max_rtt = rtt;
}
if (timex_cmp(rtt, l2_ping_stats.min_rtt) < 0) {
l2_ping_stats.min_rtt = rtt;
}
}
cv_status condition_variable::wait_until(unique_lock<mutex>& lock,
const time_point& timeout_time) {
xtimer_t timer;
// todo: use function to wait for absolute timepoint once available
timex_t before;
xtimer_now_timex(&before);
auto diff = timex_sub(timeout_time.native_handle(), before);
xtimer_set_wakeup(&timer, timex_uint64(diff), sched_active_pid);
wait(lock);
timex_t after;
xtimer_now_timex(&after);
xtimer_remove(&timer);
auto cmp = timex_cmp(after, timeout_time.native_handle());
return cmp < 1 ? cv_status::no_timeout : cv_status::timeout;
}
kernel_pid_t nhdp_start(void)
{
if (nhdp_pid == KERNEL_PID_UNDEF) {
/* Init destination address for NHDP's packets */
/* Start the NHDP thread */
nhdp_pid = thread_create(nhdp_stack, sizeof(nhdp_stack), THREAD_PRIORITY_MAIN - 1,
THREAD_CREATE_STACKTEST, _nhdp_runner, NULL, "NHDP");
#if (NHDP_METRIC_NEEDS_TIMER)
/* Configure periodic timer message to refresh metric values */
if (nhdp_pid != KERNEL_PID_UNDEF) {
metric_interval = timex_from_uint64(DAT_REFRESH_INTERVAL * SEC_IN_USEC);
metric_msg.type = NHDP_METRIC_TIMER;
metric_msg.content.ptr = NULL;
xtimer_set_msg64(&metric_timer, timex_uint64(metric_interval),
metric_msg, nhdp_pid);
}
#endif
}
return nhdp_pid;
}
static bool contains_seq_entry(uint8_t src, uint8_t id)
{
int i;
uint32_t cmp;
timex_t now_timex;
vtimer_now(&now_timex);
for (i = 0; i < MAX_SEQ_BUFFER_SIZE; i++) {
if ((seq_buffer[i].source == src) && (seq_buffer[i].identification == id)) {
/* Check if time stamp is OK */
cmp = (radio_mode == CC1100_MODE_WOR) ? cc1100_wor_config.rx_interval : 16000; /* constant RX ~16ms */
if ((timex_uint64(now_timex) - seq_buffer[i].m_ticks < cmp)) {
return true;
}
else {
seq_buffer[i].source = 0; /* Reset */
}
}
}
return false;
}
/*---------------------------------------------------------------------------*/
int cc1100_send_csmaca(radio_address_t address, protocol_t protocol, int priority, char *payload, radio_packet_length_t payload_len)
{
uint16_t min_window_size;
uint16_t max_window_size;
uint16_t difs;
uint16_t slottime;
switch(priority) {
case PRIORITY_ALARM:
min_window_size = PRIO_ALARM_MIN_WINDOW_SIZE;
max_window_size = PRIO_ALARM_MAX_WINDOW_SIZE;
difs = PRIO_ALARM_DIFS;
slottime = PRIO_ALARM_SLOTTIME;
break;
case PRIORITY_WARNING:
min_window_size = PRIO_WARN_MIN_WINDOW_SIZE;
max_window_size = PRIO_WARN_MAX_WINDOW_SIZE;
difs = PRIO_WARN_DIFS;
slottime = PRIO_WARN_SLOTTIME;
break;
default:
min_window_size = PRIO_DATA_MIN_WINDOW_SIZE;
max_window_size = PRIO_DATA_MAX_WINDOW_SIZE;
difs = PRIO_DATA_DIFS;
slottime = PRIO_DATA_SLOTTIME;
}
/* Calculate collisions per second */
if (collision_state == COLLISION_STATE_INITIAL) {
vtimer_now(&collision_measurement_start);
collision_count = 0;
collisions_per_sec = 0;
collision_state = COLLISION_STATE_MEASURE;
}
else if (collision_state == COLLISION_STATE_MEASURE) {
timex_t now;
vtimer_now(&now);
timex_t timespan = timex_sub(now, collision_measurement_start);
if (timex_cmp(timespan, timex_set(1, 0)) > 0) {
collisions_per_sec = (collision_count * 1000000) / (double) timex_uint64(timespan);
if (collisions_per_sec > 0.5 && collisions_per_sec <= 2.2) {
timex_t now;
vtimer_now(&now);
collision_measurement_start = now;
collision_state = COLLISION_STATE_KEEP;
}
else if (collisions_per_sec > 2.2) {
timex_t now;
vtimer_now(&now);
collision_measurement_start = now;
collision_state = COLLISION_STATE_KEEP;
}
else {
collision_state = COLLISION_STATE_INITIAL;
}
}
}
else if (collision_state == COLLISION_STATE_KEEP) {
timex_t now;
vtimer_now(&now);
timex_t timespan = timex_sub(now, collision_measurement_start);
if (timex_cmp(timespan, timex_set(5, 0)) > 0) {
collision_state = COLLISION_STATE_INITIAL;
}
}
/* Adjust initial window size according to collision rate */
if (collisions_per_sec > 0.5 && collisions_per_sec <= 2.2) {
min_window_size *= 2;
}
else if (collisions_per_sec > 2.2) {
min_window_size *= 4;
}
uint16_t windowSize = min_window_size; /* Start with window size of PRIO_XXX_MIN_WINDOW_SIZE */
uint16_t backoff = 0; /* Backoff between 1 and windowSize */
uint32_t total; /* Holds the total wait time before send try */
uint32_t cs_timeout; /* Current carrier sense timeout value */
if (protocol == 0) {
return RADIO_INVALID_PARAM; /* Not allowed, protocol id must be greater zero */
}
cc1100_phy_mutex_lock(); /* Lock radio for exclusive access */
/* Get carrier sense timeout based on overall error rate till now */
send_csmaca_calls++;
int fail_percentage = (send_csmaca_calls_cs_timeout * 100) / send_csmaca_calls;
if (fail_percentage == 0) {
fail_percentage = 1;
}
cs_timeout = CARRIER_SENSE_TIMEOUT / fail_percentage;
if (cs_timeout < CARRIER_SENSE_TIMEOUT_MIN) {
cs_timeout = CARRIER_SENSE_TIMEOUT_MIN;
}
cc1100_cs_init(); /* Initialize carrier sensing */
window:
if (backoff != 0) {
goto cycle; /* If backoff was 0 */
}
windowSize *= 2; /* ...double the current window size */
if (windowSize > max_window_size) {
windowSize = max_window_size; /* This is the maximum size allowed */
}
backoff = rand() % windowSize; /* ...and choose new backoff */
backoff += (uint16_t) 1;
cycle:
cs_timeout_flag = 0; /* Carrier sense timeout flag */
cs_hwtimer_id = hwtimer_set(cs_timeout, /* Set hwtimer to set CS timeout flag */
cs_timeout_cb, NULL);
while (cc1100_cs_read()) { /* Wait until air is free */
if (cs_timeout_flag) {
send_csmaca_calls_cs_timeout++;
#ifndef CSMACA_MAC_AGGRESSIVE_MODE
cc1100_phy_mutex_unlock();
cc1100_go_after_tx(); /* Go from RX to default mode */
return RADIO_CS_TIMEOUT; /* Return immediately */
#endif
#ifdef CSMACA_MAC_AGGRESSIVE_MODE
goto send; /* Send anyway */
#endif
}
}
hwtimer_remove(cs_hwtimer_id); /* Remove hwtimer */
cc1100_cs_write_cca(1); /* Air is free now */
cc1100_cs_set_enabled(true);
if (cc1100_cs_read()) {
goto window; /* GDO0 triggers on rising edge, so */
}
/* test once after interrupt is enabled */
if (backoff > 0) {
backoff--; /* Decrement backoff counter */
}
total = slottime; /* Calculate total wait time */
total *= (uint32_t)backoff; /* Slot vector set */
total += difs; /* ...and standard DIFS wait time */
cs_timeout_flag = 0; /* Carrier sense timeout flag */
cs_hwtimer_id = hwtimer_set(total, /* Set hwtimer to set CS timeout flag */
cs_timeout_cb, NULL);
while (!cs_timeout_flag
|| !cc1100_cs_read_cca()) { /* Wait until timeout is finished */
if (cc1100_cs_read_cca() == 0) { /* Is the air still free? */
hwtimer_remove(cs_hwtimer_id);
goto window; /* No. Go back to new wait period. */
}
}
cc1100_cs_set_enabled(false);
#ifdef CSMACA_MAC_AGGRESSIVE_MODE
send:
#endif
int res = cc1100_send(address, protocol, priority, payload, payload_len);
if (res < 0) {
collision_count++;
}
return res;
}
void gnrc_ndp_internal_send_rtr_adv(kernel_pid_t iface, ipv6_addr_t *src, ipv6_addr_t *dst,
bool fin)
{
gnrc_pktsnip_t *hdr, *pkt = NULL;
ipv6_addr_t all_nodes = IPV6_ADDR_ALL_NODES_LINK_LOCAL;
gnrc_ipv6_netif_t *ipv6_iface = gnrc_ipv6_netif_get(iface);
uint32_t reach_time = 0, retrans_timer = 0;
uint16_t adv_ltime = 0;
uint8_t cur_hl = 0;
if (dst == NULL) {
dst = &all_nodes;
}
DEBUG("ndp internal: send router advertisement (iface: %" PRIkernel_pid ", dst: %s%s\n",
iface, ipv6_addr_to_str(addr_str, dst, sizeof(addr_str)), fin ? ", final" : "");
mutex_lock(&ipv6_iface->mutex);
hdr = _add_pios(ipv6_iface, pkt);
if (hdr == NULL) {
/* pkt already released in _add_pios */
mutex_unlock(&ipv6_iface->mutex);
return;
}
pkt = hdr;
if (ipv6_iface->flags & GNRC_IPV6_NETIF_FLAGS_ADV_MTU) {
if ((hdr = gnrc_ndp_opt_mtu_build(ipv6_iface->mtu, pkt)) == NULL) {
DEBUG("ndp rtr: no space left in packet buffer\n");
mutex_unlock(&ipv6_iface->mutex);
gnrc_pktbuf_release(pkt);
return;
}
pkt = hdr;
}
if (src == NULL) {
/* get address from source selection algorithm */
src = gnrc_ipv6_netif_find_best_src_addr(iface, dst);
}
/* add SL2A for source address */
if (src != NULL) {
DEBUG(" - SL2A\n");
uint8_t l2src[8];
size_t l2src_len;
/* optimization note: MAY also be omitted to facilitate in-bound load balancing over
* replicated interfaces.
* source: https://tools.ietf.org/html/rfc4861#section-6.2.3 */
l2src_len = _get_l2src(iface, l2src, sizeof(l2src));
if (l2src_len > 0) {
/* add source address link-layer address option */
hdr = gnrc_ndp_opt_sl2a_build(l2src, l2src_len, NULL);
if (hdr == NULL) {
DEBUG("ndp internal: error allocating Source Link-layer address option.\n");
mutex_unlock(&ipv6_iface->mutex);
gnrc_pktbuf_release(pkt);
return;
}
pkt = hdr;
}
}
if (ipv6_iface->flags & GNRC_IPV6_NETIF_FLAGS_ADV_CUR_HL) {
cur_hl = ipv6_iface->cur_hl;
}
if (ipv6_iface->flags & GNRC_IPV6_NETIF_FLAGS_ADV_REACH_TIME) {
uint64_t tmp = timex_uint64(ipv6_iface->reach_time) / MS_IN_USEC;
if (tmp > (3600 * SEC_IN_MS)) { /* tmp > 1 hour */
tmp = (3600 * SEC_IN_MS);
}
reach_time = (uint32_t)tmp;
}
if (ipv6_iface->flags & GNRC_IPV6_NETIF_FLAGS_ADV_RETRANS_TIMER) {
uint64_t tmp = timex_uint64(ipv6_iface->retrans_timer) / MS_IN_USEC;
if (tmp > UINT32_MAX) {
tmp = UINT32_MAX;
}
retrans_timer = (uint32_t)tmp;
}
if (!fin) {
adv_ltime = ipv6_iface->adv_ltime;
}
mutex_unlock(&ipv6_iface->mutex);
hdr = gnrc_ndp_rtr_adv_build(cur_hl,
(ipv6_iface->flags & (GNRC_IPV6_NETIF_FLAGS_OTHER_CONF |
GNRC_IPV6_NETIF_FLAGS_MANAGED)) >> 8,
adv_ltime, reach_time, retrans_timer, pkt);
if (hdr == NULL) {
DEBUG("ndp internal: error allocating router advertisement.\n");
gnrc_pktbuf_release(pkt);
return;
}
pkt = hdr;
hdr = _build_headers(iface, pkt, dst, src);
if (hdr == NULL) {
DEBUG("ndp internal: error adding lower-layer headers.\n");
gnrc_pktbuf_release(pkt);
return;
}
gnrc_netapi_send(gnrc_ipv6_pid, hdr);
}
