static void restartInterval( uint8_t new_tou )
{
int32_t tou_interval = 0;
int32_t rand_val = 0;
ker_timer_stop( KER_DFT_LOADER_PID, TOU_TID );
ker_timer_stop( KER_DFT_LOADER_PID, TRAN_TID );
ker_timer_stop( KER_DFT_LOADER_PID, DATA_TID );
if ( new_tou < TOU_MAX ) {
st.tou = new_tou;
} else {
st.tou = TOU_MAX;
}
st.tran_count = 0;
st.data_count = 0;
tou_interval = TOU_INTERVAL * (1L << st.tou);
ker_timer_start( KER_DFT_LOADER_PID, TOU_TID, tou_interval );
if ( st.net_state & SEND_DATA ) {
//! pick random timeout between tou_interval / 2 and tou_interval
rand_val = ker_rand() % (tou_interval / 2);
rand_val += (tou_interval / 2);
ker_timer_start( KER_DFT_LOADER_PID, DATA_TID, rand_val );
} else {
//! pick random timeout between tou_interval / 2 and tou_interval
rand_val = ker_rand() % (tou_interval / 2);
rand_val += (tou_interval / 2);
ker_timer_start( KER_DFT_LOADER_PID, TRAN_TID, rand_val );
}
}
int8_t fetcher_request(sos_pid_t req_id, sos_shm_t key, uint16_t size, uint16_t src)
{
uint8_t bitmap_size; //! size of the bitmap in bytes
uint16_t num_fragments;
uint8_t i;
fetcher_state_t *f;
fetcher_cam_t *cam;
cam = (fetcher_cam_t *) ker_shm_get( KER_FETCHER_PID, key);
if( cam == NULL ) return -EINVAL;
//if(fst != NULL) return -EBUSY;
DEBUG_PID(KER_FETCHER_PID, "fetcher_request, req_id = %d, size = %d, src = %d\n", req_id, size, src);
num_fragments = ((size + (FETCHER_FRAGMENT_SIZE - 1))/ FETCHER_FRAGMENT_SIZE);
bitmap_size = (uint8_t)((num_fragments + 7)/ 8);
//DEBUG("size = %d\n", sizeof(fetcher_state_t) + bitmap_size);
f = ker_malloc(sizeof(fetcher_state_t) + bitmap_size, KER_FETCHER_PID);
if(f == NULL) {
return -ENOMEM;
}
//DEBUG("num_fragments = %d, bitmap_zie = %d\n", num_fragments, bitmap_size);
f->requester = req_id;
f->map.key = key;
f->map.bitmap_size = bitmap_size;
f->src_addr = src;
f->num_funcs = 0;
f->next = NULL;
f->cm = cam->cm;
for(i = 0; i < bitmap_size; i++) {
f->map.bitmap[i] = 0xff;
}
if((num_fragments) % 8) {
f->map.bitmap[bitmap_size - 1] =
(1 << (num_fragments % 8)) - 1;
}
print_bitmap(&f->map);
//! backoff first!!!
f->retx = 0;
if(fst != NULL) {
fetcher_state_t *tmp = fst;
cam->status = FETCHING_QUEUED;
while(tmp->next != NULL) { tmp = tmp->next; }
tmp->next = f;
return SOS_OK;
}
cam->status = FETCHING_STARTED;
fst = f;
//! setup timer
ker_timer_start(KER_FETCHER_PID,
FETCHER_REQUEST_TID,
FETCHER_REQUEST_BACKOFF_SLOT * ((ker_rand() % FETCHER_REQUEST_MAX_SLOT) + 1));
//DEBUG("request ret = %d\n", ret);
return SOS_OK;
}
/*************************************************************************
* Implement exponential backoff mechanism *
*************************************************************************/
static int16_t MacBackoff_congestionBackoff(int8_t retries)
{
int8_t i;
int16_t masktime = 1;
for(i=0; i<retries; i++)
masktime *= 2; //masktime = 2^retries
masktime --; //get the mask
if( masktime > 1023 )
masktime = 1023; //max backoff 1023
// return ((ker_rand() & 0xF) + TIMER_MIN_INTERVAL);
return ((ker_rand() & masktime) + TIMER_MIN_INTERVAL);
}
static void start_new_fetch(void)
{
fst = fst->next;
if (fst) {
fetcher_cam_t *cam;
cam = ker_shm_get( KER_FETCHER_PID, fst->map.key );
cam->status = FETCHING_STARTED;
ker_timer_start(KER_FETCHER_PID,
FETCHER_REQUEST_TID,
FETCHER_REQUEST_BACKOFF_SLOT *
((ker_rand() % FETCHER_REQUEST_MAX_SLOT) + 1));
}
}
void fetcher_restart(fetcher_state_t *s, uint16_t src)
{
fetcher_cam_t *cam;
cam = ker_shm_get( KER_FETCHER_PID, s->map.key );
s->src_addr = src;
s->retx = 0;
s->next = NULL;
if(fst != NULL) {
fetcher_state_t *tmp = fst;
cam->status = FETCHING_QUEUED;
while(tmp->next != NULL) { tmp = tmp->next; }
tmp->next = s;
return;
}
fst = s;
cam->status = FETCHING_STARTED;
ker_timer_start(KER_FETCHER_PID,
FETCHER_REQUEST_TID,
FETCHER_REQUEST_BACKOFF_SLOT * ((ker_rand() % FETCHER_REQUEST_MAX_SLOT) + 1));
}
static inline void restart_request_timer()
{
ker_timer_restart(KER_FETCHER_PID,
FETCHER_REQUEST_TID,
FETCHER_REQUEST_WATCHDOG + (FETCHER_REQUEST_BACKOFF_SLOT * ((ker_rand() % FETCHER_REQUEST_MAX_SLOT) + 1)));
}
