void readBondState(HSP *sp) {
for(uint32_t i = 0; i < sp->adaptorList->num_adaptors; i++) {
SFLAdaptor *adaptor = sp->adaptorList->adaptors[i];
if(adaptor && adaptor->ifIndex) {
HSPAdaptorNIO *niostate = (HSPAdaptorNIO *)adaptor->userData;
if(niostate) {
if(niostate->bond_master) {
updateBondCounters(sp, adaptor);
}
}
}
}
}
void agentCB_getCounters_interface(void *magic, SFLPoller *poller, SFL_COUNTERS_SAMPLE_TYPE *cs)
{
assert(poller->magic);
HSP *sp = (HSP *)poller->magic;
// device name was copied as userData
char *devName = (char *)poller->userData;
if(devName) {
// look up the adaptor objects
SFLAdaptor *adaptor = adaptorListGet(sp->adaptorList, devName);
if(adaptor && adaptor->userData) {
HSPAdaptorNIO *adaptorNIO = (HSPAdaptorNIO *)adaptor->userData;
// make sure the counters are up to the second
updateNioCounters(sp);
// see if we were able to discern multicast and broadcast counters
// by polling for ethtool stats. Be careful to use unsigned 32-bit
// arithmetic here:
#define UNSUPPORTED_SFLOW_COUNTER32 (uint32_t)-1
uint32_t pkts_in = adaptorNIO->nio.pkts_in;
uint32_t pkts_out = adaptorNIO->nio.pkts_out;
uint32_t mcasts_in = UNSUPPORTED_SFLOW_COUNTER32;
uint32_t mcasts_out = UNSUPPORTED_SFLOW_COUNTER32;
uint32_t bcasts_in = UNSUPPORTED_SFLOW_COUNTER32;
uint32_t bcasts_out = UNSUPPORTED_SFLOW_COUNTER32;
#ifdef HSP_ETHTOOL_STATS
// only do this if we were able to find all four
// via ethtool, otherwise it would just be too weird...
if(adaptorNIO->et_nfound == 4) {
mcasts_in = (uint32_t)adaptorNIO->et_total.mcasts_in;
bcasts_in = (uint32_t)adaptorNIO->et_total.bcasts_in;
pkts_in -= (mcasts_in + bcasts_in);
mcasts_out = (uint32_t)adaptorNIO->et_total.mcasts_out;
bcasts_out = (uint32_t)adaptorNIO->et_total.bcasts_out;
pkts_out -= (mcasts_out + bcasts_out);
}
#endif
// generic interface counters
SFLCounters_sample_element elem = { 0 };
elem.tag = SFLCOUNTERS_GENERIC;
elem.counterBlock.generic.ifIndex = poller->dsi.ds_index;
elem.counterBlock.generic.ifType = 6; // assume ethernet
elem.counterBlock.generic.ifSpeed = adaptor->ifSpeed;
elem.counterBlock.generic.ifDirection = adaptor->ifDirection;
elem.counterBlock.generic.ifStatus = adaptorNIO->up ? (SFLSTATUS_ADMIN_UP | SFLSTATUS_OPER_UP) : 0;
elem.counterBlock.generic.ifPromiscuousMode = adaptor->promiscuous;
elem.counterBlock.generic.ifInOctets = adaptorNIO->nio.bytes_in;
elem.counterBlock.generic.ifInUcastPkts = pkts_in;
elem.counterBlock.generic.ifInMulticastPkts = mcasts_in;
elem.counterBlock.generic.ifInBroadcastPkts = bcasts_in;
elem.counterBlock.generic.ifInDiscards = adaptorNIO->nio.drops_in;
elem.counterBlock.generic.ifInErrors = adaptorNIO->nio.errs_in;
elem.counterBlock.generic.ifInUnknownProtos = UNSUPPORTED_SFLOW_COUNTER32;
elem.counterBlock.generic.ifOutOctets = adaptorNIO->nio.bytes_out;
elem.counterBlock.generic.ifOutUcastPkts = pkts_out;
elem.counterBlock.generic.ifOutMulticastPkts = mcasts_out;
elem.counterBlock.generic.ifOutBroadcastPkts = bcasts_out;
elem.counterBlock.generic.ifOutDiscards = adaptorNIO->nio.drops_out;
elem.counterBlock.generic.ifOutErrors = adaptorNIO->nio.errs_out;
SFLADD_ELEMENT(cs, &elem);
// add optional interface name struct
SFLCounters_sample_element pn_elem = { 0 };
pn_elem.tag = SFLCOUNTERS_PORTNAME;
pn_elem.counterBlock.portName.portName.len = my_strlen(devName);
pn_elem.counterBlock.portName.portName.str = devName;
SFLADD_ELEMENT(cs, &pn_elem);
// possibly include LACP struct for bond master or slave
SFLCounters_sample_element lacp_elem = { 0 };
if(adaptorNIO->bond_master
|| adaptorNIO->bond_slave) {
updateBondCounters(sp, adaptor);
lacp_elem.tag = SFLCOUNTERS_LACP;
lacp_elem.counterBlock.lacp = adaptorNIO->lacp; // struct copy
SFLADD_ELEMENT(cs, &lacp_elem);
}
sfl_poller_writeCountersSample(poller, cs);
}
}
}
