void updateNioCounters(HSP *sp) {
// don't do anything if we already refreshed the numbers less than a second ago
if(sp->nio_last_update == sp->clk) {
return;
}
sp->nio_last_update = sp->clk;
// first read all the counters into new_nio
PPDH_RAW_COUNTER_ITEM value;
uint32_t icount = readMultiCounter("\\Network Interface(*)\\Bytes Received/sec",&value);
if(value) {
for(uint32_t i = 0; i < icount; i++){
//myLog(LOG_DEBUG, "bytes_received counter <%s> = %lu",
// value[i].szName,
// value[i].RawValue.FirstValue);
SFLHost_nio_counters *newctrs = getNewNIO(sp, value[i].szName);
if(newctrs) newctrs->bytes_in = value[i].RawValue.FirstValue;
}
my_free(value);
value = NULL;
}
icount = readMultiCounter("\\Network Interface(*)\\Packets Received/sec",&value);
if(value) {
for(uint32_t i = 0; i < icount; i++){
SFLHost_nio_counters *newctrs = getNewNIO(sp, value[i].szName);
if(newctrs) newctrs->pkts_in = (uint32_t)value[i].RawValue.FirstValue;
}
my_free(value);
value = NULL;
}
icount = readMultiCounter("\\Network Interface(*)\\Packets Received Errors",&value);
if(value) {
for(uint32_t i = 0; i < icount; i++){
SFLHost_nio_counters *newctrs = getNewNIO(sp, value[i].szName);
if(newctrs) newctrs->errs_in = (uint32_t)value[i].RawValue.FirstValue;
}
my_free(value);
value = NULL;
}
icount = readMultiCounter("\\Network Interface(*)\\Packets Received Discarded",&value);
if(value) {
for(uint32_t i = 0; i < icount; i++){
SFLHost_nio_counters *newctrs = getNewNIO(sp, value[i].szName);
if(newctrs) newctrs->drops_in = (uint32_t)value[i].RawValue.FirstValue;
}
my_free(value);
value = NULL;
}
icount = readMultiCounter("\\Network Interface(*)\\Bytes Sent/sec",&value);
if(value) {
for(uint32_t i = 0; i < icount; i++){
SFLHost_nio_counters *newctrs = getNewNIO(sp, value[i].szName);
if(newctrs) newctrs->bytes_out = value[i].RawValue.FirstValue;
}
my_free(value);
value = NULL;
}
icount = readMultiCounter("\\Network Interface(*)\\Packets Sent/sec",&value);
if(value) {
for(uint32_t i = 0; i < icount; i++){
SFLHost_nio_counters *newctrs = getNewNIO(sp, value[i].szName);
if(newctrs) newctrs->pkts_out = (uint32_t)value[i].RawValue.FirstValue;
}
my_free(value);
value = NULL;
}
icount = readMultiCounter("\\Network Interface(*)\\Packets Sent Errors",&value);
if(value) {
for(uint32_t i = 0; i < icount; i++){
SFLHost_nio_counters *newctrs = getNewNIO(sp, value[i].szName);
if(newctrs) newctrs->errs_out = (uint32_t)value[i].RawValue.FirstValue;
}
my_free(value);
value = NULL;
}
icount = readMultiCounter("\\Network Interface(*)\\Packets Sent Discarded",&value);
if(value) {
for(uint32_t i = 0; i < icount; i++){
SFLHost_nio_counters *newctrs = getNewNIO(sp, value[i].szName);
if(newctrs) newctrs->drops_out = (uint32_t)value[i].RawValue.FirstValue;
}
my_free(value);
value = NULL;
}
// now compute the deltas, sanity check them, accumulate and latch
for(uint32_t i = 0; i < sp->adaptorList->num_adaptors; i++) {
SFLAdaptor *ad = sp->adaptorList->adaptors[i];
if(ad) {
HSPAdaptorNIO *nio = (HSPAdaptorNIO *)ad->userData;
if(nio) {
// have to detect discontinuities here, so use a full
// set of latched counters and accumulators.
int accumulate = nio->last_update ? YES : NO;
nio->last_update = sp->clk;
uint64_t maxDeltaBytes = HSP_MAX_NIO_DELTA64;
SFLHost_nio_counters delta;
#define NIO_COMPUTE_DELTA(field) delta.field = nio->new_nio.field - nio->last_nio.field
NIO_COMPUTE_DELTA(pkts_in);
NIO_COMPUTE_DELTA(errs_in);
NIO_COMPUTE_DELTA(drops_in);
NIO_COMPUTE_DELTA(pkts_out);
NIO_COMPUTE_DELTA(errs_out);
NIO_COMPUTE_DELTA(drops_out);
if(sp->nio_polling_secs == 0) {
// 64-bit byte counters
NIO_COMPUTE_DELTA(bytes_in);
NIO_COMPUTE_DELTA(bytes_out);
}
else {
// for case where byte counters are 32-bit, we need
// to use 32-bit unsigned arithmetic to avoid spikes
delta.bytes_in = (uint32_t)nio->new_nio.bytes_in - nio->last_bytes_in32;
delta.bytes_out = (uint32_t)nio->new_nio.bytes_out - nio->last_bytes_out32;
nio->last_bytes_in32 = (uint32_t)nio->new_nio.bytes_in;
nio->last_bytes_out32 = (uint32_t)nio->new_nio.bytes_out;
maxDeltaBytes = HSP_MAX_NIO_DELTA32;
// if we detect that the OS is using 64-bits then we can turn off the faster
// NIO polling. This should probably be done based on the kernel version or some
// other include-file definition, but it's not expensive to do it here like this:
if(nio->new_nio.bytes_in > 0xFFFFFFFF || nio->new_nio.bytes_out > 0xFFFFFFFF) {
myLog(LOG_DEBUG, "detected 64-bit network counters");
sp->nio_polling_secs = 0;
}
}
if(accumulate) {
// sanity check in case the counters were reset under out feet.
// normally we leave this to the upstream collector, but these
// numbers might be getting passed through from the hardware(?)
// so we treat them with particular distrust.
if(delta.bytes_in > maxDeltaBytes ||
delta.bytes_out > maxDeltaBytes ||
delta.pkts_in > HSP_MAX_NIO_DELTA32 ||
delta.pkts_out > HSP_MAX_NIO_DELTA32) {
myLog(LOG_ERR, "detected NIO counter discontinuity");
accumulate = NO;
}
}
if(accumulate) {
#define NIO_ACCUMULATE(field) nio->nio.field += delta.field
NIO_ACCUMULATE(bytes_in);
NIO_ACCUMULATE(pkts_in);
NIO_ACCUMULATE(errs_in);
NIO_ACCUMULATE(drops_in);
NIO_ACCUMULATE(bytes_out);
NIO_ACCUMULATE(pkts_out);
NIO_ACCUMULATE(errs_out);
NIO_ACCUMULATE(drops_out);
//myLog(LOG_DEBUG, "accumulated NIO counters (new=%lu old=%lu delta=%lu nio->nio.bytes_in now = %lu)",
// nio->new_nio.bytes_in, nio->last_nio.bytes_in, delta.bytes_in, nio->nio.bytes_in);
}
#define NIO_LATCH(field) nio->last_nio.field = nio->new_nio.field
NIO_LATCH(bytes_in);
NIO_LATCH(pkts_in);
NIO_LATCH(errs_in);
NIO_LATCH(drops_in);
NIO_LATCH(bytes_out);
NIO_LATCH(pkts_out);
NIO_LATCH(errs_out);
NIO_LATCH(drops_out);
}
}
}
}
void updateNioCounters(HSP *sp) {
// don't do anything if we already refreshed the numbers less than a second ago
if(sp->adaptorNIOList.last_update == sp->clk) {
return;
}
sp->adaptorNIOList.last_update = sp->clk;
static int mib[] = { CTL_NET,
PF_ROUTE,
0,
0, /* address family */
NET_RT_IFLIST,
0 }; /* ifIndex */
size_t needed = 0;
if (sysctl(mib, 6, NULL, &needed, NULL, 0) < 0) {
myLog(LOG_ERR, "sysctl for interface list failed");
return;
}
char *buf = my_calloc(needed);
if (sysctl(mib, 6, buf, &needed, NULL, 0) < 0) {
myLog(LOG_ERR, "sysctl for interface list failed (2nd time)");
}
else {
char *lim = buf + needed;
char *next = buf;
while (next < lim) {
struct if_msghdr *ifm = (struct if_msghdr *)next;
if (ifm->ifm_type != RTM_IFINFO) {
myLog(LOG_ERR, "out of sync parsing NET_RT_IFLIST\n");
break;
}
next += ifm->ifm_msglen;
while (next < lim) {
struct if_msghdr *nextifm = (struct if_msghdr *)next;
if (nextifm->ifm_type != RTM_NEWADDR) break;
next += nextifm->ifm_msglen;
}
if (!(ifm->ifm_flags & IFF_LOOPBACK) &&
(ifm->ifm_flags & IFF_UP)) {
char deviceName[IFNAMSIZ];
uint32_t index = ifm->ifm_index;
if(if_indextoname(index, deviceName)) {
char *str = deviceName;
trimWhitespace(str);
HSPAdaptorNIO *adaptor = getAdaptorNIO(&sp->adaptorNIOList, str);
if(adaptor) {
uint64_t bytes_in = ifm->ifm_data.ifi_ibytes;
uint64_t pkts_in = ifm->ifm_data.ifi_ipackets;
uint64_t errs_in = ifm->ifm_data.ifi_ierrors;
uint64_t drops_in = ifm->ifm_data.ifi_iqdrops;
uint64_t bytes_out = ifm->ifm_data.ifi_obytes;
uint64_t pkts_out = ifm->ifm_data.ifi_opackets;
uint64_t errs_out = ifm->ifm_data.ifi_oerrors;
uint64_t drops_out = (uint64_t)-1; /* unsupported */
// have to detect discontinuities here, so use a full
// set of latched counters and accumulators.
int accumulate = adaptor->last_update ? YES : NO;
adaptor->last_update = sp->clk;
uint64_t maxDeltaBytes = HSP_MAX_NIO_DELTA64;
SFLHost_nio_counters delta;
#define NIO_COMPUTE_DELTA(field) delta.field = field - adaptor->last_nio.field
NIO_COMPUTE_DELTA(pkts_in);
NIO_COMPUTE_DELTA(errs_in);
NIO_COMPUTE_DELTA(drops_in);
NIO_COMPUTE_DELTA(pkts_out);
NIO_COMPUTE_DELTA(errs_out);
NIO_COMPUTE_DELTA(drops_out);
if(sp->adaptorNIOList.polling_secs == 0) {
// 64-bit byte counters
NIO_COMPUTE_DELTA(bytes_in);
NIO_COMPUTE_DELTA(bytes_out);
}
else {
// for case where byte counters are 32-bit, we need
// to use 32-bit unsigned arithmetic to avoid spikes
delta.bytes_in = (uint32_t)bytes_in - adaptor->last_bytes_in32;
delta.bytes_out = (uint32_t)bytes_out - adaptor->last_bytes_out32;
adaptor->last_bytes_in32 = bytes_in;
adaptor->last_bytes_out32 = bytes_out;
maxDeltaBytes = HSP_MAX_NIO_DELTA32;
// if we detect that the OS is using 64-bits then we can turn off the faster
// NIO polling. This should probably be done based on the kernel version or some
// other include-file definition, but it's not expensive to do it here like this:
if(bytes_in > 0xFFFFFFFF || bytes_out > 0xFFFFFFFF) {
myLog(LOG_INFO, "detected 64-bit counters in /proc/net/dev");
sp->adaptorNIOList.polling_secs = 0;
}
}
if(accumulate) {
// sanity check in case the counters were reset under out feet.
// normally we leave this to the upstream collector, but these
// numbers might be getting passed through from the hardware(?)
// so we treat them with particular distrust.
if(delta.bytes_in > maxDeltaBytes ||
delta.bytes_out > maxDeltaBytes ||
delta.pkts_in > HSP_MAX_NIO_DELTA32 ||
delta.pkts_out > HSP_MAX_NIO_DELTA32) {
myLog(LOG_ERR, "detected counter discontinuity in /proc/net/dev");
accumulate = NO;
}
}
if(accumulate) {
#define NIO_ACCUMULATE(field) adaptor->nio.field += delta.field
NIO_ACCUMULATE(bytes_in);
NIO_ACCUMULATE(pkts_in);
NIO_ACCUMULATE(errs_in);
NIO_ACCUMULATE(drops_in);
NIO_ACCUMULATE(bytes_out);
NIO_ACCUMULATE(pkts_out);
NIO_ACCUMULATE(errs_out);
NIO_ACCUMULATE(drops_out);
}
#define NIO_LATCH(field) adaptor->last_nio.field = field
NIO_LATCH(bytes_in);
NIO_LATCH(pkts_in);
NIO_LATCH(errs_in);
NIO_LATCH(drops_in);
NIO_LATCH(bytes_out);
NIO_LATCH(pkts_out);
NIO_LATCH(errs_out);
NIO_LATCH(drops_out);
}
}
}
}
}
my_free(buf);
}
void updateNioCounters(HSP *sp) {
// don't do anything if we already refreshed the numbers less than a second ago
if(sp->nio_last_update == sp->clk) {
return;
}
sp->nio_last_update = sp->clk;
FILE *procFile;
procFile= fopen("/proc/net/dev", "r");
if(procFile) {
#ifdef HSP_ETHTOOL_STATS
int fd = socket (PF_INET, SOCK_DGRAM, 0);
struct ifreq ifr;
memset (&ifr, 0, sizeof(ifr));
#endif
// ASCII numbers in /proc/diskstats may be 64-bit (if not now
// then someday), so it seems safer to read into
// 64-bit ints with scanf first, then copy them
// into the host_nio structure from there.
uint64_t bytes_in = 0;
uint64_t pkts_in = 0;
uint64_t errs_in = 0;
uint64_t drops_in = 0;
uint64_t bytes_out = 0;
uint64_t pkts_out = 0;
uint64_t errs_out = 0;
uint64_t drops_out = 0;
// limit the number of chars we will read from each line
// (there can be more than this - fgets will chop for us)
#define MAX_PROC_LINE_CHARS 240
char line[MAX_PROC_LINE_CHARS];
while(fgets(line, MAX_PROC_LINE_CHARS, procFile)) {
char deviceName[MAX_PROC_LINE_CHARS];
// assume the format is:
// Inter-| Receive | Transmit
// face |bytes packets errs drop fifo frame compressed multicast|bytes packets errs drop fifo colls carrier compressed
if(sscanf(line, "%[^:]:%"SCNu64" %"SCNu64" %"SCNu64" %"SCNu64" %*u %*u %*u %*u %"SCNu64" %"SCNu64" %"SCNu64" %"SCNu64"",
deviceName,
&bytes_in,
&pkts_in,
&errs_in,
&drops_in,
&bytes_out,
&pkts_out,
&errs_out,
&drops_out) == 9) {
SFLAdaptor *adaptor = adaptorListGet(sp->adaptorList, trimWhitespace(deviceName));
if(adaptor && adaptor->userData) {
HSPAdaptorNIO *niostate = (HSPAdaptorNIO *)adaptor->userData;
#ifdef HSP_ETHTOOL_STATS
HSP_ethtool_counters et_ctrs = { 0 }, et_delta = { 0 };
if (niostate->et_nfound) {
// get the latest stats block for this device via ethtool
// and read out the counters that we located by name.
uint32_t bytes = sizeof(struct ethtool_stats);
bytes += niostate->et_nctrs * sizeof(uint64_t);
bytes += 32; // pad - just in case driver wants to write more
struct ethtool_stats *et_stats = (struct ethtool_stats *)my_calloc(bytes);
et_stats->cmd = ETHTOOL_GSTATS;
et_stats->n_stats = niostate->et_nctrs;
// now issue the ioctl
strncpy(ifr.ifr_name, adaptor->deviceName, sizeof(ifr.ifr_name));
ifr.ifr_data = (char *)et_stats;
if(ioctl(fd, SIOCETHTOOL, &ifr) >= 0) {
if(debug > 2) {
for(int xx = 0; xx < et_stats->n_stats; xx++) {
myLog(LOG_INFO, "ethtool counter for %s at index %d == %"PRIu64,
adaptor->deviceName,
xx,
et_stats->data[xx]);
}
}
if(niostate->et_idx_mcasts_in) {
et_ctrs.mcasts_in = et_stats->data[niostate->et_idx_mcasts_in - 1];
et_delta.mcasts_in = et_ctrs.mcasts_in - niostate->et_last.mcasts_in;
}
if(niostate->et_idx_mcasts_out) {
et_ctrs.mcasts_out = et_stats->data[niostate->et_idx_mcasts_out - 1];
et_delta.mcasts_out = et_ctrs.mcasts_out - niostate->et_last.mcasts_out;
}
if(niostate->et_idx_bcasts_in) {
et_ctrs.bcasts_in = et_stats->data[niostate->et_idx_bcasts_in - 1];
et_delta.bcasts_in = et_ctrs.bcasts_in - niostate->et_last.bcasts_in;
}
if(niostate->et_idx_bcasts_out) {
et_ctrs.bcasts_out = et_stats->data[niostate->et_idx_bcasts_out - 1];
et_delta.bcasts_out = et_ctrs.bcasts_out - niostate->et_last.bcasts_out;
}
}
my_free(et_stats);
}
#endif
// have to detect discontinuities here, so use a full
// set of latched counters and accumulators.
int accumulate = niostate->last_update ? YES : NO;
niostate->last_update = sp->clk;
uint64_t maxDeltaBytes = HSP_MAX_NIO_DELTA64;
SFLHost_nio_counters delta;
#define NIO_COMPUTE_DELTA(field) delta.field = field - niostate->last_nio.field
NIO_COMPUTE_DELTA(pkts_in);
NIO_COMPUTE_DELTA(errs_in);
NIO_COMPUTE_DELTA(drops_in);
NIO_COMPUTE_DELTA(pkts_out);
NIO_COMPUTE_DELTA(errs_out);
NIO_COMPUTE_DELTA(drops_out);
if(sp->nio_polling_secs == 0) {
// 64-bit byte counters
NIO_COMPUTE_DELTA(bytes_in);
NIO_COMPUTE_DELTA(bytes_out);
}
else {
// for case where byte counters are 32-bit, we need
// to use 32-bit unsigned arithmetic to avoid spikes
delta.bytes_in = (uint32_t)bytes_in - niostate->last_bytes_in32;
delta.bytes_out = (uint32_t)bytes_out - niostate->last_bytes_out32;
niostate->last_bytes_in32 = bytes_in;
niostate->last_bytes_out32 = bytes_out;
maxDeltaBytes = HSP_MAX_NIO_DELTA32;
// if we detect that the OS is using 64-bits then we can turn off the faster
// NIO polling. This should probably be done based on the kernel version or some
// other include-file definition, but it's not expensive to do it here like this:
if(bytes_in > 0xFFFFFFFF || bytes_out > 0xFFFFFFFF) {
myLog(LOG_INFO, "detected 64-bit counters in /proc/net/dev");
sp->nio_polling_secs = 0;
}
}
if(accumulate) {
// sanity check in case the counters were reset under out feet.
// normally we leave this to the upstream collector, but these
// numbers might be getting passed through from the hardware(?)
// so we treat them with particular distrust.
if(delta.bytes_in > maxDeltaBytes ||
delta.bytes_out > maxDeltaBytes ||
delta.pkts_in > HSP_MAX_NIO_DELTA32 ||
delta.pkts_out > HSP_MAX_NIO_DELTA32) {
myLog(LOG_ERR, "detected counter discontinuity in /proc/net/dev for %s: deltaBytes=%"PRIu64",%"PRIu64" deltaPkts=%u,%u",
adaptor->deviceName,
delta.bytes_in,
delta.bytes_out,
delta.pkts_in,
delta.pkts_out);
accumulate = NO;
}
#ifdef HSP_ETHTOOL_STATS
if(et_delta.mcasts_in > HSP_MAX_NIO_DELTA64 ||
et_delta.mcasts_out > HSP_MAX_NIO_DELTA64 ||
et_delta.bcasts_in > HSP_MAX_NIO_DELTA64 ||
et_delta.bcasts_out > HSP_MAX_NIO_DELTA64) {
myLog(LOG_ERR, "detected counter discontinuity in ethtool stats");
accumulate = NO;
}
#endif
}
if(accumulate) {
#define NIO_ACCUMULATE(field) niostate->nio.field += delta.field
NIO_ACCUMULATE(bytes_in);
NIO_ACCUMULATE(pkts_in);
NIO_ACCUMULATE(errs_in);
NIO_ACCUMULATE(drops_in);
NIO_ACCUMULATE(bytes_out);
NIO_ACCUMULATE(pkts_out);
NIO_ACCUMULATE(errs_out);
NIO_ACCUMULATE(drops_out);
#ifdef HSP_ETHTOOL_STATS
#define ET_ACCUMULATE(field) niostate->et_total.field += et_delta.field
ET_ACCUMULATE(mcasts_in);
ET_ACCUMULATE(mcasts_out);
ET_ACCUMULATE(bcasts_in);
ET_ACCUMULATE(bcasts_out);
#endif
}
#define NIO_LATCH(field) niostate->last_nio.field = field
NIO_LATCH(bytes_in);
NIO_LATCH(pkts_in);
NIO_LATCH(errs_in);
NIO_LATCH(drops_in);
NIO_LATCH(bytes_out);
NIO_LATCH(pkts_out);
NIO_LATCH(errs_out);
NIO_LATCH(drops_out);
#ifdef HSP_ETHTOOL_STATS
niostate->et_last = et_ctrs; // struct copy
#endif
}
}
}
#ifdef HSP_ETHTOOL_STATS
if(fd >= 0) close(fd);
#endif
fclose(procFile);
}
}
/**
* Updates the cached NIO counters using PDH if the counters were updated
* more than a second ago.
* Computes the delta between current and last counters, checks for
* discontinuities (including determining whether 32 bit counters are being
* use - eg for bytes - and have wrapped), accumulates totals, and stores
* the latest counter values for delta computation on next invokation.
* If 64 bit counters are detected, indicates this by setting
* sp->nio->polling_seconds = 0 so that more
* frequent polling of counters can be turned off.
*/
void updateNioCounters(HSP *sp) {
// don't do anything if we refreshed the numbers less than a second ago
if (sp->nio_last_update == sp->clk) {
return;
}
sp->nio_last_update = sp->clk;
// first read all the counters into new_nio
if (query == NULL) {
PDH_STATUS status = createCounterQuery();
if (status != ERROR_SUCCESS) {
query = NULL;
myLog(LOG_ERR, "updateNioCounters: creating query failed: 0x%x", status);
return;
}
}
PdhCollectQueryData(query);
PPDH_RAW_COUNTER_ITEM_W values;
uint32_t icount = 0;
icount = getRawCounterValues(&bytesIn, &values);
if (icount > 0) {
for (uint32_t i = 0; i < icount; i++) {
SFLHost_nio_counters *newctrs = getNewNIO(sp, values[i].szName);
if (newctrs != NULL) {
newctrs->bytes_in = values[i].RawValue.FirstValue;
//myLog(LOG_INFO, "updateNioCounters: adapter=%S bytesIn=%lu",
// values[i].szName, newctrs->bytes_in);
}
}
my_free(values);
icount = 0;
}
icount = getRawCounterValues(&pktsIn, &values);
if (icount > 0) {
for (uint32_t i = 0; i < icount; i++) {
SFLHost_nio_counters *newctrs = getNewNIO(sp, values[i].szName);
if(newctrs != NULL) {
newctrs->pkts_in = (uint32_t)values[i].RawValue.FirstValue;
}
}
my_free(values);
icount = 0;
}
icount = getRawCounterValues(&errorsIn, &values);
if (icount > 0) {
for (uint32_t i = 0; i < icount; i++) {
SFLHost_nio_counters *newctrs = getNewNIO(sp, values[i].szName);
if(newctrs != NULL) {
newctrs->errs_in = (uint32_t)values[i].RawValue.FirstValue;
}
}
my_free(values);
icount = 0;
}
icount = getRawCounterValues(&discardsIn, &values);
if (icount > 0) {
for (uint32_t i = 0; i < icount; i++) {
SFLHost_nio_counters *newctrs = getNewNIO(sp, values[i].szName);
if (newctrs != NULL) {
newctrs->drops_in = (uint32_t)values[i].RawValue.FirstValue;
}
}
my_free(values);
icount = 0;
}
icount = getRawCounterValues(&bytesOut, &values);
if (icount > 0) {
for (uint32_t i = 0; i < icount; i++) {
SFLHost_nio_counters *newctrs = getNewNIO(sp, values[i].szName);
if (newctrs != NULL) {
newctrs->bytes_out = values[i].RawValue.FirstValue;
}
}
my_free(values);
icount = 0;
}
icount = getRawCounterValues(&pktsOut, &values);
if (icount > 0) {
for (uint32_t i = 0; i < icount; i++) {
SFLHost_nio_counters *newctrs = getNewNIO(sp, values[i].szName);
if (newctrs != NULL) {
newctrs->pkts_out = (uint32_t)values[i].RawValue.FirstValue;
}
}
my_free(values);
icount = 0;
}
icount = getRawCounterValues(&errorsOut, &values);
if (icount > 0) {
for (uint32_t i = 0; i < icount; i++) {
SFLHost_nio_counters *newctrs = getNewNIO(sp, values[i].szName);
if (newctrs != NULL) {
newctrs->errs_out = (uint32_t)values[i].RawValue.FirstValue;
}
}
my_free(values);
icount = 0;
}
icount = getRawCounterValues(&discardsOut, &values);
if (icount > 0) {
for (uint32_t i = 0; i < icount; i++) {
SFLHost_nio_counters *newctrs = getNewNIO(sp, values[i].szName);
if (newctrs != NULL) {
newctrs->drops_out = (uint32_t)values[i].RawValue.FirstValue;
}
}
my_free(values);
icount = 0;
}
// now compute the deltas, sanity check them, accumulate and latch
for (uint32_t i = 0; i < sp->adaptorList->num_adaptors; i++) {
SFLAdaptor *ad = sp->adaptorList->adaptors[i];
if (ad != NULL) {
HSPAdaptorNIO *nio = (HSPAdaptorNIO *)ad->userData;
if (nio != NULL) {
// have to detect discontinuities here, so use a full
// set of latched counters and accumulators.
BOOL accumulate = nio->last_update ? TRUE : FALSE;
nio->last_update = sp->clk;
uint64_t maxDeltaBytes = HSP_MAX_NIO_DELTA64;
SFLHost_nio_counters delta;
#define NIO_COMPUTE_DELTA(field) delta.field = nio->new_nio.field - nio->last_nio.field
NIO_COMPUTE_DELTA(pkts_in);
NIO_COMPUTE_DELTA(errs_in);
NIO_COMPUTE_DELTA(drops_in);
NIO_COMPUTE_DELTA(pkts_out);
NIO_COMPUTE_DELTA(errs_out);
NIO_COMPUTE_DELTA(drops_out);
if (sp->nio_polling_secs == 0) {
// 64-bit byte counters
NIO_COMPUTE_DELTA(bytes_in);
NIO_COMPUTE_DELTA(bytes_out);
} else {
// for case where byte counters are 32-bit, we need
// to use 32-bit unsigned arithmetic to avoid spikes
delta.bytes_in = (uint32_t)nio->new_nio.bytes_in - nio->last_bytes_in32;
delta.bytes_out = (uint32_t)nio->new_nio.bytes_out - nio->last_bytes_out32;
nio->last_bytes_in32 = (uint32_t)nio->new_nio.bytes_in;
nio->last_bytes_out32 = (uint32_t)nio->new_nio.bytes_out;
maxDeltaBytes = HSP_MAX_NIO_DELTA32;
// if we detect that the OS is using 64-bits then we can turn off the faster
// NIO polling. This should probably be done based on the kernel version or some
// other include-file definition, but it's not expensive to do it here like this:
if (nio->new_nio.bytes_in > 0xFFFFFFFF || nio->new_nio.bytes_out > 0xFFFFFFFF) {
myLog(LOG_INFO, "detected 64-bit network counters");
sp->nio_polling_secs = 0;
}
}
if (accumulate) {
// sanity check in case the counters were reset under out feet.
// normally we leave this to the upstream collector, but these
// numbers might be getting passed through from the hardware(?)
// so we treat them with particular distrust.
if (delta.bytes_in > maxDeltaBytes ||
delta.bytes_out > maxDeltaBytes ||
delta.pkts_in > HSP_MAX_NIO_DELTA32 ||
delta.pkts_out > HSP_MAX_NIO_DELTA32) {
myLog(LOG_INFO, "detected NIO counter discontinuity");
accumulate = FALSE;
}
}
if (accumulate) {
#define NIO_ACCUMULATE(field) nio->nio.field += delta.field
NIO_ACCUMULATE(bytes_in);
NIO_ACCUMULATE(pkts_in);
NIO_ACCUMULATE(errs_in);
NIO_ACCUMULATE(drops_in);
NIO_ACCUMULATE(bytes_out);
NIO_ACCUMULATE(pkts_out);
NIO_ACCUMULATE(errs_out);
NIO_ACCUMULATE(drops_out);
//myLog(LOG_INFO, "accumulated NIO counters (new=%lu old=%lu delta=%lu nio->nio.bytes_in now = %lu)",
// nio->new_nio.bytes_in, nio->last_nio.bytes_in, delta.bytes_in, nio->nio.bytes_in);
}
#define NIO_LATCH(field) nio->last_nio.field = nio->new_nio.field
NIO_LATCH(bytes_in);
NIO_LATCH(pkts_in);
NIO_LATCH(errs_in);
NIO_LATCH(drops_in);
NIO_LATCH(bytes_out);
NIO_LATCH(pkts_out);
NIO_LATCH(errs_out);
NIO_LATCH(drops_out);
}
}
}
}
