//
// Requirement here is to merge in any event records that have
// just arrived in the last timestep (from my.metric) with the
// set already being displayed.
// Additionally, we need to cull those that are no longer within
// the time window of interest.
//
void
TracingItem::updateValues(TracingEngine *engine, double left, double right)
{
QmcMetric *metric = ChartItem::my.metric;
#if DESPERATE
console->post(PmChart::DebugForce, "TracingItem::updateValues: "
"%d total events, left=%.2f right=%.2f\n"
"Metadata counts: drops=%d spans=%d points=%d "
"Metric values: %d count\n",
my.events.size(), left, right,
my.drops.size(), my.spans.size(), my.points.size(), metric->numValues());
#endif
cullOutlyingSpans(left, right);
cullOutlyingDrops(left, right);
cullOutlyingPoints(left, right);
cullOutlyingEvents(left, right);
// crack open newly arrived event records
if (metric->numValues() > 0)
updateEvents(engine, metric);
// update the display
my.dropCurve->setSamples(my.drops);
my.spanCurve->setSamples(my.spans);
my.pointCurve->setSamples(my.points);
my.selectionCurve->setSamples(my.selections);
}
QmcMetric *
QmcGroup::addMetric(pmMetricSpec *theMetric, double theScale, bool active)
{
QmcMetric *metric = new QmcMetric(this, theMetric, theScale, active);
if (metric->status() >= 0)
metric->context()->addMetric(metric);
return metric;
}
QmcMetric *
QmcGroup::addMetric(char const *string, double theScale, bool active)
{
QmcMetric *metric = new QmcMetric(this, string, theScale, active);
if (metric->status() >= 0)
metric->context()->addMetric(metric);
return metric;
}
static int
traverse(const char *str, double scale)
{
pmMetricSpec *theMetric;
char *msg;
int sts = 0;
sts = pmParseMetricSpec((char *)str, 0, (char *)0, &theMetric, &msg);
if (sts < 0) {
pmprintf("%s: Error: Unable to parse metric spec:\n%s\n",
pmProgname, msg);
free(msg);
return sts;
}
// If the metric has instances, then it cannot be traversed
if (theMetric->ninst) {
QmcMetric *metric = group->addMetric(theMetric, scale);
if (metric->status() >= 0) {
checkUnits(metric);
metrics.append(metric);
numValues += metric->numValues();
}
else
sts = -1;
}
else {
if (theMetric->isarch == 0)
doMetricType = PM_CONTEXT_HOST;
else if (theMetric->isarch == 1)
doMetricType = PM_CONTEXT_ARCHIVE;
else if (theMetric->isarch == 2)
doMetricType = PM_CONTEXT_LOCAL;
else {
pmprintf("%s: Error: invalid metric source (%d): %s\n",
pmProgname, theMetric->isarch, theMetric->metric);
sts = -1;
}
doMetricSource = theMetric->source;
if (sts >= 0)
sts = group->use(doMetricType, doMetricSource);
if (sts >= 0) {
doMetricScale = scale;
sts = pmTraversePMNS(theMetric->metric, dometric);
if (sts >= 0 && doMetricFlag == false)
sts = -1;
else if (sts < 0) {
pmprintf("%s: Error: %s: %s\n",
pmProgname, theMetric->metric, pmErrStr(sts));
}
}
}
free(theMetric);
return sts;
}
static void
dometric(const char *name)
{
QString fullname = doMetricSource;
if (fullname.length()) {
if (doMetricType == PM_CONTEXT_ARCHIVE)
fullname.append(QChar('/'));
else
fullname.append(QChar(':'));
}
fullname.append(name);
QmcMetric* metric = group->addMetric((const char *)fullname.toAscii(),
doMetricScale);
if (metric->status() >= 0) {
checkUnits(metric);
metrics.append(metric);
numValues += metric->numValues();
}
else
doMetricFlag = false;
}
void
SamplingItem::updateValues(bool forward,
bool rateConvert, pmUnits *units, int sampleHistory, int,
double, double, double)
{
pmAtomValue scaled, raw;
QmcMetric *metric = ChartItem::my.metric;
double value;
int sz;
if (metric->numValues() < 1 || metric->error(0)) {
value = qQNaN();
} else {
// convert raw value to current chart scale
raw.d = rateConvert ? metric->value(0) : metric->currentValue(0);
pmConvScale(PM_TYPE_DOUBLE, &raw, &ChartItem::my.units, &scaled, units);
value = scaled.d * my.scale;
}
if (my.dataCount < sampleHistory)
sz = qMax(0, (int)(my.dataCount * sizeof(double)));
else
sz = qMax(0, (int)((my.dataCount - 1) * sizeof(double)));
if (forward) {
memmove(&my.data[1], &my.data[0], sz);
memmove(&my.itemData[1], &my.itemData[0], sz);
my.data[0] = value;
} else {
memmove(&my.data[0], &my.data[1], sz);
memmove(&my.itemData[0], &my.itemData[1], sz);
my.data[my.dataCount - 1] = value;
}
if (my.dataCount < sampleHistory)
my.dataCount++;
}
void
Launch::addMetric(const QmcMetric &metric,
const SbColor &color,
int instance,
bool useSocks)
{
#ifdef PCP_DEBUG
if (pmDebug & DBG_TRACE_APPL1) {
cerr << "Launch::addMetric(1): Adding ";
metric.dump(cerr, true, instance);
cerr << " (" << _metricCount << ')' << endl;
}
#endif
QmcSource source = metric.context()->source();
QByteArray ba;
ba = metric.instName(instance).toLocal8Bit();
addMetric(metric.context()->handle(), source.source(), source.host(), metric.name(),
metric.hasInstances() == 0 ? NULL : ba.data(),
metric.desc(), color, metric.scale(), useSocks);
}
int
QmcContext::fetch(bool update)
{
int i, sts;
pmResult *result;
for (i = 0; i < my.metrics.size(); i++) {
QmcMetric *metric = my.metrics[i];
if (metric->status() < 0)
continue;
metric->shiftValues();
}
// Inform each indom that we are about to do a new fetch so any
// indom changes are now irrelevant
for (i = 0; i < my.indoms.size(); i++)
my.indoms[i]->newFetch();
sts = pmUseContext(my.context);
if (sts >= 0) {
for (i = 0; i < my.indoms.size(); i++) {
if (my.indoms[i]->diffProfile())
sts = my.indoms[i]->genProfile();
}
}
else if (pmDebug & DBG_TRACE_OPTFETCH) {
QTextStream cerr(stderr);
cerr << "QmcContext::fetch: Unable to switch to this context: "
<< pmErrStr(sts) << endl;
}
if (sts >= 0 && my.needReconnect) {
sts = pmReconnectContext(my.context);
if (sts >= 0) {
my.needReconnect = false;
if (pmDebug & DBG_TRACE_PMC) {
QTextStream cerr(stderr);
cerr << "QmcContext::fetch: Reconnected context \""
<< *my.source << endl;
}
}
else if (pmDebug & DBG_TRACE_PMC) {
QTextStream cerr(stderr);
cerr << "QmcContext::fetch: Reconnect failed: "
<< pmErrStr(sts) << endl;
}
}
if (sts >= 0 && my.pmids.size()) {
if (pmDebug & DBG_TRACE_OPTFETCH) {
QTextStream cerr(stderr);
cerr << "QmcContext::fetch: fetching context " << *this << endl;
}
sts = pmFetch(my.pmids.size(),
(pmID *)(my.pmids.toVector().data()), &result);
if (sts >= 0) {
my.previousTime = my.currentTime;
my.currentTime = result->timestamp;
my.delta = __pmtimevalSub(&my.currentTime, &my.previousTime);
for (i = 0; i < my.metrics.size(); i++) {
QmcMetric *metric = my.metrics[i];
if (metric->status() < 0)
continue;
Q_ASSERT((int)metric->idIndex() < result->numpmid);
metric->extractValues(result->vset[metric->idIndex()]);
}
pmFreeResult(result);
}
else {
if (pmDebug & DBG_TRACE_OPTFETCH) {
QTextStream cerr(stderr);
cerr << "QmcContext::fetch: pmFetch: " << pmErrStr(sts) << endl;
}
for (i = 0; i < my.metrics.size(); i++) {
QmcMetric *metric = my.metrics[i];
if (metric->status() < 0)
continue;
metric->setError(sts);
}
if (sts == PM_ERR_IPC || sts == PM_ERR_TIMEOUT)
my.needReconnect = true;
}
if (update) {
if (pmDebug & DBG_TRACE_OPTFETCH) {
QTextStream cerr(stderr);
cerr << "QmcContext::fetch: Updating metrics" << endl;
}
for (i = 0; i < my.metrics.size(); i++) {
QmcMetric *metric = my.metrics[i];
if (metric->status() < 0)
continue;
metric->update();
}
}
}
else if (pmDebug & DBG_TRACE_OPTFETCH) {
QTextStream cerr(stderr);
cerr << "QmcContext::fetch: nothing to fetch" << endl;
}
return sts;
}
static void
dumpHeader()
{
static bool fullOnce = false;
QmcMetric *metric;
bool instFlag = false;
QString noneStr = "none";
QString srcStr = "Source";
QString metricStr = "Metric";
QString instStr = "Inst";
QString normStr = "Normal";
QString unitStr = "Units";
QString columnStr = "Column";
const char *timeStr;
int m;
int i;
int c;
int v;
int p;
int len = 0;
if (niceFlag) {
struct timeval pos = { 0, 0 };
timeStr = dumpTime(pos);
len = strlen(timeStr);
}
if (fullFlag) {
fullOnce = true;
for (m = 0, v = 1; m < metrics.size(); m++) {
metric = metrics[m];
for (i = 0; i < metric->numValues(); i++, v++) {
cout << '[' << qSetFieldWidth(2) << v
<< qSetFieldWidth(0) << "] "
<< metric->spec(sourceFlag, true, i) << endl;
}
}
cout << endl;
}
if (fullOnce) {
if (timeFlag) {
if (len < columnStr.length()) {
columnStr.remove(len, columnStr.length() - len);
}
cout << qSetFieldWidth(len) << columnStr
<< qSetFieldWidth(0) << delimiter;
}
for (m = 0, v = 1; m < metrics.size(); m++) {
metric = metrics[m];
for (i = 0; i < metric->numValues(); i++) {
cout << qSetFieldWidth(width) << v << qSetFieldWidth(0);
if (v < numValues) {
cout << delimiter;
v++;
}
}
}
cout << endl;
}
if (niceFlag && sourceFlag) {
if (timeFlag) {
if (len < srcStr.length()) {
srcStr.remove(len, srcStr.length() - len);
}
cout << qSetFieldWidth(len) << srcStr
<< qSetFieldWidth(0) << delimiter;
}
for (m = 0, v = 1; m < metrics.size(); m++) {
metric = metrics[m];
QString const& str = metric->context()->source().host();
strncpy(buffer, (const char *)str.toAscii(), width);
buffer[width] = '\0';
for (i = 0; i < metric->numValues(); i++) {
cout << qSetFieldWidth(width) << buffer << qSetFieldWidth(0);
if (v < numValues) {
cout << delimiter;
v++;
}
}
}
cout << endl;
}
if (metricFlag || (sourceFlag && !niceFlag)) {
if (timeFlag) {
if (niceFlag) {
if (len < metricStr.length()) {
metricStr.remove(len, metricStr.length() - len);
}
cout << qSetFieldWidth(len) << metricStr << qSetFieldWidth(0);
cout << delimiter;
}
else
cout << "Time" << delimiter;
}
for (m = 0, v = 1; m < metrics.size(); m++) {
metric = metrics[m];
if (niceFlag && !instFlag && metric->hasInstances())
instFlag = true;
for (i = 0; i < metric->numValues(); i++) {
if (niceFlag) {
QString const &str = metric->spec(false, false, i);
p = str.length() - width;
if (p > 0) {
for (c = (p - 1 > 0 ? p - 1 : 0); c < str.length();
c++) {
if (str[c] == '.') {
c++;
break;
}
}
if (c < str.length())
cout << qSetFieldWidth(width)
<< ((const char *)str.toAscii() + c)
<< qSetFieldWidth(0);
else
cout << qSetFieldWidth(width)
<< ((const char *)str.toAscii() + p)
<< qSetFieldWidth(0);
}
else {
cout << qSetFieldWidth(width) << str
<< qSetFieldWidth(0);
}
}
else
cout << metric->spec(sourceFlag, true, i);
if (v < numValues) {
cout << delimiter;
v++;
}
}
}
cout << endl;
}
if (instFlag) {
if (timeFlag) {
if (niceFlag) {
if (len < instStr.length()) {
instStr.remove(len, instStr.length() - len);
}
cout << qSetFieldWidth(len) << instStr
<< qSetFieldWidth(0) << delimiter;
}
else {
cout << qSetFieldWidth(len) << errStr
<< qSetFieldWidth(0) << delimiter;
}
}
for (m = 0, v = 1; m < metrics.size(); m++) {
metric = metrics[m];
for (i = 0; i < metric->numValues(); i++) {
if (metric->hasInstances()) {
QString const &str = metric->instName(i);
strncpy(buffer, (const char *)str.toAscii(), width);
buffer[width] = '\0';
cout << qSetFieldWidth(width) << buffer
<< qSetFieldWidth(0);
}
else
cout << qSetFieldWidth(width) << "n/a"
<< qSetFieldWidth(0);
if (v < numValues) {
cout << delimiter;
v++;
}
}
}
cout << endl;
}
if (normFlag) {
if (timeFlag) {
if (niceFlag) {
if (len < normStr.length()) {
normStr.remove(len, normStr.length() - len);
}
cout << qSetFieldWidth(len) << normStr
<< qSetFieldWidth(0) << delimiter;
}
else
cout << errStr << delimiter;
}
for (m = 0, v = 1; m < metrics.size(); m++) {
metric = metrics[m];
for (i = 0; i < metric->numValues(); i++) {
if (shortFlag)
cout << qSetRealNumberPrecision(precision)
<< qSetFieldWidth(width)
<< metric->scale()
<< qSetFieldWidth(0);
else if (descFlag)
cout << qSetFieldWidth(width)
<< QmcMetric::formatNumber(metric->scale())
<< qSetFieldWidth(0);
else
cout << fixed
<< qSetRealNumberPrecision(precision)
<< qSetFieldWidth(width)
<< metric->scale()
<< qSetFieldWidth(0);
if (v < numValues) {
cout << delimiter;
v++;
}
}
}
cout << endl;
}
if (unitFlag) {
if (timeFlag) {
if (niceFlag) {
if (len < unitStr.length()) {
unitStr.remove(len, unitStr.length() - len);
}
cout << qSetFieldWidth(len) << unitStr
<< qSetFieldWidth(0) << delimiter;
}
else
cout << noneStr << delimiter;
}
for (m = 0, v = 1; m < metrics.size(); m++) {
metric = metrics[m];
QString const &str = (niceFlag ? metric->desc().shortUnits()
: metric->desc().units());
for (i = 0; i < metric->numValues(); i++) {
if (niceFlag)
if (str.length() > width)
cout << qSetFieldWidth(width)
<< ((const char *)str.toAscii() + str.length() - width)
<< qSetFieldWidth(0);
else
cout << qSetFieldWidth(width) << str
<< qSetFieldWidth(0);
else
cout << str;
if (v < numValues) {
cout << delimiter;
v++;
}
}
}
cout << endl;
}
}
