func graphite(c *GraphiteConfig) error {
now := time.Now().Unix()
du := float64(c.DurationUnit)
conn, err := net.DialTCP("tcp", nil, c.Addr)
if nil != err {
return err
}
defer conn.Close()
w := bufio.NewWriter(conn)
c.Registry.Each(func(name string, i interface{}) {
k := c.Prefix + name
switch metric := i.(type) {
case Counter:
fmt.Fprintf(w, "%s %d %d\n", m2.Counter(k, ""), metric.Count(), now)
case Gauge:
fmt.Fprintf(w, "%s %d %d\n", m2.Gauge(k, ""), metric.Value(), now)
case GaugeFloat64:
fmt.Fprintf(w, "%s %f %d\n", m2.Gauge(k, ""), metric.Value(), now)
case Histogram:
h := metric.Snapshot()
ps := h.Percentiles(c.Percentiles)
fmt.Fprintf(w, "%s %d %d\n", m2.CountMetric(k, ""), h.Count(), now)
fmt.Fprintf(w, "%s %d %d\n", m2.Min(k, "", "", ""), h.Min(), now)
fmt.Fprintf(w, "%s %d %d\n", m2.Max(k, "", "", ""), h.Max(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "", "", ""), h.Mean(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Std(k, "", "", ""), h.StdDev(), now)
for psIdx, psKey := range c.Percentiles {
pct := strings.Replace(strconv.FormatFloat(psKey*100.0, 'f', -1, 64), ".", "", 1)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Max(k, "", pct, ""), ps[psIdx], now)
}
case Meter:
m := metric.Snapshot()
fmt.Fprintf(w, "%s %d %d\n", m2.CountMetric(k, ""), m.Count(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "1m", "", "60"), m.Rate1(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "5m", "", "300"), m.Rate5(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "15m", "", "900"), m.Rate15(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "start", "", "start"), m.RateMean(), now)
case Timer:
t := metric.Snapshot()
ps := t.Percentiles(c.Percentiles)
fmt.Fprintf(w, "%s %d %d\n", m2.CountMetric(k, ""), t.Count(), now)
fmt.Fprintf(w, "%s %d %d\n", m2.Min(k, "", "", ""), t.Min()/int64(du), now)
fmt.Fprintf(w, "%s %d %d\n", m2.Max(k, "", "", ""), t.Max()/int64(du), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "", "", ""), t.Mean()/du, now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Std(k, "", "", ""), t.StdDev()/du, now)
for psIdx, psKey := range c.Percentiles {
pct := strings.Replace(strconv.FormatFloat(psKey*100.0, 'f', -1, 64), ".", "", 1)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Max(k, "", pct, ""), ps[psIdx], now)
}
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "1m", "", "60"), t.Rate1(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "5m", "", "300"), t.Rate5(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "15m", "", "900"), t.Rate15(), now)
fmt.Fprintf(w, "%s %.2f %d\n", m2.Mean(k, "start", "", "start"), t.RateMean(), now)
}
w.Flush()
})
return nil
}
// Process computes the outbound metrics for timers and puts them in the buffer
func (timers *Timers) Process(buf []byte, now int64, interval int) ([]byte, int64) {
// these are the metrics that get exposed:
// count estimate of original amount of metrics sent, by dividing received by samplerate
// count_ps same but per second
// lower
// mean // arithmetic mean
// mean_<pct> // arithmetic mean of values below <pct> percentile
// median
// std standard deviation
// sum
// sum_90
// upper
// upper_90 / lower_90
var num int64
for u, t := range timers.Values {
if len(t.Points) > 0 {
seen := len(t.Points)
count := t.Amount_submitted
count_ps := float64(count) / float64(interval)
num++
sort.Sort(t.Points)
min := t.Points[0]
max := t.Points[seen-1]
sum := float64(0)
for _, value := range t.Points {
sum += value
}
mean := float64(sum) / float64(seen)
sumOfDiffs := float64(0)
for _, value := range t.Points {
sumOfDiffs += math.Pow((float64(value) - mean), 2)
}
stddev := math.Sqrt(sumOfDiffs / float64(seen))
mid := seen / 2
var median float64
if seen%2 == 1 {
median = t.Points[mid]
} else {
median = (t.Points[mid-1] + t.Points[mid]) / 2
}
var cumulativeValues Float64Slice
cumulativeValues = make(Float64Slice, seen, seen)
cumulativeValues[0] = t.Points[0]
for i := 1; i < seen; i++ {
cumulativeValues[i] = t.Points[i] + cumulativeValues[i-1]
}
maxAtThreshold := max
sum_pct := sum
mean_pct := mean
for _, pct := range timers.pctls {
if seen > 1 {
var abs float64
if pct.float >= 0 {
abs = pct.float
} else {
abs = 100 + pct.float
}
// poor man's math.Round(x):
// math.Floor(x + 0.5)
indexOfPerc := int(math.Floor(((abs / 100.0) * float64(seen)) + 0.5))
if pct.float >= 0 {
sum_pct = cumulativeValues[indexOfPerc-1]
maxAtThreshold = t.Points[indexOfPerc-1]
} else {
maxAtThreshold = t.Points[indexOfPerc]
sum_pct = cumulativeValues[seen-1] - cumulativeValues[seen-indexOfPerc-1]
}
mean_pct = float64(sum_pct) / float64(indexOfPerc)
}
var pctstr string
var fn func(metric_in, prefix, percentile, timespec string) string
if pct.float >= 0 {
pctstr = pct.str
fn = m20.Max
} else {
pctstr = pct.str[1:]
fn = m20.Min
}
buf = common.WriteFloat64(buf, []byte(fn(u, timers.prefix, pctstr, "")), maxAtThreshold, now)
buf = common.WriteFloat64(buf, []byte(m20.Mean(u, timers.prefix, pctstr, "")), mean_pct, now)
buf = common.WriteFloat64(buf, []byte(m20.Sum(u, timers.prefix, pctstr, "")), sum_pct, now)
}
buf = common.WriteFloat64(buf, []byte(m20.Mean(u, timers.prefix, "", "")), mean, now)
buf = common.WriteFloat64(buf, []byte(m20.Median(u, timers.prefix, "", "")), median, now)
buf = common.WriteFloat64(buf, []byte(m20.Std(u, timers.prefix, "", "")), stddev, now)
buf = common.WriteFloat64(buf, []byte(m20.Sum(u, timers.prefix, "", "")), sum, now)
buf = common.WriteFloat64(buf, []byte(m20.Max(u, timers.prefix, "", "")), max, now)
buf = common.WriteFloat64(buf, []byte(m20.Min(u, timers.prefix, "", "")), min, now)
buf = common.WriteInt64(buf, []byte(m20.CountPckt(u, timers.prefix)), count, now)
buf = common.WriteFloat64(buf, []byte(m20.RatePckt(u, timers.prefix)), count_ps, now)
}
}
return buf, num
}
