VictoriaMetrics/lib/streamaggr/rate.go
Aliaksandr Valialkin 29d526e20a
lib/streamaggr: remove resetState arg from aggrState.flushState()
The resetState arg was used only for the BenchmarkAggregatorsFlushInternalSerial benchmark.
This benchmark was testing aggregate state flush performance by keeping the same state across flushes.
The benhmark didn't reflect the performance and scalability of stream aggregation in production,
while it led to non-trivial code changes related to resetState arg handling.

So let's drop the benchmark together with all the code related to resetState handling,
in order to simplify the code at lib/streamaggr a bit.

Thanks to @AndrewChubatiuk for the original idea at https://github.com/VictoriaMetrics/VictoriaMetrics/pull/6314
2024-08-07 11:46:49 +02:00

183 lines
4 KiB
Go

package streamaggr
import (
"sync"
"time"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/fasttime"
)
// rateAggrState calculates output=rate_avg and rate_sum, e.g. the average per-second increase rate for counter metrics.
type rateAggrState struct {
m sync.Map
// isAvg is set to true if rate_avg() must be calculated instead of rate_sum().
isAvg bool
// Time series state is dropped if no new samples are received during stalenessSecs.
stalenessSecs uint64
}
type rateStateValue struct {
mu sync.Mutex
lastValues map[string]rateLastValueState
deleteDeadline uint64
deleted bool
}
type rateLastValueState struct {
value float64
timestamp int64
deleteDeadline uint64
// increase stores cumulative increase for the current time series on the current aggregation interval
increase float64
// prevTimestamp is the timestamp of the last registered sample in the previous aggregation interval
prevTimestamp int64
}
func newRateAggrState(stalenessInterval time.Duration, isAvg bool) *rateAggrState {
stalenessSecs := roundDurationToSecs(stalenessInterval)
return &rateAggrState{
isAvg: isAvg,
stalenessSecs: stalenessSecs,
}
}
func (as *rateAggrState) pushSamples(samples []pushSample) {
currentTime := fasttime.UnixTimestamp()
deleteDeadline := currentTime + as.stalenessSecs
for i := range samples {
s := &samples[i]
inputKey, outputKey := getInputOutputKey(s.key)
again:
v, ok := as.m.Load(outputKey)
if !ok {
// The entry is missing in the map. Try creating it.
v = &rateStateValue{
lastValues: make(map[string]rateLastValueState),
}
outputKey = bytesutil.InternString(outputKey)
vNew, loaded := as.m.LoadOrStore(outputKey, v)
if loaded {
// Use the entry created by a concurrent goroutine.
v = vNew
}
}
sv := v.(*rateStateValue)
sv.mu.Lock()
deleted := sv.deleted
if !deleted {
lv, ok := sv.lastValues[inputKey]
if ok {
if s.timestamp < lv.timestamp {
// Skip out of order sample
sv.mu.Unlock()
continue
}
if s.value >= lv.value {
lv.increase += s.value - lv.value
} else {
// counter reset
lv.increase += s.value
}
} else {
lv.prevTimestamp = s.timestamp
}
lv.value = s.value
lv.timestamp = s.timestamp
lv.deleteDeadline = deleteDeadline
inputKey = bytesutil.InternString(inputKey)
sv.lastValues[inputKey] = lv
sv.deleteDeadline = deleteDeadline
}
sv.mu.Unlock()
if deleted {
// The entry has been deleted by the concurrent call to flushState
// Try obtaining and updating the entry again.
goto again
}
}
}
func (as *rateAggrState) flushState(ctx *flushCtx) {
currentTime := fasttime.UnixTimestamp()
suffix := as.getSuffix()
as.removeOldEntries(currentTime)
m := &as.m
m.Range(func(k, v any) bool {
sv := v.(*rateStateValue)
sv.mu.Lock()
lvs := sv.lastValues
sumRate := 0.0
countSeries := 0
for k1, lv := range lvs {
d := float64(lv.timestamp-lv.prevTimestamp) / 1000
if d > 0 {
sumRate += lv.increase / d
countSeries++
}
lv.prevTimestamp = lv.timestamp
lv.increase = 0
lvs[k1] = lv
}
deleted := sv.deleted
sv.mu.Unlock()
if countSeries == 0 || deleted {
// Nothing to update
return true
}
result := sumRate
if as.isAvg {
result /= float64(countSeries)
}
key := k.(string)
ctx.appendSeries(key, suffix, result)
return true
})
}
func (as *rateAggrState) getSuffix() string {
if as.isAvg {
return "rate_avg"
}
return "rate_sum"
}
func (as *rateAggrState) removeOldEntries(currentTime uint64) {
m := &as.m
m.Range(func(k, v any) bool {
sv := v.(*rateStateValue)
sv.mu.Lock()
if currentTime > sv.deleteDeadline {
// Mark the current entry as deleted
sv.deleted = true
sv.mu.Unlock()
m.Delete(k)
return true
}
// Delete outdated entries in sv.lastValues
lvs := sv.lastValues
for k1, lv := range lvs {
if currentTime > lv.deleteDeadline {
delete(lvs, k1)
}
}
sv.mu.Unlock()
return true
})
}