VictoriaMetrics/lib/protoparser/influx/stream/streamparser.go
Aliaksandr Valialkin 4770294732
lib/protoparser: substitute hybrid channel-based pools with plain sync.Pool
Using plain sync.Pool simplifies the code without increasing memory usage and CPU usage.
So it is better to use plain sync.Pool from readability and maintainability PoV.

This is a follow-up for 8942f290eb
2024-04-20 21:59:51 +02:00

267 lines
6.3 KiB
Go

package stream
import (
"bufio"
"flag"
"fmt"
"io"
"sync"
"time"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/flagutil"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/protoparser/common"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/protoparser/influx"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/writeconcurrencylimiter"
"github.com/VictoriaMetrics/metrics"
)
var (
maxLineSize = flagutil.NewBytes("influx.maxLineSize", 256*1024, "The maximum size in bytes for a single InfluxDB line during parsing")
trimTimestamp = flag.Duration("influxTrimTimestamp", time.Millisecond, "Trim timestamps for InfluxDB line protocol data to this duration. "+
"Minimum practical duration is 1ms. Higher duration (i.e. 1s) may be used for reducing disk space usage for timestamp data")
)
// Parse parses r with the given args and calls callback for the parsed rows.
//
// The callback can be called concurrently multiple times for streamed data from r.
//
// callback shouldn't hold rows after returning.
func Parse(r io.Reader, isGzipped bool, precision, db string, callback func(db string, rows []influx.Row) error) error {
wcr := writeconcurrencylimiter.GetReader(r)
defer writeconcurrencylimiter.PutReader(wcr)
r = wcr
if isGzipped {
zr, err := common.GetGzipReader(r)
if err != nil {
return fmt.Errorf("cannot read gzipped influx line protocol data: %w", err)
}
defer common.PutGzipReader(zr)
r = zr
}
tsMultiplier := int64(0)
switch precision {
case "ns":
tsMultiplier = 1e6
case "u", "us", "µ":
tsMultiplier = 1e3
case "ms":
tsMultiplier = 1
case "s":
tsMultiplier = -1e3
case "m":
tsMultiplier = -1e3 * 60
case "h":
tsMultiplier = -1e3 * 3600
}
ctx := getStreamContext(r)
defer putStreamContext(ctx)
for ctx.Read() {
uw := getUnmarshalWork()
uw.ctx = ctx
uw.callback = callback
uw.db = db
uw.tsMultiplier = tsMultiplier
uw.reqBuf, ctx.reqBuf = ctx.reqBuf, uw.reqBuf
ctx.wg.Add(1)
common.ScheduleUnmarshalWork(uw)
wcr.DecConcurrency()
}
ctx.wg.Wait()
if err := ctx.Error(); err != nil {
return err
}
return ctx.callbackErr
}
func (ctx *streamContext) Read() bool {
readCalls.Inc()
if ctx.err != nil || ctx.hasCallbackError() {
return false
}
ctx.reqBuf, ctx.tailBuf, ctx.err = common.ReadLinesBlockExt(ctx.br, ctx.reqBuf, ctx.tailBuf, maxLineSize.IntN())
if ctx.err != nil {
if ctx.err != io.EOF {
readErrors.Inc()
ctx.err = fmt.Errorf("cannot read influx line protocol data: %w", ctx.err)
}
return false
}
return true
}
var (
readCalls = metrics.NewCounter(`vm_protoparser_read_calls_total{type="influx"}`)
readErrors = metrics.NewCounter(`vm_protoparser_read_errors_total{type="influx"}`)
rowsRead = metrics.NewCounter(`vm_protoparser_rows_read_total{type="influx"}`)
)
type streamContext struct {
br *bufio.Reader
reqBuf []byte
tailBuf []byte
err error
wg sync.WaitGroup
callbackErrLock sync.Mutex
callbackErr error
}
func (ctx *streamContext) Error() error {
if ctx.err == io.EOF {
return nil
}
return ctx.err
}
func (ctx *streamContext) hasCallbackError() bool {
ctx.callbackErrLock.Lock()
ok := ctx.callbackErr != nil
ctx.callbackErrLock.Unlock()
return ok
}
func (ctx *streamContext) reset() {
ctx.br.Reset(nil)
ctx.reqBuf = ctx.reqBuf[:0]
ctx.tailBuf = ctx.tailBuf[:0]
ctx.err = nil
ctx.callbackErr = nil
}
func getStreamContext(r io.Reader) *streamContext {
if v := streamContextPool.Get(); v != nil {
ctx := v.(*streamContext)
ctx.br.Reset(r)
return ctx
}
return &streamContext{
br: bufio.NewReaderSize(r, 64*1024),
}
}
func putStreamContext(ctx *streamContext) {
ctx.reset()
streamContextPool.Put(ctx)
}
var streamContextPool sync.Pool
type unmarshalWork struct {
rows influx.Rows
ctx *streamContext
callback func(db string, rows []influx.Row) error
db string
tsMultiplier int64
reqBuf []byte
}
func (uw *unmarshalWork) reset() {
uw.rows.Reset()
uw.ctx = nil
uw.callback = nil
uw.db = ""
uw.tsMultiplier = 0
uw.reqBuf = uw.reqBuf[:0]
}
func (uw *unmarshalWork) runCallback(rows []influx.Row) {
ctx := uw.ctx
if err := uw.callback(uw.db, rows); err != nil {
ctx.callbackErrLock.Lock()
if ctx.callbackErr == nil {
ctx.callbackErr = fmt.Errorf("error when processing imported data: %w", err)
}
ctx.callbackErrLock.Unlock()
}
ctx.wg.Done()
}
// Unmarshal implements common.UnmarshalWork
func (uw *unmarshalWork) Unmarshal() {
uw.rows.Unmarshal(bytesutil.ToUnsafeString(uw.reqBuf))
rows := uw.rows.Rows
rowsRead.Add(len(rows))
// Adjust timestamps according to uw.tsMultiplier
currentTs := time.Now().UnixNano() / 1e6
tsMultiplier := uw.tsMultiplier
if tsMultiplier == 0 {
// Default precision is 'ns'. See https://docs.influxdata.com/influxdb/v1.7/write_protocols/line_protocol_tutorial/#timestamp
// But it can be in ns, us, ms or s depending on the number of digits in practice.
for i := range rows {
tsPtr := &rows[i].Timestamp
*tsPtr = detectTimestamp(*tsPtr, currentTs)
}
} else if tsMultiplier >= 1 {
for i := range rows {
row := &rows[i]
if row.Timestamp == 0 {
row.Timestamp = currentTs
} else {
row.Timestamp /= tsMultiplier
}
}
} else if tsMultiplier < 0 {
tsMultiplier = -tsMultiplier
currentTs -= currentTs % tsMultiplier
for i := range rows {
row := &rows[i]
if row.Timestamp == 0 {
row.Timestamp = currentTs
} else {
row.Timestamp *= tsMultiplier
}
}
}
// Trim timestamps if required.
if tsTrim := trimTimestamp.Milliseconds(); tsTrim > 1 {
for i := range rows {
row := &rows[i]
row.Timestamp -= row.Timestamp % tsTrim
}
}
uw.runCallback(rows)
putUnmarshalWork(uw)
}
func getUnmarshalWork() *unmarshalWork {
v := unmarshalWorkPool.Get()
if v == nil {
return &unmarshalWork{}
}
return v.(*unmarshalWork)
}
func putUnmarshalWork(uw *unmarshalWork) {
uw.reset()
unmarshalWorkPool.Put(uw)
}
var unmarshalWorkPool sync.Pool
func detectTimestamp(ts, currentTs int64) int64 {
if ts == 0 {
return currentTs
}
if ts >= 1e17 {
// convert nanoseconds to milliseconds
return ts / 1e6
}
if ts >= 1e14 {
// convert microseconds to milliseconds
return ts / 1e3
}
if ts >= 1e11 {
// the ts is in milliseconds
return ts
}
// convert seconds to milliseconds
return ts * 1e3
}