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package promscrape
import (
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"flag"
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"fmt"
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"math"
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"math/bits"
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"strconv"
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"strings"
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"sync"
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"time"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/leveledbytebufferpool"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/logger"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/promauth"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/prompbmarshal"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/promrelabel"
parser "github.com/VictoriaMetrics/VictoriaMetrics/lib/protoparser/prometheus"
"github.com/VictoriaMetrics/metrics"
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xxhash "github.com/cespare/xxhash/v2"
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)
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var (
suppressScrapeErrors = flag . Bool ( "promscrape.suppressScrapeErrors" , false , "Whether to suppress scrape errors logging. " +
"The last error for each target is always available at '/targets' page even if scrape errors logging is suppressed" )
)
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// ScrapeWork represents a unit of work for scraping Prometheus metrics.
type ScrapeWork struct {
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// Unique ID for the ScrapeWork.
ID uint64
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// Full URL (including query args) for the scrape.
ScrapeURL string
// Interval for scraping the ScrapeURL.
ScrapeInterval time . Duration
// Timeout for scraping the ScrapeURL.
ScrapeTimeout time . Duration
// How to deal with conflicting labels.
// See https://prometheus.io/docs/prometheus/latest/configuration/configuration/#scrape_config
HonorLabels bool
// How to deal with scraped timestamps.
// See https://prometheus.io/docs/prometheus/latest/configuration/configuration/#scrape_config
HonorTimestamps bool
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// OriginalLabels contains original labels before relabeling.
//
// These labels are needed for relabeling troubleshooting at /targets page.
OriginalLabels [ ] prompbmarshal . Label
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// Labels to add to the scraped metrics.
//
// The list contains at least the following labels according to https://prometheus.io/docs/prometheus/latest/configuration/configuration/#relabel_config
//
// * job
// * __address__
// * __scheme__
// * __metrics_path__
// * __param_<name>
// * __meta_*
// * user-defined labels set via `relabel_configs` section in `scrape_config`
//
// See also https://prometheus.io/docs/concepts/jobs_instances/
Labels [ ] prompbmarshal . Label
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// Auth config
AuthConfig * promauth . Config
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// Optional `metric_relabel_configs`.
MetricRelabelConfigs [ ] promrelabel . ParsedRelabelConfig
// The maximum number of metrics to scrape after relabeling.
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SampleLimit int
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// Whether to disable response compression when querying ScrapeURL.
DisableCompression bool
// Whether to disable HTTP keep-alive when querying ScrapeURL.
DisableKeepAlive bool
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// Whether to parse target responses in a streaming manner.
StreamParse bool
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// The original 'job_name'
jobNameOriginal string
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}
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// key returns unique identifier for the given sw.
//
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// it can be used for comparing for equality for two ScrapeWork objects.
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func ( sw * ScrapeWork ) key ( ) string {
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// Do not take into account OriginalLabels.
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key := fmt . Sprintf ( "ScrapeURL=%s, ScrapeInterval=%s, ScrapeTimeout=%s, HonorLabels=%v, HonorTimestamps=%v, Labels=%s, " +
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"AuthConfig=%s, MetricRelabelConfigs=%s, SampleLimit=%d, DisableCompression=%v, DisableKeepAlive=%v, StreamParse=%v" ,
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sw . ScrapeURL , sw . ScrapeInterval , sw . ScrapeTimeout , sw . HonorLabels , sw . HonorTimestamps , sw . LabelsString ( ) ,
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sw . AuthConfig . String ( ) , sw . metricRelabelConfigsString ( ) , sw . SampleLimit , sw . DisableCompression , sw . DisableKeepAlive , sw . StreamParse )
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return key
}
func ( sw * ScrapeWork ) metricRelabelConfigsString ( ) string {
var sb strings . Builder
for _ , prc := range sw . MetricRelabelConfigs {
fmt . Fprintf ( & sb , "%s" , prc . String ( ) )
}
return sb . String ( )
}
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// Job returns job for the ScrapeWork
func ( sw * ScrapeWork ) Job ( ) string {
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return promrelabel . GetLabelValueByName ( sw . Labels , "job" )
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}
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// LabelsString returns labels in Prometheus format for the given sw.
func ( sw * ScrapeWork ) LabelsString ( ) string {
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labelsFinalized := promrelabel . FinalizeLabels ( nil , sw . Labels )
return promLabelsString ( labelsFinalized )
}
func promLabelsString ( labels [ ] prompbmarshal . Label ) string {
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// Calculate the required memory for storing serialized labels.
n := 2 // for `{...}`
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for _ , label := range labels {
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n += len ( label . Name ) + len ( label . Value )
n += 4 // for `="...",`
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}
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b := make ( [ ] byte , 0 , n )
b = append ( b , '{' )
for i , label := range labels {
b = append ( b , label . Name ... )
b = append ( b , '=' )
b = strconv . AppendQuote ( b , label . Value )
if i + 1 < len ( labels ) {
b = append ( b , ',' )
}
}
b = append ( b , '}' )
return bytesutil . ToUnsafeString ( b )
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}
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type scrapeWork struct {
// Config for the scrape.
Config ScrapeWork
// ReadData is called for reading the data.
ReadData func ( dst [ ] byte ) ( [ ] byte , error )
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// GetStreamReader is called if Config.StreamParse is set.
GetStreamReader func ( ) ( * streamReader , error )
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// PushData is called for pushing collected data.
PushData func ( wr * prompbmarshal . WriteRequest )
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// ScrapeGroup is name of ScrapeGroup that
// scrapeWork belongs to
ScrapeGroup string
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tmpRow parser . Row
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// the seriesMap, seriesAdded and labelsHashBuf are used for fast calculation of `scrape_series_added` metric.
seriesMap map [ uint64 ] struct { }
seriesAdded int
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labelsHashBuf [ ] byte
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// prevBodyLen contains the previous response body length for the given scrape work.
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// It is used as a hint in order to reduce memory usage for body buffers.
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prevBodyLen int
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// prevRowsLen contains the number rows scraped during the previous scrape.
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// It is used as a hint in order to reduce memory usage when parsing scrape responses.
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prevRowsLen int
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}
func ( sw * scrapeWork ) run ( stopCh <- chan struct { } ) {
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// Calculate start time for the first scrape from ScrapeURL and labels.
// This should spread load when scraping many targets with different
// scrape urls and labels.
// This also makes consistent scrape times across restarts
// for a target with the same ScrapeURL and labels.
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scrapeInterval := sw . Config . ScrapeInterval
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key := fmt . Sprintf ( "ScrapeURL=%s, Labels=%s" , sw . Config . ScrapeURL , sw . Config . LabelsString ( ) )
h := uint32 ( xxhash . Sum64 ( [ ] byte ( key ) ) )
randSleep := uint64 ( float64 ( scrapeInterval ) * ( float64 ( h ) / ( 1 << 32 ) ) )
sleepOffset := uint64 ( time . Now ( ) . UnixNano ( ) ) % uint64 ( scrapeInterval )
if randSleep < sleepOffset {
randSleep += uint64 ( scrapeInterval )
}
randSleep -= sleepOffset
timer := time . NewTimer ( time . Duration ( randSleep ) )
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var timestamp int64
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var ticker * time . Ticker
select {
case <- stopCh :
timer . Stop ( )
return
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case <- timer . C :
ticker = time . NewTicker ( scrapeInterval )
timestamp = time . Now ( ) . UnixNano ( ) / 1e6
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sw . scrapeAndLogError ( timestamp , timestamp )
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}
defer ticker . Stop ( )
for {
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timestamp += scrapeInterval . Milliseconds ( )
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select {
case <- stopCh :
return
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case tt := <- ticker . C :
t := tt . UnixNano ( ) / 1e6
if d := math . Abs ( float64 ( t - timestamp ) ) ; d > 0 && d / float64 ( scrapeInterval . Milliseconds ( ) ) > 0.1 {
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// Too big jitter. Adjust timestamp
timestamp = t
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}
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sw . scrapeAndLogError ( timestamp , t )
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}
}
}
func ( sw * scrapeWork ) logError ( s string ) {
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if ! * suppressScrapeErrors {
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logger . ErrorfSkipframes ( 1 , "error when scraping %q from job %q with labels %s: %s; " +
"scrape errors can be disabled by -promscrape.suppressScrapeErrors command-line flag" ,
sw . Config . ScrapeURL , sw . Config . Job ( ) , sw . Config . LabelsString ( ) , s )
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}
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}
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func ( sw * scrapeWork ) scrapeAndLogError ( scrapeTimestamp , realTimestamp int64 ) {
if err := sw . scrapeInternal ( scrapeTimestamp , realTimestamp ) ; err != nil && ! * suppressScrapeErrors {
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logger . Errorf ( "error when scraping %q from job %q with labels %s: %s" , sw . Config . ScrapeURL , sw . Config . Job ( ) , sw . Config . LabelsString ( ) , err )
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}
}
var (
scrapeDuration = metrics . NewHistogram ( "vm_promscrape_scrape_duration_seconds" )
scrapeResponseSize = metrics . NewHistogram ( "vm_promscrape_scrape_response_size_bytes" )
scrapedSamples = metrics . NewHistogram ( "vm_promscrape_scraped_samples" )
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scrapesSkippedBySampleLimit = metrics . NewCounter ( "vm_promscrape_scrapes_skipped_by_sample_limit_total" )
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scrapesFailed = metrics . NewCounter ( "vm_promscrape_scrapes_failed_total" )
pushDataDuration = metrics . NewHistogram ( "vm_promscrape_push_data_duration_seconds" )
)
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func ( sw * scrapeWork ) scrapeInternal ( scrapeTimestamp , realTimestamp int64 ) error {
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if * streamParse || sw . Config . StreamParse {
// Read data from scrape targets in streaming manner.
// This case is optimized for targets exposing millions and more of metrics per target.
return sw . scrapeStream ( scrapeTimestamp , realTimestamp )
}
// Common case: read all the data from scrape target to memory (body) and then process it.
// This case should work more optimally for than stream parse code above for common case when scrape target exposes
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// up to a few thousand metrics.
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body := leveledbytebufferpool . Get ( sw . prevBodyLen )
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var err error
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body . B , err = sw . ReadData ( body . B [ : 0 ] )
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endTimestamp := time . Now ( ) . UnixNano ( ) / 1e6
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duration := float64 ( endTimestamp - realTimestamp ) / 1e3
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scrapeDuration . Update ( duration )
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scrapeResponseSize . Update ( float64 ( len ( body . B ) ) )
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up := 1
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wc := writeRequestCtxPool . Get ( sw . prevRowsLen )
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if err != nil {
up = 0
scrapesFailed . Inc ( )
} else {
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bodyString := bytesutil . ToUnsafeString ( body . B )
wc . rows . UnmarshalWithErrLogger ( bodyString , sw . logError )
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}
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srcRows := wc . rows . Rows
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samplesScraped := len ( srcRows )
scrapedSamples . Update ( float64 ( samplesScraped ) )
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if sw . Config . SampleLimit > 0 && samplesScraped > sw . Config . SampleLimit {
srcRows = srcRows [ : 0 ]
up = 0
scrapesSkippedBySampleLimit . Inc ( )
}
samplesPostRelabeling := 0
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for i := range srcRows {
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sw . addRowToTimeseries ( wc , & srcRows [ i ] , scrapeTimestamp , true )
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if len ( wc . labels ) > 40000 {
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// Limit the maximum size of wc.writeRequest.
// This should reduce memory usage when scraping targets with millions of metrics and/or labels.
// For example, when scraping /federate handler from Prometheus - see https://prometheus.io/docs/prometheus/latest/federation/
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samplesPostRelabeling += len ( wc . writeRequest . Timeseries )
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sw . updateSeriesAdded ( wc )
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startTime := time . Now ( )
sw . PushData ( & wc . writeRequest )
pushDataDuration . UpdateDuration ( startTime )
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wc . resetNoRows ( )
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}
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}
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samplesPostRelabeling += len ( wc . writeRequest . Timeseries )
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sw . updateSeriesAdded ( wc )
seriesAdded := sw . finalizeSeriesAdded ( samplesPostRelabeling )
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sw . addAutoTimeseries ( wc , "up" , float64 ( up ) , scrapeTimestamp )
sw . addAutoTimeseries ( wc , "scrape_duration_seconds" , duration , scrapeTimestamp )
sw . addAutoTimeseries ( wc , "scrape_samples_scraped" , float64 ( samplesScraped ) , scrapeTimestamp )
sw . addAutoTimeseries ( wc , "scrape_samples_post_metric_relabeling" , float64 ( samplesPostRelabeling ) , scrapeTimestamp )
sw . addAutoTimeseries ( wc , "scrape_series_added" , float64 ( seriesAdded ) , scrapeTimestamp )
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startTime := time . Now ( )
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sw . PushData ( & wc . writeRequest )
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pushDataDuration . UpdateDuration ( startTime )
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sw . prevRowsLen = samplesScraped
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wc . reset ( )
writeRequestCtxPool . Put ( wc )
// body must be released only after wc is released, since wc refers to body.
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sw . prevBodyLen = len ( body . B )
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leveledbytebufferpool . Put ( body )
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tsmGlobal . Update ( & sw . Config , sw . ScrapeGroup , up == 1 , realTimestamp , int64 ( duration * 1000 ) , err )
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return err
}
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func ( sw * scrapeWork ) scrapeStream ( scrapeTimestamp , realTimestamp int64 ) error {
sr , err := sw . GetStreamReader ( )
if err != nil {
return fmt . Errorf ( "cannot read data: %s" , err )
}
samplesScraped := 0
samplesPostRelabeling := 0
wc := writeRequestCtxPool . Get ( sw . prevRowsLen )
var mu sync . Mutex
err = parser . ParseStream ( sr , scrapeTimestamp , false , func ( rows [ ] parser . Row ) error {
mu . Lock ( )
defer mu . Unlock ( )
samplesScraped += len ( rows )
for i := range rows {
sw . addRowToTimeseries ( wc , & rows [ i ] , scrapeTimestamp , true )
}
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// Push the collected rows to sw before returning from the callback, since they cannot be held
// after returning from the callback - this will result in data race.
// See https://github.com/VictoriaMetrics/VictoriaMetrics/issues/825#issuecomment-723198247
samplesPostRelabeling += len ( wc . writeRequest . Timeseries )
sw . updateSeriesAdded ( wc )
startTime := time . Now ( )
sw . PushData ( & wc . writeRequest )
pushDataDuration . UpdateDuration ( startTime )
wc . resetNoRows ( )
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return nil
} )
scrapedSamples . Update ( float64 ( samplesScraped ) )
endTimestamp := time . Now ( ) . UnixNano ( ) / 1e6
duration := float64 ( endTimestamp - realTimestamp ) / 1e3
scrapeDuration . Update ( duration )
scrapeResponseSize . Update ( float64 ( sr . bytesRead ) )
sr . MustClose ( )
up := 1
if err != nil {
if samplesScraped == 0 {
up = 0
}
scrapesFailed . Inc ( )
}
seriesAdded := sw . finalizeSeriesAdded ( samplesPostRelabeling )
sw . addAutoTimeseries ( wc , "up" , float64 ( up ) , scrapeTimestamp )
sw . addAutoTimeseries ( wc , "scrape_duration_seconds" , duration , scrapeTimestamp )
sw . addAutoTimeseries ( wc , "scrape_samples_scraped" , float64 ( samplesScraped ) , scrapeTimestamp )
sw . addAutoTimeseries ( wc , "scrape_samples_post_metric_relabeling" , float64 ( samplesPostRelabeling ) , scrapeTimestamp )
sw . addAutoTimeseries ( wc , "scrape_series_added" , float64 ( seriesAdded ) , scrapeTimestamp )
startTime := time . Now ( )
sw . PushData ( & wc . writeRequest )
pushDataDuration . UpdateDuration ( startTime )
sw . prevRowsLen = len ( wc . rows . Rows )
wc . reset ( )
writeRequestCtxPool . Put ( wc )
tsmGlobal . Update ( & sw . Config , sw . ScrapeGroup , up == 1 , realTimestamp , int64 ( duration * 1000 ) , err )
return nil
}
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// leveledWriteRequestCtxPool allows reducing memory usage when writeRequesCtx
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// structs contain mixed number of labels.
//
// Its logic has been copied from leveledbytebufferpool.
type leveledWriteRequestCtxPool struct {
pools [ 30 ] sync . Pool
}
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func ( lwp * leveledWriteRequestCtxPool ) Get ( rowsCapacity int ) * writeRequestCtx {
id , capacityNeeded := lwp . getPoolIDAndCapacity ( rowsCapacity )
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for i := 0 ; i < 2 ; i ++ {
if id < 0 || id >= len ( lwp . pools ) {
break
}
if v := lwp . pools [ id ] . Get ( ) ; v != nil {
return v . ( * writeRequestCtx )
}
id ++
}
return & writeRequestCtx {
labels : make ( [ ] prompbmarshal . Label , 0 , capacityNeeded ) ,
}
}
func ( lwp * leveledWriteRequestCtxPool ) Put ( wc * writeRequestCtx ) {
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capacity := cap ( wc . rows . Rows )
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id , _ := lwp . getPoolIDAndCapacity ( capacity )
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wc . reset ( )
lwp . pools [ id ] . Put ( wc )
}
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func ( lwp * leveledWriteRequestCtxPool ) getPoolIDAndCapacity ( size int ) ( int , int ) {
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size --
if size < 0 {
size = 0
}
size >>= 3
id := bits . Len ( uint ( size ) )
if id > len ( lwp . pools ) {
id = len ( lwp . pools ) - 1
}
return id , ( 1 << ( id + 3 ) )
}
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type writeRequestCtx struct {
rows parser . Rows
writeRequest prompbmarshal . WriteRequest
labels [ ] prompbmarshal . Label
samples [ ] prompbmarshal . Sample
}
func ( wc * writeRequestCtx ) reset ( ) {
wc . rows . Reset ( )
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wc . resetNoRows ( )
}
func ( wc * writeRequestCtx ) resetNoRows ( ) {
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prompbmarshal . ResetWriteRequest ( & wc . writeRequest )
wc . labels = wc . labels [ : 0 ]
wc . samples = wc . samples [ : 0 ]
}
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var writeRequestCtxPool leveledWriteRequestCtxPool
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func ( sw * scrapeWork ) updateSeriesAdded ( wc * writeRequestCtx ) {
if sw . seriesMap == nil {
sw . seriesMap = make ( map [ uint64 ] struct { } , len ( wc . writeRequest . Timeseries ) )
}
m := sw . seriesMap
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for _ , ts := range wc . writeRequest . Timeseries {
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h := sw . getLabelsHash ( ts . Labels )
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if _ , ok := m [ h ] ; ! ok {
m [ h ] = struct { } { }
sw . seriesAdded ++
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}
}
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}
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func ( sw * scrapeWork ) finalizeSeriesAdded ( lastScrapeSize int ) int {
seriesAdded := sw . seriesAdded
sw . seriesAdded = 0
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if len ( sw . seriesMap ) > 4 * lastScrapeSize {
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// Reset seriesMap, since it occupies more than 4x metrics collected during the last scrape.
sw . seriesMap = make ( map [ uint64 ] struct { } , lastScrapeSize )
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}
return seriesAdded
}
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func ( sw * scrapeWork ) getLabelsHash ( labels [ ] prompbmarshal . Label ) uint64 {
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// It is OK if there will be hash collisions for distinct sets of labels,
// since the accuracy for `scrape_series_added` metric may be lower than 100%.
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b := sw . labelsHashBuf [ : 0 ]
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for _ , label := range labels {
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b = append ( b , label . Name ... )
b = append ( b , label . Value ... )
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}
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sw . labelsHashBuf = b
return xxhash . Sum64 ( b )
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}
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// addAutoTimeseries adds automatically generated time series with the given name, value and timestamp.
//
// See https://prometheus.io/docs/concepts/jobs_instances/#automatically-generated-labels-and-time-series
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func ( sw * scrapeWork ) addAutoTimeseries ( wc * writeRequestCtx , name string , value float64 , timestamp int64 ) {
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sw . tmpRow . Metric = name
sw . tmpRow . Tags = nil
sw . tmpRow . Value = value
sw . tmpRow . Timestamp = timestamp
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sw . addRowToTimeseries ( wc , & sw . tmpRow , timestamp , false )
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}
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func ( sw * scrapeWork ) addRowToTimeseries ( wc * writeRequestCtx , r * parser . Row , timestamp int64 , needRelabel bool ) {
labelsLen := len ( wc . labels )
wc . labels = appendLabels ( wc . labels , r . Metric , r . Tags , sw . Config . Labels , sw . Config . HonorLabels )
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if needRelabel {
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wc . labels = promrelabel . ApplyRelabelConfigs ( wc . labels , labelsLen , sw . Config . MetricRelabelConfigs , true )
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} else {
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wc . labels = promrelabel . FinalizeLabels ( wc . labels [ : labelsLen ] , wc . labels [ labelsLen : ] )
promrelabel . SortLabels ( wc . labels [ labelsLen : ] )
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}
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if len ( wc . labels ) == labelsLen {
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// Skip row without labels.
return
}
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sampleTimestamp := r . Timestamp
if ! sw . Config . HonorTimestamps || sampleTimestamp == 0 {
sampleTimestamp = timestamp
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}
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wc . samples = append ( wc . samples , prompbmarshal . Sample {
Value : r . Value ,
Timestamp : sampleTimestamp ,
} )
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wr := & wc . writeRequest
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wr . Timeseries = append ( wr . Timeseries , prompbmarshal . TimeSeries {
Labels : wc . labels [ labelsLen : ] ,
Samples : wc . samples [ len ( wc . samples ) - 1 : ] ,
} )
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}
func appendLabels ( dst [ ] prompbmarshal . Label , metric string , src [ ] parser . Tag , extraLabels [ ] prompbmarshal . Label , honorLabels bool ) [ ] prompbmarshal . Label {
dstLen := len ( dst )
dst = append ( dst , prompbmarshal . Label {
Name : "__name__" ,
Value : metric ,
} )
for i := range src {
tag := & src [ i ]
dst = append ( dst , prompbmarshal . Label {
Name : tag . Key ,
Value : tag . Value ,
} )
}
dst = append ( dst , extraLabels ... )
labels := dst [ dstLen : ]
if len ( labels ) <= 1 {
// Fast path - only a single label.
return dst
}
// de-duplicate labels
dstLabels := labels [ : 0 ]
for i := range labels {
label := & labels [ i ]
prevLabel := promrelabel . GetLabelByName ( dstLabels , label . Name )
if prevLabel == nil {
dstLabels = append ( dstLabels , * label )
continue
}
if honorLabels {
// Skip the extra label with the same name.
continue
}
// Rename the prevLabel to "exported_" + label.Name.
// See https://prometheus.io/docs/prometheus/latest/configuration/configuration/#scrape_config
exportedName := "exported_" + label . Name
if promrelabel . GetLabelByName ( dstLabels , exportedName ) != nil {
// Override duplicate with the current label.
* prevLabel = * label
continue
}
prevLabel . Name = exportedName
dstLabels = append ( dstLabels , * label )
}
return dst [ : dstLen + len ( dstLabels ) ]
}