290 lines
7.1 KiB
Go
290 lines
7.1 KiB
Go
package zipkintracer
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import (
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"sync"
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"time"
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opentracing "github.com/opentracing/opentracing-go"
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"github.com/opentracing/opentracing-go/ext"
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"github.com/opentracing/opentracing-go/log"
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otobserver "github.com/opentracing-contrib/go-observer"
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"github.com/openzipkin-contrib/zipkin-go-opentracing/thrift/gen-go/zipkincore"
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)
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// Span provides access to the essential details of the span, for use
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// by zipkintracer consumers. These methods may only be called prior
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// to (*opentracing.Span).Finish().
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type Span interface {
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opentracing.Span
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// Operation names the work done by this span instance
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Operation() string
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// Start indicates when the span began
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Start() time.Time
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}
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// Implements the `Span` interface. Created via tracerImpl (see
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// `zipkintracer.NewTracer()`).
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type spanImpl struct {
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tracer *tracerImpl
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event func(SpanEvent)
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observer otobserver.SpanObserver
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sync.Mutex // protects the fields below
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raw RawSpan
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// The number of logs dropped because of MaxLogsPerSpan.
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numDroppedLogs int
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Endpoint *zipkincore.Endpoint
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}
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var spanPool = &sync.Pool{New: func() interface{} {
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return &spanImpl{}
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}}
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func (s *spanImpl) reset() {
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s.tracer, s.event = nil, nil
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// Note: Would like to do the following, but then the consumer of RawSpan
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// (the recorder) needs to make sure that they're not holding on to the
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// baggage or logs when they return (i.e. they need to copy if they care):
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//
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// logs, baggage := s.raw.Logs[:0], s.raw.Baggage
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// for k := range baggage {
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// delete(baggage, k)
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// }
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// s.raw.Logs, s.raw.Baggage = logs, baggage
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//
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// That's likely too much to ask for. But there is some magic we should
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// be able to do with `runtime.SetFinalizer` to reclaim that memory into
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// a buffer pool when GC considers them unreachable, which should ease
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// some of the load. Hard to say how quickly that would be in practice
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// though.
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s.raw = RawSpan{
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Context: SpanContext{},
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}
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}
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func (s *spanImpl) SetOperationName(operationName string) opentracing.Span {
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if s.observer != nil {
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s.observer.OnSetOperationName(operationName)
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}
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s.Lock()
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defer s.Unlock()
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s.raw.Operation = operationName
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return s
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}
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func (s *spanImpl) trim() bool {
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return !s.raw.Context.Sampled && s.tracer.options.trimUnsampledSpans
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}
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func (s *spanImpl) SetTag(key string, value interface{}) opentracing.Span {
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defer s.onTag(key, value)
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if s.observer != nil {
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s.observer.OnSetTag(key, value)
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}
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s.Lock()
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defer s.Unlock()
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if key == string(ext.SamplingPriority) {
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if v, ok := value.(uint16); ok {
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s.raw.Context.Sampled = v != 0
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return s
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}
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}
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if s.trim() {
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return s
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}
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if s.raw.Tags == nil {
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s.raw.Tags = opentracing.Tags{}
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}
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s.raw.Tags[key] = value
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return s
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}
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func (s *spanImpl) LogKV(keyValues ...interface{}) {
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fields, err := log.InterleavedKVToFields(keyValues...)
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if err != nil {
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s.LogFields(log.Error(err), log.String("function", "LogKV"))
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return
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}
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s.LogFields(fields...)
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}
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func (s *spanImpl) appendLog(lr opentracing.LogRecord) {
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maxLogs := s.tracer.options.maxLogsPerSpan
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if maxLogs == 0 || len(s.raw.Logs) < maxLogs {
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s.raw.Logs = append(s.raw.Logs, lr)
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return
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}
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// We have too many logs. We don't touch the first numOld logs; we treat the
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// rest as a circular buffer and overwrite the oldest log among those.
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numOld := (maxLogs - 1) / 2
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numNew := maxLogs - numOld
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s.raw.Logs[numOld+s.numDroppedLogs%numNew] = lr
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s.numDroppedLogs++
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}
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func (s *spanImpl) LogFields(fields ...log.Field) {
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lr := opentracing.LogRecord{
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Fields: fields,
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}
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defer s.onLogFields(lr)
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s.Lock()
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defer s.Unlock()
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if s.trim() || s.tracer.options.dropAllLogs {
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return
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}
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if lr.Timestamp.IsZero() {
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lr.Timestamp = time.Now()
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}
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s.appendLog(lr)
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}
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func (s *spanImpl) LogEvent(event string) {
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s.Log(opentracing.LogData{
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Event: event,
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})
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}
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func (s *spanImpl) LogEventWithPayload(event string, payload interface{}) {
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s.Log(opentracing.LogData{
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Event: event,
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Payload: payload,
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})
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}
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func (s *spanImpl) Log(ld opentracing.LogData) {
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defer s.onLog(ld)
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s.Lock()
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defer s.Unlock()
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if s.trim() || s.tracer.options.dropAllLogs {
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return
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}
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if ld.Timestamp.IsZero() {
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ld.Timestamp = time.Now()
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}
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s.appendLog(ld.ToLogRecord())
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}
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func (s *spanImpl) Finish() {
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s.FinishWithOptions(opentracing.FinishOptions{})
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}
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// rotateLogBuffer rotates the records in the buffer: records 0 to pos-1 move at
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// the end (i.e. pos circular left shifts).
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func rotateLogBuffer(buf []opentracing.LogRecord, pos int) {
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// This algorithm is described in:
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// http://www.cplusplus.com/reference/algorithm/rotate
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for first, middle, next := 0, pos, pos; first != middle; {
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buf[first], buf[next] = buf[next], buf[first]
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first++
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next++
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if next == len(buf) {
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next = middle
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} else if first == middle {
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middle = next
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}
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}
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}
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func (s *spanImpl) FinishWithOptions(opts opentracing.FinishOptions) {
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finishTime := opts.FinishTime
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if finishTime.IsZero() {
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finishTime = time.Now()
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}
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duration := finishTime.Sub(s.raw.Start)
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if s.observer != nil {
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s.observer.OnFinish(opts)
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}
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s.Lock()
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defer s.Unlock()
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for _, lr := range opts.LogRecords {
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s.appendLog(lr)
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}
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for _, ld := range opts.BulkLogData {
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s.appendLog(ld.ToLogRecord())
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}
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if s.numDroppedLogs > 0 {
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// We dropped some log events, which means that we used part of Logs as a
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// circular buffer (see appendLog). De-circularize it.
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numOld := (len(s.raw.Logs) - 1) / 2
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numNew := len(s.raw.Logs) - numOld
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rotateLogBuffer(s.raw.Logs[numOld:], s.numDroppedLogs%numNew)
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// Replace the log in the middle (the oldest "new" log) with information
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// about the dropped logs. This means that we are effectively dropping one
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// more "new" log.
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numDropped := s.numDroppedLogs + 1
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s.raw.Logs[numOld] = opentracing.LogRecord{
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// Keep the timestamp of the last dropped event.
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Timestamp: s.raw.Logs[numOld].Timestamp,
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Fields: []log.Field{
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log.String("event", "dropped Span logs"),
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log.Int("dropped_log_count", numDropped),
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log.String("component", "zipkintracer"),
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},
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}
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}
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s.raw.Duration = duration
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s.onFinish(s.raw)
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s.tracer.options.recorder.RecordSpan(s.raw)
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// Last chance to get options before the span is possibly reset.
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poolEnabled := s.tracer.options.enableSpanPool
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if s.tracer.options.debugAssertUseAfterFinish {
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// This makes it much more likely to catch a panic on any subsequent
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// operation since s.tracer is accessed on every call to `Lock`.
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// We don't call `reset()` here to preserve the logs in the Span
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// which are printed when the assertion triggers.
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s.tracer = nil
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}
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if poolEnabled {
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spanPool.Put(s)
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}
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}
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func (s *spanImpl) Tracer() opentracing.Tracer {
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return s.tracer
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}
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func (s *spanImpl) Context() opentracing.SpanContext {
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return s.raw.Context
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}
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func (s *spanImpl) SetBaggageItem(key, val string) opentracing.Span {
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s.onBaggage(key, val)
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if s.trim() {
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return s
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}
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s.Lock()
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defer s.Unlock()
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s.raw.Context = s.raw.Context.WithBaggageItem(key, val)
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return s
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}
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func (s *spanImpl) BaggageItem(key string) string {
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s.Lock()
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defer s.Unlock()
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return s.raw.Context.Baggage[key]
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}
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func (s *spanImpl) Operation() string {
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return s.raw.Operation
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}
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func (s *spanImpl) Start() time.Time {
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return s.raw.Start
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}
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