// Copyright 2017, OpenCensus Authors // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package trace import ( "context" crand "crypto/rand" "encoding/binary" "fmt" "math/rand" "sync" "sync/atomic" "time" "go.opencensus.io/internal" "go.opencensus.io/trace/tracestate" ) type tracer struct{} var _ Tracer = &tracer{} // Span represents a span of a trace. It has an associated SpanContext, and // stores data accumulated while the span is active. // // Ideally users should interact with Spans by calling the functions in this // package that take a Context parameter. type span struct { // data contains information recorded about the span. // // It will be non-nil if we are exporting the span or recording events for it. // Otherwise, data is nil, and the Span is simply a carrier for the // SpanContext, so that the trace ID is propagated. data *SpanData mu sync.Mutex // protects the contents of *data (but not the pointer value.) spanContext SpanContext // lruAttributes are capped at configured limit. When the capacity is reached an oldest entry // is removed to create room for a new entry. lruAttributes *lruMap // annotations are stored in FIFO queue capped by configured limit. annotations *evictedQueue // messageEvents are stored in FIFO queue capped by configured limit. messageEvents *evictedQueue // links are stored in FIFO queue capped by configured limit. links *evictedQueue // spanStore is the spanStore this span belongs to, if any, otherwise it is nil. *spanStore endOnce sync.Once executionTracerTaskEnd func() // ends the execution tracer span } // IsRecordingEvents returns true if events are being recorded for this span. // Use this check to avoid computing expensive annotations when they will never // be used. func (s *span) IsRecordingEvents() bool { if s == nil { return false } return s.data != nil } // TraceOptions contains options associated with a trace span. type TraceOptions uint32 // IsSampled returns true if the span will be exported. func (sc SpanContext) IsSampled() bool { return sc.TraceOptions.IsSampled() } // setIsSampled sets the TraceOptions bit that determines whether the span will be exported. func (sc *SpanContext) setIsSampled(sampled bool) { if sampled { sc.TraceOptions |= 1 } else { sc.TraceOptions &= ^TraceOptions(1) } } // IsSampled returns true if the span will be exported. func (t TraceOptions) IsSampled() bool { return t&1 == 1 } // SpanContext contains the state that must propagate across process boundaries. // // SpanContext is not an implementation of context.Context. // TODO: add reference to external Census docs for SpanContext. type SpanContext struct { TraceID TraceID SpanID SpanID TraceOptions TraceOptions Tracestate *tracestate.Tracestate } type contextKey struct{} // FromContext returns the Span stored in a context, or nil if there isn't one. func (t *tracer) FromContext(ctx context.Context) *Span { s, _ := ctx.Value(contextKey{}).(*Span) return s } // NewContext returns a new context with the given Span attached. func (t *tracer) NewContext(parent context.Context, s *Span) context.Context { return context.WithValue(parent, contextKey{}, s) } // All available span kinds. Span kind must be either one of these values. const ( SpanKindUnspecified = iota SpanKindServer SpanKindClient ) // StartOptions contains options concerning how a span is started. type StartOptions struct { // Sampler to consult for this Span. If provided, it is always consulted. // // If not provided, then the behavior differs based on whether // the parent of this Span is remote, local, or there is no parent. // In the case of a remote parent or no parent, the // default sampler (see Config) will be consulted. Otherwise, // when there is a non-remote parent, no new sampling decision will be made: // we will preserve the sampling of the parent. Sampler Sampler // SpanKind represents the kind of a span. If none is set, // SpanKindUnspecified is used. SpanKind int } // StartOption apply changes to StartOptions. type StartOption func(*StartOptions) // WithSpanKind makes new spans to be created with the given kind. func WithSpanKind(spanKind int) StartOption { return func(o *StartOptions) { o.SpanKind = spanKind } } // WithSampler makes new spans to be be created with a custom sampler. // Otherwise, the global sampler is used. func WithSampler(sampler Sampler) StartOption { return func(o *StartOptions) { o.Sampler = sampler } } // StartSpan starts a new child span of the current span in the context. If // there is no span in the context, creates a new trace and span. // // Returned context contains the newly created span. You can use it to // propagate the returned span in process. func (t *tracer) StartSpan(ctx context.Context, name string, o ...StartOption) (context.Context, *Span) { var opts StartOptions var parent SpanContext if p := t.FromContext(ctx); p != nil { if ps, ok := p.internal.(*span); ok { ps.addChild() } parent = p.SpanContext() } for _, op := range o { op(&opts) } span := startSpanInternal(name, parent != SpanContext{}, parent, false, opts) ctx, end := startExecutionTracerTask(ctx, name) span.executionTracerTaskEnd = end extSpan := NewSpan(span) return t.NewContext(ctx, extSpan), extSpan } // StartSpanWithRemoteParent starts a new child span of the span from the given parent. // // If the incoming context contains a parent, it ignores. StartSpanWithRemoteParent is // preferred for cases where the parent is propagated via an incoming request. // // Returned context contains the newly created span. You can use it to // propagate the returned span in process. func (t *tracer) StartSpanWithRemoteParent(ctx context.Context, name string, parent SpanContext, o ...StartOption) (context.Context, *Span) { var opts StartOptions for _, op := range o { op(&opts) } span := startSpanInternal(name, parent != SpanContext{}, parent, true, opts) ctx, end := startExecutionTracerTask(ctx, name) span.executionTracerTaskEnd = end extSpan := NewSpan(span) return t.NewContext(ctx, extSpan), extSpan } func startSpanInternal(name string, hasParent bool, parent SpanContext, remoteParent bool, o StartOptions) *span { s := &span{} s.spanContext = parent cfg := config.Load().(*Config) if gen, ok := cfg.IDGenerator.(*defaultIDGenerator); ok { // lazy initialization gen.init() } if !hasParent { s.spanContext.TraceID = cfg.IDGenerator.NewTraceID() } s.spanContext.SpanID = cfg.IDGenerator.NewSpanID() sampler := cfg.DefaultSampler if !hasParent || remoteParent || o.Sampler != nil { // If this span is the child of a local span and no Sampler is set in the // options, keep the parent's TraceOptions. // // Otherwise, consult the Sampler in the options if it is non-nil, otherwise // the default sampler. if o.Sampler != nil { sampler = o.Sampler } s.spanContext.setIsSampled(sampler(SamplingParameters{ ParentContext: parent, TraceID: s.spanContext.TraceID, SpanID: s.spanContext.SpanID, Name: name, HasRemoteParent: remoteParent}).Sample) } if !internal.LocalSpanStoreEnabled && !s.spanContext.IsSampled() { return s } s.data = &SpanData{ SpanContext: s.spanContext, StartTime: time.Now(), SpanKind: o.SpanKind, Name: name, HasRemoteParent: remoteParent, } s.lruAttributes = newLruMap(cfg.MaxAttributesPerSpan) s.annotations = newEvictedQueue(cfg.MaxAnnotationEventsPerSpan) s.messageEvents = newEvictedQueue(cfg.MaxMessageEventsPerSpan) s.links = newEvictedQueue(cfg.MaxLinksPerSpan) if hasParent { s.data.ParentSpanID = parent.SpanID } if internal.LocalSpanStoreEnabled { var ss *spanStore ss = spanStoreForNameCreateIfNew(name) if ss != nil { s.spanStore = ss ss.add(s) } } return s } // End ends the span. func (s *span) End() { if s == nil { return } if s.executionTracerTaskEnd != nil { s.executionTracerTaskEnd() } if !s.IsRecordingEvents() { return } s.endOnce.Do(func() { exp, _ := exporters.Load().(exportersMap) mustExport := s.spanContext.IsSampled() && len(exp) > 0 if s.spanStore != nil || mustExport { sd := s.makeSpanData() sd.EndTime = internal.MonotonicEndTime(sd.StartTime) if s.spanStore != nil { s.spanStore.finished(s, sd) } if mustExport { for e := range exp { e.ExportSpan(sd) } } } }) } // makeSpanData produces a SpanData representing the current state of the Span. // It requires that s.data is non-nil. func (s *span) makeSpanData() *SpanData { var sd SpanData s.mu.Lock() sd = *s.data if s.lruAttributes.len() > 0 { sd.Attributes = s.lruAttributesToAttributeMap() sd.DroppedAttributeCount = s.lruAttributes.droppedCount } if len(s.annotations.queue) > 0 { sd.Annotations = s.interfaceArrayToAnnotationArray() sd.DroppedAnnotationCount = s.annotations.droppedCount } if len(s.messageEvents.queue) > 0 { sd.MessageEvents = s.interfaceArrayToMessageEventArray() sd.DroppedMessageEventCount = s.messageEvents.droppedCount } if len(s.links.queue) > 0 { sd.Links = s.interfaceArrayToLinksArray() sd.DroppedLinkCount = s.links.droppedCount } s.mu.Unlock() return &sd } // SpanContext returns the SpanContext of the span. func (s *span) SpanContext() SpanContext { if s == nil { return SpanContext{} } return s.spanContext } // SetName sets the name of the span, if it is recording events. func (s *span) SetName(name string) { if !s.IsRecordingEvents() { return } s.mu.Lock() s.data.Name = name s.mu.Unlock() } // SetStatus sets the status of the span, if it is recording events. func (s *span) SetStatus(status Status) { if !s.IsRecordingEvents() { return } s.mu.Lock() s.data.Status = status s.mu.Unlock() } func (s *span) interfaceArrayToLinksArray() []Link { linksArr := make([]Link, 0, len(s.links.queue)) for _, value := range s.links.queue { linksArr = append(linksArr, value.(Link)) } return linksArr } func (s *span) interfaceArrayToMessageEventArray() []MessageEvent { messageEventArr := make([]MessageEvent, 0, len(s.messageEvents.queue)) for _, value := range s.messageEvents.queue { messageEventArr = append(messageEventArr, value.(MessageEvent)) } return messageEventArr } func (s *span) interfaceArrayToAnnotationArray() []Annotation { annotationArr := make([]Annotation, 0, len(s.annotations.queue)) for _, value := range s.annotations.queue { annotationArr = append(annotationArr, value.(Annotation)) } return annotationArr } func (s *span) lruAttributesToAttributeMap() map[string]interface{} { attributes := make(map[string]interface{}, s.lruAttributes.len()) for _, key := range s.lruAttributes.keys() { value, ok := s.lruAttributes.get(key) if ok { keyStr := key.(string) attributes[keyStr] = value } } return attributes } func (s *span) copyToCappedAttributes(attributes []Attribute) { for _, a := range attributes { s.lruAttributes.add(a.key, a.value) } } func (s *span) addChild() { if !s.IsRecordingEvents() { return } s.mu.Lock() s.data.ChildSpanCount++ s.mu.Unlock() } // AddAttributes sets attributes in the span. // // Existing attributes whose keys appear in the attributes parameter are overwritten. func (s *span) AddAttributes(attributes ...Attribute) { if !s.IsRecordingEvents() { return } s.mu.Lock() s.copyToCappedAttributes(attributes) s.mu.Unlock() } func (s *span) printStringInternal(attributes []Attribute, str string) { now := time.Now() var am map[string]interface{} if len(attributes) != 0 { am = make(map[string]interface{}, len(attributes)) for _, attr := range attributes { am[attr.key] = attr.value } } s.mu.Lock() s.annotations.add(Annotation{ Time: now, Message: str, Attributes: am, }) s.mu.Unlock() } // Annotate adds an annotation with attributes. // Attributes can be nil. func (s *span) Annotate(attributes []Attribute, str string) { if !s.IsRecordingEvents() { return } s.printStringInternal(attributes, str) } // Annotatef adds an annotation with attributes. func (s *span) Annotatef(attributes []Attribute, format string, a ...interface{}) { if !s.IsRecordingEvents() { return } s.printStringInternal(attributes, fmt.Sprintf(format, a...)) } // AddMessageSendEvent adds a message send event to the span. // // messageID is an identifier for the message, which is recommended to be // unique in this span and the same between the send event and the receive // event (this allows to identify a message between the sender and receiver). // For example, this could be a sequence id. func (s *span) AddMessageSendEvent(messageID, uncompressedByteSize, compressedByteSize int64) { if !s.IsRecordingEvents() { return } now := time.Now() s.mu.Lock() s.messageEvents.add(MessageEvent{ Time: now, EventType: MessageEventTypeSent, MessageID: messageID, UncompressedByteSize: uncompressedByteSize, CompressedByteSize: compressedByteSize, }) s.mu.Unlock() } // AddMessageReceiveEvent adds a message receive event to the span. // // messageID is an identifier for the message, which is recommended to be // unique in this span and the same between the send event and the receive // event (this allows to identify a message between the sender and receiver). // For example, this could be a sequence id. func (s *span) AddMessageReceiveEvent(messageID, uncompressedByteSize, compressedByteSize int64) { if !s.IsRecordingEvents() { return } now := time.Now() s.mu.Lock() s.messageEvents.add(MessageEvent{ Time: now, EventType: MessageEventTypeRecv, MessageID: messageID, UncompressedByteSize: uncompressedByteSize, CompressedByteSize: compressedByteSize, }) s.mu.Unlock() } // AddLink adds a link to the span. func (s *span) AddLink(l Link) { if !s.IsRecordingEvents() { return } s.mu.Lock() s.links.add(l) s.mu.Unlock() } func (s *span) String() string { if s == nil { return "" } if s.data == nil { return fmt.Sprintf("span %s", s.spanContext.SpanID) } s.mu.Lock() str := fmt.Sprintf("span %s %q", s.spanContext.SpanID, s.data.Name) s.mu.Unlock() return str } var config atomic.Value // access atomically func init() { config.Store(&Config{ DefaultSampler: ProbabilitySampler(defaultSamplingProbability), IDGenerator: &defaultIDGenerator{}, MaxAttributesPerSpan: DefaultMaxAttributesPerSpan, MaxAnnotationEventsPerSpan: DefaultMaxAnnotationEventsPerSpan, MaxMessageEventsPerSpan: DefaultMaxMessageEventsPerSpan, MaxLinksPerSpan: DefaultMaxLinksPerSpan, }) } type defaultIDGenerator struct { sync.Mutex // Please keep these as the first fields // so that these 8 byte fields will be aligned on addresses // divisible by 8, on both 32-bit and 64-bit machines when // performing atomic increments and accesses. // See: // * https://github.com/census-instrumentation/opencensus-go/issues/587 // * https://github.com/census-instrumentation/opencensus-go/issues/865 // * https://golang.org/pkg/sync/atomic/#pkg-note-BUG nextSpanID uint64 spanIDInc uint64 traceIDAdd [2]uint64 traceIDRand *rand.Rand initOnce sync.Once } // init initializes the generator on the first call to avoid consuming entropy // unnecessarily. func (gen *defaultIDGenerator) init() { gen.initOnce.Do(func() { // initialize traceID and spanID generators. var rngSeed int64 for _, p := range []interface{}{ &rngSeed, &gen.traceIDAdd, &gen.nextSpanID, &gen.spanIDInc, } { binary.Read(crand.Reader, binary.LittleEndian, p) } gen.traceIDRand = rand.New(rand.NewSource(rngSeed)) gen.spanIDInc |= 1 }) } // NewSpanID returns a non-zero span ID from a randomly-chosen sequence. func (gen *defaultIDGenerator) NewSpanID() [8]byte { var id uint64 for id == 0 { id = atomic.AddUint64(&gen.nextSpanID, gen.spanIDInc) } var sid [8]byte binary.LittleEndian.PutUint64(sid[:], id) return sid } // NewTraceID returns a non-zero trace ID from a randomly-chosen sequence. // mu should be held while this function is called. func (gen *defaultIDGenerator) NewTraceID() [16]byte { var tid [16]byte // Construct the trace ID from two outputs of traceIDRand, with a constant // added to each half for additional entropy. gen.Lock() binary.LittleEndian.PutUint64(tid[0:8], gen.traceIDRand.Uint64()+gen.traceIDAdd[0]) binary.LittleEndian.PutUint64(tid[8:16], gen.traceIDRand.Uint64()+gen.traceIDAdd[1]) gen.Unlock() return tid }