// Copyright The OpenTelemetry Authors // SPDX-License-Identifier: Apache-2.0 package trace // import "go.opentelemetry.io/otel/trace" import ( "context" "encoding/json" "fmt" "math" "os" "reflect" "runtime" "strconv" "strings" "sync" "sync/atomic" "time" "unicode/utf8" "go.opentelemetry.io/otel/attribute" "go.opentelemetry.io/otel/codes" semconv "go.opentelemetry.io/otel/semconv/v1.39.0" "go.opentelemetry.io/otel/trace/embedded" "go.opentelemetry.io/otel/trace/internal/telemetry" ) // newAutoTracerProvider returns an auto-instrumentable [trace.TracerProvider]. // If an [go.opentelemetry.io/auto.Instrumentation] is configured to instrument // the process using the returned TracerProvider, all of the telemetry it // produces will be processed and handled by that Instrumentation. By default, // if no Instrumentation instruments the TracerProvider it will not generate // any trace telemetry. func newAutoTracerProvider() TracerProvider { return tracerProviderInstance } var tracerProviderInstance = new(autoTracerProvider) type autoTracerProvider struct{ embedded.TracerProvider } var _ TracerProvider = autoTracerProvider{} func (autoTracerProvider) Tracer(name string, opts ...TracerOption) Tracer { cfg := NewTracerConfig(opts...) return autoTracer{ name: name, version: cfg.InstrumentationVersion(), schemaURL: cfg.SchemaURL(), } } type autoTracer struct { embedded.Tracer name, schemaURL, version string } var _ Tracer = autoTracer{} func (t autoTracer) Start(ctx context.Context, name string, opts ...SpanStartOption) (context.Context, Span) { var psc, sc SpanContext sampled := true span := new(autoSpan) // Ask eBPF for sampling decision and span context info. t.start(ctx, span, &psc, &sampled, &sc) span.sampled.Store(sampled) span.spanContext = sc ctx = ContextWithSpan(ctx, span) if sampled { // Only build traces if sampled. cfg := NewSpanStartConfig(opts...) span.traces, span.span = t.traces(name, cfg, span.spanContext, psc) } return ctx, span } // Expected to be implemented in eBPF. // //go:noinline func (*autoTracer) start( ctx context.Context, spanPtr *autoSpan, psc *SpanContext, sampled *bool, sc *SpanContext, ) { start(ctx, spanPtr, psc, sampled, sc) } // start is used for testing. var start = func(context.Context, *autoSpan, *SpanContext, *bool, *SpanContext) {} func (t autoTracer) traces(name string, cfg SpanConfig, sc, psc SpanContext) (*telemetry.Traces, *telemetry.Span) { span := &telemetry.Span{ TraceID: telemetry.TraceID(sc.TraceID()), SpanID: telemetry.SpanID(sc.SpanID()), Flags: uint32(sc.TraceFlags()), TraceState: sc.TraceState().String(), ParentSpanID: telemetry.SpanID(psc.SpanID()), Name: name, Kind: spanKind(cfg.SpanKind()), } span.Attrs, span.DroppedAttrs = convCappedAttrs(maxSpan.Attrs, cfg.Attributes()) links := cfg.Links() if limit := maxSpan.Links; limit == 0 { n := int64(len(links)) if n > 0 { span.DroppedLinks = uint32(min(n, math.MaxUint32)) // nolint: gosec // Bounds checked. } } else { if limit > 0 { n := int64(max(len(links)-limit, 0)) span.DroppedLinks = uint32(min(n, math.MaxUint32)) // nolint: gosec // Bounds checked. links = links[n:] } span.Links = convLinks(links) } if t := cfg.Timestamp(); !t.IsZero() { span.StartTime = cfg.Timestamp() } else { span.StartTime = time.Now() } return &telemetry.Traces{ ResourceSpans: []*telemetry.ResourceSpans{ { ScopeSpans: []*telemetry.ScopeSpans{ { Scope: &telemetry.Scope{ Name: t.name, Version: t.version, }, Spans: []*telemetry.Span{span}, SchemaURL: t.schemaURL, }, }, }, }, }, span } func spanKind(kind SpanKind) telemetry.SpanKind { switch kind { case SpanKindInternal: return telemetry.SpanKindInternal case SpanKindServer: return telemetry.SpanKindServer case SpanKindClient: return telemetry.SpanKindClient case SpanKindProducer: return telemetry.SpanKindProducer case SpanKindConsumer: return telemetry.SpanKindConsumer } return telemetry.SpanKind(0) // undefined. } type autoSpan struct { embedded.Span spanContext SpanContext sampled atomic.Bool mu sync.Mutex traces *telemetry.Traces span *telemetry.Span } func (s *autoSpan) SpanContext() SpanContext { if s == nil { return SpanContext{} } // s.spanContext is immutable, do not acquire lock s.mu. return s.spanContext } func (s *autoSpan) IsRecording() bool { if s == nil { return false } return s.sampled.Load() } func (s *autoSpan) SetStatus(c codes.Code, msg string) { if s == nil || !s.sampled.Load() { return } s.mu.Lock() defer s.mu.Unlock() if s.span.Status == nil { s.span.Status = new(telemetry.Status) } s.span.Status.Message = msg switch c { case codes.Unset: s.span.Status.Code = telemetry.StatusCodeUnset case codes.Error: s.span.Status.Code = telemetry.StatusCodeError case codes.Ok: s.span.Status.Code = telemetry.StatusCodeOK } } func (s *autoSpan) SetAttributes(attrs ...attribute.KeyValue) { if s == nil || !s.sampled.Load() { return } s.mu.Lock() defer s.mu.Unlock() limit := maxSpan.Attrs if limit == 0 { // No attributes allowed. n := int64(len(attrs)) if n > 0 { s.span.DroppedAttrs += uint32(min(n, math.MaxUint32)) // nolint: gosec // Bounds checked. } return } m := make(map[string]int) for i, a := range s.span.Attrs { m[a.Key] = i } for _, a := range attrs { val := convAttrValue(a.Value) if val.Empty() { s.span.DroppedAttrs++ continue } if idx, ok := m[string(a.Key)]; ok { s.span.Attrs[idx] = telemetry.Attr{ Key: string(a.Key), Value: val, } } else if limit < 0 || len(s.span.Attrs) < limit { s.span.Attrs = append(s.span.Attrs, telemetry.Attr{ Key: string(a.Key), Value: val, }) m[string(a.Key)] = len(s.span.Attrs) - 1 } else { s.span.DroppedAttrs++ } } } // convCappedAttrs converts up to limit attrs into a []telemetry.Attr. The // number of dropped attributes is also returned. func convCappedAttrs(limit int, attrs []attribute.KeyValue) ([]telemetry.Attr, uint32) { n := len(attrs) if limit == 0 { var out uint32 if n > 0 { out = uint32(min(int64(n), math.MaxUint32)) // nolint: gosec // Bounds checked. } return nil, out } if limit < 0 { // Unlimited. return convAttrs(attrs), 0 } if n < 0 { n = 0 } limit = min(n, limit) return convAttrs(attrs[:limit]), uint32(n - limit) // nolint: gosec // Bounds checked. } func convAttrs(attrs []attribute.KeyValue) []telemetry.Attr { if len(attrs) == 0 { // Avoid allocations if not necessary. return nil } out := make([]telemetry.Attr, 0, len(attrs)) for _, attr := range attrs { key := string(attr.Key) val := convAttrValue(attr.Value) if val.Empty() { continue } out = append(out, telemetry.Attr{Key: key, Value: val}) } return out } func convAttrValue(value attribute.Value) telemetry.Value { switch value.Type() { case attribute.BOOL: return telemetry.BoolValue(value.AsBool()) case attribute.INT64: return telemetry.Int64Value(value.AsInt64()) case attribute.FLOAT64: return telemetry.Float64Value(value.AsFloat64()) case attribute.STRING: v := truncate(maxSpan.AttrValueLen, value.AsString()) return telemetry.StringValue(v) case attribute.BOOLSLICE: slice := value.AsBoolSlice() out := make([]telemetry.Value, 0, len(slice)) for _, v := range slice { out = append(out, telemetry.BoolValue(v)) } return telemetry.SliceValue(out...) case attribute.INT64SLICE: slice := value.AsInt64Slice() out := make([]telemetry.Value, 0, len(slice)) for _, v := range slice { out = append(out, telemetry.Int64Value(v)) } return telemetry.SliceValue(out...) case attribute.FLOAT64SLICE: slice := value.AsFloat64Slice() out := make([]telemetry.Value, 0, len(slice)) for _, v := range slice { out = append(out, telemetry.Float64Value(v)) } return telemetry.SliceValue(out...) case attribute.STRINGSLICE: slice := value.AsStringSlice() out := make([]telemetry.Value, 0, len(slice)) for _, v := range slice { v = truncate(maxSpan.AttrValueLen, v) out = append(out, telemetry.StringValue(v)) } return telemetry.SliceValue(out...) } return telemetry.Value{} } // truncate returns a truncated version of s such that it contains less than // the limit number of characters. Truncation is applied by returning the limit // number of valid characters contained in s. // // If limit is negative, it returns the original string. // // UTF-8 is supported. When truncating, all invalid characters are dropped // before applying truncation. // // If s already contains less than the limit number of bytes, it is returned // unchanged. No invalid characters are removed. func truncate(limit int, s string) string { // This prioritize performance in the following order based on the most // common expected use-cases. // // - Short values less than the default limit (128). // - Strings with valid encodings that exceed the limit. // - No limit. // - Strings with invalid encodings that exceed the limit. if limit < 0 || len(s) <= limit { return s } // Optimistically, assume all valid UTF-8. var b strings.Builder count := 0 for i, c := range s { if c != utf8.RuneError { count++ if count > limit { return s[:i] } continue } _, size := utf8.DecodeRuneInString(s[i:]) if size == 1 { // Invalid encoding. b.Grow(len(s) - 1) _, _ = b.WriteString(s[:i]) s = s[i:] break } } // Fast-path, no invalid input. if b.Cap() == 0 { return s } // Truncate while validating UTF-8. for i := 0; i < len(s) && count < limit; { c := s[i] if c < utf8.RuneSelf { // Optimization for single byte runes (common case). _ = b.WriteByte(c) i++ count++ continue } _, size := utf8.DecodeRuneInString(s[i:]) if size == 1 { // We checked for all 1-byte runes above, this is a RuneError. i++ continue } _, _ = b.WriteString(s[i : i+size]) i += size count++ } return b.String() } func (s *autoSpan) End(opts ...SpanEndOption) { if s == nil || !s.sampled.Swap(false) { return } // s.end exists so the lock (s.mu) is not held while s.ended is called. s.ended(s.end(opts)) } func (s *autoSpan) end(opts []SpanEndOption) []byte { s.mu.Lock() defer s.mu.Unlock() cfg := NewSpanEndConfig(opts...) if t := cfg.Timestamp(); !t.IsZero() { s.span.EndTime = cfg.Timestamp() } else { s.span.EndTime = time.Now() } b, _ := json.Marshal(s.traces) // TODO: do not ignore this error. return b } // Expected to be implemented in eBPF. // //go:noinline func (*autoSpan) ended(buf []byte) { ended(buf) } // ended is used for testing. var ended = func([]byte) {} func (s *autoSpan) RecordError(err error, opts ...EventOption) { if s == nil || err == nil || !s.sampled.Load() { return } cfg := NewEventConfig(opts...) attrs := cfg.Attributes() attrs = append(attrs, semconv.ExceptionType(typeStr(err)), semconv.ExceptionMessage(err.Error()), ) if cfg.StackTrace() { buf := make([]byte, 2048) n := runtime.Stack(buf, false) attrs = append(attrs, semconv.ExceptionStacktrace(string(buf[0:n]))) } s.mu.Lock() defer s.mu.Unlock() s.addEvent(semconv.ExceptionEventName, cfg.Timestamp(), attrs) } func typeStr(i any) string { t := reflect.TypeOf(i) if t.PkgPath() == "" && t.Name() == "" { // Likely a builtin type. return t.String() } return fmt.Sprintf("%s.%s", t.PkgPath(), t.Name()) } func (s *autoSpan) AddEvent(name string, opts ...EventOption) { if s == nil || !s.sampled.Load() { return } cfg := NewEventConfig(opts...) s.mu.Lock() defer s.mu.Unlock() s.addEvent(name, cfg.Timestamp(), cfg.Attributes()) } // addEvent adds an event with name and attrs at tStamp to the span. The span // lock (s.mu) needs to be held by the caller. func (s *autoSpan) addEvent(name string, tStamp time.Time, attrs []attribute.KeyValue) { limit := maxSpan.Events if limit == 0 { s.span.DroppedEvents++ return } if limit > 0 && len(s.span.Events) == limit { // Drop head while avoiding allocation of more capacity. copy(s.span.Events[:limit-1], s.span.Events[1:]) s.span.Events = s.span.Events[:limit-1] s.span.DroppedEvents++ } e := &telemetry.SpanEvent{Time: tStamp, Name: name} e.Attrs, e.DroppedAttrs = convCappedAttrs(maxSpan.EventAttrs, attrs) s.span.Events = append(s.span.Events, e) } func (s *autoSpan) AddLink(link Link) { if s == nil || !s.sampled.Load() { return } l := maxSpan.Links s.mu.Lock() defer s.mu.Unlock() if l == 0 { s.span.DroppedLinks++ return } if l > 0 && len(s.span.Links) == l { // Drop head while avoiding allocation of more capacity. copy(s.span.Links[:l-1], s.span.Links[1:]) s.span.Links = s.span.Links[:l-1] s.span.DroppedLinks++ } s.span.Links = append(s.span.Links, convLink(link)) } func convLinks(links []Link) []*telemetry.SpanLink { out := make([]*telemetry.SpanLink, 0, len(links)) for _, link := range links { out = append(out, convLink(link)) } return out } func convLink(link Link) *telemetry.SpanLink { l := &telemetry.SpanLink{ TraceID: telemetry.TraceID(link.SpanContext.TraceID()), SpanID: telemetry.SpanID(link.SpanContext.SpanID()), TraceState: link.SpanContext.TraceState().String(), Flags: uint32(link.SpanContext.TraceFlags()), } l.Attrs, l.DroppedAttrs = convCappedAttrs(maxSpan.LinkAttrs, link.Attributes) return l } func (s *autoSpan) SetName(name string) { if s == nil || !s.sampled.Load() { return } s.mu.Lock() defer s.mu.Unlock() s.span.Name = name } func (*autoSpan) TracerProvider() TracerProvider { return newAutoTracerProvider() } // maxSpan are the span limits resolved during startup. var maxSpan = newSpanLimits() type spanLimits struct { // Attrs is the number of allowed attributes for a span. // // This is resolved from the environment variable value for the // OTEL_SPAN_ATTRIBUTE_COUNT_LIMIT key if it exists. Otherwise, the // environment variable value for OTEL_ATTRIBUTE_COUNT_LIMIT, or 128 if // that is not set, is used. Attrs int // AttrValueLen is the maximum attribute value length allowed for a span. // // This is resolved from the environment variable value for the // OTEL_SPAN_ATTRIBUTE_VALUE_LENGTH_LIMIT key if it exists. Otherwise, the // environment variable value for OTEL_ATTRIBUTE_VALUE_LENGTH_LIMIT, or -1 // if that is not set, is used. AttrValueLen int // Events is the number of allowed events for a span. // // This is resolved from the environment variable value for the // OTEL_SPAN_EVENT_COUNT_LIMIT key, or 128 is used if that is not set. Events int // EventAttrs is the number of allowed attributes for a span event. // // The is resolved from the environment variable value for the // OTEL_EVENT_ATTRIBUTE_COUNT_LIMIT key, or 128 is used if that is not set. EventAttrs int // Links is the number of allowed Links for a span. // // This is resolved from the environment variable value for the // OTEL_SPAN_LINK_COUNT_LIMIT, or 128 is used if that is not set. Links int // LinkAttrs is the number of allowed attributes for a span link. // // This is resolved from the environment variable value for the // OTEL_LINK_ATTRIBUTE_COUNT_LIMIT, or 128 is used if that is not set. LinkAttrs int } func newSpanLimits() spanLimits { return spanLimits{ Attrs: firstEnv( 128, "OTEL_SPAN_ATTRIBUTE_COUNT_LIMIT", "OTEL_ATTRIBUTE_COUNT_LIMIT", ), AttrValueLen: firstEnv( -1, // Unlimited. "OTEL_SPAN_ATTRIBUTE_VALUE_LENGTH_LIMIT", "OTEL_ATTRIBUTE_VALUE_LENGTH_LIMIT", ), Events: firstEnv(128, "OTEL_SPAN_EVENT_COUNT_LIMIT"), EventAttrs: firstEnv(128, "OTEL_EVENT_ATTRIBUTE_COUNT_LIMIT"), Links: firstEnv(128, "OTEL_SPAN_LINK_COUNT_LIMIT"), LinkAttrs: firstEnv(128, "OTEL_LINK_ATTRIBUTE_COUNT_LIMIT"), } } // firstEnv returns the parsed integer value of the first matching environment // variable from keys. The defaultVal is returned if the value is not an // integer or no match is found. func firstEnv(defaultVal int, keys ...string) int { for _, key := range keys { strV := os.Getenv(key) if strV == "" { continue } v, err := strconv.Atoi(strV) if err == nil { return v } // Ignore invalid environment variable. } return defaultVal }