metrics, tsweb/varz: add multi-label map metrics

Updates tailscale/corp#18640 Change-Id: Ia9ae25956038e9d3266ea165537ac6f02485b74c Signed-off-by: Brad Fitzpatrick <bradfitz@tailscale.com>
8 months ago · 55baf9474f
parent 90a4d6ce69
commit 55baf9474f
4 changed files with 408 additions and 0 deletions
--- a/metrics/multilabelmap.go
+++ b/metrics/multilabelmap.go
@ -0,0 +1,259 @@
 // Copyright (c) Tailscale Inc & AUTHORS
 // SPDX-License-Identifier: BSD-3-Clause
 package metrics
 import (
 	"expvar"
 	"fmt"
 	"io"
 	"reflect"
 	"sort"
 	"strings"
 	"sync"
 )
 // MultiLabelMap is a struct-value-to-Var map variable that satisfies the
 // [expvar.Var] interface but also allows for multiple Prometheus labels to be
 // associated with each value.
 //
 // T must be a struct type with only string fields. The struct field names
 // (lowercased) are used as the labels, unless a "prom" struct tag is present.
 // The struct fields must all be strings, and the string values must be valid
 // Prometheus label values without requiring quoting.
 type MultiLabelMap[T comparable] struct {
 	Type string // optional Prometheus type ("counter", "gauge")
 	Help string // optional Prometheus help string
 	m sync.Map // map[T]expvar.Var
 	mu     sync.RWMutex
 	sorted []labelsAndValue[T] // by labels string, to match expvar.Map + for aesthetics in output
 }
 // NewMultiLabelMap creates and publishes (via expvar.Publish) a new
 // MultiLabelMap[T] variable with the given name and returns it.
 func NewMultiLabelMap[T comparable](name string, promType, helpText string) *MultiLabelMap[T] {
 	m := &MultiLabelMap[T]{
 		Type: promType,
 		Help: helpText,
 	}
 	expvar.Publish(name, m)
 	return m
 }
 type labelsAndValue[T comparable] struct {
 	key    T
 	labels string // Prometheus-formatted {label="value",label="value"} string
 	val    expvar.Var
 }
 // labelString returns a Prometheus-formatted label string for the given key.
 func labelString(k any) string {
 	rv := reflect.ValueOf(k)
 	t := rv.Type()
 	if t.Kind() != reflect.Struct {
 		panic(fmt.Sprintf("MultiLabelMap must use keys of type struct; got %v", t))
 	}
 	var sb strings.Builder
 	sb.WriteString("{")
 	for i := 0; i < t.NumField(); i++ {
 		if i > 0 {
 			sb.WriteString(",")
 		}
 		ft := t.Field(i)
 		label := ft.Tag.Get("prom")
 		if label == "" {
 			label = strings.ToLower(ft.Name)
 		}
 		fv := rv.Field(i)
 		switch fv.Kind() {
 		case reflect.String:
 			fmt.Fprintf(&sb, "%s=%q", label, fv.String())
 		case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
 			fmt.Fprintf(&sb, "%s=\"%d\"", label, fv.Int())
 		case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64:
 			fmt.Fprintf(&sb, "%s=\"%d\"", label, fv.Uint())
 		case reflect.Bool:
 			fmt.Fprintf(&sb, "%s=\"%v\"", label, fv.Bool())
 		default:
 			panic(fmt.Sprintf("MultiLabelMap key field %q has unsupported type %v", ft.Name, fv.Type()))
 		}
 	}
 	sb.WriteString("}")
 	return sb.String()
 }
 // KeyValue represents a single entry in a [MultiLabelMap].
 type KeyValue[T comparable] struct {
 	Key   T
 	Value expvar.Var
 }
 func (v *MultiLabelMap[T]) String() string {
 	return `"MultiLabelMap"`
 }
 // WritePrometheus writes v to w in Prometheus exposition format.
 // The name argument is the metric name.
 func (v *MultiLabelMap[T]) WritePrometheus(w io.Writer, name string) {
 	if v.Type != "" {
 		io.WriteString(w, "# TYPE ")
 		io.WriteString(w, name)
 		io.WriteString(w, " ")
 		io.WriteString(w, v.Type)
 		io.WriteString(w, "\n")
 	}
 	if v.Help != "" {
 		io.WriteString(w, "# HELP ")
 		io.WriteString(w, name)
 		io.WriteString(w, " ")
 		io.WriteString(w, v.Help)
 		io.WriteString(w, "\n")
 	}
 	v.mu.RLock()
 	defer v.mu.RUnlock()
 	for _, kv := range v.sorted {
 		io.WriteString(w, name)
 		io.WriteString(w, kv.labels)
 		switch v := kv.val.(type) {
 		case *expvar.Int:
 			fmt.Fprintf(w, " %d\n", v.Value())
 		case *expvar.Float:
 			fmt.Fprintf(w, " %v\n", v.Value())
 		default:
 			fmt.Fprintf(w, " %s\n", kv.val)
 		}
 	}
 }
 // Init removes all keys from the map.
 //
 // Think of it as "Reset", but it's named Init to match expvar.Map.Init.
 func (v *MultiLabelMap[T]) Init() *MultiLabelMap[T] {
 	v.mu.Lock()
 	defer v.mu.Unlock()
 	v.sorted = nil
 	v.m.Range(func(k, _ any) bool {
 		v.m.Delete(k)
 		return true
 	})
 	return v
 }
 // addKeyLocked updates the sorted list of keys in v.keys.
 //
 // v.mu must be held.
 func (v *MultiLabelMap[T]) addKeyLocked(key T, val expvar.Var) {
 	ls := labelString(key)
 	ent := labelsAndValue[T]{key, ls, val}
 	// Using insertion sort to place key into the already-sorted v.keys.
 	i := sort.Search(len(v.sorted), func(i int) bool {
 		return v.sorted[i].labels >= ls
 	})
 	if i >= len(v.sorted) {
 		v.sorted = append(v.sorted, ent)
 	} else if v.sorted[i].key == key {
 		v.sorted[i].val = val
 	} else {
 		var zero labelsAndValue[T]
 		v.sorted = append(v.sorted, zero)
 		copy(v.sorted[i+1:], v.sorted[i:])
 		v.sorted[i] = ent
 	}
 }
 // Get returns the expvar for the given key, or nil if it doesn't exist.
 func (v *MultiLabelMap[T]) Get(key T) expvar.Var {
 	i, _ := v.m.Load(key)
 	av, _ := i.(expvar.Var)
 	return av
 }
 func newInt() expvar.Var   { return new(expvar.Int) }
 func newFloat() expvar.Var { return new(expvar.Float) }
 // getOrFill returns the expvar.Var for the given key, atomically creating it
 // once (for all callers) with fill if it doesn't exist.
 func (v *MultiLabelMap[T]) getOrFill(key T, fill func() expvar.Var) expvar.Var {
 	if v := v.Get(key); v != nil {
 		return v
 	}
 	v.mu.Lock()
 	defer v.mu.Unlock()
 	if v := v.Get(key); v != nil {
 		return v
 	}
 	nv := fill()
 	v.addKeyLocked(key, nv)
 	v.m.Store(key, nv)
 	return nv
 }
 // Set sets key to val.
 //
 // This is not optimized for highly concurrent usage; it's presumed to only be
 // used rarely, at startup.
 func (v *MultiLabelMap[T]) Set(key T, val expvar.Var) {
 	v.mu.Lock()
 	defer v.mu.Unlock()
 	v.addKeyLocked(key, val)
 	v.m.Store(key, val)
 }
 // Add adds delta to the *[expvar.Int] value stored under the given map key,
 // creating it if it doesn't exist yet.
 // It does nothing if key exists but is of the wrong type.
 func (v *MultiLabelMap[T]) Add(key T, delta int64) {
 	// Add to Int; ignore otherwise.
 	if iv, ok := v.getOrFill(key, newInt).(*expvar.Int); ok {
 		iv.Add(delta)
 	}
 }
 // Add adds delta to the *[expvar.Float] value stored under the given map key,
 // creating it if it doesn't exist yet.
 // It does nothing if key exists but is of the wrong type.
 func (v *MultiLabelMap[T]) AddFloat(key T, delta float64) {
 	// Add to Float; ignore otherwise.
 	if iv, ok := v.getOrFill(key, newFloat).(*expvar.Float); ok {
 		iv.Add(delta)
 	}
 }
 // Delete deletes the given key from the map.
 //
 // This is not optimized for highly concurrent usage; it's presumed to only be
 // used rarely, at startup.
 func (v *MultiLabelMap[T]) Delete(key T) {
 	ls := labelString(key)
 	v.mu.Lock()
 	defer v.mu.Unlock()
 	// Using insertion sort to place key into the already-sorted v.keys.
 	i := sort.Search(len(v.sorted), func(i int) bool {
 		return v.sorted[i].labels >= ls
 	})
 	if i < len(v.sorted) && v.sorted[i].key == key {
 		v.sorted = append(v.sorted[:i], v.sorted[i+1:]...)
 		v.m.Delete(key)
 	}
 }
 // Do calls f for each entry in the map.
 // The map is locked during the iteration,
 // but existing entries may be concurrently updated.
 func (v *MultiLabelMap[T]) Do(f func(KeyValue[T])) {
 	v.mu.RLock()
 	defer v.mu.RUnlock()
 	for _, e := range v.sorted {
 		f(KeyValue[T]{e.key, e.val})
 	}
 }
--- a/metrics/multilabelmap_test.go
+++ b/metrics/multilabelmap_test.go
@ -0,0 +1,121 @@
 // Copyright (c) Tailscale Inc & AUTHORS
 // SPDX-License-Identifier: BSD-3-Clause
 package metrics
 import (
 	"bytes"
 	"fmt"
 	"io"
 	"testing"
 )
 type L2 struct {
 	Foo string `prom:"foo"`
 	Bar string `prom:"bar"`
 }
 func TestMultilabelMap(t *testing.T) {
 	m := new(MultiLabelMap[L2])
 	m.Add(L2{"a", "b"}, 2)
 	m.Add(L2{"b", "c"}, 4)
 	m.Add(L2{"b", "b"}, 3)
 	m.Add(L2{"a", "a"}, 1)
 	cur := func() string {
 		var buf bytes.Buffer
 		m.Do(func(kv KeyValue[L2]) {
 			if buf.Len() > 0 {
 				buf.WriteString(",")
 			}
 			fmt.Fprintf(&buf, "%s/%s=%v", kv.Key.Foo, kv.Key.Bar, kv.Value)
 		})
 		return buf.String()
 	}
 	if g, w := cur(), "a/a=1,a/b=2,b/b=3,b/c=4"; g != w {
 		t.Errorf("got %q; want %q", g, w)
 	}
 	var buf bytes.Buffer
 	m.WritePrometheus(&buf, "metricname")
 	const want = `metricname{foo="a",bar="a"} 1
 metricname{foo="a",bar="b"} 2
 metricname{foo="b",bar="b"} 3
 metricname{foo="b",bar="c"} 4
 `
 	if got := buf.String(); got != want {
 		t.Errorf("promtheus output = %q; want %q", got, want)
 	}
 	m.Delete(L2{"b", "b"})
 	if g, w := cur(), "a/a=1,a/b=2,b/c=4"; g != w {
 		t.Errorf("got %q; want %q", g, w)
 	}
 	allocs := testing.AllocsPerRun(1000, func() {
 		m.Add(L2{"a", "a"}, 1)
 	})
 	if allocs > 0 {
 		t.Errorf("allocs = %v; want 0", allocs)
 	}
 	m.Init()
 	if g, w := cur(), ""; g != w {
 		t.Errorf("got %q; want %q", g, w)
 	}
 	writeAllocs := testing.AllocsPerRun(1000, func() {
 		m.WritePrometheus(io.Discard, "test")
 	})
 	if writeAllocs > 0 {
 		t.Errorf("writeAllocs = %v; want 0", writeAllocs)
 	}
 }
 func TestMultiLabelMapTypes(t *testing.T) {
 	type LabelTypes struct {
 		S string
 		B bool
 		I int
 		U uint
 	}
 	m := new(MultiLabelMap[LabelTypes])
 	m.Type = "counter"
 	m.Help = "some good stuff"
 	m.Add(LabelTypes{"a", true, -1, 2}, 3)
 	var buf bytes.Buffer
 	m.WritePrometheus(&buf, "metricname")
 	const want = `# TYPE metricname counter
 # HELP metricname some good stuff
 metricname{s="a",b="true",i="-1",u="2"} 3
 `
 	if got := buf.String(); got != want {
 		t.Errorf("got %q; want %q", got, want)
 	}
 	writeAllocs := testing.AllocsPerRun(1000, func() {
 		m.WritePrometheus(io.Discard, "test")
 	})
 	if writeAllocs > 0 {
 		t.Errorf("writeAllocs = %v; want 0", writeAllocs)
 	}
 }
 func BenchmarkMultiLabelWriteAllocs(b *testing.B) {
 	b.ReportAllocs()
 	m := new(MultiLabelMap[L2])
 	m.Add(L2{"a", "b"}, 2)
 	m.Add(L2{"b", "c"}, 4)
 	m.Add(L2{"b", "b"}, 3)
 	m.Add(L2{"a", "a"}, 1)
 	var w io.Writer = io.Discard
 	b.ResetTimer()
 	for range b.N {
 		m.WritePrometheus(w, "test")
 	}
 }
--- a/tsweb/varz/varz.go
+++ b/tsweb/varz/varz.go
@ -133,6 +133,9 @@ func writePromExpVar(w io.Writer, prefix string, kv expvar.KeyValue) {
 			writePromExpVar(w, name+"_", kv)
 		})
 		return
 	case PrometheusWriter:
 		v.WritePrometheus(w, name)
 		return
 	case PrometheusMetricsReflectRooter:
 		root := v.PrometheusMetricsReflectRoot()
 		rv := reflect.ValueOf(root)
@ -233,6 +236,14 @@ func writePromExpVar(w io.Writer, prefix string, kv expvar.KeyValue) {
 	}
 }
 // PrometheusWriter is the interface implemented by metrics that can write
 // themselves into Prometheus exposition format.
 //
 // As of 2024-03-25, this is only *metrics.MultiLabelMap.
 type PrometheusWriter interface {
 	WritePrometheus(w io.Writer, name string)
 }
 var sortedKVsPool = &sync.Pool{New: func() any { return new(sortedKVs) }}
 // sortedKV is a KeyValue with a sort key.
--- a/tsweb/varz/varz_test.go
+++ b/tsweb/varz/varz_test.go
@ -25,6 +25,11 @@ func TestVarzHandler(t *testing.T) {
 	half := new(expvar.Float)
 	half.Set(0.5)
 	type L2 struct {
 		Foo string `prom:"foo"`
 		Bar string `prom:"bar"`
 	}
 	tests := []struct {
 		name string
 		k    string // key name
@ -193,6 +198,18 @@ func TestVarzHandler(t *testing.T) {
 			})(),
 			"foo{label=\"a\"} 1\n",
 		},
 		{
 			"metrics_multilabel_map",
 			"foo",
 			(func() *metrics.MultiLabelMap[L2] {
 				m := new(metrics.MultiLabelMap[L2])
 				m.Add(L2{"a", "b"}, 1)
 				m.Add(L2{"c", "d"}, 2)
 				return m
 			})(),
 			"foo{foo=\"a\",bar=\"b\"} 1\n" +
 				"foo{foo=\"c\",bar=\"d\"} 2\n",
 		},
 		{
 			"expvar_label_map",
 			"counter_labelmap_keyname_m",