robocar-steering-tflite-edg.../vendor/go.opentelemetry.io/otel/metric/internal/global/meter.go

348 lines
9.9 KiB
Go

// Copyright The OpenTelemetry 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 global // import "go.opentelemetry.io/otel/metric/internal/global"
import (
"context"
"sync"
"sync/atomic"
"go.opentelemetry.io/otel"
"go.opentelemetry.io/otel/metric"
"go.opentelemetry.io/otel/metric/instrument"
"go.opentelemetry.io/otel/metric/instrument/asyncfloat64"
"go.opentelemetry.io/otel/metric/instrument/asyncint64"
"go.opentelemetry.io/otel/metric/instrument/syncfloat64"
"go.opentelemetry.io/otel/metric/instrument/syncint64"
)
// meterProvider is a placeholder for a configured SDK MeterProvider.
//
// All MeterProvider functionality is forwarded to a delegate once
// configured.
type meterProvider struct {
mtx sync.Mutex
meters map[il]*meter
delegate metric.MeterProvider
}
type il struct {
name string
version string
}
// setDelegate configures p to delegate all MeterProvider functionality to
// provider.
//
// All Meters provided prior to this function call are switched out to be
// Meters provided by provider. All instruments and callbacks are recreated and
// delegated.
//
// It is guaranteed by the caller that this happens only once.
func (p *meterProvider) setDelegate(provider metric.MeterProvider) {
p.mtx.Lock()
defer p.mtx.Unlock()
p.delegate = provider
if len(p.meters) == 0 {
return
}
for _, meter := range p.meters {
meter.setDelegate(provider)
}
p.meters = nil
}
// Meter implements MeterProvider.
func (p *meterProvider) Meter(name string, opts ...metric.MeterOption) metric.Meter {
p.mtx.Lock()
defer p.mtx.Unlock()
if p.delegate != nil {
return p.delegate.Meter(name, opts...)
}
// At this moment it is guaranteed that no sdk is installed, save the meter in the meters map.
c := metric.NewMeterConfig(opts...)
key := il{
name: name,
version: c.InstrumentationVersion(),
}
if p.meters == nil {
p.meters = make(map[il]*meter)
}
if val, ok := p.meters[key]; ok {
return val
}
t := &meter{name: name, opts: opts}
p.meters[key] = t
return t
}
// meter is a placeholder for a metric.Meter.
//
// All Meter functionality is forwarded to a delegate once configured.
// Otherwise, all functionality is forwarded to a NoopMeter.
type meter struct {
name string
opts []metric.MeterOption
mtx sync.Mutex
instruments []delegatedInstrument
callbacks []delegatedCallback
delegate atomic.Value // metric.Meter
}
type delegatedInstrument interface {
setDelegate(metric.Meter)
}
// setDelegate configures m to delegate all Meter functionality to Meters
// created by provider.
//
// All subsequent calls to the Meter methods will be passed to the delegate.
//
// It is guaranteed by the caller that this happens only once.
func (m *meter) setDelegate(provider metric.MeterProvider) {
meter := provider.Meter(m.name, m.opts...)
m.delegate.Store(meter)
m.mtx.Lock()
defer m.mtx.Unlock()
for _, inst := range m.instruments {
inst.setDelegate(meter)
}
for _, callback := range m.callbacks {
callback.setDelegate(meter)
}
m.instruments = nil
m.callbacks = nil
}
// AsyncInt64 is the namespace for the Asynchronous Integer instruments.
//
// To Observe data with instruments it must be registered in a callback.
func (m *meter) AsyncInt64() asyncint64.InstrumentProvider {
if del, ok := m.delegate.Load().(metric.Meter); ok {
return del.AsyncInt64()
}
return (*aiInstProvider)(m)
}
// AsyncFloat64 is the namespace for the Asynchronous Float instruments.
//
// To Observe data with instruments it must be registered in a callback.
func (m *meter) AsyncFloat64() asyncfloat64.InstrumentProvider {
if del, ok := m.delegate.Load().(metric.Meter); ok {
return del.AsyncFloat64()
}
return (*afInstProvider)(m)
}
// RegisterCallback captures the function that will be called during Collect.
//
// It is only valid to call Observe within the scope of the passed function,
// and only on the instruments that were registered with this call.
func (m *meter) RegisterCallback(insts []instrument.Asynchronous, function func(context.Context)) error {
if del, ok := m.delegate.Load().(metric.Meter); ok {
insts = unwrapInstruments(insts)
return del.RegisterCallback(insts, function)
}
m.mtx.Lock()
defer m.mtx.Unlock()
m.callbacks = append(m.callbacks, delegatedCallback{
instruments: insts,
function: function,
})
return nil
}
type wrapped interface {
unwrap() instrument.Asynchronous
}
func unwrapInstruments(instruments []instrument.Asynchronous) []instrument.Asynchronous {
out := make([]instrument.Asynchronous, 0, len(instruments))
for _, inst := range instruments {
if in, ok := inst.(wrapped); ok {
out = append(out, in.unwrap())
} else {
out = append(out, inst)
}
}
return out
}
// SyncInt64 is the namespace for the Synchronous Integer instruments.
func (m *meter) SyncInt64() syncint64.InstrumentProvider {
if del, ok := m.delegate.Load().(metric.Meter); ok {
return del.SyncInt64()
}
return (*siInstProvider)(m)
}
// SyncFloat64 is the namespace for the Synchronous Float instruments.
func (m *meter) SyncFloat64() syncfloat64.InstrumentProvider {
if del, ok := m.delegate.Load().(metric.Meter); ok {
return del.SyncFloat64()
}
return (*sfInstProvider)(m)
}
type delegatedCallback struct {
instruments []instrument.Asynchronous
function func(context.Context)
}
func (c *delegatedCallback) setDelegate(m metric.Meter) {
insts := unwrapInstruments(c.instruments)
err := m.RegisterCallback(insts, c.function)
if err != nil {
otel.Handle(err)
}
}
type afInstProvider meter
// Counter creates an instrument for recording increasing values.
func (ip *afInstProvider) Counter(name string, opts ...instrument.Option) (asyncfloat64.Counter, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &afCounter{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
// UpDownCounter creates an instrument for recording changes of a value.
func (ip *afInstProvider) UpDownCounter(name string, opts ...instrument.Option) (asyncfloat64.UpDownCounter, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &afUpDownCounter{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
// Gauge creates an instrument for recording the current value.
func (ip *afInstProvider) Gauge(name string, opts ...instrument.Option) (asyncfloat64.Gauge, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &afGauge{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
type aiInstProvider meter
// Counter creates an instrument for recording increasing values.
func (ip *aiInstProvider) Counter(name string, opts ...instrument.Option) (asyncint64.Counter, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &aiCounter{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
// UpDownCounter creates an instrument for recording changes of a value.
func (ip *aiInstProvider) UpDownCounter(name string, opts ...instrument.Option) (asyncint64.UpDownCounter, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &aiUpDownCounter{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
// Gauge creates an instrument for recording the current value.
func (ip *aiInstProvider) Gauge(name string, opts ...instrument.Option) (asyncint64.Gauge, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &aiGauge{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
type sfInstProvider meter
// Counter creates an instrument for recording increasing values.
func (ip *sfInstProvider) Counter(name string, opts ...instrument.Option) (syncfloat64.Counter, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &sfCounter{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
// UpDownCounter creates an instrument for recording changes of a value.
func (ip *sfInstProvider) UpDownCounter(name string, opts ...instrument.Option) (syncfloat64.UpDownCounter, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &sfUpDownCounter{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
// Histogram creates an instrument for recording a distribution of values.
func (ip *sfInstProvider) Histogram(name string, opts ...instrument.Option) (syncfloat64.Histogram, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &sfHistogram{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
type siInstProvider meter
// Counter creates an instrument for recording increasing values.
func (ip *siInstProvider) Counter(name string, opts ...instrument.Option) (syncint64.Counter, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &siCounter{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
// UpDownCounter creates an instrument for recording changes of a value.
func (ip *siInstProvider) UpDownCounter(name string, opts ...instrument.Option) (syncint64.UpDownCounter, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &siUpDownCounter{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}
// Histogram creates an instrument for recording a distribution of values.
func (ip *siInstProvider) Histogram(name string, opts ...instrument.Option) (syncint64.Histogram, error) {
ip.mtx.Lock()
defer ip.mtx.Unlock()
ctr := &siHistogram{name: name, opts: opts}
ip.instruments = append(ip.instruments, ctr)
return ctr, nil
}