func TestPrintDistribution(t *testing.T) {
var (
quantiles = []int{50, 90, 95, 99}
h = expvar.NewHistogram("test_print_distribution", 0, 100, 3, quantiles...)
seed = int64(555)
mean = int64(5)
stdev = int64(1)
)
teststat.PopulateNormalHistogram(t, h, seed, mean, stdev)
var buf bytes.Buffer
metrics.PrintDistribution(&buf, h)
t.Logf("\n%s\n", buf.String())
// Count the number of bar chart characters.
// We should have ca. 100 in any distribution with a small-enough stdev.
var n int
for _, r := range buf.String() {
if r == '#' {
n++
}
}
if want, have, tol := 100, n, 5; int(math.Abs(float64(want-have))) > tol {
t.Errorf("want %d, have %d (tolerance %d)", want, have, tol)
}
}
func TestHistogramQuantiles(t *testing.T) {
metricName := "test_histogram"
quantiles := []int{50, 90, 95, 99}
h := expvar.NewHistogram(metricName, 0, 100, 3, quantiles...)
const seed, mean, stdev int64 = 424242, 50, 10
teststat.PopulateNormalHistogram(t, h, seed, mean, stdev)
teststat.AssertExpvarNormalHistogram(t, metricName, mean, stdev, quantiles)
}
func TestHistogramQuantiles(t *testing.T) {
var (
name = "test_histogram"
quantiles = []int{50, 90, 95, 99}
h = expvar.NewHistogram(name, 0, 100, 3, quantiles...).With(metrics.Field{Key: "ignored", Value: "field"})
)
const seed, mean, stdev int64 = 424242, 50, 10
teststat.PopulateNormalHistogram(t, h, seed, mean, stdev)
teststat.AssertExpvarNormalHistogram(t, name, mean, stdev, quantiles)
}
func TestInvalidQuantile(t *testing.T) {
defer func() {
if err := recover(); err == nil {
t.Errorf("expected panic, got none")
} else {
t.Logf("got expected panic: %v", err)
}
}()
expvar.NewHistogram("foo", 0.0, 100.0, 3, 50, 90, 95, 99, 101)
}
// NewMetricsExpvar initializes and returns a Metrics exposed over the expvar system.
func NewMetricsExpvar() Metrics {
return Metrics{
RequestCount: expvar.NewCounter("request_count"),
ResponseTime: metrics.NewTimeHistogram(
time.Microsecond,
expvar.NewHistogram("response_time", 0, int64(time.Second), sigfigs, quantiles...),
),
Uploads: expvar.NewCounter("uploads"),
UploadErrors: expvar.NewCounter("upload_errors"),
}
}
func NewHist(name string) metrics.Histogram {
var h metrics.Histogram
if name != "" && archaius.Conf.Collect {
h = expvar.NewHistogram(name, 1000, maxHistObservable, 1, []int{50, 99}...)
if sampleMap == nil {
sampleMap = make(map[metrics.Histogram][]int64)
}
sampleMap[h] = make([]int64, 0, sampleCount)
return h
}
return nil
}
func TestScaledHistogram(t *testing.T) {
quantiles := []int{50, 90, 99}
scale := int64(10)
metricName := "test_scaled_histogram"
var h metrics.Histogram
h = expvar.NewHistogram(metricName, 0, 1000, 3, quantiles...)
h = metrics.NewScaledHistogram(h, scale)
const seed, mean, stdev = 333, 500, 100 // input values
populateNormalHistogram(t, h, seed, mean, stdev) // will be scaled down
assertExpvarNormalHistogram(t, metricName, mean/scale, stdev/scale, quantiles)
}
func TestTimeHistogram(t *testing.T) {
const metricName string = "test_time_histogram"
quantiles := []int{50, 90, 99}
h0 := expvar.NewHistogram(metricName, 0, 200, 3, quantiles...)
h := metrics.NewTimeHistogram(time.Millisecond, h0)
const seed, mean, stdev int64 = 321, 100, 20
for i := 0; i < 4321; i++ {
sample := time.Duration(rand.NormFloat64()*float64(stdev)+float64(mean)) * time.Millisecond
h.Observe(sample)
}
assertExpvarNormalHistogram(t, metricName, mean, stdev, quantiles)
}
func TestScaledHistogram(t *testing.T) {
var (
quantiles = []int{50, 90, 99}
scale = int64(10)
metricName = "test_scaled_histogram"
)
var h metrics.Histogram
h = expvar.NewHistogram(metricName, 0, 1000, 3, quantiles...)
h = metrics.NewScaledHistogram(h, scale)
h = h.With(metrics.Field{Key: "a", Value: "b"})
const seed, mean, stdev = 333, 500, 100 // input values
teststat.PopulateNormalHistogram(t, h, seed, mean, stdev) // will be scaled down
assertExpvarNormalHistogram(t, metricName, mean/scale, stdev/scale, quantiles)
}
func TestMultiHistogram(t *testing.T) {
quantiles := []int{50, 90, 99}
h := metrics.NewMultiHistogram(
expvar.NewHistogram("omicron", 0, 100, 3, quantiles...),
prometheus.NewSummary(stdprometheus.SummaryOpts{
Namespace: "test",
Subsystem: "multi_histogram",
Name: "nu",
Help: "Nu histogram.",
}, []string{}),
)
const seed, mean, stdev int64 = 123, 50, 10
populateNormalHistogram(t, h, seed, mean, stdev)
assertExpvarNormalHistogram(t, "omicron", mean, stdev, quantiles)
assertPrometheusNormalHistogram(t, `test_multi_histogram_nu`, mean, stdev)
}
func TestTimeHistogram(t *testing.T) {
var (
metricName = "test_time_histogram"
minValue = int64(0)
maxValue = int64(200)
sigfigs = 3
quantiles = []int{50, 90, 99}
h = expvar.NewHistogram(metricName, minValue, maxValue, sigfigs, quantiles...)
th = metrics.NewTimeHistogram(time.Millisecond, h).With(metrics.Field{Key: "a", Value: "b"})
)
const seed, mean, stdev int64 = 321, 100, 20
for i := 0; i < 4321; i++ {
sample := time.Duration(rand.NormFloat64()*float64(stdev)+float64(mean)) * time.Millisecond
th.Observe(sample)
}
assertExpvarNormalHistogram(t, metricName, mean, stdev, quantiles)
}
func makeInstrumentation(namespace, name, helpCounter, helpDuration string) (metrics.Counter, metrics.TimeHistogram) {
counter := metrics.NewMultiCounter(
expvar.NewCounter(fmt.Sprintf("requests_%s", name)),
statsd.NewCounter(ioutil.Discard, fmt.Sprintf("requests_%s_total", name), time.Second),
prometheus.NewCounter(stdprometheus.CounterOpts{
Namespace: namespace,
Subsystem: name,
Name: "requests_total",
Help: helpCounter,
}, []string{}),
)
duration := metrics.NewTimeHistogram(time.Nanosecond, metrics.NewMultiHistogram(
expvar.NewHistogram(fmt.Sprintf("duration_%s_nanoseconds_total", name), 0, 1e9, 3, 50, 95, 99),
statsd.NewHistogram(ioutil.Discard, fmt.Sprintf("duration_%s_nanoseconds_total", name), time.Second),
prometheus.NewSummary(stdprometheus.SummaryOpts{
Namespace: namespace,
Subsystem: name,
Name: "duration_nanoseconds_total",
Help: helpDuration,
}, []string{}),
))
return counter, duration
}
func main() {
// Flag domain. Note that gRPC transitively registers flags via its import
// of glog. So, we define a new flag set, to keep those domains distinct.
fs := flag.NewFlagSet("", flag.ExitOnError)
var (
debugAddr = fs.String("debug.addr", ":8000", "Address for HTTP debug/instrumentation server")
httpAddr = fs.String("http.addr", ":8001", "Address for HTTP (JSON) server")
netrpcAddr = fs.String("netrpc.addr", ":8003", "Address for net/rpc server")
proxyHTTPAddr = fs.String("proxy.http.url", "", "if set, proxy requests over HTTP to this addsvc")
zipkinServiceName = fs.String("zipkin.service.name", "addsvc", "Zipkin service name")
zipkinCollectorAddr = fs.String("zipkin.collector.addr", "", "Zipkin Scribe collector address (empty will log spans)")
zipkinCollectorTimeout = fs.Duration("zipkin.collector.timeout", time.Second, "Zipkin collector timeout")
zipkinCollectorBatchSize = fs.Int("zipkin.collector.batch.size", 100, "Zipkin collector batch size")
zipkinCollectorBatchInterval = fs.Duration("zipkin.collector.batch.interval", time.Second, "Zipkin collector batch interval")
)
flag.Usage = fs.Usage // only show our flags
fs.Parse(os.Args[1:])
// `package log` domain
var logger kitlog.Logger
logger = kitlog.NewLogfmtLogger(os.Stderr)
logger = kitlog.NewContext(logger).With("ts", kitlog.DefaultTimestampUTC)
stdlog.SetOutput(kitlog.NewStdlibAdapter(logger)) // redirect stdlib logging to us
stdlog.SetFlags(0) // flags are handled in our logger
// `package metrics` domain
requests := metrics.NewMultiCounter(
expvar.NewCounter("requests"),
statsd.NewCounter(ioutil.Discard, "requests_total", time.Second),
prometheus.NewCounter(stdprometheus.CounterOpts{
Namespace: "addsvc",
Subsystem: "add",
Name: "requests_total",
Help: "Total number of received requests.",
}, []string{}),
)
duration := metrics.NewTimeHistogram(time.Nanosecond, metrics.NewMultiHistogram(
expvar.NewHistogram("duration_nanoseconds_total", 0, 1e9, 3, 50, 95, 99),
statsd.NewHistogram(ioutil.Discard, "duration_nanoseconds_total", time.Second),
prometheus.NewSummary(stdprometheus.SummaryOpts{
Namespace: "addsvc",
Subsystem: "add",
Name: "duration_nanoseconds_total",
Help: "Total nanoseconds spend serving requests.",
}, []string{}),
))
_, _ = requests, duration
// `package tracing` domain
zipkinHostPort := "localhost:1234" // TODO Zipkin makes overly simple assumptions about services
var zipkinCollector zipkin.Collector = loggingCollector{logger}
if *zipkinCollectorAddr != "" {
var err error
if zipkinCollector, err = zipkin.NewScribeCollector(
*zipkinCollectorAddr,
*zipkinCollectorTimeout,
zipkin.ScribeBatchSize(*zipkinCollectorBatchSize),
zipkin.ScribeBatchInterval(*zipkinCollectorBatchInterval),
zipkin.ScribeLogger(logger),
); err != nil {
logger.Log("err", err)
os.Exit(1)
}
}
zipkinMethodName := "add"
zipkinSpanFunc := zipkin.MakeNewSpanFunc(zipkinHostPort, *zipkinServiceName, zipkinMethodName)
// Our business and operational domain
var a add.Adder = pureAdd{}
if *proxyHTTPAddr != "" {
var e endpoint.Endpoint
e = add.NewAdderAddHTTPClient("GET", *proxyHTTPAddr, zipkin.ToRequest(zipkinSpanFunc))
e = zipkin.AnnotateClient(zipkinSpanFunc, zipkinCollector)(e)
a = add.MakeAdderClient(func(method string) endpoint.Endpoint {
if method != "Add" {
panic(fmt.Errorf("unknown method %s", method))
}
return e
})
}
// This could happen at endpoint level.
// a = logging(logger)(a)
// a = instrument(requests, duration)(a)
// Server domain
var e endpoint.Endpoint
e = add.MakeAdderEndpoints(a).Add
e = zipkin.AnnotateServer(zipkinSpanFunc, zipkinCollector)(e)
// Mechanical stuff
rand.Seed(time.Now().UnixNano())
root := context.Background()
errc := make(chan error)
go func() {
errc <- interrupt()
}()
// Transport: HTTP (debug/instrumentation)
go func() {
logger.Log("addr", *debugAddr, "transport", "debug")
errc <- http.ListenAndServe(*debugAddr, nil)
}()
// Transport: HTTP (JSON)
go func() {
ctx, cancel := context.WithCancel(root)
defer cancel()
before := []httptransport.RequestFunc{zipkin.ToContext(zipkinSpanFunc, logger)}
after := []httptransport.ResponseFunc{}
handler := add.MakeAdderAddHTTPBinding(ctx, e, before, after)
logger.Log("addr", *httpAddr, "transport", "HTTP/JSON")
errc <- http.ListenAndServe(*httpAddr, handler)
}()
// Transport: net/rpc
go func() {
ctx, cancel := context.WithCancel(root)
defer cancel()
s := rpc.NewServer()
s.RegisterName("Add", add.AdderAddNetrpcBinding{ctx, e})
s.HandleHTTP(rpc.DefaultRPCPath, rpc.DefaultDebugPath)
logger.Log("addr", *netrpcAddr, "transport", "net/rpc")
errc <- http.ListenAndServe(*netrpcAddr, s)
}()
logger.Log("fatal", <-errc)
}
func main() {
// Flag domain. Note that gRPC transitively registers flags via its import
// of glog. So, we define a new flag set, to keep those domains distinct.
fs := flag.NewFlagSet("", flag.ExitOnError)
var (
debugAddr = fs.String("debug.addr", ":8000", "Address for HTTP debug/instrumentation server")
httpAddr = fs.String("http.addr", ":8001", "Address for HTTP (JSON) server")
grpcAddr = fs.String("grpc.addr", ":8002", "Address for gRPC server")
netrpcAddr = fs.String("netrpc.addr", ":8003", "Address for net/rpc server")
thriftAddr = fs.String("thrift.addr", ":8004", "Address for Thrift server")
thriftProtocol = fs.String("thrift.protocol", "binary", "binary, compact, json, simplejson")
thriftBufferSize = fs.Int("thrift.buffer.size", 0, "0 for unbuffered")
thriftFramed = fs.Bool("thrift.framed", false, "true to enable framing")
proxyHTTPAddr = fs.String("proxy.http.url", "", "if set, proxy requests over HTTP to this addsvc")
zipkinServiceName = fs.String("zipkin.service.name", "addsvc", "Zipkin service name")
zipkinCollectorAddr = fs.String("zipkin.collector.addr", "", "Zipkin Scribe collector address (empty will log spans)")
zipkinCollectorTimeout = fs.Duration("zipkin.collector.timeout", time.Second, "Zipkin collector timeout")
zipkinCollectorBatchSize = fs.Int("zipkin.collector.batch.size", 100, "Zipkin collector batch size")
zipkinCollectorBatchInterval = fs.Duration("zipkin.collector.batch.interval", time.Second, "Zipkin collector batch interval")
)
flag.Usage = fs.Usage // only show our flags
fs.Parse(os.Args[1:])
// `package log` domain
var logger kitlog.Logger
logger = kitlog.NewLogfmtLogger(os.Stderr)
logger = kitlog.With(logger, "ts", kitlog.DefaultTimestampUTC)
stdlog.SetOutput(kitlog.NewStdlibAdapter(logger)) // redirect stdlib logging to us
stdlog.SetFlags(0) // flags are handled in our logger
// `package metrics` domain
requests := metrics.NewMultiCounter(
expvar.NewCounter("requests"),
statsd.NewCounter(ioutil.Discard, "requests_total", time.Second),
prometheus.NewCounter(stdprometheus.CounterOpts{
Namespace: "addsvc",
Subsystem: "add",
Name: "requests_total",
Help: "Total number of received requests.",
}, []string{}),
)
duration := metrics.NewTimeHistogram(time.Nanosecond, metrics.NewMultiHistogram(
expvar.NewHistogram("duration_nanoseconds_total", 0, 1e9, 3, 50, 95, 99),
statsd.NewHistogram(ioutil.Discard, "duration_nanoseconds_total", time.Second),
prometheus.NewSummary(stdprometheus.SummaryOpts{
Namespace: "addsvc",
Subsystem: "add",
Name: "duration_nanoseconds_total",
Help: "Total nanoseconds spend serving requests.",
}, []string{}),
))
// `package tracing` domain
zipkinHostPort := "localhost:1234" // TODO Zipkin makes overly simple assumptions about services
var zipkinCollector zipkin.Collector = loggingCollector{logger}
if *zipkinCollectorAddr != "" {
var err error
if zipkinCollector, err = zipkin.NewScribeCollector(
*zipkinCollectorAddr,
*zipkinCollectorTimeout,
*zipkinCollectorBatchSize,
*zipkinCollectorBatchInterval,
); err != nil {
logger.Log("err", err)
os.Exit(1)
}
}
zipkinMethodName := "add"
zipkinSpanFunc := zipkin.MakeNewSpanFunc(zipkinHostPort, *zipkinServiceName, zipkinMethodName)
zipkin.Log.Swap(logger) // log diagnostic/error details
// Our business and operational domain
var a Add = pureAdd
if *proxyHTTPAddr != "" {
var e endpoint.Endpoint
e = httpclient.NewClient("GET", *proxyHTTPAddr, zipkin.ToRequest(zipkinSpanFunc))
e = zipkin.AnnotateClient(zipkinSpanFunc, zipkinCollector)(e)
a = proxyAdd(e, logger)
}
a = logging(logger)(a)
a = instrument(requests, duration)(a)
// Server domain
var e endpoint.Endpoint
e = makeEndpoint(a)
e = zipkin.AnnotateServer(zipkinSpanFunc, zipkinCollector)(e)
// Mechanical stuff
rand.Seed(time.Now().UnixNano())
root := context.Background()
errc := make(chan error)
go func() {
errc <- interrupt()
}()
// Transport: HTTP (debug/instrumentation)
go func() {
logger.Log("addr", *debugAddr, "transport", "debug")
errc <- http.ListenAndServe(*debugAddr, nil)
}()
// Transport: HTTP (JSON)
go func() {
ctx, cancel := context.WithCancel(root)
defer cancel()
before := []httptransport.BeforeFunc{zipkin.ToContext(zipkinSpanFunc)}
after := []httptransport.AfterFunc{}
handler := makeHTTPBinding(ctx, e, before, after)
logger.Log("addr", *httpAddr, "transport", "HTTP/JSON")
errc <- http.ListenAndServe(*httpAddr, handler)
}()
// Transport: gRPC
go func() {
ln, err := net.Listen("tcp", *grpcAddr)
if err != nil {
errc <- err
return
}
s := grpc.NewServer() // uses its own context?
pb.RegisterAddServer(s, grpcBinding{e})
logger.Log("addr", *grpcAddr, "transport", "gRPC")
errc <- s.Serve(ln)
}()
// Transport: net/rpc
go func() {
ctx, cancel := context.WithCancel(root)
defer cancel()
s := rpc.NewServer()
s.RegisterName("addsvc", NetrpcBinding{ctx, e})
s.HandleHTTP(rpc.DefaultRPCPath, rpc.DefaultDebugPath)
logger.Log("addr", *netrpcAddr, "transport", "net/rpc")
errc <- http.ListenAndServe(*netrpcAddr, s)
}()
// Transport: Thrift
go func() {
ctx, cancel := context.WithCancel(root)
defer cancel()
var protocolFactory thrift.TProtocolFactory
switch *thriftProtocol {
case "binary":
protocolFactory = thrift.NewTBinaryProtocolFactoryDefault()
case "compact":
protocolFactory = thrift.NewTCompactProtocolFactory()
case "json":
protocolFactory = thrift.NewTJSONProtocolFactory()
case "simplejson":
protocolFactory = thrift.NewTSimpleJSONProtocolFactory()
default:
errc <- fmt.Errorf("invalid Thrift protocol %q", *thriftProtocol)
return
}
var transportFactory thrift.TTransportFactory
if *thriftBufferSize > 0 {
transportFactory = thrift.NewTBufferedTransportFactory(*thriftBufferSize)
} else {
transportFactory = thrift.NewTTransportFactory()
}
if *thriftFramed {
transportFactory = thrift.NewTFramedTransportFactory(transportFactory)
}
transport, err := thrift.NewTServerSocket(*thriftAddr)
if err != nil {
errc <- err
return
}
logger.Log("addr", *thriftAddr, "transport", "Thrift")
errc <- thrift.NewTSimpleServer4(
thriftadd.NewAddServiceProcessor(thriftBinding{ctx, e}),
transport,
transportFactory,
protocolFactory,
).Serve()
}()
logger.Log("fatal", <-errc)
}
// NewHistogram implements Provider.
func (p expvarProvider) NewHistogram(name string, buckets int) metrics.Histogram {
return expvar.NewHistogram(name, buckets)
}
func main() {
// Flag domain. Note that gRPC transitively registers flags via its import
// of glog. So, we define a new flag set, to keep those domains distinct.
fs := flag.NewFlagSet("", flag.ExitOnError)
var (
debugAddr = fs.String("debug.addr", ":8000", "Address for HTTP debug/instrumentation server")
httpAddr = fs.String("http.addr", ":8001", "Address for HTTP (JSON) server")
grpcAddr = fs.String("grpc.addr", ":8002", "Address for gRPC server")
netrpcAddr = fs.String("netrpc.addr", ":8003", "Address for net/rpc server")
thriftAddr = fs.String("thrift.addr", ":8004", "Address for Thrift server")
thriftProtocol = fs.String("thrift.protocol", "binary", "binary, compact, json, simplejson")
thriftBufferSize = fs.Int("thrift.buffer.size", 0, "0 for unbuffered")
thriftFramed = fs.Bool("thrift.framed", false, "true to enable framing")
// Supported OpenTracing backends
zipkinAddr = fs.String("zipkin.kafka.addr", "", "Enable Zipkin tracing via a Kafka server host:port")
appdashAddr = fs.String("appdash.addr", "", "Enable Appdash tracing via an Appdash server host:port")
lightstepAccessToken = fs.String("lightstep.token", "", "Enable LightStep tracing via a LightStep access token")
)
flag.Usage = fs.Usage // only show our flags
if err := fs.Parse(os.Args[1:]); err != nil {
fmt.Fprintf(os.Stderr, "%v", err)
os.Exit(1)
}
// package log
var logger log.Logger
{
logger = log.NewLogfmtLogger(os.Stderr)
logger = log.NewContext(logger).With("ts", log.DefaultTimestampUTC).With("caller", log.DefaultCaller)
stdlog.SetFlags(0) // flags are handled by Go kit's logger
stdlog.SetOutput(log.NewStdlibAdapter(logger)) // redirect anything using stdlib log to us
}
// package metrics
var requestDuration metrics.TimeHistogram
{
requestDuration = metrics.NewTimeHistogram(time.Nanosecond, metrics.NewMultiHistogram(
"request_duration_ns",
expvar.NewHistogram("request_duration_ns", 0, 5e9, 1, 50, 95, 99),
prometheus.NewSummary(stdprometheus.SummaryOpts{
Namespace: "myorg",
Subsystem: "addsvc",
Name: "duration_ns",
Help: "Request duration in nanoseconds.",
}, []string{"method"}),
))
}
// Set up OpenTracing
var tracer opentracing.Tracer
{
switch {
case *appdashAddr != "" && *lightstepAccessToken == "" && *zipkinAddr == "":
tracer = appdashot.NewTracer(appdash.NewRemoteCollector(*appdashAddr))
case *appdashAddr == "" && *lightstepAccessToken != "" && *zipkinAddr == "":
tracer = lightstep.NewTracer(lightstep.Options{
AccessToken: *lightstepAccessToken,
})
defer lightstep.FlushLightStepTracer(tracer)
case *appdashAddr == "" && *lightstepAccessToken == "" && *zipkinAddr != "":
collector, err := zipkin.NewKafkaCollector(
strings.Split(*zipkinAddr, ","),
zipkin.KafkaLogger(logger),
)
if err != nil {
logger.Log("err", "unable to create collector", "fatal", err)
os.Exit(1)
}
tracer, err = zipkin.NewTracer(
zipkin.NewRecorder(collector, false, "localhost:80", "addsvc"),
)
if err != nil {
logger.Log("err", "unable to create zipkin tracer", "fatal", err)
os.Exit(1)
}
case *appdashAddr == "" && *lightstepAccessToken == "" && *zipkinAddr == "":
tracer = opentracing.GlobalTracer() // no-op
default:
logger.Log("fatal", "specify a single -appdash.addr, -lightstep.access.token or -zipkin.kafka.addr")
os.Exit(1)
}
}
// Business domain
var svc server.AddService
{
svc = pureAddService{}
svc = loggingMiddleware{svc, logger}
svc = instrumentingMiddleware{svc, requestDuration}
}
// Mechanical stuff
rand.Seed(time.Now().UnixNano())
root := context.Background()
errc := make(chan error)
go func() {
errc <- interrupt()
}()
// Debug/instrumentation
go func() {
transportLogger := log.NewContext(logger).With("transport", "debug")
transportLogger.Log("addr", *debugAddr)
errc <- http.ListenAndServe(*debugAddr, nil) // DefaultServeMux
}()
// Transport: HTTP/JSON
go func() {
var (
transportLogger = log.NewContext(logger).With("transport", "HTTP/JSON")
tracingLogger = log.NewContext(transportLogger).With("component", "tracing")
mux = http.NewServeMux()
sum, concat endpoint.Endpoint
)
sum = makeSumEndpoint(svc)
sum = kitot.TraceServer(tracer, "sum")(sum)
mux.Handle("/sum", httptransport.NewServer(
root,
sum,
server.DecodeSumRequest,
server.EncodeSumResponse,
httptransport.ServerErrorLogger(transportLogger),
httptransport.ServerBefore(kitot.FromHTTPRequest(tracer, "sum", tracingLogger)),
))
concat = makeConcatEndpoint(svc)
concat = kitot.TraceServer(tracer, "concat")(concat)
mux.Handle("/concat", httptransport.NewServer(
root,
concat,
server.DecodeConcatRequest,
server.EncodeConcatResponse,
httptransport.ServerErrorLogger(transportLogger),
httptransport.ServerBefore(kitot.FromHTTPRequest(tracer, "concat", tracingLogger)),
))
transportLogger.Log("addr", *httpAddr)
errc <- http.ListenAndServe(*httpAddr, mux)
}()
// Transport: gRPC
go func() {
transportLogger := log.NewContext(logger).With("transport", "gRPC")
tracingLogger := log.NewContext(transportLogger).With("component", "tracing")
ln, err := net.Listen("tcp", *grpcAddr)
if err != nil {
errc <- err
return
}
s := grpc.NewServer() // uses its own, internal context
pb.RegisterAddServer(s, newGRPCBinding(root, tracer, svc, tracingLogger))
transportLogger.Log("addr", *grpcAddr)
errc <- s.Serve(ln)
}()
// Transport: net/rpc
go func() {
transportLogger := log.NewContext(logger).With("transport", "net/rpc")
s := rpc.NewServer()
if err := s.RegisterName("addsvc", netrpcBinding{svc}); err != nil {
errc <- err
return
}
s.HandleHTTP(rpc.DefaultRPCPath, rpc.DefaultDebugPath)
transportLogger.Log("addr", *netrpcAddr)
errc <- http.ListenAndServe(*netrpcAddr, s)
}()
// Transport: Thrift
go func() {
var protocolFactory thrift.TProtocolFactory
switch *thriftProtocol {
case "binary":
protocolFactory = thrift.NewTBinaryProtocolFactoryDefault()
case "compact":
protocolFactory = thrift.NewTCompactProtocolFactory()
case "json":
protocolFactory = thrift.NewTJSONProtocolFactory()
case "simplejson":
protocolFactory = thrift.NewTSimpleJSONProtocolFactory()
default:
errc <- fmt.Errorf("invalid Thrift protocol %q", *thriftProtocol)
return
}
var transportFactory thrift.TTransportFactory
if *thriftBufferSize > 0 {
transportFactory = thrift.NewTBufferedTransportFactory(*thriftBufferSize)
} else {
transportFactory = thrift.NewTTransportFactory()
}
if *thriftFramed {
transportFactory = thrift.NewTFramedTransportFactory(transportFactory)
}
transport, err := thrift.NewTServerSocket(*thriftAddr)
if err != nil {
errc <- err
return
}
transportLogger := log.NewContext(logger).With("transport", "thrift")
transportLogger.Log("addr", *thriftAddr)
errc <- thrift.NewTSimpleServer4(
thriftadd.NewAddServiceProcessor(thriftBinding{svc}),
transport,
transportFactory,
protocolFactory,
).Serve()
}()
logger.Log("fatal", <-errc)
}
func main() {
// Flag domain. Note that gRPC transitively registers flags via its import
// of glog. So, we define a new flag set, to keep those domains distinct.
fs := flag.NewFlagSet("", flag.ExitOnError)
var (
debugAddr = fs.String("debug.addr", ":8000", "Address for HTTP debug/instrumentation server")
httpAddr = fs.String("http.addr", ":8001", "Address for HTTP (JSON) server")
grpcAddr = fs.String("grpc.addr", ":8002", "Address for gRPC server")
netrpcAddr = fs.String("netrpc.addr", ":8003", "Address for net/rpc server")
thriftAddr = fs.String("thrift.addr", ":8004", "Address for Thrift server")
thriftProtocol = fs.String("thrift.protocol", "binary", "binary, compact, json, simplejson")
thriftBufferSize = fs.Int("thrift.buffer.size", 0, "0 for unbuffered")
thriftFramed = fs.Bool("thrift.framed", false, "true to enable framing")
zipkinHostPort = fs.String("zipkin.host.port", "my.service.domain:12345", "Zipkin host:port")
zipkinServiceName = fs.String("zipkin.service.name", "addsvc", "Zipkin service name")
zipkinCollectorAddr = fs.String("zipkin.collector.addr", "", "Zipkin Scribe collector address (empty will log spans)")
zipkinCollectorTimeout = fs.Duration("zipkin.collector.timeout", time.Second, "Zipkin collector timeout")
zipkinCollectorBatchSize = fs.Int("zipkin.collector.batch.size", 100, "Zipkin collector batch size")
zipkinCollectorBatchInterval = fs.Duration("zipkin.collector.batch.interval", time.Second, "Zipkin collector batch interval")
)
flag.Usage = fs.Usage // only show our flags
if err := fs.Parse(os.Args[1:]); err != nil {
fmt.Fprintf(os.Stderr, "%v", err)
os.Exit(1)
}
// package log
var logger log.Logger
{
logger = log.NewLogfmtLogger(os.Stderr)
logger = log.NewContext(logger).With("ts", log.DefaultTimestampUTC).With("caller", log.DefaultCaller)
stdlog.SetFlags(0) // flags are handled by Go kit's logger
stdlog.SetOutput(log.NewStdlibAdapter(logger)) // redirect anything using stdlib log to us
}
// package metrics
var requestDuration metrics.TimeHistogram
{
requestDuration = metrics.NewTimeHistogram(time.Nanosecond, metrics.NewMultiHistogram(
expvar.NewHistogram("request_duration_ns", 0, 5e9, 1, 50, 95, 99),
prometheus.NewSummary(stdprometheus.SummaryOpts{
Namespace: "myorg",
Subsystem: "addsvc",
Name: "duration_ns",
Help: "Request duration in nanoseconds.",
}, []string{"method"}),
))
}
// package tracing
var collector zipkin.Collector
{
zipkinLogger := log.NewContext(logger).With("component", "zipkin")
collector = loggingCollector{zipkinLogger} // TODO(pb)
if *zipkinCollectorAddr != "" {
var err error
if collector, err = zipkin.NewScribeCollector(
*zipkinCollectorAddr,
*zipkinCollectorTimeout,
zipkin.ScribeBatchSize(*zipkinCollectorBatchSize),
zipkin.ScribeBatchInterval(*zipkinCollectorBatchInterval),
zipkin.ScribeLogger(zipkinLogger),
); err != nil {
zipkinLogger.Log("err", err)
os.Exit(1)
}
}
}
// Business domain
var svc server.AddService
{
svc = pureAddService{}
svc = loggingMiddleware{svc, logger}
svc = instrumentingMiddleware{svc, requestDuration}
}
// Mechanical stuff
rand.Seed(time.Now().UnixNano())
root := context.Background()
errc := make(chan error)
go func() {
errc <- interrupt()
}()
// Debug/instrumentation
go func() {
transportLogger := log.NewContext(logger).With("transport", "debug")
transportLogger.Log("addr", *debugAddr)
errc <- http.ListenAndServe(*debugAddr, nil) // DefaultServeMux
}()
// Transport: HTTP/JSON
go func() {
var (
transportLogger = log.NewContext(logger).With("transport", "HTTP/JSON")
tracingLogger = log.NewContext(transportLogger).With("component", "tracing")
newSumSpan = zipkin.MakeNewSpanFunc(*zipkinHostPort, *zipkinServiceName, "sum")
newConcatSpan = zipkin.MakeNewSpanFunc(*zipkinHostPort, *zipkinServiceName, "concat")
traceSum = zipkin.ToContext(newSumSpan, tracingLogger)
traceConcat = zipkin.ToContext(newConcatSpan, tracingLogger)
mux = http.NewServeMux()
sum, concat endpoint.Endpoint
)
sum = makeSumEndpoint(svc)
sum = zipkin.AnnotateServer(newSumSpan, collector)(sum)
mux.Handle("/sum", httptransport.NewServer(
root,
sum,
server.DecodeSumRequest,
server.EncodeSumResponse,
httptransport.ServerBefore(traceSum),
httptransport.ServerErrorLogger(transportLogger),
))
concat = makeConcatEndpoint(svc)
concat = zipkin.AnnotateServer(newConcatSpan, collector)(concat)
mux.Handle("/concat", httptransport.NewServer(
root,
concat,
server.DecodeConcatRequest,
server.EncodeConcatResponse,
httptransport.ServerBefore(traceConcat),
httptransport.ServerErrorLogger(transportLogger),
))
transportLogger.Log("addr", *httpAddr)
errc <- http.ListenAndServe(*httpAddr, mux)
}()
// Transport: gRPC
go func() {
transportLogger := log.NewContext(logger).With("transport", "gRPC")
ln, err := net.Listen("tcp", *grpcAddr)
if err != nil {
errc <- err
return
}
s := grpc.NewServer() // uses its own, internal context
pb.RegisterAddServer(s, grpcBinding{svc})
transportLogger.Log("addr", *grpcAddr)
errc <- s.Serve(ln)
}()
// Transport: net/rpc
go func() {
transportLogger := log.NewContext(logger).With("transport", "net/rpc")
s := rpc.NewServer()
if err := s.RegisterName("addsvc", netrpcBinding{svc}); err != nil {
errc <- err
return
}
s.HandleHTTP(rpc.DefaultRPCPath, rpc.DefaultDebugPath)
transportLogger.Log("addr", *netrpcAddr)
errc <- http.ListenAndServe(*netrpcAddr, s)
}()
// Transport: Thrift
go func() {
var protocolFactory thrift.TProtocolFactory
switch *thriftProtocol {
case "binary":
protocolFactory = thrift.NewTBinaryProtocolFactoryDefault()
case "compact":
protocolFactory = thrift.NewTCompactProtocolFactory()
case "json":
protocolFactory = thrift.NewTJSONProtocolFactory()
case "simplejson":
protocolFactory = thrift.NewTSimpleJSONProtocolFactory()
default:
errc <- fmt.Errorf("invalid Thrift protocol %q", *thriftProtocol)
return
}
var transportFactory thrift.TTransportFactory
if *thriftBufferSize > 0 {
transportFactory = thrift.NewTBufferedTransportFactory(*thriftBufferSize)
} else {
transportFactory = thrift.NewTTransportFactory()
}
if *thriftFramed {
transportFactory = thrift.NewTFramedTransportFactory(transportFactory)
}
transport, err := thrift.NewTServerSocket(*thriftAddr)
if err != nil {
errc <- err
return
}
transportLogger := log.NewContext(logger).With("transport", "net/rpc")
transportLogger.Log("addr", *thriftAddr)
errc <- thrift.NewTSimpleServer4(
thriftadd.NewAddServiceProcessor(thriftBinding{svc}),
transport,
transportFactory,
protocolFactory,
).Serve()
}()
logger.Log("fatal", <-errc)
}
func main() {
fs := flag.NewFlagSet("", flag.ExitOnError)
var (
debugAddr = fs.String("debug.addr", ":8000", "Address for HTTP debug/instrumentation server")
httpAddr = fs.String("http.addr", ":8001", "Address for HTTP (JSON) server")
)
flag.Usage = fs.Usage // only show our flags
if err := fs.Parse(os.Args[1:]); err != nil {
fmt.Fprintf(os.Stderr, "%v", err)
os.Exit(1)
}
// package log
var logger log.Logger
{
logger = log.NewLogfmtLogger(os.Stderr)
logger = log.NewContext(logger).With("ts", log.DefaultTimestampUTC).With("caller", log.DefaultCaller)
stdlog.SetFlags(0) // flags are handled by Go kit's logger
stdlog.SetOutput(log.NewStdlibAdapter(logger)) // redirect anything using stdlib log to us
}
// package metrics
var requestDuration metrics.TimeHistogram
{
requestDuration = metrics.NewTimeHistogram(time.Nanosecond, metrics.NewMultiHistogram(
expvar.NewHistogram("request_duration_ns", 0, 5e9, 1, 50, 95, 99),
prometheus.NewSummary(stdprometheus.SummaryOpts{
Namespace: "myorg",
Subsystem: "addsvc",
Name: "duration_ns",
Help: "Request duration in nanoseconds.",
}, []string{"method"}),
))
}
// Business domain
var svc server.InfoService
{
svc = pureInfoService{}
svc = loggingMiddleware{svc, logger}
svc = instrumentingMiddleware{svc, requestDuration}
}
// Mechanical stuff
rand.Seed(time.Now().UnixNano())
root := context.Background()
errc := make(chan error)
go func() {
errc <- interrupt()
}()
// Debug/instrumentation
go func() {
transportLogger := log.NewContext(logger).With("transport", "debug")
_ = transportLogger.Log("addr", *debugAddr)
errc <- http.ListenAndServe(*debugAddr, nil) // DefaultServeMux
}()
// Transport: HTTP/JSON
go func() {
var (
transportLogger = log.NewContext(logger).With("transport", "HTTP/JSON")
mux = http.NewServeMux()
hello, host endpoint.Endpoint
)
hello = makeHelloEndpoint(svc)
mux.Handle("/hello", httptransport.NewServer(
root,
hello,
server.DecodeHelloRequest,
server.EncodeHelloResponse,
httptransport.ServerErrorLogger(transportLogger),
))
host = makeHostEndpoint(svc)
mux.Handle("/host", httptransport.NewServer(
root,
host,
server.DecodeHostRequest,
server.EncodeHostResponse,
httptransport.ServerErrorLogger(transportLogger),
))
_ = transportLogger.Log("addr", *httpAddr)
errc <- http.ListenAndServe(*httpAddr, mux)
}()
_ = logger.Log("fatal", <-errc)
}
func main() {
flag.Parse()
// package log
var logger log.Logger
{
logger = log.NewLogfmtLogger(os.Stderr)
logger = log.NewContext(logger).With("ts", log.DefaultTimestampUTC).With("caller", log.DefaultCaller)
stdlog.SetFlags(0) // flags are handled by Go kit's logger
stdlog.SetOutput(log.NewStdlibAdapter(logger)) // redirect anything using stdlib log to us
}
// package metrics
var (
requestCount metrics.Counter
requestLatency metrics.TimeHistogram
)
{
fieldKeys := []string{"method", "error"}
requestCount = kitprometheus.NewCounter(stdprometheus.CounterOpts{
Namespace: "gmuch",
Subsystem: "api",
Name: "request_count",
Help: "Number of requests received.",
}, fieldKeys)
requestLatency = metrics.NewTimeHistogram(time.Nanosecond, metrics.NewMultiHistogram(
expvar.NewHistogram("request_duration_ns", 0, 5e9, 1, 50, 95, 99),
kitprometheus.NewSummary(stdprometheus.SummaryOpts{
Namespace: "gmuch",
Subsystem: "api",
Name: "duration_ns",
Help: "Request duration in nanoseconds.",
}, fieldKeys),
))
}
// Business domain
var g server.GmuchService
{
g = gmuch.New(*dbPath, logger)
g = server.LoggingMiddleware(logger)(g)
g = server.InstrumentingMiddleware(requestCount, requestLatency)(g)
}
// Mechanical stuff
rand.Seed(time.Now().UnixNano())
root := context.Background()
errc := make(chan error)
go func() {
errc <- interrupt()
}()
// Debug/instrumentation
go func() {
transportLogger := log.NewContext(logger).With("transport", "debug")
_ = transportLogger.Log("addr", *debugAddr)
errc <- http.ListenAndServe(*debugAddr, nil) // DefaultServeMux
}()
// Transport: HTTP/JSON
go func() {
transportLogger := log.NewContext(logger).With("transport", "HTTP/JSON")
mux := http.NewServeMux()
mux.Handle("/query", httptransport.NewServer(
root,
shttp.EndpointenizeQuery(g),
shttp.DecodeQueryRequest,
shttp.EncodeQueryResponse,
httptransport.ServerErrorLogger(transportLogger),
))
mux.Handle("/thread", httptransport.NewServer(
root,
shttp.EndpointenizeThread(g),
shttp.DecodeThreadRequest,
shttp.EncodeThreadResponse,
httptransport.ServerErrorLogger(transportLogger),
))
_ = transportLogger.Log("addr", *httpAddr)
errc <- http.ListenAndServe(*httpAddr, mux)
}()
// Transport: gRPC
go func() {
transportLogger := log.NewContext(logger).With("transport", "gRPC")
ln, err := net.Listen("tcp", *grpcAddr)
if err != nil {
errc <- err
return
}
s := grpc.NewServer() // uses its own, internal context
sgrpc.RegisterGmuchServer(s, sgrpc.Binding{g})
_ = transportLogger.Log("addr", *grpcAddr)
errc <- s.Serve(ln)
}()
_ = logger.Log("fatal", <-errc)
}
