package statsd import ( "bytes" "errors" "fmt" "net" "testing" "time" "github.com/influxdata/telegraf/testutil" "github.com/stretchr/testify/assert" "github.com/stretchr/testify/require" ) const ( testMsg = "test.tcp.msg:100|c" ) func newTestTcpListener() (*Statsd, chan *bytes.Buffer) { in := make(chan *bytes.Buffer, 1500) listener := &Statsd{ Protocol: "tcp", ServiceAddress: "localhost:8125", AllowedPendingMessages: 10000, MaxTCPConnections: 250, in: in, done: make(chan struct{}), } return listener, in } func NewTestStatsd() *Statsd { s := Statsd{} // Make data structures s.done = make(chan struct{}) s.in = make(chan *bytes.Buffer, s.AllowedPendingMessages) s.gauges = make(map[string]cachedgauge) s.counters = make(map[string]cachedcounter) s.sets = make(map[string]cachedset) s.timings = make(map[string]cachedtimings) s.MetricSeparator = "_" return &s } // Test that MaxTCPConections is respected func TestConcurrentConns(t *testing.T) { listener := Statsd{ Protocol: "tcp", ServiceAddress: "localhost:8125", AllowedPendingMessages: 10000, MaxTCPConnections: 2, } acc := &testutil.Accumulator{} require.NoError(t, listener.Start(acc)) defer listener.Stop() time.Sleep(time.Millisecond * 250) _, err := net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) _, err = net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) // Connection over the limit: conn, err := net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) _, err = conn.Write([]byte(testMsg)) assert.NoError(t, err) time.Sleep(time.Millisecond * 100) assert.Zero(t, acc.NFields()) } // Test that MaxTCPConections is respected when max==1 func TestConcurrentConns1(t *testing.T) { listener := Statsd{ Protocol: "tcp", ServiceAddress: "localhost:8125", AllowedPendingMessages: 10000, MaxTCPConnections: 1, } acc := &testutil.Accumulator{} require.NoError(t, listener.Start(acc)) defer listener.Stop() time.Sleep(time.Millisecond * 250) _, err := net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) // Connection over the limit: conn, err := net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) _, err = conn.Write([]byte(testMsg)) assert.NoError(t, err) time.Sleep(time.Millisecond * 100) assert.Zero(t, acc.NFields()) } // Test that MaxTCPConections is respected func TestCloseConcurrentConns(t *testing.T) { listener := Statsd{ Protocol: "tcp", ServiceAddress: "localhost:8125", AllowedPendingMessages: 10000, MaxTCPConnections: 2, } acc := &testutil.Accumulator{} require.NoError(t, listener.Start(acc)) time.Sleep(time.Millisecond * 250) _, err := net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) _, err = net.Dial("tcp", "127.0.0.1:8125") assert.NoError(t, err) listener.Stop() } // benchmark how long it takes to accept & process 100,000 metrics: func BenchmarkUDP(b *testing.B) { listener := Statsd{ Protocol: "udp", ServiceAddress: "localhost:8125", AllowedPendingMessages: 250000, } acc := &testutil.Accumulator{Discard: true} // send multiple messages to socket for n := 0; n < b.N; n++ { err := listener.Start(acc) if err != nil { panic(err) } time.Sleep(time.Millisecond * 250) conn, err := net.Dial("udp", "127.0.0.1:8125") if err != nil { panic(err) } for i := 0; i < 250000; i++ { fmt.Fprintf(conn, testMsg) } // wait for 250,000 metrics to get added to accumulator time.Sleep(time.Millisecond) listener.Stop() } } // benchmark how long it takes to accept & process 100,000 metrics: func BenchmarkTCP(b *testing.B) { listener := Statsd{ Protocol: "tcp", ServiceAddress: "localhost:8125", AllowedPendingMessages: 250000, MaxTCPConnections: 250, } acc := &testutil.Accumulator{Discard: true} // send multiple messages to socket for n := 0; n < b.N; n++ { err := listener.Start(acc) if err != nil { panic(err) } time.Sleep(time.Millisecond * 250) conn, err := net.Dial("tcp", "127.0.0.1:8125") if err != nil { panic(err) } for i := 0; i < 250000; i++ { fmt.Fprintf(conn, testMsg) } // wait for 250,000 metrics to get added to accumulator time.Sleep(time.Millisecond) listener.Stop() } } // Valid lines should be parsed and their values should be cached func TestParse_ValidLines(t *testing.T) { s := NewTestStatsd() valid_lines := []string{ "valid:45|c", "valid:45|s", "valid:45|g", "valid.timer:45|ms", "valid.timer:45|h", } for _, line := range valid_lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } } // Tests low-level functionality of gauges func TestParse_Gauges(t *testing.T) { s := NewTestStatsd() // Test that gauge +- values work valid_lines := []string{ "plus.minus:100|g", "plus.minus:-10|g", "plus.minus:+30|g", "plus.plus:100|g", "plus.plus:+100|g", "plus.plus:+100|g", "minus.minus:100|g", "minus.minus:-100|g", "minus.minus:-100|g", "lone.plus:+100|g", "lone.minus:-100|g", "overwrite:100|g", "overwrite:300|g", "scientific.notation:4.696E+5|g", "scientific.notation.minus:4.7E-5|g", } for _, line := range valid_lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } validations := []struct { name string value float64 }{ { "scientific_notation", 469600, }, { "scientific_notation_minus", 0.000047, }, { "plus_minus", 120, }, { "plus_plus", 300, }, { "minus_minus", -100, }, { "lone_plus", 100, }, { "lone_minus", -100, }, { "overwrite", 300, }, } for _, test := range validations { err := test_validate_gauge(test.name, test.value, s.gauges) if err != nil { t.Error(err.Error()) } } } // Tests low-level functionality of sets func TestParse_Sets(t *testing.T) { s := NewTestStatsd() // Test that sets work valid_lines := []string{ "unique.user.ids:100|s", "unique.user.ids:100|s", "unique.user.ids:100|s", "unique.user.ids:100|s", "unique.user.ids:100|s", "unique.user.ids:101|s", "unique.user.ids:102|s", "unique.user.ids:102|s", "unique.user.ids:123456789|s", "oneuser.id:100|s", "oneuser.id:100|s", "scientific.notation.sets:4.696E+5|s", "scientific.notation.sets:4.696E+5|s", "scientific.notation.sets:4.697E+5|s", "string.sets:foobar|s", "string.sets:foobar|s", "string.sets:bar|s", } for _, line := range valid_lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } validations := []struct { name string value int64 }{ { "scientific_notation_sets", 2, }, { "unique_user_ids", 4, }, { "oneuser_id", 1, }, { "string_sets", 2, }, } for _, test := range validations { err := test_validate_set(test.name, test.value, s.sets) if err != nil { t.Error(err.Error()) } } } // Tests low-level functionality of counters func TestParse_Counters(t *testing.T) { s := NewTestStatsd() // Test that counters work valid_lines := []string{ "small.inc:1|c", "big.inc:100|c", "big.inc:1|c", "big.inc:100000|c", "big.inc:1000000|c", "small.inc:1|c", "zero.init:0|c", "sample.rate:1|c|@0.1", "sample.rate:1|c", "scientific.notation:4.696E+5|c", "negative.test:100|c", "negative.test:-5|c", } for _, line := range valid_lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } validations := []struct { name string value int64 }{ { "scientific_notation", 469600, }, { "small_inc", 2, }, { "big_inc", 1100101, }, { "zero_init", 0, }, { "sample_rate", 11, }, { "negative_test", 95, }, } for _, test := range validations { err := test_validate_counter(test.name, test.value, s.counters) if err != nil { t.Error(err.Error()) } } } // Tests low-level functionality of timings func TestParse_Timings(t *testing.T) { s := NewTestStatsd() s.Percentiles = []int{90} acc := &testutil.Accumulator{} // Test that counters work valid_lines := []string{ "test.timing:1|ms", "test.timing:11|ms", "test.timing:1|ms", "test.timing:1|ms", "test.timing:1|ms", } for _, line := range valid_lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } s.Gather(acc) valid := map[string]interface{}{ "90_percentile": float64(11), "count": int64(5), "lower": float64(1), "mean": float64(3), "stddev": float64(4), "sum": float64(15), "upper": float64(11), } acc.AssertContainsFields(t, "test_timing", valid) } func TestParseScientificNotation(t *testing.T) { s := NewTestStatsd() sciNotationLines := []string{ "scientific.notation:4.6968460083008E-5|ms", "scientific.notation:4.6968460083008E-5|g", "scientific.notation:4.6968460083008E-5|c", "scientific.notation:4.6968460083008E-5|h", } for _, line := range sciNotationLines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line [%s] should not have resulted in error: %s\n", line, err) } } } // Invalid lines should return an error func TestParse_InvalidLines(t *testing.T) { s := NewTestStatsd() invalid_lines := []string{ "i.dont.have.a.pipe:45g", "i.dont.have.a.colon45|c", "invalid.metric.type:45|e", "invalid.plus.minus.non.gauge:+10|s", "invalid.plus.minus.non.gauge:+10|ms", "invalid.plus.minus.non.gauge:+10|h", "invalid.value:foobar|c", "invalid.value:d11|c", "invalid.value:1d1|c", } for _, line := range invalid_lines { err := s.parseStatsdLine(line) if err == nil { t.Errorf("Parsing line %s should have resulted in an error\n", line) } } } // Invalid sample rates should be ignored and not applied func TestParse_InvalidSampleRate(t *testing.T) { s := NewTestStatsd() invalid_lines := []string{ "invalid.sample.rate:45|c|0.1", "invalid.sample.rate.2:45|c|@foo", "invalid.sample.rate:45|g|@0.1", "invalid.sample.rate:45|s|@0.1", } for _, line := range invalid_lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } counter_validations := []struct { name string value int64 cache map[string]cachedcounter }{ { "invalid_sample_rate", 45, s.counters, }, { "invalid_sample_rate_2", 45, s.counters, }, } for _, test := range counter_validations { err := test_validate_counter(test.name, test.value, test.cache) if err != nil { t.Error(err.Error()) } } err := test_validate_gauge("invalid_sample_rate", 45, s.gauges) if err != nil { t.Error(err.Error()) } err = test_validate_set("invalid_sample_rate", 1, s.sets) if err != nil { t.Error(err.Error()) } } // Names should be parsed like . -> _ func TestParse_DefaultNameParsing(t *testing.T) { s := NewTestStatsd() valid_lines := []string{ "valid:1|c", "valid.foo-bar:11|c", } for _, line := range valid_lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } validations := []struct { name string value int64 }{ { "valid", 1, }, { "valid_foo-bar", 11, }, } for _, test := range validations { err := test_validate_counter(test.name, test.value, s.counters) if err != nil { t.Error(err.Error()) } } } // Test that template name transformation works func TestParse_Template(t *testing.T) { s := NewTestStatsd() s.Templates = []string{ "measurement.measurement.host.service", } lines := []string{ "cpu.idle.localhost:1|c", "cpu.busy.host01.myservice:11|c", } for _, line := range lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } validations := []struct { name string value int64 }{ { "cpu_idle", 1, }, { "cpu_busy", 11, }, } // Validate counters for _, test := range validations { err := test_validate_counter(test.name, test.value, s.counters) if err != nil { t.Error(err.Error()) } } } // Test that template filters properly func TestParse_TemplateFilter(t *testing.T) { s := NewTestStatsd() s.Templates = []string{ "cpu.idle.* measurement.measurement.host", } lines := []string{ "cpu.idle.localhost:1|c", "cpu.busy.host01.myservice:11|c", } for _, line := range lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } validations := []struct { name string value int64 }{ { "cpu_idle", 1, }, { "cpu_busy_host01_myservice", 11, }, } // Validate counters for _, test := range validations { err := test_validate_counter(test.name, test.value, s.counters) if err != nil { t.Error(err.Error()) } } } // Test that most specific template is chosen func TestParse_TemplateSpecificity(t *testing.T) { s := NewTestStatsd() s.Templates = []string{ "cpu.* measurement.foo.host", "cpu.idle.* measurement.measurement.host", } lines := []string{ "cpu.idle.localhost:1|c", } for _, line := range lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } validations := []struct { name string value int64 }{ { "cpu_idle", 1, }, } // Validate counters for _, test := range validations { err := test_validate_counter(test.name, test.value, s.counters) if err != nil { t.Error(err.Error()) } } } // Test that most specific template is chosen func TestParse_TemplateFields(t *testing.T) { s := NewTestStatsd() s.Templates = []string{ "* measurement.measurement.field", } lines := []string{ "my.counter.f1:1|c", "my.counter.f1:1|c", "my.counter.f2:1|c", "my.counter.f3:10|c", "my.counter.f3:100|c", "my.gauge.f1:10.1|g", "my.gauge.f2:10.1|g", "my.gauge.f1:0.9|g", "my.set.f1:1|s", "my.set.f1:2|s", "my.set.f1:1|s", "my.set.f2:100|s", } for _, line := range lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } counter_tests := []struct { name string value int64 field string }{ { "my_counter", 2, "f1", }, { "my_counter", 1, "f2", }, { "my_counter", 110, "f3", }, } // Validate counters for _, test := range counter_tests { err := test_validate_counter(test.name, test.value, s.counters, test.field) if err != nil { t.Error(err.Error()) } } gauge_tests := []struct { name string value float64 field string }{ { "my_gauge", 0.9, "f1", }, { "my_gauge", 10.1, "f2", }, } // Validate gauges for _, test := range gauge_tests { err := test_validate_gauge(test.name, test.value, s.gauges, test.field) if err != nil { t.Error(err.Error()) } } set_tests := []struct { name string value int64 field string }{ { "my_set", 2, "f1", }, { "my_set", 1, "f2", }, } // Validate sets for _, test := range set_tests { err := test_validate_set(test.name, test.value, s.sets, test.field) if err != nil { t.Error(err.Error()) } } } // Test that fields are parsed correctly func TestParse_Fields(t *testing.T) { if false { t.Errorf("TODO") } } // Test that tags within the bucket are parsed correctly func TestParse_Tags(t *testing.T) { s := NewTestStatsd() tests := []struct { bucket string name string tags map[string]string }{ { "cpu.idle,host=localhost", "cpu_idle", map[string]string{ "host": "localhost", }, }, { "cpu.idle,host=localhost,region=west", "cpu_idle", map[string]string{ "host": "localhost", "region": "west", }, }, { "cpu.idle,host=localhost,color=red,region=west", "cpu_idle", map[string]string{ "host": "localhost", "region": "west", "color": "red", }, }, } for _, test := range tests { name, _, tags := s.parseName(test.bucket) if name != test.name { t.Errorf("Expected: %s, got %s", test.name, name) } for k, v := range test.tags { actual, ok := tags[k] if !ok { t.Errorf("Expected key: %s not found", k) } if actual != v { t.Errorf("Expected %s, got %s", v, actual) } } } } // Test that DataDog tags are parsed func TestParse_DataDogTags(t *testing.T) { s := NewTestStatsd() s.ParseDataDogTags = true lines := []string{ "my_counter:1|c|#host:localhost,environment:prod,endpoint:/:tenant?/oauth/ro", "my_gauge:10.1|g|#live", "my_set:1|s|#host:localhost", "my_timer:3|ms|@0.1|#live,host:localhost", } testTags := map[string]map[string]string{ "my_counter": { "host": "localhost", "environment": "prod", "endpoint": "/:tenant?/oauth/ro", }, "my_gauge": { "live": "", }, "my_set": { "host": "localhost", }, "my_timer": { "live": "", "host": "localhost", }, } for _, line := range lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } sourceTags := map[string]map[string]string{ "my_gauge": tagsForItem(s.gauges), "my_counter": tagsForItem(s.counters), "my_set": tagsForItem(s.sets), "my_timer": tagsForItem(s.timings), } for statName, tags := range testTags { for k, v := range tags { otherValue := sourceTags[statName][k] if sourceTags[statName][k] != v { t.Errorf("Error with %s, tag %s: %s != %s", statName, k, v, otherValue) } } } } func tagsForItem(m interface{}) map[string]string { switch m.(type) { case map[string]cachedcounter: for _, v := range m.(map[string]cachedcounter) { return v.tags } case map[string]cachedgauge: for _, v := range m.(map[string]cachedgauge) { return v.tags } case map[string]cachedset: for _, v := range m.(map[string]cachedset) { return v.tags } case map[string]cachedtimings: for _, v := range m.(map[string]cachedtimings) { return v.tags } } return nil } // Test that statsd buckets are parsed to measurement names properly func TestParseName(t *testing.T) { s := NewTestStatsd() tests := []struct { in_name string out_name string }{ { "foobar", "foobar", }, { "foo.bar", "foo_bar", }, { "foo.bar-baz", "foo_bar-baz", }, } for _, test := range tests { name, _, _ := s.parseName(test.in_name) if name != test.out_name { t.Errorf("Expected: %s, got %s", test.out_name, name) } } // Test with separator == "." s.MetricSeparator = "." tests = []struct { in_name string out_name string }{ { "foobar", "foobar", }, { "foo.bar", "foo.bar", }, { "foo.bar-baz", "foo.bar-baz", }, } for _, test := range tests { name, _, _ := s.parseName(test.in_name) if name != test.out_name { t.Errorf("Expected: %s, got %s", test.out_name, name) } } } // Test that measurements with the same name, but different tags, are treated // as different outputs func TestParse_MeasurementsWithSameName(t *testing.T) { s := NewTestStatsd() // Test that counters work valid_lines := []string{ "test.counter,host=localhost:1|c", "test.counter,host=localhost,region=west:1|c", } for _, line := range valid_lines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } if len(s.counters) != 2 { t.Errorf("Expected 2 separate measurements, found %d", len(s.counters)) } } // Test that measurements with multiple bits, are treated as different outputs // but are equal to their single-measurement representation func TestParse_MeasurementsWithMultipleValues(t *testing.T) { single_lines := []string{ "valid.multiple:0|ms|@0.1", "valid.multiple:0|ms|", "valid.multiple:1|ms", "valid.multiple.duplicate:1|c", "valid.multiple.duplicate:1|c", "valid.multiple.duplicate:2|c", "valid.multiple.duplicate:1|c", "valid.multiple.duplicate:1|h", "valid.multiple.duplicate:1|h", "valid.multiple.duplicate:2|h", "valid.multiple.duplicate:1|h", "valid.multiple.duplicate:1|s", "valid.multiple.duplicate:1|s", "valid.multiple.duplicate:2|s", "valid.multiple.duplicate:1|s", "valid.multiple.duplicate:1|g", "valid.multiple.duplicate:1|g", "valid.multiple.duplicate:2|g", "valid.multiple.duplicate:1|g", "valid.multiple.mixed:1|c", "valid.multiple.mixed:1|ms", "valid.multiple.mixed:2|s", "valid.multiple.mixed:1|g", } multiple_lines := []string{ "valid.multiple:0|ms|@0.1:0|ms|:1|ms", "valid.multiple.duplicate:1|c:1|c:2|c:1|c", "valid.multiple.duplicate:1|h:1|h:2|h:1|h", "valid.multiple.duplicate:1|s:1|s:2|s:1|s", "valid.multiple.duplicate:1|g:1|g:2|g:1|g", "valid.multiple.mixed:1|c:1|ms:2|s:1|g", } s_single := NewTestStatsd() s_multiple := NewTestStatsd() for _, line := range single_lines { err := s_single.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } for _, line := range multiple_lines { err := s_multiple.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } if len(s_single.timings) != 3 { t.Errorf("Expected 3 measurement, found %d", len(s_single.timings)) } if cachedtiming, ok := s_single.timings["metric_type=timingvalid_multiple"]; !ok { t.Errorf("Expected cached measurement with hash 'metric_type=timingvalid_multiple' not found") } else { if cachedtiming.name != "valid_multiple" { t.Errorf("Expected the name to be 'valid_multiple', got %s", cachedtiming.name) } // A 0 at samplerate 0.1 will add 10 values of 0, // A 0 with invalid samplerate will add a single 0, // plus the last bit of value 1 // which adds up to 12 individual datapoints to be cached if cachedtiming.fields[defaultFieldName].n != 12 { t.Errorf("Expected 12 additions, got %d", cachedtiming.fields[defaultFieldName].n) } if cachedtiming.fields[defaultFieldName].upper != 1 { t.Errorf("Expected max input to be 1, got %f", cachedtiming.fields[defaultFieldName].upper) } } // test if s_single and s_multiple did compute the same stats for valid.multiple.duplicate if err := test_validate_set("valid_multiple_duplicate", 2, s_single.sets); err != nil { t.Error(err.Error()) } if err := test_validate_set("valid_multiple_duplicate", 2, s_multiple.sets); err != nil { t.Error(err.Error()) } if err := test_validate_counter("valid_multiple_duplicate", 5, s_single.counters); err != nil { t.Error(err.Error()) } if err := test_validate_counter("valid_multiple_duplicate", 5, s_multiple.counters); err != nil { t.Error(err.Error()) } if err := test_validate_gauge("valid_multiple_duplicate", 1, s_single.gauges); err != nil { t.Error(err.Error()) } if err := test_validate_gauge("valid_multiple_duplicate", 1, s_multiple.gauges); err != nil { t.Error(err.Error()) } // test if s_single and s_multiple did compute the same stats for valid.multiple.mixed if err := test_validate_set("valid_multiple_mixed", 1, s_single.sets); err != nil { t.Error(err.Error()) } if err := test_validate_set("valid_multiple_mixed", 1, s_multiple.sets); err != nil { t.Error(err.Error()) } if err := test_validate_counter("valid_multiple_mixed", 1, s_single.counters); err != nil { t.Error(err.Error()) } if err := test_validate_counter("valid_multiple_mixed", 1, s_multiple.counters); err != nil { t.Error(err.Error()) } if err := test_validate_gauge("valid_multiple_mixed", 1, s_single.gauges); err != nil { t.Error(err.Error()) } if err := test_validate_gauge("valid_multiple_mixed", 1, s_multiple.gauges); err != nil { t.Error(err.Error()) } } // Tests low-level functionality of timings when multiple fields is enabled // and a measurement template has been defined which can parse field names func TestParse_Timings_MultipleFieldsWithTemplate(t *testing.T) { s := NewTestStatsd() s.Templates = []string{"measurement.field"} s.Percentiles = []int{90} acc := &testutil.Accumulator{} validLines := []string{ "test_timing.success:1|ms", "test_timing.success:11|ms", "test_timing.success:1|ms", "test_timing.success:1|ms", "test_timing.success:1|ms", "test_timing.error:2|ms", "test_timing.error:22|ms", "test_timing.error:2|ms", "test_timing.error:2|ms", "test_timing.error:2|ms", } for _, line := range validLines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } s.Gather(acc) valid := map[string]interface{}{ "success_90_percentile": float64(11), "success_count": int64(5), "success_lower": float64(1), "success_mean": float64(3), "success_stddev": float64(4), "success_sum": float64(15), "success_upper": float64(11), "error_90_percentile": float64(22), "error_count": int64(5), "error_lower": float64(2), "error_mean": float64(6), "error_stddev": float64(8), "error_sum": float64(30), "error_upper": float64(22), } acc.AssertContainsFields(t, "test_timing", valid) } // Tests low-level functionality of timings when multiple fields is enabled // but a measurement template hasn't been defined so we can't parse field names // In this case the behaviour should be the same as normal behaviour func TestParse_Timings_MultipleFieldsWithoutTemplate(t *testing.T) { s := NewTestStatsd() s.Templates = []string{} s.Percentiles = []int{90} acc := &testutil.Accumulator{} validLines := []string{ "test_timing.success:1|ms", "test_timing.success:11|ms", "test_timing.success:1|ms", "test_timing.success:1|ms", "test_timing.success:1|ms", "test_timing.error:2|ms", "test_timing.error:22|ms", "test_timing.error:2|ms", "test_timing.error:2|ms", "test_timing.error:2|ms", } for _, line := range validLines { err := s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } } s.Gather(acc) expectedSuccess := map[string]interface{}{ "90_percentile": float64(11), "count": int64(5), "lower": float64(1), "mean": float64(3), "stddev": float64(4), "sum": float64(15), "upper": float64(11), } expectedError := map[string]interface{}{ "90_percentile": float64(22), "count": int64(5), "lower": float64(2), "mean": float64(6), "stddev": float64(8), "sum": float64(30), "upper": float64(22), } acc.AssertContainsFields(t, "test_timing_success", expectedSuccess) acc.AssertContainsFields(t, "test_timing_error", expectedError) } func BenchmarkParse(b *testing.B) { s := NewTestStatsd() validLines := []string{ "test.timing.success:1|ms", "test.timing.success:11|ms", "test.timing.success:1|ms", "test.timing.success:1|ms", "test.timing.success:1|ms", "test.timing.error:2|ms", "test.timing.error:22|ms", "test.timing.error:2|ms", "test.timing.error:2|ms", "test.timing.error:2|ms", } for n := 0; n < b.N; n++ { for _, line := range validLines { err := s.parseStatsdLine(line) if err != nil { b.Errorf("Parsing line %s should not have resulted in an error\n", line) } } } } func BenchmarkParseWithTemplate(b *testing.B) { s := NewTestStatsd() s.Templates = []string{"measurement.measurement.field"} validLines := []string{ "test.timing.success:1|ms", "test.timing.success:11|ms", "test.timing.success:1|ms", "test.timing.success:1|ms", "test.timing.success:1|ms", "test.timing.error:2|ms", "test.timing.error:22|ms", "test.timing.error:2|ms", "test.timing.error:2|ms", "test.timing.error:2|ms", } for n := 0; n < b.N; n++ { for _, line := range validLines { err := s.parseStatsdLine(line) if err != nil { b.Errorf("Parsing line %s should not have resulted in an error\n", line) } } } } func BenchmarkParseWithTemplateAndFilter(b *testing.B) { s := NewTestStatsd() s.Templates = []string{"cpu* measurement.measurement.field"} validLines := []string{ "test.timing.success:1|ms", "test.timing.success:11|ms", "test.timing.success:1|ms", "cpu.timing.success:1|ms", "cpu.timing.success:1|ms", "cpu.timing.error:2|ms", "cpu.timing.error:22|ms", "test.timing.error:2|ms", "test.timing.error:2|ms", "test.timing.error:2|ms", } for n := 0; n < b.N; n++ { for _, line := range validLines { err := s.parseStatsdLine(line) if err != nil { b.Errorf("Parsing line %s should not have resulted in an error\n", line) } } } } func BenchmarkParseWith2TemplatesAndFilter(b *testing.B) { s := NewTestStatsd() s.Templates = []string{ "cpu1* measurement.measurement.field", "cpu2* measurement.measurement.field", } validLines := []string{ "test.timing.success:1|ms", "test.timing.success:11|ms", "test.timing.success:1|ms", "cpu1.timing.success:1|ms", "cpu1.timing.success:1|ms", "cpu2.timing.error:2|ms", "cpu2.timing.error:22|ms", "test.timing.error:2|ms", "test.timing.error:2|ms", "test.timing.error:2|ms", } for n := 0; n < b.N; n++ { for _, line := range validLines { err := s.parseStatsdLine(line) if err != nil { b.Errorf("Parsing line %s should not have resulted in an error\n", line) } } } } func BenchmarkParseWith2Templates3TagsAndFilter(b *testing.B) { s := NewTestStatsd() s.Templates = []string{ "cpu1* measurement.measurement.region.city.rack.field", "cpu2* measurement.measurement.region.city.rack.field", } validLines := []string{ "test.timing.us-east.nyc.rack01.success:1|ms", "test.timing.us-east.nyc.rack01.success:11|ms", "test.timing.us-west.sf.rack01.success:1|ms", "cpu1.timing.us-west.sf.rack01.success:1|ms", "cpu1.timing.us-east.nyc.rack01.success:1|ms", "cpu2.timing.us-east.nyc.rack01.error:2|ms", "cpu2.timing.us-west.sf.rack01.error:22|ms", "test.timing.us-west.sf.rack01.error:2|ms", "test.timing.us-west.sf.rack01.error:2|ms", "test.timing.us-east.nyc.rack01.error:2|ms", } for n := 0; n < b.N; n++ { for _, line := range validLines { err := s.parseStatsdLine(line) if err != nil { b.Errorf("Parsing line %s should not have resulted in an error\n", line) } } } } func TestParse_Timings_Delete(t *testing.T) { s := NewTestStatsd() s.DeleteTimings = true fakeacc := &testutil.Accumulator{} var err error line := "timing:100|ms" err = s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } if len(s.timings) != 1 { t.Errorf("Should be 1 timing, found %d", len(s.timings)) } s.Gather(fakeacc) if len(s.timings) != 0 { t.Errorf("All timings should have been deleted, found %d", len(s.timings)) } } // Tests the delete_gauges option func TestParse_Gauges_Delete(t *testing.T) { s := NewTestStatsd() s.DeleteGauges = true fakeacc := &testutil.Accumulator{} var err error line := "current.users:100|g" err = s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } err = test_validate_gauge("current_users", 100, s.gauges) if err != nil { t.Error(err.Error()) } s.Gather(fakeacc) err = test_validate_gauge("current_users", 100, s.gauges) if err == nil { t.Error("current_users_gauge metric should have been deleted") } } // Tests the delete_sets option func TestParse_Sets_Delete(t *testing.T) { s := NewTestStatsd() s.DeleteSets = true fakeacc := &testutil.Accumulator{} var err error line := "unique.user.ids:100|s" err = s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } err = test_validate_set("unique_user_ids", 1, s.sets) if err != nil { t.Error(err.Error()) } s.Gather(fakeacc) err = test_validate_set("unique_user_ids", 1, s.sets) if err == nil { t.Error("unique_user_ids_set metric should have been deleted") } } // Tests the delete_counters option func TestParse_Counters_Delete(t *testing.T) { s := NewTestStatsd() s.DeleteCounters = true fakeacc := &testutil.Accumulator{} var err error line := "total.users:100|c" err = s.parseStatsdLine(line) if err != nil { t.Errorf("Parsing line %s should not have resulted in an error\n", line) } err = test_validate_counter("total_users", 100, s.counters) if err != nil { t.Error(err.Error()) } s.Gather(fakeacc) err = test_validate_counter("total_users", 100, s.counters) if err == nil { t.Error("total_users_counter metric should have been deleted") } } func TestParseKeyValue(t *testing.T) { k, v := parseKeyValue("foo=bar") if k != "foo" { t.Errorf("Expected %s, got %s", "foo", k) } if v != "bar" { t.Errorf("Expected %s, got %s", "bar", v) } k2, v2 := parseKeyValue("baz") if k2 != "" { t.Errorf("Expected %s, got %s", "", k2) } if v2 != "baz" { t.Errorf("Expected %s, got %s", "baz", v2) } } // Test utility functions func test_validate_set( name string, value int64, cache map[string]cachedset, field ...string, ) error { var f string if len(field) > 0 { f = field[0] } else { f = "value" } var metric cachedset var found bool for _, v := range cache { if v.name == name { metric = v found = true break } } if !found { return errors.New(fmt.Sprintf("Test Error: Metric name %s not found\n", name)) } if value != int64(len(metric.fields[f])) { return errors.New(fmt.Sprintf("Measurement: %s, expected %d, actual %d\n", name, value, len(metric.fields[f]))) } return nil } func test_validate_counter( name string, valueExpected int64, cache map[string]cachedcounter, field ...string, ) error { var f string if len(field) > 0 { f = field[0] } else { f = "value" } var valueActual int64 var found bool for _, v := range cache { if v.name == name { valueActual = v.fields[f].(int64) found = true break } } if !found { return errors.New(fmt.Sprintf("Test Error: Metric name %s not found\n", name)) } if valueExpected != valueActual { return errors.New(fmt.Sprintf("Measurement: %s, expected %d, actual %d\n", name, valueExpected, valueActual)) } return nil } func test_validate_gauge( name string, valueExpected float64, cache map[string]cachedgauge, field ...string, ) error { var f string if len(field) > 0 { f = field[0] } else { f = "value" } var valueActual float64 var found bool for _, v := range cache { if v.name == name { valueActual = v.fields[f].(float64) found = true break } } if !found { return errors.New(fmt.Sprintf("Test Error: Metric name %s not found\n", name)) } if valueExpected != valueActual { return errors.New(fmt.Sprintf("Measurement: %s, expected %f, actual %f\n", name, valueExpected, valueActual)) } return nil }