telegraf/plugins/inputs/kafka_consumer_legacy/kafka_consumer_legacy_test.go

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package kafka_consumer_legacy
import (
"strings"
"testing"
"github.com/influxdata/telegraf/plugins/parsers"
"github.com/influxdata/telegraf/testutil"
"github.com/Shopify/sarama"
"github.com/stretchr/testify/assert"
)
const (
testMsg = "cpu_load_short,host=server01 value=23422.0 1422568543702900257\n"
testMsgGraphite = "cpu.load.short.graphite 23422 1454780029"
testMsgJSON = "{\"a\": 5, \"b\": {\"c\": 6}}\n"
invalidMsg = "cpu_load_short,host=server01 1422568543702900257\n"
)
func newTestKafka() (*Kafka, chan *sarama.ConsumerMessage) {
in := make(chan *sarama.ConsumerMessage, 1000)
k := Kafka{
ConsumerGroup: "test",
Topics: []string{"telegraf"},
ZookeeperPeers: []string{"localhost:2181"},
Offset: "oldest",
in: in,
doNotCommitMsgs: true,
errs: make(chan error, 1000),
done: make(chan struct{}),
}
return &k, in
}
// Test that the parser parses kafka messages into points
func TestRunParser(t *testing.T) {
k, in := newTestKafka()
acc := testutil.Accumulator{}
k.acc = &acc
defer close(k.done)
k.parser, _ = parsers.NewInfluxParser()
go k.receiver()
in <- saramaMsg(testMsg)
acc.Wait(1)
assert.Equal(t, acc.NFields(), 1)
}
// Test that the parser ignores invalid messages
func TestRunParserInvalidMsg(t *testing.T) {
k, in := newTestKafka()
acc := testutil.Accumulator{}
k.acc = &acc
defer close(k.done)
k.parser, _ = parsers.NewInfluxParser()
go k.receiver()
in <- saramaMsg(invalidMsg)
acc.WaitError(1)
assert.Equal(t, acc.NFields(), 0)
}
// Test that overlong messages are dropped
func TestDropOverlongMsg(t *testing.T) {
const maxMessageLen = 64 * 1024
k, in := newTestKafka()
k.MaxMessageLen = maxMessageLen
acc := testutil.Accumulator{}
k.acc = &acc
defer close(k.done)
overlongMsg := strings.Repeat("v", maxMessageLen+1)
go k.receiver()
in <- saramaMsg(overlongMsg)
acc.WaitError(1)
assert.Equal(t, acc.NFields(), 0)
}
// Test that the parser parses kafka messages into points
func TestRunParserAndGather(t *testing.T) {
k, in := newTestKafka()
acc := testutil.Accumulator{}
k.acc = &acc
defer close(k.done)
k.parser, _ = parsers.NewInfluxParser()
go k.receiver()
in <- saramaMsg(testMsg)
acc.Wait(1)
acc.GatherError(k.Gather)
assert.Equal(t, acc.NFields(), 1)
acc.AssertContainsFields(t, "cpu_load_short",
map[string]interface{}{"value": float64(23422)})
}
// Test that the parser parses kafka messages into points
func TestRunParserAndGatherGraphite(t *testing.T) {
k, in := newTestKafka()
acc := testutil.Accumulator{}
k.acc = &acc
defer close(k.done)
k.parser, _ = parsers.NewGraphiteParser("_", []string{}, nil)
go k.receiver()
in <- saramaMsg(testMsgGraphite)
acc.Wait(1)
acc.GatherError(k.Gather)
assert.Equal(t, acc.NFields(), 1)
acc.AssertContainsFields(t, "cpu_load_short_graphite",
map[string]interface{}{"value": float64(23422)})
}
// Test that the parser parses kafka messages into points
func TestRunParserAndGatherJSON(t *testing.T) {
k, in := newTestKafka()
acc := testutil.Accumulator{}
k.acc = &acc
defer close(k.done)
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k.parser, _ = parsers.NewParser(&parsers.Config{
DataFormat: "json",
MetricName: "kafka_json_test",
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})
go k.receiver()
in <- saramaMsg(testMsgJSON)
acc.Wait(1)
acc.GatherError(k.Gather)
assert.Equal(t, acc.NFields(), 2)
acc.AssertContainsFields(t, "kafka_json_test",
map[string]interface{}{
"a": float64(5),
"b_c": float64(6),
})
}
func saramaMsg(val string) *sarama.ConsumerMessage {
return &sarama.ConsumerMessage{
Key: nil,
Value: []byte(val),
Offset: 0,
Partition: 0,
}
}