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server.go
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package kafkatest
import (
"bytes"
"encoding/json"
"fmt"
"io"
"log"
"net"
"net/http"
"strconv"
"strings"
"sync"
"time"
"github.com/Adevinta/kafka/v2/proto"
)
type topicOffset struct {
offset int64
metadata string
}
// Server is container for fake kafka server data.
type Server struct {
mu sync.RWMutex
brokers []proto.MetadataRespBroker
topics map[string]map[int32][]*proto.Message
offsets map[string]map[int32]map[string]*topicOffset
ln net.Listener
middlewares []Middleware
events chan struct{}
}
// Middleware is function that is called for every incomming kafka message,
// before running default processing handler. Middleware function can return
// nil or kafka response message.
type Middleware func(nodeID int32, requestKind int16, content []byte) Response
// Response is any kafka response as defined in kafka/proto package
type Response interface {
Bytes() ([]byte, error)
}
// NewServer return new mock server instance. Any number of middlewares can be
// passed to customize request handling. For every incomming request, all
// middlewares are called one after another in order they were passed. If any
// middleware return non nil response message, response is instasntly written
// to the client and no further code execution for the request is made -- no
// other middleware is called nor the default handler is executed.
func NewServer(middlewares ...Middleware) *Server {
s := &Server{
brokers: make([]proto.MetadataRespBroker, 0),
topics: make(map[string]map[int32][]*proto.Message),
offsets: make(map[string]map[int32]map[string]*topicOffset),
middlewares: middlewares,
events: make(chan struct{}, 1000),
}
return s
}
// Addr return server instance address or empty string if not running.
func (s *Server) Addr() string {
s.mu.RLock()
defer s.mu.RUnlock()
if s.ln != nil {
return s.ln.Addr().String()
}
return ""
}
// Reset will clear out local messages and topics.
func (s *Server) Reset() {
s.mu.Lock()
defer s.mu.Unlock()
s.topics = make(map[string]map[int32][]*proto.Message)
}
// Close shut down server if running. It is safe to call it more than once.
func (s *Server) Close() (err error) {
s.mu.Lock()
defer s.mu.Unlock()
if s.ln != nil {
err = s.ln.Close()
s.ln = nil
}
return err
}
// ServeHTTP provides JSON serialized server state information.
func (s *Server) ServeHTTP(w http.ResponseWriter, r *http.Request) {
s.mu.Lock()
defer s.mu.Unlock()
topics := make(map[string]map[string][]*proto.Message)
for name, parts := range s.topics {
topics[name] = make(map[string][]*proto.Message)
for part, messages := range parts {
topics[name][strconv.Itoa(int(part))] = messages
}
}
w.Header().Set("content-type", "application/json")
err := json.NewEncoder(w).Encode(map[string]interface{}{
"topics": topics,
"brokers": s.brokers,
})
if err != nil {
log.Printf("cannot JSON encode state: %s", err)
}
}
// AddMessages append messages to given topic/partition. If topic or partition
// does not exists, it is being created.
// To only create topic/partition, call this method withough giving any
// message.
func (s *Server) AddMessages(topic string, partition int32, messages ...*proto.Message) {
s.mu.Lock()
defer s.mu.Unlock()
parts, ok := s.topics[topic]
if !ok {
parts = make(map[int32][]*proto.Message)
s.topics[topic] = parts
}
for i := int32(0); i <= partition; i++ {
if _, ok := parts[i]; !ok {
parts[i] = make([]*proto.Message, 0)
}
}
if len(messages) > 0 {
start := len(parts[partition])
for i, msg := range messages {
msg.Offset = int64(start + i)
msg.Partition = partition
msg.Topic = topic
}
parts[partition] = append(parts[partition], messages...)
}
}
// Run starts kafka mock server listening on given address.
func (s *Server) Run(addr string) error {
const nodeID = 100
s.mu.RLock()
if s.ln != nil {
s.mu.RUnlock()
log.Printf("server already running: %s", s.ln.Addr())
return fmt.Errorf("server already running: %s", s.ln.Addr())
}
ln, err := net.Listen("tcp4", addr)
if err != nil {
s.mu.RUnlock()
log.Printf("cannot listen on address %q: %s", addr, err)
return fmt.Errorf("cannot listen: %s", err)
}
defer func() {
_ = ln.Close()
}()
s.ln = ln
if host, port, err := net.SplitHostPort(ln.Addr().String()); err != nil {
s.mu.RUnlock()
log.Printf("cannot extract host/port from %q: %s", ln.Addr(), err)
return fmt.Errorf("cannot extract host/port from %q: %s", ln.Addr(), err)
} else {
prt, err := strconv.Atoi(port)
if err != nil {
s.mu.RUnlock()
log.Printf("invalid port %q: %s", port, err)
return fmt.Errorf("invalid port %q: %s", port, err)
}
s.brokers = append(s.brokers, proto.MetadataRespBroker{
NodeID: nodeID,
Host: host,
Port: int32(prt),
})
}
s.mu.RUnlock()
for {
conn, err := ln.Accept()
if err == nil {
go s.handleClient(nodeID, conn)
}
}
}
// MustSpawn run server in the background on random port. It panics if server
// cannot be spawned.
// Use Close method to stop spawned server.
func (s *Server) MustSpawn() {
const nodeID = 100
s.mu.Lock()
defer s.mu.Unlock()
if s.ln != nil {
return
}
ln, err := net.Listen("tcp4", "localhost:0")
if err != nil {
panic(fmt.Sprintf("cannot listen: %s", err))
}
s.ln = ln
if host, port, err := net.SplitHostPort(ln.Addr().String()); err != nil {
panic(fmt.Sprintf("cannot extract host/port from %q: %s", ln.Addr(), err))
} else {
prt, err := strconv.Atoi(port)
if err != nil {
panic(fmt.Sprintf("invalid port %q: %s", port, err))
}
s.brokers = append(s.brokers, proto.MetadataRespBroker{
NodeID: nodeID,
Host: host,
Port: int32(prt),
})
}
go func() {
for {
conn, err := ln.Accept()
if err == nil {
go s.handleClient(nodeID, conn)
}
}
}()
}
func (s *Server) handleClient(nodeID int32, conn net.Conn) {
defer func() {
_ = conn.Close()
}()
for {
kind, b, err := proto.ReadReq(conn)
if err != nil {
if err != io.EOF {
log.Printf("client read error: %s", err)
}
return
}
var resp response
for _, middleware := range s.middlewares {
resp = middleware(nodeID, kind, b)
if resp != nil {
break
}
}
if resp == nil {
switch kind {
case proto.ProduceReqKind:
req, err := proto.ReadProduceReq(bytes.NewBuffer(b))
if err != nil {
log.Printf("cannot parse produce request: %s\n%s", err, b)
return
}
resp = s.handleProduceRequest(nodeID, conn, req)
case proto.FetchReqKind:
req, err := proto.ReadFetchReq(bytes.NewBuffer(b))
if err != nil {
log.Printf("cannot parse fetch request: %s\n%s", err, b)
return
}
resp = s.handleFetchRequest(nodeID, conn, req)
case proto.OffsetReqKind:
req, err := proto.ReadOffsetReq(bytes.NewBuffer(b))
if err != nil {
log.Printf("cannot parse offset request: %s\n%s", err, b)
return
}
resp = s.handleOffsetRequest(nodeID, conn, req)
case proto.MetadataReqKind:
req, err := proto.ReadMetadataReq(bytes.NewBuffer(b))
if err != nil {
log.Printf("cannot parse metadata request: %s\n%s", err, b)
return
}
resp = s.handleMetadataRequest(nodeID, conn, req)
case proto.OffsetCommitReqKind:
req, err := proto.ReadOffsetCommitReq(bytes.NewBuffer(b))
if err != nil {
log.Printf("cannot parse offset commit request: %s\n%s", err, b)
return
}
resp = s.handleOffsetCommitRequest(nodeID, conn, req)
case proto.OffsetFetchReqKind:
req, err := proto.ReadOffsetFetchReq(bytes.NewBuffer(b))
if err != nil {
log.Printf("cannot parse offset fetch request: %s\n%s", err, b)
return
}
resp = s.handleOffsetFetchRequest(nodeID, conn, req)
case proto.ConsumerMetadataReqKind:
req, err := proto.ReadConsumerMetadataReq(bytes.NewBuffer(b))
if err != nil {
log.Printf("cannot parse consumer metadata request: %s\n%s", err, b)
return
}
resp = s.handleConsumerMetadataRequest(nodeID, conn, req)
case proto.APIVersionsReqKind:
req, err := proto.ReadAPIVersionsReq(bytes.NewBuffer(b))
if err != nil {
log.Printf("cannot parse API version request: %s\n%s", err, b)
return
}
resp = s.handleAPIVersionsRequest(nodeID, conn, req)
default:
log.Printf("unknown request: %d\n%s", kind, b)
return
}
}
if resp == nil {
log.Printf("no response for %d", kind)
return
}
b, err = resp.Bytes()
if err != nil {
log.Printf("cannot serialize %T response: %s", resp, err)
}
if _, err := conn.Write(b); err != nil {
log.Printf("cannot write %T response: %s", resp, err)
return
}
}
}
type response interface {
Bytes() ([]byte, error)
}
func (s *Server) handleProduceRequest(nodeID int32, conn net.Conn, req *proto.ProduceReq) response {
s.mu.Lock()
defer s.mu.Unlock()
resp := &proto.ProduceResp{
Version: proto.KafkaV0,
CorrelationID: req.GetCorrelationID(),
Topics: make([]proto.ProduceRespTopic, len(req.Topics)),
}
for ti, topic := range req.Topics {
t, ok := s.topics[topic.Name]
if !ok {
t = make(map[int32][]*proto.Message)
s.topics[topic.Name] = t
}
respParts := make([]proto.ProduceRespPartition, len(topic.Partitions))
resp.Topics[ti].Name = topic.Name
resp.Topics[ti].Partitions = respParts
for pi, part := range topic.Partitions {
p, ok := t[part.ID]
if !ok {
p = make([]*proto.Message, 0)
t[part.ID] = p
}
for _, msg := range part.Messages {
msg.Offset = int64(len(t[part.ID]))
msg.Topic = topic.Name
t[part.ID] = append(t[part.ID], msg)
}
respParts[pi].ID = part.ID
respParts[pi].Offset = int64(len(t[part.ID])) - 1
}
}
s.events <- struct{}{}
return resp
}
func (s *Server) fetchRequest(req *proto.FetchReq) (response, int) {
s.mu.RLock()
defer s.mu.RUnlock()
var messagesNum int
resp := &proto.FetchResp{
Version: proto.KafkaV0,
CorrelationID: req.GetCorrelationID(),
Topics: make([]proto.FetchRespTopic, len(req.Topics)),
}
for ti, topic := range req.Topics {
respParts := make([]proto.FetchRespPartition, len(topic.Partitions))
resp.Topics[ti].Name = topic.Name
resp.Topics[ti].Partitions = respParts
for pi, part := range topic.Partitions {
respParts[pi].ID = part.ID
partitions, ok := s.topics[topic.Name]
if !ok {
respParts[pi].Err = proto.ErrUnknownTopicOrPartition
continue
}
messages, ok := partitions[part.ID]
if !ok {
respParts[pi].Err = proto.ErrUnknownTopicOrPartition
continue
}
if part.FetchOffset > int64(len(messages)) {
respParts[pi].Err = proto.ErrOffsetOutOfRange
continue
}
respParts[pi].TipOffset = int64(len(messages))
respParts[pi].Messages = messages[part.FetchOffset:]
messagesNum += len(messages[part.FetchOffset:])
}
}
return resp, messagesNum
}
func (s *Server) handleFetchRequest(nodeID int32, conn net.Conn, req *proto.FetchReq) response {
resp, n := s.fetchRequest(req)
if n == 0 {
select {
case _ = <-s.events:
case _ = <-time.After(time.Second):
}
resp, _ = s.fetchRequest(req)
}
return resp
}
func (s *Server) handleOffsetRequest(nodeID int32, conn net.Conn, req *proto.OffsetReq) response {
s.mu.RLock()
defer s.mu.RUnlock()
resp := &proto.OffsetResp{
Version: proto.KafkaV0,
CorrelationID: req.GetCorrelationID(),
Topics: make([]proto.OffsetRespTopic, len(req.Topics)),
}
for ti, topic := range req.Topics {
respPart := make([]proto.OffsetRespPartition, len(topic.Partitions))
resp.Topics[ti].Name = topic.Name
resp.Topics[ti].Partitions = respPart
for pi, part := range topic.Partitions {
respPart[pi].ID = part.ID
switch part.TimeMs {
case -1: // oldest
msgs := len(s.topics[topic.Name][part.ID])
respPart[pi].Offsets = []int64{int64(msgs), 0}
case -2: // earliest
respPart[pi].Offsets = []int64{0, 0}
default:
log.Printf("offset time for %s:%d not supported: %d", topic.Name, part.ID, part.TimeMs)
return nil
}
}
}
return resp
}
func (s *Server) handleConsumerMetadataRequest(nodeID int32, conn net.Conn, req *proto.ConsumerMetadataReq) response {
s.mu.RLock()
defer s.mu.RUnlock()
addrps := strings.Split(s.Addr(), ":")
port, _ := strconv.Atoi(addrps[1])
return &proto.ConsumerMetadataResp{
Version: proto.KafkaV0,
CorrelationID: req.GetCorrelationID(),
CoordinatorID: 0,
CoordinatorHost: addrps[0],
CoordinatorPort: int32(port),
}
}
func (s *Server) handleAPIVersionsRequest(nodeID int32, conn net.Conn, req *proto.APIVersionsReq) response {
s.mu.RLock()
defer s.mu.RUnlock()
return &proto.APIVersionsResp{
Version: proto.KafkaV0,
CorrelationID: req.GetCorrelationID(),
APIVersions: []proto.SupportedVersion{
{APIKey: proto.ProduceReqKind, MinVersion: proto.KafkaV0, MaxVersion: proto.KafkaV0},
{APIKey: proto.FetchReqKind, MinVersion: proto.KafkaV0, MaxVersion: proto.KafkaV0},
{APIKey: proto.OffsetReqKind, MinVersion: proto.KafkaV0, MaxVersion: proto.KafkaV0},
{APIKey: proto.MetadataReqKind, MinVersion: proto.KafkaV0, MaxVersion: proto.KafkaV0},
{APIKey: proto.OffsetCommitReqKind, MinVersion: proto.KafkaV0, MaxVersion: proto.KafkaV0},
{APIKey: proto.OffsetFetchReqKind, MinVersion: proto.KafkaV0, MaxVersion: proto.KafkaV0},
{APIKey: proto.ConsumerMetadataReqKind, MinVersion: proto.KafkaV0, MaxVersion: proto.KafkaV0},
{APIKey: proto.APIVersionsReqKind, MinVersion: proto.KafkaV0, MaxVersion: proto.KafkaV0},
},
}
}
func (s *Server) getTopicOffset(group, topic string, partID int32) *topicOffset {
pmap, ok := s.offsets[topic]
if !ok {
pmap = make(map[int32]map[string]*topicOffset)
s.offsets[topic] = pmap
}
groups, ok := pmap[partID]
if !ok {
groups = make(map[string]*topicOffset)
pmap[partID] = groups
}
toffset, ok := groups[group]
if !ok {
toffset = &topicOffset{}
groups[group] = toffset
}
return toffset
}
func (s *Server) handleOffsetFetchRequest(nodeID int32, conn net.Conn, req *proto.OffsetFetchReq) response {
s.mu.RLock()
defer s.mu.RUnlock()
resp := &proto.OffsetFetchResp{
Version: proto.KafkaV0,
CorrelationID: req.GetCorrelationID(),
Topics: make([]proto.OffsetFetchRespTopic, len(req.Topics)),
}
for ti, topic := range req.Topics {
respPart := make([]proto.OffsetFetchRespPartition, len(topic.Partitions))
resp.Topics[ti].Name = topic.Name
resp.Topics[ti].Partitions = respPart
for pi, part := range topic.Partitions {
toffset := s.getTopicOffset(req.ConsumerGroup, topic.Name, part)
respPart[pi].ID = part
respPart[pi].Metadata = toffset.metadata
respPart[pi].Offset = toffset.offset
}
}
return resp
}
func (s *Server) handleOffsetCommitRequest(nodeID int32, conn net.Conn, req *proto.OffsetCommitReq) response {
s.mu.Lock()
defer s.mu.Unlock()
resp := &proto.OffsetCommitResp{
Version: proto.KafkaV0,
CorrelationID: req.GetCorrelationID(),
Topics: make([]proto.OffsetCommitRespTopic, len(req.Topics)),
}
for ti, topic := range req.Topics {
respPart := make([]proto.OffsetCommitRespPartition, len(topic.Partitions))
resp.Topics[ti].Name = topic.Name
resp.Topics[ti].Partitions = respPart
for pi, part := range topic.Partitions {
toffset := s.getTopicOffset(req.ConsumerGroup, topic.Name, part.ID)
toffset.metadata = part.Metadata
toffset.offset = part.Offset
respPart[pi].ID = part.ID
}
}
return resp
}
func (s *Server) handleMetadataRequest(nodeID int32, conn net.Conn, req *proto.MetadataReq) response {
s.mu.RLock()
defer s.mu.RUnlock()
resp := &proto.MetadataResp{
Version: proto.KafkaV0,
CorrelationID: req.GetCorrelationID(),
Topics: make([]proto.MetadataRespTopic, 0, len(s.topics)),
Brokers: s.brokers,
}
if req.Topics != nil && len(req.Topics) > 0 {
// if particular topic was requested, create empty log if does not yet exists
for _, name := range req.Topics {
partitions, ok := s.topics[name]
if !ok {
partitions = make(map[int32][]*proto.Message)
partitions[0] = make([]*proto.Message, 0)
s.topics[name] = partitions
}
parts := make([]proto.MetadataRespPartition, len(partitions))
for pid := range partitions {
p := &parts[pid]
p.ID = pid
p.Leader = nodeID
p.Replicas = []int32{nodeID}
p.Isrs = []int32{nodeID}
}
resp.Topics = append(resp.Topics, proto.MetadataRespTopic{
Name: name,
Partitions: parts,
})
}
} else {
for name, partitions := range s.topics {
parts := make([]proto.MetadataRespPartition, len(partitions))
for pid := range partitions {
p := &parts[pid]
p.ID = pid
p.Leader = nodeID
p.Replicas = []int32{nodeID}
p.Isrs = []int32{nodeID}
}
resp.Topics = append(resp.Topics, proto.MetadataRespTopic{
Name: name,
Partitions: parts,
})
}
}
return resp
}