zrepl/rpc/dataconn/dataconn_server.go

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package dataconn
import (
"bytes"
"context"
"fmt"
"github.com/golang/protobuf/proto"
2019-03-22 19:41:12 +01:00
"github.com/zrepl/zrepl/logger"
"github.com/zrepl/zrepl/replication/logic/pdu"
"github.com/zrepl/zrepl/rpc/dataconn/stream"
"github.com/zrepl/zrepl/transport"
"github.com/zrepl/zrepl/zfs"
)
// WireInterceptor has a chance to exchange the context and connection on each client connection.
type WireInterceptor func(ctx context.Context, rawConn *transport.AuthConn) (context.Context, *transport.AuthConn)
// Handler implements the functionality that is exposed by Server to the Client.
type Handler interface {
// Send handles a SendRequest.
// The returned io.ReadCloser is allowed to be nil, for example if the requested Send is a dry-run.
Send(ctx context.Context, r *pdu.SendReq) (*pdu.SendRes, zfs.StreamCopier, error)
// Receive handles a ReceiveRequest.
// It is guaranteed that Server calls Receive with a stream that holds the IdleConnTimeout
// configured in ServerConfig.Shared.IdleConnTimeout.
Receive(ctx context.Context, r *pdu.ReceiveReq, receive zfs.StreamCopier) (*pdu.ReceiveRes, error)
// PingDataconn handles a PingReq
PingDataconn(ctx context.Context, r *pdu.PingReq) (*pdu.PingRes, error)
}
type Logger = logger.Logger
type Server struct {
h Handler
wi WireInterceptor
log Logger
}
func NewServer(wi WireInterceptor, logger Logger, handler Handler) *Server {
return &Server{
h: handler,
wi: wi,
log: logger,
}
}
// Serve consumes the listener, closes it as soon as ctx is closed.
// No accept errors are returned: they are logged to the Logger passed
// to the constructor.
func (s *Server) Serve(ctx context.Context, l transport.AuthenticatedListener) {
go func() {
<-ctx.Done()
s.log.Debug("context done")
if err := l.Close(); err != nil {
s.log.WithError(err).Error("cannot close listener")
}
}()
conns := make(chan *transport.AuthConn)
go func() {
for {
conn, err := l.Accept(ctx)
if err != nil {
if ctx.Done() != nil {
s.log.Debug("stop accepting after context is done")
return
}
s.log.WithError(err).Error("accept error")
continue
}
conns <- conn
}
}()
for conn := range conns {
go s.serveConn(conn)
}
}
func (s *Server) serveConn(nc *transport.AuthConn) {
s.log.Debug("serveConn begin")
defer s.log.Debug("serveConn done")
ctx := context.Background()
if s.wi != nil {
ctx, nc = s.wi(ctx, nc)
}
c := stream.Wrap(nc, HeartbeatInterval, HeartbeatPeerTimeout)
defer func() {
s.log.Debug("close client connection")
if err := c.Close(); err != nil {
s.log.WithError(err).Error("cannot close client connection")
}
}()
header, err := c.ReadStreamedMessage(ctx, RequestHeaderMaxSize, ReqHeader)
if err != nil {
s.log.WithError(err).Error("error reading structured part")
return
}
endpoint := string(header)
reqStructured, err := c.ReadStreamedMessage(ctx, RequestStructuredMaxSize, ReqStructured)
if err != nil {
s.log.WithError(err).Error("error reading structured part")
return
}
s.log.WithField("endpoint", endpoint).Debug("calling handler")
var res proto.Message
var sendStream zfs.StreamCopier
var handlerErr error
switch endpoint {
case EndpointSend:
var req pdu.SendReq
if err := proto.Unmarshal(reqStructured, &req); err != nil {
s.log.WithError(err).Error("cannot unmarshal send request")
return
}
res, sendStream, handlerErr = s.h.Send(ctx, &req) // SHADOWING
case EndpointRecv:
var req pdu.ReceiveReq
if err := proto.Unmarshal(reqStructured, &req); err != nil {
s.log.WithError(err).Error("cannot unmarshal receive request")
return
}
res, handlerErr = s.h.Receive(ctx, &req, &streamCopier{streamConn: c, closeStreamOnClose: false}) // SHADOWING
case EndpointPing:
var req pdu.PingReq
if err := proto.Unmarshal(reqStructured, &req); err != nil {
s.log.WithError(err).Error("cannot unmarshal ping request")
return
}
res, handlerErr = s.h.PingDataconn(ctx, &req) // SHADOWING
default:
s.log.WithField("endpoint", endpoint).Error("unknown endpoint")
handlerErr = fmt.Errorf("requested endpoint does not exist")
}
s.log.WithField("endpoint", endpoint).WithField("errType", fmt.Sprintf("%T", handlerErr)).Debug("handler returned")
// prepare protobuf now to return the protobuf error in the header
// if marshaling fails. We consider failed marshaling a handler error
var protobuf *bytes.Buffer
if handlerErr == nil {
if res == nil {
handlerErr = fmt.Errorf("implementation error: handler for endpoint %q returns nil error and nil result", endpoint)
s.log.WithError(err).Error("handle implementation error")
} else {
protobufBytes, err := proto.Marshal(res)
if err != nil {
s.log.WithError(err).Error("cannot marshal handler protobuf")
handlerErr = err
}
protobuf = bytes.NewBuffer(protobufBytes) // SHADOWING
}
}
var resHeaderBuf bytes.Buffer
if handlerErr == nil {
resHeaderBuf.WriteString(responseHeaderHandlerOk)
} else {
resHeaderBuf.WriteString(responseHeaderHandlerErrorPrefix)
resHeaderBuf.WriteString(handlerErr.Error())
}
if err := c.WriteStreamedMessage(ctx, &resHeaderBuf, ResHeader); err != nil {
s.log.WithError(err).Error("cannot write response header")
return
}
if handlerErr != nil {
s.log.Debug("early exit after handler error")
return
}
if err := c.WriteStreamedMessage(ctx, protobuf, ResStructured); err != nil {
s.log.WithError(err).Error("cannot write structured part of response")
return
}
if sendStream != nil {
err := c.SendStream(ctx, sendStream, ZFSStream)
if err != nil {
s.log.WithError(err).Error("cannot write send stream")
}
}
}