func (self *ofmReply) putError(msg ofp4.ErrorMsg) {
hdr := ofp4.Header(msg)
if len(msg) == 12 {
hdr = hdr.AppendData(self.req)
}
self.resps = append(self.resps, hdr.SetXid(self.req.Xid()))
}
func Parse(data []byte) (encoding.BinaryMarshaler, error) {
switch data[0] {
default:
return nil, &Error{1, 0}
case 4: // Openflow 1.3
length := int(binary.BigEndian.Uint16(data[2:4]))
return ofp4.Header(data[0:length]), nil
}
}
func readMsg(con io.Reader) ofp4.Header {
buf := make([]byte, 8)
if n, err := con.Read(buf); err != nil || n != 8 {
panic("ofp header read error")
}
hdr := ofp4.Header(buf)
if hdr.Version() != 4 {
panic("ofp4 version error")
}
length := hdr.Length()
if length != 8 {
ext := make([]byte, length)
copy(ext, buf)
con.Read(ext[8:])
buf = ext
}
return ofp4.Header(buf)
}
func (self *Pipeline) AddChannel(conn io.ReadWriteCloser) error {
self.lock.Lock()
defer self.lock.Unlock()
ch := &channel{
Conn: conn,
}
// process hello
ch.Notify(ofp4.MakeHello(ofp4.MakeHelloElemVersionbitmap([]uint32{uint32(1 << 4)})))
head := make([]byte, 4)
if msg, err := readOfpMessage(conn, head); err != nil {
return err
} else if ofp4.Header(msg).Type() != ofp4.OFPT_HELLO {
return fmt.Errorf("The first message must be HELLO")
} else {
satisfied := false
for _, element := range ofp4.Hello(msg).Elements().Iter() {
switch element.Type() {
case ofp4.OFPHET_VERSIONBITMAP:
bitmaps := ofp4.HelloElemVersionbitmap(element).Bitmaps()
if len(bitmaps) > 0 && (bitmaps[0]&(1<<4) != 0) {
satisfied = true
}
// ensure there be no bits higher than ofp4
for i, b := range bitmaps {
if i == 0 && (b&0xFFFFFFE0) != 0 {
satisfied = false
}
if i > 0 && b != 0 {
satisfied = false
}
}
}
}
if !satisfied && ofp4.Header(msg).Version() == 4 {
satisfied = true
}
if !satisfied {
err := ofp4.MakeErrorMsg(
ofp4.OFPET_HELLO_FAILED,
ofp4.OFPHFC_INCOMPATIBLE,
)
ch.Response(ofp4.Header(err).SetXid(ofp4.Header(msg).Xid()))
return err
}
}
self.channels = append(self.channels, ch)
worker := make(chan MapReducable)
go MapReduce(worker, 4)
go func() {
defer close(worker)
defer conn.Close()
multipartCollect := make(map[uint32][][]byte)
for {
msg, err := readOfpMessage(conn, head)
if err != nil {
log.Print(err)
break
}
reply := ofmReply{pipe: self, channel: ch, req: msg}
switch ofp4.Header(msg).Type() {
case ofp4.OFPT_ERROR:
log.Print("got unexpected OFPT_ERROR")
case ofp4.OFPT_ECHO_REQUEST:
worker <- &ofmEcho{reply}
case ofp4.OFPT_ECHO_REPLY:
log.Print("got unexpected OFPT_ECHO_REPLY")
case ofp4.OFPT_EXPERIMENTER:
worker <- &ofmExperimenter{reply}
case ofp4.OFPT_FEATURES_REQUEST:
worker <- &ofmFeaturesRequest{reply}
case ofp4.OFPT_GET_CONFIG_REQUEST:
worker <- &ofmGetConfigRequest{reply}
case ofp4.OFPT_SET_CONFIG:
worker <- &ofmSetConfig{reply}
case ofp4.OFPT_PACKET_OUT:
worker <- &ofmPacketOut{ofmOutput{reply, nil}}
case ofp4.OFPT_FLOW_MOD:
worker <- &ofmFlowMod{ofmOutput{reply, nil}}
case ofp4.OFPT_GROUP_MOD:
worker <- &ofmGroupMod{reply}
case ofp4.OFPT_PORT_MOD:
worker <- &ofmPortMod{reply}
case ofp4.OFPT_TABLE_MOD:
worker <- &ofmTableMod{reply}
case ofp4.OFPT_MULTIPART_REQUEST:
xid := ofp4.Header(msg).Xid()
req := ofp4.MultipartRequest(msg)
multipartCollect[xid] = append(multipartCollect[xid], req.Body())
if req.Flags()&ofp4.OFPMPF_REQ_MORE == 0 {
reqs := multipartCollect[xid]
delete(multipartCollect, xid)
mreply := ofmMulti{
ofmReply: reply,
reqs: reqs,
chunks: nil,
}
// capture
switch req.Type() {
case ofp4.OFPMP_DESC:
worker <- &ofmMpDesc{mreply}
case ofp4.OFPMP_TABLE:
worker <- &ofmMpTable{mreply}
case ofp4.OFPMP_GROUP_DESC:
worker <- &ofmMpGroupDesc{mreply}
case ofp4.OFPMP_GROUP_FEATURES:
worker <- &ofmMpGroupFeatures{mreply}
case ofp4.OFPMP_METER_FEATURES:
worker <- &ofmMpMeterFeatures{mreply}
case ofp4.OFPMP_PORT_DESC:
worker <- &ofmMpPortDesc{mreply}
case ofp4.OFPMP_FLOW:
worker <- &ofmMpFlow{mreply}
case ofp4.OFPMP_AGGREGATE:
worker <- &ofmMpAggregate{mreply}
case ofp4.OFPMP_PORT_STATS:
worker <- &ofmMpPortStats{mreply}
case ofp4.OFPMP_QUEUE:
worker <- &ofmMpQueue{mreply}
case ofp4.OFPMP_GROUP:
worker <- &ofmMpGroup{mreply}
case ofp4.OFPMP_METER:
worker <- &ofmMpMeter{mreply}
case ofp4.OFPMP_METER_CONFIG:
worker <- &ofmMpMeterConfig{mreply}
case ofp4.OFPMP_TABLE_FEATURES:
worker <- &ofmMpTableFeatures{mreply}
case ofp4.OFPMP_EXPERIMENTER:
worker <- &ofmMpExperimenter{mreply}
default:
panic("unknown ofp_multipart_request.type")
}
}
case ofp4.OFPT_BARRIER_REQUEST:
for xid, _ := range multipartCollect {
buf := ofp4.Header(make([]byte, 8))
buf.SetXid(xid)
rep := ofmReply{pipe: self, channel: ch, req: buf}
rep.createError(ofp4.OFPET_BAD_REQUEST, ofp4.OFPBRC_BAD_MULTIPART)
worker <- &rep
delete(multipartCollect, xid)
}
worker <- &ofmBarrierRequest{reply}
case ofp4.OFPT_QUEUE_GET_CONFIG_REQUEST:
worker <- &ofmQueueGetConfigRequest{reply}
case ofp4.OFPT_ROLE_REQUEST:
worker <- &ofmRoleRequest{reply}
case ofp4.OFPT_GET_ASYNC_REQUEST:
worker <- &ofmGetAsyncRequest{reply}
case ofp4.OFPT_SET_ASYNC:
worker <- &ofmSetAsync{reply}
case ofp4.OFPT_METER_MOD:
worker <- &ofmMeterMod{reply}
default:
fmt.Printf("unknown ofp_header.type %v\n", msg)
return
}
}
}()
return nil
}
func main() {
flag.Parse()
args := flag.Args()
getConn := func(spec string) io.ReadWriter {
p := strings.SplitN(spec, ":", 2)
if len(p) == 1 {
panic(fmt.Sprintf("connection scheme failure %s", args[0]))
} else if c, err := net.Dial(p[0], p[1]); err != nil {
panic(err)
} else if n, err := c.Write([]byte(hello)); n != 8 || err != nil {
panic("hello send error")
} else if res, err := gopenflow.ReadMessage(c); err != nil {
panic(err)
} else if res[0] != 4 {
panic("openflow version error")
} else if ofp4.Header(res).Type() != ofp4.OFPT_HELLO {
panic("hello recv error")
} else {
return c
}
}
switch args[1] {
case "dump-flows":
con := getConn(args[0])
flowStatsReq := make([]byte, 32)
flowStatsReq[0] = ofp4.OFPTT_ALL
binary.BigEndian.PutUint32(flowStatsReq[4:], ofp4.OFPP_ANY)
binary.BigEndian.PutUint32(flowStatsReq[8:], ofp4.OFPG_ANY)
mphdr := make([]byte, 16)
mphdr[0] = 4
mphdr[1] = ofp4.OFPT_MULTIPART_REQUEST
binary.BigEndian.PutUint16(mphdr[8:], ofp4.OFPMP_FLOW)
msg := append(mphdr, append(flowStatsReq, ofp4.MakeMatch(nil)...)...)
binary.BigEndian.PutUint16(msg[2:], uint16(len(msg)))
con.Write(msg)
for {
var seq ofp4.FlowStats
if msg, err := gopenflow.ReadMessage(con); err != nil {
panic(err)
} else if ofp4.Header(msg).Type() != ofp4.OFPT_MULTIPART_REPLY {
panic("multipart error")
} else if mp := ofp4.MultipartReply(msg); mp.Type() != ofp4.OFPMP_FLOW {
panic("flow_stats reply error")
} else {
seq = ofp4.FlowStats(mp.Body())
}
var lines []string
for _, stat := range seq.Iter() {
lines = append(lines, fmt.Sprintf("%v pkts=%d bytes=%d dur=%d", stat, stat.PacketCount(), stat.ByteCount(), stat.DurationSec()))
}
sort.Sort(sort.Reverse(sort.StringSlice(lines)))
for _, line := range lines {
fmt.Print(line, "\n")
}
if binary.BigEndian.Uint16(mphdr[10:])&ofp4.OFPMPF_REPLY_MORE == 0 {
break
}
}
case "add-flow":
flow := ofp4.FlowMod(make([]byte, 56))
if err := flow.Parse(args[2]); err != nil {
panic(err)
} else {
con := getConn(args[0])
con.Write([]byte(flow))
con.Write([]byte(barrier))
if res, err := gopenflow.ReadMessage(con); err != nil {
panic(err)
} else if ofp4.Header(res).Type() == ofp4.OFPT_ERROR {
log.Print("error")
}
}
case "del-flows":
flow := ofp4.FlowMod(make([]byte, 56))
flow[25] = ofp4.OFPFC_DELETE
if err := flow.Parse(args[2]); err != nil {
panic(err)
} else {
con := getConn(args[0])
con.Write([]byte(flow))
con.Write([]byte(barrier))
for {
if res, err := gopenflow.ReadMessage(con); err != nil {
panic(err)
} else if ofp4.Header(res).Type() == ofp4.OFPT_BARRIER_REPLY {
break
} else {
log.Print(res)
}
}
}
default:
panic(fmt.Sprintf("unknown subcommand %s", args[1]))
}
}
func (self *ofmReply) createError(ofpet uint16, code uint16) {
self.resps = append(self.resps,
ofp4.Header(ofp4.MakeErrorMsg(ofpet, code)).AppendData(self.req).SetXid(self.req.Xid()))
}
