func (s *XLSuite) makeALocalEndPoint(c *C, node *xn.Node) {
addr := fmt.Sprintf("127.0.0.1:0")
ep, err := xt.NewTcpEndPoint(addr)
c.Assert(err, IsNil)
c.Assert(ep, Not(IsNil))
ndx, err := node.AddEndPoint(ep)
c.Assert(err, IsNil)
c.Assert(ndx, Equals, 0) // it's the only one
}
func NewMemberInfoFromToken(token *XLRegMsg_Token) (
m *xcl.MemberInfo, err error) {
var (
ck, sk *rsa.PublicKey
ctor xt.ConnectorI
ctors []xt.ConnectorI
farEnd xt.EndPointI
nodeID *xi.NodeID
peer *xn.Peer
)
if token == nil {
err = NilToken
} else {
nodeID, err = xi.New(token.GetID())
if err == nil {
ck, err = xc.RSAPubKeyFromWire(token.GetCommsKey())
if err == nil {
sk, err = xc.RSAPubKeyFromWire(token.GetSigKey())
if err == nil {
attrs := token.GetAttrs()
myEnds := token.GetMyEnds()
for i := 0; i < len(myEnds); i++ {
myEnd := myEnds[i]
farEnd, err = xt.NewTcpEndPoint(myEnd)
if err != nil {
break
}
ctor, err = xt.NewTcpConnector(farEnd)
if err != nil {
break
}
ctors = append(ctors, ctor)
}
if err == nil {
peer, err = xn.NewPeer(token.GetName(), nodeID,
ck, sk, nil, ctors)
if err == nil {
m = &xcl.MemberInfo{
Attrs: attrs,
Peer: peer,
}
}
}
}
//if err == nil {
// m, err = NewMemberInfo(token.GetName(), nodeID,
// ck, sk, token.GetAttrs(), token.GetMyEnds())
//}
}
}
}
return
}
func (s *XLSuite) shouldGetDefault(c *C, addr string) OverlayI {
e, err := xt.NewTcpEndPoint(addr)
c.Assert(err, Equals, nil)
c.Assert(e, Not(Equals), nil)
o, err := DefaultOverlay(e)
c.Assert(err, Equals, nil)
c.Assert(o.Name(), Not(Equals), "") // NPE?
c.Assert(o.Transport(), Equals, "ip")
c.Assert(o.Cost(), Equals, float32(1.0))
return o
}
func NewMockUpaxClient(name, lfs string, members []*xcl.MemberInfo,
primary uint) (mc *MockUpaxClient, err error) {
var (
ckPriv, skPriv *rsa.PrivateKey
ep []xt.EndPointI
node *xn.Node
uc *UpaxClient
)
// lfs should be a well-formed POSIX path; if the directory does
// not exist we should create it.
err = xf.CheckLFS(lfs, 0750)
// The ckPriv is an RSA key used to encrypt short messages.
if err == nil {
if ckPriv == nil {
ckPriv, err = rsa.GenerateKey(rand.Reader, 2048)
}
if err == nil {
// The skPriv is an RSA key used to create digital signatures.
if skPriv == nil {
skPriv, err = rsa.GenerateKey(rand.Reader, 2048)
}
}
}
// The mock client uses a system-assigned endpoint
if err == nil {
var endPoint *xt.TcpEndPoint
endPoint, err = xt.NewTcpEndPoint("127.0.0.1:0")
if err == nil {
ep = []xt.EndPointI{endPoint}
}
}
// spin up an XLattice node
if err == nil {
node, err = xn.New(name, nil, // get a default NodeID
lfs, ckPriv, skPriv, nil, ep, nil) // nil overlays, peers
}
if err == nil {
uc, err = NewUpaxClient(ckPriv, skPriv, node, members, primary)
if err == nil {
mc = &MockUpaxClient{
UpaxClient: *uc,
}
}
}
return
}
// same test using NewCIDRAddrRange()
func (s *XLSuite) TestIsElement2(c *C) {
rng := xr.MakeSimpleRNG()
name := rng.NextFileName(8)
a10_8, err := NewCIDRAddrRange("10.0.0.0/8")
c.Assert(err, IsNil)
o10_8, err := NewIPOverlay(name, a10_8, "ip", 1.0)
c.Assert(err, IsNil)
// bad transport(s)
mockE := xt.NewMockEndPoint("foo", "1234")
c.Assert(o10_8.IsElement(mockE), Equals, false)
// 10/8 ---------------------------------------------------------
c.Assert(a10_8.PrefixLen(), Equals, uint(8))
c.Assert(a10_8.AddrLen(), Equals, uint(32))
prefix := a10_8.Prefix()
c.Assert(prefix[0], Equals, byte(10))
e1, err := xt.NewTcpEndPoint("10.11.12.13:55555")
c.Assert(err, IsNil)
c.Assert(e1, Not(IsNil))
c.Assert(o10_8.IsElement(e1), Equals, true)
e2, err := xt.NewTcpEndPoint("9.10.11.12:4444")
c.Assert(err, IsNil)
c.Assert(e2, Not(IsNil))
c.Assert(o10_8.IsElement(e2), Equals, false)
// 192.168/16 ---------------------------------------------------
a192_168, err := NewCIDRAddrRange("192.168.0.0/16")
c.Assert(err, IsNil)
o192_168, err := NewIPOverlay(name, a192_168, "ip", 1.0)
c.Assert(err, IsNil)
c.Assert(a192_168.PrefixLen(), Equals, uint(16))
c.Assert(a192_168.AddrLen(), Equals, uint(32))
prefix = a192_168.Prefix()
c.Assert(prefix[0], Equals, byte(192))
c.Assert(prefix[1], Equals, byte(168))
e10, err := xt.NewTcpEndPoint("192.168.0.0:1")
c.Assert(err, IsNil)
c.Assert(o192_168.IsElement(e10), Equals, true)
e11, err := xt.NewTcpEndPoint("192.168.255.255:2")
c.Assert(err, IsNil)
c.Assert(o192_168.IsElement(e11), Equals, true)
e20, err := xt.NewTcpEndPoint("192.167.255.255:3")
c.Assert(err, IsNil)
c.Assert(o192_168.IsElement(e20), Equals, false)
e21, err := xt.NewTcpEndPoint("192.169.0.0:4")
c.Assert(err, IsNil)
c.Assert(o192_168.IsElement(e21), Equals, false)
}
/**
* Do whatever is necessary to transition a Node to the running state;
* in particular, open all acceptors.
*/
func (n *Node) OpenAcc() (err error) {
n.mu.Lock()
defer n.mu.Unlock()
if !n.running {
// XXX STUB
n.running = true
count := len(n.endPoints)
if count > 0 {
for i := 0; err == nil && i < count; i++ {
var acc *xt.TcpAcceptor
e := n.endPoints[i]
// DEBUG
//fmt.Printf("OpenAcc: endPoint %d is %s\n", i, e.String())
// END
if e.Transport() == "tcp" {
// XXX HACK ON ADDRESS
strAddr := e.String()[13:]
unBound := strings.HasSuffix(strAddr, ":0")
acc, err = xt.NewTcpAcceptor(strAddr)
if err == nil && unBound {
// DEBUG
//fmt.Printf("BINDING endPoint %d\n", i)
// END
strAddr = acc.String()[26:]
n.endPoints[i], err = xt.NewTcpEndPoint(strAddr)
}
// DEBUG
//fmt.Printf("OpenAcc: acceptor %d is %s\n", i, acc.String())
//fmt.Printf("OpenAcc: endPoint %d is %s\n",
// i, n.endPoints[i].String())
// END
}
if err == nil {
n.acceptors = append(n.acceptors, acc) // XXX ACCEPTORS
}
}
}
}
return
}
func (s *XLSuite) makeANode(c *C) (badGuy *xn.Node, acc xt.AcceptorI) {
rng := xr.MakeSimpleRNG()
id := make([]byte, xu.SHA1_BIN_LEN)
rng.NextBytes(id)
nodeID, err := xi.NewNodeID(id)
c.Assert(err, IsNil)
name := rng.NextFileName(8)
lfs := "tmp/" + hex.EncodeToString(id)
badGuy, err = xn.NewNew(name, nodeID, lfs)
c.Assert(err, IsNil)
accCount := badGuy.SizeAcceptors()
c.Assert(accCount, Equals, 0)
ep, err := xt.NewTcpEndPoint("127.0.0.1:0")
c.Assert(err, IsNil)
ndx, err := badGuy.AddEndPoint(ep)
c.Assert(err, IsNil)
c.Assert(ndx, Equals, 0)
acc = badGuy.GetAcceptor(0)
return
}
func (s *XLSuite) TestPeerSerialization(c *C) {
if VERBOSITY > 0 {
fmt.Println("TEST_PEER_SERIALIZATION")
}
rng := xr.MakeSimpleRNG()
// this is just a lazy way of building a peer
name := rng.NextFileName(4)
nid, err := makeNodeID(rng)
c.Assert(err, Equals, nil)
lfs := "tmp/" + hex.EncodeToString(nid.Value())
node, err := NewNew(name, nid, lfs)
c.Assert(err, Equals, nil)
// harvest its keys
ck := &node.ckPriv.PublicKey
ckPEM, err := xc.RSAPubKeyToPEM(ck)
c.Assert(err, Equals, nil)
sk := &node.skPriv.PublicKey
skPEM, err := xc.RSAPubKeyToPEM(sk)
c.Assert(err, Equals, nil)
// the other bits necessary
port := 1024 + rng.Intn(1024)
addr := fmt.Sprintf("1.2.3.4:%d", port)
ep, err := xt.NewTcpEndPoint(addr)
c.Assert(err, Equals, nil)
ctor, err := xt.NewTcpConnector(ep)
c.Assert(err, Equals, nil)
overlay, err := xo.DefaultOverlay(ep)
c.Assert(err, Equals, nil)
oSlice := []xo.OverlayI{overlay}
ctorSlice := []xt.ConnectorI{ctor}
peer, err := NewPeer(name, nid, ck, sk, oSlice, ctorSlice)
c.Assert(err, Equals, nil)
c.Assert(peer, Not(Equals), nil)
// build the expected serialization
// BaseNode
var bns []string
s.addAString(&bns, "peer {")
s.addAString(&bns, fmt.Sprintf(" name: %s", name))
s.addAString(&bns, fmt.Sprintf(" nodeID: %s", nid.String()))
s.addAString(&bns, fmt.Sprintf(" commsPubKey: %s", ckPEM))
s.addAString(&bns, fmt.Sprintf(" sigPubKey: %s", skPEM))
s.addAString(&bns, fmt.Sprintf(" overlays {"))
for i := 0; i < len(oSlice); i++ {
s.addAString(&bns, fmt.Sprintf(" %s", oSlice[i].String()))
}
s.addAString(&bns, fmt.Sprintf(" }"))
// Specific to Peer
s.addAString(&bns, fmt.Sprintf(" connectors {"))
for i := 0; i < len(ctorSlice); i++ {
s.addAString(&bns, fmt.Sprintf(" %s", ctorSlice[i].String()))
}
s.addAString(&bns, fmt.Sprintf(" }")) // closes connectors
s.addAString(&bns, fmt.Sprintf("}")) // closes peer
myVersion := strings.Join(bns, "\n")
serialized := peer.String()
c.Assert(serialized, Equals, myVersion)
backAgain, rest, err := ParsePeer(serialized)
c.Assert(err, Equals, nil)
c.Assert(len(rest), Equals, 0)
reserialized := backAgain.String()
c.Assert(reserialized, Equals, serialized)
}
func (s *XLSuite) doTestCluster(c *C, rng *xr.PRNG, whichSHA int) {
if VERBOSITY > 0 {
fmt.Printf("TEST_CLUSTER whichSHA = %v\n", whichSHA)
}
// read regCred.dat to get keys etc for a registry --------------
dat, err := ioutil.ReadFile("regCred.dat")
c.Assert(err, IsNil)
regCred, err := reg.ParseRegCred(string(dat))
c.Assert(err, IsNil)
regServerName := regCred.Name
regServerID := regCred.ID
regServerEnd := regCred.EndPoints[0]
regServerCK := regCred.CommsPubKey
regServerSK := regCred.SigPubKey
// Devise a unique cluster name. We rely on the convention -----
// that in Upax tests, the local file system for Upax servers is
// tmp/CLUSTER-NAME/SERVER-NAME.
clusterName := rng.NextFileName(8)
clusterPath := filepath.Join("tmp", clusterName)
for {
if _, err = os.Stat(clusterPath); os.IsNotExist(err) {
break
}
clusterName = rng.NextFileName(8)
clusterPath = filepath.Join("tmp", clusterName)
}
err = xf.CheckLFS(clusterPath, 0750)
c.Assert(err, IsNil)
// DEBUG
fmt.Printf("CLUSTER %s\n", clusterName)
fmt.Printf("CLUSTER_PATH %s\n", clusterPath)
// END
// Set the test size in various senses --------------------------
// K1 is the number of servers, and so the cluster size. K2 is
// the number of clients, M the number of messages sent (items to
// be added to the Upax store), LMin and LMax message lengths.
K1 := uint32(3 + rng.Intn(5)) // so 3..7
K2 := uint32(2 + rng.Intn(4)) // so 2..5
M := 16 + rng.Intn(16) // 16..31
LMin := 64 + rng.Intn(64)
LMax := 128 + rng.Intn(128)
// Use an admin client to get a clusterID for this clusterName --
const EP_COUNT = 2
an, err := reg.NewAdminClient(regServerName, regServerID, regServerEnd,
regServerCK, regServerSK, clusterName, uint64(0), K1, EP_COUNT, nil)
c.Assert(err, IsNil)
an.Start()
<-an.DoneCh
clusterID := an.ClusterID // a NodeID, not []byte
if clusterID == nil {
fmt.Println("NIL CLUSTER ID: is xlReg running??")
}
c.Assert(clusterID, NotNil)
clusterSize := an.ClusterMaxSize
c.Assert(clusterSize, Equals, uint32(K1))
epCount := an.EPCount
c.Assert(epCount, Equals, uint32(EP_COUNT))
// Create names and LFSs for the K1 members ---------------------
// We create a distinct tmp/clusterName/serverName for each
// server as its local file system (LFS).
memberNames := make([]string, K1)
memberPaths := make([]string, K1)
ckPriv := make([]*rsa.PrivateKey, K1)
skPriv := make([]*rsa.PrivateKey, K1)
for i := uint32(0); i < K1; i++ {
var found bool
memberNames[i] = rng.NextFileName(8)
memberPaths[i] = filepath.Join(clusterPath, memberNames[i])
found, err = xf.PathExists(memberPaths[i])
c.Assert(err, IsNil)
for found {
memberNames[i] = rng.NextFileName(8)
memberPaths[i] = filepath.Join(clusterPath, memberNames[i])
found, err = xf.PathExists(memberPaths[i])
c.Assert(err, IsNil)
}
// DEBUG
fmt.Printf("MEMBER_PATH[%d]: %s\n", i, memberPaths[i])
// END
err = os.MkdirAll(memberPaths[i], 0750)
c.Assert(err, IsNil)
ckPriv[i], err = rsa.GenerateKey(rand.Reader, 1024) // cheap keys
c.Assert(err, IsNil)
c.Assert(ckPriv[i], NotNil)
skPriv[i], err = rsa.GenerateKey(rand.Reader, 1024) // cheap keys
c.Assert(err, IsNil)
c.Assert(skPriv[i], NotNil)
}
// create K1 client nodes ---------------------------------------
uc := make([]*reg.UserMember, K1)
for i := uint32(0); i < K1; i++ {
var ep1, ep2 *xt.TcpEndPoint
ep1, err = xt.NewTcpEndPoint("127.0.0.1:0")
ep2, err = xt.NewTcpEndPoint("127.0.0.1:0")
c.Assert(err, IsNil)
e := []xt.EndPointI{ep1, ep2}
uc[i], err = reg.NewUserMember(memberNames[i], memberPaths[i],
ckPriv[i], skPriv[i],
regServerName, regServerID, regServerEnd, regServerCK, regServerSK,
clusterName, an.ClusterAttrs, an.ClusterID,
K1, EP_COUNT, e)
c.Assert(err, IsNil)
c.Assert(uc[i], NotNil)
c.Assert(uc[i].ClusterID, NotNil)
c.Assert(uc[i].MemberMaker.DoneCh, NotNil)
}
// Start the K1 client nodes running ----------------------------
for i := uint32(0); i < K1; i++ {
uc[i].Start()
}
fmt.Println("ALL CLIENTS STARTED")
// wait until all clientNodes are done --------------------------
for i := uint32(0); i < K1; i++ {
err = <-uc[i].MemberMaker.DoneCh
c.Assert(err, IsNil)
// nodeID := uc[i].clientID
}
fmt.Println("ALL CLIENTS DONE") // XXX NOT SEEN
// verify that all clientNodes have meaningful baseNodes --------
// XXX THESE TESTS ALWAYS FAIL
//for i := 0; i < K1; i++ {
// c.Assert(uc[i].GetName(), Equals, memberNames[i])
// c.Assert(uc[i].GetNodeID(), NotNil)
// c.Assert(uc[i].GetCommsPublicKey(), NotNil)
// c.Assert(uc[i].GetSigPublicKey(), NotNil)
//}
// convert the client nodes to UpaxServers ----------------------
us := make([]*UpaxServer, K1)
for i := uint32(0); i < K1; i++ {
err = uc[i].PersistClusterMember()
c.Assert(err, IsNil)
us[i], err = NewUpaxServer(
ckPriv[i], skPriv[i], &uc[i].ClusterMember, whichSHA)
c.Assert(err, IsNil)
c.Assert(us[i], NotNil)
}
// verify files are present and then start the servers ----------
// 11-07 TODO, modified:
// Run() causes each server to send ItsMe to all other servers;
// as each gets its Ack, it starts the KeepAlive/Ack cycle running
// at a 50 ms interval specified as a Run() argument and then sends
// on DoneCh. Second parameter is lifetime of the server in
// keep-alives, say 20 (so 1 sec in total). When this time has
// passed, the server will send again on DoneCh, and then shut down.
// XXX STUB
for i := uint32(0); i < K1; i++ {
err = us[i].Run(10*time.Millisecond, 20)
c.Assert(err, IsNil)
}
// Verify servers are running -------------------------
// 11-18: we wait for the first done from each server.
//
// XXX STUB
for i := uint32(0); i < K1; i++ {
<-us[i].DoneCh
}
// DEBUG
fmt.Println("all servers have sent first DONE")
// END
// When all UpaxServers are ready, create K2 clients.--
// Each client creates K3 separate datums of differnt
// length (L1..L2) and content. Each client signals
// when done.
// XXX STUB
// Verify for each of the K2 clients ------------------
// that its data is present on the selected server. We
// do this by an Exists() call on uDir for the server's
// LFS/U for each item posted.
// XXX STUB
// After a reasonable deltaT, verify that all servers--
// have a copy of each and every datum.
// XXX STUB
_, _, _, _ = K2, M, LMin, LMax
}
func (s *XLSuite) TestPortlandRegCred(c *C) {
if VERBOSITY > 0 {
fmt.Println("\nTEST_PORTLAND_REG_CRED")
}
rng := xr.MakeSimpleRNG()
_ = rng
// read our local copy of the reg cred
rcData, err := ioutil.ReadFile("portlandRegCred.dat")
c.Assert(err, IsNil)
rc, err := ParseRegCred(string(rcData))
c.Assert(err, IsNil)
c.Assert(rc, NotNil)
// DEBUG
fmt.Println("portlandRegCred_test PORTLAND - A PUZZLE")
// END
// set up the client --------------------------------------------
name := rng.NextFileName(8)
lfs := path.Join("tmp", name)
found, err := xf.PathExists(lfs)
c.Assert(err, IsNil)
for found {
name = rng.NextFileName(8)
lfs = path.Join("tmp", name)
found, err = xf.PathExists(lfs)
c.Assert(err, IsNil)
}
ep, err := xt.NewTcpEndPoint("127.0.0.1:0")
c.Assert(err, IsNil)
e := []xt.EndPointI{ep}
c.Assert(e, NotNil)
nodeID, err := xi.New(nil)
c.Assert(err, IsNil)
node, err := xn.NewNew(name, nodeID, lfs)
c.Assert(err, IsNil)
// DEBUG
fmt.Printf("Portland client is at %v; lfs is %s\n",
e, lfs)
// END
// set up its relationship to the server ------------------------
serverName := rc.Name
serverID := rc.ID
serverEnd := rc.EndPoints
c.Assert(serverEnd, NotNil)
c.Assert(len(serverEnd) > 0, Equals, true)
c.Assert(serverEnd[0], NotNil)
// XXX TOO RIGID
c.Assert(serverEnd[0].String(), Equals, "TcpEndPoint: 54.186.197.123:56789")
// END
serverCK := rc.CommsPubKey
serverSK := rc.SigPubKey
sc, err := NewSoloMember(node, serverName, serverID, serverEnd[0],
serverCK, serverSK, e)
c.Assert(err, IsNil)
c.Assert(sc, NotNil)
// DEBUG
fmt.Println("SoloMember CREATED")
// END
// 3. run the client
sc.Start()
err = <-sc.DoneCh
// 4. verify that the client LFS exists and is correct ---------
found, err = xf.PathExists(lfs)
c.Assert(err, IsNil)
c.Assert(found, Equals, true)
// 5. shut down the client -------------------------------------
sc.CloseAcc() // should close any acceptors
}
func (s *XLSuite) TestEphServer(c *C) {
if VERBOSITY > 0 {
fmt.Println("\nTEST_EPH_SERVER")
}
rng := xr.MakeSimpleRNG()
// 1. create a new ephemeral server ----------------------------
es, err := NewEphServer()
c.Assert(err, IsNil)
c.Assert(es, NotNil)
server := es.Server
c.Assert(&server.RegNode.ckPriv.PublicKey,
DeepEquals, server.GetCommsPublicKey())
serverName := server.GetName()
serverID := server.GetNodeID()
serverEnd := server.GetEndPoint(0)
serverCK := server.GetCommsPublicKey()
serverSK := server.GetSigPublicKey()
c.Assert(serverEnd, NotNil)
// start the ephemeral server -------------------------
err = es.Start()
c.Assert(err, IsNil)
defer es.Stop() // stop the server, closing its acceptor
// DEBUG
fmt.Printf("TestEphServer: server acc %s\n", server.GetAcceptor().String())
fmt.Printf(" serverEnd %s\n", server.GetEndPoint(0).String())
// END
// verify Bloom filter is running
reg := es.Server.Registry
c.Assert(reg, NotNil)
regID := reg.GetNodeID()
c.Assert(reg.IDCount(), Equals, uint(1)) // the registry's own ID
found, err := reg.ContainsID(regID)
c.Assert(found, Equals, true)
c.Assert(reg.IDCount(), Equals, uint(1))
// 2. create a random cluster name, size, scratch directory -----
clusterName := rng.NextFileName(8)
clusterDir := path.Join("tmp", clusterName)
for {
if _, err = os.Stat(clusterDir); os.IsNotExist(err) {
break
}
clusterName = rng.NextFileName(8)
clusterDir = path.Join("tmp", clusterName)
}
err = xf.CheckLFS(clusterDir, 0750)
c.Assert(err, IsNil)
// DEBUG
fmt.Printf("CLUSTER NAME: %s\n", clusterName)
// END
clusterAttrs := uint64(rng.Int63())
K := uint32(2 + rng.Intn(6)) // so the size is 2 .. 7
// 3. create an AdminClient, use it to get the clusterID
// DEBUG
fmt.Printf("\neph_server_test: creating ADMIN client\n")
// END
an, err := NewAdminClient(serverName, serverID, serverEnd,
serverCK, serverSK, clusterName, clusterAttrs, K, uint32(1), nil)
c.Assert(err, IsNil)
an.Start()
err = <-an.DoneCh
c.Assert(err, IsNil)
anID := an.ClusterMember.Node.GetNodeID()
// DEBUG
fmt.Println("\nADMIN CLIENT GETS:")
fmt.Printf(" regID %s\n", regID.String())
fmt.Printf(" anID %s\n", anID.String())
if an.ClusterID == nil {
fmt.Printf(" ClusterID NIL\n")
} else {
fmt.Printf(" ClusterID %s\n", an.ClusterID.String())
}
// END
c.Check(reg.IDCount(), Equals, uint(3))
c.Assert(an.ClusterID, NotNil) // the purpose of the exercise
c.Assert(an.EPCount, Equals, uint32(1))
found, err = reg.ContainsID(regID)
c.Assert(err, IsNil)
c.Assert(found, Equals, true)
found, err = reg.ContainsID(anID)
c.Assert(err, IsNil)
c.Check(found, Equals, true)
found, err = reg.ContainsID(an.ClusterID)
c.Assert(err, IsNil)
c.Check(found, Equals, true)
c.Check(reg.IDCount(), Equals, uint(3)) // regID + anID + clusterID
// 4. create K members ------------------------------------------
// DEBUG
fmt.Printf("\nCREATING %d MEMBERS\n", K)
// END
uc := make([]*UserMember, K)
ucNames := make([]string, K)
namesInUse := make(map[string]bool)
epCount := uint32(2)
for i := uint32(0); i < K; i++ {
var endPoints []xt.EndPointI
for j := uint32(0); j < epCount; j++ {
var ep *xt.TcpEndPoint
ep, err = xt.NewTcpEndPoint("127.0.0.1:0")
c.Assert(err, IsNil)
endPoints = append(endPoints, ep)
}
newName := rng.NextFileName(8)
_, ok := namesInUse[newName]
for ok {
newName = rng.NextFileName(8)
_, ok = namesInUse[newName]
}
namesInUse[newName] = true
ucNames[i] = newName // guaranteed to be LOCALLY unique
lfs := path.Join(clusterDir, newName)
uc[i], err = NewUserMember(ucNames[i], lfs,
nil, nil, // private RSA keys are generated if nil
serverName, serverID, serverEnd, serverCK, serverSK,
clusterName, an.ClusterAttrs, an.ClusterID,
K, epCount, endPoints)
c.Assert(err, IsNil)
c.Assert(uc[i], NotNil)
c.Assert(uc[i].ClusterID, NotNil)
}
// 5. initialize the K members, each in a separate goroutine ----
for i := uint32(0); i < K; i++ {
uc[i].Start()
}
// wait until all members are initialized -----------------------
for i := uint32(0); i < K; i++ {
doneErr := <-uc[i].MemberMaker.DoneCh
c.Assert(doneErr, IsNil)
// among other things, the Persist makes the nodes start listening
uc[i].MemberMaker.PersistClusterMember()
nodeID := uc[i].MemberMaker.GetNodeID()
c.Assert(nodeID, NotNil)
found, err := reg.ContainsID(nodeID)
c.Assert(err, IsNil)
c.Check(found, Equals, true)
}
c.Assert(reg.IDCount(), Equals, uint(3+K)) // regID + anID + clusterID + K
// 6. verify that the nodes are live ----------------------------
for i := uint32(0); i < K; i++ {
mn := uc[i].MemberMaker
cm := mn.ClusterMember
node := cm.Node
mnEPCount := uint32(node.SizeEndPoints())
c.Assert(mnEPCount, Equals, epCount)
actualEPCount := uint32(mn.SizeEndPoints())
c.Assert(actualEPCount, Equals, epCount)
actualAccCount := uint32(mn.SizeAcceptors())
c.Assert(actualAccCount, Equals, epCount)
for j := uint32(0); j < epCount; j++ {
nodeEP := cm.GetEndPoint(int(j)).String()
nodeAcc := cm.GetAcceptor(int(j)).String()
c.Assert(strings.HasSuffix(nodeEP, ":0"), Equals, false)
c.Assert(strings.HasSuffix(nodeAcc, nodeEP), Equals, true)
// DEBUG
fmt.Printf("node %d: endPoint %d is %s\n",
i, j, cm.GetEndPoint(int(j)).String())
// END
}
}
// verify that results are as expected --------------------------
// XXX STUB XXX
}
func ParseRegCred(s string) (rc *RegCred, err error) {
var (
line string
parts []string
name string
nodeID *xi.NodeID
ck, sk *rsa.PublicKey
e []xt.EndPointI
version xu.DecimalVersion
)
ss := strings.Split(s, "\n")
line, err = xc.NextNBLine(&ss)
if (err == nil) && (line != "regCred {") {
err = IllFormedRegCred
}
if err == nil {
line, err = xc.NextNBLine(&ss)
if err == nil {
parts = strings.Split(line, ": ")
if len(parts) == 2 && parts[0] == "Name" {
name = strings.TrimLeft(parts[1], " \t")
} else {
err = IllFormedRegCred
}
}
}
if err == nil {
var id []byte
line, err = xc.NextNBLine(&ss)
if err == nil {
parts = strings.Split(line, ": ")
if len(parts) == 2 && parts[0] == "ID" {
id, err = hex.DecodeString(parts[1])
} else {
err = IllFormedRegCred
}
}
if err == nil {
nodeID, err = xi.New(id)
}
}
if err == nil {
line, err = xc.NextNBLine(&ss)
if err == nil {
parts = strings.Split(line, ": ")
if len(parts) == 2 && parts[0] == "CommsPubKey" {
ck, err = xc.RSAPubKeyFromDisk([]byte(parts[1]))
} else {
err = IllFormedRegCred
}
}
}
if err == nil {
line, err = xc.NextNBLine(&ss)
if err == nil {
parts = strings.Split(line, ": ")
if len(parts) == 2 && parts[0] == "SigPubKey" {
sk, err = xc.RSAPubKeyFromDisk([]byte(parts[1]))
} else {
err = IllFormedRegCred
}
}
}
if err == nil {
line, err = xc.NextNBLine(&ss)
if err == nil {
// collect EndPoints section; this should be turned into a
// utility function
if line == "EndPoints {" {
for err == nil {
line = strings.TrimSpace(ss[0]) // peek
if line == "}" {
break
}
line, err = xc.NextNBLine(&ss)
if err == nil {
line = strings.TrimSpace(line)
parts := strings.Split(line, ": ")
if len(parts) != 2 || parts[0] != "TcpEndPoint" {
err = IllFormedRegCred
} else {
var ep xt.EndPointI
ep, err = xt.NewTcpEndPoint(parts[1])
if err == nil {
e = append(e, ep)
}
}
}
}
if err == nil {
line, err = xc.NextNBLine(&ss)
if (err == nil) && (line != "}") {
err = MissingClosingBrace
}
}
} else {
err = MissingEndPointsSection
}
}
}
if err == nil {
line, err = xc.NextNBLine(&ss)
if err == nil {
parts = strings.Split(line, ": ")
if len(parts) == 2 && parts[0] == "Version" {
version, err = xu.ParseDecimalVersion(parts[1])
} else {
err = IllFormedRegCred
}
}
}
if err == nil {
rc = &RegCred{
Name: name,
ID: nodeID,
CommsPubKey: ck,
SigPubKey: sk,
EndPoints: e,
Version: version,
}
}
return
}
func MockLocalHostCluster(K int) (nodes []*Node, accs []*xt.TcpAcceptor) {
rng := xr.MakeSimpleRNG()
// Create K nodes, each with a NodeID, two RSA private keys (sig and
// comms), and two RSA public keys. Each node creates a TcpAcceptor
// running on 127.0.0.1 and a random (= system-supplied) port.
names := make([]string, K)
nodeIDs := make([]*xi.NodeID, K)
for i := 0; i < K; i++ {
// TODO: MAKE NAMES UNIQUE
names[i] = rng.NextFileName(4)
val := make([]byte, xu.SHA1_BIN_LEN)
rng.NextBytes(val)
nodeIDs[i], _ = xi.NewNodeID(val)
}
nodes = make([]*Node, K)
accs = make([]*xt.TcpAcceptor, K)
accEndPoints := make([]*xt.TcpEndPoint, K)
for i := 0; i < K; i++ {
lfs := "tmp/" + hex.EncodeToString(nodeIDs[i].Value())
nodes[i], _ = NewNew(names[i], nodeIDs[i], lfs)
}
// XXX We need this functionality in using code
// defer func() {
// for i := 0; i < K; i++ {
// if accs[i] != nil {
// accs[i].CloseAcc()
// }
// }
// }()
// Collect the nodeID, public keys, and listening address from each
// node.
// all nodes on the same overlay
ar, _ := xo.NewCIDRAddrRange("127.0.0.0/8")
overlay, _ := xo.NewIPOverlay("XO", ar, "tcp", 1.0)
// add an endpoint to each node
for i := 0; i < K; i++ {
ep, _ := xt.NewTcpEndPoint("127.0.0.1:0")
nodes[i].AddEndPoint(ep)
nodes[i].OpenAcc() // XXX POSSIBLE ERRORS IGNORED
accs[i] = nodes[i].GetAcceptor(0).(*xt.TcpAcceptor)
accEndPoints[i] = accs[i].GetEndPoint().(*xt.TcpEndPoint)
}
ckPrivs := make([]*rsa.PublicKey, K)
skPrivs := make([]*rsa.PublicKey, K)
ctors := make([]*xt.TcpConnector, K)
for i := 0; i < K; i++ {
// we already have nodeIDs
ckPrivs[i] = nodes[i].GetCommsPublicKey()
skPrivs[i] = nodes[i].GetSigPublicKey()
ctors[i], _ = xt.NewTcpConnector(accEndPoints[i])
}
overlaySlice := []xo.OverlayI{overlay}
peers := make([]*Peer, K)
for i := 0; i < K; i++ {
ctorSlice := []xt.ConnectorI{ctors[i]}
_ = ctorSlice
peers[i], _ = NewPeer(names[i], nodeIDs[i], ckPrivs[i], skPrivs[i],
overlaySlice, ctorSlice)
}
// Use the information collected to configure each node.
for i := 0; i < K; i++ {
for j := 0; j < K; j++ {
if i != j {
nodes[i].AddPeer(peers[j])
}
}
}
return
}
func (s *XLSuite) TestSoloMember(c *C) {
if VERBOSITY > 0 {
fmt.Println("\nTEST_SOLO_CLIENT")
}
rng := xr.MakeSimpleRNG()
// 1. create a new ephemeral server ----------------------------
es, err := NewEphServer()
c.Assert(err, IsNil)
c.Assert(es, NotNil)
server := es.Server
c.Assert(&server.RegNode.ckPriv.PublicKey,
DeepEquals, server.GetCommsPublicKey())
serverName := server.GetName()
serverID := server.GetNodeID()
serverEnd := server.GetEndPoint(0)
serverCK := server.GetCommsPublicKey()
serverSK := server.GetSigPublicKey()
c.Assert(serverEnd, NotNil)
// start the mock server ------------------------------
err = es.Start()
c.Assert(err, IsNil)
// 2. create the solo client ------------------------------------
name := rng.NextFileName(8)
lfs := path.Join("tmp", name)
found, err := xf.PathExists(lfs)
c.Assert(err, IsNil)
for found {
name = rng.NextFileName(8)
lfs = path.Join("tmp", name)
found, err = xf.PathExists(lfs)
c.Assert(err, IsNil)
}
ep, err := xt.NewTcpEndPoint("127.0.0.1:0")
c.Assert(err, IsNil)
e := []xt.EndPointI{ep}
nodeID, err := xi.New(nil)
c.Assert(err, IsNil)
node, err := xn.NewNew(name, nodeID, lfs)
c.Assert(err, IsNil)
sc, err := NewSoloMember(node, serverName, serverID, serverEnd,
serverCK, serverSK, e)
c.Assert(err, IsNil)
c.Assert(sc, NotNil)
// 3. run the client
sc.Start()
err = <-sc.DoneCh
// 4. verify that the client LFS exists and is correct ---------
found, err = xf.PathExists(lfs)
c.Assert(err, IsNil)
c.Assert(found, Equals, true)
// 5. shut down the client -------------------------------------
sc.CloseAcc() // should close any acceptors
// 6. stop the server, closing its acceptor --------------------
es.Stop()
}
func main() {
var err error
flag.Usage = Usage
flag.Parse()
// FIXUPS ///////////////////////////////////////////////////////
if err != nil {
fmt.Println("error processing NodeID: %s\n", err.Error())
os.Exit(-1)
}
if *testing {
if *name == DEFAULT_NAME || *name == "" {
*name = "testReg"
}
if *lfs == DEFAULT_LFS || *lfs == "" {
*lfs = "./myApp/xlReg"
} else {
*lfs = path.Join("tmp", *lfs)
}
if *address == DEFAULT_ADDR {
*address = "127.0.0.1"
}
if *globalAddress == DEFAULT_GLOBAL_ADDR {
*globalAddress = "127.0.0.1"
}
if *port == DEFAULT_PORT || *port == 0 {
*port = TEST_DEFAULT_PORT
}
}
var backingFile string
if !*ephemeral {
backingFile = path.Join(*lfs, "idFilter.dat")
}
addrAndPort := fmt.Sprintf("%s:%d", *address, *port)
endPoint, err := xt.NewTcpEndPoint(addrAndPort)
if err != nil {
fmt.Printf("not a valid endPoint: %s\n", addrAndPort)
Usage()
os.Exit(-1)
}
globalAddrAndPort := fmt.Sprintf("%s:%d", *globalAddress, *port)
globalEndPoint, err := xt.NewTcpEndPoint(globalAddrAndPort)
if err != nil {
fmt.Printf("not a valid endPoint: %s\n", globalAddrAndPort)
Usage()
os.Exit(-1)
}
// SANITY CHECKS ////////////////////////////////////////////////
if err == nil {
if *m < 2 {
*m = 20
}
if *k < 2 {
*k = 8
}
err = xf.CheckLFS(*lfs, 0700) // tries to create if it doesn't exist
if err == nil {
if *logFile != "" {
*logFile = path.Join(*lfs, *logFile)
}
}
}
// DISPLAY STUFF ////////////////////////////////////////////////
if *verbose || *justShow {
fmt.Printf("address = %v\n", *address)
fmt.Printf("backingFile = %v\n", backingFile)
fmt.Printf("clearFilter = %v\n", *clearFilter)
fmt.Printf("endPoint = %v\n", endPoint)
fmt.Printf("ephemeral = %v\n", *ephemeral)
fmt.Printf("globalAddress = %v\n", *globalAddress)
fmt.Printf("globalEndPoint = %v\n", *globalEndPoint)
fmt.Printf("justShow = %v\n", *justShow)
fmt.Printf("k = %d\n", *k)
fmt.Printf("lfs = %s\n", *lfs)
fmt.Printf("logFile = %s\n", *logFile)
fmt.Printf("m = %d\n", *m)
fmt.Printf("name = %s\n", *name)
fmt.Printf("port = %d\n", *port)
fmt.Printf("testing = %v\n", *testing)
fmt.Printf("verbose = %v\n", *verbose)
}
if *justShow {
return
}
// SET UP OPTIONS ///////////////////////////////////////////////
var (
f *os.File
logger *log.Logger
opt reg.RegOptions
rs *reg.RegServer
)
if *logFile != "" {
f, err = os.OpenFile(*logFile, os.O_CREATE|os.O_WRONLY|os.O_APPEND, 0660)
if err == nil {
logger = log.New(f, "", log.Ldate|log.Ltime)
}
}
if f != nil {
defer f.Close()
}
if err == nil {
opt.Address = *address
opt.BackingFile = backingFile
opt.ClearFilter = *clearFilter
opt.Ephemeral = *ephemeral
opt.GlobalEndPoint = globalEndPoint
opt.K = uint(*k)
opt.Lfs = *lfs
opt.Logger = logger
opt.M = uint(*m)
opt.Lfs = *lfs
opt.Port = fmt.Sprintf("%d", *port)
opt.T = *t
opt.Testing = *testing
opt.Verbose = *verbose
rs, err = setup(&opt)
if err == nil {
err = serve(rs)
}
}
_ = logger // NOT YET
_ = err
}
// This was copied from cluster_test.go and minimal changes have been
// made.
//
func (s *XLSuite) doTestPair(c *C, rng *xr.PRNG, whichSHA int) {
if VERBOSITY > 0 {
fmt.Printf("TEST_PAIR whichSHA = %v\n", whichSHA)
}
// read regCred.dat to get keys etc for a registry --------------
dat, err := ioutil.ReadFile("regCred.dat")
c.Assert(err, IsNil)
regCred, err := reg.ParseRegCred(string(dat))
c.Assert(err, IsNil)
regServerName := regCred.Name
regServerID := regCred.ID
regServerEnd := regCred.EndPoints[0]
regServerCK := regCred.CommsPubKey
regServerSK := regCred.SigPubKey
// Devise a unique cluster name. We rely on the convention -----
// that in Upax tests, the local file system for Upax servers is
// tmp/CLUSTER-NAME/SERVER-NAME.
clusterName := rng.NextFileName(8)
clusterPath := filepath.Join("tmp", clusterName)
found, err := xf.PathExists(clusterPath)
c.Assert(err, IsNil)
for found {
clusterName = rng.NextFileName(8)
clusterPath = filepath.Join("tmp", clusterName)
found, err = xf.PathExists(clusterPath)
c.Assert(err, IsNil)
}
// Set the test size in various senses --------------------------
// K1 is the number of upax servers, and so the cluster size. K2 is
// the number of upax clients, M the number of messages sent (items to
// be added to the Upax store), LMin and LMax message lengths.
K1 := uint32(2)
K2 := 1
M := 16 + rng.Intn(16) // 16..31
LMin := 64 + rng.Intn(64)
LMax := 128 + rng.Intn(128)
// Use an admin client to get a clusterID for this clusterName --
const EP_COUNT = 2
an, err := reg.NewAdminClient(regServerName, regServerID, regServerEnd,
regServerCK, regServerSK, clusterName, uint64(0), K1, EP_COUNT, nil)
c.Assert(err, IsNil)
an.Start()
cn := &an.MemberMaker
<-cn.DoneCh
clusterID := cn.ClusterID
if clusterID == nil {
fmt.Println("NIL CLUSTER ID: is xlReg running??")
}
c.Assert(clusterID, NotNil) // FAILS 2016-11-13
clusterSize := cn.ClusterMaxSize
c.Assert(clusterSize, Equals, uint32(K1))
epCount := cn.EPCount
c.Assert(epCount, Equals, uint32(EP_COUNT))
// DEBUG
// fmt.Printf("cluster %s: %s\n", clusterName, clusterID.String())
// END
// Create names and LFSs for the K1 servers ---------------------
// We create a distinct tmp/clusterName/serverName for each
// server as its local file system (LFS).
serverNames := make([]string, K1)
serverPaths := make([]string, K1)
ckPriv := make([]*rsa.PrivateKey, K1)
skPriv := make([]*rsa.PrivateKey, K1)
for i := uint32(0); i < K1; i++ {
serverNames[i] = rng.NextFileName(8)
serverPaths[i] = filepath.Join(clusterPath, serverNames[i])
found, err = xf.PathExists(serverPaths[i])
c.Assert(err, IsNil)
for found {
serverNames[i] = rng.NextFileName(8)
serverPaths[i] = filepath.Join(clusterPath, serverNames[i])
found, err = xf.PathExists(serverPaths[i])
c.Assert(err, IsNil)
}
err = os.MkdirAll(serverPaths[i], 0750)
c.Assert(err, IsNil)
ckPriv[i], err = rsa.GenerateKey(rand.Reader, 1024) // cheap keys
c.Assert(err, IsNil)
c.Assert(ckPriv[i], NotNil)
skPriv[i], err = rsa.GenerateKey(rand.Reader, 1024) // cheap keys
c.Assert(err, IsNil)
c.Assert(skPriv[i], NotNil)
}
// create K1 reg client nodes -----------------------------------
uc := make([]*reg.UserMember, K1)
for i := uint32(0); i < K1; i++ {
var ep *xt.TcpEndPoint
ep, err = xt.NewTcpEndPoint("127.0.0.1:0")
c.Assert(err, IsNil)
e := []xt.EndPointI{ep}
uc[i], err = reg.NewUserMember(serverNames[i], serverPaths[i],
ckPriv[i], skPriv[i],
regServerName, regServerID, regServerEnd, regServerCK, regServerSK,
clusterName, cn.ClusterAttrs, cn.ClusterID,
K1, EP_COUNT, e)
c.Assert(err, IsNil)
c.Assert(uc[i], NotNil)
c.Assert(uc[i].ClusterID, NotNil)
}
// Start the K1 reg client nodes running ------------------------
for i := uint32(0); i < K1; i++ {
uc[i].Start()
}
// wait until all reg clientNodes are done ----------------------
for i := uint32(0); i < K1; i++ {
err := <-uc[i].MemberMaker.DoneCh
c.Assert(err, IsNil)
}
// verify that all clientNodes have meaningful baseNodes --------
//for i := 0; i < K1; i++ {
// c.Assert(uc[i].GetName(), Equals, serverNames[i])
// c.Assert(uc[i].GetNodeID(), NotNil)
// c.Assert(uc[i].GetCommsPublicKey(), NotNil)
// c.Assert(uc[i].GetSigPublicKey(), NotNil)
//}
// verify that all clientNode members have meaningful baseNodes -
for i := uint32(0); i < K1; i++ {
// fmt.Printf(" server %s\n", serverNames[i]) // DEBUG
memberCount := uint32(len(uc[i].Members))
c.Assert(memberCount, Equals, K1)
for j := uint32(0); j < memberCount; j++ {
c.Assert(uc[i].Members[j], NotNil)
// DEBUG
// fmt.Printf(" other server[%d] is %s\n", j, serverNames[j])
// END
// doesn't work because reg server does not necessarily see
// members in serverName order.
// c.Assert(uc[i].Members[j].GetName(), Equals, serverNames[j])
c.Assert(uc[i].Members[j].Peer.GetName() == "", Equals, false)
c.Assert(uc[i].Members[j].Peer.GetNodeID(), NotNil)
c.Assert(uc[i].Members[j].Peer.GetCommsPublicKey(), NotNil)
c.Assert(uc[i].Members[j].Peer.GetSigPublicKey(), NotNil)
}
}
// convert the reg client nodes to UpaxServers ------------------
us := make([]*UpaxServer, K1)
for i := uint32(0); i < K1; i++ {
err = uc[i].PersistClusterMember() // sometimes panics
c.Assert(err, IsNil)
us[i], err = NewUpaxServer(
ckPriv[i], skPriv[i], &uc[i].ClusterMember, whichSHA)
c.Assert(err, IsNil)
c.Assert(us[i], NotNil)
}
// verify files are present and then start the servers ----------
// 11-07 TODO, modified:
// Run() causes each server to send ItsMe to all other servers;
// as each gets its Ack, it starts the KeepAlive/Ack cycle running
// at a 50 ms interval specified as a Run() argument and then sends
// on DoneCh. Second parameter is lifetime of the server in
// keep-alives, say 20 (so 1 sec in total). When this time has
// passed, the server will send again on DoneCh, and then shut down.
// XXX STUB
for i := uint32(0); i < K1; i++ {
err = us[i].Run(10*time.Millisecond, 20)
c.Assert(err, IsNil)
}
// Verify servers are running -------------------------
// 11-18: we wait for the first done from each server.
//
// XXX STUB
for i := uint32(0); i < K1; i++ {
<-us[i].DoneCh
}
// DEBUG
fmt.Println("pair_test: both servers have sent first DONE")
// END
// When all UpaxServers are ready, create K2 clients.--
// Each upax client creates K3 separate datums of different
// length (L1..L2) and content. Each client signals
// when done.
// XXX STUB
// Verify for each of the K2 clients ------------------
// that its data is present on the selected server. We
// do this by an Exists() call on uDir for the server's
// LFS/U for each item posted.
// XXX STUB
// After a reasonable deltaT, verify that both servers--
// have a copy of each and every datum.
// XXX STUB
_, _, _, _ = K2, M, LMin, LMax
}
"path"
"runtime"
"time"
)
var _ = fmt.Print
var _ = xo.NewIPOverlay
const (
MIN_LEN = 1024
MAX_LEN = 2048
Q = 64 // "too many open files" if 64
)
var (
ANY_END_POINT, _ = xt.NewTcpEndPoint("127.0.0.1:0")
)
// See cluster_test.go for a general description of these tests.
//
// This test involves nodes executing on a single machine, with accessor
// IP addresses 127.0.0.1:P, where P represents a system-assigned unique
// port number.
// Accept connections from peers until a message is received on stopCh.
// For each message received from a peer, calculate its SHA1 hash,
// send that as a reply, and close the connection. Send on stoppedCh
// when all replies have been sent.
func (s *XLSuite) nodeAsServer(c *C, node *Node, stopCh, stoppedCh chan bool) {
acceptor := node.acceptors[0]
go func() {
func (s *XLSuite) shouldCreateTcpEndPoint(c *C, addr string) *xt.TcpEndPoint {
ep, err := xt.NewTcpEndPoint(addr)
c.Assert(err, Equals, nil)
c.Assert(ep, Not(Equals), nil)
return ep
}
func NewEphServer() (ms *EphServer, err error) {
// Create an XLattice node with quasi-random parameters including
// low-quality keys and an endPoint in 127.0.0.1, localhost.
var (
ckPriv, skPriv *rsa.PrivateKey
rn *RegNode
ep *xt.TcpEndPoint
node *xn.Node
reg *Registry
server *RegServer
)
rng := xr.MakeSimpleRNG()
name := rng.NextFileName(16)
idBuf := make([]byte, xu.SHA1_BIN_LEN)
rng.NextBytes(idBuf)
lfs := "tmp/" + hex.EncodeToString(idBuf)
id, err := xi.New(nil)
if err == nil {
// XXX cheap keys, too weak for any serious use
ckPriv, err = rsa.GenerateKey(rand.Reader, 1024)
if err == nil {
skPriv, err = rsa.GenerateKey(rand.Reader, 1024)
}
}
if err == nil {
ep, err = xt.NewTcpEndPoint("127.0.0.1:0")
eps := []xt.EndPointI{ep}
if err == nil {
node, err = xn.New(name, id, lfs, ckPriv, skPriv, nil, eps, nil)
if err == nil {
err = node.OpenAcc() // so acceptors are now live
if err == nil {
rn, err = NewRegNode(node, ckPriv, skPriv)
if err == nil {
// DEBUG
if rn == nil {
fmt.Println("regNode is NIL!\n")
} else {
fmt.Printf("eph server listening on %s\n",
rn.GetAcceptor(0).String())
}
// END
// a registry with no clusters and no logger
opt := &RegOptions{
EndPoint: ep, // not used
Ephemeral: true,
GlobalEndPoint: node.GetEndPoint(0),
Lfs: lfs, // redundant (is in node's BaseNode)
Logger: nil,
K: DEFAULT_K,
M: DEFAULT_M,
}
reg, err = NewRegistry(nil, rn, opt)
if err == nil {
server, err = NewRegServer(reg, true, 1)
if err == nil {
ms = &EphServer{
acc: rn.GetAcceptor(0),
Server: server,
}
}
}
}
}
}
}
}
return
}
func setup(opt *reg.RegOptions) (rs *reg.RegServer, err error) {
// If LFS/.xlattice/reg.config exists, we load that. Otherwise we
// create a node. In either case we force the node to listen on
// the designated port
var (
e []xt.EndPointI
node *xn.Node
pathToConfigFile string
rn *reg.RegNode
ckPriv, skPriv *rsa.PrivateKey
)
logger := opt.Logger
verbose := opt.Verbose
greetings := fmt.Sprintf("xlReg v%s %s start run\n",
reg.VERSION, reg.VERSION_DATE)
if verbose {
fmt.Print(greetings)
}
logger.Print(greetings)
pathToConfigFile = path.Join(path.Join(opt.Lfs, ".xlattice"), "reg.config")
found, err := xf.PathExists(pathToConfigFile)
if err == nil {
if found {
logger.Printf("Loading existing reg config from %s\n",
pathToConfigFile)
// The registry node already exists. Parse it and we are done.
var data []byte
data, err = ioutil.ReadFile(pathToConfigFile)
if err == nil {
rn, _, err = reg.ParseRegNode(string(data))
}
} else {
logger.Println("No config file found, creating new registry.")
// We need to create a registry node from scratch.
nodeID, _ := xi.New(nil)
ep, err := xt.NewTcpEndPoint(opt.Address + ":" + opt.Port)
if err == nil {
e = []xt.EndPointI{ep}
ckPriv, err = rsa.GenerateKey(rand.Reader, 2048)
if err == nil {
skPriv, err = rsa.GenerateKey(rand.Reader, 2048)
}
if err == nil {
node, err = xn.New("xlReg", nodeID, opt.Lfs, ckPriv, skPriv,
nil, e, nil)
if err == nil {
node.OpenAcc() // XXX needs a complementary close
if err == nil {
// DEBUG
fmt.Printf("XLattice node successfully created\n")
fmt.Printf(" listening on %s\n", ep.String())
// END
rn, err = reg.NewRegNode(node, ckPriv, skPriv)
if err == nil {
// DEBUG
fmt.Printf("regNode successfully created\n")
// END
err = xf.MkdirsToFile(pathToConfigFile, 0700)
if err == nil {
err = ioutil.WriteFile(pathToConfigFile,
[]byte(rn.String()), 0400)
// DEBUG
} else {
fmt.Printf("error writing config file: %v\n",
err.Error())
}
// END --------------
// DEBUG
} else {
fmt.Printf("error creating regNode: %v\n",
err.Error())
// END
}
}
}
}
}
}
}
if err == nil {
var r *reg.Registry
r, err = reg.NewRegistry(nil, // nil = clusters so far
rn, opt) // regNode, options
if err == nil {
logger.Printf("Registry name: %s\n", rn.GetName())
logger.Printf(" ID: %s\n", rn.GetNodeID().String())
}
if err == nil {
var verbosity int
if opt.Verbose {
verbosity++
}
rs, err = reg.NewRegServer(r, opt.Testing, verbosity)
}
}
if err != nil {
logger.Printf("ERROR: %s\n", err.Error())
}
return
}
