package overlay import ( "bytes" "encoding/binary" "encoding/hex" "fmt" "hash/fnv" "net" "sync" "syscall" "strconv" log "github.com/Sirupsen/logrus" "github.com/docker/libnetwork/iptables" "github.com/docker/libnetwork/ns" "github.com/docker/libnetwork/types" "github.com/vishvananda/netlink" ) const ( mark = uint32(0xD0C4E3) timeout = 30 pktExpansion = 26 // SPI(4) + SeqN(4) + IV(8) + PadLength(1) + NextHeader(1) + ICV(8) ) const ( forward = iota + 1 reverse bidir ) type key struct { value []byte tag uint32 } func (k *key) String() string { if k != nil { return fmt.Sprintf("(key: %s, tag: 0x%x)", hex.EncodeToString(k.value)[0:5], k.tag) } return "" } type spi struct { forward int reverse int } func (s *spi) String() string { return fmt.Sprintf("SPI(FWD: 0x%x, REV: 0x%x)", uint32(s.forward), uint32(s.reverse)) } type encrMap struct { nodes map[string][]*spi sync.Mutex } func (e *encrMap) String() string { e.Lock() defer e.Unlock() b := new(bytes.Buffer) for k, v := range e.nodes { b.WriteString("\n") b.WriteString(k) b.WriteString(":") b.WriteString("[") for _, s := range v { b.WriteString(s.String()) b.WriteString(",") } b.WriteString("]") } return b.String() } func (d *driver) checkEncryption(nid string, rIP net.IP, vxlanID uint32, isLocal, add bool) error { log.Debugf("checkEncryption(%s, %v, %d, %t)", nid[0:7], rIP, vxlanID, isLocal) n := d.network(nid) if n == nil || !n.secure { return nil } if len(d.keys) == 0 { return types.ForbiddenErrorf("encryption key is not present") } lIP := net.ParseIP(d.bindAddress) aIP := net.ParseIP(d.advertiseAddress) nodes := map[string]net.IP{} switch { case isLocal: if err := d.peerDbNetworkWalk(nid, func(pKey *peerKey, pEntry *peerEntry) bool { if !aIP.Equal(pEntry.vtep) { nodes[pEntry.vtep.String()] = pEntry.vtep } return false }); err != nil { log.Warnf("Failed to retrieve list of participating nodes in overlay network %s: %v", nid[0:5], err) } default: if len(d.network(nid).endpoints) > 0 { nodes[rIP.String()] = rIP } } log.Debugf("List of nodes: %s", nodes) if add { for _, rIP := range nodes { if err := setupEncryption(lIP, aIP, rIP, vxlanID, d.secMap, d.keys); err != nil { log.Warnf("Failed to program network encryption between %s and %s: %v", lIP, rIP, err) } } } else { if len(nodes) == 0 { if err := removeEncryption(lIP, rIP, d.secMap); err != nil { log.Warnf("Failed to remove network encryption between %s and %s: %v", lIP, rIP, err) } } } return nil } func setupEncryption(localIP, advIP, remoteIP net.IP, vni uint32, em *encrMap, keys []*key) error { log.Debugf("Programming encryption for vxlan %d between %s and %s", vni, localIP, remoteIP) rIPs := remoteIP.String() indices := make([]*spi, 0, len(keys)) err := programMangle(vni, true) if err != nil { log.Warn(err) } for i, k := range keys { spis := &spi{buildSPI(advIP, remoteIP, k.tag), buildSPI(remoteIP, advIP, k.tag)} dir := reverse if i == 0 { dir = bidir } fSA, rSA, err := programSA(localIP, remoteIP, spis, k, dir, true) if err != nil { log.Warn(err) } indices = append(indices, spis) if i != 0 { continue } err = programSP(fSA, rSA, true) if err != nil { log.Warn(err) } } em.Lock() em.nodes[rIPs] = indices em.Unlock() return nil } func removeEncryption(localIP, remoteIP net.IP, em *encrMap) error { em.Lock() indices, ok := em.nodes[remoteIP.String()] em.Unlock() if !ok { return nil } for i, idxs := range indices { dir := reverse if i == 0 { dir = bidir } fSA, rSA, err := programSA(localIP, remoteIP, idxs, nil, dir, false) if err != nil { log.Warn(err) } if i != 0 { continue } err = programSP(fSA, rSA, false) if err != nil { log.Warn(err) } } return nil } func programMangle(vni uint32, add bool) (err error) { var ( p = strconv.FormatUint(uint64(vxlanPort), 10) c = fmt.Sprintf("0>>22&0x3C@12&0xFFFFFF00=%d", int(vni)<<8) m = strconv.FormatUint(uint64(mark), 10) chain = "OUTPUT" rule = []string{"-p", "udp", "--dport", p, "-m", "u32", "--u32", c, "-j", "MARK", "--set-mark", m} a = "-A" action = "install" ) if add == iptables.Exists(iptables.Mangle, chain, rule...) { return } if !add { a = "-D" action = "remove" } if err = iptables.RawCombinedOutput(append([]string{"-t", string(iptables.Mangle), a, chain}, rule...)...); err != nil { log.Warnf("could not %s mangle rule: %v", action, err) } return } func programSA(localIP, remoteIP net.IP, spi *spi, k *key, dir int, add bool) (fSA *netlink.XfrmState, rSA *netlink.XfrmState, err error) { var ( action = "Removing" xfrmProgram = ns.NlHandle().XfrmStateDel ) if add { action = "Adding" xfrmProgram = ns.NlHandle().XfrmStateAdd } if dir&reverse > 0 { rSA = &netlink.XfrmState{ Src: remoteIP, Dst: localIP, Proto: netlink.XFRM_PROTO_ESP, Spi: spi.reverse, Mode: netlink.XFRM_MODE_TRANSPORT, } if add { rSA.Aead = buildAeadAlgo(k, spi.reverse) } exists, err := saExists(rSA) if err != nil { exists = !add } if add != exists { log.Debugf("%s: rSA{%s}", action, rSA) if err := xfrmProgram(rSA); err != nil { log.Warnf("Failed %s rSA{%s}: %v", action, rSA, err) } } } if dir&forward > 0 { fSA = &netlink.XfrmState{ Src: localIP, Dst: remoteIP, Proto: netlink.XFRM_PROTO_ESP, Spi: spi.forward, Mode: netlink.XFRM_MODE_TRANSPORT, } if add { fSA.Aead = buildAeadAlgo(k, spi.forward) } exists, err := saExists(fSA) if err != nil { exists = !add } if add != exists { log.Debugf("%s fSA{%s}", action, fSA) if err := xfrmProgram(fSA); err != nil { log.Warnf("Failed %s fSA{%s}: %v.", action, fSA, err) } } } return } func programSP(fSA *netlink.XfrmState, rSA *netlink.XfrmState, add bool) error { action := "Removing" xfrmProgram := ns.NlHandle().XfrmPolicyDel if add { action = "Adding" xfrmProgram = ns.NlHandle().XfrmPolicyAdd } fullMask := net.CIDRMask(8*len(fSA.Src), 8*len(fSA.Src)) fPol := &netlink.XfrmPolicy{ Src: &net.IPNet{IP: fSA.Src, Mask: fullMask}, Dst: &net.IPNet{IP: fSA.Dst, Mask: fullMask}, Dir: netlink.XFRM_DIR_OUT, Proto: 17, DstPort: 4789, Mark: &netlink.XfrmMark{ Value: mark, }, Tmpls: []netlink.XfrmPolicyTmpl{ { Src: fSA.Src, Dst: fSA.Dst, Proto: netlink.XFRM_PROTO_ESP, Mode: netlink.XFRM_MODE_TRANSPORT, Spi: fSA.Spi, }, }, } exists, err := spExists(fPol) if err != nil { exists = !add } if add != exists { log.Debugf("%s fSP{%s}", action, fPol) if err := xfrmProgram(fPol); err != nil { log.Warnf("%s fSP{%s}: %v", action, fPol, err) } } return nil } func saExists(sa *netlink.XfrmState) (bool, error) { _, err := ns.NlHandle().XfrmStateGet(sa) switch err { case nil: return true, nil case syscall.ESRCH: return false, nil default: err = fmt.Errorf("Error while checking for SA existence: %v", err) log.Warn(err) return false, err } } func spExists(sp *netlink.XfrmPolicy) (bool, error) { _, err := ns.NlHandle().XfrmPolicyGet(sp) switch err { case nil: return true, nil case syscall.ENOENT: return false, nil default: err = fmt.Errorf("Error while checking for SP existence: %v", err) log.Warn(err) return false, err } } func buildSPI(src, dst net.IP, st uint32) int { b := make([]byte, 4) binary.BigEndian.PutUint32(b, st) h := fnv.New32a() h.Write(src) h.Write(b) h.Write(dst) return int(binary.BigEndian.Uint32(h.Sum(nil))) } func buildAeadAlgo(k *key, s int) *netlink.XfrmStateAlgo { salt := make([]byte, 4) binary.BigEndian.PutUint32(salt, uint32(s)) return &netlink.XfrmStateAlgo{ Name: "rfc4106(gcm(aes))", Key: append(k.value, salt...), ICVLen: 64, } } func (d *driver) secMapWalk(f func(string, []*spi) ([]*spi, bool)) error { d.secMap.Lock() for node, indices := range d.secMap.nodes { idxs, stop := f(node, indices) if idxs != nil { d.secMap.nodes[node] = idxs } if stop { break } } d.secMap.Unlock() return nil } func (d *driver) setKeys(keys []*key) error { if d.keys != nil { return types.ForbiddenErrorf("initial keys are already present") } d.keys = keys log.Debugf("Initial encryption keys: %v", d.keys) return nil } // updateKeys allows to add a new key and/or change the primary key and/or prune an existing key // The primary key is the key used in transmission and will go in first position in the list. func (d *driver) updateKeys(newKey, primary, pruneKey *key) error { log.Debugf("Updating Keys. New: %v, Primary: %v, Pruned: %v", newKey, primary, pruneKey) log.Debugf("Current: %v", d.keys) var ( newIdx = -1 priIdx = -1 delIdx = -1 lIP = net.ParseIP(d.bindAddress) ) d.Lock() // add new if newKey != nil { d.keys = append(d.keys, newKey) newIdx += len(d.keys) } for i, k := range d.keys { if primary != nil && k.tag == primary.tag { priIdx = i } if pruneKey != nil && k.tag == pruneKey.tag { delIdx = i } } d.Unlock() if (newKey != nil && newIdx == -1) || (primary != nil && priIdx == -1) || (pruneKey != nil && delIdx == -1) { err := types.BadRequestErrorf("cannot find proper key indices while processing key update:"+ "(newIdx,priIdx,delIdx):(%d, %d, %d)", newIdx, priIdx, delIdx) log.Warn(err) return err } d.secMapWalk(func(rIPs string, spis []*spi) ([]*spi, bool) { rIP := net.ParseIP(rIPs) return updateNodeKey(lIP, rIP, spis, d.keys, newIdx, priIdx, delIdx), false }) d.Lock() // swap primary if priIdx != -1 { swp := d.keys[0] d.keys[0] = d.keys[priIdx] d.keys[priIdx] = swp } // prune if delIdx != -1 { if delIdx == 0 { delIdx = priIdx } d.keys = append(d.keys[:delIdx], d.keys[delIdx+1:]...) } d.Unlock() log.Debugf("Updated: %v", d.keys) return nil } /******************************************************** * Steady state: rSA0, rSA1, rSA2, fSA1, fSP1 * Rotation --> -rSA0, +rSA3, +fSA2, +fSP2/-fSP1, -fSA1 * Steady state: rSA1, rSA2, rSA3, fSA2, fSP2 *********************************************************/ // Spis and keys are sorted in such away the one in position 0 is the primary func updateNodeKey(lIP, rIP net.IP, idxs []*spi, curKeys []*key, newIdx, priIdx, delIdx int) []*spi { log.Debugf("Updating keys for node: %s (%d,%d,%d)", rIP, newIdx, priIdx, delIdx) spis := idxs log.Debugf("Current: %v", spis) // add new if newIdx != -1 { spis = append(spis, &spi{ forward: buildSPI(lIP, rIP, curKeys[newIdx].tag), reverse: buildSPI(rIP, lIP, curKeys[newIdx].tag), }) } if delIdx != -1 { // -rSA0 programSA(lIP, rIP, spis[delIdx], nil, reverse, false) } if newIdx > -1 { // +RSA2 programSA(lIP, rIP, spis[newIdx], curKeys[newIdx], reverse, true) } if priIdx > 0 { // +fSA2 fSA2, _, _ := programSA(lIP, rIP, spis[priIdx], curKeys[priIdx], forward, true) // +fSP2, -fSP1 fullMask := net.CIDRMask(8*len(fSA2.Src), 8*len(fSA2.Src)) fSP1 := &netlink.XfrmPolicy{ Src: &net.IPNet{IP: fSA2.Src, Mask: fullMask}, Dst: &net.IPNet{IP: fSA2.Dst, Mask: fullMask}, Dir: netlink.XFRM_DIR_OUT, Proto: 17, DstPort: 4789, Mark: &netlink.XfrmMark{ Value: mark, }, Tmpls: []netlink.XfrmPolicyTmpl{ { Src: fSA2.Src, Dst: fSA2.Dst, Proto: netlink.XFRM_PROTO_ESP, Mode: netlink.XFRM_MODE_TRANSPORT, Spi: fSA2.Spi, }, }, } log.Debugf("Updating fSP{%s}", fSP1) if err := ns.NlHandle().XfrmPolicyUpdate(fSP1); err != nil { log.Warnf("Failed to update fSP{%s}: %v", fSP1, err) } // -fSA1 programSA(lIP, rIP, spis[0], nil, forward, false) } // swap if priIdx > 0 { swp := spis[0] spis[0] = spis[priIdx] spis[priIdx] = swp } // prune if delIdx != -1 { if delIdx == 0 { delIdx = priIdx } spis = append(spis[:delIdx], spis[delIdx+1:]...) } log.Debugf("Updated: %v", spis) return spis } func (n *network) maxMTU() int { mtu := 1500 if n.mtu != 0 { mtu = n.mtu } mtu -= vxlanEncap if n.secure { // In case of encryption account for the // esp packet espansion and padding mtu -= pktExpansion mtu -= (mtu % 4) } return mtu }