package bgp import ( "encoding/binary" "fmt" "net" "strconv" ) // Validator for BGPUpdate func ValidateUpdateMsg(m *BGPUpdate, rfs map[RouteFamily]bool, doConfedCheck bool) (bool, error) { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCodeAttrList := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) eSubCodeMissing := uint8(BGP_ERROR_SUB_MISSING_WELL_KNOWN_ATTRIBUTE) if len(m.NLRI) > 0 || len(m.WithdrawnRoutes) > 0 { if _, ok := rfs[RF_IPv4_UC]; !ok { return false, NewMessageError(0, 0, nil, fmt.Sprintf("Address-family rf %d not avalible for session", RF_IPv4_UC)) } } seen := make(map[BGPAttrType]PathAttributeInterface) // check path attribute for _, a := range m.PathAttributes { // check duplication if _, ok := seen[a.GetType()]; !ok { seen[a.GetType()] = a } else { eMsg := "the path attribute apears twice. Type : " + strconv.Itoa(int(a.GetType())) return false, NewMessageError(eCode, eSubCodeAttrList, nil, eMsg) } //check specific path attribute ok, e := ValidateAttribute(a, rfs, doConfedCheck) if !ok { return false, e } } if len(m.NLRI) > 0 { // check the existence of well-known mandatory attributes exist := func(attrs []BGPAttrType) (bool, BGPAttrType) { for _, attr := range attrs { _, ok := seen[attr] if !ok { return false, attr } } return true, 0 } mandatory := []BGPAttrType{BGP_ATTR_TYPE_ORIGIN, BGP_ATTR_TYPE_AS_PATH, BGP_ATTR_TYPE_NEXT_HOP} if ok, t := exist(mandatory); !ok { eMsg := "well-known mandatory attributes are not present. type : " + strconv.Itoa(int(t)) data := []byte{byte(t)} return false, NewMessageError(eCode, eSubCodeMissing, data, eMsg) } } return true, nil } func ValidateAttribute(a PathAttributeInterface, rfs map[RouteFamily]bool, doConfedCheck bool) (bool, error) { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCodeBadOrigin := uint8(BGP_ERROR_SUB_INVALID_ORIGIN_ATTRIBUTE) eSubCodeBadNextHop := uint8(BGP_ERROR_SUB_INVALID_NEXT_HOP_ATTRIBUTE) eSubCodeUnknown := uint8(BGP_ERROR_SUB_UNRECOGNIZED_WELL_KNOWN_ATTRIBUTE) eSubCodeMalformedAspath := uint8(BGP_ERROR_SUB_MALFORMED_AS_PATH) checkPrefix := func(l []AddrPrefixInterface) error { for _, prefix := range l { rf := AfiSafiToRouteFamily(prefix.AFI(), prefix.SAFI()) if _, ok := rfs[rf]; !ok { return NewMessageError(0, 0, nil, fmt.Sprintf("Address-family %s not avalible for this session", rf)) } switch rf { case RF_FS_IPv4_UC, RF_FS_IPv6_UC, RF_FS_IPv4_VPN, RF_FS_IPv6_VPN, RF_FS_L2_VPN: t := BGPFlowSpecType(0) value := make([]FlowSpecComponentInterface, 0) switch rf { case RF_FS_IPv4_UC: value = prefix.(*FlowSpecIPv4Unicast).Value case RF_FS_IPv6_UC: value = prefix.(*FlowSpecIPv6Unicast).Value case RF_FS_IPv4_VPN: value = prefix.(*FlowSpecIPv4VPN).Value case RF_FS_IPv6_VPN: value = prefix.(*FlowSpecIPv6VPN).Value case RF_FS_L2_VPN: value = prefix.(*FlowSpecL2VPN).Value } for _, v := range value { if v.Type() <= t { return NewMessageError(0, 0, nil, fmt.Sprintf("%s nlri violate strict type ordering", rf)) } t = v.Type() } } } return nil } switch p := a.(type) { case *PathAttributeMpUnreachNLRI: rf := AfiSafiToRouteFamily(p.AFI, p.SAFI) if _, ok := rfs[rf]; !ok { return false, NewMessageError(0, 0, nil, fmt.Sprintf("Address-family rf %d not avalible for session", rf)) } if err := checkPrefix(p.Value); err != nil { return false, err } case *PathAttributeMpReachNLRI: rf := AfiSafiToRouteFamily(p.AFI, p.SAFI) if _, ok := rfs[rf]; !ok { return false, NewMessageError(0, 0, nil, fmt.Sprintf("Address-family rf %d not avalible for session", rf)) } if err := checkPrefix(p.Value); err != nil { return false, err } case *PathAttributeOrigin: v := uint8(p.Value[0]) if v != BGP_ORIGIN_ATTR_TYPE_IGP && v != BGP_ORIGIN_ATTR_TYPE_EGP && v != BGP_ORIGIN_ATTR_TYPE_INCOMPLETE { data, _ := a.Serialize() eMsg := "invalid origin attribute. value : " + strconv.Itoa(int(v)) return false, NewMessageError(eCode, eSubCodeBadOrigin, data, eMsg) } case *PathAttributeNextHop: isZero := func(ip net.IP) bool { res := ip[0] & 0xff return res == 0x00 } isClassDorE := func(ip net.IP) bool { res := ip[0] & 0xe0 return res == 0xe0 } //check IP address represents host address if p.Value.IsLoopback() || isZero(p.Value) || isClassDorE(p.Value) { eMsg := "invalid nexthop address" data, _ := a.Serialize() return false, NewMessageError(eCode, eSubCodeBadNextHop, data, eMsg) } case *PathAttributeAsPath: if doConfedCheck { for _, paramIf := range p.Value { var segType uint8 asParam, y := paramIf.(*As4PathParam) if y { segType = asParam.Type } else { segType = paramIf.(*AsPathParam).Type } if segType == BGP_ASPATH_ATTR_TYPE_CONFED_SET || segType == BGP_ASPATH_ATTR_TYPE_CONFED_SEQ { return false, NewMessageError(eCode, eSubCodeMalformedAspath, nil, fmt.Sprintf("segment type confederation(%d) found", segType)) } } } case *PathAttributeLargeCommunities: uniq := make([]*LargeCommunity, 0, len(p.Values)) for _, x := range p.Values { found := false for _, y := range uniq { if x.String() == y.String() { found = true break } } if !found { uniq = append(uniq, x) } } p.Values = uniq case *PathAttributeUnknown: if p.GetFlags()&BGP_ATTR_FLAG_OPTIONAL == 0 { eMsg := fmt.Sprintf("unrecognized well-known attribute %s", p.GetType()) data, _ := a.Serialize() return false, NewMessageError(eCode, eSubCodeUnknown, data, eMsg) } } return true, nil } // validator for PathAttribute func ValidateFlags(t BGPAttrType, flags BGPAttrFlag) (bool, string) { /* * RFC 4271 P.17 For well-known attributes, the Transitive bit MUST be set to 1. */ if flags&BGP_ATTR_FLAG_OPTIONAL == 0 && flags&BGP_ATTR_FLAG_TRANSITIVE == 0 { eMsg := fmt.Sprintf("well-known attribute %s must have transitive flag 1", t) return false, eMsg } /* * RFC 4271 P.17 For well-known attributes and for optional non-transitive attributes, * the Partial bit MUST be set to 0. */ if flags&BGP_ATTR_FLAG_OPTIONAL == 0 && flags&BGP_ATTR_FLAG_PARTIAL != 0 { eMsg := fmt.Sprintf("well-known attribute %s must have partial bit 0", t) return false, eMsg } if flags&BGP_ATTR_FLAG_OPTIONAL != 0 && flags&BGP_ATTR_FLAG_TRANSITIVE == 0 && flags&BGP_ATTR_FLAG_PARTIAL != 0 { eMsg := fmt.Sprintf("optional non-transitive attribute %s must have partial bit 0", t) return false, eMsg } // check flags are correct if f, ok := PathAttrFlags[t]; ok { if f != flags & ^BGP_ATTR_FLAG_EXTENDED_LENGTH & ^BGP_ATTR_FLAG_PARTIAL { eMsg := fmt.Sprintf("flags are invalid. attribute type: %s, expect: %s, actual: %s", t, f, flags) return false, eMsg } } return true, "" } func ValidateBGPMessage(m *BGPMessage) error { if m.Header.Len > BGP_MAX_MESSAGE_LENGTH { buf := make([]byte, 2) binary.BigEndian.PutUint16(buf, m.Header.Len) return NewMessageError(BGP_ERROR_MESSAGE_HEADER_ERROR, BGP_ERROR_SUB_BAD_MESSAGE_LENGTH, buf, "too long length") } return nil } func ValidateOpenMsg(m *BGPOpen, expectedAS uint32) error { if m.Version != 4 { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_VERSION_NUMBER, nil, fmt.Sprintf("upsuppored version %d", m.Version)) } as := uint32(m.MyAS) for _, p := range m.OptParams { paramCap, y := p.(*OptionParameterCapability) if !y { continue } for _, c := range paramCap.Capability { if c.Code() == BGP_CAP_FOUR_OCTET_AS_NUMBER { cap := c.(*CapFourOctetASNumber) as = cap.CapValue } } } if as != expectedAS { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_BAD_PEER_AS, nil, fmt.Sprintf("as number mismatch expected %d, received %d", expectedAS, as)) } if m.HoldTime < 3 && m.HoldTime != 0 { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNACCEPTABLE_HOLD_TIME, nil, fmt.Sprintf("unacceptable hold time %d", m.HoldTime)) } return nil }