// Copyright (C) 2014 Nippon Telegraph and Telephone Corporation. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or // implied. // See the License for the specific language governing permissions and // limitations under the License. package bgp import ( "bytes" "encoding/base64" "encoding/binary" "encoding/json" "errors" "fmt" "math" "net" "reflect" "regexp" "sort" "strconv" "strings" "sync" ) type MarshallingOption struct { AddPath map[RouteFamily]BGPAddPathMode Attributes map[BGPAttrType]bool } func IsAddPathEnabled(decode bool, f RouteFamily, options []*MarshallingOption) bool { for _, opt := range options { if opt == nil { continue } if o := opt.AddPath; o != nil { if decode && o[f]&BGP_ADD_PATH_RECEIVE > 0 { return true } else if !decode && o[f]&BGP_ADD_PATH_SEND > 0 { return true } } } return false } func IsAttributePresent(attr BGPAttrType, options []*MarshallingOption) bool { for _, opt := range options { if opt == nil { continue } if o := opt.Attributes; o != nil { _, ok := o[attr] return ok } } return false } const ( AFI_IP = 1 AFI_IP6 = 2 AFI_L2VPN = 25 AFI_LS = 16388 AFI_OPAQUE = 16397 ) const ( SAFI_UNICAST = 1 SAFI_MULTICAST = 2 SAFI_MPLS_LABEL = 4 SAFI_ENCAPSULATION = 7 SAFI_VPLS = 65 SAFI_EVPN = 70 SAFI_LS = 71 SAFI_SRPOLICY = 73 SAFI_MPLS_VPN = 128 SAFI_MPLS_VPN_MULTICAST = 129 SAFI_ROUTE_TARGET_CONSTRAINTS = 132 SAFI_FLOW_SPEC_UNICAST = 133 SAFI_FLOW_SPEC_VPN = 134 SAFI_KEY_VALUE = 241 ) const ( BGP_ORIGIN_ATTR_TYPE_IGP uint8 = 0 BGP_ORIGIN_ATTR_TYPE_EGP uint8 = 1 BGP_ORIGIN_ATTR_TYPE_INCOMPLETE uint8 = 2 ) const ( BGP_ASPATH_ATTR_TYPE_SET = 1 BGP_ASPATH_ATTR_TYPE_SEQ = 2 BGP_ASPATH_ATTR_TYPE_CONFED_SEQ = 3 BGP_ASPATH_ATTR_TYPE_CONFED_SET = 4 ) // RFC7153 5.1. Registries for the "Type" Field // RANGE REGISTRATION PROCEDURES // 0x00-0x3F Transitive First Come First Served // 0x40-0x7F Non-Transitive First Come First Served // 0x80-0x8F Transitive Experimental Use // 0x90-0xBF Transitive Standards Action // 0xC0-0xCF Non-Transitive Experimental Use // 0xD0-0xFF Non-Transitive Standards Action type ExtendedCommunityAttrType uint8 const ( EC_TYPE_TRANSITIVE_TWO_OCTET_AS_SPECIFIC ExtendedCommunityAttrType = 0x00 EC_TYPE_TRANSITIVE_IP6_SPECIFIC ExtendedCommunityAttrType = 0x00 // RFC5701 EC_TYPE_TRANSITIVE_IP4_SPECIFIC ExtendedCommunityAttrType = 0x01 EC_TYPE_TRANSITIVE_FOUR_OCTET_AS_SPECIFIC ExtendedCommunityAttrType = 0x02 EC_TYPE_TRANSITIVE_OPAQUE ExtendedCommunityAttrType = 0x03 EC_TYPE_TRANSITIVE_QOS_MARKING ExtendedCommunityAttrType = 0x04 EC_TYPE_COS_CAPABILITY ExtendedCommunityAttrType = 0x05 EC_TYPE_EVPN ExtendedCommunityAttrType = 0x06 EC_TYPE_FLOWSPEC_REDIRECT_MIRROR ExtendedCommunityAttrType = 0x08 EC_TYPE_NON_TRANSITIVE_TWO_OCTET_AS_SPECIFIC ExtendedCommunityAttrType = 0x40 EC_TYPE_NON_TRANSITIVE_IP6_SPECIFIC ExtendedCommunityAttrType = 0x40 // RFC5701 EC_TYPE_NON_TRANSITIVE_IP4_SPECIFIC ExtendedCommunityAttrType = 0x41 EC_TYPE_NON_TRANSITIVE_FOUR_OCTET_AS_SPECIFIC ExtendedCommunityAttrType = 0x42 EC_TYPE_NON_TRANSITIVE_OPAQUE ExtendedCommunityAttrType = 0x43 EC_TYPE_NON_TRANSITIVE_QOS_MARKING ExtendedCommunityAttrType = 0x44 EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL ExtendedCommunityAttrType = 0x80 EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL2 ExtendedCommunityAttrType = 0x81 // RFC7674 EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL3 ExtendedCommunityAttrType = 0x82 // RFC7674 ) // RFC7153 5.2. Registries for the "Sub-Type" Field // RANGE REGISTRATION PROCEDURES // 0x00-0xBF First Come First Served // 0xC0-0xFF IETF Review type ExtendedCommunityAttrSubType uint8 const ( EC_SUBTYPE_ROUTE_TARGET ExtendedCommunityAttrSubType = 0x02 // EC_TYPE: 0x00, 0x01, 0x02 EC_SUBTYPE_ROUTE_ORIGIN ExtendedCommunityAttrSubType = 0x03 // EC_TYPE: 0x00, 0x01, 0x02 EC_SUBTYPE_LINK_BANDWIDTH ExtendedCommunityAttrSubType = 0x04 // EC_TYPE: 0x40 EC_SUBTYPE_GENERIC ExtendedCommunityAttrSubType = 0x04 // EC_TYPE: 0x02, 0x42 EC_SUBTYPE_OSPF_DOMAIN_ID ExtendedCommunityAttrSubType = 0x05 // EC_TYPE: 0x00, 0x01, 0x02 EC_SUBTYPE_OSPF_ROUTE_ID ExtendedCommunityAttrSubType = 0x07 // EC_TYPE: 0x01 EC_SUBTYPE_BGP_DATA_COLLECTION ExtendedCommunityAttrSubType = 0x08 // EC_TYPE: 0x00, 0x02 EC_SUBTYPE_SOURCE_AS ExtendedCommunityAttrSubType = 0x09 // EC_TYPE: 0x00, 0x02 EC_SUBTYPE_L2VPN_ID ExtendedCommunityAttrSubType = 0x0A // EC_TYPE: 0x00, 0x01 EC_SUBTYPE_VRF_ROUTE_IMPORT ExtendedCommunityAttrSubType = 0x0B // EC_TYPE: 0x01 EC_SUBTYPE_CISCO_VPN_DISTINGUISHER ExtendedCommunityAttrSubType = 0x10 // EC_TYPE: 0x00, 0x01, 0x02 EC_SUBTYPE_OSPF_ROUTE_TYPE ExtendedCommunityAttrSubType = 0x06 // EC_TYPE: 0x03 EC_SUBTYPE_COLOR ExtendedCommunityAttrSubType = 0x0B // EC_TYPE: 0x03 EC_SUBTYPE_ENCAPSULATION ExtendedCommunityAttrSubType = 0x0C // EC_TYPE: 0x03 EC_SUBTYPE_DEFAULT_GATEWAY ExtendedCommunityAttrSubType = 0x0D // EC_TYPE: 0x03 EC_SUBTYPE_ORIGIN_VALIDATION ExtendedCommunityAttrSubType = 0x00 // EC_TYPE: 0x43 EC_SUBTYPE_FLOWSPEC_TRAFFIC_RATE ExtendedCommunityAttrSubType = 0x06 // EC_TYPE: 0x80 EC_SUBTYPE_FLOWSPEC_TRAFFIC_ACTION ExtendedCommunityAttrSubType = 0x07 // EC_TYPE: 0x80 EC_SUBTYPE_FLOWSPEC_REDIRECT ExtendedCommunityAttrSubType = 0x08 // EC_TYPE: 0x80 EC_SUBTYPE_FLOWSPEC_TRAFFIC_REMARK ExtendedCommunityAttrSubType = 0x09 // EC_TYPE: 0x80 EC_SUBTYPE_L2_INFO ExtendedCommunityAttrSubType = 0x0A // EC_TYPE: 0x80 EC_SUBTYPE_FLOWSPEC_REDIRECT_IP6 ExtendedCommunityAttrSubType = 0x0B // EC_TYPE: 0x80 EC_SUBTYPE_MAC_MOBILITY ExtendedCommunityAttrSubType = 0x00 // EC_TYPE: 0x06 EC_SUBTYPE_ESI_LABEL ExtendedCommunityAttrSubType = 0x01 // EC_TYPE: 0x06 EC_SUBTYPE_ES_IMPORT ExtendedCommunityAttrSubType = 0x02 // EC_TYPE: 0x06 EC_SUBTYPE_ROUTER_MAC ExtendedCommunityAttrSubType = 0x03 // EC_TYPE: 0x06 EC_SUBTYPE_UUID_BASED_RT ExtendedCommunityAttrSubType = 0x11 ) type TunnelType uint16 const ( TUNNEL_TYPE_L2TP3 TunnelType = 1 TUNNEL_TYPE_GRE TunnelType = 2 TUNNEL_TYPE_IP_IN_IP TunnelType = 7 TUNNEL_TYPE_VXLAN TunnelType = 8 TUNNEL_TYPE_NVGRE TunnelType = 9 TUNNEL_TYPE_MPLS TunnelType = 10 TUNNEL_TYPE_MPLS_IN_GRE TunnelType = 11 TUNNEL_TYPE_VXLAN_GRE TunnelType = 12 TUNNEL_TYPE_MPLS_IN_UDP TunnelType = 13 TUNNEL_TYPE_SR_POLICY TunnelType = 15 TUNNEL_TYPE_GENEVE TunnelType = 19 TUNNEL_TYPE_WIREGUARD TunnelType = 51820 ) func (p TunnelType) String() string { switch p { case TUNNEL_TYPE_L2TP3: return "l2tp3" case TUNNEL_TYPE_GRE: return "gre" case TUNNEL_TYPE_IP_IN_IP: return "ip-in-ip" case TUNNEL_TYPE_VXLAN: return "vxlan" case TUNNEL_TYPE_NVGRE: return "nvgre" case TUNNEL_TYPE_MPLS: return "mpls" case TUNNEL_TYPE_MPLS_IN_GRE: return "mpls-in-gre" case TUNNEL_TYPE_VXLAN_GRE: return "vxlan-gre" case TUNNEL_TYPE_MPLS_IN_UDP: return "mpls-in-udp" case TUNNEL_TYPE_SR_POLICY: return "sr-policy" case TUNNEL_TYPE_GENEVE: return "geneve" case TUNNEL_TYPE_WIREGUARD: return "wireguard" default: return fmt.Sprintf("TunnelType(%d)", uint8(p)) } } type PmsiTunnelType uint8 const ( PMSI_TUNNEL_TYPE_NO_TUNNEL PmsiTunnelType = 0 PMSI_TUNNEL_TYPE_RSVP_TE_P2MP PmsiTunnelType = 1 PMSI_TUNNEL_TYPE_MLDP_P2MP PmsiTunnelType = 2 PMSI_TUNNEL_TYPE_PIM_SSM_TREE PmsiTunnelType = 3 PMSI_TUNNEL_TYPE_PIM_SM_TREE PmsiTunnelType = 4 PMSI_TUNNEL_TYPE_BIDIR_PIM_TREE PmsiTunnelType = 5 PMSI_TUNNEL_TYPE_INGRESS_REPL PmsiTunnelType = 6 PMSI_TUNNEL_TYPE_MLDP_MP2MP PmsiTunnelType = 7 ) func (p PmsiTunnelType) String() string { switch p { case PMSI_TUNNEL_TYPE_NO_TUNNEL: return "no-tunnel" case PMSI_TUNNEL_TYPE_RSVP_TE_P2MP: return "rsvp-te-p2mp" case PMSI_TUNNEL_TYPE_MLDP_P2MP: return "mldp-p2mp" case PMSI_TUNNEL_TYPE_PIM_SSM_TREE: return "pim-ssm-tree" case PMSI_TUNNEL_TYPE_PIM_SM_TREE: return "pim-sm-tree" case PMSI_TUNNEL_TYPE_BIDIR_PIM_TREE: return "bidir-pim-tree" case PMSI_TUNNEL_TYPE_INGRESS_REPL: return "ingress-repl" case PMSI_TUNNEL_TYPE_MLDP_MP2MP: return "mldp-mp2mp" default: return fmt.Sprintf("PmsiTunnelType(%d)", uint8(p)) } } type EncapSubTLVType uint8 const ( ENCAP_SUBTLV_TYPE_ENCAPSULATION EncapSubTLVType = 1 ENCAP_SUBTLV_TYPE_PROTOCOL EncapSubTLVType = 2 ENCAP_SUBTLV_TYPE_COLOR EncapSubTLVType = 4 ENCAP_SUBTLV_TYPE_EGRESS_ENDPOINT EncapSubTLVType = 6 ENCAP_SUBTLV_TYPE_UDP_DEST_PORT EncapSubTLVType = 8 ENCAP_SUBTLV_TYPE_SRPREFERENCE EncapSubTLVType = 12 ENCAP_SUBTLV_TYPE_SRBINDING_SID EncapSubTLVType = 13 ENCAP_SUBTLV_TYPE_SRENLP EncapSubTLVType = 14 ENCAP_SUBTLV_TYPE_SRPRIORITY EncapSubTLVType = 15 ENCAP_SUBTLV_TYPE_SRSEGMENT_LIST EncapSubTLVType = 128 ENCAP_SUBTLV_TYPE_SRCANDIDATE_PATH_NAME EncapSubTLVType = 129 ) const ( _ = iota BGP_MSG_OPEN BGP_MSG_UPDATE BGP_MSG_NOTIFICATION BGP_MSG_KEEPALIVE BGP_MSG_ROUTE_REFRESH ) const ( BGP_OPT_CAPABILITY = 2 ) type BGPCapabilityCode uint8 const ( BGP_CAP_MULTIPROTOCOL BGPCapabilityCode = 1 BGP_CAP_ROUTE_REFRESH BGPCapabilityCode = 2 BGP_CAP_CARRYING_LABEL_INFO BGPCapabilityCode = 4 BGP_CAP_EXTENDED_NEXTHOP BGPCapabilityCode = 5 BGP_CAP_GRACEFUL_RESTART BGPCapabilityCode = 64 BGP_CAP_FOUR_OCTET_AS_NUMBER BGPCapabilityCode = 65 BGP_CAP_ADD_PATH BGPCapabilityCode = 69 BGP_CAP_ENHANCED_ROUTE_REFRESH BGPCapabilityCode = 70 BGP_CAP_LONG_LIVED_GRACEFUL_RESTART BGPCapabilityCode = 71 BGP_CAP_FQDN BGPCapabilityCode = 73 BGP_CAP_ROUTE_REFRESH_CISCO BGPCapabilityCode = 128 ) var CapNameMap = map[BGPCapabilityCode]string{ BGP_CAP_MULTIPROTOCOL: "multiprotocol", BGP_CAP_ROUTE_REFRESH: "route-refresh", BGP_CAP_CARRYING_LABEL_INFO: "carrying-label-info", BGP_CAP_GRACEFUL_RESTART: "graceful-restart", BGP_CAP_EXTENDED_NEXTHOP: "extended-nexthop", BGP_CAP_FOUR_OCTET_AS_NUMBER: "4-octet-as", BGP_CAP_ADD_PATH: "add-path", BGP_CAP_ENHANCED_ROUTE_REFRESH: "enhanced-route-refresh", BGP_CAP_ROUTE_REFRESH_CISCO: "cisco-route-refresh", BGP_CAP_LONG_LIVED_GRACEFUL_RESTART: "long-lived-graceful-restart", BGP_CAP_FQDN: "fqdn", } func (c BGPCapabilityCode) String() string { if n, y := CapNameMap[c]; y { return n } return fmt.Sprintf("UnknownCapability(%d)", c) } var ( // Used parsing RouteDistinguisher _regexpRouteDistinguisher = regexp.MustCompile(`^((\d+)\.(\d+)\.(\d+)\.(\d+)|((\d+)\.)?(\d+)|([\w]+:[\w:]*:[\w]+)):(\d+)$`) // Used for operator and value for the FlowSpec numeric type // Example: // re.FindStringSubmatch("&==80") // >>> ["&==80" "&" "==" "80"] _regexpFlowSpecNumericType = regexp.MustCompile(`(&?)(==|=|>|>=|<|<=|!|!=|=!)?(\d+|-\d|true|false)`) // - "=!" is used in the old style format of "tcp-flags" and "fragment". // - The value field should be one of the followings: // * Decimal value (e.g., 80) // * Combination of the small letters, decimals, "-" and "+" // (e.g., tcp, ipv4, is-fragment+first-fragment) // * Capital letters (e.g., SA) _regexpFlowSpecOperator = regexp.MustCompile(`&|=|>|<|!|[\w\-+]+`) _regexpFlowSpecOperatorValue = regexp.MustCompile(`[\w\-+]+`) // Note: "(-*)" and "(.*)" catch the invalid flags // Example: In this case, "Z" is unsupported flag type. // re.FindStringSubmatch("&==-SZU") // >>> ["&==-SZU" "&" "==" "-" "S" "ZU"] _regexpFlowSpecTCPFlag = regexp.MustCompile("(&?)(==|=|!|!=|=!)?(-*)([FSRPAUCE]+)(.*)") // Note: "(.*)" catches the invalid flags // re.FindStringSubmatch("&!=+first-fragment+last-fragment+invalid-fragment") // >>> ["&!=+first-fragment+last-fragment+invalid-fragment" "&" "!=" "+first-fragment+last-fragment" "+last-fragment" "+" "last" "+invalid-fragment"] _regexpFlowSpecFragment = regexp.MustCompile(`(&?)(==|=|!|!=|=!)?(((\+)?(dont|is|first|last|not-a)-fragment)+)(.*)`) // re.FindStringSubmatch("192.168.0.0/24") // >>> ["192.168.0.0/24" "192.168.0.0" "/24" "24"] // re.FindStringSubmatch("192.168.0.1") // >>> ["192.168.0.1" "192.168.0.1" "" ""] _regexpFindIPv4Prefix = regexp.MustCompile(`^([\d.]+)(/(\d{1,2}))?`) // re.FindStringSubmatch("2001:dB8::/64") // >>> ["2001:dB8::/64" "2001:dB8::" "/64" "64" "" ""] // re.FindStringSubmatch("2001:dB8::/64/8") // >>> ["2001:dB8::/64/8" "2001:dB8::" "/64" "64" "/8" "8"] // re.FindStringSubmatch("2001:dB8::1") // >>> ["2001:dB8::1" "2001:dB8::1" "" "" "" ""] _regexpFindIPv6Prefix = regexp.MustCompile(`^([a-fA-F\d:.]+)(/(\d{1,3}))?(/(\d{1,3}))?`) ) type ParameterCapabilityInterface interface { DecodeFromBytes([]byte) error Serialize() ([]byte, error) Len() int Code() BGPCapabilityCode } type DefaultParameterCapability struct { CapCode BGPCapabilityCode `json:"code"` CapLen uint8 `json:"-"` CapValue []byte `json:"value,omitempty"` } func (c *DefaultParameterCapability) Code() BGPCapabilityCode { return c.CapCode } func (c *DefaultParameterCapability) DecodeFromBytes(data []byte) error { c.CapCode = BGPCapabilityCode(data[0]) c.CapLen = data[1] if len(data) < 2+int(c.CapLen) { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "Not all OptionParameterCapability bytes available") } if c.CapLen > 0 { c.CapValue = data[2 : 2+c.CapLen] } return nil } func (c *DefaultParameterCapability) Serialize() ([]byte, error) { c.CapLen = uint8(len(c.CapValue)) buf := make([]byte, 2+len(c.CapValue)) buf[0] = uint8(c.CapCode) buf[1] = c.CapLen copy(buf[2:], c.CapValue) return buf, nil } func (c *DefaultParameterCapability) Len() int { return int(c.CapLen + 2) } type CapMultiProtocol struct { DefaultParameterCapability CapValue RouteFamily } func (c *CapMultiProtocol) DecodeFromBytes(data []byte) error { c.DefaultParameterCapability.DecodeFromBytes(data) data = data[2:] if len(data) < 4 { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "Not all CapabilityMultiProtocol bytes available") } c.CapValue = AfiSafiToRouteFamily(binary.BigEndian.Uint16(data[0:2]), data[3]) return nil } func (c *CapMultiProtocol) Serialize() ([]byte, error) { buf := make([]byte, 4) afi, safi := RouteFamilyToAfiSafi(c.CapValue) binary.BigEndian.PutUint16(buf[0:], afi) buf[3] = safi c.DefaultParameterCapability.CapValue = buf return c.DefaultParameterCapability.Serialize() } func (c *CapMultiProtocol) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Code BGPCapabilityCode `json:"code"` Value RouteFamily `json:"value"` }{ Code: c.Code(), Value: c.CapValue, }) } func NewCapMultiProtocol(rf RouteFamily) *CapMultiProtocol { return &CapMultiProtocol{ DefaultParameterCapability{ CapCode: BGP_CAP_MULTIPROTOCOL, }, rf, } } type CapRouteRefresh struct { DefaultParameterCapability } func NewCapRouteRefresh() *CapRouteRefresh { return &CapRouteRefresh{ DefaultParameterCapability{ CapCode: BGP_CAP_ROUTE_REFRESH, }, } } type CapCarryingLabelInfo struct { DefaultParameterCapability } func NewCapCarryingLabelInfo() *CapCarryingLabelInfo { return &CapCarryingLabelInfo{ DefaultParameterCapability{ CapCode: BGP_CAP_CARRYING_LABEL_INFO, }, } } type CapExtendedNexthopTuple struct { NLRIAFI uint16 NLRISAFI uint16 NexthopAFI uint16 } func (c *CapExtendedNexthopTuple) MarshalJSON() ([]byte, error) { return json.Marshal(struct { NLRIAddressFamily RouteFamily `json:"nlri_address_family"` NexthopAddressFamily uint16 `json:"nexthop_address_family"` }{ NLRIAddressFamily: AfiSafiToRouteFamily(c.NLRIAFI, uint8(c.NLRISAFI)), NexthopAddressFamily: c.NexthopAFI, }) } func NewCapExtendedNexthopTuple(af RouteFamily, nexthop uint16) *CapExtendedNexthopTuple { afi, safi := RouteFamilyToAfiSafi(af) return &CapExtendedNexthopTuple{ NLRIAFI: afi, NLRISAFI: uint16(safi), NexthopAFI: nexthop, } } type CapExtendedNexthop struct { DefaultParameterCapability Tuples []*CapExtendedNexthopTuple } func (c *CapExtendedNexthop) DecodeFromBytes(data []byte) error { c.DefaultParameterCapability.DecodeFromBytes(data) data = data[2:] capLen := int(c.CapLen) if capLen%6 != 0 || capLen < 6 || len(data) < capLen { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "Not all CapabilityExtendedNexthop bytes available") } c.Tuples = []*CapExtendedNexthopTuple{} for capLen >= 6 { t := &CapExtendedNexthopTuple{ binary.BigEndian.Uint16(data[0:2]), binary.BigEndian.Uint16(data[2:4]), binary.BigEndian.Uint16(data[4:6]), } c.Tuples = append(c.Tuples, t) data = data[6:] capLen -= 6 } return nil } func (c *CapExtendedNexthop) Serialize() ([]byte, error) { buf := make([]byte, len(c.Tuples)*6) for i, t := range c.Tuples { binary.BigEndian.PutUint16(buf[i*6:i*6+2], t.NLRIAFI) binary.BigEndian.PutUint16(buf[i*6+2:i*6+4], t.NLRISAFI) binary.BigEndian.PutUint16(buf[i*6+4:i*6+6], t.NexthopAFI) } c.DefaultParameterCapability.CapValue = buf return c.DefaultParameterCapability.Serialize() } func (c *CapExtendedNexthop) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Code BGPCapabilityCode `json:"code"` Tuples []*CapExtendedNexthopTuple `json:"tuples"` }{ Code: c.Code(), Tuples: c.Tuples, }) } func NewCapExtendedNexthop(tuples []*CapExtendedNexthopTuple) *CapExtendedNexthop { return &CapExtendedNexthop{ DefaultParameterCapability{ CapCode: BGP_CAP_EXTENDED_NEXTHOP, }, tuples, } } type CapGracefulRestartTuple struct { AFI uint16 SAFI uint8 Flags uint8 } func (c *CapGracefulRestartTuple) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RouteFamily RouteFamily `json:"route_family"` Flags uint8 `json:"flags"` }{ RouteFamily: AfiSafiToRouteFamily(c.AFI, c.SAFI), Flags: c.Flags, }) } func NewCapGracefulRestartTuple(rf RouteFamily, forward bool) *CapGracefulRestartTuple { afi, safi := RouteFamilyToAfiSafi(rf) flags := 0 if forward { flags = 0x80 } return &CapGracefulRestartTuple{ AFI: afi, SAFI: safi, Flags: uint8(flags), } } type CapGracefulRestart struct { DefaultParameterCapability Flags uint8 Time uint16 Tuples []*CapGracefulRestartTuple } func (c *CapGracefulRestart) DecodeFromBytes(data []byte) error { c.DefaultParameterCapability.DecodeFromBytes(data) data = data[2:] if len(data) < 2 { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "Not all CapabilityGracefulRestart bytes available") } restart := binary.BigEndian.Uint16(data[0:2]) c.Flags = uint8(restart >> 12) c.Time = restart & 0xfff data = data[2:] valueLen := int(c.CapLen) - 2 if valueLen >= 4 && len(data) >= valueLen { c.Tuples = make([]*CapGracefulRestartTuple, 0, valueLen/4) for i := valueLen; i >= 4; i -= 4 { t := &CapGracefulRestartTuple{binary.BigEndian.Uint16(data[0:2]), data[2], data[3]} c.Tuples = append(c.Tuples, t) data = data[4:] } } return nil } func (c *CapGracefulRestart) Serialize() ([]byte, error) { buf := make([]byte, 2, 2+4*len(c.Tuples)) binary.BigEndian.PutUint16(buf[0:], uint16(c.Flags)<<12|c.Time) var tbuf [4]byte for _, t := range c.Tuples { binary.BigEndian.PutUint16(tbuf[0:2], t.AFI) tbuf[2] = t.SAFI tbuf[3] = t.Flags buf = append(buf, tbuf[:]...) } c.DefaultParameterCapability.CapValue = buf return c.DefaultParameterCapability.Serialize() } func (c *CapGracefulRestart) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Code BGPCapabilityCode `json:"code"` Flags uint8 `json:"flags"` Time uint16 `json:"time"` Tuples []*CapGracefulRestartTuple `json:"tuples"` }{ Code: c.Code(), Flags: c.Flags, Time: c.Time, Tuples: c.Tuples, }) } func NewCapGracefulRestart(restarting, notification bool, time uint16, tuples []*CapGracefulRestartTuple) *CapGracefulRestart { flags := 0 if restarting { flags = 0x08 } if notification { flags |= 0x04 } return &CapGracefulRestart{ DefaultParameterCapability: DefaultParameterCapability{ CapCode: BGP_CAP_GRACEFUL_RESTART, }, Flags: uint8(flags), Time: time, Tuples: tuples, } } type CapFourOctetASNumber struct { DefaultParameterCapability CapValue uint32 } func (c *CapFourOctetASNumber) DecodeFromBytes(data []byte) error { c.DefaultParameterCapability.DecodeFromBytes(data) data = data[2:] if len(data) < 4 { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "Not all CapabilityFourOctetASNumber bytes available") } c.CapValue = binary.BigEndian.Uint32(data[0:4]) return nil } func (c *CapFourOctetASNumber) Serialize() ([]byte, error) { buf := make([]byte, 4) binary.BigEndian.PutUint32(buf, c.CapValue) c.DefaultParameterCapability.CapValue = buf return c.DefaultParameterCapability.Serialize() } func (c *CapFourOctetASNumber) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Code BGPCapabilityCode `json:"code"` Value uint32 `json:"value"` }{ Code: c.Code(), Value: c.CapValue, }) } func NewCapFourOctetASNumber(asnum uint32) *CapFourOctetASNumber { return &CapFourOctetASNumber{ DefaultParameterCapability{ CapCode: BGP_CAP_FOUR_OCTET_AS_NUMBER, }, asnum, } } type BGPAddPathMode uint8 const ( BGP_ADD_PATH_NONE BGPAddPathMode = iota BGP_ADD_PATH_RECEIVE BGP_ADD_PATH_SEND BGP_ADD_PATH_BOTH ) func (m BGPAddPathMode) String() string { switch m { case BGP_ADD_PATH_NONE: return "none" case BGP_ADD_PATH_RECEIVE: return "receive" case BGP_ADD_PATH_SEND: return "send" case BGP_ADD_PATH_BOTH: return "receive/send" default: return fmt.Sprintf("unknown(%d)", m) } } type CapAddPathTuple struct { RouteFamily RouteFamily Mode BGPAddPathMode } func (t *CapAddPathTuple) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RouteFamily RouteFamily `json:"family"` Mode uint8 `json:"mode"` }{ RouteFamily: t.RouteFamily, Mode: uint8(t.Mode), }) } func NewCapAddPathTuple(family RouteFamily, mode BGPAddPathMode) *CapAddPathTuple { return &CapAddPathTuple{ RouteFamily: family, Mode: mode, } } type CapAddPath struct { DefaultParameterCapability Tuples []*CapAddPathTuple } func (c *CapAddPath) DecodeFromBytes(data []byte) error { c.DefaultParameterCapability.DecodeFromBytes(data) data = data[2:] capLen := int(c.CapLen) if capLen%4 != 0 || capLen < 4 || len(data) < capLen { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "Not all CapabilityAddPath bytes available") } c.Tuples = []*CapAddPathTuple{} for capLen >= 4 { t := &CapAddPathTuple{ RouteFamily: AfiSafiToRouteFamily(binary.BigEndian.Uint16(data[:2]), data[2]), Mode: BGPAddPathMode(data[3]), } c.Tuples = append(c.Tuples, t) data = data[4:] capLen -= 4 } return nil } func (c *CapAddPath) Serialize() ([]byte, error) { buf := make([]byte, len(c.Tuples)*4) for i, t := range c.Tuples { afi, safi := RouteFamilyToAfiSafi(t.RouteFamily) binary.BigEndian.PutUint16(buf[i*4:i*4+2], afi) buf[i*4+2] = safi buf[i*4+3] = byte(t.Mode) } c.DefaultParameterCapability.CapValue = buf return c.DefaultParameterCapability.Serialize() } func (c *CapAddPath) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Code BGPCapabilityCode `json:"code"` Tuples []*CapAddPathTuple `json:"tuples"` }{ Code: c.Code(), Tuples: c.Tuples, }) } func NewCapAddPath(tuples []*CapAddPathTuple) *CapAddPath { return &CapAddPath{ DefaultParameterCapability: DefaultParameterCapability{ CapCode: BGP_CAP_ADD_PATH, }, Tuples: tuples, } } type CapEnhancedRouteRefresh struct { DefaultParameterCapability } func NewCapEnhancedRouteRefresh() *CapEnhancedRouteRefresh { return &CapEnhancedRouteRefresh{ DefaultParameterCapability{ CapCode: BGP_CAP_ENHANCED_ROUTE_REFRESH, }, } } type CapRouteRefreshCisco struct { DefaultParameterCapability } func NewCapRouteRefreshCisco() *CapRouteRefreshCisco { return &CapRouteRefreshCisco{ DefaultParameterCapability{ CapCode: BGP_CAP_ROUTE_REFRESH_CISCO, }, } } type CapLongLivedGracefulRestartTuple struct { AFI uint16 SAFI uint8 Flags uint8 RestartTime uint32 } func (c *CapLongLivedGracefulRestartTuple) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RouteFamily RouteFamily `json:"route_family"` Flags uint8 `json:"flags"` RestartTime uint32 `json:"restart_time"` }{ RouteFamily: AfiSafiToRouteFamily(c.AFI, c.SAFI), Flags: c.Flags, RestartTime: c.RestartTime, }) } func NewCapLongLivedGracefulRestartTuple(rf RouteFamily, forward bool, restartTime uint32) *CapLongLivedGracefulRestartTuple { afi, safi := RouteFamilyToAfiSafi(rf) flags := 0 if forward { flags = 0x80 } return &CapLongLivedGracefulRestartTuple{ AFI: afi, SAFI: safi, Flags: uint8(flags), RestartTime: restartTime, } } type CapLongLivedGracefulRestart struct { DefaultParameterCapability Tuples []*CapLongLivedGracefulRestartTuple } func (c *CapLongLivedGracefulRestart) DecodeFromBytes(data []byte) error { c.DefaultParameterCapability.DecodeFromBytes(data) data = data[2:] valueLen := int(c.CapLen) if valueLen%7 != 0 || len(data) < valueLen { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "invalid length of long lived graceful restart capablity") } for i := valueLen; i >= 7; i -= 7 { t := &CapLongLivedGracefulRestartTuple{ binary.BigEndian.Uint16(data), data[2], data[3], uint32(data[4])<<16 | uint32(data[5])<<8 | uint32(data[6]), } c.Tuples = append(c.Tuples, t) data = data[7:] } return nil } func (c *CapLongLivedGracefulRestart) Serialize() ([]byte, error) { buf := make([]byte, 7*len(c.Tuples)) for idx, t := range c.Tuples { binary.BigEndian.PutUint16(buf[idx*7:], t.AFI) buf[idx*7+2] = t.SAFI buf[idx*7+3] = t.Flags buf[idx*7+4] = uint8((t.RestartTime >> 16) & 0xff) buf[idx*7+5] = uint8((t.RestartTime >> 8) & 0xff) buf[idx*7+6] = uint8(t.RestartTime & 0xff) } c.DefaultParameterCapability.CapValue = buf return c.DefaultParameterCapability.Serialize() } func (c *CapLongLivedGracefulRestart) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Code BGPCapabilityCode `json:"code"` Tuples []*CapLongLivedGracefulRestartTuple `json:"tuples"` }{ Code: c.Code(), Tuples: c.Tuples, }) } func NewCapLongLivedGracefulRestart(tuples []*CapLongLivedGracefulRestartTuple) *CapLongLivedGracefulRestart { return &CapLongLivedGracefulRestart{ DefaultParameterCapability: DefaultParameterCapability{ CapCode: BGP_CAP_LONG_LIVED_GRACEFUL_RESTART, }, Tuples: tuples, } } type CapFQDN struct { DefaultParameterCapability HostNameLen uint8 HostName string DomainNameLen uint8 DomainName string } func (c *CapFQDN) DecodeFromBytes(data []byte) error { c.DefaultParameterCapability.DecodeFromBytes(data) data = data[2:] if len(data) < 2 { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "Not all CapabilityFQDN bytes allowed") } hostNameLen := uint8(data[0]) c.HostNameLen = hostNameLen c.HostName = string(data[1 : c.HostNameLen+1]) domainNameLen := uint8(data[c.HostNameLen+1]) c.DomainNameLen = domainNameLen c.DomainName = string(data[c.HostNameLen+2:]) return nil } func (c *CapFQDN) Serialize() ([]byte, error) { buf := make([]byte, c.HostNameLen+c.DomainNameLen+2) buf[0] = c.HostNameLen copy(buf[1:c.HostNameLen+1], c.HostName) buf[c.HostNameLen+1] = c.DomainNameLen copy(buf[c.HostNameLen+2:], c.DomainName) c.DefaultParameterCapability.CapValue = buf return c.DefaultParameterCapability.Serialize() } func (c *CapFQDN) MarshalJSON() ([]byte, error) { return json.Marshal(struct { HostNameLen uint8 `json:"hostname_len"` HostName string `json:"hostname"` DomainNameLen uint8 `json:"domainname_len"` DomainName string `json:"domainname"` }{ HostNameLen: c.HostNameLen, HostName: c.HostName, DomainNameLen: c.DomainNameLen, DomainName: c.DomainName, }) } func NewCapFQDN(hostname string, domainname string) *CapFQDN { if len(hostname) > 64 { hostname = hostname[:64] } if len(domainname) > 64 { domainname = domainname[:64] } return &CapFQDN{ DefaultParameterCapability{ CapCode: BGP_CAP_FQDN, }, uint8(len(hostname)), hostname, uint8(len(domainname)), domainname, } } type CapUnknown struct { DefaultParameterCapability } func NewCapUnknown(code BGPCapabilityCode, value []byte) *CapUnknown { return &CapUnknown{ DefaultParameterCapability{ CapCode: code, CapValue: value, }, } } func DecodeCapability(data []byte) (ParameterCapabilityInterface, error) { if len(data) < 2 { return nil, NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY, nil, "Not all ParameterCapability bytes available") } var c ParameterCapabilityInterface switch BGPCapabilityCode(data[0]) { case BGP_CAP_MULTIPROTOCOL: c = &CapMultiProtocol{} case BGP_CAP_ROUTE_REFRESH: c = &CapRouteRefresh{} case BGP_CAP_CARRYING_LABEL_INFO: c = &CapCarryingLabelInfo{} case BGP_CAP_EXTENDED_NEXTHOP: c = &CapExtendedNexthop{} case BGP_CAP_GRACEFUL_RESTART: c = &CapGracefulRestart{} case BGP_CAP_FOUR_OCTET_AS_NUMBER: c = &CapFourOctetASNumber{} case BGP_CAP_ADD_PATH: c = &CapAddPath{} case BGP_CAP_ENHANCED_ROUTE_REFRESH: c = &CapEnhancedRouteRefresh{} case BGP_CAP_ROUTE_REFRESH_CISCO: c = &CapRouteRefreshCisco{} case BGP_CAP_LONG_LIVED_GRACEFUL_RESTART: c = &CapLongLivedGracefulRestart{} case BGP_CAP_FQDN: c = &CapFQDN{} default: c = &CapUnknown{} } err := c.DecodeFromBytes(data) return c, err } type OptionParameterInterface interface { Serialize() ([]byte, error) } type OptionParameterCapability struct { ParamType uint8 ParamLen uint8 Capability []ParameterCapabilityInterface } func (o *OptionParameterCapability) DecodeFromBytes(data []byte) error { if uint8(len(data)) < o.ParamLen { return NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_OPTIONAL_PARAMETER, nil, "Not all OptionParameterCapability bytes available") } for len(data) >= 2 { c, err := DecodeCapability(data) if err != nil { return err } o.Capability = append(o.Capability, c) if c.Len() == 0 || len(data) < c.Len() { return NewMessageError(BGP_ERROR_MESSAGE_HEADER_ERROR, BGP_ERROR_SUB_BAD_MESSAGE_LENGTH, nil, "Bad capability length") } data = data[c.Len():] } return nil } func (o *OptionParameterCapability) Serialize() ([]byte, error) { buf := make([]byte, 2) buf[0] = o.ParamType for _, p := range o.Capability { pbuf, err := p.Serialize() if err != nil { return nil, err } buf = append(buf, pbuf...) } o.ParamLen = uint8(len(buf) - 2) buf[1] = o.ParamLen return buf, nil } func NewOptionParameterCapability(capability []ParameterCapabilityInterface) *OptionParameterCapability { return &OptionParameterCapability{ ParamType: BGP_OPT_CAPABILITY, Capability: capability, } } type OptionParameterUnknown struct { ParamType uint8 ParamLen uint8 Value []byte } func (o *OptionParameterUnknown) Serialize() ([]byte, error) { buf := make([]byte, 2+len(o.Value)) buf[0] = o.ParamType if o.ParamLen == 0 { o.ParamLen = uint8(len(o.Value)) } buf[1] = o.ParamLen copy(buf[2:], o.Value) return buf, nil } type BGPOpen struct { Version uint8 MyAS uint16 HoldTime uint16 ID net.IP OptParamLen uint8 OptParams []OptionParameterInterface } func (msg *BGPOpen) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { if len(data) < 10 { return NewMessageError(BGP_ERROR_MESSAGE_HEADER_ERROR, BGP_ERROR_SUB_BAD_MESSAGE_LENGTH, nil, "Not all BGP Open message bytes available") } msg.Version = data[0] msg.MyAS = binary.BigEndian.Uint16(data[1:3]) msg.HoldTime = binary.BigEndian.Uint16(data[3:5]) msg.ID = net.IP(data[5:9]).To4() msg.OptParamLen = data[9] data = data[10:] if len(data) < int(msg.OptParamLen) { return NewMessageError(BGP_ERROR_MESSAGE_HEADER_ERROR, BGP_ERROR_SUB_BAD_MESSAGE_LENGTH, nil, "Not all BGP Open message bytes available") } msg.OptParams = []OptionParameterInterface{} for rest := msg.OptParamLen; rest > 0; { if rest < 2 { return NewMessageError(BGP_ERROR_MESSAGE_HEADER_ERROR, BGP_ERROR_SUB_BAD_MESSAGE_LENGTH, nil, "Malformed BGP Open message") } paramtype := data[0] paramlen := data[1] if paramlen >= 254 || rest < paramlen+2 { return NewMessageError(BGP_ERROR_MESSAGE_HEADER_ERROR, BGP_ERROR_SUB_BAD_MESSAGE_LENGTH, nil, "Malformed BGP Open message") } rest -= paramlen + 2 if paramtype == BGP_OPT_CAPABILITY { p := &OptionParameterCapability{} p.ParamType = paramtype p.ParamLen = paramlen p.DecodeFromBytes(data[2 : 2+paramlen]) msg.OptParams = append(msg.OptParams, p) } else { p := &OptionParameterUnknown{} p.ParamType = paramtype p.ParamLen = paramlen p.Value = data[2 : 2+paramlen] msg.OptParams = append(msg.OptParams, p) } data = data[2+paramlen:] } return nil } func (msg *BGPOpen) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 10) buf[0] = msg.Version binary.BigEndian.PutUint16(buf[1:3], msg.MyAS) binary.BigEndian.PutUint16(buf[3:5], msg.HoldTime) copy(buf[5:9], msg.ID.To4()) pbuf := make([]byte, 0) for _, p := range msg.OptParams { onepbuf, err := p.Serialize() if err != nil { return nil, err } pbuf = append(pbuf, onepbuf...) } msg.OptParamLen = uint8(len(pbuf)) buf[9] = msg.OptParamLen return append(buf, pbuf...), nil } func NewBGPOpenMessage(myas uint16, holdtime uint16, id string, optparams []OptionParameterInterface) *BGPMessage { return &BGPMessage{ Header: BGPHeader{Type: BGP_MSG_OPEN}, Body: &BGPOpen{4, myas, holdtime, net.ParseIP(id).To4(), 0, optparams}, } } type AddrPrefixInterface interface { DecodeFromBytes([]byte, ...*MarshallingOption) error Serialize(...*MarshallingOption) ([]byte, error) AFI() uint16 SAFI() uint8 Len(...*MarshallingOption) int String() string MarshalJSON() ([]byte, error) // Create a flat map to describe attributes and their // values. This can be used to create structured outputs. Flat() map[string]string PathIdentifier() uint32 SetPathIdentifier(uint32) PathLocalIdentifier() uint32 SetPathLocalIdentifier(uint32) } func LabelString(nlri AddrPrefixInterface) string { label := "" switch n := nlri.(type) { case *LabeledIPAddrPrefix: label = n.Labels.String() case *LabeledIPv6AddrPrefix: label = n.Labels.String() case *LabeledVPNIPAddrPrefix: label = n.Labels.String() case *LabeledVPNIPv6AddrPrefix: label = n.Labels.String() case *EVPNNLRI: switch route := n.RouteTypeData.(type) { case *EVPNEthernetAutoDiscoveryRoute: label = fmt.Sprintf("[%d]", route.Label) case *EVPNMacIPAdvertisementRoute: ls := make([]string, len(route.Labels)) for i, l := range route.Labels { ls[i] = strconv.Itoa(int(l)) } label = fmt.Sprintf("[%s]", strings.Join(ls, ",")) case *EVPNIPPrefixRoute: label = fmt.Sprintf("[%d]", route.Label) } } return label } type PrefixDefault struct { mu sync.Mutex id uint32 localId uint32 } func (p *PrefixDefault) PathIdentifier() uint32 { p.mu.Lock() defer p.mu.Unlock() return p.id } func (p *PrefixDefault) SetPathIdentifier(id uint32) { p.mu.Lock() defer p.mu.Unlock() p.id = id } func (p *PrefixDefault) PathLocalIdentifier() uint32 { p.mu.Lock() defer p.mu.Unlock() return p.localId } func (p *PrefixDefault) SetPathLocalIdentifier(id uint32) { p.mu.Lock() defer p.mu.Unlock() p.localId = id } func (p *PrefixDefault) decodePathIdentifier(data []byte) ([]byte, error) { if len(data) < 4 { code := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) subcode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) return nil, NewMessageError(code, subcode, nil, "prefix misses path identifier field") } p.SetPathIdentifier(binary.BigEndian.Uint32(data[:4])) return data[4:], nil } func (p *PrefixDefault) serializeIdentifier() ([]byte, error) { buf := make([]byte, 4) binary.BigEndian.PutUint32(buf, p.PathLocalIdentifier()) return buf, nil } type IPAddrPrefixDefault struct { PrefixDefault Length uint8 Prefix net.IP } func (r *IPAddrPrefixDefault) decodePrefix(data []byte, bitlen uint8, addrlen uint8) error { bytelen := (int(bitlen) + 7) / 8 if len(data) < bytelen { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) return NewMessageError(eCode, eSubCode, nil, "network bytes is short") } if bitlen > addrlen*8 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) return NewMessageError(eCode, eSubCode, nil, "network bit length is too long") } b := make([]byte, addrlen) copy(b, data[:bytelen]) // clear trailing bits in the last byte. rfc doesn't require // this but some bgp implementations need this... rem := bitlen % 8 if rem != 0 { mask := 0xff00 >> rem lastByte := b[bytelen-1] & byte(mask) b[bytelen-1] = lastByte } r.Prefix = b return nil } func (r *IPAddrPrefixDefault) serializePrefix(bitLen uint8) ([]byte, error) { byteLen := (int(bitLen) + 7) / 8 buf := make([]byte, byteLen) copy(buf, r.Prefix) return buf, nil } func (r *IPAddrPrefixDefault) String() string { return fmt.Sprintf("%s/%d", r.Prefix.String(), r.Length) } func (r *IPAddrPrefixDefault) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Prefix string `json:"prefix"` }{ Prefix: r.String(), }) } type IPAddrPrefix struct { IPAddrPrefixDefault addrlen uint8 } func (r *IPAddrPrefix) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { if r.addrlen == 0 { r.addrlen = 4 } f := RF_IPv4_UC if r.addrlen == 16 { f = RF_IPv6_UC } if IsAddPathEnabled(true, f, options) { var err error data, err = r.decodePathIdentifier(data) if err != nil { return err } } if len(data) < 1 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) return NewMessageError(eCode, eSubCode, nil, "prefix misses length field") } r.Length = data[0] return r.decodePrefix(data[1:], r.Length, r.addrlen) } func (r *IPAddrPrefix) Serialize(options ...*MarshallingOption) ([]byte, error) { f := RF_IPv4_UC if r.addrlen == 16 { f = RF_IPv6_UC } var buf []byte if IsAddPathEnabled(false, f, options) { var err error buf, err = r.serializeIdentifier() if err != nil { return nil, err } } buf = append(buf, r.Length) pbuf, err := r.serializePrefix(r.Length) if err != nil { return nil, err } return append(buf, pbuf...), nil } func (r *IPAddrPrefix) AFI() uint16 { return AFI_IP } func (r *IPAddrPrefix) SAFI() uint8 { return SAFI_UNICAST } func (r *IPAddrPrefix) Len(options ...*MarshallingOption) int { return 1 + ((int(r.Length) + 7) / 8) } func NewIPAddrPrefix(length uint8, prefix string) *IPAddrPrefix { p := &IPAddrPrefix{ IPAddrPrefixDefault{ Length: length, }, 4, } p.IPAddrPrefixDefault.decodePrefix(net.ParseIP(prefix).To4(), length, 4) return p } func isIPv4MappedIPv6(ip net.IP) bool { return len(ip) == net.IPv6len && ip.To4() != nil } type IPv6AddrPrefix struct { IPAddrPrefix } func (r *IPv6AddrPrefix) AFI() uint16 { return AFI_IP6 } func (r *IPv6AddrPrefix) String() string { prefix := r.Prefix.String() if isIPv4MappedIPv6(r.Prefix) { prefix = "::ffff:" + prefix } return fmt.Sprintf("%s/%d", prefix, r.Length) } func NewIPv6AddrPrefix(length uint8, prefix string) *IPv6AddrPrefix { p := &IPv6AddrPrefix{ IPAddrPrefix{ IPAddrPrefixDefault{ Length: length, }, 16, }, } p.IPAddrPrefixDefault.decodePrefix(net.ParseIP(prefix), length, 16) return p } const ( BGP_RD_TWO_OCTET_AS = iota BGP_RD_IPV4_ADDRESS BGP_RD_FOUR_OCTET_AS ) type RouteDistinguisherInterface interface { DecodeFromBytes([]byte) error Serialize() ([]byte, error) Len() int String() string MarshalJSON() ([]byte, error) } type DefaultRouteDistinguisher struct { Type uint16 } func (rd *DefaultRouteDistinguisher) serialize(value []byte) ([]byte, error) { buf := make([]byte, 8) binary.BigEndian.PutUint16(buf, rd.Type) copy(buf[2:], value) return buf, nil } func (rd *DefaultRouteDistinguisher) Len() int { return 8 } type RouteDistinguisherTwoOctetAS struct { DefaultRouteDistinguisher Admin uint16 Assigned uint32 } func (rd *RouteDistinguisherTwoOctetAS) DecodeFromBytes(data []byte) error { rd.Admin = binary.BigEndian.Uint16(data[0:2]) rd.Assigned = binary.BigEndian.Uint32(data[2:6]) return nil } func (rd *RouteDistinguisherTwoOctetAS) Serialize() ([]byte, error) { buf := make([]byte, 6) binary.BigEndian.PutUint16(buf[0:2], rd.Admin) binary.BigEndian.PutUint32(buf[2:6], rd.Assigned) return rd.serialize(buf) } func (rd *RouteDistinguisherTwoOctetAS) String() string { return fmt.Sprintf("%d:%d", rd.Admin, rd.Assigned) } func (rd *RouteDistinguisherTwoOctetAS) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type uint16 `json:"type"` Admin uint16 `json:"admin"` Assigned uint32 `json:"assigned"` }{ Type: rd.Type, Admin: rd.Admin, Assigned: rd.Assigned, }) } func NewRouteDistinguisherTwoOctetAS(admin uint16, assigned uint32) *RouteDistinguisherTwoOctetAS { return &RouteDistinguisherTwoOctetAS{ DefaultRouteDistinguisher: DefaultRouteDistinguisher{ Type: BGP_RD_TWO_OCTET_AS, }, Admin: admin, Assigned: assigned, } } type RouteDistinguisherIPAddressAS struct { DefaultRouteDistinguisher Admin net.IP Assigned uint16 } func (rd *RouteDistinguisherIPAddressAS) DecodeFromBytes(data []byte) error { rd.Admin = data[0:4] rd.Assigned = binary.BigEndian.Uint16(data[4:6]) return nil } func (rd *RouteDistinguisherIPAddressAS) Serialize() ([]byte, error) { buf := make([]byte, 6) copy(buf[0:4], rd.Admin.To4()) binary.BigEndian.PutUint16(buf[4:6], rd.Assigned) return rd.serialize(buf) } func (rd *RouteDistinguisherIPAddressAS) String() string { return fmt.Sprintf("%s:%d", rd.Admin.String(), rd.Assigned) } func (rd *RouteDistinguisherIPAddressAS) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type uint16 `json:"type"` Admin string `json:"admin"` Assigned uint16 `json:"assigned"` }{ Type: rd.Type, Admin: rd.Admin.String(), Assigned: rd.Assigned, }) } func NewRouteDistinguisherIPAddressAS(admin string, assigned uint16) *RouteDistinguisherIPAddressAS { return &RouteDistinguisherIPAddressAS{ DefaultRouteDistinguisher: DefaultRouteDistinguisher{ Type: BGP_RD_IPV4_ADDRESS, }, Admin: net.ParseIP(admin).To4(), Assigned: assigned, } } type RouteDistinguisherFourOctetAS struct { DefaultRouteDistinguisher Admin uint32 Assigned uint16 } func (rd *RouteDistinguisherFourOctetAS) DecodeFromBytes(data []byte) error { rd.Admin = binary.BigEndian.Uint32(data[0:4]) rd.Assigned = binary.BigEndian.Uint16(data[4:6]) return nil } func (rd *RouteDistinguisherFourOctetAS) Serialize() ([]byte, error) { buf := make([]byte, 6) binary.BigEndian.PutUint32(buf[0:4], rd.Admin) binary.BigEndian.PutUint16(buf[4:6], rd.Assigned) return rd.serialize(buf) } func (rd *RouteDistinguisherFourOctetAS) String() string { fst := rd.Admin >> 16 & 0xffff snd := rd.Admin & 0xffff return fmt.Sprintf("%d.%d:%d", fst, snd, rd.Assigned) } func (rd *RouteDistinguisherFourOctetAS) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type uint16 `json:"type"` Admin uint32 `json:"admin"` Assigned uint16 `json:"assigned"` }{ Type: rd.Type, Admin: rd.Admin, Assigned: rd.Assigned, }) } func NewRouteDistinguisherFourOctetAS(admin uint32, assigned uint16) *RouteDistinguisherFourOctetAS { return &RouteDistinguisherFourOctetAS{ DefaultRouteDistinguisher: DefaultRouteDistinguisher{ Type: BGP_RD_FOUR_OCTET_AS, }, Admin: admin, Assigned: assigned, } } type RouteDistinguisherUnknown struct { DefaultRouteDistinguisher Value []byte } func (rd *RouteDistinguisherUnknown) DecodeFromBytes(data []byte) error { rd.Value = data[0:6] return nil } func (rd *RouteDistinguisherUnknown) Serialize() ([]byte, error) { return rd.DefaultRouteDistinguisher.serialize(rd.Value) } func (rd *RouteDistinguisherUnknown) String() string { return fmt.Sprintf("%v", rd.Value) } func (rd *RouteDistinguisherUnknown) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type uint16 `json:"type"` Value []byte `json:"value"` }{ Type: rd.Type, Value: rd.Value, }) } func GetRouteDistinguisher(data []byte) RouteDistinguisherInterface { typ := binary.BigEndian.Uint16(data[0:2]) switch typ { case BGP_RD_TWO_OCTET_AS: return NewRouteDistinguisherTwoOctetAS(binary.BigEndian.Uint16(data[2:4]), binary.BigEndian.Uint32(data[4:8])) case BGP_RD_IPV4_ADDRESS: return NewRouteDistinguisherIPAddressAS(net.IP(data[2:6]).String(), binary.BigEndian.Uint16(data[6:8])) case BGP_RD_FOUR_OCTET_AS: return NewRouteDistinguisherFourOctetAS(binary.BigEndian.Uint32(data[2:6]), binary.BigEndian.Uint16(data[6:8])) } rd := &RouteDistinguisherUnknown{ DefaultRouteDistinguisher: DefaultRouteDistinguisher{ Type: typ, }, } return rd } func parseRdAndRt(input string) ([]string, error) { elems := _regexpRouteDistinguisher.FindStringSubmatch(input) if len(elems) != 11 { return nil, errors.New("failed to parse") } return elems, nil } func ParseRouteDistinguisher(rd string) (RouteDistinguisherInterface, error) { elems, err := parseRdAndRt(rd) if err != nil { return nil, err } assigned, _ := strconv.ParseUint(elems[10], 10, 32) ip := net.ParseIP(elems[1]) switch { case ip.To4() != nil: return NewRouteDistinguisherIPAddressAS(elems[1], uint16(assigned)), nil case elems[6] == "" && elems[7] == "": asn, _ := strconv.ParseUint(elems[8], 10, 16) return NewRouteDistinguisherTwoOctetAS(uint16(asn), uint32(assigned)), nil default: fst, _ := strconv.ParseUint(elems[7], 10, 16) snd, _ := strconv.ParseUint(elems[8], 10, 16) asn := fst<<16 | snd return NewRouteDistinguisherFourOctetAS(uint32(asn), uint16(assigned)), nil } } // // RFC3107 Carrying Label Information in BGP-4 // // 3. Carrying Label Mapping Information // // b) Label: // // The Label field carries one or more labels (that corresponds to // the stack of labels [MPLS-ENCAPS(RFC3032)]). Each label is encoded as // 4 octets, where the high-order 20 bits contain the label value, and // the low order bit contains "Bottom of Stack" // // RFC3032 MPLS Label Stack Encoding // // 2.1. Encoding the Label Stack // // 0 1 2 3 // 0 ... 9 0 ... 9 0 1 2 3 4 ... 9 0 1 // +-----+-+-+---+-+-+-+-+-+-----+-+-+-+ // | Label | Exp |S| TTL | // +-----+-+-+---+-+-+-+-+-+-----+-+-+-+ // // RFC3107 Carrying Label Information in BGP-4 // // 3. Carrying Label Mapping Information // // The label information carried (as part of NLRI) in the Withdrawn // Routes field should be set to 0x800000. const WITHDRAW_LABEL = uint32(0x800000) const ZERO_LABEL = uint32(0) // some platform uses this as withdraw label type MPLSLabelStack struct { Labels []uint32 } func (l *MPLSLabelStack) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { labels := []uint32{} foundBottom := false bottomExpected := true if IsAttributePresent(BGP_ATTR_TYPE_PREFIX_SID, options) { // If Update carries Prefix SID attribute then one should not rely on BoS for the label stack processing, // the first and only label carries transposed variable part of the SRv6 SID. bottomExpected = false } for len(data) >= 3 { label := uint32(data[0])<<16 | uint32(data[1])<<8 | uint32(data[2]) if label == WITHDRAW_LABEL || label == ZERO_LABEL { l.Labels = []uint32{label} return nil } data = data[3:] labels = append(labels, label>>4) if !bottomExpected { // Faking found bottom. foundBottom = true break } if label&1 == 1 { foundBottom = true break } } if !foundBottom { l.Labels = []uint32{} return nil } l.Labels = labels return nil } func (l *MPLSLabelStack) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, len(l.Labels)*3) for i, label := range l.Labels { if label == WITHDRAW_LABEL { return []byte{128, 0, 0}, nil } label = label << 4 buf[i*3] = byte((label >> 16) & 0xff) buf[i*3+1] = byte((label >> 8) & 0xff) buf[i*3+2] = byte(label & 0xff) } buf[len(buf)-1] |= 1 return buf, nil } func (l *MPLSLabelStack) Len() int { return 3 * len(l.Labels) } func (l *MPLSLabelStack) String() string { if len(l.Labels) == 0 { return "" } s := bytes.NewBuffer(make([]byte, 0, 64)) s.WriteString("[") ss := make([]string, 0, len(l.Labels)) for _, label := range l.Labels { ss = append(ss, fmt.Sprintf("%d", label)) } s.WriteString(strings.Join(ss, ", ")) s.WriteString("]") return s.String() } func NewMPLSLabelStack(labels ...uint32) *MPLSLabelStack { if len(labels) == 0 { labels = []uint32{0} } return &MPLSLabelStack{labels} } func ParseMPLSLabelStack(buf string) (*MPLSLabelStack, error) { elems := strings.Split(buf, "/") labels := make([]uint32, 0, len(elems)) if len(elems) == 0 { goto ERR } for _, elem := range elems { i, err := strconv.ParseUint(elem, 10, 32) if err != nil { goto ERR } if i > ((1 << 20) - 1) { goto ERR } labels = append(labels, uint32(i)) } return NewMPLSLabelStack(labels...), nil ERR: return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "invalid mpls label stack format") } // // RFC3107 Carrying Label Information in BGP-4 // // 3. Carrying Label Mapping Information // // +----------------------+ // | Length (1 octet) | // +----------------------+ // | Label (3 octets) | // +----------------------+ // ....................... // +----------------------+ // | Prefix (variable) | // +----------------------+ // // RFC4364 BGP/MPLS IP VPNs // // 4.3.4. How VPN-IPv4 NLRI Is Carried in BGP // // The labeled VPN-IPv4 NLRI itself is encoded as specified in // [MPLS-BGP(RFC3107)], where the prefix consists of an 8-byte RD // followed by an IPv4 prefix. // type LabeledVPNIPAddrPrefix struct { IPAddrPrefixDefault Labels MPLSLabelStack RD RouteDistinguisherInterface addrlen uint8 } func (l *LabeledVPNIPAddrPrefix) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { f := RF_IPv4_VPN if l.addrlen == 16 { f = RF_IPv6_VPN } if IsAddPathEnabled(true, f, options) { var err error data, err = l.decodePathIdentifier(data) if err != nil { return err } } if len(data) < 1 { return NewMessageError(uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR), uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST), nil, "prefix misses length field") } l.Length = uint8(data[0]) data = data[1:] l.Labels.DecodeFromBytes(data, options...) if int(l.Length)-8*(l.Labels.Len()) < 0 { l.Labels.Labels = []uint32{} } data = data[l.Labels.Len():] l.RD = GetRouteDistinguisher(data) rdLen := l.RD.Len() if len(data) < rdLen { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "bad labeled VPN-IPv4 NLRI length") } data = data[l.RD.Len():] restbits := int(l.Length) - 8*(l.Labels.Len()+l.RD.Len()) return l.decodePrefix(data, uint8(restbits), l.addrlen) } func (l *LabeledVPNIPAddrPrefix) Serialize(options ...*MarshallingOption) ([]byte, error) { f := RF_IPv4_VPN if l.addrlen == 16 { f = RF_IPv6_VPN } var buf []byte if IsAddPathEnabled(false, f, options) { var err error buf, err = l.serializeIdentifier() if err != nil { return nil, err } } buf = append(buf, l.Length) lbuf, err := l.Labels.Serialize(options...) if err != nil { return nil, err } buf = append(buf, lbuf...) rbuf, err := l.RD.Serialize() if err != nil { return nil, err } buf = append(buf, rbuf...) restbits := int(l.Length) - 8*(l.Labels.Len()+l.RD.Len()) pbuf, err := l.serializePrefix(uint8(restbits)) if err != nil { return nil, err } buf = append(buf, pbuf...) return buf, nil } func (l *LabeledVPNIPAddrPrefix) AFI() uint16 { return AFI_IP } func (l *LabeledVPNIPAddrPrefix) SAFI() uint8 { return SAFI_MPLS_VPN } func (l *LabeledVPNIPAddrPrefix) IPPrefixLen() uint8 { return l.Length - 8*uint8(l.Labels.Len()+l.RD.Len()) } func (l *LabeledVPNIPAddrPrefix) Len(options ...*MarshallingOption) int { return 1 + l.Labels.Len() + l.RD.Len() + int((l.IPPrefixLen()+7)/8) } func (l *LabeledVPNIPAddrPrefix) String() string { return fmt.Sprintf("%s:%s", l.RD, l.IPPrefix()) } func (l *LabeledVPNIPAddrPrefix) IPPrefix() string { masklen := l.IPAddrPrefixDefault.Length - uint8(8*(l.Labels.Len()+l.RD.Len())) return fmt.Sprintf("%s/%d", l.IPAddrPrefixDefault.Prefix, masklen) } func (l *LabeledVPNIPAddrPrefix) MarshalJSON() ([]byte, error) { masklen := l.IPAddrPrefixDefault.Length - uint8(8*(l.Labels.Len()+l.RD.Len())) return json.Marshal(struct { Prefix string `json:"prefix"` Labels []uint32 `json:"labels"` RD RouteDistinguisherInterface `json:"rd"` }{ Prefix: fmt.Sprintf("%s/%d", l.IPAddrPrefixDefault.Prefix, masklen), Labels: l.Labels.Labels, RD: l.RD, }) } func NewLabeledVPNIPAddrPrefix(length uint8, prefix string, label MPLSLabelStack, rd RouteDistinguisherInterface) *LabeledVPNIPAddrPrefix { rdlen := 0 if rd != nil { rdlen = rd.Len() } return &LabeledVPNIPAddrPrefix{ IPAddrPrefixDefault{ Length: length + uint8(8*(label.Len()+rdlen)), Prefix: net.ParseIP(prefix).To4(), }, label, rd, 4, } } type LabeledVPNIPv6AddrPrefix struct { LabeledVPNIPAddrPrefix } func (l *LabeledVPNIPv6AddrPrefix) AFI() uint16 { return AFI_IP6 } func NewLabeledVPNIPv6AddrPrefix(length uint8, prefix string, label MPLSLabelStack, rd RouteDistinguisherInterface) *LabeledVPNIPv6AddrPrefix { rdlen := 0 if rd != nil { rdlen = rd.Len() } return &LabeledVPNIPv6AddrPrefix{ LabeledVPNIPAddrPrefix{ IPAddrPrefixDefault{ Length: length + uint8(8*(label.Len()+rdlen)), Prefix: net.ParseIP(prefix), }, label, rd, 16, }, } } type LabeledIPAddrPrefix struct { IPAddrPrefixDefault Labels MPLSLabelStack addrlen uint8 } func (r *LabeledIPAddrPrefix) AFI() uint16 { return AFI_IP } func (r *LabeledIPAddrPrefix) SAFI() uint8 { return SAFI_MPLS_LABEL } func (l *LabeledIPAddrPrefix) IPPrefixLen() uint8 { return l.Length - 8*uint8(l.Labels.Len()) } func (l *LabeledIPAddrPrefix) Len(options ...*MarshallingOption) int { return 1 + l.Labels.Len() + int((l.IPPrefixLen()+7)/8) } func (l *LabeledIPAddrPrefix) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { f := RF_IPv4_MPLS if l.addrlen == 16 { f = RF_IPv6_MPLS } if IsAddPathEnabled(true, f, options) { var err error data, err = l.decodePathIdentifier(data) if err != nil { return err } } l.Length = uint8(data[0]) data = data[1:] l.Labels.DecodeFromBytes(data) if int(l.Length)-8*(l.Labels.Len()) < 0 { l.Labels.Labels = []uint32{} } restbits := int(l.Length) - 8*(l.Labels.Len()) data = data[l.Labels.Len():] return l.decodePrefix(data, uint8(restbits), l.addrlen) } func (l *LabeledIPAddrPrefix) Serialize(options ...*MarshallingOption) ([]byte, error) { f := RF_IPv4_MPLS if l.addrlen == 16 { f = RF_IPv6_MPLS } var buf []byte if IsAddPathEnabled(false, f, options) { var err error buf, err = l.serializeIdentifier() if err != nil { return nil, err } } buf = append(buf, l.Length) restbits := int(l.Length) - 8*(l.Labels.Len()) lbuf, err := l.Labels.Serialize() if err != nil { return nil, err } buf = append(buf, lbuf...) pbuf, err := l.serializePrefix(uint8(restbits)) if err != nil { return nil, err } buf = append(buf, pbuf...) return buf, nil } func (l *LabeledIPAddrPrefix) String() string { prefix := l.Prefix.String() if isIPv4MappedIPv6(l.Prefix) { prefix = "::ffff:" + prefix } return fmt.Sprintf("%s/%d", prefix, int(l.Length)-l.Labels.Len()*8) } func (l *LabeledIPAddrPrefix) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Prefix string `json:"prefix"` Labels []uint32 `json:"labels"` }{ Prefix: l.String(), Labels: l.Labels.Labels, }) } func NewLabeledIPAddrPrefix(length uint8, prefix string, label MPLSLabelStack) *LabeledIPAddrPrefix { return &LabeledIPAddrPrefix{ IPAddrPrefixDefault{ Length: length + uint8(label.Len()*8), Prefix: net.ParseIP(prefix).To4(), }, label, 4, } } type LabeledIPv6AddrPrefix struct { LabeledIPAddrPrefix } func (l *LabeledIPv6AddrPrefix) AFI() uint16 { return AFI_IP6 } func NewLabeledIPv6AddrPrefix(length uint8, prefix string, label MPLSLabelStack) *LabeledIPv6AddrPrefix { return &LabeledIPv6AddrPrefix{ LabeledIPAddrPrefix{ IPAddrPrefixDefault{ Length: length + uint8(label.Len()*8), Prefix: net.ParseIP(prefix), }, label, 16, }, } } type RouteTargetMembershipNLRI struct { PrefixDefault Length uint8 AS uint32 RouteTarget ExtendedCommunityInterface } func (n *RouteTargetMembershipNLRI) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { if IsAddPathEnabled(true, RF_RTC_UC, options) { var err error data, err = n.decodePathIdentifier(data) if err != nil { return err } } if len(data) < 1 { return NewMessageError(uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR), uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST), nil, "prefix misses length field") } n.Length = data[0] data = data[1 : n.Length/8+1] if len(data) == 0 { return nil } else if len(data) != 12 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all RouteTargetMembershipNLRI bytes available") } n.AS = binary.BigEndian.Uint32(data[0:4]) rt, err := ParseExtended(data[4:]) n.RouteTarget = rt if err != nil { return err } return nil } func (n *RouteTargetMembershipNLRI) Serialize(options ...*MarshallingOption) ([]byte, error) { var buf []byte if IsAddPathEnabled(false, RF_RTC_UC, options) { var err error buf, err = n.serializeIdentifier() if err != nil { return nil, err } } if n.RouteTarget == nil { return append(buf, 0), nil } offset := len(buf) buf = append(buf, make([]byte, 5)...) buf[offset] = 96 binary.BigEndian.PutUint32(buf[offset+1:], n.AS) ebuf, err := n.RouteTarget.Serialize() if err != nil { return nil, err } return append(buf, ebuf...), nil } func (n *RouteTargetMembershipNLRI) AFI() uint16 { return AFI_IP } func (n *RouteTargetMembershipNLRI) SAFI() uint8 { return SAFI_ROUTE_TARGET_CONSTRAINTS } func (n *RouteTargetMembershipNLRI) Len(options ...*MarshallingOption) int { if n.AS == 0 && n.RouteTarget == nil { return 1 } return 13 } func (n *RouteTargetMembershipNLRI) String() string { target := "default" if n.RouteTarget != nil { target = n.RouteTarget.String() } return fmt.Sprintf("%d:%s", n.AS, target) } func (n *RouteTargetMembershipNLRI) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Prefix string `json:"prefix"` }{ Prefix: n.String(), }) } func NewRouteTargetMembershipNLRI(as uint32, target ExtendedCommunityInterface) *RouteTargetMembershipNLRI { l := 12 * 8 if as == 0 && target == nil { l = 1 } return &RouteTargetMembershipNLRI{ Length: uint8(l), AS: as, RouteTarget: target, } } //go:generate stringer -type=ESIType type ESIType uint8 const ( ESI_ARBITRARY ESIType = iota ESI_LACP ESI_MSTP ESI_MAC ESI_ROUTERID ESI_AS ) type EthernetSegmentIdentifier struct { Type ESIType Value []byte } func (esi *EthernetSegmentIdentifier) DecodeFromBytes(data []byte) error { if len(data) < 10 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("invalid %s length", esi.Type.String())) } esi.Type = ESIType(data[0]) esi.Value = data[1:10] switch esi.Type { case ESI_LACP, ESI_MSTP, ESI_ROUTERID, ESI_AS: if esi.Value[8] != 0x00 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("invalid %s. last octet must be 0x00 (0x%02x)", esi.Type.String(), esi.Value[8])) } } return nil } func (esi *EthernetSegmentIdentifier) Serialize() ([]byte, error) { buf := make([]byte, 10) buf[0] = uint8(esi.Type) copy(buf[1:], esi.Value) return buf, nil } func isZeroBuf(buf []byte) bool { for _, b := range buf { if b != 0 { return false } } return true } func (esi *EthernetSegmentIdentifier) String() string { toHexArray := func(data []byte) string { // Converts byte slice into the colon separated hex values and the // number of elements are 9 at most (excluding Type field). values := make([]string, 0, 9) for _, v := range data { values = append(values, fmt.Sprintf("%02x", v)) } return strings.Join(values, ":") } s := bytes.NewBuffer(make([]byte, 0, 64)) s.WriteString(fmt.Sprintf("%s | ", esi.Type.String())) switch esi.Type { case ESI_LACP: s.WriteString(fmt.Sprintf("system mac %s, ", net.HardwareAddr(esi.Value[:6]).String())) s.WriteString(fmt.Sprintf("port key %d", binary.BigEndian.Uint16(esi.Value[6:8]))) case ESI_MSTP: s.WriteString(fmt.Sprintf("bridge mac %s, ", net.HardwareAddr(esi.Value[:6]).String())) s.WriteString(fmt.Sprintf("priority %d", binary.BigEndian.Uint16(esi.Value[6:8]))) case ESI_MAC: s.WriteString(fmt.Sprintf("system mac %s, ", net.HardwareAddr(esi.Value[:6]).String())) s.WriteString(fmt.Sprintf("local discriminator %d", uint32(esi.Value[6])<<16|uint32(esi.Value[7])<<8|uint32(esi.Value[8]))) case ESI_ROUTERID: s.WriteString(fmt.Sprintf("router id %s, ", net.IP(esi.Value[:4]))) s.WriteString(fmt.Sprintf("local discriminator %d", binary.BigEndian.Uint32(esi.Value[4:8]))) case ESI_AS: s.WriteString(fmt.Sprintf("as %d, ", binary.BigEndian.Uint32(esi.Value[:4]))) s.WriteString(fmt.Sprintf("local discriminator %d", binary.BigEndian.Uint32(esi.Value[4:8]))) case ESI_ARBITRARY: if isZeroBuf(esi.Value) { return "single-homed" } fallthrough default: s.WriteString(toHexArray(esi.Value)) } return s.String() } // Decode Ethernet Segment Identifier (ESI) from string slice. // // The first element of args should be the Type field (e.g., "ARBITRARY", // "arbitrary", "ESI_ARBITRARY" or "esi_arbitrary") and "single-homed" is // the special keyword for all zeroed ESI. // For the "ARBITRARY" Value field (Type 0), it should be the colon separated // hex values and the number of elements should be 9 at most. // e.g.) args := []string{"ARBITRARY", "11:22:33:44:55:66:77:88:99"} // For the other types, the Value field format is the similar to the string // format of ESI. // e.g.) args := []string{"lacp", "aa:bb:cc:dd:ee:ff", "100"} func ParseEthernetSegmentIdentifier(args []string) (EthernetSegmentIdentifier, error) { esi := EthernetSegmentIdentifier{} argLen := len(args) if argLen == 0 || args[0] == "single-homed" { return esi, nil } typeStr := strings.TrimPrefix(strings.ToUpper(args[0]), "ESI_") switch typeStr { case "ARBITRARY": esi.Type = ESI_ARBITRARY case "LACP": esi.Type = ESI_LACP case "MSTP": esi.Type = ESI_MSTP case "MAC": esi.Type = ESI_MAC case "ROUTERID": esi.Type = ESI_ROUTERID case "AS": esi.Type = ESI_AS default: typ, err := strconv.ParseUint(args[0], 10, 8) if err != nil { return esi, fmt.Errorf("invalid esi type: %s", args[0]) } esi.Type = ESIType(typ) } invalidEsiValuesError := fmt.Errorf("invalid esi values for type %s: %s", esi.Type.String(), args[1:]) esi.Value = make([]byte, 9) switch esi.Type { case ESI_LACP: fallthrough case ESI_MSTP: if argLen < 3 { return esi, invalidEsiValuesError } // MAC mac, err := net.ParseMAC(args[1]) if err != nil { return esi, invalidEsiValuesError } copy(esi.Value[0:6], mac) // Port Key or Bridge Priority i, err := strconv.ParseUint(args[2], 10, 16) if err != nil { return esi, invalidEsiValuesError } binary.BigEndian.PutUint16(esi.Value[6:8], uint16(i)) case ESI_MAC: if argLen < 3 { return esi, invalidEsiValuesError } // MAC mac, err := net.ParseMAC(args[1]) if err != nil { return esi, invalidEsiValuesError } copy(esi.Value[0:6], mac) // Local Discriminator i, err := strconv.ParseUint(args[2], 10, 32) if err != nil { return esi, invalidEsiValuesError } iBuf := make([]byte, 4) binary.BigEndian.PutUint32(iBuf, uint32(i)) copy(esi.Value[6:9], iBuf[1:4]) case ESI_ROUTERID: if argLen < 3 { return esi, invalidEsiValuesError } // Router ID ip := net.ParseIP(args[1]) if ip == nil || ip.To4() == nil { return esi, invalidEsiValuesError } copy(esi.Value[0:4], ip.To4()) // Local Discriminator i, err := strconv.ParseUint(args[2], 10, 32) if err != nil { return esi, invalidEsiValuesError } binary.BigEndian.PutUint32(esi.Value[4:8], uint32(i)) case ESI_AS: if argLen < 3 { return esi, invalidEsiValuesError } // AS as, err := strconv.ParseUint(args[1], 10, 32) if err != nil { return esi, invalidEsiValuesError } binary.BigEndian.PutUint32(esi.Value[0:4], uint32(as)) // Local Discriminator i, err := strconv.ParseUint(args[2], 10, 32) if err != nil { return esi, invalidEsiValuesError } binary.BigEndian.PutUint32(esi.Value[4:8], uint32(i)) case ESI_ARBITRARY: fallthrough default: if argLen < 2 { // Assumes the Value field is omitted break } values := make([]byte, 0, 9) for _, e := range strings.SplitN(args[1], ":", 9) { v, err := strconv.ParseUint(e, 16, 16) if err != nil { return esi, invalidEsiValuesError } values = append(values, byte(v)) } copy(esi.Value, values) } return esi, nil } // // I-D bess-evpn-overlay-01 // // 5.1.3 Constructing EVPN BGP Routes // // For the balance of this memo, the MPLS label field will be // referred to as the VNI/VSID field. The VNI/VSID field is used for // both local and global VNIs/VSIDs, and for either case the entire 24- // bit field is used to encode the VNI/VSID value. // // We can't use type MPLSLabelStack for EVPN NLRI, because EVPN NLRI's MPLS // field can be filled with VXLAN VNI. In that case, we must avoid modifying // bottom of stack bit. // func labelDecode(data []byte) (uint32, error) { if len(data) < 3 { return 0, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all Label bytes available") } return uint32(data[0])<<16 | uint32(data[1])<<8 | uint32(data[2]), nil } func labelSerialize(label uint32) ([]byte, error) { if label > 0xffffff { return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Out of range Label: %d", label)) } buf := make([]byte, 3) buf[0] = byte((label >> 16) & 0xff) buf[1] = byte((label >> 8) & 0xff) buf[2] = byte(label & 0xff) return buf, nil } type EVPNEthernetAutoDiscoveryRoute struct { RD RouteDistinguisherInterface ESI EthernetSegmentIdentifier ETag uint32 Label uint32 } func (er *EVPNEthernetAutoDiscoveryRoute) Len() int { // RD(8) + ESI(10) + ETag(4) + Label(3) return 25 } func (er *EVPNEthernetAutoDiscoveryRoute) DecodeFromBytes(data []byte) error { er.RD = GetRouteDistinguisher(data) rdLen := er.RD.Len() if len(data) < rdLen+14 { // 14 is 10 for return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "bad Ethernet Auto-discovery Route length") } data = data[er.RD.Len():] err := er.ESI.DecodeFromBytes(data) if err != nil { return err } data = data[10:] er.ETag = binary.BigEndian.Uint32(data[0:4]) data = data[4:] if er.Label, err = labelDecode(data); err != nil { return err } return nil } func (er *EVPNEthernetAutoDiscoveryRoute) Serialize() ([]byte, error) { var buf []byte var err error if er.RD != nil { buf, err = er.RD.Serialize() if err != nil { return nil, err } } else { buf = make([]byte, 8) } tbuf, err := er.ESI.Serialize() if err != nil { return nil, err } buf = append(buf, tbuf...) var tagBuf [4]byte binary.BigEndian.PutUint32(tagBuf[:4], er.ETag) buf = append(buf, tagBuf[:4]...) tbuf, err = labelSerialize(er.Label) if err != nil { return nil, err } buf = append(buf, tbuf...) return buf, nil } func (er *EVPNEthernetAutoDiscoveryRoute) String() string { // RFC7432: BGP MPLS-Based Ethernet VPN // 7.1. Ethernet Auto-discovery Route // For the purpose of BGP route key processing, only the Ethernet // Segment Identifier and the Ethernet Tag ID are considered to be part // of the prefix in the NLRI. The MPLS Label field is to be treated as // a route attribute as opposed to being part of the route. return fmt.Sprintf("[type:A-D][rd:%s][esi:%s][etag:%d]", er.RD, er.ESI.String(), er.ETag) } func (er *EVPNEthernetAutoDiscoveryRoute) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RD RouteDistinguisherInterface `json:"rd"` ESI string `json:"esi"` Etag uint32 `json:"etag"` Label uint32 `json:"label"` }{ RD: er.RD, ESI: er.ESI.String(), Etag: er.ETag, Label: er.Label, }) } func (er *EVPNEthernetAutoDiscoveryRoute) rd() RouteDistinguisherInterface { return er.RD } func NewEVPNEthernetAutoDiscoveryRoute(rd RouteDistinguisherInterface, esi EthernetSegmentIdentifier, etag uint32, label uint32) *EVPNNLRI { return NewEVPNNLRI(EVPN_ROUTE_TYPE_ETHERNET_AUTO_DISCOVERY, &EVPNEthernetAutoDiscoveryRoute{ RD: rd, ESI: esi, ETag: etag, Label: label, }) } type EVPNMacIPAdvertisementRoute struct { RD RouteDistinguisherInterface ESI EthernetSegmentIdentifier ETag uint32 MacAddressLength uint8 MacAddress net.HardwareAddr IPAddressLength uint8 IPAddress net.IP Labels []uint32 } func (er *EVPNMacIPAdvertisementRoute) Len() int { // RD(8) + ESI(10) + ETag(4) + MacAddressLength(1) + MacAddress(6) // + IPAddressLength(1) + IPAddress(0, 4 or 16) + Labels(3 or 6) return 30 + int(er.IPAddressLength)/8 + len(er.Labels)*3 } func (er *EVPNMacIPAdvertisementRoute) DecodeFromBytes(data []byte) error { er.RD = GetRouteDistinguisher(data) rdLen := er.RD.Len() if len(data) < rdLen { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "bad length of MAC/IP Advertisement Route") } data = data[er.RD.Len():] err := er.ESI.DecodeFromBytes(data) if err != nil { return err } data = data[10:] er.ETag = binary.BigEndian.Uint32(data[0:4]) data = data[4:] er.MacAddressLength = data[0] er.MacAddress = net.HardwareAddr(data[1:7]) er.IPAddressLength = data[7] data = data[8:] if er.IPAddressLength == 32 || er.IPAddressLength == 128 { er.IPAddress = net.IP(data[0:((er.IPAddressLength) / 8)]) } else if er.IPAddressLength != 0 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Invalid IP address length: %d", er.IPAddressLength)) } data = data[(er.IPAddressLength / 8):] var label uint32 if label, err = labelDecode(data); err != nil { return err } er.Labels = append(er.Labels, label) data = data[3:] if len(data) == 3 { if label, err = labelDecode(data); err != nil { return err } er.Labels = append(er.Labels, label) } return nil } func (er *EVPNMacIPAdvertisementRoute) Serialize() ([]byte, error) { var buf []byte var err error if er.RD != nil { buf, err = er.RD.Serialize() if err != nil { return nil, err } } else { buf = make([]byte, 8) } esi, err := er.ESI.Serialize() if err != nil { return nil, err } buf = append(buf, esi...) var tbuf [7]byte binary.BigEndian.PutUint32(tbuf[:4], er.ETag) buf = append(buf, tbuf[:4]...) tbuf[0] = er.MacAddressLength copy(tbuf[1:], er.MacAddress) buf = append(buf, tbuf[:7]...) buf = append(buf, er.IPAddressLength) switch er.IPAddressLength { case 0: // IP address omitted case 32: buf = append(buf, []byte(er.IPAddress.To4())...) case 128: buf = append(buf, []byte(er.IPAddress.To16())...) default: return nil, fmt.Errorf("invalid IP address length: %d", er.IPAddressLength) } for _, l := range er.Labels { label, err := labelSerialize(l) if err != nil { return nil, err } buf = append(buf, label...) } return buf, nil } func (er *EVPNMacIPAdvertisementRoute) String() string { // RFC7432: BGP MPLS-Based Ethernet VPN // 7.2. MAC/IP Advertisement Route // For the purpose of BGP route key processing, only the Ethernet Tag // ID, MAC Address Length, MAC Address, IP Address Length, and IP // Address fields are considered to be part of the prefix in the NLRI. // The Ethernet Segment Identifier, MPLS Label1, and MPLS Label2 fields // are to be treated as route attributes as opposed to being part of the // "route". return fmt.Sprintf("[type:macadv][rd:%s][etag:%d][mac:%s][ip:%s]", er.RD, er.ETag, er.MacAddress, er.IPAddress) } func (er *EVPNMacIPAdvertisementRoute) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RD RouteDistinguisherInterface `json:"rd"` ESI string `json:"esi"` Etag uint32 `json:"etag"` MacAddress string `json:"mac"` IPAddress string `json:"ip"` Labels []uint32 `json:"labels"` }{ RD: er.RD, ESI: er.ESI.String(), Etag: er.ETag, MacAddress: er.MacAddress.String(), IPAddress: er.IPAddress.String(), Labels: er.Labels, }) } func (er *EVPNMacIPAdvertisementRoute) rd() RouteDistinguisherInterface { return er.RD } func NewEVPNMacIPAdvertisementRoute(rd RouteDistinguisherInterface, esi EthernetSegmentIdentifier, etag uint32, macAddress string, ipAddress string, labels []uint32) *EVPNNLRI { mac, _ := net.ParseMAC(macAddress) var ipLen uint8 ip := net.ParseIP(ipAddress) if ip != nil { if ipv4 := ip.To4(); ipv4 != nil { ipLen = 32 ip = ipv4 } else { ipLen = 128 } } return NewEVPNNLRI(EVPN_ROUTE_TYPE_MAC_IP_ADVERTISEMENT, &EVPNMacIPAdvertisementRoute{ RD: rd, ESI: esi, ETag: etag, MacAddressLength: 48, MacAddress: mac, IPAddressLength: ipLen, IPAddress: ip, Labels: labels, }) } type EVPNMulticastEthernetTagRoute struct { RD RouteDistinguisherInterface ETag uint32 IPAddressLength uint8 IPAddress net.IP } func (er *EVPNMulticastEthernetTagRoute) Len() int { // RD(8) + ETag(4) + IPAddressLength(1) + IPAddress(4 or 16) return 13 + int(er.IPAddressLength)/8 } func (er *EVPNMulticastEthernetTagRoute) DecodeFromBytes(data []byte) error { er.RD = GetRouteDistinguisher(data) rdLen := er.RD.Len() if len(data) < rdLen+4 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "invalid length of multicast ethernet tag route") } data = data[er.RD.Len():] er.ETag = binary.BigEndian.Uint32(data[0:4]) er.IPAddressLength = data[4] data = data[5:] if er.IPAddressLength == 32 || er.IPAddressLength == 128 { er.IPAddress = net.IP(data[:er.IPAddressLength/8]) } else { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Invalid IP address length: %d", er.IPAddressLength)) } return nil } func (er *EVPNMulticastEthernetTagRoute) Serialize() ([]byte, error) { var buf []byte var err error if er.RD != nil { buf, err = er.RD.Serialize() if err != nil { return nil, err } } else { buf = make([]byte, 8) } var tbuf [4]byte binary.BigEndian.PutUint32(tbuf[:4], er.ETag) buf = append(buf, tbuf[:4]...) buf = append(buf, er.IPAddressLength) switch er.IPAddressLength { case 32: buf = append(buf, []byte(er.IPAddress.To4())...) case 128: buf = append(buf, []byte(er.IPAddress.To16())...) default: return nil, fmt.Errorf("invalid IP address length: %d", er.IPAddressLength) } return buf, nil } func (er *EVPNMulticastEthernetTagRoute) String() string { // RFC7432: BGP MPLS-Based Ethernet VPN // 7.3. Inclusive Multicast Ethernet Tag Route // ...(snip)... For the purpose of BGP route key // processing, only the Ethernet Tag ID, IP Address Length, and // Originating Router's IP Address fields are considered to be part of // the prefix in the NLRI. return fmt.Sprintf("[type:multicast][rd:%s][etag:%d][ip:%s]", er.RD, er.ETag, er.IPAddress) } func (er *EVPNMulticastEthernetTagRoute) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RD RouteDistinguisherInterface `json:"rd"` Etag uint32 `json:"etag"` IPAddress string `json:"ip"` }{ RD: er.RD, Etag: er.ETag, IPAddress: er.IPAddress.String(), }) } func (er *EVPNMulticastEthernetTagRoute) rd() RouteDistinguisherInterface { return er.RD } func NewEVPNMulticastEthernetTagRoute(rd RouteDistinguisherInterface, etag uint32, ipAddress string) *EVPNNLRI { ipLen := uint8(32) ip := net.ParseIP(ipAddress) if ipv4 := ip.To4(); ipv4 != nil { ip = ipv4 } else { ipLen = 128 } return NewEVPNNLRI(EVPN_INCLUSIVE_MULTICAST_ETHERNET_TAG, &EVPNMulticastEthernetTagRoute{ RD: rd, ETag: etag, IPAddressLength: ipLen, IPAddress: ip, }) } type EVPNEthernetSegmentRoute struct { RD RouteDistinguisherInterface ESI EthernetSegmentIdentifier IPAddressLength uint8 IPAddress net.IP } func (er *EVPNEthernetSegmentRoute) Len() int { // RD(8) + ESI(10) + IPAddressLength(1) + IPAddress(4 or 16) return 19 + int(er.IPAddressLength)/8 } func (er *EVPNEthernetSegmentRoute) DecodeFromBytes(data []byte) error { er.RD = GetRouteDistinguisher(data) rdLen := er.RD.Len() if len(data) < rdLen { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "invalid Ethernet Segment Route length") } data = data[er.RD.Len():] er.ESI.DecodeFromBytes(data) data = data[10:] er.IPAddressLength = data[0] data = data[1:] if er.IPAddressLength == 32 || er.IPAddressLength == 128 { er.IPAddress = net.IP(data[:er.IPAddressLength/8]) } else { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Invalid IP address length: %d", er.IPAddressLength)) } return nil } func (er *EVPNEthernetSegmentRoute) Serialize() ([]byte, error) { var buf []byte var err error if er.RD != nil { buf, err = er.RD.Serialize() if err != nil { return nil, err } } else { buf = make([]byte, 8) } tbuf, err := er.ESI.Serialize() if err != nil { return nil, err } buf = append(buf, tbuf...) buf = append(buf, er.IPAddressLength) switch er.IPAddressLength { case 32: buf = append(buf, []byte(er.IPAddress.To4())...) case 128: buf = append(buf, []byte(er.IPAddress.To16())...) default: return nil, fmt.Errorf("invalid IP address length: %d", er.IPAddressLength) } return buf, nil } func (er *EVPNEthernetSegmentRoute) String() string { // RFC7432: BGP MPLS-Based Ethernet VPN // 7.4. Ethernet Segment Route // For the purpose of BGP route key processing, only the Ethernet // Segment ID, IP Address Length, and Originating Router's IP Address // fields are considered to be part of the prefix in the NLRI. return fmt.Sprintf("[type:esi][rd:%s][esi:%s][ip:%s]", er.RD, er.ESI.String(), er.IPAddress) } func (er *EVPNEthernetSegmentRoute) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RD RouteDistinguisherInterface `json:"rd"` ESI string `json:"esi"` IPAddress string `json:"ip"` }{ RD: er.RD, ESI: er.ESI.String(), IPAddress: er.IPAddress.String(), }) } func (er *EVPNEthernetSegmentRoute) rd() RouteDistinguisherInterface { return er.RD } func NewEVPNEthernetSegmentRoute(rd RouteDistinguisherInterface, esi EthernetSegmentIdentifier, ipAddress string) *EVPNNLRI { ipLen := uint8(32) ip := net.ParseIP(ipAddress) if ipv4 := ip.To4(); ipv4 != nil { ip = ipv4 } else { ipLen = 128 } return NewEVPNNLRI(EVPN_ETHERNET_SEGMENT_ROUTE, &EVPNEthernetSegmentRoute{ RD: rd, ESI: esi, IPAddressLength: ipLen, IPAddress: ip, }) } type EVPNIPPrefixRoute struct { RD RouteDistinguisherInterface ESI EthernetSegmentIdentifier ETag uint32 IPPrefixLength uint8 IPPrefix net.IP GWIPAddress net.IP Label uint32 } func (er *EVPNIPPrefixRoute) Len() int { if er.IPPrefix.To4() != nil { return 34 } return 58 } func (er *EVPNIPPrefixRoute) DecodeFromBytes(data []byte) error { addrLen := net.IPv4len switch len(data) { case 34: // RD(8) + ESI(10) + ETag(4) + IPPrefixLength(1) + IPv4 Prefix(4) + GW IPv4(4) + Label(3) case 58: // RD(8) + ESI(10) + ETag(4) + IPPrefixLength(1) + IPv6 Prefix(16) + GW IPv6(16) + Label(3) addrLen = net.IPv6len default: return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all EVPN IP Prefix Route bytes available") } er.RD = GetRouteDistinguisher(data[0:8]) err := er.ESI.DecodeFromBytes(data[8:18]) if err != nil { return err } er.ETag = binary.BigEndian.Uint32(data[18:22]) er.IPPrefixLength = data[22] offset := 23 // RD(8) + ESI(10) + ETag(4) + IPPrefixLength(1) er.IPPrefix = data[offset : offset+addrLen] offset += addrLen er.GWIPAddress = data[offset : offset+addrLen] offset += addrLen if er.Label, err = labelDecode(data[offset : offset+3]); err != nil { return err } //offset += 3 return nil } func (er *EVPNIPPrefixRoute) Serialize() ([]byte, error) { buf := make([]byte, 23) // RD(8) + ESI(10) + ETag(4) + IPPrefixLength(1) if er.RD != nil { tbuf, err := er.RD.Serialize() if err != nil { return nil, err } copy(buf[0:8], tbuf) } tbuf, err := er.ESI.Serialize() if err != nil { return nil, err } copy(buf[8:18], tbuf) binary.BigEndian.PutUint32(buf[18:22], er.ETag) buf[22] = er.IPPrefixLength if er.IPPrefix == nil { return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "IP Prefix is nil") } else if er.IPPrefix.To4() != nil { buf = append(buf, er.IPPrefix.To4()...) if er.GWIPAddress == nil { // draft-ietf-bess-evpn-prefix-advertisement: IP Prefix Advertisement in EVPN // The GW IP field SHOULD be zero if it is not used as an Overlay Index. er.GWIPAddress = net.IPv4zero } buf = append(buf, er.GWIPAddress.To4()...) } else { buf = append(buf, er.IPPrefix.To16()...) if er.GWIPAddress == nil { er.GWIPAddress = net.IPv6zero } buf = append(buf, er.GWIPAddress.To16()...) } tbuf, err = labelSerialize(er.Label) if err != nil { return nil, err } buf = append(buf, tbuf...) return buf, nil } func (er *EVPNIPPrefixRoute) String() string { // draft-ietf-bess-evpn-prefix-advertisement: IP Prefix Advertisement in EVPN // 3.1 IP Prefix Route Encoding // The RD, Eth-Tag ID, IP Prefix Length and IP Prefix will be part of // the route key used by BGP to compare routes. The rest of the fields // will not be part of the route key. return fmt.Sprintf("[type:Prefix][rd:%s][etag:%d][prefix:%s/%d]", er.RD, er.ETag, er.IPPrefix, er.IPPrefixLength) } func (er *EVPNIPPrefixRoute) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RD RouteDistinguisherInterface `json:"rd"` ESI string `json:"esi"` Etag uint32 `json:"etag"` Prefix string `json:"prefix"` Gateway string `json:"gateway"` Label uint32 `json:"label"` }{ RD: er.RD, ESI: er.ESI.String(), Etag: er.ETag, Prefix: fmt.Sprintf("%s/%d", er.IPPrefix, er.IPPrefixLength), Gateway: er.GWIPAddress.String(), Label: er.Label, }) } func (er *EVPNIPPrefixRoute) rd() RouteDistinguisherInterface { return er.RD } func NewEVPNIPPrefixRoute(rd RouteDistinguisherInterface, esi EthernetSegmentIdentifier, etag uint32, ipPrefixLength uint8, ipPrefix string, gateway string, label uint32) *EVPNNLRI { ip := net.ParseIP(ipPrefix) gw := net.ParseIP(gateway) if ipv4 := ip.To4(); ipv4 != nil { ip = ipv4 gw = gw.To4() } return NewEVPNNLRI(EVPN_IP_PREFIX, &EVPNIPPrefixRoute{ RD: rd, ESI: esi, ETag: etag, IPPrefixLength: ipPrefixLength, IPPrefix: ip, GWIPAddress: gw, Label: label, }) } type EVPNIPMSIRoute struct { RD RouteDistinguisherInterface ETag uint32 EC ExtendedCommunityInterface } func (er *EVPNIPMSIRoute) Len() int { // RD(8) + ETag(4) + EC(8) return 20 } func (er *EVPNIPMSIRoute) DecodeFromBytes(data []byte) error { er.RD = GetRouteDistinguisher(data[0:8]) data = data[er.RD.Len():] er.ETag = binary.BigEndian.Uint32(data[0:4]) data = data[4:] ec, err := ParseExtended(data[0:8]) if err != nil { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Parse extended community interface failed") } er.EC = ec return nil } func (er *EVPNIPMSIRoute) Serialize() ([]byte, error) { buf := make([]byte, 20) if er.RD != nil { tbuf, err := er.RD.Serialize() if err != nil { return nil, err } copy(buf[0:8], tbuf) } binary.BigEndian.PutUint32(buf[8:12], er.ETag) ec, err := er.EC.Serialize() if err != nil { return nil, err } return append(buf, ec...), nil } func (er *EVPNIPMSIRoute) String() string { ec := "default" if er.EC != nil { ec = er.EC.String() } return fmt.Sprintf("[type:I-PMSI][rd:%s][etag:%d][EC:%s]", er.RD, er.ETag, ec) } func (er *EVPNIPMSIRoute) MarshalJSON() ([]byte, error) { return json.Marshal(struct { RD RouteDistinguisherInterface `json:"rd"` ETag uint32 `json:"etag"` EC string `json:"ec"` }{ RD: er.RD, ETag: er.ETag, EC: er.EC.String(), }) } func (er *EVPNIPMSIRoute) rd() RouteDistinguisherInterface { return er.RD } func NewEVPNIPMSIRoute(rd RouteDistinguisherInterface, etag uint32, ec ExtendedCommunityInterface) *EVPNNLRI { return NewEVPNNLRI(EVPN_I_PMSI, &EVPNIPMSIRoute{ RD: rd, ETag: etag, EC: ec, }) } type EVPNRouteTypeInterface interface { Len() int DecodeFromBytes([]byte) error Serialize() ([]byte, error) String() string rd() RouteDistinguisherInterface MarshalJSON() ([]byte, error) } func getEVPNRouteType(t uint8) (EVPNRouteTypeInterface, error) { switch t { case EVPN_ROUTE_TYPE_ETHERNET_AUTO_DISCOVERY: return &EVPNEthernetAutoDiscoveryRoute{}, nil case EVPN_ROUTE_TYPE_MAC_IP_ADVERTISEMENT: return &EVPNMacIPAdvertisementRoute{}, nil case EVPN_INCLUSIVE_MULTICAST_ETHERNET_TAG: return &EVPNMulticastEthernetTagRoute{}, nil case EVPN_ETHERNET_SEGMENT_ROUTE: return &EVPNEthernetSegmentRoute{}, nil case EVPN_IP_PREFIX: return &EVPNIPPrefixRoute{}, nil } return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Unknown EVPN Route type: %d", t)) } const ( EVPN_ROUTE_TYPE_ETHERNET_AUTO_DISCOVERY = 1 EVPN_ROUTE_TYPE_MAC_IP_ADVERTISEMENT = 2 EVPN_INCLUSIVE_MULTICAST_ETHERNET_TAG = 3 EVPN_ETHERNET_SEGMENT_ROUTE = 4 EVPN_IP_PREFIX = 5 EVPN_I_PMSI = 9 ) type EVPNNLRI struct { PrefixDefault RouteType uint8 Length uint8 RouteTypeData EVPNRouteTypeInterface } func (n *EVPNNLRI) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { if IsAddPathEnabled(true, RF_EVPN, options) { var err error data, err = n.decodePathIdentifier(data) if err != nil { return err } } if len(data) < 2 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all EVPNNLRI bytes available") } n.RouteType = data[0] n.Length = data[1] data = data[2:] if len(data) < int(n.Length) { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all EVPNNLRI Route type bytes available") } r, err := getEVPNRouteType(n.RouteType) if err != nil { return err } n.RouteTypeData = r return n.RouteTypeData.DecodeFromBytes(data[:n.Length]) } func (n *EVPNNLRI) Serialize(options ...*MarshallingOption) ([]byte, error) { var buf []byte if IsAddPathEnabled(false, RF_EVPN, options) { var err error buf, err = n.serializeIdentifier() if err != nil { return nil, err } } offset := len(buf) buf = append(buf, make([]byte, 2)...) buf[offset] = n.RouteType tbuf, err := n.RouteTypeData.Serialize() buf[offset+1] = n.Length if err != nil { return nil, err } return append(buf, tbuf...), nil } func (n *EVPNNLRI) AFI() uint16 { return AFI_L2VPN } func (n *EVPNNLRI) SAFI() uint8 { return SAFI_EVPN } func (n *EVPNNLRI) Len(options ...*MarshallingOption) int { return int(n.Length) + 2 } func (n *EVPNNLRI) String() string { if n.RouteTypeData != nil { return n.RouteTypeData.String() } return fmt.Sprintf("%d:%d", n.RouteType, n.Length) } func (n *EVPNNLRI) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type uint8 `json:"type"` Value EVPNRouteTypeInterface `json:"value"` }{ Type: n.RouteType, Value: n.RouteTypeData, }) } func (n *EVPNNLRI) RD() RouteDistinguisherInterface { return n.RouteTypeData.rd() } func NewEVPNNLRI(routeType uint8, routeTypeData EVPNRouteTypeInterface) *EVPNNLRI { var l uint8 if routeTypeData != nil { l = uint8(routeTypeData.Len()) } return &EVPNNLRI{ RouteType: routeType, Length: l, RouteTypeData: routeTypeData, } } type EncapNLRI struct { IPAddrPrefixDefault addrlen uint8 } func (n *EncapNLRI) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { if n.addrlen == 0 { n.addrlen = 4 } f := RF_IPv4_ENCAP if n.addrlen == 16 { f = RF_IPv6_ENCAP } if IsAddPathEnabled(true, f, options) { var err error data, err = n.decodePathIdentifier(data) if err != nil { return err } } if len(data) < 4 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) return NewMessageError(eCode, eSubCode, nil, "prefix misses length field") } n.Length = data[0] if n.addrlen == 0 { n.addrlen = 4 } return n.decodePrefix(data[1:], n.Length, n.addrlen) } func (n *EncapNLRI) Serialize(options ...*MarshallingOption) ([]byte, error) { var buf []byte f := RF_IPv4_ENCAP if n.addrlen == 16 { f = RF_IPv6_ENCAP } if IsAddPathEnabled(false, f, options) { var err error buf, err = n.serializeIdentifier() if err != nil { return nil, err } } if n.Prefix.To4() != nil { buf = append(buf, net.IPv4len*8) n.Prefix = n.Prefix.To4() } else { buf = append(buf, net.IPv6len*8) } n.Length = buf[len(buf)-1] pbuf, err := n.serializePrefix(n.Length) if err != nil { return nil, err } return append(buf, pbuf...), nil } func (n *EncapNLRI) String() string { return n.Prefix.String() } func (n *EncapNLRI) AFI() uint16 { return AFI_IP } func (n *EncapNLRI) SAFI() uint8 { return SAFI_ENCAPSULATION } func (n *EncapNLRI) Len(options ...*MarshallingOption) int { return 1 + len(n.Prefix) } func NewEncapNLRI(endpoint string) *EncapNLRI { return &EncapNLRI{ IPAddrPrefixDefault{Length: 32, Prefix: net.ParseIP(endpoint).To4()}, 4, } } type Encapv6NLRI struct { EncapNLRI } func (n *Encapv6NLRI) AFI() uint16 { return AFI_IP6 } func NewEncapv6NLRI(endpoint string) *Encapv6NLRI { return &Encapv6NLRI{ EncapNLRI{ IPAddrPrefixDefault{Length: 128, Prefix: net.ParseIP(endpoint)}, 16, }, } } type BGPFlowSpecType uint8 const ( FLOW_SPEC_TYPE_UNKNOWN BGPFlowSpecType = iota FLOW_SPEC_TYPE_DST_PREFIX FLOW_SPEC_TYPE_SRC_PREFIX FLOW_SPEC_TYPE_IP_PROTO FLOW_SPEC_TYPE_PORT FLOW_SPEC_TYPE_DST_PORT FLOW_SPEC_TYPE_SRC_PORT FLOW_SPEC_TYPE_ICMP_TYPE FLOW_SPEC_TYPE_ICMP_CODE FLOW_SPEC_TYPE_TCP_FLAG FLOW_SPEC_TYPE_PKT_LEN FLOW_SPEC_TYPE_DSCP FLOW_SPEC_TYPE_FRAGMENT FLOW_SPEC_TYPE_LABEL FLOW_SPEC_TYPE_ETHERNET_TYPE // 14 FLOW_SPEC_TYPE_SRC_MAC FLOW_SPEC_TYPE_DST_MAC FLOW_SPEC_TYPE_LLC_DSAP FLOW_SPEC_TYPE_LLC_SSAP FLOW_SPEC_TYPE_LLC_CONTROL FLOW_SPEC_TYPE_SNAP FLOW_SPEC_TYPE_VID FLOW_SPEC_TYPE_COS FLOW_SPEC_TYPE_INNER_VID FLOW_SPEC_TYPE_INNER_COS ) var FlowSpecNameMap = map[BGPFlowSpecType]string{ FLOW_SPEC_TYPE_UNKNOWN: "unknown", FLOW_SPEC_TYPE_DST_PREFIX: "destination", FLOW_SPEC_TYPE_SRC_PREFIX: "source", FLOW_SPEC_TYPE_IP_PROTO: "protocol", FLOW_SPEC_TYPE_PORT: "port", FLOW_SPEC_TYPE_DST_PORT: "destination-port", FLOW_SPEC_TYPE_SRC_PORT: "source-port", FLOW_SPEC_TYPE_ICMP_TYPE: "icmp-type", FLOW_SPEC_TYPE_ICMP_CODE: "icmp-code", FLOW_SPEC_TYPE_TCP_FLAG: "tcp-flags", FLOW_SPEC_TYPE_PKT_LEN: "packet-length", FLOW_SPEC_TYPE_DSCP: "dscp", FLOW_SPEC_TYPE_FRAGMENT: "fragment", FLOW_SPEC_TYPE_LABEL: "label", FLOW_SPEC_TYPE_ETHERNET_TYPE: "ether-type", FLOW_SPEC_TYPE_SRC_MAC: "source-mac", FLOW_SPEC_TYPE_DST_MAC: "destination-mac", FLOW_SPEC_TYPE_LLC_DSAP: "llc-dsap", FLOW_SPEC_TYPE_LLC_SSAP: "llc-ssap", FLOW_SPEC_TYPE_LLC_CONTROL: "llc-control", FLOW_SPEC_TYPE_SNAP: "snap", FLOW_SPEC_TYPE_VID: "vid", FLOW_SPEC_TYPE_COS: "cos", FLOW_SPEC_TYPE_INNER_VID: "inner-vid", FLOW_SPEC_TYPE_INNER_COS: "inner-cos", } var FlowSpecValueMap = map[string]BGPFlowSpecType{ FlowSpecNameMap[FLOW_SPEC_TYPE_DST_PREFIX]: FLOW_SPEC_TYPE_DST_PREFIX, FlowSpecNameMap[FLOW_SPEC_TYPE_SRC_PREFIX]: FLOW_SPEC_TYPE_SRC_PREFIX, FlowSpecNameMap[FLOW_SPEC_TYPE_IP_PROTO]: FLOW_SPEC_TYPE_IP_PROTO, FlowSpecNameMap[FLOW_SPEC_TYPE_PORT]: FLOW_SPEC_TYPE_PORT, FlowSpecNameMap[FLOW_SPEC_TYPE_DST_PORT]: FLOW_SPEC_TYPE_DST_PORT, FlowSpecNameMap[FLOW_SPEC_TYPE_SRC_PORT]: FLOW_SPEC_TYPE_SRC_PORT, FlowSpecNameMap[FLOW_SPEC_TYPE_ICMP_TYPE]: FLOW_SPEC_TYPE_ICMP_TYPE, FlowSpecNameMap[FLOW_SPEC_TYPE_ICMP_CODE]: FLOW_SPEC_TYPE_ICMP_CODE, FlowSpecNameMap[FLOW_SPEC_TYPE_TCP_FLAG]: FLOW_SPEC_TYPE_TCP_FLAG, FlowSpecNameMap[FLOW_SPEC_TYPE_PKT_LEN]: FLOW_SPEC_TYPE_PKT_LEN, FlowSpecNameMap[FLOW_SPEC_TYPE_DSCP]: FLOW_SPEC_TYPE_DSCP, FlowSpecNameMap[FLOW_SPEC_TYPE_FRAGMENT]: FLOW_SPEC_TYPE_FRAGMENT, FlowSpecNameMap[FLOW_SPEC_TYPE_LABEL]: FLOW_SPEC_TYPE_LABEL, FlowSpecNameMap[FLOW_SPEC_TYPE_ETHERNET_TYPE]: FLOW_SPEC_TYPE_ETHERNET_TYPE, FlowSpecNameMap[FLOW_SPEC_TYPE_SRC_MAC]: FLOW_SPEC_TYPE_SRC_MAC, FlowSpecNameMap[FLOW_SPEC_TYPE_DST_MAC]: FLOW_SPEC_TYPE_DST_MAC, FlowSpecNameMap[FLOW_SPEC_TYPE_LLC_DSAP]: FLOW_SPEC_TYPE_LLC_DSAP, FlowSpecNameMap[FLOW_SPEC_TYPE_LLC_SSAP]: FLOW_SPEC_TYPE_LLC_SSAP, FlowSpecNameMap[FLOW_SPEC_TYPE_LLC_CONTROL]: FLOW_SPEC_TYPE_LLC_CONTROL, FlowSpecNameMap[FLOW_SPEC_TYPE_SNAP]: FLOW_SPEC_TYPE_SNAP, FlowSpecNameMap[FLOW_SPEC_TYPE_VID]: FLOW_SPEC_TYPE_VID, FlowSpecNameMap[FLOW_SPEC_TYPE_COS]: FLOW_SPEC_TYPE_COS, FlowSpecNameMap[FLOW_SPEC_TYPE_INNER_VID]: FLOW_SPEC_TYPE_INNER_VID, FlowSpecNameMap[FLOW_SPEC_TYPE_INNER_COS]: FLOW_SPEC_TYPE_INNER_COS, } // Joins the given and args into a single string and normalize it. // Example: // args := []string{" & <=80", " tcp != udp ", " =! SA & =U! F", " = is-fragment+last-fragment"} // fmt.Printf("%q", normalizeFlowSpecOpValues(args)) // >>> ["<=80" "tcp" "!=udp" "=!SA" "&=U" "!F" "=is-fragment+last-fragment"] func normalizeFlowSpecOpValues(args []string) []string { // Extracts keywords from the given args. sub := "" subs := make([]string, 0) for _, s := range _regexpFlowSpecOperator.FindAllString(strings.Join(args, " "), -1) { sub += s if _regexpFlowSpecOperatorValue.MatchString(s) { subs = append(subs, sub) sub = "" } } // RFC5575 says "It should be unset in the first operator byte of a // sequence". if len(subs) > 0 { subs[0] = strings.TrimPrefix(subs[0], "&") } return subs } // Parses the FlowSpec numeric operator using the given submatch which should be // the return value of func (*Regexp) FindStringSubmatch. func parseFlowSpecNumericOperator(submatch []string) (operator uint8, err error) { if submatch[1] == "&" { operator = DEC_NUM_OP_AND } value, ok := DECNumOpValueMap[submatch[2]] if !ok { return 0, fmt.Errorf("invalid numeric operator: %s%s", submatch[1], submatch[2]) } operator |= uint8(value) return operator, nil } // Parses the pairs of operator and value for the FlowSpec numeric type. The // given validationFunc is applied to evaluate whether the parsed value is // valid or not (e.g., if exceeds range or not). // Note: Each of the args should be formatted in single pair of operator and // value before calling this function. // e.g.) "&==100", ">=200" or "&<300" func parseFlowSpecNumericOpValues(typ BGPFlowSpecType, args []string, validationFunc func(uint64) error) (FlowSpecComponentInterface, error) { argsLen := len(args) items := make([]*FlowSpecComponentItem, 0, argsLen) for idx, arg := range args { m := _regexpFlowSpecNumericType.FindStringSubmatch(arg) if len(m) < 4 { return nil, fmt.Errorf("invalid argument for %s: %s in %q", typ.String(), arg, args) } operator, err := parseFlowSpecNumericOperator(m) if err != nil { return nil, err } // "true" and "false" is operator, but here handles them as value. var value uint64 switch m[3] { case "true", "false": if idx != argsLen-1 { return nil, fmt.Errorf("%s should be the last of each rule", m[3]) } operator = uint8(DECNumOpValueMap[m[3]]) default: if value, err = strconv.ParseUint(m[3], 10, 64); err != nil { return nil, fmt.Errorf("invalid numeric value: %s", m[3]) } if err = validationFunc(value); err != nil { return nil, err } } items = append(items, NewFlowSpecComponentItem(operator, value)) } // Marks end-of-list bit items[argsLen-1].Op |= uint8(DEC_NUM_OP_END) return NewFlowSpecComponent(typ, items), nil } func flowSpecNumeric1ByteParser(_ RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { args = normalizeFlowSpecOpValues(args) f := func(i uint64) error { if i <= 0xff { // 1 byte return nil } return fmt.Errorf("%s range exceeded", typ.String()) } return parseFlowSpecNumericOpValues(typ, args, f) } func flowSpecNumeric2BytesParser(_ RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { args = normalizeFlowSpecOpValues(args) f := func(i uint64) error { if i <= 0xffff { // 2 bytes return nil } return fmt.Errorf("%s range exceeded", typ.String()) } return parseFlowSpecNumericOpValues(typ, args, f) } // Parses the FlowSpec bitmask operand using the given submatch which should be // the return value of func (*Regexp) FindStringSubmatch. func parseFlowSpecBitmaskOperand(submatch []string) (operand uint8, err error) { if submatch[1] == "&" { operand = BITMASK_FLAG_OP_AND } value, ok := BitmaskFlagOpValueMap[submatch[2]] if !ok { return 0, fmt.Errorf("invalid bitmask operand: %s%s", submatch[1], submatch[2]) } operand |= uint8(value) return operand, nil } func flowSpecPrefixParser(rf RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { // args[0]: IP Prefix or IP Address (suppose prefix length is 32) // args[1]: Offset in bit (IPv6 only) // // Example: // - IPv4 Prefix // args := []string{"192.168.0.0/24"} // - IPv4 Address // args := []string{"192.168.0.1"} // - IPv6 Prefix // args := []string{"2001:db8:1::/64"} // - IPv6 Prefix with offset // args := []string{"0:db8:1::/64/16"} // args := []string{"0:db8:1::/64", "16"} // - IPv6 Address // args := []string{"2001:db8:1::1"} // - IPv6 Address with offset // args := []string{"0:db8:1::1", "16"} afi, _ := RouteFamilyToAfiSafi(rf) switch afi { case AFI_IP: if len(args) > 1 { return nil, errors.New("cannot specify offset for ipv4 prefix") } invalidIPv4PrefixError := fmt.Errorf("invalid ipv4 prefix: %s", args[0]) m := _regexpFindIPv4Prefix.FindStringSubmatch(args[0]) if len(m) < 4 { return nil, invalidIPv4PrefixError } prefix := net.ParseIP(m[1]) if prefix.To4() == nil { return nil, invalidIPv4PrefixError } var prefixLen uint64 = 32 if m[3] != "" { var err error prefixLen, err = strconv.ParseUint(m[3], 10, 8) if err != nil || prefixLen > 32 { return nil, invalidIPv4PrefixError } } switch typ { case FLOW_SPEC_TYPE_DST_PREFIX: return NewFlowSpecDestinationPrefix(NewIPAddrPrefix(uint8(prefixLen), prefix.String())), nil case FLOW_SPEC_TYPE_SRC_PREFIX: return NewFlowSpecSourcePrefix(NewIPAddrPrefix(uint8(prefixLen), prefix.String())), nil } return nil, fmt.Errorf("invalid traffic filtering rule type: %s", typ.String()) case AFI_IP6: if len(args) > 2 { return nil, fmt.Errorf("invalid arguments for ipv6 prefix: %q", args) } invalidIPv6PrefixError := fmt.Errorf("invalid ipv6 prefix: %s", args[0]) m := _regexpFindIPv6Prefix.FindStringSubmatch(args[0]) if len(m) < 4 { return nil, invalidIPv6PrefixError } prefix := net.ParseIP(m[1]) if prefix.To16() == nil { return nil, invalidIPv6PrefixError } var prefixLen uint64 = 128 if m[3] != "" { var err error prefixLen, err = strconv.ParseUint(m[3], 10, 8) if err != nil || prefixLen > 128 { return nil, invalidIPv6PrefixError } } var offset uint64 if len(args) == 1 && m[5] != "" { var err error offset, err = strconv.ParseUint(m[5], 10, 8) if err != nil || offset > 128 { return nil, fmt.Errorf("invalid ipv6 prefix offset: %s", m[5]) } } else if len(args) == 2 { if m[5] != "" { return nil, fmt.Errorf("multiple ipv6 prefix offset arguments detected: %q", args) } var err error offset, err = strconv.ParseUint(args[1], 10, 8) if err != nil || offset > 128 { return nil, fmt.Errorf("invalid ipv6 prefix offset: %s", args[1]) } } switch typ { case FLOW_SPEC_TYPE_DST_PREFIX: return NewFlowSpecDestinationPrefix6(NewIPv6AddrPrefix(uint8(prefixLen), prefix.String()), uint8(offset)), nil case FLOW_SPEC_TYPE_SRC_PREFIX: return NewFlowSpecSourcePrefix6(NewIPv6AddrPrefix(uint8(prefixLen), prefix.String()), uint8(offset)), nil } return nil, fmt.Errorf("invalid traffic filtering rule type: %s", typ.String()) } return nil, fmt.Errorf("invalid address family: %s", rf.String()) } func flowSpecIpProtoParser(_ RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { // args: List of pairs of Operator and IP protocol type // // Example: // - TCP or UDP // args := []string{"tcp", "==udp"} // - Not TCP and not UDP // args := []string{"!=tcp", "&!=udp"} args = normalizeFlowSpecOpValues(args) s := strings.Join(args, " ") for i, name := range ProtocolNameMap { s = strings.Replace(s, name, fmt.Sprintf("%d", i), -1) } args = strings.Split(s, " ") f := func(i uint64) error { if i <= 0xff { // 1 byte return nil } return fmt.Errorf("%s range exceeded", typ.String()) } return parseFlowSpecNumericOpValues(typ, args, f) } func flowSpecTcpFlagParser(_ RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { // args: List of pairs of Operand and TCP Flags // // Example: // - SYN or SYN/ACK // args := []string{"==S", "==SA"} // - Not FIN and not URG // args := []string{"!=F", "&!=U"} args = normalizeFlowSpecOpValues(args) argsLen := len(args) items := make([]*FlowSpecComponentItem, 0, argsLen) for _, arg := range args { m := _regexpFlowSpecTCPFlag.FindStringSubmatch(arg) if len(m) < 6 { return nil, fmt.Errorf("invalid argument for %s: %s in %q", typ.String(), arg, args) } else if mLast := m[len(m)-1]; mLast != "" || m[3] != "" { return nil, fmt.Errorf("invalid argument for %s: %s in %q", typ.String(), arg, args) } operand, err := parseFlowSpecBitmaskOperand(m) if err != nil { return nil, err } var value uint64 for flag, name := range TCPFlagNameMap { if strings.Contains(m[4], name) { value |= uint64(flag) } } items = append(items, NewFlowSpecComponentItem(operand, value)) } // Marks end-of-list bit items[argsLen-1].Op |= BITMASK_FLAG_OP_END return NewFlowSpecComponent(typ, items), nil } func flowSpecDscpParser(_ RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { args = normalizeFlowSpecOpValues(args) f := func(i uint64) error { if i < 64 { // 6 bits return nil } return fmt.Errorf("%s range exceeded", typ.String()) } return parseFlowSpecNumericOpValues(typ, args, f) } func flowSpecFragmentParser(_ RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { // args: List of pairs of Operator and Fragment flags // // Example: // - is-fragment or last-fragment // args := []string{"==is-fragment", "==last-fragment"} // - is-fragment and last-fragment (exact match) // args := []string{"==is-fragment+last-fragment"} args = normalizeFlowSpecOpValues(args) argsLen := len(args) items := make([]*FlowSpecComponentItem, 0, argsLen) for _, arg := range args { m := _regexpFlowSpecFragment.FindStringSubmatch(arg) if len(m) < 4 { return nil, fmt.Errorf("invalid argument for %s: %s in %q", typ.String(), arg, args) } else if mLast := m[len(m)-1]; mLast != "" { return nil, fmt.Errorf("invalid argument for %s: %s in %q", typ.String(), arg, args) } operand, err := parseFlowSpecBitmaskOperand(m) if err != nil { return nil, err } var value uint64 // Example: // m[3] = "first-fragment+last-fragment" for flag, name := range FragmentFlagNameMap { if strings.Contains(m[3], name) { value |= uint64(flag) } } items = append(items, NewFlowSpecComponentItem(operand, value)) } // Marks end-of-list bit items[argsLen-1].Op |= BITMASK_FLAG_OP_END return NewFlowSpecComponent(typ, items), nil } func flowSpecLabelParser(rf RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { afi, _ := RouteFamilyToAfiSafi(rf) if afi == AFI_IP { return nil, fmt.Errorf("%s is not supported for ipv4", typ.String()) } args = normalizeFlowSpecOpValues(args) f := func(i uint64) error { if i <= 0xfffff { // 20 bits return nil } return errors.New("flow label range exceeded") } return parseFlowSpecNumericOpValues(typ, args, f) } func flowSpecEtherTypeParser(rf RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { // args: List of pairs of Operator and Ether Types // // Example: // - ARP or IPv4 // args := []string{"==arp", "==ipv4"} // - Not IPv4 and not IPv6 // args := []string{"!=ipv4", "&!=ipv6"} if rf != RF_FS_L2_VPN { return nil, fmt.Errorf("%s is supported for only l2vpn", typ.String()) } args = normalizeFlowSpecOpValues(args) s := strings.Join(args, " ") for i, name := range EthernetTypeNameMap { s = strings.Replace(s, name, fmt.Sprintf("%d", i), -1) } args = strings.Split(s, " ") f := func(i uint64) error { if i <= 0xffff { // 2 bytes return nil } return fmt.Errorf("%s range exceeded", typ.String()) } return parseFlowSpecNumericOpValues(typ, args, f) } func flowSpecMacParser(rf RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { // args[0]: MAC address if rf != RF_FS_L2_VPN { return nil, fmt.Errorf("%s is supported for only l2vpn", typ.String()) } mac, err := net.ParseMAC(args[0]) if err != nil { return nil, fmt.Errorf("invalid mac address: %s", args[0]) } switch typ { case FLOW_SPEC_TYPE_DST_MAC: return NewFlowSpecDestinationMac(mac), nil case FLOW_SPEC_TYPE_SRC_MAC: return NewFlowSpecSourceMac(mac), nil } return nil, fmt.Errorf("invalid traffic filtering rule type: %s", typ.String()) } func flowSpecLlcParser(rf RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { if rf != RF_FS_L2_VPN { return nil, fmt.Errorf("%s is supported for only l2vpn", typ.String()) } return flowSpecNumeric1ByteParser(rf, typ, args) } func flowSpecSnapParser(rf RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { if rf != RF_FS_L2_VPN { return nil, fmt.Errorf("%s is supported for only l2vpn", typ.String()) } args = normalizeFlowSpecOpValues(args) f := func(i uint64) error { if i <= 0xffffffffff { // 5 bytes return nil } return fmt.Errorf("%s range exceeded", typ.String()) } return parseFlowSpecNumericOpValues(typ, args, f) } func flowSpecVlanIDParser(rf RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { if rf != RF_FS_L2_VPN { return nil, fmt.Errorf("%s is supported for only l2vpn", typ.String()) } args = normalizeFlowSpecOpValues(args) s := strings.Join(args, " ") for i, name := range EthernetTypeNameMap { s = strings.Replace(s, name, fmt.Sprintf("%d", i), -1) } args = strings.Split(s, " ") f := func(i uint64) error { if i <= 4095 { // 12 bits return nil } return fmt.Errorf("%s range exceeded", typ.String()) } return parseFlowSpecNumericOpValues(typ, args, f) } func flowSpecVlanCosParser(rf RouteFamily, typ BGPFlowSpecType, args []string) (FlowSpecComponentInterface, error) { if rf != RF_FS_L2_VPN { return nil, fmt.Errorf("%s is supported for only l2vpn", typ.String()) } args = normalizeFlowSpecOpValues(args) s := strings.Join(args, " ") for i, name := range EthernetTypeNameMap { s = strings.Replace(s, name, fmt.Sprintf("%d", i), -1) } args = strings.Split(s, " ") f := func(i uint64) error { if i <= 7 { // 3 bits return nil } return fmt.Errorf("%s range exceeded", typ.String()) } return parseFlowSpecNumericOpValues(typ, args, f) } var flowSpecParserMap = map[BGPFlowSpecType]func(RouteFamily, BGPFlowSpecType, []string) (FlowSpecComponentInterface, error){ FLOW_SPEC_TYPE_DST_PREFIX: flowSpecPrefixParser, FLOW_SPEC_TYPE_SRC_PREFIX: flowSpecPrefixParser, FLOW_SPEC_TYPE_IP_PROTO: flowSpecIpProtoParser, FLOW_SPEC_TYPE_PORT: flowSpecNumeric2BytesParser, FLOW_SPEC_TYPE_DST_PORT: flowSpecNumeric2BytesParser, FLOW_SPEC_TYPE_SRC_PORT: flowSpecNumeric2BytesParser, FLOW_SPEC_TYPE_ICMP_TYPE: flowSpecNumeric1ByteParser, FLOW_SPEC_TYPE_ICMP_CODE: flowSpecNumeric1ByteParser, FLOW_SPEC_TYPE_TCP_FLAG: flowSpecTcpFlagParser, FLOW_SPEC_TYPE_PKT_LEN: flowSpecNumeric2BytesParser, FLOW_SPEC_TYPE_DSCP: flowSpecDscpParser, FLOW_SPEC_TYPE_FRAGMENT: flowSpecFragmentParser, FLOW_SPEC_TYPE_LABEL: flowSpecLabelParser, FLOW_SPEC_TYPE_ETHERNET_TYPE: flowSpecEtherTypeParser, FLOW_SPEC_TYPE_DST_MAC: flowSpecMacParser, FLOW_SPEC_TYPE_SRC_MAC: flowSpecMacParser, FLOW_SPEC_TYPE_LLC_DSAP: flowSpecLlcParser, FLOW_SPEC_TYPE_LLC_SSAP: flowSpecLlcParser, FLOW_SPEC_TYPE_LLC_CONTROL: flowSpecLlcParser, FLOW_SPEC_TYPE_SNAP: flowSpecSnapParser, FLOW_SPEC_TYPE_VID: flowSpecVlanIDParser, FLOW_SPEC_TYPE_COS: flowSpecVlanCosParser, FLOW_SPEC_TYPE_INNER_VID: flowSpecVlanIDParser, FLOW_SPEC_TYPE_INNER_COS: flowSpecVlanCosParser, } func extractFlowSpecArgs(args []string) map[BGPFlowSpecType][]string { m := make(map[BGPFlowSpecType][]string, len(FlowSpecValueMap)) var typ BGPFlowSpecType for _, arg := range args { if t, ok := FlowSpecValueMap[arg]; ok { typ = t m[typ] = make([]string, 0) } else { m[typ] = append(m[typ], arg) } } return m } func ParseFlowSpecComponents(rf RouteFamily, arg string) ([]FlowSpecComponentInterface, error) { _, safi := RouteFamilyToAfiSafi(rf) switch safi { case SAFI_FLOW_SPEC_UNICAST, SAFI_FLOW_SPEC_VPN: // Valid default: return nil, fmt.Errorf("invalid address family: %s", rf.String()) } typeArgs := extractFlowSpecArgs(strings.Split(arg, " ")) rules := make([]FlowSpecComponentInterface, 0, len(typeArgs)) for typ, args := range typeArgs { parser, ok := flowSpecParserMap[typ] if !ok { return nil, fmt.Errorf("unsupported traffic filtering rule type: %s", typ.String()) } if len(args) == 0 { return nil, fmt.Errorf("specify traffic filtering rules for %s", typ.String()) } rule, err := parser(rf, typ, args) if err != nil { return nil, err } rules = append(rules, rule) } return rules, nil } func (t BGPFlowSpecType) String() string { name, ok := FlowSpecNameMap[t] if !ok { return fmt.Sprintf("%s(%d)", FlowSpecNameMap[FLOW_SPEC_TYPE_UNKNOWN], t) } return name } type FlowSpecComponentInterface interface { DecodeFromBytes([]byte, ...*MarshallingOption) error Serialize(...*MarshallingOption) ([]byte, error) Len(...*MarshallingOption) int Type() BGPFlowSpecType String() string } type flowSpecPrefix struct { Prefix AddrPrefixInterface typ BGPFlowSpecType } func (p *flowSpecPrefix) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { p.typ = BGPFlowSpecType(data[0]) return p.Prefix.DecodeFromBytes(data[1:], options...) } func (p *flowSpecPrefix) Serialize(options ...*MarshallingOption) ([]byte, error) { bbuf, err := p.Prefix.Serialize(options...) if err != nil { return nil, err } buf := make([]byte, 1+len(bbuf)) buf[0] = byte(p.Type()) copy(buf[1:], bbuf) return buf, nil } func (p *flowSpecPrefix) Len(options ...*MarshallingOption) int { buf, _ := p.Serialize(options...) return len(buf) } func (p *flowSpecPrefix) Type() BGPFlowSpecType { return p.typ } func (p *flowSpecPrefix) String() string { return fmt.Sprintf("[%s: %s]", p.Type(), p.Prefix.String()) } func (p *flowSpecPrefix) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPFlowSpecType `json:"type"` Value AddrPrefixInterface `json:"value"` }{ Type: p.Type(), Value: p.Prefix, }) } type flowSpecPrefix6 struct { Prefix AddrPrefixInterface Offset uint8 typ BGPFlowSpecType } // draft-ietf-idr-flow-spec-v6-06 // func (p *flowSpecPrefix6) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { p.typ = BGPFlowSpecType(data[0]) p.Offset = data[2] prefix := append([]byte{data[1]}, data[3:]...) return p.Prefix.DecodeFromBytes(prefix, options...) } func (p *flowSpecPrefix6) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := []byte{byte(p.Type())} bbuf, err := p.Prefix.Serialize(options...) if err != nil { return nil, err } buf = append(buf, bbuf[0]) buf = append(buf, p.Offset) return append(buf, bbuf[1:]...), nil } func (p *flowSpecPrefix6) Len(options ...*MarshallingOption) int { buf, _ := p.Serialize(options...) return len(buf) } func (p *flowSpecPrefix6) Type() BGPFlowSpecType { return p.typ } func (p *flowSpecPrefix6) String() string { return fmt.Sprintf("[%s: %s/%d]", p.Type(), p.Prefix.String(), p.Offset) } func (p *flowSpecPrefix6) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPFlowSpecType `json:"type"` Value AddrPrefixInterface `json:"value"` Offset uint8 `json:"offset"` }{ Type: p.Type(), Value: p.Prefix, Offset: p.Offset, }) } type FlowSpecDestinationPrefix struct { flowSpecPrefix } func NewFlowSpecDestinationPrefix(prefix AddrPrefixInterface) *FlowSpecDestinationPrefix { return &FlowSpecDestinationPrefix{flowSpecPrefix{prefix, FLOW_SPEC_TYPE_DST_PREFIX}} } type FlowSpecSourcePrefix struct { flowSpecPrefix } func NewFlowSpecSourcePrefix(prefix AddrPrefixInterface) *FlowSpecSourcePrefix { return &FlowSpecSourcePrefix{flowSpecPrefix{prefix, FLOW_SPEC_TYPE_SRC_PREFIX}} } type FlowSpecDestinationPrefix6 struct { flowSpecPrefix6 } func NewFlowSpecDestinationPrefix6(prefix AddrPrefixInterface, offset uint8) *FlowSpecDestinationPrefix6 { return &FlowSpecDestinationPrefix6{flowSpecPrefix6{prefix, offset, FLOW_SPEC_TYPE_DST_PREFIX}} } type FlowSpecSourcePrefix6 struct { flowSpecPrefix6 } func NewFlowSpecSourcePrefix6(prefix AddrPrefixInterface, offset uint8) *FlowSpecSourcePrefix6 { return &FlowSpecSourcePrefix6{flowSpecPrefix6{prefix, offset, FLOW_SPEC_TYPE_SRC_PREFIX}} } type flowSpecMac struct { Mac net.HardwareAddr typ BGPFlowSpecType } func (p *flowSpecMac) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { if len(data) < 2 || len(data) < 2+int(data[1]) { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "not all mac bits available") } p.typ = BGPFlowSpecType(data[0]) p.Mac = net.HardwareAddr(data[2 : 2+int(data[1])]) return nil } func (p *flowSpecMac) Serialize(options ...*MarshallingOption) ([]byte, error) { if len(p.Mac) == 0 { return nil, errors.New("mac unset") } buf := make([]byte, 2+len(p.Mac)) buf[0] = byte(p.Type()) buf[1] = byte(len(p.Mac)) copy(buf[2:], p.Mac) return buf, nil } func (p *flowSpecMac) Len(options ...*MarshallingOption) int { return 2 + len(p.Mac) } func (p *flowSpecMac) Type() BGPFlowSpecType { return p.typ } func (p *flowSpecMac) String() string { return fmt.Sprintf("[%s: %s]", p.Type(), p.Mac.String()) } func (p *flowSpecMac) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPFlowSpecType `json:"type"` Value string `json:"value"` }{ Type: p.Type(), Value: p.Mac.String(), }) } type FlowSpecSourceMac struct { flowSpecMac } func NewFlowSpecSourceMac(mac net.HardwareAddr) *FlowSpecSourceMac { return &FlowSpecSourceMac{flowSpecMac{Mac: mac, typ: FLOW_SPEC_TYPE_SRC_MAC}} } type FlowSpecDestinationMac struct { flowSpecMac } func NewFlowSpecDestinationMac(mac net.HardwareAddr) *FlowSpecDestinationMac { return &FlowSpecDestinationMac{flowSpecMac{Mac: mac, typ: FLOW_SPEC_TYPE_DST_MAC}} } type FlowSpecComponentItem struct { Op uint8 `json:"op"` Value uint64 `json:"value"` } func (v *FlowSpecComponentItem) Len() int { return 1 << ((uint32(v.Op) >> 4) & 0x3) } func (v *FlowSpecComponentItem) Serialize() ([]byte, error) { order := uint32(math.Log2(float64(v.Len()))) buf := make([]byte, 1+(1< 3 { return nil } v.Op = uint8(uint32(v.Op) | order<<4) return v } type FlowSpecComponent struct { Items []*FlowSpecComponentItem typ BGPFlowSpecType } func (p *FlowSpecComponent) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { p.typ = BGPFlowSpecType(data[0]) data = data[1:] p.Items = make([]*FlowSpecComponentItem, 0) for { if len(data) < 2 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "not all flowspec component bytes available") } op := data[0] end := op & 0x80 l := 1 << ((op >> 4) & 0x3) // (min, max) = (1, 8) v := make([]byte, 8) copy(v[8-l:], data[1:1+l]) i := binary.BigEndian.Uint64(v) item := &FlowSpecComponentItem{op, i} p.Items = append(p.Items, item) if end > 0 { break } data = data[1+l:] } return nil } func (p *FlowSpecComponent) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := []byte{byte(p.Type())} for _, v := range p.Items { bbuf, err := v.Serialize() if err != nil { return nil, err } buf = append(buf, bbuf...) } return buf, nil } func (p *FlowSpecComponent) Len(options ...*MarshallingOption) int { l := 1 for _, item := range p.Items { l += item.Len() + 1 } return l } func (p *FlowSpecComponent) Type() BGPFlowSpecType { return p.typ } func formatRaw(op uint8, value uint64) string { return fmt.Sprintf("op:%b,value:%d", op, value) } func formatNumeric(op uint8, value uint64) string { cmpFlag := DECNumOp(op & 0x7) // lower 3 bits if cmpFlag == DEC_NUM_OP_TRUE || cmpFlag == DEC_NUM_OP_FALSE { // Omit value field return DECNumOp(op).String() } return DECNumOp(op).String() + strconv.FormatUint(value, 10) } func formatProto(op uint8, value uint64) string { cmpFlag := DECNumOp(op & 0x7) // lower 3 bits if cmpFlag == DEC_NUM_OP_TRUE || cmpFlag == DEC_NUM_OP_FALSE { // Omit value field return DECNumOp(op).String() } return DECNumOp(op).String() + Protocol(value).String() } func formatTCPFlag(op uint8, value uint64) string { return BitmaskFlagOp(op).String() + TCPFlag(value).String() } func formatFragment(op uint8, value uint64) string { return BitmaskFlagOp(op).String() + FragmentFlag(value).String() } func formatEtherType(op uint8, value uint64) string { cmpFlag := DECNumOp(op & 0x7) // lower 3 bits if cmpFlag == DEC_NUM_OP_TRUE || cmpFlag == DEC_NUM_OP_FALSE { // Omit value field return DECNumOp(op).String() } return DECNumOp(op).String() + EthernetType(value).String() } var flowSpecFormatMap = map[BGPFlowSpecType]func(op uint8, value uint64) string{ FLOW_SPEC_TYPE_UNKNOWN: formatRaw, FLOW_SPEC_TYPE_IP_PROTO: formatProto, FLOW_SPEC_TYPE_PORT: formatNumeric, FLOW_SPEC_TYPE_DST_PORT: formatNumeric, FLOW_SPEC_TYPE_SRC_PORT: formatNumeric, FLOW_SPEC_TYPE_ICMP_TYPE: formatNumeric, FLOW_SPEC_TYPE_ICMP_CODE: formatNumeric, FLOW_SPEC_TYPE_TCP_FLAG: formatTCPFlag, FLOW_SPEC_TYPE_PKT_LEN: formatNumeric, FLOW_SPEC_TYPE_DSCP: formatNumeric, FLOW_SPEC_TYPE_FRAGMENT: formatFragment, FLOW_SPEC_TYPE_LABEL: formatNumeric, FLOW_SPEC_TYPE_ETHERNET_TYPE: formatEtherType, FLOW_SPEC_TYPE_LLC_DSAP: formatNumeric, FLOW_SPEC_TYPE_LLC_SSAP: formatNumeric, FLOW_SPEC_TYPE_LLC_CONTROL: formatNumeric, FLOW_SPEC_TYPE_SNAP: formatNumeric, FLOW_SPEC_TYPE_VID: formatNumeric, FLOW_SPEC_TYPE_COS: formatNumeric, FLOW_SPEC_TYPE_INNER_VID: formatNumeric, FLOW_SPEC_TYPE_INNER_COS: formatNumeric, } func (p *FlowSpecComponent) String() string { f := flowSpecFormatMap[FLOW_SPEC_TYPE_UNKNOWN] if _, ok := flowSpecFormatMap[p.typ]; ok { f = flowSpecFormatMap[p.typ] } items := make([]string, 0, len(p.Items)) for _, i := range p.Items { items = append(items, f(i.Op, i.Value)) } // Removes leading and tailing spaces value := strings.TrimSpace(strings.Join(items, "")) return fmt.Sprintf("[%s: %s]", p.typ, value) } func (p *FlowSpecComponent) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPFlowSpecType `json:"type"` Value []*FlowSpecComponentItem `json:"value"` }{ Type: p.Type(), Value: p.Items, }) } func NewFlowSpecComponent(typ BGPFlowSpecType, items []*FlowSpecComponentItem) *FlowSpecComponent { // Set end-of-list bit on the last item and unset them on the others. for i, v := range items { if i == len(items)-1 { v.Op |= 0x80 } else { v.Op &^= 0x80 } } return &FlowSpecComponent{ Items: items, typ: typ, } } type FlowSpecUnknown struct { Value []byte } func (p *FlowSpecUnknown) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { p.Value = data return nil } func (p *FlowSpecUnknown) Serialize(options ...*MarshallingOption) ([]byte, error) { return p.Value, nil } func (p *FlowSpecUnknown) Len(options ...*MarshallingOption) int { return len(p.Value) } func (p *FlowSpecUnknown) Type() BGPFlowSpecType { if len(p.Value) > 0 { return BGPFlowSpecType(p.Value[0]) } return FLOW_SPEC_TYPE_UNKNOWN } func (p *FlowSpecUnknown) String() string { return fmt.Sprintf("[unknown:%v]", p.Value) } func (p *FlowSpecUnknown) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPFlowSpecType `json:"type"` Value string `json:"value"` }{ Type: p.Type(), Value: string(p.Value), }) } type FlowSpecNLRI struct { PrefixDefault Value []FlowSpecComponentInterface rf RouteFamily rd RouteDistinguisherInterface } func (n *FlowSpecNLRI) AFI() uint16 { afi, _ := RouteFamilyToAfiSafi(n.rf) return afi } func (n *FlowSpecNLRI) SAFI() uint8 { _, safi := RouteFamilyToAfiSafi(n.rf) return safi } func (n *FlowSpecNLRI) RD() RouteDistinguisherInterface { return n.rd } func (n *FlowSpecNLRI) decodeFromBytes(rf RouteFamily, data []byte, options ...*MarshallingOption) error { if IsAddPathEnabled(true, rf, options) { var err error data, err = n.decodePathIdentifier(data) if err != nil { return err } } var length int if (data[0]>>4) == 0xf && len(data) > 2 { length = int(binary.BigEndian.Uint16(data[0:2])) data = data[2:] } else if len(data) > 1 { length = int(data[0]) data = data[1:] } else { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "not all flowspec component bytes available") } if len(data) < length { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "not all flowspec component bytes available") } n.rf = rf if n.SAFI() == SAFI_FLOW_SPEC_VPN { if length < 8 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "not all flowspec component bytes available") } n.rd = GetRouteDistinguisher(data[:8]) data = data[8:] length -= 8 } for l := length; l > 0; { if len(data) == 0 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "not all flowspec component bytes available") } t := BGPFlowSpecType(data[0]) var i FlowSpecComponentInterface switch t { case FLOW_SPEC_TYPE_DST_PREFIX: switch { case rf>>16 == AFI_IP: i = NewFlowSpecDestinationPrefix(NewIPAddrPrefix(0, "")) case rf>>16 == AFI_IP6: i = NewFlowSpecDestinationPrefix6(NewIPv6AddrPrefix(0, ""), 0) default: return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Invalid address family: %v", rf)) } case FLOW_SPEC_TYPE_SRC_PREFIX: switch { case rf>>16 == AFI_IP: i = NewFlowSpecSourcePrefix(NewIPAddrPrefix(0, "")) case rf>>16 == AFI_IP6: i = NewFlowSpecSourcePrefix6(NewIPv6AddrPrefix(0, ""), 0) default: return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Invalid address family: %v", rf)) } case FLOW_SPEC_TYPE_SRC_MAC: switch rf { case RF_FS_L2_VPN: i = NewFlowSpecSourceMac(nil) default: return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Invalid address family: %v", rf)) } case FLOW_SPEC_TYPE_DST_MAC: switch rf { case RF_FS_L2_VPN: i = NewFlowSpecDestinationMac(nil) default: return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("Invalid address family: %v", rf)) } case FLOW_SPEC_TYPE_IP_PROTO, FLOW_SPEC_TYPE_PORT, FLOW_SPEC_TYPE_DST_PORT, FLOW_SPEC_TYPE_SRC_PORT, FLOW_SPEC_TYPE_ICMP_TYPE, FLOW_SPEC_TYPE_ICMP_CODE, FLOW_SPEC_TYPE_TCP_FLAG, FLOW_SPEC_TYPE_PKT_LEN, FLOW_SPEC_TYPE_DSCP, FLOW_SPEC_TYPE_FRAGMENT, FLOW_SPEC_TYPE_LABEL, FLOW_SPEC_TYPE_ETHERNET_TYPE, FLOW_SPEC_TYPE_LLC_DSAP, FLOW_SPEC_TYPE_LLC_SSAP, FLOW_SPEC_TYPE_LLC_CONTROL, FLOW_SPEC_TYPE_SNAP, FLOW_SPEC_TYPE_VID, FLOW_SPEC_TYPE_COS, FLOW_SPEC_TYPE_INNER_VID, FLOW_SPEC_TYPE_INNER_COS: i = NewFlowSpecComponent(t, nil) default: i = &FlowSpecUnknown{} } err := i.DecodeFromBytes(data, options...) if err != nil { i = &FlowSpecUnknown{data} } l -= i.Len(options...) data = data[i.Len(options...):] n.Value = append(n.Value, i) } // Sort Traffic Filtering Rules in types order to avoid the unordered rules // are determined different. sort.SliceStable(n.Value, func(i, j int) bool { return n.Value[i].Type() < n.Value[j].Type() }) return nil } func (n *FlowSpecNLRI) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 0, 32) if n.SAFI() == SAFI_FLOW_SPEC_VPN { if n.rd == nil { return nil, errors.New("RD is nil") } b, err := n.rd.Serialize() if err != nil { return nil, err } buf = append(buf, b...) } for _, v := range n.Value { b, err := v.Serialize(options...) if err != nil { return nil, err } buf = append(buf, b...) } length := n.Len(options...) if length > 0xfff { return nil, fmt.Errorf("too large: %d", length) } else if length < 0xf0 { length -= 1 buf = append([]byte{byte(length)}, buf...) } else { length -= 2 b := make([]byte, 2) binary.BigEndian.PutUint16(buf, uint16(length)) buf = append(b, buf...) } if IsAddPathEnabled(false, n.rf, options) { id, err := n.serializeIdentifier() if err != nil { return nil, err } return append(id, buf...), nil } return buf, nil } func (n *FlowSpecNLRI) Len(options ...*MarshallingOption) int { l := 0 if n.SAFI() == SAFI_FLOW_SPEC_VPN { l += n.RD().Len() } for _, v := range n.Value { l += v.Len(options...) } if l < 0xf0 { return l + 1 } else { return l + 2 } } func (n *FlowSpecNLRI) String() string { buf := bytes.NewBuffer(make([]byte, 0, 32)) if n.SAFI() == SAFI_FLOW_SPEC_VPN { buf.WriteString(fmt.Sprintf("[rd: %s]", n.rd)) } for _, v := range n.Value { buf.WriteString(v.String()) } return buf.String() } func (n *FlowSpecNLRI) MarshalJSON() ([]byte, error) { if n.rd != nil { return json.Marshal(struct { RD RouteDistinguisherInterface `json:"rd"` Value []FlowSpecComponentInterface `json:"value"` }{ RD: n.rd, Value: n.Value, }) } return json.Marshal(struct { Value []FlowSpecComponentInterface `json:"value"` }{ Value: n.Value, }) } // // CompareFlowSpecNLRI(n, m) returns // -1 when m has precedence // 0 when n and m have same precedence // 1 when n has precedence // func CompareFlowSpecNLRI(n, m *FlowSpecNLRI) (int, error) { family := AfiSafiToRouteFamily(n.AFI(), n.SAFI()) if family != AfiSafiToRouteFamily(m.AFI(), m.SAFI()) { return 0, errors.New("address family mismatch") } longer := n.Value shorter := m.Value invert := 1 if n.SAFI() == SAFI_FLOW_SPEC_VPN { k, _ := n.Serialize() l, _ := m.Serialize() if result := bytes.Compare(k, l); result != 0 { return result, nil } } if len(n.Value) < len(m.Value) { longer = m.Value shorter = n.Value invert = -1 } for idx, v := range longer { if len(shorter) < idx+1 { return invert, nil } w := shorter[idx] if v.Type() < w.Type() { return invert, nil } else if v.Type() > w.Type() { return invert * -1, nil } else if v.Type() == FLOW_SPEC_TYPE_DST_PREFIX || v.Type() == FLOW_SPEC_TYPE_SRC_PREFIX { // RFC5575 5.1 // // For IP prefix values (IP destination and source prefix) precedence is // given to the lowest IP value of the common prefix length; if the // common prefix is equal, then the most specific prefix has precedence. var p, q *IPAddrPrefixDefault var pCommon, qCommon uint64 if n.AFI() == AFI_IP { if v.Type() == FLOW_SPEC_TYPE_DST_PREFIX { p = &v.(*FlowSpecDestinationPrefix).Prefix.(*IPAddrPrefix).IPAddrPrefixDefault q = &w.(*FlowSpecDestinationPrefix).Prefix.(*IPAddrPrefix).IPAddrPrefixDefault } else { p = &v.(*FlowSpecSourcePrefix).Prefix.(*IPAddrPrefix).IPAddrPrefixDefault q = &w.(*FlowSpecSourcePrefix).Prefix.(*IPAddrPrefix).IPAddrPrefixDefault } min := p.Length if q.Length < p.Length { min = q.Length } pCommon = uint64(binary.BigEndian.Uint32([]byte(p.Prefix.To4())) >> (32 - min)) qCommon = uint64(binary.BigEndian.Uint32([]byte(q.Prefix.To4())) >> (32 - min)) } else if n.AFI() == AFI_IP6 { if v.Type() == FLOW_SPEC_TYPE_DST_PREFIX { p = &v.(*FlowSpecDestinationPrefix6).Prefix.(*IPv6AddrPrefix).IPAddrPrefixDefault q = &w.(*FlowSpecDestinationPrefix6).Prefix.(*IPv6AddrPrefix).IPAddrPrefixDefault } else { p = &v.(*FlowSpecSourcePrefix6).Prefix.(*IPv6AddrPrefix).IPAddrPrefixDefault q = &w.(*FlowSpecSourcePrefix6).Prefix.(*IPv6AddrPrefix).IPAddrPrefixDefault } min := uint(p.Length) if q.Length < p.Length { min = uint(q.Length) } var mask uint if min-64 > 0 { mask = min - 64 } pCommon = binary.BigEndian.Uint64([]byte(p.Prefix.To16()[:8])) >> mask qCommon = binary.BigEndian.Uint64([]byte(q.Prefix.To16()[:8])) >> mask if pCommon == qCommon && mask == 0 { mask = 64 - min pCommon = binary.BigEndian.Uint64([]byte(p.Prefix.To16()[8:])) >> mask qCommon = binary.BigEndian.Uint64([]byte(q.Prefix.To16()[8:])) >> mask } } if pCommon < qCommon { return invert, nil } else if pCommon > qCommon { return invert * -1, nil } else if p.Length > q.Length { return invert, nil } else if p.Length < q.Length { return invert * -1, nil } } else { // RFC5575 5.1 // // For all other component types, unless otherwise specified, the // comparison is performed by comparing the component data as a binary // string using the memcmp() function as defined by the ISO C standard. // For strings of different lengths, the common prefix is compared. If // equal, the longest string is considered to have higher precedence // than the shorter one. p, _ := v.Serialize() q, _ := w.Serialize() min := len(p) if len(q) < len(p) { min = len(q) } if result := bytes.Compare(p[:min], q[:min]); result < 0 { return invert, nil } else if result > 0 { return invert * -1, nil } else if len(p) > len(q) { return invert, nil } else if len(q) > len(p) { return invert * -1, nil } } } return 0, nil } type FlowSpecIPv4Unicast struct { FlowSpecNLRI } func (n *FlowSpecIPv4Unicast) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { return n.decodeFromBytes(AfiSafiToRouteFamily(n.AFI(), n.SAFI()), data, options...) } func NewFlowSpecIPv4Unicast(value []FlowSpecComponentInterface) *FlowSpecIPv4Unicast { sort.SliceStable(value, func(i, j int) bool { return value[i].Type() < value[j].Type() }) return &FlowSpecIPv4Unicast{ FlowSpecNLRI: FlowSpecNLRI{ Value: value, rf: RF_FS_IPv4_UC, }, } } type FlowSpecIPv4VPN struct { FlowSpecNLRI } func (n *FlowSpecIPv4VPN) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { return n.decodeFromBytes(AfiSafiToRouteFamily(n.AFI(), n.SAFI()), data, options...) } func NewFlowSpecIPv4VPN(rd RouteDistinguisherInterface, value []FlowSpecComponentInterface) *FlowSpecIPv4VPN { sort.SliceStable(value, func(i, j int) bool { return value[i].Type() < value[j].Type() }) return &FlowSpecIPv4VPN{ FlowSpecNLRI: FlowSpecNLRI{ Value: value, rf: RF_FS_IPv4_VPN, rd: rd, }, } } type FlowSpecIPv6Unicast struct { FlowSpecNLRI } func (n *FlowSpecIPv6Unicast) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { return n.decodeFromBytes(AfiSafiToRouteFamily(n.AFI(), n.SAFI()), data, options...) } func NewFlowSpecIPv6Unicast(value []FlowSpecComponentInterface) *FlowSpecIPv6Unicast { sort.SliceStable(value, func(i, j int) bool { return value[i].Type() < value[j].Type() }) return &FlowSpecIPv6Unicast{ FlowSpecNLRI: FlowSpecNLRI{ Value: value, rf: RF_FS_IPv6_UC, }, } } type FlowSpecIPv6VPN struct { FlowSpecNLRI } func (n *FlowSpecIPv6VPN) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { return n.decodeFromBytes(AfiSafiToRouteFamily(n.AFI(), n.SAFI()), data, options...) } func NewFlowSpecIPv6VPN(rd RouteDistinguisherInterface, value []FlowSpecComponentInterface) *FlowSpecIPv6VPN { sort.SliceStable(value, func(i, j int) bool { return value[i].Type() < value[j].Type() }) return &FlowSpecIPv6VPN{ FlowSpecNLRI: FlowSpecNLRI{ Value: value, rf: RF_FS_IPv6_VPN, rd: rd, }, } } type FlowSpecL2VPN struct { FlowSpecNLRI } func (n *FlowSpecL2VPN) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { return n.decodeFromBytes(AfiSafiToRouteFamily(n.AFI(), n.SAFI()), data) } func NewFlowSpecL2VPN(rd RouteDistinguisherInterface, value []FlowSpecComponentInterface) *FlowSpecL2VPN { sort.SliceStable(value, func(i, j int) bool { return value[i].Type() < value[j].Type() }) return &FlowSpecL2VPN{ FlowSpecNLRI: FlowSpecNLRI{ Value: value, rf: RF_FS_L2_VPN, rd: rd, }, } } type OpaqueNLRI struct { PrefixDefault Length uint16 Key []byte Value []byte } func (n *OpaqueNLRI) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { if len(data) < 2 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all OpaqueNLRI bytes available") } if IsAddPathEnabled(true, RF_OPAQUE, options) { var err error data, err = n.decodePathIdentifier(data) if err != nil { return err } } n.Length = binary.BigEndian.Uint16(data[0:2]) if len(data)-2 < int(n.Length) { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all OpaqueNLRI bytes available") } n.Key = data[2 : 2+n.Length] n.Value = data[2+n.Length:] return nil } func (n *OpaqueNLRI) Serialize(options ...*MarshallingOption) ([]byte, error) { keyLen := len(n.Key) if keyLen > math.MaxUint16 { return nil, errors.New("key length too big") } buf := make([]byte, 2, 2+keyLen+len(n.Value)) binary.BigEndian.PutUint16(buf[:2], uint16(keyLen)) buf = append(buf, n.Key...) buf = append(buf, n.Value...) if IsAddPathEnabled(false, RF_OPAQUE, options) { id, err := n.serializeIdentifier() if err != nil { return nil, err } return append(id, buf...), nil } return buf, nil } func (n *OpaqueNLRI) AFI() uint16 { return AFI_OPAQUE } func (n *OpaqueNLRI) SAFI() uint8 { return SAFI_KEY_VALUE } func (n *OpaqueNLRI) Len(options ...*MarshallingOption) int { return 2 + len(n.Key) + len(n.Value) } func (n *OpaqueNLRI) String() string { return string(n.Key) } func (n *OpaqueNLRI) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Key string `json:"key"` Value string `json:"value"` }{ Key: string(n.Key), Value: string(n.Value), }) } func NewOpaqueNLRI(key, value []byte) *OpaqueNLRI { return &OpaqueNLRI{ Key: key, Value: value, } } type LsNLRIType uint16 const ( LS_NLRI_TYPE_UNKNOWN LsNLRIType = iota LS_NLRI_TYPE_NODE LS_NLRI_TYPE_LINK LS_NLRI_TYPE_PREFIX_IPV4 LS_NLRI_TYPE_PREFIX_IPV6 ) type LsNLRIInterface interface { DecodeFromBytes([]byte) error Serialize() ([]byte, error) Len() int Type() LsNLRIType String() string } type LsProtocolID uint8 const ( LS_PROTOCOL_UNKNOWN = iota LS_PROTOCOL_ISIS_L1 LS_PROTOCOL_ISIS_L2 LS_PROTOCOL_OSPF_V2 LS_PROTOCOL_DIRECT LS_PROTOCOL_STATIC LS_PROTOCOL_OSPF_V3 ) func (l LsProtocolID) String() string { switch l { case LS_PROTOCOL_ISIS_L1: return "ISIS-L1" case LS_PROTOCOL_ISIS_L2: return "ISIS-L2" case LS_PROTOCOL_OSPF_V2: return "OSPFv2" case LS_PROTOCOL_DIRECT: return "DIRECT" case LS_PROTOCOL_STATIC: return "STATIC" case LS_PROTOCOL_OSPF_V3: return "OSPFv3" default: return fmt.Sprintf("LsProtocolID(%d)", uint8(l)) } } type LsNLRI struct { NLRIType LsNLRIType Length uint16 ProtocolID LsProtocolID Identifier uint64 } const lsNLRIHdrLen = 9 func (l *LsNLRI) DecodeFromBytes(data []byte) error { if len(data) < lsNLRIHdrLen { return malformedAttrListErr("Malformed NLRI") } l.ProtocolID = LsProtocolID(data[0]) l.Identifier = binary.BigEndian.Uint64(data[1:lsNLRIHdrLen]) return nil } func (l *LsNLRI) Serialize(value []byte) ([]byte, error) { buf := make([]byte, lsNLRIHdrLen) buf[0] = uint8(l.ProtocolID) binary.BigEndian.PutUint64(buf[1:], l.Identifier) buf = append(buf, value...) return buf, nil } func (l *LsNLRI) Len() int { return int(l.Length) } func (l *LsNLRI) Type() LsNLRIType { return l.NLRIType } type LsNodeNLRI struct { LsNLRI LocalNodeDesc LsTLVInterface } func (l *LsNodeNLRI) DecodeFromBytes(data []byte) error { if err := l.LsNLRI.DecodeFromBytes(data); err != nil { return nil } tlv := data[lsNLRIHdrLen:] if len(tlv) < tlvHdrLen { return malformedAttrListErr("Malformed Node NLRI") } tlvType := LsTLVType(binary.BigEndian.Uint16(tlv[:2])) if tlvType != LS_TLV_LOCAL_NODE_DESC { return malformedAttrListErr("Mandatory TLV missing") } l.LocalNodeDesc = &LsTLVNodeDescriptor{} if err := l.LocalNodeDesc.DecodeFromBytes(tlv); err != nil { return malformedAttrListErr(fmt.Sprintf("Malformed Node NLRI: %v", err)) } return nil } func (l *LsNodeNLRI) String() string { if l.LocalNodeDesc == nil { return "NODE { EMPTY }" } local := l.LocalNodeDesc.(*LsTLVNodeDescriptor).Extract() return fmt.Sprintf("NODE { AS:%v BGP-LS ID:%v %v %v:%v }", local.Asn, local.BGPLsID, local.IGPRouterID, l.ProtocolID.String(), l.Identifier) } func (l *LsNodeNLRI) Serialize() ([]byte, error) { if l.LocalNodeDesc == nil { return nil, errors.New("local node descriptor missing") } ser, err := l.LocalNodeDesc.Serialize() if err != nil { return nil, err } return l.LsNLRI.Serialize(ser) } func (l *LsNodeNLRI) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsNLRIType `json:"type"` LocalNode LsNodeDescriptor `json:"local_node_desc"` }{ Type: l.Type(), LocalNode: *l.LocalNodeDesc.(*LsTLVNodeDescriptor).Extract(), }) } type LsLinkDescriptor struct { LinkLocalID *uint32 LinkRemoteID *uint32 InterfaceAddrIPv4 *net.IP NeighborAddrIPv4 *net.IP InterfaceAddrIPv6 *net.IP NeighborAddrIPv6 *net.IP } func (l *LsLinkDescriptor) ParseTLVs(tlvs []LsTLVInterface) { for _, tlv := range tlvs { switch v := tlv.(type) { case *LsTLVLinkID: l.LinkLocalID = &v.Local l.LinkRemoteID = &v.Remote case *LsTLVIPv4InterfaceAddr: l.InterfaceAddrIPv4 = &v.IP case *LsTLVIPv4NeighborAddr: l.NeighborAddrIPv4 = &v.IP case *LsTLVIPv6InterfaceAddr: l.InterfaceAddrIPv6 = &v.IP case *LsTLVIPv6NeighborAddr: l.NeighborAddrIPv6 = &v.IP } } } func (l *LsLinkDescriptor) String() string { switch { case l.InterfaceAddrIPv4 != nil && l.NeighborAddrIPv4 != nil: return fmt.Sprintf("%v->%v", l.InterfaceAddrIPv4, l.NeighborAddrIPv4) case l.InterfaceAddrIPv6 != nil && l.NeighborAddrIPv6 != nil: return fmt.Sprintf("%v->%v", l.InterfaceAddrIPv6, l.NeighborAddrIPv6) case l.LinkLocalID != nil && l.LinkRemoteID != nil: return fmt.Sprintf("%v->%v", *l.LinkLocalID, *l.LinkRemoteID) case l.InterfaceAddrIPv4 != nil: return fmt.Sprintf("%v->UNKNOWN", l.InterfaceAddrIPv4) case l.NeighborAddrIPv4 != nil: return fmt.Sprintf("UNKNOWN->%v", l.NeighborAddrIPv4) case l.InterfaceAddrIPv6 != nil: return fmt.Sprintf("%v->UNKNOWN", l.InterfaceAddrIPv6) case l.NeighborAddrIPv6 != nil: return fmt.Sprintf("UNKNOWN->%v", l.NeighborAddrIPv6) case l.LinkLocalID != nil: return fmt.Sprintf("%v->UNKNOWN", *l.LinkLocalID) case l.LinkRemoteID != nil: return fmt.Sprintf("UNKNOWN->%v", *l.LinkRemoteID) default: return "UNKNOWN" } } type LsLinkNLRI struct { LsNLRI LocalNodeDesc LsTLVInterface RemoteNodeDesc LsTLVInterface LinkDesc []LsTLVInterface } func (l *LsLinkNLRI) String() string { if l.LocalNodeDesc == nil || l.RemoteNodeDesc == nil { return "LINK { EMPTY }" } local := l.LocalNodeDesc.(*LsTLVNodeDescriptor).Extract() remote := l.RemoteNodeDesc.(*LsTLVNodeDescriptor).Extract() link := &LsLinkDescriptor{} link.ParseTLVs(l.LinkDesc) return fmt.Sprintf("LINK { LOCAL_NODE: %v REMOTE_NODE: %v LINK: %v}", local.IGPRouterID, remote.IGPRouterID, link) } func (l *LsLinkNLRI) DecodeFromBytes(data []byte) error { if err := l.LsNLRI.DecodeFromBytes(data); err != nil { return nil } tlv := data[lsNLRIHdrLen:] m := make(map[LsTLVType]bool) for len(tlv) >= tlvHdrLen { sub := &LsTLV{} _, err := sub.DecodeFromBytes(tlv) if err != nil { return err } m[sub.Type] = true var subTLV LsTLVInterface switch sub.Type { case LS_TLV_LOCAL_NODE_DESC, LS_TLV_REMOTE_NODE_DESC: subTLV = &LsTLVNodeDescriptor{} case LS_TLV_LINK_ID: subTLV = &LsTLVLinkID{} case LS_TLV_IPV4_INTERFACE_ADDR: subTLV = &LsTLVIPv4InterfaceAddr{} case LS_TLV_IPV4_NEIGHBOR_ADDR: subTLV = &LsTLVIPv4NeighborAddr{} case LS_TLV_IPV6_INTERFACE_ADDR: subTLV = &LsTLVIPv6InterfaceAddr{} case LS_TLV_IPV6_NEIGHBOR_ADDR: subTLV = &LsTLVIPv6NeighborAddr{} default: tlv = tlv[sub.Len():] l.Length -= uint16(sub.Len()) continue } if err := subTLV.DecodeFromBytes(tlv); err != nil { return err } tlv = tlv[subTLV.Len():] switch sub.Type { case LS_TLV_LOCAL_NODE_DESC: l.LocalNodeDesc = subTLV case LS_TLV_REMOTE_NODE_DESC: l.RemoteNodeDesc = subTLV default: l.LinkDesc = append(l.LinkDesc, subTLV) } } required := []LsTLVType{LS_TLV_LOCAL_NODE_DESC, LS_TLV_REMOTE_NODE_DESC} for _, tlv := range required { if _, ok := m[tlv]; !ok { return malformedAttrListErr("Required TLV missing") } } return nil } func (l *LsLinkNLRI) Serialize() ([]byte, error) { if l.LocalNodeDesc == nil || l.RemoteNodeDesc == nil { return nil, errors.New("required TLV missing") } buf := make([]byte, 0) s, err := l.LocalNodeDesc.Serialize() if err != nil { return nil, err } buf = append(buf, s...) s, err = l.RemoteNodeDesc.Serialize() if err != nil { return nil, err } buf = append(buf, s...) for _, tlv := range l.LinkDesc { s, err := tlv.Serialize() if err != nil { return nil, err } buf = append(buf, s...) } return l.LsNLRI.Serialize(buf) } func (l *LsLinkNLRI) MarshalJSON() ([]byte, error) { linkDesc := &LsLinkDescriptor{} linkDesc.ParseTLVs(l.LinkDesc) return json.Marshal(struct { Type LsNLRIType `json:"type"` LocalNode LsNodeDescriptor `json:"local_node_desc"` RemoteNode LsNodeDescriptor `json:"remote_node_desc"` LinkDesc LsLinkDescriptor `json:"link_desc"` }{ Type: l.Type(), LocalNode: *l.LocalNodeDesc.(*LsTLVNodeDescriptor).Extract(), RemoteNode: *l.RemoteNodeDesc.(*LsTLVNodeDescriptor).Extract(), LinkDesc: *linkDesc, }) } type LsPrefixDescriptor struct { IPReachability []net.IPNet OSPFRouteType LsOspfRouteType } func (l *LsPrefixDescriptor) ParseTLVs(tlvs []LsTLVInterface, ipv6 bool) { for _, tlv := range tlvs { switch v := tlv.(type) { case *LsTLVIPReachability: l.IPReachability = append(l.IPReachability, v.ToIPNet(ipv6)) case *LsTLVOspfRouteType: l.OSPFRouteType = v.RouteType } } } type LsPrefixV4NLRI struct { LsNLRI LocalNodeDesc LsTLVInterface PrefixDesc []LsTLVInterface } func (l *LsPrefixV4NLRI) String() string { if l.LocalNodeDesc == nil { return "PREFIXv4 { EMPTY }" } local := l.LocalNodeDesc.(*LsTLVNodeDescriptor).Extract() prefix := &LsPrefixDescriptor{} prefix.ParseTLVs(l.PrefixDesc, false) ips := make([]string, len(prefix.IPReachability)) for i, ip := range prefix.IPReachability { ips[i] = ip.String() } ospf := "" if prefix.OSPFRouteType != LS_OSPF_ROUTE_TYPE_UNKNOWN { ospf = fmt.Sprintf("OSPF_ROUTE_TYPE:%v ", prefix.OSPFRouteType) } return fmt.Sprintf("PREFIXv4 { LOCAL_NODE: %s PREFIX: %v %s}", local.IGPRouterID, ips, ospf) } func (l *LsPrefixV4NLRI) DecodeFromBytes(data []byte) error { if err := l.LsNLRI.DecodeFromBytes(data); err != nil { return nil } tlv := data[lsNLRIHdrLen:] m := make(map[LsTLVType]bool) for len(tlv) >= tlvHdrLen { sub := &LsTLV{} _, err := sub.DecodeFromBytes(tlv) if err != nil { return err } m[sub.Type] = true var subTLV LsTLVInterface switch sub.Type { case LS_TLV_LOCAL_NODE_DESC: subTLV = &LsTLVNodeDescriptor{} case LS_TLV_OSPF_ROUTE_TYPE: subTLV = &LsTLVOspfRouteType{} case LS_TLV_IP_REACH_INFO: subTLV = &LsTLVIPReachability{} default: tlv = tlv[sub.Len():] l.Length -= uint16(sub.Len()) continue } if err := subTLV.DecodeFromBytes(tlv); err != nil { return err } tlv = tlv[subTLV.Len():] switch sub.Type { case LS_TLV_LOCAL_NODE_DESC: l.LocalNodeDesc = subTLV default: l.PrefixDesc = append(l.PrefixDesc, subTLV) } } required := []LsTLVType{LS_TLV_IP_REACH_INFO, LS_TLV_LOCAL_NODE_DESC} for _, tlv := range required { if _, ok := m[tlv]; !ok { return malformedAttrListErr("Required TLV missing") } } for _, tlv := range l.PrefixDesc { switch v := tlv.(type) { case *LsTLVIPReachability: if v.PrefixLength > 8*net.IPv4len { return malformedAttrListErr("Unexpected IP Reachability info") } } } return nil } func (l *LsPrefixV4NLRI) Serialize() ([]byte, error) { if l.LocalNodeDesc == nil { return nil, errors.New("required TLV missing") } buf := make([]byte, 0) s, err := l.LocalNodeDesc.Serialize() if err != nil { return nil, err } buf = append(buf, s...) for _, tlv := range l.PrefixDesc { s, err := tlv.Serialize() if err != nil { return nil, err } buf = append(buf, s...) } return l.LsNLRI.Serialize(buf) } func (l *LsPrefixV4NLRI) MarshalJSON() ([]byte, error) { prefixDesc := &LsPrefixDescriptor{} prefixDesc.ParseTLVs(l.PrefixDesc, false) return json.Marshal(struct { Type LsNLRIType `json:"type"` LocalNode LsNodeDescriptor `json:"local_node_desc"` PrefixDesc LsPrefixDescriptor `json:"prefix_desc"` }{ Type: l.Type(), LocalNode: *l.LocalNodeDesc.(*LsTLVNodeDescriptor).Extract(), PrefixDesc: *prefixDesc, }) } type LsPrefixV6NLRI struct { LsNLRI LocalNodeDesc LsTLVInterface PrefixDesc []LsTLVInterface } func (l *LsPrefixV6NLRI) String() string { if l.LocalNodeDesc == nil { return "PREFIXv6 { EMPTY }" } local := l.LocalNodeDesc.(*LsTLVNodeDescriptor).Extract() prefix := &LsPrefixDescriptor{} prefix.ParseTLVs(l.PrefixDesc, true) ips := []string{} for _, ip := range prefix.IPReachability { ips = append(ips, ip.String()) } ospf := "" if prefix.OSPFRouteType != LS_OSPF_ROUTE_TYPE_UNKNOWN { ospf = fmt.Sprintf("OSPF_ROUTE_TYPE:%v ", prefix.OSPFRouteType) } return fmt.Sprintf("PREFIXv6 { LOCAL_NODE: %v PREFIX: %v %v}", local.IGPRouterID, ips, ospf) } func (l *LsPrefixV6NLRI) DecodeFromBytes(data []byte) error { if err := l.LsNLRI.DecodeFromBytes(data); err != nil { return nil } tlv := data[lsNLRIHdrLen:] m := make(map[LsTLVType]bool) for len(tlv) >= tlvHdrLen { sub := &LsTLV{} _, err := sub.DecodeFromBytes(tlv) if err != nil { return err } m[sub.Type] = true var subTLV LsTLVInterface switch sub.Type { case LS_TLV_LOCAL_NODE_DESC: subTLV = &LsTLVNodeDescriptor{} case LS_TLV_OSPF_ROUTE_TYPE: subTLV = &LsTLVOspfRouteType{} case LS_TLV_IP_REACH_INFO: subTLV = &LsTLVIPReachability{} default: tlv = tlv[sub.Len():] l.Length -= uint16(sub.Len()) continue } if err := subTLV.DecodeFromBytes(tlv); err != nil { return err } tlv = tlv[subTLV.Len():] switch sub.Type { case LS_TLV_LOCAL_NODE_DESC: l.LocalNodeDesc = subTLV default: l.PrefixDesc = append(l.PrefixDesc, subTLV) } } required := []LsTLVType{LS_TLV_IP_REACH_INFO, LS_TLV_LOCAL_NODE_DESC} for _, tlv := range required { if _, ok := m[tlv]; !ok { return malformedAttrListErr("Required TLV missing") } } return nil } func (l *LsPrefixV6NLRI) Serialize() ([]byte, error) { if l.LocalNodeDesc == nil { return nil, errors.New("required TLV missing") } buf := make([]byte, 0) s, err := l.LocalNodeDesc.Serialize() if err != nil { return nil, err } buf = append(buf, s...) for _, tlv := range l.PrefixDesc { s, err := tlv.Serialize() if err != nil { return nil, err } buf = append(buf, s...) } return l.LsNLRI.Serialize(buf) } func (l *LsPrefixV6NLRI) MarshalJSON() ([]byte, error) { prefixDesc := &LsPrefixDescriptor{} prefixDesc.ParseTLVs(l.PrefixDesc, true) return json.Marshal(struct { Type LsNLRIType `json:"type"` LocalNode LsNodeDescriptor `json:"local_node_desc"` PrefixDesc LsPrefixDescriptor `json:"prefix_desc"` }{ Type: l.Type(), LocalNode: *l.LocalNodeDesc.(*LsTLVNodeDescriptor).Extract(), PrefixDesc: *prefixDesc, }) } type LsTLVType uint16 // Based on https://www.iana.org/assignments/bgp-ls-parameters/bgp-ls-parameters.xhtml const ( LS_TLV_UNKNOWN LsTLVType = iota LS_TLV_LOCAL_NODE_DESC = 256 LS_TLV_REMOTE_NODE_DESC = 257 LS_TLV_LINK_ID = 258 LS_TLV_IPV4_INTERFACE_ADDR = 259 LS_TLV_IPV4_NEIGHBOR_ADDR = 260 LS_TLV_IPV6_INTERFACE_ADDR = 261 LS_TLV_IPV6_NEIGHBOR_ADDR = 262 LS_TLV_MULTI_TOPO_ID = 263 LS_TLV_OSPF_ROUTE_TYPE = 264 LS_TLV_IP_REACH_INFO = 265 LS_TLV_AS = 512 LS_TLV_BGP_LS_ID = 513 LS_TLV_OSPF_AREA = 514 LS_TLV_IGP_ROUTER_ID = 515 LS_TLV_BGP_ROUTER_ID = 516 // draft-ietf-idr-bgpls-segment-routing-epe, TODO LS_TLV_BGP_CONFEDERATION_MEMBER = 517 // draft-ietf-idr-bgpls-segment-routing-epe, TODO LS_TLV_NODE_FLAG_BITS = 1024 LS_TLV_OPAQUE_NODE_ATTR = 1025 LS_TLV_NODE_NAME = 1026 LS_TLV_ISIS_AREA = 1027 LS_TLV_IPV4_LOCAL_ROUTER_ID = 1028 LS_TLV_IPV6_LOCAL_ROUTER_ID = 1029 LS_TLV_IPV4_REMOTE_ROUTER_ID = 1030 LS_TLV_IPV6_REMOTE_ROUTER_ID = 1031 LS_TLV_SR_CAPABILITIES = 1034 // draft-ietf-idr-bgp-ls-segment-routing-ext LS_TLV_SR_ALGORITHM = 1035 // draft-ietf-idr-bgp-ls-segment-routing-ext LS_TLV_SR_LOCAL_BLOCK = 1036 // draft-ietf-idr-bgp-ls-segment-routing-ext LS_TLV_SRMS_PREFERENCE = 1037 // draft-ietf-idr-bgp-ls-segment-routing-ext, TODO LS_TLV_ADMIN_GROUP = 1088 LS_TLV_MAX_LINK_BANDWIDTH = 1089 LS_TLV_MAX_RESERVABLE_BANDWIDTH = 1090 LS_TLV_UNRESERVED_BANDWIDTH = 1091 LS_TLV_TE_DEFAULT_METRIC = 1092 LS_TLV_LINK_PROTECTION_TYPE = 1093 // TODO LS_TLV_MPLS_PROTOCOL_MASK = 1094 // TODO LS_TLV_IGP_METRIC = 1095 LS_TLV_SRLG = 1096 LS_TLV_OPAQUE_LINK_ATTR = 1097 LS_TLV_LINK_NAME = 1098 LS_TLV_ADJACENCY_SID = 1099 // draft-ietf-idr-bgp-ls-segment-routing-ext LS_TLV_LAN_ADJACENCY_SID = 1100 // draft-ietf-idr-bgp-ls-segment-routing-ext, TODO LS_TLV_PEER_NODE_SID = 1101 // draft-ietf-idr-bgpls-segment-routing-epe, TODO LS_TLV_PEER_ADJACENCY_SID = 1102 // draft-ietf-idr-bgpls-segment-routing-epe, TODO LS_TLV_PEER_SET_SID = 1103 // draft-ietf-idr-bgpls-segment-routing-epe, TODO LS_TLV_RTM_CAPABILITY = 1105 // RFC8169, TODO LS_TLV_IGP_FLAGS = 1152 LS_TLV_IGP_ROUTE_TAG = 1153 // TODO LS_TLV_EXTENDED_ROUTE_TAG = 1154 // TODO LS_TLV_PREFIX_METRIC = 1155 // TODO LS_TLV_OSPF_FORWARDING_ADDR = 1156 // TODO LS_TLV_OPAQUE_PREFIX_ATTR = 1157 LS_TLV_PREFIX_SID = 1158 // draft-ietf-idr-bgp-ls-segment-routing-ext LS_TLV_RANGE = 1159 // draft-ietf-idr-bgp-ls-segment-routing-ext, TODO LS_TLV_SID_LABEL_TLV = 1161 // draft-ietf-idr-bgp-ls-segment-routing-ext LS_TLV_PREFIX_ATTRIBUTE_FLAGS = 1170 // draft-ietf-idr-bgp-ls-segment-routing-ext, TODO LS_TLV_SOURCE_ROUTER_ID = 1171 // draft-ietf-idr-bgp-ls-segment-routing-ext, TODO LS_TLV_L2_BUNDLE_MEMBER_TLV = 1172 // draft-ietf-idr-bgp-ls-segment-routing-ext, TODO ) type LsTLVInterface interface { Len() int DecodeFromBytes([]byte) error Serialize() ([]byte, error) String() string MarshalJSON() ([]byte, error) } type LsTLV struct { Type LsTLVType Length uint16 } func malformedAttrListErr(s string) error { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, s) } const tlvHdrLen = 4 func (l *LsTLV) Len() int { return int(l.Length) + tlvHdrLen } func (l *LsTLV) Serialize(value []byte) ([]byte, error) { if len(value) != int(l.Length) { return nil, malformedAttrListErr("serialization failed: LS TLV malformed") } buf := make([]byte, tlvHdrLen+len(value)) binary.BigEndian.PutUint16(buf[:2], uint16(l.Type)) binary.BigEndian.PutUint16(buf[2:4], uint16(l.Length)) copy(buf[4:], value) return buf, nil } func (l *LsTLV) DecodeFromBytes(data []byte) ([]byte, error) { if len(data) < tlvHdrLen { return nil, malformedAttrListErr("decoding failed: LS TLV malformed") } l.Type = LsTLVType(binary.BigEndian.Uint16(data[:2])) l.Length = binary.BigEndian.Uint16(data[2:4]) if len(data) < l.Len() { return nil, malformedAttrListErr("decoding failed: LS TLV malformed") } return data[tlvHdrLen:l.Len()], nil } type LsTLVLinkID struct { LsTLV Local uint32 Remote uint32 } func (l *LsTLVLinkID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_LINK_ID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5307#section-1.1 if len(value) != 8 { return malformedAttrListErr("Incorrect Link ID length") } l.Local = binary.BigEndian.Uint32(value[:4]) l.Remote = binary.BigEndian.Uint32(value[4:]) return nil } func (l *LsTLVLinkID) Serialize() ([]byte, error) { buf := make([]byte, 8) binary.BigEndian.PutUint32(buf[:4], l.Local) binary.BigEndian.PutUint32(buf[4:], l.Remote) return l.LsTLV.Serialize(buf) } func (l *LsTLVLinkID) String() string { return fmt.Sprintf("{Link ID Remote: %v Local: %v}", l.Local, l.Remote) } func (l *LsTLVLinkID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Local uint32 `json:"local_link_id"` Remote uint32 `json:"remote_link_id"` }{ Type: l.Type, Local: l.Local, Remote: l.Remote, }) } type LsTLVIPv4InterfaceAddr struct { LsTLV IP net.IP } func (l *LsTLVIPv4InterfaceAddr) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IPV4_INTERFACE_ADDR { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5305#section-3.2 if len(value) != 4 { return malformedAttrListErr("Unexpected address size") } l.IP = net.IP(value) return nil } func (l *LsTLVIPv4InterfaceAddr) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.IP) } func (l *LsTLVIPv4InterfaceAddr) String() string { return fmt.Sprintf("{IPv4 Interface Address: %v}", l.IP) } func (l *LsTLVIPv4InterfaceAddr) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"ipv4_interface_address"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.IP), }) } type LsTLVIPv4NeighborAddr struct { LsTLV IP net.IP } func (l *LsTLVIPv4NeighborAddr) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IPV4_NEIGHBOR_ADDR { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5305#section-3.3 if len(value) != 4 { return malformedAttrListErr("Unexpected address size") } l.IP = net.IP(value) return nil } func (l *LsTLVIPv4NeighborAddr) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.IP) } func (l *LsTLVIPv4NeighborAddr) String() string { return fmt.Sprintf("{IPv4 Neighbor Address: %v}", l.IP) } func (l *LsTLVIPv4NeighborAddr) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"ipv4_neighbor_address"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.IP), }) } type LsTLVIPv6InterfaceAddr struct { LsTLV IP net.IP } func (l *LsTLVIPv6InterfaceAddr) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IPV6_INTERFACE_ADDR { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc6119#section-4.2 if len(value) != 16 { return malformedAttrListErr("Unexpected address size") } l.IP = net.IP(value) if l.IP.IsLinkLocalUnicast() { return malformedAttrListErr("Unexpected link local address") } return nil } func (l *LsTLVIPv6InterfaceAddr) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.IP) } func (l *LsTLVIPv6InterfaceAddr) String() string { return fmt.Sprintf("{IPv6 Interface Address: %v}", l.IP) } func (l *LsTLVIPv6InterfaceAddr) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"ipv6_interface_address"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.IP), }) } type LsTLVIPv6NeighborAddr struct { LsTLV IP net.IP } func (l *LsTLVIPv6NeighborAddr) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IPV6_NEIGHBOR_ADDR { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc6119#section-4.3 if len(value) != 16 { return malformedAttrListErr("Unexpected address size") } l.IP = net.IP(value) if l.IP.IsLinkLocalUnicast() { return malformedAttrListErr("Unexpected link local address") } return nil } func (l *LsTLVIPv6NeighborAddr) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.IP) } func (l *LsTLVIPv6NeighborAddr) String() string { return fmt.Sprintf("{IPv6 Neighbor Address: %v}", l.IP) } func (l *LsTLVIPv6NeighborAddr) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"ipv6_neighbor_address"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.IP), }) } // https://tools.ietf.org/html/rfc7752#section-3.3.1.1 type LsNodeFlags struct { Overload bool `json:"overload"` Attached bool `json:"attached"` External bool `json:"external"` ABR bool `json:"abr"` Router bool `json:"router"` V6 bool `json:"v6"` } type LsTLVNodeFlagBits struct { LsTLV Flags uint8 } func (l *LsTLVNodeFlagBits) Extract() *LsNodeFlags { return &LsNodeFlags{ Overload: (l.Flags & (1 << 7)) > 0, Attached: (l.Flags & (1 << 6)) > 0, External: (l.Flags & (1 << 5)) > 0, ABR: (l.Flags & (1 << 4)) > 0, Router: (l.Flags & (1 << 3)) > 0, V6: (l.Flags & (1 << 2)) > 0, } } func (l *LsTLVNodeFlagBits) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_NODE_FLAG_BITS { return malformedAttrListErr("Unexpected TLV type") } if l.Length != 1 { return malformedAttrListErr("Node Flag Bits TLV malformed") } l.Flags = value[0] return nil } func (l *LsTLVNodeFlagBits) Serialize() ([]byte, error) { return l.LsTLV.Serialize([]byte{l.Flags}) } func (l *LsTLVNodeFlagBits) String() string { flags := "XXVRBETO" var buf bytes.Buffer for i := 0; i < len(flags); i++ { if l.Flags&(1< 0 { buf.WriteString(flags[i : i+1]) } else { buf.WriteString("*") } } return fmt.Sprintf("{Node Flags: %s}", buf.String()) } func (l *LsTLVNodeFlagBits) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Flags string `json:"node_flags"` }{ Type: l.Type, Flags: l.String(), }) } type LsTLVNodeName struct { LsTLV Name string } func (l *LsTLVNodeName) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_NODE_NAME { return malformedAttrListErr("Unexpected TLV type") } // RFC5301, section 3. if l.Length < 1 || l.Length > 255 { return malformedAttrListErr("Incorrect Node Name") } l.Name = string(value) return nil } func (l *LsTLVNodeName) Serialize() ([]byte, error) { return l.LsTLV.Serialize([]byte(l.Name)) } func (l *LsTLVNodeName) String() string { return fmt.Sprintf("{Node Name: %s}", l.Name) } func (l *LsTLVNodeName) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Name string `json:"node_name"` }{ Type: l.Type, Name: l.Name, }) } type LsTLVIsisArea struct { LsTLV Area []byte } func (l *LsTLVIsisArea) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_ISIS_AREA { return malformedAttrListErr("Unexpected TLV type") } if len(value) < 1 || len(value) > 13 { return malformedAttrListErr("Incorrect ISIS Area size") } l.Area = value return nil } func (l *LsTLVIsisArea) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.Area) } func (l *LsTLVIsisArea) String() string { return fmt.Sprintf("{ISIS Area ID: %v}", l.Area) } func (l *LsTLVIsisArea) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Area string `json:"isis_area_id"` }{ Type: l.Type, Area: fmt.Sprintf("%v", l.Area), }) } type LsTLVLocalIPv4RouterID struct { LsTLV IP net.IP } func (l *LsTLVLocalIPv4RouterID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IPV4_LOCAL_ROUTER_ID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5305#section-4.3 if len(value) != 4 { return malformedAttrListErr("Unexpected address size") } l.IP = net.IP(value) return nil } func (l *LsTLVLocalIPv4RouterID) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.IP) } func (l *LsTLVLocalIPv4RouterID) String() string { return fmt.Sprintf("{Local RouterID IPv4: %v}", l.IP) } func (l *LsTLVLocalIPv4RouterID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"node_local_router_id_ipv4"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.IP), }) } type LsTLVRemoteIPv4RouterID struct { LsTLV IP net.IP } func (l *LsTLVRemoteIPv4RouterID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IPV4_REMOTE_ROUTER_ID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5305#section-4.3 if len(value) != 4 { return malformedAttrListErr("Unexpected address size") } l.IP = net.IP(value) return nil } func (l *LsTLVRemoteIPv4RouterID) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.IP) } func (l *LsTLVRemoteIPv4RouterID) String() string { return fmt.Sprintf("{Remote RouterID IPv4: %v}", l.IP) } func (l *LsTLVRemoteIPv4RouterID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"node_remote_router_id_ipv4"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.IP), }) } type LsTLVLocalIPv6RouterID struct { LsTLV IP net.IP } func (l *LsTLVLocalIPv6RouterID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IPV6_LOCAL_ROUTER_ID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc6119#section-4.1 if len(value) != 16 { return malformedAttrListErr("Unexpected address size") } l.IP = net.IP(value) return nil } func (l *LsTLVLocalIPv6RouterID) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.IP) } func (l *LsTLVLocalIPv6RouterID) String() string { return fmt.Sprintf("{Local RouterID IPv6: %v}", l.IP) } func (l *LsTLVLocalIPv6RouterID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"node_local_router_id_ipv6"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.IP), }) } type LsTLVRemoteIPv6RouterID struct { LsTLV IP net.IP } func (l *LsTLVRemoteIPv6RouterID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IPV6_REMOTE_ROUTER_ID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc6119#section-4.1 if len(value) != 16 { return malformedAttrListErr("Unexpected address size") } l.IP = net.IP(value) return nil } func (l *LsTLVRemoteIPv6RouterID) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.IP) } func (l *LsTLVRemoteIPv6RouterID) String() string { return fmt.Sprintf("{Remote RouterID IPv6: %v}", l.IP) } func (l *LsTLVRemoteIPv6RouterID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"node_remote_router_id_ipv6"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.IP), }) } type LsTLVOpaqueNodeAttr struct { LsTLV Attr []byte } func (l *LsTLVOpaqueNodeAttr) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_OPAQUE_NODE_ATTR { return malformedAttrListErr("Unexpected TLV type") } l.Attr = value return nil } func (l *LsTLVOpaqueNodeAttr) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.Attr) } func (l *LsTLVOpaqueNodeAttr) String() string { return fmt.Sprintf("{Opaque attribute: %v}", l.Attr) } func (l *LsTLVOpaqueNodeAttr) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"node_opaque_attribute"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.Attr), }) } type LsTLVAutonomousSystem struct { LsTLV ASN uint32 } func (l *LsTLVAutonomousSystem) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_AS { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc7752#section-3.2.1.4 if len(value) != 4 { return malformedAttrListErr("Incorrect AS length") } l.ASN = binary.BigEndian.Uint32(value) return nil } func (l *LsTLVAutonomousSystem) Serialize() ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], l.ASN) return l.LsTLV.Serialize(buf[:]) } func (l *LsTLVAutonomousSystem) String() string { return fmt.Sprintf("{ASN: %d}", l.ASN) } func (l *LsTLVAutonomousSystem) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` ASN uint32 `json:"asn"` }{ Type: l.Type, ASN: l.ASN, }) } type LsTLVBgpLsID struct { LsTLV BGPLsID uint32 } func (l *LsTLVBgpLsID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_BGP_LS_ID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc7752#section-3.2.1.4 if len(value) != 4 { return malformedAttrListErr("Incorrect BGP-LS ID length") } l.BGPLsID = binary.BigEndian.Uint32(value) return nil } func (l *LsTLVBgpLsID) Serialize() ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], l.BGPLsID) return l.LsTLV.Serialize(buf[:4]) } func (l *LsTLVBgpLsID) String() string { return fmt.Sprintf("{BGP LS ID: %d}", l.BGPLsID) } func (l *LsTLVBgpLsID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` BgpLsID uint32 `json:"bgp_ls_id"` }{ Type: l.Type, BgpLsID: l.BGPLsID, }) } type LsTLVIgpRouterID struct { LsTLV RouterID []byte } func (l *LsTLVIgpRouterID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IGP_ROUTER_ID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc7752#section-3.2.1.4 // 4, 6, 7, and 8 are the only valid values. switch len(value) { case 4, 6, 7, 8: break default: return malformedAttrListErr(fmt.Sprintf("Incorrect IGP Router ID length: %d", len(value))) } l.RouterID = value return nil } func (l *LsTLVIgpRouterID) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.RouterID) } func (l *LsTLVIgpRouterID) String() string { return fmt.Sprintf("{IGP Router ID: %v}", l.RouterID) } func (l *LsTLVIgpRouterID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` RouterID string `json:"igp_router_id"` }{ Type: l.Type, RouterID: fmt.Sprintf("%v", l.RouterID), }) } type LsTLVOspfAreaID struct { LsTLV AreaID uint32 } func (l *LsTLVOspfAreaID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_OSPF_AREA { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc7752#section-3.2.1.4 if len(value) != 4 { return malformedAttrListErr("Incorrect OSPF Area ID length") } l.AreaID = binary.BigEndian.Uint32(value) return nil } func (l *LsTLVOspfAreaID) Serialize() ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], l.AreaID) return l.LsTLV.Serialize(buf[:4]) } func (l *LsTLVOspfAreaID) String() string { return fmt.Sprintf("{OSPF Area ID: %d}", l.AreaID) } func (l *LsTLVOspfAreaID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` AreaID uint32 `json:"ospf_area_id"` }{ Type: l.Type, AreaID: l.AreaID, }) } type LsOspfRouteType uint8 const ( LS_OSPF_ROUTE_TYPE_UNKNOWN = iota LS_OSPF_ROUTE_TYPE_INTRA_AREA LS_OSPF_ROUTE_TYPE_INTER_AREA LS_OSPF_ROUTE_TYPE_EXTERNAL1 LS_OSPF_ROUTE_TYPE_EXTERNAL2 LS_OSPF_ROUTE_TYPE_NSSA1 LS_OSPF_ROUTE_TYPE_NSSA2 ) func (l LsOspfRouteType) String() string { switch l { case LS_OSPF_ROUTE_TYPE_INTRA_AREA: return "INTRA-AREA" case LS_OSPF_ROUTE_TYPE_INTER_AREA: return "INTER-AREA" case LS_OSPF_ROUTE_TYPE_EXTERNAL1: return "EXTERNAL1" case LS_OSPF_ROUTE_TYPE_EXTERNAL2: return "EXTERNAL2" case LS_OSPF_ROUTE_TYPE_NSSA1: return "NSSA1" case LS_OSPF_ROUTE_TYPE_NSSA2: return "NSSA2" default: return fmt.Sprintf("LsOspfRouteType(%d)", uint8(l)) } } type LsTLVOspfRouteType struct { LsTLV RouteType LsOspfRouteType } func (l *LsTLVOspfRouteType) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_OSPF_ROUTE_TYPE { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc7752#section-3.2.3.1 if len(value) != 1 { return malformedAttrListErr("Incorrect OSPF Route type length") } if value[0] < byte(LS_OSPF_ROUTE_TYPE_INTRA_AREA) || value[0] > LS_OSPF_ROUTE_TYPE_NSSA2 { return malformedAttrListErr("Incorrect OSPF Route type") } l.RouteType = LsOspfRouteType(value[0]) return nil } func (l *LsTLVOspfRouteType) Serialize() ([]byte, error) { var buf [1]byte buf[0] = byte(l.RouteType) return l.LsTLV.Serialize(buf[:]) } func (l *LsTLVOspfRouteType) String() string { return fmt.Sprintf("{OSPF Route Type: %v}", l.RouteType) } func (l *LsTLVOspfRouteType) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` RouteType string `json:"ospf_route_type"` }{ Type: l.Type, RouteType: l.RouteType.String(), }) } type LsTLVIPReachability struct { LsTLV PrefixLength uint8 Prefix []byte } func (l *LsTLVIPReachability) ToIPNet(ipv6 bool) net.IPNet { b := make([]byte, 16) for i := 0; i < int(((l.PrefixLength-1)/8)+1); i++ { b[i] = l.Prefix[i] } ip := net.IPv4(b[0], b[1], b[2], b[3]).To4() if ipv6 { ip = net.IP(b).To16() } _, n, err := net.ParseCIDR(fmt.Sprintf("%v/%v", ip, l.PrefixLength)) if err != nil { return net.IPNet{} } return *n } func (l *LsTLVIPReachability) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IP_REACH_INFO { return malformedAttrListErr("Unexpected TLV type") } if len(value) < 2 { return malformedAttrListErr("Incorrect IP reachability Info length") } // https://tools.ietf.org/html/rfc7752#section-3.2.3.2 if value[0] > 128 || value[0] == 0 { return malformedAttrListErr("Incorrect IP prefix length") } ll := int(((value[0] - 1) / 8) + 1) if len(value[1:]) != ll { return malformedAttrListErr("Malformed IP reachability TLV") } l.PrefixLength = value[0] l.Prefix = value[1 : 1+ll] return nil } func (l *LsTLVIPReachability) Serialize() ([]byte, error) { b := []byte{l.PrefixLength} return l.LsTLV.Serialize(append(b, l.Prefix...)) } func (l *LsTLVIPReachability) String() string { return fmt.Sprintf("{IP Reachability: %v/%v}", l.Prefix, l.PrefixLength) } func (l *LsTLVIPReachability) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` PrefixLength uint8 `json:"prefix_length"` Prefix string `json:"prefix"` }{ Type: l.Type, PrefixLength: l.PrefixLength, Prefix: fmt.Sprintf("%v", l.Prefix), }) } type LsTLVAdminGroup struct { LsTLV AdminGroup uint32 } func (l *LsTLVAdminGroup) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_ADMIN_GROUP { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5305#section-3.1 if len(value) != 4 { return malformedAttrListErr("Incorrect Admin Group length") } l.AdminGroup = binary.BigEndian.Uint32(value) return nil } func (l *LsTLVAdminGroup) Serialize() ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], l.AdminGroup) return l.LsTLV.Serialize(buf[:]) } func (l *LsTLVAdminGroup) String() string { return fmt.Sprintf("{Admin Group: %08x}", l.AdminGroup) } func (l *LsTLVAdminGroup) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` AdminGroup string `json:"admin_group"` }{ Type: l.Type, AdminGroup: fmt.Sprintf("%08x", l.AdminGroup), }) } type LsTLVMaxLinkBw struct { LsTLV Bandwidth float32 } func (l *LsTLVMaxLinkBw) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_MAX_LINK_BANDWIDTH { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5305#section-3.4 if len(value) != 4 { return malformedAttrListErr("Incorrect maximum link bandwidth length") } l.Bandwidth = math.Float32frombits(binary.BigEndian.Uint32(value)) if l.Bandwidth < 0 || math.IsNaN(float64(l.Bandwidth)) || math.IsInf(float64(l.Bandwidth), 0) { return malformedAttrListErr("Incorrect maximum link bandwidth value") } return nil } func (l *LsTLVMaxLinkBw) Serialize() ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], math.Float32bits(l.Bandwidth)) return l.LsTLV.Serialize(buf[:]) } func (l *LsTLVMaxLinkBw) String() string { return fmt.Sprintf("{Max Link BW: %v}", l.Bandwidth) } func (l *LsTLVMaxLinkBw) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Bandwidth float32 `json:"max_link_bw"` }{ Type: l.Type, Bandwidth: l.Bandwidth, }) } type LsTLVMaxReservableLinkBw struct { LsTLV Bandwidth float32 } func (l *LsTLVMaxReservableLinkBw) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_MAX_RESERVABLE_BANDWIDTH { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5305#section-3.5 if len(value) != 4 { return malformedAttrListErr("Incorrect maximum reservable link bandwidth length") } l.Bandwidth = math.Float32frombits(binary.BigEndian.Uint32(value)) if l.Bandwidth < 0 || math.IsNaN(float64(l.Bandwidth)) || math.IsInf(float64(l.Bandwidth), 0) { return malformedAttrListErr("Incorrect maximum reservable link bandwidth value") } return nil } func (l *LsTLVMaxReservableLinkBw) Serialize() ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], math.Float32bits(l.Bandwidth)) return l.LsTLV.Serialize(buf[:]) } func (l *LsTLVMaxReservableLinkBw) String() string { return fmt.Sprintf("{Max Reservable Link BW: %v}", l.Bandwidth) } func (l *LsTLVMaxReservableLinkBw) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Bandwidth float32 `json:"max_reservable_link_bw"` }{ Type: l.Type, Bandwidth: l.Bandwidth, }) } type LsTLVUnreservedBw struct { LsTLV Bandwidth [8]float32 } func (l *LsTLVUnreservedBw) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_UNRESERVED_BANDWIDTH { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc5305#section-3.6 if len(value) != 32 { return malformedAttrListErr("Incorrect unreserved bandwidth length") } for i := 0; i < len(l.Bandwidth); i++ { l.Bandwidth[i] = math.Float32frombits(binary.BigEndian.Uint32(value[:4])) value = value[4:] if l.Bandwidth[i] < 0 || math.IsNaN(float64(l.Bandwidth[i])) || math.IsInf(float64(l.Bandwidth[i]), 0) { return malformedAttrListErr("Incorrect unreserved bandwidth value") } } return nil } func (l *LsTLVUnreservedBw) Serialize() ([]byte, error) { buf := make([]byte, 0, 4*len(l.Bandwidth)) var b [4]byte for i := 0; i < len(l.Bandwidth); i++ { binary.BigEndian.PutUint32(b[:4], math.Float32bits(l.Bandwidth[i])) buf = append(buf, b[:]...) } return l.LsTLV.Serialize(buf) } func (l *LsTLVUnreservedBw) String() string { return fmt.Sprintf("{Unreserved BW: %v}", l.Bandwidth) } func (l *LsTLVUnreservedBw) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Bandwidth [8]float32 `json:"unreserved_bw"` }{ Type: l.Type, Bandwidth: l.Bandwidth, }) } type LsTLVTEDefaultMetric struct { LsTLV Metric uint32 } func (l *LsTLVTEDefaultMetric) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_TE_DEFAULT_METRIC { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc7752#section-3.3.2.3 if len(value) != 4 { return malformedAttrListErr("Incorrect metric length length") } l.Metric = binary.BigEndian.Uint32(value) return nil } func (l *LsTLVTEDefaultMetric) Serialize() ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], l.Metric) return l.LsTLV.Serialize(buf[:]) } func (l *LsTLVTEDefaultMetric) String() string { return fmt.Sprintf("{TE Default metric: %d}", l.Metric) } func (l *LsTLVTEDefaultMetric) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` DefaultMetric uint32 `json:"te_default_metric"` }{ Type: l.Type, DefaultMetric: l.Metric, }) } type LsTLVIGPMetric struct { LsTLV Metric uint32 } func (l *LsTLVIGPMetric) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IGP_METRIC { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc7752#section-3.3.2.4 switch len(value) { case 1: l.Metric = uint32(value[0] & 0x3F) case 2: l.Metric = uint32(binary.BigEndian.Uint16(value)) case 3: l.Metric = binary.BigEndian.Uint32([]byte{0, value[0], value[1], value[2]}) default: return malformedAttrListErr("Incorrect metric length") } return nil } func (l *LsTLVIGPMetric) Serialize() ([]byte, error) { switch l.Length { case 1: return l.LsTLV.Serialize([]byte{uint8(l.Metric) & 0x3F}) case 2: var buf [2]byte binary.BigEndian.PutUint16(buf[:2], uint16(l.Metric)) return l.LsTLV.Serialize(buf[:]) case 3: var buf [4]byte binary.BigEndian.PutUint32(buf[:4], l.Metric) return l.LsTLV.Serialize(buf[1:]) default: return nil, malformedAttrListErr("Incorrect metric length") } } func (l *LsTLVIGPMetric) String() string { return fmt.Sprintf("{IGP metric: %d}", l.Metric) } func (l *LsTLVIGPMetric) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Metric uint32 `json:"igp_metric"` }{ Type: l.Type, Metric: l.Metric, }) } type LsTLVLinkName struct { LsTLV Name string } func (l *LsTLVLinkName) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_LINK_NAME { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/rfc7752#section-3.3.2.7 if len(value) < 1 || len(value) > 255 { return malformedAttrListErr("Incorrect Link Name") } l.Name = string(value) return nil } func (l *LsTLVLinkName) Serialize() ([]byte, error) { return l.LsTLV.Serialize([]byte(l.Name)) } func (l *LsTLVLinkName) String() string { return fmt.Sprintf("{Link Name: %s}", l.Name) } func (l *LsTLVLinkName) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Name string `json:"link_name"` }{ Type: l.Type, Name: l.Name, }) } type LsTLVSrAlgorithm struct { LsTLV Algorithm []byte } func (l *LsTLVSrAlgorithm) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_SR_ALGORITHM { return malformedAttrListErr("Unexpected TLV type") } if len(value) < 1 { return malformedAttrListErr("Incorrect SR algorithm length") } l.Algorithm = value return nil } func (l *LsTLVSrAlgorithm) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.Algorithm) } func (l *LsTLVSrAlgorithm) String() string { return fmt.Sprintf("{SR Algorithms: %v}", l.Algorithm) } func (l *LsTLVSrAlgorithm) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Algorithms string `json:"sr_algorithm"` }{ Type: l.Type, Algorithms: fmt.Sprintf("%v", l.Algorithm), }) } type LsSrLabelRange struct { Range uint32 FirstLabel LsTLVSIDLabel } type LsTLVSrCapabilities struct { LsTLV Flags uint8 Ranges []LsSrLabelRange } type LsSrRange struct { Begin uint32 `json:"begin"` End uint32 `json:"end"` } type LsSrCapabilities struct { IPv4Supported bool `json:"ipv4_supported"` IPv6Supported bool `json:"ipv6_supported"` Ranges []LsSrRange `json:"ranges"` } func (l *LsTLVSrCapabilities) Extract() *LsSrCapabilities { lsc := &LsSrCapabilities{ IPv4Supported: (l.Flags & (1 << 0)) > 0, IPv6Supported: (l.Flags & (1 << 1)) > 0, } for _, r := range l.Ranges { lsc.Ranges = append(lsc.Ranges, LsSrRange{ Begin: r.FirstLabel.SID, End: r.FirstLabel.SID + r.Range, }) } return lsc } func (l *LsTLVSrCapabilities) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_SR_CAPABILITIES { return malformedAttrListErr("Unexpected TLV type") } if len(value) < 2 { return malformedAttrListErr("Incorrect SR Capabilities length") } l.Flags = value[0] // Skip two bytes: flags and reserved. value = value[2:] // The value field should be at least eight bytes long. Three bytes // for the range size and five or six bytes for the SID/Label TLV. for len(value) > 8 { // First, parse range size (3 bytes) buf := []byte{0, 0, 0, 0} for i := 1; i < len(buf); i++ { buf[i] = value[i-1] } r := binary.BigEndian.Uint32(buf) value = value[3:] // Second, parse SID/Label sub-TLV. label := LsTLVSIDLabel{} if err := label.DecodeFromBytes(value); err != nil { return err } l.Ranges = append(l.Ranges, LsSrLabelRange{ Range: r, FirstLabel: label, }) value = value[label.Len():] } if len(value) > 0 { return malformedAttrListErr("Malformed SR Capabilities TLV") } return nil } func (l *LsTLVSrCapabilities) Serialize() ([]byte, error) { buf := make([]byte, 0) buf = append(buf, l.Flags) buf = append(buf, 0) var b [4]byte for _, r := range l.Ranges { binary.BigEndian.PutUint32(b[:4], r.Range) buf = append(buf, b[1:]...) ser, err := r.FirstLabel.Serialize() if err != nil { return nil, err } buf = append(buf, ser...) } return l.LsTLV.Serialize(buf) } func (l *LsTLVSrCapabilities) String() string { var buf bytes.Buffer for _, r := range l.Ranges { buf.WriteString(fmt.Sprintf("%v:%v ", r.FirstLabel.SID, r.FirstLabel.SID+r.Range)) } return fmt.Sprintf("{SR Capabilities: Flags:%v SRGB Ranges: %v}", l.Flags, buf.String()) } func (l *LsTLVSrCapabilities) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Flags uint8 `json:"flags"` Ranges []LsSrLabelRange `json:"ranges"` }{ Type: l.Type, Flags: l.Flags, Ranges: l.Ranges, }) } type LsTLVSrLocalBlock struct { LsTLV Flags uint8 Ranges []LsSrLabelRange } type LsSrLocalBlock struct { Ranges []LsSrRange `json:"ranges"` } func (l *LsTLVSrLocalBlock) Extract() *LsSrLocalBlock { lb := &LsSrLocalBlock{} for _, r := range l.Ranges { lb.Ranges = append(lb.Ranges, LsSrRange{ Begin: r.FirstLabel.SID, End: r.FirstLabel.SID + r.Range, }) } return lb } func (l *LsTLVSrLocalBlock) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_SR_LOCAL_BLOCK { return malformedAttrListErr("Unexpected TLV type") } if len(value) < 2 { return malformedAttrListErr("Incorrect SR Local Block length") } l.Flags = value[0] // Skip two bytes: flags and reserved. value = value[2:] // The value field should be at least eight bytes long. Three bytes // for the range size and five or six bytes for the SID/Label TLV. for len(value) > 8 { // First, parse range size (3 bytes) buf := []byte{0, 0, 0, 0} for i := 1; i < len(buf); i++ { buf[i] = value[i-1] } r := binary.BigEndian.Uint32(buf) value = value[3:] // Second, parse SID/Label sub-TLV. label := LsTLVSIDLabel{} if err := label.DecodeFromBytes(value); err != nil { return err } l.Ranges = append(l.Ranges, LsSrLabelRange{ Range: r, FirstLabel: label, }) value = value[label.Len():] } if len(value) > 0 { return malformedAttrListErr("Malformed SR Local Block TLV") } return nil } func (l *LsTLVSrLocalBlock) Serialize() ([]byte, error) { buf := make([]byte, 0) buf = append(buf, l.Flags) buf = append(buf, 0) var b [4]byte for _, r := range l.Ranges { binary.BigEndian.PutUint32(b[:4], r.Range) buf = append(buf, b[1:]...) ser, err := r.FirstLabel.Serialize() if err != nil { return nil, err } buf = append(buf, ser...) } return l.LsTLV.Serialize(buf) } func (l *LsTLVSrLocalBlock) String() string { var buf bytes.Buffer for _, r := range l.Ranges { buf.WriteString(fmt.Sprintf("%v:%v ", r.FirstLabel.SID, r.FirstLabel.SID+r.Range)) } return fmt.Sprintf("{SR LocalBlock: Flags:%v SRGB Ranges: %v}", l.Flags, buf.String()) } func (l *LsTLVSrLocalBlock) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Flags uint8 `json:"flags"` Ranges []LsSrLabelRange `json:"ranges"` }{ Type: l.Type, Flags: l.Flags, Ranges: l.Ranges, }) } type LsTLVAdjacencySID struct { LsTLV Flags uint8 Weight uint8 SID uint32 } func (l *LsTLVAdjacencySID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_ADJACENCY_SID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/draft-ietf-idr-bgp-ls-segment-routing-ext-08#section-2.2.1 if len(value) != 7 && len(value) != 8 { return malformedAttrListErr("Incorrect Adjacency SID length") } l.Flags = value[0] l.Weight = value[1] v := value[4:] if len(v) == 4 { l.SID = binary.BigEndian.Uint32(v) } else { buf := []byte{0, 0, 0, 0} for i := 1; i < len(buf); i++ { buf[i] = v[i-1] } // Label is represented by 20 rightmost bits. l.SID = binary.BigEndian.Uint32(buf) & 0xfffff } return nil } func (l *LsTLVAdjacencySID) Serialize() ([]byte, error) { buf := make([]byte, 0) buf = append(buf, l.Flags) buf = append(buf, l.Weight) // Reserved buf = append(buf, []byte{0, 0}...) var b [4]byte binary.BigEndian.PutUint32(b[:4], l.SID) if l.Length == 7 { return l.LsTLV.Serialize(append(buf, b[1:]...)) } return l.LsTLV.Serialize(append(buf, b[:]...)) } func (l *LsTLVAdjacencySID) String() string { return fmt.Sprintf("{Adjacency SID: %v}", l.SID) } func (l *LsTLVAdjacencySID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` SID uint32 `json:"adjacency_sid"` }{ Type: l.Type, SID: l.SID, }) } type LsTLVSIDLabel struct { LsTLV SID uint32 } func (l *LsTLVSIDLabel) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_SID_LABEL_TLV { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/draft-ietf-idr-bgp-ls-segment-routing-ext-08#section-2.1.1 if len(value) != 4 && len(value) != 3 { return malformedAttrListErr("Incorrect SID length") } if len(value) == 4 { l.SID = binary.BigEndian.Uint32(value) } else { buf := []byte{0, 0, 0, 0} for i := 1; i < len(buf); i++ { buf[i] = value[i-1] } // Label is represented by 20 rightmost bits. l.SID = binary.BigEndian.Uint32(buf) & 0xfffff } return nil } func (l *LsTLVSIDLabel) Serialize() ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], l.SID) if l.Length == 3 { return l.LsTLV.Serialize(buf[1:]) } return l.LsTLV.Serialize(buf[:]) } func (l *LsTLVSIDLabel) String() string { return fmt.Sprintf("{SID/Label: %v}", l.SID) } func (l *LsTLVSIDLabel) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` SID uint32 `json:"sid_label"` }{ Type: l.Type, SID: l.SID, }) } type LsTLVPrefixSID struct { LsTLV Flags uint8 Algorithm uint8 SID uint32 } func (l *LsTLVPrefixSID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_PREFIX_SID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/draft-ietf-idr-bgp-ls-segment-routing-ext-08#section-2.3.1 if len(value) != 7 && len(value) != 8 { return malformedAttrListErr("Incorrect Prefix SID length") } l.Flags = value[0] l.Algorithm = value[1] // Flags (1) + Algorithm (1) + Reserved (2) v := value[4:] if len(v) == 4 { l.SID = binary.BigEndian.Uint32(v) } else { buf := []byte{0, 0, 0, 0} for i := 1; i < len(buf); i++ { buf[i] = v[i-1] } // Label is represented by 20 rightmost bits. l.SID = binary.BigEndian.Uint32(buf) & 0xfffff } return nil } func (l *LsTLVPrefixSID) Serialize() ([]byte, error) { buf := make([]byte, 0) buf = append(buf, l.Flags) buf = append(buf, l.Algorithm) // Reserved buf = append(buf, []byte{0, 0}...) var b [4]byte binary.BigEndian.PutUint32(b[:4], l.SID) if l.Length == 7 { return l.LsTLV.Serialize(append(buf, b[1:]...)) } return l.LsTLV.Serialize(append(buf, b[:]...)) } func (l *LsTLVPrefixSID) String() string { return fmt.Sprintf("{Prefix SID: %v}", l.SID) } func (l *LsTLVPrefixSID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` SID uint32 `json:"prefix_sid"` }{ Type: l.Type, SID: l.SID, }) } type LsTLVSourceRouterID struct { LsTLV RouterID []byte } func (l *LsTLVSourceRouterID) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_SOURCE_ROUTER_ID { return malformedAttrListErr("Unexpected TLV type") } // https://tools.ietf.org/html/draft-ietf-idr-bgp-ls-segment-routing-ext-08#section-2.3.3 if len(value) != 4 && len(value) != 16 { return malformedAttrListErr("Incorrect Source Router ID length") } l.RouterID = value return nil } func (l *LsTLVSourceRouterID) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.RouterID) } func (l *LsTLVSourceRouterID) String() string { return fmt.Sprintf("{Source Router ID: %v}", net.IP(l.RouterID)) } func (l *LsTLVSourceRouterID) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` RouterID string `json:"source_router_id"` }{ Type: l.Type, RouterID: fmt.Sprintf("%v", net.IP(l.RouterID)), }) } type LsTLVOpaqueLinkAttr struct { LsTLV Attr []byte } func (l *LsTLVOpaqueLinkAttr) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_OPAQUE_LINK_ATTR { return malformedAttrListErr("Unexpected TLV type") } l.Attr = value return nil } func (l *LsTLVOpaqueLinkAttr) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.Attr) } func (l *LsTLVOpaqueLinkAttr) String() string { return fmt.Sprintf("{Opaque link attribute: %v}", l.Attr) } func (l *LsTLVOpaqueLinkAttr) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"link_opaque_attribute"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.Attr), }) } type LsTLVSrlg struct { LsTLV Srlgs []uint32 } func (l *LsTLVSrlg) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_SRLG { return malformedAttrListErr("Unexpected TLV type") } if len(value)%4 != 0 { return malformedAttrListErr("Incorrect SRLG length") } for len(value) > 0 { l.Srlgs = append(l.Srlgs, binary.BigEndian.Uint32(value[:4])) value = value[4:] } return nil } func (l *LsTLVSrlg) Serialize() ([]byte, error) { buf := make([]byte, 0, 4*len(l.Srlgs)) var b [4]byte for i := 0; i < len(l.Srlgs); i++ { binary.BigEndian.PutUint32(b[:4], l.Srlgs[i]) buf = append(buf, b[:]...) } return l.LsTLV.Serialize(buf) } func (l *LsTLVSrlg) String() string { return fmt.Sprintf("{SRLG link attribute: %d}", l.Srlgs) } func (l *LsTLVSrlg) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value []uint32 `json:"link_srlg_attribute"` }{ Type: l.Type, Value: l.Srlgs, }) } type LsTLVIGPFlags struct { LsTLV Flags uint8 } // https://tools.ietf.org/html/rfc7752#section-3.3.3.1 type LsIGPFlags struct { Down bool `json:"down"` NoUnicast bool `json:"no_unicast"` LocalAddress bool `json:"local_address"` PropagateNSSA bool `json:"propagate_nssa"` } func (l *LsTLVIGPFlags) Extract() *LsIGPFlags { return &LsIGPFlags{ Down: (l.Flags & (1 << 0)) > 0, NoUnicast: (l.Flags & (1 << 1)) > 0, LocalAddress: (l.Flags & (1 << 2)) > 0, PropagateNSSA: (l.Flags & (1 << 3)) > 0, } } func (l *LsTLVIGPFlags) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_IGP_FLAGS { return malformedAttrListErr("Unexpected TLV type") } if l.Length != 1 { return malformedAttrListErr("Node Flag Bits TLV malformed") } l.Flags = value[0] return nil } func (l *LsTLVIGPFlags) Serialize() ([]byte, error) { return l.LsTLV.Serialize([]byte{l.Flags}) } func (l *LsTLVIGPFlags) String() string { flags := "XXXXPLND" var buf bytes.Buffer for i := 0; i < len(flags); i++ { if l.Flags&(1< 0 { buf.WriteString(flags[i : i+1]) } else { buf.WriteString("*") } } return fmt.Sprintf("{IGP Flags: %s}", buf.String()) } func (l *LsTLVIGPFlags) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Flags string `json:"igp_flags"` }{ Type: l.Type, Flags: l.String(), }) } type LsTLVOpaquePrefixAttr struct { LsTLV Attr []byte } func (l *LsTLVOpaquePrefixAttr) DecodeFromBytes(data []byte) error { value, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_OPAQUE_PREFIX_ATTR { return malformedAttrListErr("Unexpected TLV type") } l.Attr = value return nil } func (l *LsTLVOpaquePrefixAttr) Serialize() ([]byte, error) { return l.LsTLV.Serialize(l.Attr) } func (l *LsTLVOpaquePrefixAttr) String() string { return fmt.Sprintf("{Prefix opaque attribute: %v}", l.Attr) } func (l *LsTLVOpaquePrefixAttr) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` Value string `json:"prefix_opaque_attribute"` }{ Type: l.Type, Value: fmt.Sprintf("%v", l.Attr), }) } type LsTLVNodeDescriptor struct { LsTLV SubTLVs []LsTLVInterface } func (l *LsTLVNodeDescriptor) DecodeFromBytes(data []byte) error { tlv, err := l.LsTLV.DecodeFromBytes(data) if err != nil { return err } if l.Type != LS_TLV_LOCAL_NODE_DESC && l.Type != LS_TLV_REMOTE_NODE_DESC { return malformedAttrListErr("Unexpected TLV type") } // RFC7752, 3.2.1.4 // There can be at most one instance of each sub-TLV type present in // any Node Descriptor. The sub-TLVs within a Node Descriptor MUST // be arranged in ascending order by sub-TLV type. prevType := uint16(0) m := make(map[LsTLVType]bool) for len(tlv) >= tlvHdrLen { sub := &LsTLV{} _, err := sub.DecodeFromBytes(tlv) if err != nil { return err } if uint16(sub.Type) < prevType { return malformedAttrListErr("Incorrect TLV order") } if _, ok := m[sub.Type]; ok { return malformedAttrListErr("Duplicate TLV") } prevType = uint16(sub.Type) m[sub.Type] = true var subTLV LsTLVInterface switch sub.Type { case LS_TLV_AS: subTLV = &LsTLVAutonomousSystem{} case LS_TLV_BGP_LS_ID: subTLV = &LsTLVBgpLsID{} case LS_TLV_OSPF_AREA: subTLV = &LsTLVOspfAreaID{} case LS_TLV_IGP_ROUTER_ID: subTLV = &LsTLVIgpRouterID{} default: tlv = tlv[sub.Len():] l.Length -= uint16(sub.Len()) continue } if err := subTLV.DecodeFromBytes(tlv); err != nil { return err } l.SubTLVs = append(l.SubTLVs, subTLV) tlv = tlv[subTLV.Len():] } if _, ok := m[LS_TLV_IGP_ROUTER_ID]; !ok { return malformedAttrListErr("Required TLV missing") } return nil } func (l *LsTLVNodeDescriptor) Serialize() ([]byte, error) { buf := []byte{} for _, tlv := range l.SubTLVs { ser, err := tlv.Serialize() if err != nil { return nil, err } buf = append(buf, ser...) } return l.LsTLV.Serialize(buf) } func (l *LsTLVNodeDescriptor) String() string { nd := l.Extract() return fmt.Sprintf("{ASN: %v, BGP LS ID: %v, OSPF AREA: %v, IGP ROUTER ID: %v}", nd.Asn, nd.BGPLsID, nd.OspfAreaID, nd.IGPRouterID) } func (l *LsTLVNodeDescriptor) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsTLVType `json:"type"` LsNodeDescriptor }{ l.Type, *l.Extract(), }) } type LsNodeDescriptor struct { Asn uint32 `json:"asn"` BGPLsID uint32 `json:"bgp_ls_id"` OspfAreaID uint32 `json:"ospf_area_id"` PseudoNode bool `json:"pseudo_node"` IGPRouterID string `json:"igp_router_id"` } func parseIGPRouterID(id []byte) (string, bool) { switch len(id) { // OSPF or OSPFv3 non-pseudonode case 4: return net.IP(id).String(), false // ISIS non-pseudonode case 6: return fmt.Sprintf("%0.2x%0.2x.%0.2x%0.2x.%0.2x%0.2x", id[0], id[1], id[2], id[3], id[4], id[5]), false // ISIS pseudonode case 7: return fmt.Sprintf("%0.2x%0.2x.%0.2x%0.2x.%0.2x%0.2x-%0.2x", id[0], id[1], id[2], id[3], id[4], id[5], id[6]), true // OSPF or OSPFv3 pseudonode case 8: return fmt.Sprintf("%v:%v", net.IP(id[:4]).String(), net.IP(id[4:]).String()), true default: return fmt.Sprintf("%v", id), false } } func (l *LsTLVNodeDescriptor) Extract() *LsNodeDescriptor { nd := &LsNodeDescriptor{} for _, tlv := range l.SubTLVs { switch v := tlv.(type) { case *LsTLVAutonomousSystem: nd.Asn = v.ASN case *LsTLVBgpLsID: nd.BGPLsID = v.BGPLsID case *LsTLVOspfAreaID: nd.OspfAreaID = v.AreaID case *LsTLVIgpRouterID: nd.IGPRouterID, nd.PseudoNode = parseIGPRouterID(v.RouterID) } } return nd } type LsAddrPrefix struct { PrefixDefault Type LsNLRIType Length uint16 NLRI LsNLRIInterface } func (l *LsAddrPrefix) AFI() uint16 { return AFI_LS } func (l *LsAddrPrefix) SAFI() uint8 { return SAFI_LS } func (l *LsAddrPrefix) Len(...*MarshallingOption) int { return int(4 + l.Length) } func (l *LsAddrPrefix) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { if len(data) < 4 { return malformedAttrListErr("Malformed BGP-LS Address Prefix") } l.Type = LsNLRIType(binary.BigEndian.Uint16(data[:2])) l.Length = binary.BigEndian.Uint16(data[2:4]) switch l.Type { case LS_NLRI_TYPE_NODE: node := &LsNodeNLRI{} node.Length = l.Length node.NLRIType = LS_NLRI_TYPE_NODE l.NLRI = node case LS_NLRI_TYPE_LINK: link := &LsLinkNLRI{} link.Length = l.Length link.NLRIType = LS_NLRI_TYPE_LINK l.NLRI = link case LS_NLRI_TYPE_PREFIX_IPV4: prefixv4 := &LsPrefixV4NLRI{} prefixv4.Length = l.Length prefixv4.NLRIType = LS_NLRI_TYPE_PREFIX_IPV4 l.NLRI = prefixv4 case LS_NLRI_TYPE_PREFIX_IPV6: prefixv6 := &LsPrefixV6NLRI{} prefixv6.Length = l.Length prefixv6.NLRIType = LS_NLRI_TYPE_PREFIX_IPV4 l.NLRI = prefixv6 default: return malformedAttrListErr("Unsupported BGP-LS NLRI") } if l.NLRI != nil { return l.NLRI.DecodeFromBytes(data[4:]) } return nil } func (l *LsAddrPrefix) Serialize(options ...*MarshallingOption) ([]byte, error) { if l.NLRI == nil { return nil, errors.New("empty NLRI") } ser, err := l.NLRI.Serialize() if err != nil { return nil, err } buf := make([]byte, 4+len(ser)) binary.BigEndian.PutUint16(buf[:2], uint16(l.Type)) binary.BigEndian.PutUint16(buf[2:], l.Length) copy(buf[4:], ser) return buf, nil } func (l *LsAddrPrefix) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type LsNLRIType `json:"type"` Length uint16 `json:"length"` NLRI string `json:"nlri"` }{ l.Type, l.Length, l.String(), }) } func (l *LsAddrPrefix) String() string { if l.NLRI == nil { return "NLRI: (nil)" } return fmt.Sprintf("NLRI { %s }", l.NLRI.String()) } func (l *LsAddrPrefix) Flat() map[string]string { return map[string]string{} } type LsAttributeNode struct { Flags *LsNodeFlags `json:"flags,omitempty"` Opaque *[]byte `json:"opaque,omitempty"` Name *string `json:"name,omitempty"` IsisArea *[]byte `json:"isis_area,omitempty"` LocalRouterID *net.IP `json:"local_router_id_ipv4,omitempty"` LocalRouterIDv6 *net.IP `json:"local_router_id_ipv6,omitempty"` // Segment Routing SrCapabilties *LsSrCapabilities `json:"sr_capabilities,omitempty"` SrAlgorithms *[]byte `json:"sr_algorithms,omitempty"` SrLocalBlock *LsSrLocalBlock `json:"sr_local_block,omitempty"` } type LsAttributeLink struct { Name *string `json:"name,omitempty"` LocalRouterID *net.IP `json:"local_router_id_ipv4,omitempty"` LocalRouterIDv6 *net.IP `json:"local_router_id_ipv6,omitempty"` RemoteRouterID *net.IP `json:"remote_router_id_ipv4,omitempty"` RemoteRouterIDv6 *net.IP `json:"remote_router_id_ipv6,omitempty"` AdminGroup *uint32 `json:"admin_group,omitempty"` DefaultTEMetric *uint32 `json:"default_te_metric,omitempty"` IGPMetric *uint32 `json:"igp_metric,omitempty"` Opaque *[]byte `json:"opaque,omitempty"` // Bandwidth is expressed in bytes (not bits) per second. Bandwidth *float32 `json:"bandwidth,omitempty"` ReservableBandwidth *float32 `json:"reservable_bandwidth,omitempty"` UnreservedBandwidth *[8]float32 `json:"unreserved_bandwidth,omitempty"` Srlgs *[]uint32 `json:"srlgs,omitempty"` SrAdjacencySID *uint32 `json:"adjacency_sid,omitempty"` } type LsAttributePrefix struct { IGPFlags *LsIGPFlags `json:"igp_flags,omitempty"` Opaque *[]byte `json:"opaque,omitempty"` SrPrefixSID *uint32 `json:"sr_prefix_sid,omitempty"` } type LsAttribute struct { Node LsAttributeNode `json:"node"` Link LsAttributeLink `json:"link"` Prefix LsAttributePrefix `json:"prefix"` } type PathAttributeLs struct { PathAttribute TLVs []LsTLVInterface } func (p *PathAttributeLs) Extract() *LsAttribute { l := &LsAttribute{} for _, tlv := range p.TLVs { switch v := tlv.(type) { case *LsTLVNodeFlagBits: l.Node.Flags = v.Extract() case *LsTLVOpaqueNodeAttr: l.Node.Opaque = &v.Attr case *LsTLVNodeName: l.Node.Name = &v.Name case *LsTLVIsisArea: l.Node.IsisArea = &v.Area case *LsTLVLocalIPv4RouterID: l.Node.LocalRouterID = &v.IP l.Link.LocalRouterID = &v.IP case *LsTLVLocalIPv6RouterID: l.Node.LocalRouterIDv6 = &v.IP l.Link.LocalRouterIDv6 = &v.IP case *LsTLVSrCapabilities: l.Node.SrCapabilties = v.Extract() case *LsTLVSrAlgorithm: l.Node.SrAlgorithms = &v.Algorithm case *LsTLVSrLocalBlock: l.Node.SrLocalBlock = v.Extract() case *LsTLVRemoteIPv4RouterID: l.Link.RemoteRouterID = &v.IP case *LsTLVRemoteIPv6RouterID: l.Link.RemoteRouterIDv6 = &v.IP case *LsTLVAdminGroup: l.Link.AdminGroup = &v.AdminGroup case *LsTLVMaxLinkBw: l.Link.Bandwidth = &v.Bandwidth case *LsTLVMaxReservableLinkBw: l.Link.ReservableBandwidth = &v.Bandwidth case *LsTLVUnreservedBw: l.Link.UnreservedBandwidth = &v.Bandwidth case *LsTLVSrlg: l.Link.Srlgs = &v.Srlgs case *LsTLVTEDefaultMetric: l.Link.DefaultTEMetric = &v.Metric case *LsTLVIGPMetric: l.Link.IGPMetric = &v.Metric case *LsTLVOpaqueLinkAttr: l.Link.Opaque = &v.Attr case *LsTLVLinkName: l.Link.Name = &v.Name case *LsTLVAdjacencySID: l.Link.SrAdjacencySID = &v.SID case *LsTLVIGPFlags: l.Prefix.IGPFlags = v.Extract() case *LsTLVOpaquePrefixAttr: l.Prefix.Opaque = &v.Attr case *LsTLVPrefixSID: l.Prefix.SrPrefixSID = &v.SID } } return l } func (p *PathAttributeLs) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { tlvs, err := p.PathAttribute.DecodeFromBytes(data) if err != nil { return err } for len(tlvs) >= tlvHdrLen { t := &LsTLV{} _, err := t.DecodeFromBytes(tlvs) if err != nil { return err } var tlv LsTLVInterface switch t.Type { // Node NLRI-related TLVs (https://tools.ietf.org/html/rfc7752#section-3.3.1) case LS_TLV_NODE_FLAG_BITS: tlv = &LsTLVNodeFlagBits{} case LS_TLV_OPAQUE_NODE_ATTR: tlv = &LsTLVOpaqueNodeAttr{} case LS_TLV_NODE_NAME: tlv = &LsTLVNodeName{} case LS_TLV_ISIS_AREA: tlv = &LsTLVIsisArea{} // Used by Link NLRI as well. case LS_TLV_IPV4_LOCAL_ROUTER_ID: tlv = &LsTLVLocalIPv4RouterID{} // Used by Link NLRI as well. case LS_TLV_IPV6_LOCAL_ROUTER_ID: tlv = &LsTLVLocalIPv6RouterID{} // SR-related TLVs (draft-ietf-idr-bgp-ls-segment-routing-ext-08) for Node NLRI case LS_TLV_SR_CAPABILITIES: tlv = &LsTLVSrCapabilities{} case LS_TLV_SR_ALGORITHM: tlv = &LsTLVSrAlgorithm{} case LS_TLV_SR_LOCAL_BLOCK: tlv = &LsTLVSrLocalBlock{} // Link NLRI-related TLVs (https://tools.ietf.org/html/rfc7752#section-3.3.2) case LS_TLV_IPV4_REMOTE_ROUTER_ID: tlv = &LsTLVRemoteIPv4RouterID{} case LS_TLV_IPV6_REMOTE_ROUTER_ID: tlv = &LsTLVRemoteIPv6RouterID{} case LS_TLV_ADMIN_GROUP: tlv = &LsTLVAdminGroup{} case LS_TLV_MAX_LINK_BANDWIDTH: tlv = &LsTLVMaxLinkBw{} case LS_TLV_MAX_RESERVABLE_BANDWIDTH: tlv = &LsTLVMaxReservableLinkBw{} case LS_TLV_UNRESERVED_BANDWIDTH: tlv = &LsTLVUnreservedBw{} case LS_TLV_SRLG: tlv = &LsTLVSrlg{} case LS_TLV_TE_DEFAULT_METRIC: tlv = &LsTLVTEDefaultMetric{} case LS_TLV_IGP_METRIC: tlv = &LsTLVIGPMetric{} case LS_TLV_OPAQUE_LINK_ATTR: tlv = &LsTLVOpaqueLinkAttr{} case LS_TLV_LINK_NAME: tlv = &LsTLVLinkName{} // SR-related TLVs (draft-ietf-idr-bgp-ls-segment-routing-ext-08) for Link NLRI case LS_TLV_ADJACENCY_SID: tlv = &LsTLVAdjacencySID{} // Prefix NLRI-related TLVs (https://tools.ietf.org/html/rfc7752#section-3.3.3) case LS_TLV_IGP_FLAGS: tlv = &LsTLVIGPFlags{} case LS_TLV_OPAQUE_PREFIX_ATTR: tlv = &LsTLVOpaquePrefixAttr{} // SR-related TLVs (draft-ietf-idr-bgp-ls-segment-routing-ext-08) for Prefix NLRI case LS_TLV_PREFIX_SID: tlv = &LsTLVPrefixSID{} default: tlvs = tlvs[t.Len():] continue } if err := tlv.DecodeFromBytes(tlvs); err != nil { return err } tlvs = tlvs[t.Len():] p.TLVs = append(p.TLVs, tlv) } return nil } func (p *PathAttributeLs) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := []byte{} for _, tlv := range p.TLVs { s, err := tlv.Serialize() if err != nil { return nil, err } buf = append(buf, s...) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeLs) String() string { var buf bytes.Buffer for _, tlv := range p.TLVs { buf.WriteString(fmt.Sprintf("%s ", tlv.String())) } return fmt.Sprintf("{LsAttributes: %s}", buf.String()) } func (p *PathAttributeLs) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Flags BGPAttrFlag `json:"flags"` LsAttribute }{ p.GetType(), p.GetFlags(), *p.Extract(), }) } func AfiSafiToRouteFamily(afi uint16, safi uint8) RouteFamily { return RouteFamily(int(afi)<<16 | int(safi)) } func RouteFamilyToAfiSafi(rf RouteFamily) (uint16, uint8) { return uint16(int(rf) >> 16), uint8(int(rf) & 0xff) } type RouteFamily int func (f RouteFamily) String() string { if n, y := AddressFamilyNameMap[f]; y { return n } return fmt.Sprintf("UnknownFamily(%d)", f) } const ( RF_IPv4_UC RouteFamily = AFI_IP<<16 | SAFI_UNICAST RF_IPv6_UC RouteFamily = AFI_IP6<<16 | SAFI_UNICAST RF_IPv4_MC RouteFamily = AFI_IP<<16 | SAFI_MULTICAST RF_IPv6_MC RouteFamily = AFI_IP6<<16 | SAFI_MULTICAST RF_IPv4_VPN RouteFamily = AFI_IP<<16 | SAFI_MPLS_VPN RF_IPv6_VPN RouteFamily = AFI_IP6<<16 | SAFI_MPLS_VPN RF_IPv4_VPN_MC RouteFamily = AFI_IP<<16 | SAFI_MPLS_VPN_MULTICAST RF_IPv6_VPN_MC RouteFamily = AFI_IP6<<16 | SAFI_MPLS_VPN_MULTICAST RF_IPv4_MPLS RouteFamily = AFI_IP<<16 | SAFI_MPLS_LABEL RF_IPv6_MPLS RouteFamily = AFI_IP6<<16 | SAFI_MPLS_LABEL RF_VPLS RouteFamily = AFI_L2VPN<<16 | SAFI_VPLS RF_EVPN RouteFamily = AFI_L2VPN<<16 | SAFI_EVPN RF_RTC_UC RouteFamily = AFI_IP<<16 | SAFI_ROUTE_TARGET_CONSTRAINTS RF_IPv4_ENCAP RouteFamily = AFI_IP<<16 | SAFI_ENCAPSULATION RF_IPv6_ENCAP RouteFamily = AFI_IP6<<16 | SAFI_ENCAPSULATION RF_FS_IPv4_UC RouteFamily = AFI_IP<<16 | SAFI_FLOW_SPEC_UNICAST RF_FS_IPv4_VPN RouteFamily = AFI_IP<<16 | SAFI_FLOW_SPEC_VPN RF_FS_IPv6_UC RouteFamily = AFI_IP6<<16 | SAFI_FLOW_SPEC_UNICAST RF_FS_IPv6_VPN RouteFamily = AFI_IP6<<16 | SAFI_FLOW_SPEC_VPN RF_FS_L2_VPN RouteFamily = AFI_L2VPN<<16 | SAFI_FLOW_SPEC_VPN RF_OPAQUE RouteFamily = AFI_OPAQUE<<16 | SAFI_KEY_VALUE RF_LS RouteFamily = AFI_LS<<16 | SAFI_LS RF_SR_POLICY_IPv4 RouteFamily = AFI_IP<<16 | SAFI_SRPOLICY RF_SR_POLICY_IPv6 RouteFamily = AFI_IP6<<16 | SAFI_SRPOLICY ) var AddressFamilyNameMap = map[RouteFamily]string{ RF_IPv4_UC: "ipv4-unicast", RF_IPv6_UC: "ipv6-unicast", RF_IPv4_MC: "ipv4-multicast", RF_IPv6_MC: "ipv6-multicast", RF_IPv4_MPLS: "ipv4-labelled-unicast", RF_IPv6_MPLS: "ipv6-labelled-unicast", RF_IPv4_VPN: "l3vpn-ipv4-unicast", RF_IPv6_VPN: "l3vpn-ipv6-unicast", RF_IPv4_VPN_MC: "l3vpn-ipv4-multicast", RF_IPv6_VPN_MC: "l3vpn-ipv6-multicast", RF_VPLS: "l2vpn-vpls", RF_EVPN: "l2vpn-evpn", RF_RTC_UC: "rtc", RF_IPv4_ENCAP: "ipv4-encap", RF_IPv6_ENCAP: "ipv6-encap", RF_FS_IPv4_UC: "ipv4-flowspec", RF_FS_IPv4_VPN: "l3vpn-ipv4-flowspec", RF_FS_IPv6_UC: "ipv6-flowspec", RF_FS_IPv6_VPN: "l3vpn-ipv6-flowspec", RF_FS_L2_VPN: "l2vpn-flowspec", RF_OPAQUE: "opaque", RF_LS: "ls", RF_SR_POLICY_IPv4: "ipv4-srpolicy", RF_SR_POLICY_IPv6: "ipv6-srpolicy", } var AddressFamilyValueMap = map[string]RouteFamily{ AddressFamilyNameMap[RF_IPv4_UC]: RF_IPv4_UC, AddressFamilyNameMap[RF_IPv6_UC]: RF_IPv6_UC, AddressFamilyNameMap[RF_IPv4_MC]: RF_IPv4_MC, AddressFamilyNameMap[RF_IPv6_MC]: RF_IPv6_MC, AddressFamilyNameMap[RF_IPv4_MPLS]: RF_IPv4_MPLS, AddressFamilyNameMap[RF_IPv6_MPLS]: RF_IPv6_MPLS, AddressFamilyNameMap[RF_IPv4_VPN]: RF_IPv4_VPN, AddressFamilyNameMap[RF_IPv6_VPN]: RF_IPv6_VPN, AddressFamilyNameMap[RF_IPv4_VPN_MC]: RF_IPv4_VPN_MC, AddressFamilyNameMap[RF_IPv6_VPN_MC]: RF_IPv6_VPN_MC, AddressFamilyNameMap[RF_VPLS]: RF_VPLS, AddressFamilyNameMap[RF_EVPN]: RF_EVPN, AddressFamilyNameMap[RF_RTC_UC]: RF_RTC_UC, AddressFamilyNameMap[RF_IPv4_ENCAP]: RF_IPv4_ENCAP, AddressFamilyNameMap[RF_IPv6_ENCAP]: RF_IPv6_ENCAP, AddressFamilyNameMap[RF_FS_IPv4_UC]: RF_FS_IPv4_UC, AddressFamilyNameMap[RF_FS_IPv4_VPN]: RF_FS_IPv4_VPN, AddressFamilyNameMap[RF_FS_IPv6_UC]: RF_FS_IPv6_UC, AddressFamilyNameMap[RF_FS_IPv6_VPN]: RF_FS_IPv6_VPN, AddressFamilyNameMap[RF_FS_L2_VPN]: RF_FS_L2_VPN, AddressFamilyNameMap[RF_OPAQUE]: RF_OPAQUE, AddressFamilyNameMap[RF_LS]: RF_LS, AddressFamilyNameMap[RF_SR_POLICY_IPv4]: RF_SR_POLICY_IPv4, AddressFamilyNameMap[RF_SR_POLICY_IPv6]: RF_SR_POLICY_IPv6, } func GetRouteFamily(name string) (RouteFamily, error) { if v, ok := AddressFamilyValueMap[name]; ok { return v, nil } return RouteFamily(0), fmt.Errorf("%s isn't a valid route family name", name) } func NewPrefixFromRouteFamily(afi uint16, safi uint8, prefixStr ...string) (prefix AddrPrefixInterface, err error) { family := AfiSafiToRouteFamily(afi, safi) f := func(s string) AddrPrefixInterface { addr, net, _ := net.ParseCIDR(s) len, _ := net.Mask.Size() switch family { case RF_IPv4_UC, RF_IPv4_MC: return NewIPAddrPrefix(uint8(len), addr.String()) } return NewIPv6AddrPrefix(uint8(len), addr.String()) } switch family { case RF_IPv4_UC, RF_IPv4_MC: if len(prefixStr) > 0 { prefix = f(prefixStr[0]) } else { prefix = NewIPAddrPrefix(0, "") } case RF_IPv6_UC, RF_IPv6_MC: if len(prefixStr) > 0 { prefix = f(prefixStr[0]) } else { prefix = NewIPv6AddrPrefix(0, "") } case RF_IPv4_VPN: prefix = NewLabeledVPNIPAddrPrefix(0, "", *NewMPLSLabelStack(), nil) case RF_IPv6_VPN: prefix = NewLabeledVPNIPv6AddrPrefix(0, "", *NewMPLSLabelStack(), nil) case RF_IPv4_MPLS: prefix = NewLabeledIPAddrPrefix(0, "", *NewMPLSLabelStack()) case RF_IPv6_MPLS: prefix = NewLabeledIPv6AddrPrefix(0, "", *NewMPLSLabelStack()) case RF_EVPN: prefix = NewEVPNNLRI(0, nil) // TODO (sbezverk) Add processing SR Policy NLRI case RF_SR_POLICY_IPv4: prefix = &SRPolicyIPv4{ SRPolicyNLRI: SRPolicyNLRI{ rf: RF_SR_POLICY_IPv4, }, } case RF_SR_POLICY_IPv6: prefix = &SRPolicyIPv6{ SRPolicyNLRI: SRPolicyNLRI{ rf: RF_SR_POLICY_IPv6, }, } case RF_RTC_UC: prefix = &RouteTargetMembershipNLRI{} case RF_IPv4_ENCAP: prefix = NewEncapNLRI("") case RF_IPv6_ENCAP: prefix = NewEncapv6NLRI("") case RF_FS_IPv4_UC: prefix = &FlowSpecIPv4Unicast{FlowSpecNLRI{rf: RF_FS_IPv4_UC}} case RF_FS_IPv4_VPN: prefix = &FlowSpecIPv4VPN{FlowSpecNLRI{rf: RF_FS_IPv4_VPN}} case RF_FS_IPv6_UC: prefix = &FlowSpecIPv6Unicast{FlowSpecNLRI{rf: RF_FS_IPv6_UC}} case RF_FS_IPv6_VPN: prefix = &FlowSpecIPv6VPN{FlowSpecNLRI{rf: RF_FS_IPv6_VPN}} case RF_FS_L2_VPN: prefix = &FlowSpecL2VPN{FlowSpecNLRI{rf: RF_FS_L2_VPN}} case RF_OPAQUE: prefix = &OpaqueNLRI{} case RF_LS: prefix = &LsAddrPrefix{} default: err = fmt.Errorf("unknown route family. AFI: %d, SAFI: %d", afi, safi) } return prefix, err } type BGPAttrFlag uint8 const ( BGP_ATTR_FLAG_EXTENDED_LENGTH BGPAttrFlag = 1 << 4 BGP_ATTR_FLAG_PARTIAL BGPAttrFlag = 1 << 5 BGP_ATTR_FLAG_TRANSITIVE BGPAttrFlag = 1 << 6 BGP_ATTR_FLAG_OPTIONAL BGPAttrFlag = 1 << 7 ) func (f BGPAttrFlag) String() string { strs := make([]string, 0, 4) if f&BGP_ATTR_FLAG_EXTENDED_LENGTH > 0 { strs = append(strs, "EXTENDED_LENGTH") } if f&BGP_ATTR_FLAG_PARTIAL > 0 { strs = append(strs, "PARTIAL") } if f&BGP_ATTR_FLAG_TRANSITIVE > 0 { strs = append(strs, "TRANSITIVE") } if f&BGP_ATTR_FLAG_OPTIONAL > 0 { strs = append(strs, "OPTIONAL") } return strings.Join(strs, "|") } //go:generate stringer -type=BGPAttrType type BGPAttrType uint8 const ( _ BGPAttrType = iota BGP_ATTR_TYPE_ORIGIN BGP_ATTR_TYPE_AS_PATH BGP_ATTR_TYPE_NEXT_HOP BGP_ATTR_TYPE_MULTI_EXIT_DISC BGP_ATTR_TYPE_LOCAL_PREF BGP_ATTR_TYPE_ATOMIC_AGGREGATE BGP_ATTR_TYPE_AGGREGATOR BGP_ATTR_TYPE_COMMUNITIES BGP_ATTR_TYPE_ORIGINATOR_ID BGP_ATTR_TYPE_CLUSTER_LIST _ _ _ BGP_ATTR_TYPE_MP_REACH_NLRI // = 14 BGP_ATTR_TYPE_MP_UNREACH_NLRI BGP_ATTR_TYPE_EXTENDED_COMMUNITIES BGP_ATTR_TYPE_AS4_PATH BGP_ATTR_TYPE_AS4_AGGREGATOR _ _ _ BGP_ATTR_TYPE_PMSI_TUNNEL // = 22 BGP_ATTR_TYPE_TUNNEL_ENCAP _ BGP_ATTR_TYPE_IP6_EXTENDED_COMMUNITIES // = 25 BGP_ATTR_TYPE_AIGP // = 26 _ _ BGP_ATTR_TYPE_LS // = 29 BGP_ATTR_TYPE_LARGE_COMMUNITY BGPAttrType = 32 BGP_ATTR_TYPE_PREFIX_SID BGPAttrType = 40 ) // NOTIFICATION Error Code RFC 4271 4.5. const ( _ = iota BGP_ERROR_MESSAGE_HEADER_ERROR BGP_ERROR_OPEN_MESSAGE_ERROR BGP_ERROR_UPDATE_MESSAGE_ERROR BGP_ERROR_HOLD_TIMER_EXPIRED BGP_ERROR_FSM_ERROR BGP_ERROR_CEASE BGP_ERROR_ROUTE_REFRESH_MESSAGE_ERROR ) // NOTIFICATION Error Subcode for BGP_ERROR_MESSAGE_HEADER_ERROR const ( _ = iota BGP_ERROR_SUB_CONNECTION_NOT_SYNCHRONIZED BGP_ERROR_SUB_BAD_MESSAGE_LENGTH BGP_ERROR_SUB_BAD_MESSAGE_TYPE ) // NOTIFICATION Error Subcode for BGP_ERROR_OPEN_MESSAGE_ERROR const ( _ = iota BGP_ERROR_SUB_UNSUPPORTED_VERSION_NUMBER BGP_ERROR_SUB_BAD_PEER_AS BGP_ERROR_SUB_BAD_BGP_IDENTIFIER BGP_ERROR_SUB_UNSUPPORTED_OPTIONAL_PARAMETER BGP_ERROR_SUB_DEPRECATED_AUTHENTICATION_FAILURE BGP_ERROR_SUB_UNACCEPTABLE_HOLD_TIME BGP_ERROR_SUB_UNSUPPORTED_CAPABILITY ) // NOTIFICATION Error Subcode for BGP_ERROR_UPDATE_MESSAGE_ERROR const ( _ = iota BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST BGP_ERROR_SUB_UNRECOGNIZED_WELL_KNOWN_ATTRIBUTE BGP_ERROR_SUB_MISSING_WELL_KNOWN_ATTRIBUTE BGP_ERROR_SUB_ATTRIBUTE_FLAGS_ERROR BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR BGP_ERROR_SUB_INVALID_ORIGIN_ATTRIBUTE BGP_ERROR_SUB_DEPRECATED_ROUTING_LOOP BGP_ERROR_SUB_INVALID_NEXT_HOP_ATTRIBUTE BGP_ERROR_SUB_OPTIONAL_ATTRIBUTE_ERROR BGP_ERROR_SUB_INVALID_NETWORK_FIELD BGP_ERROR_SUB_MALFORMED_AS_PATH ) // NOTIFICATION Error Subcode for BGP_ERROR_HOLD_TIMER_EXPIRED const ( _ = iota BGP_ERROR_SUB_HOLD_TIMER_EXPIRED ) // NOTIFICATION Error Subcode for BGP_ERROR_FSM_ERROR const ( _ = iota BGP_ERROR_SUB_RECEIVE_UNEXPECTED_MESSAGE_IN_OPENSENT_STATE BGP_ERROR_SUB_RECEIVE_UNEXPECTED_MESSAGE_IN_OPENCONFIRM_STATE BGP_ERROR_SUB_RECEIVE_UNEXPECTED_MESSAGE_IN_ESTABLISHED_STATE ) // NOTIFICATION Error Subcode for BGP_ERROR_CEASE (RFC 4486) const ( _ = iota BGP_ERROR_SUB_MAXIMUM_NUMBER_OF_PREFIXES_REACHED BGP_ERROR_SUB_ADMINISTRATIVE_SHUTDOWN BGP_ERROR_SUB_PEER_DECONFIGURED BGP_ERROR_SUB_ADMINISTRATIVE_RESET BGP_ERROR_SUB_CONNECTION_REJECTED BGP_ERROR_SUB_OTHER_CONFIGURATION_CHANGE BGP_ERROR_SUB_CONNECTION_COLLISION_RESOLUTION BGP_ERROR_SUB_OUT_OF_RESOURCES BGP_ERROR_SUB_HARD_RESET //draft-ietf-idr-bgp-gr-notification-07 ) // Constants for BGP_ERROR_SUB_ADMINISTRATIVE_SHUTDOWN and BGP_ERROR_SUB_ADMINISTRATIVE_RESET const ( BGP_ERROR_ADMINISTRATIVE_COMMUNICATION_MAX = 128 ) // NOTIFICATION Error Subcode for BGP_ERROR_ROUTE_REFRESH const ( _ = iota BGP_ERROR_SUB_INVALID_MESSAGE_LENGTH ) type NotificationErrorCode uint16 func (c NotificationErrorCode) String() string { code := uint8(uint16(c) >> 8) subcode := uint8(uint16(c) & 0xff) UNDEFINED := "undefined" codeStr := UNDEFINED subcodeList := []string{} switch code { case BGP_ERROR_MESSAGE_HEADER_ERROR: codeStr = "header" subcodeList = []string{ UNDEFINED, "connection not synchronized", "bad message length", "bad message type"} case BGP_ERROR_OPEN_MESSAGE_ERROR: codeStr = "open" subcodeList = []string{ UNDEFINED, "unsupported version number", "bad peer as", "bad bgp identifier", "unsupported optional parameter", "deprecated authentication failure", "unacceptable hold time", "unsupported capability"} case BGP_ERROR_UPDATE_MESSAGE_ERROR: codeStr = "update" subcodeList = []string{ UNDEFINED, "malformed attribute list", "unrecognized well known attribute", "missing well known attribute", "attribute flags error", "attribute length error", "invalid origin attribute", "deprecated routing loop", "invalid next hop attribute", "optional attribute error", "invalid network field", "sub malformed as path"} case BGP_ERROR_HOLD_TIMER_EXPIRED: codeStr = "hold timer expired" subcodeList = []string{ UNDEFINED, "hold timer expired"} case BGP_ERROR_FSM_ERROR: codeStr = "fsm" subcodeList = []string{ UNDEFINED, "receive unexpected message in opensent state", "receive unexpected message in openconfirm state", "receive unexpected message in established state"} case BGP_ERROR_CEASE: codeStr = "cease" subcodeList = []string{ UNDEFINED, "maximum number of prefixes reached", "administrative shutdown", "peer deconfigured", "administrative reset", "connection rejected", "other configuration change", "connection collision resolution", "out of resources"} case BGP_ERROR_ROUTE_REFRESH_MESSAGE_ERROR: codeStr = "route refresh" subcodeList = []string{"invalid message length"} } subcodeStr := func(idx uint8, l []string) string { if len(l) == 0 || int(idx) > len(l)-1 { return UNDEFINED } return l[idx] }(subcode, subcodeList) return fmt.Sprintf("code %v(%v) subcode %v(%v)", code, codeStr, subcode, subcodeStr) } func NewNotificationErrorCode(code, subcode uint8) NotificationErrorCode { return NotificationErrorCode(uint16(code)<<8 | uint16(subcode)) } var PathAttrFlags map[BGPAttrType]BGPAttrFlag = map[BGPAttrType]BGPAttrFlag{ BGP_ATTR_TYPE_ORIGIN: BGP_ATTR_FLAG_TRANSITIVE, BGP_ATTR_TYPE_AS_PATH: BGP_ATTR_FLAG_TRANSITIVE, BGP_ATTR_TYPE_NEXT_HOP: BGP_ATTR_FLAG_TRANSITIVE, BGP_ATTR_TYPE_MULTI_EXIT_DISC: BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_LOCAL_PREF: BGP_ATTR_FLAG_TRANSITIVE, BGP_ATTR_TYPE_ATOMIC_AGGREGATE: BGP_ATTR_FLAG_TRANSITIVE, BGP_ATTR_TYPE_AGGREGATOR: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_COMMUNITIES: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_ORIGINATOR_ID: BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_CLUSTER_LIST: BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_MP_REACH_NLRI: BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_MP_UNREACH_NLRI: BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_EXTENDED_COMMUNITIES: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_AS4_PATH: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_AS4_AGGREGATOR: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_PMSI_TUNNEL: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_TUNNEL_ENCAP: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_IP6_EXTENDED_COMMUNITIES: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_AIGP: BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_LARGE_COMMUNITY: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_LS: BGP_ATTR_FLAG_OPTIONAL, BGP_ATTR_TYPE_PREFIX_SID: BGP_ATTR_FLAG_TRANSITIVE | BGP_ATTR_FLAG_OPTIONAL, } // getPathAttrFlags returns BGP Path Attribute flags value from its type and // length (byte length of value field). func getPathAttrFlags(typ BGPAttrType, length int) BGPAttrFlag { flags := PathAttrFlags[typ] if length > 255 { flags |= BGP_ATTR_FLAG_EXTENDED_LENGTH } return flags } type PathAttributeInterface interface { DecodeFromBytes([]byte, ...*MarshallingOption) error Serialize(...*MarshallingOption) ([]byte, error) Len(...*MarshallingOption) int GetFlags() BGPAttrFlag GetType() BGPAttrType String() string MarshalJSON() ([]byte, error) Flat() map[string]string } type PathAttribute struct { Flags BGPAttrFlag Type BGPAttrType Length uint16 // length of Value } func (p *PathAttribute) Len(options ...*MarshallingOption) int { if p.Flags&BGP_ATTR_FLAG_EXTENDED_LENGTH != 0 { return 4 + int(p.Length) } return 3 + int(p.Length) } func (p *PathAttribute) GetFlags() BGPAttrFlag { return p.Flags } func (p *PathAttribute) GetType() BGPAttrType { return p.Type } func (p *PathAttribute) DecodeFromBytes(data []byte, options ...*MarshallingOption) (value []byte, err error) { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) if len(data) < 2 { return nil, NewMessageError(eCode, eSubCode, data, "attribute header length is short") } p.Flags = BGPAttrFlag(data[0]) p.Type = BGPAttrType(data[1]) if eMsg := validatePathAttributeFlags(p.Type, p.Flags); eMsg != "" { return nil, NewMessageError(eCode, BGP_ERROR_SUB_ATTRIBUTE_FLAGS_ERROR, data, eMsg) } if p.Flags&BGP_ATTR_FLAG_EXTENDED_LENGTH != 0 { if len(data) < 4 { return nil, NewMessageError(eCode, eSubCode, data, "attribute header length is short") } p.Length = binary.BigEndian.Uint16(data[2:4]) data = data[4:] } else { if len(data) < 3 { return nil, NewMessageError(eCode, eSubCode, data, "attribute header length is short") } p.Length = uint16(data[2]) data = data[3:] } if len(data) < int(p.Length) { return nil, NewMessageError(eCode, eSubCode, data, "attribute value length is short") } return data[:p.Length], nil } func (p *PathAttribute) Serialize(value []byte, options ...*MarshallingOption) ([]byte, error) { // Note: Do not update "p.Flags" and "p.Length" to avoid data race. flags := p.Flags length := uint16(len(value)) if flags&BGP_ATTR_FLAG_EXTENDED_LENGTH == 0 && length > 255 { flags |= BGP_ATTR_FLAG_EXTENDED_LENGTH } var buf []byte if flags&BGP_ATTR_FLAG_EXTENDED_LENGTH != 0 { buf = append(make([]byte, 4), value...) binary.BigEndian.PutUint16(buf[2:4], length) } else { buf = append(make([]byte, 3), value...) buf[2] = byte(length) } buf[0] = uint8(flags) buf[1] = uint8(p.Type) return buf, nil } type PathAttributeOrigin struct { PathAttribute Value uint8 } func (p *PathAttributeOrigin) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length != 1 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) return NewMessageError(eCode, eSubCode, nil, "Origin attribute length is incorrect") } p.Value = value[0] return nil } func (p *PathAttributeOrigin) Serialize(options ...*MarshallingOption) ([]byte, error) { return p.PathAttribute.Serialize([]byte{p.Value}, options...) } func (p *PathAttributeOrigin) String() string { typ := "-" switch p.Value { case BGP_ORIGIN_ATTR_TYPE_IGP: typ = "i" case BGP_ORIGIN_ATTR_TYPE_EGP: typ = "e" case BGP_ORIGIN_ATTR_TYPE_INCOMPLETE: typ = "?" } return fmt.Sprintf("{Origin: %s}", typ) } func (p *PathAttributeOrigin) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value uint8 `json:"value"` }{ Type: p.GetType(), Value: p.Value, }) } func NewPathAttributeOrigin(value uint8) *PathAttributeOrigin { t := BGP_ATTR_TYPE_ORIGIN return &PathAttributeOrigin{ PathAttribute: PathAttribute{ Flags: PathAttrFlags[t], Type: t, Length: 1, }, Value: value, } } type AsPathParamFormat struct { start string end string separator string } var asPathParamFormatMap = map[uint8]*AsPathParamFormat{ BGP_ASPATH_ATTR_TYPE_SET: {"{", "}", ","}, BGP_ASPATH_ATTR_TYPE_SEQ: {"", "", " "}, BGP_ASPATH_ATTR_TYPE_CONFED_SET: {"(", ")", " "}, BGP_ASPATH_ATTR_TYPE_CONFED_SEQ: {"[", "]", ","}, } type AsPathParamInterface interface { GetType() uint8 GetAS() []uint32 Serialize() ([]byte, error) DecodeFromBytes([]byte) error Len() int ASLen() int MarshalJSON() ([]byte, error) String() string } func AsPathString(aspath *PathAttributeAsPath) string { s := bytes.NewBuffer(make([]byte, 0, 64)) for i, param := range aspath.Value { segType := param.GetType() asList := param.GetAS() if i != 0 { s.WriteString(" ") } sep := " " switch segType { case BGP_ASPATH_ATTR_TYPE_CONFED_SEQ: s.WriteString("(") case BGP_ASPATH_ATTR_TYPE_CONFED_SET: s.WriteString("[") sep = "," case BGP_ASPATH_ATTR_TYPE_SET: s.WriteString("{") sep = "," } for j, as := range asList { s.WriteString(fmt.Sprintf("%d", as)) if j != len(asList)-1 { s.WriteString(sep) } } switch segType { case BGP_ASPATH_ATTR_TYPE_CONFED_SEQ: s.WriteString(")") case BGP_ASPATH_ATTR_TYPE_CONFED_SET: s.WriteString("]") case BGP_ASPATH_ATTR_TYPE_SET: s.WriteString("}") } } return s.String() } type AsPathParam struct { Type uint8 Num uint8 AS []uint16 } func (a *AsPathParam) GetType() uint8 { return a.Type } func (a *AsPathParam) GetAS() []uint32 { nums := make([]uint32, 0, len(a.AS)) for _, as := range a.AS { nums = append(nums, uint32(as)) } return nums } func (a *AsPathParam) Serialize() ([]byte, error) { buf := make([]byte, 2+len(a.AS)*2) buf[0] = uint8(a.Type) buf[1] = a.Num for j, as := range a.AS { binary.BigEndian.PutUint16(buf[2+j*2:], as) } return buf, nil } func (a *AsPathParam) DecodeFromBytes(data []byte) error { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_AS_PATH) if len(data) < 2 { return NewMessageError(eCode, eSubCode, nil, "AS param header length is short") } a.Type = data[0] a.Num = data[1] data = data[2:] if len(data) < int(a.Num*2) { return NewMessageError(eCode, eSubCode, nil, "AS param data length is short") } for i := 0; i < int(a.Num); i++ { a.AS = append(a.AS, binary.BigEndian.Uint16(data)) data = data[2:] } return nil } func (a *AsPathParam) Len() int { return 2 + len(a.AS)*2 } func (a *AsPathParam) ASLen() int { switch a.Type { case BGP_ASPATH_ATTR_TYPE_SEQ: return len(a.AS) case BGP_ASPATH_ATTR_TYPE_SET: return 1 case BGP_ASPATH_ATTR_TYPE_CONFED_SET, BGP_ASPATH_ATTR_TYPE_CONFED_SEQ: return 0 } return 0 } func (a *AsPathParam) String() string { format, ok := asPathParamFormatMap[a.Type] if !ok { return fmt.Sprintf("%v", a.AS) } aspath := make([]string, 0, len(a.AS)) for _, asn := range a.AS { aspath = append(aspath, strconv.FormatUint(uint64(asn), 10)) } s := bytes.NewBuffer(make([]byte, 0, 32)) s.WriteString(format.start) s.WriteString(strings.Join(aspath, format.separator)) s.WriteString(format.end) return s.String() } func (a *AsPathParam) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type uint8 `json:"segment_type"` Num uint8 `json:"num"` AS []uint16 `json:"asns"` }{ Type: a.Type, Num: a.Num, AS: a.AS, }) } func NewAsPathParam(segType uint8, as []uint16) *AsPathParam { return &AsPathParam{ Type: segType, Num: uint8(len(as)), AS: as, } } type As4PathParam struct { Type uint8 Num uint8 AS []uint32 } func (a *As4PathParam) GetType() uint8 { return a.Type } func (a *As4PathParam) GetAS() []uint32 { return a.AS } func (a *As4PathParam) Serialize() ([]byte, error) { buf := make([]byte, 2+len(a.AS)*4) buf[0] = a.Type buf[1] = a.Num for j, as := range a.AS { binary.BigEndian.PutUint32(buf[2+j*4:], as) } return buf, nil } func (a *As4PathParam) DecodeFromBytes(data []byte) error { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_AS_PATH) if len(data) < 2 { return NewMessageError(eCode, eSubCode, nil, "AS4 param header length is short") } a.Type = data[0] a.Num = data[1] data = data[2:] if len(data) < int(a.Num)*4 { return NewMessageError(eCode, eSubCode, nil, "AS4 param data length is short") } for i := 0; i < int(a.Num); i++ { a.AS = append(a.AS, binary.BigEndian.Uint32(data)) data = data[4:] } return nil } func (a *As4PathParam) Len() int { return 2 + len(a.AS)*4 } func (a *As4PathParam) ASLen() int { switch a.Type { case BGP_ASPATH_ATTR_TYPE_SEQ: return len(a.AS) case BGP_ASPATH_ATTR_TYPE_SET: return 1 case BGP_ASPATH_ATTR_TYPE_CONFED_SET, BGP_ASPATH_ATTR_TYPE_CONFED_SEQ: return 0 } return 0 } func (a *As4PathParam) String() string { format, ok := asPathParamFormatMap[a.Type] if !ok { return fmt.Sprintf("%v", a.AS) } aspath := make([]string, 0, len(a.AS)) for _, asn := range a.AS { aspath = append(aspath, strconv.FormatUint(uint64(asn), 10)) } s := bytes.NewBuffer(make([]byte, 0, 32)) s.WriteString(format.start) s.WriteString(strings.Join(aspath, format.separator)) s.WriteString(format.end) return s.String() } func (a *As4PathParam) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type uint8 `json:"segment_type"` Num uint8 `json:"num"` AS []uint32 `json:"asns"` }{ Type: a.Type, Num: a.Num, AS: a.AS, }) } func NewAs4PathParam(segType uint8, as []uint32) *As4PathParam { return &As4PathParam{ Type: segType, Num: uint8(len(as)), AS: as, } } type PathAttributeAsPath struct { PathAttribute Value []AsPathParamInterface } func (p *PathAttributeAsPath) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length == 0 { // ibgp or something return nil } isAs4, err := validateAsPathValueBytes(value) if err != nil { err.(*MessageError).Data, _ = p.PathAttribute.Serialize(value, options...) return err } for len(value) > 0 { var tuple AsPathParamInterface if isAs4 { tuple = &As4PathParam{} } else { tuple = &AsPathParam{} } err := tuple.DecodeFromBytes(value) if err != nil { return err } p.Value = append(p.Value, tuple) value = value[tuple.Len():] } return nil } func (p *PathAttributeAsPath) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 0) for _, v := range p.Value { vbuf, err := v.Serialize() if err != nil { return nil, err } buf = append(buf, vbuf...) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeAsPath) String() string { params := make([]string, 0, len(p.Value)) for _, param := range p.Value { params = append(params, param.String()) } return strings.Join(params, " ") } func (p *PathAttributeAsPath) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value []AsPathParamInterface `json:"as_paths"` }{ Type: p.GetType(), Value: p.Value, }) } func NewPathAttributeAsPath(value []AsPathParamInterface) *PathAttributeAsPath { var l int for _, v := range value { l += v.Len() } t := BGP_ATTR_TYPE_AS_PATH return &PathAttributeAsPath{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, Value: value, } } type PathAttributeNextHop struct { PathAttribute Value net.IP } func (p *PathAttributeNextHop) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length != 4 && p.Length != 16 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "nexthop length isn't correct") } p.Value = value return nil } func (p *PathAttributeNextHop) Serialize(options ...*MarshallingOption) ([]byte, error) { return p.PathAttribute.Serialize(p.Value, options...) } func (p *PathAttributeNextHop) String() string { return fmt.Sprintf("{Nexthop: %s}", p.Value) } func (p *PathAttributeNextHop) MarshalJSON() ([]byte, error) { value := "0.0.0.0" if p.Value != nil { value = p.Value.String() } return json.Marshal(struct { Type BGPAttrType `json:"type"` Value string `json:"nexthop"` }{ Type: p.GetType(), Value: value, }) } func NewPathAttributeNextHop(addr string) *PathAttributeNextHop { t := BGP_ATTR_TYPE_NEXT_HOP ip := net.ParseIP(addr) l := net.IPv4len if ip.To4() == nil { l = net.IPv6len } else { ip = ip.To4() } return &PathAttributeNextHop{ PathAttribute: PathAttribute{ Flags: PathAttrFlags[t], Type: t, Length: uint16(l), }, Value: ip, } } type PathAttributeMultiExitDisc struct { PathAttribute Value uint32 } func (p *PathAttributeMultiExitDisc) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length != 4 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "med length isn't correct") } p.Value = binary.BigEndian.Uint32(value) return nil } func (p *PathAttributeMultiExitDisc) Serialize(options ...*MarshallingOption) ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:], p.Value) return p.PathAttribute.Serialize(buf[:], options...) } func (p *PathAttributeMultiExitDisc) String() string { return fmt.Sprintf("{Med: %d}", p.Value) } func (p *PathAttributeMultiExitDisc) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value uint32 `json:"metric"` }{ Type: p.GetType(), Value: p.Value, }) } func NewPathAttributeMultiExitDisc(value uint32) *PathAttributeMultiExitDisc { t := BGP_ATTR_TYPE_MULTI_EXIT_DISC return &PathAttributeMultiExitDisc{ PathAttribute: PathAttribute{ Flags: PathAttrFlags[t], Type: t, Length: 4, }, Value: value, } } type PathAttributeLocalPref struct { PathAttribute Value uint32 } func (p *PathAttributeLocalPref) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length != 4 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "local pref length isn't correct") } p.Value = binary.BigEndian.Uint32(value) return nil } func (p *PathAttributeLocalPref) Serialize(options ...*MarshallingOption) ([]byte, error) { var buf [4]byte binary.BigEndian.PutUint32(buf[:], p.Value) return p.PathAttribute.Serialize(buf[:], options...) } func (p *PathAttributeLocalPref) String() string { return fmt.Sprintf("{LocalPref: %d}", p.Value) } func (p *PathAttributeLocalPref) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value uint32 `json:"value"` }{ Type: p.GetType(), Value: p.Value, }) } func NewPathAttributeLocalPref(value uint32) *PathAttributeLocalPref { t := BGP_ATTR_TYPE_LOCAL_PREF return &PathAttributeLocalPref{ PathAttribute: PathAttribute{ Flags: PathAttrFlags[t], Type: t, Length: 4, }, Value: value, } } type PathAttributeAtomicAggregate struct { PathAttribute } func (p *PathAttributeAtomicAggregate) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { _, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length != 0 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "atomic aggregate should have no value") } return nil } func (p *PathAttributeAtomicAggregate) Serialize(options ...*MarshallingOption) ([]byte, error) { return p.PathAttribute.Serialize(nil, options...) } func (p *PathAttributeAtomicAggregate) String() string { return "{AtomicAggregate}" } func (p *PathAttributeAtomicAggregate) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` }{ Type: p.GetType(), }) } func NewPathAttributeAtomicAggregate() *PathAttributeAtomicAggregate { t := BGP_ATTR_TYPE_ATOMIC_AGGREGATE return &PathAttributeAtomicAggregate{ PathAttribute: PathAttribute{ Flags: PathAttrFlags[t], Type: t, Length: 0, }, } } type PathAttributeAggregatorParam struct { AS uint32 Askind reflect.Kind Address net.IP } type PathAttributeAggregator struct { PathAttribute Value PathAttributeAggregatorParam } func (p *PathAttributeAggregator) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } switch p.Length { case 6: p.Value.Askind = reflect.Uint16 p.Value.AS = uint32(binary.BigEndian.Uint16(value[0:2])) p.Value.Address = value[2:] case 8: p.Value.Askind = reflect.Uint32 p.Value.AS = binary.BigEndian.Uint32(value[0:4]) p.Value.Address = value[4:] default: eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "aggregator length isn't correct") } return nil } func (p *PathAttributeAggregator) Serialize(options ...*MarshallingOption) ([]byte, error) { var buf []byte switch p.Value.Askind { case reflect.Uint16: buf = make([]byte, 6) binary.BigEndian.PutUint16(buf, uint16(p.Value.AS)) copy(buf[2:], p.Value.Address) case reflect.Uint32: buf = make([]byte, 8) binary.BigEndian.PutUint32(buf, p.Value.AS) copy(buf[4:], p.Value.Address) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeAggregator) String() string { return fmt.Sprintf("{Aggregate: {AS: %d, Address: %s}}", p.Value.AS, p.Value.Address) } func (p *PathAttributeAggregator) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` AS uint32 `json:"as"` Address string `json:"address"` }{ Type: p.GetType(), AS: p.Value.AS, Address: p.Value.Address.String(), }) } func NewPathAttributeAggregator(as interface{}, address string) *PathAttributeAggregator { v := reflect.ValueOf(as) asKind := v.Kind() var l uint16 switch asKind { case reflect.Uint16: l = 6 case reflect.Uint32: l = 8 default: // Invalid type return nil } t := BGP_ATTR_TYPE_AGGREGATOR return &PathAttributeAggregator{ PathAttribute: PathAttribute{ Flags: PathAttrFlags[t], Type: t, Length: l, }, Value: PathAttributeAggregatorParam{ AS: uint32(v.Uint()), Askind: asKind, Address: net.ParseIP(address).To4(), }, } } type PathAttributeCommunities struct { PathAttribute Value []uint32 } func (p *PathAttributeCommunities) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length%4 != 0 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "communities length isn't correct") } for len(value) >= 4 { p.Value = append(p.Value, binary.BigEndian.Uint32(value)) value = value[4:] } return nil } func (p *PathAttributeCommunities) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, len(p.Value)*4) for i, v := range p.Value { binary.BigEndian.PutUint32(buf[i*4:], v) } return p.PathAttribute.Serialize(buf, options...) } type WellKnownCommunity uint32 const ( COMMUNITY_INTERNET WellKnownCommunity = 0x00000000 COMMUNITY_PLANNED_SHUT WellKnownCommunity = 0xffff0000 COMMUNITY_ACCEPT_OWN WellKnownCommunity = 0xffff0001 COMMUNITY_ROUTE_FILTER_TRANSLATED_v4 WellKnownCommunity = 0xffff0002 COMMUNITY_ROUTE_FILTER_v4 WellKnownCommunity = 0xffff0003 COMMUNITY_ROUTE_FILTER_TRANSLATED_v6 WellKnownCommunity = 0xffff0004 COMMUNITY_ROUTE_FILTER_v6 WellKnownCommunity = 0xffff0005 COMMUNITY_LLGR_STALE WellKnownCommunity = 0xffff0006 COMMUNITY_NO_LLGR WellKnownCommunity = 0xffff0007 COMMUNITY_BLACKHOLE WellKnownCommunity = 0xffff029a COMMUNITY_NO_EXPORT WellKnownCommunity = 0xffffff01 COMMUNITY_NO_ADVERTISE WellKnownCommunity = 0xffffff02 COMMUNITY_NO_EXPORT_SUBCONFED WellKnownCommunity = 0xffffff03 COMMUNITY_NO_PEER WellKnownCommunity = 0xffffff04 ) var WellKnownCommunityNameMap = map[WellKnownCommunity]string{ COMMUNITY_INTERNET: "internet", COMMUNITY_PLANNED_SHUT: "planned-shut", COMMUNITY_ACCEPT_OWN: "accept-own", COMMUNITY_ROUTE_FILTER_TRANSLATED_v4: "route-filter-translated-v4", COMMUNITY_ROUTE_FILTER_v4: "route-filter-v4", COMMUNITY_ROUTE_FILTER_TRANSLATED_v6: "route-filter-translated-v6", COMMUNITY_ROUTE_FILTER_v6: "route-filter-v6", COMMUNITY_LLGR_STALE: "llgr-stale", COMMUNITY_NO_LLGR: "no-llgr", COMMUNITY_BLACKHOLE: "blackhole", COMMUNITY_NO_EXPORT: "no-export", COMMUNITY_NO_ADVERTISE: "no-advertise", COMMUNITY_NO_EXPORT_SUBCONFED: "no-export-subconfed", COMMUNITY_NO_PEER: "no-peer", } var WellKnownCommunityValueMap = map[string]WellKnownCommunity{ WellKnownCommunityNameMap[COMMUNITY_INTERNET]: COMMUNITY_INTERNET, WellKnownCommunityNameMap[COMMUNITY_PLANNED_SHUT]: COMMUNITY_PLANNED_SHUT, WellKnownCommunityNameMap[COMMUNITY_ACCEPT_OWN]: COMMUNITY_ACCEPT_OWN, WellKnownCommunityNameMap[COMMUNITY_ROUTE_FILTER_TRANSLATED_v4]: COMMUNITY_ROUTE_FILTER_TRANSLATED_v4, WellKnownCommunityNameMap[COMMUNITY_ROUTE_FILTER_v4]: COMMUNITY_ROUTE_FILTER_v4, WellKnownCommunityNameMap[COMMUNITY_ROUTE_FILTER_TRANSLATED_v6]: COMMUNITY_ROUTE_FILTER_TRANSLATED_v6, WellKnownCommunityNameMap[COMMUNITY_ROUTE_FILTER_v6]: COMMUNITY_ROUTE_FILTER_v6, WellKnownCommunityNameMap[COMMUNITY_LLGR_STALE]: COMMUNITY_LLGR_STALE, WellKnownCommunityNameMap[COMMUNITY_NO_LLGR]: COMMUNITY_NO_LLGR, WellKnownCommunityNameMap[COMMUNITY_NO_EXPORT]: COMMUNITY_NO_EXPORT, WellKnownCommunityNameMap[COMMUNITY_BLACKHOLE]: COMMUNITY_BLACKHOLE, WellKnownCommunityNameMap[COMMUNITY_NO_ADVERTISE]: COMMUNITY_NO_ADVERTISE, WellKnownCommunityNameMap[COMMUNITY_NO_EXPORT_SUBCONFED]: COMMUNITY_NO_EXPORT_SUBCONFED, WellKnownCommunityNameMap[COMMUNITY_NO_PEER]: COMMUNITY_NO_PEER, } func (p *PathAttributeCommunities) String() string { l := make([]string, 0, len(p.Value)) for _, v := range p.Value { n, ok := WellKnownCommunityNameMap[WellKnownCommunity(v)] if ok { l = append(l, n) } else { l = append(l, fmt.Sprintf("%d:%d", (0xffff0000&v)>>16, 0xffff&v)) } } return fmt.Sprintf("{Communities: %s}", strings.Join(l, ", ")) } func (p *PathAttributeCommunities) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value []uint32 `json:"communities"` }{ Type: p.GetType(), Value: p.Value, }) } func NewPathAttributeCommunities(value []uint32) *PathAttributeCommunities { l := len(value) * 4 t := BGP_ATTR_TYPE_COMMUNITIES return &PathAttributeCommunities{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, Value: value, } } type PathAttributeOriginatorId struct { PathAttribute Value net.IP } func (p *PathAttributeOriginatorId) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length != 4 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "originator id length isn't correct") } p.Value = value return nil } func (p *PathAttributeOriginatorId) String() string { return fmt.Sprintf("{Originator: %s}", p.Value) } func (p *PathAttributeOriginatorId) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value string `json:"value"` }{ Type: p.GetType(), Value: p.Value.String(), }) } func (p *PathAttributeOriginatorId) Serialize(options ...*MarshallingOption) ([]byte, error) { var buf [4]byte copy(buf[:], p.Value) return p.PathAttribute.Serialize(buf[:], options...) } func NewPathAttributeOriginatorId(value string) *PathAttributeOriginatorId { t := BGP_ATTR_TYPE_ORIGINATOR_ID return &PathAttributeOriginatorId{ PathAttribute: PathAttribute{ Flags: PathAttrFlags[t], Type: t, Length: 4, }, Value: net.ParseIP(value).To4(), } } type PathAttributeClusterList struct { PathAttribute Value []net.IP } func (p *PathAttributeClusterList) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length%4 != 0 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "clusterlist length isn't correct") } for len(value) >= 4 { p.Value = append(p.Value, value[:4]) value = value[4:] } return nil } func (p *PathAttributeClusterList) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, len(p.Value)*4) for i, v := range p.Value { copy(buf[i*4:], v) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeClusterList) String() string { return fmt.Sprintf("{ClusterList: %v}", p.Value) } func (p *PathAttributeClusterList) MarshalJSON() ([]byte, error) { value := make([]string, 0, len(p.Value)) for _, v := range p.Value { value = append(value, v.String()) } return json.Marshal(struct { Type BGPAttrType `json:"type"` Value []string `json:"value"` }{ Type: p.GetType(), Value: value, }) } func NewPathAttributeClusterList(value []string) *PathAttributeClusterList { l := len(value) * 4 list := make([]net.IP, len(value)) for i, v := range value { list[i] = net.ParseIP(v).To4() } t := BGP_ATTR_TYPE_CLUSTER_LIST return &PathAttributeClusterList{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, Value: list, } } type PathAttributeMpReachNLRI struct { PathAttribute Nexthop net.IP LinkLocalNexthop net.IP AFI uint16 SAFI uint8 Value []AddrPrefixInterface } func (p *PathAttributeMpReachNLRI) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) eData, _ := p.PathAttribute.Serialize(value, options...) if p.Length < 3 { return NewMessageError(eCode, eSubCode, value, "mpreach header length is short") } afi := binary.BigEndian.Uint16(value[0:2]) safi := value[2] p.AFI = afi p.SAFI = safi _, err = NewPrefixFromRouteFamily(afi, safi) if err != nil { return NewMessageError(eCode, BGP_ERROR_SUB_INVALID_NETWORK_FIELD, eData, err.Error()) } nexthoplen := int(value[3]) if len(value) < 4+nexthoplen { return NewMessageError(eCode, eSubCode, value, "mpreach nexthop length is short") } nexthopbin := value[4 : 4+nexthoplen] if nexthoplen > 0 { v4addrlen := 4 v6addrlen := 16 offset := 0 if safi == SAFI_MPLS_VPN { offset = 8 } switch nexthoplen { case 2 * (offset + v6addrlen): p.LinkLocalNexthop = nexthopbin[offset+v6addrlen+offset : 2*(offset+v6addrlen)] fallthrough case offset + v6addrlen: p.Nexthop = nexthopbin[offset : offset+v6addrlen] case offset + v4addrlen: p.Nexthop = nexthopbin[offset : offset+v4addrlen] default: return NewMessageError(eCode, eSubCode, value, "mpreach nexthop length is incorrect") } } value = value[4+nexthoplen:] // skip reserved if len(value) == 0 { return NewMessageError(eCode, eSubCode, value, "no skip byte") } value = value[1:] addpathLen := 0 if IsAddPathEnabled(true, AfiSafiToRouteFamily(afi, safi), options) { addpathLen = 4 } for len(value) > 0 { prefix, err := NewPrefixFromRouteFamily(afi, safi) if err != nil { return NewMessageError(eCode, BGP_ERROR_SUB_INVALID_NETWORK_FIELD, eData, err.Error()) } err = prefix.DecodeFromBytes(value, options...) if err != nil { return err } if prefix.Len(options...)+addpathLen > len(value) { return NewMessageError(eCode, eSubCode, value, "prefix length is incorrect") } value = value[prefix.Len(options...)+addpathLen:] p.Value = append(p.Value, prefix) } return nil } func (p *PathAttributeMpReachNLRI) Serialize(options ...*MarshallingOption) ([]byte, error) { afi := p.AFI safi := p.SAFI nexthoplen := 4 if afi == AFI_IP6 || p.Nexthop.To4() == nil { nexthoplen = 16 } offset := 0 switch safi { case SAFI_MPLS_VPN: offset = 8 nexthoplen += offset case SAFI_FLOW_SPEC_VPN, SAFI_FLOW_SPEC_UNICAST: nexthoplen = 0 } if p.LinkLocalNexthop != nil { nexthoplen *= 2 } buf := make([]byte, 4+nexthoplen) binary.BigEndian.PutUint16(buf[0:], afi) buf[2] = safi buf[3] = uint8(nexthoplen) if nexthoplen != 0 { if p.Nexthop.To4() == nil { copy(buf[4+offset:], p.Nexthop.To16()) if p.LinkLocalNexthop != nil { copy(buf[4+offset+16:], p.LinkLocalNexthop.To16()) } } else { copy(buf[4+offset:], p.Nexthop) } } buf = append(buf, 0) for _, prefix := range p.Value { pbuf, err := prefix.Serialize(options...) if err != nil { return nil, err } buf = append(buf, pbuf...) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeMpReachNLRI) MarshalJSON() ([]byte, error) { nexthop := p.Nexthop.String() if p.Nexthop == nil { switch p.AFI { case AFI_IP: nexthop = "0.0.0.0" case AFI_IP6: nexthop = "::" default: nexthop = "fictitious" } } return json.Marshal(struct { Type BGPAttrType `json:"type"` Nexthop string `json:"nexthop"` AFI uint16 `json:"afi"` SAFI uint8 `json:"safi"` Value []AddrPrefixInterface `json:"value"` }{ Type: p.GetType(), Nexthop: nexthop, AFI: p.AFI, SAFI: p.SAFI, Value: p.Value, }) } func (p *PathAttributeMpReachNLRI) String() string { return fmt.Sprintf("{MpReach(%s): {Nexthop: %s, NLRIs: %s}}", AfiSafiToRouteFamily(p.AFI, p.SAFI), p.Nexthop, p.Value) } func NewPathAttributeMpReachNLRI(nexthop string, nlri []AddrPrefixInterface) *PathAttributeMpReachNLRI { // AFI(2) + SAFI(1) + NexthopLength(1) + Nexthop(variable) // + Reserved(1) + NLRI(variable) l := 5 var afi uint16 var safi uint8 if len(nlri) > 0 { afi = nlri[0].AFI() safi = nlri[0].SAFI() } nh := net.ParseIP(nexthop) if nh.To4() != nil && afi != AFI_IP6 { nh = nh.To4() switch safi { case SAFI_MPLS_VPN: l += 12 case SAFI_FLOW_SPEC_VPN, SAFI_FLOW_SPEC_UNICAST: // Should not have Nexthop default: l += 4 } } else { switch safi { case SAFI_MPLS_VPN: l += 24 case SAFI_FLOW_SPEC_VPN, SAFI_FLOW_SPEC_UNICAST: // Should not have Nexthop default: l += 16 } } var nlriLen int for _, n := range nlri { l += n.Len() nBuf, _ := n.Serialize() nlriLen += len(nBuf) } t := BGP_ATTR_TYPE_MP_REACH_NLRI return &PathAttributeMpReachNLRI{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, Nexthop: nh, AFI: afi, SAFI: safi, Value: nlri, } } type PathAttributeMpUnreachNLRI struct { PathAttribute AFI uint16 SAFI uint8 Value []AddrPrefixInterface } func (p *PathAttributeMpUnreachNLRI) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) eData, _ := p.PathAttribute.Serialize(value, options...) if p.Length < 3 { return NewMessageError(eCode, eSubCode, value, "unreach header length is incorrect") } afi := binary.BigEndian.Uint16(value[0:2]) safi := value[2] _, err = NewPrefixFromRouteFamily(afi, safi) if err != nil { return NewMessageError(eCode, BGP_ERROR_SUB_INVALID_NETWORK_FIELD, eData, err.Error()) } value = value[3:] p.AFI = afi p.SAFI = safi addpathLen := 0 if IsAddPathEnabled(true, AfiSafiToRouteFamily(afi, safi), options) { addpathLen = 4 } for len(value) > 0 { prefix, err := NewPrefixFromRouteFamily(afi, safi) if err != nil { return NewMessageError(eCode, BGP_ERROR_SUB_INVALID_NETWORK_FIELD, eData, err.Error()) } err = prefix.DecodeFromBytes(value, options...) if err != nil { return err } if prefix.Len(options...)+addpathLen > len(value) { return NewMessageError(eCode, eSubCode, eData, "prefix length is incorrect") } value = value[prefix.Len(options...)+addpathLen:] p.Value = append(p.Value, prefix) } return nil } func (p *PathAttributeMpUnreachNLRI) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 3) binary.BigEndian.PutUint16(buf, p.AFI) buf[2] = p.SAFI for _, prefix := range p.Value { pbuf, err := prefix.Serialize(options...) if err != nil { return nil, err } buf = append(buf, pbuf...) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeMpUnreachNLRI) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` AFI uint16 `json:"afi"` SAFI uint8 `json:"safi"` Value []AddrPrefixInterface `json:"value"` }{ Type: p.GetType(), AFI: p.AFI, SAFI: p.SAFI, Value: p.Value, }) } func (p *PathAttributeMpUnreachNLRI) String() string { if len(p.Value) > 0 { return fmt.Sprintf("{MpUnreach(%s): {NLRIs: %s}}", AfiSafiToRouteFamily(p.AFI, p.SAFI), p.Value) } return fmt.Sprintf("{MpUnreach(%s): End-of-Rib}", AfiSafiToRouteFamily(p.AFI, p.SAFI)) } func NewPathAttributeMpUnreachNLRI(nlri []AddrPrefixInterface) *PathAttributeMpUnreachNLRI { // AFI(2) + SAFI(1) + NLRI(variable) l := 3 var afi uint16 var safi uint8 if len(nlri) > 0 { afi = nlri[0].AFI() safi = nlri[0].SAFI() } for _, n := range nlri { l += n.Len() } t := BGP_ATTR_TYPE_MP_UNREACH_NLRI return &PathAttributeMpUnreachNLRI{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, AFI: afi, SAFI: safi, Value: nlri, } } type ExtendedCommunityInterface interface { Serialize() ([]byte, error) String() string GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) MarshalJSON() ([]byte, error) Flat() map[string]string } type TwoOctetAsSpecificExtended struct { SubType ExtendedCommunityAttrSubType AS uint16 LocalAdmin uint32 IsTransitive bool } func (e *TwoOctetAsSpecificExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) if e.IsTransitive { buf[0] = byte(EC_TYPE_TRANSITIVE_TWO_OCTET_AS_SPECIFIC) } else { buf[0] = byte(EC_TYPE_NON_TRANSITIVE_TWO_OCTET_AS_SPECIFIC) } buf[1] = byte(e.SubType) binary.BigEndian.PutUint16(buf[2:], e.AS) binary.BigEndian.PutUint32(buf[4:], e.LocalAdmin) return buf, nil } func (e *TwoOctetAsSpecificExtended) String() string { return fmt.Sprintf("%d:%d", e.AS, e.LocalAdmin) } func (e *TwoOctetAsSpecificExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{ Type: t, Subtype: s, Value: e.String(), }) } func (e *TwoOctetAsSpecificExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { t := EC_TYPE_TRANSITIVE_TWO_OCTET_AS_SPECIFIC if !e.IsTransitive { t = EC_TYPE_NON_TRANSITIVE_TWO_OCTET_AS_SPECIFIC } return t, e.SubType } func NewTwoOctetAsSpecificExtended(subtype ExtendedCommunityAttrSubType, as uint16, localAdmin uint32, isTransitive bool) *TwoOctetAsSpecificExtended { return &TwoOctetAsSpecificExtended{ SubType: subtype, AS: as, LocalAdmin: localAdmin, IsTransitive: isTransitive, } } type IPv4AddressSpecificExtended struct { SubType ExtendedCommunityAttrSubType IPv4 net.IP LocalAdmin uint16 IsTransitive bool } func (e *IPv4AddressSpecificExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) if e.IsTransitive { buf[0] = byte(EC_TYPE_TRANSITIVE_IP4_SPECIFIC) } else { buf[0] = byte(EC_TYPE_NON_TRANSITIVE_IP4_SPECIFIC) } buf[1] = byte(e.SubType) copy(buf[2:6], e.IPv4) binary.BigEndian.PutUint16(buf[6:], e.LocalAdmin) return buf, nil } func (e *IPv4AddressSpecificExtended) String() string { return fmt.Sprintf("%s:%d", e.IPv4.String(), e.LocalAdmin) } func (e *IPv4AddressSpecificExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{ Type: t, Subtype: s, Value: e.String(), }) } func (e *IPv4AddressSpecificExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { t := EC_TYPE_TRANSITIVE_IP4_SPECIFIC if !e.IsTransitive { t = EC_TYPE_NON_TRANSITIVE_IP4_SPECIFIC } return t, e.SubType } func NewIPv4AddressSpecificExtended(subtype ExtendedCommunityAttrSubType, ip string, localAdmin uint16, isTransitive bool) *IPv4AddressSpecificExtended { ipv4 := net.ParseIP(ip) if ipv4.To4() == nil { return nil } return &IPv4AddressSpecificExtended{ SubType: subtype, IPv4: ipv4.To4(), LocalAdmin: localAdmin, IsTransitive: isTransitive, } } type IPv6AddressSpecificExtended struct { SubType ExtendedCommunityAttrSubType IPv6 net.IP LocalAdmin uint16 IsTransitive bool } func (e *IPv6AddressSpecificExtended) Serialize() ([]byte, error) { buf := make([]byte, 20) if e.IsTransitive { buf[0] = byte(EC_TYPE_TRANSITIVE_IP6_SPECIFIC) } else { buf[0] = byte(EC_TYPE_NON_TRANSITIVE_IP6_SPECIFIC) } buf[1] = byte(e.SubType) copy(buf[2:18], e.IPv6) binary.BigEndian.PutUint16(buf[18:], e.LocalAdmin) return buf, nil } func (e *IPv6AddressSpecificExtended) String() string { return fmt.Sprintf("%s:%d", e.IPv6.String(), e.LocalAdmin) } func (e *IPv6AddressSpecificExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{ Type: t, Subtype: s, Value: e.String(), }) } func (e *IPv6AddressSpecificExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { t := EC_TYPE_TRANSITIVE_IP6_SPECIFIC if !e.IsTransitive { t = EC_TYPE_NON_TRANSITIVE_IP6_SPECIFIC } return t, e.SubType } func NewIPv6AddressSpecificExtended(subtype ExtendedCommunityAttrSubType, ip string, localAdmin uint16, isTransitive bool) *IPv6AddressSpecificExtended { ipv6 := net.ParseIP(ip) if ipv6.To16() == nil { return nil } return &IPv6AddressSpecificExtended{ SubType: subtype, IPv6: ipv6.To16(), LocalAdmin: localAdmin, IsTransitive: isTransitive, } } type FourOctetAsSpecificExtended struct { SubType ExtendedCommunityAttrSubType AS uint32 LocalAdmin uint16 IsTransitive bool } func (e *FourOctetAsSpecificExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) if e.IsTransitive { buf[0] = byte(EC_TYPE_TRANSITIVE_FOUR_OCTET_AS_SPECIFIC) } else { buf[0] = byte(EC_TYPE_NON_TRANSITIVE_FOUR_OCTET_AS_SPECIFIC) } buf[1] = byte(e.SubType) binary.BigEndian.PutUint32(buf[2:], e.AS) binary.BigEndian.PutUint16(buf[6:], e.LocalAdmin) return buf, nil } func (e *FourOctetAsSpecificExtended) String() string { var buf [4]byte binary.BigEndian.PutUint32(buf[:4], e.AS) asUpper := binary.BigEndian.Uint16(buf[0:2]) asLower := binary.BigEndian.Uint16(buf[2:4]) return fmt.Sprintf("%d.%d:%d", asUpper, asLower, e.LocalAdmin) } func (e *FourOctetAsSpecificExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{ Type: t, Subtype: s, Value: e.String(), }) } func (e *FourOctetAsSpecificExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { t := EC_TYPE_TRANSITIVE_FOUR_OCTET_AS_SPECIFIC if !e.IsTransitive { t = EC_TYPE_NON_TRANSITIVE_FOUR_OCTET_AS_SPECIFIC } return t, e.SubType } func NewFourOctetAsSpecificExtended(subtype ExtendedCommunityAttrSubType, as uint32, localAdmin uint16, isTransitive bool) *FourOctetAsSpecificExtended { return &FourOctetAsSpecificExtended{ SubType: subtype, AS: as, LocalAdmin: localAdmin, IsTransitive: isTransitive, } } func ParseExtendedCommunity(subtype ExtendedCommunityAttrSubType, com string) (ExtendedCommunityInterface, error) { if subtype == EC_SUBTYPE_ENCAPSULATION { var t TunnelType switch com { case TUNNEL_TYPE_L2TP3.String(): t = TUNNEL_TYPE_L2TP3 case TUNNEL_TYPE_GRE.String(): t = TUNNEL_TYPE_GRE case TUNNEL_TYPE_IP_IN_IP.String(): t = TUNNEL_TYPE_IP_IN_IP case TUNNEL_TYPE_VXLAN.String(): t = TUNNEL_TYPE_VXLAN case TUNNEL_TYPE_NVGRE.String(): t = TUNNEL_TYPE_NVGRE case TUNNEL_TYPE_MPLS.String(): t = TUNNEL_TYPE_MPLS case TUNNEL_TYPE_MPLS_IN_GRE.String(): t = TUNNEL_TYPE_MPLS_IN_GRE case TUNNEL_TYPE_VXLAN_GRE.String(): t = TUNNEL_TYPE_VXLAN_GRE case TUNNEL_TYPE_MPLS_IN_UDP.String(): t = TUNNEL_TYPE_MPLS_IN_UDP case TUNNEL_TYPE_GENEVE.String(): t = TUNNEL_TYPE_GENEVE case "L2TPv3 over IP": t = TUNNEL_TYPE_L2TP3 case "GRE": t = TUNNEL_TYPE_GRE case "IP in IP": t = TUNNEL_TYPE_IP_IN_IP case "VXLAN": t = TUNNEL_TYPE_VXLAN case "NVGRE": t = TUNNEL_TYPE_NVGRE case "MPLS": t = TUNNEL_TYPE_MPLS case "MPLS in GRE": t = TUNNEL_TYPE_MPLS_IN_GRE case "VXLAN GRE": t = TUNNEL_TYPE_VXLAN_GRE case "MPLS in UDP": t = TUNNEL_TYPE_MPLS_IN_UDP case "GENEVE": t = TUNNEL_TYPE_GENEVE default: return nil, fmt.Errorf("invalid encap type %s", com) } return NewEncapExtended(t), nil } if subtype == EC_SUBTYPE_ORIGIN_VALIDATION { var state ValidationState switch com { case VALIDATION_STATE_VALID.String(): state = VALIDATION_STATE_VALID case VALIDATION_STATE_NOT_FOUND.String(): state = VALIDATION_STATE_NOT_FOUND case VALIDATION_STATE_INVALID.String(): state = VALIDATION_STATE_INVALID default: return nil, errors.New("invalid validation state") } return &ValidationExtended{ State: state, }, nil } elems, err := parseRdAndRt(com) if err != nil { return nil, err } localAdmin, _ := strconv.ParseUint(elems[10], 10, 32) if subtype == EC_SUBTYPE_SOURCE_AS { localAdmin = 0 } ip := net.ParseIP(elems[1]) isTransitive := true switch { case ip.To4() != nil: return NewIPv4AddressSpecificExtended(subtype, elems[1], uint16(localAdmin), isTransitive), nil case ip.To16() != nil: return NewIPv6AddressSpecificExtended(subtype, elems[1], uint16(localAdmin), isTransitive), nil case elems[6] == "" && elems[7] == "": asn, _ := strconv.ParseUint(elems[8], 10, 16) return NewTwoOctetAsSpecificExtended(subtype, uint16(asn), uint32(localAdmin), isTransitive), nil default: fst, _ := strconv.ParseUint(elems[7], 10, 16) snd, _ := strconv.ParseUint(elems[8], 10, 16) asn := fst<<16 | snd return NewFourOctetAsSpecificExtended(subtype, uint32(asn), uint16(localAdmin), isTransitive), nil } } func ParseRouteTarget(rt string) (ExtendedCommunityInterface, error) { return ParseExtendedCommunity(EC_SUBTYPE_ROUTE_TARGET, rt) } func SerializeExtendedCommunities(comms []ExtendedCommunityInterface) ([][]byte, error) { bufs := make([][]byte, len(comms)) var err error for i, c := range comms { bufs[i], err = c.Serialize() if err != nil { return nil, err } } return bufs, err } type ValidationState uint8 const ( VALIDATION_STATE_VALID ValidationState = 0 VALIDATION_STATE_NOT_FOUND ValidationState = 1 VALIDATION_STATE_INVALID ValidationState = 2 ) func (s ValidationState) String() string { switch s { case VALIDATION_STATE_VALID: return "valid" case VALIDATION_STATE_NOT_FOUND: return "not-found" case VALIDATION_STATE_INVALID: return "invalid" } return fmt.Sprintf("unknown validation state(%d)", s) } type ValidationExtended struct { State ValidationState } func (e *ValidationExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) typ, subType := e.GetTypes() buf[0] = byte(typ) buf[1] = byte(subType) buf[7] = byte(e.State) return buf, nil } func (e *ValidationExtended) String() string { return e.State.String() } func (e *ValidationExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_NON_TRANSITIVE_OPAQUE, EC_SUBTYPE_ORIGIN_VALIDATION } func (e *ValidationExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` SubType ExtendedCommunityAttrSubType `json:"subtype"` State ValidationState `json:"value"` }{ Type: t, SubType: s, State: e.State, }) } func NewValidationExtended(state ValidationState) *ValidationExtended { return &ValidationExtended{ State: state, } } type ColorExtended struct { Color uint32 } func (e *ColorExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) typ, subType := e.GetTypes() buf[0] = byte(typ) buf[1] = byte(subType) binary.BigEndian.PutUint32(buf[4:8], uint32(e.Color)) return buf, nil } func (e *ColorExtended) String() string { return fmt.Sprintf("%d", e.Color) } func (e *ColorExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_TRANSITIVE_OPAQUE, EC_SUBTYPE_COLOR } func (e *ColorExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` SubType ExtendedCommunityAttrSubType `json:"subtype"` Color uint32 `json:"color"` }{ Type: t, SubType: s, Color: e.Color, }) } func NewColorExtended(color uint32) *ColorExtended { return &ColorExtended{ Color: color, } } type EncapExtended struct { TunnelType TunnelType } func (e *EncapExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) typ, subType := e.GetTypes() buf[0] = byte(typ) buf[1] = byte(subType) binary.BigEndian.PutUint16(buf[6:8], uint16(e.TunnelType)) return buf, nil } func (e *EncapExtended) String() string { switch e.TunnelType { case TUNNEL_TYPE_L2TP3: return "L2TPv3 over IP" case TUNNEL_TYPE_GRE: return "GRE" case TUNNEL_TYPE_IP_IN_IP: return "IP in IP" case TUNNEL_TYPE_VXLAN: return "VXLAN" case TUNNEL_TYPE_NVGRE: return "NVGRE" case TUNNEL_TYPE_MPLS: return "MPLS" case TUNNEL_TYPE_MPLS_IN_GRE: return "MPLS in GRE" case TUNNEL_TYPE_VXLAN_GRE: return "VXLAN GRE" case TUNNEL_TYPE_MPLS_IN_UDP: return "MPLS in UDP" case TUNNEL_TYPE_SR_POLICY: return "SR Policy" case TUNNEL_TYPE_GENEVE: return "GENEVE" default: return fmt.Sprintf("tunnel: %d", e.TunnelType) } } func (e *EncapExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_TRANSITIVE_OPAQUE, EC_SUBTYPE_ENCAPSULATION } func (e *EncapExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` SubType ExtendedCommunityAttrSubType `json:"subtype"` TunnelType TunnelType `json:"tunnel_type"` }{ Type: t, SubType: s, TunnelType: e.TunnelType, }) } func NewEncapExtended(tunnelType TunnelType) *EncapExtended { return &EncapExtended{ TunnelType: tunnelType, } } type DefaultGatewayExtended struct { } func (e *DefaultGatewayExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) typ, subType := e.GetTypes() buf[0] = byte(typ) buf[1] = byte(subType) return buf, nil } func (e *DefaultGatewayExtended) String() string { return "default-gateway" } func (e *DefaultGatewayExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_TRANSITIVE_OPAQUE, EC_SUBTYPE_DEFAULT_GATEWAY } func (e *DefaultGatewayExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` SubType ExtendedCommunityAttrSubType `json:"subtype"` }{ Type: t, SubType: s, }) } func NewDefaultGatewayExtended() *DefaultGatewayExtended { return &DefaultGatewayExtended{} } type OpaqueExtended struct { IsTransitive bool Value []byte } func (e *OpaqueExtended) Serialize() ([]byte, error) { if len(e.Value) != 7 { return nil, fmt.Errorf("invalid value length for opaque extended community: %d", len(e.Value)) } buf := make([]byte, 8) if e.IsTransitive { buf[0] = byte(EC_TYPE_TRANSITIVE_OPAQUE) } else { buf[0] = byte(EC_TYPE_NON_TRANSITIVE_OPAQUE) } copy(buf[1:], e.Value) return buf, nil } func (e *OpaqueExtended) String() string { var buf [8]byte copy(buf[1:], e.Value) return fmt.Sprintf("%d", binary.BigEndian.Uint64(buf[:])) } func (e *OpaqueExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { var subType ExtendedCommunityAttrSubType if len(e.Value) > 0 { // Use the first byte of value as the sub type subType = ExtendedCommunityAttrSubType(e.Value[0]) } if e.IsTransitive { return EC_TYPE_TRANSITIVE_OPAQUE, subType } return EC_TYPE_NON_TRANSITIVE_OPAQUE, subType } func (e *OpaqueExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value []byte `json:"value"` }{ Type: t, Subtype: s, Value: e.Value, }) } func NewOpaqueExtended(isTransitive bool, value []byte) *OpaqueExtended { v := make([]byte, 7) copy(v, value) return &OpaqueExtended{ IsTransitive: isTransitive, Value: v, } } func parseOpaqueExtended(data []byte) (ExtendedCommunityInterface, error) { typ := ExtendedCommunityAttrType(data[0]) isTransitive := false switch typ { case EC_TYPE_TRANSITIVE_OPAQUE: isTransitive = true case EC_TYPE_NON_TRANSITIVE_OPAQUE: // isTransitive = false default: return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("invalid opaque extended community type: %d", data[0])) } subType := ExtendedCommunityAttrSubType(data[1]) if isTransitive { switch subType { case EC_SUBTYPE_COLOR: return &ColorExtended{ Color: binary.BigEndian.Uint32(data[4:8]), }, nil case EC_SUBTYPE_ENCAPSULATION: return &EncapExtended{ TunnelType: TunnelType(binary.BigEndian.Uint16(data[6:8])), }, nil case EC_SUBTYPE_DEFAULT_GATEWAY: return &DefaultGatewayExtended{}, nil } } else { switch subType { case EC_SUBTYPE_ORIGIN_VALIDATION: return &ValidationExtended{ State: ValidationState(data[7]), }, nil } } return NewOpaqueExtended(isTransitive, data[1:8]), nil } type ESILabelExtended struct { Label uint32 IsSingleActive bool } func (e *ESILabelExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) buf[0] = byte(EC_TYPE_EVPN) buf[1] = byte(EC_SUBTYPE_ESI_LABEL) if e.IsSingleActive { buf[2] = byte(1) } buf[3] = 0 buf[4] = 0 buf[5] = byte((e.Label >> 16) & 0xff) buf[6] = byte((e.Label >> 8) & 0xff) buf[7] = byte(e.Label & 0xff) return buf, nil } func (e *ESILabelExtended) String() string { buf := bytes.NewBuffer(make([]byte, 0, 32)) buf.WriteString(fmt.Sprintf("esi-label: %d", e.Label)) if e.IsSingleActive { buf.WriteString(", single-active") } return buf.String() } func (e *ESILabelExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Label uint32 `json:"label"` IsSingleActive bool `json:"is_single_active"` }{ Type: t, Subtype: s, Label: e.Label, IsSingleActive: e.IsSingleActive, }) } func (e *ESILabelExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_EVPN, EC_SUBTYPE_ESI_LABEL } func NewESILabelExtended(label uint32, isSingleActive bool) *ESILabelExtended { return &ESILabelExtended{ Label: label, IsSingleActive: isSingleActive, } } type ESImportRouteTarget struct { ESImport net.HardwareAddr } func (e *ESImportRouteTarget) Serialize() ([]byte, error) { buf := make([]byte, 8) buf[0] = byte(EC_TYPE_EVPN) buf[1] = byte(EC_SUBTYPE_ES_IMPORT) copy(buf[2:], e.ESImport) return buf, nil } func (e *ESImportRouteTarget) String() string { return fmt.Sprintf("es-import rt: %s", e.ESImport.String()) } func (e *ESImportRouteTarget) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{ Type: t, Subtype: s, Value: e.ESImport.String(), }) } func (e *ESImportRouteTarget) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_EVPN, EC_SUBTYPE_ES_IMPORT } func NewESImportRouteTarget(mac string) *ESImportRouteTarget { esImport, err := net.ParseMAC(mac) if err != nil { return nil } return &ESImportRouteTarget{ ESImport: esImport, } } type MacMobilityExtended struct { Sequence uint32 IsSticky bool } func (e *MacMobilityExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) buf[0] = byte(EC_TYPE_EVPN) buf[1] = byte(EC_SUBTYPE_MAC_MOBILITY) if e.IsSticky { buf[2] = byte(1) } binary.BigEndian.PutUint32(buf[4:], e.Sequence) return buf, nil } func (e *MacMobilityExtended) String() string { buf := bytes.NewBuffer(make([]byte, 0, 32)) buf.WriteString(fmt.Sprintf("mac-mobility: %d", e.Sequence)) if e.IsSticky { buf.WriteString(", sticky") } return buf.String() } func (e *MacMobilityExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Sequence uint32 `json:"sequence"` IsSticky bool `json:"is_sticky"` }{ Type: t, Subtype: s, Sequence: e.Sequence, IsSticky: e.IsSticky, }) } func (e *MacMobilityExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_EVPN, EC_SUBTYPE_MAC_MOBILITY } func NewMacMobilityExtended(seq uint32, isSticky bool) *MacMobilityExtended { return &MacMobilityExtended{ Sequence: seq, IsSticky: isSticky, } } type RouterMacExtended struct { Mac net.HardwareAddr } func (e *RouterMacExtended) Serialize() ([]byte, error) { buf := make([]byte, 2, 8) buf[0] = byte(EC_TYPE_EVPN) buf[1] = byte(EC_SUBTYPE_ROUTER_MAC) buf = append(buf, e.Mac...) return buf, nil } func (e *RouterMacExtended) String() string { return fmt.Sprintf("router's mac: %s", e.Mac.String()) } func (e *RouterMacExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Mac string `json:"mac"` }{ Type: t, Subtype: s, Mac: e.Mac.String(), }) } func (e *RouterMacExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_EVPN, EC_SUBTYPE_ROUTER_MAC } func NewRoutersMacExtended(mac string) *RouterMacExtended { hw, err := net.ParseMAC(mac) if err != nil { return nil } return &RouterMacExtended{ Mac: hw, } } func parseEvpnExtended(data []byte) (ExtendedCommunityInterface, error) { if ExtendedCommunityAttrType(data[0]) != EC_TYPE_EVPN { return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("ext comm type is not EC_TYPE_EVPN: %d", data[0])) } subType := ExtendedCommunityAttrSubType(data[1]) switch subType { case EC_SUBTYPE_ESI_LABEL: var isSingleActive bool if data[2] > 0 { isSingleActive = true } label := uint32(data[5])<<16 | uint32(data[6])<<8 | uint32(data[7]) return &ESILabelExtended{ IsSingleActive: isSingleActive, Label: label, }, nil case EC_SUBTYPE_ES_IMPORT: return &ESImportRouteTarget{ ESImport: net.HardwareAddr(data[2:8]), }, nil case EC_SUBTYPE_MAC_MOBILITY: var isSticky bool if data[2] > 0 { isSticky = true } seq := binary.BigEndian.Uint32(data[4:8]) return &MacMobilityExtended{ Sequence: seq, IsSticky: isSticky, }, nil case EC_SUBTYPE_ROUTER_MAC: return &RouterMacExtended{ Mac: net.HardwareAddr(data[2:8]), }, nil } return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("unknown evpn subtype: %d", subType)) } type TrafficRateExtended struct { AS uint16 Rate float32 } func (e *TrafficRateExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) buf[0] = byte(EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL) buf[1] = byte(EC_SUBTYPE_FLOWSPEC_TRAFFIC_RATE) binary.BigEndian.PutUint16(buf[2:4], e.AS) binary.BigEndian.PutUint32(buf[4:8], math.Float32bits(e.Rate)) return buf, nil } func (e *TrafficRateExtended) String() string { buf := bytes.NewBuffer(make([]byte, 0, 32)) if e.Rate == 0 { buf.WriteString("discard") } else { buf.WriteString(fmt.Sprintf("rate: %f", e.Rate)) } if e.AS != 0 { buf.WriteString(fmt.Sprintf("(as: %d)", e.AS)) } return buf.String() } func (e *TrafficRateExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` As uint16 `json:"as"` Rate float32 `json:"rate"` }{t, s, e.AS, e.Rate}) } func (e *TrafficRateExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL, EC_SUBTYPE_FLOWSPEC_TRAFFIC_RATE } func NewTrafficRateExtended(as uint16, rate float32) *TrafficRateExtended { return &TrafficRateExtended{ AS: as, Rate: rate, } } type TrafficActionExtended struct { Terminal bool Sample bool } func (e *TrafficActionExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) buf[0] = byte(EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL) buf[1] = byte(EC_SUBTYPE_FLOWSPEC_TRAFFIC_ACTION) if e.Terminal { buf[7] = 0x01 } if e.Sample { buf[7] = buf[7] | 0x2 } return buf, nil } func (e *TrafficActionExtended) String() string { ss := make([]string, 0, 2) if e.Terminal { ss = append(ss, "terminal") } if e.Sample { ss = append(ss, "sample") } return fmt.Sprintf("action: %s", strings.Join(ss, "-")) } func (e *TrafficActionExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Terminal bool `json:"terminal"` Sample bool `json:"sample"` }{t, s, e.Terminal, e.Sample}) } func (e *TrafficActionExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL, EC_SUBTYPE_FLOWSPEC_TRAFFIC_ACTION } func NewTrafficActionExtended(terminal bool, sample bool) *TrafficActionExtended { return &TrafficActionExtended{ Terminal: terminal, Sample: sample, } } type RedirectTwoOctetAsSpecificExtended struct { TwoOctetAsSpecificExtended } func (e *RedirectTwoOctetAsSpecificExtended) Serialize() ([]byte, error) { buf, err := e.TwoOctetAsSpecificExtended.Serialize() buf[0] = byte(EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL) buf[1] = byte(EC_SUBTYPE_FLOWSPEC_REDIRECT) return buf, err } func (e *RedirectTwoOctetAsSpecificExtended) String() string { return fmt.Sprintf("redirect: %s", e.TwoOctetAsSpecificExtended.String()) } func (e *RedirectTwoOctetAsSpecificExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{t, s, e.TwoOctetAsSpecificExtended.String()}) } func (e *RedirectTwoOctetAsSpecificExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL, EC_SUBTYPE_FLOWSPEC_REDIRECT } func NewRedirectTwoOctetAsSpecificExtended(as uint16, localAdmin uint32) *RedirectTwoOctetAsSpecificExtended { return &RedirectTwoOctetAsSpecificExtended{*NewTwoOctetAsSpecificExtended(EC_SUBTYPE_ROUTE_TARGET, as, localAdmin, false)} } type RedirectIPv4AddressSpecificExtended struct { IPv4AddressSpecificExtended } func (e *RedirectIPv4AddressSpecificExtended) Serialize() ([]byte, error) { buf, err := e.IPv4AddressSpecificExtended.Serialize() buf[0] = byte(EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL2) buf[1] = byte(EC_SUBTYPE_FLOWSPEC_REDIRECT) return buf, err } func (e *RedirectIPv4AddressSpecificExtended) String() string { return fmt.Sprintf("redirect: %s", e.IPv4AddressSpecificExtended.String()) } func (e *RedirectIPv4AddressSpecificExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{t, s, e.IPv4AddressSpecificExtended.String()}) } func (e *RedirectIPv4AddressSpecificExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL2, EC_SUBTYPE_FLOWSPEC_REDIRECT } func NewRedirectIPv4AddressSpecificExtended(ipv4 string, localAdmin uint16) *RedirectIPv4AddressSpecificExtended { e := NewIPv4AddressSpecificExtended(EC_SUBTYPE_ROUTE_TARGET, ipv4, localAdmin, false) if e == nil { return nil } return &RedirectIPv4AddressSpecificExtended{*e} } type RedirectIPv6AddressSpecificExtended struct { IPv6AddressSpecificExtended } func (e *RedirectIPv6AddressSpecificExtended) Serialize() ([]byte, error) { buf, err := e.IPv6AddressSpecificExtended.Serialize() buf[0] = byte(EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL) buf[1] = byte(EC_SUBTYPE_FLOWSPEC_REDIRECT_IP6) return buf, err } func (e *RedirectIPv6AddressSpecificExtended) String() string { return fmt.Sprintf("redirect: %s", e.IPv6AddressSpecificExtended.String()) } func (e *RedirectIPv6AddressSpecificExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{t, s, e.IPv6AddressSpecificExtended.String()}) } func (e *RedirectIPv6AddressSpecificExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL, EC_SUBTYPE_FLOWSPEC_REDIRECT_IP6 } func NewRedirectIPv6AddressSpecificExtended(ipv6 string, localAdmin uint16) *RedirectIPv6AddressSpecificExtended { e := NewIPv6AddressSpecificExtended(EC_SUBTYPE_ROUTE_TARGET, ipv6, localAdmin, false) if e == nil { return nil } return &RedirectIPv6AddressSpecificExtended{*e} } type RedirectFourOctetAsSpecificExtended struct { FourOctetAsSpecificExtended } func (e *RedirectFourOctetAsSpecificExtended) Serialize() ([]byte, error) { buf, err := e.FourOctetAsSpecificExtended.Serialize() buf[0] = byte(EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL3) buf[1] = byte(EC_SUBTYPE_FLOWSPEC_REDIRECT) return buf, err } func (e *RedirectFourOctetAsSpecificExtended) String() string { return fmt.Sprintf("redirect: %s", e.FourOctetAsSpecificExtended.String()) } func (e *RedirectFourOctetAsSpecificExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value string `json:"value"` }{t, s, e.FourOctetAsSpecificExtended.String()}) } func (e *RedirectFourOctetAsSpecificExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL3, EC_SUBTYPE_FLOWSPEC_REDIRECT } func NewRedirectFourOctetAsSpecificExtended(as uint32, localAdmin uint16) *RedirectFourOctetAsSpecificExtended { return &RedirectFourOctetAsSpecificExtended{*NewFourOctetAsSpecificExtended(EC_SUBTYPE_ROUTE_TARGET, as, localAdmin, false)} } type TrafficRemarkExtended struct { DSCP uint8 } func (e *TrafficRemarkExtended) Serialize() ([]byte, error) { buf := make([]byte, 8) buf[0] = byte(EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL) buf[1] = byte(EC_SUBTYPE_FLOWSPEC_TRAFFIC_REMARK) buf[7] = byte(e.DSCP) return buf, nil } func (e *TrafficRemarkExtended) String() string { return fmt.Sprintf("remark: %d", e.DSCP) } func (e *TrafficRemarkExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value uint8 `json:"value"` }{t, s, e.DSCP}) } func (e *TrafficRemarkExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { return EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL, EC_SUBTYPE_FLOWSPEC_TRAFFIC_REMARK } func NewTrafficRemarkExtended(dscp uint8) *TrafficRemarkExtended { return &TrafficRemarkExtended{ DSCP: dscp, } } func parseFlowSpecExtended(data []byte) (ExtendedCommunityInterface, error) { typ := ExtendedCommunityAttrType(data[0]) if typ != EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL && typ != EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL2 && typ != EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL3 { return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("ext comm type is not EC_TYPE_FLOWSPEC: %d", data[0])) } subType := ExtendedCommunityAttrSubType(data[1]) switch subType { case EC_SUBTYPE_FLOWSPEC_TRAFFIC_RATE: asn := binary.BigEndian.Uint16(data[2:4]) bits := binary.BigEndian.Uint32(data[4:8]) rate := math.Float32frombits(bits) return NewTrafficRateExtended(asn, rate), nil case EC_SUBTYPE_FLOWSPEC_TRAFFIC_ACTION: terminal := data[7]&0x1 == 1 sample := (data[7]>>1)&0x1 == 1 return NewTrafficActionExtended(terminal, sample), nil case EC_SUBTYPE_FLOWSPEC_REDIRECT: // RFC7674 switch typ { case EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL: as := binary.BigEndian.Uint16(data[2:4]) localAdmin := binary.BigEndian.Uint32(data[4:8]) return NewRedirectTwoOctetAsSpecificExtended(as, localAdmin), nil case EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL2: ipv4 := net.IP(data[2:6]).String() localAdmin := binary.BigEndian.Uint16(data[6:8]) return NewRedirectIPv4AddressSpecificExtended(ipv4, localAdmin), nil case EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL3: as := binary.BigEndian.Uint32(data[2:6]) localAdmin := binary.BigEndian.Uint16(data[6:8]) return NewRedirectFourOctetAsSpecificExtended(as, localAdmin), nil } case EC_SUBTYPE_FLOWSPEC_TRAFFIC_REMARK: dscp := data[7] return NewTrafficRemarkExtended(dscp), nil case EC_SUBTYPE_FLOWSPEC_REDIRECT_IP6: ipv6 := net.IP(data[2:18]).String() localAdmin := binary.BigEndian.Uint16(data[18:20]) return NewRedirectIPv6AddressSpecificExtended(ipv6, localAdmin), nil } return &UnknownExtended{ Type: ExtendedCommunityAttrType(data[0]), Value: data[1:8], }, nil } func parseIP6FlowSpecExtended(data []byte) (ExtendedCommunityInterface, error) { typ := ExtendedCommunityAttrType(data[0]) if typ != EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL && typ != EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL2 && typ != EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL3 { return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, fmt.Sprintf("ext comm type is not EC_TYPE_FLOWSPEC: %d", data[0])) } subType := ExtendedCommunityAttrSubType(data[1]) switch subType { case EC_SUBTYPE_FLOWSPEC_REDIRECT_IP6: // RFC7674 switch typ { case EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL: ipv6 := net.IP(data[2:18]).String() localAdmin := binary.BigEndian.Uint16(data[18:20]) return NewRedirectIPv6AddressSpecificExtended(ipv6, localAdmin), nil } } return &UnknownExtended{ Type: ExtendedCommunityAttrType(data[0]), Value: data[1:20], }, nil } type UnknownExtended struct { Type ExtendedCommunityAttrType Value []byte } func (e *UnknownExtended) Serialize() ([]byte, error) { if len(e.Value) != 7 { return nil, fmt.Errorf("invalid value length for unknown extended community: %d", len(e.Value)) } buf := make([]byte, 8) buf[0] = uint8(e.Type) copy(buf[1:], e.Value) return buf, nil } func (e *UnknownExtended) String() string { var buf [8]byte copy(buf[1:], e.Value) return fmt.Sprintf("%d", binary.BigEndian.Uint64(buf[:])) } func (e *UnknownExtended) MarshalJSON() ([]byte, error) { t, s := e.GetTypes() return json.Marshal(struct { Type ExtendedCommunityAttrType `json:"type"` Subtype ExtendedCommunityAttrSubType `json:"subtype"` Value []byte `json:"value"` }{ Type: t, Subtype: s, Value: e.Value, }) } func (e *UnknownExtended) GetTypes() (ExtendedCommunityAttrType, ExtendedCommunityAttrSubType) { var subType ExtendedCommunityAttrSubType if len(e.Value) > 0 { // Use the first byte of value as the sub type subType = ExtendedCommunityAttrSubType(e.Value[0]) } return e.Type, subType } func NewUnknownExtended(typ ExtendedCommunityAttrType, value []byte) *UnknownExtended { v := make([]byte, 7) copy(v, value) return &UnknownExtended{ Type: typ, Value: v, } } type PathAttributeExtendedCommunities struct { PathAttribute Value []ExtendedCommunityInterface } func ParseExtended(data []byte) (ExtendedCommunityInterface, error) { if len(data) < 8 { return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "not all extended community bytes are available") } attrType := ExtendedCommunityAttrType(data[0]) subtype := ExtendedCommunityAttrSubType(data[1]) transitive := false switch attrType { case EC_TYPE_TRANSITIVE_TWO_OCTET_AS_SPECIFIC: transitive = true fallthrough case EC_TYPE_NON_TRANSITIVE_TWO_OCTET_AS_SPECIFIC: as := binary.BigEndian.Uint16(data[2:4]) localAdmin := binary.BigEndian.Uint32(data[4:8]) return NewTwoOctetAsSpecificExtended(subtype, as, localAdmin, transitive), nil case EC_TYPE_TRANSITIVE_IP4_SPECIFIC: transitive = true fallthrough case EC_TYPE_NON_TRANSITIVE_IP4_SPECIFIC: ipv4 := net.IP(data[2:6]).String() localAdmin := binary.BigEndian.Uint16(data[6:8]) return NewIPv4AddressSpecificExtended(subtype, ipv4, localAdmin, transitive), nil case EC_TYPE_TRANSITIVE_FOUR_OCTET_AS_SPECIFIC: transitive = true fallthrough case EC_TYPE_NON_TRANSITIVE_FOUR_OCTET_AS_SPECIFIC: as := binary.BigEndian.Uint32(data[2:6]) localAdmin := binary.BigEndian.Uint16(data[6:8]) return NewFourOctetAsSpecificExtended(subtype, as, localAdmin, transitive), nil case EC_TYPE_TRANSITIVE_OPAQUE: transitive = true fallthrough case EC_TYPE_NON_TRANSITIVE_OPAQUE: return parseOpaqueExtended(data) case EC_TYPE_EVPN: return parseEvpnExtended(data) case EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL, EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL2, EC_TYPE_GENERIC_TRANSITIVE_EXPERIMENTAL3: return parseFlowSpecExtended(data) default: return &UnknownExtended{ Type: ExtendedCommunityAttrType(data[0]), Value: data[1:8], }, nil } } func (p *PathAttributeExtendedCommunities) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length%8 != 0 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_ATTRIBUTE_LENGTH_ERROR) return NewMessageError(eCode, eSubCode, nil, "extendedcommunities length isn't correct") } for len(value) >= 8 { e, err := ParseExtended(value) if err != nil { return err } p.Value = append(p.Value, e) value = value[8:] } return nil } func (p *PathAttributeExtendedCommunities) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 0) for _, p := range p.Value { ebuf, err := p.Serialize() if err != nil { return nil, err } buf = append(buf, ebuf...) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeExtendedCommunities) String() string { buf := bytes.NewBuffer(make([]byte, 0, 32)) for idx, v := range p.Value { buf.WriteString("[") buf.WriteString(v.String()) buf.WriteString("]") if idx < len(p.Value)-1 { buf.WriteString(", ") } } return fmt.Sprintf("{Extcomms: %s}", buf.String()) } func (p *PathAttributeExtendedCommunities) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value []ExtendedCommunityInterface `json:"value"` }{ Type: p.GetType(), Value: p.Value, }) } func NewPathAttributeExtendedCommunities(value []ExtendedCommunityInterface) *PathAttributeExtendedCommunities { l := len(value) * 8 t := BGP_ATTR_TYPE_EXTENDED_COMMUNITIES return &PathAttributeExtendedCommunities{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, Value: value, } } type PathAttributeAs4Path struct { PathAttribute Value []*As4PathParam } func (p *PathAttributeAs4Path) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length == 0 { // ibgp or something return nil } eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) isAs4, err := validateAsPathValueBytes(value) if err != nil { return err } if !isAs4 { return NewMessageError(eCode, eSubCode, nil, "AS4 PATH param is malformed") } for len(value) > 0 { tuple := &As4PathParam{} tuple.DecodeFromBytes(value) p.Value = append(p.Value, tuple) if len(value) < tuple.Len() { return NewMessageError(eCode, eSubCode, nil, "AS4 PATH param is malformed") } value = value[tuple.Len():] } return nil } func (p *PathAttributeAs4Path) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 0) for _, v := range p.Value { vbuf, err := v.Serialize() if err != nil { return nil, err } buf = append(buf, vbuf...) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeAs4Path) String() string { params := make([]string, 0, len(p.Value)) for _, param := range p.Value { params = append(params, param.String()) } return strings.Join(params, " ") } func (p *PathAttributeAs4Path) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value []*As4PathParam `json:"as_paths"` }{ Type: p.GetType(), Value: p.Value, }) } func NewPathAttributeAs4Path(value []*As4PathParam) *PathAttributeAs4Path { var l int for _, v := range value { l += v.Len() } t := BGP_ATTR_TYPE_AS4_PATH return &PathAttributeAs4Path{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, Value: value, } } type PathAttributeAs4Aggregator struct { PathAttribute Value PathAttributeAggregatorParam } func (p *PathAttributeAs4Aggregator) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length != 8 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) return NewMessageError(eCode, eSubCode, nil, "AS4 Aggregator length is incorrect") } p.Value.AS = binary.BigEndian.Uint32(value[0:4]) p.Value.Address = value[4:] return nil } func (p *PathAttributeAs4Aggregator) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 8) binary.BigEndian.PutUint32(buf[0:], p.Value.AS) copy(buf[4:], p.Value.Address.To4()) return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeAs4Aggregator) String() string { return fmt.Sprintf("{As4Aggregator: {AS: %d, Address: %s}}", p.Value.AS, p.Value.Address) } func (p *PathAttributeAs4Aggregator) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` AS uint32 `json:"as"` Address string `json:"address"` }{ Type: p.GetType(), AS: p.Value.AS, Address: p.Value.Address.String(), }) } func NewPathAttributeAs4Aggregator(as uint32, address string) *PathAttributeAs4Aggregator { t := BGP_ATTR_TYPE_AS4_AGGREGATOR return &PathAttributeAs4Aggregator{ PathAttribute: PathAttribute{ Flags: PathAttrFlags[t], Type: t, Length: 8, }, Value: PathAttributeAggregatorParam{ AS: as, Address: net.ParseIP(address).To4(), }, } } type TunnelEncapSubTLVInterface interface { Len() int DecodeFromBytes([]byte) error Serialize() ([]byte, error) String() string MarshalJSON() ([]byte, error) } type TunnelEncapSubTLV struct { Type EncapSubTLVType Length uint16 } func (t *TunnelEncapSubTLV) Len() int { if t.Type >= 0x80 { return 3 + int(t.Length) } return 2 + int(t.Length) } func (t *TunnelEncapSubTLV) DecodeFromBytes(data []byte) (value []byte, err error) { t.Type = EncapSubTLVType(data[0]) if t.Type >= 0x80 { t.Length = binary.BigEndian.Uint16(data[1:3]) data = data[3:] } else { t.Length = uint16(data[1]) data = data[2:] } if len(data) < int(t.Length) { return nil, NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all TunnelEncapSubTLV bytes available") } return data[:t.Length], nil } func (t *TunnelEncapSubTLV) Serialize(value []byte) (buf []byte, err error) { t.Length = uint16(len(value)) if t.Type >= 0x80 { buf = append(make([]byte, 3), value...) binary.BigEndian.PutUint16(buf[1:3], t.Length) } else { buf = append(make([]byte, 2), value...) buf[1] = uint8(t.Length) } buf[0] = uint8(t.Type) return buf, nil } type TunnelEncapSubTLVUnknown struct { TunnelEncapSubTLV Value []byte } func (t *TunnelEncapSubTLVUnknown) DecodeFromBytes(data []byte) error { value, err := t.TunnelEncapSubTLV.DecodeFromBytes(data) if err != nil { return err } t.Value = value return nil } func (t *TunnelEncapSubTLVUnknown) Serialize() ([]byte, error) { return t.TunnelEncapSubTLV.Serialize(t.Value) } func (t *TunnelEncapSubTLVUnknown) String() string { return fmt.Sprintf("{Type: %d, Value: %x}", t.Type, t.Value) } func (t *TunnelEncapSubTLVUnknown) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type EncapSubTLVType `json:"type"` Value []byte `json:"value"` }{ Type: t.Type, Value: t.Value, }) } func NewTunnelEncapSubTLVUnknown(typ EncapSubTLVType, value []byte) *TunnelEncapSubTLVUnknown { return &TunnelEncapSubTLVUnknown{ TunnelEncapSubTLV: TunnelEncapSubTLV{ Type: typ, }, Value: value, } } type TunnelEncapSubTLVEncapsulation struct { TunnelEncapSubTLV Key uint32 // this represent both SessionID for L2TPv3 case and GRE-key for GRE case (RFC5512 4.) Cookie []byte } func (t *TunnelEncapSubTLVEncapsulation) DecodeFromBytes(data []byte) error { value, err := t.TunnelEncapSubTLV.DecodeFromBytes(data) if err != nil { return err } if t.Length < 4 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all TunnelEncapSubTLVEncapsulation bytes available") } t.Key = binary.BigEndian.Uint32(value[0:4]) t.Cookie = value[4:] return nil } func (t *TunnelEncapSubTLVEncapsulation) Serialize() ([]byte, error) { buf := make([]byte, 4, 4+len(t.Cookie)) binary.BigEndian.PutUint32(buf, t.Key) buf = append(buf, t.Cookie...) return t.TunnelEncapSubTLV.Serialize(buf) } func (t *TunnelEncapSubTLVEncapsulation) String() string { return fmt.Sprintf("{Key: %d, Cookie: %x}", t.Key, t.Cookie) } func (t *TunnelEncapSubTLVEncapsulation) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type EncapSubTLVType `json:"type"` Key uint32 `json:"key"` Cookie []byte `json:"cookie"` }{ Type: t.Type, Key: t.Key, Cookie: t.Cookie, }) } func NewTunnelEncapSubTLVEncapsulation(key uint32, cookie []byte) *TunnelEncapSubTLVEncapsulation { return &TunnelEncapSubTLVEncapsulation{ TunnelEncapSubTLV: TunnelEncapSubTLV{ Type: ENCAP_SUBTLV_TYPE_ENCAPSULATION, }, Key: key, Cookie: cookie, } } type TunnelEncapSubTLVWireguard struct { TunnelEncapSubTLV Peer []byte } func (t *TunnelEncapSubTLVWireguard) DecodeFromBytes(data []byte) error { value, err := t.TunnelEncapSubTLV.DecodeFromBytes(data) if err != nil { return err } if t.Length < 32 { // FIXME return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all TunnelEncapSubTLVWireguard bytes available") } t.Peer = value return nil } func (t *TunnelEncapSubTLVWireguard) Serialize() ([]byte, error) { return t.TunnelEncapSubTLV.Serialize(t.Peer) } func (t *TunnelEncapSubTLVWireguard) String() string { return fmt.Sprintf("{Peer: %s}", base64.StdEncoding.EncodeToString(t.Peer)) } func (t *TunnelEncapSubTLVWireguard) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type EncapSubTLVType `json:"type"` Peer []byte `json:"peer"` }{ Type: t.Type, Peer: t.Peer, }) } func NewTunnelEncapSubTLVWireguard(peer []byte) *TunnelEncapSubTLVWireguard { return &TunnelEncapSubTLVWireguard{ TunnelEncapSubTLV: TunnelEncapSubTLV{ Type: ENCAP_SUBTLV_TYPE_ENCAPSULATION, }, Peer: peer, } } type TunnelEncapSubTLVProtocol struct { TunnelEncapSubTLV Protocol uint16 } func (t *TunnelEncapSubTLVProtocol) DecodeFromBytes(data []byte) error { value, err := t.TunnelEncapSubTLV.DecodeFromBytes(data) if err != nil { return err } if t.Length < 2 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all TunnelEncapSubTLVProtocol bytes available") } t.Protocol = binary.BigEndian.Uint16(value[0:2]) return nil } func (t *TunnelEncapSubTLVProtocol) Serialize() ([]byte, error) { var buf [2]byte binary.BigEndian.PutUint16(buf[:2], t.Protocol) return t.TunnelEncapSubTLV.Serialize(buf[:]) } func (t *TunnelEncapSubTLVProtocol) String() string { return fmt.Sprintf("{Protocol: %d}", t.Protocol) } func (t *TunnelEncapSubTLVProtocol) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type EncapSubTLVType `json:"type"` Protocol uint16 `json:"protocol"` }{ Type: t.Type, Protocol: t.Protocol, }) } func NewTunnelEncapSubTLVProtocol(protocol uint16) *TunnelEncapSubTLVProtocol { return &TunnelEncapSubTLVProtocol{ TunnelEncapSubTLV: TunnelEncapSubTLV{ Type: ENCAP_SUBTLV_TYPE_PROTOCOL, }, Protocol: protocol, } } type TunnelEncapSubTLVColor struct { TunnelEncapSubTLV Color uint32 } func (t *TunnelEncapSubTLVColor) DecodeFromBytes(data []byte) error { value, err := t.TunnelEncapSubTLV.DecodeFromBytes(data) if err != nil { return err } if t.Length != 8 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Invalid TunnelEncapSubTLVColor length") } t.Color = binary.BigEndian.Uint32(value[4:8]) return nil } func (t *TunnelEncapSubTLVColor) Serialize() ([]byte, error) { var buf [8]byte buf[0] = byte(EC_TYPE_TRANSITIVE_OPAQUE) buf[1] = byte(EC_SUBTYPE_COLOR) binary.BigEndian.PutUint32(buf[4:8], t.Color) return t.TunnelEncapSubTLV.Serialize(buf[:]) } func (t *TunnelEncapSubTLVColor) String() string { return fmt.Sprintf("{Color: %d}", t.Color) } func (t *TunnelEncapSubTLVColor) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type EncapSubTLVType `json:"type"` Color uint32 `json:"color"` }{ Type: t.Type, Color: t.Color, }) } func NewTunnelEncapSubTLVColor(color uint32) *TunnelEncapSubTLVColor { return &TunnelEncapSubTLVColor{ TunnelEncapSubTLV: TunnelEncapSubTLV{ Type: ENCAP_SUBTLV_TYPE_COLOR, }, Color: color, } } type TunnelEncapSubTLVEgressEndpoint struct { TunnelEncapSubTLV Address net.IP } // Tunnel Egress Endpoint Sub-TLV subfield positions const ( EGRESS_ENDPOINT_RESERVED_POS = 0 EGRESS_ENDPOINT_FAMILY_POS = 4 EGRESS_ENDPOINT_ADDRESS_POS = 6 ) func (t *TunnelEncapSubTLVEgressEndpoint) DecodeFromBytes(data []byte) error { value, err := t.TunnelEncapSubTLV.DecodeFromBytes(data) if err != nil { return err } if t.Length < EGRESS_ENDPOINT_ADDRESS_POS { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all TunnelEncapSubTLVEgressEndpoint bytes available") } addressFamily := binary.BigEndian.Uint16(value[EGRESS_ENDPOINT_FAMILY_POS : EGRESS_ENDPOINT_FAMILY_POS+2]) var addressLen uint16 switch addressFamily { case 0: addressLen = 0 case AFI_IP: addressLen = net.IPv4len case AFI_IP6: addressLen = net.IPv6len default: return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Unsupported address family in TunnelEncapSubTLVEgressEndpoint") } if t.Length != EGRESS_ENDPOINT_ADDRESS_POS+addressLen { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all TunnelEncapSubTLVEgressEndpoint address bytes available") } t.Address = nil if addressFamily != 0 { t.Address = net.IP(value[EGRESS_ENDPOINT_ADDRESS_POS : EGRESS_ENDPOINT_ADDRESS_POS+addressLen]) } return nil } func (t *TunnelEncapSubTLVEgressEndpoint) Serialize() ([]byte, error) { var length uint32 = EGRESS_ENDPOINT_ADDRESS_POS var family uint16 var ip net.IP if t.Address == nil { family = 0 } else if t.Address.To4() != nil { length += net.IPv4len family = AFI_IP ip = t.Address.To4() } else { length += net.IPv6len family = AFI_IP6 ip = t.Address.To16() } buf := make([]byte, length) binary.BigEndian.PutUint32(buf, 0) binary.BigEndian.PutUint16(buf[EGRESS_ENDPOINT_FAMILY_POS:], family) if family != 0 { copy(buf[EGRESS_ENDPOINT_ADDRESS_POS:], ip) } return t.TunnelEncapSubTLV.Serialize(buf) } func (t *TunnelEncapSubTLVEgressEndpoint) String() string { address := "" if t.Address != nil { address = t.Address.String() } return fmt.Sprintf("{EgressEndpoint: %s}", address) } func (t *TunnelEncapSubTLVEgressEndpoint) MarshalJSON() ([]byte, error) { address := "" if t.Address != nil { address = t.Address.String() } return json.Marshal(struct { Type EncapSubTLVType `json:"type"` Address string `json:"address"` }{ Type: t.Type, Address: address, }) } func NewTunnelEncapSubTLVEgressEndpoint(address string) *TunnelEncapSubTLVEgressEndpoint { var ip net.IP = nil if address != "" { ip = net.ParseIP(address) } return &TunnelEncapSubTLVEgressEndpoint{ TunnelEncapSubTLV: TunnelEncapSubTLV{ Type: ENCAP_SUBTLV_TYPE_EGRESS_ENDPOINT, }, Address: ip, } } type TunnelEncapSubTLVUDPDestPort struct { TunnelEncapSubTLV UDPDestPort uint16 } func (t *TunnelEncapSubTLVUDPDestPort) DecodeFromBytes(data []byte) error { value, err := t.TunnelEncapSubTLV.DecodeFromBytes(data) if err != nil { return err } if t.Length < 2 { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all TunnelEncapSubTLVUDPDestPort bytes available") } t.UDPDestPort = binary.BigEndian.Uint16(value[0:2]) return nil } func (t *TunnelEncapSubTLVUDPDestPort) Serialize() ([]byte, error) { buf := make([]byte, 2) binary.BigEndian.PutUint16(buf, t.UDPDestPort) return t.TunnelEncapSubTLV.Serialize(buf) } func (t *TunnelEncapSubTLVUDPDestPort) String() string { return fmt.Sprintf("{UDPDestPort: %d}", t.UDPDestPort) } func (t *TunnelEncapSubTLVUDPDestPort) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type EncapSubTLVType `json:"type"` UDPDestPort uint16 `json:"port"` }{ Type: t.Type, UDPDestPort: t.UDPDestPort, }) } func NewTunnelEncapSubTLVUDPDestPort(port uint16) *TunnelEncapSubTLVUDPDestPort { return &TunnelEncapSubTLVUDPDestPort{ TunnelEncapSubTLV: TunnelEncapSubTLV{ Type: ENCAP_SUBTLV_TYPE_UDP_DEST_PORT, }, UDPDestPort: port, } } type TunnelEncapTLV struct { Type TunnelType Length uint16 Value []TunnelEncapSubTLVInterface } func (t *TunnelEncapTLV) Len() int { var l int for _, v := range t.Value { l += v.Len() } return 4 + l // Type(2) + Length(2) + Value(variable) } func (t *TunnelEncapTLV) DecodeFromBytes(data []byte) error { t.Type = TunnelType(binary.BigEndian.Uint16(data[0:2])) t.Length = binary.BigEndian.Uint16(data[2:4]) data = data[4:] if len(data) < int(t.Length) { return NewMessageError(BGP_ERROR_UPDATE_MESSAGE_ERROR, BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST, nil, "Not all TunnelEncapTLV bytes available") } value := data[:t.Length] for len(value) > 2 { subType := EncapSubTLVType(value[0]) var subTlv TunnelEncapSubTLVInterface switch subType { case ENCAP_SUBTLV_TYPE_ENCAPSULATION: switch t.Type { case TUNNEL_TYPE_WIREGUARD: subTlv = &TunnelEncapSubTLVWireguard{} default: subTlv = &TunnelEncapSubTLVEncapsulation{} } case ENCAP_SUBTLV_TYPE_PROTOCOL: subTlv = &TunnelEncapSubTLVProtocol{} case ENCAP_SUBTLV_TYPE_COLOR: subTlv = &TunnelEncapSubTLVColor{} case ENCAP_SUBTLV_TYPE_UDP_DEST_PORT: subTlv = &TunnelEncapSubTLVUDPDestPort{} case ENCAP_SUBTLV_TYPE_EGRESS_ENDPOINT: subTlv = &TunnelEncapSubTLVEgressEndpoint{} case ENCAP_SUBTLV_TYPE_SRPREFERENCE: subTlv = &TunnelEncapSubTLVSRPreference{} case ENCAP_SUBTLV_TYPE_SRBINDING_SID: subTlv = &TunnelEncapSubTLVSRBSID{} case ENCAP_SUBTLV_TYPE_SRSEGMENT_LIST: subTlv = &TunnelEncapSubTLVSRSegmentList{} case ENCAP_SUBTLV_TYPE_SRENLP: subTlv = &TunnelEncapSubTLVSRENLP{} case ENCAP_SUBTLV_TYPE_SRPRIORITY: subTlv = &TunnelEncapSubTLVSRPriority{} case ENCAP_SUBTLV_TYPE_SRCANDIDATE_PATH_NAME: subTlv = &TunnelEncapSubTLVSRCandidatePathName{} default: subTlv = &TunnelEncapSubTLVUnknown{ TunnelEncapSubTLV: TunnelEncapSubTLV{ Type: subType, }, } } err := subTlv.DecodeFromBytes(value) if err != nil { return err } t.Value = append(t.Value, subTlv) value = value[subTlv.Len():] } return nil } func (p *TunnelEncapTLV) Serialize() ([]byte, error) { buf := make([]byte, 4) for _, t := range p.Value { tBuf, err := t.Serialize() if err != nil { return nil, err } buf = append(buf, tBuf...) } binary.BigEndian.PutUint16(buf, uint16(p.Type)) binary.BigEndian.PutUint16(buf[2:], uint16(len(buf)-4)) return buf, nil } func (p *TunnelEncapTLV) String() string { tlvList := make([]string, len(p.Value)) for i, v := range p.Value { tlvList[i] = v.String() } return fmt.Sprintf("{%s: %s}", p.Type, strings.Join(tlvList, ", ")) } func (p *TunnelEncapTLV) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type TunnelType `json:"type"` Value []TunnelEncapSubTLVInterface `json:"value"` }{ Type: p.Type, Value: p.Value, }) } func NewTunnelEncapTLV(typ TunnelType, value []TunnelEncapSubTLVInterface) *TunnelEncapTLV { return &TunnelEncapTLV{ Type: typ, Value: value, } } type PathAttributeTunnelEncap struct { PathAttribute Value []*TunnelEncapTLV } func (p *PathAttributeTunnelEncap) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } for len(value) > 4 { tlv := &TunnelEncapTLV{} err = tlv.DecodeFromBytes(value) if err != nil { return err } p.Value = append(p.Value, tlv) value = value[4+tlv.Length:] } return nil } func (p *PathAttributeTunnelEncap) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 0) for _, t := range p.Value { bbuf, err := t.Serialize() if err != nil { return nil, err } buf = append(buf, bbuf...) } return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributeTunnelEncap) String() string { tlvList := make([]string, len(p.Value)) for i, v := range p.Value { tlvList[i] = v.String() } return fmt.Sprintf("{TunnelEncap: %s}", strings.Join(tlvList, ", ")) } func (p *PathAttributeTunnelEncap) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` Value []*TunnelEncapTLV `json:"value"` }{ Type: p.Type, Value: p.Value, }) } func NewPathAttributeTunnelEncap(value []*TunnelEncapTLV) *PathAttributeTunnelEncap { var l int for _, v := range value { l += v.Len() } t := BGP_ATTR_TYPE_TUNNEL_ENCAP return &PathAttributeTunnelEncap{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, Value: value, } } type PmsiTunnelIDInterface interface { Len() int Serialize() ([]byte, error) String() string } type DefaultPmsiTunnelID struct { Value []byte } func (i *DefaultPmsiTunnelID) Len() int { return len(i.Value) } func (i *DefaultPmsiTunnelID) Serialize() ([]byte, error) { return i.Value, nil } func (i *DefaultPmsiTunnelID) String() string { return string(i.Value) } func NewDefaultPmsiTunnelID(value []byte) *DefaultPmsiTunnelID { return &DefaultPmsiTunnelID{ Value: value, } } type IngressReplTunnelID struct { Value net.IP } func (i *IngressReplTunnelID) Len() int { return len(i.Value) } func (i *IngressReplTunnelID) Serialize() ([]byte, error) { if i.Value.To4() != nil { return []byte(i.Value.To4()), nil } return []byte(i.Value), nil } func (i *IngressReplTunnelID) String() string { return i.Value.String() } func NewIngressReplTunnelID(value string) *IngressReplTunnelID { ip := net.ParseIP(value) if ip == nil { return nil } return &IngressReplTunnelID{ Value: ip, } } type PathAttributePmsiTunnel struct { PathAttribute IsLeafInfoRequired bool TunnelType PmsiTunnelType Label uint32 TunnelID PmsiTunnelIDInterface } func (p *PathAttributePmsiTunnel) DecodeFromBytes(data []byte, options ...*MarshallingOption) error { value, err := p.PathAttribute.DecodeFromBytes(data, options...) if err != nil { return err } if p.Length < 5 { eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR) eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST) return NewMessageError(eCode, eSubCode, nil, "PMSI Tunnel length is incorrect") } if (value[0] & 0x01) > 0 { p.IsLeafInfoRequired = true } p.TunnelType = PmsiTunnelType(value[1]) if p.Label, err = labelDecode(value[2:5]); err != nil { return err } switch p.TunnelType { case PMSI_TUNNEL_TYPE_INGRESS_REPL: p.TunnelID = &IngressReplTunnelID{net.IP(value[5:])} default: p.TunnelID = &DefaultPmsiTunnelID{value[5:]} } return nil } func (p *PathAttributePmsiTunnel) Serialize(options ...*MarshallingOption) ([]byte, error) { buf := make([]byte, 2) if p.IsLeafInfoRequired { buf[0] = 0x01 } buf[1] = byte(p.TunnelType) tbuf, err := labelSerialize(p.Label) if err != nil { return nil, err } buf = append(buf, tbuf...) tbuf, err = p.TunnelID.Serialize() if err != nil { return nil, err } buf = append(buf, tbuf...) return p.PathAttribute.Serialize(buf, options...) } func (p *PathAttributePmsiTunnel) String() string { buf := bytes.NewBuffer(make([]byte, 0, 32)) buf.WriteString(fmt.Sprintf("{Pmsi: type: %s,", p.TunnelType)) if p.IsLeafInfoRequired { buf.WriteString(" leaf-info-required,") } buf.WriteString(fmt.Sprintf(" label: %d, tunnel-id: %s}", p.Label, p.TunnelID)) return buf.String() } func (p *PathAttributePmsiTunnel) MarshalJSON() ([]byte, error) { return json.Marshal(struct { Type BGPAttrType `json:"type"` IsLeafInfoRequired bool `json:"is-leaf-info-required"` TunnelType uint8 `json:"tunnel-type"` Label uint32 `json:"label"` TunnelID string `json:"tunnel-id"` }{ Type: p.Type, IsLeafInfoRequired: p.IsLeafInfoRequired, TunnelType: uint8(p.TunnelType), Label: p.Label, TunnelID: p.TunnelID.String(), }) } func NewPathAttributePmsiTunnel(typ PmsiTunnelType, isLeafInfoRequired bool, label uint32, id PmsiTunnelIDInterface) *PathAttributePmsiTunnel { if id == nil { return nil } // Flags(1) + TunnelType(1) + Label(3) + TunnelID(variable) l := 5 + id.Len() t := BGP_ATTR_TYPE_PMSI_TUNNEL return &PathAttributePmsiTunnel{ PathAttribute: PathAttribute{ Flags: getPathAttrFlags(t, l), Type: t, Length: uint16(l), }, IsLeafInfoRequired: isLeafInfoRequired, TunnelType: typ, Label: label, TunnelID: id, } } func ParsePmsiTunnel(args []string) (*PathAttributePmsiTunnel, error) { // Format: // "" ["leaf-info-required"] "