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|
package bgp
import (
"encoding/binary"
"fmt"
"math"
"net"
"strconv"
)
// Validator for BGPUpdate
func ValidateUpdateMsg(m *BGPUpdate, rfs map[RouteFamily]BGPAddPathMode, isEBGP bool, isConfed bool) (bool, error) {
var strongestError error
eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR)
eSubCodeAttrList := uint8(BGP_ERROR_SUB_MALFORMED_ATTRIBUTE_LIST)
eSubCodeMissing := uint8(BGP_ERROR_SUB_MISSING_WELL_KNOWN_ATTRIBUTE)
if len(m.NLRI) > 0 || len(m.WithdrawnRoutes) > 0 {
if _, ok := rfs[RF_IPv4_UC]; !ok {
return false, NewMessageError(0, 0, nil, fmt.Sprintf("Address-family rf %d not available for session", RF_IPv4_UC))
}
}
seen := make(map[BGPAttrType]PathAttributeInterface)
newAttrs := make([]PathAttributeInterface, 0, len(seen))
// check path attribute
for _, a := range m.PathAttributes {
// check duplication
if _, ok := seen[a.GetType()]; !ok {
seen[a.GetType()] = a
newAttrs = append(newAttrs, a)
//check specific path attribute
ok, err := ValidateAttribute(a, rfs, isEBGP, isConfed)
if !ok {
if err.(*MessageError).ErrorHandling == ERROR_HANDLING_SESSION_RESET {
return false, err
} else if err.(*MessageError).Stronger(strongestError) {
strongestError = err
}
}
} else if a.GetType() == BGP_ATTR_TYPE_MP_REACH_NLRI || a.GetType() == BGP_ATTR_TYPE_MP_UNREACH_NLRI {
eMsg := "the path attribute apears twice. Type : " + strconv.Itoa(int(a.GetType()))
return false, NewMessageError(eCode, eSubCodeAttrList, nil, eMsg)
} else {
eMsg := "the path attribute apears twice. Type : " + strconv.Itoa(int(a.GetType()))
e := NewMessageErrorWithErrorHandling(eCode, eSubCodeAttrList, nil, ERROR_HANDLING_ATTRIBUTE_DISCARD, nil, eMsg)
if e.(*MessageError).Stronger(strongestError) {
strongestError = e
}
}
}
m.PathAttributes = newAttrs
if _, ok := seen[BGP_ATTR_TYPE_MP_REACH_NLRI]; ok || len(m.NLRI) > 0 {
// check the existence of well-known mandatory attributes
exist := func(attrs []BGPAttrType) (bool, BGPAttrType) {
for _, attr := range attrs {
_, ok := seen[attr]
if !ok {
return false, attr
}
}
return true, 0
}
mandatory := []BGPAttrType{BGP_ATTR_TYPE_ORIGIN, BGP_ATTR_TYPE_AS_PATH}
if len(m.NLRI) > 0 {
mandatory = append(mandatory, BGP_ATTR_TYPE_NEXT_HOP)
}
if ok, t := exist(mandatory); !ok {
eMsg := "well-known mandatory attributes are not present. type : " + strconv.Itoa(int(t))
data := []byte{byte(t)}
e := NewMessageErrorWithErrorHandling(eCode, eSubCodeMissing, data, ERROR_HANDLING_TREAT_AS_WITHDRAW, nil, eMsg)
if e.(*MessageError).Stronger(strongestError) {
strongestError = e
}
}
}
return strongestError == nil, strongestError
}
func ValidateAttribute(a PathAttributeInterface, rfs map[RouteFamily]BGPAddPathMode, isEBGP bool, isConfed bool) (bool, error) {
var strongestError error
eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR)
eSubCodeBadOrigin := uint8(BGP_ERROR_SUB_INVALID_ORIGIN_ATTRIBUTE)
eSubCodeBadNextHop := uint8(BGP_ERROR_SUB_INVALID_NEXT_HOP_ATTRIBUTE)
eSubCodeUnknown := uint8(BGP_ERROR_SUB_UNRECOGNIZED_WELL_KNOWN_ATTRIBUTE)
eSubCodeMalformedAspath := uint8(BGP_ERROR_SUB_MALFORMED_AS_PATH)
checkPrefix := func(l []AddrPrefixInterface) error {
for _, prefix := range l {
rf := AfiSafiToRouteFamily(prefix.AFI(), prefix.SAFI())
if _, ok := rfs[rf]; !ok {
return NewMessageError(0, 0, nil, fmt.Sprintf("Address-family %s not available for this session", rf))
}
switch rf {
case RF_FS_IPv4_UC, RF_FS_IPv6_UC, RF_FS_IPv4_VPN, RF_FS_IPv6_VPN, RF_FS_L2_VPN:
t := BGPFlowSpecType(0)
value := make([]FlowSpecComponentInterface, 0)
switch rf {
case RF_FS_IPv4_UC:
value = prefix.(*FlowSpecIPv4Unicast).Value
case RF_FS_IPv6_UC:
value = prefix.(*FlowSpecIPv6Unicast).Value
case RF_FS_IPv4_VPN:
value = prefix.(*FlowSpecIPv4VPN).Value
case RF_FS_IPv6_VPN:
value = prefix.(*FlowSpecIPv6VPN).Value
case RF_FS_L2_VPN:
value = prefix.(*FlowSpecL2VPN).Value
}
for _, v := range value {
if v.Type() <= t {
return NewMessageError(0, 0, nil, fmt.Sprintf("%s nlri violate strict type ordering", rf))
}
t = v.Type()
}
}
}
return nil
}
switch p := a.(type) {
case *PathAttributeMpUnreachNLRI:
rf := AfiSafiToRouteFamily(p.AFI, p.SAFI)
if _, ok := rfs[rf]; !ok {
return false, NewMessageError(0, 0, nil, fmt.Sprintf("Address-family rf %d not available for session", rf))
}
if err := checkPrefix(p.Value); err != nil {
return false, err
}
case *PathAttributeMpReachNLRI:
rf := AfiSafiToRouteFamily(p.AFI, p.SAFI)
if _, ok := rfs[rf]; !ok {
return false, NewMessageError(0, 0, nil, fmt.Sprintf("Address-family rf %d not available for session", rf))
}
if err := checkPrefix(p.Value); err != nil {
return false, err
}
case *PathAttributeOrigin:
v := uint8(p.Value)
if v != BGP_ORIGIN_ATTR_TYPE_IGP &&
v != BGP_ORIGIN_ATTR_TYPE_EGP &&
v != BGP_ORIGIN_ATTR_TYPE_INCOMPLETE {
data, _ := a.Serialize()
eMsg := "invalid origin attribute. value : " + strconv.Itoa(int(v))
e := NewMessageErrorWithErrorHandling(eCode, eSubCodeBadOrigin, data, getErrorHandlingFromPathAttribute(p.GetType()), nil, eMsg)
if e.(*MessageError).Stronger(strongestError) {
strongestError = e
}
}
case *PathAttributeNextHop:
isZero := func(ip net.IP) bool {
res := ip[0] & 0xff
return res == 0x00
}
isClassDorE := func(ip net.IP) bool {
res := ip[0] & 0xe0
return res == 0xe0
}
//check IP address represents host address
if p.Value.IsLoopback() || isZero(p.Value) || isClassDorE(p.Value) {
eMsg := "invalid nexthop address"
data, _ := a.Serialize()
e := NewMessageErrorWithErrorHandling(eCode, eSubCodeBadNextHop, data, getErrorHandlingFromPathAttribute(p.GetType()), nil, eMsg)
if e.(*MessageError).Stronger(strongestError) {
strongestError = e
}
}
case *PathAttributeAsPath:
if isEBGP {
if isConfed {
if segType := p.Value[0].GetType(); segType != BGP_ASPATH_ATTR_TYPE_CONFED_SEQ {
return false, NewMessageError(eCode, eSubCodeMalformedAspath, nil, fmt.Sprintf("segment type is not confederation seq (%d)", segType))
}
} else {
for _, param := range p.Value {
segType := param.GetType()
switch segType {
case BGP_ASPATH_ATTR_TYPE_CONFED_SET, BGP_ASPATH_ATTR_TYPE_CONFED_SEQ:
err := NewMessageErrorWithErrorHandling(
eCode, eSubCodeMalformedAspath, nil, getErrorHandlingFromPathAttribute(p.GetType()), nil, fmt.Sprintf("segment type confederation(%d) found", segType))
if err.(*MessageError).Stronger(strongestError) {
strongestError = err
}
}
}
}
}
case *PathAttributeLargeCommunities:
uniq := make([]*LargeCommunity, 0, len(p.Values))
for _, x := range p.Values {
found := false
for _, y := range uniq {
if x.String() == y.String() {
found = true
break
}
}
if !found {
uniq = append(uniq, x)
}
}
p.Values = uniq
case *PathAttributeUnknown:
if p.GetFlags()&BGP_ATTR_FLAG_OPTIONAL == 0 {
eMsg := fmt.Sprintf("unrecognized well-known attribute %s", p.GetType())
data, _ := a.Serialize()
return false, NewMessageError(eCode, eSubCodeUnknown, data, eMsg)
}
}
return strongestError == nil, strongestError
}
// validator for PathAttribute
func validatePathAttributeFlags(t BGPAttrType, flags BGPAttrFlag) string {
/*
* RFC 4271 P.17 For well-known attributes, the Transitive bit MUST be set to 1.
*/
if flags&BGP_ATTR_FLAG_OPTIONAL == 0 && flags&BGP_ATTR_FLAG_TRANSITIVE == 0 {
eMsg := fmt.Sprintf("well-known attribute %s must have transitive flag 1", t)
return eMsg
}
/*
* RFC 4271 P.17 For well-known attributes and for optional non-transitive attributes,
* the Partial bit MUST be set to 0.
*/
if flags&BGP_ATTR_FLAG_OPTIONAL == 0 && flags&BGP_ATTR_FLAG_PARTIAL != 0 {
eMsg := fmt.Sprintf("well-known attribute %s must have partial bit 0", t)
return eMsg
}
if flags&BGP_ATTR_FLAG_OPTIONAL != 0 && flags&BGP_ATTR_FLAG_TRANSITIVE == 0 && flags&BGP_ATTR_FLAG_PARTIAL != 0 {
eMsg := fmt.Sprintf("optional non-transitive attribute %s must have partial bit 0", t)
return eMsg
}
// check flags are correct
if f, ok := PathAttrFlags[t]; ok {
if f != flags & ^BGP_ATTR_FLAG_EXTENDED_LENGTH & ^BGP_ATTR_FLAG_PARTIAL {
eMsg := fmt.Sprintf("flags are invalid. attribute type: %s, expect: %s, actual: %s", t, f, flags)
return eMsg
}
}
return ""
}
func validateAsPathValueBytes(data []byte) (bool, error) {
eCode := uint8(BGP_ERROR_UPDATE_MESSAGE_ERROR)
eSubCode := uint8(BGP_ERROR_SUB_MALFORMED_AS_PATH)
if len(data)%2 != 0 {
return false, NewMessageError(eCode, eSubCode, nil, "AS PATH length is not odd")
}
tryParse := func(data []byte, use4byte bool) (bool, error) {
for len(data) > 0 {
if len(data) < 2 {
return false, NewMessageError(eCode, eSubCode, nil, "AS PATH header is short")
}
segType := data[0]
if segType == 0 || segType > 4 {
return false, NewMessageError(eCode, eSubCode, nil, "unknown AS_PATH seg type")
}
asNum := data[1]
data = data[2:]
if asNum == 0 || int(asNum) > math.MaxUint8 {
return false, NewMessageError(eCode, eSubCode, nil, "AS PATH the number of AS is incorrect")
}
segLength := int(asNum)
if use4byte == true {
segLength *= 4
} else {
segLength *= 2
}
if int(segLength) > len(data) {
return false, NewMessageError(eCode, eSubCode, nil, "seg length is short")
}
data = data[segLength:]
}
return true, nil
}
_, err := tryParse(data, true)
if err == nil {
return true, nil
}
_, err = tryParse(data, false)
if err == nil {
return false, nil
}
return false, NewMessageError(eCode, eSubCode, nil, "can't parse AS_PATH")
}
func ValidateBGPMessage(m *BGPMessage) error {
if m.Header.Len > BGP_MAX_MESSAGE_LENGTH {
buf := make([]byte, 2)
binary.BigEndian.PutUint16(buf, m.Header.Len)
return NewMessageError(BGP_ERROR_MESSAGE_HEADER_ERROR, BGP_ERROR_SUB_BAD_MESSAGE_LENGTH, buf, "too long length")
}
return nil
}
func ValidateOpenMsg(m *BGPOpen, expectedAS uint32) (uint32, error) {
if m.Version != 4 {
return 0, NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNSUPPORTED_VERSION_NUMBER, nil, fmt.Sprintf("unsupported version %d", m.Version))
}
as := uint32(m.MyAS)
for _, p := range m.OptParams {
paramCap, y := p.(*OptionParameterCapability)
if !y {
continue
}
for _, c := range paramCap.Capability {
if c.Code() == BGP_CAP_FOUR_OCTET_AS_NUMBER {
cap := c.(*CapFourOctetASNumber)
as = cap.CapValue
}
}
}
if expectedAS != 0 && as != expectedAS {
return 0, NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_BAD_PEER_AS, nil, fmt.Sprintf("as number mismatch expected %d, received %d", expectedAS, as))
}
if m.HoldTime < 3 && m.HoldTime != 0 {
return 0, NewMessageError(BGP_ERROR_OPEN_MESSAGE_ERROR, BGP_ERROR_SUB_UNACCEPTABLE_HOLD_TIME, nil, fmt.Sprintf("unacceptable hold time %d", m.HoldTime))
}
return as, nil
}
|