package credentials import ( "bytes" "encoding/binary" "errors" "io/ioutil" "strings" "time" "unsafe" "github.com/jcmturner/gofork/encoding/asn1" "gopkg.in/jcmturner/gokrb5.v7/types" ) const ( headerFieldTagKDCOffset = 1 ) // The first byte of the file always has the value 5. // The value of the second byte contains the version number (1 through 4) // Versions 1 and 2 of the file format use native byte order for integer representations. // Versions 3 and 4 always use big-endian byte order // After the two-byte version indicator, the file has three parts: // 1) the header (in version 4 only) // 2) the default principal name // 3) a sequence of credentials // CCache is the file credentials cache as define here: https://web.mit.edu/kerberos/krb5-latest/doc/formats/ccache_file_format.html type CCache struct { Version uint8 Header header DefaultPrincipal principal Credentials []*Credential Path string } type header struct { length uint16 fields []headerField } type headerField struct { tag uint16 length uint16 value []byte } // Credential cache entry principal struct. type principal struct { Realm string PrincipalName types.PrincipalName } // Credential holds a Kerberos client's ccache credential information. type Credential struct { Client principal Server principal Key types.EncryptionKey AuthTime time.Time StartTime time.Time EndTime time.Time RenewTill time.Time IsSKey bool TicketFlags asn1.BitString Addresses []types.HostAddress AuthData []types.AuthorizationDataEntry Ticket []byte SecondTicket []byte } // LoadCCache loads a credential cache file into a CCache type. func LoadCCache(cpath string) (*CCache, error) { c := new(CCache) b, err := ioutil.ReadFile(cpath) if err != nil { return c, err } err = c.Unmarshal(b) return c, err } // Unmarshal a byte slice of credential cache data into CCache type. func (c *CCache) Unmarshal(b []byte) error { p := 0 //The first byte of the file always has the value 5 if int8(b[p]) != 5 { return errors.New("Invalid credential cache data. First byte does not equal 5") } p++ //Get credential cache version //The second byte contains the version number (1 to 4) c.Version = b[p] if c.Version < 1 || c.Version > 4 { return errors.New("Invalid credential cache data. Keytab version is not within 1 to 4") } p++ //Version 1 or 2 of the file format uses native byte order for integer representations. Versions 3 & 4 always uses big-endian byte order var endian binary.ByteOrder endian = binary.BigEndian if (c.Version == 1 || c.Version == 2) && isNativeEndianLittle() { endian = binary.LittleEndian } if c.Version == 4 { err := parseHeader(b, &p, c, &endian) if err != nil { return err } } c.DefaultPrincipal = parsePrincipal(b, &p, c, &endian) for p < len(b) { cred, err := parseCredential(b, &p, c, &endian) if err != nil { return err } c.Credentials = append(c.Credentials, cred) } return nil } func parseHeader(b []byte, p *int, c *CCache, e *binary.ByteOrder) error { if c.Version != 4 { return errors.New("Credentials cache version is not 4 so there is no header to parse.") } h := header{} h.length = uint16(readInt16(b, p, e)) for *p <= int(h.length) { f := headerField{} f.tag = uint16(readInt16(b, p, e)) f.length = uint16(readInt16(b, p, e)) f.value = b[*p : *p+int(f.length)] *p += int(f.length) if !f.valid() { return errors.New("Invalid credential cache header found") } h.fields = append(h.fields, f) } c.Header = h return nil } // Parse the Keytab bytes of a principal into a Keytab entry's principal. func parsePrincipal(b []byte, p *int, c *CCache, e *binary.ByteOrder) (princ principal) { if c.Version != 1 { //Name Type is omitted in version 1 princ.PrincipalName.NameType = readInt32(b, p, e) } nc := int(readInt32(b, p, e)) if c.Version == 1 { //In version 1 the number of components includes the realm. Minus 1 to make consistent with version 2 nc-- } lenRealm := readInt32(b, p, e) princ.Realm = string(readBytes(b, p, int(lenRealm), e)) for i := 0; i < nc; i++ { l := readInt32(b, p, e) princ.PrincipalName.NameString = append(princ.PrincipalName.NameString, string(readBytes(b, p, int(l), e))) } return princ } func parseCredential(b []byte, p *int, c *CCache, e *binary.ByteOrder) (cred *Credential, err error) { cred = new(Credential) cred.Client = parsePrincipal(b, p, c, e) cred.Server = parsePrincipal(b, p, c, e) key := types.EncryptionKey{} key.KeyType = int32(readInt16(b, p, e)) if c.Version == 3 { //repeated twice in version 3 key.KeyType = int32(readInt16(b, p, e)) } key.KeyValue = readData(b, p, e) cred.Key = key cred.AuthTime = readTimestamp(b, p, e) cred.StartTime = readTimestamp(b, p, e) cred.EndTime = readTimestamp(b, p, e) cred.RenewTill = readTimestamp(b, p, e) if ik := readInt8(b, p, e); ik == 0 { cred.IsSKey = false } else { cred.IsSKey = true } cred.TicketFlags = types.NewKrbFlags() cred.TicketFlags.Bytes = readBytes(b, p, 4, e) l := int(readInt32(b, p, e)) cred.Addresses = make([]types.HostAddress, l, l) for i := range cred.Addresses { cred.Addresses[i] = readAddress(b, p, e) } l = int(readInt32(b, p, e)) cred.AuthData = make([]types.AuthorizationDataEntry, l, l) for i := range cred.AuthData { cred.AuthData[i] = readAuthDataEntry(b, p, e) } cred.Ticket = readData(b, p, e) cred.SecondTicket = readData(b, p, e) return } // GetClientPrincipalName returns a PrincipalName type for the client the credentials cache is for. func (c *CCache) GetClientPrincipalName() types.PrincipalName { return c.DefaultPrincipal.PrincipalName } // GetClientRealm returns the reals of the client the credentials cache is for. func (c *CCache) GetClientRealm() string { return c.DefaultPrincipal.Realm } // GetClientCredentials returns a Credentials object representing the client of the credentials cache. func (c *CCache) GetClientCredentials() *Credentials { return &Credentials{ username: c.DefaultPrincipal.PrincipalName.PrincipalNameString(), realm: c.GetClientRealm(), cname: c.DefaultPrincipal.PrincipalName, } } // Contains tests if the cache contains a credential for the provided server PrincipalName func (c *CCache) Contains(p types.PrincipalName) bool { for _, cred := range c.Credentials { if cred.Server.PrincipalName.Equal(p) { return true } } return false } // GetEntry returns a specific credential for the PrincipalName provided. func (c *CCache) GetEntry(p types.PrincipalName) (*Credential, bool) { cred := new(Credential) var found bool for i := range c.Credentials { if c.Credentials[i].Server.PrincipalName.Equal(p) { cred = c.Credentials[i] found = true break } } if !found { return cred, false } return cred, true } // GetEntries filters out configuration entries an returns a slice of credentials. func (c *CCache) GetEntries() []*Credential { creds := make([]*Credential, 0) for _, cred := range c.Credentials { // Filter out configuration entries if strings.HasPrefix(cred.Server.Realm, "X-CACHECONF") { continue } creds = append(creds, cred) } return creds } func (h *headerField) valid() bool { // At this time there is only one defined header field. // Its tag value is 1, its length is always 8. // Its contents are two 32-bit integers giving the seconds and microseconds // of the time offset of the KDC relative to the client. // Adding this offset to the current time on the client should give the current time on the KDC, if that offset has not changed since the initial authentication. // Done as a switch in case other tag values are added in the future. switch h.tag { case headerFieldTagKDCOffset: if h.length != 8 || len(h.value) != 8 { return false } return true } return false } func readData(b []byte, p *int, e *binary.ByteOrder) []byte { l := readInt32(b, p, e) return readBytes(b, p, int(l), e) } func readAddress(b []byte, p *int, e *binary.ByteOrder) types.HostAddress { a := types.HostAddress{} a.AddrType = int32(readInt16(b, p, e)) a.Address = readData(b, p, e) return a } func readAuthDataEntry(b []byte, p *int, e *binary.ByteOrder) types.AuthorizationDataEntry { a := types.AuthorizationDataEntry{} a.ADType = int32(readInt16(b, p, e)) a.ADData = readData(b, p, e) return a } // Read bytes representing a timestamp. func readTimestamp(b []byte, p *int, e *binary.ByteOrder) time.Time { return time.Unix(int64(readInt32(b, p, e)), 0) } // Read bytes representing an eight bit integer. func readInt8(b []byte, p *int, e *binary.ByteOrder) (i int8) { buf := bytes.NewBuffer(b[*p : *p+1]) binary.Read(buf, *e, &i) *p++ return } // Read bytes representing a sixteen bit integer. func readInt16(b []byte, p *int, e *binary.ByteOrder) (i int16) { buf := bytes.NewBuffer(b[*p : *p+2]) binary.Read(buf, *e, &i) *p += 2 return } // Read bytes representing a thirty two bit integer. func readInt32(b []byte, p *int, e *binary.ByteOrder) (i int32) { buf := bytes.NewBuffer(b[*p : *p+4]) binary.Read(buf, *e, &i) *p += 4 return } func readBytes(b []byte, p *int, s int, e *binary.ByteOrder) []byte { buf := bytes.NewBuffer(b[*p : *p+s]) r := make([]byte, s) binary.Read(buf, *e, &r) *p += s return r } func isNativeEndianLittle() bool { var x = 0x012345678 var p = unsafe.Pointer(&x) var bp = (*[4]byte)(p) var endian bool if 0x01 == bp[0] { endian = false } else if (0x78 & 0xff) == (bp[0] & 0xff) { endian = true } else { // Default to big endian endian = false } return endian }