// Package keytab implements Kerberos keytabs: https://web.mit.edu/kerberos/krb5-devel/doc/formats/keytab_file_format.html. package keytab import ( "bytes" "encoding/binary" "errors" "fmt" "io" "io/ioutil" "time" "unsafe" "gopkg.in/jcmturner/gokrb5.v7/types" ) const ( keytabFirstByte byte = 05 ) // Keytab struct. type Keytab struct { version uint8 Entries []entry } // Keytab entry struct. type entry struct { Principal principal Timestamp time.Time KVNO8 uint8 Key types.EncryptionKey KVNO uint32 } // Keytab entry principal struct. type principal struct { NumComponents int16 Realm string Components []string NameType int32 } // New creates new, empty Keytab type. func New() *Keytab { var e []entry return &Keytab{ version: 0, Entries: e, } } // GetEncryptionKey returns the EncryptionKey from the Keytab for the newest entry with the required kvno, etype and matching principal. func (kt *Keytab) GetEncryptionKey(princName types.PrincipalName, realm string, kvno int, etype int32) (types.EncryptionKey, error) { //TODO (theme: KVNO from keytab) this function should return the kvno too var key types.EncryptionKey var t time.Time for _, k := range kt.Entries { if k.Principal.Realm == realm && len(k.Principal.Components) == len(princName.NameString) && k.Key.KeyType == etype && (k.KVNO == uint32(kvno) || kvno == 0) && k.Timestamp.After(t) { p := true for i, n := range k.Principal.Components { if princName.NameString[i] != n { p = false break } } if p { key = k.Key t = k.Timestamp } } } if len(key.KeyValue) < 1 { return key, fmt.Errorf("matching key not found in keytab. Looking for %v realm: %v kvno: %v etype: %v", princName.NameString, realm, kvno, etype) } return key, nil } // Create a new Keytab entry. func newKeytabEntry() entry { var b []byte return entry{ Principal: newPrincipal(), Timestamp: time.Time{}, KVNO8: 0, Key: types.EncryptionKey{ KeyType: 0, KeyValue: b, }, KVNO: 0, } } // Create a new principal. func newPrincipal() principal { var c []string return principal{ NumComponents: 0, Realm: "", Components: c, NameType: 0, } } // Load a Keytab file into a Keytab type. func Load(ktPath string) (*Keytab, error) { kt := new(Keytab) b, err := ioutil.ReadFile(ktPath) if err != nil { return kt, err } err = kt.Unmarshal(b) return kt, err } // Marshal keytab into byte slice func (kt *Keytab) Marshal() ([]byte, error) { b := []byte{keytabFirstByte, kt.version} for _, e := range kt.Entries { eb, err := e.marshal(int(kt.version)) if err != nil { return b, err } b = append(b, eb...) } return b, nil } // Write the keytab bytes to io.Writer. // Returns the number of bytes written func (kt *Keytab) Write(w io.Writer) (int, error) { b, err := kt.Marshal() if err != nil { return 0, fmt.Errorf("error marshaling keytab: %v", err) } return w.Write(b) } // Unmarshal byte slice of Keytab data into Keytab type. func (kt *Keytab) Unmarshal(b []byte) error { if len(b) < 2 { return fmt.Errorf("byte array is less than 2 bytes: %d", len(b)) } //The first byte of the file always has the value 5 if b[0] != keytabFirstByte { return errors.New("invalid keytab data. First byte does not equal 5") } //Get keytab version //The 2nd byte contains the version number (1 or 2) kt.version = b[1] if kt.version != 1 && kt.version != 2 { return errors.New("invalid keytab data. Keytab version is neither 1 nor 2") } //Version 1 of the file format uses native byte order for integer representations. Version 2 always uses big-endian byte order var endian binary.ByteOrder endian = binary.BigEndian if kt.version == 1 && isNativeEndianLittle() { endian = binary.LittleEndian } /* After the two-byte version indicator, the file contains a sequence of signed 32-bit record lengths followed by key records or holes. A positive record length indicates a valid key entry whose size is equal to or less than the record length. A negative length indicates a zero-filled hole whose size is the inverse of the length. A length of 0 indicates the end of the file. */ // n tracks position in the byte array n := 2 l, err := readInt32(b, &n, &endian) if err != nil { return err } for l != 0 { if l < 0 { //Zero padded so skip over l = l * -1 n = n + int(l) } else { //fmt.Printf("Bytes for entry: %v\n", b[n:n+int(l)]) if n < 0 { return fmt.Errorf("%d can't be less than zero", n) } if n+int(l) > len(b) { return fmt.Errorf("%s's length is less than %d", b, n+int(l)) } eb := b[n : n+int(l)] n = n + int(l) ke := newKeytabEntry() // p keeps track as to where we are in the byte stream var p int var err error parsePrincipal(eb, &p, kt, &ke, &endian) ke.Timestamp, err = readTimestamp(eb, &p, &endian) if err != nil { return err } rei8, err := readInt8(eb, &p, &endian) if err != nil { return err } ke.KVNO8 = uint8(rei8) rei16, err := readInt16(eb, &p, &endian) if err != nil { return err } ke.Key.KeyType = int32(rei16) rei16, err = readInt16(eb, &p, &endian) if err != nil { return err } kl := int(rei16) ke.Key.KeyValue, err = readBytes(eb, &p, kl, &endian) if err != nil { return err } //The 32-bit key version overrides the 8-bit key version. // To determine if it is present, the implementation must check that at least 4 bytes remain in the record after the other fields are read, // and that the value of the 32-bit integer contained in those bytes is non-zero. if len(eb)-p >= 4 { // The 32-bit key may be present ri32, err := readInt32(eb, &p, &endian) if err != nil { return err } ke.KVNO = uint32(ri32) } if ke.KVNO == 0 { // Handles if the value from the last 4 bytes was zero and also if there are not the 4 bytes present. Makes sense to put the same value here as KVNO8 ke.KVNO = uint32(ke.KVNO8) } // Add the entry to the keytab kt.Entries = append(kt.Entries, ke) } // Check if there are still 4 bytes left to read // Also check that n is greater than zero if n < 0 || n > len(b) || len(b[n:]) < 4 { break } // Read the size of the next entry l, err = readInt32(b, &n, &endian) if err != nil { return err } } return nil } func (e entry) marshal(v int) ([]byte, error) { var b []byte pb, err := e.Principal.marshal(v) if err != nil { return b, err } b = append(b, pb...) var endian binary.ByteOrder endian = binary.BigEndian if v == 1 && isNativeEndianLittle() { endian = binary.LittleEndian } t := make([]byte, 9) endian.PutUint32(t[0:4], uint32(e.Timestamp.Unix())) t[4] = e.KVNO8 endian.PutUint16(t[5:7], uint16(e.Key.KeyType)) endian.PutUint16(t[7:9], uint16(len(e.Key.KeyValue))) b = append(b, t...) buf := new(bytes.Buffer) err = binary.Write(buf, endian, e.Key.KeyValue) if err != nil { return b, err } b = append(b, buf.Bytes()...) t = make([]byte, 4) endian.PutUint32(t, e.KVNO) b = append(b, t...) // Add the length header t = make([]byte, 4) endian.PutUint32(t, uint32(len(b))) b = append(t, b...) return b, nil } // Parse the Keytab bytes of a principal into a Keytab entry's principal. func parsePrincipal(b []byte, p *int, kt *Keytab, ke *entry, e *binary.ByteOrder) error { var err error ke.Principal.NumComponents, err = readInt16(b, p, e) if err != nil { return err } if kt.version == 1 { //In version 1 the number of components includes the realm. Minus 1 to make consistent with version 2 ke.Principal.NumComponents-- } lenRealm, err := readInt16(b, p, e) if err != nil { return err } realmB, err := readBytes(b, p, int(lenRealm), e) if err != nil { return err } ke.Principal.Realm = string(realmB) for i := 0; i < int(ke.Principal.NumComponents); i++ { l, err := readInt16(b, p, e) if err != nil { return err } compB, err := readBytes(b, p, int(l), e) if err != nil { return err } ke.Principal.Components = append(ke.Principal.Components, string(compB)) } if kt.version != 1 { //Name Type is omitted in version 1 ke.Principal.NameType, err = readInt32(b, p, e) if err != nil { return err } } return nil } func (p principal) marshal(v int) ([]byte, error) { //var b []byte b := make([]byte, 2) var endian binary.ByteOrder endian = binary.BigEndian if v == 1 && isNativeEndianLittle() { endian = binary.LittleEndian } endian.PutUint16(b[0:], uint16(p.NumComponents)) realm, err := marshalString(p.Realm, v) if err != nil { return b, err } b = append(b, realm...) for _, c := range p.Components { cb, err := marshalString(c, v) if err != nil { return b, err } b = append(b, cb...) } if v != 1 { t := make([]byte, 4) endian.PutUint32(t, uint32(p.NameType)) b = append(b, t...) } return b, nil } func marshalString(s string, v int) ([]byte, error) { sb := []byte(s) b := make([]byte, 2) var endian binary.ByteOrder endian = binary.BigEndian if v == 1 && isNativeEndianLittle() { endian = binary.LittleEndian } endian.PutUint16(b[0:], uint16(len(sb))) buf := new(bytes.Buffer) err := binary.Write(buf, endian, sb) if err != nil { return b, err } b = append(b, buf.Bytes()...) return b, err } // Read bytes representing a timestamp. func readTimestamp(b []byte, p *int, e *binary.ByteOrder) (time.Time, error) { i32, err := readInt32(b, p, e) if err != nil { return time.Time{}, err } return time.Unix(int64(i32), 0), nil } // Read bytes representing an eight bit integer. func readInt8(b []byte, p *int, e *binary.ByteOrder) (i int8, err error) { if *p < 0 { return 0, fmt.Errorf("%d cannot be less than zero", *p) } if (*p + 1) > len(b) { return 0, fmt.Errorf("%s's length is less than %d", b, *p+1) } 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, err error) { if *p < 0 { return 0, fmt.Errorf("%d cannot be less than zero", *p) } if (*p + 2) > len(b) { return 0, fmt.Errorf("%s's length is less than %d", b, *p+2) } 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, err error) { if *p < 0 { return 0, fmt.Errorf("%d cannot be less than zero", *p) } if (*p + 4) > len(b) { return 0, fmt.Errorf("%s's length is less than %d", b, *p+4) } 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, error) { if s < 0 { return nil, fmt.Errorf("%d cannot be less than zero", s) } i := *p + s if i > len(b) { return nil, fmt.Errorf("%s's length is greater than %d", b, i) } buf := bytes.NewBuffer(b[*p:i]) r := make([]byte, s) if err := binary.Read(buf, *e, &r); err != nil { return nil, err } *p += s return r, nil } 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 }