vendor/github.com/jcmturner/gokrb5/v8/gssapi/MICToken.go - voltha-openonu-adapter-go - Gitiles

 package gssapi

 import (
 	"bytes"
 	"crypto/hmac"
 	"encoding/binary"
 	"encoding/hex"
 	"errors"
 	"fmt"

 	"github.com/jcmturner/gokrb5/v8/crypto"
 	"github.com/jcmturner/gokrb5/v8/iana/keyusage"
 	"github.com/jcmturner/gokrb5/v8/types"
 )

 // RFC 4121, section 4.2.6.1

 const (
 	// MICTokenFlagSentByAcceptor - this flag indicates the sender is the context acceptor.  When not set, it indicates the sender is the context initiator
 	MICTokenFlagSentByAcceptor = 1 << iota
 	// MICTokenFlagSealed - this flag indicates confidentiality is provided for.  It SHALL NOT be set in MIC tokens
 	MICTokenFlagSealed
 	// MICTokenFlagAcceptorSubkey - a subkey asserted by the context acceptor is used to protect the message
 	MICTokenFlagAcceptorSubkey
 )

 const (
 	micHdrLen = 16 // Length of the MIC Token's header
 )

 // MICToken represents a GSS API MIC token, as defined in RFC 4121.
 // It contains the header fields, the payload (this is not transmitted) and
 // the checksum, and provides the logic for converting to/from bytes plus
 // computing and verifying checksums
 type MICToken struct {
 	// const GSS Token ID: 0x0404
 	Flags byte // contains three flags: acceptor, sealed, acceptor subkey
 	// const Filler: 0xFF 0xFF 0xFF 0xFF 0xFF
 	SndSeqNum uint64 // sender's sequence number. big-endian
 	Payload   []byte // your data! :)
 	Checksum  []byte // checksum of { payload | header }
 }

 // Return the 2 bytes identifying a GSS API MIC token
 func getGSSMICTokenID() *[2]byte {
 	return &[2]byte{0x04, 0x04}
 }

 // Return the filler bytes used in header
 func fillerBytes() *[5]byte {
 	return &[5]byte{0xFF, 0xFF, 0xFF, 0xFF, 0xFF}
 }

 // Marshal the MICToken into a byte slice.
 // The payload should have been set and the checksum computed, otherwise an error is returned.
 func (mt *MICToken) Marshal() ([]byte, error) {
 	if mt.Checksum == nil {
 		return nil, errors.New("checksum has not been set")
 	}

 	bytes := make([]byte, micHdrLen+len(mt.Checksum))
 	copy(bytes[0:micHdrLen], mt.getMICChecksumHeader()[:])
 	copy(bytes[micHdrLen:], mt.Checksum)

 	return bytes, nil
 }

 // SetChecksum uses the passed encryption key and key usage to compute the checksum over the payload and
 // the header, and sets the Checksum field of this MICToken.
 // If the payload has not been set or the checksum has already been set, an error is returned.
 func (mt *MICToken) SetChecksum(key types.EncryptionKey, keyUsage uint32) error {
 	if mt.Checksum != nil {
 		return errors.New("checksum has already been computed")
 	}
 	checksum, err := mt.checksum(key, keyUsage)
 	if err != nil {
 		return err
 	}
 	mt.Checksum = checksum
 	return nil
 }

 // Compute and return the checksum of this token, computed using the passed key and key usage.
 // Note: This will NOT update the struct's Checksum field.
 func (mt *MICToken) checksum(key types.EncryptionKey, keyUsage uint32) ([]byte, error) {
 	if mt.Payload == nil {
 		return nil, errors.New("cannot compute checksum with uninitialized payload")
 	}
 	d := make([]byte, micHdrLen+len(mt.Payload))
 	copy(d[0:], mt.Payload)
 	copy(d[len(mt.Payload):], mt.getMICChecksumHeader())

 	encType, err := crypto.GetEtype(key.KeyType)
 	if err != nil {
 		return nil, err
 	}
 	return encType.GetChecksumHash(key.KeyValue, d, keyUsage)
 }

 // Build a header suitable for a checksum computation
 func (mt *MICToken) getMICChecksumHeader() []byte {
 	header := make([]byte, micHdrLen)
 	copy(header[0:2], getGSSMICTokenID()[:])
 	header[2] = mt.Flags
 	copy(header[3:8], fillerBytes()[:])
 	binary.BigEndian.PutUint64(header[8:16], mt.SndSeqNum)
 	return header
 }

 // Verify computes the token's checksum with the provided key and usage,
 // and compares it to the checksum present in the token.
 // In case of any failure, (false, err) is returned, with err an explanatory error.
 func (mt *MICToken) Verify(key types.EncryptionKey, keyUsage uint32) (bool, error) {
 	computed, err := mt.checksum(key, keyUsage)
 	if err != nil {
 		return false, err
 	}
 	if !hmac.Equal(computed, mt.Checksum) {
 		return false, fmt.Errorf(
 			"checksum mismatch. Computed: %s, Contained in token: %s",
 			hex.EncodeToString(computed), hex.EncodeToString(mt.Checksum))
 	}
 	return true, nil
 }

 // Unmarshal bytes into the corresponding MICToken.
 // If expectFromAcceptor is true we expect the token to have been emitted by the gss acceptor,
 // and will check the according flag, returning an error if the token does not match the expectation.
 func (mt *MICToken) Unmarshal(b []byte, expectFromAcceptor bool) error {
 	if len(b) < micHdrLen {
 		return errors.New("bytes shorter than header length")
 	}
 	if !bytes.Equal(getGSSMICTokenID()[:], b[0:2]) {
 		return fmt.Errorf("wrong Token ID, Expected %s, was %s",
 			hex.EncodeToString(getGSSMICTokenID()[:]),
 			hex.EncodeToString(b[0:2]))
 	}
 	flags := b[2]
 	isFromAcceptor := flags&MICTokenFlagSentByAcceptor != 0
 	if isFromAcceptor && !expectFromAcceptor {
 		return errors.New("unexpected acceptor flag is set: not expecting a token from the acceptor")
 	}
 	if !isFromAcceptor && expectFromAcceptor {
 		return errors.New("unexpected acceptor flag is not set: expecting a token from the acceptor, not in the initiator")
 	}
 	if !bytes.Equal(b[3:8], fillerBytes()[:]) {
 		return fmt.Errorf("unexpected filler bytes: expecting %s, was %s",
 			hex.EncodeToString(fillerBytes()[:]),
 			hex.EncodeToString(b[3:8]))
 	}

 	mt.Flags = flags
 	mt.SndSeqNum = binary.BigEndian.Uint64(b[8:16])
 	mt.Checksum = b[micHdrLen:]
 	return nil
 }

 // NewInitiatorMICToken builds a new initiator token (acceptor flag will be set to 0) and computes the authenticated checksum.
 // Other flags are set to 0.
 // Note that in certain circumstances you may need to provide a sequence number that has been defined earlier.
 // This is currently not supported.
 func NewInitiatorMICToken(payload []byte, key types.EncryptionKey) (*MICToken, error) {
 	token := MICToken{
 		Flags:     0x00,
 		SndSeqNum: 0,
 		Payload:   payload,
 	}

 	if err := token.SetChecksum(key, keyusage.GSSAPI_INITIATOR_SIGN); err != nil {
 		return nil, err
 	}

 	return &token, nil
 }
	package gssapi

	import (
	"bytes"
	"crypto/hmac"
	"encoding/binary"
	"encoding/hex"
	"errors"
	"fmt"

	"github.com/jcmturner/gokrb5/v8/crypto"
	"github.com/jcmturner/gokrb5/v8/iana/keyusage"
	"github.com/jcmturner/gokrb5/v8/types"
	)

	// RFC 4121, section 4.2.6.1

	const (
	// MICTokenFlagSentByAcceptor - this flag indicates the sender is the context acceptor. When not set, it indicates the sender is the context initiator
	MICTokenFlagSentByAcceptor = 1 << iota
	// MICTokenFlagSealed - this flag indicates confidentiality is provided for. It SHALL NOT be set in MIC tokens
	MICTokenFlagSealed
	// MICTokenFlagAcceptorSubkey - a subkey asserted by the context acceptor is used to protect the message
	MICTokenFlagAcceptorSubkey
	)

	const (
	micHdrLen = 16 // Length of the MIC Token's header
	)

	// MICToken represents a GSS API MIC token, as defined in RFC 4121.
	// It contains the header fields, the payload (this is not transmitted) and
	// the checksum, and provides the logic for converting to/from bytes plus
	// computing and verifying checksums
	type MICToken struct {
	// const GSS Token ID: 0x0404
	Flags byte // contains three flags: acceptor, sealed, acceptor subkey
	// const Filler: 0xFF 0xFF 0xFF 0xFF 0xFF
	SndSeqNum uint64 // sender's sequence number. big-endian
	Payload []byte // your data! :)
	Checksum []byte // checksum of { payload \| header }
	}

	// Return the 2 bytes identifying a GSS API MIC token
	func getGSSMICTokenID() *[2]byte {
	return &[2]byte{0x04, 0x04}
	}

	// Return the filler bytes used in header
	func fillerBytes() *[5]byte {
	return &[5]byte{0xFF, 0xFF, 0xFF, 0xFF, 0xFF}
	}

	// Marshal the MICToken into a byte slice.
	// The payload should have been set and the checksum computed, otherwise an error is returned.
	func (mt *MICToken) Marshal() ([]byte, error) {
	if mt.Checksum == nil {
	return nil, errors.New("checksum has not been set")
	}

	bytes := make([]byte, micHdrLen+len(mt.Checksum))
	copy(bytes[0:micHdrLen], mt.getMICChecksumHeader()[:])
	copy(bytes[micHdrLen:], mt.Checksum)

	return bytes, nil
	}

	// SetChecksum uses the passed encryption key and key usage to compute the checksum over the payload and
	// the header, and sets the Checksum field of this MICToken.
	// If the payload has not been set or the checksum has already been set, an error is returned.
	func (mt *MICToken) SetChecksum(key types.EncryptionKey, keyUsage uint32) error {
	if mt.Checksum != nil {
	return errors.New("checksum has already been computed")
	}
	checksum, err := mt.checksum(key, keyUsage)
	if err != nil {
	return err
	}
	mt.Checksum = checksum
	return nil
	}

	// Compute and return the checksum of this token, computed using the passed key and key usage.
	// Note: This will NOT update the struct's Checksum field.
	func (mt *MICToken) checksum(key types.EncryptionKey, keyUsage uint32) ([]byte, error) {
	if mt.Payload == nil {
	return nil, errors.New("cannot compute checksum with uninitialized payload")
	}
	d := make([]byte, micHdrLen+len(mt.Payload))
	copy(d[0:], mt.Payload)
	copy(d[len(mt.Payload):], mt.getMICChecksumHeader())

	encType, err := crypto.GetEtype(key.KeyType)
	if err != nil {
	return nil, err
	}
	return encType.GetChecksumHash(key.KeyValue, d, keyUsage)
	}

	// Build a header suitable for a checksum computation
	func (mt *MICToken) getMICChecksumHeader() []byte {
	header := make([]byte, micHdrLen)
	copy(header[0:2], getGSSMICTokenID()[:])
	header[2] = mt.Flags
	copy(header[3:8], fillerBytes()[:])
	binary.BigEndian.PutUint64(header[8:16], mt.SndSeqNum)
	return header
	}

	// Verify computes the token's checksum with the provided key and usage,
	// and compares it to the checksum present in the token.
	// In case of any failure, (false, err) is returned, with err an explanatory error.
	func (mt *MICToken) Verify(key types.EncryptionKey, keyUsage uint32) (bool, error) {
	computed, err := mt.checksum(key, keyUsage)
	if err != nil {
	return false, err
	}
	if !hmac.Equal(computed, mt.Checksum) {
	return false, fmt.Errorf(
	"checksum mismatch. Computed: %s, Contained in token: %s",
	hex.EncodeToString(computed), hex.EncodeToString(mt.Checksum))
	}
	return true, nil
	}

	// Unmarshal bytes into the corresponding MICToken.
	// If expectFromAcceptor is true we expect the token to have been emitted by the gss acceptor,
	// and will check the according flag, returning an error if the token does not match the expectation.
	func (mt *MICToken) Unmarshal(b []byte, expectFromAcceptor bool) error {
	if len(b) < micHdrLen {
	return errors.New("bytes shorter than header length")
	}
	if !bytes.Equal(getGSSMICTokenID()[:], b[0:2]) {
	return fmt.Errorf("wrong Token ID, Expected %s, was %s",
	hex.EncodeToString(getGSSMICTokenID()[:]),
	hex.EncodeToString(b[0:2]))
	}
	flags := b[2]
	isFromAcceptor := flags&MICTokenFlagSentByAcceptor != 0
	if isFromAcceptor && !expectFromAcceptor {
	return errors.New("unexpected acceptor flag is set: not expecting a token from the acceptor")
	}
	if !isFromAcceptor && expectFromAcceptor {
	return errors.New("unexpected acceptor flag is not set: expecting a token from the acceptor, not in the initiator")
	}
	if !bytes.Equal(b[3:8], fillerBytes()[:]) {
	return fmt.Errorf("unexpected filler bytes: expecting %s, was %s",
	hex.EncodeToString(fillerBytes()[:]),
	hex.EncodeToString(b[3:8]))
	}

	mt.Flags = flags
	mt.SndSeqNum = binary.BigEndian.Uint64(b[8:16])
	mt.Checksum = b[micHdrLen:]
	return nil
	}

	// NewInitiatorMICToken builds a new initiator token (acceptor flag will be set to 0) and computes the authenticated checksum.
	// Other flags are set to 0.
	// Note that in certain circumstances you may need to provide a sequence number that has been defined earlier.
	// This is currently not supported.
	func NewInitiatorMICToken(payload []byte, key types.EncryptionKey) (*MICToken, error) {
	token := MICToken{
	Flags: 0x00,
	SndSeqNum: 0,
	Payload: payload,
	}

	if err := token.SetChecksum(key, keyusage.GSSAPI_INITIATOR_SIGN); err != nil {
	return nil, err
	}

	return &token, nil
	}