keychain

package
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Published: Sep 9, 2023 License: MIT Imports: 8 Imported by: 0

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Index

Constants

View Source
const (
	// CoinTypeBitcoin specifies the BIP44 coin type for Bitcoin key
	// derivation.
	CoinTypeBitcoin uint32 = 0

	// CoinTypeTestnet specifies the BIP44 coin type for all testnet key
	// derivation.
	CoinTypeTestnet = 1

	// CoinTypeLitecoin specifies the BIP44 coin type for Litecoin key
	// derivation.
	CoinTypeLitecoin = 2
)
View Source
const (
	// KeyDerivationVersion is the version of the key derivation schema
	// defined below. We use a version as this means that we'll be able to
	// accept new seed in the future and be able to discern if the software
	// is compatible with the version of the seed.
	KeyDerivationVersion = 0

	// BIP0043Purpose is the "purpose" value that we'll use for the first
	// version or our key derivation scheme. All keys are expected to be
	// derived from this purpose, then the particular coin type of the
	// chain where the keys are to be used.  Slightly adhering to BIP0043
	// allows us to not deviate too far from a widely used standard, and
	// also fits into existing implementations of the BIP's template.
	//
	// NOTE: BRICK SQUUUUUAD.
	BIP0043Purpose = 1017
)

Variables

View Source
var (
	// MaxKeyRangeScan is the maximum number of keys that we'll attempt to
	// scan with if a caller knows the public key, but not the KeyLocator
	// and wishes to derive a private key.
	MaxKeyRangeScan = 100000

	// ErrCannotDerivePrivKey is returned when DerivePrivKey is unable to
	// derive a private key given only the public key and target key
	// family.
	ErrCannotDerivePrivKey = fmt.Errorf("unable to derive private key")
)

VersionZeroKeyFamilies is a slice of all the known key families for first version of the key derivation schema defined in this package.

Functions

This section is empty.

Types

type BtcWalletKeyRing

type BtcWalletKeyRing struct {
	// contains filtered or unexported fields
}

BtcWalletKeyRing is an implementation of both the KeyRing and SecretKeyRing interfaces backed by ltcwallet's internal root waddrmgr. Internally, we'll be using a ScopedKeyManager to do all of our derivations, using the key scope and scope addr scehma defined above. Re-using the existing key scope construction means that all key derivation will be protected under the root seed of the wallet, making each derived key fully deterministic.

func (*BtcWalletKeyRing) DeriveKey

func (b *BtcWalletKeyRing) DeriveKey(keyLoc KeyLocator) (KeyDescriptor, error)

DeriveKey attempts to derive an arbitrary key specified by the passed KeyLocator. This may be used in several recovery scenarios, or when manually rotating something like our current default node key.

NOTE: This is part of the keychain.KeyRing interface.

func (*BtcWalletKeyRing) DeriveNextKey

func (b *BtcWalletKeyRing) DeriveNextKey(keyFam KeyFamily) (KeyDescriptor, error)

DeriveNextKey attempts to derive the *next* key within the key family (account in BIP43) specified. This method should return the next external child within this branch.

NOTE: This is part of the keychain.KeyRing interface.

func (*BtcWalletKeyRing) DerivePrivKey

func (b *BtcWalletKeyRing) DerivePrivKey(keyDesc KeyDescriptor) (
	*btcec.PrivateKey, error)

DerivePrivKey attempts to derive the private key that corresponds to the passed key descriptor.

NOTE: This is part of the keychain.SecretKeyRing interface.

func (*BtcWalletKeyRing) ECDH

func (b *BtcWalletKeyRing) ECDH(keyDesc KeyDescriptor,
	pub *btcec.PublicKey) ([32]byte, error)

ECDH performs a scalar multiplication (ECDH-like operation) between the target key descriptor and remote public key. The output returned will be the sha256 of the resulting shared point serialized in compressed format. If k is our private key, and P is the public key, we perform the following operation:

sx := k*P s := sha256(sx.SerializeCompressed())

NOTE: This is part of the keychain.ECDHRing interface.

func (*BtcWalletKeyRing) SignMessage

func (b *BtcWalletKeyRing) SignMessage(keyLoc KeyLocator,
	msg []byte, doubleHash bool) (*ecdsa.Signature, error)

SignMessage signs the given message, single or double SHA256 hashing it first, with the private key described in the key locator.

NOTE: This is part of the keychain.MessageSignerRing interface.

func (*BtcWalletKeyRing) SignMessageCompact

func (b *BtcWalletKeyRing) SignMessageCompact(keyLoc KeyLocator,
	msg []byte, doubleHash bool) ([]byte, error)

SignMessageCompact signs the given message, single or double SHA256 hashing it first, with the private key described in the key locator and returns the signature in the compact, public key recoverable format.

NOTE: This is part of the keychain.MessageSignerRing interface.

type ECDHRing

type ECDHRing interface {
	// ECDH performs a scalar multiplication (ECDH-like operation) between
	// the target key descriptor and remote public key. The output
	// returned will be the sha256 of the resulting shared point serialized
	// in compressed format. If k is our private key, and P is the public
	// key, we perform the following operation:
	//
	//  sx := k*P
	//  s := sha256(sx.SerializeCompressed())
	ECDH(keyDesc KeyDescriptor, pubKey *btcec.PublicKey) ([32]byte, error)
}

ECDHRing is an interface that abstracts away basic low-level ECDH shared key generation on keys within a key ring.

type KeyDescriptor

type KeyDescriptor struct {
	// KeyLocator is the internal KeyLocator of the descriptor.
	KeyLocator

	// PubKey is an optional public key that fully describes a target key.
	// If this is nil, the KeyLocator MUST NOT be empty.
	PubKey *btcec.PublicKey
}

KeyDescriptor wraps a KeyLocator and also optionally includes a public key. Either the KeyLocator must be non-empty, or the public key pointer be non-nil. This will be used by the KeyRing interface to lookup arbitrary private keys, and also within the SignDescriptor struct to locate precisely which keys should be used for signing.

type KeyFamily

type KeyFamily uint32

KeyFamily represents a "family" of keys that will be used within various contracts created by lnd. These families are meant to be distinct branches within the HD key chain of the backing wallet. Usage of key families within the interface below are strict in order to promote integrability and the ability to restore all keys given a user master seed backup.

The key derivation in this file follows the following hierarchy based on BIP43:

  • m/1017'/coinType'/keyFamily'/0/index
const (
	// KeyFamilyMultiSig are keys to be used within multi-sig scripts.
	KeyFamilyMultiSig KeyFamily = 0

	// KeyFamilyRevocationBase are keys that are used within channels to
	// create revocation basepoints that the remote party will use to
	// create revocation keys for us.
	KeyFamilyRevocationBase KeyFamily = 1

	// KeyFamilyHtlcBase are keys used within channels that will be
	// combined with per-state randomness to produce public keys that will
	// be used in HTLC scripts.
	KeyFamilyHtlcBase KeyFamily = 2

	// KeyFamilyPaymentBase are keys used within channels that will be
	// combined with per-state randomness to produce public keys that will
	// be used in scripts that pay directly to us without any delay.
	KeyFamilyPaymentBase KeyFamily = 3

	// KeyFamilyDelayBase are keys used within channels that will be
	// combined with per-state randomness to produce public keys that will
	// be used in scripts that pay to us, but require a CSV delay before we
	// can sweep the funds.
	KeyFamilyDelayBase KeyFamily = 4

	// KeyFamilyRevocationRoot is a family of keys which will be used to
	// derive the root of a revocation tree for a particular channel.
	KeyFamilyRevocationRoot KeyFamily = 5

	// KeyFamilyNodeKey is a family of keys that will be used to derive
	// keys that will be advertised on the network to represent our current
	// "identity" within the network. Peers will need our latest node key
	// in order to establish a transport session with us on the Lightning
	// p2p level (BOLT-0008).
	KeyFamilyNodeKey KeyFamily = 6

	// KeyFamilyStaticBackup is the family of keys that will be used to
	// derive keys that we use to encrypt and decrypt our set of static
	// backups. These backups may either be stored within watch towers for
	// a payment, or self stored on disk in a single file containing all
	// the static channel backups.
	KeyFamilyStaticBackup KeyFamily = 7

	// KeyFamilyTowerSession is the family of keys that will be used to
	// derive session keys when negotiating sessions with watchtowers. The
	// session keys are limited to the lifetime of the session and are used
	// to increase privacy in the watchtower protocol.
	KeyFamilyTowerSession KeyFamily = 8

	// KeyFamilyTowerID is the family of keys used to derive the public key
	// of a watchtower. This made distinct from the node key to offer a form
	// of rudimentary whitelisting, i.e. via knowledge of the pubkey,
	// preventing others from having full access to the tower just as a
	// result of knowing the node key.
	KeyFamilyTowerID KeyFamily = 9
)

type KeyLocator

type KeyLocator struct {

	// Family is the family of key being identified.
	Family KeyFamily

	// Index is the precise index of the key being identified.
	Index uint32
}

KeyLocator is a two-tuple that can be used to derive *any* key that has ever been used under the key derivation mechanisms described in this file. Version 0 of our key derivation schema uses the following BIP43-like derivation:

  • m/1017'/coinType'/keyFamily'/0/index

Our purpose is 1017 (chosen arbitrary for now), and the coin type will vary based on which coin/chain the channels are being created on. The key family are actually just individual "accounts" in the nomenclature of BIP43. By default we assume a branch of 0 (external). Finally, the key index (which will vary per channel and use case) is the final element which allows us to deterministically derive keys.

func (KeyLocator) IsEmpty

func (k KeyLocator) IsEmpty() bool

IsEmpty returns true if a KeyLocator is "empty". This may be the case where we learn of a key from a remote party for a contract, but don't know the precise details of its derivation (as we don't know the private key!).

type KeyRing

type KeyRing interface {
	// DeriveNextKey attempts to derive the *next* key within the key
	// family (account in BIP43) specified. This method should return the
	// next external child within this branch.
	DeriveNextKey(keyFam KeyFamily) (KeyDescriptor, error)

	// DeriveKey attempts to derive an arbitrary key specified by the
	// passed KeyLocator. This may be used in several recovery scenarios,
	// or when manually rotating something like our current default node
	// key.
	DeriveKey(keyLoc KeyLocator) (KeyDescriptor, error)
}

KeyRing is the primary interface that will be used to perform public derivation of various keys used within the peer-to-peer network, and also within any created contracts. All derivation required by the KeyRing is based off of public derivation, so a system with only an extended public key (for the particular purpose+family) can derive this set of keys.

type MessageSignerRing

type MessageSignerRing interface {
	// SignMessage signs the given message, single or double SHA256 hashing
	// it first, with the private key described in the key locator.
	SignMessage(keyLoc KeyLocator, msg []byte,
		doubleHash bool) (*ecdsa.Signature, error)

	// SignMessageCompact signs the given message, single or double SHA256
	// hashing it first, with the private key described in the key locator
	// and returns the signature in the compact, public key recoverable
	// format.
	SignMessageCompact(keyLoc KeyLocator, msg []byte,
		doubleHash bool) ([]byte, error)
}

MessageSignerRing is an interface that abstracts away basic low-level ECDSA signing on keys within a key ring.

type PrivKeyECDH

type PrivKeyECDH struct {
	// PrivKey is the private key that is used for the ECDH operation.
	PrivKey *btcec.PrivateKey
}

PrivKeyECDH is an implementation of the SingleKeyECDH in which we do have the full private key. This can be used to wrap a temporary key to conform to the SingleKeyECDH interface.

func (*PrivKeyECDH) ECDH

func (p *PrivKeyECDH) ECDH(pub *btcec.PublicKey) ([32]byte, error)

ECDH performs a scalar multiplication (ECDH-like operation) between the abstracted private key and a remote public key. The output returned will be the sha256 of the resulting shared point serialized in compressed format. If k is our private key, and P is the public key, we perform the following operation:

sx := k*P
s := sha256(sx.SerializeCompressed())

NOTE: This is part of the SingleKeyECDH interface.

func (*PrivKeyECDH) PubKey

func (p *PrivKeyECDH) PubKey() *btcec.PublicKey

PubKey returns the public key of the private key that is abstracted away by the interface.

NOTE: This is part of the SingleKeyECDH interface.

type PrivKeyMessageSigner

type PrivKeyMessageSigner struct {
	// contains filtered or unexported fields
}

func NewPrivKeyMessageSigner

func NewPrivKeyMessageSigner(privKey *btcec.PrivateKey,
	keyLoc KeyLocator) *PrivKeyMessageSigner

func (*PrivKeyMessageSigner) KeyLocator

func (p *PrivKeyMessageSigner) KeyLocator() KeyLocator

func (*PrivKeyMessageSigner) PubKey

func (p *PrivKeyMessageSigner) PubKey() *btcec.PublicKey

func (*PrivKeyMessageSigner) SignMessage

func (p *PrivKeyMessageSigner) SignMessage(msg []byte,
	doubleHash bool) (*ecdsa.Signature, error)

func (*PrivKeyMessageSigner) SignMessageCompact

func (p *PrivKeyMessageSigner) SignMessageCompact(msg []byte,
	doubleHash bool) ([]byte, error)

type PubKeyECDH

type PubKeyECDH struct {
	// contains filtered or unexported fields
}

PubKeyECDH is an implementation of the SingleKeyECDH interface. It wraps an ECDH key ring so it can perform ECDH shared key generation against a single abstracted away private key.

func NewPubKeyECDH

func NewPubKeyECDH(keyDesc KeyDescriptor, ecdh ECDHRing) *PubKeyECDH

NewPubKeyECDH wraps the given key of the key ring so it adheres to the SingleKeyECDH interface.

func (*PubKeyECDH) ECDH

func (p *PubKeyECDH) ECDH(pubKey *btcec.PublicKey) ([32]byte, error)

ECDH performs a scalar multiplication (ECDH-like operation) between the abstracted private key and a remote public key. The output returned will be the sha256 of the resulting shared point serialized in compressed format. If k is our private key, and P is the public key, we perform the following operation:

sx := k*P
s := sha256(sx.SerializeCompressed())

NOTE: This is part of the SingleKeyECDH interface.

func (*PubKeyECDH) PubKey

func (p *PubKeyECDH) PubKey() *btcec.PublicKey

PubKey returns the public key of the private key that is abstracted away by the interface.

NOTE: This is part of the SingleKeyECDH interface.

type PubKeyMessageSigner

type PubKeyMessageSigner struct {
	// contains filtered or unexported fields
}

func NewPubKeyMessageSigner

func NewPubKeyMessageSigner(pubKey *btcec.PublicKey, keyLoc KeyLocator,
	signer MessageSignerRing) *PubKeyMessageSigner

func (*PubKeyMessageSigner) KeyLocator

func (p *PubKeyMessageSigner) KeyLocator() KeyLocator

func (*PubKeyMessageSigner) PubKey

func (p *PubKeyMessageSigner) PubKey() *btcec.PublicKey

func (*PubKeyMessageSigner) SignMessage

func (p *PubKeyMessageSigner) SignMessage(message []byte,
	doubleHash bool) (*ecdsa.Signature, error)

func (*PubKeyMessageSigner) SignMessageCompact

func (p *PubKeyMessageSigner) SignMessageCompact(msg []byte,
	doubleHash bool) ([]byte, error)

type SecretKeyRing

type SecretKeyRing interface {
	KeyRing

	ECDHRing

	MessageSignerRing

	// DerivePrivKey attempts to derive the private key that corresponds to
	// the passed key descriptor.  If the public key is set, then this
	// method will perform an in-order scan over the key set, with a max of
	// MaxKeyRangeScan keys. In order for this to work, the caller MUST set
	// the KeyFamily within the partially populated KeyLocator.
	DerivePrivKey(keyDesc KeyDescriptor) (*btcec.PrivateKey, error)
}

SecretKeyRing is a ring similar to the regular KeyRing interface, but it is also able to derive *private keys*. As this is a super-set of the regular KeyRing, we also expect the SecretKeyRing to implement the fully KeyRing interface. The methods in this struct may be used to extract the node key in order to accept inbound network connections, or to do manual signing for recovery purposes.

func NewBtcWalletKeyRing

func NewBtcWalletKeyRing(w *wallet.Wallet, coinType uint32) SecretKeyRing

NewBtcWalletKeyRing creates a new implementation of the keychain.SecretKeyRing interface backed by ltcwallet.

NOTE: The passed waddrmgr.Manager MUST be unlocked in order for the keychain to function.

type SingleKeyECDH

type SingleKeyECDH interface {
	// PubKey returns the public key of the wrapped private key.
	PubKey() *btcec.PublicKey

	// ECDH performs a scalar multiplication (ECDH-like operation) between
	// the wrapped private key and remote public key. The output returned
	// will be the sha256 of the resulting shared point serialized in
	// compressed format.
	ECDH(pubKey *btcec.PublicKey) ([32]byte, error)
}

SingleKeyECDH is an abstraction interface that hides the implementation of an ECDH operation by wrapping a single, specific private key.

type SingleKeyMessageSigner

type SingleKeyMessageSigner interface {
	// PubKey returns the public key of the wrapped private key.
	PubKey() *btcec.PublicKey

	// KeyLocator returns the locator that describes the wrapped private
	// key.
	KeyLocator() KeyLocator

	// SignMessage signs the given message, single or double SHA256 hashing
	// it first, with the wrapped private key.
	SignMessage(message []byte, doubleHash bool) (*ecdsa.Signature, error)

	// SignMessageCompact signs the given message, single or double SHA256
	// hashing it first, with the wrapped private key and returns the
	// signature in the compact, public key recoverable format.
	SignMessageCompact(message []byte, doubleHash bool) ([]byte, error)
}

SingleKeyMessageSigner is an abstraction interface that hides the implementation of the low-level ECDSA signing operations by wrapping a single, specific private key.

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