package crypto import ( "bytes" "errors" "fmt" "io" pb "github.com/libp2p/go-libp2p-core/crypto/pb" "golang.org/x/crypto/ed25519" ) // Ed25519PrivateKey is an ed25519 private key. type Ed25519PrivateKey struct { k ed25519.PrivateKey } // Ed25519PublicKey is an ed25519 public key. type Ed25519PublicKey struct { k ed25519.PublicKey } // GenerateEd25519Key generates a new ed25519 private and public key pair. func GenerateEd25519Key(src io.Reader) (PrivKey, PubKey, error) { pub, priv, err := ed25519.GenerateKey(src) if err != nil { return nil, nil, err } return &Ed25519PrivateKey{ k: priv, }, &Ed25519PublicKey{ k: pub, }, nil } // Type of the private key (Ed25519). func (k *Ed25519PrivateKey) Type() pb.KeyType { return pb.KeyType_Ed25519 } // Bytes marshals an ed25519 private key to protobuf bytes. func (k *Ed25519PrivateKey) Bytes() ([]byte, error) { return MarshalPrivateKey(k) } // Raw private key bytes. func (k *Ed25519PrivateKey) Raw() ([]byte, error) { // The Ed25519 private key contains two 32-bytes curve points, the private // key and the public key. // It makes it more efficient to get the public key without re-computing an // elliptic curve multiplication. buf := make([]byte, len(k.k)) copy(buf, k.k) return buf, nil } func (k *Ed25519PrivateKey) pubKeyBytes() []byte { return k.k[ed25519.PrivateKeySize-ed25519.PublicKeySize:] } // Equals compares two ed25519 private keys. func (k *Ed25519PrivateKey) Equals(o Key) bool { edk, ok := o.(*Ed25519PrivateKey) if !ok { return false } return bytes.Equal(k.k, edk.k) } // GetPublic returns an ed25519 public key from a private key. func (k *Ed25519PrivateKey) GetPublic() PubKey { return &Ed25519PublicKey{k: k.pubKeyBytes()} } // Sign returns a signature from an input message. func (k *Ed25519PrivateKey) Sign(msg []byte) ([]byte, error) { return ed25519.Sign(k.k, msg), nil } // Type of the public key (Ed25519). func (k *Ed25519PublicKey) Type() pb.KeyType { return pb.KeyType_Ed25519 } // Bytes returns a ed25519 public key as protobuf bytes. func (k *Ed25519PublicKey) Bytes() ([]byte, error) { return MarshalPublicKey(k) } // Raw public key bytes. func (k *Ed25519PublicKey) Raw() ([]byte, error) { return k.k, nil } // Equals compares two ed25519 public keys. func (k *Ed25519PublicKey) Equals(o Key) bool { edk, ok := o.(*Ed25519PublicKey) if !ok { return false } return bytes.Equal(k.k, edk.k) } // Verify checks a signature agains the input data. func (k *Ed25519PublicKey) Verify(data []byte, sig []byte) (bool, error) { return ed25519.Verify(k.k, data, sig), nil } // UnmarshalEd25519PublicKey returns a public key from input bytes. func UnmarshalEd25519PublicKey(data []byte) (PubKey, error) { if len(data) != 32 { return nil, errors.New("expect ed25519 public key data size to be 32") } return &Ed25519PublicKey{ k: ed25519.PublicKey(data), }, nil } // UnmarshalEd25519PrivateKey returns a private key from input bytes. func UnmarshalEd25519PrivateKey(data []byte) (PrivKey, error) { switch len(data) { case ed25519.PrivateKeySize + ed25519.PublicKeySize: // Remove the redundant public key. See issue #36. redundantPk := data[ed25519.PrivateKeySize:] pk := data[ed25519.PrivateKeySize-ed25519.PublicKeySize : ed25519.PrivateKeySize] if !bytes.Equal(pk, redundantPk) { return nil, errors.New("expected redundant ed25519 public key to be redundant") } // No point in storing the extra data. newKey := make([]byte, ed25519.PrivateKeySize) copy(newKey, data[:ed25519.PrivateKeySize]) data = newKey case ed25519.PrivateKeySize: default: return nil, fmt.Errorf( "expected ed25519 data size to be %d or %d, got %d", ed25519.PrivateKeySize, ed25519.PrivateKeySize+ed25519.PublicKeySize, len(data), ) } return &Ed25519PrivateKey{ k: ed25519.PrivateKey(data), }, nil }