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crypto.go
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crypto.go
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package libp2ptls
import (
"crypto/ecdsa"
"crypto/elliptic"
"crypto/rand"
"crypto/tls"
"crypto/x509"
"crypto/x509/pkix"
"encoding/asn1"
"errors"
"fmt"
"math/big"
"time"
"golang.org/x/sys/cpu"
ic "github.com/libp2p/go-libp2p-core/crypto"
"github.com/libp2p/go-libp2p-core/peer"
)
const certValidityPeriod = 100 * 365 * 24 * time.Hour // ~100 years
const certificatePrefix = "libp2p-tls-handshake:"
const alpn string = "libp2p"
var extensionID = getPrefixedExtensionID([]int{1, 1})
type signedKey struct {
PubKey []byte
Signature []byte
}
// Identity is used to secure connections
type Identity struct {
config tls.Config
}
// NewIdentity creates a new identity
func NewIdentity(privKey ic.PrivKey) (*Identity, error) {
cert, err := keyToCertificate(privKey)
if err != nil {
return nil, err
}
return &Identity{
config: tls.Config{
MinVersion: tls.VersionTLS13,
PreferServerCipherSuites: preferServerCipherSuites(),
InsecureSkipVerify: true, // This is not insecure here. We will verify the cert chain ourselves.
ClientAuth: tls.RequireAnyClientCert,
Certificates: []tls.Certificate{*cert},
VerifyPeerCertificate: func(_ [][]byte, _ [][]*x509.Certificate) error {
panic("tls config not specialized for peer")
},
NextProtos: []string{alpn},
SessionTicketsDisabled: true,
},
}, nil
}
// ConfigForAny is a short-hand for ConfigForPeer("").
func (i *Identity) ConfigForAny() (*tls.Config, <-chan ic.PubKey) {
return i.ConfigForPeer("")
}
// ConfigForPeer creates a new single-use tls.Config that verifies the peer's
// certificate chain and returns the peer's public key via the channel. If the
// peer ID is empty, the returned config will accept any peer.
//
// It should be used to create a new tls.Config before securing either an
// incoming or outgoing connection.
func (i *Identity) ConfigForPeer(remote peer.ID) (*tls.Config, <-chan ic.PubKey) {
keyCh := make(chan ic.PubKey, 1)
// We need to check the peer ID in the VerifyPeerCertificate callback.
// The tls.Config it is also used for listening, and we might also have concurrent dials.
// Clone it so we can check for the specific peer ID we're dialing here.
conf := i.config.Clone()
// We're using InsecureSkipVerify, so the verifiedChains parameter will always be empty.
// We need to parse the certificates ourselves from the raw certs.
conf.VerifyPeerCertificate = func(rawCerts [][]byte, _ [][]*x509.Certificate) error {
defer close(keyCh)
chain := make([]*x509.Certificate, len(rawCerts))
for i := 0; i < len(rawCerts); i++ {
cert, err := x509.ParseCertificate(rawCerts[i])
if err != nil {
return err
}
chain[i] = cert
}
pubKey, err := PubKeyFromCertChain(chain)
if err != nil {
return err
}
if remote != "" && !remote.MatchesPublicKey(pubKey) {
peerID, err := peer.IDFromPublicKey(pubKey)
if err != nil {
peerID = peer.ID(fmt.Sprintf("(not determined: %s)", err.Error()))
}
return fmt.Errorf("peer IDs don't match: expected %s, got %s", remote, peerID)
}
keyCh <- pubKey
return nil
}
return conf, keyCh
}
// PubKeyFromCertChain verifies the certificate chain and extract the remote's public key.
func PubKeyFromCertChain(chain []*x509.Certificate) (ic.PubKey, error) {
if len(chain) != 1 {
return nil, errors.New("expected one certificates in the chain")
}
cert := chain[0]
pool := x509.NewCertPool()
pool.AddCert(cert)
if _, err := cert.Verify(x509.VerifyOptions{Roots: pool}); err != nil {
// If we return an x509 error here, it will be sent on the wire.
// Wrap the error to avoid that.
return nil, fmt.Errorf("certificate verification failed: %s", err)
}
var found bool
var keyExt pkix.Extension
// find the libp2p key extension, skipping all unknown extensions
for _, ext := range cert.Extensions {
if extensionIDEqual(ext.Id, extensionID) {
keyExt = ext
found = true
break
}
}
if !found {
return nil, errors.New("expected certificate to contain the key extension")
}
var sk signedKey
if _, err := asn1.Unmarshal(keyExt.Value, &sk); err != nil {
return nil, fmt.Errorf("unmarshalling signed certificate failed: %s", err)
}
pubKey, err := ic.UnmarshalPublicKey(sk.PubKey)
if err != nil {
return nil, fmt.Errorf("unmarshalling public key failed: %s", err)
}
certKeyPub, err := x509.MarshalPKIXPublicKey(cert.PublicKey)
if err != nil {
return nil, err
}
valid, err := pubKey.Verify(append([]byte(certificatePrefix), certKeyPub...), sk.Signature)
if err != nil {
return nil, fmt.Errorf("signature verification failed: %s", err)
}
if !valid {
return nil, errors.New("signature invalid")
}
return pubKey, nil
}
func keyToCertificate(sk ic.PrivKey) (*tls.Certificate, error) {
certKey, err := ecdsa.GenerateKey(elliptic.P256(), rand.Reader)
if err != nil {
return nil, err
}
keyBytes, err := ic.MarshalPublicKey(sk.GetPublic())
if err != nil {
return nil, err
}
certKeyPub, err := x509.MarshalPKIXPublicKey(certKey.Public())
if err != nil {
return nil, err
}
signature, err := sk.Sign(append([]byte(certificatePrefix), certKeyPub...))
if err != nil {
return nil, err
}
value, err := asn1.Marshal(signedKey{
PubKey: keyBytes,
Signature: signature,
})
if err != nil {
return nil, err
}
sn, err := rand.Int(rand.Reader, big.NewInt(1<<62))
if err != nil {
return nil, err
}
tmpl := &x509.Certificate{
SerialNumber: sn,
NotBefore: time.Time{},
NotAfter: time.Now().Add(certValidityPeriod),
// after calling CreateCertificate, these will end up in Certificate.Extensions
ExtraExtensions: []pkix.Extension{
{Id: extensionID, Value: value},
},
}
certDER, err := x509.CreateCertificate(rand.Reader, tmpl, tmpl, certKey.Public(), certKey)
if err != nil {
return nil, err
}
return &tls.Certificate{
Certificate: [][]byte{certDER},
PrivateKey: certKey,
}, nil
}
// We want nodes without AES hardware (e.g. ARM) support to always use ChaCha.
// Only if both nodes have AES hardware support (e.g. x86), AES should be used.
// x86->x86: AES, ARM->x86: ChaCha, x86->ARM: ChaCha and ARM->ARM: Chacha
// This function returns true if we don't have AES hardware support, and false otherwise.
// Thus, ARM servers will always use their own cipher suite preferences (ChaCha first),
// and x86 servers will aways use the client's cipher suite preferences.
func preferServerCipherSuites() bool {
// Copied from the Go TLS implementation.
// Check the cpu flags for each platform that has optimized GCM implementations.
// Worst case, these variables will just all be false.
var (
hasGCMAsmAMD64 = cpu.X86.HasAES && cpu.X86.HasPCLMULQDQ
hasGCMAsmARM64 = cpu.ARM64.HasAES && cpu.ARM64.HasPMULL
// Keep in sync with crypto/aes/cipher_s390x.go.
hasGCMAsmS390X = cpu.S390X.HasAES && cpu.S390X.HasAESCBC && cpu.S390X.HasAESCTR && (cpu.S390X.HasGHASH || cpu.S390X.HasAESGCM)
hasGCMAsm = hasGCMAsmAMD64 || hasGCMAsmARM64 || hasGCMAsmS390X
)
return !hasGCMAsm
}