Import cloudflare tls

This commit is contained in:
世界 2022-09-03 23:21:35 +08:00
parent ee7e976084
commit a3bb9c2877
No known key found for this signature in database
GPG Key ID: CD109927C34A63C4
29 changed files with 14815 additions and 0 deletions

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@ -7,6 +7,10 @@ linters:
- staticcheck
- paralleltest
run:
skip-dirs:
- transport/cloudflaretls
linters-settings:
# gci:
# sections:

1
go.mod
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@ -4,6 +4,7 @@ go 1.18
require (
berty.tech/go-libtor v1.0.385
github.com/cloudflare/circl v1.2.1-0.20220831060716-4cf0150356fc
github.com/cretz/bine v0.2.0
github.com/database64128/tfo-go v1.1.2
github.com/dustin/go-humanize v1.0.0

2
go.sum
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@ -10,6 +10,8 @@ github.com/benbjohnson/clock v1.1.0 h1:Q92kusRqC1XV2MjkWETPvjJVqKetz1OzxZB7mHJLj
github.com/benbjohnson/clock v1.1.0/go.mod h1:J11/hYXuz8f4ySSvYwY0FKfm+ezbsZBKZxNJlLklBHA=
github.com/census-instrumentation/opencensus-proto v0.2.1/go.mod h1:f6KPmirojxKA12rnyqOA5BBL4O983OfeGPqjHWSTneU=
github.com/client9/misspell v0.3.4/go.mod h1:qj6jICC3Q7zFZvVWo7KLAzC3yx5G7kyvSDkc90ppPyw=
github.com/cloudflare/circl v1.2.1-0.20220831060716-4cf0150356fc h1:307gdRLiZ08dwOIKwc5lAQ19DRFaQQvdhHalyB4Asx8=
github.com/cloudflare/circl v1.2.1-0.20220831060716-4cf0150356fc/go.mod h1:+CauBF6R70Jqcyl8N2hC8pAXYbWkGIezuSbuGLtRhnw=
github.com/cncf/udpa/go v0.0.0-20191209042840-269d4d468f6f/go.mod h1:M8M6+tZqaGXZJjfX53e64911xZQV5JYwmTeXPW+k8Sc=
github.com/cncf/udpa/go v0.0.0-20201120205902-5459f2c99403/go.mod h1:WmhPx2Nbnhtbo57+VJT5O0JRkEi1Wbu0z5j0R8u5Hbk=
github.com/cncf/xds/go v0.0.0-20210312221358-fbca930ec8ed/go.mod h1:eXthEFrGJvWHgFFCl3hGmgk+/aYT6PnTQLykKQRLhEs=

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@ -0,0 +1,7 @@
# cloudflare-tls
kanged from https://github.com/cloudflare/go
branch: cf
commit: 4d2a840e50d2b4316aa19934271832d080c44f7f
go: 1.18.5
changes: use github.com/cloudflare/circl 4cf0150356fc62a0ea5c0eec2f64b756cb404145

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@ -0,0 +1,101 @@
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import "strconv"
type alert uint8
const (
// alert level
alertLevelWarning = 1
alertLevelError = 2
)
const (
alertCloseNotify alert = 0
alertUnexpectedMessage alert = 10
alertBadRecordMAC alert = 20
alertDecryptionFailed alert = 21
alertRecordOverflow alert = 22
alertDecompressionFailure alert = 30
alertHandshakeFailure alert = 40
alertBadCertificate alert = 42
alertUnsupportedCertificate alert = 43
alertCertificateRevoked alert = 44
alertCertificateExpired alert = 45
alertCertificateUnknown alert = 46
alertIllegalParameter alert = 47
alertUnknownCA alert = 48
alertAccessDenied alert = 49
alertDecodeError alert = 50
alertDecryptError alert = 51
alertExportRestriction alert = 60
alertProtocolVersion alert = 70
alertInsufficientSecurity alert = 71
alertInternalError alert = 80
alertInappropriateFallback alert = 86
alertUserCanceled alert = 90
alertNoRenegotiation alert = 100
alertMissingExtension alert = 109
alertUnsupportedExtension alert = 110
alertCertificateUnobtainable alert = 111
alertUnrecognizedName alert = 112
alertBadCertificateStatusResponse alert = 113
alertBadCertificateHashValue alert = 114
alertUnknownPSKIdentity alert = 115
alertCertificateRequired alert = 116
alertNoApplicationProtocol alert = 120
alertECHRequired alert = 121
)
var alertText = map[alert]string{
alertCloseNotify: "close notify",
alertUnexpectedMessage: "unexpected message",
alertBadRecordMAC: "bad record MAC",
alertDecryptionFailed: "decryption failed",
alertRecordOverflow: "record overflow",
alertDecompressionFailure: "decompression failure",
alertHandshakeFailure: "handshake failure",
alertBadCertificate: "bad certificate",
alertUnsupportedCertificate: "unsupported certificate",
alertCertificateRevoked: "revoked certificate",
alertCertificateExpired: "expired certificate",
alertCertificateUnknown: "unknown certificate",
alertIllegalParameter: "illegal parameter",
alertUnknownCA: "unknown certificate authority",
alertAccessDenied: "access denied",
alertDecodeError: "error decoding message",
alertDecryptError: "error decrypting message",
alertExportRestriction: "export restriction",
alertProtocolVersion: "protocol version not supported",
alertInsufficientSecurity: "insufficient security level",
alertInternalError: "internal error",
alertInappropriateFallback: "inappropriate fallback",
alertUserCanceled: "user canceled",
alertNoRenegotiation: "no renegotiation",
alertMissingExtension: "missing extension",
alertUnsupportedExtension: "unsupported extension",
alertCertificateUnobtainable: "certificate unobtainable",
alertUnrecognizedName: "unrecognized name",
alertBadCertificateStatusResponse: "bad certificate status response",
alertBadCertificateHashValue: "bad certificate hash value",
alertUnknownPSKIdentity: "unknown PSK identity",
alertCertificateRequired: "certificate required",
alertNoApplicationProtocol: "no application protocol",
alertECHRequired: "ECH required",
}
func (e alert) String() string {
s, ok := alertText[e]
if ok {
return "tls: " + s
}
return "tls: alert(" + strconv.Itoa(int(e)) + ")"
}
func (e alert) Error() string {
return e.String()
}

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@ -0,0 +1,345 @@
// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import (
"bytes"
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/elliptic"
"crypto/rsa"
"errors"
"fmt"
"hash"
"io"
circlPki "github.com/cloudflare/circl/pki"
circlSign "github.com/cloudflare/circl/sign"
)
// verifyHandshakeSignature verifies a signature against pre-hashed
// (if required) handshake contents.
func verifyHandshakeSignature(sigType uint8, pubkey crypto.PublicKey, hashFunc crypto.Hash, signed, sig []byte) error {
switch sigType {
case signatureECDSA:
pubKey, ok := pubkey.(*ecdsa.PublicKey)
if !ok {
return fmt.Errorf("expected an ECDSA public key, got %T", pubkey)
}
if !ecdsa.VerifyASN1(pubKey, signed, sig) {
return errors.New("ECDSA verification failure")
}
case signatureEd25519:
pubKey, ok := pubkey.(ed25519.PublicKey)
if !ok {
return fmt.Errorf("expected an Ed25519 public key, got %T", pubkey)
}
if !ed25519.Verify(pubKey, signed, sig) {
return errors.New("Ed25519 verification failure")
}
case signaturePKCS1v15:
pubKey, ok := pubkey.(*rsa.PublicKey)
if !ok {
return fmt.Errorf("expected an RSA public key, got %T", pubkey)
}
if err := rsa.VerifyPKCS1v15(pubKey, hashFunc, signed, sig); err != nil {
return err
}
case signatureRSAPSS:
pubKey, ok := pubkey.(*rsa.PublicKey)
if !ok {
return fmt.Errorf("expected an RSA public key, got %T", pubkey)
}
signOpts := &rsa.PSSOptions{SaltLength: rsa.PSSSaltLengthEqualsHash}
if err := rsa.VerifyPSS(pubKey, hashFunc, signed, sig, signOpts); err != nil {
return err
}
default:
scheme := circlSchemeBySigType(sigType)
if scheme == nil {
return errors.New("internal error: unknown signature type")
}
pubKey, ok := pubkey.(circlSign.PublicKey)
if !ok {
return fmt.Errorf("expected a %s public key, got %T", scheme.Name(), pubkey)
}
if !scheme.Verify(pubKey, signed, sig, nil) {
return fmt.Errorf("%s verification failure", scheme.Name())
}
}
return nil
}
const (
serverSignatureContext = "TLS 1.3, server CertificateVerify\x00"
clientSignatureContext = "TLS 1.3, client CertificateVerify\x00"
)
var signaturePadding = []byte{
0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20,
}
// signedMessage returns the pre-hashed (if necessary) message to be signed by
// certificate keys in TLS 1.3. See RFC 8446, Section 4.4.3.
func signedMessage(sigHash crypto.Hash, context string, transcript hash.Hash) []byte {
if sigHash == directSigning {
b := &bytes.Buffer{}
b.Write(signaturePadding)
io.WriteString(b, context)
b.Write(transcript.Sum(nil))
return b.Bytes()
}
h := sigHash.New()
h.Write(signaturePadding)
io.WriteString(h, context)
h.Write(transcript.Sum(nil))
return h.Sum(nil)
}
// typeAndHashFromSignatureScheme returns the corresponding signature type and
// crypto.Hash for a given TLS SignatureScheme.
func typeAndHashFromSignatureScheme(signatureAlgorithm SignatureScheme) (sigType uint8, hash crypto.Hash, err error) {
switch signatureAlgorithm {
case PKCS1WithSHA1, PKCS1WithSHA256, PKCS1WithSHA384, PKCS1WithSHA512:
sigType = signaturePKCS1v15
case PSSWithSHA256, PSSWithSHA384, PSSWithSHA512:
sigType = signatureRSAPSS
case ECDSAWithSHA1, ECDSAWithP256AndSHA256, ECDSAWithP384AndSHA384, ECDSAWithP521AndSHA512:
sigType = signatureECDSA
case Ed25519:
sigType = signatureEd25519
default:
scheme := circlPki.SchemeByTLSID(uint(signatureAlgorithm))
if scheme == nil {
return 0, 0, fmt.Errorf("unsupported signature algorithm: %v", signatureAlgorithm)
}
sigType = sigTypeByCirclScheme(scheme)
if sigType == 0 {
return 0, 0, fmt.Errorf("github.com/cloudflare/circl scheme %s not supported",
scheme.Name())
}
}
switch signatureAlgorithm {
case PKCS1WithSHA1, ECDSAWithSHA1:
hash = crypto.SHA1
case PKCS1WithSHA256, PSSWithSHA256, ECDSAWithP256AndSHA256:
hash = crypto.SHA256
case PKCS1WithSHA384, PSSWithSHA384, ECDSAWithP384AndSHA384:
hash = crypto.SHA384
case PKCS1WithSHA512, PSSWithSHA512, ECDSAWithP521AndSHA512:
hash = crypto.SHA512
case Ed25519:
hash = directSigning
default:
scheme := circlPki.SchemeByTLSID(uint(signatureAlgorithm))
if scheme == nil {
return 0, 0, fmt.Errorf("unsupported signature algorithm: %v", signatureAlgorithm)
}
hash = directSigning
}
return sigType, hash, nil
}
// legacyTypeAndHashFromPublicKey returns the fixed signature type and crypto.Hash for
// a given public key used with TLS 1.0 and 1.1, before the introduction of
// signature algorithm negotiation.
func legacyTypeAndHashFromPublicKey(pub crypto.PublicKey) (sigType uint8, hash crypto.Hash, err error) {
switch pub.(type) {
case *rsa.PublicKey:
return signaturePKCS1v15, crypto.MD5SHA1, nil
case *ecdsa.PublicKey:
return signatureECDSA, crypto.SHA1, nil
case ed25519.PublicKey:
// RFC 8422 specifies support for Ed25519 in TLS 1.0 and 1.1,
// but it requires holding on to a handshake transcript to do a
// full signature, and not even OpenSSL bothers with the
// complexity, so we can't even test it properly.
return 0, 0, fmt.Errorf("tls: Ed25519 public keys are not supported before TLS 1.2")
case circlSign.PublicKey:
return 0, 0, fmt.Errorf("tls: circl public keys are not supported before TLS 1.2")
default:
return 0, 0, fmt.Errorf("tls: unsupported public key: %T", pub)
}
}
var rsaSignatureSchemes = []struct {
scheme SignatureScheme
minModulusBytes int
maxVersion uint16
}{
// RSA-PSS is used with PSSSaltLengthEqualsHash, and requires
// emLen >= hLen + sLen + 2
{PSSWithSHA256, crypto.SHA256.Size()*2 + 2, VersionTLS13},
{PSSWithSHA384, crypto.SHA384.Size()*2 + 2, VersionTLS13},
{PSSWithSHA512, crypto.SHA512.Size()*2 + 2, VersionTLS13},
// PKCS #1 v1.5 uses prefixes from hashPrefixes in crypto/rsa, and requires
// emLen >= len(prefix) + hLen + 11
// TLS 1.3 dropped support for PKCS #1 v1.5 in favor of RSA-PSS.
{PKCS1WithSHA256, 19 + crypto.SHA256.Size() + 11, VersionTLS12},
{PKCS1WithSHA384, 19 + crypto.SHA384.Size() + 11, VersionTLS12},
{PKCS1WithSHA512, 19 + crypto.SHA512.Size() + 11, VersionTLS12},
{PKCS1WithSHA1, 15 + crypto.SHA1.Size() + 11, VersionTLS12},
}
// signatureSchemesForCertificate returns the list of supported SignatureSchemes
// for a given certificate, based on the public key and the protocol version,
// and optionally filtered by its explicit SupportedSignatureAlgorithms.
//
// This function must be kept in sync with supportedSignatureAlgorithms.
func signatureSchemesForCertificate(version uint16, cert *Certificate) []SignatureScheme {
priv, ok := cert.PrivateKey.(crypto.Signer)
if !ok {
return nil
}
var sigAlgs []SignatureScheme
switch pub := priv.Public().(type) {
case *ecdsa.PublicKey:
if version != VersionTLS13 {
// In TLS 1.2 and earlier, ECDSA algorithms are not
// constrained to a single curve.
sigAlgs = []SignatureScheme{
ECDSAWithP256AndSHA256,
ECDSAWithP384AndSHA384,
ECDSAWithP521AndSHA512,
ECDSAWithSHA1,
}
break
}
switch pub.Curve {
case elliptic.P256():
sigAlgs = []SignatureScheme{ECDSAWithP256AndSHA256}
case elliptic.P384():
sigAlgs = []SignatureScheme{ECDSAWithP384AndSHA384}
case elliptic.P521():
sigAlgs = []SignatureScheme{ECDSAWithP521AndSHA512}
default:
return nil
}
case *rsa.PublicKey:
size := pub.Size()
sigAlgs = make([]SignatureScheme, 0, len(rsaSignatureSchemes))
for _, candidate := range rsaSignatureSchemes {
if size >= candidate.minModulusBytes && version <= candidate.maxVersion {
sigAlgs = append(sigAlgs, candidate.scheme)
}
}
case ed25519.PublicKey:
sigAlgs = []SignatureScheme{Ed25519}
case circlSign.PublicKey:
scheme := pub.Scheme()
tlsScheme, ok := scheme.(circlPki.TLSScheme)
if !ok {
return nil
}
sigAlgs = []SignatureScheme{SignatureScheme(tlsScheme.TLSIdentifier())}
default:
return nil
}
if cert.SupportedSignatureAlgorithms != nil {
var filteredSigAlgs []SignatureScheme
for _, sigAlg := range sigAlgs {
if isSupportedSignatureAlgorithm(sigAlg, cert.SupportedSignatureAlgorithms) {
filteredSigAlgs = append(filteredSigAlgs, sigAlg)
}
}
return filteredSigAlgs
}
return sigAlgs
}
// selectSignatureSchemeDC picks a SignatureScheme from the peer's preference list
// that works with the selected delegated credential. It's only called for protocol
// versions that support delegated credential, so TLS 1.3.
func selectSignatureSchemeDC(vers uint16, dc *DelegatedCredential, peerAlgs []SignatureScheme, peerAlgsDC []SignatureScheme) (SignatureScheme, error) {
if vers != VersionTLS13 {
return 0, errors.New("unsupported TLS version for dc")
}
if !isSupportedSignatureAlgorithm(dc.algorithm, peerAlgs) {
return undefinedSignatureScheme, errors.New("tls: peer doesn't support the delegated credential's signature")
}
// Pick signature scheme in the peer's preference order, as our
// preference order is not configurable.
for _, preferredAlg := range peerAlgsDC {
if preferredAlg == dc.cred.expCertVerfAlgo {
return preferredAlg, nil
}
}
return 0, errors.New("tls: peer doesn't support the delegated credential's signature algorithm")
}
// selectSignatureScheme picks a SignatureScheme from the peer's preference list
// that works with the selected certificate. It's only called for protocol
// versions that support signature algorithms, so TLS 1.2 and 1.3.
func selectSignatureScheme(vers uint16, c *Certificate, peerAlgs []SignatureScheme) (SignatureScheme, error) {
supportedAlgs := signatureSchemesForCertificate(vers, c)
if len(supportedAlgs) == 0 {
return 0, unsupportedCertificateError(c)
}
if len(peerAlgs) == 0 && vers == VersionTLS12 {
// For TLS 1.2, if the client didn't send signature_algorithms then we
// can assume that it supports SHA1. See RFC 5246, Section 7.4.1.4.1.
peerAlgs = []SignatureScheme{PKCS1WithSHA1, ECDSAWithSHA1}
}
// Pick signature scheme in the peer's preference order, as our
// preference order is not configurable.
for _, preferredAlg := range peerAlgs {
if isSupportedSignatureAlgorithm(preferredAlg, supportedAlgs) {
return preferredAlg, nil
}
}
return 0, errors.New("tls: peer doesn't support any of the certificate's signature algorithms")
}
// unsupportedCertificateError returns a helpful error for certificates with
// an unsupported private key.
func unsupportedCertificateError(cert *Certificate) error {
switch cert.PrivateKey.(type) {
case rsa.PrivateKey, ecdsa.PrivateKey:
return fmt.Errorf("tls: unsupported certificate: private key is %T, expected *%T",
cert.PrivateKey, cert.PrivateKey)
case *ed25519.PrivateKey:
return fmt.Errorf("tls: unsupported certificate: private key is *ed25519.PrivateKey, expected ed25519.PrivateKey")
}
signer, ok := cert.PrivateKey.(crypto.Signer)
if !ok {
return fmt.Errorf("tls: certificate private key (%T) does not implement crypto.Signer",
cert.PrivateKey)
}
switch pub := signer.Public().(type) {
case *ecdsa.PublicKey:
switch pub.Curve {
case elliptic.P256():
case elliptic.P384():
case elliptic.P521():
default:
return fmt.Errorf("tls: unsupported certificate curve (%s)", pub.Curve.Params().Name)
}
case *rsa.PublicKey:
return fmt.Errorf("tls: certificate RSA key size too small for supported signature algorithms")
case ed25519.PublicKey:
default:
return fmt.Errorf("tls: unsupported certificate key (%T)", pub)
}
if cert.SupportedSignatureAlgorithms != nil {
return fmt.Errorf("tls: peer doesn't support the certificate custom signature algorithms")
}
return fmt.Errorf("tls: internal error: unsupported key (%T)", cert.PrivateKey)
}

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// Copyright 2022 Cloudflare, Inc. All rights reserved. Use of this source code
// is governed by a BSD-style license that can be found in the LICENSE file.
//
// Glue to add Circl's (post-quantum) hybrid KEMs.
//
// To enable set CurvePreferences with the desired scheme as the first element:
//
// import (
// "github.com/cloudflare/circl/kem/tls"
// "github.com/cloudflare/circl/kem/hybrid"
//
// [...]
//
// config.CurvePreferences = []tls.CurveID{
// hybrid.X25519Kyber512Draft00().(tls.TLSScheme).TLSCurveID(),
// tls.X25519,
// tls.P256,
// }
package tls
import (
"fmt"
"io"
"github.com/cloudflare/circl/kem"
"github.com/cloudflare/circl/kem/hybrid"
)
// Either ecdheParameters or kem.PrivateKey
type clientKeySharePrivate interface{}
var (
X25519Kyber512Draft00 = CurveID(0xfe30)
X25519Kyber768Draft00 = CurveID(0xfe31)
invalidCurveID = CurveID(0)
)
func kemSchemeKeyToCurveID(s kem.Scheme) CurveID {
switch s.Name() {
case "Kyber512-X25519":
return X25519Kyber512Draft00
case "Kyber768-X25519":
return X25519Kyber768Draft00
default:
return invalidCurveID
}
}
// Extract CurveID from clientKeySharePrivate
func clientKeySharePrivateCurveID(ks clientKeySharePrivate) CurveID {
switch v := ks.(type) {
case kem.PrivateKey:
ret := kemSchemeKeyToCurveID(v.Scheme())
if ret == invalidCurveID {
panic("cfkem: internal error: don't know CurveID for this KEM")
}
return ret
case ecdheParameters:
return v.CurveID()
default:
panic("cfkem: internal error: unknown clientKeySharePrivate")
}
}
// Returns scheme by CurveID if supported by Circl
func curveIdToCirclScheme(id CurveID) kem.Scheme {
switch id {
case X25519Kyber512Draft00:
return hybrid.Kyber512X25519()
case X25519Kyber768Draft00:
return hybrid.Kyber768X25519()
}
return nil
}
// Generate a new shared secret and encapsulates it for the packed
// public key in ppk using randomness from rnd.
func encapsulateForKem(scheme kem.Scheme, rnd io.Reader, ppk []byte) (
ct, ss []byte, alert alert, err error,
) {
pk, err := scheme.UnmarshalBinaryPublicKey(ppk)
if err != nil {
return nil, nil, alertIllegalParameter, fmt.Errorf("unpack pk: %w", err)
}
seed := make([]byte, scheme.EncapsulationSeedSize())
if _, err := io.ReadFull(rnd, seed); err != nil {
return nil, nil, alertInternalError, fmt.Errorf("random: %w", err)
}
ct, ss, err = scheme.EncapsulateDeterministically(pk, seed)
return ct, ss, alertIllegalParameter, err
}
// Generate a new keypair using randomness from rnd.
func generateKemKeyPair(scheme kem.Scheme, rnd io.Reader) (
kem.PublicKey, kem.PrivateKey, error,
) {
seed := make([]byte, scheme.SeedSize())
if _, err := io.ReadFull(rnd, seed); err != nil {
return nil, nil, err
}
pk, sk := scheme.DeriveKeyPair(seed)
return pk, sk, nil
}

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// Copyright 2010 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import (
"crypto"
"crypto/aes"
"crypto/cipher"
"crypto/des"
"crypto/hmac"
"crypto/rc4"
"crypto/sha1"
"crypto/sha256"
"fmt"
"hash"
"runtime"
"golang.org/x/crypto/chacha20poly1305"
"golang.org/x/sys/cpu"
)
// CipherSuite is a TLS cipher suite. Note that most functions in this package
// accept and expose cipher suite IDs instead of this type.
type CipherSuite struct {
ID uint16
Name string
// Supported versions is the list of TLS protocol versions that can
// negotiate this cipher suite.
SupportedVersions []uint16
// Insecure is true if the cipher suite has known security issues
// due to its primitives, design, or implementation.
Insecure bool
}
var (
supportedUpToTLS12 = []uint16{VersionTLS10, VersionTLS11, VersionTLS12}
supportedOnlyTLS12 = []uint16{VersionTLS12}
supportedOnlyTLS13 = []uint16{VersionTLS13}
)
// CipherSuites returns a list of cipher suites currently implemented by this
// package, excluding those with security issues, which are returned by
// InsecureCipherSuites.
//
// The list is sorted by ID. Note that the default cipher suites selected by
// this package might depend on logic that can't be captured by a static list,
// and might not match those returned by this function.
func CipherSuites() []*CipherSuite {
return []*CipherSuite{
{TLS_RSA_WITH_AES_128_CBC_SHA, "TLS_RSA_WITH_AES_128_CBC_SHA", supportedUpToTLS12, false},
{TLS_RSA_WITH_AES_256_CBC_SHA, "TLS_RSA_WITH_AES_256_CBC_SHA", supportedUpToTLS12, false},
{TLS_RSA_WITH_AES_128_GCM_SHA256, "TLS_RSA_WITH_AES_128_GCM_SHA256", supportedOnlyTLS12, false},
{TLS_RSA_WITH_AES_256_GCM_SHA384, "TLS_RSA_WITH_AES_256_GCM_SHA384", supportedOnlyTLS12, false},
{TLS_AES_128_GCM_SHA256, "TLS_AES_128_GCM_SHA256", supportedOnlyTLS13, false},
{TLS_AES_256_GCM_SHA384, "TLS_AES_256_GCM_SHA384", supportedOnlyTLS13, false},
{TLS_CHACHA20_POLY1305_SHA256, "TLS_CHACHA20_POLY1305_SHA256", supportedOnlyTLS13, false},
{TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA, "TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA", supportedUpToTLS12, false},
{TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA, "TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA", supportedUpToTLS12, false},
{TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA, "TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA", supportedUpToTLS12, false},
{TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA, "TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA", supportedUpToTLS12, false},
{TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256, "TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256", supportedOnlyTLS12, false},
{TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384, "TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384", supportedOnlyTLS12, false},
{TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256, "TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256", supportedOnlyTLS12, false},
{TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384, "TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384", supportedOnlyTLS12, false},
{TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256, "TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256", supportedOnlyTLS12, false},
{TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305_SHA256, "TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305_SHA256", supportedOnlyTLS12, false},
}
}
// InsecureCipherSuites returns a list of cipher suites currently implemented by
// this package and which have security issues.
//
// Most applications should not use the cipher suites in this list, and should
// only use those returned by CipherSuites.
func InsecureCipherSuites() []*CipherSuite {
// This list includes RC4, CBC_SHA256, and 3DES cipher suites. See
// cipherSuitesPreferenceOrder for details.
return []*CipherSuite{
{TLS_RSA_WITH_RC4_128_SHA, "TLS_RSA_WITH_RC4_128_SHA", supportedUpToTLS12, true},
{TLS_RSA_WITH_3DES_EDE_CBC_SHA, "TLS_RSA_WITH_3DES_EDE_CBC_SHA", supportedUpToTLS12, true},
{TLS_RSA_WITH_AES_128_CBC_SHA256, "TLS_RSA_WITH_AES_128_CBC_SHA256", supportedOnlyTLS12, true},
{TLS_ECDHE_ECDSA_WITH_RC4_128_SHA, "TLS_ECDHE_ECDSA_WITH_RC4_128_SHA", supportedUpToTLS12, true},
{TLS_ECDHE_RSA_WITH_RC4_128_SHA, "TLS_ECDHE_RSA_WITH_RC4_128_SHA", supportedUpToTLS12, true},
{TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA, "TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA", supportedUpToTLS12, true},
{TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256, "TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256", supportedOnlyTLS12, true},
{TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256, "TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256", supportedOnlyTLS12, true},
}
}
// CipherSuiteName returns the standard name for the passed cipher suite ID
// (e.g. "TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256"), or a fallback representation
// of the ID value if the cipher suite is not implemented by this package.
func CipherSuiteName(id uint16) string {
for _, c := range CipherSuites() {
if c.ID == id {
return c.Name
}
}
for _, c := range InsecureCipherSuites() {
if c.ID == id {
return c.Name
}
}
return fmt.Sprintf("0x%04X", id)
}
const (
// suiteECDHE indicates that the cipher suite involves elliptic curve
// Diffie-Hellman. This means that it should only be selected when the
// client indicates that it supports ECC with a curve and point format
// that we're happy with.
suiteECDHE = 1 << iota
// suiteECSign indicates that the cipher suite involves an ECDSA or
// EdDSA signature and therefore may only be selected when the server's
// certificate is ECDSA or EdDSA. If this is not set then the cipher suite
// is RSA based.
suiteECSign
// suiteTLS12 indicates that the cipher suite should only be advertised
// and accepted when using TLS 1.2.
suiteTLS12
// suiteSHA384 indicates that the cipher suite uses SHA384 as the
// handshake hash.
suiteSHA384
)
// A cipherSuite is a TLS 1.01.2 cipher suite, and defines the key exchange
// mechanism, as well as the cipher+MAC pair or the AEAD.
type cipherSuite struct {
id uint16
// the lengths, in bytes, of the key material needed for each component.
keyLen int
macLen int
ivLen int
ka func(version uint16) keyAgreement
// flags is a bitmask of the suite* values, above.
flags int
cipher func(key, iv []byte, isRead bool) any
mac func(key []byte) hash.Hash
aead func(key, fixedNonce []byte) aead
}
var cipherSuites = []*cipherSuite{ // TODO: replace with a map, since the order doesn't matter.
{TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305, 32, 0, 12, ecdheRSAKA, suiteECDHE | suiteTLS12, nil, nil, aeadChaCha20Poly1305},
{TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305, 32, 0, 12, ecdheECDSAKA, suiteECDHE | suiteECSign | suiteTLS12, nil, nil, aeadChaCha20Poly1305},
{TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256, 16, 0, 4, ecdheRSAKA, suiteECDHE | suiteTLS12, nil, nil, aeadAESGCM},
{TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256, 16, 0, 4, ecdheECDSAKA, suiteECDHE | suiteECSign | suiteTLS12, nil, nil, aeadAESGCM},
{TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384, 32, 0, 4, ecdheRSAKA, suiteECDHE | suiteTLS12 | suiteSHA384, nil, nil, aeadAESGCM},
{TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384, 32, 0, 4, ecdheECDSAKA, suiteECDHE | suiteECSign | suiteTLS12 | suiteSHA384, nil, nil, aeadAESGCM},
{TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256, 16, 32, 16, ecdheRSAKA, suiteECDHE | suiteTLS12, cipherAES, macSHA256, nil},
{TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA, 16, 20, 16, ecdheRSAKA, suiteECDHE, cipherAES, macSHA1, nil},
{TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256, 16, 32, 16, ecdheECDSAKA, suiteECDHE | suiteECSign | suiteTLS12, cipherAES, macSHA256, nil},
{TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA, 16, 20, 16, ecdheECDSAKA, suiteECDHE | suiteECSign, cipherAES, macSHA1, nil},
{TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA, 32, 20, 16, ecdheRSAKA, suiteECDHE, cipherAES, macSHA1, nil},
{TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA, 32, 20, 16, ecdheECDSAKA, suiteECDHE | suiteECSign, cipherAES, macSHA1, nil},
{TLS_RSA_WITH_AES_128_GCM_SHA256, 16, 0, 4, rsaKA, suiteTLS12, nil, nil, aeadAESGCM},
{TLS_RSA_WITH_AES_256_GCM_SHA384, 32, 0, 4, rsaKA, suiteTLS12 | suiteSHA384, nil, nil, aeadAESGCM},
{TLS_RSA_WITH_AES_128_CBC_SHA256, 16, 32, 16, rsaKA, suiteTLS12, cipherAES, macSHA256, nil},
{TLS_RSA_WITH_AES_128_CBC_SHA, 16, 20, 16, rsaKA, 0, cipherAES, macSHA1, nil},
{TLS_RSA_WITH_AES_256_CBC_SHA, 32, 20, 16, rsaKA, 0, cipherAES, macSHA1, nil},
{TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA, 24, 20, 8, ecdheRSAKA, suiteECDHE, cipher3DES, macSHA1, nil},
{TLS_RSA_WITH_3DES_EDE_CBC_SHA, 24, 20, 8, rsaKA, 0, cipher3DES, macSHA1, nil},
{TLS_RSA_WITH_RC4_128_SHA, 16, 20, 0, rsaKA, 0, cipherRC4, macSHA1, nil},
{TLS_ECDHE_RSA_WITH_RC4_128_SHA, 16, 20, 0, ecdheRSAKA, suiteECDHE, cipherRC4, macSHA1, nil},
{TLS_ECDHE_ECDSA_WITH_RC4_128_SHA, 16, 20, 0, ecdheECDSAKA, suiteECDHE | suiteECSign, cipherRC4, macSHA1, nil},
}
// selectCipherSuite returns the first TLS 1.01.2 cipher suite from ids which
// is also in supportedIDs and passes the ok filter.
func selectCipherSuite(ids, supportedIDs []uint16, ok func(*cipherSuite) bool) *cipherSuite {
for _, id := range ids {
candidate := cipherSuiteByID(id)
if candidate == nil || !ok(candidate) {
continue
}
for _, suppID := range supportedIDs {
if id == suppID {
return candidate
}
}
}
return nil
}
// A cipherSuiteTLS13 defines only the pair of the AEAD algorithm and hash
// algorithm to be used with HKDF. See RFC 8446, Appendix B.4.
type cipherSuiteTLS13 struct {
id uint16
keyLen int
aead func(key, fixedNonce []byte) aead
hash crypto.Hash
}
var cipherSuitesTLS13 = []*cipherSuiteTLS13{ // TODO: replace with a map.
{TLS_AES_128_GCM_SHA256, 16, aeadAESGCMTLS13, crypto.SHA256},
{TLS_CHACHA20_POLY1305_SHA256, 32, aeadChaCha20Poly1305, crypto.SHA256},
{TLS_AES_256_GCM_SHA384, 32, aeadAESGCMTLS13, crypto.SHA384},
}
// cipherSuitesPreferenceOrder is the order in which we'll select (on the
// server) or advertise (on the client) TLS 1.01.2 cipher suites.
//
// Cipher suites are filtered but not reordered based on the application and
// peer's preferences, meaning we'll never select a suite lower in this list if
// any higher one is available. This makes it more defensible to keep weaker
// cipher suites enabled, especially on the server side where we get the last
// word, since there are no known downgrade attacks on cipher suites selection.
//
// The list is sorted by applying the following priority rules, stopping at the
// first (most important) applicable one:
//
// - Anything else comes before RC4
//
// RC4 has practically exploitable biases. See https://www.rc4nomore.com.
//
// - Anything else comes before CBC_SHA256
//
// SHA-256 variants of the CBC ciphersuites don't implement any Lucky13
// countermeasures. See http://www.isg.rhul.ac.uk/tls/Lucky13.html and
// https://www.imperialviolet.org/2013/02/04/luckythirteen.html.
//
// - Anything else comes before 3DES
//
// 3DES has 64-bit blocks, which makes it fundamentally susceptible to
// birthday attacks. See https://sweet32.info.
//
// - ECDHE comes before anything else
//
// Once we got the broken stuff out of the way, the most important
// property a cipher suite can have is forward secrecy. We don't
// implement FFDHE, so that means ECDHE.
//
// - AEADs come before CBC ciphers
//
// Even with Lucky13 countermeasures, MAC-then-Encrypt CBC cipher suites
// are fundamentally fragile, and suffered from an endless sequence of
// padding oracle attacks. See https://eprint.iacr.org/2015/1129,
// https://www.imperialviolet.org/2014/12/08/poodleagain.html, and
// https://blog.cloudflare.com/yet-another-padding-oracle-in-openssl-cbc-ciphersuites/.
//
// - AES comes before ChaCha20
//
// When AES hardware is available, AES-128-GCM and AES-256-GCM are faster
// than ChaCha20Poly1305.
//
// When AES hardware is not available, AES-128-GCM is one or more of: much
// slower, way more complex, and less safe (because not constant time)
// than ChaCha20Poly1305.
//
// We use this list if we think both peers have AES hardware, and
// cipherSuitesPreferenceOrderNoAES otherwise.
//
// - AES-128 comes before AES-256
//
// The only potential advantages of AES-256 are better multi-target
// margins, and hypothetical post-quantum properties. Neither apply to
// TLS, and AES-256 is slower due to its four extra rounds (which don't
// contribute to the advantages above).
//
// - ECDSA comes before RSA
//
// The relative order of ECDSA and RSA cipher suites doesn't matter,
// as they depend on the certificate. Pick one to get a stable order.
var cipherSuitesPreferenceOrder = []uint16{
// AEADs w/ ECDHE
TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256, TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256,
TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384, TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384,
TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305, TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305,
// CBC w/ ECDHE
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA, TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA,
TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA, TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA,
// AEADs w/o ECDHE
TLS_RSA_WITH_AES_128_GCM_SHA256,
TLS_RSA_WITH_AES_256_GCM_SHA384,
// CBC w/o ECDHE
TLS_RSA_WITH_AES_128_CBC_SHA,
TLS_RSA_WITH_AES_256_CBC_SHA,
// 3DES
TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA,
TLS_RSA_WITH_3DES_EDE_CBC_SHA,
// CBC_SHA256
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256, TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256,
TLS_RSA_WITH_AES_128_CBC_SHA256,
// RC4
TLS_ECDHE_ECDSA_WITH_RC4_128_SHA, TLS_ECDHE_RSA_WITH_RC4_128_SHA,
TLS_RSA_WITH_RC4_128_SHA,
}
var cipherSuitesPreferenceOrderNoAES = []uint16{
// ChaCha20Poly1305
TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305, TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305,
// AES-GCM w/ ECDHE
TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256, TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256,
TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384, TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384,
// The rest of cipherSuitesPreferenceOrder.
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA, TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA,
TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA, TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA,
TLS_RSA_WITH_AES_128_GCM_SHA256,
TLS_RSA_WITH_AES_256_GCM_SHA384,
TLS_RSA_WITH_AES_128_CBC_SHA,
TLS_RSA_WITH_AES_256_CBC_SHA,
TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA,
TLS_RSA_WITH_3DES_EDE_CBC_SHA,
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256, TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256,
TLS_RSA_WITH_AES_128_CBC_SHA256,
TLS_ECDHE_ECDSA_WITH_RC4_128_SHA, TLS_ECDHE_RSA_WITH_RC4_128_SHA,
TLS_RSA_WITH_RC4_128_SHA,
}
// disabledCipherSuites are not used unless explicitly listed in
// Config.CipherSuites. They MUST be at the end of cipherSuitesPreferenceOrder.
var disabledCipherSuites = []uint16{
// CBC_SHA256
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256, TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256,
TLS_RSA_WITH_AES_128_CBC_SHA256,
// RC4
TLS_ECDHE_ECDSA_WITH_RC4_128_SHA, TLS_ECDHE_RSA_WITH_RC4_128_SHA,
TLS_RSA_WITH_RC4_128_SHA,
}
var (
defaultCipherSuitesLen = len(cipherSuitesPreferenceOrder) - len(disabledCipherSuites)
defaultCipherSuites = cipherSuitesPreferenceOrder[:defaultCipherSuitesLen]
)
// defaultCipherSuitesTLS13 is also the preference order, since there are no
// disabled by default TLS 1.3 cipher suites. The same AES vs ChaCha20 logic as
// cipherSuitesPreferenceOrder applies.
var defaultCipherSuitesTLS13 = []uint16{
TLS_AES_128_GCM_SHA256,
TLS_AES_256_GCM_SHA384,
TLS_CHACHA20_POLY1305_SHA256,
}
var defaultCipherSuitesTLS13NoAES = []uint16{
TLS_CHACHA20_POLY1305_SHA256,
TLS_AES_128_GCM_SHA256,
TLS_AES_256_GCM_SHA384,
}
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)
hasAESGCMHardwareSupport = runtime.GOARCH == "amd64" && hasGCMAsmAMD64 ||
runtime.GOARCH == "arm64" && hasGCMAsmARM64 ||
runtime.GOARCH == "s390x" && hasGCMAsmS390X
)
var aesgcmCiphers = map[uint16]bool{
// TLS 1.2
TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256: true,
TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384: true,
TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256: true,
TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384: true,
// TLS 1.3
TLS_AES_128_GCM_SHA256: true,
TLS_AES_256_GCM_SHA384: true,
}
var nonAESGCMAEADCiphers = map[uint16]bool{
// TLS 1.2
TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305: true,
TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305: true,
// TLS 1.3
TLS_CHACHA20_POLY1305_SHA256: true,
}
// aesgcmPreferred returns whether the first known cipher in the preference list
// is an AES-GCM cipher, implying the peer has hardware support for it.
func aesgcmPreferred(ciphers []uint16) bool {
for _, cID := range ciphers {
if c := cipherSuiteByID(cID); c != nil {
return aesgcmCiphers[cID]
}
if c := cipherSuiteTLS13ByID(cID); c != nil {
return aesgcmCiphers[cID]
}
}
return false
}
func cipherRC4(key, iv []byte, isRead bool) any {
cipher, _ := rc4.NewCipher(key)
return cipher
}
func cipher3DES(key, iv []byte, isRead bool) any {
block, _ := des.NewTripleDESCipher(key)
if isRead {
return cipher.NewCBCDecrypter(block, iv)
}
return cipher.NewCBCEncrypter(block, iv)
}
func cipherAES(key, iv []byte, isRead bool) any {
block, _ := aes.NewCipher(key)
if isRead {
return cipher.NewCBCDecrypter(block, iv)
}
return cipher.NewCBCEncrypter(block, iv)
}
// macSHA1 returns a SHA-1 based constant time MAC.
func macSHA1(key []byte) hash.Hash {
return hmac.New(newConstantTimeHash(sha1.New), key)
}
// macSHA256 returns a SHA-256 based MAC. This is only supported in TLS 1.2 and
// is currently only used in disabled-by-default cipher suites.
func macSHA256(key []byte) hash.Hash {
return hmac.New(sha256.New, key)
}
type aead interface {
cipher.AEAD
// explicitNonceLen returns the number of bytes of explicit nonce
// included in each record. This is eight for older AEADs and
// zero for modern ones.
explicitNonceLen() int
}
const (
aeadNonceLength = 12
noncePrefixLength = 4
)
// prefixNonceAEAD wraps an AEAD and prefixes a fixed portion of the nonce to
// each call.
type prefixNonceAEAD struct {
// nonce contains the fixed part of the nonce in the first four bytes.
nonce [aeadNonceLength]byte
aead cipher.AEAD
}
func (f *prefixNonceAEAD) NonceSize() int { return aeadNonceLength - noncePrefixLength }
func (f *prefixNonceAEAD) Overhead() int { return f.aead.Overhead() }
func (f *prefixNonceAEAD) explicitNonceLen() int { return f.NonceSize() }
func (f *prefixNonceAEAD) Seal(out, nonce, plaintext, additionalData []byte) []byte {
copy(f.nonce[4:], nonce)
return f.aead.Seal(out, f.nonce[:], plaintext, additionalData)
}
func (f *prefixNonceAEAD) Open(out, nonce, ciphertext, additionalData []byte) ([]byte, error) {
copy(f.nonce[4:], nonce)
return f.aead.Open(out, f.nonce[:], ciphertext, additionalData)
}
// xoredNonceAEAD wraps an AEAD by XORing in a fixed pattern to the nonce
// before each call.
type xorNonceAEAD struct {
nonceMask [aeadNonceLength]byte
aead cipher.AEAD
}
func (f *xorNonceAEAD) NonceSize() int { return 8 } // 64-bit sequence number
func (f *xorNonceAEAD) Overhead() int { return f.aead.Overhead() }
func (f *xorNonceAEAD) explicitNonceLen() int { return 0 }
func (f *xorNonceAEAD) Seal(out, nonce, plaintext, additionalData []byte) []byte {
for i, b := range nonce {
f.nonceMask[4+i] ^= b
}
result := f.aead.Seal(out, f.nonceMask[:], plaintext, additionalData)
for i, b := range nonce {
f.nonceMask[4+i] ^= b
}
return result
}
func (f *xorNonceAEAD) Open(out, nonce, ciphertext, additionalData []byte) ([]byte, error) {
for i, b := range nonce {
f.nonceMask[4+i] ^= b
}
result, err := f.aead.Open(out, f.nonceMask[:], ciphertext, additionalData)
for i, b := range nonce {
f.nonceMask[4+i] ^= b
}
return result, err
}
func aeadAESGCM(key, noncePrefix []byte) aead {
if len(noncePrefix) != noncePrefixLength {
panic("tls: internal error: wrong nonce length")
}
aes, err := aes.NewCipher(key)
if err != nil {
panic(err)
}
aead, err := cipher.NewGCM(aes)
if err != nil {
panic(err)
}
ret := &prefixNonceAEAD{aead: aead}
copy(ret.nonce[:], noncePrefix)
return ret
}
func aeadAESGCMTLS13(key, nonceMask []byte) aead {
if len(nonceMask) != aeadNonceLength {
panic("tls: internal error: wrong nonce length")
}
aes, err := aes.NewCipher(key)
if err != nil {
panic(err)
}
aead, err := cipher.NewGCM(aes)
if err != nil {
panic(err)
}
ret := &xorNonceAEAD{aead: aead}
copy(ret.nonceMask[:], nonceMask)
return ret
}
func aeadChaCha20Poly1305(key, nonceMask []byte) aead {
if len(nonceMask) != aeadNonceLength {
panic("tls: internal error: wrong nonce length")
}
aead, err := chacha20poly1305.New(key)
if err != nil {
panic(err)
}
ret := &xorNonceAEAD{aead: aead}
copy(ret.nonceMask[:], nonceMask)
return ret
}
type constantTimeHash interface {
hash.Hash
ConstantTimeSum(b []byte) []byte
}
// cthWrapper wraps any hash.Hash that implements ConstantTimeSum, and replaces
// with that all calls to Sum. It's used to obtain a ConstantTimeSum-based HMAC.
type cthWrapper struct {
h constantTimeHash
}
func (c *cthWrapper) Size() int { return c.h.Size() }
func (c *cthWrapper) BlockSize() int { return c.h.BlockSize() }
func (c *cthWrapper) Reset() { c.h.Reset() }
func (c *cthWrapper) Write(p []byte) (int, error) { return c.h.Write(p) }
func (c *cthWrapper) Sum(b []byte) []byte { return c.h.ConstantTimeSum(b) }
func newConstantTimeHash(h func() hash.Hash) func() hash.Hash {
return func() hash.Hash {
return &cthWrapper{h().(constantTimeHash)}
}
}
// tls10MAC implements the TLS 1.0 MAC function. RFC 2246, Section 6.2.3.
func tls10MAC(h hash.Hash, out, seq, header, data, extra []byte) []byte {
h.Reset()
h.Write(seq)
h.Write(header)
h.Write(data)
res := h.Sum(out)
if extra != nil {
h.Write(extra)
}
return res
}
func rsaKA(version uint16) keyAgreement {
return rsaKeyAgreement{}
}
func ecdheECDSAKA(version uint16) keyAgreement {
return &ecdheKeyAgreement{
isRSA: false,
version: version,
}
}
func ecdheRSAKA(version uint16) keyAgreement {
return &ecdheKeyAgreement{
isRSA: true,
version: version,
}
}
// mutualCipherSuite returns a cipherSuite given a list of supported
// ciphersuites and the id requested by the peer.
func mutualCipherSuite(have []uint16, want uint16) *cipherSuite {
for _, id := range have {
if id == want {
return cipherSuiteByID(id)
}
}
return nil
}
func cipherSuiteByID(id uint16) *cipherSuite {
for _, cipherSuite := range cipherSuites {
if cipherSuite.id == id {
return cipherSuite
}
}
return nil
}
func mutualCipherSuiteTLS13(have []uint16, want uint16) *cipherSuiteTLS13 {
for _, id := range have {
if id == want {
return cipherSuiteTLS13ByID(id)
}
}
return nil
}
func cipherSuiteTLS13ByID(id uint16) *cipherSuiteTLS13 {
for _, cipherSuite := range cipherSuitesTLS13 {
if cipherSuite.id == id {
return cipherSuite
}
}
return nil
}
// A list of cipher suite IDs that are, or have been, implemented by this
// package.
//
// See https://www.iana.org/assignments/tls-parameters/tls-parameters.xml
const (
// TLS 1.0 - 1.2 cipher suites.
TLS_RSA_WITH_RC4_128_SHA uint16 = 0x0005
TLS_RSA_WITH_3DES_EDE_CBC_SHA uint16 = 0x000a
TLS_RSA_WITH_AES_128_CBC_SHA uint16 = 0x002f
TLS_RSA_WITH_AES_256_CBC_SHA uint16 = 0x0035
TLS_RSA_WITH_AES_128_CBC_SHA256 uint16 = 0x003c
TLS_RSA_WITH_AES_128_GCM_SHA256 uint16 = 0x009c
TLS_RSA_WITH_AES_256_GCM_SHA384 uint16 = 0x009d
TLS_ECDHE_ECDSA_WITH_RC4_128_SHA uint16 = 0xc007
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA uint16 = 0xc009
TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA uint16 = 0xc00a
TLS_ECDHE_RSA_WITH_RC4_128_SHA uint16 = 0xc011
TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA uint16 = 0xc012
TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA uint16 = 0xc013
TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA uint16 = 0xc014
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256 uint16 = 0xc023
TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256 uint16 = 0xc027
TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256 uint16 = 0xc02f
TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256 uint16 = 0xc02b
TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384 uint16 = 0xc030
TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384 uint16 = 0xc02c
TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256 uint16 = 0xcca8
TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305_SHA256 uint16 = 0xcca9
// TLS 1.3 cipher suites.
TLS_AES_128_GCM_SHA256 uint16 = 0x1301
TLS_AES_256_GCM_SHA384 uint16 = 0x1302
TLS_CHACHA20_POLY1305_SHA256 uint16 = 0x1303
// TLS_FALLBACK_SCSV isn't a standard cipher suite but an indicator
// that the client is doing version fallback. See RFC 7507.
TLS_FALLBACK_SCSV uint16 = 0x5600
// Legacy names for the corresponding cipher suites with the correct _SHA256
// suffix, retained for backward compatibility.
TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305 = TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256
TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305 = TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305_SHA256
)

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// Code generated by "stringer -type=SignatureScheme,CurveID,ClientAuthType -output=common_string.go"; DO NOT EDIT.
package tls
import "strconv"
func _() {
// An "invalid array index" compiler error signifies that the constant values have changed.
// Re-run the stringer command to generate them again.
var x [1]struct{}
_ = x[PKCS1WithSHA256-1025]
_ = x[PKCS1WithSHA384-1281]
_ = x[PKCS1WithSHA512-1537]
_ = x[PSSWithSHA256-2052]
_ = x[PSSWithSHA384-2053]
_ = x[PSSWithSHA512-2054]
_ = x[ECDSAWithP256AndSHA256-1027]
_ = x[ECDSAWithP384AndSHA384-1283]
_ = x[ECDSAWithP521AndSHA512-1539]
_ = x[Ed25519-2055]
_ = x[PKCS1WithSHA1-513]
_ = x[ECDSAWithSHA1-515]
}
const (
_SignatureScheme_name_0 = "PKCS1WithSHA1"
_SignatureScheme_name_1 = "ECDSAWithSHA1"
_SignatureScheme_name_2 = "PKCS1WithSHA256"
_SignatureScheme_name_3 = "ECDSAWithP256AndSHA256"
_SignatureScheme_name_4 = "PKCS1WithSHA384"
_SignatureScheme_name_5 = "ECDSAWithP384AndSHA384"
_SignatureScheme_name_6 = "PKCS1WithSHA512"
_SignatureScheme_name_7 = "ECDSAWithP521AndSHA512"
_SignatureScheme_name_8 = "PSSWithSHA256PSSWithSHA384PSSWithSHA512Ed25519"
)
var (
_SignatureScheme_index_8 = [...]uint8{0, 13, 26, 39, 46}
)
func (i SignatureScheme) String() string {
switch {
case i == 513:
return _SignatureScheme_name_0
case i == 515:
return _SignatureScheme_name_1
case i == 1025:
return _SignatureScheme_name_2
case i == 1027:
return _SignatureScheme_name_3
case i == 1281:
return _SignatureScheme_name_4
case i == 1283:
return _SignatureScheme_name_5
case i == 1537:
return _SignatureScheme_name_6
case i == 1539:
return _SignatureScheme_name_7
case 2052 <= i && i <= 2055:
i -= 2052
return _SignatureScheme_name_8[_SignatureScheme_index_8[i]:_SignatureScheme_index_8[i+1]]
default:
return "SignatureScheme(" + strconv.FormatInt(int64(i), 10) + ")"
}
}
func _() {
// An "invalid array index" compiler error signifies that the constant values have changed.
// Re-run the stringer command to generate them again.
var x [1]struct{}
_ = x[CurveP256-23]
_ = x[CurveP384-24]
_ = x[CurveP521-25]
_ = x[X25519-29]
}
const (
_CurveID_name_0 = "CurveP256CurveP384CurveP521"
_CurveID_name_1 = "X25519"
)
var (
_CurveID_index_0 = [...]uint8{0, 9, 18, 27}
)
func (i CurveID) String() string {
switch {
case 23 <= i && i <= 25:
i -= 23
return _CurveID_name_0[_CurveID_index_0[i]:_CurveID_index_0[i+1]]
case i == 29:
return _CurveID_name_1
default:
return "CurveID(" + strconv.FormatInt(int64(i), 10) + ")"
}
}
func _() {
// An "invalid array index" compiler error signifies that the constant values have changed.
// Re-run the stringer command to generate them again.
var x [1]struct{}
_ = x[NoClientCert-0]
_ = x[RequestClientCert-1]
_ = x[RequireAnyClientCert-2]
_ = x[VerifyClientCertIfGiven-3]
_ = x[RequireAndVerifyClientCert-4]
}
const _ClientAuthType_name = "NoClientCertRequestClientCertRequireAnyClientCertVerifyClientCertIfGivenRequireAndVerifyClientCert"
var _ClientAuthType_index = [...]uint8{0, 12, 29, 49, 72, 98}
func (i ClientAuthType) String() string {
if i < 0 || i >= ClientAuthType(len(_ClientAuthType_index)-1) {
return "ClientAuthType(" + strconv.FormatInt(int64(i), 10) + ")"
}
return _ClientAuthType_name[_ClientAuthType_index[i]:_ClientAuthType_index[i+1]]
}

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// Copyright 2020-2021 Cloudflare, Inc. All rights reserved. Use of this source code
// is governed by a BSD-style license that can be found in the LICENSE file.
package tls
// Delegated Credentials for TLS
// (https://tools.ietf.org/html/draft-ietf-tls-subcerts) is an IETF Internet
// draft and proposed TLS extension. If the client or server supports this
// extension, then the server or client may use a "delegated credential" as the
// signing key in the handshake. A delegated credential is a short lived
// public/secret key pair delegated to the peer by an entity trusted by the
// corresponding peer. This allows a reverse proxy to terminate a TLS connection
// on behalf of the entity. Credentials can't be revoked; in order to
// mitigate risk in case the reverse proxy is compromised, the credential is only
// valid for a short time (days, hours, or even minutes).
import (
"bytes"
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/elliptic"
"crypto/rand"
"crypto/rsa"
"crypto/x509"
"encoding/binary"
"errors"
"fmt"
"io"
"time"
"golang.org/x/crypto/cryptobyte"
)
const (
// In the absence of an application profile standard specifying otherwise,
// the maximum validity period is set to 7 days.
dcMaxTTLSeconds = 60 * 60 * 24 * 7
dcMaxTTL = time.Duration(dcMaxTTLSeconds * time.Second)
dcMaxPubLen = (1 << 24) - 1 // Bytes
dcMaxSignatureLen = (1 << 16) - 1 // Bytes
)
const (
undefinedSignatureScheme SignatureScheme = 0x0000
)
var extensionDelegatedCredential = []int{1, 3, 6, 1, 4, 1, 44363, 44}
// isValidForDelegation returns true if a certificate can be used for Delegated
// Credentials.
func isValidForDelegation(cert *x509.Certificate) bool {
// Check that the digitalSignature key usage is set.
// The certificate must contains the digitalSignature KeyUsage.
if (cert.KeyUsage & x509.KeyUsageDigitalSignature) == 0 {
return false
}
// Check that the certificate has the DelegationUsage extension and that
// it's marked as non-critical (See Section 4.2 of RFC5280).
for _, extension := range cert.Extensions {
if extension.Id.Equal(extensionDelegatedCredential) {
if extension.Critical {
return false
}
return true
}
}
return false
}
// isExpired returns true if the credential has expired. The end of the validity
// interval is defined as the delegator certificate's notBefore field ('start')
// plus dc.cred.validTime seconds. This function simply checks that the current time
// ('now') is before the end of the validity interval.
func (dc *DelegatedCredential) isExpired(start, now time.Time) bool {
end := start.Add(dc.cred.validTime)
return !now.Before(end)
}
// invalidTTL returns true if the credential's validity period is longer than the
// maximum permitted. This is defined by the certificate's notBefore field
// ('start') plus the dc.validTime, minus the current time ('now').
func (dc *DelegatedCredential) invalidTTL(start, now time.Time) bool {
return dc.cred.validTime > (now.Sub(start) + dcMaxTTL).Round(time.Second)
}
// credential stores the public components of a Delegated Credential.
type credential struct {
// The amount of time for which the credential is valid. Specifically, the
// the credential expires 'validTime' seconds after the 'notBefore' of the
// delegation certificate. The delegator shall not issue Delegated
// Credentials that are valid for more than 7 days from the current time.
//
// When this data structure is serialized, this value is converted to a
// uint32 representing the duration in seconds.
validTime time.Duration
// The signature scheme associated with the credential public key.
// This is expected to be the same as the CertificateVerify.algorithm
// sent by the client or server.
expCertVerfAlgo SignatureScheme
// The credential's public key.
publicKey crypto.PublicKey
}
// DelegatedCredential stores a Delegated Credential with the credential and its
// signature.
type DelegatedCredential struct {
// The serialized form of the Delegated Credential.
raw []byte
// Cred stores the public components of a Delegated Credential.
cred *credential
// The signature scheme used to sign the Delegated Credential.
algorithm SignatureScheme
// The Credential's delegation: a signature that binds the credential to
// the end-entity certificate's public key.
signature []byte
}
// marshalPublicKeyInfo returns a DER encoded PublicKeyInfo
// from a Delegated Credential (as defined in the X.509 standard).
// The following key types are currently supported: *ecdsa.PublicKey
// and ed25519.PublicKey. Unsupported key types result in an error.
// rsa.PublicKey is not supported as defined by the draft.
func (cred *credential) marshalPublicKeyInfo() ([]byte, error) {
switch cred.expCertVerfAlgo {
case ECDSAWithP256AndSHA256,
ECDSAWithP384AndSHA384,
ECDSAWithP521AndSHA512,
Ed25519:
rawPub, err := x509.MarshalPKIXPublicKey(cred.publicKey)
if err != nil {
return nil, err
}
return rawPub, nil
default:
return nil, fmt.Errorf("tls: unsupported signature scheme: 0x%04x", cred.expCertVerfAlgo)
}
}
// marshal encodes the credential struct of the Delegated Credential.
func (cred *credential) marshal() ([]byte, error) {
var b cryptobyte.Builder
b.AddUint32(uint32(cred.validTime / time.Second))
b.AddUint16(uint16(cred.expCertVerfAlgo))
// Encode the public key
rawPub, err := cred.marshalPublicKeyInfo()
if err != nil {
return nil, err
}
// Assert that the public key encoding is no longer than 2^24-1 bytes.
if len(rawPub) > dcMaxPubLen {
return nil, errors.New("tls: public key length exceeds 2^24-1 limit")
}
b.AddUint24(uint32(len(rawPub)))
b.AddBytes(rawPub)
raw := b.BytesOrPanic()
return raw, nil
}
// unmarshalCredential decodes serialized bytes and returns a credential, if possible.
func unmarshalCredential(raw []byte) (*credential, error) {
if len(raw) < 10 {
return nil, errors.New("tls: Delegated Credential is not valid: invalid length")
}
s := cryptobyte.String(raw)
var t uint32
if !s.ReadUint32(&t) {
return nil, errors.New("tls: Delegated Credential is not valid")
}
validTime := time.Duration(t) * time.Second
var pubAlgo uint16
if !s.ReadUint16(&pubAlgo) {
return nil, errors.New("tls: Delegated Credential is not valid")
}
algo := SignatureScheme(pubAlgo)
var pubLen uint32
s.ReadUint24(&pubLen)
pubKey, err := x509.ParsePKIXPublicKey(s)
if err != nil {
return nil, err
}
return &credential{validTime, algo, pubKey}, nil
}
// getCredentialLen returns the number of bytes comprising the serialized
// credential struct inside the Delegated Credential.
func getCredentialLen(raw []byte) (int, error) {
if len(raw) < 10 {
return 0, errors.New("tls: Delegated Credential is not valid")
}
var read []byte
s := cryptobyte.String(raw)
s.ReadBytes(&read, 6)
var pubLen uint32
s.ReadUint24(&pubLen)
if !(pubLen > 0) {
return 0, errors.New("tls: Delegated Credential is not valid")
}
raw = raw[6:]
if len(raw) < int(pubLen) {
return 0, errors.New("tls: Delegated Credential is not valid")
}
return 9 + int(pubLen), nil
}
// getHash maps the SignatureScheme to its corresponding hash function.
func getHash(scheme SignatureScheme) crypto.Hash {
switch scheme {
case ECDSAWithP256AndSHA256:
return crypto.SHA256
case ECDSAWithP384AndSHA384:
return crypto.SHA384
case ECDSAWithP521AndSHA512:
return crypto.SHA512
case Ed25519:
return directSigning
case PKCS1WithSHA256, PSSWithSHA256:
return crypto.SHA256
case PSSWithSHA384:
return crypto.SHA384
case PSSWithSHA512:
return crypto.SHA512
default:
return 0 // Unknown hash function
}
}
// getECDSACurve maps the SignatureScheme to its corresponding ecdsa elliptic.Curve.
func getECDSACurve(scheme SignatureScheme) elliptic.Curve {
switch scheme {
case ECDSAWithP256AndSHA256:
return elliptic.P256()
case ECDSAWithP384AndSHA384:
return elliptic.P384()
case ECDSAWithP521AndSHA512:
return elliptic.P521()
default:
return nil
}
}
// prepareDelegationSignatureInput returns the message that the delegator is going to sign.
func prepareDelegationSignatureInput(hash crypto.Hash, cred *credential, dCert []byte, algo SignatureScheme, isClient bool) ([]byte, error) {
header := make([]byte, 64)
for i := range header {
header[i] = 0x20
}
var context string
if !isClient {
context = "TLS, server delegated credentials\x00"
} else {
context = "TLS, client delegated credentials\x00"
}
rawCred, err := cred.marshal()
if err != nil {
return nil, err
}
var rawAlgo [2]byte
binary.BigEndian.PutUint16(rawAlgo[:], uint16(algo))
if hash == directSigning {
b := &bytes.Buffer{}
b.Write(header)
io.WriteString(b, context)
b.Write(dCert)
b.Write(rawCred)
b.Write(rawAlgo[:])
return b.Bytes(), nil
}
h := hash.New()
h.Write(header)
io.WriteString(h, context)
h.Write(dCert)
h.Write(rawCred)
h.Write(rawAlgo[:])
return h.Sum(nil), nil
}
// Extract the algorithm used to sign the Delegated Credential from the
// end-entity (leaf) certificate.
func getSignatureAlgorithm(cert *Certificate) (SignatureScheme, error) {
switch sk := cert.PrivateKey.(type) {
case *ecdsa.PrivateKey:
pk := sk.Public().(*ecdsa.PublicKey)
curveName := pk.Curve.Params().Name
certAlg := cert.Leaf.PublicKeyAlgorithm
if certAlg == x509.ECDSA && curveName == "P-256" {
return ECDSAWithP256AndSHA256, nil
} else if certAlg == x509.ECDSA && curveName == "P-384" {
return ECDSAWithP384AndSHA384, nil
} else if certAlg == x509.ECDSA && curveName == "P-521" {
return ECDSAWithP521AndSHA512, nil
} else {
return undefinedSignatureScheme, fmt.Errorf("using curve %s for %s is not supported", curveName, cert.Leaf.SignatureAlgorithm)
}
case ed25519.PrivateKey:
return Ed25519, nil
case *rsa.PrivateKey:
// If the certificate has the RSAEncryption OID there are a number of valid signature schemes that may sign the DC.
// In the absence of better information, we make a reasonable choice.
return PSSWithSHA256, nil
default:
return undefinedSignatureScheme, fmt.Errorf("tls: unsupported algorithm for signing Delegated Credential")
}
}
// NewDelegatedCredential creates a new Delegated Credential using 'cert' for
// delegation, depending if the caller is the client or the server (defined by
// 'isClient'). It generates a public/private key pair for the provided signature
// algorithm ('pubAlgo') and it defines a validity interval (defined
// by 'cert.Leaf.notBefore' and 'validTime'). It signs the Delegated Credential
// using 'cert.PrivateKey'.
func NewDelegatedCredential(cert *Certificate, pubAlgo SignatureScheme, validTime time.Duration, isClient bool) (*DelegatedCredential, crypto.PrivateKey, error) {
// The granularity of DC validity is seconds.
validTime = validTime.Round(time.Second)
// Parse the leaf certificate if needed.
var err error
if cert.Leaf == nil {
if len(cert.Certificate[0]) == 0 {
return nil, nil, errors.New("tls: missing leaf certificate for Delegated Credential")
}
cert.Leaf, err = x509.ParseCertificate(cert.Certificate[0])
if err != nil {
return nil, nil, err
}
}
// Check that the leaf certificate can be used for delegation.
if !isValidForDelegation(cert.Leaf) {
return nil, nil, errors.New("tls: certificate not authorized for delegation")
}
sigAlgo, err := getSignatureAlgorithm(cert)
if err != nil {
return nil, nil, err
}
// Generate the Delegated Credential key pair based on the provided scheme
var privK crypto.PrivateKey
var pubK crypto.PublicKey
switch pubAlgo {
case ECDSAWithP256AndSHA256,
ECDSAWithP384AndSHA384,
ECDSAWithP521AndSHA512:
privK, err = ecdsa.GenerateKey(getECDSACurve(pubAlgo), rand.Reader)
if err != nil {
return nil, nil, err
}
pubK = privK.(*ecdsa.PrivateKey).Public()
case Ed25519:
pubK, privK, err = ed25519.GenerateKey(rand.Reader)
if err != nil {
return nil, nil, err
}
default:
return nil, nil, fmt.Errorf("tls: unsupported algorithm for Delegated Credential: %s", pubAlgo)
}
// Prepare the credential for signing
hash := getHash(sigAlgo)
credential := &credential{validTime, pubAlgo, pubK}
values, err := prepareDelegationSignatureInput(hash, credential, cert.Leaf.Raw, sigAlgo, isClient)
if err != nil {
return nil, nil, err
}
var sig []byte
switch sk := cert.PrivateKey.(type) {
case *ecdsa.PrivateKey:
opts := crypto.SignerOpts(hash)
sig, err = sk.Sign(rand.Reader, values, opts)
if err != nil {
return nil, nil, err
}
case ed25519.PrivateKey:
opts := crypto.SignerOpts(hash)
sig, err = sk.Sign(rand.Reader, values, opts)
if err != nil {
return nil, nil, err
}
case *rsa.PrivateKey:
opts := &rsa.PSSOptions{
SaltLength: rsa.PSSSaltLengthEqualsHash,
Hash: hash,
}
sig, err = rsa.SignPSS(rand.Reader, sk, hash, values, opts)
if err != nil {
return nil, nil, err
}
default:
return nil, nil, fmt.Errorf("tls: unsupported key type for Delegated Credential")
}
if len(sig) > dcMaxSignatureLen {
return nil, nil, errors.New("tls: unable to create a Delegated Credential")
}
return &DelegatedCredential{
cred: credential,
algorithm: sigAlgo,
signature: sig,
}, privK, nil
}
// Validate validates the Delegated Credential by checking that the signature is
// valid, that it hasn't expired, and that the TTL is valid. It also checks that
// certificate can be used for delegation.
func (dc *DelegatedCredential) Validate(cert *x509.Certificate, isClient bool, now time.Time, certVerifyMsg *certificateVerifyMsg) bool {
if dc.isExpired(cert.NotBefore, now) {
return false
}
if dc.invalidTTL(cert.NotBefore, now) {
return false
}
if dc.cred.expCertVerfAlgo != certVerifyMsg.signatureAlgorithm {
return false
}
if !isValidForDelegation(cert) {
return false
}
hash := getHash(dc.algorithm)
in, err := prepareDelegationSignatureInput(hash, dc.cred, cert.Raw, dc.algorithm, isClient)
if err != nil {
return false
}
switch dc.algorithm {
case ECDSAWithP256AndSHA256,
ECDSAWithP384AndSHA384,
ECDSAWithP521AndSHA512:
pk, ok := cert.PublicKey.(*ecdsa.PublicKey)
if !ok {
return false
}
return ecdsa.VerifyASN1(pk, in, dc.signature)
case Ed25519:
pk, ok := cert.PublicKey.(ed25519.PublicKey)
if !ok {
return false
}
return ed25519.Verify(pk, in, dc.signature)
case PSSWithSHA256,
PSSWithSHA384,
PSSWithSHA512:
pk, ok := cert.PublicKey.(*rsa.PublicKey)
if !ok {
return false
}
hash := getHash(dc.algorithm)
return rsa.VerifyPSS(pk, hash, in, dc.signature, nil) == nil
default:
return false
}
}
// Marshal encodes a DelegatedCredential structure. It also sets dc.Raw to that
// encoding.
func (dc *DelegatedCredential) Marshal() ([]byte, error) {
if len(dc.signature) > dcMaxSignatureLen {
return nil, errors.New("tls: delegated credential is not valid")
}
if len(dc.signature) == 0 {
return nil, errors.New("tls: delegated credential has no signature")
}
raw, err := dc.cred.marshal()
if err != nil {
return nil, err
}
var b cryptobyte.Builder
b.AddBytes(raw)
b.AddUint16(uint16(dc.algorithm))
b.AddUint16(uint16(len(dc.signature)))
b.AddBytes(dc.signature)
dc.raw = b.BytesOrPanic()
return dc.raw, nil
}
// UnmarshalDelegatedCredential decodes a DelegatedCredential structure.
func UnmarshalDelegatedCredential(raw []byte) (*DelegatedCredential, error) {
rawCredentialLen, err := getCredentialLen(raw)
if err != nil {
return nil, err
}
credential, err := unmarshalCredential(raw[:rawCredentialLen])
if err != nil {
return nil, err
}
raw = raw[rawCredentialLen:]
if len(raw) < 4 {
return nil, errors.New("tls: Delegated Credential is not valid")
}
s := cryptobyte.String(raw)
var algo uint16
if !s.ReadUint16(&algo) {
return nil, errors.New("tls: Delegated Credential is not valid")
}
var rawSignatureLen uint16
if !s.ReadUint16(&rawSignatureLen) {
return nil, errors.New("tls: Delegated Credential is not valid")
}
var sig []byte
if !s.ReadBytes(&sig, int(rawSignatureLen)) {
return nil, errors.New("tls: Delegated Credential is not valid")
}
return &DelegatedCredential{
cred: credential,
algorithm: SignatureScheme(algo),
signature: sig,
}, nil
}

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// Copyright 2020 Cloudflare, Inc. All rights reserved. Use of this source code
// is governed by a BSD-style license that can be found in the LICENSE file.
package tls
import (
"errors"
"fmt"
"io"
"github.com/cloudflare/circl/hpke"
"github.com/cloudflare/circl/kem"
"golang.org/x/crypto/cryptobyte"
)
// ECHConfig represents an ECH configuration.
type ECHConfig struct {
pk kem.PublicKey
raw []byte
// Parsed from raw
version uint16
configId uint8
rawPublicName []byte
rawPublicKey []byte
kemId uint16
suites []hpkeSymmetricCipherSuite
maxNameLen uint8
ignoredExtensions []byte
}
// UnmarshalECHConfigs parses a sequence of ECH configurations.
func UnmarshalECHConfigs(raw []byte) ([]ECHConfig, error) {
var (
err error
config ECHConfig
t, contents cryptobyte.String
)
configs := make([]ECHConfig, 0)
s := cryptobyte.String(raw)
if !s.ReadUint16LengthPrefixed(&t) || !s.Empty() {
return configs, errors.New("error parsing configs")
}
raw = raw[2:]
ConfigsLoop:
for !t.Empty() {
l := len(t)
if !t.ReadUint16(&config.version) ||
!t.ReadUint16LengthPrefixed(&contents) {
return nil, errors.New("error parsing config")
}
n := l - len(t)
config.raw = raw[:n]
raw = raw[n:]
if config.version != extensionECH {
continue ConfigsLoop
}
if !readConfigContents(&contents, &config) {
return nil, errors.New("error parsing config contents")
}
kem := hpke.KEM(config.kemId)
if !kem.IsValid() {
continue ConfigsLoop
}
config.pk, err = kem.Scheme().UnmarshalBinaryPublicKey(config.rawPublicKey)
if err != nil {
return nil, fmt.Errorf("error parsing public key: %s", err)
}
configs = append(configs, config)
}
return configs, nil
}
func echMarshalConfigs(configs []ECHConfig) ([]byte, error) {
var b cryptobyte.Builder
b.AddUint16LengthPrefixed(func(b *cryptobyte.Builder) {
for _, config := range configs {
if config.raw == nil {
panic("config.raw not set")
}
b.AddBytes(config.raw)
}
})
return b.Bytes()
}
func readConfigContents(contents *cryptobyte.String, config *ECHConfig) bool {
var t cryptobyte.String
if !contents.ReadUint8(&config.configId) ||
!contents.ReadUint16(&config.kemId) ||
!contents.ReadUint16LengthPrefixed(&t) ||
!t.ReadBytes(&config.rawPublicKey, len(t)) ||
!contents.ReadUint16LengthPrefixed(&t) ||
len(t)%4 != 0 {
return false
}
config.suites = nil
for !t.Empty() {
var kdfId, aeadId uint16
if !t.ReadUint16(&kdfId) || !t.ReadUint16(&aeadId) {
// This indicates an internal bug.
panic("internal error while parsing contents.cipher_suites")
}
config.suites = append(config.suites, hpkeSymmetricCipherSuite{kdfId, aeadId})
}
if !contents.ReadUint8(&config.maxNameLen) ||
!contents.ReadUint8LengthPrefixed(&t) ||
!t.ReadBytes(&config.rawPublicName, len(t)) ||
!contents.ReadUint16LengthPrefixed(&t) ||
!t.ReadBytes(&config.ignoredExtensions, len(t)) ||
!contents.Empty() {
return false
}
return true
}
// setupSealer generates the client's HPKE context for use with the ECH
// extension. It returns the context and corresponding encapsulated key.
func (config *ECHConfig) setupSealer(rand io.Reader) (enc []byte, sealer hpke.Sealer, err error) {
if config.raw == nil {
panic("config.raw not set")
}
hpkeSuite, err := config.selectSuite()
if err != nil {
return nil, nil, err
}
info := append(append([]byte(echHpkeInfoSetup), 0), config.raw...)
sender, err := hpkeSuite.NewSender(config.pk, info)
if err != nil {
return nil, nil, err
}
return sender.Setup(rand)
}
// isPeerCipherSuiteSupported returns true if this configuration indicates
// support for the given ciphersuite.
func (config *ECHConfig) isPeerCipherSuiteSupported(suite hpkeSymmetricCipherSuite) bool {
for _, configSuite := range config.suites {
if suite == configSuite {
return true
}
}
return false
}
// selectSuite returns the first ciphersuite indicated by this
// configuration that is supported by the caller.
func (config *ECHConfig) selectSuite() (hpke.Suite, error) {
for _, suite := range config.suites {
hpkeSuite, err := hpkeAssembleSuite(
config.kemId,
suite.kdfId,
suite.aeadId,
)
if err == nil {
return hpkeSuite, nil
}
}
return hpke.Suite{}, errors.New("could not negotiate a ciphersuite")
}

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// Copyright 2020 Cloudflare, Inc. All rights reserved. Use of this source code
// is governed by a BSD-style license that can be found in the LICENSE file.
package tls
import (
"errors"
"fmt"
"github.com/cloudflare/circl/hpke"
"github.com/cloudflare/circl/kem"
"golang.org/x/crypto/cryptobyte"
)
// ECHProvider specifies the interface of an ECH service provider that decrypts
// the ECH payload on behalf of the client-facing server. It also defines the
// set of acceptable ECH configurations.
type ECHProvider interface {
// GetDecryptionContext attempts to construct the HPKE context used by the
// client-facing server for decryption. (See draft-irtf-cfrg-hpke-07,
// Section 5.2.)
//
// handle encodes the parameters of the client's "encrypted_client_hello"
// extension that are needed to construct the context. Since
// draft-ietf-tls-esni-10 these are the ECH cipher suite, the identity of
// the ECH configuration, and the encapsulated key.
//
// version is the version of ECH indicated by the client.
//
// res.Status == ECHProviderStatusSuccess indicates the call was successful
// and the caller may proceed. res.Context is set.
//
// res.Status == ECHProviderStatusReject indicates the caller must reject
// ECH. res.RetryConfigs may be set.
//
// res.Status == ECHProviderStatusAbort indicates the caller should abort
// the handshake. Note that, in some cases, it's appropriate to reject
// rather than abort. In particular, aborting with "illegal_parameter" might
// "stick out". res.Alert and res.Error are set.
GetDecryptionContext(handle []byte, version uint16) (res ECHProviderResult)
}
// ECHProviderStatus is the status of the ECH provider's response.
type ECHProviderStatus uint
const (
ECHProviderSuccess ECHProviderStatus = 0
ECHProviderReject = 1
ECHProviderAbort = 2
errHPKEInvalidPublicKey = "hpke: invalid KEM public key"
)
// ECHProviderResult represents the result of invoking the ECH provider.
type ECHProviderResult struct {
Status ECHProviderStatus
// Alert is the TLS alert sent by the caller when aborting the handshake.
Alert uint8
// Error is the error propagated by the caller when aborting the handshake.
Error error
// RetryConfigs is the sequence of ECH configs to offer to the client for
// retrying the handshake. This may be set in case of success or rejection.
RetryConfigs []byte
// Context is the server's HPKE context. This is set if ECH is not rejected
// by the provider and no error was reported. The data has the following
// format (in TLS syntax):
//
// enum { sealer(0), opener(1) } HpkeRole;
//
// struct {
// HpkeRole role;
// HpkeKemId kem_id; // as defined in draft-irtf-cfrg-hpke-07
// HpkeKdfId kdf_id; // as defined in draft-irtf-cfrg-hpke-07
// HpkeAeadId aead_id; // as defined in draft-irtf-cfrg-hpke-07
// opaque exporter_secret<0..255>;
// opaque key<0..255>;
// opaque base_nonce<0..255>;
// opaque seq<0..255>;
// } HpkeContext;
Context []byte
}
// EXP_ECHKeySet implements the ECHProvider interface for a sequence of ECH keys.
//
// NOTE: This API is EXPERIMENTAL and subject to change.
type EXP_ECHKeySet struct {
// The serialized ECHConfigs, in order of the server's preference.
configs []byte
// Maps a configuration identifier to its secret key.
sk map[uint8]EXP_ECHKey
}
// EXP_NewECHKeySet constructs an EXP_ECHKeySet.
func EXP_NewECHKeySet(keys []EXP_ECHKey) (*EXP_ECHKeySet, error) {
if len(keys) > 255 {
return nil, fmt.Errorf("tls: ech provider: unable to support more than 255 ECH configurations at once")
}
keySet := new(EXP_ECHKeySet)
keySet.sk = make(map[uint8]EXP_ECHKey)
configs := make([]byte, 0)
for _, key := range keys {
if _, ok := keySet.sk[key.config.configId]; ok {
return nil, fmt.Errorf("tls: ech provider: ECH config conflict for configId %d", key.config.configId)
}
keySet.sk[key.config.configId] = key
configs = append(configs, key.config.raw...)
}
var b cryptobyte.Builder
b.AddUint16LengthPrefixed(func(b *cryptobyte.Builder) {
b.AddBytes(configs)
})
keySet.configs = b.BytesOrPanic()
return keySet, nil
}
// GetDecryptionContext is required by the ECHProvider interface.
func (keySet *EXP_ECHKeySet) GetDecryptionContext(rawHandle []byte, version uint16) (res ECHProviderResult) {
// Propagate retry configurations regardless of the result. The caller sends
// these to the clients only if it rejects.
res.RetryConfigs = keySet.configs
// Ensure we know how to proceed, i.e., the caller has indicated a supported
// version of ECH. Currently only draft-ietf-tls-esni-13 is supported.
if version != extensionECH {
res.Status = ECHProviderAbort
res.Alert = uint8(alertInternalError)
res.Error = errors.New("version not supported")
return // Abort
}
// Parse the handle.
s := cryptobyte.String(rawHandle)
handle := new(echContextHandle)
if !echReadContextHandle(&s, handle) || !s.Empty() {
// This is the result of a client-side error. However, aborting with
// "illegal_parameter" would stick out, so we reject instead.
res.Status = ECHProviderReject
res.RetryConfigs = keySet.configs
return // Reject
}
handle.raw = rawHandle
// Look up the secret key for the configuration indicated by the client.
key, ok := keySet.sk[handle.configId]
if !ok {
res.Status = ECHProviderReject
res.RetryConfigs = keySet.configs
return // Reject
}
// Ensure that support for the selected ciphersuite is indicated by the
// configuration.
suite := handle.suite
if !key.config.isPeerCipherSuiteSupported(suite) {
// This is the result of a client-side error. However, aborting with
// "illegal_parameter" would stick out, so we reject instead.
res.Status = ECHProviderReject
res.RetryConfigs = keySet.configs
return // Reject
}
// Ensure the version indicated by the client matches the version supported
// by the configuration.
if version != key.config.version {
// This is the result of a client-side error. However, aborting with
// "illegal_parameter" would stick out, so we reject instead.
res.Status = ECHProviderReject
res.RetryConfigs = keySet.configs
return // Reject
}
// Compute the decryption context.
opener, err := key.setupOpener(handle.enc, suite)
if err != nil {
if err.Error() == errHPKEInvalidPublicKey {
// This occurs if the KEM algorithm used to generate handle.enc is
// not the same as the KEM algorithm of the key. One way this can
// happen is if the client sent a GREASE ECH extension with a
// config_id that happens to match a known config, but which uses a
// different KEM algorithm.
res.Status = ECHProviderReject
res.RetryConfigs = keySet.configs
return // Reject
}
res.Status = ECHProviderAbort
res.Alert = uint8(alertInternalError)
res.Error = err
return // Abort
}
// Serialize the decryption context.
res.Context, err = opener.MarshalBinary()
if err != nil {
res.Status = ECHProviderAbort
res.Alert = uint8(alertInternalError)
res.Error = err
return // Abort
}
res.Status = ECHProviderSuccess
return // Success
}
// EXP_ECHKey represents an ECH key and its corresponding configuration. The
// encoding of an ECH Key has the format defined below (in TLS syntax). Note
// that the ECH standard does not specify this format.
//
// struct {
// opaque sk<0..2^16-1>;
// ECHConfig config<0..2^16>; // draft-ietf-tls-esni-13
// } ECHKey;
type EXP_ECHKey struct {
sk kem.PrivateKey
config ECHConfig
}
// EXP_UnmarshalECHKeys parses a sequence of ECH keys.
func EXP_UnmarshalECHKeys(raw []byte) ([]EXP_ECHKey, error) {
var (
err error
key EXP_ECHKey
sk, config, contents cryptobyte.String
)
s := cryptobyte.String(raw)
keys := make([]EXP_ECHKey, 0)
KeysLoop:
for !s.Empty() {
if !s.ReadUint16LengthPrefixed(&sk) ||
!s.ReadUint16LengthPrefixed(&config) {
return nil, errors.New("error parsing key")
}
key.config.raw = config
if !config.ReadUint16(&key.config.version) ||
!config.ReadUint16LengthPrefixed(&contents) ||
!config.Empty() {
return nil, errors.New("error parsing config")
}
if key.config.version != extensionECH {
continue KeysLoop
}
if !readConfigContents(&contents, &key.config) {
return nil, errors.New("error parsing config contents")
}
for _, suite := range key.config.suites {
if !hpke.KDF(suite.kdfId).IsValid() ||
!hpke.AEAD(suite.aeadId).IsValid() {
continue KeysLoop
}
}
kem := hpke.KEM(key.config.kemId)
if !kem.IsValid() {
continue KeysLoop
}
key.config.pk, err = kem.Scheme().UnmarshalBinaryPublicKey(key.config.rawPublicKey)
if err != nil {
return nil, fmt.Errorf("error parsing public key: %s", err)
}
key.sk, err = kem.Scheme().UnmarshalBinaryPrivateKey(sk)
if err != nil {
return nil, fmt.Errorf("error parsing secret key: %s", err)
}
keys = append(keys, key)
}
return keys, nil
}
// setupOpener computes the HPKE context used by the server in the ECH
// extension.i
func (key *EXP_ECHKey) setupOpener(enc []byte, suite hpkeSymmetricCipherSuite) (hpke.Opener, error) {
if key.config.raw == nil {
panic("raw config not set")
}
hpkeSuite, err := hpkeAssembleSuite(
key.config.kemId,
suite.kdfId,
suite.aeadId,
)
if err != nil {
return nil, err
}
info := append(append([]byte(echHpkeInfoSetup), 0), key.config.raw...)
receiver, err := hpkeSuite.NewReceiver(key.sk, info)
if err != nil {
return nil, err
}
return receiver.Setup(enc)
}

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// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:build ignore
// Generate a self-signed X.509 certificate for a TLS server. Outputs to
// 'cert.pem' and 'key.pem' and will overwrite existing files.
package main
import (
"crypto/ecdsa"
"crypto/ed25519"
"crypto/elliptic"
"crypto/rand"
"crypto/rsa"
"crypto/x509"
"crypto/x509/pkix"
"encoding/pem"
"flag"
"log"
"math/big"
"net"
"os"
"strings"
"time"
circlSign "github.com/cloudflare/circl/sign"
circlSchemes "github.com/cloudflare/circl/sign/schemes"
)
var (
host = flag.String("host", "", "Comma-separated hostnames and IPs to generate a certificate for")
validFrom = flag.String("start-date", "", "Creation date formatted as Jan 1 15:04:05 2011")
validFor = flag.Duration("duration", 365*24*time.Hour, "Duration that certificate is valid for")
isCA = flag.Bool("ca", false, "whether this cert should be its own Certificate Authority")
allowDC = flag.Bool("allowDC", false, "whether this cert can be used with Delegated Credentials")
rsaBits = flag.Int("rsa-bits", 2048, "Size of RSA key to generate. Ignored if --ecdsa-curve is set")
ecdsaCurve = flag.String("ecdsa-curve", "", "ECDSA curve to use to generate a key. Valid values are P224, P256 (recommended), P384, P521")
ed25519Key = flag.Bool("ed25519", false, "Generate an Ed25519 key")
circlKey = flag.String("github.com/cloudflare/circl", "", "Generate a key supported by Circl")
)
func publicKey(priv any) any {
switch k := priv.(type) {
case *rsa.PrivateKey:
return &k.PublicKey
case *ecdsa.PrivateKey:
return &k.PublicKey
case ed25519.PrivateKey:
return k.Public().(ed25519.PublicKey)
case circlSign.PrivateKey:
return k.Public()
default:
return nil
}
}
func main() {
flag.Parse()
if len(*host) == 0 {
log.Fatalf("Missing required --host parameter")
}
var priv any
var err error
switch *ecdsaCurve {
case "":
if *ed25519Key {
_, priv, err = ed25519.GenerateKey(rand.Reader)
} else if *circlKey != "" {
scheme := circlSchemes.ByName(*circlKey)
if scheme == nil {
log.Fatalf("No such Circl scheme: %s", *circlKey)
}
_, priv, err = scheme.GenerateKey()
} else {
priv, err = rsa.GenerateKey(rand.Reader, *rsaBits)
}
case "P224":
priv, err = ecdsa.GenerateKey(elliptic.P224(), rand.Reader)
case "P256":
priv, err = ecdsa.GenerateKey(elliptic.P256(), rand.Reader)
case "P384":
priv, err = ecdsa.GenerateKey(elliptic.P384(), rand.Reader)
case "P521":
priv, err = ecdsa.GenerateKey(elliptic.P521(), rand.Reader)
default:
log.Fatalf("Unrecognized elliptic curve: %q", *ecdsaCurve)
}
if err != nil {
log.Fatalf("Failed to generate private key: %v", err)
}
// ECDSA, ED25519 and RSA subject keys should have the DigitalSignature
// KeyUsage bits set in the x509.Certificate template
keyUsage := x509.KeyUsageDigitalSignature
// Only RSA subject keys should have the KeyEncipherment KeyUsage bits set. In
// the context of TLS this KeyUsage is particular to RSA key exchange and
// authentication.
if _, isRSA := priv.(*rsa.PrivateKey); isRSA {
keyUsage |= x509.KeyUsageKeyEncipherment
}
var notBefore time.Time
if len(*validFrom) == 0 {
notBefore = time.Now()
} else {
notBefore, err = time.Parse("Jan 2 15:04:05 2006", *validFrom)
if err != nil {
log.Fatalf("Failed to parse creation date: %v", err)
}
}
notAfter := notBefore.Add(*validFor)
serialNumberLimit := new(big.Int).Lsh(big.NewInt(1), 128)
serialNumber, err := rand.Int(rand.Reader, serialNumberLimit)
if err != nil {
log.Fatalf("Failed to generate serial number: %v", err)
}
template := x509.Certificate{
SerialNumber: serialNumber,
Subject: pkix.Name{
Organization: []string{"Acme Co"},
},
NotBefore: notBefore,
NotAfter: notAfter,
KeyUsage: keyUsage,
ExtKeyUsage: []x509.ExtKeyUsage{x509.ExtKeyUsageServerAuth},
BasicConstraintsValid: true,
}
hosts := strings.Split(*host, ",")
for _, h := range hosts {
if ip := net.ParseIP(h); ip != nil {
template.IPAddresses = append(template.IPAddresses, ip)
} else {
template.DNSNames = append(template.DNSNames, h)
}
}
if *isCA {
if *allowDC {
log.Fatal("Failed to create certificate: ca is not allowed with the dc flag")
}
template.IsCA = true
template.KeyUsage |= x509.KeyUsageCertSign
}
if *allowDC {
template.AllowDC = true
template.KeyUsage |= x509.KeyUsageDigitalSignature
}
derBytes, err := x509.CreateCertificate(rand.Reader, &template, &template, publicKey(priv), priv)
if err != nil {
log.Fatalf("Failed to create certificate: %v", err)
}
certOut, err := os.Create("cert.pem")
if err != nil {
log.Fatalf("Failed to open cert.pem for writing: %v", err)
}
if err := pem.Encode(certOut, &pem.Block{Type: "CERTIFICATE", Bytes: derBytes}); err != nil {
log.Fatalf("Failed to write data to cert.pem: %v", err)
}
if err := certOut.Close(); err != nil {
log.Fatalf("Error closing cert.pem: %v", err)
}
log.Print("wrote cert.pem\n")
keyOut, err := os.OpenFile("key.pem", os.O_WRONLY|os.O_CREATE|os.O_TRUNC, 0o600)
if err != nil {
log.Fatalf("Failed to open key.pem for writing: %v", err)
return
}
privBytes, err := x509.MarshalPKCS8PrivateKey(priv)
if err != nil {
log.Fatalf("Unable to marshal private key: %v", err)
}
if err := pem.Encode(keyOut, &pem.Block{Type: "PRIVATE KEY", Bytes: privBytes}); err != nil {
log.Fatalf("Failed to write data to key.pem: %v", err)
}
if err := keyOut.Close(); err != nil {
log.Fatalf("Error closing key.pem: %v", err)
}
log.Print("wrote key.pem\n")
}

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// Copyright 2022 Cloudflare, Inc. All rights reserved. Use of this source code
// is governed by a BSD-style license that can be found in the LICENSE file.
//go:build ignore
// Generate a delegated credential with the given signature scheme, signed with
// the given x.509 key pair. Outputs to 'dc.cred' and 'dckey.pem' and will
// overwrite existing files.
// Example usage:
// generate_delegated_credential -cert-path cert.pem -key-path key.pem -signature-scheme Ed25519 -duration 24h
package main
import (
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/rsa"
"crypto/tls"
"crypto/x509"
"encoding/pem"
"errors"
"flag"
"fmt"
"log"
"os"
"path/filepath"
"time"
circlSign "github.com/cloudflare/circl/sign"
)
var (
validFor = flag.Duration("duration", 5*24*time.Hour, "Duration that credential is valid for")
signatureScheme = flag.String("signature-scheme", "", "The signature scheme used by the DC")
certPath = flag.String("cert-path", "./cert.pem", "Path to signing cert")
keyPath = flag.String("key-path", "./key.pem", "Path to signing key")
isClient = flag.Bool("client-dc", false, "Create a client Delegated Credential")
outPath = flag.String("out-path", "./", "Path to output directory")
)
var SigStringMap = map[string]tls.SignatureScheme{
// ECDSA algorithms. Only constrained to a specific curve in TLS 1.3.
"ECDSAWithP256AndSHA256": tls.ECDSAWithP256AndSHA256,
"ECDSAWithP384AndSHA384": tls.ECDSAWithP384AndSHA384,
"ECDSAWithP521AndSHA512": tls.ECDSAWithP521AndSHA512,
// EdDSA algorithms.
"Ed25519": tls.Ed25519,
}
func main() {
flag.Parse()
sa := SigStringMap[*signatureScheme]
cert, err := tls.LoadX509KeyPair(*certPath, *keyPath)
if err != nil {
log.Fatalf("Failed to load certificate and key: %v", err)
}
cert.Leaf, err = x509.ParseCertificate(cert.Certificate[0])
if err != nil {
log.Fatalf("Failed to parse leaf certificate: %v", err)
}
validTime := time.Since(cert.Leaf.NotBefore) + *validFor
dc, priv, err := tls.NewDelegatedCredential(&cert, sa, validTime, *isClient)
if err != nil {
log.Fatalf("Failed to create a DC: %v\n", err)
}
dcBytes, err := dc.Marshal()
if err != nil {
log.Fatalf("Failed to marshal DC: %v\n", err)
}
DCOut, err := os.Create(filepath.Join(*outPath, "dc.cred"))
if err != nil {
log.Fatalf("Failed to open dc.cred for writing: %v", err)
}
DCOut.Write(dcBytes)
if err := DCOut.Close(); err != nil {
log.Fatalf("Error closing dc.cred: %v", err)
}
log.Print("wrote dc.cred\n")
derBytes, err := x509.MarshalPKCS8PrivateKey(priv)
if err != nil {
log.Fatalf("Failed to marshal DC private key: %v\n", err)
}
DCKeyOut, err := os.Create(filepath.Join(*outPath, "dckey.pem"))
if err != nil {
log.Fatalf("Failed to open dckey.pem for writing: %v", err)
}
if err := pem.Encode(DCKeyOut, &pem.Block{Type: "PRIVATE KEY", Bytes: derBytes}); err != nil {
log.Fatalf("Failed to write data to dckey.pem: %v\n", err)
}
if err := DCKeyOut.Close(); err != nil {
log.Fatalf("Error closing dckey.pem: %v\n", err)
}
log.Print("wrote dckey.pem\n")
fmt.Println("Success")
}
// Copied from tls.go, because it's private.
func parsePrivateKey(der []byte) (crypto.PrivateKey, error) {
if key, err := x509.ParsePKCS1PrivateKey(der); err == nil {
return key, nil
}
if key, err := x509.ParsePKCS8PrivateKey(der); err == nil {
switch key := key.(type) {
case *rsa.PrivateKey, *ecdsa.PrivateKey, ed25519.PrivateKey, circlSign.PrivateKey:
return key, nil
default:
return nil, errors.New("tls: found unknown private key type in PKCS#8 wrapping")
}
}
if key, err := x509.ParseECPrivateKey(der); err == nil {
return key, nil
}
return nil, errors.New("tls: failed to parse private key")
}

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// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import (
"context"
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/rsa"
"crypto/subtle"
"crypto/x509"
"errors"
"fmt"
"hash"
"io"
"sync/atomic"
"time"
circlSign "github.com/cloudflare/circl/sign"
)
// serverHandshakeState contains details of a server handshake in progress.
// It's discarded once the handshake has completed.
type serverHandshakeState struct {
c *Conn
ctx context.Context
clientHello *clientHelloMsg
hello *serverHelloMsg
suite *cipherSuite
ecdheOk bool
ecSignOk bool
rsaDecryptOk bool
rsaSignOk bool
sessionState *sessionState
finishedHash finishedHash
masterSecret []byte
cert *Certificate
}
// serverHandshake performs a TLS handshake as a server.
func (c *Conn) serverHandshake(ctx context.Context) error {
clientHello, err := c.readClientHello(ctx)
if err != nil {
return err
}
if c.vers == VersionTLS13 {
hs := serverHandshakeStateTLS13{
c: c,
ctx: ctx,
clientHello: clientHello,
hsTimings: createTLS13ServerHandshakeTimingInfo(c.config.Time),
}
return hs.handshake()
}
hs := serverHandshakeState{
c: c,
ctx: ctx,
clientHello: clientHello,
}
return hs.handshake()
}
func (hs *serverHandshakeState) handshake() error {
c := hs.c
if err := hs.processClientHello(); err != nil {
return err
}
// For an overview of TLS handshaking, see RFC 5246, Section 7.3.
c.buffering = true
if hs.checkForResumption() {
// The client has included a session ticket and so we do an abbreviated handshake.
c.didResume = true
if err := hs.doResumeHandshake(); err != nil {
return err
}
if err := hs.establishKeys(); err != nil {
return err
}
if err := hs.sendSessionTicket(); err != nil {
return err
}
if err := hs.sendFinished(c.serverFinished[:]); err != nil {
return err
}
if _, err := c.flush(); err != nil {
return err
}
c.clientFinishedIsFirst = false
if err := hs.readFinished(nil); err != nil {
return err
}
} else {
// The client didn't include a session ticket, or it wasn't
// valid so we do a full handshake.
if err := hs.pickCipherSuite(); err != nil {
return err
}
if err := hs.doFullHandshake(); err != nil {
return err
}
if err := hs.establishKeys(); err != nil {
return err
}
if err := hs.readFinished(c.clientFinished[:]); err != nil {
return err
}
c.clientFinishedIsFirst = true
c.buffering = true
if err := hs.sendSessionTicket(); err != nil {
return err
}
if err := hs.sendFinished(nil); err != nil {
return err
}
if _, err := c.flush(); err != nil {
return err
}
}
c.ekm = ekmFromMasterSecret(c.vers, hs.suite, hs.masterSecret, hs.clientHello.random, hs.hello.random)
atomic.StoreUint32(&c.handshakeStatus, 1)
return nil
}
// readClientHello reads a ClientHello message and selects the protocol version.
func (c *Conn) readClientHello(ctx context.Context) (*clientHelloMsg, error) {
msg, err := c.readHandshake()
if err != nil {
return nil, err
}
clientHello, ok := msg.(*clientHelloMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return nil, unexpectedMessageError(clientHello, msg)
}
// NOTE(cjpatton): ECH usage is resolved before calling GetConfigForClient()
// or GetCertifciate(). Hence, it is not currently possible to reject ECH if
// we don't recognize the inner SNI. This may or may not be desirable in the
// future.
clientHello, err = c.echAcceptOrReject(clientHello, false) // afterHRR == false
if err != nil {
return nil, fmt.Errorf("tls: %s", err) // Alert sent.
}
var configForClient *Config
originalConfig := c.config
if c.config.GetConfigForClient != nil {
chi := clientHelloInfo(ctx, c, clientHello)
if configForClient, err = c.config.GetConfigForClient(chi); err != nil {
c.sendAlert(alertInternalError)
return nil, err
} else if configForClient != nil {
c.config = configForClient
}
}
c.ticketKeys = originalConfig.ticketKeys(configForClient)
clientVersions := clientHello.supportedVersions
if len(clientHello.supportedVersions) == 0 {
clientVersions = supportedVersionsFromMax(clientHello.vers)
}
c.vers, ok = c.config.mutualVersion(roleServer, clientVersions)
if !ok {
c.sendAlert(alertProtocolVersion)
return nil, fmt.Errorf("tls: client offered only unsupported versions: %x", clientVersions)
}
c.haveVers = true
c.in.version = c.vers
c.out.version = c.vers
return clientHello, nil
}
func (hs *serverHandshakeState) processClientHello() error {
c := hs.c
hs.hello = new(serverHelloMsg)
hs.hello.vers = c.vers
foundCompression := false
// We only support null compression, so check that the client offered it.
for _, compression := range hs.clientHello.compressionMethods {
if compression == compressionNone {
foundCompression = true
break
}
}
if !foundCompression {
c.sendAlert(alertHandshakeFailure)
return errors.New("tls: client does not support uncompressed connections")
}
hs.hello.random = make([]byte, 32)
serverRandom := hs.hello.random
// Downgrade protection canaries. See RFC 8446, Section 4.1.3.
maxVers := c.config.maxSupportedVersion(roleServer)
if maxVers >= VersionTLS12 && c.vers < maxVers || testingOnlyForceDowngradeCanary {
if c.vers == VersionTLS12 {
copy(serverRandom[24:], downgradeCanaryTLS12)
} else {
copy(serverRandom[24:], downgradeCanaryTLS11)
}
serverRandom = serverRandom[:24]
}
_, err := io.ReadFull(c.config.rand(), serverRandom)
if err != nil {
c.sendAlert(alertInternalError)
return err
}
if len(hs.clientHello.secureRenegotiation) != 0 {
c.sendAlert(alertHandshakeFailure)
return errors.New("tls: initial handshake had non-empty renegotiation extension")
}
hs.hello.secureRenegotiationSupported = hs.clientHello.secureRenegotiationSupported
hs.hello.compressionMethod = compressionNone
if len(hs.clientHello.serverName) > 0 {
c.serverName = hs.clientHello.serverName
}
selectedProto, err := negotiateALPN(c.config.NextProtos, hs.clientHello.alpnProtocols)
if err != nil {
c.sendAlert(alertNoApplicationProtocol)
return err
}
hs.hello.alpnProtocol = selectedProto
c.clientProtocol = selectedProto
hs.cert, err = c.config.getCertificate(clientHelloInfo(hs.ctx, c, hs.clientHello))
if err != nil {
if err == errNoCertificates {
c.sendAlert(alertUnrecognizedName)
} else {
c.sendAlert(alertInternalError)
}
return err
}
if hs.clientHello.scts {
hs.hello.scts = hs.cert.SignedCertificateTimestamps
}
hs.ecdheOk = supportsECDHE(c.config, hs.clientHello.supportedCurves, hs.clientHello.supportedPoints)
if hs.ecdheOk {
// Although omitting the ec_point_formats extension is permitted, some
// old OpenSSL version will refuse to handshake if not present.
//
// Per RFC 4492, section 5.1.2, implementations MUST support the
// uncompressed point format. See golang.org/issue/31943.
hs.hello.supportedPoints = []uint8{pointFormatUncompressed}
}
if priv, ok := hs.cert.PrivateKey.(crypto.Signer); ok {
switch priv.Public().(type) {
case *ecdsa.PublicKey:
hs.ecSignOk = true
case ed25519.PublicKey:
hs.ecSignOk = true
case *rsa.PublicKey:
hs.rsaSignOk = true
default:
c.sendAlert(alertInternalError)
return fmt.Errorf("tls: unsupported signing key type (%T)", priv.Public())
}
}
if priv, ok := hs.cert.PrivateKey.(crypto.Decrypter); ok {
switch priv.Public().(type) {
case *rsa.PublicKey:
hs.rsaDecryptOk = true
default:
c.sendAlert(alertInternalError)
return fmt.Errorf("tls: unsupported decryption key type (%T)", priv.Public())
}
}
return nil
}
// negotiateALPN picks a shared ALPN protocol that both sides support in server
// preference order. If ALPN is not configured or the peer doesn't support it,
// it returns "" and no error.
func negotiateALPN(serverProtos, clientProtos []string) (string, error) {
if len(serverProtos) == 0 || len(clientProtos) == 0 {
return "", nil
}
var http11fallback bool
for _, s := range serverProtos {
for _, c := range clientProtos {
if s == c {
return s, nil
}
if s == "h2" && c == "http/1.1" {
http11fallback = true
}
}
}
// As a special case, let http/1.1 clients connect to h2 servers as if they
// didn't support ALPN. We used not to enforce protocol overlap, so over
// time a number of HTTP servers were configured with only "h2", but
// expected to accept connections from "http/1.1" clients. See Issue 46310.
if http11fallback {
return "", nil
}
return "", fmt.Errorf("tls: client requested unsupported application protocols (%s)", clientProtos)
}
// supportsECDHE returns whether ECDHE key exchanges can be used with this
// pre-TLS 1.3 client.
func supportsECDHE(c *Config, supportedCurves []CurveID, supportedPoints []uint8) bool {
supportsCurve := false
for _, curve := range supportedCurves {
if c.supportsCurve(curve) {
supportsCurve = true
break
}
}
supportsPointFormat := false
for _, pointFormat := range supportedPoints {
if pointFormat == pointFormatUncompressed {
supportsPointFormat = true
break
}
}
return supportsCurve && supportsPointFormat
}
func (hs *serverHandshakeState) pickCipherSuite() error {
c := hs.c
preferenceOrder := cipherSuitesPreferenceOrder
if !hasAESGCMHardwareSupport || !aesgcmPreferred(hs.clientHello.cipherSuites) {
preferenceOrder = cipherSuitesPreferenceOrderNoAES
}
configCipherSuites := c.config.cipherSuites()
preferenceList := make([]uint16, 0, len(configCipherSuites))
for _, suiteID := range preferenceOrder {
for _, id := range configCipherSuites {
if id == suiteID {
preferenceList = append(preferenceList, id)
break
}
}
}
hs.suite = selectCipherSuite(preferenceList, hs.clientHello.cipherSuites, hs.cipherSuiteOk)
if hs.suite == nil {
c.sendAlert(alertHandshakeFailure)
return errors.New("tls: no cipher suite supported by both client and server")
}
c.cipherSuite = hs.suite.id
for _, id := range hs.clientHello.cipherSuites {
if id == TLS_FALLBACK_SCSV {
// The client is doing a fallback connection. See RFC 7507.
if hs.clientHello.vers < c.config.maxSupportedVersion(roleServer) {
c.sendAlert(alertInappropriateFallback)
return errors.New("tls: client using inappropriate protocol fallback")
}
break
}
}
return nil
}
func (hs *serverHandshakeState) cipherSuiteOk(c *cipherSuite) bool {
if c.flags&suiteECDHE != 0 {
if !hs.ecdheOk {
return false
}
if c.flags&suiteECSign != 0 {
if !hs.ecSignOk {
return false
}
} else if !hs.rsaSignOk {
return false
}
} else if !hs.rsaDecryptOk {
return false
}
if hs.c.vers < VersionTLS12 && c.flags&suiteTLS12 != 0 {
return false
}
return true
}
// checkForResumption reports whether we should perform resumption on this connection.
func (hs *serverHandshakeState) checkForResumption() bool {
c := hs.c
if c.config.SessionTicketsDisabled || c.config.ECHEnabled {
return false
}
plaintext, usedOldKey := c.decryptTicket(hs.clientHello.sessionTicket)
if plaintext == nil {
return false
}
hs.sessionState = &sessionState{usedOldKey: usedOldKey}
ok := hs.sessionState.unmarshal(plaintext)
if !ok {
return false
}
createdAt := time.Unix(int64(hs.sessionState.createdAt), 0)
if c.config.time().Sub(createdAt) > maxSessionTicketLifetime {
return false
}
// Never resume a session for a different TLS version.
if c.vers != hs.sessionState.vers {
return false
}
cipherSuiteOk := false
// Check that the client is still offering the ciphersuite in the session.
for _, id := range hs.clientHello.cipherSuites {
if id == hs.sessionState.cipherSuite {
cipherSuiteOk = true
break
}
}
if !cipherSuiteOk {
return false
}
// Check that we also support the ciphersuite from the session.
hs.suite = selectCipherSuite([]uint16{hs.sessionState.cipherSuite},
c.config.cipherSuites(), hs.cipherSuiteOk)
if hs.suite == nil {
return false
}
sessionHasClientCerts := len(hs.sessionState.certificates) != 0
needClientCerts := requiresClientCert(c.config.ClientAuth)
if needClientCerts && !sessionHasClientCerts {
return false
}
if sessionHasClientCerts && c.config.ClientAuth == NoClientCert {
return false
}
return true
}
func (hs *serverHandshakeState) doResumeHandshake() error {
c := hs.c
hs.hello.cipherSuite = hs.suite.id
c.cipherSuite = hs.suite.id
// We echo the client's session ID in the ServerHello to let it know
// that we're doing a resumption.
hs.hello.sessionId = hs.clientHello.sessionId
hs.hello.ticketSupported = hs.sessionState.usedOldKey
hs.finishedHash = newFinishedHash(c.vers, hs.suite)
hs.finishedHash.discardHandshakeBuffer()
hs.finishedHash.Write(hs.clientHello.marshal())
hs.finishedHash.Write(hs.hello.marshal())
if _, err := c.writeRecord(recordTypeHandshake, hs.hello.marshal()); err != nil {
return err
}
if err := c.processCertsFromClient(Certificate{
Certificate: hs.sessionState.certificates,
}); err != nil {
return err
}
if c.config.VerifyConnection != nil {
if err := c.config.VerifyConnection(c.connectionStateLocked()); err != nil {
c.sendAlert(alertBadCertificate)
return err
}
}
hs.masterSecret = hs.sessionState.masterSecret
return nil
}
func (hs *serverHandshakeState) doFullHandshake() error {
c := hs.c
if hs.clientHello.ocspStapling && len(hs.cert.OCSPStaple) > 0 {
hs.hello.ocspStapling = true
}
hs.hello.ticketSupported = hs.clientHello.ticketSupported && !c.config.SessionTicketsDisabled && !c.config.ECHEnabled
hs.hello.cipherSuite = hs.suite.id
hs.finishedHash = newFinishedHash(hs.c.vers, hs.suite)
if c.config.ClientAuth == NoClientCert {
// No need to keep a full record of the handshake if client
// certificates won't be used.
hs.finishedHash.discardHandshakeBuffer()
}
hs.finishedHash.Write(hs.clientHello.marshal())
hs.finishedHash.Write(hs.hello.marshal())
if _, err := c.writeRecord(recordTypeHandshake, hs.hello.marshal()); err != nil {
return err
}
certMsg := new(certificateMsg)
certMsg.certificates = hs.cert.Certificate
hs.finishedHash.Write(certMsg.marshal())
if _, err := c.writeRecord(recordTypeHandshake, certMsg.marshal()); err != nil {
return err
}
if hs.hello.ocspStapling {
certStatus := new(certificateStatusMsg)
certStatus.response = hs.cert.OCSPStaple
hs.finishedHash.Write(certStatus.marshal())
if _, err := c.writeRecord(recordTypeHandshake, certStatus.marshal()); err != nil {
return err
}
}
keyAgreement := hs.suite.ka(c.vers)
skx, err := keyAgreement.generateServerKeyExchange(c.config, hs.cert, hs.clientHello, hs.hello)
if err != nil {
c.sendAlert(alertHandshakeFailure)
return err
}
if skx != nil {
hs.finishedHash.Write(skx.marshal())
if _, err := c.writeRecord(recordTypeHandshake, skx.marshal()); err != nil {
return err
}
}
var certReq *certificateRequestMsg
if c.config.ClientAuth >= RequestClientCert {
// Request a client certificate
certReq = new(certificateRequestMsg)
certReq.certificateTypes = []byte{
byte(certTypeRSASign),
byte(certTypeECDSASign),
}
if c.vers >= VersionTLS12 {
certReq.hasSignatureAlgorithm = true
certReq.supportedSignatureAlgorithms = c.config.supportedSignatureAlgorithms()
}
// An empty list of certificateAuthorities signals to
// the client that it may send any certificate in response
// to our request. When we know the CAs we trust, then
// we can send them down, so that the client can choose
// an appropriate certificate to give to us.
if c.config.ClientCAs != nil {
certReq.certificateAuthorities = c.config.ClientCAs.Subjects()
}
hs.finishedHash.Write(certReq.marshal())
if _, err := c.writeRecord(recordTypeHandshake, certReq.marshal()); err != nil {
return err
}
}
helloDone := new(serverHelloDoneMsg)
hs.finishedHash.Write(helloDone.marshal())
if _, err := c.writeRecord(recordTypeHandshake, helloDone.marshal()); err != nil {
return err
}
if _, err := c.flush(); err != nil {
return err
}
var pub crypto.PublicKey // public key for client auth, if any
msg, err := c.readHandshake()
if err != nil {
return err
}
// If we requested a client certificate, then the client must send a
// certificate message, even if it's empty.
if c.config.ClientAuth >= RequestClientCert {
certMsg, ok := msg.(*certificateMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(certMsg, msg)
}
hs.finishedHash.Write(certMsg.marshal())
if err := c.processCertsFromClient(Certificate{
Certificate: certMsg.certificates,
}); err != nil {
return err
}
if len(certMsg.certificates) != 0 {
pub = c.peerCertificates[0].PublicKey
}
msg, err = c.readHandshake()
if err != nil {
return err
}
}
if c.config.VerifyConnection != nil {
if err := c.config.VerifyConnection(c.connectionStateLocked()); err != nil {
c.sendAlert(alertBadCertificate)
return err
}
}
// Get client key exchange
ckx, ok := msg.(*clientKeyExchangeMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(ckx, msg)
}
hs.finishedHash.Write(ckx.marshal())
preMasterSecret, err := keyAgreement.processClientKeyExchange(c.config, hs.cert, ckx, c.vers)
if err != nil {
c.sendAlert(alertHandshakeFailure)
return err
}
if eccKex, ok := keyAgreement.(*ecdheKeyAgreement); ok {
c.handleCFEvent(CFEventTLSNegotiatedNamedKEX{
KEX: eccKex.params.CurveID(),
})
}
hs.masterSecret = masterFromPreMasterSecret(c.vers, hs.suite, preMasterSecret, hs.clientHello.random, hs.hello.random)
if err := c.config.writeKeyLog(keyLogLabelTLS12, hs.clientHello.random, hs.masterSecret); err != nil {
c.sendAlert(alertInternalError)
return err
}
// If we received a client cert in response to our certificate request message,
// the client will send us a certificateVerifyMsg immediately after the
// clientKeyExchangeMsg. This message is a digest of all preceding
// handshake-layer messages that is signed using the private key corresponding
// to the client's certificate. This allows us to verify that the client is in
// possession of the private key of the certificate.
if len(c.peerCertificates) > 0 {
msg, err = c.readHandshake()
if err != nil {
return err
}
certVerify, ok := msg.(*certificateVerifyMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(certVerify, msg)
}
var sigType uint8
var sigHash crypto.Hash
if c.vers >= VersionTLS12 {
if !isSupportedSignatureAlgorithm(certVerify.signatureAlgorithm, certReq.supportedSignatureAlgorithms) {
c.sendAlert(alertIllegalParameter)
return errors.New("tls: client certificate used with invalid signature algorithm")
}
sigType, sigHash, err = typeAndHashFromSignatureScheme(certVerify.signatureAlgorithm)
if err != nil {
return c.sendAlert(alertInternalError)
}
} else {
sigType, sigHash, err = legacyTypeAndHashFromPublicKey(pub)
if err != nil {
c.sendAlert(alertIllegalParameter)
return err
}
}
signed := hs.finishedHash.hashForClientCertificate(sigType, sigHash, hs.masterSecret)
if err := verifyHandshakeSignature(sigType, pub, sigHash, signed, certVerify.signature); err != nil {
c.sendAlert(alertDecryptError)
return errors.New("tls: invalid signature by the client certificate: " + err.Error())
}
hs.finishedHash.Write(certVerify.marshal())
}
hs.finishedHash.discardHandshakeBuffer()
return nil
}
func (hs *serverHandshakeState) establishKeys() error {
c := hs.c
clientMAC, serverMAC, clientKey, serverKey, clientIV, serverIV := keysFromMasterSecret(c.vers, hs.suite, hs.masterSecret, hs.clientHello.random, hs.hello.random, hs.suite.macLen, hs.suite.keyLen, hs.suite.ivLen)
var clientCipher, serverCipher any
var clientHash, serverHash hash.Hash
if hs.suite.aead == nil {
clientCipher = hs.suite.cipher(clientKey, clientIV, true /* for reading */)
clientHash = hs.suite.mac(clientMAC)
serverCipher = hs.suite.cipher(serverKey, serverIV, false /* not for reading */)
serverHash = hs.suite.mac(serverMAC)
} else {
clientCipher = hs.suite.aead(clientKey, clientIV)
serverCipher = hs.suite.aead(serverKey, serverIV)
}
c.in.prepareCipherSpec(c.vers, clientCipher, clientHash)
c.out.prepareCipherSpec(c.vers, serverCipher, serverHash)
return nil
}
func (hs *serverHandshakeState) readFinished(out []byte) error {
c := hs.c
if err := c.readChangeCipherSpec(); err != nil {
return err
}
msg, err := c.readHandshake()
if err != nil {
return err
}
clientFinished, ok := msg.(*finishedMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(clientFinished, msg)
}
verify := hs.finishedHash.clientSum(hs.masterSecret)
if len(verify) != len(clientFinished.verifyData) ||
subtle.ConstantTimeCompare(verify, clientFinished.verifyData) != 1 {
c.sendAlert(alertHandshakeFailure)
return errors.New("tls: client's Finished message is incorrect")
}
hs.finishedHash.Write(clientFinished.marshal())
copy(out, verify)
return nil
}
func (hs *serverHandshakeState) sendSessionTicket() error {
// ticketSupported is set in a resumption handshake if the
// ticket from the client was encrypted with an old session
// ticket key and thus a refreshed ticket should be sent.
if !hs.hello.ticketSupported {
return nil
}
c := hs.c
m := new(newSessionTicketMsg)
createdAt := uint64(c.config.time().Unix())
if hs.sessionState != nil {
// If this is re-wrapping an old key, then keep
// the original time it was created.
createdAt = hs.sessionState.createdAt
}
var certsFromClient [][]byte
for _, cert := range c.peerCertificates {
certsFromClient = append(certsFromClient, cert.Raw)
}
state := sessionState{
vers: c.vers,
cipherSuite: hs.suite.id,
createdAt: createdAt,
masterSecret: hs.masterSecret,
certificates: certsFromClient,
}
var err error
m.ticket, err = c.encryptTicket(state.marshal())
if err != nil {
return err
}
hs.finishedHash.Write(m.marshal())
if _, err := c.writeRecord(recordTypeHandshake, m.marshal()); err != nil {
return err
}
return nil
}
func (hs *serverHandshakeState) sendFinished(out []byte) error {
c := hs.c
if _, err := c.writeRecord(recordTypeChangeCipherSpec, []byte{1}); err != nil {
return err
}
finished := new(finishedMsg)
finished.verifyData = hs.finishedHash.serverSum(hs.masterSecret)
hs.finishedHash.Write(finished.marshal())
if _, err := c.writeRecord(recordTypeHandshake, finished.marshal()); err != nil {
return err
}
copy(out, finished.verifyData)
return nil
}
// processCertsFromClient takes a chain of client certificates either from a
// Certificates message or from a sessionState and verifies them. It returns
// the public key of the leaf certificate.
func (c *Conn) processCertsFromClient(certificate Certificate) error {
certificates := certificate.Certificate
certs := make([]*x509.Certificate, len(certificates))
var err error
for i, asn1Data := range certificates {
if certs[i], err = x509.ParseCertificate(asn1Data); err != nil {
c.sendAlert(alertBadCertificate)
return errors.New("tls: failed to parse client certificate: " + err.Error())
}
}
if len(certs) == 0 && requiresClientCert(c.config.ClientAuth) {
c.sendAlert(alertBadCertificate)
return errors.New("tls: client didn't provide a certificate")
}
if c.config.ClientAuth >= VerifyClientCertIfGiven && len(certs) > 0 {
opts := x509.VerifyOptions{
Roots: c.config.ClientCAs,
CurrentTime: c.config.time(),
Intermediates: x509.NewCertPool(),
KeyUsages: []x509.ExtKeyUsage{x509.ExtKeyUsageClientAuth},
}
for _, cert := range certs[1:] {
opts.Intermediates.AddCert(cert)
}
chains, err := certs[0].Verify(opts)
if err != nil {
c.sendAlert(alertBadCertificate)
return errors.New("tls: failed to verify client certificate: " + err.Error())
}
c.verifiedChains = chains
}
c.peerCertificates = certs
c.ocspResponse = certificate.OCSPStaple
c.scts = certificate.SignedCertificateTimestamps
if len(certs) > 0 {
switch certs[0].PublicKey.(type) {
case *ecdsa.PublicKey, *rsa.PublicKey, ed25519.PublicKey, circlSign.PublicKey:
default:
c.sendAlert(alertUnsupportedCertificate)
return fmt.Errorf("tls: client certificate contains an unsupported public key of type %T", certs[0].PublicKey)
}
}
if c.config.VerifyPeerCertificate != nil {
if err := c.config.VerifyPeerCertificate(certificates, c.verifiedChains); err != nil {
c.sendAlert(alertBadCertificate)
return err
}
}
return nil
}
func clientHelloInfo(ctx context.Context, c *Conn, clientHello *clientHelloMsg) *ClientHelloInfo {
supportedVersions := clientHello.supportedVersions
if len(clientHello.supportedVersions) == 0 {
supportedVersions = supportedVersionsFromMax(clientHello.vers)
}
return &ClientHelloInfo{
CipherSuites: clientHello.cipherSuites,
ServerName: clientHello.serverName,
SupportedCurves: clientHello.supportedCurves,
SupportedPoints: clientHello.supportedPoints,
SignatureSchemes: clientHello.supportedSignatureAlgorithms,
SupportedProtos: clientHello.alpnProtocols,
SupportedVersions: supportedVersions,
SupportsDelegatedCredential: clientHello.delegatedCredentialSupported,
SignatureSchemesDC: clientHello.supportedSignatureAlgorithmsDC,
Conn: c.conn,
config: c.config,
ctx: ctx,
}
}

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// Copyright 2020 Cloudflare, Inc. All rights reserved. Use of this source code
// is governed by a BSD-style license that can be found in the LICENSE file.
package tls
import (
"errors"
"fmt"
"github.com/cloudflare/circl/hpke"
)
// The mandatory-to-implement HPKE cipher suite for use with the ECH extension.
var defaultHPKESuite hpke.Suite
func init() {
var err error
defaultHPKESuite, err = hpkeAssembleSuite(
uint16(hpke.KEM_X25519_HKDF_SHA256),
uint16(hpke.KDF_HKDF_SHA256),
uint16(hpke.AEAD_AES128GCM),
)
if err != nil {
panic(fmt.Sprintf("hpke: mandatory-to-implement cipher suite not supported: %s", err))
}
}
func hpkeAssembleSuite(kemId, kdfId, aeadId uint16) (hpke.Suite, error) {
kem := hpke.KEM(kemId)
if !kem.IsValid() {
return hpke.Suite{}, errors.New("KEM is not supported")
}
kdf := hpke.KDF(kdfId)
if !kdf.IsValid() {
return hpke.Suite{}, errors.New("KDF is not supported")
}
aead := hpke.AEAD(aeadId)
if !aead.IsValid() {
return hpke.Suite{}, errors.New("AEAD is not supported")
}
return hpke.NewSuite(kem, kdf, aead), nil
}

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// Copyright 2010 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import (
"crypto"
"crypto/md5"
"crypto/rsa"
"crypto/sha1"
"crypto/x509"
"errors"
"fmt"
"io"
)
// a keyAgreement implements the client and server side of a TLS key agreement
// protocol by generating and processing key exchange messages.
type keyAgreement interface {
// On the server side, the first two methods are called in order.
// In the case that the key agreement protocol doesn't use a
// ServerKeyExchange message, generateServerKeyExchange can return nil,
// nil.
generateServerKeyExchange(*Config, *Certificate, *clientHelloMsg, *serverHelloMsg) (*serverKeyExchangeMsg, error)
processClientKeyExchange(*Config, *Certificate, *clientKeyExchangeMsg, uint16) ([]byte, error)
// On the client side, the next two methods are called in order.
// This method may not be called if the server doesn't send a
// ServerKeyExchange message.
processServerKeyExchange(*Config, *clientHelloMsg, *serverHelloMsg, *x509.Certificate, *serverKeyExchangeMsg) error
generateClientKeyExchange(*Config, *clientHelloMsg, *x509.Certificate) ([]byte, *clientKeyExchangeMsg, error)
}
var (
errClientKeyExchange = errors.New("tls: invalid ClientKeyExchange message")
errServerKeyExchange = errors.New("tls: invalid ServerKeyExchange message")
)
// rsaKeyAgreement implements the standard TLS key agreement where the client
// encrypts the pre-master secret to the server's public key.
type rsaKeyAgreement struct{}
func (ka rsaKeyAgreement) generateServerKeyExchange(config *Config, cert *Certificate, clientHello *clientHelloMsg, hello *serverHelloMsg) (*serverKeyExchangeMsg, error) {
return nil, nil
}
func (ka rsaKeyAgreement) processClientKeyExchange(config *Config, cert *Certificate, ckx *clientKeyExchangeMsg, version uint16) ([]byte, error) {
if len(ckx.ciphertext) < 2 {
return nil, errClientKeyExchange
}
ciphertextLen := int(ckx.ciphertext[0])<<8 | int(ckx.ciphertext[1])
if ciphertextLen != len(ckx.ciphertext)-2 {
return nil, errClientKeyExchange
}
ciphertext := ckx.ciphertext[2:]
priv, ok := cert.PrivateKey.(crypto.Decrypter)
if !ok {
return nil, errors.New("tls: certificate private key does not implement crypto.Decrypter")
}
// Perform constant time RSA PKCS #1 v1.5 decryption
preMasterSecret, err := priv.Decrypt(config.rand(), ciphertext, &rsa.PKCS1v15DecryptOptions{SessionKeyLen: 48})
if err != nil {
return nil, err
}
// We don't check the version number in the premaster secret. For one,
// by checking it, we would leak information about the validity of the
// encrypted pre-master secret. Secondly, it provides only a small
// benefit against a downgrade attack and some implementations send the
// wrong version anyway. See the discussion at the end of section
// 7.4.7.1 of RFC 4346.
return preMasterSecret, nil
}
func (ka rsaKeyAgreement) processServerKeyExchange(config *Config, clientHello *clientHelloMsg, serverHello *serverHelloMsg, cert *x509.Certificate, skx *serverKeyExchangeMsg) error {
return errors.New("tls: unexpected ServerKeyExchange")
}
func (ka rsaKeyAgreement) generateClientKeyExchange(config *Config, clientHello *clientHelloMsg, cert *x509.Certificate) ([]byte, *clientKeyExchangeMsg, error) {
preMasterSecret := make([]byte, 48)
preMasterSecret[0] = byte(clientHello.vers >> 8)
preMasterSecret[1] = byte(clientHello.vers)
_, err := io.ReadFull(config.rand(), preMasterSecret[2:])
if err != nil {
return nil, nil, err
}
rsaKey, ok := cert.PublicKey.(*rsa.PublicKey)
if !ok {
return nil, nil, errors.New("tls: server certificate contains incorrect key type for selected ciphersuite")
}
encrypted, err := rsa.EncryptPKCS1v15(config.rand(), rsaKey, preMasterSecret)
if err != nil {
return nil, nil, err
}
ckx := new(clientKeyExchangeMsg)
ckx.ciphertext = make([]byte, len(encrypted)+2)
ckx.ciphertext[0] = byte(len(encrypted) >> 8)
ckx.ciphertext[1] = byte(len(encrypted))
copy(ckx.ciphertext[2:], encrypted)
return preMasterSecret, ckx, nil
}
// sha1Hash calculates a SHA1 hash over the given byte slices.
func sha1Hash(slices [][]byte) []byte {
hsha1 := sha1.New()
for _, slice := range slices {
hsha1.Write(slice)
}
return hsha1.Sum(nil)
}
// md5SHA1Hash implements TLS 1.0's hybrid hash function which consists of the
// concatenation of an MD5 and SHA1 hash.
func md5SHA1Hash(slices [][]byte) []byte {
md5sha1 := make([]byte, md5.Size+sha1.Size)
hmd5 := md5.New()
for _, slice := range slices {
hmd5.Write(slice)
}
copy(md5sha1, hmd5.Sum(nil))
copy(md5sha1[md5.Size:], sha1Hash(slices))
return md5sha1
}
// hashForServerKeyExchange hashes the given slices and returns their digest
// using the given hash function (for >= TLS 1.2) or using a default based on
// the sigType (for earlier TLS versions). For Ed25519 signatures, which don't
// do pre-hashing, it returns the concatenation of the slices.
func hashForServerKeyExchange(sigType uint8, hashFunc crypto.Hash, version uint16, slices ...[]byte) []byte {
if sigType == signatureEd25519 || circlSchemeBySigType(sigType) != nil {
var signed []byte
for _, slice := range slices {
signed = append(signed, slice...)
}
return signed
}
if version >= VersionTLS12 {
h := hashFunc.New()
for _, slice := range slices {
h.Write(slice)
}
digest := h.Sum(nil)
return digest
}
if sigType == signatureECDSA {
return sha1Hash(slices)
}
return md5SHA1Hash(slices)
}
// ecdheKeyAgreement implements a TLS key agreement where the server
// generates an ephemeral EC public/private key pair and signs it. The
// pre-master secret is then calculated using ECDH. The signature may
// be ECDSA, Ed25519 or RSA.
type ecdheKeyAgreement struct {
version uint16
isRSA bool
params ecdheParameters
// ckx and preMasterSecret are generated in processServerKeyExchange
// and returned in generateClientKeyExchange.
ckx *clientKeyExchangeMsg
preMasterSecret []byte
}
func (ka *ecdheKeyAgreement) generateServerKeyExchange(config *Config, cert *Certificate, clientHello *clientHelloMsg, hello *serverHelloMsg) (*serverKeyExchangeMsg, error) {
var curveID CurveID
for _, c := range clientHello.supportedCurves {
if config.supportsCurve(c) && curveIdToCirclScheme(c) == nil {
curveID = c
break
}
}
if curveID == 0 {
return nil, errors.New("tls: no supported elliptic curves offered")
}
if _, ok := curveForCurveID(curveID); curveID != X25519 && !ok {
return nil, errors.New("tls: CurvePreferences includes unsupported curve")
}
params, err := generateECDHEParameters(config.rand(), curveID)
if err != nil {
return nil, err
}
ka.params = params
// See RFC 4492, Section 5.4.
ecdhePublic := params.PublicKey()
serverECDHEParams := make([]byte, 1+2+1+len(ecdhePublic))
serverECDHEParams[0] = 3 // named curve
serverECDHEParams[1] = byte(curveID >> 8)
serverECDHEParams[2] = byte(curveID)
serverECDHEParams[3] = byte(len(ecdhePublic))
copy(serverECDHEParams[4:], ecdhePublic)
priv, ok := cert.PrivateKey.(crypto.Signer)
if !ok {
return nil, fmt.Errorf("tls: certificate private key of type %T does not implement crypto.Signer", cert.PrivateKey)
}
var signatureAlgorithm SignatureScheme
var sigType uint8
var sigHash crypto.Hash
if ka.version >= VersionTLS12 {
signatureAlgorithm, err = selectSignatureScheme(ka.version, cert, clientHello.supportedSignatureAlgorithms)
if err != nil {
return nil, err
}
sigType, sigHash, err = typeAndHashFromSignatureScheme(signatureAlgorithm)
if err != nil {
return nil, err
}
} else {
sigType, sigHash, err = legacyTypeAndHashFromPublicKey(priv.Public())
if err != nil {
return nil, err
}
}
if (sigType == signaturePKCS1v15 || sigType == signatureRSAPSS) != ka.isRSA {
return nil, errors.New("tls: certificate cannot be used with the selected cipher suite")
}
signed := hashForServerKeyExchange(sigType, sigHash, ka.version, clientHello.random, hello.random, serverECDHEParams)
signOpts := crypto.SignerOpts(sigHash)
if sigType == signatureRSAPSS {
signOpts = &rsa.PSSOptions{SaltLength: rsa.PSSSaltLengthEqualsHash, Hash: sigHash}
}
sig, err := priv.Sign(config.rand(), signed, signOpts)
if err != nil {
return nil, errors.New("tls: failed to sign ECDHE parameters: " + err.Error())
}
skx := new(serverKeyExchangeMsg)
sigAndHashLen := 0
if ka.version >= VersionTLS12 {
sigAndHashLen = 2
}
skx.key = make([]byte, len(serverECDHEParams)+sigAndHashLen+2+len(sig))
copy(skx.key, serverECDHEParams)
k := skx.key[len(serverECDHEParams):]
if ka.version >= VersionTLS12 {
k[0] = byte(signatureAlgorithm >> 8)
k[1] = byte(signatureAlgorithm)
k = k[2:]
}
k[0] = byte(len(sig) >> 8)
k[1] = byte(len(sig))
copy(k[2:], sig)
return skx, nil
}
func (ka *ecdheKeyAgreement) processClientKeyExchange(config *Config, cert *Certificate, ckx *clientKeyExchangeMsg, version uint16) ([]byte, error) {
if len(ckx.ciphertext) == 0 || int(ckx.ciphertext[0]) != len(ckx.ciphertext)-1 {
return nil, errClientKeyExchange
}
preMasterSecret := ka.params.SharedKey(ckx.ciphertext[1:])
if preMasterSecret == nil {
return nil, errClientKeyExchange
}
return preMasterSecret, nil
}
func (ka *ecdheKeyAgreement) processServerKeyExchange(config *Config, clientHello *clientHelloMsg, serverHello *serverHelloMsg, cert *x509.Certificate, skx *serverKeyExchangeMsg) error {
if len(skx.key) < 4 {
return errServerKeyExchange
}
if skx.key[0] != 3 { // named curve
return errors.New("tls: server selected unsupported curve")
}
curveID := CurveID(skx.key[1])<<8 | CurveID(skx.key[2])
publicLen := int(skx.key[3])
if publicLen+4 > len(skx.key) {
return errServerKeyExchange
}
serverECDHEParams := skx.key[:4+publicLen]
publicKey := serverECDHEParams[4:]
sig := skx.key[4+publicLen:]
if len(sig) < 2 {
return errServerKeyExchange
}
if _, ok := curveForCurveID(curveID); curveID != X25519 && !ok {
return errors.New("tls: server selected unsupported curve")
}
params, err := generateECDHEParameters(config.rand(), curveID)
if err != nil {
return err
}
ka.params = params
ka.preMasterSecret = params.SharedKey(publicKey)
if ka.preMasterSecret == nil {
return errServerKeyExchange
}
ourPublicKey := params.PublicKey()
ka.ckx = new(clientKeyExchangeMsg)
ka.ckx.ciphertext = make([]byte, 1+len(ourPublicKey))
ka.ckx.ciphertext[0] = byte(len(ourPublicKey))
copy(ka.ckx.ciphertext[1:], ourPublicKey)
var sigType uint8
var sigHash crypto.Hash
if ka.version >= VersionTLS12 {
signatureAlgorithm := SignatureScheme(sig[0])<<8 | SignatureScheme(sig[1])
sig = sig[2:]
if len(sig) < 2 {
return errServerKeyExchange
}
if !isSupportedSignatureAlgorithm(signatureAlgorithm, clientHello.supportedSignatureAlgorithms) {
return errors.New("tls: certificate used with invalid signature algorithm")
}
sigType, sigHash, err = typeAndHashFromSignatureScheme(signatureAlgorithm)
if err != nil {
return err
}
} else {
sigType, sigHash, err = legacyTypeAndHashFromPublicKey(cert.PublicKey)
if err != nil {
return err
}
}
if (sigType == signaturePKCS1v15 || sigType == signatureRSAPSS) != ka.isRSA {
return errServerKeyExchange
}
sigLen := int(sig[0])<<8 | int(sig[1])
if sigLen+2 != len(sig) {
return errServerKeyExchange
}
sig = sig[2:]
signed := hashForServerKeyExchange(sigType, sigHash, ka.version, clientHello.random, serverHello.random, serverECDHEParams)
if err := verifyHandshakeSignature(sigType, cert.PublicKey, sigHash, signed, sig); err != nil {
return errors.New("tls: invalid signature by the server certificate: " + err.Error())
}
return nil
}
func (ka *ecdheKeyAgreement) generateClientKeyExchange(config *Config, clientHello *clientHelloMsg, cert *x509.Certificate) ([]byte, *clientKeyExchangeMsg, error) {
if ka.ckx == nil {
return nil, nil, errors.New("tls: missing ServerKeyExchange message")
}
return ka.preMasterSecret, ka.ckx, nil
}

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// Copyright 2018 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import (
"crypto/elliptic"
"crypto/hmac"
"errors"
"hash"
"io"
"math/big"
"golang.org/x/crypto/cryptobyte"
"golang.org/x/crypto/curve25519"
"golang.org/x/crypto/hkdf"
)
// This file contains the functions necessary to compute the TLS 1.3 key
// schedule. See RFC 8446, Section 7.
const (
resumptionBinderLabel = "res binder"
clientHandshakeTrafficLabel = "c hs traffic"
serverHandshakeTrafficLabel = "s hs traffic"
clientApplicationTrafficLabel = "c ap traffic"
serverApplicationTrafficLabel = "s ap traffic"
exporterLabel = "exp master"
resumptionLabel = "res master"
trafficUpdateLabel = "traffic upd"
)
// expandLabel implements HKDF-Expand-Label from RFC 8446, Section 7.1.
func (c *cipherSuiteTLS13) expandLabel(secret []byte, label string, context []byte, length int) []byte {
var hkdfLabel cryptobyte.Builder
hkdfLabel.AddUint16(uint16(length))
hkdfLabel.AddUint8LengthPrefixed(func(b *cryptobyte.Builder) {
b.AddBytes([]byte("tls13 "))
b.AddBytes([]byte(label))
})
hkdfLabel.AddUint8LengthPrefixed(func(b *cryptobyte.Builder) {
b.AddBytes(context)
})
out := make([]byte, length)
n, err := hkdf.Expand(c.hash.New, secret, hkdfLabel.BytesOrPanic()).Read(out)
if err != nil || n != length {
panic("tls: HKDF-Expand-Label invocation failed unexpectedly")
}
return out
}
// deriveSecret implements Derive-Secret from RFC 8446, Section 7.1.
func (c *cipherSuiteTLS13) deriveSecret(secret []byte, label string, transcript hash.Hash) []byte {
if transcript == nil {
transcript = c.hash.New()
}
return c.expandLabel(secret, label, transcript.Sum(nil), c.hash.Size())
}
// extract implements HKDF-Extract with the cipher suite hash.
func (c *cipherSuiteTLS13) extract(newSecret, currentSecret []byte) []byte {
if newSecret == nil {
newSecret = make([]byte, c.hash.Size())
}
return hkdf.Extract(c.hash.New, newSecret, currentSecret)
}
// nextTrafficSecret generates the next traffic secret, given the current one,
// according to RFC 8446, Section 7.2.
func (c *cipherSuiteTLS13) nextTrafficSecret(trafficSecret []byte) []byte {
return c.expandLabel(trafficSecret, trafficUpdateLabel, nil, c.hash.Size())
}
// trafficKey generates traffic keys according to RFC 8446, Section 7.3.
func (c *cipherSuiteTLS13) trafficKey(trafficSecret []byte) (key, iv []byte) {
key = c.expandLabel(trafficSecret, "key", nil, c.keyLen)
iv = c.expandLabel(trafficSecret, "iv", nil, aeadNonceLength)
return
}
// finishedHash generates the Finished verify_data or PskBinderEntry according
// to RFC 8446, Section 4.4.4. See sections 4.4 and 4.2.11.2 for the baseKey
// selection.
func (c *cipherSuiteTLS13) finishedHash(baseKey []byte, transcript hash.Hash) []byte {
finishedKey := c.expandLabel(baseKey, "finished", nil, c.hash.Size())
verifyData := hmac.New(c.hash.New, finishedKey)
verifyData.Write(transcript.Sum(nil))
return verifyData.Sum(nil)
}
// exportKeyingMaterial implements RFC5705 exporters for TLS 1.3 according to
// RFC 8446, Section 7.5.
func (c *cipherSuiteTLS13) exportKeyingMaterial(masterSecret []byte, transcript hash.Hash) func(string, []byte, int) ([]byte, error) {
expMasterSecret := c.deriveSecret(masterSecret, exporterLabel, transcript)
return func(label string, context []byte, length int) ([]byte, error) {
secret := c.deriveSecret(expMasterSecret, label, nil)
h := c.hash.New()
h.Write(context)
return c.expandLabel(secret, "exporter", h.Sum(nil), length), nil
}
}
// ecdheParameters implements Diffie-Hellman with either NIST curves or X25519,
// according to RFC 8446, Section 4.2.8.2.
type ecdheParameters interface {
CurveID() CurveID
PublicKey() []byte
SharedKey(peerPublicKey []byte) []byte
}
func generateECDHEParameters(rand io.Reader, curveID CurveID) (ecdheParameters, error) {
if curveID == X25519 {
privateKey := make([]byte, curve25519.ScalarSize)
if _, err := io.ReadFull(rand, privateKey); err != nil {
return nil, err
}
publicKey, err := curve25519.X25519(privateKey, curve25519.Basepoint)
if err != nil {
return nil, err
}
return &x25519Parameters{privateKey: privateKey, publicKey: publicKey}, nil
}
curve, ok := curveForCurveID(curveID)
if !ok {
return nil, errors.New("tls: internal error: unsupported curve")
}
p := &nistParameters{curveID: curveID}
var err error
p.privateKey, p.x, p.y, err = elliptic.GenerateKey(curve, rand)
if err != nil {
return nil, err
}
return p, nil
}
func curveForCurveID(id CurveID) (elliptic.Curve, bool) {
switch id {
case CurveP256:
return elliptic.P256(), true
case CurveP384:
return elliptic.P384(), true
case CurveP521:
return elliptic.P521(), true
default:
return nil, false
}
}
type nistParameters struct {
privateKey []byte
x, y *big.Int // public key
curveID CurveID
}
func (p *nistParameters) CurveID() CurveID {
return p.curveID
}
func (p *nistParameters) PublicKey() []byte {
curve, _ := curveForCurveID(p.curveID)
return elliptic.Marshal(curve, p.x, p.y)
}
func (p *nistParameters) SharedKey(peerPublicKey []byte) []byte {
curve, _ := curveForCurveID(p.curveID)
// Unmarshal also checks whether the given point is on the curve.
x, y := elliptic.Unmarshal(curve, peerPublicKey)
if x == nil {
return nil
}
xShared, _ := curve.ScalarMult(x, y, p.privateKey)
sharedKey := make([]byte, (curve.Params().BitSize+7)/8)
return xShared.FillBytes(sharedKey)
}
type x25519Parameters struct {
privateKey []byte
publicKey []byte
}
func (p *x25519Parameters) CurveID() CurveID {
return X25519
}
func (p *x25519Parameters) PublicKey() []byte {
return p.publicKey[:]
}
func (p *x25519Parameters) SharedKey(peerPublicKey []byte) []byte {
sharedKey, err := curve25519.X25519(p.privateKey, peerPublicKey)
if err != nil {
return nil
}
return sharedKey
}

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// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import (
"crypto"
"crypto/hmac"
"crypto/md5"
"crypto/sha1"
"crypto/sha256"
"crypto/sha512"
"errors"
"fmt"
"hash"
)
// Split a premaster secret in two as specified in RFC 4346, Section 5.
func splitPreMasterSecret(secret []byte) (s1, s2 []byte) {
s1 = secret[0 : (len(secret)+1)/2]
s2 = secret[len(secret)/2:]
return
}
// pHash implements the P_hash function, as defined in RFC 4346, Section 5.
func pHash(result, secret, seed []byte, hash func() hash.Hash) {
h := hmac.New(hash, secret)
h.Write(seed)
a := h.Sum(nil)
j := 0
for j < len(result) {
h.Reset()
h.Write(a)
h.Write(seed)
b := h.Sum(nil)
copy(result[j:], b)
j += len(b)
h.Reset()
h.Write(a)
a = h.Sum(nil)
}
}
// prf10 implements the TLS 1.0 pseudo-random function, as defined in RFC 2246, Section 5.
func prf10(result, secret, label, seed []byte) {
hashSHA1 := sha1.New
hashMD5 := md5.New
labelAndSeed := make([]byte, len(label)+len(seed))
copy(labelAndSeed, label)
copy(labelAndSeed[len(label):], seed)
s1, s2 := splitPreMasterSecret(secret)
pHash(result, s1, labelAndSeed, hashMD5)
result2 := make([]byte, len(result))
pHash(result2, s2, labelAndSeed, hashSHA1)
for i, b := range result2 {
result[i] ^= b
}
}
// prf12 implements the TLS 1.2 pseudo-random function, as defined in RFC 5246, Section 5.
func prf12(hashFunc func() hash.Hash) func(result, secret, label, seed []byte) {
return func(result, secret, label, seed []byte) {
labelAndSeed := make([]byte, len(label)+len(seed))
copy(labelAndSeed, label)
copy(labelAndSeed[len(label):], seed)
pHash(result, secret, labelAndSeed, hashFunc)
}
}
const (
masterSecretLength = 48 // Length of a master secret in TLS 1.1.
finishedVerifyLength = 12 // Length of verify_data in a Finished message.
)
var (
masterSecretLabel = []byte("master secret")
keyExpansionLabel = []byte("key expansion")
clientFinishedLabel = []byte("client finished")
serverFinishedLabel = []byte("server finished")
)
func prfAndHashForVersion(version uint16, suite *cipherSuite) (func(result, secret, label, seed []byte), crypto.Hash) {
switch version {
case VersionTLS10, VersionTLS11:
return prf10, crypto.Hash(0)
case VersionTLS12:
if suite.flags&suiteSHA384 != 0 {
return prf12(sha512.New384), crypto.SHA384
}
return prf12(sha256.New), crypto.SHA256
default:
panic("unknown version")
}
}
func prfForVersion(version uint16, suite *cipherSuite) func(result, secret, label, seed []byte) {
prf, _ := prfAndHashForVersion(version, suite)
return prf
}
// masterFromPreMasterSecret generates the master secret from the pre-master
// secret. See RFC 5246, Section 8.1.
func masterFromPreMasterSecret(version uint16, suite *cipherSuite, preMasterSecret, clientRandom, serverRandom []byte) []byte {
seed := make([]byte, 0, len(clientRandom)+len(serverRandom))
seed = append(seed, clientRandom...)
seed = append(seed, serverRandom...)
masterSecret := make([]byte, masterSecretLength)
prfForVersion(version, suite)(masterSecret, preMasterSecret, masterSecretLabel, seed)
return masterSecret
}
// keysFromMasterSecret generates the connection keys from the master
// secret, given the lengths of the MAC key, cipher key and IV, as defined in
// RFC 2246, Section 6.3.
func keysFromMasterSecret(version uint16, suite *cipherSuite, masterSecret, clientRandom, serverRandom []byte, macLen, keyLen, ivLen int) (clientMAC, serverMAC, clientKey, serverKey, clientIV, serverIV []byte) {
seed := make([]byte, 0, len(serverRandom)+len(clientRandom))
seed = append(seed, serverRandom...)
seed = append(seed, clientRandom...)
n := 2*macLen + 2*keyLen + 2*ivLen
keyMaterial := make([]byte, n)
prfForVersion(version, suite)(keyMaterial, masterSecret, keyExpansionLabel, seed)
clientMAC = keyMaterial[:macLen]
keyMaterial = keyMaterial[macLen:]
serverMAC = keyMaterial[:macLen]
keyMaterial = keyMaterial[macLen:]
clientKey = keyMaterial[:keyLen]
keyMaterial = keyMaterial[keyLen:]
serverKey = keyMaterial[:keyLen]
keyMaterial = keyMaterial[keyLen:]
clientIV = keyMaterial[:ivLen]
keyMaterial = keyMaterial[ivLen:]
serverIV = keyMaterial[:ivLen]
return
}
func newFinishedHash(version uint16, cipherSuite *cipherSuite) finishedHash {
var buffer []byte
if version >= VersionTLS12 {
buffer = []byte{}
}
prf, hash := prfAndHashForVersion(version, cipherSuite)
if hash != 0 {
return finishedHash{hash.New(), hash.New(), nil, nil, buffer, version, prf}
}
return finishedHash{sha1.New(), sha1.New(), md5.New(), md5.New(), buffer, version, prf}
}
// A finishedHash calculates the hash of a set of handshake messages suitable
// for including in a Finished message.
type finishedHash struct {
client hash.Hash
server hash.Hash
// Prior to TLS 1.2, an additional MD5 hash is required.
clientMD5 hash.Hash
serverMD5 hash.Hash
// In TLS 1.2, a full buffer is sadly required.
buffer []byte
version uint16
prf func(result, secret, label, seed []byte)
}
func (h *finishedHash) Write(msg []byte) (n int, err error) {
h.client.Write(msg)
h.server.Write(msg)
if h.version < VersionTLS12 {
h.clientMD5.Write(msg)
h.serverMD5.Write(msg)
}
if h.buffer != nil {
h.buffer = append(h.buffer, msg...)
}
return len(msg), nil
}
func (h finishedHash) Sum() []byte {
if h.version >= VersionTLS12 {
return h.client.Sum(nil)
}
out := make([]byte, 0, md5.Size+sha1.Size)
out = h.clientMD5.Sum(out)
return h.client.Sum(out)
}
// clientSum returns the contents of the verify_data member of a client's
// Finished message.
func (h finishedHash) clientSum(masterSecret []byte) []byte {
out := make([]byte, finishedVerifyLength)
h.prf(out, masterSecret, clientFinishedLabel, h.Sum())
return out
}
// serverSum returns the contents of the verify_data member of a server's
// Finished message.
func (h finishedHash) serverSum(masterSecret []byte) []byte {
out := make([]byte, finishedVerifyLength)
h.prf(out, masterSecret, serverFinishedLabel, h.Sum())
return out
}
// hashForClientCertificate returns the handshake messages so far, pre-hashed if
// necessary, suitable for signing by a TLS client certificate.
func (h finishedHash) hashForClientCertificate(sigType uint8, hashAlg crypto.Hash, masterSecret []byte) []byte {
if (h.version >= VersionTLS12 || sigType == signatureEd25519 || circlSchemeBySigType(sigType) != nil) && h.buffer == nil {
panic("tls: handshake hash for a client certificate requested after discarding the handshake buffer")
}
if sigType == signatureEd25519 || circlSchemeBySigType(sigType) != nil {
return h.buffer
}
if h.version >= VersionTLS12 {
hash := hashAlg.New()
hash.Write(h.buffer)
return hash.Sum(nil)
}
if sigType == signatureECDSA {
return h.server.Sum(nil)
}
return h.Sum()
}
// discardHandshakeBuffer is called when there is no more need to
// buffer the entirety of the handshake messages.
func (h *finishedHash) discardHandshakeBuffer() {
h.buffer = nil
}
// noExportedKeyingMaterial is used as a value of
// ConnectionState.ekm when renegotiation is enabled and thus
// we wish to fail all key-material export requests.
func noExportedKeyingMaterial(label string, context []byte, length int) ([]byte, error) {
return nil, errors.New("crypto/tls: ExportKeyingMaterial is unavailable when renegotiation is enabled")
}
// ekmFromMasterSecret generates exported keying material as defined in RFC 5705.
func ekmFromMasterSecret(version uint16, suite *cipherSuite, masterSecret, clientRandom, serverRandom []byte) func(string, []byte, int) ([]byte, error) {
return func(label string, context []byte, length int) ([]byte, error) {
switch label {
case "client finished", "server finished", "master secret", "key expansion":
// These values are reserved and may not be used.
return nil, fmt.Errorf("crypto/tls: reserved ExportKeyingMaterial label: %s", label)
}
seedLen := len(serverRandom) + len(clientRandom)
if context != nil {
seedLen += 2 + len(context)
}
seed := make([]byte, 0, seedLen)
seed = append(seed, clientRandom...)
seed = append(seed, serverRandom...)
if context != nil {
if len(context) >= 1<<16 {
return nil, fmt.Errorf("crypto/tls: ExportKeyingMaterial context too long")
}
seed = append(seed, byte(len(context)>>8), byte(len(context)))
seed = append(seed, context...)
}
keyMaterial := make([]byte, length)
prfForVersion(version, suite)(keyMaterial, masterSecret, []byte(label), seed)
return keyMaterial, nil
}
}

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// Copyright 2012 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import (
"bytes"
"crypto/aes"
"crypto/cipher"
"crypto/hmac"
"crypto/sha256"
"crypto/subtle"
"errors"
"io"
"golang.org/x/crypto/cryptobyte"
)
// sessionState contains the information that is serialized into a session
// ticket in order to later resume a connection.
type sessionState struct {
vers uint16
cipherSuite uint16
createdAt uint64
masterSecret []byte // opaque master_secret<1..2^16-1>;
// struct { opaque certificate<1..2^24-1> } Certificate;
certificates [][]byte // Certificate certificate_list<0..2^24-1>;
// usedOldKey is true if the ticket from which this session came from
// was encrypted with an older key and thus should be refreshed.
usedOldKey bool
}
func (m *sessionState) marshal() []byte {
var b cryptobyte.Builder
b.AddUint16(m.vers)
b.AddUint16(m.cipherSuite)
addUint64(&b, m.createdAt)
b.AddUint16LengthPrefixed(func(b *cryptobyte.Builder) {
b.AddBytes(m.masterSecret)
})
b.AddUint24LengthPrefixed(func(b *cryptobyte.Builder) {
for _, cert := range m.certificates {
b.AddUint24LengthPrefixed(func(b *cryptobyte.Builder) {
b.AddBytes(cert)
})
}
})
return b.BytesOrPanic()
}
func (m *sessionState) unmarshal(data []byte) bool {
*m = sessionState{usedOldKey: m.usedOldKey}
s := cryptobyte.String(data)
if ok := s.ReadUint16(&m.vers) &&
s.ReadUint16(&m.cipherSuite) &&
readUint64(&s, &m.createdAt) &&
readUint16LengthPrefixed(&s, &m.masterSecret) &&
len(m.masterSecret) != 0; !ok {
return false
}
var certList cryptobyte.String
if !s.ReadUint24LengthPrefixed(&certList) {
return false
}
for !certList.Empty() {
var cert []byte
if !readUint24LengthPrefixed(&certList, &cert) {
return false
}
m.certificates = append(m.certificates, cert)
}
return s.Empty()
}
// sessionStateTLS13 is the content of a TLS 1.3 session ticket. Its first
// version (revision = 0) doesn't carry any of the information needed for 0-RTT
// validation and the nonce is always empty.
type sessionStateTLS13 struct {
// uint8 version = 0x0304;
// uint8 revision = 0;
cipherSuite uint16
createdAt uint64
resumptionSecret []byte // opaque resumption_master_secret<1..2^8-1>;
certificate Certificate // CertificateEntry certificate_list<0..2^24-1>;
}
func (m *sessionStateTLS13) marshal() []byte {
var b cryptobyte.Builder
b.AddUint16(VersionTLS13)
b.AddUint8(0) // revision
b.AddUint16(m.cipherSuite)
addUint64(&b, m.createdAt)
b.AddUint8LengthPrefixed(func(b *cryptobyte.Builder) {
b.AddBytes(m.resumptionSecret)
})
marshalCertificate(&b, m.certificate)
return b.BytesOrPanic()
}
func (m *sessionStateTLS13) unmarshal(data []byte) bool {
*m = sessionStateTLS13{}
s := cryptobyte.String(data)
var version uint16
var revision uint8
return s.ReadUint16(&version) &&
version == VersionTLS13 &&
s.ReadUint8(&revision) &&
revision == 0 &&
s.ReadUint16(&m.cipherSuite) &&
readUint64(&s, &m.createdAt) &&
readUint8LengthPrefixed(&s, &m.resumptionSecret) &&
len(m.resumptionSecret) != 0 &&
unmarshalCertificate(&s, &m.certificate) &&
s.Empty()
}
func (c *Conn) encryptTicket(state []byte) ([]byte, error) {
if len(c.ticketKeys) == 0 {
return nil, errors.New("tls: internal error: session ticket keys unavailable")
}
encrypted := make([]byte, ticketKeyNameLen+aes.BlockSize+len(state)+sha256.Size)
keyName := encrypted[:ticketKeyNameLen]
iv := encrypted[ticketKeyNameLen : ticketKeyNameLen+aes.BlockSize]
macBytes := encrypted[len(encrypted)-sha256.Size:]
if _, err := io.ReadFull(c.config.rand(), iv); err != nil {
return nil, err
}
key := c.ticketKeys[0]
copy(keyName, key.keyName[:])
block, err := aes.NewCipher(key.aesKey[:])
if err != nil {
return nil, errors.New("tls: failed to create cipher while encrypting ticket: " + err.Error())
}
cipher.NewCTR(block, iv).XORKeyStream(encrypted[ticketKeyNameLen+aes.BlockSize:], state)
mac := hmac.New(sha256.New, key.hmacKey[:])
mac.Write(encrypted[:len(encrypted)-sha256.Size])
mac.Sum(macBytes[:0])
return encrypted, nil
}
func (c *Conn) decryptTicket(encrypted []byte) (plaintext []byte, usedOldKey bool) {
if len(encrypted) < ticketKeyNameLen+aes.BlockSize+sha256.Size {
return nil, false
}
keyName := encrypted[:ticketKeyNameLen]
iv := encrypted[ticketKeyNameLen : ticketKeyNameLen+aes.BlockSize]
macBytes := encrypted[len(encrypted)-sha256.Size:]
ciphertext := encrypted[ticketKeyNameLen+aes.BlockSize : len(encrypted)-sha256.Size]
keyIndex := -1
for i, candidateKey := range c.ticketKeys {
if bytes.Equal(keyName, candidateKey.keyName[:]) {
keyIndex = i
break
}
}
if keyIndex == -1 {
return nil, false
}
key := &c.ticketKeys[keyIndex]
mac := hmac.New(sha256.New, key.hmacKey[:])
mac.Write(encrypted[:len(encrypted)-sha256.Size])
expected := mac.Sum(nil)
if subtle.ConstantTimeCompare(macBytes, expected) != 1 {
return nil, false
}
block, err := aes.NewCipher(key.aesKey[:])
if err != nil {
return nil, false
}
plaintext = make([]byte, len(ciphertext))
cipher.NewCTR(block, iv).XORKeyStream(plaintext, ciphertext)
return plaintext, keyIndex > 0
}

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// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Package tls partially implements TLS 1.2, as specified in RFC 5246,
// and TLS 1.3, as specified in RFC 8446.
//
// This package implements the "Encrypted ClientHello (ECH)" extension, as
// specified by draft-ietf-tls-esni-13. This extension allows the client to
// encrypt its ClientHello to the public key of an ECH-service provider, known
// as the client-facing server. If successful, then the client-facing server
// forwards the decrypted ClientHello to the intended recipient, known as the
// backend server. The goal of this mechanism is to ensure that connections made
// to backend servers are indistinguishable from one another.
//
// This package implements the "Delegated Credentials" extension, as
// specified by draft-ietf-tls-subcerts-10. This extension allows the usage
// of a limited delegation mechanism that allows a TLS peer to issue its own
// credentials within the scope of a certificate issued by an external
// CA. These credentials only enable the recipient of the delegation to
// speak for names that the CA has authorized. If the client or server supports
// this extension, then the server or client may use a "delegated credential"
// as the signing key in the handshake. A delegated credential is a short lived
// public/secret key pair delegated to the peer by an entity trusted by the
// corresponding peer. This allows a reverse proxy to terminate a TLS connection
// on behalf of the entity. Credentials can't be revoked; in order to
// mitigate risk in case the reverse proxy is compromised, the credential is only
// valid for a short time (days, hours, or even minutes).
package tls
// BUG(cjpatton): In order to achieve its security goal, the ECH extension
// requires padding in order to ensure that the length of handshake messages
// doesn't depend on who terminates the connection. This package does not yet
// implement server-side padding: see
// https://github.com/tlswg/draft-ietf-tls-esni/issues/264.
// BUG(cjpatton): The interaction of the ECH extension with PSK has not yet been
// fully vetted. For now, the server disables session tickets if ECH is enabled.
// BUG(cjpatton): Upon ECH rejection, if retry configurations are provided, then
// the client is expected to retry the connection. Otherwise, it may regard ECH
// as being securely disabled by the client-facing server. The client in this
// package does not attempt to retry the handshake.
// BUG(cjpatton): If the client offers the ECH extension and the client-facing
// server rejects it, then only the client-facing server is authenticated. In
// particular, the client is expected to respond to a CertificateRequest with an
// empty certificate. This package does not yet implement this behavior.
// BUG(agl): The crypto/tls package only implements some countermeasures
// against Lucky13 attacks on CBC-mode encryption, and only on SHA1
// variants. See http://www.isg.rhul.ac.uk/tls/TLStiming.pdf and
// https://www.imperialviolet.org/2013/02/04/luckythirteen.html.
import (
"bytes"
"context"
"crypto"
"crypto/ecdsa"
"crypto/ed25519"
"crypto/rsa"
"crypto/x509"
"encoding/pem"
"errors"
"fmt"
"net"
"os"
"strings"
circlSign "github.com/cloudflare/circl/sign"
)
// Server returns a new TLS server side connection
// using conn as the underlying transport.
// The configuration config must be non-nil and must include
// at least one certificate or else set GetCertificate.
func Server(conn net.Conn, config *Config) *Conn {
c := &Conn{
conn: conn,
config: config,
}
c.handshakeFn = c.serverHandshake
return c
}
// Client returns a new TLS client side connection
// using conn as the underlying transport.
// The config cannot be nil: users must set either ServerName or
// InsecureSkipVerify in the config.
func Client(conn net.Conn, config *Config) *Conn {
c := &Conn{
conn: conn,
config: config,
isClient: true,
}
c.handshakeFn = c.clientHandshake
return c
}
// A listener implements a network listener (net.Listener) for TLS connections.
type listener struct {
net.Listener
config *Config
}
// Accept waits for and returns the next incoming TLS connection.
// The returned connection is of type *Conn.
func (l *listener) Accept() (net.Conn, error) {
c, err := l.Listener.Accept()
if err != nil {
return nil, err
}
return Server(c, l.config), nil
}
// NewListener creates a Listener which accepts connections from an inner
// Listener and wraps each connection with Server.
// The configuration config must be non-nil and must include
// at least one certificate or else set GetCertificate.
func NewListener(inner net.Listener, config *Config) net.Listener {
l := new(listener)
l.Listener = inner
l.config = config
return l
}
// Listen creates a TLS listener accepting connections on the
// given network address using net.Listen.
// The configuration config must be non-nil and must include
// at least one certificate or else set GetCertificate.
func Listen(network, laddr string, config *Config) (net.Listener, error) {
if config == nil || len(config.Certificates) == 0 &&
config.GetCertificate == nil && config.GetConfigForClient == nil {
return nil, errors.New("tls: neither Certificates, GetCertificate, nor GetConfigForClient set in Config")
}
l, err := net.Listen(network, laddr)
if err != nil {
return nil, err
}
return NewListener(l, config), nil
}
type timeoutError struct{}
func (timeoutError) Error() string { return "tls: DialWithDialer timed out" }
func (timeoutError) Timeout() bool { return true }
func (timeoutError) Temporary() bool { return true }
// DialWithDialer connects to the given network address using dialer.Dial and
// then initiates a TLS handshake, returning the resulting TLS connection. Any
// timeout or deadline given in the dialer apply to connection and TLS
// handshake as a whole.
//
// DialWithDialer interprets a nil configuration as equivalent to the zero
// configuration; see the documentation of Config for the defaults.
//
// DialWithDialer uses context.Background internally; to specify the context,
// use Dialer.DialContext with NetDialer set to the desired dialer.
func DialWithDialer(dialer *net.Dialer, network, addr string, config *Config) (*Conn, error) {
return dial(context.Background(), dialer, network, addr, config)
}
func dial(ctx context.Context, netDialer *net.Dialer, network, addr string, config *Config) (*Conn, error) {
if netDialer.Timeout != 0 {
var cancel context.CancelFunc
ctx, cancel = context.WithTimeout(ctx, netDialer.Timeout)
defer cancel()
}
if !netDialer.Deadline.IsZero() {
var cancel context.CancelFunc
ctx, cancel = context.WithDeadline(ctx, netDialer.Deadline)
defer cancel()
}
rawConn, err := netDialer.DialContext(ctx, network, addr)
if err != nil {
return nil, err
}
colonPos := strings.LastIndex(addr, ":")
if colonPos == -1 {
colonPos = len(addr)
}
hostname := addr[:colonPos]
if config == nil {
config = defaultConfig()
}
// If no ServerName is set, infer the ServerName
// from the hostname we're connecting to.
if config.ServerName == "" {
// Make a copy to avoid polluting argument or default.
c := config.Clone()
c.ServerName = hostname
config = c
}
conn := Client(rawConn, config)
if err := conn.HandshakeContext(ctx); err != nil {
rawConn.Close()
return nil, err
}
return conn, nil
}
// Dial connects to the given network address using net.Dial
// and then initiates a TLS handshake, returning the resulting
// TLS connection.
// Dial interprets a nil configuration as equivalent to
// the zero configuration; see the documentation of Config
// for the defaults.
func Dial(network, addr string, config *Config) (*Conn, error) {
return DialWithDialer(new(net.Dialer), network, addr, config)
}
// Dialer dials TLS connections given a configuration and a Dialer for the
// underlying connection.
type Dialer struct {
// NetDialer is the optional dialer to use for the TLS connections'
// underlying TCP connections.
// A nil NetDialer is equivalent to the net.Dialer zero value.
NetDialer *net.Dialer
// Config is the TLS configuration to use for new connections.
// A nil configuration is equivalent to the zero
// configuration; see the documentation of Config for the
// defaults.
Config *Config
}
// Dial connects to the given network address and initiates a TLS
// handshake, returning the resulting TLS connection.
//
// The returned Conn, if any, will always be of type *Conn.
//
// Dial uses context.Background internally; to specify the context,
// use DialContext.
func (d *Dialer) Dial(network, addr string) (net.Conn, error) {
return d.DialContext(context.Background(), network, addr)
}
func (d *Dialer) netDialer() *net.Dialer {
if d.NetDialer != nil {
return d.NetDialer
}
return new(net.Dialer)
}
// DialContext connects to the given network address and initiates a TLS
// handshake, returning the resulting TLS connection.
//
// The provided Context must be non-nil. If the context expires before
// the connection is complete, an error is returned. Once successfully
// connected, any expiration of the context will not affect the
// connection.
//
// The returned Conn, if any, will always be of type *Conn.
func (d *Dialer) DialContext(ctx context.Context, network, addr string) (net.Conn, error) {
c, err := dial(ctx, d.netDialer(), network, addr, d.Config)
if err != nil {
// Don't return c (a typed nil) in an interface.
return nil, err
}
return c, nil
}
// LoadX509KeyPair reads and parses a public/private key pair from a pair
// of files. The files must contain PEM encoded data. The certificate file
// may contain intermediate certificates following the leaf certificate to
// form a certificate chain. On successful return, Certificate.Leaf will
// be nil because the parsed form of the certificate is not retained.
func LoadX509KeyPair(certFile, keyFile string) (Certificate, error) {
certPEMBlock, err := os.ReadFile(certFile)
if err != nil {
return Certificate{}, err
}
keyPEMBlock, err := os.ReadFile(keyFile)
if err != nil {
return Certificate{}, err
}
return X509KeyPair(certPEMBlock, keyPEMBlock)
}
// X509KeyPair parses a public/private key pair from a pair of
// PEM encoded data. On successful return, Certificate.Leaf will be nil because
// the parsed form of the certificate is not retained.
func X509KeyPair(certPEMBlock, keyPEMBlock []byte) (Certificate, error) {
fail := func(err error) (Certificate, error) { return Certificate{}, err }
var cert Certificate
var skippedBlockTypes []string
for {
var certDERBlock *pem.Block
certDERBlock, certPEMBlock = pem.Decode(certPEMBlock)
if certDERBlock == nil {
break
}
if certDERBlock.Type == "CERTIFICATE" {
cert.Certificate = append(cert.Certificate, certDERBlock.Bytes)
} else {
skippedBlockTypes = append(skippedBlockTypes, certDERBlock.Type)
}
}
if len(cert.Certificate) == 0 {
if len(skippedBlockTypes) == 0 {
return fail(errors.New("tls: failed to find any PEM data in certificate input"))
}
if len(skippedBlockTypes) == 1 && strings.HasSuffix(skippedBlockTypes[0], "PRIVATE KEY") {
return fail(errors.New("tls: failed to find certificate PEM data in certificate input, but did find a private key; PEM inputs may have been switched"))
}
return fail(fmt.Errorf("tls: failed to find \"CERTIFICATE\" PEM block in certificate input after skipping PEM blocks of the following types: %v", skippedBlockTypes))
}
skippedBlockTypes = skippedBlockTypes[:0]
var keyDERBlock *pem.Block
for {
keyDERBlock, keyPEMBlock = pem.Decode(keyPEMBlock)
if keyDERBlock == nil {
if len(skippedBlockTypes) == 0 {
return fail(errors.New("tls: failed to find any PEM data in key input"))
}
if len(skippedBlockTypes) == 1 && skippedBlockTypes[0] == "CERTIFICATE" {
return fail(errors.New("tls: found a certificate rather than a key in the PEM for the private key"))
}
return fail(fmt.Errorf("tls: failed to find PEM block with type ending in \"PRIVATE KEY\" in key input after skipping PEM blocks of the following types: %v", skippedBlockTypes))
}
if keyDERBlock.Type == "PRIVATE KEY" || strings.HasSuffix(keyDERBlock.Type, " PRIVATE KEY") {
break
}
skippedBlockTypes = append(skippedBlockTypes, keyDERBlock.Type)
}
// We don't need to parse the public key for TLS, but we so do anyway
// to check that it looks sane and matches the private key.
x509Cert, err := x509.ParseCertificate(cert.Certificate[0])
if err != nil {
return fail(err)
}
cert.PrivateKey, err = parsePrivateKey(keyDERBlock.Bytes)
if err != nil {
return fail(err)
}
switch pub := x509Cert.PublicKey.(type) {
case *rsa.PublicKey:
priv, ok := cert.PrivateKey.(*rsa.PrivateKey)
if !ok {
return fail(errors.New("tls: private key type does not match public key type"))
}
if pub.N.Cmp(priv.N) != 0 {
return fail(errors.New("tls: private key does not match public key"))
}
case *ecdsa.PublicKey:
priv, ok := cert.PrivateKey.(*ecdsa.PrivateKey)
if !ok {
return fail(errors.New("tls: private key type does not match public key type"))
}
if pub.X.Cmp(priv.X) != 0 || pub.Y.Cmp(priv.Y) != 0 {
return fail(errors.New("tls: private key does not match public key"))
}
case ed25519.PublicKey:
priv, ok := cert.PrivateKey.(ed25519.PrivateKey)
if !ok {
return fail(errors.New("tls: private key type does not match public key type"))
}
if !bytes.Equal(priv.Public().(ed25519.PublicKey), pub) {
return fail(errors.New("tls: private key does not match public key"))
}
case circlSign.PublicKey:
priv, ok := cert.PrivateKey.(circlSign.PrivateKey)
if !ok {
return fail(errors.New("tls: private key type does not match public key type"))
}
pkBytes, err := priv.Public().(circlSign.PublicKey).MarshalBinary()
pkBytes2, err2 := pub.MarshalBinary()
if err != nil || err2 != nil || !bytes.Equal(pkBytes, pkBytes2) {
return fail(errors.New("tls: private key does not match public key"))
}
default:
return fail(errors.New("tls: unknown public key algorithm"))
}
return cert, nil
}
// Attempt to parse the given private key DER block. OpenSSL 0.9.8 generates
// PKCS #1 private keys by default, while OpenSSL 1.0.0 generates PKCS #8 keys.
// OpenSSL ecparam generates SEC1 EC private keys for ECDSA. We try all three.
func parsePrivateKey(der []byte) (crypto.PrivateKey, error) {
if key, err := x509.ParsePKCS1PrivateKey(der); err == nil {
return key, nil
}
if key, err := x509.ParsePKCS8PrivateKey(der); err == nil {
switch key := key.(type) {
case *rsa.PrivateKey, *ecdsa.PrivateKey, ed25519.PrivateKey, circlSign.PrivateKey:
return key, nil
default:
return nil, errors.New("tls: found unknown private key type in PKCS#8 wrapping")
}
}
if key, err := x509.ParseECPrivateKey(der); err == nil {
return key, nil
}
return nil, errors.New("tls: failed to parse private key")
}

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// Copyright 2021 Cloudflare, Inc. All rights reserved. Use of this source code
// is governed by a BSD-style license that can be found in the LICENSE file.
package tls
import (
"time"
circlPki "github.com/cloudflare/circl/pki"
circlSign "github.com/cloudflare/circl/sign"
"github.com/cloudflare/circl/sign/eddilithium3"
)
const (
// Constants for ECH status events.
echStatusBypassed = 1 + iota
echStatusInner
echStatusOuter
)
// To add a signature scheme from Circl
//
// 1. make sure it implements TLSScheme and CertificateScheme,
// 2. follow the instructions in crypto/x509/x509_cf.go
// 3. add a signature<NameOfAlg> to the iota in common.go
// 4. add row in the circlSchemes lists below
var circlSchemes = [...]struct {
sigType uint8
scheme circlSign.Scheme
}{
{signatureEdDilithium3, eddilithium3.Scheme()},
}
func circlSchemeBySigType(sigType uint8) circlSign.Scheme {
for _, cs := range circlSchemes {
if cs.sigType == sigType {
return cs.scheme
}
}
return nil
}
func sigTypeByCirclScheme(scheme circlSign.Scheme) uint8 {
for _, cs := range circlSchemes {
if cs.scheme == scheme {
return cs.sigType
}
}
return 0
}
var supportedSignatureAlgorithmsWithCircl []SignatureScheme
// supportedSignatureAlgorithms returns enabled signature schemes. PQ signature
// schemes are only included when tls.Config#PQSignatureSchemesEnabled is set.
func (c *Config) supportedSignatureAlgorithms() []SignatureScheme {
if c != nil && c.PQSignatureSchemesEnabled {
return supportedSignatureAlgorithmsWithCircl
}
return supportedSignatureAlgorithms
}
func init() {
supportedSignatureAlgorithmsWithCircl = append([]SignatureScheme{}, supportedSignatureAlgorithms...)
for _, cs := range circlSchemes {
supportedSignatureAlgorithmsWithCircl = append(supportedSignatureAlgorithmsWithCircl,
SignatureScheme(cs.scheme.(circlPki.TLSScheme).TLSIdentifier()))
}
}
// CFEvent is a value emitted at various points in the handshake that is
// handled by the callback Config.CFEventHandler.
type CFEvent interface {
Name() string
}
// CFEventTLS13ClientHandshakeTimingInfo carries intra-stack time durations for
// TLS 1.3 client-state machine changes. It can be used for tracking metrics
// during a connection. Some durations may be sensitive, such as the amount of
// time to process a particular handshake message, so this event should only be
// used for experimental purposes.
type CFEventTLS13ClientHandshakeTimingInfo struct {
timer func() time.Time
start time.Time
WriteClientHello time.Duration
ProcessServerHello time.Duration
ReadEncryptedExtensions time.Duration
ReadCertificate time.Duration
ReadCertificateVerify time.Duration
ReadServerFinished time.Duration
WriteCertificate time.Duration
WriteCertificateVerify time.Duration
WriteClientFinished time.Duration
}
// Name is required by the CFEvent interface.
func (e CFEventTLS13ClientHandshakeTimingInfo) Name() string {
return "TLS13ClientHandshakeTimingInfo"
}
func (e CFEventTLS13ClientHandshakeTimingInfo) elapsedTime() time.Duration {
if e.timer == nil {
return 0
}
return e.timer().Sub(e.start)
}
func createTLS13ClientHandshakeTimingInfo(timerFunc func() time.Time) CFEventTLS13ClientHandshakeTimingInfo {
timer := time.Now
if timerFunc != nil {
timer = timerFunc
}
return CFEventTLS13ClientHandshakeTimingInfo{
timer: timer,
start: timer(),
}
}
// CFEventTLS13ServerHandshakeTimingInfo carries intra-stack time durations
// for TLS 1.3 state machine changes. It can be used for tracking metrics during a
// connection. Some durations may be sensitive, such as the amount of time to
// process a particular handshake message, so this event should only be used
// for experimental purposes.
type CFEventTLS13ServerHandshakeTimingInfo struct {
timer func() time.Time
start time.Time
ProcessClientHello time.Duration
WriteServerHello time.Duration
WriteEncryptedExtensions time.Duration
WriteCertificate time.Duration
WriteCertificateVerify time.Duration
WriteServerFinished time.Duration
ReadCertificate time.Duration
ReadCertificateVerify time.Duration
ReadClientFinished time.Duration
}
// Name is required by the CFEvent interface.
func (e CFEventTLS13ServerHandshakeTimingInfo) Name() string {
return "TLS13ServerHandshakeTimingInfo"
}
func (e CFEventTLS13ServerHandshakeTimingInfo) elapsedTime() time.Duration {
if e.timer == nil {
return 0
}
return e.timer().Sub(e.start)
}
func createTLS13ServerHandshakeTimingInfo(timerFunc func() time.Time) CFEventTLS13ServerHandshakeTimingInfo {
timer := time.Now
if timerFunc != nil {
timer = timerFunc
}
return CFEventTLS13ServerHandshakeTimingInfo{
timer: timer,
start: timer(),
}
}
// CFEventECHClientStatus is emitted once it is known whether the client
// bypassed, offered, or greased ECH.
type CFEventECHClientStatus int
// Bypassed returns true if the client bypassed ECH.
func (e CFEventECHClientStatus) Bypassed() bool {
return e == echStatusBypassed
}
// Offered returns true if the client offered ECH.
func (e CFEventECHClientStatus) Offered() bool {
return e == echStatusInner
}
// Greased returns true if the client greased ECH.
func (e CFEventECHClientStatus) Greased() bool {
return e == echStatusOuter
}
// Name is required by the CFEvent interface.
func (e CFEventECHClientStatus) Name() string {
return "ech client status"
}
// CFEventECHServerStatus is emitted once it is known whether the client
// bypassed, offered, or greased ECH.
type CFEventECHServerStatus int
// Bypassed returns true if the client bypassed ECH.
func (e CFEventECHServerStatus) Bypassed() bool {
return e == echStatusBypassed
}
// Accepted returns true if the client offered ECH.
func (e CFEventECHServerStatus) Accepted() bool {
return e == echStatusInner
}
// Rejected returns true if the client greased ECH.
func (e CFEventECHServerStatus) Rejected() bool {
return e == echStatusOuter
}
// Name is required by the CFEvent interface.
func (e CFEventECHServerStatus) Name() string {
return "ech server status"
}
// CFEventECHPublicNameMismatch is emitted if the outer SNI does not match
// match the public name of the ECH configuration. Note that we do not record
// the outer SNI in order to avoid collecting this potentially sensitive data.
type CFEventECHPublicNameMismatch struct{}
// Name is required by the CFEvent interface.
func (e CFEventECHPublicNameMismatch) Name() string {
return "ech public name does not match outer sni"
}
// For backwards compatibility.
type CFEventTLS13NegotiatedKEX = CFEventTLSNegotiatedNamedKEX
// CFEventTLSNegotiatedNamedKEX is emitted when a key agreement mechanism has been
// established that uses a named group. This includes all key agreements
// in TLSv1.3, but excludes RSA and DH in TLS 1.2 and earlier.
type CFEventTLSNegotiatedNamedKEX struct {
KEX CurveID
}
func (e CFEventTLSNegotiatedNamedKEX) Name() string {
return "CFEventTLSNegotiatedNamedKEX"
}
// CFEventTLS13HRR is emitted when a HRR is sent or received
type CFEventTLS13HRR struct{}
func (e CFEventTLS13HRR) Name() string {
return "CFEventTLS13HRR"
}