ssl/test/runner/prf.go - third_party/github/google/boringssl - Git at Google

 // 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 runner

 import (
 	"crypto"
 	"crypto/hkdf"
 	"crypto/hmac"
 	"crypto/md5"
 	"crypto/sha1"
 	"crypto/sha256"
 	"encoding"
 	"hash"

 	"golang.org/x/crypto/cryptobyte"
 )

 // copyHash returns a copy of |h|, which must be an instance of |hashType|.
 func copyHash(h hash.Hash, hash crypto.Hash) hash.Hash {
 	// While hash.Hash is not copyable, the documentation says all standard
 	// library hash.Hash implementations implement BinaryMarshaler and
 	// BinaryUnmarshaler interfaces.
 	m, ok := h.(encoding.BinaryMarshaler)
 	if !ok {
 		panic("hash did not implement encoding.BinaryMarshaler")
 	}
 	data, err := m.MarshalBinary()
 	if err != nil {
 		panic(err)
 	}
 	ret := hash.New()
 	u, ok := ret.(encoding.BinaryUnmarshaler)
 	if !ok {
 		panic("hash did not implement BinaryUnmarshaler")
 	}
 	if err := u.UnmarshalBinary(data); err != nil {
 		panic(err)
 	}
 	return ret
 }

 // 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)
 		todo := len(b)
 		if j+todo > len(result) {
 			todo = len(result) - j
 		}
 		copy(result[j:j+todo], b)
 		j += todo

 		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 (
 	tlsRandomLength      = 32 // Length of a random nonce in TLS 1.1.
 	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")
 var extendedMasterSecretLabel = []byte("extended master secret")
 var keyExpansionLabel = []byte("key expansion")
 var clientFinishedLabel = []byte("client finished")
 var serverFinishedLabel = []byte("server finished")
 var finishedLabel = []byte("finished")
 var channelIDLabel = []byte("TLS Channel ID signature\x00")
 var channelIDResumeLabel = []byte("Resumption\x00")

 func prfForVersion(version uint16, suite *cipherSuite) func(result, secret, label, seed []byte) {
 	switch version {
 	case VersionTLS10, VersionTLS11:
 		return prf10
 	case VersionTLS12:
 		return prf12(suite.hash().New)
 	}
 	panic("unknown version")
 }

 // masterFromPreMasterSecret generates the master secret from the pre-master
 // secret. See http://tools.ietf.org/html/rfc5246#section-8.1
 func masterFromPreMasterSecret(version uint16, suite *cipherSuite, preMasterSecret, clientRandom, serverRandom []byte) []byte {
 	var seed [tlsRandomLength * 2]byte
 	copy(seed[0:len(clientRandom)], clientRandom)
 	copy(seed[len(clientRandom):], serverRandom)
 	masterSecret := make([]byte, masterSecretLength)
 	prfForVersion(version, suite)(masterSecret, preMasterSecret, masterSecretLabel, seed[0:])
 	return masterSecret
 }

 // extendedMasterFromPreMasterSecret generates the master secret from the
 // pre-master secret when the Triple Handshake fix is in effect. See
 // https://tools.ietf.org/html/rfc7627
 func extendedMasterFromPreMasterSecret(version uint16, suite *cipherSuite, preMasterSecret []byte, h finishedHash) []byte {
 	masterSecret := make([]byte, masterSecretLength)
 	prfForVersion(version, suite)(masterSecret, preMasterSecret, extendedMasterSecretLabel, h.Sum())
 	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) {
 	var seed [tlsRandomLength * 2]byte
 	copy(seed[0:len(clientRandom)], serverRandom)
 	copy(seed[len(serverRandom):], clientRandom)

 	n := 2*macLen + 2*keyLen + 2*ivLen
 	keyMaterial := make([]byte, n)
 	prfForVersion(version, suite)(keyMaterial, masterSecret, keyExpansionLabel, seed[0:])
 	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(wireVersion uint16, isDTLS bool, cipherSuite *cipherSuite) finishedHash {
 	version, ok := wireToVersion(wireVersion, isDTLS)
 	if !ok {
 		panic("unknown version")
 	}

 	var ret finishedHash
 	if version >= VersionTLS12 {
 		ret.hash = cipherSuite.hash().New()

 		if version == VersionTLS12 {
 			ret.prf = prf12(cipherSuite.hash().New)
 		} else {
 			ret.secret = make([]byte, ret.hash.Size())
 		}
 	} else {
 		ret.hash = sha1.New()
 		ret.md5 = md5.New()

 		ret.prf = prf10
 	}

 	ret.suite = cipherSuite
 	ret.buffer = []byte{}
 	ret.version = version
 	ret.wireVersion = wireVersion
 	ret.isDTLS = isDTLS
 	return ret
 }

 // A finishedHash calculates the hash of a set of handshake messages suitable
 // for including in a Finished message.
 type finishedHash struct {
 	suite *cipherSuite

 	// hash maintains a running hash of handshake messages. In TLS 1.2 and up,
 	// the hash is determined from suite.hash(). In TLS 1.0 and 1.1, this is the
 	// SHA-1 half of the MD5/SHA-1 concatenation.
 	hash hash.Hash

 	// md5 is the MD5 half of the TLS 1.0 and 1.1 MD5/SHA1 concatenation.
 	md5 hash.Hash

 	// In TLS 1.2, a full buffer is required.
 	buffer []byte

 	version     uint16
 	wireVersion uint16
 	isDTLS      bool
 	prf         func(result, secret, label, seed []byte)

 	// secret, in TLS 1.3, is the running input secret.
 	secret []byte
 }

 func (h *finishedHash) UpdateForHelloRetryRequest() {
 	data := cryptobyte.NewBuilder(nil)
 	data.AddUint8(typeMessageHash)
 	data.AddUint24(uint32(h.hash.Size()))
 	data.AddBytes(h.Sum())
 	h.hash = h.suite.hash().New()
 	if h.buffer != nil {
 		h.buffer = []byte{}
 	}
 	h.Write(data.BytesOrPanic())
 }

 func (h *finishedHash) Write(msg []byte) (n int, err error) {
 	h.hash.Write(msg)

 	if h.version < VersionTLS12 {
 		h.md5.Write(msg)
 	}

 	if h.buffer != nil {
 		h.buffer = append(h.buffer, msg...)
 	}

 	return len(msg), nil
 }

 // WriteHandshake appends |msg| to the hash, which must be a serialized
 // handshake message with a TLS header. In DTLS, the header is rewritten to a
 // DTLS header with |seqno| as the sequence number.
 func (h *finishedHash) WriteHandshake(msg []byte, seqno uint16) {
 	if h.isDTLS && h.version <= VersionTLS12 {
 		// This is somewhat hacky. DTLS <= 1.2 hashes a slightly different format. (DTLS 1.3 uses the same format as TLS.)
 		// First, the TLS header.
 		h.Write(msg[:4])
 		// Then the sequence number and reassembled fragment offset (always 0).
 		h.Write([]byte{byte(seqno >> 8), byte(seqno), 0, 0, 0})
 		// Then the reassembled fragment (always equal to the message length).
 		h.Write(msg[1:4])
 		// And then the message body.
 		h.Write(msg[4:])
 	} else {
 		h.Write(msg)
 	}
 }

 func (h finishedHash) Sum() []byte {
 	if h.version >= VersionTLS12 {
 		return h.hash.Sum(nil)
 	}

 	out := make([]byte, 0, md5.Size+sha1.Size)
 	out = h.md5.Sum(out)
 	return h.hash.Sum(out)
 }

 // clientSum returns the contents of the verify_data member of a client's
 // Finished message.
 func (h finishedHash) clientSum(baseKey []byte) []byte {
 	if h.version < VersionTLS13 {
 		out := make([]byte, finishedVerifyLength)
 		h.prf(out, baseKey, clientFinishedLabel, h.Sum())
 		return out
 	}

 	clientFinishedKey := hkdfExpandLabel(h.suite.hash(), baseKey, finishedLabel, nil, h.hash.Size(), h.isDTLS)
 	finishedHMAC := hmac.New(h.suite.hash().New, clientFinishedKey)
 	finishedHMAC.Write(h.appendContextHashes(nil))
 	return finishedHMAC.Sum(nil)
 }

 // serverSum returns the contents of the verify_data member of a server's
 // Finished message.
 func (h finishedHash) serverSum(baseKey []byte) []byte {
 	if h.version < VersionTLS13 {
 		out := make([]byte, finishedVerifyLength)
 		h.prf(out, baseKey, serverFinishedLabel, h.Sum())
 		return out
 	}

 	serverFinishedKey := hkdfExpandLabel(h.suite.hash(), baseKey, finishedLabel, nil, h.hash.Size(), h.isDTLS)
 	finishedHMAC := hmac.New(h.suite.hash().New, serverFinishedKey)
 	finishedHMAC.Write(h.appendContextHashes(nil))
 	return finishedHMAC.Sum(nil)
 }

 // hashForChannelID returns the hash to be signed for TLS Channel
 // ID. If a resumption, resumeHash has the previous handshake
 // hash. Otherwise, it is nil.
 func (h finishedHash) hashForChannelID(resumeHash []byte) []byte {
 	hash := sha256.New()
 	hash.Write(channelIDLabel)
 	if resumeHash != nil {
 		hash.Write(channelIDResumeLabel)
 		hash.Write(resumeHash)
 	}
 	hash.Write(h.Sum())
 	return hash.Sum(nil)
 }

 // discardHandshakeBuffer is called when there is no more need to
 // buffer the entirety of the handshake messages.
 func (h *finishedHash) discardHandshakeBuffer() {
 	h.buffer = nil
 }

 // zeroSecretTLS13 returns the default all zeros secret for TLS 1.3, used when a
 // given secret is not available in the handshake. See RFC 8446, section 7.1.
 func (h *finishedHash) zeroSecret() []byte {
 	return make([]byte, h.hash.Size())
 }

 // addEntropy incorporates ikm into the running TLS 1.3 secret with HKDF-Expand.
 func (h *finishedHash) addEntropy(ikm []byte) {
 	var err error
 	h.secret, err = hkdf.Extract(h.suite.hash().New, ikm, h.secret)
 	if err != nil {
 		panic(err)
 	}
 }

 func (h *finishedHash) nextSecret() {
 	h.secret = hkdfExpandLabel(h.suite.hash(), h.secret, []byte("derived"), h.suite.hash().New().Sum(nil), h.hash.Size(), h.isDTLS)
 }

 // hkdfExpandLabel implements TLS 1.3's HKDF-Expand-Label function, as defined
 // in section 7.1 of RFC 8446.
 func hkdfExpandLabel(hash crypto.Hash, secret, label, hashValue []byte, length int, isDTLS bool) []byte {
 	if len(label) > 255 || len(hashValue) > 255 {
 		panic("hkdfExpandLabel: label or hashValue too long")
 	}

 	versionLabel := []byte("tls13 ")
 	if isDTLS {
 		versionLabel = []byte("dtls13")
 	}
 	hkdfLabel := make([]byte, 3+len(versionLabel)+len(label)+1+len(hashValue))
 	x := hkdfLabel
 	x[0] = byte(length >> 8)
 	x[1] = byte(length)
 	x[2] = byte(len(versionLabel) + len(label))
 	x = x[3:]
 	copy(x, versionLabel)
 	x = x[len(versionLabel):]
 	copy(x, label)
 	x = x[len(label):]
 	x[0] = byte(len(hashValue))
 	copy(x[1:], hashValue)
 	ret, err := hkdf.Expand(hash.New, secret, string(hkdfLabel), length)
 	if err != nil {
 		panic(err)
 	}
 	return ret
 }

 // appendContextHashes returns the concatenation of the handshake hash and the
 // resumption context hash, as used in TLS 1.3.
 func (h *finishedHash) appendContextHashes(b []byte) []byte {
 	b = h.hash.Sum(b)
 	return b
 }

 var (
 	externalPSKBinderLabel        = []byte("ext binder")
 	resumptionPSKBinderLabel      = []byte("res binder")
 	earlyTrafficLabel             = []byte("c e traffic")
 	clientHandshakeTrafficLabel   = []byte("c hs traffic")
 	serverHandshakeTrafficLabel   = []byte("s hs traffic")
 	clientApplicationTrafficLabel = []byte("c ap traffic")
 	serverApplicationTrafficLabel = []byte("s ap traffic")
 	applicationTrafficLabel       = []byte("traffic upd")
 	earlyExporterLabel            = []byte("e exp master")
 	exporterLabel                 = []byte("exp master")
 	resumptionLabel               = []byte("res master")

 	resumptionPSKLabel = []byte("resumption")

 	echAcceptConfirmationLabel    = []byte("ech accept confirmation")
 	echAcceptConfirmationHRRLabel = []byte("hrr ech accept confirmation")
 )

 // deriveSecret implements TLS 1.3's Derive-Secret function, as defined in
 // section 7.1 of RFC8446.
 func (h *finishedHash) deriveSecret(label []byte) []byte {
 	return hkdfExpandLabel(h.suite.hash(), h.secret, label, h.appendContextHashes(nil), h.hash.Size(), h.isDTLS)
 }

 // echAcceptConfirmation computes the ECH accept confirmation signal, as defined
 // in sections 7.2 and 7.2.1 of draft-ietf-tls-esni-13. The transcript hash is
 // computed by concatenating |h| with |extraMessages|.
 func (h *finishedHash) echAcceptConfirmation(clientRandom, label, extraMessages []byte) []byte {
 	secret, err := hkdf.Extract(h.suite.hash().New, clientRandom, h.zeroSecret())
 	if err != nil {
 		panic(err)
 	}
 	hashCopy := copyHash(h.hash, h.suite.hash())
 	hashCopy.Write(extraMessages)
 	return hkdfExpandLabel(h.suite.hash(), secret, label, hashCopy.Sum(nil), echAcceptConfirmationLength, h.isDTLS)
 }

 // The following are context strings for CertificateVerify in TLS 1.3.
 var (
 	clientCertificateVerifyContextTLS13 = []byte("TLS 1.3, client CertificateVerify")
 	serverCertificateVerifyContextTLS13 = []byte("TLS 1.3, server CertificateVerify")
 	channelIDContextTLS13               = []byte("TLS 1.3, Channel ID")
 )

 // certificateVerifyMessage returns the input to be signed for CertificateVerify
 // in TLS 1.3.
 func (h *finishedHash) certificateVerifyInput(context []byte) []byte {
 	const paddingLen = 64
 	b := make([]byte, paddingLen, paddingLen+len(context)+1+2*h.hash.Size())
 	for i := 0; i < paddingLen; i++ {
 		b[i] = 32
 	}
 	b = append(b, context...)
 	b = append(b, 0)
 	b = h.appendContextHashes(b)
 	return b
 }

 type trafficDirection int

 const (
 	clientWrite trafficDirection = iota
 	serverWrite
 )

 var (
 	keyTLS13 = []byte("key")
 	ivTLS13  = []byte("iv")
 )

 // deriveTrafficAEAD derives traffic keys and constructs an AEAD given a traffic
 // secret.
 func deriveTrafficAEAD(version uint16, suite *cipherSuite, secret []byte, side trafficDirection, isDTLS bool) any {
 	key := hkdfExpandLabel(suite.hash(), secret, keyTLS13, nil, suite.keyLen, isDTLS)
 	iv := hkdfExpandLabel(suite.hash(), secret, ivTLS13, nil, suite.ivLen(version), isDTLS)

 	return suite.aead(version, key, iv)
 }

 func updateTrafficSecret(hash crypto.Hash, version uint16, secret []byte, isDTLS bool) []byte {
 	return hkdfExpandLabel(hash, secret, applicationTrafficLabel, nil, hash.Size(), isDTLS)
 }

 func computePSKBinder(psk []byte, version uint16, isDTLS bool, label []byte, cipherSuite *cipherSuite, clientHello, helloRetryRequest, truncatedHello []byte) []byte {
 	finishedHash := newFinishedHash(version, isDTLS, cipherSuite)
 	finishedHash.addEntropy(psk)
 	binderKey := finishedHash.deriveSecret(label)
 	finishedHash.Write(clientHello)
 	if len(helloRetryRequest) != 0 {
 		finishedHash.UpdateForHelloRetryRequest()
 	}
 	finishedHash.Write(helloRetryRequest)
 	finishedHash.Write(truncatedHello)
 	return finishedHash.clientSum(binderKey)
 }

 func deriveSessionPSK(suite *cipherSuite, version uint16, masterSecret []byte, nonce []byte, isDTLS bool) []byte {
 	hash := suite.hash()
 	return hkdfExpandLabel(hash, masterSecret, resumptionPSKLabel, nonce, hash.Size(), isDTLS)
 }
	// 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 runner

	import (
	"crypto"
	"crypto/hkdf"
	"crypto/hmac"
	"crypto/md5"
	"crypto/sha1"
	"crypto/sha256"
	"encoding"
	"hash"

	"golang.org/x/crypto/cryptobyte"
	)

	// copyHash returns a copy of \|h\|, which must be an instance of \|hashType\|.
	func copyHash(h hash.Hash, hash crypto.Hash) hash.Hash {
	// While hash.Hash is not copyable, the documentation says all standard
	// library hash.Hash implementations implement BinaryMarshaler and
	// BinaryUnmarshaler interfaces.
	m, ok := h.(encoding.BinaryMarshaler)
	if !ok {
	panic("hash did not implement encoding.BinaryMarshaler")
	}
	data, err := m.MarshalBinary()
	if err != nil {
	panic(err)
	}
	ret := hash.New()
	u, ok := ret.(encoding.BinaryUnmarshaler)
	if !ok {
	panic("hash did not implement BinaryUnmarshaler")
	}
	if err := u.UnmarshalBinary(data); err != nil {
	panic(err)
	}
	return ret
	}

	// 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)
	todo := len(b)
	if j+todo > len(result) {
	todo = len(result) - j
	}
	copy(result[j:j+todo], b)
	j += todo

	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 (
	tlsRandomLength = 32 // Length of a random nonce in TLS 1.1.
	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")
	var extendedMasterSecretLabel = []byte("extended master secret")
	var keyExpansionLabel = []byte("key expansion")
	var clientFinishedLabel = []byte("client finished")
	var serverFinishedLabel = []byte("server finished")
	var finishedLabel = []byte("finished")
	var channelIDLabel = []byte("TLS Channel ID signature\x00")
	var channelIDResumeLabel = []byte("Resumption\x00")

	func prfForVersion(version uint16, suite *cipherSuite) func(result, secret, label, seed []byte) {
	switch version {
	case VersionTLS10, VersionTLS11:
	return prf10
	case VersionTLS12:
	return prf12(suite.hash().New)
	}
	panic("unknown version")
	}

	// masterFromPreMasterSecret generates the master secret from the pre-master
	// secret. See http://tools.ietf.org/html/rfc5246#section-8.1
	func masterFromPreMasterSecret(version uint16, suite *cipherSuite, preMasterSecret, clientRandom, serverRandom []byte) []byte {
	var seed [tlsRandomLength * 2]byte
	copy(seed[0:len(clientRandom)], clientRandom)
	copy(seed[len(clientRandom):], serverRandom)
	masterSecret := make([]byte, masterSecretLength)
	prfForVersion(version, suite)(masterSecret, preMasterSecret, masterSecretLabel, seed[0:])
	return masterSecret
	}

	// extendedMasterFromPreMasterSecret generates the master secret from the
	// pre-master secret when the Triple Handshake fix is in effect. See
	// https://tools.ietf.org/html/rfc7627
	func extendedMasterFromPreMasterSecret(version uint16, suite *cipherSuite, preMasterSecret []byte, h finishedHash) []byte {
	masterSecret := make([]byte, masterSecretLength)
	prfForVersion(version, suite)(masterSecret, preMasterSecret, extendedMasterSecretLabel, h.Sum())
	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) {
	var seed [tlsRandomLength * 2]byte
	copy(seed[0:len(clientRandom)], serverRandom)
	copy(seed[len(serverRandom):], clientRandom)

	n := 2macLen + 2keyLen + 2*ivLen
	keyMaterial := make([]byte, n)
	prfForVersion(version, suite)(keyMaterial, masterSecret, keyExpansionLabel, seed[0:])
	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(wireVersion uint16, isDTLS bool, cipherSuite *cipherSuite) finishedHash {
	version, ok := wireToVersion(wireVersion, isDTLS)
	if !ok {
	panic("unknown version")
	}

	var ret finishedHash
	if version >= VersionTLS12 {
	ret.hash = cipherSuite.hash().New()

	if version == VersionTLS12 {
	ret.prf = prf12(cipherSuite.hash().New)
	} else {
	ret.secret = make([]byte, ret.hash.Size())
	}
	} else {
	ret.hash = sha1.New()
	ret.md5 = md5.New()

	ret.prf = prf10
	}

	ret.suite = cipherSuite
	ret.buffer = []byte{}
	ret.version = version
	ret.wireVersion = wireVersion
	ret.isDTLS = isDTLS
	return ret
	}

	// A finishedHash calculates the hash of a set of handshake messages suitable
	// for including in a Finished message.
	type finishedHash struct {
	suite *cipherSuite

	// hash maintains a running hash of handshake messages. In TLS 1.2 and up,
	// the hash is determined from suite.hash(). In TLS 1.0 and 1.1, this is the
	// SHA-1 half of the MD5/SHA-1 concatenation.
	hash hash.Hash

	// md5 is the MD5 half of the TLS 1.0 and 1.1 MD5/SHA1 concatenation.
	md5 hash.Hash

	// In TLS 1.2, a full buffer is required.
	buffer []byte

	version uint16
	wireVersion uint16
	isDTLS bool
	prf func(result, secret, label, seed []byte)

	// secret, in TLS 1.3, is the running input secret.
	secret []byte
	}

	func (h *finishedHash) UpdateForHelloRetryRequest() {
	data := cryptobyte.NewBuilder(nil)
	data.AddUint8(typeMessageHash)
	data.AddUint24(uint32(h.hash.Size()))
	data.AddBytes(h.Sum())
	h.hash = h.suite.hash().New()
	if h.buffer != nil {
	h.buffer = []byte{}
	}
	h.Write(data.BytesOrPanic())
	}

	func (h *finishedHash) Write(msg []byte) (n int, err error) {
	h.hash.Write(msg)

	if h.version < VersionTLS12 {
	h.md5.Write(msg)
	}

	if h.buffer != nil {
	h.buffer = append(h.buffer, msg...)
	}

	return len(msg), nil
	}

	// WriteHandshake appends \|msg\| to the hash, which must be a serialized
	// handshake message with a TLS header. In DTLS, the header is rewritten to a
	// DTLS header with \|seqno\| as the sequence number.
	func (h *finishedHash) WriteHandshake(msg []byte, seqno uint16) {
	if h.isDTLS && h.version <= VersionTLS12 {
	// This is somewhat hacky. DTLS <= 1.2 hashes a slightly different format. (DTLS 1.3 uses the same format as TLS.)
	// First, the TLS header.
	h.Write(msg[:4])
	// Then the sequence number and reassembled fragment offset (always 0).
	h.Write([]byte{byte(seqno >> 8), byte(seqno), 0, 0, 0})
	// Then the reassembled fragment (always equal to the message length).
	h.Write(msg[1:4])
	// And then the message body.
	h.Write(msg[4:])
	} else {
	h.Write(msg)
	}
	}

	func (h finishedHash) Sum() []byte {
	if h.version >= VersionTLS12 {
	return h.hash.Sum(nil)
	}

	out := make([]byte, 0, md5.Size+sha1.Size)
	out = h.md5.Sum(out)
	return h.hash.Sum(out)
	}

	// clientSum returns the contents of the verify_data member of a client's
	// Finished message.
	func (h finishedHash) clientSum(baseKey []byte) []byte {
	if h.version < VersionTLS13 {
	out := make([]byte, finishedVerifyLength)
	h.prf(out, baseKey, clientFinishedLabel, h.Sum())
	return out
	}

	clientFinishedKey := hkdfExpandLabel(h.suite.hash(), baseKey, finishedLabel, nil, h.hash.Size(), h.isDTLS)
	finishedHMAC := hmac.New(h.suite.hash().New, clientFinishedKey)
	finishedHMAC.Write(h.appendContextHashes(nil))
	return finishedHMAC.Sum(nil)
	}

	// serverSum returns the contents of the verify_data member of a server's
	// Finished message.
	func (h finishedHash) serverSum(baseKey []byte) []byte {
	if h.version < VersionTLS13 {
	out := make([]byte, finishedVerifyLength)
	h.prf(out, baseKey, serverFinishedLabel, h.Sum())
	return out
	}

	serverFinishedKey := hkdfExpandLabel(h.suite.hash(), baseKey, finishedLabel, nil, h.hash.Size(), h.isDTLS)
	finishedHMAC := hmac.New(h.suite.hash().New, serverFinishedKey)
	finishedHMAC.Write(h.appendContextHashes(nil))
	return finishedHMAC.Sum(nil)
	}

	// hashForChannelID returns the hash to be signed for TLS Channel
	// ID. If a resumption, resumeHash has the previous handshake
	// hash. Otherwise, it is nil.
	func (h finishedHash) hashForChannelID(resumeHash []byte) []byte {
	hash := sha256.New()
	hash.Write(channelIDLabel)
	if resumeHash != nil {
	hash.Write(channelIDResumeLabel)
	hash.Write(resumeHash)
	}
	hash.Write(h.Sum())
	return hash.Sum(nil)
	}

	// discardHandshakeBuffer is called when there is no more need to
	// buffer the entirety of the handshake messages.
	func (h *finishedHash) discardHandshakeBuffer() {
	h.buffer = nil
	}

	// zeroSecretTLS13 returns the default all zeros secret for TLS 1.3, used when a
	// given secret is not available in the handshake. See RFC 8446, section 7.1.
	func (h *finishedHash) zeroSecret() []byte {
	return make([]byte, h.hash.Size())
	}

	// addEntropy incorporates ikm into the running TLS 1.3 secret with HKDF-Expand.
	func (h *finishedHash) addEntropy(ikm []byte) {
	var err error
	h.secret, err = hkdf.Extract(h.suite.hash().New, ikm, h.secret)
	if err != nil {
	panic(err)
	}
	}

	func (h *finishedHash) nextSecret() {
	h.secret = hkdfExpandLabel(h.suite.hash(), h.secret, []byte("derived"), h.suite.hash().New().Sum(nil), h.hash.Size(), h.isDTLS)
	}

	// hkdfExpandLabel implements TLS 1.3's HKDF-Expand-Label function, as defined
	// in section 7.1 of RFC 8446.
	func hkdfExpandLabel(hash crypto.Hash, secret, label, hashValue []byte, length int, isDTLS bool) []byte {
	if len(label) > 255 \|\| len(hashValue) > 255 {
	panic("hkdfExpandLabel: label or hashValue too long")
	}

	versionLabel := []byte("tls13 ")
	if isDTLS {
	versionLabel = []byte("dtls13")
	}
	hkdfLabel := make([]byte, 3+len(versionLabel)+len(label)+1+len(hashValue))
	x := hkdfLabel
	x[0] = byte(length >> 8)
	x[1] = byte(length)
	x[2] = byte(len(versionLabel) + len(label))
	x = x[3:]
	copy(x, versionLabel)
	x = x[len(versionLabel):]
	copy(x, label)
	x = x[len(label):]
	x[0] = byte(len(hashValue))
	copy(x[1:], hashValue)
	ret, err := hkdf.Expand(hash.New, secret, string(hkdfLabel), length)
	if err != nil {
	panic(err)
	}
	return ret
	}

	// appendContextHashes returns the concatenation of the handshake hash and the
	// resumption context hash, as used in TLS 1.3.
	func (h *finishedHash) appendContextHashes(b []byte) []byte {
	b = h.hash.Sum(b)
	return b
	}

	var (
	externalPSKBinderLabel = []byte("ext binder")
	resumptionPSKBinderLabel = []byte("res binder")
	earlyTrafficLabel = []byte("c e traffic")
	clientHandshakeTrafficLabel = []byte("c hs traffic")
	serverHandshakeTrafficLabel = []byte("s hs traffic")
	clientApplicationTrafficLabel = []byte("c ap traffic")
	serverApplicationTrafficLabel = []byte("s ap traffic")
	applicationTrafficLabel = []byte("traffic upd")
	earlyExporterLabel = []byte("e exp master")
	exporterLabel = []byte("exp master")
	resumptionLabel = []byte("res master")

	resumptionPSKLabel = []byte("resumption")

	echAcceptConfirmationLabel = []byte("ech accept confirmation")
	echAcceptConfirmationHRRLabel = []byte("hrr ech accept confirmation")
	)

	// deriveSecret implements TLS 1.3's Derive-Secret function, as defined in
	// section 7.1 of RFC8446.
	func (h *finishedHash) deriveSecret(label []byte) []byte {
	return hkdfExpandLabel(h.suite.hash(), h.secret, label, h.appendContextHashes(nil), h.hash.Size(), h.isDTLS)
	}

	// echAcceptConfirmation computes the ECH accept confirmation signal, as defined
	// in sections 7.2 and 7.2.1 of draft-ietf-tls-esni-13. The transcript hash is
	// computed by concatenating \|h\| with \|extraMessages\|.
	func (h *finishedHash) echAcceptConfirmation(clientRandom, label, extraMessages []byte) []byte {
	secret, err := hkdf.Extract(h.suite.hash().New, clientRandom, h.zeroSecret())
	if err != nil {
	panic(err)
	}
	hashCopy := copyHash(h.hash, h.suite.hash())
	hashCopy.Write(extraMessages)
	return hkdfExpandLabel(h.suite.hash(), secret, label, hashCopy.Sum(nil), echAcceptConfirmationLength, h.isDTLS)
	}

	// The following are context strings for CertificateVerify in TLS 1.3.
	var (
	clientCertificateVerifyContextTLS13 = []byte("TLS 1.3, client CertificateVerify")
	serverCertificateVerifyContextTLS13 = []byte("TLS 1.3, server CertificateVerify")
	channelIDContextTLS13 = []byte("TLS 1.3, Channel ID")
	)

	// certificateVerifyMessage returns the input to be signed for CertificateVerify
	// in TLS 1.3.
	func (h *finishedHash) certificateVerifyInput(context []byte) []byte {
	const paddingLen = 64
	b := make([]byte, paddingLen, paddingLen+len(context)+1+2*h.hash.Size())
	for i := 0; i < paddingLen; i++ {
	b[i] = 32
	}
	b = append(b, context...)
	b = append(b, 0)
	b = h.appendContextHashes(b)
	return b
	}

	type trafficDirection int

	const (
	clientWrite trafficDirection = iota
	serverWrite
	)

	var (
	keyTLS13 = []byte("key")
	ivTLS13 = []byte("iv")
	)

	// deriveTrafficAEAD derives traffic keys and constructs an AEAD given a traffic
	// secret.
	func deriveTrafficAEAD(version uint16, suite *cipherSuite, secret []byte, side trafficDirection, isDTLS bool) any {
	key := hkdfExpandLabel(suite.hash(), secret, keyTLS13, nil, suite.keyLen, isDTLS)
	iv := hkdfExpandLabel(suite.hash(), secret, ivTLS13, nil, suite.ivLen(version), isDTLS)

	return suite.aead(version, key, iv)
	}

	func updateTrafficSecret(hash crypto.Hash, version uint16, secret []byte, isDTLS bool) []byte {
	return hkdfExpandLabel(hash, secret, applicationTrafficLabel, nil, hash.Size(), isDTLS)
	}

	func computePSKBinder(psk []byte, version uint16, isDTLS bool, label []byte, cipherSuite *cipherSuite, clientHello, helloRetryRequest, truncatedHello []byte) []byte {
	finishedHash := newFinishedHash(version, isDTLS, cipherSuite)
	finishedHash.addEntropy(psk)
	binderKey := finishedHash.deriveSecret(label)
	finishedHash.Write(clientHello)
	if len(helloRetryRequest) != 0 {
	finishedHash.UpdateForHelloRetryRequest()
	}
	finishedHash.Write(helloRetryRequest)
	finishedHash.Write(truncatedHello)
	return finishedHash.clientSum(binderKey)
	}

	func deriveSessionPSK(suite *cipherSuite, version uint16, masterSecret []byte, nonce []byte, isDTLS bool) []byte {
	hash := suite.hash()
	return hkdfExpandLabel(hash, masterSecret, resumptionPSKLabel, nonce, hash.Size(), isDTLS)
	}