// 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/ecdsa" "crypto/elliptic" "crypto/md5" "crypto/rsa" "crypto/sha1" "crypto/sha256" "crypto/x509" "encoding/asn1" "errors" "io" "math/big" ) // 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) { preMasterSecret := make([]byte, 48) _, err := io.ReadFull(config.rand(), preMasterSecret[2:]) if err != nil { return nil, err } if len(ckx.ciphertext) < 2 { return nil, errors.New("bad ClientKeyExchange") } ciphertext := ckx.ciphertext if version != VersionSSL30 { ciphertextLen := int(ckx.ciphertext[0])<<8 | int(ckx.ciphertext[1]) if ciphertextLen != len(ckx.ciphertext)-2 { return nil, errors.New("bad ClientKeyExchange") } ciphertext = ckx.ciphertext[2:] } err = rsa.DecryptPKCS1v15SessionKey(config.rand(), cert.PrivateKey.(*rsa.PrivateKey), ciphertext, preMasterSecret) 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("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 } encrypted, err := rsa.EncryptPKCS1v15(config.rand(), cert.PublicKey.(*rsa.PublicKey), 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 } // sha256Hash implements TLS 1.2's hash function. func sha256Hash(slices [][]byte) []byte { h := sha256.New() for _, slice := range slices { h.Write(slice) } return h.Sum(nil) } // hashForServerKeyExchange hashes the given slices and returns their digest // and the identifier of the hash function used. The hashFunc argument is only // used for >= TLS 1.2 and precisely identifies the hash function to use. func hashForServerKeyExchange(sigType, hashFunc uint8, version uint16, slices ...[]byte) ([]byte, crypto.Hash, error) { if version >= VersionTLS12 { switch hashFunc { case hashSHA256: return sha256Hash(slices), crypto.SHA256, nil case hashSHA1: return sha1Hash(slices), crypto.SHA1, nil default: return nil, crypto.Hash(0), errors.New("tls: unknown hash function used by peer") } } if sigType == signatureECDSA { return sha1Hash(slices), crypto.SHA1, nil } return md5SHA1Hash(slices), crypto.MD5SHA1, nil } // pickTLS12HashForSignature returns a TLS 1.2 hash identifier for signing a // ServerKeyExchange given the signature type being used and the client's // advertized list of supported signature and hash combinations. func pickTLS12HashForSignature(sigType uint8, clientSignatureAndHashes []signatureAndHash) (uint8, error) { if len(clientSignatureAndHashes) == 0 { // If the client didn't specify any signature_algorithms // extension then we can assume that it supports SHA1. See // http://tools.ietf.org/html/rfc5246#section-7.4.1.4.1 return hashSHA1, nil } for _, sigAndHash := range clientSignatureAndHashes { if sigAndHash.signature != sigType { continue } switch sigAndHash.hash { case hashSHA1, hashSHA256: return sigAndHash.hash, nil } } return 0, errors.New("tls: client doesn't support any common hash functions") } // ecdheRSAKeyAgreement implements a TLS key agreement where the server // generates a ephemeral EC public/private key pair and signs it. The // pre-master secret is then calculated using ECDH. The signature may // either be ECDSA or RSA. type ecdheKeyAgreement struct { version uint16 sigType uint8 privateKey []byte curve elliptic.Curve x, y *big.Int } func (ka *ecdheKeyAgreement) generateServerKeyExchange(config *Config, cert *Certificate, clientHello *clientHelloMsg, hello *serverHelloMsg) (*serverKeyExchangeMsg, error) { var curveid uint16 Curve: for _, c := range clientHello.supportedCurves { switch c { case curveP256: ka.curve = elliptic.P256() curveid = c break Curve case curveP384: ka.curve = elliptic.P384() curveid = c break Curve case curveP521: ka.curve = elliptic.P521() curveid = c break Curve } } if curveid == 0 { return nil, errors.New("tls: no supported elliptic curves offered") } var x, y *big.Int var err error ka.privateKey, x, y, err = elliptic.GenerateKey(ka.curve, config.rand()) if err != nil { return nil, err } ecdhePublic := elliptic.Marshal(ka.curve, x, y) // http://tools.ietf.org/html/rfc4492#section-5.4 serverECDHParams := make([]byte, 1+2+1+len(ecdhePublic)) serverECDHParams[0] = 3 // named curve serverECDHParams[1] = byte(curveid >> 8) serverECDHParams[2] = byte(curveid) serverECDHParams[3] = byte(len(ecdhePublic)) copy(serverECDHParams[4:], ecdhePublic) var tls12HashId uint8 if ka.version >= VersionTLS12 { if tls12HashId, err = pickTLS12HashForSignature(ka.sigType, clientHello.signatureAndHashes); err != nil { return nil, err } } digest, hashFunc, err := hashForServerKeyExchange(ka.sigType, tls12HashId, ka.version, clientHello.random, hello.random, serverECDHParams) if err != nil { return nil, err } var sig []byte switch ka.sigType { case signatureECDSA: privKey, ok := cert.PrivateKey.(*ecdsa.PrivateKey) if !ok { return nil, errors.New("ECDHE ECDSA requires an ECDSA server private key") } r, s, err := ecdsa.Sign(config.rand(), privKey, digest) if err != nil { return nil, errors.New("failed to sign ECDHE parameters: " + err.Error()) } sig, err = asn1.Marshal(ecdsaSignature{r, s}) case signatureRSA: privKey, ok := cert.PrivateKey.(*rsa.PrivateKey) if !ok { return nil, errors.New("ECDHE RSA requires a RSA server private key") } sig, err = rsa.SignPKCS1v15(config.rand(), privKey, hashFunc, digest) if err != nil { return nil, errors.New("failed to sign ECDHE parameters: " + err.Error()) } default: return nil, errors.New("unknown ECDHE signature algorithm") } skx := new(serverKeyExchangeMsg) sigAndHashLen := 0 if ka.version >= VersionTLS12 { sigAndHashLen = 2 } skx.key = make([]byte, len(serverECDHParams)+sigAndHashLen+2+len(sig)) copy(skx.key, serverECDHParams) k := skx.key[len(serverECDHParams):] if ka.version >= VersionTLS12 { k[0] = tls12HashId k[1] = ka.sigType 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, errors.New("bad ClientKeyExchange") } x, y := elliptic.Unmarshal(ka.curve, ckx.ciphertext[1:]) if x == nil { return nil, errors.New("bad ClientKeyExchange") } x, _ = ka.curve.ScalarMult(x, y, ka.privateKey) preMasterSecret := make([]byte, (ka.curve.Params().BitSize+7)>>3) xBytes := x.Bytes() copy(preMasterSecret[len(preMasterSecret)-len(xBytes):], xBytes) return preMasterSecret, nil } var errServerKeyExchange = errors.New("invalid ServerKeyExchange") 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("server selected unsupported curve") } curveid := uint16(skx.key[1])<<8 | uint16(skx.key[2]) switch curveid { case curveP256: ka.curve = elliptic.P256() case curveP384: ka.curve = elliptic.P384() case curveP521: ka.curve = elliptic.P521() default: return errors.New("server selected unsupported curve") } publicLen := int(skx.key[3]) if publicLen+4 > len(skx.key) { return errServerKeyExchange } ka.x, ka.y = elliptic.Unmarshal(ka.curve, skx.key[4:4+publicLen]) if ka.x == nil { return errServerKeyExchange } serverECDHParams := skx.key[:4+publicLen] sig := skx.key[4+publicLen:] if len(sig) < 2 { return errServerKeyExchange } var tls12HashId uint8 if ka.version >= VersionTLS12 { // handle SignatureAndHashAlgorithm var sigAndHash []uint8 sigAndHash, sig = sig[:2], sig[2:] if sigAndHash[1] != ka.sigType { return errServerKeyExchange } tls12HashId = sigAndHash[0] if len(sig) < 2 { return errServerKeyExchange } } sigLen := int(sig[0])<<8 | int(sig[1]) if sigLen+2 != len(sig) { return errServerKeyExchange } sig = sig[2:] digest, hashFunc, err := hashForServerKeyExchange(ka.sigType, tls12HashId, ka.version, clientHello.random, serverHello.random, serverECDHParams) if err != nil { return err } switch ka.sigType { case signatureECDSA: pubKey, ok := cert.PublicKey.(*ecdsa.PublicKey) if !ok { return errors.New("ECDHE ECDSA requires a ECDSA server public key") } ecdsaSig := new(ecdsaSignature) if _, err := asn1.Unmarshal(sig, ecdsaSig); err != nil { return err } if ecdsaSig.R.Sign() <= 0 || ecdsaSig.S.Sign() <= 0 { return errors.New("ECDSA signature contained zero or negative values") } if !ecdsa.Verify(pubKey, digest, ecdsaSig.R, ecdsaSig.S) { return errors.New("ECDSA verification failure") } case signatureRSA: pubKey, ok := cert.PublicKey.(*rsa.PublicKey) if !ok { return errors.New("ECDHE RSA requires a RSA server public key") } if err := rsa.VerifyPKCS1v15(pubKey, hashFunc, digest, sig); err != nil { return err } default: return errors.New("unknown ECDHE signature algorithm") } return nil } func (ka *ecdheKeyAgreement) generateClientKeyExchange(config *Config, clientHello *clientHelloMsg, cert *x509.Certificate) ([]byte, *clientKeyExchangeMsg, error) { if ka.curve == nil { return nil, nil, errors.New("missing ServerKeyExchange message") } priv, mx, my, err := elliptic.GenerateKey(ka.curve, config.rand()) if err != nil { return nil, nil, err } x, _ := ka.curve.ScalarMult(ka.x, ka.y, priv) preMasterSecret := make([]byte, (ka.curve.Params().BitSize+7)>>3) xBytes := x.Bytes() copy(preMasterSecret[len(preMasterSecret)-len(xBytes):], xBytes) serialized := elliptic.Marshal(ka.curve, mx, my) ckx := new(clientKeyExchangeMsg) ckx.ciphertext = make([]byte, 1+len(serialized)) ckx.ciphertext[0] = byte(len(serialized)) copy(ckx.ciphertext[1:], serialized) return preMasterSecret, ckx, nil }