package connect import ( "crypto/tls" "crypto/x509" "crypto/x509/pkix" "encoding/asn1" "errors" "fmt" "io/ioutil" "log" "net" "net/url" "sync" "github.com/hashicorp/consul/agent/connect" "github.com/hashicorp/consul/api" ) // parseLeafX509Cert will parse an X509 certificate // from the TLS certificate and store the parsed // value in the TLS certificate as the Leaf field. func parseLeafX509Cert(leaf *tls.Certificate) error { if leaf == nil { // nothing to parse for nil cert return nil } if leaf.Leaf != nil { // leaf cert was already parsed return nil } cert, err := x509.ParseCertificate(leaf.Certificate[0]) if err != nil { return err } leaf.Leaf = cert return nil } // verifierFunc is a function that can accept rawCertificate bytes from a peer // and verify them against a given tls.Config. It's called from the // tls.Config.VerifyPeerCertificate hook. // // We don't pass verifiedChains since that is always nil in our usage. // Implementations can use the roots provided in the cfg to verify the certs. // // The passed *tls.Config may have a nil VerifyPeerCertificates function but // will have correct roots, leaf and other fields. type verifierFunc func(cfg *tls.Config, rawCerts [][]byte) error // defaultTLSConfig returns the standard config with no peer verifier. It is // insecure to use it as-is. func defaultTLSConfig() *tls.Config { cfg := &tls.Config{ MinVersion: tls.VersionTLS12, ClientAuth: tls.RequireAndVerifyClientCert, // We don't have access to go internals that decide if AES hardware // acceleration is available in order to prefer CHA CHA if not. So let's // just always prefer AES for now. We can look into doing something uglier // later like using an external lib for AES checking if it seems important. // https://github.com/golang/go/blob/df91b8044dbe790c69c16058330f545be069cc1f/src/crypto/tls/common.go#L919:14 CipherSuites: []uint16{ tls.TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256, tls.TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384, tls.TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256, tls.TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384, tls.TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305, tls.TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305, }, // We have to set this since otherwise Go will attempt to verify DNS names // match DNS SAN/CN which we don't want. We hook up VerifyPeerCertificate to // do our own path validation as well as Connect AuthZ. InsecureSkipVerify: true, // Include h2 to allow connect http servers to automatically support http2. // See: https://github.com/golang/go/blob/917c33fe8672116b04848cf11545296789cafd3b/src/net/http/server.go#L2724-L2731 NextProtos: []string{"h2"}, } return cfg } // devTLSConfigFromFiles returns a default TLS Config but with certs and CAs // based on local files for dev. No verification is setup. func devTLSConfigFromFiles(caFile, certFile, keyFile string) (*tls.Config, error) { roots := x509.NewCertPool() bs, err := ioutil.ReadFile(caFile) if err != nil { return nil, err } roots.AppendCertsFromPEM(bs) cert, err := tls.LoadX509KeyPair(certFile, keyFile) if err != nil { return nil, err } cfg := defaultTLSConfig() cfg.Certificates = []tls.Certificate{cert} cfg.RootCAs = roots cfg.ClientCAs = roots return cfg, nil } // PKIXNameFromRawSubject attempts to parse a DER encoded "Subject" as a PKIX // Name. It's useful for inspecting root certificates in an x509.CertPool which // only expose RawSubject via the Subjects method. func PKIXNameFromRawSubject(raw []byte) (*pkix.Name, error) { var subject pkix.RDNSequence if _, err := asn1.Unmarshal(raw, &subject); err != nil { return nil, err } var name pkix.Name name.FillFromRDNSequence(&subject) return &name, nil } // CommonNamesFromCertPool returns the common names of the certificates in the // cert pool. func CommonNamesFromCertPool(p *x509.CertPool) ([]string, error) { var names []string for _, rawSubj := range p.Subjects() { n, err := PKIXNameFromRawSubject(rawSubj) if err != nil { return nil, err } names = append(names, n.CommonName) } return names, nil } // CertURIFromConn is a helper to extract the service identifier URI from a // net.Conn. If the net.Conn is not a *tls.Conn then an error is always // returned. If the *tls.Conn didn't present a valid connect certificate, or is // not yet past the handshake, an error is returned. func CertURIFromConn(conn net.Conn) (connect.CertURI, error) { tc, ok := conn.(*tls.Conn) if !ok { return nil, fmt.Errorf("invalid non-TLS connect client") } gotURI, err := extractCertURI(tc.ConnectionState().PeerCertificates) if err != nil { return nil, err } return connect.ParseCertURI(gotURI) } // extractCertURI returns the first URI SAN from the leaf certificate presented // in the slice. The slice is expected to be the passed from // tls.Conn.ConnectionState().PeerCertificates and requires that the leaf has at // least one URI and the first URI is the correct one to use. func extractCertURI(certs []*x509.Certificate) (*url.URL, error) { if len(certs) < 1 { return nil, errors.New("no peer certificate presented") } // Only check the first cert assuming this is the only leaf. It's not clear if // services might ever legitimately present multiple leaf certificates or if // the slice is just to allow presenting the whole chain of intermediates. cert := certs[0] // Our certs will only ever have a single URI for now so only check that if len(cert.URIs) < 1 { return nil, errors.New("peer certificate invalid") } return cert.URIs[0], nil } // verifyServerCertMatchesURI is used on tls connections dialled to a connect // server to ensure that the certificate it presented has the correct identity. func verifyServerCertMatchesURI(certs []*x509.Certificate, expected connect.CertURI) error { expectedStr := expected.URI().String() gotURI, err := extractCertURI(certs) if err != nil { return errors.New("peer certificate mismatch") } // We may want to do better than string matching later in some special // cases and/or encapsulate the "match" logic inside the CertURI // implementation but for now this is all we need. if gotURI.String() == expectedStr { return nil } return fmt.Errorf("peer certificate mismatch got %s, want %s", gotURI.String(), expectedStr) } // newServerSideVerifier returns a verifierFunc that wraps the provided // api.Client to verify the TLS chain and perform AuthZ for the server end of // the connection. The service name provided is used as the target service name // for the Authorization. func newServerSideVerifier(client *api.Client, serviceName string) verifierFunc { return func(tlsCfg *tls.Config, rawCerts [][]byte) error { leaf, err := verifyChain(tlsCfg, rawCerts, false) if err != nil { log.Printf("connect: failed TLS verification: %s", err) return err } // Check leaf is a cert we understand if len(leaf.URIs) < 1 { log.Printf("connect: invalid leaf certificate") return errors.New("connect: invalid leaf certificate") } certURI, err := connect.ParseCertURI(leaf.URIs[0]) if err != nil { log.Printf("connect: invalid leaf certificate URI") return errors.New("connect: invalid leaf certificate URI") } // No AuthZ if there is no client. if client == nil { log.Printf("connect: nil client") return nil } // Perform AuthZ req := &api.AgentAuthorizeParams{ Target: serviceName, ClientCertURI: certURI.URI().String(), ClientCertSerial: connect.HexString(leaf.SerialNumber.Bytes()), } resp, err := client.Agent().ConnectAuthorize(req) if err != nil { log.Printf("connect: authz call failed: %s", err) return errors.New("connect: authz call failed: " + err.Error()) } if !resp.Authorized { log.Printf("connect: authz call denied: %s", resp.Reason) return errors.New("connect: authz denied: " + resp.Reason) } return nil } } // clientSideVerifier is a verifierFunc that performs verification of certificates // on the client end of the connection. For now it is just basic TLS // verification since the identity check needs additional state and becomes // clunky to customise the callback for every outgoing request. That is done // within Service.Dial for now. func clientSideVerifier(tlsCfg *tls.Config, rawCerts [][]byte) error { _, err := verifyChain(tlsCfg, rawCerts, true) return err } // verifyChain performs standard TLS verification without enforcing remote // hostname matching. func verifyChain(tlsCfg *tls.Config, rawCerts [][]byte, client bool) (*x509.Certificate, error) { // Fetch leaf and intermediates. This is based on code form tls handshake. if len(rawCerts) < 1 { return nil, errors.New("tls: no certificates from peer") } certs := make([]*x509.Certificate, len(rawCerts)) for i, asn1Data := range rawCerts { cert, err := x509.ParseCertificate(asn1Data) if err != nil { return nil, errors.New("tls: failed to parse certificate from peer: " + err.Error()) } certs[i] = cert } cas := tlsCfg.RootCAs if client { cas = tlsCfg.ClientCAs } opts := x509.VerifyOptions{ Roots: cas, Intermediates: x509.NewCertPool(), } if !client { // Server side only sets KeyUsages in tls. This defaults to ServerAuth in // x509 lib. See // https://github.com/golang/go/blob/ee7dd810f9ca4e63ecfc1d3044869591783b8b74/src/crypto/x509/verify.go#L866-L868 opts.KeyUsages = []x509.ExtKeyUsage{x509.ExtKeyUsageClientAuth} } // All but the first cert are intermediates for _, cert := range certs[1:] { opts.Intermediates.AddCert(cert) } _, err := certs[0].Verify(opts) return certs[0], err } // dynamicTLSConfig represents the state for returning a tls.Config that can // have root and leaf certificates updated dynamically with all existing clients // and servers automatically picking up the changes. It requires initialising // with a valid base config from which all the non-certificate and verification // params are used. The base config passed should not be modified externally as // it is assumed to be serialised by the embedded mutex. type dynamicTLSConfig struct { base *tls.Config sync.RWMutex leaf *tls.Certificate roots *x509.CertPool // readyCh is closed when the config first gets both leaf and roots set. // Watchers can wait on this via ReadyWait. readyCh chan struct{} } type tlsCfgUpdate struct { ch chan struct{} next *tlsCfgUpdate } // newDynamicTLSConfig returns a dynamicTLSConfig constructed from base. // base.Certificates[0] is used as the initial leaf and base.RootCAs is used as // the initial roots. func newDynamicTLSConfig(base *tls.Config, logger *log.Logger) *dynamicTLSConfig { cfg := &dynamicTLSConfig{ base: base, } if len(base.Certificates) > 0 { cfg.leaf = &base.Certificates[0] // If this does error then future calls to Ready will fail // It is better to handle not-Ready rather than failing if err := parseLeafX509Cert(cfg.leaf); err != nil && logger != nil { logger.Printf("[ERR] Error parsing configured leaf certificate: %v", err) } } if base.RootCAs != nil { cfg.roots = base.RootCAs } if !cfg.Ready() { cfg.readyCh = make(chan struct{}) } return cfg } // Get fetches the lastest tls.Config with all the hooks attached to keep it // loading the most recent roots and certs even after future changes to cfg. // // The verifierFunc passed will be attached to the config returned such that it // runs with the _latest_ config object returned passed to it. That means that a // client can use this config for a long time and will still verify against the // latest roots even though the roots in the struct is has can't change. func (cfg *dynamicTLSConfig) Get(v verifierFunc) *tls.Config { cfg.RLock() defer cfg.RUnlock() copy := cfg.base.Clone() copy.RootCAs = cfg.roots copy.ClientCAs = cfg.roots if v != nil { copy.VerifyPeerCertificate = func(rawCerts [][]byte, chains [][]*x509.Certificate) error { return v(cfg.Get(nil), rawCerts) } } copy.GetCertificate = func(_ *tls.ClientHelloInfo) (*tls.Certificate, error) { leaf := cfg.Leaf() if leaf == nil { return nil, errors.New("tls: no certificates configured") } return leaf, nil } copy.GetClientCertificate = func(_ *tls.CertificateRequestInfo) (*tls.Certificate, error) { leaf := cfg.Leaf() if leaf == nil { return nil, errors.New("tls: no certificates configured") } return leaf, nil } copy.GetConfigForClient = func(*tls.ClientHelloInfo) (*tls.Config, error) { return cfg.Get(v), nil } return copy } // SetRoots sets new roots. func (cfg *dynamicTLSConfig) SetRoots(roots *x509.CertPool) error { cfg.Lock() defer cfg.Unlock() cfg.roots = roots cfg.notify() return nil } // SetLeaf sets a new leaf. func (cfg *dynamicTLSConfig) SetLeaf(leaf *tls.Certificate) error { cfg.Lock() defer cfg.Unlock() if err := parseLeafX509Cert(leaf); err != nil { return err } cfg.leaf = leaf cfg.notify() return nil } // notify is called under lock during an update to check if we are now ready. func (cfg *dynamicTLSConfig) notify() { if cfg.readyCh != nil && cfg.leaf != nil && cfg.roots != nil && cfg.leaf.Leaf != nil { close(cfg.readyCh) cfg.readyCh = nil } } func (cfg *dynamicTLSConfig) VerifyLeafWithRoots() error { cfg.RLock() defer cfg.RUnlock() if cfg.roots == nil { return fmt.Errorf("No roots are set") } else if cfg.leaf == nil { return fmt.Errorf("No leaf certificate is set") } else if cfg.leaf.Leaf == nil { return fmt.Errorf("Leaf certificate has not been parsed") } _, err := cfg.leaf.Leaf.Verify(x509.VerifyOptions{Roots: cfg.roots}) return err } // Roots returns the current CA root CertPool. func (cfg *dynamicTLSConfig) Roots() *x509.CertPool { cfg.RLock() defer cfg.RUnlock() return cfg.roots } // Leaf returns the current Leaf certificate. func (cfg *dynamicTLSConfig) Leaf() *tls.Certificate { cfg.RLock() defer cfg.RUnlock() return cfg.leaf } // Ready returns whether or not both roots and a leaf certificate are // configured. If both are non-nil, they are assumed to be valid and usable. func (cfg *dynamicTLSConfig) Ready() bool { // not locking because VerifyLeafWithRoots will do that return cfg.VerifyLeafWithRoots() == nil } // ReadyWait returns a chan that is closed when the the Service becomes ready // for use for the first time. Note that if the Service is ready when it is // called it returns a nil chan. Ready means that it has root and leaf // certificates configured but not that the combination is valid nor that // the current time is within the validity window of the certificate. The // service may subsequently stop being "ready" if it's certificates expire // or are revoked and an error prevents new ones from being loaded but this // method will not stop returning a nil chan in that case. It is only useful // for initial startup. For ongoing health Ready() should be used. func (cfg *dynamicTLSConfig) ReadyWait() <-chan struct{} { return cfg.readyCh }