package caddytls import ( "crypto/tls" "crypto/x509" "errors" "io/ioutil" "log" "strings" "sync" "time" "golang.org/x/crypto/ocsp" ) // certCache stores certificates in memory, // keying certificates by name. var certCache = make(map[string]Certificate) var certCacheMu sync.RWMutex // Certificate is a tls.Certificate with associated metadata tacked on. // Even if the metadata can be obtained by parsing the certificate, // we can be more efficient by extracting the metadata once so it's // just there, ready to use. type Certificate struct { tls.Certificate // Names is the list of names this certificate is written for. // The first is the CommonName (if any), the rest are SAN. Names []string // NotAfter is when the certificate expires. NotAfter time.Time // OCSP contains the certificate's parsed OCSP response. OCSP *ocsp.Response // Config is the configuration with which the certificate was // loaded or obtained and with which it should be maintained. Config *Config } // getCertificate gets a certificate that matches name (a server name) // from the in-memory cache. If there is no exact match for name, it // will be checked against names of the form '*.example.com' (wildcard // certificates) according to RFC 6125. If a match is found, matched will // be true. If no matches are found, matched will be false and a default // certificate will be returned with defaulted set to true. If no default // certificate is set, defaulted will be set to false. // // The logic in this function is adapted from the Go standard library, // which is by the Go Authors. // // This function is safe for concurrent use. func getCertificate(name string) (cert Certificate, matched, defaulted bool) { var ok bool // Not going to trim trailing dots here since RFC 3546 says, // "The hostname is represented ... without a trailing dot." // Just normalize to lowercase. name = strings.ToLower(name) certCacheMu.RLock() defer certCacheMu.RUnlock() // exact match? great, let's use it if cert, ok = certCache[name]; ok { matched = true return } // try replacing labels in the name with wildcards until we get a match labels := strings.Split(name, ".") for i := range labels { labels[i] = "*" candidate := strings.Join(labels, ".") if cert, ok = certCache[candidate]; ok { matched = true return } } // if nothing matches, use the default certificate or bust cert, defaulted = certCache[""] return } // CacheManagedCertificate loads the certificate for domain into the // cache, flagging it as Managed and, if onDemand is true, as "OnDemand" // (meaning that it was obtained or loaded during a TLS handshake). // // This function is safe for concurrent use. func CacheManagedCertificate(domain string, cfg *Config) (Certificate, error) { storage, err := cfg.StorageFor(cfg.CAUrl) if err != nil { return Certificate{}, err } siteData, err := storage.LoadSite(domain) if err != nil { return Certificate{}, err } cert, err := makeCertificate(siteData.Cert, siteData.Key) if err != nil { return cert, err } cert.Config = cfg cacheCertificate(cert) return cert, nil } // cacheUnmanagedCertificatePEMFile loads a certificate for host using certFile // and keyFile, which must be in PEM format. It stores the certificate in // memory. The Managed and OnDemand flags of the certificate will be set to // false. // // This function is safe for concurrent use. func cacheUnmanagedCertificatePEMFile(certFile, keyFile string) error { cert, err := makeCertificateFromDisk(certFile, keyFile) if err != nil { return err } cacheCertificate(cert) return nil } // cacheUnmanagedCertificatePEMBytes makes a certificate out of the PEM bytes // of the certificate and key, then caches it in memory. // // This function is safe for concurrent use. func cacheUnmanagedCertificatePEMBytes(certBytes, keyBytes []byte) error { cert, err := makeCertificate(certBytes, keyBytes) if err != nil { return err } cacheCertificate(cert) return nil } // makeCertificateFromDisk makes a Certificate by loading the // certificate and key files. It fills out all the fields in // the certificate except for the Managed and OnDemand flags. // (It is up to the caller to set those.) func makeCertificateFromDisk(certFile, keyFile string) (Certificate, error) { certPEMBlock, err := ioutil.ReadFile(certFile) if err != nil { return Certificate{}, err } keyPEMBlock, err := ioutil.ReadFile(keyFile) if err != nil { return Certificate{}, err } return makeCertificate(certPEMBlock, keyPEMBlock) } // makeCertificate turns a certificate PEM bundle and a key PEM block into // a Certificate, with OCSP and other relevant metadata tagged with it, // except for the OnDemand and Managed flags. It is up to the caller to // set those properties. func makeCertificate(certPEMBlock, keyPEMBlock []byte) (Certificate, error) { var cert Certificate // Convert to a tls.Certificate tlsCert, err := tls.X509KeyPair(certPEMBlock, keyPEMBlock) if err != nil { return cert, err } if len(tlsCert.Certificate) == 0 { return cert, errors.New("certificate is empty") } cert.Certificate = tlsCert // Parse leaf certificate, extract relevant metadata, and staple OCSP leaf, err := x509.ParseCertificate(tlsCert.Certificate[0]) if err != nil { return cert, err } err = fillCertFromLeaf(&cert, leaf) if err != nil { return cert, err } err = stapleOCSP(&cert, certPEMBlock) if err != nil { log.Printf("[WARNING] Stapling OCSP: %v", err) } return cert, nil } // fillCertFromLeaf populates cert.Names and cert.NotAfter // using data in leaf. func fillCertFromLeaf(cert *Certificate, leaf *x509.Certificate) error { if leaf.Subject.CommonName != "" { cert.Names = []string{strings.ToLower(leaf.Subject.CommonName)} } for _, name := range leaf.DNSNames { if name != leaf.Subject.CommonName { cert.Names = append(cert.Names, strings.ToLower(name)) } } for _, ip := range leaf.IPAddresses { if ipStr := ip.String(); ipStr != leaf.Subject.CommonName { cert.Names = append(cert.Names, strings.ToLower(ipStr)) } } for _, email := range leaf.EmailAddresses { if email != leaf.Subject.CommonName { cert.Names = append(cert.Names, strings.ToLower(email)) } } if len(cert.Names) == 0 { return errors.New("certificate has no names") } cert.NotAfter = leaf.NotAfter return nil } // cacheCertificate adds cert to the in-memory cache. If the cache is // empty, cert will be used as the default certificate. If the cache is // full, random entries are deleted until there is room to map all the // names on the certificate. // // This certificate will be keyed to the names in cert.Names. Any name // that is already a key in the cache will be replaced with this cert. // // This function is safe for concurrent use. func cacheCertificate(cert Certificate) { if cert.Config == nil { cert.Config = new(Config) } certCacheMu.Lock() if _, ok := certCache[""]; !ok { // use as default - must be *appended* to end of list, or bad things happen! cert.Names = append(cert.Names, "") certCache[""] = cert } for len(certCache)+len(cert.Names) > 10000 { // for simplicity, just remove random elements for key := range certCache { if key == "" { // ... but not the default cert continue } delete(certCache, key) break } } for _, name := range cert.Names { certCache[name] = cert } certCacheMu.Unlock() } // uncacheCertificate deletes name's certificate from the // cache. If name is not a key in the certificate cache, // this function does nothing. func uncacheCertificate(name string) { certCacheMu.Lock() delete(certCache, name) certCacheMu.Unlock() }