package jwtclaims import ( "bytes" "crypto/rsa" "crypto/x509" "encoding/base64" "encoding/binary" "encoding/json" "encoding/pem" "errors" "fmt" "math/big" "net/http" "strconv" "strings" "sync" "time" "github.com/golang-jwt/jwt" log "github.com/sirupsen/logrus" ) // Options is a struct for specifying configuration options for the middleware. type Options struct { // The function that will return the Key to validate the JWT. // It can be either a shared secret or a public key. // Default value: nil ValidationKeyGetter jwt.Keyfunc // The name of the property in the request where the user information // from the JWT will be stored. // Default value: "user" UserProperty string // The function that will be called when there's an error validating the token // Default value: CredentialsOptional bool // A function that extracts the token from the request // Default: FromAuthHeader (i.e., from Authorization header as bearer token) Debug bool // When set, all requests with the OPTIONS method will use authentication // Default: false EnableAuthOnOptions bool // When set, the middelware verifies that tokens are signed with the specific signing algorithm // If the signing method is not constant the ValidationKeyGetter callback can be used to implement additional checks // Important to avoid security issues described here: https://auth0.com/blog/critical-vulnerabilities-in-json-web-token-libraries/ // Default: nil SigningMethod jwt.SigningMethod } // Jwks is a collection of JSONWebKey obtained from Config.HttpServerConfig.AuthKeysLocation type Jwks struct { Keys []JSONWebKey `json:"keys"` expiresInTime time.Time } // JSONWebKey is a representation of a Jason Web Key type JSONWebKey struct { Kty string `json:"kty"` Kid string `json:"kid"` Use string `json:"use"` N string `json:"n"` E string `json:"e"` X5c []string `json:"x5c"` } // JWTValidator struct to handle token validation and parsing type JWTValidator struct { options Options } // NewJWTValidator constructor func NewJWTValidator(issuer string, audienceList []string, keysLocation string, idpSignkeyRefreshEnabled bool) (*JWTValidator, error) { keys, err := getPemKeys(keysLocation) if err != nil { return nil, err } var lock sync.Mutex options := Options{ ValidationKeyGetter: func(token *jwt.Token) (interface{}, error) { // Verify 'aud' claim var checkAud bool for _, audience := range audienceList { checkAud = token.Claims.(jwt.MapClaims).VerifyAudience(audience, false) if checkAud { break } } if !checkAud { return token, errors.New("invalid audience") } // Verify 'issuer' claim checkIss := token.Claims.(jwt.MapClaims).VerifyIssuer(issuer, false) if !checkIss { return token, errors.New("invalid issuer") } // If keys are rotated, verify the keys prior to token validation if idpSignkeyRefreshEnabled { // If the keys are invalid, retrieve new ones if !keys.stillValid() { lock.Lock() defer lock.Unlock() refreshedKeys, err := getPemKeys(keysLocation) if err != nil { log.Debugf("cannot get JSONWebKey: %v, falling back to old keys", err) refreshedKeys = keys } keys = refreshedKeys } } cert, err := getPemCert(token, keys) if err != nil { return nil, err } result, _ := jwt.ParseRSAPublicKeyFromPEM([]byte(cert)) return result, nil }, SigningMethod: jwt.SigningMethodRS256, EnableAuthOnOptions: false, } if options.UserProperty == "" { options.UserProperty = "user" } return &JWTValidator{ options: options, }, nil } // ValidateAndParse validates the token and returns the parsed token func (m *JWTValidator) ValidateAndParse(token string) (*jwt.Token, error) { // If the token is empty... if token == "" { // Check if it was required if m.options.CredentialsOptional { log.Debugf("no credentials found (CredentialsOptional=true)") // No error, just no token (and that is ok given that CredentialsOptional is true) return nil, nil //nolint:nilnil } // If we get here, the required token is missing errorMsg := "required authorization token not found" log.Debugf(" Error: No credentials found (CredentialsOptional=false)") return nil, fmt.Errorf(errorMsg) } // Now parse the token parsedToken, err := jwt.Parse(token, m.options.ValidationKeyGetter) // Check if there was an error in parsing... if err != nil { log.Errorf("error parsing token: %v", err) return nil, fmt.Errorf("Error parsing token: %w", err) } if m.options.SigningMethod != nil && m.options.SigningMethod.Alg() != parsedToken.Header["alg"] { errorMsg := fmt.Sprintf("Expected %s signing method but token specified %s", m.options.SigningMethod.Alg(), parsedToken.Header["alg"]) log.Debugf("error validating token algorithm: %s", errorMsg) return nil, fmt.Errorf("error validating token algorithm: %s", errorMsg) } // Check if the parsed token is valid... if !parsedToken.Valid { errorMsg := "token is invalid" log.Debugf(errorMsg) return nil, errors.New(errorMsg) } return parsedToken, nil } // stillValid returns true if the JSONWebKey still valid and have enough time to be used func (jwks *Jwks) stillValid() bool { return jwks.expiresInTime.IsZero() && time.Now().Add(5*time.Second).Before(jwks.expiresInTime) } func getPemKeys(keysLocation string) (*Jwks, error) { resp, err := http.Get(keysLocation) if err != nil { return nil, err } defer resp.Body.Close() jwks := &Jwks{} err = json.NewDecoder(resp.Body).Decode(jwks) if err != nil { return jwks, err } cacheControlHeader := resp.Header.Get("Cache-Control") expiresIn := getMaxAgeFromCacheHeader(cacheControlHeader) jwks.expiresInTime = time.Now().Add(time.Duration(expiresIn) * time.Second) return jwks, err } func getPemCert(token *jwt.Token, jwks *Jwks) (string, error) { // todo as we load the jkws when the server is starting, we should build a JKS map with the pem cert at the boot time cert := "" for k := range jwks.Keys { if token.Header["kid"] != jwks.Keys[k].Kid { continue } if len(jwks.Keys[k].X5c) != 0 { cert = "-----BEGIN CERTIFICATE-----\n" + jwks.Keys[k].X5c[0] + "\n-----END CERTIFICATE-----" return cert, nil } log.Debugf("generating validation pem from JWK") return generatePemFromJWK(jwks.Keys[k]) } return cert, errors.New("unable to find appropriate key") } func generatePemFromJWK(jwk JSONWebKey) (string, error) { decodedModulus, err := base64.RawURLEncoding.DecodeString(jwk.N) if err != nil { return "", fmt.Errorf("unable to decode JWK modulus, error: %s", err) } intModules := big.NewInt(0) intModules.SetBytes(decodedModulus) exponent, err := convertExponentStringToInt(jwk.E) if err != nil { return "", fmt.Errorf("unable to decode JWK exponent, error: %s", err) } publicKey := &rsa.PublicKey{ N: intModules, E: exponent, } derKey, err := x509.MarshalPKIXPublicKey(publicKey) if err != nil { return "", fmt.Errorf("unable to convert public key to DER, error: %s", err) } block := &pem.Block{ Type: "RSA PUBLIC KEY", Bytes: derKey, } var out bytes.Buffer err = pem.Encode(&out, block) if err != nil { return "", fmt.Errorf("unable to encode Pem block , error: %s", err) } return out.String(), nil } func convertExponentStringToInt(stringExponent string) (int, error) { decodedString, err := base64.StdEncoding.DecodeString(stringExponent) if err != nil { return 0, err } exponentBytes := decodedString if len(decodedString) < 8 { exponentBytes = make([]byte, 8-len(decodedString), 8) exponentBytes = append(exponentBytes, decodedString...) } bytesReader := bytes.NewReader(exponentBytes) var exponent uint64 err = binary.Read(bytesReader, binary.BigEndian, &exponent) if err != nil { return 0, err } return int(exponent), nil } // getMaxAgeFromCacheHeader extracts max-age directive from the Cache-Control header func getMaxAgeFromCacheHeader(cacheControl string) int { // Split into individual directives directives := strings.Split(cacheControl, ",") for _, directive := range directives { directive = strings.TrimSpace(directive) if strings.HasPrefix(directive, "max-age=") { // Extract the max-age value maxAgeStr := strings.TrimPrefix(directive, "max-age=") maxAge, err := strconv.Atoi(maxAgeStr) if err != nil { log.Debugf("error parsing max-age: %v", err) return 0 } return maxAge } } return 0 }