// Copyright (c) 2017-2022 Snowflake Computing Inc. All rights reserved. package ocsp import ( "bytes" "context" "crypto" "crypto/tls" "crypto/x509" "crypto/x509/pkix" "encoding/asn1" "encoding/base64" "errors" "fmt" "io" "math/big" "net" "net/http" "net/url" "strconv" "strings" "sync" "time" "github.com/hashicorp/go-hclog" "github.com/hashicorp/go-multierror" "github.com/hashicorp/go-retryablehttp" lru "github.com/hashicorp/golang-lru" "github.com/hashicorp/vault/sdk/helper/certutil" "golang.org/x/crypto/ocsp" ) // FailOpenMode is OCSP fail open mode. FailOpenTrue by default and may // set to ocspModeFailClosed for fail closed mode type FailOpenMode uint32 type requestFunc func(method, urlStr string, body interface{}) (*retryablehttp.Request, error) type clientInterface interface { Do(req *retryablehttp.Request) (*http.Response, error) } const ( httpHeaderContentType = "Content-Type" httpHeaderAccept = "accept" httpHeaderContentLength = "Content-Length" httpHeaderHost = "Host" ocspRequestContentType = "application/ocsp-request" ocspResponseContentType = "application/ocsp-response" ) const ( ocspFailOpenNotSet FailOpenMode = iota // FailOpenTrue represents OCSP fail open mode. FailOpenTrue // FailOpenFalse represents OCSP fail closed mode. FailOpenFalse ) const ( ocspModeFailOpen = "FAIL_OPEN" ocspModeFailClosed = "FAIL_CLOSED" ocspModeInsecure = "INSECURE" ) const ocspCacheKey = "ocsp_cache" const ( // defaultOCSPResponderTimeout is the total timeout for OCSP responder. defaultOCSPResponderTimeout = 10 * time.Second ) const ( // cacheExpire specifies cache data expiration time in seconds. cacheExpire = float64(24 * 60 * 60) ) type ocspCachedResponse struct { time float64 producedAt float64 thisUpdate float64 nextUpdate float64 status ocspStatusCode } type Client struct { // caRoot includes the CA certificates. caRoot map[string]*x509.Certificate // certPool includes the CA certificates. certPool *x509.CertPool ocspResponseCache *lru.TwoQueueCache ocspResponseCacheLock sync.RWMutex // cacheUpdated is true if the memory cache is updated cacheUpdated bool logFactory func() hclog.Logger } type ocspStatusCode int type ocspStatus struct { code ocspStatusCode err error } const ( ocspSuccess ocspStatusCode = 0 ocspStatusGood ocspStatusCode = -1 ocspStatusRevoked ocspStatusCode = -2 ocspStatusUnknown ocspStatusCode = -3 ocspStatusOthers ocspStatusCode = -4 ocspFailedDecomposeRequest ocspStatusCode = -5 ocspInvalidValidity ocspStatusCode = -6 ocspMissedCache ocspStatusCode = -7 ocspCacheExpired ocspStatusCode = -8 ) // copied from crypto/ocsp.go type certID struct { HashAlgorithm pkix.AlgorithmIdentifier NameHash []byte IssuerKeyHash []byte SerialNumber *big.Int } // cache key type certIDKey struct { NameHash string IssuerKeyHash string SerialNumber string } // copied from crypto/ocsp var hashOIDs = map[crypto.Hash]asn1.ObjectIdentifier{ crypto.SHA1: asn1.ObjectIdentifier([]int{1, 3, 14, 3, 2, 26}), crypto.SHA256: asn1.ObjectIdentifier([]int{2, 16, 840, 1, 101, 3, 4, 2, 1}), crypto.SHA384: asn1.ObjectIdentifier([]int{2, 16, 840, 1, 101, 3, 4, 2, 2}), crypto.SHA512: asn1.ObjectIdentifier([]int{2, 16, 840, 1, 101, 3, 4, 2, 3}), } // copied from crypto/ocsp func getOIDFromHashAlgorithm(target crypto.Hash) (asn1.ObjectIdentifier, error) { for hash, oid := range hashOIDs { if hash == target { return oid, nil } } return nil, fmt.Errorf("no valid OID is found for the hash algorithm: %v", target) } func (c *Client) ClearCache() { c.ocspResponseCache.Purge() } func (c *Client) getHashAlgorithmFromOID(target pkix.AlgorithmIdentifier) crypto.Hash { for hash, oid := range hashOIDs { if oid.Equal(target.Algorithm) { return hash } } // no valid hash algorithm is found for the oid. Falling back to SHA1 return crypto.SHA1 } // isInValidityRange checks the validity func isInValidityRange(currTime, nextUpdate time.Time) bool { return !nextUpdate.IsZero() && !currTime.After(nextUpdate) } func extractCertIDKeyFromRequest(ocspReq []byte) (*certIDKey, *ocspStatus) { r, err := ocsp.ParseRequest(ocspReq) if err != nil { return nil, &ocspStatus{ code: ocspFailedDecomposeRequest, err: err, } } // encode CertID, used as a key in the cache encodedCertID := &certIDKey{ base64.StdEncoding.EncodeToString(r.IssuerNameHash), base64.StdEncoding.EncodeToString(r.IssuerKeyHash), r.SerialNumber.String(), } return encodedCertID, &ocspStatus{ code: ocspSuccess, } } func (c *Client) encodeCertIDKey(certIDKeyBase64 string) (*certIDKey, error) { r, err := base64.StdEncoding.DecodeString(certIDKeyBase64) if err != nil { return nil, err } var cid certID rest, err := asn1.Unmarshal(r, &cid) if err != nil { // error in parsing return nil, err } if len(rest) > 0 { // extra bytes to the end return nil, err } return &certIDKey{ base64.StdEncoding.EncodeToString(cid.NameHash), base64.StdEncoding.EncodeToString(cid.IssuerKeyHash), cid.SerialNumber.String(), }, nil } func (c *Client) checkOCSPResponseCache(encodedCertID *certIDKey, subject, issuer *x509.Certificate) (*ocspStatus, error) { c.ocspResponseCacheLock.RLock() var cacheValue *ocspCachedResponse v, ok := c.ocspResponseCache.Get(*encodedCertID) if ok { cacheValue = v.(*ocspCachedResponse) } c.ocspResponseCacheLock.RUnlock() status, err := c.extractOCSPCacheResponseValue(cacheValue, subject, issuer) if err != nil { return nil, err } if !isValidOCSPStatus(status.code) { c.deleteOCSPCache(encodedCertID) } return status, err } func (c *Client) deleteOCSPCache(encodedCertID *certIDKey) { c.ocspResponseCacheLock.Lock() c.ocspResponseCache.Remove(*encodedCertID) c.cacheUpdated = true c.ocspResponseCacheLock.Unlock() } func validateOCSP(ocspRes *ocsp.Response) (*ocspStatus, error) { curTime := time.Now() if ocspRes == nil { return nil, errors.New("OCSP Response is nil") } if !isInValidityRange(curTime, ocspRes.NextUpdate) { return &ocspStatus{ code: ocspInvalidValidity, err: fmt.Errorf("invalid validity: producedAt: %v, thisUpdate: %v, nextUpdate: %v", ocspRes.ProducedAt, ocspRes.ThisUpdate, ocspRes.NextUpdate), }, nil } return returnOCSPStatus(ocspRes), nil } func returnOCSPStatus(ocspRes *ocsp.Response) *ocspStatus { switch ocspRes.Status { case ocsp.Good: return &ocspStatus{ code: ocspStatusGood, err: nil, } case ocsp.Revoked: return &ocspStatus{ code: ocspStatusRevoked, } case ocsp.Unknown: return &ocspStatus{ code: ocspStatusUnknown, err: errors.New("OCSP status unknown."), } default: return &ocspStatus{ code: ocspStatusOthers, err: fmt.Errorf("OCSP others. %v", ocspRes.Status), } } } // retryOCSP is the second level of retry method if the returned contents are corrupted. It often happens with OCSP // serer and retry helps. func (c *Client) retryOCSP( ctx context.Context, client clientInterface, req requestFunc, ocspHost *url.URL, headers map[string]string, reqBody []byte, issuer *x509.Certificate, ) (ocspRes *ocsp.Response, ocspResBytes []byte, ocspS *ocspStatus, retErr error) { doRequest := func(request *retryablehttp.Request) (*http.Response, error) { if request != nil { request = request.WithContext(ctx) for k, v := range headers { request.Header[k] = append(request.Header[k], v) } } res, err := client.Do(request) if err != nil { return nil, err } c.Logger().Debug("StatusCode from OCSP Server:", "statusCode", res.StatusCode) return res, err } for _, method := range []string{"GET", "POST"} { reqUrl := *ocspHost var body []byte switch method { case "GET": reqUrl.Path = reqUrl.Path + "/" + base64.StdEncoding.EncodeToString(reqBody) case "POST": body = reqBody default: // Programming error; all request/systems errors are multierror // and appended. return nil, nil, nil, fmt.Errorf("unknown request method: %v", method) } var res *http.Response request, err := req(method, reqUrl.String(), bytes.NewBuffer(body)) if err != nil { err = fmt.Errorf("error creating %v request: %w", method, err) retErr = multierror.Append(retErr, err) continue } if res, err = doRequest(request); err != nil { err = fmt.Errorf("error doing %v request: %w", method, err) retErr = multierror.Append(retErr, err) continue } else { defer res.Body.Close() } if res.StatusCode != http.StatusOK { err = fmt.Errorf("HTTP code is not OK on %v request. %v: %v", method, res.StatusCode, res.Status) retErr = multierror.Append(retErr, err) continue } ocspResBytes, err = io.ReadAll(res.Body) if err != nil { err = fmt.Errorf("error reading %v request body: %w", method, err) retErr = multierror.Append(retErr, err) continue } // Reading an OCSP response shouldn't be fatal. A misconfigured // endpoint might return invalid results for e.g., GET but return // valid results for POST on retry. This could happen if e.g., the // server responds with JSON. ocspRes, err = ocsp.ParseResponse(ocspResBytes /*issuer = */, nil /* !!unsafe!! */) if err != nil { err = fmt.Errorf("error parsing %v OCSP response: %w", method, err) retErr = multierror.Append(retErr, err) continue } // Above, we use the unsafe issuer=nil parameter to ocsp.ParseResponse // because Go's library does the wrong thing. // // Here, we lack a full chain, but we know we trust the parent issuer, // so if the Go library incorrectly discards useful certificates, we // likely cannot verify this without passing through the full chain // back to the root. // // Instead, take one of two paths: 1. if there is no certificate in // the ocspRes, verify the OCSP response directly with our trusted // issuer certificate, or 2. if there is a certificate, either verify // it directly matches our trusted issuer certificate, or verify it // is signed by our trusted issuer certificate. // // See also: https://github.com/golang/go/issues/59641 // // This addresses the !!unsafe!! behavior above. if ocspRes.Certificate == nil { if err := ocspRes.CheckSignatureFrom(issuer); err != nil { err = fmt.Errorf("error directly verifying signature on %v OCSP response: %w", method, err) retErr = multierror.Append(retErr, err) continue } } else { // Because we have at least one certificate here, we know that // Go's ocsp library verified the signature from this certificate // onto the response and it was valid. Now we need to know we trust // this certificate. There's two ways we can do this: // // 1. Via confirming issuer == ocspRes.Certificate, or // 2. Via confirming ocspRes.Certificate.CheckSignatureFrom(issuer). if !bytes.Equal(issuer.Raw, ocspRes.Raw) { // 1 must not hold, so 2 holds; verify the signature. if err := ocspRes.Certificate.CheckSignatureFrom(issuer); err != nil { err = fmt.Errorf("error checking chain of trust on %v OCSP response via %v failed: %w", method, issuer.Subject.String(), err) retErr = multierror.Append(retErr, err) continue } // Verify the OCSP responder certificate is still valid and // contains the required EKU since it is a delegated OCSP // responder certificate. if ocspRes.Certificate.NotAfter.Before(time.Now()) { err := fmt.Errorf("error checking delegated OCSP responder on %v OCSP response: certificate has expired", method) retErr = multierror.Append(retErr, err) continue } haveEKU := false for _, ku := range ocspRes.Certificate.ExtKeyUsage { if ku == x509.ExtKeyUsageOCSPSigning { haveEKU = true break } } if !haveEKU { err := fmt.Errorf("error checking delegated OCSP responder on %v OCSP response: certificate lacks the OCSP Signing EKU", method) retErr = multierror.Append(retErr, err) continue } } } // While we haven't validated the signature on the OCSP response, we // got what we presume is a definitive answer and simply changing // methods will likely not help us in that regard. Use this status // to return without retrying another method, when it looks definitive. // // We don't accept ocsp.Unknown here: presumably, we could've hit a CDN // with static mapping of request->responses, with a default "unknown" // handler for everything else. By retrying here, we use POST, which // could hit a live OCSP server with fresher data than the cached CDN. if ocspRes.Status == ocsp.Good || ocspRes.Status == ocsp.Revoked { break } // Here, we didn't have a valid response. Even though we didn't get an // error, we should inform the user that this (valid-looking) response // wasn't utilized. err = fmt.Errorf("fetched %v OCSP response of status %v; wanted either good (%v) or revoked (%v)", method, ocspRes.Status, ocsp.Good, ocsp.Revoked) retErr = multierror.Append(retErr, err) } if ocspRes != nil && ocspResBytes != nil { // Clear retErr, because we have one parseable-but-maybe-not-quite-correct // OCSP response. retErr = nil ocspS = &ocspStatus{ code: ocspSuccess, } } return } // GetRevocationStatus checks the certificate revocation status for subject using issuer certificate. func (c *Client) GetRevocationStatus(ctx context.Context, subject, issuer *x509.Certificate, conf *VerifyConfig) (*ocspStatus, error) { status, ocspReq, encodedCertID, err := c.validateWithCache(subject, issuer) if err != nil { return nil, err } if isValidOCSPStatus(status.code) { return status, nil } if ocspReq == nil || encodedCertID == nil { return status, nil } c.Logger().Debug("cache missed", "server", subject.OCSPServer) if len(subject.OCSPServer) == 0 && len(conf.OcspServersOverride) == 0 { return nil, fmt.Errorf("no OCSP responder URL: subject: %v", subject.Subject) } ocspHosts := subject.OCSPServer if len(conf.OcspServersOverride) > 0 { ocspHosts = conf.OcspServersOverride } var wg sync.WaitGroup ocspStatuses := make([]*ocspStatus, len(ocspHosts)) ocspResponses := make([]*ocsp.Response, len(ocspHosts)) errors := make([]error, len(ocspHosts)) for i, ocspHost := range ocspHosts { u, err := url.Parse(ocspHost) if err != nil { return nil, err } hostname := u.Hostname() headers := make(map[string]string) headers[httpHeaderContentType] = ocspRequestContentType headers[httpHeaderAccept] = ocspResponseContentType headers[httpHeaderContentLength] = strconv.Itoa(len(ocspReq)) headers[httpHeaderHost] = hostname timeout := defaultOCSPResponderTimeout ocspClient := retryablehttp.NewClient() ocspClient.HTTPClient.Timeout = timeout ocspClient.HTTPClient.Transport = newInsecureOcspTransport(conf.ExtraCas) doRequest := func() error { if conf.QueryAllServers { defer wg.Done() } ocspRes, _, ocspS, err := c.retryOCSP( ctx, ocspClient, retryablehttp.NewRequest, u, headers, ocspReq, issuer) ocspResponses[i] = ocspRes if err != nil { errors[i] = err return err } if ocspS.code != ocspSuccess { ocspStatuses[i] = ocspS return nil } ret, err := validateOCSP(ocspRes) if err != nil { errors[i] = err return err } if isValidOCSPStatus(ret.code) { ocspStatuses[i] = ret } return nil } if conf.QueryAllServers { wg.Add(1) go doRequest() } else { err = doRequest() if err == nil { break } } } if conf.QueryAllServers { wg.Wait() } // Good by default var ret *ocspStatus ocspRes := ocspResponses[0] var firstError error for i := range ocspHosts { if errors[i] != nil { if firstError == nil { firstError = errors[i] } } else if ocspStatuses[i] != nil { switch ocspStatuses[i].code { case ocspStatusRevoked: ret = ocspStatuses[i] ocspRes = ocspResponses[i] break case ocspStatusGood: // Use this response only if we don't have a status already, or if what we have was unknown if ret == nil || ret.code == ocspStatusUnknown { ret = ocspStatuses[i] ocspRes = ocspResponses[i] } case ocspStatusUnknown: if ret == nil { // We may want to use this as the overall result ret = ocspStatuses[i] ocspRes = ocspResponses[i] } } } } // If no server reported the cert revoked, but we did have an error, report it if (ret == nil || ret.code == ocspStatusUnknown) && firstError != nil { return nil, firstError } // otherwise ret should contain a response for the overall request if !isValidOCSPStatus(ret.code) { return ret, nil } v := ocspCachedResponse{ status: ret.code, time: float64(time.Now().UTC().Unix()), producedAt: float64(ocspRes.ProducedAt.UTC().Unix()), thisUpdate: float64(ocspRes.ThisUpdate.UTC().Unix()), nextUpdate: float64(ocspRes.NextUpdate.UTC().Unix()), } c.ocspResponseCacheLock.Lock() c.ocspResponseCache.Add(*encodedCertID, &v) c.cacheUpdated = true c.ocspResponseCacheLock.Unlock() return ret, nil } func isValidOCSPStatus(status ocspStatusCode) bool { return status == ocspStatusGood || status == ocspStatusRevoked || status == ocspStatusUnknown } type VerifyConfig struct { OcspEnabled bool ExtraCas []*x509.Certificate OcspServersOverride []string OcspFailureMode FailOpenMode QueryAllServers bool } // VerifyLeafCertificate verifies just the subject against it's direct issuer func (c *Client) VerifyLeafCertificate(ctx context.Context, subject, issuer *x509.Certificate, conf *VerifyConfig) error { results, err := c.GetRevocationStatus(ctx, subject, issuer, conf) if err != nil { return err } if results.code == ocspStatusGood { return nil } else { serial := issuer.SerialNumber serialHex := strings.TrimSpace(certutil.GetHexFormatted(serial.Bytes(), ":")) if results.code == ocspStatusRevoked { return fmt.Errorf("certificate with serial number %s has been revoked", serialHex) } else if conf.OcspFailureMode == FailOpenFalse { return fmt.Errorf("unknown OCSP status for cert with serial number %s", strings.TrimSpace(certutil.GetHexFormatted(serial.Bytes(), ":"))) } else { c.Logger().Warn("could not validate OCSP status for cert, but continuing in fail open mode", "serial", serialHex) } } return nil } // VerifyPeerCertificate verifies all of certificate revocation status func (c *Client) VerifyPeerCertificate(ctx context.Context, verifiedChains [][]*x509.Certificate, conf *VerifyConfig) error { for i := 0; i < len(verifiedChains); i++ { // Certificate signed by Root CA. This should be one before the last in the Certificate Chain numberOfNoneRootCerts := len(verifiedChains[i]) - 1 if !verifiedChains[i][numberOfNoneRootCerts].IsCA || string(verifiedChains[i][numberOfNoneRootCerts].RawIssuer) != string(verifiedChains[i][numberOfNoneRootCerts].RawSubject) { // Check if the last Non Root Cert is also a CA or is self signed. // if the last certificate is not, add it to the list rca := c.caRoot[string(verifiedChains[i][numberOfNoneRootCerts].RawIssuer)] if rca == nil { return fmt.Errorf("failed to find root CA. pkix.name: %v", verifiedChains[i][numberOfNoneRootCerts].Issuer) } verifiedChains[i] = append(verifiedChains[i], rca) numberOfNoneRootCerts++ } results, err := c.GetAllRevocationStatus(ctx, verifiedChains[i], conf) if err != nil { return err } if r := c.canEarlyExitForOCSP(results, numberOfNoneRootCerts, conf); r != nil { return r.err } } return nil } func (c *Client) canEarlyExitForOCSP(results []*ocspStatus, chainSize int, conf *VerifyConfig) *ocspStatus { msg := "" if conf.OcspFailureMode == FailOpenFalse { // Fail closed. any error is returned to stop connection for _, r := range results { if r.err != nil { return r } } } else { // Fail open and all results are valid. allValid := len(results) == chainSize for _, r := range results { if !isValidOCSPStatus(r.code) { allValid = false break } } for _, r := range results { if allValid && r.code == ocspStatusRevoked { return r } if r != nil && r.code != ocspStatusGood && r.err != nil { msg += "" + r.err.Error() } } } if len(msg) > 0 { c.Logger().Warn( "OCSP is set to fail-open, and could not retrieve OCSP based revocation checking but proceeding.", "detail", msg) } return nil } func (c *Client) validateWithCacheForAllCertificates(verifiedChains []*x509.Certificate) (bool, error) { n := len(verifiedChains) - 1 for j := 0; j < n; j++ { subject := verifiedChains[j] issuer := verifiedChains[j+1] status, _, _, err := c.validateWithCache(subject, issuer) if err != nil { return false, err } if !isValidOCSPStatus(status.code) { return false, nil } } return true, nil } func (c *Client) validateWithCache(subject, issuer *x509.Certificate) (*ocspStatus, []byte, *certIDKey, error) { ocspReq, err := ocsp.CreateRequest(subject, issuer, &ocsp.RequestOptions{}) if err != nil { return nil, nil, nil, fmt.Errorf("failed to create OCSP request from the certificates: %v", err) } encodedCertID, ocspS := extractCertIDKeyFromRequest(ocspReq) if ocspS.code != ocspSuccess { return nil, nil, nil, fmt.Errorf("failed to extract CertID from OCSP Request: %v", err) } status, err := c.checkOCSPResponseCache(encodedCertID, subject, issuer) if err != nil { return nil, nil, nil, err } return status, ocspReq, encodedCertID, nil } func (c *Client) GetAllRevocationStatus(ctx context.Context, verifiedChains []*x509.Certificate, conf *VerifyConfig) ([]*ocspStatus, error) { _, err := c.validateWithCacheForAllCertificates(verifiedChains) if err != nil { return nil, err } n := len(verifiedChains) - 1 results := make([]*ocspStatus, n) for j := 0; j < n; j++ { results[j], err = c.GetRevocationStatus(ctx, verifiedChains[j], verifiedChains[j+1], conf) if err != nil { return nil, err } if !isValidOCSPStatus(results[j].code) { return results, nil } } return results, nil } // verifyPeerCertificateSerial verifies the certificate revocation status in serial. func (c *Client) verifyPeerCertificateSerial(conf *VerifyConfig) func(_ [][]byte, verifiedChains [][]*x509.Certificate) (err error) { return func(_ [][]byte, verifiedChains [][]*x509.Certificate) error { return c.VerifyPeerCertificate(context.TODO(), verifiedChains, conf) } } func (c *Client) extractOCSPCacheResponseValueWithoutSubject(cacheValue ocspCachedResponse) (*ocspStatus, error) { return c.extractOCSPCacheResponseValue(&cacheValue, nil, nil) } func (c *Client) extractOCSPCacheResponseValue(cacheValue *ocspCachedResponse, subject, issuer *x509.Certificate) (*ocspStatus, error) { subjectName := "Unknown" if subject != nil { subjectName = subject.Subject.CommonName } curTime := time.Now() if cacheValue == nil { return &ocspStatus{ code: ocspMissedCache, err: fmt.Errorf("miss cache data. subject: %v", subjectName), }, nil } currentTime := float64(curTime.UTC().Unix()) if currentTime-cacheValue.time >= cacheExpire { return &ocspStatus{ code: ocspCacheExpired, err: fmt.Errorf("cache expired. current: %v, cache: %v", time.Unix(int64(currentTime), 0).UTC(), time.Unix(int64(cacheValue.time), 0).UTC()), }, nil } return validateOCSP(&ocsp.Response{ ProducedAt: time.Unix(int64(cacheValue.producedAt), 0).UTC(), ThisUpdate: time.Unix(int64(cacheValue.thisUpdate), 0).UTC(), NextUpdate: time.Unix(int64(cacheValue.nextUpdate), 0).UTC(), Status: int(cacheValue.status), }) } /* // writeOCSPCache writes a OCSP Response cache func (c *Client) writeOCSPCache(ctx context.Context, storage logical.Storage) error { c.Logger().Debug("writing OCSP Response cache") t := time.Now() m := make(map[string][]interface{}) keys := c.ocspResponseCache.Keys() if len(keys) > persistedCacheSize { keys = keys[:persistedCacheSize] } for _, k := range keys { e, ok := c.ocspResponseCache.Get(k) if ok { entry := e.(*ocspCachedResponse) // Don't store if expired if isInValidityRange(t, time.Unix(int64(entry.thisUpdate), 0), time.Unix(int64(entry.nextUpdate), 0)) { key := k.(certIDKey) cacheKeyInBase64, err := decodeCertIDKey(&key) if err != nil { return err } m[cacheKeyInBase64] = []interface{}{entry.status, entry.time, entry.producedAt, entry.thisUpdate, entry.nextUpdate} } } } v, err := jsonutil.EncodeJSONAndCompress(m, nil) if err != nil { return err } entry := logical.StorageEntry{ Key: ocspCacheKey, Value: v, } return storage.Put(ctx, &entry) } // readOCSPCache reads a OCSP Response cache from storage func (c *Client) readOCSPCache(ctx context.Context, storage logical.Storage) error { c.Logger().Debug("reading OCSP Response cache") entry, err := storage.Get(ctx, ocspCacheKey) if err != nil { return err } if entry == nil { return nil } var untypedCache map[string][]interface{} err = jsonutil.DecodeJSON(entry.Value, &untypedCache) if err != nil { return errors.New("failed to unmarshal OCSP cache") } for k, v := range untypedCache { key, err := c.encodeCertIDKey(k) if err != nil { return err } var times [4]float64 for i, t := range v[1:] { if jn, ok := t.(json.Number); ok { times[i], err = jn.Float64() if err != nil { return err } } else { times[i] = t.(float64) } } var status int if jn, ok := v[0].(json.Number); ok { s, err := jn.Int64() if err != nil { return err } status = int(s) } else { status = v[0].(int) } c.ocspResponseCache.Add(*key, &ocspCachedResponse{ status: ocspStatusCode(status), time: times[0], producedAt: times[1], thisUpdate: times[2], nextUpdate: times[3], }) } return nil } */ func New(logFactory func() hclog.Logger, cacheSize int) *Client { if cacheSize < 100 { cacheSize = 100 } cache, _ := lru.New2Q(cacheSize) c := Client{ caRoot: make(map[string]*x509.Certificate), ocspResponseCache: cache, logFactory: logFactory, } return &c } func (c *Client) Logger() hclog.Logger { return c.logFactory() } // insecureOcspTransport is the transport object that doesn't do certificate revocation check. func newInsecureOcspTransport(extraCas []*x509.Certificate) *http.Transport { // Get the SystemCertPool, continue with an empty pool on error rootCAs, _ := x509.SystemCertPool() if rootCAs == nil { rootCAs = x509.NewCertPool() } for _, c := range extraCas { rootCAs.AddCert(c) } config := &tls.Config{ RootCAs: rootCAs, } return &http.Transport{ MaxIdleConns: 10, IdleConnTimeout: 30 * time.Minute, Proxy: http.ProxyFromEnvironment, DialContext: (&net.Dialer{ Timeout: 30 * time.Second, KeepAlive: 30 * time.Second, }).DialContext, TLSClientConfig: config, } } // NewTransport includes the certificate revocation check with OCSP in sequential. func (c *Client) NewTransport(conf *VerifyConfig) *http.Transport { rootCAs := c.certPool if rootCAs == nil { rootCAs, _ = x509.SystemCertPool() } if rootCAs == nil { rootCAs = x509.NewCertPool() } for _, c := range conf.ExtraCas { rootCAs.AddCert(c) } return &http.Transport{ TLSClientConfig: &tls.Config{ RootCAs: rootCAs, VerifyPeerCertificate: c.verifyPeerCertificateSerial(conf), }, MaxIdleConns: 10, IdleConnTimeout: 30 * time.Minute, Proxy: http.ProxyFromEnvironment, DialContext: (&net.Dialer{ Timeout: 30 * time.Second, KeepAlive: 30 * time.Second, }).DialContext, } } /* func (c *Client) WriteCache(ctx context.Context, storage logical.Storage) error { c.ocspResponseCacheLock.Lock() defer c.ocspResponseCacheLock.Unlock() if c.cacheUpdated { err := c.writeOCSPCache(ctx, storage) if err == nil { c.cacheUpdated = false } return err } return nil } func (c *Client) ReadCache(ctx context.Context, storage logical.Storage) error { c.ocspResponseCacheLock.Lock() defer c.ocspResponseCacheLock.Unlock() return c.readOCSPCache(ctx, storage) } */ /* Apache License Version 2.0, January 2004 http://www.apache.org/licenses/ TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION 1. 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