/** * Validate the passed in certificate as being of the correct type to be used for time stamping. * To be valid it must have an ExtendedKeyUsage extension which has a key purpose identifier of * id-kp-timeStamping. * * @param cert the certificate of interest. * @throws TSPValidationException if the certicate fails on one of the check points. */ public static void validateCertificate(X509Certificate cert) throws TSPValidationException { if (cert.getVersion() != 3) { throw new IllegalArgumentException("Certificate must have an ExtendedKeyUsage extension."); } byte[] ext = cert.getExtensionValue(X509Extensions.ExtendedKeyUsage.getId()); if (ext == null) { throw new TSPValidationException("Certificate must have an ExtendedKeyUsage extension."); } if (!cert.getCriticalExtensionOIDs().contains(X509Extensions.ExtendedKeyUsage.getId())) { throw new TSPValidationException( "Certificate must have an ExtendedKeyUsage extension marked as critical."); } ASN1InputStream aIn = new ASN1InputStream(new ByteArrayInputStream(ext)); try { aIn = new ASN1InputStream( new ByteArrayInputStream(((ASN1OctetString) aIn.readObject()).getOctets())); ExtendedKeyUsage extKey = ExtendedKeyUsage.getInstance(aIn.readObject()); if (!extKey.hasKeyPurposeId(KeyPurposeId.id_kp_timeStamping) || extKey.size() != 1) { throw new TSPValidationException("ExtendedKeyUsage not solely time stamping."); } } catch (IOException e) { throw new TSPValidationException("cannot process ExtendedKeyUsage extension"); } }
public static void checkUsageForCodeSigning( X509Certificate paramX509Certificate, int paramInt, boolean paramBoolean) throws CertificateException, IOException { String str = null; Set localSet = paramX509Certificate.getCriticalExtensionOIDs(); if (localSet == null) localSet = Collections.EMPTY_SET; if (!checkBasicConstraintsForCodeSigning(paramX509Certificate, localSet, paramInt)) { Trace.msgSecurityPrintln("trustdecider.check.basicconstraints"); str = ResourceManager.getMessage("trustdecider.check.basicconstraints"); throw new CertificateException(str); } if (paramInt == 0) { if (!checkLeafKeyUsageForCodeSigning(paramX509Certificate, localSet, paramBoolean)) { Trace.msgSecurityPrintln("trustdecider.check.leafkeyusage"); str = ResourceManager.getMessage("trustdecider.check.leafkeyusage"); throw new CertificateException(str); } } else if (!checkSignerKeyUsage(paramX509Certificate, localSet)) { Trace.msgSecurityPrintln("trustdecider.check.signerkeyusage"); str = ResourceManager.getMessage("trustdecider.check.signerkeyusage"); throw new CertificateException(str); } if (!localSet.isEmpty()) { Trace.msgSecurityPrintln("trustdecider.check.extensions"); str = ResourceManager.getMessage("trustdecider.check.extensions"); throw new CertificateException(str); } }
protected static void prepareNextCertB1( int i, List[] policyNodes, String id_p, Map m_idp, X509Certificate cert) throws AnnotatedException, CertPathValidatorException { boolean idp_found = false; Iterator nodes_i = policyNodes[i].iterator(); while (nodes_i.hasNext()) { PKIXPolicyNode node = (PKIXPolicyNode) nodes_i.next(); if (node.getValidPolicy().equals(id_p)) { idp_found = true; node.expectedPolicies = (Set) m_idp.get(id_p); break; } } if (!idp_found) { nodes_i = policyNodes[i].iterator(); while (nodes_i.hasNext()) { PKIXPolicyNode node = (PKIXPolicyNode) nodes_i.next(); if (ANY_POLICY.equals(node.getValidPolicy())) { Set pq = null; ASN1Sequence policies = (ASN1Sequence) getExtensionValue(cert, CERTIFICATE_POLICIES); Enumeration e = policies.getObjects(); while (e.hasMoreElements()) { PolicyInformation pinfo = PolicyInformation.getInstance(e.nextElement()); if (ANY_POLICY.equals(pinfo.getPolicyIdentifier().getId())) { pq = getQualifierSet(pinfo.getPolicyQualifiers()); break; } } boolean ci = false; if (cert.getCriticalExtensionOIDs() != null) { ci = cert.getCriticalExtensionOIDs().contains(CERTIFICATE_POLICIES); } PKIXPolicyNode p_node = (PKIXPolicyNode) node.getParent(); if (ANY_POLICY.equals(p_node.getValidPolicy())) { PKIXPolicyNode c_node = new PKIXPolicyNode(new ArrayList(), i, (Set) m_idp.get(id_p), p_node, pq, id_p, ci); p_node.addChild(c_node); policyNodes[i].add(c_node); } break; } } } }
/** @tests java.security.cert.X509Certificate#getExtensionValue(java.lang.String) */ public void test_getExtensionValueLjava_lang_String() throws Exception { InputStream is = Support_Resources.getResourceStream("hyts_certificate_PEM.txt"); CertificateFactory certFact = CertificateFactory.getInstance("X509"); X509Certificate pemCert = (X509Certificate) certFact.generateCertificate(is); Vector<String> extensionOids = new Vector<String>(); extensionOids.addAll(pemCert.getCriticalExtensionOIDs()); extensionOids.addAll(pemCert.getNonCriticalExtensionOIDs()); Iterator i = extensionOids.iterator(); while (i.hasNext()) { String oid = (String) i.next(); byte[] value = pemCert.getExtensionValue(oid); if (value != null && value.length > 0) { // check that it is an encoded as a OCTET STRING assertEquals( "The extension value for the oid " + oid + " was not encoded as an OCTET STRING", 0x04, value[0]); } } }
/** * Verifies a matching certificate. * * <p>This method executes any of the validation steps in the PKIX path validation algorithm which * were not satisfied via filtering out non-compliant certificates with certificate matching * rules. * * <p>If the last certificate is being verified (the one whose subject matches the target subject, * then the steps in Section 6.1.4 of the Certification Path Validation algorithm are NOT * executed, regardless of whether or not the last cert is an end-entity cert or not. This allows * callers to certify CA certs as well as EE certs. * * @param cert the certificate to be verified * @param currentState the current state against which the cert is verified * @param certPathList the certPathList generated thus far */ void verifyCert(X509Certificate cert, State currState, List certPathList) throws GeneralSecurityException { if (debug != null) debug.println( "ReverseBuilder.verifyCert(SN: " + Debug.toHexString(cert.getSerialNumber()) + "\n Subject: " + cert.getSubjectX500Principal() + ")"); ReverseState currentState = (ReverseState) currState; /* we don't perform any validation of the trusted cert */ if (currentState.isInitial()) { return; } /* * check for looping - abort a loop if * ((we encounter the same certificate twice) AND * ((policyMappingInhibited = true) OR (no policy mapping * extensions can be found between the occurences of the same * certificate))) * in order to facilitate the check to see if there are * any policy mapping extensions found between the occurences * of the same certificate, we reverse the certpathlist first */ if ((certPathList != null) && (!certPathList.isEmpty())) { List reverseCertList = new ArrayList(); Iterator iter = certPathList.iterator(); while (iter.hasNext()) { reverseCertList.add(0, iter.next()); } Iterator cpListIter = reverseCertList.iterator(); boolean policyMappingFound = false; while (cpListIter.hasNext()) { X509Certificate cpListCert = (X509Certificate) cpListIter.next(); X509CertImpl cpListCertImpl = X509CertImpl.toImpl(cpListCert); PolicyMappingsExtension policyMappingsExt = cpListCertImpl.getPolicyMappingsExtension(); if (policyMappingsExt != null) { policyMappingFound = true; } if (debug != null) debug.println("policyMappingFound = " + policyMappingFound); if (cert.equals(cpListCert)) { if ((buildParams.isPolicyMappingInhibited()) || (!policyMappingFound)) { if (debug != null) debug.println("loop detected!!"); throw new CertPathValidatorException("loop detected"); } } } } /* check if target cert */ boolean finalCert = cert.getSubjectX500Principal().equals(targetSubjectDN); /* check if CA cert */ boolean caCert = (cert.getBasicConstraints() != -1 ? true : false); /* if there are more certs to follow, verify certain constraints */ if (!finalCert) { /* check if CA cert */ if (!caCert) throw new CertPathValidatorException("cert is NOT a CA cert"); /* If the certificate was not self-issued, verify that * remainingCerts is greater than zero */ if ((currentState.remainingCACerts <= 0) && !X509CertImpl.isSelfIssued(cert)) { throw new CertPathValidatorException("pathLenConstraint violated, path too long"); } /* * Check keyUsage extension (only if CA cert and not final cert) */ KeyChecker.verifyCAKeyUsage(cert); } else { /* * If final cert, check that it satisfies specified target * constraints */ if (targetCertSelector.match(cert) == false) { throw new CertPathValidatorException("target certificate " + "constraints check failed"); } } /* * Check revocation. */ if (buildParams.isRevocationEnabled()) { boolean crlSign = currentState.crlChecker.check(cert, currentState.pubKey, true); // if this cert can't vouch for the CRL on the next cert, and // if this wasn't the last cert in the chain, then we can't // keep going from here! // NOTE: if we ever add indirect/idp support, this will have // to change... if ((!crlSign) && (!finalCert)) throw new CertPathValidatorException("cert can't vouch for crl"); } /* Check name constraints if this is not a self-issued cert */ if (finalCert || !X509CertImpl.isSelfIssued(cert)) { if (currentState.nc != null) { try { if (!currentState.nc.verify(cert)) { throw new CertPathValidatorException("name constraints check failed"); } } catch (IOException ioe) { throw new CertPathValidatorException(ioe); } } } /* * Check policy */ X509CertImpl certImpl = X509CertImpl.toImpl(cert); currentState.rootNode = PolicyChecker.processPolicies( currentState.certIndex, initPolicies, currentState.explicitPolicy, currentState.policyMapping, currentState.inhibitAnyPolicy, buildParams.getPolicyQualifiersRejected(), currentState.rootNode, certImpl, finalCert); /* * Check CRITICAL private extensions */ Set unresolvedCritExts = cert.getCriticalExtensionOIDs(); if (unresolvedCritExts == null) { unresolvedCritExts = Collections.EMPTY_SET; } Iterator i = currentState.userCheckers.iterator(); while (i.hasNext()) { PKIXCertPathChecker checker = (PKIXCertPathChecker) i.next(); checker.check(cert, unresolvedCritExts); } /* * Look at the remaining extensions and remove any ones we have * already checked. If there are any left, throw an exception! */ if (!unresolvedCritExts.isEmpty()) { unresolvedCritExts.remove(PKIXExtensions.BasicConstraints_Id.toString()); unresolvedCritExts.remove(PKIXExtensions.NameConstraints_Id.toString()); unresolvedCritExts.remove(PKIXExtensions.CertificatePolicies_Id.toString()); unresolvedCritExts.remove(PKIXExtensions.PolicyMappings_Id.toString()); unresolvedCritExts.remove(PKIXExtensions.PolicyConstraints_Id.toString()); unresolvedCritExts.remove(PKIXExtensions.InhibitAnyPolicy_Id.toString()); unresolvedCritExts.remove(PKIXExtensions.SubjectAlternativeName_Id.toString()); unresolvedCritExts.remove(PKIXExtensions.KeyUsage_Id.toString()); unresolvedCritExts.remove(PKIXExtensions.ExtendedKeyUsage_Id.toString()); if (!unresolvedCritExts.isEmpty()) throw new CertificateException("Unrecognized critical extension(s)"); } /* * Check signature. */ if (buildParams.getSigProvider() != null) { cert.verify(currentState.pubKey, buildParams.getSigProvider()); } else { cert.verify(currentState.pubKey); } }
/* * This method performs a depth first search for a certification * path while building forward which meets the requirements set in * the parameters object. * It uses an adjacency list to store all certificates which were * tried (i.e. at one time added to the path - they may not end up in * the final path if backtracking occurs). This information can * be used later to debug or demo the build. * * See "Data Structure and Algorithms, by Aho, Hopcroft, and Ullman" * for an explanation of the DFS algorithm. * * @param dN the distinguished name being currently searched for certs * @param currentState the current PKIX validation state */ private void depthFirstSearchForward( X500Principal dN, ForwardState currentState, ForwardBuilder builder, List<List<Vertex>> adjList, LinkedList<X509Certificate> cpList) throws GeneralSecurityException, IOException { if (debug != null) { debug.println( "SunCertPathBuilder.depthFirstSearchForward(" + dN + ", " + currentState.toString() + ")"); } /* * Find all the certificates issued to dN which * satisfy the PKIX certification path constraints. */ Collection<X509Certificate> certs = builder.getMatchingCerts(currentState, buildParams.certStores()); List<Vertex> vertices = addVertices(certs, adjList); if (debug != null) { debug.println( "SunCertPathBuilder.depthFirstSearchForward(): " + "certs.size=" + vertices.size()); } /* * For each cert in the collection, verify anything * that hasn't been checked yet (signature, revocation, etc) * and check for loops. Call depthFirstSearchForward() * recursively for each good cert. */ vertices: for (Vertex vertex : vertices) { /** * Restore state to currentState each time through the loop. This is important because some of * the user-defined checkers modify the state, which MUST be restored if the cert eventually * fails to lead to the target and the next matching cert is tried. */ ForwardState nextState = (ForwardState) currentState.clone(); X509Certificate cert = vertex.getCertificate(); try { builder.verifyCert(cert, nextState, cpList); } catch (GeneralSecurityException gse) { if (debug != null) { debug.println( "SunCertPathBuilder.depthFirstSearchForward()" + ": validation failed: " + gse); gse.printStackTrace(); } vertex.setThrowable(gse); continue; } /* * Certificate is good. * If cert completes the path, * process userCheckers that don't support forward checking * and process policies over whole path * and backtrack appropriately if there is a failure * else if cert does not complete the path, * add it to the path */ if (builder.isPathCompleted(cert)) { if (debug != null) debug.println( "SunCertPathBuilder.depthFirstSearchForward()" + ": commencing final verification"); List<X509Certificate> appendedCerts = new ArrayList<>(cpList); /* * if the trust anchor selected is specified as a trusted * public key rather than a trusted cert, then verify this * cert (which is signed by the trusted public key), but * don't add it yet to the cpList */ if (builder.trustAnchor.getTrustedCert() == null) { appendedCerts.add(0, cert); } Set<String> initExpPolSet = Collections.singleton(PolicyChecker.ANY_POLICY); PolicyNodeImpl rootNode = new PolicyNodeImpl(null, PolicyChecker.ANY_POLICY, null, false, initExpPolSet, false); List<PKIXCertPathChecker> checkers = new ArrayList<>(); PolicyChecker policyChecker = new PolicyChecker( buildParams.initialPolicies(), appendedCerts.size(), buildParams.explicitPolicyRequired(), buildParams.policyMappingInhibited(), buildParams.anyPolicyInhibited(), buildParams.policyQualifiersRejected(), rootNode); checkers.add(policyChecker); // add the algorithm checker checkers.add(new AlgorithmChecker(builder.trustAnchor)); BasicChecker basicChecker = null; if (nextState.keyParamsNeeded()) { PublicKey rootKey = cert.getPublicKey(); if (builder.trustAnchor.getTrustedCert() == null) { rootKey = builder.trustAnchor.getCAPublicKey(); if (debug != null) debug.println( "SunCertPathBuilder.depthFirstSearchForward " + "using buildParams public key: " + rootKey.toString()); } TrustAnchor anchor = new TrustAnchor(cert.getSubjectX500Principal(), rootKey, null); // add the basic checker basicChecker = new BasicChecker(anchor, buildParams.date(), buildParams.sigProvider(), true); checkers.add(basicChecker); } buildParams.setCertPath(cf.generateCertPath(appendedCerts)); boolean revCheckerAdded = false; List<PKIXCertPathChecker> ckrs = buildParams.certPathCheckers(); for (PKIXCertPathChecker ckr : ckrs) { if (ckr instanceof PKIXRevocationChecker) { if (revCheckerAdded) { throw new CertPathValidatorException( "Only one PKIXRevocationChecker can be specified"); } revCheckerAdded = true; // if it's our own, initialize it if (ckr instanceof RevocationChecker) { ((RevocationChecker) ckr).init(builder.trustAnchor, buildParams); } } } // only add a RevocationChecker if revocation is enabled and // a PKIXRevocationChecker has not already been added if (buildParams.revocationEnabled() && !revCheckerAdded) { checkers.add(new RevocationChecker(builder.trustAnchor, buildParams)); } checkers.addAll(ckrs); // Why we don't need BasicChecker and RevocationChecker // if nextState.keyParamsNeeded() is false? for (int i = 0; i < appendedCerts.size(); i++) { X509Certificate currCert = appendedCerts.get(i); if (debug != null) debug.println("current subject = " + currCert.getSubjectX500Principal()); Set<String> unresCritExts = currCert.getCriticalExtensionOIDs(); if (unresCritExts == null) { unresCritExts = Collections.<String>emptySet(); } for (PKIXCertPathChecker currChecker : checkers) { if (!currChecker.isForwardCheckingSupported()) { if (i == 0) { currChecker.init(false); // The user specified // AlgorithmChecker may not be // able to set the trust anchor until now. if (currChecker instanceof AlgorithmChecker) { ((AlgorithmChecker) currChecker).trySetTrustAnchor(builder.trustAnchor); } } try { currChecker.check(currCert, unresCritExts); } catch (CertPathValidatorException cpve) { if (debug != null) debug.println( "SunCertPathBuilder.depthFirstSearchForward(): " + "final verification failed: " + cpve); // If the target cert itself is revoked, we // cannot trust it. We can bail out here. if (buildParams.targetCertConstraints().match(currCert) && cpve.getReason() == BasicReason.REVOKED) { throw cpve; } vertex.setThrowable(cpve); continue vertices; } } } /* * Remove extensions from user checkers that support * forward checking. After this step, we will have * removed all extensions that all user checkers * are capable of processing. */ for (PKIXCertPathChecker checker : buildParams.certPathCheckers()) { if (checker.isForwardCheckingSupported()) { Set<String> suppExts = checker.getSupportedExtensions(); if (suppExts != null) { unresCritExts.removeAll(suppExts); } } } if (!unresCritExts.isEmpty()) { unresCritExts.remove(BasicConstraints_Id.toString()); unresCritExts.remove(NameConstraints_Id.toString()); unresCritExts.remove(CertificatePolicies_Id.toString()); unresCritExts.remove(PolicyMappings_Id.toString()); unresCritExts.remove(PolicyConstraints_Id.toString()); unresCritExts.remove(InhibitAnyPolicy_Id.toString()); unresCritExts.remove(SubjectAlternativeName_Id.toString()); unresCritExts.remove(KeyUsage_Id.toString()); unresCritExts.remove(ExtendedKeyUsage_Id.toString()); if (!unresCritExts.isEmpty()) { throw new CertPathValidatorException( "unrecognized critical extension(s)", null, null, -1, PKIXReason.UNRECOGNIZED_CRIT_EXT); } } } if (debug != null) debug.println( "SunCertPathBuilder.depthFirstSearchForward()" + ": final verification succeeded - path completed!"); pathCompleted = true; /* * if the user specified a trusted public key rather than * trusted certs, then add this cert (which is signed by * the trusted public key) to the cpList */ if (builder.trustAnchor.getTrustedCert() == null) builder.addCertToPath(cert, cpList); // Save the trust anchor this.trustAnchor = builder.trustAnchor; /* * Extract and save the final target public key */ if (basicChecker != null) { finalPublicKey = basicChecker.getPublicKey(); } else { Certificate finalCert; if (cpList.isEmpty()) { finalCert = builder.trustAnchor.getTrustedCert(); } else { finalCert = cpList.getLast(); } finalPublicKey = finalCert.getPublicKey(); } policyTreeResult = policyChecker.getPolicyTree(); return; } else { builder.addCertToPath(cert, cpList); } /* Update the PKIX state */ nextState.updateState(cert); /* * Append an entry for cert in adjacency list and * set index for current vertex. */ adjList.add(new LinkedList<Vertex>()); vertex.setIndex(adjList.size() - 1); /* recursively search for matching certs at next dN */ depthFirstSearchForward(cert.getIssuerX500Principal(), nextState, builder, adjList, cpList); /* * If path has been completed, return ASAP! */ if (pathCompleted) { return; } else { /* * If we get here, it means we have searched all possible * certs issued by the dN w/o finding any matching certs. * This means we have to backtrack to the previous cert in * the path and try some other paths. */ if (debug != null) debug.println("SunCertPathBuilder.depthFirstSearchForward()" + ": backtracking"); builder.removeFinalCertFromPath(cpList); } } }