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package sun.security.provider.certpath;

import java.io.IOException;
import java.security.GeneralSecurityException;
import java.security.InvalidKeyException;
import java.security.PublicKey;
import java.security.cert.CertificateException;
import java.security.cert.CertPathValidatorException;
import java.security.cert.PKIXReason;
import java.security.cert.CertStore;
import java.security.cert.CertStoreException;
import java.security.cert.PKIXBuilderParameters;
import java.security.cert.PKIXCertPathChecker;
import java.security.cert.TrustAnchor;
import java.security.cert.X509Certificate;
import java.security.cert.X509CertSelector;
import java.util.*;
import javax.security.auth.x500.X500Principal;

import sun.security.provider.certpath.PKIX.BuilderParams;
import sun.security.util.Debug;
import sun.security.x509.AccessDescription;
import sun.security.x509.AuthorityInfoAccessExtension;
import sun.security.x509.AuthorityKeyIdentifierExtension;
import static sun.security.x509.PKIXExtensions.*;
import sun.security.x509.X500Name;
import sun.security.x509.X509CertImpl;

This class represents a forward builder, which is able to retrieve matching certificates from CertStores and verify a particular certificate against a ForwardState.
Author: Yassir Elley, Sean Mullan
Since: 1.4
/** * This class represents a forward builder, which is able to retrieve * matching certificates from CertStores and verify a particular certificate * against a ForwardState. * * @since 1.4 * @author Yassir Elley * @author Sean Mullan */
class ForwardBuilder extends Builder { private static final Debug debug = Debug.getInstance("certpath"); private final Set<X509Certificate> trustedCerts; private final Set<X500Principal> trustedSubjectDNs; private final Set<TrustAnchor> trustAnchors; private X509CertSelector eeSelector; private AdaptableX509CertSelector caSelector; private X509CertSelector caTargetSelector; TrustAnchor trustAnchor; private boolean searchAllCertStores = true;
Initialize the builder with the input parameters.
Params:
  • params – the parameter set used to build a certification path
/** * Initialize the builder with the input parameters. * * @param params the parameter set used to build a certification path */
ForwardBuilder(BuilderParams buildParams, boolean searchAllCertStores) { super(buildParams); // populate sets of trusted certificates and subject DNs trustAnchors = buildParams.trustAnchors(); trustedCerts = new HashSet<X509Certificate>(trustAnchors.size()); trustedSubjectDNs = new HashSet<X500Principal>(trustAnchors.size()); for (TrustAnchor anchor : trustAnchors) { X509Certificate trustedCert = anchor.getTrustedCert(); if (trustedCert != null) { trustedCerts.add(trustedCert); trustedSubjectDNs.add(trustedCert.getSubjectX500Principal()); } else { trustedSubjectDNs.add(anchor.getCA()); } } this.searchAllCertStores = searchAllCertStores; }
Retrieves all certs from the specified CertStores that satisfy the requirements specified in the parameters and the current PKIX state (name constraints, policy constraints, etc).
Params:
  • currentState – the current state. Must be an instance of ForwardState
  • certStores – list of CertStores
/** * Retrieves all certs from the specified CertStores that satisfy the * requirements specified in the parameters and the current * PKIX state (name constraints, policy constraints, etc). * * @param currentState the current state. * Must be an instance of <code>ForwardState</code> * @param certStores list of CertStores */
@Override Collection<X509Certificate> getMatchingCerts(State currentState, List<CertStore> certStores) throws CertStoreException, CertificateException, IOException { if (debug != null) { debug.println("ForwardBuilder.getMatchingCerts()..."); } ForwardState currState = (ForwardState) currentState; /* * We store certs in a Set because we don't want duplicates. * As each cert is added, it is sorted based on the PKIXCertComparator * algorithm. */ Comparator<X509Certificate> comparator = new PKIXCertComparator(trustedSubjectDNs, currState.cert); Set<X509Certificate> certs = new TreeSet<>(comparator); /* * Only look for EE certs if search has just started. */ if (currState.isInitial()) { getMatchingEECerts(currState, certStores, certs); } getMatchingCACerts(currState, certStores, certs); return certs; } /* * Retrieves all end-entity certificates which satisfy constraints * and requirements specified in the parameters and PKIX state. */ private void getMatchingEECerts(ForwardState currentState, List<CertStore> certStores, Collection<X509Certificate> eeCerts) throws IOException { if (debug != null) { debug.println("ForwardBuilder.getMatchingEECerts()..."); } /* * Compose a certificate matching rule to filter out * certs which don't satisfy constraints * * First, retrieve clone of current target cert constraints, * and then add more selection criteria based on current validation * state. Since selector never changes, cache local copy & reuse. */ if (eeSelector == null) { eeSelector = (X509CertSelector) targetCertConstraints.clone(); /* * Match on certificate validity date */ eeSelector.setCertificateValid(buildParams.date()); /* * Policy processing optimizations */ if (buildParams.explicitPolicyRequired()) { eeSelector.setPolicy(getMatchingPolicies()); } /* * Require EE certs */ eeSelector.setBasicConstraints(-2); } /* Retrieve matching EE certs from CertStores */ addMatchingCerts(eeSelector, certStores, eeCerts, searchAllCertStores); }
Retrieves all CA certificates which satisfy constraints and requirements specified in the parameters and PKIX state.
/** * Retrieves all CA certificates which satisfy constraints * and requirements specified in the parameters and PKIX state. */
private void getMatchingCACerts(ForwardState currentState, List<CertStore> certStores, Collection<X509Certificate> caCerts) throws IOException { if (debug != null) { debug.println("ForwardBuilder.getMatchingCACerts()..."); } int initialSize = caCerts.size(); /* * Compose a CertSelector to filter out * certs which do not satisfy requirements. */ X509CertSelector sel = null; if (currentState.isInitial()) { if (targetCertConstraints.getBasicConstraints() == -2) { // no need to continue: this means we never can match a CA cert return; } /* This means a CA is the target, so match on same stuff as * getMatchingEECerts */ if (debug != null) { debug.println("ForwardBuilder.getMatchingCACerts(): " + "the target is a CA"); } if (caTargetSelector == null) { caTargetSelector = (X509CertSelector) targetCertConstraints.clone(); /* * Since we don't check the validity period of trusted * certificates, please don't set the certificate valid * criterion unless the trusted certificate matching is * completed. */ /* * Policy processing optimizations */ if (buildParams.explicitPolicyRequired()) caTargetSelector.setPolicy(getMatchingPolicies()); } sel = caTargetSelector; } else { if (caSelector == null) { caSelector = new AdaptableX509CertSelector(); /* * Since we don't check the validity period of trusted * certificates, please don't set the certificate valid * criterion unless the trusted certificate matching is * completed. */ /* * Policy processing optimizations */ if (buildParams.explicitPolicyRequired()) caSelector.setPolicy(getMatchingPolicies()); } /* * Match on subject (issuer of previous cert) */ caSelector.setSubject(currentState.issuerDN); /* * Match on subjectNamesTraversed (both DNs and AltNames) * (checks that current cert's name constraints permit it * to certify all the DNs and AltNames that have been traversed) */ CertPathHelper.setPathToNames (caSelector, currentState.subjectNamesTraversed); /* * check the validity period */ caSelector.setValidityPeriod(currentState.cert.getNotBefore(), currentState.cert.getNotAfter()); sel = caSelector; } /* * For compatibility, conservatively, we don't check the path * length constraint of trusted anchors. Please don't set the * basic constraints criterion unless the trusted certificate * matching is completed. */ sel.setBasicConstraints(-1); for (X509Certificate trustedCert : trustedCerts) { if (sel.match(trustedCert)) { if (debug != null) { debug.println("ForwardBuilder.getMatchingCACerts: " + "found matching trust anchor." + "\n SN: " + Debug.toHexString(trustedCert.getSerialNumber()) + "\n Subject: " + trustedCert.getSubjectX500Principal() + "\n Issuer: " + trustedCert.getIssuerX500Principal()); } if (caCerts.add(trustedCert) && !searchAllCertStores) { return; } } } /* * The trusted certificate matching is completed. We need to match * on certificate validity date. */ sel.setCertificateValid(buildParams.date()); /* * Require CA certs with a pathLenConstraint that allows * at least as many CA certs that have already been traversed */ sel.setBasicConstraints(currentState.traversedCACerts); /* * If we have already traversed as many CA certs as the maxPathLength * will allow us to, then we don't bother looking through these * certificate pairs. If maxPathLength has a value of -1, this * means it is unconstrained, so we always look through the * certificate pairs. */ if (currentState.isInitial() || (buildParams.maxPathLength() == -1) || (buildParams.maxPathLength() > currentState.traversedCACerts)) { if (addMatchingCerts(sel, certStores, caCerts, searchAllCertStores) && !searchAllCertStores) { return; } } if (!currentState.isInitial() && Builder.USE_AIA) { // check for AuthorityInformationAccess extension AuthorityInfoAccessExtension aiaExt = currentState.cert.getAuthorityInfoAccessExtension(); if (aiaExt != null) { getCerts(aiaExt, caCerts); } } if (debug != null) { int numCerts = caCerts.size() - initialSize; debug.println("ForwardBuilder.getMatchingCACerts: found " + numCerts + " CA certs"); } }
Download Certificates from the given AIA and add them to the specified Collection.
/** * Download Certificates from the given AIA and add them to the * specified Collection. */
// cs.getCertificates(caSelector) returns a collection of X509Certificate's // because of the selector, so the cast is safe @SuppressWarnings("unchecked") private boolean getCerts(AuthorityInfoAccessExtension aiaExt, Collection<X509Certificate> certs) { if (Builder.USE_AIA == false) { return false; } List<AccessDescription> adList = aiaExt.getAccessDescriptions(); if (adList == null || adList.isEmpty()) { return false; } boolean add = false; for (AccessDescription ad : adList) { CertStore cs = URICertStore.getInstance(ad); if (cs != null) { try { if (certs.addAll((Collection<X509Certificate>) cs.getCertificates(caSelector))) { add = true; if (!searchAllCertStores) { return true; } } } catch (CertStoreException cse) { if (debug != null) { debug.println("exception getting certs from CertStore:"); cse.printStackTrace(); } } } } return add; }
This inner class compares 2 PKIX certificates according to which should be tried first when building a path from the target. The preference order is as follows: Given trusted certificate(s): Subject:ou=D,ou=C,o=B,c=A Preference order for current cert: 1) The key identifier of an AKID extension (if present) in the previous certificate matches the key identifier in the SKID extension 2) Issuer matches a trusted subject Issuer: ou=D,ou=C,o=B,c=A 3) Issuer is a descendant of a trusted subject (in order of number of links to the trusted subject) a) Issuer: ou=E,ou=D,ou=C,o=B,c=A [links=1] b) Issuer: ou=F,ou=E,ou=D,ou=C,ou=B,c=A [links=2] 4) Issuer is an ancestor of a trusted subject (in order of number of links to the trusted subject) a) Issuer: ou=C,o=B,c=A [links=1] b) Issuer: o=B,c=A [links=2] 5) Issuer is in the same namespace as a trusted subject (in order of number of links to the trusted subject) a) Issuer: ou=G,ou=C,o=B,c=A [links=2] b) Issuer: ou=H,o=B,c=A [links=3] 6) Issuer is an ancestor of certificate subject (in order of number of links to the certificate subject) a) Issuer: ou=K,o=J,c=A Subject: ou=L,ou=K,o=J,c=A b) Issuer: o=J,c=A Subject: ou=L,ou=K,0=J,c=A 7) Any other certificates
/** * This inner class compares 2 PKIX certificates according to which * should be tried first when building a path from the target. * The preference order is as follows: * * Given trusted certificate(s): * Subject:ou=D,ou=C,o=B,c=A * * Preference order for current cert: * * 1) The key identifier of an AKID extension (if present) in the * previous certificate matches the key identifier in the SKID extension * * 2) Issuer matches a trusted subject * Issuer: ou=D,ou=C,o=B,c=A * * 3) Issuer is a descendant of a trusted subject (in order of * number of links to the trusted subject) * a) Issuer: ou=E,ou=D,ou=C,o=B,c=A [links=1] * b) Issuer: ou=F,ou=E,ou=D,ou=C,ou=B,c=A [links=2] * * 4) Issuer is an ancestor of a trusted subject (in order of number of * links to the trusted subject) * a) Issuer: ou=C,o=B,c=A [links=1] * b) Issuer: o=B,c=A [links=2] * * 5) Issuer is in the same namespace as a trusted subject (in order of * number of links to the trusted subject) * a) Issuer: ou=G,ou=C,o=B,c=A [links=2] * b) Issuer: ou=H,o=B,c=A [links=3] * * 6) Issuer is an ancestor of certificate subject (in order of number * of links to the certificate subject) * a) Issuer: ou=K,o=J,c=A * Subject: ou=L,ou=K,o=J,c=A * b) Issuer: o=J,c=A * Subject: ou=L,ou=K,0=J,c=A * * 7) Any other certificates */
static class PKIXCertComparator implements Comparator<X509Certificate> { static final String METHOD_NME = "PKIXCertComparator.compare()"; private final Set<X500Principal> trustedSubjectDNs; private final X509CertSelector certSkidSelector; PKIXCertComparator(Set<X500Principal> trustedSubjectDNs, X509CertImpl previousCert) throws IOException { this.trustedSubjectDNs = trustedSubjectDNs; this.certSkidSelector = getSelector(previousCert); }
Returns an X509CertSelector for matching on the authority key identifier, or null if not applicable.
/** * Returns an X509CertSelector for matching on the authority key * identifier, or null if not applicable. */
private X509CertSelector getSelector(X509CertImpl previousCert) throws IOException { if (previousCert != null) { AuthorityKeyIdentifierExtension akidExt = previousCert.getAuthorityKeyIdentifierExtension(); if (akidExt != null) { byte[] skid = akidExt.getEncodedKeyIdentifier(); if (skid != null) { X509CertSelector selector = new X509CertSelector(); selector.setSubjectKeyIdentifier(skid); return selector; } } } return null; }
Params:
  • oCert1 – First X509Certificate to be compared
  • oCert2 – Second X509Certificate to be compared
Throws:
Returns:-1 if oCert1 is preferable to oCert2, or if oCert1 and oCert2 are equally preferable (in this case it doesn't matter which is preferable, but we don't return 0 because the comparator would behave strangely when used in a SortedSet). 1 if oCert2 is preferable to oCert1 0 if oCert1.equals(oCert2). We only return 0 if the certs are equal so that this comparator behaves correctly when used in a SortedSet.
/** * @param oCert1 First X509Certificate to be compared * @param oCert2 Second X509Certificate to be compared * @return -1 if oCert1 is preferable to oCert2, or * if oCert1 and oCert2 are equally preferable (in this * case it doesn't matter which is preferable, but we don't * return 0 because the comparator would behave strangely * when used in a SortedSet). * 1 if oCert2 is preferable to oCert1 * 0 if oCert1.equals(oCert2). We only return 0 if the * certs are equal so that this comparator behaves * correctly when used in a SortedSet. * @throws ClassCastException if either argument is not of type * X509Certificate */
@Override public int compare(X509Certificate oCert1, X509Certificate oCert2) { // if certs are the same, return 0 if (oCert1.equals(oCert2)) return 0; // If akid/skid match then it is preferable if (certSkidSelector != null) { if (certSkidSelector.match(oCert1)) { return -1; } if (certSkidSelector.match(oCert2)) { return 1; } } X500Principal cIssuer1 = oCert1.getIssuerX500Principal(); X500Principal cIssuer2 = oCert2.getIssuerX500Principal(); X500Name cIssuer1Name = X500Name.asX500Name(cIssuer1); X500Name cIssuer2Name = X500Name.asX500Name(cIssuer2); if (debug != null) { debug.println(METHOD_NME + " o1 Issuer: " + cIssuer1); debug.println(METHOD_NME + " o2 Issuer: " + cIssuer2); } /* If one cert's issuer matches a trusted subject, then it is * preferable. */ if (debug != null) { debug.println(METHOD_NME + " MATCH TRUSTED SUBJECT TEST..."); } boolean m1 = trustedSubjectDNs.contains(cIssuer1); boolean m2 = trustedSubjectDNs.contains(cIssuer2); if (debug != null) { debug.println(METHOD_NME + " m1: " + m1); debug.println(METHOD_NME + " m2: " + m2); } if (m1 && m2) { return -1; } else if (m1) { return -1; } else if (m2) { return 1; } /* If one cert's issuer is a naming descendant of a trusted subject, * then it is preferable, in order of increasing naming distance. */ if (debug != null) { debug.println(METHOD_NME + " NAMING DESCENDANT TEST..."); } for (X500Principal tSubject : trustedSubjectDNs) { X500Name tSubjectName = X500Name.asX500Name(tSubject); int distanceTto1 = Builder.distance(tSubjectName, cIssuer1Name, -1); int distanceTto2 = Builder.distance(tSubjectName, cIssuer2Name, -1); if (debug != null) { debug.println(METHOD_NME +" distanceTto1: " + distanceTto1); debug.println(METHOD_NME +" distanceTto2: " + distanceTto2); } if (distanceTto1 > 0 || distanceTto2 > 0) { if (distanceTto1 == distanceTto2) { return -1; } else if (distanceTto1 > 0 && distanceTto2 <= 0) { return -1; } else if (distanceTto1 <= 0 && distanceTto2 > 0) { return 1; } else if (distanceTto1 < distanceTto2) { return -1; } else { // distanceTto1 > distanceTto2 return 1; } } } /* If one cert's issuer is a naming ancestor of a trusted subject, * then it is preferable, in order of increasing naming distance. */ if (debug != null) { debug.println(METHOD_NME + " NAMING ANCESTOR TEST..."); } for (X500Principal tSubject : trustedSubjectDNs) { X500Name tSubjectName = X500Name.asX500Name(tSubject); int distanceTto1 = Builder.distance (tSubjectName, cIssuer1Name, Integer.MAX_VALUE); int distanceTto2 = Builder.distance (tSubjectName, cIssuer2Name, Integer.MAX_VALUE); if (debug != null) { debug.println(METHOD_NME +" distanceTto1: " + distanceTto1); debug.println(METHOD_NME +" distanceTto2: " + distanceTto2); } if (distanceTto1 < 0 || distanceTto2 < 0) { if (distanceTto1 == distanceTto2) { return -1; } else if (distanceTto1 < 0 && distanceTto2 >= 0) { return -1; } else if (distanceTto1 >= 0 && distanceTto2 < 0) { return 1; } else if (distanceTto1 > distanceTto2) { return -1; } else { return 1; } } } /* If one cert's issuer is in the same namespace as a trusted * subject, then it is preferable, in order of increasing naming * distance. */ if (debug != null) { debug.println(METHOD_NME +" SAME NAMESPACE AS TRUSTED TEST..."); } for (X500Principal tSubject : trustedSubjectDNs) { X500Name tSubjectName = X500Name.asX500Name(tSubject); X500Name tAo1 = tSubjectName.commonAncestor(cIssuer1Name); X500Name tAo2 = tSubjectName.commonAncestor(cIssuer2Name); if (debug != null) { debug.println(METHOD_NME +" tAo1: " + String.valueOf(tAo1)); debug.println(METHOD_NME +" tAo2: " + String.valueOf(tAo2)); } if (tAo1 != null || tAo2 != null) { if (tAo1 != null && tAo2 != null) { int hopsTto1 = Builder.hops (tSubjectName, cIssuer1Name, Integer.MAX_VALUE); int hopsTto2 = Builder.hops (tSubjectName, cIssuer2Name, Integer.MAX_VALUE); if (debug != null) { debug.println(METHOD_NME +" hopsTto1: " + hopsTto1); debug.println(METHOD_NME +" hopsTto2: " + hopsTto2); } if (hopsTto1 == hopsTto2) { } else if (hopsTto1 > hopsTto2) { return 1; } else { // hopsTto1 < hopsTto2 return -1; } } else if (tAo1 == null) { return 1; } else { return -1; } } } /* If one cert's issuer is an ancestor of that cert's subject, * then it is preferable, in order of increasing naming distance. */ if (debug != null) { debug.println(METHOD_NME+" CERT ISSUER/SUBJECT COMPARISON TEST..."); } X500Principal cSubject1 = oCert1.getSubjectX500Principal(); X500Principal cSubject2 = oCert2.getSubjectX500Principal(); X500Name cSubject1Name = X500Name.asX500Name(cSubject1); X500Name cSubject2Name = X500Name.asX500Name(cSubject2); if (debug != null) { debug.println(METHOD_NME + " o1 Subject: " + cSubject1); debug.println(METHOD_NME + " o2 Subject: " + cSubject2); } int distanceStoI1 = Builder.distance (cSubject1Name, cIssuer1Name, Integer.MAX_VALUE); int distanceStoI2 = Builder.distance (cSubject2Name, cIssuer2Name, Integer.MAX_VALUE); if (debug != null) { debug.println(METHOD_NME + " distanceStoI1: " + distanceStoI1); debug.println(METHOD_NME + " distanceStoI2: " + distanceStoI2); } if (distanceStoI2 > distanceStoI1) { return -1; } else if (distanceStoI2 < distanceStoI1) { return 1; } /* Otherwise, certs are equally preferable. */ if (debug != null) { debug.println(METHOD_NME + " no tests matched; RETURN 0"); } return -1; } }
Verifies a matching certificate. This method executes the validation steps in the PKIX path validation algorithm which were not satisfied by the selection criteria used by getCertificates() to find the certs and only the steps that can be executed in a forward direction (target to trust anchor). Those steps that can only be executed in a reverse direction are deferred until the complete path has been built. Trust anchor certs are not validated, but are used to verify the signature and revocation status of the previous cert. If the last certificate is being verified (the one whose subject matches the target subject, then steps in 6.1.4 of the PKIX 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.
Params:
  • cert – the certificate to be verified
  • currentState – the current state against which the cert is verified
  • certPathList – the certPathList generated thus far
/** * Verifies a matching certificate. * * This method executes the validation steps in the PKIX path * validation algorithm <draft-ietf-pkix-new-part1-08.txt> which were * not satisfied by the selection criteria used by getCertificates() * to find the certs and only the steps that can be executed in a * forward direction (target to trust anchor). Those steps that can * only be executed in a reverse direction are deferred until the * complete path has been built. * * Trust anchor certs are not validated, but are used to verify the * signature and revocation status of the previous cert. * * If the last certificate is being verified (the one whose subject * matches the target subject, then steps in 6.1.4 of the PKIX * 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 */
@Override void verifyCert(X509Certificate cert, State currentState, List<X509Certificate> certPathList) throws GeneralSecurityException { if (debug != null) { debug.println("ForwardBuilder.verifyCert(SN: " + Debug.toHexString(cert.getSerialNumber()) + "\n Issuer: " + cert.getIssuerX500Principal() + ")" + "\n Subject: " + cert.getSubjectX500Principal() + ")"); } ForwardState currState = (ForwardState)currentState; // Don't bother to verify untrusted certificate more. currState.untrustedChecker.check(cert, Collections.<String>emptySet()); /* * check for looping - abort a loop if we encounter the same * certificate twice */ if (certPathList != null) { for (X509Certificate cpListCert : certPathList) { if (cert.equals(cpListCert)) { if (debug != null) { debug.println("loop detected!!"); } throw new CertPathValidatorException("loop detected"); } } } /* check if trusted cert */ boolean isTrustedCert = trustedCerts.contains(cert); /* we don't perform any validation of the trusted cert */ if (!isTrustedCert) { /* * Check CRITICAL private extensions for user checkers that * support forward checking (forwardCheckers) and remove * ones we know how to check. */ Set<String> unresCritExts = cert.getCriticalExtensionOIDs(); if (unresCritExts == null) { unresCritExts = Collections.<String>emptySet(); } for (PKIXCertPathChecker checker : currState.forwardCheckers) { checker.check(cert, unresCritExts); } /* * Remove extensions from user checkers that don't 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> supportedExts = checker.getSupportedExtensions(); if (supportedExts != null) { unresCritExts.removeAll(supportedExts); } } } /* * Look at the remaining extensions and remove any ones we know how * to check. If there are any left, throw an exception! */ 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 this is the target certificate (init=true), then we are * not able to do any more verification, so just return */ if (currState.isInitial()) { return; } /* we don't perform any validation of the trusted cert */ if (!isTrustedCert) { /* Make sure this is a CA cert */ if (cert.getBasicConstraints() == -1) { throw new CertificateException("cert is NOT a CA cert"); } /* * Check keyUsage extension */ KeyChecker.verifyCAKeyUsage(cert); } /* * the following checks are performed even when the cert * is a trusted cert, since we are only extracting the * subjectDN, and publicKey from the cert * in order to verify a previous cert */ /* * Check signature only if no key requiring key parameters has been * encountered. */ if (!currState.keyParamsNeeded()) { (currState.cert).verify(cert.getPublicKey(), buildParams.sigProvider()); } }
Verifies whether the input certificate completes the path. First checks the cert against each trust anchor that was specified, in order, and returns true if the cert matches the trust anchor specified as a certificate or has the same key and subject of an anchor specified as a trusted {pubkey, caname} pair. If no match has been found, does a second check of the cert against anchors specified as a trusted {pubkey, caname} pair to see if the cert was issued by that anchor. Returns false if none of the trust anchors are valid for this cert.
Params:
  • cert – the certificate to test
Returns:a boolean value indicating whether the cert completes the path.
/** * Verifies whether the input certificate completes the path. * First checks the cert against each trust anchor that was specified, * in order, and returns true if the cert matches the trust anchor * specified as a certificate or has the same key and subject of an anchor * specified as a trusted {pubkey, caname} pair. * If no match has been found, does a second check of the cert against * anchors specified as a trusted {pubkey, caname} pair to see if the cert * was issued by that anchor. * Returns false if none of the trust anchors are valid for this cert. * * @param cert the certificate to test * @return a boolean value indicating whether the cert completes the path. */
@Override boolean isPathCompleted(X509Certificate cert) { List<TrustAnchor> otherAnchors = new ArrayList<>(); // first, check if cert is already trusted for (TrustAnchor anchor : trustAnchors) { if (anchor.getTrustedCert() != null) { if (cert.equals(anchor.getTrustedCert())) { this.trustAnchor = anchor; return true; } else { continue; } } X500Principal principal = anchor.getCA(); PublicKey publicKey = anchor.getCAPublicKey(); if (principal != null && publicKey != null && principal.equals(cert.getSubjectX500Principal())) { if (publicKey.equals(cert.getPublicKey())) { // the cert itself is a trust anchor this.trustAnchor = anchor; return true; } // else, it is a self-issued certificate of the anchor } otherAnchors.add(anchor); } // next, check if cert is issued by anchor specified by key/name for (TrustAnchor anchor : otherAnchors) { X500Principal principal = anchor.getCA(); PublicKey publicKey = anchor.getCAPublicKey(); // Check subject/issuer name chaining if (principal == null || !principal.equals(cert.getIssuerX500Principal())) { continue; } // skip anchor if it contains a DSA key with no DSA params if (PKIX.isDSAPublicKeyWithoutParams(publicKey)) { continue; } /* * Check signature */ try { cert.verify(publicKey, buildParams.sigProvider()); } catch (InvalidKeyException ike) { if (debug != null) { debug.println("ForwardBuilder.isPathCompleted() invalid " + "DSA key found"); } continue; } catch (GeneralSecurityException e){ if (debug != null) { debug.println("ForwardBuilder.isPathCompleted() " + "unexpected exception"); e.printStackTrace(); } continue; } this.trustAnchor = anchor; return true; } return false; }
Adds the certificate to the certPathList
Params:
  • cert – the certificate to be added
  • certPathList – the certification path list
/** Adds the certificate to the certPathList * * @param cert the certificate to be added * @param certPathList the certification path list */
@Override void addCertToPath(X509Certificate cert, LinkedList<X509Certificate> certPathList) { certPathList.addFirst(cert); }
Removes final certificate from the certPathList
Params:
  • certPathList – the certification path list
/** Removes final certificate from the certPathList * * @param certPathList the certification path list */
@Override void removeFinalCertFromPath(LinkedList<X509Certificate> certPathList) { certPathList.removeFirst(); } }