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/*

This is not an official specification document, and usage is restricted.

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(c) 2005-2007 Sun Microsystems, Inc. All Rights Reserved.

Neither this file nor any files generated from it describe a complete specification, and they may only be used as described below. For example, no permission is given for you to incorporate this file, in whole or in part, in an implementation of a Java specification.

Sun Microsystems Inc. owns the copyright in this file and it is provided to you for informative, as opposed to normative, use. The file and any files generated from it may be used to generate other informative documentation, such as a unified set of documents of API signatures for a platform that includes technologies expressed as Java APIs. The file may also be used to produce "compilation stubs," which allow applications to be compiled and validated for such platforms.

Any work generated from this file, such as unified javadocs or compiled stub files, must be accompanied by this notice in its entirety.

This work corresponds to the API signatures of JSR 219: Foundation Profile 1.1. In the event of a discrepency between this work and the JSR 219 specification, which is available at http://www.jcp.org/en/jsr/detail?id=219, the latter takes precedence. */ package java.security.cert; import java.math.BigInteger; import java.security.Principal; import java.security.PublicKey; import java.util.Collection; import java.util.Date; import java.util.List; import javax.security.auth.x500.X500Principal; /** *

* Abstract class for X.509 certificates. This provides a standard * way to access all the attributes of an X.509 certificate. *

* In June of 1996, the basic X.509 v3 format was completed by * ISO/IEC and ANSI X9, which is described below in ASN.1: *

 * Certificate  ::=  SEQUENCE  {
 *     tbsCertificate       TBSCertificate,
 *     signatureAlgorithm   AlgorithmIdentifier,
 *     signature            BIT STRING  }
 * 
*

* These certificates are widely used to support authentication and * other functionality in Internet security systems. Common applications * include Privacy Enhanced Mail (PEM), Transport Layer Security (SSL), * code signing for trusted software distribution, and Secure Electronic * Transactions (SET). *

* These certificates are managed and vouched for by Certificate * Authorities (CAs). CAs are services which create certificates by * placing data in the X.509 standard format and then digitally signing * that data. CAs act as trusted third parties, making introductions * between principals who have no direct knowledge of each other. * CA certificates are either signed by themselves, or by some other * CA such as a "root" CA. *

* More information can be found in RFC 2459, * "Internet X.509 Public Key Infrastructure Certificate and CRL * Profile" at * http://www.ietf.org/rfc/rfc2459.txt . *

* The ASN.1 definition of tbsCertificate is: *

 * TBSCertificate  ::=  SEQUENCE  {
 *     version         [0]  EXPLICIT Version DEFAULT v1,
 *     serialNumber         CertificateSerialNumber,
 *     signature            AlgorithmIdentifier,
 *     issuer               Name,
 *     validity             Validity,
 *     subject              Name,
 *     subjectPublicKeyInfo SubjectPublicKeyInfo,
 *     issuerUniqueID  [1]  IMPLICIT UniqueIdentifier OPTIONAL,
 *                          -- If present, version must be v2 or v3
 *     subjectUniqueID [2]  IMPLICIT UniqueIdentifier OPTIONAL,
 *                          -- If present, version must be v2 or v3
 *     extensions      [3]  EXPLICIT Extensions OPTIONAL
 *                          -- If present, version must be v3
 *     }
 * 
*

* Certificates are instantiated using a certificate factory. The following is * an example of how to instantiate an X.509 certificate: *

 
 * InputStream inStream = new FileInputStream("fileName-of-cert");
 * CertificateFactory cf = CertificateFactory.getInstance("X.509");
 * X509Certificate cert = (X509Certificate)cf.generateCertificate(inStream);
 * inStream.close();
 * 
* * @author Hemma Prafullchandra * * @version 1.27 * * @see Certificate * @see CertificateFactory * @see X509Extension */ public abstract class X509Certificate extends Certificate implements X509Extension { /** * Constructor for X.509 certificates. */ protected X509Certificate() { super("X.509"); } /** * Checks that the certificate is currently valid. It is if * the current date and time are within the validity period given in the * certificate. *

* The validity period consists of two date/time values: * the first and last dates (and times) on which the certificate * is valid. It is defined in * ASN.1 as: *

     * validity             Validity

* Validity ::= SEQUENCE { * notBefore CertificateValidityDate, * notAfter CertificateValidityDate }

* CertificateValidityDate ::= CHOICE { * utcTime UTCTime, * generalTime GeneralizedTime } *

* * @exception CertificateExpiredException if the certificate has expired. * @exception CertificateNotYetValidException if the certificate is not * yet valid. */ public abstract void checkValidity() throws CertificateExpiredException, CertificateNotYetValidException; /** * Checks that the given date is within the certificate's * validity period. In other words, this determines whether the * certificate would be valid at the given date/time. * * @param date the Date to check against to see if this certificate * is valid at that date/time. * * @exception CertificateExpiredException if the certificate has expired * with respect to the date supplied. * @exception CertificateNotYetValidException if the certificate is not * yet valid with respect to the date supplied. * * @see #checkValidity() */ public abstract void checkValidity(Date date) throws CertificateExpiredException, CertificateNotYetValidException; /** * Gets the version (version number) value from the * certificate. * The ASN.1 definition for this is: *
     * version  [0] EXPLICIT Version DEFAULT v1

* Version ::= INTEGER { v1(0), v2(1), v3(2) } *

* @return the version number, i.e. 1, 2 or 3. */ public abstract int getVersion(); /** * Gets the serialNumber value from the certificate. * The serial number is an integer assigned by the certification * authority to each certificate. It must be unique for each * certificate issued by a given CA (i.e., the issuer name and * serial number identify a unique certificate). * The ASN.1 definition for this is: *
     * serialNumber     CertificateSerialNumber

* * CertificateSerialNumber ::= INTEGER *

* * @return the serial number. */ public abstract BigInteger getSerialNumber(); /** * Gets the issuer (issuer distinguished name) value from * the certificate. The issuer name identifies the entity that signed (and * issued) the certificate. * *

The issuer name field contains an * X.500 distinguished name (DN). * The ASN.1 definition for this is: *

     * issuer    Name

* * Name ::= CHOICE { RDNSequence } * RDNSequence ::= SEQUENCE OF RelativeDistinguishedName * RelativeDistinguishedName ::= * SET OF AttributeValueAssertion * * AttributeValueAssertion ::= SEQUENCE { * AttributeType, * AttributeValue } * AttributeType ::= OBJECT IDENTIFIER * AttributeValue ::= ANY *

* The Name describes a hierarchical name composed of * attributes, * such as country name, and corresponding values, such as US. * The type of the AttributeValue component is determined by * the AttributeType; in general it will be a * directoryString. A directoryString is usually * one of PrintableString, * TeletexString or UniversalString. * * @return a Principal whose name is the issuer distinguished name. */ public abstract Principal getIssuerDN(); /** * Returns the issuer (issuer distinguished name) value from the * certificate as an X500Principal. *

* It is recommended that subclasses override this method to provide * an efficient implementation. * * @return an X500Principal representing the issuer * distinguished name * @since 1.4 */ public X500Principal getIssuerX500Principal() { return null; } /** * Gets the subject (subject distinguished name) value * from the certificate. If the subject value is empty, * then the getName() method of the returned * Principal object returns an empty string (""). * *

The ASN.1 definition for this is: *

     * subject    Name
     * 
* *

See {@link #getIssuerDN() getIssuerDN} for Name * and other relevant definitions. * * @return a Principal whose name is the subject name. */ public abstract Principal getSubjectDN(); /** * Returns the subject (subject distinguished name) value from the * certificate as an X500Principal. If the subject value * is empty, then the getName() method of the returned * X500Principal object returns an empty string (""). *

* It is recommended that subclasses override this method to provide * an efficient implementation. * * @return an X500Principal representing the subject * distinguished name * @since 1.4 */ public X500Principal getSubjectX500Principal() { return null; } /** * Gets the notBefore date from the validity period of * the certificate. * The relevant ASN.1 definitions are: *

     * validity             Validity

* * Validity ::= SEQUENCE { * notBefore CertificateValidityDate, * notAfter CertificateValidityDate }

* CertificateValidityDate ::= CHOICE { * utcTime UTCTime, * generalTime GeneralizedTime } *

* * @return the start date of the validity period. * @see #checkValidity */ public abstract Date getNotBefore(); /** * Gets the notAfter date from the validity period of * the certificate. See {@link #getNotBefore() getNotBefore} * for relevant ASN.1 definitions. * * @return the end date of the validity period. * @see #checkValidity */ public abstract Date getNotAfter(); /** * Gets the DER-encoded certificate information, the * tbsCertificate from this certificate. * This can be used to verify the signature independently. * * @return the DER-encoded certificate information. * @exception CertificateEncodingException if an encoding error occurs. */ public abstract byte[] getTBSCertificate() throws CertificateEncodingException; /** * Gets the signature value (the raw signature bits) from * the certificate. * The ASN.1 definition for this is: *
     * signature     BIT STRING  
     * 
* * @return the signature. */ public abstract byte[] getSignature(); /** * Gets the signature algorithm name for the certificate * signature algorithm. An example is the string "SHA-1/DSA". * The ASN.1 definition for this is: *
     * signatureAlgorithm   AlgorithmIdentifier

* AlgorithmIdentifier ::= SEQUENCE { * algorithm OBJECT IDENTIFIER, * parameters ANY DEFINED BY algorithm OPTIONAL } * -- contains a value of the type * -- registered for use with the * -- algorithm object identifier value *

* *

The algorithm name is determined from the algorithm * OID string. * * @return the signature algorithm name. */ public abstract String getSigAlgName(); /** * Gets the signature algorithm OID string from the certificate. * An OID is represented by a set of nonnegative whole numbers separated * by periods. * For example, the string "1.2.840.10040.4.3" identifies the SHA-1 * with DSA signature algorithm, as per RFC 2459. * *

See {@link #getSigAlgName() getSigAlgName} for * relevant ASN.1 definitions. * * @return the signature algorithm OID string. */ public abstract String getSigAlgOID(); /** * Gets the DER-encoded signature algorithm parameters from this * certificate's signature algorithm. In most cases, the signature * algorithm parameters are null; the parameters are usually * supplied with the certificate's public key. * If access to individual parameter values is needed then use * {@link java.security.AlgorithmParameters AlgorithmParameters} * and instantiate with the name returned by * {@link #getSigAlgName() getSigAlgName}. * *

See {@link #getSigAlgName() getSigAlgName} for * relevant ASN.1 definitions. * * @return the DER-encoded signature algorithm parameters, or * null if no parameters are present. */ public abstract byte[] getSigAlgParams(); /** * Gets the issuerUniqueID value from the certificate. * The issuer unique identifier is present in the certificate * to handle the possibility of reuse of issuer names over time. * RFC 2459 recommends that names not be reused and that * conforming certificates not make use of unique identifiers. * Applications conforming to that profile should be capable of * parsing unique identifiers and making comparisons. * *

The ASN.1 definition for this is: *

     * issuerUniqueID  [1]  IMPLICIT UniqueIdentifier OPTIONAL

* UniqueIdentifier ::= BIT STRING *

* * @return the issuer unique identifier or null if it is not * present in the certificate. */ public abstract boolean[] getIssuerUniqueID(); /** * Gets the subjectUniqueID value from the certificate. * *

The ASN.1 definition for this is: *

     * subjectUniqueID  [2]  IMPLICIT UniqueIdentifier OPTIONAL

* UniqueIdentifier ::= BIT STRING *

* * @return the subject unique identifier or null if it is not * present in the certificate. */ public abstract boolean[] getSubjectUniqueID(); /** * Gets a boolean array representing bits of * the KeyUsage extension, (OID = 2.5.29.15). * The key usage extension defines the purpose (e.g., encipherment, * signature, certificate signing) of the key contained in the * certificate. * The ASN.1 definition for this is: *
     * KeyUsage ::= BIT STRING {
     *     digitalSignature        (0),
     *     nonRepudiation          (1),
     *     keyEncipherment         (2),
     *     dataEncipherment        (3),
     *     keyAgreement            (4),
     *     keyCertSign             (5),
     *     cRLSign                 (6),
     *     encipherOnly            (7),
     *     decipherOnly            (8) }
     * 
* RFC 2459 recommends that when used, this be marked * as a critical extension. * * @return the KeyUsage extension of this certificate, represented as * an array of booleans. The order of KeyUsage values in the array is * the same as in the above ASN.1 definition. The array will contain a * value for each KeyUsage defined above. If the KeyUsage list encoded * in the certificate is longer than the above list, it will not be * truncated. Returns null if this certificate does not * contain a KeyUsage extension. */ public abstract boolean[] getKeyUsage(); /** * Gets an unmodifiable list of Strings representing the OBJECT * IDENTIFIERs of the ExtKeyUsageSyntax field of the * extended key usage extension, (OID = 2.5.29.37). It indicates * one or more purposes for which the certified public key may be * used, in addition to or in place of the basic purposes * indicated in the key usage extension field. The ASN.1 * definition for this is: *
     * ExtKeyUsageSyntax ::= SEQUENCE SIZE (1..MAX) OF KeyPurposeId

* * KeyPurposeId ::= OBJECT IDENTIFIER

*

* * Key purposes may be defined by any organization with a * need. Object identifiers used to identify key purposes shall be * assigned in accordance with IANA or ITU-T Rec. X.660 | * ISO/IEC/ITU 9834-1. *

* This method was added to version 1.4 of the Java 2 Platform Standard * Edition. In order to maintain backwards compatibility with existing * service providers, this method is not abstract * and it provides a default implementation. Subclasses * should override this method with a correct implementation. * * @return the ExtendedKeyUsage extension of this certificate, * as an unmodifiable list of object identifiers represented * as Strings. Returns null if this certificate does not * contain an ExtendedKeyUsage extension. * @throws CertificateParsingException if the extension cannot be decoded * @since 1.4 */ public List getExtendedKeyUsage() throws CertificateParsingException { return null; } /** * Gets the certificate constraints path length from the * critical BasicConstraints extension, (OID = 2.5.29.19). *

* The basic constraints extension identifies whether the subject * of the certificate is a Certificate Authority (CA) and * how deep a certification path may exist through that CA. The * pathLenConstraint field (see below) is meaningful * only if cA is set to TRUE. In this case, it gives the * maximum number of CA certificates that may follow this certificate in a * certification path. A value of zero indicates that only an end-entity * certificate may follow in the path. *

* Note that for RFC 2459 this extension is always marked * critical if cA is TRUE, meaning this certificate belongs * to a Certificate Authority. *

* The ASN.1 definition for this is: *

     * BasicConstraints ::= SEQUENCE {
     *     cA                  BOOLEAN DEFAULT FALSE,
     *     pathLenConstraint   INTEGER (0..MAX) OPTIONAL }
     * 
* * @return the value of pathLenConstraint if the * BasicConstraints extension is present in the certificate and the * subject of the certificate is a CA, otherwise -1. * If the subject of the certificate is a CA and * pathLenConstraint does not appear, * Integer.MAX_VALUE is returned to indicate that there is no * limit to the allowed length of the certification path. */ public abstract int getBasicConstraints(); /** * Gets an immutable collection of subject alternative names from the * SubjectAltName extension, (OID = 2.5.29.17). *

* The ASN.1 definition of the SubjectAltName extension is: *

     * SubjectAltName ::= GeneralNames
     *
     * GeneralNames :: = SEQUENCE SIZE (1..MAX) OF GeneralName
     *
     * GeneralName ::= CHOICE {
     *      otherName                       [0]     OtherName,
     *      rfc822Name                      [1]     IA5String,
     *      dNSName                         [2]     IA5String,
     *      x400Address                     [3]     ORAddress,
     *      directoryName                   [4]     Name,
     *      ediPartyName                    [5]     EDIPartyName,
     *      uniformResourceIdentifier       [6]     IA5String,
     *      iPAddress                       [7]     OCTET STRING,
     *      registeredID                    [8]     OBJECT IDENTIFIER}
     * 
*

* If this certificate does not contain a SubjectAltName * extension, null is returned. Otherwise, a * Collection is returned with an entry representing each * GeneralName included in the extension. Each entry is a * List whose first entry is an Integer * (the name type, 0-8) and whose second entry is a String * or a byte array (the name, in string or ASN.1 DER encoded form, * respectively). *

* RFC 822, DNS, and URI names are returned as Strings, * using the well-established string formats for those types (subject to * the restrictions included in RFC 2459). IPv4 address names are * returned using dotted quad notation. IPv6 address names are returned * in the form "a1:a2:...:a8", where a1-a8 are hexadecimal values * representing the eight 16-bit pieces of the address. OID names are * returned as Strings represented as a series of nonnegative * integers separated by periods. And directory names (distinguished names) * are returned in RFC 2253 string format. No standard string format is * defined for otherNames, X.400 names, EDI party names, or any * other type of names. They are returned as byte arrays * containing the ASN.1 DER encoded form of the name. *

* Note that the Collection returned may contain more * than one name of the same type. Also, note that the returned * Collection is immutable and any entries containing byte * arrays are cloned to protect against subsequent modifications. *

* This method was added to version 1.4 of the Java 2 Platform Standard * Edition. In order to maintain backwards compatibility with existing * service providers, this method is not abstract * and it provides a default implementation. Subclasses * should override this method with a correct implementation. * * @return an immutable Collection of subject alternative * names (or null) * @throws CertificateParsingException if the extension cannot be decoded * @since 1.4 */ public Collection getSubjectAlternativeNames() throws CertificateParsingException { return null; } /** * Gets an immutable collection of issuer alternative names from the * IssuerAltName extension, (OID = 2.5.29.18). *

* The ASN.1 definition of the IssuerAltName extension is: *

     * IssuerAltName ::= GeneralNames
     * 
* The ASN.1 definition of GeneralNames is defined * in {@link #getSubjectAlternativeNames getSubjectAlternativeNames}. *

* If this certificate does not contain an IssuerAltName * extension, null is returned. Otherwise, a * Collection is returned with an entry representing each * GeneralName included in the extension. Each entry is a * List whose first entry is an Integer * (the name type, 0-8) and whose second entry is a String * or a byte array (the name, in string or ASN.1 DER encoded form, * respectively). For more details about the formats used for each * name type, see the getSubjectAlternativeNames method. *

* Note that the Collection returned may contain more * than one name of the same type. Also, note that the returned * Collection is immutable and any entries containing byte * arrays are cloned to protect against subsequent modifications. *

* This method was added to version 1.4 of the Java 2 Platform Standard * Edition. In order to maintain backwards compatibility with existing * service providers, this method is not abstract * and it provides a default implementation. Subclasses * should override this method with a correct implementation. * * @return an immutable Collection of issuer alternative * names (or null) * @throws CertificateParsingException if the extension cannot be decoded * @since 1.4 */ public Collection getIssuerAlternativeNames() throws CertificateParsingException { return null; } }





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