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A Java security provider for supporting ShangMi algorithms in public key infrastructure

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/*
 * Copyright (c) 1996, 2022, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
 * by Oracle in the LICENSE file that accompanied this code.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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package com.tencent.kona.sun.security.x509;

import java.io.IOException;
import java.security.Principal;
import java.util.*;
import java.util.StringJoiner;

import com.tencent.kona.sun.security.util.DerInputStream;
import com.tencent.kona.sun.security.util.DerOutputStream;
import com.tencent.kona.sun.security.util.DerValue;
import com.tencent.kona.sun.security.util.KnownOIDs;
import com.tencent.kona.sun.security.util.ObjectIdentifier;
import com.tencent.kona.sun.security.util.Oid;

import javax.security.auth.x500.X500Principal;

/**
 * Note:  As of 1.4, the public class,
 * javax.security.auth.x500.X500Principal,
 * should be used when parsing, generating, and comparing X.500 DNs.
 * This class contains other useful methods for checking name constraints
 * and retrieving DNs by keyword.
 *
 * 

X.500 names are used to identify entities, such as those which are * identified by X.509 certificates. They are world-wide, hierarchical, * and descriptive. Entities can be identified by attributes, and in * some systems can be searched for according to those attributes. *

* The ASN.1 for this is: *

 * GeneralName ::= CHOICE {
 * ....
 *     directoryName                   [4]     Name,
 * ....
 * Name ::= CHOICE {
 *   RDNSequence }
 *
 * RDNSequence ::= SEQUENCE OF RelativeDistinguishedName
 *
 * RelativeDistinguishedName ::=
 *   SET OF AttributeTypeAndValue
 *
 * AttributeTypeAndValue ::= SEQUENCE {
 *   type     AttributeType,
 *   value    AttributeValue }
 *
 * AttributeType ::= OBJECT IDENTIFIER
 *
 * AttributeValue ::= ANY DEFINED BY AttributeType
 * ....
 * DirectoryString ::= CHOICE {
 *       teletexString           TeletexString (SIZE (1..MAX)),
 *       printableString         PrintableString (SIZE (1..MAX)),
 *       universalString         UniversalString (SIZE (1..MAX)),
 *       utf8String              UTF8String (SIZE (1.. MAX)),
 *       bmpString               BMPString (SIZE (1..MAX)) }
 * 
*

* This specification requires only a subset of the name comparison * functionality specified in the X.500 series of specifications. The * requirements for conforming implementations are as follows: *

    *
  1. attribute values encoded in different types (e.g., * PrintableString and BMPString) may be assumed to represent * different strings; * *
  2. attribute values in types other than PrintableString are case * sensitive (this permits matching of attribute values as binary * objects); * *
  3. attribute values in PrintableString are not case sensitive * (e.g., "Marianne Swanson" is the same as "MARIANNE SWANSON"); and * *
  4. attribute values in PrintableString are compared after * removing leading and trailing white space and converting internal * substrings of one or more consecutive white space characters to a * single space. *
*

* These name comparison rules permit a certificate user to validate * certificates issued using languages or encodings unfamiliar to the * certificate user. *

* In addition, implementations of this specification MAY use these * comparison rules to process unfamiliar attribute types for name * chaining. This allows implementations to process certificates with * unfamiliar attributes in the issuer name. *

* Note that the comparison rules defined in the X.500 series of * specifications indicate that the character sets used to encode data * in distinguished names are irrelevant. The characters themselves are * compared without regard to encoding. Implementations of the profile * are permitted to use the comparison algorithm defined in the X.500 * series. Such an implementation will recognize a superset of name * matches recognized by the algorithm specified above. *

* Note that instances of this class are immutable. * * @author David Brownell * @author Amit Kapoor * @author Hemma Prafullchandra * @see GeneralName * @see GeneralNames * @see GeneralNameInterface */ public class X500Name implements GeneralNameInterface, Principal { private String dn; // roughly RFC 1779 DN, or null private String rfc1779Dn; // RFC 1779 compliant DN, or null private String rfc2253Dn; // RFC 2253 DN, or null private String canonicalDn; // canonical RFC 2253 DN or null private RDN[] names; // RDNs (never null) private X500Principal x500Principal; private byte[] encoded; // cached immutable list of the RDNs and all the AVAs private volatile List rdnList; private volatile List allAvaList; /** * Constructs a name from a conventionally formatted string, such * as "CN=Dave, OU=JavaSoft, O=Sun Microsystems, C=US". * (RFC 1779, 2253, or 4514 style). * * @param dname the X.500 Distinguished Name */ public X500Name(String dname) throws IOException { this(dname, Collections.emptyMap()); } /** * Constructs a name from a conventionally formatted string, such * as "CN=Dave, OU=JavaSoft, O=Sun Microsystems, C=US". * (RFC 1779, 2253, or 4514 style). * * @param dname the X.500 Distinguished Name * @param keywordMap an additional keyword/OID map */ public X500Name(String dname, Map keywordMap) throws IOException { parseDN(dname, keywordMap); } /** * Constructs a name from a string formatted according to format. * Currently, the formats DEFAULT and RFC2253 are supported. * DEFAULT is the default format used by the X500Name(String) * constructor. RFC2253 is the format strictly according to RFC2253 * without extensions. * * @param dname the X.500 Distinguished Name * @param format the specified format of the String DN */ public X500Name(String dname, String format) throws IOException { if (dname == null) { throw new NullPointerException("Name must not be null"); } if (format.equalsIgnoreCase("RFC2253")) { parseRFC2253DN(dname); } else if (format.equalsIgnoreCase("DEFAULT")) { parseDN(dname, Collections.emptyMap()); } else { throw new IOException("Unsupported format " + format); } } /** * Constructs a name from fields common in enterprise application * environments. * *

NOTE: The behaviour when any of * these strings contain characters outside the ASCII range * is unspecified in currently relevant standards. * * @param commonName common name of a person, e.g. "Vivette Davis" * @param organizationUnit small organization name, e.g. "Purchasing" * @param organizationName large organization name, e.g. "Onizuka, Inc." * @param country two letter country code, e.g. "CH" */ public X500Name(String commonName, String organizationUnit, String organizationName, String country) throws IOException { names = new RDN[4]; /* * NOTE: it's only on output that little-endian * ordering is used. */ names[3] = new RDN(1); names[3].assertion[0] = new AVA(commonName_oid, new DerValue(commonName)); names[2] = new RDN(1); names[2].assertion[0] = new AVA(orgUnitName_oid, new DerValue(organizationUnit)); names[1] = new RDN(1); names[1].assertion[0] = new AVA(orgName_oid, new DerValue(organizationName)); names[0] = new RDN(1); names[0].assertion[0] = new AVA(countryName_oid, new DerValue(country)); } /** * Constructs a name from fields common in Internet application * environments. * *

NOTE: The behaviour when any of * these strings contain characters outside the ASCII range * is unspecified in currently relevant standards. * * @param commonName common name of a person, e.g. "Vivette Davis" * @param organizationUnit small organization name, e.g. "Purchasing" * @param organizationName large organization name, e.g. "Onizuka, Inc." * @param localityName locality (city) name, e.g. "Palo Alto" * @param stateName state name, e.g. "California" * @param country two letter country code, e.g. "CH" */ public X500Name(String commonName, String organizationUnit, String organizationName, String localityName, String stateName, String country) throws IOException { RDN name; List list = new ArrayList<>(6); if (country != null) { name = new RDN(1); name.assertion[0] = new AVA(countryName_oid, new DerValue(country)); list.add(name); } if (stateName != null) { name = new RDN(1); name.assertion[0] = new AVA(stateName_oid, new DerValue(stateName)); list.add(name); } if (localityName != null) { name = new RDN(1); name.assertion[0] = new AVA(localityName_oid, new DerValue(localityName)); list.add(name); } if (organizationName != null) { name = new RDN(1); name.assertion[0] = new AVA(orgName_oid, new DerValue(organizationName)); list.add(name); } if (organizationUnit != null) { name = new RDN(1); name.assertion[0] = new AVA(orgUnitName_oid, new DerValue(organizationUnit)); list.add(name); } if (commonName != null) { name = new RDN(1); name.assertion[0] = new AVA(commonName_oid, new DerValue(commonName)); list.add(name); } names = list.toArray(new RDN[0]); } /** * Constructs a name from an array of relative distinguished names * * @param rdnArray array of relative distinguished names * @throws IOException on error */ public X500Name(RDN[] rdnArray) throws IOException { if (rdnArray == null) { names = new RDN[0]; } else { names = rdnArray.clone(); for (int i = 0; i < names.length; i++) { if (names[i] == null) { throw new IOException("Cannot create an X500Name"); } } } } /** * Constructs a name from an ASN.1 encoded value. The encoding * of the name in the stream uses DER (a BER/1 subset). * * @param value a DER-encoded value holding an X.500 name. */ public X500Name(DerValue value) throws IOException { //Note that toDerInputStream uses only the buffer (data) and not //the tag, so an empty SEQUENCE (OF) will yield an empty DerInputStream this(value.toDerInputStream()); } /** * Constructs a name from an ASN.1 encoded input stream. The encoding * of the name in the stream uses DER (a BER/1 subset). * * @param in DER-encoded data holding an X.500 name. */ public X500Name(DerInputStream in) throws IOException { parseDER(in); } /** * Constructs a name from an ASN.1 encoded byte array. * * @param name DER-encoded byte array holding an X.500 name. */ public X500Name(byte[] name) throws IOException { DerInputStream in = new DerInputStream(name); parseDER(in); } /** * Return an immutable List of all RDNs in this X500Name. */ public List rdns() { List list = rdnList; if (list == null) { list = Collections.unmodifiableList(Arrays.asList(names)); rdnList = list; } return list; } /** * Return the number of RDNs in this X500Name. */ public int size() { return names.length; } /** * Return an immutable List of the AVAs contained in all the * RDNs of this X500Name. */ public List allAvas() { List list = allAvaList; if (list == null) { list = new ArrayList<>(); for (int i = 0; i < names.length; i++) { list.addAll(names[i].avas()); } list = Collections.unmodifiableList(list); allAvaList = list; } return list; } /** * Return the total number of AVAs contained in all the RDNs of * this X500Name. */ public int avaSize() { return allAvas().size(); } /** * Return whether this X500Name is empty. An X500Name is not empty * if it has at least one RDN containing at least one AVA. */ public boolean isEmpty() { int n = names.length; for (int i = 0; i < n; i++) { if (names[i].assertion.length != 0) { return false; } } return true; } /** * Calculates a hash code value for the object. Objects * which are equal will also have the same hashcode. */ public int hashCode() { return getRFC2253CanonicalName().hashCode(); } /** * Compares this name with another, for equality. * * @return true iff the names are identical. */ public boolean equals(Object obj) { if (this == obj) { return true; } if (obj instanceof X500Name == false) { return false; } X500Name other = (X500Name)obj; // if we already have the canonical forms, compare now if ((this.canonicalDn != null) && (other.canonicalDn != null)) { return this.canonicalDn.equals(other.canonicalDn); } // quick check that number of RDNs and AVAs match before canonicalizing int n = this.names.length; if (n != other.names.length) { return false; } for (int i = 0; i < n; i++) { RDN r1 = this.names[i]; RDN r2 = other.names[i]; if (r1.assertion.length != r2.assertion.length) { return false; } } // definite check via canonical form String thisCanonical = this.getRFC2253CanonicalName(); String otherCanonical = other.getRFC2253CanonicalName(); return thisCanonical.equals(otherCanonical); } /* * Returns the name component as a Java string, regardless of its * encoding restrictions. */ private String getString(DerValue attribute) throws IOException { if (attribute == null) return null; String value = attribute.getAsString(); if (value == null) throw new IOException("not a DER string encoding, " + attribute.tag); else return value; } /** * Return type of GeneralName. */ public int getType() { return (GeneralNameInterface.NAME_DIRECTORY); } /** * Returns a "Country" name component. If more than one * such attribute exists, the topmost one is returned. * * @return "C=" component of the name, if any. */ public String getCountry() throws IOException { DerValue attr = findAttribute(countryName_oid); return getString(attr); } /** * Returns an "Organization" name component. If more than * one such attribute exists, the topmost one is returned. * * @return "O=" component of the name, if any. */ public String getOrganization() throws IOException { DerValue attr = findAttribute(orgName_oid); return getString(attr); } /** * Returns an "Organizational Unit" name component. If more * than one such attribute exists, the topmost one is returned. * * @return "OU=" component of the name, if any. */ public String getOrganizationalUnit() throws IOException { DerValue attr = findAttribute(orgUnitName_oid); return getString(attr); } /** * Returns a "Common Name" component. If more than one such * attribute exists, the topmost one is returned. * * @return "CN=" component of the name, if any. */ public String getCommonName() throws IOException { DerValue attr = findAttribute(commonName_oid); return getString(attr); } /** * Returns a "Locality" name component. If more than one * such component exists, the topmost one is returned. * * @return "L=" component of the name, if any. */ public String getLocality() throws IOException { DerValue attr = findAttribute(localityName_oid); return getString(attr); } /** * Returns a "State" name component. If more than one * such component exists, the topmost one is returned. * * @return "S=" component of the name, if any. */ public String getState() throws IOException { DerValue attr = findAttribute(stateName_oid); return getString(attr); } /** * Returns a "Domain" name component. If more than one * such component exists, the topmost one is returned. * * @return "DC=" component of the name, if any. */ public String getDomain() throws IOException { DerValue attr = findAttribute(DOMAIN_COMPONENT_OID); return getString(attr); } /** * Returns a "DN Qualifier" name component. If more than one * such component exists, the topmost one is returned. * * @return "DNQ=" component of the name, if any. */ public String getDNQualifier() throws IOException { DerValue attr = findAttribute(DNQUALIFIER_OID); return getString(attr); } /** * Returns a "Surname" name component. If more than one * such component exists, the topmost one is returned. * * @return "SURNAME=" component of the name, if any. */ public String getSurname() throws IOException { DerValue attr = findAttribute(SURNAME_OID); return getString(attr); } /** * Returns a "Given Name" name component. If more than one * such component exists, the topmost one is returned. * * @return "GIVENNAME=" component of the name, if any. */ public String getGivenName() throws IOException { DerValue attr = findAttribute(GIVENNAME_OID); return getString(attr); } /** * Returns an "Initials" name component. If more than one * such component exists, the topmost one is returned. * * @return "INITIALS=" component of the name, if any. */ public String getInitials() throws IOException { DerValue attr = findAttribute(INITIALS_OID); return getString(attr); } /** * Returns a "Generation Qualifier" name component. If more than one * such component exists, the topmost one is returned. * * @return "GENERATION=" component of the name, if any. */ public String getGeneration() throws IOException { DerValue attr = findAttribute(GENERATIONQUALIFIER_OID); return getString(attr); } /** * Returns an "IP address" name component. If more than one * such component exists, the topmost one is returned. * * @return "IP=" component of the name, if any. */ public String getIP() throws IOException { DerValue attr = findAttribute(ipAddress_oid); return getString(attr); } /** * Returns a string form of the X.500 distinguished name. * The format of the string is from RFC 1779. The returned string * may contain non-standardised keywords for more readability * (keywords from RFCs 1779, 2253, and 5280). */ public String toString() { if (dn == null) { generateDN(); } return dn; } /** * Returns a string form of the X.500 distinguished name * using the algorithm defined in RFC 1779. Only standard attribute type * keywords defined in RFC 1779 are emitted. */ public String getRFC1779Name() { return getRFC1779Name(Collections.emptyMap()); } /** * Returns a string form of the X.500 distinguished name * using the algorithm defined in RFC 1779. Attribute type * keywords defined in RFC 1779 are emitted, as well as additional * keywords contained in the OID/keyword map. */ public String getRFC1779Name(Map oidMap) throws IllegalArgumentException { if (oidMap.isEmpty()) { // return cached result if (rfc1779Dn != null) { return rfc1779Dn; } else { rfc1779Dn = generateRFC1779DN(oidMap); return rfc1779Dn; } } return generateRFC1779DN(oidMap); } /** * Returns a string form of the X.500 distinguished name * using the algorithm defined in RFC 2253. Only standard attribute type * keywords defined in RFC 2253 are emitted. */ public String getRFC2253Name() { return getRFC2253Name(Collections.emptyMap()); } /** * Returns a string form of the X.500 distinguished name * using the algorithm defined in RFC 2253. Attribute type * keywords defined in RFC 2253 are emitted, as well as additional * keywords contained in the OID/keyword map. */ public String getRFC2253Name(Map oidMap) { /* check for and return cached name */ if (oidMap.isEmpty()) { if (rfc2253Dn != null) { return rfc2253Dn; } else { rfc2253Dn = generateRFC2253DN(oidMap); return rfc2253Dn; } } return generateRFC2253DN(oidMap); } private String generateRFC2253DN(Map oidMap) { /* * Section 2.1 : if the RDNSequence is an empty sequence * the result is the empty or zero length string. */ if (names.length == 0) { return ""; } /* * 2.1 (continued) : Otherwise, the output consists of the string * encodings of each RelativeDistinguishedName in the RDNSequence * (according to 2.2), starting with the last element of the sequence * and moving backwards toward the first. * * The encodings of adjoining RelativeDistinguishedNames are separated * by a comma character (',' ASCII 44). */ StringJoiner sj = new StringJoiner(","); for (int i = names.length - 1; i >= 0; i--) { sj.add(names[i].toRFC2253String(oidMap)); } return sj.toString(); } public String getRFC2253CanonicalName() { /* check for and return cached name */ if (canonicalDn != null) { return canonicalDn; } /* * Section 2.1 : if the RDNSequence is an empty sequence * the result is the empty or zero length string. */ if (names.length == 0) { canonicalDn = ""; return canonicalDn; } /* * 2.1 (continued) : Otherwise, the output consists of the string * encodings of each RelativeDistinguishedName in the RDNSequence * (according to 2.2), starting with the last element of the sequence * and moving backwards toward the first. * * The encodings of adjoining RelativeDistinguishedNames are separated * by a comma character (',' ASCII 44). */ StringJoiner sj = new StringJoiner(","); for (int i = names.length - 1; i >= 0; i--) { sj.add(names[i].toRFC2253String(true)); } canonicalDn = sj.toString(); return canonicalDn; } /** * Returns the value of toString(). This call is needed to * implement the java.security.Principal interface. */ public String getName() { return toString(); } /** * Find the first instance of this attribute in a "top down" * search of all the attributes in the name. */ private DerValue findAttribute(ObjectIdentifier attribute) { if (names != null) { for (int i = 0; i < names.length; i++) { DerValue value = names[i].findAttribute(attribute); if (value != null) { return value; } } } return null; } /** * Find the most specific ("last") attribute of the given * type. */ public DerValue findMostSpecificAttribute(ObjectIdentifier attribute) { if (names != null) { for (int i = names.length - 1; i >= 0; i--) { DerValue value = names[i].findAttribute(attribute); if (value != null) { return value; } } } return null; } /****************************************************************/ private void parseDER(DerInputStream in) throws IOException { // // X.500 names are a "SEQUENCE OF" RDNs, which means zero or // more and order matters. We scan them in order, which // conventionally is big-endian. // DerValue[] nameseq = null; byte[] derBytes = in.toByteArray(); try { nameseq = in.getSequence(5); } catch (IOException ioe) { if (derBytes == null) { nameseq = null; } else { DerValue derVal = new DerValue(DerValue.tag_Sequence, derBytes); derBytes = derVal.toByteArray(); nameseq = new DerInputStream(derBytes).getSequence(5); } } if (nameseq == null) { names = new RDN[0]; } else { names = new RDN[nameseq.length]; for (int i = 0; i < nameseq.length; i++) { names[i] = new RDN(nameseq[i]); } } } /** * Encodes the name in DER-encoded form. * * @deprecated Use encode() instead * @param out where to put the DER-encoded X.500 name */ @Deprecated public void emit(DerOutputStream out) throws IOException { encode(out); } /** * Encodes the name in DER-encoded form. * * @param out where to put the DER-encoded X.500 name */ public void encode(DerOutputStream out) throws IOException { DerOutputStream tmp = new DerOutputStream(); for (int i = 0; i < names.length; i++) { names[i].encode(tmp); } out.write(DerValue.tag_Sequence, tmp); } /** * Returned the encoding as an uncloned byte array. Callers must * guarantee that they neither modify it not expose it to untrusted * code. */ public byte[] getEncodedInternal() throws IOException { if (encoded == null) { DerOutputStream out = new DerOutputStream(); DerOutputStream tmp = new DerOutputStream(); for (int i = 0; i < names.length; i++) { names[i].encode(tmp); } out.write(DerValue.tag_Sequence, tmp); encoded = out.toByteArray(); } return encoded; } /** * Gets the name in DER-encoded form. * * @return the DER encoded byte array of this name. */ public byte[] getEncoded() throws IOException { return getEncodedInternal().clone(); } /* * Parses a Distinguished Name (DN) in printable representation. * * According to RFC 1779, RDNs in a DN are separated by comma. * The following examples show both methods of quoting a comma, so that it * is not considered a separator: * * O="Sue, Grabbit and Runn" or * O=Sue\, Grabbit and Runn * * This method can parse RFC 1779, 2253 or 4514 DNs and non-standard 5280 * keywords. Additional keywords can be specified in the keyword/OID map. */ private void parseDN(String input, Map keywordMap) throws IOException { if (input == null || input.isEmpty()) { names = new RDN[0]; return; } List dnVector = new ArrayList<>(); int dnOffset = 0; int rdnEnd; String rdnString; int quoteCount = 0; String dnString = input; int searchOffset = 0; int nextComma = dnString.indexOf(','); int nextSemiColon = dnString.indexOf(';'); while (nextComma >=0 || nextSemiColon >=0) { if (nextSemiColon < 0) { rdnEnd = nextComma; } else if (nextComma < 0) { rdnEnd = nextSemiColon; } else { rdnEnd = Math.min(nextComma, nextSemiColon); } quoteCount += countQuotes(dnString, searchOffset, rdnEnd); /* * We have encountered an RDN delimiter (comma or a semicolon). * If the comma or semicolon in the RDN under consideration is * preceded by a backslash (escape), or by a double quote, it * is part of the RDN. Otherwise, it is used as a separator, to * delimit the RDN under consideration from any subsequent RDNs. */ if (rdnEnd >= 0 && quoteCount != 1 && !escaped(rdnEnd, searchOffset, dnString)) { /* * Comma/semicolon is a separator */ rdnString = dnString.substring(dnOffset, rdnEnd); // Parse RDN, and store it in vector RDN rdn = new RDN(rdnString, keywordMap); dnVector.add(rdn); // Increase the offset dnOffset = rdnEnd + 1; // Set quote counter back to zero quoteCount = 0; } searchOffset = rdnEnd + 1; nextComma = dnString.indexOf(',', searchOffset); nextSemiColon = dnString.indexOf(';', searchOffset); } // Parse last or only RDN, and store it in vector rdnString = dnString.substring(dnOffset); RDN rdn = new RDN(rdnString, keywordMap); dnVector.add(rdn); /* * Store the vector elements as an array of RDNs * NOTE: It's only on output that little-endian ordering is used. */ Collections.reverse(dnVector); names = dnVector.toArray(new RDN[dnVector.size()]); } private void parseRFC2253DN(String dnString) throws IOException { if (dnString.isEmpty()) { names = new RDN[0]; return; } List dnVector = new ArrayList<>(); int dnOffset = 0; String rdnString; int searchOffset = 0; int rdnEnd = dnString.indexOf(','); while (rdnEnd >=0) { /* * We have encountered an RDN delimiter (comma). * If the comma in the RDN under consideration is * preceded by a backslash (escape), it * is part of the RDN. Otherwise, it is used as a separator, to * delimit the RDN under consideration from any subsequent RDNs. */ if (rdnEnd > 0 && !escaped(rdnEnd, searchOffset, dnString)) { /* * Comma is a separator */ rdnString = dnString.substring(dnOffset, rdnEnd); // Parse RDN, and store it in vector RDN rdn = new RDN(rdnString, "RFC2253"); dnVector.add(rdn); // Increase the offset dnOffset = rdnEnd + 1; } searchOffset = rdnEnd + 1; rdnEnd = dnString.indexOf(',', searchOffset); } // Parse last or only RDN, and store it in vector rdnString = dnString.substring(dnOffset); RDN rdn = new RDN(rdnString, "RFC2253"); dnVector.add(rdn); /* * Store the vector elements as an array of RDNs * NOTE: It's only on output that little-endian ordering is used. */ Collections.reverse(dnVector); names = dnVector.toArray(new RDN[dnVector.size()]); } /* * Counts double quotes in string. * Escaped quotes are ignored. */ static int countQuotes(String string, int from, int to) { int count = 0; for (int i = from; i < to; i++) { if ((string.charAt(i) == '"' && i == from) || (string.charAt(i) == '"' && string.charAt(i-1) != '\\')) { count++; } } return count; } private static boolean escaped (int rdnEnd, int searchOffset, String dnString) { if (rdnEnd == 1 && dnString.charAt(rdnEnd - 1) == '\\') { // case 1: // \, return true; } else if (rdnEnd > 1 && dnString.charAt(rdnEnd - 1) == '\\' && dnString.charAt(rdnEnd - 2) != '\\') { // case 2: // foo\, return true; } else if (rdnEnd > 1 && dnString.charAt(rdnEnd - 1) == '\\' && dnString.charAt(rdnEnd - 2) == '\\') { // case 3: // foo\\\\\, int count = 0; rdnEnd--; // back up to last backSlash while (rdnEnd >= searchOffset) { if (dnString.charAt(rdnEnd) == '\\') { count++; // count consecutive backslashes } rdnEnd--; } // if count is odd, then rdnEnd is escaped return (count % 2) != 0 ? true : false; } else { return false; } } /* * Dump the printable form of a distinguished name. Each relative * name is separated from the next by a ",", and assertions in the * relative names have "label=value" syntax. * * Uses RFC 1779 syntax (i.e. little-endian, comma separators) */ private void generateDN() { if (names.length == 1) { dn = names[0].toString(); return; } if (names == null) { dn = ""; return; } StringJoiner sj = new StringJoiner(", "); for (int i = names.length - 1; i >= 0; i--) { sj.add(names[i].toString()); } dn = sj.toString(); } /* * Dump the printable form of a distinguished name. Each relative * name is separated from the next by a ",", and assertions in the * relative names have "label=value" syntax. * * Uses RFC 1779 syntax (i.e. little-endian, comma separators) * Valid keywords from RFC 1779 are used. Additional keywords can be * specified in the OID/keyword map. */ private String generateRFC1779DN(Map oidMap) { if (names.length == 1) { return names[0].toRFC1779String(oidMap); } if (names == null) { return ""; } StringJoiner sj = new StringJoiner(", "); for (int i = names.length - 1; i >= 0; i--) { sj.add(names[i].toRFC1779String(oidMap)); } return sj.toString(); } /****************************************************************/ /* * Selected OIDs from X.520 * Includes all those specified in RFC 5280 as MUST or SHOULD * be recognized */ // OID for the "CN=" attribute, denoting a person's common name. public static final ObjectIdentifier commonName_oid = Oid.of(KnownOIDs.CommonName); // OID for the "SURNAME=" attribute, denoting a person's surname. public static final ObjectIdentifier SURNAME_OID = Oid.of(KnownOIDs.Surname); // OID for the "SERIALNUMBER=" attribute, denoting a serial number for. // a name. Do not confuse with PKCS#9 issuerAndSerialNumber or the // certificate serial number. public static final ObjectIdentifier SERIALNUMBER_OID = Oid.of(KnownOIDs.SerialNumber); // OID for the "C=" attribute, denoting a country. public static final ObjectIdentifier countryName_oid = Oid.of(KnownOIDs.CountryName); // OID for the "L=" attribute, denoting a locality (such as a city). public static final ObjectIdentifier localityName_oid = Oid.of(KnownOIDs.LocalityName); // OID for the "S=" attribute, denoting a state (such as Delaware). public static final ObjectIdentifier stateName_oid = Oid.of(KnownOIDs.StateName); // OID for the "STREET=" attribute, denoting a street address. public static final ObjectIdentifier streetAddress_oid = Oid.of(KnownOIDs.StreetAddress); // OID for the "O=" attribute, denoting an organization name. public static final ObjectIdentifier orgName_oid = Oid.of(KnownOIDs.OrgName); // OID for the "OU=" attribute, denoting an organizational unit name. public static final ObjectIdentifier orgUnitName_oid = Oid.of(KnownOIDs.OrgUnitName); // OID for the "T=" attribute, denoting a person's title. public static final ObjectIdentifier title_oid = Oid.of(KnownOIDs.Title); // OID for the "GIVENNAME=" attribute, denoting a person's given name. public static final ObjectIdentifier GIVENNAME_OID = Oid.of(KnownOIDs.GivenName); // OID for the "INITIALS=" attribute, denoting a person's initials. public static final ObjectIdentifier INITIALS_OID = Oid.of(KnownOIDs.Initials); // OID for the "GENERATION=" attribute, denoting Jr., II, etc. public static final ObjectIdentifier GENERATIONQUALIFIER_OID = Oid.of(KnownOIDs.GenerationQualifier); // OID for the "DNQUALIFIER=" or "DNQ=" attribute, denoting DN // disambiguating information. public static final ObjectIdentifier DNQUALIFIER_OID = Oid.of(KnownOIDs.DNQualifier); // OIDs from other sources which show up in X.500 names we // expect to deal with often. // // OID for "IP=" IP address attributes, used with SKIP. public static final ObjectIdentifier ipAddress_oid = Oid.of(KnownOIDs.SkipIPAddress); // Domain component OID from RFC 1274, RFC 2247, RFC 5280. // // OID for "DC=" domain component attributes.used with DNSNames in DN // format. public static final ObjectIdentifier DOMAIN_COMPONENT_OID = Oid.of(KnownOIDs.UCL_DomainComponent); // OID for "UID=" denoting a user id, defined in RFCs 1274 & 2798. public static final ObjectIdentifier userid_oid = Oid.of(KnownOIDs.UCL_UserID); /** * Return constraint type:

    *
  • NAME_DIFF_TYPE = -1: input name is different type from this name * (i.e. does not constrain) *
  • NAME_MATCH = 0: input name matches this name *
  • NAME_NARROWS = 1: input name narrows this name *
  • NAME_WIDENS = 2: input name widens this name *
  • NAME_SAME_TYPE = 3: input name does not match or narrow this name, * but is same type. *
* These results are used in checking NameConstraints during * certification path verification. * * @param inputName to be checked for being constrained * @return constraint type above * @throws UnsupportedOperationException if name is not exact match, but * narrowing and widening are not supported for this name type. */ public int constrains(GeneralNameInterface inputName) throws UnsupportedOperationException { int constraintType; if (inputName == null) { constraintType = NAME_DIFF_TYPE; } else if (inputName.getType() != NAME_DIRECTORY) { constraintType = NAME_DIFF_TYPE; } else { // type == NAME_DIRECTORY X500Name inputX500 = (X500Name)inputName; if (inputX500.equals(this)) { constraintType = NAME_MATCH; } else if (inputX500.names.length == 0) { constraintType = NAME_WIDENS; } else if (this.names.length == 0) { constraintType = NAME_NARROWS; } else if (inputX500.isWithinSubtree(this)) { constraintType = NAME_NARROWS; } else if (isWithinSubtree(inputX500)) { constraintType = NAME_WIDENS; } else { constraintType = NAME_SAME_TYPE; } } return constraintType; } /** * Compares this name with another and determines if * it is within the subtree of the other. Useful for * checking against the name constraints extension. * * @return true iff this name is within the subtree of other. */ private boolean isWithinSubtree(X500Name other) { if (this == other) { return true; } if (other == null) { return false; } if (other.names.length == 0) { return true; } if (this.names.length == 0) { return false; } if (names.length < other.names.length) { return false; } for (int i = 0; i < other.names.length; i++) { if (!names[i].equals(other.names[i])) { return false; } } return true; } /** * Return subtree depth of this name for purposes of determining * NameConstraints minimum and maximum bounds and for calculating * path lengths in name subtrees. * * @return distance of name from root * @throws UnsupportedOperationException if not supported for this name type */ public int subtreeDepth() throws UnsupportedOperationException { return names.length; } /** * Return lowest common ancestor of this name and other name * * @param other another X500Name * @return X500Name of lowest common ancestor; null if none */ public X500Name commonAncestor(X500Name other) { if (other == null) { return null; } int otherLen = other.names.length; int thisLen = this.names.length; if (thisLen == 0 || otherLen == 0) { return null; } int minLen = (thisLen < otherLen) ? thisLen: otherLen; //Compare names from highest RDN down the naming tree //Note that these are stored in RDN[0]... int i=0; for (; i < minLen; i++) { if (!names[i].equals(other.names[i])) { if (i == 0) { return null; } else { break; } } } //Copy matching RDNs into new RDN array RDN[] ancestor = new RDN[i]; for (int j=0; j < i; j++) { ancestor[j] = names[j]; } X500Name commonAncestor = null; try { commonAncestor = new X500Name(ancestor); } catch (IOException ioe) { return null; } return commonAncestor; } // /** // * Constructor object for use by asX500Principal(). // */ // private static final Constructor principalConstructor; // // /** // * Field object for use by asX500Name(). // */ // private static final Field principalField; // // /** // * Retrieve the Constructor and Field we need for reflective access // * and make them accessible. // */ // static { // PrivilegedExceptionAction pa = // new PrivilegedExceptionAction() { // public Object[] run() throws Exception { // Class pClass = X500Principal.class; // Class[] args = new Class[] { sun.security.x509.X500Name.class }; // Constructor cons = pClass.getDeclaredConstructor(args); // cons.setAccessible(true); // Field field = pClass.getDeclaredField("thisX500Name"); // field.setAccessible(true); // return new Object[] {cons, field}; // } // }; // try { // @SuppressWarnings("removal") // Object[] result = AccessController.doPrivileged(pa); // @SuppressWarnings("unchecked") // Constructor constr = // (Constructor)result[0]; // principalConstructor = constr; // principalField = (Field)result[1]; // } catch (Exception e) { // throw new InternalError("Could not obtain X500Principal access", e); // } // } /** * Get an X500Principal backed by this X500Name. * * Note that we are using privileged reflection to access the hidden * package private constructor in X500Principal. */ public X500Principal asX500Principal() { if (x500Principal == null) { try { x500Principal = new X500Principal(getEncoded()); } catch (Exception e) { throw new RuntimeException("Unexpected exception", e); } } return x500Principal; } /** * Get the X500Name contained in the given X500Principal. * * Note that the X500Name is retrieved using reflection. */ public static X500Name asX500Name(X500Principal p) { try { X500Name name = new X500Name(p.getEncoded()); name.x500Principal = p; return name; } catch (Exception e) { throw new RuntimeException("Unexpected exception", e); } } }




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