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Java example source code file (MessageToken_v2.java)
The MessageToken_v2.java Java example source code/* * Copyright (c) 2004, 2011, 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 * or visit www.oracle.com if you need additional information or have any * questions. */ package sun.security.jgss.krb5; import org.ietf.jgss.*; import java.io.InputStream; import java.io.OutputStream; import java.io.IOException; import java.io.ByteArrayInputStream; import java.io.ByteArrayOutputStream; import java.security.MessageDigest; import java.util.Arrays; /** * This class is a base class for new GSS token definitions, as defined * in RFC 4121, that pertain to per-message GSS-API calls. Conceptually * GSS-API has two types of per-message tokens: WrapToken and MicToken. * They differ in the respect that a WrapToken carries additional plaintext * or ciphertext application data besides just the sequence number and * checksum. This class encapsulates the commonality in the structure of * the WrapToken and the MicToken. This structure can be represented as: * <p> * <pre> * Wrap Tokens * * Octet no Name Description * --------------------------------------------------------------- * 0..1 TOK_ID Identification field. Tokens emitted by * GSS_Wrap() contain the hex value 05 04 * expressed in big-endian order in this field. * 2 Flags Attributes field, as described in section * 4.2.2. * 3 Filler Contains the hex value FF. * 4..5 EC Contains the "extra count" field, in big- * endian order as described in section 4.2.3. * 6..7 RRC Contains the "right rotation count" in big * endian order, as described in section 4.2.5. * 8..15 SND_SEQ Sequence number field in clear text, * expressed in big-endian order. * 16..last Data Encrypted data for Wrap tokens with * confidentiality, or plaintext data followed * by the checksum for Wrap tokens without * confidentiality, as described in section * 4.2.4. * MIC Tokens * * Octet no Name Description * ----------------------------------------------------------------- * 0..1 TOK_ID Identification field. Tokens emitted by * GSS_GetMIC() contain the hex value 04 04 * expressed in big-endian order in this field. * 2 Flags Attributes field, as described in section * 4.2.2. * 3..7 Filler Contains five octets of hex value FF. * 8..15 SND_SEQ Sequence number field in clear text, * expressed in big-endian order. * 16..last SGN_CKSUM Checksum of the "to-be-signed" data and * octet 0..15, as described in section 4.2.4. * * </pre> * <p> * This class is the super class of WrapToken_v2 and MicToken_v2. The token's * header (bytes[0..15]) and data (byte[16..]) are saved in tokenHeader and * tokenData fields. Since there is no easy way to find out the exact length * of a WrapToken_v2 token from any header info, in the case of reading from * stream, we read all available() bytes into the token. * <p> * All read actions are performed in this super class. On the write part, the * super class only write the tokenHeader, and the content writing is inside * child classes. * * @author Seema Malkani */ abstract class MessageToken_v2 extends Krb5Token { protected static final int TOKEN_HEADER_SIZE = 16; private static final int TOKEN_ID_POS = 0; private static final int TOKEN_FLAG_POS = 2; private static final int TOKEN_EC_POS = 4; private static final int TOKEN_RRC_POS = 6; /** * The size of the random confounder used in a WrapToken. */ protected static final int CONFOUNDER_SIZE = 16; // RFC 4121, key usage values static final int KG_USAGE_ACCEPTOR_SEAL = 22; static final int KG_USAGE_ACCEPTOR_SIGN = 23; static final int KG_USAGE_INITIATOR_SEAL = 24; static final int KG_USAGE_INITIATOR_SIGN = 25; // RFC 4121, Flags Field private static final int FLAG_SENDER_IS_ACCEPTOR = 1; private static final int FLAG_WRAP_CONFIDENTIAL = 2; private static final int FLAG_ACCEPTOR_SUBKEY = 4; private static final int FILLER = 0xff; private MessageTokenHeader tokenHeader = null; // Common field private int tokenId = 0; private int seqNumber; protected byte[] tokenData; // content of token, without the header protected int tokenDataLen; // Key usage number for crypto action private int key_usage = 0; // EC and RRC fields, WrapToken only private int ec = 0; private int rrc = 0; // Checksum. Always in MicToken, might be in WrapToken byte[] checksum = null; // Context properties private boolean confState = true; private boolean initiator = true; private boolean have_acceptor_subkey = false; /* cipher instance used by the corresponding GSSContext */ CipherHelper cipherHelper = null; /** * Constructs a MessageToken from a byte array. * * @param tokenId the token id that should be contained in this token as * it is read. * @param context the Kerberos context associated with this token * @param tokenBytes the byte array containing the token * @param tokenOffset the offset where the token begins * @param tokenLen the length of the token * @param prop the MessageProp structure in which the properties of the * token should be stored. * @throws GSSException if there is a problem parsing the token */ MessageToken_v2(int tokenId, Krb5Context context, byte[] tokenBytes, int tokenOffset, int tokenLen, MessageProp prop) throws GSSException { this(tokenId, context, new ByteArrayInputStream(tokenBytes, tokenOffset, tokenLen), prop); } /** * Constructs a MessageToken from an InputStream. Bytes will be read on * demand and the thread might block if there are not enough bytes to * complete the token. Please note there is no accurate way to find out * the size of a token, but we try our best to make sure there is * enough bytes to construct one. * * @param tokenId the token id that should be contained in this token as * it is read. * @param context the Kerberos context associated with this token * @param is the InputStream from which to read * @param prop the MessageProp structure in which the properties of the * token should be stored. * @throws GSSException if there is a problem reading from the * InputStream or parsing the token */ MessageToken_v2(int tokenId, Krb5Context context, InputStream is, MessageProp prop) throws GSSException { init(tokenId, context); try { if (!confState) { prop.setPrivacy(false); } tokenHeader = new MessageTokenHeader(is, prop, tokenId); // set key_usage if (tokenId == Krb5Token.WRAP_ID_v2) { key_usage = (!initiator ? KG_USAGE_INITIATOR_SEAL : KG_USAGE_ACCEPTOR_SEAL); } else if (tokenId == Krb5Token.MIC_ID_v2) { key_usage = (!initiator ? KG_USAGE_INITIATOR_SIGN : KG_USAGE_ACCEPTOR_SIGN); } int minSize = 0; // minimal size for token data if (tokenId == Krb5Token.WRAP_ID_v2 && prop.getPrivacy()) { minSize = CONFOUNDER_SIZE + TOKEN_HEADER_SIZE + cipherHelper.getChecksumLength(); } else { minSize = cipherHelper.getChecksumLength(); } // Read token data if (tokenId == Krb5Token.MIC_ID_v2) { // The only case we can precisely predict the token data length tokenDataLen = minSize; tokenData = new byte[minSize]; readFully(is, tokenData); } else { tokenDataLen = is.available(); if (tokenDataLen >= minSize) { // read in one shot tokenData = new byte[tokenDataLen]; readFully(is, tokenData); } else { byte[] tmp = new byte[minSize]; readFully(is, tmp); // Hope while blocked in the read above, more data would // come and is.available() below contains the whole token. int more = is.available(); tokenDataLen = minSize + more; tokenData = Arrays.copyOf(tmp, tokenDataLen); readFully(is, tokenData, minSize, more); } } if (tokenId == Krb5Token.WRAP_ID_v2) { rotate(); } if (tokenId == Krb5Token.MIC_ID_v2 || (tokenId == Krb5Token.WRAP_ID_v2 && !prop.getPrivacy())) { // Read checksum int chkLen = cipherHelper.getChecksumLength(); checksum = new byte[chkLen]; System.arraycopy(tokenData, tokenDataLen-chkLen, checksum, 0, chkLen); // validate EC for Wrap tokens without confidentiality if (tokenId == Krb5Token.WRAP_ID_v2 && !prop.getPrivacy()) { if (chkLen != ec) { throw new GSSException(GSSException.DEFECTIVE_TOKEN, -1, getTokenName(tokenId) + ":" + "EC incorrect!"); } } } } catch (IOException e) { throw new GSSException(GSSException.DEFECTIVE_TOKEN, -1, getTokenName(tokenId) + ":" + e.getMessage()); } } /** * Used to obtain the token id that was contained in this token. * @return the token id in the token */ public final int getTokenId() { return tokenId; } /** * Used to obtain the key_usage type for this token. * @return the key_usage for the token */ public final int getKeyUsage() { return key_usage; } /** * Used to determine if this token contains any encrypted data. * @return true if it contains any encrypted data, false if there is only * plaintext data or if there is no data. */ public final boolean getConfState() { return confState; } /** * Generates the checksum field and the sequence number field. * * @param prop the MessageProp structure * @param data the application data to checksum * @param offset the offset where the data starts * @param len the length of the data * * @throws GSSException if an error occurs in the checksum calculation or * sequence number calculation. */ public void genSignAndSeqNumber(MessageProp prop, byte[] data, int offset, int len) throws GSSException { // debug("Inside MessageToken.genSignAndSeqNumber:\n"); int qop = prop.getQOP(); if (qop != 0) { qop = 0; prop.setQOP(qop); } if (!confState) { prop.setPrivacy(false); } // Create a new gss token header as defined in RFC 4121 tokenHeader = new MessageTokenHeader(tokenId, prop.getPrivacy()); // debug("\n\t Message Header = " + // getHexBytes(tokenHeader.getBytes(), tokenHeader.getBytes().length)); // set key_usage if (tokenId == Krb5Token.WRAP_ID_v2) { key_usage = (initiator ? KG_USAGE_INITIATOR_SEAL : KG_USAGE_ACCEPTOR_SEAL); } else if (tokenId == Krb5Token.MIC_ID_v2) { key_usage = (initiator ? KG_USAGE_INITIATOR_SIGN : KG_USAGE_ACCEPTOR_SIGN); } // Calculate SGN_CKSUM if ((tokenId == MIC_ID_v2) || (!prop.getPrivacy() && (tokenId == WRAP_ID_v2))) { checksum = getChecksum(data, offset, len); // debug("\n\tCalc checksum=" + // getHexBytes(checksum, checksum.length)); } // In Wrap tokens without confidentiality, the EC field SHALL be used // to encode the number of octets in the trailing checksum if (!prop.getPrivacy() && (tokenId == WRAP_ID_v2)) { byte[] tok_header = tokenHeader.getBytes(); tok_header[4] = (byte) (checksum.length >>> 8); tok_header[5] = (byte) (checksum.length); } } /** * Verifies the validity of checksum field * * @param data the application data * @param offset the offset where the data begins * @param len the length of the application data * * @throws GSSException if an error occurs in the checksum calculation */ public final boolean verifySign(byte[] data, int offset, int len) throws GSSException { // debug("\t====In verifySign:====\n"); // debug("\t\t checksum: [" + getHexBytes(checksum) + "]\n"); // debug("\t\t data = [" + getHexBytes(data) + "]\n"); byte[] myChecksum = getChecksum(data, offset, len); // debug("\t\t mychecksum: [" + getHexBytes(myChecksum) +"]\n"); if (MessageDigest.isEqual(checksum, myChecksum)) { // debug("\t\t====Checksum PASS:====\n"); return true; } return false; } /** * Rotate bytes as per the "RRC" (Right Rotation Count) received. * Our implementation does not do any rotates when sending, only * when receiving, we rotate left as per the RRC count, to revert it. */ private void rotate() { if (rrc % tokenDataLen != 0) { rrc = rrc % tokenDataLen; byte[] newBytes = new byte[tokenDataLen]; System.arraycopy(tokenData, rrc, newBytes, 0, tokenDataLen-rrc); System.arraycopy(tokenData, 0, newBytes, tokenDataLen-rrc, rrc); tokenData = newBytes; } } public final int getSequenceNumber() { return seqNumber; } /** * Computes the checksum based on the algorithm stored in the * tokenHeader. * * @param data the application data * @param offset the offset where the data begins * @param len the length of the application data * * @throws GSSException if an error occurs in the checksum calculation. */ byte[] getChecksum(byte[] data, int offset, int len) throws GSSException { // debug("Will do getChecksum:\n"); /* * For checksum calculation the token header bytes i.e., the first 16 * bytes following the GSSHeader, are logically prepended to the * application data to bind the data to this particular token. * * Note: There is no such requirement wrt adding padding to the * application data for checksumming, although the cryptographic * algorithm used might itself apply some padding. */ byte[] tokenHeaderBytes = tokenHeader.getBytes(); // check confidentiality int conf_flag = tokenHeaderBytes[TOKEN_FLAG_POS] & FLAG_WRAP_CONFIDENTIAL; // clear EC and RRC in token header for checksum calculation if ((conf_flag == 0) && (tokenId == WRAP_ID_v2)) { tokenHeaderBytes[4] = 0; tokenHeaderBytes[5] = 0; tokenHeaderBytes[6] = 0; tokenHeaderBytes[7] = 0; } return cipherHelper.calculateChecksum(tokenHeaderBytes, data, offset, len, key_usage); } /** * Constructs an empty MessageToken for the local context to send to * the peer. It also increments the local sequence number in the * Krb5Context instance it uses after obtaining the object lock for * it. * * @param tokenId the token id that should be contained in this token * @param context the Kerberos context associated with this token */ MessageToken_v2(int tokenId, Krb5Context context) throws GSSException { /* debug("\n============================"); debug("\nMySessionKey=" + getHexBytes(context.getMySessionKey().getBytes())); debug("\nPeerSessionKey=" + getHexBytes(context.getPeerSessionKey().getBytes())); debug("\n============================\n"); */ init(tokenId, context); this.seqNumber = context.incrementMySequenceNumber(); } private void init(int tokenId, Krb5Context context) throws GSSException { this.tokenId = tokenId; // Just for consistency check in Wrap this.confState = context.getConfState(); this.initiator = context.isInitiator(); this.have_acceptor_subkey = context.getKeySrc() == Krb5Context.ACCEPTOR_SUBKEY; this.cipherHelper = context.getCipherHelper(null); // debug("In MessageToken.Cons"); } /** * Encodes a MessageTokenHeader onto an OutputStream. * * @param os the OutputStream to which this should be written * @throws IOException is an error occurs while writing to the OutputStream */ protected void encodeHeader(OutputStream os) throws IOException { tokenHeader.encode(os); } /** * Encodes a MessageToken_v2 onto an OutputStream. * * @param os the OutputStream to which this should be written * @throws IOException is an error occurs while encoding the token */ public abstract void encode(OutputStream os) throws IOException; protected final byte[] getTokenHeader() { return (tokenHeader.getBytes()); } // ******************************************* // // I N N E R C L A S S E S F O L L O W // ******************************************* // /** * This inner class represents the initial portion of the message token. * It constitutes the first 16 bytes of the message token. */ class MessageTokenHeader { private int tokenId; private byte[] bytes = new byte[TOKEN_HEADER_SIZE]; // Writes a new token header public MessageTokenHeader(int tokenId, boolean conf) throws GSSException { this.tokenId = tokenId; bytes[0] = (byte) (tokenId >>> 8); bytes[1] = (byte) (tokenId); // Flags (Note: MIT impl requires subkey) int flags = 0; flags = (initiator ? 0 : FLAG_SENDER_IS_ACCEPTOR) | ((conf && tokenId != MIC_ID_v2) ? FLAG_WRAP_CONFIDENTIAL : 0) | (have_acceptor_subkey ? FLAG_ACCEPTOR_SUBKEY : 0); bytes[2] = (byte) flags; // filler bytes[3] = (byte) FILLER; if (tokenId == WRAP_ID_v2) { // EC field bytes[4] = (byte) 0; bytes[5] = (byte) 0; // RRC field bytes[6] = (byte) 0; bytes[7] = (byte) 0; } else if (tokenId == MIC_ID_v2) { // more filler for MicToken for (int i = 4; i < 8; i++) { bytes[i] = (byte) FILLER; } } // Calculate SND_SEQ, only write 4 bytes from the 12th position writeBigEndian(seqNumber, bytes, 12); } /** * Reads a MessageTokenHeader from an InputStream and sets the * appropriate confidentiality and quality of protection * values in a MessageProp structure. * * @param is the InputStream to read from * @param prop the MessageProp to populate * @throws IOException is an error occurs while reading from the * InputStream */ public MessageTokenHeader(InputStream is, MessageProp prop, int tokId) throws IOException, GSSException { readFully(is, bytes, 0, TOKEN_HEADER_SIZE); tokenId = readInt(bytes, TOKEN_ID_POS); // validate Token ID if (tokenId != tokId) { throw new GSSException(GSSException.DEFECTIVE_TOKEN, -1, getTokenName(tokenId) + ":" + "Defective Token ID!"); } /* * Validate new GSS TokenHeader */ // valid acceptor_flag // If I am initiator, the received token should have ACCEPTOR on int acceptor_flag = (initiator ? FLAG_SENDER_IS_ACCEPTOR : 0); int flag = bytes[TOKEN_FLAG_POS] & FLAG_SENDER_IS_ACCEPTOR; if (flag != acceptor_flag) { throw new GSSException(GSSException.DEFECTIVE_TOKEN, -1, getTokenName(tokenId) + ":" + "Acceptor Flag Error!"); } // check for confidentiality int conf_flag = bytes[TOKEN_FLAG_POS] & FLAG_WRAP_CONFIDENTIAL; if ((conf_flag == FLAG_WRAP_CONFIDENTIAL) && (tokenId == WRAP_ID_v2)) { prop.setPrivacy(true); } else { prop.setPrivacy(false); } if (tokenId == WRAP_ID_v2) { // validate filler if ((bytes[3] & 0xff) != FILLER) { throw new GSSException(GSSException.DEFECTIVE_TOKEN, -1, getTokenName(tokenId) + ":" + "Defective Token Filler!"); } // read EC field ec = readBigEndian(bytes, TOKEN_EC_POS, 2); // read RRC field rrc = readBigEndian(bytes, TOKEN_RRC_POS, 2); } else if (tokenId == MIC_ID_v2) { for (int i = 3; i < 8; i++) { if ((bytes[i] & 0xff) != FILLER) { throw new GSSException(GSSException.DEFECTIVE_TOKEN, -1, getTokenName(tokenId) + ":" + "Defective Token Filler!"); } } } // set default QOP prop.setQOP(0); // sequence number seqNumber = readBigEndian(bytes, 0, 8); } /** * Encodes this MessageTokenHeader onto an OutputStream * @param os the OutputStream to write to * @throws IOException is an error occurs while writing */ public final void encode(OutputStream os) throws IOException { os.write(bytes); } /** * Returns the token id for the message token. * @return the token id * @see sun.security.jgss.krb5.Krb5Token#MIC_ID_v2 * @see sun.security.jgss.krb5.Krb5Token#WRAP_ID_v2 */ public final int getTokenId() { return tokenId; } /** * Returns the bytes of this header. * @return 8 bytes that form this header */ public final byte[] getBytes() { return bytes; } } // end of class MessageTokenHeader } Other Java examples (source code examples)Here is a short list of links related to this Java MessageToken_v2.java source code file: |
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