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The Bouncy Castle Crypto package is a Java implementation of cryptographic algorithms. This jar contains JCE provider and lightweight API for the Bouncy Castle Cryptography APIs for JDK 1.5 to JDK 1.8.

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package org.bouncycastle.crypto.agreement.jpake;

import java.math.BigInteger;
import java.security.SecureRandom;

import org.bouncycastle.crypto.CryptoException;
import org.bouncycastle.crypto.CryptoServicesRegistrar;
import org.bouncycastle.crypto.Digest;
import org.bouncycastle.crypto.digests.SHA256Digest;
import org.bouncycastle.util.Arrays;
import org.bouncycastle.util.Exceptions;

/**
 * A participant in a Password Authenticated Key Exchange by Juggling (J-PAKE) exchange.
 * 

* The J-PAKE exchange is defined by Feng Hao and Peter Ryan in the paper * * "Password Authenticated Key Exchange by Juggling, 2008." *

* The J-PAKE protocol is symmetric. * There is no notion of a client or server, but rather just two participants. * An instance of {@link JPAKEParticipant} represents one participant, and * is the primary interface for executing the exchange. *

* To execute an exchange, construct a {@link JPAKEParticipant} on each end, * and call the following 7 methods * (once and only once, in the given order, for each participant, sending messages between them as described): *

    *
  1. {@link #createRound1PayloadToSend()} - and send the payload to the other participant
  2. *
  3. {@link #validateRound1PayloadReceived(JPAKERound1Payload)} - use the payload received from the other participant
  4. *
  5. {@link #createRound2PayloadToSend()} - and send the payload to the other participant
  6. *
  7. {@link #validateRound2PayloadReceived(JPAKERound2Payload)} - use the payload received from the other participant
  8. *
  9. {@link #calculateKeyingMaterial()}
  10. *
  11. {@link #createRound3PayloadToSend(BigInteger)} - and send the payload to the other participant
  12. *
  13. {@link #validateRound3PayloadReceived(JPAKERound3Payload, BigInteger)} - use the payload received from the other participant
  14. *
*

* Each side should derive a session key from the keying material returned by {@link #calculateKeyingMaterial()}. * The caller is responsible for deriving the session key using a secure key derivation function (KDF). *

* Round 3 is an optional key confirmation process. * If you do not execute round 3, then there is no assurance that both participants are using the same key. * (i.e. if the participants used different passwords, then their session keys will differ.) *

* If the round 3 validation succeeds, then the keys are guaranteed to be the same on both sides. *

* The symmetric design can easily support the asymmetric cases when one party initiates the communication. * e.g. Sometimes the round1 payload and round2 payload may be sent in one pass. * Also, in some cases, the key confirmation payload can be sent together with the round2 payload. * These are the trivial techniques to optimize the communication. *

* The key confirmation process is implemented as specified in * NIST SP 800-56A Revision 1, * Section 8.2 Unilateral Key Confirmation for Key Agreement Schemes. *

* This class is stateful and NOT threadsafe. * Each instance should only be used for ONE complete J-PAKE exchange * (i.e. a new {@link JPAKEParticipant} should be constructed for each new J-PAKE exchange). *

*/ public class JPAKEParticipant { /* * Possible internal states. Used for state checking. */ public static final int STATE_INITIALIZED = 0; public static final int STATE_ROUND_1_CREATED = 10; public static final int STATE_ROUND_1_VALIDATED = 20; public static final int STATE_ROUND_2_CREATED = 30; public static final int STATE_ROUND_2_VALIDATED = 40; public static final int STATE_KEY_CALCULATED = 50; public static final int STATE_ROUND_3_CREATED = 60; public static final int STATE_ROUND_3_VALIDATED = 70; /** * Unique identifier of this participant. * The two participants in the exchange must NOT share the same id. */ private final String participantId; /** * Shared secret. This only contains the secret between construction * and the call to {@link #calculateKeyingMaterial()}. *

* i.e. When {@link #calculateKeyingMaterial()} is called, this buffer overwritten with 0's, * and the field is set to null. *

*/ private char[] password; /** * Digest to use during calculations. */ private final Digest digest; /** * Source of secure random data. */ private final SecureRandom random; private final BigInteger p; private final BigInteger q; private final BigInteger g; /** * The participantId of the other participant in this exchange. */ private String partnerParticipantId; /** * Alice's x1 or Bob's x3. */ private BigInteger x1; /** * Alice's x2 or Bob's x4. */ private BigInteger x2; /** * Alice's g^x1 or Bob's g^x3. */ private BigInteger gx1; /** * Alice's g^x2 or Bob's g^x4. */ private BigInteger gx2; /** * Alice's g^x3 or Bob's g^x1. */ private BigInteger gx3; /** * Alice's g^x4 or Bob's g^x2. */ private BigInteger gx4; /** * Alice's B or Bob's A. */ private BigInteger b; /** * The current state. * See the STATE_* constants for possible values. */ private int state; /** * Convenience constructor for a new {@link JPAKEParticipant} that uses * the {@link JPAKEPrimeOrderGroups#NIST_3072} prime order group, * a SHA-256 digest, and a default {@link SecureRandom} implementation. *

* After construction, the {@link #getState() state} will be {@link #STATE_INITIALIZED}. * * @param participantId unique identifier of this participant. * The two participants in the exchange must NOT share the same id. * @param password shared secret. * A defensive copy of this array is made (and cleared once {@link #calculateKeyingMaterial()} is called). * Caller should clear the input password as soon as possible. * @throws NullPointerException if any argument is null * @throws IllegalArgumentException if password is empty */ public JPAKEParticipant( String participantId, char[] password) { this( participantId, password, JPAKEPrimeOrderGroups.NIST_3072); } /** * Convenience constructor for a new {@link JPAKEParticipant} that uses * a SHA-256 digest and a default {@link SecureRandom} implementation. *

* After construction, the {@link #getState() state} will be {@link #STATE_INITIALIZED}. * * @param participantId unique identifier of this participant. * The two participants in the exchange must NOT share the same id. * @param password shared secret. * A defensive copy of this array is made (and cleared once {@link #calculateKeyingMaterial()} is called). * Caller should clear the input password as soon as possible. * @param group prime order group. * See {@link JPAKEPrimeOrderGroups} for standard groups * @throws NullPointerException if any argument is null * @throws IllegalArgumentException if password is empty */ public JPAKEParticipant( String participantId, char[] password, JPAKEPrimeOrderGroup group) { this( participantId, password, group, SHA256Digest.newInstance(), CryptoServicesRegistrar.getSecureRandom()); } /** * Construct a new {@link JPAKEParticipant}. *

* After construction, the {@link #getState() state} will be {@link #STATE_INITIALIZED}. * * @param participantId unique identifier of this participant. * The two participants in the exchange must NOT share the same id. * @param password shared secret. * A defensive copy of this array is made (and cleared once {@link #calculateKeyingMaterial()} is called). * Caller should clear the input password as soon as possible. * @param group prime order group. * See {@link JPAKEPrimeOrderGroups} for standard groups * @param digest digest to use during zero knowledge proofs and key confirmation (SHA-256 or stronger preferred) * @param random source of secure random data for x1 and x2, and for the zero knowledge proofs * @throws NullPointerException if any argument is null * @throws IllegalArgumentException if password is empty */ public JPAKEParticipant( String participantId, char[] password, JPAKEPrimeOrderGroup group, Digest digest, SecureRandom random) { JPAKEUtil.validateNotNull(participantId, "participantId"); JPAKEUtil.validateNotNull(password, "password"); JPAKEUtil.validateNotNull(group, "p"); JPAKEUtil.validateNotNull(digest, "digest"); JPAKEUtil.validateNotNull(random, "random"); if (password.length == 0) { throw new IllegalArgumentException("Password must not be empty."); } this.participantId = participantId; /* * Create a defensive copy so as to fully encapsulate the password. * * This array will contain the password for the lifetime of this * participant BEFORE {@link #calculateKeyingMaterial()} is called. * * i.e. When {@link #calculateKeyingMaterial()} is called, the array will be cleared * in order to remove the password from memory. * * The caller is responsible for clearing the original password array * given as input to this constructor. */ this.password = Arrays.copyOf(password, password.length); this.p = group.getP(); this.q = group.getQ(); this.g = group.getG(); this.digest = digest; this.random = random; this.state = STATE_INITIALIZED; } /** * Gets the current state of this participant. * See the STATE_* constants for possible values. */ public int getState() { return this.state; } /** * Creates and returns the payload to send to the other participant during round 1. *

* After execution, the {@link #getState() state} will be {@link #STATE_ROUND_1_CREATED}. */ public JPAKERound1Payload createRound1PayloadToSend() { if (this.state >= STATE_ROUND_1_CREATED) { throw new IllegalStateException("Round1 payload already created for " + participantId); } this.x1 = JPAKEUtil.generateX1(q, random); this.x2 = JPAKEUtil.generateX2(q, random); this.gx1 = JPAKEUtil.calculateGx(p, g, x1); this.gx2 = JPAKEUtil.calculateGx(p, g, x2); BigInteger[] knowledgeProofForX1 = JPAKEUtil.calculateZeroKnowledgeProof(p, q, g, gx1, x1, participantId, digest, random); BigInteger[] knowledgeProofForX2 = JPAKEUtil.calculateZeroKnowledgeProof(p, q, g, gx2, x2, participantId, digest, random); this.state = STATE_ROUND_1_CREATED; return new JPAKERound1Payload(participantId, gx1, gx2, knowledgeProofForX1, knowledgeProofForX2); } /** * Validates the payload received from the other participant during round 1. *

* Must be called prior to {@link #createRound2PayloadToSend()}. *

* After execution, the {@link #getState() state} will be {@link #STATE_ROUND_1_VALIDATED}. * * @throws CryptoException if validation fails. * @throws IllegalStateException if called multiple times. */ public void validateRound1PayloadReceived(JPAKERound1Payload round1PayloadReceived) throws CryptoException { if (this.state >= STATE_ROUND_1_VALIDATED) { throw new IllegalStateException("Validation already attempted for round1 payload for" + participantId); } this.partnerParticipantId = round1PayloadReceived.getParticipantId(); this.gx3 = round1PayloadReceived.getGx1(); this.gx4 = round1PayloadReceived.getGx2(); BigInteger[] knowledgeProofForX3 = round1PayloadReceived.getKnowledgeProofForX1(); BigInteger[] knowledgeProofForX4 = round1PayloadReceived.getKnowledgeProofForX2(); JPAKEUtil.validateParticipantIdsDiffer(participantId, round1PayloadReceived.getParticipantId()); JPAKEUtil.validateGx4(gx4); JPAKEUtil.validateZeroKnowledgeProof(p, q, g, gx3, knowledgeProofForX3, round1PayloadReceived.getParticipantId(), digest); JPAKEUtil.validateZeroKnowledgeProof(p, q, g, gx4, knowledgeProofForX4, round1PayloadReceived.getParticipantId(), digest); this.state = STATE_ROUND_1_VALIDATED; } /** * Creates and returns the payload to send to the other participant during round 2. *

* {@link #validateRound1PayloadReceived(JPAKERound1Payload)} must be called prior to this method. *

* After execution, the {@link #getState() state} will be {@link #STATE_ROUND_2_CREATED}. * * @throws IllegalStateException if called prior to {@link #validateRound1PayloadReceived(JPAKERound1Payload)}, or multiple times */ public JPAKERound2Payload createRound2PayloadToSend() { if (this.state >= STATE_ROUND_2_CREATED) { throw new IllegalStateException("Round2 payload already created for " + this.participantId); } if (this.state < STATE_ROUND_1_VALIDATED) { throw new IllegalStateException("Round1 payload must be validated prior to creating Round2 payload for " + this.participantId); } BigInteger gA = JPAKEUtil.calculateGA(p, gx1, gx3, gx4); BigInteger s = calculateS(); BigInteger x2s = JPAKEUtil.calculateX2s(q, x2, s); BigInteger A = JPAKEUtil.calculateA(p, q, gA, x2s); BigInteger[] knowledgeProofForX2s = JPAKEUtil.calculateZeroKnowledgeProof(p, q, gA, A, x2s, participantId, digest, random); this.state = STATE_ROUND_2_CREATED; return new JPAKERound2Payload(participantId, A, knowledgeProofForX2s); } /** * Validates the payload received from the other participant during round 2. *

* Note that this DOES NOT detect a non-common password. * The only indication of a non-common password is through derivation * of different keys (which can be detected explicitly by executing round 3 and round 4) *

* Must be called prior to {@link #calculateKeyingMaterial()}. *

* After execution, the {@link #getState() state} will be {@link #STATE_ROUND_2_VALIDATED}. * * @throws CryptoException if validation fails. * @throws IllegalStateException if called prior to {@link #validateRound1PayloadReceived(JPAKERound1Payload)}, or multiple times */ public void validateRound2PayloadReceived(JPAKERound2Payload round2PayloadReceived) throws CryptoException { if (this.state >= STATE_ROUND_2_VALIDATED) { throw new IllegalStateException("Validation already attempted for round2 payload for" + participantId); } if (this.state < STATE_ROUND_1_VALIDATED) { throw new IllegalStateException("Round1 payload must be validated prior to validating Round2 payload for " + this.participantId); } BigInteger gB = JPAKEUtil.calculateGA(p, gx3, gx1, gx2); this.b = round2PayloadReceived.getA(); BigInteger[] knowledgeProofForX4s = round2PayloadReceived.getKnowledgeProofForX2s(); JPAKEUtil.validateParticipantIdsDiffer(participantId, round2PayloadReceived.getParticipantId()); JPAKEUtil.validateParticipantIdsEqual(this.partnerParticipantId, round2PayloadReceived.getParticipantId()); JPAKEUtil.validateGa(gB); JPAKEUtil.validateZeroKnowledgeProof(p, q, gB, b, knowledgeProofForX4s, round2PayloadReceived.getParticipantId(), digest); this.state = STATE_ROUND_2_VALIDATED; } /** * Calculates and returns the key material. * A session key must be derived from this key material using a secure key derivation function (KDF). * The KDF used to derive the key is handled externally (i.e. not by {@link JPAKEParticipant}). *

* The keying material will be identical for each participant if and only if * each participant's password is the same. i.e. If the participants do not * share the same password, then each participant will derive a different key. * Therefore, if you immediately start using a key derived from * the keying material, then you must handle detection of incorrect keys. * If you want to handle this detection explicitly, you can optionally perform * rounds 3 and 4. See {@link JPAKEParticipant} for details on how to execute * rounds 3 and 4. *

* The keying material will be in the range [0, p-1]. *

* {@link #validateRound2PayloadReceived(JPAKERound2Payload)} must be called prior to this method. *

* As a side effect, the internal {@link #password} array is cleared, since it is no longer needed. *

* After execution, the {@link #getState() state} will be {@link #STATE_KEY_CALCULATED}. * * @throws IllegalStateException if called prior to {@link #validateRound2PayloadReceived(JPAKERound2Payload)}, * or if called multiple times. */ public BigInteger calculateKeyingMaterial() { if (this.state >= STATE_KEY_CALCULATED) { throw new IllegalStateException("Key already calculated for " + participantId); } if (this.state < STATE_ROUND_2_VALIDATED) { throw new IllegalStateException("Round2 payload must be validated prior to creating key for " + participantId); } BigInteger s = calculateS(); /* * Clear the password array from memory, since we don't need it anymore. * * Also set the field to null as a flag to indicate that the key has already been calculated. */ Arrays.fill(password, (char)0); this.password = null; BigInteger keyingMaterial = JPAKEUtil.calculateKeyingMaterial(p, q, gx4, x2, s, b); /* * Clear the ephemeral private key fields as well. * Note that we're relying on the garbage collector to do its job to clean these up. * The old objects will hang around in memory until the garbage collector destroys them. * * If the ephemeral private keys x1 and x2 are leaked, * the attacker might be able to brute-force the password. */ this.x1 = null; this.x2 = null; this.b = null; /* * Do not clear gx* yet, since those are needed by round 3. */ this.state = STATE_KEY_CALCULATED; return keyingMaterial; } /** * Creates and returns the payload to send to the other participant during round 3. *

* See {@link JPAKEParticipant} for more details on round 3. *

* After execution, the {@link #getState() state} will be {@link #STATE_ROUND_3_CREATED}. * * @param keyingMaterial The keying material as returned from {@link #calculateKeyingMaterial()}. * @throws IllegalStateException if called prior to {@link #calculateKeyingMaterial()}, or multiple times */ public JPAKERound3Payload createRound3PayloadToSend(BigInteger keyingMaterial) { if (this.state >= STATE_ROUND_3_CREATED) { throw new IllegalStateException("Round3 payload already created for " + this.participantId); } if (this.state < STATE_KEY_CALCULATED) { throw new IllegalStateException("Keying material must be calculated prior to creating Round3 payload for " + this.participantId); } BigInteger macTag = JPAKEUtil.calculateMacTag( this.participantId, this.partnerParticipantId, this.gx1, this.gx2, this.gx3, this.gx4, keyingMaterial, this.digest); this.state = STATE_ROUND_3_CREATED; return new JPAKERound3Payload(participantId, macTag); } /** * Validates the payload received from the other participant during round 3. *

* See {@link JPAKEParticipant} for more details on round 3. *

* After execution, the {@link #getState() state} will be {@link #STATE_ROUND_3_VALIDATED}. * * @param round3PayloadReceived The round 3 payload received from the other participant. * @param keyingMaterial The keying material as returned from {@link #calculateKeyingMaterial()}. * @throws CryptoException if validation fails. * @throws IllegalStateException if called prior to {@link #calculateKeyingMaterial()}, or multiple times */ public void validateRound3PayloadReceived(JPAKERound3Payload round3PayloadReceived, BigInteger keyingMaterial) throws CryptoException { if (this.state >= STATE_ROUND_3_VALIDATED) { throw new IllegalStateException("Validation already attempted for round3 payload for" + participantId); } if (this.state < STATE_KEY_CALCULATED) { throw new IllegalStateException("Keying material must be calculated validated prior to validating Round3 payload for " + this.participantId); } JPAKEUtil.validateParticipantIdsDiffer(participantId, round3PayloadReceived.getParticipantId()); JPAKEUtil.validateParticipantIdsEqual(this.partnerParticipantId, round3PayloadReceived.getParticipantId()); JPAKEUtil.validateMacTag( this.participantId, this.partnerParticipantId, this.gx1, this.gx2, this.gx3, this.gx4, keyingMaterial, this.digest, round3PayloadReceived.getMacTag()); /* * Clear the rest of the fields. */ this.gx1 = null; this.gx2 = null; this.gx3 = null; this.gx4 = null; this.state = STATE_ROUND_3_VALIDATED; } private BigInteger calculateS() { try { return JPAKEUtil.calculateS(q, password); } catch (CryptoException e) { throw Exceptions.illegalStateException(e.getMessage(), e); } } }





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