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The Bouncy Castle Java API for handling the OpenPGP protocol. This jar contains the OpenPGP API for JDK 1.4. The APIs can be used in conjunction with a JCE/JCA provider such as the one provided with the Bouncy Castle Cryptography APIs.

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package org.bouncycastle.openpgp;

import java.io.ByteArrayInputStream;
import java.io.ByteArrayOutputStream;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.math.BigInteger;
import java.util.ArrayList;
import java.util.Date;
import java.util.Iterator;
import java.util.List;

import org.bouncycastle.asn1.x9.ECNamedCurveTable;
import org.bouncycastle.bcpg.BCPGInputStream;
import org.bouncycastle.bcpg.BCPGObject;
import org.bouncycastle.bcpg.BCPGOutputStream;
import org.bouncycastle.bcpg.ContainedPacket;
import org.bouncycastle.bcpg.DSASecretBCPGKey;
import org.bouncycastle.bcpg.ECDSAPublicBCPGKey;
import org.bouncycastle.bcpg.ECSecretBCPGKey;
import org.bouncycastle.bcpg.ElGamalSecretBCPGKey;
import org.bouncycastle.bcpg.HashAlgorithmTags;
import org.bouncycastle.bcpg.PublicKeyAlgorithmTags;
import org.bouncycastle.bcpg.PublicKeyPacket;
import org.bouncycastle.bcpg.RSASecretBCPGKey;
import org.bouncycastle.bcpg.S2K;
import org.bouncycastle.bcpg.SecretKeyPacket;
import org.bouncycastle.bcpg.SecretSubkeyPacket;
import org.bouncycastle.bcpg.SymmetricKeyAlgorithmTags;
import org.bouncycastle.bcpg.UserAttributePacket;
import org.bouncycastle.bcpg.UserIDPacket;
import org.bouncycastle.openpgp.operator.KeyFingerPrintCalculator;
import org.bouncycastle.openpgp.operator.PBEProtectionRemoverFactory;
import org.bouncycastle.openpgp.operator.PBESecretKeyDecryptor;
import org.bouncycastle.openpgp.operator.PBESecretKeyEncryptor;
import org.bouncycastle.openpgp.operator.PGPContentSignerBuilder;
import org.bouncycastle.openpgp.operator.PGPDigestCalculator;

/**
 * general class to handle and construct  a PGP secret key object.
 */
public class PGPSecretKey
{    
    SecretKeyPacket secret;
    PGPPublicKey    pub;

    PGPSecretKey(
        SecretKeyPacket secret,
        PGPPublicKey    pub)
    {
        this.secret = secret;
        this.pub = pub;
    }
    
    PGPSecretKey(
        PGPPrivateKey   privKey,
        PGPPublicKey    pubKey,
        PGPDigestCalculator checksumCalculator,
        PBESecretKeyEncryptor keyEncryptor)
        throws PGPException
    {
        this(privKey, pubKey, checksumCalculator, false, keyEncryptor);
    }

    /**
     * Construct a PGPSecretKey using the passed in private key and public key. This constructor will not add any
     * certifications but assumes that pubKey already has what is required.
     *
     * @param privKey the private key component.
     * @param pubKey the public key component.
     * @param checksumCalculator a calculator for the private key checksum
     * @param isMasterKey true if the key is a master key, false otherwise.
     * @param keyEncryptor an encryptor for the key if required (null otherwise).
     * @throws PGPException if there is an issue creating the secret key packet.
     */
    public PGPSecretKey(
        PGPPrivateKey   privKey,
        PGPPublicKey    pubKey,
        PGPDigestCalculator checksumCalculator,
        boolean         isMasterKey,
        PBESecretKeyEncryptor keyEncryptor)
        throws PGPException
    {
        this.pub = pubKey;
        this.secret = buildSecretKeyPacket(isMasterKey, privKey, pubKey, keyEncryptor, checksumCalculator);
    }

    private static SecretKeyPacket buildSecretKeyPacket(boolean isMasterKey, PGPPrivateKey privKey, PGPPublicKey pubKey, PBESecretKeyEncryptor keyEncryptor, PGPDigestCalculator checksumCalculator)
        throws PGPException
    {
        BCPGObject secKey = (BCPGObject)privKey.getPrivateKeyDataPacket();

        if (secKey == null)
        {
            if (isMasterKey)
            {
                return new SecretKeyPacket(pubKey.publicPk, SymmetricKeyAlgorithmTags.NULL, null, null, new byte[0]);
            }
            else
            {
                return new SecretSubkeyPacket(pubKey.publicPk, SymmetricKeyAlgorithmTags.NULL, null, null, new byte[0]);
            }
        }

        try
        {
            ByteArrayOutputStream bOut = new ByteArrayOutputStream();
            BCPGOutputStream pOut = new BCPGOutputStream(bOut);

            pOut.writeObject(secKey);

            byte[]    keyData = bOut.toByteArray();

            pOut.write(checksum(checksumCalculator, keyData, keyData.length));

            int encAlgorithm = (keyEncryptor != null) ? keyEncryptor.getAlgorithm() : SymmetricKeyAlgorithmTags.NULL;

            if (encAlgorithm != SymmetricKeyAlgorithmTags.NULL)
            {
                keyData = bOut.toByteArray(); // include checksum

                byte[] encData = keyEncryptor.encryptKeyData(keyData, 0, keyData.length);
                byte[] iv = keyEncryptor.getCipherIV();

                S2K s2k = keyEncryptor.getS2K();

                int s2kUsage;

                if (checksumCalculator != null)
                {
                    if (checksumCalculator.getAlgorithm() != HashAlgorithmTags.SHA1)
                    {
                        throw new PGPException("only SHA1 supported for key checksum calculations.");
                    }
                    s2kUsage = SecretKeyPacket.USAGE_SHA1;
                }
                else
                {
                    s2kUsage = SecretKeyPacket.USAGE_CHECKSUM;
                }

                if (isMasterKey)
                {
                    return new SecretKeyPacket(pubKey.publicPk, encAlgorithm, s2kUsage, s2k, iv, encData);
                }
                else
                {
                    return new SecretSubkeyPacket(pubKey.publicPk, encAlgorithm, s2kUsage, s2k, iv, encData);
                }
            }
            else
            {
                if (isMasterKey)
                {
                    return new SecretKeyPacket(pubKey.publicPk, encAlgorithm, null, null, bOut.toByteArray());
                }
                else
                {
                    return new SecretSubkeyPacket(pubKey.publicPk, encAlgorithm, null, null, bOut.toByteArray());
                }
            }
        }
        catch (PGPException e)
        {
            throw e;
        }
        catch (Exception e)
        {
            throw new PGPException("Exception encrypting key", e);
        }
    }

    /**
     * Construct a PGPSecretKey using the passed in private/public key pair and binding it to the passed in id
     * using a generated certification of certificationLevel.The secret key checksum is calculated using the original
     * non-digest based checksum.
     *
     * @param certificationLevel the type of certification to be added.
     * @param keyPair the public/private keys to use.
     * @param id the id to bind to the key.
     * @param hashedPcks the hashed packets to be added to the certification.
     * @param unhashedPcks the unhashed packets to be added to the certification.
     * @param certificationSignerBuilder the builder for generating the certification.
     * @param keyEncryptor an encryptor for the key if required (null otherwise).
     * @throws PGPException if there is an issue creating the secret key packet or the certification.
     */
    public PGPSecretKey(
        int                         certificationLevel,
        PGPKeyPair                  keyPair,
        String                      id,
        PGPSignatureSubpacketVector hashedPcks,
        PGPSignatureSubpacketVector unhashedPcks,
        PGPContentSignerBuilder     certificationSignerBuilder,
        PBESecretKeyEncryptor       keyEncryptor)
        throws PGPException
    {
        this(certificationLevel, keyPair, id, null, hashedPcks, unhashedPcks, certificationSignerBuilder, keyEncryptor);
    }

    /**
     * Construct a PGPSecretKey using the passed in private/public key pair and binding it to the passed in id
     * using a generated certification of certificationLevel.
     *
     * @param certificationLevel the type of certification to be added.
     * @param keyPair the public/private keys to use.
     * @param id the id to bind to the key.
     * @param checksumCalculator a calculator for the private key checksum.
     * @param hashedPcks the hashed packets to be added to the certification.
     * @param unhashedPcks the unhashed packets to be added to the certification.
     * @param certificationSignerBuilder the builder for generating the certification.
     * @param keyEncryptor an encryptor for the key if required (null otherwise).
     * @throws PGPException if there is an issue creating the secret key packet or the certification.
     */
    public PGPSecretKey(
        int                         certificationLevel,
        PGPKeyPair                  keyPair,
        String                      id,
        PGPDigestCalculator         checksumCalculator,
        PGPSignatureSubpacketVector hashedPcks,
        PGPSignatureSubpacketVector unhashedPcks,
        PGPContentSignerBuilder     certificationSignerBuilder,
        PBESecretKeyEncryptor       keyEncryptor)
        throws PGPException
    {
        this(keyPair.getPrivateKey(), certifiedPublicKey(certificationLevel, keyPair, id, hashedPcks, unhashedPcks, certificationSignerBuilder), checksumCalculator, true, keyEncryptor);
    }

    private static PGPPublicKey certifiedPublicKey(
        int certificationLevel,
        PGPKeyPair keyPair,
        String id,
        PGPSignatureSubpacketVector hashedPcks,
        PGPSignatureSubpacketVector unhashedPcks,
        PGPContentSignerBuilder     certificationSignerBuilder)
        throws PGPException
    {
        PGPSignatureGenerator    sGen;

        try
        {
            sGen = new PGPSignatureGenerator(certificationSignerBuilder);
        }
        catch (Exception e)
        {
            throw new PGPException("creating signature generator: " + e, e);
        }

        //
        // generate the certification
        //
        sGen.init(certificationLevel, keyPair.getPrivateKey());

        sGen.setHashedSubpackets(hashedPcks);
        sGen.setUnhashedSubpackets(unhashedPcks);

        try
        {
            PGPSignature    certification = sGen.generateCertification(id, keyPair.getPublicKey());

            return PGPPublicKey.addCertification(keyPair.getPublicKey(), id, certification);
        }
        catch (Exception e)
        {
            throw new PGPException("exception doing certification: " + e, e);
        }
    }

    /**
     * Return true if this key has an algorithm type that makes it suitable to use for signing.
     * 

* Note: with version 4 keys KeyFlags subpackets should also be considered when present for * determining the preferred use of the key. * * @return true if this key algorithm is suitable for use with signing. */ public boolean isSigningKey() { int algorithm = pub.getAlgorithm(); return ((algorithm == PGPPublicKey.RSA_GENERAL) || (algorithm == PGPPublicKey.RSA_SIGN) || (algorithm == PGPPublicKey.DSA) || (algorithm == PGPPublicKey.ECDSA) || (algorithm == PGPPublicKey.ELGAMAL_GENERAL)); } /** * Return true if this is a master key. * @return true if a master key. */ public boolean isMasterKey() { return pub.isMasterKey(); } /** * Detect if the Secret Key's Private Key is empty or not * * @return boolean whether or not the private key is empty */ public boolean isPrivateKeyEmpty() { byte[] secKeyData = secret.getSecretKeyData(); return (secKeyData == null || secKeyData.length < 1); } /** * return the algorithm the key is encrypted with. * * @return the algorithm used to encrypt the secret key. */ public int getKeyEncryptionAlgorithm() { return secret.getEncAlgorithm(); } /** * Return the keyID of the public key associated with this key. * * @return the keyID associated with this key. */ public long getKeyID() { return pub.getKeyID(); } /** * Return the S2K usage associated with this key. * * @return the key's S2K usage */ public int getS2KUsage() { return secret.getS2KUsage(); } /** * Return the S2K used to process this key * * @return the key's S2K, null if one is not present. */ public S2K getS2K() { return secret.getS2K(); } /** * Return the public key associated with this key. * * @return the public key for this key. */ public PGPPublicKey getPublicKey() { return pub; } /** * Return any userIDs associated with the key. * * @return an iterator of Strings. */ public Iterator getUserIDs() { return pub.getUserIDs(); } /** * Return any user attribute vectors associated with the key. * * @return an iterator of PGPUserAttributeSubpacketVector. */ public Iterator getUserAttributes() { return pub.getUserAttributes(); } private byte[] extractKeyData( PBESecretKeyDecryptor decryptorFactory) throws PGPException { byte[] encData = secret.getSecretKeyData(); byte[] data = null; if (secret.getEncAlgorithm() != SymmetricKeyAlgorithmTags.NULL) { try { if (secret.getPublicKeyPacket().getVersion() == 4) { byte[] key = decryptorFactory.makeKeyFromPassPhrase(secret.getEncAlgorithm(), secret.getS2K()); data = decryptorFactory.recoverKeyData(secret.getEncAlgorithm(), key, secret.getIV(), encData, 0, encData.length); boolean useSHA1 = secret.getS2KUsage() == SecretKeyPacket.USAGE_SHA1; byte[] check = checksum(useSHA1 ? decryptorFactory.getChecksumCalculator(HashAlgorithmTags.SHA1) : null, data, (useSHA1) ? data.length - 20 : data.length - 2); for (int i = 0; i != check.length; i++) { if (check[i] != data[data.length - check.length + i]) { throw new PGPException("checksum mismatch at " + i + " of " + check.length); } } } else // version 2 or 3, RSA only. { byte[] key = decryptorFactory.makeKeyFromPassPhrase(secret.getEncAlgorithm(), secret.getS2K()); data = new byte[encData.length]; byte[] iv = new byte[secret.getIV().length]; System.arraycopy(secret.getIV(), 0, iv, 0, iv.length); // // read in the four numbers // int pos = 0; for (int i = 0; i != 4; i++) { int encLen = (((encData[pos] << 8) | (encData[pos + 1] & 0xff)) + 7) / 8; data[pos] = encData[pos]; data[pos + 1] = encData[pos + 1]; byte[] tmp = decryptorFactory.recoverKeyData(secret.getEncAlgorithm(), key, iv, encData, pos + 2, encLen); System.arraycopy(tmp, 0, data, pos + 2, tmp.length); pos += 2 + encLen; if (i != 3) { System.arraycopy(encData, pos - iv.length, iv, 0, iv.length); } } // // verify and copy checksum // data[pos] = encData[pos]; data[pos + 1] = encData[pos + 1]; int cs = ((encData[pos] << 8) & 0xff00) | (encData[pos + 1] & 0xff); int calcCs = 0; for (int j = 0; j < data.length - 2; j++) { calcCs += data[j] & 0xff; } calcCs &= 0xffff; if (calcCs != cs) { throw new PGPException("checksum mismatch: passphrase wrong, expected " + Integer.toHexString(cs) + " found " + Integer.toHexString(calcCs)); } } } catch (PGPException e) { throw e; } catch (Exception e) { throw new PGPException("Exception decrypting key", e); } } else { data = encData; } return data; } /** * Extract a PGPPrivate key from the SecretKey's encrypted contents. * * @param decryptorFactory factory to use to generate a decryptor for the passed in secretKey. * @return PGPPrivateKey the unencrypted private key. * @throws PGPException on failure. */ public PGPPrivateKey extractPrivateKey( PBESecretKeyDecryptor decryptorFactory) throws PGPException { if (isPrivateKeyEmpty()) { return null; } PublicKeyPacket pubPk = secret.getPublicKeyPacket(); try { byte[] data = extractKeyData(decryptorFactory); BCPGInputStream in = new BCPGInputStream(new ByteArrayInputStream(data)); switch (pubPk.getAlgorithm()) { case PGPPublicKey.RSA_ENCRYPT: case PGPPublicKey.RSA_GENERAL: case PGPPublicKey.RSA_SIGN: RSASecretBCPGKey rsaPriv = new RSASecretBCPGKey(in); return new PGPPrivateKey(this.getKeyID(), pubPk, rsaPriv); case PGPPublicKey.DSA: DSASecretBCPGKey dsaPriv = new DSASecretBCPGKey(in); return new PGPPrivateKey(this.getKeyID(), pubPk, dsaPriv); case PGPPublicKey.ELGAMAL_ENCRYPT: case PGPPublicKey.ELGAMAL_GENERAL: ElGamalSecretBCPGKey elPriv = new ElGamalSecretBCPGKey(in); return new PGPPrivateKey(this.getKeyID(), pubPk, elPriv); case PGPPublicKey.ECDH: case PGPPublicKey.ECDSA: ECSecretBCPGKey ecPriv = new ECSecretBCPGKey(in); return new PGPPrivateKey(this.getKeyID(), pubPk, ecPriv); default: throw new PGPException("unknown public key algorithm encountered"); } } catch (PGPException e) { throw e; } catch (Exception e) { throw new PGPException("Exception constructing key", e); } } private static byte[] checksum(PGPDigestCalculator digCalc, byte[] bytes, int length) throws PGPException { if (digCalc != null) { OutputStream dOut = digCalc.getOutputStream(); try { dOut.write(bytes, 0, length); dOut.close(); } catch (Exception e) { throw new PGPException("checksum digest calculation failed: " + e.getMessage(), e); } return digCalc.getDigest(); } else { int checksum = 0; for (int i = 0; i != length; i++) { checksum += bytes[i] & 0xff; } byte[] check = new byte[2]; check[0] = (byte)(checksum >> 8); check[1] = (byte)checksum; return check; } } public byte[] getEncoded() throws IOException { ByteArrayOutputStream bOut = new ByteArrayOutputStream(); this.encode(bOut); return bOut.toByteArray(); } public void encode( OutputStream outStream) throws IOException { BCPGOutputStream out; if (outStream instanceof BCPGOutputStream) { out = (BCPGOutputStream)outStream; } else { out = new BCPGOutputStream(outStream); } out.writePacket(secret); if (pub.trustPk != null) { out.writePacket(pub.trustPk); } if (pub.subSigs == null) // is not a sub key { for (int i = 0; i != pub.keySigs.size(); i++) { ((PGPSignature)pub.keySigs.get(i)).encode(out); } for (int i = 0; i != pub.ids.size(); i++) { if (pub.ids.get(i) instanceof UserIDPacket) { UserIDPacket id = (UserIDPacket)pub.ids.get(i); out.writePacket(id); } else { PGPUserAttributeSubpacketVector v = (PGPUserAttributeSubpacketVector)pub.ids.get(i); out.writePacket(new UserAttributePacket(v.toSubpacketArray())); } if (pub.idTrusts.get(i) != null) { out.writePacket((ContainedPacket)pub.idTrusts.get(i)); } List sigs = (ArrayList)pub.idSigs.get(i); for (int j = 0; j != sigs.size(); j++) { ((PGPSignature)sigs.get(j)).encode(out); } } } else { for (int j = 0; j != pub.subSigs.size(); j++) { ((PGPSignature)pub.subSigs.get(j)).encode(out); } } } /** * Return a copy of the passed in secret key, encrypted using a new * password and the passed in algorithm. * * @param key the PGPSecretKey to be copied. * @param oldKeyDecryptor the current decryptor based on the current password for key. * @param newKeyEncryptor a new encryptor based on a new password for encrypting the secret key material. */ public static PGPSecretKey copyWithNewPassword( PGPSecretKey key, PBESecretKeyDecryptor oldKeyDecryptor, PBESecretKeyEncryptor newKeyEncryptor) throws PGPException { if (key.isPrivateKeyEmpty()) { throw new PGPException("no private key in this SecretKey - public key present only."); } byte[] rawKeyData = key.extractKeyData(oldKeyDecryptor); int s2kUsage = key.secret.getS2KUsage(); byte[] iv = null; S2K s2k = null; byte[] keyData; int newEncAlgorithm = SymmetricKeyAlgorithmTags.NULL; if (newKeyEncryptor == null || newKeyEncryptor.getAlgorithm() == SymmetricKeyAlgorithmTags.NULL) { s2kUsage = SecretKeyPacket.USAGE_NONE; if (key.secret.getS2KUsage() == SecretKeyPacket.USAGE_SHA1) // SHA-1 hash, need to rewrite checksum { keyData = new byte[rawKeyData.length - 18]; System.arraycopy(rawKeyData, 0, keyData, 0, keyData.length - 2); byte[] check = checksum(null, keyData, keyData.length - 2); keyData[keyData.length - 2] = check[0]; keyData[keyData.length - 1] = check[1]; } else { keyData = rawKeyData; } } else { if (s2kUsage == SecretKeyPacket.USAGE_NONE) { s2kUsage = SecretKeyPacket.USAGE_CHECKSUM; } if (key.secret.getPublicKeyPacket().getVersion() < 4) { // Version 2 or 3 - RSA Keys only byte[] encKey = newKeyEncryptor.getKey(); keyData = new byte[rawKeyData.length]; if (newKeyEncryptor.getHashAlgorithm() != HashAlgorithmTags.MD5) { throw new PGPException("MD5 Digest Calculator required for version 3 key encryptor."); } // // process 4 numbers // int pos = 0; for (int i = 0; i != 4; i++) { int encLen = (((rawKeyData[pos] << 8) | (rawKeyData[pos + 1] & 0xff)) + 7) / 8; keyData[pos] = rawKeyData[pos]; keyData[pos + 1] = rawKeyData[pos + 1]; byte[] tmp; if (i == 0) { tmp = newKeyEncryptor.encryptKeyData(encKey, rawKeyData, pos + 2, encLen); iv = newKeyEncryptor.getCipherIV(); } else { byte[] tmpIv = new byte[iv.length]; System.arraycopy(keyData, pos - iv.length, tmpIv, 0, tmpIv.length); tmp = newKeyEncryptor.encryptKeyData(encKey, tmpIv, rawKeyData, pos + 2, encLen); } System.arraycopy(tmp, 0, keyData, pos + 2, tmp.length); pos += 2 + encLen; } // // copy in checksum. // keyData[pos] = rawKeyData[pos]; keyData[pos + 1] = rawKeyData[pos + 1]; s2k = newKeyEncryptor.getS2K(); newEncAlgorithm = newKeyEncryptor.getAlgorithm(); } else { keyData = newKeyEncryptor.encryptKeyData(rawKeyData, 0, rawKeyData.length); iv = newKeyEncryptor.getCipherIV(); s2k = newKeyEncryptor.getS2K(); newEncAlgorithm = newKeyEncryptor.getAlgorithm(); } } SecretKeyPacket secret; if (key.secret instanceof SecretSubkeyPacket) { secret = new SecretSubkeyPacket(key.secret.getPublicKeyPacket(), newEncAlgorithm, s2kUsage, s2k, iv, keyData); } else { secret = new SecretKeyPacket(key.secret.getPublicKeyPacket(), newEncAlgorithm, s2kUsage, s2k, iv, keyData); } return new PGPSecretKey(secret, key.pub); } /** * Replace the passed the public key on the passed in secret key. * * @param secretKey secret key to change * @param publicKey new public key. * @return a new secret key. * @throws IllegalArgumentException if keyIDs do not match. */ public static PGPSecretKey replacePublicKey(PGPSecretKey secretKey, PGPPublicKey publicKey) { if (publicKey.getKeyID() != secretKey.getKeyID()) { throw new IllegalArgumentException("keyIDs do not match"); } return new PGPSecretKey(secretKey.secret, publicKey); } /** * Parse a secret key from one of the GPG S expression keys associating it with the passed in public key. * * @return a secret key object. */ public static PGPSecretKey parseSecretKeyFromSExpr(InputStream inputStream, PBEProtectionRemoverFactory keyProtectionRemoverFactory, PGPPublicKey pubKey) throws IOException, PGPException { SXprUtils.skipOpenParenthesis(inputStream); String type; type = SXprUtils.readString(inputStream, inputStream.read()); if (type.equals("protected-private-key")) { SXprUtils.skipOpenParenthesis(inputStream); String curveName; String keyType = SXprUtils.readString(inputStream, inputStream.read()); if (keyType.equals("ecc")) { SXprUtils.skipOpenParenthesis(inputStream); String curveID = SXprUtils.readString(inputStream, inputStream.read()); curveName = SXprUtils.readString(inputStream, inputStream.read()); SXprUtils.skipCloseParenthesis(inputStream); } else { throw new PGPException("no curve details found"); } byte[] qVal; SXprUtils.skipOpenParenthesis(inputStream); type = SXprUtils.readString(inputStream, inputStream.read()); if (type.equals("q")) { qVal = SXprUtils.readBytes(inputStream, inputStream.read()); } else { throw new PGPException("no q value found"); } SXprUtils.skipCloseParenthesis(inputStream); byte[] dValue = getDValue(inputStream, keyProtectionRemoverFactory, curveName); // TODO: check SHA-1 hash. return new PGPSecretKey(new SecretKeyPacket(pubKey.getPublicKeyPacket(), SymmetricKeyAlgorithmTags.NULL, null, null, new ECSecretBCPGKey(new BigInteger(1, dValue)).getEncoded()), pubKey); } throw new PGPException("unknown key type found"); } /** * Parse a secret key from one of the GPG S expression keys. * * @return a secret key object. */ public static PGPSecretKey parseSecretKeyFromSExpr(InputStream inputStream, PBEProtectionRemoverFactory keyProtectionRemoverFactory, KeyFingerPrintCalculator fingerPrintCalculator) throws IOException, PGPException { SXprUtils.skipOpenParenthesis(inputStream); String type; type = SXprUtils.readString(inputStream, inputStream.read()); if (type.equals("protected-private-key")) { SXprUtils.skipOpenParenthesis(inputStream); String curveName; String keyType = SXprUtils.readString(inputStream, inputStream.read()); if (keyType.equals("ecc")) { SXprUtils.skipOpenParenthesis(inputStream); String curveID = SXprUtils.readString(inputStream, inputStream.read()); curveName = SXprUtils.readString(inputStream, inputStream.read()); if (curveName.startsWith("NIST ")) { curveName = curveName.substring("NIST ".length()); } SXprUtils.skipCloseParenthesis(inputStream); } else { throw new PGPException("no curve details found"); } byte[] qVal; SXprUtils.skipOpenParenthesis(inputStream); type = SXprUtils.readString(inputStream, inputStream.read()); if (type.equals("q")) { qVal = SXprUtils.readBytes(inputStream, inputStream.read()); } else { throw new PGPException("no q value found"); } PublicKeyPacket pubPacket = new PublicKeyPacket(PublicKeyAlgorithmTags.ECDSA, new Date(), new ECDSAPublicBCPGKey(ECNamedCurveTable.getOID(curveName), new BigInteger(1, qVal))); SXprUtils.skipCloseParenthesis(inputStream); byte[] dValue = getDValue(inputStream, keyProtectionRemoverFactory, curveName); // TODO: check SHA-1 hash. return new PGPSecretKey(new SecretKeyPacket(pubPacket, SymmetricKeyAlgorithmTags.NULL, null, null, new ECSecretBCPGKey(new BigInteger(1, dValue)).getEncoded()), new PGPPublicKey(pubPacket, fingerPrintCalculator)); } throw new PGPException("unknown key type found"); } private static byte[] getDValue(InputStream inputStream, PBEProtectionRemoverFactory keyProtectionRemoverFactory, String curveName) throws IOException, PGPException { String type; SXprUtils.skipOpenParenthesis(inputStream); String protection; S2K s2k; byte[] iv; byte[] secKeyData; type = SXprUtils.readString(inputStream, inputStream.read()); if (type.equals("protected")) { protection = SXprUtils.readString(inputStream, inputStream.read()); SXprUtils.skipOpenParenthesis(inputStream); s2k = SXprUtils.parseS2K(inputStream); iv = SXprUtils.readBytes(inputStream, inputStream.read()); SXprUtils.skipCloseParenthesis(inputStream); secKeyData = SXprUtils.readBytes(inputStream, inputStream.read()); } else { throw new PGPException("protected block not found"); } PBESecretKeyDecryptor keyDecryptor = keyProtectionRemoverFactory.createDecryptor(protection); // TODO: recognise other algorithms byte[] key = keyDecryptor.makeKeyFromPassPhrase(SymmetricKeyAlgorithmTags.AES_128, s2k); byte[] data = keyDecryptor.recoverKeyData(SymmetricKeyAlgorithmTags.AES_128, key, iv, secKeyData, 0, secKeyData.length); // // parse the secret key S-expr // InputStream keyIn = new ByteArrayInputStream(data); SXprUtils.skipOpenParenthesis(keyIn); SXprUtils.skipOpenParenthesis(keyIn); SXprUtils.skipOpenParenthesis(keyIn); String name = SXprUtils.readString(keyIn, keyIn.read()); return SXprUtils.readBytes(keyIn, keyIn.read()); } }





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