/** * Copyright (C) 2011 Whisper Systems * Copyright (C) 2013 Open Whisper Systems * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program 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 for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ package org.thoughtcrime.securesms.crypto; import org.thoughtcrime.securesms.util.Base64; import org.thoughtcrime.securesms.util.Util; import org.whispersystems.libaxolotl.InvalidKeyException; import org.whispersystems.libaxolotl.InvalidMessageException; import org.whispersystems.libaxolotl.ecc.Curve; import org.whispersystems.libaxolotl.ecc.ECKeyPair; import org.whispersystems.libaxolotl.ecc.ECPrivateKey; import org.whispersystems.libaxolotl.ecc.ECPublicKey; import org.thoughtcrime.securesms.util.Conversions; import java.io.IOException; import java.security.NoSuchAlgorithmException; import javax.crypto.Mac; import javax.crypto.spec.SecretKeySpec; /** * This class is used to asymmetricly encrypt local data. This is used in the case * where TextSecure receives an SMS, but the user's local encryption passphrase is * not cached (either because of a timeout, or because it hasn't yet been entered). * * In this case, we have access to the public key of a local keypair. We encrypt * the message with this, and put it into the DB. When the user enters their passphrase, * we can get access to the private key of the local keypair, decrypt the message, and * replace it into the DB with symmetric encryption. * * The encryption protocol is as follows: * * 1) Generate an ephemeral keypair. * 2) Do ECDH with the public key of the local durable keypair. * 3) Do KMF with the ECDH result to obtain a master secret. * 4) Encrypt the message with that master secret. * * @author Moxie Marlinspike * */ public class AsymmetricMasterCipher { private final AsymmetricMasterSecret asymmetricMasterSecret; public AsymmetricMasterCipher(AsymmetricMasterSecret asymmetricMasterSecret) { this.asymmetricMasterSecret = asymmetricMasterSecret; } public byte[] encryptBytes(byte[] body) { try { ECPublicKey theirPublic = asymmetricMasterSecret.getDjbPublicKey(); ECKeyPair ourKeyPair = Curve.generateKeyPair(); byte[] secret = Curve.calculateAgreement(theirPublic, ourKeyPair.getPrivateKey()); MasterCipher masterCipher = getMasterCipherForSecret(secret); byte[] encryptedBodyBytes = masterCipher.encryptBytes(body); PublicKey ourPublicKey = new PublicKey(31337, ourKeyPair.getPublicKey()); byte[] publicKeyBytes = ourPublicKey.serialize(); return Util.combine(publicKeyBytes, encryptedBodyBytes); } catch (InvalidKeyException e) { throw new AssertionError(e); } } public byte[] decryptBytes(byte[] combined) throws IOException, InvalidMessageException { try { byte[][] parts = Util.split(combined, PublicKey.KEY_SIZE, combined.length - PublicKey.KEY_SIZE); PublicKey theirPublicKey = new PublicKey(parts[0], 0); ECPrivateKey ourPrivateKey = asymmetricMasterSecret.getPrivateKey(); byte[] secret = Curve.calculateAgreement(theirPublicKey.getKey(), ourPrivateKey); MasterCipher masterCipher = getMasterCipherForSecret(secret); return masterCipher.decryptBytes(parts[1]); } catch (InvalidKeyException e) { throw new InvalidMessageException(e); } } public String decryptBody(String body) throws IOException, InvalidMessageException { byte[] combined = Base64.decode(body); return new String(decryptBytes(combined)); } public String encryptBody(String body) { return Base64.encodeBytes(encryptBytes(body.getBytes())); } private MasterCipher getMasterCipherForSecret(byte[] secretBytes) { SecretKeySpec cipherKey = deriveCipherKey(secretBytes); SecretKeySpec macKey = deriveMacKey(secretBytes); MasterSecret masterSecret = new MasterSecret(cipherKey, macKey); return new MasterCipher(masterSecret); } private SecretKeySpec deriveMacKey(byte[] secretBytes) { byte[] digestedBytes = getDigestedBytes(secretBytes, 1); byte[] macKeyBytes = new byte[20]; System.arraycopy(digestedBytes, 0, macKeyBytes, 0, macKeyBytes.length); return new SecretKeySpec(macKeyBytes, "HmacSHA1"); } private SecretKeySpec deriveCipherKey(byte[] secretBytes) { byte[] digestedBytes = getDigestedBytes(secretBytes, 0); byte[] cipherKeyBytes = new byte[16]; System.arraycopy(digestedBytes, 0, cipherKeyBytes, 0, cipherKeyBytes.length); return new SecretKeySpec(cipherKeyBytes, "AES"); } private byte[] getDigestedBytes(byte[] secretBytes, int iteration) { try { Mac mac = Mac.getInstance("HmacSHA256"); mac.init(new SecretKeySpec(secretBytes, "HmacSHA256")); return mac.doFinal(Conversions.intToByteArray(iteration)); } catch (NoSuchAlgorithmException | java.security.InvalidKeyException e) { throw new AssertionError(e); } } }