284 lines
8.9 KiB
JavaScript
284 lines
8.9 KiB
JavaScript
/**
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* A Javascript implementation of AES Cipher Suites for TLS.
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*
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* @author Dave Longley
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*
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* Copyright (c) 2009-2015 Digital Bazaar, Inc.
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*
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*/
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var forge = require('./forge');
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require('./aes');
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require('./tls');
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var tls = module.exports = forge.tls;
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/**
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* Supported cipher suites.
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*/
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tls.CipherSuites['TLS_RSA_WITH_AES_128_CBC_SHA'] = {
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id: [0x00,0x2f],
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name: 'TLS_RSA_WITH_AES_128_CBC_SHA',
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initSecurityParameters: function(sp) {
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sp.bulk_cipher_algorithm = tls.BulkCipherAlgorithm.aes;
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sp.cipher_type = tls.CipherType.block;
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sp.enc_key_length = 16;
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sp.block_length = 16;
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sp.fixed_iv_length = 16;
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sp.record_iv_length = 16;
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sp.mac_algorithm = tls.MACAlgorithm.hmac_sha1;
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sp.mac_length = 20;
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sp.mac_key_length = 20;
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},
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initConnectionState: initConnectionState
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};
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tls.CipherSuites['TLS_RSA_WITH_AES_256_CBC_SHA'] = {
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id: [0x00,0x35],
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name: 'TLS_RSA_WITH_AES_256_CBC_SHA',
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initSecurityParameters: function(sp) {
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sp.bulk_cipher_algorithm = tls.BulkCipherAlgorithm.aes;
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sp.cipher_type = tls.CipherType.block;
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sp.enc_key_length = 32;
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sp.block_length = 16;
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sp.fixed_iv_length = 16;
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sp.record_iv_length = 16;
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sp.mac_algorithm = tls.MACAlgorithm.hmac_sha1;
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sp.mac_length = 20;
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sp.mac_key_length = 20;
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},
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initConnectionState: initConnectionState
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};
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function initConnectionState(state, c, sp) {
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var client = (c.entity === forge.tls.ConnectionEnd.client);
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// cipher setup
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state.read.cipherState = {
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init: false,
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cipher: forge.cipher.createDecipher('AES-CBC', client ?
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sp.keys.server_write_key : sp.keys.client_write_key),
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iv: client ? sp.keys.server_write_IV : sp.keys.client_write_IV
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};
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state.write.cipherState = {
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init: false,
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cipher: forge.cipher.createCipher('AES-CBC', client ?
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sp.keys.client_write_key : sp.keys.server_write_key),
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iv: client ? sp.keys.client_write_IV : sp.keys.server_write_IV
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};
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state.read.cipherFunction = decrypt_aes_cbc_sha1;
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state.write.cipherFunction = encrypt_aes_cbc_sha1;
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// MAC setup
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state.read.macLength = state.write.macLength = sp.mac_length;
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state.read.macFunction = state.write.macFunction = tls.hmac_sha1;
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}
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/**
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* Encrypts the TLSCompressed record into a TLSCipherText record using AES
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* in CBC mode.
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*
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* @param record the TLSCompressed record to encrypt.
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* @param s the ConnectionState to use.
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*
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* @return true on success, false on failure.
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*/
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function encrypt_aes_cbc_sha1(record, s) {
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var rval = false;
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// append MAC to fragment, update sequence number
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var mac = s.macFunction(s.macKey, s.sequenceNumber, record);
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record.fragment.putBytes(mac);
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s.updateSequenceNumber();
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// TLS 1.1+ use an explicit IV every time to protect against CBC attacks
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var iv;
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if(record.version.minor === tls.Versions.TLS_1_0.minor) {
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// use the pre-generated IV when initializing for TLS 1.0, otherwise use
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// the residue from the previous encryption
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iv = s.cipherState.init ? null : s.cipherState.iv;
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} else {
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iv = forge.random.getBytesSync(16);
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}
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s.cipherState.init = true;
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// start cipher
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var cipher = s.cipherState.cipher;
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cipher.start({iv: iv});
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// TLS 1.1+ write IV into output
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if(record.version.minor >= tls.Versions.TLS_1_1.minor) {
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cipher.output.putBytes(iv);
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}
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// do encryption (default padding is appropriate)
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cipher.update(record.fragment);
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if(cipher.finish(encrypt_aes_cbc_sha1_padding)) {
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// set record fragment to encrypted output
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record.fragment = cipher.output;
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record.length = record.fragment.length();
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rval = true;
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}
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return rval;
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}
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/**
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* Handles padding for aes_cbc_sha1 in encrypt mode.
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*
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* @param blockSize the block size.
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* @param input the input buffer.
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* @param decrypt true in decrypt mode, false in encrypt mode.
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*
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* @return true on success, false on failure.
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*/
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function encrypt_aes_cbc_sha1_padding(blockSize, input, decrypt) {
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/* The encrypted data length (TLSCiphertext.length) is one more than the sum
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of SecurityParameters.block_length, TLSCompressed.length,
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SecurityParameters.mac_length, and padding_length.
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The padding may be any length up to 255 bytes long, as long as it results in
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the TLSCiphertext.length being an integral multiple of the block length.
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Lengths longer than necessary might be desirable to frustrate attacks on a
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protocol based on analysis of the lengths of exchanged messages. Each uint8
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in the padding data vector must be filled with the padding length value.
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The padding length should be such that the total size of the
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GenericBlockCipher structure is a multiple of the cipher's block length.
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Legal values range from zero to 255, inclusive. This length specifies the
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length of the padding field exclusive of the padding_length field itself.
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This is slightly different from PKCS#7 because the padding value is 1
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less than the actual number of padding bytes if you include the
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padding_length uint8 itself as a padding byte. */
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if(!decrypt) {
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// get the number of padding bytes required to reach the blockSize and
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// subtract 1 for the padding value (to make room for the padding_length
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// uint8)
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var padding = blockSize - (input.length() % blockSize);
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input.fillWithByte(padding - 1, padding);
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}
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return true;
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}
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/**
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* Handles padding for aes_cbc_sha1 in decrypt mode.
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*
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* @param blockSize the block size.
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* @param output the output buffer.
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* @param decrypt true in decrypt mode, false in encrypt mode.
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*
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* @return true on success, false on failure.
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*/
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function decrypt_aes_cbc_sha1_padding(blockSize, output, decrypt) {
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var rval = true;
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if(decrypt) {
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/* The last byte in the output specifies the number of padding bytes not
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including itself. Each of the padding bytes has the same value as that
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last byte (known as the padding_length). Here we check all padding
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bytes to ensure they have the value of padding_length even if one of
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them is bad in order to ward-off timing attacks. */
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var len = output.length();
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var paddingLength = output.last();
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for(var i = len - 1 - paddingLength; i < len - 1; ++i) {
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rval = rval && (output.at(i) == paddingLength);
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}
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if(rval) {
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// trim off padding bytes and last padding length byte
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output.truncate(paddingLength + 1);
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}
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}
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return rval;
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}
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/**
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* Decrypts a TLSCipherText record into a TLSCompressed record using
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* AES in CBC mode.
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*
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* @param record the TLSCipherText record to decrypt.
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* @param s the ConnectionState to use.
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*
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* @return true on success, false on failure.
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*/
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var count = 0;
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function decrypt_aes_cbc_sha1(record, s) {
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var rval = false;
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++count;
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var iv;
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if(record.version.minor === tls.Versions.TLS_1_0.minor) {
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// use pre-generated IV when initializing for TLS 1.0, otherwise use the
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// residue from the previous decryption
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iv = s.cipherState.init ? null : s.cipherState.iv;
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} else {
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// TLS 1.1+ use an explicit IV every time to protect against CBC attacks
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// that is appended to the record fragment
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iv = record.fragment.getBytes(16);
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}
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s.cipherState.init = true;
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// start cipher
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var cipher = s.cipherState.cipher;
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cipher.start({iv: iv});
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// do decryption
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cipher.update(record.fragment);
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rval = cipher.finish(decrypt_aes_cbc_sha1_padding);
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// even if decryption fails, keep going to minimize timing attacks
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// decrypted data:
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// first (len - 20) bytes = application data
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// last 20 bytes = MAC
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var macLen = s.macLength;
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// create a random MAC to check against should the mac length check fail
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// Note: do this regardless of the failure to keep timing consistent
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var mac = forge.random.getBytesSync(macLen);
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// get fragment and mac
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var len = cipher.output.length();
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if(len >= macLen) {
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record.fragment = cipher.output.getBytes(len - macLen);
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mac = cipher.output.getBytes(macLen);
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} else {
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// bad data, but get bytes anyway to try to keep timing consistent
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record.fragment = cipher.output.getBytes();
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}
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record.fragment = forge.util.createBuffer(record.fragment);
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record.length = record.fragment.length();
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// see if data integrity checks out, update sequence number
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var mac2 = s.macFunction(s.macKey, s.sequenceNumber, record);
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s.updateSequenceNumber();
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rval = compareMacs(s.macKey, mac, mac2) && rval;
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return rval;
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}
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/**
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* Safely compare two MACs. This function will compare two MACs in a way
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* that protects against timing attacks.
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*
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* TODO: Expose elsewhere as a utility API.
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*
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* See: https://www.nccgroup.trust/us/about-us/newsroom-and-events/blog/2011/february/double-hmac-verification/
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*
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* @param key the MAC key to use.
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* @param mac1 as a binary-encoded string of bytes.
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* @param mac2 as a binary-encoded string of bytes.
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*
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* @return true if the MACs are the same, false if not.
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*/
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function compareMacs(key, mac1, mac2) {
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var hmac = forge.hmac.create();
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hmac.start('SHA1', key);
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hmac.update(mac1);
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mac1 = hmac.digest().getBytes();
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hmac.start(null, null);
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hmac.update(mac2);
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mac2 = hmac.digest().getBytes();
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return mac1 === mac2;
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}
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