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209 lines
5.9 KiB
JavaScript
209 lines
5.9 KiB
JavaScript
/** @fileOverview Low-level AES implementation.
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*
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* This file contains a low-level implementation of AES, optimized for
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* size and for efficiency on several browsers. It is based on
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* OpenSSL's aes_core.c, a public-domain implementation by Vincent
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* Rijmen, Antoon Bosselaers and Paulo Barreto.
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*
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* An older version of this implementation is available in the public
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* domain, but this one is (c) Emily Stark, Mike Hamburg, Dan Boneh,
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* Stanford University 2008-2010 and BSD-licensed for liability
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* reasons.
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*
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* @author Emily Stark
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* @author Mike Hamburg
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* @author Dan Boneh
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*/
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/**
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* Schedule out an AES key for both encryption and decryption. This
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* is a low-level class. Use a cipher mode to do bulk encryption.
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*
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* @constructor
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* @param {Array} key The key as an array of 4, 6 or 8 words.
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*
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* @class Advanced Encryption Standard (low-level interface)
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*/
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sjcl.cipher.aes = function (key) {
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if (!this._tables[0][0][0]) {
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this._precompute();
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}
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var i, j, tmp,
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encKey, decKey,
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sbox = this._tables[0][4], decTable = this._tables[1],
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keyLen = key.length, rcon = 1;
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if (keyLen !== 4 && keyLen !== 6 && keyLen !== 8) {
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throw new sjcl.exception.invalid("invalid aes key size");
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}
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this._key = [encKey = key.slice(0), decKey = []];
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// schedule encryption keys
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for (i = keyLen; i < 4 * keyLen + 28; i++) {
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tmp = encKey[i-1];
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// apply sbox
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if (i%keyLen === 0 || (keyLen === 8 && i%keyLen === 4)) {
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tmp = sbox[tmp>>>24]<<24 ^ sbox[tmp>>16&255]<<16 ^ sbox[tmp>>8&255]<<8 ^ sbox[tmp&255];
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// shift rows and add rcon
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if (i%keyLen === 0) {
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tmp = tmp<<8 ^ tmp>>>24 ^ rcon<<24;
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rcon = rcon<<1 ^ (rcon>>7)*283;
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}
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}
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encKey[i] = encKey[i-keyLen] ^ tmp;
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}
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// schedule decryption keys
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for (j = 0; i; j++, i--) {
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tmp = encKey[j&3 ? i : i - 4];
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if (i<=4 || j<4) {
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decKey[j] = tmp;
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} else {
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decKey[j] = decTable[0][sbox[tmp>>>24 ]] ^
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decTable[1][sbox[tmp>>16 & 255]] ^
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decTable[2][sbox[tmp>>8 & 255]] ^
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decTable[3][sbox[tmp & 255]];
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}
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}
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};
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sjcl.cipher.aes.prototype = {
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// public
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/* Something like this might appear here eventually
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name: "AES",
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blockSize: 4,
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keySizes: [4,6,8],
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*/
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/**
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* Encrypt an array of 4 big-endian words.
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* @param {Array} data The plaintext.
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* @return {Array} The ciphertext.
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*/
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encrypt:function (data) { return this._crypt(data,0); },
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/**
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* Decrypt an array of 4 big-endian words.
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* @param {Array} data The ciphertext.
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* @return {Array} The plaintext.
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*/
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decrypt:function (data) { return this._crypt(data,1); },
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/**
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* The expanded S-box and inverse S-box tables. These will be computed
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* on the client so that we don't have to send them down the wire.
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*
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* There are two tables, _tables[0] is for encryption and
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* _tables[1] is for decryption.
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*
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* The first 4 sub-tables are the expanded S-box with MixColumns. The
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* last (_tables[01][4]) is the S-box itself.
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*
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* @private
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*/
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_tables: [[[],[],[],[],[]],[[],[],[],[],[]]],
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/**
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* Expand the S-box tables.
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*
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* @private
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*/
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_precompute: function () {
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var encTable = this._tables[0], decTable = this._tables[1],
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sbox = encTable[4], sboxInv = decTable[4],
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i, x, xInv, d=[], th=[], x2, x4, x8, s, tEnc, tDec;
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// Compute double and third tables
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for (i = 0; i < 256; i++) {
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th[( d[i] = i<<1 ^ (i>>7)*283 )^i]=i;
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}
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for (x = xInv = 0; !sbox[x]; x ^= x2 || 1, xInv = th[xInv] || 1) {
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// Compute sbox
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s = xInv ^ xInv<<1 ^ xInv<<2 ^ xInv<<3 ^ xInv<<4;
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s = s>>8 ^ s&255 ^ 99;
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sbox[x] = s;
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sboxInv[s] = x;
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// Compute MixColumns
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x8 = d[x4 = d[x2 = d[x]]];
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tDec = x8*0x1010101 ^ x4*0x10001 ^ x2*0x101 ^ x*0x1010100;
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tEnc = d[s]*0x101 ^ s*0x1010100;
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for (i = 0; i < 4; i++) {
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encTable[i][x] = tEnc = tEnc<<24 ^ tEnc>>>8;
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decTable[i][s] = tDec = tDec<<24 ^ tDec>>>8;
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}
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}
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// Compactify. Considerable speedup on Firefox.
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for (i = 0; i < 5; i++) {
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encTable[i] = encTable[i].slice(0);
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decTable[i] = decTable[i].slice(0);
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}
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},
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/**
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* Encryption and decryption core.
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* @param {Array} input Four words to be encrypted or decrypted.
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* @param dir The direction, 0 for encrypt and 1 for decrypt.
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* @return {Array} The four encrypted or decrypted words.
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* @private
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*/
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_crypt:function (input, dir) {
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if (input.length !== 4) {
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throw new sjcl.exception.invalid("invalid aes block size");
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}
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var key = this._key[dir],
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// state variables a,b,c,d are loaded with pre-whitened data
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a = input[0] ^ key[0],
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b = input[dir ? 3 : 1] ^ key[1],
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c = input[2] ^ key[2],
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d = input[dir ? 1 : 3] ^ key[3],
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a2, b2, c2,
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nInnerRounds = key.length/4 - 2,
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i,
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kIndex = 4,
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out = [0,0,0,0],
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table = this._tables[dir],
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// load up the tables
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t0 = table[0],
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t1 = table[1],
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t2 = table[2],
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t3 = table[3],
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sbox = table[4];
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// Inner rounds. Cribbed from OpenSSL.
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for (i = 0; i < nInnerRounds; i++) {
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a2 = t0[a>>>24] ^ t1[b>>16 & 255] ^ t2[c>>8 & 255] ^ t3[d & 255] ^ key[kIndex];
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b2 = t0[b>>>24] ^ t1[c>>16 & 255] ^ t2[d>>8 & 255] ^ t3[a & 255] ^ key[kIndex + 1];
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c2 = t0[c>>>24] ^ t1[d>>16 & 255] ^ t2[a>>8 & 255] ^ t3[b & 255] ^ key[kIndex + 2];
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d = t0[d>>>24] ^ t1[a>>16 & 255] ^ t2[b>>8 & 255] ^ t3[c & 255] ^ key[kIndex + 3];
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kIndex += 4;
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a=a2; b=b2; c=c2;
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}
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// Last round.
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for (i = 0; i < 4; i++) {
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out[dir ? 3&-i : i] =
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sbox[a>>>24 ]<<24 ^
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sbox[b>>16 & 255]<<16 ^
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sbox[c>>8 & 255]<<8 ^
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sbox[d & 255] ^
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key[kIndex++];
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a2=a; a=b; b=c; c=d; d=a2;
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}
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return out;
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}
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};
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