e44a7e37b6
git-svn-id: https://semanticscuttle.svn.sourceforge.net/svnroot/semanticscuttle/trunk@151 b3834d28-1941-0410-a4f8-b48e95affb8f
443 lines
17 KiB
JavaScript
443 lines
17 KiB
JavaScript
if(!dojo._hasResource["dojox._sql._crypto"]){ //_hasResource checks added by build. Do not use _hasResource directly in your code.
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dojo._hasResource["dojox._sql._crypto"] = true;
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// Taken from http://www.movable-type.co.uk/scripts/aes.html by
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// Chris Veness (CLA signed); adapted for Dojo and Google Gears Worker Pool
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// by Brad Neuberg, bkn3@columbia.edu
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dojo.provide("dojox._sql._crypto");
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dojo.mixin(dojox._sql._crypto,{
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// _POOL_SIZE:
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// Size of worker pool to create to help with crypto
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_POOL_SIZE: 100,
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encrypt: function(plaintext, password, callback){
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// summary:
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// Use Corrected Block TEA to encrypt plaintext using password
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// (note plaintext & password must be strings not string objects).
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// Results will be returned to the 'callback' asychronously.
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this._initWorkerPool();
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var msg ={plaintext: plaintext, password: password};
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msg = dojo.toJson(msg);
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msg = "encr:" + String(msg);
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this._assignWork(msg, callback);
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},
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decrypt: function(ciphertext, password, callback){
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// summary:
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// Use Corrected Block TEA to decrypt ciphertext using password
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// (note ciphertext & password must be strings not string objects).
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// Results will be returned to the 'callback' asychronously.
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this._initWorkerPool();
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var msg ={ciphertext: ciphertext, password: password};
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msg = dojo.toJson(msg);
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msg = "decr:" + String(msg);
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this._assignWork(msg, callback);
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},
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_initWorkerPool: function(){
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// bugs in Google Gears prevents us from dynamically creating
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// and destroying workers as we need them -- the worker
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// pool functionality stops working after a number of crypto
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// cycles (probably related to a memory leak in Google Gears).
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// this is too bad, since it results in much simpler code.
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// instead, we have to create a pool of workers and reuse them. we
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// keep a stack of 'unemployed' Worker IDs that are currently not working.
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// if a work request comes in, we pop off the 'unemployed' stack
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// and put them to work, storing them in an 'employed' hashtable,
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// keyed by their Worker ID with the value being the callback function
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// that wants the result. when an employed worker is done, we get
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// a message in our 'manager' which adds this worker back to the
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// unemployed stack and routes the result to the callback that
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// wanted it. if all the workers were employed in the past but
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// more work needed to be done (i.e. it's a tight labor pool ;)
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// then the work messages are pushed onto
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// a 'handleMessage' queue as an object tuple{msg: msg, callback: callback}
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if(!this._manager){
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try{
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this._manager = google.gears.factory.create("beta.workerpool", "1.0");
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this._unemployed = [];
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this._employed ={};
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this._handleMessage = [];
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var self = this;
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this._manager.onmessage = function(msg, sender){
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// get the callback necessary to serve this result
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var callback = self._employed["_" + sender];
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// make this worker unemployed
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self._employed["_" + sender] = undefined;
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self._unemployed.push("_" + sender);
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// see if we need to assign new work
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// that was queued up needing to be done
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if(self._handleMessage.length){
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var handleMe = self._handleMessage.shift();
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self._assignWork(handleMe.msg, handleMe.callback);
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}
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// return results
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callback(msg);
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}
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var workerInit = "function _workerInit(){"
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+ "gearsWorkerPool.onmessage = "
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+ String(this._workerHandler)
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+ ";"
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+ "}";
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var code = workerInit + " _workerInit();";
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// create our worker pool
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for(var i = 0; i < this._POOL_SIZE; i++){
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this._unemployed.push("_" + this._manager.createWorker(code));
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}
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}catch(exp){
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throw exp.message||exp;
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}
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}
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},
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_assignWork: function(msg, callback){
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// can we immediately assign this work?
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if(!this._handleMessage.length && this._unemployed.length){
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// get an unemployed worker
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var workerID = this._unemployed.shift().substring(1); // remove _
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// list this worker as employed
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this._employed["_" + workerID] = callback;
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// do the worke
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this._manager.sendMessage(msg, workerID);
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}else{
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// we have to queue it up
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this._handleMessage ={msg: msg, callback: callback};
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}
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},
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_workerHandler: function(msg, sender){
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/* Begin AES Implementation */
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/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */
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// Sbox is pre-computed multiplicative inverse in GF(2^8) used in SubBytes and KeyExpansion [§5.1.1]
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var Sbox = [0x63,0x7c,0x77,0x7b,0xf2,0x6b,0x6f,0xc5,0x30,0x01,0x67,0x2b,0xfe,0xd7,0xab,0x76,
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0xca,0x82,0xc9,0x7d,0xfa,0x59,0x47,0xf0,0xad,0xd4,0xa2,0xaf,0x9c,0xa4,0x72,0xc0,
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0xb7,0xfd,0x93,0x26,0x36,0x3f,0xf7,0xcc,0x34,0xa5,0xe5,0xf1,0x71,0xd8,0x31,0x15,
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0x04,0xc7,0x23,0xc3,0x18,0x96,0x05,0x9a,0x07,0x12,0x80,0xe2,0xeb,0x27,0xb2,0x75,
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0x09,0x83,0x2c,0x1a,0x1b,0x6e,0x5a,0xa0,0x52,0x3b,0xd6,0xb3,0x29,0xe3,0x2f,0x84,
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0x53,0xd1,0x00,0xed,0x20,0xfc,0xb1,0x5b,0x6a,0xcb,0xbe,0x39,0x4a,0x4c,0x58,0xcf,
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0xd0,0xef,0xaa,0xfb,0x43,0x4d,0x33,0x85,0x45,0xf9,0x02,0x7f,0x50,0x3c,0x9f,0xa8,
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0x51,0xa3,0x40,0x8f,0x92,0x9d,0x38,0xf5,0xbc,0xb6,0xda,0x21,0x10,0xff,0xf3,0xd2,
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0xcd,0x0c,0x13,0xec,0x5f,0x97,0x44,0x17,0xc4,0xa7,0x7e,0x3d,0x64,0x5d,0x19,0x73,
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0x60,0x81,0x4f,0xdc,0x22,0x2a,0x90,0x88,0x46,0xee,0xb8,0x14,0xde,0x5e,0x0b,0xdb,
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0xe0,0x32,0x3a,0x0a,0x49,0x06,0x24,0x5c,0xc2,0xd3,0xac,0x62,0x91,0x95,0xe4,0x79,
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0xe7,0xc8,0x37,0x6d,0x8d,0xd5,0x4e,0xa9,0x6c,0x56,0xf4,0xea,0x65,0x7a,0xae,0x08,
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0xba,0x78,0x25,0x2e,0x1c,0xa6,0xb4,0xc6,0xe8,0xdd,0x74,0x1f,0x4b,0xbd,0x8b,0x8a,
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0x70,0x3e,0xb5,0x66,0x48,0x03,0xf6,0x0e,0x61,0x35,0x57,0xb9,0x86,0xc1,0x1d,0x9e,
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0xe1,0xf8,0x98,0x11,0x69,0xd9,0x8e,0x94,0x9b,0x1e,0x87,0xe9,0xce,0x55,0x28,0xdf,
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0x8c,0xa1,0x89,0x0d,0xbf,0xe6,0x42,0x68,0x41,0x99,0x2d,0x0f,0xb0,0x54,0xbb,0x16];
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// Rcon is Round Constant used for the Key Expansion [1st col is 2^(r-1) in GF(2^8)] [§5.2]
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var Rcon = [ [0x00, 0x00, 0x00, 0x00],
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[0x01, 0x00, 0x00, 0x00],
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[0x02, 0x00, 0x00, 0x00],
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[0x04, 0x00, 0x00, 0x00],
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[0x08, 0x00, 0x00, 0x00],
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[0x10, 0x00, 0x00, 0x00],
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[0x20, 0x00, 0x00, 0x00],
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[0x40, 0x00, 0x00, 0x00],
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[0x80, 0x00, 0x00, 0x00],
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[0x1b, 0x00, 0x00, 0x00],
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[0x36, 0x00, 0x00, 0x00] ];
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/*
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* AES Cipher function: encrypt 'input' with Rijndael algorithm
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*
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* takes byte-array 'input' (16 bytes)
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* 2D byte-array key schedule 'w' (Nr+1 x Nb bytes)
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*
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* applies Nr rounds (10/12/14) using key schedule w for 'add round key' stage
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*
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* returns byte-array encrypted value (16 bytes)
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*/
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function Cipher(input, w) { // main Cipher function [§5.1]
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var Nb = 4; // block size (in words): no of columns in state (fixed at 4 for AES)
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var Nr = w.length/Nb - 1; // no of rounds: 10/12/14 for 128/192/256-bit keys
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var state = [[],[],[],[]]; // initialise 4xNb byte-array 'state' with input [§3.4]
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for (var i=0; i<4*Nb; i++) state[i%4][Math.floor(i/4)] = input[i];
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state = AddRoundKey(state, w, 0, Nb);
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for (var round=1; round<Nr; round++) {
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state = SubBytes(state, Nb);
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state = ShiftRows(state, Nb);
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state = MixColumns(state, Nb);
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state = AddRoundKey(state, w, round, Nb);
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}
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state = SubBytes(state, Nb);
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state = ShiftRows(state, Nb);
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state = AddRoundKey(state, w, Nr, Nb);
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var output = new Array(4*Nb); // convert state to 1-d array before returning [§3.4]
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for (var i=0; i<4*Nb; i++) output[i] = state[i%4][Math.floor(i/4)];
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return output;
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}
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function SubBytes(s, Nb) { // apply SBox to state S [§5.1.1]
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for (var r=0; r<4; r++) {
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for (var c=0; c<Nb; c++) s[r][c] = Sbox[s[r][c]];
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}
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return s;
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}
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function ShiftRows(s, Nb) { // shift row r of state S left by r bytes [§5.1.2]
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var t = new Array(4);
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for (var r=1; r<4; r++) {
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for (var c=0; c<4; c++) t[c] = s[r][(c+r)%Nb]; // shift into temp copy
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for (var c=0; c<4; c++) s[r][c] = t[c]; // and copy back
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} // note that this will work for Nb=4,5,6, but not 7,8 (always 4 for AES):
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return s; // see fp.gladman.plus.com/cryptography_technology/rijndael/aes.spec.311.pdf
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}
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function MixColumns(s, Nb) { // combine bytes of each col of state S [§5.1.3]
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for (var c=0; c<4; c++) {
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var a = new Array(4); // 'a' is a copy of the current column from 's'
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var b = new Array(4); // 'b' is a•{02} in GF(2^8)
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for (var i=0; i<4; i++) {
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a[i] = s[i][c];
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b[i] = s[i][c]&0x80 ? s[i][c]<<1 ^ 0x011b : s[i][c]<<1;
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}
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// a[n] ^ b[n] is a•{03} in GF(2^8)
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s[0][c] = b[0] ^ a[1] ^ b[1] ^ a[2] ^ a[3]; // 2*a0 + 3*a1 + a2 + a3
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s[1][c] = a[0] ^ b[1] ^ a[2] ^ b[2] ^ a[3]; // a0 * 2*a1 + 3*a2 + a3
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s[2][c] = a[0] ^ a[1] ^ b[2] ^ a[3] ^ b[3]; // a0 + a1 + 2*a2 + 3*a3
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s[3][c] = a[0] ^ b[0] ^ a[1] ^ a[2] ^ b[3]; // 3*a0 + a1 + a2 + 2*a3
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}
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return s;
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}
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function AddRoundKey(state, w, rnd, Nb) { // xor Round Key into state S [§5.1.4]
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for (var r=0; r<4; r++) {
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for (var c=0; c<Nb; c++) state[r][c] ^= w[rnd*4+c][r];
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}
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return state;
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}
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function KeyExpansion(key) { // generate Key Schedule (byte-array Nr+1 x Nb) from Key [§5.2]
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var Nb = 4; // block size (in words): no of columns in state (fixed at 4 for AES)
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var Nk = key.length/4 // key length (in words): 4/6/8 for 128/192/256-bit keys
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var Nr = Nk + 6; // no of rounds: 10/12/14 for 128/192/256-bit keys
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var w = new Array(Nb*(Nr+1));
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var temp = new Array(4);
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for (var i=0; i<Nk; i++) {
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var r = [key[4*i], key[4*i+1], key[4*i+2], key[4*i+3]];
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w[i] = r;
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}
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for (var i=Nk; i<(Nb*(Nr+1)); i++) {
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w[i] = new Array(4);
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for (var t=0; t<4; t++) temp[t] = w[i-1][t];
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if (i % Nk == 0) {
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temp = SubWord(RotWord(temp));
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for (var t=0; t<4; t++) temp[t] ^= Rcon[i/Nk][t];
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} else if (Nk > 6 && i%Nk == 4) {
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temp = SubWord(temp);
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}
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for (var t=0; t<4; t++) w[i][t] = w[i-Nk][t] ^ temp[t];
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}
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return w;
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}
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function SubWord(w) { // apply SBox to 4-byte word w
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for (var i=0; i<4; i++) w[i] = Sbox[w[i]];
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return w;
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}
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function RotWord(w) { // rotate 4-byte word w left by one byte
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w[4] = w[0];
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for (var i=0; i<4; i++) w[i] = w[i+1];
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return w;
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}
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/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */
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/*
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* Use AES to encrypt 'plaintext' with 'password' using 'nBits' key, in 'Counter' mode of operation
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* - see http://csrc.nist.gov/publications/nistpubs/800-38a/sp800-38a.pdf
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* for each block
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* - outputblock = cipher(counter, key)
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* - cipherblock = plaintext xor outputblock
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*/
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function AESEncryptCtr(plaintext, password, nBits) {
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if (!(nBits==128 || nBits==192 || nBits==256)) return ''; // standard allows 128/192/256 bit keys
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// for this example script, generate the key by applying Cipher to 1st 16/24/32 chars of password;
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// for real-world applications, a more secure approach would be to hash the password e.g. with SHA-1
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var nBytes = nBits/8; // no bytes in key
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var pwBytes = new Array(nBytes);
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for (var i=0; i<nBytes; i++) pwBytes[i] = password.charCodeAt(i) & 0xff;
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var key = Cipher(pwBytes, KeyExpansion(pwBytes));
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key = key.concat(key.slice(0, nBytes-16)); // key is now 16/24/32 bytes long
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// initialise counter block (NIST SP800-38A §B.2): millisecond time-stamp for nonce in 1st 8 bytes,
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// block counter in 2nd 8 bytes
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var blockSize = 16; // block size fixed at 16 bytes / 128 bits (Nb=4) for AES
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var counterBlock = new Array(blockSize); // block size fixed at 16 bytes / 128 bits (Nb=4) for AES
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var nonce = (new Date()).getTime(); // milliseconds since 1-Jan-1970
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// encode nonce in two stages to cater for JavaScript 32-bit limit on bitwise ops
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for (var i=0; i<4; i++) counterBlock[i] = (nonce >>> i*8) & 0xff;
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for (var i=0; i<4; i++) counterBlock[i+4] = (nonce/0x100000000 >>> i*8) & 0xff;
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// generate key schedule - an expansion of the key into distinct Key Rounds for each round
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var keySchedule = KeyExpansion(key);
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var blockCount = Math.ceil(plaintext.length/blockSize);
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var ciphertext = new Array(blockCount); // ciphertext as array of strings
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for (var b=0; b<blockCount; b++) {
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// set counter (block #) in last 8 bytes of counter block (leaving nonce in 1st 8 bytes)
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// again done in two stages for 32-bit ops
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for (var c=0; c<4; c++) counterBlock[15-c] = (b >>> c*8) & 0xff;
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for (var c=0; c<4; c++) counterBlock[15-c-4] = (b/0x100000000 >>> c*8)
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var cipherCntr = Cipher(counterBlock, keySchedule); // -- encrypt counter block --
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// calculate length of final block:
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var blockLength = b<blockCount-1 ? blockSize : (plaintext.length-1)%blockSize+1;
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var ct = '';
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for (var i=0; i<blockLength; i++) { // -- xor plaintext with ciphered counter byte-by-byte --
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var plaintextByte = plaintext.charCodeAt(b*blockSize+i);
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var cipherByte = plaintextByte ^ cipherCntr[i];
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ct += String.fromCharCode(cipherByte);
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}
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// ct is now ciphertext for this block
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ciphertext[b] = escCtrlChars(ct); // escape troublesome characters in ciphertext
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}
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// convert the nonce to a string to go on the front of the ciphertext
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var ctrTxt = '';
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for (var i=0; i<8; i++) ctrTxt += String.fromCharCode(counterBlock[i]);
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ctrTxt = escCtrlChars(ctrTxt);
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// use '-' to separate blocks, use Array.join to concatenate arrays of strings for efficiency
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return ctrTxt + '-' + ciphertext.join('-');
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}
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/*
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* Use AES to decrypt 'ciphertext' with 'password' using 'nBits' key, in Counter mode of operation
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*
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* for each block
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* - outputblock = cipher(counter, key)
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* - cipherblock = plaintext xor outputblock
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*/
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function AESDecryptCtr(ciphertext, password, nBits) {
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if (!(nBits==128 || nBits==192 || nBits==256)) return ''; // standard allows 128/192/256 bit keys
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var nBytes = nBits/8; // no bytes in key
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var pwBytes = new Array(nBytes);
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for (var i=0; i<nBytes; i++) pwBytes[i] = password.charCodeAt(i) & 0xff;
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var pwKeySchedule = KeyExpansion(pwBytes);
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var key = Cipher(pwBytes, pwKeySchedule);
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key = key.concat(key.slice(0, nBytes-16)); // key is now 16/24/32 bytes long
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var keySchedule = KeyExpansion(key);
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ciphertext = ciphertext.split('-'); // split ciphertext into array of block-length strings
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// recover nonce from 1st element of ciphertext
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var blockSize = 16; // block size fixed at 16 bytes / 128 bits (Nb=4) for AES
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var counterBlock = new Array(blockSize);
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var ctrTxt = unescCtrlChars(ciphertext[0]);
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for (var i=0; i<8; i++) counterBlock[i] = ctrTxt.charCodeAt(i);
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var plaintext = new Array(ciphertext.length-1);
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for (var b=1; b<ciphertext.length; b++) {
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// set counter (block #) in last 8 bytes of counter block (leaving nonce in 1st 8 bytes)
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for (var c=0; c<4; c++) counterBlock[15-c] = ((b-1) >>> c*8) & 0xff;
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for (var c=0; c<4; c++) counterBlock[15-c-4] = ((b/0x100000000-1) >>> c*8) & 0xff;
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var cipherCntr = Cipher(counterBlock, keySchedule); // encrypt counter block
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ciphertext[b] = unescCtrlChars(ciphertext[b]);
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|
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var pt = '';
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for (var i=0; i<ciphertext[b].length; i++) {
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// -- xor plaintext with ciphered counter byte-by-byte --
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var ciphertextByte = ciphertext[b].charCodeAt(i);
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var plaintextByte = ciphertextByte ^ cipherCntr[i];
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pt += String.fromCharCode(plaintextByte);
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}
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// pt is now plaintext for this block
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|
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plaintext[b-1] = pt; // b-1 'cos no initial nonce block in plaintext
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}
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|
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return plaintext.join('');
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}
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|
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/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */
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function escCtrlChars(str) { // escape control chars which might cause problems handling ciphertext
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return str.replace(/[\0\t\n\v\f\r\xa0!-]/g, function(c) { return '!' + c.charCodeAt(0) + '!'; });
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} // \xa0 to cater for bug in Firefox; include '-' to leave it free for use as a block marker
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|
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function unescCtrlChars(str) { // unescape potentially problematic control characters
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return str.replace(/!\d\d?\d?!/g, function(c) { return String.fromCharCode(c.slice(1,-1)); });
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}
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/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */
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|
|
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function encrypt(plaintext, password){
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return AESEncryptCtr(plaintext, password, 256);
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}
|
|
|
|
function decrypt(ciphertext, password){
|
|
return AESDecryptCtr(ciphertext, password, 256);
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}
|
|
|
|
/* End AES Implementation */
|
|
|
|
var cmd = msg.substr(0,4);
|
|
var arg = msg.substr(5);
|
|
if(cmd == "encr"){
|
|
arg = eval("(" + arg + ")");
|
|
var plaintext = arg.plaintext;
|
|
var password = arg.password;
|
|
var results = encrypt(plaintext, password);
|
|
gearsWorkerPool.sendMessage(String(results), sender);
|
|
}else if(cmd == "decr"){
|
|
arg = eval("(" + arg + ")");
|
|
var ciphertext = arg.ciphertext;
|
|
var password = arg.password;
|
|
var results = decrypt(ciphertext, password);
|
|
gearsWorkerPool.sendMessage(String(results), sender);
|
|
}
|
|
}
|
|
});
|
|
|
|
}
|