Datasets:

andy-gg
/

LUAR_RP_PC

	require("bit");

	local gf = require("aeslua.gf");
	local util = require("aeslua.util");

	--
	-- Implementation of AES with nearly pure lua (only bitlib is needed)
	--
	-- AES with lua is slow, really slow :-)
	--

	local public = {};
	local private = {};

	aeslua.aes = public;

	-- some constants
	public.ROUNDS = "rounds";
	public.KEY_TYPE = "type";
	public.ENCRYPTION_KEY=1;
	public.DECRYPTION_KEY=2;

	-- aes SBOX
	private.SBox = {};
	private.iSBox = {};

	-- aes tables
	private.table0 = {};
	private.table1 = {};
	private.table2 = {};
	private.table3 = {};

	private.tableInv0 = {};
	private.tableInv1 = {};
	private.tableInv2 = {};
	private.tableInv3 = {};

	-- round constants
	private.rCon = {0x01000000,
	0x02000000,
	0x04000000,
	0x08000000,
	0x10000000,
	0x20000000,
	0x40000000,
	0x80000000,
	0x1b000000,
	0x36000000,
	0x6c000000,
	0xd8000000,
	0xab000000,
	0x4d000000,
	0x9a000000,
	0x2f000000};

	--
	-- affine transformation for calculating the S-Box of AES
	--
	function private.affinMap(byte)
	mask = 0xf8;
	result = 0;
	for i = 1,8 do
	result = bit.lshift(result,1);

	parity = util.byteParity(bit.band(byte,mask));
	result = result + parity

	-- simulate roll
	lastbit = bit.band(mask, 1);
	mask = bit.band(bit.rshift(mask, 1),0xff);
	if (lastbit ~= 0) then
	mask = bit.bor(mask, 0x80);
	else
	mask = bit.band(mask, 0x7f);
	end
	end

	return bit.bxor(result, 0x63);
	end

	--
	-- calculate S-Box and inverse S-Box of AES
	-- apply affine transformation to inverse in finite field 2^8
	--
	function private.calcSBox()
	for i = 0, 255 do
	if (i ~= 0) then
	inverse = gf.invert(i);
	else
	inverse = i;
	end
	mapped = private.affinMap(inverse);
	private.SBox[i] = mapped;
	private.iSBox[mapped] = i;
	end
	end

	--
	-- Calculate round tables
	-- round tables are used to calculate shiftRow, MixColumn and SubBytes
	-- with 4 table lookups and 4 xor operations.
	--
	function private.calcRoundTables()
	for x = 0,255 do
	byte = private.SBox[x];
	private.table0[x] = util.putByte(gf.mul(0x03, byte), 0)
	+ util.putByte( byte , 1)
	+ util.putByte( byte , 2)
	+ util.putByte(gf.mul(0x02, byte), 3);
	private.table1[x] = util.putByte( byte , 0)
	+ util.putByte( byte , 1)
	+ util.putByte(gf.mul(0x02, byte), 2)
	+ util.putByte(gf.mul(0x03, byte), 3);
	private.table2[x] = util.putByte( byte , 0)
	+ util.putByte(gf.mul(0x02, byte), 1)
	+ util.putByte(gf.mul(0x03, byte), 2)
	+ util.putByte( byte , 3);
	private.table3[x] = util.putByte(gf.mul(0x02, byte), 0)
	+ util.putByte(gf.mul(0x03, byte), 1)
	+ util.putByte( byte , 2)
	+ util.putByte( byte , 3);
	end
	end

	--
	-- Calculate inverse round tables
	-- does the inverse of the normal roundtables for the equivalent
	-- decryption algorithm.
	--
	function private.calcInvRoundTables()
	for x = 0,255 do
	byte = private.iSBox[x];
	private.tableInv0[x] = util.putByte(gf.mul(0x0b, byte), 0)
	+ util.putByte(gf.mul(0x0d, byte), 1)
	+ util.putByte(gf.mul(0x09, byte), 2)
	+ util.putByte(gf.mul(0x0e, byte), 3);
	private.tableInv1[x] = util.putByte(gf.mul(0x0d, byte), 0)
	+ util.putByte(gf.mul(0x09, byte), 1)
	+ util.putByte(gf.mul(0x0e, byte), 2)
	+ util.putByte(gf.mul(0x0b, byte), 3);
	private.tableInv2[x] = util.putByte(gf.mul(0x09, byte), 0)
	+ util.putByte(gf.mul(0x0e, byte), 1)
	+ util.putByte(gf.mul(0x0b, byte), 2)
	+ util.putByte(gf.mul(0x0d, byte), 3);
	private.tableInv3[x] = util.putByte(gf.mul(0x0e, byte), 0)
	+ util.putByte(gf.mul(0x0b, byte), 1)
	+ util.putByte(gf.mul(0x0d, byte), 2)
	+ util.putByte(gf.mul(0x09, byte), 3);
	end
	end


	--
	-- rotate word: 0xaabbccdd gets 0xbbccddaa
	-- used for key schedule
	--
	function private.rotWord(word)
	local tmp = bit.band(word,0xff000000);
	return (bit.lshift(word,8) + bit.rshift(tmp,24)) ;
	end

	--
	-- replace all bytes in a word with the SBox.
	-- used for key schedule
	--
	function private.subWord(word)
	return util.putByte(private.SBox[util.getByte(word,0)],0)
	+ util.putByte(private.SBox[util.getByte(word,1)],1)
	+ util.putByte(private.SBox[util.getByte(word,2)],2)
	+ util.putByte(private.SBox[util.getByte(word,3)],3);
	end

	--
	-- generate key schedule for aes encryption
	--
	-- returns table with all round keys and
	-- the necessary number of rounds saved in [public.ROUNDS]
	--
	function public.expandEncryptionKey(key)
	local keySchedule = {};
	local keyWords = math.floor(#key / 4);


	if ((keyWords ~= 4 and keyWords ~= 6 and keyWords ~= 8) or (keyWords * 4 ~= #key)) then
	print("Invalid key size: ", keyWords);
	return nil;
	end

	keySchedule[public.ROUNDS] = keyWords + 6;
	keySchedule[public.KEY_TYPE] = public.ENCRYPTION_KEY;

	for i = 0,keyWords - 1 do
	keySchedule[i] = util.putByte(key[i*4+1], 3)
	+ util.putByte(key[i*4+2], 2)
	+ util.putByte(key[i*4+3], 1)
	+ util.putByte(key[i*4+4], 0);
	end

	for i = keyWords, (keySchedule[public.ROUNDS] + 1)*4 - 1 do
	local tmp = keySchedule[i-1];

	if ( i % keyWords == 0) then
	tmp = private.rotWord(tmp);
	tmp = private.subWord(tmp);

	local index = math.floor(i/keyWords);
	tmp = bit.bxor(tmp,private.rCon[index]);
	elseif (keyWords > 6 and i % keyWords == 4) then
	tmp = private.subWord(tmp);
	end

	keySchedule[i] = bit.bxor(keySchedule[(i-keyWords)],tmp);
	end

	return keySchedule;
	end

	--
	-- Inverse mix column
	-- used for key schedule of decryption key
	--
	function private.invMixColumnOld(word)
	local b0 = util.getByte(word,3);
	local b1 = util.getByte(word,2);
	local b2 = util.getByte(word,1);
	local b3 = util.getByte(word,0);

	return util.putByte(gf.add(gf.add(gf.add(gf.mul(0x0b, b1),
	gf.mul(0x0d, b2)),
	gf.mul(0x09, b3)),
	gf.mul(0x0e, b0)),3)
	+ util.putByte(gf.add(gf.add(gf.add(gf.mul(0x0b, b2),
	gf.mul(0x0d, b3)),
	gf.mul(0x09, b0)),
	gf.mul(0x0e, b1)),2)
	+ util.putByte(gf.add(gf.add(gf.add(gf.mul(0x0b, b3),
	gf.mul(0x0d, b0)),
	gf.mul(0x09, b1)),
	gf.mul(0x0e, b2)),1)
	+ util.putByte(gf.add(gf.add(gf.add(gf.mul(0x0b, b0),
	gf.mul(0x0d, b1)),
	gf.mul(0x09, b2)),
	gf.mul(0x0e, b3)),0);
	end

	--
	-- Optimized inverse mix column
	-- look at http://fp.gladman.plus.com/cryptography_technology/rijndael/aes.spec.311.pdf
	-- TODO: make it work
	--
	function private.invMixColumn(word)
	local b0 = util.getByte(word,3);
	local b1 = util.getByte(word,2);
	local b2 = util.getByte(word,1);
	local b3 = util.getByte(word,0);

	local t = bit.bxor(b3,b2);
	local u = bit.bxor(b1,b0);
	local v = bit.bxor(t,u);
	v = bit.bxor(v,gf.mul(0x08,v));
	w = bit.bxor(v,gf.mul(0x04, bit.bxor(b2,b0)));
	v = bit.bxor(v,gf.mul(0x04, bit.bxor(b3,b1)));

	return util.putByte( bit.bxor(bit.bxor(b3,v), gf.mul(0x02, bit.bxor(b0,b3))), 0)
	+ util.putByte( bit.bxor(bit.bxor(b2,w), gf.mul(0x02, t )), 1)
	+ util.putByte( bit.bxor(bit.bxor(b1,v), gf.mul(0x02, bit.bxor(b0,b3))), 2)
	+ util.putByte( bit.bxor(bit.bxor(b0,w), gf.mul(0x02, u )), 3);
	end

	--
	-- generate key schedule for aes decryption
	--
	-- uses key schedule for aes encryption and transforms each
	-- key by inverse mix column.
	--
	function public.expandDecryptionKey(key)
	local keySchedule = public.expandEncryptionKey(key);
	if (keySchedule == nil) then
	return nil;
	end

	keySchedule[public.KEY_TYPE] = public.DECRYPTION_KEY;

	for i = 4, (keySchedule[public.ROUNDS] + 1)*4 - 5 do
	keySchedule[i] = private.invMixColumnOld(keySchedule[i]);
	end

	return keySchedule;
	end

	--
	-- xor round key to state
	--
	function private.addRoundKey(state, key, round)
	for i = 0, 3 do
	state[i] = bit.bxor(state[i], key[round*4+i]);
	end
	end

	--
	-- do encryption round (ShiftRow, SubBytes, MixColumn together)
	--
	function private.doRound(origState, dstState)
	dstState[0] = bit.bxor(bit.bxor(bit.bxor(
	private.table0[util.getByte(origState[0],3)],
	private.table1[util.getByte(origState[1],2)]),
	private.table2[util.getByte(origState[2],1)]),
	private.table3[util.getByte(origState[3],0)]);

	dstState[1] = bit.bxor(bit.bxor(bit.bxor(
	private.table0[util.getByte(origState[1],3)],
	private.table1[util.getByte(origState[2],2)]),
	private.table2[util.getByte(origState[3],1)]),
	private.table3[util.getByte(origState[0],0)]);

	dstState[2] = bit.bxor(bit.bxor(bit.bxor(
	private.table0[util.getByte(origState[2],3)],
	private.table1[util.getByte(origState[3],2)]),
	private.table2[util.getByte(origState[0],1)]),
	private.table3[util.getByte(origState[1],0)]);

	dstState[3] = bit.bxor(bit.bxor(bit.bxor(
	private.table0[util.getByte(origState[3],3)],
	private.table1[util.getByte(origState[0],2)]),
	private.table2[util.getByte(origState[1],1)]),
	private.table3[util.getByte(origState[2],0)]);
	end

	--
	-- do last encryption round (ShiftRow and SubBytes)
	--
	function private.doLastRound(origState, dstState)
	dstState[0] = util.putByte(private.SBox[util.getByte(origState[0],3)], 3)
	+ util.putByte(private.SBox[util.getByte(origState[1],2)], 2)
	+ util.putByte(private.SBox[util.getByte(origState[2],1)], 1)
	+ util.putByte(private.SBox[util.getByte(origState[3],0)], 0);

	dstState[1] = util.putByte(private.SBox[util.getByte(origState[1],3)], 3)
	+ util.putByte(private.SBox[util.getByte(origState[2],2)], 2)
	+ util.putByte(private.SBox[util.getByte(origState[3],1)], 1)
	+ util.putByte(private.SBox[util.getByte(origState[0],0)], 0);

	dstState[2] = util.putByte(private.SBox[util.getByte(origState[2],3)], 3)
	+ util.putByte(private.SBox[util.getByte(origState[3],2)], 2)
	+ util.putByte(private.SBox[util.getByte(origState[0],1)], 1)
	+ util.putByte(private.SBox[util.getByte(origState[1],0)], 0);

	dstState[3] = util.putByte(private.SBox[util.getByte(origState[3],3)], 3)
	+ util.putByte(private.SBox[util.getByte(origState[0],2)], 2)
	+ util.putByte(private.SBox[util.getByte(origState[1],1)], 1)
	+ util.putByte(private.SBox[util.getByte(origState[2],0)], 0);
	end

	--
	-- do decryption round
	--
	function private.doInvRound(origState, dstState)
	dstState[0] = bit.bxor(bit.bxor(bit.bxor(
	private.tableInv0[util.getByte(origState[0],3)],
	private.tableInv1[util.getByte(origState[3],2)]),
	private.tableInv2[util.getByte(origState[2],1)]),
	private.tableInv3[util.getByte(origState[1],0)]);

	dstState[1] = bit.bxor(bit.bxor(bit.bxor(
	private.tableInv0[util.getByte(origState[1],3)],
	private.tableInv1[util.getByte(origState[0],2)]),
	private.tableInv2[util.getByte(origState[3],1)]),
	private.tableInv3[util.getByte(origState[2],0)]);

	dstState[2] = bit.bxor(bit.bxor(bit.bxor(
	private.tableInv0[util.getByte(origState[2],3)],
	private.tableInv1[util.getByte(origState[1],2)]),
	private.tableInv2[util.getByte(origState[0],1)]),
	private.tableInv3[util.getByte(origState[3],0)]);

	dstState[3] = bit.bxor(bit.bxor(bit.bxor(
	private.tableInv0[util.getByte(origState[3],3)],
	private.tableInv1[util.getByte(origState[2],2)]),
	private.tableInv2[util.getByte(origState[1],1)]),
	private.tableInv3[util.getByte(origState[0],0)]);
	end

	--
	-- do last decryption round
	--
	function private.doInvLastRound(origState, dstState)
	dstState[0] = util.putByte(private.iSBox[util.getByte(origState[0],3)], 3)
	+ util.putByte(private.iSBox[util.getByte(origState[3],2)], 2)
	+ util.putByte(private.iSBox[util.getByte(origState[2],1)], 1)
	+ util.putByte(private.iSBox[util.getByte(origState[1],0)], 0);

	dstState[1] = util.putByte(private.iSBox[util.getByte(origState[1],3)], 3)
	+ util.putByte(private.iSBox[util.getByte(origState[0],2)], 2)
	+ util.putByte(private.iSBox[util.getByte(origState[3],1)], 1)
	+ util.putByte(private.iSBox[util.getByte(origState[2],0)], 0);

	dstState[2] = util.putByte(private.iSBox[util.getByte(origState[2],3)], 3)
	+ util.putByte(private.iSBox[util.getByte(origState[1],2)], 2)
	+ util.putByte(private.iSBox[util.getByte(origState[0],1)], 1)
	+ util.putByte(private.iSBox[util.getByte(origState[3],0)], 0);

	dstState[3] = util.putByte(private.iSBox[util.getByte(origState[3],3)], 3)
	+ util.putByte(private.iSBox[util.getByte(origState[2],2)], 2)
	+ util.putByte(private.iSBox[util.getByte(origState[1],1)], 1)
	+ util.putByte(private.iSBox[util.getByte(origState[0],0)], 0);
	end

	--
	-- encrypts 16 Bytes
	-- key encryption key schedule
	-- input array with input data
	-- inputOffset start index for input
	-- output array for encrypted data
	-- outputOffset start index for output
	--
	function public.encrypt(key, input, inputOffset, output, outputOffset)
	--default parameters
	inputOffset = inputOffset or 1;
	output = output or {};
	outputOffset = outputOffset or 1;

	local state = {};
	local tmpState = {};

	if (key[public.KEY_TYPE] ~= public.ENCRYPTION_KEY) then
	print("No encryption key: ", key[public.KEY_TYPE]);
	return;
	end

	state = util.bytesToInts(input, inputOffset, 4);
	private.addRoundKey(state, key, 0);

	local round = 1;
	while (round < key[public.ROUNDS] - 1) do
	-- do a double round to save temporary assignments
	private.doRound(state, tmpState);
	private.addRoundKey(tmpState, key, round);
	round = round + 1;

	private.doRound(tmpState, state);
	private.addRoundKey(state, key, round);
	round = round + 1;
	end

	private.doRound(state, tmpState);
	private.addRoundKey(tmpState, key, round);
	round = round +1;

	private.doLastRound(tmpState, state);
	private.addRoundKey(state, key, round);

	return util.intsToBytes(state, output, outputOffset);
	end

	--
	-- decrypt 16 bytes
	-- key decryption key schedule
	-- input array with input data
	-- inputOffset start index for input
	-- output array for decrypted data
	-- outputOffset start index for output
	---
	function public.decrypt(key, input, inputOffset, output, outputOffset)
	-- default arguments
	inputOffset = inputOffset or 1;
	output = output or {};
	outputOffset = outputOffset or 1;

	local state = {};
	local tmpState = {};

	if (key[public.KEY_TYPE] ~= public.DECRYPTION_KEY) then
	print("No decryption key: ", key[public.KEY_TYPE]);
	return;
	end

	state = util.bytesToInts(input, inputOffset, 4);
	private.addRoundKey(state, key, key[public.ROUNDS]);

	local round = key[public.ROUNDS] - 1;
	while (round > 2) do
	-- do a double round to save temporary assignments
	private.doInvRound(state, tmpState);
	private.addRoundKey(tmpState, key, round);
	round = round - 1;

	private.doInvRound(tmpState, state);
	private.addRoundKey(state, key, round);
	round = round - 1;
	end

	private.doInvRound(state, tmpState);
	private.addRoundKey(tmpState, key, round);
	round = round - 1;

	private.doInvLastRound(tmpState, state);
	private.addRoundKey(state, key, round);

	return util.intsToBytes(state, output, outputOffset);
	end

	-- calculate all tables when loading this file
	private.calcSBox();
	private.calcRoundTables();
	private.calcInvRoundTables();

	return public;