mirror of
https://github.com/LDDestroier/CC/
synced 2024-11-19 00:04:53 +00:00
1736cf4b46
Ported by SquidDev. I really gotta move all these APIs over to this github, it's partially why I made it
1199 lines
27 KiB
Lua
1199 lines
27 KiB
Lua
local function _W(f) local e=setmetatable({}, {__index = _ENV or getfenv()}) if setfenv then setfenv(f, e) end return f(e) or e end
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local bit=_W(function(_ENV, ...)
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--[[
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This bit API is designed to cope with unsigned integers instead of normal integers
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To do this we add checks for overflows: (x > 2^31 ? x - 2 ^ 32 : x)
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These are written in long form because no constant folding.
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]]
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local floor = math.floor
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local lshift, rshift
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rshift = function(a,disp)
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return floor(a % 4294967296 / 2^disp)
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end
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lshift = function(a,disp)
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return (a * 2^disp) % 4294967296
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end
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return {
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-- bit operations
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bnot = bit.bnot,
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band = bit.band,
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bor = bit.bor,
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bxor = bit.bxor,
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rshift = rshift,
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lshift = lshift,
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}
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end)
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local gf=_W(function(_ENV, ...)
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-- finite field with base 2 and modulo irreducible polynom x^8+x^4+x^3+x+1 = 0x11d
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local bxor = bit.bxor
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local lshift = bit.lshift
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-- private data of gf
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local n = 0x100
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local ord = 0xff
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local irrPolynom = 0x11b
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local exp = {}
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local log = {}
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--
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-- add two polynoms (its simply xor)
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--
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local function add(operand1, operand2)
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return bxor(operand1,operand2)
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end
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--
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-- subtract two polynoms (same as addition)
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--
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local function sub(operand1, operand2)
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return bxor(operand1,operand2)
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end
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--
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-- inverts element
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-- a^(-1) = g^(order - log(a))
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--
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local function invert(operand)
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-- special case for 1
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if (operand == 1) then
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return 1
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end
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-- normal invert
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local exponent = ord - log[operand]
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return exp[exponent]
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end
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--
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-- multiply two elements using a logarithm table
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-- a*b = g^(log(a)+log(b))
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--
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local function mul(operand1, operand2)
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if (operand1 == 0 or operand2 == 0) then
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return 0
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end
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local exponent = log[operand1] + log[operand2]
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if (exponent >= ord) then
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exponent = exponent - ord
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end
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return exp[exponent]
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end
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--
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-- divide two elements
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-- a/b = g^(log(a)-log(b))
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--
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local function div(operand1, operand2)
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if (operand1 == 0) then
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return 0
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end
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-- TODO: exception if operand2 == 0
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local exponent = log[operand1] - log[operand2]
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if (exponent < 0) then
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exponent = exponent + ord
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end
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return exp[exponent]
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end
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--
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-- print logarithmic table
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--
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local function printLog()
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for i = 1, n do
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print("log(", i-1, ")=", log[i-1])
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end
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end
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--
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-- print exponentiation table
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--
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local function printExp()
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for i = 1, n do
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print("exp(", i-1, ")=", exp[i-1])
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end
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end
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--
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-- calculate logarithmic and exponentiation table
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--
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local function initMulTable()
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local a = 1
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for i = 0,ord-1 do
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exp[i] = a
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log[a] = i
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-- multiply with generator x+1 -> left shift + 1
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a = bxor(lshift(a, 1), a)
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-- if a gets larger than order, reduce modulo irreducible polynom
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if a > ord then
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a = sub(a, irrPolynom)
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end
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end
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end
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initMulTable()
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return {
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add = add,
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sub = sub,
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invert = invert,
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mul = mul,
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div = dib,
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printLog = printLog,
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printExp = printExp,
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}
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end)
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util=_W(function(_ENV, ...)
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-- Cache some bit operators
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local bxor = bit.bxor
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local rshift = bit.rshift
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local band = bit.band
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local lshift = bit.lshift
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local sleepCheckIn
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--
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-- calculate the parity of one byte
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--
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local function byteParity(byte)
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byte = bxor(byte, rshift(byte, 4))
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byte = bxor(byte, rshift(byte, 2))
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byte = bxor(byte, rshift(byte, 1))
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return band(byte, 1)
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end
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--
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-- get byte at position index
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--
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local function getByte(number, index)
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if (index == 0) then
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return band(number,0xff)
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else
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return band(rshift(number, index*8),0xff)
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end
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end
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--
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-- put number into int at position index
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--
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local function putByte(number, index)
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if (index == 0) then
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return band(number,0xff)
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else
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return lshift(band(number,0xff),index*8)
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end
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end
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--
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-- convert byte array to int array
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--
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local function bytesToInts(bytes, start, n)
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local ints = {}
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for i = 0, n - 1 do
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ints[i + 1] =
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putByte(bytes[start + (i*4)], 3) +
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putByte(bytes[start + (i*4) + 1], 2) +
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putByte(bytes[start + (i*4) + 2], 1) +
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putByte(bytes[start + (i*4) + 3], 0)
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if n % 10000 == 0 then sleepCheckIn() end
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end
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return ints
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end
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--
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-- convert int array to byte array
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--
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local function intsToBytes(ints, output, outputOffset, n)
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n = n or #ints
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for i = 0, n - 1 do
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for j = 0,3 do
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output[outputOffset + i*4 + (3 - j)] = getByte(ints[i + 1], j)
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end
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if n % 10000 == 0 then sleepCheckIn() end
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end
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return output
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end
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--
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-- convert bytes to hexString
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--
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local function bytesToHex(bytes)
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local hexBytes = ""
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for i,byte in ipairs(bytes) do
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hexBytes = hexBytes .. string.format("%02x ", byte)
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end
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return hexBytes
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end
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local function hexToBytes(bytes)
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local out = {}
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for i = 1, #bytes, 2 do
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out[#out + 1] = tonumber(bytes:sub(i, i + 1), 16)
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end
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return out
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end
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--
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-- convert data to hex string
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--
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local function toHexString(data)
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local type = type(data)
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if (type == "number") then
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return string.format("%08x",data)
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elseif (type == "table") then
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return bytesToHex(data)
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elseif (type == "string") then
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local bytes = {string.byte(data, 1, #data)}
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return bytesToHex(bytes)
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else
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return data
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end
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end
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local function padByteString(data)
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local dataLength = #data
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local random1 = math.random(0,255)
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local random2 = math.random(0,255)
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local prefix = string.char(random1,
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random2,
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random1,
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random2,
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getByte(dataLength, 3),
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getByte(dataLength, 2),
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getByte(dataLength, 1),
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getByte(dataLength, 0)
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)
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data = prefix .. data
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local paddingLength = math.ceil(#data/16)*16 - #data
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local padding = ""
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for i=1,paddingLength do
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padding = padding .. string.char(math.random(0,255))
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end
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return data .. padding
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end
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local function properlyDecrypted(data)
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local random = {string.byte(data,1,4)}
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if (random[1] == random[3] and random[2] == random[4]) then
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return true
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end
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return false
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end
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local function unpadByteString(data)
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if (not properlyDecrypted(data)) then
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return nil
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end
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local dataLength = putByte(string.byte(data,5), 3)
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+ putByte(string.byte(data,6), 2)
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+ putByte(string.byte(data,7), 1)
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+ putByte(string.byte(data,8), 0)
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return string.sub(data,9,8+dataLength)
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end
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local function xorIV(data, iv)
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for i = 1,16 do
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data[i] = bxor(data[i], iv[i])
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end
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end
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local function increment(data)
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local i = 16
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while true do
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local value = data[i] + 1
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if value >= 256 then
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data[i] = value - 256
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i = (i - 2) % 16 + 1
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else
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data[i] = value
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break
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end
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end
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end
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-- Called every encryption cycle
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local push, pull, time = os.queueEvent, coroutine.yield, os.time
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local oldTime = time()
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local function sleepCheckIn()
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local newTime = time()
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if newTime - oldTime >= 0.03 then -- (0.020 * 1.5)
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oldTime = newTime
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push("sleep")
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pull("sleep")
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end
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end
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local function getRandomData(bytes)
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local char, random, sleep, insert = string.char, math.random, sleepCheckIn, table.insert
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local result = {}
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for i=1,bytes do
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insert(result, random(0,255))
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if i % 10240 == 0 then sleep() end
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end
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return result
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end
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local function getRandomString(bytes)
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local char, random, sleep, insert = string.char, math.random, sleepCheckIn, table.insert
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local result = {}
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for i=1,bytes do
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insert(result, char(random(0,255)))
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if i % 10240 == 0 then sleep() end
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end
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return table.concat(result)
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end
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return {
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byteParity = byteParity,
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getByte = getByte,
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putByte = putByte,
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bytesToInts = bytesToInts,
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intsToBytes = intsToBytes,
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bytesToHex = bytesToHex,
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hexToBytes = hexToBytes,
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toHexString = toHexString,
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padByteString = padByteString,
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properlyDecrypted = properlyDecrypted,
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unpadByteString = unpadByteString,
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xorIV = xorIV,
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increment = increment,
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sleepCheckIn = sleepCheckIn,
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getRandomData = getRandomData,
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getRandomString = getRandomString,
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}
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end)
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aes=_W(function(_ENV, ...)
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-- Implementation of AES with nearly pure lua
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-- AES with lua is slow, really slow :-)
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local putByte = util.putByte
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local getByte = util.getByte
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-- some constants
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local ROUNDS = 'rounds'
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local KEY_TYPE = "type"
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local ENCRYPTION_KEY=1
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local DECRYPTION_KEY=2
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-- aes SBOX
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local SBox = {}
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local iSBox = {}
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-- aes tables
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local table0 = {}
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local table1 = {}
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local table2 = {}
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local table3 = {}
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local tableInv0 = {}
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local tableInv1 = {}
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local tableInv2 = {}
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local tableInv3 = {}
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-- round constants
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local rCon = {
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0x01000000,
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0x02000000,
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0x04000000,
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0x08000000,
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0x10000000,
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0x20000000,
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0x40000000,
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0x80000000,
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0x1b000000,
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0x36000000,
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0x6c000000,
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0xd8000000,
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0xab000000,
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0x4d000000,
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0x9a000000,
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0x2f000000,
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}
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--
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-- affine transformation for calculating the S-Box of AES
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--
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local function affinMap(byte)
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mask = 0xf8
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result = 0
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for i = 1,8 do
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result = bit.lshift(result,1)
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parity = util.byteParity(bit.band(byte,mask))
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result = result + parity
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-- simulate roll
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lastbit = bit.band(mask, 1)
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mask = bit.band(bit.rshift(mask, 1),0xff)
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if (lastbit ~= 0) then
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mask = bit.bor(mask, 0x80)
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else
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mask = bit.band(mask, 0x7f)
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end
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end
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return bit.bxor(result, 0x63)
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end
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--
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-- calculate S-Box and inverse S-Box of AES
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-- apply affine transformation to inverse in finite field 2^8
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--
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local function calcSBox()
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for i = 0, 255 do
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if (i ~= 0) then
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inverse = gf.invert(i)
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else
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inverse = i
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end
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mapped = affinMap(inverse)
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SBox[i] = mapped
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iSBox[mapped] = i
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end
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end
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--
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-- Calculate round tables
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-- round tables are used to calculate shiftRow, MixColumn and SubBytes
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-- with 4 table lookups and 4 xor operations.
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--
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local function calcRoundTables()
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for x = 0,255 do
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byte = SBox[x]
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table0[x] = putByte(gf.mul(0x03, byte), 0)
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+ putByte( byte , 1)
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+ putByte( byte , 2)
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+ putByte(gf.mul(0x02, byte), 3)
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table1[x] = putByte( byte , 0)
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+ putByte( byte , 1)
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+ putByte(gf.mul(0x02, byte), 2)
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+ putByte(gf.mul(0x03, byte), 3)
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table2[x] = putByte( byte , 0)
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+ putByte(gf.mul(0x02, byte), 1)
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+ putByte(gf.mul(0x03, byte), 2)
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+ putByte( byte , 3)
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table3[x] = putByte(gf.mul(0x02, byte), 0)
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+ putByte(gf.mul(0x03, byte), 1)
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+ putByte( byte , 2)
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+ putByte( byte , 3)
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end
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end
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--
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-- Calculate inverse round tables
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-- does the inverse of the normal roundtables for the equivalent
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-- decryption algorithm.
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--
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local function calcInvRoundTables()
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for x = 0,255 do
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byte = iSBox[x]
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tableInv0[x] = putByte(gf.mul(0x0b, byte), 0)
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+ putByte(gf.mul(0x0d, byte), 1)
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+ putByte(gf.mul(0x09, byte), 2)
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+ putByte(gf.mul(0x0e, byte), 3)
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tableInv1[x] = putByte(gf.mul(0x0d, byte), 0)
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+ putByte(gf.mul(0x09, byte), 1)
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+ putByte(gf.mul(0x0e, byte), 2)
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+ putByte(gf.mul(0x0b, byte), 3)
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tableInv2[x] = putByte(gf.mul(0x09, byte), 0)
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+ putByte(gf.mul(0x0e, byte), 1)
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+ putByte(gf.mul(0x0b, byte), 2)
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+ putByte(gf.mul(0x0d, byte), 3)
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tableInv3[x] = putByte(gf.mul(0x0e, byte), 0)
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+ putByte(gf.mul(0x0b, byte), 1)
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+ putByte(gf.mul(0x0d, byte), 2)
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+ putByte(gf.mul(0x09, byte), 3)
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end
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end
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--
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-- rotate word: 0xaabbccdd gets 0xbbccddaa
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-- used for key schedule
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--
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local function rotWord(word)
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local tmp = bit.band(word,0xff000000)
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return (bit.lshift(word,8) + bit.rshift(tmp,24))
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end
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--
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-- replace all bytes in a word with the SBox.
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-- used for key schedule
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--
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local function subWord(word)
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return putByte(SBox[getByte(word,0)],0)
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+ putByte(SBox[getByte(word,1)],1)
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+ putByte(SBox[getByte(word,2)],2)
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+ putByte(SBox[getByte(word,3)],3)
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end
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--
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-- generate key schedule for aes encryption
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--
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-- returns table with all round keys and
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-- the necessary number of rounds saved in [ROUNDS]
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--
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local function expandEncryptionKey(key)
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local keySchedule = {}
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local keyWords = math.floor(#key / 4)
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if ((keyWords ~= 4 and keyWords ~= 6 and keyWords ~= 8) or (keyWords * 4 ~= #key)) then
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error("Invalid key size: " .. tostring(keyWords))
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return nil
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end
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keySchedule[ROUNDS] = keyWords + 6
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keySchedule[KEY_TYPE] = ENCRYPTION_KEY
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for i = 0,keyWords - 1 do
|
|
keySchedule[i] = putByte(key[i*4+1], 3)
|
|
+ putByte(key[i*4+2], 2)
|
|
+ putByte(key[i*4+3], 1)
|
|
+ putByte(key[i*4+4], 0)
|
|
end
|
|
|
|
for i = keyWords, (keySchedule[ROUNDS] + 1)*4 - 1 do
|
|
local tmp = keySchedule[i-1]
|
|
|
|
if ( i % keyWords == 0) then
|
|
tmp = rotWord(tmp)
|
|
tmp = subWord(tmp)
|
|
|
|
local index = math.floor(i/keyWords)
|
|
tmp = bit.bxor(tmp,rCon[index])
|
|
elseif (keyWords > 6 and i % keyWords == 4) then
|
|
tmp = 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
|
|
--
|
|
local function invMixColumnOld(word)
|
|
local b0 = getByte(word,3)
|
|
local b1 = getByte(word,2)
|
|
local b2 = getByte(word,1)
|
|
local b3 = getByte(word,0)
|
|
|
|
return putByte(gf.add(gf.add(gf.add(gf.mul(0x0b, b1),
|
|
gf.mul(0x0d, b2)),
|
|
gf.mul(0x09, b3)),
|
|
gf.mul(0x0e, b0)),3)
|
|
+ putByte(gf.add(gf.add(gf.add(gf.mul(0x0b, b2),
|
|
gf.mul(0x0d, b3)),
|
|
gf.mul(0x09, b0)),
|
|
gf.mul(0x0e, b1)),2)
|
|
+ putByte(gf.add(gf.add(gf.add(gf.mul(0x0b, b3),
|
|
gf.mul(0x0d, b0)),
|
|
gf.mul(0x09, b1)),
|
|
gf.mul(0x0e, b2)),1)
|
|
+ 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
|
|
--
|
|
local function invMixColumn(word)
|
|
local b0 = getByte(word,3)
|
|
local b1 = getByte(word,2)
|
|
local b2 = getByte(word,1)
|
|
local b3 = 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 putByte( bit.bxor(bit.bxor(b3,v), gf.mul(0x02, bit.bxor(b0,b3))), 0)
|
|
+ putByte( bit.bxor(bit.bxor(b2,w), gf.mul(0x02, t )), 1)
|
|
+ putByte( bit.bxor(bit.bxor(b1,v), gf.mul(0x02, bit.bxor(b0,b3))), 2)
|
|
+ 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.
|
|
--
|
|
local function expandDecryptionKey(key)
|
|
local keySchedule = expandEncryptionKey(key)
|
|
if (keySchedule == nil) then
|
|
return nil
|
|
end
|
|
|
|
keySchedule[KEY_TYPE] = DECRYPTION_KEY
|
|
|
|
for i = 4, (keySchedule[ROUNDS] + 1)*4 - 5 do
|
|
keySchedule[i] = invMixColumnOld(keySchedule[i])
|
|
end
|
|
|
|
return keySchedule
|
|
end
|
|
|
|
--
|
|
-- xor round key to state
|
|
--
|
|
local function addRoundKey(state, key, round)
|
|
for i = 0, 3 do
|
|
state[i + 1] = bit.bxor(state[i + 1], key[round*4+i])
|
|
end
|
|
end
|
|
|
|
--
|
|
-- do encryption round (ShiftRow, SubBytes, MixColumn together)
|
|
--
|
|
local function doRound(origState, dstState)
|
|
dstState[1] = bit.bxor(bit.bxor(bit.bxor(
|
|
table0[getByte(origState[1],3)],
|
|
table1[getByte(origState[2],2)]),
|
|
table2[getByte(origState[3],1)]),
|
|
table3[getByte(origState[4],0)])
|
|
|
|
dstState[2] = bit.bxor(bit.bxor(bit.bxor(
|
|
table0[getByte(origState[2],3)],
|
|
table1[getByte(origState[3],2)]),
|
|
table2[getByte(origState[4],1)]),
|
|
table3[getByte(origState[1],0)])
|
|
|
|
dstState[3] = bit.bxor(bit.bxor(bit.bxor(
|
|
table0[getByte(origState[3],3)],
|
|
table1[getByte(origState[4],2)]),
|
|
table2[getByte(origState[1],1)]),
|
|
table3[getByte(origState[2],0)])
|
|
|
|
dstState[4] = bit.bxor(bit.bxor(bit.bxor(
|
|
table0[getByte(origState[4],3)],
|
|
table1[getByte(origState[1],2)]),
|
|
table2[getByte(origState[2],1)]),
|
|
table3[getByte(origState[3],0)])
|
|
end
|
|
|
|
--
|
|
-- do last encryption round (ShiftRow and SubBytes)
|
|
--
|
|
local function doLastRound(origState, dstState)
|
|
dstState[1] = putByte(SBox[getByte(origState[1],3)], 3)
|
|
+ putByte(SBox[getByte(origState[2],2)], 2)
|
|
+ putByte(SBox[getByte(origState[3],1)], 1)
|
|
+ putByte(SBox[getByte(origState[4],0)], 0)
|
|
|
|
dstState[2] = putByte(SBox[getByte(origState[2],3)], 3)
|
|
+ putByte(SBox[getByte(origState[3],2)], 2)
|
|
+ putByte(SBox[getByte(origState[4],1)], 1)
|
|
+ putByte(SBox[getByte(origState[1],0)], 0)
|
|
|
|
dstState[3] = putByte(SBox[getByte(origState[3],3)], 3)
|
|
+ putByte(SBox[getByte(origState[4],2)], 2)
|
|
+ putByte(SBox[getByte(origState[1],1)], 1)
|
|
+ putByte(SBox[getByte(origState[2],0)], 0)
|
|
|
|
dstState[4] = putByte(SBox[getByte(origState[4],3)], 3)
|
|
+ putByte(SBox[getByte(origState[1],2)], 2)
|
|
+ putByte(SBox[getByte(origState[2],1)], 1)
|
|
+ putByte(SBox[getByte(origState[3],0)], 0)
|
|
end
|
|
|
|
--
|
|
-- do decryption round
|
|
--
|
|
local function doInvRound(origState, dstState)
|
|
dstState[1] = bit.bxor(bit.bxor(bit.bxor(
|
|
tableInv0[getByte(origState[1],3)],
|
|
tableInv1[getByte(origState[4],2)]),
|
|
tableInv2[getByte(origState[3],1)]),
|
|
tableInv3[getByte(origState[2],0)])
|
|
|
|
dstState[2] = bit.bxor(bit.bxor(bit.bxor(
|
|
tableInv0[getByte(origState[2],3)],
|
|
tableInv1[getByte(origState[1],2)]),
|
|
tableInv2[getByte(origState[4],1)]),
|
|
tableInv3[getByte(origState[3],0)])
|
|
|
|
dstState[3] = bit.bxor(bit.bxor(bit.bxor(
|
|
tableInv0[getByte(origState[3],3)],
|
|
tableInv1[getByte(origState[2],2)]),
|
|
tableInv2[getByte(origState[1],1)]),
|
|
tableInv3[getByte(origState[4],0)])
|
|
|
|
dstState[4] = bit.bxor(bit.bxor(bit.bxor(
|
|
tableInv0[getByte(origState[4],3)],
|
|
tableInv1[getByte(origState[3],2)]),
|
|
tableInv2[getByte(origState[2],1)]),
|
|
tableInv3[getByte(origState[1],0)])
|
|
end
|
|
|
|
--
|
|
-- do last decryption round
|
|
--
|
|
local function doInvLastRound(origState, dstState)
|
|
dstState[1] = putByte(iSBox[getByte(origState[1],3)], 3)
|
|
+ putByte(iSBox[getByte(origState[4],2)], 2)
|
|
+ putByte(iSBox[getByte(origState[3],1)], 1)
|
|
+ putByte(iSBox[getByte(origState[2],0)], 0)
|
|
|
|
dstState[2] = putByte(iSBox[getByte(origState[2],3)], 3)
|
|
+ putByte(iSBox[getByte(origState[1],2)], 2)
|
|
+ putByte(iSBox[getByte(origState[4],1)], 1)
|
|
+ putByte(iSBox[getByte(origState[3],0)], 0)
|
|
|
|
dstState[3] = putByte(iSBox[getByte(origState[3],3)], 3)
|
|
+ putByte(iSBox[getByte(origState[2],2)], 2)
|
|
+ putByte(iSBox[getByte(origState[1],1)], 1)
|
|
+ putByte(iSBox[getByte(origState[4],0)], 0)
|
|
|
|
dstState[4] = putByte(iSBox[getByte(origState[4],3)], 3)
|
|
+ putByte(iSBox[getByte(origState[3],2)], 2)
|
|
+ putByte(iSBox[getByte(origState[2],1)], 1)
|
|
+ putByte(iSBox[getByte(origState[1],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
|
|
--
|
|
local function 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[KEY_TYPE] ~= ENCRYPTION_KEY) then
|
|
error("No encryption key: " .. tostring(key[KEY_TYPE]) .. ", expected " .. ENCRYPTION_KEY)
|
|
return
|
|
end
|
|
|
|
state = util.bytesToInts(input, inputOffset, 4)
|
|
addRoundKey(state, key, 0)
|
|
|
|
|
|
local round = 1
|
|
while (round < key[ROUNDS] - 1) do
|
|
-- do a double round to save temporary assignments
|
|
doRound(state, tmpState)
|
|
addRoundKey(tmpState, key, round)
|
|
round = round + 1
|
|
|
|
doRound(tmpState, state)
|
|
addRoundKey(state, key, round)
|
|
round = round + 1
|
|
end
|
|
|
|
doRound(state, tmpState)
|
|
addRoundKey(tmpState, key, round)
|
|
round = round +1
|
|
|
|
doLastRound(tmpState, state)
|
|
addRoundKey(state, key, round)
|
|
|
|
util.sleepCheckIn()
|
|
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
|
|
---
|
|
local function 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[KEY_TYPE] ~= DECRYPTION_KEY) then
|
|
error("No decryption key: " .. tostring(key[KEY_TYPE]))
|
|
return
|
|
end
|
|
|
|
state = util.bytesToInts(input, inputOffset, 4)
|
|
addRoundKey(state, key, key[ROUNDS])
|
|
|
|
local round = key[ROUNDS] - 1
|
|
while (round > 2) do
|
|
-- do a double round to save temporary assignments
|
|
doInvRound(state, tmpState)
|
|
addRoundKey(tmpState, key, round)
|
|
round = round - 1
|
|
|
|
doInvRound(tmpState, state)
|
|
addRoundKey(state, key, round)
|
|
round = round - 1
|
|
end
|
|
|
|
|
|
doInvRound(state, tmpState)
|
|
addRoundKey(tmpState, key, round)
|
|
round = round - 1
|
|
|
|
doInvLastRound(tmpState, state)
|
|
addRoundKey(state, key, round)
|
|
|
|
util.sleepCheckIn()
|
|
return util.intsToBytes(state, output, outputOffset)
|
|
end
|
|
|
|
-- calculate all tables when loading this file
|
|
calcSBox()
|
|
calcRoundTables()
|
|
calcInvRoundTables()
|
|
|
|
return {
|
|
ROUNDS = ROUNDS,
|
|
KEY_TYPE = KEY_TYPE,
|
|
ENCRYPTION_KEY = ENCRYPTION_KEY,
|
|
DECRYPTION_KEY = DECRYPTION_KEY,
|
|
|
|
expandEncryptionKey = expandEncryptionKey,
|
|
expandDecryptionKey = expandDecryptionKey,
|
|
encrypt = encrypt,
|
|
decrypt = decrypt,
|
|
}
|
|
end)
|
|
local buffer=_W(function(_ENV, ...)
|
|
local function new ()
|
|
return {}
|
|
end
|
|
|
|
local function addString (stack, s)
|
|
table.insert(stack, s)
|
|
end
|
|
|
|
local function toString (stack)
|
|
return table.concat(stack)
|
|
end
|
|
|
|
return {
|
|
new = new,
|
|
addString = addString,
|
|
toString = toString,
|
|
}
|
|
end)
|
|
ciphermode=_W(function(_ENV, ...)
|
|
local public = {}
|
|
|
|
--
|
|
-- Encrypt strings
|
|
-- key - byte array with key
|
|
-- string - string to encrypt
|
|
-- modefunction - function for cipher mode to use
|
|
--
|
|
|
|
local random = math.random
|
|
function public.encryptString(key, data, modeFunction, iv)
|
|
if iv then
|
|
local ivCopy = {}
|
|
for i = 1, 16 do ivCopy[i] = iv[i] end
|
|
iv = ivCopy
|
|
else
|
|
iv = {0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0}
|
|
end
|
|
|
|
local keySched = aes.expandEncryptionKey(key)
|
|
local encryptedData = buffer.new()
|
|
|
|
for i = 1, #data/16 do
|
|
local offset = (i-1)*16 + 1
|
|
local byteData = {string.byte(data,offset,offset +15)}
|
|
|
|
iv = modeFunction(keySched, byteData, iv)
|
|
|
|
buffer.addString(encryptedData, string.char(unpack(byteData)))
|
|
end
|
|
|
|
return buffer.toString(encryptedData)
|
|
end
|
|
|
|
--
|
|
-- the following 4 functions can be used as
|
|
-- modefunction for encryptString
|
|
--
|
|
|
|
-- Electronic code book mode encrypt function
|
|
function public.encryptECB(keySched, byteData, iv)
|
|
aes.encrypt(keySched, byteData, 1, byteData, 1)
|
|
end
|
|
|
|
-- Cipher block chaining mode encrypt function
|
|
function public.encryptCBC(keySched, byteData, iv)
|
|
util.xorIV(byteData, iv)
|
|
aes.encrypt(keySched, byteData, 1, byteData, 1)
|
|
return byteData
|
|
end
|
|
|
|
-- Output feedback mode encrypt function
|
|
function public.encryptOFB(keySched, byteData, iv)
|
|
aes.encrypt(keySched, iv, 1, iv, 1)
|
|
util.xorIV(byteData, iv)
|
|
return iv
|
|
end
|
|
|
|
-- Cipher feedback mode encrypt function
|
|
function public.encryptCFB(keySched, byteData, iv)
|
|
aes.encrypt(keySched, iv, 1, iv, 1)
|
|
util.xorIV(byteData, iv)
|
|
return byteData
|
|
end
|
|
|
|
function public.encryptCTR(keySched, byteData, iv)
|
|
local nextIV = {}
|
|
for j = 1, 16 do nextIV[j] = iv[j] end
|
|
|
|
aes.encrypt(keySched, iv, 1, iv, 1)
|
|
util.xorIV(byteData, iv)
|
|
|
|
util.increment(nextIV)
|
|
|
|
return nextIV
|
|
end
|
|
|
|
--
|
|
-- Decrypt strings
|
|
-- key - byte array with key
|
|
-- string - string to decrypt
|
|
-- modefunction - function for cipher mode to use
|
|
--
|
|
function public.decryptString(key, data, modeFunction, iv)
|
|
if iv then
|
|
local ivCopy = {}
|
|
for i = 1, 16 do ivCopy[i] = iv[i] end
|
|
iv = ivCopy
|
|
else
|
|
iv = {0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0}
|
|
end
|
|
|
|
local keySched
|
|
if modeFunction == public.decryptOFB or modeFunction == public.decryptCFB or modeFunction == public.decryptCTR then
|
|
keySched = aes.expandEncryptionKey(key)
|
|
else
|
|
keySched = aes.expandDecryptionKey(key)
|
|
end
|
|
|
|
local decryptedData = buffer.new()
|
|
|
|
for i = 1, #data/16 do
|
|
local offset = (i-1)*16 + 1
|
|
local byteData = {string.byte(data,offset,offset +15)}
|
|
|
|
iv = modeFunction(keySched, byteData, iv)
|
|
|
|
buffer.addString(decryptedData, string.char(unpack(byteData)))
|
|
end
|
|
|
|
return buffer.toString(decryptedData)
|
|
end
|
|
|
|
--
|
|
-- the following 4 functions can be used as
|
|
-- modefunction for decryptString
|
|
--
|
|
|
|
-- Electronic code book mode decrypt function
|
|
function public.decryptECB(keySched, byteData, iv)
|
|
aes.decrypt(keySched, byteData, 1, byteData, 1)
|
|
return iv
|
|
end
|
|
|
|
-- Cipher block chaining mode decrypt function
|
|
function public.decryptCBC(keySched, byteData, iv)
|
|
local nextIV = {}
|
|
for j = 1, 16 do nextIV[j] = byteData[j] end
|
|
|
|
aes.decrypt(keySched, byteData, 1, byteData, 1)
|
|
util.xorIV(byteData, iv)
|
|
|
|
return nextIV
|
|
end
|
|
|
|
-- Output feedback mode decrypt function
|
|
function public.decryptOFB(keySched, byteData, iv)
|
|
aes.encrypt(keySched, iv, 1, iv, 1)
|
|
util.xorIV(byteData, iv)
|
|
|
|
return iv
|
|
end
|
|
|
|
-- Cipher feedback mode decrypt function
|
|
function public.decryptCFB(keySched, byteData, iv)
|
|
local nextIV = {}
|
|
for j = 1, 16 do nextIV[j] = byteData[j] end
|
|
|
|
aes.encrypt(keySched, iv, 1, iv, 1)
|
|
util.xorIV(byteData, iv)
|
|
|
|
return nextIV
|
|
end
|
|
|
|
public.decryptCTR = public.encryptCTR
|
|
|
|
return public
|
|
end)
|
|
-- Simple API for encrypting strings.
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--
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AES128 = 16
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AES192 = 24
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AES256 = 32
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ECBMODE = 1
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CBCMODE = 2
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OFBMODE = 3
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CFBMODE = 4
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CTRMODE = 4
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local function pwToKey(password, keyLength, iv)
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local padLength = keyLength
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if (keyLength == AES192) then
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padLength = 32
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end
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if (padLength > #password) then
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local postfix = ""
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for i = 1,padLength - #password do
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postfix = postfix .. string.char(0)
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end
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password = password .. postfix
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else
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password = string.sub(password, 1, padLength)
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end
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local pwBytes = {string.byte(password,1,#password)}
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password = ciphermode.encryptString(pwBytes, password, ciphermode.encryptCBC, iv)
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password = string.sub(password, 1, keyLength)
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return {string.byte(password,1,#password)}
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end
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--
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-- Encrypts string data with password password.
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-- password - the encryption key is generated from this string
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-- data - string to encrypt (must not be too large)
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-- keyLength - length of aes key: 128(default), 192 or 256 Bit
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-- mode - mode of encryption: ecb, cbc(default), ofb, cfb
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--
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-- mode and keyLength must be the same for encryption and decryption.
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--
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function encrypt(password, data, keyLength, mode, iv)
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assert(password ~= nil, "Empty password.")
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assert(password ~= nil, "Empty data.")
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local mode = mode or CBCMODE
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local keyLength = keyLength or AES128
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local key = pwToKey(password, keyLength, iv)
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local paddedData = util.padByteString(data)
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if mode == ECBMODE then
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return ciphermode.encryptString(key, paddedData, ciphermode.encryptECB, iv)
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elseif mode == CBCMODE then
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return ciphermode.encryptString(key, paddedData, ciphermode.encryptCBC, iv)
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elseif mode == OFBMODE then
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return ciphermode.encryptString(key, paddedData, ciphermode.encryptOFB, iv)
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elseif mode == CFBMODE then
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return ciphermode.encryptString(key, paddedData, ciphermode.encryptCFB, iv)
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elseif mode == CTRMODE then
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return ciphermode.encryptString(key, paddedData, ciphermode.encryptCTR, iv)
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else
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error("Unknown mode", 2)
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end
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end
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--
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-- Decrypts string data with password password.
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-- password - the decryption key is generated from this string
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-- data - string to encrypt
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-- keyLength - length of aes key: 128(default), 192 or 256 Bit
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-- mode - mode of decryption: ecb, cbc(default), ofb, cfb
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--
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-- mode and keyLength must be the same for encryption and decryption.
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--
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function decrypt(password, data, keyLength, mode, iv)
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local mode = mode or CBCMODE
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local keyLength = keyLength or AES128
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local key = pwToKey(password, keyLength, iv)
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local plain
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if mode == ECBMODE then
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plain = ciphermode.decryptString(key, data, ciphermode.decryptECB, iv)
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elseif mode == CBCMODE then
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plain = ciphermode.decryptString(key, data, ciphermode.decryptCBC, iv)
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elseif mode == OFBMODE then
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plain = ciphermode.decryptString(key, data, ciphermode.decryptOFB, iv)
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elseif mode == CFBMODE then
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plain = ciphermode.decryptString(key, data, ciphermode.decryptCFB, iv)
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elseif mode == CTRMODE then
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plain = ciphermode.decryptString(key, data, ciphermode.decryptCTR, iv)
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else
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error("Unknown mode", 2)
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end
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result = util.unpadByteString(plain)
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if (result == nil) then
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return nil
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end
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return result
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end
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