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sha2.lua
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sha2.lua
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--------------------------------------------------------------------------------------------------------------------------
-- sha2.lua
--------------------------------------------------------------------------------------------------------------------------
-- VERSION: 12 (2022-02-23)
-- AUTHOR: Egor Skriptunoff
-- LICENSE: MIT (the same license as Lua itself)
-- URL: https://github.com/Egor-Skriptunoff/pure_lua_SHA
--
-- DESCRIPTION:
-- This module contains functions to calculate SHA digest:
-- MD5, SHA-1,
-- SHA-224, SHA-256, SHA-512/224, SHA-512/256, SHA-384, SHA-512,
-- SHA3-224, SHA3-256, SHA3-384, SHA3-512, SHAKE128, SHAKE256,
-- HMAC,
-- BLAKE2b, BLAKE2s, BLAKE2bp, BLAKE2sp, BLAKE2Xb, BLAKE2Xs,
-- BLAKE3, BLAKE3_KDF
-- Written in pure Lua.
-- Compatible with:
-- Lua 5.1, Lua 5.2, Lua 5.3, Lua 5.4, Fengari, LuaJIT 2.0/2.1 (any CPU endianness).
-- Main feature of this module: it was heavily optimized for speed.
-- For every Lua version the module contains particular implementation branch to get benefits from version-specific features.
-- - branch for Lua 5.1 (emulating bitwise operators using look-up table)
-- - branch for Lua 5.2 (using bit32/bit library), suitable for both Lua 5.2 with native "bit32" and Lua 5.1 with external library "bit"
-- - branch for Lua 5.3/5.4 (using native 64-bit bitwise operators)
-- - branch for Lua 5.3/5.4 (using native 32-bit bitwise operators) for Lua built with LUA_INT_TYPE=LUA_INT_INT
-- - branch for LuaJIT without FFI library (useful in a sandboxed environment)
-- - branch for LuaJIT x86 without FFI library (LuaJIT x86 has oddity because of lack of CPU registers)
-- - branch for LuaJIT 2.0 with FFI library (bit.* functions work only with Lua numbers)
-- - branch for LuaJIT 2.1 with FFI library (bit.* functions can work with "int64_t" arguments)
--
--
-- USAGE:
-- Input data should be provided as a binary string: either as a whole string or as a sequence of substrings (chunk-by-chunk loading, total length < 9*10^15 bytes).
-- Result (SHA digest) is returned in hexadecimal representation as a string of lowercase hex digits.
-- Simplest usage example:
-- local sha = require("sha2")
-- local your_hash = sha.sha256("your string")
-- See file "sha2_test.lua" for more examples.
--
--
-- CHANGELOG:
-- version date description
-- ------- ---------- -----------
-- 12 2022-02-23 Now works in Luau (but NOT optimized for speed)
-- 11 2022-01-09 BLAKE3 added
-- 10 2022-01-02 BLAKE2 functions added
-- 9 2020-05-10 Now works in OpenWrt's Lua (dialect of Lua 5.1 with "double" + "invisible int32")
-- 8 2019-09-03 SHA-3 functions added
-- 7 2019-03-17 Added functions to convert to/from base64
-- 6 2018-11-12 HMAC added
-- 5 2018-11-10 SHA-1 added
-- 4 2018-11-03 MD5 added
-- 3 2018-11-02 Bug fixed: incorrect hashing of long (2 GByte) data streams on Lua 5.3/5.4 built with "int32" integers
-- 2 2018-10-07 Decreased module loading time in Lua 5.1 implementation branch (thanks to Peter Melnichenko for giving a hint)
-- 1 2018-10-06 First release (only SHA-2 functions)
-----------------------------------------------------------------------------
local print_debug_messages = false -- set to true to view some messages about your system's abilities and implementation branch chosen for your system
local unpack, table_concat, byte, char, string_rep, sub, gsub, gmatch, string_format, floor, ceil, math_min, math_max, tonumber, type, math_huge =
table.unpack or unpack, table.concat, string.byte, string.char, string.rep, string.sub, string.gsub, string.gmatch, string.format, math.floor, math.ceil, math.min, math.max, tonumber, type, math.huge
--------------------------------------------------------------------------------
-- EXAMINING YOUR SYSTEM
--------------------------------------------------------------------------------
local function get_precision(one)
-- "one" must be either float 1.0 or integer 1
-- returns bits_precision, is_integer
-- This function works correctly with all floating point datatypes (including non-IEEE-754)
local k, n, m, prev_n = 0, one, one
while true do
k, prev_n, n, m = k + 1, n, n + n + 1, m + m + k % 2
if k > 256 or n - (n - 1) ~= 1 or m - (m - 1) ~= 1 or n == m then
return k, false -- floating point datatype
elseif n == prev_n then
return k, true -- integer datatype
end
end
end
-- Make sure Lua has "double" numbers
local x = 2/3
local Lua_has_double = x * 5 > 3 and x * 4 < 3 and get_precision(1.0) >= 53
assert(Lua_has_double, "at least 53-bit floating point numbers are required")
-- Q:
-- SHA2 was designed for FPU-less machines.
-- So, why floating point numbers are needed for this module?
-- A:
-- 53-bit "double" numbers are useful to calculate "magic numbers" used in SHA.
-- I prefer to write 50 LOC "magic numbers calculator" instead of storing more than 200 constants explicitly in this source file.
local int_prec, Lua_has_integers = get_precision(1)
local Lua_has_int64 = Lua_has_integers and int_prec == 64
local Lua_has_int32 = Lua_has_integers and int_prec == 32
assert(Lua_has_int64 or Lua_has_int32 or not Lua_has_integers, "Lua integers must be either 32-bit or 64-bit")
-- Q:
-- Does it mean that almost all non-standard configurations are not supported?
-- A:
-- Yes. Sorry, too many problems to support all possible Lua numbers configurations.
-- Lua 5.1/5.2 with "int32" will not work.
-- Lua 5.1/5.2 with "int64" will not work.
-- Lua 5.1/5.2 with "int128" will not work.
-- Lua 5.1/5.2 with "float" will not work.
-- Lua 5.1/5.2 with "double" is OK. (default config for Lua 5.1, Lua 5.2, LuaJIT)
-- Lua 5.3/5.4 with "int32" + "float" will not work.
-- Lua 5.3/5.4 with "int64" + "float" will not work.
-- Lua 5.3/5.4 with "int128" + "float" will not work.
-- Lua 5.3/5.4 with "int32" + "double" is OK. (config used by Fengari)
-- Lua 5.3/5.4 with "int64" + "double" is OK. (default config for Lua 5.3, Lua 5.4)
-- Lua 5.3/5.4 with "int128" + "double" will not work.
-- Using floating point numbers better than "double" instead of "double" is OK (non-IEEE-754 floating point implementation are allowed).
-- Using "int128" instead of "int64" is not OK: "int128" would require different branch of implementation for optimized SHA512.
-- Check for LuaJIT and 32-bit bitwise libraries
local is_LuaJIT = ({false, [1] = true})[1] and _VERSION ~= "Luau" and (type(jit) ~= "table" or jit.version_num >= 20000) -- LuaJIT 1.x.x and Luau are treated as vanilla Lua 5.1/5.2
local is_LuaJIT_21 -- LuaJIT 2.1+
local LuaJIT_arch
local ffi -- LuaJIT FFI library (as a table)
local b -- 32-bit bitwise library (as a table)
local library_name
if is_LuaJIT then
-- Assuming "bit" library is always available on LuaJIT
b = require"bit"
library_name = "bit"
-- "ffi" is intentionally disabled on some systems for safety reason
local LuaJIT_has_FFI, result = pcall(require, "ffi")
if LuaJIT_has_FFI then
ffi = result
end
is_LuaJIT_21 = not not loadstring"b=0b0"
LuaJIT_arch = type(jit) == "table" and jit.arch or ffi and ffi.arch or nil
else
-- For vanilla Lua, "bit"/"bit32" libraries are searched in global namespace only. No attempt is made to load a library if it's not loaded yet.
for _, libname in ipairs(_VERSION == "Lua 5.2" and {"bit32", "bit"} or {"bit", "bit32"}) do
if type(_G[libname]) == "table" and _G[libname].bxor then
b = _G[libname]
library_name = libname
break
end
end
end
--------------------------------------------------------------------------------
-- You can disable here some of your system's abilities (for testing purposes)
--------------------------------------------------------------------------------
-- is_LuaJIT = nil
-- is_LuaJIT_21 = nil
-- ffi = nil
-- Lua_has_int32 = nil
-- Lua_has_int64 = nil
-- b, library_name = nil
--------------------------------------------------------------------------------
if print_debug_messages then
-- Printing list of abilities of your system
print("Abilities:")
print(" Lua version: "..(is_LuaJIT and "LuaJIT "..(is_LuaJIT_21 and "2.1 " or "2.0 ")..(LuaJIT_arch or "")..(ffi and " with FFI" or " without FFI") or _VERSION))
print(" Integer bitwise operators: "..(Lua_has_int64 and "int64" or Lua_has_int32 and "int32" or "no"))
print(" 32-bit bitwise library: "..(library_name or "not found"))
end
-- Selecting the most suitable implementation for given set of abilities
local method, branch
if is_LuaJIT and ffi then
method = "Using 'ffi' library of LuaJIT"
branch = "FFI"
elseif is_LuaJIT then
method = "Using special code for sandboxed LuaJIT (no FFI)"
branch = "LJ"
elseif Lua_has_int64 then
method = "Using native int64 bitwise operators"
branch = "INT64"
elseif Lua_has_int32 then
method = "Using native int32 bitwise operators"
branch = "INT32"
elseif library_name then -- when bitwise library is available (Lua 5.2 with native library "bit32" or Lua 5.1 with external library "bit")
method = "Using '"..library_name.."' library"
branch = "LIB32"
else
method = "Emulating bitwise operators using look-up table"
branch = "EMUL"
end
if print_debug_messages then
-- Printing the implementation selected to be used on your system
print("Implementation selected:")
print(" "..method)
end
--------------------------------------------------------------------------------
-- BASIC 32-BIT BITWISE FUNCTIONS
--------------------------------------------------------------------------------
local AND, OR, XOR, SHL, SHR, ROL, ROR, NOT, NORM, HEX, XOR_BYTE
-- Only low 32 bits of function arguments matter, high bits are ignored
-- The result of all functions (except HEX) is an integer inside "correct range":
-- for "bit" library: (-2^31)..(2^31-1)
-- for "bit32" library: 0..(2^32-1)
if branch == "FFI" or branch == "LJ" or branch == "LIB32" then
-- Your system has 32-bit bitwise library (either "bit" or "bit32")
AND = b.band -- 2 arguments
OR = b.bor -- 2 arguments
XOR = b.bxor -- 2..5 arguments
SHL = b.lshift -- second argument is integer 0..31
SHR = b.rshift -- second argument is integer 0..31
ROL = b.rol or b.lrotate -- second argument is integer 0..31
ROR = b.ror or b.rrotate -- second argument is integer 0..31
NOT = b.bnot -- only for LuaJIT
NORM = b.tobit -- only for LuaJIT
HEX = b.tohex -- returns string of 8 lowercase hexadecimal digits
assert(AND and OR and XOR and SHL and SHR and ROL and ROR and NOT, "Library '"..library_name.."' is incomplete")
XOR_BYTE = XOR -- XOR of two bytes (0..255)
elseif branch == "EMUL" then
-- Emulating 32-bit bitwise operations using 53-bit floating point arithmetic
function SHL(x, n)
return (x * 2^n) % 2^32
end
function SHR(x, n)
x = x % 2^32 / 2^n
return x - x % 1
end
function ROL(x, n)
x = x % 2^32 * 2^n
local r = x % 2^32
return r + (x - r) / 2^32
end
function ROR(x, n)
x = x % 2^32 / 2^n
local r = x % 1
return r * 2^32 + (x - r)
end
local AND_of_two_bytes = {[0] = 0} -- look-up table (256*256 entries)
local idx = 0
for y = 0, 127 * 256, 256 do
for x = y, y + 127 do
x = AND_of_two_bytes[x] * 2
AND_of_two_bytes[idx] = x
AND_of_two_bytes[idx + 1] = x
AND_of_two_bytes[idx + 256] = x
AND_of_two_bytes[idx + 257] = x + 1
idx = idx + 2
end
idx = idx + 256
end
local function and_or_xor(x, y, operation)
-- operation: nil = AND, 1 = OR, 2 = XOR
local x0 = x % 2^32
local y0 = y % 2^32
local rx = x0 % 256
local ry = y0 % 256
local res = AND_of_two_bytes[rx + ry * 256]
x = x0 - rx
y = (y0 - ry) / 256
rx = x % 65536
ry = y % 256
res = res + AND_of_two_bytes[rx + ry] * 256
x = (x - rx) / 256
y = (y - ry) / 256
rx = x % 65536 + y % 256
res = res + AND_of_two_bytes[rx] * 65536
res = res + AND_of_two_bytes[(x + y - rx) / 256] * 16777216
if operation then
res = x0 + y0 - operation * res
end
return res
end
function AND(x, y)
return and_or_xor(x, y)
end
function OR(x, y)
return and_or_xor(x, y, 1)
end
function XOR(x, y, z, t, u) -- 2..5 arguments
if z then
if t then
if u then
t = and_or_xor(t, u, 2)
end
z = and_or_xor(z, t, 2)
end
y = and_or_xor(y, z, 2)
end
return and_or_xor(x, y, 2)
end
function XOR_BYTE(x, y)
return x + y - 2 * AND_of_two_bytes[x + y * 256]
end
end
HEX = HEX
or
pcall(string_format, "%x", 2^31) and
function (x) -- returns string of 8 lowercase hexadecimal digits
return string_format("%08x", x % 4294967296)
end
or
function (x) -- for OpenWrt's dialect of Lua
return string_format("%08x", (x + 2^31) % 2^32 - 2^31)
end
local function XORA5(x, y)
return XOR(x, y or 0xA5A5A5A5) % 4294967296
end
local function create_array_of_lanes()
return {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}
end
--------------------------------------------------------------------------------
-- CREATING OPTIMIZED INNER LOOP
--------------------------------------------------------------------------------
-- Inner loop functions
local sha256_feed_64, sha512_feed_128, md5_feed_64, sha1_feed_64, keccak_feed, blake2s_feed_64, blake2b_feed_128, blake3_feed_64
-- Arrays of SHA-2 "magic numbers" (in "INT64" and "FFI" branches "*_lo" arrays contain 64-bit values)
local sha2_K_lo, sha2_K_hi, sha2_H_lo, sha2_H_hi, sha3_RC_lo, sha3_RC_hi = {}, {}, {}, {}, {}, {}
local sha2_H_ext256 = {[224] = {}, [256] = sha2_H_hi}
local sha2_H_ext512_lo, sha2_H_ext512_hi = {[384] = {}, [512] = sha2_H_lo}, {[384] = {}, [512] = sha2_H_hi}
local md5_K, md5_sha1_H = {}, {0x67452301, 0xEFCDAB89, 0x98BADCFE, 0x10325476, 0xC3D2E1F0}
local md5_next_shift = {0, 0, 0, 0, 0, 0, 0, 0, 28, 25, 26, 27, 0, 0, 10, 9, 11, 12, 0, 15, 16, 17, 18, 0, 20, 22, 23, 21}
local HEX64, lanes_index_base -- defined only for branches that internally use 64-bit integers: "INT64" and "FFI"
local common_W = {} -- temporary table shared between all calculations (to avoid creating new temporary table every time)
local common_W_blake2b, common_W_blake2s, v_for_blake2s_feed_64 = common_W, common_W, {}
local K_lo_modulo, hi_factor, hi_factor_keccak = 4294967296, 0, 0
local sigma = {
{ 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16 },
{ 15, 11, 5, 9, 10, 16, 14, 7, 2, 13, 1, 3, 12, 8, 6, 4 },
{ 12, 9, 13, 1, 6, 3, 16, 14, 11, 15, 4, 7, 8, 2, 10, 5 },
{ 8, 10, 4, 2, 14, 13, 12, 15, 3, 7, 6, 11, 5, 1, 16, 9 },
{ 10, 1, 6, 8, 3, 5, 11, 16, 15, 2, 12, 13, 7, 9, 4, 14 },
{ 3, 13, 7, 11, 1, 12, 9, 4, 5, 14, 8, 6, 16, 15, 2, 10 },
{ 13, 6, 2, 16, 15, 14, 5, 11, 1, 8, 7, 4, 10, 3, 9, 12 },
{ 14, 12, 8, 15, 13, 2, 4, 10, 6, 1, 16, 5, 9, 7, 3, 11 },
{ 7, 16, 15, 10, 12, 4, 1, 9, 13, 3, 14, 8, 2, 5, 11, 6 },
{ 11, 3, 9, 5, 8, 7, 2, 6, 16, 12, 10, 15, 4, 13, 14, 1 },
}; sigma[11], sigma[12] = sigma[1], sigma[2]
local perm_blake3 = {
1, 3, 4, 11, 13, 10, 12, 6,
1, 3, 4, 11, 13, 10,
2, 7, 5, 8, 14, 15, 16, 9,
2, 7, 5, 8, 14, 15,
}
local function build_keccak_format(elem)
local keccak_format = {}
for _, size in ipairs{1, 9, 13, 17, 18, 21} do
keccak_format[size] = "<"..string_rep(elem, size)
end
return keccak_format
end
if branch == "FFI" then
local common_W_FFI_int32 = ffi.new("int32_t[?]", 80) -- 64 is enough for SHA256, but 80 is needed for SHA-1
common_W_blake2s = common_W_FFI_int32
v_for_blake2s_feed_64 = ffi.new("int32_t[?]", 16)
perm_blake3 = ffi.new("uint8_t[?]", #perm_blake3 + 1, 0, unpack(perm_blake3))
for j = 1, 10 do
sigma[j] = ffi.new("uint8_t[?]", #sigma[j] + 1, 0, unpack(sigma[j]))
end; sigma[11], sigma[12] = sigma[1], sigma[2]
-- SHA256 implementation for "LuaJIT with FFI" branch
function sha256_feed_64(H, str, offs, size)
-- offs >= 0, size >= 0, size is multiple of 64
local W, K = common_W_FFI_int32, sha2_K_hi
for pos = offs, offs + size - 1, 64 do
for j = 0, 15 do
pos = pos + 4
local a, b, c, d = byte(str, pos - 3, pos) -- slow, but doesn't depend on endianness
W[j] = OR(SHL(a, 24), SHL(b, 16), SHL(c, 8), d)
end
for j = 16, 63 do
local a, b = W[j-15], W[j-2]
W[j] = NORM( XOR(ROR(a, 7), ROL(a, 14), SHR(a, 3)) + XOR(ROL(b, 15), ROL(b, 13), SHR(b, 10)) + W[j-7] + W[j-16] )
end
local a, b, c, d, e, f, g, h = H[1], H[2], H[3], H[4], H[5], H[6], H[7], H[8]
for j = 0, 63, 8 do -- Thanks to Peter Cawley for this workaround (unroll the loop to avoid "PHI shuffling too complex" due to PHIs overlap)
local z = NORM( XOR(g, AND(e, XOR(f, g))) + XOR(ROR(e, 6), ROR(e, 11), ROL(e, 7)) + (W[j] + K[j+1] + h) )
h, g, f, e = g, f, e, NORM( d + z )
d, c, b, a = c, b, a, NORM( XOR(AND(a, XOR(b, c)), AND(b, c)) + XOR(ROR(a, 2), ROR(a, 13), ROL(a, 10)) + z )
z = NORM( XOR(g, AND(e, XOR(f, g))) + XOR(ROR(e, 6), ROR(e, 11), ROL(e, 7)) + (W[j+1] + K[j+2] + h) )
h, g, f, e = g, f, e, NORM( d + z )
d, c, b, a = c, b, a, NORM( XOR(AND(a, XOR(b, c)), AND(b, c)) + XOR(ROR(a, 2), ROR(a, 13), ROL(a, 10)) + z )
z = NORM( XOR(g, AND(e, XOR(f, g))) + XOR(ROR(e, 6), ROR(e, 11), ROL(e, 7)) + (W[j+2] + K[j+3] + h) )
h, g, f, e = g, f, e, NORM( d + z )
d, c, b, a = c, b, a, NORM( XOR(AND(a, XOR(b, c)), AND(b, c)) + XOR(ROR(a, 2), ROR(a, 13), ROL(a, 10)) + z )
z = NORM( XOR(g, AND(e, XOR(f, g))) + XOR(ROR(e, 6), ROR(e, 11), ROL(e, 7)) + (W[j+3] + K[j+4] + h) )
h, g, f, e = g, f, e, NORM( d + z )
d, c, b, a = c, b, a, NORM( XOR(AND(a, XOR(b, c)), AND(b, c)) + XOR(ROR(a, 2), ROR(a, 13), ROL(a, 10)) + z )
z = NORM( XOR(g, AND(e, XOR(f, g))) + XOR(ROR(e, 6), ROR(e, 11), ROL(e, 7)) + (W[j+4] + K[j+5] + h) )
h, g, f, e = g, f, e, NORM( d + z )
d, c, b, a = c, b, a, NORM( XOR(AND(a, XOR(b, c)), AND(b, c)) + XOR(ROR(a, 2), ROR(a, 13), ROL(a, 10)) + z )
z = NORM( XOR(g, AND(e, XOR(f, g))) + XOR(ROR(e, 6), ROR(e, 11), ROL(e, 7)) + (W[j+5] + K[j+6] + h) )
h, g, f, e = g, f, e, NORM( d + z )
d, c, b, a = c, b, a, NORM( XOR(AND(a, XOR(b, c)), AND(b, c)) + XOR(ROR(a, 2), ROR(a, 13), ROL(a, 10)) + z )
z = NORM( XOR(g, AND(e, XOR(f, g))) + XOR(ROR(e, 6), ROR(e, 11), ROL(e, 7)) + (W[j+6] + K[j+7] + h) )
h, g, f, e = g, f, e, NORM( d + z )
d, c, b, a = c, b, a, NORM( XOR(AND(a, XOR(b, c)), AND(b, c)) + XOR(ROR(a, 2), ROR(a, 13), ROL(a, 10)) + z )
z = NORM( XOR(g, AND(e, XOR(f, g))) + XOR(ROR(e, 6), ROR(e, 11), ROL(e, 7)) + (W[j+7] + K[j+8] + h) )
h, g, f, e = g, f, e, NORM( d + z )
d, c, b, a = c, b, a, NORM( XOR(AND(a, XOR(b, c)), AND(b, c)) + XOR(ROR(a, 2), ROR(a, 13), ROL(a, 10)) + z )
end
H[1], H[2], H[3], H[4] = NORM(a + H[1]), NORM(b + H[2]), NORM(c + H[3]), NORM(d + H[4])
H[5], H[6], H[7], H[8] = NORM(e + H[5]), NORM(f + H[6]), NORM(g + H[7]), NORM(h + H[8])
end
end
local common_W_FFI_int64 = ffi.new("int64_t[?]", 80)
common_W_blake2b = common_W_FFI_int64
local int64 = ffi.typeof"int64_t"
local int32 = ffi.typeof"int32_t"
local uint32 = ffi.typeof"uint32_t"
hi_factor = int64(2^32)
if is_LuaJIT_21 then -- LuaJIT 2.1 supports bitwise 64-bit operations
local AND64, OR64, XOR64, NOT64, SHL64, SHR64, ROL64, ROR64 -- introducing synonyms for better code readability
= AND, OR, XOR, NOT, SHL, SHR, ROL, ROR
HEX64 = HEX
-- BLAKE2b implementation for "LuaJIT 2.1 + FFI" branch
do
local v = ffi.new("int64_t[?]", 16)
local W = common_W_blake2b
local function G(a, b, c, d, k1, k2)
local va, vb, vc, vd = v[a], v[b], v[c], v[d]
va = W[k1] + (va + vb)
vd = ROR64(XOR64(vd, va), 32)
vc = vc + vd
vb = ROR64(XOR64(vb, vc), 24)
va = W[k2] + (va + vb)
vd = ROR64(XOR64(vd, va), 16)
vc = vc + vd
vb = ROL64(XOR64(vb, vc), 1)
v[a], v[b], v[c], v[d] = va, vb, vc, vd
end
function blake2b_feed_128(H, _, str, offs, size, bytes_compressed, last_block_size, is_last_node)
-- offs >= 0, size >= 0, size is multiple of 128
local h1, h2, h3, h4, h5, h6, h7, h8 = H[1], H[2], H[3], H[4], H[5], H[6], H[7], H[8]
for pos = offs, offs + size - 1, 128 do
if str then
for j = 1, 16 do
pos = pos + 8
local a, b, c, d, e, f, g, h = byte(str, pos - 7, pos)
W[j] = XOR64(OR(SHL(h, 24), SHL(g, 16), SHL(f, 8), e) * int64(2^32), uint32(int32(OR(SHL(d, 24), SHL(c, 16), SHL(b, 8), a))))
end
end
v[0x0], v[0x1], v[0x2], v[0x3], v[0x4], v[0x5], v[0x6], v[0x7] = h1, h2, h3, h4, h5, h6, h7, h8
v[0x8], v[0x9], v[0xA], v[0xB], v[0xD], v[0xE], v[0xF] = sha2_H_lo[1], sha2_H_lo[2], sha2_H_lo[3], sha2_H_lo[4], sha2_H_lo[6], sha2_H_lo[7], sha2_H_lo[8]
bytes_compressed = bytes_compressed + (last_block_size or 128)
v[0xC] = XOR64(sha2_H_lo[5], bytes_compressed) -- t0 = low_8_bytes(bytes_compressed)
-- t1 = high_8_bytes(bytes_compressed) = 0, message length is always below 2^53 bytes
if last_block_size then -- flag f0
v[0xE] = NOT64(v[0xE])
end
if is_last_node then -- flag f1
v[0xF] = NOT64(v[0xF])
end
for j = 1, 12 do
local row = sigma[j]
G(0, 4, 8, 12, row[ 1], row[ 2])
G(1, 5, 9, 13, row[ 3], row[ 4])
G(2, 6, 10, 14, row[ 5], row[ 6])
G(3, 7, 11, 15, row[ 7], row[ 8])
G(0, 5, 10, 15, row[ 9], row[10])
G(1, 6, 11, 12, row[11], row[12])
G(2, 7, 8, 13, row[13], row[14])
G(3, 4, 9, 14, row[15], row[16])
end
h1 = XOR64(h1, v[0x0], v[0x8])
h2 = XOR64(h2, v[0x1], v[0x9])
h3 = XOR64(h3, v[0x2], v[0xA])
h4 = XOR64(h4, v[0x3], v[0xB])
h5 = XOR64(h5, v[0x4], v[0xC])
h6 = XOR64(h6, v[0x5], v[0xD])
h7 = XOR64(h7, v[0x6], v[0xE])
h8 = XOR64(h8, v[0x7], v[0xF])
end
H[1], H[2], H[3], H[4], H[5], H[6], H[7], H[8] = h1, h2, h3, h4, h5, h6, h7, h8
return bytes_compressed
end
end
-- SHA-3 implementation for "LuaJIT 2.1 + FFI" branch
local arr64_t = ffi.typeof"int64_t[?]"
-- lanes array is indexed from 0
lanes_index_base = 0
hi_factor_keccak = int64(2^32)
function create_array_of_lanes()
return arr64_t(30) -- 25 + 5 for temporary usage
end
function keccak_feed(lanes, _, str, offs, size, block_size_in_bytes)
-- offs >= 0, size >= 0, size is multiple of block_size_in_bytes, block_size_in_bytes is positive multiple of 8
local RC = sha3_RC_lo
local qwords_qty = SHR(block_size_in_bytes, 3)
for pos = offs, offs + size - 1, block_size_in_bytes do
for j = 0, qwords_qty - 1 do
pos = pos + 8
local h, g, f, e, d, c, b, a = byte(str, pos - 7, pos) -- slow, but doesn't depend on endianness
lanes[j] = XOR64(lanes[j], OR64(OR(SHL(a, 24), SHL(b, 16), SHL(c, 8), d) * int64(2^32), uint32(int32(OR(SHL(e, 24), SHL(f, 16), SHL(g, 8), h)))))
end
for round_idx = 1, 24 do
for j = 0, 4 do
lanes[25 + j] = XOR64(lanes[j], lanes[j+5], lanes[j+10], lanes[j+15], lanes[j+20])
end
local D = XOR64(lanes[25], ROL64(lanes[27], 1))
lanes[1], lanes[6], lanes[11], lanes[16] = ROL64(XOR64(D, lanes[6]), 44), ROL64(XOR64(D, lanes[16]), 45), ROL64(XOR64(D, lanes[1]), 1), ROL64(XOR64(D, lanes[11]), 10)
lanes[21] = ROL64(XOR64(D, lanes[21]), 2)
D = XOR64(lanes[26], ROL64(lanes[28], 1))
lanes[2], lanes[7], lanes[12], lanes[22] = ROL64(XOR64(D, lanes[12]), 43), ROL64(XOR64(D, lanes[22]), 61), ROL64(XOR64(D, lanes[7]), 6), ROL64(XOR64(D, lanes[2]), 62)
lanes[17] = ROL64(XOR64(D, lanes[17]), 15)
D = XOR64(lanes[27], ROL64(lanes[29], 1))
lanes[3], lanes[8], lanes[18], lanes[23] = ROL64(XOR64(D, lanes[18]), 21), ROL64(XOR64(D, lanes[3]), 28), ROL64(XOR64(D, lanes[23]), 56), ROL64(XOR64(D, lanes[8]), 55)
lanes[13] = ROL64(XOR64(D, lanes[13]), 25)
D = XOR64(lanes[28], ROL64(lanes[25], 1))
lanes[4], lanes[14], lanes[19], lanes[24] = ROL64(XOR64(D, lanes[24]), 14), ROL64(XOR64(D, lanes[19]), 8), ROL64(XOR64(D, lanes[4]), 27), ROL64(XOR64(D, lanes[14]), 39)
lanes[9] = ROL64(XOR64(D, lanes[9]), 20)
D = XOR64(lanes[29], ROL64(lanes[26], 1))
lanes[5], lanes[10], lanes[15], lanes[20] = ROL64(XOR64(D, lanes[10]), 3), ROL64(XOR64(D, lanes[20]), 18), ROL64(XOR64(D, lanes[5]), 36), ROL64(XOR64(D, lanes[15]), 41)
lanes[0] = XOR64(D, lanes[0])
lanes[0], lanes[1], lanes[2], lanes[3], lanes[4] = XOR64(lanes[0], AND64(NOT64(lanes[1]), lanes[2]), RC[round_idx]), XOR64(lanes[1], AND64(NOT64(lanes[2]), lanes[3])), XOR64(lanes[2], AND64(NOT64(lanes[3]), lanes[4])), XOR64(lanes[3], AND64(NOT64(lanes[4]), lanes[0])), XOR64(lanes[4], AND64(NOT64(lanes[0]), lanes[1]))
lanes[5], lanes[6], lanes[7], lanes[8], lanes[9] = XOR64(lanes[8], AND64(NOT64(lanes[9]), lanes[5])), XOR64(lanes[9], AND64(NOT64(lanes[5]), lanes[6])), XOR64(lanes[5], AND64(NOT64(lanes[6]), lanes[7])), XOR64(lanes[6], AND64(NOT64(lanes[7]), lanes[8])), XOR64(lanes[7], AND64(NOT64(lanes[8]), lanes[9]))
lanes[10], lanes[11], lanes[12], lanes[13], lanes[14] = XOR64(lanes[11], AND64(NOT64(lanes[12]), lanes[13])), XOR64(lanes[12], AND64(NOT64(lanes[13]), lanes[14])), XOR64(lanes[13], AND64(NOT64(lanes[14]), lanes[10])), XOR64(lanes[14], AND64(NOT64(lanes[10]), lanes[11])), XOR64(lanes[10], AND64(NOT64(lanes[11]), lanes[12]))
lanes[15], lanes[16], lanes[17], lanes[18], lanes[19] = XOR64(lanes[19], AND64(NOT64(lanes[15]), lanes[16])), XOR64(lanes[15], AND64(NOT64(lanes[16]), lanes[17])), XOR64(lanes[16], AND64(NOT64(lanes[17]), lanes[18])), XOR64(lanes[17], AND64(NOT64(lanes[18]), lanes[19])), XOR64(lanes[18], AND64(NOT64(lanes[19]), lanes[15]))
lanes[20], lanes[21], lanes[22], lanes[23], lanes[24] = XOR64(lanes[22], AND64(NOT64(lanes[23]), lanes[24])), XOR64(lanes[23], AND64(NOT64(lanes[24]), lanes[20])), XOR64(lanes[24], AND64(NOT64(lanes[20]), lanes[21])), XOR64(lanes[20], AND64(NOT64(lanes[21]), lanes[22])), XOR64(lanes[21], AND64(NOT64(lanes[22]), lanes[23]))
end
end
end
local A5_long = 0xA5A5A5A5 * int64(2^32 + 1) -- It's impossible to use constant 0xA5A5A5A5A5A5A5A5LL because it will raise syntax error on other Lua versions
function XORA5(long, long2)
return XOR64(long, long2 or A5_long)
end
-- SHA512 implementation for "LuaJIT 2.1 + FFI" branch
function sha512_feed_128(H, _, str, offs, size)
-- offs >= 0, size >= 0, size is multiple of 128
local W, K = common_W_FFI_int64, sha2_K_lo
for pos = offs, offs + size - 1, 128 do
for j = 0, 15 do
pos = pos + 8
local a, b, c, d, e, f, g, h = byte(str, pos - 7, pos) -- slow, but doesn't depend on endianness
W[j] = OR64(OR(SHL(a, 24), SHL(b, 16), SHL(c, 8), d) * int64(2^32), uint32(int32(OR(SHL(e, 24), SHL(f, 16), SHL(g, 8), h))))
end
for j = 16, 79 do
local a, b = W[j-15], W[j-2]
W[j] = XOR64(ROR64(a, 1), ROR64(a, 8), SHR64(a, 7)) + XOR64(ROR64(b, 19), ROL64(b, 3), SHR64(b, 6)) + W[j-7] + W[j-16]
end
local a, b, c, d, e, f, g, h = H[1], H[2], H[3], H[4], H[5], H[6], H[7], H[8]
for j = 0, 79, 8 do
local z = XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23)) + XOR64(g, AND64(e, XOR64(f, g))) + h + K[j+1] + W[j]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XOR64(AND64(XOR64(a, b), c), AND64(a, b)) + XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30)) + z
z = XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23)) + XOR64(g, AND64(e, XOR64(f, g))) + h + K[j+2] + W[j+1]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XOR64(AND64(XOR64(a, b), c), AND64(a, b)) + XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30)) + z
z = XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23)) + XOR64(g, AND64(e, XOR64(f, g))) + h + K[j+3] + W[j+2]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XOR64(AND64(XOR64(a, b), c), AND64(a, b)) + XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30)) + z
z = XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23)) + XOR64(g, AND64(e, XOR64(f, g))) + h + K[j+4] + W[j+3]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XOR64(AND64(XOR64(a, b), c), AND64(a, b)) + XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30)) + z
z = XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23)) + XOR64(g, AND64(e, XOR64(f, g))) + h + K[j+5] + W[j+4]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XOR64(AND64(XOR64(a, b), c), AND64(a, b)) + XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30)) + z
z = XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23)) + XOR64(g, AND64(e, XOR64(f, g))) + h + K[j+6] + W[j+5]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XOR64(AND64(XOR64(a, b), c), AND64(a, b)) + XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30)) + z
z = XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23)) + XOR64(g, AND64(e, XOR64(f, g))) + h + K[j+7] + W[j+6]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XOR64(AND64(XOR64(a, b), c), AND64(a, b)) + XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30)) + z
z = XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23)) + XOR64(g, AND64(e, XOR64(f, g))) + h + K[j+8] + W[j+7]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XOR64(AND64(XOR64(a, b), c), AND64(a, b)) + XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30)) + z
end
H[1] = a + H[1]
H[2] = b + H[2]
H[3] = c + H[3]
H[4] = d + H[4]
H[5] = e + H[5]
H[6] = f + H[6]
H[7] = g + H[7]
H[8] = h + H[8]
end
end
else -- LuaJIT 2.0 doesn't support 64-bit bitwise operations
local U = ffi.new("union{int64_t i64; struct{int32_t "..(ffi.abi("le") and "lo, hi" or "hi, lo")..";} i32;}[3]")
-- this array of unions is used for fast splitting int64 into int32_high and int32_low
-- "xorrific" 64-bit functions :-)
-- int64 input is splitted into two int32 parts, some bitwise 32-bit operations are performed, finally the result is converted to int64
-- these functions are needed because bit.* functions in LuaJIT 2.0 don't work with int64_t
local function XORROR64_1(a)
-- return XOR64(ROR64(a, 1), ROR64(a, 8), SHR64(a, 7))
U[0].i64 = a
local a_lo, a_hi = U[0].i32.lo, U[0].i32.hi
local t_lo = XOR(SHR(a_lo, 1), SHL(a_hi, 31), SHR(a_lo, 8), SHL(a_hi, 24), SHR(a_lo, 7), SHL(a_hi, 25))
local t_hi = XOR(SHR(a_hi, 1), SHL(a_lo, 31), SHR(a_hi, 8), SHL(a_lo, 24), SHR(a_hi, 7))
return t_hi * int64(2^32) + uint32(int32(t_lo))
end
local function XORROR64_2(b)
-- return XOR64(ROR64(b, 19), ROL64(b, 3), SHR64(b, 6))
U[0].i64 = b
local b_lo, b_hi = U[0].i32.lo, U[0].i32.hi
local u_lo = XOR(SHR(b_lo, 19), SHL(b_hi, 13), SHL(b_lo, 3), SHR(b_hi, 29), SHR(b_lo, 6), SHL(b_hi, 26))
local u_hi = XOR(SHR(b_hi, 19), SHL(b_lo, 13), SHL(b_hi, 3), SHR(b_lo, 29), SHR(b_hi, 6))
return u_hi * int64(2^32) + uint32(int32(u_lo))
end
local function XORROR64_3(e)
-- return XOR64(ROR64(e, 14), ROR64(e, 18), ROL64(e, 23))
U[0].i64 = e
local e_lo, e_hi = U[0].i32.lo, U[0].i32.hi
local u_lo = XOR(SHR(e_lo, 14), SHL(e_hi, 18), SHR(e_lo, 18), SHL(e_hi, 14), SHL(e_lo, 23), SHR(e_hi, 9))
local u_hi = XOR(SHR(e_hi, 14), SHL(e_lo, 18), SHR(e_hi, 18), SHL(e_lo, 14), SHL(e_hi, 23), SHR(e_lo, 9))
return u_hi * int64(2^32) + uint32(int32(u_lo))
end
local function XORROR64_6(a)
-- return XOR64(ROR64(a, 28), ROL64(a, 25), ROL64(a, 30))
U[0].i64 = a
local b_lo, b_hi = U[0].i32.lo, U[0].i32.hi
local u_lo = XOR(SHR(b_lo, 28), SHL(b_hi, 4), SHL(b_lo, 30), SHR(b_hi, 2), SHL(b_lo, 25), SHR(b_hi, 7))
local u_hi = XOR(SHR(b_hi, 28), SHL(b_lo, 4), SHL(b_hi, 30), SHR(b_lo, 2), SHL(b_hi, 25), SHR(b_lo, 7))
return u_hi * int64(2^32) + uint32(int32(u_lo))
end
local function XORROR64_4(e, f, g)
-- return XOR64(g, AND64(e, XOR64(f, g)))
U[0].i64 = f
U[1].i64 = g
U[2].i64 = e
local f_lo, f_hi = U[0].i32.lo, U[0].i32.hi
local g_lo, g_hi = U[1].i32.lo, U[1].i32.hi
local e_lo, e_hi = U[2].i32.lo, U[2].i32.hi
local result_lo = XOR(g_lo, AND(e_lo, XOR(f_lo, g_lo)))
local result_hi = XOR(g_hi, AND(e_hi, XOR(f_hi, g_hi)))
return result_hi * int64(2^32) + uint32(int32(result_lo))
end
local function XORROR64_5(a, b, c)
-- return XOR64(AND64(XOR64(a, b), c), AND64(a, b))
U[0].i64 = a
U[1].i64 = b
U[2].i64 = c
local a_lo, a_hi = U[0].i32.lo, U[0].i32.hi
local b_lo, b_hi = U[1].i32.lo, U[1].i32.hi
local c_lo, c_hi = U[2].i32.lo, U[2].i32.hi
local result_lo = XOR(AND(XOR(a_lo, b_lo), c_lo), AND(a_lo, b_lo))
local result_hi = XOR(AND(XOR(a_hi, b_hi), c_hi), AND(a_hi, b_hi))
return result_hi * int64(2^32) + uint32(int32(result_lo))
end
local function XORROR64_7(a, b, m)
-- return ROR64(XOR64(a, b), m), m = 1..31
U[0].i64 = a
U[1].i64 = b
local a_lo, a_hi = U[0].i32.lo, U[0].i32.hi
local b_lo, b_hi = U[1].i32.lo, U[1].i32.hi
local c_lo, c_hi = XOR(a_lo, b_lo), XOR(a_hi, b_hi)
local t_lo = XOR(SHR(c_lo, m), SHL(c_hi, -m))
local t_hi = XOR(SHR(c_hi, m), SHL(c_lo, -m))
return t_hi * int64(2^32) + uint32(int32(t_lo))
end
local function XORROR64_8(a, b)
-- return ROL64(XOR64(a, b), 1)
U[0].i64 = a
U[1].i64 = b
local a_lo, a_hi = U[0].i32.lo, U[0].i32.hi
local b_lo, b_hi = U[1].i32.lo, U[1].i32.hi
local c_lo, c_hi = XOR(a_lo, b_lo), XOR(a_hi, b_hi)
local t_lo = XOR(SHL(c_lo, 1), SHR(c_hi, 31))
local t_hi = XOR(SHL(c_hi, 1), SHR(c_lo, 31))
return t_hi * int64(2^32) + uint32(int32(t_lo))
end
local function XORROR64_9(a, b)
-- return ROR64(XOR64(a, b), 32)
U[0].i64 = a
U[1].i64 = b
local a_lo, a_hi = U[0].i32.lo, U[0].i32.hi
local b_lo, b_hi = U[1].i32.lo, U[1].i32.hi
local t_hi, t_lo = XOR(a_lo, b_lo), XOR(a_hi, b_hi)
return t_hi * int64(2^32) + uint32(int32(t_lo))
end
local function XOR64(a, b)
-- return XOR64(a, b)
U[0].i64 = a
U[1].i64 = b
local a_lo, a_hi = U[0].i32.lo, U[0].i32.hi
local b_lo, b_hi = U[1].i32.lo, U[1].i32.hi
local t_lo, t_hi = XOR(a_lo, b_lo), XOR(a_hi, b_hi)
return t_hi * int64(2^32) + uint32(int32(t_lo))
end
local function XORROR64_11(a, b, c)
-- return XOR64(a, b, c)
U[0].i64 = a
U[1].i64 = b
U[2].i64 = c
local a_lo, a_hi = U[0].i32.lo, U[0].i32.hi
local b_lo, b_hi = U[1].i32.lo, U[1].i32.hi
local c_lo, c_hi = U[2].i32.lo, U[2].i32.hi
local t_lo, t_hi = XOR(a_lo, b_lo, c_lo), XOR(a_hi, b_hi, c_hi)
return t_hi * int64(2^32) + uint32(int32(t_lo))
end
function XORA5(long, long2)
-- return XOR64(long, long2 or 0xA5A5A5A5A5A5A5A5)
U[0].i64 = long
local lo32, hi32 = U[0].i32.lo, U[0].i32.hi
local long2_lo, long2_hi = 0xA5A5A5A5, 0xA5A5A5A5
if long2 then
U[1].i64 = long2
long2_lo, long2_hi = U[1].i32.lo, U[1].i32.hi
end
lo32 = XOR(lo32, long2_lo)
hi32 = XOR(hi32, long2_hi)
return hi32 * int64(2^32) + uint32(int32(lo32))
end
function HEX64(long)
U[0].i64 = long
return HEX(U[0].i32.hi)..HEX(U[0].i32.lo)
end
-- SHA512 implementation for "LuaJIT 2.0 + FFI" branch
function sha512_feed_128(H, _, str, offs, size)
-- offs >= 0, size >= 0, size is multiple of 128
local W, K = common_W_FFI_int64, sha2_K_lo
for pos = offs, offs + size - 1, 128 do
for j = 0, 15 do
pos = pos + 8
local a, b, c, d, e, f, g, h = byte(str, pos - 7, pos) -- slow, but doesn't depend on endianness
W[j] = OR(SHL(a, 24), SHL(b, 16), SHL(c, 8), d) * int64(2^32) + uint32(int32(OR(SHL(e, 24), SHL(f, 16), SHL(g, 8), h)))
end
for j = 16, 79 do
W[j] = XORROR64_1(W[j-15]) + XORROR64_2(W[j-2]) + W[j-7] + W[j-16]
end
local a, b, c, d, e, f, g, h = H[1], H[2], H[3], H[4], H[5], H[6], H[7], H[8]
for j = 0, 79, 8 do
local z = XORROR64_3(e) + XORROR64_4(e, f, g) + h + K[j+1] + W[j]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XORROR64_5(a, b, c) + XORROR64_6(a) + z
z = XORROR64_3(e) + XORROR64_4(e, f, g) + h + K[j+2] + W[j+1]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XORROR64_5(a, b, c) + XORROR64_6(a) + z
z = XORROR64_3(e) + XORROR64_4(e, f, g) + h + K[j+3] + W[j+2]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XORROR64_5(a, b, c) + XORROR64_6(a) + z
z = XORROR64_3(e) + XORROR64_4(e, f, g) + h + K[j+4] + W[j+3]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XORROR64_5(a, b, c) + XORROR64_6(a) + z
z = XORROR64_3(e) + XORROR64_4(e, f, g) + h + K[j+5] + W[j+4]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XORROR64_5(a, b, c) + XORROR64_6(a) + z
z = XORROR64_3(e) + XORROR64_4(e, f, g) + h + K[j+6] + W[j+5]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XORROR64_5(a, b, c) + XORROR64_6(a) + z
z = XORROR64_3(e) + XORROR64_4(e, f, g) + h + K[j+7] + W[j+6]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XORROR64_5(a, b, c) + XORROR64_6(a) + z
z = XORROR64_3(e) + XORROR64_4(e, f, g) + h + K[j+8] + W[j+7]
h, g, f, e = g, f, e, z + d
d, c, b, a = c, b, a, XORROR64_5(a, b, c) + XORROR64_6(a) + z
end
H[1] = a + H[1]
H[2] = b + H[2]
H[3] = c + H[3]
H[4] = d + H[4]
H[5] = e + H[5]
H[6] = f + H[6]
H[7] = g + H[7]
H[8] = h + H[8]
end
end
-- BLAKE2b implementation for "LuaJIT 2.0 + FFI" branch
do
local v = ffi.new("int64_t[?]", 16)
local W = common_W_blake2b
local function G(a, b, c, d, k1, k2)
local va, vb, vc, vd = v[a], v[b], v[c], v[d]
va = W[k1] + (va + vb)
vd = XORROR64_9(vd, va)
vc = vc + vd
vb = XORROR64_7(vb, vc, 24)
va = W[k2] + (va + vb)
vd = XORROR64_7(vd, va, 16)
vc = vc + vd
vb = XORROR64_8(vb, vc)
v[a], v[b], v[c], v[d] = va, vb, vc, vd
end
function blake2b_feed_128(H, _, str, offs, size, bytes_compressed, last_block_size, is_last_node)
-- offs >= 0, size >= 0, size is multiple of 128
local h1, h2, h3, h4, h5, h6, h7, h8 = H[1], H[2], H[3], H[4], H[5], H[6], H[7], H[8]
for pos = offs, offs + size - 1, 128 do
if str then
for j = 1, 16 do
pos = pos + 8
local a, b, c, d, e, f, g, h = byte(str, pos - 7, pos)
W[j] = XOR64(OR(SHL(h, 24), SHL(g, 16), SHL(f, 8), e) * int64(2^32), uint32(int32(OR(SHL(d, 24), SHL(c, 16), SHL(b, 8), a))))
end
end
v[0x0], v[0x1], v[0x2], v[0x3], v[0x4], v[0x5], v[0x6], v[0x7] = h1, h2, h3, h4, h5, h6, h7, h8
v[0x8], v[0x9], v[0xA], v[0xB], v[0xD], v[0xE], v[0xF] = sha2_H_lo[1], sha2_H_lo[2], sha2_H_lo[3], sha2_H_lo[4], sha2_H_lo[6], sha2_H_lo[7], sha2_H_lo[8]
bytes_compressed = bytes_compressed + (last_block_size or 128)
v[0xC] = XOR64(sha2_H_lo[5], bytes_compressed) -- t0 = low_8_bytes(bytes_compressed)
-- t1 = high_8_bytes(bytes_compressed) = 0, message length is always below 2^53 bytes
if last_block_size then -- flag f0
v[0xE] = -1 - v[0xE]
end
if is_last_node then -- flag f1
v[0xF] = -1 - v[0xF]
end
for j = 1, 12 do
local row = sigma[j]
G(0, 4, 8, 12, row[ 1], row[ 2])
G(1, 5, 9, 13, row[ 3], row[ 4])
G(2, 6, 10, 14, row[ 5], row[ 6])
G(3, 7, 11, 15, row[ 7], row[ 8])
G(0, 5, 10, 15, row[ 9], row[10])
G(1, 6, 11, 12, row[11], row[12])
G(2, 7, 8, 13, row[13], row[14])
G(3, 4, 9, 14, row[15], row[16])
end
h1 = XORROR64_11(h1, v[0x0], v[0x8])
h2 = XORROR64_11(h2, v[0x1], v[0x9])
h3 = XORROR64_11(h3, v[0x2], v[0xA])
h4 = XORROR64_11(h4, v[0x3], v[0xB])
h5 = XORROR64_11(h5, v[0x4], v[0xC])
h6 = XORROR64_11(h6, v[0x5], v[0xD])
h7 = XORROR64_11(h7, v[0x6], v[0xE])
h8 = XORROR64_11(h8, v[0x7], v[0xF])
end
H[1], H[2], H[3], H[4], H[5], H[6], H[7], H[8] = h1, h2, h3, h4, h5, h6, h7, h8
return bytes_compressed
end
end
end
-- MD5 implementation for "LuaJIT with FFI" branch
function md5_feed_64(H, str, offs, size)
-- offs >= 0, size >= 0, size is multiple of 64
local W, K = common_W_FFI_int32, md5_K
for pos = offs, offs + size - 1, 64 do
for j = 0, 15 do
pos = pos + 4
local a, b, c, d = byte(str, pos - 3, pos) -- slow, but doesn't depend on endianness
W[j] = OR(SHL(d, 24), SHL(c, 16), SHL(b, 8), a)
end
local a, b, c, d = H[1], H[2], H[3], H[4]
for j = 0, 15, 4 do
a, d, c, b = d, c, b, NORM(ROL(XOR(d, AND(b, XOR(c, d))) + (K[j+1] + W[j ] + a), 7) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(d, AND(b, XOR(c, d))) + (K[j+2] + W[j+1] + a), 12) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(d, AND(b, XOR(c, d))) + (K[j+3] + W[j+2] + a), 17) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(d, AND(b, XOR(c, d))) + (K[j+4] + W[j+3] + a), 22) + b)
end
for j = 16, 31, 4 do
local g = 5*j
a, d, c, b = d, c, b, NORM(ROL(XOR(c, AND(d, XOR(b, c))) + (K[j+1] + W[AND(g + 1, 15)] + a), 5) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(c, AND(d, XOR(b, c))) + (K[j+2] + W[AND(g + 6, 15)] + a), 9) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(c, AND(d, XOR(b, c))) + (K[j+3] + W[AND(g - 5, 15)] + a), 14) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(c, AND(d, XOR(b, c))) + (K[j+4] + W[AND(g , 15)] + a), 20) + b)
end
for j = 32, 47, 4 do
local g = 3*j
a, d, c, b = d, c, b, NORM(ROL(XOR(b, c, d) + (K[j+1] + W[AND(g + 5, 15)] + a), 4) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(b, c, d) + (K[j+2] + W[AND(g + 8, 15)] + a), 11) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(b, c, d) + (K[j+3] + W[AND(g - 5, 15)] + a), 16) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(b, c, d) + (K[j+4] + W[AND(g - 2, 15)] + a), 23) + b)
end
for j = 48, 63, 4 do
local g = 7*j
a, d, c, b = d, c, b, NORM(ROL(XOR(c, OR(b, NOT(d))) + (K[j+1] + W[AND(g , 15)] + a), 6) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(c, OR(b, NOT(d))) + (K[j+2] + W[AND(g + 7, 15)] + a), 10) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(c, OR(b, NOT(d))) + (K[j+3] + W[AND(g - 2, 15)] + a), 15) + b)
a, d, c, b = d, c, b, NORM(ROL(XOR(c, OR(b, NOT(d))) + (K[j+4] + W[AND(g + 5, 15)] + a), 21) + b)
end
H[1], H[2], H[3], H[4] = NORM(a + H[1]), NORM(b + H[2]), NORM(c + H[3]), NORM(d + H[4])
end
end
-- SHA-1 implementation for "LuaJIT with FFI" branch
function sha1_feed_64(H, str, offs, size)
-- offs >= 0, size >= 0, size is multiple of 64
local W = common_W_FFI_int32
for pos = offs, offs + size - 1, 64 do
for j = 0, 15 do
pos = pos + 4
local a, b, c, d = byte(str, pos - 3, pos) -- slow, but doesn't depend on endianness
W[j] = OR(SHL(a, 24), SHL(b, 16), SHL(c, 8), d)
end
for j = 16, 79 do
W[j] = ROL(XOR(W[j-3], W[j-8], W[j-14], W[j-16]), 1)
end
local a, b, c, d, e = H[1], H[2], H[3], H[4], H[5]
for j = 0, 19, 5 do
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(d, AND(b, XOR(d, c))) + (W[j] + 0x5A827999 + e)) -- constant = floor(2^30 * sqrt(2))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(d, AND(b, XOR(d, c))) + (W[j+1] + 0x5A827999 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(d, AND(b, XOR(d, c))) + (W[j+2] + 0x5A827999 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(d, AND(b, XOR(d, c))) + (W[j+3] + 0x5A827999 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(d, AND(b, XOR(d, c))) + (W[j+4] + 0x5A827999 + e))
end
for j = 20, 39, 5 do
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j] + 0x6ED9EBA1 + e)) -- 2^30 * sqrt(3)
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j+1] + 0x6ED9EBA1 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j+2] + 0x6ED9EBA1 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j+3] + 0x6ED9EBA1 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j+4] + 0x6ED9EBA1 + e))
end
for j = 40, 59, 5 do
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(AND(d, XOR(b, c)), AND(b, c)) + (W[j] + 0x8F1BBCDC + e)) -- 2^30 * sqrt(5)
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(AND(d, XOR(b, c)), AND(b, c)) + (W[j+1] + 0x8F1BBCDC + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(AND(d, XOR(b, c)), AND(b, c)) + (W[j+2] + 0x8F1BBCDC + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(AND(d, XOR(b, c)), AND(b, c)) + (W[j+3] + 0x8F1BBCDC + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(AND(d, XOR(b, c)), AND(b, c)) + (W[j+4] + 0x8F1BBCDC + e))
end
for j = 60, 79, 5 do
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j] + 0xCA62C1D6 + e)) -- 2^30 * sqrt(10)
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j+1] + 0xCA62C1D6 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j+2] + 0xCA62C1D6 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j+3] + 0xCA62C1D6 + e))
e, d, c, b, a = d, c, ROR(b, 2), a, NORM(ROL(a, 5) + XOR(b, c, d) + (W[j+4] + 0xCA62C1D6 + e))
end
H[1], H[2], H[3], H[4], H[5] = NORM(a + H[1]), NORM(b + H[2]), NORM(c + H[3]), NORM(d + H[4]), NORM(e + H[5])
end
end
end
if branch == "FFI" and not is_LuaJIT_21 or branch == "LJ" then
if branch == "FFI" then
local arr32_t = ffi.typeof"int32_t[?]"
function create_array_of_lanes()
return arr32_t(31) -- 25 + 5 + 1 (due to 1-based indexing)
end