const std = @import("std");
const assert = std.debug.assert;
const math = std.math;
const mem = std.mem;
pub fn KeccakF(comptime f: u11) type {
comptime assert(f > 200 and f <= 1600 and f % 200 == 0);
const T = std.meta.Int(.unsigned, f / 25);
const Block = [25]T;
const PI = [_]u5{
10, 7, 11, 17, 18, 3, 5, 16, 8, 21, 24, 4, 15, 23, 19, 13, 12, 2, 20, 14, 22, 9, 6, 1,
};
return struct {
const Self = @This();
pub const block_bytes = f / 8;
pub const max_rounds = 12 + 2 * math.log2(f / 25);
const RC = rc: {
const RC64 = [_]u64{
0x0000000000000001, 0x0000000000008082, 0x800000000000808a, 0x8000000080008000,
0x000000000000808b, 0x0000000080000001, 0x8000000080008081, 0x8000000000008009,
0x000000000000008a, 0x0000000000000088, 0x0000000080008009, 0x000000008000000a,
0x000000008000808b, 0x800000000000008b, 0x8000000000008089, 0x8000000000008003,
0x8000000000008002, 0x8000000000000080, 0x000000000000800a, 0x800000008000000a,
0x8000000080008081, 0x8000000000008080, 0x0000000080000001, 0x8000000080008008,
};
var rc: [max_rounds]T = undefined;
for (&rc, RC64[0..max_rounds]) |*t, c| t.* = @truncate(T, c);
break :rc rc;
};
st: Block = [_]T{0} ** 25,
pub fn init(bytes: [block_bytes]u8) Self {
var self: Self = undefined;
inline for (&self.st, 0..) |*r, i| {
r.* = mem.readIntLittle(T, bytes[@sizeOf(T) * i ..][0..@sizeOf(T)]);
}
return self;
}
pub fn asBytes(self: *Self) *[block_bytes]u8 {
return mem.asBytes(&self.st);
}
pub fn endianSwap(self: *Self) void {
for (&self.st) |*w| {
w.* = mem.littleTooNative(T, w.*);
}
}
pub fn setBytes(self: *Self, bytes: []const u8) void {
var i: usize = 0;
while (i + @sizeOf(T) <= bytes.len) : (i += @sizeOf(T)) {
self.st[i / @sizeOf(T)] = mem.readIntLittle(T, bytes[i..][0..@sizeOf(T)]);
}
if (i < bytes.len) {
var padded = [_]u8{0} ** @sizeOf(T);
mem.copy(u8, padded[0 .. bytes.len - i], bytes[i..]);
self.st[i / @sizeOf(T)] = mem.readIntLittle(T, padded[0..]);
}
}
pub fn addByte(self: *Self, byte: u8, offset: usize) void {
const z = @sizeOf(T) * @truncate(math.Log2Int(T), offset % @sizeOf(T));
self.st[offset / @sizeOf(T)] ^= @as(T, byte) << z;
}
pub fn addBytes(self: *Self, bytes: []const u8) void {
var i: usize = 0;
while (i + @sizeOf(T) <= bytes.len) : (i += @sizeOf(T)) {
self.st[i / @sizeOf(T)] ^= mem.readIntLittle(T, bytes[i..][0..@sizeOf(T)]);
}
if (i < bytes.len) {
var padded = [_]u8{0} ** @sizeOf(T);
mem.copy(u8, padded[0 .. bytes.len - i], bytes[i..]);
self.st[i / @sizeOf(T)] ^= mem.readIntLittle(T, padded[0..]);
}
}
pub fn extractBytes(self: *Self, out: []u8) void {
var i: usize = 0;
while (i + @sizeOf(T) <= out.len) : (i += @sizeOf(T)) {
mem.writeIntLittle(T, out[i..][0..@sizeOf(T)], self.st[i / @sizeOf(T)]);
}
if (i < out.len) {
var padded = [_]u8{0} ** @sizeOf(T);
mem.writeIntLittle(T, padded[0..], self.st[i / @sizeOf(T)]);
mem.copy(u8, out[i..], padded[0 .. out.len - i]);
}
}
pub fn xorBytes(self: *Self, out: []u8, in: []const u8) void {
assert(out.len == in.len);
var i: usize = 0;
while (i + @sizeOf(T) <= in.len) : (i += @sizeOf(T)) {
const x = mem.readIntNative(T, in[i..][0..@sizeOf(T)]) ^ mem.nativeToLittle(T, self.st[i / @sizeOf(T)]);
mem.writeIntNative(T, out[i..][0..@sizeOf(T)], x);
}
if (i < in.len) {
var padded = [_]u8{0} ** @sizeOf(T);
mem.copy(u8, padded[0 .. in.len - i], in[i..]);
const x = mem.readIntNative(T, &padded) ^ mem.nativeToLittle(T, self.st[i / @sizeOf(T)]);
mem.writeIntNative(T, &padded, x);
mem.copy(u8, out[i..], padded[0 .. in.len - i]);
}
}
pub fn clear(self: *Self, from: usize, to: usize) void {
mem.set(T, self.st[from / @sizeOf(T) .. (to + @sizeOf(T) - 1) / @sizeOf(T)], 0);
}
pub fn secureZero(self: *Self) void {
std.crypto.utils.secureZero(T, &self.st);
}
inline fn round(self: *Self, rc: T) void {
const st = &self.st;
var t = [_]T{0} ** 5;
inline for (0..5) |i| {
inline for (0..5) |j| {
t[i] ^= st[j * 5 + i];
}
}
inline for (0..5) |i| {
inline for (0..5) |j| {
st[j * 5 + i] ^= t[(i + 4) % 5] ^ math.rotl(T, t[(i + 1) % 5], 1);
}
}
var last = st[1];
comptime var rotc = 0;
inline for (0..24) |i| {
const x = PI[i];
const tmp = st[x];
rotc = (rotc + i + 1) % @bitSizeOf(T);
st[x] = math.rotl(T, last, rotc);
last = tmp;
}
inline for (0..5) |i| {
inline for (0..5) |j| {
t[j] = st[i * 5 + j];
}
inline for (0..5) |j| {
st[i * 5 + j] = t[j] ^ (~t[(j + 1) % 5] & t[(j + 2) % 5]);
}
}
st[0] ^= rc;
}
pub fn permuteR(self: *Self, comptime rounds: u5) void {
var i = RC.len - rounds;
while (i < RC.len - RC.len % 3) : (i += 3) {
self.round(RC[i]);
self.round(RC[i + 1]);
self.round(RC[i + 2]);
}
while (i < RC.len) : (i += 1) {
self.round(RC[i]);
}
}
pub fn permute(self: *Self) void {
self.permuteR(max_rounds);
}
};
}
pub fn State(comptime f: u11, comptime capacity: u11, comptime delim: u8, comptime rounds: u5) type {
comptime assert(f > 200 and f <= 1600 and f % 200 == 0);
comptime assert(capacity < f and capacity % 8 == 0);
return struct {
const Self = @This();
pub const rate = KeccakF(f).block_bytes - capacity / 8;
pub const Options = struct {};
offset: usize = 0,
buf: [rate]u8 = undefined,
st: KeccakF(f) = .{},
pub fn absorb(self: *Self, bytes_: []const u8) void {
var bytes = bytes_;
if (self.offset > 0) {
const left = math.min(rate - self.offset, bytes.len);
mem.copy(u8, self.buf[self.offset..], bytes[0..left]);
self.offset += left;
if (self.offset == rate) {
self.offset = 0;
self.st.addBytes(self.buf[0..]);
self.st.permuteR(rounds);
}
if (left == bytes.len) return;
bytes = bytes[left..];
}
while (bytes.len >= rate) {
self.st.addBytes(bytes[0..rate]);
self.st.permuteR(rounds);
bytes = bytes[rate..];
}
if (bytes.len > 0) {
mem.copy(u8, &self.buf, bytes);
self.offset = bytes.len;
}
}
pub fn pad(self: *Self) void {
self.st.addBytes(self.buf[0..self.offset]);
self.st.addByte(delim, self.offset);
self.st.addByte(0x80, rate - 1);
self.st.permuteR(rounds);
self.offset = 0;
}
pub fn squeeze(self: *Self, out: []u8) void {
var i: usize = 0;
while (i < out.len) : (i += rate) {
const left = math.min(rate, out.len - i);
self.st.extractBytes(out[i..][0..left]);
self.st.permuteR(rounds);
}
}
};
}
test "Keccak-f800" {
var st: KeccakF(800) = .{
.st = .{
0xE531D45D, 0xF404C6FB, 0x23A0BF99, 0xF1F8452F, 0x51FFD042, 0xE539F578, 0xF00B80A7,
0xAF973664, 0xBF5AF34C, 0x227A2424, 0x88172715, 0x9F685884, 0xB15CD054, 0x1BF4FC0E,
0x6166FA91, 0x1A9E599A, 0xA3970A1F, 0xAB659687, 0xAFAB8D68, 0xE74B1015, 0x34001A98,
0x4119EFF3, 0x930A0E76, 0x87B28070, 0x11EFE996,
},
};
st.permute();
const expected: [25]u32 = .{
0x75BF2D0D, 0x9B610E89, 0xC826AF40, 0x64CD84AB, 0xF905BDD6, 0xBC832835, 0x5F8001B9,
0x15662CCE, 0x8E38C95E, 0x701FE543, 0x1B544380, 0x89ACDEFF, 0x51EDB5DE, 0x0E9702D9,
0x6C19AA16, 0xA2913EEE, 0x60754E9A, 0x9819063C, 0xF4709254, 0xD09F9084, 0x772DA259,
0x1DB35DF7, 0x5AA60162, 0x358825D5, 0xB3783BAB,
};
try std.testing.expectEqualSlices(u32, &st.st, &expected);
}