zig/lib/std/crypto/gimli.zig

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// Gimli is a 384-bit permutation designed to achieve high security with high
// performance across a broad range of platforms, including 64-bit Intel/AMD
// server CPUs, 64-bit and 32-bit ARM smartphone CPUs, 32-bit ARM
// microcontrollers, 8-bit AVR microcontrollers, FPGAs, ASICs without
// side-channel protection, and ASICs with side-channel protection.
//
// https://gimli.cr.yp.to/
// https://csrc.nist.gov/CSRC/media/Projects/Lightweight-Cryptography/documents/round-1/spec-doc/gimli-spec.pdf
const std = @import("../std.zig");
const mem = std.mem;
const math = std.math;
const debug = std.debug;
const assert = std.debug.assert;
const testing = std.testing;
const htest = @import("test.zig");
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const Vector = std.meta.Vector;
const AuthenticationError = std.crypto.errors.AuthenticationError;
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pub const State = struct {
pub const BLOCKBYTES = 48;
pub const RATE = 16;
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data: [BLOCKBYTES / 4]u32 align(16),
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const Self = @This();
pub fn init(initial_state: [State.BLOCKBYTES]u8) Self {
var data: [BLOCKBYTES / 4]u32 = undefined;
var i: usize = 0;
while (i < State.BLOCKBYTES) : (i += 4) {
data[i / 4] = mem.readIntNative(u32, initial_state[i..][0..4]);
}
return Self{ .data = data };
}
/// TODO follow the span() convention instead of having this and `toSliceConst`
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pub fn toSlice(self: *Self) *[BLOCKBYTES]u8 {
return mem.asBytes(&self.data);
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}
/// TODO follow the span() convention instead of having this and `toSlice`
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pub fn toSliceConst(self: *const Self) *const [BLOCKBYTES]u8 {
return mem.asBytes(&self.data);
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}
inline fn endianSwap(self: *Self) void {
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for (self.data) |*w| {
w.* = mem.littleToNative(u32, w.*);
}
}
fn permute_unrolled(self: *Self) void {
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self.endianSwap();
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const state = &self.data;
comptime var round = @as(u32, 24);
inline while (round > 0) : (round -= 1) {
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var column = @as(usize, 0);
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while (column < 4) : (column += 1) {
const x = math.rotl(u32, state[column], 24);
const y = math.rotl(u32, state[4 + column], 9);
const z = state[8 + column];
state[8 + column] = ((x ^ (z << 1)) ^ ((y & z) << 2));
state[4 + column] = ((y ^ x) ^ ((x | z) << 1));
state[column] = ((z ^ y) ^ ((x & y) << 3));
}
switch (round & 3) {
0 => {
mem.swap(u32, &state[0], &state[1]);
mem.swap(u32, &state[2], &state[3]);
state[0] ^= round | 0x9e377900;
},
2 => {
mem.swap(u32, &state[0], &state[2]);
mem.swap(u32, &state[1], &state[3]);
},
else => {},
}
}
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self.endianSwap();
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}
fn permute_small(self: *Self) void {
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self.endianSwap();
const state = &self.data;
var round = @as(u32, 24);
while (round > 0) : (round -= 1) {
var column = @as(usize, 0);
while (column < 4) : (column += 1) {
const x = math.rotl(u32, state[column], 24);
const y = math.rotl(u32, state[4 + column], 9);
const z = state[8 + column];
state[8 + column] = ((x ^ (z << 1)) ^ ((y & z) << 2));
state[4 + column] = ((y ^ x) ^ ((x | z) << 1));
state[column] = ((z ^ y) ^ ((x & y) << 3));
}
switch (round & 3) {
0 => {
mem.swap(u32, &state[0], &state[1]);
mem.swap(u32, &state[2], &state[3]);
state[0] ^= round | 0x9e377900;
},
2 => {
mem.swap(u32, &state[0], &state[2]);
mem.swap(u32, &state[1], &state[3]);
},
else => {},
}
}
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self.endianSwap();
}
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const Lane = Vector(4, u32);
inline fn shift(x: Lane, comptime n: comptime_int) Lane {
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return x << @splat(4, @as(u5, n));
}
fn permute_vectorized(self: *Self) void {
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self.endianSwap();
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const state = &self.data;
var x = Lane{ state[0], state[1], state[2], state[3] };
var y = Lane{ state[4], state[5], state[6], state[7] };
var z = Lane{ state[8], state[9], state[10], state[11] };
var round = @as(u32, 24);
while (round > 0) : (round -= 1) {
x = math.rotl(Lane, x, 24);
y = math.rotl(Lane, y, 9);
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const newz = x ^ shift(z, 1) ^ shift(y & z, 2);
const newy = y ^ x ^ shift(x | z, 1);
const newx = z ^ y ^ shift(x & y, 3);
x = newx;
y = newy;
z = newz;
switch (round & 3) {
0 => {
x = @shuffle(u32, x, undefined, [_]i32{ 1, 0, 3, 2 });
x[0] ^= round | 0x9e377900;
},
2 => {
x = @shuffle(u32, x, undefined, [_]i32{ 2, 3, 0, 1 });
},
else => {},
}
}
comptime var i: usize = 0;
inline while (i < 4) : (i += 1) {
state[0 + i] = x[i];
state[4 + i] = y[i];
state[8 + i] = z[i];
}
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self.endianSwap();
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}
pub const permute = if (std.Target.current.cpu.arch == .x86_64) impl: {
break :impl permute_vectorized;
} else if (std.builtin.mode == .ReleaseSmall) impl: {
break :impl permute_small;
} else impl: {
break :impl permute_unrolled;
};
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pub fn squeeze(self: *Self, out: []u8) void {
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var i = @as(usize, 0);
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while (i + RATE <= out.len) : (i += RATE) {
self.permute();
mem.copy(u8, out[i..], self.toSliceConst()[0..RATE]);
}
const leftover = out.len - i;
if (leftover != 0) {
self.permute();
mem.copy(u8, out[i..], self.toSliceConst()[0..leftover]);
}
}
};
test "permute" {
// test vector from gimli-20170627
const tv_input = [3][4]u32{
[4]u32{ 0x00000000, 0x9e3779ba, 0x3c6ef37a, 0xdaa66d46 },
[4]u32{ 0x78dde724, 0x1715611a, 0xb54cdb2e, 0x53845566 },
[4]u32{ 0xf1bbcfc8, 0x8ff34a5a, 0x2e2ac522, 0xcc624026 },
};
var input: [48]u8 = undefined;
var i: usize = 0;
while (i < 12) : (i += 1) {
mem.writeIntLittle(u32, input[i * 4 ..][0..4], tv_input[i / 4][i % 4]);
}
var state = State.init(input);
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state.permute();
const tv_output = [3][4]u32{
[4]u32{ 0xba11c85a, 0x91bad119, 0x380ce880, 0xd24c2c68 },
[4]u32{ 0x3eceffea, 0x277a921c, 0x4f73a0bd, 0xda5a9cd8 },
[4]u32{ 0x84b673f0, 0x34e52ff7, 0x9e2bef49, 0xf41bb8d6 },
};
var expected_output: [48]u8 = undefined;
i = 0;
while (i < 12) : (i += 1) {
mem.writeIntLittle(u32, expected_output[i * 4 ..][0..4], tv_output[i / 4][i % 4]);
}
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try testing.expectEqualSlices(u8, state.toSliceConst(), expected_output[0..]);
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}
pub const Hash = struct {
state: State,
buf_off: usize,
pub const block_length = State.RATE;
pub const digest_length = 32;
pub const Options = struct {};
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const Self = @This();
pub fn init(options: Options) Self {
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_ = options;
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return Self{
.state = State{ .data = [_]u32{0} ** (State.BLOCKBYTES / 4) },
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.buf_off = 0,
};
}
/// Also known as 'absorb'
pub fn update(self: *Self, data: []const u8) void {
const buf = self.state.toSlice();
var in = data;
while (in.len > 0) {
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const left = State.RATE - self.buf_off;
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const ps = math.min(in.len, left);
for (buf[self.buf_off .. self.buf_off + ps]) |*p, i| {
p.* ^= in[i];
}
self.buf_off += ps;
in = in[ps..];
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if (self.buf_off == State.RATE) {
self.state.permute();
self.buf_off = 0;
}
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}
}
/// Finish the current hashing operation, writing the hash to `out`
///
/// From 4.9 "Application to hashing"
/// By default, Gimli-Hash provides a fixed-length output of 32 bytes
/// (the concatenation of two 16-byte blocks). However, Gimli-Hash can
/// be used as an “extendable one-way function” (XOF).
pub fn final(self: *Self, out: []u8) void {
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const buf = self.state.toSlice();
// XOR 1 into the next byte of the state
buf[self.buf_off] ^= 1;
// XOR 1 into the last byte of the state, position 47.
buf[buf.len - 1] ^= 1;
self.state.squeeze(out);
}
};
pub fn hash(out: []u8, in: []const u8, options: Hash.Options) void {
var st = Hash.init(options);
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st.update(in);
st.final(out);
}
test "hash" {
// a test vector (30) from NIST KAT submission.
var msg: [58 / 2]u8 = undefined;
_ = try std.fmt.hexToBytes(&msg, "000102030405060708090A0B0C0D0E0F101112131415161718191A1B1C");
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var md: [32]u8 = undefined;
hash(&md, &msg, .{});
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try htest.assertEqual("1C9A03DC6A5DDC5444CFC6F4B154CFF5CF081633B2CEA4D7D0AE7CCFED5AAA44", &md);
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}
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test "hash test vector 17" {
var msg: [32 / 2]u8 = undefined;
_ = try std.fmt.hexToBytes(&msg, "000102030405060708090A0B0C0D0E0F");
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var md: [32]u8 = undefined;
hash(&md, &msg, .{});
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try htest.assertEqual("404C130AF1B9023A7908200919F690FFBB756D5176E056FFDE320016A37C7282", &md);
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}
test "hash test vector 33" {
var msg: [32]u8 = undefined;
_ = try std.fmt.hexToBytes(&msg, "000102030405060708090A0B0C0D0E0F101112131415161718191A1B1C1D1E1F");
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var md: [32]u8 = undefined;
hash(&md, &msg, .{});
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try htest.assertEqual("A8F4FA28708BDA7EFB4C1914CA4AFA9E475B82D588D36504F87DBB0ED9AB3C4B", &md);
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}
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pub const Aead = struct {
pub const tag_length = State.RATE;
pub const nonce_length = 16;
pub const key_length = 32;
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/// ad: Associated Data
/// npub: public nonce
/// k: private key
fn init(ad: []const u8, npub: [nonce_length]u8, k: [key_length]u8) State {
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var state = State{
.data = undefined,
};
const buf = state.toSlice();
// Gimli-Cipher initializes a 48-byte Gimli state to a 16-byte nonce
// followed by a 32-byte key.
assert(npub.len + k.len == State.BLOCKBYTES);
std.mem.copy(u8, buf[0..npub.len], &npub);
std.mem.copy(u8, buf[npub.len .. npub.len + k.len], &k);
// It then applies the Gimli permutation.
state.permute();
{
// Gimli-Cipher then handles each block of associated data, including
// exactly one final non-full block, in the same way as Gimli-Hash.
var data = ad;
while (data.len >= State.RATE) : (data = data[State.RATE..]) {
for (buf[0..State.RATE]) |*p, i| {
p.* ^= data[i];
}
state.permute();
}
for (buf[0..data.len]) |*p, i| {
p.* ^= data[i];
}
// XOR 1 into the next byte of the state
buf[data.len] ^= 1;
// XOR 1 into the last byte of the state, position 47.
buf[buf.len - 1] ^= 1;
state.permute();
}
return state;
}
/// c: ciphertext: output buffer should be of size m.len
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/// tag: authentication tag: output MAC
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/// m: message
/// ad: Associated Data
/// npub: public nonce
/// k: private key
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pub fn encrypt(c: []u8, tag: *[tag_length]u8, m: []const u8, ad: []const u8, npub: [nonce_length]u8, k: [key_length]u8) void {
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assert(c.len == m.len);
var state = Aead.init(ad, npub, k);
const buf = state.toSlice();
// Gimli-Cipher then handles each block of plaintext, including
// exactly one final non-full block, in the same way as Gimli-Hash.
// Whenever a plaintext byte is XORed into a state byte, the new state
// byte is output as ciphertext.
var in = m;
var out = c;
while (in.len >= State.RATE) : ({
in = in[State.RATE..];
out = out[State.RATE..];
}) {
for (in[0..State.RATE]) |v, i| {
buf[i] ^= v;
}
mem.copy(u8, out[0..State.RATE], buf[0..State.RATE]);
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state.permute();
}
for (in[0..]) |v, i| {
buf[i] ^= v;
out[i] = buf[i];
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}
// XOR 1 into the next byte of the state
buf[in.len] ^= 1;
// XOR 1 into the last byte of the state, position 47.
buf[buf.len - 1] ^= 1;
state.permute();
// After the final non-full block of plaintext, the first 16 bytes
// of the state are output as an authentication tag.
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std.mem.copy(u8, tag, buf[0..State.RATE]);
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}
/// m: message: output buffer should be of size c.len
/// c: ciphertext
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/// tag: authentication tag
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/// ad: Associated Data
/// npub: public nonce
/// k: private key
/// NOTE: the check of the authentication tag is currently not done in constant time
pub fn decrypt(m: []u8, c: []const u8, tag: [tag_length]u8, ad: []const u8, npub: [nonce_length]u8, k: [key_length]u8) AuthenticationError!void {
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assert(c.len == m.len);
var state = Aead.init(ad, npub, k);
const buf = state.toSlice();
var in = c;
var out = m;
while (in.len >= State.RATE) : ({
in = in[State.RATE..];
out = out[State.RATE..];
}) {
const d = in[0..State.RATE].*;
for (d) |v, i| {
out[i] = buf[i] ^ v;
}
mem.copy(u8, buf[0..State.RATE], d[0..State.RATE]);
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state.permute();
}
for (buf[0..in.len]) |*p, i| {
const d = in[i];
out[i] = p.* ^ d;
p.* = d;
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}
// XOR 1 into the next byte of the state
buf[in.len] ^= 1;
// XOR 1 into the last byte of the state, position 47.
buf[buf.len - 1] ^= 1;
state.permute();
// After the final non-full block of plaintext, the first 16 bytes
// of the state are the authentication tag.
// TODO: use a constant-time equality check here, see https://github.com/ziglang/zig/issues/1776
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if (!mem.eql(u8, buf[0..State.RATE], &tag)) {
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@memset(m.ptr, undefined, m.len);
return error.AuthenticationFailed;
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}
}
};
test "cipher" {
var key: [32]u8 = undefined;
_ = try std.fmt.hexToBytes(&key, "000102030405060708090A0B0C0D0E0F101112131415161718191A1B1C1D1E1F");
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var nonce: [16]u8 = undefined;
_ = try std.fmt.hexToBytes(&nonce, "000102030405060708090A0B0C0D0E0F");
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{ // test vector (1) from NIST KAT submission.
const ad: [0]u8 = undefined;
const pt: [0]u8 = undefined;
var ct: [pt.len]u8 = undefined;
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var tag: [16]u8 = undefined;
Aead.encrypt(&ct, &tag, &pt, &ad, nonce, key);
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try htest.assertEqual("", &ct);
try htest.assertEqual("14DA9BB7120BF58B985A8E00FDEBA15B", &tag);
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var pt2: [pt.len]u8 = undefined;
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try Aead.decrypt(&pt2, &ct, tag, &ad, nonce, key);
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try testing.expectEqualSlices(u8, &pt, &pt2);
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}
{ // test vector (34) from NIST KAT submission.
const ad: [0]u8 = undefined;
var pt: [2 / 2]u8 = undefined;
_ = try std.fmt.hexToBytes(&pt, "00");
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var ct: [pt.len]u8 = undefined;
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var tag: [16]u8 = undefined;
Aead.encrypt(&ct, &tag, &pt, &ad, nonce, key);
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try htest.assertEqual("7F", &ct);
try htest.assertEqual("80492C317B1CD58A1EDC3A0D3E9876FC", &tag);
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var pt2: [pt.len]u8 = undefined;
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try Aead.decrypt(&pt2, &ct, tag, &ad, nonce, key);
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try testing.expectEqualSlices(u8, &pt, &pt2);
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}
{ // test vector (106) from NIST KAT submission.
var ad: [12 / 2]u8 = undefined;
_ = try std.fmt.hexToBytes(&ad, "000102030405");
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var pt: [6 / 2]u8 = undefined;
_ = try std.fmt.hexToBytes(&pt, "000102");
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var ct: [pt.len]u8 = undefined;
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var tag: [16]u8 = undefined;
Aead.encrypt(&ct, &tag, &pt, &ad, nonce, key);
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try htest.assertEqual("484D35", &ct);
try htest.assertEqual("030BBEA23B61C00CED60A923BDCF9147", &tag);
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var pt2: [pt.len]u8 = undefined;
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try Aead.decrypt(&pt2, &ct, tag, &ad, nonce, key);
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try testing.expectEqualSlices(u8, &pt, &pt2);
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}
{ // test vector (790) from NIST KAT submission.
var ad: [60 / 2]u8 = undefined;
_ = try std.fmt.hexToBytes(&ad, "000102030405060708090A0B0C0D0E0F101112131415161718191A1B1C1D");
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var pt: [46 / 2]u8 = undefined;
_ = try std.fmt.hexToBytes(&pt, "000102030405060708090A0B0C0D0E0F10111213141516");
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var ct: [pt.len]u8 = undefined;
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var tag: [16]u8 = undefined;
Aead.encrypt(&ct, &tag, &pt, &ad, nonce, key);
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try htest.assertEqual("6815B4A0ECDAD01596EAD87D9E690697475D234C6A13D1", &ct);
try htest.assertEqual("DFE23F1642508290D68245279558B2FB", &tag);
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var pt2: [pt.len]u8 = undefined;
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try Aead.decrypt(&pt2, &ct, tag, &ad, nonce, key);
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try testing.expectEqualSlices(u8, &pt, &pt2);
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}
{ // test vector (1057) from NIST KAT submission.
const ad: [0]u8 = undefined;
var pt: [64 / 2]u8 = undefined;
_ = try std.fmt.hexToBytes(&pt, "000102030405060708090A0B0C0D0E0F101112131415161718191A1B1C1D1E1F");
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var ct: [pt.len]u8 = undefined;
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var tag: [16]u8 = undefined;
Aead.encrypt(&ct, &tag, &pt, &ad, nonce, key);
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try htest.assertEqual("7F8A2CF4F52AA4D6B2E74105C30A2777B9D0C8AEFDD555DE35861BD3011F652F", &ct);
try htest.assertEqual("7256456FA935AC34BBF55AE135F33257", &tag);
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var pt2: [pt.len]u8 = undefined;
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try Aead.decrypt(&pt2, &ct, tag, &ad, nonce, key);
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try testing.expectEqualSlices(u8, &pt, &pt2);
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}
}