mirror of
https://github.com/ziglang/zig.git
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237 lines
10 KiB
Zig
237 lines
10 KiB
Zig
// SPDX-License-Identifier: MIT
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// Copyright (c) 2015-2021 Zig Contributors
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// This file is part of [zig](https://ziglang.org/), which is MIT licensed.
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// The MIT license requires this copyright notice to be included in all copies
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// and substantial portions of the software.
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const std = @import("std");
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const mem = std.mem;
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const primes = [_]u64{
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0xa0761d6478bd642f,
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0xe7037ed1a0b428db,
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0x8ebc6af09c88c6e3,
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0x589965cc75374cc3,
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0x1d8e4e27c47d124f,
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};
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fn read_bytes(comptime bytes: u8, data: []const u8) u64 {
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const T = std.meta.Int(.unsigned, 8 * bytes);
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return mem.readIntLittle(T, data[0..bytes]);
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}
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fn read_8bytes_swapped(data: []const u8) u64 {
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return (read_bytes(4, data) << 32 | read_bytes(4, data[4..]));
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}
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fn mum(a: u64, b: u64) u64 {
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var r = std.math.mulWide(u64, a, b);
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r = (r >> 64) ^ r;
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return @truncate(u64, r);
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}
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fn mix0(a: u64, b: u64, seed: u64) u64 {
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return mum(a ^ seed ^ primes[0], b ^ seed ^ primes[1]);
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}
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fn mix1(a: u64, b: u64, seed: u64) u64 {
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return mum(a ^ seed ^ primes[2], b ^ seed ^ primes[3]);
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}
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// Wyhash version which does not store internal state for handling partial buffers.
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// This is needed so that we can maximize the speed for the short key case, which will
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// use the non-iterative api which the public Wyhash exposes.
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const WyhashStateless = struct {
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seed: u64,
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msg_len: usize,
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pub fn init(seed: u64) WyhashStateless {
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return WyhashStateless{
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.seed = seed,
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.msg_len = 0,
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};
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}
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fn round(self: *WyhashStateless, b: []const u8) void {
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std.debug.assert(b.len == 32);
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self.seed = mix0(
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read_bytes(8, b[0..]),
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read_bytes(8, b[8..]),
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self.seed,
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) ^ mix1(
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read_bytes(8, b[16..]),
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read_bytes(8, b[24..]),
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self.seed,
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);
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}
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pub fn update(self: *WyhashStateless, b: []const u8) void {
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std.debug.assert(b.len % 32 == 0);
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var off: usize = 0;
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while (off < b.len) : (off += 32) {
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@call(.{ .modifier = .always_inline }, self.round, .{b[off .. off + 32]});
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}
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self.msg_len += b.len;
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}
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pub fn final(self: *WyhashStateless, b: []const u8) u64 {
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std.debug.assert(b.len < 32);
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const seed = self.seed;
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const rem_len = @intCast(u5, b.len);
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const rem_key = b[0..rem_len];
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self.seed = switch (rem_len) {
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0 => seed,
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1 => mix0(read_bytes(1, rem_key), primes[4], seed),
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2 => mix0(read_bytes(2, rem_key), primes[4], seed),
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3 => mix0((read_bytes(2, rem_key) << 8) | read_bytes(1, rem_key[2..]), primes[4], seed),
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4 => mix0(read_bytes(4, rem_key), primes[4], seed),
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5 => mix0((read_bytes(4, rem_key) << 8) | read_bytes(1, rem_key[4..]), primes[4], seed),
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6 => mix0((read_bytes(4, rem_key) << 16) | read_bytes(2, rem_key[4..]), primes[4], seed),
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7 => mix0((read_bytes(4, rem_key) << 24) | (read_bytes(2, rem_key[4..]) << 8) | read_bytes(1, rem_key[6..]), primes[4], seed),
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8 => mix0(read_8bytes_swapped(rem_key), primes[4], seed),
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9 => mix0(read_8bytes_swapped(rem_key), read_bytes(1, rem_key[8..]), seed),
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10 => mix0(read_8bytes_swapped(rem_key), read_bytes(2, rem_key[8..]), seed),
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11 => mix0(read_8bytes_swapped(rem_key), (read_bytes(2, rem_key[8..]) << 8) | read_bytes(1, rem_key[10..]), seed),
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12 => mix0(read_8bytes_swapped(rem_key), read_bytes(4, rem_key[8..]), seed),
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13 => mix0(read_8bytes_swapped(rem_key), (read_bytes(4, rem_key[8..]) << 8) | read_bytes(1, rem_key[12..]), seed),
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14 => mix0(read_8bytes_swapped(rem_key), (read_bytes(4, rem_key[8..]) << 16) | read_bytes(2, rem_key[12..]), seed),
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15 => mix0(read_8bytes_swapped(rem_key), (read_bytes(4, rem_key[8..]) << 24) | (read_bytes(2, rem_key[12..]) << 8) | read_bytes(1, rem_key[14..]), seed),
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16 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed),
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17 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_bytes(1, rem_key[16..]), primes[4], seed),
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18 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_bytes(2, rem_key[16..]), primes[4], seed),
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19 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1((read_bytes(2, rem_key[16..]) << 8) | read_bytes(1, rem_key[18..]), primes[4], seed),
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20 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_bytes(4, rem_key[16..]), primes[4], seed),
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21 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1((read_bytes(4, rem_key[16..]) << 8) | read_bytes(1, rem_key[20..]), primes[4], seed),
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22 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1((read_bytes(4, rem_key[16..]) << 16) | read_bytes(2, rem_key[20..]), primes[4], seed),
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23 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1((read_bytes(4, rem_key[16..]) << 24) | (read_bytes(2, rem_key[20..]) << 8) | read_bytes(1, rem_key[22..]), primes[4], seed),
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24 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_8bytes_swapped(rem_key[16..]), primes[4], seed),
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25 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_8bytes_swapped(rem_key[16..]), read_bytes(1, rem_key[24..]), seed),
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26 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_8bytes_swapped(rem_key[16..]), read_bytes(2, rem_key[24..]), seed),
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27 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_8bytes_swapped(rem_key[16..]), (read_bytes(2, rem_key[24..]) << 8) | read_bytes(1, rem_key[26..]), seed),
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28 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_8bytes_swapped(rem_key[16..]), read_bytes(4, rem_key[24..]), seed),
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29 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_8bytes_swapped(rem_key[16..]), (read_bytes(4, rem_key[24..]) << 8) | read_bytes(1, rem_key[28..]), seed),
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30 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_8bytes_swapped(rem_key[16..]), (read_bytes(4, rem_key[24..]) << 16) | read_bytes(2, rem_key[28..]), seed),
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31 => mix0(read_8bytes_swapped(rem_key), read_8bytes_swapped(rem_key[8..]), seed) ^ mix1(read_8bytes_swapped(rem_key[16..]), (read_bytes(4, rem_key[24..]) << 24) | (read_bytes(2, rem_key[28..]) << 8) | read_bytes(1, rem_key[30..]), seed),
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};
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self.msg_len += b.len;
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return mum(self.seed ^ self.msg_len, primes[4]);
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}
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pub fn hash(seed: u64, input: []const u8) u64 {
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const aligned_len = input.len - (input.len % 32);
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var c = WyhashStateless.init(seed);
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@call(.{ .modifier = .always_inline }, c.update, .{input[0..aligned_len]});
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return @call(.{ .modifier = .always_inline }, c.final, .{input[aligned_len..]});
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}
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};
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/// Fast non-cryptographic 64bit hash function.
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/// See https://github.com/wangyi-fudan/wyhash
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pub const Wyhash = struct {
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state: WyhashStateless,
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buf: [32]u8,
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buf_len: usize,
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pub fn init(seed: u64) Wyhash {
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return Wyhash{
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.state = WyhashStateless.init(seed),
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.buf = undefined,
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.buf_len = 0,
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};
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}
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pub fn update(self: *Wyhash, b: []const u8) void {
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var off: usize = 0;
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if (self.buf_len != 0 and self.buf_len + b.len >= 32) {
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off += 32 - self.buf_len;
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mem.copy(u8, self.buf[self.buf_len..], b[0..off]);
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self.state.update(self.buf[0..]);
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self.buf_len = 0;
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}
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const remain_len = b.len - off;
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const aligned_len = remain_len - (remain_len % 32);
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self.state.update(b[off .. off + aligned_len]);
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mem.copy(u8, self.buf[self.buf_len..], b[off + aligned_len ..]);
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self.buf_len += @intCast(u8, b[off + aligned_len ..].len);
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}
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pub fn final(self: *Wyhash) u64 {
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const seed = self.state.seed;
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const rem_len = @intCast(u5, self.buf_len);
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const rem_key = self.buf[0..self.buf_len];
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return self.state.final(rem_key);
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}
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pub fn hash(seed: u64, input: []const u8) u64 {
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return WyhashStateless.hash(seed, input);
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}
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};
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const expectEqual = std.testing.expectEqual;
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test "test vectors" {
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const hash = Wyhash.hash;
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expectEqual(hash(0, ""), 0x0);
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expectEqual(hash(1, "a"), 0xbed235177f41d328);
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expectEqual(hash(2, "abc"), 0xbe348debe59b27c3);
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expectEqual(hash(3, "message digest"), 0x37320f657213a290);
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expectEqual(hash(4, "abcdefghijklmnopqrstuvwxyz"), 0xd0b270e1d8a7019c);
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expectEqual(hash(5, "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789"), 0x602a1894d3bbfe7f);
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expectEqual(hash(6, "12345678901234567890123456789012345678901234567890123456789012345678901234567890"), 0x829e9c148b75970e);
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}
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test "test vectors streaming" {
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var wh = Wyhash.init(5);
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for ("ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789") |e| {
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wh.update(mem.asBytes(&e));
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}
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expectEqual(wh.final(), 0x602a1894d3bbfe7f);
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const pattern = "1234567890";
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const count = 8;
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const result = 0x829e9c148b75970e;
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expectEqual(Wyhash.hash(6, pattern ** 8), result);
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wh = Wyhash.init(6);
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var i: u32 = 0;
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while (i < count) : (i += 1) {
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wh.update(pattern);
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}
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expectEqual(wh.final(), result);
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}
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test "iterative non-divisible update" {
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var buf: [8192]u8 = undefined;
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for (buf) |*e, i| {
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e.* = @truncate(u8, i);
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}
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const seed = 0x128dad08f;
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var end: usize = 32;
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while (end < buf.len) : (end += 32) {
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const non_iterative_hash = Wyhash.hash(seed, buf[0..end]);
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var wy = Wyhash.init(seed);
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var i: usize = 0;
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while (i < end) : (i += 33) {
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wy.update(buf[i..std.math.min(i + 33, end)]);
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}
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const iterative_hash = wy.final();
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std.testing.expectEqual(iterative_hash, non_iterative_hash);
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}
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}
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