// The engines provided here should be initialized from an external source. For now, randomBytes // from the crypto package is the most suitable. Be sure to use a CSPRNG when required, otherwise using // a normal PRNG will be faster and use substantially less stack space. // // ``` // var buf: [8]u8 = undefined; // try std.crypto.randomBytes(buf[0..]); // const seed = mem.readIntLittle(u64, buf[0..8]); // // var r = DefaultPrng.init(seed); // // const s = r.random.int(u64); // ``` // // TODO(tiehuis): Benchmark these against other reference implementations. const std = @import("std.zig"); const builtin = @import("builtin"); const assert = std.debug.assert; const expect = std.testing.expect; const expectEqual = std.testing.expectEqual; const mem = std.mem; const math = std.math; const ziggurat = @import("rand/ziggurat.zig"); const maxInt = std.math.maxInt; // When you need fast unbiased random numbers pub const DefaultPrng = Xoroshiro128; // When you need cryptographically secure random numbers pub const DefaultCsprng = Isaac64; pub const Random = struct { fillFn: fn (r: *Random, buf: []u8) void, /// Read random bytes into the specified buffer until full. pub fn bytes(r: *Random, buf: []u8) void { r.fillFn(r, buf); } pub fn boolean(r: *Random) bool { return r.int(u1) != 0; } /// Returns a random int `i` such that `0 <= i <= maxInt(T)`. /// `i` is evenly distributed. pub fn int(r: *Random, comptime T: type) T { const UnsignedT = std.meta.Int(false, T.bit_count); const ByteAlignedT = std.meta.Int(false, @divTrunc(T.bit_count + 7, 8) * 8); var rand_bytes: [@sizeOf(ByteAlignedT)]u8 = undefined; r.bytes(rand_bytes[0..]); // use LE instead of native endian for better portability maybe? // TODO: endian portability is pointless if the underlying prng isn't endian portable. // TODO: document the endian portability of this library. const byte_aligned_result = mem.readIntSliceLittle(ByteAlignedT, &rand_bytes); const unsigned_result = @truncate(UnsignedT, byte_aligned_result); return @bitCast(T, unsigned_result); } /// Constant-time implementation off `uintLessThan`. /// The results of this function may be biased. pub fn uintLessThanBiased(r: *Random, comptime T: type, less_than: T) T { comptime assert(T.is_signed == false); comptime assert(T.bit_count <= 64); // TODO: workaround: LLVM ERROR: Unsupported library call operation! assert(0 < less_than); if (T.bit_count <= 32) { return @intCast(T, limitRangeBiased(u32, r.int(u32), less_than)); } else { return @intCast(T, limitRangeBiased(u64, r.int(u64), less_than)); } } /// Returns an evenly distributed random unsigned integer `0 <= i < less_than`. /// This function assumes that the underlying `fillFn` produces evenly distributed values. /// Within this assumption, the runtime of this function is exponentially distributed. /// If `fillFn` were backed by a true random generator, /// the runtime of this function would technically be unbounded. /// However, if `fillFn` is backed by any evenly distributed pseudo random number generator, /// this function is guaranteed to return. /// If you need deterministic runtime bounds, use `uintLessThanBiased`. pub fn uintLessThan(r: *Random, comptime T: type, less_than: T) T { comptime assert(T.is_signed == false); comptime assert(T.bit_count <= 64); // TODO: workaround: LLVM ERROR: Unsupported library call operation! assert(0 < less_than); // Small is typically u32 const Small = std.meta.Int(false, @divTrunc(T.bit_count + 31, 32) * 32); // Large is typically u64 const Large = std.meta.Int(false, Small.bit_count * 2); // adapted from: // http://www.pcg-random.org/posts/bounded-rands.html // "Lemire's (with an extra tweak from me)" var x: Small = r.int(Small); var m: Large = @as(Large, x) * @as(Large, less_than); var l: Small = @truncate(Small, m); if (l < less_than) { // TODO: workaround for https://github.com/ziglang/zig/issues/1770 // should be: // var t: Small = -%less_than; var t: Small = @bitCast(Small, -%@bitCast(std.meta.Int(true, Small.bit_count), @as(Small, less_than))); if (t >= less_than) { t -= less_than; if (t >= less_than) { t %= less_than; } } while (l < t) { x = r.int(Small); m = @as(Large, x) * @as(Large, less_than); l = @truncate(Small, m); } } return @intCast(T, m >> Small.bit_count); } /// Constant-time implementation off `uintAtMost`. /// The results of this function may be biased. pub fn uintAtMostBiased(r: *Random, comptime T: type, at_most: T) T { assert(T.is_signed == false); if (at_most == maxInt(T)) { // have the full range return r.int(T); } return r.uintLessThanBiased(T, at_most + 1); } /// Returns an evenly distributed random unsigned integer `0 <= i <= at_most`. /// See `uintLessThan`, which this function uses in most cases, /// for commentary on the runtime of this function. pub fn uintAtMost(r: *Random, comptime T: type, at_most: T) T { assert(T.is_signed == false); if (at_most == maxInt(T)) { // have the full range return r.int(T); } return r.uintLessThan(T, at_most + 1); } /// Constant-time implementation off `intRangeLessThan`. /// The results of this function may be biased. pub fn intRangeLessThanBiased(r: *Random, comptime T: type, at_least: T, less_than: T) T { assert(at_least < less_than); if (T.is_signed) { // Two's complement makes this math pretty easy. const UnsignedT = std.meta.Int(false, T.bit_count); const lo = @bitCast(UnsignedT, at_least); const hi = @bitCast(UnsignedT, less_than); const result = lo +% r.uintLessThanBiased(UnsignedT, hi -% lo); return @bitCast(T, result); } else { // The signed implementation would work fine, but we can use stricter arithmetic operators here. return at_least + r.uintLessThanBiased(T, less_than - at_least); } } /// Returns an evenly distributed random integer `at_least <= i < less_than`. /// See `uintLessThan`, which this function uses in most cases, /// for commentary on the runtime of this function. pub fn intRangeLessThan(r: *Random, comptime T: type, at_least: T, less_than: T) T { assert(at_least < less_than); if (T.is_signed) { // Two's complement makes this math pretty easy. const UnsignedT = std.meta.Int(false, T.bit_count); const lo = @bitCast(UnsignedT, at_least); const hi = @bitCast(UnsignedT, less_than); const result = lo +% r.uintLessThan(UnsignedT, hi -% lo); return @bitCast(T, result); } else { // The signed implementation would work fine, but we can use stricter arithmetic operators here. return at_least + r.uintLessThan(T, less_than - at_least); } } /// Constant-time implementation off `intRangeAtMostBiased`. /// The results of this function may be biased. pub fn intRangeAtMostBiased(r: *Random, comptime T: type, at_least: T, at_most: T) T { assert(at_least <= at_most); if (T.is_signed) { // Two's complement makes this math pretty easy. const UnsignedT = std.meta.Int(false, T.bit_count); const lo = @bitCast(UnsignedT, at_least); const hi = @bitCast(UnsignedT, at_most); const result = lo +% r.uintAtMostBiased(UnsignedT, hi -% lo); return @bitCast(T, result); } else { // The signed implementation would work fine, but we can use stricter arithmetic operators here. return at_least + r.uintAtMostBiased(T, at_most - at_least); } } /// Returns an evenly distributed random integer `at_least <= i <= at_most`. /// See `uintLessThan`, which this function uses in most cases, /// for commentary on the runtime of this function. pub fn intRangeAtMost(r: *Random, comptime T: type, at_least: T, at_most: T) T { assert(at_least <= at_most); if (T.is_signed) { // Two's complement makes this math pretty easy. const UnsignedT = std.meta.Int(false, T.bit_count); const lo = @bitCast(UnsignedT, at_least); const hi = @bitCast(UnsignedT, at_most); const result = lo +% r.uintAtMost(UnsignedT, hi -% lo); return @bitCast(T, result); } else { // The signed implementation would work fine, but we can use stricter arithmetic operators here. return at_least + r.uintAtMost(T, at_most - at_least); } } pub const scalar = @compileError("deprecated; use boolean() or int() instead"); pub const range = @compileError("deprecated; use intRangeLessThan()"); /// Return a floating point value evenly distributed in the range [0, 1). pub fn float(r: *Random, comptime T: type) T { // Generate a uniform value between [1, 2) and scale down to [0, 1). // Note: The lowest mantissa bit is always set to 0 so we only use half the available range. switch (T) { f32 => { const s = r.int(u32); const repr = (0x7f << 23) | (s >> 9); return @bitCast(f32, repr) - 1.0; }, f64 => { const s = r.int(u64); const repr = (0x3ff << 52) | (s >> 12); return @bitCast(f64, repr) - 1.0; }, else => @compileError("unknown floating point type"), } } /// Return a floating point value normally distributed with mean = 0, stddev = 1. /// /// To use different parameters, use: floatNorm(...) * desiredStddev + desiredMean. pub fn floatNorm(r: *Random, comptime T: type) T { const value = ziggurat.next_f64(r, ziggurat.NormDist); switch (T) { f32 => return @floatCast(f32, value), f64 => return value, else => @compileError("unknown floating point type"), } } /// Return an exponentially distributed float with a rate parameter of 1. /// /// To use a different rate parameter, use: floatExp(...) / desiredRate. pub fn floatExp(r: *Random, comptime T: type) T { const value = ziggurat.next_f64(r, ziggurat.ExpDist); switch (T) { f32 => return @floatCast(f32, value), f64 => return value, else => @compileError("unknown floating point type"), } } /// Shuffle a slice into a random order. pub fn shuffle(r: *Random, comptime T: type, buf: []T) void { if (buf.len < 2) { return; } var i: usize = 0; while (i < buf.len - 1) : (i += 1) { const j = r.intRangeLessThan(usize, i, buf.len); mem.swap(T, &buf[i], &buf[j]); } } }; /// Convert a random integer 0 <= random_int <= maxValue(T), /// into an integer 0 <= result < less_than. /// This function introduces a minor bias. pub fn limitRangeBiased(comptime T: type, random_int: T, less_than: T) T { comptime assert(T.is_signed == false); const T2 = std.meta.Int(false, T.bit_count * 2); // adapted from: // http://www.pcg-random.org/posts/bounded-rands.html // "Integer Multiplication (Biased)" var m: T2 = @as(T2, random_int) * @as(T2, less_than); return @intCast(T, m >> T.bit_count); } const SequentialPrng = struct { const Self = @This(); random: Random, next_value: u8, pub fn init() Self { return Self{ .random = Random{ .fillFn = fill }, .next_value = 0, }; } fn fill(r: *Random, buf: []u8) void { const self = @fieldParentPtr(Self, "random", r); for (buf) |*b| { b.* = self.next_value; } self.next_value +%= 1; } }; test "Random int" { testRandomInt(); comptime testRandomInt(); } fn testRandomInt() void { var r = SequentialPrng.init(); expect(r.random.int(u0) == 0); r.next_value = 0; expect(r.random.int(u1) == 0); expect(r.random.int(u1) == 1); expect(r.random.int(u2) == 2); expect(r.random.int(u2) == 3); expect(r.random.int(u2) == 0); r.next_value = 0xff; expect(r.random.int(u8) == 0xff); r.next_value = 0x11; expect(r.random.int(u8) == 0x11); r.next_value = 0xff; expect(r.random.int(u32) == 0xffffffff); r.next_value = 0x11; expect(r.random.int(u32) == 0x11111111); r.next_value = 0xff; expect(r.random.int(i32) == -1); r.next_value = 0x11; expect(r.random.int(i32) == 0x11111111); r.next_value = 0xff; expect(r.random.int(i8) == -1); r.next_value = 0x11; expect(r.random.int(i8) == 0x11); r.next_value = 0xff; expect(r.random.int(u33) == 0x1ffffffff); r.next_value = 0xff; expect(r.random.int(i1) == -1); r.next_value = 0xff; expect(r.random.int(i2) == -1); r.next_value = 0xff; expect(r.random.int(i33) == -1); } test "Random boolean" { testRandomBoolean(); comptime testRandomBoolean(); } fn testRandomBoolean() void { var r = SequentialPrng.init(); expect(r.random.boolean() == false); expect(r.random.boolean() == true); expect(r.random.boolean() == false); expect(r.random.boolean() == true); } test "Random intLessThan" { @setEvalBranchQuota(10000); testRandomIntLessThan(); comptime testRandomIntLessThan(); } fn testRandomIntLessThan() void { var r = SequentialPrng.init(); r.next_value = 0xff; expect(r.random.uintLessThan(u8, 4) == 3); expect(r.next_value == 0); expect(r.random.uintLessThan(u8, 4) == 0); expect(r.next_value == 1); r.next_value = 0; expect(r.random.uintLessThan(u64, 32) == 0); // trigger the bias rejection code path r.next_value = 0; expect(r.random.uintLessThan(u8, 3) == 0); // verify we incremented twice expect(r.next_value == 2); r.next_value = 0xff; expect(r.random.intRangeLessThan(u8, 0, 0x80) == 0x7f); r.next_value = 0xff; expect(r.random.intRangeLessThan(u8, 0x7f, 0xff) == 0xfe); r.next_value = 0xff; expect(r.random.intRangeLessThan(i8, 0, 0x40) == 0x3f); r.next_value = 0xff; expect(r.random.intRangeLessThan(i8, -0x40, 0x40) == 0x3f); r.next_value = 0xff; expect(r.random.intRangeLessThan(i8, -0x80, 0) == -1); r.next_value = 0xff; expect(r.random.intRangeLessThan(i3, -4, 0) == -1); r.next_value = 0xff; expect(r.random.intRangeLessThan(i3, -2, 2) == 1); } test "Random intAtMost" { @setEvalBranchQuota(10000); testRandomIntAtMost(); comptime testRandomIntAtMost(); } fn testRandomIntAtMost() void { var r = SequentialPrng.init(); r.next_value = 0xff; expect(r.random.uintAtMost(u8, 3) == 3); expect(r.next_value == 0); expect(r.random.uintAtMost(u8, 3) == 0); // trigger the bias rejection code path r.next_value = 0; expect(r.random.uintAtMost(u8, 2) == 0); // verify we incremented twice expect(r.next_value == 2); r.next_value = 0xff; expect(r.random.intRangeAtMost(u8, 0, 0x7f) == 0x7f); r.next_value = 0xff; expect(r.random.intRangeAtMost(u8, 0x7f, 0xfe) == 0xfe); r.next_value = 0xff; expect(r.random.intRangeAtMost(i8, 0, 0x3f) == 0x3f); r.next_value = 0xff; expect(r.random.intRangeAtMost(i8, -0x40, 0x3f) == 0x3f); r.next_value = 0xff; expect(r.random.intRangeAtMost(i8, -0x80, -1) == -1); r.next_value = 0xff; expect(r.random.intRangeAtMost(i3, -4, -1) == -1); r.next_value = 0xff; expect(r.random.intRangeAtMost(i3, -2, 1) == 1); expect(r.random.uintAtMost(u0, 0) == 0); } test "Random Biased" { var r = DefaultPrng.init(0); // Not thoroughly checking the logic here. // Just want to execute all the paths with different types. expect(r.random.uintLessThanBiased(u1, 1) == 0); expect(r.random.uintLessThanBiased(u32, 10) < 10); expect(r.random.uintLessThanBiased(u64, 20) < 20); expect(r.random.uintAtMostBiased(u0, 0) == 0); expect(r.random.uintAtMostBiased(u1, 0) <= 0); expect(r.random.uintAtMostBiased(u32, 10) <= 10); expect(r.random.uintAtMostBiased(u64, 20) <= 20); expect(r.random.intRangeLessThanBiased(u1, 0, 1) == 0); expect(r.random.intRangeLessThanBiased(i1, -1, 0) == -1); expect(r.random.intRangeLessThanBiased(u32, 10, 20) >= 10); expect(r.random.intRangeLessThanBiased(i32, 10, 20) >= 10); expect(r.random.intRangeLessThanBiased(u64, 20, 40) >= 20); expect(r.random.intRangeLessThanBiased(i64, 20, 40) >= 20); // uncomment for broken module error: //expect(r.random.intRangeAtMostBiased(u0, 0, 0) == 0); expect(r.random.intRangeAtMostBiased(u1, 0, 1) >= 0); expect(r.random.intRangeAtMostBiased(i1, -1, 0) >= -1); expect(r.random.intRangeAtMostBiased(u32, 10, 20) >= 10); expect(r.random.intRangeAtMostBiased(i32, 10, 20) >= 10); expect(r.random.intRangeAtMostBiased(u64, 20, 40) >= 20); expect(r.random.intRangeAtMostBiased(i64, 20, 40) >= 20); } // Generator to extend 64-bit seed values into longer sequences. // // The number of cycles is thus limited to 64-bits regardless of the engine, but this // is still plenty for practical purposes. const SplitMix64 = struct { s: u64, pub fn init(seed: u64) SplitMix64 { return SplitMix64{ .s = seed }; } pub fn next(self: *SplitMix64) u64 { self.s +%= 0x9e3779b97f4a7c15; var z = self.s; z = (z ^ (z >> 30)) *% 0xbf58476d1ce4e5b9; z = (z ^ (z >> 27)) *% 0x94d049bb133111eb; return z ^ (z >> 31); } }; test "splitmix64 sequence" { var r = SplitMix64.init(0xaeecf86f7878dd75); const seq = [_]u64{ 0x5dbd39db0178eb44, 0xa9900fb66b397da3, 0x5c1a28b1aeebcf5c, 0x64a963238f776912, 0xc6d4177b21d1c0ab, 0xb2cbdbdb5ea35394, }; for (seq) |s| { expect(s == r.next()); } } // PCG32 - http://www.pcg-random.org/ // // PRNG pub const Pcg = struct { const default_multiplier = 6364136223846793005; random: Random, s: u64, i: u64, pub fn init(init_s: u64) Pcg { var pcg = Pcg{ .random = Random{ .fillFn = fill }, .s = undefined, .i = undefined, }; pcg.seed(init_s); return pcg; } fn next(self: *Pcg) u32 { const l = self.s; self.s = l *% default_multiplier +% (self.i | 1); const xor_s = @truncate(u32, ((l >> 18) ^ l) >> 27); const rot = @intCast(u32, l >> 59); return (xor_s >> @intCast(u5, rot)) | (xor_s << @intCast(u5, (0 -% rot) & 31)); } fn seed(self: *Pcg, init_s: u64) void { // Pcg requires 128-bits of seed. var gen = SplitMix64.init(init_s); self.seedTwo(gen.next(), gen.next()); } fn seedTwo(self: *Pcg, init_s: u64, init_i: u64) void { self.s = 0; self.i = (init_s << 1) | 1; self.s = self.s *% default_multiplier +% self.i; self.s +%= init_i; self.s = self.s *% default_multiplier +% self.i; } fn fill(r: *Random, buf: []u8) void { const self = @fieldParentPtr(Pcg, "random", r); var i: usize = 0; const aligned_len = buf.len - (buf.len & 7); // Complete 4 byte segments. while (i < aligned_len) : (i += 4) { var n = self.next(); comptime var j: usize = 0; inline while (j < 4) : (j += 1) { buf[i + j] = @truncate(u8, n); n >>= 8; } } // Remaining. (cuts the stream) if (i != buf.len) { var n = self.next(); while (i < buf.len) : (i += 1) { buf[i] = @truncate(u8, n); n >>= 4; } } } }; test "pcg sequence" { var r = Pcg.init(0); const s0: u64 = 0x9394bf54ce5d79de; const s1: u64 = 0x84e9c579ef59bbf7; r.seedTwo(s0, s1); const seq = [_]u32{ 2881561918, 3063928540, 1199791034, 2487695858, 1479648952, 3247963454, }; for (seq) |s| { expect(s == r.next()); } } // Xoroshiro128+ - http://xoroshiro.di.unimi.it/ // // PRNG pub const Xoroshiro128 = struct { random: Random, s: [2]u64, pub fn init(init_s: u64) Xoroshiro128 { var x = Xoroshiro128{ .random = Random{ .fillFn = fill }, .s = undefined, }; x.seed(init_s); return x; } fn next(self: *Xoroshiro128) u64 { const s0 = self.s[0]; var s1 = self.s[1]; const r = s0 +% s1; s1 ^= s0; self.s[0] = math.rotl(u64, s0, @as(u8, 55)) ^ s1 ^ (s1 << 14); self.s[1] = math.rotl(u64, s1, @as(u8, 36)); return r; } // Skip 2^64 places ahead in the sequence fn jump(self: *Xoroshiro128) void { var s0: u64 = 0; var s1: u64 = 0; const table = [_]u64{ 0xbeac0467eba5facb, 0xd86b048b86aa9922, }; inline for (table) |entry| { var b: usize = 0; while (b < 64) : (b += 1) { if ((entry & (@as(u64, 1) << @intCast(u6, b))) != 0) { s0 ^= self.s[0]; s1 ^= self.s[1]; } _ = self.next(); } } self.s[0] = s0; self.s[1] = s1; } fn seed(self: *Xoroshiro128, init_s: u64) void { // Xoroshiro requires 128-bits of seed. var gen = SplitMix64.init(init_s); self.s[0] = gen.next(); self.s[1] = gen.next(); } fn fill(r: *Random, buf: []u8) void { const self = @fieldParentPtr(Xoroshiro128, "random", r); var i: usize = 0; const aligned_len = buf.len - (buf.len & 7); // Complete 8 byte segments. while (i < aligned_len) : (i += 8) { var n = self.next(); comptime var j: usize = 0; inline while (j < 8) : (j += 1) { buf[i + j] = @truncate(u8, n); n >>= 8; } } // Remaining. (cuts the stream) if (i != buf.len) { var n = self.next(); while (i < buf.len) : (i += 1) { buf[i] = @truncate(u8, n); n >>= 8; } } } }; test "xoroshiro sequence" { var r = Xoroshiro128.init(0); r.s[0] = 0xaeecf86f7878dd75; r.s[1] = 0x01cd153642e72622; const seq1 = [_]u64{ 0xb0ba0da5bb600397, 0x18a08afde614dccc, 0xa2635b956a31b929, 0xabe633c971efa045, 0x9ac19f9706ca3cac, 0xf62b426578c1e3fb, }; for (seq1) |s| { expect(s == r.next()); } r.jump(); const seq2 = [_]u64{ 0x95344a13556d3e22, 0xb4fb32dafa4d00df, 0xb2011d9ccdcfe2dd, 0x05679a9b2119b908, 0xa860a1da7c9cd8a0, 0x658a96efe3f86550, }; for (seq2) |s| { expect(s == r.next()); } } // Gimli // // CSPRNG pub const Gimli = struct { random: Random, state: std.crypto.gimli.State, pub fn init(init_s: u64) Gimli { var self = Gimli{ .random = Random{ .fillFn = fill }, .state = std.crypto.gimli.State{ .data = [_]u32{0} ** (std.crypto.gimli.State.BLOCKBYTES / 4), }, }; self.state.data[0] = @truncate(u32, init_s >> 32); self.state.data[1] = @truncate(u32, init_s); return self; } fn fill(r: *Random, buf: []u8) void { const self = @fieldParentPtr(Gimli, "random", r); self.state.squeeze(buf); } }; // ISAAC64 - http://www.burtleburtle.net/bob/rand/isaacafa.html // // CSPRNG // // Follows the general idea of the implementation from here with a few shortcuts. // https://doc.rust-lang.org/rand/src/rand/prng/isaac64.rs.html pub const Isaac64 = struct { random: Random, r: [256]u64, m: [256]u64, a: u64, b: u64, c: u64, i: usize, pub fn init(init_s: u64) Isaac64 { var isaac = Isaac64{ .random = Random{ .fillFn = fill }, .r = undefined, .m = undefined, .a = undefined, .b = undefined, .c = undefined, .i = undefined, }; // seed == 0 => same result as the unseeded reference implementation isaac.seed(init_s, 1); return isaac; } fn step(self: *Isaac64, mix: u64, base: usize, comptime m1: usize, comptime m2: usize) void { const x = self.m[base + m1]; self.a = mix +% self.m[base + m2]; const y = self.a +% self.b +% self.m[@intCast(usize, (x >> 3) % self.m.len)]; self.m[base + m1] = y; self.b = x +% self.m[@intCast(usize, (y >> 11) % self.m.len)]; self.r[self.r.len - 1 - base - m1] = self.b; } fn refill(self: *Isaac64) void { const midpoint = self.r.len / 2; self.c +%= 1; self.b +%= self.c; { var i: usize = 0; while (i < midpoint) : (i += 4) { self.step(~(self.a ^ (self.a << 21)), i + 0, 0, midpoint); self.step(self.a ^ (self.a >> 5), i + 1, 0, midpoint); self.step(self.a ^ (self.a << 12), i + 2, 0, midpoint); self.step(self.a ^ (self.a >> 33), i + 3, 0, midpoint); } } { var i: usize = 0; while (i < midpoint) : (i += 4) { self.step(~(self.a ^ (self.a << 21)), i + 0, midpoint, 0); self.step(self.a ^ (self.a >> 5), i + 1, midpoint, 0); self.step(self.a ^ (self.a << 12), i + 2, midpoint, 0); self.step(self.a ^ (self.a >> 33), i + 3, midpoint, 0); } } self.i = 0; } fn next(self: *Isaac64) u64 { if (self.i >= self.r.len) { self.refill(); } const value = self.r[self.i]; self.i += 1; return value; } fn seed(self: *Isaac64, init_s: u64, comptime rounds: usize) void { // We ignore the multi-pass requirement since we don't currently expose full access to // seeding the self.m array completely. mem.set(u64, self.m[0..], 0); self.m[0] = init_s; // prescrambled golden ratio constants var a = [_]u64{ 0x647c4677a2884b7c, 0xb9f8b322c73ac862, 0x8c0ea5053d4712a0, 0xb29b2e824a595524, 0x82f053db8355e0ce, 0x48fe4a0fa5a09315, 0xae985bf2cbfc89ed, 0x98f5704f6c44c0ab, }; comptime var i: usize = 0; inline while (i < rounds) : (i += 1) { var j: usize = 0; while (j < self.m.len) : (j += 8) { comptime var x1: usize = 0; inline while (x1 < 8) : (x1 += 1) { a[x1] +%= self.m[j + x1]; } a[0] -%= a[4]; a[5] ^= a[7] >> 9; a[7] +%= a[0]; a[1] -%= a[5]; a[6] ^= a[0] << 9; a[0] +%= a[1]; a[2] -%= a[6]; a[7] ^= a[1] >> 23; a[1] +%= a[2]; a[3] -%= a[7]; a[0] ^= a[2] << 15; a[2] +%= a[3]; a[4] -%= a[0]; a[1] ^= a[3] >> 14; a[3] +%= a[4]; a[5] -%= a[1]; a[2] ^= a[4] << 20; a[4] +%= a[5]; a[6] -%= a[2]; a[3] ^= a[5] >> 17; a[5] +%= a[6]; a[7] -%= a[3]; a[4] ^= a[6] << 14; a[6] +%= a[7]; comptime var x2: usize = 0; inline while (x2 < 8) : (x2 += 1) { self.m[j + x2] = a[x2]; } } } mem.set(u64, self.r[0..], 0); self.a = 0; self.b = 0; self.c = 0; self.i = self.r.len; // trigger refill on first value } fn fill(r: *Random, buf: []u8) void { const self = @fieldParentPtr(Isaac64, "random", r); var i: usize = 0; const aligned_len = buf.len - (buf.len & 7); // Fill complete 64-byte segments while (i < aligned_len) : (i += 8) { var n = self.next(); comptime var j: usize = 0; inline while (j < 8) : (j += 1) { buf[i + j] = @truncate(u8, n); n >>= 8; } } // Fill trailing, ignoring excess (cut the stream). if (i != buf.len) { var n = self.next(); while (i < buf.len) : (i += 1) { buf[i] = @truncate(u8, n); n >>= 8; } } } }; test "isaac64 sequence" { var r = Isaac64.init(0); // from reference implementation const seq = [_]u64{ 0xf67dfba498e4937c, 0x84a5066a9204f380, 0xfee34bd5f5514dbb, 0x4d1664739b8f80d6, 0x8607459ab52a14aa, 0x0e78bc5a98529e49, 0xfe5332822ad13777, 0x556c27525e33d01a, 0x08643ca615f3149f, 0xd0771faf3cb04714, 0x30e86f68a37b008d, 0x3074ebc0488a3adf, 0x270645ea7a2790bc, 0x5601a0a8d3763c6a, 0x2f83071f53f325dd, 0xb9090f3d42d2d2ea, }; for (seq) |s| { expect(s == r.next()); } } /// Sfc64 pseudo-random number generator from Practically Random. /// Fastest engine of pracrand and smallest footprint. /// See http://pracrand.sourceforge.net/ pub const Sfc64 = struct { random: Random, a: u64 = undefined, b: u64 = undefined, c: u64 = undefined, counter: u64 = undefined, const Rotation = 24; const RightShift = 11; const LeftShift = 3; pub fn init(init_s: u64) Sfc64 { var x = Sfc64{ .random = Random{ .fillFn = fill }, }; x.seed(init_s); return x; } fn next(self: *Sfc64) u64 { const tmp = self.a +% self.b +% self.counter; self.counter += 1; self.a = self.b ^ (self.b >> RightShift); self.b = self.c +% (self.c << LeftShift); self.c = math.rotl(u64, self.c, Rotation) +% tmp; return tmp; } fn seed(self: *Sfc64, init_s: u64) void { self.a = init_s; self.b = init_s; self.c = init_s; self.counter = 1; var i: u32 = 0; while (i < 12) : (i += 1) { _ = self.next(); } } fn fill(r: *Random, buf: []u8) void { const self = @fieldParentPtr(Sfc64, "random", r); var i: usize = 0; const aligned_len = buf.len - (buf.len & 7); // Complete 8 byte segments. while (i < aligned_len) : (i += 8) { var n = self.next(); comptime var j: usize = 0; inline while (j < 8) : (j += 1) { buf[i + j] = @truncate(u8, n); n >>= 8; } } // Remaining. (cuts the stream) if (i != buf.len) { var n = self.next(); while (i < buf.len) : (i += 1) { buf[i] = @truncate(u8, n); n >>= 8; } } } }; test "Sfc64 sequence" { // Unfortunately there does not seem to be an official test sequence. var r = Sfc64.init(0); const seq = [_]u64{ 0x3acfa029e3cc6041, 0xf5b6515bf2ee419c, 0x1259635894a29b61, 0xb6ae75395f8ebd6, 0x225622285ce302e2, 0x520d28611395cb21, 0xdb909c818901599d, 0x8ffd195365216f57, 0xe8c4ad5e258ac04a, 0x8f8ef2c89fdb63ca, 0xf9865b01d98d8e2f, 0x46555871a65d08ba, 0x66868677c6298fcd, 0x2ce15a7e6329f57d, 0xb2f1833ca91ca79, 0x4b0890ac9bf453ca, }; for (seq) |s| { expectEqual(s, r.next()); } } // Actual Random helper function tests, pcg engine is assumed correct. test "Random float" { var prng = DefaultPrng.init(0); var i: usize = 0; while (i < 1000) : (i += 1) { const val1 = prng.random.float(f32); expect(val1 >= 0.0); expect(val1 < 1.0); const val2 = prng.random.float(f64); expect(val2 >= 0.0); expect(val2 < 1.0); } } test "Random shuffle" { var prng = DefaultPrng.init(0); var seq = [_]u8{ 0, 1, 2, 3, 4 }; var seen = [_]bool{false} ** 5; var i: usize = 0; while (i < 1000) : (i += 1) { prng.random.shuffle(u8, seq[0..]); seen[seq[0]] = true; expect(sumArray(seq[0..]) == 10); } // we should see every entry at the head at least once for (seen) |e| { expect(e == true); } } fn sumArray(s: []const u8) u32 { var r: u32 = 0; for (s) |e| r += e; return r; } test "Random range" { var prng = DefaultPrng.init(0); testRange(&prng.random, -4, 3); testRange(&prng.random, -4, -1); testRange(&prng.random, 10, 14); testRange(&prng.random, -0x80, 0x7f); } fn testRange(r: *Random, start: i8, end: i8) void { testRangeBias(r, start, end, true); testRangeBias(r, start, end, false); } fn testRangeBias(r: *Random, start: i8, end: i8, biased: bool) void { const count = @intCast(usize, @as(i32, end) - @as(i32, start)); var values_buffer = [_]bool{false} ** 0x100; const values = values_buffer[0..count]; var i: usize = 0; while (i < count) { const value: i32 = if (biased) r.intRangeLessThanBiased(i8, start, end) else r.intRangeLessThan(i8, start, end); const index = @intCast(usize, value - start); if (!values[index]) { i += 1; values[index] = true; } } } test "" { std.meta.refAllDecls(@This()); }