mirror of
https://github.com/vlang/v.git
synced 2023-08-10 21:13:21 +03:00
739 lines
23 KiB
V
739 lines
23 KiB
V
// Copyright (c) 2019-2022 Alexander Medvednikov. All rights reserved.
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// Use of this source code is governed by an MIT license
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// that can be found in the LICENSE file.
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[has_globals]
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module rand
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import math.bits
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import rand.config
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import rand.constants
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import rand.wyrand
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import time
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// PRNG is a common interface for all PRNGs that can be used seamlessly with the rand
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// modules's API. It defines all the methods that a PRNG (in the vlib or custom made) must
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// implement in order to ensure that _all_ functions can be used with the generator.
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pub interface PRNG {
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mut:
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seed(seed_data []u32)
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u8() u8
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u16() u16
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u32() u32
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u64() u64
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block_size() int
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free()
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}
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// bytes returns a buffer of `bytes_needed` random bytes
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[inline]
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pub fn (mut rng PRNG) bytes(bytes_needed int) ![]u8 {
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if bytes_needed < 0 {
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return error('can not read < 0 random bytes')
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}
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mut buffer := []u8{len: bytes_needed}
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read_internal(mut rng, mut buffer)
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return buffer
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}
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// read fills in `buf` with a maximum of `buf.len` random bytes
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pub fn (mut rng PRNG) read(mut buf []u8) {
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read_internal(mut rng, mut buf)
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}
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// u32n returns a uniformly distributed pseudorandom 32-bit signed positive `u32` in range `[0, max)`.
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[inline]
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pub fn (mut rng PRNG) u32n(max u32) !u32 {
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if max == 0 {
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return error('max must be positive integer')
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}
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// Owing to the pigeon-hole principle, we can't simply do
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// val := rng.u32() % max.
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// It'll wreck the properties of the distribution unless
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// max evenly divides 2^32. So we divide evenly to
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// the closest power of two. Then we loop until we find
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// an int in the required range
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bit_len := bits.len_32(max)
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if bit_len == 32 {
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for {
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value := rng.u32()
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if value < max {
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return value
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}
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}
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} else {
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mask := (u32(1) << (bit_len + 1)) - 1
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for {
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value := rng.u32() & mask
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if value < max {
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return value
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}
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}
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}
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return u32(0)
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}
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// u64n returns a uniformly distributed pseudorandom 64-bit signed positive `u64` in range `[0, max)`.
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[inline]
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pub fn (mut rng PRNG) u64n(max u64) !u64 {
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if max == 0 {
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return error('max must be positive integer')
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}
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bit_len := bits.len_64(max)
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if bit_len == 64 {
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for {
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value := rng.u64()
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if value < max {
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return value
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}
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}
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} else {
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mask := (u64(1) << (bit_len + 1)) - 1
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for {
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value := rng.u64() & mask
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if value < max {
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return value
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}
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}
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}
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return u64(0)
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}
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// u32_in_range returns a uniformly distributed pseudorandom 32-bit unsigned `u32` in range `[min, max)`.
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[inline]
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pub fn (mut rng PRNG) u32_in_range(min u32, max u32) !u32 {
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if max <= min {
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return error('max must be greater than min')
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}
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return min + rng.u32n(max - min)!
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}
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// u64_in_range returns a uniformly distributed pseudorandom 64-bit unsigned `u64` in range `[min, max)`.
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[inline]
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pub fn (mut rng PRNG) u64_in_range(min u64, max u64) !u64 {
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if max <= min {
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return error('max must be greater than min')
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}
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return min + rng.u64n(max - min)!
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}
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// i8 returns a (possibly negative) pseudorandom 8-bit `i8`.
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[inline]
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pub fn (mut rng PRNG) i8() i8 {
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return i8(rng.u8())
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}
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// i16 returns a (possibly negative) pseudorandom 16-bit `i16`.
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[inline]
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pub fn (mut rng PRNG) i16() i16 {
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return i16(rng.u16())
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}
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// int returns a (possibly negative) pseudorandom 32-bit `int`.
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[inline]
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pub fn (mut rng PRNG) int() int {
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return int(rng.u32())
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}
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// i64 returns a (possibly negative) pseudorandom 64-bit `i64`.
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[inline]
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pub fn (mut rng PRNG) i64() i64 {
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return i64(rng.u64())
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}
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// int31 returns a positive pseudorandom 31-bit `int`.
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[inline]
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pub fn (mut rng PRNG) int31() int {
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return int(rng.u32() & constants.u31_mask) // Set the 32nd bit to 0.
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}
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// int63 returns a positive pseudorandom 63-bit `i64`.
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[inline]
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pub fn (mut rng PRNG) int63() i64 {
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return i64(rng.u64() & constants.u63_mask) // Set the 64th bit to 0.
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}
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// intn returns a pseudorandom `int` in range `[0, max)`.
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[inline]
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pub fn (mut rng PRNG) intn(max int) !int {
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if max <= 0 {
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return error('max has to be positive.')
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}
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return int(rng.u32n(u32(max))!)
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}
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// i64n returns a pseudorandom int that lies in `[0, max)`.
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[inline]
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pub fn (mut rng PRNG) i64n(max i64) !i64 {
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if max <= 0 {
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return error('max has to be positive.')
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}
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return i64(rng.u64n(u64(max))!)
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}
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// int_in_range returns a pseudorandom `int` in range `[min, max)`.
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[inline]
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pub fn (mut rng PRNG) int_in_range(min int, max int) !int {
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if max <= min {
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return error('max must be greater than min')
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}
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// This supports negative ranges like [-10, -5) because the difference is positive
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return min + rng.intn(max - min)!
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}
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// i64_in_range returns a pseudorandom `i64` in range `[min, max)`.
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[inline]
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pub fn (mut rng PRNG) i64_in_range(min i64, max i64) !i64 {
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if max <= min {
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return error('max must be greater than min')
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}
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return min + rng.i64n(max - min)!
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}
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// f32 returns a pseudorandom `f32` value in range `[0, 1)`
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// using rng.u32() multiplied by an f64 constant.
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[inline]
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pub fn (mut rng PRNG) f32() f32 {
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return f32((rng.u32() >> 9) * constants.reciprocal_2_23rd)
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}
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// f32cp returns a pseudorandom `f32` value in range `[0, 1)`
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// with full precision (mantissa random between 0 and 1
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// and the exponent varies as well.)
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// See https://allendowney.com/research/rand/ for background on the method.
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[inline]
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pub fn (mut rng PRNG) f32cp() f32 {
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mut x := rng.u32()
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mut exp := u32(126)
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mut mask := u32(1) << 31
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// check if prng returns 0; rare but keep looking for precision
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if _unlikely_(x == 0) {
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x = rng.u32()
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exp -= 31
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}
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// count leading one bits and scale exponent accordingly
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for {
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if x & mask != 0 {
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mask >>= 1
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exp -= 1
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} else {
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break
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}
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}
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// if we used any high-order mantissa bits; replace x
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if exp < (126 - 8) {
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x = rng.u32()
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}
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// Assumes little-endian IEEE floating point.
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x = (exp << 23) | (x >> 8) & constants.ieee754_mantissa_f32_mask
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return bits.f32_from_bits(x)
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}
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// f64 returns a pseudorandom `f64` value in range `[0, 1)`
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// using rng.u64() multiplied by a constant.
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[inline]
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pub fn (mut rng PRNG) f64() f64 {
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return f64((rng.u64() >> 12) * constants.reciprocal_2_52nd)
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}
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// f64cp returns a pseudorandom `f64` value in range `[0, 1)`
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// with full precision (mantissa random between 0 and 1
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// and the exponent varies as well.)
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// See https://allendowney.com/research/rand/ for background on the method.
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[inline]
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pub fn (mut rng PRNG) f64cp() f64 {
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mut x := rng.u64()
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mut exp := u64(1022)
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mut mask := u64(1) << 63
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mut bitcount := u32(0)
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// check if prng returns 0; unlikely.
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if _unlikely_(x == 0) {
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x = rng.u64()
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exp -= 31
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}
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// count leading one bits and scale exponent accordingly
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for {
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if x & mask != 0 {
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mask >>= 1
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bitcount += 1
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} else {
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break
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}
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}
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exp -= bitcount
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if bitcount > 11 {
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x = rng.u64()
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}
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x = (exp << 52) | (x & constants.ieee754_mantissa_f64_mask)
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return bits.f64_from_bits(x)
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}
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// f32n returns a pseudorandom `f32` value in range `[0, max]`.
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[inline]
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pub fn (mut rng PRNG) f32n(max f32) !f32 {
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if max < 0 {
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return error('max has to be non-negative.')
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}
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return rng.f32() * max
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}
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// f64n returns a pseudorandom `f64` value in range `[0, max]`.
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[inline]
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pub fn (mut rng PRNG) f64n(max f64) !f64 {
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if max < 0 {
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return error('max has to be non-negative.')
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}
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return rng.f64() * max
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}
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// f32_in_range returns a pseudorandom `f32` in range `[min, max]`.
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[inline]
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pub fn (mut rng PRNG) f32_in_range(min f32, max f32) !f32 {
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if max < min {
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return error('max must be greater than or equal to min')
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}
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return min + rng.f32n(max - min)!
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}
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// i64_in_range returns a pseudorandom `i64` in range `[min, max]`.
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[inline]
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pub fn (mut rng PRNG) f64_in_range(min f64, max f64) !f64 {
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if max < min {
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return error('max must be greater than or equal to min')
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}
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return min + rng.f64n(max - min)!
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}
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// ulid generates an Unique Lexicographically sortable IDentifier.
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// See https://github.com/ulid/spec .
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// Note: ULIDs can leak timing information, if you make them public, because
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// you can infer the rate at which some resource is being created, like
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// users or business transactions.
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// (https://news.ycombinator.com/item?id=14526173)
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pub fn (mut rng PRNG) ulid() string {
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return internal_ulid_at_millisecond(mut rng, u64(time.utc().unix_time_milli()))
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}
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// ulid_at_millisecond does the same as `ulid` but takes a custom Unix millisecond timestamp via `unix_time_milli`.
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pub fn (mut rng PRNG) ulid_at_millisecond(unix_time_milli u64) string {
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return internal_ulid_at_millisecond(mut rng, unix_time_milli)
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}
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// string_from_set returns a string of length `len` containing random characters sampled from the given `charset`
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pub fn (mut rng PRNG) string_from_set(charset string, len int) string {
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return internal_string_from_set(mut rng, charset, len)
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}
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// string returns a string of length `len` containing random characters in range `[a-zA-Z]`.
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pub fn (mut rng PRNG) string(len int) string {
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return internal_string_from_set(mut rng, rand.english_letters, len)
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}
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// hex returns a hexadecimal number of length `len` containing random characters in range `[a-f0-9]`.
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pub fn (mut rng PRNG) hex(len int) string {
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return internal_string_from_set(mut rng, rand.hex_chars, len)
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}
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// ascii returns a random string of the printable ASCII characters with length `len`.
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pub fn (mut rng PRNG) ascii(len int) string {
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return internal_string_from_set(mut rng, rand.ascii_chars, len)
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}
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// bernoulli returns true with a probability p. Note that 0 <= p <= 1.
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pub fn (mut rng PRNG) bernoulli(p f64) !bool {
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if p < 0 || p > 1 {
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return error('${p} is not a valid probability value.')
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}
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return rng.f64() <= p
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}
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// normal returns a normally distributed pseudorandom f64 in range `[0, 1)`.
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// NOTE: Use normal_pair() instead if you're generating a lot of normal variates.
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pub fn (mut rng PRNG) normal(conf config.NormalConfigStruct) !f64 {
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x, _ := rng.normal_pair(conf)!
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return x
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}
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// normal_pair returns a pair of normally distributed pseudorandom f64 in range `[0, 1)`.
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pub fn (mut rng PRNG) normal_pair(conf config.NormalConfigStruct) !(f64, f64) {
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if conf.sigma <= 0 {
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return error('Standard deviation must be positive')
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}
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// This is an implementation of the Marsaglia polar method
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// See: https://doi.org/10.1137%2F1006063
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// Also: https://en.wikipedia.org/wiki/Marsaglia_polar_method
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for {
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u := rng.f64_in_range(-1, 1) or { 0.0 }
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v := rng.f64_in_range(-1, 1) or { 0.0 }
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s := u * u + v * v
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if s >= 1 || s == 0 {
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continue
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}
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t := msqrt(-2 * mlog(s) / s)
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x := conf.mu + conf.sigma * t * u
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y := conf.mu + conf.sigma * t * v
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return x, y
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}
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return error('Implementation error. Please file an issue.')
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}
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// binomial returns the number of successful trials out of n when the
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// probability of success for each trial is p.
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pub fn (mut rng PRNG) binomial(n int, p f64) !int {
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if p < 0 || p > 1 {
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return error('${p} is not a valid probability value.')
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}
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mut count := 0
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for _ in 0 .. n {
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if rng.bernoulli(p)! {
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count++
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}
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}
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return count
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}
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// exponential returns an exponentially distributed random number with the rate paremeter
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// lambda. It is expected that lambda is positive.
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pub fn (mut rng PRNG) exponential(lambda f64) f64 {
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if lambda <= 0 {
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panic('The rate (lambda) must be positive.')
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}
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// Use the inverse transform sampling method
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return -mlog(rng.f64()) / lambda
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}
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// shuffle randomly permutates the elements in `a`. The range for shuffling is
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// optional and the entire array is shuffled by default. Leave the end as 0 to
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// shuffle all elements until the end.
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[direct_array_access]
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pub fn (mut rng PRNG) shuffle[T](mut a []T, config config.ShuffleConfigStruct) ! {
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config.validate_for(a)!
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new_end := if config.end == 0 { a.len } else { config.end }
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// We implement the Fisher-Yates shuffle:
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// https://en.wikipedia.org/wiki/Fisher%E2%80%93Yates_shuffle#The_modern_algorithm
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for i in config.start .. new_end - 2 {
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x := rng.int_in_range(i, new_end) or { i }
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// swap
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a_i := a[i]
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a[i] = a[x]
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a[x] = a_i
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}
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}
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// shuffle_clone returns a random permutation of the elements in `a`.
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// The permutation is done on a fresh clone of `a`, so `a` remains unchanged.
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pub fn (mut rng PRNG) shuffle_clone[T](a []T, config config.ShuffleConfigStruct) ![]T {
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mut res := a.clone()
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rng.shuffle[T](mut res, config)!
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return res
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}
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// choose samples k elements from the array without replacement.
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// This means the indices cannot repeat and it restricts the sample size to be less than or equal to the size of the given array.
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// Note that if the array has repeating elements, then the sample may have repeats as well.
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pub fn (mut rng PRNG) choose[T](array []T, k int) ![]T {
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n := array.len
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if k > n {
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return error('Cannot choose ${k} elements without replacement from a ${n}-element array.')
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}
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mut results := []T{len: k}
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mut indices := []int{len: n, init: it}
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rng.shuffle[int](mut indices)!
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for i in 0 .. k {
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results[i] = array[indices[i]]
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}
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return results
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}
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// element returns a random element from the given array.
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// Note that all the positions in the array have an equal chance of being selected. This means that if the array has repeating elements, then the probability of selecting a particular element is not uniform.
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pub fn (mut rng PRNG) element[T](array []T) !T {
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if array.len == 0 {
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return error('Cannot choose an element from an empty array.')
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}
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return array[rng.intn(array.len)!]
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}
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// sample samples k elements from the array with replacement.
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// This means the elements can repeat and the size of the sample may exceed the size of the array.
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pub fn (mut rng PRNG) sample[T](array []T, k int) []T {
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mut results := []T{len: k}
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for i in 0 .. k {
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results[i] = array[rng.intn(array.len) or { 0 }]
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}
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return results
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}
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__global default_rng &PRNG
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// new_default returns a new instance of the default RNG. If the seed is not provided, the current time will be used to seed the instance.
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[manualfree]
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pub fn new_default(config config.PRNGConfigStruct) &PRNG {
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mut rng := &wyrand.WyRandRNG{}
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rng.seed(config.seed_)
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unsafe { config.seed_.free() }
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return &PRNG(rng)
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}
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// get_current_rng returns the PRNG instance currently in use. If it is not changed, it will be an instance of wyrand.WyRandRNG.
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pub fn get_current_rng() &PRNG {
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return default_rng
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}
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|
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// set_rng changes the default RNG from wyrand.WyRandRNG (or whatever the last RNG was) to the one
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// provided by the user. Note that this new RNG must be seeded manually with a constant seed or the
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// `seed.time_seed_array()` method. Also, it is recommended to store the old RNG in a variable and
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// should be restored if work with the custom RNG is complete. It is not necessary to restore if the
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// program terminates soon afterwards.
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pub fn set_rng(rng &PRNG) {
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default_rng = unsafe { rng }
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}
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// seed sets the given array of `u32` values as the seed for the `default_rng`. The default_rng is
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// an instance of WyRandRNG which takes 2 u32 values. When using a custom RNG, make sure to use
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// the correct number of u32s.
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pub fn seed(seed []u32) {
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default_rng.seed(seed)
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}
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// u32 returns a uniformly distributed `u32` in range `[0, 2³²)`.
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pub fn u32() u32 {
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return default_rng.u32()
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}
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|
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// u64 returns a uniformly distributed `u64` in range `[0, 2⁶⁴)`.
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|
pub fn u64() u64 {
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return default_rng.u64()
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|
}
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|
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// u32n returns a uniformly distributed pseudorandom 32-bit signed positive `u32` in range `[0, max)`.
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pub fn u32n(max u32) !u32 {
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return default_rng.u32n(max)
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}
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|
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// u64n returns a uniformly distributed pseudorandom 64-bit signed positive `u64` in range `[0, max)`.
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pub fn u64n(max u64) !u64 {
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|
return default_rng.u64n(max)
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|
}
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|
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// u32_in_range returns a uniformly distributed pseudorandom 32-bit unsigned `u32` in range `[min, max)`.
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|
pub fn u32_in_range(min u32, max u32) !u32 {
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|
return default_rng.u32_in_range(min, max)
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|
}
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|
|
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// u64_in_range returns a uniformly distributed pseudorandom 64-bit unsigned `u64` in range `[min, max)`.
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|
pub fn u64_in_range(min u64, max u64) !u64 {
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|
return default_rng.u64_in_range(min, max)
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|
}
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|
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|
// i16 returns a uniformly distributed pseudorandom 16-bit signed (possibly negative) `i16`.
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|
pub fn i16() i16 {
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|
return default_rng.i16()
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|
}
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|
|
|
// int returns a uniformly distributed pseudorandom 32-bit signed (possibly negative) `int`.
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|
pub fn int() int {
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|
return default_rng.int()
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|
}
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|
|
|
// intn returns a uniformly distributed pseudorandom 32-bit signed positive `int` in range `[0, max)`.
|
|
pub fn intn(max int) !int {
|
|
return default_rng.intn(max)
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|
}
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|
|
|
// byte returns a uniformly distributed pseudorandom 8-bit unsigned positive `byte`.
|
|
pub fn u8() u8 {
|
|
return default_rng.u8()
|
|
}
|
|
|
|
// int_in_range returns a uniformly distributed pseudorandom 32-bit signed int in range `[min, max)`.
|
|
// Both `min` and `max` can be negative, but we must have `min < max`.
|
|
pub fn int_in_range(min int, max int) !int {
|
|
return default_rng.int_in_range(min, max)
|
|
}
|
|
|
|
// int31 returns a uniformly distributed pseudorandom 31-bit signed positive `int`.
|
|
pub fn int31() int {
|
|
return default_rng.int31()
|
|
}
|
|
|
|
// i64 returns a uniformly distributed pseudorandom 64-bit signed (possibly negative) `i64`.
|
|
pub fn i64() i64 {
|
|
return default_rng.i64()
|
|
}
|
|
|
|
// i64n returns a uniformly distributed pseudorandom 64-bit signed positive `i64` in range `[0, max)`.
|
|
pub fn i64n(max i64) !i64 {
|
|
return default_rng.i64n(max)
|
|
}
|
|
|
|
// i64_in_range returns a uniformly distributed pseudorandom 64-bit signed `i64` in range `[min, max)`.
|
|
pub fn i64_in_range(min i64, max i64) !i64 {
|
|
return default_rng.i64_in_range(min, max)
|
|
}
|
|
|
|
// int63 returns a uniformly distributed pseudorandom 63-bit signed positive `i64`.
|
|
pub fn int63() i64 {
|
|
return default_rng.int63()
|
|
}
|
|
|
|
// f32 returns a uniformly distributed 32-bit floating point in range `[0, 1)`.
|
|
pub fn f32() f32 {
|
|
return default_rng.f32()
|
|
}
|
|
|
|
// f32cp returns a uniformly distributed 32-bit floating point in range `[0, 1)`
|
|
// with full precision mantissa.
|
|
pub fn f32cp() f32 {
|
|
return default_rng.f32cp()
|
|
}
|
|
|
|
// f64 returns a uniformly distributed 64-bit floating point in range `[0, 1)`.
|
|
pub fn f64() f64 {
|
|
return default_rng.f64()
|
|
}
|
|
|
|
// f64 returns a uniformly distributed 64-bit floating point in range `[0, 1)`
|
|
// with full precision mantissa.
|
|
pub fn f64cp() f64 {
|
|
return default_rng.f64cp()
|
|
}
|
|
|
|
// f32n returns a uniformly distributed 32-bit floating point in range `[0, max)`.
|
|
pub fn f32n(max f32) !f32 {
|
|
return default_rng.f32n(max)
|
|
}
|
|
|
|
// f64n returns a uniformly distributed 64-bit floating point in range `[0, max)`.
|
|
pub fn f64n(max f64) !f64 {
|
|
return default_rng.f64n(max)
|
|
}
|
|
|
|
// f32_in_range returns a uniformly distributed 32-bit floating point in range `[min, max)`.
|
|
pub fn f32_in_range(min f32, max f32) !f32 {
|
|
return default_rng.f32_in_range(min, max)
|
|
}
|
|
|
|
// f64_in_range returns a uniformly distributed 64-bit floating point in range `[min, max)`.
|
|
pub fn f64_in_range(min f64, max f64) !f64 {
|
|
return default_rng.f64_in_range(min, max)
|
|
}
|
|
|
|
// bytes returns a buffer of `bytes_needed` random bytes
|
|
pub fn bytes(bytes_needed int) ![]u8 {
|
|
return default_rng.bytes(bytes_needed)
|
|
}
|
|
|
|
// read fills in `buf` a maximum of `buf.len` random bytes
|
|
pub fn read(mut buf []u8) {
|
|
read_internal(mut default_rng, mut buf)
|
|
}
|
|
|
|
const (
|
|
english_letters = 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ'
|
|
hex_chars = 'abcdef0123456789'
|
|
ascii_chars = '!"#$%&\'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ\\^_`abcdefghijklmnopqrstuvwxyz{|}~'
|
|
)
|
|
|
|
// ulid generates an Unique Lexicographically sortable IDentifier.
|
|
// See https://github.com/ulid/spec .
|
|
// Note: ULIDs can leak timing information, if you make them public, because
|
|
// you can infer the rate at which some resource is being created, like
|
|
// users or business transactions.
|
|
// (https://news.ycombinator.com/item?id=14526173)
|
|
pub fn ulid() string {
|
|
return default_rng.ulid()
|
|
}
|
|
|
|
// ulid_at_millisecond does the same as `ulid` but takes a custom Unix millisecond timestamp via `unix_time_milli`.
|
|
pub fn ulid_at_millisecond(unix_time_milli u64) string {
|
|
return default_rng.ulid_at_millisecond(unix_time_milli)
|
|
}
|
|
|
|
// string_from_set returns a string of length `len` containing random characters sampled from the given `charset`
|
|
pub fn string_from_set(charset string, len int) string {
|
|
return default_rng.string_from_set(charset, len)
|
|
}
|
|
|
|
// string returns a string of length `len` containing random characters in range `[a-zA-Z]`.
|
|
pub fn string(len int) string {
|
|
return string_from_set(rand.english_letters, len)
|
|
}
|
|
|
|
// hex returns a hexadecimal number of length `len` containing random characters in range `[a-f0-9]`.
|
|
pub fn hex(len int) string {
|
|
return string_from_set(rand.hex_chars, len)
|
|
}
|
|
|
|
// ascii returns a random string of the printable ASCII characters with length `len`.
|
|
pub fn ascii(len int) string {
|
|
return string_from_set(rand.ascii_chars, len)
|
|
}
|
|
|
|
// shuffle randomly permutates the elements in `a`. The range for shuffling is
|
|
// optional and the entire array is shuffled by default. Leave the end as 0 to
|
|
// shuffle all elements until the end.
|
|
pub fn shuffle[T](mut a []T, config config.ShuffleConfigStruct) ! {
|
|
default_rng.shuffle[T](mut a, config)!
|
|
}
|
|
|
|
// shuffle_clone returns a random permutation of the elements in `a`.
|
|
// The permutation is done on a fresh clone of `a`, so `a` remains unchanged.
|
|
pub fn shuffle_clone[T](a []T, config config.ShuffleConfigStruct) ![]T {
|
|
return default_rng.shuffle_clone[T](a, config)
|
|
}
|
|
|
|
// choose samples k elements from the array without replacement.
|
|
// This means the indices cannot repeat and it restricts the sample size to be less than or equal to the size of the given array.
|
|
// Note that if the array has repeating elements, then the sample may have repeats as well.
|
|
pub fn choose[T](array []T, k int) ![]T {
|
|
return default_rng.choose[T](array, k)
|
|
}
|
|
|
|
// element returns a random element from the given array.
|
|
// Note that all the positions in the array have an equal chance of being selected. This means that if the array has repeating elements, then the probability of selecting a particular element is not uniform.
|
|
pub fn element[T](array []T) !T {
|
|
return default_rng.element[T](array)
|
|
}
|
|
|
|
// sample samples k elements from the array with replacement.
|
|
// This means the elements can repeat and the size of the sample may exceed the size of the array.
|
|
pub fn sample[T](array []T, k int) []T {
|
|
return default_rng.sample[T](array, k)
|
|
}
|
|
|
|
// bernoulli returns true with a probability p. Note that 0 <= p <= 1.
|
|
pub fn bernoulli(p f64) !bool {
|
|
return default_rng.bernoulli(p)
|
|
}
|
|
|
|
// normal returns a normally distributed pseudorandom f64 in range `[0, 1)`.
|
|
// NOTE: Use normal_pair() instead if you're generating a lot of normal variates.
|
|
pub fn normal(conf config.NormalConfigStruct) !f64 {
|
|
return default_rng.normal(conf)
|
|
}
|
|
|
|
// normal_pair returns a pair of normally distributed pseudorandom f64 in range `[0, 1)`.
|
|
pub fn normal_pair(conf config.NormalConfigStruct) !(f64, f64) {
|
|
return default_rng.normal_pair(conf)
|
|
}
|
|
|
|
// binomial returns the number of successful trials out of n when the
|
|
// probability of success for each trial is p.
|
|
pub fn binomial(n int, p f64) !int {
|
|
return default_rng.binomial(n, p)
|
|
}
|
|
|
|
// exponential returns an exponentially distributed random number with the rate paremeter
|
|
// lambda. It is expected that lambda is positive.
|
|
pub fn exponential(lambda f64) f64 {
|
|
return default_rng.exponential(lambda)
|
|
}
|