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authorIndrajith K L2022-12-03 17:00:20 +0530
committerIndrajith K L2022-12-03 17:00:20 +0530
commitf5c4671bfbad96bf346bd7e9a21fc4317b4959df (patch)
tree2764fc62da58f2ba8da7ed341643fc359873142f /v_windows/v/old/vlib/rand/dist
downloadcli-tools-windows-master.tar.gz
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Adds most of the toolsHEADmaster
Diffstat (limited to 'v_windows/v/old/vlib/rand/dist')
-rw-r--r--v_windows/v/old/vlib/rand/dist/README.md10
-rw-r--r--v_windows/v/old/vlib/rand/dist/dist.v85
-rw-r--r--v_windows/v/old/vlib/rand/dist/dist_test.v134
3 files changed, 229 insertions, 0 deletions
diff --git a/v_windows/v/old/vlib/rand/dist/README.md b/v_windows/v/old/vlib/rand/dist/README.md
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+# Non-Uniform Distribution Functions
+
+This module contains functions for sampling from non-uniform distributions.
+
+All implementations of the `rand.PRNG` interface generate numbers from uniform
+distributions. This library exists to allow the generation of pseudorandom numbers
+sampled from non-uniform distributions. Additionally, it allows the user to use any
+PRNG of their choice. This is because the default RNG can be reassigned to a different
+generator. It can either be one of the pre-existing one (which are well-tested and
+recommended) or a custom user-defined one. See `rand.set_rng()`. \ No newline at end of file
diff --git a/v_windows/v/old/vlib/rand/dist/dist.v b/v_windows/v/old/vlib/rand/dist/dist.v
new file mode 100644
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+++ b/v_windows/v/old/vlib/rand/dist/dist.v
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+// Copyright (c) 2019-2021 Alexander Medvednikov. All rights reserved.
+// Use of this source code is governed by an MIT license
+// that can be found in the LICENSE file.
+module dist
+
+import math
+import rand
+
+fn check_probability_range(p f64) {
+ if p < 0 || p > 1 {
+ panic('$p is not a valid probability value.')
+ }
+}
+
+// bernoulli returns true with a probability p. Note that 0 <= p <= 1.
+pub fn bernoulli(p f64) bool {
+ check_probability_range(p)
+ return rand.f64() <= p
+}
+
+// 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 {
+ check_probability_range(p)
+ mut count := 0
+ for _ in 0 .. n {
+ if bernoulli(p) {
+ count++
+ }
+ }
+ return count
+}
+
+// Configuration struct for the `normal_pair` function. The default value for
+// `mu` is 0 and the default value for `sigma` is 1.
+pub struct NormalConfigStruct {
+ mu f64 = 0.0
+ sigma f64 = 1.0
+}
+
+// normal_pair returns a pair of normally distributed random numbers with the mean mu
+// and standard deviation sigma. If not specified, mu is 0 and sigma is 1. Intended usage is
+// `x, y := normal_pair(mu: mean, sigma: stdev)`, or `x, y := normal_pair()`.
+pub fn normal_pair(config NormalConfigStruct) (f64, f64) {
+ if config.sigma <= 0 {
+ panic('The standard deviation has to be positive.')
+ }
+ // This is an implementation of the Marsaglia polar method
+ // See: https://doi.org/10.1137%2F1006063
+ // Also: https://en.wikipedia.org/wiki/Marsaglia_polar_method
+ for {
+ u := rand.f64_in_range(-1, 1)
+ v := rand.f64_in_range(-1, 1)
+
+ s := u * u + v * v
+ if s >= 1 || s == 0 {
+ continue
+ }
+ t := math.sqrt(-2 * math.log(s) / s)
+ x := config.mu + config.sigma * t * u
+ y := config.mu + config.sigma * t * v
+ return x, y
+ }
+ return config.mu, config.mu
+}
+
+// normal returns a normally distributed random number with the mean mu and standard deviation
+// sigma. If not specified, mu is 0 and sigma is 1. Intended usage is
+// `x := normal(mu: mean, sigma: etdev)` or `x := normal()`.
+// **NOTE:** If you are generating a lot of normal variates, use `the normal_pair` function
+// instead. This function discards one of the two variates generated by the `normal_pair` function.
+pub fn normal(config NormalConfigStruct) f64 {
+ x, _ := normal_pair(config)
+ return x
+}
+
+// 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 {
+ if lambda <= 0 {
+ panic('The rate (lambda) must be positive.')
+ }
+ // Use the inverse transform sampling method
+ return -math.log(rand.f64()) / lambda
+}
diff --git a/v_windows/v/old/vlib/rand/dist/dist_test.v b/v_windows/v/old/vlib/rand/dist/dist_test.v
new file mode 100644
index 0000000..a7c565e
--- /dev/null
+++ b/v_windows/v/old/vlib/rand/dist/dist_test.v
@@ -0,0 +1,134 @@
+import math
+import rand
+import rand.dist
+
+const (
+ // The sample size to be used
+ count = 2000
+ // Accepted error is within 5% of the actual values.
+ error = 0.05
+ // The seeds used (for reproducible testing)
+ seeds = [[u32(0xffff24), 0xabcd], [u32(0x141024), 0x42851],
+ [u32(0x1452), 0x90cd],
+ ]
+)
+
+fn test_bernoulli() {
+ ps := [0.0, 0.1, 1.0 / 3.0, 0.5, 0.8, 17.0 / 18.0, 1.0]
+
+ for seed in seeds {
+ rand.seed(seed)
+ for p in ps {
+ mut successes := 0
+ for _ in 0 .. count {
+ if dist.bernoulli(p) {
+ successes++
+ }
+ }
+ assert math.abs(f64(successes) / count - p) < error
+ }
+ }
+}
+
+fn test_binomial() {
+ ns := [100, 200, 1000]
+ ps := [0.0, 0.5, 0.95, 1.0]
+
+ for seed in seeds {
+ rand.seed(seed)
+ for n in ns {
+ for p in ps {
+ np := n * p
+ npq := np * (1 - p)
+
+ mut sum := 0
+ mut var := 0.0
+ for _ in 0 .. count {
+ x := dist.binomial(n, p)
+ sum += x
+ dist := (x - np)
+ var += dist * dist
+ }
+
+ assert math.abs(f64(sum / count) - np) / n < error
+ assert math.abs(f64(var / count) - npq) / n < error
+ }
+ }
+ }
+}
+
+fn test_normal_pair() {
+ mus := [0, 10, 100, -40]
+ sigmas := [1, 2, 40, 5]
+ total := 2 * count
+
+ for seed in seeds {
+ rand.seed(seed)
+ for mu in mus {
+ for sigma in sigmas {
+ mut sum := 0.0
+ mut var := 0.0
+ for _ in 0 .. count {
+ x, y := dist.normal_pair(mu: mu, sigma: sigma)
+ sum += x + y
+ dist_x := x - mu
+ dist_y := y - mu
+ var += dist_x * dist_x
+ var += dist_y * dist_y
+ }
+
+ variance := sigma * sigma
+ assert math.abs(f64(sum / total) - mu) / sigma < 1
+ assert math.abs(f64(var / total) - variance) / variance < 2 * error
+ }
+ }
+ }
+}
+
+fn test_normal() {
+ mus := [0, 10, 100, -40, 20]
+ sigmas := [1, 2, 5]
+
+ for seed in seeds {
+ rand.seed(seed)
+ for mu in mus {
+ for sigma in sigmas {
+ mut sum := 0.0
+ mut var := 0.0
+ for _ in 0 .. count {
+ x := dist.normal(mu: mu, sigma: sigma)
+ sum += x
+ dist := x - mu
+ var += dist * dist
+ }
+
+ variance := sigma * sigma
+ assert math.abs(f64(sum / count) - mu) / sigma < 1
+ assert math.abs(f64(var / count) - variance) / variance < 2 * error
+ }
+ }
+ }
+}
+
+fn test_exponential() {
+ lambdas := [1.0, 10, 1 / 20.0, 1 / 10000.0, 1 / 524.0, 200]
+
+ for seed in seeds {
+ rand.seed(seed)
+ for lambda in lambdas {
+ mu := 1 / lambda
+ variance := mu * mu
+ mut sum := 0.0
+ mut var := 0.0
+ for _ in 0 .. count {
+ x := dist.exponential(lambda)
+ sum += x
+ dist := x - mu
+ var += dist * dist
+ }
+
+ assert math.abs((f64(sum / count) - mu) / mu) < error
+ assert math.abs((f64(var / count) - variance) / variance) < 2 * error
+ }
+ }
+}