Add 2 more samplers, replace SimpleChain with generator.chain
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package scientifik.kmath.prob.samplers
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import scientifik.kmath.chains.Chain
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import scientifik.kmath.prob.RandomGenerator
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import scientifik.kmath.prob.Sampler
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import scientifik.kmath.prob.chain
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import scientifik.kmath.prob.next
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import kotlin.math.*
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class AhrensDieterMarsagliaTsangGammaSampler private constructor(
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alpha: Double,
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theta: Double
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) : Sampler<Double> {
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private val delegate: BaseGammaSampler =
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if (alpha < 1) AhrensDieterGammaSampler(alpha, theta) else MarsagliaTsangGammaSampler(
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alpha,
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theta
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)
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private abstract class BaseGammaSampler internal constructor(
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protected val alpha: Double,
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protected val theta: Double
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) : Sampler<Double> {
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init {
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require(alpha > 0) { "alpha is not strictly positive: $alpha" }
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require(theta > 0) { "theta is not strictly positive: $theta" }
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}
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override fun toString(): String = "Ahrens-Dieter-Marsaglia-Tsang Gamma deviate"
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}
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private class AhrensDieterGammaSampler internal constructor(alpha: Double, theta: Double) :
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BaseGammaSampler(alpha, theta) {
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private val oneOverAlpha: Double = 1.0 / alpha
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private val bGSOptim: Double = 1.0 + alpha / E
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override fun sample(generator: RandomGenerator): Chain<Double> = generator.chain {
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var x: Double
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// [1]: p. 228, Algorithm GS.
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while (true) {
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// Step 1:
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val u = generator.nextDouble()
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val p = bGSOptim * u
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if (p <= 1) {
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// Step 2:
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x = p.pow(oneOverAlpha)
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val u2 = generator.nextDouble()
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if (u2 > exp(-x)) // Reject.
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continue
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break
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}
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// Step 3:
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x = -ln((bGSOptim - p) * oneOverAlpha)
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val u2: Double = generator.nextDouble()
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if (u2 <= x.pow(alpha - 1.0)) break
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// Reject and continue.
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}
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x * theta
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}
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}
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private class MarsagliaTsangGammaSampler internal constructor(alpha: Double, theta: Double) :
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BaseGammaSampler(alpha, theta) {
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private val dOptim: Double
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private val cOptim: Double
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private val gaussian: NormalizedGaussianSampler
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init {
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gaussian = ZigguratNormalizedGaussianSampler.of()
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dOptim = alpha - ONE_THIRD
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cOptim = ONE_THIRD / sqrt(dOptim)
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}
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override fun sample(generator: RandomGenerator): Chain<Double> = generator.chain {
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var v: Double
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while (true) {
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val x = gaussian.next(generator)
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val oPcTx = 1 + cOptim * x
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v = oPcTx * oPcTx * oPcTx
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if (v <= 0) continue
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val x2 = x * x
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val u = generator.nextDouble()
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// Squeeze.
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if (u < 1 - 0.0331 * x2 * x2) break
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if (ln(u) < 0.5 * x2 + dOptim * (1 - v + ln(v))) break
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}
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theta * dOptim * v
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}
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companion object {
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private const val ONE_THIRD = 1.0 / 3.0
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}
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}
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override fun sample(generator: RandomGenerator): Chain<Double> = delegate.sample(generator)
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override fun toString(): String = delegate.toString()
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companion object {
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fun of(
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alpha: Double,
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theta: Double
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): Sampler<Double> = AhrensDieterMarsagliaTsangGammaSampler(alpha, theta)
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}
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}
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@ -0,0 +1,260 @@
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package scientifik.kmath.prob.samplers
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import scientifik.kmath.chains.Chain
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import scientifik.kmath.prob.RandomGenerator
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import scientifik.kmath.prob.Sampler
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import scientifik.kmath.prob.chain
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import kotlin.jvm.JvmOverloads
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import kotlin.math.ceil
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import kotlin.math.max
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import kotlin.math.min
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open class AliasMethodDiscreteSampler private constructor(
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// Deliberate direct storage of input arrays
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protected val probability: LongArray,
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protected val alias: IntArray
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) : Sampler<Int> {
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private class SmallTableAliasMethodDiscreteSampler internal constructor(
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probability: LongArray,
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alias: IntArray
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) : AliasMethodDiscreteSampler(probability, alias) {
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// Assume the table size is a power of 2 and create the mask
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private val mask: Int = alias.size - 1
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override fun sample(generator: RandomGenerator): Chain<Int> = generator.chain {
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val bits = generator.nextInt()
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// Isolate lower bits
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val j = bits and mask
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// Optimisation for zero-padded input tables
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if (j >= probability.size)
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// No probability must use the alias
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return@chain alias[j]
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// Create a uniform random deviate as a long.
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// This replicates functionality from the o.a.c.rng.core.utils.NumberFactory.makeLong
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val longBits = generator.nextInt().toLong() shl 32 or (bits.toLong() and hex_ffffffff)
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// Choose between the two. Use a 53-bit long for the probability.
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if (longBits ushr 11 < probability[j]) j else alias[j]
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}
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private companion object {
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private const val hex_ffffffff = 4294967295L
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}
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}
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override fun sample(generator: RandomGenerator): Chain<Int> = generator.chain {
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// This implements the algorithm as per Vose (1991):
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// v = uniform() in [0, 1)
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// j = uniform(n) in [0, n)
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// if v < prob[j] then
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// return j
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// else
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// return alias[j]
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val j = generator.nextInt(alias.size)
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// Optimisation for zero-padded input tables
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// No probability must use the alias
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if (j >= probability.size) return@chain alias[j]
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// Note: We could check the probability before computing a deviate.
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// p(j) == 0 => alias[j]
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// p(j) == 1 => j
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// However it is assumed these edge cases are rare:
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//
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// The probability table will be 1 for approximately 1/n samples, i.e. only the
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// last unpaired probability. This is only worth checking for when the table size (n)
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// is small. But in that case the user should zero-pad the table for performance.
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//
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// The probability table will be 0 when an input probability was zero. We
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// will assume this is also rare if modelling a discrete distribution where
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// all samples are possible. The edge case for zero-padded tables is handled above.
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// Choose between the two. Use a 53-bit long for the probability.
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if (generator.nextLong() ushr 11 < probability[j]) j else alias[j]
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}
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override fun toString(): String = "Alias method"
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companion object {
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private const val DEFAULT_ALPHA = 0
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private const val ZERO = 0.0
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private const val ONE_AS_NUMERATOR = 1L shl 53
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private const val CONVERT_TO_NUMERATOR: Double = ONE_AS_NUMERATOR.toDouble()
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private const val MAX_SMALL_POWER_2_SIZE = 1 shl 11
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@JvmOverloads
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fun of(
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probabilities: DoubleArray,
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alpha: Int = DEFAULT_ALPHA
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): Sampler<Int> {
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// The Alias method balances N categories with counts around the mean into N sections,
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// each allocated 'mean' observations.
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//
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// Consider 4 categories with counts 6,3,2,1. The histogram can be balanced into a
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// 2D array as 4 sections with a height of the mean:
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//
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// 6
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// 6
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// 6
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// 63 => 6366 --
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// 632 6326 |-- mean
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// 6321 6321 --
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//
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// section abcd
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//
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// Each section is divided as:
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// a: 6=1/1
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// b: 3=1/1
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// c: 2=2/3; 6=1/3 (6 is the alias)
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// d: 1=1/3; 6=2/3 (6 is the alias)
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//
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// The sample is obtained by randomly selecting a section, then choosing which category
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// from the pair based on a uniform random deviate.
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val sumProb = InternalUtils.validateProbabilities(probabilities)
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// Allow zero-padding
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val n = computeSize(probabilities.size, alpha)
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// Partition into small and large by splitting on the average.
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val mean = sumProb / n
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// The cardinality of smallSize + largeSize = n.
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// So fill the same array from either end.
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val indices = IntArray(n)
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var large = n
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var small = 0
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probabilities.indices.forEach { i ->
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if (probabilities[i] >= mean) indices[--large] = i else indices[small++] = i
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}
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small = fillRemainingIndices(probabilities.size, indices, small)
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// This may be smaller than the input length if the probabilities were already padded.
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val nonZeroIndex = findLastNonZeroIndex(probabilities)
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// The probabilities are modified so use a copy.
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// Note: probabilities are required only up to last nonZeroIndex
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val remainingProbabilities = probabilities.copyOf(nonZeroIndex + 1)
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// Allocate the final tables.
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// Probability table may be truncated (when zero padded).
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// The alias table is full length.
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val probability = LongArray(remainingProbabilities.size)
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val alias = IntArray(n)
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// This loop uses each large in turn to fill the alias table for small probabilities that
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// do not reach the requirement to fill an entire section alone (i.e. p < mean).
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// Since the sum of the small should be less than the sum of the large it should use up
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// all the small first. However floating point round-off can result in
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// misclassification of items as small or large. The Vose algorithm handles this using
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// a while loop conditioned on the size of both sets and a subsequent loop to use
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// unpaired items.
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while (large != n && small != 0) {
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// Index of the small and the large probabilities.
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val j = indices[--small]
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val k = indices[large++]
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// Optimisation for zero-padded input:
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// p(j) = 0 above the last nonZeroIndex
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if (j > nonZeroIndex)
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// The entire amount for the section is taken from the alias.
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remainingProbabilities[k] -= mean
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else {
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val pj = remainingProbabilities[j]
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// Item j is a small probability that is below the mean.
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// Compute the weight of the section for item j: pj / mean.
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// This is scaled by 2^53 and the ceiling function used to round-up
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// the probability to a numerator of a fraction in the range [1,2^53].
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// Ceiling ensures non-zero values.
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probability[j] = ceil(CONVERT_TO_NUMERATOR * (pj / mean)).toLong()
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// The remaining amount for the section is taken from the alias.
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// Effectively: probabilities[k] -= (mean - pj)
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remainingProbabilities[k] += pj - mean
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}
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// If not j then the alias is k
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alias[j] = k
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// Add the remaining probability from large to the appropriate list.
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if (remainingProbabilities[k] >= mean) indices[--large] = k else indices[small++] = k
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}
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// Final loop conditions to consume unpaired items.
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// Note: The large set should never be non-empty but this can occur due to round-off
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// error so consume from both.
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fillTable(probability, alias, indices, 0, small)
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fillTable(probability, alias, indices, large, n)
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// Change the algorithm for small power of 2 sized tables
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return if (isSmallPowerOf2(n))
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SmallTableAliasMethodDiscreteSampler(probability, alias)
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else
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AliasMethodDiscreteSampler(probability, alias)
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}
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private fun fillRemainingIndices(length: Int, indices: IntArray, small: Int): Int {
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var updatedSmall = small
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(length until indices.size).forEach { i -> indices[updatedSmall++] = i }
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return updatedSmall
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}
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private fun findLastNonZeroIndex(probabilities: DoubleArray): Int {
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// No bounds check is performed when decrementing as the array contains at least one
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// value above zero.
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var nonZeroIndex = probabilities.size - 1
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while (probabilities[nonZeroIndex] == ZERO) nonZeroIndex--
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return nonZeroIndex
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}
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private fun computeSize(length: Int, alpha: Int): Int {
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// If No padding
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if (alpha < 0) return length
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// Use the number of leading zeros function to find the next power of 2,
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// i.e. ceil(log2(x))
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var pow2 = 32 - numberOfLeadingZeros(length - 1)
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// Increase by the alpha. Clip this to limit to a positive integer (2^30)
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pow2 = min(30, pow2 + alpha)
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// Use max to handle a length above the highest possible power of 2
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return max(length, 1 shl pow2)
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}
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private fun fillTable(
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probability: LongArray,
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alias: IntArray,
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indices: IntArray,
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start: Int,
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end: Int
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) = (start until end).forEach { i ->
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val index = indices[i]
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probability[index] = ONE_AS_NUMERATOR
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alias[index] = index
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}
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private fun isSmallPowerOf2(n: Int): Boolean = n <= MAX_SMALL_POWER_2_SIZE && n and n - 1 == 0
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private fun numberOfLeadingZeros(i: Int): Int {
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var mutI = i
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if (mutI <= 0) return if (mutI == 0) 32 else 0
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var n = 31
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if (mutI >= 1 shl 16) {
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n -= 16
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mutI = mutI ushr 16
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}
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if (mutI >= 1 shl 8) {
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n -= 8
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mutI = mutI ushr 8
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}
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if (mutI >= 1 shl 4) {
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n -= 4
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mutI = mutI ushr 4
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}
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if (mutI >= 1 shl 2) {
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n -= 2
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mutI = mutI ushr 2
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}
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return n - (mutI ushr 1)
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}
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}
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}
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@ -18,6 +18,22 @@ internal object InternalUtils {
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fun factorial(n: Int): Long = FACTORIALS[n]
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fun factorial(n: Int): Long = FACTORIALS[n]
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fun validateProbabilities(probabilities: DoubleArray?): Double {
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require(!(probabilities == null || probabilities.isEmpty())) { "Probabilities must not be empty." }
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var sumProb = 0.0
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probabilities.forEach { prob ->
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validateProbability(prob)
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sumProb += prob
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}
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require(!(sumProb.isInfinite() || sumProb <= 0)) { "Invalid sum of probabilities: $sumProb" }
|
||||||
|
return sumProb
|
||||||
|
}
|
||||||
|
|
||||||
|
private fun validateProbability(probability: Double): Unit =
|
||||||
|
require(!(probability < 0 || probability.isInfinite() || probability.isNaN())) { "Invalid probability: $probability" }
|
||||||
|
|
||||||
class FactorialLog private constructor(
|
class FactorialLog private constructor(
|
||||||
numValues: Int,
|
numValues: Int,
|
||||||
cache: DoubleArray?
|
cache: DoubleArray?
|
||||||
@ -30,9 +46,11 @@ internal object InternalUtils {
|
|||||||
if (cache != null && cache.size > BEGIN_LOG_FACTORIALS) {
|
if (cache != null && cache.size > BEGIN_LOG_FACTORIALS) {
|
||||||
// Copy available values.
|
// Copy available values.
|
||||||
endCopy = min(cache.size, numValues)
|
endCopy = min(cache.size, numValues)
|
||||||
cache.copyInto(logFactorials,
|
cache.copyInto(
|
||||||
|
logFactorials,
|
||||||
BEGIN_LOG_FACTORIALS,
|
BEGIN_LOG_FACTORIALS,
|
||||||
BEGIN_LOG_FACTORIALS, endCopy)
|
BEGIN_LOG_FACTORIALS, endCopy
|
||||||
|
)
|
||||||
}
|
}
|
||||||
// All values to be computed
|
// All values to be computed
|
||||||
else endCopy = BEGIN_LOG_FACTORIALS
|
else endCopy = BEGIN_LOG_FACTORIALS
|
||||||
@ -50,15 +68,11 @@ internal object InternalUtils {
|
|||||||
if (n < logFactorials.size)
|
if (n < logFactorials.size)
|
||||||
return logFactorials[n]
|
return logFactorials[n]
|
||||||
|
|
||||||
return if (n < FACTORIALS.size) ln(
|
return if (n < FACTORIALS.size) ln(FACTORIALS[n].toDouble()) else InternalGamma.logGamma(n + 1.0)
|
||||||
FACTORIALS[n].toDouble()) else InternalGamma.logGamma(
|
|
||||||
n + 1.0
|
|
||||||
)
|
|
||||||
}
|
}
|
||||||
|
|
||||||
companion object {
|
companion object {
|
||||||
fun create(): FactorialLog =
|
fun create(): FactorialLog = FactorialLog(0, null)
|
||||||
FactorialLog(0, null)
|
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
|
@ -2,9 +2,9 @@ package scientifik.kmath.prob.samplers
|
|||||||
|
|
||||||
import scientifik.kmath.chains.Chain
|
import scientifik.kmath.chains.Chain
|
||||||
import scientifik.kmath.chains.ConstantChain
|
import scientifik.kmath.chains.ConstantChain
|
||||||
import scientifik.kmath.chains.SimpleChain
|
|
||||||
import scientifik.kmath.prob.RandomGenerator
|
import scientifik.kmath.prob.RandomGenerator
|
||||||
import scientifik.kmath.prob.Sampler
|
import scientifik.kmath.prob.Sampler
|
||||||
|
import scientifik.kmath.prob.chain
|
||||||
import scientifik.kmath.prob.next
|
import scientifik.kmath.prob.next
|
||||||
import kotlin.math.*
|
import kotlin.math.*
|
||||||
|
|
||||||
@ -35,7 +35,7 @@ class LargeMeanPoissonSampler private constructor(val mean: Double) : Sampler<In
|
|||||||
else // Not used.
|
else // Not used.
|
||||||
KempSmallMeanPoissonSampler.of(mean - lambda)
|
KempSmallMeanPoissonSampler.of(mean - lambda)
|
||||||
|
|
||||||
override fun sample(generator: RandomGenerator): Chain<Int> = SimpleChain {
|
override fun sample(generator: RandomGenerator): Chain<Int> = generator.chain {
|
||||||
// This will never be null. It may be a no-op delegate that returns zero.
|
// This will never be null. It may be a no-op delegate that returns zero.
|
||||||
val y2 = smallMeanPoissonSampler.next(generator)
|
val y2 = smallMeanPoissonSampler.next(generator)
|
||||||
var x: Double
|
var x: Double
|
||||||
|
@ -1,7 +1,6 @@
|
|||||||
package scientifik.kmath.prob.samplers
|
package scientifik.kmath.prob.samplers
|
||||||
|
|
||||||
import scientifik.kmath.chains.Chain
|
import scientifik.kmath.chains.Chain
|
||||||
import scientifik.kmath.chains.SimpleChain
|
|
||||||
import scientifik.kmath.prob.RandomGenerator
|
import scientifik.kmath.prob.RandomGenerator
|
||||||
import scientifik.kmath.prob.Sampler
|
import scientifik.kmath.prob.Sampler
|
||||||
import scientifik.kmath.prob.chain
|
import scientifik.kmath.prob.chain
|
||||||
|
@ -1,7 +1,6 @@
|
|||||||
package scientifik.kmath.prob.samplers
|
package scientifik.kmath.prob.samplers
|
||||||
|
|
||||||
import scientifik.kmath.chains.Chain
|
import scientifik.kmath.chains.Chain
|
||||||
import scientifik.kmath.chains.SimpleChain
|
|
||||||
import scientifik.kmath.prob.RandomGenerator
|
import scientifik.kmath.prob.RandomGenerator
|
||||||
import scientifik.kmath.prob.Sampler
|
import scientifik.kmath.prob.Sampler
|
||||||
import scientifik.kmath.prob.chain
|
import scientifik.kmath.prob.chain
|
||||||
|
Loading…
Reference in New Issue
Block a user