Dev #11

Merged
altavir merged 7 commits from dev into master 2018-08-03 09:33:11 +03:00
14 changed files with 428 additions and 50 deletions

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@ -1,2 +1,31 @@
# kmath # KMath
Kotlin mathematics extensions library Kotlin MATHematics library is intended as a kotlin based analog of numpy python library. Contrary to `numpy`
and `scipy` it is modular and has a lightweight core.
## Features
* **Algebra**
* Mathematical operation entities like rings, spaces and fields with (**TODO** add example to wiki)
* Basic linear algebra operations (summs products, etc) backed by `Space` API.
* [In progress] advanced linear algebra operations like matrix inversions.
* **Array-like structures** Full support of numpy-like ndarray including mixed ariphmetic operations and function operations
on arrays and numbers just like it works in python (with benefit of static type checking).
## Multi-platform support
KMath is developed as a multi-platform library, which means that most of interfaces are declared in common module.
Implementation is also done in common module wherever it is possible. In some cases features are delegated to
platform even if they could be done in common module because of platform performance optimization.
## Performance
The calculation performance is one of major goals of KMath in the future, but in some cases it is not possible to achieve
both performance and flexibility. We expect to firstly focus on creating convenient universal API and then work on
increasing performance for specific cases. We expect the worst KMath performance still be better than natural python,
but worse than optimized native/scipy (mostly due to boxing operations on primitive numbers). The best performance
of optimized parts should be better than scipy.
## Releases
The project is currently in pre-release stage. Work builds could be obtained with
[![](https://jitpack.io/v/altavir/kmath.svg)](https://jitpack.io/#altavir/kmath).
## Contributing
The project requires a lot of additional work. Please fill free to contribute in any way and propose new features.

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@ -1,5 +1,5 @@
buildscript { buildscript {
ext.kotlin_version = '1.2.41' ext.kotlin_version = '1.2.60'
repositories { repositories {
mavenCentral() mavenCentral()

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@ -1,5 +1,16 @@
package scientifik.kmath.operations package scientifik.kmath.operations
/**
* The generic mathematics elements which is able to store its context
*/
interface MathElement<T, S>{
/**
* The context this element belongs to
*/
val context: S
}
/** /**
* A general interface representing linear context of some kind. * A general interface representing linear context of some kind.
* The context defines sum operation for its elements and multiplication by real value. * The context defines sum operation for its elements and multiplication by real value.
@ -37,23 +48,20 @@ interface Space<T> {
/** /**
* The element of linear context * The element of linear context
* @param S self type of the element. Needed for static type checking * @param T self type of the element. Needed for static type checking
* @param S the type of space
*/ */
interface SpaceElement<S : SpaceElement<S>> { interface SpaceElement<T, S : Space<T>>: MathElement<T,S> {
/**
* The context this element belongs to
*/
val context: Space<S>
/** /**
* Self value. Needed for static type checking. Needed to avoid type erasure on JVM. * Self value. Needed for static type checking. Needed to avoid type erasure on JVM.
*/ */
val self: S val self: T
operator fun plus(b: S): S = context.add(self, b) operator fun plus(b: T): T = context.add(self, b)
operator fun minus(b: S): S = context.add(self, context.multiply(b, -1.0)) operator fun minus(b: T): T = context.add(self, context.multiply(b, -1.0))
operator fun times(k: Number): S = context.multiply(self, k.toDouble()) operator fun times(k: Number): T = context.multiply(self, k.toDouble())
operator fun div(k: Number): S = context.multiply(self, 1.0 / k.toDouble()) operator fun div(k: Number): T = context.multiply(self, 1.0 / k.toDouble())
} }
/** /**
@ -77,10 +85,10 @@ interface Ring<T> : Space<T> {
/** /**
* Ring element * Ring element
*/ */
interface RingElement<S : RingElement<S>> : SpaceElement<S> { interface RingElement<T, S : Ring<T>> : SpaceElement<T, S> {
override val context: Ring<S> override val context: S
operator fun times(b: S): S = context.multiply(self, b) operator fun times(b: T): T = context.multiply(self, b)
} }
/** /**
@ -96,8 +104,8 @@ interface Field<T> : Ring<T> {
/** /**
* Field element * Field element
*/ */
interface FieldElement<S : FieldElement<S>> : RingElement<S> { interface FieldElement<T, S : Field<T>> : RingElement<T, S> {
override val context: Field<S> override val context: S
operator fun div(b: S): S = context.divide(self, b) operator fun div(b: T): T = context.divide(self, b)
} }

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@ -1,23 +1,39 @@
package scientifik.kmath.operations package scientifik.kmath.operations
import kotlin.math.pow
import kotlin.math.sqrt import kotlin.math.sqrt
/** /**
* Field for real values * Field for real values
*/ */
object RealField : Field<Real> { object RealField : Field<Real>, TrigonometricOperations<Real>, PowerOperations<Real>, ExponentialOperations<Real> {
override val zero: Real = Real(0.0) override val zero: Real = Real(0.0)
override fun add(a: Real, b: Real): Real = Real(a.value + b.value) override fun add(a: Real, b: Real): Real = Real(a.value + b.value)
override val one: Real = Real(1.0) override val one: Real = Real(1.0)
override fun multiply(a: Real, b: Real): Real = Real(a.value * b.value) override fun multiply(a: Real, b: Real): Real = Real(a.value * b.value)
override fun multiply(a: Real, k: Double): Real = Real(a.value * k) override fun multiply(a: Real, k: Double): Real = Real(a.value * k)
override fun divide(a: Real, b: Real): Real = Real(a.value / b.value) override fun divide(a: Real, b: Real): Real = Real(a.value / b.value)
override fun sin(arg: Real): Real = Real(kotlin.math.sin(arg.value))
override fun cos(arg: Real): Real = Real(kotlin.math.cos(arg.value))
override fun power(arg: Real, pow: Double): Real = Real(arg.value.pow(pow))
override fun exp(arg: Real): Real = Real(kotlin.math.exp(arg.value))
override fun ln(arg: Real): Real = Real(kotlin.math.ln(arg.value))
} }
/** /**
* Real field element wrapping double * Real field element wrapping double.
*
* TODO could be replaced by inline class in kotlin 1.3 if it would allow to avoid boxing
*/ */
class Real(val value: Double) : FieldElement<Real>, Number() { class Real(val value: Double) : Number(), FieldElement<Real, RealField> {
/*
* The class uses composition instead of inheritance since Double is final
*/
override fun toByte(): Byte = value.toByte() override fun toByte(): Byte = value.toByte()
override fun toChar(): Char = value.toChar() override fun toChar(): Char = value.toChar()
override fun toDouble(): Double = value override fun toDouble(): Double = value
@ -29,8 +45,10 @@ class Real(val value: Double) : FieldElement<Real>, Number() {
//values are dynamically calculated to save memory //values are dynamically calculated to save memory
override val self override val self
get() = this get() = this
override val context override val context
get() = RealField get() = RealField
} }
/** /**
@ -54,10 +72,9 @@ object ComplexField : Field<Complex> {
/** /**
* Complex number class * Complex number class
*/ */
data class Complex(val re: Double, val im: Double) : FieldElement<Complex> { data class Complex(val re: Double, val im: Double) : FieldElement<Complex, ComplexField> {
override val self: Complex override val self: Complex get() = this
get() = this override val context: ComplexField
override val context: Field<Complex>
get() = ComplexField get() = ComplexField
/** /**
@ -72,15 +89,15 @@ data class Complex(val re: Double, val im: Double) : FieldElement<Complex> {
val module: Double val module: Double
get() = sqrt(square) get() = sqrt(square)
//TODO is it convenient?
operator fun not() = conjugate
} }
/**
* A field for double without boxing. Does not produce appropriate field element
*/
object DoubleField : Field<Double> { object DoubleField : Field<Double> {
override val zero: Double = 0.0 override val zero: Double = 0.0
override fun add(a: Double, b: Double): Double = a + b override fun add(a: Double, b: Double): Double = a + b
override fun multiply(a: Double, b: Double): Double = a * b override fun multiply(a: Double, @Suppress("PARAMETER_NAME_CHANGED_ON_OVERRIDE") b: Double): Double = a * b
override val one: Double = 1.0 override val one: Double = 1.0
override fun divide(a: Double, b: Double): Double = a / b override fun divide(a: Double, b: Double): Double = a / b
} }

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package scientifik.kmath.operations
/* Trigonometric operations */
/**
* A container for trigonometric operations for specific type. Trigonometric operations are limited to fields.
*
* The operations are not exposed to class directly to avoid method bloat but instead are declared in the field.
* It also allows to override behavior for optional operations
*
*/
interface TrigonometricOperations<T>: Field<T> {
fun sin(arg: T): T
fun cos(arg: T): T
fun tg(arg: T): T = sin(arg) / cos(arg)
fun ctg(arg: T): T = cos(arg) / sin(arg)
}
fun <T : FieldElement<T, out TrigonometricOperations<T>>> sin(arg: T): T = arg.context.sin(arg)
fun <T : FieldElement<T, out TrigonometricOperations<T>>> cos(arg: T): T = arg.context.cos(arg)
fun <T : FieldElement<T, out TrigonometricOperations<T>>> tg(arg: T): T = arg.context.tg(arg)
fun <T : FieldElement<T, out TrigonometricOperations<T>>> ctg(arg: T): T = arg.context.ctg(arg)
/* Power and roots */
/**
* A context extension to include power operations like square roots, etc
*/
interface PowerOperations<T> {
fun power(arg: T, pow: Double): T
}
infix fun <T : MathElement<T, out PowerOperations<T>>> T.pow(power: Double): T = context.power(this, power)
fun <T : MathElement<T, out PowerOperations<T>>> sqrt(arg: T): T = arg pow 0.5
fun <T : MathElement<T, out PowerOperations<T>>> sqr(arg: T): T = arg pow 2.0
/* Exponential */
interface ExponentialOperations<T>{
fun exp(arg: T): T
fun ln(arg: T): T
}
fun <T: MathElement<T, out ExponentialOperations<T>>> exp(arg:T): T = arg.context.exp(arg)
fun <T: MathElement<T, out ExponentialOperations<T>>> ln(arg:T): T = arg.context.ln(arg)

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package scientifik.kmath.structures
import scientifik.kmath.operations.DoubleField
import scientifik.kmath.operations.Field
import scientifik.kmath.operations.Space
import scientifik.kmath.operations.SpaceElement
/**
* The space for linear elements. Supports scalar product alongside with standard linear operations.
* @param T type of individual element of the vector or matrix
* @param V the type of vector space element
*/
abstract class LinearSpace<T : Any, V : LinearStructure<out T>>(val rows: Int, val columns: Int, val field: Field<T>) : Space<V> {
/**
* Produce the element of this space
*/
abstract fun produce(initializer: (Int, Int) -> T): V
/**
* Produce new linear space with given dimensions
*/
abstract fun produceSpace(rows: Int, columns: Int): LinearSpace<T, V>
override val zero: V by lazy {
produce { _, _ -> field.zero }
}
override fun add(a: V, b: V): V {
return produce { i, j -> with(field) { a[i, j] + b[i, j] } }
}
override fun multiply(a: V, k: Double): V {
//TODO it is possible to implement scalable linear elements which normed values and adjustable scale to save memory and processing poser
return produce { i, j -> with(field) { a[i, j] * k } }
}
/**
* Dot product
*/
fun multiply(a: V, b: V): V {
if (a.rows != b.columns) {
//TODO replace by specific exception
error("Dimension mismatch in vector dot product")
}
return produceSpace(a.rows, b.columns).produce { i, j ->
(0..a.columns).asSequence().map { k -> field.multiply(a[i, k], b[k, j]) }.reduce { first, second -> field.add(first, second) }
}
}
infix fun V.dot(b: V): V = multiply(this, b)
}
/**
* A matrix-like structure that is not dependent on specific space implementation
*/
interface LinearStructure<T : Any> {
val rows: Int
val columns: Int
operator fun get(i: Int, j: Int): T
fun transpose(): LinearStructure<T> {
return object : LinearStructure<T> {
override val rows: Int = this@LinearStructure.columns
override val columns: Int = this@LinearStructure.rows
override fun get(i: Int, j: Int): T = this@LinearStructure.get(j, i)
}
}
}
interface Vector<T : Any> : LinearStructure<T> {
override val columns: Int
get() = 1
operator fun get(i: Int) = get(i, 0)
}
/**
* DoubleArray-based implementation of vector space
*/
class ArraySpace<T : Any>(rows: Int, columns: Int, field: Field<T>) : LinearSpace<T, LinearStructure<out T>>(rows, columns, field) {
override fun produce(initializer: (Int, Int) -> T): LinearStructure<T> = ArrayMatrix<T>(this, initializer)
override fun produceSpace(rows: Int, columns: Int): LinearSpace<T, LinearStructure<out T>> {
return ArraySpace(rows, columns, field)
}
}
/**
* Member of [ArraySpace] which wraps 2-D array
*/
class ArrayMatrix<T : Any>(override val context: ArraySpace<T>, initializer: (Int, Int) -> T) : LinearStructure<T>, SpaceElement<LinearStructure<out T>, ArraySpace<T>> {
val list: List<List<T>> = (0 until rows).map { i -> (0 until columns).map { j -> initializer(i, j) } }
override val rows: Int get() = context.rows
override val columns: Int get() = context.columns
override fun get(i: Int, j: Int): T {
return list[i][j]
}
override val self: ArrayMatrix<T> get() = this
}
class ArrayVector<T : Any>(override val context: ArraySpace<T>, initializer: (Int) -> T) : Vector<T>, SpaceElement<LinearStructure<out T>, ArraySpace<T>> {
init {
if (context.columns != 1) {
error("Vector must have single column")
}
}
val list: List<T> = (0 until context.rows).map(initializer)
override val rows: Int get() = context.rows
override val columns: Int = 1
override fun get(i: Int, j: Int): T {
return list[i]
}
override val self: ArrayVector<T> get() = this
}
fun <T : Any> vector(size: Int, field: Field<T>, initializer: (Int) -> T) = ArrayVector(ArraySpace(size, 1, field), initializer)
//TODO replace by primitive array version
fun realVector(size: Int, initializer: (Int) -> Double) = vector(size, DoubleField, initializer)
fun <T : Any> Array<T>.asVector(field: Field<T>) = vector(size, field) { this[it] }
//TODO add inferred field from field element
fun DoubleArray.asVector() = realVector(this.size) { this[it] }
fun <T : Any> matrix(rows: Int, columns: Int, field: Field<T>, initializer: (Int, Int) -> T) = ArrayMatrix<T>(ArraySpace(rows, columns, field), initializer)
fun realMatrix(rows: Int, columns: Int, initializer: (Int, Int) -> Double) = matrix(rows, columns, DoubleField, initializer)

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@ -3,22 +3,32 @@ package scientifik.kmath.structures
import scientifik.kmath.operations.Field import scientifik.kmath.operations.Field
import scientifik.kmath.operations.FieldElement import scientifik.kmath.operations.FieldElement
/**
* An exception is thrown when the expected ans actual shape of NDArray differs
*/
class ShapeMismatchException(val expected: List<Int>, val actual: List<Int>) : RuntimeException() class ShapeMismatchException(val expected: List<Int>, val actual: List<Int>) : RuntimeException()
/** /**
* Field for n-dimensional arrays. * Field for n-dimensional arrays.
* @param shape - the list of dimensions of the array * @param shape - the list of dimensions of the array
* @param field - operations field defined on individual array element * @param field - operations field defined on individual array element
* @param T the type of the element contained in NDArray
*/ */
abstract class NDField<T>(val shape: List<Int>, val field: Field<T>) : Field<NDArray<T>> { abstract class NDField<T>(val shape: List<Int>, val field: Field<T>) : Field<NDArray<T>> {
/** /**
* Create new instance of NDArray using field shape and given initializer * Create new instance of NDArray using field shape and given initializer
* The producer takes list of indices as argument and returns contained value
*/ */
abstract fun produce(initializer: (List<Int>) -> T): NDArray<T> abstract fun produce(initializer: (List<Int>) -> T): NDArray<T>
override val zero: NDArray<T> override val zero: NDArray<T> by lazy {
get() = produce { this.field.zero } produce { this.field.zero }
}
/**
* Check the shape of given NDArray and throw exception if it does not coincide with shape of the field
*/
private fun checkShape(vararg arrays: NDArray<T>) { private fun checkShape(vararg arrays: NDArray<T>) {
arrays.forEach { arrays.forEach {
if (shape != it.shape) { if (shape != it.shape) {
@ -40,7 +50,7 @@ abstract class NDField<T>(val shape: List<Int>, val field: Field<T>) : Field<NDA
*/ */
override fun multiply(a: NDArray<T>, k: Double): NDArray<T> { override fun multiply(a: NDArray<T>, k: Double): NDArray<T> {
checkShape(a) checkShape(a)
return produce { with(field) {a[it] * k} } return produce { with(field) { a[it] * k } }
} }
override val one: NDArray<T> override val one: NDArray<T>
@ -51,7 +61,7 @@ abstract class NDField<T>(val shape: List<Int>, val field: Field<T>) : Field<NDA
*/ */
override fun multiply(a: NDArray<T>, b: NDArray<T>): NDArray<T> { override fun multiply(a: NDArray<T>, b: NDArray<T>): NDArray<T> {
checkShape(a) checkShape(a)
return produce { with(field) {a[it] * b[it]} } return produce { with(field) { a[it] * b[it] } }
} }
/** /**
@ -59,18 +69,18 @@ abstract class NDField<T>(val shape: List<Int>, val field: Field<T>) : Field<NDA
*/ */
override fun divide(a: NDArray<T>, b: NDArray<T>): NDArray<T> { override fun divide(a: NDArray<T>, b: NDArray<T>): NDArray<T> {
checkShape(a) checkShape(a)
return produce { with(field) {a[it] / b[it]} } return produce { with(field) { a[it] / b[it] } }
} }
} }
interface NDArray<T> : FieldElement<NDArray<T>>, Iterable<Pair<List<Int>, T>> { interface NDArray<T> : FieldElement<NDArray<T>, NDField<T>> {
/** /**
* The list of dimensions of this NDArray * The list of dimensions of this NDArray
*/ */
val shape: List<Int> val shape: List<Int>
get() = (context as NDField<T>).shape get() = context.shape
/** /**
* The number of dimentsions for this array * The number of dimentsions for this array
@ -87,14 +97,14 @@ interface NDArray<T> : FieldElement<NDArray<T>>, Iterable<Pair<List<Int>, T>> {
return get(*index.toIntArray()) return get(*index.toIntArray())
} }
override operator fun iterator(): Iterator<Pair<List<Int>, T>> { operator fun iterator(): Iterator<Pair<List<Int>, T>> {
return iterateIndexes(shape).map { Pair(it, this[it]) }.iterator() return iterateIndexes(shape).map { Pair(it, this[it]) }.iterator()
} }
/** /**
* Generate new NDArray, using given transformation for each element * Generate new NDArray, using given transformation for each element
*/ */
fun transform(action: (List<Int>, T) -> T): NDArray<T> = (context as NDField<T>).produce { action(it, this[it]) } fun transform(action: (List<Int>, T) -> T): NDArray<T> = context.produce { action(it, this[it]) }
companion object { companion object {
/** /**
@ -115,6 +125,79 @@ interface NDArray<T> : FieldElement<NDArray<T>>, Iterable<Pair<List<Int>, T>> {
} }
} }
/**
* Element by element application of any operation on elements to the whole array. Just like in numpy
*/
operator fun <T> Function1<T, T>.invoke(ndArray: NDArray<T>): NDArray<T> = ndArray.transform { _, value -> this(value) }
/* plus and minus */
/**
* Summation operation for [NDArray] and single element
*/
operator fun <T> NDArray<T>.plus(arg: T): NDArray<T> = transform { _, value ->
with(context.field){
arg + value
}
}
/**
* Reverse sum operation
*/
operator fun <T> T.plus(arg: NDArray<T>): NDArray<T> = arg + this
/**
* Subtraction operation between [NDArray] and single element
*/
operator fun <T> NDArray<T>.minus(arg: T): NDArray<T> = transform { _, value ->
with(context.field){
arg - value
}
}
/**
* Reverse minus operation
*/
operator fun <T> T.minus(arg: NDArray<T>): NDArray<T> = arg.transform { _, value ->
with(arg.context.field){
this@minus - value
}
}
/* prod and div */
/**
* Product operation for [NDArray] and single element
*/
operator fun <T> NDArray<T>.times(arg: T): NDArray<T> = transform { _, value ->
with(context.field){
arg * value
}
}
/**
* Reverse product operation
*/
operator fun <T> T.times(arg: NDArray<T>): NDArray<T> = arg * this
/**
* Division operation between [NDArray] and single element
*/
operator fun <T> NDArray<T>.div(arg: T): NDArray<T> = transform { _, value ->
with(context.field){
arg / value
}
}
/**
* Reverse division operation
*/
operator fun <T> T.div(arg: NDArray<T>): NDArray<T> = arg.transform { _, value ->
with(arg.context.field){
this@div/ value
}
}
/** /**
* Create a platform-specific NDArray of doubles * Create a platform-specific NDArray of doubles
*/ */

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@ -0,0 +1,14 @@
package scientifik.kmath.operations
import kotlin.test.Test
import kotlin.test.assertEquals
class RealFieldTest {
@Test
fun testSqrt() {
val sqrt = with(RealField) {
sqrt(25 * one)
}
assertEquals(5.0, sqrt.toDouble())
}
}

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@ -5,7 +5,7 @@ repositories {
} }
dependencies { dependencies {
expectedBy project(":common") expectedBy project(":kmath-common")
compile "org.jetbrains.kotlin:kotlin-stdlib-jdk8:$kotlin_version" compile "org.jetbrains.kotlin:kotlin-stdlib-jdk8:$kotlin_version"
testCompile "junit:junit:4.12" testCompile "junit:junit:4.12"
testCompile "org.jetbrains.kotlin:kotlin-test-junit:$kotlin_version" testCompile "org.jetbrains.kotlin:kotlin-test-junit:$kotlin_version"

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@ -35,6 +35,7 @@ private class RealNDField(shape: List<Int>) : NDField<Double>(shape, DoubleField
override fun produce(initializer: (List<Int>) -> Double): NDArray<Double> { override fun produce(initializer: (List<Int>) -> Double): NDArray<Double> {
//TODO use sparse arrays for large capacities //TODO use sparse arrays for large capacities
val buffer = DoubleBuffer.allocate(capacity) val buffer = DoubleBuffer.allocate(capacity)
//FIXME there could be performance degradation due to iteration procedure. Replace by straight iteration
NDArray.iterateIndexes(shape).forEach { NDArray.iterateIndexes(shape).forEach {
buffer.put(offset(it), initializer(it)) buffer.put(offset(it), initializer(it))
} }
@ -68,7 +69,7 @@ private class RealNDField(shape: List<Int>) : NDField<Double>(shape, DoubleField
//TODO generate fixed hash code for quick comparison? //TODO generate fixed hash code for quick comparison?
override val self: NDArray<Double> = this override val self: NDArray<Double> get() = this
} }
} }

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@ -0,0 +1,26 @@
package scientifik.kmath.structures
import org.junit.Assert.assertEquals
import org.junit.Test
class ArrayMatrixTest {
@Test
fun testSum() {
val vector1 = realVector(5) { it.toDouble() }
val vector2 = realVector(5) { 5 - it.toDouble() }
val sum = vector1 + vector2
assertEquals(5.0, sum[2, 0], 0.1)
}
@Test
fun testDot() {
val vector1 = realVector(5) { it.toDouble() }
val vector2 = realVector(5) { 5 - it.toDouble() }
val product = with(vector1.context) {
vector1 dot (vector2.transpose())
}
assertEquals(10.0, product[1, 0], 0.1)
}
}

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@ -1,6 +1,7 @@
package scientifik.kmath.structures package scientifik.kmath.structures
import org.junit.Assert.assertEquals import org.junit.Assert.assertEquals
import kotlin.math.pow
import kotlin.test.Test import kotlin.test.Test
class RealNDFieldTest { class RealNDFieldTest {
@ -14,8 +15,8 @@ class RealNDFieldTest {
} }
@Test @Test
fun testProduct(){ fun testProduct() {
val product = array1*array2 val product = array1 * array2
assertEquals(0.0, product[2, 2], 0.1) assertEquals(0.0, product[2, 2], 0.1)
} }
@ -24,11 +25,18 @@ class RealNDFieldTest {
val array = real2DArray(3, 3) { i, j -> (i * 10 + j).toDouble() } val array = real2DArray(3, 3) { i, j -> (i * 10 + j).toDouble() }
for(i in 0..2){ for (i in 0..2) {
for(j in 0..2){ for (j in 0..2) {
val expected= (i * 10 + j).toDouble() val expected = (i * 10 + j).toDouble()
assertEquals("Error at index [$i, $j]", expected, array[i,j], 0.1) assertEquals("Error at index [$i, $j]", expected, array[i, j], 0.1)
} }
} }
} }
@Test
fun testExternalFunction() {
val function: (Double) -> Double = { x -> x.pow(2) + 2 * x + 1 }
val result = function(array1) + 1.0
assertEquals(10.0, result[1,1],0.01)
}
} }

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@ -1,4 +1,4 @@
rootProject.name = 'kmath' rootProject.name = 'kmath'
include 'common' include 'kmath-common'
include 'jvm' include 'kmath-jvm'