/* * Copyright 2010-2021 JetBrains s.r.o. and Kotlin Programming Language contributors. * Use of this source code is governed by the Apache 2.0 license that can be found in the license/LICENSE.txt file. */ package kotlin.collections // // NOTE: THIS FILE IS AUTO-GENERATED by the GenerateStandardLib.kt // See: https://github.com/JetBrains/kotlin/tree/master/libraries/stdlib // import kotlin.ranges.contains import kotlin.ranges.reversed /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun Array.elementAt(index: Int): T { return get(index) } /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun ByteArray.elementAt(index: Int): Byte { return get(index) } /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun ShortArray.elementAt(index: Int): Short { return get(index) } /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun IntArray.elementAt(index: Int): Int { return get(index) } /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun LongArray.elementAt(index: Int): Long { return get(index) } /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun FloatArray.elementAt(index: Int): Float { return get(index) } /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun DoubleArray.elementAt(index: Int): Double { return get(index) } /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun BooleanArray.elementAt(index: Int): Boolean { return get(index) } /** * Returns an element at the given [index] or throws an [IndexOutOfBoundsException] if the [index] is out of bounds of this array. * * @sample samples.collections.Collections.Elements.elementAt */ @kotlin.internal.InlineOnly public actual inline fun CharArray.elementAt(index: Int): Char { return get(index) } /** * Returns a [List] that wraps the original array. */ public actual fun Array.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: T): Boolean = this@asList.contains(element) override fun get(index: Int): T = this@asList[index] override fun indexOf(element: T): Int = this@asList.indexOf(element) override fun lastIndexOf(element: T): Int = this@asList.lastIndexOf(element) } } /** * Returns a [List] that wraps the original array. */ public actual fun ByteArray.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: Byte): Boolean = this@asList.contains(element) override fun get(index: Int): Byte = this@asList[index] override fun indexOf(element: Byte): Int = this@asList.indexOf(element) override fun lastIndexOf(element: Byte): Int = this@asList.lastIndexOf(element) } } /** * Returns a [List] that wraps the original array. */ public actual fun ShortArray.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: Short): Boolean = this@asList.contains(element) override fun get(index: Int): Short = this@asList[index] override fun indexOf(element: Short): Int = this@asList.indexOf(element) override fun lastIndexOf(element: Short): Int = this@asList.lastIndexOf(element) } } /** * Returns a [List] that wraps the original array. */ public actual fun IntArray.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: Int): Boolean = this@asList.contains(element) override fun get(index: Int): Int = this@asList[index] override fun indexOf(element: Int): Int = this@asList.indexOf(element) override fun lastIndexOf(element: Int): Int = this@asList.lastIndexOf(element) } } /** * Returns a [List] that wraps the original array. */ public actual fun LongArray.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: Long): Boolean = this@asList.contains(element) override fun get(index: Int): Long = this@asList[index] override fun indexOf(element: Long): Int = this@asList.indexOf(element) override fun lastIndexOf(element: Long): Int = this@asList.lastIndexOf(element) } } /** * Returns a [List] that wraps the original array. */ public actual fun FloatArray.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: Float): Boolean = this@asList.any { it.toBits() == element.toBits() } override fun get(index: Int): Float = this@asList[index] override fun indexOf(element: Float): Int = this@asList.indexOfFirst { it.toBits() == element.toBits() } override fun lastIndexOf(element: Float): Int = this@asList.indexOfLast { it.toBits() == element.toBits() } } } /** * Returns a [List] that wraps the original array. */ public actual fun DoubleArray.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: Double): Boolean = this@asList.any { it.toBits() == element.toBits() } override fun get(index: Int): Double = this@asList[index] override fun indexOf(element: Double): Int = this@asList.indexOfFirst { it.toBits() == element.toBits() } override fun lastIndexOf(element: Double): Int = this@asList.indexOfLast { it.toBits() == element.toBits() } } } /** * Returns a [List] that wraps the original array. */ public actual fun BooleanArray.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: Boolean): Boolean = this@asList.contains(element) override fun get(index: Int): Boolean = this@asList[index] override fun indexOf(element: Boolean): Int = this@asList.indexOf(element) override fun lastIndexOf(element: Boolean): Int = this@asList.lastIndexOf(element) } } /** * Returns a [List] that wraps the original array. */ public actual fun CharArray.asList(): List { return object : AbstractList(), RandomAccess { override val size: Int get() = this@asList.size override fun isEmpty(): Boolean = this@asList.isEmpty() override fun contains(element: Char): Boolean = this@asList.contains(element) override fun get(index: Int): Char = this@asList[index] override fun indexOf(element: Char): Int = this@asList.indexOf(element) override fun lastIndexOf(element: Char): Int = this@asList.lastIndexOf(element) } } /** * Returns `true` if the two specified arrays are *deeply* equal to one another, * i.e. contain the same number of the same elements in the same order. * * If two corresponding elements are nested arrays, they are also compared deeply. * If any of arrays contains itself on any nesting level the behavior is undefined. * * The elements of other types are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.1") @kotlin.internal.LowPriorityInOverloadResolution public actual infix fun Array.contentDeepEquals(other: Array): Boolean { return this.contentDeepEquals(other) } /** * Returns `true` if the two specified arrays are *deeply* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The specified arrays are also considered deeply equal if both are `null`. * * If two corresponding elements are nested arrays, they are also compared deeply. * If any of arrays contains itself on any nesting level the behavior is undefined. * * The elements of other types are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun Array?.contentDeepEquals(other: Array?): Boolean { return contentDeepEqualsImpl(other) } /** * Returns a hash code based on the contents of this array as if it is [List]. * Nested arrays are treated as lists too. * * If any of arrays contains itself on any nesting level the behavior is undefined. */ @SinceKotlin("1.1") @kotlin.internal.LowPriorityInOverloadResolution public actual fun Array.contentDeepHashCode(): Int { return this.contentDeepHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. * Nested arrays are treated as lists too. * * If any of arrays contains itself on any nesting level the behavior is undefined. */ @SinceKotlin("1.4") public actual fun Array?.contentDeepHashCode(): Int { return contentDeepHashCodeImpl() } /** * Returns a string representation of the contents of this array as if it is a [List]. * Nested arrays are treated as lists too. * * If any of arrays contains itself on any nesting level that reference * is rendered as `"[...]"` to prevent recursion. * * @sample samples.collections.Arrays.ContentOperations.contentDeepToString */ @SinceKotlin("1.1") @kotlin.internal.LowPriorityInOverloadResolution public actual fun Array.contentDeepToString(): String { return this.contentDeepToString() } /** * Returns a string representation of the contents of this array as if it is a [List]. * Nested arrays are treated as lists too. * * If any of arrays contains itself on any nesting level that reference * is rendered as `"[...]"` to prevent recursion. * * @sample samples.collections.Arrays.ContentOperations.contentDeepToString */ @SinceKotlin("1.4") public actual fun Array?.contentDeepToString(): String { return contentDeepToStringImpl() } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun Array.contentEquals(other: Array): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun ByteArray.contentEquals(other: ByteArray): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun ShortArray.contentEquals(other: ShortArray): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun IntArray.contentEquals(other: IntArray): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun LongArray.contentEquals(other: LongArray): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun FloatArray.contentEquals(other: FloatArray): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun DoubleArray.contentEquals(other: DoubleArray): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun BooleanArray.contentEquals(other: BooleanArray): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual infix fun CharArray.contentEquals(other: CharArray): Boolean { return this.contentEquals(other) } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun Array?.contentEquals(other: Array?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (this[i] != other[i]) return false } return true } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun ByteArray?.contentEquals(other: ByteArray?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (this[i] != other[i]) return false } return true } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun ShortArray?.contentEquals(other: ShortArray?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (this[i] != other[i]) return false } return true } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun IntArray?.contentEquals(other: IntArray?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (this[i] != other[i]) return false } return true } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun LongArray?.contentEquals(other: LongArray?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (this[i] != other[i]) return false } return true } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun FloatArray?.contentEquals(other: FloatArray?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (!this[i].equals(other[i])) return false } return true } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun DoubleArray?.contentEquals(other: DoubleArray?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (!this[i].equals(other[i])) return false } return true } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun BooleanArray?.contentEquals(other: BooleanArray?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (this[i] != other[i]) return false } return true } /** * Returns `true` if the two specified arrays are *structurally* equal to one another, * i.e. contain the same number of the same elements in the same order. * * The elements are compared for equality with the [equals][Any.equals] function. * For floating point numbers it means that `NaN` is equal to itself and `-0.0` is not equal to `0.0`. */ @SinceKotlin("1.4") public actual infix fun CharArray?.contentEquals(other: CharArray?): Boolean { if (this === other) return true if (this === null || other === null) return false if (size != other.size) return false for (i in indices) { if (this[i] != other[i]) return false } return true } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun Array.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun ByteArray.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun ShortArray.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun IntArray.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun LongArray.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun FloatArray.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun DoubleArray.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun BooleanArray.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun CharArray.contentHashCode(): Int { return this.contentHashCode() } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun Array?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun ByteArray?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun ShortArray?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun IntArray?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun LongArray?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun FloatArray?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun DoubleArray?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun BooleanArray?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a hash code based on the contents of this array as if it is [List]. */ @SinceKotlin("1.4") public actual fun CharArray?.contentHashCode(): Int { if (this === null) return 0 var result = 1 for (element in this) result = 31 * result + element.hashCode() return result } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun Array.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun ByteArray.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun ShortArray.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun IntArray.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun LongArray.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun FloatArray.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun DoubleArray.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun BooleanArray.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @Deprecated("Use Kotlin compiler 1.4 to avoid deprecation warning.") @SinceKotlin("1.1") @DeprecatedSinceKotlin(hiddenSince = "1.4") public actual fun CharArray.contentToString(): String { return this.contentToString() } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun Array?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun ByteArray?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun ShortArray?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun IntArray?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun LongArray?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun FloatArray?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun DoubleArray?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun BooleanArray?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Returns a string representation of the contents of the specified array as if it is [List]. * * @sample samples.collections.Arrays.ContentOperations.contentToString */ @SinceKotlin("1.4") public actual fun CharArray?.contentToString(): String { return this?.joinToString(", ", "[", "]") ?: "null" } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun Array.copyInto(destination: Array, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): Array { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun ByteArray.copyInto(destination: ByteArray, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): ByteArray { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun ShortArray.copyInto(destination: ShortArray, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): ShortArray { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun IntArray.copyInto(destination: IntArray, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): IntArray { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun LongArray.copyInto(destination: LongArray, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): LongArray { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun FloatArray.copyInto(destination: FloatArray, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): FloatArray { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun DoubleArray.copyInto(destination: DoubleArray, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): DoubleArray { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun BooleanArray.copyInto(destination: BooleanArray, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): BooleanArray { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Copies this array or its subrange into the [destination] array and returns that array. * * It's allowed to pass the same array in the [destination] and even specify the subrange so that it overlaps with the destination range. * * @param destination the array to copy to. * @param destinationOffset the position in the [destination] array to copy to, 0 by default. * @param startIndex the beginning (inclusive) of the subrange to copy, 0 by default. * @param endIndex the end (exclusive) of the subrange to copy, size of this array by default. * * @throws IndexOutOfBoundsException or [IllegalArgumentException] when [startIndex] or [endIndex] is out of range of this array indices or when `startIndex > endIndex`. * @throws IndexOutOfBoundsException when the subrange doesn't fit into the [destination] array starting at the specified [destinationOffset], * or when that index is out of the [destination] array indices range. * * @return the [destination] array. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun CharArray.copyInto(destination: CharArray, destinationOffset: Int = 0, startIndex: Int = 0, endIndex: Int = size): CharArray { AbstractList.checkRangeIndexes(startIndex, endIndex, this.size) val rangeSize = endIndex - startIndex AbstractList.checkRangeIndexes(destinationOffset, destinationOffset + rangeSize, destination.size) if (this !== destination || destinationOffset <= startIndex) { for (index in 0 until rangeSize) { destination[destinationOffset + index] = this[startIndex + index] } } else { for (index in rangeSize - 1 downTo 0) { destination[destinationOffset + index] = this[startIndex + index] } } return destination } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun Array.copyOf(): Array { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun ByteArray.copyOf(): ByteArray { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun ShortArray.copyOf(): ShortArray { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun IntArray.copyOf(): IntArray { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun LongArray.copyOf(): LongArray { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun FloatArray.copyOf(): FloatArray { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun DoubleArray.copyOf(): DoubleArray { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun BooleanArray.copyOf(): BooleanArray { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array. * * @sample samples.collections.Arrays.CopyOfOperations.copyOf */ public actual fun CharArray.copyOf(): CharArray { return this.copyOfUninitializedElements(size) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with zero values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with zero values. * * @sample samples.collections.Arrays.CopyOfOperations.resizedPrimitiveCopyOf */ public actual fun ByteArray.copyOf(newSize: Int): ByteArray { return this.copyOfUninitializedElements(newSize) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with zero values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with zero values. * * @sample samples.collections.Arrays.CopyOfOperations.resizedPrimitiveCopyOf */ public actual fun ShortArray.copyOf(newSize: Int): ShortArray { return this.copyOfUninitializedElements(newSize) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with zero values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with zero values. * * @sample samples.collections.Arrays.CopyOfOperations.resizedPrimitiveCopyOf */ public actual fun IntArray.copyOf(newSize: Int): IntArray { return this.copyOfUninitializedElements(newSize) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with zero values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with zero values. * * @sample samples.collections.Arrays.CopyOfOperations.resizedPrimitiveCopyOf */ public actual fun LongArray.copyOf(newSize: Int): LongArray { return this.copyOfUninitializedElements(newSize) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with zero values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with zero values. * * @sample samples.collections.Arrays.CopyOfOperations.resizedPrimitiveCopyOf */ public actual fun FloatArray.copyOf(newSize: Int): FloatArray { return this.copyOfUninitializedElements(newSize) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with zero values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with zero values. * * @sample samples.collections.Arrays.CopyOfOperations.resizedPrimitiveCopyOf */ public actual fun DoubleArray.copyOf(newSize: Int): DoubleArray { return this.copyOfUninitializedElements(newSize) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with `false` values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with `false` values. * * @sample samples.collections.Arrays.CopyOfOperations.resizedPrimitiveCopyOf */ public actual fun BooleanArray.copyOf(newSize: Int): BooleanArray { return this.copyOfUninitializedElements(newSize) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with null char (`\u0000`) values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with null char (`\u0000`) values. * * @sample samples.collections.Arrays.CopyOfOperations.resizedPrimitiveCopyOf */ public actual fun CharArray.copyOf(newSize: Int): CharArray { return this.copyOfUninitializedElements(newSize) } /** * Returns new array which is a copy of the original array, resized to the given [newSize]. * The copy is either truncated or padded at the end with `null` values if necessary. * * - If [newSize] is less than the size of the original array, the copy array is truncated to the [newSize]. * - If [newSize] is greater than the size of the original array, the extra elements in the copy array are filled with `null` values. * * @sample samples.collections.Arrays.CopyOfOperations.resizingCopyOf */ public actual fun Array.copyOf(newSize: Int): Array { TODO("Wasm stdlib: copyOf(newSize: Int)") } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun Array.copyOfRange(fromIndex: Int, toIndex: Int): Array { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun ByteArray.copyOfRange(fromIndex: Int, toIndex: Int): ByteArray { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun ShortArray.copyOfRange(fromIndex: Int, toIndex: Int): ShortArray { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun IntArray.copyOfRange(fromIndex: Int, toIndex: Int): IntArray { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun LongArray.copyOfRange(fromIndex: Int, toIndex: Int): LongArray { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun FloatArray.copyOfRange(fromIndex: Int, toIndex: Int): FloatArray { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun DoubleArray.copyOfRange(fromIndex: Int, toIndex: Int): DoubleArray { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun BooleanArray.copyOfRange(fromIndex: Int, toIndex: Int): BooleanArray { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns a new array which is a copy of the specified range of the original array. * * @param fromIndex the start of the range (inclusive) to copy. * @param toIndex the end of the range (exclusive) to copy. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ public actual fun CharArray.copyOfRange(fromIndex: Int, toIndex: Int): CharArray { checkCopyOfRangeArguments(fromIndex, toIndex, size) return copyOfUninitializedElements(fromIndex, toIndex) } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun Array.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): Array { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = arrayOfUninitializedElements(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun ByteArray.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): ByteArray { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = ByteArray(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun ShortArray.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): ShortArray { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = ShortArray(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun IntArray.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): IntArray { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = IntArray(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun LongArray.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): LongArray { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = LongArray(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun FloatArray.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): FloatArray { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = FloatArray(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun DoubleArray.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): DoubleArray { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = DoubleArray(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun BooleanArray.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): BooleanArray { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = BooleanArray(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array's range between [fromIndex] (inclusive) * and [toIndex] (exclusive) with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun CharArray.copyOfUninitializedElements(fromIndex: Int, toIndex: Int): CharArray { val newSize = toIndex - fromIndex if (newSize < 0) { throw IllegalArgumentException("$fromIndex > $toIndex") } val result = CharArray(newSize) this.copyInto(result, 0, fromIndex, toIndex.coerceAtMost(size)) return result } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun Array.copyOfUninitializedElements(newSize: Int): Array { return copyOfUninitializedElements(0, newSize) } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun ByteArray.copyOfUninitializedElements(newSize: Int): ByteArray { return copyOfUninitializedElements(0, newSize) } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun ShortArray.copyOfUninitializedElements(newSize: Int): ShortArray { return copyOfUninitializedElements(0, newSize) } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun IntArray.copyOfUninitializedElements(newSize: Int): IntArray { return copyOfUninitializedElements(0, newSize) } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun LongArray.copyOfUninitializedElements(newSize: Int): LongArray { return copyOfUninitializedElements(0, newSize) } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun FloatArray.copyOfUninitializedElements(newSize: Int): FloatArray { return copyOfUninitializedElements(0, newSize) } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun DoubleArray.copyOfUninitializedElements(newSize: Int): DoubleArray { return copyOfUninitializedElements(0, newSize) } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun BooleanArray.copyOfUninitializedElements(newSize: Int): BooleanArray { return copyOfUninitializedElements(0, newSize) } /** * Returns new array which is a copy of the original array with new elements filled with **lateinit** _uninitialized_ values. * Attempts to read _uninitialized_ values from this array work in implementation-dependent manner, * either throwing exception or returning some kind of implementation-specific default value. */ internal fun CharArray.copyOfUninitializedElements(newSize: Int): CharArray { return copyOfUninitializedElements(0, newSize) } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun Array.fill(element: T, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun ByteArray.fill(element: Byte, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun ShortArray.fill(element: Short, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun IntArray.fill(element: Int, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun LongArray.fill(element: Long, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun FloatArray.fill(element: Float, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun DoubleArray.fill(element: Double, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun BooleanArray.fill(element: Boolean, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Fills this array or its subrange with the specified [element] value. * * @param fromIndex the start of the range (inclusive) to fill, 0 by default. * @param toIndex the end of the range (exclusive) to fill, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @SinceKotlin("1.3") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun CharArray.fill(element: Char, fromIndex: Int = 0, toIndex: Int = size): Unit { for (index in fromIndex..toIndex) { this[index] = element } } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun Array.plus(element: T): Array { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun ByteArray.plus(element: Byte): ByteArray { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun ShortArray.plus(element: Short): ShortArray { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun IntArray.plus(element: Int): IntArray { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun LongArray.plus(element: Long): LongArray { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun FloatArray.plus(element: Float): FloatArray { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun DoubleArray.plus(element: Double): DoubleArray { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun BooleanArray.plus(element: Boolean): BooleanArray { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ public actual operator fun CharArray.plus(element: Char): CharArray { val index = size val result = copyOfUninitializedElements(index + 1) result[index] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun Array.plus(elements: Collection): Array { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun ByteArray.plus(elements: Collection): ByteArray { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun ShortArray.plus(elements: Collection): ShortArray { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun IntArray.plus(elements: Collection): IntArray { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun LongArray.plus(elements: Collection): LongArray { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun FloatArray.plus(elements: Collection): FloatArray { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun DoubleArray.plus(elements: Collection): DoubleArray { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun BooleanArray.plus(elements: Collection): BooleanArray { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] collection. */ public actual operator fun CharArray.plus(elements: Collection): CharArray { var index = size val result = copyOfUninitializedElements(index + elements.size) for (element in elements) result[index++] = element return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun Array.plus(elements: Array): Array { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun ByteArray.plus(elements: ByteArray): ByteArray { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun ShortArray.plus(elements: ShortArray): ShortArray { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun IntArray.plus(elements: IntArray): IntArray { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun LongArray.plus(elements: LongArray): LongArray { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun FloatArray.plus(elements: FloatArray): FloatArray { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun DoubleArray.plus(elements: DoubleArray): DoubleArray { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun BooleanArray.plus(elements: BooleanArray): BooleanArray { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then all elements of the given [elements] array. */ public actual operator fun CharArray.plus(elements: CharArray): CharArray { val thisSize = size val arraySize = elements.size val result = copyOfUninitializedElements(thisSize + arraySize) elements.copyInto(result, thisSize) return result } /** * Returns an array containing all elements of the original array and then the given [element]. */ @kotlin.internal.InlineOnly public actual inline fun Array.plusElement(element: T): Array { return plus(element) } /** * Sorts the array in-place. * * @sample samples.collections.Arrays.Sorting.sortArray */ public actual fun IntArray.sort(): Unit { TODO("Wasm stdlib: sort()") } /** * Sorts the array in-place. * * @sample samples.collections.Arrays.Sorting.sortArray */ public actual fun LongArray.sort(): Unit { TODO("Wasm stdlib: sort()") } /** * Sorts the array in-place. * * @sample samples.collections.Arrays.Sorting.sortArray */ public actual fun ByteArray.sort(): Unit { TODO("Wasm stdlib: sort()") } /** * Sorts the array in-place. * * @sample samples.collections.Arrays.Sorting.sortArray */ public actual fun ShortArray.sort(): Unit { TODO("Wasm stdlib: sort()") } /** * Sorts the array in-place. * * @sample samples.collections.Arrays.Sorting.sortArray */ public actual fun DoubleArray.sort(): Unit { TODO("Wasm stdlib: sort()") } /** * Sorts the array in-place. * * @sample samples.collections.Arrays.Sorting.sortArray */ public actual fun FloatArray.sort(): Unit { TODO("Wasm stdlib: sort()") } /** * Sorts the array in-place. * * @sample samples.collections.Arrays.Sorting.sortArray */ public actual fun CharArray.sort(): Unit { TODO("Wasm stdlib: sort()") } /** * Sorts the array in-place according to the natural order of its elements. * * The sort is _stable_. It means that equal elements preserve their order relative to each other after sorting. * * @sample samples.collections.Arrays.Sorting.sortArrayOfComparable */ public actual fun > Array.sort(): Unit { TODO("Wasm stdlib: sort()") } /** * Sorts a range in the array in-place. * * The sort is _stable_. It means that equal elements preserve their order relative to each other after sorting. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. * * @sample samples.collections.Arrays.Sorting.sortRangeOfArrayOfComparable */ @SinceKotlin("1.4") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun > Array.sort(fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sort(fromIndex: Int = 0, toIndex: Int = size)") } /** * Sorts a range in the array in-place. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. * * @sample samples.collections.Arrays.Sorting.sortRangeOfArray */ @SinceKotlin("1.4") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun ByteArray.sort(fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sort(fromIndex: Int = 0, toIndex: Int = size)") } /** * Sorts a range in the array in-place. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. * * @sample samples.collections.Arrays.Sorting.sortRangeOfArray */ @SinceKotlin("1.4") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun ShortArray.sort(fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sort(fromIndex: Int = 0, toIndex: Int = size)") } /** * Sorts a range in the array in-place. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. * * @sample samples.collections.Arrays.Sorting.sortRangeOfArray */ @SinceKotlin("1.4") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun IntArray.sort(fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sort(fromIndex: Int = 0, toIndex: Int = size)") } /** * Sorts a range in the array in-place. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. * * @sample samples.collections.Arrays.Sorting.sortRangeOfArray */ @SinceKotlin("1.4") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun LongArray.sort(fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sort(fromIndex: Int = 0, toIndex: Int = size)") } /** * Sorts a range in the array in-place. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. * * @sample samples.collections.Arrays.Sorting.sortRangeOfArray */ @SinceKotlin("1.4") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun FloatArray.sort(fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sort(fromIndex: Int = 0, toIndex: Int = size)") } /** * Sorts a range in the array in-place. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. * * @sample samples.collections.Arrays.Sorting.sortRangeOfArray */ @SinceKotlin("1.4") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun DoubleArray.sort(fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sort(fromIndex: Int = 0, toIndex: Int = size)") } /** * Sorts a range in the array in-place. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. * * @sample samples.collections.Arrays.Sorting.sortRangeOfArray */ @SinceKotlin("1.4") @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun CharArray.sort(fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sort(fromIndex: Int = 0, toIndex: Int = size)") } /** * Sorts the array in-place according to the order specified by the given [comparator]. * * The sort is _stable_. It means that equal elements preserve their order relative to each other after sorting. */ public actual fun Array.sortWith(comparator: Comparator): Unit { if (size > 1) sortArrayWith(this, 0, size, comparator) } /** * Sorts a range in the array in-place with the given [comparator]. * * The sort is _stable_. It means that equal elements preserve their order relative to each other after sorting. * * @param fromIndex the start of the range (inclusive) to sort, 0 by default. * @param toIndex the end of the range (exclusive) to sort, size of this array by default. * * @throws IndexOutOfBoundsException if [fromIndex] is less than zero or [toIndex] is greater than the size of this array. * @throws IllegalArgumentException if [fromIndex] is greater than [toIndex]. */ @Suppress("ACTUAL_FUNCTION_WITH_DEFAULT_ARGUMENTS") public actual fun Array.sortWith(comparator: Comparator, fromIndex: Int = 0, toIndex: Int = size): Unit { TODO("Wasm stdlib: sortWith(comparator: Comparator, fromIndex: Int = 0, toIndex: Int = size)") } /** * Returns a *typed* object array containing all of the elements of this primitive array. */ public actual fun ByteArray.toTypedArray(): Array { return Array(size) { index -> this[index] } } /** * Returns a *typed* object array containing all of the elements of this primitive array. */ public actual fun ShortArray.toTypedArray(): Array { return Array(size) { index -> this[index] } } /** * Returns a *typed* object array containing all of the elements of this primitive array. */ public actual fun IntArray.toTypedArray(): Array { return Array(size) { index -> this[index] } } /** * Returns a *typed* object array containing all of the elements of this primitive array. */ public actual fun LongArray.toTypedArray(): Array { return Array(size) { index -> this[index] } } /** * Returns a *typed* object array containing all of the elements of this primitive array. */ public actual fun FloatArray.toTypedArray(): Array { return Array(size) { index -> this[index] } } /** * Returns a *typed* object array containing all of the elements of this primitive array. */ public actual fun DoubleArray.toTypedArray(): Array { return Array(size) { index -> this[index] } } /** * Returns a *typed* object array containing all of the elements of this primitive array. */ public actual fun BooleanArray.toTypedArray(): Array { return Array(size) { index -> this[index] } } /** * Returns a *typed* object array containing all of the elements of this primitive array. */ public actual fun CharArray.toTypedArray(): Array { return Array(size) { index -> this[index] } }