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undirected-graph-typed - npm Package Compare versions

Comparing version 1.47.4 to 1.47.5

6

dist/data-structures/hash/hash-map.d.ts

@@ -146,3 +146,3 @@ /**

*/
filter(predicate: (element: [K, V], map: HashMap<K, V>) => boolean): HashMap<K, V>;
filter(predicate: (element: [K, V], index: number, map: HashMap<K, V>) => boolean): HashMap<K, V>;
/**

@@ -155,3 +155,3 @@ * The `map` function takes a callback function and returns a new HashMap with the values transformed

*/
map<NV>(callback: (element: [K, V], map: HashMap<K, V>) => NV): HashMap<K, NV>;
map<NV>(callback: (element: [K, V], index: number, map: HashMap<K, V>) => NV): HashMap<K, NV>;
/**

@@ -169,3 +169,3 @@ * The `reduce` function iterates over the elements of a HashMap and applies a callback function to

*/
reduce<A>(callback: (accumulator: A, element: [K, V], map: HashMap<K, V>) => A, initialValue: A): A;
reduce<A>(callback: (accumulator: A, element: [K, V], index: number, map: HashMap<K, V>) => A, initialValue: A): A;
/**

@@ -172,0 +172,0 @@ * Time Complexity: O(n), where n is the number of elements in the HashMap.

@@ -290,6 +290,8 @@ "use strict";

const filteredMap = new HashMap();
let index = 0;
for (const [key, value] of this) {
if (predicate([key, value], this)) {
if (predicate([key, value], index, this)) {
filteredMap.set(key, value);
}
index++;
}

@@ -307,5 +309,7 @@ return filteredMap;

const mappedMap = new HashMap();
let index = 0;
for (const [key, value] of this) {
const newValue = callback([key, value], this);
const newValue = callback([key, value], index, this);
mappedMap.set(key, newValue);
index++;
}

@@ -328,4 +332,6 @@ return mappedMap;

let accumulator = initialValue;
for (const element of this) {
accumulator = callback(accumulator, element, this);
let index = 0;
for (const entry of this) {
accumulator = callback(accumulator, entry, index, this);
index++;
}

@@ -332,0 +338,0 @@ return accumulator;

@@ -11,7 +11,7 @@ /**

value: V;
next: HashTableNode<K, V> | null;
next: HashTableNode<K, V> | undefined;
constructor(key: K, value: V);
}
import { HashFunction } from '../../types';
export declare class HashTable<K, V> {
export declare class HashTable<K = any, V = any> {
protected static readonly DEFAULT_CAPACITY = 16;

@@ -24,4 +24,4 @@ protected static readonly LOAD_FACTOR = 0.75;

get size(): number;
protected _buckets: Array<HashTableNode<K, V> | null>;
get buckets(): Array<HashTableNode<K, V> | null>;
protected _buckets: Array<HashTableNode<K, V> | undefined>;
get buckets(): Array<HashTableNode<K, V> | undefined>;
protected _hashFn: HashFunction<K>;

@@ -55,2 +55,7 @@ get hashFn(): HashFunction<K>;

delete(key: K): void;
[Symbol.iterator](): Generator<[K, V], void, undefined>;
forEach(callback: (entry: [K, V], index: number, table: HashTable<K, V>) => void): void;
filter(predicate: (entry: [K, V], index: number, table: HashTable<K, V>) => boolean): HashTable<K, V>;
map<T>(callback: (entry: [K, V], index: number, table: HashTable<K, V>) => T): HashTable<K, T>;
reduce<T>(callback: (accumulator: T, entry: [K, V], index: number, table: HashTable<K, V>) => T, initialValue: T): T;
/**

@@ -57,0 +62,0 @@ * The function `_defaultHashFn` calculates the hash value of a given key and returns the remainder when divided by the

@@ -15,3 +15,3 @@ "use strict";

this.value = value;
this.next = null;
this.next = undefined;
}

@@ -25,3 +25,3 @@ }

this._size = 0;
this._buckets = new Array(this._capacity).fill(null);
this._buckets = new Array(this._capacity).fill(undefined);
}

@@ -106,3 +106,3 @@ get capacity() {

let currentNode = this._buckets[index];
let prevNode = null;
let prevNode = undefined;
while (currentNode) {

@@ -117,3 +117,3 @@ if (currentNode.key === key) {

this._size--;
currentNode.next = null; // Release memory
currentNode.next = undefined; // Release memory
return;

@@ -125,2 +125,47 @@ }

}
*[Symbol.iterator]() {
for (const bucket of this._buckets) {
let currentNode = bucket;
while (currentNode) {
yield [currentNode.key, currentNode.value];
currentNode = currentNode.next;
}
}
}
forEach(callback) {
let index = 0;
for (const entry of this) {
callback(entry, index, this);
index++;
}
}
filter(predicate) {
const newTable = new HashTable();
let index = 0;
for (const [key, value] of this) {
if (predicate([key, value], index, this)) {
newTable.set(key, value);
}
index++;
}
return newTable;
}
map(callback) {
const newTable = new HashTable();
let index = 0;
for (const [key, value] of this) {
newTable.set(key, callback([key, value], index, this));
index++;
}
return newTable;
}
reduce(callback, initialValue) {
let accumulator = initialValue;
let index = 0;
for (const entry of this) {
accumulator = callback(accumulator, entry, index, this);
index++;
}
return accumulator;
}
/**

@@ -216,3 +261,3 @@ * The function `_defaultHashFn` calculates the hash value of a given key and returns the remainder when divided by the

const newCapacity = this._capacity * 2;
const newBuckets = new Array(newCapacity).fill(null);
const newBuckets = new Array(newCapacity).fill(undefined);
for (const bucket of this._buckets) {

@@ -219,0 +264,0 @@ let currentNode = bucket;

@@ -150,3 +150,3 @@ /**

*/
dfs(order: DFSOrderPattern): E[];
dfs(order?: DFSOrderPattern): E[];
/**

@@ -199,2 +199,7 @@ * Time Complexity: O(n)

fix(): void;
[Symbol.iterator](): Generator<E, void, unknown>;
forEach(callback: (element: E, index: number, heap: this) => void): void;
filter(predicate: (element: E, index: number, heap: Heap<E>) => boolean): Heap<E>;
map<T>(callback: (element: E, index: number, heap: Heap<E>) => T, comparator: Comparator<T>): Heap<T>;
reduce<T>(callback: (accumulator: T, currentValue: E, currentIndex: number, heap: Heap<E>) => T, initialValue: T): T;
/**

@@ -201,0 +206,0 @@ * Time Complexity: O(log n)

@@ -207,20 +207,21 @@ "use strict";

*/
dfs(order) {
dfs(order = 'pre') {
const result = [];
// Auxiliary recursive function, traverses the binary heap according to the traversal order
const dfsHelper = (index) => {
const _dfs = (index) => {
const left = 2 * index + 1, right = left + 1;
if (index < this.size) {
if (order === 'in') {
dfsHelper(2 * index + 1);
_dfs(left);
result.push(this.elements[index]);
dfsHelper(2 * index + 2);
_dfs(right);
}
else if (order === 'pre') {
result.push(this.elements[index]);
dfsHelper(2 * index + 1);
dfsHelper(2 * index + 2);
_dfs(left);
_dfs(right);
}
else if (order === 'post') {
dfsHelper(2 * index + 1);
dfsHelper(2 * index + 2);
_dfs(left);
_dfs(right);
result.push(this.elements[index]);

@@ -230,3 +231,3 @@ }

};
dfsHelper(0); // Traverse starting from the root node
_dfs(0); // Traverse starting from the root node
return result;

@@ -299,2 +300,43 @@ }

}
*[Symbol.iterator]() {
for (const element of this.elements) {
yield element;
}
}
forEach(callback) {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
}
filter(predicate) {
const filteredHeap = new Heap({ comparator: this.comparator });
let index = 0;
for (const el of this) {
if (predicate(el, index, this)) {
filteredHeap.push(el);
}
index++;
}
return filteredHeap;
}
map(callback, comparator) {
const mappedHeap = new Heap({ comparator: comparator });
let index = 0;
for (const el of this) {
mappedHeap.add(callback(el, index, this));
index++;
}
return mappedHeap;
}
reduce(callback, initialValue) {
let accumulator = initialValue;
let index = 0;
for (const el of this) {
accumulator = callback(accumulator, el, index, this);
index++;
}
return accumulator;
}
/**

@@ -301,0 +343,0 @@ * Time Complexity: O(log n)

@@ -260,2 +260,19 @@ /**

*
* The `insertAfter` function inserts a new node with a given value after an existing node in a doubly linked list.
* @param {E | DoublyLinkedListNode<E>} existingValueOrNode - The existing value or node in the doubly linked list
* after which the new value will be inserted. It can be either the value of the existing node or the existing node
* itself.
* @param {E} newValue - The value that you want to insert into the doubly linked list.
* @returns The method returns a boolean value. It returns true if the insertion is successful, and false if the
* existing value or node is not found in the doubly linked list.
*/
insertAfter(existingValueOrNode: E | DoublyLinkedListNode<E>, newValue: E): boolean;
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `deleteAt` function removes an element at a specified index from a linked list and returns the removed element.

@@ -284,14 +301,2 @@ * @param {number} index - The index parameter represents the position of the element that needs to be deleted in the

/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `toArray` function converts a linked list into an array.
* @returns The `toArray()` method is returning an array of type `E[]`.
*/
toArray(): E[];
/**
* The function checks if a variable has a length greater than zero and returns a boolean value.

@@ -353,2 +358,13 @@ * @returns A boolean value is being returned.

* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `reverse` function reverses the order of the elements in a doubly linked list.
*/
reverse(): void;
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)

@@ -360,18 +376,23 @@ */

*
* The `toArrayBackward` function converts a doubly linked list into an array in reverse order.
* @returns The `toArrayBackward()` function returns an array of type `E[]`.
* The `toArray` function converts a linked list into an array.
* @returns The `toArray()` method is returning an array of type `E[]`.
*/
toArrayBackward(): E[];
toArray(): E[];
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
* Space Complexity: O(n)
*
* The `reverse` function reverses the order of the elements in a doubly linked list.
* The `toReversedArray` function converts a doubly linked list into an array in reverse order.
* @returns The `toReversedArray()` function returns an array of type `E[]`.
*/
reverse(): void;
toReversedArray(): E[];
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
[Symbol.iterator](): Generator<E, void, unknown>;
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.

@@ -389,3 +410,3 @@ * Space Complexity: O(1)

*/
forEach(callback: (value: E, index: number) => void): void;
forEach(callback: (value: E, index: number, list: DoublyLinkedList<E>) => void): void;
/**

@@ -399,10 +420,9 @@ * Time Complexity: O(n), where n is the number of elements in the linked list.

*
* The `map` function takes a callback function and applies it to each element in the DoublyLinkedList, returning a new
* DoublyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original DoublyLinkedList) and returns a value of type U (the type of values that will be stored in the mapped
* DoublyLinkedList).
* @returns The `map` function is returning a new instance of `DoublyLinkedList<U>` that contains the mapped values.
* The `filter` function iterates through a DoublyLinkedList and returns a new DoublyLinkedList containing only the
* elements that satisfy the given callback function.
* @param callback - The `callback` parameter is a function that takes a value of type `E` and returns a boolean value.
* It is used to determine whether a value should be included in the filtered list or not.
* @returns The filtered list, which is an instance of the DoublyLinkedList class.
*/
map<U>(callback: (value: E) => U): DoublyLinkedList<U>;
filter(callback: (value: E, index: number, list: DoublyLinkedList<E>) => boolean): DoublyLinkedList<E>;
/**

@@ -416,9 +436,10 @@ * Time Complexity: O(n), where n is the number of elements in the linked list.

*
* The `filter` function iterates through a DoublyLinkedList and returns a new DoublyLinkedList containing only the
* elements that satisfy the given callback function.
* @param callback - The `callback` parameter is a function that takes a value of type `E` and returns a boolean value.
* It is used to determine whether a value should be included in the filtered list or not.
* @returns The filtered list, which is an instance of the DoublyLinkedList class.
* The `map` function takes a callback function and applies it to each element in the DoublyLinkedList, returning a new
* DoublyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original DoublyLinkedList) and returns a value of type T (the type of values that will be stored in the mapped
* DoublyLinkedList).
* @returns The `map` function is returning a new instance of `DoublyLinkedList<T>` that contains the mapped values.
*/
filter(callback: (value: E) => boolean): DoublyLinkedList<E>;
map<T>(callback: (value: E, index: number, list: DoublyLinkedList<E>) => T): DoublyLinkedList<T>;
/**

@@ -436,3 +457,3 @@ * Time Complexity: O(n), where n is the number of elements in the linked list.

* used to perform a specific operation on each element of the linked list.
* @param {U} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* @param {T} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* point for the reduction operation.

@@ -442,24 +463,3 @@ * @returns The `reduce` method is returning the final value of the accumulator after iterating through all the

*/
reduce<U>(callback: (accumulator: U, value: E) => U, initialValue: U): U;
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `insertAfter` function inserts a new node with a given value after an existing node in a doubly linked list.
* @param {E | DoublyLinkedListNode<E>} existingValueOrNode - The existing value or node in the doubly linked list
* after which the new value will be inserted. It can be either the value of the existing node or the existing node
* itself.
* @param {E} newValue - The value that you want to insert into the doubly linked list.
* @returns The method returns a boolean value. It returns true if the insertion is successful, and false if the
* existing value or node is not found in the doubly linked list.
*/
insertAfter(existingValueOrNode: E | DoublyLinkedListNode<E>, newValue: E): boolean;
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
[Symbol.iterator](): Generator<E, void, unknown>;
reduce<T>(callback: (accumulator: T, value: E, index: number, list: DoublyLinkedList<E>) => T, initialValue: T): T;
}

@@ -414,2 +414,42 @@ "use strict";

*
* The `insertAfter` function inserts a new node with a given value after an existing node in a doubly linked list.
* @param {E | DoublyLinkedListNode<E>} existingValueOrNode - The existing value or node in the doubly linked list
* after which the new value will be inserted. It can be either the value of the existing node or the existing node
* itself.
* @param {E} newValue - The value that you want to insert into the doubly linked list.
* @returns The method returns a boolean value. It returns true if the insertion is successful, and false if the
* existing value or node is not found in the doubly linked list.
*/
insertAfter(existingValueOrNode, newValue) {
let existingNode;
if (existingValueOrNode instanceof DoublyLinkedListNode) {
existingNode = existingValueOrNode;
}
else {
existingNode = this.getNode(existingValueOrNode);
}
if (existingNode) {
const newNode = new DoublyLinkedListNode(newValue);
newNode.next = existingNode.next;
if (existingNode.next) {
existingNode.next.prev = newNode;
}
newNode.prev = existingNode;
existingNode.next = newNode;
if (existingNode === this.tail) {
this._tail = newNode;
}
this._length++;
return true;
}
return false;
}
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `deleteAt` function removes an element at a specified index from a linked list and returns the removed element.

@@ -477,22 +517,2 @@ * @param {number} index - The index parameter represents the position of the element that needs to be deleted in the

/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `toArray` function converts a linked list into an array.
* @returns The `toArray()` method is returning an array of type `E[]`.
*/
toArray() {
const array = [];
let current = this.head;
while (current) {
array.push(current.value);
current = current.next;
}
return array;
}
/**
* The function checks if a variable has a length greater than zero and returns a boolean value.

@@ -589,2 +609,21 @@ * @returns A boolean value is being returned.

* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `reverse` function reverses the order of the elements in a doubly linked list.
*/
reverse() {
let current = this.head;
[this._head, this._tail] = [this.tail, this.head];
while (current) {
const next = current.next;
[current.prev, current.next] = [current.next, current.prev];
current = next;
}
}
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)

@@ -596,11 +635,11 @@ */

*
* The `toArrayBackward` function converts a doubly linked list into an array in reverse order.
* @returns The `toArrayBackward()` function returns an array of type `E[]`.
* The `toArray` function converts a linked list into an array.
* @returns The `toArray()` method is returning an array of type `E[]`.
*/
toArrayBackward() {
toArray() {
const array = [];
let current = this.tail;
let current = this.head;
while (current) {
array.push(current.value);
current = current.prev;
current = current.next;
}

@@ -611,17 +650,28 @@ return array;

* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
* Space Complexity: O(n)
*
* The `reverse` function reverses the order of the elements in a doubly linked list.
* The `toReversedArray` function converts a doubly linked list into an array in reverse order.
* @returns The `toReversedArray()` function returns an array of type `E[]`.
*/
reverse() {
toReversedArray() {
const array = [];
let current = this.tail;
while (current) {
array.push(current.value);
current = current.prev;
}
return array;
}
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
*[Symbol.iterator]() {
let current = this.head;
[this._head, this._tail] = [this.tail, this.head];
while (current) {
const next = current.next;
[current.prev, current.next] = [current.next, current.prev];
current = next;
yield current.value;
current = current.next;
}

@@ -643,7 +693,5 @@ }

forEach(callback) {
let current = this.head;
let index = 0;
while (current) {
callback(current.value, index);
current = current.next;
for (const el of this) {
callback(el, index, this);
index++;

@@ -660,17 +708,18 @@ }

*
* The `map` function takes a callback function and applies it to each element in the DoublyLinkedList, returning a new
* DoublyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original DoublyLinkedList) and returns a value of type U (the type of values that will be stored in the mapped
* DoublyLinkedList).
* @returns The `map` function is returning a new instance of `DoublyLinkedList<U>` that contains the mapped values.
* The `filter` function iterates through a DoublyLinkedList and returns a new DoublyLinkedList containing only the
* elements that satisfy the given callback function.
* @param callback - The `callback` parameter is a function that takes a value of type `E` and returns a boolean value.
* It is used to determine whether a value should be included in the filtered list or not.
* @returns The filtered list, which is an instance of the DoublyLinkedList class.
*/
map(callback) {
const mappedList = new DoublyLinkedList();
let current = this.head;
while (current) {
mappedList.push(callback(current.value));
current = current.next;
filter(callback) {
const filteredList = new DoublyLinkedList();
let index = 0;
for (const current of this) {
if (callback(current, index, this)) {
filteredList.push(current);
}
index++;
}
return mappedList;
return filteredList;
}

@@ -685,18 +734,17 @@ /**

*
* The `filter` function iterates through a DoublyLinkedList and returns a new DoublyLinkedList containing only the
* elements that satisfy the given callback function.
* @param callback - The `callback` parameter is a function that takes a value of type `E` and returns a boolean value.
* It is used to determine whether a value should be included in the filtered list or not.
* @returns The filtered list, which is an instance of the DoublyLinkedList class.
* The `map` function takes a callback function and applies it to each element in the DoublyLinkedList, returning a new
* DoublyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original DoublyLinkedList) and returns a value of type T (the type of values that will be stored in the mapped
* DoublyLinkedList).
* @returns The `map` function is returning a new instance of `DoublyLinkedList<T>` that contains the mapped values.
*/
filter(callback) {
const filteredList = new DoublyLinkedList();
let current = this.head;
while (current) {
if (callback(current.value)) {
filteredList.push(current.value);
}
current = current.next;
map(callback) {
const mappedList = new DoublyLinkedList();
let index = 0;
for (const current of this) {
mappedList.push(callback(current, index, this));
index++;
}
return filteredList;
return mappedList;
}

@@ -715,3 +763,3 @@ /**

* used to perform a specific operation on each element of the linked list.
* @param {U} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* @param {T} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* point for the reduction operation.

@@ -723,60 +771,10 @@ * @returns The `reduce` method is returning the final value of the accumulator after iterating through all the

let accumulator = initialValue;
let current = this.head;
while (current) {
accumulator = callback(accumulator, current.value);
current = current.next;
let index = 0;
for (const current of this) {
accumulator = callback(accumulator, current, index, this);
index++;
}
return accumulator;
}
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `insertAfter` function inserts a new node with a given value after an existing node in a doubly linked list.
* @param {E | DoublyLinkedListNode<E>} existingValueOrNode - The existing value or node in the doubly linked list
* after which the new value will be inserted. It can be either the value of the existing node or the existing node
* itself.
* @param {E} newValue - The value that you want to insert into the doubly linked list.
* @returns The method returns a boolean value. It returns true if the insertion is successful, and false if the
* existing value or node is not found in the doubly linked list.
*/
insertAfter(existingValueOrNode, newValue) {
let existingNode;
if (existingValueOrNode instanceof DoublyLinkedListNode) {
existingNode = existingValueOrNode;
}
else {
existingNode = this.getNode(existingValueOrNode);
}
if (existingNode) {
const newNode = new DoublyLinkedListNode(newValue);
newNode.next = existingNode.next;
if (existingNode.next) {
existingNode.next.prev = newNode;
}
newNode.prev = existingNode;
existingNode.next = newNode;
if (existingNode === this.tail) {
this._tail = newNode;
}
this._length++;
return true;
}
return false;
}
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
*[Symbol.iterator]() {
let current = this.head;
while (current) {
yield current.value;
current = current.next;
}
}
}
exports.DoublyLinkedList = DoublyLinkedList;

@@ -348,8 +348,12 @@ /**

/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as it needs to reverse the pointers of each node.
* Space Complexity: O(1) - Constant space.
* The function returns an iterator that iterates over the values of a linked list.
*/
[Symbol.iterator](): Generator<E, void, unknown>;
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as it needs to reverse the pointers of each node.
* Space Complexity: O(1) - Constant space.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*

@@ -361,27 +365,11 @@ * The `forEach` function iterates over each element in a linked list and applies a callback function to each element.

*/
forEach(callback: (value: E, index: number) => void): void;
forEach(callback: (value: E, index: number, list: SinglyLinkedList<E>) => void): void;
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the SinglyLinkedList, returning a new
* SinglyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original SinglyLinkedList) and returns a value of type U (the type of values that will be stored in the mapped
* SinglyLinkedList).
* @returns The `map` function is returning a new instance of `SinglyLinkedList<U>` that contains the mapped values.
*/
map<U>(callback: (value: E) => U): SinglyLinkedList<U>;
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
*
* The `filter` function iterates through a SinglyLinkedList and returns a new SinglyLinkedList containing only the

@@ -393,11 +381,27 @@ * elements that satisfy the given callback function.

*/
filter(callback: (value: E) => boolean): SinglyLinkedList<E>;
filter(callback: (value: E, index: number, list: SinglyLinkedList<E>) => boolean): SinglyLinkedList<E>;
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the SinglyLinkedList, returning a new
* SinglyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original SinglyLinkedList) and returns a value of type T (the type of values that will be stored in the mapped
* SinglyLinkedList).
* @returns The `map` function is returning a new instance of `SinglyLinkedList<T>` that contains the mapped values.
*/
map<T>(callback: (value: E, index: number, list: SinglyLinkedList<E>) => T): SinglyLinkedList<T>;
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `reduce` function iterates over a linked list and applies a callback function to each element, accumulating a

@@ -407,3 +411,3 @@ * single value.

* used to perform a specific operation on each element of the linked list.
* @param {U} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* @param {T} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* point for the reduction operation.

@@ -413,7 +417,3 @@ * @returns The `reduce` method is returning the final value of the accumulator after iterating through all the

*/
reduce<U>(callback: (accumulator: U, value: E) => U, initialValue: U): U;
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
[Symbol.iterator](): Generator<E, void, unknown>;
reduce<T>(callback: (accumulator: T, value: E, index: number, list: SinglyLinkedList<E>) => T, initialValue: T): T;
}

@@ -608,8 +608,18 @@ "use strict";

/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as it needs to reverse the pointers of each node.
* Space Complexity: O(1) - Constant space.
* The function returns an iterator that iterates over the values of a linked list.
*/
*[Symbol.iterator]() {
let current = this.head;
while (current) {
yield current.value;
current = current.next;
}
}
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as it needs to reverse the pointers of each node.
* Space Complexity: O(1) - Constant space.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*

@@ -622,7 +632,5 @@ * The `forEach` function iterates over each element in a linked list and applies a callback function to each element.

forEach(callback) {
let current = this.head;
let index = 0;
while (current) {
callback(current.value, index);
current = current.next;
for (const el of this) {
callback(el, index, this);
index++;

@@ -632,33 +640,9 @@ }

/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the SinglyLinkedList, returning a new
* SinglyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original SinglyLinkedList) and returns a value of type U (the type of values that will be stored in the mapped
* SinglyLinkedList).
* @returns The `map` function is returning a new instance of `SinglyLinkedList<U>` that contains the mapped values.
*/
map(callback) {
const mappedList = new SinglyLinkedList();
let current = this.head;
while (current) {
mappedList.push(callback(current.value));
current = current.next;
}
return mappedList;
}
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
*
* The `filter` function iterates through a SinglyLinkedList and returns a new SinglyLinkedList containing only the

@@ -672,8 +656,8 @@ * elements that satisfy the given callback function.

const filteredList = new SinglyLinkedList();
let current = this.head;
while (current) {
if (callback(current.value)) {
filteredList.push(current.value);
let index = 0;
for (const current of this) {
if (callback(current, index, this)) {
filteredList.push(current);
}
current = current.next;
index++;
}

@@ -683,9 +667,33 @@ return filteredList;

/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the SinglyLinkedList, returning a new
* SinglyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original SinglyLinkedList) and returns a value of type T (the type of values that will be stored in the mapped
* SinglyLinkedList).
* @returns The `map` function is returning a new instance of `SinglyLinkedList<T>` that contains the mapped values.
*/
map(callback) {
const mappedList = new SinglyLinkedList();
let index = 0;
for (const current of this) {
mappedList.push(callback(current, index, this));
index++;
}
return mappedList;
}
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `reduce` function iterates over a linked list and applies a callback function to each element, accumulating a

@@ -695,3 +703,3 @@ * single value.

* used to perform a specific operation on each element of the linked list.
* @param {U} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* @param {T} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* point for the reduction operation.

@@ -703,20 +711,10 @@ * @returns The `reduce` method is returning the final value of the accumulator after iterating through all the

let accumulator = initialValue;
let current = this.head;
while (current) {
accumulator = callback(accumulator, current.value);
current = current.next;
let index = 0;
for (const current of this) {
accumulator = callback(accumulator, current, index, this);
index++;
}
return accumulator;
}
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
*[Symbol.iterator]() {
let current = this.head;
while (current) {
yield current.value;
current = current.next;
}
}
}
exports.SinglyLinkedList = SinglyLinkedList;

@@ -321,8 +321,10 @@ /**

*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
* The `find` function iterates over the elements in a deque and returns the first element for which
* the callback function returns true, or undefined if no such element is found.
* @param callback - A function that takes three parameters: element, index, and deque. It should
* return a boolean value indicating whether the element satisfies a certain condition.
* @returns The method `find` returns the first element in the deque that satisfies the condition
* specified by the callback function. If no element satisfies the condition, it returns `undefined`.
*/
forEach(callback: (element: E, index: number, deque: Deque<E>) => void): void;
find(callback: (element: E, index: number, deque: Deque<E>) => boolean): E | undefined;
/**

@@ -336,10 +338,10 @@ * Time Complexity: O(n)

*
* The `find` function iterates over the elements in a deque and returns the first element for which
* the callback function returns true, or undefined if no such element is found.
* @param callback - A function that takes three parameters: element, index, and deque. It should
* return a boolean value indicating whether the element satisfies a certain condition.
* @returns The method `find` returns the first element in the deque that satisfies the condition
* specified by the callback function. If no element satisfies the condition, it returns `undefined`.
* The function "indexOf" returns the index of the first occurrence of a given element in an array,
* or -1 if the element is not found.
* @param {E} element - The "element" parameter represents the element that you want to find the
* index of in the data structure.
* @returns The indexOf function returns the index of the first occurrence of the specified element
* in the data structure. If the element is not found, it returns -1.
*/
find(callback: (element: E, index: number, deque: Deque<E>) => boolean): E | undefined;
indexOf(element: E): number;
/**

@@ -359,16 +361,28 @@ * Time Complexity: O(n)

* Time Complexity: O(n)
* Space Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
* Space Complexity: O(1)
*
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Deque` object with the transformed elements.
* The above function is an implementation of the iterator protocol in TypeScript, allowing the
* object to be iterated over using a for...of loop.
*/
map<T>(callback: (element: E, index: number, deque: Deque<E>) => T): Deque<T>;
[Symbol.iterator](): Generator<E, void, unknown>;
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
*/
forEach(callback: (element: E, index: number, deque: this) => void): void;
/**
* Time Complexity: O(n)
* Space Complexity: O(n)

@@ -387,5 +401,19 @@ */

*/
filter(predicate: (element: E, index: number, deque: Deque<E>) => boolean): Deque<E>;
filter(predicate: (element: E, index: number, deque: this) => boolean): Deque<E>;
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Deque` object with the transformed elements.
*/
map<T>(callback: (element: E, index: number, deque: this) => T): Deque<T>;
/**
* Time Complexity: O(n)
* Space Complexity: O(1)

@@ -406,33 +434,5 @@ */

*/
reduce<T>(callback: (accumulator: T, element: E, index: number, deque: Deque<E>) => T, initialValue: T): T;
reduce<T>(callback: (accumulator: T, element: E, index: number, deque: this) => T, initialValue: T): T;
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The function "indexOf" returns the index of the first occurrence of a given element in an array,
* or -1 if the element is not found.
* @param {E} element - The "element" parameter represents the element that you want to find the
* index of in the data structure.
* @returns The indexOf function returns the index of the first occurrence of the specified element
* in the data structure. If the element is not found, it returns -1.
*/
indexOf(element: E): number;
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The above function is an implementation of the iterator protocol in TypeScript, allowing the
* object to be iterated over using a for...of loop.
*/
[Symbol.iterator](): Generator<E, void, unknown>;
/**
* Time Complexity: O(n)
* Space Complexity: O(n)

@@ -439,0 +439,0 @@ */

@@ -597,11 +597,17 @@ "use strict";

*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
* The `find` function iterates over the elements in a deque and returns the first element for which
* the callback function returns true, or undefined if no such element is found.
* @param callback - A function that takes three parameters: element, index, and deque. It should
* return a boolean value indicating whether the element satisfies a certain condition.
* @returns The method `find` returns the first element in the deque that satisfies the condition
* specified by the callback function. If no element satisfies the condition, it returns `undefined`.
*/
forEach(callback) {
find(callback) {
for (let i = 0; i < this.size; ++i) {
callback(this.getAt(i), i, this);
const element = this.getAt(i);
if (callback(element, i, this)) {
return element;
}
}
return undefined;
}

@@ -616,17 +622,16 @@ /**

*
* The `find` function iterates over the elements in a deque and returns the first element for which
* the callback function returns true, or undefined if no such element is found.
* @param callback - A function that takes three parameters: element, index, and deque. It should
* return a boolean value indicating whether the element satisfies a certain condition.
* @returns The method `find` returns the first element in the deque that satisfies the condition
* specified by the callback function. If no element satisfies the condition, it returns `undefined`.
* The function "indexOf" returns the index of the first occurrence of a given element in an array,
* or -1 if the element is not found.
* @param {E} element - The "element" parameter represents the element that you want to find the
* index of in the data structure.
* @returns The indexOf function returns the index of the first occurrence of the specified element
* in the data structure. If the element is not found, it returns -1.
*/
find(callback) {
indexOf(element) {
for (let i = 0; i < this.size; ++i) {
const element = this.getAt(i);
if (callback(element, i, this)) {
return element;
if (this.getAt(i) === element) {
return i;
}
}
return undefined;
return -1;
}

@@ -653,22 +658,38 @@ /**

* Time Complexity: O(n)
* Space Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
* Space Complexity: O(1)
*
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Deque` object with the transformed elements.
* The above function is an implementation of the iterator protocol in TypeScript, allowing the
* object to be iterated over using a for...of loop.
*/
map(callback) {
const newDeque = new Deque([], this._bucketSize);
*[Symbol.iterator]() {
for (let i = 0; i < this.size; ++i) {
newDeque.push(callback(this.getAt(i), i, this));
yield this.getAt(i);
}
return newDeque;
}
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
*/
forEach(callback) {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
}
/**
* Time Complexity: O(n)
* Space Complexity: O(n)

@@ -689,7 +710,8 @@ */

const newDeque = new Deque([], this._bucketSize);
for (let i = 0; i < this.size; ++i) {
const element = this.getAt(i);
if (predicate(element, i, this)) {
newDeque.push(element);
let index = 0;
for (const el of this) {
if (predicate(el, index, this)) {
newDeque.push(el);
}
index++;
}

@@ -700,2 +722,24 @@ return newDeque;

* Time Complexity: O(n)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Deque` object with the transformed elements.
*/
map(callback) {
const newDeque = new Deque([], this._bucketSize);
let index = 0;
for (const el of this) {
newDeque.push(callback(el, index, this));
index++;
}
return newDeque;
}
/**
* Time Complexity: O(n)
* Space Complexity: O(1)

@@ -718,4 +762,6 @@ */

let accumulator = initialValue;
for (let i = 0; i < this.size; ++i) {
accumulator = callback(accumulator, this.getAt(i), i, this);
let index = 0;
for (const el of this) {
accumulator = callback(accumulator, el, index, this);
index++;
}

@@ -726,41 +772,2 @@ return accumulator;

* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The function "indexOf" returns the index of the first occurrence of a given element in an array,
* or -1 if the element is not found.
* @param {E} element - The "element" parameter represents the element that you want to find the
* index of in the data structure.
* @returns The indexOf function returns the index of the first occurrence of the specified element
* in the data structure. If the element is not found, it returns -1.
*/
indexOf(element) {
for (let i = 0; i < this.size; ++i) {
if (this.getAt(i) === element) {
return i;
}
}
return -1;
}
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The above function is an implementation of the iterator protocol in TypeScript, allowing the
* object to be iterated over using a for...of loop.
*/
*[Symbol.iterator]() {
for (let i = 0; i < this.size; ++i) {
yield this.getAt(i);
}
}
/**
* Time Complexity: O(n)
* Space Complexity: O(n)

@@ -767,0 +774,0 @@ */

@@ -209,2 +209,47 @@ /**

[Symbol.iterator](): Generator<E, void, unknown>;
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
*/
forEach(callback: (element: E, index: number, queue: this) => void): void;
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*
* The `filter` function creates a new deque containing only the elements that satisfy the given
* predicate function.
* @param predicate - The `predicate` parameter is a function that takes three arguments: `element`,
* `index`, and `deque`.
* @returns The `filter` method is returning a new `Queue` object that contains only the elements
* that satisfy the given `predicate` function.
*/
filter(predicate: (element: E, index: number, queue: this) => boolean): Queue<E>;
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Queue` object with the transformed elements.
*/
map<T>(callback: (element: E, index: number, queue: this) => T): Queue<T>;
reduce<T>(callback: (accumulator: T, element: E, index: number, queue: this) => T, initialValue: T): T;
}

@@ -273,3 +273,80 @@ "use strict";

}
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
*/
forEach(callback) {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
}
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*
* The `filter` function creates a new deque containing only the elements that satisfy the given
* predicate function.
* @param predicate - The `predicate` parameter is a function that takes three arguments: `element`,
* `index`, and `deque`.
* @returns The `filter` method is returning a new `Queue` object that contains only the elements
* that satisfy the given `predicate` function.
*/
filter(predicate) {
const newDeque = new Queue([]);
let index = 0;
for (const el of this) {
if (predicate(el, index, this)) {
newDeque.push(el);
}
index++;
}
return newDeque;
}
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Queue` object with the transformed elements.
*/
map(callback) {
const newDeque = new Queue([]);
let index = 0;
for (const el of this) {
newDeque.push(callback(el, index, this));
index++;
}
return newDeque;
}
reduce(callback, initialValue) {
let accumulator = initialValue;
let index = 0;
for (const el of this) {
accumulator = callback(accumulator, el, index, this);
index++;
}
return accumulator;
}
}
exports.Queue = Queue;

@@ -21,2 +21,7 @@ /**

/**
* The size() function returns the number of elements in an array.
* @returns The size of the elements array.
*/
get size(): number;
/**
* Time Complexity: O(n), where n is the number of elements in the input array. Similar to the constructor, it requires iterating through each element.

@@ -37,7 +42,2 @@ * Space Complexity: O(n), as it creates a new stack with the elements from the input array.

/**
* The size() function returns the number of elements in an array.
* @returns The size of the elements array.
*/
size(): number;
/**
* Time Complexity: O(1), as it only involves accessing the last element of the array.

@@ -108,2 +108,15 @@ * Space Complexity: O(1), as it does not use any additional space.

clone(): Stack<E>;
/**
* Custom iterator for the Stack class.
* @returns An iterator object.
*/
[Symbol.iterator](): Generator<E, void, unknown>;
/**
* Applies a function to each element of the stack.
* @param {function(E): void} callback - A function to apply to each element.
*/
forEach(callback: (element: E, index: number, stack: this) => void): void;
filter(predicate: (element: E, index: number, stack: this) => boolean): Stack<E>;
map<T>(callback: (element: E, index: number, stack: this) => T): Stack<T>;
reduce<T>(callback: (accumulator: T, element: E, index: number, stack: this) => T, initialValue: T): T;
}

@@ -27,2 +27,9 @@ "use strict";

/**
* The size() function returns the number of elements in an array.
* @returns The size of the elements array.
*/
get size() {
return this.elements.length;
}
/**
* Time Complexity: O(n), where n is the number of elements in the input array. Similar to the constructor, it requires iterating through each element.

@@ -47,9 +54,2 @@ * Space Complexity: O(n), as it creates a new stack with the elements from the input array.

/**
* The size() function returns the number of elements in an array.
* @returns The size of the elements array.
*/
size() {
return this.elements.length;
}
/**
* Time Complexity: O(1), as it only involves accessing the last element of the array.

@@ -137,3 +137,52 @@ * Space Complexity: O(1), as it does not use any additional space.

}
/**
* Custom iterator for the Stack class.
* @returns An iterator object.
*/
*[Symbol.iterator]() {
for (let i = this.elements.length - 1; i >= 0; i--) {
yield this.elements[i];
}
}
/**
* Applies a function to each element of the stack.
* @param {function(E): void} callback - A function to apply to each element.
*/
forEach(callback) {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
}
filter(predicate) {
const newStack = new Stack();
let index = 0;
for (const el of this) {
if (predicate(el, index, this)) {
newStack.push(el);
}
index++;
}
return newStack;
}
map(callback) {
const newStack = new Stack();
let index = 0;
for (const el of this) {
newStack.push(callback(el, index, this));
index++;
}
return newStack;
}
reduce(callback, initialValue) {
let accumulator = initialValue;
let index = 0;
for (const el of this) {
accumulator = callback(accumulator, el, index, this);
index++;
}
return accumulator;
}
}
exports.Stack = Stack;

@@ -143,2 +143,7 @@ /**

getWords(prefix?: string, max?: number, isAllWhenEmptyPrefix?: boolean): string[];
[Symbol.iterator](): IterableIterator<string>;
forEach(callback: (word: string, index: number, trie: this) => void): void;
filter(predicate: (word: string, index: number, trie: this) => boolean): string[];
map(callback: (word: string, index: number, trie: this) => string): Trie;
reduce<T>(callback: (accumulator: T, word: string, index: number, trie: this) => T, initialValue: T): T;
/**

@@ -145,0 +150,0 @@ * Time Complexity: O(M), where M is the length of the input string.

@@ -308,2 +308,49 @@ "use strict";

}
*[Symbol.iterator]() {
function* _dfs(node, path) {
if (node.isEnd) {
yield path;
}
for (const [char, childNode] of node.children) {
yield* _dfs(childNode, path + char);
}
}
yield* _dfs(this.root, '');
}
forEach(callback) {
let index = 0;
for (const word of this) {
callback(word, index, this);
index++;
}
}
filter(predicate) {
const results = [];
let index = 0;
for (const word of this) {
if (predicate(word, index, this)) {
results.push(word);
}
index++;
}
return results;
}
map(callback) {
const newTrie = new Trie();
let index = 0;
for (const word of this) {
newTrie.add(callback(word, index, this));
index++;
}
return newTrie;
}
reduce(callback, initialValue) {
let accumulator = initialValue;
let index = 0;
for (const word of this) {
accumulator = callback(accumulator, word, index, this);
index++;
}
return accumulator;
}
/**

@@ -310,0 +357,0 @@ * Time Complexity: O(M), where M is the length of the input string.

{
"name": "undirected-graph-typed",
"version": "1.47.4",
"version": "1.47.5",
"description": "Undirected Graph. Javascript & Typescript Data Structure.",

@@ -5,0 +5,0 @@ "main": "dist/index.js",

@@ -316,8 +316,10 @@ /**

*/
filter(predicate: (element: [K, V], map: HashMap<K, V>) => boolean): HashMap<K, V> {
filter(predicate: (element: [K, V], index: number, map: HashMap<K, V>) => boolean): HashMap<K, V> {
const filteredMap = new HashMap<K, V>();
let index = 0;
for (const [key, value] of this) {
if (predicate([key, value], this)) {
if (predicate([key, value], index, this)) {
filteredMap.set(key, value);
}
index++;
}

@@ -334,7 +336,9 @@ return filteredMap;

*/
map<NV>(callback: (element: [K, V], map: HashMap<K, V>) => NV): HashMap<K, NV> {
map<NV>(callback: (element: [K, V], index: number, map: HashMap<K, V>) => NV): HashMap<K, NV> {
const mappedMap = new HashMap<K, NV>();
let index = 0;
for (const [key, value] of this) {
const newValue = callback([key, value], this);
const newValue = callback([key, value], index, this);
mappedMap.set(key, newValue);
index++;
}

@@ -356,6 +360,8 @@ return mappedMap;

*/
reduce<A>(callback: (accumulator: A, element: [K, V], map: HashMap<K, V>) => A, initialValue: A): A {
reduce<A>(callback: (accumulator: A, element: [K, V], index: number, map: HashMap<K, V>) => A, initialValue: A): A {
let accumulator = initialValue;
for (const element of this) {
accumulator = callback(accumulator, element, this);
let index = 0;
for (const entry of this) {
accumulator = callback(accumulator, entry, index, this);
index++;
}

@@ -362,0 +368,0 @@ return accumulator;

@@ -12,3 +12,3 @@ /**

value: V;
next: HashTableNode<K, V> | null;
next: HashTableNode<K, V> | undefined;

@@ -18,3 +18,3 @@ constructor(key: K, value: V) {

this.value = value;
this.next = null;
this.next = undefined;
}

@@ -25,3 +25,3 @@ }

export class HashTable<K, V> {
export class HashTable<K = any, V = any> {
protected static readonly DEFAULT_CAPACITY = 16;

@@ -34,3 +34,3 @@ protected static readonly LOAD_FACTOR = 0.75;

this._size = 0;
this._buckets = new Array<HashTableNode<K, V> | null>(this._capacity).fill(null);
this._buckets = new Array<HashTableNode<K, V> | undefined>(this._capacity).fill(undefined);
}

@@ -50,5 +50,5 @@

protected _buckets: Array<HashTableNode<K, V> | null>;
protected _buckets: Array<HashTableNode<K, V> | undefined>;
get buckets(): Array<HashTableNode<K, V> | null> {
get buckets(): Array<HashTableNode<K, V> | undefined> {
return this._buckets;

@@ -133,3 +133,3 @@ }

let currentNode = this._buckets[index];
let prevNode: HashTableNode<K, V> | null = null;
let prevNode: HashTableNode<K, V> | undefined = undefined;

@@ -144,3 +144,3 @@ while (currentNode) {

this._size--;
currentNode.next = null; // Release memory
currentNode.next = undefined; // Release memory
return;

@@ -153,2 +153,52 @@ }

* [Symbol.iterator](): Generator<[K, V], void, undefined> {
for (const bucket of this._buckets) {
let currentNode = bucket;
while (currentNode) {
yield [currentNode.key, currentNode.value];
currentNode = currentNode.next;
}
}
}
forEach(callback: (entry: [K, V], index: number, table: HashTable<K, V>) => void): void {
let index = 0;
for (const entry of this) {
callback(entry, index, this);
index++;
}
}
filter(predicate: (entry: [K, V], index: number, table: HashTable<K, V>) => boolean): HashTable<K, V> {
const newTable = new HashTable<K, V>();
let index = 0;
for (const [key, value] of this) {
if (predicate([key, value], index, this)) {
newTable.set(key, value);
}
index++;
}
return newTable;
}
map<T>(callback: (entry: [K, V], index: number, table: HashTable<K, V>) => T): HashTable<K, T> {
const newTable = new HashTable<K, T>();
let index = 0;
for (const [key, value] of this) {
newTable.set(key, callback([key, value], index, this));
index++;
}
return newTable;
}
reduce<T>(callback: (accumulator: T, entry: [K, V], index: number, table: HashTable<K, V>) => T, initialValue: T): T {
let accumulator = initialValue;
let index = 0;
for (const entry of this) {
accumulator = callback(accumulator, entry, index, this);
index++;
}
return accumulator;
}
/**

@@ -252,3 +302,3 @@ * The function `_defaultHashFn` calculates the hash value of a given key and returns the remainder when divided by the

const newCapacity = this._capacity * 2;
const newBuckets = new Array<HashTableNode<K, V> | null>(newCapacity).fill(null);
const newBuckets = new Array<HashTableNode<K, V> | undefined>(newCapacity).fill(undefined);

@@ -255,0 +305,0 @@ for (const bucket of this._buckets) {

@@ -229,19 +229,20 @@ /**

*/
dfs(order: DFSOrderPattern): E[] {
dfs(order: DFSOrderPattern = 'pre'): E[] {
const result: E[] = [];
// Auxiliary recursive function, traverses the binary heap according to the traversal order
const dfsHelper = (index: number) => {
const _dfs = (index: number) => {
const left = 2 * index + 1, right = left + 1;
if (index < this.size) {
if (order === 'in') {
dfsHelper(2 * index + 1);
_dfs(left);
result.push(this.elements[index]);
dfsHelper(2 * index + 2);
_dfs(right);
} else if (order === 'pre') {
result.push(this.elements[index]);
dfsHelper(2 * index + 1);
dfsHelper(2 * index + 2);
_dfs(left);
_dfs(right);
} else if (order === 'post') {
dfsHelper(2 * index + 1);
dfsHelper(2 * index + 2);
_dfs(left);
_dfs(right);
result.push(this.elements[index]);

@@ -252,3 +253,3 @@ }

dfsHelper(0); // Traverse starting from the root node
_dfs(0); // Traverse starting from the root node

@@ -329,2 +330,52 @@ return result;

* [Symbol.iterator]() {
for (const element of this.elements) {
yield element;
}
}
forEach(callback: (element: E, index: number, heap: this) => void): void {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
}
filter(predicate: (element: E, index: number, heap: Heap<E>) => boolean): Heap<E> {
const filteredHeap: Heap<E> = new Heap<E>({ comparator: this.comparator });
let index = 0;
for (const el of this) {
if (predicate(el, index, this)) {
filteredHeap.push(el);
}
index++;
}
return filteredHeap;
}
map<T>(callback: (element: E, index: number, heap: Heap<E>) => T, comparator: Comparator<T>): Heap<T> {
const mappedHeap: Heap<T> = new Heap<T>({ comparator: comparator });
let index = 0;
for (const el of this) {
mappedHeap.add(callback(el, index, this));
index++;
}
return mappedHeap;
}
reduce<T>(
callback: (accumulator: T, currentValue: E, currentIndex: number, heap: Heap<E>) => T,
initialValue: T
): T {
let accumulator: T = initialValue;
let index = 0;
for (const el of this) {
accumulator = callback(accumulator, el, index, this);
index++;
}
return accumulator;
}
/**

@@ -331,0 +382,0 @@ * Time Complexity: O(log n)

@@ -453,2 +453,46 @@ /**

*
* The `insertAfter` function inserts a new node with a given value after an existing node in a doubly linked list.
* @param {E | DoublyLinkedListNode<E>} existingValueOrNode - The existing value or node in the doubly linked list
* after which the new value will be inserted. It can be either the value of the existing node or the existing node
* itself.
* @param {E} newValue - The value that you want to insert into the doubly linked list.
* @returns The method returns a boolean value. It returns true if the insertion is successful, and false if the
* existing value or node is not found in the doubly linked list.
*/
insertAfter(existingValueOrNode: E | DoublyLinkedListNode<E>, newValue: E): boolean {
let existingNode;
if (existingValueOrNode instanceof DoublyLinkedListNode) {
existingNode = existingValueOrNode;
} else {
existingNode = this.getNode(existingValueOrNode);
}
if (existingNode) {
const newNode = new DoublyLinkedListNode(newValue);
newNode.next = existingNode.next;
if (existingNode.next) {
existingNode.next.prev = newNode;
}
newNode.prev = existingNode;
existingNode.next = newNode;
if (existingNode === this.tail) {
this._tail = newNode;
}
this._length++;
return true;
}
return false;
}
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `deleteAt` function removes an element at a specified index from a linked list and returns the removed element.

@@ -516,24 +560,2 @@ * @param {number} index - The index parameter represents the position of the element that needs to be deleted in the

/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `toArray` function converts a linked list into an array.
* @returns The `toArray()` method is returning an array of type `E[]`.
*/
toArray(): E[] {
const array: E[] = [];
let current = this.head;
while (current) {
array.push(current.value);
current = current.next;
}
return array;
}
/**
* The function checks if a variable has a length greater than zero and returns a boolean value.

@@ -638,2 +660,23 @@ * @returns A boolean value is being returned.

* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `reverse` function reverses the order of the elements in a doubly linked list.
*/
reverse(): void {
let current = this.head;
[this._head, this._tail] = [this.tail, this.head];
while (current) {
const next = current.next;
[current.prev, current.next] = [current.next, current.prev];
current = next;
}
}
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)

@@ -646,11 +689,11 @@ */

*
* The `toArrayBackward` function converts a doubly linked list into an array in reverse order.
* @returns The `toArrayBackward()` function returns an array of type `E[]`.
* The `toArray` function converts a linked list into an array.
* @returns The `toArray()` method is returning an array of type `E[]`.
*/
toArrayBackward(): E[] {
toArray(): E[] {
const array: E[] = [];
let current = this.tail;
let current = this.head;
while (current) {
array.push(current.value);
current = current.prev;
current = current.next;
}

@@ -662,3 +705,3 @@ return array;

* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
* Space Complexity: O(n)
*/

@@ -668,13 +711,26 @@

* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
* Space Complexity: O(n)
*
* The `reverse` function reverses the order of the elements in a doubly linked list.
* The `toReversedArray` function converts a doubly linked list into an array in reverse order.
* @returns The `toReversedArray()` function returns an array of type `E[]`.
*/
reverse(): void {
toReversedArray(): E[] {
const array: E[] = [];
let current = this.tail;
while (current) {
array.push(current.value);
current = current.prev;
}
return array;
}
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
* [Symbol.iterator]() {
let current = this.head;
[this._head, this._tail] = [this.tail, this.head];
while (current) {
const next = current.next;
[current.prev, current.next] = [current.next, current.prev];
current = next;
yield current.value;
current = current.next;
}

@@ -697,8 +753,6 @@ }

*/
forEach(callback: (value: E, index: number) => void): void {
let current = this.head;
forEach(callback: (value: E, index: number, list: DoublyLinkedList<E>) => void): void {
let index = 0;
while (current) {
callback(current.value, index);
current = current.next;
for (const el of this) {
callback(el, index, this);
index++;

@@ -717,17 +771,18 @@ }

*
* The `map` function takes a callback function and applies it to each element in the DoublyLinkedList, returning a new
* DoublyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original DoublyLinkedList) and returns a value of type U (the type of values that will be stored in the mapped
* DoublyLinkedList).
* @returns The `map` function is returning a new instance of `DoublyLinkedList<U>` that contains the mapped values.
* The `filter` function iterates through a DoublyLinkedList and returns a new DoublyLinkedList containing only the
* elements that satisfy the given callback function.
* @param callback - The `callback` parameter is a function that takes a value of type `E` and returns a boolean value.
* It is used to determine whether a value should be included in the filtered list or not.
* @returns The filtered list, which is an instance of the DoublyLinkedList class.
*/
map<U>(callback: (value: E) => U): DoublyLinkedList<U> {
const mappedList = new DoublyLinkedList<U>();
let current = this.head;
while (current) {
mappedList.push(callback(current.value));
current = current.next;
filter(callback: (value: E, index: number, list: DoublyLinkedList<E>) => boolean): DoublyLinkedList<E> {
const filteredList = new DoublyLinkedList<E>();
let index = 0;
for (const current of this) {
if (callback(current, index, this)) {
filteredList.push(current);
}
index++;
}
return mappedList;
return filteredList;
}

@@ -744,18 +799,18 @@

*
* The `filter` function iterates through a DoublyLinkedList and returns a new DoublyLinkedList containing only the
* elements that satisfy the given callback function.
* @param callback - The `callback` parameter is a function that takes a value of type `E` and returns a boolean value.
* It is used to determine whether a value should be included in the filtered list or not.
* @returns The filtered list, which is an instance of the DoublyLinkedList class.
* The `map` function takes a callback function and applies it to each element in the DoublyLinkedList, returning a new
* DoublyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original DoublyLinkedList) and returns a value of type T (the type of values that will be stored in the mapped
* DoublyLinkedList).
* @returns The `map` function is returning a new instance of `DoublyLinkedList<T>` that contains the mapped values.
*/
filter(callback: (value: E) => boolean): DoublyLinkedList<E> {
const filteredList = new DoublyLinkedList<E>();
let current = this.head;
while (current) {
if (callback(current.value)) {
filteredList.push(current.value);
}
current = current.next;
map<T>(callback: (value: E, index: number, list: DoublyLinkedList<E>) => T): DoublyLinkedList<T> {
const mappedList = new DoublyLinkedList<T>();
let index = 0;
for (const current of this) {
mappedList.push(callback(current, index, this));
index++;
}
return filteredList;
return mappedList;
}

@@ -776,3 +831,3 @@

* used to perform a specific operation on each element of the linked list.
* @param {U} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* @param {T} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* point for the reduction operation.

@@ -782,67 +837,12 @@ * @returns The `reduce` method is returning the final value of the accumulator after iterating through all the

*/
reduce<U>(callback: (accumulator: U, value: E) => U, initialValue: U): U {
reduce<T>(callback: (accumulator: T, value: E, index: number, list: DoublyLinkedList<E>) => T, initialValue: T): T {
let accumulator = initialValue;
let current = this.head;
while (current) {
accumulator = callback(accumulator, current.value);
current = current.next;
let index = 0;
for (const current of this) {
accumulator = callback(accumulator, current, index, this);
index++;
}
return accumulator;
}
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `insertAfter` function inserts a new node with a given value after an existing node in a doubly linked list.
* @param {E | DoublyLinkedListNode<E>} existingValueOrNode - The existing value or node in the doubly linked list
* after which the new value will be inserted. It can be either the value of the existing node or the existing node
* itself.
* @param {E} newValue - The value that you want to insert into the doubly linked list.
* @returns The method returns a boolean value. It returns true if the insertion is successful, and false if the
* existing value or node is not found in the doubly linked list.
*/
insertAfter(existingValueOrNode: E | DoublyLinkedListNode<E>, newValue: E): boolean {
let existingNode;
if (existingValueOrNode instanceof DoublyLinkedListNode) {
existingNode = existingValueOrNode;
} else {
existingNode = this.getNode(existingValueOrNode);
}
if (existingNode) {
const newNode = new DoublyLinkedListNode(newValue);
newNode.next = existingNode.next;
if (existingNode.next) {
existingNode.next.prev = newNode;
}
newNode.prev = existingNode;
existingNode.next = newNode;
if (existingNode === this.tail) {
this._tail = newNode;
}
this._length++;
return true;
}
return false;
}
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
* [Symbol.iterator]() {
let current = this.head;
while (current) {
yield current.value;
current = current.next;
}
}
}

@@ -669,22 +669,10 @@ /**

/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as it needs to reverse the pointers of each node.
* Space Complexity: O(1) - Constant space.
* The function returns an iterator that iterates over the values of a linked list.
*/
* [Symbol.iterator]() {
let current = this.head;
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as it needs to reverse the pointers of each node.
* Space Complexity: O(1) - Constant space.
*
* The `forEach` function iterates over each element in a linked list and applies a callback function to each element.
* @param callback - The callback parameter is a function that takes two arguments: value and index. The value argument
* represents the value of the current node in the linked list, and the index argument represents the index of the
* current node in the linked list.
*/
forEach(callback: (value: E, index: number) => void): void {
let current = this.head;
let index = 0;
while (current) {
callback(current.value, index);
yield current.value;
current = current.next;
index++;
}

@@ -694,35 +682,31 @@ }

/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(1)
*
* The `map` function takes a callback function and applies it to each element in the SinglyLinkedList, returning a new
* SinglyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original SinglyLinkedList) and returns a value of type U (the type of values that will be stored in the mapped
* SinglyLinkedList).
* @returns The `map` function is returning a new instance of `SinglyLinkedList<U>` that contains the mapped values.
* The `forEach` function iterates over each element in a linked list and applies a callback function to each element.
* @param callback - The callback parameter is a function that takes two arguments: value and index. The value argument
* represents the value of the current node in the linked list, and the index argument represents the index of the
* current node in the linked list.
*/
map<U>(callback: (value: E) => U): SinglyLinkedList<U> {
const mappedList = new SinglyLinkedList<U>();
let current = this.head;
while (current) {
mappedList.push(callback(current.value));
current = current.next;
forEach(callback: (value: E, index: number, list: SinglyLinkedList<E>) => void): void {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
return mappedList;
}
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*

@@ -735,10 +719,10 @@ * The `filter` function iterates through a SinglyLinkedList and returns a new SinglyLinkedList containing only the

*/
filter(callback: (value: E) => boolean): SinglyLinkedList<E> {
filter(callback: (value: E, index: number, list: SinglyLinkedList<E>) => boolean): SinglyLinkedList<E> {
const filteredList = new SinglyLinkedList<E>();
let current = this.head;
while (current) {
if (callback(current.value)) {
filteredList.push(current.value);
let index = 0;
for (const current of this) {
if (callback(current, index, this)) {
filteredList.push(current);
}
current = current.next;
index++;
}

@@ -749,10 +733,37 @@ return filteredList;

/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n) - Linear time, where n is the length of the list, as they need to traverse the entire list to apply the callback or reduce the list.
* Space Complexity: O(n) - Linear space, as they create new nodes or arrays.
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the SinglyLinkedList, returning a new
* SinglyLinkedList with the transformed values.
* @param callback - The callback parameter is a function that takes a value of type E (the type of values stored in
* the original SinglyLinkedList) and returns a value of type T (the type of values that will be stored in the mapped
* SinglyLinkedList).
* @returns The `map` function is returning a new instance of `SinglyLinkedList<T>` that contains the mapped values.
*/
map<T>(callback: (value: E, index: number, list: SinglyLinkedList<E>) => T): SinglyLinkedList<T> {
const mappedList = new SinglyLinkedList<T>();
let index = 0;
for (const current of this) {
mappedList.push(callback(current, index, this));
index++;
}
return mappedList;
}
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n), where n is the number of elements in the linked list.
* Space Complexity: O(n)
*
* The `reduce` function iterates over a linked list and applies a callback function to each element, accumulating a

@@ -762,3 +773,3 @@ * single value.

* used to perform a specific operation on each element of the linked list.
* @param {U} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* @param {T} initialValue - The `initialValue` parameter is the initial value of the accumulator. It is the starting
* point for the reduction operation.

@@ -768,23 +779,12 @@ * @returns The `reduce` method is returning the final value of the accumulator after iterating through all the

*/
reduce<U>(callback: (accumulator: U, value: E) => U, initialValue: U): U {
reduce<T>(callback: (accumulator: T, value: E, index: number, list: SinglyLinkedList<E>) => T, initialValue: T): T {
let accumulator = initialValue;
let current = this.head;
while (current) {
accumulator = callback(accumulator, current.value);
current = current.next;
let index = 0;
for (const current of this) {
accumulator = callback(accumulator, current, index, this);
index++;
}
return accumulator;
}
/**
* The function returns an iterator that iterates over the values of a linked list.
*/
* [Symbol.iterator]() {
let current = this.head;
while (current) {
yield current.value;
current = current.next;
}
}
}

@@ -640,11 +640,17 @@ /**

*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
* The `find` function iterates over the elements in a deque and returns the first element for which
* the callback function returns true, or undefined if no such element is found.
* @param callback - A function that takes three parameters: element, index, and deque. It should
* return a boolean value indicating whether the element satisfies a certain condition.
* @returns The method `find` returns the first element in the deque that satisfies the condition
* specified by the callback function. If no element satisfies the condition, it returns `undefined`.
*/
forEach(callback: (element: E, index: number, deque: Deque<E>) => void) {
find(callback: (element: E, index: number, deque: Deque<E>) => boolean): E | undefined {
for (let i = 0; i < this.size; ++i) {
callback(this.getAt(i), i, this);
const element = this.getAt(i);
if (callback(element, i, this)) {
return element;
}
}
return undefined;
}

@@ -661,17 +667,16 @@

*
* The `find` function iterates over the elements in a deque and returns the first element for which
* the callback function returns true, or undefined if no such element is found.
* @param callback - A function that takes three parameters: element, index, and deque. It should
* return a boolean value indicating whether the element satisfies a certain condition.
* @returns The method `find` returns the first element in the deque that satisfies the condition
* specified by the callback function. If no element satisfies the condition, it returns `undefined`.
* The function "indexOf" returns the index of the first occurrence of a given element in an array,
* or -1 if the element is not found.
* @param {E} element - The "element" parameter represents the element that you want to find the
* index of in the data structure.
* @returns The indexOf function returns the index of the first occurrence of the specified element
* in the data structure. If the element is not found, it returns -1.
*/
find(callback: (element: E, index: number, deque: Deque<E>) => boolean): E | undefined {
indexOf(element: E): number {
for (let i = 0; i < this.size; ++i) {
const element = this.getAt(i);
if (callback(element, i, this)) {
return element;
if (this.getAt(i) === element) {
return i;
}
}
return undefined;
return -1;
}

@@ -701,3 +706,3 @@

* Time Complexity: O(n)
* Space Complexity: O(n)
* Space Complexity: O(1)
*/

@@ -707,15 +712,11 @@

* Time Complexity: O(n)
* Space Complexity: O(n)
* Space Complexity: O(1)
*
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Deque` object with the transformed elements.
* The above function is an implementation of the iterator protocol in TypeScript, allowing the
* object to be iterated over using a for...of loop.
*/
map<T>(callback: (element: E, index: number, deque: Deque<E>) => T): Deque<T> {
const newDeque = new Deque<T>([], this._bucketSize);
* [Symbol.iterator]() {
for (let i = 0; i < this.size; ++i) {
newDeque.push(callback(this.getAt(i), i, this));
yield this.getAt(i);
}
return newDeque;
}

@@ -725,2 +726,24 @@

* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
*/
forEach(callback: (element: E, index: number, deque: this) => void) {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
}
/**
* Time Complexity: O(n)
* Space Complexity: O(n)

@@ -740,9 +763,10 @@ */

*/
filter(predicate: (element: E, index: number, deque: Deque<E>) => boolean): Deque<E> {
filter(predicate: (element: E, index: number, deque: this) => boolean): Deque<E> {
const newDeque = new Deque<E>([], this._bucketSize);
for (let i = 0; i < this.size; ++i) {
const element = this.getAt(i);
if (predicate(element, i, this)) {
newDeque.push(element);
let index = 0;
for (const el of this) {
if (predicate(el, index, this)) {
newDeque.push(el);
}
index++;
}

@@ -754,3 +778,3 @@ return newDeque;

* Time Complexity: O(n)
* Space Complexity: O(1)
* Space Complexity: O(n)
*/

@@ -760,19 +784,17 @@

* Time Complexity: O(n)
* Space Complexity: O(1)
* Space Complexity: O(n)
*
* The `reduce` function iterates over the elements of a deque and applies a callback function to
* each element, accumulating a single value.
* @param callback - The `callback` parameter is a function that takes four arguments:
* @param {T} initialValue - The `initialValue` parameter is the initial value of the accumulator. It
* is the value that will be passed as the first argument to the `callback` function when reducing
* the elements of the deque.
* @returns the final value of the accumulator after iterating over all elements in the deque and
* applying the callback function to each element.
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Deque` object with the transformed elements.
*/
reduce<T>(callback: (accumulator: T, element: E, index: number, deque: Deque<E>) => T, initialValue: T): T {
let accumulator = initialValue;
for (let i = 0; i < this.size; ++i) {
accumulator = callback(accumulator, this.getAt(i), i, this);
map<T>(callback: (element: E, index: number, deque: this) => T): Deque<T> {
const newDeque = new Deque<T>([], this._bucketSize);
let index = 0;
for (const el of this) {
newDeque.push(callback(el, index, this));
index++;
}
return accumulator;
return newDeque;
}

@@ -789,16 +811,19 @@

*
* The function "indexOf" returns the index of the first occurrence of a given element in an array,
* or -1 if the element is not found.
* @param {E} element - The "element" parameter represents the element that you want to find the
* index of in the data structure.
* @returns The indexOf function returns the index of the first occurrence of the specified element
* in the data structure. If the element is not found, it returns -1.
* The `reduce` function iterates over the elements of a deque and applies a callback function to
* each element, accumulating a single value.
* @param callback - The `callback` parameter is a function that takes four arguments:
* @param {T} initialValue - The `initialValue` parameter is the initial value of the accumulator. It
* is the value that will be passed as the first argument to the `callback` function when reducing
* the elements of the deque.
* @returns the final value of the accumulator after iterating over all elements in the deque and
* applying the callback function to each element.
*/
indexOf(element: E): number {
for (let i = 0; i < this.size; ++i) {
if (this.getAt(i) === element) {
return i;
}
reduce<T>(callback: (accumulator: T, element: E, index: number, deque: this) => T, initialValue: T): T {
let accumulator = initialValue;
let index = 0;
for (const el of this) {
accumulator = callback(accumulator, el, index, this);
index++;
}
return -1;
return accumulator;
}

@@ -808,20 +833,2 @@

* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The above function is an implementation of the iterator protocol in TypeScript, allowing the
* object to be iterated over using a for...of loop.
*/
* [Symbol.iterator]() {
for (let i = 0; i < this.size; ++i) {
yield this.getAt(i);
}
}
/**
* Time Complexity: O(n)
* Space Complexity: O(n)

@@ -828,0 +835,0 @@ */

@@ -308,2 +308,86 @@ /**

}
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(1)
*
* The `forEach` function iterates over each element in a deque and applies a callback function to
* each element.
* @param callback - The callback parameter is a function that will be called for each element in the
* deque. It takes three parameters:
*/
forEach(callback: (element: E, index: number, queue: this) => void) {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
}
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*
* The `filter` function creates a new deque containing only the elements that satisfy the given
* predicate function.
* @param predicate - The `predicate` parameter is a function that takes three arguments: `element`,
* `index`, and `deque`.
* @returns The `filter` method is returning a new `Queue` object that contains only the elements
* that satisfy the given `predicate` function.
*/
filter(predicate: (element: E, index: number, queue: this) => boolean): Queue<E> {
const newDeque = new Queue<E>([]);
let index = 0;
for (const el of this) {
if (predicate(el, index, this)) {
newDeque.push(el);
}
index++;
}
return newDeque;
}
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*/
/**
* Time Complexity: O(n)
* Space Complexity: O(n)
*
* The `map` function takes a callback function and applies it to each element in the deque,
* returning a new deque with the results.
* @param callback - The `callback` parameter is a function that takes three arguments:
* @returns The `map` method is returning a new `Queue` object with the transformed elements.
*/
map<T>(callback: (element: E, index: number, queue: this) => T): Queue<T> {
const newDeque = new Queue<T>([]);
let index = 0;
for (const el of this) {
newDeque.push(callback(el, index, this));
index++;
}
return newDeque;
}
reduce<T>(callback: (accumulator: T, element: E, index: number, queue: this) => T, initialValue: T): T {
let accumulator = initialValue;
let index = 0;
for (const el of this) {
accumulator = callback(accumulator, el, index, this);
index++;
}
return accumulator;
}
}

@@ -29,2 +29,10 @@ /**

/**
* The size() function returns the number of elements in an array.
* @returns The size of the elements array.
*/
get size(): number {
return this.elements.length;
}
/**
* Time Complexity: O(n), where n is the number of elements in the input array. Similar to the constructor, it requires iterating through each element.

@@ -51,10 +59,2 @@ * Space Complexity: O(n), as it creates a new stack with the elements from the input array.

/**
* The size() function returns the number of elements in an array.
* @returns The size of the elements array.
*/
size(): number {
return this.elements.length;
}
/**
* Time Complexity: O(1), as it only involves accessing the last element of the array.

@@ -152,2 +152,58 @@ * Space Complexity: O(1), as it does not use any additional space.

}
/**
* Custom iterator for the Stack class.
* @returns An iterator object.
*/
* [Symbol.iterator]() {
for (let i = this.elements.length - 1; i >= 0; i--) {
yield this.elements[i];
}
}
/**
* Applies a function to each element of the stack.
* @param {function(E): void} callback - A function to apply to each element.
*/
forEach(callback: (element: E, index: number, stack: this) => void): void {
let index = 0;
for (const el of this) {
callback(el, index, this);
index++;
}
}
filter(predicate: (element: E, index: number, stack: this) => boolean): Stack<E> {
const newStack = new Stack<E>();
let index = 0;
for (const el of this) {
if (predicate(el, index, this)) {
newStack.push(el);
}
index++;
}
return newStack;
}
map<T>(callback: (element: E, index: number, stack: this) => T): Stack<T> {
const newStack = new Stack<T>();
let index = 0;
for (const el of this) {
newStack.push(callback(el, index, this));
index++;
}
return newStack;
}
reduce<T>(callback: (accumulator: T, element: E, index: number, stack: this) => T, initialValue: T): T {
let accumulator = initialValue;
let index = 0;
for (const el of this) {
accumulator = callback(accumulator, el, index, this);
index++;
}
return accumulator;
}
}

@@ -327,2 +327,55 @@ /**

* [Symbol.iterator](): IterableIterator<string> {
function* _dfs(node: TrieNode, path: string): IterableIterator<string> {
if (node.isEnd) {
yield path;
}
for (const [char, childNode] of node.children) {
yield* _dfs(childNode, path + char);
}
}
yield* _dfs(this.root, '');
}
forEach(callback: (word: string, index: number, trie: this) => void): void {
let index = 0;
for (const word of this) {
callback(word, index, this);
index++;
}
}
filter(predicate: (word: string, index: number, trie: this) => boolean): string[] {
const results: string[] = [];
let index = 0;
for (const word of this) {
if (predicate(word, index, this)) {
results.push(word);
}
index++;
}
return results;
}
map(callback: (word: string, index: number, trie: this) => string): Trie {
const newTrie = new Trie();
let index = 0;
for (const word of this) {
newTrie.add(callback(word, index, this));
index++;
}
return newTrie;
}
reduce<T>(callback: (accumulator: T, word: string, index: number, trie: this) => T, initialValue: T): T {
let accumulator = initialValue;
let index = 0;
for (const word of this) {
accumulator = callback(accumulator, word, index, this);
index++;
}
return accumulator;
}
/**

@@ -329,0 +382,0 @@ * Time Complexity: O(M), where M is the length of the input string.

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