mirror of
https://github.moeyy.xyz/https://github.com/trekhleb/javascript-algorithms.git
synced 2024-12-27 15:41:16 +08:00
add chinese overview (#17)
This commit is contained in:
parent
e10ea04926
commit
2364de7061
218
Readme.zh-TW.md
Normal file
218
Readme.zh-TW.md
Normal file
@ -0,0 +1,218 @@
|
||||
# JavaScript 演算法與資料結構
|
||||
|
||||
[![build status](https://travis-ci.org/trekhleb/javascript-algorithms.svg?branch=master)](https://travis-ci.org/trekhleb/javascript-algorithms)
|
||||
[![codecov](https://codecov.io/gh/trekhleb/javascript-algorithms/branch/master/graph/badge.svg)](https://codecov.io/gh/trekhleb/javascript-algorithms)
|
||||
|
||||
這個知識庫包含許多 JavaScript 的資料結構與演算法的基礎範例。
|
||||
每個演算法和資料結構都有其個別的文件,內有相關的解釋以及更多相關的文章或Youtube影片連結。
|
||||
|
||||
_Read this in other languages:_ [简体中文](https://github.com/trekhleb/javascript-algorithms/blob/master/README.zh-CN.md)
|
||||
|
||||
_Read this in other languages:_ [繁體中文](https://github.com/trekhleb/javascript-algorithms/blob/master/README.zh-TW.md)
|
||||
|
||||
## 資料結構
|
||||
|
||||
資料結構是一個電腦用來組織和排序資料的特定方式,透過這樣的方式資料可以有效率地被讀取以及修改。更精確地說,一個資料結構是一個資料值的集合、彼此間的關係,函數或者運作可以應用於資料上。
|
||||
|
||||
* [Linked List 鏈結串列](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/linked-list)
|
||||
* [Queue 貯列](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/queue)
|
||||
* [Stack 堆疊](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/stack)
|
||||
* [Hash Table 雜湊表](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/hash-table)
|
||||
* [Heap 堆](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/heap)
|
||||
* [Priority Queue 優先貯列](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/priority-queue)
|
||||
* [Trie 字典樹](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/trie)
|
||||
* [Tree 樹](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/tree)
|
||||
* [Binary Search Tree 二元搜尋樹](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/tree/binary-search-tree)
|
||||
* [AVL Tree AVL樹](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/tree/avl-tree)
|
||||
* Red-Black Tree
|
||||
* Suffix Tree
|
||||
* Segment Tree or Interval Tree
|
||||
* Binary Indexed Tree or Fenwick Tree
|
||||
* [Graph 圖](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/graph) (both directed and undirected)
|
||||
* [Disjoint Set 互斥集](https://github.com/trekhleb/javascript-algorithms/tree/master/src/data-structures/disjoint-set)
|
||||
|
||||
## 演算法
|
||||
|
||||
演算法是一個如何解決一類問題的非模糊規格。演算法是一個具有精確地定義了一系列運作的規則的集合
|
||||
|
||||
### 演算法議題分類 TODO
|
||||
|
||||
* **數學類**
|
||||
* [Factorial](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/factorial)
|
||||
* [Fibonacci Number](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/fibonacci)
|
||||
* [Primality Test](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/primality-test) (trial division method)
|
||||
* [Euclidean Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/euclidean-algorithm) - calculate the Greatest Common Divisor (GCD)
|
||||
* [Least Common Multiple](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/least-common-multiple) (LCM)
|
||||
* [Integer Partition](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/integer-partition)
|
||||
* **集合**
|
||||
* [Cartesian Product](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/cartesian-product) - product of multiple sets
|
||||
* [Power Set](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/power-set) - all subsets of the set
|
||||
* [Permutations](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/permutations) (with and without repetitions)
|
||||
* [Combinations](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/combinations) (with and without repetitions)
|
||||
* [Fisher–Yates Shuffle](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/fisher-yates) - random permutation of a finite sequence
|
||||
* [Longest Common Subsequence](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/longest-common-subsequnce) (LCS)
|
||||
* [Longest Increasing subsequence](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/longest-increasing-subsequence)
|
||||
* [Shortest Common Supersequence](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/shortest-common-supersequence) (SCS)
|
||||
* [Knapsack Problem](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/knapsack-problem) - "0/1" and "Unbound" ones
|
||||
* [Maximum Subarray](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/maximum-subarray) - "Brute Force" and "Dynamic Programming" (Kadane's) versions
|
||||
* **字串**
|
||||
* [Levenshtein Distance](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/string/levenshtein-distance) - minimum edit distance between two sequences
|
||||
* [Hamming Distance](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/string/hamming-distance) - number of positions at which the symbols are different
|
||||
* [Knuth–Morris–Pratt Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/string/knuth-morris-pratt) - substring search
|
||||
* [Rabin Karp Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/string/rabin-karp) - substring search
|
||||
* [Longest Common Substring](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/string/longest-common-substring)
|
||||
* **搜尋**
|
||||
* [Binary Search](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/search/binary-search)
|
||||
* **排序**
|
||||
* [Bubble Sort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/bubble-sort)
|
||||
* [Selection Sort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/selection-sort)
|
||||
* [Insertion Sort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/insertion-sort)
|
||||
* [Heap Sort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/heap-sort)
|
||||
* [Merge Sort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/merge-sort)
|
||||
* [Quicksort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/quick-sort)
|
||||
* [Shellsort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/shell-sort)
|
||||
* **樹**
|
||||
* [Depth-First Search](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/tree/depth-first-search) (DFS)
|
||||
* [Breadth-First Search](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/tree/breadth-first-search) (BFS)
|
||||
* **圖**
|
||||
* [Depth-First Search](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/depth-first-search) (DFS)
|
||||
* [Breadth-First Search](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/breadth-first-search) (BFS)
|
||||
* [Dijkstra Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/dijkstra) - finding shortest path to all graph vertices
|
||||
* [Bellman-Ford Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/bellman-ford) - finding shortest path to all graph vertices
|
||||
* [Detect Cycle](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/detect-cycle) - for both directed and undirected graphs (DFS and Disjoint Set based versions)
|
||||
* [Prim’s Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/prim) - finding Minimum Spanning Tree (MST) for weighted undirected graph
|
||||
* [Kruskal’s Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/kruskal) - finding Minimum Spanning Tree (MST) for weighted undirected graph
|
||||
* [Topological Sorting](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/topological-sorting) - DFS method
|
||||
* [Articulation Points](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/articulation-points) - Tarjan's algorithm (DFS based)
|
||||
* [Bridges](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/bridges) - DFS based algorithm
|
||||
* [Eulerian Path and Eulerian Circuit](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/eulerian-path) - Fleury's algorithm - Visit every edge exactly once
|
||||
* [Hamiltonian Cycle](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/hamiltonian-cycle) - Visit every vertex exactly once
|
||||
* [Strongly Connected Components](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/strongly-connected-components) - Kosaraju's algorithm
|
||||
* [Travelling Salesman Problem](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/travelling-salesman) - shortest possible route that visits each city and returns to the origin city
|
||||
* **未分類**
|
||||
* [Tower of Hanoi](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/uncategorized/hanoi-tower)
|
||||
* [N-Queens Problem](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/uncategorized/n-queens)
|
||||
* [Knight's Tour](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/uncategorized/knight-tour)
|
||||
|
||||
### Algorithms by Paradigm
|
||||
|
||||
An algorithmic paradigm is a generic method or approach which underlies the design of a class
|
||||
of algorithms. It is an abstraction higher than the notion of an algorithm, just as an
|
||||
algorithm is an abstraction higher than a computer program.
|
||||
|
||||
* **Brute Force** - look at all the possibilities and selects the best solution
|
||||
* [Maximum Subarray](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/maximum-subarray)
|
||||
* [Travelling Salesman Problem](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/travelling-salesman) - shortest possible route that visits each city and returns to the origin city
|
||||
* **Greedy** - choose the best option at the current time, without any consideration for the future
|
||||
* [Unbound Knapsack Problem](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/knapsack-problem)
|
||||
* [Dijkstra Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/dijkstra) - finding shortest path to all graph vertices
|
||||
* [Prim’s Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/prim) - finding Minimum Spanning Tree (MST) for weighted undirected graph
|
||||
* [Kruskal’s Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/kruskal) - finding Minimum Spanning Tree (MST) for weighted undirected graph
|
||||
* **Divide and Conquer** - divide the problem into smaller parts and then solve those parts
|
||||
* [Binary Search](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/search/binary-search)
|
||||
* [Tower of Hanoi](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/uncategorized/hanoi-tower)
|
||||
* [Euclidean Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/euclidean-algorithm) - calculate the Greatest Common Divisor (GCD)
|
||||
* [Permutations](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/permutations) (with and without repetitions)
|
||||
* [Combinations](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/combinations) (with and without repetitions)
|
||||
* [Merge Sort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/merge-sort)
|
||||
* [Quicksort](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sorting/quick-sort)
|
||||
* [Tree Depth-First Search](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/tree/depth-first-search) (DFS)
|
||||
* [Graph Depth-First Search](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/depth-first-search) (DFS)
|
||||
* **Dynamic Programming** - build up to a solution using previously found sub-solutions
|
||||
* [Fibonacci Number](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/fibonacci)
|
||||
* [Levenshtein Distance](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/string/levenshtein-distance) - minimum edit distance between two sequences
|
||||
* [Longest Common Subsequence](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/longest-common-subsequnce) (LCS)
|
||||
* [Longest Common Substring](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/string/longest-common-substring)
|
||||
* [Longest Increasing subsequence](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/longest-increasing-subsequence)
|
||||
* [Shortest Common Supersequence](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/shortest-common-supersequence)
|
||||
* [0/1 Knapsack Problem](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/knapsack-problem)
|
||||
* [Integer Partition](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/math/integer-partition)
|
||||
* [Maximum Subarray](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/maximum-subarray)
|
||||
* [Bellman-Ford Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/bellman-ford) - finding shortest path to all graph vertices
|
||||
* **Backtracking** - similarly to brute force try to generate all possible solutions but each time you generate a solution test
|
||||
if it satisfies all conditions, and only then continue generating subsequent solutions. Otherwise backtrack and go on a
|
||||
different path of finding solution
|
||||
* [Hamiltonian Cycle](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/hamiltonian-cycle) - Visit every vertex exactly once
|
||||
* [N-Queens Problem](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/uncategorized/n-queens)
|
||||
* [Knight's Tour](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/uncategorized/knight-tour)
|
||||
* **Branch & Bound**
|
||||
|
||||
## 如何使用本知識庫
|
||||
|
||||
**安裝所有必須套件**
|
||||
|
||||
```
|
||||
npm install
|
||||
```
|
||||
|
||||
**執行所有測試**
|
||||
```
|
||||
npm test
|
||||
```
|
||||
|
||||
**以名稱執行該測試**
|
||||
```
|
||||
npm test -- -t 'LinkedList'
|
||||
```
|
||||
**Playground**
|
||||
|
||||
You may play with data-structures and algorithms in `./src/playground/playground.js` file and write
|
||||
tests for it in `./src/playground/__test__/playground.test.js`.
|
||||
|
||||
Then just simply run the following command to test if your playground code works as expected:
|
||||
|
||||
```
|
||||
npm test -- -t 'playground'
|
||||
```
|
||||
|
||||
## 有用的資訊
|
||||
|
||||
### 參考
|
||||
|
||||
[▶ Data Structures and Algorithms on YouTube](https://www.youtube.com/playlist?list=PLLXdhg_r2hKA7DPDsunoDZ-Z769jWn4R8)
|
||||
|
||||
### 大 O 標記
|
||||
|
||||
Order of growth of algorithms specified in Big O notation.
|
||||
|
||||
![Big O 表](https://github.com/trekhleb/javascript-algorithms/blob/master/assets/big-o-graph.png?raw=true)
|
||||
|
||||
資料來源: [Big O Cheat Sheet](http://bigocheatsheet.com/).
|
||||
|
||||
Below is the list of some of the most used Big O notations and their performance comparisons against different sizes of the input data.
|
||||
|
||||
| Big O Notation | Computations for 10 elements | Computations for 100 elements | Computations for 1000 elements |
|
||||
| -------------- | ---------------------------- | ----------------------------- | ------------------------------- |
|
||||
| **O(1)** | 1 | 1 | 1 |
|
||||
| **O(log N)** | 3 | 6 | 9 |
|
||||
| **O(N)** | 10 | 100 | 1000 |
|
||||
| **O(N log N)** | 30 | 600 | 9000 |
|
||||
| **O(N^2)** | 100 | 10000 | 1000000 |
|
||||
| **O(2^N)** | 1024 | 1.26e+29 | 1.07e+301 |
|
||||
| **O(N!)** | 3628800 | 9.3e+157 | 4.02e+2567 |
|
||||
|
||||
### Data Structure Operations Complexity
|
||||
|
||||
| Data Structure | Access | Search | Insertion | Deletion |
|
||||
| ----------------------- | :-------: | :-------: | :-------: | :-------: |
|
||||
| **Array** | 1 | n | n | n |
|
||||
| **Stack** | n | n | 1 | 1 |
|
||||
| **Queue** | n | n | 1 | 1 |
|
||||
| **Linked List** | n | n | 1 | 1 |
|
||||
| **Hash Table** | - | n | n | n |
|
||||
| **Binary Search Tree** | n | n | n | n |
|
||||
| **B-Tree** | log(n) | log(n) | log(n) | log(n) |
|
||||
| **Red-Black Tree** | log(n) | log(n) | log(n) | log(n) |
|
||||
| **AVL Tree** | log(n) | log(n) | log(n) | log(n) |
|
||||
|
||||
### Array Sorting Algorithms Complexity
|
||||
|
||||
| Name | Best | Average | Worst | Memory | Stable |
|
||||
| --------------------- | :-------: | :-------: | :-----------: | :-------: | :-------: |
|
||||
| **Bubble sort** | n | n^2 | n^2 | 1 | Yes |
|
||||
| **Insertion sort** | n | n^2 | n^2 | 1 | Yes |
|
||||
| **Selection sort** | n^2 | n^2 | n^2 | 1 | No |
|
||||
| **Heap sort** | n log(n) | n log(n) | n log(n) | 1 | No |
|
||||
| **Merge sort** | n log(n) | n log(n) | n log(n) | n | Yes |
|
||||
| **Quick sort** | n log(n) | n log(n) | n^2 | log(n) | No |
|
||||
| **Shell sort** | n log(n) | depends on gap sequence | n (log(n))^2 | 1 | No |
|
Loading…
Reference in New Issue
Block a user