程序開發(fā)中常用的十種算法,你用過幾種?
作者:架構(gòu)師老盧
當(dāng)編寫程序時(shí),了解和使用不同的算法對(duì)解決問題至關(guān)重要。以下是C#中常用的10種算法,每個(gè)算法都伴隨著示例代碼和詳細(xì)說明。
1、冒泡排序 (Bubble Sort):
冒泡排序是一種簡(jiǎn)單的比較排序算法,它多次遍歷數(shù)組,將較大的元素逐漸浮動(dòng)到數(shù)組的末尾。
public static void BubbleSort(int[] arr)
{
int n = arr.Length;
for (int i = 0; i < n - 1; i++)
{
for (int j = 0; j < n - i - 1; j++)
{
if (arr[j] > arr[j + 1])
{
int temp = arr[j];
arr[j] = arr[j + 1];
arr[j + 1] = temp;
}
}
}
}2、快速排序 (Quick Sort):
快速排序是一種高效的分治排序算法,它通過選擇一個(gè)基準(zhǔn)元素并將數(shù)組分為較小和較大的兩部分來進(jìn)行排序。
public static void QuickSort(int[] arr, int low, int high)
{
if (low < high)
{
int partitionIndex = Partition(arr, low, high);
QuickSort(arr, low, partitionIndex - 1);
QuickSort(arr, partitionIndex + 1, high);
}
}
public static int Partition(int[] arr, int low, int high)
{
int pivot = arr[high];
int i = low - 1;
for (int j = low; j < high; j++)
{
if (arr[j] < pivot)
{
i++;
int temp = arr[i];
arr[i] = arr[j];
arr[j] = temp;
}
}
int swap = arr[i + 1];
arr[i + 1] = arr[high];
arr[high] = swap;
return i + 1;
}3、合并排序 (Merge Sort):
合并排序是一種穩(wěn)定的分治排序算法,它將數(shù)組分成兩半,分別排序后再合并。
public static void MergeSort(int[] arr)
{
int n = arr.Length;
if (n > 1)
{
int mid = n / 2;
int[] left = new int[mid];
int[] right = new int[n - mid];
for (int i = 0; i < mid; i++)
left[i] = arr[i];
for (int i = mid; i < n; i++)
right[i - mid] = arr[i];
MergeSort(left);
MergeSort(right);
int i = 0, j = 0, k = 0;
while (i < mid && j < (n - mid))
{
if (left[i] < right[j])
arr[k++] = left[i++];
else
arr[k++] = right[j++];
}
while (i < mid)
arr[k++] = left[i++];
while (j < (n - mid))
arr[k++] = right[j++];
}
}4、二分查找 (Binary Search):
二分查找是一種高效的查找算法,它要求在有序數(shù)組中查找特定元素。
public static int BinarySearch(int[] arr, int target)
{
int low = 0, high = arr.Length - 1;
while (low <= high)
{
int mid = (low + high) / 2;
if (arr[mid] == target)
return mid;
else if (arr[mid] < target)
low = mid + 1;
else
high = mid - 1;
}
return -1;
}5、深度優(yōu)先搜索 (Depth-First Search, DFS):
DFS 是一種圖遍歷算法,它從起始節(jié)點(diǎn)開始,沿著路徑盡可能深入,然后返回并繼續(xù)搜索。
using System;
using System.Collections.Generic;
public class Graph
{
private int V;
private List<int>[] adj;
public Graph(int v)
{
V = v;
adj = new List<int>[v];
for (int i = 0; i < v; i++)
adj[i] = new List<int>();
}
public void AddEdge(int v, int w)
{
adj[v].Add(w);
}
public void DFS(int v)
{
bool[] visited = new bool[V];
DFSUtil(v, visited);
}
private void DFSUtil(int v, bool[] visited)
{
visited[v] = true;
Console.Write(v + " ");
foreach (var n in adj[v])
{
if (!visited[n])
DFSUtil(n, visited);
}
}
}6、廣度優(yōu)先搜索 (Breadth-First Search, BFS):
BFS 是一種圖遍歷算法,它從起始節(jié)點(diǎn)開始,逐層遍歷,先訪問所有相鄰的節(jié)點(diǎn),然后再逐層擴(kuò)展。
using System;
using System.Collections.Generic;
public class Graph
{
private int V;
private List<int>[] adj;
public Graph(int v)
{
V = v;
adj = new List<int>[v];
for (int i = 0; i < v; i++)
adj[i] = new List<int>();
}
public void AddEdge(int v, int w)
{
adj[v].Add(w);
}
public void BFS(int s)
{
bool[] visited = new bool[V];
Queue<int> queue = new Queue<int>();
visited[s] = true;
queue.Enqueue(s);
while (queue.Count != 0)
{
s = queue.Dequeue();
Console.Write(s + " ");
foreach (var n in adj[s])
{
if (!visited[n])
{
visited[n] = true;
queue.Enqueue(n);
}
}
}
}
}7、Dijkstra算法:
Dijkstra算法是一種用于查找圖中最短路徑的算法。
public class Dijkstra
{
private static int V = 9;
private int MinDistance(int[] dist, bool[] sptSet)
{
int min = int.MaxValue;
int minIndex = 0;
for (int v = 0; v < V; v++)
{
if (!sptSet[v] && dist
[v] <= min)
{
min = dist[v];
minIndex = v;
}
}
return minIndex;
}
private void PrintSolution(int[] dist)
{
Console.WriteLine("Vertex \t Distance from Source");
for (int i = 0; i < V; i++)
{
Console.WriteLine(i + " \t " + dist[i]);
}
}
public void FindShortestPath(int[,] graph, int src)
{
int[] dist = new int[V];
bool[] sptSet = new bool[V];
for (int i = 0; i < V; i++)
{
dist[i] = int.MaxValue;
sptSet[i] = false;
}
dist[src] = 0;
for (int count = 0; count < V - 1; count++)
{
int u = MinDistance(dist, sptSet);
sptSet[u] = true;
for (int v = 0; v < V; v++)
{
if (!sptSet[v] && graph[u, v] != 0 && dist[u] != int.MaxValue && dist[u] + graph[u, v] < dist[v])
{
dist[v] = dist[u] + graph[u, v];
}
}
}
PrintSolution(dist);
}
}8、最小生成樹 (Minimum Spanning Tree, MST) - Prim算法:
Prim算法用于找到圖的最小生成樹,它從一個(gè)初始頂點(diǎn)開始,逐漸擴(kuò)展生成樹。
public class PrimMST
{
private static int V = 5;
private int MinKey(int[] key, bool[] mstSet)
{
int min = int.MaxValue;
int minIndex = 0;
for (int v = 0; v < V; v++)
{
if (!mstSet[v] && key[v] < min)
{
min = key[v];
minIndex = v;
}
}
return minIndex;
}
private void PrintMST(int[] parent, int[,] graph)
{
Console.WriteLine("Edge \t Weight");
for (int i = 1; i < V; i++)
{
Console.WriteLine(parent[i] + " - " + i + " \t " + graph[i, parent[i]]);
}
}
public void FindMST(int[,] graph)
{
int[] parent = new int[V];
int[] key = new int[V];
bool[] mstSet = new bool[V];
for (int i = 0; i < V; i++)
{
key[i] = int.MaxValue;
mstSet[i] = false;
}
key[0] = 0;
parent[0] = -1;
for (int count = 0; count < V - 1; count++)
{
int u = MinKey(key, mstSet);
mstSet[u] = true;
for (int v = 0; v < V; v++)
{
if (graph[u, v] != 0 && !mstSet[v] && graph[u, v] < key[v])
{
parent[v] = u;
key[v] = graph[u, v];
}
}
}
PrintMST(parent, graph);
}
}9、最小生成樹 (Minimum Spanning Tree, MST) - Kruskal算法:
Kruskal算法也用于找到圖的最小生成樹,它基于邊的權(quán)重排序。
using System;
using System.Collections.Generic;
public class Graph
{
private int V, E;
private List<Edge> edges;
public Graph(int v, int e)
{
V = v;
E = e;
edges = new List<Edge>(e);
}
public void AddEdge(int src, int dest, int weight)
{
edges.Add(new Edge(src, dest, weight));
}
public void KruskalMST()
{
edges.Sort();
int[] parent = new int[V];
int[] rank = new int[V];
for (int i = 0; i < V; i++)
{
parent[i] = i;
rank[i] = 0;
}
int i = 0;
int e = 0;
List<Edge> mst = new List<Edge>();
while (e < V - 1)
{
Edge nextEdge = edges[i++];
int x = Find(parent, nextEdge.src);
int y = Find(parent, nextEdge.dest);
if (x != y)
{
mst.Add(nextEdge);
Union(parent, rank, x, y);
e++;
}
}
Console.WriteLine("Edges in Minimum Spanning Tree:");
foreach (var edge in mst)
{
Console.WriteLine($"{edge.src} - {edge.dest} with weight {edge.weight}");
}
}
private int Find(int[] parent, int i)
{
if (parent[i] == i)
return i;
return Find(parent, parent[i]);
}
private void Union(int[] parent, int[] rank, int x, int y)
{
int xRoot = Find(parent, x);
int yRoot = Find(parent, y);
if (rank[xRoot] < rank[yRoot])
parent[xRoot] = yRoot;
else if (rank[xRoot] > rank[yRoot])
parent[yRoot] = xRoot;
else
{
parent[yRoot] = xRoot;
rank[xRoot]++;
}
}
}
public class Edge : IComparable<Edge>
{
public int src, dest, weight;
public Edge(int src, int dest, int weight)
{
this.src = src;
this.dest = dest;
this.weight = weight;
}
public int CompareTo(Edge other)
{
return weight - other.weight;
}
}10、Floyd-Warshall算法是一種用于解決所有點(diǎn)對(duì)最短路徑的動(dòng)態(tài)規(guī)劃算法。
下面是C#中的Floyd-Warshall算法的實(shí)現(xiàn)示例:
using System;
class FloydWarshall
{
private static int INF = int.MaxValue; // 代表無窮大的值
public static void FindShortestPath(int[,] graph)
{
int V = graph.GetLength(0);
// 創(chuàng)建一個(gè)二維數(shù)組dist,用于保存最短路徑的長(zhǎng)度
int[,] dist = new int[V, V];
// 初始化dist數(shù)組
for (int i = 0; i < V; i++)
{
for (int j = 0; j < V; j++)
{
dist[i, j] = graph[i, j];
}
}
// 逐個(gè)頂點(diǎn)考慮,如果經(jīng)過k頂點(diǎn)路徑比原路徑短,就更新dist數(shù)組
for (int k = 0; k < V; k++)
{
for (int i = 0; i < V; i++)
{
for (int j = 0; j < V; j++)
{
if (dist[i, k] != INF && dist[k, j] != INF
&& dist[i, k] + dist[k, j] < dist[i, j])
{
dist[i, j] = dist[i, k] + dist[k, j];
}
}
}
}
// 輸出最短路徑矩陣
Console.WriteLine("最短路徑矩陣:");
for (int i = 0; i < V; i++)
{
for (int j = 0; j < V; j++)
{
if (dist[i, j] == INF)
Console.Write("INF\t");
else
Console.Write(dist[i, j] + "\t");
}
Console.WriteLine();
}
}
static void Main(string[] args)
{
int V = 4; // 頂點(diǎn)數(shù)
int[,] graph = {
{0, 5, INF, 10},
{INF, 0, 3, INF},
{INF, INF, 0, 1},
{INF, INF, INF, 0}
};
FindShortestPath(graph);
}
}在這個(gè)示例中,我們使用Floyd-Warshall算法來計(jì)算給定圖的最短路徑矩陣。該算法通過考慮逐個(gè)中間頂點(diǎn)k,不斷更新最短路徑矩陣dist。最終,我們可以獲得所有點(diǎn)對(duì)之間的最短路徑長(zhǎng)度。
責(zé)任編輯:姜華
來源:
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