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446 lines
21 KiB
Markdown
446 lines
21 KiB
Markdown
---
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title: 图算法
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date: 2018-09-06 19:10
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categories: 数据结构与算法
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tags: [图,算法]
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keywords: 图,算法
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mathjax: true
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description:
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---
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<!-- TOC -->
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- [1. 图](#1-图)
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- [1.1. 概念](#11-概念)
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- [1.1.1. 性质](#111-性质)
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- [1.2. 图的表示](#12-图的表示)
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- [1.3. 树](#13-树)
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- [2. 搜索](#2-搜索)
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- [2.1. BFS](#21-bfs)
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- [2.2. DFS](#22-dfs)
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- [2.2.1. DFS 的性质](#221-dfs-的性质)
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- [2.3. 拓扑排序](#23-拓扑排序)
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- [2.4. 强连通分量](#24-强连通分量)
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- [3. 最小生成树](#3-最小生成树)
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- [3.1. Kruskal 算法](#31-kruskal-算法)
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- [3.2. Prim 算法](#32-prim-算法)
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- [4. 单源最短路](#4-单源最短路)
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- [4.1. 负权重的边](#41-负权重的边)
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- [4.2. 初始化](#42-初始化)
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- [4.3. 松弛操作](#43-松弛操作)
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- [4.4. 有向无环图的单源最短路问题](#44-有向无环图的单源最短路问题)
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- [4.5. Bellman-Ford 算法](#45-bellman-ford-算法)
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- [4.6. Dijkstra 算法](#46-dijkstra-算法)
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- [5. 所有结点对的最短路问题](#5-所有结点对的最短路问题)
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- [5.1. 矩阵乘法](#51-矩阵乘法)
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- [5.2. Floyd-Warshall 算法](#52-floyd-warshall-算法)
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- [5.3. Johnson 算法](#53-johnson-算法)
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- [6. 最大流](#6-最大流)
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- [6.1. 定理](#61-定理)
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- [6.2. 多个源,汇](#62-多个源汇)
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- [6.3. Ford-Fulkerson 方法](#63-ford-fulkerson-方法)
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- [6.3.1. 残存网络](#631-残存网络)
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- [6.3.2. 增广路径](#632-增广路径)
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- [6.3.3. 割](#633-割)
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- [6.4. 基本的 Ford-Fulkerson算法](#64-基本的-ford-fulkerson算法)
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- [6.5. TBD](#65-tbd)
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- [7. 参考资料](#7-参考资料)
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<!-- /TOC -->
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<a id="markdown-1-图" name="1-图"></a>
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# 1. 图
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<a id="markdown-11-概念" name="11-概念"></a>
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## 1.1. 概念
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* 顶
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* 顶点的度 d
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* 边
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* 相邻
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* 重边
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* 环
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* 完全图: 所有顶都相邻
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* 二分图: ![](https://latex.codecogs.com/gif.latex?V(G)&space;=&space;X&space;\cup&space;Y,&space;X\cap&space;Y&space;=&space;\varnothing), X中, Y 中任两顶不相邻
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* 轨道
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* 圈
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<a id="markdown-111-性质" name="111-性质"></a>
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### 1.1.1. 性质
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* ![](https://latex.codecogs.com/gif.latex?\sum_{v\in&space;V}&space;d(v)&space;=&space;2|E|)
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* G是二分图 ![](https://latex.codecogs.com/gif.latex?\Leftrightarrow) G无奇圈
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* 树是无圈连通图
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* 树中, ![](https://latex.codecogs.com/gif.latex?|E|&space;=&space;|V|&space;-1)
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<a id="markdown-12-图的表示" name="12-图的表示"></a>
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## 1.2. 图的表示
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* 邻接矩阵
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* 邻接链表
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![](https://upload-images.jianshu.io/upload_images/7130568-57ce6db904992656.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
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<a id="markdown-13-树" name="13-树"></a>
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## 1.3. 树
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无圈连通图, ![](https://latex.codecogs.com/gif.latex?E&space;=&space;V-1), 详细见[树](https://mbinary.xyz/tree.html),
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<a id="markdown-2-搜索" name="2-搜索"></a>
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# 2. 搜索
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求图的生成树[^1]
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<a id="markdown-21-bfs" name="21-bfs"></a>
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## 2.1. BFS
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```python
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for v in V:
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v.d = MAX
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v.pre = None
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v.isFind = False
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root. isFind = True
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root.d = 0
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que = [root]
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while que !=[]:
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nd = que.pop(0)
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for v in Adj(nd):
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if not v.isFind :
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v.d = nd.d+1
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v.pre = nd
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v.isFind = True
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que.append(v)
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```
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时间复杂度 ![](https://latex.codecogs.com/gif.latex?O(V+E))
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<a id="markdown-22-dfs" name="22-dfs"></a>
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## 2.2. DFS
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![](https://latex.codecogs.com/gif.latex?\Theta(V+E))
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```python
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def dfs(G):
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time = 0
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for v in V:
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v.pre = None
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v.isFind = False
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for v in V : # note this,
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if not v.isFind:
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dfsVisit(v)
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def dfsVisit(G,u):
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time =time+1
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u.begin = time
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u.isFind = True
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for v in Adj(u):
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if not v.isFind:
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v.pre = u
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dfsVisit(G,v)
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time +=1
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u.end = time
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```
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begin, end 分别是结点的发现时间与完成时间
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<a id="markdown-221-dfs-的性质" name="221-dfs-的性质"></a>
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### 2.2.1. DFS 的性质
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* 其生成的前驱子图![](https://latex.codecogs.com/gif.latex?G_{pre}) 形成一个由多棵树构成的森林, 这是因为其与 dfsVisit 的递归调用树相对应
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* 括号化结构
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![](https://upload-images.jianshu.io/upload_images/7130568-ba62e68e5b883b6c.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
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* 括号化定理:
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考察两个结点的发现时间与结束时间的区间 [u,begin,u.end] 与 [v.begin,v.end]
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* 如果两者没有交集, 则两个结点在两个不同的子树上(递归树)
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* 如果 u 的区间包含在 v 的区间, 则 u 是v 的后代
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<a id="markdown-23-拓扑排序" name="23-拓扑排序"></a>
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## 2.3. 拓扑排序
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利用 DFS, 结点的完成时间的逆序就是拓扑排序
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同一个图可能有不同的拓扑排序
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<a id="markdown-24-强连通分量" name="24-强连通分量"></a>
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## 2.4. 强连通分量
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在有向图中, 强连通分量中的结点互达
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定义 ![](https://latex.codecogs.com/gif.latex?Grev) 为 ![](https://latex.codecogs.com/gif.latex?G) 中所有边反向后的图
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将图分解成强连通分量的算法
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在 Grev 上根据 G 中结点的拓扑排序来 dfsVisit, 即
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```python
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compute Grev
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initalization
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for v in topo-sort(G.V):
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if not v.isFind: dfsVisit(Grev,v)
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```
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然后得到的DFS 森林(也是递归树森林)中每个树就是一个强连通分量
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<a id="markdown-3-最小生成树" name="3-最小生成树"></a>
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# 3. 最小生成树
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利用了贪心算法,
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<a id="markdown-31-kruskal-算法" name="31-kruskal-算法"></a>
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## 3.1. Kruskal 算法
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总体上, 从最开始 每个结点就是一颗树的森林中(不相交集合, 并查集), 逐渐添加不形成圈的(两个元素不再同一个集合),最小边权的边.
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```python
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edges=[]
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for edge as u,v in sorted(G.E):
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if find-set(u) != find-set(v):
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edges.append(edge)
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union(u,v)
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return edges
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```
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如果并查集的实现采用了 按秩合并与路径压缩技巧, 则 find 与 union 的时间接近常数
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所以时间复杂度在于排序边, 即 ![](https://latex.codecogs.com/gif.latex?O(ElgE)), 而 ![](https://latex.codecogs.com/gif.latex?E\<&space;V^2), 所以 ![](https://latex.codecogs.com/gif.latex?lgE&space;=&space;O(lgV)), 时间复杂度为 ![](https://latex.codecogs.com/gif.latex?O(ElgV))
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<a id="markdown-32-prim-算法" name="32-prim-算法"></a>
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## 3.2. Prim 算法
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用了 BFS, 类似 Dijkstra 算法
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从根结点开始 BFS, 一直保持成一颗树
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```python
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for v in V:
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v.minAdjEdge = MAX
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v.pre = None
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root.minAdjEdge = 0
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que = priority-queue (G.V) # sort by minAdjEdge
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while not que.isempty():
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u = que.extractMin()
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for v in Adj(u):
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if v in que and v.minAdjEdge>w(u,v):
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v.pre = u
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v.minAdjEdge = w(u,v)
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```
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* 建堆 ![](https://latex.codecogs.com/gif.latex?O(V)) `//note it's v, not vlgv`
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* 主循环中
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* extractMin: ![](https://latex.codecogs.com/gif.latex?O(VlgV))
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* in 操作 可以另设标志位, 在常数时间完成, 总共 ![](https://latex.codecogs.com/gif.latex?O(E))
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* 设置结点的 minAdjEdge, 需要![](https://latex.codecogs.com/gif.latex?O(lgv)), 循环 E 次,则 总共![](https://latex.codecogs.com/gif.latex?O(ElgV))
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综上, 时间复杂度为![](https://latex.codecogs.com/gif.latex?O(ElgV))
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如果使用的是 [斐波那契堆](https://mbinary.xyz/fib-heap.html), 则可改进到 ![](https://latex.codecogs.com/gif.latex?O(E+VlgV))
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<a id="markdown-4-单源最短路" name="4-单源最短路"></a>
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# 4. 单源最短路
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求一个结点到其他结点的最短路径, 可以用 Bellman-Ford算法, 或者 Dijkstra算法.
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定义两个结点u,v间的最短路
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![](https://latex.codecogs.com/gif.latex?&space;\delta(u,v)&space;=&space;\begin{cases}&space;min(w(path)),\quad&space;u\xrightarrow{path}&space;v\\&space;MAX,&space;\quad&space;u&space;rightarrow&space;v&space;\end{cases}&space;)
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问题的变体
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* 单目的地最短路问题: 可以将所有边反向转换成求单源最短路问题
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* 单结点对的最短路径
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* 所有结点对最短路路径
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<a id="markdown-41-负权重的边" name="41-负权重的边"></a>
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## 4.1. 负权重的边
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Dijkstra 算法不能处理负权边, 只能用 Bellman-Ford 算法,
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而且如果有负值圈, 则没有最短路, bellman-ford算法也可以检测出来
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<a id="markdown-42-初始化" name="42-初始化"></a>
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## 4.2. 初始化
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```python
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def initialaize(G,s):
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for v in G.V:
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v.pre = None
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v.distance = MAX
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s.distance = 0
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```
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<a id="markdown-43-松弛操作" name="43-松弛操作"></a>
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## 4.3. 松弛操作
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```python
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def relax(u,v,w):
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if v.distance > u.distance + w:
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v.distance = u.distance + w:
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v.pre = u
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```
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性质
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* 三角不等式: ![](https://latex.codecogs.com/gif.latex?\delta(s,v)&space;\leqslant&space;\delta(s,u)&space;+&space;w(u,v))
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* 上界: ![](https://latex.codecogs.com/gif.latex?v.distance&space;\geqslant&space;\delta(s,v))
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* 收敛: 对于某些结点u,v 如果s->...->u->v是图G中的一条最短路径,并且在对边,进行松弛前任意时间有 ![](https://latex.codecogs.com/gif.latex?u.distance=\delta(s,u))则在之后的所有时间有 ![](https://latex.codecogs.com/gif.latex?v.distance=\delta(s,v))
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* 路径松弛性质: 如果![](https://latex.codecogs.com/gif.latex?p=v_0&space;v_1&space;\ldots&space;v_k)是从源结点下v0到结点vk的一条最短路径,并且对p中的边所进行松弛的次序为![](https://latex.codecogs.com/gif.latex?(v_0,v_1),(v_1,v_2),&space;\ldots&space;,(v_{k-1},v_k)), 则 ![](https://latex.codecogs.com/gif.latex?v_k.distance&space;=&space;\delta(s,v_k))
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该性质的成立与任何其他的松弛操作无关,即使这些松弛操作是与对p上的边所进行的松弛操作穿插进行的。
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证明
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![](https://upload-images.jianshu.io/upload_images/7130568-424a6929bd389825.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
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<a id="markdown-44-有向无环图的单源最短路问题" name="44-有向无环图的单源最短路问题"></a>
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## 4.4. 有向无环图的单源最短路问题
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```python
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def dag-shortest-path(G,s):
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initialize(G,s)
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for u in topo-sort(G.V):
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for v in Adj(v):
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relax(u,v,w(u,v))
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```
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<a id="markdown-45-bellman-ford-算法" name="45-bellman-ford-算法"></a>
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## 4.5. Bellman-Ford 算法
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```python
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def bellman-ford(G,s):
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initialize(G,s)
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for ct in range(|V|-1): # v-1times
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for u,v as edge in E:
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relax(u,v,w(u,v))
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for u,v as edge in E:
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if v.distance > u.distance + w(u,v):
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return False
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return True
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```
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第一个 for 循环就是进行松弛操作, 最后结果已经存储在 结点的distance 和 pre 属性中了, 第二个 for 循环利用三角不等式检查有不有负值圈.
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下面是证明该算法的正确性![](https://upload-images.jianshu.io/upload_images/7130568-f84e00ac35aadc81.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
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<a id="markdown-46-dijkstra-算法" name="46-dijkstra-算法"></a>
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## 4.6. Dijkstra 算法
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```python
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def dijkstra(G,s):
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initialize(G,s)
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paths=[]
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q = priority-queue(G.V) # sort by distance
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while not q.empty():
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u = q.extract-min()
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paths.append(u)
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for v in Adj(u):
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relax(u,v,w(u,v))
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```
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<a id="markdown-5-所有结点对的最短路问题" name="5-所有结点对的最短路问题"></a>
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# 5. 所有结点对的最短路问题
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<a id="markdown-51-矩阵乘法" name="51-矩阵乘法"></a>
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## 5.1. 矩阵乘法
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使用动态规划算法, 可以得到最短路径的结构
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设 ![](https://latex.codecogs.com/gif.latex?l_{ij}^{(m)})为从结点i 到结点 j 的至多包含 m 条边的任意路径的最小权重,当m = 0, 此时i=j, 则 为0,
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可以得到递归定义
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![](https://latex.codecogs.com/gif.latex?&space;l_{ij}^{(m)}&space;=\min(&space;l_{ij}^{(m-1)},&space;\min_{1\leqslant&space;k\leqslant&space;n}(&space;l_{ik}^{(m-1)}+w_{kj}))&space;=&space;\min_{1\leqslant&space;k\leqslant&space;n}(&space;l_{ik}^{(m-1)}+w_{kj}))&space;)
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由于是简单路径, 则包含的边最多为 |V|-1 条, 所以
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![](https://latex.codecogs.com/gif.latex?&space;\delta(i,j)&space;=&space;l_{ij}^{(|V|-1)}&space;=&space;l_{ij}^{(|V|)}&space;=l_{ij}^{(|V|&space;+&space;1)}=&space;...&space;)
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所以可以自底向上计算, 如下
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输入权值矩阵 ![](https://latex.codecogs.com/gif.latex?W(w_{ij})),&space;L^{(m-1)}),输出![](https://latex.codecogs.com/gif.latex?L^{(m)}), 其中 ![](https://latex.codecogs.com/gif.latex?L^{(1)}&space;=&space;W),
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```python
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n = L.rows
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L' = new matrix(nxn)
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for i in range(n):
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for j in range(n):
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l'[i][j] = MAX
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for k in range(n):
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l'[i][j] = min(l'[i][j], l[i][k]+w[k][j])
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return L'
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```
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可以看出该算法与矩阵乘法的关系
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![](https://latex.codecogs.com/gif.latex?L^{(m)}&space;=&space;W^m),
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所以可以直接计算乘法, 每次计算一个乘积是 ![](https://latex.codecogs.com/gif.latex?O(V^3)), 计算 V 次, 所以总体 ![](https://latex.codecogs.com/gif.latex?O(V^4)), 使用矩阵快速幂可以将时间复杂度降低为![](https://latex.codecogs.com/gif.latex?O(V^3lgV))
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```python
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def f(W):
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L = W
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i = 1
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while i<W.rows:
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L = L*L
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i*=2
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return L
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```
|
||
|
||
<a id="markdown-52-floyd-warshall-算法" name="52-floyd-warshall-算法"></a>
|
||
## 5.2. Floyd-Warshall 算法
|
||
同样要求可以存在负权边, 但不能有负值圈. 用动态规划算法:
|
||
设 ![](https://latex.codecogs.com/gif.latex?d_{ij}^{(k)}) 为 从 i 到 j 所有中间结点来自集合 ![](https://latex.codecogs.com/gif.latex?{\{1,2,\ldots,k\}}) 的一条最短路径的权重. 则有
|
||
![](https://latex.codecogs.com/gif.latex?&space;d_{ij}^{(k)}&space;=&space;\begin{cases}&space;w_{ij},\quad&space;k=0\\&space;min(d_{ij}^{(k-1)},d_{ik}^{(k-1)}+d_{kj}^{(k-1)}),\quad&space;k\geqslant&space;1&space;\end{cases}&space;)
|
||
而且为了找出路径, 需要记录前驱结点, 定义如下前驱矩阵 ![](https://latex.codecogs.com/gif.latex?\Pi), 设 ![](https://latex.codecogs.com/gif.latex?\pi_{ij}^{(k)}) 为 从 i 到 j 所有中间结点来自集合 ![](https://latex.codecogs.com/gif.latex?{\{1,2,\ldots,k\}}) 的最短路径上 j 的前驱结点
|
||
则
|
||
![](https://latex.codecogs.com/gif.latex?&space;\pi_{ij}^{(0)}&space;=&space;\begin{cases}&space;nil,\quad&space;i=j&space;\&space;or&space;\&space;w_{ij}=MAX\\&space;i,&space;\quad&space;i&space;eq&space;j&space;and&space;\&space;w_{ij}<MAX&space;\end{cases}&space;)
|
||
对 ![](https://latex.codecogs.com/gif.latex?k\geqslant&space;1)
|
||
![](https://latex.codecogs.com/gif.latex?&space;\pi_{ij}^{(k)}&space;=&space;\begin{cases}&space;\pi_{ij}^{(k-1)}&space;,\quad&space;d_{ij}^{(k-1)}\leqslant&space;d_{ik}^{(k-1)}+d_{kj}^{(k-1)}\\&space;\pi_{kj}^{(k-1)}&space;,\quad&space;otherwise&space;\end{cases}&space;)
|
||
|
||
由此得出此算法
|
||
```python
|
||
def floyd-warshall(w):
|
||
n = len(w)
|
||
d= w
|
||
initial pre # 0
|
||
for k in range(n):
|
||
d2 = d.copy()
|
||
pre2 = pre.copy()
|
||
for j in range(n):
|
||
for i in range(v)
|
||
if d[i][j] > d[i][k]+d[k][j]:
|
||
d2[i][j] = min(d[i][j], d[i][k]+d[k][j])
|
||
pre2[i][j] = pre[k][j]
|
||
pre = pre2
|
||
d = d2
|
||
return d,pre
|
||
```
|
||
<a id="markdown-53-johnson-算法" name="53-johnson-算法"></a>
|
||
## 5.3. Johnson 算法
|
||
思路是通过重新赋予权重, 将图中负权边转换为正权,然后就可以用 dijkstra 算法(要求是正值边)来计算一个结点到其他所有结点的, 然后对所有结点用dijkstra
|
||
|
||
1. 首先构造一个新图 G'
|
||
先将G拷贝到G', 再添加一个新结点 s, 添加 G.V条边, s 到G中顶点的, 权赋值为 0
|
||
2. 用 Bellman-Ford 算法检查是否有负值圈, 如果没有, 同时求出 ![](https://latex.codecogs.com/gif.latex?\delta(s,v)&space;Recorded-as&space;h(v))
|
||
3. 求新的非负值权, w'(u,v) = w(u,v)+h(u)-h(v)
|
||
4. 对所有结点在 新的权矩阵w'上 用 Dijkstra 算法
|
||
![image.png](https://upload-images.jianshu.io/upload_images/7130568-6c2146ad64d692f3.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
|
||
|
||
```python
|
||
JOHNSON (G, u)
|
||
|
||
s = newNode
|
||
G' = G.copy()
|
||
G'.addNode(s)
|
||
for v in G.V: G'.addArc(s,v,w=0)
|
||
|
||
if BELLMAN-FORD(G' , w, s) ==FALSE
|
||
error "the input graph contains a negative-weight cycle"
|
||
|
||
for v in G'.V:
|
||
# computed by the bellman-ford algorithm, delta(s,v) is the shortest distance from s to v
|
||
h(v) = delta(s,v)
|
||
for edge(u,v) in G'.E:
|
||
w' = w(u,v)+h(u)-h(v)
|
||
d = matrix(n,n)
|
||
for u in G:
|
||
dijkstra(G,w',u) # compute delta' for all v in G.V
|
||
for v in G.V:
|
||
d[u][v] = delta'(u,v) + h(v)-h(u)
|
||
return d
|
||
```
|
||
<a id="markdown-6-最大流" name="6-最大流"></a>
|
||
# 6. 最大流
|
||
G 是弱连通严格有向加权图, s为源, t 为汇, 每条边e容量 c(e), 由此定义了网络N(G,s,t,c(e)),
|
||
* 流函数 ![](https://latex.codecogs.com/gif.latex?f(e):E&space;\rightarrow&space;R)
|
||
![](https://latex.codecogs.com/gif.latex?&space;\begin{aligned}&space;(1)\quad&space;&&space;0\leqslant&space;f(e)&space;\leqslant&space;c(e),\quad&space;e&space;\in&space;E\\&space;(2)\quad&space;&&space;\sum_{e\in&space;\alpha(v)}&space;f(e)=&space;\sum_{e\in&space;\beta(v)}f(e),\quad&space;v&space;\in&space;V-\{s,t\}&space;\end{aligned}&space;)
|
||
其中 ![](https://latex.codecogs.com/gif.latex?\alpha(v)) 是以 v 为头的边集, ![](https://latex.codecogs.com/gif.latex?\beta(v))是以 v 为尾的边集
|
||
* 流量: ![](https://latex.codecogs.com/gif.latex?F&space;=&space;\sum_{e\in&space;\alpha(t)}&space;f(e)-&space;\sum_{e\in&space;-\beta(t)}f(e),)
|
||
* 截![](https://latex.codecogs.com/gif.latex?(S,\overline&space;S)): ![](https://latex.codecogs.com/gif.latex?S\subset&space;V,s\in&space;S,&space;t\in&space;\overline&space;S&space;=V-S)
|
||
* 截量![](https://latex.codecogs.com/gif.latex?C(S)&space;=&space;\sum_{e\in(S,\overline&space;S)}c(e))
|
||
<a id="markdown-61-定理" name="61-定理"></a>
|
||
## 6.1. 定理
|
||
参考 图论[^2]
|
||
* 对于任一截![](https://latex.codecogs.com/gif.latex?(S,\overline&space;S)), 有 ![](https://latex.codecogs.com/gif.latex?F&space;=&space;\sum_{e\in&space;(S,\overline&space;S)}&space;f(e)-&space;\sum_{e\in(\overline&space;S,S)}f(e),)
|
||
![prove](https://upload-images.jianshu.io/upload_images/7130568-19bf6cc3c7d6ce06.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
|
||
* ![](https://latex.codecogs.com/gif.latex?F\leqslant&space;C(S))
|
||
证明: 由上面定理
|
||
![](https://latex.codecogs.com/gif.latex?F&space;=&space;\sum_{e\in&space;(S,\overline&space;S)}&space;f(e)-&space;\sum_{e\in(\overline&space;S,S)}f(e),)
|
||
而 ![](https://latex.codecogs.com/gif.latex?0\leqslant&space;f(e)&space;\leqslant&space;c(e)), 则
|
||
![](https://latex.codecogs.com/gif.latex?F\leqslant&space;\sum_{e\in&space;(S,\overline&space;S)}&space;f(e)&space;\leqslant&space;\sum_{e\in&space;(S,\overline&space;S)}&space;c(e)&space;=&space;C(S))
|
||
* 最大流,最小截: 若![](https://latex.codecogs.com/gif.latex?F=&space;C(S)), 则F'是最大流量, C(S) 是最小截量
|
||
<a id="markdown-62-多个源汇" name="62-多个源汇"></a>
|
||
## 6.2. 多个源,汇
|
||
可以新增一个总的源,一个总的汇,
|
||
![](https://upload-images.jianshu.io/upload_images/7130568-3e9e87fdf9655883.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
|
||
|
||
<a id="markdown-63-ford-fulkerson-方法" name="63-ford-fulkerson-方法"></a>
|
||
## 6.3. Ford-Fulkerson 方法
|
||
由于其实现可以有不同的运行时间, 所以称其为方法, 而不是算法.
|
||
思路是 循环增加流的值, 在一个关联的"残存网络" 中寻找一条"增广路径", 然后对这些边进行修改流量. 重复直至残存网络上不再存在增高路径为止.
|
||
```python
|
||
def ford-fulkerson(G,s,t):
|
||
initialize flow f to 0
|
||
while exists an augmenting path p in residual network Gf:
|
||
augment flow f along p
|
||
return f
|
||
```
|
||
<a id="markdown-631-残存网络" name="631-残存网络"></a>
|
||
### 6.3.1. 残存网络
|
||
![](https://upload-images.jianshu.io/upload_images/7130568-c74a571b9121dbbf.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
|
||
|
||
<a id="markdown-632-增广路径" name="632-增广路径"></a>
|
||
### 6.3.2. 增广路径
|
||
![](https://upload-images.jianshu.io/upload_images/7130568-b9e841cfa4d04b57.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
|
||
<a id="markdown-633-割" name="633-割"></a>
|
||
### 6.3.3. 割
|
||
![](https://upload-images.jianshu.io/upload_images/7130568-74b065e86eb285b7.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
|
||
<a id="markdown-64-基本的-ford-fulkerson算法" name="64-基本的-ford-fulkerson算法"></a>
|
||
## 6.4. 基本的 Ford-Fulkerson算法
|
||
```python
|
||
def ford-fulkerson(G,s,t):
|
||
for edge in G.E: edge.f = 0
|
||
while exists path p:s->t in Gf:
|
||
cf(p) = min{cf(u,v):(u,v) is in p}
|
||
for edge in p:
|
||
if edge in E:
|
||
edge.f +=cf(p)
|
||
else: reverse_edge.f -=cf(p)
|
||
```
|
||
|
||
<a id="markdown-65-tbd" name="65-tbd"></a>
|
||
## 6.5. TBD
|
||
|
||
<a id="markdown-7-参考资料" name="7-参考资料"></a>
|
||
# 7. 参考资料
|
||
[^1]: 算法导论
|
||
[^2]: 图论, 王树禾
|