|
|
Line 1: |
Line 1: |
− | <pre>
| + | |
− | Working with the list of edges of an undirected graph G
| |
− | Read the edges of G and create an adjacency matrix A, and simultaneously calculate the degree of each vertex in the array B # O(m)
| |
− | - Consider an edge UW, if the data about it already exists A[U][W] == A[W][U] == 1, then a multiple edge is found, skip it
| |
− | Initialize the queue Q
| |
− | Add to Q all vertexes whose degree is 2 # O(n) iterations, O(1) get the vertex degree via the array B
| |
− | - The presence of a vertex in the queue is noted in the array C, which consists of bool flags
| |
− | Loop until the queue Q is empty: # O(n) iterations
| |
− | - Extract vertex V from Q # V has degree 2 => V located between vertexes U and W
| |
− | - Delete the edge UV, B[U] -= 1
| |
− | - Delete the edge VW, B[W] -= 1
| |
− | - Delete vertex V, C[V] = False
| |
− | - If U and W are not adjacent, connect U and W with an edge and increase the degrees of U and W by 1 # Checking the adjacency O(1) via the adjacency matrix
| |
− | - If U's degree is 2 and U is not in queue Q, add U to Q # Getting vertex degree via B O(1), checking for presence in the queue via C O(1)
| |
− | - If W's degree is 2 and W is not in queue Q, add W to Q
| |
− | </pre>--[[User:Bkarpov96|Bkarpov96]] ([[User talk:Bkarpov96|talk]]) 08:17, 7 July 2020 (UTC)
| |