""" The following undirected network consists of seven vertices and twelve edges with a total weight of 243.  The same network can be represented by the matrix below. A B C D E F G A - 16 12 21 - - - B 16 - - 17 20 - - C 12 - - 28 - 31 - D 21 17 28 - 18 19 23 E - 20 - 18 - - 11 F - - 31 19 - - 27 G - - - 23 11 27 - However, it is possible to optimise the network by removing some edges and still ensure that all points on the network remain connected. The network which achieves the maximum saving is shown below. It has a weight of 93, representing a saving of 243 - 93 = 150 from the original network. Using network.txt (right click and 'Save Link/Target As...'), a 6K text file containing a network with forty vertices, and given in matrix form, find the maximum saving which can be achieved by removing redundant edges whilst ensuring that the network remains connected. Solution: We use Prim's algorithm to find a Minimum Spanning Tree. Reference: https://en.wikipedia.org/wiki/Prim%27s_algorithm """ from __future__ import annotations import os from collections.abc import Mapping EdgeT = tuple[int, int] class Graph: """ A class representing an undirected weighted graph. """ def __init__(self, vertices: set[int], edges: Mapping[EdgeT, int]) -> None: self.vertices: set[int] = vertices self.edges: dict[EdgeT, int] = { (min(edge), max(edge)): weight for edge, weight in edges.items() } def add_edge(self, edge: EdgeT, weight: int) -> None: """ Add a new edge to the graph. >>> graph = Graph({1, 2}, {(2, 1): 4}) >>> graph.add_edge((3, 1), 5) >>> sorted(graph.vertices) [1, 2, 3] >>> sorted([(v,k) for k,v in graph.edges.items()]) [(4, (1, 2)), (5, (1, 3))] """ self.vertices.add(edge[0]) self.vertices.add(edge[1]) self.edges[(min(edge), max(edge))] = weight def prims_algorithm(self) -> Graph: """ Run Prim's algorithm to find the minimum spanning tree. Reference: https://en.wikipedia.org/wiki/Prim%27s_algorithm >>> graph = Graph({1,2,3,4},{(1,2):5, (1,3):10, (1,4):20, (2,4):30, (3,4):1}) >>> mst = graph.prims_algorithm() >>> sorted(mst.vertices) [1, 2, 3, 4] >>> sorted(mst.edges) [(1, 2), (1, 3), (3, 4)] """ subgraph: Graph = Graph({min(self.vertices)}, {}) min_edge: EdgeT min_weight: int edge: EdgeT weight: int while len(subgraph.vertices) < len(self.vertices): min_weight = max(self.edges.values()) + 1 for edge, weight in self.edges.items(): if (edge[0] in subgraph.vertices) ^ ( edge[1] in subgraph.vertices ) and weight < min_weight: min_edge = edge min_weight = weight subgraph.add_edge(min_edge, min_weight) return subgraph def solution(filename: str = "p107_network.txt") -> int: """ Find the maximum saving which can be achieved by removing redundant edges whilst ensuring that the network remains connected. >>> solution("test_network.txt") 150 """ script_dir: str = os.path.abspath(os.path.dirname(__file__)) network_file: str = os.path.join(script_dir, filename) edges: dict[EdgeT, int] = {} data: list[str] edge1: int edge2: int with open(network_file) as f: data = f.read().strip().split("\n") adjaceny_matrix = [line.split(",") for line in data] for edge1 in range(1, len(adjaceny_matrix)): for edge2 in range(edge1): if adjaceny_matrix[edge1][edge2] != "-": edges[(edge2, edge1)] = int(adjaceny_matrix[edge1][edge2]) graph: Graph = Graph(set(range(len(adjaceny_matrix))), edges) subgraph: Graph = graph.prims_algorithm() initial_total: int = sum(graph.edges.values()) optimal_total: int = sum(subgraph.edges.values()) return initial_total - optimal_total if __name__ == "__main__": print(f"{solution() = }")