【用deepseek和chatgpt做算法竞赛】——还得DeepSeek来 -Minimum Cost Trees_5
往期
- 【用deepseek和chatgpt做算法竞赛】——华为算法精英实战营第十九期-Minimum Cost Trees_0:介绍了题目和背景
- 【用deepseek和chatgpt做算法竞赛】——华为算法精英实战营第十九期-Minimum Cost Trees_1:题目输入的格式说明,选择了邻接表来表示图
- 【用deepseek和chatgpt做算法竞赛】——华为算法精英实战营第十九期-Minimum Cost Trees_2:介绍了邻接表,题目输出的格式说明
- 【用deepseek和chatgpt做算法竞赛】——华为算法精英实战营第十九期-Minimum Cost Trees_3:期主要写一个初代程序,能完整一些简单的例子
- 【用deepseek和chatgpt做算法竞赛】——ChatGPT还是不行呀 -Minimum Cost Trees_4:介绍了评分规则,让GPT输出了一个看着正确实际不行的代码
这一期,我选择用伪代码的方式与GPT沟通,让GPT做军师和程序员,一定要写一个有分的程序呀
0 基础程序
下面这个程序就是根据题目要求写的一个输入数据读取的程序
import sys
import heapq
from collections import defaultdict
def read_graph_from_file(file_path):
""" 从文件读取图数据并解析 """
with open(file_path, 'r') as f:
lines = f.read().strip().split("\n")
n = int(lines[0].strip()) # 节点数
s = int(lines[1].strip()) # 源点
k = int(lines[2].strip()) # 目标节点数
terminals = list(map(int, lines[3].strip().split())) # 目标节点列表
D = int(lines[4].strip()) # 延迟约束
m = int(lines[5].strip()) # 边数
graph = defaultdict(list)
for i in range(6, 6 + m):
a, b, c, d = map(int, lines[i].strip().split())
graph[a].append((b, c, d)) # 存储 a -> b 的边
graph[b].append((a, c, d)) # 存储 b -> a 的边(无向图)
return n, s, terminals, D, graph
def process_and_output(file_path):
graph_data = read_graph_from_file(file_path)
if not graph_data:
return
if __name__ == "__main__":
# 输入文件路径
file_path = "../sample-cases/01" # 请根据实际文件路径修改
process_and_output(file_path)
1 ChatGPT思路
ChatGPT给的思路流程
- 初始化图数据
- 构建主树
- 构建冗余树
- 验证冗余树
- 输出
这个其实就有问题了,因为先构建出主树,为了找到一颗最好的主树,就很有可能把冗余树堵死了
2 从简单的开始
我们先尝试只找一棵树,即只要拿前两个条件的分
- 单棵树: 如果是单棵树,得 5 分。
- 满足延迟约束的单棵树: 如果树满足延迟约束,则得 10 分。
很尴尬的事情发生了,ChatGPT崩了,接下的事情让deepseek来吧,我用的是浙江大学的满血版DeepSeek的“浙大先生”
实际使用还是有一些问题,就是输入框很小呀一次只能能看到一行呀,看不到我完整的输入,修改起来比较麻烦,但是是免费的就很棒,现在是2025年2月21日,希望后面能改进,感谢浙大!
deepseek给出的代码如下
满足了简单的要求能找到一颗树了,且拿到了分
import sys
import heapq
from collections import defaultdict
def read_graph_from_file():
""" 从标准输入读取图数据并解析 """
lines = sys.stdin.read().strip().split("\n")
n = int(lines[0].strip()) # 节点数
s = int(lines[1].strip()) # 源点
k = int(lines[2].strip()) # 目标节点数
terminals = list(map(int, lines[3].strip().split())) # 目标节点列表
D = int(lines[4].strip()) # 延迟约束
m = int(lines[5].strip()) # 边数
graph = defaultdict(list)
for i in range(6, 6 + m):
a, b, c, d = map(int, lines[i].strip().split())
graph[a].append((b, c, d)) # 存储 a -> b 的边
graph[b].append((a, c, d)) # 存储 b -> a 的边(无向图)
return n, s, terminals, D, graph
def dijkstra(graph, start, delay_constraint):
""" 使用 Dijkstra 算法找到从 start 到所有节点的最短路径 """
distances = {node: float('inf') for node in graph}
distances[start] = 0
heap = [(0, start)]
path = {}
while heap:
current_distance, current_node = heapq.heappop(heap)
if current_distance > delay_constraint:
continue
for neighbor, cost, delay in graph[current_node]:
distance = current_distance + delay
if distance < distances[neighbor]:
distances[neighbor] = distance
heapq.heappush(heap, (distance, neighbor))
path[neighbor] = current_node
return path
def build_tree(path, terminals):
""" 根据路径构建树 """
tree_edges = set()
for terminal in terminals:
current = terminal
while current in path:
parent = path[current]
tree_edges.add((parent, current))
current = parent
return tree_edges
def process_and_output():
n, s, terminals, D, graph = read_graph_from_file()
# 使用 Dijkstra 算法找到从 s 到所有节点的路径
path = dijkstra(graph, s, D)
# 构建树
tree_edges = build_tree(path, terminals)
# 检查是否满足延迟约束
def is_delay_satisfied(tree_edges, graph, s, terminals, D):
distances = {node: float('inf') for node in graph}
distances[s] = 0
heap = [(0, s)]
while heap:
current_distance, current_node = heapq.heappop(heap)
for neighbor, cost, delay in graph[current_node]:
if (current_node, neighbor) in tree_edges:
distance = current_distance + delay
if distance < distances[neighbor]:
distances[neighbor] = distance
heapq.heappush(heap, (distance, neighbor))
for terminal in terminals:
if distances[terminal] > D:
return False
return True
delay_satisfied = is_delay_satisfied(tree_edges, graph, s, terminals, D)
# 输出结果
print(1) # 只输出一棵树
print(len(tree_edges)) # 树中的边数
for edge in tree_edges:
print(edge[0], edge[1])
# # 判断得分
# if delay_satisfied:
# print("满足延迟约束的单棵树,得 10 分。")
# else:
# print("单棵树,得 5 分。")
if __name__ == "__main__":
process_and_output()
恭喜恭喜有分了,虽然垫底,但迈出了第一步,祝贺;
