20 changed files with 111 additions and 433 deletions
--- a/.coverage
+++ b/.coverage
--- a/.idea/.gitignore
+++ b/.idea/.gitignore
@ -1,8 +0,0 @@
 # 默认忽略的文件
 /shelf/
 /workspace.xml
 # 基于编辑器的 HTTP 客户端请求
 /httpRequests/
 # Datasource local storage ignored files
 /dataSources/
 /dataSources.local.xml
--- a/.idea/SELab1.iml
+++ b/.idea/SELab1.iml
@ -1,8 +0,0 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <module type="PYTHON_MODULE" version="4">
  <component name="NewModuleRootManager">
    <content url="file://$MODULE_DIR$" />
    <orderEntry type="jdk" jdkName="C:\Users\Gao42H\miniconda3" jdkType="Python SDK" />
    <orderEntry type="sourceFolder" forTests="false" />
  </component>
 </module>
--- a/.idea/inspectionProfiles/profiles_settings.xml
+++ b/.idea/inspectionProfiles/profiles_settings.xml
@ -1,6 +0,0 @@
 <component name="InspectionProjectProfileManager">
  <settings>
    <option name="USE_PROJECT_PROFILE" value="false" />
    <version value="1.0" />
  </settings>
 </component>
--- a/.idea/misc.xml
+++ b/.idea/misc.xml
@ -1,7 +0,0 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <project version="4">
  <component name="Black">
    <option name="sdkName" value="Python 3.12" />
  </component>
  <component name="ProjectRootManager" version="2" project-jdk-name="C:\Users\Gao42H\miniconda3" project-jdk-type="Python SDK" />
 </project>
--- a/.idea/modules.xml
+++ b/.idea/modules.xml
@ -1,8 +0,0 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <project version="4">
  <component name="ProjectModuleManager">
    <modules>
      <module fileurl="file://$PROJECT_DIR$/.idea/SELab1.iml" filepath="$PROJECT_DIR$/.idea/SELab1.iml" />
    </modules>
  </component>
 </project>
--- a/.idea/other.xml
+++ b/.idea/other.xml
@ -1,6 +0,0 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <project version="4">
  <component name="PySciProjectComponent">
    <option name="PY_INTERACTIVE_PLOTS_SUGGESTED" value="true" />
  </component>
 </project>
--- a/.idea/vcs.xml
+++ b/.idea/vcs.xml
@ -1,6 +0,0 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <project version="4">
  <component name="VcsDirectoryMappings">
    <mapping directory="" vcs="Git" />
  </component>
 </project>
--- a/.txt
+++ b/.txt
@ -1,3 +0,0 @@
 symphony
 of
 nature
--- a/1.txt
+++ b/1.txt
@ -1 +0,0 @@
 The sunlight filtered through the dense canopy, casting intricate patterns on the forest floor. Birds chirped melodiously, creating a symphony of nature finest sounds. Amidst the greenery, a small stream gurgled, its waters crystal clear and refreshing. Suddenly, a deer darted past, startling.To @ explore strange new worlds and worlds and seek strange,To seek out new life and new worlds and new civilizations?
--- a/Lab1实验报告.doc
+++ b/Lab1实验报告.doc
--- a/SEreport1.docx
+++ b/SEreport1.docx
--- a/pycache/oop.cpython-310.pyc
+++ b/pycache/oop.cpython-310.pyc
--- a/pycache/test.cpython-310.pyc
+++ b/pycache/test.cpython-310.pyc
--- a/oop.py
+++ b/oop.py
@ -1,26 +1,25 @@
 import copy
 import heapq
 import re
 import sys
 import time
 from math import isinf,inf
 import matplotlib.patches
 import networkx as nx
 import matplotlib.pyplot as plt
-from typing import Dict, Generator, List, Optional
+from typing import Dict, Generator, List, Optional, cast
 import random
 import os
 def main():
    # print("Welcome to Lab1")
    print("功能5中输入@停止功能")
    tu = None
    while True:
        i = input("请输入操作（q:退出, 0:读入文件, 1:展示图形, 2:查找桥接词, 3:生成新文本, 4:计算最短路径, 5:随机游走）：")
        if i == "q" :
-            sys.exit()
+            exit(0)
-        if i == "0":
+        if i == "0": #shengchengTu
            tu=Tu()
            file_name=input("请输入文件名称：")
@ -56,15 +55,15 @@ def main():
            print("Invalid input")
 class Tu :
    def __init__(self):
        self.dict={}
        self.graph=nx.MultiDiGraph()
-    @staticmethod
+    def read_text_file(self,filename):
    def read_text_file(filename):
        try:
-            with open(filename, 'r', encoding="utf-8") as file:
+            with open(filename, 'r') as file:
                text = file.read()
                # 用正则表达式将非字母字符替换为空格，并将换行符也替换为空格
                text = re.sub(r'[^a-zA-Z\n]+', ' ', text)
@ -77,7 +76,7 @@ class Tu:
            return []
    def generate_directed_dict(self,word_sequence):
-        graph = self.dict
+        graph = self.dict #chunfuzhi,yiqigai
        for i in range(len(word_sequence) - 1):
            current_word = word_sequence[i]
            next_word = word_sequence[i + 1]
@ -110,10 +109,9 @@ class Tu:
    def draw_directed_graph(self):
        G=self.graph
        pos = nx.spring_layout(G)
-        plt.rcParams['figure.figsize'] = (12.8, 7.2)
+
-        nx.draw_networkx(G, pos, with_labels=True, node_size=1000,
+        nx.draw_networkx(G, pos, with_labels=True, node_size=1000, node_color="skyblue",edge_color="black", font_size=10, font_weight="bold",
-                         node_color="skyblue", edge_color="black", font_size=10,
+                arrows=True, connectionstyle='arc3,rad=0.2')
                         font_weight="bold", arrows=True, connectionstyle='arc3,rad=0.2')
        edge_labels = nx.get_edge_attributes(G, 'weight')
        # 调整箭头位置
        for edge, weight in edge_labels.items():
@ -121,11 +119,9 @@ class Tu:
                dx = pos[edge[0]][0] - pos[edge[1]][0]
                dy = pos[edge[0]][1] - pos[edge[1]][1]
                plt.annotate(weight, (
-                    (pos[edge[0]][0] + pos[edge[1]][0]) / 2 + dy * 0.1,
+                (pos[edge[0]][0] + pos[edge[1]][0]) / 2 + dy * 0.1, (pos[edge[0]][1] + pos[edge[1]][1]) / 2 - dx * 0.1))
                    (pos[edge[0]][1] + pos[edge[1]][1]) / 2 - dx * 0.1))
            else: # 反向边不存在
-                plt.annotate(weight, ((pos[edge[0]][0] + pos[edge[1]][0]) / 2,
+                plt.annotate(weight, ((pos[edge[0]][0] + pos[edge[1]][0]) / 2, (pos[edge[0]][1] + pos[edge[1]][1]) / 2))
                                      (pos[edge[0]][1] + pos[edge[1]][1]) / 2))
        plt.show()
    def drawDirectedGraph(self):
@ -138,15 +134,27 @@ class Tu:
            print("No", word1, "or", word2, "in the graph!")
            return []
-        bridge_words = [
+        bridge_words = []
-            word for word in graph[word1]
+        bridge_words_origin = []
-            if word2 in graph.get(word, {})
+        for bridge_word in graph:
-        ]
+            if word1 == bridge_word:
                bridge_words = list(graph[bridge_word].keys())
                bridge_words_origin = copy.deepcopy(bridge_words)
        for wordi in bridge_words_origin:
            if graph.get(wordi) != None:
                if word2 not in graph[wordi].keys():
                    bridge_words.remove(wordi)
            else:
                bridge_words.remove(wordi)
        return bridge_words
-    @staticmethod
+    def print_bridge_words(self,bridge_words,word1,word2):
    def print_bridge_words(bridge_words, word1, word2):
        if not bridge_words:
            print("No bridge words from", word1, "to", word2, "!")
@ -161,11 +169,7 @@ class Tu:
        word1 = self.input_check(word1)
        word2 = self.input_check(word2)
        bridge_words = self.find_bridge_words(word1, word2)
        if bridge_words:
        self.print_bridge_words(bridge_words,word1,word2)
            return bridge_words
        else:
            return bridge_words
    def insert_bridge_words(self, text):
@ -198,42 +202,24 @@ class Tu:
            print("There are upper characters in your input")
        print(self.insert_bridge_words(text_re))
-    def find_shortest_path_old(self, word1, word2):
+    def find_shortest_path(self,word1, word2):
        graph=self.graph
        try:
-            shortest_path_generator = (
+            shortest_path_generator = nx.all_shortest_paths(graph, source=word1, target=word2, weight='weight')
-                nx.all_shortest_paths(graph, source=word1, target=word2, weight='weight'))
+            shortest_length = nx.shortest_path_length(graph, source=word1, target=word2, weight='weight')
-            shortest_length = (
+            return shortest_path_generator, shortest_length
-                nx.shortest_path_length(graph, source=word1, target=word2, weight='weight'))
+        except nx.NetworkXNoPath:
            return None, None
    def find_shortest_path_re(self,word1, word2):
        graph=self.graph
        try:
            shortest_path_generator = self.all_simple_paths_graph(word1, word2)
            shortest_length=self.calc_shortest_path_len(word1,word2)
            return shortest_path_generator, shortest_length
        except nx.NetworkXNoPath:
            return None, None
    def find_shortest_path(self, word1, word2):
        try:
            (shortest_path_list, shortest_length) = self.calc_shortest_path_len(word1, word2)
            return shortest_path_list, shortest_length
        except nx.NetworkXNoPath:
            return None, None
    def find_shortest_path_ex(self, word1, word2):
        try:
            shortest_path_generator = self.all_simple_paths_graph(word1, word2)
            shortest_length = self.calc_shortest_path_len(word1, word2)
            shortest_path_list = []
            for shortest_path in shortest_path_generator:
                if shortest_path.__len__() == shortest_length:
                    shortest_path_list.append(shortest_path)
            return shortest_path_list, shortest_length
        except nx.NetworkXNoPath:
            return None, None
    def draw_shortest_path(self, shortest_path_list):
        graph=self.graph
@ -241,6 +227,7 @@ class Tu:
        # !!! HUATU ROLL YANSE
        pos = nx.spring_layout(graph)
        nx.draw_networkx_nodes(graph, pos, node_size=1000, node_color="skyblue")
        nx.draw_networkx_labels(graph, pos, font_size=10, font_weight="bold")
@ -255,57 +242,39 @@ class Tu:
                #print(shortest_path)
-                if (edge in zip(shortest_path[:-1], shortest_path[1:]) or
+                if edge in zip(shortest_path[:-1], shortest_path[1:]) or edge in zip(shortest_path[1:], shortest_path[:-1]):
                        edge in zip(shortest_path[1:], shortest_path[:-1])):
-                    nx.draw_networkx_edges(graph, pos, edgelist=[edge], width=2.0, edge_color=num,
+
-                                           arrows=True, arrowstyle="->", arrowsize=30,
+
-                                           connectionstyle='arc3,rad=0.2')
+
                    nx.draw_networkx_edges(graph, pos, edgelist=[edge], width=2.0, edge_color=num, arrows=True,arrowstyle="->",arrowsize=30
                                        ,connectionstyle='arc3,rad=0.2')
                else:
-                    nx.draw_networkx_edges(graph, pos, edgelist=[edge], width=1.0,
+                    nx.draw_networkx_edges(graph, pos, edgelist=[edge], width=1.0, edge_color="black", arrows=True,arrowstyle="->",arrowsize=30
-                                           edge_color="black",
+                                       ,connectionstyle='arc3,rad=0.2')
                                           arrows=True, arrowstyle="->", arrowsize=30,
                                           connectionstyle='arc3,rad=0.2')
        plt.show()
-        time.sleep(1)
+
    def calcShortestPath(self,word1, word2):
        if word2 == "":
            word1 = self.input_check(word1)
            if word1 not in self.graph :
                print("No", word1, "or", word2, "in the graph!")
                return [], 0
            for wordtmp in self.dict :
                if wordtmp == word1 :
                    continue
                else:
-                    result=self.calc_shortest_path(word1, wordtmp)
+                    self.calc_shortest_path(word1,wordtmp)
                    if result == []:
                        print("No path exists between", word1, "and", word2)
                    else:
                        print(result)
            pass
        else:
            if word1 not in self.graph or word2 not in self.graph:
                print("No", word1, "or", word2, "in the graph!")
                return [], 0
            word1 = self.input_check(word1)
            word2 = self.input_check(word2)
-            result = self.calc_shortest_path(word1, word2)
+            self.calc_shortest_path(word1,word2)
            pass
        if result==[] :
            print("No path exists between", word1, "and", word2)
        else:
            print(result)
        result_len = 0 if result==[] or result is None else len(result[0])-1
        return result,result_len
    def calc_shortest_path_old(self, word1, word2):
-        shortest_path_generator, shortest_length = self.find_shortest_path_old(word1, word2)
+    def calc_shortest_path(self,word1, word2):
        shortest_path_generator, shortest_length = self.find_shortest_path_re(word1, word2)
        shortest_path_list=[]
        for shortest_path in shortest_path_generator:
@ -316,28 +285,8 @@ class Tu:
                shortest_path_list.append(shortest_path)
        if shortest_path_list.__len__()>0:
            self.draw_shortest_path(shortest_path_list)
            return shortest_path_list
        else:
-            return []
+            print("No path exists between", word1, "and", word2)
            #print("No path exists between", word1, "and", word2)
    def calc_shortest_path(self, word1, word2):
        shortest_path_list, shortest_length = self.find_shortest_path_ex(word1, word2)
        for shortest_path in shortest_path_list:
            if shortest_path:
                print("Shortest path:", '→'.join(shortest_path))
                print("Length of shortest path:", shortest_length)
        if shortest_path_list.__len__() > 0:
            self.draw_shortest_path(shortest_path_list)
            return shortest_path_list
        else:
            return []
            #print("No path exists between", word1, "and", word2)
    def random_traversal(self):
@ -345,6 +294,7 @@ class Tu:
        filename = input("Enter the filename to save traversal results: ")
        filename+=".txt"
        graph=copy.deepcopy(self.dict)
        start_node = random.choice(list(graph.keys()))
        visited_nodes = set()
@ -359,7 +309,7 @@ class Tu:
                if input()=="@":
                    file.close()
                    break
-                if graph.get(current_node) is not None:
+                if graph.get(current_node) != None:
                    pass
                else:
                    break
@ -379,10 +329,11 @@ class Tu:
    def randomWalk(self):
        self.random_traversal()
-    @staticmethod
+
-    def input_check(input_word):
+    def input_check(self, input_word):
        (input_word_re,input_word_ren)=re.subn(r'[^a-zA-Z\n]', ' ', input_word)
        if input_word_ren>0 :
            print("There are illegal signs in your input,the amount is "+str(input_word_ren))
@ -394,6 +345,7 @@ class Tu:
        return tmp[0]
    def all_simple_paths_graph(self, source: str, targets: str) -> Generator[List[str], None, None]:
        G = self.graph
        cutoff = len(G) - 1  # 设置路径的最大深度，防止无限循环。
@ -422,15 +374,13 @@ class Tu:
                stack.pop()
                visited.popitem()
-    def calc_shortest_path_len(self, word1: str, word2: str) -> int:
+    def calc_shortest_path_len(self, word1: str, word2: str) -> str:
        if word1 not in self.graph.nodes or word2 not in self.graph.nodes:
-            return 0
+            return ""
-        distances = {node: inf for node in self.graph.nodes}
+        distances = {node: inf for node in self.graph.nodes}  # 存储word1到所有结点的距离，初始化为无穷大
-        # 存储word1到所有结点的距离，初始化为无穷大
+        previous_nodes: Dict[str, Optional[str]] = {node: None for node in self.graph.nodes}  # 存储每个节点最短路径中的前一个节点，初始化为None
        previous_nodes: Dict[str, Optional[str]] = {node: None for node in
                                                    self.graph.nodes}  # 存储每个节点最短路径中的前一个节点，初始化为None
        distances[word1] = 0  # 距离初始化为0
        priority_queue = [(0, word1)]  # 优先级队列，用于按照从小到大获取节点
@ -462,9 +412,9 @@ class Tu:
            path.insert(0, current_node)
        if isinf(distances[word2]):  # 目标节点不可达
-            return 0
+            return ""
        return path.__len__()
-        # return (' '.join(path),path.__len__())
+        return ' '.join(path)
 if __name__ == '__main__':
--- a/t1.txt
+++ b/t1.txt
@ -1,3 +0,0 @@
 small
 stream
 gurgled
--- a/t2.txt
+++ b/t2.txt
@ -1,28 +0,0 @@
 melodiously
 creating
 a
 small
 stream
 gurgled
 its
 waters
 crystal
 clear
 and
 refreshing
 suddenly
 a
 deer
 darted
 past
 startling
 to
 seek
 out
 new
 worlds
 and
 new
 life
 and
 worlds
--- a/t3.txt
+++ b/t3.txt
@ -1,34 +0,0 @@
 and
 seek
 out
 new
 life
 and
 refreshing
 suddenly
 a
 symphony
 of
 nature
 finest
 sounds
 amidst
 the
 forest
 floor
 birds
 chirped
 melodiously
 creating
 a
 deer
 darted
 past
 startling
 to
 explore
 strange
 new
 worlds
 and
 worlds
--- a/t4.txt
+++ b/t4.txt
@ -1,24 +0,0 @@
 nature
 finest
 sounds
 amidst
 the
 greenery
 a
 deer
 darted
 past
 startling
 to
 seek
 strange
 new
 life
 and
 seek
 out
 new
 worlds
 and
 new
 civilizations
--- a/test.py
+++ b/test.py
@ -1,130 +0,0 @@
 import unittest
 from oop import Tu
 class TextProcessor(Tu):
    def __init__(self):
        super().__init__()
 class TestQueryBridgeWords(unittest.TestCase):
    def setUp(self):
            # Initialize a graph for testing
        self.graph = {
                'a': {'b': 1, 'c': 2},
                'b': {'c': 1, 'd': 2},
                'c': {'d': 1},
                'x': {},
                'z': {}
        }
        self.processor = TextProcessor()
        self.processor.generate_directed_dict(self.processor.read_text_file("1.txt"))
        self.processor.generate_directed_graph()
    def test_normal_path1(self):
        # 正常情况：存在路径
        word1 = 'to'
        word2 = 'out'
        expected_path = ['to', 'seek', 'out']
        expected_length = 2
        path,length = self.processor.calcShortestPath(word1, word2)
        self.assertEqual(path, [expected_path])
        self.assertEqual(length, expected_length)
    """def test_normal_path2(self):
        # 正常情况：存在路径
        word1 = 'to'
        word2 = 'new'
        expected_path = ['to', 'seek', 'out',"new"],['to', 'seek', "strange",'new'],['to', 'explore', "strange",'new']
        expected_length = 3
        path, length = self.processor.calcShortestPath(word1, word2)
        path_set=set([])
        for i in path :
            path_set.add(i)
        self.assertSetEqual(path_set, set(expected_path))
        self.assertEqual(length, expected_length)"""
    def test_no_path(self):
        # 无路径情况
        word1 = 'civilizations'
        word2 = 'to'
        expected_path = []
        expected_length = 0
        path, length = self.processor.calcShortestPath(word1, word2)
        self.assertEqual(path, expected_path)
        self.assertEqual(length, expected_length)
    def test_node_not_exists(self):
        # 节点不存在情况
        word1 = 'now'
        word2 = 'lod'
        expected_path = []
        expected_length = 0
        path, length = self.processor.calcShortestPath(word1, word2)
        self.assertEqual(path, expected_path)
        self.assertEqual(length, expected_length)
    def test_same_node(self):
        # 同一节点情况
        word1 = 'to'
        word2 = 'to'
        expected_path = []
        expected_length = 0
        path, length = self.processor.calcShortestPath(word1, word2)
        self.assertEqual(path, expected_path)
        self.assertEqual(length, expected_length)
    def test_valid_bridge_words_exist(self):
        # Valid equivalence class: bridge words exist
        result = self.processor.queryBridgeWords('the', 'floor')
        self.assertIn('forest', result)
    def test_valid_bridge_words_not_exist(self):
        # Valid equivalence class: no bridge words
        result = self.processor.queryBridgeWords('on', 'the')
        self.assertEqual(result, [])
    def test_invalid_word1_not_in_graph(self):
        # Invalid equivalence class: word1 not in graph
        result = self.processor.queryBridgeWords('an', 'a')
        self.assertEqual(result, [])
    def test_invalid_word2_not_in_graph(self):
        # Invalid equivalence class: word2 not in graph
        result = self.processor.queryBridgeWords('a', 'an')
        self.assertEqual(result, [])
    def test_invalid_both_words_not_in_graph(self):
        # Invalid equivalence class: both words not in graph
        result = self.processor.queryBridgeWords('now', 'lod')
        self.assertEqual(result, [])
    def test_edge_case_min_word(self):
        # Edge case: minimum word
        result = self.processor.queryBridgeWords('a', 'b')
        self.assertEqual(result, [])
    def test_edge_case_max_word(self):
        # Edge case: maximum word
        result = self.processor.queryBridgeWords('x', 'z')
        self.assertEqual(result, [])
    def test_edge_case_no_bridge_words(self):
        # Edge case: no bridge words
        result = self.processor.queryBridgeWords('new', 'worlds')
        self.assertEqual(result, [])
    def test_edge_case_single_bridge_word(self):
        # Edge case: single bridge word
        result = self.processor.queryBridgeWords('the', 'floor')
        self.assertIn('forest', result)
 if __name__ == '__main__':
    unittest.main()
		`@ -1 +0,0 @@`
			`The sunlight filtered through the dense canopy, casting intricate patterns on the forest floor. Birds chirped melodiously, creating a symphony of nature finest sounds. Amidst the greenery, a small stream gurgled, its waters crystal clear and refreshing. Suddenly, a deer darted past, startling.To @ explore strange new worlds and worlds and seek strange,To seek out new life and new worlds and new civilizations?`