def SelectFinalRoutes(candidatewaypath, savefinalroutespath):
"""
本函数与SelectFinalRoute功能相同,只是本函数处理完整的轨迹时,如果大于50.会重新开始计算最大连通性
根据坐标点的候选路段选出路网的匹配路线
保存格式为:车辆名:路线(如果不确定,可能为多条),车辆名为txt文件名
:param candidatewaypath: 坐标点候选路段的txt文件路径,如H:\\CandidateWay\\NewStrategy\\334e4763-f125-425f-ae42-8028245764fe.txt
:param savefinalroutespath: 最终路线保存路径
:return:
"""
#file = open("H:\GPS_Data\Road_Network\BYQBridge\FinalRoutes\\334e4763-f125-425f-ae42-8028245764fe.txt", 'a')
max_connect = 0 #记录计算最大连通的轨迹点数
(tempath, tempfilename) = os.path.split(
candidatewaypath) # tempfilename为txt文件名(包含后缀)
(trunkname, extension) = os.path.splitext(
tempfilename) # filename 为传入的csv文件名 extension为后缀
savetxtfilename = trunkname + '.txt'
Resetflag = 0 #标记最终路段是否重新开始计算
file = open(os.path.join(savefinalroutespath, savetxtfilename), 'a')
with open(candidatewaypath) as candidatewayfile:
filelines = candidatewayfile.readlines()
linesnum = len(filelines)
finalline = [] #存储最终路线,可能为多条,随着坐标点的迭代,会变化,直到处理完最有一个坐标点
for key in eval(filelines[0].strip('\n').split(">>>")[-1]).keys():
finalline.append([key])
#print(finalline)
# 遍历每个坐标点的候选路段
print("需要处理坐标数为:{}".format(linesnum))
for lineindex in range(1, linesnum):
print(f"正在处理第{lineindex+1}个坐标")
if filelines[lineindex].strip('\n').split(
">>>")[-1] == "BreakPoint": #轨迹分段,分开计算
file.write("New_Road\n")
for sub in finalline:
file.write(str(sub) + "\n")
file.flush()
Resetflag = 1 #标记从下一个点要重新开始匹配轨迹了
max_connect = 0
continue
if max_connect == 100:
file.write("New_Road\n")
for sub in finalline:
file.write(str(sub) + "\n")
file.flush()
Resetflag = 1 #标记从下一个点要重新开始匹配轨迹了
max_connect = 0
continue
if Resetflag == 1:
finalline.clear()
for key in eval(filelines[lineindex].strip('\n').split(">>>")
[-1]).keys():
finalline.append([key])
Resetflag = 0
continue
templine = [] #存储临时路线
#print("处理坐标{}:{}".format(lineindex,eval(filelines[lineindex].strip('\n').split(">>>")[-1])))
#print("处理路段{}".format(eval(filelines[lineindex].strip('\n').split(">>>")[-1])))
connect_next_flag = 0 #记录下一步是否能有能走通的路段
for subline in finalline: #遍历每一条的候选路线
for key in eval(filelines[lineindex].strip('\n').split(">>>")
[-1]).keys(): #遍历每个轨迹点的候选路段
#此代码块只加入key,不加入完整路线
print("路段:{}匹配key:{}".format(subline[-1], key))
# 只需要查看subline的最后一个路段与路段key是否连通即可,因为subline的连通性是通过测试的
connectroute = Common_Functions.InquireConn(
subline[-1], key, "connects") #先查表
#connectroute = -1
if connectroute != 0 and connectroute != 1: #表中没有记录 再用简易导航
connectroute = MapNavigation.waytoway(
subline[-1], key) # 为列表
if connectroute:
connect_next_flag = 1
temsubline = copy.deepcopy(subline)
temsubline.append(key) # 只加入轨迹点所属路段,而不加入这两个路段走通的路线
templine.append(temsubline)
else:
# 此路线不连通,舍弃当前路段key
pass
"""
#此代码块是加入完整路线
#connectroute = Common_Functions.InquireConn(subline[-1], key,"connects") #先查表
#connectroute = -1
connectroute = MapNavigation.Nodirectionwaytoway(subline[-1], key) # 为列表
if subline[-1] == key:
temsubline = copy.deepcopy(subline)
templine.append(temsubline)
#elif connectroute !=0 and connectroute!= 1: #表中没有记录 再用简易导航
#connectroute = MapNavigation.Nodirectionwaytoway(subline[-1], key) # 为列表
elif connectroute:
#路段可连通
temsubline = copy.deepcopy(subline)
temsubline.extend(connectroute[1:]) #将走通的路线加入到子路线,扩展当前路线
templine.append(temsubline)
else:pass
"""
if connect_next_flag == 0: #所有的候选路线与当前轨迹点的候选路段均不能相通,跳过此轨迹点
pass
else:
finalline.clear()
# print(templine)
finalline = Common_Functions.DoubleDel(templine) # 去相邻重复 再去重
finalline = Common_Functions.Main_Auxiliary_road(
finalline) # 去除头尾路段一样的候选路线,路线只有一个路段 不会处理
# print(finalline)
#finalline = Common_Functions.Start_End(finalline) # 对于[wayid1,wayid2,wayid3] [wayid1,wayid4,wayid5,wayid3] 去除路段多的,如果包含路段数量一致 暂不处理
finalline = Common_Functions.Sequential_subset(
finalline) # 最后去路线(至少两个及以上的其他路线是其前缀)
max_connect += 1
file.write("New_Road\n")
for sub in finalline:
file.write(str(sub) + "\n")
file.flush()
file.close()
def SelectFinalRoutes(candidatewaypath, savefinalroutespath):
"""
本函数与SelectFinalRoute功能相同,只是本函数处理完整的轨迹时,如果大于50.会重新开始计算最大连通性
根据坐标点的候选路段选出路网的匹配路线
保存格式为:车辆名:路线(如果不确定,可能为多条),车辆名为txt文件名
:param candidatewaypath: 坐标点候选路段的txt文件路径,如H:\\CandidateWay\\NewStrategy\\334e4763-f125-425f-ae42-8028245764fe.txt
:param savefinalroutespath: 最终路线保存路径
:return:
"""
#file = open("H:\GPS_Data\Road_Network\BYQBridge\FinalRoutes\\334e4763-f125-425f-ae42-8028245764fe.txt", 'a')
max_connect = 0
(tempath, tempfilename) = os.path.split(
candidatewaypath) # tempfilename为txt文件名(包含后缀)
(trunkname, extension) = os.path.splitext(
tempfilename) # filename 为传入的csv文件名 extension为后缀
savetxtfilename = trunkname + '.txt'
file = open(os.path.join(savefinalroutespath, savetxtfilename), 'a')
with open(candidatewaypath) as candidatewayfile:
filelines = candidatewayfile.readlines()
linesnum = len(filelines)
finalline = [] #存储最终路线,可能为多条,随着坐标点的迭代,会变化,直到处理完最有一个坐标点
for key in eval(filelines[0].strip('\n').split(">>>")[-1]).keys():
finalline.append([key])
predict = eval(filelines[0].strip('\n').split(">>>")[-1])
# 遍历每个坐标点的候选路段
print(f"需要处理坐标数为:{linesnum}")
for lineindex in range(1, linesnum):
templine = [] #存储临时路线
curdict = eval(filelines[lineindex].strip('\n').split(">>>")[-1])
flag = 0 #标记之前的路线与当前轨迹点的所有候选路段是否能连通,不能连通,舍弃该轨迹点
newdic = {}
for subline in finalline: #遍历每一条的候选路线
#print(f"ID{lineindex-1}:{predict},{curdict}")
for key in curdict.keys(): #遍历每个轨迹点的候选路段
connectroute = Common_Functions.InquireConn(
subline[-1], key, "connects") #先查表
if connectroute != 0:
#print(subline[-1], predict[subline[-1]], key, curdict[key])
connectroute = GridMapNavigation.CandidateWay_Connect(
subline[-1], predict[subline[-1]], key,
curdict[key]) # 双重列表
#print(f"next:{connectroute}")
if connectroute:
flag = 1
for line in connectroute:
temsubline = copy.deepcopy(subline)
temsubline.extend(line) # 将走通的路线加入到子路线,扩展当前路线
templine.append(temsubline)
#newdic[line[-1]] = curdict[line[-1]]
else:
pass
else:
pass
if flag == 1:
finalline.clear()
predict = curdict
templine = Common_Functions.DoubleDel(templine)
templine = Common_Functions.Main_Auxiliary_road(
templine) #去除头尾路段一样的候选路线,路线只有一个路段 不会处理
templine = Common_Functions.Start_End(
templine
) # 对于[wayid1,wayid2,wayid3] [wayid1,wayid4,wayid5,wayid3] 去除路段多的,如果包含路段数量一致 暂不处理
Common_Functions.Sequential_subset(
finalline) # 最后去路线(至少两个及以上的其他路线是其前缀)
for sub in templine:
finalline.append(Common_Functions.del_adjacent(sub))
else:
pass
#print(f"final:{finalline}")
print("共选出{}条路".format(len(finalline)))
for sub in finalline:
print(sub)
file.write(str(sub) + "\n")
file.close()
def Nodirectionwaytoway(way_id1,way_id2,max_sum=8):
"""
无方向 有交点就会认为通行
:param way_id1:
:param way_id2:
:param max_sum:
:return:
"""
if way_id1 == way_id2:
return [way_id1,way_id2]
finalroute = []
node_id = TwoWay_intersection(way_id1, way_id2) #两条路段交点
if node_id:
if JudgeTwoWay(way_id1,way_id2):
finalroute.extend([way_id1, way_id2])
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 1)
return finalroute
else:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
else:
#两条路段没有直接交点
Candidate_Routes = [[way_id1]] # 候选路线
flag = 0
count = 0 #迭代多少次之后仍然没有找到可行路线,则认为不可走
exitflag = 0 #标记是否是通过找到满足条件的路线而退出的
grid1 = Getway_startendnode_grid(way_id1,flag=0)
startx = grid1[0]
starty = grid1[1]
grid2 = Getway_startendnode_grid(way_id1, flag=0)
Endx = grid2[0]
Endy = grid2[1]
while True:
temCandidate_Routes = [] # 存储当前这一轮新的候选路线
AllNextways = []
MaxDel = [] #存因路段数目大于阈值,而筛除的路线
for sub in Candidate_Routes:
if way_id2 in sub:
flag = 1
break
if len(sub) > max_sum: #防止寻找时间过长,如果目的是为了查找路线,可将此条件删除
MaxDel.append(sub)
for sub in MaxDel:
Candidate_Routes.remove(sub)
if len(Candidate_Routes)==0:
flag = 1
exitflag = 1
if count==8:
flag=1
exitflag = 1
if flag == 1:
break
for subroute in Candidate_Routes:
# subroute 表示正在处理的路线
preways = subroute #表示当前路线已有的路段
processingway = subroute[-1] # 表示要处理的路段
nextway = NodirectionFindNextWay(processingway,preways) # 下一步的可选路段
if len(nextway)==0:
#当前路线下一步没有能走的路
pass
else:
AllNextways.extend(nextway)
for next in nextway:
temroute = copy.deepcopy(subroute)
temroute.append(next)
temCandidate_Routes.append(temroute)
count += 1
Candidate_Routes.clear()
Candidate_Routes = temCandidate_Routes
Candidate_Routes = Common_Functions.Double_layer_list(Candidate_Routes)
Candidate_Routes = Common_Functions.Main_Auxiliary_road(Candidate_Routes) # 去除头尾路段一样的候选路线
Candidate_Routes = Common_Functions.Start_End(Candidate_Routes) # 对于[wayid1,wayid2,wayid3] [wayid1,wayid4,wayid5,wayid3] 去除路段多的,如果包含路段数量一致 暂不处理
Candidate_Routes = Common_Functions.Sequential_subset(Candidate_Routes) # 最后去前缀
#print(len(Candidate_Routes))
delsub = []
for sub in Candidate_Routes:
#判断行驶方向
secondgrid = Getway_startendnode_grid(sub[-1], flag=0)
if secondgrid:
curx = secondgrid[0]
cury = secondgrid[1]
if Endx > startx and Endy>starty: #路段way_id2 在way_id1 的右上部
if curx < startx and cury < starty:
delsub.append(sub) #此路线方向向左下部走 删除此路线
if Endx > startx and Endy < starty: # 路段way_id2 在way_id1 的右下部
if curx < startx and cury > starty:
delsub.append(sub) # 此路线方向向左上部走 删除此路线
if Endx <startx and Endy < starty: # 路段way_id2 在way_id1 的左下部
if curx > startx and cury > starty:
delsub.append(sub) # 此路线方向向右上部走 删除此路线
if Endx < startx and Endy > starty: # 路段way_id2 在way_id1 的左上部
if curx > startx and cury < starty:
delsub.append(sub) # 此路线方向向右上部走 删除此路线
else:
delsub.append(sub)
for sub in Common_Functions.Double_layer_list(delsub):
Candidate_Routes.remove(sub)
#print(len(Candidate_Routes))
if len(AllNextways)==0:
#所有的候选路线都没有下一步路可走
flag=1
exitflag = 1
minnum = float("inf")
if exitflag==1:
#证明是循环跳出不是因为找到路径跳出的
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
Deleteways = []
#print(Candidate_Routes)
for sub in Candidate_Routes:
#由于以上为没有方向的判断,所以在此循环中要加入方向的判断
if way_id2 in sub:
if len(sub)==1:
return sub
elif len(sub)==2 and JudgeTwoWay(sub[0],sub[1]):
pass
elif len(sub) >= 3 and JudgeLines(sub):
pass
else:
Deleteways.append(sub)
else:
Deleteways.append(sub)
if len(Deleteways)!=0:
for delsub in Common_Functions.Double_layer_list(Deleteways):
Candidate_Routes.remove(delsub)
if len(Candidate_Routes)==0:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
for sub in Candidate_Routes:
if way_id2 in sub:
if len(sub) < minnum:
finalroute = sub
minnum = len(sub)
else:
pass
if len(finalroute)==0:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2,0)
return False
else:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 1)
return finalroute
def SelectFinalRoute(candidatewaypath, savefinalroutespath):
"""
根据坐标点的候选路段选出路网的匹配路线
保存格式为:车辆名:路线(如果不确定,可能为多条),车辆名为txt文件名
:param candidatewaypath: 坐标点候选路段的txt文件路径,如H:\\CandidateWay\\NewStrategy\\334e4763-f125-425f-ae42-8028245764fe.txt
:param savefinalroutespath: 最终路线保存路径
:return:
"""
#file = open("H:\GPS_Data\Road_Network\BYQBridge\FinalRoutes\\334e4763-f125-425f-ae42-8028245764fe.txt", 'a')
(tempath, tempfilename) = os.path.split(
candidatewaypath) # tempfilename为txt文件名(包含后缀)
(trunkname, extension) = os.path.splitext(
tempfilename) # filename 为传入的csv文件名 extension为后缀
savetxtfilename = trunkname + '.txt'
file = open(os.path.join(savefinalroutespath, savetxtfilename), 'a')
with open(candidatewaypath) as candidatewayfile:
filelines = candidatewayfile.readlines()
linesnum = len(filelines)
finalline = [] #存储最终路线,可能为多条,随着坐标点的迭代,会变化,直到处理完最有一个坐标点
for key in eval(filelines[0].strip('\n').split(">>>")[-1]).keys():
finalline.append([key])
#print(finalline)
# 遍历每个坐标点的候选路段
print("需要处理坐标数为:{}".format(linesnum))
for lineindex in range(1, linesnum):
templine = [] #存储临时路线
# 遍历到最后一行
print(len(finalline))
print(finalline)
print("处理坐标{}:{}".format(
lineindex,
eval(filelines[lineindex].strip('\n').split(">>>")[-1])))
#print("处理路段{}".format(eval(filelines[lineindex].strip('\n').split(">>>")[-1])))
for subline in finalline:
for key in eval(filelines[lineindex].strip('\n').split(">>>")
[-1]).keys():
temsubline = []
#此代码块只加入key,不加入完整路线
print("路段:{}匹配key:{}".format(subline[-1], key))
# 只需要查看subline的最后一个路段与路段key是否连通即可,因为subline的连通性是通过测试的
connectroute = Common_Functions.InquireConn(
subline[-1], key, "connects") #先查表
#connectroute = -1
if connectroute != 0 and connectroute != 1: #表中没有记录 再用简易导航
connectroute = MapNavigation.waytoway(
subline[-1], key) # 为列表
if connectroute:
temsubline = copy.deepcopy(subline)
temsubline.append(key) # 只加入轨迹点所属路段,而不加入这两个路段走通的路线
templine.append(temsubline)
else:
# 此路线不连通,舍弃当前路段key
pass
"""
#此代码块是加入完整路线
#connectroute = Common_Functions.InquireConn(subline[-1], key,"connects") #先查表
#connectroute = -1
connectroute = MapNavigation.Nodirectionwaytoway(subline[-1], key) # 为列表
if subline[-1] == key:
temsubline = copy.deepcopy(subline)
templine.append(temsubline)
#elif connectroute !=0 and connectroute!= 1: #表中没有记录 再用简易导航
#connectroute = MapNavigation.Nodirectionwaytoway(subline[-1], key) # 为列表
elif connectroute:
#路段可连通
temsubline = copy.deepcopy(subline)
temsubline.extend(connectroute[1:]) #将走通的路线加入到子路线,扩展当前路线
templine.append(temsubline)
else:pass
"""
# print(temsubline)
# print(templine)
finalline.clear()
#print(templine)
finalline = Common_Functions.DoubleDel(templine) #去相邻重复 再去重
finalline = Common_Functions.Main_Auxiliary_road(
finalline) #去除头尾路段一样的候选路线,路线只有一个路段 不会处理
#print(finalline)
finalline = Common_Functions.Start_End(
finalline
) # 对于[wayid1,wayid2,wayid3] [wayid1,wayid4,wayid5,wayid3] 去除路段多的,如果包含路段数量一致 暂不处理
finalline = Common_Functions.Sequential_subset(
finalline) # 最后去路线(至少两个及以上的其他路线是其前缀)
print("共选出{}条路".format(len(finalline)))
for sub in finalline:
file.write(str(sub) + "\n")
file.flush()
print(finalline)
file.close()
def waytoway(way_id1,way_id2,max_num=8):
"""
实现从way_id1到way_id2的路线规划,当此函数完全用作简易导航,可设置max_num为无穷
设置 max_num 与Count 的原因为防止查找完全不通的两个路段而耗费过长的时间
有方向通行
问题:即使很近的两个路段(实际短距离不能通行),但是会花费较多的时间去判断是否能通行
47574526,403874395两个路段不能互通 但是只在北野场桥一部分就花费了5分钟去判断可行性
:param way_id1:
:param way_id2:
:return:
首先判断两个路段是否有交集,有交集则这两条路不需要经过其他路线的连接
"""
if way_id1 == way_id2:
return [way_id1,way_id2]
finalroute = []
node_id = TwoWay_intersection(way_id1, way_id2) #两条路段交点
if node_id:
if JudgeTwoWay(way_id1,way_id2):
finalroute.extend([way_id1, way_id2])
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 1)
return finalroute
else:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
else:
#两条路段没有直接交点
Candidate_Routes = [[way_id1]] # 候选路线
flag = 0
count = 0 # 迭代多少次之后仍然没有找到可行路线,则认为不可走
exitflag = 0 #标记是否是通过找到满足条件的路线而退出的
grid1 = Getway_startendnode_grid(way_id1, flag=0)
startx = grid1[0]
starty = grid1[1]
grid2 = Getway_startendnode_grid(way_id1, flag=0)
Endx = grid2[0]
Endy = grid2[1]
startendwaydis = twoway_distance(way_id1, way_id2)+ 0.01 # 加1000米弹性范围,0.0003为30米
while True:
print(Candidate_Routes)
temCandidate_Routes = [] # 存储当前这一轮新的候选路线
AllNextways = []
print(count)
for subroute in Candidate_Routes:
# subroute 表示正在处理的路线
processingway = subroute[-1] # 表示要处理的路段
wayflag,nextway = FindNextWay(processingway,subroute,way_id2) # 下一步的可选路段
#wayflag为FALSE 标记wayid2在nextway,但是由于方向问题,被删除,所以直接判定为不通
if not wayflag:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
if len(nextway) == 0:
# 当前路线下一步没有能走的路
pass
else:
AllNextways.extend(nextway)
for next in nextway:
temroute = copy.deepcopy(subroute)
temroute.append(next)
temCandidate_Routes.append(temroute)
if len(AllNextways)==0:
#所有的候选路线都没有下一步路可走
flag=1
exitflag = 1
count += 1
Candidate_Routes.clear()
Candidate_Routes = temCandidate_Routes
Candidate_Routes = Common_Functions.Double_layer_list(Candidate_Routes)
Candidate_Routes = Common_Functions.Main_Auxiliary_road(Candidate_Routes) # 去除头尾路段一样的候选路线
Candidate_Routes = Common_Functions.Start_End(Candidate_Routes) # 对于[wayid1,wayid2,wayid3] [wayid1,wayid4,wayid5,wayid3] 去除路段多的,如果包含路段数量一致 暂不处理
Candidate_Routes = Common_Functions.Sequential_subset(Candidate_Routes) # 最后去前缀
delsub = []
for sub in Candidate_Routes:
if way_id2 in sub:
flag = 1
break
if len(Candidate_Routes) == 0:
flag = 1
exitflag = 1
if count == max_num:
flag = 1
exitflag = 1
if flag == 1:
break
for sub in Candidate_Routes:
if len(sub) >= 3:
if JudgeLines(sub): # 判断当前路线是否能通
for i in combinations(sub,2):
Common_Functions.SaveRoutesConn("connects", i[0],i[1], 1)
elif not JudgeLines(sub) and way_id2 in sub: # 目标路段在子路线中 但是不能走通
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
else:
delsub.append(sub)
continue
elif len(sub) == 2:
if JudgeTwoWay(sub[0], sub[1]):
Common_Functions.SaveRoutesConn("connects", sub[0], sub[1], 1)
pass
elif JudgeTwoWay(sub[0], sub[1]) and way_id2 in sub: # 目标路段在子路线中 但是不能走通
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
else:
delsub.append(sub)
continue
else:
pass
for sub in Candidate_Routes:
# 判断行驶方向
secondgrid = Getway_startendnode_grid(sub[-1], flag=0)
if secondgrid:
curx = secondgrid[0]
cury = secondgrid[1]
if Endx > startx and Endy > starty: # 路段way_id2 在way_id1 的右上部
if abs(startx - curx) <= 5 or abs(starty - cury) <= 5: # 防止道路过近,出现偏差,方向加500米偏差
pass
elif curx <= startx and cury <= starty:
delsub.append(sub) # 此路线方向向左下部走 删除此路线
if Endx > startx and Endy < starty: # 路段way_id2 在way_id1 的右下部
if abs(startx - curx) <= 5 or abs(starty - cury) <= 5: # 防止道路过近,出现偏差,方向加500米偏差
pass
elif curx < startx and cury > starty:
delsub.append(sub) # 此路线方向向左上部走 删除此路线
if Endx < startx and Endy < starty: # 路段way_id2 在way_id1 的左下部
if abs(startx - curx) <= 5 or abs(starty - cury) <= 5: # 防止道路过近,出现偏差,方向加500米偏差
pass
elif curx > startx and cury > starty:
delsub.append(sub) # 此路线方向向右上部走 删除此路线
if Endx < startx and Endy > starty: # 路段way_id2 在way_id1 的左上部
if abs(startx - curx) <= 5 or abs(starty - cury) <= 5: # 防止道路过近,出现偏差,方向加500米偏差
pass
elif curx > startx and cury < starty:
delsub.append(sub) # 此路线方向向右上部走 删除此路线
else:
pass
temstaryendwaydis = twoway_distance(way_id1, sub[-1])
if temstaryendwaydis > startendwaydis:
delsub.append(sub)
for sub in Common_Functions.Double_layer_list(delsub):
Candidate_Routes.remove(sub)
if exitflag==1:
#证明是循环跳出不是因为找到路径跳出的
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
Deleteways = []
for sub in Candidate_Routes:
if way_id2 in sub:
if len(sub) == 1:
return sub
elif len(sub) == 2 and JudgeTwoWay(sub[0], sub[1]):
pass
elif len(sub) >= 3 and JudgeLines(sub):
for i in combinations(sub, 2):
Common_Functions.SaveRoutesConn("connects", i[0], i[1], 1)
pass
else:
Deleteways.append(sub)
else:
Deleteways.append(sub)
if len(Deleteways)!=0:
for delsub in Common_Functions.Double_layer_list(Deleteways):
Candidate_Routes.remove(delsub)
if len(Candidate_Routes)==0:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
minnum = float("inf")
for sub in Candidate_Routes:
if way_id2 in sub:
if len(sub) < minnum:
finalroute = sub
minnum = len(sub)
else:
pass
if len(finalroute)==0:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 0)
return False
else:
Common_Functions.SaveRoutesConn("connects", way_id1, way_id2, 1)
return finalroute