# Google OR-Tools TSP spanning multiple days with start/stop times

I am using Google OR-Tools to optimize the routing of a single vehicle over the span of a several day.

I am trying to:

• Be able to specify the number of days over which to optimize routing.
• Be able to specify the start location and end location for each day.
• Be able to specify the start time and end time for each day.

I have a set of 40 locations. For each day I want to include in my range of days for optimization, I prepend the start and end location to the matrix. So if I want to optimize for one day, I would have a total of 42 locations in my matrix. If I want to optimize for two days, I would have a total of 44 locations in my matrix. And so on. The pattern would like like this:

``````1 Day:
Matrix = [[start day 1], [end day 1], [location], [location], ... ]

2 Days:
Matrix = [[start day 1], [end day 1], [start day 2], [end day 2], [location], [location], ... ]

3 Days:
Matrix = [[start day 1], [end day 1], [start day 2], [end day 2], [start day 3], [end day 3], [location], [location], ... ]
``````

I want to allow locations to be dropped in order to achieve a feasible solution, as well as only allow locations to be visited during their specified time windows, both of which I believe I have successfully implemented.

My current implementation is available here, as well as on GitHub.

I warmly welcome any suggestions, guidance, or support. Thank you!

Source: (Seeded with data for a two-day solution)

``````from ortools.constraint_solver import pywrapcp
from ortools.constraint_solver import routing_enums_pb2

Matrix = 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0.5,943.5,657.6,927.4,1052.6,851.7,832.1,1035.4,1220.7,1169.1,591.6,586.3,829,1015.4,1185.9,1001.2,643.8,0,238.5,765.7,1773.3,1955.3,220.9,1377.1,1743.4,1500.4],[492.4,1695,348.7,492.4,1946,1585.3,1894.8,1999.7,1313.4,1720.6,1735.8,1702.6,1254.1,1324.1,1088.1,1295.7,716.9,931.6,697.8,1040,754.1,1023.9,1142,918.1,990.9,1194.2,1379.5,1265.6,688.1,732.7,827.2,1174.2,1344.7,1147.6,790.2,227.3,0,855.1,1862.7,2044.7,241.1,1237.1,1647.7,1355.3],[614.6,2143.9,845.8,614.6,2002.1,1697.4,1719.6,1598,944.8,1881.7,1896.9,1863.7,1366.2,1485.2,1249.2,1456.8,863.6,1043.7,713.4,680.8,484.2,584.9,551.3,310.8,1152,1355.3,1540.6,863.9,436,1174.1,1406.6,1335.3,1505.8,1589,1231.6,725.5,828.2,0,1334.4,1516.4,669.4,900.9,1304.5,1161],[1677.7,2333.7,1908.9,1677.7,2805.5,2497.2,2501.6,1345.9,1713,2723.2,2960,2926.8,2137.9,2433.2,2256.2,2490.1,1926.7,2106.8,1837.2,1717.5,1626.1,1481.4,945.3,1182.9,2215.1,2418.4,2603.7,1191.6,1559.8,2209.4,1673.1,2398.4,2568.9,2297.3,2125.9,1788.6,1891.3,1315.1,0,630,1732.5,874,604.7,1053.3],[1884,2890.3,2115.2,1884,3030.5,2722.2,2726.6,1570.9,1938,2948.2,3166.3,3133.1,2362.9,2658.2,2481.2,2715.1,2133,2313.1,2043.5,1923.8,1832.4,1687.7,1151.6,1389.2,2421.4,2624.7,2810,1397.9,1766.1,2443.5,2156,2604.7,2775.2,2753.2,2501,1994.9,2097.6,1521.4,732.6,0,1938.8,1430.6,1161.3,1609.9],[310.5,1654.5,356.4,310.5,1718.8,1358.1,1667.6,1834.8,1086.2,1493.4,1508.6,1475.4,1026.9,1096.9,860.9,1068.5,489.7,704.4,538.1,875.1,589.2,859,984.2,783.3,763.7,967,1152.3,1100.7,523.2,684.7,901.1,947,1117.5,1099.6,742.2,195,244.2,697.3,1704.9,1886.9,0,1308.7,1675,1452.6],[1233.7,1726.5,1422.2,1233.7,2677.2,2316.5,2414.6,1702.1,1639.8,2402.6,2445.4,2407.9,1985.3,2104.3,1868.3,2075.9,1482.7,1662.8,1393.2,1375.8,1182.1,997.8,690.8,688.2,1771.1,1903.8,2089.1,1095.2,1115.8,1460.5,951.2,1883.8,2050,1548.4,1377,1335.7,1205.8,837.3,948.4,1348.6,1285.8,0,520.1,358.8],[1656.1,2007.2,1844.6,1656.1,2935.8,2627.5,2631.9,1766.4,1843.3,2775.1,2829,2780.4,2268.2,2526.7,2290.7,2498.3,1905.1,2085.2,1815.6,1730,1604.5,1420.2,957.8,1110.6,2193.5,2326.2,2511.5,1204.1,1538.2,1882.9,1346.6,2306.2,2422.5,1970.8,1799.4,1758.1,1628.2,1259.7,675.4,1075.6,1708.2,547.5,0,687.3],[1388.7,1750.6,1537.5,1388.7,2838.1,2477.4,2671.7,1959.2,1896.9,2517.9,2560.7,2523.2,2146.2,2239.9,2003.9,2211.5,1637.7,1823.7,1532.5,1632.9,1439.2,1254.9,947.9,945.3,1906.7,2019.1,2204.4,1352.3,1372.9,1575.8,1066.5,1999.1,2165.3,1663.7,1492.3,1451,1321.1,1094.4,1101.4,1501.6,1401.1,346.4,664.6,0]]

# Day 1 - Start at 8:00am at Location 1 (index 0)
# Day 1 - End at 4:00pm at Location 2 (index 1)
# Day 2 - Start at 6:00am at Location 3 (index 2)
# Day 2 - End at 6:00pm at Location 4 (index 3)
Windows = [[28800, 28800], [57600, 57600], [21600, 21600], [64800, 64800], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400], [0, 86400]]

Durations = [0, 0, 0, 0, 0, 0, 900, 900, 900, 900, 900, 900, 900, 900, 900, 900, 900, 900, 900, 900, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 1800, 3600, 3600, 3600, 3600, 3600]

Penalties = [576460752303423487, 576460752303423487, 576460752303423487, 576460752303423487, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000]

NUM_DAYS = 2

START_NODES = []
for node in range(0, NUM_DAYS):
START_NODES.append(node * 2)

END_NODES = []
for node in range(0, NUM_DAYS):
END_NODES.append(node * 2 + 1)

REGULAR_NODES = []
for node in range(NUM_DAYS * 2, len(Matrix)):
REGULAR_NODES.append(node)

def transit_callback(from_index, to_index):

# Returns the travel time between the two nodes.
# Convert from routing variable Index to time matrix NodeIndex.
from_node = manager.IndexToNode(from_index)
to_node = manager.IndexToNode(to_index)

# prevent movement from start nodes to start nodes
if from_node in START_NODES:
if to_node in START_NODES:
return 576460752303423487

# prevent movement from start nodes to end nodes
if from_node in START_NODES:
if to_node in END_NODES:
return 576460752303423487

# prevent movement from end nodes to end nodes
if from_node in END_NODES:
if to_node in END_NODES:
return 576460752303423487

# prevent movement from end nodes to non start nodes
if from_node in END_NODES:
if to_node  in START_NODES:
return 0
else:
return 576460752303423487

return Matrix[from_node][to_node]

def time_callback(from_index, to_index):

# Returns the travel time plus service time between the two nodes.
# Convert from routing variable Index to time matrix NodeIndex.
from_node = manager.IndexToNode(from_index)
to_node = manager.IndexToNode(to_index)

if from_node in END_NODES:
Reset = Windows[from_node][1]
else:
Reset = 0

return Matrix[from_node][to_node] + Durations[from_node] - Reset

# Create the routing index manager.
manager = pywrapcp.RoutingIndexManager(len(Matrix), 1, [0], [1])

# Create Routing Model.
routing = pywrapcp.RoutingModel(manager)

# Register the Transit Callback.
transit_callback_index = routing.RegisterTransitCallback(transit_callback)

# Set the arc cost evaluator for all vehicles
routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index)

# Register the Time Callback.
time_callback_index = routing.RegisterTransitCallback(time_callback)

# Add Time Windows constraint.
time_callback_index,
86400, # An upper bound for slack (the wait times at the locations).
86400, # An upper bound for the total time over each vehicle's route.
False,
'Time')
time_dimension = routing.GetDimensionOrDie('Time')

# Get rid of slack for all regular nodes
# for node in range(len(START_NODES) + len(END_NODES), len(Matrix)):
#   index = manager.NodeToIndex(node)
#   time_dimension.SlackVar(index).SetValue(0)

# Get rid of slack for all start nodes
# for node in START_NODES:
#   index = manager.NodeToIndex(node)
#   time_dimension.SlackVar(index).SetValue(0)

# Allow all regular nodes to be droppable.
for node in range(len(START_NODES) + len(END_NODES), len(Matrix)):

# Add time window constraints for all regular nodes.
for location_index, time_window in enumerate(Windows):
if location_index in REGULAR_NODES:
index = manager.NodeToIndex(location_index)
time_dimension.CumulVar(index).SetRange(time_window[0], time_window[1])

# TODO! - I think this needs to be handled differently for each day
# Add time window constraints for start node.
index = routing.Start(0)
time_dimension.CumulVar(index).SetRange(Windows[0][0],Windows[0][1])
index = routing.End(0)
time_dimension.CumulVar(index).SetRange(Windows[1][0],Windows[1][1])

# Setting first solution heuristic.
search_parameters = pywrapcp.DefaultRoutingSearchParameters()
search_parameters.first_solution_strategy = (routing_enums_pb2.FirstSolutionStrategy.PARALLEL_CHEAPEST_INSERTION)

# Setting local search metaheuristics:
search_parameters.local_search_metaheuristic = (routing_enums_pb2.LocalSearchMetaheuristic.GUIDED_LOCAL_SEARCH)
search_parameters.time_limit.seconds = 15
search_parameters.log_search = False

# Solve the problem.
solution = routing.SolveWithParameters(search_parameters)
if not solution:
print("no solution found")
else:
print("solution found.  Objective value is ",solution.ObjectiveValue())

# Print the results
result = {
'Dropped': [],
'Scheduled': []
}

# Return the dropped locations
for index in range(routing.Size()):
if routing.IsStart(index) or routing.IsEnd(index):
continue
node = manager.IndexToNode(index)
if node in END_NODES or node in START_NODES:
continue
if solution.Value(routing.NextVar(index)) == index:
result['Dropped'].append(node)

# Return the scheduled locations
time = 0
index = routing.Start(0)
while not routing.IsEnd(index):
time = time_dimension.CumulVar(index)
result['Scheduled'].append([manager.IndexToNode(index), solution.Min(time), solution.Max(time)])
index = solution.Value(routing.NextVar(index))
time = time_dimension.CumulVar(index)
result['Scheduled'].append([manager.IndexToNode(index), solution.Min(time), solution.Max(time)])

print('Dropped')
print(result['Dropped'])

print('Scheduled')
for line in result['Scheduled']:
print(line)
``````

Output:

``````solution found.  Objective value is  22468
Dropped
[]
Scheduled
[0, 28800, 28800]
[28, 29216, 35021]
[20, 31277, 37082]
[21, 33510, 39315]
[19, 35787, 41592]
[8, 37197, 43002]
[6, 39278, 45083]
[4, 40829, 46634]
[5, 41386, 47191]
[9, 42037, 47842]
[26, 43496, 49301]
[10, 45818, 51623]
[11, 47690, 53495]
[32, 49169, 54974]
[31, 51530, 57335]
[24, 53621, 59426]
[25, 55790, 61595]
[15, 57982, 63787]
[13, 59251, 65056]
[14, 60366, 66171]
[12, 61559, 67364]
[17, 62886, 68691]
[16, 64245, 70050]
[18, 65428, 71233]
[3, 66607, 72412]
[2, 2334, 8139]
[35, 2530, 8335]
[36, 4568, 10373]
[40, 6609, 12414]
[37, 10906, 16711]
[23, 13016, 18821]
[22, 15163, 20968]
[27, 17473, 23278]
[7, 20179, 25984]
[39, 22710, 28515]
[38, 27042, 32847]
[42, 29446, 35251]
[41, 33593, 39398]
[43, 37551, 43356]
[30, 42217, 48022]
[34, 44789, 50594]
[29, 46839, 52644]
[33, 49177, 54982]
[1, 57600, 57600]
``````
• I don't see something that is wrong on first sight, at least not something that is obvious. Have you tried relaxing the constraints? Start with relaxing all constraints and re-activate them one by one to see what may cause a problem. Start by increasing capacity and max slack to something very large (e.g. 1e10). Also, set `log_search=True`and increase the local search heuristic time. Just run it for 30 minutes and see if still finds solutions. Aside from that I wouldn't recommend modelling your problem with a start time at `0`. (1/2)
– k88
Dec 1, 2020 at 15:10
• It is better to model using your own domain models that map to the problem you are solving. This way you can keep track of times, vehicles and locations in a way that makes sense to a human (proper date times, coordinates, etc.). Then you can convert that to the OR-Tools model and map it back and make sense of the solution. Note: for time I would recommend using epoch time, that way you can easily model using a longer time horizon. Hope this helps (2/2)
– k88
Dec 1, 2020 at 15:13

You may have something like that:

``````python plop.py
Objective: 93780
droped: []
Route for vehicle 0:
0 [21600;21600] -> 38 [21902;57722] -> 33 [23897;59717] -> 34 [25935;61755] -> 28 [28562;64382] -> 41 [31374;67194] -> 39 [33520;69340] -> 40 [35840;71660] -> 36 [38315;74135] -> 37 [40745;76565] -> 5 [44115;79935] -> 25 [46810;82630] -> 20 [49163;84983] -> 21 [51370;790+1day] -> 35 [53471;2891+1day] -> 26 [55707;5127+1day] -> 18 [57768;7188+1day] -> 19 [60001;9421+1day] -> 17 [62278;11698+1day] -> 6 [64588;14008+1day] -> 4 [67569;16989+1day] -> 2 [70020;19440+1day] -> 3 [72377;21797+1day] -> 7 [74828;24248+1day] -> 24 [77187;26607+1day] -> 8 [79509;28929+1day] -> 9 [82281;31701+1day] -> 30 [84660;34080+1day] -> 31 [778+1day;36598+1day] -> 32 [3163+1day;38983+1day] -> 27 [5213+1day;41033+1day] -> 22 [7579+1day;43399+1day] -> 29 [9715+1day;45535+1day] -> 23 [11863+1day;47683+1day] -> 13 [14055+1day;49875+1day] -> 11 [16224+1day;52044+1day] -> 12 [18239+1day;54059+1day] -> 10 [20332+1day;56152+1day] -> 15 [22559+1day;58379+1day] -> 14 [24818+1day;60638+1day] -> 16 [26901+1day;62721+1day] -> 1 [64800+1day;64800+1day]
``````
``````%diff -u plop.py plop_final.py
--- plop.py 2020-12-01 17:48:15.187255138 +0100
+++ plop_final.py   2020-12-01 17:47:41.033692899 +0100
@@ -7,6 +7,7 @@
Penalties = [576460752303423487, 576460752303423487, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000, 100000]
Slack_Max = 86400
Capacity = 86400
+OneDay = 86400

# The inputs to RoutingIndexManager are:
#   1. The number of rows of the time matrix, which is the number of locations (including the depot).
@@ -36,7 +37,7 @@
transit_callback_index,
Slack_Max,  # An upper bound for slack (the wait times at the locations).
-    Capacity,  # An upper bound for the total time over each vehicle's route.
+    2*Capacity,  # An upper bound for the total time over each vehicle's route.
False,  # Determine whether the cumulative variable is set to zero at the start of the vehicle's route.
'Time')
time_dimension = routing.GetDimensionOrDie('Time')
@@ -50,13 +51,14 @@
if location_idx == 0 or location_idx == 1:
continue
index = manager.NodeToIndex(location_idx)
-  time_dimension.CumulVar(index).SetRange(time_window[0], time_window[1])
+  time_dimension.CumulVar(index).SetRange(time_window[0], time_window[1]+OneDay)
+  time_dimension.CumulVar(index).RemoveInterval(time_window[1], time_window[0]+OneDay)

# Add time window constraints for each vehicle start node.
index = routing.Start(0)
time_dimension.CumulVar(index).SetRange(Windows[0][0],Windows[0][1])
index = routing.End(0)
-time_dimension.CumulVar(index).SetRange(Windows[1][0],Windows[1][1])
+time_dimension.CumulVar(index).SetRange(Windows[1][0]+OneDay,Windows[1][1]+OneDay)

# Instantiate route start and end times to produce feasible times.
@@ -73,28 +75,24 @@

# Solve the problem.
solution = routing.SolveWithParameters(search_parameters)
-
-# Print the results
-result = {
-  'Dropped': [],
-  'Scheduled': []
-}
+print(f"Objective: {solution.ObjectiveValue()}")

# Return the dropped locations
+dropped = []
for node in range(routing.Size()):
if routing.IsStart(node) or routing.IsEnd(node):
continue
if solution.Value(routing.NextVar(node)) == node:
-    result['Dropped'].append(manager.IndexToNode(node))
+    dropped.append(manager.IndexToNode(node))
+print(f"droped: {dropped}")

# Return the scheduled locations
-time = 0
index = routing.Start(0)
+plan_output = 'Route for vehicle 0:\n'
while not routing.IsEnd(index):
time = time_dimension.CumulVar(index)
-  result['Scheduled'].append([manager.IndexToNode(index), solution.Min(time),solution.Max(time)])
+  tw_min = solution.Min(time)
+  if tw_min > OneDay:
+      tw_min = f"{tw_min%OneDay}+1day"
+  tw_max = solution.Max(time)
+  if tw_max > OneDay:
+      tw_max = f"{tw_max%OneDay}+1day"
+
+  plan_output += f'{manager.IndexToNode(index)} [{tw_min};{tw_max}] -> '
index = solution.Value(routing.NextVar(index))
time = time_dimension.CumulVar(index)
-result['Scheduled'].append([manager.IndexToNode(index), solution.Min(time),solution.Max(time)])
-
-print(result)
+tw_min = solution.Min(time)
+tw_max = solution.Max(time)
+if tw_min > OneDay:
+    tw_min = f"{tw_min%OneDay}+1day"
+tw_max = solution.Max(time)
+if tw_max > OneDay:
+    tw_max = f"{tw_max%OneDay}+1day"
+plan_output += f'{manager.IndexToNode(index)} [{tw_min};{tw_max}]'
+print(plan_output)
``````

My changes:

ps: If you have question, please join our or-tools discord (link in the README on github) ;)

## Step 2

Currently:

• your TW for location is `[0;86400]` while your vehicle is working from `21600` to `64800`.
• Your end TW is `[64800, 64800]` instead I would use `[21600;64800]` i.e. finish ASAP instead of dispatching visit until 6pm ?

So let's hack your TW data as follow:

``````Windows = [[21600, 21600], [21600, 64800], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400], [21600, 86400]]
``````

Then you'll get the following result:

``````python plop_final.py
Objective: 93780
droped: []
Route for vehicle 0:
0 [21600;21600] -> 38 [21902;23641] -> 33 [23897;25636] -> 34 [25935;27674] -> 28 [28562;30301] -> 41 [31374;33113] -> 39 [33520;35259] -> 40 [35840;37579] -> 36 [38315;40054] -> 37 [40745;42484] -> 5 [44115;45854] -> 25 [46810;48549] -> 20 [49163;50902] -> 21 [51370;53109] -> 35 [53471;55210] -> 26 [55707;57446] -> 18 [57768;59507] -> 19 [60001;61740] -> 17 [62278;64017] -> 6 [64588;66327] -> 4 [67569;69308] -> 2 [70020;71759] -> 3 [72377;74116] -> 7 [74828;76567] -> 24 [77187;78926] -> 8 [79509;81248] -> 9 [82281;84020] -> 30 [84660;86399] -> 31 [21601+1day;21601+1day] -> 32 [23986+1day;23986+1day] -> 27 [26036+1day;26036+1day] -> 22 [28402+1day;28402+1day] -> 29 [30538+1day;30538+1day] -> 23 [32686+1day;32686+1day] -> 13 [34878+1day;34878+1day] -> 11 [37047+1day;37047+1day] -> 12 [39062+1day;39062+1day] -> 10 [41155+1day;41155+1day] -> 15 [43382+1day;43382+1day] -> 14 [45641+1day;45641+1day] -> 16 [47724+1day;47724+1day] -> 1 [49803+1day;49803+1day]
``````

note: You can find my fork here: https://github.com/Mizux/tsp_multiple_days

Follow up with my solution, which is also available on GitHub.

The nature of my original question was pretty particular - my goal was to make locations in the traveling salesperson problem available for recurring time windows each day over an arbitrary number of days (i.e. making a location only available between 2:00pm - 4:00pm during each day over the span of some days that the vehicle would be active).

The solution came down to modeling the problem in a way such that the entire span of days would be represented as one large range of time between the start of the first day and the end of the last day; all durations of unavailability (due to night time, existing events, unavailable time windows, etc) would be removed from this range. This was achieved by using SetRange and RemoveInterval.

I've included the Google OR-Tools python library implementation below, but my sample data is too large, so it will remain available in the repository that I previously linked to above.

``````from ortools.constraint_solver import pywrapcp
from ortools.constraint_solver import routing_enums_pb2
import math
import sys
import json

# Specify the JSON data file
with open('3_days_60_locations.json') as file:

Locations = event['Locations']
Matrix = event['Matrix']
Windows = event['Windows']
ServiceCosts = event['ServiceCosts']
Penalties = event['Penalties']
NUM_DAYS = event['NumberOfDays']
NUM_EVENTS = event['NumberOfEvents']
DURATION = event['Duration']
ONE_DAY = 86400

def transit_callback(from_index, to_index):
# Returns the travel time plus service time between the two nodes.
# Convert from routing variable Index to time matrix NodeIndex.
from_node = manager.IndexToNode(from_index)
to_node = manager.IndexToNode(to_index)
return Matrix[from_node][to_node] + ServiceCosts[from_node]

# Create the routing index manager.
# Start is the start location of the first day
# End is the end location of the last day
manager = pywrapcp.RoutingIndexManager(len(Matrix), 1, [0], [2*NUM_DAYS-1])

# Create Routing Model.
routing = pywrapcp.RoutingModel(manager)

# Register the Transit Callback.
transit_callback_index = routing.RegisterTransitCallback(transit_callback)

# Set the arc cost evaluator for all vehicles
routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index)

# Add Time Windows constraint.
transit_callback_index,
ONE_DAY * NUM_DAYS, # An upper bound for slack (the wait times at the locations).
ONE_DAY * NUM_DAYS, # An upper bound for the total time over each vehicle's route.
False, # Determine whether the cumulative variable is set to zero at the start of the vehicle's route.
'Time')
time_dimension = routing.GetDimensionOrDie('Time')

# Allow locations to be droppable.
# Do not allow the start location of the first day to be droppable.
# Do not allow the end location of the last day to be droppable.
for node in range(0, len(Matrix)):
if node != 0 and node != (2 * NUM_DAYS) - 1:

# Add time window constraints for all start and end locations.
for i in range(0, NUM_DAYS*2):
if i == 0:
index = routing.Start(0)
elif i == NUM_DAYS*2 - 1:
index = routing.End(0)
else:
index = manager.NodeToIndex(i)
time_dimension.CumulVar(index).SetRange(Windows[i][0],Windows[i][1])

# Add time window constraints for all additional event locations.
for location_index, time_window in enumerate(Windows):
if location_index in range(NUM_DAYS * 2, NUM_DAYS * 2 + NUM_EVENTS):
index = manager.NodeToIndex(location_index)

# Add the range between the start of the first day and the end of the last day
time_dimension.CumulVar(index).SetRange(Windows[location_index][0],Windows[location_index][1])

# Add time window constraints for all regular locations.
for location_index, time_window in enumerate(Windows):
if location_index in range(NUM_DAYS * 2 + NUM_EVENTS, len(Matrix)):
index = manager.NodeToIndex(location_index)

# Add the range between the start of the first day and the end of the last day
time_dimension.CumulVar(index).SetRange(0, 86400 * NUM_DAYS)

for Day in range(NUM_DAYS):

Day_Start = Day * ONE_DAY
Day_End = Day_Start + ONE_DAY
Working_Start = Windows[Day * 2][0]
Working_End =   Windows[Day * 2 + 1][0]

# Remove the range between the start of the day and the start of work
time_dimension.CumulVar(index).RemoveInterval(Day_Start, Working_Start)

# Remove the range between the start of the day and the start of location
time_dimension.CumulVar(index).RemoveInterval(Day_Start, Day_Start + time_window[0])

# Remove the range between the end of work and the end of the day
time_dimension.CumulVar(index).RemoveInterval(Working_End, Day_End)

# Remove the range between the end of location and the end of the day
time_dimension.CumulVar(index).RemoveInterval(Day_Start + time_window[1], Day_End)

# Instantiate route start and end times to produce feasible times

# Setting first solution heuristic.
search_parameters = pywrapcp.DefaultRoutingSearchParameters()
search_parameters.first_solution_strategy = (routing_enums_pb2.FirstSolutionStrategy.ALL_UNPERFORMED)

# Setting local search metaheuristics:
search_parameters.local_search_metaheuristic = (routing_enums_pb2.LocalSearchMetaheuristic.GUIDED_LOCAL_SEARCH)
search_parameters.time_limit.seconds = DURATION
search_parameters.log_search = False

# Solve the problem
solution = routing.SolveWithParameters(search_parameters)

if not solution:
print("No solution found !")
sys.exit(1)

result = {
'DroppedLocations': [],
'ScheduledLocations': []
}

# Return dropped locations
for node in range(routing.Size()):
if routing.IsStart(node) or routing.IsEnd(node):
continue
if solution.Value(routing.NextVar(node)) == node:
index = manager.IndexToNode(node)
result['DroppedLocations'].append(Locations[index])

# Return scheduled locations
index = routing.Start(0)
while not routing.IsEnd(index):
time = time_dimension.CumulVar(index)
Location = Locations[manager.IndexToNode(index)]
Location['earliestArrivalTime'] = solution.Min(time);
Location['latestArrivalTime'] = solution.Max(time);
result['ScheduledLocations'].append(Location)
index = solution.Value(routing.NextVar(index))
time = time_dimension.CumulVar(index)
Location = Locations[manager.IndexToNode(index)]
Location['earliestArrivalTime'] = solution.Min(time);
Location['latestArrivalTime'] = solution.Max(time);
result['ScheduledLocations'].append(Location)

print(result)
``````