def test_dual_processors(env, geometry_a):
# move content from two different limited containers to an unlimited container at the same time
limited_container_1 = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=1000,
level=0,
nr_resources=1)
limited_container_2 = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=1000,
level=0,
nr_resources=1)
unlimited_container = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=2000,
level=1000,
nr_resources=100)
processor1 = Processor(
env=env,
name="Processor 1",
loading_func=model.get_loading_func(2),
unloading_func=model.get_unloading_func(2),
geometry=geometry_a,
)
processor2 = Processor(
env=env,
name="Processor 2",
loading_func=model.get_loading_func(1),
unloading_func=model.get_unloading_func(1),
geometry=geometry_a,
)
processor1.ActivityID = "Test activity"
processor2.ActivityID = "Test activity"
env.process(
processor1.process(limited_container_1, 400, unlimited_container))
env.process(
processor2.process(limited_container_2, 400, unlimited_container))
env.run()
np.testing.assert_almost_equal(env.now, env.epoch + 400)
assert unlimited_container.container.level == 200
assert limited_container_1.container.level == 400
assert limited_container_2.container.level == 400
env.process(
processor1.process(limited_container_1, 100, unlimited_container))
env.process(
processor2.process(limited_container_2, 300, unlimited_container))
start = env.now
env.run()
time_spent = env.now - start
np.testing.assert_almost_equal(time_spent, 150)
assert unlimited_container.container.level == 600
assert limited_container_1.container.level == 100
assert limited_container_2.container.level == 300
def test_container_transfer_hub(env, geometry_a, Location, TransportProcessingResource):
from_location = Location(
env=env, name="From", geometry=geometry_a, capacity=1000, level=1000
)
transfer_location = Location(
env=env, name="Transfer", geometry=geometry_a, capacity=500, level=0
)
to_location = Location(
env=env, name="To", geometry=geometry_a, capacity=1000, level=0
)
delivery_vessel = TransportProcessingResource(
env=env,
name="Delivery",
geometry=geometry_a,
loading_func=model.get_loading_func(1),
unloading_func=model.get_unloading_func(1),
capacity=100,
compute_v=(lambda x: 1),
)
collection_vessel = TransportProcessingResource(
env=env,
name="Collection",
geometry=geometry_a,
loading_func=model.get_loading_func(2),
unloading_func=model.get_unloading_func(2),
capacity=100,
compute_v=(lambda x: 1),
)
model.Activity(
env=env,
name="Delivery Activity",
origin=from_location,
destination=transfer_location,
loader=delivery_vessel,
mover=delivery_vessel,
unloader=delivery_vessel,
stop_event=env.timeout(3000),
)
model.Activity(
env=env,
name="Collection Activity",
origin=transfer_location,
destination=to_location,
loader=collection_vessel,
mover=collection_vessel,
unloader=collection_vessel,
stop_event=env.timeout(3000),
)
env.run()
assert from_location.container.level == 0
assert transfer_location.container.level == 0
assert to_location.container.level == 1000
def test_basic_processor(env, geometry_a):
# move content from one container to another, then move some of it back again
source = BasicStorageUnit(
env=env, geometry=geometry_a, capacity=1000, level=1000, nr_resources=1
)
dest = BasicStorageUnit(
env=env, geometry=geometry_a, capacity=1000, level=0, nr_resources=1
)
processor = Processor(
env=env,
loading_func=model.get_loading_func(2),
unloading_func=model.get_unloading_func(2),
geometry=geometry_a,
)
processor.ActivityID = "Test activity"
env.process(processor.process(source, 400, dest))
env.run()
np.testing.assert_almost_equal(env.now, env.epoch + 300)
assert source.container.level == 400
assert dest.container.level == 600
env.process(processor.process(dest, 300, source))
start = env.now
env.run()
time_spent = env.now - start
np.testing.assert_almost_equal(time_spent, 150)
assert source.container.level == 700
assert dest.container.level == 300
def test_processor(env, geometry_a, energy_use_sailing, energy_use_loading,
energy_use_unloading):
source = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=1000,
level=1000,
nr_resources=1)
dest = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=1000,
level=0,
nr_resources=1)
processor = type(
"processor",
(core.Processor, core.EnergyUse, core.Locatable, core.Log), {})
data_processor = {
"env": env,
"unloading_func": model.get_unloading_func(2),
"loading_func": model.get_loading_func(2),
"geometry": geometry_a,
"energy_use_sailing": energy_use_sailing,
"energy_use_loading": energy_use_loading,
"energy_use_unloading": energy_use_unloading,
}
processor = processor(**data_processor)
processor.ActivityID = "Test activity"
# Log fuel use of the processor in step 1
start = env.now
env.process(processor.process(source, 400, dest))
env.run()
np.testing.assert_almost_equal(processor.log["Value"][-1],
(env.now - start) * 4)
# Log fuel use of the processor in step 2
start = env.now
env.process(processor.process(dest, 300, source))
env.run()
np.testing.assert_almost_equal(processor.log["Value"][-1],
(env.now - start) * 4)
def test_sequential_activities(
env, geometry_a, geometry_b, Location, TransportProcessingResource
):
""" Test if activities only start after another one is finished. """
amount = 10_000
# Initialize from site with correct parameters
data_from_location = {
"env": env, # The simpy environment
"name": "Location A", # The name of the "from location"
"geometry": geometry_a, # The coordinates of the "from location"
"capacity": amount, # The capacity of the "from location"
"level": amount,
} # The actual volume of the "from location"
data_to_location = {
"env": env, # The simpy environment
"name": "Location B", # The name of the "to location"
"geometry": geometry_b, # The coordinates of the "to location"
"capacity": amount / 2, # The capacity of the "to location"
"level": 0,
} # The actual volume of the "to location"
from_location = Location(**data_from_location)
to_location_1 = Location(**data_to_location)
to_location_2 = Location(**data_to_location)
# make the vessel
data_vessel = {
"env": env, # The simpy environment
"name": "Vessel",
"geometry": geometry_a, # It is located at the "from location"
"unloading_func": model.get_unloading_func(
1
), # Unloading production is 1 amount / s
"loading_func": model.get_loading_func(1), # Loading production is 1 amount / s
"capacity": 1_000, # Capacity of the vessel
"compute_v": (lambda x: 1),
} # Speed is always 1 m / s
"v": 1, # Speed always 1 m/s
"compute_draught": compute_draught(4.0, 7.0), # Variable draught
"waves": [0.5, 1], # Waves with specific ukc
"ukc": [0.75, 1], # UKC corresponding to the waves
"filling": None,
} # The filling degree
mover = Mover(**data)
mover.ActivityID = "Test activity"
data = {
"env": env, # The simpy environment
"name": "Quay Crane", # Name
"geometry": geometry_a, # It starts at the "from site"
"loading_func": model.get_loading_func(1.0), # Loading rate
"unloading_func": model.get_unloading_func(1.0),
} # Unloading rate
crane = Processor(**data)
crane.rate = crane.loading_func
crane.ActivityID = "Test activity"
# Initialize the LocationWeather
data = {
"env": env, # The simpy environment defined in the first cel
"name": "Limited Location", # The name of the site
"geometry": geometry_a, # Location
"capacity": 500_000, # The capacity of the site
"level": 500_000, # The actual volume of the site
"dataframe": weather_data, # The dataframe containing the weather data
"bed": -7,
data_to_site = {
"env": env, # The simpy environment
"name": "Location B", # The name of the "to location"
"geometry": location, # The coordinates of the "to location"
"capacity": 1_000, # The capacity of the "to location"
"level": 0,
} # The actual volume of the "to location"
to_site = Location(**data_to_site)
# make the processor with source terms
data_processor = {
"env": env, # The simpy environment
"geometry": location, # The coordinates of the "processore"
"unloading_func": model.get_unloading_func(
1
), # Unloading production is 1 amount / s
"loading_func": model.get_loading_func(1),
} # Loading production is 1 amount / s
processor = Processor(**data_processor)
processor.ActivityID = "Test activity"
# Log fuel use of the processor in step 1
env.process(processor.process(from_site, 0, to_site))
env.run()
assert "fines released" in processor.log["Message"]
fines = [
processor.log["Value"][i]
for i in range(len(processor.log["Value"]))
if processor.log["Message"][i] == "fines released"
def test_Processor_ContainerDependentMovable(
env,
geometry_a,
geometry_b,
locatable_a,
locatable_b,
energy_use_sailing,
energy_use_loading,
energy_use_unloading,
):
source = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=1000,
level=1000,
nr_resources=1)
dest = BasicStorageUnit(env=env,
geometry=geometry_b,
capacity=1000,
level=0,
nr_resources=1)
# The generic class for an object that can process (a quay crane for example)
ProcessingResource = type(
"ProcessingResource",
(
core.Identifiable, # Give it a name
core.Locatable, # Allow logging of location
core.Log, # Allow logging of all discrete events
core.Processor, # Allow for loading and unloading
core.HasResource, # Add information on serving equipment
core.EnergyUse,
), # Add information on fuel
{},
)
processor_1 = {
"env": env, # The simpy environment
"name": "Processor 1", # Name
"geometry": geometry_a, # It is located at location A
"unloading_func": model.get_unloading_func(1), # Unloading rate
"loading_func": model.get_loading_func(2), # Loading rate
"energy_use_loading": energy_use_loading, # Variable fuel use
"energy_use_sailing": energy_use_sailing, # Variable fuel use
"energy_use_unloading": energy_use_loading,
} # Variable fuel use
processor_2 = {
"env": env, # The simpy environment
"name": "Processor 2", # Name
"geometry": geometry_b, # It is located at location B
"unloading_func": model.get_unloading_func(1), # Unloading rate
"loading_func": model.get_loading_func(2), # Loading rate
"energy_use_loading": energy_use_unloading, # Variable fuel use
"energy_use_sailing": energy_use_sailing, # Variable fuel use
"energy_use_unloading": energy_use_unloading,
} # Variable fuel use
# The generic class for an object that can move an amount (a containervessel)
mover = type(
"Mover",
(core.ContainerDependentMovable, core.EnergyUse, core.HasResource,
core.Log),
{},
)
data_mover = {
"compute_v": lambda x: 1,
"geometry": geometry_a,
"env": env,
"capacity": 1000,
"energy_use_sailing": energy_use_sailing,
"energy_use_loading": energy_use_loading,
"energy_use_unloading": energy_use_unloading,
}
# The simulation objects
processor_1 = ProcessingResource(**processor_1)
processor_2 = ProcessingResource(**processor_2)
containervessel = mover(**data_mover)
processor_1.ActivityID = "Test activity"
processor_2.ActivityID = "Test activity"
containervessel.ActivityID = "Test activity"
# Simulation starts with loading
start = env.now
env.process(processor_1.process(containervessel, 500, source))
env.run()
np.testing.assert_almost_equal(processor_1.log["Value"][-1],
(env.now - start) * 4)
# Simulation continues with moving from A to B
start = env.now
env.process(containervessel.move(locatable_b))
env.run()
np.testing.assert_almost_equal(containervessel.log["Value"][-2],
(env.now - start) * 2.5,
decimal=5)
# Simulation ends with unloading
start = env.now
env.process(processor_2.process(containervessel, 0, dest))
env.run()
np.testing.assert_almost_equal(processor_2.log["Value"][-1],
(env.now - start) * 3)
def test_TransportProcessingResource(
env,
geometry_a,
geometry_b,
locatable_a,
locatable_b,
energy_use_sailing,
energy_use_loading,
energy_use_unloading,
):
source = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=1000,
level=1000,
nr_resources=1)
dest = BasicStorageUnit(env=env,
geometry=geometry_b,
capacity=1000,
level=0,
nr_resources=1)
# The generic class for an object that can move and transport (a TSHD for example)
TransportProcessingResource = type(
"TransportProcessingResource",
(
core.Identifiable, # Give it a name
core.Log, # Allow logging of all discrete events
core.
ContainerDependentMovable, # A moving container, so capacity and location
core.Processor, # Allow for loading and unloading
core.HasResource, # Allow queueing
core.EnergyUse,
), # Allow logging energy use
{},
)
# TSHD variables
data_hopper = {
"env": env, # The simpy environment
"name": "Hopper", # Name
"geometry": geometry_b, # It starts at the "to site"
"unloading_func": model.get_unloading_func(1), # Unloading rate
"loading_func": model.get_loading_func(2), # Loading rate
"capacity": 500, # Capacity of the hopper
"compute_v": lambda x: 1, # Variable speed
"energy_use_loading": energy_use_loading, # Variable fuel use
"energy_use_sailing": energy_use_sailing, # Variable fuel use
"energy_use_unloading": energy_use_unloading,
} # Variable fuel use
# The simulation object
hopper = TransportProcessingResource(**data_hopper)
hopper.ActivityID = "Test activity"
# Simulation starts with moving to A
start = env.now
env.process(hopper.move(source))
env.run()
# moving empty to energy use is 2 per second
np.testing.assert_almost_equal(hopper.log["Value"][-2],
(env.now - start) * 2,
decimal=5)
# Simulation continues with loading
start = env.now
env.process(hopper.process(hopper, 500, source))
env.run()
# Duration should be amount / 2
# Energy use duration * 4
np.testing.assert_almost_equal(hopper.log["Value"][-2],
(env.now - start) * 4)
# Simulation continues with moving from A to B
start = env.now
env.process(hopper.move(locatable_b))
env.run()
# moving full so energy use is 3 per second
np.testing.assert_almost_equal(hopper.log["Value"][-2],
(env.now - start) * 3,
decimal=5)
# Simulation ends with unloading
hopper.rate = hopper.unloading_func
start = env.now
env.process(hopper.process(hopper, 0, dest))
env.run()
np.testing.assert_almost_equal(hopper.log["Value"][-2],
(env.now - start) * 3)
def available_equipment(env):
# should be read from database
equipment_data = [
{
"id": "EGG123",
"type": "Side stone dumping vessel",
"speed loaded": 6.5,
"tonnage": 2601,
"lat": 52.94239823421129,
"lon": 5.019298185633251,
"tags": ["mover"],
},
{
"id": "Boaty McBoatStone",
"type": "Multi purpose support vessel",
"speed loaded": 7.0,
"tonnage": 1824,
"capacity": 10.3,
"lat": 52.94239823421129,
"lon": 5.019298185633251,
"tags": ["loader", "mover"],
},
{
"id": "Loady McLoader",
"type": "Simple Loading Crane",
"lat": 52.94239823421129,
"lon": 5.019298185633251,
"capacity": 13.2,
},
{
"id": "Unloady McUnloader",
"type": "Simple Loading Crane",
"lat": 52.94042293840172,
"lon": 5.054676856441372,
"capacity": 12.1,
},
]
type_to_mixins_mapping = {
"Side stone dumping vessel": (
core.Identifiable,
core.Log,
core.ContainerDependentMovable,
core.HasResource,
core.Locatable,
),
"Multi purpose support vessel": (
core.Identifiable,
core.Log,
core.ContainerDependentMovable,
core.Processor,
core.HasResource,
core.Locatable,
),
"Simple Loading Crane": (
core.Identifiable,
core.Log,
core.Processor,
core.HasResource,
core.Locatable,
),
}
ship_mixins = {}
for data in equipment_data:
ship_type = data["type"]
mixin_classes = type_to_mixins_mapping[ship_type]
klass = type(type_to_class_name(ship_type), mixin_classes, {})
ureg = pint.UnitRegistry()
kwargs = dict(env=env, name=data["id"])
if issubclass(klass, core.Processor):
processing_speed = (
data["capacity"] * ureg.ton / ureg.minute
).to_base_units()
kwargs["loading_func"] = model.get_loading_func(processing_speed.magnitude)
kwargs["unloading_func"] = model.get_unloading_func(
processing_speed.magnitude
)
if issubclass(klass, core.HasResource):
kwargs["nr_resources"] = 1
if issubclass(klass, core.HasContainer):
tonnage = (data["tonnage"] * ureg.metric_ton).to_base_units()
kwargs["capacity"] = tonnage.magnitude
if issubclass(klass, core.Locatable):
# todo change this to something read from the database
kwargs["geometry"] = shapely.geometry.Point(data["lon"], data["lat"])
if issubclass(klass, core.Movable):
speed_loaded = (data["speed loaded"] * ureg.knot).to_base_units().magnitude
if issubclass(klass, core.ContainerDependentMovable):
kwargs["compute_v"] = compute_v_linear(speed_loaded * 2, speed_loaded)
else:
kwargs["v"] = speed_loaded
ship = klass(**kwargs)
ship_mixins[data["id"]] = ship
return ship_mixins
def test_dual_processors_with_limit(env, geometry_a):
# move content into a limited container, have two process wait for each other to finish
unlimited_container_1 = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=1000,
level=1000,
nr_resources=100)
unlimited_container_2 = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=1000,
level=1000,
nr_resources=100)
unlimited_container_3 = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=2000,
level=0,
nr_resources=100)
limited_container = BasicStorageUnit(env=env,
geometry=geometry_a,
capacity=2000,
level=0,
nr_resources=1)
processor1 = Processor(
env=env,
name="Processor 1",
loading_func=model.get_loading_func(1),
unloading_func=model.get_unloading_func(1),
geometry=geometry_a,
)
processor2 = Processor(
env=env,
name="Processor 2",
loading_func=model.get_loading_func(1),
unloading_func=model.get_unloading_func(1),
geometry=geometry_a,
)
processor1.ActivityID = "Test activity"
processor2.ActivityID = "Test activity"
env.process(
model.single_run_process(
processor1,
env,
unlimited_container_1,
limited_container,
processor1,
unlimited_container_3,
processor1,
))
env.process(
model.single_run_process(
processor2,
env,
unlimited_container_2,
limited_container,
processor2,
unlimited_container_3,
processor2,
))
env.run()
# Simultaneous accessing limited_container, so waiting event of 1000 seconds
np.testing.assert_almost_equal(env.now, env.epoch + 3000)
assert limited_container.container.level == 2000
assert unlimited_container_1.container.level == 0
assert unlimited_container_2.container.level == 0