src/emuvim/examples/simple_topology_restapi.py - osm/vim-emu - Gitiles

 """
 This is an example topology for the distributed cloud emulator (dcemulator).
 (c) 2015 by Manuel Peuster <manuel.peuster@upb.de>


 This is an example that shows how a user of the emulation tool can
 define network topologies with multiple emulated cloud data centers.

 The definition is done with a Python API which looks very similar to the
 Mininet API (in fact it is a wrapper for it).

 We only specify the topology *between* data centers not within a single
 data center (data center internal setups or placements are not of interest,
 we want to experiment with VNF chains deployed across multiple PoPs).

 The original Mininet API has to be completely hidden and not be used by this
 script.
 """
 import logging
 from mininet.log import setLogLevel
 from emuvim.dcemulator.net import DCNetwork
 from emuvim.api.rest.rest_api_endpoint import RestApiEndpoint

 from emuvim.api.zerorpc.compute import ZeroRpcApiEndpoint
 from emuvim.api.zerorpc.network import ZeroRpcApiEndpointDCNetwork

 logging.basicConfig(level=logging.INFO)


 def create_topology1():
     """
     1. Create a data center network object (DCNetwork)
     """
     net = DCNetwork(monitor=True, enable_learning=False)

     """
     1b. add a monitoring agent to the DCNetwork
     """
     #keep old zeroRPC interface to test the prometheus metric query
     mon_api = ZeroRpcApiEndpointDCNetwork("0.0.0.0", 5151)
     mon_api.connectDCNetwork(net)
     mon_api.start()
     """
     2. Add (logical) data centers to the topology
        (each data center is one "bigswitch" in our simplified
         first prototype)
     """
     dc1 = net.addDatacenter("datacenter1")
     dc2 = net.addDatacenter("datacenter2")
     dc3 = net.addDatacenter("long_data_center_name3")
     dc4 = net.addDatacenter(
         "datacenter4",
         metadata={"mydata": "we can also add arbitrary metadata to each DC"})

     """
     3. You can add additional SDN switches for data center
        interconnections to the network.
     """
     s1 = net.addSwitch("s1")

     """
     4. Add links between your data centers and additional switches
        to define you topology.
        These links can use Mininet's features to limit bw, add delay or jitter.
     """
     net.addLink(dc1, dc2)
     net.addLink("datacenter1", s1)
     net.addLink(s1, dc3)
     net.addLink(s1, "datacenter4")

     """
     5. We want to access and control our data centers from the outside,
        e.g., we want to connect an orchestrator to start/stop compute
        resources aka. VNFs (represented by Docker containers in the emulated)

        So we need to instantiate API endpoints (e.g. a zerorpc or REST
        interface). Depending on the endpoint implementations, we can connect
        one or more data centers to it, which can then be controlled through
        this API, e.g., start/stop/list compute instances.
     """
     # keep the old zeroRPC interface for the prometheus metric query test
     zapi1 = ZeroRpcApiEndpoint("0.0.0.0", 4242)
     # connect data centers to this endpoint
     zapi1.connectDatacenter(dc1)
     zapi1.connectDatacenter(dc2)
     # run API endpoint server (in another thread, don't block)
     zapi1.start()

     # create a new instance of a endpoint implementation
     api1 = RestApiEndpoint("127.0.0.1", 5001)
     # connect data centers to this endpoint
     api1.connectDatacenter(dc1)
     api1.connectDatacenter(dc2)
     api1.connectDatacenter(dc3)
     api1.connectDatacenter(dc4)
     # connect total network also, needed to do the chaining and monitoring
     api1.connectDCNetwork(net)
     # run API endpoint server (in another thread, don't block)
     api1.start()

     """
     6. Finally we are done and can start our network (the emulator).
        We can also enter the Mininet CLI to interactively interact
        with our compute resources (just like in default Mininet).
        But we can also implement fully automated experiments that
        can be executed again and again.
     """
     net.start()
     net.CLI()
     # when the user types exit in the CLI, we stop the emulator
     net.stop()


 def main():
     setLogLevel('info')  # set Mininet loglevel
     create_topology1()


 if __name__ == '__main__':
     main()
	"""
	This is an example topology for the distributed cloud emulator (dcemulator).
	(c) 2015 by Manuel Peuster <manuel.peuster@upb.de>


	This is an example that shows how a user of the emulation tool can
	define network topologies with multiple emulated cloud data centers.

	The definition is done with a Python API which looks very similar to the
	Mininet API (in fact it is a wrapper for it).

	We only specify the topology between data centers not within a single
	data center (data center internal setups or placements are not of interest,
	we want to experiment with VNF chains deployed across multiple PoPs).

	The original Mininet API has to be completely hidden and not be used by this
	script.
	"""
	import logging
	from mininet.log import setLogLevel
	from emuvim.dcemulator.net import DCNetwork
	from emuvim.api.rest.rest_api_endpoint import RestApiEndpoint

	from emuvim.api.zerorpc.compute import ZeroRpcApiEndpoint
	from emuvim.api.zerorpc.network import ZeroRpcApiEndpointDCNetwork

	logging.basicConfig(level=logging.INFO)


	def create_topology1():
	"""
	1. Create a data center network object (DCNetwork)
	"""
	net = DCNetwork(monitor=True, enable_learning=False)

	"""
	1b. add a monitoring agent to the DCNetwork
	"""
	#keep old zeroRPC interface to test the prometheus metric query
	mon_api = ZeroRpcApiEndpointDCNetwork("0.0.0.0", 5151)
	mon_api.connectDCNetwork(net)
	mon_api.start()
	"""
	2. Add (logical) data centers to the topology
	(each data center is one "bigswitch" in our simplified
	first prototype)
	"""
	dc1 = net.addDatacenter("datacenter1")
	dc2 = net.addDatacenter("datacenter2")
	dc3 = net.addDatacenter("long_data_center_name3")
	dc4 = net.addDatacenter(
	"datacenter4",
	metadata={"mydata": "we can also add arbitrary metadata to each DC"})

	"""
	3. You can add additional SDN switches for data center
	interconnections to the network.
	"""
	s1 = net.addSwitch("s1")

	"""
	4. Add links between your data centers and additional switches
	to define you topology.
	These links can use Mininet's features to limit bw, add delay or jitter.
	"""
	net.addLink(dc1, dc2)
	net.addLink("datacenter1", s1)
	net.addLink(s1, dc3)
	net.addLink(s1, "datacenter4")

	"""
	5. We want to access and control our data centers from the outside,
	e.g., we want to connect an orchestrator to start/stop compute
	resources aka. VNFs (represented by Docker containers in the emulated)

	So we need to instantiate API endpoints (e.g. a zerorpc or REST
	interface). Depending on the endpoint implementations, we can connect
	one or more data centers to it, which can then be controlled through
	this API, e.g., start/stop/list compute instances.
	"""
	# keep the old zeroRPC interface for the prometheus metric query test
	zapi1 = ZeroRpcApiEndpoint("0.0.0.0", 4242)
	# connect data centers to this endpoint
	zapi1.connectDatacenter(dc1)
	zapi1.connectDatacenter(dc2)
	# run API endpoint server (in another thread, don't block)
	zapi1.start()

	# create a new instance of a endpoint implementation
	api1 = RestApiEndpoint("127.0.0.1", 5001)
	# connect data centers to this endpoint
	api1.connectDatacenter(dc1)
	api1.connectDatacenter(dc2)
	api1.connectDatacenter(dc3)
	api1.connectDatacenter(dc4)
	# connect total network also, needed to do the chaining and monitoring
	api1.connectDCNetwork(net)
	# run API endpoint server (in another thread, don't block)
	api1.start()

	"""
	6. Finally we are done and can start our network (the emulator).
	We can also enter the Mininet CLI to interactively interact
	with our compute resources (just like in default Mininet).
	But we can also implement fully automated experiments that
	can be executed again and again.
	"""
	net.start()
	net.CLI()
	# when the user types exit in the CLI, we stop the emulator
	net.stop()


	def main():
	setLogLevel('info') # set Mininet loglevel
	create_topology1()


	if __name__ == '__main__':
	main()