def __init__(self, interval=1, logfile = dconf.LinksMonitor_LogFile): self.db = DatabaseHandler() log.info("LINKS MONITOR -- interval: %s -- logfile: %s --\n"%(str(interval),logfile)) log.info("-"*60+"\n") log.info("Read all edges from network...\n") self.links = self.db.getAllEdges() self.interval = interval log.info("Start all counters...\n") self.counters = self._startCounters() self.logfile = logfile log.info("%s\n"%self.printLinksToEdges())
def __init__(self, *args, **kwargs): super(TrafficGenerator, self).__init__(*args, **kwargs) self.scheduler = sched.scheduler(time.time, time.sleep) self.db = DatabaseHandler() self.thread_handlers = [] # IP of the Load Balancer Controller host. try: self._lbc_ip = ipaddress.ip_interface(self.db.getIpFromHostName(dconf.LBC_Hostname)).ip.compressed except: log.info("WARNING: Load balancer controller could not be found in the network\n") self._lbc_ip = None
def __init__(self, requestQueue, responseQueue): super(feedbackThread, self).__init__() # Create queue attributes self.requestQueue = requestQueue self.responseQueue = responseQueue # Read network database self.db = DatabaseHandler() # Fill router cap files self.capFilesDict = self.pickCapFiles() # Data structure that maintains a set of current flows passing # through each router in the last second self.router_flowsets = {} self.updateRouterFlowSets()
def __init__(self, capacity_graph, lock, logfile, median_filter=False, interval=1.01): super(LinksMonitorThread, self).__init__() # Read network database self.db = DatabaseHandler() # Lock object to access capacity graph self.lock = lock # Counters read interval self.interval = interval # Capacity graph object self.cg = capacity_graph # Dictionary that holds the binding between router id and the # router ip in the control network self.ip_to_control = {} # Start router counters self.counters = self._startCounters() # Perform median filter or not? self.median_filter = median_filter # Start router-to-router links self.links = self._startLinks() # Used internally for the logs self.link_to_edge_bindings = self._createLinkToEdgeBindings() # Set log file if logfile: self.logfile = logfile # Write first line with links with open(self.logfile, 'w') as f: f.write(self.printLinkToEdgesLine(self.cg)) else: self.logfile = None
class LinksMonitor(object): """ Implements the class. """ def __init__(self, interval=1, logfile = dconf.LinksMonitor_LogFile): self.db = DatabaseHandler() log.info("LINKS MONITOR -- interval: %s -- logfile: %s --\n"%(str(interval),logfile)) log.info("-"*60+"\n") log.info("Read all edges from network...\n") self.links = self.db.getAllEdges() self.interval = interval log.info("Start all counters...\n") self.counters = self._startCounters() self.logfile = logfile log.info("%s\n"%self.printLinksToEdges()) def printLinksToEdges(self): s = "Links to edges:\n" taken = [] for link, data in self.links.iteritems(): (x, y) = data['edge'] if (x,y) in taken or (y,x) in taken: continue if not('r' in x and 'r' in y): continue taken.append((x,y)) s += link+' -> '+str(data['edge'])+'\n' s += '\n\n' return s def printLinkToEdgesLine(self): s = "" taken = [] for link, data in self.links.iteritems(): (x, y) = data['edge'] if (x,y) in taken or (y,x) in taken: continue taken.append((x,y)) (x,y) = data['edge'] s += link+'->(%s %s),'%(x,y) s += '\n' return s def __str__(self): s = "" taken = [] for link, data in self.links.iteritems(): (x, y) = data['edge'] if (x,y) in taken or (y,x) in taken: continue taken.append((x,y)) s += "%s %s -> load: (%.2f%%)\n"%(link, data['edge'], (100*data['load'])/data['bw']) s += '\n' return s def log(self): """This function logs the state of the links. f is supposed to be an open python file with write access """ f = open(self.logfile, 'a') s = "%s"%time.time() taken = [] for link, data in self.links.iteritems(): (x, y) = data['edge'] if (x,y) in taken or (y,x) in taken: continue taken.append((x,y)) load = data['load'] s += ",(%s %.3f%%)"%(link, load) s += '\n' f.write(s) f.close() def run(self): """ """ log.info("Going inside the run() loop...\n") # Write edges info to log file (first line) f = open(self.logfile, 'a') f.write(self.printLinkToEdgesLine()) f.close() while True: # Update links with fresh data from the counters self.updateLinks() #log.info("Links updated...\n") # Log new values to logfile #log.info("Logging...\n") self.log() # Go to sleep for some interval time #log.info("Going to sleep...\n") time.sleep(self.interval/2) def _startCounters(self): start = time.time() routers = self.db.getRouters() counters_dict = {name:{'routerid':rid, 'counter': SnmpCounters(routerIp=rid)} for name, rid in routers} if time_info: log.info("linksmonitor.py: _startCounters() took %d seconds\n"%(time.time()-start)) return counters_dict def _updateCounters(self): """Reads all counters of the routers in the network. Blocks until the counters have been updated. """ start = time.time() for r, data in self.counters.iteritems(): counter = data['counter'] while (counter.fromLastLecture() < self.interval): pass counter.updateCounters32() if time_info: log.info("linksmonitor.py: _updateCounters() took %d seconds\n"%(time.time()-start)) def _setLinkLoad(self, iface_name, load): name = [name for name, data in self.links.iteritems() if data['interface'] == iface_name] if name != []: name = name[0] self.links[name]['load'] = load def updateLinks(self): # Update the counters first start = time.time() self._updateCounters() log.info("%s\n"%str(self.links)) # Iterate the counters for name, data in self.counters.iteritems(): # Get the counter object for each router counter = data['counter'] # Get the router id for the counter routerid = counter.routerIp # Get ifaces name and load for each router interface iface_names = [data['name'] for data in counter.interfaces] loads = counter.getLoads() elapsed_time = counter.timeDiff bandwidths = [] for ifacename in iface_names: bw_tmp= [d['bw'] for link, d in self.links.iteritems() if d['interface'] == ifacename] if bw_tmp != []: bandwidths.append(bw_tmp[0]) bandwidths = np.asarray(bandwidths) currentPercentages = np.multiply(loads/(np.multiply(bandwidths, elapsed_time)), 100) #log.info("Elapsed time: %s\n"%elapsed_time) #log.info("Loads: %s\n"%str(loads)) #log.info("Bws: %s\n"%str(bandwidths)) # Set link loads by interface name for i, iface_name in enumerate(iface_names): iface_load = currentPercentages[i] self._setLinkLoad(iface_name, iface_load) if time_info: log.info("linksmonitor.py: updateLinks() took %d seconds\n"%(time.time()-start))
def __init__(self, congestionThreshold = 0.95): """It basically reads the network topology from the MyGraphProvider, which is running in another thread because SouthboundManager.run() is blocking. Here we are assuming that the topology does not change. """ # Dictionary that keeps the allocation of the flows in the network paths self.flow_allocation = {} # {prefixA: {flow1 : [path_list], flow2 : [path_list]}, # prefixB: {flow4 : [path_list], flow3 : [path_list]}} # Lock to make flow_allocation thread-safe self.flowAllocationLock = threading.Lock() # From where to read events self.eventQueue = eventQueue # Used to schedule flow alloc. removals self.thread_handlers = {} # Data structure that holds the current forwarding dags for # all advertised destinations in the network self.dagsLock = threading.Lock() self.dags = {} # Set the congestion threshold self.congestionThreshold = congestionThreshold t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Congestion Threshold is set to %.2f%% of the link\n"%(t, (self.congestionThreshold)*100.0)) # Used to stop the thread self._stop = threading.Event() # Object that handles the topology database self.db = DatabaseHandler() # Connects to the southbound controller. Must be called before # create instance of SouthboundManager CFG.read(dconf.C1_Cfg) # Start the Southbound manager in a different thread. self.sbmanager = MyGraphProvider() t = threading.Thread(target=self.sbmanager.run, name="Graph Listener") t.start() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Graph Listener thread started\n"%t) # Blocks until initial graph arrived notification is received # from southbound manager HAS_INITIAL_GRAPH.wait() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Initial graph received\n"%t) # Retreieve network graph from southbound manager self.network_graph = self.sbmanager.igp_graph # Mantains the list of the network prefixes advertised by the OSPF routers self.ospf_prefixes = self._fillInitialOSPFPrefixes() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Initial OSPF prefixes read\n"%t) # Include BW data inside the initial graph. n_router_links = self._countRouter2RouterEdges() self._readBwDataFromDB() i = 0 while not self._bwInAllRouterEdges(n_router_links): i += 1 time.sleep(1) self._readBwDataFromDB() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Bandwidths written in network_graph after %d iterations\n"%(t,i)) # Read the initial graph. We keep this as a copy of the # physical topology. In initial graph, the instantaneous # capacities of the links are kept. self.initial_graph = self.network_graph.copy() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Created IP-names bindings\n"%t) log.info("\tHostname\tip\tsubnet\n") for name, data in self.db.hosts_to_ip.iteritems(): log.info("\t%s\t%s\t%s\n"%(name, data['iface_host'], data['iface_router'])) log.info("\tRouter name\tip\t\n") for name, ip in self.db.routers_to_ip.iteritems(): log.info("\t%s\t%s\n"%(name, ip)) # Create here the initial DAGS for each destination in the # network self._createInitialDags() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Initial DAGS created\n"%t) # Spawn Json listener thread jl = JsonListener(self.eventQueue) jl.start() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Json listener thread created\n"%t) # Create attributes self.feedbackRequestQueue = feedbackRequestQueue self.feedbackResponseQueue = feedbackResponseQueue # Dict in which we save flows pending for allocation feedback self.pendingForFeedback = {} # Spawn FeedbackThread ft = feedbackThread(self.feedbackRequestQueue, self.feedbackResponseQueue) ft.start() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - feedbackThread started\n"%t)
class LBController(object): def __init__(self, congestionThreshold = 0.95): """It basically reads the network topology from the MyGraphProvider, which is running in another thread because SouthboundManager.run() is blocking. Here we are assuming that the topology does not change. """ # Dictionary that keeps the allocation of the flows in the network paths self.flow_allocation = {} # {prefixA: {flow1 : [path_list], flow2 : [path_list]}, # prefixB: {flow4 : [path_list], flow3 : [path_list]}} # Lock to make flow_allocation thread-safe self.flowAllocationLock = threading.Lock() # From where to read events self.eventQueue = eventQueue # Used to schedule flow alloc. removals self.thread_handlers = {} # Data structure that holds the current forwarding dags for # all advertised destinations in the network self.dagsLock = threading.Lock() self.dags = {} # Set the congestion threshold self.congestionThreshold = congestionThreshold t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Congestion Threshold is set to %.2f%% of the link\n"%(t, (self.congestionThreshold)*100.0)) # Used to stop the thread self._stop = threading.Event() # Object that handles the topology database self.db = DatabaseHandler() # Connects to the southbound controller. Must be called before # create instance of SouthboundManager CFG.read(dconf.C1_Cfg) # Start the Southbound manager in a different thread. self.sbmanager = MyGraphProvider() t = threading.Thread(target=self.sbmanager.run, name="Graph Listener") t.start() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Graph Listener thread started\n"%t) # Blocks until initial graph arrived notification is received # from southbound manager HAS_INITIAL_GRAPH.wait() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Initial graph received\n"%t) # Retreieve network graph from southbound manager self.network_graph = self.sbmanager.igp_graph # Mantains the list of the network prefixes advertised by the OSPF routers self.ospf_prefixes = self._fillInitialOSPFPrefixes() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Initial OSPF prefixes read\n"%t) # Include BW data inside the initial graph. n_router_links = self._countRouter2RouterEdges() self._readBwDataFromDB() i = 0 while not self._bwInAllRouterEdges(n_router_links): i += 1 time.sleep(1) self._readBwDataFromDB() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Bandwidths written in network_graph after %d iterations\n"%(t,i)) # Read the initial graph. We keep this as a copy of the # physical topology. In initial graph, the instantaneous # capacities of the links are kept. self.initial_graph = self.network_graph.copy() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Created IP-names bindings\n"%t) log.info("\tHostname\tip\tsubnet\n") for name, data in self.db.hosts_to_ip.iteritems(): log.info("\t%s\t%s\t%s\n"%(name, data['iface_host'], data['iface_router'])) log.info("\tRouter name\tip\t\n") for name, ip in self.db.routers_to_ip.iteritems(): log.info("\t%s\t%s\n"%(name, ip)) # Create here the initial DAGS for each destination in the # network self._createInitialDags() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Initial DAGS created\n"%t) # Spawn Json listener thread jl = JsonListener(self.eventQueue) jl.start() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Json listener thread created\n"%t) # Create attributes self.feedbackRequestQueue = feedbackRequestQueue self.feedbackResponseQueue = feedbackResponseQueue # Dict in which we save flows pending for allocation feedback self.pendingForFeedback = {} # Spawn FeedbackThread ft = feedbackThread(self.feedbackRequestQueue, self.feedbackResponseQueue) ft.start() t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - feedbackThread started\n"%t) def run(self): """Main loop that deals with new incoming events """ while not self.isStopped(): # Get event from the queue (blocking) event = self.eventQueue.get() log.info(lineend) t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - run(): NEW event in the queue\n"%t) log.info("\t* Type: %s\n"%event['type']) if event['type'] == 'newFlowStarted': # Fetch flow from queue flow = event['data'] log.info("\t* Flow: %s\n"%self.toLogFlowNames(flow)) # We assume that upon dealing with a new flow, the # self.dags is not accessed by any other thread with self.dagsLock: with self.flowAllocationLock: # Deal with new flow self.dealWithNewFlow(flow) else: t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - run(): UNKNOWN Event\n"%t) log.info("\t* Event: "%str(event)) def dealWithNewFlow(self, flow): """Called when a new flow arrives. This method should be overwritten by each of the subclasses performing the various algorithms. When this function is called, no algorithm to allocate flows is called. The LBController only keeps track of the default allocations of the flows. """ # In general, this won't be True that often... ecmp = False # Get the communicating interfaces src_iface = flow['src'] dst_iface = flow['dst'] # Get host ip's src_ip = src_iface.ip dst_ip = dst_iface.ip # Get their correspoding networks src_network = src_iface.network dst_network = self.getCurrentOSPFPrefix(dst_iface.compressed) # Get the string-type prefixes src_prefix = src_network.compressed dst_prefix = dst_network.compressed # Get the current path from source to destination currentPaths = self.getActivePaths(src_iface, dst_iface, dst_prefix) if len(currentPaths) > 1: # ECMP is happening ecmp = True t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - dealWithNewFlow(): ECMP is ACTIVE\n"%t) elif len(currentPaths) == 1: ecmp = False t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - dealWithNewFlow(): ECMP is NOT active\n"%t) else: t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - dealWithNewFlow(): ERROR\n"%t) # Detect if flow is going to create congestion if self.canAllocateFlow(flow, currentPaths): t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - dealWithNewFlow(): Flow can be ALLOCATED\n"%t) else: t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - dealWithNewFlow(): Flow will cause CONGESTION\n"%t) # We just allocate the flow to the currentPaths self.addAllocationEntry(dst_prefix, flow, currentPaths) def stop(self): """Stop the LBController correctly """ #Here we should deal with the handlers of the spawned threads #and subprocesses... self._stop.set() def isStopped(self): """Check if LBController is set to be stopped or not """ return self._stop.isSet() def _readBwDataFromDB(self): """Introduces BW data from /tmp/db.topo into the network DiGraph and sets the capacity to the link bandwidth. """ for (x, y, data) in self.network_graph.edges(data=True): if 'C' in x or 'C' in y: # means is the controller... continue if self.network_graph.is_router(x) and self.network_graph.is_router(y): # Fill edges between routers only! xname = self.db.getNameFromIP(x) yname = self.db.getNameFromIP(y) if xname and yname: try: bw = self.db.interface_bandwidth(xname, yname) data['bw'] = int(bw*1e6) data['capacity'] = int(bw*1e6) data['mincap'] = (1-self.congestionThreshold)*(bw*1e6) except: import ipdb; ipdb.set_trace() print "EXCEPTION" print x,y print xname, yname else: t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - _readBwDataFromDB(): ERROR: did not find %s (%s) and %s (%s)\n"%(t, x, xname, y, yname)) def _countRouter2RouterEdges(self): """ Counts how many unidirectional links between routers exist in the network """ routers = [n for (n, data) in self.db.network.iteritems() if data['type'] == 'router'] edges_count = 0 for r in routers: data = self.db.network[r] for n, d in data.iteritems(): if type(d) == dict: try: self.db.routerid(n) except TypeError: pass else: edges_count +=1 return edges_count def _countWrittenBw(self): ep = [1 if 'capacity' in data.keys() and 'bw' in data.keys() else 0 for (x, y, data) in self.network_graph.edges(data=True) if self.network_graph.is_router(x) and self.network_graph.is_router(y)] return sum(ep) def _bwInAllRouterEdges(self, n_router_links): current_count = self._countWrittenBw() return current_count == n_router_links and current_count != 0 def _fillInitialOSPFPrefixes(self): """ Fills up the data structure """ prefixes = [] for prefix in self.network_graph.prefixes: prefixes.append(ipaddress.ip_network(prefix)) return prefixes def getCurrentOSPFPrefix(self, interface_ip): """Given a interface ip address of a host in the mininet network, returns the longest prefix currently being advertised by the OSPF routers. :param interface_ip: string representing a host's interface ip address. E.g: '192.168.233.254/30' Returns: an ipaddress.IPv4Network object """ iface = ipaddress.ip_interface(interface_ip) iface_nw = iface.network iface_ip = iface.ip longest_match = (None, 0) for prefix in self.ospf_prefixes: prefix_len = prefix.prefixlen if iface_ip in prefix and prefix_len > longest_match[1]: longest_match = (prefix, prefix_len) return longest_match[0] def getCurrentDag(self, dst): """ Returns a copy of the current DAG towards destination """ return self.dags[dst].copy() def getInitialDag(self, dst): currentDag = self.getCurrentDag(dst) initialDag = currentDag.copy() # set fibbed edges to notactive and default-ones to active for (u, v, data) in currentDag.edges(data=True): if data['fibbed'] == True: initialDag.get_edge_data(u,v)['active'] = False else: initialDag.get_edge_data(u,v)['active'] = True return initialDag def setCurrentDag(self, dst, dag): """ Sets the current DAG towards destination """ self.dags[dst] = dag def getActiveEdges(self, dag, node): activeEdges = [] for n, data in dag[node].iteritems(): if data['active'] == True: activeEdges.append((node, n)) return activeEdges def getFibbedEdges(self, dag, node): """ Returns the fibbed edges in the """ fibbedEdges = [] for n, data in dag[node].iteritems(): if data['fibbed'] == True: fibbedEdges.append((node, n)) return fibbedEdges def getDefaultEdges(self, dag, node): """Returns the list of edges from node that are used by default in OSPF""" defaultEdges = [] for n, data in dag[node].iteritems(): if data['fibbed'] == False: defaultEdges.append((node, n)) return defaultEdges def switchDagEdgesData(self, dag, path_list, **kwargs): """Sets the data of the edges in path_list to the attributes expressed in kwargs. :param dag: nx.DiGraph representing the dag of the destination subnet that we want to change the edges state. :param path_list: list of paths. E.g: [[A,B,C],[A,G,C]...] :param **kwargs: Edge attributes to be set. """ # Check first if we have a path_list or a edges_list if path_list != [] and isinstance(path_list[0], tuple): # We have an edges list edge_list = path_list elif path_list != [] and isinstance(path_list[0], list): # We have a path_list edge_list = self.getEdgesFromPathList(path_list) if path_list != []: for (u,v) in edge_list: if (u,v) not in dag.edges(): # The initial edges will never get the fibbed # attribute set to True, since they exist in the dag # from the beginning. dag.add_edge(u,v) edge_data = dag.get_edge_data(u,v) dag.get_edge_data(u,v)['fibbed'] = True # Do for all edges edge_data = dag.get_edge_data(u,v) for key, value in kwargs.iteritems(): edge_data[key] = value # Return modified dag when finished return dag def getActiveDag(self, dst): """Returns the DAG being currently deployed in practice for the given destination. """ dag = self.dags[dst] active_dag = dag.copy() action = [active_dag.remove_edge(u,v) for (u,v, data) in active_dag.edges(data=True) if data['active'] == False] return active_dag def getActivePaths(self, src_iface, dst_iface, dst_prefix): """Returns the current active path between two host interface ips and the destination prefix for which we want to retrieve the current active path. :param src_iface, dst_iface: ipaddres.ip_interface object :param dst_prefix: string representing the destination prefix (i.e: 192.168.225.0/25). """ # Get current active DAG for that destination active_dag = self.getActiveDag(dst_prefix) # Get src_iface and dst_iface attached routers routers = list(self.network_graph.routers) src_rid = None dst_rid = None for r in routers: if self.network_graph.has_successor(r, src_iface.network.compressed): d = src_iface.network.compressed if self.network_graph[r][d]['fake'] == False: src_rid = r if self.network_graph.has_successor(r, dst_iface.network.compressed): d = dst_iface.network.compressed if self.network_graph[r][d]['fake'] == False: dst_rid = r if src_rid and dst_rid: # Calculate path and return it active_paths = self._getAllPathsLimDAG(active_dag, src_rid, dst_rid, 0) return active_paths else: t = time.strftime("%H:%M:%S", time.gmtime()) to_print = "%s - getActivePaths(): No paths could be found between %s and %s for subnet prefix %s\n" log.info(to_print%(t, str(src_iface), str(dst_iface), dst_prefix)) return [[]] def _createInitialDags(self): """Populates the self.dags attribute by creating a complete DAG for each destination. In other words, a DAG representing all-shortest paths from any router in the network towards each destination. """ # Log it t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Creating initial DAGs\n"%t) pairs_already_logged = [] apdp = nx.all_pairs_dijkstra_path(self.initial_graph, weight='metric') for prefix in self.network_graph.prefixes: dag = nx.DiGraph() # Get IP of the connected router cr = [r for r in self.network_graph.routers if self.network_graph.has_successor(r, prefix)][0] # Get subnet prefix subnet_prefix = prefix other_routers = [rn for rn in self.network_graph.routers if rn != cr] for r in other_routers: # Get the shortest path dpath = apdp[r][cr] # Are there possibly more paths with the same cost? Let's check: # Get length of the default dijkstra shortest path dlength = self.getPathLength(dpath) # Get all paths with length equal to the defaul path length default_paths = self._getAllPathsLim(self.initial_graph, r, cr, dlength) if len(default_paths) > 1: # ECMP is happening ecmp = True if (cr, r) not in pairs_already_logged and (r, cr) not in pairs_already_logged: to_print = "\tECMP is ACTIVE between %s and %s. There are %d paths with equal cost of %d\n" log.info(to_print%(self.db.getNameFromIP(cr), self.db.getNameFromIP(r), len(default_paths), dlength)) pairs_already_logged.append((cr, r)) elif len(default_paths) == 1: ecmp = False default_paths = [dpath] else: t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - _createInitialDags(): ERROR. At least there should be a path\n"%t) # Iterate through paths and add edges to DAG for path in default_paths: edge_list = zip(path[:-1], path[1:]) for (u,v) in edge_list: if self.network_graph.is_router(u) and self.network_graph.is_router(v): dag.add_edge(u,v) edge_data = dag.get_edge_data(u,v) edge_data['active'] = True edge_data['fibbed'] = False edge_data['default'] = True edge_data['ongoing_flows'] = False # Add DAG to prefix self.dags[subnet_prefix] = dag def getEdgesFromPathList(self, path_list): """Given a list of paths, returns a list of all the edges contained in these paths. """ edge_list = [] for path in path_list: edge_list += zip(path[:-1], path[1:]) return edge_list def isFibbed(self, dst_prefix): """Returns true if there exist fake LSA for that prefix in the network. TODO: probably must be changed... """ return (self.getLiesFromPrefix(dst_prefix) != []) def isFibbedPath(self, dst_prefix, path): """Returns True if it finds a fibbed edge active along the path in dst_prefix DAG """ currentDag = self.getCurrentDag(dst_prefix) for (u,v) in zip(path[:-1], path[1:]): edge_data = currentDag.get_edge_data(u,v) if edge_data['fibbed'] == True and edge_data['active'] == True: # Fake edge found return True return False def addAllocationEntry(self, prefix, flow, path_list): """Add entry in the flow_allocation table. :param prefix: destination prefix. Expressed as an IPv4Interface object :param path_list: List of paths for which this flow will be multi-pathed towards destination prefix: [[A, B, C], [A, D, C]]""" if prefix not in self.flow_allocation.keys(): # prefix not in table self.flow_allocation[prefix] = {flow : path_list} else: self.flow_allocation[prefix][flow] = path_list # Loggin a bit... t = time.strftime("%H:%M:%S", time.gmtime()) to_print = "%s - flow ALLOCATED to Paths\n" log.info(to_print%t) log.info("\t* Dest_prefix: %s\n"%prefix) log.info("\t* Paths (%s): %s\n"%(len(path_list), str([self.toLogRouterNames(path) for path in path_list]))) log.info("\t* Flow: %s\n"%self.toLogFlowNames(flow)) # Current dag for destination current_dag = self.getCurrentDag(prefix) # Iterate the paths for path in path_list: # Calculate paths with only routers path_only_routers = [p for p in path if self.network_graph.is_router(p)] # Extract the edges of the path edges = zip(path_only_routers[:-1], path_only_routers[1:]) # Modify first the current destination dag: ongoing_flows = True current_dag = self.switchDagEdgesData(current_dag, edges, ongoing_flows=True) # Set the current dag self.setCurrentDag(prefix, current_dag) # Define the removeAllocatoinEntry thread t = threading.Thread(target=self.removeAllocationEntry, args=(prefix, flow)) # Start the thread t.start() # Add handler to list and start thread self.thread_handlers[flow] = t def removeAllocationEntry(self, prefix, flow): """ Removes the flow from the allocation entry prefix and restores the corresponding. """ # Wait until flow finishes time.sleep(flow['duration']) # Acquire locks for self.flow_allocation and self.dags # dictionaries self.flowAllocationLock.acquire() self.dagsLock.acquire() log.info(lineend) if prefix not in self.flow_allocation.keys(): # prefix not in table raise KeyError("The is no such prefix allocated: %s"%str(prefix)) else: if flow in self.flow_allocation[prefix].keys(): path_list = self.flow_allocation[prefix].pop(flow, None) else: raise KeyError("%s is not alloacated in this prefix %s"%str(repr(flow))) t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Flow REMOVED from Paths\n"%t) log.info("\t* Dest_prefix: %s\n"%prefix) log.info("\t* Paths (%s): %s\n"%(len(path_list), str([self.toLogRouterNames(path) for path in path_list]))) log.info("\t* Flow: %s\n"%self.toLogFlowNames(flow)) # Check first how many ECMP paths are there ecmp_paths = float(len(path_list)) # Current dag for destination current_dag = self.getCurrentDag(prefix) # Get the active Dag activeDag = self.getActiveDag(prefix) log.info("\t* removeAllocationEntry: initial DAG\n\t %s\n"%str(self.toLogDagNames(activeDag).edges())) # Get current remaining allocated flows for destination remaining_flows = self.getAllocatedFlows(prefix) # Acumulate edges for which there are flows ongoing ongoing_edge_list = [] for (f, f_path_list) in remaining_flows: ongoing_edge_list += self.getEdgesFromPathList(f_path_list) # Iterate the path_list for path in path_list: # Get paths with only routers path_only_routers = [p for p in path if self.network_graph.is_router(p)] # Calculate edges of the path edges = zip(path_only_routers[:-1], path_only_routers[1:]) # Calculate which of these edges can be set to ongoing_flows = False edges_without_flows = [(u, v) for (u, v) in edges if (u, v) not in ongoing_edge_list] # Set them current_dag = self.switchDagEdgesData(current_dag, edges_without_flows, ongoing_flows=False) # Set the new calculated dag to its destination prefix dag self.setCurrentDag(prefix, current_dag) # Remove the lies for the given prefix self.removePrefixLies(prefix, path_list) # Release locks self.flowAllocationLock.release() self.dagsLock.release() def removePrefixLies(self, prefix, path_list): """Remove lies for a given prefix only if there are no more flows allocated for that prefix flowing through some edge of path_list. :param prefix: subnet prefix :param path_list: List of paths from source to destination. E.g: [[A,B,C],[A,D,C]] """ # log a bit t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Removing existing lies...\n"%t) # Get the current DAG for that prefix current_dag = self.getCurrentDag(prefix) # Get the active Dag activeDag = self.getActiveDag(prefix) to_log = "\t* removePrefixLies: initial DAG\n\t %s\n" log.info(to_log%str(self.toLogDagNames(activeDag).edges())) # Check if fibbed edge in paths thereIsFibbedPath = False for path in path_list: thereIsFibbedPath = thereIsFibbedPath or self.isFibbedPath(prefix, path) if not thereIsFibbedPath: # Paths for this flow are not fibbed to_print = "\t* No fibbed edges found in paths %s for prefix: %s\n" log.info(to_print%(str(self.toLogRouterNames(path_list)), prefix)) else: # Get the lies for prefix lsa = self.getLiesFromPrefix(prefix) to_log = "\t* Found fibbed edges in paths: %s\n" log.info(to_log%str(self.toLogRouterNames(path_list))) # Fibbed prefix # Let's check if there are other flows for prefix fist allocated_flows = self.getAllocatedFlows(prefix) # Check if there are flows to prefix going through some # path in path_list. If not, we can delete the # lies. Otherwise, we must wait. if allocated_flows == []: log.info("\t* No allocated flows remain for prefix\n") # Obviously, if no flows are found, we can already # remove the lies. # Set the DAG for the prefix destination to its # original version path_list_edges = [] for path in path_list: path_list_edges += zip(path[:-1], path[1:]) # Remove edges from initial paths for path in path_list: for node in path: # Set edges to initial situation (fibbed=True, # active=False) and (fibbed=False, active=True) default_edges = self.getDefaultEdges(current_dag, node) current_dag = self.switchDagEdgesData(current_dag, default_edges, active=True) fibbed_edges = self.getFibbedEdges(current_dag, node) current_dag = self.switchDagEdgesData(current_dag, fibbed_edges, active=False) # Set current Dag self.setCurrentDag(prefix, current_dag) # Get the active Dag activeDag = self.getActiveDag(prefix) log.info("\t* removePrefixLies: final DAG\n\t %s\n"%str(self.toLogDagNames(activeDag).edges())) # Get the active Dag activeDag = self.getActiveDag(prefix) # Force it to fibbing self.sbmanager.add_dag_requirement(prefix, activeDag.copy()) # Log it log.info("\t* Removed lies for prefix: %s\n"%prefix) log.info("\t* LSAs: %s\n"%(str(lsa))) else: log.info("\t* Some flows for prefix still remain ongoing\n") canRemoveLSA = True # Collect first the edges of the paths to remove path_edges_list = [] for path in path_list: path_edges_list += zip(path[:-1], path[1:]) log.info("Edges of the paths to remove: %s\n"%self.toLogRouterNames(path_edges_list)) for (flow, flow_path_list) in allocated_flows: log.info("flow: %s, path: %s\n"%(self.toLogFlowNames(flow), self.toLogRouterNames(flow_path_list))) # Get all edges used by flows sending to same # destination prefix flow_edges_list = [] for flow_path in flow_path_list: flow_edges_list += zip(flow_path[:-1], flow_path[1:]) check = [True if (u,v) in path_edges_list else False for (u,v) in flow_edges_list] log.info("CHECK list: %s\n"%str(check)) if sum(check) > 0: # Do not remove lsas yet. Other flows ongoing # in one of the paths in path_list canRemoveLSA = False break if canRemoveLSA == False: # Just log it flows = [f for (f, p) in allocated_flows] to_print = "\t* Lies for prefix %s not removed. Flows yet ongoing:\n" log.info(to_print%prefix) for f in flows: log.info("\t\t%s\n"%(self.toLogFlowNames(f))) else: # Set the DAG for the prefix destination to its # original version path_list_edges = [] for path in path_list: path_list_edges += zip(path[:-1], path[1:]) # Remove edges from initial paths for path in path_list: for node in path: # Set edges to initial situation (fibbed=True, # active=False) and (fibbed=False, active=True) default_edges = self.getDefaultEdges(current_dag, node) current_dag = self.switchDagEdgesData(current_dag, default_edges, active=True) fibbed_edges = self.getFibbedEdges(current_dag, node) current_dag = self.switchDagEdgesData(current_dag, fibbed_edges, active=False) self.setCurrentDag(prefix, current_dag) # Get the active Dag activeDag = self.getActiveDag(prefix) # Force it to fibbing self.sbmanager.add_dag_requirement(prefix, activeDag.copy()) # Log it log.info("\t* Removed lies for prefix: %s\n"%prefix) log.info("\t* LSAs: %s\n"%(str(lsa))) log.info(lineend) def getDefaultDijkstraPath(self, network_graph, flow): """Returns an list of network nodes representing the default Dijkstra path given the flow and a network graph. """ # We assume here that Flow is well formed, and that the # interface addresses of the hosts are given. src_name = self.db.getNameFromIP(flow['src'].compressed) src_router_name, src_router_id = self.db.getConnectedRouter(src_name) dst_network = flow['dst'].network.compressed # We take only routers in the route route = nx.dijkstra_path(network_graph, src_router_id, dst_network, weight='metric') return route def getPathLength(self, path): """Given a path as a list of traversed routers, it returns the sum of the weights of the traversed links along the path. """ routers = [n for n in path if self.initial_graph.is_router(n)] edges = [self.initial_graph.get_edge_data(u,v)['metric'] for (u,v) in zip(path[:-1], path[1:])] return sum(edges) def canAllocateFlow(self, flow, path_list): """Returns true if there is at least flow.size bandwidth available in all links along the path (or multiple paths in case of ECMP) from flow.src to src.dst, """ for path in path_list: if self.getMinCapacity(path) < flow.size: return False return True def getMinCapacity(self, path): """Returns the minimum capacity of the edges along the path. :param path: List of network nodes defining a path [A, B, C, D]""" caps_in_path = [] for (u,v) in zip(path[:-1], path[1:]): edge_data = self.initial_graph.get_edge_data(u, v) cap = edge_data.get('capacity', None) caps_in_path.append(cap) try: mini = min(caps_in_path) return mini except ValueError: t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - getMinCapacity(): ERROR: min could not be calculated\n"%t) log.info("\t* Path: %s\n"%path) raise ValueError def getMinCapacityEdge(self, path): """Returns the edge with the minimum capacity along the path. :param path: List of network nodes defining a path [A, B, C, D] """ edges_in_path = [((path[i], path[i+1]), self.initial_graph.get_edge_data(path[i], path[i+1])['capacity']) for i in range(len(path)-1) if 'capacity' in self.initial_graph.get_edge_data(path[i], path[i+1]).keys()] if edges_in_path: minim_c = edges_in_path[0][1] minim_edge = edges_in_path[0][0] for ((x,y), c) in edges_in_path: if c < minim_c: minim_c = c minim_edge = (x,y) return minim_edge else: raise StandardError("%s has no edges!"%str(path)) def getAllocatedFlows(self, prefix): """ Given a prefix, returns a list of tuples: [(flow, path), (flow, path), ...] """ if prefix in self.flow_allocation.keys(): return [(f, p) for f, p in self.flow_allocation[prefix].iteritems()] else: t = time.strftime("%H:%M:%S", time.gmtime()) to_print = "%s - getAllocatedFlows(): WARNING: " to_print += "prefix %s not yet in flow_allocation table\n" #log.info(to_print%(t, prefix)) return [] def getFlowSizes(self, prefix): """Returns the sum of flows with destination prefix, and how many flows there are """ allocated_flows = self.getAllocatedFlows(prefix) sizes = [f['size'] for (f, p) in allocated_flows] return sum(a), len(a) def getLiesFromPrefix(self, prefix): """Retrieves the LSA of the associated prefix from the southbound manager. """ lsa_set = self.sbmanager.advertized_lsa.copy() lsa_list = [] while lsa_set != set(): lsa = lsa_set.pop() dst = lsa.dest if prefix == dst: lsa_list.append(lsa) return lsa_list def getNetworkWithoutFullEdges(self, network_graph, flow_size): """Returns a nx.DiGraph representing the network graph without the edge that can't allocate a flow of flow_size. :param network_graph: IGPGraph representing the network. :param flow_size: Attribute of a flow defining its size (in bytes). """ ng_temp = network_graph.copy() for (x, y, data) in network_graph.edges(data=True): cap = data.get('capacity') if cap and cap <= flow_size and self.network_graph.is_router(x) and self.network_graph.is_router(y): edge = (x, y) ng_temp.remove_edge(x, y) return ng_temp def getAllPathsRanked(self, igp_graph, start, end, ranked_by='length'): """Recursive function that returns an ordered list representing all paths between node x and y in network_graph. Paths are ordered in increasing length. :param igp_graph: IGPGraph representing the network :param start: router if of source's connected router :param end: compressed subnet address of the destination prefix.""" paths = self._getAllPathsLim(igp_graph, start, end, 0) if ranked_by == 'length': ordered_paths = self._orderByLength(paths) elif ranked_by == 'capacity': ordered_paths = self._orderByCapacityLeft(paths) return ordered_paths def _getAllPathsLim(self, igp_graph, start, end, k, path=[], len_path=0, die=False): """Recursive function that finds all paths from start node to end node with maximum length of k. """ if die == False: # Accumulate path length first if path == []: len_path = 0 else: last_node = path[-1] len_path += igp_graph.get_edge_data(last_node, start)['metric'] # Accumulate nodes in path path = path + [start] if start == end: # Arrived to the end. Go back returning everything if k == 0: return [path] elif len_path < k+1: return [path] else: self._getAllPathsLim(igp_graph, start, end, k, path=path, len_path=len_path, die=True) if not start in igp_graph: return [] paths = [] for node in igp_graph[start]: if node not in path: # Ommiting loops here if k == 0: # If we do not want any length limit newpaths = self._getAllPathsLim(igp_graph, node, end, k, path=path, len_path=len_path) for newpath in newpaths: paths.append(newpath) elif len_path < k+1: newpaths = self._getAllPathsLim(igp_graph, node, end, k, path=path, len_path=len_path) for newpath in newpaths: paths.append(newpath) return paths else: # Recursive call dies here pass def _getAllPathsLimDAG(self, dag, start, end, k, path=[]): """Recursive function that finds all paths from start node to end node with maximum length of k. If the function is called with k=0, returns all existing loopless paths between start and end nodes. :param dag: nx.DiGraph representing the current paths towards a certain destination. :param start, end: string representing the ip address of the star and end routers (or nodes) (i.e: 10.0.0.3). :param k: specified maximum path length (here means hops, since the dags do not have weights). """ # Accumulate nodes in path path = path + [start] if start == end: # Arrived to the end. Go back returning everything return [path] if not start in dag: return [] paths = [] for node in dag[start]: if node not in path: # Ommiting loops here if k == 0: # If we do not want any length limit newpaths = self._getAllPathsLimDAG(dag, node, end, k, path=path) for newpath in newpaths: paths.append(newpath) elif len(path) < k+1: newpaths = self._getAllPathsLimDAG(dag, node, end, k, path=path) for newpath in newpaths: paths.append(newpath) return paths def _orderByLength(self, paths): """Given a list of arbitrary paths. It ranks them by lenght (or total edges weight). """ # Search for path lengths ordered_paths = [] for path in paths: pathlen = 0 for (u,v) in zip(path[:-1], path[1:]): if self.network_graph.is_router(v): pathlen += self.network_graph.get_edge_data(u,v)['metric'] ordered_paths.append((path, pathlen)) # Now rank them ordered_paths = sorted(ordered_paths, key=lambda x: x[1]) return ordered_paths def _orderByCapacityLeft(self, paths): """Given a list of arbitrary paths. It ranks them by capacity left (or total edges weight). Function is implemented in TEControllerLab1 """ pass def toLogDagNames(self, dag): """ """ dag_to_print = nx.DiGraph() for (u,v, data) in dag.edges(data=True): u_temp = self.db.getNameFromIP(u) v_temp = self.db.getNameFromIP(v) dag_to_print.add_edge(u_temp, v_temp, **data) return dag_to_print def toLogRouterNames(self, path_list): """ """ total = [] if isinstance(path_list[0], list): for path in path_list: r = [self.db.getNameFromIP(p) for p in path if self.network_graph.is_router(p)] total.append(r) return total elif isinstance(path_list[0], tuple): r = [(self.db.getNameFromIP(u), self.db.getNameFromIP(v)) for (u,v) in path_list if self.network_graph.is_router(u) and self.network_graph.is_router(v)] return r else: return [self.db.getNameFromIP(p) for p in path_list if self.network_graph.is_router(p)] def toLogFlowNames(self, flow): a = "Flow[(%s -> %s): %s, t_o: %s, duration: %s]" return a%(self.db.getNameFromIP(flow.src.compressed), self.db.getNameFromIP(flow.dst.compressed), flow.setSizeToStr(flow.size), flow.setTimeToStr(flow.start_time), flow.setTimeToStr(flow.duration))
class feedbackThread(threading.Thread): """ """ def __init__(self, requestQueue, responseQueue): super(feedbackThread, self).__init__() # Create queue attributes self.requestQueue = requestQueue self.responseQueue = responseQueue # Read network database self.db = DatabaseHandler() # Fill router cap files self.capFilesDict = self.pickCapFiles() # Data structure that maintains a set of current flows passing # through each router in the last second self.router_flowsets = {} self.updateRouterFlowSets() def run(self): """ A dictionary of flow -> possible path list is read from the requestQueue. A dictionary indexed by flow -> allocated path is returned """ queueLookupPeriod = 2 #seconds while True: try: requestFlowsDict = self.requestQueue.get(timeout=queueLookupPeriod) # Blocking read except: # Update flow sets for each router self.updateRouterFlowSets() else: #log.info("*** FEEDBACK REQUEST RECEIVED:\n") #log.info(" %s\n"%str(requestFlowsDict)) self.updateRouterFlowSets() responsePathDict = self.dealWithRequest(requestFlowsDict) if responsePathDict != {}: self.responseQueue.put(responsePathDict) def updateRouterFlowSets(self): for rid, capfile in self.capFilesDict.iteritems(): lines = capfile.readlines() # Create new empty set ridSet = set() for line in lines: try: # Parse ip's src_tmp = line.split(' ')[2] src_ip_tmp = src_tmp.split('.')[:4] src_ip = ipaddress.ip_address('.'.join(map(str, src_ip_tmp))) dst_tmp = line.split(' ')[4].strip(':') dst_ip_tmp = dst_tmp.split('.')[:4] dport = dst_tmp.split('.')[4] dst_ip = ipaddress.ip_address('.'.join(map(str, dst_ip_tmp))) ridSet.update({((src_ip, 's'), (dst_ip, 'd'), dport)}) except: pass # Add set into dictionary self.router_flowsets[rid] = ridSet def dealWithRequest(self, requestFlowsDict): """ """ # Results are saved here responsePathDict = {} start_time = time.time() for f, pl in requestFlowsDict.iteritems(): #flowsSet.update({(f.src, f.sport, f.dst, f.dport)}) # We can't fix the source port from iperf client, so it # will never match. This implies that same host can't same # two UDP flows to the same destination host. flowSet = set() flowSet.update({((f.src.ip, 's'), (f.dst.ip, 'd'), str(f.dport))}) # Set of routers containing flow routers_containing_flow = {self.db.getIpFromHostName(rid) for rid, rset in self.router_flowsets.iteritems() if rset.intersection(flowSet) != set()} #log.info("*** SEARCHING:\n") #log.info(" - %s\n"%f) #log.info(" - %s\n"%str(list(routers_containing_flow))) # Iterate path list and choose which of them is the one in # which the flow is allocated pathSetList = [(p, set(p)) for p in pl] # Retrieve path that matches chosen_path = [(p, pset) for (p, pset) in pathSetList if pset == routers_containing_flow] if len(chosen_path) == 1: responsePathDict[f] = chosen_path[0][0] elif len(chosen_path) == 0: pass else: log.info("*** FEEDBACK THREAD ERROR\n") return responsePathDict def pickCapFiles(self): """ Returns a dictionary indexed by router id -> corresponding .cap file """ return {rid: open(dconf.CAP_Path+rid+'.cap', 'r') for rid in self.db.routers_to_ip.keys()}
class LinksMonitorThread(threading.Thread): """This class defines a thread that will be spawned by the TEController algorithm in order to periodically update the available capacities for the network links. It is passed a capacity graph and a lock from its parent, and it modifies it periodically. """ def __init__(self, capacity_graph, lock, logfile, median_filter=False, interval=1.01): super(LinksMonitorThread, self).__init__() # Read network database self.db = DatabaseHandler() # Lock object to access capacity graph self.lock = lock # Counters read interval self.interval = interval # Capacity graph object self.cg = capacity_graph # Dictionary that holds the binding between router id and the # router ip in the control network self.ip_to_control = {} # Start router counters self.counters = self._startCounters() # Perform median filter or not? self.median_filter = median_filter # Start router-to-router links self.links = self._startLinks() # Used internally for the logs self.link_to_edge_bindings = self._createLinkToEdgeBindings() # Set log file if logfile: self.logfile = logfile # Write first line with links with open(self.logfile, 'w') as f: f.write(self.printLinkToEdgesLine(self.cg)) else: self.logfile = None def _createLinkToEdgeBindings(self): bindings = {} taken = [] i = 0 for (u, v) in self.cg.edges(): #if (u, v) in taken or (v, u) in taken: # continue #else: #taken.append((u,v)) bindings[i] = (u, v) i = i + 1 return bindings def run(self): while True: start_time = time.time() # Read capacities from SNMP self.updateLinksCapacities() # Log them in the log file too if self.logfile: self.logLinksLoads() #log.info("It took %.3f to update and log the new capacities readout\n"%(time.time()-start_time)) # Go to sleep remaining time to interval elapsed_time = (time.time() - start_time) if elapsed_time < self.interval: sleep_time = self.interval - elapsed_time time.sleep(sleep_time) else: pass def updateLinksCapacities(self): """ """ # Update counters first self._updateCounters() # List in which we hold the already updated interfaces interfaces_updated = [] for router, counter in self.counters.iteritems(): # Get router interfaces names iface_names = [data['name'] for data in counter.interfaces] # Get current loads for router interfaces # (difference from last read-out) loads = counter.getLoads() # Get the time that has elapsed since last read-out elapsed_time = counter.timeDiff currentThroughputs = loads/float(elapsed_time) # Retrieve the bandwidths for router-connected links bandwidths = [] for ifacename in iface_names: # Get bandwidth for link in that interface bw_tmp = [edge_data['bw'] for edge, edge_data in self.links.iteritems() if edge_data['interface'] == ifacename] if bw_tmp != []: bandwidths.append(bw_tmp[0]) else: bandwidths.append(0) # Convert as a numpy array bandwidths = np.asarray(bandwidths) # Calculate available capacities availableCaps = bandwidths - currentThroughputs # Set link available capacities by interface name # Get lock first for i, iface_name in enumerate(iface_names): if iface_name not in interfaces_updated: iface_availableCap = availableCaps[i] # Get interface of other side of the link edge = [edge for edge, data in self.links.iteritems() if data['interface'] == iface_name] if edge == []: # Means is not a router-to-router link pass else: (x,y) = edge[0] #iface_opposed_name = self.links[(y,x)]['interface'] self.updateLinkCapacity(iface_name, iface_availableCap) #self.updateLinkCapacity(iface_opposed_name, iface_availableCap) interfaces_updated.append(iface_name) #interfaces_updated.append(iface_opposed_name) def logLinksLoads(self): # Make a copy of the self.cg and release the lock with self.lock: cg_copy = self.cg.copy() with open(self.logfile, 'a') as f: s = "%s"%time.time() to_iterate = sorted(self.link_to_edge_bindings.keys()) for index in to_iterate: (x,y) = self.link_to_edge_bindings[index] link_index = index availableCapactiy = cg_copy[x][y]['capacity'] bandwidth = cg_copy[x][y]['bw'] usedCapacity = bandwidth - availableCapactiy load = (usedCapacity/float(bandwidth))*100.0 s += ",(L%d %.3f%%)"%(link_index, load) s += '\n' f.write(s) def _updateCounters(self): """Updates all interface counters of the routers in the network. Blocks until the counters have been updated. """ for r, counter in self.counters.iteritems(): #start_time = time.time() while (counter.fromLastLecture() < self.interval): pass #log.info("I was stuck %.3f seconds waiting for interval to pass\n"%(time.time()-start_time)) counter.updateCounters32() def updateLinkCapacity(self, iface_name, new_capacity): # Get nodes from the link with such iface_name edge = [edge for edge, data in self.links.iteritems() if data['interface'] == iface_name] if edge != []: (x, y) = edge[0] else: return with self.lock: if self.median_filter == True: # Perform median filter of window size = 3 window = self.cg[x][y]['window'] cap = self.cg[x][y]['capacity'] if len(window) == 3: #median filter window size = 3 # Remove last element window.pop() # Add new capacity readout to filter window window = [new_capacity] + window # Perform the median filtering # Sort them by magnitude window_ordered = window[:] window_ordered.sort() # Take the median element chosen_cap = window_ordered[len(window_ordered)/2] # Update edge data self.cg[x][y]['window'] = window self.cg[x][y]['capacity'] = chosen_cap else: window = self.cg[x][y]['window'] if len(window) == 3: window.pop() # Rate of new capacity wrt previous one rate = new_capacity/float(window[0]) if rate < 2.05 and rate > 1.95: # Double read-out found new_capacity = window[0] window = [new_capacity] + window # No median filter but we store also the last 3 # capacities in the window self.cg[x][y]['window'] = window self.cg[x][y]['capacity'] = new_capacity else: window = [new_capacity] + window self.cg[x][y]['window'] = window self.cg[x][y]['capacity'] = new_capacity else: window = [new_capacity] + window self.cg[x][y]['window'] = window self.cg[x][y]['capacity'] = new_capacity def printLinkToEdgesLine(self, capacity_graph): s = "" to_iterate = sorted(self.link_to_edge_bindings.keys()) for index in to_iterate: (x,y) = self.link_to_edge_bindings[index] link_number = index x_name = self.db.getNameFromIP(x) y_name = self.db.getNameFromIP(y) s += ("L%d"%link_number)+'->(%s %s),'%(x_name, y_name) s += '\n' return s def _startCounters(self): """This function iterates the routers in the network and creates a dictionary mapping each router to a SnmpCounter object. Returns a dict: routerip -> SnmpCounters. """ counters_dict = {} with self.lock: for r in self.cg.routers: # Get control ip for router r_control_ip = self.db.getRouterControlIp(r) self.ip_to_control[r] = r_control_ip if r_control_ip: counters_dict[r] = SnmpCounters(routerIp = r_control_ip) else: counters_dict[r] = SnmpCounters(routerIp = r) return counters_dict def _startLinks(self): """ Only router-to-router links are of interest (since we can't modify routes inside subnetworks). """ return self.db.getAllRouterEdges()
class TrafficGenerator(Base): """Object that creates a Traffic Generator in the network. """ def __init__(self, *args, **kwargs): super(TrafficGenerator, self).__init__(*args, **kwargs) self.scheduler = sched.scheduler(time.time, time.sleep) self.db = DatabaseHandler() self.thread_handlers = [] # IP of the Load Balancer Controller host. try: self._lbc_ip = ipaddress.ip_interface(self.db.getIpFromHostName(dconf.LBC_Hostname)).ip.compressed except: log.info("WARNING: Load balancer controller could not be found in the network\n") self._lbc_ip = None def _signal_handler(self, signal, frame): """ Terminates trafficgenerator thread gracefully. """ log.info("Signal caught... shuting down!\n") # collect all open _createFlow threads for t in self.thread_handlers: # t.join() log.info("_createFlow thread terminated\n") # exit sys.exit(0) def informLBController(self, flow): """Part of the code that deals with the JSON interface to inform to LBController a new flow created in the network. """ url = "http://%s:%s/newflowstarted" % (self._lbc_ip, dconf.LBC_JsonPort) log.info("\t Informing LBController\n") log.info("\t * Flow: %s\n" % self.toLogFlowNames(flow)) log.info("\t * Url: %s\n" % url) try: requests.post(url, json=flow.toJSON()) except Exception: log.info("ERROR: LBC could not be informed!\n") log.info("LOG: Exception in user code:\n") log.info("-" * 60 + "\n") log.info(traceback.print_exc()) log.info("-" * 60 + "\n") def toLogFlowNames(self, flow): a = "(%s -> %s): %s, t_o: %s, duration: %s" return a % ( self.db.getNameFromIP(flow.src.compressed), self.db.getNameFromIP(flow.dst.compressed), flow.setSizeToStr(flow.size), flow.setTimeToStr(flow.start_time), flow.setTimeToStr(flow.duration), ) def createFlow(self, flow): """Calls _createFlow in a different Thread (for efficiency) """ # Start thread that will send the Flask request t = Thread(target=self._createFlow, name="_createFlow", args=(flow,)).start() # Append thread handler to list self.thread_handlers.append(t) def _createFlow(self, flow): """Creates the corresponding iperf command to actually install the given flow in the network. This function has to call self.informLBController! """ # Sleep after it is your time to start time.sleep(flow["start_time"]) # Call to informLBController if it is active if self._lbc_ip: self.informLBController(flow) # time.sleep(0.2) # Create new flow with hosts ip's instead of interfaces # Iperf only understands ip's flow2 = Flow( src=flow["src"].ip.compressed, dst=flow["dst"].ip.compressed, sport=flow["sport"], dport=flow["dport"], size=flow["size"], start_time=flow["start_time"], duration=flow["duration"], ) url = "http://%s:%s/startflow" % (flow2["src"], dconf.Hosts_JsonPort) t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Starting Flow\n" % t) log.info("\t Sending request to host %s\n" % str(flow["src"])) log.info("\t * Flow: %s\n" % self.toLogFlowNames(flow)) log.info("\t * Url: %s\n" % url) # Send request to host to start new iperf client session try: requests.post(url, json=flow2.toJSON()) except Exception: log.info("ERROR: Request could not be sent to Host!\n") log.info("LOG: Exception in user code:\n") log.info("-" * 60 + "\n") log.info(traceback.print_exc()) log.info("-" * 60 + "\n") def stopFlow(self, flow): """Instructs host to stop iperf client session (flow). """ flow2 = Flow( src=flow["src"].ip.compressed, dst=flow["dst"].ip.compressed, sport=flow["sport"], dport=flow["dport"], size=flow["size"], start_time=flow["start_time"], duration=flow["duration"], ) url = "http://%s:%s/stopflow" % (flow2["src"], dconf.Hosts_JsonPort) t = time.strftime("%H:%M:%S", time.gmtime()) log.info("%s - Stopping Flow\n" % t) log.info("\t Sending request to host to stop flow %s\n" % str(flow["src"])) log.info("\t * Flow: %s\n" % self.toLogFlowNames(flow)) log.info("\t * Url: %s\n" % url) # Send request to host to start new iperf client session try: requests.post(url, json=flow2.toJSON()) except Exception: log.info("ERROR: Stop flow request could not be sent to Host!\n") def createRandomFlow(self): """Creates a random flow in the network """ pass def scheduleRandomFlows(self, ex_time=60, max_size="40M"): """Creates a random schedule of random flows in the network. This will be useful later to evaluate the performance of the LBController. """ pass def scheduleFileFlows(self, flowfile): """Schedules the flows specified in the flowfile """ f = open(flowfile, "r") flows = f.readlines() if flows: for flowline in flows: flowline = flowline.replace(" ", "").replace("\n", "") if flowline != "" and flowline[0] != "#": try: [s, d, sp, dp, size, s_t, dur] = flowline.strip("\n").split(",") # Get hosts IPs src_iface = self.db.getIpFromHostName(s) dst_iface = self.db.getIpFromHostName(d) except Exception: log.info("EP, SOMETHING HAPPENS HERE\n") src_iface = None dst_iface = None if src_iface != None and dst_iface != None: flow = Flow( src=src_iface, dst=dst_iface, sport=sp, dport=dp, size=size, start_time=s_t, duration=dur ) # Schedule flow creation self.scheduler.enter(0, 1, self.createFlow, ([flow])) else: log.info("ERROR! Hosts %s and/or %s do not exist in the network!\n" % (s, d)) # Make the scheduler run after file has been parsed self.scheduler.run() else: log.info("\t No flows to schedule in file\n")