def test_logical_random(): """Test the creation of a logical random network topology.""" from distriopt import VirtualNetwork virtual = VirtualNetwork.create_random_nw( 20, req_cores=2, req_memory=8000, req_rate=200 ) assert virtual.number_of_nodes() == 20 for node in virtual.nodes(): assert virtual.req_cores(node) == 2 assert virtual.req_memory(node) == 8000 for i, j in virtual.edges(): assert virtual.req_rate(i, j) == 200
import networkx as nx g = nx.Graph() g.add_node("Node_0", cores=3, memory=3000) g.add_node("Node_1", cores=3, memory=3000) g.add_edge("Node_0", "Node_1", rate=20000) virtual_topo = VirtualNetwork(g) # unfeasible, not enough rate physical_topo = PhysicalNetwork.create_test_nw(cores=4, memory=4000, rate=10000, group_interfaces=False) prob = EmbedPartition(virtual_topo, physical_topo) time_solution, status = prob.solve() print(status) exit(1) physical_topo = PhysicalNetwork.from_files("grisou", group_interfaces=False) virtual_topo = VirtualNetwork.create_random_nw(n_nodes=66) # virtual_topo = VirtualNetwork.create_fat_tree(k=4) embed = EmbedPartition(virtual_topo, physical_topo) time_solution = embed.solve() print(time_solution, embed.status) print(embed.solution)
res_link_mapping[(u, v)].append((i, device_id, j)) # build solution from the output self.solution = Solution.build_solution( self.virtual, self.physical, res_node_mapping, res_link_mapping ) self.status = Solved return Solved except (NodeResourceError, NoPathFoundError): # unfeasible, increase the number of partitions to be used pass else: self.status = Infeasible return Infeasible if __name__ == "__main__": from distriopt.embedding import PhysicalNetwork from distriopt import VirtualNetwork physical_topo = PhysicalNetwork.from_files("grisou", group_interfaces=True) virtual_topo = VirtualNetwork.create_random_nw(n_nodes=120, seed=1) # virtual_topo = VirtualNetwork.create_fat_tree(k=4) embed = EmbedBalanced(virtual_topo, physical_topo) time_solution = embed.solve() print(time_solution, embed.status, embed.solution.n_machines_used) exit(1) print(embed.solution)
def time_comparison_grid5000(timelimit, net_type="fat-tree"): """ Custom Network (for the moment fat tree and random are available on virtual.py) """ # create the physical network representation physical = PhysicalNetwork.from_files("grisou") solvers_ilp = {"cplex"} solvers_heu = { "GreedyPartition": EmbedGreedy, "k-balanced": EmbedBalanced, "DivideSwap": EmbedPartition, } res_experiments = {"x": [], "time": {}, "value": {}} for method_name in solvers_ilp | solvers_heu.keys(): res_experiments["time"][method_name] = {} res_experiments["value"][method_name] = {} if net_type == "fat-tree": min_v = 2 max_v = 12 step_size = 2 elif net_type == "random": min_v = 25 max_v = 175 step_size = 25 else: raise ValueError("invalid experiment type") for v in range(min_v, max_v + 1, step_size): res_experiments["x"].append(v) if net_type == "fat-tree": virtual = VirtualNetwork.create_fat_tree(v) else: virtual = VirtualNetwork.create_random_nw(v) # ILP solver prob = EmbedILP(virtual, physical) for solver_name in solvers_ilp: time_solution, status = prob.solve(solver_name=solver_name, timelimit=timelimit) if SolutionStatus[status] != "Solved": res_experiments["time"][solver_name][v] = time_solution res_experiments["value"][solver_name][v] = prob.current_val else: res_experiments["time"][solver_name][v] = time_solution res_experiments["value"][solver_name][ v] = prob.solution.n_machines_used # Heuristic approaches for heu in solvers_heu: prob = solvers_heu[heu](virtual, physical) time_solution, status = prob.solve() if SolutionStatus[status] == "Not Solved": sys.exit("Failed to solve") elif SolutionStatus[status] == "Unfeasible": sys.exit("unfeasible Problem") else: pass res_experiments["time"][heu][v] = time_solution res_experiments["value"][heu][v] = prob.solution.n_machines_used pprint.pprint(res_experiments) with open( os.path.join("results", f"res_{net_type}_{timelimit}s.pickle"), "wb") as res_file: pickle.dump(res_experiments, res_file, protocol=pickle.HIGHEST_PROTOCOL)