# # A library to manage ARCFIRE experiments # # Copyright (C) 2017 Nextworks S.r.l. # Copyright (C) 2017 imec # # Sander Vrijders # Dimitri Staessens # Vincenzo Maffione # Marco Capitani # Nick Aerts # # This library is free software; you can redistribute it and/or # modify it under the terms of the GNU Lesser General Public # License as published by the Free Software Foundation; either # version 2.1 of the License, or (at your option) any later version. # # This library is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU # Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public # License along with this library; if not, write to the Free Software # Foundation, Inc., http://www.fsf.org/about/contact/. # import abc import os import stat import time import shutil from enum import Enum import rumba.log as log logger = log.get_logger(__name__) tmp_dir = '/tmp/rumba' try: os.mkdir(tmp_dir) os.chmod(tmp_dir, stat.S_IRWXU | stat.S_IRWXG | stat.S_IRWXO) except OSError: # Already there, nothing to do pass cache_parent_dir = os.path.join(os.path.expanduser("~"), '.cache/') try: os.mkdir(cache_parent_dir) except OSError: # Already there, nothing to do pass cache_dir = os.path.join(os.path.expanduser("~"), '.cache/rumba/') try: os.mkdir(cache_dir) except OSError: # Already there, nothing to do pass # Represents generic testbed info # # @username [string] user name # @password [string] password # @proj_name [string] project name # @exp_name [string] experiment name # class Testbed(object): def __init__(self, exp_name, username, password, proj_name, http_proxy=None, system_logs=None): self.username = username self.password = password self.proj_name = proj_name self.exp_name = exp_name self.http_proxy = http_proxy self.flags = {'no_vlan_offload': False} if system_logs is None: self.system_logs = ['/var/log/syslog'] elif isinstance(system_logs, str): self.system_logs = [system_logs] else: self.system_logs = system_logs def swap_in(self, experiment): """ Swaps experiment in :param experiment: The experiment. """ for node in experiment.nodes: node.executor = self.executor self._swap_in(experiment) for dif in experiment.dif_ordering: if isinstance(dif, ShimEthDIF): dif.link_quality.apply(dif) @abc.abstractmethod def _swap_in(self, experiment): logger.info("_swap_in(): nothing to do") def swap_out(self, experiment): """ Swaps experiment out :param experiment: The experiment. """ self._swap_out(experiment) @abc.abstractmethod def _swap_out(self, experiment): logger.info("swap_out(): nothing to do") # Base class for DIFs # # @name [string] DIF name # class DIF(object): def __init__(self, name, members=None): self.name = name if members is None: members = list() self.members = members self.ipcps = list() def __repr__(self): s = "DIF %s" % self.name return s def __hash__(self): return hash(self.name) def __eq__(self, other): return other is not None and self.name == other.name def __neq__(self, other): return not self == other def add_member(self, node): self.members.append(node) def del_member(self, node): self.members.remove(node) def get_ipcp_class(self): return IPCP # Shim over UDP # class ShimUDPDIF(DIF): def __init__(self, name, members=None): DIF.__init__(self, name, members) def get_ipcp_class(self): return ShimUDPIPCP # Shim over Ethernet # # @link_speed [int] Speed of the Ethernet network, in Mbps # class ShimEthDIF(DIF): def get_e_id(self): return "ShimEthDIF." + self.name def __init__(self, name, members=None, link_quality=None): DIF.__init__(self, name, members) self._link_quality = link_quality if link_quality is not None else LinkQuality() def get_ipcp_class(self): return ShimEthIPCP def add_member(self, node): super(ShimEthDIF, self).add_member(node) if len(self.members) > 2: raise Exception("More than 2 members in %s!" % self.name) @property def link_quality(self): return self._link_quality @link_quality.setter def link_quality(self, _link_quality): if not _link_quality: raise ValueError("Cannot set link_quality to None, use del " "link_quality to reset") self._link_quality = _link_quality _link_quality.apply(self) @link_quality.deleter def link_quality(self): self._link_quality.deactivate(self) def set_delay(self, delay=0, jitter=None, correlation=None, distribution=None): """ Set the delay parameters of the underlying link. Parameters as in :py:meth:`.Delay.__init__` :param delay: average delay in ms :type delay: :py:class:`int` :param jitter: jitter in ms :type jitter: :py:class:`int` :param correlation: correlation in % :type correlation: :py:class:`int` :param distribution: delay distribution, defaults to a Normal distribution :type distribution: :py:class:`.Distribution` """ new_delay = Delay(delay, jitter, correlation, distribution) new_quality = LinkQuality.clone(self.link_quality, delay=new_delay) self.link_quality = new_quality def set_loss(self, loss=0, correlation=None): """ Set the loss parameter of the underlying link. Parameters as in :py:meth:`.Loss.__init__` :param loss: loss in percentage :type loss: :py:class:`int` or :py:class:`float` :param correlation: correlation in percentage :type correlation: :py:class:`int` or :py:class:`float` """ new_loss = Loss(loss, correlation) new_quality = LinkQuality.clone(self.link_quality, loss=new_loss) self.link_quality = new_quality def set_rate(self, rate=None): """ Set the rate parameter of the underlying link. :param rate: The desired rate in mbps :type rate: :py:class:`int` """ new_quality = LinkQuality.clone(self.link_quality, rate=rate) self.link_quality = new_quality def set_quality(self, delay, loss, rate): """ Configure the basic quality parameters of the underlying link :param delay: the link delay, in ms :type delay: :py:class:`int` :param loss: the link loss, as a percentage :type loss: :py:class:`float` or :py:class:`int` :param rate: the link rate in mbps :type rate: :py:class:`int` """ new_quality = LinkQuality(delay, loss, rate) self.link_quality = new_quality # Normal DIF # # @policies [dict] Policies of the normal DIF. Format: # dict( componentName: str --> comp_policy: # dict( policy_name: str --> parameters: # dict( name: str --> value: str ))) # class NormalDIF(DIF): def __init__(self, name, members=None, policy=None): DIF.__init__(self, name, members) if policy is None: policy = Policy(self) self.policy = policy def add_policy(self, comp, pol, **params): self.policy.add_policy(comp, pol, **params) def del_policy(self, comp=None, policy_name=None): self.policy.del_policy(comp, policy_name) def show(self): s = DIF.__repr__(self) for comp, pol_dict in self.policy.get_policies().items(): for pol, params in pol_dict.items(): s += "\n Component %s has policy %s with params %s" \ % (comp, pol, params) return s class Distribution(Enum): NORMAL = 1 PARETO = 2 PARETONORMAL = 3 class Delay(object): def __init__(self, delay=0, jitter=None, correlation=None, distribution=None): """ Configure link delay :param delay: average delay in ms :type delay: :py:class:`int` :param jitter: jitter in ms :type jitter: :py:class:`int` :param correlation: correlation in % :type correlation: :py:class:`int` :param distribution: delay distribution, defaults to a Normal distribution :type distribution: :py:class:`.Distribution` """ if delay < 0: raise ValueError("Delay needs to be at least 0") if jitter and not jitter > 0: raise ValueError("Jitter needs to be higher than 0") if (not jitter) and correlation: raise ValueError("Correlation requires a value for jitter") if correlation and (correlation < 0 or correlation > 100): raise ValueError("Correlation needs to be between 0 and 100") self._delay = delay self._jitter = jitter self._correlation = correlation self._distribution = distribution @property def delay(self): return self._delay @property def jitter(self): return self._jitter @property def correlation(self): return self._correlation @property def distribution(self): return self._distribution def build_command(self): opts = ["delay %ims" % self.delay] if self.jitter: opts.append("%ims" % self.jitter) if self.correlation: opts.append("%f%%" % self.correlation) if self.distribution: opts.append("distribution %s" % self.distribution.name.lower()) return " ".join(opts) class Loss(object): def __init__(self, loss, correlation=None): """ Configure link loss :param loss: loss in percentage :type loss: :py:class:`int` or :py:class:`float` :param correlation: correlation in percentage :type correlation: :py:class:`int` or :py:class:`float` """ if loss and (loss < 0 or loss > 100): raise ValueError("Loss needs to be between 0 and 100") if correlation and (correlation < 0 or correlation > 100): raise ValueError("Correlation needs to be between 0 and 100") self._loss = loss self._correlation = correlation @property def loss(self): return self._loss @property def correlation(self): return self._correlation def build_command(self): opts = ["loss %f%%" % self.loss] if self.correlation: opts.append("%f%%" % self.correlation) return " ".join(opts) class LinkQuality(object): _active = set() @classmethod def clone(cls, old_quality, delay=None, loss=None, rate=None): """ Clone old_quality, updating it with the provided parameters if present :param old_quality: A :py:class`.LinkQuality` instance to use as a base :type old_quality: :py:class`.LinkQuality` :param delay: Delay object holding delay configuration or number corresponding to delay in ms :type delay: :py:class:`.Delay` or :py:class:`int` :param loss: Loss object holding delay configuration or number corresponding to loss percentage :type loss: :py:class:`.Loss` or :py:class:`float` :param rate: The rate of the link in mbit :type rate: :py:class:`int` :return: a new :py:class`.LinkQuality` instance :rtype :py:class`LinkQuality` """ if delay is None: delay = old_quality.delay if loss is None: loss = old_quality.loss if rate is None: rate = old_quality.rate return LinkQuality(delay, loss, rate) def __init__(self, delay=None, loss=None, rate=None): """ Link quality configuration :param delay: Delay object holding delay configuration or number corresponding to delay in ms :type delay: :py:class:`.Delay` or :py:class:`int` :param loss: Loss object holding delay configuration or number corresponding to loss percentage :type loss: :py:class:`.Loss` or :py:class:`float` :param rate: The rate of the link in mbit :type rate: :py:class:`int` """ if rate and not rate > 0: raise ValueError("Rate needs to be higher than 0") if isinstance(delay, int): delay = Delay(delay) if isinstance(loss, int) or isinstance(loss, float): loss = Loss(loss) self._delay = delay self._loss = loss self._rate = rate @property def delay(self): return self._delay @property def loss(self): return self._loss @property def rate(self): return self._rate def build_command(self, ipcp): cmd = [] if ipcp in LinkQuality._active: cmd.append("tc qdisc change dev %s root netem" % ipcp.ifname) else: cmd.append("tc qdisc add dev %s root netem" % ipcp.ifname) if self.delay: cmd.append(self.delay.build_command()) if self.loss: cmd.append(self.loss.build_command()) if self.rate: cmd.append("rate %imbit" % self.rate) return " ".join(cmd) def apply(self, shim): if not (self.delay or self.loss or self.rate): self.deactivate(shim) else: for ipcp in shim.ipcps: if not ipcp.ifname: logger.error("Could not apply LinkQuality to IPCP because " "the interface name is None") continue ipcp.node.execute_command(self.build_command(ipcp), as_root=True) LinkQuality._active.add(ipcp) def deactivate(self, shim): for ipcp in shim.ipcps: if ipcp not in LinkQuality._active: continue if not ipcp.ifname: logger.error("Could not remove LinkQuality from IPCP because " "the interface name is None") continue ipcp.node.execute_command("tc qdisc del dev %s root " "netem" % ipcp.ifname, as_root=True) LinkQuality._active.remove(ipcp) # SSH Configuration # class SSHConfig(object): def __init__(self, hostname, port=22, proxy_server=None): self.username = None self.password = None self.hostname = hostname self.port = port self.proxy_server = proxy_server self.client = None self.proxy_client = None self.http_proxy = None def set_username(self, username): self.username = username def set_password(self, password): self.password = password def set_http_proxy(self, proxy): self.http_proxy = proxy # A node in the experiment # # @difs: DIFs the node will have an IPCP in # @dif_registrations: Which DIF is registered in which DIF # @policies: dict of dif -> policy to apply for that dif in this node # # class Node(object): def get_e_id(self): return "Node." + self.name def __init__(self, name, difs=None, dif_registrations=None, policies=None, machine_type=None): self.name = name if difs is None: difs = list() self.difs = difs for dif in self.difs: dif.add_member(self) if dif_registrations is None: dif_registrations = dict() self.dif_registrations = dif_registrations self.machine_type = machine_type self.ssh_config = SSHConfig(name) self.ipcps = [] self.policies = dict() self.has_tcpdump = False if policies is None: policies = dict() for dif in self.difs: if hasattr(dif, 'policy'): # check if the dif supports policies self.policies[dif] = policies.get(dif, Policy(dif, self)) self.executor = None # will be set by testbed on swap_in self.startup_command = None # will be set by prototype self._validate() def get_ipcp_by_dif(self, dif): for ipcp in self.ipcps: if ipcp.dif == dif: return ipcp def _undeclared_dif(self, dif): if dif not in self.difs: raise Exception("Invalid registration: node %s is not declared " "to be part of DIF %s" % (self.name, dif.name)) def _validate(self): # Check that DIFs referenced in self.dif_registrations # are part of self.difs for upper in self.dif_registrations: self._undeclared_dif(upper) for lower in self.dif_registrations[upper]: self._undeclared_dif(lower) def __repr__(self): s = "Node " + self.name + ":\n" s += " DIFs: [ " s += " ".join([d.name for d in self.difs]) s += " ]\n" s += " DIF registrations: [ " rl = [] for upper in self.dif_registrations: difs = self.dif_registrations[upper] x = "%s => [" % upper.name x += " ".join([lower.name for lower in difs]) x += "]" rl.append(x) s += ", ".join(rl) s += " ]\n" return s def __hash__(self): return hash(self.name) def __eq__(self, other): return other is not None and self.name == other.name def __neq__(self, other): return not self == other def add_dif(self, dif): self.difs.append(dif) dif.add_member(self) if hasattr(dif, 'policy'): self.policies[dif] = Policy(dif, self) self._validate() def del_dif(self, dif): self.difs.remove(dif) dif.del_member(self) try: del self.policies[dif] except KeyError: # It was not in there, so nothing to do pass self._validate() def add_dif_registration(self, upper, lower): self.dif_registrations[upper].append(lower) self._validate() def del_dif_registration(self, upper, lower): self.dif_registrations[upper].remove(lower) self._validate() def add_policy(self, dif, component_name, policy_name, **parameters): self.policies[dif].add_policy(component_name, policy_name, **parameters) def del_policy(self, dif, component_name=None, policy_name=None): self.policies[dif].del_policy(component_name, policy_name) def get_policy(self, dif): return self.policies[dif] def execute_commands(self, commands, as_root=False, time_out=3, use_proxy=False): return self.executor.execute_commands(self, commands, as_root, time_out) def execute_command(self, command, as_root=False, time_out=3, use_proxy=False): return self.executor.execute_command(self, command, as_root, time_out) def write_text_to_file(self, text, file_name): # ssh_support.write_text_to_file( # self.ssh_config, # self.ssh_config, # text, # file_name # ) return def copy_file(self, path, destination): self.executor.copy_file(self, path, destination) def copy_files(self, paths, destination): self.executor.copy_files(self, paths, destination) def fetch_files(self, paths, destination, sudo=False): self.executor.fetch_files(self, paths, destination, sudo) def fetch_file(self, path, destination, sudo=False): self.executor.fetch_file(self, path, destination, sudo) def set_link_state(self, dif, state): ipcp = self.get_ipcp_by_dif(dif) self.execute_command('ip link set dev ' + ipcp.ifname + ' ' + state, as_root=True) # Base class representing an IPC Process to be created in the experiment # # @name [string]: IPCP name # @node: Node where the IPCP gets created # @dif: the DIF the IPCP belongs to # class IPCP(object): def __init__(self, name, node, dif): self.name = name self.node = node self.dif = dif self.registrations = [] # Is this IPCP the first in its DIF, so that it does not need # to enroll to anyone ? self.dif_bootstrapper = False def __repr__(self): return "{IPCP=%s,DIF=%s,N-1-DIFs=(%s)%s}" % \ (self.name, self.dif.name, ' '.join([dif.name for dif in self.registrations]), ',bootstrapper' if self.dif_bootstrapper else '' ) def __hash__(self): return hash((self.name, self.dif.name)) def __eq__(self, other): return other is not None and self.name == other.name \ and self.dif == other.dif def __neq__(self, other): return not self == other class ShimEthIPCP(IPCP): def __init__(self, name, node, dif, ifname=None): IPCP.__init__(self, name, node, dif) self.ifname = ifname class ShimUDPIPCP(IPCP): def __init__(self, name, node, dif): IPCP.__init__(self, name, node, dif) # TODO: add IP and port # Class representing DIF and Node policies # # @dif: the dif this policy is applied to. # @node: the node # class Policy(object): def __init__(self, dif, node=None, policies=None): self.dif = dif # type: NormalDIF self.node = node if policies is None: self._dict = dict() else: self._dict = policies def add_policy(self, component_name, policy_name, **parameters): self._dict.setdefault(component_name, dict())[policy_name] = parameters # # Fetches effective policy info # def get_policies(self, component_name=None, policy_name=None): policy = self._superimpose() if component_name is None: return policy._dict elif policy_name is None: return policy._dict[component_name] else: return policy._dict[component_name][policy_name] def del_policy(self, component_name=None, policy_name=None): if component_name is None: self._dict = dict() elif policy_name is None: del self._dict[component_name] else: del self._dict[component_name][policy_name] # # Merges this policy into that of its dif, obtaining # the effective policy acting on self.node. # def _superimpose(self): if self.node is None: return self other = self.dif.policy base = dict(other._dict) base.update(self._dict) return Policy(self.dif, self.node, base) def __eq__(self, other): if not isinstance(other, Policy): return False else: return other.dif == self.dif \ and other.node == self.node \ and other._dict == self._dict def __str__(self): node_str = (" Node: " + self.node) if self.node is not None else "" return "Policy[Dif: %(dif)s,%(node_str)s Dict: %(dict)s]" \ % {"dif": self.dif, "node_str": node_str, "dict": self._dict} def __repr__(self): node_str = (" Node: " + self.node) if self.node is not None else "" s = "Policy[ Dif: %(dif)s,%(node_str)s" \ % {"dif": self.dif, "node_str": node_str} comps = [] for component in self._dict: for policy in self._dict[component]: comps.append("\n Component %s has policy %s with params %s" % (component, policy, self._dict[component][policy])) s += ",".join(comps) s += "\n]\n" return s # Base class for ARCFIRE experiments # # @name [string] Name of the experiment # @nodes: Nodes in the experiment # class Experiment(object): __metaclass__ = abc.ABCMeta def __init__(self, testbed, nodes=None, git_repo=None, git_branch=None, log_dir=None, prototype_logs=None): if nodes is None: nodes = list() self.nodes = nodes self.git_repo = git_repo self.git_branch = git_branch self.testbed = testbed # the strategy employed for completing the enrollment phase in # the different DIFs self.enrollment_strategy = 'minimal' # 'full-mesh', 'manual' # the strategy employed for setting up the data transfer # networks in the DIFs after enrollment self.dt_strategy = 'full-mesh' # 'minimal', 'manual' self.dif_ordering = [] self.enrollments = [] # a list of per-DIF lists of enrollments self.dt_flows = [] # a list of per-DIF lists of data transfer flows self.mgmt_flows = [] # a list of per-DIF lists of management flows # Determine log directory if log_dir is None: # If it is None, use /tmp/rumba/{project} # Wipe it and make it again exp_name = self.testbed.exp_name.replace('/', '_') # Just in case log_dir = os.path.join(tmp_dir, exp_name) shutil.rmtree(log_dir, ignore_errors=True) os.mkdir(log_dir) self.log_dir = log_dir if not os.path.isdir(self.log_dir): raise Exception('Destination "%s" is not a directory. ' 'Cannot fetch logs.' % self.log_dir) self.prototype_logs = prototype_logs \ if prototype_logs is not None else [] # Generate missing information self.generate() def __repr__(self): s = "" for n in self.nodes: s += "\n" + str(n) return s def add_node(self, node): self.nodes.append(node) self.generate() def del_node(self, node): self.nodes.remove(node) self.generate() # Compute registration/enrollment order for DIFs def compute_dif_ordering(self): # Compute DIFs dependency graph, as both adjacency and incidence list. difsdeps_adj = dict() difsdeps_inc = dict() for node in self.nodes: for dif in node.difs: if dif not in difsdeps_adj: difsdeps_adj[dif] = set() for upper in node.dif_registrations: for lower in node.dif_registrations[upper]: if upper not in difsdeps_inc: difsdeps_inc[upper] = set() if lower not in difsdeps_inc: difsdeps_inc[lower] = set() if upper not in difsdeps_adj: difsdeps_adj[upper] = set() if lower not in difsdeps_adj: difsdeps_adj[lower] = set() difsdeps_inc[upper].add(lower) difsdeps_adj[lower].add(upper) # Kahn's algorithm below only needs per-node count of # incident edges, so we compute these counts from the # incidence list and drop the latter. difsdeps_inc_cnt = dict() for dif in difsdeps_inc: difsdeps_inc_cnt[dif] = len(difsdeps_inc[dif]) del difsdeps_inc # Init difsdeps_inc_cnt for those DIFs that do not # act as lower IPCPs nor upper IPCPs for registration # operations for node in self.nodes: for dif in node.difs: if dif not in difsdeps_inc_cnt: difsdeps_inc_cnt[dif] = 0 # Run Kahn's algorithm to compute topological # ordering on the DIFs graph. frontier = set() self.dif_ordering = [] for dif in difsdeps_inc_cnt: if difsdeps_inc_cnt[dif] == 0: frontier.add(dif) while len(frontier): cur = frontier.pop() self.dif_ordering.append(cur) for nxt in difsdeps_adj[cur]: difsdeps_inc_cnt[nxt] -= 1 if difsdeps_inc_cnt[nxt] == 0: frontier.add(nxt) difsdeps_adj[cur] = set() circular_set = [dif for dif in difsdeps_inc_cnt if difsdeps_inc_cnt[dif] != 0] if len(circular_set): raise Exception("Fatal error: The specified DIFs topology" "has one or more" "circular dependencies, involving the following" " DIFs: %s" % circular_set) logger.debug("DIF topological ordering: %s", self.dif_ordering) # Compute all the enrollments, to be called after compute_dif_ordering() def compute_enrollments(self): dif_graphs = dict() self.enrollments = [] self.mgmt_flows = [] self.dt_flows = [] for dif in self.dif_ordering: neighsets = dict() dif_graphs[dif] = dict() first = None # For each N-1-DIF supporting this DIF, compute the set of nodes # that share such N-1-DIF. This set will be called the 'neighset' of # the N-1-DIF for the current DIF. for node in self.nodes: if dif in node.dif_registrations: dif_graphs[dif][node] = [] # init for later use if first is None: # pick any node for later use first = node for lower_dif in node.dif_registrations[dif]: if lower_dif not in neighsets: neighsets[lower_dif] = [] neighsets[lower_dif].append(node) # Build the graph, represented as adjacency list for lower_dif in neighsets: # Each neighset corresponds to a complete (sub)graph. for node1 in neighsets[lower_dif]: for node2 in neighsets[lower_dif]: if node1 != node2: dif_graphs[dif][node1].append((node2, lower_dif)) self.enrollments.append([]) self.dt_flows.append([]) self.mgmt_flows.append([]) if first is None: # This is a shim DIF, nothing to do continue er = [] for node in dif_graphs[dif]: for edge in dif_graphs[dif][node]: er.append("%s --[%s]--> %s" % (node.name, edge[1].name, edge[0].name)) logger.debug("DIF graph for %s: %s", dif, ', '.join(er)) # To generate the list of mgmt flows, minimal enrollments # and minimal dt flows, we simulate it, using # breadth-first traversal. enrolled = {first} frontier = {first} while len(frontier): cur = frontier.pop() for edge in dif_graphs[dif][cur]: if edge[0] not in enrolled: enrolled.add(edge[0]) enrollee = edge[0].get_ipcp_by_dif(dif) assert(enrollee is not None) enroller = cur.get_ipcp_by_dif(dif) assert(enroller is not None) if self.enrollment_strategy == 'minimal': self.enrollments[-1].append({'dif': dif, 'enrollee': enrollee, 'enroller': enroller, 'lower_dif': edge[1]}) self.mgmt_flows[-1].append({'src': enrollee, 'dst': enroller}) if self.dt_strategy == 'minimal': self.dt_flows[-1].append({'src': enrollee, 'dst': enroller}) frontier.add(edge[0]) if len(dif.members) != len(enrolled): raise Exception("Disconnected DIF found: %s" % (dif,)) # In case of a full mesh enrollment or dt flows for cur in dif_graphs[dif]: for edge in dif_graphs[dif][cur]: if cur.name < edge[0].name: enrollee = cur.get_ipcp_by_dif(dif) assert(enrollee is not None) enroller = edge[0].get_ipcp_by_dif(dif) assert(enroller is not None) if self.enrollment_strategy == 'full-mesh': self.enrollments[-1].append({'dif': dif, 'enrollee': enrollee, 'enroller': enroller, 'lower_dif': edge[1]}) if self.dt_strategy == 'full-mesh': self.dt_flows[-1].append({'src': enrollee, 'dst': enroller}) if not (self.dt_strategy == 'minimal' or self.dt_strategy == 'full-mesh') \ or not (self.enrollment_strategy == 'full-mesh' or self.enrollment_strategy == 'minimal'): # This is a bug assert False log_string = "Enrollments:\n" for el in self.enrollments: for e in el: log_string += (" [%s] %s --> %s through N-1-DIF %s\n" % (e['dif'], e['enrollee'].name, e['enroller'].name, e['lower_dif'])) logger.debug(log_string) log_string = "Mgmt flows:\n" for el in self.mgmt_flows: for e in el: log_string += (" %s --> %s \n" % (e['src'].name, e['dst'].name)) logger.debug(log_string) log_string = "Dt flows:\n" for el in self.dt_flows: for e in el: log_string += (" %s --> %s \n" % (e['src'].name, e['dst'].name)) logger.debug(log_string) def compute_ipcps(self): # For each node, compute the required IPCP instances, and associated # registrations for node in self.nodes: node.ipcps = [] # We want also the node.ipcps list to be generated in # topological ordering for dif in self.dif_ordering: if dif not in node.difs: continue # Create an instance of the required IPCP class ipcp = dif.get_ipcp_class()( name='%s.%s' % (dif.name, node.name), node=node, dif=dif) if dif in node.dif_registrations: for lower in node.dif_registrations[dif]: ipcp.registrations.append(lower) node.ipcps.append(ipcp) dif.ipcps.append(ipcp) def compute_bootstrappers(self): for node in self.nodes: for ipcp in node.ipcps: ipcp.dif_bootstrapper = True for el in self.enrollments: for e in el: if e['dif'] != ipcp.dif: # Skip this DIF break if e['enrollee'] == ipcp: ipcp.dif_bootstrapper = False # Exit the loops break if not ipcp.dif_bootstrapper: break def dump_ssh_info(self): f = open(os.path.join(tmp_dir, 'ssh_info'), 'w') for node in self.nodes: f.write("%s;%s;%s;%s;%s\n" % (node.name, self.testbed.username, node.ssh_config.hostname, node.ssh_config.port, node.ssh_config.proxy_server)) f.close() # Examine the nodes and DIFs, compute the registration and enrollment # order, the list of IPCPs to create, registrations, ... def generate(self): start = time.time() self.compute_dif_ordering() self.compute_ipcps() self.compute_enrollments() self.compute_bootstrappers() for node in self.nodes: logger.info("IPCPs for node %s: %s", node.name, node.ipcps) end = time.time() logger.info("Layer ordering computation took %.2f seconds", end - start) def install_prototype(self): start = time.time() self._install_prototype() end = time.time() logger.info("Install took %.2f seconds", end - start) def set_startup_command(self, command): for node in self.nodes: node.startup_command = command def bootstrap_prototype(self): start = time.time() self._bootstrap_prototype() end = time.time() logger.info("Bootstrap took %.2f seconds", end - start) @abc.abstractmethod def _install_prototype(self): raise Exception('install_prototype() method not implemented') @abc.abstractmethod def _bootstrap_prototype(self): raise Exception('bootstrap_prototype() method not implemented') @abc.abstractmethod def prototype_name(self): raise Exception('prototype_name() method not implemented') @abc.abstractmethod def _terminate_prototype(self): raise Exception('terminate_prototype() method not implemented') def swap_in(self): # Realize the experiment testbed (testbed-specific) start = time.time() self.testbed.swap_in(self) self.dump_ssh_info() end = time.time() logger.info("Swap-in took %.2f seconds", end - start) def swap_out(self): start = time.time() # Terminate prototype gracefully self._terminate_prototype() for node in self.nodes: if node.ssh_config.client is not None: node.ssh_config.client.close() if node.ssh_config.proxy_client is not None: node.ssh_config.proxy_client.close() # Undo the testbed (testbed-specific) self.testbed.swap_out(self) end = time.time() logger.info("Swap-out took %.2f seconds", end - start) class Executor: __metaclass__ = abc.ABCMeta @abc.abstractmethod def execute_command(self, node, command, as_root=False, time_out=3): # Execute command on a node return def execute_commands(self, node, commands, as_root=False, time_out=3): for command in commands: self.execute_command(node, command, as_root, time_out) @abc.abstractmethod def copy_file(self, node, path, destination): return def copy_files(self, node, paths, destination): for path in paths: self.copy_file(node, path, destination) @abc.abstractmethod def fetch_file(self, node, path, destination, sudo=False): return def fetch_files(self, node, paths, destination, sudo=False): for path in paths: self.fetch_file(node, path, destination, sudo)