def test_acc_monitor_handles_adding_instances(monitor: AccumulatingMonitorStrategy): monitor.add_instance(2) triggered_time = simulate_ordering(monitor, 100.0, 2) # Monitor should not be triggered before timeout monitor.update_time(triggered_time + 0.8 * ACC_MONITOR_TIMEOUT) assert not monitor.is_master_degraded() assert not monitor.is_instance_degraded(1) assert not monitor.is_instance_degraded(2) # Monitor should be triggered after timeout monitor.update_time(triggered_time + 1.2 * ACC_MONITOR_TIMEOUT) assert monitor.is_master_degraded() assert monitor.is_instance_degraded(1) # TODO: Monitor behaves like this now, but is it okay? assert not monitor.is_instance_degraded(2)
class Monitor(HasActionQueue, PluginLoaderHelper): """ Implementation of RBFT's monitoring mechanism. The monitoring metrics are collected at the level of a node. Each node monitors the performance of each instance. Throughput of requests and latency per client request are measured. """ def __init__(self, name: str, Delta: float, Lambda: float, Omega: float, instances: Instances, nodestack, blacklister: Blacklister, nodeInfo: Dict, notifierEventTriggeringConfig: Dict, pluginPaths: Iterable[str] = None, notifierEventsEnabled: bool = True): self.name = name self.instances = instances self.nodestack = nodestack self.blacklister = blacklister self.nodeInfo = nodeInfo self.notifierEventTriggeringConfig = notifierEventTriggeringConfig self.notifierEventsEnabled = notifierEventsEnabled self.Delta = Delta self.Lambda = Lambda self.Omega = Omega self.statsConsumers = self.getPluginsByType(pluginPaths, PLUGIN_TYPE_STATS_CONSUMER) self.config = getConfig() # Number of ordered requests by each replica. The value at key `i` in # the dict is a tuple of the number of ordered requests by replica and # the time taken to order those requests by the replica of the `i`th # protocol instance self.numOrderedRequests = dict() # type: Dict[int, Tuple[int, int]] # Dict(instance_id, throughput) of throughputs for replicas. Key is a instId and value is a instance of # ThroughputMeasurement class and provide throughputs evaluating mechanism self.throughputs = dict() # type: Dict[int, ThroughputMeasurement] # Utility object for tracking requests order start and end # TODO: Has very similar cleanup logic to propagator.Requests self.requestTracker = RequestTimeTracker(instances.ids) # Request latencies for the master protocol instances. Key of the # dictionary is a tuple of client id and request id and the value is # the time the master instance took for ordering it self.masterReqLatencies = {} # type: Dict[Tuple[str, int], float] # Indicates that request latency in previous snapshot of master req # latencies was too high self.masterReqLatencyTooHigh = False # Request latency(time taken to be ordered) for the client. The value # at key `i` in the dict is the LatencyMeasurement object which accumulate # average latency and total request for each client. self.clientAvgReqLatencies = dict() # type: Dict[int, LatencyMeasurement] # TODO: Set this if this monitor belongs to a node which has primary # of master. Will be used to set `totalRequests` self.hasMasterPrimary = None # Total requests that have been ordered since the node started self.totalRequests = 0 self.started = datetime.utcnow().isoformat() self.orderedRequestsInLast = [] # attention: handlers will work over unordered request only once self.unordered_requests_handlers = [] # type: List[Callable] # Monitoring suspicious spikes in cluster throughput self.clusterThroughputSpikeMonitorData = { 'value': 0, 'cnt': 0, 'accum': [] } psutil.cpu_percent(interval=None) self.lastKnownTraffic = self.calculateTraffic() self.totalViewChanges = 0 self._lastPostedViewChange = 0 HasActionQueue.__init__(self) if self.config.SendMonitorStats: self.startRepeating(self.sendPeriodicStats, self.config.DashboardUpdateFreq) self.startRepeating( self.checkPerformance, self.config.notifierEventTriggeringConfig['clusterThroughputSpike']['freq']) self.startRepeating(self.check_unordered, self.config.UnorderedCheckFreq) if 'disable_view_change' in self.config.unsafe: self.isMasterDegraded = lambda: False if 'disable_monitor' in self.config.unsafe: self.requestOrdered = lambda *args, **kwargs: {} self.sendPeriodicStats = lambda: None self.checkPerformance = lambda: None self.latency_avg_for_backup_cls = self.config.LatencyAveragingStrategyClass self.latency_measurement_cls = self.config.LatencyMeasurementCls self.throughput_avg_strategy_cls = self.config.throughput_averaging_strategy_class self.acc_monitor = None if self.config.ACC_MONITOR_ENABLED: self.acc_monitor = AccumulatingMonitorStrategy( start_time=time.perf_counter(), instances=instances.ids, txn_delta_k=self.config.ACC_MONITOR_TXN_DELTA_K, timeout=self.config.ACC_MONITOR_TIMEOUT, input_rate_reaction_half_time=self.config.ACC_MONITOR_INPUT_RATE_REACTION_HALF_TIME) def __repr__(self): return self.name def metrics(self): """ Calculate and return the metrics. """ masterThrp, backupThrp = self.getThroughputs(self.instances.masterId) r = self.instance_throughput_ratio(self.instances.masterId) m = [ ("{} Monitor metrics:".format(self), None), ("Delta", self.Delta), ("Lambda", self.Lambda), ("Omega", self.Omega), ("instances started", self.instances.started), ("ordered request counts", {i: r[0] for i, r in self.numOrderedRequests.items()}), ("ordered request durations", {i: r[1] for i, r in self.numOrderedRequests.items()}), ("master request latencies", self.masterReqLatencies), ("client avg request latencies", {i: self.getLatency(i) for i in self.instances.ids}), ("throughput", {i: self.getThroughput(i) for i in self.instances.ids}), ("master throughput", masterThrp), ("total requests", self.totalRequests), ("avg backup throughput", backupThrp), ("master throughput ratio", r)] return m @property def prettymetrics(self) -> str: """ Pretty printing for metrics """ rendered = ["{}: {}".format(*m) for m in self.metrics()] return "\n ".join(rendered) def calculateTraffic(self): currNetwork = psutil.net_io_counters() currNetwork = currNetwork.bytes_sent + currNetwork.bytes_recv currNetwork /= 1024 return currNetwork @staticmethod def create_throughput_measurement(config, start_ts=time.perf_counter()): tm = config.throughput_measurement_class( **config.throughput_measurement_params) tm.init_time(start_ts) return tm def reset(self): """ Reset the monitor. Sets all monitored values to defaults. """ logger.debug("{}'s Monitor being reset".format(self)) instances_ids = self.instances.started.keys() self.numOrderedRequests = {inst_id: (0, 0) for inst_id in instances_ids} self.requestTracker.reset() self.masterReqLatencies = {} self.masterReqLatencyTooHigh = False self.totalViewChanges += 1 self.lastKnownTraffic = self.calculateTraffic() if self.acc_monitor: self.acc_monitor.reset() for i in instances_ids: rm = self.create_throughput_measurement(self.config) self.throughputs[i] = rm lm = self.latency_measurement_cls(self.config) self.clientAvgReqLatencies[i] = lm def addInstance(self, inst_id): """ Add one protocol instance for monitoring. """ self.instances.add(inst_id) self.requestTracker.add_instance(inst_id) self.numOrderedRequests[inst_id] = (0, 0) rm = self.create_throughput_measurement(self.config) self.throughputs[inst_id] = rm lm = self.latency_measurement_cls(self.config) self.clientAvgReqLatencies[inst_id] = lm if self.acc_monitor: self.acc_monitor.add_instance(inst_id) def removeInstance(self, inst_id): if self.acc_monitor: self.acc_monitor.remove_instance(inst_id) if self.instances.count > 0: self.instances.remove(inst_id) self.requestTracker.remove_instance(inst_id) self.numOrderedRequests.pop(inst_id, None) self.clientAvgReqLatencies.pop(inst_id, None) self.throughputs.pop(inst_id, None) def requestOrdered(self, reqIdrs: List[str], instId: int, requests, byMaster: bool = False) -> Dict: """ Measure the time taken for ordering of a request and return it. Monitor might have been reset due to view change due to which this method returns None """ now = time.perf_counter() if self.acc_monitor: self.acc_monitor.update_time(now) durations = {} for key in reqIdrs: if key not in self.requestTracker: logger.debug("Got untracked ordered request with digest {}". format(key)) continue if self.acc_monitor: self.acc_monitor.request_ordered(key, instId) if key in self.requestTracker.handled_unordered(): started = self.requestTracker.started(key) logger.info('Consensus for ReqId: {} was achieved by {}:{} in {} seconds.' .format(key, self.name, instId, now - started)) duration = self.requestTracker.order(instId, key, now) self.throughputs[instId].add_request(now) if byMaster: # TODO for now, view_change procedure can take more that 15 minutes # (5 minutes for catchup and 10 minutes for primary's answer). # Therefore, view_change triggering by max latency is not indicative now. # self.masterReqLatencies[key] = duration self.orderedRequestsInLast.append(now) if key in requests: identifier = requests[key].request.identifier self.clientAvgReqLatencies[instId].add_duration(identifier, duration) durations[key] = duration reqs, tm = self.numOrderedRequests[instId] orderedNow = len(durations) self.numOrderedRequests[instId] = (reqs + orderedNow, tm + sum(durations.values())) # TODO: Inefficient, as on every request a minimum of a large list is # calculated if min(r[0] for r in self.numOrderedRequests.values()) == (reqs + orderedNow): # If these requests is ordered by the last instance then increment # total requests, but why is this important, why cant is ordering # by master not enough? self.totalRequests += orderedNow self.postOnReqOrdered() if 0 == reqs: self.postOnNodeStarted(self.started) return durations def requestUnOrdered(self, key: str): """ Record the time at which request ordering started. """ now = time.perf_counter() if self.acc_monitor: self.acc_monitor.update_time(now) self.acc_monitor.request_received(key) self.requestTracker.start(key, now) def check_unordered(self): now = time.perf_counter() new_unordereds = [(req, now - started) for req, started in self.requestTracker.unhandled_unordered() if now - started > self.config.UnorderedCheckFreq] if len(new_unordereds) == 0: return for handler in self.unordered_requests_handlers: handler(new_unordereds) for unordered in new_unordereds: self.requestTracker.handle(unordered[0]) logger.debug('Following requests were not ordered for more than {} seconds: {}' .format(self.config.UnorderedCheckFreq, unordered[0])) def isMasterDegraded(self): """ Return whether the master instance is slow. """ if self.acc_monitor: self.acc_monitor.update_time(time.perf_counter()) return self.acc_monitor.is_master_degraded() else: return (self.instances.masterId is not None and (self.isMasterThroughputTooLow() or # TODO for now, view_change procedure can take more that 15 minutes # (5 minutes for catchup and 10 minutes for primary's answer). # Therefore, view_change triggering by max latency now is not indicative. # self.isMasterReqLatencyTooHigh() or self.isMasterAvgReqLatencyTooHigh())) def areBackupsDegraded(self): """ Return slow instance. """ slow_instances = [] if self.acc_monitor: for instance in self.instances.backupIds: if self.acc_monitor.is_instance_degraded(instance): slow_instances.append(instance) else: for instance in self.instances.backupIds: if self.is_instance_throughput_too_low(instance) or \ self.is_instance_avg_req_latency_too_high(instance): slow_instances.append(instance) return slow_instances def instance_throughput_ratio(self, inst_id): """ The relative throughput of an instance compared to the backup instances. """ inst_thrp, otherThrp = self.getThroughputs(inst_id) # Backup throughput may be 0 so moving ahead only if it is not 0 r = inst_thrp / otherThrp if otherThrp and inst_thrp is not None \ else None return r def isMasterThroughputTooLow(self): """ Return whether the throughput of the master instance is greater than the acceptable threshold """ return self.is_instance_throughput_too_low(self.instances.masterId) def is_instance_throughput_too_low(self, inst_id): """ Return whether the throughput of the master instance is greater than the acceptable threshold """ logging = self.instances.masterId == inst_id r = self.instance_throughput_ratio(inst_id) if r is None: if logging: logger.debug("{} instance {} throughput is not " "measurable.".format(self, inst_id)) return None too_low = r < self.Delta if logging and too_low: logger.display("{}{} instance {} throughput ratio {} is lower than Delta {}.". format(MONITORING_PREFIX, self, inst_id, r, self.Delta)) elif logging: logger.trace("{} instance {} throughput ratio {} is acceptable.". format(self, inst_id, r)) return too_low def isMasterReqLatencyTooHigh(self): """ Return whether the request latency of the master instance is greater than the acceptable threshold """ # TODO for now, view_change procedure can take more that 15 minutes # (5 minutes for catchup and 10 minutes for primary's answer). # Therefore, view_change triggering by max latency is not indicative now. r = self.masterReqLatencyTooHigh or \ next(((key, lat) for key, lat in self.masterReqLatencies.items() if lat > self.Lambda), None) if r: logger.display("{}{} found master's latency {} to be higher than the threshold for request {}.". format(MONITORING_PREFIX, self, r[1], r[0])) else: logger.trace("{} found master's latency to be lower than the " "threshold for all requests.".format(self)) return r def isMasterAvgReqLatencyTooHigh(self): """ Return whether the average request latency of the master instance is greater than the acceptable threshold """ return self.is_instance_avg_req_latency_too_high(self.instances.masterId) def is_instance_avg_req_latency_too_high(self, inst_id): """ Return whether the average request latency of an instance is greater than the acceptable threshold """ avg_lat, avg_lat_others = self.getLatencies() if not avg_lat or not avg_lat_others: return False d = avg_lat - avg_lat_others if d < self.Omega: return False if inst_id == self.instances.masterId: logger.info("{}{} found difference between master's and " "backups's avg latency {} to be higher than the " "threshold".format(MONITORING_PREFIX, self, d)) logger.trace( "{}'s master's avg request latency is {} and backup's " "avg request latency is {}".format(self, avg_lat, avg_lat_others)) return True def getThroughputs(self, desired_inst_id: int): """ Return a tuple of the throughput of the given instance and the average throughput of the remaining instances. :param instId: the id of the protocol instance """ instance_thrp = self.getThroughput(desired_inst_id) totalReqs, totalTm = self.getInstanceMetrics(forAllExcept=desired_inst_id) # Average backup replica's throughput if len(self.throughputs) > 1: thrs = [] for inst_id, thr_obj in self.throughputs.items(): if inst_id != desired_inst_id: thr = self.getThroughput(inst_id) if thr is not None: thrs.append(thr) if thrs: other_thrp = self.throughput_avg_strategy_cls.get_avg(thrs) else: other_thrp = None else: other_thrp = None if instance_thrp == 0: if self.numOrderedRequests[desired_inst_id] == (0, 0): avgReqsPerInst = (totalReqs or 0) / self.instances.count if avgReqsPerInst <= 1: # too early to tell if we need an instance change instance_thrp = None return instance_thrp, other_thrp def getThroughput(self, instId: int) -> float: """ Return the throughput of the specified instance. :param instId: the id of the protocol instance """ # We are using the instanceStarted time in the denominator instead of # a time interval. This is alright for now as all the instances on a # node are started at almost the same time. if instId not in self.instances.ids: return None perf_time = time.perf_counter() throughput = self.throughputs[instId].get_throughput(perf_time) return throughput def getInstanceMetrics( self, forAllExcept: int) -> Tuple[Optional[int], Optional[float]]: """ Calculate and return the average throughput of all the instances except the one specified as `forAllExcept`. """ m = [(reqs, tm) for i, (reqs, tm) in self.numOrderedRequests.items() if i != forAllExcept] if m: reqs, tm = zip(*m) return sum(reqs), sum(tm) else: return None, None def getLatencies(self, desired_inst_id=None): if desired_inst_id is None: desired_inst_id = self.instances.masterId avg_lat = self.getLatency(desired_inst_id) avg_lat_others_by_inst = [] for inst_id in self.instances.ids: if desired_inst_id == inst_id: continue lat = self.getLatency(inst_id) if lat: avg_lat_others_by_inst.append(lat) avg_lat_others = self.latency_avg_for_backup_cls.get_avg(avg_lat_others_by_inst)\ if avg_lat_others_by_inst else None return avg_lat, avg_lat_others def getLatency(self, instId: int) -> float: """ Return a dict with client identifier as a key and calculated latency as a value """ if len(self.clientAvgReqLatencies) == 0: return 0.0 return self.clientAvgReqLatencies[instId].get_avg_latency() def sendPeriodicStats(self): thoughputData = self.sendThroughput() self.clusterThroughputSpikeMonitorData['accum'].append( thoughputData['throughput']) self.sendLatencies() self.sendKnownNodesInfo() self.sendNodeInfo() self.sendSystemPerfomanceInfo() self.sendTotalRequests() def checkPerformance(self): self.sendClusterThroughputSpike() def sendClusterThroughputSpike(self): if self.instances.masterId is None: return None accum = 0 for val in self.clusterThroughputSpikeMonitorData['accum']: accum += val if len(self.clusterThroughputSpikeMonitorData['accum']): accum /= len(self.clusterThroughputSpikeMonitorData['accum']) self.clusterThroughputSpikeMonitorData['accum'] = [] return pluginManager.sendMessageUponSuspiciousSpike( notifierPluginTriggerEvents['clusterThroughputSpike'], self.clusterThroughputSpikeMonitorData, accum, self.notifierEventTriggeringConfig['clusterThroughputSpike'], self.name, self.notifierEventsEnabled ) @property def highResThroughput(self): # TODO:KS Move these computations as well to plenum-stats project return self.getThroughput(self.instances.masterId) def sendThroughput(self): logger.debug("{} sending throughput".format(self)) throughput = self.highResThroughput utcTime = datetime.utcnow() mtrStats = { "throughput": throughput, "timestamp": utcTime.isoformat(), "nodeName": self.name, # Multiply by 1000 for JavaScript date conversion "time": time.mktime(utcTime.timetuple()) * 1000 } self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_THROUGHPUT, mtrStats) return mtrStats @property def masterLatency(self): master_latency, _ = self.getLatencies() return master_latency @property def avgBackupLatency(self): _, lat_backup = self.getLatencies() return lat_backup def sendLatencies(self): logger.debug("{} sending latencies".format(self)) utcTime = datetime.utcnow() # Multiply by 1000 to make it compatible to JavaScript Date() jsTime = time.mktime(utcTime.timetuple()) * 1000 latencies = dict( masterLatency=self.masterLatency, averageBackupLatency=self.avgBackupLatency, time=jsTime, nodeName=self.name, timestamp=utcTime.isoformat() ) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_LATENCIES, latencies) def sendKnownNodesInfo(self): logger.debug("{} sending nodestack".format(self)) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_NODES, remotesInfo( self.nodestack, self.blacklister)) def sendSystemPerfomanceInfo(self): logger.debug("{} sending system performance".format(self)) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_SYSTEM_PERFORMANCE_INFO, self.captureSystemPerformance()) def sendNodeInfo(self): logger.debug("{} sending node info".format(self)) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_NODE_INFO, self.nodeInfo['data']) def sendTotalRequests(self): logger.debug("{} sending total requests".format(self)) totalRequests = dict( totalRequests=self.totalRequests ) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_TOTAL_REQUESTS, totalRequests) def captureSystemPerformance(self): logger.debug("{} capturing system performance".format(self)) timestamp = time.time() cpu = psutil.cpu_percent(interval=None) ram = psutil.virtual_memory() curr_network = self.calculateTraffic() network = curr_network - self.lastKnownTraffic self.lastKnownTraffic = curr_network cpu_data = { 'time': timestamp, 'value': cpu } ram_data = { 'time': timestamp, 'value': ram.percent } traffic_data = { 'time': timestamp, 'value': network } return { 'cpu': cpu_data, 'ram': ram_data, 'traffic': traffic_data } def postOnReqOrdered(self): utcTime = datetime.utcnow() # Multiply by 1000 to make it compatible to JavaScript Date() jsTime = time.mktime(utcTime.timetuple()) * 1000 if self.totalViewChanges != self._lastPostedViewChange: self._lastPostedViewChange = self.totalViewChanges viewChange = dict( time=jsTime, viewChange=self._lastPostedViewChange ) self._sendStatsDataIfRequired(EVENT_VIEW_CHANGE, viewChange) reqOrderedEventDict = dict(self.metrics()) reqOrderedEventDict["created_at"] = utcTime.isoformat() reqOrderedEventDict["nodeName"] = self.name reqOrderedEventDict["time"] = jsTime reqOrderedEventDict["hasMasterPrimary"] = "Y" if self.hasMasterPrimary else "N" self._sendStatsDataIfRequired(EVENT_REQ_ORDERED, reqOrderedEventDict) self._clearSnapshot() def postOnNodeStarted(self, startedAt): throughputData = { "updateFrequency": self.config.DashboardUpdateFreq, "graphDuration": self.config.ThroughputGraphDuration } startedAtData = {"startedAt": startedAt, "ctx": "DEMO"} startedEventDict = { "startedAtData": startedAtData, "throughputConfig": throughputData } self._sendStatsDataIfRequired(EVENT_NODE_STARTED, startedEventDict) def _clearSnapshot(self): self.masterReqLatencyTooHigh = self.isMasterReqLatencyTooHigh() self.masterReqLatencies = {} def _sendStatsDataIfRequired(self, event, stats): if self.config.SendMonitorStats: for sc in self.statsConsumers: sc.sendStats(event, stats) @staticmethod def mean(data): return 0 if len(data) == 0 else mean(data)
class Monitor(HasActionQueue, PluginLoaderHelper): """ Implementation of RBFT's monitoring mechanism. The monitoring metrics are collected at the level of a node. Each node monitors the performance of each instance. Throughput of requests and latency per client request are measured. """ def __init__(self, name: str, Delta: float, Lambda: float, Omega: float, instances: Instances, nodestack, blacklister: Blacklister, nodeInfo: Dict, notifierEventTriggeringConfig: Dict, pluginPaths: Iterable[str] = None, notifierEventsEnabled: bool = True): self.name = name self.instances = instances self.nodestack = nodestack self.blacklister = blacklister self.nodeInfo = nodeInfo self.notifierEventTriggeringConfig = notifierEventTriggeringConfig self.notifierEventsEnabled = notifierEventsEnabled self.Delta = Delta self.Lambda = Lambda self.Omega = Omega self.statsConsumers = self.getPluginsByType(pluginPaths, PLUGIN_TYPE_STATS_CONSUMER) self.config = getConfig() # Number of ordered requests by each replica. The value at key `i` in # the dict is a tuple of the number of ordered requests by replica and # the time taken to order those requests by the replica of the `i`th # protocol instance self.numOrderedRequests = dict() # type: Dict[int, Tuple[int, int]] # Dict(instance_id, throughput) of throughputs for replicas. Key is a instId and value is a instance of # ThroughputMeasurement class and provide throughputs evaluating mechanism self.throughputs = dict() # type: Dict[int, ThroughputMeasurement] # Utility object for tracking requests order start and end # TODO: Has very similar cleanup logic to propagator.Requests self.requestTracker = RequestTimeTracker(instances.ids) # Request latencies for the master protocol instances. Key of the # dictionary is a tuple of client id and request id and the value is # the time the master instance took for ordering it self.masterReqLatencies = {} # type: Dict[Tuple[str, int], float] # Indicates that request latency in previous snapshot of master req # latencies was too high self.masterReqLatencyTooHigh = False # Request latency(time taken to be ordered) for the client. The value # at key `i` in the dict is the LatencyMeasurement object which accumulate # average latency and total request for each client. self.clientAvgReqLatencies = dict() # type: Dict[int, LatencyMeasurement] # TODO: Set this if this monitor belongs to a node which has primary # of master. Will be used to set `totalRequests` self.hasMasterPrimary = None # Total requests that have been ordered since the node started self.totalRequests = 0 self.started = datetime.utcnow().isoformat() # attention: handlers will work over unordered request only once self.unordered_requests_handlers = [] # type: List[Callable] # Monitoring suspicious spikes in cluster throughput self.clusterThroughputSpikeMonitorData = { 'value': 0, 'cnt': 0, 'accum': [] } psutil.cpu_percent(interval=None) self.lastKnownTraffic = self.calculateTraffic() self.totalViewChanges = 0 self._lastPostedViewChange = 0 HasActionQueue.__init__(self) if self.config.SendMonitorStats: self.startRepeating(self.sendPeriodicStats, self.config.DashboardUpdateFreq) self.startRepeating( self.checkPerformance, self.config.notifierEventTriggeringConfig['clusterThroughputSpike']['freq']) self.startRepeating(self.check_unordered, self.config.UnorderedCheckFreq) if 'disable_view_change' in self.config.unsafe: self.isMasterDegraded = lambda: False if 'disable_monitor' in self.config.unsafe: self.requestOrdered = lambda *args, **kwargs: {} self.sendPeriodicStats = lambda: None self.checkPerformance = lambda: None self.latency_avg_for_backup_cls = self.config.LatencyAveragingStrategyClass self.latency_measurement_cls = self.config.LatencyMeasurementCls self.throughput_avg_strategy_cls = self.config.throughput_averaging_strategy_class self.acc_monitor = None if self.config.ACC_MONITOR_ENABLED: self.acc_monitor = AccumulatingMonitorStrategy( start_time=time.perf_counter(), instances=instances.ids, txn_delta_k=self.config.ACC_MONITOR_TXN_DELTA_K, timeout=self.config.ACC_MONITOR_TIMEOUT, input_rate_reaction_half_time=self.config.ACC_MONITOR_INPUT_RATE_REACTION_HALF_TIME) def __repr__(self): return self.name def metrics(self): """ Calculate and return the metrics. """ masterThrp, backupThrp = self.getThroughputs(self.instances.masterId) r = self.instance_throughput_ratio(self.instances.masterId) m = [ ("{} Monitor metrics:".format(self), None), ("Delta", self.Delta), ("Lambda", self.Lambda), ("Omega", self.Omega), ("instances started", self.instances.started), ("ordered request counts", {i: r[0] for i, r in self.numOrderedRequests.items()}), ("ordered request durations", {i: r[1] for i, r in self.numOrderedRequests.items()}), ("master request latencies", self.masterReqLatencies), ("client avg request latencies", {i: self.getLatency(i) for i in self.instances.ids}), ("throughput", {i: self.getThroughput(i) for i in self.instances.ids}), ("master throughput", masterThrp), ("total requests", self.totalRequests), ("avg backup throughput", backupThrp), ("master throughput ratio", r)] return m @property def prettymetrics(self) -> str: """ Pretty printing for metrics """ rendered = ["{}: {}".format(*m) for m in self.metrics()] return "\n ".join(rendered) def calculateTraffic(self): currNetwork = psutil.net_io_counters() currNetwork = currNetwork.bytes_sent + currNetwork.bytes_recv currNetwork /= 1024 return currNetwork @staticmethod def create_throughput_measurement(config, start_ts=None): if start_ts is None: start_ts = time.perf_counter() tm = config.throughput_measurement_class( **config.throughput_measurement_params) tm.init_time(start_ts) logger.trace("Creating throughput measurement class {} with parameters {} in start time {}" .format(str(config.throughput_measurement_class), str(config.throughput_measurement_params), start_ts)) return tm def reset(self): """ Reset the monitor. Sets all monitored values to defaults. """ logger.debug("{}'s Monitor being reset".format(self)) instances_ids = self.instances.started.keys() self.numOrderedRequests = {inst_id: (0, 0) for inst_id in instances_ids} self.requestTracker.reset() self.masterReqLatencies = {} self.masterReqLatencyTooHigh = False self.totalViewChanges += 1 self.lastKnownTraffic = self.calculateTraffic() if self.acc_monitor: self.acc_monitor.reset() for i in instances_ids: rm = self.create_throughput_measurement(self.config) self.throughputs[i] = rm lm = self.latency_measurement_cls(self.config) self.clientAvgReqLatencies[i] = lm def addInstance(self, inst_id): """ Add one protocol instance for monitoring. """ self.instances.add(inst_id) self.requestTracker.add_instance(inst_id) self.numOrderedRequests[inst_id] = (0, 0) rm = self.create_throughput_measurement(self.config) self.throughputs[inst_id] = rm lm = self.latency_measurement_cls(self.config) self.clientAvgReqLatencies[inst_id] = lm if self.acc_monitor: self.acc_monitor.add_instance(inst_id) def removeInstance(self, inst_id): if self.acc_monitor: self.acc_monitor.remove_instance(inst_id) if self.instances.count > 0: self.instances.remove(inst_id) self.requestTracker.remove_instance(inst_id) self.numOrderedRequests.pop(inst_id, None) self.clientAvgReqLatencies.pop(inst_id, None) self.throughputs.pop(inst_id, None) def requestOrdered(self, reqIdrs: List[str], instId: int, requests, byMaster: bool = False) -> Dict: """ Measure the time taken for ordering of a request and return it. Monitor might have been reset due to view change due to which this method returns None """ now = time.perf_counter() if self.acc_monitor: self.acc_monitor.update_time(now) durations = {} for key in reqIdrs: if key not in self.requestTracker: logger.debug("Got untracked ordered request with digest {}". format(key)) continue if self.acc_monitor: self.acc_monitor.request_ordered(key, instId) if key in self.requestTracker.handled_unordered(): started = self.requestTracker.started(key) logger.info('Consensus for ReqId: {} was achieved by {}:{} in {} seconds.' .format(key, self.name, instId, now - started)) duration = self.requestTracker.order(instId, key, now) self.throughputs[instId].add_request(now) if key in requests: identifier = requests[key].request.identifier self.clientAvgReqLatencies[instId].add_duration(identifier, duration) durations[key] = duration reqs, tm = self.numOrderedRequests[instId] orderedNow = len(durations) self.numOrderedRequests[instId] = (reqs + orderedNow, tm + sum(durations.values())) # TODO: Inefficient, as on every request a minimum of a large list is # calculated if min(r[0] for r in self.numOrderedRequests.values()) == (reqs + orderedNow): # If these requests is ordered by the last instance then increment # total requests, but why is this important, why cant is ordering # by master not enough? self.totalRequests += orderedNow self.postOnReqOrdered() if 0 == reqs: self.postOnNodeStarted(self.started) return durations def requestUnOrdered(self, key: str): """ Record the time at which request ordering started. """ now = time.perf_counter() if self.acc_monitor: self.acc_monitor.update_time(now) self.acc_monitor.request_received(key) self.requestTracker.start(key, now) def check_unordered(self): now = time.perf_counter() new_unordereds = [(req, now - started) for req, started in self.requestTracker.unhandled_unordered() if now - started > self.config.UnorderedCheckFreq] if len(new_unordereds) == 0: return for handler in self.unordered_requests_handlers: handler(new_unordereds) for unordered in new_unordereds: self.requestTracker.handle(unordered[0]) logger.debug('Following requests were not ordered for more than {} seconds: {}' .format(self.config.UnorderedCheckFreq, unordered[0])) def isMasterDegraded(self): """ Return whether the master instance is slow. """ if self.acc_monitor: self.acc_monitor.update_time(time.perf_counter()) return self.acc_monitor.is_master_degraded() else: return (self.instances.masterId is not None and (self.isMasterThroughputTooLow() or # TODO for now, view_change procedure can take more that 15 minutes # (5 minutes for catchup and 10 minutes for primary's answer). # Therefore, view_change triggering by max latency now is not indicative. # self.isMasterReqLatencyTooHigh() or self.isMasterAvgReqLatencyTooHigh())) def areBackupsDegraded(self): """ Return slow instance. """ slow_instances = [] if self.acc_monitor: for instance in self.instances.backupIds: if self.acc_monitor.is_instance_degraded(instance): slow_instances.append(instance) else: for instance in self.instances.backupIds: if self.is_instance_throughput_too_low(instance): slow_instances.append(instance) return slow_instances def instance_throughput_ratio(self, inst_id): """ The relative throughput of an instance compared to the backup instances. """ inst_thrp, otherThrp = self.getThroughputs(inst_id) # Backup throughput may be 0 so moving ahead only if it is not 0 r = inst_thrp / otherThrp if otherThrp and inst_thrp is not None \ else None return r def isMasterThroughputTooLow(self): """ Return whether the throughput of the master instance is greater than the acceptable threshold """ return self.is_instance_throughput_too_low(self.instances.masterId) def is_instance_throughput_too_low(self, inst_id): """ Return whether the throughput of the master instance is greater than the acceptable threshold """ r = self.instance_throughput_ratio(inst_id) if r is None: logger.debug("{} instance {} throughput is not " "measurable.".format(self, inst_id)) return None too_low = r < self.Delta if too_low: logger.display("{}{} instance {} throughput ratio {} is lower than Delta {}.". format(MONITORING_PREFIX, self, inst_id, r, self.Delta)) else: logger.trace("{} instance {} throughput ratio {} is acceptable.". format(self, inst_id, r)) return too_low def isMasterReqLatencyTooHigh(self): """ Return whether the request latency of the master instance is greater than the acceptable threshold """ # TODO for now, view_change procedure can take more that 15 minutes # (5 minutes for catchup and 10 minutes for primary's answer). # Therefore, view_change triggering by max latency is not indicative now. r = self.masterReqLatencyTooHigh or \ next(((key, lat) for key, lat in self.masterReqLatencies.items() if lat > self.Lambda), None) if r: logger.display("{}{} found master's latency {} to be higher than the threshold for request {}.". format(MONITORING_PREFIX, self, r[1], r[0])) else: logger.trace("{} found master's latency to be lower than the " "threshold for all requests.".format(self)) return r def isMasterAvgReqLatencyTooHigh(self): """ Return whether the average request latency of the master instance is greater than the acceptable threshold """ return self.is_instance_avg_req_latency_too_high(self.instances.masterId) def is_instance_avg_req_latency_too_high(self, inst_id): """ Return whether the average request latency of an instance is greater than the acceptable threshold """ avg_lat, avg_lat_others = self.getLatencies() if not avg_lat or not avg_lat_others: return False d = avg_lat - avg_lat_others if d < self.Omega: return False if inst_id == self.instances.masterId: logger.info("{}{} found difference between master's and " "backups's avg latency {} to be higher than the " "threshold".format(MONITORING_PREFIX, self, d)) logger.trace( "{}'s master's avg request latency is {} and backup's " "avg request latency is {}".format(self, avg_lat, avg_lat_others)) return True def getThroughputs(self, desired_inst_id: int): """ Return a tuple of the throughput of the given instance and the average throughput of the remaining instances. :param instId: the id of the protocol instance """ instance_thrp = self.getThroughput(desired_inst_id) totalReqs, totalTm = self.getInstanceMetrics(forAllExcept=desired_inst_id) # Average backup replica's throughput if len(self.throughputs) > 1: thrs = [] for inst_id, thr_obj in self.throughputs.items(): if inst_id == desired_inst_id: continue thr = self.getThroughput(inst_id) if thr is not None: thrs.append(thr) if thrs: other_thrp = self.throughput_avg_strategy_cls.get_avg(thrs) else: other_thrp = None else: other_thrp = None if instance_thrp == 0: if self.numOrderedRequests[desired_inst_id] == (0, 0): avgReqsPerInst = (totalReqs or 0) / self.instances.count if avgReqsPerInst <= 1: # too early to tell if we need an instance change instance_thrp = None return instance_thrp, other_thrp def getThroughput(self, instId: int) -> float: """ Return the throughput of the specified instance. :param instId: the id of the protocol instance """ # We are using the instanceStarted time in the denominator instead of # a time interval. This is alright for now as all the instances on a # node are started at almost the same time. if instId not in self.instances.ids: return None perf_time = time.perf_counter() throughput = self.throughputs[instId].get_throughput(perf_time) return throughput def getInstanceMetrics( self, forAllExcept: int) -> Tuple[Optional[int], Optional[float]]: """ Calculate and return the average throughput of all the instances except the one specified as `forAllExcept`. """ m = [(reqs, tm) for i, (reqs, tm) in self.numOrderedRequests.items() if i != forAllExcept] if m: reqs, tm = zip(*m) return sum(reqs), sum(tm) else: return None, None def getLatencies(self, desired_inst_id=None): if desired_inst_id is None: desired_inst_id = self.instances.masterId avg_lat = self.getLatency(desired_inst_id) avg_lat_others_by_inst = [] for inst_id in self.instances.ids: if desired_inst_id == inst_id: continue lat = self.getLatency(inst_id) if lat: avg_lat_others_by_inst.append(lat) avg_lat_others = self.latency_avg_for_backup_cls.get_avg(avg_lat_others_by_inst)\ if avg_lat_others_by_inst else None return avg_lat, avg_lat_others def getLatency(self, instId: int) -> float: """ Return a dict with client identifier as a key and calculated latency as a value """ if len(self.clientAvgReqLatencies) == 0: return 0.0 return self.clientAvgReqLatencies[instId].get_avg_latency() def sendPeriodicStats(self): thoughputData = self.sendThroughput() self.clusterThroughputSpikeMonitorData['accum'].append( thoughputData['throughput']) self.sendLatencies() self.sendKnownNodesInfo() self.sendNodeInfo() self.sendSystemPerfomanceInfo() self.sendTotalRequests() def checkPerformance(self): self.sendClusterThroughputSpike() def sendClusterThroughputSpike(self): if self.instances.masterId is None: return None accum = 0 for val in self.clusterThroughputSpikeMonitorData['accum']: accum += val if len(self.clusterThroughputSpikeMonitorData['accum']): accum /= len(self.clusterThroughputSpikeMonitorData['accum']) self.clusterThroughputSpikeMonitorData['accum'] = [] return pluginManager.sendMessageUponSuspiciousSpike( notifierPluginTriggerEvents['clusterThroughputSpike'], self.clusterThroughputSpikeMonitorData, accum, self.notifierEventTriggeringConfig['clusterThroughputSpike'], self.name, self.notifierEventsEnabled ) @property def highResThroughput(self): # TODO:KS Move these computations as well to plenum-stats project return self.getThroughput(self.instances.masterId) def sendThroughput(self): logger.debug("{} sending throughput".format(self)) throughput = self.highResThroughput utcTime = datetime.utcnow() mtrStats = { "throughput": throughput, "timestamp": utcTime.isoformat(), "nodeName": self.name, # Multiply by 1000 for JavaScript date conversion "time": time.mktime(utcTime.timetuple()) * 1000 } self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_THROUGHPUT, mtrStats) return mtrStats @property def masterLatency(self): master_latency, _ = self.getLatencies() return master_latency @property def avgBackupLatency(self): _, lat_backup = self.getLatencies() return lat_backup def sendLatencies(self): logger.debug("{} sending latencies".format(self)) utcTime = datetime.utcnow() # Multiply by 1000 to make it compatible to JavaScript Date() jsTime = time.mktime(utcTime.timetuple()) * 1000 latencies = dict( masterLatency=self.masterLatency, averageBackupLatency=self.avgBackupLatency, time=jsTime, nodeName=self.name, timestamp=utcTime.isoformat() ) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_LATENCIES, latencies) def sendKnownNodesInfo(self): logger.debug("{} sending nodestack".format(self)) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_NODES, remotesInfo( self.nodestack, self.blacklister)) def sendSystemPerfomanceInfo(self): logger.debug("{} sending system performance".format(self)) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_SYSTEM_PERFORMANCE_INFO, self.captureSystemPerformance()) def sendNodeInfo(self): logger.debug("{} sending node info".format(self)) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_NODE_INFO, self.nodeInfo['data']) def sendTotalRequests(self): logger.debug("{} sending total requests".format(self)) totalRequests = dict( totalRequests=self.totalRequests ) self._sendStatsDataIfRequired( EVENT_PERIODIC_STATS_TOTAL_REQUESTS, totalRequests) def captureSystemPerformance(self): logger.debug("{} capturing system performance".format(self)) timestamp = time.time() cpu = psutil.cpu_percent(interval=None) ram = psutil.virtual_memory() curr_network = self.calculateTraffic() network = curr_network - self.lastKnownTraffic self.lastKnownTraffic = curr_network cpu_data = { 'time': timestamp, 'value': cpu } ram_data = { 'time': timestamp, 'value': ram.percent } traffic_data = { 'time': timestamp, 'value': network } return { 'cpu': cpu_data, 'ram': ram_data, 'traffic': traffic_data } def postOnReqOrdered(self): utcTime = datetime.utcnow() # Multiply by 1000 to make it compatible to JavaScript Date() jsTime = time.mktime(utcTime.timetuple()) * 1000 if self.totalViewChanges != self._lastPostedViewChange: self._lastPostedViewChange = self.totalViewChanges viewChange = dict( time=jsTime, viewChange=self._lastPostedViewChange ) self._sendStatsDataIfRequired(EVENT_VIEW_CHANGE, viewChange) reqOrderedEventDict = dict(self.metrics()) reqOrderedEventDict["created_at"] = utcTime.isoformat() reqOrderedEventDict["nodeName"] = self.name reqOrderedEventDict["time"] = jsTime reqOrderedEventDict["hasMasterPrimary"] = "Y" if self.hasMasterPrimary else "N" self._sendStatsDataIfRequired(EVENT_REQ_ORDERED, reqOrderedEventDict) self._clearSnapshot() def postOnNodeStarted(self, startedAt): throughputData = { "updateFrequency": self.config.DashboardUpdateFreq, "graphDuration": self.config.ThroughputGraphDuration } startedAtData = {"startedAt": startedAt, "ctx": "DEMO"} startedEventDict = { "startedAtData": startedAtData, "throughputConfig": throughputData } self._sendStatsDataIfRequired(EVENT_NODE_STARTED, startedEventDict) def _clearSnapshot(self): self.masterReqLatencyTooHigh = self.isMasterReqLatencyTooHigh() self.masterReqLatencies = {} def _sendStatsDataIfRequired(self, event, stats): if self.config.SendMonitorStats: for sc in self.statsConsumers: sc.sendStats(event, stats) @staticmethod def mean(data): return 0 if len(data) == 0 else mean(data)