コード例 #1
0
ファイル: MOGOMEA.py プロジェクト: thversfelt/MO-GOMEA 
    def clusterPopulation(self):
        """Clusters the given population into k clusters using balanced k-leader-means clustering."""
        # TODO: POSSIBLE CHANGE = CALCULATE OPTIMAL k VALUE

        # The first leader is the solution with maximum value in an arbitrary objective.
        leaders = [self.population[0]]
        for solution in self.population:
            if solution.fitness[0] > leaders[0].fitness[0]:
                leaders[0] = solution

        # The solution with the largest nearest-leader distance is chosen as the next leader,
        # repeated k - 1 times to obtain k leaders.
        for _ in range(self.amountOfClusters - 1):
            nearestLeaderDistance = {}
            for solution in self.population:
                if solution not in leaders:
                    nearestLeaderDistance[solution] = util.euclidianDistance(
                        solution.fitness, leaders[0].fitness)
                    for leader in leaders:
                        leaderDistance = util.euclidianDistance(
                            solution.fitness, leader.fitness)
                        if leaderDistance < nearestLeaderDistance[solution]:
                            nearestLeaderDistance[solution] = leaderDistance
            leader = max(nearestLeaderDistance, key=nearestLeaderDistance.get)
            leaders.append(leader)

        # k-means clustering is performed with k leaders as the initial cluster means.
        clusters = []
        for leader in leaders:
            mean = leader.fitness
            cluster = Cluster(mean, self.problem)
            clusters.append(cluster)

        # Perform k-means clustering until all clusters are unchanged.
        while True in [cluster.changed for cluster in clusters]:
            for solution in self.population:
                nearestCluster = clusters[0]
                nearestClusterDistance = util.euclidianDistance(
                    solution.fitness, nearestCluster.mean)
                for cluster in clusters:
                    clusterDistance = util.euclidianDistance(
                        solution.fitness, cluster.mean)
                    if clusterDistance < nearestClusterDistance:
                        nearestCluster = cluster
                        nearestClusterDistance = clusterDistance
                nearestCluster.append(solution)

            for cluster in clusters:
                cluster.computeMean()
                cluster.clear()

        # Expand the clusters with the closest c solutions.
        c = int(2 / self.amountOfClusters * self.populationSize)
        for cluster in clusters:
            distance = {}
            for solution in self.population:
                distance[solution] = util.euclidianDistance(
                    solution.fitness, cluster.mean)
            for _ in range(c):
                if len(distance) > 0:
                    solution = min(distance, key=distance.get)
                    del distance[solution]
                    cluster.append(solution)
        self.clusters = clusters
コード例 #2
0
def k_means(points, min_x, max_x, min_y, max_y, min_z, max_z):
	pos1 = utl.randomPosition(min_x, min_y, min_z, max_x, max_y, max_z)
	pos2 = utl.randomPosition(min_x, min_y, min_z, max_x, max_y, max_z)
	pos3 = utl.randomPosition(min_x, min_y, min_z, max_x, max_y, max_z)

	cluster1 = Cluster(pos1, 'r')
	cluster2 = Cluster(pos2, 'g')
	cluster3 = Cluster(pos3, 'b')

	changed = True

	while(changed):
		changed = False

		while(cluster1.isEmpty() or cluster2.isEmpty() or cluster3.isEmpty()):
			cluster1.clear()
			cluster2.clear()
			cluster3.clear()


			for point in points:
				cluster = utl.closerCluster3D(cluster1, cluster2, cluster3, point)
				cluster.addPoint(point)
			
			randomPosition(cluster1, min_x, max_x, min_y, max_y, min_z, max_z)
			randomPosition(cluster2, min_x, max_x, min_y, max_y, min_z, max_z)
			randomPosition(cluster3, min_x, max_x, min_y, max_y, min_z, max_z)

		utl.draw(cluster1, cluster2, cluster3)

		cluster1.centralize();
		cluster2.centralize();
		cluster3.centralize();

		utl.draw(cluster1, cluster2, cluster3)

		for point in points:
			cluster = utl.closerCluster3D(cluster1, cluster2, cluster3, point)
			print("after center")
			if(not cluster.hasPoint(point)):
				print("changed")
				changed = True
				cluster1.clear()
				cluster2.clear()
				cluster3.clear()
				break;


	print("cluster 1:")
	for point in cluster1.points:
		print("x: ", point.x, " y: ", point.y, " z: ", point.z)
	print("cluster 2:")
	for point in cluster2.points:
		print("x: ", point.x, " y: ", point.y, " z: ", point.z)
	print("cluster 3:")
	for point in cluster3.points:
		print("x: ", point.x, " y: ", point.y, " z: ", point.z)
	utl.draw(cluster1, cluster2, cluster3)
コード例 #3
0
ファイル: scheduler_base.py プロジェクト: yxd886/scheduler 
class Scheduler(object):
    def __init__(self, name, trace, logger):
        self.name = name  # e.g., 'DRF'
        self.trace = trace
        if logger is None:
            assert name
            self.logger = log.getLogger(name=name, fh=False)
        else:
            self.logger = logger

        self.cluster = Cluster(self.logger)
        self.curr_ts = 0
        self.end = False

        self.running_jobs = set()
        self.uncompleted_jobs = set()
        self.completed_jobs = set()

        self.data = None  # all state action pairs in one ts
        self.rewards = []

    def step(self):
        # step by one timeslot
        assert not self.end
        self._prepare()
        self._schedule()
        self._progress()
        if len(self.completed_jobs) == pm.TOT_NUM_JOBS:
            self.end = True
        self.curr_ts += 1
        return self.data

    def get_results(self):
        # get final results, including avg jct, makespan and avg reward
        jct_list = [(job.end_time - job.arrv_time + 1.0)
                    for job in self.completed_jobs]
        makespan = max([job.end_time + 1.0 for job in self.completed_jobs])
        assert jct_list
        return (len(self.completed_jobs), 1.0 * sum(jct_list) / len(jct_list),
                makespan, sum(self.rewards) / len(self.rewards))

    def get_job_jcts(self):
        jcts = dict()
        for job in self.completed_jobs:
            jcts[job.id] = job.end_time - job.arrv_time + 1.0
        return jcts

    def _prepare(self):
        self.cluster.clear()
        self.data = []
        self.running_jobs.clear()
        if self.curr_ts in self.trace:
            for job in self.trace[self.curr_ts]:
                job.reset(
                )  # must reset since it is trained for multiple epochs
                self.uncompleted_jobs.add(job)
                self.logger.debug(job.info())
        for job in self.uncompleted_jobs:
            job.num_workers = 0
            job.curr_worker_placement = []
            if pm.PS_WORKER:
                job.num_ps = 0
                job.curr_ps_placement = []
        # sort based on used resources from smallest to largest for load balancing
        self.node_used_resr_queue = Queue.PriorityQueue()
        for i in range(pm.CLUSTER_NUM_NODES):
            self.node_used_resr_queue.put((0, i))

    def _schedule(self):
        self.logger.info("This method is to be implemented on child class!")

    def _progress(self):
        reward = 0
        for job in self.running_jobs.copy():
            epoch = job.step()
            reward += epoch / job.num_epochs
            if job.progress >= job.real_num_epochs:
                job.end_time = self.curr_ts
                # self.running_jobs.remove(job)
                self.uncompleted_jobs.remove(job)
                self.completed_jobs.add(job)
        if pm.NUM_UNCOMPLETED_JOB_REWARD:
            reward = len(self.uncompleted_jobs)
        self.rewards.append(reward)

    def observe(self):
        '''
		existing resource share of each job: 0-1
		job type 0-8
		job normalized progress 0-1
		num of backlogs: percentage of total number of jobs in the trace
		'''
        # cluster_state = self.cluster.get_cluster_state()
        # for test, first use dominant resource share of each job as input state
        q = Queue.PriorityQueue()
        for job in self.uncompleted_jobs:
            if pm.PS_WORKER:
                if job.num_workers >= pm.MAX_NUM_WORKERS and job.num_ps >= pm.MAX_NUM_WORKERS:  # and, not or
                    continue
            else:
                if job.num_workers >= pm.MAX_NUM_WORKERS:  # not schedule it any more
                    continue
            if pm.JOB_SORT_PRIORITY == "Resource":
                q.put((job.dom_share, job.arrv_time, job))
            elif pm.JOB_SORT_PRIORITY == "Arrival":
                q.put((job.arrv_time, job.arrv_time, job))
            elif pm.JOB_SORT_PRIORITY == "Progress":
                q.put((1 - job.progress / job.num_epochs, job.arrv_time, job))

        if pm.ZERO_PADDING:
            state = np.zeros(shape=pm.STATE_DIM)  # zero padding instead of -1
        else:
            state = -1 * np.ones(shape=pm.STATE_DIM)
        self.window_jobs = [None for _ in range(pm.SCHED_WINDOW_SIZE)]

        shuffle = np.array([i for i in range(pm.SCHED_WINDOW_SIZE)
                            ])  # default keep order
        if pm.JOB_ORDER_SHUFFLE:
            shuffle = np.random.choice(pm.SCHED_WINDOW_SIZE,
                                       pm.SCHED_WINDOW_SIZE,
                                       replace=False)

        # resource share / job arrival / progress
        for order in shuffle:
            if not q.empty():
                _, _, job = q.get()
                j = 0
                for (
                        input, enable
                ) in pm.INPUTS_GATE:  # INPUTS_GATE=[("TYPE",True), ("STAY",False), ("PROGRESS",False), ("DOM_RESR",False), ("WORKERS",True)]
                    if enable:
                        if input == "TYPE":
                            if not pm.INPUT_RESCALE:
                                if not pm.TYPE_BINARY:
                                    state[j][order] = job.type
                                else:
                                    bin_str = "{0:b}".format(job.type).zfill(4)
                                    for bin_ch in bin_str:
                                        state[j][order] = int(bin_ch)
                                        j += 1
                                    j -= 1
                            else:
                                state[j][order] = float(job.type) / 8
                        elif input == "STAY":
                            if not pm.INPUT_RESCALE:
                                state[j][order] = self.curr_ts - job.arrv_time
                            else:
                                state[j][order] = float(self.curr_ts -
                                                        job.arrv_time) / 100
                        elif input == "PROGRESS":
                            state[j][order] = 1 - job.progress / job.num_epochs
                        elif input == "DOM_RESR":
                            state[j][order] = job.dom_share
                        elif input == "WORKERS":
                            if not pm.INPUT_RESCALE:
                                state[j][order] = job.num_workers
                            else:
                                state[j][order] = float(
                                    job.num_workers) / pm.MAX_NUM_WORKERS
                        elif input == "PS":
                            if not pm.INPUT_RESCALE:
                                state[j][order] = job.num_ps
                            else:
                                state[j][order] = float(
                                    job.num_ps) / pm.MAX_NUM_WORKERS
                        else:
                            raise RuntimeError
                        j += 1
                self.window_jobs[order] = job

        # backlog = float(max(len(self.uncompleted_jobs) - pm.SCHED_WINDOW_SIZE, 0))/len(pm.TOT_NUM_JOBS)
        self.logger.debug("ts: " + str(self.curr_ts) \
              + " backlog: " + str(max(len(self.uncompleted_jobs) - pm.SCHED_WINDOW_SIZE, 0)) \
              + " completed jobs: " + str(len(self.completed_jobs)) \
              + " uncompleted jobs: " + str(len(self.uncompleted_jobs)))
        return state

    def _state(
        self,
        label_job_id,
        role="worker"
    ):  # whether this action selection leads to worker increment or ps increment
        # cluster_state = self.cluster.get_cluster_state()
        input = self.observe()  #  NN input
        label = np.zeros(pm.ACTION_DIM)
        for i in range(pm.SCHED_WINDOW_SIZE):
            job = self.window_jobs[i]
            if job and job.id == label_job_id:
                if pm.PS_WORKER:
                    if pm.BUNDLE_ACTION:
                        if role == "worker":
                            label[i * 3] = 1
                        elif role == "ps":
                            label[i * 3 + 1] = 1
                        elif role == "bundle":
                            label[i * 3 + 2] = 1
                    else:
                        if role == "worker":
                            label[i * 2] = 1
                        elif role == "ps":
                            label[i * 2 + 1] = 1
                else:
                    label[i] = 1
        self.data.append((input, label))