Exemplo n.º 1
0
def run_boids(dims, boid_q, big_boid_q, is_running):
    global __is_running
    __is_running = True

    boids, big_boids = create_boids(dims)

    # Increase to have more frames per velocity change. This slows down and smooths visualisation.
    smoothness = 3

    t = SimpleTimer()
    i = 0

    # Number of iterations after which to reset target for boids to move at.
    # Needs to be run more often in 2D than in 3D.
    new_target_iter = dims * 10
    while __is_running and is_running.value:
        # apply rules that govern velocity
        boids.update_velocity()
        big_boids.update_velocity()

        for _ in xrange(smoothness):
            # move with a fixed velocity
            boids.move(1.0 / smoothness)
            big_boids.move(1.0 / smoothness)
            # copy the boids datastructure to avoid simultanious modification
            t.print_time("putting boids (copies) in queue")
            boid_q.put(boids.copy())
            big_boid_q.put(big_boids.copy())

        i += 1
        if i % new_target_iter == 0:
            t.print_time("set new position")
            boids.set_random_direction()
Exemplo n.º 2
0
def compress_binary_data(data):

	# 0x0: Get the length of data.
	length_of_data = len(data)

	number_of_zeros = 0
	number_of_ones = 0
	for b in data:
		if b is 1:
			number_of_ones += 1
		else:
			number_of_zeros += 1

	print('Number of 0s: ' + str(number_of_zeros))
	print('Number of 1s: ' + str(number_of_ones))

	percentage_of_digits_hit_needed = 0.15

	timer = SimpleTimer()

	print('Obtaining linear functions...', end='')
	timer.start_timer()
	linear_functions = linear.get_formulas_for_linear_functions(percentage_of_digits_hit_needed, data, length_of_data, number_of_ones)
	timer.end_timer()
	timer.print_time()

	print('Obtaining quadratic functions...', end='')
	timer.start_timer()
	quadratic_functions = quadratic.get_formulas_for_quadratic_functions(percentage_of_digits_hit_needed, data, length_of_data, number_of_ones)
	timer.end_timer()
	timer.print_time()

	all_functions = []

	print('Simplifying the linear functions.')

	print('Functions that work: ')
	for f in linear_functions:
		print(f)
		all_functions.append(f)

	for f in quadratic_functions:
		print(f)
		all_functions.append(f)

	print('Testing all combinations of functions to make a universal one...')

	return '1 LOLOL'
Exemplo n.º 3
0
class BoidSimulation(worker.Worker):
    def init(self):
        self.t = SimpleTimer(use_process_name=True)
        # Number of iterations after which to reset target for boids to move at.
        # Needs to be run more often in 2D than in 3D.
        self.new_target_iter = 45
        self.i = 0
        self.init_boids()
        self.worker.add_result('boids', self.boids.copy())
        self.worker.add_result('big_boids', self.big_boids.copy())

    def init_boids(self):
        N_BIG_BOIDS = 0
        self.boids, self.big_boids = create_boids_3D(num_boids,
                                                     N_BIG_BOIDS,
                                                     use_process=True)

    def iteration(self, input, input_nowait):
        self.t.print_time("viewer.run_boids(): top of loop")

        if 'escape' in input_nowait:
            escapes = input_nowait['escape']
            for near, far in escapes:
                self.boids.add_escapes_between(near, far)
            if len(escapes) > 0:
                self.i = 0

        self.boids.move(1.0)
        self.big_boids.move(1.0)
        self.t.print_time("viewer.run_boids(): moved boids")

        self.boids.update_velocity()
        self.big_boids.update_velocity()
        self.t.print_time("viewer.run_boids(): velocity computed")

        self.i += 1

        if self.i % self.new_target_iter == 0:
            self.boids.clear_escapes()

        self.t.print_time("viewer.run_boids(): placed boids (copies) in queue")
        return {'boids': self.boids.copy(), 'big_boids': self.big_boids.copy()}

    def finalize(self):
        print "finalizing boids"
        self.boids.finalize()
Exemplo n.º 4
0
def run_server_monitoring():
    """This checks the CPU and Memory performance of all designated servers every X seconds.
    :return: Void.
    """

    database_api = DatabaseSimpleCommands()

    timer = SimpleTimer()

    pulse_rate_in_seconds = 3.0
    start_time = time.time()

    global keep_monitoring_servers
    while keep_monitoring_servers:

        timer.start_timer()
        # CPU/MEMORY Monitor here.
        global all_servers
        for server in all_servers:

            # Only poll the server if it is alive.
            if server.get_is_alive():
                '''
                From 'top's man page.
                -----------------------------------------------------------------------------------------------------------------------------------
                -n  :Number-of-iterations limit as:  -n number
                Specifies the maximum number of iterations,  or  frames,  top should produce before ending.
                -----------------------------------------------------------------------------------------------------------------------------------
                -b  :Batch-mode operation
                Starts top in 'Batch' mode, which could be useful for sending output from top to other programs or to a file. In this
                mode, top will not accept input and runs until the iterations limit  you've  set with the '-n' command-line option or until
                killed.
                -----------------------------------------------------------------------------------------------------------------------------------
                -p  :Monitor-PIDs mode as:  -pN1 -pN2 ...  or  -pN1,N2,N3 ...
                Monitor only processes with specified process IDs. This option can be given up to 20 times, or you can provide a comma
                delimited list with up to 20 pids. Co-mingling both approaches is permitted.

                A  pid value of zero will be treated as the process id of the top program itself once it is running.

                This is a command-line option only and  should  you  wish  to return  to  normal operation, it is not necessary to quit and
                restart top  --  just issue any  of  these  interactive  commands: '=', 'u' or 'U'.

                The 'p', 'u' and 'U' command-line options are mutually exclusive.
                ------------------------------------------------------------------------------------------------------------------------------------
                '''

                p = subprocess.Popen(['top', '-p', str(server.get_pid()), '-n', '1', '-b'], stdout=subprocess.PIPE, stderr=subprocess.PIPE)
                out, err = p.communicate()

                top_output = out.decode('ascii')
                #print(top_output)
                if 'utarsuno' in top_output:
                    #print(top_output[top_output.index('utarsuno'):len(top_output) - 1])

                    output_split = top_output[top_output.index('utarsuno'):len(top_output) - 1].split()
                    #print('CPU: ' + str(output_split[7]) + '\tMEMORY: ' + str(output_split[8]))

                    database_api.insert_row_into_table(daa.GLOBAL_TABLE_SERVER_MONITOR.get_table_name(), daa.GLOBAL_TABLE_SERVER_MONITOR.get_all_column_names(),
                                                       ["'" + server.get_name() + "'", "'" + simple_timer.get_now_timestamp_as_string() + "'", str(output_split[7]), str(output_split[8]), 'true'])
                else:
                    server.set_is_alive(False)
                    # The server is dead here
                    database_api.insert_row_into_table(daa.GLOBAL_TABLE_SERVER_MONITOR.get_table_name(), daa.GLOBAL_TABLE_SERVER_MONITOR.get_all_column_names(),
                                                       ["'" + server.get_name() + "'", "'" + simple_timer.get_now_timestamp_as_string() + "'", '0.0', '0.0', 'false'])
            else:
                # The server is dead here
                database_api.insert_row_into_table(daa.GLOBAL_TABLE_SERVER_MONITOR.get_table_name(), daa.GLOBAL_TABLE_SERVER_MONITOR.get_all_column_names(),
                                                   ["'" + server.get_name() + "'", "'" + simple_timer.get_now_timestamp_as_string() + "'", '0.0', '0.0', 'false'])

                #if server == scraper_server:
                    #print('Turning on the scraper server.')
                    #scraper_server.launch_server()


        timer.end_timer()
        timer.print_time()
        time.sleep(pulse_rate_in_seconds - ((time.time() - start_time) % pulse_rate_in_seconds))

    database_api.terminate()
    print('Server monitoring has terminated!')
Exemplo n.º 5
0
    big_boids = bds.get_result('big_boids')

    if with_shadow_model:
        shadow_bds = worker.WorkerProcess(
            'unaltered boids', ShadowBoidSimulation(boids, big_boids), {}, {
                'boids': 2,
                'big_boids': 2
            })

        shadow_boids = shadow_bds.get_result('boids')
        shadow_big_boids = shadow_bds.get_result('big_boids')
    else:
        shadow_boids = shadow_big_boids = None

    t = SimpleTimer(name="main")
    t.print_time('Starting 3D interface')

    glgame = GLPyGame3D(settings, interactions_file)

    while bds.continue_run():

        t.print_time('calling process_events()')
        points = process_events(glgame, bds, boids, big_boids, shadow_boids,
                                shadow_big_boids)

        if glgame.animate and bds.continue_run():

            t.print_time('getting boids from queue')

            boids = bds.get_result('boids')
            big_boids = bds.get_result('big_boids')
Exemplo n.º 6
0
    def calculate_velocity(self):
        t = SimpleTimer(use_process_name=True)
        tmp_velocity = np.zeros((self.size, self.dimensions))
        self.adjacency_list
        t.print_time("computed adjacency list")
        if self.use_process:
            self.velocity_worker.add_input(
                'matrix', (self.velocity, self.adjacency_list))
            self.position_worker.add_input(
                'matrix', (self.position, self.adjacency_list))
            t.print_time("sent message to rule process")
        else:
            tmp_velocity += self.converge_velocity_neighbors()
            t.print_time("converge velocity")
            tmp_velocity += self.converge_position_neighbors()
            t.print_time("converge position")

        tmp_velocity += self.avoid_neighbors()
        t.print_time("avoid neighbor")

        # self.velocity += self.approach_position(self.center, self.rule1_factor)
        if self.enforce_bounds:
            tmp_velocity += self.ruleBounds()
            t.print_time("avoid bounds")
        if self.in_random_direction:
            tmp_velocity += self.ruleDirection()
            t.print_time("random direction")

        for e in self.escapes:
            tmp_velocity += self.escape_position(e, self.escape_threshold)
        t.print_time("avoid escapes")
        for bb in self.big_boids.position:
            tmp_velocity += self.escape_position(bb, self.escape_threshold)

        # self.velocity += (np.random.random((self.size, self.dimensions)) - 0.5)*0.00005
        if self.use_process:
            tmp_velocity += self.velocity_worker.get_result('converged')
            tmp_velocity += self.position_worker.get_result('converged')
            t.print_time("applied process results")

        self.velocity += tmp_velocity
        self.apply_min_max_velocity()
        t.print_time("apply min max")

        self.update_redness()
Exemplo n.º 7
0
class WorkerClient(object):
    def __init__(self, target, input_queues, nowait_queues, result_queues,
                 is_running, *queues):
        self.target = target
        self.input_queues = input_queues
        self.nowait_queues = nowait_queues
        self.result_queues = result_queues
        self.is_running = is_running
        self.t = SimpleTimer(use_process_name=True)

    def work(self):
        self.t.reset()
        self.target.setWorkerClient(self)
        self.target.init()
        try:
            self.target.run()
        except Exception as e:
            print e

        self.t.print_time("finished running")
        # empty input queue
        clear_queues(self.input_queues)
        clear_queues(self.nowait_queues)
        close_queues(self.result_queues)

        self.t.print_time("finalizing target")
        self.target.finalize()
        self.t.print_time("finalized target")

    def get_all_input(self):
        return dict((k, self.get_input(k)) for k in self.input_queues.keys())

    def get_all_nowait(self):
        nowait_inputs = {}
        for key in self.nowait_queues.keys():
            nowait_inputs[key] = []
            try:
                while True:
                    value = self.get_input_nowait(key)
                    if value is None:
                        nowait_inputs[key] = None
                        break
                    nowait_inputs[key].append(value)
            except:
                continue

        return nowait_inputs

    def has_input_queue(self, queue):
        return queue in self.input_queues

    def has_input(self, queue):
        return not self.input_queues[queue].empty()

    def add_result(self, queue, value):
        self.result_queues[queue].put(value)

    def add_all_results(self, results):
        for queue, result in results.iteritems():
            self.add_result(queue, result)

    def get_input(self, queue):
        value = self.input_queues[queue].get()
        # don't finalize final queue
        if value is None:
            del self.input_queues[queue]
        return value

    def get_input_nowait(self, queue):
        value = self.nowait_queues[queue].get_nowait()
        # don't finalize final queue
        if value is None:
            del self.nowait_queues[queue]
        return value

    def continue_run(self):
        return self.is_running.value
Exemplo n.º 8
0
class WorkerProcess(object):
    def __init__(self, pname, target, input_queue_args, result_queue_args):
        self.t = SimpleTimer(name='manager_' + pname)
        input_queues = {}
        nowait_queues = {}
        result_queues = {}

        for name, size in input_queue_args.iteritems():
            if size is None:
                input_queues[name] = mp.Queue()
            elif size is 0:
                nowait_queues[name] = mp.Queue()
            else:
                input_queues[name] = mp.Queue(maxsize=size)

        for name, size in result_queue_args.iteritems():
            if size is None:
                result_queues[name] = mp.Queue()
            else:
                result_queues[name] = mp.Queue(maxsize=size)

        is_running = mp.Value('b', True)

        args = (target, input_queues, nowait_queues, result_queues, is_running)
        print args

        self.process = mp.Process(name=pname, target=do_work, args=args)
        self.process.start()

        self.client = WorkerClient(*args)

    def has_result_queue(self, queue):
        return queue in self.client.result_queues

    def get_result(self, queue):
        value = self.client.result_queues[queue].get()
        # don't finalize final queue
        if value is None:
            del self.client.result_queues[queue]
        return value

    def add_input(self, queue, value):
        self.client.input_queues[queue].put(value)

    def add_input_nowait(self, queue, value):
        self.client.nowait_queues[queue].put(value)

    def finalize(self):
        self.t.reset()
        self.stop_running()
        # send final call
        self.t.print_time("final iter value")
        close_queues(self.client.input_queues)
        self.t.print_time("final nowait value")
        close_queues(self.client.nowait_queues)
        # empty result queue
        clear_queues(self.client.result_queues, empty_first=True)

        self.process.join()

    def continue_run(self):
        return self.client.is_running.value

    def stop_running(self):
        self.client.is_running.value = False