Exemplo n.º 1
0
def revive_simulation(rev_parameters, sim_functions):
    print('\n[' + rev_parameters["simulation_name"].upper() + ' REVIVAL SIMULATION]')
    Populations = {}
    if "sim_folder" in rev_parameters:
        print('Accessing simulation files directory...') 
        print('Excavating World entity: ' + rev_parameters['eco_file'] + '...')
        World = excavate_world(rev_parameters['sim_folder'] + \
                               rev_parameters['eco_file'])
        print('Updating parameters with World dimensions...')
        rev_parameters["world_z"] = len(World.ecosystem[0][0][0])
        rev_parameters["world_y"] = len(World.ecosystem[0][0])
        rev_parameters["world_x"] = len(World.ecosystem[0])
        for i in range(len(rev_parameters["pop_files"])):
            print('\nReviving population file: ' + \
                rev_parameters["pop_files"][i] + '...')
            pop_file = rev_parameters["sim_folder"] + \
                rev_parameters["pop_files"][i]
            Populations[rev_parameters["population_names"][i]] = \
                revive_population(pop_file)
        print('\nUpdating revival generation start in simulation parameters...')
        rev_parameters["rev_start"] = [Populations[pop_name].generation 
                                       for pop_name in Populations]
    elif "database_source" in rev_parameters:
        print('Constructing database directory...')
        dbpath = os.sep.join([os.getcwd(), 
                              'Simulations', 
                              rev_parameters["database_source"]])
        print('Connecting to database file: ' + \
            rev_parameters["database_source"] + '...')
        (con, cur) = connect_database(dbpath, None)
        if rev_parameters["simulation_time"] == 'default':
            print('Acquiring simulation starting time...')
            rev_parameters["simulation_time"] = db_list_simulations(cur)[0][0]
        print('Reconstructing old simulation parameters...')
        temp_parameters = db_reconstruct_simulation_parameters(cur, 
                                    rev_parameters["simulation_time"])
        print('Assimilating old simulation parameters with new simulation parameters...')
        for key in temp_parameters:
            if key not in rev_parameters:
                rev_parameters[key] = temp_parameters[key]
        print('Reconstructing World entity...')
        World = db_reconstruct_world(cur, rev_parameters["simulation_time"], 
                                     rev_parameters["rev_start"][0])
        print('\nUpdating population names parameter...')
        for pop_name in rev_parameters["population_names"]:
            print('Reconstructing population: ' + pop_name + '...')
            Populations[pop_name] = db_reconstruct_population(cur, 
                              rev_parameters["simulation_time"], pop_name, 
            rev_parameters["rev_start"][rev_parameters["population_names"].index(pop_name)])
        print('Terminating database connection...')
        con.close()
    print('Updating last generation revival and population size simulation parameters...')
    rev_parameters["rev_finish"] = [(Populations[pop_name].generation + \
                                     rev_parameters["extend_gen"]) 
                                    for pop_name in Populations]
    rev_parameters["rev_pop_size"] = [len(Populations[pop_name].agents) 
                                      for pop_name in Populations]
    print('\nStarting simulation core...')
    simulation_core(sim_functions, rev_parameters, Populations, World)
Exemplo n.º 2
0
 def __init__(self, db_source, population_name, starting_time = 'default'):
     print('\n[INITIALIZING ANALYSIS]')
     self.db_source = db_source
     self.population_name = population_name
     print('Assembling database file directory...')
     dbpath = os.getcwd().split(os.sep)
     dbpath[-1] = 'examples'
     dbpath = os.sep.join(dbpath)
     dbpath = os.sep.join([dbpath, 'Simulations', db_source])
     print('Connecting to database file: ' + db_source + '...')
     (self.con, self.cur) = database_calls.connect_database(dbpath, None)
     print('Acquiring simulation starting time...')
     if starting_time == 'default':
         self.starting_time = database_calls.db_list_simulations(self.cur)[0][0]
     else:
         self.starting_time = starting_time
Exemplo n.º 3
0
 def __init__(self, db_source, population_name, starting_time='default'):
     print('\n[INITIALIZING ANALYSIS]')
     self.db_source = db_source
     self.population_name = population_name
     print('Assembling database file directory...')
     dbpath = os.getcwd().split(os.sep)
     dbpath[-1] = 'examples'
     dbpath = os.sep.join(dbpath)
     dbpath = os.sep.join([dbpath, 'Simulations', db_source])
     print('Connecting to database file: ' + db_source + '...')
     (self.con, self.cur) = \
         database_calls.connect_database(dbpath, None)
     print('Acquiring simulation starting time...')
     if starting_time == 'default':
         self.starting_time = \
             database_calls.db_list_simulations(self.cur)[0][0]
     else:
         self.starting_time = starting_time
Exemplo n.º 4
0
def simulation_core(sim_functions, sim_parameters, eb, populations, world):
    '''
    Sequential ecological cell DOSE simulator.
    
    Performs the following operations:
        - Creating simulation file directory for results text file, population 
        freeze, and world burial storage
        - Generate a simulation start time to identify the current simulation
        - Define active Ragaraja instructions
        - Connecting to logging database (if needed)
        - Writing simulation parameters into results text file
        - Initialize World and Population
        - Deploy population(s) onto the world
        - Run the simulation and recording the results
        - Writing final results into results text file
        - Close logging database (if used)
        - Copy simulation script into simulation file directory

    Events available for subscription and data:
        - SIMULATION_START:
            - time_start: datetime = simulation start time
            - directory: String = simulation file path directory
            - max_generation: int = maximum generations
            - generation: int = starting generation
        - GENERATION_WORLD_UPDATE:
            - world: dose_world.World = world object
            - generation: int = current generation
        - GENERATION_POPULATIONS_UPDATE:
            - populations: dict = dictionary of population objects
            - generation: int = current generation
        - SIMULATION_END:
            - time_end: datetime = simulation end time
    
    @param sim_functions: implemented simulation functions (see 
    dose.dose_functions)
    @param sim_parameters: simulation parameters dictionary (see Examples)
    @param eb: An instance of dose.event_broker
    @param populations: dictionary of population objects
    @param world: dose_world.World object
    '''

    eb.log('Started simulation preparation')

    time_start = datetime.utcnow()
    time_start_str = '-'.join([str(time_start).split(' ')[0], str(time())])

    eb.log('Creating simulation file directories')
    directory = '_'.join([sim_parameters["simulation_name"], time_start_str])
    directory = os.sep.join([os.getcwd(), 'Simulations', directory]) + os.sep
    if not os.path.exists(directory):
        os.makedirs(directory)

    eb.log('Adding simulation directory to simulation parameters')
    sim_parameters["directory"] = directory

    eb.log('Adding starting time to simulation parameters')
    sim_parameters["starting_time"] = time_start_str

    sim_functions = sim_functions()

    eb.log('Activating ragaraja version: ' + str(sim_parameters["ragaraja_version"]))
    if sim_parameters["ragaraja_version"] == 0:
        ragaraja.activate_version(sim_parameters["ragaraja_version"], sim_parameters["ragaraja_instructions"])
    else:
        ragaraja.activate_version(sim_parameters["ragaraja_version"])

    con = None
    cur = None
    if "database_file" in sim_parameters and "database_logging_frequency" in sim_parameters:
        eb.log('Connecting to database file: ' + sim_parameters["database_file"])
        (con, cur) = connect_database(None, sim_parameters)
        eb.log('Logging simulation parameters to database file')
        (con, cur) = db_log_simulation_parameters(con, cur, sim_parameters)

    max_generations = None
    generation_count = None
    for pop_name in populations:
        eb.log('Preparing population: ' + pop_name + ' for simulation')
        if 'sim_folder' in sim_parameters or 'database_source' in sim_parameters:
            eb.log('Calculating final generation count')
            max_generations = sim_parameters["rev_start"][sim_parameters["population_names"].index(pop_name)] + \
                sim_parameters["extend_gen"]
            eb.log('Updating generation count from previous simulation')
            generation_count = sim_parameters["rev_start"][0]
        else:
            eb.log('Deploying population in World entity')
            if sim_parameters["deployment_code"] == 0:
                eb.log('Executing user defined deployment scheme')
                deploy_0(sim_parameters, populations, pop_name, world)
            elif sim_parameters["deployment_code"] == 1:
                eb.log('Executing deployment code 1: Single eco-cell deployment')
                deploy_1(sim_parameters, populations, pop_name, world)
            elif sim_parameters["deployment_code"] == 2:
                eb.log('Executing deployment code 2: Random eco-cell deployment')
                deploy_2(sim_parameters, populations, pop_name, world)
            elif sim_parameters["deployment_code"] == 3:
                eb.log('Executing deployment code 3: Even eco-cell deployment')
                deploy_3(sim_parameters, populations, pop_name, world)
            elif sim_parameters["deployment_code"] == 4:
                eb.log('Executing deployment code 4: Centralized eco-cell deployment')
                deploy_4(sim_parameters, populations, pop_name, world)
            max_generations = sim_parameters["maximum_generations"]
            generation_count = 0

        eb.log('Writing simulation parameters into txt file report')
        write_parameters(sim_parameters, pop_name)

        eb.log('Updating generation count')
        populations[pop_name].generation = generation_count

    eb.log('Simulation preparation complete')
    eb.publish(events.SIMULATION_START, {
        'time_start': time_start,
        'directory': directory,
        'max_generation': max_generations,
        'generation': generation_count
    })

    while generation_count < max_generations:
        generation_count += 1

        sim_functions.ecoregulate(world)
        eco_cell_iterator(world, sim_parameters, sim_functions.update_ecology)
        eco_cell_iterator(world, sim_parameters, sim_functions.update_local)
        eco_cell_iterator(world, sim_parameters, sim_functions.report)
        eb.publish(events.GENERATION_WORLD_UPDATE, {
            'world': world,
            'generation': generation_count
        })

        if generation_count % int(sim_parameters["eco_buried_frequency"]) == 0:
            bury_world(sim_parameters, world, generation_count)

        for pop_name in populations:
            if sim_parameters["interpret_chromosome"]:
                interpret_chromosome(sim_parameters, populations, pop_name, world)

            report_generation(sim_parameters, populations, pop_name, sim_functions, generation_count)
            sim_functions.organism_movement(populations, pop_name, world)
            sim_functions.organism_location(populations, pop_name, world)

        eb.publish(events.GENERATION_POPULATIONS_UPDATE, {
            'populations': populations,
            'generation': generation_count
        })

        if "database_file" in sim_parameters and "database_logging_frequency" in sim_parameters and \
                generation_count % int(sim_parameters["database_logging_frequency"]) == 0:
                (con, cur) = db_report(con, cur, sim_functions, sim_parameters["starting_time"], populations, world,
                                       generation_count)

        eb.log('Generation ' + str(generation_count) + ' complete')

    eb.log('Closing simulation results')
    for pop_name in populations:
        close_results(sim_parameters, pop_name)

    if "database_file" in sim_parameters and "database_logging_frequency" in sim_parameters:
        eb.log('Committing logged data into database file and terminating database connection')
        con.commit()
        con.close()

    eb.log('Copying simulation file script to simulation results directory')

    # DV on my system, the inspect.stack()[2][1] value returns the full
    # path to the file ('/home/douwe/scr/.../scriptname.py').
    # The end result is an error for the original code, below, as the
    # copyfile command is pointed to a wrong location: the directory
    # is added twice. This might be Py3, or Windows functionality.
    # With using the os.path module, this should give an OS-independent
    # way of extracting the basename and linking to the directory.
    sim_script_basename = os.path.basename(inspect.stack()[2][1])
    copyfile(inspect.stack()[2][1],
            # DV_original
            # sim_parameters['directory'] + inspect.stack()[2][1])
             os.path.join(sim_parameters['directory'], sim_script_basename))
    eb.log('Simulation ended')
    eb.publish(events.SIMULATION_END, {
        'time_end': datetime.utcnow()
    })
Exemplo n.º 5
0
def revive_simulation(rev_parameters, sim_functions, eb = event_broker()):

    eb.log("[" + rev_parameters["simulation_name"].upper() + " REVIVAL SIMULATION]")

    populations = {}
    world = None
    eb.log("Accessing simulation files directory")
    if "sim_folder" in rev_parameters:

        eb.log('Excavating World entity: ' + rev_parameters['eco_file'])
        world = excavate_world(rev_parameters['sim_folder'] + rev_parameters['eco_file'])

        eb.log('Updating parameters with World dimensions')
        rev_parameters["world_z"] = len(world.ecosystem[0][0][0])
        rev_parameters["world_y"] = len(world.ecosystem[0][0])
        rev_parameters["world_x"] = len(world.ecosystem[0])

        for i in range(len(rev_parameters["pop_files"])):
            eb.log('Reviving population file: ' + rev_parameters["pop_files"][i])
            pop_file = rev_parameters["sim_folder"] + rev_parameters["pop_files"][i]
            populations[rev_parameters["population_names"][i]] = revive_population(pop_file)

        eb.log('Updating revival generation start in simulation parameters')
        rev_parameters["rev_start"] = [populations[pop_name].generation for pop_name in populations]

    elif "database_source" in rev_parameters:

        eb.log('Constructing database directory')
        dbpath = os.sep.join([os.getcwd(), 'Simulations', rev_parameters["database_source"]])

        eb.log('Connecting to database file: ' + rev_parameters["database_source"])
        (con, cur) = connect_database(dbpath, None)

        if rev_parameters["simulation_time"] == 'default':
            eb.log('Acquiring simulation starting time')
            rev_parameters["simulation_time"] = db_list_simulations(cur)[0][0]

        eb.log('Reconstructing old simulation parameters')
        temp_parameters = db_reconstruct_simulation_parameters(cur, rev_parameters["simulation_time"])

        eb.log('Assimilating old simulation parameters with new simulation parameters')
        for key in temp_parameters:
            if key not in rev_parameters:
                rev_parameters[key] = temp_parameters[key]

        eb.log('Reconstructing World entity')
        world = db_reconstruct_world(cur, rev_parameters["simulation_time"], rev_parameters["rev_start"][0])

        eb.log('Updating population names parameter')
        for pop_name in rev_parameters["population_names"]:
            eb.log('Reconstructing population: ' + pop_name)
            populations[pop_name] = db_reconstruct_population(cur, rev_parameters["simulation_time"], pop_name,
                                                              rev_parameters["rev_start"][rev_parameters
                                                              ["population_names"].index(pop_name)])
        eb.log('Terminating database connection')
        con.close()

    eb.log('Updating last generation revival and population size simulation parameters')
    rev_parameters["rev_finish"] = [(populations[pop_name].generation + rev_parameters["extend_gen"])
                                    for pop_name in populations]
    rev_parameters["rev_pop_size"] = [len(populations[pop_name].agents) for pop_name in populations]

    eb.log('Starting simulation core')
    simulation_core(sim_functions, rev_parameters, populations, world)
Exemplo n.º 6
0
# needed to run this example without prior
# installation of DOSE into Python site-packages
import run_examples_without_installation

# Example codes starts from here
import dose, genetic, random, os
import simulation_calls as helper
import database_calls

dbpath = os.sep.join([os.getcwd(),
                      'Simulations',
                      "case_study_01"])
(con, cur) = database_calls.connect_database(dbpath, None)

World = database_calls.db_reconstruct_world(cur, '2013-10-19-1382200534.1', 1000)
Exemplo n.º 7
0
# needed to run this example without prior
# installation of DOSE into Python site-packages
import run_examples_without_installation

# Example codes starts from here
import dose, genetic, random, os
import simulation_calls as helper
import database_calls

dbpath = os.sep.join([os.getcwd(), 'Simulations', "case_study_01"])
(con, cur) = database_calls.connect_database(dbpath, None)

World = database_calls.db_reconstruct_world(cur, '2013-10-19-1382200534.1',
                                            1000)
def simulation_core(sim_functions, sim_parameters, Populations, World):
    '''
    Sequential ecological cell DOSE simulator.
    
    Performs the following operations:
        - Creating simulation file directory for results text file, population 
        freeze, and world burial storage
        - Generate a simulation start time to identify the current simulation
        - Define active Ragaraja instructions
        - Connecting to logging database (if needed)
        - Writing simulation parameters into results text file
        - Initialize World and Population
        - Deploy population(s) onto the world
        - Run the simulation and recording the results
        - Writing final results into results text file
        - Close logging database (if used)
        - Copy simulation script into simulation file directory
    
    @param sim_functions: implemented simulation functions (see 
    dose.dose_functions)
    @param sim_parameters: simulation parameters dictionary (see Examples)
    @param Populations: dictionary of population objects
    @param World: dose_world.World object
    '''
    time_start = '-'.join([str(datetime.utcnow()).split(' ')[0],
                           str(time())])
    print('Creating simulation file directories...')
    directory ='_'.join([sim_parameters["simulation_name"],time_start])
    directory = os.sep.join([os.getcwd(), 'Simulations', directory]) 
    directory = directory + os.sep
    if not os.path.exists(directory): os.makedirs(directory)
    print('Adding simulation directory to simulation parameters...')
    sim_parameters["directory"] = directory
    print('Adding starting time to simulation parameters...')
    sim_parameters["starting_time"] = time_start
    sim_functions = sim_functions()
    if sim_parameters["ragaraja_version"] == 0:
        print('Activating ragaraja version: 0...')
        ragaraja.activate_version(sim_parameters["ragaraja_version"],
                                  sim_parameters["ragaraja_instructions"])
    else:
        print('Activating ragaraja version: ' + \
            str(sim_parameters["ragaraja_version"]) + '...')
        ragaraja.activate_version(sim_parameters["ragaraja_version"])
    if "database_file" in sim_parameters and \
        "database_logging_frequency" in sim_parameters: 
        print('Connecting to database file: ' + \
            sim_parameters["database_file"] + '...')
        (con, cur) = connect_database(None, sim_parameters)
        print('Logging simulation parameters to database file...')
        (con, cur) = db_log_simulation_parameters(con, cur, sim_parameters)
    for pop_name in Populations:
        print('\nPreparing population: ' + pop_name + ' for simulation...')
        if 'sim_folder' in sim_parameters or \
            'database_source' in sim_parameters:
            print('Calculating final generation count...')
            max = sim_parameters["rev_start"] \
                [sim_parameters["population_names"].index(pop_name)] + \
                sim_parameters["extend_gen"]
            print('Updating generation count from previous simulation...')
            generation_count = sim_parameters["rev_start"][0]
        else:
            print('Deploying population in World entity...')
            if sim_parameters["deployment_code"] == 0:
                print('Executing user defined deployment scheme...')
                deploy_0(sim_parameters, Populations, pop_name, World)      
            elif sim_parameters["deployment_code"] == 1:
                print('Executing deployment code 1: Single eco-cell deployment...')
                deploy_1(sim_parameters, Populations, pop_name, World)  
            elif sim_parameters["deployment_code"] == 2:
                print('Executing deployment code 2: Random eco-cell deployment...')
                deploy_2(sim_parameters, Populations, pop_name, World)  
            elif sim_parameters["deployment_code"] == 3:
                print('Executing deployment code 3: Even eco-cell deployment...')
                deploy_3(sim_parameters, Populations, pop_name, World)  
            elif sim_parameters["deployment_code"] == 4:
                print('Executing deployment code 4: Centralized eco-cell deployment...')
                deploy_4(sim_parameters, Populations, pop_name, World)
            print('Adding maximum generations to simulation parameters...')
            max = sim_parameters["maximum_generations"]
            generation_count = 0
        print('Writing simulation parameters into txt file report...')
        write_parameters(sim_parameters, pop_name)
        print('Updating generation count...')
        Populations[pop_name].generation = generation_count
    print('\nSimulation preparation complete...')
    while generation_count < max:
        generation_count = generation_count + 1
        sim_functions.ecoregulate(World)
        eco_cell_iterator(World, sim_parameters,
                          sim_functions.update_ecology)
        eco_cell_iterator(World, sim_parameters,
                          sim_functions.update_local)
        eco_cell_iterator(World, sim_parameters, sim_functions.report)
        bury_world(sim_parameters, World, generation_count)
        for pop_name in Populations:
            if sim_parameters["interpret_chromosome"]:
                interpret_chromosome(sim_parameters, Populations, 
                                     pop_name, World)
            report_generation(sim_parameters, Populations, pop_name, 
                              sim_functions, generation_count)
            sim_functions.organism_movement(Populations, pop_name, World)
            sim_functions.organism_location(Populations, pop_name, World)
        if "database_file" in sim_parameters and \
            "database_logging_frequency" in sim_parameters and \
            generation_count % \
            int(sim_parameters["database_logging_frequency"]) == 0: 
                (con, cur) = db_report(con, cur, sim_functions,
                                   sim_parameters["starting_time"],
                                   Populations, World, generation_count)
        print('Generation ' + str(generation_count) + ' complete...')
    print('\nClosing simulation results...')
    for pop_name in Populations: close_results(sim_parameters, pop_name)
    if "database_file" in sim_parameters and \
        "database_logging_frequency" in sim_parameters:
        print('Committing logged data into database file...') 
        con.commit()
        print('Terminating database connection...') 
        con.close()
    print('Copying simulation file script to simulation results directory...')

    #DV on my system, the inspect.stack()[2][1] value returns the full
    #   path to the file ('/home/douwe/scr/.../scriptname.py'). 
    #   The end result is an error for the original code, below, as the 
    #   copyfile command is pointed to a wrong location: the directory
    #   is added twice. This might be Py3, or Windows functionality.
    #   With using the os.path module, this should give an OS-independent
    #   way of extracting the basename and linking to the directory.
    sim_script_basename = os.path.basename(inspect.stack()[2][1])
    copyfile(inspect.stack()[2][1], 
#DV_original#             sim_parameters['directory'] + inspect.stack()[2][1])
             os.path.join(sim_parameters['directory'], sim_script_basename))
    print('\nSimulation ended...')