def __load_bounds(self):
"""
Attempts to load the persisted size/location details from the geometry
settings files, and adjust the form's current state to match.
"""
do_default_loc = True
if self.__persist_size_key_s or self.__persist_loc_key_s:
prefs = load_map(Resources.GEOMETRY_FILE)
# grab the stored size value, if any, and apply it
if self.__persist_size_key_s and self.__persist_size_key_s in prefs:
try:
size = prefs[self.__persist_size_key_s].split(',')
self.Size = Size(int(size[0]), int(size[1]))
except:
# didn't work, just stick with the forms current size
pass
# grab the stored location value, if any, and apply it
if self.__persist_loc_key_s and self.__persist_loc_key_s in prefs:
try:
loc = prefs[self.__persist_loc_key_s].split(',')
loc = Point(int(loc[0]), int(loc[1]))
self.Location = loc
do_default_loc = False
except:
do_default_loc = True
if do_default_loc:
self.CenterToParent()
def __init__(self, map_file=''):
if map_file == '':
print "No map file name supplied with map_class"
sys.exit()
self.map = utils.load_map(map_file+'_col.lvl')
self.height = len(self.map)-1
self.width = len(self.map[0])-1
self.floor = 0
def delegate():
if self.__persist_size_key_s or self.__persist_loc_key_s:
prefs = load_map(Resources.GEOMETRY_FILE)
if self.__persist_loc_key_s:
prefs[self.__persist_loc_key_s] =\
sstr(self.Location.X) + "," + sstr(self.Location.Y)
if self.__persist_size_key_s:
prefs[self.__persist_size_key_s] =\
sstr(self.Width) + "," + sstr(self.Height)
persist_map(prefs, Resources.GEOMETRY_FILE)
def __init__(self, width, height, map_file=''):
if map_file == '':
self.width = width
self.height = height
self.totalArea = width*height
self.map = []
self.buildGrid(self.wall)
self.fillGrid()
else:
self.map = utils.load_map('level1_col.lvl')
self.height = len(self.map)-1
self.width = len(self.map[0])-1
self.totalArea = width*height
def loadMapFile(self, map_file):
# Load the tile images
for infile in glob.glob( os.path.join('../data/images/tiles', '*.*') ):
self.tiles[infile[len(infile)-5]] = pygame.image.load(infile).convert_alpha()
# Load the sprite images
self.map_sprites = [pygame.image.load('../data/images/sprites/sprite%d.png' % n).convert_alpha() for n in range(6)]
self.map_sprites_rd = [53, 0, 128, 128, 0, 0]
self.map_sprites_list = []
self.tileWidth, self.tileHeight = self.tiles['0'].get_size()
# Load tiles
self.map_file = map_file
self.tileData1 = utils.load_char_map(self.map_file+'_layer1.lvl')
self.tileData2 = utils.load_char_map(self.map_file+'_layer2.lvl')
self.col_data = utils.load_map(self.map_file+'_col.lvl')
self.map_size = len(self.tileData1[0])-1
# Load up sprites
self.spriteData = utils.load_map(self.map_file+'_sprites.lvl')
for x in range(self.map_size):
for y in range(self.map_size):
if self.spriteData[y][x] is not 1: self.map_sprites_list.append((x,y,self.spriteData[y][x]))
def main():
parser = argparse.ArgumentParser()
parser.add_argument('-t', '--test', help="A test directory containing map.pgm, measure.csv, control.csv, and ground.csv files", required=True)
parser.add_argument('-s', '--states', help='The file containing the starting states to use')
parser.add_argument('-v', '--visualizer', action='store_const', const=True, help='Add this flag to turn on the visualizer', default=False)
parser.add_argument('-n', '--numstart', type=int, default=200)
args = parser.parse_args()
lmap = utils.load_map('tests/' + args.test + '/map.pgm')
controls = utils.load_csv('tests/' + args.test + '/control.csv') #a Tx2 array of T (delta phi, velocity)'s
measurements = utils.load_measurements('tests/' + args.test + '/measure.csv') #a TxMx2 array of T sets of M measurements containing a degree and a measured distance at that degree
true_start = utils.load_csv('tests/' + args.test + '/ground.csv')
if args.states:
start_posns = utils.load_csv(args.states) #a Nx3 array of N (x,y,phi)'s
else:
start_posns = generate_init_states(lmap, args.numstart)
print("Using particle_filter function...")
particle_filter(start_posns, controls, measurements, lmap, true_start, args.visualizer)
def load_defaults(self):
'''
Loads any settings that are saved in the user's settings files (if there
are any) and stores them in this Configuration object.
'''
# load the loaded dict out of the serialized file
loaded = {}
if File.Exists(Resources.SETTINGS_FILE):
loaded = load_map(Resources.SETTINGS_FILE)
# any settings that the serialized dict happens to contain
if Configuration.__API_KEY in loaded:
self.api_key_s = loaded[Configuration.__API_KEY]
if Configuration.__UPDATE_SERIES in loaded:
self.update_series_b = loaded[Configuration.__UPDATE_SERIES]
if Configuration.__UPDATE_NUMBER in loaded:
self.update_number_b = loaded[Configuration.__UPDATE_NUMBER]
if Configuration.__UPDATE_PUBLISHED in loaded:
self.update_published_b = loaded[Configuration.__UPDATE_PUBLISHED]
if Configuration.__UPDATE_RELEASED in loaded:
self.update_released_b = loaded[Configuration.__UPDATE_RELEASED]
if Configuration.__UPDATE_TITLE in loaded:
self.update_title_b = loaded[Configuration.__UPDATE_TITLE]
if Configuration.__UPDATE_CROSSOVERS in loaded:
self.update_crossovers_b = loaded[Configuration.__UPDATE_CROSSOVERS]
if Configuration.__UPDATE_WRITER in loaded:
self.update_writer_b = loaded[Configuration.__UPDATE_WRITER]
if Configuration.__UPDATE_PENCILLER in loaded:
self.update_penciller_b = loaded[Configuration.__UPDATE_PENCILLER]
if Configuration.__UPDATE_INKER in loaded:
self.update_inker_b = loaded[Configuration.__UPDATE_INKER]
if Configuration.__UPDATE_COVER_ARTIST in loaded:
self.update_cover_artist_b = loaded[Configuration.__UPDATE_COVER_ARTIST]
if Configuration.__UPDATE_COLORIST in loaded:
self.update_colorist_b = loaded[Configuration.__UPDATE_COLORIST]
if Configuration.__UPDATE_LETTERER in loaded:
self.update_letterer_b = loaded[Configuration.__UPDATE_LETTERER]
if Configuration.__UPDATE_EDITOR in loaded:
self.update_editor_b = loaded[Configuration.__UPDATE_EDITOR]
if Configuration.__UPDATE_SUMMARY in loaded:
self.update_summary_b = loaded[Configuration.__UPDATE_SUMMARY]
if Configuration.__UPDATE_IMPRINT in loaded:
self.update_imprint_b = loaded[Configuration.__UPDATE_IMPRINT]
if Configuration.__UPDATE_PUBLISHER in loaded:
self.update_publisher_b = loaded[Configuration.__UPDATE_PUBLISHER]
if Configuration.__UPDATE_VOLUME in loaded:
self.update_volume_b = loaded[Configuration.__UPDATE_VOLUME]
if Configuration.__UPDATE_CHARACTERS in loaded:
self.update_characters_b = loaded[Configuration.__UPDATE_CHARACTERS]
if Configuration.__UPDATE_TEAMS in loaded:
self.update_teams_b = loaded[Configuration.__UPDATE_TEAMS]
if Configuration.__UPDATE_LOCATIONS in loaded:
self.update_locations_b = loaded[Configuration.__UPDATE_LOCATIONS]
if Configuration.__UPDATE_WEBPAGE in loaded:
self.update_webpage_b = loaded[Configuration.__UPDATE_WEBPAGE]
if Configuration.__OVERWRITE_EXISTING in loaded:
self.ow_existing_b = loaded[Configuration.__OVERWRITE_EXISTING]
if Configuration.__IGNORE_BLANKS in loaded:
self.ignore_blanks_b = loaded[Configuration.__IGNORE_BLANKS]
if Configuration.__CONVERT_IMPRINTS in loaded:
self.convert_imprints_b = loaded[Configuration.__CONVERT_IMPRINTS]
if Configuration.__AUTOCHOOSE_SERIES in loaded:
self.autochoose_series_b = loaded[Configuration.__AUTOCHOOSE_SERIES]
if Configuration.__CONFIRM_ISSUE in loaded:
self.confirm_issue_b = loaded[Configuration.__CONFIRM_ISSUE]
if Configuration.__DOWNLOAD_THUMBS in loaded:
self.download_thumbs_b=loaded[Configuration.__DOWNLOAD_THUMBS]
if Configuration.__PRESERVE_THUMBS in loaded:
self.preserve_thumbs_b=loaded[Configuration.__PRESERVE_THUMBS]
if Configuration.__FAST_RESCRAPE in loaded:
self.fast_rescrape_b=loaded[Configuration.__FAST_RESCRAPE]
if Configuration.__RESCRAPE_NOTES in loaded:
self.rescrape_notes_b = loaded[Configuration.__RESCRAPE_NOTES]
if Configuration.__RESCRAPE_TAGS in loaded:
self.rescrape_tags_b = loaded[Configuration.__RESCRAPE_TAGS]
if Configuration.__SUMMARY_DIALOG in loaded:
self.summary_dialog_b = loaded[Configuration.__SUMMARY_DIALOG]
# grab the contents of the advanced settings file, too
if File.Exists(Resources.ADVANCED_FILE):
self.advanced_settings_s = load_string(Resources.ADVANCED_FILE)
def main():
parser = argparse.ArgumentParser(description="")
parser.add_argument("-b", "--biom-file", help="An input biom file", required=True)
parser.add_argument("-m", "--mapping-file", help="A mapping file", required=True)
parser.add_argument("-c", "--class-label", help="Which data are we trying to analyze", required=True)
parser.add_argument(
"-d",
"--subclass",
action="append",
help="Subselect only some of the data - if specified, this should appear at least twice with the adequate options. ex: -c SEX -d male -d female",
required=False,
)
parser.add_argument("-o", "--output-folder", help="The folder to output our data to", required=True)
parser.add_argument("-p", "--min-features", help="Minimum number of features to test", default=50, required=False)
parser.add_argument("-q", "--max-features", help="Maximum number of features to test", default=150, required=False)
parser.add_argument(
"-s",
"--step-size",
help="Step size within the range of the number of features to be tested",
default=1,
required=False,
)
# parser.add_argument("-p", "--predictor", help="Classifier/Predictor used", default="nbc", required=False) # As of today, contains only nbc
parser.add_argument(
"-j",
"--objective-function",
help="Objective function for the feature selection algorithm",
default="mim",
required=False,
)
parser.add_argument(
"-t",
"--output-type",
help="data output format. default: CSV options: csv, matlab, r, numpy",
default="csv",
required=False,
)
parser.add_argument(
"-f",
"--select-field",
help="Field to extract a subset of the data. e.g. EN_BIOME, COUNTRY. The default considers the whole dataset",
default=None,
required=False,
)
parser.add_argument(
"-g",
"--value-field",
action="append",
help="When used with -f specifies the value of the field to filter - THIS IS REQUIRED IF -f if present",
default=None,
required=False,
)
parser.add_argument(
"-k",
"--cluster",
action="append",
help="Allows to subgroup some of the labels. Ex: -k 'Vegan Vegan+Seafood'. The different values are separated with semi colon. Requires at least two appearances. This cannot be used in conjunction with the -d option",
default=None,
required=False,
)
## Need to be continued!!!!
print "Definition of the arguments done"
global output_type
print "Start of the program"
args = parser.parse_args()
output_type = args.output_type.lower()
# if our folder doesn't exist create it
if not os.path.isdir(args.output_folder):
os.mkdir(args.output_folder)
nb_features = range(int(args.min_features), int(args.max_features) + 1, int(args.step_size))
print "nb_features prepared"
matrix, site_names, otu_ids, otu_phylo = utils.load_biom(args.biom_file)
metadata = utils.load_map(args.mapping_file)
class_labels = []
for sample in site_names:
class_labels.append(metadata[sample][args.class_label])
print "class_labels loaded"
interesting_samples = range(0, len(site_names))
if args.select_field is not None:
interesting_fields = [it.lower() for it in args.value_field]
print interesting_fields
subsample_habitat = [
i
for i, sample in enumerate(site_names)
if metadata[sample][args.select_field].lower() in interesting_fields
]
interesting_samples = list(set(interesting_samples).intersection(set(subsample_habitat)))
if args.subclass is not None:
target_labels = [it.lower() for it in args.subclass]
subsamples = [i for i in xrange(0, len(class_labels)) if class_labels[i].lower() in target_labels]
interesting_samples = list(set(interesting_samples).intersection(set(subsamples)))
if (args.cluster is not None) and (args.subclass is None):
print "In da cluster separation"
clusters = [it for it in args.cluster]
clusters_dict = {}
print "Initial Dictionary created"
for idx, a_cluster in enumerate(clusters):
print "In da loop"
# keys = a_cluster.split()
keys = a_cluster.split(";")
print keys
for a_key in keys:
clusters_dict[a_key.lower()] = idx
subsamples = [i for i in xrange(0, len(class_labels)) if class_labels[i].lower() in clusters_dict]
interesting_samples = list(set(interesting_samples).intersection(set(subsamples)))
for i in subsamples:
class_labels[i] = "cluster" + str(clusters_dict[class_labels[i].lower()])
matrix = matrix[interesting_samples, :]
class_labels = [class_labels[i] for i in interesting_samples]
class_labels, labels_key = utils.discretize(class_labels)
matrix = matrix + 1
row_sums = matrix.sum(axis=1)
matrix = matrix / row_sums[:, np.newaxis]
matrix = np.ceil(matrix / matrix.min())
# So far, we have the biom file open and the environment parameters
# We can now launch our feature selection algorithm
further_param = [] # This has to be adapted to the case we are using other objective functions
nb_tests = 10
nb_folds = 5
launch_tests_feature_selection(
matrix,
np.array(map(int, class_labels)),
site_names,
otu_ids,
otu_phylo,
args.objective_function,
nb_features,
nb_tests,
args.output_folder,
nb_folds,
)
avg_consistency, max_consistency, min_consistency, std_consistency = get_consistencies(
nb_features, len(otu_ids), nb_tests, args.output_folder
)
save_results(
"consistency",
os.path.join(args.output_folder, "consistencyresults.txt"),
avg_consistency,
max_consistency,
min_consistency,
std_consistency,
)
avg_accuracy_g, max_accuracy_g, min_accuracy_g, std_accuracy_g, avg_accuracy, max_accuracy, min_accuracy, std_accuracy = get_accuracies(
nb_features, len(otu_ids), nb_tests, args.output_folder
)
save_results(
"Accuracy",
os.path.join(args.output_folder, "accuracyGaussianresults.txt"),
avg_accuracy_g,
max_accuracy_g,
min_accuracy_g,
std_accuracy_g,
)
def __init__(self):
''' Initializes a new Configuration object with default settings '''
self.__prior_series_sl = set(utils.load_map(Resources.SERIES_FILE).keys())
def __init__(self):
''' Initializes a new Configuration object with default settings '''
self.__prior_series_sl = set(utils.load_map(Resources.SERIES_FILE).keys())
def runtest(mapfile, start, goal, verbose=True):
# directory to save results
result_dir = 'results'
if not os.path.exists(result_dir):
os.mkdir(result_dir)
map_name = mapfile.split('.')[-2].split('/')[-1]
plots_save_path = os.path.join(result_dir, map_name)
if os.path.exists(plots_save_path):
for file_name in os.listdir(plots_save_path):
os.remove(os.path.join(plots_save_path, file_name))
os.rmdir(plots_save_path)
os.mkdir(plots_save_path)
# display the environment
boundary, blocks = load_map(mapfile)
if verbose:
fig, ax, hb, hs, hg = draw_map(boundary, blocks, start, goal, 'map')
# mng = plt.get_current_fig_manager()
# mng.resize(*mng.window.maxsize())
plt.savefig(os.path.join(plots_save_path, 'result%04d.png' % 0))
# instantiate a robot planner
# RP = RobotPlannerGreedy(boundary, blocks)
# RP = RobotPlannerRTAA(boundary, blocks)
RP = RobotPlannerRRT(boundary,
blocks,
map_name,
display=True,
map_data=[fig, ax])
# main loop
robotpos = np.copy(start)
numofmoves = 0
max_time = 0
total_time = 0
trajectory = np.copy(start)
while True:
# call the robot planner
newrobotpos, move_time = RP.plan(robotpos, goal)
total_time += move_time
max_time = max(move_time, max_time)
movetime = max(1, np.ceil(move_time / 2.0))
# check if the planner was done on time
if movetime > 1:
newrobotpos = robotpos - 0.5 + np.random.rand(3)
print('\nWarning: move time exceeds limit.')
# check if the commanded position is valid
if not check(robotpos, newrobotpos, blocks, boundary):
success = False
break
# make the move
robotpos = newrobotpos
numofmoves += 1
trajectory = np.vstack((trajectory, robotpos))
print('\rNum of moves: %04d, move time: %.2f s, max time: %.2f s' %
(numofmoves, move_time, max_time),
end='',
flush=True)
# update plot
if verbose:
hs[0].set_xdata(robotpos[0])
hs[0].set_ydata(robotpos[1])
hs[0].set_3d_properties(robotpos[2])
ax.plot(trajectory[-2:, 0], trajectory[-2:, 1], trajectory[-2:, 2],
'r')
fig.canvas.flush_events()
plt.savefig(
os.path.join(plots_save_path, 'result%05d.png' % numofmoves))
# check if the goal is reached
if sum((robotpos - goal)**2) <= 0.1:
success = True
break
# exit if number of moves exceeds limit
if numofmoves >= 9999:
success = False
break
# calculate distance
distance = np.sum(np.linalg.norm(trajectory[1:] - trajectory[:-1], axis=1))
# save video & plot
if verbose:
print('\rSaving results...', end='', flush=True)
result_name = os.path.join(result_dir, map_name)
# save plot
hs[0].set_xdata(start[0])
hs[0].set_ydata(start[1])
hs[0].set_3d_properties(start[2])
ax.plot(trajectory[-2:, 0], trajectory[-2:, 1], trajectory[-2:, 2],
'r')
fig.canvas.flush_events()
plt.savefig(result_name + '.png')
save_gif(plots_save_path, result_name + '.gif')
print('\rResults have been saved to \'' + result_name + '.gif|png\'.',
end='',
flush=True)
plt.close(fig)
return success, numofmoves, distance, total_time, max_time
def load_defaults(self):
'''
Loads any settings that are saved in the user's settings files (if there
are any) and stores them in this Configuration object.
'''
# load the loaded dict out of the serialized file
loaded = {}
if File.Exists(Resources.SETTINGS_FILE):
loaded = load_map(Resources.SETTINGS_FILE)
# any settings that the serialized dict happens to contain
if Configuration.__API_KEY in loaded:
self.api_key_s = loaded[Configuration.__API_KEY]
if Configuration.__UPDATE_SERIES in loaded:
self.update_series_b = loaded[Configuration.__UPDATE_SERIES]
if Configuration.__UPDATE_NUMBER in loaded:
self.update_number_b = loaded[Configuration.__UPDATE_NUMBER]
if Configuration.__UPDATE_PUBLISHED in loaded:
self.update_published_b = loaded[Configuration.__UPDATE_PUBLISHED]
if Configuration.__UPDATE_RELEASED in loaded:
self.update_released_b = loaded[Configuration.__UPDATE_RELEASED]
if Configuration.__UPDATE_TITLE in loaded:
self.update_title_b = loaded[Configuration.__UPDATE_TITLE]
if Configuration.__UPDATE_CROSSOVERS in loaded:
self.update_crossovers_b = loaded[Configuration.__UPDATE_CROSSOVERS]
if Configuration.__UPDATE_WRITER in loaded:
self.update_writer_b = loaded[Configuration.__UPDATE_WRITER]
if Configuration.__UPDATE_PENCILLER in loaded:
self.update_penciller_b = loaded[Configuration.__UPDATE_PENCILLER]
if Configuration.__UPDATE_INKER in loaded:
self.update_inker_b = loaded[Configuration.__UPDATE_INKER]
if Configuration.__UPDATE_COVER_ARTIST in loaded:
self.update_cover_artist_b = loaded[Configuration.__UPDATE_COVER_ARTIST]
if Configuration.__UPDATE_COLORIST in loaded:
self.update_colorist_b = loaded[Configuration.__UPDATE_COLORIST]
if Configuration.__UPDATE_LETTERER in loaded:
self.update_letterer_b = loaded[Configuration.__UPDATE_LETTERER]
if Configuration.__UPDATE_EDITOR in loaded:
self.update_editor_b = loaded[Configuration.__UPDATE_EDITOR]
if Configuration.__UPDATE_SUMMARY in loaded:
self.update_summary_b = loaded[Configuration.__UPDATE_SUMMARY]
if Configuration.__UPDATE_IMPRINT in loaded:
self.update_imprint_b = loaded[Configuration.__UPDATE_IMPRINT]
if Configuration.__UPDATE_PUBLISHER in loaded:
self.update_publisher_b = loaded[Configuration.__UPDATE_PUBLISHER]
if Configuration.__UPDATE_VOLUME in loaded:
self.update_volume_b = loaded[Configuration.__UPDATE_VOLUME]
if Configuration.__UPDATE_CHARACTERS in loaded:
self.update_characters_b = loaded[Configuration.__UPDATE_CHARACTERS]
if Configuration.__UPDATE_TEAMS in loaded:
self.update_teams_b = loaded[Configuration.__UPDATE_TEAMS]
if Configuration.__UPDATE_LOCATIONS in loaded:
self.update_locations_b = loaded[Configuration.__UPDATE_LOCATIONS]
if Configuration.__UPDATE_WEBPAGE in loaded:
self.update_webpage_b = loaded[Configuration.__UPDATE_WEBPAGE]
if Configuration.__OVERWRITE_EXISTING in loaded:
self.ow_existing_b = loaded[Configuration.__OVERWRITE_EXISTING]
if Configuration.__IGNORE_BLANKS in loaded:
self.ignore_blanks_b = loaded[Configuration.__IGNORE_BLANKS]
if Configuration.__CONVERT_IMPRINTS in loaded:
self.convert_imprints_b = loaded[Configuration.__CONVERT_IMPRINTS]
if Configuration.__AUTOCHOOSE_SERIES in loaded:
self.autochoose_series_b = loaded[Configuration.__AUTOCHOOSE_SERIES]
if Configuration.__CONFIRM_ISSUE in loaded:
self.confirm_issue_b = loaded[Configuration.__CONFIRM_ISSUE]
if Configuration.__DOWNLOAD_THUMBS in loaded:
self.download_thumbs_b=loaded[Configuration.__DOWNLOAD_THUMBS]
if Configuration.__PRESERVE_THUMBS in loaded:
self.preserve_thumbs_b=loaded[Configuration.__PRESERVE_THUMBS]
if Configuration.__FAST_RESCRAPE in loaded:
self.fast_rescrape_b=loaded[Configuration.__FAST_RESCRAPE]
if Configuration.__RESCRAPE_NOTES in loaded:
self.rescrape_notes_b = loaded[Configuration.__RESCRAPE_NOTES]
if Configuration.__RESCRAPE_TAGS in loaded:
self.rescrape_tags_b = loaded[Configuration.__RESCRAPE_TAGS]
if Configuration.__SUMMARY_DIALOG in loaded:
self.summary_dialog_b = loaded[Configuration.__SUMMARY_DIALOG]
# grab the contents of the advanced settings file, too
if File.Exists(Resources.ADVANCED_FILE):
self.advanced_settings_s = load_string(Resources.ADVANCED_FILE)
while (game_state == "char_screen"):
event_list = pygame.event.get()
for event in event_list:
if event.type == pygame.QUIT:
pygame.quit()
sys.exit()
elif event.type == pygame.KEYDOWN:
if event.key == pygame.K_s:
game_state = "cinematic_screen"
life = 3
jsonMap = "cave2.json"
initial_pos = (412, -1150)
shadow = 0
losing_time = 250
(x, y) = player.rect.x, player.rect.y
gameMap = load_map(jsonMap, initial_pos)
player_imgs = [
"dogefront.png", "dogeback.png", "dogeright.png",
"dogeleft.png"
]
player = Player(player_imgs[0], screen_center)
player.setImage(player_imgs[0])
radius = 300
offset = 130
elif event.type == pygame.MOUSEBUTTONDOWN:
current_mouse_pos = pygame.mouse.get_pos()
if (doge_portrait.pos.collidepoint(current_mouse_pos)):
print "Doge Character Selected"
game_state = "cinematic_screen"
doge_portrait.click = True
doge_portrait.state = "clicked"
def __init__(
self,
map,
robot_controller_class,
init_position=None,
steering_noise=0.01,
sonar_noise=0.1,
distance_noise=0.001,
measurement_noise=0.2,
speed=5.0,
turning_speed=0.4 * pi,
execution_cpu_time_limit=10.0,
simulation_time_limit=10.0,
simulation_dt=0.0,
frame_dt=0.1,
gps_delay=2.0,
collision_threshold=50,
iteration_write_frequency=1000,
visualisation=True,
print_robot=True,
print_logger=False,
):
"""
Initialize KrakrobotSimulator object
@param steering_noise - variance of steering in move
@param distance_noise - variance of distance in move
@param measurement_noise - variance of measurement (GPS??)
@param map - map for the robot simulator representing the maze or file to map
@param init_position - starting position of the Robot (can be moved to map class) [x,y,heading]
@param speed - distance travelled by one move action (cannot be bigger than 0.5, or he could traverse the walls)
@param simulation_time_limit - limit in ms for whole robot execution (also with init)
@param collision_threshold - maximum number of collisions after which robot is destroyed
@param simulation_dt - controlls simulation calculation intensivity
@param frame_dt - save frame every dt
@param robot - RobotController class that will be simulated in run procedure
"""
if type(map) is str:
grid, metadata = load_map(map)
self.map_title = metadata["title"]
self.grid = grid
for row in grid:
logger.info(row)
else:
self.grid = map
self.map_title = ""
self.N = len(self.grid)
self.M = len(self.grid[0])
self.iteration_write_frequency = iteration_write_frequency
self.collision_threshold = collision_threshold
if init_position is not None:
self.init_position = tuple(init_position)
else:
for i in xrange(self.N):
for j in xrange(self.M):
if self.grid[i][j] == MAP_START_POSITION:
self.init_position = (i, j, 0)
self.speed = speed
self.turning_speed = turning_speed
self.simulation_dt = simulation_dt
self.frame_dt = frame_dt
self.robot_controller = robot_controller_class()
self.print_robot = print_robot
self.print_logger = print_logger
self.visualisation = visualisation
self.sonar_time = SONAR_TIME
self.gps_delay = gps_delay
self.light_sensor_time = FIELD_TIME
self.tick_move = TICK_MOVE
self.tick_rotate = TICK_ROTATE
self.simulation_time_limit = simulation_time_limit
self.execution_cpu_time_limit = execution_cpu_time_limit
self.goal_threshold = 0.5 # When to declare goal reach
self.sonar_noise = sonar_noise
self.distance_noise = distance_noise
self.measurement_noise = measurement_noise
self.steering_noise = steering_noise
self.reset()
# TODO: Disable logger printing when needed
if self.print_logger:
logger.propagate = True
else:
logger.propagate = False
for i in xrange(self.N):
for j in xrange(self.M):
if self.grid[i][j] == MAP_GOAL:
self.goal = (i, j)
