326 lines
12 KiB
Python
326 lines
12 KiB
Python
import json
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import random
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import project_constants as const
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# import tile class
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import tile as tl
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# import mine models
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import mine_models.standard_mine as sm
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import mine_models.time_mine as tm
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import mine_models.chained_mine as cm
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class JsonGenerator:
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grid = dict()
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# constructor that can be used to set agent's initial state
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def __init__(self, agents_initial_position=(0, 0), agents_initial_direction=const.Direction.UP.value):
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# saving agent's initial state (position & direction)
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self.agents_initial_position = agents_initial_position
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self.agents_initial_direction = agents_initial_direction
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# saving data to the grid dictionary
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self.grid["agents_initial_state"] = {
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"position": format_position_to_str(agents_initial_position),
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"direction": agents_initial_direction
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}
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# sets agent's initial state
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def set_agents_initial_state(self, position=(0, 0), direction=const.Direction.UP.value):
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# setting fields in the instance
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self.agents_initial_position = position
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self.agents_initial_direction = direction
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# setting new agent's initial state
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self.grid["agents_initial_state"] = {
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"position": format_position_to_str(position),
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"direction": direction
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}
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# overwrites grid field with a new grid with randomized colors and mines
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def generate_randomized_grid(self, dimensions, mine_appearance_chance=0.15, predecessor_chance_decrease=0.25):
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# clearing grid field
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self.clear_grid()
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# getting grid dimensions
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num_of_rows, num_of_columns = dimensions
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tile_pool = []
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for i in range(num_of_rows):
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for j in range(num_of_columns):
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# picking random values for tiles
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random_tile_color = random.choice(const.STRUCT_TILE_COLORS)
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# adding added tile's indexes to a pool
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tile_pool.append((i, j))
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# creating random tile
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self.add_tile((i, j), random_tile_color)
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# deleting agent's starting tile from the pool
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deleted_row, deleted_column = self.agents_initial_position
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tile_pool.remove((int(deleted_row), int(deleted_column)))
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for i in range(num_of_rows):
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for j in range(num_of_columns):
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# checking if a mine will appear
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if random.random() < mine_appearance_chance and len(tile_pool) > 0 and tile_pool.__contains__((i, j)):
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# removing current tile from the pool
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tile_pool.remove((i, j))
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# choosing random mine parameters
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random_mine_type = random.choice(const.STRUCT_MINE_TYPES)
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random_attribute_values = []
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for attr_type in const.STRUCT_MINE_ATTRIBUTE_TYPES[random_mine_type]:
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random_attribute_values.append(_get_random_attribute_values(attr_type, dimensions))
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# adding the mine
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self.set_a_mine((i, j), random_mine_type, random_attribute_values)
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# if is ChainedMine create predecessors
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if random_mine_type == "chained":
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predecessor_appearance_chance = 1.0
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current_tile = format_position_to_str((i, j))
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# create chained predecessors
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while random.random() < predecessor_appearance_chance and len(tile_pool) > 0:
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predecessor_appearance_chance -= predecessor_chance_decrease
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predecessor_position = random.choice(tile_pool)
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predecessor = format_position_to_str(predecessor_position)
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tile_pool.remove(predecessor_position)
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self.set_a_mine(predecessor_position, "chained", [])
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self.grid[current_tile]["mine"]["predecessor"] = predecessor
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self.grid[predecessor]["mine"]["predecessor"] = None
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current_tile = predecessor
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# adds a new tile or edits an existing one in the grid field
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def add_tile(self, position, color):
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# creating new tile without a mine
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self.grid[format_position_to_str(position)] = {
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"color": color,
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"mine": None
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}
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# adds a new tile with a mine or edits an existing one in the grid field
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def add_tile_with_a_mine(self, position, color, mine_type, attribute_values):
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# setting mine data using attribute_values
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mine_values = const.STRUCT_MINE_ATTRIBUTES[mine_type]
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for key in mine_values.keys():
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if key not in const.HARDCODED_VALUES and len(attribute_values) > 0:
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mine_values[key] = attribute_values.pop(0)
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# creating a new tile
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self.grid[format_position_to_str(position)] = {
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"color": color
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}
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# updating the tile with a mine field
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self.grid[format_position_to_str(position)]["mine"] = {}
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for key in mine_values.keys():
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self.grid[format_position_to_str()]["mine"][key] = mine_values[key]
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# deletes a mine with a given position from the grid field
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def delete_a_tile(self, position):
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# deleting a tile with given key
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self.grid.pop(format_position_to_str(position))
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# adds a mine to a tile stored in the grid field
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def set_a_mine(self, position, mine_type, attribute_values):
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# setting mine data using attribute_values
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mine_values = const.STRUCT_MINE_ATTRIBUTES[mine_type]
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for key in mine_values.keys():
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if key not in const.HARDCODED_VALUES and len(attribute_values) > 0:
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mine_values[key] = attribute_values.pop(0)
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# adding a mine to the edited tile
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self.grid[format_position_to_str(position)]["mine"] = {}
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for key in mine_values.keys():
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self.grid[format_position_to_str(position)]["mine"][key] = mine_values[key]
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# deletes a mine from a tile stored in the grid field
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def delete_a_mine(self, position):
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# removing mine from the edited tile
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self.grid[format_position_to_str(position)]["mine"] = None
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# returns chosen tiles data
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def get_tile(self, position):
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return self.grid[format_position_to_str(position)]
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# returns chosen mines data
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def get_mine(self, position):
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return self.grid[format_position_to_str(position)]["mine"]
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# returns the grid field
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def get_grid(self):
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return self.grid
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# clears the grid field
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def clear_grid(self):
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# clearing grid dict
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self.grid.clear()
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# re-setting the agent's initial state
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self.grid["agents_initial_state"] = {
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"position": format_position_to_str(self.agents_initial_position),
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"direction": self.agents_initial_direction
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}
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# loads a grid from a file and overwrites the grid field
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def load_from_a_file(self, file_path):
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# opening a file for reading
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with open(file_path, 'r') as input_file:
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# overwriting the grid field with the grid stored in a file
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self.grid = json.load(input_file)
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# saves the current grid field to a file
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def save_to_a_file(self, file_path, access_mode):
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# opening a file with a given access mode (w - write / a - append)
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with open(file_path, access_mode) as output_file:
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# saving the grid to the file
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json.dump(self.grid, output_file, indent=2, sort_keys=True)
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# edits a grid in a file. doesn't delete data, only overwrites and adds new entries
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def edit_a_file(self, file_path):
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# opening a file for reading
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with open(file_path, "r") as input_file:
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# loading data that was stored in the file previously
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previous_data = json.load(input_file)
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# creating and updating a new grid using it's own grid field
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new_grid = previous_data
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new_grid.update(self.grid)
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# opening the file for writing
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with open(file_path, "w") as output_file:
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# saving the newly created grid
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json.dump(new_grid, output_file, indent=2, sort_keys=True)
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# STATIC "PUBLIC" FUNCTIONS
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# creates a Mine (Standard or Time or Chained) instance from mine dict data
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# doesn't link chained mines, since it has no actual access to a grid
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def create_a_mine(mine_dict, position):
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# initializing a mine with no value
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mine = None
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# if mine doesn't exist - returning None
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if mine_dict is None:
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return mine
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# formatting position to right format - in case it's not
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position = format_position_to_tuple(position)
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# if mine's type is "standard" - creating standard mine
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if mine_dict["mine_type"] == "standard":
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mine = sm.StandardMine(position)
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# if mine's type is "time" - creating time mine
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elif mine_dict["mine_type"] == "time":
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timer_value = mine_dict["timer"]
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mine = tm.TimeMine(position, timer_value)
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# if mine's type is "chained" - creating chained mine (no successors assigned yet)
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elif mine_dict["mine_type"] == "chained":
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mine = cm.ChainedMine(position)
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return mine
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# creates a Tile instance with a mine (if a mine exists) from tile dict data
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def create_a_tile(tile_dict, position):
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# formatting position to right format - in case it's not
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position = format_position_to_tuple(position)
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# getting tile's parameters
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color = tile_dict["color"]
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mine = create_a_mine(position, tile_dict["mine"])
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# creating and returning a tile with the parameters set above
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return tl.Tile(position, color, mine)
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# returns a list of tuples containing chained mine's position and it's predecessors position
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# data is in format [(chained_mine_position, its_predecessors_position), ...]
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def get_chained_mine_and_its_predecessor_pairs(minefield_dictionary):
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predecessors = list()
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# iterate for each key in the grid field
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for key in minefield_dictionary.keys():
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# if a chained mine with predecessor exists - adding it's and it's predecessors positions as a tuple to a list
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if key != "agents_initial_state" and minefield_dictionary[key]["mine"] is not None\
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and minefield_dictionary[key]["mine"]["mine_type"] == "chained"\
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and minefield_dictionary[key]["mine"]["predecessor"] is not None:
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# getting the chained mines and it's predecessors positions
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this_mines_position = tuple(int(i) for i in key.split(','))
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its_predecessors_position = tuple(int(i) for i in minefield_dictionary[key]["mine"]["predecessor"].split(','))
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# adding the positions to the list as a tuple
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predecessors.append((this_mines_position, its_predecessors_position))
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return predecessors
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# changes position from str or tuple format to str format
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def format_position_to_str(position):
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# if mine's position is in "row,column" format - that means position parameter is already in good format
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if isinstance(position, str):
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pass
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# if mine's position is in (row:int, column:int) - creating string from tuple
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elif isinstance(position, tuple) and list(map(type, position)) == [int, int]:
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row, column = position
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return str(row) + ',' + str(column)
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# if mine's position is not in any of 2 formats above - returning None - unsupported format
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else:
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return None
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return position
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# changes position from str or tuple format to tuple format
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def format_position_to_tuple(position):
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# if mine's position is in "row,column" format - getting parameters from string
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if isinstance(position, str):
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position = tuple(int(i) for i in position.split(','))
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# if mine's position is in (row:int, column:int) - that means position parameter is already in good format
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elif isinstance(position, tuple) and list(map(type, position)) == [int, int]:
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pass
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# if mine's position is not in any of 2 formats above - returning None - unsupported format
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else:
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return None
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return position
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# AUXILIARY "PRIVATE" FUNCTIONS
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# auxiliary function that returns random attribute values based on their type
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def _get_random_attribute_values(attr_type, grid_dimensions):
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num_of_rows, num_of_columns = grid_dimensions
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if attr_type == int:
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# temporary solution
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return random.randint(num_of_rows + num_of_columns, (2 * num_of_rows + num_of_columns))
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else:
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return None
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