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72 changed files with 1131 additions and 778 deletions

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@ -13,7 +13,7 @@ There are currently no releases of the game. To install the current version on G
## Installing From Source
Requirements:
- Python 3.7
- Python 3.10 or greater
- Pip
- Git

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@ -4,7 +4,7 @@ import pocket_friends
script_dir = os.path.dirname(os.path.abspath(__file__))
PyInstaller.__main__.preprocess([
PyInstaller.__main__.run([
'{0}/pocket_friends/__main__.py'.format(script_dir),
'--clean',
'--noconsole',

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@ -1,4 +1 @@
"""Pocket Friends is a game where you raise your own little pocket friend! These pocket friends, called bloops,
are great little companions to have! You can feed them, play with them, and watch them grow up!"""
__version__ = 'dev_0.1.0'
__version__ = 'dev_0.0.3'

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@ -2,25 +2,28 @@
Launch script for Pocket Friends.
"""
import os
from pathlib import Path
import pygame
import sys
from pathlib import Path
import pocket_friends.game as game
from pocket_friends.game_files.game import main as game_main
from pocket_friends.development.dev_menu import main as dev_menu_main
if __name__ == '__main__':
enable_dev = False
resolution = 240
# enable dev mode if --dev argument is passed
if len(sys.argv) > 0:
for arg in sys.argv:
if arg == '--delete-save':
for args in sys.argv:
if args == '--dev':
enable_dev = True
if args == '--delete-save':
save_dir = os.path.join(Path.home(), '.pocket_friends')
os.remove(save_dir + '/save.json')
if '--res=' in arg:
resolution = int(arg.split('=')[1])
game.start_game(resolution)
if not enable_dev:
game_main()
else:
dev_menu_main()
pygame.quit()
sys.exit()

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@ -0,0 +1,56 @@
"""
Module used to fake the RPi.GPIO module so that
the hardware can be run without the actual hardware.
"""
# Constants used by RPi.GPIO
BOARD = 0
IN = 0
FALLING = 0
def setmode(new_mode):
"""
Fake setmode function.
:param new_mode:
"""
pass
def setup(channel, mode, initial=None, pull_up_down=None):
"""
Fake setup function.
:param channel:
:param mode:
:param initial:
:param pull_up_down:
"""
pass
def add_event_detect(channel, edge_type, callback=None, bouncetime=0):
"""
Fake function to add a non-existent event detect.
:param channel:
:param edge_type:
:param callback:
:param bouncetime:
"""
pass
def event_detected(channel):
"""
Fake function to detect an event. Always returns false.
:param channel:
:return:
"""
return False
def cleanup(channel=None):
"""
Fake cleanup function.
:param channel:
"""
pass

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@ -2,7 +2,7 @@
Module to test the GPIO input on the Raspberry Pi.
"""
from collections import deque
from pocket_friends.game_files.io.gpio_handler import Constants, GPIOHandler
from ..hardware.gpio_handler import Constants, GPIOHandler
def button_test():

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@ -8,13 +8,13 @@ import pygame
import time
from .button_test import button_test
from .menus import Menu
from pocket_friends.game_files.io.gpio_handler import GPIOHandler, Constants
from ..hardware.gpio_handler import GPIOHandler, Constants
try:
importlib.util.find_spec('RPi.GPIO')
import RPi.GPIO as GPIO
except ImportError:
import pocket_friends.game_files.io.fake_gpio as GPIO
import pocket_friends.development.FakeGPIO as GPIO
# Global variable to keep track of the current menu.
menu = 'main'

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@ -63,7 +63,7 @@ class Menu:
:param kwargs: keyword arguments to be passed to the function
"""
try:
return self._options[self._selection].preprocess(*args, **kwargs)
return self._options[self._selection].run(*args, **kwargs)
except IndexError as ex:
raise Exception('menu has no options, cannot run a non-existent option') from ex

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@ -1 +0,0 @@
"""Submodule for use in the game. Helps with the drawing of various objects such as sprites and text boxes."""

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@ -1,277 +0,0 @@
import pygame
import json
class SpriteSheet:
"""
Class to be used by sprites in order to give them a texture and an animation.
Attributes:
images (list) List of all the sprites in the animation separated from the sprite sheet.
"""
def __init__(self, sprite_sheet, texture_json):
"""
Creates a sprite sheet given a sprite image and its corresponding JSON file.
Args:
sprite_sheet (str): The path of the sprite sheet image component.
texture_json (str): The path of the sprite sheet JSON component, contains the number of frames in the
sprite sheet, and the width and height of an individual sprite from the sprite sheet.
"""
# Load in whole sprite sheet as one image.
sprite_sheet = pygame.image.load(sprite_sheet).convert_alpha()
self.images = []
# Get the sprite sheet json file.
with open(texture_json, 'r') as json_file:
img_attrib = json.load(json_file)
json_file.close()
# Count for how many images have been added in the image list
image_count = 0
# Get the sprite size as a tuple
sprite_size = img_attrib['width'], img_attrib['height']
# Iterate through every image location on the sprite sheet given the sprite size
for i in range(sprite_sheet.get_size()[1] // sprite_size[1]):
i *= sprite_size[1]
for j in range(sprite_sheet.get_size()[0] // sprite_size[0]):
j *= sprite_size[0]
# Create a new transparent surface
sprite = pygame.Surface(sprite_size, pygame.SRCALPHA)
# Blit the sprite onto the image
sprite.blit(sprite_sheet, (0, 0), (j, i, sprite_size[0], sprite_size[1]))
# Add the image to the list of images
self.images.append(sprite)
image_count += 1
# Break the loop if the specified number of frames has been reached.
if image_count >= img_attrib['frames']:
break
if image_count >= img_attrib['frames']:
break
class SelectionEgg(pygame.sprite.Sprite):
"""
Sprite to render the egg on the egg selection screen.
Attributes:
egg_color (str): The color of the egg (also its name).
description (str): The description of the egg to be displayed when selected.
contentedness (int): How likely the egg is to stay happy, ranges from 0-5.
metabolism (int): How quickly the egg will get hungry, ranges from 0-5.
rect (pygame.Rect): Pygame rectangle used to position the egg on screen.
"""
def __init__(self, egg_color, resources_dir):
"""
Creates a SelectionEgg object given an egg color and a resource location.
Args:
egg_color (str): The color egg that should be rendered.
resources_dir (str): The path of the resources directory.
"""
pygame.sprite.Sprite.__init__(self)
self.egg_color = egg_color
# Loads the JSON file of the egg to read in data.
with open(resources_dir + '/data/bloop_info/{0}.json'.format(egg_color), 'r') as save_file:
json_file = json.load(save_file)
save_file.close()
# Gets the description off the egg from the JSON file.
self.description = json_file.get('description')
self.contentedness = json_file.get('contentedness')
self.metabolism = json_file.get('metabolism')
# Load the egg from the given color and get the bounding rectangle for the image.
sprite_sheet = SpriteSheet(resources_dir + '/images/bloops/{0}/egg.png'.format(self.egg_color),
resources_dir + '/images/bloops/{0}/egg.json'.format(self.egg_color))
self._images = sprite_sheet.images
# Get the rectangle from the first image in the list
self.rect = self._images[0].get_rect()
self._index = 0
self.image = self._images[self._index]
def update(self):
"""
Update the sprite to the next animation frame.
"""
# Animate the sprite
self._index = (self._index + 1) % len(self._images)
self.image = self._images[self._index]
class InfoText:
"""
Class for drawing large amounts of text on the screen at a time
"""
def __init__(self, resources_dir, game_res, text='Test text.'):
"""
Creates an InfoText object to be used on a surface.
Args:
resources_dir (str): The full path of the game's resources directory
game_res (int): The internal resolution of the game. Used for correct scaling.
text (:obj:`str`, optional): The given text to render. Defaults to "Test text."'
"""
self.font = pygame.font.Font(resources_dir + '/fonts/5Pts5.ttf', 10)
self.text = [] # Text broken up into a list according to how it will fit on screen.
self.max_lines = 6 # Max number of lines to be shown on screen at a time.
self.offset = 0
self.game_res = game_res
# Arrow icons to indicate scrolling
self.up_arrow = pygame.image.load(resources_dir + '/images/gui/up_arrow.png').convert_alpha()
self.down_arrow = pygame.image.load(resources_dir + '/images/gui/down_arrow.png').convert_alpha()
raw_text = text # Copy the text to a different variable to be cut up.
margins = 4.5
max_line_width = self.game_res - (margins * 2) # The maximum pixel width that drawn text can be.
cut_chars = '.,! ' # Characters that will be considered "cuts" aka when a line break can occur.
# Prevents freezing if the end of the string does not end in a cut character
# Will fix eventually more elegantly
if raw_text[-1:] not in cut_chars:
raw_text += ' '
# Calculating line breaks.
while len(raw_text) > 0:
index = 0
test_text = '' # Chunk of text to pseudo-render and test the width of.
# Loops until the testing text has reached the size limit.
while True:
# Break if the current index is larger than the remaining text.
if index + 1 > len(raw_text):
index -= 1
break
# Add one character to the testing text from the raw text.
test_text += raw_text[index]
# Get the width of the pseudo-rendered text.
text_width = self.font.size(test_text)[0]
# Break if the text is larger than the defined max width.
if text_width > max_line_width:
break
index += 1
pass
# Gets the chunk of text to be added to the list.
text_chunk = raw_text[0:index + 1]
# Determines if the chunk of text has any break characters.
has_breaks = any(cut_chars in text_chunk for cut_chars in cut_chars)
# If the text has break characters, start with the last character and go backwards until
# one has been found, decreasing the index each time.
if has_breaks:
while raw_text[index] not in cut_chars:
index -= 1
text_chunk = raw_text[0:index + 1]
# If there are no break characters in the chunk, simply decrease the index by one and insert
# a dash at the end of the line to indicate the word continues.
else:
index -= 1
text_chunk = raw_text[0:index + 1]
text_chunk += '-'
# Append the text chunk to the list of text to draw.
self.text.append(text_chunk)
# Cut the text to repeat the process with the new cut string.
raw_text = raw_text[index + 1:]
def draw(self, surface):
"""
Draw the text on a given surface.
Args:
surface (:obj:`pygame.Surface`): The surface to draw the text on
"""
# Constants to help draw the text
line_separation = 7
left_margin = 3
top_margin = 25
bottom_margin = 10
# Draw the lines on the screen
for i in range(min(len(self.text), self.max_lines)):
text = self.font.render(self.text[i + self.offset], False, (64, 64, 64))
surface.blit(text, (left_margin, top_margin + (i * line_separation)))
# Draw the arrows if there is more text than is on screen.
if self.offset != 0:
surface.blit(self.up_arrow, ((self.game_res / 2) - (self.up_arrow.get_rect().width / 2), top_margin - 3))
if len(self.text) - (self.offset + 1) >= self.max_lines:
surface.blit(self.down_arrow,
((self.game_res / 2) - (self.down_arrow.get_rect().width / 2), self.game_res - bottom_margin))
def scroll_down(self):
"""
Scrolls the text on the screen down.
"""
# Ensures that the offset cannot be too big as to try to render non-existent lines.
if len(self.text) - (self.offset + 1) >= self.max_lines:
self.offset += 1
def scroll_up(self):
"""
Scrolls the text on the screen up.
"""
if self.offset > 0: # Ensures a non-zero offset is not possible.
self.offset -= 1
class EggInfo:
"""
Class to draw the contentedness and metabolism value off the egg on the info screen.
"""
def __init__(self, resources_dir, contentedness, metabolism, location):
self.contentedness = contentedness
self.metabolism = metabolism
self.x = location[0]
self.y = location[1]
# Create a new surface to blit onto the other surface
self.surface = pygame.Surface((44, 15), pygame.SRCALPHA)
# Blit the two indicator icons on screen
smiley = pygame.image.load(resources_dir + '/images/gui/smiley.png').convert_alpha()
self.surface.blit(smiley, (0, 0))
apple = pygame.image.load(resources_dir + '/images/gui/apple.png').convert_alpha()
self.surface.blit(apple, (1, 9))
# Draw 5 stars. If the value of the contentedness is less than the current star, make it a blank star.
for i in range(5):
if i < self.contentedness:
star = pygame.image.load(resources_dir + '/images/gui/star.png').convert_alpha()
else:
star = pygame.image.load(resources_dir + '/images/gui/blank_star.png').convert_alpha()
self.surface.blit(star, (11 + (i * 6), 1))
# Draw 5 stars. If the value of the metabolism is less than the current star, make it a blank star.
for i in range(5):
if i < self.metabolism:
star = pygame.image.load(resources_dir + '/images/gui/star.png').convert_alpha()
else:
star = pygame.image.load(resources_dir + '/images/gui/blank_star.png').convert_alpha()
self.surface.blit(star, (11 + (i * 6), 10))
def draw(self, surface):
"""
Draw the info icons on a given surface.
Args:
surface (:obj:`pygame.Surface`): The surface to draw the text on
"""
# Blit the info onto the given surface.
surface.blit(self.surface, (self.x, self.y))

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@ -1,46 +0,0 @@
"""Module to aid in the drawing of surfaces to make switching from one screen to another easier."""
import pygame
from ..io.input_handler import InputHandler
class GameSurface(pygame.Surface):
"""
Class to be used as the backbone of all game surfaces.
Attributes:
running (bool): Boolean to tell whether the surface is running or not.
next_surface (:obj:`str`): What the next surface should be after halting.
resource_dir (:obj:`str`): The path of the game's main resource directory.
game_fps (int): How many frames per second the game will run at.
additional_args (dict): Additional arguments to send to the next surface after halting.
"""
def __init__(self, game_res, resources_dir, game_fps):
"""
Create a GameSurface object.
Args:
game_res (int): The internal resolution of the surface.
resources_dir (:obj:`str`): The path of the game's main resource directory.
game_fps: (int): How many frames per second the game will run at.
"""
super().__init__(game_res, pygame.SRCALPHA)
self.running = True
self.next_surface = None
self.resource_dir = resources_dir
self._clock = pygame.time.Clock()
self.game_fps = game_fps
self._input_handler = InputHandler(self._clock)
self.additional_args = {}
self._bg = pygame.image.load(self.resource_dir + '/images/bg.png').convert_alpha()
self.sprites = pygame.sprite.Group()
def preprocess(self):
"""
Advance the surface by one frame and draw the background.
"""
self._clock.tick(self.game_fps)
self.blit(self._bg, (0, 0))
self.sprites.update()
self.sprites.draw(self)
self._input_handler.update()

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@ -1,74 +0,0 @@
import pygame
import os
import pocket_friends
import importlib
valid_surfaces = [
'title',
'egg_select',
'selection_info',
'error_screen'
]
# Add all the surface modules to a dictionary for easy switching
surface_modules = {}
for module in valid_surfaces:
surface_modules[module] = importlib.import_module('pocket_friends.surfaces.{0}'.format(module))
starting_surface = 'title'
# FPS for the game to run at.
game_fps = 16
# The internal resolution of the game
game_res = 80
# Get the path for where all game resources are (images, fonts, sounds, etc.)
script_dir = os.path.dirname(os.path.abspath(__file__))
resources_dir = script_dir + '/resources'
# Makes Pygame draw on the display of the RPi.
os.environ['SDL_FBDEV'] = '/dev/fb1'
def start_game(resolution=240):
"""
Starts the game.
Args:
resolution (int, optional): Resolution to display the game at. Defaults to 240.
"""
pygame.init()
# Hide the cursor for the Pi display.
pygame.mouse.set_visible(False)
window = pygame.display.set_mode((resolution, resolution))
surface = surface_modules.get(starting_surface).Surface((game_res, game_res), resources_dir, game_fps)
# Only really useful for PCs. Does nothing on the Raspberry Pi.
pygame.display.set_caption('Pocket Friends {0}'.format(pocket_friends.__version__))
# Add an icon to the pygame window.
icon = pygame.image.load(resources_dir + '/icon/icon.png').convert_alpha()
pygame.display.set_icon(icon)
running = True
while running:
surface.update()
# The game is only 80x80px, however it is upscaled to whatever the running resolution is.
frame = pygame.transform.scale(surface, (resolution, resolution))
window.blit(frame, frame.get_rect())
if not surface.running:
next_surface = surface.next_surface
additional_args = surface.additional_args
if next_surface not in valid_surfaces:
next_surface = 'error_screen'
surface = surface_modules.get(next_surface).Surface((game_res, game_res), resources_dir,
game_fps, **additional_args)
pygame.display.flip()
pygame.quit()

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@ -0,0 +1,984 @@
"""
Main file for the entire game. Controls everything except for GPIO input.
"""
from collections import deque
import importlib.util
import json
import os
from pathlib import Path
import pocket_friends
import pygame
from pygame.locals import *
from ..hardware.gpio_handler import Constants, GPIOHandler
# FPS for the entire game to run at.
game_fps = 16
# The resolution the game is rendered at.
game_res = 80
# Gets the directory of the script for importing and the save directory
script_dir = os.path.dirname(os.path.abspath(__file__))
save_dir = os.path.join(Path.home(), '.pocket_friends')
# Tries to make the save directory. Does nothing if it already exists.
try:
os.mkdir(save_dir)
except FileExistsError:
pass
class SpriteSheet:
"""
Imports a sprite sheet as separate pygame images given an image file and a json file.
"""
def __init__(self, sprite_sheet, texture_json):
# Load in whole sprite sheet as one image.
self.sprite_sheet = pygame.image.load(sprite_sheet).convert_alpha()
self.images = []
# Get the sprite sheet json file.
with open(texture_json, 'r') as json_file:
self.img_attrib = json.load(json_file)
json_file.close()
# Count for how many images have been added in the image list
image_count = 0
# Get the sprite size as a tuple
sprite_size = self.img_attrib['width'], self.img_attrib['height']
# Iterate through every image location on the sprite sheet given the sprite size
for i in range(self.sprite_sheet.get_size()[1] // sprite_size[1]):
i *= sprite_size[1]
for j in range(self.sprite_sheet.get_size()[0] // sprite_size[0]):
j *= sprite_size[0]
# Create a new transparent surface
sprite = pygame.Surface(sprite_size, SRCALPHA)
# Blit the sprite onto the image
sprite.blit(self.sprite_sheet, (0, 0), (j, i, sprite_size[0], sprite_size[1]))
# Add the image to the list of images
self.images.append(sprite)
image_count += 1
# Break the loop if the specified number of frames has been reached.
if image_count >= self.img_attrib['frames']:
break
if image_count >= self.img_attrib['frames']:
break
class DataHandler:
"""
Class that handles the hardware attributes and save files.
"""
def __init__(self):
# Attributes that are saved to a file to recover upon startup.
self.attributes = {
'version': pocket_friends.__version__,
'time_elapsed': 0,
'bloop': '',
'age': 0,
'health': 0,
'hunger': 0,
'happiness': 0,
'care_counter': 0,
'missed_care': 0,
'adult': 0,
'evolution_stage': '',
}
# Frame counter
self.frames_passed = 0
def write_save(self):
"""
Writes attributes of class to "save.json" file.
"""
with open(save_dir + '/save.json', 'w') as save_file:
json.dump(self.attributes, save_file)
save_file.close()
def read_save(self):
"""
Reads from "save.json" and inserts into attributes dictionary. Creates file if it does not exist.
"""
# Open up the save file and read it into self.attributes.
try:
with open(save_dir + '/save.json', 'r') as save_file:
self.attributes = json.load(save_file)
save_file.close()
# If there is no save file, write one with the defaults.
except FileNotFoundError:
self.write_save()
def update(self):
"""
Run the game logic.
"""
self.frames_passed += 1
# Run logic of the game every second.
if self.frames_passed >= game_fps:
# Add one to the age of the bloop.
self.attributes['age'] += 1
# Save the data when the age of the bloop is a multiple of 10.
if self.attributes['age'] % 10 == 0:
self.write_save()
# Reset frame counter
self.frames_passed = 0
class PlaygroundFriend(pygame.sprite.Sprite):
"""
Class for the sprite of the creature on the main playground.
"""
def __init__(self, data_handler):
pygame.sprite.Sprite.__init__(self)
# All attributes of the bloops
self.bloop = data_handler.attributes['bloop']
self.adult = data_handler.attributes['adult']
self.evolution_stage = data_handler.attributes['evolution_stage']
self.direction = 0
if self.evolution_stage == 'adult':
image = self.evolution_stage + self.adult
else:
image = self.evolution_stage
# Draw the correct bloop depending on the stage
sprite_sheet = SpriteSheet(script_dir + '/resources/images/bloops/{0}/{1}.png'.format(self.bloop, image),
script_dir + '/resources/images/bloops/{0}/{1}.json'.format(self.bloop, image))
# Load the images from the sprite sheet
self.images = sprite_sheet.images
# Put the egg in the middle of the screen.
self.rect = self.images[0].get_rect()
self.rect.x = (game_res / 2) - (self.rect.width / 2)
self.rect.y = (game_res / 2) - (self.rect.height / 2)
# Start animation at the beginning of the sprite sheet.
self.index = 0
self.image = self.images[self.index]
self.movement_frames = game_fps / 2 # How many frames pass before the bloop moves
self.current_frame = 0
def pet(self):
"""
Pet the bloop!
"""
pass
def update(self):
"""
Takes the images loaded and animates it, spacing it out equally for the framerate.
"""
margins = 9 # Margins for how far the bloop can move from the left and the right of the screen
movement_amount = 2 # Pixels that the bloop moves in one movement
self.current_frame += 1
# Check to see if the number of movement frames has passed
if self.current_frame >= self.movement_frames:
self.current_frame = 0
# Move only if the bloop is not in the egg stage
if self.evolution_stage != 'egg':
# Change direction if the bloop has reached either edge of the screen
if self.rect.x < margins:
self.direction = 1
elif self.rect.x > game_res - margins - self.rect.width:
self.direction = 0
# Move according to the direction.
if self.direction == 0:
self.rect.x -= movement_amount
else:
self.rect.x += movement_amount
# Animate the bloop
self.index = (self.index + 1) % len(self.images)
self.image = self.images[self.index]
class SelectionEgg(pygame.sprite.Sprite):
"""
Class for the eggs on the egg selection screen.
"""
def __init__(self, egg_color):
pygame.sprite.Sprite.__init__(self)
self.egg_color = egg_color
# Loads the JSON file of the egg to read in data.
with open(script_dir + '/resources/data/bloop_info/{0}.json'.format(egg_color), 'r') as save_file:
json_file = json.load(save_file)
save_file.close()
# Gets the description off the egg from the JSON file.
self.description = json_file.get('description')
self.contentedness = json_file.get('contentedness')
self.metabolism = json_file.get('metabolism')
# Load the egg from the given color and get the bounding rectangle for the image.
sprite_sheet = SpriteSheet(script_dir + '/resources/images/bloops/{0}/egg.png'.format(self.egg_color),
script_dir + '/resources/images/bloops/{0}/egg.json'.format(self.egg_color))
self.images = sprite_sheet.images
# Get the rectangle from the first image in the list
self.rect = self.images[0].get_rect()
self.index = 0
self.image = self.images[self.index]
def update(self):
"""
Updates the sprite object.
"""
# Animate the sprite
self.index = (self.index + 1) % len(self.images)
self.image = self.images[self.index]
class EggInfo:
"""
Class to draw the contentedness and metabolism value off the egg on the info screen.
"""
def __init__(self, contentedness, metabolism, location):
self.contentedness = contentedness
self.metabolism = metabolism
self.x = location[0]
self.y = location[1]
# Create a new surface to blit onto the other surface
self.surface = pygame.Surface((44, 15), SRCALPHA)
# Blit the two indicator icons on screen
smiley = pygame.image.load(script_dir + '/resources/images/gui/smiley.png').convert_alpha()
self.surface.blit(smiley, (0, 0))
apple = pygame.image.load(script_dir + '/resources/images/gui/apple.png').convert_alpha()
self.surface.blit(apple, (1, 9))
# Draw 5 stars. If the value of the contentedness is less than the current star, make it a blank star.
for i in range(5):
if i < self.contentedness:
star = pygame.image.load(script_dir + '/resources/images/gui/star.png').convert_alpha()
else:
star = pygame.image.load(script_dir + '/resources/images/gui/blank_star.png').convert_alpha()
self.surface.blit(star, (11 + (i * 6), 1))
# Draw 5 stars. If the value of the metabolism is less than the current star, make it a blank star.
for i in range(5):
if i < self.metabolism:
star = pygame.image.load(script_dir + '/resources/images/gui/star.png').convert_alpha()
else:
star = pygame.image.load(script_dir + '/resources/images/gui/blank_star.png').convert_alpha()
self.surface.blit(star, (11 + (i * 6), 10))
def draw(self, surface):
"""
Draw the info icons on a given surface.
:param surface: the surface to draw the icons on.
"""
# Blit the info onto the given surface.
surface.blit(self.surface, (self.x, self.y))
class InfoText:
"""
Class for drawing large amounts of text on the screen at a time
"""
def __init__(self, font, text='Lorem ipsum dolor sit amet, consectetur adipiscing elit. Nam commodo tempor '
'aliquet. Suspendisse placerat accumsan neque, nec volutpat nunc porta ut.'):
self.font = font
self.text = [] # Text broken up into a list according to how it will fit on screen.
self.max_lines = 6 # Max number of lines to be shown on screen at a time.
self.offset = 0
# Arrow icons to indicate scrolling
self.up_arrow = pygame.image.load(script_dir + '/resources/images/gui/up_arrow.png').convert_alpha()
self.down_arrow = pygame.image.load(script_dir + '/resources/images/gui/down_arrow.png').convert_alpha()
raw_text = text # Copy the text to a different variable to be cut up.
margins = 4.5
max_line_width = game_res - (margins * 2) # The maximum pixel width that drawn text can be.
cut_chars = '.,! ' # Characters that will be considered "cuts" aka when a line break can occur.
# Prevents freezing if the end of the string does not end in a cut character
# Will fix eventually more elegantly
if raw_text[-1:] not in cut_chars:
raw_text += ' '
# Calculating line breaks.
while len(raw_text) > 0:
index = 0
test_text = '' # Chunk of text to pseudo-render and test the width of.
# Loops until the testing text has reached the size limit.
while True:
# Break if the current index is larger than the remaining text.
if index + 1 > len(raw_text):
index -= 1
break
# Add one character to the testing text from the raw text.
test_text += raw_text[index]
# Get the width of the pseudo-rendered text.
text_width = font.size(test_text)[0]
# Break if the text is larger than the defined max width.
if text_width > max_line_width:
break
index += 1
pass
# Gets the chunk of text to be added to the list.
text_chunk = raw_text[0:index + 1]
# Determines if the chunk of text has any break characters.
has_breaks = any(cut_chars in text_chunk for cut_chars in cut_chars)
# If the text has break characters, start with the last character and go backwards until
# one has been found, decreasing the index each time.
if has_breaks:
while raw_text[index] not in cut_chars:
index -= 1
text_chunk = raw_text[0:index + 1]
# If there are no break characters in the chunk, simply decrease the index by one and insert
# a dash at the end of the line to indicate the word continues.
else:
index -= 1
text_chunk = raw_text[0:index + 1]
text_chunk += '-'
# Append the text chunk to the list of text to draw.
self.text.append(text_chunk)
# Cut the text to repeat the process with the new cut string.
raw_text = raw_text[index + 1:]
def draw(self, surface):
"""
Draws the text on a given surface.
:param surface: The surface for the text to be drawn on.
"""
# Constants to help draw the text
line_separation = 7
left_margin = 3
top_margin = 25
bottom_margin = 10
# Draw the lines on the screen
for i in range(min(len(self.text), self.max_lines)):
text = self.font.render(self.text[i + self.offset], False, (64, 64, 64))
surface.blit(text, (left_margin, top_margin + (i * line_separation)))
# Draw the arrows if there is more text than is on screen.
if self.offset != 0:
surface.blit(self.up_arrow, ((game_res / 2) - (self.up_arrow.get_rect().width / 2), top_margin - 3))
if len(self.text) - (self.offset + 1) >= self.max_lines:
surface.blit(self.down_arrow,
((game_res / 2) - (self.down_arrow.get_rect().width / 2), game_res - bottom_margin))
def scroll_down(self):
"""
Scrolls the text on the screen down.
"""
# Ensures that the offset cannot be too big as to try to render non-existent lines.
if len(self.text) - (self.offset + 1) >= self.max_lines:
self.offset += 1
def scroll_up(self):
"""
Scrolls the text on the screen up.
"""
if self.offset > 0: # Ensures a non-zero offset is not possible.
self.offset -= 1
class MenuIcon(pygame.sprite.Sprite):
"""
Sprite for an icon on the main popup menu.
"""
def __init__(self, icon):
pygame.sprite.Sprite.__init__(self)
self.icon = icon
# Load the sprite sheet from the icon name
sprite_sheet = SpriteSheet(script_dir + '/resources/images/gui/popup_menu/{0}.png'.format(self.icon),
script_dir + '/resources/images/gui/popup_menu/{0}.json'.format(self.icon))
self.images = sprite_sheet.images
# Get the rectangle from the first image in the list
self.rect = self.images[0].get_rect()
self.image = self.images[0]
def select(self):
"""
Change the icon sprite to the selected icon.
"""
self.image = self.images[1]
def deselect(self):
"""
Change the icon sprite to the not selected icon.
"""
self.image = self.images[0]
class PopupMenu:
"""
Class to create a popup menu that can be hidden and shown at will
"""
def __init__(self, position):
# Background frame of the popup menu
self.frame = pygame.image.load(script_dir + '/resources/images/gui/popup_menu/frame.png').convert_alpha()
self.draw_menu = False # Whether or not to draw the popup menu
self.menu_sprites = pygame.sprite.Group() # Sprite group for the icons
self.selected = 0 # The currently selected icon
# The names of the icons to be drawn
icon_names = ['apple', 'dumbbell', 'stats', 'controller', 'bed']
self.icons = []
# Create an icon sprite for each name in the list and add it to the icon list
for i in icon_names:
self.icons.append(MenuIcon(i))
# Add each sprite in the icon list to the sprite group
for i in range(len(self.icons)):
icon = self.icons[i]
if i == self.selected: # Make the default selected icon glow
icon.select()
# Calculate the position of the icon on screen
icon.rect.x = 10 + (i * 15) - (icon.image.get_width() / 2)
icon.rect.y = position[1] + self.frame.get_height() / 2 - icon.image.get_height() / 2
# Add the icon to the sprite group.
self.menu_sprites.add(icon)
def toggle(self):
"""
Toggles the menu on or off.
"""
self.draw_menu = not self.draw_menu
def next(self):
"""
Changes the selection to the next icon (to the right.)
"""
if self.draw_menu: # Only change if the menu is on screen
self.icons[self.selected].deselect() # Deselect the current icon
self.selected += 1 # Change selection to the next icon
if self.selected >= len(self.icons): # Wrap around if new value is invalid
self.selected = 0
self.icons[self.selected].select() # Select the newly selected icon
def prev(self):
"""
Changes the selection to the previous icon (to the left.)
"""
if self.draw_menu: # Only change if the menu is on screen
self.icons[self.selected].deselect() # Deselect the current icon
self.selected -= 1 # Change selection to the previous icon
if self.selected < 0: # Wrap around if new value is invalid
self.selected = len(self.icons) - 1
self.icons[self.selected].select() # Select the newly selected icon
def draw(self, surface):
"""
Draw the menu onto a given surface
:param surface: the surface to draw the menu on.
"""
# Draw the menu only if it is toggled on.
if self.draw_menu:
surface.blit(self.frame, (3, 3))
self.menu_sprites.draw(surface)
# Makes Pygame draw on the display of the RPi.
os.environ["SDL_FBDEV"] = "/dev/fb1"
# Useful for debugging on the PC. Imports a fake RPi.GPIO library if one is not found (which it can't
# be on a PC, RPi.GPIO cannot be installed outside of a Raspberry Pi.
try:
importlib.util.find_spec('RPi.GPIO')
import RPi.GPIO as GPIO
on_hardware = True
except ImportError:
import pocket_friends.development.FakeGPIO as GPIO
on_hardware = False
def game():
"""
Starts the game.
"""
pygame.init()
# Hide the cursor for the Pi display.
pygame.mouse.set_visible(False)
# The game is normally rendered at 80 pixels and upscaled from there. If changing displays, change the
# screen_size to reflect what the resolution of the new display is.
screen_size = 240
window = pygame.display.set_mode((screen_size, screen_size))
surface = pygame.Surface((game_res, game_res))
# Only really useful for PCs. Does nothing on the Raspberry Pi.
pygame.display.set_caption('Pocket Friends {0}'.format(pocket_friends.__version__))
# Add an icon to the pygame window.
icon = pygame.image.load(script_dir + '/resources/images/icon/icon.png').convert_alpha()
pygame.display.set_icon(icon)
clock = pygame.time.Clock()
# Font used for small text in the game. Bigger text is usually image files.
small_font = pygame.font.Font(script_dir + '/resources/fonts/5Pts5.ttf', 10)
# Default game state when the game first starts.
game_state = 'title'
running = True
data_handler = DataHandler()
# A group of all the sprites on screen. Used to update all sprites at onc
all_sprites = pygame.sprite.Group()
# Start the GPIO handler to take in buttons from the RPi HAT.
GPIOHandler.setup()
# Dev code used to exit the game. Default Down, Down, Up, Up, Down, Down, Up, Up, A, A, B
dev_code = deque()
for button in [Constants.buttons.get('j_d'), Constants.buttons.get('j_d'), Constants.buttons.get('j_u'),
Constants.buttons.get('j_u'), Constants.buttons.get('j_d'), Constants.buttons.get('j_d'),
Constants.buttons.get('j_u'), Constants.buttons.get('j_u'), Constants.buttons.get('a'),
Constants.buttons.get('a'), Constants.buttons.get('b')]:
dev_code.append(button)
# Log of the inputs.
input_log = deque()
# Time since last input. Used to help regulate double presses of buttons.
last_input_tick = 0
def draw():
"""
Draws the main pygame display.
"""
# Draws all the sprites on screen and scales the screen to the correct size from the rendered size.
all_sprites.update()
all_sprites.draw(surface)
frame = pygame.transform.scale(surface, (screen_size, screen_size))
window.blit(frame, frame.get_rect())
# Update the entire display.
pygame.display.flip()
def draw_bg():
"""
Draws the main game background image onto a given surface.
"""
bg_image = pygame.image.load(script_dir + '/resources/images/bg.png').convert()
surface.blit(bg_image, (0, 0))
def log_button(pressed_button):
"""
Logs the button presses to register the dev code.
:param pressed_button: The button code to be logged
"""
input_log.append(pressed_button)
if len(input_log) > len(dev_code):
input_log.popleft()
def create_event(pressed_button):
"""
Creates a pygame event with a given keyboard code
:param pressed_button:
"""
nonlocal last_input_tick
# Register a button click so long as the last button click happened no less than two frames ago
if pygame.time.get_ticks() - last_input_tick > clock.get_time() * 2 or not on_hardware:
pygame.event.post(pygame.event.Event(KEYDOWN, {'key': pressed_button}))
pygame.event.post(pygame.event.Event(KEYUP, {'key': pressed_button}))
log_button(pressed_button)
last_input_tick = pygame.time.get_ticks()
def check_dev_code():
"""
Checks if the dev code has been entered. If it has, stop the program.
"""
nonlocal running
if dev_code == input_log:
running = False
def handle_gpio():
"""
Handles getting GPIO button presses and making a pygame event when a press is detected.
"""
for pressed_button in Constants.buttons:
code = Constants.buttons.get(pressed_button)
# Check if a button has been pressed. If it has, create a pygame event for it.
if GPIOHandler.get_press(code):
create_event(code)
def keyboard_handler():
"""
Simulates key presses to GPIO button presses. Also handles quitting the game.
"""
nonlocal running
# Checks if a corresponding keyboard key has been pressed. If it has, emulate a button press.
for keyboard_event in pygame.event.get():
if keyboard_event.type == pygame.QUIT:
running = False
if keyboard_event.type == pygame.KEYDOWN:
if keyboard_event.key == pygame.K_a:
create_event(Constants.buttons.get('a'))
if keyboard_event.key == pygame.K_b:
create_event(Constants.buttons.get('b'))
if keyboard_event.key == pygame.K_PERIOD:
create_event(Constants.buttons.get('j_i'))
if keyboard_event.key == pygame.K_RIGHT:
create_event(Constants.buttons.get('j_r'))
if keyboard_event.key == pygame.K_LEFT:
create_event(Constants.buttons.get('j_l'))
if keyboard_event.key == pygame.K_DOWN:
create_event(Constants.buttons.get('j_d'))
if keyboard_event.key == pygame.K_UP:
create_event(Constants.buttons.get('j_u'))
if keyboard_event.key == pygame.K_ESCAPE:
running = False
def pre_handler():
"""
Runs at the beginning of each loop, handles drawing the background, controlling game speed, and
controlling the GPIO button inputs and keyboard handler
"""
# Regulate the speed of the game.
clock.tick(game_fps)
# Handle all inputs for both debugging and real GPIO button presses.
keyboard_handler()
handle_gpio()
check_dev_code()
# Draw the background.
draw_bg()
while running:
if game_state == 'title':
all_sprites.empty()
pre_handler()
# Draw the title image in the middle of the screen.
title_image = pygame.image.load(script_dir + '/resources/images/title.png').convert_alpha()
surface.blit(title_image, (0, 0))
draw()
# Show the title for 1 second then move on to the initialization phase of the game.
pygame.time.wait(1000)
game_state = 'init'
elif game_state == 'playground':
# Submenu used within the playground.
submenu = 'main'
while running and game_state == 'playground':
all_sprites.empty()
if submenu == 'main':
# Create the bloop and the menu
bloop = PlaygroundFriend(data_handler)
all_sprites.add(bloop)
popup_menu = PopupMenu((3, 3))
while running and game_state == 'playground' and submenu == 'main':
pre_handler()
data_handler.update()
for event in pygame.event.get():
if event.type == pygame.KEYDOWN:
if event.key == Constants.buttons.get('j_r'):
# Move selection to the next item
popup_menu.next()
if event.key == Constants.buttons.get('j_l'):
# Move selection to the previous item
popup_menu.prev()
if event.key == Constants.buttons.get('a'):
# Change submenu to the menu the icon points to
if popup_menu.draw_menu:
submenu = popup_menu.icons[popup_menu.selected].icon
else: # Pet the bloop otherwise
bloop.pet()
if event.key == Constants.buttons.get('b'):
# Toggle the popup menu on or off
popup_menu.toggle()
# Draw the popup menu if toggled on
popup_menu.draw(surface)
draw()
else: # Go to the error state if an invalid state is set.
game_state = None
elif game_state == 'init':
all_sprites.empty()
pre_handler()
draw()
# Read the save file.
data_handler.read_save()
# Determines if it is a new game or not by looking at the evolution stage. If it is -1, the egg has
# not been created yet, and the game sends you to the egg selection screen. If not, the game sends
# you to the playground.
if data_handler.attributes['bloop'] == '':
game_state = 'egg_select'
else:
game_state = 'playground'
elif game_state == 'egg_select':
# Submenu used within the egg selection menu.
submenu = 'main'
selected = 0
selected_color = ""
while running and game_state == 'egg_select':
all_sprites.empty()
if submenu == 'main':
# Creates and holds the egg objects in a list.
eggs = [SelectionEgg('dev_egg'), SelectionEgg('blue'), SelectionEgg('rainbow')]
# How many eggs per row should be displayed.
eggs_per_row = 3
distance_between_eggs = 36 / eggs_per_row
# Count the total rows.
total_rows = -(-len(eggs) // eggs_per_row)
distance_between_rows = 32 / eggs_per_row
# Determine the location of each egg.
for egg in eggs:
current_row = eggs.index(egg) // eggs_per_row
rows_after = total_rows - (current_row + 1)
egg_in_row = eggs.index(egg) % eggs_per_row
eggs_after = min(len(eggs) - (current_row * eggs_per_row), eggs_per_row) - (egg_in_row + 1)
x_offset = 32
y_offset = 30
# The x coordinate of an egg is determined by which egg in the row it is, and how many eggs
# are in that row. If there is only 1 egg in a row, it is in the middle of the screen. If
# there are two, they're on equal halves and so on.
x = x_offset - (eggs_after * distance_between_eggs) + (egg_in_row * distance_between_eggs)
y = y_offset - (rows_after * distance_between_rows) + (current_row * distance_between_rows)
egg.rect.x = x
egg.rect.y = y
# Add the egg to the sprite list.
all_sprites.add(egg)
def get_cursor_coords(selection):
"""
Gets the coordinates of an egg on the selection screen by index and returns it as a tuple
:param selection: index of the egg to be selected
:return: tuple of the coordinates of the selected egg
"""
cursor_x_offset = -2
cursor_y_offset = -2
return eggs[selection].rect.x + cursor_x_offset, eggs[selection].rect.y + cursor_y_offset
def sel_left():
"""
Select the egg to the left with constraints.
"""
nonlocal selected
if selected % eggs_per_row != 0:
selected -= 1
def sel_right():
"""
Select the egg to the right with constraints.
"""
nonlocal selected
row = selected // eggs_per_row
eggs_in_row = min(len(eggs) - (row * eggs_per_row), eggs_per_row)
if selected % eggs_per_row != eggs_in_row - 1:
selected += 1
def sel_up():
"""
Select the egg above with constraints.
"""
nonlocal selected
if selected // eggs_per_row != 0:
selected -= eggs_per_row
def sel_down():
"""
Select the egg below with constraints.
"""
nonlocal selected
if selected // eggs_per_row != total_rows - 1:
selected += eggs_per_row
while running and game_state == 'egg_select' and submenu == 'main':
pre_handler()
for event in pygame.event.get():
if event.type == pygame.KEYDOWN:
if event.key == Constants.buttons.get('j_r'):
sel_right()
if event.key == Constants.buttons.get('j_l'):
sel_left()
if event.key == Constants.buttons.get('j_d'):
sel_down()
if event.key == Constants.buttons.get('j_u'):
sel_up()
if event.key == Constants.buttons.get('a'):
# Advance to the egg info screen for the selected egg.
submenu = 'bloop_info'
# Draws the cursor on screen.
cursor = pygame.image.load(
script_dir + '/resources/images/gui/egg_selector.png').convert_alpha()
surface.blit(cursor, get_cursor_coords(selected))
selected_color = eggs[selected].egg_color
draw()
elif submenu == 'bloop_info':
# Draw the selected egg on screen
egg = SelectionEgg(selected_color)
egg.rect.x = 8
egg.rect.y = 3
all_sprites.add(egg)
# Info screen for the eggs.
info_text = InfoText(small_font, egg.description)
info_icons = EggInfo(egg.contentedness, egg.metabolism, (32, 4))
while running and game_state == 'egg_select' and submenu == 'bloop_info':
pre_handler()
for event in pygame.event.get():
if event.type == pygame.KEYDOWN:
if event.key == Constants.buttons.get('j_d'):
# Scroll down on the info screen.
info_text.scroll_down()
if event.key == Constants.buttons.get('j_u'):
# Scroll up on the info screen.
info_text.scroll_up()
if event.key == Constants.buttons.get('a'):
# Write save file with new attributes
data_handler.attributes['bloop'] = egg.egg_color
data_handler.attributes['health'] = 10
data_handler.attributes['hunger'] = 10
data_handler.attributes['happiness'] = 10
data_handler.attributes['evolution_stage'] = 'egg'
data_handler.write_save()
# Go to playground
game_state = 'playground'
if event.key == Constants.buttons.get('b'):
# Go back to the egg selection screen.
submenu = 'main'
# Draw the info screen.
info_text.draw(surface)
info_icons.draw(surface)
draw()
else: # Go to the error state if an invalid state is set.
game_state = None
else:
# Error screen. This appears when an invalid game state has been selected.
all_sprites.empty()
frames_passed = 0 # Counter for frames, helps ensure the game isn't frozen.
while running and game_state != 'title':
pre_handler()
# Draw the error screen
error_screen = pygame.image.load(script_dir + '/resources/images/debug/invalid.png').convert_alpha()
surface.blit(error_screen, (0, -8))
# Counts the frames passed. Resets every second.
frames_passed += 1
if frames_passed >= game_fps:
frames_passed = 0
# Draws the frame counter.
frame_counter = small_font.render('frames: {0}'.format(frames_passed), False, (64, 64, 64))
surface.blit(frame_counter, (1, game_res - 10))
for event in pygame.event.get():
if event.type == pygame.KEYDOWN:
if event.key == Constants.buttons.get('b'):
# Reset back to the title screen.
game_state = 'title'
draw()
def main():
"""
Calls the game() function to start the game.
"""
game()
GPIOHandler.teardown()
pygame.quit()

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"""
Module that helps with the handling of taking inputs from the GPIO pins on the Raspberry
Pi and converting them to events to be used in other places (pygame, etc.)
"""
import importlib.util
try:
importlib.util.find_spec('RPi.GPIO')
import RPi.GPIO as GPIO
except ImportError:
import pocket_friends.development.FakeGPIO as GPIO
class Constants:
"""
Contains the constants used by the HAT to read in buttons
"""
buttons = {
'a': 31, # A button
'b': 29, # B button
'j_i': 7, # Joystick in
'j_u': 11, # Joystick up
'j_d': 15, # Joystick down
'j_l': 13, # Joystick left
'j_r': 16 # Joystick right
}
class GPIOHandler:
"""
Class to handle the GPIO inputs from the buttons.
"""
@staticmethod
def setup():
"""
Primes the GPIO pins for reading the inputs of the buttons.
"""
GPIO.setmode(GPIO.BOARD)
GPIO.setup(Constants.buttons.get('a'), GPIO.IN)
GPIO.setup(Constants.buttons.get('b'), GPIO.IN)
GPIO.setup(Constants.buttons.get('j_i'), GPIO.IN)
GPIO.setup(Constants.buttons.get('j_u'), GPIO.IN)
GPIO.setup(Constants.buttons.get('j_d'), GPIO.IN)
GPIO.setup(Constants.buttons.get('j_l'), GPIO.IN)
GPIO.setup(Constants.buttons.get('j_r'), GPIO.IN)
GPIO.add_event_detect(Constants.buttons.get('a'), GPIO.FALLING)
GPIO.add_event_detect(Constants.buttons.get('b'), GPIO.FALLING)
GPIO.add_event_detect(Constants.buttons.get('j_i'), GPIO.FALLING)
GPIO.add_event_detect(Constants.buttons.get('j_u'), GPIO.FALLING)
GPIO.add_event_detect(Constants.buttons.get('j_d'), GPIO.FALLING)
GPIO.add_event_detect(Constants.buttons.get('j_l'), GPIO.FALLING)
GPIO.add_event_detect(Constants.buttons.get('j_r'), GPIO.FALLING)
@staticmethod
def teardown():
"""
Cleans up the GPIO handler.
"""
GPIO.cleanup()
@staticmethod
def get_press(button):
"""
Returns true if a button has moved from not pressed to pressed.
:param button: button to be detected
:return: True if the button is has been pressed, False otherwise
"""
return GPIO.event_detected(button)

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"""Subpackage for handling all I/O operations including keyboard input (GPIO input when connected to a Raspberry Pi)
and save data reading and writing."""

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import pocket_friends
import json
class SaveData:
"""
Class used to read and write save data for the game
Attributes:
attributes (dict): Dictionary containing all the attributes to read and write from a save file.
"""
def __init__(self):
"""
Constructs the object with all starting values.
"""
# Attributes that are saved to a file to recover upon startup.
self.attributes = {
'version': pocket_friends.__version__,
'time_elapsed': 0,
'bloop': '',
'age': 0,
'health': 0,
'hunger': 0,
'happiness': 0,
'care_counter': 0,
'missed_care': 0,
'adult': 0,
'evolution_stage': '',
}
# Frame counter
self.frames_passed = 0
def write_save(self):
"""
Writes attributes of the save object to "save.json" file.
"""
with open(save_dir + '/save.json', 'w') as save_file:
json.dump(self.attributes, save_file)
save_file.close()
def read_save(self):
"""
Reads from "save.json" and inserts into the save object's attributes dictionary. Creates file if it does not
exist.
"""
# Open up the save file and read it into self.attributes.
try:
with open(save_dir + '/save.json', 'r') as save_file:
self.attributes = json.load(save_file)
save_file.close()
# If there is no save file, write one with the defaults.
except FileNotFoundError:
self.write_save()

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import pygame
class InputHandler:
"""
Class that is implemented into surfaces in order to control the
pressing of buttons on both the real hardware and on a keyboard.
Attributes:
clock (pygame.time.Clock): Pygame clock used for input time calculations.
last_input_tick (int): The tick that the last input was registered on.
"""
def __init__(self, pygame_clock, tick_check=True):
"""
Create a InputHandler object using a given Pygame clock.
Args:
pygame_clock (:obj:`pygame.time.Clock`): A pygame clock to use as the clock for input time calculations.
tick_check (bool, optional): Bool to ignore inputs that happen to quickly after another. Defaults to True.
"""
self.clock = pygame_clock
self.tick_check = tick_check
self.last_input_tick = 0
def create_event(self, pressed_button):
"""
Create a pygame event given a GPIO code and post it to the pygame event handler.
Args:
pressed_button (int): The GPIO code to be registered and pressed.
"""
# Register a button click so long as the last button click happened no less than two frames ago
if self.tick_check:
if pygame.time.get_ticks() - self.last_input_tick > self.clock.get_time() * 2:
pygame.event.post(pygame.event.Event(pygame.KEYDOWN, {'key': pressed_button}))
pygame.event.post(pygame.event.Event(pygame.KEYUP, {'key': pressed_button}))
else:
pygame.event.post(pygame.event.Event(pygame.KEYDOWN, {'key': pressed_button}))
pygame.event.post(pygame.event.Event(pygame.KEYUP, {'key': pressed_button}))
self.last_input_tick = pygame.time.get_ticks()
def handle_keyboard(self):
"""Handle keyboard presses and generate corresponding GPIO codes to create events."""
# Checks if a corresponding keyboard key has been pressed. If it has, emulate a button press.
for keyboard_event in pygame.event.get():
if keyboard_event.type == pygame.QUIT:
running = False
if keyboard_event.type == pygame.KEYDOWN:
if keyboard_event.key == pygame.K_a:
self.create_event(pygame.K_a)
if keyboard_event.key == pygame.K_b:
self.create_event(pygame.K_b)
if keyboard_event.key == pygame.K_KP_ENTER:
self.create_event(pygame.K_KP_ENTER)
if keyboard_event.key == pygame.K_RIGHT:
self.create_event(pygame.K_RIGHT)
if keyboard_event.key == pygame.K_LEFT:
self.create_event(pygame.K_LEFT)
if keyboard_event.key == pygame.K_DOWN:
self.create_event(pygame.K_DOWN)
if keyboard_event.key == pygame.K_UP:
self.create_event(pygame.K_UP)
if keyboard_event.key == pygame.K_ESCAPE:
running = False
def update(self):
"""Run either the GPIO handler or the keyboard handler to check for input and create events."""
self.handle_keyboard()

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import pygame
from pocket_friends.elements import sprites
from pocket_friends.elements import surface
class Surface(surface.GameSurface):
def __init__(self, game_res, resources_dir, game_fps, **kwargs):
super().__init__(game_res, resources_dir, game_fps)
preselected_color = None
for key in kwargs.keys():
if key == 'selected_color':
preselected_color = kwargs.get(key)
egg_list = [
'dev_egg',
'blue',
'rainbow'
]
self.eggs = []
for egg in egg_list:
self.eggs.append(sprites.SelectionEgg(egg, self.resource_dir))
self.eggs_per_row = 3
distance_between_eggs = 36 / self.eggs_per_row
# Count the total rows.
self.total_rows = -(-len(self.eggs) // self.eggs_per_row)
distance_between_rows = 32 / self.eggs_per_row
# Determine the location of each egg.
for egg in self.eggs:
current_row = self.eggs.index(egg) // self.eggs_per_row
rows_after = self.total_rows - (current_row + 1)
egg_in_row = self.eggs.index(egg) % self.eggs_per_row
eggs_after = min(len(self.eggs) - (current_row * self.eggs_per_row), self.eggs_per_row) - (egg_in_row + 1)
x_offset = 32
y_offset = 30
# The x coordinate of an egg is determined by which egg in the row it is, and how many eggs
# are in that row. If there is only 1 egg in a row, it is in the middle of the screen. If
# there are two, they're on equal halves and so on.
x = x_offset - (eggs_after * distance_between_eggs) + (egg_in_row * distance_between_eggs)
y = y_offset - (rows_after * distance_between_rows) + (current_row * distance_between_rows)
egg.rect.x = x
egg.rect.y = y
# Add the egg to the sprite list.
self.sprites.add(egg)
self.selected_egg = 0
self.selected_color = ''
if preselected_color is not None:
self.selected_color = self.eggs[self.selected_egg].egg_color
for i in range(len(self.eggs)):
if self.eggs[i].egg_color == preselected_color:
self.selected_egg = i
def get_cursor_coords(self):
"""
Gets the coordinates of an egg on the selection screen by index and returns it as a tuple
:return: tuple of the coordinates of the selected egg
"""
cursor_x_offset = -2
cursor_y_offset = -2
return (self.eggs[self.selected_egg].rect.x + cursor_x_offset,
self.eggs[self.selected_egg].rect.y + cursor_y_offset)
def sel_left(self):
"""
Select the egg to the left with constraints.
"""
if self.selected_egg % self.eggs_per_row != 0:
self.selected_egg -= 1
def sel_right(self):
"""
Select the egg to the right with constraints.
"""
row = self.selected_egg // self.eggs_per_row
eggs_in_row = min(len(self.eggs) - (row * self.eggs_per_row), self.eggs_per_row)
if self.selected_egg % self.eggs_per_row != eggs_in_row - 1:
self.selected_egg += 1
def sel_up(self):
"""
Select the egg above with constraints.
"""
if self.selected_egg // self.eggs_per_row != 0:
self.selected_egg -= self.eggs_per_row
def sel_down(self):
"""
Select the egg below with constraints.
"""
if self.selected_egg // self.eggs_per_row != self.total_rows - 1:
self.selected_egg += self.eggs_per_row
def update(self):
self.preprocess()
cursor = pygame.image.load(
self.resource_dir + '/images/gui/egg_selector.png').convert_alpha()
self.blit(cursor, self.get_cursor_coords())
self.selected_color = self.eggs[self.selected_egg].egg_color
for event in pygame.event.get():
if event.type == pygame.KEYDOWN:
if event.key == pygame.K_RIGHT:
self.sel_right()
if event.key == pygame.K_LEFT:
self.sel_left()
if event.key == pygame.K_DOWN:
self.sel_down()
if event.key == pygame.K_UP:
self.sel_up()
if event.key == pygame.K_a:
self.additional_args = {'selected_egg': self.selected_color}
self.next_surface = 'selection_info'
self.running = False

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import pygame
from pocket_friends.elements import surface
class Surface(surface.GameSurface):
def __init__(self, game_res, resources_dir, game_fps, **kwargs):
super().__init__(game_res, resources_dir, game_fps)
self.frames = 1
self.game_fps = game_fps
self.delay = 1
self.font = pygame.font.Font(resources_dir + '/fonts/5Pts5.ttf', 10)
self.title = pygame.image.load(resources_dir + '/images/debug/invalid.png').convert_alpha()
self.next_surface = 'title'
def update(self):
self.preprocess()
self.blit(self.title, (0, -4))
text = self.font.render('Frames: {0}'.format(self.frames), False, (64, 64, 64))
self.blit(text, (3, 68))
self.frames += 1
self.frames %= self.game_fps
for event in pygame.event.get():
if event.type == pygame.KEYDOWN:
if event.key == pygame.K_b:
self.running = False

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import pygame
from pocket_friends.elements import sprites
from pocket_friends.elements import surface
class Surface(surface.GameSurface):
def __init__(self, game_res, resources_dir, game_fps, **kwargs):
super().__init__(game_res, resources_dir, game_fps)
preselected_color = None
for key in kwargs.keys():
if key == 'selected_color':
preselected_color = kwargs.get(key)
self.selected_egg = None
for key in kwargs.keys():
if key == 'selected_egg':
self.selected_egg = kwargs.get(key)
egg = sprites.SelectionEgg(self.selected_egg, resources_dir)
egg.rect.x = 8
egg.rect.y = 3
self.sprites.add(egg)
self.info_text = sprites.InfoText(resources_dir, game_res[0], egg.description)
self.info_icons = sprites.EggInfo(resources_dir, egg.contentedness, egg.metabolism, (32, 4))
def update(self):
self.preprocess()
self.info_text.draw(self)
self.info_icons.draw(self)
for event in pygame.event.get():
if event.type == pygame.KEYDOWN:
if event.key == pygame.K_DOWN:
# Scroll down on the info screen.
self.info_text.scroll_down()
if event.key == pygame.K_UP:
# Scroll up on the info screen.
self.info_text.scroll_up()
if event.key == pygame.K_a:
self.running = False
self.additional_args = {'selected_color': self.selected_egg}
self.next_surface = 'playground'
if event.key == pygame.K_b:
self.running = False
self.additional_args = {'selected_color': self.selected_egg}
self.next_surface = 'egg_select'

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import pygame
from pocket_friends.elements import surface
class Surface(surface.GameSurface):
def __init__(self, game_res, resources_dir, game_fps):
super().__init__(game_res, resources_dir, game_fps)
self.frames = 0
self.delay = 1
self.title = pygame.image.load(resources_dir + '/images/title.png').convert_alpha()
def update(self):
"""
Advance the surface logic by one frame.
"""
self.preprocess()
self.blit(self.title, (0, 0))
print(self.frames)
self.frames += 1
if self.frames > self.game_fps * self.delay:
self.next_surface = 'egg_select'
self.running = False

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pygame~=1.9.6
pygame~=2.1.2

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@ -21,6 +21,6 @@ setuptools.setup(
classifiers=[
],
install_requires=required,
python_requires='>=3.7',
python_requires='>=3.10',
include_package_data=True,
)