init 5 python: class DollChibi(renpy.Displayable): # class attribute instances = {} def __init__(self, name, layer="screens", zorder=12, zoom=0.28, **properties): super().__init__(**properties) self.name = name self.tag = name + "_chibi" self.pose = None self.walk = "walk" self.idle = "stand" self.layer = layer self.zorder = zorder self.zoom = zoom self.pos = (0,0) self.xzoom = 1 self.char = eval(name) self.poses = {} # Animation self.anim_frames = None self.anim_sprite = None self.anim_speed = 1.0 self.anim_fps = 8.0 self.anim_trans = None self.anim_interval = None self.anim_interval_total = None # ATL self.atl_time = 0 self.atl_time_total = 0 self.atl_partial = None self.atl_looping = False self.atl_pause = False self.atl_at_list = [] self.instances[name] = self def register(self, pose, frames, size): self.poses[pose] = (frames, size) if config.developer: print(f"Registered \"{pose}\" pose for {self.name}") @functools.cache def build_image(self, hash, pose): states = self.char.states items = [v[0] for v in states.values() if v[0] and v[2]] subpath = posixpath.join("chibi", pose) sprites = [(ltype, img, z) for i in items for ltype, img, z in i.build_image(i._hash, subpath, maxsize=None)] masks = [sprites.pop(sprites.index(i)) for i in sprites if i[0] == "mask"] sprites.sort(key=itemgetter(2)) masks.sort(key=itemgetter(2)) back_sprites = [x[1] for x in sprites if x[2] < 0] #Apply alpha mask for m in masks: _, mask, mask_zorder = m for i, s in enumerate(sprites): _, sprite, sprite_zorder = s if i < 1 or mask_zorder > sprite_zorder: continue masked = AlphaMask(Fixed(*(x[1] for x in sprites[:i]), fit_first=True), mask) sprites = sprites[i:] sprites.insert(0, (None, masked, mask_zorder)) break sprites = back_sprites + [x[1] for x in sprites] return Fixed(*sprites, fit_first=True) def build_animation(self): pose = self.pose frames = self.poses[pose][0] sprite = self.build_image(self.char._hash, pose) if frames > 1: interval = self.anim_speed / self.anim_fps else: interval = (365.25 * 86400.0) # About one year self.anim_frames = frames self.anim_interval = interval self.anim_interval_total = (frames * interval) self.anim_sprite = sprite def render(self, width, height, st, at): frame_width, frame_height = self.poses[self.pose][1] # Calculate the current frame based on the time trans = self.anim_trans interval = self.anim_interval time = (st % self.anim_interval_total) frame = int(time / interval) sprite = self.anim_sprite if trans and st >= interval: sprite = trans(old_widget=sprite, new_widget=sprite) cr = renpy.render(sprite, width, height, st, at) sheet_width, sheet_height = cr.get_size() # Calculate the position of the current frame within the sprite sheet sheet_cols = sheet_width // frame_width sheet_row = int(frame / sheet_cols) sheet_col = frame % sheet_cols frame_x = sheet_col * frame_width frame_y = sheet_row * frame_height rv = renpy.Render(frame_width, frame_height) rv.blit(cr.subsurface((frame_x, frame_y, frame_width, frame_height)), (0, 0)) if not self.atl_looping and st > self.atl_time_total: renpy.timeout(0) elif not renpy.game.less_updates: renpy.redraw(self, interval - time) return rv def event(self, ev, x, y, st): # Determine pose change if show time exceeds animation time. # Looping animations ignore this check because they are rebuilt every loop. if renpy.in_rollback(): # We don't want to use 'raise renpy.IgnoreEvent' because it blocks events in other displayables, including interfaces return elif renpy.is_skipping(): self.stop() return elif ((not self.atl_looping and st > self.atl_time_total) or (ev.type == pygame.MOUSEBUTTONUP and ev.button == 1) or (ev.type == pygame.KEYDOWN and ev.key in [pygame.K_RETURN, pygame.K_SPACE, pygame.K_KP_ENTER, pygame.K_SELECT])): self.stop() # def per_interact(self): # # Handle interrupt events # if (renpy.is_skipping() or self.atl_pause) and not self.pose == self.idle: # self.stop() def set_pose(self, pose): if self.pose == pose: return self.pose = pose self.update() def place(self, pos=None, speed=1.0, pause=False, at_list=[], pose=None, xzoom=None): self.set_pose(pose or self.idle) self.atl_time = 0 self.atl_time_total = 0 self.atl_partial = None self.atl_looping = False self.atl_pause = False self.atl_at_list = [] frames = self.anim_frames if frames > 1: interval = (self.anim_speed / self.anim_fps) / speed interval_total = (frames * interval) self.anim_interval = interval self.anim_interval_total = interval_total xzoom = xzoom or (-1 if (pos > self.pos) else 1) self.pos = pos or self.pos self.xzoom = xzoom transform = Transform(pos=pos, zoom=self.zoom, xzoom=xzoom, anchor=(0.5, 1.0)) self.show(transform, at_list, self.layer, self.zorder) if pause: renpy.pause(None) return def move(self, path, speed=1.0, pause=True, loop=False, warper="linear", at_list=[], pose=None, repeat=None, wrap=True, reverse=True): """Makes chibi move""" self.atl_looping = loop self.atl_pause = pause self.atl_at_list = at_list if isinstance(path, tuple): path = [path] # If 'A' position is not supplied for A -> B movement, use last known position instead. if len(path) < 2: path = [self.pos] + path # If reverse and loop/repeat is True, and pathing has more than two entries, # use complex looping by joining the reversed paths elif reverse and (loop or repeat): # Reverses the list, strips last entry from the reverse list, and finally joins them. path += path[1::-1] if repeat: path *= repeat if wrap: # Wrap pathing back to starting position path.append(path[0]) self.set_pose(pose or self.walk) # Note: Warper names and their count can change over time, # so it's easier to just evaluate the input. # List of available warpers: # https://www.renpy.org/doc/html/atl.html?#warpers warper = eval(f"_warper.{warper}") distances = [] times = [] if loop: # Append first position as last to create a looped path. path.append(path[0]) # Calculate distances and timings using euclidean distance algorithm. for xy1, xy2 in zip(path, path[1:]): x1, y1 = xy1 x2, y2 = xy2 distance = math.hypot(x2 - x1, y2 - y1) time = distance / (100.0 * speed) distances.append(distance) times.append(time) # Calculate total ATL time required to reach the destination total_time = sum(times) self.atl_time_total = total_time # Recalculate animation intervals when necessary, including speed factors. frames = self.anim_frames if frames > 1: interval = (self.anim_speed / self.anim_fps) / speed interval_total = (frames * interval) self.anim_interval = interval self.anim_interval_total = interval_total # renpy.partial allows us to pass arguments into a transform function. partial = renpy.partial(self.move_atl, path, times, loop, warper) self.atl_partial = partial transform = Transform(function=partial, anchor=(0.5, 1.0)) self.show(transform, at_list, self.layer, self.zorder) if pause: if loop: renpy.pause(None) else: renpy.pause(total_time) return (distances, times) def stop(self): if not self.atl_partial: return # Freezes the animation (*_, opos, pos), _, _, _ = self.atl_partial.args xzoom = -1 if (pos > opos) else 1 zpos = self.zorder + (config.screen_height / pos[1]) self.pos = pos self.xzoom = xzoom self.atl_time = 0 self.atl_time_total = 0 self.set_pose(self.idle) transform = Transform(pos=pos, zoom=self.zoom, xzoom=xzoom, anchor=(0.5, 1.0)) self.show(transform, self.atl_at_list, self.layer, zpos) def move_atl(self, path, times, loop, warper, trans, st, at): """Animations are time based, so each segment will happen at a specific frame time.""" if self.atl_time_total == 0: # Stops updating the animation return None if loop: timer = st % self.atl_time_total else: timer = st if timer > self.atl_time_total: return None internal_time = 0 current_segment = 0 # TODO: This loop feels unnecessary, need to find a better way. for i, t in enumerate(times): if (internal_time + t) > timer: current_segment = i break internal_time += t segment_time = (timer - internal_time) / times[current_segment] next_segment = current_segment + 1 path_current_segment = path[current_segment] path_next_segment = path[next_segment] # Adjust XY position trans.pos = renpy.atl.interpolate(warper(segment_time), path_current_segment, path_next_segment, renpy.atl.PROPERTIES["pos"]) self.pos = trans.pos # Adjust X zoom based on target X position # 1 = Facing Right, -1 = Facing Left trans.xzoom = 1 if (path_current_segment[0] > path_next_segment[0]) else -1 self.xzoom = trans.xzoom # Adjust zoom trans.zoom = self.zoom # Adjust Z position based on Y axis # TODO: Add room support with bottom, middle, and top vanishing points. # room_scale = 0.5 # zpos1 = ((path_current_segment[1] / 600.0) * 1000.0) * room_scale # zpos2 = ((path_next_segment[1] / 600.0) * 1000.0) * room_scale # trans.zpos = renpy.atl.interpolate(warper(segment_time), zpos1, zpos2, renpy.atl.PROPERTIES["zpos"]) # self.zpos = trans.zpos # TODO: Using zorders is suboptimal and expensive, using 3D staging would be preferable. zpos = self.zorder + (config.screen_height / self.pos[1]) renpy.change_zorder(self.layer, self.tag, zpos) return 0 def show(self, transform, at_list, layer, zorder): # The safest way to restart the transform is to rebuild it. # Other methods proved to be too finicky... image = At(self, transform) # IMPORTANT: Enable perspective and gl_depth for 3D staging if not renpy.is_init_phase(): renpy.show(name=self.tag, what=image, at_list=at_list, layer=layer, zorder=zorder) def hide(self): if not renpy.is_init_phase(): renpy.hide(name=self.tag) def update(self): self.build_animation() renpy.redraw(self, 0) @property def image(self): return self init offset = 5 default hooch_chibi = DollChibi(name="hooch", doll=hooch) # default cho_chibi_new = DollChibi(name="cho", doll=cho) # default tonks_chibi_new = DollChibi(name="tonks", doll=tonks) # label chibitest: # chibi tonks register ("stand", 1, (600, 800)) # chibi tonks register ("walk", 8, (600, 800)) # "Rollback block" # $ renpy.block_rollback() # "repeat 3" # chibi tonks move (path=[(500, 421), (650, 521), (800, 421)], repeat=3) # "loop" # chibi tonks move (path=[(500, 421), (650, 521), (800, 421)], loop=True) # "doll synchronisation" # chibi tonks move (path=[(500, 421), (650, 521), (800, 421)], loop=True, pause=False) # ton @ hair default "Default" ("base", "base", "base", "mid") # ton @ hair angry "Angry" ("angry", "narrow", "angry", "mid") # ton @ hair scared "Scared" ("scream", "wide", "worried", "mid") # "End" # hide tonks_chibi # hide tonks_main # jump main_room_menu # label chibitest2: # chibi tonks register ("stand", 1, (600, 800)) # chibi tonks register ("walk", 8, (600, 800)) # "Rollback block" # $ renpy.block_rollback() # "pos 1" # chibi tonks place (pos=(300,300)) # "pos 2" # chibi tonks place (pos=(400,300)) # "pos 3" # chibi tonks place (pos=(400,400)) # "pos 4" # chibi tonks place (pos=(200,400)) # "pos 5" # chibi tonks place (pos=(600,400)) # "End" # hide tonks_chibi # hide tonks_main # jump main_room_menu