# Copyright 2022 The Kubric Authors # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # https://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. """ Worker file for the Multi-Object Video (MOVi) C (and CC) datasets. * The number of objects is randomly chosen between --min_num_objects (3) and --max_num_objects (10) * The objects are randomly chosen from the Google Scanned Objects dataset * Background is an random HDRI from the HDRI Haven dataset, projected onto a Dome (half-sphere). The HDRI is also used for lighting the scene. """ import logging import bpy import copy import os import kubric as kb from kubric.simulator import PyBullet from kubric.renderer import Blender import numpy as np import random import shutil from GSO_transfer import GSO_dict from utils import save_scene_instruction, dataset_dir # --- Some configuration values DATASET_TYPE = "location" # the region in which to place objects [(min), (max)] SPAWN_REGION = [(-8, -8, 0), (8, 8, 5)] SPAWN_REGION_OBJ = [[-6, -6, 0.5], [6, 6, 0.5]] VELOCITY_RANGE = [(-4., -4., 0.), (4., 4., 0.)] # --- CLI arguments parser = kb.ArgumentParser() parser.add_argument("--objects_split", choices=["train", "test"], default="train") # Configuration for the objects of the scene parser.add_argument("--min_num_objects", type=int, default=1, help="minimum number of objects") parser.add_argument("--max_num_objects", type=int, default=5, help="maximum number of objects") # Configuration for the floor and background parser.add_argument("--floor_friction", type=float, default=0.3) parser.add_argument("--floor_restitution", type=float, default=0.5) parser.add_argument("--backgrounds_split", choices=["train", "test"], default="train") parser.add_argument("--camera", choices=["fixed_random", "linear_movement"], default="fixed_random") parser.add_argument("--max_camera_movement", type=float, default=4.0) parser.add_argument("--smallest_scale", type=float, default=2.) parser.add_argument("--largest_scale", type=float, default=4.) # Configuration for the source of the assets parser.add_argument("--kubasic_assets", type=str, default="gs://kubric-public/assets/KuBasic/KuBasic.json") parser.add_argument("--hdri_assets", type=str, default="gs://kubric-public/assets/HDRI_haven/HDRI_haven.json") parser.add_argument("--gso_assets", type=str, default="gs://kubric-public/assets/GSO/GSO.json") parser.add_argument("--save_state", dest="save_state", action="store_true") parser.set_defaults(save_state=False, frame_end=24, frame_rate=12, resolution=512) parser.add_argument("--sub_outputdir", type=str, default="test sub output dir") parser.add_argument("--generate_idx", type=int, default=-1, help="generation idx") FLAGS = parser.parse_args() import pyquaternion as pyquat def default_rng(): return np.random.RandomState() def random_rotation(axis=None, rng=default_rng()): """ Compute a random rotation as a quaternion. If axis is None the rotation is sampled uniformly over all possible orientations. Otherwise it corresponds to a random rotation around the given axis.""" if axis is None: # uniform across rotation space # copied from pyquat.Quaternion.random to be able to use a custom rng r1, r2, r3 = rng.random(3) q1 = np.sqrt(1.0 - r1) * (np.sin(2 * np.pi * r2)) q2 = np.sqrt(1.0 - r1) * (np.cos(2 * np.pi * r2)) q3 = np.sqrt(r1) * (np.sin(2 * np.pi * r3)) q4 = np.sqrt(r1) * (np.cos(2 * np.pi * r3)) return q1, q2, q3, q4 else: if isinstance(axis, str) and axis.upper() in ["X", "Y", "Z"]: axis = {"X": (1., 0., 0.), "Y": (0., 1., 0.), "Z": (0., 0., 1.)}[axis.upper()] # quat = pyquat.Quaternion(axis=axis, angle=rng.uniform(0, 2*np.pi)) quat = pyquat.Quaternion(axis=axis, angle=rng.uniform(-0.5*np.pi, 0.5*np.pi)) # -0.5pi -- 0.5pi return tuple(quat) from kubric.core import objects def rotation_sampler(axis=None): def _sampler(obj: objects.PhysicalObject, rng): obj.quaternion = random_rotation(axis=axis, rng=rng) return _sampler def move_until_no_overlap(asset, simulator, spawn_region=((-1, -1, -1), (1, 1, 1)), max_trials=100, rng=default_rng()): return kb.randomness.resample_while(asset, # samplers=[rotation_sampler(axis='Z'), kb.randomness.position_sampler(spawn_region)], samplers=[kb.randomness.position_sampler(spawn_region)], condition=simulator.check_overlap, max_trials=max_trials, rng=rng) def check_ok(obj, pos, region): # import pdb; pdb.set_trace() x, y, z = pos if pos[0]region[1][0] or pos[1]region[1][1]: #or pos[2]region[1][2]: return False if simulator.check_overlap(obj): return False return True def get_obj_x_left(bound, scale): return -bound[0][0] * scale[0] def get_obj_x_right(bound, scale): return bound[1][0] * scale[0] def get_obj_y_front(bound, scale): return -bound[0][1] * scale[1] def get_obj_y_behind(bound, scale): return bound[1][1] * scale[1] def get_obj_z(bound, scale): return bound[0][2] * scale[2] def get_obj_z_up(bound, scale): return bound[1][2] * scale[2] def get_new_pos(bounds, scale, ref_location, ref_pos, ref_z_up, ref_object, rng): obj_z = - get_obj_z(bounds, scale) # import pdb; pdb.set_trace() ref_x_left, ref_x_right, ref_y_front, ref_y_behind = get_obj_x_left(ref_object.bounds, ref_object.scale), get_obj_x_right(ref_object.bounds, ref_object.scale), get_obj_y_front(ref_object.bounds, ref_object.scale), get_obj_y_behind(ref_object.bounds, ref_object.scale) ref_x, ref_y, ref_z = ref_pos if ref_location == 'front': return [rng.uniform(ref_x-0.5, ref_x+0.5), rng.uniform(ref_y-ref_y_front-6, ref_y-ref_y_front-2), obj_z+0.02] elif ref_location == 'behind': return [rng.uniform(ref_x-0.5, ref_x+0.5), rng.uniform(ref_y+ref_y_behind+2, ref_y+ref_y_behind+6), obj_z+0.02] elif ref_location == 'left': return [rng.uniform(ref_x-ref_x_left-6, ref_x-ref_x_left-2), rng.uniform(ref_y-0.5, ref_y+0.5), obj_z+0.02] elif ref_location == 'right': return [rng.uniform(ref_x+ref_x_right+2, ref_x+ref_x_right+6), rng.uniform(ref_y-0.5, ref_y+0.5), obj_z+0.02] elif ref_location == 'on': return [ref_x, ref_y, ref_z+ref_z_up+obj_z+1] # def get_new_pos(bounds, scale, ref_location, ref_pos, ref_z_up, ref_object, rng): # # Calculate the z-position based on the object's bounds and scale # obj_z = -get_obj_z(bounds, scale) + 0.2 # Ensuring the object is slightly above the ground # # Extract the bounds from the SPAWN_REGION_OBJ variable # spawn_x_min, spawn_y_min, _ = SPAWN_REGION_OBJ[0] # spawn_x_max, spawn_y_max, _ = SPAWN_REGION_OBJ[1] # # Calculate the maximum offsets within the given spawn bounds # max_offset_x = spawn_x_max - spawn_x_min + 1 # max_offset_y = spawn_y_max - spawn_y_min + 1 # # Define absolute positions for each location using straightforward calculations # locations = { # 'closer': [ref_pos[0], max(spawn_y_min, ref_pos[1] - max_offset_y), obj_z], # 'further away': [ref_pos[0], min(spawn_y_max, ref_pos[1] + max_offset_y), obj_z], # 'further left': [max(spawn_x_min, ref_pos[0] - max_offset_x), ref_pos[1], obj_z], # 'further right': [min(spawn_x_max, ref_pos[0] + max_offset_x), ref_pos[1], obj_z], # } # # Return the position for the specified location # return locations.get(ref_location, [ref_pos[0], ref_pos[1], obj_z]) # Default position if location is not specified def add_new_obj(scene, new_obj, ref_location, ref_object, rng, max_trails=50): ref_obj_pos = ref_object.position # import pdb; pdb.set_trace() ref_obj_z_up = get_obj_z_up(ref_object.bounds, ref_object.scale) new_obj_pos = get_new_pos(new_obj.bounds, new_obj.scale, ref_location, ref_obj_pos, ref_obj_z_up, ref_object, rng) new_obj.position = new_obj_pos scene += new_obj # import pdb; pdb.set_trace() trails = 0 while not check_ok(new_obj, new_obj.position, SPAWN_REGION_OBJ): trails += 1 # import pdb; pdb.set_trace() new_obj.position = get_new_pos(new_obj.bounds, new_obj.scale, ref_location, ref_obj_pos, ref_obj_z_up, ref_object, rng) # new_obj.quaternion = random_rotation(axis="Z", rng=rng) if trails > max_trails: print('cannot put the object, break') # import pdb; pdb.set_trace() return None print('try {} times'.format(trails)) return scene def gen_caption(obj_name, obj_scale, ref_obj_name, ref_obj_scale, location): # def get_size(scale): # if scale < 1.: # return ' small' # elif scale > 2.5: # return ' large' # else: # return '' # import pdb; pdb.set_trace() # obj_size_exp = get_size(obj_scale) # ref_obj_size_exp = get_size(ref_obj_scale) # verb_exp = random.choice(['is', 'is located', 'is placed']) if location == 'front': location_exp = 'in front of' elif location == 'behind': location_exp = 'behind' elif location == 'left': location_exp = random.choice(['on the left of', 'on the left side of', 'on the left hand of']) elif location == 'right': location_exp = random.choice(['on the right of', 'on the right side of', 'on the right hand of']) elif location == 'on': location_exp = random.choice(['on the top of', 'above']) # elif location == 'further right': # location_exp = 'further right' # elif location == 'further left': # location_exp = 'further left' # elif location == 'further away': # location_exp = 'further away' # elif location == 'closer': # location_exp = 'closer' edit_verb = random.choice(['put', 'shift', 'change', 'place']) # caption = f'the{obj_size_exp} {obj_name} {verb_exp} {location_exp} the{ref_obj_size_exp} {ref_obj_name}' if edit_verb in ['put', 'place']: caption = f'{edit_verb} the {obj_name} {location_exp} the {ref_obj_name}' else: caption = f'{edit_verb} the position of the {obj_name} {location_exp} the {ref_obj_name}' return caption def sample_unique_items(GSO_dict, num_samples): unique_items = {} sampled_values = set() active_keys = list(GSO_dict.keys()) while len(unique_items) < num_samples: key = random.choice(active_keys) value = GSO_dict[key] if value not in sampled_values: sampled_values.add(value) unique_items[key] = value active_keys.remove(key) if not active_keys: break return list(unique_items.keys()) # --- Common setups & resources print('Generate {} Sample'.format(FLAGS.generate_idx)) scene, rng, output_dir, scratch_dir = kb.setup(FLAGS) output_dir = output_dir / FLAGS.sub_outputdir simulator = PyBullet(scene, scratch_dir) renderer = Blender(scene, scratch_dir, samples_per_pixel=64) kubasic = kb.AssetSource.from_manifest(FLAGS.kubasic_assets) gso = kb.AssetSource.from_manifest(FLAGS.gso_assets) hdri_source = kb.AssetSource.from_manifest(FLAGS.hdri_assets) # --- Populate the scene # background HDRI train_backgrounds, test_backgrounds = hdri_source.get_test_split(fraction=0.) logging.info("Choosing one of the %d training backgrounds...", len(train_backgrounds)) hdri_id = rng.choice(train_backgrounds) background_hdri = hdri_source.create(asset_id=hdri_id) #assert isinstance(background_hdri, kb.Texture) logging.info("Using background %s", hdri_id) scene.metadata["background"] = hdri_id renderer._set_ambient_light_hdri(background_hdri.filename) # Dome dome = kubasic.create(asset_id="dome", name="dome", friction=FLAGS.floor_friction, restitution=FLAGS.floor_restitution, static=True, background=True) assert isinstance(dome, kb.FileBasedObject) scene += dome dome_blender = dome.linked_objects[renderer] texture_node = dome_blender.data.materials[0].node_tree.nodes["Image Texture"] texture_node.image = bpy.data.images.load(background_hdri.filename) def get_linear_camera_motion_start_end( movement_speed: float, inner_radius: float = 8., outer_radius: float = 12., z_offset: float = 0.1, ): """Sample a linear path which starts and ends within a half-sphere shell.""" while True: camera_start = np.array(kb.sample_point_in_half_sphere_shell(inner_radius, outer_radius, z_offset)) direction = rng.rand(3) - 0.5 movement = direction / np.linalg.norm(direction) * movement_speed camera_end = camera_start + movement if (inner_radius <= np.linalg.norm(camera_end) <= outer_radius and camera_end[2] > z_offset): return camera_start, camera_end # Camera logging.info("Setting up the Camera...") scene.camera = kb.PerspectiveCamera(focal_length=35., sensor_width=36) if FLAGS.camera == "fixed_random": # scene.camera.position = kb.sample_point_in_half_sphere_shell( # inner_radius=7., outer_radius=9., offset=4) scene.camera.position = (0, -10, 15) scene.camera.look_at((0, 0, 0)) elif FLAGS.camera == "linear_movement": camera_start, camera_end = get_linear_camera_motion_start_end( movement_speed=rng.uniform(low=0., high=FLAGS.max_camera_movement) ) # linearly interpolate the camera position between these two points # while keeping it focused on the center of the scene # we start one frame early and end one frame late to ensure that # forward and backward flow are still consistent for the last and first frames for frame in range(FLAGS.frame_start - 1, FLAGS.frame_end + 2): interp = ((frame - FLAGS.frame_start + 1) / (FLAGS.frame_end - FLAGS.frame_start + 3)) scene.camera.position = (interp * np.array(camera_start) + (1 - interp) * np.array(camera_end)) scene.camera.look_at((0, 0, 0)) scene.camera.keyframe_insert("position", frame) scene.camera.keyframe_insert("quaternion", frame) # Add random objects train_split, test_split = gso.get_test_split(fraction=0.) # if FLAGS.objects_split == "train": logging.info("Choosing one of the %d training objects...", len(train_split)) # active_split = train_split active_split = list(GSO_dict.keys()) num_objects = rng.randint(FLAGS.min_num_objects, FLAGS.max_num_objects+1) logging.info("Step 1: Randomly placing %d objects:", num_objects) object_state_save_dict = {} object_state_ref_dict = {} # not resample objects # object_id_list = random.sample(active_split, num_objects+1) object_id_list = sample_unique_items(GSO_dict, num_objects+1) for i in range(num_objects): # object_id = rng.choice(active_split) object_id = object_id_list[i] obj = gso.create(asset_id=object_id) assert isinstance(obj, kb.FileBasedObject) scale = rng.uniform(FLAGS.smallest_scale, FLAGS.largest_scale) obj.scale = scale / np.max(obj.bounds[1] - obj.bounds[0]) obj_pos_z = - get_obj_z(obj.bounds, obj.scale) SPAWN_REGION_OBJ[0][2], SPAWN_REGION_OBJ[1][2] = obj_pos_z, obj_pos_z obj.position = rng.uniform(*SPAWN_REGION_OBJ) obj.metadata["scale"] = scale scene += obj move_until_no_overlap(obj, simulator, spawn_region=SPAWN_REGION_OBJ, rng=rng) # initialize velocity randomly but biased towards center # obj.velocity = (rng.uniform(*VELOCITY_RANGE) - # [obj.position[0], obj.position[1], 0]) # print(obj.position) obj.velocity = [0, 0, 0] logging.info(" Added %s at %s", obj.asset_id, obj.position) object_state_save_dict[i] = {'object_id': object_id, 'object_scale': obj.scale, 'object_quaternion': obj.quaternion, 'object_bounds': obj.bounds} object_state_ref_dict[i] = {'object': obj} ref_object = object_state_ref_dict[rng.choice(list(object_state_ref_dict.keys()))]['object'] # random choose an reference object ref_object_name = GSO_dict[ref_object.asset_id] ref_location = ref_object.position # random choose two location LOC_SET = ['front', 'behind', 'left', 'right', 'on'] # LOC_SET = ['further right', 'further left', 'further away', 'closer'] ref_location1, ref_location2 = random.sample(LOC_SET, 2) # 1st print('Generate the first scene.') # object_id = rng.choice(active_split) object_id = object_id_list[-1] obj = gso.create(asset_id=object_id) scale = rng.uniform(FLAGS.smallest_scale, FLAGS.largest_scale) obj.scale = scale / np.max(obj.bounds[1] - obj.bounds[0]) obj.metadata["scale"] = scale new_object_name = GSO_dict[obj.asset_id] print('Add new object {}'.format(new_object_name)) scene = add_new_obj(scene, obj, ref_location1, ref_object, rng, max_trails=500) if scene is None: exit() frame = renderer.render_still() os.makedirs(output_dir/'{}'.format(FLAGS.generate_idx), exist_ok=True) kb.write_png(frame["rgba"], output_dir/"{}/image0.png".format(FLAGS.generate_idx)) caption_1 = gen_caption(new_object_name, obj.metadata["scale"], ref_object_name, ref_object.metadata["scale"], ref_location1) print(caption_1) # save meta ann object_state_save_dict[i+1] = {'object_id': object_id, 'object_scale': obj.scale, 'object_pos': obj.position, 'object_quaternion': obj.quaternion, 'object_bounds': obj.bounds} # import json # json.dump(object_state_save_dict, open(output_dir/'{}/meta_ann1.json'.format(FLAGS.generate_idx), 'w')) # np.save(output_dir/'{}/meta_ann1.npy'.format(FLAGS.generate_idx), object_state_save_dict) # renderer.save_state(output_dir/'{}/image1.blend'.format(FLAGS.generate_idx)) # 2nd print('Generate the second scene.') # delete the last object to generate the second frame # import pdb; pdb.set_trace() # scene.remove(obj) # scene= add_new_obj(scene, obj, ref_location2, ref_object, rng, max_trails=100) ref_obj_pos = ref_object.position ref_obj_z_up = get_obj_z_up(ref_object.bounds, ref_object.scale) new_obj_pos = get_new_pos(obj.bounds, obj.scale, ref_location2, ref_obj_pos, ref_obj_z_up, ref_object, rng) obj.position = new_obj_pos max_trails=500 trails = 0 while not check_ok(obj, obj.position, SPAWN_REGION_OBJ): trails += 1 obj.position = get_new_pos(obj.bounds, obj.scale, ref_location2, ref_obj_pos, ref_obj_z_up, ref_object, rng) # obj.quaternion = random_rotation(axis="Z", rng=rng) if trails > max_trails: print('cannot put the object, break') shutil.rmtree(output_dir/'{}'.format(FLAGS.generate_idx)) exit() print('try {} times'.format(trails)) frame = renderer.render_still() kb.write_png(frame["rgba"], output_dir/"{}/image1.png".format(FLAGS.generate_idx)) caption_2 = gen_caption(new_object_name, obj.metadata["scale"], ref_object_name, ref_object.metadata["scale"], ref_location2) print(caption_2) # save meta ann object_state_save_dict[i+1] = {'object_id': object_id, 'object_scale': obj.scale, 'object_pos': obj.position, 'object_quaternion': obj.quaternion, 'object_bounds': obj.bounds} # import json # json.dump(object_state_save_dict, open(output_dir/'{}/meta_ann2.json'.format(FLAGS.generate_idx), 'w')) # np.save(output_dir/'{}/meta_ann2.npy'.format(FLAGS.generate_idx), object_state_save_dict) # renderer.save_state(output_dir/'{}/image2.blend'.format(FLAGS.generate_idx)) # save json # local_ann = {'image0':"{}/image0.png".format(FLAGS.generate_idx), 'caption0':caption_1, # 'image1':"{}/image1.png".format(FLAGS.generate_idx), 'caption1':caption_2, # 'ann_path':"{}/ann.json".format(FLAGS.generate_idx), # 'obj_num':num_objects+1} # json.dump(local_ann, open("{}/{}/ann.json".format(str(output_dir), FLAGS.generate_idx), 'w')) # import pdb; pdb.set_trace() # if not os.path.exists("{}/global_ann.json".format(str(output_dir))): # json.dump([], open("{}/global_ann.json".format(str(output_dir)), 'w')) # with open("{}/global_ann.json".format(str(output_dir)), 'r') as f: # old_data = json.load(f) # old_data.append(local_ann) # with open("{}/global_ann.json".format(str(output_dir)), "w") as f: # json.dump(old_data, f) local_ann = [{ 'input': dataset_dir(DATASET_TYPE) + "{}/image0.png".format(FLAGS.generate_idx), 'output': dataset_dir(DATASET_TYPE) + "{}/image1.png".format(FLAGS.generate_idx), 'instruction': caption_2, }, { 'input': dataset_dir(DATASET_TYPE) + "{}/image1.png".format(FLAGS.generate_idx), 'output': dataset_dir(DATASET_TYPE) + "{}/image0.png".format(FLAGS.generate_idx), 'instruction': caption_1, } ] save_scene_instruction(f"{output_dir}/eq_kubric_{DATASET_TYPE}.json", local_ann, DATASET_TYPE, FLAGS.generate_idx) kb.done()