コード例 #1
0
    def run(self):
        """ Generate room using COCO_TDW dataset """
        objects_in_scene = 15
        object_ids = []
        # Get Category-Object mapping
        TDW_COCO_models = TDW_relationships.get_COCO_TDW_mapping()
        # print("TDWCOCO:", TDW_COCO_models)
        # print("KEYS:", TDW_COCO_models.keys())

        # Gets COCO categories co-occurring in a scene
        # +5 is for dealing with failed object insertion attempts
        COCO_configurations = msCOCO_matrix.get_max_co_occurrence(5, int(objects_in_scene + 5))
        configuration_1 = COCO_configurations[0]
        print("Config 1:", configuration_1)
        # TDW models/objects
        objects = []
        for COCO_object in configuration_1:
            print(COCO_object)
            print(COCO_object.split())
            if len(COCO_object.split()) > 1:
                COCO_object = COCO_object.split()[-1]
                print(COCO_object)
            # Check if COCO category is a key in the COCO-TDW mapping
            if COCO_object in TDW_COCO_models.keys():
                # Gets random TDW model (from COCO-to-TDW map) based on COCO category key
                print(TDW_COCO_models[COCO_object])
                model = TDW_COCO_models[COCO_object][random.randint(0, len(TDW_COCO_models[COCO_object]) - 1)]
                objects.append(model)

        print("COCO to TDW objects:", objects)
        # print(len(objects))

        # Stores object categories that other objects can be placed upon (e.g. table, chair, couch, bed)
        surface_properties_list = TDW_COCO_models['table'] + TDW_COCO_models['chair'] + \
                                  TDW_COCO_models['bed'] + TDW_COCO_models['couch'] + \
                                  TDW_COCO_models['bench'] + TDW_COCO_models['refrigerator']
        surface_categories = []
        for surface_properties in surface_properties_list:
            surface_categories.append(surface_properties[0])

        print("Surface Categories:", surface_categories)

        # Stores the actual surface object instances/ids alongside number of objects on the surface
        surface_object_ids = {}

        self.start()
        positions_list = []  # Stores current model locations and radii
        scene_dimensions = []  # Store scene/environment dimensions
        init_setup_commands = [{"$type": "set_screen_size",
                                "width": 640,
                                "height": 481},
                               {"$type": "set_render_quality",
                                "render_quality": 1}]
        self.communicate(init_setup_commands)

        scene_lib = SceneLibrarian()
        # Disable physics when adding in new objects (objects float)
        self.communicate({"$type": "simulate_physics",
                          "value": False})

        for scene in scenes[1:]:
            # Load in scene
            # print("Scene", scene[0])
            if scene[3] == "interior" and scene[0] == "box_room_2018":
                self.start()
                scene_record = scene_lib.get_record(scene[0])
                self.communicate({"$type": "add_scene",
                                  "name": scene_record.name,
                                  "url": scene_record.get_url()})

                # Gets dimensions of environments (e.g. inside, outside) in the scene
                # This command returns environment data in the form of a list of serialized byte arrays
                scene_bytes = self.communicate({"$type": "send_environments",
                                                "frequency": "once"})

                # Iterating through data and parsing byte array
                # Ignoring the last element (the frame count)
                for b in scene_bytes[:-1]:
                    e = Environments(b)
                    for i in range(e.get_num()):
                        center = e.get_center(i)
                        bounds = e.get_bounds(i)
                        env_id = e.get_id(i)
                    scene_dimensions = [center, bounds, env_id]  # Center, bounds are tuples

                # Must come before set_pass_masks
                avatar_position = TDWUtils.array_to_vector3([0.9 * scene_dimensions[1][0] / 2,
                                                             scene_dimensions[1][1] / 2,
                                                             0])
                # print("Avatar Position:", avatar_position)
                self.communicate(TDWUtils.create_avatar(avatar_id="avatar",
                                                        position=avatar_position,
                                                        look_at={"x": 0,
                                                                 "y": scene_dimensions[0][1] / 2,
                                                                 "z": 0}))
                # Set collision mode
                self.communicate({"$type": "set_avatar_collision_detection_mode",
                                  "mode": "continuous_speculative",
                                  "avatar_id": "avatar"})

                # Alter FOV
                self.communicate({"$type": "set_field_of_view",
                                  "field_of_view": 80,
                                  "avatar_id": "avatar"})

                # # Gets rid of header (Model: Category)
                # objects = TDW_COCO_models[1:]
                # random.shuffle(objects)
                obj_count = 0
                obj_overlaps = 0  # Number of failed attempts to place object due to over-dense objects area
                while obj_count < objects_in_scene and obj_overlaps < 5:
                    # Handles if object has been added to a flat surface
                    added_to_surface = False
                    print("Object COUNT:", obj_count)
                    # Need to have random position for Bounds Data to return meaningful info
                    valid_obj_pos = {"x": random.uniform(-1 * scene_dimensions[1][0] / 2,
                                                         0.5 * scene_dimensions[1][0] / 2),
                                     "y": scene_dimensions[1][1] / 4,
                                     "z": random.uniform(-0.9 * scene_dimensions[1][2] / 2,
                                                         0.9 * scene_dimensions[1][2] / 2)}
                    print("First random position")
                    # Add in the object at random position
                    # Object will later be removed or updated accordingly after performing collision calculations
                    record = ModelLibrarian(library="models_full.json").get_record(objects[obj_count][0])
                    print("Record gotten")
                    print(objects[obj_count][0])
                    o_id = self.communicate({"$type": "add_object",
                                             "name": objects[obj_count][0],
                                             "url": record.get_url(),
                                             "scale_factor": record.scale_factor,
                                             "position": valid_obj_pos,
                                             "rotation": TDWUtils.VECTOR3_ZERO,
                                             "category": record.wcategory,
                                             "id": obj_count})

                    print("Random first add")

                    # Returns bound data for added object
                    bounds_data = self.communicate({"$type": "send_bounds",
                                                    "frequency": "once"})

                    print("Bounds returned")

                    # Appends object, with information on position and obj_radius, to positions_list
                    # Length of buffer array should be 1
                    # print("Bounds Data:", bounds_data)
                    for b in bounds_data[:-1]:
                        # print("Buffer Loop:", b)
                        b_id = OutputData.get_data_type_id(b)
                        if b_id == "boun":
                            # print("BOUNDS")
                            o = Bounds(b)
                            # print("# of Objects:", o.get_num())
                            # print("# of Failed Attempts:", obj_overlaps)
                            # print("Buffer Array:", b)
                            # print("Bounds Object:", o)
                            for i in range(o.get_num()):
                                print("Object ID:", o.get_id(i))
                                print("obj_count:", obj_count)
                                print("Object:", objects[obj_count][0], "Category:", objects[obj_count][1])
                                # print("Object Center:", o.get_center(i))
                                # Only want to compute valid_position for object we are about to add
                                # Skip any computation if this is not the case
                                if o.get_id(i) != obj_count:
                                    continue
                                # Useful for detecting if object fits in environment
                                # print("Calculating if object fits in environment")
                                width = distance.euclidean(o.get_left(i), o.get_right(i))
                                depth = distance.euclidean(o.get_front(i), o.get_back(i))
                                height = distance.euclidean(o.get_top(i), o.get_bottom(i))
                                # print("Width:", width)
                                # print("Depth:", depth)
                                # ("Height:", height)

                                # Useful for avoiding object overlap
                                # print("Calculating Object Bounds")
                                center_to_top = distance.euclidean(o.get_center(i), o.get_top(i))
                                center_to_bottom = distance.euclidean(o.get_center(i), o.get_bottom(i))
                                center_to_left = distance.euclidean(o.get_center(i), o.get_left(i))
                                center_to_right = distance.euclidean(o.get_center(i), o.get_right(i))
                                center_to_front = distance.euclidean(o.get_center(i), o.get_front(i))
                                center_to_back = distance.euclidean(o.get_center(i), o.get_back(i))
                                # Max object radius (center to diagonal of bounding box)
                                obj_radius = \
                                    max(math.sqrt(center_to_top ** 2 + center_to_left ** 2 + center_to_front ** 2),
                                        math.sqrt(center_to_top ** 2 + center_to_right ** 2 + center_to_front ** 2),
                                        math.sqrt(center_to_top ** 2 + center_to_left ** 2 + center_to_back ** 2),
                                        math.sqrt(center_to_top ** 2 + center_to_right ** 2 + center_to_back ** 2),
                                        math.sqrt(center_to_bottom ** 2 + center_to_left ** 2 + center_to_front ** 2),
                                        math.sqrt(center_to_bottom ** 2 + center_to_right ** 2 + center_to_front ** 2),
                                        math.sqrt(center_to_bottom ** 2 + center_to_left ** 2 + center_to_back ** 2),
                                        math.sqrt(center_to_bottom ** 2 + center_to_right ** 2 + center_to_back ** 2))

                                # print("Obj_Radius:", obj_radius)

                                # Set sweeping radius, based on scene plane dimensions
                                l_radius = random.uniform(0, min(0.5 * scene_dimensions[1][0] / 2,
                                                                 0.5 * scene_dimensions[1][2] / 2))

                                # Checking that object fits in scene viewing
                                if (width > min(0.7 * scene_dimensions[1][0], 0.7 * scene_dimensions[1][2]) or
                                        depth > min(0.7 * scene_dimensions[1][0], 0.7 * scene_dimensions[1][2]) or
                                        height > 0.7 * scene_dimensions[1][1]):

                                    print("Object does not fit in scene")
                                    self.communicate([{"$type": "send_images",
                                                       "frequency": "never"},
                                                      {"$type": "destroy_object",
                                                       "id": obj_count}])
                                    # Ensures next attempt to load in item is not the same item as before
                                    random.shuffle(objects)
                                    break

                                # Not possible to find valid object position -- too many overlapping objects
                                elif (not self._get_object_position(scene_dimensions=scene_dimensions,
                                                                    object_positions=positions_list,
                                                                    object_to_add_radius=obj_radius,
                                                                    max_tries=20,
                                                                    location_radius=l_radius)[0]):
                                    print("Could not calculate valid object location")
                                    self.communicate([{"$type": "send_images",
                                                       "frequency": "never"},
                                                      {"$type": "destroy_object",
                                                       "id": obj_count}])
                                    obj_overlaps += 1
                                    # Ensures next attempt to load in item is not the same item as before
                                    random.shuffle(objects)
                                    break

                                # Find appropriate, non-overlapping object position
                                # Reset object position to the valid position
                                else:
                                    print("Object fits in scene")
                                    # Check if object fits on table, chair, couch, etc.
                                    # Add object if it fits, place it somewhere on top of the surface
                                    for surface_id in surface_object_ids.keys():
                                        print("Surface ID:", surface_id)
                                        # Skip placement feasibility if the object is already a surface-type object
                                        # Ex. no chair on top of a table
                                        if objects[obj_count][0] in surface_categories:
                                            print("Object: %s is already a surface object" % objects[obj_count][0])
                                            break

                                        # Check how many objects are on surface
                                        if surface_object_ids[surface_id] >= 3:
                                            print("Too many objects on surface")
                                            print("From surface objects dict:", surface_object_ids[surface_id])
                                            continue

                                        surface_bounds = self.get_bounds_data(surface_id)
                                        surface_area = distance.euclidean(surface_bounds.get_left(0),
                                                                          surface_bounds.get_right(0)) * \
                                                       distance.euclidean(surface_bounds.get_front(0),
                                                                          surface_bounds.get_back(0))
                                        obj_area = width * height
                                        if obj_area < surface_area:
                                            s_center_to_top = distance.euclidean(surface_bounds.get_center(0),
                                                                                 surface_bounds.get_top(0))
                                            s_center_to_bottom = distance.euclidean(surface_bounds.get_center(0),
                                                                                    surface_bounds.get_bottom(0))
                                            s_center_to_left = distance.euclidean(surface_bounds.get_center(0),
                                                                                  surface_bounds.get_left(0))
                                            s_center_to_right = distance.euclidean(surface_bounds.get_center(0),
                                                                                   surface_bounds.get_right(0))
                                            s_center_to_front = distance.euclidean(surface_bounds.get_center(0),
                                                                                   surface_bounds.get_front(0))
                                            s_center_to_back = distance.euclidean(surface_bounds.get_center(0),
                                                                                  surface_bounds.get_back(0))

                                            surface_radius = \
                                                max(math.sqrt(
                                                    s_center_to_top ** 2 + s_center_to_left ** 2 + s_center_to_front ** 2),
                                                    math.sqrt(
                                                        s_center_to_top ** 2 + s_center_to_right ** 2 + s_center_to_front ** 2),
                                                    math.sqrt(
                                                        s_center_to_top ** 2 + s_center_to_left ** 2 + s_center_to_back ** 2),
                                                    math.sqrt(
                                                        s_center_to_top ** 2 + s_center_to_right ** 2 + s_center_to_back ** 2),
                                                    math.sqrt(
                                                        s_center_to_bottom ** 2 + s_center_to_left ** 2 + s_center_to_front ** 2),
                                                    math.sqrt(
                                                        s_center_to_bottom ** 2 + s_center_to_right ** 2 + s_center_to_front ** 2),
                                                    math.sqrt(
                                                        s_center_to_bottom ** 2 + s_center_to_left ** 2 + s_center_to_back ** 2),
                                                    math.sqrt(
                                                        s_center_to_bottom ** 2 + s_center_to_right ** 2 + s_center_to_back ** 2))

                                            print("Surface-type object")
                                            self.communicate({"$type": "destroy_object",
                                                              "id": obj_count})

                                            # Adding the object to the top of the surface
                                            on_pos = surface_bounds.get_top(0)
                                            on_y = on_pos[1]
                                            on_pos = TDWUtils.get_random_point_in_circle(np.array(on_pos),
                                                                                         0.7 * surface_radius)
                                            on_pos[1] = on_y
                                            on_pos = TDWUtils.array_to_vector3(on_pos)
                                            on_rot = {"x": 0, "y": random.uniform(-45, 45), "z": 0}
                                            # Add the object.
                                            print("Model Name on Surface:", objects[obj_count][0])
                                            record = ModelLibrarian(library="models_full.json").get_record(
                                                objects[obj_count][0])
                                            on_id = self.communicate({"$type": "add_object",
                                                                      "name": objects[obj_count][0],
                                                                      "url": record.get_url(),
                                                                      "scale_factor": record.scale_factor,
                                                                      "position": on_pos,
                                                                      "rotation": on_rot,
                                                                      "category": record.wcategory,
                                                                      "id": obj_count})
                                            obj_count += 1
                                            surface_object_ids[surface_id] += 1
                                            object_ids.append(obj_count)
                                            print("Object added on top of surface")
                                            added_to_surface = True
                                            # Breaking out of surface objects loop
                                            break

                                    if added_to_surface:
                                        print("Breaking out of object loop")
                                        # Breaking out of object loop
                                        break

                                    print("Post-surface")

                                    valid_obj_pos = self._get_object_position(scene_dimensions=scene_dimensions,
                                                                              object_positions=positions_list,
                                                                              object_to_add_radius=obj_radius,
                                                                              max_tries=20,
                                                                              location_radius=l_radius)[1]
                                    print("Position calculated")
                                    positions_list.append(ObjectPosition(valid_obj_pos, obj_radius))
                                    self.communicate([{"$type": "send_images",
                                                       "frequency": "never"},
                                                      {"$type": "destroy_object",
                                                       "id": obj_count}])
                                    added_object_id = self.communicate({"$type": "add_object",
                                                                        "name": objects[obj_count][0],
                                                                        "url": record.get_url(),
                                                                        "scale_factor": record.scale_factor,
                                                                        "position": valid_obj_pos,
                                                                        "rotation": {"x": 0, "y": 0, "z": 0},
                                                                        "category": record.wcategory,
                                                                        "id": obj_count})
                                    # print("Object ID:", added_object_id)
                                    print("Regular object add")
                                    object_ids.append(added_object_id)
                                    # If TDW model belongs to surface categories, store id_information
                                    if objects[obj_count][0] in surface_categories:
                                        surface_object_ids[obj_count] = 0
                                    # Rotate the object randomly
                                    print("Rotating object")
                                    self.communicate({"$type": "rotate_object_by",
                                                      "angle": random.uniform(-45, 45),
                                                      "axis": "yaw",
                                                      "id": obj_count,
                                                      "is_world": True})

                                     # Minimal rotating for position differences
                                     # Don't rotate the object if doing so will result in overlap into scene
                                     if not (o.get_bottom(i)[1] < 0 or o.get_top(i)[1] > 0.9 * scene_dimensions[1][1]):
                                         pitch_angle = random.uniform(-45, 45)
                                         self.communicate({"$type": "rotate_object_by",
                                                           "angle": pitch_angle,
                                                           "axis": "pitch",
                                                           "id": obj_count,
                                                           "is_world": True})
                                         roll_angle = random.uniform(-45, 45)
                                         self.communicate({"$type": "rotate_object_by",
                                                           "angle": roll_angle,
                                                           "axis": "roll",
                                                           "id": obj_count,
                                    
                                                           "is_world": True})
                                     # Don't need this for just changing positions
                                     # Setting random materials/textures
                                     # Looping through sub-objects and materials
                                     sub_count = 0
                                     for sub_object in record.substructure:
                                         # Loop through materials in sub-objects
                                         for j in range(len(sub_object)):
                                             # Get random material and load in
                                             material = random.choice(materials[1:])
                                             self.load_material(material)
                                             print("Material loaded")
                                    
                                             # Set random material on material of sub-object
                                             self.communicate({"$type": "set_visual_material",
                                                               "material_index": j,
                                                               "material_name": material[0],
                                                               "object_name": sub_object['name'],
                                                               "id": obj_count})
                                             print("Material set")
                                             sub_count += 1
                                             if sub_count > 10:
                                                 break
                                         break

                                    print("Updating count")
                                    obj_count += 1
                                    print("Breaking out of object_id loop")
                                    break

                            # Break out of buffer loop
                            print("Breaking out of buffer loop")
                            break

                    # Move onto next iteration of while loop (next object to load in)
                    print("Object added - next while loop iteration")
                    continue

                # for i in range(200):
                #     self.communicate({"$type": "simulate_physics",
                #                       "value": False})

                # Enable image capture
                self.communicate({"$type": "set_pass_masks",
                                  "avatar_id": "avatar",
                                  "pass_masks": ["_img", "_id"]})

                self.communicate({"$type": "send_images",
                                  "frequency": "always"})

                # Capture scene
                # NOTE: THESE SCENES GET REPLACED IN THE TARGET DIRECTORY
                scene_data = self.communicate({"$type": "look_at_position",
                                               "avatar_id": "avatar",
                                               "position": {"x": 0,
                                                            "y": scene_dimensions[0][1] / 2,
                                                            "z": 0}})
                images = Images(scene_data[0])
                TDWUtils.save_images(images, TDWUtils.zero_padding(i), output_directory=path)
                print("Object ids:", object_ids)
コード例 #2
0
    def run(self):
        self.start()
        positions_list = []  # Stores current model locations and radii
        scene_dimensions = []  # Store scene/environment dimensions
        init_setup_commands = [{
            "$type": "set_screen_size",
            "width": 1280,
            "height": 962
        }, {
            "$type": "set_render_quality",
            "render_quality": 5
        }]
        self.communicate(init_setup_commands)

        scene_lib = SceneLibrarian()
        # Disable physics when adding in new objects (objects float)
        self.communicate({"$type": "simulate_physics", "value": False})

        for scene in scenes[1:]:
            # Load in scene
            print("Scene", scene[0])
            if scene[3] == "interior" and scene[0] == "box_room_2018":
                self.start()
                scene_record = scene_lib.get_record(scene[0])
                self.communicate({
                    "$type": "add_scene",
                    "name": scene_record.name,
                    "url": scene_record.get_url()
                })

                # Gets dimensions of environments (e.g. inside, outside) in the scene
                # This command returns environment data in the form of a list of serialized byte arrays
                scene_bytes = self.communicate({
                    "$type": "send_environments",
                    "frequency": "once"
                })

                # Iterating through data and parsing byte array
                # Ignoring the last element (the frame count)
                for b in scene_bytes[:-1]:
                    e = Environments(b)
                    for i in range(e.get_num()):
                        center = e.get_center(i)
                        bounds = e.get_bounds(i)
                        env_id = e.get_id(i)
                    scene_dimensions = [center, bounds,
                                        env_id]  # Center, bounds are tuples

                # Must come before set_pass_masks
                avatar_position = TDWUtils.array_to_vector3([
                    0.9 * scene_dimensions[1][0] / 2,
                    scene_dimensions[1][1] / 2, 0
                ])
                print("Avatar Position:", avatar_position)
                self.communicate(
                    TDWUtils.create_avatar(avatar_id="avatar",
                                           position=avatar_position,
                                           look_at={
                                               "x": 0,
                                               "y": scene_dimensions[0][1] / 2,
                                               "z": 0
                                           }))
                # Set collision mode
                self.communicate({
                    "$type": "set_avatar_collision_detection_mode",
                    "mode": "continuous_speculative",
                    "avatar_id": "avatar"
                })

                # Alter FOV
                self.communicate({
                    "$type": "set_field_of_view",
                    "field_of_view": 80,
                    "avatar_id": "avatar"
                })

                # Gets rid of header (Model: Category)
                objects = models[1:]
                random.shuffle(objects)
                obj_count = 0
                obj_overlaps = 0  # Number of failed attempts to place object due to over-dense objects area
                while obj_count < 30 and obj_overlaps < 5:
                    # Need to have random position for Bounds Data to return meaningful info
                    valid_obj_pos = {
                        "x":
                        random.uniform(-1 * scene_dimensions[1][0] / 2,
                                       0.5 * scene_dimensions[1][0] / 2),
                        "y":
                        scene_dimensions[1][1] / 4,
                        "z":
                        random.uniform(-0.9 * scene_dimensions[1][2] / 2,
                                       0.9 * scene_dimensions[1][2] / 2)
                    }

                    # Add in the object at random position
                    # Object will later be removed or updated accordingly after performing collision calculations
                    record = ModelLibrarian(
                        library="models_full.json").get_record(
                            objects[obj_count][0])
                    self.communicate({
                        "$type": "add_object",
                        "name": objects[obj_count][0],
                        "url": record.get_url(),
                        "scale_factor": record.scale_factor,
                        "position": valid_obj_pos,
                        "rotation": {
                            "x": 0,
                            "y": 0,
                            "z": 0
                        },
                        "category": record.wcategory,
                        "id": obj_count
                    })

                    # Returns bound data for added object
                    bounds_data = self.communicate({
                        "$type": "send_bounds",
                        "frequency": "once"
                    })

                    # Appends object, with information on position and obj_radius, to positions_list
                    # Length of buffer array should be 1
                    print("Bounds Data:", bounds_data)
                    for b in bounds_data[:-1]:
                        print("Buffer Loop:", b)
                        b_id = OutputData.get_data_type_id(b)
                        if b_id == "boun":
                            print("BOUNDS")
                            o = Bounds(b)
                            print("# of Objects:", o.get_num())
                            print("# of Failed Attempts:", obj_overlaps)
                            print("Buffer Array:", b)
                            print("Bounds Object:", o)
                            for i in range(o.get_num()):
                                print("Object ID:", o.get_id(i))
                                print("obj_count:", obj_count)
                                print("Object:", objects[obj_count][0],
                                      "Category:", objects[obj_count][1])
                                print("Object Center:", o.get_center(i))
                                # Only want to compute valid_position for object we are about to add
                                # Skip any computation if this is not the case
                                if o.get_id(i) != obj_count:
                                    continue
                                # Useful for detecting if object fits in environment
                                print(
                                    "Calculating if object fits in environment"
                                )
                                width = distance.euclidean(
                                    o.get_left(i), o.get_right(i))
                                depth = distance.euclidean(
                                    o.get_front(i), o.get_back(i))
                                height = distance.euclidean(
                                    o.get_top(i), o.get_bottom(i))
                                print("Width:", width)
                                print("Depth:", depth)
                                print("Height:", height)

                                # Useful for avoiding object overlap
                                print("Calculating Object Bounds")
                                center_to_top = distance.euclidean(
                                    o.get_center(i), o.get_top(i))
                                center_to_bottom = distance.euclidean(
                                    o.get_center(i), o.get_bottom(i))
                                center_to_left = distance.euclidean(
                                    o.get_center(i), o.get_left(i))
                                center_to_right = distance.euclidean(
                                    o.get_center(i), o.get_right(i))
                                center_to_front = distance.euclidean(
                                    o.get_center(i), o.get_front(i))
                                center_to_back = distance.euclidean(
                                    o.get_center(i), o.get_back(i))
                                # Max object radius (center to diagonal of bounding box)
                                obj_radius = \
                                    max(math.sqrt(center_to_top ** 2 + center_to_left ** 2 + center_to_front ** 2),
                                        math.sqrt(center_to_top ** 2 + center_to_right ** 2 + center_to_front ** 2),
                                        math.sqrt(center_to_top ** 2 + center_to_left ** 2 + center_to_back ** 2),
                                        math.sqrt(center_to_top ** 2 + center_to_right ** 2 + center_to_back ** 2),
                                        math.sqrt(center_to_bottom ** 2 + center_to_left ** 2 + center_to_front ** 2),
                                        math.sqrt(center_to_bottom ** 2 + center_to_right ** 2 + center_to_front ** 2),
                                        math.sqrt(center_to_bottom ** 2 + center_to_left ** 2 + center_to_back ** 2),
                                        math.sqrt(center_to_bottom ** 2 + center_to_right ** 2 + center_to_back ** 2))

                                print("Obj_Radius:", obj_radius)

                                # Set sweeping radius, based on scene plane dimensions
                                l_radius = random.uniform(
                                    0,
                                    min(0.9 * scene_dimensions[1][0] / 2,
                                        0.9 * scene_dimensions[1][2] / 2))

                                # Checking that object fits in scene viewing
                                if (width > min(0.7 * scene_dimensions[1][0],
                                                0.7 * scene_dimensions[1][2])
                                        or depth > min(
                                            0.7 * scene_dimensions[1][0],
                                            0.7 * scene_dimensions[1][2]) or
                                        height > 0.7 * scene_dimensions[1][1]):

                                    print("Object does not fit in scene")
                                    self.communicate([{
                                        "$type": "send_images",
                                        "frequency": "never"
                                    }, {
                                        "$type": "destroy_object",
                                        "id": obj_count
                                    }])
                                    # Ensures next attempt to load in item is not the same item as before
                                    random.shuffle(objects)
                                    break

                                # Not possible to find valid object position -- too many overlapping objects
                                elif (not self._get_object_position(
                                        scene_dimensions=scene_dimensions,
                                        object_positions=positions_list,
                                        object_to_add_radius=obj_radius,
                                        max_tries=20,
                                        location_radius=l_radius)[0]):
                                    print(
                                        "Could not calculate valid object location"
                                    )
                                    self.communicate([{
                                        "$type": "send_images",
                                        "frequency": "never"
                                    }, {
                                        "$type": "destroy_object",
                                        "id": obj_count
                                    }])
                                    obj_overlaps += 1
                                    # Ensures next attempt to load in item is not the same item as before
                                    random.shuffle(objects)
                                    break

                                # Find appropriate, non-overlapping object position
                                # Reset object position to the valid position
                                else:
                                    print("Object fits in scene")
                                    valid_obj_pos = self._get_object_position(
                                        scene_dimensions=scene_dimensions,
                                        object_positions=positions_list,
                                        object_to_add_radius=obj_radius,
                                        max_tries=20,
                                        location_radius=l_radius)[1]
                                    print("Position calculated")
                                    positions_list.append(
                                        ObjectPosition(valid_obj_pos,
                                                       obj_radius))
                                    self.communicate([{
                                        "$type": "send_images",
                                        "frequency": "never"
                                    }, {
                                        "$type": "destroy_object",
                                        "id": obj_count
                                    }])
                                    print("Object ready to reset")
                                    self.communicate([{
                                        "$type": "send_images",
                                        "frequency": "never"
                                    }, {
                                        "$type":
                                        "add_object",
                                        "name":
                                        objects[obj_count][0],
                                        "url":
                                        record.get_url(),
                                        "scale_factor":
                                        record.scale_factor,
                                        "position":
                                        valid_obj_pos,
                                        "rotation": {
                                            "x": 0,
                                            "y": 0,
                                            "z": 0
                                        },
                                        "category":
                                        record.wcategory,
                                        "id":
                                        obj_count
                                    }])
                                    print("Object reset")

                                    # Rotate the object randomly
                                    print("Rotating object")
                                    self.communicate({
                                        "$type":
                                        "rotate_object_by",
                                        "angle":
                                        random.uniform(-45, 45),
                                        "axis":
                                        "yaw",
                                        "id":
                                        obj_count,
                                        "is_world":
                                        True
                                    })

                                    # Don't rotate the object if doing so will result in overlap into scene
                                    if not (o.get_bottom(i)[1] < 0
                                            or o.get_top(i)[1] >
                                            0.9 * scene_dimensions[1][1]):
                                        pitch_angle = random.uniform(-45, 45)
                                        self.communicate({
                                            "$type": "rotate_object_by",
                                            "angle": pitch_angle,
                                            "axis": "pitch",
                                            "id": obj_count,
                                            "is_world": True
                                        })
                                        roll_angle = random.uniform(-45, 45)
                                        self.communicate({
                                            "$type": "rotate_object_by",
                                            "angle": roll_angle,
                                            "axis": "roll",
                                            "id": obj_count,
                                            "is_world": True
                                        })

                                    # Setting random materials/textures
                                    # Looping through sub-objects and materials
                                    sub_count = 0
                                    for sub_object in record.substructure:
                                        # Loop through materials in sub-objects
                                        for j in range(len(sub_object)):
                                            # Get random material and load in
                                            material = random.choice(
                                                materials[1:])
                                            self.load_material(material)
                                            print("Material loaded")

                                            # Set random material on material of sub-object
                                            self.communicate({
                                                "$type":
                                                "set_visual_material",
                                                "material_index":
                                                j,
                                                "material_name":
                                                material[0],
                                                "object_name":
                                                sub_object['name'],
                                                "id":
                                                obj_count
                                            })
                                            print("Material set")
                                            sub_count += 1
                                            if sub_count > 10:
                                                break
                                        break

                                    print("Updating count")
                                    obj_count += 1
                                    print("Breaking out of object_id loop")
                                    break

                            # Break out of buffer loop
                            print("Breaking out of buffer loop")
                            break

                    # Move onto next iteration of while loop (next object to load in)
                    print("Object added - next while loop iteration")
                    continue

                # Enable image capture
                self.communicate({
                    "$type": "set_pass_masks",
                    "avatar_id": "avatar",
                    "pass_masks": ["_img", "_id"]
                })

                self.communicate({
                    "$type": "send_images",
                    "frequency": "always"
                })

                # Capture scene
                scene_data = self.communicate({
                    "$type": "look_at_position",
                    "avatar_id": "avatar",
                    "position": {
                        "x": 0,
                        "y": scene_dimensions[0][1] / 2,
                        "z": 0
                    }
                })
                images = Images(scene_data[0])
                TDWUtils.save_images(images,
                                     TDWUtils.zero_padding(i),
                                     output_directory=path)
コード例 #3
0
    def run(self) -> None:
        self.start()

        # Get IDs for the object, the table, and the avatars.
        o_id = self.get_unique_id()
        table_id = self.get_unique_id()
        table_position = {"x": 0, "y": 0, "z": 6.8}
        a = "a"

        # 1. Create the room.
        commands = [TDWUtils.create_empty_room(20, 20)]
        # 2. Add the avatar.
        commands.extend(
            TDWUtils.create_avatar(avatar_type="A_StickyMitten_Adult",
                                   avatar_id="a"))
        # 3. Add the objects. Scale the objects. Set a high mass for the table.
        # 4. Disable the avatar's cameras.
        # 5. Set the stickiness of the avatar's left mitten. Set a high drag. Rotate the head.
        # 6. Request AvatarChildrenNames data and Bounds data (this frame only).
        # 7. Strengthen the left shoulder a bit.
        commands.extend([
            self.get_add_object("jug05",
                                position={
                                    "x": -0.417,
                                    "y": 0.197,
                                    "z": 0.139
                                },
                                rotation={
                                    "x": 90,
                                    "y": 0,
                                    "z": 0
                                },
                                object_id=o_id), {
                                    "$type": "scale_object",
                                    "scale_factor": {
                                        "x": 2,
                                        "y": 2,
                                        "z": 2
                                    },
                                    "id": o_id
                                },
            self.get_add_object("small_table_green_marble",
                                position={
                                    "x": 0,
                                    "y": 0,
                                    "z": 6.8
                                },
                                rotation={
                                    "x": 0,
                                    "y": 0,
                                    "z": 0
                                },
                                object_id=table_id), {
                                    "$type": "scale_object",
                                    "scale_factor": {
                                        "x": 2,
                                        "y": 0.5,
                                        "z": 2
                                    },
                                    "id": table_id
                                },
            {
                "$type": "set_object_collision_detection_mode",
                "id": table_id,
                "mode": "continuous_dynamic"
            }, {
                "$type": "set_object_collision_detection_mode",
                "id": o_id,
                "mode": "continuous_dynamic"
            }, {
                "$type": "set_mass",
                "mass": 100,
                "id": table_id
            }, {
                "$type": "toggle_image_sensor",
                "sensor_name": "SensorContainer",
                "avatar_id": a
            }, {
                "$type": "toggle_image_sensor",
                "sensor_name": "FollowCamera",
                "avatar_id": a
            }, {
                "$type": "set_stickiness",
                "sub_mitten": "back",
                "sticky": True,
                "is_left": True,
                "avatar_id": a
            }, {
                "$type": "set_avatar_drag",
                "drag": 1000,
                "angular_drag": 1000,
                "avatar_id": a
            }, {
                "$type": "rotate_head_by",
                "axis": "pitch",
                "angle": 5
            }, {
                "$type": "send_avatar_children_names",
                "ids": [a],
                "frequency": "once"
            }, {
                "$type": "send_bounds",
                "ids": [table_id],
                "frequency": "once"
            }, {
                "$type": "adjust_joint_force_by",
                "delta": 2,
                "joint": "shoulder_left",
                "axis": "pitch"
            }
        ])
        # 7. Add a 3rd-person camera.
        commands.extend(
            TDWUtils.create_avatar(avatar_type="A_Img_Caps_Kinematic",
                                   avatar_id="c",
                                   position={
                                       "x": -3.9,
                                       "y": 2.3,
                                       "z": 4.3
                                   }))
        # 8. Request StickyMittenAvatar and Images data per-frame.
        commands.extend([{
            "$type": "set_pass_masks",
            "pass_masks": ["_img"],
            "avatar_id": self.cam_id
        }, {
            "$type": "send_avatars",
            "ids": [a],
            "frequency": "always"
        }, {
            "$type": "send_images",
            "ids": [self.cam_id],
            "frequency": "always"
        }])

        resp = self.communicate(commands)
        # Get the object ID of the left mitten, the size of the table, and the avatar's position.
        mitten_left_id = None
        table_size: Tuple[float, float, float] = (0, 0, 0)

        for r in resp[:-1]:
            r_id = OutputData.get_data_type_id(r)
            # Get the mitten ID.
            if r_id == "avcn":
                avcn = AvatarChildrenNames(r)
                for i in range(avcn.get_num_children()):
                    if avcn.get_child_name(i) == "mitten_left":
                        mitten_left_id = avcn.get_child_id(i)
            # Get the table bounds.
            elif r_id == "boun":
                boun = Bounds(r)
                for i in range(boun.get_num()):
                    if boun.get_id(i) == table_id:
                        table_size = (boun.get_right(i)[0] -
                                      boun.get_left(i)[0], boun.get_top(i)[1] -
                                      boun.get_bottom(i)[1],
                                      boun.get_front(i)[2] -
                                      boun.get_back(i)[2])
            # Get the avatar's position.
            elif r_id == "avsm":
                self.avatar_position = AvatarStickyMitten(r).get_position()

        # Pick up the object.
        # Lift up the object.
        self._bend_arm_joints([{
            "$type": "pick_up_proximity",
            "distance": 20,
            "grip": 10000,
            "is_left": True,
            "avatar_id": a
        }, {
            "$type": "rotate_head_by",
            "axis": "pitch",
            "angle": 20,
            "avatar_id": a
        }, {
            "$type": "bend_arm_joint_by",
            "angle": 25,
            "joint": "shoulder_left",
            "axis": "pitch",
            "avatar_id": a
        }, {
            "$type": "bend_arm_joint_by",
            "angle": -25,
            "joint": "shoulder_left",
            "axis": "yaw",
            "avatar_id": a
        }, {
            "$type": "bend_arm_joint_by",
            "angle": 60,
            "joint": "shoulder_left",
            "axis": "roll",
            "avatar_id": a
        }, {
            "$type": "bend_arm_joint_by",
            "angle": 100,
            "joint": "elbow_left",
            "axis": "pitch",
            "avatar_id": a
        }])
        # Allow the avatar to move again.
        self._do_frame({
            "$type": "set_avatar_drag",
            "drag": 0.125,
            "angular_drag": 1000,
            "avatar_id": a
        })

        # Move to the table.
        move_to_table = True
        # The position of the side of the table the avatar is aiming for.
        table_side_position = {
            "x": table_position["x"],
            "y": 0,
            "z": table_position["z"] - table_size[2]
        }
        while move_to_table:
            # Stop moving if we are close enough.
            if TDWUtils.get_distance(
                    table_side_position,
                    TDWUtils.array_to_vector3(self.avatar_position)) < 0.7:
                move_to_table = False
            # Keep moving forward.
            else:
                self._do_frame({
                    "$type": "move_avatar_forward_by",
                    "avatar_id": a,
                    "magnitude": 20
                })
        # Stop.
        # Allow the avatar to move again.
        self._do_frame({
            "$type": "set_avatar_drag",
            "drag": 1000,
            "angular_drag": 1000,
            "avatar_id": a
        })

        mitten_over_table = False
        target_z = table_side_position["z"] + 0.17
        # Keep lifting until the mitten is over the table.
        while not mitten_over_table:
            avsm = self._bend_arm_joints([{
                "$type": "bend_arm_joint_by",
                "angle": 15,
                "joint": "shoulder_left",
                "axis": "pitch",
                "avatar_id": a
            }, {
                "$type": "bend_arm_joint_by",
                "angle": -10,
                "joint": "elbow_left",
                "axis": "pitch",
                "avatar_id": a
            }])
            # Get the mitten.
            for i in range(avsm.get_num_body_parts()):
                if avsm.get_body_part_id(i) == mitten_left_id:
                    # Check if the mitten is over the table.
                    mitten_over_table = avsm.get_body_part_position(
                        i)[2] >= target_z

        # Drop the arm gently.
        mitten_near_table = False
        while not mitten_near_table:
            avsm = self._bend_arm_joints([{
                "$type": "bend_arm_joint_by",
                "angle": -25,
                "joint": "shoulder_left",
                "axis": "pitch",
                "avatar_id": a
            }])
            # Get the mitten.
            for i in range(avsm.get_num_body_parts()):
                if avsm.get_body_part_id(i) == mitten_left_id:
                    # Check if the mitten very close to the table surface.
                    mitten_near_table = avsm.get_body_part_position(
                        i)[1] - table_size[1] <= 0.1
        # Drop the object.
        # Allow the avatar to move again.
        self._do_frame([{
            "$type": "put_down",
            "is_left": True,
            "avatar_id": a
        }, {
            "$type": "set_avatar_drag",
            "drag": 0.125,
            "angular_drag": 1000,
            "avatar_id": a
        }])
        # Back away from the table.
        mitten_away_from_table = False
        while not mitten_away_from_table:
            avsm = self._do_frame({
                "$type": "move_avatar_forward_by",
                "avatar_id": a,
                "magnitude": -50
            })
            # Get the mitten.
            for i in range(avsm.get_num_body_parts()):
                if avsm.get_body_part_id(i) == mitten_left_id:
                    # Check if the mitten has cleared the table.
                    mitten_away_from_table = avsm.get_body_part_position(
                        i)[2] < target_z
        # Drop the arm.
        self._do_frame([{
            "$type": "rotate_head_by",
            "axis": "pitch",
            "angle": -25
        }, {
            "$type": "bend_arm_joint_to",
            "angle": 0,
            "joint": "shoulder_left",
            "axis": "pitch",
            "avatar_id": a
        }, {
            "$type": "bend_arm_joint_to",
            "angle": 0,
            "joint": "shoulder_left",
            "axis": "yaw",
            "avatar_id": a
        }, {
            "$type": "bend_arm_joint_to",
            "angle": 0,
            "joint": "shoulder_left",
            "axis": "roll",
            "avatar_id": a
        }, {
            "$type": "bend_arm_joint_to",
            "angle": 0,
            "joint": "elbow_left",
            "axis": "pitch",
            "avatar_id": a
        }])
        # Back away from the table.
        away_from_table = False
        while not away_from_table:
            self._do_frame({
                "$type": "move_avatar_forward_by",
                "avatar_id": a,
                "magnitude": -20
            })
            away_from_table = TDWUtils.get_distance(
                TDWUtils.array_to_vector3(self.avatar_position),
                table_position) > 1.8
        # Let the joints drop.
        self._bend_arm_joints([])
        self.communicate({"$type": "terminate"})
コード例 #4
0
    def trial(self, scene: Scene, record: ModelRecord, output_path: Path,
              scene_index: int) -> None:
        """
        Run a trial in a scene that has been initialized.

        :param scene: Data for the current scene.
        :param record: The model's metadata record.
        :param output_path: Write the .wav file to this path.
        :param scene_index: The scene identifier.
        """

        self.py_impact.reset(initial_amp=0.05)

        # Initialize the scene, positioning objects, furniture, etc.
        resp = self.communicate(scene.initialize_scene(self))
        center = scene.get_center(self)

        max_y = scene.get_max_y()

        # The object's initial position.
        o_x = RNG.uniform(center["x"] - 0.15, center["x"] + 0.15)
        o_y = RNG.uniform(max_y - 0.5, max_y)
        o_z = RNG.uniform(center["z"] - 0.15, center["z"] + 0.15)
        # Physics values.
        mass = self.object_info[record.name].mass + RNG.uniform(
            self.object_info[record.name].mass * -0.15,
            self.object_info[record.name].mass * 0.15)
        static_friction = RNG.uniform(0.1, 0.3)
        dynamic_friction = RNG.uniform(0.7, 0.9)
        # Angles of rotation.
        yaw = RNG.uniform(-30, 30)
        pitch = RNG.uniform(0, 45)
        roll = RNG.uniform(-45, 45)
        # The force applied to the object.
        force = RNG.uniform(0, 5)
        # The avatar's position.
        a_r = RNG.uniform(1.5, 2.2)
        a_x = center["x"] + a_r
        a_y = RNG.uniform(1.5, 3)
        a_z = center["z"] + a_r
        cam_angle_min, cam_angle_max = scene.get_camera_angles()
        theta = np.radians(RNG.uniform(cam_angle_min, cam_angle_max))
        a_x = np.cos(theta) * (a_x - center["x"]) - np.sin(theta) * (
            a_z - center["z"]) + center["x"]
        a_z = np.sin(theta) * (a_x - center["x"]) + np.cos(theta) * (
            a_z - center["z"]) + center["z"]

        o_id = 0
        # Create the object and apply a force.
        commands = [{
            "$type": "add_object",
            "name": record.name,
            "url": record.get_url(),
            "scale_factor": record.scale_factor,
            "position": {
                "x": o_x,
                "y": o_y,
                "z": o_z
            },
            "category": record.wcategory,
            "id": o_id
        }, {
            "$type": "set_mass",
            "id": o_id,
            "mass": mass
        }, {
            "$type": "set_physic_material",
            "id": o_id,
            "bounciness": self.object_info[record.name].bounciness,
            "static_friction": static_friction,
            "dynamic_friction": dynamic_friction
        }, {
            "$type": "rotate_object_by",
            "angle": yaw,
            "id": o_id,
            "axis": "yaw",
            "is_world": True
        }, {
            "$type": "rotate_object_by",
            "angle": pitch,
            "id": o_id,
            "axis": "pitch",
            "is_world": True
        }, {
            "$type": "rotate_object_by",
            "angle": roll,
            "id": o_id,
            "axis": "roll",
            "is_world": True
        }, {
            "$type": "apply_force_magnitude_to_object",
            "magnitude": force,
            "id": o_id
        }, {
            "$type": "send_rigidbodies",
            "frequency": "always"
        }, {
            "$type": "send_collisions",
            "enter": True,
            "exit": False,
            "stay": False,
            "collision_types": ["obj", "env"]
        }, {
            "$type": "send_transforms",
            "frequency": "always"
        }]
        # Parse bounds data to get the centroid of all objects currently in the scene.
        bounds = Bounds(resp[0])
        if bounds.get_num() == 0:
            look_at = {"x": center["x"], "y": 0.1, "z": center["z"]}
        else:
            centers = []
            for i in range(bounds.get_num()):
                centers.append(bounds.get_center(i))
            centers_x, centers_y, centers_z = zip(*centers)
            centers_len = len(centers_x)
            look_at = {
                "x": sum(centers_x) / centers_len,
                "y": sum(centers_y) / centers_len,
                "z": sum(centers_z) / centers_len
            }
        # Add the avatar.
        # Set the position at a given distance (r) from the center of the scene.
        # Rotate around that position to a random angle constrained by the scene's min and max angles.
        commands.extend([{
            "$type": "teleport_avatar_to",
            "position": {
                "x": a_x,
                "y": a_y,
                "z": a_z
            }
        }, {
            "$type": "look_at_position",
            "position": look_at
        }])

        # Send the commands.
        resp = self.communicate(commands)

        AudioUtils.start(output_path=output_path, until=(0, 10))

        # Loop until all objects are sleeping.
        done = False
        while not done and AudioUtils.is_recording():
            commands = []
            collisions, environment_collisions, rigidbodies = PyImpact.get_collisions(
                resp)
            # Create impact sounds from object-object collisions.
            for collision in collisions:
                if PyImpact.is_valid_collision(collision):
                    # Get the audio material and amp.
                    collider_id = collision.get_collider_id()
                    collider_material, collider_amp = self._get_object_info(
                        collider_id, Scene.OBJECT_IDS, record.name)
                    collidee_id = collision.get_collider_id()
                    collidee_material, collidee_amp = self._get_object_info(
                        collidee_id, Scene.OBJECT_IDS, record.name)
                    impact_sound_command = self.py_impact.get_impact_sound_command(
                        collision=collision,
                        rigidbodies=rigidbodies,
                        target_id=collidee_id,
                        target_amp=collidee_amp,
                        target_mat=collidee_material.name,
                        other_id=collider_id,
                        other_mat=collider_material.name,
                        other_amp=collider_amp,
                        play_audio_data=False)
                    commands.append(impact_sound_command)
            # Create impact sounds from object-environment collisions.
            for collision in environment_collisions:
                collider_id = collision.get_object_id()
                if self._get_velocity(rigidbodies, collider_id) > 0:
                    collider_material, collider_amp = self._get_object_info(
                        collider_id, Scene.OBJECT_IDS, record.name)
                    surface_material = scene.get_surface_material()
                    impact_sound_command = self.py_impact.get_impact_sound_command(
                        collision=collision,
                        rigidbodies=rigidbodies,
                        target_id=collider_id,
                        target_amp=collider_amp,
                        target_mat=collider_material.name,
                        other_id=-1,
                        other_amp=0.01,
                        other_mat=surface_material.name,
                        play_audio_data=False)
                    commands.append(impact_sound_command)
            # If there were no collisions, check for movement. If nothing is moving, the trial is done.
            if len(commands) == 0:
                transforms = AudioDataset._get_transforms(resp)
                done = True
                for i in range(rigidbodies.get_num()):
                    if self._is_moving(rigidbodies.get_id(i), transforms,
                                       rigidbodies):
                        done = False
                        break
            # Continue the trial.
            if not done:
                resp = self.communicate(commands)

        # Stop listening for anything except audio data..
        resp = self.communicate([{
            "$type": "send_rigidbodies",
            "frequency": "never"
        }, {
            "$type": "send_transforms",
            "frequency": "never"
        }, {
            "$type": "send_collisions",
            "enter": False,
            "exit": False,
            "stay": False,
            "collision_types": []
        }, {
            "$type": "send_audio_sources",
            "frequency": "always"
        }])
        # Wait for the audio to finish.
        done = False
        while not done and AudioUtils.is_recording():
            done = True
            for r in resp[:-1]:
                if OutputData.get_data_type_id(r) == "audi":
                    audio_sources = AudioSources(r)
                    for i in range(audio_sources.get_num()):
                        if audio_sources.get_is_playing(i):
                            done = False
            if not done:
                resp = self.communicate([])
        # Cleanup.
        commands = [{
            "$type": "send_audio_sources",
            "frequency": "never"
        }, {
            "$type": "destroy_object",
            "id": o_id
        }]
        for scene_object_id in Scene.OBJECT_IDS:
            commands.append({"$type": "destroy_object", "id": scene_object_id})
        self.communicate(commands)

        # Insert the trial's values into the database.
        self.db_c.execute(
            "INSERT INTO sound20k VALUES(?,?,?,?,?,?,?,?,?,?,?,?,?,?,?)",
            (output_path.name, scene_index, a_x, a_y, a_z, o_x, o_y, o_z, mass,
             static_friction, dynamic_friction, yaw, pitch, roll, force))
        self.conn.commit()
コード例 #5
0
    def __init__(self,
                 object_id: int,
                 rigidbodies: Rigidbodies,
                 segmentation_colors: SegmentationColors,
                 bounds: Bounds,
                 audio: ObjectInfo,
                 target_object: bool = False):
        """
        :param object_id: The unique ID of the object.
        :param rigidbodies: Rigidbodies output data.
        :param bounds: Bounds output data.
        :param segmentation_colors: Segmentation colors output data.
        """

        self.object_id = object_id
        self.model_name = audio.name
        self.container = self.model_name in StaticObjectInfo.CONTAINERS
        self.kinematic = self.model_name in StaticObjectInfo._KINEMATIC
        self.target_object = target_object

        self.category = ""
        # This is a sub-object of a composite object.
        if audio.library == "":
            # Get the record of the composite object.
            for k in StaticObjectInfo._COMPOSITE_OBJECTS:
                for v in StaticObjectInfo._COMPOSITE_OBJECTS[k]:
                    if v == audio.name:
                        record = TransformInitData.LIBRARIES[
                            "models_core.json"].get_record(k)
                        # Get the semantic category.
                        self.category = record.wcategory
                        break
        else:
            # Get the model record from the audio data.
            record = TransformInitData.LIBRARIES[audio.library].get_record(
                audio.name)
            # Get the semantic category.
            self.category = record.wcategory

        # Get the segmentation color.
        self.segmentation_color: Optional[np.array] = None
        for i in range(segmentation_colors.get_num()):
            if segmentation_colors.get_object_id(i) == self.object_id:
                self.segmentation_color = np.array(
                    segmentation_colors.get_object_color(i))
                break
        assert self.segmentation_color is not None, f"Segmentation color not found: {self.object_id}"

        # Get the size of the object.
        self.size = np.array([0, 0, 0])
        for i in range(bounds.get_num()):
            if bounds.get_id(i) == self.object_id:
                self.size = np.array([
                    float(
                        np.abs(bounds.get_right(i)[0] -
                               bounds.get_left(i)[0])),
                    float(
                        np.abs(bounds.get_top(i)[1] -
                               bounds.get_bottom(i)[1])),
                    float(
                        np.abs(bounds.get_front(i)[2] - bounds.get_back(i)[2]))
                ])
                break
        assert np.linalg.norm(
            self.size) > 0, f"Bounds data not found for: {self.object_id}"

        # Get the mass.
        self.mass: float = -1
        for i in range(rigidbodies.get_num()):
            if rigidbodies.get_id(i) == self.object_id:
                self.mass = rigidbodies.get_mass(i)
                break
        assert self.mass >= 0, f"Mass not found: {self.object_id}"