def display_grasps(self, object_name, gripper_name, metric_name, config=None): """ Display grasps for an object Parameters ---------- object_name : :obj:`str` Object to display gripper_name : :obj:`str` Gripper for which to display grasps metric_name : :obj:`str` Metric to color/rank grasps with config : :obj:`dict` Configuration dict for visualization. Parameters are in Other parameters. Values from self.default_config are used for keys not provided. Other Parameters ---------------- gripper_dir Directory where the grippers models and parameters are. quality_scale Range to scale quality metric values to show_gripper Whether or not to show the gripper in the visualization min_metric lowest value of metric to show grasps for max_plot_gripper Number of grasps to plot animate Whether or not to animate the displayed object """ self._check_opens() config = self._get_config(config) grippers = os.listdir(config['gripper_dir']) if gripper_name not in grippers: raise ValueError( "{} is not a valid gripper name".format(gripper_name)) gripper = gr.RobotGripper.load(gripper_name, gripper_dir=config['gripper_dir']) objects = self.dataset.object_keys if object_name not in objects: raise ValueError( "{} is not a valid object name".format(object_name)) metrics = self.dataset.available_metrics(object_name, gripper=gripper.name) if metric_name not in metrics: raise ValueError( "{} is not computed for gripper {}, object {}".format( metric_name, gripper.name, object_name)) logger.info('Displaying grasps for gripper %s on object %s' % (gripper.name, object_name)) object = self.dataset[object_name] grasps, metrics = self.dataset.sorted_grasps(object_name, metric_name, gripper=gripper.name) if len(grasps) == 0: raise RuntimeError('No grasps for gripper %s on object %s' % (gripper.name, object_name)) return low = np.min(metrics) high = np.max(metrics) if low == high: q_to_c = lambda quality: config['quality_scale'] else: q_to_c = lambda quality: config['quality_scale'] * ( quality - low) / (high - low) if config['show_gripper']: i = 0 stable_pose = self.dataset.stable_pose(object.key, 'pose_1') for grasp, metric in zip(grasps, metrics): if metric <= config['min_metric']: continue print 'Grasp %d %s=%.5f' % (grasp.id, metric_name, metric) T_obj_world = RigidTransform(from_frame='obj', to_frame='world') color = plt.get_cmap('hsv')(q_to_c(metric))[:-1] T_obj_gripper = grasp.gripper_pose(gripper) grasp = grasp.perpendicular_table(stable_pose) vis.figure() vis.gripper_on_object(gripper, grasp, object, gripper_color=(0.25, 0.25, 0.25), stable_pose=stable_pose, plot_table=False) vis.show(animate=config['animate']) i += 1 if i >= config['max_plot_gripper']: break else: i = 0 vis.figure() vis.mesh(object.mesh, style='surface') for grasp, metric in zip(grasps, metrics): if metric <= config['min_metric']: continue print 'Grasp %d %s=%.5f' % (grasp.id, metric_name, metric) T_obj_world = RigidTransform(from_frame='obj', to_frame='world') color = plt.get_cmap('hsv')(q_to_c(metric))[:-1] T_obj_gripper = grasp.gripper_pose(gripper) vis.grasp(grasp, grasp_axis_color=color, endpoint_color=color) i += 1 if i >= config['max_plot_gripper']: break vis.show(animate=config['animate'])
def generate_gqcnn_dataset(dataset_path, database, target_object_keys, env_rv_params, gripper_name, config): """ Generates a GQ-CNN TensorDataset for training models with new grippers, quality metrics, objects, and cameras. Parameters ---------- dataset_path : str path to save the dataset to database : :obj:`Hdf5Database` Dex-Net database containing the 3D meshes, grasps, and grasp metrics target_object_keys : :obj:`OrderedDict` dictionary mapping dataset names to target objects (either 'all' or a list of specific object keys) env_rv_params : :obj:`OrderedDict` parameters of the camera and object random variables used in sampling (see meshpy_berkeley.UniformPlanarWorksurfaceImageRandomVariable for more info) gripper_name : str name of the gripper to use config : :obj:`autolab_core.YamlConfig` other parameters for dataset generation Notes ----- Required parameters of config are specified in Other Parameters Other Parameters ---------------- images_per_stable_pose : int number of object and camera poses to sample for each stable pose stable_pose_min_p : float minimum probability of occurrence for a stable pose to be used in data generation (used to prune bad stable poses gqcnn/crop_width : int width, in pixels, of crop region around each grasp center, before resize (changes the size of the region seen by the GQ-CNN) gqcnn/crop_height : int height, in pixels, of crop region around each grasp center, before resize (changes the size of the region seen by the GQ-CNN) gqcnn/final_width : int width, in pixels, of final transformed grasp image for input to the GQ-CNN (defaults to 32) gqcnn/final_height : int height, in pixels, of final transformed grasp image for input to the GQ-CNN (defaults to 32) table_alignment/max_approach_table_angle : float max angle between the grasp axis and the table normal when the grasp approach is maximally aligned with the table normal table_alignment/max_approach_offset : float max deviation from perpendicular approach direction to use in grasp collision checking table_alignment/num_approach_offset_samples : int number of approach samples to use in collision checking collision_checking/table_offset : float max allowable interpenetration between the gripper and table to be considered collision free collision_checking/table_mesh_filename : str path to a table mesh for collision checking (default data/meshes/table.obj) collision_checking/approach_dist : float distance, in meters, between the approach pose and final grasp pose along the grasp axis collision_checking/delta_approach : float amount, in meters, to discretize the straight-line path from the gripper approach pose to the final grasp pose tensors/datapoints_per_file : int number of datapoints to store in each unique tensor file on disk tensors/fields : :obj:`dict` dictionary mapping field names to dictionaries specifying the data type, height, width, and number of channels for each tensor debug : bool True (or 1) if the random seed should be set to enforce deterministic behavior, False (0) otherwise vis/candidate_grasps : bool True (or 1) if the collision free candidate grasps should be displayed in 3D (for debugging) vis/rendered_images : bool True (or 1) if the rendered images for each stable pose should be displayed (for debugging) vis/grasp_images : bool True (or 1) if the transformed grasp images should be displayed (for debugging) """ # read data gen params output_dir = dataset_path gripper = RobotGripper.load(gripper_name) image_samples_per_stable_pose = config['images_per_stable_pose'] stable_pose_min_p = config['stable_pose_min_p'] # read gqcnn params gqcnn_params = config['gqcnn'] im_crop_height = gqcnn_params['crop_height'] im_crop_width = gqcnn_params['crop_width'] im_final_height = gqcnn_params['final_height'] im_final_width = gqcnn_params['final_width'] cx_crop = float(im_crop_width) / 2 cy_crop = float(im_crop_height) / 2 # open database dataset_names = target_object_keys.keys() datasets = [database.dataset(dn) for dn in dataset_names] # set target objects for dataset in datasets: if target_object_keys[dataset.name] == 'all': target_object_keys[dataset.name] = dataset.object_keys # setup grasp params table_alignment_params = config['table_alignment'] min_grasp_approach_offset = -np.deg2rad( table_alignment_params['max_approach_offset']) max_grasp_approach_offset = np.deg2rad( table_alignment_params['max_approach_offset']) max_grasp_approach_table_angle = np.deg2rad( table_alignment_params['max_approach_table_angle']) num_grasp_approach_samples = table_alignment_params[ 'num_approach_offset_samples'] phi_offsets = [] if max_grasp_approach_offset == min_grasp_approach_offset: phi_inc = 1 elif num_grasp_approach_samples == 1: phi_inc = max_grasp_approach_offset - min_grasp_approach_offset + 1 else: phi_inc = (max_grasp_approach_offset - min_grasp_approach_offset) / ( num_grasp_approach_samples - 1) phi = min_grasp_approach_offset while phi <= max_grasp_approach_offset: phi_offsets.append(phi) phi += phi_inc # setup collision checking coll_check_params = config['collision_checking'] approach_dist = coll_check_params['approach_dist'] delta_approach = coll_check_params['delta_approach'] table_offset = coll_check_params['table_offset'] table_mesh_filename = coll_check_params['table_mesh_filename'] if not os.path.isabs(table_mesh_filename): table_mesh_filename = os.path.join( os.path.dirname(os.path.realpath(__file__)), '..', table_mesh_filename) table_mesh = ObjFile(table_mesh_filename).read() # set tensor dataset config tensor_config = config['tensors'] tensor_config['fields']['depth_ims_tf_table']['height'] = im_final_height tensor_config['fields']['depth_ims_tf_table']['width'] = im_final_width tensor_config['fields']['obj_masks']['height'] = im_final_height tensor_config['fields']['obj_masks']['width'] = im_final_width # add available metrics (assuming same are computed for all objects) metric_names = [] dataset = datasets[0] obj_keys = dataset.object_keys if len(obj_keys) == 0: raise ValueError('No valid objects in dataset %s' % (dataset.name)) obj = dataset[obj_keys[0]] grasps = dataset.grasps(obj.key, gripper=gripper.name) grasp_metrics = dataset.grasp_metrics(obj.key, grasps, gripper=gripper.name) metric_names = grasp_metrics[grasp_metrics.keys()[0]].keys() for metric_name in metric_names: tensor_config['fields'][metric_name] = {} tensor_config['fields'][metric_name]['dtype'] = 'float32' # init tensor dataset tensor_dataset = TensorDataset(output_dir, tensor_config) tensor_datapoint = tensor_dataset.datapoint_template # setup log file experiment_log_filename = os.path.join(output_dir, 'dataset_generation.log') formatter = logging.Formatter('%(asctime)s %(levelname)s: %(message)s') hdlr = logging.FileHandler(experiment_log_filename) hdlr.setFormatter(formatter) logging.getLogger().addHandler(hdlr) root_logger = logging.getLogger() # copy config out_config_filename = os.path.join(output_dir, 'dataset_generation.json') ordered_dict_config = collections.OrderedDict() for key in config.keys(): ordered_dict_config[key] = config[key] with open(out_config_filename, 'w') as outfile: json.dump(ordered_dict_config, outfile) # 1. Precompute the set of valid grasps for each stable pose: # i) Perpendicular to the table # ii) Collision-free along the approach direction # load grasps if they already exist grasp_cache_filename = os.path.join(output_dir, CACHE_FILENAME) if os.path.exists(grasp_cache_filename): logging.info('Loading grasp candidates from file') candidate_grasps_dict = pkl.load(open(grasp_cache_filename, 'rb')) # otherwise re-compute by reading from the database and enforcing constraints else: # create grasps dict candidate_grasps_dict = {} # loop through datasets and objects for dataset in datasets: logging.info('Reading dataset %s' % (dataset.name)) for obj in dataset: if obj.key not in target_object_keys[dataset.name]: continue # init candidate grasp storage candidate_grasps_dict[obj.key] = {} # setup collision checker collision_checker = GraspCollisionChecker(gripper) collision_checker.set_graspable_object(obj) # read in the stable poses of the mesh stable_poses = dataset.stable_poses(obj.key) for i, stable_pose in enumerate(stable_poses): # render images if stable pose is valid if stable_pose.p > stable_pose_min_p: candidate_grasps_dict[obj.key][stable_pose.id] = [] # setup table in collision checker T_obj_stp = stable_pose.T_obj_table.as_frames( 'obj', 'stp') T_obj_table = obj.mesh.get_T_surface_obj( T_obj_stp, delta=table_offset).as_frames('obj', 'table') T_table_obj = T_obj_table.inverse() collision_checker.set_table(table_mesh_filename, T_table_obj) # read grasp and metrics grasps = dataset.grasps(obj.key, gripper=gripper.name) logging.info( 'Aligning %d grasps for object %s in stable %s' % (len(grasps), obj.key, stable_pose.id)) # align grasps with the table aligned_grasps = [ grasp.perpendicular_table(stable_pose) for grasp in grasps ] # check grasp validity logging.info( 'Checking collisions for %d grasps for object %s in stable %s' % (len(grasps), obj.key, stable_pose.id)) for aligned_grasp in aligned_grasps: # check angle with table plane and skip unaligned grasps _, grasp_approach_table_angle, _ = aligned_grasp.grasp_angles_from_stp_z( stable_pose) perpendicular_table = ( np.abs(grasp_approach_table_angle) < max_grasp_approach_table_angle) if not perpendicular_table: continue # check whether any valid approach directions are collision free collision_free = False for phi_offset in phi_offsets: rotated_grasp = aligned_grasp.grasp_y_axis_offset( phi_offset) collides = collision_checker.collides_along_approach( rotated_grasp, approach_dist, delta_approach) if not collides: collision_free = True break # store if aligned to table candidate_grasps_dict[obj.key][ stable_pose.id].append( GraspInfo(aligned_grasp, collision_free)) # visualize if specified if collision_free and config['vis'][ 'candidate_grasps']: logging.info('Grasp %d' % (aligned_grasp.id)) vis.figure() vis.gripper_on_object(gripper, aligned_grasp, obj, stable_pose.T_obj_world) vis.show() # save to file logging.info('Saving to file') pkl.dump(candidate_grasps_dict, open(grasp_cache_filename, 'wb')) # 2. Render a dataset of images and associate the gripper pose with image coordinates for each grasp in the Dex-Net database # setup variables obj_category_map = {} pose_category_map = {} cur_pose_label = 0 cur_obj_label = 0 cur_image_label = 0 # render images for each stable pose of each object in the dataset render_modes = [RenderMode.SEGMASK, RenderMode.DEPTH_SCENE] for dataset in datasets: logging.info('Generating data for dataset %s' % (dataset.name)) # iterate through all object keys object_keys = dataset.object_keys for obj_key in object_keys: obj = dataset[obj_key] if obj.key not in target_object_keys[dataset.name]: continue # read in the stable poses of the mesh stable_poses = dataset.stable_poses(obj.key) for i, stable_pose in enumerate(stable_poses): # render images if stable pose is valid if stable_pose.p > stable_pose_min_p: # log progress logging.info('Rendering images for object %s in %s' % (obj.key, stable_pose.id)) # add to category maps if obj.key not in obj_category_map.keys(): obj_category_map[obj.key] = cur_obj_label pose_category_map['%s_%s' % (obj.key, stable_pose.id)] = cur_pose_label # read in candidate grasps and metrics candidate_grasp_info = candidate_grasps_dict[obj.key][ stable_pose.id] candidate_grasps = [g.grasp for g in candidate_grasp_info] grasp_metrics = dataset.grasp_metrics(obj.key, candidate_grasps, gripper=gripper.name) # compute object pose relative to the table T_obj_stp = stable_pose.T_obj_table.as_frames('obj', 'stp') T_obj_stp = obj.mesh.get_T_surface_obj(T_obj_stp) # sample images from random variable T_table_obj = RigidTransform(from_frame='table', to_frame='obj') scene_objs = { 'table': SceneObject(table_mesh, T_table_obj) } urv = UniformPlanarWorksurfaceImageRandomVariable( obj.mesh, render_modes, 'camera', env_rv_params, stable_pose=stable_pose, scene_objs=scene_objs) render_start = time.time() render_samples = urv.rvs( size=image_samples_per_stable_pose) render_stop = time.time() logging.info('Rendering images took %.3f sec' % (render_stop - render_start)) # visualize if config['vis']['rendered_images']: d = int(np.ceil( np.sqrt(image_samples_per_stable_pose))) # binary vis2d.figure() for j, render_sample in enumerate(render_samples): vis2d.subplot(d, d, j + 1) vis2d.imshow(render_sample.renders[ RenderMode.SEGMASK].image) # depth table vis2d.figure() for j, render_sample in enumerate(render_samples): vis2d.subplot(d, d, j + 1) vis2d.imshow(render_sample.renders[ RenderMode.DEPTH_SCENE].image) vis2d.show() # tally total amount of data num_grasps = len(candidate_grasps) num_images = image_samples_per_stable_pose num_save = num_images * num_grasps logging.info('Saving %d datapoints' % (num_save)) # for each candidate grasp on the object compute the projection # of the grasp into image space for render_sample in render_samples: # read images binary_im = render_sample.renders[ RenderMode.SEGMASK].image depth_im_table = render_sample.renders[ RenderMode.DEPTH_SCENE].image # read camera params T_stp_camera = render_sample.camera.object_to_camera_pose shifted_camera_intr = render_sample.camera.camera_intr # read pixel offsets cx = depth_im_table.center[1] cy = depth_im_table.center[0] # compute intrinsics for virtual camera of the final # cropped and rescaled images camera_intr_scale = float(im_final_height) / float( im_crop_height) cropped_camera_intr = shifted_camera_intr.crop( im_crop_height, im_crop_width, cy, cx) final_camera_intr = cropped_camera_intr.resize( camera_intr_scale) # create a thumbnail for each grasp for grasp_info in candidate_grasp_info: # read info grasp = grasp_info.grasp collision_free = grasp_info.collision_free # get the gripper pose T_obj_camera = T_stp_camera * T_obj_stp.as_frames( 'obj', T_stp_camera.from_frame) grasp_2d = grasp.project_camera( T_obj_camera, shifted_camera_intr) # center images on the grasp, rotate to image x axis dx = cx - grasp_2d.center.x dy = cy - grasp_2d.center.y translation = np.array([dy, dx]) binary_im_tf = binary_im.transform( translation, grasp_2d.angle) depth_im_tf_table = depth_im_table.transform( translation, grasp_2d.angle) # crop to image size binary_im_tf = binary_im_tf.crop( im_crop_height, im_crop_width) depth_im_tf_table = depth_im_tf_table.crop( im_crop_height, im_crop_width) # resize to image size binary_im_tf = binary_im_tf.resize( (im_final_height, im_final_width), interp='nearest') depth_im_tf_table = depth_im_tf_table.resize( (im_final_height, im_final_width)) # visualize the transformed images if config['vis']['grasp_images']: grasp_center = Point( depth_im_tf_table.center, frame=final_camera_intr.frame) tf_grasp_2d = Grasp2D( grasp_center, 0, grasp_2d.depth, width=gripper.max_width, camera_intr=final_camera_intr) # plot 2D grasp image vis2d.figure() vis2d.subplot(2, 2, 1) vis2d.imshow(binary_im) vis2d.grasp(grasp_2d) vis2d.subplot(2, 2, 2) vis2d.imshow(depth_im_table) vis2d.grasp(grasp_2d) vis2d.subplot(2, 2, 3) vis2d.imshow(binary_im_tf) vis2d.grasp(tf_grasp_2d) vis2d.subplot(2, 2, 4) vis2d.imshow(depth_im_tf_table) vis2d.grasp(tf_grasp_2d) vis2d.title('Coll Free? %d' % (grasp_info.collision_free)) vis2d.show() # plot 3D visualization vis.figure() T_obj_world = vis.mesh_stable_pose( obj.mesh, stable_pose.T_obj_world, style='surface', dim=0.5) vis.gripper(gripper, grasp, T_obj_world, color=(0.3, 0.3, 0.3)) vis.show() # form hand pose array hand_pose = np.r_[grasp_2d.center.y, grasp_2d.center.x, grasp_2d.depth, grasp_2d.angle, grasp_2d.center.y - shifted_camera_intr.cy, grasp_2d.center.x - shifted_camera_intr.cx, grasp_2d.width_px] # store to data buffers tensor_datapoint[ 'depth_ims_tf_table'] = depth_im_tf_table.raw_data tensor_datapoint[ 'obj_masks'] = binary_im_tf.raw_data tensor_datapoint['hand_poses'] = hand_pose tensor_datapoint['collision_free'] = collision_free tensor_datapoint['obj_labels'] = cur_obj_label tensor_datapoint['pose_labels'] = cur_pose_label tensor_datapoint['image_labels'] = cur_image_label for metric_name, metric_val in grasp_metrics[ grasp.id].iteritems(): coll_free_metric = ( 1 * collision_free) * metric_val tensor_datapoint[ metric_name] = coll_free_metric tensor_dataset.add(tensor_datapoint) # update image label cur_image_label += 1 # update pose label cur_pose_label += 1 # force clean up gc.collect() # update object label cur_obj_label += 1 # force clean up gc.collect() # save last file tensor_dataset.flush() # save category mappings obj_cat_filename = os.path.join(output_dir, 'object_category_map.json') json.dump(obj_category_map, open(obj_cat_filename, 'w')) pose_cat_filename = os.path.join(output_dir, 'pose_category_map.json') json.dump(pose_category_map, open(pose_cat_filename, 'w'))