def main(display='execute'): # control | execute | step connect(use_gui=True) disable_real_time() draw_global_system() with HideOutput(): robot = load_model(DRAKE_IIWA_URDF) # KUKA_IIWA_URDF | DRAKE_IIWA_URDF floor = load_model('models/short_floor.urdf') block = load_model(BLOCK_URDF, fixed_base=False) set_pose(block, Pose(Point(y=0.5, z=stable_z(block, floor)))) set_default_camera(distance=2) dump_world() saved_world = WorldSaver() command = plan(robot, block, fixed=[floor], teleport=False) if (command is None) or (display is None): print('Unable to find a plan!') return saved_world.restore() update_state() wait_if_gui('{}?'.format(display)) if display == 'control': enable_gravity() command.control(real_time=False, dt=0) elif display == 'execute': command.refine(num_steps=10).execute(time_step=0.005) elif display == 'step': command.step() else: raise ValueError(display) print('Quit?') wait_if_gui() disconnect()
def main(display='control'): # control | execute | step connect(use_gui=True) disable_real_time() # KUKA_IIWA_URDF | DRAKE_IIWA_URDF robot = load_model(DRAKE_IIWA_URDF, fixed_base=True) # floor = load_model('models/short_floor.urdf') floor = p.loadURDF("plane.urdf") block = load_model( "models/drake/objects/block_for_pick_and_place_heavy.urdf", fixed_base=False) set_pose(block, Pose(Point(y=0.5, z=stable_z(block, floor)))) set_default_camera() dump_world() saved_world = WorldSaver() command = plan(robot, block, fixed=[floor], teleport=False) if (command is None) or (display is None): print('Unable to find a plan!') return saved_world.restore() update_state() user_input('{}?'.format(display)) if display == 'control': enable_gravity() command.control(real_time=False, dt=0) elif display == 'execute': command.refine(num_steps=10).execute(time_step=0.005) elif display == 'step': command.step() else: raise ValueError(display) print('Quit?') wait_for_user() disconnect()
def plan(robot, block, fixed, teleport): grasp_gen = get_grasp_gen(robot, 'top') ik_fn = get_ik_fn(robot, fixed=fixed, teleport=teleport) free_motion_fn = get_free_motion_gen(robot, fixed=([block] + fixed), teleport=teleport) holding_motion_fn = get_holding_motion_gen(robot, fixed=fixed, teleport=teleport) pose0 = BodyPose(block) conf0 = BodyConf(robot) saved_world = WorldSaver() for grasp, in grasp_gen(block): saved_world.restore() result1 = ik_fn(block, pose0, grasp) if result1 is None: continue conf1, path2 = result1 pose0.assign() result2 = free_motion_fn(conf0, conf1) if result2 is None: continue path1, = result2 result3 = holding_motion_fn(conf1, conf0, block, grasp) if result3 is None: continue path3, = result3 return Command(path1.body_paths + path2.body_paths + path3.body_paths) return None
def plan(robot, block, fixed, teleport): grasp_gen = get_grasp_gen(robot, 'top', TOOL_FRAME) ik_fn = get_ik_fn(robot, fixed=fixed, teleport=teleport, self_collisions=ENABLE_SELF_COLLISION) free_motion_fn = get_free_motion_gen(robot, fixed=([block] + fixed), teleport=teleport, self_collisions=ENABLE_SELF_COLLISION) holding_motion_fn = get_holding_motion_gen(robot, fixed=fixed, teleport=teleport, self_collisions=ENABLE_SELF_COLLISION) movable_joints = get_track_arm_joints(robot) if USE_IKFAST else get_movable_joints(robot) pose0 = BodyPose(block) conf0 = BodyConf(robot, joints=movable_joints) saved_world = WorldSaver() for grasp, in grasp_gen(block): saved_world.restore() result1 = ik_fn(block, pose0, grasp) if result1 is None: continue conf1, path2 = result1 pose0.assign() result2 = free_motion_fn(conf0, conf1) if result2 is None: continue path1, = result2 result3 = holding_motion_fn(conf1, conf0, block, grasp) if result3 is None: continue path3, = result3 return Command(path1.body_paths + path2.body_paths + path3.body_paths) return None
def main(): connect(use_gui=True) disable_real_time() set_default_camera() problem = pick_problem(arm='left', grasp_type='side') grasp_gen = get_grasp_gen(problem, collisions=False) ik_ir_fn = get_ik_ir_gen(problem, max_attempts=100, teleport=False) pose = Pose(problem.movable[0], support=problem.surfaces[0]) base_conf = Conf(problem.robot, get_group_joints(problem.robot, 'base')) ik_fn = get_ik_fn(problem) found = False saved_world = WorldSaver() for grasp, in grasp_gen(problem.movable[0]): print(grasp.value) # confs_cmds = ik_ir_fn(problem.arms[0], problem.movable[0], pose, grasp) # for conf, cmds in confs_cmds: # found = True cmds = ik_fn(problem.arms[0], problem.movable[0], pose, grasp, base_conf) if cmds is not None: cmds = cmds[0] found = True if found: break if not found: raise Exception('No grasp found') saved_world.restore() for cmd in cmds.commands: print(cmd) control_commands(cmds.commands) print('Quit?') wait_for_user() disconnect()
def main(display='execute'): # control | execute | step # One of the arm's gantry carriage is fixed when the other is moving. connect(use_gui=True) set_camera(yaw=-90, pitch=-40, distance=10, target_position=(0, 7.5, 0)) draw_pose(unit_pose(), length=1.0) disable_real_time() with HideOutput(): root_directory = os.path.dirname(os.path.abspath(__file__)) robot = load_pybullet(os.path.join(root_directory, ETH_RFL_URDF), fixed_base=True) # floor = load_model('models/short_floor.urdf') block = load_model(BLOCK_URDF, fixed_base=False) #link = link_from_name(robot, 'gantry_base_link') #print(get_aabb(robot, link)) block_x = -0.2 #block_y = 1 if ARM == 'right' else 13.5 #block_x = 10 block_y = 5. # set_pose(floor, Pose(Point(x=floor_x, y=1, z=1.3))) # set_pose(block, Pose(Point(x=floor_x, y=0.6, z=stable_z(block, floor)))) set_pose(block, Pose(Point(x=block_x, y=block_y, z=3.5))) # set_default_camera() dump_world() #print(get_camera()) saved_world = WorldSaver() with LockRenderer(): command = plan(robot, block, fixed=[], teleport=False) # fixed=[floor], if (command is None) or (display is None): print('Unable to find a plan! Quit?') wait_for_interrupt() disconnect() return saved_world.restore() update_state() print('{}?'.format(display)) wait_for_interrupt() if display == 'control': enable_gravity() command.control(real_time=False, dt=0) elif display == 'execute': command.refine(num_steps=10).execute(time_step=0.002) elif display == 'step': command.step() else: raise ValueError(display) print('Quit?') wait_for_interrupt() disconnect()
def main(display='execute'): # control | execute | step connect(use_gui=True) disable_real_time() with HideOutput(): root_directory = os.path.dirname(os.path.abspath(__file__)) robot = load_pybullet(os.path.join(root_directory, IRB6600_TRACK_URDF), fixed_base=True) floor = load_model('models/short_floor.urdf') block = load_model(BLOCK_URDF, fixed_base=False) floor_x = 2 set_pose(floor, Pose(Point(x=floor_x, z=0.5))) set_pose(block, Pose(Point(x=floor_x, y=0, z=stable_z(block, floor)))) # set_default_camera() dump_world() saved_world = WorldSaver() with LockRenderer(): command = plan(robot, block, fixed=[floor], teleport=False) if (command is None) or (display is None): print('Unable to find a plan!') print('Quit?') wait_for_interrupt() disconnect() return saved_world.restore() update_state() user_input('{}?'.format(display)) if display == 'control': enable_gravity() command.control(real_time=False, dt=0) elif display == 'execute': command.refine(num_steps=10).execute(time_step=0.002) elif display == 'step': command.step() else: raise ValueError(display) print('Quit?') wait_for_interrupt() disconnect()
def plan(robot, block, fixed, teleport): grasp_gen = get_grasp_gen(robot, 'bottom', get_tool_frame(ARM)) #'top' ik_fn = get_ik_fn(robot, fixed=fixed, teleport=teleport, self_collisions=ENABLE_SELF_COLLISION) free_motion_fn = get_free_motion_gen(robot, fixed=([block] + fixed), teleport=teleport, self_collisions=ENABLE_SELF_COLLISION) holding_motion_fn = get_holding_motion_gen(robot, fixed=fixed, teleport=teleport, self_collisions=ENABLE_SELF_COLLISION) #arm_joints = get_torso_arm_joints(robot, ARM) arm_joints = joints_from_names(robot, get_arm_joint_names(ARM)) pose0 = BodyPose(block) conf0 = BodyConf(robot, joints=arm_joints) saved_world = WorldSaver() for grasp, in grasp_gen(block): saved_world.restore() result1 = ik_fn(block, pose0, grasp) if result1 is None: print('ik fn fails!') continue conf1, path2 = result1 pose0.assign() result2 = free_motion_fn(conf0, conf1) if result2 is None: print("free motion plan fails!") continue path1, = result2 result3 = holding_motion_fn(conf1, conf0, block, grasp) if result3 is None: print('holding motion fails!') continue path3, = result3 return Command(path1.body_paths + path2.body_paths + path3.body_paths) return None
def run_loop(args, ros_world, policy): items = wait_until_observation(args.problem, ros_world) if items is None: ros_world.controller.speak("Observation failure") print('Failed to detect the required objects') return None task_fn = get_task_fn(PROBLEMS, 'collect_{}'.format(args.problem)) task, feature = task_fn(args, ros_world) feature['simulation'] = False #print('Arms:', task.arms) #print('Required:', task.required) init_stackings = add_scales(task, ros_world) if task.use_scales else {} print('Scale stackings:', str_from_object(init_stackings)) print('Surfaces:', ros_world.perception.get_surfaces()) print('Items:', ros_world.perception.get_items()) add_walls(ros_world) with ros_world: remove_all_debug() draw_names(ros_world) draw_forward_reachability(ros_world, task.arms) ######################### init_raw_masses = read_raw_masses(init_stackings) if init_raw_masses is None: ros_world.controller.speak("Scale failure") return None # Should be robust to material starting in the target initial_contains = bowls_holding_material(task.init) print('Initial contains:', initial_contains) #bowl_masses = {bowl: MODEL_MASSES[get_type(bowl)] if bowl in initial_contains else init_raw_masses[bowl] # for bowl in init_stackings.values()} bowl_masses = { bowl: MODEL_MASSES[get_type(bowl)] for bowl in init_stackings.values() } print('Material:', args.material) init_masses = estimate_masses(init_raw_masses, bowl_masses, args.material) init_total_mass = sum(init_masses.values()) print('Total mass:', init_total_mass) if POUR and (init_total_mass < 1e-3): ros_world.controller.speak("Material failure") print('Initial total mass is {:.3f}'.format(init_total_mass)) return None # for bowl, mass in init_masses.items(): # if bowl in initial_contains: # if mass < 0: # return None # else: # if 0 <= mass: # return None ######################### policy_name = policy if isinstance(policy, str) else '' print('Feature:', feature) collector = SKILL_COLLECTORS[args.problem] parameter_fns, parameter, prediction = get_parameter_fns( ros_world, collector, policy, feature, valid=True) # valid=not args.active) print('Policy:', policy_name) print('Parameter:', parameter) print('Prediction:', prediction) result = { SKILL: args.problem, 'date': datetime.datetime.now().strftime(DATE_FORMAT), 'simulated': False, 'material': args.material, # TODO: pass to feature 'dataset': 'train' if args.train else 'test', 'feature': feature, 'parameter': parameter, 'score': None, } plan = None if test_validity(result, ros_world, collector, feature, parameter, prediction): planning_world = PlanningWorld(task, visualize=args.visualize_planning) with ClientSaver(planning_world.client): #set_caching(False) planning_world.load(ros_world) print(planning_world) start_time = time.time() saver = WorldSaver() plan = None while (plan is None) and (elapsed_time(start_time) < 45): # Doesn't typically timeout plan = plan_actions(planning_world, parameter_fns=parameter_fns, collisions=True, max_time=30) saver.restore() planning_world.stop() result.update({ 'success': plan is not None, 'plan-time': elapsed_time(start_time), # TODO: should be elapsed time }) if plan is None: print('Failed to find a plan') ros_world.controller.speak("Planning failure") return result ######################### #if not review_plan(task, ros_world, plan): # return start_time = time.time() ros_world.controller.speak("Executing") success = execute_plan(ros_world, plan, joint_speed=0.5, default_sleep=0.25) print('Finished! Success:', success) result['execution'] = success result['execution-time'] = elapsed_time(start_time) if not success: ros_world.controller.speak("Execution failure") return None ######################### # TODO: could read scales while returning home final_raw_masses = read_raw_masses(init_stackings) if final_raw_masses is None: ros_world.controller.speak("Scale failure") return None result['score'] = {} result['score'].update( score_masses(args, task, ros_world, init_total_mass, bowl_masses, final_raw_masses)) result['score'].update(score_poses( args.problem, task, ros_world)) # TODO: fail if fail to detect result['score'].update({ 'initial_{}_mass'.format(name): mass for name, mass in init_raw_masses.items() }) result['score'].update({ 'final_{}_mass'.format(name): mass for name, mass in final_raw_masses.items() }) ros_world.controller.speak("Done") return result
def main(): parser = argparse.ArgumentParser() parser.add_argument('-c', '--cfree', action='store_true', help='When enabled, disables collision checking.') # parser.add_argument('-p', '--problem', default='test_pour', choices=sorted(problem_fn_from_name), # help='The name of the problem to solve.') parser.add_argument('--holonomic', action='store_true', # '-h', help='') parser.add_argument('-l', '--lock', action='store_false', help='') parser.add_argument('-s', '--seed', default=None, type=int, help='The random seed to use.') parser.add_argument('-v', '--viewer', action='store_false', help='') args = parser.parse_args() connect(use_gui=args.viewer) seed = args.seed #seed = 0 #seed = time.time() set_random_seed(seed=seed) # None: 2147483648 = 2**31 set_numpy_seed(seed=seed) print('Random seed:', get_random_seed(), random.random()) print('Numpy seed:', get_numpy_seed(), np.random.random()) ######################### robot, base_limits, goal_conf, obstacles = problem1() draw_base_limits(base_limits) custom_limits = create_custom_base_limits(robot, base_limits) base_joints = joints_from_names(robot, BASE_JOINTS) base_link = link_from_name(robot, BASE_LINK_NAME) if args.cfree: obstacles = [] # for obstacle in obstacles: # draw_aabb(get_aabb(obstacle)) # Updates automatically resolutions = None #resolutions = np.array([0.05, 0.05, math.radians(10)]) set_all_static() # Doesn't seem to affect region_aabb = AABB(lower=-np.ones(3), upper=+np.ones(3)) draw_aabb(region_aabb) step_simulation() # Need to call before get_bodies_in_region #update_scene() # TODO: https://github.com/bulletphysics/bullet3/pull/3331 bodies = get_bodies_in_region(region_aabb) print(len(bodies), bodies) # https://github.com/bulletphysics/bullet3/search?q=broadphase # https://github.com/bulletphysics/bullet3/search?p=1&q=getCachedOverlappingObjects&type=&utf8=%E2%9C%93 # https://andysomogyi.github.io/mechanica/bullet.html # http://www.cs.kent.edu/~ruttan/GameEngines/lectures/Bullet_User_Manual #draw_pose(get_link_pose(robot, base_link), length=0.5) for conf in [get_joint_positions(robot, base_joints), goal_conf]: draw_pose(pose_from_pose2d(conf, z=DRAW_Z), length=DRAW_LENGTH) aabb = get_aabb(robot) #aabb = get_subtree_aabb(robot, base_link) draw_aabb(aabb) for link in [BASE_LINK, base_link]: print(link, get_collision_data(robot, link), pairwise_link_collision(robot, link, robot, link)) ######################### saver = WorldSaver() start_time = time.time() profiler = Profiler(field='tottime', num=50) # tottime | cumtime | None profiler.save() with LockRenderer(lock=args.lock): path = plan_motion(robot, base_joints, goal_conf, holonomic=args.holonomic, obstacles=obstacles, custom_limits=custom_limits, resolutions=resolutions, use_aabb=True, cache=True, max_distance=0., restarts=2, iterations=20, smooth=20) # 20 | None saver.restore() #wait_for_duration(duration=1e-3) profiler.restore() ######################### solved = path is not None length = INF if path is None else len(path) cost = sum(get_distance_fn(robot, base_joints, weights=resolutions)(*pair) for pair in get_pairs(path)) print('Solved: {} | Length: {} | Cost: {:.3f} | Runtime: {:.3f} sec'.format( solved, length, cost, elapsed_time(start_time))) if path is None: disconnect() return iterate_path(robot, base_joints, path) disconnect()
def iterate_path(robot, joints, path, simulate=False, step_size=None, resolutions=None, smooth=False, **kwargs): # 1e-2 | None if path is None: return saver = WorldSaver() path = adjust_path(robot, joints, path) with LockRenderer(): handles = draw_path(path) waypoints = path #waypoints = waypoints_from_path(path) #curve = interpolate_path(robot, joints, waypoints, k=1, velocity_fraction=1) # TODO: no velocities in the URDF if not smooth: curve = retime_path(robot, joints, path, max_velocities=MAX_VELOCITIES, max_accelerations=MAX_ACCELERATIONS) else: curve = smooth_path(robot, joints, path, resolutions=resolutions, max_velocities=MAX_VELOCITIES, max_accelerations=MAX_ACCELERATIONS, **kwargs) path = discretize_curve(robot, joints, curve, resolutions=resolutions) print('Steps: {} | Start: {:.3f} | End: {:.3f} | Knots: {}'.format( len(path), curve.x[0], curve.x[-1], len(curve.x))) with LockRenderer(): handles = draw_path(path) if False: # TODO: handle circular joints #curve_collision_fn = lambda *args, **kwargs: False curve_collision_fn = get_curve_collision_fn(robot, joints, resolutions=resolutions, **kwargs) with LockRenderer(): with Profiler(): curve = smooth_curve(curve, MAX_VELOCITIES, MAX_ACCELERATIONS, curve_collision_fn, max_time=5) #, curve_collision_fn=[]) saver.restore() path = [conf for t, conf in sample_curve(curve, time_step=step_size)] print('Steps: {} | Start: {:.3f} | End: {:.3f} | Knots: {}'.format( len(path), curve.x[0], curve.x[-1], len(curve.x))) with LockRenderer(): handles = draw_path(path) if simulate: simulate_curve(robot, joints, curve) else: path = [conf for t, conf in sample_curve(curve, time_step=step_size)] step_curve(robot, joints, path, step_size=step_size)
def main(execute='execute'): parser = argparse.ArgumentParser() # Automatically includes help parser.add_argument('-viewer', action='store_true', help='enable viewer.') #parser.add_argument('-display', action='store_true', help='enable viewer.') args = parser.parse_args() #display = args.display display = True connect(use_gui=args.viewer) robot, block = load_world() #robot2 = clone_body(robot) #block2 = clone_body(block) #dump_world() saved_world = WorldSaver() dump_world() ss_problem = ss_from_problem(robot, movable=[block], teleport=False, movable_collisions=True) #ss_problem = ss_problem.debug_problem() #print(ss_problem) t0 = time.time() plan, evaluations = dual_focused(ss_problem, verbose=True) # plan, evaluations = incremental(ss_problem, verbose=True) print_plan(plan, evaluations) print(time.time() - t0) if (not display) or (plan is None): disconnect() return paths = [] for action, params in plan: if action.name == 'place': paths += params[-1].reverse().body_paths elif action.name in ['move_free', 'move_holding', 'pick']: paths += params[-1].body_paths print(paths) command = Command(paths) if not args.viewer: # TODO: how to reenable the viewer disconnect() connect(use_gui=True) load_world() saved_world.restore() user_input('Execute?') if execute == 'control': command.control() elif execute == 'execute': command.refine(num_steps=10).execute(time_step=0.001) elif execute == 'step': command.step() else: raise ValueError(execute) #dt = 1. / 240 # Bullet default #p.setTimeStep(dt) wait_for_interrupt() disconnect()
def solve_pddlstream(belief, problem, args, skeleton=None, replan_actions=set(), max_time=INF, max_memory=MAX_MEMORY, max_cost=INF): set_cost_scale(COST_SCALE) reset_globals() stream_info = get_stream_info() #print(set(stream_map) - set(stream_info)) skeletons = create_ordered_skeleton(skeleton) max_cost = min(max_cost, COST_BOUND) print('Max cost: {:.3f} | Max runtime: {:.3f}'.format(max_cost, max_time)) constraints = PlanConstraints(skeletons=skeletons, max_cost=max_cost, exact=True) success_cost = 0 if args.anytime else INF planner = 'ff-astar' if args.anytime else 'ff-wastar2' search_sample_ratio = 0.5 # 0.5 max_planner_time = 10 # TODO: max number of samples per iteration flag # TODO: don't greedily expand samples with too high of a complexity if out of time pr = cProfile.Profile() pr.enable() saver = WorldSaver() sim_state = belief.sample_state() sim_state.assign() wait_for_duration(0.1) with LockRenderer(lock=not args.visualize): # TODO: option to only consider costs during local optimization # effort_weight = 0 if args.anytime else 1 effort_weight = 1e-3 if args.anytime else 1 #effort_weight = 0 #effort_weight = None solution = solve_focused( problem, constraints=constraints, stream_info=stream_info, replan_actions=replan_actions, initial_complexity=5, planner=planner, max_planner_time=max_planner_time, unit_costs=args.unit, success_cost=success_cost, max_time=max_time, max_memory=max_memory, verbose=True, debug=False, unit_efforts=True, effort_weight=effort_weight, max_effort=INF, # bind=True, max_skeletons=None, search_sample_ratio=search_sample_ratio) saver.restore() # print([(s.cost, s.time) for s in SOLUTIONS]) # print(SOLUTIONS) print_solution(solution) pr.disable() pstats.Stats(pr).sort_stats('tottime').print_stats(25) # cumtime | tottime return solution
def plan_extrusion(args_list, viewer=False, verify=False, verbose=False, watch=False): results = [] if not args_list: return results # TODO: setCollisionFilterGroupMask if not verbose: sys.stdout = open(os.devnull, 'w') problems = {args.problem for args in args_list} assert len(problems) == 1 [problem] = problems # TODO: change dir for pddlstream extrusion_path = get_extrusion_path(problem) #extrusion_path = rotate_problem(extrusion_path) element_from_id, node_points, ground_nodes = load_extrusion(extrusion_path, verbose=True) elements = sorted(element_from_id.values()) #node_points = transform_model(problem, elements, node_points, ground_nodes) connect(use_gui=viewer, shadows=SHADOWS, color=BACKGROUND_COLOR) with LockRenderer(lock=True): #draw_pose(unit_pose(), length=1.) obstacles, robot = load_world() #draw_model(elements, node_points, ground_nodes) #wait_for_user() color = apply_alpha(BLACK, alpha=0) # 0, 1 #color = None element_bodies = dict(zip(elements, create_elements_bodies(node_points, elements, color=color))) set_extrusion_camera(node_points) #if viewer: # label_nodes(node_points) saver = WorldSaver() #visualize_stiffness(extrusion_path) #debug_elements(robot, node_points, node_order, elements) initial_position = point_from_pose(get_link_pose(robot, link_from_name(robot, TOOL_LINK))) checker = None plan = None for args in args_list: if args.stiffness and (checker is None): checker = create_stiffness_checker(extrusion_path, verbose=False) saver.restore() #initial_conf = get_joint_positions(robot, get_movable_joints(robot)) with LockRenderer(lock=not viewer): start_time = time.time() plan, data = None, {} with timeout(args.max_time): with Profiler(num=10, cumulative=False): plan, data = solve_extrusion(robot, obstacles, element_from_id, node_points, element_bodies, extrusion_path, ground_nodes, args, checker=checker) runtime = elapsed_time(start_time) sequence = recover_directed_sequence(plan) if verify: max_translation, max_rotation = compute_plan_deformation(extrusion_path, recover_sequence(plan)) valid = check_plan(extrusion_path, sequence) print('Valid:', valid) safe = validate_trajectories(element_bodies, obstacles, plan) print('Safe:', safe) data.update({ 'safe': safe, 'valid': valid, 'max_translation': max_translation, 'max_rotation': max_rotation, }) data.update({ 'runtime': runtime, 'num_elements': len(elements), 'ee_distance': compute_sequence_distance(node_points, sequence, start=initial_position, end=initial_position), 'print_distance': get_print_distance(plan, teleport=True), 'distance': get_print_distance(plan, teleport=False), 'sequence': sequence, 'parameters': get_global_parameters(), 'problem': args.problem, 'algorithm': args.algorithm, 'heuristic': args.bias, 'plan_extrusions': not args.disable, 'use_collisions': not args.cfree, 'use_stiffness': args.stiffness, }) print(data) #plan_path = '{}_solution.json'.format(args.problem) #with open(plan_path, 'w') as f: # json.dump(plan_data, f, indent=2, sort_keys=True) results.append((args, data)) reset_simulation() disconnect() if watch and (plan is not None): args = args_list[-1] animate = not (args.disable or args.ee_only) connect(use_gui=True, shadows=SHADOWS, color=BACKGROUND_COLOR) # TODO: avoid reconnecting obstacles, robot = load_world() display_trajectories(node_points, ground_nodes, plan, #time_step=None, video=True, animate=animate) reset_simulation() disconnect() if not verbose: sys.stdout.close() return results
def solve_serialized(robots, obstacles, node_points, element_bodies, ground_nodes, layer_from_n, trajectories=[], post_process=False, collisions=True, disable=False, max_time=INF, **kwargs): start_time = time.time() saver = WorldSaver() elements = set(element_bodies) elements_from_layers = compute_elements_from_layer(elements, layer_from_n) layers = sorted(elements_from_layers.keys()) print('Layers:', layers) full_plan = [] makespan = 0. removed = set() for layer in reversed(layers): print(SEPARATOR) print('Layer: {}'.format(layer)) saver.restore() remaining = elements_from_layers[layer] printed = elements - remaining - removed draw_model(remaining, node_points, ground_nodes, color=GREEN) draw_model(printed, node_points, ground_nodes, color=RED) problem = get_pddlstream(robots, obstacles, node_points, element_bodies, ground_nodes, layer_from_n, printed=printed, removed=removed, return_home=False, trajectories=trajectories, collisions=collisions, disable=disable, **kwargs) layer_plan, certificate = solve_pddlstream(problem, node_points, element_bodies, max_time=max_time - elapsed_time(start_time)) remove_all_debug() if layer_plan is None: return None if post_process: print(SEPARATOR) # Allows the planner to continue to check collisions problem.init[:] = certificate.all_facts #static_facts = extract_static_facts(layer_plan, ...) #problem.init.extend(('Order',) + pair for pair in compute_total_orders(layer_plan)) for fact in [('print', ), ('move', )]: if fact in problem.init: problem.init.remove(fact) new_layer_plan, _ = solve_pddlstream(problem, node_points, element_bodies, planner=POSTPROCESS_PLANNER, max_time=max_time - elapsed_time(start_time)) if (new_layer_plan is not None) and (compute_duration(new_layer_plan) < compute_duration(layer_plan)): layer_plan = new_layer_plan user_input('{:.3f}->{:.3f}'.format( compute_duration(layer_plan), compute_duration(new_layer_plan))) # TODO: replan in a cost sensitive way layer_plan = apply_start(layer_plan, makespan) duration = compute_duration(layer_plan) makespan += duration print( '\nLength: {} | Start: {:.3f} | End: {:.3f} | Duration: {:.3f} | Makespan: {:.3f}' .format(len(layer_plan), compute_start(layer_plan), compute_end(layer_plan), duration, makespan)) full_plan.extend(layer_plan) removed.update(remaining) print(SEPARATOR) print_plan(full_plan) return full_plan, None
def stripstream(robot1, obstacles, node_points, element_bodies, ground_nodes, dual=True, serialize=False, hierarchy=False, **kwargs): robots = mirror_robot(robot1, node_points) if dual else [robot1] elements = set(element_bodies) initial_confs = { ROBOT_TEMPLATE.format(i): Conf(robot) for i, robot in enumerate(robots) } saver = WorldSaver() layer_from_n = compute_layer_from_vertex(elements, node_points, ground_nodes) #layer_from_n = cluster_vertices(elements, node_points, ground_nodes) # TODO: increase resolution for small structures # TODO: compute directions from first, layer from second max_layer = max(layer_from_n.values()) print('Max layer: {}'.format(max_layer)) data = {} if serialize: plan, certificate = solve_serialized(robots, obstacles, node_points, element_bodies, ground_nodes, layer_from_n, initial_confs=initial_confs, **kwargs) else: plan, certificate = solve_joint(robots, obstacles, node_points, element_bodies, ground_nodes, layer_from_n, initial_confs=initial_confs, **kwargs) if plan is None: return None, data if hierarchy: print(SEPARATOR) static_facts = extract_static_facts(plan, certificate, initial_confs) partial_orders = compute_total_orders(plan) plan, certificate = solve_joint(robots, obstacles, node_points, element_bodies, ground_nodes, layer_from_n, initial_confs=initial_confs, can_print=False, can_transit=True, additional_init=static_facts, additional_orders=partial_orders, **kwargs) if plan is None: return None, data if plan and not isinstance(plan[0], DurativeAction): time_from_start = 0. retimed_plan = [] for name, args in plan: command = args[-1] command.retime(start_time=time_from_start) retimed_plan.append( DurativeAction(name, args, time_from_start, command.duration)) time_from_start += command.duration plan = retimed_plan plan = reverse_plan(plan) print('\nLength: {} | Makespan: {:.3f}'.format(len(plan), compute_duration(plan))) # TODO: retime using the TFD duration # TODO: attempt to resolve once without any optimistic facts to see if a solution exists # TODO: choose a better initial config # TODO: decompose into layers hierarchically #planned_elements = [args[2] for name, args, _, _ in sorted(plan, key=lambda a: get_end(a))] # TODO: remove approach #if not check_plan(extrusion_path, planned_elements): # return None, data if has_gui(): saver.restore() #label_nodes(node_points) # commands = [action.args[-1] for action in reversed(plan) if action.name == 'print'] # trajectories = flatten_commands(commands) # elements = recover_sequence(trajectories) # draw_ordered(elements, node_points) # wait_if_gui('Continue?') #simulate_printing(node_points, trajectories) #display_trajectories(node_points, ground_nodes, trajectories) simulate_parallel(robots, plan) return None, data
def main(): np.set_printoptions(precision=N_DIGITS, suppress=True, threshold=3) # , edgeitems=1) #, linewidth=1000) parser = argparse.ArgumentParser() parser.add_argument( '-a', '--algorithm', default='rrt_connect', # choices=[], help='The motion planning algorithm to use.') parser.add_argument('-c', '--cfree', action='store_true', help='When enabled, disables collision checking.') # parser.add_argument('-p', '--problem', default='test_pour', choices=sorted(problem_fn_from_name), # help='The name of the problem to solve.') parser.add_argument( '--holonomic', action='store_true', # '-h', help='') parser.add_argument('-l', '--lock', action='store_false', help='') parser.add_argument('-r', '--reversible', action='store_true', help='') parser.add_argument( '-s', '--seed', default=None, type=int, # None | 1 help='The random seed to use.') parser.add_argument('-n', '--num', default=10, type=int, help='The number of obstacles.') parser.add_argument('-o', '--orientation', action='store_true', help='') parser.add_argument('-v', '--viewer', action='store_false', help='') args = parser.parse_args() connect(use_gui=args.viewer) #set_aabb_buffer(buffer=1e-3) #set_separating_axis_collisions() #seed = 0 #seed = time.time() seed = args.seed if seed is None: seed = random.randint(0, 10**3 - 1) print('Seed:', seed) set_random_seed(seed=seed) # None: 2147483648 = 2**31 set_numpy_seed(seed=seed) #print('Random seed:', get_random_seed(), random.random()) #print('Numpy seed:', get_numpy_seed(), np.random.random()) ######################### robot, base_limits, goal_conf, obstacles = problem1(n_obstacles=args.num) custom_limits = create_custom_base_limits(robot, base_limits) base_joints = joints_from_names(robot, BASE_JOINTS) draw_base_limits(base_limits) # draw_pose(get_link_pose(robot, base_link), length=0.5) start_conf = get_joint_positions(robot, base_joints) for conf in [start_conf, goal_conf]: draw_waypoint(conf) #resolutions = None #resolutions = np.array([0.05, 0.05, math.radians(10)]) plan_joints = base_joints[:2] if not args.orientation else base_joints d = len(plan_joints) holonomic = args.holonomic or (d != 3) resolutions = 1. * DEFAULT_RESOLUTION * np.ones( d) # TODO: default resolutions, velocities, accelerations fns #weights = np.reciprocal(resolutions) weights = np.array([1, 1, 1e-3])[:d] cost_fn = get_acceleration_fn(robot, plan_joints, max_velocities=MAX_VELOCITIES[:d], max_accelerations=MAX_ACCELERATIONS[:d]) # TODO: check that taking shortest turning direction (reversible affecting?) if args.cfree: obstacles = [] # for obstacle in obstacles: # draw_aabb(get_aabb(obstacle)) # Updates automatically #set_all_static() # Doesn't seem to affect #test_aabb(robot) #test_caching(robot, obstacles) #return ######################### # TODO: filter if straight-line path is feasible saver = WorldSaver() wait_for_duration(duration=1e-2) start_time = time.time() with LockRenderer(lock=args.lock): with Profiler(field='cumtime', num=25): # tottime | cumtime | None # TODO: draw the search tree path = plan_base_joint_motion( robot, plan_joints, goal_conf[:d], holonomic=holonomic, reversible=args.reversible, obstacles=obstacles, self_collisions=False, custom_limits=custom_limits, use_aabb=True, cache=True, max_distance=MIN_PROXIMITY, resolutions=resolutions, weights=weights, # TODO: use KDTrees circular={ 2: UNBOUNDED_LIMITS if holonomic else CIRCULAR_LIMITS }, cost_fn=cost_fn, algorithm=args.algorithm, verbose=True, restarts=5, max_iterations=50, smooth=None if holonomic else 100, smooth_time=1, # None | 100 | INF ) saver.restore() # TODO: draw ROADMAPS #wait_for_duration(duration=1e-3) ######################### solved = path is not None length = INF if path is None else len(path) cost = compute_cost(robot, base_joints, path, resolutions=resolutions[:len(plan_joints)]) print( 'Solved: {} | Length: {} | Cost: {:.3f} | Runtime: {:.3f} sec'.format( solved, length, cost, elapsed_time(start_time))) if path is None: wait_if_gui() disconnect() return # for i, conf in enumerate(path): # set_joint_positions(robot, plan_joints, conf) # wait_if_gui('{}/{}) Continue?'.format(i + 1, len(path))) path = extract_full_path(robot, plan_joints, path, base_joints) with LockRenderer(): draw_last_roadmap(robot, base_joints) # for i, conf in enumerate(path): # set_joint_positions(robot, base_joints, conf) # wait_if_gui('{}/{}) Continue?'.format(i+1, len(path))) iterate_path( robot, base_joints, path, step_size=2e-2, smooth=holonomic, custom_limits=custom_limits, resolutions=DEFAULT_RESOLUTION * np.ones(3), # resolutions obstacles=obstacles, self_collisions=False, max_distance=MIN_PROXIMITY) disconnect()