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import torch
import pandas as pd
from tqdm import tqdm
import yaml
from box import Box
import numpy as np
import dataclasses
from gpudrive.env.config import EnvConfig, RenderConfig
from gpudrive.env.env_torch import GPUDriveTorchEnv
from gpudrive.env.dataset import SceneDataLoader
from gpudrive.visualize.utils import img_from_fig
from gpudrive.datatypes.observation import GlobalEgoState
from gpudrive.networks.late_fusion import NeuralNet
import logging
import torch
logging.basicConfig(level=logging.INFO)
import pdb
class RandomPolicy:
def __init__(self, action_space_n):
self.action_space_n = action_space_n
def __call__(self, obs, deterministic=False):
"""Generate random actions."""
# Uniformly sample integers from the action space for each observation
batch_size = obs.shape[0]
random_action = torch.randint(
0, self.action_space_n, (batch_size,), dtype=torch.int64
)
return random_action, None, None, None
def load_policy(path_to_cpt, model_name, device, env=None):
"""Load a policy from a given path."""
# Load the saved checkpoint
if model_name == "random_baseline":
return RandomPolicy(env.action_space.n)
else: # Load a trained model
saved_cpt = torch.load(
f=f"{path_to_cpt}/{model_name}.pt",
map_location=device,
weights_only=False,
)
logging.info(f"Load model from {path_to_cpt}/{model_name}.pt")
# Create policy architecture from saved checkpoint
policy = NeuralNet(
input_dim=saved_cpt["model_arch"]["input_dim"],
action_dim=saved_cpt["action_dim"],
hidden_dim=saved_cpt["model_arch"]["hidden_dim"],
).to(device)
# Load the model parameters
policy.load_state_dict(saved_cpt["parameters"])
logging.info("Load model parameters")
return policy.eval()
def rollout(
env,
policy,
device,
deterministic: bool = False,
render_sim_state: bool = False,
render_every_n_steps: int = 1,
zoom_radius: int = 100,
return_agent_positions: bool = False,
center_on_ego: bool = False,
):
"""
Perform a rollout of a policy in the environment.
Args:
env: The simulation environment.
policy: The policy to be rolled out.
device: The device to execute computations on (CPU/GPU).
deterministic (bool): Whether to use deterministic policy actions.
render_sim_state (bool): Whether to render the simulation state.
Returns:
tuple: Averages for goal achieved, collisions, off-road occurrences,
controlled agents count, and simulation state frames.
"""
# Initialize storage
sim_state_frames = {env_id: [] for env_id in range(env.num_worlds)}
num_worlds = env.num_worlds
max_agent_count = env.max_agent_count
episode_len = env.config.episode_len
agent_positions = torch.zeros((env.num_worlds, env.max_agent_count, episode_len, 2))
# Reset episode
next_obs = env.reset()
# Storage
goal_achieved = torch.zeros((num_worlds, max_agent_count), device=device)
collided = torch.zeros((num_worlds, max_agent_count), device=device)
off_road = torch.zeros((num_worlds, max_agent_count), device=device)
active_worlds = np.arange(num_worlds).tolist()
episode_lengths = torch.zeros(num_worlds)
control_mask = env.cont_agent_mask
live_agent_mask = control_mask.clone()
for time_step in range(episode_len):
print(f't: {time_step}')
# Get actions for active agents
if live_agent_mask.any():
action, _, _, _ = policy(
next_obs[live_agent_mask], deterministic=deterministic
)
# Insert actions into a template
action_template = torch.zeros(
(num_worlds, max_agent_count), dtype=torch.int64, device=device
)
action_template[live_agent_mask] = action.to(device)
# Step the environment
env.step_dynamics(action_template)
# Render
if render_sim_state and len(active_worlds) > 0:
has_live_agent = torch.where(
live_agent_mask[active_worlds, :].sum(axis=1) > 0
)[0].tolist()
if time_step % render_every_n_steps == 0:
if center_on_ego:
agent_indices = torch.argmax(control_mask.to(torch.uint8), dim=1).tolist()
else:
agent_indices = None
sim_state_figures = env.vis.plot_simulator_state(
env_indices=has_live_agent,
time_steps=[time_step] * len(has_live_agent),
zoom_radius=zoom_radius,
center_agent_indices=agent_indices,
)
for idx, env_id in enumerate(has_live_agent):
sim_state_frames[env_id].append(
img_from_fig(sim_state_figures[idx])
)
# Update observations, dones, and infos
next_obs = env.get_obs()
dones = env.get_dones().bool()
infos = env.get_infos()
off_road[live_agent_mask] += infos.off_road[live_agent_mask]
collided[live_agent_mask] += infos.collided[live_agent_mask]
goal_achieved[live_agent_mask] += infos.goal_achieved[live_agent_mask]
# Update live agent mask
live_agent_mask[dones] = False
# Process completed worlds
num_dones_per_world = (dones & control_mask).sum(dim=1)
total_controlled_agents = control_mask.sum(dim=1)
done_worlds = (num_dones_per_world == total_controlled_agents).nonzero(
as_tuple=True
)[0]
for world in done_worlds:
if world in active_worlds:
active_worlds.remove(world)
episode_lengths[world] = time_step
if return_agent_positions:
global_agent_states = GlobalEgoState.from_tensor(env.sim.absolute_self_observation_tensor())
agent_positions[:, :, time_step, 0] = global_agent_states.pos_x
agent_positions[:, :, time_step, 1] = global_agent_states.pos_y
if not active_worlds: # Exit early if all worlds are done
break
# Aggregate metrics to obtain averages across scenes
controlled_per_scene = control_mask.sum(dim=1).float()
# Counts
goal_achieved_count = (goal_achieved > 0).float().sum(axis=1)
collided_count = (collided > 0).float().sum(axis=1)
off_road_count = (off_road > 0).float().sum(axis=1)
not_goal_nor_crash_count = torch.logical_and(
goal_achieved == 0, # Didn't reach the goal
torch.logical_and(
collided == 0, # Didn't collide
torch.logical_and(
off_road == 0, # Didn't go off-road
control_mask, # Only count controlled agents
),
),
).float().sum(dim=1)
# Fractions per scene
frac_goal_achieved = goal_achieved_count / controlled_per_scene
frac_collided = collided_count / controlled_per_scene
frac_off_road = off_road_count / controlled_per_scene
frac_not_goal_nor_crash_per_scene = not_goal_nor_crash_count / controlled_per_scene
return (
goal_achieved_count,
frac_goal_achieved,
collided_count,
frac_collided,
off_road_count,
frac_off_road,
not_goal_nor_crash_count,
frac_not_goal_nor_crash_per_scene,
controlled_per_scene,
sim_state_frames,
agent_positions,
episode_lengths,
)
def load_config(cfg: str) -> Box:
"""Load configurations as a Box object.
Args:
cfg (str): Name of config file.
Returns:
Box: Box representation of configurations.
"""
with open(f"{cfg}.yaml", "r") as stream:
config = Box(yaml.safe_load(stream))
return config
def make_env(config, train_loader, render_3d=False):
"""Make the environment with the given config."""
# Override any default environment settings
env_config = dataclasses.replace(
EnvConfig(),
ego_state=config.ego_state,
road_map_obs=config.road_map_obs,
partner_obs=config.partner_obs,
reward_type=config.reward_type,
norm_obs=config.norm_obs,
dynamics_model=config.dynamics_model,
collision_behavior=config.collision_behavior,
dist_to_goal_threshold=config.dist_to_goal_threshold,
polyline_reduction_threshold=config.polyline_reduction_threshold,
remove_non_vehicles=config.remove_non_vehicles,
lidar_obs=config.lidar_obs,
disable_classic_obs=True if config.lidar_obs else False,
obs_radius=config.obs_radius,
steer_actions = torch.round(
torch.linspace(-torch.pi, torch.pi, config.action_space_steer_disc), decimals=3
),
accel_actions = torch.round(
torch.linspace(-4.0, 4.0, config.action_space_accel_disc), decimals=3
),
)
render_config = RenderConfig()
render_config.render_3d = render_3d
env = GPUDriveTorchEnv(
config=env_config,
data_loader=train_loader,
max_cont_agents=config.max_controlled_agents,
device=config.device,
render_config=render_config
)
return env
def evaluate_policy(
env,
policy,
data_loader,
dataset_name,
device="cuda",
deterministic=False,
render_sim_state=False,
):
"""Evaluate policy in the environment."""
res_dict = {
"scene": [],
"goal_achieved_count": [],
"goal_achieved_frac": [],
"collided_count": [],
"collided_frac": [],
"off_road_count": [],
"off_road_frac": [],
"other_count": [],
"other_frac": [],
"controlled_agents_in_scene": [],
"episode_lengths": [],
}
for batch in tqdm(
data_loader,
desc=f"Processing {dataset_name} batches",
total=len(data_loader),
colour="blue",
):
# Update simulator with the new batch of data
env.swap_data_batch(batch)
# Rollout policy in the environments
(
goal_achieved_count,
goal_achieved_frac,
collided_count,
collided_frac,
off_road_count,
off_road_frac,
other_count,
other_frac,
controlled_agents_in_scene,
sim_state_frames,
agent_positions,
episode_lengths,
) = rollout(
env=env,
policy=policy,
device=device,
deterministic=deterministic,
render_sim_state=render_sim_state,
)
# Get names from env
scenario_to_worlds_dict = env.get_env_filenames()
res_dict["scene"].extend(scenario_to_worlds_dict.values())
res_dict["goal_achieved_count"].extend(goal_achieved_count.cpu().numpy())
res_dict["goal_achieved_frac"].extend(goal_achieved_frac.cpu().numpy())
res_dict["collided_count"].extend(collided_count.cpu().numpy())
res_dict["collided_frac"].extend(collided_frac.cpu().numpy())
res_dict["off_road_count"].extend(off_road_count.cpu().numpy())
res_dict["off_road_frac"].extend(off_road_frac.cpu().numpy())
res_dict["other_count"].extend(other_count.cpu().numpy())
res_dict["other_frac"].extend(other_frac.cpu().numpy())
res_dict["controlled_agents_in_scene"].extend(
controlled_agents_in_scene.cpu().numpy()
)
res_dict["episode_lengths"].extend(episode_lengths.cpu().numpy())
# Convert to pandas dataframe
df_res = pd.DataFrame(res_dict)
df_res["dataset"] = dataset_name
return df_res