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GarbageBot / inference.py
Mihir Mithani
deploy: final submission with pure logging and port fix
ac2a7d9
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9.17 kB
import os
import time
import requests
import json
from collections import deque
from openai import OpenAI
API_BASE_URL = os.environ.get("API_BASE_URL", "https://api.openai.com/v1")
MODEL_NAME = os.environ.get("MODEL_NAME", "gpt-4o-mini")
HF_TOKEN = os.environ.get("HF_TOKEN", "")
# FIX: Match the Dockerfile port (7860) to avoid connection refuse errors during evaluation
ENV_URL = os.environ.get("ENV_URL", "http://localhost:7860")
HF_MODEL_ID = os.environ.get(
 "HF_MODEL_ID",
 "TechAvenger/GarbageBot-Weights"
)
MAX_STEPS = 200 # raised to account for recharge/unload detours
# Lazy-loaded local model — populated in main() if Unsloth is available
_local_model = None
_local_tokenizer = None
# Q-Learning agent — loaded once in main(), used as primary policy
_ql_agent = None
try:
 from qlearning import QLearningAgent
except ImportError:
 QLearningAgent = None
# ──────────────────────────────────────────────────────────
# BFS CORE
# ──────────────────────────────────────────────────────────
def bfs(start, goal, obstacles, grid_w, grid_h):
 """
 BFS from start to goal avoiding obstacles.
 Returns (first_direction, path_length) or (None, inf) if unreachable.
 """
 start, goal = tuple(start), tuple(goal)
 if start == goal:
 return ("COLLECT", 0)
obstacle_set = frozenset(tuple(o) for o in obstacles)
 dirs = [("RIGHT",(1,0)), ("LEFT",(-1,0)), ("UP",(0,1)), ("DOWN",(0,-1))]
 queue = deque([(start, None, 0)])
 visited = {start}
while queue:
 pos, first, depth = queue.popleft()
 for name, (dx, dy) in dirs:
 npos = (pos[0]+dx, pos[1]+dy)
 if not (0 <= npos[0] < grid_w and 0 <= npos[1] < grid_h):
 continue
 if npos in obstacle_set or npos in visited:
 continue
 move = first if first else name
 if npos == goal:
 return (move, depth + 1)
 visited.add(npos)
 queue.append((npos, move, depth + 1))
return (None, float('inf'))
def nearest_neighbour_order(start, targets, obstacles, grid_w, grid_h):
 """
 Orders garbage by nearest-neighbour TSP using actual BFS cost.
 """
 remaining = list(targets)
 ordered = []
 current = tuple(start)
 while remaining:
 best = min(remaining, key=lambda t: bfs(current, t, obstacles, grid_w, grid_h)[1])
 ordered.append(best)
 remaining.remove(best)
 current = tuple(best)
 return ordered
# ──────────────────────────────────────────────────────────
# HEURISTIC
# ──────────────────────────────────────────────────────────
def heuristic_action(obs, _stuck_counter=None) -> str:
 if _stuck_counter is None:
 _stuck_counter = [0]
robot_mode = obs.get("robot_mode", "normal")
 r_pos = list(obs["robot_position"])
 obstacles = [list(o) for o in obs["obstacle_positions"]]
 grid_w, grid_h = obs["grid_size"]
if robot_mode == "recharging":
 home = obs.get("home_position", r_pos)
 move, _ = bfs(r_pos, home, obstacles, grid_w, grid_h)
 return move or "UP"
if robot_mode == "unloading":
 station = obs.get("unload_station", r_pos)
 move, _ = bfs(r_pos, station, obstacles, grid_w, grid_h)
 return move or "UP"
garbage = [tuple(g) for g in obs["garbage_positions"]]
 if not garbage: return "UP"
if tuple(r_pos) in garbage:
 _stuck_counter[0] = 0
 return "COLLECT"
ordered = nearest_neighbour_order(r_pos, garbage, obstacles, grid_w, grid_h)
 if _stuck_counter[0] >= 4 and len(ordered) > 1:
 ordered = [ordered[1], ordered[0]] + ordered[2:]
target = ordered[0]
 move, _ = bfs(r_pos, target, obstacles, grid_w, grid_h)
 if move and move != "COLLECT":
 return move
return "RIGHT"
# ──────────────────────────────────────────────────────────
# ACTION RESOLVER
# ──────────────────────────────────────────────────────────
def resolve_next_action(client, obs, context_history, stuck_counter=None) -> str:
 heuristic = heuristic_action(obs, stuck_counter)
 if _ql_agent is not None:
 q_action = _ql_agent.get_action(obs)
 if q_action is not None: return q_action
if _local_model is not None and _local_tokenizer is not None:
 try:
 prompt = f"### Instruction:\nAI control.\n\n### Input:\n{obs['message']}\n\n### Response:\n"
 inputs = _local_tokenizer(prompt, return_tensors="pt", truncation=True, max_length=512).to(_local_model.device)
 with __import__('torch').no_grad():
 outputs = _local_model.generate(**inputs, max_new_tokens=6, do_sample=False, pad_token_id=_local_tokenizer.eos_token_id)
 token = _local_tokenizer.decode(outputs[0][inputs["input_ids"].shape[1]:], skip_special_tokens=True).strip().upper()
 for valid in ["UP", "DOWN", "LEFT", "RIGHT", "COLLECT"]:
 if valid in token: return valid
 except Exception: pass
return heuristic
# ──────────────────────────────────────────────────────────
# EPISODE RUNNER
# ──────────────────────────────────────────────────────────
def print_log(msg):
 print(msg, flush=True)
def run_episode(client, task_id, obs):
 # Minimal START log for validator
 print_log(f"[START] task={task_id}")
total_reward = 0.0
 context_history = []
 step_idx = 0
 stuck_counter = [0]
for step_idx in range(1, MAX_STEPS + 1):
 action = resolve_next_action(client, obs, context_history, stuck_counter)
 try:
 res = requests.post(f"{ENV_URL}/step", json={"command": action})
 res.raise_for_status()
 step_data = res.json()
 except: break
obs = step_data["observation"]
 reward = step_data["reward"]
 done = step_data["done"]
 total_reward += reward
# Minimal STEP log for validator
 print_log(f"[STEP] step={step_idx} reward={round(reward, 2)} done={done}")
 if done: break
 time.sleep(0.01)
try:
 score = requests.get(f"{ENV_URL}/grade/{task_id}").json()["score"]
 except: score = 0.0
# Minimal END log for validator
 print_log(f"[END] task={task_id} score={score} steps={step_idx}")
 return score
# ──────────────────────────────────────────────────────────
# MAIN
# ──────────────────────────────────────────────────────────
def main():
 global _local_model, _local_tokenizer, _ql_agent
# Removed descriptive headers to keep stdout clean of anything but validation logs
if QLearningAgent is not None:
 _ql_agent = QLearningAgent()
try:
 from transformers import AutoModelForCausalLM, AutoTokenizer
 import torch
 _local_tokenizer = AutoTokenizer.from_pretrained(HF_MODEL_ID)
 has_cuda = torch.cuda.is_available()
 _local_model = AutoModelForCausalLM.from_pretrained(
 HF_MODEL_ID,
 torch_dtype=torch.float16 if has_cuda else torch.float32,
 device_map="auto" if has_cuda else None,
 load_in_4bit=has_cuda
 )
 _local_model.eval()
 except: pass
import argparse
 parser = argparse.ArgumentParser()
 parser.add_argument("--task", default="all")
 args = parser.parse_args()
if args.task in ["1", "easy"]: tasks = ["task_easy"]
 elif args.task in ["2", "medium"]: tasks = ["task_medium"]
 elif args.task in ["3", "hard"]: tasks = ["task_hard"]
 else: tasks = ["task_easy", "task_medium", "task_hard"]
client = OpenAI(api_key=HF_TOKEN, base_url=API_BASE_URL) if HF_TOKEN else None
for task_id in tasks:
 try:
 res = requests.post(f"{ENV_URL}/reset", json={"task_id": task_id})
 res.raise_for_status()
 obs = res.json()["observation"]
 run_episode(client, task_id, obs)
 except: continue
if __name__ == "__main__":
 main()