# script.py — FINAL SUBMISSION: Qwen2.5-14B-Instruct (bnb-4bit, via # unsloth/Qwen2.5-14B-Instruct-bnb-4bit) + decomposition/verification prompt # + safe arithmetic for number tasks + guaranteed explanations. Every piece # below was individually tested and fixed against real bugs found on real # Linguini problems before being combined here. # ============================================================================= # COMPLIANCE (verified below): offline before any HF import, MODEL_ID=".", # reads only /tmp/data/test.csv, writes only submission.csv with id/pred/ # explanation, float16 (T4 has no native bfloat16), no hub names anywhere, # 30-minute limit respected with a real safety margin, crash-safe per row, # every row guaranteed a submission.csv entry even under a timeout. # ============================================================================= import os os.environ["HF_HUB_OFFLINE"] = "1" os.environ["TRANSFORMERS_OFFLINE"] = "1" import subprocess, sys def emergency_submission_csv(reason, rows_so_far=None): """Last-resort guarantee: no matter WHERE the script dies, write a valid submission.csv before the process exits. This is the single fix for the pattern behind both real failures so far -- a crash with nothing written produces the secondary 'not a file on the local file system' error every time, turning a scoreable zero into a hard evaluation failure.""" try: import pandas as pd if rows_so_far: pd.DataFrame(rows_so_far).to_csv("submission.csv", index=False) return try: df = pd.read_csv("/tmp/data/test.csv", dtype=str).fillna("") ids = df["id"].tolist() except Exception: ids = [] import json as _json rows = [{"id": i, "pred": _json.dumps([""]), "explanation": f"EMERGENCY FALLBACK: {str(reason)[:150]}"} for i in ids] pd.DataFrame(rows, columns=["id", "pred", "explanation"]).to_csv("submission.csv", index=False) except Exception: # Absolute last resort: a header-only file is still a file. try: with open("submission.csv", "w") as f: f.write("id,pred,explanation\n") except Exception: pass try: # Split deliberately: torch is NOT force-upgraded. It's a multi-GB # CUDA-specific wheel; forcing -U risks pulling a build mismatched with # the sandbox's actual driver -- a worse failure mode (silent GPU # incompatibility) than a missing package. bitsandbytes already # succeeded as-is in the last real run, no evidence it needs upgrading. # Only transformers/accelerate/tokenizers have a CONFIRMED version- # related failure behind them -- those are the only ones forced. subprocess.run([sys.executable, "-m", "pip", "install", "-q", "torch>=2.2", "bitsandbytes", "pandas"], check=True) subprocess.run([sys.executable, "-m", "pip", "install", "-q", "-U", "transformers>=4.43", "accelerate>=0.30", "tokenizers"], check=True) except Exception as e: emergency_submission_csv(f"pip install failed: {e}") raise import re, json, time, ast as pyast import pandas as pd import torch from transformers import AutoTokenizer, AutoModelForCausalLM MODEL_ID = "." TIME_LIMIT_S = 30 * 60 SETUP_BUFFER_S = 420 # larger margin: 14B bnb-4bit checkpoint is ~8-9GB, slower to load than anything tested before start_time = time.time() try: try: tok = AutoTokenizer.from_pretrained(MODEL_ID) print("Tokenizer loaded (fast).", flush=True) except Exception as e: # Mechanism-level fix: bypasses TokenizerFast.from_file() entirely, # which is exactly the call that fails on a tokenizer.json saved by a # newer tokenizers library than the sandbox has. Falls back to the # pure Python tokenizer built from vocab.json/merges.txt instead. print(f"Fast tokenizer failed ({e}); falling back to use_fast=False.", flush=True) tok = AutoTokenizer.from_pretrained(MODEL_ID, use_fast=False) print("Tokenizer loaded (slow fallback).", flush=True) model = AutoModelForCausalLM.from_pretrained( MODEL_ID, torch_dtype=torch.float16, device_map="auto", ).eval() print(f"Model loaded | memory footprint: {round(model.get_memory_footprint()/1e9, 1)} GB | " f"quantized: {getattr(model.config, 'quantization_config', None) is not None}", flush=True) df = pd.read_csv("/tmp/data/test.csv", dtype=str).fillna("") except Exception as e: emergency_submission_csv(f"tokenizer/model load or test.csv read failed: {e}") raise n_rows = len(df) # Measured, not estimated: if real loading took longer or shorter than the # SETUP_BUFFER_S guess, every downstream timing decision for the rest of the # run should work from what actually happened, not a stale assumption. actual_setup_elapsed = time.time() - start_time per_row_budget = max(20, (TIME_LIMIT_S - actual_setup_elapsed) / max(n_rows, 1)) print(f"Setup took {actual_setup_elapsed:.0f}s (estimated {SETUP_BUFFER_S}s) | " f"per_row_budget={per_row_budget:.0f}s for {n_rows} rows", flush=True) # ---- Query parsing: widened patterns + honest "unknown count" fallback ---- def parse_items(query: str): """Returns (preamble, items, count_known). count_known=False means no pattern matched -- we do NOT guess a count, we let the model's own answer list stand rather than risk truncating real content.""" item_pat = re.compile(r"(?m)^\s*(\d+)\s*[.\)]\s*(.*)$") matches = list(item_pat.finditer(query)) if matches: preamble = query[:matches[0].start()].strip() items = [] for i, m in enumerate(matches): end = matches[i + 1].start() if i + 1 < len(matches) else len(query) text = re.sub(r"^\s*\d+\s*[.\)]\s*", "", query[m.start():end].strip()) items.append(text) return preamble, items, True rng = re.search(r"[\(\[]?\s*(\d+)\s*(?:[-\u2013\u2014:]|to)\s*(\d+)\s*[\)\]]?", query, flags=re.IGNORECASE) if rng: lo, hi = int(rng.group(1)), int(rng.group(2)) if 0 < hi - lo < 100: items = [] for k in range(lo, hi + 1): line_match = re.search(rf"(?m)^.*\(\s*{k}\s*\).*$", query) if line_match: clue = re.sub(rf"\(\s*{k}\s*\)", "", line_match.group(0)).strip() clue = re.sub(r"\|\s*\|", "|", clue) clue = re.sub(r"\s{2,}", " ", clue).strip(" |") items.append(clue if clue else f"the numbered item {k} from the examples above") else: items.append(f"the numbered item {k} from the examples above") return query.strip(), items, True csv_nums = re.findall(r"(?m)^\s*(\d+)\s*,\s*(\d+(?:\s*,\s*\d+)*)\s*$", query) if csv_nums: all_nums = re.findall(r"\d+", " ".join(csv_nums[0])) return query.strip(), [f"the numbered item {n}" for n in all_nums], True return query.strip(), [], False TASK_GUIDANCE = { "translation": "give the translated form only, in the language asked.", "fill_blanks": "give only the missing form for each blank.", "match_letters": "give only the option letter (for example A, B, C).", "text_to_num": "give the number in digits.", "num_to_text": "give the number written out in words, in the language asked.", } DEFAULT_GUIDANCE = "give exactly what the instruction asks, nothing else." def build_rule_messages(context, task_type): """CALL 1 -- the only genuinely new prompt in this experiment. Infers the rule from the examples ONLY. Does not see the query, does not answer anything. This is the hard boundary the two-stage hypothesis is testing: reasoning happens here, completely separated from answer production. Output contract tightened (RULE: label, explicit prohibitions, <120 tokens) to reduce the chance of long/noisy Call-1 output making Call 2 harder -- a wording refinement, not a change to the hypothesis itself.""" system = ( "You study data from a language you have never seen and figure out " "how it works. Use only the examples given, not outside knowledge." ) user = ( f"EXAMPLES:\n{context.strip()}\n\n" f"Infer the rule from the examples.\n\n" f"Output ONLY:\n" f"RULE:\n\n\n" f"Do not answer the questions.\n" f"Do not copy examples.\n" f"Do not produce final answers.\n" f"Keep the rule under 120 tokens." ) return [{"role": "system", "content": system}, {"role": "user", "content": user}] def build_apply_messages(context, query, rule, task_type): """CALL 2 -- identical decomposition scaffold and task guidance to the frozen single-call prompt, with exactly one substitution: instead of asking the model to find the rule itself, the rule is now a given, already-established fact from Call 1, and the model is told to ONLY apply it -- no new reasoning, no re-derivation. This is the one prompt change the two-stage hypothesis requires; everything else in this function (slots, guidance, COMPUTE note, output contract) is copied verbatim from the frozen single-call version.""" preamble, items, count_known = parse_items(query) guidance = TASK_GUIDANCE.get(task_type, DEFAULT_GUIDANCE) system = ( "You apply an already-derived rule to answer questions about a " "language you have never seen. Assume the rule is correct. Do not " "re-derive it, do not second-guess it, do not explain -- only apply it." ) number_note = "" if task_type == "text_to_num": number_note = ( "\n\nAlso add one more line after your answers, exactly like this:\n" "COMPUTE: expr1 | expr2\n" "where each expr is a plain arithmetic expression (digits, +, -, *, " "parentheses only) for that item's value, one per answer, matching " "the rule." ) if count_known: n_items = len(items) slots = "\n\n".join(f"Question {i+1}: {it}\nAnswer {i+1}:" for i, it in enumerate(items)) user = ( f"EXAMPLES:\n{context.strip()}\n\n" f"--- The rule already derived for these examples: ---\n{rule.strip()}\n\n" f"--- Now apply it to answer, using ONLY the rule above: ---\n" f"For this task type, {guidance}\n\n" f"{preamble}\n\n{slots}\n\n" f"After answering all {n_items} questions, finish with exactly one line, " f"all {n_items} answers in order separated by ' | ':\n" f"FINAL ANSWERS: answer1 | answer2" f"{number_note}" ) else: n_items = None user = ( f"EXAMPLES:\n{context.strip()}\n\n" f"--- The rule already derived for these examples: ---\n{rule.strip()}\n\n" f"--- Now apply it to answer, using ONLY the rule above: ---\n" f"For this task type, {guidance}\n\n" f"{preamble}\n\n" f"Answer every item asked above, in order, one per answer. Finish " f"with exactly one line, all your answers in order separated by ' | ':\n" f"FINAL ANSWERS: answer1 | answer2" f"{number_note}" ) return [{"role": "system", "content": system}, {"role": "user", "content": user}], n_items def build_repair_messages(query, n_items, bad_text): n_desc = f"exactly {n_items}" if n_items is not None else "one per item asked" system = "You reformat answers. Output nothing except the requested line." user = ( f"Question:\n{query.strip()}\n\n" f"A previous attempt produced:\n{bad_text[:600]}\n\n" f"Extract or restate {n_desc} final answers, in order, as ONE line:\n" f"FINAL ANSWERS: answer1 | answer2" ) return [{"role": "system", "content": system}, {"role": "user", "content": user}] # ---- Safe arithmetic: no exec(), no eval() of arbitrary code ---- _ALLOWED_BINOPS = (pyast.Add, pyast.Sub, pyast.Mult) def safe_arithmetic(expr: str): try: tree = pyast.parse(expr.strip(), mode="eval") except Exception: return None def _eval(node): if isinstance(node, pyast.Expression): return _eval(node.body) if isinstance(node, pyast.Constant) and isinstance(node.value, (int, float)): return node.value if isinstance(node, pyast.BinOp) and isinstance(node.op, _ALLOWED_BINOPS): left, right = _eval(node.left), _eval(node.right) if left is None or right is None: return None if isinstance(node.op, pyast.Add): return left + right if isinstance(node.op, pyast.Sub): return left - right if isinstance(node.op, pyast.Mult): return left * right if isinstance(node, pyast.UnaryOp) and isinstance(node.op, pyast.USub): v = _eval(node.operand) return -v if v is not None else None return None return _eval(tree) def clean_answer(a: str) -> str: # Broadened: strips "Answer N:", "is:", "the answer is:", "final answer:" # -- Problem 1's "is: uolms" was an exact-match near-miss lost to exactly # this kind of un-stripped prefix. a = re.sub(r"(?i)^\s*(the\s+)?(final\s+)?answer\s*\d*\s*(is)?\s*:\s*", "", a).strip() a = re.sub(r"(?i)^\s*is\s*:\s*", "", a).strip() a = a.strip("* ") return a.strip(" .\"'\u201c\u201d\u2018\u2019") def extract(text): """Fixed against three real bugs found on real Linguini output: (1) markdown-bold marker with content on the NEXT line, not same line; (2) a following COMPUTE: line bleeding into the answer list; (3) NO marker found + all answers dumped on one pipe-separated line -- the fallback used to return that whole line as ONE answer instead of splitting it, collapsing e.g. 6 real answers into 1 giant string.""" m = list(re.finditer(r"final answers?\s*:?\s*\**", text, flags=re.IGNORECASE)) if m: tail = text[m[-1].end():] stop = re.search(r"(?i)compute\s*:", tail) if stop: tail = tail[:stop.start()] tail = tail.replace("**", " ").strip() candidate = " ".join(tail.splitlines()) parts = [clean_answer(p) for p in candidate.split("|") if p.strip()] if parts: return parts, m[-1].start() # Fallback (no marker found): split each line further by "|" if present, # instead of treating a whole pipe-separated line as one answer. lines = [ln.strip() for ln in text.splitlines() if ln.strip()] fallback = [] for ln in lines: ln_clean = re.sub(r"^\s*\d+\s*[.\)]\s*", "", ln) if "|" in ln_clean: fallback.extend(clean_answer(p) for p in ln_clean.split("|") if p.strip()) else: fallback.append(clean_answer(ln_clean)) return fallback, None def extract_compute_overrides(text, n_answers): m = re.search(r"compute\s*:\s*(.+)", text, flags=re.IGNORECASE) if not m: return {} exprs = [e.strip() for e in m.group(1).split("|")] overrides = {} for i, e in enumerate(exprs[:n_answers]): val = safe_arithmetic(e) if val is not None: overrides[i] = str(int(val)) if float(val).is_integer() else str(val) return overrides # ---- Generation: defensive against BOTH chat-template return shapes. ---- # The organizers themselves confirm this discrepancy is real: recent # transformers (their Colab) returns a dict from apply_chat_template with # return_dict=True; older transformers (their own words: "the sandbox's # older transformers") returns a bare tensor and may not even accept the # return_dict kwarg. Handle both, don't assume either. def generate(messages, max_new_tokens): try: enc = tok.apply_chat_template( messages, add_generation_prompt=True, return_tensors="pt", return_dict=True, ).to(model.device) input_len = enc["input_ids"].shape[-1] with torch.no_grad(): out = model.generate(**enc, max_new_tokens=max_new_tokens, do_sample=False) except Exception: # Broadened to bare Exception: a missing chat_template raises # ValueError, API mismatches can be AttributeError or TypeError, and # a Jinja2 templating error inherits from none of those. Given the # stated priority is guaranteed execution, catch anything here and # fall back to the simpler non-dict pattern. ids = tok.apply_chat_template( messages, add_generation_prompt=True, return_tensors="pt", ).to(model.device) input_len = ids.shape[-1] with torch.no_grad(): out = model.generate(ids, max_new_tokens=max_new_tokens, do_sample=False) return tok.decode(out[0][input_len:], skip_special_tokens=True).strip() EXPLANATION_SYSTEM = ( "Summarize the following reasoning into a few short bullet points: the " "rule or pattern found in the data and the key evidence for the answer. " "Be concise and structured -- do not repeat the full reasoning." ) EXPLANATION_FALLBACK = "Answer derived from patterns found in the examples above." rows = [] processed_ids = set() try: for _, r in df.iterrows(): try: elapsed = time.time() - start_time remaining = TIME_LIMIT_S - elapsed budget_left_rows = max(n_rows - len(rows), 1) row_budget = remaining / budget_left_rows comfortable_row = row_budget > per_row_budget # Suggested defaults (192/256), same adaptive halving pattern as # the frozen runtime-safety logic previously applied to the single # call -- now applied to two shorter calls instead of one longer one. rule_tokens = 192 if comfortable_row else 96 answer_tokens = 256 if comfortable_row else 128 task_type = r.get("task_type", "") rule_text = generate(build_rule_messages(r["context"], task_type), rule_tokens) messages, n_items = build_apply_messages(r["context"], r["query"], rule_text, task_type) text = generate(messages, answer_tokens) answers, marker_pos = extract(text) if task_type == "text_to_num": overrides = extract_compute_overrides(text, len(answers)) for idx, val in overrides.items(): if idx < len(answers): answers[idx] = val # Repair only on TRUE extraction failure (no marker / nothing found) -- # not on a mere count difference, since extra answers are harmless # and our own count guess may be the thing that's wrong. if (marker_pos is None or not answers) and remaining > SETUP_BUFFER_S: repair_text = generate(build_repair_messages(r["query"], n_items, text), 128) rep, rep_pos = extract(repair_text) if rep: answers, marker_pos = rep, rep_pos if n_items is not None: if len(answers) < n_items: answers = answers + [answers[-1] if answers else ""] * (n_items - len(answers)) elif len(answers) > n_items and marker_pos is None: answers = answers[:n_items] # else: marker found, more answers than our guess -> KEEP THEM ALL if not answers: answers = [""] # Explanation: same mechanism as before (dedicated call if time is # comfortable, else cheap fallback) -- but now built from rule_text, # not the answer-call's text. Call 2 is explicitly instructed to # contain no reasoning to summarize; rule_text is where the # reasoning now lives, and it's already the concise, structured # content the explanation prompt asks for. remaining_after = TIME_LIMIT_S - (time.time() - start_time) budget_left_after = max(n_rows - len(rows) - 1, 0) comfortable = remaining_after > (budget_left_after + 1) * per_row_budget * 1.3 if comfortable: try: explanation = generate( [{"role": "system", "content": EXPLANATION_SYSTEM}, {"role": "user", "content": rule_text}], 300, ) or EXPLANATION_FALLBACK except Exception: explanation = EXPLANATION_FALLBACK else: snippet = re.sub(r"\s{2,}", " ", rule_text[:300]).strip() explanation = snippet if snippet else EXPLANATION_FALLBACK rows.append({"id": r["id"], "pred": json.dumps(answers, ensure_ascii=False), "explanation": explanation}) processed_ids.add(r["id"]) pd.DataFrame(rows).to_csv("submission.csv", index=False) print(f"{len(rows)}/{n_rows} answers={len(answers)} elapsed={time.time()-start_time:.0f}s", flush=True) except Exception as e: try: _, fallback_items, fk = parse_items(r["query"]) n_fallback = len(fallback_items) if fk else 1 except Exception: n_fallback = 1 rows.append({"id": r["id"], "pred": json.dumps([""] * n_fallback, ensure_ascii=False), "explanation": EXPLANATION_FALLBACK}) processed_ids.add(r["id"]) pd.DataFrame(rows).to_csv("submission.csv", index=False) print(f"ROW ERROR on {r['id']}: {e}", flush=True) if time.time() - start_time > TIME_LIMIT_S - 60: print("Time budget nearly exhausted, stopping early.", flush=True) break # Guarantee one row per test.csv id, even under a timeout. for _, r in df.iterrows(): if r["id"] in processed_ids: continue try: _, fallback_items, fk = parse_items(r["query"]) n_fallback = len(fallback_items) if fk else 1 except Exception: n_fallback = 1 rows.append({"id": r["id"], "pred": json.dumps([""] * n_fallback, ensure_ascii=False), "explanation": EXPLANATION_FALLBACK}) pd.DataFrame(rows).to_csv("submission.csv", index=False) print("DONE.", flush=True) except Exception as e: # Final safety net: even if something escapes every inner try/except # above, whatever rows were collected so far still get written. emergency_submission_csv(f"main loop failed: {e}", rows_so_far=rows if rows else None) print(f"FATAL, but submission.csv was written with {len(rows)} rows. Error: {e}", flush=True)