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tinyforge-zero/experiments/recursive_bootstrap.py

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Ship every paper-referenced experiment script Reorganizes the repo so every section of the paper has a corresponding script. Previously only the core recipe + control + evals were here. New subdirs: - tts/ — test-time sampling (§2.2, §3.3): scaling sweep, HE, MATH-500, AIME, 14B-recipe + TTS, 8B-raw-TTS control. - experiments/ — every §3 finding as a runnable script: · self_consistency (§3.4) · recipe_x_tts_synergy (§3.5, novel) · mbpp_seeded_cross_arch (§3.9) · cross_domain_code_to_math (§3.10) · self_correction_math_{naive,fixed} (§3.10, the catastrophic-then-recovered case) · math500_seeded_mining (§3.10 distribution mismatch) · bcb_hard_eval (§3.10 distribution mismatch) · recursive_bootstrap (§3.10 plateau) · diversity_cued_mining (§3.10 low yield) · aime_scaling (TTS curve) · star_baseline_gsm8k (related-work baseline) - evals/ — moved out of recipe/ (eval_raw, eval_plus, confirm) Also adds: bootstrap_14b_4bit_harvest, curriculum_code, math_bootstrap to recipe/ for completeness. REPRODUCE.md now maps each paper section / table / figure to its exact script and expected output.
2026-05-13 21:09:54 +05:00
"""Recursive self-bootstrap: iter1->iter2->iter3.
Iter k:
- Use model from previous iter (or base for iter 1)
- Mine pairs on MBPP-train
- Train fresh LoRA from BASE on accumulated pairs
- Eval on HE
"""
import os, json, time, re, subprocess, tempfile, argparse, gc, random
os.environ.setdefault("HF_HOME", "/workspace/hf")
os.environ["TRANSFORMERS_VERBOSITY"] = "error"
import torch
from datasets import load_dataset
T0 = time.time()
def log(m): print(f"[{time.time()-T0:7.1f}s] {m}", flush=True)
def run_python(code, timeout=10):
with tempfile.NamedTemporaryFile("w", suffix=".py", delete=False) as f:
f.write(code); path = f.name
try:
r = subprocess.run(["python3", path], capture_output=True, timeout=timeout, text=True, cwd="/tmp")
return r.returncode == 0
except subprocess.TimeoutExpired: return False
finally:
try: os.unlink(path)
except: pass
def mbpp_prompt(p):
return f"# Task: {p['prompt']}\n# Tests:\n# " + "\n# ".join(p["test_list"]) + "\n\n"
def he_prompt(p): return p["prompt"]
def vllm_gen(llm, prompts, max_new=400, temperature=0.0, n=1, lora_req=None, stops=None):
from vllm import SamplingParams
sp = SamplingParams(temperature=temperature, top_p=0.95 if temperature > 0 else 1.0,
max_tokens=max_new, n=n,
stop=stops or ["\nclass Test", "\nif __name__", "\n\nprint", "\nassert "])
if lora_req:
out = llm.generate(prompts, sp, lora_request=lora_req, use_tqdm=False)
else:
out = llm.generate(prompts, sp, use_tqdm=False)
if n == 1: return [o.outputs[0].text for o in out]
return [[c.text for c in o.outputs] for o in out]
def main():
ap = argparse.ArgumentParser()
ap.add_argument("--model", required=True)
ap.add_argument("--tag", required=True)
ap.add_argument("--out_dir", required=True)
ap.add_argument("--n_iters", type=int, default=3)
ap.add_argument("--n_mining", type=int, default=200)
ap.add_argument("--attempts_per", type=int, default=8)
args = ap.parse_args()
os.makedirs(args.out_dir, exist_ok=True)
from vllm import LLM, SamplingParams
from vllm.lora.request import LoRARequest
from transformers import AutoTokenizer
log(f"loading {args.model}")
tok = AutoTokenizer.from_pretrained(args.model)
if tok.pad_token is None: tok.pad_token = tok.eos_token
he = list(load_dataset("openai_humaneval", split="test"))
mbpp_full = list(load_dataset("mbpp", split="train"))
random.seed(42); random.shuffle(mbpp_full)
seeds_pool = []
for p in mbpp_full[:args.n_mining * args.n_iters]:
prompt_text = p.get("prompt") or p.get("text", "")
if prompt_text and p.get("test_list"):
seeds_pool.append({"prompt": prompt_text, "test_list": p["test_list"]})
log(f"seeds pool: {len(seeds_pool)}")
iter_results = []
accumulated_pairs = []
current_adapter = None # path
for it in range(1, args.n_iters + 1):
log(f"\n========== ITER {it} ==========")
# Load model (with current adapter if exists)
llm = LLM(model=args.model, dtype="bfloat16", gpu_memory_utilization=0.85,
max_model_len=2048,
enable_lora=(current_adapter is not None), max_lora_rank=16)
lora_req = LoRARequest("cur", 1, current_adapter) if current_adapter else None
log(f" loaded {'(with adapter)' if current_adapter else '(base)'}")
# Mine pairs using current model
seeds = seeds_pool[(it-1)*args.n_mining:it*args.n_mining]
log(f" mining from {len(seeds)} new seeds")
prompts = [mbpp_prompt(p) for p in seeds]
greedy_outs = vllm_gen(llm, prompts, max_new=400, lora_req=lora_req)
hard_idx = []
for i, (p, raw) in enumerate(zip(seeds, greedy_outs)):
test_code = raw + "\n\n" + "\n".join(p["test_list"])
if not run_python(test_code, 8):
hard_idx.append(i)
log(f" greedy: {len(seeds)-len(hard_idx)} pass, {len(hard_idx)} hard")
if hard_idx:
hard_prompts = [mbpp_prompt(seeds[i]) for i in hard_idx]
sample_outs = vllm_gen(llm, hard_prompts, max_new=400, temperature=0.8,
n=args.attempts_per, lora_req=lora_req)
new_pairs = []
for j, i in enumerate(hard_idx):
attempts = sample_outs[j]
passes = []
for a in attempts:
if run_python(a + "\n\n" + "\n".join(seeds[i]["test_list"]), 8):
passes.append(a); break
if passes:
new_pairs.append({"problem": seeds[i]["prompt"], "tests": seeds[i]["test_list"],
"broken": greedy_outs[i].strip(), "fixed": passes[0].strip(),
"iter": it})
accumulated_pairs.extend(new_pairs)
log(f" mined {len(new_pairs)} new pairs (cumulative: {len(accumulated_pairs)})")
# Eval current model on HE
log(f" eval HE...")
he_outs = vllm_gen(llm, [he_prompt(p) for p in he], max_new=400, lora_req=lora_req,
stops=["\nclass ", "\nif __name__", "\n\nprint"])
he_correct = 0
for p, raw in zip(he, he_outs):
full = p["prompt"] + "\n" + raw
test_code = full + "\n\n" + p["test"] + f"\n\ncheck({p['entry_point']})"
if run_python(test_code, 10): he_correct += 1
log(f" HE iter{it} (pre-train): {he_correct}/{len(he)}")
iter_results.append({"iter": it, "he_pretrain": he_correct, "cumulative_pairs": len(accumulated_pairs)})
# Tear down vLLM, train new adapter on accumulated pairs
del llm; gc.collect(); torch.cuda.empty_cache()
if len(accumulated_pairs) < 5:
log(f" too few pairs to train, skipping iter {it} training")
continue
from transformers import AutoModelForCausalLM, TrainingArguments, Trainer
from datasets import Dataset as HFDataset
from peft import LoraConfig, get_peft_model
def mk_ex(r):
user = (f"# Task: {r['problem']}\n# Tests:\n# " + "\n# ".join(r['tests']) + "\n"
f"# My broken attempt:\n{r['broken']}\n# Corrected:\n")
target = r["fixed"]
full = user + target
full_ids = tok(full, add_special_tokens=False)["input_ids"]
user_ids = tok(user, add_special_tokens=False)["input_ids"]
MAX = 1024
full_ids = full_ids[:MAX]
labels = list(full_ids)
n_user = min(len(user_ids), len(labels))
for i in range(n_user): labels[i] = -100
pad = MAX - len(full_ids)
return {"input_ids": full_ids + [tok.pad_token_id]*pad,
"attention_mask": [1]*len(full_ids) + [0]*pad,
"labels": labels + [-100]*pad}
log(f" training fresh adapter on {len(accumulated_pairs)} pairs...")
model = AutoModelForCausalLM.from_pretrained(args.model, torch_dtype=torch.bfloat16, device_map="cuda:0")
lora_cfg = LoraConfig(r=16, lora_alpha=32, lora_dropout=0.05, bias="none",
target_modules=["q_proj", "k_proj", "v_proj", "o_proj"], task_type="CAUSAL_LM")
model = get_peft_model(model, lora_cfg)
ds_train = HFDataset.from_list([mk_ex(r) for r in accumulated_pairs])
targs = TrainingArguments(
output_dir=f"{args.out_dir}/iter{it}_ckpt", num_train_epochs=2,
per_device_train_batch_size=1, gradient_accumulation_steps=4,
learning_rate=1e-4, bf16=True, logging_steps=20,
save_strategy="no", report_to="none", remove_unused_columns=False, warmup_ratio=0.05,
)
Trainer(model=model, args=targs, train_dataset=ds_train, tokenizer=tok).train()
adapter_dir = f"{args.out_dir}/iter{it}_adapter"
model.save_pretrained(adapter_dir)
del model; gc.collect(); torch.cuda.empty_cache()
current_adapter = adapter_dir
# Re-eval with new adapter to get post-train HE
log(f" eval post-train HE...")
llm = LLM(model=args.model, dtype="bfloat16", gpu_memory_utilization=0.85, max_model_len=2048,
enable_lora=True, max_lora_rank=16)
lora_req = LoRARequest(f"iter{it}", it, current_adapter)
he_outs = vllm_gen(llm, [he_prompt(p) for p in he], max_new=400, lora_req=lora_req,
stops=["\nclass ", "\nif __name__", "\n\nprint"])
he_correct = 0
for p, raw in zip(he, he_outs):
full = p["prompt"] + "\n" + raw
test_code = full + "\n\n" + p["test"] + f"\n\ncheck({p['entry_point']})"
if run_python(test_code, 10): he_correct += 1
log(f" HE iter{it} (post-train): {he_correct}/{len(he)}")
iter_results[-1]["he_posttrain"] = he_correct
del llm; gc.collect(); torch.cuda.empty_cache()
# Save pairs and results
with open(f"{args.out_dir}/pairs.jsonl", "w") as fh:
for r in accumulated_pairs: fh.write(json.dumps(r) + "\n")
result = {"model": args.model, "tag": args.tag, "n_iters": args.n_iters,
"iter_results": iter_results, "total_pairs": len(accumulated_pairs),
"elapsed_s": time.time() - T0}
with open(f"{args.out_dir}/result.json", "w") as fh: json.dump(result, fh, indent=2)
print()
print("=" * 70)
print(f" {args.model} — RECURSIVE BOOTSTRAP")
for r in iter_results:
pre = r.get("he_pretrain", "-")
post = r.get("he_posttrain", "-")
print(f" iter {r['iter']}: cum_pairs={r['cumulative_pairs']} HE_pre={pre} HE_post={post}")
print(f" Time: {time.time()-T0:.0f}s")
print("=" * 70)
if __name__ == "__main__":
main()
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