30b-f / scripts /run_gpqa_d_runtime_latency.py
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import argparse, json, os, re, sys, time, random
sys.path.insert(0, os.path.dirname(os.path.dirname(os.path.abspath(__file__))))
import torch
from tqdm import tqdm
from configs import get_config
from configs.paths import LOG_DIR, dim_paths, ensure_dirs
from src.detectors import BehaviorDetector
from src.interventions import generate_plain, generate_with_alpha
from src.utils import (
build_chat_prompt,
get_device,
load_model_and_tokenizer,
read_json,
read_jsonl,
setup_logger,
write_json,
)
def extract_boxed_letter(text):
if not text:
return None
matches, idx = [], 0
while True:
i = text.find("\\boxed", idx)
if i < 0:
break
j = text.find("{", i)
if j < 0:
break
depth, end = 0, -1
for k in range(j, len(text)):
if text[k] == "{":
depth += 1
elif text[k] == "}":
depth -= 1
if depth == 0:
end = k
break
if end > j:
matches.append(text[j + 1:end].strip())
idx = end + 1
else:
break
if not matches:
return None
last = matches[-1].strip().upper()
m = re.match(r"\(?\s*([ABCD])", last)
return m.group(1) if m else None
def repetition_score(text, tail_chars=400, ngram=30):
tail = text[-tail_chars:] if len(text) > tail_chars else text
if len(tail) < ngram * 2:
return 0.0
seen, repeated, total = {}, 0, 0
for i in range(len(tail) - ngram):
chunk = tail[i:i + ngram]
total += 1
if chunk in seen:
repeated += 1
else:
seen[chunk] = 1
return repeated / total if total else 0.0
def count_tokens(tokenizer, text):
return len(tokenizer(text, add_special_tokens=False)["input_ids"])
def think_tokens(tokenizer, cot):
seg = cot.split("</think>")[0] if "</think>" in cot else cot
return count_tokens(tokenizer, seg)
def cuda_sync():
if torch.cuda.is_available():
torch.cuda.synchronize()
def cuda_reset_peak():
if torch.cuda.is_available():
torch.cuda.empty_cache()
torch.cuda.reset_peak_memory_stats()
torch.cuda.synchronize()
def cuda_mem_stats():
if not torch.cuda.is_available():
return {
"max_mem_allocated_gb": None,
"max_mem_reserved_gb": None,
"current_mem_allocated_gb": None,
"current_mem_reserved_gb": None,
}
return {
"max_mem_allocated_gb": torch.cuda.max_memory_allocated() / (1024 ** 3),
"max_mem_reserved_gb": torch.cuda.max_memory_reserved() / (1024 ** 3),
"current_mem_allocated_gb": torch.cuda.memory_allocated() / (1024 ** 3),
"current_mem_reserved_gb": torch.cuda.memory_reserved() / (1024 ** 3),
}
def choose_subset_indices(n_total, limit, subset_seed):
rng = random.Random(subset_seed)
idxs = sorted(rng.sample(range(n_total), min(limit, n_total)))
return idxs
def main():
ap = argparse.ArgumentParser()
ap.add_argument("--dimension", default="monitoring")
ap.add_argument("--seed", type=int, default=64)
ap.add_argument("--subset-seed", type=int, default=64)
ap.add_argument("--limit", type=int, default=50)
ap.add_argument("--alphas", type=float, nargs="+", default=[1.0, 0.7, 0.3])
ap.add_argument("--sel-suffix", default="_allmonoV2")
ap.add_argument("--gen-max-tokens", type=int, default=None)
ap.add_argument("--data-path", default=None)
ap.add_argument("--out-suffix", default="_n50_s64")
ap.add_argument("--force", action="store_true")
args = ap.parse_args()
ensure_dirs(args.dimension)
cfg = get_config(args.dimension)
p = dim_paths(args.dimension)
gen_max = args.gen_max_tokens or cfg.GEN_MAX_NEW_TOKENS
temperature = getattr(cfg, "DEFAULT_TEMPERATURE", 0.6)
top_p = getattr(cfg, "DEFAULT_TOP_P", 0.95)
data_path = args.data_path or os.path.join(
os.path.dirname(os.path.dirname(os.path.abspath(__file__))),
"data",
"gpqa_d.jsonl",
)
out_path = os.path.join(p.RESULTS_DIR, f"run_gpqa_d_runtime_latency{args.out_suffix}.jsonl")
sum_path = os.path.join(p.RESULTS_DIR, f"run_gpqa_d_runtime_latency{args.out_suffix}_summary.json")
log = setup_logger(
"gpqa_runtime_latency",
os.path.join(LOG_DIR, f"run_gpqa_d_runtime_latency{args.out_suffix}.log"),
)
log.info("=" * 80)
log.info("GPQA-D wall-clock latency / throughput benchmark")
log.info(f"seed={args.seed}")
log.info(f"subset_seed={args.subset_seed}")
log.info(f"limit={args.limit}")
log.info(f"alphas={args.alphas}")
log.info(f"gen_max={gen_max}")
log.info(f"temperature={temperature}")
log.info(f"top_p={top_p}")
log.info(f"data_path={data_path}")
log.info("=" * 80)
items = read_jsonl(data_path)
subset_indices = choose_subset_indices(len(items), args.limit, args.subset_seed)
gt = {i: items[i]["answer"].strip().upper() for i in subset_indices}
log.info(f"subset_indices={subset_indices}")
need_steering = any(abs(float(a) - 1.0) > 1e-9 for a in args.alphas)
directions = {}
selected_layers = []
sel_path = None
if need_steering:
if not os.path.exists(p.DIRECTIONS):
raise FileNotFoundError(f"Missing directions file: {p.DIRECTIONS}")
dblob = torch.load(p.DIRECTIONS, map_location="cpu", weights_only=False)
directions_all = {int(L): v for L, v in dblob["directions"].items()}
base, ext = os.path.splitext(p.SELECTED_LAYERS)
sel_path = f"{base}{args.sel_suffix}{ext}"
if not os.path.exists(sel_path):
raise FileNotFoundError(f"Missing selected layer file: {sel_path}")
selected_json = read_json(sel_path)
selected_layers = [int(L) for L in selected_json["selected_layers"] if int(L) in directions_all]
directions = {L: directions_all[L] for L in selected_layers}
log.info(f"selected_layer_file={sel_path}")
log.info(f"selected_layers({len(selected_layers)})={selected_layers}")
if args.force and os.path.exists(out_path):
os.remove(out_path)
seen = set()
if os.path.exists(out_path):
for line in open(out_path, encoding="utf-8"):
if not line.strip():
continue
try:
seen.add(json.loads(line)["_key"])
except Exception:
pass
log.info(f"[resume] found {len(seen)} completed records")
todo = []
for pi in subset_indices:
for alpha in args.alphas:
key = f"P{pi}_A{float(alpha):.2f}"
if key not in seen:
todo.append((pi, float(alpha), key))
log.info(f"records to compute: {len(todo)} / {len(subset_indices) * len(args.alphas)}")
detector = BehaviorDetector(cfg)
device = get_device()
model = tokenizer = None
if todo:
log.info("Loading model...")
model, tokenizer = load_model_and_tokenizer(device=device)
fh = open(out_path, "a", encoding="utf-8") if todo else None
for pi, alpha, key in tqdm(todo, desc="gpqa_runtime_latency", dynamic_ncols=True, mininterval=10):
problem = items[pi]["problem"]
prompt = build_chat_prompt(tokenizer, problem, enable_thinking=True, system="")
prompt_tokens = count_tokens(tokenizer, prompt)
gen_seed = args.seed * 1000 + pi
cuda_reset_peak()
cuda_sync()
t0 = time.perf_counter()
if abs(alpha - 1.0) < 1e-9:
method = "baseline_no_hook"
cot = generate_plain(
model,
tokenizer,
prompt,
device,
max_new_tokens=gen_max,
do_sample=True,
temperature=temperature,
top_p=top_p,
seed=gen_seed,
)
else:
method = "crest_projection_removal"
alpha_per_layer = {L: alpha for L in selected_layers}
cot = generate_with_alpha(
model,
tokenizer,
prompt,
directions,
alpha_per_layer,
device,
max_new_tokens=gen_max,
do_sample=True,
temperature=temperature,
top_p=top_p,
seed=gen_seed,
)
cuda_sync()
elapsed = time.perf_counter() - t0
mem = cuda_mem_stats()
pred = extract_boxed_letter(cot)
det = detector.detect(cot)
rep = repetition_score(cot)
gen_tokens = count_tokens(tokenizer, cot)
ttok = think_tokens(tokenizer, cot)
rec = {
"_key": key,
"problem_idx": pi,
"dataset": "gpqa_d",
"subset_seed": args.subset_seed,
"limit": args.limit,
"seed": args.seed,
"method": method,
"alpha": alpha,
"temperature": temperature,
"top_p": top_p,
"gen_max": gen_max,
"prompt_tokens": prompt_tokens,
"generated_tokens": gen_tokens,
"think_tokens": ttok,
"wall_clock_s": elapsed,
"tokens_per_sec": gen_tokens / elapsed if elapsed > 0 else None,
"think_tokens_per_sec": ttok / elapsed if elapsed > 0 else None,
"max_mem_allocated_gb": mem["max_mem_allocated_gb"],
"max_mem_reserved_gb": mem["max_mem_reserved_gb"],
"current_mem_allocated_gb": mem["current_mem_allocated_gb"],
"current_mem_reserved_gb": mem["current_mem_reserved_gb"],
"n_layers": len(selected_layers) if method != "baseline_no_hook" else 0,
"selected_layer_file": sel_path,
"layers": selected_layers if method != "baseline_no_hook" else [],
"pred": pred,
"gt": gt.get(pi),
"correct": (pred == gt.get(pi)) if pred and gt.get(pi) else False,
"has_boxed": pred is not None,
"has_think_end": "</think>" in cot,
"mon_total": det["total"],
"repetition_score": rep,
"collapse": rep > 0.5,
"near_32768_think": ttok >= 0.95 * gen_max,
"problem": problem,
"cot": cot,
}
fh.write(json.dumps(rec, ensure_ascii=False) + "\n")
fh.flush()
log.info(
f"{key}: method={method} pred={pred} gt={gt.get(pi)} "
f"{'OK' if rec['correct'] else 'x'} "
f"wall={elapsed:.1f}s gen_tok={gen_tokens} think_tok={ttok} "
f"tok/s={rec['tokens_per_sec']:.2f} mem_alloc={mem['max_mem_allocated_gb']}GB "
f"mon={det['total']} rep={rep:.2f}"
)
if fh:
fh.close()
records = []
if os.path.exists(out_path):
for line in open(out_path, encoding="utf-8"):
if not line.strip():
continue
try:
records.append(json.loads(line))
except Exception:
pass
avg = lambda xs: sum(xs) / len(xs) if xs else 0.0
summary = {
"dataset": "GPQA-Diamond",
"benchmark": "wall_clock_latency_throughput",
"seed": args.seed,
"subset_seed": args.subset_seed,
"limit": args.limit,
"alphas": args.alphas,
"temperature": temperature,
"top_p": top_p,
"gen_max": gen_max,
"selected_layer_file": sel_path,
"selected_layers": selected_layers,
"n_selected_layers": len(selected_layers),
"subset_indices": subset_indices,
"out_jsonl": out_path,
"per_alpha": {},
}
log.info("\n=== SUMMARY: GPQA-D runtime latency / throughput ===")
log.info(
f"{'alpha':>6} {'n':>4} {'acc':>8} {'wall_s':>10} {'gen_tok':>10} "
f"{'think_tok':>10} {'tok/s':>8} {'mem_alloc':>10} {'mem_resv':>10} {'collapse':>9}"
)
for alpha in args.alphas:
rs = [r for r in records if abs(float(r["alpha"]) - float(alpha)) < 1e-9]
if not rs:
continue
n = len(rs)
n_correct = sum(bool(r["correct"]) for r in rs)
collapse_rate = sum(bool(r["collapse"]) for r in rs) / n if n else 0.0
item = {
"n": n,
"accuracy": n_correct / n if n else 0.0,
"n_correct": n_correct,
"mean_wall_clock_s": avg([r["wall_clock_s"] for r in rs]),
"median_wall_clock_s": sorted([r["wall_clock_s"] for r in rs])[n // 2] if n else 0.0,
"total_wall_clock_s": sum(r["wall_clock_s"] for r in rs),
"mean_generated_tokens": avg([r["generated_tokens"] for r in rs]),
"mean_think_tokens": avg([r["think_tokens"] for r in rs]),
"mean_tokens_per_sec": avg([r["tokens_per_sec"] for r in rs if r["tokens_per_sec"] is not None]),
"mean_think_tokens_per_sec": avg([r["think_tokens_per_sec"] for r in rs if r["think_tokens_per_sec"] is not None]),
"mean_max_mem_allocated_gb": avg([r["max_mem_allocated_gb"] for r in rs if r["max_mem_allocated_gb"] is not None]),
"mean_max_mem_reserved_gb": avg([r["max_mem_reserved_gb"] for r in rs if r["max_mem_reserved_gb"] is not None]),
"mean_mon": avg([r["mon_total"] for r in rs]),
"collapse_rate": collapse_rate,
"near_32768_think_rate": sum(bool(r["near_32768_think"]) for r in rs) / n if n else 0.0,
}
summary["per_alpha"][str(alpha)] = item
log.info(
f"{alpha:>6.2f} {n:>4} {item['accuracy']:>7.1%} "
f"{item['mean_wall_clock_s']:>10.1f} "
f"{item['mean_generated_tokens']:>10.0f} "
f"{item['mean_think_tokens']:>10.0f} "
f"{item['mean_tokens_per_sec']:>8.2f} "
f"{item['mean_max_mem_allocated_gb']:>10.2f} "
f"{item['mean_max_mem_reserved_gb']:>10.2f} "
f"{collapse_rate*100:>8.1f}%"
)
# Add relative speedup against alpha=1.
base = summary["per_alpha"].get("1.0") or summary["per_alpha"].get("1")
if base:
base_wall = base["mean_wall_clock_s"]
base_tok = base["mean_think_tokens"]
for k, item in summary["per_alpha"].items():
item["wall_clock_reduction_vs_alpha1"] = (
(base_wall - item["mean_wall_clock_s"]) / base_wall if base_wall else None
)
item["think_token_reduction_vs_alpha1"] = (
(base_tok - item["mean_think_tokens"]) / base_tok if base_tok else None
)
item["speedup_vs_alpha1"] = (
base_wall / item["mean_wall_clock_s"] if item["mean_wall_clock_s"] else None
)
write_json(summary, sum_path)
log.info(f"Saved {out_path}")
log.info(f"Saved {sum_path}")
log.info("Done.")
if __name__ == "__main__":
main()