30 / scripts /bench_test_generate_iv.py
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"""Generate test-split predictions for Spatial-Qwen IV / Neural-IV checkpoints.
Why this file exists (vs bench_test_generate.py):
bench_test_generate.py reuses `scripts/batch_bench_spatial_beats_qa.py`,
which imports `build_model` from `train_spatial_beats_qa.py`. That path
is the **BEATs** encoder and the model class/config fields are different
from the IV / Neural-IV baselines, so it cannot load IV checkpoints
(spatial_encoder_type=iv|neural_iv). This script is the IV sibling:
same output schema (`predictions.jsonl`), same CLI, but it builds the
model through `train_spatial_iv_qa.py`.
Generation-only; scoring stays in scripts/score_test_predictions.py.
Usage (single checkpoint):
torchrun --nproc_per_node=8 scripts/bench_test_generate_iv.py \\
--checkpoint-paths runs/v13d_easy_llmqa_iv/stage2_encoder_lora/checkpoints/best_trainable.pt \\
--qa-root /path/to/easy_filtered --split test \\
--output-dir runs/v13d_easy_llmqa_iv/stage2_encoder_lora/bench/test
Multiple checkpoints / globbing behaves the same as bench_test_generate.py.
"""
from __future__ import annotations
import argparse
import json
import os
import sys
from pathlib import Path
from typing import Any, Dict, List, Optional
import torch
from tqdm.auto import tqdm
REPO_ROOT = os.path.abspath(os.path.join(os.path.dirname(__file__), ".."))
if REPO_ROOT not in sys.path:
sys.path.insert(0, REPO_ROOT)
# Generic helpers — these do NOT depend on the BEATs vs IV path.
from scripts.batch_bench_spatial_beats_qa import ( # type: ignore # noqa: E402
clean_generated_answer,
filter_dataset,
finalize_distributed_prediction_file,
get_model_device,
resolve_checkpoint_paths,
to_generation_inputs,
)
# IV-path model builder. Importing the train module as a whole runs its
# argparse at import time if you `python train_spatial_iv_qa.py ...` but
# as a library import it's fine.
from train_spatial_iv_qa import ( # type: ignore # noqa: E402
DEFAULT_OUTPUT_DIR,
DEFAULT_QA_ROOT,
DEFAULT_SPATIAL_QWEN_REPO,
QwenAudioFeatureCache,
SpatialBeatsQACollator,
apply_llm_lora,
build_model,
build_processor,
build_qa_dataset,
cleanup_distributed,
configure_encoder_lora_training,
distributed_barrier,
freeze_all_but_projector,
get_rank,
is_main_process,
make_loader,
normalize_answer,
rank0_print,
setup_distributed,
shard_dataset_for_rank,
unwrap_model,
)
# --------------------------------------------------------------------------- #
# IV-specific model instantiation #
# --------------------------------------------------------------------------- #
def _load_json(path: str) -> Dict[str, Any]:
with open(path, "r", encoding="utf-8") as handle:
return json.load(handle)
def infer_train_args_path(checkpoint_path: str) -> str:
"""`<run_dir>/checkpoints/foo_trainable.pt` → `<run_dir>/train_args.json`."""
run_dir = os.path.dirname(os.path.dirname(os.path.abspath(checkpoint_path)))
path = os.path.join(run_dir, "train_args.json")
if not os.path.exists(path):
raise FileNotFoundError(
f"train_args.json not found for checkpoint: {checkpoint_path} "
f"(expected at {path}). The IV training script writes this at "
"the start of training; make sure you're pointing at a completed "
"run dir, not just a bare checkpoint."
)
return path
# IV-specific fields we expect in train_args.json. If the user's runs were
# done with an older training script that didn't dump all of these, we fall
# back to sensible defaults that match the launch shell.
_IV_DEFAULTS: Dict[str, Any] = {
"spatial_encoder_type": "iv",
"iv_token_dim": 256,
"iv_projector_hidden_dim": 512,
"iv_num_mel_bins": 64,
"iv_band_pool": 0,
"iv_output_scale": 0.02,
"iv_feature_to_seld_ratio": 5,
"iv_downsample_factor": 4,
"neural_iv_hidden_channels": 64,
"baseline_repo_path": "/apdcephfs_cq10/share_1603164/user/schmittzhu/code/DCASE2024_seld_baseline",
"seld233_feature_stats_dir": "/apdcephfs_cq10/share_1603164/user/schmittzhu/data/seld_feat_label/starss23_plus_foa_16k_29cls",
"train_mode": "projector_only",
"lora_r": 16,
"lora_alpha": 32,
"lora_dropout": 0.05,
"lora_target_modules": ["q_proj", "k_proj", "v_proj", "o_proj"],
"lora_target_prefixes": ["thinker.model"],
"dtype": "bfloat16",
"attn_impl": "auto",
"iv_modules_fp32": False,
"spatial_qwen_repo": DEFAULT_SPATIAL_QWEN_REPO,
}
def build_eval_model_args(runtime_args: argparse.Namespace,
train_args: Dict[str, Any]) -> argparse.Namespace:
merged = dict(_IV_DEFAULTS)
merged.update({k: v for k, v in train_args.items() if v is not None})
# Runtime-only knobs (device / attn impl) may be overridden via CLI.
# CRITICAL: always forward runtime_args.device so DDP ranks each land on
# their own cuda:{LOCAL_RANK}. train_args.json stores the training-time
# device (usually "cuda:0"), which would otherwise pile all 8 ranks onto
# cuda:0 and OOM.
merged["device"] = runtime_args.device
if getattr(runtime_args, "device_map", None):
merged["device_map"] = runtime_args.device_map
if getattr(runtime_args, "attn_impl", None):
merged["attn_impl"] = runtime_args.attn_impl
merged["dtype"] = runtime_args.dtype
merged.setdefault("model_id", train_args.get("model_id")
or "/apdcephfs_cq10/share_1603164/user/schmittzhu/model/Qwen2.5-Omni-7B")
return argparse.Namespace(**merged)
def instantiate_iv_model_for_checkpoint(runtime_args: argparse.Namespace,
checkpoint_path: str):
train_args = _load_json(infer_train_args_path(checkpoint_path))
model_args = build_eval_model_args(runtime_args, train_args)
processor = build_processor(model_args.model_id, model_args.spatial_qwen_repo)
processor.tokenizer.padding_side = "left"
model = build_model(model_args, processor)
train_mode = str(model_args.train_mode)
if train_mode == "projector_only":
freeze_all_but_projector(model)
elif train_mode == "encoder_lora":
model, _ = apply_llm_lora(model, model_args)
configure_encoder_lora_training(model, model_args)
else:
raise ValueError(
f"Unsupported train_mode for IV baseline: {train_mode!r} "
f"(expected projector_only or encoder_lora)"
)
checkpoint = torch.load(checkpoint_path, map_location="cpu")
state_dict = checkpoint.get("trainable_state_dict", checkpoint)
load_result = model.load_state_dict(state_dict, strict=False)
model.eval()
return model, processor, train_args, checkpoint, load_result
# --------------------------------------------------------------------------- #
# Generation loop (same schema as bench_test_generate.py, no ablation) #
# --------------------------------------------------------------------------- #
def run_generation_bench(
model,
processor,
loader,
output_jsonl_path: str,
max_new_tokens: int,
num_beams: int,
do_sample: bool,
bench_name: str,
) -> Dict[str, Any]:
model.eval()
local_records: List[Dict[str, Any]] = []
rank = get_rank()
shard_output_path = f"{output_jsonl_path}.rank{rank}.jsonl"
os.makedirs(os.path.dirname(output_jsonl_path), exist_ok=True)
eval_model = unwrap_model(model)
input_device = get_model_device(eval_model)
with open(shard_output_path, "w", encoding="utf-8") as handle:
with torch.no_grad():
progress = tqdm(loader, desc=bench_name, leave=False,
disable=not is_main_process())
for step_i, batch in enumerate(progress):
generation_inputs = to_generation_inputs(batch, input_device)
generated = eval_model.generate(
**generation_inputs,
return_audio=False,
max_new_tokens=max_new_tokens,
num_beams=num_beams,
do_sample=do_sample,
)
ml = generation_inputs["input_ids"].shape[1]
generated = generated.detach().cpu()
for index in range(len(batch["meta"])):
prediction_ids = generated[index, ml:]
prediction_text = processor.tokenizer.decode(
prediction_ids, skip_special_tokens=True).strip()
cleaned_prediction = clean_generated_answer(prediction_text)
meta = batch["meta"][index]
answer_text = str(meta["answer"]).strip()
cleaned_answer = clean_generated_answer(answer_text)
raw_em = int(normalize_answer(prediction_text) == normalize_answer(answer_text))
cln_em = int(normalize_answer(cleaned_prediction) == normalize_answer(cleaned_answer))
record = {
"pair_id": meta.get("pair_id"),
"task_name": meta.get("task_name"),
"question": meta.get("question"),
"prompt": meta.get("prompt"),
"answer": answer_text,
"audio_path": meta.get("audio_path"),
"scene_id": meta.get("scene_id"),
"segment_stem": meta.get("segment_stem"),
"canonical_answer": meta.get("canonical_answer"),
"prediction": prediction_text,
"prediction_cleaned": cleaned_prediction,
"raw_exact_match": raw_em,
"cleaned_exact_match": cln_em,
}
local_records.append(record)
handle.write(json.dumps(record, ensure_ascii=False) + "\n")
handle.flush()
del generated, generation_inputs
if (step_i + 1) % 50 == 0 and torch.cuda.is_available():
torch.cuda.empty_cache()
distributed_barrier()
if not is_main_process():
return {}
merged = finalize_distributed_prediction_file(output_jsonl_path)
total = max(len(merged), 1)
raw_em = sum(float(r["raw_exact_match"]) for r in merged) / total
cln_em = sum(float(r["cleaned_exact_match"]) for r in merged) / total
return {
"examples": len(merged),
"raw_exact_match": raw_em,
"cleaned_exact_match": cln_em,
}
# --------------------------------------------------------------------------- #
# Main #
# --------------------------------------------------------------------------- #
def parse_args() -> argparse.Namespace:
p = argparse.ArgumentParser(
description=__doc__,
formatter_class=argparse.RawDescriptionHelpFormatter,
)
# Checkpoint selection
p.add_argument("--run-dir", type=str, default=DEFAULT_OUTPUT_DIR)
p.add_argument("--checkpoint-tags", nargs="+", default=None)
p.add_argument("--checkpoint-paths", nargs="+", default=None)
p.add_argument("--checkpoint-glob", type=str, default=None)
# Data
p.add_argument("--qa-root", type=str, default=DEFAULT_QA_ROOT)
p.add_argument("--split", type=str, default="test")
p.add_argument("--max-samples", type=int, default=None)
p.add_argument("--task-names", nargs="+", default=None)
p.add_argument("--question-classes", nargs="+", default=None)
# Caching
p.add_argument("--audio-feature-cache-manifest", type=str, default=None)
p.add_argument("--audio-feature-cache-max-entries", type=int, default=256)
# Output
p.add_argument("--output-dir", type=str, default=None)
p.add_argument("--skip-existing", action="store_true")
# Inference config
p.add_argument("--batch-size", type=int, default=1)
p.add_argument("--num-workers", type=int, default=0)
p.add_argument("--persistent-workers", action="store_true")
p.add_argument("--prefetch-factor", type=int, default=2)
p.add_argument("--device", type=str, default="cuda:0")
p.add_argument("--device-map", type=str, default=None)
p.add_argument("--dtype", type=str, default="bfloat16",
choices=("float32", "bfloat16", "float16"))
p.add_argument("--attn-impl", type=str, default="auto",
choices=("auto", "flash_attention_2", "sdpa", "eager"))
p.add_argument("--max-new-tokens", type=int, default=96)
p.add_argument("--num-beams", type=int, default=1)
p.add_argument("--do-sample", action="store_true")
# DDP
p.add_argument("--local-rank", type=int, default=-1)
return p.parse_args()
def main() -> int:
args = parse_args()
args = setup_distributed(args)
checkpoint_paths = resolve_checkpoint_paths(args)
audio_feature_cache: Optional[QwenAudioFeatureCache] = None
if args.audio_feature_cache_manifest:
audio_feature_cache = QwenAudioFeatureCache(
manifest_path=args.audio_feature_cache_manifest,
max_entries=args.audio_feature_cache_max_entries,
)
rank0_print(
f"[bench-iv] audio feature cache: {audio_feature_cache.manifest_path} "
f"(entries={len(audio_feature_cache):,})"
)
dataset, _, _ = build_qa_dataset([args.qa_root], args.split, args.max_samples)
dataset = filter_dataset(dataset, args.task_names, args.question_classes)
dataset = shard_dataset_for_rank(dataset)
if len(dataset) == 0:
raise RuntimeError("Empty dataset after filtering.")
output_dir = os.path.abspath(
args.output_dir or os.path.join(args.run_dir, "bench", args.split)
)
os.makedirs(output_dir, exist_ok=True)
rank0_print(f"[bench-iv] output_dir={output_dir}")
rank0_print(f"[bench-iv] {len(checkpoint_paths)} checkpoint(s) to run")
summary: List[Dict[str, Any]] = []
for checkpoint_path in checkpoint_paths:
ckpt_name = Path(checkpoint_path).stem.replace("_trainable", "")
ckpt_out_dir = os.path.join(output_dir, ckpt_name)
predictions_jsonl = os.path.join(ckpt_out_dir, "predictions.jsonl")
if args.skip_existing and os.path.exists(predictions_jsonl):
rank0_print(f"[bench-iv] {ckpt_name}: skip (predictions.jsonl exists)")
distributed_barrier()
continue
rank0_print(f"\n[bench-iv] === {ckpt_name} ===")
model, processor, train_args, checkpoint, load_result = \
instantiate_iv_model_for_checkpoint(args, checkpoint_path)
rank0_print(
f"[bench-iv] {ckpt_name}: loaded "
f"missing={len(load_result.missing_keys)} "
f"unexpected={len(load_result.unexpected_keys)}"
)
# Build an eval-only collator by reusing SpatialBeatsQACollator with
# include_generation_inputs=True. We don't need labels here.
collator = SpatialBeatsQACollator(
processor=processor,
audio_feature_cache=audio_feature_cache,
include_generation_inputs=True,
)
loader = make_loader(
dataset=dataset,
collator=collator,
batch_size=args.batch_size,
num_workers=args.num_workers,
shuffle=False,
sampler=None,
persistent_workers=args.persistent_workers,
prefetch_factor=args.prefetch_factor,
)
quick_metrics = run_generation_bench(
model=model,
processor=processor,
loader=loader,
output_jsonl_path=predictions_jsonl,
max_new_tokens=args.max_new_tokens,
num_beams=args.num_beams,
do_sample=args.do_sample,
bench_name=f"bench-iv:{ckpt_name}",
)
distributed_barrier()
del model
if torch.cuda.is_available():
torch.cuda.empty_cache()
if is_main_process():
payload: Dict[str, Any] = {
"checkpoint": os.path.abspath(checkpoint_path),
"checkpoint_epoch": checkpoint.get("epoch"),
"predictions_jsonl": os.path.abspath(predictions_jsonl),
"quick_metrics": quick_metrics,
"train_mode": train_args.get("train_mode"),
"spatial_encoder_type": train_args.get("spatial_encoder_type"),
"task_filter": args.task_names,
"question_class_filter": args.question_classes,
}
with open(os.path.join(ckpt_out_dir, "bench_summary.json"),
"w", encoding="utf-8") as handle:
json.dump(payload, handle, indent=2, sort_keys=True,
ensure_ascii=False)
summary.append(payload)
rank0_print(
f"[bench-iv] {ckpt_name}: predictions={quick_metrics.get('examples', 0)} "
f"raw_em={quick_metrics.get('raw_exact_match', 0.0):.4f} "
f"cleaned_em={quick_metrics.get('cleaned_exact_match', 0.0):.4f} "
f"→ {predictions_jsonl}"
)
distributed_barrier()
if is_main_process() and summary:
summary_path = os.path.join(output_dir, "summary.json")
with open(summary_path, "w", encoding="utf-8") as handle:
json.dump(summary, handle, indent=2, sort_keys=True, ensure_ascii=False)
rank0_print(f"[bench-iv] wrote {summary_path}")
rank0_print(
"[bench-iv] Next step: run `scripts/score_test_predictions.py` "
"on each predictions.jsonl to get task-aware metrics + LLM judge."
)
cleanup_distributed()
return 0
if __name__ == "__main__":
sys.exit(main())