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 #
# For licensing see accompanying LICENSE file.
# Copyright (C) 2025 Apple Inc. All Rights Reserved.
#
import os
import json
import argparse
import gc
from datetime import timedelta
from collections import defaultdict, Counter
from typing import List, Dict, Any, Optional, Tuple
import torch
import numpy as np
from accelerate import Accelerator, InitProcessGroupKwargs
from transformers import AutoModel
from datasets import load_dataset
from tqdm import tqdm
import matplotlib.pyplot as plt
from sklearn.manifold import TSNE
from sklearn.decomposition import PCA
try:
import spacy
SPACY_AVAILABLE = True
except Exception as e:
SPACY_AVAILABLE = False
print(f"Warning: spacy not available ({e}). Entity extraction will be disabled.")
try:
import evaluate as eval_lib
EVAL_LIB_AVAILABLE = True
except Exception as e:
EVAL_LIB_AVAILABLE = False
eval_lib = None
print(f"Warning: evaluate library not available ({e}). BERTScore and ROUGE metrics will be disabled.")
import re
import string
from openrlhf.models.modeling_clara import CLaRa
# Environment setup
os.environ["NCCL_TIMEOUT"] = "5400"
os.environ["PYTORCH_CUDA_ALLOC_CONF"] = "expandable_segments:True"
# Global constants
TARGET_ENTITY_CATEGORIES = {"PERSON", "GPE", "DATE", "CARDINAL", "ORG"}
class EvaluationMetrics:
"""Handles all evaluation metrics and scoring functions."""
def __init__(self):
if EVAL_LIB_AVAILABLE:
self.bertscore = eval_lib.load("bertscore")
self.rouge = eval_lib.load("rouge")
else:
self.bertscore = None
self.rouge = None
if SPACY_AVAILABLE:
self.nlp = spacy.load("en_core_web_sm")
else:
self.nlp = None
@staticmethod
def normalize_answer(text: str) -> str:
"""Normalize text for comparison."""
def remove_articles(text):
return re.sub(r"\b(a|an|the)\b", " ", text)
def white_space_fix(text):
return " ".join(text.split())
def remove_punc(text):
exclude = set(string.punctuation)
return "".join(ch for ch in text if ch not in exclude)
return white_space_fix(remove_articles(remove_punc(text.lower())))
@staticmethod
def bool_mapping(text: str) -> str:
"""Map boolean values to yes/no."""
mapping = {"True": "yes", "False": "no"}
return mapping.get(text, text)
def exact_match_score(self, prediction: str, ground_truth: str) -> bool:
"""Calculate exact match score."""
pred_norm = self.normalize_answer(self.bool_mapping(prediction))
gt_norm = self.normalize_answer(self.bool_mapping(ground_truth))
return pred_norm == gt_norm
def cover_exact_match_score(self, prediction: str, ground_truth: str) -> bool:
"""Calculate coverage exact match score."""
pred_tokens = self.normalize_answer(self.bool_mapping(prediction)).split()
gt_tokens = self.normalize_answer(self.bool_mapping(ground_truth)).split()
return all(token in pred_tokens for token in gt_tokens)
def f1_score(self, prediction: str, ground_truth: str) -> float:
"""Calculate F1 score."""
pred_norm = self.normalize_answer(self.bool_mapping(prediction))
gt_norm = self.normalize_answer(self.bool_mapping(ground_truth))
# Handle yes/no/noanswer cases
if pred_norm in ["yes", "no", "noanswer"] and pred_norm != gt_norm:
return 0.0
if gt_norm in ["yes", "no", "noanswer"] and pred_norm != gt_norm:
return 0.0
pred_tokens = pred_norm.split()
gt_tokens = gt_norm.split()
common = Counter(pred_tokens) & Counter(gt_tokens)
num_same = sum(common.values())
if num_same == 0:
return 0.0
precision = num_same / len(pred_tokens)
recall = num_same / len(gt_tokens)
return (2 * precision * recall) / (precision + recall)
def extract_entities(self, text: str) -> set:
"""Extract entities from text."""
if self.nlp is None:
return set() # Return empty set if spacy unavailable
doc = self.nlp(text)
return set(ent.text.lower().strip() for ent in doc.ents)
def extract_entities_by_category(self, text: str) -> Dict[str, set]:
"""Extract entities by category."""
if self.nlp is None:
return defaultdict(set) # Return empty dict if spacy unavailable
doc = self.nlp(text)
entities_by_category = defaultdict(set)
for ent in doc.ents:
if ent.label_ in TARGET_ENTITY_CATEGORIES:
entities_by_category[ent.label_].add(ent.text.lower().strip())
return entities_by_category
def entity_preserve_metric(self, prediction: str, reference: str) -> float:
"""Calculate entity preservation rate."""
ref_entities = self.extract_entities(reference)
pred_entities = self.extract_entities(prediction)
if not ref_entities:
return 1.0
preserved = ref_entities.intersection(pred_entities)
return len(preserved) / len(ref_entities)
def entity_preserve_metric_by_category(self, prediction_tokens: List[List[str]],
reference_docs: List[str]) -> Dict[str, float]:
"""Calculate entity preservation by category."""
# Merge prediction tokens
all_prediction_tokens = []
for tokens in prediction_tokens:
all_prediction_tokens.extend(tokens)
prediction_text = " ".join(all_prediction_tokens)
# Merge reference documents
reference_text = " ".join(reference_docs)
# Extract entities
pred_entities = self.extract_entities_by_category(prediction_text)
ref_entities = self.extract_entities_by_category(reference_text)
# Calculate preservation rates
preservation_rates = {}
for category in TARGET_ENTITY_CATEGORIES:
ref_ents = ref_entities.get(category, set())
pred_ents = pred_entities.get(category, set())
if not ref_ents:
preservation_rates[category] = 1.0
else:
preserved = ref_ents.intersection(pred_ents)
preservation_rates[category] = len(preserved) / len(ref_ents)
# Calculate overall preservation
all_ref_entities = set()
all_pred_entities = set()
for entities_set in ref_entities.values():
all_ref_entities.update(entities_set)
for entities_set in pred_entities.values():
all_pred_entities.update(entities_set)
if not all_ref_entities:
preservation_rates["overall"] = 1.0
else:
preserved_overall = all_ref_entities.intersection(all_pred_entities)
preservation_rates["overall"] = len(preserved_overall) / len(all_ref_entities)
return preservation_rates
class ResultCalculator:
"""Handles result calculation and visualization."""
def __init__(self):
self.metrics = EvaluationMetrics()
def calculate_basic_metrics(self, result_list: List[Dict]) -> Dict[str, float]:
"""Calculate basic metrics (F1, accuracy, exact match)."""
f1_total = 0
acc_total = 0
em_total = 0
avg_output_length = 0
answer_key = "golden_answers" if "golden_answers" in result_list[0] else "answer"
for result in result_list:
prediction = result['CLaRa_normal_output']
ground_truth = result[answer_key][0] if answer_key == "golden_answers" else result[answer_key]
acc_total += self.metrics.cover_exact_match_score(prediction, ground_truth)
f1_total += self.metrics.f1_score(prediction, ground_truth)
em_total += self.metrics.exact_match_score(prediction, ground_truth)
avg_output_length += len(prediction.split())
n = len(result_list)
return {
"f1": f1_total / n,
"acc": acc_total / n,
"em": em_total / n,
"avg_output_length": avg_output_length / n
}
def calculate_stage2_metrics(self, result_list: List[Dict], k_values: List[int] = [1, 3, 5]) -> Dict[str, float]:
"""Calculate stage2 metrics with recall and precision."""
basic_metrics = self.calculate_basic_metrics(result_list)
recall = {k: 0 for k in k_values}
precision = {k: 0 for k in k_values}
for result in result_list:
scores = result['topk_idx']
pos_index = set(result['pos_index'])
for k in k_values:
top_k = set(scores[:k])
hit = len(top_k & pos_index)
recall[k] += hit / len(pos_index) if len(pos_index) > 0 else 0
precision[k] += hit / k
n = len(result_list)
recall_metrics = {f"recall@{k}": v / n for k, v in recall.items()}
precision_metrics = {f"precision@{k}": v / n for k, v in precision.items()}
return {**basic_metrics, **recall_metrics, **precision_metrics}
def calculate_paraphrase_metrics(self, result_list: List[Dict]) -> Dict[str, float]:
"""Calculate paraphrase metrics."""
seen_metrics = {'bert-score': 0, 'rouge-1': 0, 'rouge-L': 0, 'entity_preserve': 0}
unseen_metrics = {'bert-score': 0, 'rouge-1': 0, 'rouge-L': 0, 'entity_preserve': 0}
# Process seen data (first 2000)
for result in result_list[:2000]:
prediction = result['CLaRa_normal_output']
ground_truth = result['doc']
if EVAL_LIB_AVAILABLE and self.metrics.bertscore is not None:
bs = self.metrics.bertscore.compute(predictions=[prediction], references=[ground_truth], lang="en")
seen_metrics['bert-score'] += bs['f1'][0]
if EVAL_LIB_AVAILABLE and self.metrics.rouge is not None:
rouge_scores = self.metrics.rouge.compute(predictions=[prediction], references=[ground_truth])
seen_metrics['rouge-1'] += rouge_scores['rouge1']
seen_metrics['rouge-L'] += rouge_scores['rougeL']
seen_metrics['entity_preserve'] += self.metrics.entity_preserve_metric(prediction, ground_truth)
# Process unseen data (after 2000)
for result in result_list[2000:]:
prediction = result['CLaRa_normal_output']
ground_truth = result['doc']
if EVAL_LIB_AVAILABLE and self.metrics.bertscore is not None:
bs = self.metrics.bertscore.compute(predictions=[prediction], references=[ground_truth], lang="en")
unseen_metrics['bert-score'] += bs['f1'][0]
if EVAL_LIB_AVAILABLE and self.metrics.rouge is not None:
rouge_scores = self.metrics.rouge.compute(predictions=[prediction], references=[ground_truth])
unseen_metrics['rouge-1'] += rouge_scores['rouge1']
unseen_metrics['rouge-L'] += rouge_scores['rougeL']
unseen_metrics['entity_preserve'] += self.metrics.entity_preserve_metric(prediction, ground_truth)
# Normalize
n_seen = min(len(result_list[:2000]), 2000)
n_unseen = max(len(result_list) - 2000, 0)
final_metrics = {}
if n_seen > 0:
for key, value in seen_metrics.items():
final_metrics[f'seen_{key}'] = float(value / n_seen)
if n_unseen > 0:
for key, value in unseen_metrics.items():
final_metrics[f'unseen_{key}'] = float(value / n_unseen)
return final_metrics
def visualize_mse(self, result_list: List[Dict], save_path: str) -> Dict[str, Any]:
"""Create t-SNE visualization for MSE analysis."""
# Set scientific style
plt.rcParams.update({
'font.family': 'serif',
'font.size': 12,
'axes.labelsize': 14,
'axes.titlesize': 16,
'figure.titlesize': 18,
'axes.linewidth': 1.2,
'grid.alpha': 0.3,
})
# Collect representations
mem_reps = []
non_mem_reps = []
for result in result_list:
mem_rep = result['CLaRa_compressed_output']
non_mem_rep = result['CLaRa_normal_output']
if isinstance(mem_rep, torch.Tensor):
mem_rep = mem_rep.float().cpu().numpy()
if isinstance(non_mem_rep, torch.Tensor):
non_mem_rep = non_mem_rep.float().cpu().numpy()
mem_reps.append(mem_rep)
non_mem_reps.append(non_mem_rep)
mem_reps = np.array(mem_reps)
non_mem_reps = np.array(non_mem_reps)
print(f"Memory representations shape: {mem_reps.shape}")
print(f"Document representations shape: {non_mem_reps.shape}")
# Combine data for t-SNE
all_data = np.vstack([mem_reps, non_mem_reps])
original_dim = all_data.shape[1]
# PCA preprocessing if needed
if all_data.shape[1] > 50:
print(f"Applying PCA preprocessing from {all_data.shape[1]} to 50 dimensions...")
pca = PCA(n_components=50)
all_data = pca.fit_transform(all_data)
print(f"PCA explained variance ratio: {pca.explained_variance_ratio_[:5].sum():.3f}")
# Apply t-SNE
print("Applying t-SNE...")
perplexity = min(30, max(5, len(all_data) // 3))
tsne = TSNE(n_components=2, random_state=42, perplexity=perplexity,
max_iter=1000, learning_rate=200, verbose=1)
tsne_results = tsne.fit_transform(all_data)
# Separate results
mem_tsne = tsne_results[:len(mem_reps)]
doc_tsne = tsne_results[len(mem_reps):]
# Create visualization
fig, ax = plt.subplots(1, 1, figsize=(10, 8))
# Add jitter to separate overlapping points
np.random.seed(42)
jitter_strength = 1.0
mem_jitter = mem_tsne.copy()
doc_jitter = doc_tsne.copy()
mem_jitter[:, 0] += np.random.normal(0.5, jitter_strength, len(mem_tsne))
mem_jitter[:, 1] += np.random.normal(0.5, jitter_strength, len(mem_tsne))
doc_jitter[:, 0] += np.random.normal(-0.5, jitter_strength, len(doc_tsne))
doc_jitter[:, 1] += np.random.normal(-0.5, jitter_strength, len(doc_tsne))
# Plot scatter points
ax.scatter(doc_jitter[:, 0], doc_jitter[:, 1], c='#0066CC', alpha=0.7, s=25,
marker='o', edgecolors='white', linewidth=0.5,
label='Document Representations', zorder=2)
ax.scatter(mem_jitter[:, 0], mem_jitter[:, 1], c='#FF3333', alpha=0.7, s=25,
marker='o', edgecolors='white', linewidth=0.5,
label='Memory Tokens Representations', zorder=3)
# Configure plot
ax.set_xlabel('')
ax.set_ylabel('')
ax.set_title('')
legend = ax.legend(frameon=True, fancybox=True, shadow=True,
loc='upper center', bbox_to_anchor=(0.5, 1.05), ncol=2, fontsize=14)
legend.get_frame().set_facecolor('white')
legend.get_frame().set_alpha(0.9)
ax.grid(True, alpha=0.3, linestyle='-', linewidth=0.5)
ax.set_axisbelow(True)
plt.tight_layout()
# Save visualization
os.makedirs(save_path, exist_ok=True)
plt.savefig(os.path.join(save_path, 'tsne_visualization_scientific.png'),
dpi=300, bbox_inches='tight', facecolor='white')
plt.show()
# Calculate statistics
distances = np.array([
np.linalg.norm(mem_reps[i] - non_mem_reps[i])
for i in range(len(mem_reps))
])
statistics = {
'mean_distance': float(np.mean(distances)),
'std_distance': float(np.std(distances)),
'median_distance': float(np.median(distances)),
'min_distance': float(np.min(distances)),
'max_distance': float(np.max(distances))
}
print("\n" + "="*60)
print("VISUALIZATION ANALYSIS REPORT")
print("="*60)
print(f"Dataset Statistics:")
print(f" • Total samples: {len(mem_reps)}")
print(f" • Original dimension: {original_dim}")
print(f" • t-SNE perplexity: {perplexity}")
print(f"\nDistance Analysis:")
for key, value in statistics.items():
print(f" • {key.replace('_', ' ').title()}: {value:.4f}")
print("="*60)
return {
'mem_tsne': mem_tsne,
'doc_tsne': doc_tsne,
'original_distances': distances,
'statistics': statistics
}
class DataLoader:
"""Handles data loading for different datasets and stages."""
@staticmethod
def load_stage1_data(dataset: str, gold_retrieval: bool) -> List[Dict]:
"""Load stage1 evaluation data."""
retrieval_type = "with_pos" if gold_retrieval else "no_pos"
file_path = f"/mnt/conductor_data/data/compression_rag_data/generator_training_val_data/stage1_eval/{dataset}/eval_processed_{retrieval_type}.jsonl"
data = []
with open(file_path, 'r') as f:
for line in f:
data.append(json.loads(line))
processed_data = []
for index, item in enumerate(data):
docs = item['docs'][:5] # Take top 5 documents
processed_item = {
'original_data': item,
'documents': docs,
'question': item['question'],
'global_index': index
}
processed_data.append(processed_item)
return processed_data
@staticmethod
def load_stage2_data(dataset: str, gold_retrieval: bool) -> List[Dict]:
"""Load stage2 evaluation data."""
retrieval_type = "with_pos" if gold_retrieval else "no_pos"
file_path = f"/mnt/conductor_data/data/compression_rag_data/generator_training_val_data/stage2_eval/{dataset}/eval_processed_{retrieval_type}.jsonl"
processed_data = []
with open(file_path, 'r') as f:
for index, line in enumerate(f):
item = json.loads(line)
processed_item = {
'original_data': item,
'documents': item['docs'],
'question': item['question'],
'global_index': index,
'pos_index': item['pos_index']
}
processed_data.append(processed_item)
return processed_data
@staticmethod
def load_paraphrase_data(file_path: str) -> List[Dict]:
"""Load paraphrase data."""
data = []
with open(file_path, 'r') as f:
for line in f:
data.append(json.loads(line))
processed_data = []
for index, item in enumerate(data):
processed_item = {
'original_data': item,
'documents': [item['doc']],
'question': "",
'global_index': index
}
processed_data.append(processed_item)
return processed_data
class AcceleratedCLaRaInference:
"""Main inference engine using Accelerate for distributed processing."""
def __init__(self, model_path: str, training_stage: str = None,
generation_top_k: int = None, args = None):
self.args = args
# Initialize Accelerator
process_group_kwargs = InitProcessGroupKwargs(timeout=timedelta(seconds=5400))
self.accelerator = Accelerator(kwargs_handlers=[process_group_kwargs])
if self.accelerator.is_main_process:
print(f"Using {self.accelerator.num_processes} GPUs for distributed inference")
print(f"Current process: {self.accelerator.process_index}")
print("Loading CLaRa model...")
# Load model
self.model = CLaRa.from_pretrained(
model_path,
training_stage=training_stage,
generation_top_k=generation_top_k,
pure_inference=True
)
# Prepare model with Accelerator
self.model = self.accelerator.prepare(self.model)
self.model.eval()
if self.accelerator.is_main_process:
print("Model preparation completed")
def _get_model(self):
"""Get the actual model (handles distributed vs single GPU)."""
return self.model.module if hasattr(self.model, 'module') else self.model
def process_batch(self, batch_questions: List[str], batch_documents: List[List[str]] = None,
stage2_mips: bool = False, training_stage: str = None,
batch_answers: List[str] = None, time_count: bool = False) -> Tuple:
"""Process a batch of questions and documents."""
model = self._get_model()
with torch.no_grad():
try:
if training_stage == 'stage2':
return self._process_stage2(model, batch_questions, batch_documents,
stage2_mips, time_count)
elif training_stage in ['stage1', 'stage1_2']:
return self._process_stage1(model, batch_questions, batch_documents)
elif training_stage == 'stage2_reasoning':
return self._process_reasoning(model, batch_questions, batch_answers)
elif training_stage == 'stage1_paraphrase':
return self._process_paraphrase(model, batch_questions, batch_documents)
elif training_stage == 'stage1_mse_visulize':
return self._process_mse_visualize(model, batch_documents)
else:
raise ValueError(f"Unknown training stage: {training_stage}")
except torch.cuda.OutOfMemoryError as e:
self.accelerator.print(f"CUDA OOM error: {e}")
torch.cuda.empty_cache()
gc.collect()
return self._create_empty_results(batch_questions, training_stage)
def _process_stage2(self, model, batch_questions, batch_documents, stage2_mips, time_count):
"""Process stage2 inference."""
if time_count:
if stage2_mips:
results = model.generate_from_questions(
questions=batch_questions,
max_new_tokens=64,
stage2_mips=stage2_mips,
time_count=True
)
else:
results = model.generate_from_questions(
questions=batch_questions,
max_new_tokens=64,
stage2_mips=stage2_mips,
documents=batch_documents,
time_count=True
)
return results
else:
if stage2_mips:
batch_out_normal, topk_idx = model.generate_from_questions(
questions=batch_questions,
max_new_tokens=64,
stage2_mips=stage2_mips
)
else:
batch_out_normal, topk_idx = model.generate_from_questions(
questions=batch_questions,
max_new_tokens=64,
stage2_mips=stage2_mips,
documents=batch_documents
)
return batch_out_normal, batch_out_normal, topk_idx
def _process_stage1(self, model, batch_questions, batch_documents):
"""Process stage1 inference."""
batch_out_compressed = []
for docs, question in zip(batch_documents, batch_questions):
embeddings, _ = model.compress_documents(documents=docs)
out_compressed = model.generate_from_compressed_documents_and_questions(
questions=[question],
compressed_documents=embeddings
)
batch_out_compressed.extend(out_compressed)
del embeddings
torch.cuda.empty_cache()
return batch_out_compressed, batch_out_compressed, None
def _process_reasoning(self, model, batch_questions, batch_answers):
"""Process reasoning inference."""
batch_out_normal = []
batch_out_reasoning_list = []
for question, answer in zip(batch_questions, batch_answers):
temp_out, temp_out_reasoning = model.generate_from_reasoning(
questions=[question],
max_new_tokens=1024,
answers=[answer],
save_dir=self.args.model_path
)
batch_out_normal.append(temp_out[0])
batch_out_reasoning_list.extend(temp_out_reasoning)
return batch_out_normal, batch_out_normal, None, batch_out_reasoning_list
def _process_paraphrase(self, model, batch_questions, batch_documents):
"""Process paraphrase inference."""
batch_out_compressed = []
for docs, question in zip(batch_documents, batch_questions):
out_compressed = model.generate_from_paraphrase(
questions=["" for _ in range(len(docs))],
documents=[docs]
)
batch_out_compressed.extend(out_compressed)
torch.cuda.empty_cache()
return batch_out_compressed, batch_out_compressed, None
def _process_mse_visualize(self, model, batch_documents):
"""Process MSE visualization."""
batch_out_normal = []
batch_out_compressed = []
for docs in batch_documents:
mem_rep, non_mem_rep = model.compress_documents_mse_visulize(documents=docs)
batch_out_compressed.append(mem_rep[0])
batch_out_normal.append(non_mem_rep[0])
return batch_out_normal, batch_out_compressed
def _create_empty_results(self, batch_questions, training_stage):
"""Create empty results for error cases."""
empty_results = [""] * len(batch_questions)
if training_stage == 'stage2_reasoning':
return empty_results, empty_results, None, empty_results
elif training_stage == 'stage1_mse_visulize':
return empty_results, empty_results
else:
return empty_results, empty_results, None
def convert_embeddings_to_list(data):
"""Convert tensor embeddings to lists for JSON serialization."""
if isinstance(data, dict):
return {k: convert_embeddings_to_list(v) for k, v in data.items()}
elif isinstance(data, list):
return [convert_embeddings_to_list(item) for item in data]
elif isinstance(data, torch.Tensor):
return data.cpu().to(torch.float32).numpy().tolist()
elif isinstance(data, np.ndarray):
return data.tolist()
else:
return data
def main():
parser = argparse.ArgumentParser(description="CLaRa Model Inference")
parser.add_argument('--model_path', type=str, required=True, help='Path to model checkpoint')
parser.add_argument('--batch_size', type=int, default=4, help='Batch size per GPU')
parser.add_argument('--stage', type=str, default='stage1',
choices=['stage1', 'stage1_2', 'stage2', 'stage2_reasoning',
'stage1_paraphrase', 'stage1_mse_visulize'],
help='Training stage')
parser.add_argument('--stage2_mips', action='store_true', help='Use MIPS for stage2')
parser.add_argument('--dataset', type=str, default='musique',
help='Comma-separated list of datasets')
parser.add_argument('--gold_retrieval', action='store_true',
help='Use gold retrieval context')
parser.add_argument('--generation_top_k', type=int, default=5, help='Top-k for generation')
parser.add_argument('--paraphrase_path', type=str, help='Path to paraphrase data')
parser.add_argument('--mse_visulize_path', type=str, help='Path to save MSE visualization')
parser.add_argument('--efficient_count', action='store_true', help='Count efficiency metrics')
args = parser.parse_args()
# Process datasets
all_results_metrics = {}
datasets_list = args.dataset.split(',')
for dataset in datasets_list:
print(f"Processing dataset: {dataset}")
# Load data based on stage
if args.stage in ['stage1', 'stage1_2']:
processed_data = DataLoader.load_stage1_data(dataset, args.gold_retrieval)
elif args.stage == 'stage2':
processed_data = DataLoader.load_stage2_data(dataset, args.gold_retrieval)
elif args.stage in ['stage1_paraphrase', 'stage1_mse_visulize']:
if not args.paraphrase_path:
raise ValueError(f"--paraphrase_path required for stage {args.stage}")
processed_data = DataLoader.load_paraphrase_data(args.paraphrase_path)
else:
raise ValueError(f"Unsupported stage: {args.stage}")
print(f"Loaded {len(processed_data)} samples for {dataset}")
# Initialize inference engine
# Use model_path directly if absolute, otherwise use SageMaker path
if os.path.isabs(args.model_path):
model_path = args.model_path
else:
model_path = os.path.join('/mnt/task_wrapper/user_output/artifacts/data/train_checkpoint', args.model_path)
args.model_path = model_path
inference_engine = AcceleratedCLaRaInference(
model_path=model_path,
training_stage=args.stage,
generation_top_k=args.generation_top_k,
args=args
)
# Wait for all processes to be ready
inference_engine.accelerator.wait_for_everyone()
# Store results
all_results = []
time_count_dic = {"compress_time": 0, "query_time": 0, "generate_time": 0, "total_time": 0, "count": 0}
# Process data in batches using accelerator
with inference_engine.accelerator.split_between_processes(processed_data, apply_padding=False) as local_data:
print(f"Process {inference_engine.accelerator.process_index}: processing {len(local_data)} samples")
batch_size = args.batch_size
num_batches = (len(local_data) + batch_size - 1) // batch_size
for batch_idx in tqdm(range(num_batches),
desc=f"GPU {inference_engine.accelerator.process_index}",
disable=not inference_engine.accelerator.is_local_main_process):
# Get current batch
start_idx = batch_idx * batch_size
end_idx = min(start_idx + batch_size, len(local_data))
batch = local_data[start_idx:end_idx]
# Prepare batch data
batch_questions = [item['question'] for item in batch]
batch_documents = [item['documents'] for item in batch] if 'documents' in batch[0] else None
batch_answers = [item.get('answer') for item in batch] if args.stage == 'stage2_reasoning' else None
# Process batch
if args.efficient_count and args.stage == 'stage2':
results = inference_engine.process_batch(
batch_questions=batch_questions,
batch_documents=batch_documents,
stage2_mips=args.stage2_mips,
training_stage=args.stage,
time_count=True
)
batch_out_normal, batch_out_compressed, batch_topk_idx, compress_time, query_time, generate_time, total_time = results
time_count_dic["compress_time"] += compress_time
time_count_dic["query_time"] += query_time
time_count_dic["generate_time"] += generate_time
time_count_dic["total_time"] += total_time
time_count_dic["count"] += 1
else:
results = inference_engine.process_batch(
batch_questions=batch_questions,
batch_documents=batch_documents,
stage2_mips=args.stage2_mips,
training_stage=args.stage,
batch_answers=batch_answers
)
if args.stage == 'stage2_reasoning':
batch_out_normal, batch_out_compressed, batch_topk_idx, batch_out_reasoning = results
elif args.stage == 'stage1_mse_visulize':
batch_out_normal, batch_out_compressed = results
batch_topk_idx = None
else:
batch_out_normal, batch_out_compressed, batch_topk_idx = results
# Prepare results
batch_results = []
for i, (item, normal_out, compressed_out) in enumerate(zip(batch, batch_out_normal, batch_out_compressed)):
result_item = item['original_data'].copy()
result_item['CLaRa_normal_output'] = normal_out
result_item['CLaRa_compressed_output'] = compressed_out
result_item['global_index'] = item['global_index']
if args.stage == 'stage2' and batch_topk_idx is not None:
result_item['topk_idx'] = batch_topk_idx[i].tolist()
elif args.stage == 'stage2_reasoning':
result_item['reasoning_output'] = batch_out_reasoning[i]
batch_results.append(result_item)
all_results.extend(batch_results)
# Clean up memory
torch.cuda.empty_cache()
if batch_idx % 10 == 0:
gc.collect()
# Save efficiency metrics if requested
if args.efficient_count and inference_engine.accelerator.is_main_process:
eff_dic = {
"compress_time_ms": round((time_count_dic['compress_time'] / time_count_dic['count']) * 1000, 2),
"query_time_ms": round((time_count_dic['query_time'] / time_count_dic['count']) * 1000, 2),
"generate_time_ms": round((time_count_dic['generate_time'] / time_count_dic['count']) * 1000, 2),
"total_time_ms": round((time_count_dic['total_time'] / time_count_dic['count']) * 1000, 2),
"sample_count": time_count_dic['count']
}
eff_output_path = os.path.join(model_path, f"efficiency_{dataset}_{args.stage}_{args.gold_retrieval}_{args.generation_top_k}.json")
with open(eff_output_path, 'w') as f:
json.dump(eff_dic, f, indent=2)
# Wait for all processes to complete
inference_engine.accelerator.wait_for_everyone()
# Gather results from all processes
if inference_engine.accelerator.is_main_process:
print("Collecting results from all processes...")
all_results_gathered = inference_engine.accelerator.gather_for_metrics(all_results)
# Process and save results (main process only)
if inference_engine.accelerator.is_main_process:
print("Processing and saving results...")
# Flatten results
final_results = []
if isinstance(all_results_gathered, list):
for result_batch in all_results_gathered:
if isinstance(result_batch, list):
final_results.extend(result_batch)
else:
final_results.append(result_batch)
print(f"Collected {len(final_results)} results")
# Sort by global index to maintain order
final_results.sort(key=lambda x: x.get('global_index', 0))
# Verify data integrity
processed_indices = set(item.get('global_index', -1) for item in final_results)
expected_indices = set(range(len(processed_data)))
missing_indices = expected_indices - processed_indices
if missing_indices:
print(f"Warning: Missing indices: {sorted(list(missing_indices))}")
else:
print("✓ Data integrity verification passed")
# Remove global index for clean output
for item in final_results:
item.pop('global_index', None)
# Save results
output_path = os.path.join(model_path, f"{dataset}_{args.stage}_{args.gold_retrieval}_{args.generation_top_k}.jsonl")
with open(output_path, 'w') as f:
if args.stage == 'stage1_mse_visulize':
converted_results = convert_embeddings_to_list(final_results)
for item in converted_results:
f.write(json.dumps(item) + '\n')
else:
for item in final_results:
f.write(json.dumps(item) + '\n')
print(f"Results saved to: {output_path}")
# Calculate metrics
calculator = ResultCalculator()
if args.stage == 'stage2':
metrics = calculator.calculate_stage2_metrics(final_results)
elif args.stage == 'stage1_paraphrase':
metrics = calculator.calculate_paraphrase_metrics(final_results)
elif args.stage == 'stage1_mse_visulize':
if args.mse_visulize_path:
metrics = calculator.visualize_mse(final_results, args.mse_visulize_path)
else:
metrics = {"visualization": "completed"}
else:
metrics = calculator.calculate_basic_metrics(final_results)
print(f"Metrics for {dataset}: {metrics}")
all_results_metrics[dataset] = metrics
# Clean up
del inference_engine
torch.cuda.empty_cache()
gc.collect()
# Save final metrics
if len(all_results_metrics) > 0:
metrics_path = os.path.join(model_path, f"results_metrics_{args.stage}_{args.gold_retrieval}_{args.generation_top_k}.json")
with open(metrics_path, 'w') as f:
json.dump(all_results_metrics, f, indent=2)
print(f"Final metrics saved to: {metrics_path}")
if __name__ == '__main__':
main()