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Upload 0_entities_phoner_wr2_125negs_no_se_proj_1's state dict

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0_entities_phoner_wr2_125negs_no_se_proj_1/0_entities_phoner_wr2_125negs_no_se_proj_1.py ADDED
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1
+ # %% [code]
2
+ get_ipython().system('pip install evaluate seqeval underthesea positional-encodings[pytorch]')
3
+
4
+ # %% [code]
5
+ import warnings
6
+ warnings.filterwarnings('ignore')
7
+
8
+ import torch
9
+ import torch.nn as nn
10
+ import torch.optim as optim
11
+ from torch.utils.data import Dataset, TensorDataset, DataLoader
12
+ import torch.nn.functional as F
13
+ import albumentations as albu
14
+ from transformers import AutoTokenizer, AutoModel
15
+ import torch.distributed as dist
16
+ from torch.nn.parallel import DistributedDataParallel as DDP
17
+ from positional_encodings.torch_encodings import PositionalEncoding1D
18
+
19
+ from sklearn.metrics import f1_score
20
+ from sklearn.preprocessing import MinMaxScaler, StandardScaler
21
+ from scipy.spatial.transform import Rotation as R
22
+ from sklearn.model_selection import KFold, StratifiedGroupKFold, GroupKFold, StratifiedKFold
23
+ from sklearn.metrics import precision_recall_fscore_support
24
+ from timm.utils import ModelEmaV3
25
+ import timm
26
+
27
+ import os
28
+ import gc
29
+ import json
30
+ from pathlib import Path
31
+ import pickle
32
+ from tqdm.auto import tqdm
33
+ import copy
34
+ import numpy as np
35
+ import pandas as pd
36
+ import polars as pl
37
+ from PIL import Image
38
+ import time
39
+ from tqdm import tqdm
40
+ from matplotlib import pyplot as plt
41
+ import seaborn as sns
42
+ from multiprocessing import Manager as MemoryManager
43
+ from functools import lru_cache
44
+ import shutil
45
+ import glob
46
+ import cv2
47
+ import random
48
+ import re
49
+ import joblib
50
+ import math
51
+ from huggingface_hub import HfApi, snapshot_download
52
+ import evaluate
53
+ from underthesea import word_tokenize as vi_tokenize_tool
54
+ import spacy
55
+ en_tokenize_tool = spacy.load("en_core_web_sm")
56
+ from collections import defaultdict, Counter
57
+
58
+ # %% [code]
59
+ # Global config
60
+ SEEDS = [26092004]
61
+ topk = 1
62
+ nfolds = 5
63
+ only_fold_idx = 0
64
+ test_only = 0
65
+ debug_only = 0
66
+
67
+ # Config thư mục
68
+ dataset = 'phoner' # conll003, ontonotes, phoner, vietbio, vietmed, vimed, kltn/only_entities, kltn/raw
69
+ root_dir = f'/kaggle/input/notebooks/sambui22022517/kltn-data/{dataset}' ## Thư mục chứa file train, val, test
70
+ train_dir = f'{root_dir}'
71
+ # val_dir = f'{root_dir}/val'
72
+ test_dir = f'{root_dir}'
73
+
74
+ # Config checkpoints
75
+
76
+ # Config training
77
+ epochs = 18 if not debug_only else 2
78
+ batch_size = 32
79
+ device = "cuda" if torch.cuda.is_available() else "cpu"
80
+ # # Thêm biến toàn cục nào đó vào đây
81
+ repo_name = 'SS3M/kltn-ie-experiments'
82
+ state_dict_save_name = "0_entities_phoner_wr2_125negs_no_se_proj_1"
83
+ checkpoints_dir = state_dict_save_name
84
+ pretrained_dir = "/kaggle/working"
85
+ os.makedirs(f'{checkpoints_dir}', exist_ok=True)
86
+
87
+ backbone_model_name = "bert-base-uncased" if dataset in ["conll003", "ontonotes"] else "vinai/phobert-base"
88
+ word_tokenize = lambda text: [token.text for token in en_tokenize_tool(text)] if dataset == dataset in ["conll003", "ontonotes"] else vi_tokenize_tool(text)
89
+ max_len_dict = {
90
+ 'kltn/raw': 256,
91
+ 'kltn/only_entities': 68,
92
+ 'conll003': 46,
93
+ 'ontonotes': 61,
94
+ 'phoner': 68,
95
+ 'vietbio': 125,
96
+ 'vietmed': 36,
97
+ 'vimed': 100,
98
+ }
99
+ zero_entities_rate_dict = {
100
+ 'kltn/raw': 1000,
101
+ 'kltn/only_entities': 0.2,
102
+ 'conll003': 1000, # mean keep all zero-entities samples
103
+ 'ontonotes': 1000,
104
+ 'phoner': 1000,
105
+ 'vietbio': 1000,
106
+ 'vietmed': 1000,
107
+ 'vimed': 1000,
108
+ }
109
+
110
+ max_len = max_len_dict[dataset]
111
+ max_n_parts = 3 if dataset in ['kltn/raw'] else 1
112
+ max_span_len = 14
113
+ zero_entities_rate = zero_entities_rate_dict[dataset]
114
+ n_negs = 125
115
+
116
+ # Trainer
117
+ trainer_params = {
118
+ "training_time": "00:11:30:00",
119
+ "eval_mode": "max",
120
+ "topk": topk,
121
+ "save_name": state_dict_save_name,
122
+ "save_best": True,
123
+ "save_last": True,
124
+ "device": device,
125
+ "logging": True,
126
+ "logging_file": True,
127
+ "checkpoints_dir": checkpoints_dir,
128
+ "early_stopping": 30,
129
+ "eval_from_ratio": 0.4,
130
+ "eval_every": 1,
131
+ "schedule_in_step": False,
132
+ "use_ema": True,
133
+ "ema_from_ratio": 0.3,
134
+ "ema_decay": 0.9995,
135
+ "max_grad_norm": 200.0,
136
+ "return_best": True,
137
+ "return_last": True,
138
+ }
139
+
140
+ # Memory
141
+ train_memory_params = {
142
+ 'max_len': max_len,
143
+ 'max_n_parts': max_n_parts,
144
+ 'max_span_len': max_span_len,
145
+ 'n_negs': n_negs,
146
+ 'weight_sampling': True,
147
+ 'weight_rate': 2,
148
+ }
149
+ val_memory_params = {
150
+ 'max_len': max_len,
151
+ 'max_n_parts': max_n_parts,
152
+ 'max_span_len': max_span_len,
153
+ 'n_negs': n_negs,
154
+ 'weight_sampling': True,
155
+ 'weight_rate': 2,
156
+ }
157
+
158
+ # Data Loader
159
+ def seed_worker(worker_id):
160
+ worker_seed = torch.initial_seed() % 2**32
161
+ np.random.seed(worker_seed)
162
+ random.seed(worker_seed)
163
+
164
+ train_loader_params = {
165
+ 'batch_size': batch_size,
166
+ 'shuffle': True,
167
+ 'pin_memory':True,
168
+ 'num_workers': 2,
169
+ 'drop_last': False,
170
+ 'worker_init_fn': seed_worker,
171
+ 'persistent_workers': False,
172
+ }
173
+ val_loader_params = {
174
+ 'batch_size': batch_size,
175
+ 'shuffle': False,
176
+ 'pin_memory':True,
177
+ 'num_workers': 1,
178
+ 'drop_last': False,
179
+ 'worker_init_fn': seed_worker,
180
+ 'persistent_workers': False,
181
+ }
182
+
183
+ # Model
184
+ model_params = {
185
+ 'backbone_model_name': backbone_model_name,
186
+ }
187
+
188
+ # Loss Func
189
+ loss_func_params = {
190
+
191
+ }
192
+ eval_func_params = {}
193
+
194
+ # Optim
195
+ optim_params = {
196
+ 'name': 'AdamW',
197
+ 'lr': 1e-4,
198
+ 'weight_decay': 1e-4,
199
+ }
200
+ scheduler_params = {
201
+ 'name': 'CosineAnnealingLR',
202
+ 'T_max': 20, # Số epoch để hoàn thành một chu kỳ giảm LR
203
+ 'eta_min': 1e-6 # Learning rate nhỏ nhất trong chu kỳ
204
+ }
205
+
206
+ # %% [code]
207
+ def set_seed(seed=42):
208
+ random.seed(seed)
209
+ np.random.seed(seed)
210
+ torch.manual_seed(seed)
211
+ torch.cuda.manual_seed(seed)
212
+ torch.cuda.manual_seed_all(seed) # if using multi-GPU
213
+ torch.use_deterministic_algorithms(False)
214
+ torch.backends.cudnn.deterministic = True
215
+ torch.backends.cudnn.benchmark = False
216
+ os.environ['PYTHONHASHSEED'] = str(seed)
217
+
218
+ # %% [code]
219
+ class CustomLoss(nn.Module):
220
+ def __init__(self):
221
+ super().__init__()
222
+
223
+ def forward(self, logits, labels, weights=None):
224
+ B, N, C = logits.shape
225
+
226
+ flat_logits = logits.reshape(-1, C)
227
+ flat_labels = labels.reshape(-1)
228
+
229
+ valid_mask = flat_labels != -100
230
+
231
+ if valid_mask.any():
232
+ losses = F.cross_entropy(
233
+ flat_logits,
234
+ flat_labels,
235
+ reduction='none'
236
+ )
237
+
238
+ losses = losses[valid_mask]
239
+
240
+ if weights is not None:
241
+ flat_weights = weights.reshape(-1)[valid_mask]
242
+ span_loss = (losses * flat_weights).mean()
243
+ else:
244
+ span_loss = losses.mean()
245
+
246
+ else:
247
+ span_loss = logits.new_tensor(0.0)
248
+
249
+ return {
250
+ "total": span_loss,
251
+ "span_loss": span_loss,
252
+ }
253
+
254
+ # %% [code]
255
+ ## Viết eval_fn vào đây
256
+
257
+ # Bỏ hết eval_fn và trọng số vào đây
258
+ class CustomEvalFn(nn.Module):
259
+ def __init__(self):
260
+ super().__init__()
261
+
262
+ def compute_f1(self, tp, fp, fn):
263
+ precision = tp / (tp + fp + 1e-8)
264
+ recall = tp / (tp + fn + 1e-8)
265
+ f1 = 2 * precision * recall / (precision + recall + 1e-8)
266
+ return precision, recall, f1
267
+
268
+ def forward(self, pred, gold):
269
+ pred_set = set(pred)
270
+ gold_set = set(gold)
271
+
272
+ tp = len(pred_set & gold_set)
273
+ fp = len(pred_set - gold_set)
274
+ fn = len(gold_set - pred_set)
275
+
276
+ precision, recall, f1 = self.compute_f1(tp, fp, fn)
277
+
278
+ return {
279
+ f"precision": precision,
280
+ f"recall": recall,
281
+ f"f1": f1,
282
+ }
283
+
284
+ class SpanErrorAnalyzer:
285
+ def __init__(self, pad_token_id=0):
286
+ self.pad_token_id = pad_token_id
287
+
288
+ # ===== helper =====
289
+ def _to_set(self, data):
290
+ """
291
+ data: list of (b, tuple(ids))
292
+ -> dict[b] = set(tuple(ids))
293
+ """
294
+ res = defaultdict(set)
295
+ for b, ids in data:
296
+ ids = tuple([i for i in ids if i != self.pad_token_id])
297
+ if len(ids) > 0:
298
+ res[b].add(ids)
299
+ return res
300
+
301
+ def _iou(self, a, b):
302
+ """
303
+ a, b: tuple(ids)
304
+ """
305
+ set_a, set_b = set(a), set(b)
306
+ inter = len(set_a & set_b)
307
+ union = len(set_a | set_b)
308
+ if union == 0:
309
+ return 0.0
310
+ return inter / union
311
+
312
+ def _boundary_error(self, pred, gold):
313
+ """
314
+ đo lệch boundary dựa trên overlap prefix/suffix
315
+ """
316
+ # left match
317
+ left = 0
318
+ for i in range(min(len(pred), len(gold))):
319
+ if pred[i] == gold[i]:
320
+ left += 1
321
+ else:
322
+ break
323
+
324
+ # right match
325
+ right = 0
326
+ for i in range(1, min(len(pred), len(gold)) + 1):
327
+ if pred[-i] == gold[-i]:
328
+ right += 1
329
+ else:
330
+ break
331
+
332
+ return {
333
+ "left_match": left,
334
+ "right_match": right,
335
+ "pred_len": len(pred),
336
+ "gold_len": len(gold),
337
+ }
338
+
339
+ # ===== main =====
340
+ def analyze(self, preds, golds):
341
+ pred_map = self._to_set(preds)
342
+ gold_map = self._to_set(golds)
343
+
344
+ all_batches = set(pred_map.keys()) | set(gold_map.keys())
345
+
346
+ stats = Counter()
347
+
348
+ detailed_errors = []
349
+
350
+ for b in all_batches:
351
+ pset = pred_map.get(b, set())
352
+ gset = gold_map.get(b, set())
353
+
354
+ matched_gold = set()
355
+
356
+ # ===== check predictions =====
357
+ for p in pset:
358
+ if p in gset:
359
+ stats["exact_match"] += 1
360
+ matched_gold.add(p)
361
+ else:
362
+ # tìm gold gần nhất
363
+ best_iou = 0
364
+ best_g = None
365
+
366
+ for g in gset:
367
+ iou = self._iou(p, g)
368
+ if iou > best_iou:
369
+ best_iou = iou
370
+ best_g = g
371
+
372
+ if best_iou > 0:
373
+ stats["partial_match"] += 1
374
+
375
+ boundary = self._boundary_error(p, best_g)
376
+
377
+ detailed_errors.append({
378
+ "type": "boundary_error",
379
+ "batch": b,
380
+ "pred": p,
381
+ "gold": best_g,
382
+ "iou": best_iou,
383
+ **boundary
384
+ })
385
+ else:
386
+ if b not in gold_map:
387
+ stats["no_event_sample"] += 1
388
+ err_type = "no_event_sample"
389
+ else:
390
+ stats["completely_wrong"] += 1
391
+ err_type = "completely_wrong"
392
+
393
+ detailed_errors.append({
394
+ "type": err_type,
395
+ "batch": b,
396
+ "pred": p
397
+ })
398
+
399
+ # ===== check missing =====
400
+ for g in gset:
401
+ if g not in matched_gold:
402
+ # check if any pred overlaps
403
+ overlap = any(self._iou(p, g) > 0 for p in pset)
404
+
405
+ if overlap:
406
+ stats["miss_with_overlap"] += 1
407
+ else:
408
+ stats["miss"] += 1
409
+
410
+ detailed_errors.append({
411
+ "type": "miss",
412
+ "batch": b,
413
+ "gold": g
414
+ })
415
+
416
+ return {
417
+ "summary": {
418
+ "exact_match": (stats["exact_match"], stats["exact_match"] / len(preds)),
419
+ "partial_match": (stats["partial_match"], stats["partial_match"] / len(preds)),
420
+ "no_event_sample": (stats["no_event_sample"], stats["no_event_sample"] / len(preds)),
421
+ "completely_wrong": (stats["completely_wrong"], stats["completely_wrong"] / len(preds)),
422
+ "miss": (stats["miss"], stats["miss"] / len(golds)),
423
+ "miss_with_overlap": (stats["miss_with_overlap"], stats["miss_with_overlap"] / len(golds)),
424
+ },
425
+ "details": detailed_errors
426
+ }
427
+
428
+ # %% [code]
429
+ class DataParallelProxy(nn.DataParallel):
430
+ def __getattr__(self, name):
431
+ try:
432
+ return super().__getattr__(name)
433
+
434
+ except AttributeError:
435
+
436
+ attr = getattr(self.module, name)
437
+
438
+ if callable(attr):
439
+
440
+ def wrapper(*args, **kwargs):
441
+ return self._parallel_apply_method(
442
+ name,
443
+ *args,
444
+ **kwargs
445
+ )
446
+
447
+ return wrapper
448
+
449
+ return attr
450
+
451
+ def _parallel_apply_method(self, method_name, *inputs, **kwargs):
452
+ if not self.device_ids:
453
+ return getattr(self.module, method_name)(*inputs, **kwargs)
454
+
455
+ inputs_scattered, kwargs_scattered = self.scatter(
456
+ inputs,
457
+ kwargs,
458
+ self.device_ids
459
+ )
460
+
461
+ replicas = self.replicate(
462
+ self.module,
463
+ self.device_ids[:len(inputs_scattered)]
464
+ )
465
+
466
+ outputs = self.parallel_apply(
467
+ [getattr(replica, method_name) for replica in replicas],
468
+ inputs_scattered,
469
+ kwargs_scattered
470
+ )
471
+
472
+ return self._custom_gather(outputs, self.output_device)
473
+
474
+ def gather(self, outputs, output_device):
475
+ return self._custom_gather(outputs, output_device)
476
+
477
+ def _custom_gather(self, outputs, output_device):
478
+ first = outputs[0]
479
+
480
+ if torch.is_tensor(first):
481
+ return self._gather_tensor(outputs, output_device)
482
+
483
+ if isinstance(first, tuple):
484
+ return tuple(
485
+ self._custom_gather(
486
+ list(items),
487
+ output_device
488
+ )
489
+ for items in zip(*outputs)
490
+ )
491
+
492
+ if isinstance(first, list):
493
+ if len(first) > 0 and torch.is_tensor(first[0]):
494
+ return self._gather_tensor_list(outputs, output_device)
495
+
496
+ merged = []
497
+ for out in outputs:
498
+ merged.extend(out)
499
+ return merged
500
+
501
+ if isinstance(first, dict):
502
+ return {
503
+ k: self._custom_gather(
504
+ [o[k] for o in outputs],
505
+ output_device
506
+ )
507
+ for k in first.keys()
508
+ }
509
+ return outputs
510
+
511
+ def _gather_tensor(self, tensors, output_device):
512
+ tensors = [
513
+ t.to(output_device)
514
+ for t in tensors
515
+ ]
516
+
517
+ try:
518
+ return torch.cat(tensors, dim=0)
519
+ except RuntimeError:
520
+ pass
521
+
522
+ max_shape = list(tensors[0].shape)
523
+ for t in tensors[1:]:
524
+ for d in range(len(max_shape)):
525
+ max_shape[d] = max(max_shape[d], t.shape[d])
526
+
527
+ padded = []
528
+ for t in tensors:
529
+ pad = []
530
+
531
+ for d in reversed(range(len(max_shape))):
532
+ if d == 0:
533
+ pad.extend([0, 0])
534
+ continue
535
+
536
+ diff = max_shape[d] - t.shape[d]
537
+ pad.extend([0, diff])
538
+
539
+ t = F.pad(t, pad)
540
+ padded.append(t)
541
+ return torch.cat(padded, dim=0)
542
+
543
+ def _gather_tensor_list(self, outputs, output_device):
544
+ merged = []
545
+
546
+ for out in outputs:
547
+ merged.extend(out)
548
+
549
+ return self._gather_tensor(merged, output_device)
550
+
551
+ # %% [code]
552
+ class SpanExtractor(nn.Module):
553
+ def __init__(self, hidden_size):
554
+ super().__init__()
555
+
556
+ # self.start_proj = MLP(hidden_size, hidden_size, hidden_size)
557
+ # self.end_proj = MLP(hidden_size, hidden_size, hidden_size)
558
+
559
+ self.span_attn = nn.Sequential(
560
+ nn.Linear(hidden_size, hidden_size),
561
+ nn.GELU(),
562
+ nn.Linear(hidden_size, 1)
563
+ )
564
+
565
+ def forward(self, hidden_states, spans):
566
+ B, L, H = hidden_states.shape
567
+ N = spans.size(1)
568
+
569
+ start_hidden = hidden_states
570
+ end_hidden = hidden_states
571
+
572
+ batch_idx = torch.arange(B, device=hidden_states.device).unsqueeze(1)
573
+ start_idx = spans[..., 0]
574
+ end_idx = spans[..., 1]
575
+
576
+ start_h = start_hidden[batch_idx, start_idx]
577
+ end_h = end_hidden[batch_idx, end_idx]
578
+
579
+ token_idx = torch.arange(L, device=hidden_states.device).view(1, 1, L)
580
+ span_mask = (token_idx >= start_idx.unsqueeze(-1)) & (token_idx <= end_idx.unsqueeze(-1))
581
+
582
+ attn_scores = self.span_attn(hidden_states).squeeze(-1).unsqueeze(1).expand(-1, N, -1)
583
+ attn_scores = attn_scores.masked_fill(~span_mask, float('-inf'))
584
+ attn_weights = torch.softmax(attn_scores, dim=-1)
585
+ span_context = torch.einsum("bnl,blh->bnh", attn_weights, hidden_states)
586
+
587
+ span_repr = torch.cat([start_h, end_h, end_h - start_h, end_h * start_h, span_context], dim=-1)
588
+ # span_repr = torch.cat([start_h, end_h, span_context], dim=-1)
589
+
590
+ return span_repr
591
+
592
+ class MLP(nn.Module):
593
+ def __init__(self, in_size, hid_size, out_size, dropout=0.1):
594
+ super().__init__()
595
+
596
+ self.input_proj = nn.Identity() if in_size == hid_size else nn.Linear(in_size, hid_size)
597
+
598
+ self.block = nn.Sequential(
599
+ nn.Linear(hid_size, hid_size),
600
+ nn.LayerNorm(hid_size),
601
+ nn.GELU(),
602
+ nn.Dropout(dropout),
603
+
604
+ nn.Linear(hid_size, hid_size),
605
+ nn.LayerNorm(hid_size),
606
+ nn.GELU(),
607
+ nn.Dropout(dropout),
608
+ )
609
+
610
+ self.out = nn.Linear(hid_size, out_size)
611
+
612
+ def forward(self, x):
613
+ x = self.input_proj(x)
614
+ x = x + self.block(x) # residual
615
+ return self.out(x)
616
+
617
+ class IEModel(nn.Module):
618
+ def __init__(self, backbone_model_name, num_labels):
619
+ super().__init__()
620
+
621
+ self.encoder = AutoModel.from_pretrained(backbone_model_name)
622
+ hidden_size = self.encoder.config.hidden_size
623
+
624
+ self.span_extractor = SpanExtractor(hidden_size)
625
+ self.spans_classifier = MLP(5 * hidden_size, hidden_size, num_labels)
626
+
627
+ def encode(self, input_ids, attention_mask):
628
+ B, n_parts, L = input_ids.shape
629
+
630
+ input_ids = input_ids.view(-1, L)
631
+ attention_mask = attention_mask.view(-1, L)
632
+
633
+ outputs = self.encoder(input_ids=input_ids, attention_mask=attention_mask)
634
+ hidden_states = outputs.last_hidden_state
635
+
636
+ hidden_states = hidden_states.view(B, n_parts, L, -1).reshape(B, n_parts * L, -1)
637
+ return hidden_states
638
+
639
+ def get_span_logits(self, span_reprs):
640
+ return self.spans_classifier(span_reprs)
641
+
642
+ def forward(self, input_ids, attention_mask, sampled_spans):
643
+ hidden_states = self.encode(input_ids, attention_mask)
644
+
645
+ span_reprs = self.span_extractor(hidden_states, sampled_spans)
646
+ span_logits = self.get_span_logits(span_reprs)
647
+ return span_logits
648
+
649
+ def test_model():
650
+ model = nn.DataParallel(IEModel(backbone_model_name, 17)).to(device)
651
+ model.eval()
652
+ total_params = sum(p.numel() for p in model.parameters())
653
+ print(f"Total params: {total_params:,}")
654
+
655
+ vocab_size = model.module.encoder.config.vocab_size
656
+ max_len = model.module.encoder.config.max_position_embeddings
657
+
658
+ bz = 32
659
+ i = torch.randint(0, vocab_size, (bz, 5, 10)).to(device)
660
+ a = torch.ones(bz, 5, 10).to(device)
661
+ s = torch.ones(bz, 3, 2, dtype=torch.long).to(device)
662
+ gs = torch.ones(bz, 3, 2, dtype=torch.long).to(device)
663
+
664
+ with torch.no_grad():
665
+ r = model(i, a, s)
666
+
667
+ if type(r) == tuple:
668
+ print([r[i].shape if type(r[i]) == type(torch.Tensor()) else len(r[i]) for i in range(len(r))])
669
+ else:
670
+ print(r.shape)
671
+
672
+ test_model()
673
+
674
+ # %% [code]
675
+ def configure_optimizers(network, optim_params, scheduler_params):
676
+ try:
677
+ optim_params = copy.copy(optim_params)
678
+ scheduler_params = copy.copy(scheduler_params)
679
+
680
+ optim_name = optim_params.pop('name')
681
+ scheduler_name = scheduler_params.pop('name')
682
+
683
+ optimizer_cls = globals().get(optim_name) or getattr(optim, optim_name, None)
684
+ scheduler_cls = globals().get(scheduler_name) or getattr(optim.lr_scheduler, scheduler_name, None)
685
+
686
+ if optimizer_cls is None:
687
+ raise ValueError(f"Optimizer '{optim_name}' is not available!")
688
+
689
+ optimizer = optimizer_cls(network.parameters(), **optim_params)
690
+
691
+ scheduler = None
692
+ if scheduler_params and scheduler_cls: # Chỉ tạo scheduler nếu có tham số
693
+ scheduler = scheduler_cls(optimizer, **scheduler_params)
694
+
695
+ return optimizer, scheduler
696
+
697
+ except KeyError as e:
698
+ raise ValueError(f"Missing {e} in config!!")
699
+
700
+ def freeze(self, model):
701
+ model.eval()
702
+ for param in model.parameters():
703
+ param.requires_grad = False
704
+
705
+ def unfreeze(self, model):
706
+ model.train()
707
+ for param in model.parameters():
708
+ param.requires_grad = True
709
+
710
+ def reduce_batch_size(loader, ratio=0.5):
711
+ new_bs = max(1, int(loader.batch_size * ratio))
712
+
713
+ shuffle = isinstance(loader.sampler, RandomSampler)
714
+
715
+ new_loader = DataLoader(
716
+ dataset=loader.dataset,
717
+ batch_size=new_bs,
718
+ shuffle=shuffle,
719
+ sampler=None if shuffle else loader.sampler,
720
+ num_workers=loader.num_workers,
721
+ collate_fn=loader.collate_fn,
722
+ pin_memory=loader.pin_memory,
723
+ drop_last=loader.drop_last,
724
+ timeout=loader.timeout,
725
+ worker_init_fn=loader.worker_init_fn,
726
+ multiprocessing_context=loader.multiprocessing_context,
727
+ generator=loader.generator,
728
+ prefetch_factor=loader.prefetch_factor if loader.num_workers > 0 else None,
729
+ persistent_workers=loader.persistent_workers,
730
+ pin_memory_device=loader.pin_memory_device
731
+ )
732
+
733
+ return new_loader
734
+
735
+ def list_to_tuple(x):
736
+ if isinstance(x, (list, tuple)):
737
+ return tuple(list_to_tuple(i) for i in x)
738
+ return x
739
+
740
+ def fmt(x):
741
+ if isinstance(x, float):
742
+ return round(x, 5)
743
+ if isinstance(x, dict):
744
+ return {k: fmt(v) for k, v in x.items()}
745
+ if isinstance(x, list):
746
+ return [fmt(v) for v in x]
747
+ return x
748
+
749
+ class ModelEmaV3Proxy(ModelEmaV3):
750
+ def __getattr__(self, name):
751
+ try:
752
+ return super().__getattr__(name)
753
+ except AttributeError:
754
+ return getattr(self.module, name)
755
+
756
+ def extract_entities(
757
+ input_ids, # (B, L)
758
+ logits, # (B, N, C)
759
+ pred_spans, # (B, N, 2)
760
+ id2label
761
+ ):
762
+ """
763
+ Return: [(batch_idx, ([token_ids], label_name)),...]
764
+ """
765
+
766
+ # (B, N)
767
+ pred_labels = logits.softmax(dim=-1).argmax(dim=-1)
768
+ start_idx = pred_spans[..., 0] # (B, N)
769
+ end_idx = pred_spans[..., 1] # (B, N)
770
+ keep = ((pred_labels > 0) & (start_idx > 0) & (end_idx > 0))
771
+
772
+ results = []
773
+ B, N = pred_labels.shape
774
+ for bidx in range(B):
775
+ valid_idxes = keep[bidx].nonzero(as_tuple=False).squeeze(-1)
776
+
777
+ for idx in valid_idxes:
778
+ lb = pred_labels[bidx, idx]
779
+
780
+ s, e = pred_spans[bidx, idx].tolist()
781
+ token_ids = input_ids[bidx, s:e+1].tolist()
782
+
783
+ results.append((bidx, (token_ids, id2label[lb.item()])))
784
+
785
+ return results
786
+
787
+ class Trainer:
788
+ def __init__(
789
+ self, training_time="00:11:30:00", eval_mode="max", topk=1, save_name="network", save_best=True, save_last=False, max_grad_norm=200.0,
790
+ logging=0, logging_file=False, checkpoints_dir="", early_stopping=False, eval_from_ratio=-1, eval_every=1, device='cpu',
791
+ schedule_in_step=True, use_ema=True, ema_from_ratio=-1, ema_decay=0.999, return_best=True, return_last=True
792
+ ):
793
+ self.ema_net = None
794
+
795
+ self.training_time = self._time_str_to_seconds(training_time)
796
+ self.mode = eval_mode
797
+ self.topk = topk
798
+ self.device = device
799
+ self.logging = logging if logging < epochs else 1
800
+ self.logging_file = logging_file
801
+ self.checkpoints_dir = checkpoints_dir
802
+ self.early_stopping = early_stopping
803
+ self.eval_from_ratio = eval_from_ratio
804
+ self.eval_every = eval_every
805
+ self.save_name = save_name
806
+ self.save_best = save_best
807
+ self.save_last = save_last
808
+ self.return_best = return_best
809
+ self.return_last = return_last
810
+ self.max_grad_norm = max_grad_norm
811
+ self.schedule_in_step = schedule_in_step
812
+ self.use_ema = use_ema
813
+ self.ema_from_ratio = ema_from_ratio
814
+ self.ema_decay = ema_decay
815
+
816
+ self.best_stage = [[float('-inf') if self.mode == 'max' else float('inf'), None, None]]
817
+ self.grad_scaler = torch.amp.GradScaler(self.device, init_scale=1024.0)
818
+
819
+ def fit(self, network, optimizer, scheduler, loss_fn, epochs, train_loader, val_loader=None, eval_fn=None, start_epoch=1, start_training_time=None, id2label=None):
820
+ if eval_fn is None:
821
+ if self.mode == "max":
822
+ eval_fn = lambda *x: -loss_fn(*x)
823
+ else:
824
+ eval_fn = lambda *x: loss_fn(*x)
825
+
826
+ if torch.cuda.device_count() > 1:
827
+ network = DataParallelProxy(network)
828
+ network = network.to(self.device)
829
+
830
+ if not start_training_time:
831
+ start_training_time = time.time()
832
+
833
+ start_ema = int(epochs * self.ema_from_ratio)
834
+ start_eval = int(epochs * self.eval_from_ratio)
835
+
836
+ if val_loader is None:
837
+ print(f'[Trainer CallBack] 📢 Không có Val Set, không thể đánh giá và Early Stopping!')
838
+ else:
839
+ model_to_use_str = 'mô hình EMA' if self.use_ema else 'mô hình gốc'
840
+ start_model_update_str = f'Bắt đầu cập nhật EMA từ epoch {start_epoch + start_ema}!' if self.use_ema else ''
841
+ print(f'[Trainer CallBack] 📢 Đánh giá bằng {model_to_use_str} từ epoch {start_epoch + start_eval}!', start_model_update_str)
842
+
843
+ training_log = {}
844
+ for epoch in range(start_epoch, epochs+start_epoch):
845
+ if self.use_ema and self.ema_net is None and epoch - start_epoch >= start_ema:
846
+ self.ema_net = ModelEmaV3Proxy(network, self.ema_decay, device=self.device)
847
+
848
+ try:
849
+ teaching_rate = math.cos(math.pi / 2 * epoch / epochs)
850
+ train_loss_epoch, train_loss_epoch_dict = self._train_epoch(network, train_loader, optimizer, scheduler, loss_fn, teaching_rate)
851
+ logging_dict = {'lr': [group['lr'] for group in optimizer.param_groups], 'train_loss': train_loss_epoch}
852
+ logging_dict.update(train_loss_epoch_dict)
853
+
854
+ if val_loader is not None and epoch - start_epoch >= start_eval and (epoch - start_epoch - start_eval) % self.eval_every == 0:
855
+ eval_net = self.ema_net.module if (self.use_ema and self.ema_net is not None) else network
856
+
857
+ val_score, val_score_dict, _ = self._eval_epoch(eval_net, val_loader, eval_fn, id2label)
858
+ update = self._update_best_network(eval_net, val_score, epoch)
859
+ logging_dict.update({'val_score': val_score, 'best_score': self.best_stage[0][0], 'new_best_model': update})
860
+ logging_dict.update(val_score_dict)
861
+ if not self.schedule_in_step and scheduler:
862
+ scheduler.step()
863
+
864
+ except RuntimeError as e:
865
+ if "out of memory" in str(e).lower():
866
+ print(f"[Trainer CallBack] ⚠️ Epoch {epoch}/{epochs}: CUDA Out of Memory! Clearing GPU cache...")
867
+ torch.cuda.empty_cache()
868
+ gc.collect()
869
+ if torch.cuda.is_available():
870
+ torch.cuda.synchronize()
871
+ print(f"[Trainer CallBack] ✅ Epoch {epoch}/{epochs}: GPU memory cleared")
872
+
873
+ train_loader = reduce_batch_size(train_loader, ratio=0.5)
874
+ if val_loader is not None:
875
+ val_loader = reduce_batch_size(val_loader, ratio=0.5)
876
+
877
+ logging_dict = {'lr': [group['lr'] for group in optimizer.param_groups], 'train_loss': float('inf')}
878
+ else:
879
+ raise
880
+
881
+ training_log[epoch] = logging_dict
882
+ if self.is_early_stopping(epoch):
883
+ print(f'[Trainer CallBack] 📢 Epoch {epoch}/{epochs}: Detect Overfitting! Breaking Training Process...')
884
+ break
885
+ if self.logging:
886
+ if epoch % self.logging == 0:
887
+ print(f'[Trainer CallBack] 📢 Epoch {epoch}/{epochs}:', fmt(logging_dict))
888
+ else:
889
+ print(f'{epoch}...', end=' ')
890
+
891
+ if self._at_time_limit(start_training_time):
892
+ print(f'[Trainer CallBack] ⚠️ Epoch {epoch}/{epochs}: Thời gian training giới hạn là {self.training_time}, hết giờ tại epoch {epoch}/{epochs}')
893
+ break
894
+
895
+ if self.logging_file:
896
+ os.makedirs(f'{self.checkpoints_dir}/logs', exist_ok=True)
897
+ with open(f"{self.checkpoints_dir}/logs/{self.save_name}_logging.json", "a", encoding="utf-8") as f:
898
+ f.write(json.dumps(training_log))
899
+
900
+ if self.use_ema and self.ema_net is not None:
901
+ self._save_state_dict(self.ema_net.module)
902
+ else:
903
+ self._save_state_dict(network)
904
+ print(f'[Trainer CallBack] 📢 Kết thúc training.\n')
905
+
906
+ best_model, last_model = None, None
907
+ eval_net = self.ema_net.module if (self.use_ema and self.ema_net is not None) else network
908
+ if self.return_best :
909
+ best_model = self.best_stage[0][2] if self.best_stage[0][2] is not None else eval_net.state_dict()
910
+ best_model = {k.replace("module.", ""): v.detach().cpu().clone() for k, v in best_model.items()}
911
+ if self.return_last:
912
+ last_model = eval_net.state_dict()
913
+ last_model = {k.replace("module.", ""): v.detach().cpu().clone() for k, v in last_model.items()}
914
+
915
+ del network
916
+ torch.cuda.empty_cache()
917
+ gc.collect()
918
+ return training_log, best_model, last_model
919
+
920
+ def _time_str_to_seconds(self, time_str):
921
+ days, hours, minutes, seconds = map(int, time_str.split(":"))
922
+ return days * 86400 + hours * 3600 + minutes * 60 + seconds
923
+
924
+ def _update_best_network(self, network, val_score, epoch):
925
+ topk = max(1, self.topk)
926
+ self.best_stage.append([val_score, epoch, {k: v.detach().cpu().clone() for k, v in network.state_dict().items()}])
927
+ self.best_stage = sorted(self.best_stage, reverse=(self.mode == 'max'), key=lambda x: x[0])[:topk]
928
+ if val_score in [x[0] for x in self.best_stage]:
929
+ return True
930
+ return False
931
+
932
+ def is_early_stopping(self, epoch):
933
+ if self.best_stage[0][1] is None:
934
+ return False
935
+ if not self.early_stopping:
936
+ return False
937
+ return epoch - self.best_stage[0][1] >= self.early_stopping
938
+
939
+ def _at_time_limit(self, start_training_time):
940
+ return time.time() - start_training_time >= self.training_time
941
+
942
+ def _save_state_dict(self, network):
943
+ if self.topk <= 0:
944
+ return
945
+
946
+ if self.save_best:
947
+ for r in range(self.topk):
948
+ os.makedirs(f'{self.checkpoints_dir}/r{r+1}s', exist_ok=True)
949
+
950
+ for rank, (score, epoch, state_dict) in enumerate(self.best_stage):
951
+ if state_dict is None:
952
+ continue
953
+ state_dict = {k.replace("module.", ""): v.detach().cpu().clone() for k, v in state_dict.items()}
954
+ torch.save(state_dict, f'{self.checkpoints_dir}/r{rank+1}s/{self.save_name}_r{rank+1}_vs{score:.5f}_{"ema" if self.ema_net is not None else ""}.pth')
955
+ if self.save_last:
956
+ os.makedirs(f'{self.checkpoints_dir}/lasts', exist_ok=True)
957
+ state_dict = {k.replace("module.", ""): v.detach().cpu().clone() for k, v in network.state_dict().items()}
958
+ torch.save(state_dict, f'{self.checkpoints_dir}/lasts/{self.save_name}_last_{"ema" if self.ema_net is not None else ""}.pth')
959
+
960
+ def _train_epoch(self, network, train_loader, optimizer, scheduler, loss_fn, teaching_rate):
961
+ network.train()
962
+ total_loss = 0
963
+ total_loss_dict = {}
964
+ for batch_idx, batch in enumerate(train_loader):
965
+ optimizer.zero_grad()
966
+ with torch.autocast(device_type=self.device, dtype=torch.float16):
967
+ loss, loss_dict = self._cal_loss(network, batch, batch_idx, loss_fn, teaching_rate)
968
+
969
+ for k, v in loss_dict.items():
970
+ t = total_loss_dict.get(k, 0)
971
+ total_loss_dict[k] = t + v
972
+ self.grad_scaler.scale(loss).backward()
973
+ self.grad_scaler.unscale_(optimizer)
974
+ grad_norm = nn.utils.clip_grad_norm_(network.parameters(), self.max_grad_norm)
975
+ # print(grad_norm) # Bỏ cmt dòng này để biết nên chọn max_grad_norm bằng bao nhiêu...
976
+ self.grad_scaler.step(optimizer)
977
+ self.grad_scaler.update()
978
+ if self.schedule_in_step and scheduler:
979
+ scheduler.step()
980
+ if self.use_ema and self.ema_net is not None:
981
+ self.ema_net.update(network)
982
+ total_loss += loss
983
+ return (total_loss / len(train_loader)).item(), {k: v.item() / len(train_loader) for k, v in total_loss_dict.items()}
984
+
985
+ def _eval_epoch(self, network, val_loader, eval_fn, id2label):
986
+ network.eval()
987
+ total_score = 0.0
988
+ total_score_dict = {}
989
+ object_lists = None # sẽ init sau
990
+
991
+ with torch.no_grad():
992
+ for batch_idx, batch in enumerate(val_loader):
993
+ score, score_dict, objects = self._cal_val_score(network, batch, batch_idx, eval_fn, id2label)
994
+ total_score += score
995
+
996
+ for k, v in score_dict.items():
997
+ t = total_score_dict.get(k, 0)
998
+ total_score_dict[k] = t + v
999
+
1000
+ if objects:
1001
+ if object_lists is None:
1002
+ object_lists = [[] for _ in range(len(objects))]
1003
+
1004
+ for i, obj in enumerate(objects):
1005
+ object_lists[i].append(obj.detach())
1006
+
1007
+ if object_lists is not None:
1008
+ object_arrays = [
1009
+ torch.concat(obj_list, dim=0).cpu().numpy()
1010
+ for obj_list in object_lists
1011
+ ]
1012
+ else:
1013
+ object_arrays = []
1014
+
1015
+ return total_score / len(val_loader), {k: v / len(val_loader) for k, v in total_score_dict.items()}, object_arrays
1016
+
1017
+ def _cal_loss(self, network, batch, batch_idx, loss_fn, teaching_rate):
1018
+ # Bạn cần override _cal_loss để tính loss
1019
+ input_ids = batch['input_ids'].to(self.device)
1020
+ attention_mask = batch['attention_mask'].to(self.device)
1021
+
1022
+ sampled_spans = batch['sampled_spans'].to(self.device) # B, M, 2
1023
+ sampled_labels = batch['sampled_labels'].to(self.device) # B, M
1024
+ sampled_weights = batch['sampled_weights'].to(self.device) # B, M
1025
+
1026
+ span_logits = network(input_ids, attention_mask, sampled_spans)
1027
+
1028
+ loss_dict = loss_fn(
1029
+ span_logits, sampled_labels, sampled_weights,
1030
+ )
1031
+ return loss_dict['total'], loss_dict
1032
+
1033
+ def _cal_val_score(self, network, batch, batch_idx, eval_fn, id2label):
1034
+ # Bạn cần override _cal_val_score để tính val score, list bên cạnh là để trả về y hay pred gì đó (nếu cần)
1035
+ input_ids = batch['input_ids'].to(self.device)
1036
+ attention_mask = batch['attention_mask'].to(self.device)
1037
+ all_spans = batch['all_spans'].to(self.device) # B, N, 2
1038
+ gold_entities = batch['gold_entities']
1039
+
1040
+ B, _, _ = input_ids.shape
1041
+
1042
+ span_logits = network(input_ids, attention_mask, all_spans)
1043
+
1044
+ pred_ids = extract_entities(input_ids.reshape(B, -1), span_logits, all_spans, id2label)
1045
+ pred_ids = list_to_tuple(pred_ids)
1046
+
1047
+ gold_ids = list_to_tuple(gold_entities)
1048
+
1049
+ score_dict = eval_fn(pred_ids, gold_ids)
1050
+ return score_dict['f1'], score_dict, []
1051
+
1052
+ # %% [code]
1053
+ class PhoBERTSpanAligner:
1054
+ def __init__(self, tokenizer, max_len):
1055
+ self.tokenizer = tokenizer
1056
+ self.max_len = max_len
1057
+
1058
+ # ===== 1. Extract discontinuous spans =====
1059
+ def extract_spans(self, sample):
1060
+ entity_spans = []
1061
+
1062
+ for event in sample["entities"]:
1063
+ entity_type = event["label"]
1064
+ spans = [tuple(event["offset"])]
1065
+ entity_spans.append({
1066
+ "spans": spans,
1067
+ "label": entity_type
1068
+ })
1069
+
1070
+ return entity_spans
1071
+
1072
+ # ===== 2. Word offsets =====
1073
+ def build_word_offsets(self, text, words):
1074
+ offsets = []
1075
+ pointer = 0
1076
+
1077
+ for word in words:
1078
+ start = text.find(word, pointer)
1079
+ end = start + len(word)
1080
+ offsets.append((start, end))
1081
+ pointer = end
1082
+
1083
+ return offsets
1084
+
1085
+ # ===== 3. Char → word =====
1086
+ def char_span_to_word_span(self, word_offsets, start, end):
1087
+ start_word = None
1088
+ end_word = None
1089
+
1090
+ for i, (w_start, w_end) in enumerate(word_offsets):
1091
+ if w_start <= start < w_end:
1092
+ start_word = i
1093
+ if w_start < end <= w_end:
1094
+ end_word = i
1095
+
1096
+ return start_word, end_word
1097
+
1098
+ # ===== 4. Word → subword =====
1099
+ def word_to_subword_map(self, words):
1100
+ mapping = []
1101
+ subword_index = 1 # <s>
1102
+
1103
+ for word in words:
1104
+ sub_tokens = self.tokenizer.tokenize(word)
1105
+ start = subword_index
1106
+ end = subword_index + len(sub_tokens) - 1
1107
+ mapping.append((start, end))
1108
+ subword_index += len(sub_tokens)
1109
+
1110
+ return mapping
1111
+
1112
+ # ===== 5. Span → subword =====
1113
+ def span_to_subword(self, word_offsets, word_subword_map, spans):
1114
+ sub_spans = []
1115
+
1116
+ for span_start, span_end in spans:
1117
+ w_start, w_end = self.char_span_to_word_span(
1118
+ word_offsets, span_start, span_end
1119
+ )
1120
+ if w_start is None or w_end is None:
1121
+ continue
1122
+
1123
+ sub_start = word_subword_map[w_start][0]
1124
+ sub_end = word_subword_map[w_end][1]
1125
+ sub_spans.append((sub_start, sub_end))
1126
+
1127
+ return sub_spans
1128
+
1129
+ def extract_valid_spans(self, sub_spans):
1130
+ valid_spans = []
1131
+ for s, e in sub_spans:
1132
+ if s < 0 or e < 0 or s >= self.max_len or e >= self.max_len or s > e:
1133
+ continue
1134
+ valid_spans.append((s, e))
1135
+ return valid_spans
1136
+
1137
+ def encode(self, sample):
1138
+ text = sample["text"]
1139
+ entities = self.extract_spans(sample)
1140
+
1141
+ # ===== 1. Word tokenize =====
1142
+ words = word_tokenize(text)
1143
+ sentence = " ".join(words)
1144
+
1145
+ # ===== 2. Mapping =====
1146
+ word_offsets = self.build_word_offsets(text, words)
1147
+ word_subword_map = self.word_to_subword_map(words)
1148
+
1149
+ # ===== 3. Tokenize FULL =====
1150
+ encoding = self.tokenizer(
1151
+ sentence,
1152
+ max_length=self.max_len,
1153
+ truncation=True,
1154
+ padding="max_length",
1155
+ return_tensors="pt"
1156
+ )
1157
+ input_ids = encoding["input_ids"][0]
1158
+ attention_mask = encoding["attention_mask"][0]
1159
+
1160
+ # ===== 5. Convert spans =====
1161
+ entities_gold_spans = []
1162
+
1163
+ for ent in entities:
1164
+ label = ent["label"]
1165
+
1166
+ sub_spans = self.span_to_subword(
1167
+ word_offsets,
1168
+ word_subword_map,
1169
+ ent["spans"]
1170
+ )
1171
+ valid_spans = self.extract_valid_spans(sub_spans)
1172
+ if len(valid_spans) == 0:
1173
+ continue
1174
+ entities_gold_spans.append((tuple(valid_spans), label))
1175
+
1176
+ return {
1177
+ "input_ids": input_ids,
1178
+ "attention_mask": attention_mask,
1179
+ "entities_gold_spans": entities_gold_spans,
1180
+ }
1181
+
1182
+ def generate_spans(attention_mask, max_span_len):
1183
+ seq_len = attention_mask.sum().item() - 2
1184
+ spans = []
1185
+ for i in range(1, seq_len+1):
1186
+ for j in range(i, min(i+max_span_len, seq_len+1)):
1187
+ spans.append((i, j))
1188
+ return spans
1189
+
1190
+ def match_gold_labels(
1191
+ gold_spans, # (N, 2)
1192
+ gold_labels, # (N,)
1193
+ pred_spans, # (M, 2)
1194
+ default_label=-100
1195
+ ):
1196
+ """
1197
+ Return:
1198
+ pred_labels: (M,)
1199
+ """
1200
+
1201
+ pred_labels = torch.full(
1202
+ (pred_spans.size(0),),
1203
+ default_label,
1204
+ dtype=gold_labels.dtype,
1205
+ device=gold_labels.device
1206
+ )
1207
+ if gold_spans.size(0) == 0:
1208
+ return pred_labels
1209
+
1210
+ # (M, N)
1211
+ matched = (pred_spans[:, None, :] == gold_spans[None, :, :]).all(dim=-1)
1212
+ has_match = matched.any(dim=1)
1213
+
1214
+ # lấy index gold đầu tiên match
1215
+ gold_idx = matched.float().argmax(dim=1)
1216
+
1217
+ pred_labels[has_match] = gold_labels[gold_idx[has_match]]
1218
+
1219
+ return pred_labels
1220
+
1221
+ class KLTNDataset(Dataset):
1222
+ def __init__(
1223
+ self,
1224
+ all_data, using_idxes, label2id, tokenizer,
1225
+ max_len, max_n_parts, max_span_len, n_negs,
1226
+ weight_sampling=False, weight_rate=0.0
1227
+ ):
1228
+ super().__init__()
1229
+
1230
+ self.tokenizer = tokenizer
1231
+ self.aligner = PhoBERTSpanAligner(tokenizer, max_len * max_n_parts)
1232
+
1233
+ self.all_data = all_data
1234
+ self.using_idxes = using_idxes
1235
+ self.label2id = label2id
1236
+
1237
+ self.max_len = max_len
1238
+ self.max_n_parts = max_n_parts
1239
+ self.max_span_len = max_span_len
1240
+
1241
+ self.n_negs = n_negs
1242
+ self.weight_sampling = weight_sampling
1243
+ self.weight_rate = weight_rate
1244
+
1245
+ def __len__(self):
1246
+ return len(self.using_idxes)
1247
+
1248
+ def compute_iou(self, spans1, spans2):
1249
+ s1 = spans1[:, None, 0]
1250
+ e1 = spans1[:, None, 1]
1251
+
1252
+ s2 = spans2[None, :, 0]
1253
+ e2 = spans2[None, :, 1]
1254
+
1255
+ inter = (torch.minimum(e1, e2) - torch.maximum(s1, s2) + 1).clamp(min=0)
1256
+
1257
+ len1 = e1 - s1 + 1
1258
+ len2 = e2 - s2 + 1
1259
+
1260
+ union = len1 + len2 - inter
1261
+
1262
+ return inter.float() / union.float()
1263
+
1264
+ def sample_spans(self, all_spans, all_labels, gold_spans):
1265
+ pos_mask = all_labels != 0
1266
+ neg_mask = all_labels == 0
1267
+
1268
+ pos_indices = torch.nonzero(pos_mask, as_tuple=False).squeeze(-1)
1269
+ neg_indices = torch.nonzero(neg_mask, as_tuple=False).squeeze(-1)
1270
+
1271
+ n_negs = min(self.n_negs, len(neg_indices))
1272
+
1273
+ sampled_neg_weights = torch.ones(len(neg_indices), dtype=torch.float)
1274
+
1275
+ if len(gold_spans) > 0 and len(neg_indices) > 0:
1276
+ neg_spans = all_spans[neg_indices]
1277
+
1278
+ ious = self.compute_iou(neg_spans, gold_spans)
1279
+
1280
+ max_ious = ious.max(dim=1).values
1281
+
1282
+ sampled_neg_weights = 1.0 + self.weight_rate * max_ious
1283
+
1284
+ if n_negs > 0:
1285
+ if self.weight_sampling and len(neg_indices) > 0:
1286
+ probs = sampled_neg_weights / sampled_neg_weights.sum()
1287
+
1288
+ sampled_neg_ids = torch.multinomial(
1289
+ probs,
1290
+ n_negs,
1291
+ replacement=False
1292
+ )
1293
+
1294
+ neg_indices = neg_indices[sampled_neg_ids]
1295
+ sampled_neg_weights = sampled_neg_weights[sampled_neg_ids]
1296
+
1297
+ else:
1298
+ perm = torch.randperm(len(neg_indices))[:n_negs]
1299
+
1300
+ neg_indices = neg_indices[perm]
1301
+ sampled_neg_weights = sampled_neg_weights[perm]
1302
+
1303
+ pos_weights = torch.ones(len(pos_indices), dtype=torch.float)
1304
+
1305
+ sampled_indices = torch.cat([pos_indices, neg_indices], dim=0)
1306
+
1307
+ sampled_weights = torch.cat([pos_weights, sampled_neg_weights], dim=0)
1308
+
1309
+ if len(sampled_indices) > 0:
1310
+ perm = torch.randperm(len(sampled_indices))
1311
+
1312
+ sampled_indices = sampled_indices[perm]
1313
+ sampled_weights = sampled_weights[perm]
1314
+
1315
+ sampled_spans = all_spans[sampled_indices]
1316
+ sampled_labels = all_labels[sampled_indices]
1317
+
1318
+ return sampled_spans, sampled_labels, sampled_weights
1319
+
1320
+ def __getitem__(self, idx):
1321
+ ridx = self.using_idxes[idx]
1322
+
1323
+ sample = self.all_data[ridx]
1324
+
1325
+ result = self.aligner.encode(sample)
1326
+
1327
+ input_ids = result["input_ids"].squeeze(0)
1328
+ attention_mask = result["attention_mask"].squeeze(0)
1329
+
1330
+ entities_gold_spans = result["entities_gold_spans"]
1331
+
1332
+ all_spans = torch.tensor(generate_spans(attention_mask, self.max_span_len))
1333
+
1334
+ gold_spans = (
1335
+ torch.tensor([spans[0] for spans, _ in entities_gold_spans], dtype=torch.long)
1336
+ if entities_gold_spans else
1337
+ torch.empty(0, 2, dtype=torch.long)
1338
+ )
1339
+
1340
+ gold_labels = (
1341
+ torch.tensor([self.label2id[label] for _, label in entities_gold_spans], dtype=torch.long)
1342
+ if entities_gold_spans else
1343
+ torch.empty(0, dtype=torch.long)
1344
+ )
1345
+
1346
+ all_labels = match_gold_labels(
1347
+ gold_spans,
1348
+ gold_labels,
1349
+ all_spans,
1350
+ default_label=0
1351
+ )
1352
+
1353
+ sampled_spans, sampled_labels, sampled_weights = self.sample_spans(
1354
+ all_spans,
1355
+ all_labels,
1356
+ gold_spans
1357
+ )
1358
+
1359
+ gold_entities = []
1360
+
1361
+ for spans, label in entities_gold_spans:
1362
+ s, e = spans[0]
1363
+
1364
+ gold_entities.append((tuple(input_ids[s:e+1].tolist()), label))
1365
+
1366
+ input_ids = input_ids.reshape(self.max_n_parts, self.max_len)
1367
+ attention_mask = attention_mask.reshape(self.max_n_parts, self.max_len)
1368
+
1369
+ n_valid_parts = math.ceil(attention_mask.sum().item() / self.max_len)
1370
+
1371
+ input_ids = input_ids[:n_valid_parts]
1372
+ attention_mask = attention_mask[:n_valid_parts]
1373
+
1374
+ return {
1375
+ "input_ids": input_ids,
1376
+ "attention_mask": attention_mask,
1377
+
1378
+ "sampled_spans": sampled_spans,
1379
+ "sampled_labels": sampled_labels,
1380
+ "sampled_weights": sampled_weights,
1381
+
1382
+ "all_spans": all_spans,
1383
+
1384
+ "gold_entities": gold_entities,
1385
+ }
1386
+
1387
+ def _pad_batch(tensor_list, pad_value=0):
1388
+ """
1389
+ tensor_list: list of tensors
1390
+ mỗi tensor shape: (Nk, n_parts_i, max_len_i)
1391
+
1392
+ return:
1393
+ padded tensor shape: (B, max_Nk, max_n_parts, max_len)
1394
+ """
1395
+
1396
+ # lấy max toàn batch
1397
+ max_Nk = max(t.size(0) for t in tensor_list)
1398
+ max_n_parts = max(t.size(1) for t in tensor_list)
1399
+ max_len = max(t.size(2) for t in tensor_list)
1400
+
1401
+ padded = []
1402
+
1403
+ for t in tensor_list:
1404
+ Nk, n_parts_i, max_len_i = t.shape
1405
+
1406
+ # pad chiều n_parts và max_len trước
1407
+ if n_parts_i < max_n_parts or max_len_i < max_len:
1408
+ new_t = t.new_full(
1409
+ (Nk, max_n_parts, max_len),
1410
+ pad_value
1411
+ )
1412
+ new_t[:, :n_parts_i, :max_len_i] = t
1413
+ t = new_t
1414
+
1415
+ # pad chiều Nk
1416
+ if Nk < max_Nk:
1417
+ pad_tensor = t.new_full(
1418
+ (max_Nk - Nk, max_n_parts, max_len),
1419
+ pad_value
1420
+ )
1421
+ t = torch.cat([t, pad_tensor], dim=0)
1422
+
1423
+ padded.append(t)
1424
+
1425
+ return torch.stack(padded) # (B, max_Nk, max_n_parts, max_len)
1426
+
1427
+ def collate_fn(batch):
1428
+ gold_entities = []
1429
+ for bidx, b in enumerate(batch):
1430
+ for entity in b['gold_entities']:
1431
+ gold_entities.append([bidx, entity])
1432
+
1433
+ input_ids = [b["input_ids"].unsqueeze(-1) for b in batch]
1434
+ attention_mask = [b["attention_mask"].unsqueeze(-1) for b in batch]
1435
+ sampled_spans = [b["sampled_spans"].unsqueeze(-1) for b in batch]
1436
+ sampled_labels = [b["sampled_labels"].unsqueeze(-1).unsqueeze(-1) for b in batch]
1437
+ sampled_weights = [b["sampled_weights"].unsqueeze(-1).unsqueeze(-1) for b in batch]
1438
+ all_spans = [b["all_spans"].unsqueeze(-1) for b in batch]
1439
+
1440
+ # pad theo Nk
1441
+ input_ids = _pad_batch(input_ids, pad_value=0).squeeze(-1)
1442
+ attention_mask = _pad_batch(attention_mask, pad_value=0).squeeze(-1)
1443
+ sampled_spans = _pad_batch(sampled_spans, pad_value=0).squeeze(-1)
1444
+ sampled_labels = _pad_batch(sampled_labels, pad_value=-100).squeeze(-1).squeeze(-1)
1445
+ sampled_weights = _pad_batch(sampled_weights, pad_value=0).squeeze(-1).squeeze(-1)
1446
+ all_spans = _pad_batch(all_spans, pad_value=0).squeeze(-1)
1447
+
1448
+ return {
1449
+ "input_ids": input_ids,
1450
+ "attention_mask": attention_mask,
1451
+
1452
+ "sampled_spans": sampled_spans,
1453
+ "sampled_labels": sampled_labels,
1454
+ "sampled_weights": sampled_weights,
1455
+
1456
+ "all_spans": all_spans,
1457
+ "gold_entities": gold_entities,
1458
+ }
1459
+
1460
+ # %% [code]
1461
+ def shift_bidx(spans, batch_idx):
1462
+ shifted = []
1463
+ for bidx, ent in spans:
1464
+ new_bidx = bidx + batch_idx * batch_size
1465
+ shifted.append((new_bidx, ent))
1466
+ return shifted
1467
+
1468
+ def refactor_entities(entities, save_dict):
1469
+ i, c = [], []
1470
+ for bidx, (ids, lb) in entities:
1471
+ if (bidx, ids) not in i:
1472
+ i.append((bidx, ids))
1473
+
1474
+ if (bidx, (ids, lb)) not in c:
1475
+ c.append((bidx, (ids, lb)))
1476
+
1477
+ save_dict['Ent-I'].extend(i)
1478
+ save_dict['Ent-C'].extend(c)
1479
+
1480
+ def test(network, state_dicts, test_loader, eval_fn, analyzer, device, id2label, tokenizer):
1481
+ if torch.cuda.device_count() > 1:
1482
+ network = DataParallelProxy(network)
1483
+ network = network.to(device)
1484
+ network.eval()
1485
+
1486
+ eval_types = ['Ent-I', 'Ent-C']
1487
+
1488
+ all_pred = {eval_type: [] for eval_type in eval_types}
1489
+ all_gold = {eval_type: [] for eval_type in eval_types}
1490
+
1491
+ list_input_ids = []
1492
+
1493
+ with torch.no_grad():
1494
+ for batch_idx, batch in enumerate(test_loader):
1495
+ input_ids = batch['input_ids'].to(device)
1496
+ attention_mask = batch['attention_mask'].to(device)
1497
+ all_spans = batch['all_spans'].to(device)
1498
+ gold_entities = batch['gold_entities']
1499
+
1500
+ B, _, _ = input_ids.shape
1501
+ list_input_ids.extend(input_ids.reshape(B, -1).tolist())
1502
+
1503
+ list_hidden_states = []
1504
+ list_logits = []
1505
+ list_start_logits = []
1506
+ list_end_logits = []
1507
+ for sd in state_dicts:
1508
+ if torch.cuda.device_count() > 1:
1509
+ network.module.load_state_dict(sd)
1510
+ else:
1511
+ network.load_state_dict(sd)
1512
+
1513
+ span_logits = network(input_ids, attention_mask, all_spans)
1514
+ list_logits.append(span_logits)
1515
+
1516
+ ensemble_logits = torch.stack(list_logits, dim=0).mean(dim=0)
1517
+ pred_entities = extract_entities(input_ids.reshape(B, -1), ensemble_logits, all_spans, id2label)
1518
+ pred_entities = shift_bidx(pred_entities, batch_idx)
1519
+ refactor_entities(pred_entities, all_pred)
1520
+
1521
+ gold_entities = shift_bidx(gold_entities, batch_idx)
1522
+ refactor_entities(gold_entities, all_gold)
1523
+
1524
+ # ===== GLOBAL EVAL =====
1525
+ final_score = {}
1526
+ for eval_type in eval_types:
1527
+ score = eval_fn(list_to_tuple(all_pred[eval_type]), list_to_tuple(all_gold[eval_type]))
1528
+ final_score[eval_type] = score
1529
+
1530
+ analyze_result = analyzer.analyze(list_to_tuple(all_pred['Ent-I']), list_to_tuple(all_gold['Ent-I']))
1531
+
1532
+ # ===== PREDICT =====
1533
+ predictions = []
1534
+ for input_ids in list_input_ids:
1535
+ predictions.append([tokenizer.decode(input_ids, skip_special_tokens=True, clean_up_tokenization_spaces=True)])
1536
+ for bidx, (ids, lb) in all_pred['Ent-C']:
1537
+ predictions[bidx].append((tokenizer.decode(ids, skip_special_tokens=True, clean_up_tokenization_spaces=True), lb))
1538
+
1539
+ return final_score, analyze_result, predictions
1540
+
1541
+ # %% [code]
1542
+ with open(f'{train_dir}/train.json', "r", encoding="utf-8") as f:
1543
+ data_train = json.load(f)
1544
+
1545
+ with open(f'{test_dir}/test.json', "r", encoding="utf-8") as f:
1546
+ data_test = json.load(f)
1547
+
1548
+ print('Train:', len(data_train))
1549
+ print('Test:', len(data_test))
1550
+
1551
+ # %% [code]
1552
+ entity_types = ['O'] + sorted(list(set([e['label'] for d in data_train + data_test for e in d['entities']])))
1553
+ # bio_entity_type = ['O'] + [f'{prefix}-{ent}' for ent in entity_types for prefix in ['B', 'I']]
1554
+ label2id = {l: i for i, l in enumerate(entity_types)}
1555
+ id2label = {i: l for l, i in label2id.items()}
1556
+
1557
+ # %% [code]
1558
+ zero_entities_idxes = []
1559
+ for idx, d in enumerate(data_train):
1560
+ if len(d['entities']) == 0:
1561
+ zero_entities_idxes.append(idx)
1562
+
1563
+ n_zero_entities_samples = len(zero_entities_idxes)
1564
+ n_has_entities_samples = len(data_train) - n_zero_entities_samples
1565
+
1566
+ random.seed(42)
1567
+ k = min(int(n_has_entities_samples * zero_entities_rate), len(zero_entities_idxes))
1568
+ sampled_zero_entities_idxes = random.sample(zero_entities_idxes, k)
1569
+
1570
+ new_data_train = []
1571
+ for idx, d in enumerate(data_train):
1572
+ if len(d['entities']) == 0:
1573
+ if idx in sampled_zero_entities_idxes:
1574
+ new_data_train.append(d)
1575
+ else:
1576
+ new_data_train.append(d)
1577
+ data_train = new_data_train
1578
+
1579
+ print('Train:', len(data_train))
1580
+
1581
+ # %% [code]
1582
+ if debug_only:
1583
+ data_train = data_train[:20]
1584
+ data_test = data_test[:20]
1585
+
1586
+ print('Train:', len(data_train))
1587
+ print('Test:', len(data_test))
1588
+
1589
+ # %% [code]
1590
+ tokenizer = AutoTokenizer.from_pretrained(backbone_model_name)
1591
+
1592
+ # %% [code]
1593
+ print('Experiment name:', state_dict_save_name)
1594
+
1595
+ # %% [code]
1596
+ # trainset = KLTNDataset(data_train, np.array(range(len(data_train))), label2id, tokenizer, **train_memory_params)
1597
+ # train_loader = DataLoader(trainset, collate_fn=collate_fn, **train_loader_params)
1598
+ # for b in train_loader:
1599
+ # break
1600
+
1601
+ # %% [code]
1602
+ if not test_only:
1603
+ full_idxes = np.array(range(len(data_train)))
1604
+ training_logs, best_models, last_models = [], [], []
1605
+ start_training_time = time.time()
1606
+ for seed in SEEDS:
1607
+ kf = KFold(n_splits=nfolds, shuffle=True, random_state=seed)
1608
+ for fold_idx, (tr_idx, va_idx) in enumerate(kf.split(full_idxes)):
1609
+ if only_fold_idx is not None and only_fold_idx >= 0 and only_fold_idx != fold_idx:
1610
+ continue
1611
+ set_seed(seed)
1612
+
1613
+ train_idxes, val_idxes = full_idxes[tr_idx], full_idxes[va_idx]
1614
+
1615
+ trainset = KLTNDataset(data_train, train_idxes, label2id, tokenizer, **train_memory_params)
1616
+ valset = KLTNDataset(data_train, val_idxes, label2id, tokenizer, **val_memory_params)
1617
+
1618
+ generator = torch.Generator()
1619
+ generator.manual_seed(seed)
1620
+ train_loader = DataLoader(trainset, generator=generator, collate_fn=collate_fn, **train_loader_params)
1621
+ val_loader = DataLoader(valset, generator=generator, collate_fn=collate_fn, **val_loader_params)
1622
+
1623
+ my_model = IEModel(
1624
+ num_labels=len(label2id),
1625
+ **model_params
1626
+ )
1627
+ total_params = sum(p.numel() for p in my_model.parameters())
1628
+ print(f"Total params: {total_params:,}")
1629
+
1630
+ # optimizer, scheduler = configure_optimizers(my_model, optim_params, scheduler_params)
1631
+ encoder_params = set(map(id, my_model.encoder.parameters()))
1632
+ other_params = [
1633
+ p for p in my_model.parameters()
1634
+ if id(p) not in encoder_params
1635
+ ]
1636
+ optimizer = optim.AdamW([
1637
+ {"params": my_model.encoder.parameters(), "lr": 2e-5},
1638
+ {"params": other_params}
1639
+ ], lr=5e-4)
1640
+ scheduler = optim.lr_scheduler.CosineAnnealingLR(optimizer, T_max=20, eta_min=1e-6)
1641
+
1642
+ loss_fn = CustomLoss(
1643
+ **loss_func_params
1644
+ )
1645
+ eval_fn = CustomEvalFn(**eval_func_params)
1646
+ trainer_params['save_name'] = f'{state_dict_save_name}_s{seed}_f{fold_idx}'
1647
+ trainer = Trainer(**trainer_params)
1648
+
1649
+ print(f'Start Training Fold {fold_idx}...')
1650
+ training_log, best_model, last_model = trainer.fit(
1651
+ my_model, optimizer, scheduler, loss_fn, epochs, train_loader, val_loader, eval_fn,
1652
+ start_epoch=1, start_training_time=start_training_time, id2label=id2label
1653
+ )
1654
+
1655
+ training_logs.append(training_log)
1656
+ best_models.append(best_model)
1657
+ last_models.append(last_model)
1658
+
1659
+ # %% [code]
1660
+ def load_all_state_dicts(folder):
1661
+ files = []
1662
+
1663
+ for file in os.listdir(folder):
1664
+ if file.endswith(".pt") or file.endswith(".pth"):
1665
+ m = re.search(r"f(\d+)", file) # tìm f<số>
1666
+ if m:
1667
+ fold = int(m.group(1))
1668
+ files.append((fold, file))
1669
+
1670
+ # sort theo fold
1671
+ files.sort(key=lambda x: x[0])
1672
+
1673
+ state_dicts = []
1674
+ for fold, file in files:
1675
+ path = os.path.join(folder, file)
1676
+ print(f"Loading fold {fold}: {file}")
1677
+ state_dict = torch.load(path, map_location="cpu")
1678
+ state_dicts.append(state_dict)
1679
+
1680
+ return state_dicts
1681
+
1682
+ if test_only:
1683
+ snapshot_download(repo_id=repo_name, local_dir="", repo_type="model", allow_patterns=[f"{state_dict_save_name}/**"])
1684
+ get_ipython().system('rm -rf .cache .gitattributes')
1685
+
1686
+ best_models = load_all_state_dicts(f"{state_dict_save_name}/r1s")
1687
+ last_models = load_all_state_dicts(f"{state_dict_save_name}/lasts")
1688
+
1689
+ # %% [code]
1690
+ os.makedirs(f'{checkpoints_dir}/results', exist_ok=True)
1691
+ testset = KLTNDataset(data_test, range(len(data_test)), label2id, tokenizer, **val_memory_params)
1692
+ generator = torch.Generator()
1693
+ test_loader = DataLoader(testset, generator=generator, collate_fn=collate_fn, **val_loader_params)
1694
+ eval_fn = CustomEvalFn(**eval_func_params)
1695
+ analyzer = SpanErrorAnalyzer()
1696
+ my_model = IEModel(
1697
+ num_labels=len(label2id),
1698
+ **model_params
1699
+ )
1700
+ total_params = sum(p.numel() for p in my_model.parameters())
1701
+ print(f"Total params: {total_params:,}")
1702
+
1703
+ # %% [code]
1704
+ start_time = time.time()
1705
+
1706
+ best_score, best_analyze_result, best_pred_test = test(my_model, best_models, test_loader, eval_fn, analyzer, device, id2label, tokenizer)
1707
+ last_score, last_analyze_result, last_pred_test = test(my_model, last_models, test_loader, eval_fn, analyzer, device, id2label, tokenizer)
1708
+
1709
+ result_test = {"Best model": best_score, "Last model": last_score}
1710
+ analyze_result = {"Best model": best_analyze_result, "Last model": last_analyze_result}
1711
+ analyze_result_sumary = {"Best model": best_analyze_result['summary'], "Last model": last_analyze_result['summary']}
1712
+ pred_test = {"Best model": best_pred_test, "Last model": last_pred_test}
1713
+
1714
+ with open(f"{checkpoints_dir}/results/{state_dict_save_name}_test.json", "w", encoding="utf-8") as f:
1715
+ json.dump(result_test, f, ensure_ascii=False, indent=2)
1716
+
1717
+ with open(f"{checkpoints_dir}/results/{state_dict_save_name}_error_analyze_result.json", "w", encoding="utf-8") as f:
1718
+ json.dump(analyze_result, f, ensure_ascii=False, indent=2)
1719
+
1720
+ with open(f"{checkpoints_dir}/results/{state_dict_save_name}_pred_test.json", "w", encoding="utf-8") as f:
1721
+ json.dump(pred_test, f, ensure_ascii=False, indent=2)
1722
+
1723
+ print('Test:', time.time() - start_time, 's --> Done!')
1724
+ print(json.dumps(analyze_result_sumary, ensure_ascii=False, indent=4))
1725
+
1726
+ # %% [code]
1727
+ best_pred_test[:10]
1728
+
1729
+ # %% [code]
1730
+ last_pred_test[:10]
1731
+
1732
+ # %% [code]
1733
+ def dict_to_df(data):
1734
+ row_tuples = []
1735
+ row_values = []
1736
+
1737
+ metrics = ["precision", "recall", "f1"]
1738
+
1739
+ # L���y model đầu tiên
1740
+ first_model = next(iter(data.values()))
1741
+
1742
+ # eval_keys
1743
+ eval_keys = list(first_model.keys())
1744
+
1745
+ for eval_key in eval_keys:
1746
+ row_tuples.append(eval_key)
1747
+ row = {}
1748
+
1749
+ for model_name, model_data in data.items():
1750
+ for metric in metrics:
1751
+ row[(model_name, metric)] = model_data[eval_key][metric]
1752
+
1753
+ row_values.append(row)
1754
+
1755
+ # ===== DataFrame =====
1756
+ df = pd.DataFrame(row_values)
1757
+
1758
+ # MultiIndex columns
1759
+ df.columns = pd.MultiIndex.from_tuples(df.columns)
1760
+
1761
+ # Index
1762
+ df.index = pd.Index(row_tuples, name="evaluation")
1763
+
1764
+ # ===== Sort =====
1765
+ sort_keys = []
1766
+ if ("Best model", "f1") in df.columns:
1767
+ sort_keys.append(("Best model", "f1"))
1768
+ if ("Last model", "f1") in df.columns:
1769
+ sort_keys.append(("Last model", "f1"))
1770
+
1771
+ if sort_keys:
1772
+ df = df.sort_values(by=sort_keys, ascending=False)
1773
+
1774
+ return df
1775
+
1776
+ result_test_df = dict_to_df(result_test)
1777
+ result_test_df.to_excel(f"{checkpoints_dir}/results/{state_dict_save_name}_test_df.xlsx")
1778
+ result_test_df
1779
+
1780
+ # %% [code]
1781
+ key = ("Best model", "f1")
1782
+ result_test_df_best = result_test_df.sort_values(by=key, ascending=False).groupby(level="evaluation").head(1)
1783
+ result_test_df_best.to_excel(f"{checkpoints_dir}/results/{state_dict_save_name}_test_df_best.xlsx")
1784
+ result_test_df_best
1785
+
1786
+ # %% [code]
1787
+ def get_avg_best_score(logs):
1788
+ return float(np.mean([list(log.values())[-1]['best_score'] for log in logs]))
1789
+
1790
+ def get_avg_log(logs, epochs):
1791
+ avg_log = {}
1792
+
1793
+ for epoch in range(1, epochs + 1):
1794
+ val_score = 0.0
1795
+ train_loss = 0.0
1796
+ n_eval = 0
1797
+
1798
+ for idx in range(len(logs)):
1799
+ log = logs[idx].get(epoch, logs[idx].get(str(epoch)))
1800
+ if log is None:
1801
+ continue
1802
+
1803
+ val_score += log.get('val_score', 0.0)
1804
+ train_loss += log.get('train_loss', 0.0)
1805
+ n_eval += 1
1806
+
1807
+ if n_eval == 0:
1808
+ continue
1809
+
1810
+ avg_log[epoch] = {
1811
+ 'train_loss': train_loss / n_eval,
1812
+ 'val_score': val_score / n_eval if val_score != 0 else float('inf')
1813
+ }
1814
+
1815
+ return avg_log
1816
+
1817
+ def parse_label_key(label: str):
1818
+ try:
1819
+ first = float(label.split('_', 1)[0]) # số đầu: trước dấu _
1820
+ last = float(re.findall(r'_(\d+(?:\.\d+)?)$', label)[0])
1821
+ return first, last
1822
+ except:
1823
+ return (0, 0)
1824
+
1825
+ def plot_training_logs(logs_dict, save_path=None, figsize=(24, 10)):
1826
+ fig, axes = plt.subplots(1, 2, figsize=figsize)
1827
+
1828
+ # ===== Plot Train Loss =====
1829
+ for name, log in logs_dict.items():
1830
+ epochs = sorted(log.keys())
1831
+ train_loss = [log[e]['train_loss'] for e in epochs]
1832
+ axes[0].plot(epochs, train_loss, label=name)
1833
+
1834
+ axes[0].set_xlabel('Epoch')
1835
+ axes[0].set_ylabel('Train Loss')
1836
+ axes[0].set_title('Training Loss')
1837
+ axes[0].grid(True)
1838
+
1839
+ # ===== Plot Validation Score =====
1840
+ for name, log in logs_dict.items():
1841
+ epochs = sorted(log.keys())
1842
+ val_score = [log[e]['val_score'] for e in epochs]
1843
+ axes[1].plot(epochs, val_score, label=name)
1844
+
1845
+ axes[1].set_xlabel('Epoch')
1846
+ axes[1].set_ylabel('Validation Score')
1847
+ axes[1].set_title('Validation Score')
1848
+ axes[1].grid(True)
1849
+
1850
+ # ===== Shared Legend =====
1851
+ handles, labels = axes[0].get_legend_handles_labels()
1852
+ pairs = list(zip(handles, labels))
1853
+ pairs_sorted = sorted(
1854
+ pairs,
1855
+ key=lambda x: parse_label_key(x[1])
1856
+ )
1857
+ handles_sorted, labels_sorted = zip(*pairs_sorted)
1858
+
1859
+ axes[0].legend(
1860
+ handles_sorted,
1861
+ labels_sorted,
1862
+ loc='center left',
1863
+ bbox_to_anchor=(1.01, 0.5),
1864
+ borderaxespad=0.
1865
+ )
1866
+
1867
+ plt.tight_layout(rect=[0, 0, 1, 1])
1868
+
1869
+ if save_path is not None:
1870
+ os.makedirs(os.path.dirname(save_path), exist_ok=True) if os.path.dirname(save_path) else None
1871
+ plt.savefig(save_path, dpi=300, bbox_inches='tight')
1872
+
1873
+ plt.show()
1874
+
1875
+ # %% [code]
1876
+ # if not test_only:
1877
+ # snapshot_download(repo_id=repo_name, local_dir="", repo_type="model", allow_patterns=["**/*.json"])
1878
+ # !rm -rf .cache .gitattributes
1879
+
1880
+ # %% [code]
1881
+ if not test_only:
1882
+ experiments = {}
1883
+ for experiment in os.listdir(pretrained_dir):
1884
+ if '.virtual_documents' in experiment:
1885
+ continue
1886
+ experiment_logs = []
1887
+ try:
1888
+ for seed in SEEDS:
1889
+ for fold_idx in range(nfolds):
1890
+ with open(f"{pretrained_dir}/{experiment}/logs/{experiment}_s{seed}_f{fold_idx}_logging.json", "r", encoding="utf-8") as f:
1891
+ experiment_log = json.load(f)
1892
+ experiment_logs.append(experiment_log)
1893
+ except:
1894
+ pass
1895
+ experiments[experiment] = get_avg_log(experiment_logs, 1000)
1896
+ experiments[state_dict_save_name] = get_avg_log(training_logs, 1000)
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+
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+ # %% [code]
1899
+ if not test_only:
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+ score = get_avg_best_score(training_logs)
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+ state_dict_save_name, score
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+
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+ # %% [code]
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+ if not test_only:
1905
+ plot_training_logs(experiments, save_path=f'{checkpoints_dir}/logs/{state_dict_save_name}_log_plot.jpg', figsize=(18, 7.5))
1906
+
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