MRaCL / ASDA /dataset /data_loader_gref_sbert.py

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	# -- coding: utf-8 --

	"""
	refcoco, refcoco+ and refcocog referring image detection and segmentation PyTorch dataset.
	"""
	import sys
	import cv2
	import os
	import torch
	import json
	import random
	import numpy as np
	import os.path as osp
	import torch.utils.data as data
	sys.path.append('.')
	import utils
	import re

	# from pytorch_pretrained_bert.tokenization import BertTokenizer
	from utils.transforms import letterbox, random_affine, random_copy, random_crop, random_erase
	import copy

	import clip

	sys.modules['utils'] = utils
	cv2.setNumThreads(0)

	class ReferDataset(data.Dataset):
	SUPPORTED_DATASETS = {
	'refcoco': {
	'splits': ('train', 'val', 'testA', 'testB'),
	'params': {'dataset': 'refcoco', 'split_by': 'unc'}
	},
	'refcoco+': {
	'splits': ('train', 'val', 'testA', 'testB'),
	'params': {'dataset': 'refcoco+', 'split_by': 'unc'}
	},
	'refcocog': {
	'splits': ('train', 'val', 'test'),
	'params': {'dataset': 'refcocog', 'split_by': 'unc'}
	},
	'refcocog_g': {
	'splits': ('train', 'val'),
	'params': {'dataset': 'refcocog', 'split_by': 'google'}
	},
	'refcocog_u': {
	'splits': ('train', 'val', 'test'),
	'params': {'dataset': 'refcocog', 'split_by': 'unc'}
	},
	'grefcoco': {
	'splits': ('train', 'val', 'testA', 'testB'),
	'params': {'dataset': 'grefcoco', 'split_by': 'unc'}
	}
	}


	def _load_multi_obj_ref_ids(self):
	# Load multi-object reference IDs based on configurations
	if not self.exclude_multiobj and not self.exclude_position :
	return None
	elif self.exclude_position:
	multiobj_path = os.path.join(self.ROOT, 'multiobj_ov2_nopos.txt')
	elif self.exclude_multiobj :
	multiobj_path = os.path.join(self.ROOT, 'multiobj_ov3.txt')
	with open(multiobj_path, 'r') as f:
	return [int(line.strip()) for line in f.readlines()]

	def _load_metadata(self):
	# Load metadata for hard positive verb phrases, hard negative queries
	# we set refined file as default option
	hardpos_path = '/data2/projects/seunghoon/VerbRIS/CrossVLT/hardpos_verdict_gref_v4.json'
	with open(hardpos_path, 'r', encoding='utf-8') as f:
	hardpos_json = json.load(f)
	return hardpos_json

	def __init__(self, data_root, split_root='data', dataset='refcoco', imsize=256, splitby='umd',
	transform=None, augment=False, split='train', max_query_len=128, metric_learning=None):
	images_tmp = []
	self.data_root = data_root
	self.split_root = split_root
	self.dataset = dataset
	self.imsize = imsize
	self.query_len = max_query_len
	self.transform = transform
	self.word_len = 17
	self.emb_size = 384
	self.split = split
	self.augment=augment

	valid_splits = self.SUPPORTED_DATASETS[self.dataset]['splits']

	if split not in valid_splits:
	raise ValueError(
	'Dataset {0} does not have split {1}'.format(
	self.dataset, split))

	self.anns_root = osp.join(self.data_root, 'anns', self.dataset, self.split+'.txt')
	if self.dataset == 'refcocog' :
	mask_anno_str = '{0}_{1}'.format(self.dataset, splitby)
	self.mask_root = osp.join(self.data_root, 'masks', mask_anno_str)
	else :
	self.mask_root = osp.join(self.data_root, 'masks', self.dataset)

	self.im_dir = osp.join(self.data_root, 'images', 'train2014')


	if self.dataset == 'refcocog' :
	dataset_path = osp.join(self.split_root, self.dataset + '_' + splitby)
	splits = [split]
	for split in splits:
	imgset_file = '{0}_{1}_{2}.pth'.format(self.dataset, splitby, split)
	imgset_path = osp.join(dataset_path, imgset_file)
	images_tmp += torch.load(imgset_path)

	# metric learning options
	self.ROOT = '/data2/projects/seunghoon/VerbRIS/VerbCentric_CY/'
	self.all_hp_root = "/data2/dataset/RefCOCO/refcocog/SBERT_gref_umd"
	# self.exclude_position = args.exclude_pos
	self.exclude_position = True
	self.exclude_multiobj = True
	self.metric_learning = metric_learning

	# self.metric_mode = args.metric_mode
	self.hp_selection = 'strict'

	# meta data loading
	if self.metric_learning and self.split == 'train':
	self.multi_obj_ref_ids = self._load_multi_obj_ref_ids()
	self.hardpos_meta = self._load_metadata()

	# make new self.images file with sentence idx and total sent num (per ref_id)
	from collections import defaultdict
	ref_sentence_counts = defaultdict(int)
	for item in images_tmp:
	ref_sentence_counts[item[1]] += 1

	self.images = []
	ref_sentence_indices = defaultdict(int)
	for item in images_tmp:
	img_name, seg_id, box, sentence = item
	sent_index = ref_sentence_indices[seg_id]
	total_sentences = ref_sentence_counts[seg_id]
	self.images.append((img_name, seg_id, box, sentence, sent_index, total_sentences))
	ref_sentence_indices[seg_id] += 1

	else :
	self.images = images_tmp
	self.multi_obj_ref_ids = None
	self.hardpos_meta = None

	else :
	dataset_path = osp.join(self.split_root, self.dataset)
	splits = [split]
	for split in splits:
	imgset_file = '{0}_{1}.pth'.format(self.dataset, split)
	imgset_path = osp.join(dataset_path, imgset_file)
	self.images += torch.load(imgset_path)

	def exists_dataset(self):
	return osp.exists(osp.join(self.split_root, self.dataset))

	def _get_hardpos_verb(self, seg_id, sent_idx):
	"""
	Handle the logic for selecting hard positive verb phrases during metric learning.
	Returns the sentence, raw_verb, and tokenized verb if applicable.
	"""
	# If the object appears multiple times, no hard positive is used
	if seg_id in self.multi_obj_ref_ids:
	verb_embed = torch.zeros(self.emb_size, dtype=torch.float32)
	return '', verb_embed

	# Extract metadata for hard positives if present
	hardpos_dict = self.hardpos_meta.get(str(seg_id), {})
	if self.hp_selection == 'strict' :
	sent_id_list = list(hardpos_dict.keys())
	cur_sent_id = sent_id_list[sent_idx]
	cur_hardpos = hardpos_dict.get(cur_sent_id, {}).get('phrases', [])

	if cur_hardpos:
	# Assign a hard positive verb phrase if available
	rand_index = random.randint(0, len(cur_hardpos) - 1)
	raw_verb = cur_hardpos[rand_index]
	verb_embed = torch.from_numpy(self._get_hardpos_embed(seg_id, cur_sent_id, rand_index))
	# print("Positive phrase : " , raw_verb)
	return raw_verb, verb_embed

	verb_embed = torch.zeros(self.emb_size, dtype=torch.float32)
	return '', verb_embed


	def _get_hardpos_embed(self, seg_id, sent_id, rand_index):
	emb_folder = os.path.join(self.all_hp_root, str(seg_id))
	emb_files = sorted([f for f in os.listdir(emb_folder) if f.startswith(f"hp_{sent_id}_") and f.endswith(".npy")])
	selected_emb_file = os.path.join(emb_folder, emb_files[rand_index])

	return np.load(selected_emb_file)


	def pull_item(self, idx):
	# if metric learning and in train mode
	if self.metric_learning and self.augment :
	# sent_idx refers to index of sent among sent_num-1
	img_file, seg_id, bbox, phrase, sent_idx, sent_num = self.images[idx]
	else :
	img_file, seg_id, bbox, phrase = self.images[idx]
	bbox = np.array(bbox, dtype=int) # x1y1x2y2

	img_path = osp.join(self.im_dir, img_file)
	img = cv2.imread(img_path) # BGR [512, 640, 3]
	## duplicate channel if gray image
	if img.shape[-1] > 1:
	img = cv2.cvtColor(img, cv2.COLOR_BGR2RGB) #RGB
	else:
	img = np.stack([img] * 3)

	## seg map
	seg_map = np.load(osp.join(self.mask_root, str(seg_id)+'.npy')) # [512, 640]
	seg_map = np.array(seg_map).astype(np.float32)

	if self.metric_learning and self.split == 'train' :
	return img, phrase, bbox, seg_map, seg_id, sent_idx
	else :
	return img, phrase, bbox, seg_map, seg_id

	def __len__(self):
	return len(self.images)

	def __getitem__(self, idx):
	if self.metric_learning and self.augment :
	img, phrase, bbox, seg_map, seg_id, sent_idx = self.pull_item(idx)
	else :
	img, phrase, bbox, seg_map, seg_id = self.pull_item(idx)

	phrase = phrase.lower()
	if self.augment:
	augment_flip, augment_hsv, augment_affine, augment_crop, augment_copy, augment_erase = \
	True, True, True, False, False, False

	## seems a bug in torch transformation resize, so separate in advance
	h,w = img.shape[0], img.shape[1]
	# print("img.shape", img.shape)
	if self.augment:
	## random horizontal flip
	if augment_flip and random.random() > 0.5:
	img = cv2.flip(img, 1)
	seg_map = cv2.flip(seg_map, 1)
	bbox[0], bbox[2] = w-bbox[2]-1, w-bbox[0]-1
	phrase = phrase.replace('right','&^special^&').replace('left','right').replace('&^special^&','left')

	## random copy and add left or right
	if augment_copy:
	img, seg_map, phrase, bbox = random_copy(img, seg_map, phrase, bbox)

	## random erase for occluded
	if augment_erase:
	img, seg_map = random_erase(img, seg_map)

	## random padding and crop
	if augment_crop:
	img, seg_map = random_crop(img, seg_map, 40, h, w)

	## random intensity, saturation change
	if augment_hsv:
	fraction = 0.50
	img_hsv = cv2.cvtColor(cv2.cvtColor(img, cv2.COLOR_RGB2BGR), cv2.COLOR_BGR2HSV)
	S = img_hsv[:, :, 1].astype(np.float32)
	V = img_hsv[:, :, 2].astype(np.float32)
	a = (random.random() * 2 - 1) * fraction + 1
	if a > 1:
	np.clip(S, a_min=0, a_max=255, out=S)
	a = (random.random() * 2 - 1) * fraction + 1
	V *= a
	if a > 1:
	np.clip(V, a_min=0, a_max=255, out=V)

	img_hsv[:, :, 1] = S.astype(np.uint8)
	img_hsv[:, :, 2] = V.astype(np.uint8)
	img = cv2.cvtColor(cv2.cvtColor(img_hsv, cv2.COLOR_HSV2BGR), cv2.COLOR_BGR2RGB)

	img, seg_map, ratio, dw, dh = letterbox(img, seg_map, self.imsize)
	bbox[0], bbox[2] = bbox[0]ratio+dw, bbox[2]ratio+dw
	bbox[1], bbox[3] = bbox[1]ratio+dh, bbox[3]ratio+dh

	## random affine transformation
	if augment_affine:
	img, seg_map, bbox, M = random_affine(img, seg_map, bbox, \
	degrees=(-5, 5), translate=(0.10, 0.10), scale=(0.90, 1.10)) # 255 white fill

	else: ## should be inference, or specified training
	img, _, ratio, dw, dh = letterbox(img, None, self.imsize)
	bbox[0], bbox[2] = bbox[0]ratio+dw, bbox[2]ratio+dw
	bbox[1], bbox[3] = bbox[1]ratio+dh, bbox[3]ratio+dh

	draw_img = copy.deepcopy(img)
	# Norm, to tensor
	if self.transform is not None:
	img = self.transform(img)


	## encode phrase to clip input
	word_id = clip.tokenize(phrase, 17, truncate=True)
	word_mask = ~ (word_id == 0)

	orig_word_id = np.array(word_id, dtype=int)
	orig_word_mask = np.array(word_mask, dtype=int)

	# Get hardpos verb phrase
	if self.metric_learning and self.augment:
	raw_hardpos, hardpos_emb = self._get_hardpos_verb(seg_id, sent_idx)
	pos_type = 'nopos'
	if raw_hardpos:
	pos_type = 'hardpos'
	hardpos_id = clip.tokenize(raw_hardpos, self.word_len, truncate=True)
	else:
	# Empty phrase → Create a zero tensor matching shape of tokenized input
	hardpos_id = np.zeros((1, self.word_len), dtype=int)

	# Masking
	hardpos_mask = hardpos_id != 0 # Mask should be boolean

	hp_word_id = np.array(hardpos_id, dtype=int)
	hp_word_mask = np.array(hardpos_mask, dtype=int)

	if self.augment: # train
	seg_map = cv2.resize(seg_map, (self.imsize // 2, self.imsize // 2),interpolation=cv2.INTER_NEAREST) # (208, 208)
	seg_map = np.reshape(seg_map, [1, np.shape(seg_map)[0], np.shape(seg_map)[1]])
	if self.metric_learning :
	params = {
	'hp_word_id' : hp_word_id,
	'hp_word_mask' : hp_word_mask,
	'hardpos_emb' : hardpos_emb.unsqueeze(0),
	'pos_type' : pos_type
	}
	return img, orig_word_id, orig_word_mask, np.array(bbox, dtype=np.float32), \
	np.array(seg_map, dtype=np.float32), params
	else :
	return img, orig_word_id, orig_word_mask, \
	np.array(bbox, dtype=np.float32), np.array(seg_map, dtype=np.float32)
	else:
	seg_map = np.reshape(seg_map, [1, np.shape(seg_map)[0], np.shape(seg_map)[1]])
	return img, orig_word_id, orig_word_mask, \
	np.array(bbox, dtype=np.float32), np.array(seg_map, dtype=np.float32), np.array(ratio, dtype=np.float32), \
	np.array(dw, dtype=np.float32), np.array(dh, dtype=np.float32), self.images[idx][0], self.images[idx][3], np.array(draw_img, dtype=np.uint8)