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blip / models /blip_vqa.py

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	from models.med import BertConfig, BertModel, BertLMHeadModel
	from models.blip import create_vit, init_tokenizer, load_checkpoint

	import torch
	from torch import nn
	import torch.nn.functional as F
	from transformers import BertTokenizer
	import numpy as np

	class BLIP_VQA(nn.Module):
	def __init__(self,
	med_config = 'configs/med_config.json',
	image_size = 480,
	vit = 'base',
	vit_grad_ckpt = False,
	vit_ckpt_layer = 0,
	):
	"""
	Args:
	med_config (str): path for the mixture of encoder-decoder model's configuration file
	image_size (int): input image size
	vit (str): model size of vision transformer
	"""
	super().__init__()

	self.visual_encoder, vision_width = create_vit(vit, image_size, vit_grad_ckpt, vit_ckpt_layer, drop_path_rate=0.1)
	self.tokenizer = init_tokenizer()

	encoder_config = BertConfig.from_json_file(med_config)
	encoder_config.encoder_width = vision_width
	self.text_encoder = BertModel(config=encoder_config, add_pooling_layer=False)

	decoder_config = BertConfig.from_json_file(med_config)
	self.text_decoder = BertLMHeadModel(config=decoder_config)


	def forward(self, image, question, answer=None, n=None, weights=None, train=True, inference='rank', k_test=128):

	image_embeds = self.visual_encoder(image)
	image_atts = torch.ones(image_embeds.size()[:-1],dtype=torch.long).to(image.device)

	question = self.tokenizer(question, padding='longest', truncation=True, max_length=35,
	return_tensors="pt").to(image.device)
	question.input_ids[:,0] = self.tokenizer.enc_token_id

	if train:
	'''
	n: number of answers for each question
	weights: weight for each answer
	'''
	answer = self.tokenizer(answer, padding='longest', return_tensors="pt").to(image.device)
	answer.input_ids[:,0] = self.tokenizer.bos_token_id
	answer_targets = answer.input_ids.masked_fill(answer.input_ids == self.tokenizer.pad_token_id, -100)

	question_output = self.text_encoder(question.input_ids,
	attention_mask = question.attention_mask,
	encoder_hidden_states = image_embeds,
	encoder_attention_mask = image_atts,
	return_dict = True)

	question_states = []
	question_atts = []
	for b, n in enumerate(n):
	question_states += [question_output.last_hidden_state[b]]*n
	question_atts += [question.attention_mask[b]]*n
	question_states = torch.stack(question_states,0)
	question_atts = torch.stack(question_atts,0)

	answer_output = self.text_decoder(answer.input_ids,
	attention_mask = answer.attention_mask,
	encoder_hidden_states = question_states,
	encoder_attention_mask = question_atts,
	labels = answer_targets,
	return_dict = True,
	reduction = 'none',
	)

	loss = weights * answer_output.loss
	loss = loss.sum()/image.size(0)

	return loss


	else:
	question_output = self.text_encoder(question.input_ids,
	attention_mask = question.attention_mask,
	encoder_hidden_states = image_embeds,
	encoder_attention_mask = image_atts,
	return_dict = True)

	if inference=='generate':
	num_beams = 3
	question_states = question_output.last_hidden_state.repeat_interleave(num_beams,dim=0)
	question_atts = torch.ones(question_states.size()[:-1],dtype=torch.long).to(question_states.device)
	model_kwargs = {"encoder_hidden_states": question_states, "encoder_attention_mask":question_atts}

	bos_ids = torch.full((image.size(0),1),fill_value=self.tokenizer.bos_token_id,device=image.device)

	outputs = self.text_decoder.generate(input_ids=bos_ids,
	max_length=10,
	min_length=1,
	num_beams=num_beams,
	eos_token_id=self.tokenizer.sep_token_id,
	pad_token_id=self.tokenizer.pad_token_id,
	**model_kwargs)

	answers = []
	for output in outputs:
	answer = self.tokenizer.decode(output, skip_special_tokens=True)
	answers.append(answer)
	return answers

	elif inference=='rank':
	max_ids = self.rank_answer(question_output.last_hidden_state, question.attention_mask,
	answer.input_ids, answer.attention_mask, k_test)
	return max_ids



	def rank_answer(self, question_states, question_atts, answer_ids, answer_atts, k):

	num_ques = question_states.size(0)
	start_ids = answer_ids[0,0].repeat(num_ques,1) # bos token

	start_output = self.text_decoder(start_ids,
	encoder_hidden_states = question_states,
	encoder_attention_mask = question_atts,
	return_dict = True,
	reduction = 'none')
	logits = start_output.logits[:,0,:] # first token's logit

	# topk_probs: top-k probability
	# topk_ids: [num_question, k]
	answer_first_token = answer_ids[:,1]
	prob_first_token = F.softmax(logits,dim=1).index_select(dim=1, index=answer_first_token)
	topk_probs, topk_ids = prob_first_token.topk(k,dim=1)

	# answer input: [num_question*k, answer_len]
	input_ids = []
	input_atts = []
	for b, topk_id in enumerate(topk_ids):
	input_ids.append(answer_ids.index_select(dim=0, index=topk_id))
	input_atts.append(answer_atts.index_select(dim=0, index=topk_id))
	input_ids = torch.cat(input_ids,dim=0)
	input_atts = torch.cat(input_atts,dim=0)

	targets_ids = input_ids.masked_fill(input_ids == self.tokenizer.pad_token_id, -100)

	# repeat encoder's output for top-k answers
	question_states = tile(question_states, 0, k)
	question_atts = tile(question_atts, 0, k)

	output = self.text_decoder(input_ids,
	attention_mask = input_atts,
	encoder_hidden_states = question_states,
	encoder_attention_mask = question_atts,
	labels = targets_ids,
	return_dict = True,
	reduction = 'none')

	log_probs_sum = -output.loss
	log_probs_sum = log_probs_sum.view(num_ques,k)

	max_topk_ids = log_probs_sum.argmax(dim=1)
	max_ids = topk_ids[max_topk_ids>=0,max_topk_ids]

	return max_ids


	def blip_vqa(pretrained='',**kwargs):
	model = BLIP_VQA(**kwargs)
	if pretrained:
	model,msg = load_checkpoint(model,pretrained)
	# assert(len(msg.missing_keys)==0)
	return model


	def tile(x, dim, n_tile):
	init_dim = x.size(dim)
	repeat_idx = [1] * x.dim()
	repeat_idx[dim] = n_tile
	x = x.repeat(*(repeat_idx))
	order_index = torch.LongTensor(np.concatenate([init_dim * np.arange(n_tile) + i for i in range(init_dim)]))
	return torch.index_select(x, dim, order_index.to(x.device))