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Grounded-Segment-Anything / ram_train_eval.py

liuyizhang

add ram

7a7f9d8 about 1 year ago

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	import os
	import time
	from datetime import timedelta
	import numpy as np
	import torch
	import torch.nn as nn
	import torch.nn.functional as F

	from mmengine.config import Config
	from mmengine.utils import ProgressBar
	from transformers import AutoConfig, AutoModel

	class RamDataset(torch.utils.data.Dataset):
	def __init__(self, data_path, is_train=True, num_relation_classes=56):
	super().__init__()
	self.num_relation_classes = num_relation_classes
	data = np.load(data_path, allow_pickle=True)
	self.samples = data["arr_0"]
	sample_num = self.samples.size
	self.sample_idx_list = []
	for idx in range(sample_num):
	if self.samples[idx]["is_train"] == is_train:
	self.sample_idx_list.append(idx)

	def __getitem__(self, idx):
	sample = self.samples[self.sample_idx_list[idx]]
	object_num = sample["feat"].shape[0]
	embedding = torch.from_numpy(sample["feat"])
	gt_rels = sample["relations"]
	rel_target = self._get_target(object_num, gt_rels)
	return embedding, rel_target, gt_rels

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

	def _get_target(self, object_num, gt_rels):
	rel_target = torch.zeros([self.num_relation_classes, object_num, object_num])
	for ii, jj, cls_relationship in gt_rels:
	rel_target[cls_relationship, ii, jj] = 1
	return rel_target


	class RamModel(nn.Module):
	def __init__(
	self,
	pretrained_model_name_or_path,
	load_pretrained_weights=True,
	num_transformer_layer=2,
	input_feature_size=256,
	output_feature_size=768,
	cls_feature_size=512,
	num_relation_classes=56,
	pred_type="attention",
	loss_type="bce",
	):
	super().__init__()
	# 0. config
	self.cls_feature_size = cls_feature_size
	self.num_relation_classes = num_relation_classes
	self.pred_type = pred_type
	self.loss_type = loss_type

	# 1. fc input and output
	self.fc_input = nn.Sequential(
	nn.Linear(input_feature_size, output_feature_size),
	nn.LayerNorm(output_feature_size),
	)
	self.fc_output = nn.Sequential(
	nn.Linear(output_feature_size, output_feature_size),
	nn.LayerNorm(output_feature_size),
	)
	# 2. transformer model
	if load_pretrained_weights:
	self.model = AutoModel.from_pretrained(pretrained_model_name_or_path)
	else:
	config = AutoConfig.from_pretrained(pretrained_model_name_or_path)
	self.model = AutoModel.from_config(config)
	if num_transformer_layer != "all" and isinstance(num_transformer_layer, int):
	self.model.encoder.layer = self.model.encoder.layer[:num_transformer_layer]
	# 3. predict head
	self.cls_sub = nn.Linear(output_feature_size, cls_feature_size * num_relation_classes)
	self.cls_obj = nn.Linear(output_feature_size, cls_feature_size * num_relation_classes)
	# 4. loss
	if self.loss_type == "bce":
	self.bce_loss = nn.BCEWithLogitsLoss()
	elif self.loss_type == "multi_label_ce":
	print("Use Multi Label Cross Entropy Loss.")

	def forward(self, embeds, attention_mask=None):
	"""
	embeds: (batch_size, token_num, feature_size)
	attention_mask: (batch_size, token_num)
	"""
	# 1. fc input
	embeds = self.fc_input(embeds)
	# 2. transformer model
	position_ids = torch.ones([1, embeds.shape[1]]).to(embeds.device).to(torch.long)
	outputs = self.model.forward(inputs_embeds=embeds, attention_mask=attention_mask, position_ids=position_ids)
	embeds = outputs["last_hidden_state"]
	# 3. fc output
	embeds = self.fc_output(embeds)
	# 4. predict head
	batch_size, token_num, feature_size = embeds.shape
	sub_embeds = self.cls_sub(embeds).reshape([batch_size, token_num, self.num_relation_classes, self.cls_feature_size]).permute([0, 2, 1, 3])
	obj_embeds = self.cls_obj(embeds).reshape([batch_size, token_num, self.num_relation_classes, self.cls_feature_size]).permute([0, 2, 1, 3])
	if self.pred_type == "attention":
	cls_pred = sub_embeds @ torch.transpose(obj_embeds, 2, 3) / self.cls_feature_size**0.5 # noqa
	elif self.pred_type == "einsum":
	cls_pred = torch.einsum("nrsc,nroc->nrso", sub_embeds, obj_embeds)
	return cls_pred

	def loss(self, pred, target, attention_mask):
	loss_dict = dict()
	batch_size, relation_num, _, _ = pred.shape

	mask = torch.zeros_like(pred).to(pred.device)
	for idx in range(batch_size):
	n = torch.sum(attention_mask[idx]).to(torch.int)
	mask[idx, :, :n, :n] = 1
	pred = pred * mask - 9999 * (1 - mask)

	if self.loss_type == "bce":
	loss = self.bce_loss(pred, target)
	elif self.loss_type == "multi_label_ce":
	input_tensor = torch.permute(pred, (1, 0, 2, 3))
	target_tensor = torch.permute(target, (1, 0, 2, 3))
	input_tensor = pred.reshape([relation_num, -1])
	target_tensor = target.reshape([relation_num, -1])
	loss = self.multilabel_categorical_crossentropy(target_tensor, input_tensor)
	weight = loss / loss.max()
	loss = loss * weight
	loss = loss.mean()
	loss_dict["loss"] = loss

	# running metric
	recall_20 = get_recall_N(pred, target, object_num=20)
	loss_dict["recall@20"] = recall_20
	return loss_dict

	def multilabel_categorical_crossentropy(self, y_true, y_pred):
	"""
	https://kexue.fm/archives/7359
	"""
	y_pred = (1 - 2 * y_true) * y_pred
	y_pred_neg = y_pred - y_true * 9999
	y_pred_pos = y_pred - (1 - y_true) * 9999
	zeros = torch.zeros_like(y_pred[..., :1])
	y_pred_neg = torch.cat([y_pred_neg, zeros], dim=-1)
	y_pred_pos = torch.cat([y_pred_pos, zeros], dim=-1)
	neg_loss = torch.logsumexp(y_pred_neg, dim=-1)
	pos_loss = torch.logsumexp(y_pred_pos, dim=-1)
	return neg_loss + pos_loss


	def get_recall_N(y_pred, y_true, object_num=20):
	"""
	y_pred: [batch_size, 56, object_num, object_num]
	y_true: [batch_size, 56, object_num, object_num]
	"""

	device = y_pred.device
	recall_list = []

	for idx in range(len(y_true)):
	sample_y_true = []
	sample_y_pred = []

	# find topk
	_, topk_indices = torch.topk(
	y_true[idx : idx + 1].reshape(
	[
	-1,
	]
	),
	k=object_num,
	)
	for index in topk_indices:
	pred_cls = index // (y_true.shape[2] ** 2)
	index_subject_object = index % (y_true.shape[2] ** 2)
	pred_subject = index_subject_object // y_true.shape[2]
	pred_object = index_subject_object % y_true.shape[2]
	if y_true[idx, pred_cls, pred_subject, pred_object] == 0:
	continue
	sample_y_true.append([pred_subject, pred_object, pred_cls])

	# find topk
	_, topk_indices = torch.topk(
	y_pred[idx : idx + 1].reshape(
	[
	-1,
	]
	),
	k=object_num,
	)
	for index in topk_indices:
	pred_cls = index // (y_pred.shape[2] ** 2)
	index_subject_object = index % (y_pred.shape[2] ** 2)
	pred_subject = index_subject_object // y_pred.shape[2]
	pred_object = index_subject_object % y_pred.shape[2]
	sample_y_pred.append([pred_subject, pred_object, pred_cls])

	recall = len([x for x in sample_y_pred if x in sample_y_true]) / (len(sample_y_true) + 1e-8)
	recall_list.append(recall)

	recall = torch.tensor(recall_list).to(device).mean() * 100
	return recall


	class RamTrainer(object):
	def __init__(self, config):
	self.config = config
	self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
	self._build_dataset()
	self._build_dataloader()
	self._build_model()
	self._build_optimizer()
	self._build_lr_scheduler()

	def _build_dataset(self):
	self.dataset = RamDataset(**self.config.dataset)

	def _build_dataloader(self):
	self.dataloader = torch.utils.data.DataLoader(
	self.dataset,
	batch_size=self.config.dataloader.batch_size,
	shuffle=True if self.config.dataset.is_train else False,
	)

	def _build_model(self):
	self.model = RamModel(**self.config.model).to(self.device)
	if self.config.load_from is not None:
	self.model.load_state_dict(torch.load(self.config.load_from))
	self.model.train()

	def _build_optimizer(self):
	self.optimizer = torch.optim.AdamW(self.model.parameters(), lr=self.config.optim.lr, weight_decay=self.config.optim.weight_decay, eps=self.config.optim.eps, betas=self.config.optim.betas)

	def _build_lr_scheduler(self):
	self.lr_scheduler = torch.optim.lr_scheduler.MultiStepLR(self.optimizer, milestones=self.config.optim.lr_scheduler.step, gamma=self.config.optim.lr_scheduler.gamma)

	def train(self):
	t_start = time.time()
	running_avg_loss = 0
	for epoch_idx in range(self.config.num_epoch):
	for batch_idx, batch_data in enumerate(self.dataloader):
	batch_embeds = batch_data[0].to(torch.float32).to(self.device)
	batch_target = batch_data[1].to(torch.float32).to(self.device)
	attention_mask = batch_embeds.new_ones((batch_embeds.shape[0], batch_embeds.shape[1]))
	batch_pred = self.model.forward(batch_embeds, attention_mask)
	loss_dict = self.model.loss(batch_pred, batch_target, attention_mask)
	loss = loss_dict["loss"]
	recall_20 = loss_dict["recall@20"]
	self.optimizer.zero_grad()
	loss.backward()
	torch.nn.utils.clip_grad_norm_(self.model.parameters(), self.config.optim.max_norm, self.config.optim.norm_type)
	self.optimizer.step()
	running_avg_loss += loss.item()

	if batch_idx % 100 == 0:
	t_current = time.time()
	num_finished_step = epoch_idx * self.config.num_epoch * len(self.dataloader) + batch_idx + 1
	num_to_do_step = (self.config.num_epoch - epoch_idx - 1) * len(self.dataloader) + (len(self.dataloader) - batch_idx - 1)
	avg_speed = num_finished_step / (t_current - t_start)
	eta = num_to_do_step / avg_speed
	print(
	"ETA={:0>8}, Epoch={}, Batch={}/{}, LR={}, Loss={:.4f}, RunningAvgLoss={:.4f}, Recall@20={:.2f}%".format(
	str(timedelta(seconds=int(eta))), epoch_idx + 1, batch_idx, len(self.dataloader), self.lr_scheduler.get_last_lr()[0], loss.item(), running_avg_loss / num_finished_step, recall_20.item()
	)
	)
	self.lr_scheduler.step()
	if not os.path.exists(self.config.output_dir):
	os.makedirs(self.config.output_dir)
	save_path = os.path.join(self.config.output_dir, "epoch_{}.pth".format(epoch_idx + 1))
	print("Save epoch={} checkpoint to {}".format(epoch_idx + 1, save_path))
	torch.save(self.model.state_dict(), save_path)
	return save_path


	class RamPredictor(object):
	def __init__(self, config):
	self.config = config
	self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
	self._build_dataset()
	self._build_dataloader()
	self._build_model()

	def _build_dataset(self):
	self.dataset = RamDataset(**self.config.dataset)

	def _build_dataloader(self):
	self.dataloader = torch.utils.data.DataLoader(self.dataset, batch_size=self.config.dataloader.batch_size, shuffle=False)

	def _build_model(self):
	self.model = RamModel(**self.config.model).to(self.device)
	if self.config.load_from is not None:
	self.model.load_state_dict(torch.load(self.config.load_from))
	self.model.eval()

	def predict(self, batch_embeds, pred_keep_num=100):
	"""
	Parameters
	----------
	batch_embeds: (batch_size=1, token_num, feature_size)
	pred_keep_num: int
	Returns
	-------
	batch_pred: (batch_size, relation_num, object_num, object_num)
	pred_rels: [[sub_id, obj_id, rel_id], ...]
	"""
	if not isinstance(batch_embeds, torch.Tensor):
	batch_embeds = torch.asarray(batch_embeds)
	batch_embeds = batch_embeds.to(torch.float32).to(self.device)
	attention_mask = batch_embeds.new_ones((batch_embeds.shape[0], batch_embeds.shape[1]))
	batch_pred = self.model.forward(batch_embeds, attention_mask)
	for idx_i in range(batch_pred.shape[2]):
	batch_pred[:, :, idx_i, idx_i] = -9999
	batch_pred = batch_pred.sigmoid()

	pred_rels = []
	_, topk_indices = torch.topk(
	batch_pred.reshape(
	[
	-1,
	]
	),
	k=pred_keep_num,
	)

	# subject, object, relation
	for index in topk_indices:
	pred_relation = index // (batch_pred.shape[2] ** 2)
	index_subject_object = index % (batch_pred.shape[2] ** 2)
	pred_subject = index_subject_object // batch_pred.shape[2]
	pred_object = index_subject_object % batch_pred.shape[2]
	pred = [pred_subject.item(), pred_object.item(), pred_relation.item()]
	pred_rels.append(pred)
	return batch_pred, pred_rels

	def eval(self):
	sum_recall_20 = 0.0
	sum_recall_50 = 0.0
	sum_recall_100 = 0.0
	prog_bar = ProgressBar(len(self.dataloader))
	for batch_idx, batch_data in enumerate(self.dataloader):
	batch_embeds = batch_data[0]
	batch_target = batch_data[1]
	gt_rels = batch_data[2]
	batch_pred, pred_rels = self.predict(batch_embeds)
	this_recall_20 = get_recall_N(batch_pred, batch_target, object_num=20)
	this_recall_50 = get_recall_N(batch_pred, batch_target, object_num=50)
	this_recall_100 = get_recall_N(batch_pred, batch_target, object_num=100)
	sum_recall_20 += this_recall_20.item()
	sum_recall_50 += this_recall_50.item()
	sum_recall_100 += this_recall_100.item()
	prog_bar.update()
	recall_20 = sum_recall_20 / len(self.dataloader)
	recall_50 = sum_recall_50 / len(self.dataloader)
	recall_100 = sum_recall_100 / len(self.dataloader)
	metric = {
	"recall_20": recall_20,
	"recall_50": recall_50,
	"recall_100": recall_100,
	}
	return metric


	if __name__ == "__main__":
	# Config
	config = dict(
	dataset=dict(
	data_path="./data/feat_0420.npz",
	is_train=True,
	num_relation_classes=56,
	),
	dataloader=dict(
	batch_size=4,
	),
	model=dict(
	pretrained_model_name_or_path="bert-base-uncased",
	load_pretrained_weights=True,
	num_transformer_layer=2,
	input_feature_size=256,
	output_feature_size=768,
	cls_feature_size=512,
	num_relation_classes=56,
	pred_type="attention",
	loss_type="multi_label_ce",
	),
	optim=dict(
	lr=1e-4,
	weight_decay=0.05,
	eps=1e-8,
	betas=(0.9, 0.999),
	max_norm=0.01,
	norm_type=2,
	lr_scheduler=dict(
	step=[6, 10],
	gamma=0.1,
	),
	),
	num_epoch=12,
	output_dir="./work_dirs",
	load_from=None,
	)

	# Train
	config = Config(config)
	trainer = RamTrainer(config)
	last_model_path = trainer.train()

	# Test/Eval
	config.dataset.is_train = False
	config.load_from = last_model_path
	predictor = RamPredictor(config)
	metric = predictor.eval()
	print(metric)