aptlm / api_prediction.py
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import torch
from torch.utils.tensorboard import SummaryWriter
from torch.utils.data import DataLoader
import numpy as np
from sklearn.metrics import *
from omegaconf import OmegaConf
import os
import random
from aptatrans_pipeline import AptaTransPipeline
from mcts import MCTS
import esm
from encoders import AptaTrans
from utils import get_scores, API_Dataset, get_esm_dataset, rna2vec
from accelerate import Accelerator
# accelerator = Accelerator(kwargs_handlers=[DistributedDataParallelKwargs(find_unused_parameters=True)]) # NOTE: Buggy | Disables unused parameter issue
accelerator = Accelerator()
class AptaTransPipeline_Dist(AptaTransPipeline):
"""In-house API prediction score pipeline, inheriting from AptaTrans (Shin et al., 2023)."""
def __init__(self, lr, weight_decay, epochs, model_type, model_version, model_save_path, accelerate_save_path, tensorboard_logdir, *args, **kwargs):
super().__init__(*args, **kwargs)
self.device = accelerator.device
self.lr = lr
self.weight_decay = weight_decay
self.epochs = epochs
self.model_type = model_type
self.model_version = model_version
self.model_save_path = model_save_path
self.accelerate_save_path = accelerate_save_path
self.tensorboard_logdir = tensorboard_logdir
esm_prot_encoder, self.esm_alphabet = esm.pretrained.esm.pretrained.esm2_t33_650M_UR50D() # ESM-2 Encoder
# Freeze ESM-2
for name, param in esm_prot_encoder.named_parameters():
param.requires_grad = False
for name, param in esm_prot_encoder.named_parameters():
# if "layers.28" in name or "layers.29" in name or "layers.30" in name or "layers.31" in name or "layers.32" in name:
if "layers.30" in name or "layers.31" in name or "layers.32" in name:
param.requires_grad = True
self.batch_converter = self.esm_alphabet.get_batch_converter()
self.model = AptaTrans(
apta_encoder=self.encoder_aptamer.encoder,
prot_encoder=esm_prot_encoder,
n_apta_vocabs=self.n_apta_vocabs,
n_prot_vocabs=self.n_prot_vocabs,
dropout=0.1,
apta_max_len=self.apta_max_len,
prot_max_len=self.prot_max_len
).to(self.device)
self.criterion = torch.nn.BCELoss().to(self.device)
def train(self):
print('Training the model!')
# Initialize writer instance
writer = SummaryWriter(log_dir=f"log/{self.model_type}/{self.model_version}")
# Initialize early stopping
self.early_stopper = EarlyStopper(3, 3)
self.optimizer = torch.optim.AdamW(self.model.parameters(), lr=self.lr, weight_decay=self.weight_decay)
# Configure pytorch objects for distributed environment (i.e. sharded dataloader, multiple copies of model, etc.)
self.model, self.optimizer, self.train_loader, self.test_loader, self.bench_loader = accelerator.prepare(self.model, self.optimizer, self.train_loader, self.test_loader, self.bench_loader)
best_auc = 0
for epoch in range(1, self.epochs+1):
self.model.train()
loss_train, _, _ = self.batch_step(self.train_loader, train_mode=True)
self.model.eval()
with torch.no_grad():
loss_test, pred_test, target_test = self.batch_step(self.test_loader, train_mode=False)
scores = get_scores(target_test, pred_test)
print("\tTrain Loss: {: .6f}\tTest Loss: {: .6f}\tTest ACC: {:.6f}\tTest AUC: {:.6f}\tTest MCC: {:.6f}\tTest PR_AUC: {:.6f}\tF1: {:.6f}\n".format(loss_train ,loss_test, scores['acc'], scores['roc_auc'], scores['mcc'], scores['pr_auc'], scores['f1']))
stop_early = self.early_stopper.early_stop(loss_test)
# Early stop - model has not improved on eval set.
if stop_early:
break
if epoch > 15:
with torch.no_grad():
loss_bench, pred_bench, target_bench = self.batch_step(self.bench_loader, train_mode=False)
scores = get_scores(target_bench, pred_bench)
print("\Bench Loss: {: .6f}\Bench ACC: {:.6f}\Bench AUC: {:.6f}\tBench MCC: {:.6f}\tBench PR_AUC: {:.6f}\tBench F1: {:.6f}\n".format(loss_bench, scores['acc'], scores['roc_auc'], scores['mcc'], scores['pr_auc'], scores['f1']))
# Checkpoint based off of benchmark criteria
# If model has improved and early stopping patience counter was just reset:
if scores['roc_auc'] > best_auc and self.early_stopper.counter == 0 and accelerator.is_main_process:
best_auc = scores['roc_auc']
accelerator.save_state(self.accelerate_save_path)
model = accelerator.unwrap_model(self.model)
torch.save(model.state_dict(), f'{self.model_save_path}/model_epoch={epoch}.pt')
print(f'Model saved at {self.model_save_path}')
print(f'Accelerate statistics saved at {self.accelerate_save_path}!') # Access via accelerator.load_state("./output")
# logging
writer.add_scalar("Loss/train", loss_train, epoch)
writer.add_scalar("Loss/test", loss_test, epoch)
for k, v in scores.items():
if isinstance(v, float):
writer.add_scalar(f'{k}/test', scores[k], epoch)
print("Training finished | access tensorboard via 'tensorboard --logdir=runs'.")
writer.flush()
writer.close()
def batch_step(self, loader, train_mode = True):
loss_total = 0
pred = np.array([])
target = np.array([])
for batch_idx, (apta, esm_prot, y) in enumerate(loader):
if train_mode:
self.optimizer.zero_grad()
y_pred = self.predict(apta, esm_prot)
y_true = torch.tensor(y, dtype=torch.float32).to(self.device) # not needed since accelerator modifies dataloader to automatically map input objects to correct dev
loss = self.criterion(torch.flatten(y_pred), y_true)
if train_mode:
accelerator.backward(loss) # Accelerate backward() method scales gradients and uses appropriate backward method as configured across devices
self.optimizer.step()
loss_total += loss.item()
pred = np.append(pred, torch.flatten(y_pred).clone().detach().cpu().numpy())
target = np.append(target, torch.flatten(y_true).clone().detach().cpu().numpy())
mode = 'train' if train_mode else 'eval'
print(mode + "[{}/{}({:.0f}%)]".format(batch_idx, len(loader), 100. * batch_idx / len(loader)), end = "\r", flush=True)
loss_total /= len(loader)
return loss_total, pred, target
def predict(self, apta, esm_prot):
y_pred = self.model(apta, esm_prot)
return y_pred
def inference(self, apta, prot, labels):
"""Perform inference on a batch of aptamer/protein pairs."""
print('Predicting the Aptamer-Protein Interaction')
try:
print("loading the best model for api!")
self.model.load_state_dict(torch.load('./models/model.pt', map_location=self.device))
except:
print('there is no best model file.')
print('You need to train the model for predicting API!')
y_place = np.zeros((len(prot), 1))
inputs = [(i, j) for i, j in zip(y_place, prot)]
_, _, prot_tokens = self.batch_converter(inputs)
apta_tokenized = rna2vec(np.array(apta))
# truncating
prot_tokenized = prot_tokens[:, :1678]
# padding
prot_ex = torch.ones((prot_tokenized.shape[0], 1678), dtype=torch.int64)*self.esm_alphabet.padding_idx
prot_ex[:, :prot_tokenized.shape[1]] = prot_tokenized
loader = DataLoader(API_Dataset(apta_tokenized, prot_ex, labels), batch_size=4, shuffle=False)
self.model, loader = accelerator.prepare(self.model, loader)
_, pred, _ = self.batch_step(loader, train_mode=False)
# self.model.eval()
# with torch.no_grad():
# y_pred = self.model(apta_tokenized.to('cuda'), prot_ex.to('cuda'))
# score = y_pred.detach().cpu().numpy()
# print('Score : ', score)
return pred
def recommend(self, target, n_aptamers, depth, iteration, verbose=True):
try:
print("load the best model for api!")
self.model.load_state_dict(torch.load('models/aptaESM2_trainable_l5/test_lr=1e-06_batch_size=16_dropout=0.05_wd=1e-06/model.pt', map_location=self.device))
except:
print('there is no best model file.')
print('You need to train the model for predicting API!')
candidates = []
_, _, prot_tokens = self.batch_converter([(1, target)])
prot_tokenized = torch.tensor(prot_tokens, dtype=torch.int64)
# adjusting for max protein sequence length during model training
encoded_targetprotein = torch.ones((prot_tokenized.shape[0], 1678), dtype=torch.int64)*self.esm_alphabet.padding_idx
encoded_targetprotein[:, :prot_tokenized.shape[1]] = prot_tokenized
encoded_targetprotein = encoded_targetprotein.to(self.device)
mcts = MCTS(encoded_targetprotein, depth=depth, iteration=iteration, states=8, target_protein=target, device=self.device)
for _ in range(n_aptamers):
mcts.make_candidate(self.model)
candidates.append(mcts.get_candidate())
self.model.eval()
with torch.no_grad():
sim_seq = np.array([mcts.get_candidate()])
apta = torch.tensor(rna2vec(sim_seq), dtype=torch.int64).to(self.device)
score = self.model(apta.to(self.device), encoded_targetprotein)
if verbose:
print("candidate:\t", mcts.get_candidate(), "\tscore:\t", score)
print("*"*80)
mcts.reset()
def set_data_for_training(self, filepath, batch_size):
ds_train, ds_test = get_esm_dataset(filepath, self.batch_converter)
self.train_loader = DataLoader(API_Dataset(ds_train[0], ds_train[1], ds_train[2]), batch_size=batch_size, shuffle=True)
self.test_loader = DataLoader(API_Dataset(ds_test[0], ds_test[1], ds_test[2]), batch_size=batch_size, shuffle=False)
class EarlyStopper:
def __init__(self, patience=1, min_delta=0):
self.patience = patience
self.min_delta = min_delta
self.counter = 0
self.min_validation_loss = float('inf')
def early_stop(self, validation_loss):
if validation_loss < self.min_validation_loss:
self.min_validation_loss = validation_loss
self.counter = 0
elif validation_loss > (self.min_validation_loss + self.min_delta):
self.counter += 1
if self.counter >= self.patience:
return True
return False
def seed_torch(seed=1029):
random.seed(seed)
os.environ['PYTHONHASHSEED'] = str(seed)
np.random.seed(seed)
torch.manual_seed(seed)
torch.cuda.manual_seed(seed)
torch.cuda.manual_seed_all(seed) # if you are using multi-GPU.
torch.backends.cudnn.benchmark = False
torch.backends.cudnn.deterministic = True
def main():
conf = OmegaConf.load('config.yaml')
hyperparameters = conf.hyperparameters
logging = conf.logging
lr = hyperparameters['lr']
wd = hyperparameters['weight_decay']
dropout = hyperparameters['dropout']
batch_size = hyperparameters['batch_size']
epochs = hyperparameters['epochs']
model_type = logging['model_type']
model_version = logging['model_version']
model_save_path = logging['model_save_path']
accelerate_save_path = logging['accelerate_save_path']
tensorboard_logdir = logging['tensorboard_logdir']
seed = hyperparameters['seed']
if not os.path.exists(model_save_path):
os.makedirs(model_save_path)
seed_torch(seed=seed)
pipeline = AptaTransPipeline_Dist(
lr=lr,
weight_decay=wd,
epochs=epochs,
model_type=model_type,
model_version=model_version,
model_save_path=model_save_path,
accelerate_save_path=accelerate_save_path,
tensorboard_logdir=tensorboard_logdir,
d_model=128,
d_ff=512,
n_layers=6,
n_heads=8,
dropout=dropout,
load_best_pt=True, # already loads the pretrained model using the datasets included in repo -- no need to run the bottom two cells
device='cuda',
seed=seed)
datapath = "./data/dataset_li.pickle"
pipeline.set_data_for_training(datapath, batch_size=batch_size)
pipeline.train()
return
if __name__ == "__main__":
# launch training w/ the following: "accelerate launch api_prediction.py [args]"
main()