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ETM.py
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ETM.py
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#!/usr/bin/env python
# -*- encoding: utf-8 -*-
'''
@File : ETM.py
@Time : 2020/09/30 15:26:45
@Author : Leilan Zhang
@Version : 1.0
@Contact : [email protected]
@Desc : None
'''
import os
import re
import time
import pickle
import torch
import torch.nn as nn
import torch.nn.functional as F
from torch.utils.data import Dataset,DataLoader
import numpy as np
from tqdm import tqdm
from .vae import VAE
import matplotlib.pyplot as plt
import sys
import codecs
sys.path.append('..')
from utils import evaluate_topic_quality, smooth_curve
class EVAE(VAE):
def __init__(self, encode_dims=[2000,1024,512,20],decode_dims=[20,1024,2000],dropout=0.0,emb_dim=300):
super(EVAE,self).__init__(encode_dims=encode_dims,decode_dims=decode_dims,dropout=dropout)
self.emb_dim = emb_dim
self.vocab_size = encode_dims[0]
self.n_topic = encode_dims[-1]
self.rho = nn.Linear(emb_dim,self.vocab_size)
self.alpha = nn.Linear(emb_dim,self.n_topic)
self.decoder = None
def decode(self,z):
wght_dec = self.alpha(self.rho.weight) #[K,V]
beta = F.softmax(wght_dec,dim=0).transpose(1,0)
res = torch.mm(z,beta)
logits = torch.log(res+1e-6)
return logits
class ETM:
def __init__(self,bow_dim=10000,n_topic=20,taskname=None,device=None,emb_dim=300):
self.bow_dim = bow_dim
self.n_topic = n_topic
self.emb_dim = emb_dim
#TBD_fc1
self.vae = EVAE(encode_dims=[bow_dim,1024,512,n_topic],decode_dims=[n_topic,512,bow_dim],dropout=0.0,emb_dim=emb_dim)
self.device = device
self.id2token = None
self.taskname = taskname
if device!=None:
self.vae = self.vae.to(device)
def train(self,train_data,batch_size=256,learning_rate=1e-3,test_data=None,num_epochs=100,is_evaluate=False,log_every=5,beta=1.0,criterion='cross_entropy',ckpt=None):
self.vae.train()
self.id2token = {v:k for k,v in train_data.dictionary.token2id.items()}
data_loader = DataLoader(train_data,batch_size=batch_size,shuffle=True,num_workers=4,collate_fn=train_data.collate_fn)
optimizer = torch.optim.Adam(self.vae.parameters(),lr=learning_rate)
#scheduler = torch.optim.lr_scheduler.StepLR(optimizer, step_size=10, gamma=0.5)
if ckpt:
self.load_model(ckpt["net"])
optimizer.load_state_dict(ckpt["optimizer"])
start_epoch = ckpt["epoch"] + 1
else:
start_epoch = 0
trainloss_lst, valloss_lst = [], []
recloss_lst, klloss_lst = [],[]
c_v_lst, c_w2v_lst, c_uci_lst, c_npmi_lst, mimno_tc_lst, td_lst = [], [], [], [], [], []
for epoch in range(start_epoch, num_epochs):
epochloss_lst = []
for iter,data in enumerate(data_loader):
optimizer.zero_grad()
txts,bows = data
bows = bows.to(self.device)
'''
n_samples = 20
rec_loss = torch.tensor(0.0).to(self.device)
for i in range(n_samples):
bows_recon,mus,log_vars = self.vae(bows,lambda x:torch.softmax(x,dim=1))
logsoftmax = torch.log_softmax(bows_recon,dim=1)
_rec_loss = -1.0 * torch.sum(bows*logsoftmax)
rec_loss += _rec_loss
rec_loss = rec_loss / n_samples
'''
bows_recon,mus,log_vars = self.vae(bows,lambda x:torch.softmax(x,dim=1))
if criterion=='cross_entropy':
logsoftmax = torch.log_softmax(bows_recon,dim=1)
rec_loss = -1.0 * torch.sum(bows*logsoftmax)
elif criterion=='bce_softmax':
rec_loss = F.binary_cross_entropy(torch.softmax(bows_recon,dim=1),bows,reduction='sum')
elif criterion=='bce_sigmoid':
rec_loss = F.binary_cross_entropy(torch.sigmoid(bows_recon),bows,reduction='sum')
kl_div = -0.5 * torch.sum(1+log_vars-mus.pow(2)-log_vars.exp())
loss = rec_loss + kl_div * beta
loss.backward()
optimizer.step()
trainloss_lst.append(loss.item()/len(bows))
epochloss_lst.append(loss.item()/len(bows))
if (iter+1) % 10==0:
print(f'Epoch {(epoch+1):>3d}\tIter {(iter+1):>4d}\tLoss:{loss.item()/len(bows):<.7f}\tRec Loss:{rec_loss.item()/len(bows):<.7f}\tKL Div:{kl_div.item()/len(bows):<.7f}')
#scheduler.step()
if (epoch+1) % log_every==0:
save_name = f'./ckpt/ETM_{self.taskname}_tp{self.n_topic}_{time.strftime("%Y-%m-%d-%H-%M", time.localtime())}_ep{epoch+1}.ckpt'
checkpoint = {
"net": self.vae.state_dict(),
"optimizer": optimizer.state_dict(),
"epoch": epoch,
"param": {
"bow_dim": self.bow_dim,
"n_topic": self.n_topic,
"taskname": self.taskname,
"emb_dim": self.emb_dim
}
}
torch.save(checkpoint,save_name)
# The code lines between this and the next comment lines are duplicated with WLDA.py, consider to simpify them.
print(f'Epoch {(epoch+1):>3d}\tLoss:{sum(epochloss_lst)/len(epochloss_lst):<.7f}')
print('\n'.join([str(lst) for lst in self.show_topic_words()]))
print('='*30)
smth_pts = smooth_curve(trainloss_lst)
plt.plot(np.array(range(len(smth_pts)))*log_every,smth_pts)
plt.xlabel('epochs')
plt.title('Train Loss')
plt.savefig('gsm_trainloss.png')
if test_data!=None:
c_v,c_w2v,c_uci,c_npmi,mimno_tc, td = self.evaluate(test_data,calc4each=False)
c_v_lst.append(c_v), c_w2v_lst.append(c_w2v), c_uci_lst.append(c_uci),c_npmi_lst.append(c_npmi), mimno_tc_lst.append(mimno_tc), td_lst.append(td)
save_name = f'./ckpt/ETM_{self.taskname}_tp{self.n_topic}_{time.strftime("%Y-%m-%d-%H-%M", time.localtime())}.ckpt'
torch.save(self.vae.state_dict(),save_name)
scrs = {'c_v':c_v_lst,'c_w2v':c_w2v_lst,'c_uci':c_uci_lst,'c_npmi':c_npmi_lst,'mimno_tc':mimno_tc_lst,'td':td_lst}
'''
for scr_name,scr_lst in scrs.items():
plt.cla()
plt.plot(np.array(range(len(scr_lst)))*log_every,scr_lst)
plt.savefig(f'wlda_{scr_name}.png')
'''
plt.cla()
for scr_name,scr_lst in scrs.items():
if scr_name in ['c_v','c_w2v','td']:
plt.plot(np.array(range(len(scr_lst)))*log_every,scr_lst,label=scr_name)
plt.title('Topic Coherence')
plt.xlabel('epochs')
plt.legend()
plt.savefig(f'gsm_tc_scores.png')
# The code lines between this and the last comment lines are duplicated with WLDA.py, consider to simpify them.
def evaluate(self,test_data,calc4each=False):
topic_words = self.show_topic_words()
return evaluate_topic_quality(topic_words, test_data, taskname=self.taskname, calc4each=calc4each)
def inference_by_bow(self,doc_bow):
# doc_bow: torch.tensor [vocab_size]; optional: np.array [vocab_size]
if isinstance(doc_bow,np.ndarray):
doc_bow = torch.from_numpy(doc_bow)
doc_bow = doc_bow.reshape(-1,self.bow_dim).to(self.device)
with torch.no_grad():
mu,log_var = self.vae.encode(doc_bow)
mu = self.vae.fc1(mu)
theta = F.softmax(mu,dim=1)
return theta.detach().cpu().squeeze(0).numpy()
def inference(self, doc_tokenized, dictionary,normalize=True):
doc_bow = torch.zeros(1,self.bow_dim)
for token in doc_tokenized:
try:
idx = dictionary.token2id[token]
doc_bow[0][idx] += 1.0
except:
print(f'{token} not in the vocabulary.')
doc_bow = doc_bow.to(self.device)
with torch.no_grad():
mu,log_var = self.vae.encode(doc_bow)
mu = self.vae.fc1(mu)
if normalize:
theta = F.softmax(mu,dim=1)
return theta.detach().cpu().squeeze(0).numpy()
def get_embed(self,train_data, num=1000):
self.vae.eval()
data_loader = DataLoader(train_data, batch_size=512,shuffle=False, num_workers=4, collate_fn=train_data.collate_fn)
embed_lst = []
txt_lst = []
cnt = 0
for data_batch in data_loader:
txts, bows = data_batch
embed = self.inference_by_bow(bows)
embed_lst.append(embed)
txt_lst.append(txts)
cnt += embed.shape[0]
if cnt>=num:
break
embed_lst = np.concatenate(embed_lst,axis=0)[:num]
txt_lst = np.concatenate(txt_lst,axis=0)[:num]
return txt_lst, embed_lst
def get_topic_word_dist(self,normalize=True):
self.vae.eval()
with torch.no_grad():
idxes = torch.eye(self.n_topic).to(self.device)
word_dist = self.vae.decode(idxes) # word_dist: [n_topic, vocab.size]
if normalize:
word_dist = F.softmax(word_dist,dim=1)
return word_dist.detach().cpu().numpy()
def show_topic_words(self,topic_id=None,topK=15, dictionary=None):
topic_words = []
idxes = torch.eye(self.n_topic).to(self.device)
word_dist = self.vae.decode(idxes)
word_dist = torch.softmax(word_dist,dim=1)
vals,indices = torch.topk(word_dist,topK,dim=1)
vals = vals.cpu().tolist()
indices = indices.cpu().tolist()
if self.id2token==None and dictionary!=None:
self.id2token = {v:k for k,v in dictionary.token2id.items()}
if topic_id==None:
for i in range(self.n_topic):
topic_words.append([self.id2token[idx] for idx in indices[i]])
else:
topic_words.append([self.id2token[idx] for idx in indices[topic_id]])
return topic_words
def load_model(self, model):
self.vae.load_state_dict(model)
if __name__ == '__main__':
model = EVAE(encode_dims=[1024,512,256,20],decode_dims=[20,128,768,1024],emb_dim=300)
model = model.cuda()
inpt = torch.randn(234,1024).cuda()
out,mu,log_var = model(inpt)
print(out.shape)
print(mu.shape)