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| | import pandas as pd |
| | import numpy as np |
| | import torch |
| | from transformers import RobertaTokenizer, RobertaForSequenceClassification |
| | from torch import nn |
| | from torch.nn import init, MarginRankingLoss |
| | from transformers import BertModel, RobertaModel |
| | from transformers import BertTokenizer, RobertaTokenizer |
| | from torch.optim import Adam |
| | from distutils.version import LooseVersion |
| | from torch.utils.data import Dataset, DataLoader |
| | from torch.utils.tensorboard import SummaryWriter |
| | from datetime import datetime |
| | from torch.autograd import Variable |
| | from transformers import AutoConfig, AutoModel, AutoTokenizer |
| | import nltk |
| | import re |
| | import Levenshtein |
| | import spacy |
| | import en_core_web_sm |
| | import torch.optim as optim |
| | from torch.distributions import Categorical |
| | from numpy import linalg as LA |
| | from transformers import AutoModelForMaskedLM |
| | from nltk.corpus import wordnet |
| | import torch.nn.functional as F |
| | import random |
| | from transformers import get_linear_schedule_with_warmup |
| | from sklearn.metrics import precision_recall_fscore_support |
| | from nltk.corpus import words as wal |
| | from sklearn.utils import resample |
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| | class MyDataset(Dataset): |
| | def __init__(self,file_name): |
| | df1 = pd.read_csv(file_name) |
| | df1 = df1[230000:] |
| | df1 = df1.fillna("") |
| | res = df1['X'] |
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| | self.X_list = res.to_numpy() |
| | self.y_list = df1['y'].to_numpy() |
| | def __len__(self): |
| | return len(self.X_list) |
| | def __getitem__(self,idx): |
| | mapi = [] |
| | mapi.append(self.X_list[idx]) |
| | mapi.append(self.y_list[idx]) |
| | return mapi |
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| | class Step1_model(nn.Module): |
| | def __init__(self, hidden_size=512): |
| | super(Step1_model, self).__init__() |
| | self.hidden_size = hidden_size |
| | self.tokenizer = AutoTokenizer.from_pretrained("microsoft/graphcodebert-base") |
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| | def forward(self, mapi): |
| | y = mapi[1] |
| | print(y) |
| | nl = re.findall(r'[A-Z](?:[a-z]+|[A-Z]*(?=[A-Z]|$))|[a-z]+|\d+', y) |
| | lb = ' '.join(nl).lower() |
| | x = tokenizer.tokenize(lb) |
| | nlab = len(x) |
| | print(nlab) |
| | rand_no = random.random() |
| | tok_map = {2: 0.4363429005892416, |
| | 1: 0.6672580202327398, |
| | 4: 0.7476060740459144, |
| | 3: 0.9618703668504087, |
| | 6: 0.9701028532809564, |
| | 7: 0.9729244545819342, |
| | 8: 0.9739508754144756, |
| | 5: 0.9994508859743607, |
| | 9: 0.9997507867114407, |
| | 10: 0.9999112969650892, |
| | 11: 0.9999788802297832, |
| | 0: 0.9999831041838266, |
| | 12: 0.9999873281378701, |
| | 22: 0.9999957760459568, |
| | 14: 1.0000000000000002} |
| | for key in tok_map.keys(): |
| | if rand_no < tok_map[key]: |
| | pred = key |
| | break |
| | predicted = torch.tensor([pred], dtype = float) |
| | if pred == nlab: |
| | l2 = 0 |
| | else: |
| | l2 = 1 |
| | actual = torch.tensor([nlab], dtype = float) |
| | l1 = Variable(torch.tensor([(actual-predicted)**2],dtype=float),requires_grad = True) |
| | return {'loss':l1, 'actual_pred':pred, 'acc': l2} |
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| | epoch_number = 0 |
| | EPOCHS = 5 |
| | run_int = 0 |
| | tokenizer = AutoTokenizer.from_pretrained("microsoft/graphcodebert-base") |
| | model = Step1_model() |
| | myDs=MyDataset('dat_test.csv') |
| | train_loader=DataLoader(myDs,batch_size=2,shuffle=True) |
| | best_loss = torch.full((1,), fill_value=100000) |
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| | flag = 0 |
| | def train_one_epoch(transformer_model, dataset): |
| | global flag |
| | tot_loss1 = 0.0 |
| | tot_loss2 = 0.0 |
| | cnt = 0 |
| | for batch in dataset: |
| | p = 0 |
| | inputs = batch |
| | for i in range(len(inputs[0])): |
| | cnt += 1 |
| | l = [] |
| | l.append(inputs[0][i]) |
| | l.append(inputs[1][i]) |
| | opi = transformer_model(l) |
| | loss1 = opi['loss'] |
| | loss2 = opi['acc'] |
| | tot_loss1 += loss1 |
| | tot_loss2 += loss2 |
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| | tot_loss1/=cnt |
| | tot_loss2/=cnt |
| | print('MSE loss: ') |
| | print(tot_loss1) |
| | print('accuracy: ') |
| | print(tot_loss2) |
| | return {'MSE loss': tot_loss1, 'accuracy': tot_loss2} |
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| | model.eval() |
| | avg_loss = train_one_epoch(model,train_loader) |
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