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| import torch | |
| from torch import nn | |
| import pandas as pd | |
| from pathlib import Path | |
| import matplotlib.pyplot as plt | |
| from torch.nn.modules.loss import CrossEntropyLoss | |
| from torch.utils.data import DataLoader, TensorDataset | |
| from sklearn.metrics import accuracy_score, f1_score | |
| from sklearn.model_selection import train_test_split | |
| ##################################################################################################################### | |
| def preprocess_data(label_X, target_y): | |
| preprocessed= TensorDataset(label_X, target_y) | |
| return preprocessed | |
| def dataloader(dataset, batch_size, shuffle, num_workers): | |
| dataloader= DataLoader(dataset=dataset, | |
| batch_size=batch_size, | |
| shuffle= shuffle, | |
| num_workers=num_workers) | |
| return (dataloader) | |
| class RNN_model(nn.Module): | |
| def __init__(self): | |
| super().__init__() | |
| self.rnn= nn.RNN(input_size=1477, hidden_size=240,num_layers=1, nonlinearity= 'relu', bias= True).to('cuda') | |
| self.output= nn.Linear(in_features=240, out_features=24).to('cuda') | |
| def forward(self, x): | |
| y, hidden= self.rnn(x) | |
| y = y.to('cuda') | |
| x= self.output(y).to('cuda') | |
| return(x) | |
| ##################################################################################################################### | |
| # import data | |
| df= pd.read_csv('Symptom2Disease_1.csv') | |
| target=['Psoriasis', 'Varicose Veins', 'Typhoid', 'Chicken pox', | |
| 'Impetigo', 'Dengue', 'Fungal infection', 'Common Cold', | |
| 'Pneumonia', 'Dimorphic Hemorrhoids', 'Arthritis', 'Acne', | |
| 'Bronchial Asthma', 'Hypertension', 'Migraine', | |
| 'Cervical spondylosis', 'Jaundice', 'Malaria', | |
| 'urinary tract infection', 'allergy', | |
| 'gastroesophageal reflux disease', 'drug reaction', | |
| 'peptic ulcer disease', 'diabetes'] | |
| target_dict= {i:j for i,j in enumerate(sorted(target))} | |
| df['label']= df['label'].replace({j:i for i,j in enumerate(sorted(target))}) | |
| df.drop('Unnamed: 0', axis= 1, inplace= True) | |
| df.duplicated().sum() | |
| df[df.duplicated] | |
| df.drop_duplicates(inplace= True) | |
| df['label'].value_counts() | |
| ##################################################################################################################### | |
| train_data, test_data= train_test_split(df, test_size=0.15, random_state=42 ) | |
| train_data['label'].value_counts().sort_index() | |
| test_data['label'].value_counts().sort_index() | |
| #vectorizer= nltk_u.vectorizer() | |
| from sklearn.feature_extraction.text import TfidfVectorizer | |
| from spacy.lang.de.stop_words import STOP_WORDS | |
| vectorizer = TfidfVectorizer(stop_words=list(STOP_WORDS)) | |
| vectorizer.fit(train_data.text) | |
| vectorizer.get_feature_names_out()[: 100] | |
| vectorizer= vectorizer | |
| data_input= vectorizer.transform(train_data.text) | |
| test_data_input= vectorizer.transform(test_data.text) | |
| ##################################################################################################################### | |
| # Convert vectors to tensors | |
| input_data_tensors= torch.tensor(data_input.toarray()).to(torch.float32) | |
| test_data_tensors= torch.tensor(test_data_input.toarray()).to(torch.float32) | |
| train_data_output= torch.tensor(train_data['label'].values) | |
| test_data_output= torch.tensor(test_data['label'].values) | |
| train_dataset= preprocess_data(input_data_tensors, train_data_output) | |
| test_dataset= preprocess_data(test_data_tensors, test_data_output) | |
| train_dataloader= dataloader(dataset=train_dataset, | |
| batch_size=32, shuffle= True, num_workers=2) | |
| test_dataloader= dataloader(dataset=test_dataset, | |
| batch_size=32, shuffle= False, num_workers=2) | |
| text, target= next(iter(train_dataloader)) | |
| ##################################################################################################################### | |
| if torch.cuda.is_available(): | |
| device = "cuda" | |
| print(f'################################################################# device: {device}#################################################################') | |
| else: | |
| device = "cpu" | |
| ##################################################################################################################### | |
| model= RNN_model().to(device) | |
| loss_fn= CrossEntropyLoss() | |
| optimizer= torch.optim.SGD(model.parameters(), lr= 0.1, weight_decay=0) | |
| ##################################################################################################################### | |
| ## train model | |
| epoch= 300 | |
| results= { | |
| "train_loss": [], | |
| "train_accuracy": [], | |
| "test_loss": [], | |
| "test_accuracy": [] | |
| } | |
| for i in range(epoch): | |
| train_loss=0 | |
| train_acc=0 | |
| for batch, (X, y) in enumerate(train_dataloader): | |
| X, y= X.to('cuda'), y.to('cuda') | |
| # Train the model | |
| model.train() | |
| optimizer.zero_grad() | |
| y_logits= model(X).to('cuda') | |
| # Calculate the loss | |
| loss= loss_fn(y_logits, y).to('cuda') | |
| train_loss += loss | |
| # ypreds | |
| y_preds= torch.argmax(torch.softmax(y_logits, dim=1), dim=1) | |
| accuracy = accuracy_score(y.cpu(), y_preds.cpu()) | |
| train_acc += accuracy | |
| # zero grad | |
| optimizer.zero_grad() | |
| # Loss backward | |
| loss.backward() | |
| # Optimizer step | |
| optimizer.step() | |
| train_loss /= len(train_dataloader) | |
| train_acc /=len(train_dataloader) | |
| test_loss = 0 | |
| test_acc=0 | |
| model.eval() | |
| with torch.inference_mode(): | |
| for X, y in test_dataloader: | |
| X, y= X.to('cuda'), y.to('cuda') | |
| y_logits= model(X).to('cuda') | |
| loss= loss_fn(y_logits, y).to('cuda') | |
| test_loss += loss | |
| test_preds= torch.argmax(torch.softmax(y_logits, dim=1), dim=1).to('cuda') | |
| accuracy = accuracy_score(y.cpu(), test_preds.cpu()) | |
| test_acc += accuracy | |
| test_loss /= len(test_dataloader) | |
| test_acc /= len(test_dataloader) | |
| results['train_loss'].append(train_loss) | |
| results['train_accuracy'].append(train_acc) | |
| results['test_loss'].append(test_loss) | |
| results['test_accuracy'].append(test_acc) | |
| if i % 50 == 0: | |
| print(f"\nTrain loss: {train_loss:.5f} | Train Acc: {train_acc:.5f} | Test loss: {test_loss:.5f} | Test Acc: {test_acc:.5f} |") | |
| ##################################################################################################################### | |
| ''' | |
| plt.figure(figsize=(10,5)) | |
| plt.subplot(1,2,1) | |
| plt.plot(results['train_loss'], label= 'train') | |
| plt.plot(results['test_loss'], label= 'test') | |
| plt.title('loss curve for train and test') | |
| plt.legend() | |
| plt.subplot(1,2,2) | |
| plt.plot(results['train_accuracy'], label= 'train') | |
| plt.plot(results['test_accuracy'], label= 'test') | |
| plt.title('accuracy score for train and test') | |
| plt.legend() | |
| ''' | |
| ##################################################################################################################### | |
| new_data= 'I have been having burning pain anytime i am peeing, what could be the issue?' | |
| transformed_new= vectorizer.transform([new_data]) | |
| transformed_new= torch.tensor(transformed_new.toarray()).to(torch.float32).to('cuda') | |
| model.eval() | |
| with torch.inference_mode(): | |
| y_logits=model(transformed_new).to('cuda') | |
| test_preds= torch.argmax(torch.softmax(y_logits, dim=1), dim=1).to('cuda') | |
| test_pred= target_dict[test_preds.item()] | |
| print(f'based on your symptoms, I believe you are having {test_pred}') | |
| target_dir_path = Path('') | |
| target_dir_path.mkdir(parents=True, | |
| exist_ok=True) | |
| model_path= target_dir_path / 'pretrained_gru_model.pth' | |
| torch.save(obj=model.state_dict(),f= model_path) | |
| print('########### model saved ###########') | |
| ##################################################################################################################### |