#!/usr/bin/env python # coding: utf-8 # In[1]: import torch import jovian import torchvision import matplotlib import torch.nn as nn import pandas as pd import matplotlib.pyplot as plt import seaborn as sns import torch.nn.functional as F from torchvision.datasets.utils import download_url from torch.utils.data import DataLoader, TensorDataset, random_split import random import os import sys # In[2]: # EPOCHS = int(sys.argv[1]) EPOCHS = 1000 #load data dataframe = pd.read_csv("understat.csv") #choose columns input_cols=list(dataframe.columns)[4:11] output_cols = ['position'] input_cols, output_cols # In[4]: def dataframe_to_arrays(dataframe): dataframe_loc = dataframe.copy(deep=True) inputs_array = dataframe_loc[input_cols].to_numpy() targets_array = dataframe_loc[output_cols].to_numpy() return inputs_array, targets_array inputs_array, targets_array = dataframe_to_arrays(dataframe) inputs = torch.from_numpy(inputs_array).type(torch.float) targets = torch.from_numpy(targets_array).type(torch.float) dataset = TensorDataset(inputs, targets) # In[7]: train_ds, val_ds = random_split(dataset, [548, 136]) batch_size=50 train_loader = DataLoader(train_ds, batch_size, shuffle=True) val_loader = DataLoader(val_ds, batch_size) # In[8]: class Model_xPosition(nn.Module): def __init__(self): super().__init__() self.linear = nn.Linear(input_size,output_size) def forward(self, xb): out = self.linear(xb) return out def training_step(self, batch): inputs, targets = batch # Generate predictions out = self(inputs) # Calcuate loss loss = F.l1_loss(out,targets) return loss def validation_step(self, batch): inputs, targets = batch out = self(inputs) loss = F.l1_loss(out,targets) return {'val_loss': loss.detach()} def validation_epoch_end(self, outputs): batch_losses = [x['val_loss'] for x in outputs] epoch_loss = torch.stack(batch_losses).mean() return {'val_loss': epoch_loss.item()} def epoch_end(self, epoch, result, num_epochs): if (epoch+1) % 100 == 0 or epoch == num_epochs-1: print("Epoch {} loss: {:.4f}".format(epoch+1, result['val_loss'])) def evaluate(model, val_loader): outputs = [model.validation_step(batch) for batch in val_loader] return model.validation_epoch_end(outputs) def fit(epochs, lr, model, train_loader, val_loader, opt_func=torch.optim.SGD): history = [] optimizer = opt_func(model.parameters(), lr) for epoch in range(epochs): for batch in train_loader: loss = model.training_step(batch) loss.backward() optimizer.step() optimizer.zero_grad() result = evaluate(model, val_loader) model.epoch_end(epoch, result, epochs) history.append(result) return history # In[9]: input_size = len(input_cols) output_size = len(output_cols) model=Model_xPosition() # In[11]: epochs = EPOCHS lr = 1e-5 learning_proccess = fit(epochs, lr, model, train_loader, val_loader) # In[13]: def predict_single(input, target, model): inputs = input.unsqueeze(0) predictions = model(inputs) prediction = predictions[0].detach() return "Target: "+str(target)+" Predicted: "+str(prediction)+"\n" # In[14]: for i in random.sample(range(0, len(val_ds)), 10): input_, target = val_ds[i] print(predict_single(input_, target, model),end="") # In[15]: with open("result.txt", "w+") as file: for i in range(0, len(val_ds), 1): input_, target = val_ds[i] file.write(str(predict_single(input_, target, model))) torch.save(model, "Model_xPosition.pkl")