2022-05-09 01:15:29 +02:00
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import sys
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import torch
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import torch.nn as nn
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import pandas as pd
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import numpy as np
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import matplotlib.pyplot as plt
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from sklearn.model_selection import train_test_split
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from sklearn.metrics import accuracy_score, precision_recall_fscore_support, explained_variance_score, \
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mean_squared_error, mean_absolute_error
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def drop_relevant_columns(imbd_data):
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imbd_data.drop(columns=["Poster_Link"], inplace=True)
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imbd_data.drop(columns=["Overview"], inplace=True)
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imbd_data.drop(columns=["Certificate"], inplace=True)
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return imbd_data
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def lowercase_columns_names(imbd_data):
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imbd_data["Series_Title"] = imbd_data["Series_Title"].str.lower()
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imbd_data["Genre"] = imbd_data["Genre"].str.lower()
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imbd_data["Director"] = imbd_data["Director"].str.lower()
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imbd_data["Star1"] = imbd_data["Star1"].str.lower()
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imbd_data["Star2"] = imbd_data["Star2"].str.lower()
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imbd_data["Star3"] = imbd_data["Star3"].str.lower()
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imbd_data["Star4"] = imbd_data["Star4"].str.lower()
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return imbd_data
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def data_to_numeric(imbd_data):
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imbd_data = imbd_data.replace(np.nan, '', regex=True)
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imbd_data["Gross"] = imbd_data["Gross"].str.replace(',', '')
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imbd_data["Gross"] = pd.to_numeric(imbd_data["Gross"], errors='coerce')
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imbd_data["Runtime"] = imbd_data["Runtime"].str.replace(' min', '')
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imbd_data["Runtime"] = pd.to_numeric(imbd_data["Runtime"], errors='coerce')
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imbd_data["IMDB_Rating"] = pd.to_numeric(imbd_data["IMDB_Rating"], errors='coerce')
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imbd_data["Meta_score"] = pd.to_numeric(imbd_data["Meta_score"], errors='coerce')
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imbd_data["Released_Year"] = pd.to_numeric(imbd_data["Released_Year"], errors='coerce')
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imbd_data = imbd_data.dropna()
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imbd_data = imbd_data.reset_index()
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imbd_data.drop(columns=["index"], inplace=True)
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return imbd_data
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def create_train_dev_test(imbd_data):
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data_train, data_test = train_test_split(imbd_data, test_size=230, random_state=1, shuffle=True)
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data_test, data_dev = train_test_split(data_test, test_size=115, random_state=1, shuffle=True)
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data_test.to_csv("data_test.csv", encoding="utf-8", index=False)
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data_dev.to_csv("data_dev.csv", encoding="utf-8", index=False)
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data_train.to_csv("data_train.csv", encoding="utf-8", index=False)
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def normalize_gross(imbd_data):
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imbd_data[["Gross"]] = imbd_data[["Gross"]] / 10000000
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return imbd_data
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def prepare_dataset():
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2022-06-06 00:42:12 +02:00
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df = pd.read_csv('biblioteka_DL/imdb_top_1000.csv')
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2022-05-09 01:15:29 +02:00
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df = drop_relevant_columns(df)
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df_lowercase = lowercase_columns_names(df)
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df = data_to_numeric(df_lowercase)
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df = normalize_gross(df)
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return df
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class LinearRegressionModel(torch.nn.Module):
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def __init__(self):
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super(LinearRegressionModel, self).__init__()
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self.linear = torch.nn.Linear(1, 1) # One in and one out
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def forward(self, x):
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y_pred = self.linear(x)
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return y_pred
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df = prepare_dataset()
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data_train, data_test = train_test_split(df, random_state=1, shuffle=True)
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X_train = pd.DataFrame(data_train["Meta_score"], dtype=np.float64)
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X_train = X_train.to_numpy()
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y_train = pd.DataFrame(data_train["Gross"], dtype=np.float64)
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y_train = y_train.to_numpy()
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X_train = X_train.reshape(-1, 1)
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y_train = y_train.reshape(-1, 1)
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X_train = torch.from_numpy(X_train.astype(np.float32)).view(-1, 1)
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y_train = torch.from_numpy(y_train.astype(np.float32)).view(-1, 1)
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input_size = 1
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output_size = 1
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model = torch.load("model.pkl")
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X_test = pd.DataFrame(data_test["Meta_score"], dtype=np.float64)
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X_test = X_test.to_numpy()
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X_test = X_test.reshape(-1, 1)
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X_test = torch.from_numpy(X_test.astype(np.float32)).view(-1, 1)
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predicted = model(X_test).detach().numpy()
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gross_test_g = pd.DataFrame(data_test["Gross"], dtype=np.float64)
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gross_test_g = gross_test_g.to_numpy()
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gross_test_g = gross_test_g.reshape(-1, 1)
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pred = pd.DataFrame(predicted)
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predicted = []
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expected = []
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for i in range(0, len(X_test)):
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predicted.append(np.argmax(model(X_test[i]).detach().numpy(), axis=0))
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expected.append(gross_test_g[i])
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for i in range(0, len(expected)):
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expected[i] = expected[i][0]
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rmse = mean_squared_error(gross_test_g, pred, squared=False)
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mse = mean_squared_error(gross_test_g, pred)
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evr = explained_variance_score(gross_test_g, pred)
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mae = mean_absolute_error(gross_test_g, pred)
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res = f"Explained variance regression score: {evr}, RMSE: {rmse}, MSE: {mse}, MAE: {mae}"
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with open('mae.txt', 'a+') as f:
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f.write(str(mae) + '\n')
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with open('rmse.txt', 'a+') as f:
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f.write(str(rmse) + '\n')
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with open('mse.txt', 'a+') as f:
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f.write(str(mse) + '\n')
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with open('evr.txt', 'a+') as f:
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f.write(str(evr) + '\n')
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with open('mae.txt') as f:
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mae_val = [float(line) for line in f if line]
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builds = list(range(1, len(mae_val) + 1))
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with open('rmse.txt') as f:
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rmse_val = [float(line) for line in f if line]
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with open('mse.txt') as f:
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mse_val = [float(line) for line in f if line]
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with open('evr.txt') as f:
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evr_val = [float(line) for line in f if line]
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ax = plt.gca()
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ax.set_title('Build')
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mae_line = ax.plot(mae_val, color='blue', label="MAE")
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rmse_line = ax.plot(rmse_val, color='green', label="RMSE")
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mse_line = ax.plot(mse_val, color='red', label="MSE")
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evr_line = ax.plot(evr_val, color='orange', label="EVR")
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ax.legend(bbox_to_anchor=(0., 1.01, 1.0, .1), loc=3,
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ncol=2, mode="expand", borderaxespad=0.)
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plt.show()
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plt.savefig('metrics.png')
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