algorithm
/
rov-offline


			
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							import os
import lightgbm as lgb
import pandas as pd

from sklearn.model_selection import train_test_split
from sklearn.metrics import mean_absolute_error, r2_score, mean_absolute_percentage_error
from config import set_config
from utils import read_from_pickle, write_to_pickle
from log import Log

config_ = set_config()
log_ = Log()


def process_data(filename):
    """
    数据清洗、预处理
    :param filename: type-DataFrame
    :return: x, y, video_ids, features
    """
    # 获取数据
    data = read_from_pickle(filename)
    # 获取y,并将 y <= 0 的值更新为1
    data['futre7dayreturn'].loc[data['futre7dayreturn'] <= 0] = 1
    y = data['futre7dayreturn']

    # 获取视频id列
    video_ids = data['videoid']

    # 获取x
    drop_columns = ['videoid', 'dt', 'futre7dayreturn', 'videotags', 'words_without_tags']
    x = data.drop(columns=drop_columns)
    # 计算后一天的回流比前一天的回流差值
    x['stage_four_return_added'] = x['stage_four_retrn'] - x['stage_three_retrn']
    x['stage_three_return_added'] = x['stage_three_retrn'] - x['stage_two_retrn']
    x['stage_two_return_added'] = x['stage_two_retrn'] - x['stage_one_retrn']
    # 计算后一天回流比前一天回流的增长率
    x['stage_four_return_ratio'] = x['stage_four_return_added'] / x['stage_four_retrn']
    x['stage_three_return_ratio'] = x['stage_three_return_added'] / x['stage_three_retrn']
    x['stage_two_return_ratio'] = x['stage_two_return_added'] / x['stage_two_retrn']

    # 缺失值填充为0
    x.fillna(0)

    # 获取当前所使用的特征列表
    features = list(x)

    return x, y, video_ids, features


def train(x, y, features):
    """
    训练模型
    :param x: X
    :param y: Y
    :param features: 特征列表
    :return: None
    """
    # 训练集、测试集分割
    x_train, x_test, y_train, y_test = train_test_split(x, y, test_size=0.33)
    log_.info('x_train shape: {}, y_train shape: {}'.format(x_train.shape, y_train.shape))
    log_.info('x_test shape: {}, y_test shape: {}'.format(x_test.shape, y_test.shape))

    # 训练参数设置
    params = {
        "objective": "regression",
        "reg_sqrt": True,
        "metric": "mape",
        "max_depth": -1,
        "num_leaves": 50,
        "learning_rate": 0.1,
        "bagging_fraction": 0.7,
        "feature_fraction": 0.7,
        "bagging_freq": 8,
        "bagging_seed": 2018,
        "lambda_l1": 0.11,
        "boosting": "dart",
        "nthread": 4,
        "verbosity": -1
    }
    # 初始化数据集
    train_set = lgb.Dataset(data=x_train, label=y_train)
    test_set = lgb.Dataset(data=x_test, label=y_test)
    # 模型训练
    evals_result = {}

    model = lgb.train(params=params, train_set=train_set, num_boost_round=5000,
                      valid_sets=[test_set], early_stopping_rounds=100,
                      verbose_eval=100, evals_result=evals_result)

    # 将模型特征重要度存入csv
    feature_importance_data = {'feature': features, 'feature_importance': model.feature_importance()}
    feature_importance_filename = 'model_feature_importance.csv'
    pack_result_to_csv(filename=feature_importance_filename, sort_columns=['feature_importance'],
                       ascending=False, **feature_importance_data)

    # 测试集预测
    pre_y_test = model.predict(data=x_test, num_iteration=model.best_iteration)
    y_test = y_test.values

    err_mae = mean_absolute_error(y_test, pre_y_test)
    err_mape = mean_absolute_percentage_error(y_test, pre_y_test)
    r2 = r2_score(y_test, pre_y_test)

    # 将测试集结果存入csv
    test_data = {'pre_y_test': pre_y_test, 'y_test': y_test}
    test_result_filename = 'test_result.csv'
    pack_result_to_csv(filename=test_result_filename, sort_columns=['pre_y_test'], ascending=False, **test_data)

    print(err_mae, err_mape, r2)

    # 保存模型
    write_to_pickle(data=model, filename=config_.MODEL_FILENAME)


def pack_result_to_csv(filename, sort_columns=None, filepath=config_.DATA_DIR_PATH, ascending=True, **data):
    """
    打包数据并存入csv
    :param filename: csv文件名
    :param sort_columns: 指定排序列名列名，type-list, 默认为None
    :param filepath: csv文件存放路径，默认为config_.DATA_DIR_PATH
    :param ascending: 是否按指定列的数组升序排列，默认为True，即升序排列
    :param data: 数据
    :return: None
    """
    if not os.path.exists(filepath):
        os.makedirs(filepath)
    file = os.path.join(filepath, filename)
    df = pd.DataFrame(data=data)
    if sort_columns:
        df = df.sort_values(by=sort_columns, ascending=ascending)
    df.to_csv(file, index=False)


def predict():
    """预测"""
    # 读取预测数据并进行清洗
    x, y, video_ids, _ = process_data(config_.PREDICT_DATA_FILENAME)
    # 获取训练好的模型
    model = read_from_pickle(filename=config_.MODEL_FILENAME)
    # 预测
    y_ = model.predict(x)
    # 打包预测结果存入csv
    predict_data = {'y_': y_, 'y': y, 'video_ids': video_ids}
    predict_result_filename = 'predict.csv'
    pack_result_to_csv(filename=predict_result_filename, sort_columns=['y_'], ascending=False, **predict_data)


if __name__ == '__main__':
    train_filename = config_.TRAIN_DATA_FILENAME
    X, Y, videos, fea = process_data(filename=train_filename)
    print(X.shape, Y.shape)
    print(len(fea), fea)
    train(X, Y, features=fea)
    predict()