# -*- coding:utf-8 -*-
"""
@author: yq
@time: 2023/12/28
@desc:  特征工具类
"""
import pandas as pd
from sklearn.preprocessing import KBinsDiscretizer
from entitys import DataSplitEntity
from enums import BinsStrategyEnum
import scorecardpy as sc
import toad as td


def f_get_bins(data: DataSplitEntity, feat: str, strategy: str='quantile', nbins: int=10) -> pd.DataFrame:
    # 等频分箱
    if strategy == BinsStrategyEnum.QUANTILE.value:
        kbin_encoder = KBinsDiscretizer(n_bins=nbins, encode='ordinal', strategy='quantile')
        feature_binned = kbin_encoder.fit_transform(data[feat])
        return feature_binned.astype(int).astype(str)
    # 等宽分箱
    if strategy == BinsStrategyEnum.WIDTH.value:
        bin_width = (data.train_data()[feat].max() - data.train_data()[feat].min()) / nbins
        return pd.cut(data.train_data()[feat], bins=nbins, labels=[f'Bin_{i}' for i in range(1, nbins + 1)])
    # 使用toad分箱
    '''
    c = td.transfrom.Combiner()
    # method参数需要根据toad指定的几种方法名称选择
    c.fit(data, y = 'target', method = strategy, min_samples=None, n_bins = nbins, empty_separate = False)
    # 返回toad分箱combiner，用于训练集和测试集的分箱
    # 可使用c.export()[feature]查看某一特征的分箱临界值
    return c
    '''

# 此函数入参应为scorecardpy进行woebin函数转换后的dataframe
def f_get_bins_display(bins_info: pd.DataFrame) -> pd.DataFrame:
    df_list = []
    for col, bin_data in bins_info.items():
        tmp_df = pd.DataFrame(bin_data)
        df_list.append(tmp_df)
    result_df = pd.concat(df_list, ignore_index = True)
    total_bad = result_df['bad'].sum()
    total_cnt = result_df['count'].sum()
    # 整体的坏样本率
    br_overall = total_bad / total_cnt
    result_df['lift'] = result_df['badprob'] / br_overall
    result_df = result_df.sort_values(['total_iv', 'variable'], ascending=False).set_index(['variable','total_iv','bin'])\
                    [['count_distr','count','good','bad','badprob','lift','bin_iv','woe']]
    return result_df.style.format(subset=['count','good','bad'], precision=0).format(subset=['count_distr','bad','lift',
                                    'badprob','woe','bin_iv'],precision=4).bar(subset=['badprob','bin_iv','lift'],color=['#d65f58','#5fbb7a'])

# 此函数筛除变量分箱不单调或非U型的变量
def f_bins_filter(bins: pd.DataFrame, cols: list) -> list:
    result_cols = []
    # 遍历原始变量列表
    for tmp_col in cols:
        tmp_br = bins[tmp_col]['bad_prob'].values.tolist()
        tmp_len = len(tmp_br)
        if tmp_len <= 2:
            result_cols.append(tmp_col)
        else:
            start_tr = tmp_br[1] - tmp_br[0]
            pos_neg_flag = 0
            for i in range(2,tmp_len):
                tmp_tr = tmp_br[i] - tmp_br[i-1]
                # 后一位bad_rate减前一位bad_rate，保证bad_rate的单调性
                # 记录符号变化, 允许 最多一次符号变化，即U型分布
                if (tmp_tr >= 0 and start_tr >= 0) or  (tmp_tr <= 0 and start_tr <= 0):
                    # 满足趋势保持，查看下一位
                    continue
                else:
                    # 记录一次符号变化
                    pos_neg_flag += 1
            # 记录满足趋势要求的变量
            if pos_neg_flag <= 1:
                result_cols.append(tmp_col)
    return result_cols

def f_get_woe(data: DataSplitEntity, c: td.transform.Combiner, to_drop:list) -> pd.DataFrame:
    transer = td.transform.WOETransformer()
    # 根据训练数据来训练woe转换器，并选择目标变量和排除变量
    train_woe = transer.fit_transform(c.transform(data.train_data()), data.train_data()['target'],exclude=to_drop+['target'])
    test_woe = transer.transform(c.transfrom(data.test_data()))
    oot_woe = transer.transform(c.transform(data.val_data()))
    return train_woe, test_woe, oot_woe

def f_get_iv(data: DataSplitEntity) -> pd.DataFrame:
    # 计算前，先排除掉不需要计算IV的cols
    return td.quality(data, 'target',iv_only=True)

def f_get_psi(train_data: DataSplitEntity, oot_data: DataSplitEntity) -> pd.DataFrame:
    # 计算前，先排除掉不需要的cols
    return td.metrics.PSI(train_data, oot_data)


def f_get_corr(data: DataSplitEntity, meth: str='spearman') -> pd.DataFrame:
    return data.train_data().corr(method=meth)

def f_get_ivf(data: DataSplitEntity) -> pd.DataFrame:
    pass