data-maker/data/maker/prepare/__init__.py

"""
(c) 2018 - 2021, Vanderbilt University Medical Center
Steve L. Nyemba, steve.l.nyemba@vumc.org

This file is designed to handle preconditions for a generative adversarial network:
    - The file will read/get data from a source specified by transport (or data-frame)
    - The class will convert the data to a binary vector
    - The class will also help rebuild the data from a binary matrix.
Usage :

"""
import transport
import json
import pandas as pd
import numpy as np
# import cupy as cp
import sys
import os
#
# The following is to address the issue over creating a large matrix ...
# 
# from multiprocessing import Process, Queue

# if 'GPU' in os.environ :
#     import cupy as np
# else:
#     import numpy as np    
class void:
    pass
class Hardware :
    """
    This class is intended to allow the use of hardware i.e GPU, index or CPU
    """
    pass

class Input :
    """
    This class is designed to read data from a source and and perform a variet of operations :
        - provide a feature space, and rows (matrix profile)
        - a data index map
    """

    def __init__(self,**_args):
        """
        :param data    
        :param store    data-store parameters/configuration
        :param sql      sql query  that pulls a representative sample of the data
        """
        self._schema = _args['schema'] if 'schema' in _args else {}
        self.df = _args['data']
        if 'sql' not in _args :
            self._initdata(**_args)   
            # 
            pass  
        else:
            self._initsql(**_args)
        #
        # We need to have a means to map of values,columns and vector positions in order
        # to perform convert and revert to and from binary
        #
        self._map = {} if 'map' not in _args else _args['map']
        
    def _initsql(self,**_args):
        """
        This function will initialize the class on the basis of a data-store and optionally pre-defined columns to be used to be synthesized 
        :param store        data-store configuration
        :param columns      list of columns to be 
        """
        
        if 'columns' not in _args :
            self._initcols(data=self.df)
        else:
            self._initcols(data=self.df,columns=_args['columns'])
        
        pass     
    def _initcols (self,**_args) :
        """
        This function will initialize the columns to be synthesized and/or determine which ones can be synthesized
        :param data         data-frame that holds the data (matrix)
        :param columns      optional columns to be synthesized 
        """
        # df = _args['data'].copy()
        row_count = self.df.shape[0]
        cols    = None if 'columns' not in _args else _args['columns']
        self.columns = self.df.columns.tolist()
        self._io = []

        if 'columns' in _args :
            self._columns = _args['columns']
        # else:
        #
        # We will look into the count and make a judgment call
        try:
            # _df = pd.DataFrame(self.df.apply(lambda col: col.dropna().unique().size )).T
            # MIN_SPACE_SIZE = 2
            # self._columns  = cols if cols else _df.apply(lambda col:None if col[0] == row_count or col[0] < MIN_SPACE_SIZE else col.name).dropna().tolist()
            # self._io = _df.to_dict(orient='records')
            _df  = pd.DataFrame(self.df.nunique().T / self.df.shape[0]).T
            self._io =  (_df.to_dict(orient='records'))
            
        except Exception as e:
            print (e)
            self._io = []
    def _initdata(self,**_args):
        """
        This function will initialize the class with a data-frame and columns of interest (if any)
        :param data       data-frame that holds the data
        :param columns columns that need to be synthesized if any
        """
        self._initcols(**_args)

    def convert(self,**_args):
        """
        This function will convert a data-frame into a binary matrix and provide a map to be able to map the values back to the matrix 
        :param columns  in case we specify the columns to account for (just in case the original assumptions don't hold)
        """
        if 'columns' in _args or 'column' in _args :
            columns = _args['columns'] if 'columns' in _args else [_args['column']]
        else:
            columns = self._columns
        _df = self.df if 'data' not in _args else _args['data']
        #
        # At this point we have the list of features we want to use
        i = 0
        
        _m = np.array([])
        _values  = []
        for name in columns :
            #
            # In case we have  dataset with incomplete value space, we should still be able to generate something meaningful
            #
            values = None if name not in self._map else list(self._map[name]['values'])
            _type = self._schema[name] if name in self._schema else _df[name].dtype
            cols, _matrix = self.tobinary(_df[name],values)
            _beg,_end = i,i+len(cols)
            if name not in self._map :
                self._map[name] = {"beg":_beg,"end":_end ,"values":cols.tolist()}
            i += len(cols)
            if not _m.shape[0]:
                _m = _matrix ;
            else:
                _m = np.concatenate((_m,_matrix),axis=1)
            if values :
                _values += list(values)
        #
        # @NOTE:
        # The map should allow us to be able to convert or reconvert the binary matrix to whatever we want ...
        #
        # self._matrix = _m
        
        return _values,_m
        
    def revert(self,**_args) :
        """
        This function will take in a binary matrix and based on the map of values it will repopulate it with values
        :param _matrix  binary matrix
        :param column|columns   column name or columns if the column is specified
        """
        _column = _args['column'] if 'column' in _args else None
            
        
        matrix = _args['matrix']
        row_count = matrix.shape[0]
        r = {}
        for key in self._map :
            if _column and key != _column :
                continue
            _item = self._map[key]
            _beg = _item['beg']
            _end = _item['end']
            columns = np.array(_item['values'])
            #
            # @NOTE: We are accessing matrices in terms of [row,col], 
            # The beg,end variables are for the columns in the matrix (mini matrix)
            #
            # if not _column :
            #     _matrix = matrix[:,_beg:_end] #-- The understanding is that _end is not included
            # else:
                # _matrix = matrix
            _matrix = matrix[:,_beg:_end]
            #
            # vectorize the matrix to replace the bits by their actual values (accounting for the data-types)
            # @TODO: Find ways to do this on a GPU (for big data) or across threads
            #
            row_count = _matrix.shape[0]
            # r[key] = [columns[np.where(row == 1) [0][0] ] for row in _matrix[:,_beg:_end]]
            
            r[key] = [columns[np.where(row==1)[0][0]] if np.where(row==1)[0].size > 0 else '' for row in _matrix]
            
            
        return pd.DataFrame(r)
     
    def tobinary(self,rows,cols=None) :
        """
        This function will compile a binary matrix from a row of values this allows hopefully this can be done in parallel, this function can be vectorized and processed 
        :param rows     np.array or list of vector of values
        :param cols     a space of values if it were to be different fromt he current sample.
        """
        if not cols:
            #
            # In the advent the sample rows do NOT have the values of the 
            cols = rows.unique()
        cols = np.array(cols)
        row_count = np.int64(len(rows))
        # if 'GPU' not in os.environ :
        # _matrix = np.zeros([row_count,cols.size],dtype=int)
        #
        # @NOTE: For some reason, there is an out of memory error created here, this seems to fix it (go figure)
        #
        _matrix = np.array([np.repeat(0,cols.size) for i in range(0,row_count)])
        
        [np.put(_matrix[i], np.where(cols ==  rows[i])  ,1)for i in np.arange(row_count) if np.where(cols == rows[i])[0].size > 0]
        # else:
        #     _matrix = cp.zeros([row_count,cols.size])
        #     [cp.put(_matrix[i], cp.where(cols ==  rows[i]),1)for i in cp.arange(row_count) ]
        #     _matrix = _matrix.asnumpy()

        
        return cols,_matrix