import copy
import logging
import warnings
from collections import defaultdict
import dask.dataframe as dd
import numpy as np
import pandas as pd
from woodwork import init_series
from woodwork.logical_types import Datetime
from featuretools.entityset import deserialize, serialize
from featuretools.entityset.relationship import Relationship, RelationshipPath
from featuretools.feature_base.feature_base import _ES_REF
from featuretools.utils.gen_utils import Library, import_or_none, is_instance
from featuretools.utils.plot_utils import (
check_graphviz,
get_graphviz_format,
save_graph
)
from featuretools.utils.wrangle import _check_timedelta
ks = import_or_none('databricks.koalas')
pd.options.mode.chained_assignment = None # default='warn'
logger = logging.getLogger('featuretools.entityset')
LTI_COLUMN_NAME = '_ft_last_time'
WW_SCHEMA_KEY = '_ww__getstate__schemas'
[docs]class EntitySet(object):
"""
Stores all actual data and typing information for an entityset
Attributes:
id
dataframe_dict
relationships
time_type
Properties:
metadata
"""
[docs] def __init__(self, id=None, dataframes=None, relationships=None):
"""Creates EntitySet
Args:
id (str) : Unique identifier to associate with this instance
dataframes (dict[str -> tuple(DataFrame, str, str, dict[str -> str/Woodwork.LogicalType], dict[str->str/set], boolean)]):
Dictionary of DataFrames. Entries take the format
{dataframe name -> (dataframe, index column, time_index, logical_types, semantic_tags, make_index)}.
Note that only the dataframe is required. If a Woodwork DataFrame is supplied, any other parameters
will be ignored.
relationships (list[(str, str, str, str)]): List of relationships
between dataframes. List items are a tuple with the format
(parent dataframe name, parent column, child dataframe name, child column).
Example:
.. code-block:: python
dataframes = {
"cards" : (card_df, "id"),
"transactions" : (transactions_df, "id", "transaction_time")
}
relationships = [("cards", "id", "transactions", "card_id")]
ft.EntitySet("my-entity-set", dataframes, relationships)
"""
self.id = id
self.dataframe_dict = {}
self.relationships = []
self.time_type = None
dataframes = dataframes or {}
relationships = relationships or []
for df_name in dataframes:
df = dataframes[df_name][0]
if df.ww.schema is not None and df.ww.name != df_name:
raise ValueError(f"Naming conflict in dataframes dictionary: dictionary key '{df_name}' does not match dataframe name '{df.ww.name}'")
index_column = None
time_index = None
make_index = False
semantic_tags = None
logical_types = None
if len(dataframes[df_name]) > 1:
index_column = dataframes[df_name][1]
if len(dataframes[df_name]) > 2:
time_index = dataframes[df_name][2]
if len(dataframes[df_name]) > 3:
logical_types = dataframes[df_name][3]
if len(dataframes[df_name]) > 4:
semantic_tags = dataframes[df_name][4]
if len(dataframes[df_name]) > 5:
make_index = dataframes[df_name][5]
self.add_dataframe(dataframe_name=df_name,
dataframe=df,
index=index_column,
time_index=time_index,
logical_types=logical_types,
semantic_tags=semantic_tags,
make_index=make_index)
for relationship in relationships:
parent_df, parent_column, child_df, child_column = relationship
self.add_relationship(parent_df, parent_column, child_df, child_column)
self.reset_data_description()
_ES_REF[self.id] = self
def __sizeof__(self):
return sum([df.__sizeof__() for df in self.dataframes])
def __dask_tokenize__(self):
return (EntitySet, serialize.entityset_to_description(self.metadata))
def __eq__(self, other, deep=False):
if self.id != other.id:
return False
if self.time_type != other.time_type:
return False
if len(self.dataframe_dict) != len(other.dataframe_dict):
return False
for df_name, df in self.dataframe_dict.items():
if df_name not in other.dataframe_dict:
return False
if not df.ww.__eq__(other[df_name].ww, deep=deep):
return False
if not len(self.relationships) == len(other.relationships):
return False
for r in self.relationships:
if r not in other.relationships:
return False
return True
def __ne__(self, other, deep=False):
return not self.__eq__(other, deep=deep)
[docs] def __getitem__(self, dataframe_name):
"""Get dataframe instance from entityset
Args:
dataframe_name (str): Name of dataframe.
Returns:
:class:`.DataFrame` : Instance of dataframe with Woodwork typing information. None if dataframe doesn't
exist on the entityset.
"""
if dataframe_name in self.dataframe_dict:
return self.dataframe_dict[dataframe_name]
name = self.id or "entity set"
raise KeyError('DataFrame %s does not exist in %s' % (dataframe_name, name))
def __deepcopy__(self, memo):
cls = self.__class__
result = cls.__new__(cls)
memo[id(self)] = result
for k, v in self.__dict__.items():
if k == 'dataframe_dict':
# Copy the DataFrames, retaining Woodwork typing information
copied_attr = copy.copy(v)
for df_name, df in copied_attr.items():
copied_attr[df_name] = df.ww.copy()
else:
copied_attr = copy.deepcopy(v, memo)
setattr(result, k, copied_attr)
for df in result.dataframe_dict.values():
result._add_references_to_metadata(df)
return result
@property
def dataframes(self):
return list(self.dataframe_dict.values())
@property
def dataframe_type(self):
'''String specifying the library used for the dataframes. Null if no dataframes'''
df_type = None
if self.dataframes:
if isinstance(self.dataframes[0], pd.DataFrame):
df_type = Library.PANDAS.value
elif isinstance(self.dataframes[0], dd.DataFrame):
df_type = Library.DASK.value
elif is_instance(self.dataframes[0], ks, 'DataFrame'):
df_type = Library.KOALAS.value
return df_type
@property
def metadata(self):
'''Returns the metadata for this EntitySet. The metadata will be recomputed if it does not exist.'''
if self._data_description is None:
description = serialize.entityset_to_description(self)
self._data_description = deserialize.description_to_entityset(description)
return self._data_description
def reset_data_description(self):
self._data_description = None
[docs] def to_pickle(self, path, compression=None, profile_name=None):
'''Write entityset in the pickle format, location specified by `path`.
Path could be a local path or a S3 path.
If writing to S3 a tar archive of files will be written.
Args:
path (str): location on disk to write to (will be created as a directory)
compression (str) : Name of the compression to use. Possible values are: {'gzip', 'bz2', 'zip', 'xz', None}.
profile_name (str) : Name of AWS profile to use, False to use an anonymous profile, or None.
'''
serialize.write_data_description(self, path, format='pickle', compression=compression, profile_name=profile_name)
return self
[docs] def to_parquet(self, path, engine='auto', compression=None, profile_name=None):
'''Write entityset to disk in the parquet format, location specified by `path`.
Path could be a local path or a S3 path.
If writing to S3 a tar archive of files will be written.
Args:
path (str): location on disk to write to (will be created as a directory)
engine (str) : Name of the engine to use. Possible values are: {'auto', 'pyarrow'}.
compression (str) : Name of the compression to use. Possible values are: {'snappy', 'gzip', 'brotli', None}.
profile_name (str) : Name of AWS profile to use, False to use an anonymous profile, or None.
'''
serialize.write_data_description(self, path, format='parquet', engine=engine, compression=compression, profile_name=profile_name)
return self
[docs] def to_csv(self, path, sep=',', encoding='utf-8', engine='python', compression=None, profile_name=None):
'''Write entityset to disk in the csv format, location specified by `path`.
Path could be a local path or a S3 path.
If writing to S3 a tar archive of files will be written.
Args:
path (str) : Location on disk to write to (will be created as a directory)
sep (str) : String of length 1. Field delimiter for the output file.
encoding (str) : A string representing the encoding to use in the output file, defaults to 'utf-8'.
engine (str) : Name of the engine to use. Possible values are: {'c', 'python'}.
compression (str) : Name of the compression to use. Possible values are: {'gzip', 'bz2', 'zip', 'xz', None}.
profile_name (str) : Name of AWS profile to use, False to use an anonymous profile, or None.
'''
if self.dataframe_type == Library.KOALAS.value:
compression = str(compression)
serialize.write_data_description(self, path, format='csv', index=False, sep=sep, encoding=encoding, engine=engine, compression=compression, profile_name=profile_name)
return self
def to_dictionary(self):
return serialize.entityset_to_description(self)
###########################################################################
# Public getter/setter methods #########################################
###########################################################################
def __repr__(self):
repr_out = u"Entityset: {}\n".format(self.id)
repr_out += u" DataFrames:"
for df in self.dataframes:
if df.shape:
repr_out += u"\n {} [Rows: {}, Columns: {}]".format(
df.ww.name, df.shape[0], df.shape[1])
else:
repr_out += u"\n {} [Rows: None, Columns: None]".format(
df.ww.name)
repr_out += "\n Relationships:"
if len(self.relationships) == 0:
repr_out += u"\n No relationships"
for r in self.relationships:
repr_out += u"\n %s.%s -> %s.%s" % \
(r._child_dataframe_name, r._child_column_name,
r._parent_dataframe_name, r._parent_column_name)
return repr_out
[docs] def add_relationships(self, relationships):
"""Add multiple new relationships to a entityset
Args:
relationships (list[tuple(str, str, str, str)] or list[Relationship]) : List of
new relationships to add. Relationships are specified either as a :class:`.Relationship`
object or a four element tuple identifying the parent and child columns:
(parent_dataframe_name, parent_column_name, child_dataframe_name, child_column_name)
"""
for rel in relationships:
if isinstance(rel, Relationship):
self.add_relationship(relationship=rel)
else:
self.add_relationship(*rel)
return self
[docs] def add_relationship(self,
parent_dataframe_name=None,
parent_column_name=None,
child_dataframe_name=None,
child_column_name=None,
relationship=None):
"""Add a new relationship between dataframes in the entityset. Relationships can be specified
by passing dataframe and columns names or by passing a :class:`.Relationship` object.
Args:
parent_dataframe_name (str): Name of the parent dataframe in the EntitySet. Must be specified
if relationship is not.
parent_column_name (str): Name of the parent column. Must be specified if relationship is not.
child_dataframe_name (str): Name of the child dataframe in the EntitySet. Must be specified
if relationship is not.
child_column_name (str): Name of the child column. Must be specified if relationship is not.
relationship (Relationship): Instance of new relationship to be added. Must be specified
if dataframe and column names are not supplied.
"""
if relationship and (parent_dataframe_name or parent_column_name or child_dataframe_name or child_column_name):
raise ValueError("Cannot specify dataframe and column name values and also supply a Relationship")
if not relationship:
relationship = Relationship(self,
parent_dataframe_name,
parent_column_name,
child_dataframe_name,
child_column_name)
if relationship in self.relationships:
warnings.warn(
"Not adding duplicate relationship: " + str(relationship))
return self
# _operations?
# this is a new pair of dataframes
child_df = relationship.child_dataframe
child_column = relationship._child_column_name
if child_df.ww.index == child_column:
msg = "Unable to add relationship because child column '{}' in '{}' is also its index"
raise ValueError(msg.format(child_column, child_df.ww.name))
parent_df = relationship.parent_dataframe
parent_column = relationship._parent_column_name
if parent_df.ww.index != parent_column:
parent_df.ww.set_index(parent_column)
# Empty dataframes (as a result of accessing metadata)
# default to object dtypes for categorical columns, but
# indexes/foreign keys default to ints. In this case, we convert
# the empty column's type to int
if isinstance(child_df, pd.DataFrame) and \
(child_df.empty and child_df[child_column].dtype == object and
parent_df.ww.columns[parent_column].is_numeric):
child_df.ww[child_column] = pd.Series(name=child_column, dtype=np.int64)
parent_ltype = parent_df.ww.logical_types[parent_column]
child_ltype = child_df.ww.logical_types[child_column]
if parent_ltype != child_ltype:
difference_msg = ''
if str(parent_ltype) == str(child_ltype):
difference_msg = "There is a conflict between the parameters. "
warnings.warn(f'Logical type {child_ltype} for child column {child_column} does not match '
f'parent column {parent_column} logical type {parent_ltype}. {difference_msg}'
'Changing child logical type to match parent.')
child_df.ww.set_types(logical_types={child_column: parent_ltype})
if 'foreign_key' not in child_df.ww.semantic_tags[child_column]:
child_df.ww.add_semantic_tags({child_column: 'foreign_key'})
self.relationships.append(relationship)
self.reset_data_description()
return self
[docs] def set_secondary_time_index(self, dataframe_name, secondary_time_index):
"""
Set the secondary time index for a dataframe in the EntitySet using its dataframe name.
Args:
dataframe_name (str) : name of the dataframe for which to set the secondary time index.
secondary_time_index (dict[str-> list[str]]): Name of column containing time data to
be used as a secondary time index mapped to a list of the columns in the dataframe
associated with that secondary time index.
"""
dataframe = self[dataframe_name]
self._set_secondary_time_index(dataframe, secondary_time_index)
def _set_secondary_time_index(self, dataframe, secondary_time_index):
'''Sets the secondary time index for a Woodwork dataframe passed in'''
assert dataframe.ww.schema is not None, \
"Cannot set secondary time index if Woodwork is not initialized"
self._check_secondary_time_index(dataframe, secondary_time_index)
if secondary_time_index is not None:
dataframe.ww.metadata['secondary_time_index'] = secondary_time_index
###########################################################################
# Relationship access/helper methods ###################################
###########################################################################
[docs] def find_forward_paths(self, start_dataframe_name, goal_dataframe_name):
"""
Generator which yields all forward paths between a start and goal
dataframe. Does not include paths which contain cycles.
Args:
start_dataframe_name (str) : name of dataframe to start the search from
goal_dataframe_name (str) : name of dataframe to find forward path to
See Also:
:func:`BaseEntitySet.find_backward_paths`
"""
for sub_dataframe_name, path in self._forward_dataframe_paths(start_dataframe_name):
if sub_dataframe_name == goal_dataframe_name:
yield path
[docs] def find_backward_paths(self, start_dataframe_name, goal_dataframe_name):
"""
Generator which yields all backward paths between a start and goal
dataframe. Does not include paths which contain cycles.
Args:
start_dataframe_name (str) : Name of dataframe to start the search from.
goal_dataframe_name (str) : Name of dataframe to find backward path to.
See Also:
:func:`BaseEntitySet.find_forward_paths`
"""
for path in self.find_forward_paths(goal_dataframe_name, start_dataframe_name):
# Reverse path
yield path[::-1]
def _forward_dataframe_paths(self, start_dataframe_name, seen_dataframes=None):
"""
Generator which yields the names of all dataframes connected through forward
relationships, and the path taken to each. A dataframe will be yielded
multiple times if there are multiple paths to it.
Implemented using depth first search.
"""
if seen_dataframes is None:
seen_dataframes = set()
if start_dataframe_name in seen_dataframes:
return
seen_dataframes.add(start_dataframe_name)
yield start_dataframe_name, []
for relationship in self.get_forward_relationships(start_dataframe_name):
next_dataframe = relationship._parent_dataframe_name
# Copy seen dataframes for each next node to allow multiple paths (but
# not cycles).
descendants = self._forward_dataframe_paths(next_dataframe, seen_dataframes.copy())
for sub_dataframe_name, sub_path in descendants:
yield sub_dataframe_name, [relationship] + sub_path
[docs] def get_forward_dataframes(self, dataframe_name, deep=False):
"""
Get dataframes that are in a forward relationship with dataframe
Args:
dataframe_name (str): Name of dataframe to search from.
deep (bool): if True, recursively find forward dataframes.
Yields a tuple of (descendent_name, path from dataframe_name to descendant).
"""
for relationship in self.get_forward_relationships(dataframe_name):
parent_dataframe_name = relationship._parent_dataframe_name
direct_path = RelationshipPath([(True, relationship)])
yield parent_dataframe_name, direct_path
if deep:
sub_dataframes = self.get_forward_dataframes(parent_dataframe_name, deep=True)
for sub_dataframe_name, path in sub_dataframes:
yield sub_dataframe_name, direct_path + path
[docs] def get_backward_dataframes(self, dataframe_name, deep=False):
"""
Get dataframes that are in a backward relationship with dataframe
Args:
dataframe_name (str): Name of dataframe to search from.
deep (bool): if True, recursively find backward dataframes.
Yields a tuple of (descendent_name, path from dataframe_name to descendant).
"""
for relationship in self.get_backward_relationships(dataframe_name):
child_dataframe_name = relationship._child_dataframe_name
direct_path = RelationshipPath([(False, relationship)])
yield child_dataframe_name, direct_path
if deep:
sub_dataframes = self.get_backward_dataframes(child_dataframe_name, deep=True)
for sub_dataframe_name, path in sub_dataframes:
yield sub_dataframe_name, direct_path + path
def get_forward_relationships(self, dataframe_name):
"""Get relationships where dataframe "dataframe_name" is the child
Args:
dataframe_name (str): Name of dataframe to get relationships for.
Returns:
list[:class:`.Relationship`]: List of forward relationships.
"""
return [r for r in self.relationships if r._child_dataframe_name == dataframe_name]
def get_backward_relationships(self, dataframe_name):
"""
get relationships where dataframe "dataframe_name" is the parent.
Args:
dataframe_name (str): Name of dataframe to get relationships for.
Returns:
list[:class:`.Relationship`]: list of backward relationships
"""
return [r for r in self.relationships if r._parent_dataframe_name == dataframe_name]
def has_unique_forward_path(self, start_dataframe_name, end_dataframe_name):
"""
Is the forward path from start to end unique?
This will raise if there is no such path.
"""
paths = self.find_forward_paths(start_dataframe_name, end_dataframe_name)
next(paths)
second_path = next(paths, None)
return not second_path
###########################################################################
# DataFrame creation methods ##############################################
###########################################################################
[docs] def add_dataframe(self,
dataframe,
dataframe_name=None,
index=None,
logical_types=None,
semantic_tags=None,
make_index=False,
time_index=None,
secondary_time_index=None,
already_sorted=False):
"""
Add a DataFrame to the EntitySet with Woodwork typing information.
Args:
dataframe (pandas.DataFrame) : Dataframe containing the data.
dataframe_name (str, optional) : Unique name to associate with this dataframe. Must be
provided if Woodwork is not initialized on the input DataFrame.
index (str, optional): Name of the column used to index the dataframe.
Must be unique. If None, take the first column.
logical_types (dict[str -> Woodwork.LogicalTypes/str, optional]):
Keys are column names and values are logical types. Will be inferred if not specified.
semantic_tags (dict[str -> str/set], optional):
Keys are column names and values are semantic tags.
make_index (bool, optional) : If True, assume index does not
exist as a column in dataframe, and create a new column of that name
using integers. Otherwise, assume index exists.
time_index (str, optional): Name of the column containing
time data. Type must be numeric or datetime in nature.
secondary_time_index (dict[str -> list[str]]): Name of column containing time data to
be used as a secondary time index mapped to a list of the columns in the dataframe
associated with that secondary time index.
already_sorted (bool, optional) : If True, assumes that input dataframe
is already sorted by time. Defaults to False.
Notes:
Will infer logical types from the data.
Example:
.. ipython:: python
import featuretools as ft
import pandas as pd
transactions_df = pd.DataFrame({"id": [1, 2, 3, 4, 5, 6],
"session_id": [1, 2, 1, 3, 4, 5],
"amount": [100.40, 20.63, 33.32, 13.12, 67.22, 1.00],
"transaction_time": pd.date_range(start="10:00", periods=6, freq="10s"),
"fraud": [True, False, True, False, True, True]})
es = ft.EntitySet("example")
es.add_dataframe(dataframe_name="transactions",
index="id",
time_index="transaction_time",
dataframe=transactions_df)
es["transactions"]
"""
logical_types = logical_types or {}
semantic_tags = semantic_tags or {}
if len(self.dataframes) > 0:
if not isinstance(dataframe, type(self.dataframes[0])):
raise ValueError("All dataframes must be of the same type. "
"Cannot add dataframe of type {} to an entityset with existing dataframes "
"of type {}".format(type(dataframe), type(self.dataframes[0])))
# Only allow string column names
non_string_names = [name for name in dataframe.columns if not isinstance(name, str)]
if non_string_names:
raise ValueError("All column names must be strings (Columns {} "
"are not strings)".format(non_string_names))
if dataframe.ww.schema is None:
if dataframe_name is None:
raise ValueError('Cannot add dataframe to EntitySet without a name. '
'Please provide a value for the dataframe_name parameter.')
# Warn when performing inference on Dask or Koalas DataFrames
if not set(dataframe.columns).issubset(set(logical_types.keys())) and \
(isinstance(dataframe, dd.DataFrame) or is_instance(dataframe, ks, 'DataFrame')):
warnings.warn('Performing type inference on Dask or Koalas DataFrames may be computationally intensive. '
'Specify logical types for each column to speed up EntitySet initialization.')
index_was_created, index, dataframe = _get_or_create_index(index, make_index, dataframe)
dataframe.ww.init(name=dataframe_name,
index=index,
time_index=time_index,
logical_types=logical_types,
semantic_tags=semantic_tags,
already_sorted=already_sorted)
if index_was_created:
dataframe.ww.metadata['created_index'] = index
else:
if dataframe.ww.name is None:
raise ValueError('Cannot add a Woodwork DataFrame to EntitySet without a name')
if dataframe.ww.index is None:
raise ValueError('Cannot add Woodwork DataFrame to EntitySet without index')
extra_params = []
if index is not None:
extra_params.append('index')
if time_index is not None:
extra_params.append('time_index')
if logical_types:
extra_params.append('logical_types')
if make_index:
extra_params.append('make_index')
if semantic_tags:
extra_params.append('semantic_tags')
if already_sorted:
extra_params.append('already_sorted')
if dataframe_name is not None and dataframe_name != dataframe.ww.name:
extra_params.append('dataframe_name')
if extra_params:
warnings.warn("A Woodwork-initialized DataFrame was provided, so the following parameters were ignored: " + ", ".join(extra_params))
if dataframe.ww.time_index is not None:
self._check_uniform_time_index(dataframe)
self._check_secondary_time_index(dataframe)
if secondary_time_index:
self._set_secondary_time_index(dataframe, secondary_time_index=secondary_time_index)
self.dataframe_dict[dataframe.ww.name] = dataframe
self.reset_data_description()
self._add_references_to_metadata(dataframe)
return self
def __setitem__(self, key, value):
self.add_dataframe(dataframe=value, dataframe_name=key)
[docs] def normalize_dataframe(self, base_dataframe_name, new_dataframe_name, index,
additional_columns=None, copy_columns=None,
make_time_index=None,
make_secondary_time_index=None,
new_dataframe_time_index=None,
new_dataframe_secondary_time_index=None):
"""Create a new dataframe and relationship from unique values of an existing column.
Args:
base_dataframe_name (str) : Datarame name from which to split.
new_dataframe_name (str): Name of the new dataframe.
index (str): Column in old dataframe
that will become index of new dataframe. Relationship
will be created across this column.
additional_columns (list[str]):
List of column names to remove from
base_dataframe and move to new dataframe.
copy_columns (list[str]): List of
column names to copy from old dataframe
and move to new dataframe.
make_time_index (bool or str, optional): Create time index for new dataframe based
on time index in base_dataframe, optionally specifying which column in base_dataframe
to use for time_index. If specified as True without a specific column name,
uses the primary time index. Defaults to True if base dataframe has a time index.
make_secondary_time_index (dict[str -> list[str]], optional): Create a secondary time index
from key. Values of dictionary are the columns to associate with a secondary time index.
Only one secondary time index is allowed. If None, only associate the time index.
new_dataframe_time_index (str, optional): Rename new dataframe time index.
new_dataframe_secondary_time_index (str, optional): Rename new dataframe secondary time index.
"""
base_dataframe = self.dataframe_dict[base_dataframe_name]
additional_columns = additional_columns or []
copy_columns = copy_columns or []
for list_name, col_list in {'copy_columns': copy_columns,
'additional_columns': additional_columns}.items():
if not isinstance(col_list, list):
raise TypeError("'{}' must be a list, but received type {}"
.format(list_name, type(col_list)))
if len(col_list) != len(set(col_list)):
raise ValueError(f"'{list_name}' contains duplicate columns. All columns must be unique.")
for col_name in col_list:
if col_name == index:
raise ValueError("Not adding {} as both index and column in {}".format(col_name, list_name))
for col in additional_columns:
if col == base_dataframe.ww.time_index:
raise ValueError("Not moving {} as it is the base time index column. Perhaps, move the column to the copy_columns.".format(col))
if isinstance(make_time_index, str):
if make_time_index not in base_dataframe.columns:
raise ValueError("'make_time_index' must be a column in the base dataframe")
elif make_time_index not in additional_columns + copy_columns:
raise ValueError("'make_time_index' must be specified in 'additional_columns' or 'copy_columns'")
if index == base_dataframe.ww.index:
raise ValueError("'index' must be different from the index column of the base dataframe")
transfer_types = {}
# Types will be a tuple of (logical_type, semantic_tags, column_metadata, column_description)
transfer_types[index] = (base_dataframe.ww.logical_types[index],
base_dataframe.ww.semantic_tags[index],
base_dataframe.ww.columns[index].metadata,
base_dataframe.ww.columns[index].description)
for col_name in additional_columns + copy_columns:
# Remove any existing time index tags
transfer_types[col_name] = (base_dataframe.ww.logical_types[col_name],
(base_dataframe.ww.semantic_tags[col_name] - {'time_index'}),
base_dataframe.ww.columns[col_name].metadata,
base_dataframe.ww.columns[col_name].description)
# create and add new dataframe
new_dataframe = self[base_dataframe_name].copy()
if make_time_index is None and base_dataframe.ww.time_index is not None:
make_time_index = True
if isinstance(make_time_index, str):
# Set the new time index to make_time_index.
base_time_index = make_time_index
new_dataframe_time_index = make_time_index
already_sorted = (new_dataframe_time_index == base_dataframe.ww.time_index)
elif make_time_index:
# Create a new time index based on the base dataframe time index.
base_time_index = base_dataframe.ww.time_index
if new_dataframe_time_index is None:
new_dataframe_time_index = "first_%s_time" % (base_dataframe.ww.name)
already_sorted = True
assert base_dataframe.ww.time_index is not None, \
"Base dataframe doesn't have time_index defined"
if base_time_index not in [col for col in copy_columns]:
copy_columns.append(base_time_index)
time_index_types = (base_dataframe.ww.logical_types[base_dataframe.ww.time_index],
base_dataframe.ww.semantic_tags[base_dataframe.ww.time_index],
base_dataframe.ww.columns[base_dataframe.ww.time_index].metadata,
base_dataframe.ww.columns[base_dataframe.ww.time_index].description)
else:
# If base_time_index is in copy_columns then we've already added the transfer types
# but since we're changing the name, we have to remove it
time_index_types = transfer_types[base_dataframe.ww.time_index]
del transfer_types[base_dataframe.ww.time_index]
transfer_types[new_dataframe_time_index] = time_index_types
else:
new_dataframe_time_index = None
already_sorted = False
if new_dataframe_time_index is not None and new_dataframe_time_index == index:
raise ValueError("time_index and index cannot be the same value, %s" % (new_dataframe_time_index))
selected_columns = [index] +\
[col for col in additional_columns] +\
[col for col in copy_columns]
new_dataframe = new_dataframe.dropna(subset=[index])
new_dataframe2 = new_dataframe. \
drop_duplicates(index, keep='first')[selected_columns]
if make_time_index:
new_dataframe2 = new_dataframe2.rename(columns={base_time_index: new_dataframe_time_index})
if make_secondary_time_index:
assert len(make_secondary_time_index) == 1, "Can only provide 1 secondary time index"
secondary_time_index = list(make_secondary_time_index.keys())[0]
secondary_columns = [index, secondary_time_index] + list(make_secondary_time_index.values())[0]
secondary_df = new_dataframe. \
drop_duplicates(index, keep='last')[secondary_columns]
if new_dataframe_secondary_time_index:
secondary_df = secondary_df.rename(columns={secondary_time_index: new_dataframe_secondary_time_index})
secondary_time_index = new_dataframe_secondary_time_index
else:
new_dataframe_secondary_time_index = secondary_time_index
secondary_df = secondary_df.set_index(index)
new_dataframe = new_dataframe2.join(secondary_df, on=index)
else:
new_dataframe = new_dataframe2
base_dataframe_index = index
if make_secondary_time_index:
old_ti_name = list(make_secondary_time_index.keys())[0]
ti_cols = list(make_secondary_time_index.values())[0]
ti_cols = [c if c != old_ti_name else secondary_time_index for c in ti_cols]
make_secondary_time_index = {secondary_time_index: ti_cols}
if is_instance(new_dataframe, ks, 'DataFrame'):
already_sorted = False
# will initialize Woodwork on this DataFrame
logical_types = {}
semantic_tags = {}
column_metadata = {}
column_descriptions = {}
for col_name, (ltype, tags, metadata, description) in transfer_types.items():
logical_types[col_name] = ltype
semantic_tags[col_name] = tags - {'time_index'}
column_metadata[col_name] = copy.deepcopy(metadata)
column_descriptions[col_name] = description
new_dataframe.ww.init(name=new_dataframe_name, index=index,
already_sorted=already_sorted,
time_index=new_dataframe_time_index,
logical_types=logical_types,
semantic_tags=semantic_tags,
column_metadata=column_metadata,
column_descriptions=column_descriptions
)
self.add_dataframe(
new_dataframe,
secondary_time_index=make_secondary_time_index
)
self.dataframe_dict[base_dataframe_name] = self.dataframe_dict[base_dataframe_name].ww.drop(additional_columns)
self.dataframe_dict[base_dataframe_name].ww.add_semantic_tags({base_dataframe_index: 'foreign_key'})
self.add_relationship(new_dataframe_name, index, base_dataframe_name, base_dataframe_index)
self.reset_data_description()
return self
# ###########################################################################
# # Data wrangling methods ###############################################
# ###########################################################################
[docs] def concat(self, other, inplace=False):
'''Combine entityset with another to create a new entityset with the
combined data of both entitysets.
'''
if not self.__eq__(other):
raise ValueError("Entitysets must have the same dataframes, relationships"
", and column names")
if inplace:
combined_es = self
else:
combined_es = copy.deepcopy(self)
lib = pd
if self.dataframe_type == Library.KOALAS.value:
lib = ks
elif self.dataframe_type == Library.DASK.value:
lib = dd
has_last_time_index = []
for df in self.dataframes:
self_df = df
other_df = other[df.ww.name]
combined_df = lib.concat([self_df, other_df])
# If both DataFrames have made indexes, there will likely
# be overlap in the index column, so we use the other values
if self_df.ww.metadata.get('created_index') or other_df.ww.metadata.get('created_index'):
columns = [col for col in combined_df.columns if
col != df.ww.index or col != df.ww.time_index]
else:
columns = [df.ww.index]
combined_df.drop_duplicates(columns, inplace=True)
self_lti_col = df.ww.metadata.get('last_time_index')
other_lti_col = other[df.ww.name].ww.metadata.get('last_time_index')
if (self_lti_col is not None or
other_lti_col is not None):
has_last_time_index.append(df.ww.name)
combined_es.replace_dataframe(
dataframe_name=df.ww.name,
df=combined_df,
recalculate_last_time_indexes=False,
already_sorted=False
)
if has_last_time_index:
combined_es.add_last_time_indexes(updated_dataframes=has_last_time_index)
combined_es.reset_data_description()
return combined_es
###########################################################################
# Indexing methods ###############################################
###########################################################################
[docs] def add_last_time_indexes(self, updated_dataframes=None):
"""
Calculates the last time index values for each dataframe (the last time
an instance or children of that instance were observed). Used when
calculating features using training windows. Adds the last time index as
a series named _ft_last_time on the dataframe.
Args:
updated_dataframes (list[str]): List of dataframe names to update last_time_index for
(will update all parents of those dataframes as well)
"""
# Generate graph of dataframes to find leaf dataframes
children = defaultdict(list) # parent --> child mapping
child_cols = defaultdict(dict)
for r in self.relationships:
children[r._parent_dataframe_name].append(r.child_dataframe)
child_cols[r._parent_dataframe_name][r._child_dataframe_name] = r.child_column
updated_dataframes = updated_dataframes or []
if updated_dataframes:
# find parents of updated_dataframes
parent_queue = updated_dataframes[:]
parents = set()
while len(parent_queue):
df_name = parent_queue.pop(0)
if df_name in parents:
continue
parents.add(df_name)
for parent_name, _ in self.get_forward_dataframes(df_name):
parent_queue.append(parent_name)
queue = [self[p] for p in parents]
to_explore = parents
else:
to_explore = set(self.dataframe_dict.keys())
queue = self.dataframes[:]
explored = set()
# Store the last time indexes for the entire entityset in a dictionary to update
es_lti_dict = {}
for df in self.dataframes:
lti_col = df.ww.metadata.get('last_time_index')
if lti_col is not None:
lti_col = df[lti_col]
es_lti_dict[df.ww.name] = lti_col
for df in queue:
es_lti_dict[df.ww.name] = None
# We will explore children of dataframes on the queue,
# which may not be in the to_explore set. Therefore,
# we check whether all elements of to_explore are in
# explored, rather than just comparing length
while not to_explore.issubset(explored):
dataframe = queue.pop(0)
if es_lti_dict[dataframe.ww.name] is None:
if dataframe.ww.time_index is not None:
lti = dataframe[dataframe.ww.time_index].copy()
if isinstance(dataframe, dd.DataFrame):
# The current Dask implementation doesn't set the index of the dataframe
# to the dataframe's index, so we have to do it manually here
lti.index = dataframe[dataframe.ww.index].copy()
else:
lti = dataframe.ww[dataframe.ww.index].copy()
if isinstance(dataframe, dd.DataFrame):
lti.index = dataframe[dataframe.ww.index].copy()
lti = lti.apply(lambda x: None)
elif is_instance(dataframe, ks, 'DataFrame'):
lti = ks.Series(pd.Series(index=lti.to_list(), name=lti.name))
else:
# Cannot have a category dtype with nans when calculating last time index
lti = lti.astype('object')
lti[:] = None
es_lti_dict[dataframe.ww.name] = lti
if dataframe.ww.name in children:
child_dataframes = children[dataframe.ww.name]
# if all children not explored, skip for now
if not set([df.ww.name for df in child_dataframes]).issubset(explored):
# Now there is a possibility that a child dataframe
# was not explicitly provided in updated_dataframes,
# and never made it onto the queue. If updated_dataframes
# is None then we just load all dataframes onto the queue
# so we didn't need this logic
for df in child_dataframes:
if df.ww.name not in explored and df.ww.name not in [q.ww.name for q in queue]:
# must also reset last time index here
es_lti_dict[df.ww.name] = None
queue.append(df)
queue.append(dataframe)
continue
# updated last time from all children
for child_df in child_dataframes:
# TODO: Figure out if Dask code related to indexes is important for Koalas
if es_lti_dict[child_df.ww.name] is None:
continue
link_col = child_cols[dataframe.ww.name][child_df.ww.name].name
lti_is_dask = isinstance(es_lti_dict[child_df.ww.name], dd.Series)
lti_is_koalas = is_instance(es_lti_dict[child_df.ww.name], ks, 'Series')
if lti_is_dask or lti_is_koalas:
to_join = child_df[link_col]
if lti_is_dask:
to_join.index = child_df[child_df.ww.index]
lti_df = es_lti_dict[child_df.ww.name].to_frame(name='last_time').join(
to_join.to_frame(name=dataframe.ww.index)
)
if lti_is_dask:
new_index = lti_df.index.copy()
new_index.name = None
lti_df.index = new_index
lti_df = lti_df.groupby(lti_df[dataframe.ww.index]).agg('max')
lti_df = es_lti_dict[dataframe.ww.name].to_frame(name='last_time_old').join(lti_df)
else:
lti_df = pd.DataFrame({'last_time': es_lti_dict[child_df.ww.name],
dataframe.ww.index: child_df[link_col]})
# sort by time and keep only the most recent
lti_df.sort_values(['last_time', dataframe.ww.index],
kind="mergesort", inplace=True)
lti_df.drop_duplicates(dataframe.ww.index,
keep='last',
inplace=True)
lti_df.set_index(dataframe.ww.index, inplace=True)
lti_df = lti_df.reindex(es_lti_dict[dataframe.ww.name].index)
lti_df['last_time_old'] = es_lti_dict[dataframe.ww.name]
if not (lti_is_dask or lti_is_koalas) and lti_df.empty:
# Pandas errors out if it tries to do fillna and then max on an empty dataframe
lti_df = pd.Series()
else:
if lti_is_koalas:
lti_df['last_time'] = ks.to_datetime(lti_df['last_time'])
lti_df['last_time_old'] = ks.to_datetime(lti_df['last_time_old'])
# TODO: Figure out a workaround for fillna and replace
lti_df = lti_df.max(axis=1)
else:
lti_df['last_time'] = lti_df['last_time'].astype('datetime64[ns]')
lti_df['last_time_old'] = lti_df['last_time_old'].astype('datetime64[ns]')
lti_df = lti_df.fillna(pd.to_datetime('1800-01-01 00:00')).max(axis=1)
lti_df = lti_df.replace(pd.to_datetime('1800-01-01 00:00'), pd.NaT)
es_lti_dict[dataframe.ww.name] = lti_df
es_lti_dict[dataframe.ww.name].name = 'last_time'
explored.add(dataframe.ww.name)
# Store the last time index on the DataFrames
dfs_to_update = {}
for df in self.dataframes:
lti = es_lti_dict[df.ww.name]
if lti is not None:
lti_ltype = None
if self.time_type == 'numeric':
if lti.dtype == 'datetime64[ns]':
# Woodwork cannot convert from datetime to numeric
lti = lti.apply(lambda x: x.value)
lti = init_series(lti, logical_type='Double')
lti_ltype = 'Double'
else:
lti = init_series(lti, logical_type='Datetime')
lti_ltype = 'Datetime'
lti.name = LTI_COLUMN_NAME
if LTI_COLUMN_NAME in df.columns:
if 'last_time_index' in df.ww.semantic_tags[LTI_COLUMN_NAME]:
# Remove any previous last time index placed by featuretools
df.ww.pop(LTI_COLUMN_NAME)
else:
raise ValueError("Cannot add a last time index on DataFrame with an existing "
f"'{LTI_COLUMN_NAME}' column. Please rename '{LTI_COLUMN_NAME}'.")
# Add the new column to the DataFrame
if isinstance(df, dd.DataFrame):
new_df = df.merge(lti.reset_index(), on=df.ww.index)
new_df.ww.init(schema=df.ww.schema, logical_types={LTI_COLUMN_NAME: lti_ltype})
new_idx = new_df[new_df.ww.index]
new_idx.name = None
new_df.index = new_idx
dfs_to_update[df.ww.name] = new_df
elif is_instance(df, ks, 'DataFrame'):
new_df = df.merge(lti, left_on=df.ww.index, right_index=True)
new_df.ww.init(schema=df.ww.schema, logical_types={LTI_COLUMN_NAME: lti_ltype})
dfs_to_update[df.ww.name] = new_df
else:
df.ww[LTI_COLUMN_NAME] = lti
if 'last_time_index' not in df.ww.semantic_tags[LTI_COLUMN_NAME]:
df.ww.add_semantic_tags({LTI_COLUMN_NAME: 'last_time_index'})
df.ww.metadata['last_time_index'] = LTI_COLUMN_NAME
for df in dfs_to_update.values():
df.ww.add_semantic_tags({LTI_COLUMN_NAME: 'last_time_index'})
df.ww.metadata['last_time_index'] = LTI_COLUMN_NAME
self.dataframe_dict[df.ww.name] = df
self.reset_data_description()
for df in self.dataframes:
self._add_references_to_metadata(df)
# ###########################################################################
# # Pickling ###############################################
# ###########################################################################
def __getstate__(self):
return {
**self.__dict__,
WW_SCHEMA_KEY: {df_name: df.ww.schema for df_name, df in self.dataframe_dict.items()}
}
def __setstate__(self, state):
ww_schemas = state.pop(WW_SCHEMA_KEY)
for df_name, df in state.get('dataframe_dict', {}).items():
if ww_schemas[df_name] is not None:
df.ww.init(schema=ww_schemas[df_name], validate=False)
self.__dict__.update(state)
# ###########################################################################
# # Other ###############################################
# ###########################################################################
[docs] def add_interesting_values(self, max_values=5, verbose=False, dataframe_name=None, values=None):
"""Find or set interesting values for categorical columns, to be used to generate "where" clauses
Args:
max_values (int) : Maximum number of values per column to add.
verbose (bool) : If True, print summary of interesting values found.
dataframe_name (str) : The dataframe in the EntitySet for which to add interesting values.
If not specified interesting values will be added for all dataframes.
values (dict): A dictionary mapping column names to the interesting values to set
for the column. If specified, a corresponding dataframe_name must also be provided.
If not specified, interesting values will be set for all eligible columns. If values
are specified, max_values and verbose parameters will be ignored.
Notes:
Finding interesting values is not supported with Dask or Koalas EntitySets.
To set interesting values for Dask or Koalas EntitySets, values must be
specified with the ``values`` parameter.
Returns:
None
"""
if dataframe_name is None and values is not None:
raise ValueError("dataframe_name must be specified if values are provided")
if dataframe_name is not None and values is not None:
for column, vals in values.items():
self[dataframe_name].ww.columns[column].metadata['interesting_values'] = vals
return
if dataframe_name:
dataframes = [self[dataframe_name]]
else:
dataframes = self.dataframes
def add_value(df, col, val, verbose):
if verbose:
msg = "Column {}: Marking {} as an interesting value"
logger.info(msg.format(col, val))
interesting_vals = df.ww.columns[col].metadata.get('interesting_values', [])
interesting_vals.append(val)
df.ww.columns[col].metadata['interesting_values'] = interesting_vals
for df in dataframes:
value_counts = df.ww.value_counts(top_n=max(25, max_values), dropna=True)
total_count = len(df)
for col, counts in value_counts.items():
if {'index', 'foreign_key'}.intersection(df.ww.semantic_tags[col]):
continue
for i in range(min(max_values, len(counts))):
# Categorical columns will include counts of 0 for all values
# in categories. Stop when we encounter a 0 count.
if counts[i]['count'] == 0:
break
if len(counts) < 25:
value = counts[i]['value']
add_value(df, col, value, verbose)
else:
fraction = counts[i]['count'] / total_count
if fraction > 0.05 and fraction < 0.95:
value = counts[i]['value']
add_value(df, col, value, verbose)
else:
break
self.reset_data_description()
[docs] def plot(self, to_file=None):
"""
Create a UML diagram-ish graph of the EntitySet.
Args:
to_file (str, optional) : Path to where the plot should be saved.
If set to None (as by default), the plot will not be saved.
Returns:
graphviz.Digraph : Graph object that can directly be displayed in
Jupyter notebooks. Nodes of the graph correspond to the DataFrames
in the EntitySet, showing the typing information for each column.
Note:
The typing information displayed for each column is based off of the Woodwork
ColumnSchema for that column and is represented as ``LogicalType; semantic_tags``,
but the standard semantic tags have been removed for brevity.
"""
graphviz = check_graphviz()
format_ = get_graphviz_format(graphviz=graphviz,
to_file=to_file)
# Initialize a new directed graph
graph = graphviz.Digraph(self.id, format=format_,
graph_attr={'splines': 'ortho'})
# Draw dataframes
for df in self.dataframes:
column_typing_info = []
for col_name, col_schema in df.ww.columns.items():
col_string = col_name + ' : ' + str(col_schema.logical_type)
tags = col_schema.semantic_tags - col_schema.logical_type.standard_tags
if tags:
col_string += '; '
col_string += ', '.join(tags)
column_typing_info.append(col_string)
columns_string = '\l'.join(column_typing_info) # noqa: W605
if isinstance(df, dd.DataFrame): # dataframe is a dask dataframe
label = '{%s |%s\l}' % (df.ww.name, columns_string) # noqa: W605
else:
nrows = df.shape[0]
label = '{%s (%d row%s)|%s\l}' % (df.ww.name, nrows, 's' * (nrows > 1), columns_string) # noqa: W605
graph.node(df.ww.name, shape='record', label=label)
# Draw relationships
for rel in self.relationships:
# Display the key only once if is the same for both related dataframes
if rel._parent_column_name == rel._child_column_name:
label = rel._parent_column_name
else:
label = '%s -> %s' % (rel._parent_column_name,
rel._child_column_name)
graph.edge(rel._child_dataframe_name, rel._parent_dataframe_name, xlabel=label)
if to_file:
save_graph(graph, to_file, format_)
return graph
def _handle_time(self, dataframe_name, df, time_last=None, training_window=None, include_cutoff_time=True):
"""
Filter a dataframe for all instances before time_last.
If the dataframe does not have a time index, return the original
dataframe.
"""
schema = self[dataframe_name].ww.schema
if is_instance(df, ks, 'DataFrame') and isinstance(time_last, np.datetime64):
time_last = pd.to_datetime(time_last)
if schema.time_index:
df_empty = df.empty if isinstance(df, pd.DataFrame) else False
if time_last is not None and not df_empty:
if include_cutoff_time:
df = df[df[schema.time_index] <= time_last]
else:
df = df[df[schema.time_index] < time_last]
if training_window is not None:
training_window = _check_timedelta(training_window)
if include_cutoff_time:
mask = df[schema.time_index] > time_last - training_window
else:
mask = df[schema.time_index] >= time_last - training_window
lti_col = schema.metadata.get('last_time_index')
if lti_col is not None:
if include_cutoff_time:
lti_mask = df[lti_col] > time_last - training_window
else:
lti_mask = df[lti_col] >= time_last - training_window
mask = mask | lti_mask
else:
warnings.warn(
"Using training_window but last_time_index is "
"not set for dataframe %s" % (dataframe_name)
)
df = df[mask]
secondary_time_indexes = schema.metadata.get('secondary_time_index') or {}
for secondary_time_index, columns in secondary_time_indexes.items():
# should we use ignore time last here?
df_empty = df.empty if isinstance(df, pd.DataFrame) else False
if time_last is not None and not df_empty:
mask = df[secondary_time_index] >= time_last
if isinstance(df, dd.DataFrame):
for col in columns:
df[col] = df[col].mask(mask, np.nan)
elif is_instance(df, ks, 'DataFrame'):
df.loc[mask, columns] = None
else:
df.loc[mask, columns] = np.nan
return df
[docs] def query_by_values(self, dataframe_name, instance_vals, column_name=None, columns=None,
time_last=None, training_window=None, include_cutoff_time=True):
"""Query instances that have column with given value
Args:
dataframe_name (str): The id of the dataframe to query
instance_vals (pd.Dataframe, pd.Series, list[str] or str) :
Instance(s) to match.
column_name (str) : Column to query on. If None, query on index.
columns (list[str]) : Columns to return. Return all columns if None.
time_last (pd.TimeStamp) : Query data up to and including this
time. Only applies if dataframe has a time index.
training_window (Timedelta, optional):
Window defining how much time before the cutoff time data
can be used when calculating features. If None, all data before cutoff time is used.
include_cutoff_time (bool):
If True, data at cutoff time are included in calculating features
Returns:
pd.DataFrame : instances that match constraints with ids in order of underlying dataframe
"""
dataframe = self[dataframe_name]
if not column_name:
column_name = dataframe.ww.index
instance_vals = _vals_to_series(instance_vals, column_name)
training_window = _check_timedelta(training_window)
if training_window is not None:
assert training_window.has_no_observations(), "Training window cannot be in observations"
if instance_vals is None:
df = dataframe.copy()
elif isinstance(instance_vals, pd.Series) and instance_vals.empty:
df = dataframe.head(0)
else:
if is_instance(instance_vals, (dd, ks), 'Series'):
df = dataframe.merge(instance_vals.to_frame(), how="inner", on=column_name)
elif isinstance(instance_vals, pd.Series) and is_instance(dataframe, ks, 'DataFrame'):
df = dataframe.merge(ks.DataFrame({column_name: instance_vals}), how="inner", on=column_name)
else:
df = dataframe[dataframe[column_name].isin(instance_vals)]
if isinstance(dataframe, pd.DataFrame):
df = df.set_index(dataframe.ww.index, drop=False)
# ensure filtered df has same categories as original
# workaround for issue below
# github.com/pandas-dev/pandas/issues/22501#issuecomment-415982538
#
# Pandas claims that bug is fixed but it still shows up in some
# cases. More investigation needed.
#
# Note: Woodwork stores categorical columns with a `string` dtype for Koalas
if dataframe.ww.columns[column_name].is_categorical and not is_instance(df, ks, 'DataFrame'):
categories = pd.api.types.CategoricalDtype(categories=dataframe[column_name].cat.categories)
df[column_name] = df[column_name].astype(categories)
df = self._handle_time(dataframe_name=dataframe_name,
df=df,
time_last=time_last,
training_window=training_window,
include_cutoff_time=include_cutoff_time)
if columns is not None:
df = df[columns]
return df
[docs] def replace_dataframe(self, dataframe_name, df, already_sorted=False, recalculate_last_time_indexes=True):
'''Replace the internal dataframe of an EntitySet table, keeping Woodwork typing information the same.
Optionally makes sure that data is sorted, that reference indexes to other dataframes are consistent,
and that last_time_indexes are updated to reflect the new data. If an index was created for the original
dataframe and is not present on the new dataframe, an index column of the same name will be added to the
new dataframe.
'''
if not isinstance(df, type(self[dataframe_name])):
raise TypeError('Incorrect DataFrame type used')
# If the original DataFrame has a last time index column and the new one doesnt
# remove the column and the reference to last time index from that dataframe
last_time_index_column = self[dataframe_name].ww.metadata.get('last_time_index')
if last_time_index_column is not None and last_time_index_column not in df.columns:
self[dataframe_name].ww.pop(last_time_index_column)
del self[dataframe_name].ww.metadata['last_time_index']
# If the original DataFrame had an index created via make_index,
# we may need to remake the index if it's not in the new DataFrame
created_index = self[dataframe_name].ww.metadata.get('created_index')
if created_index is not None and created_index not in df.columns:
df = _create_index(df, created_index)
old_column_names = list(self[dataframe_name].columns)
if len(df.columns) != len(old_column_names):
raise ValueError("New dataframe contains {} columns, expecting {}".format(len(df.columns),
len(old_column_names)))
for col_name in old_column_names:
if col_name not in df.columns:
raise ValueError("New dataframe is missing new {} column".format(col_name))
if df.ww.schema is not None:
warnings.warn('Woodwork typing information on new dataframe will be replaced '
f'with existing typing information from {dataframe_name}')
df.ww.init(schema=self[dataframe_name].ww._schema, already_sorted=already_sorted)
# Make sure column ordering matches original ordering
df = df.ww[old_column_names]
self.dataframe_dict[dataframe_name] = df
if self[dataframe_name].ww.time_index is not None:
self._check_uniform_time_index(self[dataframe_name])
df_metadata = self[dataframe_name].ww.metadata
self.set_secondary_time_index(dataframe_name, df_metadata.get('secondary_time_index'))
if recalculate_last_time_indexes and last_time_index_column is not None:
self.add_last_time_indexes(updated_dataframes=[dataframe_name])
self.reset_data_description()
self._add_references_to_metadata(df)
def _check_time_indexes(self):
for dataframe in self.dataframe_dict.values():
self._check_uniform_time_index(dataframe)
self._check_secondary_time_index(dataframe)
def _check_secondary_time_index(self, dataframe, secondary_time_index=None):
secondary_time_index = secondary_time_index or dataframe.ww.metadata.get('secondary_time_index', {})
if secondary_time_index and dataframe.ww.time_index is None:
raise ValueError('Cannot set secondary time index on a DataFrame that has no primary time index.')
for time_index, columns in secondary_time_index.items():
self._check_uniform_time_index(dataframe, column_name=time_index)
if time_index not in columns:
columns.append(time_index)
def _check_uniform_time_index(self, dataframe, column_name=None):
column_name = column_name or dataframe.ww.time_index
if column_name is None:
return
time_type = self._get_time_type(dataframe, column_name)
if self.time_type is None:
self.time_type = time_type
elif self.time_type != time_type:
info = "%s time index is %s type which differs from other entityset time indexes"
raise TypeError(info % (dataframe.ww.name, time_type))
def _get_time_type(self, dataframe, column_name=None):
column_name = column_name or dataframe.ww.time_index
column_schema = dataframe.ww.columns[column_name]
time_type = None
if column_schema.is_numeric:
time_type = 'numeric'
elif column_schema.is_datetime:
time_type = Datetime
if time_type is None:
info = "%s time index not recognized as numeric or datetime"
raise TypeError(info % dataframe.ww.name)
return time_type
def _add_references_to_metadata(self, dataframe):
dataframe.ww.metadata.update(entityset_id=self.id)
for column in dataframe.columns:
metadata = dataframe.ww._schema.columns[column].metadata
metadata.update(dataframe_name=dataframe.ww.name)
metadata.update(entityset_id=self.id)
_ES_REF[self.id] = self
def _vals_to_series(instance_vals, column_id):
"""
instance_vals may be a pd.Dataframe, a pd.Series, a list, a single
value, or None. This function always returns a Series or None.
"""
if instance_vals is None:
return None
# If this is a single value, make it a list
if not hasattr(instance_vals, '__iter__'):
instance_vals = [instance_vals]
# convert iterable to pd.Series
if isinstance(instance_vals, pd.DataFrame):
out_vals = instance_vals[column_id]
elif is_instance(instance_vals, (pd, dd, ks), 'Series'):
out_vals = instance_vals.rename(column_id)
else:
out_vals = pd.Series(instance_vals)
# no duplicates or NaN values
out_vals = out_vals.drop_duplicates().dropna()
# want index to have no name for the merge in query_by_values
out_vals.index.name = None
return out_vals
def _get_or_create_index(index, make_index, df):
'''Handles index creation logic base on user input'''
index_was_created = False
if index is None:
# Case 1: user wanted to make index but did not specify column name
assert not make_index, "Must specify an index name if make_index is True"
# Case 2: make_index not specified but no index supplied, use first column
warnings.warn(("Using first column as index. "
"To change this, specify the index parameter"))
index = df.columns[0]
elif make_index and index in df.columns:
# Case 3: user wanted to make index but column already exists
raise RuntimeError(f"Cannot make index: column with name {index} already present")
elif index not in df.columns:
if not make_index:
# Case 4: user names index, it is not in df. does not specify
# make_index. Make new index column and warn
warnings.warn("index {} not found in dataframe, creating new "
"integer column".format(index))
# Case 5: make_index with no errors or warnings
# (Case 4 also uses this code path)
df = _create_index(df, index)
index_was_created = True
# Case 6: user specified index, which is already in df. No action needed.
return index_was_created, index, df
def _create_index(df, index):
if isinstance(df, dd.DataFrame):
df[index] = 1
df[index] = df[index].cumsum() - 1
elif is_instance(df, ks, 'DataFrame'):
df = df.koalas.attach_id_column('distributed-sequence', index)
else:
df.insert(0, index, range(len(df)))
return df